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authorArthur Heymans <arthur@aheymans.xyz>2019-11-19 15:46:49 +0100
committerKyösti Mälkki <kyosti.malkki@gmail.com>2019-11-20 19:08:30 +0000
commitffcac3eb502bbe0acbb30d6fe804f00e07461a7a (patch)
treed5deda572bb252a683a5ece24a5c4916ee198836 /src/northbridge
parent1ca978ee6529251ed80b47da679be7adc75fa46a (diff)
nb/amd/fam10: Drop support
Relocatable ramstage, postcar stage and C_ENVIRONMENT_BOOTBLOCK are now mandatory features, which this platform lacks. Change-Id: If36ef0749dbb661f731fb04829bd7e2202ebb422 Signed-off-by: Arthur Heymans <arthur@aheymans.xyz> Reviewed-on: https://review.coreboot.org/c/coreboot/+/36962 Tested-by: build bot (Jenkins) <no-reply@coreboot.org> Reviewed-by: HAOUAS Elyes <ehaouas@noos.fr> Reviewed-by: Kyösti Mälkki <kyosti.malkki@gmail.com> Reviewed-by: Angel Pons <th3fanbus@gmail.com>
Diffstat (limited to 'src/northbridge')
-rw-r--r--src/northbridge/amd/agesa/family14/acpi/northbridge.asl2
-rw-r--r--src/northbridge/amd/agesa/family14/acpi/thermal_mixin.asl (renamed from src/northbridge/amd/amdfam10/thermal_mixin.asl)0
-rw-r--r--src/northbridge/amd/amdfam10/Kconfig145
-rw-r--r--src/northbridge/amd/amdfam10/Makefile.inc34
-rw-r--r--src/northbridge/amd/amdfam10/acpi.c351
-rw-r--r--src/northbridge/amd/amdfam10/amdfam10.h1025
-rw-r--r--src/northbridge/amd/amdfam10/amdfam10_util.asl321
-rw-r--r--src/northbridge/amd/amdfam10/amdfam10_util.c112
-rw-r--r--src/northbridge/amd/amdfam10/bootblock.c22
-rw-r--r--src/northbridge/amd/amdfam10/chip.h25
-rw-r--r--src/northbridge/amd/amdfam10/debug.c324
-rw-r--r--src/northbridge/amd/amdfam10/debug.h45
-rw-r--r--src/northbridge/amd/amdfam10/early_ht.c176
-rw-r--r--src/northbridge/amd/amdfam10/early_ht.h21
-rw-r--r--src/northbridge/amd/amdfam10/get_pci1234.c132
-rw-r--r--src/northbridge/amd/amdfam10/ht_config.c229
-rw-r--r--src/northbridge/amd/amdfam10/ht_config.h54
-rw-r--r--src/northbridge/amd/amdfam10/inline_helper.c31
-rw-r--r--src/northbridge/amd/amdfam10/link_control.c153
-rw-r--r--src/northbridge/amd/amdfam10/misc_control.c261
-rw-r--r--src/northbridge/amd/amdfam10/nb_control.c85
-rw-r--r--src/northbridge/amd/amdfam10/northbridge.c1928
-rw-r--r--src/northbridge/amd/amdfam10/northbridge.h21
-rw-r--r--src/northbridge/amd/amdfam10/nums.h36
-rw-r--r--src/northbridge/amd/amdfam10/pci.c72
-rw-r--r--src/northbridge/amd/amdfam10/pci.h26
-rw-r--r--src/northbridge/amd/amdfam10/raminit.h47
-rw-r--r--src/northbridge/amd/amdfam10/raminit_amdmct.c620
-rw-r--r--src/northbridge/amd/amdfam10/raminit_sysinfo_in_ram.c81
-rw-r--r--src/northbridge/amd/amdfam10/reset_test.c136
-rw-r--r--src/northbridge/amd/amdfam10/resourcemap.c282
-rw-r--r--src/northbridge/amd/amdfam10/setup_resource_map.c184
-rw-r--r--src/northbridge/amd/amdfam10/util.c261
-rw-r--r--src/northbridge/amd/amdht/AsPsDefs.h273
-rw-r--r--src/northbridge/amd/amdht/AsPsNb.c121
-rw-r--r--src/northbridge/amd/amdht/AsPsNb.h22
-rw-r--r--src/northbridge/amd/amdht/Makefile.inc5
-rw-r--r--src/northbridge/amd/amdht/comlib.c238
-rw-r--r--src/northbridge/amd/amdht/comlib.h42
-rw-r--r--src/northbridge/amd/amdht/h3ffeat.h180
-rw-r--r--src/northbridge/amd/amdht/h3finit.c1879
-rw-r--r--src/northbridge/amd/amdht/h3finit.h620
-rw-r--r--src/northbridge/amd/amdht/h3gtopo.h355
-rw-r--r--src/northbridge/amd/amdht/h3ncmn.c2549
-rw-r--r--src/northbridge/amd/amdht/h3ncmn.h115
-rw-r--r--src/northbridge/amd/amdht/ht_wrapper.c384
-rw-r--r--src/northbridge/amd/amdht/ht_wrapper.h28
-rw-r--r--src/northbridge/amd/amdht/porting.h79
-rw-r--r--src/northbridge/amd/amdk8/amdk8.h31
-rw-r--r--src/northbridge/amd/amdk8/reset_test.c94
-rw-r--r--src/northbridge/amd/amdmct/amddefs.h158
-rw-r--r--src/northbridge/amd/amdmct/mct/Makefile.inc16
-rw-r--r--src/northbridge/amd/amdmct/mct/mct.h539
-rw-r--r--src/northbridge/amd/amdmct/mct/mct_d.c3980
-rw-r--r--src/northbridge/amd/amdmct/mct/mct_d.h804
-rw-r--r--src/northbridge/amd/amdmct/mct/mct_d_gcc.c351
-rw-r--r--src/northbridge/amd/amdmct/mct/mct_d_gcc.h48
-rw-r--r--src/northbridge/amd/amdmct/mct/mctardk3.c179
-rw-r--r--src/northbridge/amd/amdmct/mct/mctardk4.c149
-rw-r--r--src/northbridge/amd/amdmct/mct/mctchi_d.c125
-rw-r--r--src/northbridge/amd/amdmct/mct/mctcsi_d.c140
-rw-r--r--src/northbridge/amd/amdmct/mct/mctdqs_d.c1207
-rw-r--r--src/northbridge/amd/amdmct/mct/mctecc_d.c314
-rw-r--r--src/northbridge/amd/amdmct/mct/mctgr.c84
-rw-r--r--src/northbridge/amd/amdmct/mct/mcthdi.c30
-rw-r--r--src/northbridge/amd/amdmct/mct/mctmtr_d.c254
-rw-r--r--src/northbridge/amd/amdmct/mct/mctndi_d.c234
-rw-r--r--src/northbridge/amd/amdmct/mct/mctpro_d.c396
-rw-r--r--src/northbridge/amd/amdmct/mct/mctsrc.c1090
-rw-r--r--src/northbridge/amd/amdmct/mct/mctsrc1p.c91
-rw-r--r--src/northbridge/amd/amdmct/mct/mctsrc2p.c130
-rw-r--r--src/northbridge/amd/amdmct/mct/mcttmrl.c409
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/Makefile.inc31
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mct_d.c8220
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mct_d.h1165
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mct_d_gcc.c296
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mct_d_gcc.h50
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctardk5.c100
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctardk6.c114
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctchi_d.c123
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctcsi_d.c144
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctdqs_d.c2493
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctecc_d.c389
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mcthdi.c33
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mcthwl.c305
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctmtr_d.c256
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctndi_d.c233
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctprob.c45
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctproc.c113
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctprod.c66
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctrci.c474
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctsdi.c1210
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctsrc.c2438
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctsrc1p.c104
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctsrc2p.c126
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mcttmrl.c398
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mctwl.c509
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mhwlc_d.c1519
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/modtrd.c95
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/modtrdim.c262
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mport_d.c42
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mutilc_d.c374
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/mwlc_d.h192
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/s3utils.c1237
-rw-r--r--src/northbridge/amd/amdmct/mct_ddr3/s3utils.h31
-rw-r--r--src/northbridge/amd/amdmct/wrappers/Makefile.inc5
-rw-r--r--src/northbridge/amd/amdmct/wrappers/mcti.h153
-rw-r--r--src/northbridge/amd/amdmct/wrappers/mcti_d.c543
108 files changed, 1 insertions, 48872 deletions
diff --git a/src/northbridge/amd/agesa/family14/acpi/northbridge.asl b/src/northbridge/amd/agesa/family14/acpi/northbridge.asl
index e95c95a019..06199a1b07 100644
--- a/src/northbridge/amd/agesa/family14/acpi/northbridge.asl
+++ b/src/northbridge/amd/agesa/family14/acpi/northbridge.asl
@@ -128,5 +128,5 @@ Device(NBF3) {
Name(_ADR, 0x00180003)
/* k10temp thermal zone */
- #include <northbridge/amd/amdfam10/thermal_mixin.asl>
+ #include "thermal_mixin.asl"
} /* end NBF3 */
diff --git a/src/northbridge/amd/amdfam10/thermal_mixin.asl b/src/northbridge/amd/agesa/family14/acpi/thermal_mixin.asl
index fb33772c1e..fb33772c1e 100644
--- a/src/northbridge/amd/amdfam10/thermal_mixin.asl
+++ b/src/northbridge/amd/agesa/family14/acpi/thermal_mixin.asl
diff --git a/src/northbridge/amd/amdfam10/Kconfig b/src/northbridge/amd/amdfam10/Kconfig
deleted file mode 100644
index 64358875f1..0000000000
--- a/src/northbridge/amd/amdfam10/Kconfig
+++ /dev/null
@@ -1,145 +0,0 @@
-##
-## This file is part of the coreboot project.
-##
-## Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
-## Copyright (C) 2007-2009 coresystems GmbH
-##
-## This program is free software; you can redistribute it and/or modify
-## it under the terms of the GNU General Public License as published by
-## the Free Software Foundation; version 2 of the License.
-##
-## This program is distributed in the hope that it will be useful,
-## but WITHOUT ANY WARRANTY; without even the implied warranty of
-## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
-## GNU General Public License for more details.
-##
-
-config NORTHBRIDGE_AMD_AMDFAM10
- bool
- select HAVE_DEBUG_RAM_SETUP
- select HAVE_DEBUG_SMBUS
- select HAVE_DEBUG_CAR
- select HYPERTRANSPORT_PLUGIN_SUPPORT
- select PCIEXP_ASPM
- select PCIEXP_COMMON_CLOCK
- select PCIEXP_CLK_PM
- select PCIEXP_L1_SUB_STATE
- select NO_RELOCATABLE_RAMSTAGE
-
-if NORTHBRIDGE_AMD_AMDFAM10
-config AGP_APERTURE_SIZE
- hex
- default 0x4000000
-
-config HW_MEM_HOLE_SIZEK
- hex
- default 0x100000
-
-config MMCONF_BASE_ADDRESS
- hex
- default 0xc0000000
-
-config MMCONF_BUS_NUMBER
- int
- default 256
-
-# TODO: Reservation for heap seems excessive
-config HEAP_SIZE
- hex
- default 0xc0000
-
-config BOOTBLOCK_NORTHBRIDGE_INIT
- string
- default "northbridge/amd/amdfam10/bootblock.c"
-
-config SB_HT_CHAIN_UNITID_OFFSET_ONLY
- bool
- default n
-
-config HT_CHAIN_DISTRIBUTE
- def_bool n
-
-config DIMM_DDR2
- bool
- default n
-
-config DIMM_DDR3
- bool
- default n
-
-config DIMM_REGISTERED
- bool
- default n
-
-config DIMM_VOLTAGE_SET_SUPPORT
- bool
- default n
-
-config S3_DATA_SIZE
- int
- default 32768
- depends on (HAVE_ACPI_RESUME)
-
-config S3_DATA_POS
- hex
- default 0x0
- depends on (HAVE_ACPI_RESUME)
-
-config SVI_HIGH_FREQ
- bool
- default n
- help
- Select this for boards with a Voltage Regulator able to operate
- at 3.4 MHz in SVI mode. Ignored unless the AMD CPU is rev C3.
-
-menu "HyperTransport setup"
- #could be implemented for K8 (NORTHBRIDGE_AMD_AMDK8)
- depends on (NORTHBRIDGE_AMD_AMDFAM10)
-
-choice
- prompt "HyperTransport downlink width"
- default LIMIT_HT_DOWN_WIDTH_16
- help
- This option sets the maximum permissible HyperTransport
- downlink width.
-
- Use of this option will only limit the autodetected HT width.
- It will not (and cannot) increase the width beyond the autodetected
- limits.
-
- This is primarily used to work around poorly designed or laid out HT
- traces on certain motherboards.
-
-config LIMIT_HT_DOWN_WIDTH_8
- bool "8 bits"
-config LIMIT_HT_DOWN_WIDTH_16
- bool "16 bits"
-endchoice
-
-choice
- prompt "HyperTransport uplink width"
- default LIMIT_HT_UP_WIDTH_16
- help
- This option sets the maximum permissible HyperTransport
- uplink width.
-
- Use of this option will only limit the autodetected HT width.
- It will not (and cannot) increase the width beyond the autodetected
- limits.
-
- This is primarily used to work around poorly designed or laid out HT
- traces on certain motherboards.
-
-config LIMIT_HT_UP_WIDTH_8
- bool "8 bits"
-config LIMIT_HT_UP_WIDTH_16
- bool "16 bits"
-endchoice
-
-endmenu
-
-config MAX_REBOOT_CNT
- int
- default 6
-
-endif # NORTHBRIDGE_AMD_AMDFAM10
diff --git a/src/northbridge/amd/amdfam10/Makefile.inc b/src/northbridge/amd/amdfam10/Makefile.inc
deleted file mode 100644
index 787f4444ce..0000000000
--- a/src/northbridge/amd/amdfam10/Makefile.inc
+++ /dev/null
@@ -1,34 +0,0 @@
-ifeq ($(CONFIG_NORTHBRIDGE_AMD_AMDFAM10),y)
-
-subdirs-y += ../amdht
-subdirs-y += ../amdmct/wrappers
-subdirs-$(CONFIG_DIMM_DDR3) += ../amdmct/mct_ddr3
-subdirs-$(CONFIG_DIMM_DDR2) += ../amdmct/mct
-
-# Generic ROMSTAGE stuff
-romstage-y += reset_test.c debug.c setup_resource_map.c raminit_sysinfo_in_ram.c
-romstage-y += raminit_amdmct.c pci.c early_ht.c amdfam10_util.c
-
-# RAMSTAGE
-ramstage-y += northbridge.c misc_control.c link_control.c nb_control.c
-ramstage-y += amdfam10_util.c ht_config.c get_pci1234.c
-ramstage-$(CONFIG_HAVE_ACPI_TABLES) += acpi.c
-
-# Enable this if you want to check the values of the PCI routing registers.
-# Call show_all_routes() anywhere amdfam10.h is included.
-#ramstage-y += util.c
-
-# Reserve 2x CONFIG_S3_DATA_SIZE to allow for random file placement
-# (not respecting erase sector boundaries) within CBFS
-$(obj)/coreboot_s3nv.rom: $(obj)/config.h
- echo " S3 NVRAM $(CONFIG_S3_DATA_POS) (S3 storage area)"
- # force C locale, so cygwin awk doesn't try to interpret the 0xff below as UTF-8 (or worse)
- printf %d $(CONFIG_S3_DATA_SIZE) | LC_ALL=C awk '{for (i=0; i<$$1*2; i++) {printf "%c", 255}}' > $@.tmp
- mv $@.tmp $@
-
-cbfs-files-$(CONFIG_HAVE_ACPI_RESUME) += s3nv
-s3nv-file := $(obj)/coreboot_s3nv.rom
-s3nv-align := $(CONFIG_S3_DATA_SIZE)
-s3nv-type := raw
-
-endif
diff --git a/src/northbridge/amd/amdfam10/acpi.c b/src/northbridge/amd/amdfam10/acpi.c
deleted file mode 100644
index dc139adb87..0000000000
--- a/src/northbridge/amd/amdfam10/acpi.c
+++ /dev/null
@@ -1,351 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <console/console.h>
-#include <string.h>
-#include <arch/acpi.h>
-#include <arch/acpigen.h>
-#include <device/pci.h>
-#include <cpu/x86/msr.h>
-#include <cpu/amd/mtrr.h>
-#include <cpu/amd/amdfam10_sysconf.h>
-#include "amdfam10.h"
-
-//it seems some functions can be moved arch/x86/boot/acpi.c
-
-unsigned long acpi_create_madt_lapic_nmis(unsigned long current, u16 flags, u8 lint)
-{
- struct device *cpu;
- int cpu_index = 0;
-
- for (cpu = all_devices; cpu; cpu = cpu->next) {
- if ((cpu->path.type != DEVICE_PATH_APIC) ||
- (cpu->bus->dev->path.type != DEVICE_PATH_CPU_CLUSTER)) {
- continue;
- }
- if (!cpu->enabled) {
- continue;
- }
- current += acpi_create_madt_lapic_nmi((acpi_madt_lapic_nmi_t *)current, cpu_index, flags, lint);
- cpu_index++;
- }
- return current;
-}
-
-unsigned long acpi_create_srat_lapics(unsigned long current)
-{
- struct device *cpu;
- int cpu_index = 0;
-
- for (cpu = all_devices; cpu; cpu = cpu->next) {
- if ((cpu->path.type != DEVICE_PATH_APIC) ||
- (cpu->bus->dev->path.type != DEVICE_PATH_CPU_CLUSTER)) {
- continue;
- }
- if (!cpu->enabled) {
- continue;
- }
- printk(BIOS_DEBUG, "SRAT: lapic cpu_index=%02x, node_id=%02x, apic_id=%02x\n", cpu_index, cpu->path.apic.node_id, cpu->path.apic.apic_id);
- current += acpi_create_srat_lapic((acpi_srat_lapic_t *)current, cpu->path.apic.node_id, cpu->path.apic.apic_id);
- cpu_index++;
- }
- return current;
-}
-
-static unsigned long resk(uint64_t value)
-{
- unsigned long resultk;
- if (value < (1ULL << 42)) {
- resultk = value >> 10;
- } else {
- resultk = 0xffffffff;
- }
- return resultk;
-}
-
-struct acpi_srat_mem_state {
- unsigned long current;
-};
-
-static void set_srat_mem(void *gp, struct device *dev, struct resource *res)
-{
- struct acpi_srat_mem_state *state = gp;
- unsigned long basek, sizek;
- basek = resk(res->base);
- sizek = resk(res->size);
-
- printk(BIOS_DEBUG, "set_srat_mem: dev %s, res->index=%04lx startk=%08lx, sizek=%08lx\n",
- dev_path(dev), res->index, basek, sizek);
- /*
- * 0-640K must be on node 0
- * next range is from 1M---
- * So will cut off before 1M in the mem range
- */
- if ((basek+sizek)<1024) return;
-
- if (basek < 1024) {
- sizek -= 1024 - basek;
- basek = 1024;
- }
-
- // need to figure out NV
- if (res->index > 0xf) /* Exclude MMIO resources, e.g. as set in northbridge.c amdfam10_domain_read_resources() */
- state->current += acpi_create_srat_mem((acpi_srat_mem_t *)state->current, (res->index & 0xf), basek, sizek, 1);
-}
-
-static unsigned long acpi_fill_srat(unsigned long current)
-{
- struct acpi_srat_mem_state srat_mem_state;
-
- /* create all subtables for processors */
- current = acpi_create_srat_lapics(current);
-
- /* create all subteble for memory range */
-
- /* 0-640K must be on node 0 */
- current += acpi_create_srat_mem((acpi_srat_mem_t *)current, 0, 0, 640, 1);//enable
-
- srat_mem_state.current = current;
- search_global_resources(
- IORESOURCE_MEM | IORESOURCE_CACHEABLE, IORESOURCE_MEM | IORESOURCE_CACHEABLE,
- set_srat_mem, &srat_mem_state);
-
- current = srat_mem_state.current;
- return current;
-}
-
-static unsigned long acpi_fill_slit(unsigned long current)
-{
- /* Implement SLIT algorithm in BKDG Rev. 3.62 Section 2.3.6.1
- * Fill the first 8 bytes with the node number,
- * then fill the next num*num byte with the distance,
- * Distance entries vary with topology; the local node
- * is always 10.
- *
- * Fully connected:
- * Set all non-local nodes to 16
- *
- * Partially connected; with probe filter:
- * Set all non-local nodes to 10+(num_hops*6)
- *
- * Partially connected; without probe filter:
- * Set all non-local nodes to 13
- *
- * FIXME
- * The partially connected cases are not implemented;
- * once a means is found to detect partially connected
- * topologies, implement the remaining cases.
- */
-
- u8 *p = (u8 *)current;
- int nodes = sysconf.nodes;
- int i,j;
-
- memset(p, 0, 8+nodes*nodes);
- *p = (u8) nodes;
- p += 8;
-
- for (i = 0; i < nodes; i++) {
- for (j = 0; j < nodes; j++) {
- if (i == j)
- p[i*nodes+j] = 10;
- else
- p[i*nodes+j] = 16;
- }
- }
-
- current += 8+nodes*nodes;
- return current;
-}
-
-void update_ssdtx(void *ssdtx, int i)
-{
- u8 *PCI;
- u8 *HCIN;
- u8 *UID;
-
- PCI = ssdtx + 0x32;
- HCIN = ssdtx + 0x39;
- UID = ssdtx + 0x40;
-
- if (i < 7) {
- *PCI = (u8) ('4' + i - 1);
- } else {
- *PCI = (u8) ('A' + i - 1 - 6);
- }
- *HCIN = (u8) i;
- *UID = (u8) (i + 3);
-
- /* FIXME: need to update the GSI id in the ssdtx too */
-
-}
-
-void northbridge_acpi_write_vars(struct device *device)
-{
- /*
- * If more than one physical CPU is installed, northbridge_acpi_write_vars()
- * is called more than once and the resultant SSDT table is corrupted
- * (duplicated entries).
- * This prevents Linux from booting, with log messages like these:
- * ACPI Error: [BUSN] Namespace lookup failure, AE_ALREADY_EXISTS (/dswload-353)
- * ACPI Exception: AE_ALREADY_EXISTS, During name lookup/catalog (/psobject-222)
- * followed by a slew of ACPI method failures and a hang when the invalid PCI
- * resource entries are used.
- * This routine prevents the SSDT table from being corrupted.
- */
- static uint8_t ssdt_generated = 0;
- if (ssdt_generated)
- return;
- ssdt_generated = 1;
-
- msr_t msr;
- char pscope[] = "\\_SB.PCI0";
- int i;
-
- acpigen_write_scope(pscope);
-
- acpigen_write_name("BUSN");
- acpigen_write_package(HC_NUMS);
- for (i = 0; i < HC_NUMS; i++) {
- acpigen_write_dword(sysconf.ht_c_conf_bus[i]);
- }
- // minus the opcode
- acpigen_pop_len();
-
- acpigen_write_name("MMIO");
-
- acpigen_write_package(HC_NUMS * 4);
-
- for (i = 0; i<(HC_NUMS*2); i++) { // FIXME: change to more chain
- acpigen_write_dword(sysconf.conf_mmio_addrx[i]); //base
- acpigen_write_dword(sysconf.conf_mmio_addr[i]); //mask
- }
- // minus the opcode
- acpigen_pop_len();
-
- acpigen_write_name("PCIO");
-
- acpigen_write_package(HC_NUMS * 2);
-
- for (i = 0; i < HC_NUMS; i++) { // FIXME: change to more chain
- acpigen_write_dword(sysconf.conf_io_addrx[i]);
- acpigen_write_dword(sysconf.conf_io_addr[i]);
- }
-
- // minus the opcode
- acpigen_pop_len();
-
- acpigen_write_name_byte("SBLK", sysconf.sblk);
-
- msr = rdmsr(TOP_MEM);
- acpigen_write_name_dword("TOM1", msr.lo);
-
- msr = rdmsr(TOP_MEM2);
- /*
- * Since XP only implements parts of ACPI 2.0, we can't use a qword
- * here.
- * See http://www.acpi.info/presentations/S01USMOBS169_OS%2520new.ppt
- * slide 22ff.
- * Shift value right by 20 bit to make it fit into 32bit,
- * giving us 1MB granularity and a limit of almost 4Exabyte of memory.
- */
- acpigen_write_name_dword("TOM2", (msr.hi << 12) | msr.lo >> 20);
-
-
- acpigen_write_name_dword("SBDN", sysconf.sbdn);
-
- acpigen_write_name("HCLK");
-
- acpigen_write_package(HC_POSSIBLE_NUM);
-
- for (i = 0; i < sysconf.hc_possible_num; i++) {
- acpigen_write_dword(sysconf.pci1234[i]);
- }
- for (i = sysconf.hc_possible_num; i < HC_POSSIBLE_NUM; i++) { // in case we set array size to other than 8
- acpigen_write_dword(0x00000000);
- }
- // minus the opcode
- acpigen_pop_len();
-
- acpigen_write_name("HCDN");
-
- acpigen_write_package(HC_POSSIBLE_NUM);
-
- for (i = 0; i < sysconf.hc_possible_num; i++) {
- acpigen_write_dword(sysconf.hcdn[i]);
- }
- for (i = sysconf.hc_possible_num; i < HC_POSSIBLE_NUM; i++) { // in case we set array size to other than 8
- acpigen_write_dword(0x20202020);
- }
- // minus the opcode
- acpigen_pop_len();
-
- acpigen_write_name_byte("CBB", CONFIG_CBB);
-
- u8 CBST, CBB2, CBS2;
-
- if (CONFIG_CBB == 0xff) {
- CBST = (u8) (0x0f);
- } else {
- if ((sysconf.pci1234[0] >> 12) & 0xff) { //sb chain on other than bus 0
- CBST = (u8) (0x0f);
- } else {
- CBST = (u8) (0x00);
- }
- }
-
- acpigen_write_name_byte("CBST", CBST);
-
- if ((CONFIG_CBB == 0xff) && (sysconf.nodes > 32)) {
- CBS2 = 0x0f;
- CBB2 = (u8)(CONFIG_CBB-1);
- } else {
- CBS2 = 0x00;
- CBB2 = 0x00;
- }
-
- acpigen_write_name_byte("CBB2", CBB2);
- acpigen_write_name_byte("CBS2", CBS2);
-
- //minus opcode
- acpigen_pop_len();
-}
-
-unsigned long northbridge_write_acpi_tables(struct device *device,
- unsigned long current,
- struct acpi_rsdp *rsdp)
-{
- acpi_srat_t *srat;
- acpi_slit_t *slit;
-
- /* SRAT */
- current = ALIGN(current, 8);
- printk(BIOS_DEBUG, "ACPI: * SRAT at %lx\n", current);
- srat = (acpi_srat_t *) current;
- acpi_create_srat(srat, acpi_fill_srat);
- current += srat->header.length;
- acpi_add_table(rsdp, srat);
-
- /* SLIT */
- current = ALIGN(current, 8);
- printk(BIOS_DEBUG, "ACPI: * SLIT at %lx\n", current);
- slit = (acpi_slit_t *) current;
- acpi_create_slit(slit, acpi_fill_slit);
- current += slit->header.length;
- acpi_add_table(rsdp, slit);
-
- return current;
-}
diff --git a/src/northbridge/amd/amdfam10/amdfam10.h b/src/northbridge/amd/amdfam10/amdfam10.h
deleted file mode 100644
index ad8d01365d..0000000000
--- a/src/northbridge/amd/amdfam10/amdfam10.h
+++ /dev/null
@@ -1,1025 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef AMDFAM10_H
-#define AMDFAM10_H
-
-#include <stdint.h>
-#include <device/device.h>
-#include "early_ht.h"
-
-#include "inline_helper.c"
-struct DCTStatStruc;
-struct MCTStatStruc;
-
-
-/* Definitions for setup_resourcemap() variants. */
-
-#define PCI_ADDR(SEGBUS, DEV, FN, WHERE) ( \
- (((SEGBUS) & 0xFFF) << 20) | \
- (((DEV) & 0x1F) << 15) | \
- (((FN) & 0x07) << 12) | \
- ((WHERE) & 0xFFF))
-
-#define ADDRMAP_REG(r) PCI_ADDR(CONFIG_CBB, CONFIG_CDB, 1, r)
-
-#define RES_PCI_IO 0x10
-#define RES_PORT_IO_8 0x22
-#define RES_PORT_IO_32 0x20
-#define RES_MEM_IO 0x40
-
-#define NODE_ID 0x60
-#define HT_INIT_CONTROL 0x6c
-#define HTIC_ColdR_Detect (1<<4)
-#define HTIC_BIOSR_Detect (1<<5)
-#define HTIC_INIT_Detect (1<<6)
-
-/* Definitions of various FAM10 registers */
-/* Function 0 */
-#define HT_TRANSACTION_CONTROL 0x68
-#define HTTC_DIS_RD_B_P (1 << 0)
-#define HTTC_DIS_RD_DW_P (1 << 1)
-#define HTTC_DIS_WR_B_P (1 << 2)
-#define HTTC_DIS_WR_DW_P (1 << 3)
-#define HTTC_DIS_MTS (1 << 4)
-#define HTTC_CPU1_EN (1 << 5)
-#define HTTC_CPU_REQ_PASS_PW (1 << 6)
-#define HTTC_CPU_RD_RSP_PASS_PW (1 << 7)
-#define HTTC_DIS_P_MEM_C (1 << 8)
-#define HTTC_DIS_RMT_MEM_C (1 << 9)
-#define HTTC_DIS_FILL_P (1 << 10)
-#define HTTC_RSP_PASS_PW (1 << 11)
-#define HTTC_BUF_REL_PRI_SHIFT 13
-#define HTTC_BUF_REL_PRI_MASK 3
-#define HTTC_BUF_REL_PRI_64 0
-#define HTTC_BUF_REL_PRI_16 1
-#define HTTC_BUF_REL_PRI_8 2
-#define HTTC_BUF_REL_PRI_2 3
-#define HTTC_LIMIT_CLDT_CFG (1 << 15)
-#define HTTC_LINT_EN (1 << 16)
-#define HTTC_APIC_EXT_BRD_CST (1 << 17)
-#define HTTC_APIC_EXT_ID (1 << 18)
-#define HTTC_APIC_EXT_SPUR (1 << 19)
-#define HTTC_SEQ_ID_SRC_NODE_EN (1 << 20)
-#define HTTC_DS_NP_REQ_LIMIT_SHIFT 21
-#define HTTC_DS_NP_REQ_LIMIT_MASK 3
-#define HTTC_DS_NP_REQ_LIMIT_NONE 0
-#define HTTC_DS_NP_REQ_LIMIT_1 1
-#define HTTC_DS_NP_REQ_LIMIT_4 2
-#define HTTC_DS_NP_REQ_LIMIT_8 3
-
-
-/* Function 1 */
-#define PCI_IO_BASE0 0xc0
-#define PCI_IO_BASE1 0xc8
-#define PCI_IO_BASE2 0xd0
-#define PCI_IO_BASE3 0xd8
-#define PCI_IO_BASE_VGA_EN (1 << 4)
-#define PCI_IO_BASE_NO_ISA (1 << 5)
-
-/* Function 2 */
-// 0x1xx is for DCT1
-#define DRAM_CSBASE 0x40
-#define DRAM_CSMASK 0x60
-#define DRAM_BANK_ADDR_MAP 0x80
-
-#define DRAM_CTRL 0x78
-#define DC_RdPtrInit_SHIFT 0
-#define DC_RdPrtInit_MASK 0xf
-#define DC_Twrrd3_2_SHIFT 8 /*DDR3 */
-#define DC_Twrrd3_2_MASK 3
-#define DC_Twrwr3_2_SHIFT 10 /*DDR3 */
-#define DC_Twrwr3_2_MASK 3
-#define DC_Trdrd3_2_SHIFT 12 /*DDR3 */
-#define DC_Trdrd3_2_MASK 3
-#define DC_AltVidC3MemClkTriEn (1<<16)
-#define DC_DqsRcvEnTrain (1<<18)
-#define DC_MaxRdLatency_SHIFT 22
-#define DC_MaxRdLatency_MASK 0x3ff
-
-#define DRAM_INIT 0x7c
-#define DI_MrsAddress_SHIFT 0
-#define DI_MrsAddress_MASK 0xffff
-#define DI_MrsBank_SHIFT 16
-#define DI_MrsBank_MASK 7
-#define DI_MrsChipSel_SHIFT 20
-#define DI_MrsChipSel_MASK 7
-#define DI_SendRchgAll (1<<24)
-#define DI_SendAutoRefresh (1<<25)
-#define DI_SendMrsCmd (1<<26)
-#define DI_DeassertMemRstX (1<<27)
-#define DI_AssertCke (1<<28)
-#define DI_SendZQCmd (1<<29) /*DDR3 */
-#define DI_EnMrsCmd (1<<30)
-#define DI_EnDramInit (1<<31)
-
-#define DRAM_MRS 0x84
-#define DM_BurstCtrl_SHIFT 0
-#define DM_BurstCtrl_MASK 3
-#define DM_DrvImpCtrl_SHIFT 2 /* DDR3 */
-#define DM_DrvImpCtrl_MASK 3
-#define DM_Twr_SHIFT 4 /* DDR3 */
-#define DM_Twr_MASK 7
-#define DM_Twr_BASE 4
-#define DM_Twr_MIN 5
-#define DM_Twr_MAX 12
-#define DM_DramTerm_SHIFT 7 /*DDR3 */
-#define DM_DramTerm_MASK 7
-#define DM_DramTermDyn_SHIFT 10 /* DDR3 */
-#define DM_DramTermDyn_MASK 3
-#define DM_Ooff (1<<13)
-#define DM_ASR (1<<18)
-#define DM_SRT (1<<19)
-#define DM_Tcwl_SHIFT 20
-#define DM_Tcwl_MASK 7
-#define DM_PchgPDModeSel (1<<23) /* DDR3 */
-#define DM_MPrLoc_SHIFT 24 /* DDR3 */
-#define DM_MPrLoc_MASK 3
-#define DM_MprEn (1<<26) /* DDR3 */
-
-#define DRAM_TIMING_LOW 0x88
-#define DTL_TCL_SHIFT 0
-#define DTL_TCL_MASK 0xf
-#define DTL_TCL_BASE 1 /* DDR3 =4 */
-#define DTL_TCL_MIN 3 /* DDR3 =4 */
-#define DTL_TCL_MAX 6 /* DDR3 =12 */
-#define DTL_TRCD_SHIFT 4
-#define DTL_TRCD_MASK 3 /* DDR3 =7 */
-#define DTL_TRCD_BASE 3 /* DDR3 =5 */
-#define DTL_TRCD_MIN 3 /* DDR3 =5 */
-#define DTL_TRCD_MAX 6 /* DDR3 =12 */
-#define DTL_TRP_SHIFT 8 /* DDR3 =7 */
-#define DTL_TRP_MASK 3 /* DDR3 =7 */
-#define DTL_TRP_BASE 3 /* DDR3 =5 */
-#define DTL_TRP_MIN 3 /* DDR3 =5 */
-#define DTL_TRP_MAX 6 /* DDR3 =12 */
-#define DTL_TRTP_SHIFT 11 /*DDR3 =10 */
-#define DTL_TRTP_MASK 1 /*DDR3 =3 */
-#define DTL_TRTP_BASE 2 /* DDR3 =4 */
-#define DTL_TRTP_MIN 2 /* 4 for 64 bytes*/ /* DDR3 =4 for 32bytes or 64bytes */
-#define DTL_TRTP_MAX 3 /* 5 for 64 bytes */ /* DDR3 =7 for 32Bytes or 64bytes */
-#define DTL_TRAS_SHIFT 12
-#define DTL_TRAS_MASK 0xf
-#define DTL_TRAS_BASE 3 /* DDR3 =15 */
-#define DTL_TRAS_MIN 5 /* DDR3 =15 */
-#define DTL_TRAS_MAX 18 /*DDR3 =30 */
-#define DTL_TRC_SHIFT 16
-#define DTL_TRC_MASK 0xf /* DDR3 =0x1f */
-#define DTL_TRC_BASE 11
-#define DTL_TRC_MIN 11
-#define DTL_TRC_MAX 26 /* DDR3 =43 */
-#define DTL_TWR_SHIFT 20 /* only for DDR2, DDR3's is on DC */
-#define DTL_TWR_MASK 3
-#define DTL_TWR_BASE 3
-#define DTL_TWR_MIN 3
-#define DTL_TWR_MAX 6
-#define DTL_TRRD_SHIFT 22
-#define DTL_TRRD_MASK 3
-#define DTL_TRRD_BASE 2 /* DDR3 =4 */
-#define DTL_TRRD_MIN 2 /* DDR3 =4 */
-#define DTL_TRRD_MAX 5 /* DDR3 =7 */
-#define DTL_MemClkDis_SHIFT 24 /* Channel A */
-#define DTL_MemClkDis3 (1 << 26)
-#define DTL_MemClkDis2 (1 << 27)
-#define DTL_MemClkDis1 (1 << 28)
-#define DTL_MemClkDis0 (1 << 29)
-/* DTL_MemClkDis for m2 and s1g1 is different */
-
-#define DRAM_TIMING_HIGH 0x8c
-#define DTH_TRWTWB_SHIFT 0
-#define DTH_TRWTWB_MASK 3
-#define DTH_TRWTWB_BASE 3 /* DDR3 =4 */
-#define DTH_TRWTWB_MIN 3 /* DDR3 =5 */
-#define DTH_TRWTWB_MAX 10 /* DDR3 =11 */
-#define DTH_TRWTTO_SHIFT 4
-#define DTH_TRWTTO_MASK 7
-#define DTH_TRWTTO_BASE 2 /* DDR3 =3 */
-#define DTH_TRWTTO_MIN 2 /* DDR3 =3 */
-#define DTH_TRWTTO_MAX 9 /* DDR3 =10 */
-#define DTH_TWTR_SHIFT 8
-#define DTH_TWTR_MASK 3
-#define DTH_TWTR_BASE 0 /* DDR3 =4 */
-#define DTH_TWTR_MIN 1 /* DDR3 =4 */
-#define DTH_TWTR_MAX 3 /* DDR3 =7 */
-#define DTH_TWRRD_SHIFT 10
-#define DTH_TWRRD_MASK 3 /* For DDR3 3_2 is at 0x78 DC */
-#define DTH_TWRRD_BASE 0 /* DDR3 =0 */
-#define DTH_TWRRD_MIN 0 /* DDR3 =2 */
-#define DTH_TWRRD_MAX 3 /* DDR3 =12 */
-#define DTH_TWRWR_SHIFT 12
-#define DTH_TWRWR_MASK 3 /* For DDR3 3_2 is at 0x78 DC */
-#define DTH_TWRWR_BASE 1
-#define DTH_TWRWR_MIN 1 /* DDR3 =3 */
-#define DTH_TWRWR_MAX 3 /* DDR3 =12 */
-#define DTH_TRDRD_SHIFT 14
-#define DTH_TRDRD_MASK 3 /* For DDR3 3_2 is at 0x78 DC */
-#define DTH_TRDRD_BASE 2
-#define DTH_TRDRD_MIN 2
-#define DTH_TRDRD_MAX 5 /* DDR3 =10 */
-#define DTH_TREF_SHIFT 16
-#define DTH_TREF_MASK 3
-#define DTH_TREF_7_8_US 2
-#define DTH_TREF_3_9_US 3
-#define DTH_DisAutoRefresh (1<<18)
-#define DTH_TRFC0_SHIFT 20 /* for Logical DIMM0 */
-#define DTH_TRFC_MASK 7
-#define DTH_TRFC_75_256M 0
-#define DTH_TRFC_105_512M 1
-#define DTH_TRFC_127_5_1G 2
-#define DTH_TRFC_195_2G 3
-#define DTH_TRFC_327_5_4G 4
-#define DTH_TRFC1_SHIFT 23 /*for Logical DIMM1 */
-#define DTH_TRFC2_SHIFT 26 /*for Logical DIMM2 */
-#define DTH_TRFC3_SHIFT 29 /*for Logical DIMM3 */
-
-#define DRAM_CONFIG_LOW 0x90
-#define DCL_InitDram (1<<0)
-#define DCL_ExitSelfRef (1<<1)
-#define DCL_PllLockTime_SHIFT 2
-#define DCL_PllLockTime_MASK 3
-#define DCL_PllLockTime_15US 0
-#define DCL_PllLockTime_6US 1
-#define DCL_DramTerm_SHIFT 4
-#define DCL_DramTerm_MASK 3
-#define DCL_DramTerm_No 0
-#define DCL_DramTerm_75_OH 1
-#define DCL_DramTerm_150_OH 2
-#define DCL_DramTerm_50_OH 3
-#define DCL_DisDqsBar (1<<6) /* only for DDR2 */
-#define DCL_DramDrvWeak (1<<7) /* only for DDR2 */
-#define DCL_ParEn (1<<8)
-#define DCL_SelfRefRateEn (1<<9) /* only for DDR2 */
-#define DCL_BurstLength32 (1<<10) /* only for DDR3 */
-#define DCL_Width128 (1<<11)
-#define DCL_X4Dimm_SHIFT 12
-#define DCL_X4Dimm_MASK 0xf
-#define DCL_UnBuffDimm (1<<16)
-#define DCL_EnPhyDqsRcvEnTr (1<<18)
-#define DCL_DimmEccEn (1<<19)
-#define DCL_DynPageCloseEn (1<<20)
-#define DCL_IdleCycInit_SHIFT 21
-#define DCL_IdleCycInit_MASK 3
-#define DCL_IdleCycInit_16CLK 0
-#define DCL_IdleCycInit_32CLK 1
-#define DCL_IdleCycInit_64CLK 2
-#define DCL_IdleCycInit_96CLK 3
-#define DCL_ForceAutoPchg (1<<23)
-
-#define DRAM_CONFIG_HIGH 0x94
-#define DCH_MemClkFreq_SHIFT 0
-#define DCH_MemClkFreq_MASK 7
-#define DCH_MemClkFreq_200MHz 0 /* DDR2 */
-#define DCH_MemClkFreq_266MHz 1 /* DDR2 */
-#define DCH_MemClkFreq_333MHz 2 /* DDR2 */
-#define DCH_MemClkFreq_400MHz 3 /* DDR2 and DDR 3*/
-#define DCH_MemClkFreq_533MHz 4 /* DDR 3 */
-#define DCH_MemClkFreq_667MHz 5 /* DDR 3 */
-#define DCH_MemClkFreq_800MHz 6 /* DDR 3 */
-#define DCH_MemClkFreqVal (1<<3)
-#define DCH_Ddr3Mode (1<<8)
-#define DCH_LegacyBiosMode (1<<9)
-#define DCH_ZqcsInterval_SHIFT 10
-#define DCH_ZqcsInterval_MASK 3
-#define DCH_ZqcsInterval_DIS 0
-#define DCH_ZqcsInterval_64MS 1
-#define DCH_ZqcsInterval_128MS 2
-#define DCH_ZqcsInterval_256MS 3
-#define DCH_RDqsEn (1<<12) /* only for DDR2 */
-#define DCH_DisSimulRdWr (1<<13)
-#define DCH_DisDramInterface (1<<14)
-#define DCH_PowerDownEn (1<<15)
-#define DCH_PowerDownMode_SHIFT 16
-#define DCH_PowerDownMode_MASK 1
-#define DCH_PowerDownMode_Channel_CKE 0
-#define DCH_PowerDownMode_ChipSelect_CKE 1
-#define DCH_FourRankSODimm (1<<17)
-#define DCH_FourRankRDimm (1<<18)
-#define DCH_SlowAccessMode (1<<20)
-#define DCH_BankSwizzleMode (1<<22)
-#define DCH_DcqBypassMax_SHIFT 24
-#define DCH_DcqBypassMax_MASK 0xf
-#define DCH_DcqBypassMax_BASE 0
-#define DCH_DcqBypassMax_MIN 0
-#define DCH_DcqBypassMax_MAX 15
-#define DCH_FourActWindow_SHIFT 28
-#define DCH_FourActWindow_MASK 0xf
-#define DCH_FourActWindow_BASE 7 /* DDR3 15 */
-#define DCH_FourActWindow_MIN 8 /* DDR3 16 */
-#define DCH_FourActWindow_MAX 20 /* DDR3 30 */
-
-
-// for 0x98 index and 0x9c data for DCT0
-// for 0x198 index and 0x19c data for DCT1
-// even at ganged mode, 0x198/0x19c will be used for channel B
-
-#define DRAM_CTRL_ADDI_DATA_OFFSET 0x98
-#define DCAO_DctOffset_SHIFT 0
-#define DCAO_DctOffset_MASK 0x3fffffff
-#define DCAO_DctAccessWrite (1<<30)
-#define DCAO_DctAccessDone (1<<31)
-
-#define DRAM_CTRL_ADDI_DATA_PORT 0x9c
-
-#define DRAM_OUTPUT_DRV_COMP_CTRL 0x00
-#define DODCC_CkeDrvStren_SHIFT 0
-#define DODCC_CkeDrvStren_MASK 3
-#define DODCC_CkeDrvStren_1_0X 0
-#define DODCC_CkeDrvStren_1_25X 1
-#define DODCC_CkeDrvStren_1_5X 2
-#define DODCC_CkeDrvStren_2_0X 3
-#define DODCC_CsOdtDrvStren_SHIFT 4
-#define DODCC_CsOdtDrvStren_MASK 3
-#define DODCC_CsOdtDrvStren_1_0X 0
-#define DODCC_CsOdtDrvStren_1_25X 1
-#define DODCC_CsOdtDrvStren_1_5X 2
-#define DODCC_CsOdtDrvStren_2_0X 3
-#define DODCC_AddrCmdDrvStren_SHIFT 8
-#define DODCC_AddrCmdDrvStren_MASK 3
-#define DODCC_AddrCmdDrvStren_1_0X 0
-#define DODCC_AddrCmdDrvStren_1_25X 1
-#define DODCC_AddrCmdDrvStren_1_5X 2
-#define DODCC_AddrCmdDrvStren_2_0X 3
-#define DODCC_ClkDrvStren_SHIFT 12
-#define DODCC_ClkDrvStren_MASK 3
-#define DODCC_ClkDrvStren_0_75X 0
-#define DODCC_ClkDrvStren_1_0X 1
-#define DODCC_ClkDrvStren_1_25X 2
-#define DODCC_ClkDrvStren_1_5X 3
-#define DODCC_DataDrvStren_SHIFT 16
-#define DODCC_DataDrvStren_MASK 3
-#define DODCC_DataDrvStren_0_75X 0
-#define DODCC_DataDrvStren_1_0X 1
-#define DODCC_DataDrvStren_1_25X 2
-#define DODCC_DataDrvStren_1_5X 3
-#define DODCC_DqsDrvStren_SHIFT 20
-#define DODCC_DqsDrvStren_MASK 3
-#define DODCC_DqsDrvStren_0_75X 0
-#define DODCC_DqsDrvStren_1_0X 1
-#define DODCC_DqsDrvStren_1_25X 2
-#define DODCC_DqsDrvStren_1_5X 3
-#define DODCC_ProcOdt_SHIFT 28
-#define DODCC_ProcOdt_MASK 3
-#define DODCC_ProcOdt_300_OHMS 0
-#define DODCC_ProcOdt_150_OHMS 1
-#define DODCC_ProcOdt_75_OHMS 2
-
-/*
- for DDR2 400, 533, 667, F2x[1,0]9C_x[02:01], [03], [06:05], [07] control timing of all DIMMs
- for DDR2 800, DDR3 800, 1067, 1333, 1600, F2x[1,0]9C_x[02:01], [03], [06:05], [07] control timing of DIMM0
- F2x[1,0]9C_x[102:101], [103], [106:105], [107] control timing of DIMM1
- So Socket F with Four Logical DIMM will only support DDR2 800 ?
-*/
-/* there are index +100 ===> for DIMM1
-that are corresponding to 0x01, 0x02, 0x03, 0x05, 0x06, 0x07
-*/
-//02/15/2006 18:37
-#define DRAM_WRITE_DATA_TIMING_CTRL_LOW 0x01
-#define DWDTC_WrDatFineDlyByte0_SHIFT 0
-#define DWDTC_WrDatFineDlyByte_MASK 0x1f
-#define DWDTC_WrDatFineDlyByte_BASE 0
-#define DWDTC_WrDatFineDlyByte_MIN 0
-#define DWDTC_WrDatFineDlyByte_MAX 31 // 1/64 MEMCLK
-#define DWDTC_WrDatGrossDlyByte0_SHIFT 5
-#define DWDTC_WrDatGrossDlyByte_MASK 0x3
-#define DWDTC_WrDatGrossDlyByte_NO_DELAY 0
-#define DWDTC_WrDatGrossDlyByte_0_5_ 1
-#define DWDTC_WrDatGrossDlyByte_1 2
-#define DWDTC_WrDatFineDlyByte1_SHIFT 8
-#define DWDTC_WrDatGrossDlyByte1_SHIFT 13
-#define DWDTC_WrDatFineDlyByte2_SHIFT 16
-#define DWDTC_WrDatGrossDlyByte2_SHIFT 21
-#define DWDTC_WrDatFineDlyByte3_SHIFT 24
-#define DWDTC_WrDatGrossDlyByte3_SHIFT 29
-
-#define DRAM_WRITE_DATA_TIMING_CTRL_HIGH 0x02
-#define DWDTC_WrDatFineDlyByte4_SHIFT 0
-#define DWDTC_WrDatGrossDlyByte4_SHIFT 5
-#define DWDTC_WrDatFineDlyByte5_SHIFT 8
-#define DWDTC_WrDatGrossDlyByte5_SHIFT 13
-#define DWDTC_WrDatFineDlyByte6_SHIFT 16
-#define DWDTC_WrDatGrossDlyByte6_SHIFT 21
-#define DWDTC_WrDatFineDlyByte7_SHIFT 24
-#define DWDTC_WrDatGrossDlyByte7_SHIFT 29
-
-#define DRAM_WRITE_ECC_TIMING_CTRL 0x03
-#define DWETC_WrChkFinDly_SHIFT 0
-#define DWETC_WrChkGrossDly_SHIFT 5
-
-#define DRAM_ADDR_CMD_TIMING_CTRL 0x04
-#define DACTC_CkeFineDelay_SHIFT 0
-#define DACTC_CkeFineDelay_MASK 0x1f
-#define DACTC_CkeFineDelay_BASE 0
-#define DACTC_CkeFineDelay_MIN 0
-#define DACTC_CkeFineDelay_MAX 31
-#define DACTC_CkeSetup (1<<5)
-#define DACTC_CsOdtFineDelay_SHIFT 8
-#define DACTC_CsOdtFineDelay_MASK 0x1f
-#define DACTC_CsOdtFineDelay_BASE 0
-#define DACTC_CsOdtFineDelay_MIN 0
-#define DACTC_CsOdtFineDelay_MAX 31
-#define DACTC_CsOdtSetup (1<<13)
-#define DACTC_AddrCmdFineDelay_SHIFT 16
-#define DACTC_AddrCmdFineDelay_MASK 0x1f
-#define DACTC_AddrCmdFineDelay_BASE 0
-#define DACTC_AddrCmdFineDelay_MIN 0
-#define DACTC_AddrCmdFineDelay_MAX 31
-#define DACTC_AddrCmdSetup (1<<21)
-
-#define DRAM_READ_DQS_TIMING_CTRL_LOW 0x05
-#define DRDTC_RdDqsTimeByte0_SHIFT 0
-#define DRDTC_RdDqsTimeByte_MASK 0x3f
-#define DRDTC_RdDqsTimeByte_BASE 0
-#define DRDTC_RdDqsTimeByte_MIN 0
-#define DRDTC_RdDqsTimeByte_MAX 63 // 1/128 MEMCLK
-#define DRDTC_RdDqsTimeByte1_SHIFT 8
-#define DRDTC_RdDqsTimeByte2_SHIFT 16
-#define DRDTC_RdDqsTimeByte3_SHIFT 24
-
-#define DRAM_READ_DQS_TIMING_CTRL_HIGH 0x06
-#define DRDTC_RdDqsTimeByte4_SHIFT 0
-#define DRDTC_RdDqsTimeByte5_SHIFT 8
-#define DRDTC_RdDqsTimeByte6_SHIFT 16
-#define DRDTC_RdDqsTimeByte7_SHIFT 24
-
-#define DRAM_READ_DQS_ECC_TIMING_CTRL 0x07
-#define DRDETC_RdDqsTimeCheck_SHIFT 0
-
-#define DRAM_PHY_CTRL 0x08
-#define DPC_WrtLvTrEn (1<<0)
-#define DPC_WrtLvTrMode (1<<1)
-#define DPC_TrNibbleSel (1<<2)
-#define DPC_TrDimmSel_SHIFT 4
-#define DPC_TrDimmSel_MASK 3 /* 0-->dimm0, 1-->dimm1, 2--->dimm2, 3--->dimm3 */
-#define DPC_WrLvOdt_SHIFT 8
-#define DPC_WrLvOdt_MASK 0xf /* bit 0-->odt 0, ...*/
-#define DPC_WrLvODtEn (1<<12)
-#define DPC_DqsRcvTrEn (1<<13)
-#define DPC_DisAutoComp (1<<30)
-#define DPC_AsyncCompUpdate (1<<31)
-
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_0_0 0x10 //DIMM0 Channel A
-#define DDRETC_DqsRcvEnFineDelayByte0_SHIFT 0
-#define DDRETC_DqsRcvEnFineDelayByte0_MASK 0x1f
-#define DDRETC_DqsRcvEnGrossDelayByte0_SHIFT 5
-#define DDRETC_DqsRcvEnGrossDelayByte0_MASK 0x3
-#define DDRETC_DqsRcvEnFineDelayByte1_SHIFT 8
-#define DDRETC_DqsRcvEnGrossDelayByte1_SHIFT 13
-#define DDRETC_DqsRcvEnFineDelayByte2_SHIFT 16
-#define DDRETC_DqsRcvEnGrossDelayByte2_SHIFT 21
-#define DDRETC_DqsRcvEnFineDelayByte3_SHIFT 24
-#define DDRETC_DqsRcvEnGrossDelayByte3_SHIFT 29
-
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_0_1 0x11 //DIMM0 Channel A
-#define DDRETC_DqsRcvEnFineDelayByte4_SHIFT 0
-#define DDRETC_DqsRcvEnGrossDelayByte4_SHIFT 5
-#define DDRETC_DqsRcvEnFineDelayByte5_SHIFT 8
-#define DDRETC_DqsRcvEnGrossDelayByte5_SHIFT 13
-#define DDRETC_DqsRcvEnFineDelayByte6_SHIFT 16
-#define DDRETC_DqsRcvEnGrossDelayByte6_SHIFT 21
-#define DDRETC_DqsRcvEnFineDelayByte7_SHIFT 24
-#define DDRETC_DqsRcvEnGrossDelayByte7_SHIFT 29
-
-#define DRAM_DQS_RECV_ENABLE_TIMING_CTRL_ECC_0_0 0x12
-#define DDRETCE_WrChkFineDlyByte0_SHIFT 0
-#define DDRETCE_WrChkGrossDlyByte0_SHIFT 5
-
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_0_2 0x20 //DIMM0 channel B
-#define DDRETC_DqsRcvEnFineDelayByte8_SHIFT 0
-#define DDRETC_DqsRcvEnGrossDelayByte8_SHIFT 5
-#define DDRETC_DqsRcvEnFineDelayByte9_SHIFT 8
-#define DDRETC_DqsRcvEnGrossDelayByte9_SHIFT 13
-#define DDRETC_DqsRcvEnFineDelayByte10_SHIFT 16
-#define DDRETC_DqsRcvEnGrossDelayByte10_SHIFT 21
-#define DDRETC_DqsRcvEnFineDelayByte11_SHIFT 24
-#define DDRETC_DqsRcvEnGrossDelayByte11_SHIFT 29
-
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_0_3 0x21 // DIMM0 Channel B
-#define DDRETC_DqsRcvEnFineDelayByte12_SHIFT 0
-#define DDRETC_DqsRcvEnGrossDelayByte12_SHIFT 5
-#define DDRETC_DqsRcvEnFineDelayByte13_SHIFT 8
-#define DDRETC_DqsRcvEnGrossDelayByte13_SHIFT 13
-#define DDRETC_DqsRcvEnFineDelayByte14_SHIFT 16
-#define DDRETC_DqsRcvEnGrossDelayByte14_SHIFT 21
-#define DDRETC_DqsRcvEnFineDelayByte15_SHIFT 24
-#define DDRETC_DqsRcvEnGrossDelayByte15_SHIFT 29
-
-#define DRAM_DQS_RECV_ENABLE_TIMING_CTRL_ECC_0_1 0x22
-#define DDRETCE_WrChkFineDlyByte1_SHIFT 0
-#define DDRETCE_WrChkGrossDlyByte1_SHIFT 5
-
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_1_0 0x13 //DIMM1
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_1_1 0x14
-#define DRAM_DQS_RECV_ENABLE_TIMING_CTRL_ECC_1_0 0x15
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_1_2 0x23
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_1_3 0x24
-#define DRAM_DQS_RECV_ENABLE_TIMING_CTRL_ECC_1_1 0x25
-
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_2_0 0x16 // DIMM2
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_2_1 0x17
-#define DRAM_DQS_RECV_ENABLE_TIMING_CTRL_ECC_2_0 0x18
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_2_2 0x26
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_2_3 0x27
-#define DRAM_DQS_RECV_ENABLE_TIMING_CTRL_ECC_2_1 0x28
-
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_3_0 0x19 // DIMM3
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_3_1 0x1a
-#define DRAM_DQS_RECV_ENABLE_TIMING_CTRL_ECC_3_0 0x1b
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_3_2 0x29
-#define DRAM_DQS_RECV_ENABLE_TIME_CTRL_3_3 0x2a
-#define DRAM_DQS_RECV_ENABLE_TIMING_CTRL_ECC_3_1 0x2b
-
-/* 04.06.2006 19:12 */
-
-#define DRAM_PHASE_RECOVERY_CTRL_0 0x50
-#define DPRC_PhRecFineDlyByte0_SHIFT 0
-#define DDWTC_PhRecFineDlyByte0_MASK 0x1f
-#define DDWTC_PhRecGrossDlyByte0_SHIFT 5
-#define DDWTC_PhRecGrossDlyByte0_MASK 0x3
-#define DDWTC_PhRecFineDlyByte1_SHIFT 8
-#define DDWTC_PhRecGrossDlyByte1_SHIFT 13
-#define DDWTC_PhRecFineDlyByte2_SHIFT 16
-#define DDWTC_PhRecGrossDlyByte2_SHIFT 21
-#define DDWTC_PhRecFineDlyByte3_SHIFT 24
-#define DDWTC_PhRecGrossDlyByte3_SHIFT 29
-
-#define DRAM_PHASE_RECOVERY_CTRL_1 0x51
-#define DPRC_PhRecFineDlyByte4_SHIFT 0
-#define DDWTC_PhRecGrossDlyByte4_SHIFT 5
-#define DDWTC_PhRecFineDlyByte5_SHIFT 8
-#define DDWTC_PhRecGrossDlyByte5_SHIFT 13
-#define DDWTC_PhRecFineDlyByte6_SHIFT 16
-#define DDWTC_PhRecGrossDlyByte6_SHIFT 21
-#define DDWTC_PhRecFineDlyByte7_SHIFT 24
-#define DDWTC_PhRecGrossDlyByte7_SHIFT 29
-
-#define DRAM_ECC_PHASE_RECOVERY_CTRL 0x52
-#define DEPRC_PhRecEccDlyByte0_SHIFT 0
-#define DEPRC_PhRecEccGrossDlyByte0_SHIFT 5
-
-#define DRAM_WRITE_LEVEL_ERROR 0x53 /* read only */
-#define DWLE_WrLvErr_SHIFT 0
-#define DWLE_WrLvErr_MASK 0xff
-
-#define DRAM_CTRL_MISC 0xa0
-#define DCM_MemCleared (1<<0) /* RD == F2x110 [MemCleared] */
-#define DCM_DramEnabled (1<<9) /* RD == F2x110 [DramEnabled] */
-
-#define NB_TIME_STAMP_COUNT_LOW 0xb0
-#define TscLow_SHIFT 0
-#define TscLow_MASK 0xffffffff
-
-#define NB_TIME_STAMP_COUNT_HIGH 0xb4
-#define TscHigh_SHIFT 0
-#define TscHigh_Mask 0xff
-
-#define DCT_DEBUG_CTRL 0xf0 /* 0xf0 for DCT0, 0x1f0 is for DCT1*/
-#define DDC_DllAdjust_SHIFT 0
-#define DDC_DllAdjust_MASK 0xff
-#define DDC_DllSlower (1<<8)
-#define DDC_DllFaster (1<<9)
-#define DDC_WrtDqsAdjust_SHIFT 16
-#define DDC_WrtDqsAdjust_MASK 0x7
-#define DDC_WrtDqsAdjustEn (1<<19)
-
-#define DRAM_CTRL_SEL_LOW 0x110
-#define DCSL_DctSelHiRngEn (1<<0)
-#define DCSL_DctSelHi (1<<1)
-#define DCSL_DctSelIntLvEn (1<<2)
-#define DCSL_MemClrInit (1<<3) /* WR only */
-#define DCSL_DctGangEn (1<<4)
-#define DCSL_DctDataIntLv (1<<5)
-#define DCSL_DctSelIntLvAddr_SHIFT
-#define DCSL_DctSelIntLvAddr_MASK 3
-#define DCSL_DramEnable (1<<8) /* RD only */
-#define DCSL_MemClrBusy (1<<9) /* RD only */
-#define DCSL_MemCleared (1<<10) /* RD only */
-#define DCSL_DctSelBaseAddr_47_27_SHIFT 11
-#define DCSL_DctSelBaseAddr_47_27_MASK 0x1fffff
-
-#define DRAM_CTRL_SEL_HIGH 0x114
-#define DCSH_DctSelBaseOffset_47_26_SHIFT 10
-#define DCSH_DctSelBaseOffset_47_26_MASK 0x3fffff
-
-#define MEM_CTRL_CONF_LOW 0x118
-#define MCCL_MctPriCpuRd (1<<0)
-#define MCCL_MctPriCpuWr (1<<1)
-#define MCCL_MctPriIsocRd_SHIFT 4
-#define MCCL_MctPriIsoc_MASK 0x3
-#define MCCL_MctPriIsocWr_SHIFT 6
-#define MCCL_MctPriIsocWe_MASK 0x3
-#define MCCL_MctPriDefault_SHIFT 8
-#define MCCL_MctPriDefault_MASK 0x3
-#define MCCL_MctPriWr_SHIFT 10
-#define MCCL_MctPriWr_MASK 0x3
-#define MCCL_MctPriIsoc_SHIFT 12
-#define MCCL_MctPriIsoc_MASK 0x3
-#define MCCL_MctPriTrace_SHIFT 14
-#define MCCL_MctPriTrace_MASK 0x3
-#define MCCL_MctPriScrub_SHIFT 16
-#define MCCL_MctPriScrub_MASK 0x3
-#define MCCL_McqMedPriByPassMax_SHIFT 20
-#define MCCL_McqMedPriByPassMax_MASK 0x7
-#define MCCL_McqHiPriByPassMax_SHIFT 24
-#define MCCL_McqHiPriByPassMax_MASK 0x7
-#define MCCL_MctVarPriCntLmt_SHIFT 28
-#define MCCL_MctVarPriCntLmt_MASK 0x7
-
-#define MEM_CTRL_CONF_HIGH 0x11c
-#define MCCH_DctWrLimit_SHIFT 0
-#define MCCH_DctWrLimit_MASK 0x3
-#define MCCH_MctWrLimit_SHIFT 2
-#define MCCH_MctWrLimit_MASK 0x1f
-#define MCCH_MctPrefReqLimit_SHIFT 7
-#define MCCH_MctPrefReqLimit_MASK 0x1f
-#define MCCH_PrefCpuDis (1<<12)
-#define MCCH_PrefIoDis (1<<13)
-#define MCCH_PrefIoFixStrideEn (1<<14)
-#define MCCH_PrefFixStrideEn (1<<15)
-#define MCCH_PrefFixDist_SHIFT 16
-#define MCCH_PrefFixDist_MASK 0x3
-#define MCCH_PrefConfSat_SHIFT 18
-#define MCCH_PrefConfSat_MASK 0x3
-#define MCCH_PrefOneConf_SHIFT 20
-#define MCCH_PrefOneConf_MASK 0x3
-#define MCCH_PrefTwoConf_SHIFT 22
-#define MCCH_PrefTwoConf_MASK 0x7
-#define MCCH_PrefThreeConf_SHIFT 25
-#define MCCH_prefThreeConf_MASK 0x7
-#define MCCH_PrefDramTrainMode (1<<28)
-#define MCCH_FlushWrOnStpGnt (1<<29)
-#define MCCH_FlushWr (1<<30)
-#define MCCH_MctScrubEn (1<<31)
-
-
-/* Function 3 */
-#define MCA_NB_CONTROL 0x40
-#define MNCT_CorrEccEn (1<<0)
-#define MNCT_UnCorrEccEn (1<<1)
-#define MNCT_CrcErr0En (1<<2) /* Link 0 */
-#define MNCT_CrcErr1En (1<<3)
-#define MNCT_CrcErr2En (1<<4)
-#define MBCT_SyncPkt0En (1<<5) /* Link 0 */
-#define MBCT_SyncPkt1En (1<<6)
-#define MBCT_SyncPkt2En (1<<7)
-#define MBCT_MstrAbrtEn (1<<8)
-#define MBCT_TgtAbrtEn (1<<9)
-#define MBCT_GartTblEkEn (1<<10)
-#define MBCT_AtomicRMWEn (1<<11)
-#define MBCT_WdogTmrRptEn (1<<12)
-#define MBCT_DevErrEn (1<<13)
-#define MBCT_L3ArrayCorEn (1<<14)
-#define MBCT_L3ArrayUncEn (1<<15)
-#define MBCT_HtProtEn (1<<16)
-#define MBCT_HtDataEn (1<<17)
-#define MBCT_DramParEn (1<<18)
-#define MBCT_RtryHt0En (1<<19) /* Link 0 */
-#define MBCT_RtryHt1En (1<<20)
-#define MBCT_RtryHt2En (1<<21)
-#define MBCT_RtryHt3En (1<<22)
-#define MBCT_CrcErr3En (1<<23) /* Link 3*/
-#define MBCT_SyncPkt3En (1<<24) /* Link 4 */
-#define MBCT_McaUsPwDatErrEn (1<<25)
-#define MBCT_NbArrayParEn (1<<26)
-#define MBCT_TblWlkDatErrEn (1<<27)
-#define MBCT_FbDimmCorErrEn (1<<28)
-#define MBCT_FbDimmUnCorErrEn (1<<29)
-
-
-
-#define MCA_NB_CONFIG 0x44
-#define MNC_CpuRdDatErrEn (1<<1)
-#define MNC_SyncOnUcEccEn (1<<2)
-#define MNC_SynvPktGenDis (1<<3)
-#define MNC_SyncPktPropDis (1<<4)
-#define MNC_IoMstAbortDis (1<<5)
-#define MNC_CpuErrDis (1<<6)
-#define MNC_IoErrDis (1<<7)
-#define MNC_WdogTmrDis (1<<8)
-#define MNC_WdogTmrCntSel_2_0_SHIFT 9 /* 3 is ar f3x180 */
-#define MNC_WdogTmrCntSel_2_0_MASK 0x3
-#define MNC_WdogTmrBaseSel_SHIFT 12
-#define MNC_WdogTmrBaseSel_MASK 0x3
-#define MNC_LdtLinkSel_SHIFT 14
-#define MNC_LdtLinkSel_MASK 0x3
-#define MNC_GenCrcErrByte0 (1<<16)
-#define MNC_GenCrcErrByte1 (1<<17)
-#define MNC_SubLinkSel_SHIFT 18
-#define MNC_SubLinkSel_MASK 0x3
-#define MNC_SyncOnWdogEn (1<<20)
-#define MNC_SyncOnAnyErrEn (1<<21)
-#define MNC_DramEccEn (1<<22)
-#define MNC_ChipKillEccEn (1<<23)
-#define MNC_IoRdDatErrEn (1<<24)
-#define MNC_DisPciCfgCpuErrRsp (1<<25)
-#define MNC_CorrMcaExcEn (1<<26)
-#define MNC_NbMcaToMstCpuEn (1<<27)
-#define MNC_DisTgtAbtCpuErrRsp (1<<28)
-#define MNC_DisMstAbtCpuErrRsp (1<<29)
-#define MNC_SyncOnDramAdrParErrEn (1<<30)
-#define MNC_NbMcaLogEn (1<<31)
-
-#define MCA_NB_STATUS_LOW 0x48
-#define MNSL_ErrorCode_SHIFT 0
-#define MNSL_ErrorCode_MASK 0xffff
-#define MNSL_ErrorCodeExt_SHIFT 16
-#define MNSL_ErrorCodeExt_MASK 0x1f
-#define MNSL_Syndrome_15_8_SHIFT 24
-#define MNSL_Syndrome_15_8_MASK 0xff
-
-#define MCA_NB_STATUS_HIGH 0x4c
-#define MNSH_ErrCPU_SHIFT 0
-#define MNSH_ErrCPU_MASK 0xf
-#define MNSH_LDTLink_SHIFT 4
-#define MNSH_LDTLink_MASK 0xf
-#define MNSH_ErrScrub (1<<8)
-#define MNSH_SubLink (1<<9)
-#define MNSH_McaStatusSubCache_SHIFT 10
-#define MNSH_McaStatusSubCache_MASK 0x3
-#define MNSH_Deffered (1<<12)
-#define MNSH_UnCorrECC (1<<13)
-#define MNSH_CorrECC (1<<14)
-#define MNSH_Syndrome_7_0_SHIFT 15
-#define MNSH_Syndrome_7_0_MASK 0xff
-#define MNSH_PCC (1<<25)
-#define MNSH_ErrAddrVal (1<<26)
-#define MNSH_ErrMiscVal (1<<27)
-#define MNSH_ErrEn (1<<28)
-#define MNSH_ErrUnCorr (1<<29)
-#define MNSH_ErrOver (1<<30)
-#define MNSH_ErrValid (1<<31)
-
-#define MCA_NB_ADDR_LOW 0x50
-#define MNAL_ErrAddr_31_1_SHIFT 1
-#define MNAL_ErrAddr_31_1_MASK 0x7fffffff
-
-#define MCA_NB_ADDR_HIGH 0x54
-#define MNAL_ErrAddr_47_32_SHIFT 0
-#define MNAL_ErrAddr_47_32_MASK 0xffff
-
-#define DRAM_SCRUB_RATE_CTRL 0x58
-#define SCRUB_NONE 0
-#define SCRUB_40ns 1
-#define SCRUB_80ns 2
-#define SCRUB_160ns 3
-#define SCRUB_320ns 4
-#define SCRUB_640ns 5
-#define SCRUB_1_28us 6
-#define SCRUB_2_56us 7
-#define SCRUB_5_12us 8
-#define SCRUB_10_2us 9
-#define SCRUB_20_5us 0xa
-#define SCRUB_41_0us 0xb
-#define SCRUB_81_9us 0xc
-#define SCRUB_163_8us 0xd
-#define SCRUB_327_7us 0xe
-#define SCRUB_655_4us 0xf
-#define SCRUB_1_31ms 0x10
-#define SCRUB_2_62ms 0x11
-#define SCRUB_5_24ms 0x12
-#define SCRUB_10_49ms 0x13
-#define SCRUB_20_97ms 0x14
-#define SCRUB_42ms 0x15
-#define SCRUB_84ms 0x16
-#define DSRC_DramScrub_SHFIT 0
-#define DSRC_DramScrub_MASK 0x1f
-#define DSRC_L2Scrub_SHIFT 8
-#define DSRC_L2Scrub_MASK 0x1f
-#define DSRC_DcacheScrub_SHIFT 16
-#define DSRC_DcacheScrub_MASK 0x1f
-#define DSRC_L3Scrub_SHIFT 24
-#define DSRC_L3Scrub_MASK 0x1f
-
-#define DRAM_SCRUB_ADDR_LOW 0x5C
-#define DSAL_ScrubReDirEn (1<<0)
-#define DSAL_ScrubAddrLo_SHIFT 6
-#define DSAL_ScrubAddrLo_MASK 0x3ffffff
-
-#define DRAM_SCRUB_ADDR_HIGH 0x60
-#define DSAH_ScrubAddrHi_SHIFT 0
-#define DSAH_ScrubAddrHi_MASK 0xffff
-
-#define HW_THERMAL_CTRL 0x64
-
-#define SW_THERMAL_CTRL 0x68
-
-#define DATA_BUF_CNT 0x6c
-
-#define SRI_XBAR_CMD_BUF_CNT 0x70
-
-#define XBAR_SRI_CMD_BUF_CNT 0x74
-
-#define MCT_XBAR_CMD_BUF_CNT 0x78
-
-#define ACPI_PWR_STATE_CTRL 0x80 /* till 0x84 */
-
-#define NB_CONFIG_LOW 0x88
-#define NB_CONFIG_HIGH 0x8c
-
-#define GART_APERTURE_CTRL 0x90
-
-#define GART_APERTURE_BASE 0x94
-
-#define GART_TBL_BASE 0x98
-
-#define GART_CACHE_CTRL 0x9c
-
-#define PWR_CTRL_MISC 0xa0
-
-#define RPT_TEMP_CTRL 0xa4
-
-#define ON_LINE_SPARE_CTRL 0xb0
-
-#define SBI_P_STATE_LIMIT 0xc4
-
-#define CLK_PWR_TIMING_CTRL0 0xd4
-#define CLK_PWR_TIMING_CTRL1 0xd8
-#define CLK_PWR_TIMING_CTRL2 0xdc
-
-#define THERMTRIP_STATUS 0xE4
-
-
-#define NORTHBRIDGE_CAP 0xE8
-#define NBCAP_TwoChanDRAMcap (1 << 0)
-#define NBCAP_DualNodeMPcap (1 << 1)
-#define NBCAP_EightNodeMPcap (1 << 2)
-#define NBCAP_ECCcap (1 << 3)
-#define NBCAP_ChipkillECCcap (1 << 4)
-#define NBCAP_DdrMaxRate_SHIFT 5
-#define NBCAP_DdrMaxRate_MASK 7
-#define NBCAP_DdrMaxRate_400 7
-#define NBCAP_DdrMaxRate_533 6
-#define NBCAP_DdrMaxRate_667 5
-#define NBCAP_DdrMaxRate_800 4
-#define NBCAP_DdrMaxRate_1067 3
-#define NBCAP_DdrMaxRate_1333 2
-#define NBCAP_DdrMaxRate_1600 1
-#define NBCAP_DdrMaxRate_3_2G 6
-#define NBCAP_DdrMaxRate_4_0G 5
-#define NBCAP_DdrMaxRate_4_8G 4
-#define NBCAP_DdrMaxRate_6_4G 3
-#define NBCAP_DdrMaxRate_8_0G 2
-#define NBCAP_DdrMaxRate_9_6G 1
-#define NBCAP_Mem_ctrl_cap (1 << 8)
-#define MBCAP_SVMCap (1<<9)
-#define NBCAP_HtcCap (1<<10)
-#define NBCAP_CmpCap_SHIFT 12
-#define NBCAP_CmpCap_MASK 3
-#define NBCAP_MpCap_SHIFT 16
-#define NBCAP_MpCap_MASK 7
-#define NBCAP_MpCap_1N 7
-#define NBCAP_MpCap_2N 6
-#define NBCAP_MpCap_4N 5
-#define NBCAP_MpCap_8N 4
-#define NBCAP_MpCap_32N 0
-#define NBCAP_UnGangEn_SHIFT 20
-#define NBCAP_UnGangEn_MASK 0xf
-#define NBCAP_L3Cap (1<<25)
-#define NBCAP_HtAcCap (1<<26)
-
-/* 04/04/2006 18:00 */
-
-#define EXT_NB_MCA_CTRL 0x180
-
-#define NB_EXT_CONF 0x188
-#define DOWNCORE_CTRL 0x190
-#define DWNCC_DisCore_SHIFT 0
-#define DWNCC_DisCore_MASK 0xf
-
-/* Function 5 for FBDIMM */
-#define FBD_DRAM_TIMING_LOW
-
-#define LinkConnected (1 << 0)
-#define InitComplete (1 << 1)
-#define NonCoherent (1 << 2)
-#define ConnectionPending (1 << 4)
-
-// Use the LAPIC timer count register to hold each core's init status
-// Format: byte 0 - state
-// byte 1 - fid_max
-// byte 2 - nb_cof_vid_update
-// byte 3 - apic id
-
-#define LAPIC_MSG_REG 0x380
-#define F10_APSTATE_STARTED 0x13 // start of AP execution
-#define F10_APSTATE_ASLEEP 0x14 // AP sleeping
-#define F10_APSTATE_STOPPED 0x15 // allow AP to stop
-#define F10_APSTATE_RESET 0x01 // waiting for warm reset
-
-#define MAX_CORES_SUPPORTED 128
-
-#include "nums.h"
-
-#if NODE_NUMS == 64
- #define NODE_PCI(x, fn) ((x < 32)?(PCI_DEV(CONFIG_CBB,(CONFIG_CDB+x),fn)):(PCI_DEV((CONFIG_CBB-1),(CONFIG_CDB+x-32),fn)))
-#else
- #define NODE_PCI(x, fn) PCI_DEV(CONFIG_CBB,(CONFIG_CDB+x),fn)
-#endif
-
-/* Include wrapper for MCT (works for DDR2 or DDR3) */
-#include <northbridge/amd/amdmct/wrappers/mcti.h>
-
-struct link_pair_t {
- pci_devfn_t udev;
- u32 upos;
- u32 uoffs;
- pci_devfn_t dev;
- u32 pos;
- u32 offs;
- u8 host;
- u8 nodeid;
- u8 linkn;
- u8 rsv;
-} __packed;
-
-struct nodes_info_t {
- u32 nodes_in_group; // could be 2, 3, 4, 5, 6, 7, 8
- u32 groups_in_plane; // could be 1, 2, 3, 4, 5
- u32 planes; // could be 1, 2
- u32 up_planes; // down planes will be [up_planes, planes)
-} __packed;
-
-struct ht_link_config {
- uint32_t ht_speed_limit; // Speed in MHz; 0 for autodetect (default)
-};
-
-/* be careful with the alignment of sysinfo, bacause sysinfo may be shared by coreboot_car and ramstage stage. and ramstage may be running at 64bit later.*/
-
-struct sys_info {
- int32_t needs_reset;
-
- u8 ln[NODE_NUMS*NODE_NUMS];// [0, 3] link n, [4, 7] will be hop num
- u16 ln_tn[NODE_NUMS*8]; // for 0x0zzz: bit [0,7] target node num, bit[8,11] respone link from target num; 0x80ff mean not inited, 0x4yyy mean non coherent and yyy is link pair index
- struct nodes_info_t nodes_info;
- u32 nodes;
-
- u8 host_link_freq[NODE_NUMS*8]; // record freq for every link from cpu, 0x0f means don't need to touch it
- u16 host_link_freq_cap[NODE_NUMS*8]; //cap
-
- struct ht_link_config ht_link_cfg;
-
- u32 segbit;
- u32 sbdn;
- u32 sblk;
- u32 sbbusn;
-
- u32 ht_c_num;
- u32 ht_c_conf_bus[HC_NUMS]; // 4-->32
-
- struct link_pair_t link_pair[HC_NUMS*4];// enough? only in_conherent, 32 chain and every chain have 4 HT device
- u32 link_pair_num;
-
- struct mem_controller ctrl[NODE_NUMS];
-
- struct MCTStatStruc MCTstat;
- struct DCTStatStruc DCTstatA[NODE_NUMS];
-} __packed;
-
-struct device *get_node_pci(u32 nodeid, u32 fn);
-
-void showallroutes(int level, pci_devfn_t dev);
-
-void setup_resource_map_offset(const u32 *register_values, u32 max, u32
- offset_pci_dev, u32 offset_io_base);
-
-void setup_resource_map_x_offset(const u32 *register_values, u32 max, u32
- offset_pci_dev, u32 offset_io_base);
-
-void setup_resource_map_x(const u32 *register_values, u32 max);
-void setup_resource_map(const u32 *register_values, u32 max);
-void setup_mb_resource_map(void);
-
-/* reset_test.c */
-u32 cpu_init_detected(u8 nodeid);
-u32 bios_reset_detected(void);
-u32 cold_reset_detected(void);
-u32 other_reset_detected(void);
-u32 warm_reset_detect(u8 nodeid);
-void distinguish_cpu_resets(u8 nodeid);
-u32 get_sblk(void);
-u8 get_sbbusn(u8 sblk);
-void set_bios_reset(void);
-
-#include "northbridge/amd/amdht/porting.h"
-BOOL AMD_CB_ManualBUIDSwapList(u8 Node, u8 Link, const u8 **List);
-
-struct acpi_rsdp;
-
-unsigned long northbridge_write_acpi_tables(struct device *device,
- unsigned long start,
- struct acpi_rsdp *rsdp);
-void northbridge_acpi_write_vars(struct device *device);
-
-#endif /* AMDFAM10_H */
diff --git a/src/northbridge/amd/amdfam10/amdfam10_util.asl b/src/northbridge/amd/amdfam10/amdfam10_util.asl
deleted file mode 100644
index 6e2118d1ae..0000000000
--- a/src/northbridge/amd/amdfam10/amdfam10_util.asl
+++ /dev/null
@@ -1,321 +0,0 @@
-//
-// This file is part of the coreboot project.
-//
-// Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
-// Copyright (C) 2007 Advanced Micro Devices, Inc.
-//
-// This program is free software; you can redistribute it and/or modify
-// it under the terms of the GNU General Public License as published by
-// the Free Software Foundation; version 2 of the License.
-//
-// This program is distributed in the hope that it will be useful,
-// but WITHOUT ANY WARRANTY; without even the implied warranty of
-// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
-// GNU General Public License for more details.
-//
-
-//AMD FAM10 util for BUSB and res range
-
-Scope (\_SB)
-{
-
- Name (OSTB, Ones)
- Method (OSVR, 0, NotSerialized)
- {
- If (LEqual (^OSTB, Ones))
- {
- Store (0x00, ^OSTB)
- }
-
- Return (^OSTB)
- }
-
- Method (SEQL, 2, Serialized)
- {
- Store (SizeOf (Arg0), Local0)
- Store (SizeOf (Arg1), Local1)
- If (LNot (LEqual (Local0, Local1))) { Return (Zero) }
-
- Name (BUF0, Buffer (Local0) {})
- Store (Arg0, BUF0)
- Name (BUF1, Buffer (Local0) {})
- Store (Arg1, BUF1)
- Store (Zero, Local2)
- While (LLess (Local2, Local0))
- {
- Store (DerefOf (Index (BUF0, Local2)), Local3)
- Store (DerefOf (Index (BUF1, Local2)), Local4)
- If (LNot (LEqual (Local3, Local4))) { Return (Zero) }
-
- Increment (Local2)
- }
-
- Return (One)
- }
-
-
- Method (DADD, 2, NotSerialized)
- {
- Store(Arg1, Local0)
- Store(Arg0, Local1)
- Add(ShiftLeft(Local1,16), Local0, Local0)
- Return (Local0)
- }
-
-
- Method (GHCE, 1, NotSerialized) // check if the HC enabled
- {
- Store (DerefOf (Index (\_SB.PCI0.HCLK, Arg0)), Local1)
- if (LEqual (And(Local1, 0x01), 0x01)) { Return (0x0F) }
- Else { Return (0x00) }
- }
-
- Method (GHCN, 1, NotSerialized) // get the node num for the HC
- {
- Store (0x00, Local0)
- Store (DerefOf (Index (\_SB.PCI0.HCLK, Arg0)), Local1)
- Store (ShiftRight(And (Local1, 0xfc), 0x02), Local0)
- Return (Local0)
- }
-
- Method (GHCL, 1, NotSerialized) // get the link num on node for the HC
- {
- Store (0x00, Local0)
- Store (DerefOf (Index (\_SB.PCI0.HCLK, Arg0)), Local1)
- Store (ShiftRight(And (Local1, 0x700), 0x08), Local0)
- Return (Local0)
- }
-
- Method (GHCD, 2, NotSerialized) // get the unit id base for the HT device in HC
- {
- Store (0x00, Local0)
- Store (DerefOf (Index (\_SB.PCI0.HCDN, Arg0)), Local1)
- Store (Arg1, Local2) // Arg1 could be 3, 2, 1, 0
- Multiply (Local2, 0x08, Local2) // change to 24, 16, 8, 0
- Store (And (ShiftRight(Local1, Local2), 0xff), Local0)
- Return (Local0)
- }
-
- Method (GBUS, 2, NotSerialized)
- {
- Store (0x00, Local0)
- While (LLess (Local0, 0x20)) // 32 ht links
- {
- Store (DerefOf (Index (\_SB.PCI0.BUSN, Local0)), Local1)
- If (LEqual (And (Local1, 0x03), 0x03))
- {
- If (LEqual (Arg0, ShiftRight (And (Local1, 0xfc), 0x02)))
- {
- If (LOr (LEqual (Arg1, 0xFF), LEqual (Arg1, ShiftRight (And (Local1, 0x0700), 0x08))))
- {
- Return (ShiftRight (And (Local1, 0x000FF000), 0x0c))
- }
- }
- }
-
- Increment (Local0)
- }
-
- Return (0x00)
- }
-
- Method (GWBN, 2, Serialized)
- {
- Name (BUF0, ResourceTemplate ()
- {
- WordBusNumber (ResourceProducer, MinFixed, MaxFixed, PosDecode,
- 0x0000, // Address Space Granularity
- 0x0000, // Address Range Minimum
- 0x0000, // Address Range Maximum
- 0x0000, // Address Translation Offset
- 0x0001,,,)
- })
- CreateWordField (BUF0, 0x08, BMIN)
- CreateWordField (BUF0, 0x0A, BMAX)
- CreateWordField (BUF0, 0x0E, BLEN)
- Store (0x00, Local0)
- While (LLess (Local0, 0x20))
- {
- Store (DerefOf (Index (\_SB.PCI0.BUSN, Local0)), Local1)
- If (LEqual (And (Local1, 0x03), 0x03))
- {
- If (LEqual (Arg0, ShiftRight (And (Local1, 0xfc), 0x02)))
- {
- If (LOr (LEqual (Arg1, 0xFF), LEqual (Arg1, ShiftRight (And (Local1, 0x0700), 0x08))))
- {
- Store (ShiftRight (And (Local1, 0x000FF000), 0x0c), BMIN)
- Store (ShiftRight (Local1, 0x14), BMAX)
- Subtract (BMAX, BMIN, BLEN)
- Increment (BLEN)
- Return (RTAG (BUF0))
- }
- }
- }
-
- Increment (Local0)
- }
-
- Return (RTAG (BUF0))
- }
-
- Method (GMEM, 2, Serialized)
- {
- Name (BUF0, ResourceTemplate ()
- {
- DWordMemory (ResourceProducer, PosDecode, MinFixed, MaxFixed, NonCacheable, ReadWrite,
- 0x00000000, // Address Space Granularity
- 0x00000000, // Address Range Minimum
- 0x00000000, // Address Range Maximum
- 0x00000000, // Address Translation Offset
- 0x00000001,,,
- , AddressRangeMemory, TypeStatic)
- })
- CreateDWordField (BUF0, 0x0A, MMIN)
- CreateDWordField (BUF0, 0x0E, MMAX)
- CreateDWordField (BUF0, 0x16, MLEN)
- Store (0x00, Local0)
- Store (0x00, Local4)
- Store (0x00, Local3)
- While (LLess (Local0, 0x80)) // 0x20 links * 2(mem, prefmem) *2 (base, limit)
- {
- Store (DerefOf (Index (\_SB.PCI0.MMIO, Local0)), Local1)
- Increment (Local0)
- Store (DerefOf (Index (\_SB.PCI0.MMIO, Local0)), Local2)
- If (LEqual (And (Local1, 0x03), 0x03))
- {
- If (LEqual (Arg0, And (Local2, 0x3f)))
- {
- If (LOr (LEqual (Arg1, 0xFF), LEqual (Arg1, ShiftRight (And (Local1, 0x70), 0x04))))
- {
- Store (ShiftLeft (And (Local1, 0xFFFFFF00), 0x08), MMIN)
- Store (ShiftLeft (And (Local2, 0xFFFFFF00), 0x08), MMAX)
- Or (MMAX, 0xFFFF, MMAX)
- Subtract (MMAX, MMIN, MLEN)
- Increment (MLEN)
-
- If (Local4)
- {
- Concatenate (RTAG (BUF0), Local3, Local5)
- Store (Local5, Local3)
- }
- Else
- {
- Store (RTAG (BUF0), Local3)
- }
-
- Increment (Local4)
- }
- }
- }
-
- Increment (Local0)
- }
-
- If (LNot (Local4))
- {
- Store (BUF0, Local3)
- }
-
- Return (Local3)
- }
-
- Method (GIOR, 2, Serialized)
- {
- Name (BUF0, ResourceTemplate ()
- {
- DWordIO (ResourceProducer, MinFixed, MaxFixed, PosDecode, EntireRange,
- 0x00000000, // Address Space Granularity
- 0x00000000, // Address Range Minimum
- 0x00000000, // Address Range Maximum
- 0x00000000, // Address Translation Offset
- 0x00000001,,,
- , TypeStatic)
- })
- CreateDWordField (BUF0, 0x0A, PMIN)
- CreateDWordField (BUF0, 0x0E, PMAX)
- CreateDWordField (BUF0, 0x16, PLEN)
- Store (0x00, Local0)
- Store (0x00, Local4)
- Store (0x00, Local3)
- While (LLess (Local0, 0x40)) // 0x20 ht links * 2 (base, limit)
- {
- Store (DerefOf (Index (\_SB.PCI0.PCIO, Local0)), Local1)
- Increment (Local0)
- Store (DerefOf (Index (\_SB.PCI0.PCIO, Local0)), Local2)
- If (LEqual (And (Local1, 0x03), 0x03))
- {
- If (LEqual (Arg0, And (Local2, 0x3f)))
- {
- If (LOr (LEqual (Arg1, 0xFF), LEqual (Arg1, ShiftRight (And (Local1, 0x70), 0x04))))
- {
- Store (And (Local1, 0x01FFF000), PMIN)
- Store (And (Local2, 0x01FFF000), PMAX)
- Or (PMAX, 0x0FFF, PMAX)
- Subtract (PMAX, PMIN, PLEN)
- Increment (PLEN)
-
- If (Local4)
- {
- Concatenate (RTAG (BUF0), Local3, Local5)
- Store (Local5, Local3)
- }
- Else
- {
- If (LGreater (PMAX, PMIN))
- {
- If (LOr (LAnd (LEqual (Arg1, 0xFF), LEqual (Arg0, 0x00)), LEqual (Arg1, \_SB.PCI0.SBLK)))
- {
- Store (0x0D00, PMIN)
- Subtract (PMAX, PMIN, PLEN)
- Increment (PLEN)
- }
-
- Store (RTAG (BUF0), Local3)
- Increment (Local4)
- }
-
- If (And (Local1, 0x10))
- {
- Store (0x03B0, PMIN)
- Store (0x03DF, PMAX)
- Store (0x30, PLEN)
-
- If (Local4)
- {
- Concatenate (RTAG (BUF0), Local3, Local5)
- Store (Local5, Local3)
- }
- Else
- {
- Store (RTAG (BUF0), Local3)
- }
- }
- }
-
- Increment (Local4)
- }
- }
- }
-
- Increment (Local0)
- }
-
- If (LNot (Local4))
- {
- Store (RTAG (BUF0), Local3)
- }
-
- Return (Local3)
- }
-
- Method (RTAG, 1, NotSerialized)
- {
- Store (Arg0, Local0)
- Store (SizeOf (Local0), Local1)
- Subtract (Local1, 0x02, Local1)
- Multiply (Local1, 0x08, Local1)
- CreateField (Local0, 0x00, Local1, RETB)
- Store (RETB, Local2)
- Return (Local2)
- }
-}
diff --git a/src/northbridge/amd/amdfam10/amdfam10_util.c b/src/northbridge/amd/amdfam10/amdfam10_util.c
deleted file mode 100644
index 23e92323a8..0000000000
--- a/src/northbridge/amd/amdfam10/amdfam10_util.c
+++ /dev/null
@@ -1,112 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/cpu.h>
-#include <console/console.h>
-#include <device/pci_ops.h>
-#include <device/pci_def.h>
-#include "raminit.h"
-#include <northbridge/amd/amdmct/amddefs.h>
-
-#if !ENV_PCI_SIMPLE_DEVICE
-u32 Get_NB32(u32 dev, u32 reg)
-{
- return pci_read_config32(pcidev_path_on_root(PCI_DEV2DEVFN(dev)), reg);
-}
-#endif
-
-uint64_t mctGetLogicalCPUID(u32 Node)
-{
- /* Converts the CPUID to a logical ID MASK that is used to check
- CPU version support versions */
- u32 dev;
- u32 val, valx;
- u32 family, model, stepping;
- uint64_t ret;
-
- if (Node == 0xFF) { /* current node */
- val = cpuid_eax(0x80000001);
- } else {
- dev = PA_NBMISC(Node);
- val = Get_NB32(dev, 0xfc);
- }
-
- family = ((val >> 8) & 0x0f) + ((val >> 20) & 0xff);
- model = ((val >> 4) & 0x0f) | ((val >> (16-4)) & 0xf0);
- stepping = val & 0x0f;
-
- valx = (family << 12) | (model << 4) | (stepping);
-
- switch (valx) {
- case 0x10000:
- ret = AMD_DR_A0A;
- break;
- case 0x10001:
- ret = AMD_DR_A1B;
- break;
- case 0x10002:
- ret = AMD_DR_A2;
- break;
- case 0x10020:
- ret = AMD_DR_B0;
- break;
- case 0x10021:
- ret = AMD_DR_B1;
- break;
- case 0x10022:
- ret = AMD_DR_B2;
- break;
- case 0x10023:
- ret = AMD_DR_B3;
- break;
- case 0x10042:
- ret = AMD_RB_C2;
- break;
- case 0x10043:
- ret = AMD_RB_C3;
- break;
- case 0x10062:
- ret = AMD_DA_C2;
- break;
- case 0x10063:
- ret = AMD_DA_C3;
- break;
- case 0x10080:
- ret = AMD_HY_D0;
- break;
- case 0x10081:
- case 0x10091:
- ret = AMD_HY_D1;
- break;
- case 0x100a0:
- ret = AMD_PH_E0;
- break;
- case 0x15012:
- case 0x1501f:
- ret = AMD_OR_B2;
- break;
- case 0x15020:
- case 0x15101:
- ret = AMD_OR_C0;
- break;
- default:
- /* FIXME: mabe we should die() here. */
- printk(BIOS_ERR, "FIXME! CPU Version unknown or not supported! %08x\n", valx);
- ret = 0;
- }
-
- return ret;
-}
diff --git a/src/northbridge/amd/amdfam10/bootblock.c b/src/northbridge/amd/amdfam10/bootblock.c
deleted file mode 100644
index f2d5f89ec7..0000000000
--- a/src/northbridge/amd/amdfam10/bootblock.c
+++ /dev/null
@@ -1,22 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "northbridge/amd/amdfam10/early_ht.c"
-
-static void bootblock_northbridge_init(void) {
- /* Nothing special needs to be done to find bus 0 */
- /* Allow the HT devices to be found */
- /* mov bsp to bus 0xff when > 8 nodes */
- set_bsp_node_CHtExtNodeCfgEn();
- enumerate_ht_chain();
-}
diff --git a/src/northbridge/amd/amdfam10/chip.h b/src/northbridge/amd/amdfam10/chip.h
deleted file mode 100644
index daf429d91a..0000000000
--- a/src/northbridge/amd/amdfam10/chip.h
+++ /dev/null
@@ -1,25 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef _AMD_FAM10_CHIP_H_
-#define _AMD_FAM10_CHIP_H_
-
-#include <stdint.h>
-
-struct northbridge_amd_amdfam10_config {
- uint64_t maximum_memory_capacity;
-};
-
-#endif /* _AMD_FAM10_CHIP_H_ */
diff --git a/src/northbridge/amd/amdfam10/debug.c b/src/northbridge/amd/amdfam10/debug.c
deleted file mode 100644
index 5090352e9a..0000000000
--- a/src/northbridge/amd/amdfam10/debug.c
+++ /dev/null
@@ -1,324 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "debug.h"
-#include <console/console.h>
-#include <arch/io.h>
-#include <device/pci_ops.h>
-#include <device/pci_def.h>
-#include <delay.h>
-
-void print_debug_addr(const char *str, void *val)
-{
-#if CONFIG(DEBUG_CAR)
- printk(BIOS_DEBUG, "------Address debug: %s%p------\n", str, val);
-#endif
-}
-
-void print_debug_pci_dev(u32 dev)
-{
- printk(BIOS_DEBUG, "PCI: %02x:%02x.%02x", (dev>>20) & 0xff, (dev>>15) & 0x1f, (dev>>12) & 0x7);
-}
-
-void print_pci_devices(void)
-{
- pci_devfn_t dev;
- for (dev = PCI_DEV(0, 0, 0);
- dev <= PCI_DEV(0xff, 0x1f, 0x7);
- dev += PCI_DEV(0,0,1)) {
- u32 id;
- id = pci_read_config32(dev, PCI_VENDOR_ID);
- if (((id & 0xffff) == 0x0000) || ((id & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0x0000)) {
- continue;
- }
- print_debug_pci_dev(dev);
- printk(BIOS_DEBUG, " %04x:%04x\n", (id & 0xffff), (id>>16));
- if (((dev>>12) & 0x07) == 0) {
- u8 hdr_type;
- hdr_type = pci_read_config8(dev, PCI_HEADER_TYPE);
- if ((hdr_type & 0x80) != 0x80) {
- dev += PCI_DEV(0,0,7);
- }
- }
- }
-}
-
-void print_pci_devices_on_bus(u32 busn)
-{
- pci_devfn_t dev;
- for (dev = PCI_DEV(busn, 0, 0);
- dev <= PCI_DEV(busn, 0x1f, 0x7);
- dev += PCI_DEV(0,0,1)) {
- u32 id;
- id = pci_read_config32(dev, PCI_VENDOR_ID);
- if (((id & 0xffff) == 0x0000) || ((id & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0x0000)) {
- continue;
- }
- print_debug_pci_dev(dev);
- printk(BIOS_DEBUG, " %04x:%04x\n", (id & 0xffff), (id>>16));
- if (((dev>>12) & 0x07) == 0) {
- u8 hdr_type;
- hdr_type = pci_read_config8(dev, PCI_HEADER_TYPE);
- if ((hdr_type & 0x80) != 0x80) {
- dev += PCI_DEV(0,0,7);
- }
- }
- }
-}
-
-void dump_pci_device_range(u32 dev, u32 start_reg, u32 size)
-{
- int i;
- print_debug_pci_dev(dev);
- int j;
- int end = start_reg + size;
-
- for (i = start_reg; i < end; i+=4) {
- u32 val;
- if ((i & 0x0f) == 0) {
- printk(BIOS_DEBUG, "\n%04x:",i);
- }
- val = pci_read_config32(dev, i);
- for (j = 0; j < 4; j++) {
- printk(BIOS_DEBUG, " %02x", val & 0xff);
- val >>= 8;
- }
- }
- printk(BIOS_DEBUG, "\n");
-}
-
-void dump_pci_device(u32 dev)
-{
- dump_pci_device_range(dev, 0, 4096);
-}
-
-void dump_pci_device_index_wait_range(u32 dev, u32 index_reg, u32 start,
- u32 size)
-{
- int i;
- int end = start + size;
- print_debug_pci_dev(dev);
- printk(BIOS_DEBUG, " -- index_reg=%08x", index_reg);
-
- for (i = start; i < end; i++) {
- u32 val;
- int j;
- printk(BIOS_DEBUG, "\n%02x:",i);
- val = pci_read_config32_index_wait(dev, index_reg, i);
- for (j = 0; j < 4; j++) {
- printk(BIOS_DEBUG, " %02x", val & 0xff);
- val >>= 8;
- }
-
- }
- printk(BIOS_DEBUG, "\n");
-}
-
-void dump_pci_device_index_wait(u32 dev, u32 index_reg)
-{
- dump_pci_device_index_wait_range(dev, index_reg, 0, 0x54);
- dump_pci_device_index_wait_range(dev, index_reg, 0x100, 0x08); //DIMM1 when memclk > 400Hz
-}
-
-void dump_pci_device_index(u32 dev, u32 index_reg, u32 type, u32 length)
-{
- int i;
- print_debug_pci_dev(dev);
-
- printk(BIOS_DEBUG, " index reg: %04x type: %02x", index_reg, type);
-
- type<<=28;
-
- for (i = 0; i < length; i++) {
- u32 val;
- if ((i & 0x0f) == 0) {
- printk(BIOS_DEBUG, "\n%02x:",i);
- }
- val = pci_read_config32_index(dev, index_reg, i|type);
- printk(BIOS_DEBUG, " %08x", val);
- }
- printk(BIOS_DEBUG, "\n");
-}
-
-void dump_pci_devices(void)
-{
- pci_devfn_t dev;
- for (dev = PCI_DEV(0, 0, 0);
- dev <= PCI_DEV(0xff, 0x1f, 0x7);
- dev += PCI_DEV(0,0,1)) {
- u32 id;
- id = pci_read_config32(dev, PCI_VENDOR_ID);
- if (((id & 0xffff) == 0x0000) || ((id & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0x0000)) {
- continue;
- }
- dump_pci_device(dev);
-
- if (((dev>>12) & 0x07) == 0) {
- u8 hdr_type;
- hdr_type = pci_read_config8(dev, PCI_HEADER_TYPE);
- if ((hdr_type & 0x80) != 0x80) {
- dev += PCI_DEV(0,0,7);
- }
- }
- }
-}
-
-void dump_pci_devices_on_bus(u32 busn)
-{
- pci_devfn_t dev;
- for (dev = PCI_DEV(busn, 0, 0);
- dev <= PCI_DEV(busn, 0x1f, 0x7);
- dev += PCI_DEV(0,0,1)) {
- u32 id;
- id = pci_read_config32(dev, PCI_VENDOR_ID);
- if (((id & 0xffff) == 0x0000) || ((id & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0x0000)) {
- continue;
- }
- dump_pci_device(dev);
-
- if (((dev>>12) & 0x07) == 0) {
- u8 hdr_type;
- hdr_type = pci_read_config8(dev, PCI_HEADER_TYPE);
- if ((hdr_type & 0x80) != 0x80) {
- dev += PCI_DEV(0,0,7);
- }
- }
- }
-}
-
-#if CONFIG(DEBUG_SMBUS)
-void dump_spd_registers(const struct mem_controller *ctrl)
-{
- int i;
- printk(BIOS_DEBUG, "\n");
- for (i = 0; i < DIMM_SOCKETS; i++) {
- u32 device;
- device = ctrl->spd_addr[i];
- if (device) {
- int j;
- printk(BIOS_DEBUG, "dimm: %02x.0: %02x", i, device);
- for (j = 0; j < 128; j++) {
- int status;
- u8 byte;
- if ((j & 0xf) == 0) {
- printk(BIOS_DEBUG, "\n%02x: ", j);
- }
- status = smbus_read_byte(device, j);
- if (status < 0) {
- break;
- }
- byte = status & 0xff;
- printk(BIOS_DEBUG, "%02x ", byte);
- }
- printk(BIOS_DEBUG, "\n");
- }
- device = ctrl->spd_addr[i+DIMM_SOCKETS];
- if (device) {
- int j;
- printk(BIOS_DEBUG, "dimm: %02x.1: %02x", i, device);
- for (j = 0; j < 128; j++) {
- int status;
- u8 byte;
- if ((j & 0xf) == 0) {
- printk(BIOS_DEBUG, "\n%02x: ", j);
- }
- status = smbus_read_byte(device, j);
- if (status < 0) {
- break;
- }
- byte = status & 0xff;
- printk(BIOS_DEBUG, "%02x ", byte);
- }
- printk(BIOS_DEBUG, "\n");
- }
- }
-}
-
-void dump_smbus_registers(void)
-{
- u32 device;
- printk(BIOS_DEBUG, "\n");
- for (device = 1; device < 0x80; device++) {
- int j;
- if (smbus_read_byte(device, 0) < 0) continue;
- printk(BIOS_DEBUG, "smbus: %02x", device);
- for (j = 0; j < 256; j++) {
- int status;
- u8 byte;
- status = smbus_read_byte(device, j);
- if (status < 0) {
- break;
- }
- if ((j & 0xf) == 0) {
- printk(BIOS_DEBUG, "\n%02x: ",j);
- }
- byte = status & 0xff;
- printk(BIOS_DEBUG, "%02x ", byte);
- }
- printk(BIOS_DEBUG, "\n");
- }
-}
-#endif
-
-void dump_io_resources(u32 port)
-{
-
- int i;
- udelay(2000);
- printk(BIOS_DEBUG, "%04x:\n", port);
- for (i = 0; i < 256; i++) {
- u8 val;
- if ((i & 0x0f) == 0) {
- printk(BIOS_DEBUG, "%02x:", i);
- }
- val = inb(port);
- printk(BIOS_DEBUG, " %02x",val);
- if ((i & 0x0f) == 0x0f) {
- printk(BIOS_DEBUG, "\n");
- }
- port++;
- }
-}
-
-#if CONFIG(DIMM_DDR2)
-void print_tx(const char *strval, u32 val)
-{
-#if CONFIG(DEBUG_RAM_SETUP)
- printk(BIOS_DEBUG, "%s%08x\n", strval, val);
-#endif
-}
-
-void print_t(const char *strval)
-{
-#if CONFIG(DEBUG_RAM_SETUP)
- printk(BIOS_DEBUG, "%s", strval);
-#endif
-}
-#endif /* CONFIG_DIMM_DDR2 */
-
-void print_tf(const char *func, const char *strval)
-{
-#if CONFIG(DEBUG_RAM_SETUP)
- printk(BIOS_DEBUG, "%s: %s", func, strval);
-#endif
-}
diff --git a/src/northbridge/amd/amdfam10/debug.h b/src/northbridge/amd/amdfam10/debug.h
deleted file mode 100644
index 01d87d96af..0000000000
--- a/src/northbridge/amd/amdfam10/debug.h
+++ /dev/null
@@ -1,45 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef AMDFAM10_DEBUG_H
-#define AMDFAM10_DEBUG_H
-
-#include <stdint.h>
-#include "pci.h"
-
-void print_debug_addr(const char *str, void *val);
-void print_debug_pci_dev(u32 dev);
-void print_pci_devices(void);
-void print_pci_devices_on_bus(u32 busn);
-void dump_pci_device_range(u32 dev, u32 start_reg, u32 size);
-void dump_pci_device(u32 dev);
-void dump_pci_device_index_wait_range(u32 dev, u32 index_reg, u32 start,
- u32 size);
-void dump_pci_device_index_wait(u32 dev, u32 index_reg);
-void dump_pci_device_index(u32 dev, u32 index_reg, u32 type, u32 length);
-void dump_pci_devices(void);
-void dump_pci_devices_on_bus(u32 busn);
-
-#if CONFIG(DEBUG_SMBUS)
-void dump_spd_registers(const struct mem_controller *ctrl);
-void dump_smbus_registers(void);
-#endif
-
-void dump_io_resources(u32 port);
-
-void print_tx(const char *strval, u32 val);
-void print_t(const char *strval);
-void print_tf(const char *func, const char *strval);
-#endif
diff --git a/src/northbridge/amd/amdfam10/early_ht.c b/src/northbridge/amd/amdfam10/early_ht.c
deleted file mode 100644
index dc0f6840e2..0000000000
--- a/src/northbridge/amd/amdfam10/early_ht.c
+++ /dev/null
@@ -1,176 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "early_ht.h"
-#include <stdint.h>
-#include <device/pci_ops.h>
-#include <device/pci_def.h>
-
-// For SB HT chain only
-// mmconf is not ready yet
-void set_bsp_node_CHtExtNodeCfgEn(void)
-{
-#if CONFIG(EXT_RT_TBL_SUPPORT)
- u32 dword;
- dword = pci_io_read_config32(PCI_DEV(0, 0x18, 0), 0x68);
- dword |= (1<<27) | (1<<25);
- /* CHtExtNodeCfgEn: coherent link extended node configuration enable,
- Nodes[31:0] will be 0xff:[31:0], Nodes[63:32] will be 0xfe:[31:0]
- ---- 32 nodes now only
- It can be used even nodes less than 8 nodes.
- We can have 8 more device on bus 0 in that case
- */
-
- /* CHtExtAddrEn */
- pci_io_write_config32(PCI_DEV(0, 0x18, 0), 0x68, dword);
- // CPU on bus 0xff and 0xfe now. For now on we can use CONFIG_CBB and CONFIG_CDB.
-#endif
-}
-
-void enumerate_ht_chain(void)
-{
-#if CONFIG_HT_CHAIN_UNITID_BASE != 0
-/* CONFIG_HT_CHAIN_UNITID_BASE could be 0 (only one ht device in the ht chain),
- if so, don't need to go through the chain */
-
- /* Assumption the HT chain that is bus 0 has the HT I/O Hub on it.
- * On most boards this just happens. If a CPU has multiple
- * non Coherent links the appropriate bus registers for the
- * links needs to be programed to point at bus 0.
- */
- unsigned int next_unitid, last_unitid = 0;
-#if CONFIG_HT_CHAIN_END_UNITID_BASE != 0x20
- // let't record the device of last ht device, So we can set the
- // Unitid to CONFIG_HT_CHAIN_END_UNITID_BASE
- unsigned int real_last_unitid = 0;
- u8 real_last_pos = 0;
- int ht_dev_num = 0; // except host_bridge
- u8 end_used = 0;
-#endif
-
- next_unitid = CONFIG_HT_CHAIN_UNITID_BASE;
- do {
- u32 id;
- u8 hdr_type, pos;
- last_unitid = next_unitid;
-
- id = pci_io_read_config32(PCI_DEV(0,0,0), PCI_VENDOR_ID);
- /* If the chain is enumerated quit */
- if (((id & 0xffff) == 0x0000) || ((id & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0xffff) ||
- (((id >> 16) & 0xffff) == 0x0000))
- {
- break;
- }
-
- hdr_type = pci_io_read_config8(PCI_DEV(0,0,0), PCI_HEADER_TYPE);
- pos = 0;
- hdr_type &= 0x7f;
-
- if ((hdr_type == PCI_HEADER_TYPE_NORMAL) ||
- (hdr_type == PCI_HEADER_TYPE_BRIDGE))
- {
- pos = pci_io_read_config8(PCI_DEV(0,0,0), PCI_CAPABILITY_LIST);
- }
- while (pos != 0) {
- u8 cap;
- cap = pci_io_read_config8(PCI_DEV(0,0,0), pos + PCI_CAP_LIST_ID);
- if (cap == PCI_CAP_ID_HT) {
- u16 flags;
- /* Read and write and reread flags so the link
- * direction bit is valid.
- */
- flags = pci_io_read_config16(PCI_DEV(0,0,0), pos + PCI_CAP_FLAGS);
- pci_io_write_config16(PCI_DEV(0,0,0), pos + PCI_CAP_FLAGS, flags);
- flags = pci_io_read_config16(PCI_DEV(0,0,0), pos + PCI_CAP_FLAGS);
- if ((flags >> 13) == 0) {
- unsigned int count;
- unsigned int ctrl, ctrl_off;
- pci_devfn_t devx;
-
-#if CONFIG_HT_CHAIN_END_UNITID_BASE != 0x20
- if (next_unitid >= 0x18) {
- if (!end_used) {
- next_unitid = CONFIG_HT_CHAIN_END_UNITID_BASE;
- end_used = 1;
- } else {
- goto out;
- }
- }
- real_last_unitid = next_unitid;
- real_last_pos = pos;
- ht_dev_num++;
-#endif
- #if !CONFIG_HT_CHAIN_END_UNITID_BASE
- if (!next_unitid)
- goto out;
- #endif
- flags &= ~0x1f;
- flags |= next_unitid & 0x1f;
- count = (flags >> 5) & 0x1f;
- devx = PCI_DEV(0, next_unitid, 0);
- next_unitid += count;
-
- pci_io_write_config16(PCI_DEV(0, 0, 0), pos + PCI_CAP_FLAGS, flags);
-
- /* Test for end of chain */
- ctrl_off = ((flags >> 10) & 1)?
- PCI_HT_CAP_SLAVE_CTRL0 : PCI_HT_CAP_SLAVE_CTRL1;
-
- do {
- ctrl = pci_io_read_config16(devx, pos + ctrl_off);
- /* Is this the end of the hypertransport chain? */
- if (ctrl & (1 << 6)) {
- goto out;
- }
-
- if (ctrl & ((1 << 4) | (1 << 8))) {
- /*
- * Either the link has failed, or we have
- * a CRC error.
- * Sometimes this can happen due to link
- * retrain, so lets knock it down and see
- * if its transient
- */
- ctrl |= ((1 << 4) | (1 <<8)); // Link fail + Crc
- pci_io_write_config16(devx, pos + ctrl_off, ctrl);
- ctrl = pci_io_read_config16(devx, pos + ctrl_off);
- if (ctrl & ((1 << 4) | (1 << 8))) {
- // can not clear the error
- break;
- }
- }
- } while ((ctrl & (1 << 5)) == 0);
-
- break;
- }
- }
- pos = pci_io_read_config8(PCI_DEV(0, 0, 0), pos + PCI_CAP_LIST_NEXT);
- }
- } while (last_unitid != next_unitid);
-
-out: ;
-#if CONFIG_HT_CHAIN_END_UNITID_BASE != 0x20
- if ((ht_dev_num > 1) && (real_last_unitid != CONFIG_HT_CHAIN_END_UNITID_BASE) && !end_used) {
- u16 flags;
- flags = pci_io_read_config16(PCI_DEV(0,real_last_unitid,0), real_last_pos + PCI_CAP_FLAGS);
- flags &= ~0x1f;
- flags |= CONFIG_HT_CHAIN_END_UNITID_BASE & 0x1f;
- pci_io_write_config16(PCI_DEV(0, real_last_unitid, 0), real_last_pos + PCI_CAP_FLAGS, flags);
- }
-#endif
-
-#endif
-}
diff --git a/src/northbridge/amd/amdfam10/early_ht.h b/src/northbridge/amd/amdfam10/early_ht.h
deleted file mode 100644
index 67476fd849..0000000000
--- a/src/northbridge/amd/amdfam10/early_ht.h
+++ /dev/null
@@ -1,21 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-#ifndef EARLY_HT_H
-#define EARLY_HT_H
-
-void set_bsp_node_CHtExtNodeCfgEn(void);
-void enumerate_ht_chain(void);
-
-#endif
diff --git a/src/northbridge/amd/amdfam10/get_pci1234.c b/src/northbridge/amd/amdfam10/get_pci1234.c
deleted file mode 100644
index 94ec831d65..0000000000
--- a/src/northbridge/amd/amdfam10/get_pci1234.c
+++ /dev/null
@@ -1,132 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <bootstate.h>
-#include <device/pci.h>
-#include <stdint.h>
-
-#include <cpu/amd/amdfam10_sysconf.h>
-
-
-/* Need pci1234 array
- * pci1234[0] will record sblink and bus range
- * pci1234[i] will record ht chain i.
- * It will keep the sequence when some ht io card is not installed.
- *
- * 1n: 8
- * 2n: 7x2
- * 3n: 6x3
- * 4n: 5x4
- * 5n: 4x5
- * 6n: 3x6
- * 7n: 2x7
- * 8n: 1x8
- *
- * 8n(4x2): 8x4
- * 16n(4x4): 16*2
- * 20n(4x5): 20x1
- * 32n(4x4+4x4): 16x1
- *
- * Total: xxx: I just want to use 32 instead, If you have more, you may need to
- * reset HC_POSSIBLE_NUM and update ssdt.dsl (hcdn, hclk)
- *
- * Put all the possible ht node/link to the list tp pci1234[] in get_bus_conf.c
- * on MB dir. How about co-processor on socket 1 on 2 way system.
- * or socket 2, and socket3 on 4 way system? treat that as one hc too!
- *
- */
-
-#include "northbridge.h"
-
-void get_pci1234(void)
-{
-
- int i,j;
- u32 dword;
-
- dword = sysconf.sblk<<8;
- dword |= 1;
- sysconf.pci1234[0] = dword; // sblink
- sysconf.hcid[0] = 0;
-
- /* about hardcode numbering for HT_IO support
- set the node_id and link_id that could have ht chain in the one array,
- then check if is enabled.... then update final value
- */
-
- //here we need to set hcdn
- //1. hypertransport.c need to record hcdn_reg together with 0xe0, 0xe4, 0xe8, 0xec when are set
- //2. so at the same time we need update hsdn with hcdn_reg here
-
- for (j = 0; j < sysconf.ht_c_num; j++) {
- u32 dwordx;
- dwordx = sysconf.ht_c_conf_bus[j];
- dwordx &=0xfffffffd; //keep bus num, node_id, link_num, enable bits
- if ((dwordx & 0x7fd) == dword) { //SBLINK
- sysconf.pci1234[0] = dwordx;
- sysconf.hcdn[0] = sysconf.hcdn_reg[j];
- continue;
- }
- if ((dwordx & 1)) {
- // We need to find out the number of HC
- // for exact match
- for (i = 1; i < sysconf.hc_possible_num; i++) {
- if ((dwordx & 0x7fc) == (sysconf.pci1234[i] & 0x7fc)) { // same node and same linkn
- sysconf.pci1234[i] = dwordx;
- sysconf.hcdn[i] = sysconf.hcdn_reg[j];
- break;
- }
- }
- // for 0xffc match or same node
- for (i = 1; i < sysconf.hc_possible_num; i++) {
- if ((dwordx & 0x7fc) == (dwordx & sysconf.pci1234[i] & 0x7fc)) {
- sysconf.pci1234[i] = dwordx;
- sysconf.hcdn[i] = sysconf.hcdn_reg[j];
- break;
- }
- }
- }
- }
-
- for (i = 1; i < sysconf.hc_possible_num; i++) {
- if (!(sysconf.pci1234[i] & 1)) {
- sysconf.pci1234[i] = 0;
- sysconf.hcdn[i] = 0x20202020;
- }
- sysconf.hcid[i] = 0;
- }
-}
-
-void get_default_pci1234(int mb_hc_possible)
-{
- int i;
-
- for (i = 0; i < mb_hc_possible; i++) {
- sysconf.pci1234[i] = 0x0000ffc;
- sysconf.hcdn[i] = 0x20202020;
- }
- sysconf.hc_possible_num = mb_hc_possible;
- get_pci1234();
-}
-
-static void amd_bs_sysconf(void *arg)
-{
- /* Prepare sysconf structures, which are used to generate IRQ,
- * MP and ACPI table entries.
- */
- get_bus_conf();
-}
-
-BOOT_STATE_INIT_ENTRY(BS_WRITE_TABLES, BS_ON_ENTRY, amd_bs_sysconf, NULL);
diff --git a/src/northbridge/amd/amdfam10/ht_config.c b/src/northbridge/amd/amdfam10/ht_config.c
deleted file mode 100644
index 8499dbb623..0000000000
--- a/src/northbridge/amd/amdfam10/ht_config.c
+++ /dev/null
@@ -1,229 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include <console/console.h>
-#include <device/device.h>
-#include <device/pci_ops.h>
-
-#include <cpu/amd/amdfam10_sysconf.h>
-#include "northbridge.h"
-#include "amdfam10.h"
-#include "ht_config.h"
-
-struct dram_base_mask_t get_dram_base_mask(u32 nodeid)
-{
- struct dram_base_mask_t d;
- struct device *dev = __f1_dev[0];
-
- u32 temp;
- temp = pci_read_config32(dev, 0x44 + (nodeid << 3)); //[39:24] at [31:16]
- d.mask = ((temp & 0xfff80000)>>(8+3)); // mask out DramMask [26:24] too
- temp = pci_read_config32(dev, 0x144 + (nodeid <<3)) & 0xff; //[47:40] at [7:0]
- d.mask |= temp<<21;
-
- temp = pci_read_config32(dev, 0x40 + (nodeid << 3)); //[39:24] at [31:16]
- d.mask |= (temp & 1); // enable bit
-
- d.base = ((temp & 0xfff80000)>>(8+3)); // mask out DramBase [26:24) too
- temp = pci_read_config32(dev, 0x140 + (nodeid <<3)) & 0xff; //[47:40] at [7:0]
- d.base |= temp<<21;
- return d;
-}
-
-void set_config_map_reg(struct bus *link)
-{
- u32 tempreg;
- u32 i;
- u32 ht_c_index = get_ht_c_index(link);
- u32 linkn = link->link_num & 0x0f;
- u32 busn_min = (link->secondary >> sysconf.segbit) & 0xff;
- u32 busn_max = (link->subordinate >> sysconf.segbit) & 0xff;
- u32 nodeid = amdfam10_nodeid(link->dev);
-
- tempreg = ((nodeid & 0x30) << (12-4)) | ((nodeid & 0xf) << 4) | 3;
- tempreg |= (busn_max << 24)|(busn_min << 16)|(linkn << 8);
-
- for (i = 0; i < sysconf.nodes; i++) {
- struct device *dev = __f1_dev[i];
- pci_write_config32(dev, 0xe0 + ht_c_index * 4, tempreg);
- }
-}
-
-void clear_config_map_reg(struct bus *link)
-{
- u32 i;
- u32 ht_c_index = get_ht_c_index(link);
-
- for (i = 0; i < sysconf.nodes; i++) {
- struct device *dev = __f1_dev[i];
- pci_write_config32(dev, 0xe0 + ht_c_index * 4, 0);
- }
-}
-
-
-static u32 ht_c_key(struct bus *link)
-{
- u32 nodeid = amdfam10_nodeid(link->dev);
- u32 linkn = link->link_num & 0x0f;
- u32 val = (linkn << 8) | ((nodeid & 0x3f) << 2) | 3;
- return val;
-}
-
-static u32 get_ht_c_index_by_key(u32 key, sys_info_conf_t *sysinfo)
-{
- u32 ht_c_index = 0;
-
- for (ht_c_index = 0; ht_c_index < 32; ht_c_index++) {
- if ((sysinfo->ht_c_conf_bus[ht_c_index] & 0xfff) == key) {
- return ht_c_index;
- }
- }
-
- for (ht_c_index = 0; ht_c_index < 32; ht_c_index++) {
- if (sysinfo->ht_c_conf_bus[ht_c_index] == 0) {
- return ht_c_index;
- }
- }
-
- return -1;
-}
-
-u32 get_ht_c_index(struct bus *link)
-{
- u32 val = ht_c_key(link);
- return get_ht_c_index_by_key(val, &sysconf);
-}
-
-void store_ht_c_conf_bus(struct bus *link)
-{
- u32 val = ht_c_key(link);
- u32 ht_c_index = get_ht_c_index_by_key(val, &sysconf);
-
- u32 segn = (link->subordinate >> 8) & 0x0f;
- u32 busn_min = link->secondary & 0xff;
- u32 busn_max = link->subordinate & 0xff;
-
- val |= (segn << 28) | (busn_max << 20) | (busn_min << 12);
-
- sysconf.ht_c_conf_bus[ht_c_index] = val;
- sysconf.hcdn_reg[ht_c_index] = link->hcdn_reg;
- sysconf.ht_c_num++;
-}
-
-u32 get_io_addr_index(u32 nodeid, u32 linkn)
-{
- u32 index;
-
- for (index = 0; index < 256; index++) {
-
- if (index + 4 >= ARRAY_SIZE(sysconf.conf_io_addrx))
- die("Error! Out of bounds read in %s:%s\n", __FILE__, __func__);
-
- if (sysconf.conf_io_addrx[index+4] == 0) {
- sysconf.conf_io_addr[index+4] = (nodeid & 0x3f);
- sysconf.conf_io_addrx[index+4] = 1 | ((linkn & 0x7)<<4);
- return index;
- }
- }
-
- return 0;
-}
-
-u32 get_mmio_addr_index(u32 nodeid, u32 linkn)
-{
- u32 index;
-
- for (index = 0; index < 64; index++) {
-
- if (index + 8 >= ARRAY_SIZE(sysconf.conf_mmio_addrx))
- die("Error! Out of bounds read in %s:%s\n", __FILE__, __func__);
-
- if (sysconf.conf_mmio_addrx[index+8] == 0) {
- sysconf.conf_mmio_addr[index+8] = (nodeid & 0x3f);
- sysconf.conf_mmio_addrx[index+8] = 1 | ((linkn & 0x7)<<4);
- return index;
- }
- }
-
- return 0;
-}
-
-
-void store_conf_io_addr(u32 nodeid, u32 linkn, u32 reg, u32 index,
- u32 io_min, u32 io_max)
-{
- u32 val;
-
- /* io range allocation */
- index = (reg-0xc0)>>3;
-
- val = (nodeid & 0x3f); // 6 bits used
- sysconf.conf_io_addr[index] = val | ((io_max<<8) & 0xfffff000); //limit : with nodeid
- val = 3 | ((linkn & 0x7)<<4); // 8 bits used
- sysconf.conf_io_addrx[index] = val | ((io_min<<8) & 0xfffff000); // base : with enable bit
-
- if (sysconf.io_addr_num < (index+1))
- sysconf.io_addr_num = index+1;
-}
-
-
-void store_conf_mmio_addr(u32 nodeid, u32 linkn, u32 reg, u32 index,
- u32 mmio_min, u32 mmio_max)
-{
- u32 val;
-
- /* io range allocation */
- index = (reg-0x80)>>3;
-
- val = (nodeid & 0x3f); // 6 bits used
- sysconf.conf_mmio_addr[index] = val | (mmio_max & 0xffffff00); //limit : with nodeid and linkn
- val = 3 | ((linkn & 0x7)<<4); // 8 bits used
- sysconf.conf_mmio_addrx[index] = val | (mmio_min & 0xffffff00); // base : with enable bit
-
- if (sysconf.mmio_addr_num<(index+1))
- sysconf.mmio_addr_num = index+1;
-}
-
-
-void set_io_addr_reg(struct device *dev, u32 nodeid, u32 linkn, u32 reg,
- u32 io_min, u32 io_max)
-{
- u32 i;
- u32 tempreg;
-
- /* io range allocation */
- tempreg = (nodeid&0xf) | ((nodeid & 0x30)<<(8-4)) | (linkn<<4) | ((io_max&0xf0)<<(12-4)); //limit
- for (i = 0; i < sysconf.nodes; i++)
- pci_write_config32(__f1_dev[i], reg+4, tempreg);
-
- tempreg = 3 /*| (3<<4)*/ | ((io_min&0xf0)<<(12-4)); //base :ISA and VGA ?
- for (i = 0; i < sysconf.nodes; i++)
- pci_write_config32(__f1_dev[i], reg, tempreg);
-}
-
-void set_mmio_addr_reg(u32 nodeid, u32 linkn, u32 reg, u32 index, u32 mmio_min, u32 mmio_max, u32 nodes)
-{
- u32 i;
- u32 tempreg;
-
- /* io range allocation */
- tempreg = (nodeid&0xf) | (linkn<<4) | (mmio_max&0xffffff00); //limit
- for (i = 0; i < nodes; i++)
- pci_write_config32(__f1_dev[i], reg+4, tempreg);
- tempreg = 3 | (nodeid & 0x30) | (mmio_min&0xffffff00);
- for (i = 0; i < sysconf.nodes; i++)
- pci_write_config32(__f1_dev[i], reg, tempreg);
-}
diff --git a/src/northbridge/amd/amdfam10/ht_config.h b/src/northbridge/amd/amdfam10/ht_config.h
deleted file mode 100644
index 748a9818c1..0000000000
--- a/src/northbridge/amd/amdfam10/ht_config.h
+++ /dev/null
@@ -1,54 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef __AMDFAM10_HT_CONFIG_H__
-#define __AMDFAM10_HT_CONFIG_H__
-
-typedef struct amdfam10_sysconf_t sys_info_conf_t;
-
-/* FIXME */
-u32 amdfam10_nodeid(struct device *dev);
-extern struct device *__f1_dev[];
-
-struct dram_base_mask_t {
- u32 base; //[47:27] at [28:8]
- u32 mask; //[47:27] at [28:8] and enable at bit 0
-};
-
-struct dram_base_mask_t get_dram_base_mask(u32 nodeid);
-
-u32 get_ht_c_index(struct bus *link);
-void store_ht_c_conf_bus(struct bus *link);
-
-void set_config_map_reg(struct bus *link);
-void clear_config_map_reg(struct bus *link);
-
-
-void store_conf_io_addr(u32 nodeid, u32 linkn, u32 reg, u32 index,
- u32 io_min, u32 io_max);
-
-void store_conf_mmio_addr(u32 nodeid, u32 linkn, u32 reg, u32 index,
- u32 mmio_min, u32 mmio_max);
-
-
-u32 get_io_addr_index(u32 nodeid, u32 linkn);
-u32 get_mmio_addr_index(u32 nodeid, u32 linkn);
-
-void set_io_addr_reg(struct device *dev, u32 nodeid, u32 linkn, u32 reg,
- u32 io_min, u32 io_max);
-
-void set_mmio_addr_reg(u32 nodeid, u32 linkn, u32 reg, u32 index, u32 mmio_min, u32 mmio_max, u32 nodes);
-
-#endif
diff --git a/src/northbridge/amd/amdfam10/inline_helper.c b/src/northbridge/amd/amdfam10/inline_helper.c
deleted file mode 100644
index 7f260318f7..0000000000
--- a/src/northbridge/amd/amdfam10/inline_helper.c
+++ /dev/null
@@ -1,31 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/cpu.h>
-
-static inline uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
diff --git a/src/northbridge/amd/amdfam10/link_control.c b/src/northbridge/amd/amdfam10/link_control.c
deleted file mode 100644
index 384772374b..0000000000
--- a/src/northbridge/amd/amdfam10/link_control.c
+++ /dev/null
@@ -1,153 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* Configure various power control registers, including processor
- * boost support.
- */
-
-#include <console/console.h>
-#include <device/device.h>
-#include <device/pci.h>
-#include <device/pci_ids.h>
-#include <device/pci_ops.h>
-#include <pc80/mc146818rtc.h>
-#include <cpu/amd/model_10xxx_rev.h>
-#include <types.h>
-
-#include "amdfam10.h"
-
-static void nb_control_init(struct device *dev)
-{
- uint8_t enable_c_states;
- uint8_t enable_cc6;
- uint32_t dword;
-
- printk(BIOS_DEBUG, "NB: Function 4 Link Control.. ");
-
- /* Configure L3 Power Control */
- dword = pci_read_config32(dev, 0x1c4);
- dword |= (0x1 << 8); /* L3PwrSavEn = 1 */
- pci_write_config32(dev, 0x1c4, dword);
-
- if (is_fam15h()) {
- /* Configure L3 Control 2 */
- dword = pci_read_config32(dev, 0x1cc);
- dword &= ~(0x7 << 6); /* ImplRdProjDelayThresh = 0x2 */
- dword |= (0x2 << 6);
- pci_write_config32(dev, 0x1cc, dword);
-
- /* Configure TDP Accumulator Divisor Control */
- dword = pci_read_config32(dev, 0x104);
- dword &= ~(0xfff << 2); /* TdpAccDivRate = 0xc8 */
- dword |= (0xc8 << 2);
- dword &= ~0x3; /* TdpAccDivVal = 0x1 */
- dword |= 0x1;
- pci_write_config32(dev, 0x104, dword);
-
- /* Configure Sample and Residency Timers */
- dword = pci_read_config32(dev, 0x110);
- dword &= ~0xfff; /* CSampleTimer = 0x1 */
- dword |= 0x1;
- pci_write_config32(dev, 0x110, dword);
-
- /* Configure APM TDP Control */
- dword = pci_read_config32(dev, 0x16c);
- dword |= (0x1 << 4); /* ApmTdpLimitIntEn = 1 */
- pci_write_config32(dev, 0x16c, dword);
-
- /* Enable APM */
- dword = pci_read_config32(dev, 0x15c);
- dword |= (0x1 << 7); /* ApmMasterEn = 1 */
- pci_write_config32(dev, 0x15c, dword);
-
- enable_c_states = 0;
- enable_cc6 = 0;
-#if CONFIG(HAVE_ACPI_TABLES)
- uint8_t nvram;
-
- if (get_option(&nvram, "cpu_c_states") == CB_SUCCESS)
- enable_c_states = !!nvram;
-
- if (get_option(&nvram, "cpu_cc6_state") == CB_SUCCESS)
- enable_cc6 = !!nvram;
-#endif
-
- if (enable_c_states) {
- /* Configure C-state Control 1 */
- dword = pci_read_config32(dev, 0x118);
- dword |= (0x1 << 24); /* PwrGateEnCstAct1 = 1 */
- dword &= ~(0x7 << 21); /* ClkDivisorCstAct1 = 0x0 */
- dword &= ~(0x3 << 18); /* CacheFlushTmrSelCstAct1 = 0x1 */
- dword |= (0x1 << 18);
- dword |= (0x1 << 17); /* CacheFlushEnCstAct1 = 1 */
- dword |= (0x1 << 16); /* CpuPrbEnCstAct1 = 1 */
- dword &= ~(0x1 << 8); /* PwrGateEnCstAct0 = 0 */
- dword &= ~(0x7 << 5); /* ClkDivisorCstAct0 = 0x0 */
- dword &= ~(0x3 << 2); /* CacheFlushTmrSelCstAct0 = 0x2 */
- dword |= (0x2 << 2);
- dword |= (0x1 << 1); /* CacheFlushEnCstAct0 = 1 */
- dword |= 0x1; /* CpuPrbEnCstAct0 = 1 */
- pci_write_config32(dev, 0x118, dword);
-
- /* Configure C-state Control 2 */
- dword = pci_read_config32(dev, 0x11c);
- dword &= ~(0x1 << 8); /* PwrGateEnCstAct2 = 0 */
- dword &= ~(0x7 << 5); /* ClkDivisorCstAct2 = 0x0 */
- dword &= ~(0x3 << 2); /* CacheFlushTmrSelCstAct0 = 0x0 */
- dword &= ~(0x1 << 1); /* CacheFlushEnCstAct0 = 0 */
- dword &= ~(0x1); /* CpuPrbEnCstAct0 = 0 */
- pci_write_config32(dev, 0x11c, dword);
-
- /* Configure C-state Policy Control 1 */
- dword = pci_read_config32(dev, 0x128);
- dword &= ~(0x7f << 5); /* CacheFlushTmr = 0x28 */
- dword |= (0x28 << 5);
- dword &= ~0x1; /* CoreCstateMode = !enable_cc6 */
- dword |= ((enable_cc6)?0:1);
- pci_write_config32(dev, 0x128, dword);
- }
- }
-
- printk(BIOS_DEBUG, "done.\n");
-}
-
-
-static struct device_operations mcf4_ops = {
- .read_resources = pci_dev_read_resources,
- .set_resources = pci_dev_set_resources,
- .enable_resources = pci_dev_enable_resources,
- .init = nb_control_init,
- .scan_bus = 0,
- .ops_pci = 0,
-};
-
-static const struct pci_driver mcf4_driver_fam10 __pci_driver = {
- .ops = &mcf4_ops,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1204,
-};
-
-static const struct pci_driver mcf4_driver_fam15_model10 __pci_driver = {
- .ops = &mcf4_ops,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1404,
-};
-
-static const struct pci_driver mcf4_driver_fam15 __pci_driver = {
- .ops = &mcf4_ops,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1604,
-};
diff --git a/src/northbridge/amd/amdfam10/misc_control.c b/src/northbridge/amd/amdfam10/misc_control.c
deleted file mode 100644
index b0a1ab679a..0000000000
--- a/src/northbridge/amd/amdfam10/misc_control.c
+++ /dev/null
@@ -1,261 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2003 by Eric Biederman
- * Copyright (C) Stefan Reinauer
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* Turn off machine check triggers when reading
- * pci space where there are no devices.
- * This is necessary when scanning the bus for
- * devices which is done by the kernel
- */
-
-#include <console/console.h>
-#include <device/device.h>
-#include <device/pci.h>
-#include <device/pci_ids.h>
-#include <device/pci_ops.h>
-#include <pc80/mc146818rtc.h>
-#include <lib.h>
-#include <cbmem.h>
-#include <cpu/amd/model_10xxx_rev.h>
-#include <types.h>
-
-#include "amdfam10.h"
-
-/**
- * @brief Read resources for AGP aperture
- *
- * @param dev
- *
- * There is only one AGP aperture resource needed. The resource is added to
- * the northbridge of BSP.
- *
- * The same trick can be used to augment legacy VGA resources which can
- * be detect by generic pci reousrce allocator for VGA devices.
- * BAD: it is more tricky than I think, the resource allocation code is
- * implemented in a way to NOT DOING legacy VGA resource allocation on
- * purpose :-(.
- */
-static void mcf3_read_resources(struct device *dev)
-{
- struct resource *resource;
- unsigned char gart;
- /* Read the generic PCI resources */
- pci_dev_read_resources(dev);
-
- /* If we are not the first processor don't allocate the gart apeture */
- if (dev->path.pci.devfn != PCI_DEVFN(CONFIG_CDB, 3)) {
- return;
- }
-
- gart = 1;
- get_option(&gart, "gart");
-
- if (gart) {
- /* Add a Gart apeture resource */
- resource = new_resource(dev, 0x94);
- resource->size = CONFIG_AGP_APERTURE_SIZE;
- resource->align = log2(resource->size);
- resource->gran = log2(resource->size);
- resource->limit = 0xffffffff; /* 4G */
- resource->flags = IORESOURCE_MEM;
- }
-}
-
-static void set_agp_aperture(struct device *dev, uint32_t pci_id)
-{
- uint32_t dword;
- struct resource *resource;
-
- resource = probe_resource(dev, 0x94);
- if (resource) {
- struct device *pdev;
- u32 gart_base, gart_acr;
-
- /* Remember this resource has been stored */
- resource->flags |= IORESOURCE_STORED;
-
- /* Find the size of the GART aperture */
- gart_acr = (0<<6)|(0<<5)|(0<<4)|((resource->gran - 25) << 1)|(0<<0);
-
- /* Get the base address */
- gart_base = ((resource->base) >> 25) & 0x00007fff;
-
- /* Update the other northbriges */
- pdev = 0;
- while ((pdev = dev_find_device(PCI_VENDOR_ID_AMD, pci_id, pdev))) {
- /* Store the GART size but don't enable it */
- pci_write_config32(pdev, 0x90, gart_acr);
-
- /* Store the GART base address */
- pci_write_config32(pdev, 0x94, gart_base);
-
- /* Don't set the GART Table base address */
- pci_write_config32(pdev, 0x98, 0);
-
- /* Report the resource has been stored... */
- report_resource_stored(pdev, resource, " <gart>");
-
- /* Errata 540 workaround */
- dword = pci_read_config32(pdev, 0x90);
- dword |= 0x1 << 6; /* DisGartTblWlkPrb = 0x1 */
- pci_write_config32(pdev, 0x90, dword);
- }
- }
-}
-
-static void mcf3_set_resources_fam10h(struct device *dev)
-{
- /* Set the gart aperture */
- set_agp_aperture(dev, 0x1203);
-
- /* Set the generic PCI resources */
- pci_dev_set_resources(dev);
-}
-
-static void mcf3_set_resources_fam15h_model10(struct device *dev)
-{
- /* Set the gart aperture */
- set_agp_aperture(dev, 0x1403);
-
- /* Set the generic PCI resources */
- pci_dev_set_resources(dev);
-}
-
-static void mcf3_set_resources_fam15h(struct device *dev)
-{
- /* Set the gart aperture */
- set_agp_aperture(dev, 0x1603);
-
- /* Set the generic PCI resources */
- pci_dev_set_resources(dev);
-}
-
-static void misc_control_init(struct device *dev)
-{
- uint32_t dword;
- uint8_t nvram;
- uint8_t boost_limit;
- uint8_t current_boost;
-
- printk(BIOS_DEBUG, "NB: Function 3 Misc Control.. ");
-
-#if CONFIG(DIMM_DDR3) && !CONFIG(NORTHBRIDGE_AMD_AGESA)
- uint8_t node;
- uint8_t slot;
- uint8_t dimm_present;
-
- /* Restore DRAM MCA registers */
- struct amdmct_memory_info *mem_info;
- mem_info = cbmem_find(CBMEM_ID_AMDMCT_MEMINFO);
- if (mem_info) {
- node = PCI_SLOT(dev->path.pci.devfn) - 0x18;
-
- /* Check node for installed DIMMs */
- dimm_present = 0;
-
- /* Check all slots for installed DIMMs */
- for (slot = 0; slot < MAX_DIMMS_SUPPORTED; slot++) {
- if (mem_info->dct_stat[node].DIMMPresent & (1 << slot)) {
- dimm_present = 1;
- break;
- }
- }
-
- if (dimm_present) {
- uint32_t mc4_status_high = pci_read_config32(dev, 0x4c);
- uint32_t mc4_status_low = pci_read_config32(dev, 0x48);
- if ((mc4_status_high & (0x1 << 31)) && (mc4_status_high != 0xffffffff)) {
- printk(BIOS_WARNING, "\nWARNING: MC4 Machine Check Exception detected on node %d!\n"
- "Signature: %08x%08x\n", node, mc4_status_high, mc4_status_low);
- }
-
- /* Clear MC4 error status */
- pci_write_config32(dev, 0x48, 0x0);
- pci_write_config32(dev, 0x4c, 0x0);
- }
- }
-#endif
-
- /* Disable Machine checks from Invalid Locations.
- * This is needed for PC backwards compatibility.
- */
- dword = pci_read_config32(dev, 0x44);
- dword |= (1<<6) | (1<<25);
- pci_write_config32(dev, 0x44, dword);
-
- boost_limit = 0xf;
- if (get_option(&nvram, "maximum_p_state_limit") == CB_SUCCESS)
- boost_limit = nvram & 0xf;
-
- /* Set P-state maximum value */
- dword = pci_read_config32(dev, 0xdc);
- current_boost = (dword >> 8) & 0x7;
- if (boost_limit > current_boost)
- boost_limit = current_boost;
- dword &= ~(0x7 << 8);
- dword |= (boost_limit & 0x7) << 8;
- pci_write_config32(dev, 0xdc, dword);
-
- printk(BIOS_DEBUG, "done.\n");
-}
-
-
-static struct device_operations mcf3_ops_fam10h = {
- .read_resources = mcf3_read_resources,
- .set_resources = mcf3_set_resources_fam10h,
- .enable_resources = pci_dev_enable_resources,
- .init = misc_control_init,
- .scan_bus = 0,
- .ops_pci = 0,
-};
-
-static struct device_operations mcf3_ops_fam15h_model10 = {
- .read_resources = mcf3_read_resources,
- .set_resources = mcf3_set_resources_fam15h_model10,
- .enable_resources = pci_dev_enable_resources,
- .init = misc_control_init,
- .scan_bus = 0,
- .ops_pci = 0,
-};
-
-static struct device_operations mcf3_ops_fam15h = {
- .read_resources = mcf3_read_resources,
- .set_resources = mcf3_set_resources_fam15h,
- .enable_resources = pci_dev_enable_resources,
- .init = misc_control_init,
- .scan_bus = 0,
- .ops_pci = 0,
-};
-
-static const struct pci_driver mcf3_driver __pci_driver = {
- .ops = &mcf3_ops_fam10h,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1203,
-};
-
-static const struct pci_driver mcf3_driver_fam15_model10 __pci_driver = {
- .ops = &mcf3_ops_fam15h_model10,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1403,
-};
-
-static const struct pci_driver mcf3_driver_fam15 __pci_driver = {
- .ops = &mcf3_ops_fam15h,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1603,
-};
diff --git a/src/northbridge/amd/amdfam10/nb_control.c b/src/northbridge/amd/amdfam10/nb_control.c
deleted file mode 100644
index a9bdb18415..0000000000
--- a/src/northbridge/amd/amdfam10/nb_control.c
+++ /dev/null
@@ -1,85 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* Configure various power control registers, including processor boost
- * and TDP monitoring support.
- */
-
-#include <console/console.h>
-#include <device/device.h>
-#include <device/pci.h>
-#include <device/pci_ids.h>
-#include <device/pci_ops.h>
-#include <cpu/amd/model_10xxx_rev.h>
-
-#include "amdfam10.h"
-
-static void nb_control_init(struct device *dev)
-{
- uint32_t dword;
- uint32_t f5x80;
- uint8_t cu_enabled;
- uint8_t compute_unit_count = 0;
-
- printk(BIOS_DEBUG, "NB: Function 5 Northbridge Control.. ");
-
- /* Determine the number of active compute units on this node */
- f5x80 = pci_read_config32(dev, 0x80);
- cu_enabled = f5x80 & 0xf;
- if (cu_enabled == 0x1)
- compute_unit_count = 1;
- if (cu_enabled == 0x3)
- compute_unit_count = 2;
- if (cu_enabled == 0x7)
- compute_unit_count = 3;
- if (cu_enabled == 0xf)
- compute_unit_count = 4;
-
- /* Configure Processor TDP Running Average */
- dword = pci_read_config32(dev, 0xe0);
- dword &= ~0xf; /* RunAvgRange = 0x9 */
- dword |= 0x9;
- pci_write_config32(dev, 0xe0, dword);
-
- /* Configure northbridge P-states */
- dword = pci_read_config32(dev, 0x170);
- dword &= ~(0x7 << 9); /* NbPstateThreshold = compute_unit_count */
- dword |= (compute_unit_count & 0x7) << 9;
- pci_write_config32(dev, 0x170, dword);
-
- printk(BIOS_DEBUG, "done.\n");
-}
-
-static struct device_operations mcf5_ops = {
- .read_resources = pci_dev_read_resources,
- .set_resources = pci_dev_set_resources,
- .enable_resources = pci_dev_enable_resources,
- .init = nb_control_init,
- .scan_bus = 0,
- .ops_pci = 0,
-};
-
-static const struct pci_driver mcf5_driver_fam15_model10 __pci_driver = {
- .ops = &mcf5_ops,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1405,
-};
-
-static const struct pci_driver mcf5_driver_fam15 __pci_driver = {
- .ops = &mcf5_ops,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1605,
-};
diff --git a/src/northbridge/amd/amdfam10/northbridge.c b/src/northbridge/amd/amdfam10/northbridge.c
deleted file mode 100644
index df1d947cdb..0000000000
--- a/src/northbridge/amd/amdfam10/northbridge.c
+++ /dev/null
@@ -1,1928 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- * Copyright (C) 2015 - 2017 Timothy Pearson <tpearson@raptorengineering.com>, Raptor Engineering
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <console/console.h>
-#include <device/pci_ops.h>
-#include <stdint.h>
-#include <device/device.h>
-#include <device/pci.h>
-#include <device/pci_ids.h>
-#include <device/hypertransport.h>
-#include <stdlib.h>
-#include <string.h>
-#include <lib.h>
-#include <smbios.h>
-#include <cpu/cpu.h>
-#include <delay.h>
-#include <cpu/x86/lapic.h>
-#include <cpu/x86/cache.h>
-#include <cpu/amd/mtrr.h>
-#include <cpu/amd/amdfam10_sysconf.h>
-#include <cpu/amd/msr.h>
-#include <cpu/amd/family_10h-family_15h/ram_calc.h>
-#include <types.h>
-
-#if CONFIG(LOGICAL_CPUS)
-#include <cpu/amd/multicore.h>
-#include <pc80/mc146818rtc.h>
-#endif
-
-#include "northbridge.h"
-#include "amdfam10.h"
-#include "ht_config.h"
-#include "chip.h"
-
-#if CONFIG_HW_MEM_HOLE_SIZEK != 0
-#include <cpu/amd/model_10xxx_rev.h>
-#endif
-
-#if CONFIG(DIMM_DDR3)
-#include "../amdmct/mct_ddr3/s3utils.h"
-#endif
-
-struct amdfam10_sysconf_t sysconf;
-u8 pirq_router_bus;
-
-#define FX_DEVS NODE_NUMS
-static struct device *__f0_dev[FX_DEVS];
-struct device *__f1_dev[FX_DEVS];
-static struct device *__f2_dev[FX_DEVS];
-static struct device *__f4_dev[FX_DEVS];
-static unsigned int fx_devs = 0;
-
-struct device *get_node_pci(u32 nodeid, u32 fn)
-{
-#if NODE_NUMS + CONFIG_CDB >= 32
- if ((CONFIG_CDB + nodeid) < 32) {
- return dev_find_slot(CONFIG_CBB, PCI_DEVFN(CONFIG_CDB + nodeid, fn));
- } else {
- return dev_find_slot(CONFIG_CBB-1, PCI_DEVFN(CONFIG_CDB + nodeid - 32, fn));
- }
-
-#else
- return dev_find_slot(CONFIG_CBB, PCI_DEVFN(CONFIG_CDB + nodeid, fn));
-#endif
-}
-
-static void get_fx_devs(void)
-{
- int i;
- for (i = 0; i < FX_DEVS; i++) {
- __f0_dev[i] = get_node_pci(i, 0);
- __f1_dev[i] = get_node_pci(i, 1);
- __f2_dev[i] = get_node_pci(i, 2);
- __f4_dev[i] = get_node_pci(i, 4);
- if (__f0_dev[i] != NULL && __f1_dev[i] != NULL)
- fx_devs = i+1;
- }
- if (__f1_dev[0] == NULL || __f0_dev[0] == NULL || fx_devs == 0) {
- die("Cannot find 0:0x18.[0|1]\n");
- }
-}
-
-static u32 f1_read_config32(unsigned int reg)
-{
- if (fx_devs == 0)
- get_fx_devs();
- return pci_read_config32(__f1_dev[0], reg);
-}
-
-static void f1_write_config32(unsigned int reg, u32 value)
-{
- int i;
- if (fx_devs == 0)
- get_fx_devs();
- for (i = 0; i < fx_devs; i++) {
- struct device *dev;
- dev = __f1_dev[i];
- if (dev && dev->enabled) {
- pci_write_config32(dev, reg, value);
- }
- }
-}
-
-u32 amdfam10_nodeid(struct device *dev)
-{
-#if NODE_NUMS == 64
- unsigned int busn;
- busn = dev->bus->secondary;
- if (busn != CONFIG_CBB) {
- return (dev->path.pci.devfn >> 3) - CONFIG_CDB + 32;
- } else {
- return (dev->path.pci.devfn >> 3) - CONFIG_CDB;
- }
-
-#else
- return (dev->path.pci.devfn >> 3) - CONFIG_CDB;
-#endif
-}
-
-static void set_vga_enable_reg(u32 nodeid, u32 linkn)
-{
- u32 val;
-
- val = 1 | (nodeid<<4) | (linkn<<12);
- /* it will routing (1)mmio 0xa0000:0xbffff (2) io 0x3b0:0x3bb,
- 0x3c0:0x3df */
- f1_write_config32(0xf4, val);
-
-}
-
-typedef enum {
- HT_ROUTE_CLOSE,
- HT_ROUTE_SCAN,
- HT_ROUTE_FINAL,
-} scan_state;
-
-static void ht_route_link(struct bus *link, scan_state mode)
-{
- struct bus *parent = link->dev->bus;
- u32 busses;
-
- if (mode == HT_ROUTE_SCAN) {
- if (parent->subordinate == 0)
- link->secondary = 0;
- else
- link->secondary = parent->subordinate + 1;
-
- link->subordinate = link->secondary;
- }
-
- /* Configure the bus numbers for this bridge: the configuration
- * transactions will not be propagated by the bridge if it is
- * not correctly configured
- */
- busses = pci_read_config32(link->dev, link->cap + 0x14);
- busses &= ~(0xff << 8);
- busses |= parent->secondary & 0xff;
- if (mode == HT_ROUTE_CLOSE)
- busses |= 0xff << 8;
- else if (mode == HT_ROUTE_SCAN)
- busses |= ((u32) link->secondary & 0xff) << 8;
- else if (mode == HT_ROUTE_FINAL)
- busses |= ((u32) link->secondary & 0xff) << 8;
- pci_write_config32(link->dev, link->cap + 0x14, busses);
-
- if (mode == HT_ROUTE_FINAL) {
- if (CONFIG(HT_CHAIN_DISTRIBUTE))
- parent->subordinate = ALIGN_UP(link->subordinate, 8) - 1;
- else
- parent->subordinate = link->subordinate;
- }
-}
-
-static void amd_g34_fixup(struct bus *link, struct device *dev)
-{
- uint32_t nodeid = amdfam10_nodeid(dev);
- uint8_t rev_gte_d = 0;
- uint8_t dual_node = 0;
- uint32_t f3xe8;
-
- if (cpuid_eax(0x80000001) >= 0x8)
- /* Revision D or later */
- rev_gte_d = 1;
-
- if (rev_gte_d || is_fam15h()) {
- f3xe8 = pci_read_config32(get_node_pci(0, 3), 0xe8);
-
- /* Check for dual node capability */
- if (f3xe8 & 0x20000000)
- dual_node = 1;
-
- if (dual_node) {
- /* Each G34 processor contains a defective HT link.
- * See the BKDG Rev 3.62 section 2.7.1.5 for details.
- */
- f3xe8 = pci_read_config32(get_node_pci(nodeid, 3), 0xe8);
- uint8_t internal_node_number = ((f3xe8 & 0xc0000000) >> 30);
- if (internal_node_number == 0) {
- /* Node 0 */
- if (link->link_num == 6) /* Link 2 Sublink 1 */
- printk(BIOS_DEBUG, "amdfam10_scan_chain(): node %d (internal node ID %d): skipping defective HT link\n", nodeid, internal_node_number);
- } else {
- /* Node 1 */
- if (link->link_num == 5) /* Link 1 Sublink 1 */
- printk(BIOS_DEBUG, "amdfam10_scan_chain(): node %d (internal node ID %d): skipping defective HT link\n", nodeid, internal_node_number);
- }
- }
- }
-}
-
-static void amdfam10_scan_chain(struct bus *link)
-{
- unsigned int next_unitid;
-
- /* See if there is an available configuration space mapping
- * register in function 1.
- */
- if (get_ht_c_index(link) >= 4)
- return;
-
- /* Set up the primary, secondary and subordinate bus numbers.
- * We have no idea how many busses are behind this bridge yet,
- * so we set the subordinate bus number to 0xff for the moment.
- */
-
- ht_route_link(link, HT_ROUTE_SCAN);
-
- /* set the config map space */
- set_config_map_reg(link);
-
- /* Now we can scan all of the subordinate busses i.e. the
- * chain on the hypertranport link
- */
-
- next_unitid = hypertransport_scan_chain(link);
-
- /* Now that nothing is overlapping it is safe to scan the children. */
- pci_scan_bus(link, 0x00, ((next_unitid - 1) << 3) | 7);
-
- ht_route_link(link, HT_ROUTE_FINAL);
-
- /* We know the number of busses behind this bridge. Set the
- * subordinate bus number to it's real value
- */
- if (0) {
- /* Clear the extend reg. */
- clear_config_map_reg(link);
- }
-
- set_config_map_reg(link);
-
- store_ht_c_conf_bus(link);
-}
-
-/* Do sb ht chain at first, in case s2885 put sb chain
- * (8131/8111) on link2, but put 8151 on link0.
- */
-static void relocate_sb_ht_chain(void)
-{
- struct device *dev;
- struct bus *link, *prev = NULL;
- u8 sblink;
-
- dev = dev_find_slot(CONFIG_CBB, PCI_DEVFN(CONFIG_CDB, 0));
- sblink = (pci_read_config32(dev, 0x64)>>8) & 7;
- link = dev->link_list;
-
- while (link) {
- if (link->link_num == sblink) {
- if (!prev)
- return;
- prev->next = link->next;
- link->next = dev->link_list;
- dev->link_list = link;
- return;
- }
- prev = link;
- link = link->next;
- }
-}
-
-static void trim_ht_chain(struct device *dev)
-{
- struct bus *link;
-
- /* Check for connected link. */
- for (link = dev->link_list; link; link = link->next) {
- link->cap = 0x80 + (link->link_num * 0x20);
- link->ht_link_up = ht_is_non_coherent_link(link);
- }
-}
-
-static void amdfam10_scan_chains(struct device *dev)
-{
- struct bus *link;
-
-#if CONFIG(CPU_AMD_SOCKET_G34_NON_AGESA)
- if (is_fam15h()) {
- uint8_t current_link_number = 0;
-
- for (link = dev->link_list; link; link = link->next) {
- /* The following links have changed position in Fam15h G34 processors:
- * Fam10 Fam15
- * Node 0
- * L3 --> L1
- * L0 --> L3
- * L1 --> L2
- * L2 --> L0
- * Node 1
- * L0 --> L0
- * L1 --> L3
- * L2 --> L1
- * L3 --> L2
- */
- if (link->link_num == 0)
- link->link_num = 3;
- else if (link->link_num == 1)
- link->link_num = 2;
- else if (link->link_num == 2)
- link->link_num = 0;
- else if (link->link_num == 3)
- link->link_num = 1;
- else if (link->link_num == 5)
- link->link_num = 7;
- else if (link->link_num == 6)
- link->link_num = 5;
- else if (link->link_num == 7)
- link->link_num = 6;
-
- current_link_number++;
- if (current_link_number > 3)
- current_link_number = 0;
- }
- }
-#endif
-
- /* Do sb ht chain at first, in case s2885 put sb chain (8131/8111) on link2, but put 8151 on link0 */
- trim_ht_chain(dev);
-
- for (link = dev->link_list; link; link = link->next) {
- if (link->ht_link_up) {
- if (CONFIG(CPU_AMD_MODEL_10XXX))
- amd_g34_fixup(link, dev);
- amdfam10_scan_chain(link);
- }
- }
-}
-
-
-static int reg_useable(unsigned int reg, struct device *goal_dev, unsigned int goal_nodeid,
- unsigned int goal_link)
-{
- struct resource *res;
- unsigned int nodeid, link = 0;
- int result;
- res = 0;
- for (nodeid = 0; !res && (nodeid < fx_devs); nodeid++) {
- struct device *dev;
- dev = __f0_dev[nodeid];
- if (!dev)
- continue;
- for (link = 0; !res && (link < 8); link++) {
- res = probe_resource(dev, IOINDEX(0x1000 + reg, link));
- }
- }
- result = 2;
- if (res) {
- result = 0;
- if ( (goal_link == (link - 1)) &&
- (goal_nodeid == (nodeid - 1)) &&
- (res->flags <= 1)) {
- result = 1;
- }
- }
- return result;
-}
-
-static struct resource *amdfam10_find_iopair(struct device *dev, unsigned int nodeid, unsigned int link)
-{
- struct resource *resource;
- u32 free_reg, reg;
- resource = 0;
- free_reg = 0;
- for (reg = 0xc0; reg <= 0xd8; reg += 0x8) {
- int result;
- result = reg_useable(reg, dev, nodeid, link);
- if (result == 1) {
- /* I have been allocated this one */
- break;
- } else if (result > 1) {
- /* I have a free register pair */
- free_reg = reg;
- }
- }
- if (reg > 0xd8) {
- reg = free_reg; // if no free, the free_reg still be 0
- }
-
- //Ext conf space
- if (!reg) {
- //because of Extend conf space, we will never run out of reg, but we need one index to differ them. so same node and same link can have multi range
- u32 index = get_io_addr_index(nodeid, link);
- reg = 0x110+ (index<<24) + (4<<20); // index could be 0, 255
- }
-
- resource = new_resource(dev, IOINDEX(0x1000 + reg, link));
-
- return resource;
-}
-
-static struct resource *amdfam10_find_mempair(struct device *dev, u32 nodeid, u32 link)
-{
- struct resource *resource;
- u32 free_reg, reg;
- resource = 0;
- free_reg = 0;
- for (reg = 0x80; reg <= 0xb8; reg += 0x8) {
- int result;
- result = reg_useable(reg, dev, nodeid, link);
- if (result == 1) {
- /* I have been allocated this one */
- break;
- } else if (result > 1) {
- /* I have a free register pair */
- free_reg = reg;
- }
- }
- if (reg > 0xb8) {
- reg = free_reg;
- }
-
- //Ext conf space
- if (!reg) {
- //because of Extend conf space, we will never run out of reg,
- // but we need one index to differ them. so same node and
- // same link can have multi range
- u32 index = get_mmio_addr_index(nodeid, link);
- reg = 0x110+ (index<<24) + (6<<20); // index could be 0, 63
-
- }
- resource = new_resource(dev, IOINDEX(0x1000 + reg, link));
- return resource;
-}
-
-
-static void amdfam10_link_read_bases(struct device *dev, u32 nodeid, u32 link)
-{
- struct resource *resource;
-
- /* Initialize the io space constraints on the current bus */
- resource = amdfam10_find_iopair(dev, nodeid, link);
- if (resource) {
- u32 align;
- align = log2(HT_IO_HOST_ALIGN);
- resource->base = 0;
- resource->size = 0;
- resource->align = align;
- resource->gran = align;
- resource->limit = 0xffffUL;
- resource->flags = IORESOURCE_IO | IORESOURCE_BRIDGE;
- }
-
- /* Initialize the prefetchable memory constraints on the current bus */
- resource = amdfam10_find_mempair(dev, nodeid, link);
- if (resource) {
- resource->base = 0;
- resource->size = 0;
- resource->align = log2(HT_MEM_HOST_ALIGN);
- resource->gran = log2(HT_MEM_HOST_ALIGN);
- resource->limit = 0xffffffffffULL;
- resource->flags = IORESOURCE_MEM | IORESOURCE_PREFETCH;
- resource->flags |= IORESOURCE_BRIDGE;
- }
-
- /* Initialize the memory constraints on the current bus */
- resource = amdfam10_find_mempair(dev, nodeid, link);
- if (resource) {
- resource->base = 0;
- resource->size = 0;
- resource->align = log2(HT_MEM_HOST_ALIGN);
- resource->gran = log2(HT_MEM_HOST_ALIGN);
- resource->limit = 0xffffffffffULL;
- resource->flags = IORESOURCE_MEM | IORESOURCE_BRIDGE;
- }
-}
-
-static void amdfam10_read_resources(struct device *dev)
-{
- u32 nodeid;
- struct bus *link;
- nodeid = amdfam10_nodeid(dev);
- for (link = dev->link_list; link; link = link->next) {
- if (link->children) {
- amdfam10_link_read_bases(dev, nodeid, link->link_num);
- }
- }
-}
-
-static void amdfam10_set_resource(struct device *dev, struct resource *resource,
- u32 nodeid)
-{
- resource_t rbase, rend;
- unsigned int reg, link_num;
- char buf[50];
-
- /* Make certain the resource has actually been set */
- if (!(resource->flags & IORESOURCE_ASSIGNED)) {
- return;
- }
-
- /* If I have already stored this resource don't worry about it */
- if (resource->flags & IORESOURCE_STORED) {
- return;
- }
-
- /* Only handle PCI memory and IO resources */
- if (!(resource->flags & (IORESOURCE_MEM | IORESOURCE_IO)))
- return;
-
- /* Ensure I am actually looking at a resource of function 1 */
- if ((resource->index & 0xffff) < 0x1000) {
- return;
- }
- /* Get the base address */
- rbase = resource->base;
-
- /* Get the limit (rounded up) */
- rend = resource_end(resource);
-
- /* Get the register and link */
- reg = resource->index & 0xfff; // 4k
- link_num = IOINDEX_LINK(resource->index);
-
- if (resource->flags & IORESOURCE_IO) {
-
- set_io_addr_reg(dev, nodeid, link_num, reg, rbase>>8, rend>>8);
- store_conf_io_addr(nodeid, link_num, reg, (resource->index >> 24), rbase>>8, rend>>8);
- } else if (resource->flags & IORESOURCE_MEM) {
- set_mmio_addr_reg(nodeid, link_num, reg, (resource->index >>24), rbase>>8, rend>>8, sysconf.nodes); // [39:8]
- store_conf_mmio_addr(nodeid, link_num, reg, (resource->index >>24), rbase>>8, rend>>8);
- }
- resource->flags |= IORESOURCE_STORED;
- snprintf(buf, sizeof(buf), " <node %x link %x>",
- nodeid, link_num);
- report_resource_stored(dev, resource, buf);
-}
-
-/**
- * I tried to reuse the resource allocation code in amdfam10_set_resource()
- * but it is too difficult to deal with the resource allocation magic.
- */
-
-static void amdfam10_create_vga_resource(struct device *dev, unsigned int nodeid)
-{
- struct bus *link;
- struct resource *res;
-
- /* find out which link the VGA card is connected,
- * we only deal with the 'first' vga card */
- for (link = dev->link_list; link; link = link->next) {
- if (link->bridge_ctrl & PCI_BRIDGE_CTL_VGA) {
-#if CONFIG(MULTIPLE_VGA_ADAPTERS)
- extern struct device *vga_pri; // the primary vga device, defined in device.c
- printk(BIOS_DEBUG, "VGA: vga_pri bus num = %d bus range [%d,%d]\n", vga_pri->bus->secondary,
- link->secondary,link->subordinate);
- /* We need to make sure the vga_pri is under the link */
- if ((vga_pri->bus->secondary >= link->secondary) &&
- (vga_pri->bus->secondary <= link->subordinate))
-#endif
- break;
- }
- }
-
- /* no VGA card installed */
- if (link == NULL)
- return;
-
- printk(BIOS_DEBUG, "VGA: %s (aka node %d) link %d has VGA device\n", dev_path(dev), nodeid, link->link_num);
- set_vga_enable_reg(nodeid, link->link_num);
-
- /* Redirect VGA memory access to MMIO
- * This signals the Family 10h resource parser
- * to add a new MMIO mapping to the Range 11
- * MMIO control registers (starting at F1x1B8),
- * and also reserves the resource in the E820 map.
- */
- res = new_resource(dev, IOINDEX(0x1000 + 0x1b8, link->link_num));
- res->base = 0xa0000;
- res->size = 0x20000;
- res->flags = IORESOURCE_MEM | IORESOURCE_ASSIGNED | IORESOURCE_FIXED;
- amdfam10_set_resource(dev, res, nodeid);
-}
-
-static void amdfam10_set_resources(struct device *dev)
-{
- unsigned int nodeid;
- struct bus *bus;
- struct resource *res;
-
- /* Find the nodeid */
- nodeid = amdfam10_nodeid(dev);
-
- amdfam10_create_vga_resource(dev, nodeid);
-
- /* Set each resource we have found */
- for (res = dev->resource_list; res; res = res->next) {
- amdfam10_set_resource(dev, res, nodeid);
- }
-
- for (bus = dev->link_list; bus; bus = bus->next) {
- if (bus->children) {
- assign_resources(bus);
- }
- }
-}
-
-static void mcf0_control_init(struct device *dev)
-{
-}
-
-#if CONFIG(HAVE_ACPI_TABLES)
-static const char *amdfam10_northbridge_acpi_name(const struct device *dev)
-{
- return "";
-}
-#endif
-
-static struct device_operations northbridge_operations = {
- .read_resources = amdfam10_read_resources,
- .set_resources = amdfam10_set_resources,
- .enable_resources = pci_dev_enable_resources,
- .init = mcf0_control_init,
- .scan_bus = amdfam10_scan_chains,
-#if CONFIG(HAVE_ACPI_TABLES)
- .write_acpi_tables = northbridge_write_acpi_tables,
- .acpi_fill_ssdt_generator = northbridge_acpi_write_vars,
- .acpi_name = amdfam10_northbridge_acpi_name,
-#endif
- .enable = 0,
- .ops_pci = 0,
-};
-
-static const struct pci_driver mcf0_driver __pci_driver = {
- .ops = &northbridge_operations,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1200,
-};
-
-static void amdfam10_nb_init(void *chip_info)
-{
- relocate_sb_ht_chain();
-}
-
-static const struct pci_driver mcf0_driver_fam15_model10 __pci_driver = {
- .ops = &northbridge_operations,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1400,
-};
-
-static const struct pci_driver mcf0_driver_fam15 __pci_driver = {
- .ops = &northbridge_operations,
- .vendor = PCI_VENDOR_ID_AMD,
- .device = 0x1600,
-};
-
-struct chip_operations northbridge_amd_amdfam10_ops = {
- CHIP_NAME("AMD Family 10h/15h Northbridge")
- .enable_dev = 0,
- .init = amdfam10_nb_init,
-};
-
-static void amdfam10_domain_read_resources(struct device *dev)
-{
- unsigned int reg;
- uint8_t nvram;
- uint8_t enable_cc6;
-
- /* Find the already assigned resource pairs */
- get_fx_devs();
- for (reg = 0x80; reg <= 0xd8; reg+= 0x08) {
- u32 base, limit;
- base = f1_read_config32(reg);
- limit = f1_read_config32(reg + 0x04);
- /* Is this register allocated? */
- if ((base & 3) != 0) {
- unsigned int nodeid, reg_link;
- struct device *reg_dev;
- if (reg < 0xc0) { // mmio
- nodeid = (limit & 0xf) + (base&0x30);
- } else { // io
- nodeid = (limit & 0xf) + ((base>>4)&0x30);
- }
- reg_link = (limit >> 4) & 7;
- reg_dev = __f0_dev[nodeid];
- if (reg_dev) {
- /* Reserve the resource */
- struct resource *res;
- res = new_resource(reg_dev, IOINDEX(0x1000 + reg, reg_link));
- if (res) {
- res->flags = 1;
- }
- }
- }
- }
- /* FIXME: do we need to check extend conf space?
- I don't believe that much preset value */
-
- pci_domain_read_resources(dev);
-
- /* We have MMCONF_SUPPORT, create the resource window. */
- mmconf_resource(dev, MMIO_CONF_BASE);
-
- /* Reserve lower DRAM region to force PCI MMIO region to correct location above 0xefffffff */
- ram_resource(dev, 7, 0, rdmsr(TOP_MEM).lo >> 10);
-
- if (is_fam15h()) {
- enable_cc6 = 0;
- if (get_option(&nvram, "cpu_cc6_state") == CB_SUCCESS)
- enable_cc6 = !!nvram;
-
- if (enable_cc6) {
- uint8_t node;
- uint8_t interleaved;
- int8_t range;
- uint8_t max_node;
- uint64_t max_range_limit;
- uint32_t dword;
- uint32_t dword2;
- uint64_t qword;
- uint8_t num_nodes;
-
- /* Find highest DRAM range (DramLimitAddr) */
- num_nodes = 0;
- max_node = 0;
- interleaved = 0;
- max_range_limit = 0;
- struct device *node_dev;
- for (node = 0; node < FX_DEVS; node++) {
- node_dev = get_node_pci(node, 0);
- /* Test for node presence */
- if ((!node_dev) || (pci_read_config32(node_dev, PCI_VENDOR_ID) == 0xffffffff))
- continue;
-
- num_nodes++;
- for (range = 0; range < 8; range++) {
- dword = pci_read_config32(get_node_pci(node, 1), 0x40 + (range * 0x8));
- if (!(dword & 0x3))
- continue;
-
- if ((dword >> 8) & 0x7)
- interleaved = 1;
-
- dword = pci_read_config32(get_node_pci(node, 1), 0x44 + (range * 0x8));
- dword2 = pci_read_config32(get_node_pci(node, 1), 0x144 + (range * 0x8));
- qword = 0xffffff;
- qword |= ((((uint64_t)dword) >> 16) & 0xffff) << 24;
- qword |= (((uint64_t)dword2) & 0xff) << 40;
-
- if (qword > max_range_limit) {
- max_range_limit = qword;
- max_node = dword & 0x7;
- }
- }
- }
-
- /* Calculate CC6 storage area size */
- if (interleaved)
- qword = (uint64_t)0x1000000 * num_nodes;
- else
- qword = 0x1000000;
-
- /* FIXME
- * The BKDG appears to be incorrect as to the location of the CC6 save region
- * lower boundary on non-interleaved systems, causing lockups on attempted write
- * to the CC6 save region.
- *
- * For now, work around by allocating the maximum possible CC6 save region size.
- *
- * Determine if this is a BKDG error or a setup problem and remove this warning!
- */
- qword = (0x1 << 27);
- max_range_limit = (((uint64_t)(pci_read_config32(get_node_pci(max_node, 1), 0x124) & 0x1fffff)) << 27) - 1;
-
- printk(BIOS_INFO, "Reserving CC6 save segment base: %08llx size: %08llx\n", (max_range_limit + 1), qword);
-
- /* Reserve the CC6 save segment */
- reserved_ram_resource(dev, 8, (max_range_limit + 1) >> 10, qword >> 10);
- }
- }
-}
-
-static u32 my_find_pci_tolm(struct bus *bus, u32 tolm)
-{
- struct resource *min;
- min = 0;
- search_bus_resources(bus, IORESOURCE_MEM, IORESOURCE_MEM, tolm_test, &min);
- if (min && tolm > min->base) {
- tolm = min->base;
- }
- return tolm;
-}
-
-#if CONFIG_HW_MEM_HOLE_SIZEK != 0
-
-struct hw_mem_hole_info {
- unsigned int hole_startk;
- int node_id;
-};
-
-static struct hw_mem_hole_info get_hw_mem_hole_info(void)
-{
- struct hw_mem_hole_info mem_hole;
- int i;
-
- mem_hole.hole_startk = CONFIG_HW_MEM_HOLE_SIZEK;
- mem_hole.node_id = -1;
-
- for (i = 0; i < sysconf.nodes; i++) {
- struct dram_base_mask_t d;
- u32 hole;
- d = get_dram_base_mask(i);
- if (!(d.mask & 1)) continue; // no memory on this node
-
- hole = pci_read_config32(__f1_dev[i], 0xf0);
- if (hole & 1) { // we find the hole
- mem_hole.hole_startk = (hole & (0xff<<24)) >> 10;
- mem_hole.node_id = i; // record the node No with hole
- break; // only one hole
- }
- }
-
- /* We need to double check if there is special set on base reg and limit reg
- * are not continuous instead of hole, it will find out its hole_startk.
- */
- if (mem_hole.node_id==-1) {
- resource_t limitk_pri = 0;
- for (i = 0; i < sysconf.nodes; i++) {
- struct dram_base_mask_t d;
- resource_t base_k, limit_k;
- d = get_dram_base_mask(i);
- if (!(d.base & 1)) continue;
-
- base_k = ((resource_t)(d.base & 0x1fffff00)) <<9;
- if (base_k > 4 *1024 * 1024) break; // don't need to go to check
- if (limitk_pri != base_k) { // we find the hole
- mem_hole.hole_startk = (unsigned int)limitk_pri; // must beblow 4G
- mem_hole.node_id = i;
- break; //only one hole
- }
-
- limit_k = ((resource_t)((d.mask + 0x00000100) & 0x1fffff00)) << 9;
- limitk_pri = limit_k;
- }
- }
- return mem_hole;
-}
-
-#endif
-
-#include <cbmem.h>
-
-static void setup_uma_memory(void)
-{
-#if CONFIG(GFXUMA)
- uint32_t topmem = (uint32_t) bsp_topmem();
- uma_memory_size = get_uma_memory_size(topmem);
- uma_memory_base = topmem - uma_memory_size; /* TOP_MEM1 */
- printk(BIOS_INFO, "%s: uma size 0x%08llx, memory start 0x%08llx\n",
- __func__, uma_memory_size, uma_memory_base);
-#endif
-}
-
-static void amdfam10_domain_set_resources(struct device *dev)
-{
- unsigned long mmio_basek;
- u32 pci_tolm;
- int i, idx;
- struct bus *link;
-#if CONFIG_HW_MEM_HOLE_SIZEK != 0
- struct hw_mem_hole_info mem_hole;
-#endif
-
- pci_tolm = 0xffffffffUL;
- for (link = dev->link_list; link; link = link->next) {
- pci_tolm = my_find_pci_tolm(link, pci_tolm);
- }
-
- // FIXME handle interleaved nodes. If you fix this here, please fix
- // amdk8, too.
- mmio_basek = pci_tolm >> 10;
- /* Round mmio_basek to something the processor can support */
- mmio_basek &= ~((1 << 6) -1);
-
- // FIXME improve mtrr.c so we don't use up all of the mtrrs with a 64M
- // MMIO hole. If you fix this here, please fix amdk8, too.
- /* Round the mmio hole to 64M */
- mmio_basek &= ~((64*1024) - 1);
-
-#if CONFIG_HW_MEM_HOLE_SIZEK != 0
-/* if the hw mem hole is already set in raminit stage, here we will compare
- * mmio_basek and hole_basek. if mmio_basek is bigger that hole_basek and will
- * use hole_basek as mmio_basek and we don't need to reset hole.
- * otherwise We reset the hole to the mmio_basek
- */
-
- mem_hole = get_hw_mem_hole_info();
-
- // Use hole_basek as mmio_basek, and we don't need to reset hole anymore
- if ((mem_hole.node_id != -1) && (mmio_basek > mem_hole.hole_startk)) {
- mmio_basek = mem_hole.hole_startk;
- }
-
-#endif
-
- idx = 0x10;
- for (i = 0; i < sysconf.nodes; i++) {
- struct dram_base_mask_t d;
- resource_t basek, limitk, sizek; // 4 1T
- d = get_dram_base_mask(i);
-
- if (!(d.mask & 1)) continue;
- basek = ((resource_t)(d.base & 0x1fffff00)) << 9; // could overflow, we may lost 6 bit here
- limitk = ((resource_t)((d.mask + 0x00000100) & 0x1fffff00)) << 9;
- sizek = limitk - basek;
-
- /* see if we need a hole from 0xa0000 to 0xbffff */
- if ((basek < ((8*64)+(8*16))) && (sizek > ((8*64)+(16*16)))) {
- ram_resource(dev, (idx | i), basek, ((8*64)+(8*16)) - basek);
- idx += 0x10;
- basek = (8*64)+(16*16);
- sizek = limitk - ((8*64)+(16*16));
-
- }
-
- /* split the region to accommodate pci memory space */
- if ((basek < 4*1024*1024) && (limitk > mmio_basek)) {
- if (basek <= mmio_basek) {
- unsigned int pre_sizek;
- pre_sizek = mmio_basek - basek;
- if (pre_sizek > 0) {
- ram_resource(dev, (idx | i), basek, pre_sizek);
- idx += 0x10;
- sizek -= pre_sizek;
- }
- basek = mmio_basek;
- }
- if ((basek + sizek) <= 4*1024*1024) {
- sizek = 0;
- } else {
- basek = 4*1024*1024;
- sizek -= (4*1024*1024 - mmio_basek);
- }
- }
-
- ram_resource(dev, (idx | i), basek, sizek);
- idx += 0x10;
- printk(BIOS_DEBUG, "%d: mmio_basek=%08lx, basek=%08llx, limitk=%08llx\n",
- i, mmio_basek, basek, limitk);
- }
-
-#if CONFIG(GFXUMA)
- uma_resource(dev, 7, uma_memory_base >> 10, uma_memory_size >> 10);
-#endif
-
- for (link = dev->link_list; link; link = link->next) {
- if (link->children) {
- assign_resources(link);
- }
- }
-}
-
-static void amdfam10_domain_scan_bus(struct device *dev)
-{
- u32 reg;
- int i;
- struct bus *link;
- /* Unmap all of the HT chains */
- for (reg = 0xe0; reg <= 0xec; reg += 4) {
- f1_write_config32(reg, 0);
- }
-
- for (link = dev->link_list; link; link = link->next) {
- link->secondary = dev->bus->subordinate;
- pci_scan_bus(link, PCI_DEVFN(CONFIG_CDB, 0), 0xff);
- dev->bus->subordinate = link->subordinate;
- }
-
- /* Tune the hypertransport transaction for best performance.
- * Including enabling relaxed ordering if it is safe.
- */
- get_fx_devs();
- for (i = 0; i < fx_devs; i++) {
- struct device *f0_dev;
- f0_dev = __f0_dev[i];
- if (f0_dev && f0_dev->enabled) {
- u32 httc;
- httc = pci_read_config32(f0_dev, HT_TRANSACTION_CONTROL);
- httc &= ~HTTC_RSP_PASS_PW;
- if (!dev->link_list->disable_relaxed_ordering) {
- httc |= HTTC_RSP_PASS_PW;
- }
- printk(BIOS_SPEW, "%s passpw: %s\n",
- dev_path(dev),
- (!dev->link_list->disable_relaxed_ordering)?
- "enabled":"disabled");
- pci_write_config32(f0_dev, HT_TRANSACTION_CONTROL, httc);
- }
- }
-}
-
-#if CONFIG(GENERATE_SMBIOS_TABLES)
-static int amdfam10_get_smbios_data16(int *count, int handle,
- unsigned long *current)
-{
- struct amdmct_memory_info *mem_info;
- mem_info = cbmem_find(CBMEM_ID_AMDMCT_MEMINFO);
- if (mem_info == NULL)
- return 0; /* can't find amdmct information in cbmem */
-
- struct device *dev = get_node_pci(0, 0);
- struct northbridge_amd_amdfam10_config *config = dev->chip_info;
-
- int node;
- int slot;
-
- struct smbios_type16 *t = (struct smbios_type16 *)*current;
- int len = sizeof(struct smbios_type16);
-
- memset(t, 0, sizeof(struct smbios_type16));
- t->type = SMBIOS_PHYS_MEMORY_ARRAY;
- t->handle = handle;
- t->length = len - 2;
- t->location = MEMORY_ARRAY_LOCATION_SYSTEM_BOARD;
- t->use = MEMORY_ARRAY_USE_SYSTEM;
- t->memory_error_correction = MEMORY_ARRAY_ECC_NONE;
- if ((mem_info->ecc_enabled)
- && (mem_info->mct_stat.GStatus & (1 << GSB_ECCDIMMs))
- && !(mem_info->mct_stat.GStatus & (1 << GSB_DramECCDis)))
- /* Single-bit ECC enabled */
- t->memory_error_correction = MEMORY_ARRAY_ECC_SINGLE_BIT;
- t->maximum_capacity = config->maximum_memory_capacity / 1024; /* Convert to kilobytes */
- t->memory_error_information_handle = 0xFFFE; /* no error information handle available */
-
- t->number_of_memory_devices = 0;
- /* Check all nodes for installed DIMMs */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++)
- /* Check all slots for installed DIMMs */
- for (slot = 0; slot < MAX_DIMMS_SUPPORTED; slot++)
- if (mem_info->dct_stat[node].DIMMPresent & (1 << slot))
- /* Found an installed DIMM; increment count */
- t->number_of_memory_devices++;
-
- *current += len;
- *count += 1;
- return len;
-}
-
-static uint16_t amdmct_mct_speed_enum_to_mhz(uint8_t speed)
-{
- if (is_fam15h()) {
- if (CONFIG(DIMM_DDR3)) {
- switch (speed) {
- case 0x4:
- return 333;
- case 0x6:
- return 400;
- case 0xa:
- return 533;
- case 0xe:
- return 667;
- case 0x12:
- return 800;
- case 0x16:
- return 933;
- default:
- return 0;
- }
- } else {
- return 0;
- }
- } else {
- if (CONFIG(DIMM_DDR2)) {
- switch (speed) {
- case 1:
- return 200;
- case 2:
- return 266;
- case 3:
- return 333;
- case 4:
- return 400;
- case 5:
- return 533;
- default:
- return 0;
- }
- } else if (CONFIG(DIMM_DDR3)) {
- switch (speed) {
- case 3:
- return 333;
- case 4:
- return 400;
- case 5:
- return 533;
- case 6:
- return 667;
- case 7:
- return 800;
- default:
- return 0;
- }
- } else {
- return 0;
- }
- }
-}
-
-static int amdfam10_get_smbios_data17(int *count, int handle, int parent_handle,
- unsigned long *current)
-{
- struct amdmct_memory_info *mem_info;
- mem_info = cbmem_find(CBMEM_ID_AMDMCT_MEMINFO);
- if (mem_info == NULL)
- return 0; /* can't find amdmct information in cbmem */
-
- int single_len;
- int len = 0;
- int node;
- int slot;
-
- /* Check all nodes for installed DIMMs */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- /* Get configured RAM bus speed */
- uint16_t speed;
- speed = amdmct_mct_speed_enum_to_mhz(mem_info->dct_stat[node].Speed);
-
- /* Get maximum RAM bus speed */
- uint16_t max_speed;
- max_speed = amdmct_mct_speed_enum_to_mhz(mem_info->dct_stat[node].DIMMAutoSpeed);
-
- /* Check all slots for installed DIMMs */
- for (slot = 0; slot < MAX_DIMMS_SUPPORTED; slot++) {
- if (mem_info->dct_stat[node].DIMMPresent & (1 << slot)) {
- /* Found an installed DIMM; populate tables */
- struct smbios_type17 *t = (struct smbios_type17 *)*current;
- char string_buffer[256];
-
- /* Initialize structure */
- memset(t, 0, sizeof(struct smbios_type17));
-
- /* Calculate the total module size in bytes:
- * Primary data width * 2^(#rows) * 2^(#cols) * #banks * #ranks
- */
- uint8_t width, rows, cols, banks, ranks;
- uint64_t chip_size;
- uint32_t chip_width;
- rows = mem_info->dct_stat[node].DimmRows[slot];
- cols = mem_info->dct_stat[node].DimmCols[slot];
- ranks = mem_info->dct_stat[node].DimmRanks[slot];
- banks = mem_info->dct_stat[node].DimmBanks[slot];
-#if CONFIG(DIMM_DDR3)
- chip_size = mem_info->dct_stat[node].DimmChipSize[slot];
- chip_width = mem_info->dct_stat[node].DimmChipWidth[slot];
-#else
- chip_size = 0;
- chip_width = 0;
-#endif
- uint64_t dimm_size_bytes;
- if (CONFIG(DIMM_DDR3)) {
- width = mem_info->dct_stat[node].DimmWidth[slot];
- dimm_size_bytes = ((width / chip_width) * chip_size * ranks) / 8;
- } else {
- width = 8;
- dimm_size_bytes = width * (1ULL << rows) * (1ULL << cols) * banks * ranks;
- }
-
- memset(t, 0, sizeof(struct smbios_type17));
- t->type = SMBIOS_MEMORY_DEVICE;
- t->handle = handle;
- t->phys_memory_array_handle = parent_handle;
- t->length = sizeof(struct smbios_type17) - 2;
- if (dimm_size_bytes > 0x800000000) {
- t->size = 0x7FFF;
- t->extended_size = dimm_size_bytes >> 16;
- } else {
- t->size = dimm_size_bytes / (1024*1024);
- t->size &= (~0x8000); /* size specified in megabytes */
- }
- t->total_width = t->data_width = 64;
- if (mem_info->dct_stat[node].DimmECCPresent & (1 << slot))
- t->total_width += 8;
- t->attributes = 0;
- t->attributes |= ranks & 0xf; /* rank number is stored in the lowest 4 bits of the attributes field */
- t->form_factor = MEMORY_FORMFACTOR_DIMM;
- if (mem_info->dct_stat[node].Dual_Node_Package) {
- snprintf(string_buffer, sizeof(string_buffer), "NODE %d DIMM_%s%d", node >> 1,
- (mem_info->dct_stat[node].Internal_Node_ID)?((slot & 0x1)?"D":"C"):((slot & 0x1)?"B":"A"), (slot >> 1) + 1);
- } else {
- snprintf(string_buffer, sizeof(string_buffer), "NODE %d DIMM_%s%d", node, (slot & 0x1)?"B":"A", (slot >> 1) + 1);
- }
- t->device_locator = smbios_add_string(t->eos, string_buffer);
- if (CONFIG(DIMM_DDR2))
- t->memory_type = MEMORY_TYPE_DDR2;
- else if (CONFIG(DIMM_DDR3))
- t->memory_type = MEMORY_TYPE_DDR3;
- t->type_detail = MEMORY_TYPE_DETAIL_SYNCHRONOUS;
- if (mem_info->dct_stat[node].DimmRegistered[slot])
- t->type_detail |= MEMORY_TYPE_DETAIL_REGISTERED;
- else
- t->type_detail |= MEMORY_TYPE_DETAIL_UNBUFFERED;
- t->speed = max_speed;
- t->clock_speed = speed;
- smbios_fill_dimm_manufacturer_from_id(mem_info->dct_stat[node].DimmManufacturerID[slot], t);
- t->part_number = smbios_add_string(t->eos, mem_info->dct_stat[node].DimmPartNumber[slot]);
- if (mem_info->dct_stat[node].DimmSerialNumber[slot] == 0) {
- t->serial_number = smbios_add_string(t->eos, "None");
- } else {
- snprintf(string_buffer, sizeof(string_buffer), "%08X", mem_info->dct_stat[node].DimmSerialNumber[slot]);
- t->serial_number = smbios_add_string(t->eos, string_buffer);
- }
- if (CONFIG(DIMM_DDR2)) {
- /* JEDEC specifies 1.8V only, so assume that the memory is configured for 1.8V */
- t->minimum_voltage = 1800;
- t->maximum_voltage = 1800;
- t->configured_voltage = 1800;
- } else if (CONFIG(DIMM_DDR3)) {
-#if CONFIG(DIMM_DDR3)
- /* Find the maximum and minimum supported voltages */
- uint8_t supported_voltages = mem_info->dct_stat[node].DimmSupportedVoltages[slot];
- uint8_t configured_voltage = mem_info->dct_stat[node].DimmConfiguredVoltage[slot];
-
- if (supported_voltages & 0x8)
- t->minimum_voltage = 1150;
- else if (supported_voltages & 0x4)
- t->minimum_voltage = 1250;
- else if (supported_voltages & 0x2)
- t->minimum_voltage = 1350;
- else if (supported_voltages & 0x1)
- t->minimum_voltage = 1500;
-
- if (supported_voltages & 0x1)
- t->maximum_voltage = 1500;
- else if (supported_voltages & 0x2)
- t->maximum_voltage = 1350;
- else if (supported_voltages & 0x4)
- t->maximum_voltage = 1250;
- else if (supported_voltages & 0x8)
- t->maximum_voltage = 1150;
-
- if (configured_voltage & 0x8)
- t->configured_voltage = 1150;
- else if (configured_voltage & 0x4)
- t->configured_voltage = 1250;
- else if (configured_voltage & 0x2)
- t->configured_voltage = 1350;
- else if (configured_voltage & 0x1)
- t->configured_voltage = 1500;
-#endif
- }
- t->memory_error_information_handle = 0xFFFE; /* no error information handle available */
- single_len = t->length + smbios_string_table_len(t->eos);
- len += single_len;
- *current += single_len;
- handle++;
- *count += 1;
- }
- }
- }
-
- return len;
-}
-
-static int amdfam10_get_smbios_data(struct device *dev, int *handle, unsigned long *current)
-{
- int len;
- int count = 0;
- len = amdfam10_get_smbios_data16(&count, *handle, current);
- len += amdfam10_get_smbios_data17(&count, *handle + 1, *handle, current);
- *handle += count;
- return len;
-}
-#endif
-
-#if CONFIG(HAVE_ACPI_TABLES)
-static const char *amdfam10_domain_acpi_name(const struct device *dev)
-{
- if (dev->path.type == DEVICE_PATH_DOMAIN)
- return "PCI0";
-
- return NULL;
-}
-#endif
-
-static struct device_operations pci_domain_ops = {
- .read_resources = amdfam10_domain_read_resources,
- .set_resources = amdfam10_domain_set_resources,
- .enable_resources = NULL,
- .init = NULL,
- .scan_bus = amdfam10_domain_scan_bus,
-#if CONFIG(HAVE_ACPI_TABLES)
- .acpi_name = amdfam10_domain_acpi_name,
-#endif
-#if CONFIG(GENERATE_SMBIOS_TABLES)
- .get_smbios_data = amdfam10_get_smbios_data,
-#endif
-};
-
-static void sysconf_init(struct device *dev) // first node
-{
- sysconf.sblk = (pci_read_config32(dev, 0x64)>>8) & 7; // don't forget sublink1
- sysconf.segbit = 0;
- sysconf.ht_c_num = 0;
-
- unsigned int ht_c_index;
-
- for (ht_c_index = 0; ht_c_index < 32; ht_c_index++) {
- sysconf.ht_c_conf_bus[ht_c_index] = 0;
- }
-
- sysconf.nodes = ((pci_read_config32(dev, 0x60)>>4) & 7) + 1;
-#if CONFIG_MAX_PHYSICAL_CPUS > 8
- sysconf.nodes += (((pci_read_config32(dev, 0x160)>>4) & 7)<<3);
-#endif
-
- sysconf.enabled_apic_ext_id = 0;
- sysconf.lift_bsp_apicid = 0;
-
- /* Find the bootstrap processors apicid */
- sysconf.bsp_apicid = lapicid();
- sysconf.apicid_offset = sysconf.bsp_apicid;
-
-#if CONFIG(ENABLE_APIC_EXT_ID)
- if (pci_read_config32(dev, 0x68) & (HTTC_APIC_EXT_ID|HTTC_APIC_EXT_BRD_CST))
- {
- sysconf.enabled_apic_ext_id = 1;
- }
- #if (CONFIG_APIC_ID_OFFSET > 0)
- if (sysconf.enabled_apic_ext_id) {
- if (sysconf.bsp_apicid == 0) {
- /* bsp apic id is not changed */
- sysconf.apicid_offset = CONFIG_APIC_ID_OFFSET;
- } else {
- sysconf.lift_bsp_apicid = 1;
- }
- }
- #endif
-#endif
-}
-
-static void remap_bsp_lapic(struct bus *cpu_bus)
-{
- struct device_path cpu_path;
- struct device *cpu;
- u32 bsp_lapic_id = lapicid();
-
- if (bsp_lapic_id) {
- cpu_path.type = DEVICE_PATH_APIC;
- cpu_path.apic.apic_id = 0;
- cpu = find_dev_path(cpu_bus, &cpu_path);
- if (cpu)
- cpu->path.apic.apic_id = bsp_lapic_id;
- }
-}
-
-static void cpu_bus_scan(struct device *dev)
-{
- struct bus *cpu_bus;
- struct device *dev_mc;
-#if CONFIG_CBB
- struct device *pci_domain;
-#endif
- int nvram = 0;
- int i,j;
- int nodes;
- unsigned int nb_cfg_54;
- unsigned int siblings;
- int cores_found;
- int disable_siblings;
- uint8_t disable_cu_siblings = 0;
- unsigned int ApicIdCoreIdSize;
-
- nb_cfg_54 = 0;
- ApicIdCoreIdSize = (cpuid_ecx(0x80000008)>>12 & 0xf);
- if (ApicIdCoreIdSize) {
- siblings = (1<<ApicIdCoreIdSize)-1;
- } else {
- siblings = 3; //quad core
- }
-
- disable_siblings = !CONFIG(LOGICAL_CPUS);
-#if CONFIG(LOGICAL_CPUS)
- get_option(&disable_siblings, "multi_core");
-#endif
-
- // How can I get the nb_cfg_54 of every node's nb_cfg_54 in bsp???
- nb_cfg_54 = read_nb_cfg_54();
-
-#if CONFIG_CBB
- dev_mc = pcidev_on_root(CONFIG_CDB, 0); //0x00
- if (dev_mc && dev_mc->bus) {
- printk(BIOS_DEBUG, "%s found", dev_path(dev_mc));
- pci_domain = dev_mc->bus->dev;
- if (pci_domain && (pci_domain->path.type == DEVICE_PATH_DOMAIN)) {
- printk(BIOS_DEBUG, "\n%s move to ",dev_path(dev_mc));
- dev_mc->bus->secondary = CONFIG_CBB; // move to 0xff
- printk(BIOS_DEBUG, "%s",dev_path(dev_mc));
-
- } else {
- printk(BIOS_DEBUG, " but it is not under pci_domain directly ");
- }
- printk(BIOS_DEBUG, "\n");
- }
- dev_mc = dev_find_slot(CONFIG_CBB, PCI_DEVFN(CONFIG_CDB, 0));
- if (!dev_mc) {
- dev_mc = pcidev_on_root(0x18, 0);
- if (dev_mc && dev_mc->bus) {
- printk(BIOS_DEBUG, "%s found\n", dev_path(dev_mc));
- pci_domain = dev_mc->bus->dev;
- if (pci_domain && (pci_domain->path.type == DEVICE_PATH_DOMAIN)) {
- if ((pci_domain->link_list) && (pci_domain->link_list->children == dev_mc)) {
- printk(BIOS_DEBUG, "%s move to ",dev_path(dev_mc));
- dev_mc->bus->secondary = CONFIG_CBB; // move to 0xff
- printk(BIOS_DEBUG, "%s\n",dev_path(dev_mc));
- while (dev_mc) {
- printk(BIOS_DEBUG, "%s move to ",dev_path(dev_mc));
- dev_mc->path.pci.devfn -= PCI_DEVFN(0x18,0);
- printk(BIOS_DEBUG, "%s\n",dev_path(dev_mc));
- dev_mc = dev_mc->sibling;
- }
- }
- }
- }
- }
-
-#endif
-
- dev_mc = dev_find_slot(CONFIG_CBB, PCI_DEVFN(CONFIG_CDB, 0));
- if (!dev_mc) {
- printk(BIOS_ERR, "%02x:%02x.0 not found", CONFIG_CBB, CONFIG_CDB);
- die("");
- }
-
- sysconf_init(dev_mc);
-
- nodes = sysconf.nodes;
-
-#if CONFIG_CBB && (NODE_NUMS > 32)
- if (nodes > 32) { // need to put node 32 to node 63 to bus 0xfe
- if (pci_domain->link_list && !pci_domain->link_list->next) {
- struct bus *new_link = new_link(pci_domain);
- pci_domain->link_list->next = new_link;
- new_link->link_num = 1;
- new_link->dev = pci_domain;
- new_link->children = 0;
- printk(BIOS_DEBUG, "%s links now 2\n", dev_path(pci_domain));
- }
- pci_domain->link_list->next->secondary = CONFIG_CBB - 1;
- }
-#endif
- /* Find which cpus are present */
- cpu_bus = dev->link_list;
-
- /* Always use the devicetree node with lapic_id 0 for BSP. */
- remap_bsp_lapic(cpu_bus);
-
- if (get_option(&nvram, "compute_unit_siblings") == CB_SUCCESS)
- disable_cu_siblings = !!nvram;
-
- if (disable_cu_siblings)
- printk(BIOS_DEBUG, "Disabling siblings on each compute unit as requested\n");
-
- for (i = 0; i < nodes; i++) {
- struct device *cdb_dev;
- unsigned int busn, devn;
- struct bus *pbus;
-
- uint8_t fam15h = 0;
- uint8_t rev_gte_d = 0;
- uint8_t dual_node = 0;
- uint32_t f3xe8;
- uint32_t model;
-
- busn = CONFIG_CBB;
- devn = CONFIG_CDB+i;
- pbus = dev_mc->bus;
-#if CONFIG_CBB && (NODE_NUMS > 32)
- if (i >= 32) {
- busn--;
- devn-=32;
- pbus = pci_domain->link_list->next;
- }
-#endif
-
- /* Find the cpu's pci device */
- cdb_dev = dev_find_slot(busn, PCI_DEVFN(devn, 0));
- if (!cdb_dev) {
- /* If I am probing things in a weird order
- * ensure all of the cpu's pci devices are found.
- */
- int fn;
- for (fn = 0; fn <= 5; fn++) { //FBDIMM?
- cdb_dev = pci_probe_dev(NULL, pbus,
- PCI_DEVFN(devn, fn));
- }
- }
-
-
- /* Ok, We need to set the links for that device.
- * otherwise the device under it will not be scanned
- */
- cdb_dev = dev_find_slot(busn, PCI_DEVFN(devn, 0));
- if (cdb_dev)
- add_more_links(cdb_dev, 4);
-
- cdb_dev = dev_find_slot(busn, PCI_DEVFN(devn, 4));
- if (cdb_dev)
- add_more_links(cdb_dev, 4);
-
- f3xe8 = pci_read_config32(get_node_pci(0, 3), 0xe8);
-
- model = cpuid_eax(0x80000001);
- model = ((model & 0xf0000) >> 12) | ((model & 0xf0) >> 4);
-
- if (is_fam15h()) {
- /* Family 15h or later */
- fam15h = 1;
- nb_cfg_54 = 1;
- }
-
- if ((model >= 0x8) || fam15h)
- /* Revision D or later */
- rev_gte_d = 1;
-
- if (rev_gte_d)
- /* Check for dual node capability */
- if (f3xe8 & 0x20000000)
- dual_node = 1;
-
- cores_found = 0; // one core
- if (fam15h)
- cdb_dev = dev_find_slot(busn, PCI_DEVFN(devn, 5));
- else
- cdb_dev = dev_find_slot(busn, PCI_DEVFN(devn, 3));
- int enable_node = cdb_dev && cdb_dev->enabled;
- if (enable_node) {
- if (fam15h) {
- cores_found = pci_read_config32(cdb_dev, 0x84) & 0xff;
- } else {
- j = pci_read_config32(cdb_dev, 0xe8);
- cores_found = (j >> 12) & 3; // dev is func 3
- if (siblings > 3)
- cores_found |= (j >> 13) & 4;
- }
- printk(BIOS_DEBUG, " %s siblings=%d\n", dev_path(cdb_dev), cores_found);
- }
-
- if (siblings > cores_found)
- siblings = cores_found;
-
- u32 jj;
- if (disable_siblings) {
- jj = 0;
- } else
- {
- jj = cores_found;
- }
-
- for (j = 0; j <=jj; j++) {
- u32 apic_id;
-
- if (dual_node) {
- apic_id = 0;
- if (fam15h) {
- apic_id |= ((i >> 1) & 0x3) << 5; /* Node ID */
- apic_id |= ((i & 0x1) * (siblings + 1)) + j; /* Core ID */
- } else {
- if (nb_cfg_54) {
- apic_id |= ((i >> 1) & 0x3) << 4; /* Node ID */
- apic_id |= ((i & 0x1) * (siblings + 1)) + j; /* Core ID */
- } else {
- apic_id |= i & 0x3; /* Node ID */
- apic_id |= (((i & 0x1) * (siblings + 1)) + j) << 4; /* Core ID */
- }
- }
- } else {
- if (fam15h) {
- apic_id = 0;
- apic_id |= (i & 0x7) << 4; /* Node ID */
- apic_id |= j & 0xf; /* Core ID */
- } else {
- apic_id = i * (nb_cfg_54?(siblings+1):1) + j * (nb_cfg_54?1:64); // ?
- }
- }
-
-#if CONFIG(ENABLE_APIC_EXT_ID) && (CONFIG_APIC_ID_OFFSET > 0)
- if (sysconf.enabled_apic_ext_id) {
- if (apic_id != 0 || sysconf.lift_bsp_apicid) {
- apic_id += sysconf.apicid_offset;
- }
- }
-#endif
- if (disable_cu_siblings && (j & 0x1))
- continue;
-
- struct device *cpu = add_cpu_device(cpu_bus, apic_id, enable_node);
- if (cpu)
- amd_cpu_topology(cpu, i, j);
- }
- }
-}
-
-static void detect_and_enable_probe_filter(struct device *dev)
-{
- uint32_t dword;
-
- uint8_t nvram;
- uint8_t enable_probe_filter;
-
- /* Check to see if the probe filter is allowed */
- enable_probe_filter = 1;
- if (get_option(&nvram, "probe_filter") == CB_SUCCESS)
- enable_probe_filter = !!nvram;
-
- if (!enable_probe_filter)
- return;
-
- uint8_t fam15h = 0;
- uint8_t rev_gte_d = 0;
- uint32_t model;
-
- model = cpuid_eax(0x80000001);
- model = ((model & 0xf0000) >> 12) | ((model & 0xf0) >> 4);
-
- if (is_fam15h()) {
- /* Family 15h or later */
- fam15h = 1;
- }
-
- if ((model >= 0x8) || fam15h)
- /* Revision D or later */
- rev_gte_d = 1;
-
- if (rev_gte_d && (sysconf.nodes > 1)) {
- /* Enable the probe filter */
- uint8_t i;
- uint8_t pfmode = 0x0;
-
- uint32_t f3x58[MAX_NODES_SUPPORTED];
- uint32_t f3x5c[MAX_NODES_SUPPORTED];
-
- printk(BIOS_DEBUG, "Enabling probe filter\n");
-
- /* Disable L3 and DRAM scrubbers and configure system for probe filter support */
- for (i = 0; i < sysconf.nodes; i++) {
- struct device *f2x_dev = pcidev_on_root(0x18 + i, 2);
- struct device *f3x_dev = pcidev_on_root(0x18 + i, 3);
-
- f3x58[i] = pci_read_config32(f3x_dev, 0x58);
- f3x5c[i] = pci_read_config32(f3x_dev, 0x5c);
- pci_write_config32(f3x_dev, 0x58, f3x58[i] & ~((0x1f << 24) | 0x1f));
- pci_write_config32(f3x_dev, 0x5c, f3x5c[i] & ~0x1);
-
- dword = pci_read_config32(f2x_dev, 0x1b0);
- dword &= ~(0x7 << 8); /* CohPrefPrbLmt = 0x0 */
- pci_write_config32(f2x_dev, 0x1b0, dword);
-
- msr_t msr = rdmsr_amd(BU_CFG2_MSR);
- msr.hi |= 1 << (42 - 32);
- wrmsr_amd(BU_CFG2_MSR, msr);
-
- if (is_fam15h()) {
- uint8_t subcache_size = 0x0;
- uint8_t pref_so_repl = 0x0;
- uint32_t f3x1c4 = pci_read_config32(f3x_dev, 0x1c4);
- if ((f3x1c4 & 0xffff) == 0xcccc) {
- subcache_size = 0x1;
- pref_so_repl = 0x2;
- pfmode = 0x3;
- } else {
- pfmode = 0x2;
- }
-
- dword = pci_read_config32(f3x_dev, 0x1d4);
- dword |= 0x1 << 29; /* PFLoIndexHashEn = 0x1 */
- dword &= ~(0x3 << 20); /* PFPreferredSORepl = pref_so_repl */
- dword |= (pref_so_repl & 0x3) << 20;
- dword |= 0x1 << 17; /* PFWayHashEn = 0x1 */
- dword |= 0xf << 12; /* PFSubCacheEn = 0xf */
- dword &= ~(0x3 << 10); /* PFSubCacheSize3 = subcache_size */
- dword |= (subcache_size & 0x3) << 10;
- dword &= ~(0x3 << 8); /* PFSubCacheSize2 = subcache_size */
- dword |= (subcache_size & 0x3) << 8;
- dword &= ~(0x3 << 6); /* PFSubCacheSize1 = subcache_size */
- dword |= (subcache_size & 0x3) << 6;
- dword &= ~(0x3 << 4); /* PFSubCacheSize0 = subcache_size */
- dword |= (subcache_size & 0x3) << 4;
- dword &= ~(0x3 << 2); /* PFWayNum = 0x2 */
- dword |= 0x2 << 2;
- pci_write_config32(f3x_dev, 0x1d4, dword);
- } else {
- pfmode = 0x2;
-
- dword = pci_read_config32(f3x_dev, 0x1d4);
- dword |= 0x1 << 29; /* PFLoIndexHashEn = 0x1 */
- dword &= ~(0x3 << 20); /* PFPreferredSORepl = 0x2 */
- dword |= 0x2 << 20;
- dword |= 0xf << 12; /* PFSubCacheEn = 0xf */
- dword &= ~(0x3 << 10); /* PFSubCacheSize3 = 0x0 */
- dword &= ~(0x3 << 8); /* PFSubCacheSize2 = 0x0 */
- dword &= ~(0x3 << 6); /* PFSubCacheSize1 = 0x0 */
- dword &= ~(0x3 << 4); /* PFSubCacheSize0 = 0x0 */
- dword &= ~(0x3 << 2); /* PFWayNum = 0x2 */
- dword |= 0x2 << 2;
- pci_write_config32(f3x_dev, 0x1d4, dword);
- }
- }
-
- udelay(40);
-
- disable_cache();
- wbinvd();
-
- /* Enable probe filter */
- for (i = 0; i < sysconf.nodes; i++) {
- struct device *f3x_dev = pcidev_on_root(0x18 + i, 3);
-
- dword = pci_read_config32(f3x_dev, 0x1c4);
- dword |= (0x1 << 31); /* L3TagInit = 1 */
- pci_write_config32(f3x_dev, 0x1c4, dword);
- do {
- } while (pci_read_config32(f3x_dev, 0x1c4) & (0x1 << 31));
-
- dword = pci_read_config32(f3x_dev, 0x1d4);
- dword &= ~0x3; /* PFMode = pfmode */
- dword |= pfmode & 0x3;
- pci_write_config32(f3x_dev, 0x1d4, dword);
- do {
- } while (!(pci_read_config32(f3x_dev, 0x1d4) & (0x1 << 19)));
- }
-
- if (is_fam15h()) {
- printk(BIOS_DEBUG, "Enabling ATM mode\n");
-
- /* Enable ATM mode */
- for (i = 0; i < sysconf.nodes; i++) {
- struct device *f0x_dev =
- pcidev_on_root(0x18 + i, 0);
- struct device *f3x_dev =
- pcidev_on_root(0x18 + i, 3);
-
- dword = pci_read_config32(f0x_dev, 0x68);
- dword |= (0x1 << 12); /* ATMModeEn = 1 */
- pci_write_config32(f0x_dev, 0x68, dword);
-
- dword = pci_read_config32(f3x_dev, 0x1b8);
- dword |= (0x1 << 27); /* L3ATMModeEn = 1 */
- pci_write_config32(f3x_dev, 0x1b8, dword);
- }
- }
-
- enable_cache();
-
- /* Reenable L3 and DRAM scrubbers */
- for (i = 0; i < sysconf.nodes; i++) {
- struct device *f3x_dev = pcidev_on_root(0x18 + i, 3);
-
- pci_write_config32(f3x_dev, 0x58, f3x58[i]);
- pci_write_config32(f3x_dev, 0x5c, f3x5c[i]);
- }
-
- }
-}
-
-static void detect_and_enable_cache_partitioning(struct device *dev)
-{
- uint8_t i;
- uint32_t dword;
-
- uint8_t nvram;
- uint8_t enable_l3_cache_partitioning;
-
- /* Check to see if cache partitioning is allowed */
- enable_l3_cache_partitioning = 0;
- if (get_option(&nvram, "l3_cache_partitioning") == CB_SUCCESS)
- enable_l3_cache_partitioning = !!nvram;
-
- if (!enable_l3_cache_partitioning)
- return;
-
- if (is_fam15h()) {
- printk(BIOS_DEBUG, "Enabling L3 cache partitioning\n");
-
- uint32_t f5x80;
- uint8_t cu_enabled;
- uint8_t compute_unit_count = 0;
-
- for (i = 0; i < sysconf.nodes; i++) {
- struct device *f3x_dev = pcidev_on_root(0x18 + i, 3);
- struct device *f4x_dev = pcidev_on_root(0x18 + i, 4);
- struct device *f5x_dev = pcidev_on_root(0x18 + i, 5);
-
- /* Determine the number of active compute units on this node */
- f5x80 = pci_read_config32(f5x_dev, 0x80);
- cu_enabled = f5x80 & 0xf;
- if (cu_enabled == 0x1)
- compute_unit_count = 1;
- if (cu_enabled == 0x3)
- compute_unit_count = 2;
- if (cu_enabled == 0x7)
- compute_unit_count = 3;
- if (cu_enabled == 0xf)
- compute_unit_count = 4;
-
- /* Disable BAN mode */
- dword = pci_read_config32(f3x_dev, 0x1b8);
- dword &= ~(0x7 << 19); /* L3BanMode = 0x0 */
- pci_write_config32(f3x_dev, 0x1b8, dword);
-
- /* Set up cache mapping */
- dword = pci_read_config32(f4x_dev, 0x1d4);
- if (compute_unit_count == 1) {
- dword |= 0xf; /* ComputeUnit0SubCacheEn = 0xf */
- }
- if (compute_unit_count == 2) {
- dword &= ~(0xf << 4); /* ComputeUnit1SubCacheEn = 0xc */
- dword |= (0xc << 4);
- dword &= ~0xf; /* ComputeUnit0SubCacheEn = 0x3 */
- dword |= 0x3;
- }
- if (compute_unit_count == 3) {
- dword &= ~(0xf << 8); /* ComputeUnit2SubCacheEn = 0x8 */
- dword |= (0x8 << 8);
- dword &= ~(0xf << 4); /* ComputeUnit1SubCacheEn = 0x4 */
- dword |= (0x4 << 4);
- dword &= ~0xf; /* ComputeUnit0SubCacheEn = 0x3 */
- dword |= 0x3;
- }
- if (compute_unit_count == 4) {
- dword &= ~(0xf << 12); /* ComputeUnit3SubCacheEn = 0x8 */
- dword |= (0x8 << 12);
- dword &= ~(0xf << 8); /* ComputeUnit2SubCacheEn = 0x4 */
- dword |= (0x4 << 8);
- dword &= ~(0xf << 4); /* ComputeUnit1SubCacheEn = 0x2 */
- dword |= (0x2 << 4);
- dword &= ~0xf; /* ComputeUnit0SubCacheEn = 0x1 */
- dword |= 0x1;
- }
- pci_write_config32(f4x_dev, 0x1d4, dword);
-
- /* Enable cache partitioning */
- pci_write_config32(f4x_dev, 0x1d4, dword);
- if (compute_unit_count == 1) {
- dword &= ~(0xf << 26); /* MaskUpdateForComputeUnit = 0x1 */
- dword |= (0x1 << 26);
- } else if (compute_unit_count == 2) {
- dword &= ~(0xf << 26); /* MaskUpdateForComputeUnit = 0x3 */
- dword |= (0x3 << 26);
- } else if (compute_unit_count == 3) {
- dword &= ~(0xf << 26); /* MaskUpdateForComputeUnit = 0x7 */
- dword |= (0x7 << 26);
- } else if (compute_unit_count == 4) {
- dword |= (0xf << 26); /* MaskUpdateForComputeUnit = 0xf */
- }
- pci_write_config32(f4x_dev, 0x1d4, dword);
- }
- }
-}
-
-static void cpu_bus_init(struct device *dev)
-{
- detect_and_enable_probe_filter(dev);
- detect_and_enable_cache_partitioning(dev);
- initialize_cpus(dev->link_list);
-}
-
-static struct device_operations cpu_bus_ops = {
- .read_resources = DEVICE_NOOP,
- .set_resources = DEVICE_NOOP,
- .enable_resources = DEVICE_NOOP,
- .init = cpu_bus_init,
- .scan_bus = cpu_bus_scan,
-};
-
-static void root_complex_enable_dev(struct device *dev)
-{
- static int done = 0;
-
- /* Do not delay UMA setup, as a device on the PCI bus may evaluate
- the global uma_memory variables already in its enable function. */
- if (!done) {
- setup_bsp_ramtop();
- setup_uma_memory();
- done = 1;
- }
-
- /* Set the operations if it is a special bus type */
- if (dev->path.type == DEVICE_PATH_DOMAIN) {
- dev->ops = &pci_domain_ops;
- } else if (dev->path.type == DEVICE_PATH_CPU_CLUSTER) {
- dev->ops = &cpu_bus_ops;
- }
-}
-
-static void root_complex_finalize(void *chip_info) {
-#if CONFIG(HAVE_ACPI_RESUME) && CONFIG(DIMM_DDR3)
- save_mct_information_to_nvram();
-#endif
-}
-
-struct chip_operations northbridge_amd_amdfam10_root_complex_ops = {
- CHIP_NAME("AMD Family 10h/15h Root Complex")
- .enable_dev = root_complex_enable_dev,
- .final = root_complex_finalize,
-};
diff --git a/src/northbridge/amd/amdfam10/northbridge.h b/src/northbridge/amd/amdfam10/northbridge.h
deleted file mode 100644
index fdfd4c8c2c..0000000000
--- a/src/northbridge/amd/amdfam10/northbridge.h
+++ /dev/null
@@ -1,21 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef NORTHBRIDGE_AMD_AMDFAM10_H
-#define NORTHBRIDGE_AMD_AMDFAM10_H
-
-u32 amdfam10_scan_root_bus(struct device *root, u32 max);
-
-#endif /* NORTHBRIDGE_AMD_AMDFAM10_H */
diff --git a/src/northbridge/amd/amdfam10/nums.h b/src/northbridge/amd/amdfam10/nums.h
deleted file mode 100644
index 771ef12b95..0000000000
--- a/src/northbridge/amd/amdfam10/nums.h
+++ /dev/null
@@ -1,36 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef AMDFAM10_NUMS_H
-
-#define AMDFAM10_NUMS_H
-
-#if CONFIG_MAX_PHYSICAL_CPUS > 8
- #if CONFIG_MAX_PHYSICAL_CPUS > 32
- #define NODE_NUMS 64
- #else
- #define NODE_NUMS 32
- #endif
-#else
- #define NODE_NUMS 8
-#endif
-
-// max HC installed at the same time. ...could be bigger than (48+24) if we have 3x4x4
-#define HC_NUMS 32
-
-//it could be more bigger
-#define HC_POSSIBLE_NUM 32
-
-#endif
diff --git a/src/northbridge/amd/amdfam10/pci.c b/src/northbridge/amd/amdfam10/pci.c
deleted file mode 100644
index 410923a01e..0000000000
--- a/src/northbridge/amd/amdfam10/pci.c
+++ /dev/null
@@ -1,72 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <device/pci_ops.h>
-#include "pci.h"
-
-/* bit [10,8] are dev func, bit[1,0] are dev index */
-
-u32 pci_read_config32_index(pci_devfn_t dev, u32 index_reg, u32 index)
-{
- u32 dword;
-
- pci_write_config32(dev, index_reg, index);
- dword = pci_read_config32(dev, index_reg+0x4);
- return dword;
-}
-
-#ifdef UNUSED_CODE
-void pci_write_config32_index(pci_devfn_t dev, u32 index_reg, u32 index,
- u32 data)
-{
-
- pci_write_config32(dev, index_reg, index);
-
- pci_write_config32(dev, index_reg + 0x4, data);
-
-}
-#endif
-
-u32 pci_read_config32_index_wait(pci_devfn_t dev, u32 index_reg,
- u32 index)
-{
-
- u32 dword;
-
- index &= ~(1<<30);
- pci_write_config32(dev, index_reg, index);
- do {
- dword = pci_read_config32(dev, index_reg);
- } while (!(dword & (1<<31)));
- dword = pci_read_config32(dev, index_reg+0x4);
- return dword;
-}
-
-#ifdef UNUSED_CODE
-void pci_write_config32_index_wait(pci_devfn_t dev, u32 index_reg,
- u32 index, u32 data)
-{
-
- u32 dword;
-
- pci_write_config32(dev, index_reg + 0x4, data);
- index |= (1<<30);
- pci_write_config32(dev, index_reg, index);
- do {
- dword = pci_read_config32(dev, index_reg);
- } while (!(dword & (1<<31)));
-
-}
-#endif
diff --git a/src/northbridge/amd/amdfam10/pci.h b/src/northbridge/amd/amdfam10/pci.h
deleted file mode 100644
index 21623c1168..0000000000
--- a/src/northbridge/amd/amdfam10/pci.h
+++ /dev/null
@@ -1,26 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef AMDFAM10_PCI_H
-#define AMDFAM10_PCI_H
-
-#include <stdint.h>
-#include <device/pci_type.h>
-#include <device/pci_def.h>
-
-u32 pci_read_config32_index(pci_devfn_t dev, u32 index_reg, u32 index);
-u32 pci_read_config32_index_wait(pci_devfn_t dev, u32 index_reg, u32 index);
-
-#endif
diff --git a/src/northbridge/amd/amdfam10/raminit.h b/src/northbridge/amd/amdfam10/raminit.h
deleted file mode 100644
index c9c57ff2c2..0000000000
--- a/src/northbridge/amd/amdfam10/raminit.h
+++ /dev/null
@@ -1,47 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef AMDFAM10_RAMINIT_H
-#define AMDFAM10_RAMINIT_H
-
-#include <device/pci.h>
-#include <northbridge/amd/amdmct/amddefs.h>
-#include <northbridge/amd/amdmct/wrappers/mcti.h>
-
-struct sys_info;
-struct DCTStatStruc;
-struct MCTStatStruc;
-
-void activate_spd_rom(const struct mem_controller *ctrl);
-
-int mctRead_SPD(u32 smaddr, u32 reg);
-void mctSMBhub_Init(u32 node);
-void mctGet_DIMMAddr(struct DCTStatStruc *pDCTstat, u32 node);
-void set_sysinfo_in_ram(u32 val);
-struct sys_info *get_sysinfo(void);
-void raminit_amdmct(struct sys_info *sysinfo);
-void amdmct_cbmem_store_info(struct sys_info *sysinfo);
-void fill_mem_ctrl(u32 controllers, struct mem_controller *ctrl_a, const u8 *spd_addr);
-uint16_t mct_MaxLoadFreq(uint8_t count, uint8_t highest_rank_count, uint8_t registered, uint8_t voltage, uint16_t freq);
-u8 mctGetProcessorPackageType(void);
-void Set_NB32_DCT(uint32_t dev, uint8_t dct, uint32_t reg, uint32_t val);
-uint32_t Get_NB32_DCT(uint32_t dev, uint8_t dct, uint32_t reg);
-uint32_t Get_NB32_index_wait_DCT(uint32_t dev, uint8_t dct, uint32_t index_reg, uint32_t index);
-void Set_NB32_index_wait_DCT(uint32_t dev, uint8_t dct, uint32_t index_reg, uint32_t index, uint32_t data);
-void fam15h_switch_dct(uint32_t dev, uint8_t dct);
-uint32_t Get_NB32_DCT_NBPstate(uint32_t dev, uint8_t dct, uint8_t nb_pstate, uint32_t reg);
-void Set_NB32_DCT_NBPstate(uint32_t dev, uint8_t dct, uint8_t nb_pstate, uint32_t reg, uint32_t val);
-
-#endif
diff --git a/src/northbridge/amd/amdfam10/raminit_amdmct.c b/src/northbridge/amd/amdfam10/raminit_amdmct.c
deleted file mode 100644
index a25a1510c8..0000000000
--- a/src/northbridge/amd/amdfam10/raminit_amdmct.c
+++ /dev/null
@@ -1,620 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include <arch/acpi.h>
-#include <arch/cpu.h>
-#include <device/pci.h>
-#include <string.h>
-#include <cbmem.h>
-#include <console/console.h>
-#include <northbridge/amd/amdfam10/debug.h>
-#include <northbridge/amd/amdfam10/raminit.h>
-#include <northbridge/amd/amdfam10/amdfam10.h>
-#include <timestamp.h>
-
-/* Global allocation of sysinfo_car */
-#include <arch/early_variables.h>
-static struct sys_info sysinfo_car CAR_GLOBAL;
-
-struct sys_info *get_sysinfo(void)
-{
- return car_get_var_ptr(&sysinfo_car);
-}
-
-struct mem_controller;
-extern int spd_read_byte(unsigned int device, unsigned int address);
-
-void __weak activate_spd_rom(const struct mem_controller *ctrl)
-{
-}
-
-void fam15h_switch_dct(uint32_t dev, uint8_t dct)
-{
- uint32_t dword;
-
- dword = Get_NB32(dev, 0x10c);
- dword &= ~0x1;
- dword |= (dct & 0x1);
- Set_NB32(dev, 0x10c, dword);
-}
-
-static inline void fam15h_switch_nb_pstate_config_reg(uint32_t dev, uint8_t nb_pstate)
-{
- uint32_t dword;
-
- dword = Get_NB32(dev, 0x10c);
- dword &= ~(0x3 << 4);
- dword |= (nb_pstate & 0x3) << 4;
- Set_NB32(dev, 0x10c, dword);
-}
-
-uint32_t Get_NB32_DCT(uint32_t dev, uint8_t dct, uint32_t reg)
-{
- if (is_fam15h()) {
- /* Obtain address of function 0x1 */
- uint32_t dev_map = (dev & (~(0x7 << 12))) | (0x1 << 12);
- fam15h_switch_dct(dev_map, dct);
- return Get_NB32(dev, reg);
- } else {
- return Get_NB32(dev, (0x100 * dct) + reg);
- }
-}
-
-void Set_NB32_DCT(uint32_t dev, uint8_t dct, uint32_t reg, uint32_t val)
-{
- if (is_fam15h()) {
- /* Obtain address of function 0x1 */
- uint32_t dev_map = (dev & (~(0x7 << 12))) | (0x1 << 12);
- fam15h_switch_dct(dev_map, dct);
- Set_NB32(dev, reg, val);
- } else {
- Set_NB32(dev, (0x100 * dct) + reg, val);
- }
-}
-
-uint32_t Get_NB32_DCT_NBPstate(uint32_t dev, uint8_t dct, uint8_t nb_pstate, uint32_t reg)
-{
- if (is_fam15h()) {
- /* Obtain address of function 0x1 */
- uint32_t dev_map = (dev & (~(0x7 << 12))) | (0x1 << 12);
- fam15h_switch_dct(dev_map, dct);
- fam15h_switch_nb_pstate_config_reg(dev_map, nb_pstate);
- return Get_NB32(dev, reg);
- } else {
- return Get_NB32(dev, (0x100 * dct) + reg);
- }
-}
-
-void Set_NB32_DCT_NBPstate(uint32_t dev, uint8_t dct, uint8_t nb_pstate, uint32_t reg, uint32_t val)
-{
- if (is_fam15h()) {
- /* Obtain address of function 0x1 */
- uint32_t dev_map = (dev & (~(0x7 << 12))) | (0x1 << 12);
- fam15h_switch_dct(dev_map, dct);
- fam15h_switch_nb_pstate_config_reg(dev_map, nb_pstate);
- Set_NB32(dev, reg, val);
- } else {
- Set_NB32(dev, (0x100 * dct) + reg, val);
- }
-}
-
-uint32_t Get_NB32_index_wait_DCT(uint32_t dev, uint8_t dct, uint32_t index_reg, uint32_t index)
-{
- if (is_fam15h()) {
- /* Obtain address of function 0x1 */
- uint32_t dev_map = (dev & (~(0x7 << 12))) | (0x1 << 12);
- fam15h_switch_dct(dev_map, dct);
- return Get_NB32_index_wait(dev, index_reg, index);
- } else {
- return Get_NB32_index_wait(dev, (0x100 * dct) + index_reg, index);
- }
-}
-
-void Set_NB32_index_wait_DCT(uint32_t dev, uint8_t dct, uint32_t index_reg, uint32_t index, uint32_t data)
-{
- if (is_fam15h()) {
- /* Obtain address of function 0x1 */
- uint32_t dev_map = (dev & (~(0x7 << 12))) | (0x1 << 12);
- fam15h_switch_dct(dev_map, dct);
- Set_NB32_index_wait(dev, index_reg, index, data);
- } else {
- Set_NB32_index_wait(dev, (0x100 * dct) + index_reg, index, data);
- }
-}
-
-static uint16_t voltage_index_to_mv(uint8_t index)
-{
- if (index & 0x8)
- return 1150;
- if (index & 0x4)
- return 1250;
- else if (index & 0x2)
- return 1350;
- else
- return 1500;
-}
-
-uint16_t mct_MaxLoadFreq(uint8_t count, uint8_t highest_rank_count, uint8_t registered, uint8_t voltage, uint16_t freq)
-{
- /* FIXME
- * Mainboards need to be able to specify the maximum number of DIMMs installable per channel
- * For now assume a maximum of 2 DIMMs per channel can be installed
- */
- uint8_t MaxDimmsInstallable = 2;
-
- /* Return limited maximum RAM frequency */
- if (CONFIG(DIMM_DDR2)) {
- if (CONFIG(DIMM_REGISTERED) && registered) {
- /* K10 BKDG Rev. 3.62 Table 53 */
- if (count > 2) {
- /* Limit to DDR2-533 */
- if (freq > 266) {
- freq = 266;
- print_tf(__func__, ": More than 2 registered DIMMs on channel; limiting to DDR2-533\n");
- }
- }
- } else {
- /* K10 BKDG Rev. 3.62 Table 52 */
- if (count > 1) {
- /* Limit to DDR2-800 */
- if (freq > 400) {
- freq = 400;
- print_tf(__func__, ": More than 1 unbuffered DIMM on channel; limiting to DDR2-800\n");
- }
- }
- }
- } else if (CONFIG(DIMM_DDR3)) {
- if (voltage == 0) {
- printk(BIOS_DEBUG, "%s: WARNING: Mainboard DDR3 voltage unknown, assuming 1.5V!\n", __func__);
- voltage = 0x1;
- }
-
- if (is_fam15h()) {
- if (CONFIG_CPU_SOCKET_TYPE == 0x15) {
- /* Socket G34 */
- if (CONFIG(DIMM_REGISTERED) && registered) {
- /* Fam15h BKDG Rev. 3.14 Table 27 */
- if (voltage & 0x4) {
- /* 1.25V */
- if (count > 1) {
- if (highest_rank_count > 1) {
- /* Limit to DDR3-1066 */
- if (freq > 533) {
- freq = 533;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1066\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: 1 registered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else if (voltage & 0x2) {
- /* 1.35V */
- if (count > 1) {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: 1 registered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else if (voltage & 0x1) {
- /* 1.50V */
- if (count > 1) {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1866 */
- if (freq > 933) {
- freq = 933;
- printk(BIOS_DEBUG, "%s: 1 registered DIMM on %dmV channel; limiting to DDR3-1866\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- }
- } else {
- /* Fam15h BKDG Rev. 3.14 Table 26 */
- if (voltage & 0x4) {
- /* 1.25V */
- if (count > 1) {
- if (highest_rank_count > 1) {
- /* Limit to DDR3-1066 */
- if (freq > 533) {
- freq = 533;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1066\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else if (voltage & 0x2) {
- /* 1.35V */
- if (MaxDimmsInstallable > 1) {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else if (voltage & 0x1) {
- if (MaxDimmsInstallable == 1) {
- if (count > 1) {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1866 */
- if (freq > 933) {
- freq = 933;
- printk(BIOS_DEBUG, "%s: 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1866\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- if (count > 1) {
- if (highest_rank_count > 1) {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- }
- }
- }
- } else if (CONFIG_CPU_SOCKET_TYPE == 0x14) {
- /* Socket C32 */
- if (CONFIG(DIMM_REGISTERED) && registered) {
- /* Fam15h BKDG Rev. 3.14 Table 30 */
- if (voltage & 0x4) {
- /* 1.25V */
- if (count > 1) {
- if (highest_rank_count > 2) {
- /* Limit to DDR3-800 */
- if (freq > 400) {
- freq = 400;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-800\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: 1 registered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else if (voltage & 0x2) {
- /* 1.35V */
- if (count > 1) {
- if (highest_rank_count > 2) {
- /* Limit to DDR3-800 */
- if (freq > 400) {
- freq = 400;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-800\n", __func__, voltage_index_to_mv(voltage));
- }
- } else if (highest_rank_count > 1) {
- /* Limit to DDR3-1066 */
- if (freq > 533) {
- freq = 533;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1066\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: 1 registered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else if (voltage & 0x1) {
- /* 1.50V */
- if (count > 1) {
- if (highest_rank_count > 2) {
- /* Limit to DDR3-800 */
- if (freq > 400) {
- freq = 400;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-800\n", __func__, voltage_index_to_mv(voltage));
- }
- } else if (highest_rank_count > 1) {
- /* Limit to DDR3-1066 */
- if (freq > 533) {
- freq = 533;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1066\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- if (highest_rank_count > 2) {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: More than 1 registered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- }
- }
- } else {
- /* Fam15h BKDG Rev. 3.14 Table 29 */
- if (voltage & 0x4) {
- /* 1.25V */
- if (count > 1) {
- /* Limit to DDR3-1066 */
- if (freq > 533) {
- freq = 533;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1066\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else if (voltage & 0x2) {
- if (count > 1) {
- if (highest_rank_count > 1) {
- /* Limit to DDR3-1066 */
- if (freq > 533) {
- freq = 533;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1066\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else if (voltage & 0x1) {
- if (MaxDimmsInstallable == 1) {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- if (count > 1) {
- if (highest_rank_count > 1) {
- /* Limit to DDR3-1066 */
- if (freq > 533) {
- freq = 533;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1066\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: More than 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- /* Limit to DDR3-1600 */
- if (freq > 800) {
- freq = 800;
- printk(BIOS_DEBUG, "%s: 1 unbuffered DIMM on %dmV channel; limiting to DDR3-1600\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- }
- }
- }
- } else {
- /* TODO
- * Other socket support unimplemented
- */
- }
- } else {
- if (CONFIG(DIMM_REGISTERED) && registered) {
- /* K10 BKDG Rev. 3.62 Table 34 */
- if (count > 2) {
- /* Limit to DDR3-800 */
- if (freq > 400) {
- freq = 400;
- printk(BIOS_DEBUG, "%s: More than 2 registered DIMMs on %dmV channel; limiting to DDR3-800\n", __func__, voltage_index_to_mv(voltage));
- }
- } else if (count == 2) {
- /* Limit to DDR3-1066 */
- if (freq > 533) {
- freq = 533;
- printk(BIOS_DEBUG, "%s: 2 registered DIMMs on %dmV channel; limiting to DDR3-1066\n", __func__, voltage_index_to_mv(voltage));
- }
- } else {
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: 1 registered DIMM on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- } else {
- /* K10 BKDG Rev. 3.62 Table 33 */
- /* Limit to DDR3-1333 */
- if (freq > 666) {
- freq = 666;
- printk(BIOS_DEBUG, "%s: unbuffered DIMMs on %dmV channel; limiting to DDR3-1333\n", __func__, voltage_index_to_mv(voltage));
- }
- }
- }
- }
-
- return freq;
-}
-
-int mctRead_SPD(u32 smaddr, u32 reg)
-{
- return spd_read_byte(smaddr, reg);
-}
-
-
-void mctSMBhub_Init(u32 node)
-{
- struct sys_info *sysinfo = &sysinfo_car;
- struct mem_controller *ctrl = &(sysinfo->ctrl[node]);
- activate_spd_rom(ctrl);
-}
-
-
-void mctGet_DIMMAddr(struct DCTStatStruc *pDCTstat, u32 node)
-{
- int j;
- struct sys_info *sysinfo = &sysinfo_car;
- struct mem_controller *ctrl = &(sysinfo->ctrl[node]);
-
- for (j = 0; j < DIMM_SOCKETS; j++) {
- pDCTstat->DIMMAddr[j*2] = ctrl->spd_addr[j] & 0xff;
- pDCTstat->DIMMAddr[j*2+1] = ctrl->spd_addr[DIMM_SOCKETS + j] & 0xff;
- }
-
-}
-
-#if CONFIG(SET_FIDVID)
-u8 mctGetProcessorPackageType(void) {
- /* FIXME: I guess this belongs wherever mctGetLogicalCPUID ends up ? */
- u32 BrandId = cpuid_ebx(0x80000001);
- return (u8)((BrandId >> 28) & 0x0F);
-}
-#endif
-
-void raminit_amdmct(struct sys_info *sysinfo)
-{
- struct MCTStatStruc *pMCTstat = &(sysinfo->MCTstat);
- struct DCTStatStruc *pDCTstatA = sysinfo->DCTstatA;
-
- printk(BIOS_DEBUG, "raminit_amdmct begin:\n");
- timestamp_add_now(TS_BEFORE_INITRAM);
-
- mctAutoInitMCT_D(pMCTstat, pDCTstatA);
-
- timestamp_add_now(TS_AFTER_INITRAM);
- printk(BIOS_DEBUG, "raminit_amdmct end:\n");
-}
-
-void amdmct_cbmem_store_info(struct sys_info *sysinfo)
-{
- if (!sysinfo)
- return;
-
- /* Save memory info structures for use in ramstage */
- size_t i;
- struct DCTStatStruc *pDCTstatA = NULL;
-
- if (!acpi_is_wakeup_s3()) {
- /* Allocate memory */
- struct amdmct_memory_info *mem_info;
- mem_info = cbmem_add(CBMEM_ID_AMDMCT_MEMINFO, sizeof(struct amdmct_memory_info));
- if (!mem_info)
- return;
-
- printk(BIOS_DEBUG, "%s: Storing AMDMCT configuration in CBMEM\n", __func__);
-
- /* Initialize memory */
- memset(mem_info, 0, sizeof(struct amdmct_memory_info));
-
- /* Copy data */
- memcpy(&mem_info->mct_stat, &sysinfo->MCTstat, sizeof(struct MCTStatStruc));
- for (i = 0; i < MAX_NODES_SUPPORTED; i++) {
- pDCTstatA = sysinfo->DCTstatA + i;
- memcpy(&mem_info->dct_stat[i], pDCTstatA, sizeof(struct DCTStatStruc));
- }
- mem_info->ecc_enabled = mctGet_NVbits(NV_ECC_CAP);
- mem_info->ecc_scrub_rate = mctGet_NVbits(NV_DramBKScrub);
-
- /* Zero out invalid/unused pointers */
-#if CONFIG(DIMM_DDR3)
- for (i = 0; i < MAX_NODES_SUPPORTED; i++) {
- mem_info->dct_stat[i].C_MCTPtr = NULL;
- mem_info->dct_stat[i].C_DCTPtr[0] = NULL;
- mem_info->dct_stat[i].C_DCTPtr[1] = NULL;
- }
-#endif
- }
-}
diff --git a/src/northbridge/amd/amdfam10/raminit_sysinfo_in_ram.c b/src/northbridge/amd/amdfam10/raminit_sysinfo_in_ram.c
deleted file mode 100644
index 218df75887..0000000000
--- a/src/northbridge/amd/amdfam10/raminit_sysinfo_in_ram.c
+++ /dev/null
@@ -1,81 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <device/pci_ops.h>
-#include <northbridge/amd/amdfam10/raminit.h>
-#include <northbridge/amd/amdfam10/amdfam10.h>
-#include <delay.h>
-
-static void set_htic_bit(u8 i, u32 val, u8 bit)
-{
- u32 dword;
- dword = pci_read_config32(NODE_PCI(i, 0), HT_INIT_CONTROL);
- dword &= ~(1<<bit);
- dword |= ((val & 1) <<bit);
- pci_write_config32(NODE_PCI(i, 0), HT_INIT_CONTROL, dword);
-}
-
-#ifdef UNUSED_CODE
-static u32 get_htic_bit(u8 i, u8 bit)
-{
- u32 dword;
- dword = pci_read_config32(NODE_PCI(i, 0), HT_INIT_CONTROL);
- dword &= (1<<bit);
- return dword;
-}
-
-static void wait_till_sysinfo_in_ram(void)
-{
- while (1) {
- /* give the NB a break, many CPUs spinning on one bit makes a
- * lot of traffic and time is not too important to APs.
- */
- udelay(1000);
- if (get_htic_bit(0, 9)) return;
- }
-}
-#endif
-
-void fill_mem_ctrl(u32 controllers, struct mem_controller *ctrl_a, const u8 *spd_addr)
-{
- int i;
- int j;
- int index = 0;
- struct mem_controller *ctrl;
- for (i = 0; i < controllers; i++) {
- ctrl = &ctrl_a[i];
- ctrl->node_id = i;
- ctrl->f0 = NODE_PCI(i, 0);
- ctrl->f1 = NODE_PCI(i, 1);
- ctrl->f2 = NODE_PCI(i, 2);
- ctrl->f3 = NODE_PCI(i, 3);
- ctrl->f4 = NODE_PCI(i, 4);
- ctrl->f5 = NODE_PCI(i, 5);
-
- if (spd_addr == (void *)0) continue;
-
- ctrl->spd_switch_addr = spd_addr[index++];
-
- for (j = 0; j < 8; j++) {
- ctrl->spd_addr[j] = spd_addr[index++];
-
- }
- }
-}
-
-void set_sysinfo_in_ram(u32 val)
-{
- set_htic_bit(0, val, 9);
-}
diff --git a/src/northbridge/amd/amdfam10/reset_test.c b/src/northbridge/amd/amdfam10/reset_test.c
deleted file mode 100644
index 76d1144e7d..0000000000
--- a/src/northbridge/amd/amdfam10/reset_test.c
+++ /dev/null
@@ -1,136 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include <cpu/x86/lapic.h>
-#include <device/pci_ops.h>
-#include <northbridge/amd/amdfam10/raminit.h>
-#include <northbridge/amd/amdfam10/amdfam10.h>
-
-/* mmconf is not ready */
-/* io_ext is not ready */
-u32 cpu_init_detected(u8 nodeid)
-{
- u32 htic;
- pci_devfn_t dev;
-
- dev = NODE_PCI(nodeid, 0);
- htic = pci_io_read_config32(dev, HT_INIT_CONTROL);
-
- return !!(htic & HTIC_INIT_Detect);
-}
-
-u32 bios_reset_detected(void)
-{
- u32 htic;
- htic = pci_io_read_config32(PCI_DEV(CONFIG_CBB, CONFIG_CDB, 0), HT_INIT_CONTROL);
-
- return (htic & HTIC_ColdR_Detect) && !(htic & HTIC_BIOSR_Detect);
-}
-
-u32 cold_reset_detected(void)
-{
- u32 htic;
- htic = pci_io_read_config32(PCI_DEV(CONFIG_CBB, CONFIG_CDB, 0), HT_INIT_CONTROL);
-
- return !(htic & HTIC_ColdR_Detect);
-}
-
-u32 other_reset_detected(void) // other warm reset not started by BIOS
-{
- u32 htic;
- htic = pci_io_read_config32(PCI_DEV(CONFIG_CBB, CONFIG_CDB, 0), HT_INIT_CONTROL);
-
- return (htic & HTIC_ColdR_Detect) && (htic & HTIC_BIOSR_Detect);
-}
-
-void distinguish_cpu_resets(u8 nodeid)
-{
- u32 htic;
- pci_devfn_t device;
- device = NODE_PCI(nodeid, 0);
- htic = pci_io_read_config32(device, HT_INIT_CONTROL);
- htic |= HTIC_ColdR_Detect | HTIC_BIOSR_Detect | HTIC_INIT_Detect;
- pci_io_write_config32(device, HT_INIT_CONTROL, htic);
-}
-
-u32 warm_reset_detect(u8 nodeid)
-{
- u32 htic;
- pci_devfn_t device;
- device = NODE_PCI(nodeid, 0);
- htic = pci_io_read_config32(device, HT_INIT_CONTROL);
- return (htic & HTIC_ColdR_Detect) && !(htic & HTIC_BIOSR_Detect);
-}
-
-void set_bios_reset(void)
-{
-
- u32 nodes;
- u32 htic;
- pci_devfn_t dev;
- int i;
-
- nodes = ((pci_read_config32(PCI_DEV(CONFIG_CBB, CONFIG_CDB, 0), 0x60) >> 4) & 7) + 1;
-
- for (i = 0; i < nodes; i++) {
- dev = NODE_PCI(i,0);
- htic = pci_read_config32(dev, HT_INIT_CONTROL);
- htic &= ~HTIC_BIOSR_Detect;
- pci_write_config32(dev, HT_INIT_CONTROL, htic);
- }
-}
-
-
-/* Look up a which bus a given node/link combination is on.
- * return 0 when we can't find the answer.
- */
-static u8 node_link_to_bus(u8 node, u8 link) // node are 6 bit, and link three bit
-{
- u32 reg;
- u32 val;
-
- // put node and link in correct bit
- val = ((node & 0x0f)<<4) | ((node & 0x30)<< (12-4)) | ((link & 0x07)<<8);
-
- for (reg = 0xE0; reg < 0xF0; reg += 0x04) {
- u32 config_map;
- config_map = pci_io_read_config32(PCI_DEV(CONFIG_CBB, CONFIG_CDB, 1), reg);
- if ((config_map & 3) != 3) {
- continue;
- }
- if ((config_map & (((63 & 0x0f)<<4) | ((63 & 0x30)<< (12-4)) | ((7 & 0x07)<<8))
- ) == val)
- {
- return (config_map >> 16) & 0xff;
- }
- }
-
- return 0;
-}
-
-u32 get_sblk(void)
-{
- u32 reg;
- /* read PCI_DEV(CONFIG_CBB,CONFIG_CDB,0) 0x64 bit [8:9] to find out SbLink m */
- reg = pci_io_read_config32(PCI_DEV(CONFIG_CBB, CONFIG_CDB, 0), 0x64);
- return ((reg>>8) & 3);
-}
-
-
-u8 get_sbbusn(u8 sblk)
-{
- return node_link_to_bus(0, sblk);
-}
diff --git a/src/northbridge/amd/amdfam10/resourcemap.c b/src/northbridge/amd/amdfam10/resourcemap.c
deleted file mode 100644
index fa4ab3cfd7..0000000000
--- a/src/northbridge/amd/amdfam10/resourcemap.c
+++ /dev/null
@@ -1,282 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-static void setup_default_resource_map(void)
-{
- static const u32 register_values[] = {
- /* Careful set limit registers before base registers which contain
- the enables */
- /* DRAM Limit i Registers
- * F1:0x44 i = 0
- * F1:0x4C i = 1
- * F1:0x54 i = 2
- * F1:0x5C i = 3
- * F1:0x64 i = 4
- * F1:0x6C i = 5
- * F1:0x74 i = 6
- * F1:0x7C i = 7
- * [ 2: 0] Destination Node ID
- * 000 = Node 0
- * 001 = Node 1
- * 010 = Node 2
- * 011 = Node 3
- * 100 = Node 4
- * 101 = Node 5
- * 110 = Node 6
- * 111 = Node 7
- * [ 7: 3] Reserved
- * [10: 8] Interleave select
- * specifies the values of A[14:12] to use with
- * interleave enable.
- * [15:11] Reserved
- * [31:16] DRAM Limit Address i Bits 39-24
- * This field defines the upper address bits of a 40 bit
- * address that define the end of the DRAM region.
- */
- ADDRMAP_REG(0x44), 0x0000f8f8, 0x00000000,
- ADDRMAP_REG(0x4C), 0x0000f8f8, 0x00000001,
- ADDRMAP_REG(0x54), 0x0000f8f8, 0x00000002,
- ADDRMAP_REG(0x5C), 0x0000f8f8, 0x00000003,
- ADDRMAP_REG(0x64), 0x0000f8f8, 0x00000004,
- ADDRMAP_REG(0x6C), 0x0000f8f8, 0x00000005,
- ADDRMAP_REG(0x74), 0x0000f8f8, 0x00000006,
- ADDRMAP_REG(0x7C), 0x0000f8f8, 0x00000007,
- /* DRAM Base i Registers
- * F1:0x40 i = 0
- * F1:0x48 i = 1
- * F1:0x50 i = 2
- * F1:0x58 i = 3
- * F1:0x60 i = 4
- * F1:0x68 i = 5
- * F1:0x70 i = 6
- * F1:0x78 i = 7
- * [ 0: 0] Read Enable
- * 0 = Reads Disabled
- * 1 = Reads Enabled
- * [ 1: 1] Write Enable
- * 0 = Writes Disabled
- * 1 = Writes Enabled
- * [ 7: 2] Reserved
- * [10: 8] Interleave Enable
- * 000 = No interleave
- * 001 = Interleave on A[12] (2 nodes)
- * 010 = reserved
- * 011 = Interleave on A[12] and A[14] (4 nodes)
- * 100 = reserved
- * 101 = reserved
- * 110 = reserved
- * 111 = Interleve on A[12] and A[13] and A[14] (8 nodes)
- * [15:11] Reserved
- * [13:16] DRAM Base Address i Bits 39-24
- * This field defines the upper address bits of a 40-bit
- * address that define the start of the DRAM region.
- */
- ADDRMAP_REG(0x40), 0x0000f8fc, 0x00000000,
- ADDRMAP_REG(0x48), 0x0000f8fc, 0x00000000,
- ADDRMAP_REG(0x50), 0x0000f8fc, 0x00000000,
- ADDRMAP_REG(0x58), 0x0000f8fc, 0x00000000,
- ADDRMAP_REG(0x60), 0x0000f8fc, 0x00000000,
- ADDRMAP_REG(0x68), 0x0000f8fc, 0x00000000,
- ADDRMAP_REG(0x70), 0x0000f8fc, 0x00000000,
- ADDRMAP_REG(0x78), 0x0000f8fc, 0x00000000,
-
- /* Memory-Mapped I/O Limit i Registers
- * F1:0x84 i = 0
- * F1:0x8C i = 1
- * F1:0x94 i = 2
- * F1:0x9C i = 3
- * F1:0xA4 i = 4
- * F1:0xAC i = 5
- * F1:0xB4 i = 6
- * F1:0xBC i = 7
- * [ 2: 0] Destination Node ID
- * 000 = Node 0
- * 001 = Node 1
- * 010 = Node 2
- * 011 = Node 3
- * 100 = Node 4
- * 101 = Node 5
- * 110 = Node 6
- * 111 = Node 7
- * [ 3: 3] Reserved
- * [ 5: 4] Destination Link ID
- * 00 = Link 0
- * 01 = Link 1
- * 10 = Link 2
- * 11 = Reserved
- * [ 6: 6] Reserved
- * [ 7: 7] Non-Posted
- * 0 = CPU writes may be posted
- * 1 = CPU writes must be non-posted
- * [31: 8] Memory-Mapped I/O Limit Address i (39-16)
- * This field defines the upp address bits of a 40-bit
- * address that defines the end of a memory-mapped
- * I/O region n
- */
- ADDRMAP_REG(0x84), 0x00000048, 0x00000000,
- ADDRMAP_REG(0x8C), 0x00000048, 0x00000000,
- ADDRMAP_REG(0x94), 0x00000048, 0x00000000,
- ADDRMAP_REG(0x9C), 0x00000048, 0x00000000,
- ADDRMAP_REG(0xA4), 0x00000048, 0x00000000,
- ADDRMAP_REG(0xAC), 0x00000048, 0x00000000,
- ADDRMAP_REG(0xB4), 0x00000048, 0x00000000,
- ADDRMAP_REG(0xBC), 0x00000048, 0x00ffff00,
-
- /* Memory-Mapped I/O Base i Registers
- * F1:0x80 i = 0
- * F1:0x88 i = 1
- * F1:0x90 i = 2
- * F1:0x98 i = 3
- * F1:0xA0 i = 4
- * F1:0xA8 i = 5
- * F1:0xB0 i = 6
- * F1:0xB8 i = 7
- * [ 0: 0] Read Enable
- * 0 = Reads disabled
- * 1 = Reads Enabled
- * [ 1: 1] Write Enable
- * 0 = Writes disabled
- * 1 = Writes Enabled
- * [ 2: 2] Cpu Disable
- * 0 = Cpu can use this I/O range
- * 1 = Cpu requests do not use this I/O range
- * [ 3: 3] Lock
- * 0 = base/limit registers i are read/write
- * 1 = base/limit registers i are read-only
- * [ 7: 4] Reserved
- * [31: 8] Memory-Mapped I/O Base Address i (39-16)
- * This field defines the upper address bits of a 40bit
- * address that defines the start of memory-mapped
- * I/O region i
- */
- ADDRMAP_REG(0x80), 0x000000f0, 0x00000000,
- ADDRMAP_REG(0x88), 0x000000f0, 0x00000000,
- ADDRMAP_REG(0x90), 0x000000f0, 0x00000000,
- ADDRMAP_REG(0x98), 0x000000f0, 0x00000000,
- ADDRMAP_REG(0xA0), 0x000000f0, 0x00000000,
- ADDRMAP_REG(0xA8), 0x000000f0, 0x00000000,
- ADDRMAP_REG(0xB0), 0x000000f0, 0x00000000,
- ADDRMAP_REG(0xB8), 0x000000f0, 0x00fc0003,
-
- /* PCI I/O Limit i Registers
- * F1:0xC4 i = 0
- * F1:0xCC i = 1
- * F1:0xD4 i = 2
- * F1:0xDC i = 3
- * [ 2: 0] Destination Node ID
- * 000 = Node 0
- * 001 = Node 1
- * 010 = Node 2
- * 011 = Node 3
- * 100 = Node 4
- * 101 = Node 5
- * 110 = Node 6
- * 111 = Node 7
- * [ 3: 3] Reserved
- * [ 5: 4] Destination Link ID
- * 00 = Link 0
- * 01 = Link 1
- * 10 = Link 2
- * 11 = reserved
- * [11: 6] Reserved
- * [24:12] PCI I/O Limit Address i
- * This field defines the end of PCI I/O region n
- * [31:25] Reserved
- */
- ADDRMAP_REG(0xC4), 0xFE000FC8, 0x01fff000,
- ADDRMAP_REG(0xCC), 0xFE000FC8, 0x00000000,
- ADDRMAP_REG(0xD4), 0xFE000FC8, 0x00000000,
- ADDRMAP_REG(0xDC), 0xFE000FC8, 0x00000000,
-
- /* PCI I/O Base i Registers
- * F1:0xC0 i = 0
- * F1:0xC8 i = 1
- * F1:0xD0 i = 2
- * F1:0xD8 i = 3
- * [ 0: 0] Read Enable
- * 0 = Reads Disabled
- * 1 = Reads Enabled
- * [ 1: 1] Write Enable
- * 0 = Writes Disabled
- * 1 = Writes Enabled
- * [ 3: 2] Reserved
- * [ 4: 4] VGA Enable
- * 0 = VGA matches Disabled
- * 1 = matches all address < 64K and where A[9:0] is in
- * the range 3B0-3BB or 3C0-3DF independent of the
- * base & limit registers
- * [ 5: 5] ISA Enable
- * 0 = ISA matches Disabled
- * 1 = Blocks address < 64K and in the last 768 bytes of
- * eack 1K block from matching agains this base/limit
- * pair
- * [11: 6] Reserved
- * [24:12] PCI I/O Base i
- * This field defines the start of PCI I/O region n
- * [31:25] Reserved
- */
- ADDRMAP_REG(0xC0), 0xFE000FCC, 0x00000003,
- ADDRMAP_REG(0xC8), 0xFE000FCC, 0x00000000,
- ADDRMAP_REG(0xD0), 0xFE000FCC, 0x00000000,
- ADDRMAP_REG(0xD8), 0xFE000FCC, 0x00000000,
-
- /* Config Base and Limit i Registers
- * F1:0xE0 i = 0
- * F1:0xE4 i = 1
- * F1:0xE8 i = 2
- * F1:0xEC i = 3
- * [ 0: 0] Read Enable
- * 0 = Reads Disabled
- * 1 = Reads Enabled
- * [ 1: 1] Write Enable
- * 0 = Writes Disabled
- * 1 = Writes Enabled
- * [ 2: 2] Device Number Compare Enable
- * 0 = The ranges are based on bus number
- * 1 = The ranges are ranges of devices on bus 0
- * [ 3: 3] Reserved
- * [ 6: 4] Destination Node
- * 000 = Node 0
- * 001 = Node 1
- * 010 = Node 2
- * 011 = Node 3
- * 100 = Node 4
- * 101 = Node 5
- * 110 = Node 6
- * 111 = Node 7
- * [ 7: 7] Reserved
- * [ 9: 8] Destination Link
- * 00 = Link 0
- * 01 = Link 1
- * 10 = Link 2
- * 11 - Reserved
- * [15:10] Reserved
- * [23:16] Bus Number Base i
- * This field defines the lowest bus number in
- * configuration region i
- * [31:24] Bus Number Limit i
- * This field defines the highest bus number in
- * configuration regin i
- */
- ADDRMAP_REG(0xE0), 0x0000FC88, 0xff000003,
- ADDRMAP_REG(0xE4), 0x0000FC88, 0x00000000,
- ADDRMAP_REG(0xE8), 0x0000FC88, 0x00000000,
- ADDRMAP_REG(0xEC), 0x0000FC88, 0x00000000,
- };
-
- u32 max;
- max = ARRAY_SIZE(register_values);
- setup_resource_map(register_values, max);
-}
diff --git a/src/northbridge/amd/amdfam10/setup_resource_map.c b/src/northbridge/amd/amdfam10/setup_resource_map.c
deleted file mode 100644
index 735d72bbf7..0000000000
--- a/src/northbridge/amd/amdfam10/setup_resource_map.c
+++ /dev/null
@@ -1,184 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/io.h>
-#include <stdint.h>
-#include <console/console.h>
-#include <device/pci_ops.h>
-#include <northbridge/amd/amdfam10/raminit.h>
-#include <northbridge/amd/amdfam10/amdfam10.h>
-
-#define RES_DEBUG 0
-
-void setup_resource_map(const u32 *register_values, u32 max)
-{
- u32 i;
-
- for (i = 0; i < max; i += 3) {
- pci_devfn_t dev;
- u32 where;
- u32 reg;
-
- dev = register_values[i] & ~0xfff;
- where = register_values[i] & 0xfff;
- reg = pci_read_config32(dev, where);
- reg &= register_values[i+1];
- reg |= register_values[i+2];
- pci_write_config32(dev, where, reg);
- }
-}
-
-
-void setup_resource_map_offset(const u32 *register_values, u32 max, u32 offset_pci_dev, u32 offset_io_base)
-{
- u32 i;
-
- for (i = 0; i < max; i += 3) {
- pci_devfn_t dev;
- u32 where;
- unsigned long reg;
- dev = (register_values[i] & ~0xfff) + offset_pci_dev;
- where = register_values[i] & 0xfff;
- reg = pci_read_config32(dev, where);
- reg &= register_values[i+1];
- reg |= register_values[i+2] + offset_io_base;
- pci_write_config32(dev, where, reg);
- }
-}
-
-void setup_resource_map_x_offset(const u32 *register_values, u32 max, u32 offset_pci_dev, u32 offset_io_base)
-{
- u32 i;
-
- if (RES_DEBUG)
- printk(BIOS_DEBUG, "setting up resource map ex offset....\n");
-
- for (i = 0; i < max; i += 4) {
- if (RES_DEBUG)
- printk(BIOS_DEBUG, "%04x: %02x %08x <- & %08x | %08x\n",
- i/4, register_values[i],
- register_values[i+1] + ((register_values[i]==RES_PCI_IO) ? offset_pci_dev : 0),
- register_values[i+2],
- register_values[i+3] + (((register_values[i] & RES_PORT_IO_32) == RES_PORT_IO_32) ? offset_io_base : 0)
- );
- switch (register_values[i]) {
- case RES_PCI_IO: //PCI
- {
- pci_devfn_t dev;
- u32 where;
- u32 reg;
- dev = (register_values[i+1] & ~0xfff) + offset_pci_dev;
- where = register_values[i+1] & 0xfff;
- reg = pci_read_config32(dev, where);
- if (RES_DEBUG)
- printk(BIOS_SPEW, "WAS: %08x\n", reg);
- reg &= register_values[i+2];
- reg |= register_values[i+3];
- pci_write_config32(dev, where, reg);
- if (RES_DEBUG)
- printk(BIOS_SPEW, "NOW: %08x\n", reg);
- }
- break;
- case RES_PORT_IO_8: // io 8
- {
- u32 where;
- u32 reg;
- where = register_values[i+1] + offset_io_base;
- reg = inb(where);
- if (RES_DEBUG)
- printk(BIOS_SPEW, "WAS: %08x\n", reg);
- reg &= register_values[i+2];
- reg |= register_values[i+3];
- outb(reg, where);
- if (RES_DEBUG)
- printk(BIOS_SPEW, "NOW: %08x\n", reg);
- }
- break;
- case RES_PORT_IO_32: //io32
- {
- u32 where;
- u32 reg;
- where = register_values[i+1] + offset_io_base;
- reg = inl(where);
- if (RES_DEBUG)
- printk(BIOS_SPEW, "WAS: %08x\n", reg);
- reg &= register_values[i+2];
- reg |= register_values[i+3];
- outl(reg, where);
- if (RES_DEBUG)
- printk(BIOS_SPEW, "NOW: %08x\n", reg);
- }
- break;
- }
- }
-
- if (RES_DEBUG)
- printk(BIOS_DEBUG, "done.\n");
-}
-
-void setup_resource_map_x(const u32 *register_values, u32 max)
-{
- u32 i;
-
- if (RES_DEBUG)
- printk(BIOS_DEBUG, "setting up resource map ex offset....\n");
-
- for (i = 0; i < max; i += 4) {
- if (RES_DEBUG)
- printk(BIOS_DEBUG, "%04x: %02x %08x <- & %08x | %08x\n",
- i/4, register_values[i],register_values[i+1], register_values[i+2], register_values[i+3]);
- switch (register_values[i]) {
- case RES_PCI_IO: //PCI
- {
- pci_devfn_t dev;
- u32 where;
- u32 reg;
- dev = register_values[i+1] & ~0xfff;
- where = register_values[i+1] & 0xfff;
- reg = pci_read_config32(dev, where);
- reg &= register_values[i+2];
- reg |= register_values[i+3];
- pci_write_config32(dev, where, reg);
- }
- break;
- case RES_PORT_IO_8: // io 8
- {
- u32 where;
- u32 reg;
- where = register_values[i+1];
- reg = inb(where);
- reg &= register_values[i+2];
- reg |= register_values[i+3];
- outb(reg, where);
- }
- break;
- case RES_PORT_IO_32: //io32
- {
- u32 where;
- u32 reg;
- where = register_values[i+1];
- reg = inl(where);
- reg &= register_values[i+2];
- reg |= register_values[i+3];
- outl(reg, where);
- }
- break;
- }
- }
-
- if (RES_DEBUG)
- printk(BIOS_DEBUG, "done.\n");
-}
diff --git a/src/northbridge/amd/amdfam10/util.c b/src/northbridge/amd/amdfam10/util.c
deleted file mode 100644
index ed5556ff70..0000000000
--- a/src/northbridge/amd/amdfam10/util.c
+++ /dev/null
@@ -1,261 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2008 Vincent Legoll <vincent.legoll@gmail.com>
- * Copyright (C) 2008 Ronald G. Minnich <rminnich@gmail.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/*
- * fam10 northbridge utilities (dump routing registers).
- * Designed to be called at any time.
- * It can be called before RAM is set up by including this file.
- * It can be called after RAM is set up by including amdfam10.h and enabling the
- * compilation of this file in src/northbridge/amd/amdfam10/Makefile.inc.
- */
-#include <console/console.h>
-#include <device/pci.h>
-#include <device/pci_ops.h>
-
-#include "amdfam10.h"
-
-/* Function 1 */
-/* the DRAM, MMIO,and PCIIO routing are 64-bit registers, hence the ending at
- * 0x78, 0xb8, and 0xd8
- */
-#define DRAM_ROUTE_START 0x40
-#define DRAM_ROUTE_END 0x78
-#define MMIO_ROUTE_START 0x80
-#define MMIO_ROUTE_END 0xb8
-#define PCIIO_ROUTE_START 0xc0
-#define PCIIO_ROUTE_END 0xd8
-#define CONF_ROUTE_START 0xe0
-#define CONF_ROUTE_END 0xec
-
-#define BITS(r, shift, mask) (((r>>shift)&mask))
-
-/**
- * Return "R" if the register has read-enable bit set.
- */
-static const char *re(u32 i)
-{
- return ((i & 1) ? "R" : "");
-}
-
-/**
- * Return "W" if the register has write-enable bit set.
- */
-static const char *we(u32 i)
-{
- return ((i & 1) ? "W" : "");
-}
-
-/**
- * Return a string containing the interleave settings.
- */
-static const char *ileave(u32 base)
-{
- switch ((base >> 8) & 7) {
- case 0:
- return "No interleave";
- case 1:
- return "2 nodes";
- case 3:
- return "4 nodes";
- case 7:
- return "8 nodes";
- default:
- return "Reserved";
- }
-}
-
-/**
- * Return the node number.
- * For one case (config registers) these are not the right bit fields.
- */
-static int r_node(u32 reg)
-{
- return BITS(reg, 0, 0x7);
-}
-
-/**
- * Return the link number.
- * For one case (config registers) these are not the right bit fields.
- */
-static int r_link(u32 reg)
-{
- return BITS(reg, 4, 0x3);
-}
-
-/**
- * Print the DRAM routing info for one base/limit pair.
- *
- * Show base, limit, dest node, dest link on that node, read and write
- * enable, and interleave information.
- *
- * @param level Printing level
- * @param which Register number
- * @param base Base register
- * @param lim Limit register
- */
-static void showdram(int level, u8 which, u32 base, u32 lim)
-{
- printk(level, "DRAM(%02x)%010llx-%010llx, ->(%d), %s, %s, %s, %d\n",
- which, (((u64) base & 0xffff0000) << 8),
- (((u64) lim & 0xffff0000) << 8) + 0xffffff,
- r_node(lim), re(base), we(base), ileave(base), (lim >> 8) & 3);
-}
-
-/**
- * Print the config routing info for a config register.
- *
- * Show base, limit, dest node, dest link on that node, read and write
- * enable, and device number compare enable
- *
- * @param level Printing level
- * @param which Register number
- * @param reg Config register
- */
-static void showconfig(int level, u8 which, u32 reg)
-{
- /* Don't use r_node() and r_link() here. */
- printk(level, "Config(%02x)%02x-%02x ->(%d,%d),%s %s (%s numbers)\n",
- which, BITS(reg, 16, 0xff), BITS(reg, 24, 0xff),
- BITS(reg, 4, 0x7), BITS(reg, 8, 0x3),
- re(reg), we(reg),
- BITS(reg, 2, 0x1)?"dev":"bus");
-}
-
-/**
- * Print the PCIIO routing info for one base/limit pair.
- *
- * Show base, limit, dest node, dest link on that node, read and write
- * enable, and VGA and ISA Enable.
- *
- * @param level Printing level
- * @param which Register number
- * @param base Base register
- * @param lim Limit register
- */
-static void showpciio(int level, u8 which, u32 base, u32 lim)
-{
- printk(level, "PCIIO(%02x)%07x-%07x, ->(%d,%d), %s, %s,VGA %d ISA %d\n",
- which, BITS(base, 12, 0x3fff) << 12,
- (BITS(lim, 12, 0x3fff) << 12) + 0xfff, r_node(lim), r_link(lim),
- re(base), we(base), BITS(base, 4, 0x1), BITS(base, 5, 0x1));
-}
-
-/**
- * Print the MMIO routing info for one base/limit pair.
- *
- * Show base, limit, dest node, dest link on that node, read and write
- * enable, and CPU Disable, Lock, and Non-posted.
- *
- * @param level Printing level
- * @param which Register number
- * @param base Base register
- * @param lim Limit register
- */
-static void showmmio(int level, u8 which, u32 base, u32 lim)
-{
- printk(level, "MMIO(%02x)%010llx-%010llx, ->(%d,%d), %s, %s, "
- "CPU disable %d, Lock %d, Non posted %d\n",
- which, ((u64) BITS(base, 0, 0xffffff00)) << 8,
- (((u64) BITS(lim, 0, 0xffffff00)) << 8) + 0xffff, r_node(lim),
- r_link(lim), re(base), we(base), BITS(base, 4, 0x1),
- BITS(base, 7, 0x1), BITS(lim, 7, 0x1));
-}
-
-/**
- * Show all DRAM routing registers. This function is callable at any time.
- *
- * @param level The debug level.
- * @param dev A 32-bit number in the standard bus/dev/fn format which is used
- * raw config space.
- */
-static void showalldram(int level, struct device *dev)
-{
- u8 reg;
- for (reg = DRAM_ROUTE_START; reg <= DRAM_ROUTE_END; reg += 8) {
- u32 base = pci_read_config32(dev, reg);
- u32 lim = pci_read_config32(dev, reg + 4);
- if (base || lim!=(reg-DRAM_ROUTE_START)/8)
- showdram(level, reg, base, lim);
- }
-}
-
-/**
- * Show all MMIO routing registers. This function is callable at any time.
- *
- * @param level The debug level.
- * @param dev A 32-bit number in the standard bus/dev/fn format which is used
- * raw config space.
- */
-static void showallmmio(int level, struct device *dev)
-{
- u8 reg;
- for (reg = MMIO_ROUTE_START; reg <= MMIO_ROUTE_END; reg += 8) {
- u32 base = pci_read_config32(dev, reg);
- u32 lim = pci_read_config32(dev, reg + 4);
- if (base || lim)
- showmmio(level, reg, base, lim);
- }
-}
-
-/**
- * Show all PCIIO routing registers. This function is callable at any time.
- *
- * @param level The debug level.
- * @param dev A 32-bit number in the standard bus/dev/fn format which is used
- * raw config space.
- */
-static void showallpciio(int level, struct device *dev)
-{
- u8 reg;
- for (reg = PCIIO_ROUTE_START; reg <= PCIIO_ROUTE_END; reg += 8) {
- u32 base = pci_read_config32(dev, reg);
- u32 lim = pci_read_config32(dev, reg + 4);
- if (base || lim)
- showpciio(level, reg, base, lim);
- }
-}
-
-/**
- * Show all config routing registers. This function is callable at any time.
- *
- * @param level The debug level.
- * @param dev A 32-bit number in the standard bus/dev/fn format which is used
- * raw config space.
- */
-static void showallconfig(int level, struct device *dev)
-{
- u8 reg;
- for (reg = CONF_ROUTE_START; reg <= CONF_ROUTE_END; reg += 4) {
- u32 val = pci_read_config32(dev, reg);
- if (val)
- showconfig(level, reg, val);
- }
-}
-
-/**
- * Show all routing registers. This function is callable at any time.
- *
- * @param level The debug level.
- * @param dev A 32-bit number in the standard bus/dev/fn format which is used
- * raw config space.
- */
-void showallroutes(int level, struct device *dev)
-{
- showalldram(level, dev);
- showallmmio(level, dev);
- showallpciio(level, dev);
- showallconfig(level, dev);
-}
diff --git a/src/northbridge/amd/amdht/AsPsDefs.h b/src/northbridge/amd/amdht/AsPsDefs.h
deleted file mode 100644
index 30f4d759b6..0000000000
--- a/src/northbridge/amd/amdht/AsPsDefs.h
+++ /dev/null
@@ -1,273 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-
-#ifndef ASPSDEFS_H
-#define ASPSDEFS_H
-
-/* P-state register offset */
-#define PS_REG0 0 /* offset for P0 */
-#define PS_REG1 1 /* offset for P1 */
-#define PS_REG2 2 /* offset for P2 */
-#define PS_REG3 3 /* offset for P3 */
-#define PS_REG4 4 /* offset for P4 */
-
-#define PS_IDD_VALUE_SHFT 0 /* IddValue: current value
- field offset for msr.hi */
-#define PS_IDD_VALUE_MASK 0xFF /* IddValue: current value
- field mask for msr.hi */
-#define PS_PSDIS_MASK 0x7fffffff /* disable P-state register */
-#define PS_EN_MASK 0x80000000 /* P-state register enable mask */
-#define PS_NB_DID_MASK 0x400000 /* P-state Reg[NbDid] Mask */
-#define PS_NB_VID_M_OFF 0x01ffffff /* P-state Reg[NbVid] Mask OFF */
-#define PS_CPU_VID_M_ON 0x0fe00 /* P-state Reg[CpuVid] Mask On */
-#define PS_NB_VID_M_ON 0x0fe000000 /* P-state Reg[NbVid] Mask On */
-#define PS_CPU_VID_SHFT 9 /* P-state bit shift for CpuVid */
-#define PS_NB_VID_SHFT 25 /* P-state bit shift for NbVid */
-#define PS_BOTH_VID_OFF 0x01ff01ff /* Mask NbVid & CpuVid */
-#define PS_CPU_NB_VID_SHFT 16 /* P-state bit shift from CpuVid to NbVid */
-#define PS_DIS 0x7fffffff /* disable P-state reg */
-#define PS_EN 0x80000000 /* enable P-state reg */
-#define PS_CPU_FID_MASK 0x03f /* MSRC001_00[68:64][CpuFid]
- Core Frequency Id */
-#define PS_CURDIV_SHFT 8 /* P-state Current Divisor shift position */
-#define PS_CPUDID_SHIFT 6 /* P-state CPU DID shift position */
-
-/* for unfused parts */
-#define PS_NB_VID_110V 0x48000000
-#define PS_NB_VID_1175V 0x3c000000
-/* NB VID 1.100V =0x12[PVI]=0x24[SVI] = 0100100b 7-bit code */
-
-#define PS_NB_DID0 0 /* NB DID 0 */
-#define PS_NB_DID1 0x400000 /* NB DID 1 */
-#define PS_CPU_VID_110V 0x4800 /* CPU VID 1.100V */
-#define PS_CPU_VID_1175V 0x3c00 /* CPU VID 1.175V */
-#define PS_CPU_DID 0x40 /* CPU DID 1 = divisor of 2 */
-#define PS_CPU_DID0 0 /* CPU DID 0 = divisor of 1 */
-#define PS_CPU_FID_16G 0x00 /* CPU FID of 00 = 1.6GHz */
-#define PS_CPU_FID_16G1 0x10 /* CPU FId of 16 COF = 16+16/2 = 16 */
-#define PS_CPU_FID_18G 20 /* CPU FId of 20 COF = 20+16/2 = 18 */
-#define PS_CPU_FID_19G 22 /* CPU FId of 20 COF = 22+16/2 = 19 */
-#define PS_CPU_FID_20G 24 /* CPU FId of 20 COF = 24+16/2 = 20 */
-#define PS_CPU_FID_22G 28 /* CPU FId of 2C COF = 28+16/2 = 22 */
-#define PS_CPU_FID_30G 44 /* CPU FId of 2C COF = 44+16/2 = 30 */
-
-
-
-#define PCI_DEV_BASE 24 /* System PCI device ID base */
-#define LOCAL_APIC_ID_SHIFT 24 /* Local APIC ID shift bit # */
-#define APIC_CID_SIZE_SHIFT 12 /* ApicCoreIdSize shift bit # */
-#define FN_0 0 /* Function 0 */
-#define FN_1 1 /* Function 1 */
-#define FN_2 2 /* Function 2 */
-#define FN_3 3 /* Function 3 */
-#define FN_4 4 /* Function 4 */
-#define FN_5 5 /* Function 5 */
-#define FN_80000000 0x80000000 /* Function 8000_0000 */
-#define FN_80000001 0x80000001 /* Function 8000_0001 */
-#define FN_80000008 0x80000008 /* Function 8000_0008 */
-
-#define LNK_INIT_REG 0x6C /* F0x6C link initialization control register */
-#define WARM_RESET_BIT 0x10 /* bit 4 =1 : warm reset */
-
-#define HTC_REG 0x64 /* hardware thermal control reg */
-#define HTC_PS_LMT_MASK 0x8fffffff /* HtcPstateLimit mask off */
-#define PS_LIMIT_POS 28 /* PstateLimit position for HTC & STC */
-
-#define STC_REG 0x68 /* software thermal control reg */
-#define STC_PS_LMT_MASK 0x8fffffff /* StcPstateLimit mask off */
-
-#define CPTC0 0x0d4 /* Clock Power/Timing Control0 Register*/
-#define CPTC0_MASK 0x000cffff /* Reset mask for this register */
-#define CPTC0_NBFID_MASK 0xffffffe0 /* NbFid mask off for this register */
-#define CPTC0_NBFID_MON 0x1f /* NbFid mask on for this register */
-#define NB_FID_EN 0x20 /* NbFidEn bit ON */
-#define NB_CLKDID_ALL 0x80000000 /* NbClkDidApplyAll bit ON */
-#define NB_CLKDID 0x40000000 /* NbClkDid value set by BIOS */
-#define NB_CLKDID_SHIFT 28 /* NbClkDid bit shift */
-#define PW_STP_UP50 0x08000000 /* PowerStepUp 50nS(1000b) */
-#define PW_STP_DN50 0x00800000 /* PowerStepDown 50nS (1000b)*/
-#define PW_STP_UP100 0x03000000 /* PowerStepUp 100nS(0011b) */
-#define PW_STP_DN100 0x00300000 /* PowerStepDown 100nS (0011b)*/
-#define PW_STP_UP200 0x02000000 /* PowerStepUp 200nS(0010b) */
-#define PW_STP_DN200 0x00200000 /* PowerStepDown 200nS (0010b)*/
-#define PW_STP_UP400 0x00000000 /* PowerStepUp 400nS(0000b) */
-#define PW_STP_DN400 0x00000000 /* PowerStepDown 400nS (0000b)*/
-#define CLK_RAMP_HYST_SEL_VAL 0x00000f00 /* value mask for clock ramp
- hysteresis select. BIOS
- should program
- F3xC4[ClkRampHystSel] to
- 1111b */
-
-
-#define LNK_PLL_LOCK 0x00010000 /* LnkPllLock value set (01b) by BIOS */
-
-
-
-#define PSTATE_CTL 0xC0010070 /* P-state Control Register */
-#define NB_VID_POS 25 /* NbVid bit shift for position */
-#define NB_VID_MASK_OFF 0x01ffffff /* NbVid bits mask off */
-#define NB_VID_MASK_ON 0xfe000000 /* NbVid bits mask on */
-#define CPU_VID_POS 0x9 /* CpuVid bit shift for position */
-#define CPU_VID_MASK_OFF 0xffff01ff /* CpuVid bits mask off */
-#define CPU_VID_MASK_ON 0x0000fe00 /* CpuVid bits mask on */
-#define CPU_FID_DID_M_ON 0x000001ff /* CpuFid & CpuDid mask on */
-#define CPU_FID_DID_M_OFF 0xfffffe00 /* CpuFid & CpuDid mask off */
-#define NB_DID_VID_M_ON 0xfe400000 /* NbDid & NbVid mask on */
-#define NB_DID_M_ON 0x00400000 /* NbDid mask on */
-#define NB_DID_M_OFF 0xffbfffff /* NbDid mask off */
-#define NB_DID_POS 22 /* NbDid bit shift for position */
-#define PS_M_OFF 0xfff8ffff /* Cur Pstate mask off */
-#define PS_1 0x00010000 /* P-state 1 */
-#define PS_2 0x00020000 /* P-state 2 */
-#define PS_CPU_DID_1 0x40 /* Cpu Did 1 */
-
-#define NB_VID1_MASK 0x00003f80 /* F3x1F4[NbVid1]*/
-#define NB_VID1_SHIFT 7 /* F3x1F4[NbVid1] */
-
-
-
-#define PSTATE_STS 0xC0010071 /* P-state Status Register */
-#define STARTUP_PS_MASK 0x7 /* StartupPstate Mask */
-
-/* define for NB VID & CPU VID transition functions */
-#define IS_NB 1
-#define IS_CPU 0
-
-/* F3xD8 Clock Power/Timing Control 1 Register */
-#define CPTC1 0xd8 /* Clock Power/Timing Control1 Register*/
-#define VSRAMP_SLAM_MASK 0xffffff88 /* MaskOff [VSRampTime]&[VSSlamTime] */
-#define VSRAMP_SLAM_VALUE 0x16 /* [VSRampTime]=001b&[VSSlamTime]=110b */
-#define VSRAMP_MASK 0xffffff8f /* MaskOff [VSRampTime] */
-#define VSRAMP_VALUE 0x10 /* [VSRampTime]=001b */
-#define VS_RAMP_T 4 /* VSRampTime bit position */
-#define VSSLAM_MASK 0xfffffff8 /* MaskOff [VSSlamTime] */
-#define PWR_PLN_SHIFT 28 /* PwrPlanes bit shift */
-#define PWR_PLN_ON 0x10000000 /* PwrPlanes bit ON */
-#define PWR_PLN_OFF 0x0efffffff /* PwrPlanes bit OFF */
-
-
-
-/* Northbridge Capability Register */
-#define NB_CAP 0xe8 /* Northbridge Cap Reg */
-#define CMP_CAP_SHFT 12 /* CMP CAP - number of enabled cores */
-
-/* F3xDC Clock Power/Timing Control 2 Register */
-#define CPTC2 0xdc /* Clock Power/Timing Control2 Register*/
-#define PS_MAX_VAL_POS 8 /* PstateMaxValue bit shift */
-#define PS_MAX_VAL_MASK 0xfffff8ff /* PstateMaxValue Mask off */
-#define NB_SYN_PTR_ADJ_POS 12 /* NbsynPtrAdj bit shift */
-#define NB_SYN_PTR_ADJ_MASK (0x7 << NB_SYN_PTR_ADJ_POS) /* NbsynPtrAdj bit mask */
-
-#define PRCT_INFO 0x1fc /* Product Info Register */
-#define DUAL_PLANE_ONLY_MASK 0x80000000 /* F3x1FC[DualPlaneOnly] */
-#define UNI_NB_FID_BIT 2 /* UniNbFid bit position */
-#define UNI_NB_VID_BIT 7 /* UniNbVid bit position */
-#define SPLT_NB_FID_OFFSET 14 /* SpltNbFidOffset value bit position */
-#define SPLT_NB_VID_OFFSET 17 /* SpltNbVidOffset value bit position */
-#define NB_CV_UPDATE 0x01 /* F3x1FC[NbCofVidUpdated] bit mask */
-#define NB_VID_UPDATE_ALL 0x02 /* F3x1FC[NbVidUpdatedAll] bit mask */
-#define C_FID_DID_M_OFF 0xfffffe00 /* mask off Core FID & DID */
-
-#define CPB_MASK 0x00000020 /* core performance
- boost. CPUID Fn8000 0007 edx */
-#define NC_MASK 0x000000FF /* number of cores - 1. CPUID
- Fn8000 0008 ecx */
-#define PW_CTL_MISC 0x0a0 /* Power Control Miscellaneous Register */
-#define COF_VID_PROG_BIT 0x80000000 /* CofVidProg bit. 0= unfused part */
-#define DUAL_VDD_BIT 0x40000000 /* DualVdd bit. */
-#define NB_COFVID_UPDATE_BIT 0x01 /* NbCOFVIDUpdated bit */
-#define PVI_MODE 0x100 /* PviMode bit mask */
-#define VID_SLAM_OFF 0x0dfffffff /* set VidSlamMode OFF */
-#define VID_SLAM_ON 0x020000000 /* set VidSlamMode ON */
-#define NB_PSTATE_FORCE_ON 0x010000000 /* set Northbridge P-state
- force on next LDTSTOP
- assertion on, in F3xA0 */
-#define BP_INS_TRI_EN_ON 0x00004000 /* breakpoint pins tristate
- enable in F3xA0 */
-#define PLLLOCK_OFF 0x0ffffc7ff /* PllLockTime Mask OFF */
-#define PLLLOCK_DFT 0x00001800 /* PllLockTime default value = 011b */
-#define PLLLOCK_DFT_L 0x00002800 /* PllLockTime long value = 101b */
-
-#define SVI_HIGH_FREQ_ON 0x00000200 /* F3xA0[SviHighFreqSel] for
- 3.4 MHz SVI in rev. C3 */
-
-/* P-state Specification register base in PCI space */
-#define PS_SPEC_REG 0x1e0 /* PS Spec register base address */
-#define PCI_REG_LEN 4 /* PCI register length */
-#define NB_DID_MASK 0x10000 /* NbDid bit mask */
-#define NB_DID_2 2 /* NbDid = 2 */
-#define NB_DID_1 1 /* NbDid = 1 */
-#define SPEC_PWRDIV_M_ON 0x06000000 /* PwrDiv mask on */
-#define SPEC_PWRVAL_M_ON 0x01e00000 /* PwrValue mask on */
-#define SPEC_PWRDIV_SHFT 25 /* PwrDiv shift */
-#define SPEC_PWRVAL_SHFT 17 /* PwrValue shift */
-
-/* F4x1F4 Northbridge P-state spec register */
-#define NB_PS_SPEC_REG 0x1f4 /* Nb PS spec reg */
-
-/* F3x1F0 Product Information Register */
-#define NB_PSTATE_MASK 0x00070000 /* NbPstate for CPU rev C3 */
-
-/* F3x1FC Product Information Register */
-#define NB_COF_VID_UPDATE_MASK 1 /* for CPU rev <= C */
-#define SINGLE_PLANE_NB_FID_MASK 0x007c/* for CPU rev <= C */
-#define SINGLE_PLANE_NB_FID_SHIFT 2/* for CPU rev <= C */
-#define SINGLE_PLANE_NB_VID_MASK 0x3f80/* for CPU rev <= C */
-#define SINGLE_PLANE_NB_VID_SHIFT 7/* for CPU rev <= C */
-
-#define DUAL_PLANE_NB_FID_OFF_MASK 0x001c000/* for CPU rev <= C */
-#define DUAL_PLANE_NB_FID_SHIFT 14/* for CPU rev <= C */
-#define DUAL_PLANE_NB_VID_OFF_MASK 0x3e0000/* for CPU rev <= C */
-#define DUAL_PLANE_NB_VID_SHIFT 17/* for CPU rev <= C */
-
-#define NM_PS_REG (is_fam15h()?8:5) /* number of P-state MSR registers */
-
-/* sFidVidInit.outFlags defines */
-#define PWR_CK_OK 0 /* System board check OK */
-#define PWR_CK_NO_PS 1 /* All P-state registers are over
- the limit */
-
-/* bit mask */
-#define BIT_MASK_1 0x1
-#define BIT_MASK_2 0x3
-#define BIT_MASK_3 0x7
-#define BIT_MASK_4 0x0f
-#define BIT_MASK_5 0x1f
-#define BIT_MASK_6 0x3f
-#define BIT_MASK_7 0x7f
-#define BIT_MASK_8 0x0ff
-
-/* VID Code */
-#define VID_1_100V 0x12 /* 1.100V */
-#define VID_1_175V 0x1E /* 1.175V */
-
-/* Nb Fid Code */
-#define NB_FID_800M 0x00 /* 800MHz */
-
-/* Nb DID Code */
-#define NB_DID_0 0
-#define NB_DID_1 1
-
-/* GH Logical ID */
-#define GH_REV_A2 0x4 /* GH Rev A2 logical ID, Upper half */
-
-#define TSC_FREQ_SEL_SHIFT 24
-#define TSC_FREQ_SEL_MASK (1 << TSC_FREQ_SEL_SHIFT)
-
-#define WAIT_PSTATE_TIMEOUT 80000000 /* 0.1 s , unit : 1.25 ns */
-
-#endif
diff --git a/src/northbridge/amd/amdht/AsPsNb.c b/src/northbridge/amd/amdht/AsPsNb.c
deleted file mode 100644
index 70dbacfbab..0000000000
--- a/src/northbridge/amd/amdht/AsPsNb.c
+++ /dev/null
@@ -1,121 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "comlib.h"
-#include "AsPsDefs.h"
-#include "AsPsNb.h"
-
-u8 getNumOfNodeNb(void);
-u8 translateNodeIdToDeviceIdNb(u8 nodeId);
-
-/**
- * Return the minimum possible NbCOF (in 100MHz) for the system.
- *
- * This function can be run on any core and is used by the HT & Memory init
- * code in Phase 1.
- *
- * @return minNbCOF (in multiple of half of CLKIN, 100MHz).
- */
-u8 getMinNbCOF(void)
-{
- u8 numOfNode, i, j, deviceId, nbDid, nbFid, nextNbFid;
- u32 dtemp;
-
- nbDid = 0;
- nbFid = 0;
-
- /* get number of node in the system */
- numOfNode = getNumOfNodeNb();
-
- /* go through each node for the minimum NbCOF (in multiple of CLKIN/2) */
- for (i = 0; i < numOfNode; i++)
- {
- /* stub function for APIC ID virtualization for large MP system later */
- deviceId = translateNodeIdToDeviceIdNb(i);
-
- /* read all P-state spec registers for NbDid = 1 */
- for (j = 0; j < 5; j++)
- {
- AmdPCIRead(MAKE_SBDFO(0,0,deviceId,FN_4,PS_SPEC_REG+(j*PCI_REG_LEN)), &dtemp); /*F4x1E0 + j*4 */
- /* get NbDid */
- if (dtemp & NB_DID_MASK)
- nbDid = 1;
- }
- /* if F3x1FC[NbCofVidUpdate]=0, NbFid = default value */
- AmdPCIRead(MAKE_SBDFO(0,0,deviceId,FN_3,PRCT_INFO), &dtemp); /*F3x1FC*/
- if (!(dtemp & NB_CV_UPDATE)) /* F3x1FC[NbCofVidUpdated]=0, use default VID */
- {
- AmdPCIRead(MAKE_SBDFO(0,0,deviceId,FN_3,CPTC0), &dtemp); /*F3xD4*/
- nextNbFid = (u8) (dtemp & BIT_MASK_5);
- if (nbDid)
- nextNbFid = (u8) (nextNbFid >> 1);
- }
- else
- {
- /* check PVI/SPI */
- AmdPCIRead(MAKE_SBDFO(0,0,deviceId,FN_3,PW_CTL_MISC), &dtemp); /*F3xA0*/
- if (dtemp & PVI_MODE) /* PVI */
- {
- AmdPCIRead(MAKE_SBDFO(0,0,deviceId,FN_3,PRCT_INFO), &dtemp); /*F3x1FC*/
- nextNbFid = (u8) (dtemp >> UNI_NB_FID_BIT);
- nextNbFid &= BIT_MASK_5;
- /* if (nbDid)
- nextNbFid = nextNbFid >> 1; */
- }
- else /* SVI */
- {
- AmdPCIRead(MAKE_SBDFO(0,0,deviceId,FN_3,PRCT_INFO), &dtemp); /*F3x1FC*/
- nextNbFid = (u8) ((dtemp >> UNI_NB_FID_BIT) & BIT_MASK_5);
- nextNbFid = (u8) (nextNbFid + ((dtemp >> SPLT_NB_FID_OFFSET) & BIT_MASK_3));
- /* if (nbDid)
- nextNbFid = nextNbFid >> 1; */
- }
- }
- if (i == 0)
- nbFid = nextNbFid;
- else if (nbFid > nextNbFid)
- nbFid = nextNbFid;
- }
-
- /* add the base and convert to 100MHz divide by 2 if DID = 1 */
- if (nbDid)
- nbFid = (u8) (nbFid + 4);
- else
- nbFid = (u8) ((nbFid + 4) << 1);
- return nbFid;
-}
-
-u8 getNumOfNodeNb(void)
-{
- u32 dtemp;
-
- AmdPCIRead(MAKE_SBDFO(0,0,24,0,0x60), &dtemp);
- dtemp = (dtemp >> 4) & BIT_MASK_3;
- dtemp++;
- return (u8)dtemp;
-}
-
-/**
- * Return the PCI device ID for PCI access using node ID.
- *
- * This function may need to change node ID to device ID in big MP systems.
- *
- * @param nodeId Node ID of the node.
- * @return PCI device ID of the node.
- */
-u8 translateNodeIdToDeviceIdNb(u8 nodeId)
-{
- return (u8) (nodeId+PCI_DEV_BASE);
-}
diff --git a/src/northbridge/amd/amdht/AsPsNb.h b/src/northbridge/amd/amdht/AsPsNb.h
deleted file mode 100644
index 35008920fe..0000000000
--- a/src/northbridge/amd/amdht/AsPsNb.h
+++ /dev/null
@@ -1,22 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-
-#ifndef ASPSNB_H
-#define ASPSNB_H
-
-u8 getMinNbCOF(void);
-
-#endif
diff --git a/src/northbridge/amd/amdht/Makefile.inc b/src/northbridge/amd/amdht/Makefile.inc
deleted file mode 100644
index 0b33352e7c..0000000000
--- a/src/northbridge/amd/amdht/Makefile.inc
+++ /dev/null
@@ -1,5 +0,0 @@
-ifeq ($(CONFIG_NORTHBRIDGE_AMD_AMDFAM10),y)
-
-romstage-y += h3finit.c ht_wrapper.c comlib.c AsPsNb.c h3ncmn.c
-
-endif
diff --git a/src/northbridge/amd/amdht/comlib.c b/src/northbridge/amd/amdht/comlib.c
deleted file mode 100644
index 883f634c74..0000000000
--- a/src/northbridge/amd/amdht/comlib.c
+++ /dev/null
@@ -1,238 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "comlib.h"
-
-#include <device/pci.h>
-#include <device/pci_ops.h>
-#include <cpu/amd/msr.h>
-#include <device/pci_def.h>
-
-
-/*
- *---------------------------------------------------------------------------
- * EXPORTED FUNCTIONS
- *
- *---------------------------------------------------------------------------
- */
-
-void CALLCONV AmdPCIReadBits(SBDFO loc, u8 highbit, u8 lowbit, u32 *pValue)
-{
- ASSERT(highbit < 32 && lowbit < 32 && highbit >= lowbit && (loc & 3) == 0);
-
- AmdPCIRead(loc, pValue);
- *pValue = *pValue >> lowbit; /* Shift */
-
- /* A 1<<32 == 1<<0 due to x86 SHL instruction, so skip if that is the case */
- if ((highbit-lowbit) != 31)
- *pValue &= (((u32)1 << (highbit-lowbit+1))-1);
-}
-
-
-void CALLCONV AmdPCIWriteBits(SBDFO loc, u8 highbit, u8 lowbit, u32 *pValue)
-{
- u32 temp, mask;
-
- ASSERT(highbit < 32 && lowbit < 32 && highbit >= lowbit && (loc & 3) == 0);
-
- /* A 1<<32 == 1<<0 due to x86 SHL instruction, so skip if that is the case */
- if ((highbit-lowbit) != 31)
- mask = (((u32)1 << (highbit-lowbit+1))-1);
- else
- mask = (u32)0xFFFFFFFF;
-
- AmdPCIRead(loc, &temp);
- temp &= ~(mask << lowbit);
- temp |= (*pValue & mask) << lowbit;
- AmdPCIWrite(loc, &temp);
-}
-
-
-/*
- * Given a SBDFO this routine will find the next PCI capabilities list entry.
- * If the end of the list of reached, or if a problem is detected, then
- * ILLEGAL_SBDFO is returned.
- *
- * To start a new search from the beginning of head of the list, specify a
- * SBDFO with a offset of zero.
- */
-void CALLCONV AmdPCIFindNextCap(SBDFO *pCurrent)
-{
- SBDFO base;
- u32 offset;
- u32 temp;
-
- if (*pCurrent == ILLEGAL_SBDFO)
- return;
-
- offset = SBDFO_OFF(*pCurrent);
- base = *pCurrent - offset;
- *pCurrent = ILLEGAL_SBDFO;
-
- /* Verify that the SBDFO points to a valid PCI device SANITY CHECK */
- AmdPCIRead(base, &temp);
- if (temp == 0xFFFFFFFF)
- return; /* There is no device at this address */
-
- /* Verify that the device supports a capability list */
- AmdPCIReadBits(base + 0x04, 20, 20, &temp);
- if (temp == 0)
- return; /* This PCI device does not support capability lists */
-
- if (offset != 0)
- {
- /* If we are continuing on an existing list */
- AmdPCIReadBits(base + offset, 15, 8, &temp);
- }
- else
- {
- /* We are starting on a new list */
- AmdPCIReadBits(base + 0x34, 7, 0, &temp);
- }
-
- if (temp == 0)
- return; /* We have reached the end of the capabilties list */
-
- /* Error detection and recovery- The statement below protects against
- PCI devices with broken PCI capabilities lists. Detect a pointer
- that is not u32 aligned, points into the first 64 reserved DWORDs
- or points back to itself.
- */
- if (((temp & 3) != 0) || (temp == offset) || (temp < 0x40))
- return;
-
- *pCurrent = base + temp;
- return;
-}
-
-
-void CALLCONV Amdmemcpy(void *pDst, const void *pSrc, u32 length)
-{
- ASSERT(length <= 32768);
- ASSERT(pDst != NULL);
- ASSERT(pSrc != NULL);
-
- while (length--) {
- // *(((u8*)pDst)++) = *(((u8*)pSrc)++);
- *((u8*)pDst) = *((u8*)pSrc);
- pDst++;
- pSrc++;
- }
-}
-
-
-void CALLCONV Amdmemset(void *pBuf, u8 val, u32 length)
-{
- ASSERT(length <= 32768);
- ASSERT(pBuf != NULL);
-
- while (length--) {
- //*(((u8*)pBuf)++) = val;
- *(((u8*)pBuf)) = val;
- pBuf++;
- }
-}
-
-
-u8 CALLCONV AmdBitScanReverse(u32 value)
-{
- u8 i;
-
- for (i = 31; i != 0xFF; i--)
- {
- if (value & ((u32)1 << i))
- break;
- }
-
- return i;
-}
-
-
-u32 CALLCONV AmdRotateRight(u32 value, u8 size, u32 count)
-{
- u32 msb, mask;
- ASSERT(size > 0 && size <= 32);
-
- msb = (u32)1 << (size-1);
- mask = ((msb-1) << 1) + 1;
-
- value = value & mask;
-
- while (count--)
- {
- if (value & 1)
- value = (value >> 1) | msb;
- else
- value = value >> 1;
- }
-
- return value;
-}
-
-
-u32 CALLCONV AmdRotateLeft(u32 value, u8 size, u32 count)
-{
- u32 msb, mask;
- ASSERT(size > 0 && size <= 32);
-
- msb = (u32)1 << (size-1);
- mask = ((msb-1) << 1) + 1;
-
- value = value & mask;
-
- while (count--)
- {
- if (value & msb)
- value = ((value << 1) & mask) | (u32)1;
- else
- value = ((value << 1) & mask);
- }
-
- return value;
-}
-
-
-void CALLCONV AmdPCIRead(SBDFO loc, u32 *Value)
-{
- /* Use coreboot PCI functions */
- *Value = pci_read_config32((loc & 0xFFFFF000), SBDFO_OFF(loc));
-}
-
-
-void CALLCONV AmdPCIWrite(SBDFO loc, u32 *Value)
-{
- /* Use coreboot PCI functions */
- pci_write_config32((loc & 0xFFFFF000), SBDFO_OFF(loc), *Value);
-}
-
-
-void CALLCONV AmdMSRRead(uint32 Address, uint64 *Value)
-{
- msr_t msr;
-
- msr = rdmsr(Address);
- Value->lo = msr.lo;
- Value->hi = msr.hi;
-}
-
-
-void CALLCONV AmdMSRWrite(uint32 Address, uint64 *Value)
-{
- msr_t msr;
-
- msr.lo = Value->lo;
- msr.hi = Value->hi;
- wrmsr(Address, msr);
-}
diff --git a/src/northbridge/amd/amdht/comlib.h b/src/northbridge/amd/amdht/comlib.h
deleted file mode 100644
index 98326b280f..0000000000
--- a/src/northbridge/amd/amdht/comlib.h
+++ /dev/null
@@ -1,42 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef COMLIB_H
-#define COMLIB_H
-
-#include <assert.h>
-#include <stdint.h>
-#include <stdlib.h>
-#include "porting.h"
-
-#ifdef AMD_DEBUG_ERROR_STOP
- /* Macro to aid debugging, causes program to halt and display the line number of the halt */
- #define STOP_HERE ASSERT(0)
-#else
- #define STOP_HERE
-#endif
-
-void CALLCONV AmdPCIReadBits(SBDFO loc, uint8 highbit, uint8 lowbit, uint32 *value);
-void CALLCONV AmdPCIWriteBits(SBDFO loc, uint8 highbit, uint8 lowbit, uint32 *value);
-void CALLCONV AmdPCIFindNextCap(SBDFO *current);
-
-void CALLCONV Amdmemcpy(void *dst, const void *src, uint32 length);
-void CALLCONV Amdmemset(void *buf, uint8 val, uint32 length);
-
-uint8 CALLCONV AmdBitScanReverse(uint32 value);
-uint32 CALLCONV AmdRotateRight(uint32 value, uint8 size, uint32 count);
-uint32 CALLCONV AmdRotateLeft(uint32 value, uint8 size, uint32 count);
-
-#endif
diff --git a/src/northbridge/amd/amdht/h3ffeat.h b/src/northbridge/amd/amdht/h3ffeat.h
deleted file mode 100644
index 2cf4bd1a1c..0000000000
--- a/src/northbridge/amd/amdht/h3ffeat.h
+++ /dev/null
@@ -1,180 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-
-#ifndef H3FFEAT_H
-#define H3FFEAT_H
-
-#include "h3finit.h"
-
-/*----------------------------------------------------------------------------
- * Mixed (DEFINITIONS AND MACROS / TYPEDEFS, STRUCTURES, ENUMS)
- *
- *----------------------------------------------------------------------------
- */
-
-/*-----------------------------------------------------------------------------
- * DEFINITIONS AND MACROS
- *
- *-----------------------------------------------------------------------------
- */
-
-#define MAX_NODES 8
-#define MAX_LINKS 8
-#define MAX_PLATFORM_LINKS 64 /* 8x8 fully connected (28) + 4 chains with two HT devices */
-
-/* These following are internal definitions */
-#define ROUTETOSELF 0x0F
-#define INVALID_LINK 0xCC /* Used in port list data structure to mark unused data entries.
- Can also be used for no link found in a port list search */
-
-/* definitions for working with the port list structure */
-#define PORTLIST_TYPE_CPU 0
-#define PORTLIST_TYPE_IO 1
-
-/*
- * Hypertransport Capability definitions and macros
- *
- */
-
-/* HT Host Capability */
-/* bool isHTHostCapability(u32 reg) */
-#define IS_HT_HOST_CAPABILITY(reg) \
- ((reg & (u32)0xE00000FF) == (u32)0x20000008)
-
-#define HT_HOST_CAP_SIZE 0x20
-
-/* Host CapabilityRegisters */
-#define HTHOST_LINK_CAPABILITY_REG 0x00
-#define HTHOST_LINK_CONTROL_REG 0x04
-#define HTHOST_FREQ_REV_REG 0x08
-#define HTHOST_FREQ_REV_REG_2 0x1c
- #define HT_HOST_REV_REV3 0x60
-#define HTHOST_FEATURE_CAP_REG 0x0C
-#define HTHOST_BUFFER_COUNT_REG 0x10
-#define HTHOST_ISOC_REG 0x14
-#define HTHOST_LINK_TYPE_REG 0x18
- #define HTHOST_TYPE_COHERENT 3
- #define HTHOST_TYPE_NONCOHERENT 7
- #define HTHOST_TYPE_MASK 0x1F
-
-/* HT Slave Capability (HT1 compat) */
-#define IS_HT_SLAVE_CAPABILITY(reg) \
- ((reg & (u32)0xE00000FF) == (u32)0x00000008)
-#define HTSLAVE_LINK01_OFFSET 4
-#define HTSLAVE_LINK_CONTROL_0_REG 4
-#define HTSLAVE_FREQ_REV_0_REG 0xC
-#define HTSLAVE_FEATURE_CAP_REG 0x10
-
-/* HT3 gen Capability */
-#define IS_HT_GEN3_CAPABILITY(reg) \
- ((reg & (u32)0xF80000FF) == (u32)0xD0000008)
-#define HTGEN3_LINK01_OFFSET 0x10
-#define HTGEN3_LINK_TRAINING_0_REG 0x10
-
-/* HT3 Retry Capability */
-#define IS_HT_RETRY_CAPABILITY(reg) \
- ((reg & (u32)0xF80000FF) == (u32)0xC0000008)
-
-#define HTRETRY_CONTROL_REG 4
-
-/* Unit ID Clumping Capability */
-#define IS_HT_UNITID_CAPABILITY(reg) \
- ((reg & (u32)0xF80000FF) == (u32)0x90000008)
-
-#define HTUNIT_SUPPORT_REG 4
-#define HTUNIT_ENABLE_REG 8
-
-/*----------------------------------------------------------------------------
- * TYPEDEFS, STRUCTURES, ENUMS
- *
- *----------------------------------------------------------------------------
- */
-
-typedef struct cNorthBridge cNorthBridge;
-
-/* A pair consists of a source node, a link to the destination node, the
- * destination node, and its link back to source node. The even indices are
- * the source nodes and links, and the odd indices are for the destination
- * nodes and links.
- */
-typedef struct
-{
- /* This section is where the link is in the system and how to find it */
- u8 Type; /* 0 = CPU, 1 = Device, all others reserved */
- u8 Link; /* 0-1 for devices, 0-7 for CPUs */
- u8 NodeID; /* The node, or a pointer to the devices parent node */
- u8 HostLink, HostDepth; /* Link of parent node + depth in chain. Only used by devices */
- SBDFO Pointer; /* A pointer to the device's slave HT capability, so we don't have to keep searching */
-
- /* This section is for the final settings, which are written to hardware */
- BOOL SelRegang; /* Only used for CPU->CPU links */
- u8 SelWidthIn;
- u8 SelWidthOut;
- u8 SelFrequency;
- uint8_t enable_isochronous_mode;
-
- /* This section is for keeping track of capabilities and possible configurations */
- BOOL RegangCap;
- uint32_t PrvFrequencyCap;
- uint32_t PrvFeatureCap;
- u8 PrvWidthInCap;
- u8 PrvWidthOutCap;
- uint32_t CompositeFrequencyCap;
-
-} sPortDescriptor;
-
-
-/*
- * Our global state data structure
- */
-typedef struct {
- AMD_HTBLOCK *HtBlock;
-
- u8 NodesDiscovered; /* One less than the number of nodes found in the system */
- u8 TotalLinks;
- u8 sysMpCap; /* The maximum number of nodes that all processors are capable of */
-
- /* Two ports for each link
- * Note: The Port pair 2*N and 2*N+1 are connected together to form a link
- * (e.g. 0,1 and 8,9 are ports on either end of an HT link) The lower number
- * port (2*N) is the source port. The device that owns the source port is
- * always the device closer to the BSP. (i.e. nearer the CPU in a
- * non-coherent chain, or the CPU with the lower NodeID).
- */
- sPortDescriptor PortList[MAX_PLATFORM_LINKS*2];
-
- /* The number of coherent links coming off of each node (i.e. the 'Degree' of the node) */
- u8 sysDegree[MAX_NODES];
- /* The systems adjency (sysMatrix[i][j] is true if Node_i has a link to Node_j) */
- BOOL sysMatrix[MAX_NODES][MAX_NODES];
-
- /* Same as above, but for the currently selected database entry */
- u8 dbDegree[MAX_NODES];
- BOOL dbMatrix[MAX_NODES][MAX_NODES];
-
- u8 Perm[MAX_NODES]; /* The node mapping from the database to the system */
- u8 ReversePerm[MAX_NODES]; /* The node mapping from the system to the database */
-
- /* Data for non-coherent initialization */
- u8 AutoBusCurrent;
- u8 UsedCfgMapEntires;
-
- /* 'This' pointer for northbridge */
- cNorthBridge *nb;
-} sMainData;
-
-#endif /* H3FFEAT_H */
diff --git a/src/northbridge/amd/amdht/h3finit.c b/src/northbridge/amd/amdht/h3finit.c
deleted file mode 100644
index cda0a28cef..0000000000
--- a/src/northbridge/amd/amdht/h3finit.c
+++ /dev/null
@@ -1,1879 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/*
- *----------------------------------------------------------------------------
- * MODULES USED
- *
- *----------------------------------------------------------------------------
- */
-
-#include "h3finit.h"
-#include "h3ffeat.h"
-#include "h3ncmn.h"
-#include "h3gtopo.h"
-#include "AsPsNb.h"
-
-#include <arch/cpu.h>
-#include <device/pci.h>
-#include <device/pci_ops.h>
-#include <console/console.h>
-#include <cpu/x86/lapic_def.h>
-#include <cpu/amd/msr.h>
-#include <device/pci_def.h>
-#include <northbridge/amd/amdfam10/raminit.h>
-#include <northbridge/amd/amdfam10/amdfam10.h>
-#include <types.h>
-
-/*----------------------------------------------------------------------------
- * DEFINITIONS AND MACROS
- *
- *----------------------------------------------------------------------------
- */
-
-#define NVRAM_LIMIT_HT_SPEED_200 0x12
-#define NVRAM_LIMIT_HT_SPEED_300 0x11
-#define NVRAM_LIMIT_HT_SPEED_400 0x10
-#define NVRAM_LIMIT_HT_SPEED_500 0xf
-#define NVRAM_LIMIT_HT_SPEED_600 0xe
-#define NVRAM_LIMIT_HT_SPEED_800 0xd
-#define NVRAM_LIMIT_HT_SPEED_1000 0xc
-#define NVRAM_LIMIT_HT_SPEED_1200 0xb
-#define NVRAM_LIMIT_HT_SPEED_1400 0xa
-#define NVRAM_LIMIT_HT_SPEED_1600 0x9
-#define NVRAM_LIMIT_HT_SPEED_1800 0x8
-#define NVRAM_LIMIT_HT_SPEED_2000 0x7
-#define NVRAM_LIMIT_HT_SPEED_2200 0x6
-#define NVRAM_LIMIT_HT_SPEED_2400 0x5
-#define NVRAM_LIMIT_HT_SPEED_2600 0x4
-#define NVRAM_LIMIT_HT_SPEED_2800 0x3
-#define NVRAM_LIMIT_HT_SPEED_3000 0x2
-#define NVRAM_LIMIT_HT_SPEED_3200 0x1
-#define NVRAM_LIMIT_HT_SPEED_AUTO 0x0
-
-static const uint32_t ht_speed_limit[20] =
- {0xFFFFF, 0xFFFFF, 0x7FFFF, 0x3FFFF,
- 0x0FFFF, 0x07FFF, 0x03FFF, 0x01FFF,
- 0x00FFF, 0x007FF, 0x003FF, 0x001FF,
- 0x000FF, 0x0007F, 0x0003F, 0x0001F,
- 0x0000F, 0x00007, 0x00003, 0x00001};
-
-static const struct ht_speed_limit_map_t {
- uint16_t mhz;
- uint8_t nvram;
-} ht_speed_limit_map[] = {
- {0, NVRAM_LIMIT_HT_SPEED_AUTO},
- {200, NVRAM_LIMIT_HT_SPEED_200},
- {300, NVRAM_LIMIT_HT_SPEED_300},
- {400, NVRAM_LIMIT_HT_SPEED_400},
- {500, NVRAM_LIMIT_HT_SPEED_500},
- {600, NVRAM_LIMIT_HT_SPEED_600},
- {800, NVRAM_LIMIT_HT_SPEED_800},
- {1000, NVRAM_LIMIT_HT_SPEED_1000},
- {1200, NVRAM_LIMIT_HT_SPEED_1200},
- {1400, NVRAM_LIMIT_HT_SPEED_1400},
- {1600, NVRAM_LIMIT_HT_SPEED_1600},
- {1800, NVRAM_LIMIT_HT_SPEED_1800},
- {2000, NVRAM_LIMIT_HT_SPEED_2000},
- {2200, NVRAM_LIMIT_HT_SPEED_2200},
- {2400, NVRAM_LIMIT_HT_SPEED_2400},
- {2600, NVRAM_LIMIT_HT_SPEED_2600},
- {2800, NVRAM_LIMIT_HT_SPEED_2800},
- {3000, NVRAM_LIMIT_HT_SPEED_3000},
- {3200, NVRAM_LIMIT_HT_SPEED_3200},
-};
-
-static const uint32_t ht_speed_mhz_to_hw(uint16_t mhz)
-{
- size_t i;
- for (i = 0; i < ARRAY_SIZE(ht_speed_limit_map); i++)
- if (ht_speed_limit_map[i].mhz == mhz)
- return ht_speed_limit[ht_speed_limit_map[i].nvram];
-
- printk(BIOS_WARNING,
- "WARNING: Invalid HT link limit frequency %d specified, ignoring...\n",
- mhz);
- return ht_speed_limit[NVRAM_LIMIT_HT_SPEED_AUTO];
-}
-
-/*----------------------------------------------------------------------------
- * TYPEDEFS AND STRUCTURES
- *
- *----------------------------------------------------------------------------
- */
-
-/*----------------------------------------------------------------------------
- * PROTOTYPES OF LOCAL FUNCTIONS
- *
- *----------------------------------------------------------------------------
- */
-
-/*----------------------------------------------------------------------------
- * EXPORTED FUNCTIONS
- *
- *----------------------------------------------------------------------------
- */
-
-/*----------------------------------------------------------------------------
- * LOCAL FUNCTIONS
- *
- *----------------------------------------------------------------------------
- */
-#ifndef HT_BUILD_NC_ONLY
-/*
- **************************************************************************
- * Routing table decompressor
- **************************************************************************
- */
-
-/*
- **************************************************************************
- * Graph Support routines
- * These routines provide support for dealing with the graph representation
- * of the topologies, along with the routing table information for that topology.
- * The routing information is compressed and these routines currently decompress
- * 'on the fly'. A graph is represented as a set of routes. All the edges in the
- * graph are routes; a direct route from node i to node j exists in the graph IFF
- * there is an edge directly connecting node i to node j. All other routes designate
- * the edge which the route to that node initially takes, by designating a node
- * to which a direct connection exists. That is, the route to non-adjacent node j
- * from node i specifies node k where node i directly connects to node k.
- *
- *
- * pseudo definition of compressed graph:
- * typedef struct
- * {
- * BIT broadcast[8];
- * uint4 responseRoute;
- * uint4 requestRoute;
- * } sRoute;
- * typedef struct
- * {
- * u8 size;
- * sRoute graph[size][size];
- * } sGraph;
- *
- **************************************************************************
- */
-
-/*----------------------------------------------------------------------------------------
- * u8
- * graphHowManyNodes(u8 *graph)
- *
- * Description:
- * Returns the number of nodes in the compressed graph
- *
- * Parameters:
- * @param[in] graph = a compressed graph
- * @param[out] results = the number of nodes in the graph
- * ---------------------------------------------------------------------------------------
- */
-static u8 graphHowManyNodes(u8 *graph)
-{
- return graph[0];
-}
-
-/*----------------------------------------------------------------------------------------
- * BOOL
- * graphIsAdjacent(u8 *graph, u8 nodeA, u8 nodeB)
- *
- * Description:
- * Returns true if NodeA is directly connected to NodeB, false otherwise
- * (if NodeA == NodeB also returns false)
- * Relies on rule that directly connected nodes always route requests directly.
- *
- * Parameters:
- * @param[in] graph = the graph to examine
- * @param[in] nodeA = the node number of the first node
- * @param[in] nodeB = the node number of the second node
- * @param[out] results = true if nodeA connects to nodeB false if not
- * ---------------------------------------------------------------------------------------
- */
-static BOOL graphIsAdjacent(u8 *graph, u8 nodeA, u8 nodeB)
-{
- u8 size = graph[0];
- ASSERT(size <= MAX_NODES);
- ASSERT((nodeA < size) && (nodeB < size));
- return (graph[1+(nodeA*size+nodeB)*2+1] & 0x0F) == nodeB;
-}
-
-/*----------------------------------------------------------------------------------------
- * u8
- * graphGetRsp(u8 *graph, u8 nodeA, u8 nodeB)
- *
- * Description:
- * Returns the graph node used by nodeA to route responses targeted at nodeB.
- * This will be a node directly connected to nodeA (possibly nodeB itself),
- * or "Route to Self" if nodeA and nodeB are the same node.
- * Note that all node numbers are abstract node numbers of the topology graph,
- * it is the responsibility of the caller to apply any permutation needed.
- *
- * Parameters:
- * @param[in] u8 graph = the graph to examine
- * @param[in] u8 nodeA = the node number of the first node
- * @param[in] u8 nodeB = the node number of the second node
- * @param[out] u8 results = The response route node
- * ---------------------------------------------------------------------------------------
- */
-static u8 graphGetRsp(u8 *graph, u8 nodeA, u8 nodeB)
-{
- u8 size = graph[0];
- ASSERT(size <= MAX_NODES);
- ASSERT((nodeA < size) && (nodeB < size));
- return (graph[1+(nodeA*size+nodeB)*2+1] & 0xF0)>>4;
-}
-
-/*----------------------------------------------------------------------------------------
- * u8
- * graphGetReq(u8 *graph, u8 nodeA, u8 nodeB)
- *
- * Description:
- * Returns the graph node used by nodeA to route requests targeted at nodeB.
- * This will be a node directly connected to nodeA (possibly nodeB itself),
- * or "Route to Self" if nodeA and nodeB are the same node.
- * Note that all node numbers are abstract node numbers of the topology graph,
- * it is the responsibility of the caller to apply any permutation needed.
- *
- * Parameters:
- * @param[in] graph = the graph to examine
- * @param[in] nodeA = the node number of the first node
- * @param[in] nodeB = the node number of the second node
- * @param[out] results = The request route node
- * ---------------------------------------------------------------------------------------
- */
-static u8 graphGetReq(u8 *graph, u8 nodeA, u8 nodeB)
-{
- u8 size = graph[0];
- ASSERT(size <= MAX_NODES);
- ASSERT((nodeA < size) && (nodeB < size));
- return (graph[1+(nodeA*size+nodeB)*2+1] & 0x0F);
-}
-
-/*----------------------------------------------------------------------------------------
- * u8
- * graphGetBc(u8 *graph, u8 nodeA, u8 nodeB)
- *
- * Description:
- * Returns a bit vector of nodes that nodeA should forward a broadcast from
- * nodeB towards
- *
- * Parameters:
- * @param[in] graph = the graph to examine
- * @param[in] nodeA = the node number of the first node
- * @param[in] nodeB = the node number of the second node
- * OU results = the broadcast routes for nodeA from nodeB
- * ---------------------------------------------------------------------------------------
- */
-static u8 graphGetBc(u8 *graph, u8 nodeA, u8 nodeB)
-{
- u8 size = graph[0];
- ASSERT(size <= MAX_NODES);
- ASSERT((nodeA < size) && (nodeB < size));
- return graph[1+(nodeA*size+nodeB)*2];
-}
-
-
-/***************************************************************************
- *** GENERIC HYPERTRANSPORT DISCOVERY CODE ***
- ***************************************************************************/
-
-/*----------------------------------------------------------------------------------------
- * void
- * routeFromBSP(u8 targetNode, u8 actualTarget, sMainData *pDat)
- *
- * Description:
- * Ensure a request / response route from target node to bsp. Since target node is
- * always a predecessor of actual target node, each node gets a route to actual target
- * on the link that goes to target. The routing produced by this routine is adequate
- * for config access during discovery, but NOT for coherency.
- *
- * Parameters:
- * @param[in] u8 targetNode = the path to actual target goes through target
- * @param[in] u8 actualTarget = the ultimate target being routed to
- * @param[in] sMainData* pDat = our global state, port config info
- * ---------------------------------------------------------------------------------------
- */
-static void routeFromBSP(u8 targetNode, u8 actualTarget, sMainData *pDat)
-{
- u8 predecessorNode, predecessorLink, currentPair;
-
- if (targetNode == 0)
- return; /* BSP has no predecessor, stop */
-
- /* Search for the link that connects targetNode to its predecessor */
- currentPair = 0;
- while (pDat->PortList[currentPair*2+1].NodeID != targetNode)
- {
- currentPair++;
- ASSERT(currentPair < pDat->TotalLinks);
- }
-
- predecessorNode = pDat->PortList[currentPair*2].NodeID;
- predecessorLink = pDat->PortList[currentPair*2].Link;
-
- /* Recursively call self to ensure the route from the BSP to the Predecessor */
- /* Node is established */
- routeFromBSP(predecessorNode, actualTarget, pDat);
-
- pDat->nb->writeRoutingTable(predecessorNode, actualTarget, predecessorLink, pDat->nb);
-}
-
-/*---------------------------------------------------------------------------*/
-
-/**
- * u8
- * convertNodeToLink(u8 srcNode, u8 targetNode, sMainData *pDat)
- *
- * Description:
- * Return the link on source node which connects to target node
- *
- * Parameters:
- * @param[in] srcNode = the source node
- * @param[in] targetNode = the target node to find the link to
- * @param[in] pDat = our global state
- * @return the link on source which connects to target
- *
- */
-static u8 convertNodeToLink(u8 srcNode, u8 targetNode, sMainData *pDat)
-{
- u8 targetlink = INVALID_LINK;
- u8 k;
-
- for (k = 0; k < pDat->TotalLinks*2; k += 2)
- {
- if ((pDat->PortList[k+0].NodeID == srcNode) && (pDat->PortList[k+1].NodeID == targetNode))
- {
- targetlink = pDat->PortList[k+0].Link;
- break;
- }
- else if ((pDat->PortList[k+1].NodeID == srcNode) && (pDat->PortList[k+0].NodeID == targetNode))
- {
- targetlink = pDat->PortList[k+1].Link;
- break;
- }
- }
- ASSERT(targetlink != INVALID_LINK);
-
- return targetlink;
-}
-
-
-/*----------------------------------------------------------------------------------------
- * void
- * htDiscoveryFloodFill(sMainData *pDat)
- *
- * Description:
- * Discover all coherent devices in the system, initializing some basics like node IDs
- * and total nodes found in the process. As we go we also build a representation of the
- * discovered system which we will use later to program the routing tables. During this
- * step, the routing is via default link back to BSP and to each new node on the link it
- * was discovered on (no coherency is active yet).
- *
- * Parameters:
- * @param[in] sMainData* pDat = our global state
- * ---------------------------------------------------------------------------------------
- */
-static void htDiscoveryFloodFill(sMainData *pDat)
-{
- uint8_t currentNode = 0;
- uint8_t currentLink;
- uint8_t currentLinkID;
-
- /* NOTE
- * Each node inside a dual node (socket G34) processor must share
- * an adjacent node ID. Alter the link scan order such that the
- * other internal node is always scanned first...
- */
- uint8_t currentLinkScanOrder_Default[8] = {0, 1, 2, 3, 4, 5, 6, 7};
- uint8_t currentLinkScanOrder_G34_Fam10[8] = {1, 0, 2, 3, 4, 5, 6, 7};
- uint8_t currentLinkScanOrder_G34_Fam15[8] = {2, 0, 1, 3, 4, 5, 6, 7};
-
- uint8_t fam15h = 0;
- uint8_t rev_gte_d = 0;
- uint8_t dual_node = 0;
- uint32_t f3xe8;
- uint32_t family;
- uint32_t model;
-
- f3xe8 = pci_read_config32(NODE_PCI(0, 3), 0xe8);
-
- family = model = cpuid_eax(0x80000001);
- model = ((model & 0xf0000) >> 12) | ((model & 0xf0) >> 4);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f) {
- /* Family 15h or later */
- fam15h = 1;
- }
-
- if ((model >= 0x8) || fam15h)
- /* Revision D or later */
- rev_gte_d = 1;
-
- if (rev_gte_d)
- /* Check for dual node capability */
- if (f3xe8 & 0x20000000)
- dual_node = 1;
-
- /* Entries are always added in pairs, the even indices are the 'source'
- * side closest to the BSP, the odd indices are the 'destination' side
- */
- while (currentNode <= pDat->NodesDiscovered)
- {
- u32 temp;
-
- if (currentNode != 0)
- {
- /* Set path from BSP to currentNode */
- routeFromBSP(currentNode, currentNode, pDat);
-
- /* Set path from BSP to currentNode for currentNode+1 if
- * currentNode+1 != MAX_NODES
- */
- if (currentNode+1 != MAX_NODES)
- routeFromBSP(currentNode, currentNode+1, pDat);
-
- /* Configure currentNode to route traffic to the BSP through its
- * default link
- */
- pDat->nb->writeRoutingTable(currentNode, 0, pDat->nb->readDefLnk(currentNode, pDat->nb), pDat->nb);
- }
-
- /* Set currentNode's NodeID field to currentNode */
- pDat->nb->writeNodeID(currentNode, currentNode, pDat->nb);
-
- /* Enable routing tables on currentNode */
- pDat->nb->enableRoutingTables(currentNode, pDat->nb);
-
- for (currentLinkID = 0; currentLinkID < pDat->nb->maxLinks; currentLinkID++)
- {
- BOOL linkfound;
- u8 token;
-
- if (currentLinkID < 8) {
- if (dual_node) {
- if (fam15h)
- currentLink = currentLinkScanOrder_G34_Fam15[currentLinkID];
- else
- currentLink = currentLinkScanOrder_G34_Fam10[currentLinkID];
- } else {
- currentLink = currentLinkScanOrder_Default[currentLinkID];
- }
- } else {
- currentLink = currentLinkID;
- }
-
- if (pDat->HtBlock->AMD_CB_IgnoreLink && pDat->HtBlock->AMD_CB_IgnoreLink(currentNode, currentLink))
- continue;
-
- if (pDat->nb->readTrueLinkFailStatus(currentNode, currentLink, pDat, pDat->nb))
- continue;
-
- /* Make sure that the link is connected, coherent, and ready */
- if (!pDat->nb->verifyLinkIsCoherent(currentNode, currentLink, pDat->nb))
- continue;
-
-
- /* Test to see if the currentLink has already been explored */
- linkfound = FALSE;
- for (temp = 0; temp < pDat->TotalLinks; temp++)
- {
- if ((pDat->PortList[temp*2+1].NodeID == currentNode) &&
- (pDat->PortList[temp*2+1].Link == currentLink))
- {
- linkfound = TRUE;
- break;
- }
- }
- if (linkfound)
- {
- /* We had already expored this link */
- continue;
- }
-
- if (pDat->nb->handleSpecialLinkCase(currentNode, currentLink, pDat, pDat->nb))
- {
- continue;
- }
-
- /* Modify currentNode's routing table to use currentLink to send
- * traffic to currentNode+1
- */
- pDat->nb->writeRoutingTable(currentNode, currentNode+1, currentLink, pDat->nb);
-
- /* Check the northbridge of the node we just found, to make sure it is compatible
- * before doing anything else to it.
- */
- if (!pDat->nb->isCompatible(currentNode+1, pDat->nb))
- {
- u8 nodeToKill;
-
- /* Notify BIOS of event (while variables are still the same) */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventCohFamilyFeud evt;
- evt.eSize = sizeof(sHtEventCohFamilyFeud);
- evt.node = currentNode;
- evt.link = currentLink;
- evt.totalNodes = pDat->NodesDiscovered;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_ERROR,
- HT_EVENT_COH_FAMILY_FEUD,
- (u8 *)&evt);
- }
-
- /* If node is not compatible, force boot to 1P
- * If they are not compatible stop cHT init and:
- * 1. Disable all cHT links on the BSP
- * 2. Configure the BSP routing tables as a UP.
- * 3. Notify main BIOS.
- */
- pDat->NodesDiscovered = 0;
- currentNode = 0;
- pDat->TotalLinks = 0;
- /* Abandon our coherent link data structure. At this point there may
- * be coherent links on the BSP that are not yet in the portList, and
- * we have to turn them off anyway. So depend on the hardware to tell us.
- */
- for (currentLink = 0; currentLink < pDat->nb->maxLinks; currentLink++)
- {
- /* Stop all links which are connected, coherent, and ready */
- if (pDat->nb->verifyLinkIsCoherent(currentNode, currentLink, pDat->nb))
- pDat->nb->stopLink(currentNode, currentLink, pDat->nb);
- }
-
- for (nodeToKill = 0; nodeToKill < pDat->nb->maxNodes; nodeToKill++)
- {
- pDat->nb->writeFullRoutingTable(0, nodeToKill, ROUTETOSELF, ROUTETOSELF, 0, pDat->nb);
- }
-
- /* End Coherent Discovery */
- STOP_HERE;
- break;
- }
-
- /* Read token from Current+1 */
- token = pDat->nb->readToken(currentNode+1, pDat->nb);
- ASSERT(token <= pDat->NodesDiscovered);
- if (token == 0)
- {
- pDat->NodesDiscovered++;
- ASSERT(pDat->NodesDiscovered < pDat->nb->maxNodes);
- /* Check the capability of northbridges against the currently known configuration */
- if (!pDat->nb->isCapable(currentNode+1, pDat, pDat->nb))
- {
- u8 nodeToKill;
-
- /* Notify BIOS of event */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventCohMpCapMismatch evt;
- evt.eSize = sizeof(sHtEventCohMpCapMismatch);
- evt.node = currentNode;
- evt.link = currentLink;
- evt.sysMpCap = pDat->sysMpCap;
- evt.totalNodes = pDat->NodesDiscovered;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_ERROR,
- HT_EVENT_COH_MPCAP_MISMATCH,
- (u8 *)&evt);
- }
-
- pDat->NodesDiscovered = 0;
- currentNode = 0;
- pDat->TotalLinks = 0;
-
- for (nodeToKill = 0; nodeToKill < pDat->nb->maxNodes; nodeToKill++)
- {
- pDat->nb->writeFullRoutingTable(0, nodeToKill, ROUTETOSELF, ROUTETOSELF, 0, pDat->nb);
- }
-
- /* End Coherent Discovery */
- STOP_HERE;
- break;
- }
-
- token = pDat->NodesDiscovered;
- pDat->nb->writeToken(currentNode+1, token, pDat->nb);
- /* Inform that we have discovered a node, so that logical id to
- * socket mapping info can be recorded.
- */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventCohNodeDiscovered evt;
- evt.eSize = sizeof(sHtEventCohNodeDiscovered);
- evt.node = currentNode;
- evt.link = currentLink;
- evt.newNode = token;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_INFO,
- HT_EVENT_COH_NODE_DISCOVERED,
- (u8 *)&evt);
- }
- }
-
- if (pDat->TotalLinks == MAX_PLATFORM_LINKS)
- {
- /*
- * Exceeded our capacity to describe all coherent links found in the system.
- * Error strategy:
- * Auto recovery is not possible because data space is already all used.
- * If the callback is not implemented or returns we will continue to initialize
- * the fabric we are capable of representing, adding no more nodes or links.
- * This should yield a bootable topology, but likely not the one intended.
- * We cannot continue discovery, there may not be any way to route a new
- * node back to the BSP if we can't add links to our representation of the system.
- */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventCohLinkExceed evt;
- evt.eSize = sizeof(sHtEventCohLinkExceed);
- evt.node = currentNode;
- evt.link = currentLink;
- evt.targetNode = token;
- evt.totalNodes = pDat->NodesDiscovered;
- evt.maxLinks = pDat->nb->maxLinks;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_ERROR,
- HT_EVENT_COH_LINK_EXCEED,
- (u8 *)&evt);
- }
- /* Force link and node loops to halt */
- STOP_HERE;
- currentNode = pDat->NodesDiscovered;
- break;
- }
-
- pDat->PortList[pDat->TotalLinks*2].Type = PORTLIST_TYPE_CPU;
- pDat->PortList[pDat->TotalLinks*2].Link = currentLink;
- pDat->PortList[pDat->TotalLinks*2].NodeID = currentNode;
-
- pDat->PortList[pDat->TotalLinks*2+1].Type = PORTLIST_TYPE_CPU;
- pDat->PortList[pDat->TotalLinks*2+1].Link = pDat->nb->readDefLnk(currentNode+1, pDat->nb);
- pDat->PortList[pDat->TotalLinks*2+1].NodeID = token;
-
- pDat->TotalLinks++;
-
- if (!pDat->sysMatrix[currentNode][token])
- {
- pDat->sysDegree[currentNode]++;
- pDat->sysDegree[token]++;
- pDat->sysMatrix[currentNode][token] = TRUE;
- pDat->sysMatrix[token][currentNode] = TRUE;
- }
- }
- currentNode++;
- }
-}
-
-
-/***************************************************************************
- *** ISOMORPHISM BASED ROUTING TABLE GENERATION CODE ***
- ***************************************************************************/
-
-/*----------------------------------------------------------------------------------------
- * BOOL
- * isoMorph(u8 i, sMainData *pDat)
- *
- * Description:
- * Is graphA isomorphic to graphB?
- * if this function returns true, then Perm will contain the permutation
- * required to transform graphB into graphA.
- * We also use the degree of each node, that is the number of connections it has, to
- * speed up rejection of non-isomorphic graphs (if there is a node in graphA with n
- * connections, there must be at least one unmatched in graphB with n connections).
- *
- * Parameters:
- * @param[in] u8 i = the discovered node which we are trying to match
- * with a permutation the topology
- * @param[in]/@param[out] sMainData* pDat = our global state, degree and adjacency matrix,
- * output a permutation if successful
- * @param[out] BOOL results = the graphs are (or are not) isomorphic
- * ---------------------------------------------------------------------------------------
- */
-static BOOL isoMorph(u8 i, sMainData *pDat)
-{
- u8 j, k;
- u8 nodecnt;
-
- /* We have only been called if nodecnt == pSelected->size ! */
- nodecnt = pDat->NodesDiscovered+1;
-
- if (i != nodecnt)
- {
- /* Keep building the permutation */
- for (j = 0; j < nodecnt; j++)
- {
- /* Make sure the degree matches */
- if (pDat->sysDegree[i] != pDat->dbDegree[j])
- continue;
-
- /* Make sure that j hasn't been used yet (ought to use a "used" */
- /* array instead, might be faster) */
- for (k = 0; k < i; k++)
- {
- if (pDat->Perm[k] == j)
- break;
- }
- if (k != i)
- continue;
- pDat->Perm[i] = j;
- if (isoMorph(i+1, pDat))
- return TRUE;
- }
- return FALSE;
- } else {
- /* Test to see if the permutation is isomorphic */
- for (j = 0; j < nodecnt; j++)
- {
- for (k = 0; k < nodecnt; k++)
- {
- if (pDat->sysMatrix[j][k] !=
- pDat->dbMatrix[pDat->Perm[j]][pDat->Perm[k]])
- return FALSE;
- }
- }
- return TRUE;
- }
-}
-
-
-/*----------------------------------------------------------------------------------------
- * void
- * lookupComputeAndLoadRoutingTables(sMainData *pDat)
- *
- * Description:
- * Using the description of the fabric topology we discovered, try to find a match
- * among the supported topologies. A supported topology description matches
- * the discovered fabric if the nodes can be matched in such a way that all the nodes connected
- * in one set are exactly the nodes connected in the other (formally, that the graphs are
- * isomorphic). Which links are used is not really important to matching. If the graphs
- * match, then there is a permutation of one that translates the node positions and linkages
- * to the other.
- *
- * In order to make the isomorphism test efficient, we test for matched number of nodes
- * (a 4 node fabric is not isomorphic to a 2 node topology), and provide degrees of nodes
- * to the isomorphism test.
- *
- * The generic routing table solution for any topology is predetermined and represented
- * as part of the topology. The permutation we computed tells us how to interpret the
- * routing onto the fabric we discovered. We do this working backward from the last
- * node discovered to the BSP, writing the routing tables as we go.
- *
- * Parameters:
- * @param[in] sMainData* pDat = our global state, the discovered fabric,
- * @param[out] degree matrix, permutation
- * ---------------------------------------------------------------------------------------
- */
-static void lookupComputeAndLoadRoutingTables(sMainData *pDat)
-{
- u8 **pTopologyList;
- u8 *pSelected;
-
- int i, j, k, size;
-
- size = pDat->NodesDiscovered + 1;
- /* Use the provided topology list or the internal, default one. */
- pTopologyList = pDat->HtBlock->topolist;
- if (pTopologyList == NULL)
- {
- getAmdTopolist(&pTopologyList);
- }
-
- pSelected = *pTopologyList;
- while (pSelected != NULL)
- {
- if (graphHowManyNodes(pSelected) == size)
- {
- /* Build Degree vector and Adjency Matrix for this entry */
- for (i = 0; i < size; i++)
- {
- pDat->dbDegree[i] = 0;
- for (j = 0; j < size; j++)
- {
- if (graphIsAdjacent(pSelected, i, j))
- {
- pDat->dbMatrix[i][j] = 1;
- pDat->dbDegree[i]++;
- }
- else
- {
- pDat->dbMatrix[i][j] = 0;
- }
- }
- }
- if (isoMorph(0, pDat))
- break; /* A matching topology was found */
- }
-
- pTopologyList++;
- pSelected = *pTopologyList;
- }
-
- if (pSelected != NULL)
- {
- /* Compute the reverse Permutation */
- for (i = 0; i < size; i++)
- {
- pDat->ReversePerm[pDat->Perm[i]] = i;
- }
-
- /* Start with the last discovered node, and move towards the BSP */
- for (i = size-1; i >= 0; i--)
- {
- for (j = 0; j < size; j++)
- {
- u8 ReqTargetLink, RspTargetLink;
- u8 ReqTargetNode, RspTargetNode;
-
- u8 AbstractBcTargetNodes = graphGetBc(pSelected, pDat->Perm[i], pDat->Perm[j]);
- u32 BcTargetLinks = 0;
-
- for (k = 0; k < MAX_NODES; k++)
- {
- if (AbstractBcTargetNodes & ((u32)1<<k))
- {
- BcTargetLinks |= (u32)1 << convertNodeToLink(i, pDat->ReversePerm[k], pDat);
- }
- }
-
- if (i == j)
- {
- ReqTargetLink = ROUTETOSELF;
- RspTargetLink = ROUTETOSELF;
- }
- else
- {
- ReqTargetNode = graphGetReq(pSelected, pDat->Perm[i], pDat->Perm[j]);
- ReqTargetLink = convertNodeToLink(i, pDat->ReversePerm[ReqTargetNode], pDat);
-
- RspTargetNode = graphGetRsp(pSelected, pDat->Perm[i], pDat->Perm[j]);
- RspTargetLink = convertNodeToLink(i, pDat->ReversePerm[RspTargetNode], pDat);
- }
-
- pDat->nb->writeFullRoutingTable(i, j, ReqTargetLink, RspTargetLink, BcTargetLinks, pDat->nb);
- }
- /* Clean up discovery 'footprint' that otherwise remains in the routing table. It didn't hurt
- * anything, but might cause confusion during debug and validation. Do this by setting the
- * route back to all self routes. Since it's the node that would be one more than actually installed,
- * this only applies if less than maxNodes were found.
- */
- if (size < pDat->nb->maxNodes)
- {
- pDat->nb->writeFullRoutingTable(i, size, ROUTETOSELF, ROUTETOSELF, 0, pDat->nb);
- }
- }
-
- }
- else
- {
- /*
- * No Matching Topology was found
- * Error Strategy:
- * Auto recovery doesn't seem likely, Force boot as 1P.
- * For reporting, logging, provide number of nodes
- * If not implemented or returns, boot as BSP uniprocessor.
- */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventCohNoTopology evt;
- evt.eSize = sizeof(sHtEventCohNoTopology);
- evt.totalNodes = pDat->NodesDiscovered;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_ERROR,
- HT_EVENT_COH_NO_TOPOLOGY,
- (u8 *)&evt);
- }
- STOP_HERE;
- /* Force 1P */
- pDat->NodesDiscovered = 0;
- pDat->TotalLinks = 0;
- pDat->nb->enableRoutingTables(0, pDat->nb);
- }
-}
-#endif /* HT_BUILD_NC_ONLY */
-
-
-/*----------------------------------------------------------------------------------------
- * void
- * finializeCoherentInit(sMainData *pDat)
- *
- * Description:
- * Find the total number of cores and update the number of nodes and cores in all cpus.
- * Limit CPU config access to installed cpus.
- *
- * Parameters:
- * @param[in] sMainData* pDat = our global state, number of nodes discovered.
- * ---------------------------------------------------------------------------------------
- */
-static void finializeCoherentInit(sMainData *pDat)
-{
- u8 curNode;
-
- u8 totalCores = 0;
- for (curNode = 0; curNode < pDat->NodesDiscovered+1; curNode++)
- {
- totalCores += pDat->nb->getNumCoresOnNode(curNode, pDat->nb);
- }
-
- for (curNode = 0; curNode < pDat->NodesDiscovered+1; curNode++)
- {
- pDat->nb->setTotalNodesAndCores(curNode, pDat->NodesDiscovered+1, totalCores, pDat->nb);
- }
-
- for (curNode = 0; curNode < pDat->NodesDiscovered+1; curNode++)
- {
- pDat->nb->limitNodes(curNode, pDat->nb);
- }
-
-}
-
-/*----------------------------------------------------------------------------------------
- * void
- * coherentInit(sMainData *pDat)
- *
- * Description:
- * Perform discovery and initialization of the coherent fabric.
- *
- * Parameters:
- * @param[in] sMainData* pDat = our global state
- * ---------------------------------------------------------------------------------------
- */
-static void coherentInit(sMainData *pDat)
-{
-#ifdef HT_BUILD_NC_ONLY
- /* Replace discovery process with:
- * No other nodes, no coherent links
- * Enable routing tables on currentNode, for power on self route
- */
- pDat->NodesDiscovered = 0;
- pDat->TotalLinks = 0;
- pDat->nb->enableRoutingTables(0, pDat->nb);
-#else
- u8 i, j;
-
- pDat->NodesDiscovered = 0;
- pDat->TotalLinks = 0;
- for (i = 0; i < MAX_NODES; i++)
- {
- pDat->sysDegree[i] = 0;
- for (j = 0; j < MAX_NODES; j++)
- {
- pDat->sysMatrix[i][j] = 0;
- }
- }
-
- htDiscoveryFloodFill(pDat);
- lookupComputeAndLoadRoutingTables(pDat);
-#endif
- finializeCoherentInit(pDat);
-}
-
-/***************************************************************************
- *** Non-coherent init code ***
- *** Algorithms ***
- ***************************************************************************/
-/*----------------------------------------------------------------------------------------
- * void
- * processLink(u8 node, u8 link, sMainData *pDat)
- *
- * Description:
- * Process a non-coherent link, enabling a range of bus numbers, and setting the device
- * ID for all devices found
- *
- * Parameters:
- * @param[in] u8 node = Node on which to process nc init
- * @param[in] u8 link = The non-coherent link on that node
- * @param[in] sMainData* pDat = our global state
- * ---------------------------------------------------------------------------------------
- */
-static void processLink(u8 node, u8 link, sMainData *pDat)
-{
- u8 secBus, subBus;
- u32 currentBUID;
- u32 temp;
- u32 unitIDcnt;
- SBDFO currentPtr;
- u8 depth;
- const u8 *pSwapPtr;
-
- SBDFO lastSBDFO = ILLEGAL_SBDFO;
- u8 lastLink = 0;
-
- ASSERT(node < pDat->nb->maxNodes && link < pDat->nb->maxLinks);
-
- if ((pDat->HtBlock->AMD_CB_OverrideBusNumbers == NULL)
- || !pDat->HtBlock->AMD_CB_OverrideBusNumbers(node, link, &secBus, &subBus))
- {
- /* Assign Bus numbers */
- if (pDat->AutoBusCurrent >= pDat->HtBlock->AutoBusMax)
- {
- /* If we run out of Bus Numbers notify, if call back unimplemented or if it
- * returns, skip this chain
- */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHTEventNcohBusMaxExceed evt;
- evt.eSize = sizeof(sHTEventNcohBusMaxExceed);
- evt.node = node;
- evt.link = link;
- evt.bus = pDat->AutoBusCurrent;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_ERROR,HT_EVENT_NCOH_BUS_MAX_EXCEED,(u8 *)&evt);
- }
- STOP_HERE;
- return;
- }
-
- if (pDat->UsedCfgMapEntires >= 4)
- {
- /* If we have used all the PCI Config maps we can't add another chain.
- * Notify and if call back is unimplemented or returns, skip this chain.
- */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventNcohCfgMapExceed evt;
- evt.eSize = sizeof(sHtEventNcohCfgMapExceed);
- evt.node = node;
- evt.link = link;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_ERROR,
- HT_EVENT_NCOH_CFG_MAP_EXCEED,
- (u8 *)&evt);
- }
- STOP_HERE;
- return;
- }
-
- secBus = pDat->AutoBusCurrent;
- subBus = secBus + pDat->HtBlock->AutoBusIncrement-1;
- pDat->AutoBusCurrent += pDat->HtBlock->AutoBusIncrement;
- }
-
- pDat->nb->setCFGAddrMap(pDat->UsedCfgMapEntires, secBus, subBus, node, link, pDat, pDat->nb);
- pDat->UsedCfgMapEntires++;
-
- if ((pDat->HtBlock->AMD_CB_ManualBUIDSwapList != NULL)
- && pDat->HtBlock->AMD_CB_ManualBUIDSwapList(node, link, &pSwapPtr))
- {
- /* Manual non-coherent BUID assignment */
- currentBUID = 1;
-
- /* Assign BUID's per manual override */
- while (*pSwapPtr != 0xFF)
- {
- currentPtr = MAKE_SBDFO(0, secBus, *pSwapPtr, 0, 0);
- pSwapPtr++;
-
- do
- {
- AmdPCIFindNextCap(&currentPtr);
- ASSERT(currentPtr != ILLEGAL_SBDFO);
- AmdPCIRead(currentPtr, &temp);
- } while (!IS_HT_SLAVE_CAPABILITY(temp));
-
- currentBUID = *pSwapPtr;
- pSwapPtr++;
- AmdPCIWriteBits(currentPtr, 20, 16, &currentBUID);
- }
-
- /* Build chain of devices */
- depth = 0;
- pSwapPtr++;
- while (*pSwapPtr != 0xFF)
- {
- pDat->PortList[pDat->TotalLinks*2].NodeID = node;
- if (depth == 0)
- {
- pDat->PortList[pDat->TotalLinks*2].Type = PORTLIST_TYPE_CPU;
- pDat->PortList[pDat->TotalLinks*2].Link = link;
- }
- else
- {
- pDat->PortList[pDat->TotalLinks*2].Type = PORTLIST_TYPE_IO;
- pDat->PortList[pDat->TotalLinks*2].Link = 1-lastLink;
- pDat->PortList[pDat->TotalLinks*2].HostLink = link;
- pDat->PortList[pDat->TotalLinks*2].HostDepth = depth-1;
- pDat->PortList[pDat->TotalLinks*2].Pointer = lastSBDFO;
- }
-
- pDat->PortList[pDat->TotalLinks*2+1].Type = PORTLIST_TYPE_IO;
- pDat->PortList[pDat->TotalLinks*2+1].NodeID = node;
- pDat->PortList[pDat->TotalLinks*2+1].HostLink = link;
- pDat->PortList[pDat->TotalLinks*2+1].HostDepth = depth;
-
- currentPtr = MAKE_SBDFO(0, secBus, (*pSwapPtr & 0x3F), 0, 0);
- do
- {
- AmdPCIFindNextCap(&currentPtr);
- ASSERT(currentPtr != ILLEGAL_SBDFO);
- AmdPCIRead(currentPtr, &temp);
- } while (!IS_HT_SLAVE_CAPABILITY(temp));
- pDat->PortList[pDat->TotalLinks*2+1].Pointer = currentPtr;
- lastSBDFO = currentPtr;
-
- /* Bit 6 indicates whether orientation override is desired.
- * Bit 7 indicates the upstream link if overriding.
- */
- /* assert catches at least the one known incorrect setting */
- ASSERT ((*pSwapPtr & 0x40) || (!(*pSwapPtr & 0x80)));
- if (*pSwapPtr & 0x40)
- {
- /* Override the device's orientation */
- lastLink = *pSwapPtr >> 7;
- }
- else
- {
- /* Detect the device's orientation */
- AmdPCIReadBits(currentPtr, 26, 26, &temp);
- lastLink = (u8)temp;
- }
- pDat->PortList[pDat->TotalLinks*2+1].Link = lastLink;
-
- depth++;
- pDat->TotalLinks++;
- pSwapPtr++;
- }
- }
- else
- {
- /* Automatic non-coherent device detection */
- depth = 0;
- currentBUID = 1;
- while (1)
- {
- currentPtr = MAKE_SBDFO(0, secBus, 0, 0, 0);
-
- AmdPCIRead(currentPtr, &temp);
- if (temp == 0xFFFFFFFF)
- /* No device found at currentPtr */
- break;
-
- if (pDat->TotalLinks == MAX_PLATFORM_LINKS)
- {
- /*
- * Exceeded our capacity to describe all non-coherent links found in the system.
- * Error strategy:
- * Auto recovery is not possible because data space is already all used.
- */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventNcohLinkExceed evt;
- evt.eSize = sizeof(sHtEventNcohLinkExceed);
- evt.node = node;
- evt.link = link;
- evt.depth = depth;
- evt.maxLinks = pDat->nb->maxLinks;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_ERROR,
- HT_EVENT_NCOH_LINK_EXCEED,
- (u8 *)&evt);
- }
- /* Force link loop to halt */
- STOP_HERE;
- break;
- }
-
- pDat->PortList[pDat->TotalLinks*2].NodeID = node;
- if (depth == 0)
- {
- pDat->PortList[pDat->TotalLinks*2].Type = PORTLIST_TYPE_CPU;
- pDat->PortList[pDat->TotalLinks*2].Link = link;
- }
- else
- {
- pDat->PortList[pDat->TotalLinks*2].Type = PORTLIST_TYPE_IO;
- pDat->PortList[pDat->TotalLinks*2].Link = 1-lastLink;
- pDat->PortList[pDat->TotalLinks*2].HostLink = link;
- pDat->PortList[pDat->TotalLinks*2].HostDepth = depth-1;
- pDat->PortList[pDat->TotalLinks*2].Pointer = lastSBDFO;
- }
-
- pDat->PortList[pDat->TotalLinks*2+1].Type = PORTLIST_TYPE_IO;
- pDat->PortList[pDat->TotalLinks*2+1].NodeID = node;
- pDat->PortList[pDat->TotalLinks*2+1].HostLink = link;
- pDat->PortList[pDat->TotalLinks*2+1].HostDepth = depth;
-
- do
- {
- AmdPCIFindNextCap(&currentPtr);
- ASSERT(currentPtr != ILLEGAL_SBDFO);
- AmdPCIRead(currentPtr, &temp);
- } while (!IS_HT_SLAVE_CAPABILITY(temp));
-
- AmdPCIReadBits(currentPtr, 25, 21, &unitIDcnt);
- if ((unitIDcnt + currentBUID > 31) || ((secBus == 0) && (unitIDcnt + currentBUID > 24)))
- {
- /* An error handler for the case where we run out of BUID's on a chain */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventNcohBuidExceed evt;
- evt.eSize = sizeof(sHtEventNcohBuidExceed);
- evt.node = node;
- evt.link = link;
- evt.depth = depth;
- evt.currentBUID = (uint8)currentBUID;
- evt.unitCount = (uint8)unitIDcnt;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_ERROR,HT_EVENT_NCOH_BUID_EXCEED,(u8 *)&evt);
- }
- STOP_HERE;
- break;
- }
- AmdPCIWriteBits(currentPtr, 20, 16, &currentBUID);
-
-
- currentPtr += MAKE_SBDFO(0, 0, currentBUID, 0, 0);
- AmdPCIReadBits(currentPtr, 20, 16, &temp);
- if (temp != currentBUID)
- {
- /* An error handler for this critical error */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventNcohDeviceFailed evt;
- evt.eSize = sizeof(sHtEventNcohDeviceFailed);
- evt.node = node;
- evt.link = link;
- evt.depth = depth;
- evt.attemptedBUID = (uint8)currentBUID;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_ERROR,HT_EVENT_NCOH_DEVICE_FAILED,(u8 *)&evt);
- }
- STOP_HERE;
- break;
- }
-
- AmdPCIReadBits(currentPtr, 26, 26, &temp);
- pDat->PortList[pDat->TotalLinks*2+1].Link = (u8)temp;
- pDat->PortList[pDat->TotalLinks*2+1].Pointer = currentPtr;
-
- lastLink = (u8)temp;
- lastSBDFO = currentPtr;
-
- depth++;
- pDat->TotalLinks++;
- currentBUID += unitIDcnt;
- }
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- /* Provide information on automatic device results */
- sHtEventNcohAutoDepth evt;
- evt.eSize = sizeof(sHtEventNcohAutoDepth);
- evt.node = node;
- evt.link = link;
- evt.depth = (depth - 1);
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_INFO,HT_EVENT_NCOH_AUTO_DEPTH,(u8 *)&evt);
- }
- }
-}
-
-
-/*----------------------------------------------------------------------------------------
- * void
- * ncInit(sMainData *pDat)
- *
- * Description:
- * Initialize the non-coherent fabric. Begin with the compat link on the BSP, then
- * find and initialize all other non-coherent chains.
- *
- * Parameters:
- * @param[in] sMainData* pDat = our global state
- * ---------------------------------------------------------------------------------------
- */
-static void ncInit(sMainData *pDat)
-{
- u8 node, link;
- u8 compatLink;
-
- compatLink = pDat->nb->readSbLink(pDat->nb);
- processLink(0, compatLink, pDat);
-
- for (node = 0; node <= pDat->NodesDiscovered; node++)
- {
- for (link = 0; link < pDat->nb->maxLinks; link++)
- {
- if (pDat->HtBlock->AMD_CB_IgnoreLink && pDat->HtBlock->AMD_CB_IgnoreLink(node, link))
- continue; /* Skip the link */
-
- if (node == 0 && link == compatLink)
- continue;
-
- if (pDat->nb->readTrueLinkFailStatus(node, link, pDat, pDat->nb))
- continue;
-
- if (pDat->nb->verifyLinkIsNonCoherent(node, link, pDat->nb))
- processLink(node, link, pDat);
- }
- }
-}
-
-/***************************************************************************
- *** Link Optimization ***
- ***************************************************************************/
-
-/*----------------------------------------------------------------------------------------
- * void
- * regangLinks(sMainData *pDat)
- *
- * Description:
- * Test the sublinks of a link to see if they qualify to be reganged. If they do,
- * update the port list data to indicate that this should be done. Note that no
- * actual hardware state is changed in this routine.
- *
- * Parameters:
- * @param[in,out] sMainData* pDat = our global state
- * ---------------------------------------------------------------------------------------
- */
-static void regangLinks(sMainData *pDat)
-{
-#ifndef HT_BUILD_NC_ONLY
- u8 i, j;
- for (i = 0; i < pDat->TotalLinks*2; i += 2)
- {
- ASSERT(pDat->PortList[i].Type < 2 && pDat->PortList[i].Link < pDat->nb->maxLinks); /* Data validation */
- ASSERT(pDat->PortList[i+1].Type < 2 && pDat->PortList[i+1].Link < pDat->nb->maxLinks); /* data validation */
- ASSERT(!(pDat->PortList[i].Type == PORTLIST_TYPE_IO && pDat->PortList[i+1].Type == PORTLIST_TYPE_CPU)); /* ensure src is closer to the bsp than dst */
-
- /* Regang is false unless we pass all conditions below */
- pDat->PortList[i].SelRegang = FALSE;
- pDat->PortList[i+1].SelRegang = FALSE;
-
- if ((pDat->PortList[i].Type != PORTLIST_TYPE_CPU) || (pDat->PortList[i+1].Type != PORTLIST_TYPE_CPU))
- continue; /* Only process CPU to CPU links */
-
- for (j = i+2; j < pDat->TotalLinks*2; j += 2)
- {
- if ((pDat->PortList[j].Type != PORTLIST_TYPE_CPU) || (pDat->PortList[j+1].Type != PORTLIST_TYPE_CPU))
- continue; /* Only process CPU to CPU links */
-
- if (pDat->PortList[i].NodeID != pDat->PortList[j].NodeID)
- continue; /* Links must be from the same source */
-
- if (pDat->PortList[i+1].NodeID != pDat->PortList[j+1].NodeID)
- continue; /* Link must be to the same target */
-
- if ((pDat->PortList[i].Link & 3) != (pDat->PortList[j].Link & 3))
- continue; /* Ensure same source base port */
-
- if ((pDat->PortList[i+1].Link & 3) != (pDat->PortList[j+1].Link & 3))
- continue; /* Ensure same destination base port */
-
- if ((pDat->PortList[i].Link & 4) != (pDat->PortList[i+1].Link & 4))
- continue; /* Ensure sublink0 routes to sublink0 */
-
- ASSERT((pDat->PortList[j].Link & 4) == (pDat->PortList[j+1].Link & 4)); /* (therefore sublink1 routes to sublink1) */
-
- if (pDat->HtBlock->AMD_CB_SkipRegang &&
- pDat->HtBlock->AMD_CB_SkipRegang(pDat->PortList[i].NodeID,
- pDat->PortList[i].Link & 0x03,
- pDat->PortList[i+1].NodeID,
- pDat->PortList[i+1].Link & 0x03))
- {
- continue; /* Skip regang */
- }
-
-
- pDat->PortList[i].Link &= 0x03; /* Force to point to sublink0 */
- pDat->PortList[i+1].Link &= 0x03;
- pDat->PortList[i].SelRegang = TRUE; /* Enable link reganging */
- pDat->PortList[i+1].SelRegang = TRUE;
- pDat->PortList[i].PrvWidthOutCap = HT_WIDTH_16_BITS;
- pDat->PortList[i+1].PrvWidthOutCap = HT_WIDTH_16_BITS;
- pDat->PortList[i].PrvWidthInCap = HT_WIDTH_16_BITS;
- pDat->PortList[i+1].PrvWidthInCap = HT_WIDTH_16_BITS;
-
- /* Delete PortList[j, j+1], slow but easy to debug implementation */
- pDat->TotalLinks--;
- Amdmemcpy(&(pDat->PortList[j]), &(pDat->PortList[j+2]), sizeof(sPortDescriptor)*(pDat->TotalLinks*2-j));
- Amdmemset(&(pDat->PortList[pDat->TotalLinks*2]), INVALID_LINK, sizeof(sPortDescriptor)*2);
-
- /* //High performance, but would make debuging harder due to 'shuffling' of the records */
- /* //Amdmemcpy(PortList[TotalPorts-2], PortList[j], SIZEOF(sPortDescriptor)*2); */
- /* //TotalPorts -=2; */
-
- break; /* Exit loop, advance to PortList[i+2] */
- }
- }
-#endif /* HT_BUILD_NC_ONLY */
-}
-
-static void detectIoLinkIsochronousCapable(sMainData *pDat)
-{
- uint8_t i;
- unsigned char iommu;
- uint8_t isochronous_capable = 0;
-
- iommu = 1;
- get_option(&iommu, "iommu");
-
- for (i = 0; i < pDat->TotalLinks*2; i += 2) {
- if ((pDat->PortList[i].Type == PORTLIST_TYPE_CPU) && (pDat->PortList[i+1].Type == PORTLIST_TYPE_IO)) {
- if ((pDat->PortList[i].PrvFeatureCap & 0x1) && (pDat->PortList[i+1].PrvFeatureCap & 0x1)) {
- pDat->PortList[i].enable_isochronous_mode = 1;
- pDat->PortList[i+1].enable_isochronous_mode = 1;
- isochronous_capable = 1;
- } else {
- pDat->PortList[i].enable_isochronous_mode = 0;
- pDat->PortList[i+1].enable_isochronous_mode = 0;
- }
- }
- }
-
- if (isochronous_capable && iommu) {
- printk(BIOS_DEBUG, "Forcing HT links to isochronous mode due to enabled IOMMU\n");
- /* Isochronous mode must be set on all links if the IOMMU is enabled */
- for (i = 0; i < pDat->TotalLinks*2; i += 2) {
- pDat->PortList[i].enable_isochronous_mode = 1;
- pDat->PortList[i+1].enable_isochronous_mode = 1;
- }
- }
-}
-
-/*----------------------------------------------------------------------------------------
- * void
- * selectOptimalWidthAndFrequency(sMainData *pDat)
- *
- * Description:
- * For all links:
- * Examine both sides of a link and determine the optimal frequency and width,
- * taking into account externally provided limits and enforcing any other limit
- * or matching rules as applicable except sublink balancing. Update the port
- * list date with the optimal settings.
- * Note no hardware state changes in this routine.
- *
- * Parameters:
- * @param[in,out] sMainData* pDat = our global state, port list data
- * ---------------------------------------------------------------------------------------
- */
-static void selectOptimalWidthAndFrequency(sMainData *pDat)
-{
- u8 i, j;
- uint32_t temp;
- uint32_t cbPCBFreqLimit;
- uint32_t cbPCBFreqLimit_NVRAM;
- u8 cbPCBABDownstreamWidth;
- u8 cbPCBBAUpstreamWidth;
-
- cbPCBFreqLimit_NVRAM = 0xfffff;
- if (get_option(&temp, "hypertransport_speed_limit") == CB_SUCCESS)
- cbPCBFreqLimit_NVRAM = ht_speed_limit[temp & 0xf];
-
- if (!is_fam15h()) {
- /* FIXME
- * By default limit frequency to 2.6 GHz as there are residual
- * problems with HT v3.1 implementation on at least some Socket G34
- * mainboards / Fam10h CPUs.
- * Debug the issues and reenable this...
- */
- if (cbPCBFreqLimit_NVRAM > 0xffff)
- cbPCBFreqLimit_NVRAM = 0xffff;
- }
-
- for (i = 0; i < pDat->TotalLinks*2; i += 2)
- {
- cbPCBFreqLimit = 0xfffff; // Maximum allowed by autoconfiguration
- if (pDat->HtBlock->ht_link_configuration)
- cbPCBFreqLimit = ht_speed_mhz_to_hw(pDat->HtBlock->ht_link_configuration->ht_speed_limit);
- cbPCBFreqLimit = min(cbPCBFreqLimit, cbPCBFreqLimit_NVRAM);
-
-#if CONFIG(LIMIT_HT_DOWN_WIDTH_8)
- cbPCBABDownstreamWidth = 8;
-#else
- cbPCBABDownstreamWidth = 16;
-#endif
-
-#if CONFIG(LIMIT_HT_UP_WIDTH_8)
- cbPCBBAUpstreamWidth = 8;
-#else
- cbPCBBAUpstreamWidth = 16;
-#endif
-
- if ((pDat->PortList[i].Type == PORTLIST_TYPE_CPU) && (pDat->PortList[i+1].Type == PORTLIST_TYPE_CPU))
- {
- if (pDat->HtBlock->AMD_CB_Cpu2CpuPCBLimits)
- {
- pDat->HtBlock->AMD_CB_Cpu2CpuPCBLimits(
- pDat->PortList[i].NodeID,
- pDat->PortList[i].Link,
- pDat->PortList[i+1].NodeID,
- pDat->PortList[i+1].Link,
- &cbPCBABDownstreamWidth,
- &cbPCBBAUpstreamWidth, &cbPCBFreqLimit
- );
- }
- }
- else
- {
- if (pDat->HtBlock->AMD_CB_IOPCBLimits)
- {
- pDat->HtBlock->AMD_CB_IOPCBLimits(
- pDat->PortList[i+1].NodeID,
- pDat->PortList[i+1].HostLink,
- pDat->PortList[i+1].HostDepth,
- &cbPCBABDownstreamWidth,
- &cbPCBBAUpstreamWidth, &cbPCBFreqLimit
- );
- }
- }
-
- temp = pDat->PortList[i].PrvFrequencyCap;
- temp &= pDat->PortList[i+1].PrvFrequencyCap;
- temp &= cbPCBFreqLimit;
- pDat->PortList[i].CompositeFrequencyCap = temp;
- pDat->PortList[i+1].CompositeFrequencyCap = temp;
-
- ASSERT (temp != 0);
- for (j = 19;; j--)
- {
- if ((j == 16) || (j == 15))
- continue;
- if (temp & ((uint32_t)1 << j))
- break;
- }
-
- pDat->PortList[i].SelFrequency = j;
- pDat->PortList[i+1].SelFrequency = j;
-
- temp = pDat->PortList[i].PrvWidthOutCap;
- if (pDat->PortList[i+1].PrvWidthInCap < temp)
- temp = pDat->PortList[i+1].PrvWidthInCap;
- if (cbPCBABDownstreamWidth < temp)
- temp = cbPCBABDownstreamWidth;
- pDat->PortList[i].SelWidthOut = (u8)temp;
- pDat->PortList[i+1].SelWidthIn = (u8)temp;
-
- temp = pDat->PortList[i].PrvWidthInCap;
- if (pDat->PortList[i+1].PrvWidthOutCap < temp)
- temp = pDat->PortList[i+1].PrvWidthOutCap;
- if (cbPCBBAUpstreamWidth < temp)
- temp = cbPCBBAUpstreamWidth;
- pDat->PortList[i].SelWidthIn = (u8)temp;
- pDat->PortList[i+1].SelWidthOut = (u8)temp;
- }
-}
-
-/*----------------------------------------------------------------------------------------
- * void
- * hammerSublinkFixup(sMainData *pDat)
- *
- * Description:
- * Iterate through all links, checking the frequency of each sublink pair. Make the
- * adjustment to the port list data so that the frequencies are at a valid ratio,
- * reducing frequency as needed to achieve this. (All links support the minimum 200 MHz
- * frequency.) Repeat the above until no adjustments are needed.
- * Note no hardware state changes in this routine.
- *
- * Parameters:
- * @param[in,out] sMainData* pDat = our global state, link state and port list
- * ---------------------------------------------------------------------------------------
- */
-static void hammerSublinkFixup(sMainData *pDat)
-{
-#ifndef HT_BUILD_NC_ONLY
- u8 i, j, k;
- BOOL changes, downgrade;
-
- u8 hiIndex;
- u8 hiFreq, loFreq;
-
- u32 temp;
-
- do
- {
- changes = FALSE;
- for (i = 0; i < pDat->TotalLinks*2; i++)
- {
- if (pDat->PortList[i].Type != PORTLIST_TYPE_CPU) /* Must be a CPU link */
- continue;
- if (pDat->PortList[i].Link < 4) /* Only look for sublink1's */
- continue;
-
- for (j = 0; j < pDat->TotalLinks*2; j++)
- {
- /* Step 1. Find the matching sublink0 */
- if (pDat->PortList[j].Type != PORTLIST_TYPE_CPU)
- continue;
- if (pDat->PortList[j].NodeID != pDat->PortList[i].NodeID)
- continue;
- if (pDat->PortList[j].Link != (pDat->PortList[i].Link & 0x03))
- continue;
-
- /* Step 2. Check for an illegal frequency ratio */
- if (pDat->PortList[i].SelFrequency >= pDat->PortList[j].SelFrequency)
- {
- hiIndex = i;
- hiFreq = pDat->PortList[i].SelFrequency;
- loFreq = pDat->PortList[j].SelFrequency;
- }
- else
- {
- hiIndex = j;
- hiFreq = pDat->PortList[j].SelFrequency;
- loFreq = pDat->PortList[i].SelFrequency;
- }
-
- if (hiFreq == loFreq)
- break; /* The frequencies are 1:1, no need to do anything */
-
- downgrade = FALSE;
-
- if (hiFreq == 13)
- {
- if ((loFreq != 7) && /* {13, 7} 2400MHz / 1200MHz 2:1 */
- (loFreq != 4) && /* {13, 4} 2400MHz / 600MHz 4:1 */
- (loFreq != 2)) /* {13, 2} 2400MHz / 400MHz 6:1 */
- downgrade = TRUE;
- }
- else if (hiFreq == 11)
- {
- if ((loFreq != 6)) /* {11, 6} 2000MHz / 1000MHz 2:1 */
- downgrade = TRUE;
- }
- else if (hiFreq == 9)
- {
- if ((loFreq != 5) && /* { 9, 5} 1600MHz / 800MHz 2:1 */
- (loFreq != 2) && /* { 9, 2} 1600MHz / 400MHz 4:1 */
- (loFreq != 0)) /* { 9, 0} 1600MHz / 200MHz 8:1 */
- downgrade = TRUE;
- }
- else if (hiFreq == 7)
- {
- if ((loFreq != 4) && /* { 7, 4} 1200MHz / 600MHz 2:1 */
- (loFreq != 0)) /* { 7, 0} 1200MHz / 200MHz 6:1 */
- downgrade = TRUE;
- }
- else if (hiFreq == 5)
- {
- if ((loFreq != 2) && /* { 5, 2} 800MHz / 400MHz 2:1 */
- (loFreq != 0)) /* { 5, 0} 800MHz / 200MHz 4:1 */
- downgrade = TRUE;
- }
- else if (hiFreq == 2)
- {
- if ((loFreq != 0)) /* { 2, 0} 400MHz / 200MHz 2:1 */
- downgrade = TRUE;
- }
- else
- {
- downgrade = TRUE; /* no legal ratios for hiFreq */
- }
-
- /* Step 3. Downgrade the higher of the two frequencies, and set nochanges to FALSE */
- if (downgrade)
- {
- /* Although the problem was with the port specified by hiIndex, we need to */
- /* downgrade both ends of the link. */
- hiIndex = hiIndex & 0xFE; /* Select the 'upstream' (i.e. even) port */
-
- temp = pDat->PortList[hiIndex].CompositeFrequencyCap;
-
- /* Remove hiFreq from the list of valid frequencies */
- temp = temp & ~((uint32)1 << hiFreq);
- ASSERT (temp != 0);
- pDat->PortList[hiIndex].CompositeFrequencyCap = temp;
- pDat->PortList[hiIndex+1].CompositeFrequencyCap = temp;
-
- for (k = 19;; k--)
- {
- if ((j == 16) || (j == 15))
- continue;
- if (temp & ((uint32_t)1 << k))
- break;
- }
-
- pDat->PortList[hiIndex].SelFrequency = k;
- pDat->PortList[hiIndex+1].SelFrequency = k;
-
- changes = TRUE;
- }
- }
- }
- } while (changes); /* Repeat until a valid configuration is reached */
-#endif /* HT_BUILD_NC_ONLY */
-}
-
-/*----------------------------------------------------------------------------------------
- * void
- * linkOptimization(sMainData *pDat)
- *
- * Description:
- * Based on link capabilities, apply optimization rules to come up with the real best
- * settings, including several external limit decision from call backs. This includes
- * handling of sublinks. Finally, after the port list data is updated, set the hardware
- * state for all links.
- *
- * Parameters:
- * @param[in] sMainData* pDat = our global state
- * ---------------------------------------------------------------------------------------
- */
-static void linkOptimization(sMainData *pDat)
-{
- pDat->nb->gatherLinkData(pDat, pDat->nb);
- regangLinks(pDat);
- if (is_fam15h())
- detectIoLinkIsochronousCapable(pDat);
- selectOptimalWidthAndFrequency(pDat);
- hammerSublinkFixup(pDat);
- pDat->nb->setLinkData(pDat, pDat->nb);
-}
-
-
-/*----------------------------------------------------------------------------------------
- * void
- * trafficDistribution(sMainData *pDat)
- *
- * Description:
- * In the case of a two node system with both sublinks used, enable the traffic
- * distribution feature.
- *
- * Parameters:
- * @param[in] sMainData* pDat = our global state, port list data
- * ---------------------------------------------------------------------------------------
- */
-static void trafficDistribution(sMainData *pDat)
-{
-#ifndef HT_BUILD_NC_ONLY
- u32 links01, links10;
- u8 linkCount;
- u8 i;
-
- /* Traffic Distribution is only used when there are exactly two nodes in the system */
- if (pDat->NodesDiscovered+1 != 2)
- return;
-
- links01 = 0;
- links10 = 0;
- linkCount = 0;
- for (i = 0; i < pDat->TotalLinks*2; i += 2)
- {
- if ((pDat->PortList[i].Type == PORTLIST_TYPE_CPU) && (pDat->PortList[i+1].Type == PORTLIST_TYPE_CPU))
- {
- links01 |= (u32)1 << pDat->PortList[i].Link;
- links10 |= (u32)1 << pDat->PortList[i+1].Link;
- linkCount++;
- }
- }
- ASSERT(linkCount != 0);
- if (linkCount == 1)
- return; /* Don't setup Traffic Distribution if only one link is being used */
-
- pDat->nb->writeTrafficDistribution(links01, links10, pDat->nb);
-#endif /* HT_BUILD_NC_ONLY */
-}
-
-/*----------------------------------------------------------------------------------------
- * void
- * tuning(sMainData *pDat)
- *
- * Description:
- * Handle system and performance tunings, such as traffic distribution, fifo and
- * buffer tuning, and special config tunings.
- *
- * Parameters:
- * @param[in] sMainData* pDat = our global state, port list data
- * ---------------------------------------------------------------------------------------
- */
-static void tuning(sMainData *pDat)
-{
- u8 i;
-
- /* See if traffic distribution can be done and do it if so
- * or allow system specific customization
- */
- if ((pDat->HtBlock->AMD_CB_CustomizeTrafficDistribution == NULL)
- || !pDat->HtBlock->AMD_CB_CustomizeTrafficDistribution())
- {
- trafficDistribution(pDat);
- }
-
- /* For each node, invoke northbridge specific buffer tunings or
- * system specific customizations.
- */
- for (i = 0; i < pDat->NodesDiscovered + 1; i++)
- {
- if ((pDat->HtBlock->AMD_CB_CustomizeBuffers == NULL)
- || !pDat->HtBlock->AMD_CB_CustomizeBuffers(i))
- {
- pDat->nb->bufferOptimizations(i, pDat, pDat->nb);
- }
- }
-}
-
-/*----------------------------------------------------------------------------------------
- * BOOL
- * isSanityCheckOk()
- *
- * Description:
- * Perform any general sanity checks which should prevent HT from running if they fail.
- * Currently only the "Must run on BSP only" check.
- *
- * Parameters:
- * @param[out] result BOOL = true if check is ok, false if it failed
- * ---------------------------------------------------------------------------------------
- */
-static BOOL isSanityCheckOk(void)
-{
- uint64 qValue;
-
- AmdMSRRead(LAPIC_BASE_MSR, &qValue);
-
- return ((qValue.lo & LAPIC_BASE_MSR_BOOTSTRAP_PROCESSOR) != 0);
-}
-
-/***************************************************************************
- *** HT Initialize ***
- ***************************************************************************/
-
-/*----------------------------------------------------------------------------------------
- * void
- * htInitialize(AMD_HTBLOCK *pBlock)
- *
- * Description:
- * This is the top level external interface for Hypertransport Initialization.
- * Create our initial internal state, initialize the coherent fabric,
- * initialize the non-coherent chains, and perform any required fabric tuning or
- * optimization.
- *
- * Parameters:
- * @param[in] AMD_HTBLOCK* pBlock = Our Initial State including possible
- * topologies and routings, non coherent bus
- * assignment info, and actual
- * wrapper or OEM call back routines.
- * ---------------------------------------------------------------------------------------
- */
-void amdHtInitialize(AMD_HTBLOCK *pBlock)
-{
- sMainData pDat;
- cNorthBridge nb;
-
- if (isSanityCheckOk())
- {
- newNorthBridge(0, &nb);
-
- pDat.HtBlock = pBlock;
- pDat.nb = &nb;
- pDat.sysMpCap = nb.maxNodes;
- nb.isCapable(0, &pDat, pDat.nb);
- coherentInit(&pDat);
-
- pDat.AutoBusCurrent = pBlock->AutoBusStart;
- pDat.UsedCfgMapEntires = 0;
- ncInit(&pDat);
- linkOptimization(&pDat);
- tuning(&pDat);
- }
-}
diff --git a/src/northbridge/amd/amdht/h3finit.h b/src/northbridge/amd/amdht/h3finit.h
deleted file mode 100644
index 743ae97065..0000000000
--- a/src/northbridge/amd/amdht/h3finit.h
+++ /dev/null
@@ -1,620 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef H3FINIT_H
-#define H3FINIT_H
-
-#include "comlib.h"
-
-/*----------------------------------------------------------------------------
- * Mixed (DEFINITIONS AND MACROS / TYPEDEFS, STRUCTURES, ENUMS)
- *
- *----------------------------------------------------------------------------
- */
-
-/*-----------------------------------------------------------------------------
- * DEFINITIONS AND MACROS
- *
- *-----------------------------------------------------------------------------
- */
-
-/* Width equates for call backs */
-#define HT_WIDTH_8_BITS 8
-#define HT_WIDTH_16_BITS 16
-#define HT_WIDTH_4_BITS 4
-#define HT_WIDTH_2_BITS 2
-
-/* Frequency equates for call backs which take an actual frequency setting */
-#define HT_FREQUENCY_200M 0
-#define HT_FREQUENCY_400M 2
-#define HT_FREQUENCY_600M 4
-#define HT_FREQUENCY_800M 5
-#define HT_FREQUENCY_1000M 6
-#define HT_FREQUENCY_1200M 7
-#define HT_FREQUENCY_1400M 8
-#define HT_FREQUENCY_1600M 9
-#define HT_FREQUENCY_1800M 10
-#define HT_FREQUENCY_2000M 11
-#define HT_FREQUENCY_2200M 12
-#define HT_FREQUENCY_2400M 13
-#define HT_FREQUENCY_2600M 14
-#define HT_FREQUENCY_2800M 17
-#define HT_FREQUENCY_3000M 18
-#define HT_FREQUENCY_3200M 19
-
-/* Frequency Limit equates for call backs which take a frequency supported mask. */
-#define HT_FREQUENCY_LIMIT_200M 1
-#define HT_FREQUENCY_LIMIT_400M 7
-#define HT_FREQUENCY_LIMIT_600M 0x1F
-#define HT_FREQUENCY_LIMIT_800M 0x3F
-#define HT_FREQUENCY_LIMIT_1000M 0x7F
-#define HT_FREQUENCY_LIMIT_HT1_ONLY 0x7F
-#define HT_FREQUENCY_LIMIT_1200M 0xFF
-#define HT_FREQUENCY_LIMIT_1400M 0x1FF
-#define HT_FREQUENCY_LIMIT_1600M 0x3FF
-#define HT_FREQUENCY_LIMIT_1800M 0x7FF
-#define HT_FREQUENCY_LIMIT_2000M 0xFFF
-#define HT_FREQUENCY_LIMIT_2200M 0x1FFF
-#define HT_FREQUENCY_LIMIT_2400M 0x3FFF
-#define HT_FREQUENCY_LIMIT_2600M 0x7FFF
-#define HT_FREQUENCY_LIMIT_2800M 0x3FFFF
-#define HT_FREQUENCY_LIMIT_3000M 0x7FFFF
-#define HT_FREQUENCY_LIMIT_3200M 0xFFFFF
-
-/*
- * Event Notify definitions
- */
-
-/* Event Class definitions */
-#define HT_EVENT_CLASS_CRITICAL 1
-#define HT_EVENT_CLASS_ERROR 2
-#define HT_EVENT_CLASS_HW_FAULT 3
-#define HT_EVENT_CLASS_WARNING 4
-#define HT_EVENT_CLASS_INFO 5
-
-/* Event definitions. */
-
-/* Coherent subfunction events */
-#define HT_EVENT_COH_EVENTS 0x1000
-#define HT_EVENT_COH_NO_TOPOLOGY 0x1001
-#define HT_EVENT_COH_LINK_EXCEED 0x1002
-#define HT_EVENT_COH_FAMILY_FEUD 0x1003
-#define HT_EVENT_COH_NODE_DISCOVERED 0x1004
-#define HT_EVENT_COH_MPCAP_MISMATCH 0x1005
-
-/* Non-coherent subfunction events */
-#define HT_EVENT_NCOH_EVENTS 0x2000
-#define HT_EVENT_NCOH_BUID_EXCEED 0x2001
-#define HT_EVENT_NCOH_LINK_EXCEED 0x2002
-#define HT_EVENT_NCOH_BUS_MAX_EXCEED 0x2003
-#define HT_EVENT_NCOH_CFG_MAP_EXCEED 0x2004
-#define HT_EVENT_NCOH_DEVICE_FAILED 0x2005
-#define HT_EVENT_NCOH_AUTO_DEPTH 0x2006
-
-/* Optimization subfunction events */
-#define HT_EVENT_OPT_EVENTS 0x3000
-#define HT_EVENT_OPT_REQUIRED_CAP_RETRY 0x3001
-#define HT_EVENT_OPT_REQUIRED_CAP_GEN3 0x3002
-
-/* HW Fault events */
-#define HT_EVENT_HW_EVENTS 0x4000
-#define HT_EVENT_HW_SYNCHFLOOD 0x4001
-#define HT_EVENT_HW_HTCRC 0x4002
-
-/* The bbHT component (hb*) uses 0x5000 for events.
- * For consistency, we avoid that range here.
- */
-
-/*----------------------------------------------------------------------------
- * TYPEDEFS, STRUCTURES, ENUMS
- *
- *----------------------------------------------------------------------------
- */
-
-typedef struct {
- u8 **topolist;
- u8 AutoBusStart;
- /* Note: This should always be the form AutoBusCurrent+N*AutoBusIncrement, also bus 253-255 are reserved */
- u8 AutoBusMax;
- u8 AutoBusIncrement;
-
- /**----------------------------------------------------------------------------------------
- *
- * BOOL
- * AMD_CB_IgnoreLink(u8 Node, u8 Link)
- *
- * Description:
- * This routine is called every time a coherent link is found and then every
- * time a non-coherent link from a CPU is found.
- * Any coherent or non-coherent link from a CPU can be ignored and not used
- * for discovery or initialization. Useful for connection based systems.
- * (Note: not called for IO device to IO Device links.)
- *
- * Parameters:
- * @param[in] u8 node = The node on which this link is located
- * @param[in] u8 link = The link about to be initialized
- * @param[out] BOOL result = true to ignore this link and skip it
- * false to initialize the link normally
- *
- * ---------------------------------------------------------------------------------------
- */
- BOOL (*AMD_CB_IgnoreLink)(u8 Node, u8 Link);
-
- /**----------------------------------------------------------------------------------------
- *
- * BOOL
- * AMD_CB_OverrideBusNumbers(u8 Node, u8 Link, u8 *SecBus, u8 *SubBus)
- *
- * Description:
- * This routine is called every time a non-coherent chain is processed.
- * If a system can not use the auto Bus numbering feature for non-coherent chain bus
- * assignments, this routine can provide explicit control. For each chain, provide
- * the bus number range to use.
- *
- * Parameters:
- * @param[in] u8 node = The node on which this chain is located
- * @param[in] u8 link = The link on the host for this chain
- * @param[out] u8 secBus = Secondary Bus number for this non-coherent chain
- * @param[out] u8 *subBus = Subordinate Bus number
- * @param[out] BOOL result = true this routine is supplying the bus numbers
- * false use auto Bus numbering
- *
- * ---------------------------------------------------------------------------------------
- */
- BOOL (*AMD_CB_OverrideBusNumbers)(u8 Node, u8 Link, u8 *SecBus, u8 *SubBus);
-
- /**----------------------------------------------------------------------------------------
- *
- * BOOL
- * AMD_CB_ManualBUIDSwapList(u8 Node, u8 Link, u8 **List)
- *
- * Description:
- * This routine is called every time a non-coherent chain is processed.
- * BUID assignment may be controlled explicitly on a non-coherent chain. Provide a
- * swap list. The first part of the list controls the BUID assignment and the
- * second part of the list provides the device to device linking. Device orientation
- * can be detected automatically, or explicitly. See documentation for more details.
- *
- * Automatic non-coherent init assigns BUIDs starting at 1 and incrementing sequentially
- * based on each device's unit count.
- *
- * Parameters:
- * @param[in] u8 node = The node on which this chain is located
- * @param[in] u8 link = The link on the host for this chain
- * @param[out] u8 **list = supply a pointer to a list
- * @param[out] BOOL result = true to use a manual list
- * false to initialize the link automatically
- *
- * ---------------------------------------------------------------------------------------
- */
- BOOL (*AMD_CB_ManualBUIDSwapList)(u8 Node, u8 Link, const u8 **List);
-
- /**----------------------------------------------------------------------------------------
- *
- * void
- * AMD_CB_DeviceCapOverride(u8 HostNode, u8 HostLink, u8 Depth, u8 Segment,
- * u8 Bus, u8 Dev, u32 DevVenID, u8 Link,
- * u8 *LinkWidthIn, u8 *LinkWidthOut, u16 *FreqCap)
- *
- * Description:
- * This routine is called once for every link on every IO device.
- * Update the width and frequency capability if needed for this device.
- * This is used along with device capabilities, the limit call backs, and northbridge
- * limits to compute the default settings. The components of the device's PCI config
- * address are provided, so its settings can be consulted if need be. The input width
- * and frequency are the reported device capabilities.
- *
- * Parameters:
- * @param[in] u8 hostNode = The node on which this chain is located
- * @param[in] u8 hostLink = The link on the host for this chain
- * @param[in] u8 Depth = The depth in the I/O chain from the Host
- * @param[in] u8 Segment = The Device's PCI Bus Segment number
- * @param[in] u8 Bus = The Device's PCI Bus number
- * @param[in] u8 Dev = The Device's PCI device Number
- * @param[in] u32 DevVenID = The Device's PCI Vendor + Device ID (offset 0x00)
- * @param[in] u8 Link = The Device's link number (0 or 1)
- * @param[in,out] u8 *LinkWidthIn = modify to change the Link Witdh In
- * @param[in,out] u8 *LinkWidthOut = modify to change the Link Witdh Out
- * @param[in,out] u32 *FreqCap = modify to change the link's frequency capability
- * @param[in,out] u32 *FeatureCap = modify to change the link's feature capability
- *
- * ---------------------------------------------------------------------------------------
- */
- void (*AMD_CB_DeviceCapOverride)(
- u8 HostNode,
- u8 HostLink,
- u8 Depth,
- u8 Segment,
- u8 Bus,
- u8 Dev,
- u32 DevVenID,
- u8 Link,
- u8 *LinkWidthIn,
- u8 *LinkWidthOut,
- u32 *FreqCap,
- u32 *FeatureCap
- );
-
- /**----------------------------------------------------------------------------------------
- *
- * void
- * AMD_CB_Cpu2CpuPCBLimits(u8 NodeA, u8 LinkA, u8 NodeB, u8 LinkB,
- * u8 *ABLinkWidthLimit, u8 *BALinkWidthLimit, u16 *PCBFreqCap)
- *
- * Description:
- * For each coherent connection this routine is called once.
- * Update the frequency and width if needed for this link (usually based on board
- * restriction). This is used with CPU device capabilities and northbridge limits
- * to compute the default settings. The input width and frequency are valid, but do
- * not necessarily reflect the minimum setting that will be chosen.
- *
- * Parameters:
- * @param[in] u8 nodeA = One node on which this link is located
- * @param[in] u8 linkA = The link on this node
- * @param[in] u8 nodeB = The other node on which this link is located
- * @param[in] u8 linkB = The link on that node
- * @param[in,out] u8 *ABLinkWidthLimit = modify to change the Link Witdh In
- * @param[in,out] u8 *BALinkWidthLimit = modify to change the Link Witdh Out
- * @param[in,out] u32 *PCBFreqCap = modify to change the link's frequency capability
- *
- * ---------------------------------------------------------------------------------------
- */
- void (*AMD_CB_Cpu2CpuPCBLimits)(
- u8 NodeA,
- u8 LinkA,
- u8 NodeB,
- u8 LinkB,
- u8 *ABLinkWidthLimit,
- u8 *BALinkWidthLimit,
- u32 *PCBFreqCap
- );
-
- /**----------------------------------------------------------------------------------------
- *
- * void
- * AMD_CB_IOPCBLimits(u8 HostNode, u8 HostLink, u8 Depth, u8 *DownstreamLinkWidthLimit,
- * u8 *UpstreamLinkWidthLimit, u16 *PCBFreqCap)
- *
- * Description:
- * For each non-coherent connection this routine is called once.
- * Update the frequency and width if needed for this link (usually based on board
- * restriction). This is used with device capabilities, device overrides, and northbridge limits
- * to compute the default settings. The input width and frequency are valid, but do
- * not necessarily reflect the minimum setting that will be chosen.
- *
- * Parameters:
- * @param[in] u8 hostNode = The node on which this link is located
- * @param[in] u8 hostLink = The link about to be initialized
- * @param[in] u8 Depth = The depth in the I/O chain from the Host
- * @param[in,out] u8 *DownstreamLinkWidthLimit = modify to change the Link Witdh In
- * @param[in,out] u8 *UpstreamLinkWidthLimit = modify to change the Link Witdh Out
- * @param[in,out] u32 *PCBFreqCap = modify to change the link's frequency capability
- *
- * ---------------------------------------------------------------------------------------
- */
- void (*AMD_CB_IOPCBLimits)(
- u8 HostNode,
- u8 HostLink,
- u8 Depth,
- u8 *DownstreamLinkWidthLimit,
- u8 *UpstreamLinkWidthLimit,
- u32 *PCBFreqCap
- );
-
- /**----------------------------------------------------------------------------------------
- *
- * BOOL
- * AMD_CB_SkipRegang(u8 NodeA, u8 LinkA, u8 NodeB, u8 LinkB)
- *
- * Description:
- * This routine is called whenever two sublinks are both connected to the same CPUs.
- * Normally, unganged subsinks between the same two CPUs are reganged.
- * Return true from this routine to leave the links unganged.
- *
- * Parameters:
- * @param[in] u8 nodeA = One node on which this link is located
- * @param[in] u8 linkA = The link on this node
- * @param[in] u8 nodeB = The other node on which this link is located
- * @param[in] u8 linkB = The link on that node
- * @param[out] BOOL result = true to leave link unganged
- * false to regang link automatically
- *
- * ---------------------------------------------------------------------------------------
- */
- BOOL (*AMD_CB_SkipRegang)(
- u8 NodeA,
- u8 LinkA,
- u8 NodeB,
- u8 LinkB
- );
-
- /**----------------------------------------------------------------------------------------
- *
- * BOOL
- * AMD_CB_CustomizeTrafficDistribution()
- *
- * Description:
- * Near the end of HT initialization, this routine is called once.
- * If this routine will handle traffic distribution in a proprietary way,
- * after detecting which links to distribute traffic on and configuring the system,
- * return true. Return false to let the HT code detect and do traffic distribution
- * This routine can also be used to simply turn this feature off, or to pre-process
- * the system before normal traffic distribution.
- *
- * Parameters:
- * @param[out] BOOL result = true skip traffic distribution
- * false do normal traffic distribution
- *
- * ---------------------------------------------------------------------------------------
- */
- BOOL (*AMD_CB_CustomizeTrafficDistribution)(void);
-
-
- /**----------------------------------------------------------------------------------------
- *
- * BOOL
- * AMD_CB_CustomizeBuffers(u8 Node)
- *
- * Description:
- * Near the end of HT initialization, this routine is called once per CPU node.
- * Implement proprietary buffer tuning and return true, or return false for normal tuning.
- * This routine can also be used to simply turn this feature off, or to pre-process
- * the system before normal tuning.
- *
- * Parameters:
- * @param[in] u8 node = buffer allocation may apply to this node
- * @param[out] BOOL result = true skip buffer allocation on this node
- * false tune buffers normally
- *
- * ---------------------------------------------------------------------------------------
- */
- BOOL (*AMD_CB_CustomizeBuffers)(u8 node);
-
- /**----------------------------------------------------------------------------------------
- *
- * void
- * AMD_CB_OverrideDevicePort(u8 HostNode, u8 HostLink, u8 Depth, u8 *LinkWidthIn,
- * u8 *LinkWidthOut, u16 *LinkFrequency)
- *
- * Description:
- * Called once for each active link on each IO device.
- * Provides an opportunity to directly control the frequency and width,
- * intended for test and debug. The input frequency and width will be used
- * if not overridden.
- *
- * Parameters:
- * @param[in] u8 hostNode = The node on which this link is located
- * @param[in] u8 hostLink = The link about to be initialized
- * @param[in] u8 Depth = The depth in the I/O chain from the Host
- * @param[in] u8 Link = the link on the device (0 or 1)
- * @param[in,out] u8 *LinkWidthIn = modify to change the Link Witdh In
- * @param[in,out] u8 *LinkWidthOut = modify to change the Link Witdh Out
- * @param[in,out] u16 *LinkFrequency = modify to change the link's frequency capability
- *
- * ---------------------------------------------------------------------------------------
- */
- void (*AMD_CB_OverrideDevicePort)(
- u8 HostNode,
- u8 HostLink,
- u8 Depth,
- u8 Link,
- u8 *LinkWidthIn,
- u8 *LinkWidthOut,
- u8 *LinkFrequency
- );
-
- /**----------------------------------------------------------------------------------------
- *
- * void
- * AMD_CB_OverrideCpuPort(u8 Node, u8 Link, u8 *LinkWidthIn, u8 *LinkWidthOut,
- * u16 *LinkFrequency)
- *
- * Description:
- * Called once for each active link on each CPU.
- * Provides an opportunity to directly control the frequency and width,
- * intended for test and debug. The input frequency and width will be used
- * if not overridden.
- *
- * Parameters:
- * @param[in] u8 node = One node on which this link is located
- * @param[in] u8 link = The link on this node
- * @param[in,out] u8 *LinkWidthIn = modify to change the Link Witdh In
- * @param[in,out] u8 *LinkWidthOut = modify to change the Link Witdh Out
- * @param[in,out] u16 *LinkFrequency = modify to change the link's frequency capability
- *
- *---------------------------------------------------------------------------------------
- */
- void (*AMD_CB_OverrideCpuPort)(
- u8 Node,
- u8 Link,
- u8 *LinkWidthIn,
- u8 *LinkWidthOut,
- u8 *LinkFrequency
- );
-
- /**----------------------------------------------------------------------------------------
- *
- * void
- * AMD_CB_EventNotify(u8 evtClass, u16 event, const u8 *pEventData0)
- *
- * Description:
- * Errors, events, faults, warnings, and useful information are provided by
- * calling this routine as often as necessary, once for each notification.
- * See elsewhere in this file for class, event, and event data definitions.
- * See the documentation for more details.
- *
- * Parameters:
- * @param[in] u8 evtClass = What level event is this
- * @param[in] u16 event = A unique ID of this event
- * @param[in] u8 *pEventData0 = useful data associated with the event.
- *
- * ---------------------------------------------------------------------------------------
- */
- void (*AMD_CB_EventNotify) (
- u8 evtClass,
- u16 event,
- const u8 *pEventData0
- );
-
- const struct ht_link_config *ht_link_configuration;
-
-} AMD_HTBLOCK;
-
-/*
- * Event Notification Structures
- * These structures are passed to AMD_CB_EventNotify as *pEventData0.
- */
-
-/* For event HT_EVENT_HW_SYNCHFLOOD */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
-} sHtEventHWSynchFlood;
-
-/* For event HT_EVENT_HW_HTCRC */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 laneMask;
-} sHtEventHWHtCrc;
-
-/* For event HT_EVENT_NCOH_BUS_MAX_EXCEED */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 bus;
-} sHTEventNcohBusMaxExceed;
-
-/* For event HT_EVENT_NCOH_LINK_EXCEED */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 depth;
- u8 maxLinks;
-} sHtEventNcohLinkExceed;
-
-/* For event HT_EVENT_NCOH_CFG_MAP_EXCEED */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
-} sHtEventNcohCfgMapExceed;
-
-/* For event HT_EVENT_NCOH_BUID_EXCEED */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 depth;
- u8 currentBUID;
- u8 unitCount;
-} sHtEventNcohBuidExceed;
-
-/* For event HT_EVENT_NCOH_DEVICE_FAILED */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 depth;
- u8 attemptedBUID;
-} sHtEventNcohDeviceFailed;
-
-/* For event HT_EVENT_NCOH_AUTO_DEPTH */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 depth;
-} sHtEventNcohAutoDepth;
-
-/* For event HT_EVENT_OPT_REQUIRED_CAP_RETRY,
- * HT_EVENT_OPT_REQUIRED_CAP_GEN3
- */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 depth;
-} sHtEventOptRequiredCap;
-
-/* For event HT_EVENT_COH_NO_TOPOLOGY */
-typedef struct
-{
- u8 eSize;
- u8 totalNodes;
-} sHtEventCohNoTopology;
-
-/* For event HT_EVENT_COH_LINK_EXCEED */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 targetNode;
- u8 totalNodes;
- u8 maxLinks;
-} sHtEventCohLinkExceed;
-
-/* For event HT_EVENT_COH_FAMILY_FEUD */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 totalNodes;
-} sHtEventCohFamilyFeud;
-
-/* For event HT_EVENT_COH_NODE_DISCOVERED */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 newNode;
-} sHtEventCohNodeDiscovered;
-
-/* For event HT_EVENT_COH_MPCAP_MISMATCH */
-typedef struct
-{
- u8 eSize;
- u8 node;
- u8 link;
- u8 sysMpCap;
- u8 totalNodes;
-} sHtEventCohMpCapMismatch;
-
-/*----------------------------------------------------------------------------
- * FUNCTIONS PROTOTYPE
- *
- *----------------------------------------------------------------------------
- */
-void amdHtInitialize(AMD_HTBLOCK *pBlock);
-
-
-#endif /* H3FINIT_H */
diff --git a/src/northbridge/amd/amdht/h3gtopo.h b/src/northbridge/amd/amdht/h3gtopo.h
deleted file mode 100644
index e211d4c006..0000000000
--- a/src/northbridge/amd/amdht/h3gtopo.h
+++ /dev/null
@@ -1,355 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software * you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation * version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY * without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef HTTOPO_H
-#define HTTOPO_H
-
-#include <stddef.h>
-
-/*----------------------------------------------------------------------------
- * Mixed (DEFINITIONS AND MACROS / TYPEDEFS, STRUCTURES, ENUMS)
- *
- *----------------------------------------------------------------------------
- */
-
-/*-----------------------------------------------------------------------------
- * DEFINITIONS AND MACROS
- *
- *-----------------------------------------------------------------------------
- */
-
-/*----------------------------------------------------------------------------
- * TYPEDEFS, STRUCTURES, ENUMS
- *
- *----------------------------------------------------------------------------
- */
-
-/*
- * 0
- */
-static u8 const amdHtTopologySingleNode[] = {
- 0x01,
- 0x00, 0xFF // Node 0
-};
-
-/*
- * 0---1
- */
-static u8 const amdHtTopologyDualNode[] = {
- 0x02,
- 0x02, 0xFF, 0x00, 0x11, // Node 0
- 0x00, 0x00, 0x01, 0xFF // Node 1
-};
-
-/*
- * 2
- * |
- * |
- * 0---1
- */
-static u8 const amdHtTopologyThreeLine[] = {
- 0x03,
- 0x06, 0xFF, 0x04, 0x11, 0x02, 0x22, // Node 0
- 0x00, 0x00, 0x01, 0xFF, 0x00, 0x00, // Node 1
- 0x00, 0x00, 0x00, 0x00, 0x01, 0xFF // Node 2
-};
-
-/*
- * 2
- * |\
- * | \
- * 0---1
- */
-static u8 const amdHtTopologyTriangle[] = {
- 0x03,
- 0x06, 0xFF, 0x00, 0x11, 0x00, 0x22, // Node 0
- 0x00, 0x00, 0x05, 0xFF, 0x00, 0x22, // Node 1
- 0x00, 0x00, 0x00, 0x11, 0x03, 0xFF // Node 2
-};
-
-/*
- * 2 3
- * |\ |
- * | \|
- * 0---1
- */
-static u8 const amdHtTopologyFourDegenerate[] = {
- 0x04,
- 0x06, 0xFF, 0x00, 0x11, 0x00, 0x22, 0x00, 0x11, // Node 0
- 0x08, 0x00, 0x0D, 0xFF, 0x08, 0x22, 0x05, 0x33, // Node 1
- 0x00, 0x00, 0x00, 0x11, 0x03, 0xFF, 0x00, 0x11, // Node 2
- 0x00, 0x11, 0x00, 0x11, 0x00, 0x11, 0x02, 0xFF // Node 3
-};
-
-/*
- * 2---3
- * |\ /|
- * |/ \|
- * 0---1
- */
-static u8 const amdHtTopologyFourFully[] = {
- 0x04,
- 0x0E, 0xFF, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, // Node 0
- 0x00, 0x00, 0x0D, 0xFF, 0x00, 0x22, 0x00, 0x33, // Node 1
- 0x00, 0x00, 0x00, 0x11, 0x0B, 0xFF, 0x00, 0x33, // Node 2
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x07, 0xFF // Node 3
-};
-
-
-/*
- * 2---3
- * |\ |
- * | \|
- * 0---1
- */
-static u8 const amdHtTopologyFourKite[] = {
- 0x04,
- 0x06, 0xFF, 0x00, 0x11, 0x00, 0x22, 0x00, 0x11, // Node 0
- 0x08, 0x00, 0x0D, 0xFF, 0x00, 0x22, 0x00, 0x33, // Node 1
- 0x00, 0x00, 0x00, 0x11, 0x0B, 0xFF, 0x01, 0x33, // Node 2
- 0x00, 0x22, 0x00, 0x11, 0x00, 0x22, 0x06, 0xFF // Node 3
-};
-
-
-/*
- * 2 3
- * | |
- * | |
- * 0---1
- */
-static u8 const amdHtTopologyFourLine[] = {
- 0x04,
- 0x06, 0xFF, 0x04, 0x11, 0x02, 0x22, 0x04, 0x11, // Node 0
- 0x08, 0x00, 0x09, 0xFF, 0x08, 0x00, 0x01, 0x33, // Node 1
- 0x00, 0x00, 0x00, 0x00, 0x01, 0xFF, 0x00, 0x00, // Node 2
- 0x00, 0x11, 0x00, 0x11, 0x00, 0x11, 0x02, 0xFF // Node 3
-};
-
-
-/*
- * 2---3
- * | |
- * | |
- * 0---1
- */
-static u8 const amdHtTopologyFourSquare[] = {
- 0x04,
- 0x06, 0xFF, 0x00, 0x11, 0x02, 0x22, 0x00, 0x22, // Node 0
- 0x00, 0x00, 0x09, 0xFF, 0x00, 0x33, 0x01, 0x33, // Node 1
- 0x08, 0x00, 0x00, 0x00, 0x09, 0xFF, 0x00, 0x33, // Node 2
- 0x00, 0x11, 0x04, 0x11, 0x00, 0x22, 0x06, 0xFF, // Node 3
-};
-
-
-/*
- * 2---3
- * |\
- * | \
- * 0 1
- */
-static u8 const amdHtTopologyFourStar[] = {
- 0x04,
- 0x04, 0xFF, 0x00, 0x22, 0x00, 0x22, 0x00, 0x22, // Node 0
- 0x00, 0x22, 0x04, 0xFF, 0x00, 0x22, 0x00, 0x22, // Node 1
- 0x0A, 0x00, 0x09, 0x11, 0x0B, 0xFF, 0x03, 0x33, // Node 2
- 0x00, 0x22, 0x00, 0x22, 0x00, 0x22, 0x04, 0xFF, // Node 3
-};
-
-
-static u8 const amdHtTopologyFiveFully[] = {
- 0x05,
- 0x1E, 0xFF, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, // Node 0
- 0x00, 0x00, 0x1D, 0xFF, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, // Node 1
- 0x00, 0x00, 0x00, 0x11, 0x1B, 0xFF, 0x00, 0x33, 0x00, 0x44, // Node 2
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x17, 0xFF, 0x00, 0x44, // Node 3
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x0F, 0xFF // Node 4
-};
-
-
-/*
- *
- * 4
- * |\
- * | \
- * 2 3
- * | |
- * 0---1
- */
-static u8 const amdHtTopologyFiveTwistedLadder[] = {
- 0x05,
- 0x06, 0xFF, 0x04, 0x11, 0x02, 0x22, 0x00, 0x11, 0x00, 0x22, // Node0
- 0x08, 0x00, 0x09, 0xFF, 0x08, 0x00, 0x01, 0x33, 0x00, 0x30, // Node1
- 0x10, 0x00, 0x10, 0x00, 0x11, 0xFF, 0x00, 0x40, 0x01, 0x44, // Node2
- 0x00, 0x11, 0x00, 0x11, 0x00, 0x14, 0x12, 0xFF, 0x02, 0x44, // Node3
- 0x00, 0x22, 0x00, 0x23, 0x00, 0x22, 0x04, 0x33, 0x0C, 0xFF // Node4
-};
-
-
-static u8 const amdHtTopologySixFully[] = {
- 0x06,
- 0x3E, 0xFF, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, // Node 0
- 0x00, 0x00, 0x3D, 0xFF, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, // Node 1
- 0x00, 0x00, 0x00, 0x11, 0x3B, 0xFF, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, // Node 2
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x37, 0xFF, 0x00, 0x44, 0x00, 0x55, // Node 3
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x2F, 0xFF, 0x00, 0x55, // Node 4
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x1F, 0xFF // Node 5
-};
-
-/*
- *
- * 4 5
- * |\ /|
- * |/ \|
- * 2 3
- * | |
- * 0---1
- */
-static u8 const amdHtTopologySixTwistedLadder[] = {
- 0x06,
- 0x06, 0xFF, 0x04, 0x11, 0x02, 0x22, 0x00, 0x11, 0x02, 0x22, 0x00, 0x12, // Node0
- 0x08, 0x00, 0x09, 0xFF, 0x00, 0x00, 0x01, 0x33, 0x00, 0x03, 0x01, 0x33, // Node1
- 0x30, 0x00, 0x00, 0x00, 0x31, 0xFF, 0x00, 0x54, 0x21, 0x44, 0x00, 0x55, // Node2
- 0x00, 0x11, 0x30, 0x11, 0x00, 0x45, 0x32, 0xFF, 0x00, 0x44, 0x12, 0x55, // Node3
- 0x00, 0x22, 0x00, 0x32, 0x08, 0x22, 0x00, 0x33, 0x0C, 0xFF, 0x00, 0x32, // Node4
- 0x00, 0x23, 0x00, 0x33, 0x00, 0x22, 0x04, 0x33, 0x00, 0x23, 0x0C, 0xFF // Node5
-};
-
-
-static u8 const amdHtTopologySevenFully[] = {
- 0x07,
- 0x7E, 0xFF, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, 0x00, 0x66, // Node 0
- 0x00, 0x00, 0x7D, 0xFF, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, 0x00, 0x66, // Node 1
- 0x00, 0x00, 0x00, 0x11, 0x7B, 0xFF, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, 0x00, 0x66, // Node 2
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x77, 0xFF, 0x00, 0x44, 0x00, 0x55, 0x00, 0x66, // Node 3
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x6F, 0xFF, 0x00, 0x55, 0x00, 0x66, // Node 4
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x5F, 0xFF, 0x00, 0x66, // Node 5
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, 0x3F, 0xFF, // Node 6
-};
-
-
-/* 6
- * |
- * 4 5
- * |\ /|
- * |/ \|
- * 2 3
- * | |
- * 0---1
- */
-static u8 const amdHtTopologySevenTwistedLadder[] = {
- 0x07,
- 0x06, 0xFF, 0x00, 0x11, 0x02, 0x22, 0x00, 0x12, 0x00, 0x22, 0x00, 0x22, 0x00, 0x22, // Node0
- 0x00, 0x00, 0x09, 0xFF, 0x00, 0x03, 0x01, 0x33, 0x00, 0x33, 0x00, 0x33, 0x00, 0x33, // Node1
- 0x30, 0x00, 0x00, 0x50, 0x31, 0xFF, 0x00, 0x54, 0x21, 0x44, 0x01, 0x55, 0x21, 0x44, // Node2
- 0x00, 0x41, 0x30, 0x11, 0x00, 0x45, 0x32, 0xFF, 0x02, 0x44, 0x12, 0x55, 0x02, 0x44, // Node3
- 0x48, 0x22, 0x40, 0x33, 0x48, 0x22, 0x40, 0x33, 0x4C, 0xFF, 0x40, 0x32, 0x0C, 0x66, // Node4
- 0x00, 0x22, 0x04, 0x33, 0x00, 0x22, 0x04, 0x33, 0x00, 0x23, 0x0C, 0xFF, 0x00, 0x23, // Node5
- 0x00, 0x44, 0x00, 0x44, 0x00, 0x44, 0x00, 0x44, 0x00, 0x44, 0x00, 0x44, 0x10, 0xFF // Node6
-};
-
-
-/*
- * 5--4
- * /####\
- * 6######3
- * |######|
- * 7######2
- * \####/
- * 0--1
- */
-static u8 const amdHtTopologyEightFully [] = {
- 0x08,
- 0xFE, 0xFF, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, 0x00, 0x66, 0x00, 0x77, // Node 0
- 0x00, 0x00, 0xFD, 0xFF, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, 0x00, 0x66, 0x00, 0x77, // Node 1
- 0x00, 0x00, 0x00, 0x11, 0xFB, 0xFF, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, 0x00, 0x66, 0x00, 0x77, // Node 2
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0xF7, 0xFF, 0x00, 0x44, 0x00, 0x55, 0x00, 0x66, 0x00, 0x77, // Node 3
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0xEF, 0xFF, 0x00, 0x55, 0x00, 0x66, 0x00, 0x77, // Node 4
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0xDF, 0xFF, 0x00, 0x66, 0x00, 0x77, // Node 5
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, 0xBF, 0xFF, 0x00, 0x77, // Node 6
- 0x00, 0x00, 0x00, 0x11, 0x00, 0x22, 0x00, 0x33, 0x00, 0x44, 0x00, 0x55, 0x00, 0x66, 0x7F, 0xFF // Node 7
-};
-
-
-/* 6---7
- * | |
- * 4---5
- * | |
- * 2---3
- * | |
- * 0---1
- */
-static u8 const amdHtTopologyEightStraightLadder[] = {
- 0x08,
- 0x06, 0xFF, 0x00, 0x11, 0x02, 0x22, 0x00, 0x22, 0x02, 0x22, 0x00, 0x22, 0x02, 0x22, 0x00, 0x22, // Node0
- 0x00, 0x00, 0x09, 0xFF, 0x00, 0x33, 0x01, 0x33, 0x00, 0x33, 0x01, 0x33, 0x00, 0x33, 0x01, 0x33, // Node1
- 0x18, 0x00, 0x00, 0x00, 0x19, 0xFF, 0x00, 0x33, 0x09, 0x44, 0x00, 0x44, 0x09, 0x44, 0x00, 0x44, // Node2
- 0x00, 0x11, 0x24, 0x11, 0x00, 0x22, 0x26, 0xFF, 0x00, 0x55, 0x06, 0x55, 0x00, 0x55, 0x06, 0x55, // Node3
- 0x60, 0x22, 0x00, 0x22, 0x60, 0x22, 0x00, 0x22, 0x64, 0xFF, 0x00, 0x55, 0x24, 0x66, 0x00, 0x66, // Node4
- 0x00, 0x33, 0x90, 0x33, 0x00, 0x33, 0x90, 0x33, 0x00, 0x44, 0x98, 0xFF, 0x00, 0x77, 0x18, 0x77, // Node5
- 0x80, 0x44, 0x00, 0x44, 0x80, 0x44, 0x00, 0x44, 0x80, 0x44, 0x00, 0x44, 0x90, 0xFF, 0x00, 0x77, // Node6
- 0x00, 0x55, 0x40, 0x55, 0x00, 0x55, 0x40, 0x55, 0x00, 0x55, 0x40, 0x55, 0x00, 0x66, 0x60, 0xFF // Node7
-};
-
-
-/* 6---7
- * | |
- * 4 5
- * |\ /|
- * |/ \|
- * 2 3
- * | |
- * 0---1
- */
-static u8 const amdHtTopologyEightTwistedLadder[] = {
- 0x08,
- 0x06, 0xFF, 0x00, 0x11, 0x02, 0x22, 0x00, 0x12, 0x00, 0x22, 0x00, 0x22, 0x00, 0x22, 0x00, 0x22, // Node0
- 0x00, 0x00, 0x09, 0xFF, 0x00, 0x03, 0x01, 0x33, 0x00, 0x33, 0x00, 0x33, 0x00, 0x33, 0x00, 0x33, // Node1
- 0x30, 0x00, 0x00, 0x50, 0x31, 0xFF, 0x00, 0x54, 0x21, 0x44, 0x01, 0x55, 0x21, 0x44, 0x01, 0x55, // Node2
- 0x00, 0x41, 0x30, 0x11, 0x00, 0x45, 0x32, 0xFF, 0x02, 0x44, 0x12, 0x55, 0x02, 0x44, 0x12, 0x55, // Node3
- 0x48, 0x22, 0x40, 0x33, 0x48, 0x22, 0x40, 0x33, 0x4C, 0xFF, 0x00, 0x32, 0x0C, 0x66, 0x00, 0x36, // Node4
- 0x80, 0x22, 0x84, 0x33, 0x80, 0x22, 0x84, 0x33, 0x00, 0x23, 0x8C, 0xFF, 0x00, 0x27, 0x0C, 0x77, // Node5
- 0x00, 0x44, 0x00, 0x44, 0x00, 0x44, 0x00, 0x44, 0x80, 0x44, 0x00, 0x74, 0x90, 0xFF, 0x00, 0x77, // Node6
- 0x00, 0x55, 0x00, 0x55, 0x00, 0x55, 0x00, 0x55, 0x00, 0x65, 0x40, 0x55, 0x00, 0x66, 0x60, 0xFF // Node7
-};
-
-static const u8 *const amd_topo_list[] = {
- amdHtTopologySingleNode,
- amdHtTopologyDualNode,
- amdHtTopologyThreeLine,
- amdHtTopologyTriangle,
- amdHtTopologyFourLine,
- amdHtTopologyFourStar,
- amdHtTopologyFourDegenerate,
- amdHtTopologyFourSquare,
- amdHtTopologyFourKite,
- amdHtTopologyFourFully,
- amdHtTopologyFiveFully,
- amdHtTopologySixFully,
- amdHtTopologySevenFully,
- amdHtTopologyEightFully,
- amdHtTopologyEightTwistedLadder,
- amdHtTopologyEightStraightLadder,
- NULL // NULL to mark end of list
-};
-
-/*----------------------------------------------------------------------------
- * FUNCTIONS PROTOTYPE
- *
- *----------------------------------------------------------------------------
- */
-void getAmdTopolist(u8 ***p);
-
-
-#endif /* HTTOPO_H */
diff --git a/src/northbridge/amd/amdht/h3ncmn.c b/src/northbridge/amd/amdht/h3ncmn.c
deleted file mode 100644
index 830e9888c9..0000000000
--- a/src/northbridge/amd/amdht/h3ncmn.c
+++ /dev/null
@@ -1,2549 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-
-/*----------------------------------------------------------------------------
- * MODULES USED
- *
- *----------------------------------------------------------------------------
- */
-
-#include "h3ncmn.h"
-#include "h3finit.h"
-#include "h3ffeat.h"
-#include "AsPsNb.h"
-
-#include <arch/cpu.h>
-#include <device/pci.h>
-#include <cpu/amd/msr.h>
-#include <device/pci_def.h>
-#include <northbridge/amd/amdfam10/raminit.h>
-#include <northbridge/amd/amdfam10/amdfam10.h>
-
-/*----------------------------------------------------------------------------
- * DEFINITIONS AND MACROS
- *
- *----------------------------------------------------------------------------
- */
-
-/* CPU Northbridge Functions */
-#define CPU_HTNB_FUNC_00 0
-#define CPU_HTNB_FUNC_04 4
-#define CPU_ADDR_FUNC_01 1
-#define CPU_NB_FUNC_03 3
-#define CPU_NB_FUNC_05 5
-
-/* Function 0 registers */
-#define REG_ROUTE0_0X40 0x40
-#define REG_ROUTE1_0X44 0x44
-#define REG_NODE_ID_0X60 0x60
-#define REG_UNIT_ID_0X64 0x64
-#define REG_LINK_TRANS_CONTROL_0X68 0x68
-#define REG_LINK_INIT_CONTROL_0X6C 0x6c
-#define REG_HT_CAP_BASE_0X80 0x80
-#define REG_NORTHBRIDGE_CFG_3X8C 0x8c
-#define REG_HT_LINK_RETRY0_0X130 0x130
-#define REG_HT_TRAFFIC_DIST_0X164 0x164
-#define REG_HT_LINK_EXT_CONTROL0_0X170 0x170
-
-#define HT_CONTROL_CLEAR_CRC (~(3 << 8))
-
-/* Function 1 registers */
-#define REG_ADDR_CONFIG_MAP0_1XE0 0xE0
-#define CPU_ADDR_NUM_CONFIG_MAPS 4
-
-/* Function 3 registers */
-#define REG_NB_SRI_XBAR_BUF_3X70 0x70
-#define REG_NB_MCT_XBAR_BUF_3X78 0x78
-#define REG_NB_FIFOPTR_3XDC 0xDC
-#define REG_NB_CAPABILITY_3XE8 0xE8
-#define REG_NB_CPUID_3XFC 0xFC
-#define REG_NB_LINK_XCS_TOKEN0_3X148 0x148
-#define REG_NB_DOWNCORE_3X190 0x190
-#define REG_NB_CAPABILITY_5X84 0x84
-
-/* Function 4 registers */
-
-
-/*----------------------------------------------------------------------------
- * TYPEDEFS AND STRUCTURES
- *
- *----------------------------------------------------------------------------
- */
-/*----------------------------------------------------------------------------
- * PROTOTYPES OF LOCAL FUNCTIONS
- *
- *----------------------------------------------------------------------------
- */
-
-/***************************************************************************
- *** FAMILY/NORTHBRIDGE SPECIFIC FUNCTIONS ***
- ***************************************************************************/
-
-inline uint8_t is_gt_rev_d(void)
-{
- uint8_t fam15h = 0;
- uint8_t rev_gte_d = 0;
- uint32_t family;
- uint32_t model;
-
- family = model = cpuid_eax(0x80000001);
- model = ((model & 0xf0000) >> 12) | ((model & 0xf0) >> 4);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- if ((model >= 0x8) || fam15h)
- /* Revision D or later */
- rev_gte_d = 1;
-
- return rev_gte_d;
-}
-
-/***************************************************************************//**
- *
- * SBDFO
- * makeLinkBase(u8 currentNode, u8 currentLink)
- *
- * Description:
- * Private to northbridge implementation. Return the HT Host capability base
- * PCI config address for a link.
- *
- * Parameters:
- * @param[in] node = the node this link is on
- * @param[in] link = the link
- *
- *****************************************************************************/
-static SBDFO makeLinkBase(u8 node, u8 link)
-{
- SBDFO linkBase;
-
- /* With rev F can not be called with a 4th link or with the sublinks */
- if (link < 4)
- linkBase = MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_HT_CAP_BASE_0X80 + link*HT_HOST_CAP_SIZE);
- else
- linkBase = MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_04,
- REG_HT_CAP_BASE_0X80 + (link-4)*HT_HOST_CAP_SIZE);
- return linkBase;
-}
-
-/***************************************************************************//**
- *
- * void
- * setHtControlRegisterBits(SBDFO reg, u8 hiBit, u8 loBit, u32 *pValue)
- *
- * Description:
- * Private to northbridge implementation. Provide a common routine for accessing the
- * HT Link Control registers (84, a4, c4, e4), to enforce not clearing the
- * HT CRC error bits. Replaces direct use of AmdPCIWriteBits().
- * NOTE: This routine is called for IO Devices as well as CPUs!
- *
- * Parameters:
- * @param[in] reg = the PCI config address the control register
- * @param[in] hiBit = the high bit number
- * @param[in] loBit = the low bit number
- * @param[in] pValue = the value to write to that bit range. Bit 0 => loBit.
- *
- *****************************************************************************/
-static void setHtControlRegisterBits(SBDFO reg, u8 hiBit, u8 loBit, u32 *pValue)
-{
- u32 temp, mask;
-
- ASSERT((hiBit < 32) && (loBit < 32) && (hiBit >= loBit) && ((reg & 0x3) == 0));
- ASSERT((hiBit < 8) || (loBit > 9));
-
- /* A 1<<32 == 1<<0 due to x86 SHL instruction, so skip if that is the case */
- if ((hiBit-loBit) != 31)
- mask = (((u32)1 << (hiBit-loBit+1))-1);
- else
- mask = (u32)0xFFFFFFFF;
-
- AmdPCIRead(reg, &temp);
- temp &= ~(mask << loBit);
- temp |= (*pValue & mask) << loBit;
- temp &= (u32)HT_CONTROL_CLEAR_CRC;
- AmdPCIWrite(reg, &temp);
-}
-
-/***************************************************************************//**
- *
- * static void
- * writeRoutingTable(u8 node, u8 target, u8 Link, cNorthBridge *nb)
- *
- * Description:
- * This routine will modify the routing tables on the
- * SourceNode to cause it to route both request and response traffic to the
- * targetNode through the specified Link.
- *
- * NOTE: This routine is to be used for early discovery and initialization. The
- * final routing tables must be loaded some other way because this
- * routine does not address the issue of probes, or independent request
- * response paths.
- *
- * Parameters:
- * @param[in] node = the node that will have it's routing tables modified.
- * @param[in] target = For routing to node target
- * @param[in] link = Link from node to target
- * @param[in] *nb = this northbridge
- *
- *****************************************************************************/
-
-static void writeRoutingTable(u8 node, u8 target, u8 link, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
- u32 temp = (nb->selfRouteResponseMask | nb->selfRouteRequestMask) << (link + 1);
- ASSERT((node < nb->maxNodes) && (target < nb->maxNodes) && (link < nb->maxLinks));
- AmdPCIWrite(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_ROUTE0_0X40 + target*4),
- &temp);
-#else
- STOP_HERE;
-#endif
-}
-
-/***************************************************************************//**
- *
- * static void
- * writeNodeID(u8 node, u8 nodeID, cNorthBridge *nb)
- *
- * Description:
- * Modifies the NodeID register on the target node
- *
- * Parameters:
- * @param[in] node = the node that will have its NodeID altered.
- * @param[in] nodeID = the new value for NodeID
- * @param[in] *nb = this northbridge
- *
- *****************************************************************************/
-
-static void writeNodeID(u8 node, u8 nodeID, cNorthBridge *nb)
-{
- u32 temp;
- ASSERT((node < nb->maxNodes) && (nodeID < nb->maxNodes));
- if (is_fam15h()) {
- temp = 1;
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NORTHBRIDGE_CFG_3X8C),
- 22, 22, &temp);
- }
- temp = nodeID;
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_NODE_ID_0X60),
- 2, 0, &temp);
-}
-
-/***************************************************************************//**
- *
- * static void
- * readDefLnk(u8 node, cNorthBridge *nb)
- *
- * Description:
- * Read the DefLnk (the source link of the current packet)
- * from node
- *
- * Parameters:
- * @param[in] node = the node that will have its NodeID altered.
- * @param[in] *nb = this northbridge
- * @return The HyperTransport link where the request to
- * read the default link came from. Since this
- * code is running on the BSP, this should be the link
- * pointing back towards the BSP.
- *
- *****************************************************************************/
-
-static u8 readDefLnk(u8 node, cNorthBridge *nb)
-{
- u32 deflink = 0;
- SBDFO licr;
- u32 temp;
-
- licr = MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_LINK_INIT_CONTROL_0X6C);
-
- ASSERT((node < nb->maxNodes));
- AmdPCIReadBits(licr, 3, 2, &deflink);
- AmdPCIReadBits(licr, 8, 8, &temp); /* on rev F, this bit is reserved == 0 */
- deflink |= temp << 2;
- return (u8)deflink;
-}
-
-/***************************************************************************//**
- *
- * static void
- * enableRoutingTables(u8 node, cNorthBridge *nb)
- *
- * Description:
- * Turns routing tables on for a given node
- *
- * Parameters:
- * @param[in] node = the node that will have it's routing tables enabled
- * @param[in] *nb = this northbridge
- *
- *****************************************************************************/
-
-static void enableRoutingTables(u8 node, cNorthBridge *nb)
-{
- u32 temp = 0;
- ASSERT((node < nb->maxNodes));
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_LINK_INIT_CONTROL_0X6C),
- 0, 0, &temp);
-}
-
-
-/***************************************************************************//**
- *
- * static BOOL
- * verifyLinkIsCoherent(u8 node, u8 Link, cNorthBridge *nbk)
- *
- * Description:
- * Verify that the link is coherent, connected, and ready
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] link = the link on that Node to examine
- * @param[in] *nb = this northbridge
- * @return true - The link has the following status
- * linkCon = 1, Link is connected
- * InitComplete = 1, Link initialization is complete
- * NC = 0, Link is coherent
- * UniP-cLDT = 0, Link is not Uniprocessor cLDT
- * LinkConPend = 0 Link connection is not pending
- * false- The link has some other status
- *
- *****************************************************************************/
-
-static BOOL verifyLinkIsCoherent(u8 node, u8 link, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
-
- u32 linkType;
- SBDFO linkBase;
-
- ASSERT((node < nb->maxNodes) && (link < nb->maxLinks));
-
- linkBase = makeLinkBase(node, link);
-
- /* FN0_98/A4/C4 = LDT Type Register */
- AmdPCIRead(linkBase + HTHOST_LINK_TYPE_REG, &linkType);
-
- /* Verify LinkCon = 1, InitComplete = 1, NC = 0, UniP-cLDT = 0, LinkConPend = 0 */
- return (linkType & HTHOST_TYPE_MASK) == HTHOST_TYPE_COHERENT;
-#else
- return 0;
-#endif /* HT_BUILD_NC_ONLY */
-}
-
-/***************************************************************************//**
- *
- * static bool
- * readTrueLinkFailStatus(u8 node, u8 link, sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Return the LinkFailed status AFTER an attempt is made to clear the bit.
- * Also, call event notify if a Hardware Fault caused a synch flood on a previous boot.
- *
- * The table below summarizes correct responses of this routine.
- * Family before after unconnected Notify? return
- * 0F 0 0 0 No 0
- * 0F 1 0 0 Yes 0
- * 0F 1 1 X No 1
- * 10 0 0 0 No 0
- * 10 1 0 0 Yes 0
- * 10 1 0 3 No 1
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] link = the link on that node to examine
- * @param[in] *pDat = access to call back routine
- * @param[in] *nb = this northbridge
- * @return true - the link is not connected or has hard error
- * false- if the link is connected
- *
- *****************************************************************************/
-
-static BOOL readTrueLinkFailStatus(u8 node, u8 link, sMainData *pDat, cNorthBridge *nb)
-{
- u32 before, after, unconnected, crc;
- SBDFO linkBase;
-
- ASSERT((node < nb->maxNodes) && (link < nb->maxLinks));
-
- linkBase = makeLinkBase(node, link);
-
- /* Save the CRC status before doing anything else.
- * Read, Clear, the Re-read the error bits in the Link Control Register
- * FN0_84/A4/C4[4] = LinkFail bit
- * and the connection status, TransOff and EndOfChain
- */
- AmdPCIReadBits(linkBase + HTHOST_LINK_CONTROL_REG, 9, 8, &crc);
- AmdPCIReadBits(linkBase + HTHOST_LINK_CONTROL_REG, 4, 4, &before);
- setHtControlRegisterBits(linkBase + HTHOST_LINK_CONTROL_REG, 4, 4, &before);
- AmdPCIReadBits(linkBase + HTHOST_LINK_CONTROL_REG, 4, 4, &after);
- AmdPCIReadBits(linkBase + HTHOST_LINK_CONTROL_REG, 7, 6, &unconnected);
-
- if (before != after)
- {
- if (!unconnected)
- {
- if (crc != 0)
- {
- /* A synch flood occurred due to HT CRC */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- /* Pass the node and link on which the generic synch flood event occurred. */
- sHtEventHWHtCrc evt;
- evt.eSize = sizeof(sHtEventHWHtCrc);
- evt.node = node;
- evt.link = link;
- evt.laneMask = (uint8)crc;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_HW_FAULT,
- HT_EVENT_HW_HTCRC,
- (u8 *)&evt);
- }
- }
- else
- {
- /* Some synch flood occurred */
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- /* Pass the node and link on which the generic synch flood event occurred. */
- sHtEventHWSynchFlood evt;
- evt.eSize = sizeof(sHtEventHWSynchFlood);
- evt.node = node;
- evt.link = link;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_HW_FAULT,
- HT_EVENT_HW_SYNCHFLOOD,
- (u8 *)&evt);
- }
- }
- }
- }
- return ((after != 0) || unconnected);
-}
-
-
-/***************************************************************************//**
- *
- * static u8
- * readToken(u8 node, cNorthBridge *nb)
- *
- * Description:
- * Read the token stored in the scratchpad register
- * NOTE: The location used to store the token is arbitrary. The only
- * requirement is that the location warm resets to zero, and that
- * using it will have no ill-effects during HyperTransport initialization.
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] *nb = this northbridge
- * @return the Token read from the node
- *
- *****************************************************************************/
-static u8 readToken(u8 node, cNorthBridge *nb)
-{
- u32 temp;
-
- ASSERT((node < nb->maxNodes));
- /* Use CpuCnt as a scratch register */
- /* Limiting use to 4 bits makes code GH to rev F compatible. */
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_NODE_ID_0X60),
- 19, 16, &temp);
-
- return (u8)temp;
-}
-
-
-/***************************************************************************//**
- *
- * static void
- * writeToken(u8 node, u8 Value, cNorthBridge *nb)
- *
- * Description:
- * Write the token stored in the scratchpad register
- * NOTE: The location used to store the token is arbitrary. The only
- * requirement is that the location warm resets to zero, and that
- * using it will have no ill-effects during HyperTransport initialization.
- * Limiting use to 4 bits makes code GH to rev F compatible.
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param value
- * @param[in] *nb = this northbridge
- *
- *****************************************************************************/
-static void writeToken(u8 node, u8 value, cNorthBridge *nb)
-{
- u32 temp = value;
- ASSERT((node < nb->maxNodes));
- /* Use CpuCnt as a scratch register */
- /* Limiting use to 4 bits makes code GH to rev F compatible. */
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_NODE_ID_0X60),
- 19, 16, &temp);
-}
-
-/***************************************************************************//**
- *
- * static u8
- * fam0FGetNumCoresOnNode(u8 node, cNorthBridge *nb)
- *
- * Description:
- * Return the number of cores (1 based count) on node.
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] *nb = this northbridge
- * @return = the number of cores
- *
- * ---------------------------------------------------------------------------------------
- */
-static u8 fam0FGetNumCoresOnNode(u8 node, cNorthBridge *nb)
-{
- u32 temp;
-
- ASSERT((node < nb->maxNodes));
- /* Read CmpCap */
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CAPABILITY_3XE8),
- 13, 12, &temp);
-
- /* and add one */
- return (u8)(temp+1);
-}
-
-/***************************************************************************//**
- *
- * static u8
- * fam10GetNumCoresOnNode(u8 node, cNorthBridge *nb)
- *
- * Description:
- * Return the number of cores (1 based count) on node.
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] *nb = this northbridge
- * @return = the number of cores
- *
- *
- */
-static u8 fam10GetNumCoresOnNode(u8 node, cNorthBridge *nb)
-{
- u32 temp, leveling, cores;
- u8 i;
-
- ASSERT((node < nb->maxNodes));
- /* Read CmpCap [2][1:0] */
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CAPABILITY_3XE8),
- 15, 12, &temp);
-
- /* bits[15,13,12] specify the cores */
- temp = ((temp & 8) >> 1) + (temp & 3);
- cores = temp + 1;
-
- /* Support Downcoring */
- AmdPCIReadBits (MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_DOWNCORE_3X190),
- 3, 0, &leveling);
- for (i = 0; i < cores; i++)
- {
- if (leveling & ((u32) 1 << i))
- {
- temp--;
- }
- }
- return (u8)(temp+1);
-}
-
-/***************************************************************************//**
- *
- * static u8
- * fam15GetNumCoresOnNode(u8 node, cNorthBridge *nb)
- *
- * Description:
- * Return the number of cores (1 based count) on node.
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] *nb = this northbridge
- * @return = the number of cores
- *
- *
- */
-static u8 fam15GetNumCoresOnNode(u8 node, cNorthBridge *nb)
-{
- u32 temp, leveling, cores;
- u8 i;
-
- ASSERT((node < nb->maxNodes));
- /* Read CmpCap [7:0] */
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_05,
- REG_NB_CAPABILITY_5X84),
- 7, 0, &temp);
-
- /* bits[7:0] specify the cores */
- temp = temp & 0xff;
- cores = temp + 1;
-
- /* Support Downcoring */
- AmdPCIReadBits (MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_DOWNCORE_3X190),
- 31, 0, &leveling);
- for (i = 0; i < cores; i++)
- {
- if (leveling & ((u32) 1 << i))
- {
- temp--;
- }
- }
- return (u8)(temp+1);
-}
-
-/***************************************************************************//**
- *
- * static void
- * setTotalNodesAndCores(u8 node, u8 totalNodes, u8 totalCores, cNorthBridge *nb)
- *
- * Description:
- * Write the total number of cores and nodes to the node
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] totalNodes = the total number of nodes
- * @param[in] totalCores = the total number of cores
- * @param[in] *nb = this northbridge
- *
- * ---------------------------------------------------------------------------------------
- */
-static void setTotalNodesAndCores(u8 node, u8 totalNodes, u8 totalCores, cNorthBridge *nb)
-{
- SBDFO nodeIDReg;
- u32 temp;
-
- ASSERT((node < nb->maxNodes) && (totalNodes <= nb->maxNodes));
- nodeIDReg = MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_NODE_ID_0X60);
-
- temp = totalCores-1;
- /* Rely on max number of nodes:cores for rev F and GH to make
- * this code work, even though we write reserved bit 20 on rev F it will be
- * zero in that case.
- */
- AmdPCIWriteBits(nodeIDReg, 20, 16, &temp);
- temp = totalNodes-1;
- AmdPCIWriteBits(nodeIDReg, 6, 4, &temp);
-}
-
-/***************************************************************************//**
- *
- * static void
- * limitNodes(u8 node, cNorthBridge *nb)
- *
- * Description:
- * Limit coherent config accesses to cpus as indicated by nodecnt.
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] *nb = this northbridge
- *
- * ---------------------------------------------------------------------------------------
- */
-static void limitNodes(u8 node, cNorthBridge *nb)
-{
- u32 temp = 1;
- ASSERT((node < nb->maxNodes));
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_LINK_TRANS_CONTROL_0X68),
- 15, 15, &temp);
-}
-
-/***************************************************************************//**
- *
- * static void
- * writeFullRoutingTable(u8 node, u8 target, u8 reqLink, u8 rspLink, u32 BClinks, cNorthBridge *nb)
- *
- * Description:
- * Write the routing table entry for node to target, using the request link, response
- * link, and broadcast links provided.
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] target = the target node for these routes
- * @param[in] reqLink = the link for requests to target
- * @param[in] rspLink = the link for responses to target
- * @param[in] bClinks = the broadcast links
- * @param[in] *nb = this northbridge
- *
- * ---------------------------------------------------------------------------------------
- */
-static void writeFullRoutingTable(u8 node, u8 target, u8 reqLink, u8 rspLink, u32 bClinks, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
- u32 value = 0;
-
- ASSERT((node < nb->maxNodes) && (target < nb->maxNodes));
- if (reqLink == ROUTETOSELF)
- value |= nb->selfRouteRequestMask;
- else
- value |= nb->selfRouteRequestMask << (reqLink+1);
-
- if (rspLink == ROUTETOSELF)
- value |= nb->selfRouteResponseMask;
- else
- value |= nb->selfRouteResponseMask << (rspLink+1);
-
- /* Allow us to accept a Broadcast ourselves, then set broadcasts for routes */
- value |= (u32)1 << nb->broadcastSelfBit;
- value |= (u32)bClinks << (nb->broadcastSelfBit + 1);
-
- AmdPCIWrite(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_HTNB_FUNC_00,
- REG_ROUTE0_0X40 + target*4), &value);
-#else
- STOP_HERE;
-#endif /* HT_BUILD_NC_ONLY */
-}
-
-/***************************************************************************//**
- *
- * static u32
- * makeKey(u8 currentNode)
- *
- * Description:
- * Private routine to northbridge code.
- * Determine whether a node is compatible with the discovered configuration so
- * far. Currently, that means the family, extended family of the new node are the
- * same as the BSP's.
- *
- * Parameters:
- * @param[in] node = the node
- * @return = the key value
- *
- * ---------------------------------------------------------------------------------------
- */
-static u32 makeKey(u8 node)
-{
- u32 extFam, baseFam;
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CPUID_3XFC),
- 27, 20, &extFam);
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CPUID_3XFC),
- 11, 8, &baseFam);
- return ((u32)(baseFam << 8) | extFam);
-}
-
-
-/***************************************************************************//**
- *
- * static BOOL
- * isCompatible(u8 currentNode, cNorthBridge *nb)
- *
- * Description:
- * Determine whether a node is compatible with the discovered configuration so
- * far. Currently, that means the family, extended family of the new node are the
- * same as the BSP's.
- *
- * Parameters:
- * @param[in] node = the node
- * @param[in] *nb = this northbridge
- * @return = true: the new is compatible, false: it is not
- *
- * ---------------------------------------------------------------------------------------
- */
-static BOOL isCompatible(u8 node, cNorthBridge *nb)
-{
- return (makeKey(node) == nb->compatibleKey);
-}
-
-/***************************************************************************//**
- *
- * static BOOL
- * fam0fIsCapable(u8 node, sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Get node capability and update the minimum supported system capability.
- * Return whether the current configuration exceeds the capability.
- *
- * Parameters:
- * @param[in] node = the node
- * @param[in,out] *pDat = sysMpCap (updated) and NodesDiscovered
- * @param[in] *nb = this northbridge
- * @return true: system is capable of current config.
- * false: system is not capable of current config.
- *
- * ---------------------------------------------------------------------------------------
- */
-static BOOL fam0fIsCapable(u8 node, sMainData *pDat, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
- u32 temp;
- u8 maxNodes;
-
- ASSERT(node < nb->maxNodes);
-
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CAPABILITY_3XE8),
- 2, 1, &temp);
- if (temp > 1)
- {
- maxNodes = 8;
- } else {
- if (temp == 1)
- {
- maxNodes = 2;
- } else {
- maxNodes = 1;
- }
- }
- if (pDat->sysMpCap > maxNodes)
- {
- pDat->sysMpCap = maxNodes;
- }
- /* Note since sysMpCap is one based and NodesDiscovered is zero based, equal is false */
- return (pDat->sysMpCap > pDat->NodesDiscovered);
-#else
- return 1;
-#endif
-}
-
-/***************************************************************************//**
- *
- * static BOOL
- * fam10IsCapable(u8 node, sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Get node capability and update the minimum supported system capability.
- * Return whether the current configuration exceeds the capability.
- *
- * Parameters:
- * @param[in] node = the node
- * @param[in,out] *pDat = sysMpCap (updated) and NodesDiscovered
- * @param[in] *nb = this northbridge
- * @return true: system is capable of current config.
- * false: system is not capable of current config.
- *
- * ---------------------------------------------------------------------------------------
- */
-static BOOL fam10IsCapable(u8 node, sMainData *pDat, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
- u32 temp;
- u8 maxNodes;
-
- ASSERT(node < nb->maxNodes);
-
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CAPABILITY_3XE8),
- 18, 16, &temp);
-
- if (temp != 0)
- {
- maxNodes = (1 << (~temp & 0x3)); /* That is, 1, 2, 4, or 8 */
- }
- else
- {
- maxNodes = 8;
- }
-
- if (pDat->sysMpCap > maxNodes)
- {
- pDat->sysMpCap = maxNodes;
- }
- /* Note since sysMpCap is one based and NodesDiscovered is zero based, equal is false */
- return (pDat->sysMpCap > pDat->NodesDiscovered);
-#else
- return 1;
-#endif
-}
-
-/***************************************************************************//**
- *
- * static BOOL
- * fam15IsCapable(u8 node, sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Get node capability and update the minimum supported system capability.
- * Return whether the current configuration exceeds the capability.
- *
- * Parameters:
- * @param[in] node = the node
- * @param[in,out] *pDat = sysMpCap (updated) and NodesDiscovered
- * @param[in] *nb = this northbridge
- * @return true: system is capable of current config.
- * false: system is not capable of current config.
- *
- * ---------------------------------------------------------------------------------------
- */
-static BOOL fam15IsCapable(u8 node, sMainData *pDat, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
- u32 temp;
- u8 maxNodes;
-
- ASSERT(node < nb->maxNodes);
-
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CAPABILITY_3XE8),
- 18, 16, &temp);
-
- if (temp != 0)
- {
- maxNodes = (1 << (~temp & 0x3)); /* That is, 1, 2, 4, or 8 */
- }
- else
- {
- /* Check if CPU package is dual node */
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CAPABILITY_3XE8),
- 29, 29, &temp);
- if (temp)
- maxNodes = 4;
- else
- maxNodes = 8;
- }
-
- if (pDat->sysMpCap > maxNodes)
- {
- pDat->sysMpCap = maxNodes;
- }
- /* Note since sysMpCap is one based and NodesDiscovered is zero based, equal is false */
- return (pDat->sysMpCap > pDat->NodesDiscovered);
-#else
- return 1;
-#endif
-}
-
-/***************************************************************************//**
- *
- * static void
- * fam0fStopLink(u8 currentNode, u8 currentLink, cNorthBridge *nb)
- *
- * Description:
- * Disable a cHT link on node by setting F0x[E4, C4, A4, 84][TransOff, EndOfChain]=1
- *
- * Parameters:
- * @param[in] node = the node this link is on
- * @param[in] link = the link to stop
- * @param[in] *nb = this northbridge
- *
- * ---------------------------------------------------------------------------------------
- */
-static void fam0fStopLink(u8 node, u8 link, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
- u32 temp;
- SBDFO linkBase;
-
- ASSERT((node < nb->maxNodes) && (link < nb->maxLinks));
-
- linkBase = makeLinkBase(node, link);
-
- /* Set TransOff, EndOfChain */
- temp = 3;
- setHtControlRegisterBits(linkBase + HTHOST_LINK_CONTROL_REG, 7, 6, &temp);
-#endif
-}
-
-/***************************************************************************//**
- *
- * static void
- * commonVoid()
- *
- * Description:
- * Nothing.
- *
- * Parameters:
- * None.
- *
- * ---------------------------------------------------------------------------------------
- */
-static void commonVoid(void)
-{
-}
-
-/***************************************************************************//**
- *
- * static BOOL
- * commonReturnFalse()
- *
- * Description:
- * Return False.
- *
- * Parameters:
- * @return = false
- *
- */
-static BOOL commonReturnFalse(void)
-{
- return 0;
-}
-
-/***************************************************************************
- *** Non-coherent init code ***
- *** Northbridge access routines ***
- ***************************************************************************/
-
-/***************************************************************************//**
- *
- * static u8
- * readSbLink(cNorthBridge *nb)
- *
- * Description:
- * Return the link to the Southbridge
- *
- * Parameters:
- * @param[in] *nb = this northbridge
- * @return the link to the southbridge
- *
- * ---------------------------------------------------------------------------------------
- */
-static u8 readSbLink(cNorthBridge *nb)
-{
- u32 temp;
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(0),
- makePCIBusFromNode(0),
- makePCIDeviceFromNode(0),
- CPU_HTNB_FUNC_00,
- REG_UNIT_ID_0X64),
- 10, 8, &temp);
- return (u8)temp;
-}
-
-/***************************************************************************//**
- *
- * static BOOL
- * verifyLinkIsNonCoherent(u8 node, u8 link, cNorthBridge *nb)
- *
- * Description:
- * Verify that the link is non-coherent, connected, and ready
- *
- * Parameters:
- * @param[in] node = the node that will be examined
- * @param[in] link = the Link on that node to examine
- * @param[in] *nb = this northbridge
- * @return = true - The link has the following status
- * LinkCon = 1, Link is connected
- * InitComplete = 1,Link initialization is complete
- * NC = 1, Link is coherent
- * UniP-cLDT = 0, Link is not Uniprocessor cLDT
- * LinkConPend = 0 Link connection is not pending
- * false- The link has some other status
- *
- * ---------------------------------------------------------------------------------------
- */
-static BOOL verifyLinkIsNonCoherent(u8 node, u8 link, cNorthBridge *nb)
-{
- u32 linkType;
- SBDFO linkBase;
-
- ASSERT((node < nb->maxNodes) && (link < nb->maxLinks));
-
- linkBase = makeLinkBase(node, link);
-
- /* FN0_98/A4/C4 = LDT Type Register */
- AmdPCIRead(linkBase + HTHOST_LINK_TYPE_REG, &linkType);
-
- /* Verify linkCon = 1, InitComplete = 1, NC = 0, UniP-cLDT = 0, LinkConPend = 0 */
- return (linkType & HTHOST_TYPE_MASK) == HTHOST_TYPE_NONCOHERENT;
-}
-
-/***************************************************************************//**
- *
- * static void
- * ht3SetCFGAddrMap(u8 cfgMapIndex, u8 secBus, u8 subBus, u8 targetNode, u8 targetLink, sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Configure and enable config access to a non-coherent chain for the given bus range.
- *
- * Parameters:
- * @param[in] cfgMapIndex = the map entry to set
- * @param[in] secBus = The secondary bus number to use
- * @param[in] subBus = The subordinate bus number to use
- * @param[in] targetNode = The node that shall be the recipient of the traffic
- * @param[in] targetLink = The link that shall be the recipient of the traffic
- * @param[in] pDat = our global state
- * @param[in] *nb = this northbridge
- *
- * ---------------------------------------------------------------------------------------
- */
-static void ht3SetCFGAddrMap(u8 cfgMapIndex, u8 secBus, u8 subBus, u8 targetNode, u8 targetLink, sMainData *pDat, cNorthBridge *nb)
-{
- u8 curNode;
- SBDFO linkBase;
- u32 temp;
-
- linkBase = makeLinkBase(targetNode, targetLink);
-
- ASSERT(secBus <= subBus);
- temp = secBus;
- AmdPCIWriteBits(linkBase + HTHOST_ISOC_REG, 15, 8, &temp);
-
- /* For target link, note that rev F uses bits 9:8 and only with GH is bit 10
- * set to indicate a sublink. For node, we are currently not supporting Extended
- * routing tables.
- */
- temp = ((u32)subBus << 24) + ((u32)secBus << 16) + ((u32)targetLink << 8)
- + ((u32)targetNode << 4) + (u32)3;
- for (curNode = 0; curNode < pDat->NodesDiscovered+1; curNode++)
- AmdPCIWrite(MAKE_SBDFO(makePCISegmentFromNode(curNode),
- makePCIBusFromNode(curNode),
- makePCIDeviceFromNode(curNode),
- CPU_ADDR_FUNC_01,
- REG_ADDR_CONFIG_MAP0_1XE0 + 4*cfgMapIndex),
- &temp);
-}
-
-/***************************************************************************//**
- *
- * static void
- * ht1SetCFGAddrMap(u8 cfgMapIndex, u8 secBus, u8 subBus, u8 targetNode, u8 targetLink, sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Configure and enable config access to a non-coherent chain for the given bus range.
- *
- * Parameters:
- * @param[in] cfgMapIndex = the map entry to set
- * @param[in] secBus = The secondary bus number to use
- * @param[in] subBus = The subordinate bus number to use
- * @param[in] targetNode = The node that shall be the recipient of the traffic
- * @param[in] targetLink = The link that shall be the recipient of the traffic
- * @param[in] pDat = our global state
- * @param[in] *nb = this northbridge
- *
- ******************************************************************************/
-static void ht1SetCFGAddrMap(u8 cfgMapIndex, u8 secBus, u8 subBus, u8 targetNode, u8 targetLink, sMainData *pDat, cNorthBridge *nb)
-{
- u8 curNode;
- SBDFO linkBase;
- u32 temp;
-
- linkBase = makeLinkBase(targetNode, targetLink);
-
- ASSERT(secBus <= subBus);
- temp = secBus;
- AmdPCIWriteBits(linkBase + HTHOST_ISOC_REG, 15, 8, &temp);
-
- temp = subBus;
- AmdPCIWriteBits(linkBase + HTHOST_ISOC_REG, 23, 16, &temp);
-
- /* For target link, note that rev F uses bits 9:8 and only with GH is bit 10
- * set to indicate a sublink. For node, we are currently not supporting Extended
- * routing tables.
- */
- temp = ((u32)subBus << 24) + ((u32)secBus << 16) + ((u32)targetLink << 8)
- + ((u32)targetNode << 4) + (u32)3;
- for (curNode = 0; curNode < pDat->NodesDiscovered+1; curNode++)
- AmdPCIWrite(MAKE_SBDFO(makePCISegmentFromNode(curNode),
- makePCIBusFromNode(curNode),
- makePCIDeviceFromNode(curNode),
- CPU_ADDR_FUNC_01,
- REG_ADDR_CONFIG_MAP0_1XE0 + 4*cfgMapIndex),
- &temp);
-}
-
-/***************************************************************************
- *** Link Optimization ***
- ***************************************************************************/
-
-/**
- * static u8
- * convertBitsToWidth(u8 value, cNorthBridge *nb)
- *
- * Description:
- * Given the bits set in the register field, return the width it represents
- *
- * Parameters:
- * @param[in] value = The bits for the register
- * @param[in] *nb = this northbridge
- * @return The width
- *
- ******************************************************************************/
-static u8 convertBitsToWidth(u8 value, cNorthBridge *nb)
-{
- switch (value) {
- case 1: return 16;
- case 0: return 8;
- case 5: return 4;
- case 4: return 2;
- default: STOP_HERE; /* This is an error internal condition */
- }
- return 0; // shut up GCC.
-}
-
-/***************************************************************************//**
- *
- * static u8
- * convertWidthToBits(u8 value, cNorthBridge *nb)
- *
- * Description:
- * Translate a desired width setting to the bits to set in the register field
- *
- * Parameters:
- * @param[in] value = The width
- * @param[in] *nb = this northbridge
- * @return The bits for the register
- *
- ******************************************************************************/
-static u8 convertWidthToBits(u8 value, cNorthBridge *nb)
-{
- switch (value) {
- case 16: return 1;
- case 8: return 0;
- case 4: return 5;
- case 2: return 4;
- default: STOP_HERE; /* This is an internal error condition */
- }
- return 0; // shut up GCC
-}
-
-/***************************************************************************//**
- *
- * static u16
- * ht1NorthBridgeFreqMask(u8 NodeID, cNorthBridge *nb)
- *
- * Description:
- * Return a mask that eliminates HT frequencies that cannot be used due to a slow
- * northbridge frequency.
- *
- * Parameters:
- * @param[in] node = Result could (later) be for a specific node
- * @param[in] *nb = this northbridge
- * @return Frequency mask
- *
- ******************************************************************************/
-static uint32_t ht1NorthBridgeFreqMask(u8 node, cNorthBridge *nb)
-{
- /* only up to HT1 speeds */
- return (HT_FREQUENCY_LIMIT_HT1_ONLY);
-}
-
-/***************************************************************************//**
- *
- * static u16
- * fam10NorthBridgeFreqMask(u8 NodeID, cNorthBridge *nb)
- *
- * Description:
- * Return a mask that eliminates HT frequencies that cannot be used due to a slow
- * northbridge frequency.
- *
- * Parameters:
- * @param[in] node = Result could (later) be for a specific node
- * @param[in] *nb = this northbridge
- * @return = Frequency mask
- *
- ******************************************************************************/
-static uint32_t fam10NorthBridgeFreqMask(u8 node, cNorthBridge *nb)
-{
- u8 nbCOF;
- uint32_t supported;
-
- nbCOF = getMinNbCOF();
- /*
- * nbCOF is minimum northbridge speed in hundreds of MHz.
- * HT can not go faster than the minimum speed of the northbridge.
- */
- if ((nbCOF >= 6) && (nbCOF < 10))
- {
- /* Generation 1 HT link frequency */
- /* Convert frequency to bit and all less significant bits,
- * by setting next power of 2 and subtracting 1.
- */
- supported = ((uint32_t)1 << ((nbCOF >> 1) + 2)) - 1;
- }
- else if ((nbCOF >= 10) && (nbCOF <= 32))
- {
- /* Generation 3 HT link frequency
- * Assume error retry is enabled on all Gen 3 links
- */
- if (is_gt_rev_d()) {
- nbCOF *= 2;
- if (nbCOF > 32)
- nbCOF = 32;
- }
-
- /* Convert frequency to bit and all less significant bits,
- * by setting next power of 2 and subtracting 1.
- */
- supported = ((uint32_t)1 << ((nbCOF >> 1) + 2)) - 1;
- }
- else if (nbCOF > 32)
- {
- supported = HT_FREQUENCY_LIMIT_3200M;
- }
- /* unlikely cases, but include as a defensive measure, also avoid trick above */
- else if (nbCOF == 4)
- {
- supported = HT_FREQUENCY_LIMIT_400M;
- }
- else if (nbCOF == 2)
- {
- supported = HT_FREQUENCY_LIMIT_200M;
- }
- else
- {
- STOP_HERE;
- supported = HT_FREQUENCY_LIMIT_200M;
- }
-
- return (fixEarlySampleFreqCapability(supported));
-}
-
-/***************************************************************************//**
- *
- * static u16
- * fam15NorthBridgeFreqMask(u8 NodeID, cNorthBridge *nb)
- *
- * Description:
- * Return a mask that eliminates HT frequencies that cannot be used due to a slow
- * northbridge frequency.
- *
- * Parameters:
- * @param[in] node = Result could (later) be for a specific node
- * @param[in] *nb = this northbridge
- * @return = Frequency mask
- *
- ******************************************************************************/
-static uint32_t fam15NorthBridgeFreqMask(u8 node, cNorthBridge *nb)
-{
- u8 nbCOF;
- uint32_t supported;
-
- nbCOF = getMinNbCOF();
- /*
- * nbCOF is minimum northbridge speed in hundreds of MHz.
- * HT can not go faster than the minimum speed of the northbridge.
- */
- if ((nbCOF >= 6) && (nbCOF < 10))
- {
- /* Generation 1 HT link frequency */
- /* Convert frequency to bit and all less significant bits,
- * by setting next power of 2 and subtracting 1.
- */
- supported = ((uint32_t)1 << ((nbCOF >> 1) + 2)) - 1;
- }
- else if ((nbCOF >= 10) && (nbCOF <= 32))
- {
- /* Generation 3 HT link frequency
- * Assume error retry is enabled on all Gen 3 links
- */
- nbCOF *= 2;
- if (nbCOF > 32)
- nbCOF = 32;
-
- /* Convert frequency to bit and all less significant bits,
- * by setting next power of 2 and subtracting 1.
- */
- supported = ((uint32_t)1 << ((nbCOF >> 1) + 2)) - 1;
- }
- else if (nbCOF > 32)
- {
- supported = HT_FREQUENCY_LIMIT_3200M;
- }
- /* unlikely cases, but include as a defensive measure, also avoid trick above */
- else if (nbCOF == 4)
- {
- supported = HT_FREQUENCY_LIMIT_400M;
- }
- else if (nbCOF == 2)
- {
- supported = HT_FREQUENCY_LIMIT_200M;
- }
- else
- {
- STOP_HERE;
- supported = HT_FREQUENCY_LIMIT_200M;
- }
-
- return (fixEarlySampleFreqCapability(supported));
-}
-
-/***************************************************************************//**
- *
- * static void
- * gatherLinkData(sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * For all discovered links, populate the port list with the frequency and width
- * capabilities.
- *
- * Parameters:
- * @param[in,out] pDat = our global state, port list
- * @param[in] *nb = this northbridge
- *
- ******************************************************************************/
-static void gatherLinkData(sMainData *pDat, cNorthBridge *nb)
-{
- u8 i;
- SBDFO linkBase;
- u32 temp;
-
- for (i = 0; i < pDat->TotalLinks*2; i++)
- {
- if (pDat->PortList[i].Type == PORTLIST_TYPE_CPU)
- {
- linkBase = makeLinkBase(pDat->PortList[i].NodeID, pDat->PortList[i].Link);
-
- pDat->PortList[i].Pointer = linkBase;
-
- AmdPCIReadBits(linkBase + HTHOST_LINK_CONTROL_REG, 22, 20, &temp);
- pDat->PortList[i].PrvWidthOutCap = convertBitsToWidth((u8)temp, pDat->nb);
-
- AmdPCIReadBits(linkBase + HTHOST_LINK_CONTROL_REG, 18, 16, &temp);
- pDat->PortList[i].PrvWidthInCap = convertBitsToWidth((u8)temp, pDat->nb);
-
- AmdPCIReadBits(linkBase + HTHOST_FREQ_REV_REG, 31, 16, &temp);
- pDat->PortList[i].PrvFrequencyCap = temp & 0x7FFF /* Mask off bit 15, reserved value */
- & nb->northBridgeFreqMask(pDat->PortList[i].NodeID, pDat->nb);
- if (is_gt_rev_d()) {
- AmdPCIReadBits(linkBase + HTHOST_FREQ_REV_REG_2, 15, 1, &temp);
- temp &= 0x7; /* Mask off reserved values */
- pDat->PortList[i].PrvFrequencyCap |= (temp << 17);
- }
-
- AmdPCIReadBits(linkBase + HTHOST_FEATURE_CAP_REG, 9, 0, &temp);
- pDat->PortList[i].PrvFeatureCap = (u16)temp;
- }
- else
- {
- linkBase = pDat->PortList[i].Pointer;
- if (pDat->PortList[i].Link == 1)
- linkBase += HTSLAVE_LINK01_OFFSET;
-
- AmdPCIReadBits(linkBase + HTSLAVE_LINK_CONTROL_0_REG, 22, 20, &temp);
- pDat->PortList[i].PrvWidthOutCap = convertBitsToWidth((u8)temp, pDat->nb);
-
- AmdPCIReadBits(linkBase + HTSLAVE_LINK_CONTROL_0_REG, 18, 16, &temp);
- pDat->PortList[i].PrvWidthInCap = convertBitsToWidth((u8)temp, pDat->nb);
-
- AmdPCIReadBits(linkBase + HTSLAVE_FREQ_REV_0_REG, 31, 16, &temp);
- pDat->PortList[i].PrvFrequencyCap = (u16)temp;
-
- AmdPCIReadBits(linkBase + HTSLAVE_FEATURE_CAP_REG, 7, 0, &temp);
- pDat->PortList[i].PrvFeatureCap = (u16)temp;
-
- if (pDat->HtBlock->AMD_CB_DeviceCapOverride)
- {
- linkBase &= 0xFFFFF000;
- AmdPCIRead(linkBase, &temp);
-
- pDat->HtBlock->AMD_CB_DeviceCapOverride(
- pDat->PortList[i].NodeID,
- pDat->PortList[i].HostLink,
- pDat->PortList[i].HostDepth,
- (u8)SBDFO_SEG(pDat->PortList[i].Pointer),
- (u8)SBDFO_BUS(pDat->PortList[i].Pointer),
- (u8)SBDFO_DEV(pDat->PortList[i].Pointer),
- temp,
- pDat->PortList[i].Link,
- &(pDat->PortList[i].PrvWidthInCap),
- &(pDat->PortList[i].PrvWidthOutCap),
- &(pDat->PortList[i].PrvFrequencyCap),
- &(pDat->PortList[i].PrvFeatureCap));
- }
- }
- }
-}
-
-/***************************************************************************//**
- *
- * static void
- * setLinkData(sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Change the hardware state for all links according to the now optimized data in the
- * port list data structure.
- *
- * Parameters:
- * @param[in] pDat = our global state, port list
- * @param[in] *nb = this northbridge
- *
- ******************************************************************************/
-static void setLinkData(sMainData *pDat, cNorthBridge *nb)
-{
- u8 i;
- SBDFO linkBase;
- u32 temp, temp2, frequency_index, widthin, widthout, bits;
-
- for (i = 0; i < pDat->TotalLinks*2; i++)
- {
-
- ASSERT(pDat->PortList[i&0xFE].SelWidthOut == pDat->PortList[(i&0xFE)+1].SelWidthIn);
- ASSERT(pDat->PortList[i&0xFE].SelWidthIn == pDat->PortList[(i&0xFE)+1].SelWidthOut);
- ASSERT(pDat->PortList[i&0xFE].SelFrequency == pDat->PortList[(i&0xFE)+1].SelFrequency);
-
- if (pDat->PortList[i].SelRegang)
- {
- ASSERT(pDat->PortList[i].Type == PORTLIST_TYPE_CPU);
- ASSERT(pDat->PortList[i].Link < 4);
- temp = 1;
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(pDat->PortList[i].NodeID),
- makePCIBusFromNode(pDat->PortList[i].NodeID),
- makePCIDeviceFromNode(pDat->PortList[i].NodeID),
- CPU_HTNB_FUNC_00,
- REG_HT_LINK_EXT_CONTROL0_0X170 + 4*pDat->PortList[i].Link),
- 0, 0, &temp);
- }
-
- if (pDat->PortList[i].Type == PORTLIST_TYPE_CPU)
- {
- if (pDat->HtBlock->AMD_CB_OverrideCpuPort)
- pDat->HtBlock->AMD_CB_OverrideCpuPort(pDat->PortList[i].NodeID,
- pDat->PortList[i].Link,
- &(pDat->PortList[i].SelWidthIn),
- &(pDat->PortList[i].SelWidthOut),
- &(pDat->PortList[i].SelFrequency));
- }
- else
- {
- if (pDat->HtBlock->AMD_CB_OverrideDevicePort)
- pDat->HtBlock->AMD_CB_OverrideDevicePort(pDat->PortList[i].NodeID,
- pDat->PortList[i].HostLink,
- pDat->PortList[i].HostDepth,
- pDat->PortList[i].Link,
- &(pDat->PortList[i].SelWidthIn),
- &(pDat->PortList[i].SelWidthOut),
- &(pDat->PortList[i].SelFrequency));
- }
-
- linkBase = pDat->PortList[i].Pointer;
- if ((pDat->PortList[i].Type == PORTLIST_TYPE_IO) && (pDat->PortList[i].Link == 1))
- linkBase += HTSLAVE_LINK01_OFFSET;
-
- /* Some IO devices don't work properly when setting widths, so write them in a single operation,
- * rather than individually.
- */
- widthout = convertWidthToBits(pDat->PortList[i].SelWidthOut, pDat->nb);
- ASSERT(widthout == 1 || widthout == 0 || widthout == 5 || widthout == 4);
- widthin = convertWidthToBits(pDat->PortList[i].SelWidthIn, pDat->nb);
- ASSERT(widthin == 1 || widthin == 0 || widthin == 5 || widthin == 4);
-
- temp = (widthin & 7) | ((widthout & 7) << 4);
- setHtControlRegisterBits(linkBase + HTHOST_LINK_CONTROL_REG, 31, 24, &temp);
-
- temp = pDat->PortList[i].SelFrequency;
- if (pDat->PortList[i].Type == PORTLIST_TYPE_CPU)
- {
- ASSERT((temp >= HT_FREQUENCY_600M && temp <= HT_FREQUENCY_3200M)
- || (temp == HT_FREQUENCY_200M) || (temp == HT_FREQUENCY_400M));
- frequency_index = temp;
- if (temp > 0xf) {
- temp2 = (temp >> 4) & 0x1;
- temp &= 0xf;
- } else {
- temp2 = 0x0;
- }
- /* NOTE
- * The Family 15h BKDG Rev. 3.14 is wrong
- * Freq[4] must be set before Freq[3:0], otherwise the register writes will be ignored!
- */
- if (is_gt_rev_d())
- AmdPCIWriteBits(linkBase + HTHOST_FREQ_REV_REG_2, 0, 0, &temp2);
- AmdPCIWriteBits(linkBase + HTHOST_FREQ_REV_REG, 11, 8, &temp);
-
- /* Enable isochronous flow control mode if supported by chipset */
- if (is_fam15h()) {
- if (pDat->PortList[i].enable_isochronous_mode)
- temp = 1;
- else
- temp = 0;
- setHtControlRegisterBits(linkBase + HTHOST_LINK_CONTROL_REG, 12, 12, &temp);
- }
-
- if (frequency_index > HT_FREQUENCY_1000M) /* Gen1 = 200MHz -> 1000MHz, Gen3 = 1200MHz -> 3200MHz */
- {
- /* Enable for Gen3 frequencies */
- temp = 1;
- }
- else
- {
- /* Disable for Gen1 frequencies */
- temp = 0;
- }
- /* HT3 retry mode enable / disable */
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(pDat->PortList[i].NodeID),
- makePCIBusFromNode(pDat->PortList[i].NodeID),
- makePCIDeviceFromNode(pDat->PortList[i].NodeID),
- CPU_HTNB_FUNC_00,
- REG_HT_LINK_RETRY0_0X130 + 4*pDat->PortList[i].Link),
- 0, 0, &temp);
-
- /* and Scrambling enable / disable */
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(pDat->PortList[i].NodeID),
- makePCIBusFromNode(pDat->PortList[i].NodeID),
- makePCIDeviceFromNode(pDat->PortList[i].NodeID),
- CPU_HTNB_FUNC_00,
- REG_HT_LINK_EXT_CONTROL0_0X170 + 4*pDat->PortList[i].Link),
- 3, 3, &temp);
- }
- else
- {
- SBDFO currentPtr;
- BOOL isFound;
-
- ASSERT(temp <= HT_FREQUENCY_3200M);
- /* Write the frequency setting */
- AmdPCIWriteBits(linkBase + HTSLAVE_FREQ_REV_0_REG, 11, 8, &temp);
-
- /* Handle additional HT3 frequency requirements, if needed,
- * or clear them if switching down to ht1 on a warm reset.
- * Gen1 = 200MHz -> 1000MHz, Gen3 = 1200MHz -> 2600MHz
- *
- * Even though we assert if debugging, we need to check that the capability was found
- * always, since this is an unknown hardware device, also we are taking
- * unqualified frequency from the call backs
- * (could be trying to do ht3 on an ht1 IO device).
- */
-
- if (temp > HT_FREQUENCY_1000M)
- {
- /* Enabling features if gen 3 */
- bits = 1;
- }
- else
- {
- /* Disabling features if gen 1 */
- bits = 0;
- }
-
- /* Enable isochronous flow control mode if supported by chipset */
- if (is_fam15h()) {
- if (pDat->PortList[i].enable_isochronous_mode)
- temp = 1;
- else
- temp = 0;
- }
-
- /* Retry Enable */
- isFound = FALSE;
- currentPtr = linkBase & (u32)0xFFFFF000; /* Set PCI Offset to 0 */
- do
- {
- AmdPCIFindNextCap(&currentPtr);
- if (currentPtr != ILLEGAL_SBDFO)
- {
- AmdPCIRead(currentPtr, &temp);
- /* HyperTransport Retry Capability? */
- if (IS_HT_RETRY_CAPABILITY(temp))
- {
- ASSERT(pDat->PortList[i].Link < 2);
- AmdPCIWriteBits(currentPtr + HTRETRY_CONTROL_REG,
- pDat->PortList[i].Link*16,
- pDat->PortList[i].Link*16,
- &bits);
- isFound = TRUE;
- }
- /* Some other capability, keep looking */
- }
- else
- {
- /* If we are turning it off, that may mean the device was only ht1 capable,
- * so don't complain that we can't do it.
- */
- if (bits != 0)
- {
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventOptRequiredCap evt;
- evt.eSize = sizeof(sHtEventOptRequiredCap);
- evt.node = pDat->PortList[i].NodeID;
- evt.link = pDat->PortList[i].HostLink;
- evt.depth = pDat->PortList[i].HostDepth;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_WARNING,
- HT_EVENT_OPT_REQUIRED_CAP_RETRY,
- (u8 *)&evt);
- }
- STOP_HERE;
- }
- isFound = TRUE;
- }
- } while (!isFound);
-
- /* Scrambling enable */
- isFound = FALSE;
- currentPtr = linkBase & (u32)0xFFFFF000; /* Set PCI Offset to 0 */
- do
- {
- AmdPCIFindNextCap(&currentPtr);
- if (currentPtr != ILLEGAL_SBDFO)
- {
- AmdPCIRead(currentPtr, &temp);
- /* HyperTransport Gen3 Capability? */
- if (IS_HT_GEN3_CAPABILITY(temp))
- {
- ASSERT(pDat->PortList[i].Link < 2);
- AmdPCIWriteBits((currentPtr +
- HTGEN3_LINK_TRAINING_0_REG +
- pDat->PortList[i].Link*HTGEN3_LINK01_OFFSET),
- 3, 3, &bits);
- isFound = TRUE;
- }
- /* Some other capability, keep looking */
- }
- else
- {
- /* If we are turning it off, that may mean the device was only ht1 capable,
- * so don't complain that we can't do it.
- */
- if (bits != 0)
- {
- if (pDat->HtBlock->AMD_CB_EventNotify)
- {
- sHtEventOptRequiredCap evt;
- evt.eSize = sizeof(sHtEventOptRequiredCap);
- evt.node = pDat->PortList[i].NodeID;
- evt.link = pDat->PortList[i].HostLink;
- evt.depth = pDat->PortList[i].HostDepth;
-
- pDat->HtBlock->AMD_CB_EventNotify(HT_EVENT_CLASS_WARNING,
- HT_EVENT_OPT_REQUIRED_CAP_GEN3,
- (u8 *)&evt);
- }
- STOP_HERE;
- }
- isFound = TRUE;
- }
- } while (!isFound);
- }
- }
-}
-
-/***************************************************************************//**
- *
- * void
- * fam0fWriteHTLinkCmdBufferAlloc(u8 node, u8 link, u8 req, u8 preq, u8 rsp, u8 prb)
- *
- * Description:
- * Set the command buffer allocations in the buffer count register for the node and link.
- * The command buffer settings in the low 16 bits are the same on both
- * family 10h and family 0fh northbridges.
- *
- * Parameters:
- * @param[in] node = The node to set allocations on
- * @param[in] link = the link to set allocations on
- * @param[in] req = non-posted Request Command Buffers
- * @param[in] preq = Posted Request Command Buffers
- * @param[in] rsp = Response Command Buffers
- * @param[in] prb = Probe Command Buffers
- *
- ******************************************************************************/
-#ifndef HT_BUILD_NC_ONLY
-
-static void fam0fWriteHTLinkCmdBufferAlloc(u8 node, u8 link, u8 req, u8 preq, u8 rsp, u8 prb)
-{
- u32 temp;
- SBDFO currentPtr;
-
- currentPtr = makeLinkBase(node, link);
- currentPtr += HTHOST_BUFFER_COUNT_REG;
-
- /* non-posted Request Command Buffers */
- temp = req;
- AmdPCIWriteBits(currentPtr, 3, 0, &temp);
- /* Posted Request Command Buffers */
- temp = preq;
- AmdPCIWriteBits(currentPtr, 7, 4, &temp);
- /* Response Command Buffers */
- temp = rsp;
- AmdPCIWriteBits(currentPtr, 11, 8, &temp);
- /* Probe Command Buffers */
- temp = prb;
- AmdPCIWriteBits(currentPtr, 15, 12, &temp);
- /* LockBc */
- temp = 1;
- AmdPCIWriteBits(currentPtr, 31, 31, &temp);
-}
-#endif /* HT_BUILD_NC_ONLY */
-
-/***************************************************************************//**
- *
- * void
- * fam0fWriteHTLinkDatBufferAlloc(u8 node, u8 link, u8 reqD, u8 preqD, u8 rspD)
- *
- * Description:
- * Set the data buffer allocations in the buffer count register for the node and link.
- * The command buffer settings in the high 16 bits are not the same on both
- * family 10h and family 0fh northbridges.
- *
- * Parameters:
- * @param[in] node = The node to set allocations on
- * @param[in] link = the link to set allocations on
- * @param[in] reqD = non-posted Request Data Buffers
- * @param[in] preqD = Posted Request Data Buffers
- * @param[in] rspD = Response Data Buffers
- *
- ******************************************************************************/
-#ifndef HT_BUILD_NC_ONLY
-
-static void fam0fWriteHTLinkDatBufferAlloc(u8 node, u8 link, u8 reqD, u8 preqD, u8 rspD)
-{
- u32 temp;
- SBDFO currentPtr;
-
- currentPtr = makeLinkBase(node, link);
- currentPtr += HTHOST_BUFFER_COUNT_REG;
-
- /* Request Data Buffers */
- temp = reqD;
- AmdPCIWriteBits(currentPtr, 18, 16, &temp);
- /* Posted Request Data Buffers */
- temp = preqD;
- AmdPCIWriteBits(currentPtr, 22, 20, &temp);
- /* Response Data Buffers */
- temp = rspD;
- AmdPCIWriteBits(currentPtr, 26, 24, &temp);
-}
-#endif /* HT_BUILD_NC_ONLY */
-
-/***************************************************************************//**
- *
- * static void
- * ht3WriteTrafficDistribution(u32 links01, u32 links10, cNorthBridge *nb)
- *
- * Description:
- * Set the traffic distribution register for the links provided.
- *
- * Parameters:
- * @param[in] links01 = coherent links from node 0 to 1
- * @param[in] links10 = coherent links from node 1 to 0
- * @param[in] nb = this northbridge
- *
- ******************************************************************************/
-static void ht3WriteTrafficDistribution(u32 links01, u32 links10, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
- u32 temp;
-
- /* Node 0 */
- /* DstLnk */
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(0),
- makePCIBusFromNode(0),
- makePCIDeviceFromNode(0),
- CPU_HTNB_FUNC_00,
- REG_HT_TRAFFIC_DIST_0X164),
- 23, 16, &links01);
- /* DstNode = 1, cHTPrbDistEn = 1, cHTRspDistEn = 1, cHTReqDistEn = 1 */
- temp = 0x0107;
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(0),
- makePCIBusFromNode(0),
- makePCIDeviceFromNode(0),
- CPU_HTNB_FUNC_00,
- REG_HT_TRAFFIC_DIST_0X164),
- 15, 0, &temp);
-
- /* Node 1 */
- /* DstLnk */
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(1),
- makePCIBusFromNode(1),
- makePCIDeviceFromNode(1),
- CPU_HTNB_FUNC_00,
- REG_HT_TRAFFIC_DIST_0X164),
- 23, 16, &links10);
- /* DstNode = 0, cHTPrbDistEn = 1, cHTRspDistEn = 1, cHTReqDistEn = 1 */
- temp = 0x0007;
- AmdPCIWriteBits(MAKE_SBDFO(makePCISegmentFromNode(1),
- makePCIBusFromNode(1),
- makePCIDeviceFromNode(1),
- CPU_HTNB_FUNC_00,
- REG_HT_TRAFFIC_DIST_0X164),
- 15, 0, &temp);
-#endif /* HT_BUILD_NC_ONLY */
-}
-
-/***************************************************************************//**
- *
- * static void
- * ht1WriteTrafficDistribution(u32 links01, u32 links10, cNorthBridge *nb)
- *
- * Description:
- * Traffic distribution is more complex in this case as the routing table must be
- * adjusted to use one link for requests and the other for responses. Also,
- * perform the buffer tunings on the links required for this config.
- *
- * Parameters:
- * @param[in] links01 = coherent links from node 0 to 1
- * @param[in] links10 = coherent links from node 1 to 0
- * @param[in] nb = this northbridge
- *
- ******************************************************************************/
-static void ht1WriteTrafficDistribution(u32 links01, u32 links10, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
- u32 route01, route10;
- u8 req0, req1, rsp0, rsp1, nclink;
-
- /*
- * Get the current request route for 0->1 and 1->0. This will indicate which of the links
- * in links01 are connected to which links in links10. Since we have to route to distribute
- * traffic, we need to know that. The link used by htinit will become the request, probe link.
- * the other link will be used for responses.
- */
-
- /* Get the routes, and hang on to them, we will write them back updated. */
- AmdPCIRead(MAKE_SBDFO(makePCISegmentFromNode(0),
- makePCIBusFromNode(0),
- makePCIDeviceFromNode(0),
- CPU_HTNB_FUNC_00,
- REG_ROUTE1_0X44),
- &route01);
- AmdPCIRead(MAKE_SBDFO(makePCISegmentFromNode(1),
- makePCIBusFromNode(1),
- makePCIDeviceFromNode(1),
- CPU_HTNB_FUNC_00,
- REG_ROUTE0_0X40),
- &route10);
-
- /* Convert the request routes to a link number. Note "0xE" is ht1 nb specific.
- * Find the response link numbers.
- */
- ASSERT((route01 & 0xE) && (route10 & 0xE)); /* no route! error! */
- req0 = (u8)AmdBitScanReverse((route01 & 0xE)) - 1;
- req1 = (u8)AmdBitScanReverse((route10 & 0xE)) - 1;
- /* Now, find the other link for the responses */
- rsp0 = (u8)AmdBitScanReverse((links01 & ~((u32)1 << req0)));
- rsp1 = (u8)AmdBitScanReverse((links10 & ~((u32)1 << req1)));
-
- /* ht1 nb restriction, must have exactly two links */
- ASSERT(((((links01 & ~((u32)1 << req0)) & ~((u32)1 << rsp0))) == 0)
- && ((((links10 & ~((u32)1 << req1)) & ~((u32)1 << rsp1))) == 0));
-
- route01 = (route01 & ~0x0E00) | ((u32)0x0100<<(rsp0 + 1));
- route10 = (route10 & ~0x0E00) | ((u32)0x0100<<(rsp1 + 1));
-
- AmdPCIWrite(MAKE_SBDFO(makePCISegmentFromNode(0),
- makePCIBusFromNode(0),
- makePCIDeviceFromNode(0),
- CPU_HTNB_FUNC_00,
- REG_ROUTE1_0X44),
- &route01);
-
- AmdPCIWrite(MAKE_SBDFO(makePCISegmentFromNode(1),
- makePCIBusFromNode(1),
- makePCIDeviceFromNode(1),
- CPU_HTNB_FUNC_00,
- REG_ROUTE0_0X40),
- &route10);
-
- /* While we otherwise do buffer tunings elsewhere, for the dual cHT DP case with
- * ht1 northbridges like family 0Fh, do the tunings here where we have all the
- * link and route info at hand and don't need to recalculate it.
- */
-
- /* Node 0, Request / Probe Link (note family F only has links < 4) */
- fam0fWriteHTLinkCmdBufferAlloc(0, req0, 6, 3, 1, 6);
- fam0fWriteHTLinkDatBufferAlloc(0, req0, 4, 3, 1);
- /* Node 0, Response Link (note family F only has links < 4) */
- fam0fWriteHTLinkCmdBufferAlloc(0, rsp0, 1, 0, 15, 0);
- fam0fWriteHTLinkDatBufferAlloc(0, rsp0, 1, 1, 6);
- /* Node 1, Request / Probe Link (note family F only has links < 4) */
- fam0fWriteHTLinkCmdBufferAlloc(1, req1, 6, 3, 1, 6);
- fam0fWriteHTLinkDatBufferAlloc(1, req1, 4, 3, 1);
- /* Node 1, Response Link (note family F only has links < 4) */
- fam0fWriteHTLinkCmdBufferAlloc(1, rsp1, 1, 0, 15, 0);
- fam0fWriteHTLinkDatBufferAlloc(1, rsp1, 1, 1, 6);
-
- /* Node 0, is the third link non-coherent? */
- nclink = (u8)AmdBitScanReverse(((u8)0x07 & ~((u32)1 << req0) & ~((u32)1 << rsp0)));
- if (nb->verifyLinkIsNonCoherent(0, nclink, nb))
- {
- fam0fWriteHTLinkCmdBufferAlloc(0, nclink, 6, 5, 2, 0);
- }
-
- /* Node 1, is the third link non-coherent? */
- nclink = (u8)AmdBitScanReverse(((u8)0x07 & ~((u32)1 << req1) & ~((u32)1 << rsp1)));
- if (nb->verifyLinkIsNonCoherent(1, nclink, nb))
- {
- fam0fWriteHTLinkCmdBufferAlloc(1, nclink, 6, 5, 2, 0);
- }
-#endif /* HT_BUILD_NC_ONLY */
-}
-
-/***************************************************************************//**
- *
- * static void
- * fam0fBufferOptimizations(u8 node, sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Buffer tunings are inherently northbridge specific. Check for specific configs
- * which require adjustments and apply any standard workarounds to this node.
- *
- * Parameters:
- * @param[in] node = the node to
- * @param[in] *pDat = coherent links from node 0 to 1
- * @param[in] nb = this northbridge
- *
- ******************************************************************************/
-static void fam0fBufferOptimizations(u8 node, sMainData *pDat, cNorthBridge *nb)
-{
-#ifndef HT_BUILD_NC_ONLY
- u8 i;
- u32 temp;
- SBDFO currentPtr;
-
- ASSERT(node < nb->maxNodes);
-
- /* Fix the FIFO pointer register before changing speeds */
- currentPtr = MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_FIFOPTR_3XDC);
- for (i = 0; i < nb->maxLinks; i++)
- {
- temp = 0;
- if (nb->verifyLinkIsCoherent(node, i, nb))
- {
- temp = 0x26;
- ASSERT(i < 3);
- AmdPCIWriteBits(currentPtr, 8*i + 5, 8*i, &temp);
- }
- else
- {
- if (nb->verifyLinkIsNonCoherent(node, i, nb))
- {
- temp = 0x25;
- ASSERT(i < 3);
- AmdPCIWriteBits(currentPtr, 8*i + 5, 8*i, &temp);
- }
- }
- }
- /*
- * 8P Buffer tuning.
- * Either apply the BKDG tunings or, if applicable, apply the more restrictive errata 153
- * workaround.
- * If 8 nodes, Check this node for 'inner' or 'outer'.
- * Tune each link based on coherent or non-coherent
- */
- if (pDat->NodesDiscovered >= 6)
- {
- u8 j;
- BOOL isOuter;
- BOOL isErrata153;
-
- /* This is for family 0Fh, so assuming dual core max then 7 or 8 nodes are required
- * to be in the situation of 14 or more cores. We checked nodes above, cross check
- * that the number of cores is 14 or more. We want both 14 cores with at least 7 or 8 nodes
- * not one condition alone, to apply the errata 153 workaround. Otherwise, 7 or 8 rev F
- * nodes use the BKDG tuning.
- */
-
- isErrata153 = 0;
-
- AmdPCIReadBits (MAKE_SBDFO(makePCISegmentFromNode(0),
- makePCIBusFromNode(0),
- makePCIDeviceFromNode(0),
- CPU_HTNB_FUNC_00,
- REG_NODE_ID_0X60),
- 19, 16, &temp);
-
- if (temp >= 14)
- {
- /* Check whether we need to do errata 153 tuning or BKDG tuning.
- * Errata 153 applies to JH-1, JH-2 and older. It is fixed in JH-3
- * (and, one assumes, from there on).
- */
- for (i = 0; i < (pDat->NodesDiscovered +1); i++)
- {
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(i),
- makePCIBusFromNode(i),
- makePCIDeviceFromNode(i),
- CPU_NB_FUNC_03,
- REG_NB_CPUID_3XFC),
- 7, 0, &temp);
- if (((u8)temp & ~0x40) < 0x13)
- {
- isErrata153 = 1;
- break;
- }
- }
- }
-
- for (i = 0; i < CPU_ADDR_NUM_CONFIG_MAPS; i++)
- {
- isOuter = FALSE;
- /* Check for outer node by scanning the config maps on node 0 for one
- * which is assigned to this node.
- */
- currentPtr = MAKE_SBDFO(makePCISegmentFromNode(0),
- makePCIBusFromNode(0),
- makePCIDeviceFromNode(0),
- CPU_ADDR_FUNC_01,
- REG_ADDR_CONFIG_MAP0_1XE0 + (4 * i));
- AmdPCIReadBits (currentPtr, 1, 0, &temp);
- /* Make sure this config map is valid, if it is it will be enabled for read/write */
- if (temp == 3)
- {
- /* It's valid, get the node (that node is an outer node) */
- AmdPCIReadBits (currentPtr, 6, 4, &temp);
- /* Is the node we're working on now? */
- if (node == (u8)temp)
- {
- /* This is an outer node. Tune it appropriately. */
- for (j = 0; j < nb->maxLinks; j++)
- {
- if (isErrata153)
- {
- if (nb->verifyLinkIsCoherent(node, j, nb))
- {
- fam0fWriteHTLinkCmdBufferAlloc(node, j, 1, 1, 6, 4);
- }
- else
- {
- if (nb->verifyLinkIsNonCoherent(node, j, nb))
- {
- fam0fWriteHTLinkCmdBufferAlloc(node, j, 5, 4, 1, 0);
- }
- }
- }
- else
- {
- if (nb->verifyLinkIsCoherent(node, j, nb))
- {
- fam0fWriteHTLinkCmdBufferAlloc(node, j, 1, 1, 8, 5);
- }
- }
- }
- /*
- * SRI to XBAR Buffer Counts are correct for outer node at power on defaults.
- */
- isOuter = TRUE;
- break;
- }
- }
- /* We fill config maps in ascending order, so if we didn't use this one, we're done. */
- else break;
- }
- if (!isOuter)
- {
- if (isErrata153)
- {
- /* Tuning for inner node coherent links */
- for (j = 0; j < nb->maxLinks; j++)
- {
- if (nb->verifyLinkIsCoherent(node, j, nb))
- {
- fam0fWriteHTLinkCmdBufferAlloc(node, j, 2, 1, 5, 4);
- }
-
- }
- /* SRI to XBAR Buffer Count for inner nodes, zero DReq and DPReq */
- temp = 0;
- AmdPCIWriteBits (MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_SRI_XBAR_BUF_3X70),
- 31, 28, &temp);
- }
- }
-
- /*
- * Tune MCT to XBAR Buffer Count the same an all nodes, 2 Probes, 5 Response
- */
- if (isErrata153)
- {
- temp = 0x25;
- AmdPCIWriteBits (MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_MCT_XBAR_BUF_3X78),
- 14, 8, &temp);
- }
- }
-#endif /* HT_BUILD_NC_ONLY */
-}
-
-/***************************************************************************//**
- *
- * static void
- * fam10BufferOptimizations(u8 node, sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Buffer tunings are inherently northbridge specific. Check for specific configs
- * which require adjustments and apply any standard workarounds to this node.
- *
- * Parameters:
- * @param[in] node = the node to tune
- * @param[in] *pDat = global state
- * @param[in] nb = this northbridge
- *
- ******************************************************************************/
-static void fam10BufferOptimizations(u8 node, sMainData *pDat, cNorthBridge *nb)
-{
- u32 temp;
- SBDFO currentPtr;
- u8 i;
-
- ASSERT(node < nb->maxNodes);
-
- /*
- * Link to XCS Token Count Tuning
- *
- * For each active link that we reganged (so this unfortunately can't go into the PCI reg
- * table), we have to switch the Link to XCS Token Counts to the ganged state.
- * We do this here for the non-uma case, which is to write the values that would have
- * been power on defaults if the link was ganged at cold reset.
- */
- for (i = 0; i < pDat->TotalLinks*2; i++)
- {
- if ((pDat->PortList[i].NodeID == node) && (pDat->PortList[i].Type == PORTLIST_TYPE_CPU))
- {
- /* If the link is greater than 4, this is a sublink 1, so it is not reganged. */
- if (pDat->PortList[i].Link < 4)
- {
- currentPtr = MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_LINK_XCS_TOKEN0_3X148 + 4*pDat->PortList[i].Link);
- if (pDat->PortList[i].SelRegang)
- {
- /* Handle all the regang Token count adjustments */
-
- /* Sublink 0: [Probe0tok] = 2 [Rsp0tok] = 2 [PReq0tok] = 2 [Req0tok] = 2 */
- temp = 0xAA;
- AmdPCIWriteBits(currentPtr, 7, 0, &temp);
- /* Sublink 1: [Probe1tok] = 0 [Rsp1tok] = 0 [PReq1tok] = 0 [Req1tok] = 0 */
- temp = 0;
- AmdPCIWriteBits(currentPtr, 23, 16, &temp);
- /* [FreeTok] = 3 */
- temp = 3;
- AmdPCIWriteBits(currentPtr, 15, 14, &temp);
- }
- else
- {
- /* Read the regang bit in hardware */
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(pDat->PortList[i].NodeID),
- makePCIBusFromNode(pDat->PortList[i].NodeID),
- makePCIDeviceFromNode(pDat->PortList[i].NodeID),
- CPU_HTNB_FUNC_00,
- REG_HT_LINK_EXT_CONTROL0_0X170 + 4*pDat->PortList[i].Link),
- 0, 0, &temp);
- if (temp == 1)
- {
- /* handle a minor adjustment for stapped ganged links. If SelRegang is false we
- * didn't do the regang, so if the bit is on then it's hardware strapped.
- */
-
- /* [FreeTok] = 3 */
- temp = 3;
- AmdPCIWriteBits(currentPtr, 15, 14, &temp);
- }
- }
- }
- }
- }
-}
-
-/***************************************************************************//**
- *
- * static void
- * fam15BufferOptimizations(u8 node, sMainData *pDat, cNorthBridge *nb)
- *
- * Description:
- * Buffer tunings are inherently northbridge specific. Check for specific configs
- * which require adjustments and apply any standard workarounds to this node.
- *
- * Parameters:
- * @param[in] node = the node to tune
- * @param[in] *pDat = global state
- * @param[in] nb = this northbridge
- *
- ******************************************************************************/
-static void fam15BufferOptimizations(u8 node, sMainData *pDat, cNorthBridge *nb)
-{
- /* Buffer count setup on Family 15h is currently handled in cpuSetAMDPCI */
-}
-
-/*
- * North Bridge 'constructor'.
- *
- */
-
-/***************************************************************************//**
- *
- * void
- * newNorthBridge(u8 node, cNorthBridge *nb)
- *
- * Description:
- * Construct a new northbridge. This routine encapsulates knowledge of how to tell
- * significant differences between families of supported northbridges and what routines
- * can be used in common and which are unique. A fully populated northbridge interface
- * is provided by nb.
- *
- * Parameters:
- * @param node
- * @param[out] nb = the caller's northbridge structure to initialize.
- *
- ******************************************************************************/
-void newNorthBridge(u8 node, cNorthBridge *nb)
-{
- u32 match;
- u32 extFam, baseFam, model;
-
- cNorthBridge fam15 =
- {
-#ifdef HT_BUILD_NC_ONLY
- 8,
- 1,
- 12,
-#else
- 8,
- 8,
- 64,
-#endif /* HT_BUILD_NC_ONLY*/
- writeRoutingTable,
- writeNodeID,
- readDefLnk,
- enableRoutingTables,
- verifyLinkIsCoherent,
- readTrueLinkFailStatus,
- readToken,
- writeToken,
- fam15GetNumCoresOnNode,
- setTotalNodesAndCores,
- limitNodes,
- writeFullRoutingTable,
- isCompatible,
- fam15IsCapable,
- (void (*)(u8, u8, cNorthBridge*))commonVoid,
- (BOOL (*)(u8, u8, sMainData*, cNorthBridge*))commonReturnFalse,
- readSbLink,
- verifyLinkIsNonCoherent,
- ht3SetCFGAddrMap,
- convertBitsToWidth,
- convertWidthToBits,
- fam15NorthBridgeFreqMask,
- gatherLinkData,
- setLinkData,
- ht3WriteTrafficDistribution,
- fam15BufferOptimizations,
- 0x00000001,
- 0x00000200,
- 18,
- 0x00000f06
- };
-
- cNorthBridge fam10 =
- {
-#ifdef HT_BUILD_NC_ONLY
- 8,
- 1,
- 12,
-#else
- 8,
- 8,
- 64,
-#endif /* HT_BUILD_NC_ONLY*/
- writeRoutingTable,
- writeNodeID,
- readDefLnk,
- enableRoutingTables,
- verifyLinkIsCoherent,
- readTrueLinkFailStatus,
- readToken,
- writeToken,
- fam10GetNumCoresOnNode,
- setTotalNodesAndCores,
- limitNodes,
- writeFullRoutingTable,
- isCompatible,
- fam10IsCapable,
- (void (*)(u8, u8, cNorthBridge*))commonVoid,
- (BOOL (*)(u8, u8, sMainData*, cNorthBridge*))commonReturnFalse,
- readSbLink,
- verifyLinkIsNonCoherent,
- ht3SetCFGAddrMap,
- convertBitsToWidth,
- convertWidthToBits,
- fam10NorthBridgeFreqMask,
- gatherLinkData,
- setLinkData,
- ht3WriteTrafficDistribution,
- fam10BufferOptimizations,
- 0x00000001,
- 0x00000200,
- 18,
- 0x00000f01
- };
-
- cNorthBridge fam0f =
- {
-#ifdef HT_BUILD_NC_ONLY
- 3,
- 1,
- 12,
-#else
- 3,
- 8,
- 32,
-#endif /* HT_BUILD_NC_ONLY*/
- writeRoutingTable,
- writeNodeID,
- readDefLnk,
- enableRoutingTables,
- verifyLinkIsCoherent,
- readTrueLinkFailStatus,
- readToken,
- writeToken,
- fam0FGetNumCoresOnNode,
- setTotalNodesAndCores,
- limitNodes,
- writeFullRoutingTable,
- isCompatible,
- fam0fIsCapable,
- fam0fStopLink,
- (BOOL (*)(u8, u8, sMainData*, cNorthBridge*))commonReturnFalse,
- readSbLink,
- verifyLinkIsNonCoherent,
- ht1SetCFGAddrMap,
- convertBitsToWidth,
- convertWidthToBits,
- ht1NorthBridgeFreqMask,
- gatherLinkData,
- setLinkData,
- ht1WriteTrafficDistribution,
- fam0fBufferOptimizations,
- 0x00000001,
- 0x00000100,
- 16,
- 0x00000f00
- };
-
- /* Start with enough of the key to identify the northbridge interface */
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CPUID_3XFC),
- 27, 20, &extFam);
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CPUID_3XFC),
- 11, 8, &baseFam);
- AmdPCIReadBits(MAKE_SBDFO(makePCISegmentFromNode(node),
- makePCIBusFromNode(node),
- makePCIDeviceFromNode(node),
- CPU_NB_FUNC_03,
- REG_NB_CPUID_3XFC),
- 7, 4, &model);
- match = (u32)((baseFam << 8) | extFam);
-
- /* Test each in turn looking for a match.
- * Initialize the struct if found.
- */
- if (match == fam15.compatibleKey)
- {
- Amdmemcpy((void *)nb, (const void *)&fam15, (u32) sizeof(cNorthBridge));
- }
- else if (match == fam10.compatibleKey)
- {
- Amdmemcpy((void *)nb, (const void *)&fam10, (u32) sizeof(cNorthBridge));
- }
- else
- {
- if (match == fam0f.compatibleKey)
- {
- Amdmemcpy((void *)nb, (const void *)&fam0f, (u32) sizeof(cNorthBridge));
- }
- else
- {
- STOP_HERE;
- }
- }
-
- /* Update the initial limited key to the real one, which may include other matching info */
- nb->compatibleKey = makeKey(node);
-}
diff --git a/src/northbridge/amd/amdht/h3ncmn.h b/src/northbridge/amd/amdht/h3ncmn.h
deleted file mode 100644
index db057c0f1c..0000000000
--- a/src/northbridge/amd/amdht/h3ncmn.h
+++ /dev/null
@@ -1,115 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef H3NCMN_H
-#define H3NCMN_H
-
-#include <stdint.h>
-#include <device/pci.h>
-#include <cpu/amd/msr.h>
-
-#include "comlib.h"
-#include "h3finit.h"
-#include "h3ffeat.h"
-
-/* Use a macro to convert a node number to a PCI device. If some future port of
- * this code needs to, this can easily be replaced by a function call:
- * u8 makePCIDeviceFromNode(u8 node);
- */
-#define makePCIDeviceFromNode(node) \
- ((u8)(24 + node))
-
-/* Use a macro to convert a node number to a PCI bus. If some future port of
- * this code needs to, this can easily be replaced by a function call:
- * u8 makePCIBusFromNode(u8 node);
- */
-#define makePCIBusFromNode(node) \
- ((u8)(0))
-
-/* Use a macro to convert a node number to a PCI Segment. If some future port of
- * this code needs to, this can easily be replaced by a function call:
- * u8 makePCISegmentFromNode(u8 node);
- */
-#define makePCISegmentFromNode(node) \
- ((u8)(0))
-
-/* Macros to fix support issues that come up with early sample processors, which
- * sometimes do things like report capabilities that are actually unsupported.
- * Use the build flag, HT_BUILD_EARLY_SAMPLE_CPU_SUPPORT, to enable this support.
- *
- * It's not envisioned this would be replaced by an external function, but the prototype is
- * u16 fixEarlySampleFreqCapability(u16 fc);
- */
-#ifndef HT_BUILD_EARLY_SAMPLE_CPU_SUPPORT
-#define fixEarlySampleFreqCapability(fc) \
- ((u16)fc)
-#else
-#define fixEarlySampleFreqCapability(fc) \
- ((u16)fc & HT_FREQUENCY_LIMIT_HT1_ONLY)
-#endif
-
-struct cNorthBridge
-{
- /* Public data, clients of northbridge can access */
- u8 maxLinks;
- u8 maxNodes;
- u8 maxPlatformLinks;
-
- /* Public Interfaces for northbridge clients, coherent init*/
- void (*writeRoutingTable)(u8 node, u8 target, u8 link, cNorthBridge *nb);
- void (*writeNodeID)(u8 node, u8 nodeID, cNorthBridge *nb);
- u8 (*readDefLnk)(u8 node, cNorthBridge *nb);
- void (*enableRoutingTables)(u8 node, cNorthBridge *nb);
- BOOL (*verifyLinkIsCoherent)(u8 node, u8 link, cNorthBridge *nb);
- BOOL (*readTrueLinkFailStatus)(u8 node, u8 link, sMainData *pDat, cNorthBridge *nb);
- u8 (*readToken)(u8 node, cNorthBridge *nb);
- void (*writeToken)(u8 node, u8 value, cNorthBridge *nb);
- u8 (*getNumCoresOnNode)(u8 node, cNorthBridge *nb);
- void (*setTotalNodesAndCores)(u8 node, u8 totalNodes, u8 totalCores, cNorthBridge *nb);
- void (*limitNodes)(u8 node, cNorthBridge *nb);
- void (*writeFullRoutingTable)(u8 node, u8 target, u8 reqLink, u8 rspLink, u32 bClinks, cNorthBridge *nb);
- BOOL (*isCompatible)(u8 node, cNorthBridge *nb);
- BOOL (*isCapable)(u8 node, sMainData *pDat, cNorthBridge *nb);
- void (*stopLink)(u8 node, u8 link, cNorthBridge *nb);
- BOOL (*handleSpecialLinkCase)(u8 node, u8 link, sMainData *pDat, cNorthBridge *nb);
-
- /* Public Interfaces for northbridge clients, noncoherent init */
- u8 (*readSbLink)(cNorthBridge *nb);
- BOOL (*verifyLinkIsNonCoherent)(u8 node, u8 link, cNorthBridge *nb);
- void (*setCFGAddrMap)(u8 cfgMapIndex, u8 secBus, u8 subBus, u8 targetNode, u8 targetLink, sMainData *pDat, cNorthBridge *nb);
-
- /* Public Interfaces for northbridge clients, Optimization */
- u8 (*convertBitsToWidth)(u8 value, cNorthBridge *nb);
- u8 (*convertWidthToBits)(u8 value, cNorthBridge *nb);
- uint32_t (*northBridgeFreqMask)(u8 node, cNorthBridge *nb);
- void (*gatherLinkData)(sMainData *pDat, cNorthBridge *nb);
- void (*setLinkData)(sMainData *pDat, cNorthBridge *nb);
-
- /* Public Interfaces for northbridge clients, System and performance Tuning. */
- void (*writeTrafficDistribution)(u32 links01, u32 links10, cNorthBridge *nb);
- void (*bufferOptimizations)(u8 node, sMainData *pDat, cNorthBridge *nb);
-
- /* Private Data for northbridge implementation use only */
- u32 selfRouteRequestMask;
- u32 selfRouteResponseMask;
- u8 broadcastSelfBit;
- u32 compatibleKey;
-} ;
-
-void newNorthBridge(u8 node, cNorthBridge *nb);
-uint8_t is_gt_rev_d(void);
-
-#endif /* H3NCMN_H */
diff --git a/src/northbridge/amd/amdht/ht_wrapper.c b/src/northbridge/amd/amdht/ht_wrapper.c
deleted file mode 100644
index 89ff46eae3..0000000000
--- a/src/northbridge/amd/amdht/ht_wrapper.c
+++ /dev/null
@@ -1,384 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/cpu.h>
-#include <cpu/x86/msr.h>
-#include <console/console.h>
-#include <device/pci_ops.h>
-#include "ht_wrapper.h"
-
-/*----------------------------------------------------------------------------
- * TYPEDEFS, DEFINITIONS AND MACROS
- *
- *----------------------------------------------------------------------------
- */
-
-/* Single CPU system? */
-#if (CONFIG_MAX_PHYSICAL_CPUS == 1)
- /* FIXME
- * This #define is used by other #included .c files
- * When set, multiprocessor support is completely disabled
- */
- #define HT_BUILD_NC_ONLY 1
-#endif
-
-/* Debugging Options */
-//#define AMD_DEBUG_ERROR_STOP 1
-
-/*----------------------------------------------------------------------------
- * MODULES USED
- *
- *----------------------------------------------------------------------------
- */
-
-#include "comlib.h"
-#include "h3gtopo.h"
-#include "h3finit.h"
-
-/*----------------------------------------------------------------------------
- * LOCAL FUNCTIONS
- *
- *----------------------------------------------------------------------------
- */
-
-static const char * event_class_string_decodes[] = {
- [HT_EVENT_CLASS_CRITICAL] = "CRITICAL",
- [HT_EVENT_CLASS_ERROR] = "ERROR",
- [HT_EVENT_CLASS_HW_FAULT] = "HARDWARE FAULT",
- [HT_EVENT_CLASS_WARNING] = "WARNING",
- [HT_EVENT_CLASS_INFO] = "INFO"
-};
-
-typedef struct {
- uint32_t code;
- const char *string;
-} event_string_decode_t;
-
-static const event_string_decode_t event_string_decodes[] = {
- { HT_EVENT_COH_EVENTS, "HT_EVENT_COH_EVENTS" },
- { HT_EVENT_COH_NO_TOPOLOGY, "HT_EVENT_COH_NO_TOPOLOGY" },
- { HT_EVENT_COH_LINK_EXCEED, "HT_EVENT_COH_LINK_EXCEED" },
- { HT_EVENT_COH_FAMILY_FEUD, "HT_EVENT_COH_FAMILY_FEUD" },
- { HT_EVENT_COH_NODE_DISCOVERED, "HT_EVENT_COH_NODE_DISCOVERED" },
- { HT_EVENT_COH_MPCAP_MISMATCH, "HT_EVENT_COH_MPCAP_MISMATCH" },
- { HT_EVENT_NCOH_EVENTS, "HT_EVENT_NCOH_EVENTS" },
- { HT_EVENT_NCOH_BUID_EXCEED, "HT_EVENT_NCOH_BUID_EXCEED" },
- { HT_EVENT_NCOH_LINK_EXCEED, "HT_EVENT_NCOH_LINK_EXCEED" },
- { HT_EVENT_NCOH_BUS_MAX_EXCEED, "HT_EVENT_NCOH_BUS_MAX_EXCEED" },
- { HT_EVENT_NCOH_CFG_MAP_EXCEED, "HT_EVENT_NCOH_CFG_MAP_EXCEED" },
- { HT_EVENT_NCOH_DEVICE_FAILED, "HT_EVENT_NCOH_DEVICE_FAILED" },
- { HT_EVENT_NCOH_AUTO_DEPTH, "HT_EVENT_NCOH_AUTO_DEPTH" },
- { HT_EVENT_OPT_EVENTS, "HT_EVENT_OPT_EVENTS" },
- { HT_EVENT_OPT_REQUIRED_CAP_RETRY, "HT_EVENT_OPT_REQUIRED_CAP_RETRY" },
- { HT_EVENT_OPT_REQUIRED_CAP_GEN3, "HT_EVENT_OPT_REQUIRED_CAP_GEN3" },
- { HT_EVENT_HW_EVENTS, "HT_EVENT_HW_EVENTS" },
- { HT_EVENT_HW_SYNCHFLOOD, "HT_EVENT_HW_SYNCHFLOOD" },
- { HT_EVENT_HW_HTCRC, "HT_EVENT_HW_HTCRC" }
-};
-
-static const char *event_string_decode(uint32_t event)
-{
- uint32_t i;
- for (i = 0; i < ARRAY_SIZE(event_string_decodes); i++)
- if (event_string_decodes[i].code == event)
- break;
- if (i == ARRAY_SIZE(event_string_decodes))
- return "ERROR: Unmatched event code! "
- "Did you forget to update event_string_decodes[]?";
- return event_string_decodes[i].string;
-}
-
-/**
- * void AMD_CB_EventNotify (u8 evtClass, u16 event, const u8 *pEventData0)
- */
-static void AMD_CB_EventNotify (u8 evtClass, u16 event, const u8 *pEventData0)
-{
- uint8_t i;
- uint8_t log_level;
- uint8_t dump_event_detail;
-
- printk(BIOS_DEBUG, "%s: ", __func__);
-
- /* Decode event */
- dump_event_detail = 1;
- switch (evtClass) {
- case HT_EVENT_CLASS_CRITICAL:
- case HT_EVENT_CLASS_ERROR:
- case HT_EVENT_CLASS_HW_FAULT:
- case HT_EVENT_CLASS_WARNING:
- case HT_EVENT_CLASS_INFO:
- log_level = BIOS_DEBUG;
- printk(log_level, "%s", event_class_string_decodes[evtClass]);
- break;
- default:
- log_level = BIOS_DEBUG;
- printk(log_level, "UNKNOWN");
- break;
- }
- printk(log_level, ": ");
-
- switch (event) {
- case HT_EVENT_COH_EVENTS:
- case HT_EVENT_COH_NO_TOPOLOGY:
- case HT_EVENT_COH_LINK_EXCEED:
- case HT_EVENT_COH_FAMILY_FEUD:
- printk(log_level, "%s", event_string_decode(event));
- break;
- case HT_EVENT_COH_NODE_DISCOVERED:
- {
- printk(log_level, "HT_EVENT_COH_NODE_DISCOVERED");
- sHtEventCohNodeDiscovered *evt = (sHtEventCohNodeDiscovered*)pEventData0;
- printk(log_level, ": node %d link %d new node: %d",
- evt->node, evt->link, evt->newNode);
- dump_event_detail = 0;
- break;
- }
- case HT_EVENT_COH_MPCAP_MISMATCH:
- case HT_EVENT_NCOH_EVENTS:
- case HT_EVENT_NCOH_BUID_EXCEED:
- case HT_EVENT_NCOH_LINK_EXCEED:
- case HT_EVENT_NCOH_BUS_MAX_EXCEED:
- case HT_EVENT_NCOH_CFG_MAP_EXCEED:
- printk(log_level, "%s", event_string_decode(event));
- break;
- case HT_EVENT_NCOH_DEVICE_FAILED:
- {
- printk(log_level, "%s", event_string_decode(event));
- sHtEventNcohDeviceFailed *evt = (sHtEventNcohDeviceFailed*)pEventData0;
- printk(log_level, ": node %d link %d depth: %d attemptedBUID: %d",
- evt->node, evt->link, evt->depth, evt->attemptedBUID);
- dump_event_detail = 0;
- break;
- }
- case HT_EVENT_NCOH_AUTO_DEPTH:
- {
- printk(log_level, "%s", event_string_decode(event));
- sHtEventNcohAutoDepth *evt = (sHtEventNcohAutoDepth*)pEventData0;
- printk(log_level, ": node %d link %d depth: %d",
- evt->node, evt->link, evt->depth);
- dump_event_detail = 0;
- break;
- }
- case HT_EVENT_OPT_EVENTS:
- case HT_EVENT_OPT_REQUIRED_CAP_RETRY:
- case HT_EVENT_OPT_REQUIRED_CAP_GEN3:
- case HT_EVENT_HW_EVENTS:
- case HT_EVENT_HW_SYNCHFLOOD:
- case HT_EVENT_HW_HTCRC:
- printk(log_level, "%s", event_string_decode(event));
- break;
- default:
- printk(log_level, "HT_EVENT_UNKNOWN");
- break;
- }
- printk(log_level, "\n");
-
- if (dump_event_detail) {
- printk(BIOS_DEBUG, " event class: %02x\n event: %04x\n data: ", evtClass, event);
-
- for (i = 0; i < *pEventData0; i++) {
- printk(BIOS_DEBUG, " %02x ", *(pEventData0 + i));
- }
- printk(BIOS_DEBUG, "\n");
- }
-}
-
-/**
- * void getAmdTopolist(u8 ***p)
- *
- * point to the stock topo list array
- *
- */
-void getAmdTopolist(u8 ***p)
-{
- *p = (u8 **)amd_topo_list;
-}
-
-/**
- * BOOL AMD_CB_IgnoreLink(u8 Node, u8 Link)
- * Description:
- * This routine is used to ignore connected yet faulty HT links,
- * such as those present in a G34 processor package.
- *
- * Parameters:
- * @param[in] node = The node on which this chain is located
- * @param[in] link = The link on the host for this chain
- */
-static BOOL AMD_CB_IgnoreLink (u8 node, u8 link)
-{
- return 0;
-}
-
-/**
- * void amd_ht_init(struct sys_info *sysinfo)
- *
- * AMD HT init coreboot wrapper
- *
- */
-void amd_ht_init(struct sys_info *sysinfo)
-{
-
- if (!sysinfo) {
- printk(BIOS_DEBUG, "Skipping %s\n", __func__);
- return;
- }
-
- AMD_HTBLOCK ht_wrapper = {
- NULL, // u8 **topolist;
- 0, // u8 AutoBusStart;
- 32, // u8 AutoBusMax;
- 6, // u8 AutoBusIncrement;
- AMD_CB_IgnoreLink, // BOOL (*AMD_CB_IgnoreLink)();
- NULL, // BOOL (*AMD_CB_OverrideBusNumbers)();
- AMD_CB_ManualBUIDSwapList, // BOOL (*AMD_CB_ManualBUIDSwapList)();
- NULL, // void (*AMD_CB_DeviceCapOverride)();
- NULL, // void (*AMD_CB_Cpu2CpuPCBLimits)();
- NULL, // void (*AMD_CB_IOPCBLimits)();
- NULL, // BOOL (*AMD_CB_SkipRegang)();
- NULL, // BOOL (*AMD_CB_CustomizeTrafficDistribution)();
- NULL, // BOOL (*AMD_CB_CustomizeBuffers)();
- NULL, // void (*AMD_CB_OverrideDevicePort)();
- NULL, // void (*AMD_CB_OverrideCpuPort)();
- AMD_CB_EventNotify, // void (*AMD_CB_EventNotify) ();
- &sysinfo->ht_link_cfg // struct ht_link_config*
- };
-
- printk(BIOS_DEBUG, "Enter %s\n", __func__);
- amdHtInitialize(&ht_wrapper);
- printk(BIOS_DEBUG, "Exit %s\n", __func__);
-}
-
-/**
- * void amd_ht_fixup(struct sys_info *sysinfo)
- *
- * AMD HT fixup
- *
- */
-void amd_ht_fixup(struct sys_info *sysinfo) {
- printk(BIOS_DEBUG, "%s\n", __func__);
- if (CONFIG(CPU_AMD_MODEL_10XXX)) {
- uint8_t rev_gte_d = 0;
- uint8_t fam15h = 0;
- uint8_t dual_node = 0;
- uint32_t f3xe8;
- uint32_t family;
- uint32_t model;
-
- family = model = cpuid_eax(0x80000001);
- model = ((model & 0xf0000) >> 12) | ((model & 0xf0) >> 4);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- if ((model >= 0x8) || fam15h)
- /* Family 10h Revision D or later */
- rev_gte_d = 1;
-
- if (rev_gte_d) {
- f3xe8 = pci_read_config32(NODE_PCI(0, 3), 0xe8);
-
- /* Check for dual node capability */
- if (f3xe8 & 0x20000000)
- dual_node = 1;
-
- if (dual_node) {
- /* Each G34 processor contains a defective HT link.
- * See the Family 10h BKDG Rev 3.62 section 2.7.1.5 for details
- * For Family 15h see the BKDG Rev. 3.14 section 2.12.1.5 for details.
- */
- uint8_t node;
- uint8_t node_count = get_nodes();
- uint32_t dword;
- for (node = 0; node < node_count; node++) {
- f3xe8 = pci_read_config32(NODE_PCI(node, 3), 0xe8);
- uint8_t internal_node_number = ((f3xe8 & 0xc0000000) >> 30);
- printk(BIOS_DEBUG,
- "%s: node %d (internal node "
- "ID %d): disabling defective "
- "HT link", __func__, node,
- internal_node_number);
- if (internal_node_number == 0) {
- uint8_t package_link_3_connected = pci_read_config32(NODE_PCI(node, 0), (fam15h)?0x98:0xd8) & 0x1;
- printk(BIOS_DEBUG, " (L3 connected: %d)\n", package_link_3_connected);
- if (package_link_3_connected) {
- /* Set WidthIn and WidthOut to 0 */
- dword = pci_read_config32(NODE_PCI(node, 0), (fam15h)?0x84:0xc4);
- dword &= ~0x77000000;
- pci_write_config32(NODE_PCI(node, 0), (fam15h)?0x84:0xc4, dword);
- /* Set Ganged to 1 */
- dword = pci_read_config32(NODE_PCI(node, 0), (fam15h)?0x170:0x178);
- dword |= 0x00000001;
- pci_write_config32(NODE_PCI(node, 0), (fam15h)?0x170:0x178, dword);
- } else {
- /* Set ConnDly to 1 */
- dword = pci_read_config32(NODE_PCI(node, 0), 0x16c);
- dword |= 0x00000100;
- pci_write_config32(NODE_PCI(node, 0), 0x16c, dword);
- /* Set TransOff and EndOfChain to 1 */
- dword = pci_read_config32(NODE_PCI(node, 4), (fam15h)?0x84:0xc4);
- dword |= 0x000000c0;
- pci_write_config32(NODE_PCI(node, 4), (fam15h)?0x84:0xc4, dword);
- }
- } else if (internal_node_number == 1) {
- uint8_t package_link_3_connected = pci_read_config32(NODE_PCI(node, 0), (fam15h)?0xf8:0xb8) & 0x1;
- printk(BIOS_DEBUG, " (L3 connected: %d)\n", package_link_3_connected);
- if (package_link_3_connected) {
- /* Set WidthIn and WidthOut to 0 */
- dword = pci_read_config32(NODE_PCI(node, 0), (fam15h)?0xe4:0xa4);
- dword &= ~0x77000000;
- pci_write_config32(NODE_PCI(node, 0), (fam15h)?0xe4:0xa4, dword);
- /* Set Ganged to 1 */
- /* WARNING
- * The Family 15h BKDG states that 0x18c should be set,
- * however this is in error. 0x17c is the correct control
- * register (sublink 0) for these processors...
- */
- dword = pci_read_config32(NODE_PCI(node, 0), (fam15h)?0x17c:0x174);
- dword |= 0x00000001;
- pci_write_config32(NODE_PCI(node, 0), (fam15h)?0x17c:0x174, dword);
- } else {
- /* Set ConnDly to 1 */
- dword = pci_read_config32(NODE_PCI(node, 0), 0x16c);
- dword |= 0x00000100;
- pci_write_config32(NODE_PCI(node, 0), 0x16c, dword);
- /* Set TransOff and EndOfChain to 1 */
- dword = pci_read_config32(NODE_PCI(node, 4), (fam15h)?0xe4:0xa4);
- dword |= 0x000000c0;
- pci_write_config32(NODE_PCI(node, 4), (fam15h)?0xe4:0xa4, dword);
- }
- }
- }
- }
- }
- }
-}
-
-u32 get_nodes(void)
-{
- pci_devfn_t dev;
- u32 nodes;
-
- dev = PCI_DEV(CONFIG_CBB, CONFIG_CDB, 0);
- nodes = ((pci_read_config32(dev, 0x60)>>4) & 7);
-#if CONFIG_MAX_PHYSICAL_CPUS > 8
- nodes += (((pci_read_config32(dev, 0x160)>>4) & 7)<<3);
-#endif
- nodes++;
-
- return nodes;
-}
diff --git a/src/northbridge/amd/amdht/ht_wrapper.h b/src/northbridge/amd/amdht/ht_wrapper.h
deleted file mode 100644
index 629e08f4fe..0000000000
--- a/src/northbridge/amd/amdht/ht_wrapper.h
+++ /dev/null
@@ -1,28 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef AMD_HT_WRAPPER_H
-#define AMD_HT_WRAPPER_H
-
-#include <northbridge/amd/amdfam10/raminit.h>
-#include <northbridge/amd/amdfam10/amdfam10.h>
-#include <stdint.h>
-#include "h3finit.h"
-
-void amd_ht_fixup(struct sys_info *sysinfo);
-u32 get_nodes(void);
-void amd_ht_init(struct sys_info *sysinfo);
-
-#endif
diff --git a/src/northbridge/amd/amdht/porting.h b/src/northbridge/amd/amdht/porting.h
deleted file mode 100644
index 9058d4d0e1..0000000000
--- a/src/northbridge/amd/amdht/porting.h
+++ /dev/null
@@ -1,79 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef PORTING_H
-#define PORTING_H
-
-
-/* For AMD64 or 32-bit GCC */
-typedef int int32;
-typedef unsigned int uint32;
-typedef short int16;
-typedef unsigned short uint16;
-typedef char int8;
-typedef unsigned char uint8;
-
-/* Create the Boolean type */
-#define TRUE 1
-#define FALSE 0
-typedef unsigned char BOOL;
-
-/* Force tight packing of structures */
-#pragma pack(1)
-
-#define CALLCONV
-
-
-typedef struct _uint64
-{
- uint32 lo;
- uint32 hi;
-}uint64;
-
-
-/*
- * SBDFO - Segment Bus Device Function Offset
- * 31:28 Segment (4-bits)
- * 27:20 Bus (8-bits)
- * 19:15 Device (5-bits)
- * 14:12 Function(3-bits)
- * 11:00 Offset (12-bits)
- */
-typedef uint32 SBDFO;
-
-#define MAKE_SBDFO(seg,bus,dev,fun,off) ((((uint32)(seg))<<28) | (((uint32)(bus))<<20) | \
- (((uint32)(dev))<<15) | (((uint32)(fun))<<12) | ((uint32)(off)))
-#define SBDFO_SEG(x) (((uint32)(x)>>28) & 0x0F)
-#define SBDFO_BUS(x) (((uint32)(x)>>20) & 0xFF)
-#define SBDFO_DEV(x) (((uint32)(x)>>15) & 0x1F)
-#define SBDFO_FUN(x) (((uint32)(x)>>12) & 0x07)
-#define SBDFO_OFF(x) (((uint32)(x)) & 0xFFF)
-#define ILLEGAL_SBDFO 0xFFFFFFFF
-
-void CALLCONV AmdMSRRead(uint32 Address, uint64 *Value);
-void CALLCONV AmdMSRWrite(uint32 Address, uint64 *Value);
-void CALLCONV AmdIORead(uint8 IOSize, uint16 Address, uint32 *Value);
-void CALLCONV AmdIOWrite(uint8 IOSize, uint16 Address, uint32 *Value);
-void CALLCONV AmdMemRead(uint8 MemSize, uint64 *Address, uint32 *Value);
-void CALLCONV AmdMemWrite(uint8 MemSize, uint64 *Address, uint32 *Value);
-void CALLCONV AmdPCIRead(SBDFO loc, uint32 *Value);
-void CALLCONV AmdPCIWrite(SBDFO loc, uint32 *Value);
-void CALLCONV AmdCPUIDRead(uint32 Address, uint32 Regs[4]);
-
-#define BYTESIZE 1
-#define WORDSIZE 2
-#define DWORDSIZE 4
-
-#endif /* PORTING_H */
diff --git a/src/northbridge/amd/amdk8/amdk8.h b/src/northbridge/amd/amdk8/amdk8.h
deleted file mode 100644
index 2b821b7c9e..0000000000
--- a/src/northbridge/amd/amdk8/amdk8.h
+++ /dev/null
@@ -1,31 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef AMDK8_H
-#define AMDK8_H
-
-#define HT_INIT_CONTROL 0x6C
-#define HTIC_ColdR_Detect (1<<4)
-#define HTIC_BIOSR_Detect (1<<5)
-#define HTIC_INIT_Detect (1<<6)
-
-#define NODE_HT(x) PCI_DEV(0,24+x,0)
-#define NODE_MP(x) PCI_DEV(0,24+x,1)
-#define NODE_MC(x) PCI_DEV(0,24+x,3)
-
-void set_bios_reset(void);
-void distinguish_cpu_resets(unsigned int nodeid);
-unsigned int get_sblk(void);
-unsigned int get_sbbusn(unsigned int sblk);
-
-#endif /* AMDK8_H */
diff --git a/src/northbridge/amd/amdk8/reset_test.c b/src/northbridge/amd/amdk8/reset_test.c
deleted file mode 100644
index 214aed448a..0000000000
--- a/src/northbridge/amd/amdk8/reset_test.c
+++ /dev/null
@@ -1,94 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <device/pci_ops.h>
-#include <stdint.h>
-#include <cpu/x86/lapic.h>
-#include "amdk8.h"
-
-static inline int cpu_init_detected(unsigned int nodeid)
-{
- u32 htic;
- pci_devfn_t dev;
-
- dev = PCI_DEV(0, 0x18 + nodeid, 0);
- htic = pci_io_read_config32(dev, HT_INIT_CONTROL);
-
- return !!(htic & HTIC_INIT_Detect);
-}
-
-static inline int bios_reset_detected(void)
-{
- u32 htic;
- htic = pci_io_read_config32(PCI_DEV(0, 0x18, 0), HT_INIT_CONTROL);
-
- return (htic & HTIC_ColdR_Detect) && !(htic & HTIC_BIOSR_Detect);
-}
-
-static inline int cold_reset_detected(void)
-{
- u32 htic;
- htic = pci_io_read_config32(PCI_DEV(0, 0x18, 0), HT_INIT_CONTROL);
-
- return !(htic & HTIC_ColdR_Detect);
-}
-
-void distinguish_cpu_resets(unsigned int nodeid)
-{
- u32 htic;
- pci_devfn_t device;
- device = PCI_DEV(0, 0x18 + nodeid, 0);
- htic = pci_io_read_config32(device, HT_INIT_CONTROL);
- htic |= HTIC_ColdR_Detect | HTIC_BIOSR_Detect | HTIC_INIT_Detect;
- pci_io_write_config32(device, HT_INIT_CONTROL, htic);
-}
-
-void set_bios_reset(void)
-{
- u32 htic;
- htic = pci_io_read_config32(PCI_DEV(0, 0x18, 0), HT_INIT_CONTROL);
- htic &= ~HTIC_BIOSR_Detect;
- pci_io_write_config32(PCI_DEV(0, 0x18, 0), HT_INIT_CONTROL, htic);
-}
-
-static unsigned int node_link_to_bus(unsigned int node, unsigned int link)
-{
- u8 reg;
-
- for (reg = 0xE0; reg < 0xF0; reg += 0x04) {
- u32 config_map;
- config_map = pci_io_read_config32(PCI_DEV(0, 0x18, 1), reg);
- if ((config_map & 3) != 3) {
- continue;
- }
- if ((((config_map >> 4) & 7) == node) &&
- (((config_map >> 8) & 3) == link))
- {
- return (config_map >> 16) & 0xff;
- }
- }
- return 0;
-}
-
-unsigned int get_sblk(void)
-{
- u32 reg;
- /* read PCI_DEV(0,0x18,0) 0x64 bit [8:9] to find out SbLink m */
- reg = pci_io_read_config32(PCI_DEV(0, 0x18, 0), 0x64);
- return ((reg>>8) & 3);
-}
-
-unsigned int get_sbbusn(unsigned int sblk)
-{
- return node_link_to_bus(0, sblk);
-}
diff --git a/src/northbridge/amd/amdmct/amddefs.h b/src/northbridge/amd/amdmct/amddefs.h
deleted file mode 100644
index 1a442082ff..0000000000
--- a/src/northbridge/amd/amdmct/amddefs.h
+++ /dev/null
@@ -1,158 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-#ifndef AMDDEFS_H
-#define AMDDEFS_H
-
-/* FIXME: this file should be moved to include/cpu/amd/amddefs.h */
-
-/* Public Revisions - USE THESE VERSIONS TO MAKE COMPARE WITH CPULOGICALID RETURN VALUE*/
-#define AMD_SAFEMODE 0x8000000000000000 /* Unknown future revision - SAFE MODE */
-#define AMD_NPT_F0 0x0000000000000001 /* F0 stepping */
-#define AMD_NPT_F1 0x0000000000000002 /* F1 stepping */
-#define AMD_NPT_F2C 0x0000000000000004
-#define AMD_NPT_F2D 0x0000000000000008
-#define AMD_NPT_F2E 0x0000000000000010 /* F2 stepping E */
-#define AMD_NPT_F2G 0x0000000000000020 /* F2 stepping G */
-#define AMD_NPT_F2J 0x0000000000000040
-#define AMD_NPT_F2K 0x0000000000000080
-#define AMD_NPT_F3L 0x0000000000000100 /* F3 Stepping */
-#define AMD_NPT_G0A 0x0000000000000200 /* G0 stepping */
-#define AMD_NPT_G1B 0x0000000000000400 /* G1 stepping */
-#define AMD_DR_A0A 0x0000000000010000 /* Barcelona A0 */
-#define AMD_DR_A1B 0x0000000000020000 /* Barcelona A1 */
-#define AMD_DR_A2 0x0000000000040000 /* Barcelona A2 */
-#define AMD_DR_B0 0x0000000000080000 /* Barcelona B0 */
-#define AMD_DR_B1 0x0000000000100000 /* Barcelona B1 */
-#define AMD_DR_B2 0x0000000000200000 /* Barcelona B2 */
-#define AMD_DR_BA 0x0000000000400000 /* Barcelona BA */
-#define AMD_DR_B3 0x0000000000800000 /* Barcelona B3 */
-#define AMD_RB_C2 0x0000000001000000 /* Shanghai C2 */
-#define AMD_DA_C2 0x0000000002000000 /* XXXX C2 */
-#define AMD_HY_D0 0x0000000004000000 /* Istanbul D0 */
-#define AMD_RB_C3 0x0000000008000000 /* ??? C3 */
-#define AMD_DA_C3 0x0000000010000000 /* XXXX C3 */
-#define AMD_HY_D1 0x0000000020000000 /* Istanbul D1 */
-#define AMD_PH_E0 0x0000000040000000 /* Phenom II X4 X6 */
-#define AMD_OR_B2 0x0000000080000000 /* Interlagos */
-#define AMD_OR_C0 0x0000000100000000 /* Abu Dhabi */
-
-/*
- * Groups - Create as many as you wish, from the above public values
- */
-#define AMD_NPT_F2 (AMD_NPT_F2C | AMD_NPT_F2D | AMD_NPT_F2E | AMD_NPT_F2G | AMD_NPT_F2J | AMD_NPT_F2K)
-#define AMD_NPT_F3 (AMD_NPT_F3L)
-#define AMD_NPT_Fx (AMD_NPT_F0 | AMD_NPT_F1 | AMD_NPT_F2 | AMD_NPT_F3)
-#define AMD_NPT_Gx (AMD_NPT_G0A | AMD_NPT_G1B)
-#define AMD_NPT_ALL (AMD_NPT_Fx | AMD_NPT_Gx)
-#define AMD_FINEDELAY (AMD_NPT_F0 | AMD_NPT_F1 | AMD_NPT_F2)
-#define AMD_GT_F0 (AMD_NPT_ALL AND NOT AMD_NPT_F0)
-#define AMD_DR_Ax (AMD_DR_A0A + AMD_DR_A1B + AMD_DR_A2)
-#define AMD_DR_Bx (AMD_DR_B0 | AMD_DR_B1 | AMD_DR_B2 | AMD_DR_B3 | AMD_DR_BA)
-#define AMD_DR_Cx (AMD_RB_C2 | AMD_RB_C3 | AMD_DA_Cx)
-#define AMD_DR_Dx (AMD_HY_D0 | AMD_HY_D1)
-#define AMD_DR_Ex (AMD_PH_E0)
-#define AMD_DR_LT_B2 (AMD_DR_B0 | AMD_DR_B1 | AMD_DR_BA)
-#define AMD_DR_LT_B3 (AMD_DR_B0 | AMD_DR_B1 | AMD_DR_B2 | AMD_DR_BA)
-#define AMD_DR_GT_B0 (AMD_DR_ALL & ~(AMD_DR_B0))
-#define AMD_DR_GT_Bx (AMD_DR_ALL & ~(AMD_DR_Ax | AMD_DR_Bx))
-#define AMD_DR_GT_D0 ((AMD_DR_Dx & ~(AMD_HY_D0)) | AMD_DR_Ex)
-#define AMD_DR_ALL (AMD_DR_Ax | AMD_DR_Bx | AMD_DR_Cx | AMD_DR_Dx | AMD_DR_Ex)
-#define AMD_FAM10_ALL (AMD_DR_ALL | AMD_RB_C2 | AMD_HY_D0 | AMD_DA_C3 | AMD_DA_C2 | AMD_RB_C3 | AMD_HY_D1 | AMD_PH_E0)
-#define AMD_FAM10_LT_D (AMD_FAM10_ALL & ~(AMD_HY_D0))
-#define AMD_FAM10_GT_B0 (AMD_FAM10_ALL & ~(AMD_DR_B0))
-#define AMD_FAM10_REV_D (AMD_HY_D0 | AMD_HY_D1)
-#define AMD_DA_Cx (AMD_DA_C2 | AMD_DA_C3)
-#define AMD_FAM10_C3 (AMD_RB_C3 | AMD_DA_C3)
-#define AMD_DRBH_Cx (AMD_DR_Cx | AMD_HY_D0)
-#define AMD_DRBA23_RBC2 (AMD_DR_BA | AMD_DR_B2 | AMD_DR_B3 | AMD_RB_C2)
-#define AMD_DR_DAC2_OR_C3 (AMD_DA_C2 | AMD_DA_C3 | AMD_RB_C3)
-#define AMD_FAM15_ALL (AMD_OR_B2 | AMD_OR_C0)
-
-/*
- * Public Platforms - USE THESE VERSIONS TO MAKE COMPARE WITH CPUPLATFORMTYPE RETURN VALUE
- */
-#define AMD_PTYPE_DSK 0x001 /* Desktop/DTR/UP */
-#define AMD_PTYPE_MOB 0x002 /* Mobile/Cool-n-quiet */
-#define AMD_PTYPE_SVR 0x004 /* Workstation/Server/Multicore DT */
-#define AMD_PTYPE_UC 0x008 /* Single Core */
-#define AMD_PTYPE_DC 0x010 /* Dual Core */
-#define AMD_PTYPE_MC 0x020 /* Multi Core (>2) */
-#define AMD_PTYPE_UMA 0x040 /* UMA required */
-
-/*
- * Groups - Create as many as you wish, from the above public values
- */
-#define AMD_PTYPE_ALL 0xFFFFFFFF /* A mask for all */
-
-
-/*
- * CPU PCI HT PHY REGISTER, LINK TYPES - PRIVATE
- */
-#define HTPHY_LINKTYPE_HT3 0x00000001
-#define HTPHY_LINKTYPE_HT1 0x00000002
-#define HTPHY_LINKTYPE_COHERENT 0x00000004
-#define HTPHY_LINKTYPE_NONCOHERENT 0x00000008
-#define HTPHY_LINKTYPE_CONNECTED (HTPHY_LINKTYPE_COHERENT | HTPHY_LINKTYPE_NONCOHERENT)
-#define HTPHY_LINKTYPE_GANGED 0x00000010
-#define HTPHY_LINKTYPE_UNGANGED 0x00000020
-#define HTPHY_LINKTYPE_ALL 0x7FFFFFFF
-
-
-/*
- * CPU HT PHY REGISTERS, FIELDS, AND MASKS
- */
-#define HTPHY_OFFSET_MASK 0xE000FFFF
-#define HTPHY_WRITE_CMD 0x40000000
-#define HTPHY_IS_COMPLETE_MASK 0x80000000
-#define HTPHY_DIRECT_MAP 0x20000000
-#define HTPHY_DIRECT_OFFSET_MASK 0xE000FFFF
-
-/*
- * Processor package types
- */
-#define AMD_PKGTYPE_FrX_1207 0
-#define AMD_PKGTYPE_AM3_2r2 1
-#define AMD_PKGTYPE_S1gX 2
-#define AMD_PKGTYPE_G34 3
-#define AMD_PKGTYPE_ASB2 4
-#define AMD_PKGTYPE_C32 5
-#define AMD_PKGTYPE_FM2 6
-
-//DDR2 REG and unbuffered : Socket F 1027 and AM3
-/* every channel have 4 DDR2 DIMM for socket F
- * 2 for socket M2/M3
- * 1 for socket s1g1
- */
-#define DIMM_SOCKETS 4
-struct mem_controller {
- u32 node_id;
- pci_devfn_t f0, f1, f2, f3, f4, f5;
- /* channel0 is DCT0 --- channelA
- * channel1 is DCT1 --- channelB
- * can be ganged, a single dual-channel DCT ---> 128 bit
- * or unganged a two single-channel DCTs ---> 64bit
- * When the DCTs are ganged, the writes to DCT1 set of registers
- * (F2x1XX) are ignored and reads return all 0's
- * The exception is the DCT phy registers, F2x[1,0]98, F2x[1,0]9C,
- * and all the associated indexed registers, are still
- * independently accessiable
- */
- /* FIXME: I will only support ganged mode for easy support */
- u8 spd_switch_addr;
- u8 spd_addr[DIMM_SOCKETS*2];
-};
-
-#endif
diff --git a/src/northbridge/amd/amdmct/mct/Makefile.inc b/src/northbridge/amd/amdmct/mct/Makefile.inc
deleted file mode 100644
index f986201c6d..0000000000
--- a/src/northbridge/amd/amdmct/mct/Makefile.inc
+++ /dev/null
@@ -1,16 +0,0 @@
-ifeq ($(CONFIG_NORTHBRIDGE_AMD_AMDFAM10),y)
-
-# DDR2
-romstage-y += mct_d.c mct_d_gcc.c mctcsi_d.c mctmtr_d.c mctecc_d.c
-romstage-y += mctpro_d.c mctdqs_d.c mctsrc.c mctsrc1p.c mcttmrl.c
-romstage-y += mcthdi.c mctndi_d.c mctchi_d.c
-
-ifeq ($(CONFIG_CPU_SOCKET_TYPE), 0x10)
-romstage-y += mctardk3.c
-endif
-
-ifeq ($(CONFIG_CPU_SOCKET_TYPE), 0x11)
-romstage-y += mctardk4.c
-endif
-
-endif
diff --git a/src/northbridge/amd/amdmct/mct/mct.h b/src/northbridge/amd/amdmct/mct/mct.h
deleted file mode 100644
index 598ab37e76..0000000000
--- a/src/northbridge/amd/amdmct/mct/mct.h
+++ /dev/null
@@ -1,539 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef MCT_H
-#define MCT_H
-
-#include <stdint.h>
-
-/*===========================================================================
- CPU - K8/FAM10
-===========================================================================*/
-#define PT_L1 0 /* CPU Package Type*/
-#define PT_M2 1
-#define PT_S1 2
-
-#define J_MIN 0 /* j loop constraint. 1 = CL 2.0 T*/
-#define J_MAX 4 /* j loop constraint. 4 = CL 6.0 T*/
-#define K_MIN 1 /* k loop constraint. 1 = 200 MHz*/
-#define K_MAX 4 /* k loop constraint. 9 = 400 MHz*/
-#define CL_DEF 2 /* Default value for failsafe operation. 2 = CL 4.0 T*/
-#define T_DEF 1 /* Default value for failsafe operation. 1 = 5ns (cycle time)*/
-
-#define BSCRate 1 /* reg bit field = rate of dram scrubber for ecc*/
- /* memory initialization (ecc and check-bits).*/
- /* 1 = 40 ns/64 bytes.*/
-#define FirstPass 1 /* First pass through RcvEn training*/
-#define SecondPass 2 /* Second pass through Rcven training*/
-
-#define RCVREN_MARGIN 6 /* number of DLL taps to delay beyond first passing position*/
-#define MAXASYNCLATCTL_3 60 /* Max Async Latency Control value (This value will be divided by 20)*/
-#define DQS_FAIL 1
-#define DQS_PASS 0
-#define DQS_WRITEDIR 0
-#define DQS_READDIR 1
-#define MIN_DQS_WNDW 3
-#define secPassOffset 6
-
-#define PA_HOST (((24 << 3)+0) << 8) /* Node 0 Host Bus function PCI Address bits [15:0] */
-#define PA_MAP (((24 << 3)+1) << 8) /* Node 0 MAP function PCI Address bits [15:0] */
-#define PA_DCT (((24 << 3)+2) << 8) /* Node 0 DCT function PCI Address bits [15:0] */
-#define PA_DCTADDL (((00 << 3)+2) << 8) /* Node x DCT function, Additional Registers PCI Address bits [15:0] */
-#define PA_NBMISC (((24 << 3)+3) << 8) /* Node 0 Misc PCI Address bits [15:0] */
-#define PA_NBDEVOP (((00 << 3)+3) << 8) /* Node 0 Misc PCI Address bits [15:0] */
-
-#define DCC_EN 1 /* X:2:0x94[19]*/
-#define ILD_Lmt 3 /* X:2:0x94[18:16]*/
-
-#define EncodedTSPD 0x00191709 /* encodes which SPD byte to get T from*/
- /* versus CL X, CL X-.5, and CL X-1*/
-
-#define Bias_TrpT 3 /* bias to convert bus clocks to bit field value*/
-#define Bias_TrrdT 2
-#define Bias_TrcdT 3
-#define Bias_TrasT 3
-#define Bias_TrcT 11
-#define Bias_TrtpT 4
-#define Bias_TwrT 3
-#define Bias_TwtrT 0
-
-#define Min_TrpT 3 /* min programmable value in busclocks*/
-#define Max_TrpT 6 /* max programmable value in busclocks*/
-#define Min_TrrdT 2
-#define Max_TrrdT 5
-#define Min_TrcdT 3
-#define Max_TrcdT 6
-#define Min_TrasT 5
-#define Max_TrasT 18
-#define Min_TrcT 11
-#define Max_TrcT 26
-#define Min_TrtpT 4
-#define Max_TrtpT 5
-#define Min_TwrT 3
-#define Max_TwrT 6
-#define Min_TwtrT 1
-#define Max_TwtrT 3
-
-/* common register bit names */
-#define DramHoleValid 0 /* func 1, offset F0h, bit 0 */
-#define CSEnable 0 /* func 2, offset 40h-5C, bit 0 */
-#define Spare 1 /* func 2, offset 40h-5C, bit 1 */
-#define TestFail 2 /* func 2, offset 40h-5C, bit 2 */
-#define DqsRcvEnTrain 18 /* func 2, offset 78h, bit 18 */
-#define EnDramInit 31 /* func 2, offset 7Ch, bit 31 */
-#define DisAutoRefresh 18 /* func 2, offset 8Ch, bit 18 */
-#define InitDram 0 /* func 2, offset 90h, bit 0 */
-#define BurstLength32 10 /* func 2, offset 90h, bit 10 */
-#define Width128 11 /* func 2, offset 90h, bit 11 */
-#define X4Dimm 12 /* func 2, offset 90h, bit 12 */
-#define UnBuffDimm 16 /* func 2, offset 90h, bit 16 */
-#define DimmEcEn 19 /* func 2, offset 90h, bit 19 */
-#define MemClkFreqVal 3 /* func 2, offset 94h, bit 3 */
-#define RDqsEn 12 /* func 2, offset 94h, bit 12 */
-#define DisDramInterface 14 /* func 2, offset 94h, bit 14 */
-#define DctAccessWrite 30 /* func 2, offset 98h, bit 30 */
-#define DctAccessDone 31 /* func 2, offset 98h, bit 31 */
-#define PwrSavingsEn 10 /* func 2, offset A0h, bit 10 */
-#define Mod64BitMux 4 /* func 2, offset A0h, bit 4 */
-#define DisableJitter 1 /* func 2, offset A0h, bit 1 */
-#define DramEnabled 9 /* func 2, offset A0h, bit 9 */
-#define SyncOnUcEccEn 2 /* func 3, offset 44h, bit 2 */
-
-/*=============================================================================
- Jedec DDR II
-=============================================================================*/
-#define SPD_TYPE 2 /* SPD byte read location*/
- #define JED_DDRSDRAM 0x07 /* Jedec defined bit field*/
- #define JED_DDR2SDRAM 0x08 /* Jedec defined bit field*/
-
-#define SPD_DIMMTYPE 20
-#define SPD_ATTRIB 21
- #define JED_DIFCKMSK 0x20 /* Differential Clock Input*/
- #define JED_REGADCMSK 0x11 /* Registered Address/Control*/
- #define JED_PROBEMSK 0x40 /* Analysis Probe installed*/
-#define SPD_DEVATTRIB 22
-#define SPD_EDCTYPE 11
- #define JED_ECC 0x02
- #define JED_ADRCPAR 0x04
-#define SPD_ROWSZ 3
-#define SPD_COLSZ 4
-#define SPD_LBANKS 17 /* number of [logical] banks on each device*/
-#define SPD_DMBANKS 5 /* number of physical banks on dimm*/
- #define SPDPLBit 4 /* Dram package bit*/
-#define SPD_BANKSZ 31 /* capacity of physical bank*/
-#define SPD_DEVWIDTH 13
-#define SPD_CASLAT 18
-#define SPD_TRP 27
-#define SPD_TRRD 28
-#define SPD_TRCD 29
-#define SPD_TRAS 30
-#define SPD_TWR 36
-#define SPD_TWTR 37
-#define SPD_TRTP 38
-#define SPD_TRCRFC 40
-#define SPD_TRC 41
-#define SPD_TRFC 42
-
-#define SPD_MANDATEYR 93 /* Module Manufacturing Year (BCD) */
-
-#define SPD_MANDATEWK 94 /* Module Manufacturing Week (BCD) */
-
-/*--------------------------------------
- Jedec DDR II related equates
---------------------------------------*/
-#define MYEAR06 6 /* Manufacturing Year BCD encoding of 2006 - 06d*/
-#define MWEEK24 0x24 /* Manufacturing Week BCD encoding of June - 24d*/
-
-/*=============================================================================
- Macros
-=============================================================================*/
-
-#define _2GB_RJ8 (2<<(30-8))
-#define _4GB_RJ8 (4<<(30-8))
-#define _4GB_RJ4 (4<<(30-4))
-
-#define BigPagex8_RJ8 (1<<(17+3-8)) /* 128KB * 8 >> 8 */
-
-/*=============================================================================
- Global MCT Status Structure
-=============================================================================*/
-struct MCTStatStruc {
- u32 GStatus; /* Global Status bitfield*/
- u32 HoleBase; /* If not zero, BASE[39:8] (system address)
- of sub 4GB dram hole for HW remapping.*/
- u32 Sub4GCacheTop; /* If not zero, the 32-bit top of cacheable memory.*/
- u32 SysLimit; /* LIMIT[39:8] (system address)*/
-};
-/*=============================================================================
- Global MCT Configuration Status Word (GStatus)
-=============================================================================*/
-/*These should begin at bit 0 of GStatus[31:0]*/
-#define GSB_MTRRshort 0 /* Ran out of MTRRs while mapping memory*/
-#define GSB_ECCDIMMs 1 /* All banks of all Nodes are ECC capable*/
-#define GSB_DramECCDis 2 /* Dram ECC requested but not enabled.*/
-#define GSB_SoftHole 3 /* A Node Base gap was created*/
-#define GSB_HWHole 4 /* A HW dram remap was created*/
-#define GSB_NodeIntlv 5 /* Node Memory interleaving was enabled*/
-#define GSB_SpIntRemapHole 16 /* Special condition for Node Interleave and HW remapping*/
-
-
-/*===============================================================================
- Local DCT Status structure (a structure for each DCT)
-===============================================================================*/
-
-struct DCTStatStruc { /* A per Node structure*/
- u8 Node_ID; /* Node ID of current controller*/
- u8 ErrCode; /* Current error condition of Node
- 0= no error
- 1= Variance Error, DCT is running but not in an optimal configuration.
- 2= Stop Error, DCT is NOT running
- 3= Fatal Error, DCT/MCT initialization has been halted.*/
- u32 ErrStatus; /* Error Status bit Field */
- u32 Status; /* Status bit Field*/
- u8 DIMMAddr[8]; /* SPD address of DIMM controlled by MA0_CS_L[0,1]*/
- /* SPD address of..MB0_CS_L[0,1]*/
- /* SPD address of..MA1_CS_L[0,1]*/
- /* SPD address of..MB1_CS_L[0,1]*/
- /* SPD address of..MA2_CS_L[0,1]*/
- /* SPD address of..MB2_CS_L[0,1]*/
- /* SPD address of..MA3_CS_L[0,1]*/
- /* SPD address of..MB3_CS_L[0,1]*/
- u16 DIMMPresent; /* For each bit n 0..7, 1 = DIMM n is present.
- DIMM# Select Signal
- 0 MA0_CS_L[0,1]
- 1 MB0_CS_L[0,1]
- 2 MA1_CS_L[0,1]
- 3 MB1_CS_L[0,1]
- 4 MA2_CS_L[0,1]
- 5 MB2_CS_L[0,1]
- 6 MA3_CS_L[0,1]
- 7 MB3_CS_L[0,1]*/
- u16 DIMMValid; /* For each bit n 0..7, 1 = DIMM n is valid and is/will be configured*/
- u16 DIMMSPDCSE; /* For each bit n 0..7, 1 = DIMM n SPD checksum error*/
- u16 DimmECCPresent; /* For each bit n 0..7, 1 = DIMM n is ECC capable.*/
- u16 DimmPARPresent; /* For each bit n 0..7, 1 = DIMM n is ADR/CMD Parity capable.*/
- u16 Dimmx4Present; /* For each bit n 0..7, 1 = DIMM n contains x4 data devices.*/
- u16 Dimmx8Present; /* For each bit n 0..7, 1 = DIMM n contains x8 data devices.*/
- u16 Dimmx16Present; /* For each bit n 0..7, 1 = DIMM n contains x16 data devices.*/
- u16 DIMM1Kpage; /* For each bit n 0..7, 1 = DIMM n contains 1K page devices.*/
- u8 MAload[2]; /* Number of devices loading MAA bus*/
- /* Number of devices loading MAB bus*/
- u8 MAdimms[2]; /* Number of DIMMs loading CH A*/
- /* Number of DIMMs loading CH B*/
- u8 DATAload[2]; /* Number of ranks loading CH A DATA*/
- /* Number of ranks loading CH B DATA*/
- u8 DIMMAutoSpeed; /* Max valid Mfg. Speed of DIMMs
- 1 = 200MHz
- 2 = 266MHz
- 3 = 333MHz
- 4 = 400MHz */
- u8 DIMMCASL; /* Min valid Mfg. CL bitfield
- 0 = 2.0
- 1 = 3.0
- 2 = 4.0
- 3 = 5.0
- 4 = 6.0 */
- u16 DIMMTrcd; /* Minimax Trcd*40 (ns) of DIMMs*/
- u16 DIMMTrp; /* Minimax Trp*40 (ns) of DIMMs*/
- u16 DIMMTrtp; /* Minimax Trtp*40 (ns) of DIMMs*/
- u16 DIMMTras; /* Minimax Tras*40 (ns) of DIMMs*/
- u16 DIMMTrc; /* Minimax Trc*40 (ns) of DIMMs*/
- u16 DIMMTwr; /* Minimax Twr*40 (ns) of DIMMs*/
- u16 DIMMTrrd; /* Minimax Trrd*40 (ns) of DIMMs*/
- u16 DIMMTwtr; /* Minimax Twtr*40 (ns) of DIMMs*/
- u8 Speed; /* Bus Speed (to set Controller)
- 1 = 200MHz
- 2 = 266MHz
- 3 = 333MHz
- 4 = 400MHz */
- u8 CASL; /* CAS latency DCT setting
- 0 = 2.0
- 1 = 3.0
- 2 = 4.0
- 3 = 5.0
- 4 = 6.0 */
- u8 Trcd; /* DCT Trcd (busclocks) */
- u8 Trp; /* DCT Trp (busclocks) */
- u8 Trtp; /* DCT Trtp (busclocks) */
- u8 Tras; /* DCT Tras (busclocks) */
- u8 Trc; /* DCT Trc (busclocks) */
- u8 Twr; /* DCT Twr (busclocks) */
- u8 Trrd; /* DCT Trrd (busclocks) */
- u8 Twtr; /* DCT Twtr (busclocks) */
- u8 Trfc[4]; /* DCT Logical DIMM0 Trfc
- 0 = 75ns (for 256Mb devs)
- 1 = 105ns (for 512Mb devs)
- 2 = 127.5ns (for 1Gb devs)
- 3 = 195ns (for 2Gb devs)
- 4 = 327.5ns (for 4Gb devs) */
- /* DCT Logical DIMM1 Trfc (see Trfc0 for format) */
- /* DCT Logical DIMM2 Trfc (see Trfc0 for format) */
- /* DCT Logical DIMM3 Trfc (see Trfc0 for format) */
- u16 CSPresent; /* For each bit n 0..7, 1 = Chip-select n is present */
- u16 CSTestFail; /* For each bit n 0..7, 1 = Chip-select n is present but disabled */
- u32 DCTSysBase; /* BASE[39:8] (system address) of this Node's DCTs. */
- u32 DCTHoleBase; /* If not zero, BASE[39:8] (system address) of dram hole for HW remapping. Dram hole exists on this Node's DCTs. */
- u32 DCTSysLimit; /* LIMIT[39:8] (system address) of this Node's DCTs */
- u16 PresetmaxFreq; /* Maximum OEM defined DDR frequency
- 200 = 200MHz (DDR400)
- 266 = 266MHz (DDR533)
- 333 = 333MHz (DDR667)
- 400 = 400MHz (DDR800) */
- u8 _2Tmode; /* 1T or 2T CMD mode (slow access mode)
- 1 = 1T
- 2 = 2T */
- u8 TrwtTO; /* DCT TrwtTO (busclocks)*/
- u8 Twrrd; /* DCT Twrrd (busclocks)*/
- u8 Twrwr; /* DCT Twrwr (busclocks)*/
- u8 Trdrd; /* DCT Trdrd (busclocks)*/
- u32 CH_ODC_CTL[2]; /* Output Driver Strength (see BKDG FN2:Offset 9Ch, index 00h*/
- u32 CH_ADDR_TMG[2]; /* Address Bus Timing (see BKDG FN2:Offset 9Ch, index 04h*/
- /* Output Driver Strength (see BKDG FN2:Offset 9Ch, index 20h*/
- /* Address Bus Timing (see BKDG FN2:Offset 9Ch, index 24h*/
- u16 CH_EccDQSLike[2]; /* CHA DQS ECC byte like...*/
- u8 CH_EccDQSScale[2]; /* CHA DQS ECC byte scale*/
-// u8 reserved_b_1; /* Reserved*/
- /* CHB DQS ECC byte like...*/
- /* CHB DQS ECC byte scale*/
-// u8 reserved_b_2; /*Reserved*/
- u8 MaxAsyncLat; /* Max Asynchronous Latency (ns)*/
- u8 CH_B_DQS[2][2][9]; /* CHA Byte 0 - 7 and Check Write DQS Delay*/
- /* Reserved*/
- /* CHA Byte 0 - 7 and Check Read DQS Delay*/
- /* Reserved*/
- /* CHB Byte 0 - 7 and Check Write DQS Delay*/
- /* Reserved*/
- /* CHB Byte 0 - 7 and Check Read DQS Delay*/
- /* Reserved*/
- u8 CH_D_RCVRDLY[2][4]; /* CHA DIMM 0 - 3 Receiver Enable Delay*/
- /* CHB DIMM 0 - 3 Receiver Enable Delay*/
- u32 PtrPatternBufA; /* Ptr on stack to aligned DQS testing pattern*/
- u32 PtrPatternBufB; /*Ptr on stack to aligned DQS testing pattern*/
- u8 Channel; /* Current Channel (0= CH A, 1 = CH B)*/
- u8 ByteLane; /* Current Byte Lane (0..7)*/
- u8 Direction; /* Current DQS-DQ training write direction (0 = read, 1 = write)*/
- u8 Pattern; /* Current pattern*/
- u8 DQSDelay; /* Current DQS delay value*/
- u32 TrainErrors; /* Current Training Errors*/
-// u8 reserved_b_3; /* RSVD */
- u32 AMC_TSC_DeltaLo; /* Time Stamp Counter measurement of AMC, Low dword*/
- u32 AMC_TSC_DeltaHi; /* Time Stamp Counter measurement of AMC, High dword*/
- u8 CH_B_Dly[2][2][2][8]; /* CH A byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH A byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- /* CH A byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH A byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- u32 LogicalCPUID; /* The logical CPUID of the node*/
- u16 HostBiosSrvc1; /* Word sized general purpose field for use by host BIOS. Scratch space.*/
- u32 HostBiosSrvc2; /* Dword sized general purpose field for use by host BIOS. Scratch space.*/
- u16 DimmQRPresent; /* QuadRank DIMM present?*/
- u16 DimmTrainFail; /* Bitmap showing which dimms failed training*/
- u16 CSTrainFail; /* Bitmap showing which chipselects failed training*/
- u16 DimmYr06; /* Bitmap indicating which Dimms have a manufactur's year code <= 2006*/
- u16 DimmWk2406; /* Bitmap indicating which Dimms have a manufactur's week code <= 24 of 2006 (June)*/
- u16 DimmDRPresent; /* Bitmap indicating that Dual Rank Dimms are present*/
- u16 DimmPlPresent; /* Bitmap indicating that Planar (1) or Stacked (0) Dimms are present.*/
- u16 ChannelTrainFail; /* Bitmap showing the channel information about failed Chip Selects*/
- /* 0 in any bit field indicates Channel 0*/
- /* 1 in any bit field indicates Channel 1*/
-};
-
-/*===============================================================================
- Local Error Status Codes (DCTStatStruc.ErrCode)
-===============================================================================*/
-#define SC_RunningOK 0
-#define SC_VarianceErr 1 /* Running non-optimally*/
-#define SC_StopError 2 /* Not Running*/
-#define SC_FatalErr 3 /* Fatal Error, MCTB has exited immediately*/
-
-/*===============================================================================
- Local Error Status (DCTStatStruc.ErrStatus[31:0])
- ===============================================================================*/
-#define SB_NoDimms 0
-#define SB_DIMMChkSum 1
-#define SB_DimmMismatchM 2 /* dimm module type(buffer) mismatch*/
-#define SB_DimmMismatchT 3 /* dimm CL/T mismatch*/
-#define SB_DimmMismatchO 4 /* dimm organization mismatch (128-bit)*/
-#define SB_NoTrcTrfc 5 /* SPD missing Trc or Trfc info*/
-#define SB_NoCycTime 6 /* SPD missing byte 23 or 25*/
-#define SB_BkIntDis 7 /* Bank interleave requested but not enabled*/
-#define SB_DramECCDis 8 /* Dram ECC requested but not enabled*/
-#define SB_SpareDis 9 /* Online spare requested but not enabled*/
-#define SB_MinimumMode 10 /* Running in Minimum Mode*/
-#define SB_NORCVREN 11 /* No DQS Receiver Enable pass window found*/
-#define SB_CHA2BRCVREN 12 /* DQS Rcvr En pass window CHA to CH B too large*/
-#define SB_SmallRCVR 13 /* DQS Rcvr En pass window too small (far right of dynamic range)*/
-#define SB_NODQSPOS 14 /* No DQS-DQ passing positions*/
-#define SB_SMALLDQS 15 /* DQS-DQ passing window too small*/
-
-/*===============================================================================
- Local Configuration Status (DCTStatStruc.Status[31:0])
-===============================================================================*/
-#define SB_Registered 0 /* All DIMMs are Registered*/
-#define SB_ECCDIMMs 1 /* All banks ECC capable*/
-#define SB_PARDIMMs 2 /* All banks Addr/CMD Parity capable*/
-#define SB_DiagClks 3 /* Jedec ALL slots clock enable diag mode*/
-#define SB_128bitmode 4 /* DCT in 128-bit mode operation*/
-#define SB_64MuxedMode 5 /* DCT in 64-bit mux'ed mode.*/
-#define SB_2TMode 6 /* 2T CMD timing mode is enabled.*/
-#define SB_SWNodeHole 7 /* Remapping of Node Base on this Node to create a gap.*/
-#define SB_HWHole 8 /* Memory Hole created on this Node using HW remapping.*/
-
-
-
-/*===============================================================================
- NVRAM/run-time-configurable Items
-===============================================================================*/
-/* Platform Configuration */
-#define NV_PACK_TYPE 0 /* CPU Package Type (2-bits)
- 0 = NPT L1
- 1 = NPT M2
- 2 = NPT S1*/
-#define NV_MAX_NODES 1 /* Number of Nodes/Sockets (4-bits)*/
-#define NV_MAX_DIMMS 2 /* Number of DIMM slots for the specified Node ID (4-bits)*/
-#define NV_MAX_MEMCLK 3 /* Maximum platform demonstrated Memclock (10-bits)
- 200 = 200MHz (DDR400)
- 266 = 266MHz (DDR533)
- 333 = 333MHz (DDR667)
- 400 = 400MHz (DDR800)*/
-#define NV_ECC_CAP 4 /* Bus ECC capable (1-bits)
- 0 = Platform not capable
- 1 = Platform is capable*/
-#define NV_4RANKType 5 /* Quad Rank DIMM slot type (2-bits)
- 0 = Normal
- 1 = R4 (4-Rank Registered DIMMs in AMD server configuration)
- 2 = S4 (Unbuffered SO-DIMMs)*/
-#define NV_BYPMAX 6 /* Value to set DcqBypassMax field (See Function 2, Offset 94h, [27:24] of BKDG for field definition).
- 4 = 4 times bypass (normal for non-UMA systems)
- 7 = 7 times bypass (normal for UMA systems)*/
-#define NV_RDWRQBYP 7 /* Value to set RdWrQByp field (See Function 2, Offset A0h, [3:2] of BKDG for field definition).
- 2 = 8 times (normal for non-UMA systems)
- 3 = 16 times (normal for UMA systems)*/
-
-
-/* Dram Timing */
-#define NV_MCTUSRTMGMODE 10 /* User Memclock Mode (2-bits)
- 0 = Auto, no user limit
- 1 = Auto, user limit provided in NV_MemCkVal
- 2 = Manual, user value provided in NV_MemCkVal*/
-#define NV_MemCkVal 11 /* Memory Clock Value (2-bits)
- 0 = 200MHz
- 1 = 266MHz
- 2 = 333MHz
- 3 = 400MHz*/
-
-/* Dram Configuration */
-#define NV_BankIntlv 20 /* Dram Bank (chip-select) Interleaving (1-bits)
- 0 = disable
- 1 = enable*/
-#define NV_AllMemClks 21 /* Turn on All DIMM clocks (1-bits)
- 0 = normal
- 1 = enable all memclocks*/
-#define NV_SPDCHK_RESTRT 22 /* SPD Check control bitmap (1-bits)
- 0 = Exit current node init if any DIMM has SPD checksum error
- 1 = Ignore faulty SPD checksums (Note: DIMM cannot be enabled)*/
-#define NV_DQSTrainCTL 23 /* DQS Signal Timing Training Control
- 0 = skip DQS training
- 1 = perform DQS training*/
-#define NV_NodeIntlv 24 /* Node Memory Interleaving (1-bits)
- 0 = disable
- 1 = enable*/
-#define NV_BurstLen32 25 /* burstLength32 for 64-bit mode (1-bits)
- 0 = disable (normal)
- 1 = enable (4 beat burst when width is 64-bits)*/
-
-/* Dram Power */
-#define NV_CKE_PDEN 30 /* CKE based power down mode (1-bits)
- 0 = disable
- 1 = enable*/
-#define NV_CKE_CTL 31 /* CKE based power down control (1-bits)
- 0 = per Channel control
- 1 = per Chip select control*/
-#define NV_CLKHZAltVidC3 32 /* Memclock tri-stating during C3 and Alt VID (1-bits)
- 0 = disable
- 1 = enable*/
-
-/* Memory Map/Mgt.*/
-#define NV_BottomIO 40 /* Bottom of 32-bit IO space (8-bits)
- NV_BottomIO[7:0]=Addr[31:24]*/
-#define NV_BottomUMA 41 /* Bottom of shared graphics dram (8-bits)
- NV_BottomUMA[7:0]=Addr[31:24]*/
-#define NV_MemHole 42 /* Memory Hole Remapping (1-bits)
- 0 = disable
- 1 = enable */
-
-/* ECC */
-#define NV_ECC 50 /* Dram ECC enable*/
-#define NV_NBECC 52 /* ECC MCE enable*/
-#define NV_ChipKill 53 /* Chip-Kill ECC Mode enable*/
-#define NV_ECCRedir 54 /* Dram ECC Redirection enable*/
-#define NV_DramBKScrub 55 /* Dram ECC Background Scrubber CTL*/
-#define NV_L2BKScrub 56 /* L2 ECC Background Scrubber CTL*/
-#define NV_DCBKScrub 57 /* DCache ECC Background Scrubber CTL*/
-#define NV_CS_SpareCTL 58 /* Chip Select Spare Control bit 0:
- 0 = disable Spare
- 1 = enable Spare */
- /*Chip Select Spare Control bit 1-4:
- Reserved, must be zero*/
-#define NV_Parity 60 /* Parity Enable*/
-#define NV_SyncOnUnEccEn 61 /* SyncOnUnEccEn control
- 0 = disable
- 1 = enable*/
-
-
-/* global function */
-u32 NodePresent(u32 Node);
-u32 Get_NB32n(struct DCTStatStruc *pDCTstat, u32 addrx);
-u32 Get_NB32(u32 addr); /* NOTE: extend addr to 32 bit for bus > 0 */
-uint64_t mctGetLogicalCPUID(u32 Node);
-
-void K8FInterleaveBanks(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-
-void mctInitWithWritetoCS(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-
-void mctGet_PS_Cfg(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void Get_ChannelPS_Cfg0(unsigned int MAAdimms, unsigned int Speed, unsigned int MAAload, unsigned int DATAAload,
- unsigned int *AddrTmgCTL, unsigned int *ODC_CTL);
-void Get_ChannelPS_Cfg1(unsigned int MAAdimms, unsigned int Speed, unsigned int MAAload,
- unsigned int *AddrTmgCTL, unsigned int *ODC_CTL, unsigned int *val);
-void Get_ChannelPS_Cfg2(unsigned int MAAdimms, unsigned int Speed, unsigned int MAAload,
- unsigned int *AddrTmgCTL, unsigned int *ODC_CTL, unsigned int *val);
-
-u8 MCTDefRet(void);
-
-u32 Get_RcvrSysAddr(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 channel, u8 receiver, u8 *valid);
-u32 Get_MCTSysAddr(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 channel, u8 chipsel, u8 *valid);
-void K8FTrainReceiverEn(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA, u8 pass);
-void K8FTrainDQSPos(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-u32 SetUpperFSbase(u32 addr_hi);
-
-
-void K8FECCInit(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-
-void amd_MCTInit(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-
-void K8FCPUMemTyping(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void K8FCPUMemTyping_clear(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-
-void K8FWaitMemClrDelay(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-unsigned int K8FCalcFinalDQSRcvValue(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, unsigned int LeftRcvEn, unsigned int RightRcvEn, unsigned int *valid);
-
-void K8FGetDeltaTSCPart1(struct DCTStatStruc *pDCTstat);
-void K8FGetDeltaTSCPart2(struct DCTStatStruc *pDCTstat);
-#endif
diff --git a/src/northbridge/amd/amdmct/mct/mct_d.c b/src/northbridge/amd/amdmct/mct/mct_d.c
deleted file mode 100644
index 60a2c66de3..0000000000
--- a/src/northbridge/amd/amdmct/mct/mct_d.c
+++ /dev/null
@@ -1,3980 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015-2017 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* Description: Main memory controller system configuration for DDR 2 */
-
-
-/* KNOWN ISSUES - ERRATA
- *
- * Trtp is not calculated correctly when the controller is in 64-bit mode, it
- * is 1 busclock off. No fix planned. The controller is not ordinarily in
- * 64-bit mode.
- *
- * 32 Byte burst not supported. No fix planned. The controller is not
- * ordinarily in 64-bit mode.
- *
- * Trc precision does not use extra Jedec defined fractional component.
- * Instead Trc (course) is rounded up to nearest 1 ns.
- *
- * Mini and Micro DIMM not supported. Only RDIMM, UDIMM, SO-DIMM defined types
- * supported.
- */
-
-#include <string.h>
-#include <console/console.h>
-#include <cpu/amd/msr.h>
-#include <device/pci_ops.h>
-
-#include "mct_d.h"
-
-static u8 ReconfigureDIMMspare_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void DQSTiming_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void LoadDQSSigTmgRegs_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void HTMemMapInit_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void DCTMemClr_Sync_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void SyncDCTsReady_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void StartupDCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void ClearDCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 AutoCycTiming_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void GetPresetmaxF_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void SPDGetTCL_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 AutoConfig_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 PlatformSpec_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 mct_PlatformSpec(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void SPDSetBanks_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void StitchMemory_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 Get_DefTrc_k_D(u8 k);
-static u16 Get_40Tk_D(u8 k);
-static u16 Get_Fk_D(u8 k);
-static u8 Dimm_Supports_D(struct DCTStatStruc *pDCTstat, u8 i, u8 j, u8 k);
-static u8 Sys_Capability_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, int j, int k);
-static u8 Get_DIMMAddress_D(struct DCTStatStruc *pDCTstat, u8 i);
-static void mct_initDCT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_DramInit(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_SyncDCTsReady(struct DCTStatStruc *pDCTstat);
-static void Get_Trdrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_AfterGetCLT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 mct_SPDCalcWidth(struct MCTStatStruc *pMCTstat,\
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_AfterStitchMemory(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 mct_DIMMPresence(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Set_OtherTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Get_Twrwr(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Get_Twrrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Get_TrwtTO(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Get_TrwtWB(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static u8 Check_DqsRcvEn_Diff(struct DCTStatStruc *pDCTstat, u8 dct,
- u32 dev, u32 index_reg, u32 index);
-static u8 Get_DqsRcvEnGross_Diff(struct DCTStatStruc *pDCTstat,
- u32 dev, u32 index_reg);
-static u8 Get_WrDatGross_Diff(struct DCTStatStruc *pDCTstat, u8 dct,
- u32 dev, u32 index_reg);
-static u16 Get_DqsRcvEnGross_MaxMin(struct DCTStatStruc *pDCTstat,
- u32 dev, u32 index_reg, u32 index);
-static void mct_FinalMCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static u16 Get_WrDatGross_MaxMin(struct DCTStatStruc *pDCTstat, u8 dct,
- u32 dev, u32 index_reg, u32 index);
-static void mct_InitialMCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_init(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void clear_legacy_Mode(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_HTMemMapExt(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void SetCSTriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void SetODTTriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void InitPhyCompensation(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u32 mct_NodePresent_D(void);
-static void WaitRoutine_D(u32 time);
-static void mct_OtherTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void mct_ResetDataStruct_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void mct_EarlyArbEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_BeforeDramInit_Prod_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void mct_ClrClToNB_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static u8 CheckNBCOFEarlyArbEn(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void mct_ClrWbEnhWsbDis_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_BeforeDQSTrain_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void AfterDramInit_D(struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_ResetDLL_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u32 mct_DisDllShutdownSR(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 DramConfigLo, u8 dct);
-static void mct_EnDllShutdownSR(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-
-/*See mctAutoInitMCT header for index relationships to CL and T*/
-static const u16 Table_F_k[] = {00,200,266,333,400,533 };
-static const u8 Table_T_k[] = {0x00,0x50,0x3D,0x30,0x25, 0x18 };
-static const u8 Table_CL2_j[] = {0x04,0x08,0x10,0x20,0x40, 0x80 };
-static const u8 Tab_defTrc_k[] = {0x0,0x41,0x3C,0x3C,0x3A, 0x3A };
-static const u16 Tab_40T_k[] = {00,200,150,120,100,75 };
-static const u8 Tab_BankAddr[] = {0x0,0x08,0x09,0x10,0x0C,0x0D,0x11,0x0E,0x15,0x16,0x0F,0x17};
-static const u8 Tab_tCL_j[] = {0,2,3,4,5};
-static const u8 Tab_1KTfawT_k[] = {00,8,10,13,14,20};
-static const u8 Tab_2KTfawT_k[] = {00,10,14,17,18,24};
-static const u8 Tab_L1CLKDis[] = {8,8,6,4,2,0,8,8};
-static const u8 Tab_M2CLKDis[] = {2,0,8,8,2,0,2,0};
-static const u8 Tab_S1CLKDis[] = {8,0,8,8,8,0,8,0};
-static const u8 Table_Comp_Rise_Slew_20x[] = {7, 3, 2, 2, 0xFF};
-static const u8 Table_Comp_Rise_Slew_15x[] = {7, 7, 3, 2, 0xFF};
-static const u8 Table_Comp_Fall_Slew_20x[] = {7, 5, 3, 2, 0xFF};
-static const u8 Table_Comp_Fall_Slew_15x[] = {7, 7, 5, 3, 0xFF};
-
-const u8 Table_DQSRcvEn_Offset[] = {0x00,0x01,0x10,0x11,0x2};
-
-void mctAutoInitMCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /*
- * Memory may be mapped contiguously all the way up to 4GB (depending
- * on setup options). It is the responsibility of PCI subsystem to
- * create an uncacheable IO region below 4GB and to adjust TOP_MEM
- * downward prior to any IO mapping or accesses. It is the same
- * responsibility of the CPU sub-system prior to accessing LAPIC.
- *
- * Slot Number is an external convention, and is determined by OEM with
- * accompanying silk screening. OEM may choose to use Slot number
- * convention which is consistent with DIMM number conventions.
- * All AMD engineering
- * platforms do.
- *
- * Run-Time Requirements:
- * 1. Complete Hypertransport Bus Configuration
- * 2. SMBus Controller Initialized
- * 3. Checksummed or Valid NVRAM bits
- * 4. MCG_CTL=-1, MC4_CTL_EN = 0 for all CPUs
- * 5. MCi_STS from shutdown/warm reset recorded (if desired) prior to
- * entry
- * 6. All var MTRRs reset to zero
- * 7. State of NB_CFG.DisDatMsk set properly on all CPUs
- * 8. All CPUs at 2GHz Speed (unless DQS training is not installed).
- * 9. All cHT links at max Speed/Width (unless DQS training is not
- * installed).
- *
- *
- * Global relationship between index values and item values:
- * j CL(j) k F(k)
- * --------------------------
- * 0 2.0 - -
- * 1 3.0 1 200 MHz
- * 2 4.0 2 266 MHz
- * 3 5.0 3 333 MHz
- * 4 6.0 4 400 MHz
- * 5 7.0 5 533 MHz
- */
- u8 Node, NodesWmem;
- u32 node_sys_base;
-
-restartinit:
- mctInitMemGPIOs_A_D(); /* Set any required GPIOs*/
- NodesWmem = 0;
- node_sys_base = 0;
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- pDCTstat->Node_ID = Node;
- pDCTstat->dev_host = PA_HOST(Node);
- pDCTstat->dev_map = PA_MAP(Node);
- pDCTstat->dev_dct = PA_DCT(Node);
- pDCTstat->dev_nbmisc = PA_NBMISC(Node);
- pDCTstat->NodeSysBase = node_sys_base;
-
- if (mctGet_NVbits(NV_PACK_TYPE) == PT_GR) {
- uint32_t dword;
- pDCTstat->Dual_Node_Package = 1;
-
- /* Get the internal node number */
- dword = Get_NB32(pDCTstat->dev_nbmisc, 0xe8);
- dword = (dword >> 30) & 0x3;
- pDCTstat->Internal_Node_ID = dword;
- } else {
- pDCTstat->Dual_Node_Package = 0;
- }
-
- print_tx("mctAutoInitMCT_D: mct_init Node ", Node);
- mct_init(pMCTstat, pDCTstat);
- mctNodeIDDebugPort_D();
- pDCTstat->NodePresent = NodePresent_D(Node);
- if (pDCTstat->NodePresent) { /* See if Node is there*/
- print_t("mctAutoInitMCT_D: clear_legacy_Mode\n");
- clear_legacy_Mode(pMCTstat, pDCTstat);
- pDCTstat->LogicalCPUID = mctGetLogicalCPUID_D(Node);
-
- print_t("mctAutoInitMCT_D: mct_InitialMCT_D\n");
- mct_InitialMCT_D(pMCTstat, pDCTstat);
-
- print_t("mctAutoInitMCT_D: mctSMBhub_Init\n");
- mctSMBhub_Init(Node); /* Switch SMBUS crossbar to proper node*/
-
- print_t("mctAutoInitMCT_D: mct_initDCT\n");
- mct_initDCT(pMCTstat, pDCTstat);
- if (pDCTstat->ErrCode == SC_FatalErr) {
- goto fatalexit; /* any fatal errors?*/
- } else if (pDCTstat->ErrCode < SC_StopError) {
- NodesWmem++;
- }
- } /* if Node present */
- node_sys_base = pDCTstat->NodeSysBase;
- node_sys_base += (pDCTstat->NodeSysLimit + 2) & ~0x0F;
- }
- if (NodesWmem == 0) {
- printk(BIOS_DEBUG, "No Nodes?!\n");
- goto fatalexit;
- }
-
- print_t("mctAutoInitMCT_D: SyncDCTsReady_D\n");
- SyncDCTsReady_D(pMCTstat, pDCTstatA); /* Make sure DCTs are ready for accesses.*/
-
- print_t("mctAutoInitMCT_D: HTMemMapInit_D\n");
- HTMemMapInit_D(pMCTstat, pDCTstatA); /* Map local memory into system address space.*/
- mctHookAfterHTMap();
-
- print_t("mctAutoInitMCT_D: CPUMemTyping_D\n");
- CPUMemTyping_D(pMCTstat, pDCTstatA); /* Map dram into WB/UC CPU cacheability */
- mctHookAfterCPU(); /* Setup external northbridge(s) */
-
- print_t("mctAutoInitMCT_D: DQSTiming_D\n");
- DQSTiming_D(pMCTstat, pDCTstatA); /* Get Receiver Enable and DQS signal timing*/
-
- print_t("mctAutoInitMCT_D: UMAMemTyping_D\n");
- UMAMemTyping_D(pMCTstat, pDCTstatA); /* Fix up for UMA sizing */
-
- print_t("mctAutoInitMCT_D: :OtherTiming\n");
- mct_OtherTiming(pMCTstat, pDCTstatA);
-
- if (ReconfigureDIMMspare_D(pMCTstat, pDCTstatA)) { /* RESET# if 1st pass of DIMM spare enabled*/
- goto restartinit;
- }
-
- InterleaveNodes_D(pMCTstat, pDCTstatA);
- InterleaveChannels_D(pMCTstat, pDCTstatA);
-
- print_t("mctAutoInitMCT_D: ECCInit_D\n");
- if (ECCInit_D(pMCTstat, pDCTstatA)) { /* Setup ECC control and ECC check-bits*/
- print_t("mctAutoInitMCT_D: MCTMemClr_D\n");
- MCTMemClr_D(pMCTstat,pDCTstatA);
- }
-
- mct_FinalMCT_D(pMCTstat, (pDCTstatA + 0)); // Node 0
- print_tx("mctAutoInitMCT_D Done: Global Status: ", pMCTstat->GStatus);
- return;
-
-fatalexit:
- die("mct_d: fatalexit");
-}
-
-
-static u8 ReconfigureDIMMspare_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 ret;
-
- if (mctGet_NVbits(NV_CS_SpareCTL)) {
- if (MCT_DIMM_SPARE_NO_WARM) {
- /* Do no warm-reset DIMM spare */
- if (pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW)) {
- LoadDQSSigTmgRegs_D(pMCTstat, pDCTstatA);
- ret = 0;
- } else {
- mct_ResetDataStruct_D(pMCTstat, pDCTstatA);
- pMCTstat->GStatus |= 1 << GSB_EnDIMMSpareNW;
- ret = 1;
- }
- } else {
- /* Do warm-reset DIMM spare */
- if (mctGet_NVbits(NV_DQSTrainCTL))
- mctWarmReset_D();
- ret = 0;
- }
-
-
- } else {
- ret = 0;
- }
-
- return ret;
-}
-
-
-static void DQSTiming_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 nv_DQSTrainCTL;
-
- if (pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW)) {
- return;
- }
- nv_DQSTrainCTL = mctGet_NVbits(NV_DQSTrainCTL);
- /* FIXME: BOZO- DQS training every time*/
- nv_DQSTrainCTL = 1;
-
- print_t("DQSTiming_D: mct_BeforeDQSTrain_D:\n");
- mct_BeforeDQSTrain_D(pMCTstat, pDCTstatA);
- phyAssistedMemFnceTraining(pMCTstat, pDCTstatA);
-
- if (nv_DQSTrainCTL) {
- mctHookBeforeAnyTraining(pMCTstat, pDCTstatA);
-
- print_t("DQSTiming_D: TrainReceiverEn_D FirstPass:\n");
- TrainReceiverEn_D(pMCTstat, pDCTstatA, FirstPass);
-
- print_t("DQSTiming_D: mct_TrainDQSPos_D\n");
- mct_TrainDQSPos_D(pMCTstat, pDCTstatA);
-
- // Second Pass never used for Barcelona!
- //print_t("DQSTiming_D: TrainReceiverEn_D SecondPass:\n");
- //TrainReceiverEn_D(pMCTstat, pDCTstatA, SecondPass);
-
- print_t("DQSTiming_D: mctSetEccDQSRcvrEn_D\n");
- mctSetEccDQSRcvrEn_D(pMCTstat, pDCTstatA);
-
- print_t("DQSTiming_D: TrainMaxReadLatency_D\n");
-//FIXME - currently uses calculated value TrainMaxReadLatency_D(pMCTstat, pDCTstatA);
- mctHookAfterAnyTraining();
- mctSaveDQSSigTmg_D();
-
- print_t("DQSTiming_D: mct_EndDQSTraining_D\n");
- mct_EndDQSTraining_D(pMCTstat, pDCTstatA);
-
- print_t("DQSTiming_D: MCTMemClr_D\n");
- MCTMemClr_D(pMCTstat, pDCTstatA);
- } else {
- mctGetDQSSigTmg_D(); /* get values into data structure */
- LoadDQSSigTmgRegs_D(pMCTstat, pDCTstatA); /* load values into registers.*/
- //mctDoWarmResetMemClr_D();
- MCTMemClr_D(pMCTstat, pDCTstatA);
- }
-}
-
-
-static void LoadDQSSigTmgRegs_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node, Receiver, Channel, Dir, DIMM;
- u32 dev;
- u32 index_reg;
- u32 reg;
- u32 index;
- u32 val;
-
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->DCTSysLimit) {
- dev = pDCTstat->dev_dct;
- for (Channel = 0;Channel < 2; Channel++) {
- /* there are four receiver pairs,
- loosely associated with chipselects.*/
- index_reg = 0x98 + Channel * 0x100;
- for (Receiver = 0; Receiver < 8; Receiver += 2) {
- /* Set Receiver Enable Values */
- mct_SetRcvrEnDly_D(pDCTstat,
- 0, /* RcvrEnDly */
- 1, /* FinalValue, From stack */
- Channel,
- Receiver,
- dev, index_reg,
- (Receiver >> 1) * 3 + 0x10, /* Addl_Index */
- 2); /* Pass Second Pass ? */
-
- }
- }
- for (Channel = 0; Channel < 2; Channel++) {
- SetEccDQSRcvrEn_D(pDCTstat, Channel);
- }
-
- for (Channel = 0; Channel < 2; Channel++) {
- u8 *p;
- index_reg = 0x98 + Channel * 0x100;
-
- /* NOTE:
- * when 400, 533, 667, it will support dimm0/1/2/3,
- * and set conf for dimm0, hw will copy to dimm1/2/3
- * set for dimm1, hw will copy to dimm3
- * Rev A/B only support DIMM0/1 when 800MHz and above
- * + 0x100 to next dimm
- * Rev C support DIMM0/1/2/3 when 800MHz and above
- * + 0x100 to next dimm
- */
- for (DIMM = 0; DIMM < 2; DIMM++) {
- if (DIMM == 0) {
- index = 0; /* CHA Write Data Timing Low */
- } else {
- if (pDCTstat->Speed >= 4) {
- index = 0x100 * DIMM;
- } else {
- break;
- }
- }
- for (Dir = 0; Dir < 2; Dir++) {//RD/WR
- p = pDCTstat->persistentData.CH_D_DIR_B_DQS[Channel][DIMM][Dir];
- val = stream_to_int(p); /* CHA Read Data Timing High */
- Set_NB32_index_wait(dev, index_reg, index+1, val);
- val = stream_to_int(p+4); /* CHA Write Data Timing High */
- Set_NB32_index_wait(dev, index_reg, index+2, val);
- val = *(p+8); /* CHA Write ECC Timing */
- Set_NB32_index_wait(dev, index_reg, index+3, val);
- index += 4;
- }
- }
- }
-
- for (Channel = 0; Channel < 2; Channel++) {
- reg = 0x78 + Channel * 0x100;
- val = Get_NB32(dev, reg);
- val &= ~(0x3ff<<22);
- val |= ((u32) pDCTstat->CH_MaxRdLat[Channel] << 22);
- val &= ~(1 << DqsRcvEnTrain);
- Set_NB32(dev, reg, val); /* program MaxRdLatency to correspond with current delay*/
- }
- }
- }
-}
-
-#ifdef UNUSED_CODE
-static void ResetNBECCstat_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void ResetNBECCstat_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /* Clear MC4_STS for all Nodes in the system. This is required in some
- * circumstances to clear left over garbage from cold reset, shutdown,
- * or normal ECC memory conditioning.
- */
-
- //FIXME: this function depends on pDCTstat Array (with Node id) - Is this really a problem?
-
- u32 dev;
- u8 Node;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- dev = pDCTstat->dev_nbmisc;
- /*MCA NB Status Low (alias to MC4_STS[31:0] */
- Set_NB32(dev, 0x48, 0);
- /* MCA NB Status High (alias to MC4_STS[63:32] */
- Set_NB32(dev, 0x4C, 0);
- }
- }
-}
-#endif
-
-static void HTMemMapInit_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u32 NextBase, BottomIO;
- u8 _MemHoleRemap, DramHoleBase;
- u32 HoleSize, DramSelBaseAddr;
-
- u32 val;
- u32 base;
- u32 limit;
- u32 dev, devx;
- struct DCTStatStruc *pDCTstat;
-
- _MemHoleRemap = mctGet_NVbits(NV_MemHole);
-
- if (pMCTstat->HoleBase == 0) {
- DramHoleBase = mctGet_NVbits(NV_BottomIO);
- } else {
- DramHoleBase = pMCTstat->HoleBase >> (24-8);
- }
-
- BottomIO = DramHoleBase << (24-8);
-
- NextBase = 0;
- pDCTstat = pDCTstatA + 0;
- dev = pDCTstat->dev_map;
-
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
- devx = pDCTstat->dev_map;
- DramSelBaseAddr = 0;
- if (!pDCTstat->GangedMode) {
- DramSelBaseAddr = pDCTstat->NodeSysLimit - pDCTstat->DCTSysLimit;
- /*In unganged mode, we must add DCT0 and DCT1 to DCTSysLimit */
- val = pDCTstat->NodeSysLimit;
- if ((val & 0xFF) == 0xFE) {
- DramSelBaseAddr++;
- val++;
- }
- pDCTstat->DCTSysLimit = val;
- }
-
- base = pDCTstat->DCTSysBase;
- limit = pDCTstat->DCTSysLimit;
- if (limit > base) {
- base += NextBase;
- limit += NextBase;
- DramSelBaseAddr += NextBase;
- printk(BIOS_DEBUG, " Node: %02x base: %02x limit: %02x BottomIO: %02x\n", Node, base, limit, BottomIO);
-
- if (_MemHoleRemap) {
- if ((base < BottomIO) && (limit >= BottomIO)) {
- /* HW Dram Remap */
- pDCTstat->Status |= 1 << SB_HWHole;
- pMCTstat->GStatus |= 1 << GSB_HWHole;
- pDCTstat->DCTSysBase = base;
- pDCTstat->DCTSysLimit = limit;
- pDCTstat->DCTHoleBase = BottomIO;
- pMCTstat->HoleBase = BottomIO;
- HoleSize = _4GB_RJ8 - BottomIO; /* HoleSize[39:8] */
- if ((DramSelBaseAddr > 0) && (DramSelBaseAddr < BottomIO))
- base = DramSelBaseAddr;
- val = ((base + HoleSize) >> (24-8)) & 0xFF;
- val <<= 8; /* shl 16, rol 24 */
- val |= DramHoleBase << 24;
- val |= 1 << DramHoleValid;
- Set_NB32(devx, 0xF0, val); /* Dram Hole Address Reg */
- pDCTstat->DCTSysLimit += HoleSize;
- base = pDCTstat->DCTSysBase;
- limit = pDCTstat->DCTSysLimit;
- } else if (base == BottomIO) {
- /* SW Node Hoist */
- pMCTstat->GStatus |= 1 << GSB_SpIntRemapHole;
- pDCTstat->Status |= 1 << SB_SWNodeHole;
- pMCTstat->GStatus |= 1 << GSB_SoftHole;
- pMCTstat->HoleBase = base;
- limit -= base;
- base = _4GB_RJ8;
- limit += base;
- pDCTstat->DCTSysBase = base;
- pDCTstat->DCTSysLimit = limit;
- } else {
- /* No Remapping. Normal Contiguous mapping */
- pDCTstat->DCTSysBase = base;
- pDCTstat->DCTSysLimit = limit;
- }
- } else {
- /*No Remapping. Normal Contiguous mapping*/
- pDCTstat->DCTSysBase = base;
- pDCTstat->DCTSysLimit = limit;
- }
- base |= 3; /* set WE,RE fields*/
- pMCTstat->SysLimit = limit;
- }
- Set_NB32(dev, 0x40 + (Node << 3), base); /* [Node] + Dram Base 0 */
-
- /* if Node limit > 1GB then set it to 1GB boundary for each node */
- if ((mctSetNodeBoundary_D()) && (limit > 0x00400000)) {
- limit++;
- limit &= 0xFFC00000;
- limit--;
- }
- val = limit & 0xFFFF0000;
- val |= Node;
- Set_NB32(dev, 0x44 + (Node << 3), val); /* set DstNode */
-
- limit = pDCTstat->DCTSysLimit;
- if (limit) {
- NextBase = (limit & 0xFFFF0000) + 0x10000;
- if ((mctSetNodeBoundary_D()) && (NextBase > 0x00400000)) {
- NextBase++;
- NextBase &= 0xFFC00000;
- NextBase--;
- }
- }
- }
-
- /* Copy dram map from Node 0 to Node 1-7 */
- for (Node = 1; Node < MAX_NODES_SUPPORTED; Node++) {
- u32 reg;
- pDCTstat = pDCTstatA + Node;
- devx = pDCTstat->dev_map;
-
- if (pDCTstat->NodePresent) {
- printk(BIOS_DEBUG, " Copy dram map from Node 0 to Node %02x\n", Node);
- reg = 0x40; /*Dram Base 0*/
- do {
- val = Get_NB32(dev, reg);
- Set_NB32(devx, reg, val);
- reg += 4;
- } while (reg < 0x80);
- } else {
- break; /* stop at first absent Node */
- }
- }
-
- /*Copy dram map to F1x120/124*/
- mct_HTMemMapExt(pMCTstat, pDCTstatA);
-}
-
-
-void MCTMemClr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
-
- /* Initiates a memory clear operation for all node. The mem clr
- * is done in parallel. After the memclr is complete, all processors
- * status are checked to ensure that memclr has completed.
- */
- u8 Node;
- struct DCTStatStruc *pDCTstat;
-
- if (!mctGet_NVbits(NV_DQSTrainCTL)) {
- // FIXME: callback to wrapper: mctDoWarmResetMemClr_D
- } else { // NV_DQSTrainCTL == 1
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- DCTMemClr_Init_D(pMCTstat, pDCTstat);
- }
- }
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- DCTMemClr_Sync_D(pMCTstat, pDCTstat);
- }
- }
- }
-}
-
-
-void DCTMemClr_Init_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 val;
- u32 dev;
- u32 reg;
-
- /* Initiates a memory clear operation on one node */
- if (pDCTstat->DCTSysLimit) {
- dev = pDCTstat->dev_dct;
- reg = 0x110;
-
- do {
- val = Get_NB32(dev, reg);
- } while (val & (1 << MemClrBusy));
-
- val |= (1 << MemClrInit);
- Set_NB32(dev, reg, val);
-
- }
-}
-
-
-void MCTMemClrSync_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /* Ensures that memory clear has completed on all node.*/
- u8 Node;
- struct DCTStatStruc *pDCTstat;
-
- if (!mctGet_NVbits(NV_DQSTrainCTL)) {
- // callback to wrapper: mctDoWarmResetMemClr_D
- } else { // NV_DQSTrainCTL == 1
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- DCTMemClr_Sync_D(pMCTstat, pDCTstat);
- }
- }
- }
-}
-
-
-static void DCTMemClr_Sync_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 val;
- u32 dev = pDCTstat->dev_dct;
- u32 reg;
-
- /* Ensure that a memory clear operation has completed on one node */
- if (pDCTstat->DCTSysLimit) {
- reg = 0x110;
-
- do {
- val = Get_NB32(dev, reg);
- } while (val & (1 << MemClrBusy));
-
- do {
- val = Get_NB32(dev, reg);
- } while (!(val & (1 << Dr_MemClrStatus)));
- }
-
- /* Implement BKDG Rev 3.62 recommendations */
- val = 0x0FE40F80;
- if (!(mctGetLogicalCPUID(0) & AMD_FAM10_LT_D) && mctGet_NVbits(NV_Unganged))
- val |= (0x18 << 2);
- else
- val |= (0x10 << 2);
- val |= MCCH_FlushWrOnStpGnt; // Set for S3
- Set_NB32(dev, 0x11C, val);
-}
-
-
-u8 NodePresent_D(u8 Node)
-{
- /*
- * Determine if a single Hammer Node exists within the network.
- */
-
- u32 dev;
- u32 val;
- u32 dword;
- u8 ret = 0;
-
- dev = PA_HOST(Node); /*test device/vendor id at host bridge */
- val = Get_NB32(dev, 0);
- dword = mct_NodePresent_D(); /* FIXME: BOZO -11001022h rev for F */
- if (val == dword) { /* AMD Hammer Family CPU HT Configuration */
- if (oemNodePresent_D(Node, &ret))
- goto finish;
- /* Node ID register */
- val = Get_NB32(dev, 0x60);
- val &= 0x07;
- dword = Node;
- if (val == dword) /* current nodeID = requested nodeID ? */
- ret = 1;
-finish:
- ;
- }
-
- return ret;
-}
-
-
-static void DCTInit_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /*
- * Initialize DRAM on single Athlon 64/Opteron Node.
- */
-
- u8 stopDCTflag;
- u32 val;
-
- ClearDCT_D(pMCTstat, pDCTstat, dct);
- stopDCTflag = 1; /*preload flag with 'disable' */
- if (mct_DIMMPresence(pMCTstat, pDCTstat, dct) < SC_StopError) {
- print_t("\t\tDCTInit_D: mct_DIMMPresence Done\n");
- if (mct_SPDCalcWidth(pMCTstat, pDCTstat, dct) < SC_StopError) {
- print_t("\t\tDCTInit_D: mct_SPDCalcWidth Done\n");
- if (AutoCycTiming_D(pMCTstat, pDCTstat, dct) < SC_StopError) {
- print_t("\t\tDCTInit_D: AutoCycTiming_D Done\n");
- if (AutoConfig_D(pMCTstat, pDCTstat, dct) < SC_StopError) {
- print_t("\t\tDCTInit_D: AutoConfig_D Done\n");
- if (PlatformSpec_D(pMCTstat, pDCTstat, dct) < SC_StopError) {
- print_t("\t\tDCTInit_D: PlatformSpec_D Done\n");
- stopDCTflag = 0;
- if (!(pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW))) {
- print_t("\t\tDCTInit_D: StartupDCT_D\n");
- StartupDCT_D(pMCTstat, pDCTstat, dct); /*yeaahhh! */
- }
- }
- }
- }
- }
- }
- if (stopDCTflag) {
- u32 reg_off = dct * 0x100;
- val = 1<<DisDramInterface;
- Set_NB32(pDCTstat->dev_dct, reg_off+0x94, val);
- /*To maximize power savings when DisDramInterface = 1b,
- all of the MemClkDis bits should also be set.*/
- val = 0xFF000000;
- Set_NB32(pDCTstat->dev_dct, reg_off+0x88, val);
- } else {
- mct_EnDllShutdownSR(pMCTstat, pDCTstat, dct);
- }
-}
-
-
-static void SyncDCTsReady_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /* Wait (and block further access to dram) for all DCTs to be ready,
- * by polling all InitDram bits and waiting for possible memory clear
- * operations to be complete. Read MemClkFreqVal bit to see if
- * the DIMMs are present in this node.
- */
-
- u8 Node;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- mct_SyncDCTsReady(pDCTstat);
- }
-}
-
-
-static void StartupDCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Read MemClkFreqVal bit to see if the DIMMs are present in this node.
- * If the DIMMs are present then set the DRAM Enable bit for this node.
- *
- * Setting dram init starts up the DCT state machine, initializes the
- * dram devices with MRS commands, and kicks off any
- * HW memory clear process that the chip is capable of. The sooner
- * that dram init is set for all nodes, the faster the memory system
- * initialization can complete. Thus, the init loop is unrolled into
- * two loops so as to start the processes for non BSP nodes sooner.
- * This procedure will not wait for the process to finish.
- * Synchronization is handled elsewhere.
- */
-
- u32 val;
- u32 dev;
- u8 byte;
- u32 reg;
- u32 reg_off = dct * 0x100;
-
- dev = pDCTstat->dev_dct;
- val = Get_NB32(dev, 0x94 + reg_off);
- if (val & (1 << MemClkFreqVal)) {
- print_t("\t\t\tStartupDCT_D: MemClkFreqVal\n");
- byte = mctGet_NVbits(NV_DQSTrainCTL);
- if (byte == 1) {
- /* Enable DQSRcvEn training mode */
- print_t("\t\t\tStartupDCT_D: DqsRcvEnTrain set\n");
- reg = 0x78 + reg_off;
- val = Get_NB32(dev, reg);
- /* Setting this bit forces a 1T window with hard left
- * pass/fail edge and a probabilistic right pass/fail
- * edge. LEFT edge is referenced for final
- * receiver enable position.*/
- val |= 1 << DqsRcvEnTrain;
- Set_NB32(dev, reg, val);
- }
- mctHookBeforeDramInit(); /* generalized Hook */
- print_t("\t\t\tStartupDCT_D: DramInit\n");
- mct_DramInit(pMCTstat, pDCTstat, dct);
- AfterDramInit_D(pDCTstat, dct);
- mctHookAfterDramInit(); /* generalized Hook*/
- }
-}
-
-
-static void ClearDCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 reg_end;
- u32 dev = pDCTstat->dev_dct;
- u32 reg = 0x40 + 0x100 * dct;
- u32 val = 0;
-
- if (pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW)) {
- reg_end = 0x78 + 0x100 * dct;
- } else {
- reg_end = 0xA4 + 0x100 * dct;
- }
-
- while (reg < reg_end) {
- Set_NB32(dev, reg, val);
- reg += 4;
- }
-
- val = 0;
- dev = pDCTstat->dev_map;
- reg = 0xF0;
- Set_NB32(dev, reg, val);
-}
-
-
-static u8 AutoCycTiming_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Initialize DCT Timing registers as per DIMM SPD.
- * For primary timing (T, CL) use best case T value.
- * For secondary timing params., use most aggressive settings
- * of slowest DIMM.
- *
- * There are three components to determining "maximum frequency":
- * SPD component, Bus load component, and "Preset" max frequency
- * component.
- *
- * The SPD component is a function of the min cycle time specified
- * by each DIMM, and the interaction of cycle times from all DIMMs
- * in conjunction with CAS latency. The SPD component only applies
- * when user timing mode is 'Auto'.
- *
- * The Bus load component is a limiting factor determined by electrical
- * characteristics on the bus as a result of varying number of device
- * loads. The Bus load component is specific to each platform but may
- * also be a function of other factors. The bus load component only
- * applies when user timing mode is 'Auto'.
- *
- * The Preset component is subdivided into three items and is the
- * minimum of the set: Silicon revision, user limit setting when user
- * timing mode is 'Auto' and memclock mode is 'Limit', OEM build
- * specification of the maximum frequency. The Preset component is only
- * applies when user timing mode is 'Auto'.
- */
-
- u8 i;
- u8 Twr, Trtp;
- u8 Trp, Trrd, Trcd, Tras, Trc, Trfc[4], Rows;
- u32 DramTimingLo, DramTimingHi;
- u16 Tk40;
- u8 Twtr;
- u8 LDIMM;
- u8 DDR2_1066;
- u8 byte;
- u32 dword;
- u32 dev;
- u32 reg;
- u32 reg_off;
- u32 val;
- u16 smbaddr;
-
- /* Get primary timing (CAS Latency and Cycle Time) */
- if (pDCTstat->Speed == 0) {
- mctGet_MaxLoadFreq(pDCTstat);
-
- /* and Factor in presets (setup options, Si cap, etc.) */
- GetPresetmaxF_D(pMCTstat, pDCTstat);
-
- /* Go get best T and CL as specified by DIMM mfgs. and OEM */
- SPDGetTCL_D(pMCTstat, pDCTstat, dct);
- /* skip callback mctForce800to1067_D */
- pDCTstat->Speed = pDCTstat->DIMMAutoSpeed;
- pDCTstat->CASL = pDCTstat->DIMMCASL;
-
- /* if "manual" memclock mode */
- if (mctGet_NVbits(NV_MCTUSRTMGMODE) == 2)
- pDCTstat->Speed = mctGet_NVbits(NV_MemCkVal) + 1;
-
- }
- mct_AfterGetCLT(pMCTstat, pDCTstat, dct);
-
- /* Gather all DIMM mini-max values for cycle timing data */
- Rows = 0;
- Trp = 0;
- Trrd = 0;
- Trcd = 0;
- Trtp = 0;
- Tras = 0;
- Trc = 0;
- Twr = 0;
- Twtr = 0;
- for (i = 0; i < 4; i++)
- Trfc[i] = 0;
-
- for (i = 0; i< MAX_DIMMS_SUPPORTED; i++) {
- LDIMM = i >> 1;
- if (pDCTstat->DIMMValid & (1 << i)) {
- smbaddr = Get_DIMMAddress_D(pDCTstat, dct + i);
- byte = mctRead_SPD(smbaddr, SPD_ROWSZ);
- if (Rows < byte)
- Rows = byte; /* keep track of largest row sz */
-
- byte = mctRead_SPD(smbaddr, SPD_TRP);
- if (Trp < byte)
- Trp = byte;
-
- byte = mctRead_SPD(smbaddr, SPD_TRRD);
- if (Trrd < byte)
- Trrd = byte;
-
- byte = mctRead_SPD(smbaddr, SPD_TRCD);
- if (Trcd < byte)
- Trcd = byte;
-
- byte = mctRead_SPD(smbaddr, SPD_TRTP);
- if (Trtp < byte)
- Trtp = byte;
-
- byte = mctRead_SPD(smbaddr, SPD_TWR);
- if (Twr < byte)
- Twr = byte;
-
- byte = mctRead_SPD(smbaddr, SPD_TWTR);
- if (Twtr < byte)
- Twtr = byte;
-
- val = mctRead_SPD(smbaddr, SPD_TRC);
- if ((val == 0) || (val == 0xFF)) {
- pDCTstat->ErrStatus |= 1<<SB_NoTrcTrfc;
- pDCTstat->ErrCode = SC_VarianceErr;
- val = Get_DefTrc_k_D(pDCTstat->Speed);
- } else {
- byte = mctRead_SPD(smbaddr, SPD_TRCRFC);
- if (byte & 0xF0) {
- val++; /* round up in case fractional extension is non-zero.*/
- }
- }
- if (Trc < val)
- Trc = val;
-
- /* dev density = rank size/#devs per rank */
- byte = mctRead_SPD(smbaddr, SPD_BANKSZ);
-
- val = ((byte >> 5) | (byte << 3)) & 0xFF;
- val <<= 2;
-
- byte = mctRead_SPD(smbaddr, SPD_DEVWIDTH) & 0xFE; /* dev density = 2^(rows+columns+banks) */
- if (byte == 4) {
- val >>= 4;
- } else if (byte == 8) {
- val >>= 3;
- } else if (byte == 16) {
- val >>= 2;
- }
-
- byte = bsr(val);
-
- if (Trfc[LDIMM] < byte)
- Trfc[LDIMM] = byte;
-
- byte = mctRead_SPD(smbaddr, SPD_TRAS);
- if (Tras < byte)
- Tras = byte;
- } /* Dimm Present */
- }
-
- /* Convert DRAM CycleTiming values and store into DCT structure */
- DDR2_1066 = 0;
- byte = pDCTstat->Speed;
- if (byte == 5)
- DDR2_1066 = 1;
- Tk40 = Get_40Tk_D(byte);
-
- /* Notes:
- 1. All secondary time values given in SPDs are in binary with units of ns.
- 2. Some time values are scaled by four, in order to have least count of 0.25 ns
- (more accuracy). JEDEC SPD spec. shows which ones are x1 and x4.
- 3. Internally to this SW, cycle time, Tk, is scaled by 10 to affect a
- least count of 0.1 ns (more accuracy).
- 4. SPD values not scaled are multiplied by 10 and then divided by 10T to find
- equivalent minimum number of bus clocks (a remainder causes round-up of clocks).
- 5. SPD values that are prescaled by 4 are multiplied by 10 and then divided by 40T to find
- equivalent minimum number of bus clocks (a remainder causes round-up of clocks).*/
-
- /* Tras */
- dword = Tras * 40;
- pDCTstat->DIMMTras = (u16)dword;
- val = dword / Tk40;
- if (dword % Tk40) { /* round up number of busclocks */
- val++;
- }
- if (DDR2_1066) {
- if (val < Min_TrasT_1066)
- val = Min_TrasT_1066;
- else if (val > Max_TrasT_1066)
- val = Max_TrasT_1066;
- } else {
- if (val < Min_TrasT)
- val = Min_TrasT;
- else if (val > Max_TrasT)
- val = Max_TrasT;
- }
- pDCTstat->Tras = val;
-
- /* Trp */
- dword = Trp * 10;
- pDCTstat->DIMMTrp = dword;
- val = dword / Tk40;
- if (dword % Tk40) { /* round up number of busclocks */
- val++;
- }
- if (DDR2_1066) {
- if (val < Min_TrasT_1066)
- val = Min_TrpT_1066;
- else if (val > Max_TrpT_1066)
- val = Max_TrpT_1066;
- } else {
- if (val < Min_TrpT)
- val = Min_TrpT;
- else if (val > Max_TrpT)
- val = Max_TrpT;
- }
- pDCTstat->Trp = val;
-
- /*Trrd*/
- dword = Trrd * 10;
- pDCTstat->DIMMTrrd = dword;
- val = dword / Tk40;
- if (dword % Tk40) { /* round up number of busclocks */
- val++;
- }
- if (DDR2_1066) {
- if (val < Min_TrrdT_1066)
- val = Min_TrrdT_1066;
- else if (val > Max_TrrdT_1066)
- val = Max_TrrdT_1066;
- } else {
- if (val < Min_TrrdT)
- val = Min_TrrdT;
- else if (val > Max_TrrdT)
- val = Max_TrrdT;
- }
- pDCTstat->Trrd = val;
-
- /* Trcd */
- dword = Trcd * 10;
- pDCTstat->DIMMTrcd = dword;
- val = dword / Tk40;
- if (dword % Tk40) { /* round up number of busclocks */
- val++;
- }
- if (DDR2_1066) {
- if (val < Min_TrcdT_1066)
- val = Min_TrcdT_1066;
- else if (val > Max_TrcdT_1066)
- val = Max_TrcdT_1066;
- } else {
- if (val < Min_TrcdT)
- val = Min_TrcdT;
- else if (val > Max_TrcdT)
- val = Max_TrcdT;
- }
- pDCTstat->Trcd = val;
-
- /* Trc */
- dword = Trc * 40;
- pDCTstat->DIMMTrc = dword;
- val = dword / Tk40;
- if (dword % Tk40) { /* round up number of busclocks */
- val++;
- }
- if (DDR2_1066) {
- if (val < Min_TrcT_1066)
- val = Min_TrcT_1066;
- else if (val > Max_TrcT_1066)
- val = Max_TrcT_1066;
- } else {
- if (val < Min_TrcT)
- val = Min_TrcT;
- else if (val > Max_TrcT)
- val = Max_TrcT;
- }
- pDCTstat->Trc = val;
-
- /* Trtp */
- dword = Trtp * 10;
- pDCTstat->DIMMTrtp = dword;
- val = pDCTstat->Speed;
- if (val <= 2) { /* 7.75ns / Speed in ns to get clock # */
- val = 2; /* for DDR400/DDR533 */
- } else { /* Note a speed of 3 will be a Trtp of 3 */
- val = 3; /* for DDR667/DDR800/DDR1066 */
- }
- pDCTstat->Trtp = val;
-
- /* Twr */
- dword = Twr * 10;
- pDCTstat->DIMMTwr = dword;
- val = dword / Tk40;
- if (dword % Tk40) { /* round up number of busclocks */
- val++;
- }
- if (DDR2_1066) {
- if (val < Min_TwrT_1066)
- val = Min_TwrT_1066;
- else if (val > Max_TwrT_1066)
- val = Max_TwrT_1066;
- } else {
- if (val < Min_TwrT)
- val = Min_TwrT;
- else if (val > Max_TwrT)
- val = Max_TwrT;
- }
- pDCTstat->Twr = val;
-
- /* Twtr */
- dword = Twtr * 10;
- pDCTstat->DIMMTwtr = dword;
- val = dword / Tk40;
- if (dword % Tk40) { /* round up number of busclocks */
- val++;
- }
- if (DDR2_1066) {
- if (val < Min_TwrT_1066)
- val = Min_TwtrT_1066;
- else if (val > Max_TwtrT_1066)
- val = Max_TwtrT_1066;
- } else {
- if (val < Min_TwtrT)
- val = Min_TwtrT;
- else if (val > Max_TwtrT)
- val = Max_TwtrT;
- }
- pDCTstat->Twtr = val;
-
-
- /* Trfc0-Trfc3 */
- for (i = 0; i < 4; i++)
- pDCTstat->Trfc[i] = Trfc[i];
-
- mctAdjustAutoCycTmg_D();
-
- /* Program DRAM Timing values */
- DramTimingLo = 0; /* Dram Timing Low init */
- val = pDCTstat->CASL;
- val = Tab_tCL_j[val];
- DramTimingLo |= val;
-
- val = pDCTstat->Trcd;
- if (DDR2_1066)
- val -= Bias_TrcdT_1066;
- else
- val -= Bias_TrcdT;
-
- DramTimingLo |= val << 4;
-
- val = pDCTstat->Trp;
- if (DDR2_1066)
- val -= Bias_TrpT_1066;
- else {
- val -= Bias_TrpT;
- val <<= 1;
- }
- DramTimingLo |= val << 7;
-
- val = pDCTstat->Trtp;
- val -= Bias_TrtpT;
- DramTimingLo |= val << 11;
-
- val = pDCTstat->Tras;
- if (DDR2_1066)
- val -= Bias_TrasT_1066;
- else
- val -= Bias_TrasT;
- DramTimingLo |= val << 12;
-
- val = pDCTstat->Trc;
- val -= Bias_TrcT;
- DramTimingLo |= val << 16;
-
- if (!DDR2_1066) {
- val = pDCTstat->Twr;
- val -= Bias_TwrT;
- DramTimingLo |= val << 20;
- }
-
- val = pDCTstat->Trrd;
- if (DDR2_1066)
- val -= Bias_TrrdT_1066;
- else
- val -= Bias_TrrdT;
- DramTimingLo |= val << 22;
-
-
- DramTimingHi = 0; /* Dram Timing Low init */
- val = pDCTstat->Twtr;
- if (DDR2_1066)
- val -= Bias_TwtrT_1066;
- else
- val -= Bias_TwtrT;
- DramTimingHi |= val << 8;
-
- val = 2;
- DramTimingHi |= val << 16;
-
- val = 0;
- for (i = 4; i > 0; i--) {
- val <<= 3;
- val |= Trfc[i-1];
- }
- DramTimingHi |= val << 20;
-
-
- dev = pDCTstat->dev_dct;
- reg_off = 0x100 * dct;
- print_tx("AutoCycTiming: DramTimingLo ", DramTimingLo);
- print_tx("AutoCycTiming: DramTimingHi ", DramTimingHi);
-
- Set_NB32(dev, 0x88 + reg_off, DramTimingLo); /*DCT Timing Low*/
- DramTimingHi |=0x0000FC77;
- Set_NB32(dev, 0x8c + reg_off, DramTimingHi); /*DCT Timing Hi*/
-
- if (DDR2_1066) {
- /* Twr */
- dword = pDCTstat->Twr;
- dword -= Bias_TwrT_1066;
- dword <<= 4;
- reg = 0x84 + reg_off;
- val = Get_NB32(dev, reg);
- val &= 0x8F;
- val |= dword;
- Set_NB32(dev, reg, val);
- }
-
- print_tx("AutoCycTiming: Status ", pDCTstat->Status);
- print_tx("AutoCycTiming: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("AutoCycTiming: ErrCode ", pDCTstat->ErrCode);
- print_t("AutoCycTiming: Done\n");
-
- mctHookAfterAutoCycTmg();
-
- return pDCTstat->ErrCode;
-}
-
-
-static void GetPresetmaxF_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Get max frequency from OEM platform definition, from any user
- * override (limiting) of max frequency, and from any Si Revision
- * Specific information. Return the least of these three in
- * DCTStatStruc.PresetmaxFreq.
- */
-
- u16 proposedFreq;
- u16 word;
-
- /* Get CPU Si Revision defined limit (NPT) */
- proposedFreq = 533; /* Rev F0 programmable max memclock is */
-
- /*Get User defined limit if "limit" mode */
- if (mctGet_NVbits(NV_MCTUSRTMGMODE) == 1) {
- word = Get_Fk_D(mctGet_NVbits(NV_MemCkVal) + 1);
- if (word < proposedFreq)
- proposedFreq = word;
-
- /* Get Platform defined limit */
- word = mctGet_NVbits(NV_MAX_MEMCLK);
- if (word < proposedFreq)
- proposedFreq = word;
-
- word = pDCTstat->PresetmaxFreq;
- if (word > proposedFreq)
- word = proposedFreq;
-
- pDCTstat->PresetmaxFreq = word;
- }
-}
-
-
-
-static void SPDGetTCL_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Find the best T and CL primary timing parameter pair, per Mfg.,
- * for the given set of DIMMs, and store into DCTStatStruc
- * (.DIMMAutoSpeed and .DIMMCASL). See "Global relationship between
- * index values and item values" for definition of CAS latency
- * index (j) and Frequency index (k).
- */
- int i, j, k;
- u8 T1min, CL1min;
-
- /* i={0..7} (std. physical DIMM number)
- * j is an integer which enumerates increasing CAS latency.
- * k is an integer which enumerates decreasing cycle time.
- * CL no. {0,1,2} corresponds to CL X, CL X-.5, or CL X-1 (per individual DIMM)
- * Max timing values are per parameter, of all DIMMs, spec'd in ns like the SPD.
- */
-
- CL1min = 0xFF;
- T1min = 0xFF;
- for (k = K_MAX; k >= K_MIN; k--) {
- for (j = J_MIN; j <= J_MAX; j++) {
- if (Sys_Capability_D(pMCTstat, pDCTstat, j, k)) {
- /* 1. check to see if DIMMi is populated.
- 2. check if DIMMi supports CLj and Tjk */
- for (i = 0; i < MAX_DIMMS_SUPPORTED; i++) {
- if (pDCTstat->DIMMValid & (1 << i)) {
- if (Dimm_Supports_D(pDCTstat, i, j, k))
- break;
- }
- } /* while ++i */
- if (i == MAX_DIMMS_SUPPORTED) {
- T1min = k;
- CL1min = j;
- goto got_TCL;
- }
- }
- } /* while ++j */
- } /* while --k */
-
-got_TCL:
- if (T1min != 0xFF) {
- pDCTstat->DIMMCASL = CL1min; /*mfg. optimized */
- pDCTstat->DIMMAutoSpeed = T1min;
- print_tx("SPDGetTCL_D: DIMMCASL ", pDCTstat->DIMMCASL);
- print_tx("SPDGetTCL_D: DIMMAutoSpeed ", pDCTstat->DIMMAutoSpeed);
-
- } else {
- pDCTstat->DIMMCASL = CL_DEF; /* failsafe values (running in min. mode) */
- pDCTstat->DIMMAutoSpeed = T_DEF;
- pDCTstat->ErrStatus |= 1 << SB_DimmMismatchT;
- pDCTstat->ErrStatus |= 1 << SB_MinimumMode;
- pDCTstat->ErrCode = SC_VarianceErr;
- }
- print_tx("SPDGetTCL_D: Status ", pDCTstat->Status);
- print_tx("SPDGetTCL_D: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("SPDGetTCL_D: ErrCode ", pDCTstat->ErrCode);
- print_t("SPDGetTCL_D: Done\n");
-}
-
-
-static u8 PlatformSpec_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 dev;
- u32 reg;
- u32 val;
-
- mctGet_PS_Cfg_D(pMCTstat, pDCTstat, dct);
-
- if (pDCTstat->GangedMode) {
- mctGet_PS_Cfg_D(pMCTstat, pDCTstat, 1);
- }
-
- if (pDCTstat->_2Tmode == 2) {
- dev = pDCTstat->dev_dct;
- reg = 0x94 + 0x100 * dct; /* Dram Configuration Hi */
- val = Get_NB32(dev, reg);
- val |= 1 << 20; /* 2T CMD mode */
- Set_NB32(dev, reg, val);
- }
-
- mct_PlatformSpec(pMCTstat, pDCTstat, dct);
- InitPhyCompensation(pMCTstat, pDCTstat, dct);
- mctHookAfterPSCfg();
- return pDCTstat->ErrCode;
-}
-
-
-static u8 AutoConfig_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 DramControl, DramTimingLo, Status;
- u32 DramConfigLo, DramConfigHi, DramConfigMisc, DramConfigMisc2;
- u32 val;
- u32 reg_off;
- u32 dev;
- u16 word;
- u32 dword;
- u8 byte;
-
- print_tx("AutoConfig_D: DCT: ", dct);
-
- DramConfigLo = 0;
- DramConfigHi = 0;
- DramConfigMisc = 0;
- DramConfigMisc2 = 0;
-
- /* set bank addressing and Masks, plus CS pops */
- SPDSetBanks_D(pMCTstat, pDCTstat, dct);
- if (pDCTstat->ErrCode == SC_StopError)
- goto AutoConfig_exit;
-
- /* map chip-selects into local address space */
- StitchMemory_D(pMCTstat, pDCTstat, dct);
- InterleaveBanks_D(pMCTstat, pDCTstat, dct);
-
- /* temp image of status (for convenience). RO usage! */
- Status = pDCTstat->Status;
-
- dev = pDCTstat->dev_dct;
- reg_off = 0x100 * dct;
-
-
- /* Build Dram Control Register Value */
- DramConfigMisc2 = Get_NB32 (dev, 0xA8 + reg_off); /* Dram Control*/
- DramControl = Get_NB32 (dev, 0x78 + reg_off); /* Dram Control*/
-
- if (mctGet_NVbits(NV_CLKHZAltVidC3))
- DramControl |= 1<<16;
-
- // FIXME: Add support(skip) for Ax and Cx versions
- DramControl |= 5; /* RdPtrInit */
-
-
- /* Build Dram Config Lo Register Value */
- DramConfigLo |= 1 << 4; /* 75 Ohms ODT */
- if (mctGet_NVbits(NV_MAX_DIMMS) == 8) {
- if (pDCTstat->Speed == 3) {
- if (pDCTstat->MAdimms[dct] == 4)
- DramConfigLo |= 1 << 5; /* 50 Ohms ODT */
- } else if (pDCTstat->Speed == 4) {
- if (pDCTstat->MAdimms[dct] != 1)
- DramConfigLo |= 1 << 5; /* 50 Ohms ODT */
- }
- } else {
- // FIXME: Skip for Ax versions
- if (pDCTstat->MAdimms[dct] == 4) {
- if (pDCTstat->DimmQRPresent != 0) {
- if ((pDCTstat->Speed == 3) || (pDCTstat->Speed == 4)) {
- DramConfigLo |= 1 << 5; /* 50 Ohms ODT */
- }
- } else if (pDCTstat->MAdimms[dct] == 4) {
- if (pDCTstat->Speed == 4) {
- if (pDCTstat->DimmQRPresent != 0) {
- DramConfigLo |= 1 << 5; /* 50 Ohms ODT */
- }
- }
- }
- } else if (pDCTstat->MAdimms[dct] == 2) {
- DramConfigLo |= 1 << 5; /* 50 Ohms ODT */
- }
-
- }
-
- // FIXME: Skip for Ax versions
- /* callback not required - if (!mctParityControl_D()) */
- if (Status & (1 << SB_PARDIMMs)) {
- DramConfigLo |= 1 << ParEn;
- DramConfigMisc2 |= 1 << ActiveCmdAtRst;
- } else {
- DramConfigLo &= ~(1 << ParEn);
- DramConfigMisc2 &= ~(1 << ActiveCmdAtRst);
- }
-
- if (mctGet_NVbits(NV_BurstLen32)) {
- if (!pDCTstat->GangedMode)
- DramConfigLo |= 1 << BurstLength32;
- }
-
- if (Status & (1 << SB_128bitmode))
- DramConfigLo |= 1 << Width128; /* 128-bit mode (normal) */
-
- word = dct;
- dword = X4Dimm;
- while (word < 8) {
- if (pDCTstat->Dimmx4Present & (1 << word))
- DramConfigLo |= 1 << dword; /* X4Dimm[3:0] */
- word++;
- word++;
- dword++;
- }
-
- if (!(Status & (1 << SB_Registered)))
- DramConfigLo |= 1 << UnBuffDimm; /* Unbuffered DIMMs */
-
- if (mctGet_NVbits(NV_ECC_CAP))
- if (Status & (1 << SB_ECCDIMMs))
- if (mctGet_NVbits(NV_ECC))
- DramConfigLo |= 1 << DimmEcEn;
-
- DramConfigLo = mct_DisDllShutdownSR(pMCTstat, pDCTstat, DramConfigLo, dct);
-
- /* Build Dram Config Hi Register Value */
- dword = pDCTstat->Speed;
- DramConfigHi |= dword - 1; /* get MemClk encoding */
- DramConfigHi |= 1 << MemClkFreqVal;
-
- if (Status & (1 << SB_Registered))
- if ((pDCTstat->Dimmx4Present != 0) && (pDCTstat->Dimmx8Present != 0))
- /* set only if x8 Registered DIMMs in System*/
- DramConfigHi |= 1 << RDqsEn;
-
- if (mctGet_NVbits(NV_CKE_PDEN)) {
- DramConfigHi |= 1 << 15; /* PowerDownEn */
- if (mctGet_NVbits(NV_CKE_CTL))
- /*Chip Select control of CKE*/
- DramConfigHi |= 1 << 16;
- }
-
- /* Control Bank Swizzle */
- if (0) /* call back not needed mctBankSwizzleControl_D()) */
- DramConfigHi &= ~(1 << BankSwizzleMode);
- else
- DramConfigHi |= 1 << BankSwizzleMode; /* recommended setting (default) */
-
- /* Check for Quadrank DIMM presence */
- if (pDCTstat->DimmQRPresent != 0) {
- byte = mctGet_NVbits(NV_4RANKType);
- if (byte == 2)
- DramConfigHi |= 1 << 17; /* S4 (4-Rank SO-DIMMs) */
- else if (byte == 1)
- DramConfigHi |= 1 << 18; /* R4 (4-Rank Registered DIMMs) */
- }
-
- if (0) /* call back not needed mctOverrideDcqBypMax_D) */
- val = mctGet_NVbits(NV_BYPMAX);
- else
- val = 0x0f; // recommended setting (default)
- DramConfigHi |= val << 24;
-
- val = pDCTstat->DIMM2Kpage;
- if (pDCTstat->GangedMode != 0) {
- if (dct != 0) {
- val &= 0x55;
- } else {
- val &= 0xAA;
- }
- }
- if (val)
- val = Tab_2KTfawT_k[pDCTstat->Speed];
- else
- val = Tab_1KTfawT_k[pDCTstat->Speed];
-
- if (pDCTstat->Speed == 5)
- val >>= 1;
-
- val -= Bias_TfawT;
- val <<= 28;
- DramConfigHi |= val; /* Tfaw for 1K or 2K paged drams */
-
- // FIXME: Skip for Ax versions
- DramConfigHi |= 1 << DcqArbBypassEn;
-
-
- /* Build MemClkDis Value from Dram Timing Lo and
- Dram Config Misc Registers
- 1. We will assume that MemClkDis field has been preset prior to this
- point.
- 2. We will only set MemClkDis bits if a DIMM is NOT present AND if:
- NV_AllMemClks <>0 AND SB_DiagClks == 0 */
-
-
- /* Dram Timing Low (owns Clock Enable bits) */
- DramTimingLo = Get_NB32(dev, 0x88 + reg_off);
- if (mctGet_NVbits(NV_AllMemClks) == 0) {
- /* Special Jedec SPD diagnostic bit - "enable all clocks" */
- if (!(pDCTstat->Status & (1 << SB_DiagClks))) {
- const u8 *p;
- byte = mctGet_NVbits(NV_PACK_TYPE);
- if (byte == PT_L1)
- p = Tab_L1CLKDis;
- else if (byte == PT_M2)
- p = Tab_M2CLKDis;
- else
- p = Tab_S1CLKDis;
-
- dword = 0;
- while (dword < MAX_DIMMS_SUPPORTED) {
- val = p[dword];
- print_tx("DramTimingLo: val=", val);
- if (!(pDCTstat->DIMMValid & (1 << val)))
- /*disable memclk*/
- DramTimingLo |= 1 << (dword+24);
- dword++;
- }
- }
- }
-
- print_tx("AutoConfig_D: DramControl: ", DramControl);
- print_tx("AutoConfig_D: DramTimingLo: ", DramTimingLo);
- print_tx("AutoConfig_D: DramConfigMisc: ", DramConfigMisc);
- print_tx("AutoConfig_D: DramConfigMisc2: ", DramConfigMisc2);
- print_tx("AutoConfig_D: DramConfigLo: ", DramConfigLo);
- print_tx("AutoConfig_D: DramConfigHi: ", DramConfigHi);
-
- /* Write Values to the registers */
- Set_NB32(dev, 0x78 + reg_off, DramControl);
- Set_NB32(dev, 0x88 + reg_off, DramTimingLo);
- Set_NB32(dev, 0xA0 + reg_off, DramConfigMisc);
- Set_NB32(dev, 0xA8 + reg_off, DramConfigMisc2);
- Set_NB32(dev, 0x90 + reg_off, DramConfigLo);
- mct_SetDramConfigHi_D(pDCTstat, dct, DramConfigHi);
- mct_ForceAutoPrecharge_D(pDCTstat, dct);
- mct_EarlyArbEn_D(pMCTstat, pDCTstat);
- mctHookAfterAutoCfg();
-
- print_tx("AutoConfig: Status ", pDCTstat->Status);
- print_tx("AutoConfig: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("AutoConfig: ErrCode ", pDCTstat->ErrCode);
- print_t("AutoConfig: Done\n");
-AutoConfig_exit:
- return pDCTstat->ErrCode;
-}
-
-
-static void SPDSetBanks_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Set bank addressing, program Mask values and build a chip-select
- * population map. This routine programs PCI 0:24N:2x80 config register
- * and PCI 0:24N:2x60,64,68,6C config registers (CS Mask 0-3).
- */
-
- u8 ChipSel, Rows, Cols, Ranks, Banks;
- u32 BankAddrReg, csMask;
-
- u32 val;
- u32 reg;
- u32 dev;
- u32 reg_off;
- u8 byte;
- u16 word;
- u32 dword;
- u16 smbaddr;
-
- dev = pDCTstat->dev_dct;
- reg_off = 0x100 * dct;
-
- BankAddrReg = 0;
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel+=2) {
- byte = ChipSel;
- if ((pDCTstat->Status & (1 << SB_64MuxedMode)) && ChipSel >=4)
- byte -= 3;
-
- if (pDCTstat->DIMMValid & (1 << byte)) {
- smbaddr = Get_DIMMAddress_D(pDCTstat, (ChipSel + dct));
-
- byte = mctRead_SPD(smbaddr, SPD_ROWSZ);
- Rows = byte & 0x1f;
-
- byte = mctRead_SPD(smbaddr, SPD_COLSZ);
- Cols = byte & 0x1f;
-
- Banks = mctRead_SPD(smbaddr, SPD_LBANKS);
-
- byte = mctRead_SPD(smbaddr, SPD_DEVWIDTH);
-
- byte = mctRead_SPD(smbaddr, SPD_DMBANKS);
- Ranks = (byte & 7) + 1;
-
- /* Configure Bank encoding
- * Use a 6-bit key into a lookup table.
- * Key (index) = CCCBRR, where CCC is the number of
- * Columns minus 9,RR is the number of Rows minus 13,
- * and B is the number of banks minus 2.
- * See "6-bit Bank Addressing Table" at the end of
- * this file.*/
- byte = Cols - 9; /* 9 Cols is smallest dev size */
- byte <<= 3; /* make room for row and bank bits*/
- if (Banks == 8)
- byte |= 4;
-
- /* 13 Rows is smallest dev size */
- byte |= Rows - 13; /* CCCBRR internal encode */
-
- for (dword = 0; dword < 12; dword++) {
- if (byte == Tab_BankAddr[dword])
- break;
- }
-
- if (dword < 12) {
-
- /* bit no. of CS field in address mapping reg.*/
- dword <<= (ChipSel << 1);
- BankAddrReg |= dword;
-
- /* Mask value=(2pow(rows+cols+banks+3)-1)>>8,
- or 2pow(rows+cols+banks-5)-1*/
- csMask = 0;
-
- byte = Rows + Cols; /* cl = rows+cols*/
- if (Banks == 8)
- byte -= 2; /* 3 banks - 5 */
- else
- byte -= 3; /* 2 banks - 5 */
- /* mask size (64-bit rank only) */
-
- if (pDCTstat->Status & (1 << SB_128bitmode))
- byte++; /* double mask size if in 128-bit mode*/
-
- csMask |= 1 << byte;
- csMask--;
-
- /*set ChipSelect population indicator even bits*/
- pDCTstat->CSPresent |= (1 << ChipSel);
- if (Ranks >= 2)
- /*set ChipSelect population indicator odd bits*/
- pDCTstat->CSPresent |= 1 << (ChipSel + 1);
-
- reg = 0x60+(ChipSel << 1) + reg_off; /*Dram CS Mask Register */
- val = csMask;
- val &= 0x1FF83FE0; /* Mask out reserved bits.*/
- Set_NB32(dev, reg, val);
- }
- } else {
- if (pDCTstat->DIMMSPDCSE & (1 << ChipSel))
- pDCTstat->CSTestFail |= (1 << ChipSel);
- } /* if DIMMValid*/
- } /* while ChipSel*/
-
- SetCSTriState(pMCTstat, pDCTstat, dct);
- /* SetCKETriState */
- SetODTTriState(pMCTstat, pDCTstat, dct);
-
- if (pDCTstat->Status & (1 << SB_128bitmode)) {
- SetCSTriState(pMCTstat, pDCTstat, 1); /* force dct1) */
- SetODTTriState(pMCTstat, pDCTstat, 1); /* force dct1) */
- }
- word = pDCTstat->CSPresent;
- mctGetCS_ExcludeMap(); /* mask out specified chip-selects */
- word ^= pDCTstat->CSPresent;
- pDCTstat->CSTestFail |= word; /* enable ODT to disabled DIMMs */
- if (!pDCTstat->CSPresent)
- pDCTstat->ErrCode = SC_StopError;
-
- reg = 0x80 + reg_off; /* Bank Addressing Register */
- Set_NB32(dev, reg, BankAddrReg);
-
- print_tx("SPDSetBanks: Status ", pDCTstat->Status);
- print_tx("SPDSetBanks: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("SPDSetBanks: ErrCode ", pDCTstat->ErrCode);
- print_t("SPDSetBanks: Done\n");
-}
-
-
-static void SPDCalcWidth_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Per SPDs, check the symmetry of DIMM pairs (DIMM on Channel A
- * matching with DIMM on Channel B), the overall DIMM population,
- * and determine the width mode: 64-bit, 64-bit muxed, 128-bit.
- */
-
- u8 i;
- u8 smbaddr, smbaddr1;
- u8 byte, byte1;
-
- /* Check Symmetry of Channel A and Channel B DIMMs
- (must be matched for 128-bit mode).*/
- for (i = 0; i < MAX_DIMMS_SUPPORTED; i += 2) {
- if ((pDCTstat->DIMMValid & (1 << i)) && (pDCTstat->DIMMValid & (1<<(i+1)))) {
- smbaddr = Get_DIMMAddress_D(pDCTstat, i);
- smbaddr1 = Get_DIMMAddress_D(pDCTstat, i+1);
-
- byte = mctRead_SPD(smbaddr, SPD_ROWSZ) & 0x1f;
- byte1 = mctRead_SPD(smbaddr1, SPD_ROWSZ) & 0x1f;
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1 << SB_DimmMismatchO);
- break;
- }
-
- byte = mctRead_SPD(smbaddr, SPD_COLSZ) & 0x1f;
- byte1 = mctRead_SPD(smbaddr1, SPD_COLSZ) & 0x1f;
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1 << SB_DimmMismatchO);
- break;
- }
-
- byte = mctRead_SPD(smbaddr, SPD_BANKSZ);
- byte1 = mctRead_SPD(smbaddr1, SPD_BANKSZ);
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1 << SB_DimmMismatchO);
- break;
- }
-
- byte = mctRead_SPD(smbaddr, SPD_DEVWIDTH) & 0x7f;
- byte1 = mctRead_SPD(smbaddr1, SPD_DEVWIDTH) & 0x7f;
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1 << SB_DimmMismatchO);
- break;
- }
-
- byte = mctRead_SPD(smbaddr, SPD_DMBANKS) & 7; /* #ranks-1 */
- byte1 = mctRead_SPD(smbaddr1, SPD_DMBANKS) & 7; /* #ranks-1 */
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1 << SB_DimmMismatchO);
- break;
- }
-
- }
- }
-
-}
-
-
-static void StitchMemory_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Requires that Mask values for each bank be programmed first and that
- * the chip-select population indicator is correctly set.
- */
-
- u8 b = 0;
- u32 nxtcsBase, curcsBase;
- u8 p, q;
- u32 BiggestBank;
- u8 _DSpareEn;
-
- u16 word;
- u32 dev;
- u32 reg;
- u32 reg_off;
- u32 val;
-
-
- dev = pDCTstat->dev_dct;
- reg_off = 0x100 * dct;
-
- _DSpareEn = 0;
-
- /* CS Sparing 1 = enabled, 0 = disabled */
- if (mctGet_NVbits(NV_CS_SpareCTL) & 1) {
- if (MCT_DIMM_SPARE_NO_WARM) {
- /* Do no warm-reset DIMM spare */
- if (pMCTstat->GStatus & 1 << GSB_EnDIMMSpareNW) {
- word = pDCTstat->CSPresent;
- val = bsf(word);
- word &= ~(1<<val);
- if (word)
- /* Make sure at least two chip-selects are available */
- _DSpareEn = 1;
- else
- pDCTstat->ErrStatus |= 1 << SB_SpareDis;
- }
- } else {
- if (!mctGet_NVbits(NV_DQSTrainCTL)) { /*DQS Training 1 = enabled, 0 = disabled */
- word = pDCTstat->CSPresent;
- val = bsf(word);
- word &= ~(1 << val);
- if (word)
- /* Make sure at least two chip-selects are available */
- _DSpareEn = 1;
- else
- pDCTstat->ErrStatus |= 1 << SB_SpareDis;
- }
- }
- }
-
- nxtcsBase = 0; /* Next available cs base ADDR[39:8] */
- for (p = 0; p < MAX_DIMMS_SUPPORTED; p++) {
- BiggestBank = 0;
- for (q = 0; q < MAX_CS_SUPPORTED; q++) { /* from DIMMS to CS */
- if (pDCTstat->CSPresent & (1 << q)) { /* bank present? */
- reg = 0x40 + (q << 2) + reg_off; /* Base[q] reg.*/
- val = Get_NB32(dev, reg);
- if (!(val & 3)) { /* (CSEnable|Spare == 1)bank is enabled already? */
- reg = 0x60 + ((q << 1) & 0xc) + reg_off; /*Mask[q] reg.*/
- val = Get_NB32(dev, reg);
- val >>= 19;
- val++;
- val <<= 19;
- if (val > BiggestBank) {
- /*Bingo! possibly Map this chip-select next! */
- BiggestBank = val;
- b = q;
- }
- }
- } /*if bank present */
- } /* while q */
- if (BiggestBank !=0) {
- curcsBase = nxtcsBase; /* curcsBase = nxtcsBase*/
- /* DRAM CS Base b Address Register offset */
- reg = 0x40 + (b << 2) + reg_off;
- if (_DSpareEn) {
- BiggestBank = 0;
- val = 1 << Spare; /* Spare Enable*/
- } else {
- val = curcsBase;
- val |= 1 << CSEnable; /* Bank Enable */
- }
- Set_NB32(dev, reg, val);
- if (_DSpareEn)
- _DSpareEn = 0;
- else
- /* let nxtcsBase+=Size[b] */
- nxtcsBase += BiggestBank;
- }
-
- /* bank present but disabled?*/
- if (pDCTstat->CSTestFail & (1 << p)) {
- /* DRAM CS Base b Address Register offset */
- reg = (p << 2) + 0x40 + reg_off;
- val = 1 << TestFail;
- Set_NB32(dev, reg, val);
- }
- }
-
- if (nxtcsBase) {
- pDCTstat->DCTSysLimit = nxtcsBase - 1;
- mct_AfterStitchMemory(pMCTstat, pDCTstat, dct);
- }
-
- print_tx("StitchMemory: Status ", pDCTstat->Status);
- print_tx("StitchMemory: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("StitchMemory: ErrCode ", pDCTstat->ErrCode);
- print_t("StitchMemory: Done\n");
-}
-
-
-static u8 Get_Tk_D(u8 k)
-{
- return Table_T_k[k];
-}
-
-
-static u8 Get_CLj_D(u8 j)
-{
- return Table_CL2_j[j];
-}
-
-static u8 Get_DefTrc_k_D(u8 k)
-{
- return Tab_defTrc_k[k];
-}
-
-
-static u16 Get_40Tk_D(u8 k)
-{
- return Tab_40T_k[k]; /* FIXME: k or k<<1 ?*/
-}
-
-
-static u16 Get_Fk_D(u8 k)
-{
- return Table_F_k[k]; /* FIXME: k or k<<1 ? */
-}
-
-
-static u8 Dimm_Supports_D(struct DCTStatStruc *pDCTstat,
- u8 i, u8 j, u8 k)
-{
- u8 Tk, CLj, CL_i;
- u8 ret = 0;
-
- u32 DIMMi;
- u8 byte;
- u16 word, wordx;
-
- DIMMi = Get_DIMMAddress_D(pDCTstat, i);
-
- CLj = Get_CLj_D(j);
-
- /* check if DIMMi supports CLj */
- CL_i = mctRead_SPD(DIMMi, SPD_CASLAT);
- byte = CL_i & CLj;
- if (byte) {
- /*find out if its CL X, CLX-1, or CLX-2 */
- word = bsr(byte); /* bit position of CLj */
- wordx = bsr(CL_i); /* bit position of CLX of CLi */
- wordx -= word; /* CL number (CL no. = 0,1, 2, or 3) */
- wordx <<= 3; /* 8 bits per SPD byte index */
- /*get T from SPD byte 9, 23, 25*/
- word = (EncodedTSPD >> wordx) & 0xFF;
- Tk = Get_Tk_D(k);
- byte = mctRead_SPD(DIMMi, word); /* DIMMi speed */
- if (Tk < byte) {
- ret = 1;
- } else if (byte == 0) {
- pDCTstat->ErrStatus |= 1 << SB_NoCycTime;
- ret = 1;
- } else {
- ret = 0; /* DIMM is capable! */
- }
- } else {
- ret = 1;
- }
- return ret;
-}
-
-
-static u8 DIMMPresence_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Check DIMMs present, verify checksum, flag SDRAM type,
- * build population indicator bitmaps, and preload bus loading
- * of DIMMs into DCTStatStruc.
- * MAAload = number of devices on the "A" bus.
- * MABload = number of devices on the "B" bus.
- * MAAdimms = number of DIMMs on the "A" bus slots.
- * MABdimms = number of DIMMs on the "B" bus slots.
- * DATAAload = number of ranks on the "A" bus slots.
- * DATABload = number of ranks on the "B" bus slots.
- */
-
- u16 i, j, k;
- u8 smbaddr, Index;
- u16 Checksum;
- u8 SPDCtrl;
- u16 RegDIMMPresent, MaxDimms;
- u8 devwidth;
- u16 DimmSlots;
- u8 byte = 0, bytex;
- u16 word;
-
- /* preload data structure with addrs */
- mctGet_DIMMAddr(pDCTstat, pDCTstat->Node_ID);
-
- DimmSlots = MaxDimms = mctGet_NVbits(NV_MAX_DIMMS);
-
- SPDCtrl = mctGet_NVbits(NV_SPDCHK_RESTRT);
-
- RegDIMMPresent = 0;
- pDCTstat->DimmQRPresent = 0;
-
- for (i = 0; i< MAX_DIMMS_SUPPORTED; i++) {
- if (i >= MaxDimms)
- break;
-
- if ((pDCTstat->DimmQRPresent & (1 << i)) || (i < DimmSlots)) {
- print_tx("\t DIMMPresence: i=", i);
- smbaddr = Get_DIMMAddress_D(pDCTstat, i);
- print_tx("\t DIMMPresence: smbaddr=", smbaddr);
- if (smbaddr) {
- Checksum = 0;
- for (Index = 0; Index < 64; Index++) {
- int status;
- status = mctRead_SPD(smbaddr, Index);
- if (status < 0)
- break;
- byte = status & 0xFF;
- if (Index < 63)
- Checksum += byte;
- }
-
- if (Index == 64) {
- pDCTstat->DIMMPresent |= 1 << i;
- if ((Checksum & 0xFF) == byte) {
- byte = mctRead_SPD(smbaddr, SPD_TYPE);
- if (byte == JED_DDR2SDRAM) {
- /*Dimm is 'Present'*/
- pDCTstat->DIMMValid |= 1 << i;
- }
- } else {
- pDCTstat->DIMMSPDCSE = 1 << i;
- if (SPDCtrl == 0) {
- pDCTstat->ErrStatus |= 1 << SB_DIMMChkSum;
- pDCTstat->ErrCode = SC_StopError;
- } else {
- /*if NV_SPDCHK_RESTRT is set to 1, ignore faulty SPD checksum*/
- pDCTstat->ErrStatus |= 1 << SB_DIMMChkSum;
- byte = mctRead_SPD(smbaddr, SPD_TYPE);
- if (byte == JED_DDR2SDRAM)
- pDCTstat->DIMMValid |= 1 << i;
- }
- }
- /* Get module information for SMBIOS */
- if (pDCTstat->DIMMValid & (1 << i)) {
- pDCTstat->DimmManufacturerID[i] = 0;
- for (k = 0; k < 8; k++)
- pDCTstat->DimmManufacturerID[i] |= ((uint64_t)mctRead_SPD(smbaddr, SPD_MANID_START + k)) << (k * 8);
- for (k = 0; k < SPD_PARTN_LENGTH; k++)
- pDCTstat->DimmPartNumber[i][k] = mctRead_SPD(smbaddr, SPD_PARTN_START + k);
- pDCTstat->DimmPartNumber[i][SPD_PARTN_LENGTH] = 0;
- pDCTstat->DimmRevisionNumber[i] = 0;
- for (k = 0; k < 2; k++)
- pDCTstat->DimmRevisionNumber[i] |= ((uint16_t)mctRead_SPD(smbaddr, SPD_REVNO_START + k)) << (k * 8);
- pDCTstat->DimmSerialNumber[i] = 0;
- for (k = 0; k < 4; k++)
- pDCTstat->DimmSerialNumber[i] |= ((uint32_t)mctRead_SPD(smbaddr, SPD_SERIAL_START + k)) << (k * 8);
- pDCTstat->DimmRows[i] = mctRead_SPD(smbaddr, SPD_ROWSZ) & 0xf;
- pDCTstat->DimmCols[i] = mctRead_SPD(smbaddr, SPD_COLSZ) & 0xf;
- pDCTstat->DimmRanks[i] = (mctRead_SPD(smbaddr, SPD_DMBANKS) & 0x7) + 1;
- pDCTstat->DimmBanks[i] = mctRead_SPD(smbaddr, SPD_LBANKS);
- pDCTstat->DimmWidth[i] = mctRead_SPD(smbaddr, SPD_DEVWIDTH);
- }
- /* Check module type */
- byte = mctRead_SPD(smbaddr, SPD_DIMMTYPE);
- if (byte & JED_REGADCMSK) {
- RegDIMMPresent |= 1 << i;
- pDCTstat->DimmRegistered[i] = 1;
- } else {
- pDCTstat->DimmRegistered[i] = 0;
- }
- /* Check ECC capable */
- byte = mctRead_SPD(smbaddr, SPD_EDCTYPE);
- if (byte & JED_ECC) {
- /* DIMM is ECC capable */
- pDCTstat->DimmECCPresent |= 1 << i;
- }
- if (byte & JED_ADRCPAR) {
- /* DIMM is ECC capable */
- pDCTstat->DimmPARPresent |= 1 << i;
- }
- /* Check if x4 device */
- devwidth = mctRead_SPD(smbaddr, SPD_DEVWIDTH) & 0xFE;
- if (devwidth == 4) {
- /* DIMM is made with x4 or x16 drams */
- pDCTstat->Dimmx4Present |= 1 << i;
- } else if (devwidth == 8) {
- pDCTstat->Dimmx8Present |= 1 << i;
- } else if (devwidth == 16) {
- pDCTstat->Dimmx16Present |= 1 << i;
- }
- /* check page size */
- byte = mctRead_SPD(smbaddr, SPD_COLSZ);
- byte &= 0x0F;
- word = 1 << byte;
- word >>= 3;
- word *= devwidth; /* (((2^COLBITS) / 8) * ORG) / 2048 */
- word >>= 11;
- if (word)
- pDCTstat->DIMM2Kpage |= 1 << i;
-
- /*Check if SPD diag bit 'analysis probe installed' is set */
- byte = mctRead_SPD(smbaddr, SPD_ATTRIB);
- if (byte & JED_PROBEMSK)
- pDCTstat->Status |= 1 << SB_DiagClks;
-
- byte = mctRead_SPD(smbaddr, SPD_DMBANKS);
- if (!(byte & (1 << SPDPLBit)))
- pDCTstat->DimmPlPresent |= 1 << i;
- byte &= 7;
- byte++; /* ranks */
- if (byte > 2) {
- /* if any DIMMs are QR, we have to make two passes through DIMMs*/
- if (pDCTstat->DimmQRPresent == 0) {
- MaxDimms <<= 1;
- }
- if (i < DimmSlots) {
- pDCTstat->DimmQRPresent |= (1 << i) | (1 << (i+4));
- }
- byte = 2; /* upper two ranks of QR DIMM will be counted on another DIMM number iteration*/
- } else if (byte == 2) {
- pDCTstat->DimmDRPresent |= 1 << i;
- }
- bytex = devwidth;
- if (devwidth == 16)
- bytex = 4;
- else if (devwidth == 4)
- bytex = 16;
-
- if (byte == 2)
- bytex <<= 1; /*double Addr bus load value for dual rank DIMMs*/
-
- j = i & (1<<0);
- pDCTstat->DATAload[j] += byte; /*number of ranks on DATA bus*/
- pDCTstat->MAload[j] += bytex; /*number of devices on CMD/ADDR bus*/
- pDCTstat->MAdimms[j]++; /*number of DIMMs on A bus */
- /*check for DRAM package Year <= 06*/
- byte = mctRead_SPD(smbaddr, SPD_MANDATEYR);
- if (byte < MYEAR06) {
- /*Year < 06 and hence Week < 24 of 06 */
- pDCTstat->DimmYr06 |= 1 << i;
- pDCTstat->DimmWk2406 |= 1 << i;
- } else if (byte == MYEAR06) {
- /*Year = 06, check if Week <= 24 */
- pDCTstat->DimmYr06 |= 1 << i;
- byte = mctRead_SPD(smbaddr, SPD_MANDATEWK);
- if (byte <= MWEEK24)
- pDCTstat->DimmWk2406 |= 1 << i;
- }
- }
- }
- }
- }
- print_tx("\t DIMMPresence: DIMMValid=", pDCTstat->DIMMValid);
- print_tx("\t DIMMPresence: DIMMPresent=", pDCTstat->DIMMPresent);
- print_tx("\t DIMMPresence: RegDIMMPresent=", RegDIMMPresent);
- print_tx("\t DIMMPresence: DimmECCPresent=", pDCTstat->DimmECCPresent);
- print_tx("\t DIMMPresence: DimmPARPresent=", pDCTstat->DimmPARPresent);
- print_tx("\t DIMMPresence: Dimmx4Present=", pDCTstat->Dimmx4Present);
- print_tx("\t DIMMPresence: Dimmx8Present=", pDCTstat->Dimmx8Present);
- print_tx("\t DIMMPresence: Dimmx16Present=", pDCTstat->Dimmx16Present);
- print_tx("\t DIMMPresence: DimmPlPresent=", pDCTstat->DimmPlPresent);
- print_tx("\t DIMMPresence: DimmDRPresent=", pDCTstat->DimmDRPresent);
- print_tx("\t DIMMPresence: DimmQRPresent=", pDCTstat->DimmQRPresent);
- print_tx("\t DIMMPresence: DATAload[0]=", pDCTstat->DATAload[0]);
- print_tx("\t DIMMPresence: MAload[0]=", pDCTstat->MAload[0]);
- print_tx("\t DIMMPresence: MAdimms[0]=", pDCTstat->MAdimms[0]);
- print_tx("\t DIMMPresence: DATAload[1]=", pDCTstat->DATAload[1]);
- print_tx("\t DIMMPresence: MAload[1]=", pDCTstat->MAload[1]);
- print_tx("\t DIMMPresence: MAdimms[1]=", pDCTstat->MAdimms[1]);
-
- if (pDCTstat->DIMMValid != 0) { /* If any DIMMs are present...*/
- if (RegDIMMPresent != 0) {
- if ((RegDIMMPresent ^ pDCTstat->DIMMValid) !=0) {
- /* module type DIMM mismatch (reg'ed, unbuffered) */
- pDCTstat->ErrStatus |= 1 << SB_DimmMismatchM;
- pDCTstat->ErrCode = SC_StopError;
- } else{
- /* all DIMMs are registered */
- pDCTstat->Status |= 1 << SB_Registered;
- }
- }
- if (pDCTstat->DimmECCPresent != 0) {
- if ((pDCTstat->DimmECCPresent ^ pDCTstat->DIMMValid) == 0) {
- /* all DIMMs are ECC capable */
- pDCTstat->Status |= 1 << SB_ECCDIMMs;
- }
- }
- if (pDCTstat->DimmPARPresent != 0) {
- if ((pDCTstat->DimmPARPresent ^ pDCTstat->DIMMValid) == 0) {
- /*all DIMMs are Parity capable */
- pDCTstat->Status |= 1 << SB_PARDIMMs;
- }
- }
- } else {
- /* no DIMMs present or no DIMMs that qualified. */
- pDCTstat->ErrStatus |= 1 << SB_NoDimms;
- pDCTstat->ErrCode = SC_StopError;
- }
-
- print_tx("\t DIMMPresence: Status ", pDCTstat->Status);
- print_tx("\t DIMMPresence: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("\t DIMMPresence: ErrCode ", pDCTstat->ErrCode);
- print_t("\t DIMMPresence: Done\n");
-
- mctHookAfterDIMMpre();
-
- return pDCTstat->ErrCode;
-}
-
-
-static u8 Sys_Capability_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, int j, int k)
-{
- /* Determine if system is capable of operating at given input
- * parameters for CL, and T. There are three components to
- * determining "maximum frequency" in AUTO mode: SPD component,
- * Bus load component, and "Preset" max frequency component.
- * This procedure is used to help find the SPD component and relies
- * on pre-determination of the bus load component and the Preset
- * components. The generalized algorithm for finding maximum
- * frequency is structured this way so as to optimize for CAS
- * latency (which might get better as a result of reduced frequency).
- * See "Global relationship between index values and item values"
- * for definition of CAS latency index (j) and Frequency index (k).
- */
- u8 freqOK, ClOK;
- u8 ret = 0;
-
- if (Get_Fk_D(k) > pDCTstat->PresetmaxFreq)
- freqOK = 0;
- else
- freqOK = 1;
-
- /* compare proposed CAS latency with AMD Si capabilities */
- if ((j < J_MIN) || (j > J_MAX))
- ClOK = 0;
- else
- ClOK = 1;
-
- if (freqOK && ClOK)
- ret = 1;
-
- return ret;
-}
-
-
-static u8 Get_DIMMAddress_D(struct DCTStatStruc *pDCTstat, u8 i)
-{
- u8 *p;
-
- p = pDCTstat->DIMMAddr;
- return p[i];
-}
-
-
-static void mct_initDCT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 val;
- u8 err_code;
-
- /* Config. DCT0 for Ganged or unganged mode */
- print_t("\tmct_initDCT: DCTInit_D 0\n");
- DCTInit_D(pMCTstat, pDCTstat, 0);
- if (pDCTstat->ErrCode == SC_FatalErr) {
- // Do nothing goto exitDCTInit; /* any fatal errors? */
- } else {
- /* Configure DCT1 if unganged and enabled*/
- if (!pDCTstat->GangedMode) {
- if (pDCTstat->DIMMValidDCT[1] > 0) {
- print_t("\tmct_initDCT: DCTInit_D 1\n");
- err_code = pDCTstat->ErrCode; /* save DCT0 errors */
- pDCTstat->ErrCode = 0;
- DCTInit_D(pMCTstat, pDCTstat, 1);
- if (pDCTstat->ErrCode == 2) /* DCT1 is not Running */
- pDCTstat->ErrCode = err_code; /* Using DCT0 Error code to update pDCTstat.ErrCode */
- } else {
- val = 1 << DisDramInterface;
- Set_NB32(pDCTstat->dev_dct, 0x100 + 0x94, val);
- }
- }
- }
-// exitDCTInit:
-}
-
-
-static void mct_DramInit(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
-
- mct_BeforeDramInit_Prod_D(pMCTstat, pDCTstat);
- // FIXME: for rev A: mct_BeforeDramInit_D(pDCTstat, dct);
-
- /* Disable auto refresh before Dram init when in ganged mode (Erratum 278) */
- if (pDCTstat->LogicalCPUID & (AMD_DR_B0 | AMD_DR_B1 | AMD_DR_BA)) {
- if (pDCTstat->GangedMode) {
- val = Get_NB32(pDCTstat->dev_dct, 0x8C + (0x100 * dct));
- val |= 1 << DisAutoRefresh;
- Set_NB32(pDCTstat->dev_dct, 0x8C + (0x100 * dct), val);
- }
- }
-
- mct_DramInit_Hw_D(pMCTstat, pDCTstat, dct);
-
- /* Re-enable auto refresh after Dram init when in ganged mode
- * to ensure both DCTs are in sync (Erratum 278)
- */
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_B0 | AMD_DR_B1 | AMD_DR_BA)) {
- if (pDCTstat->GangedMode) {
- do {
- val = Get_NB32(pDCTstat->dev_dct, 0x90 + (0x100 * dct));
- } while (!(val & (1 << InitDram)));
-
- WaitRoutine_D(50);
-
- val = Get_NB32(pDCTstat->dev_dct, 0x8C + (0x100 * dct));
- val &= ~(1 << DisAutoRefresh);
- Set_NB32(pDCTstat->dev_dct, 0x8C + (0x100 * dct), val);
- val |= 1 << DisAutoRefresh;
- Set_NB32(pDCTstat->dev_dct, 0x8C + (0x100 * dct), val);
- val &= ~(1 << DisAutoRefresh);
- Set_NB32(pDCTstat->dev_dct, 0x8C + (0x100 * dct), val);
- }
- }
-}
-
-
-static u8 mct_setMode(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 byte;
- u8 bytex;
- u32 val;
- u32 reg;
-
- byte = bytex = pDCTstat->DIMMValid;
- bytex &= 0x55; /* CHA DIMM pop */
- pDCTstat->DIMMValidDCT[0] = bytex;
-
- byte &= 0xAA; /* CHB DIMM popa */
- byte >>= 1;
- pDCTstat->DIMMValidDCT[1] = byte;
-
- if (byte != bytex) {
- pDCTstat->ErrStatus &= ~(1 << SB_DimmMismatchO);
- } else {
- if (mctGet_NVbits(NV_Unganged))
- pDCTstat->ErrStatus |= (1 << SB_DimmMismatchO);
-
- if (!(pDCTstat->ErrStatus & (1 << SB_DimmMismatchO))) {
- pDCTstat->GangedMode = 1;
- /* valid 128-bit mode population. */
- pDCTstat->Status |= 1 << SB_128bitmode;
- reg = 0x110;
- val = Get_NB32(pDCTstat->dev_dct, reg);
- val |= 1 << DctGangEn;
- Set_NB32(pDCTstat->dev_dct, reg, val);
- print_tx("setMode: DRAM Controller Select Low Register = ", val);
- }
- }
- return pDCTstat->ErrCode;
-}
-
-
-u32 Get_NB32(u32 dev, u32 reg)
-{
- return pci_read_config32(dev, reg);
-}
-
-
-void Set_NB32(u32 dev, u32 reg, u32 val)
-{
- pci_write_config32(dev, reg, val);
-}
-
-
-u32 Get_NB32_index(u32 dev, u32 index_reg, u32 index)
-{
- u32 dword;
-
- Set_NB32(dev, index_reg, index);
- dword = Get_NB32(dev, index_reg+0x4);
-
- return dword;
-}
-
-void Set_NB32_index(u32 dev, u32 index_reg, u32 index, u32 data)
-{
- Set_NB32(dev, index_reg, index);
- Set_NB32(dev, index_reg + 0x4, data);
-}
-
-
-u32 Get_NB32_index_wait(u32 dev, u32 index_reg, u32 index)
-{
-
- u32 dword;
-
-
- index &= ~(1 << DctAccessWrite);
- Set_NB32(dev, index_reg, index);
- do {
- dword = Get_NB32(dev, index_reg);
- } while (!(dword & (1 << DctAccessDone)));
- dword = Get_NB32(dev, index_reg + 0x4);
-
- return dword;
-}
-
-
-void Set_NB32_index_wait(u32 dev, u32 index_reg, u32 index, u32 data)
-{
- u32 dword;
-
-
- Set_NB32(dev, index_reg + 0x4, data);
- index |= (1 << DctAccessWrite);
- Set_NB32(dev, index_reg, index);
- do {
- dword = Get_NB32(dev, index_reg);
- } while (!(dword & (1 << DctAccessDone)));
-
-}
-
-
-static u8 mct_PlatformSpec(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Get platform specific config/timing values from the interface layer
- * and program them into DCT.
- */
-
- u32 dev = pDCTstat->dev_dct;
- u32 index_reg;
- u8 i, i_start, i_end;
-
- if (pDCTstat->GangedMode) {
- SyncSetting(pDCTstat);
- i_start = 0;
- i_end = 2;
- } else {
- i_start = dct;
- i_end = dct + 1;
- }
- for (i = i_start; i < i_end; i++) {
- index_reg = 0x98 + (i * 0x100);
- Set_NB32_index_wait(dev, index_reg, 0x00, pDCTstat->CH_ODC_CTL[i]); /* Channel A Output Driver Compensation Control */
- Set_NB32_index_wait(dev, index_reg, 0x04, pDCTstat->CH_ADDR_TMG[i]); /* Channel A Output Driver Compensation Control */
- }
-
- return pDCTstat->ErrCode;
-
-}
-
-
-static void mct_SyncDCTsReady(struct DCTStatStruc *pDCTstat)
-{
- u32 dev;
- u32 val;
-
- if (pDCTstat->NodePresent) {
- print_tx("mct_SyncDCTsReady: Node ", pDCTstat->Node_ID);
- dev = pDCTstat->dev_dct;
-
- if ((pDCTstat->DIMMValidDCT[0]) || (pDCTstat->DIMMValidDCT[1])) { /* This Node has dram */
- do {
- val = Get_NB32(dev, 0x110);
- } while (!(val & (1 << DramEnabled)));
- print_t("mct_SyncDCTsReady: DramEnabled\n");
- }
- } /* Node is present */
-}
-
-
-static void mct_AfterGetCLT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- if (!pDCTstat->GangedMode) {
- if (dct == 0) {
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[dct];
- if (pDCTstat->DIMMValidDCT[dct] == 0)
- pDCTstat->ErrCode = SC_StopError;
- } else {
- pDCTstat->CSPresent = 0;
- pDCTstat->CSTestFail = 0;
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[dct];
- if (pDCTstat->DIMMValidDCT[dct] == 0)
- pDCTstat->ErrCode = SC_StopError;
- }
- }
-}
-
-static u8 mct_SPDCalcWidth(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 ret;
-
- if (dct == 0) {
- SPDCalcWidth_D(pMCTstat, pDCTstat);
- ret = mct_setMode(pMCTstat, pDCTstat);
- } else {
- ret = pDCTstat->ErrCode;
- }
-
- print_tx("SPDCalcWidth: Status ", pDCTstat->Status);
- print_tx("SPDCalcWidth: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("SPDCalcWidth: ErrCode ", pDCTstat->ErrCode);
- print_t("SPDCalcWidth: Done\n");
-
- return ret;
-}
-
-
-static void mct_AfterStitchMemory(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 dword;
- u32 dev;
- u32 reg;
- u8 _MemHoleRemap;
- u32 DramHoleBase;
-
- _MemHoleRemap = mctGet_NVbits(NV_MemHole);
- DramHoleBase = mctGet_NVbits(NV_BottomIO);
- DramHoleBase <<= 8;
- /* Increase hole size so;[31:24]to[31:16]
- * it has granularity of 128MB shl eax,8
- * Set 'effective' bottom IOmov DramHoleBase,eax
- */
- pMCTstat->HoleBase = (DramHoleBase & 0xFFFFF800) << 8;
-
- /* In unganged mode, we must add DCT0 and DCT1 to DCTSysLimit */
- if (!pDCTstat->GangedMode) {
- dev = pDCTstat->dev_dct;
- pDCTstat->NodeSysLimit += pDCTstat->DCTSysLimit;
- /* if DCT0 and DCT1 both exist, set DctSelBaseAddr[47:27] to the top of DCT0 */
- if (dct == 0) {
- if (pDCTstat->DIMMValidDCT[1] > 0) {
- dword = pDCTstat->DCTSysLimit + 1;
- dword += pDCTstat->NodeSysBase;
- dword >>= 8; /* scale [39:8] to [47:27],and to F2x110[31:11] */
- if ((dword >= DramHoleBase) && _MemHoleRemap) {
- pMCTstat->HoleBase = (DramHoleBase & 0xFFFFF800) << 8;
- val = pMCTstat->HoleBase;
- val >>= 16;
- val = (((~val) & 0xFF) + 1);
- val <<= 8;
- dword += val;
- }
- reg = 0x110;
- val = Get_NB32(dev, reg);
- val &= 0x7F;
- val |= dword;
- val |= 3; /* Set F2x110[DctSelHiRngEn], F2x110[DctSelHi] */
- Set_NB32(dev, reg, val);
- print_tx("AfterStitch DCT0 and DCT1: DRAM Controller Select Low Register = ", val);
- print_tx("AfterStitch DCT0 and DCT1: DRAM Controller Select High Register = ", dword);
-
- reg = 0x114;
- val = dword;
- Set_NB32(dev, reg, val);
- }
- } else {
- /* Program the DctSelBaseAddr value to 0
- if DCT 0 is disabled */
- if (pDCTstat->DIMMValidDCT[0] == 0) {
- dword = pDCTstat->NodeSysBase;
- dword >>= 8;
- if ((dword >= DramHoleBase) && _MemHoleRemap) {
- pMCTstat->HoleBase = (DramHoleBase & 0xFFFFF800) << 8;
- val = pMCTstat->HoleBase;
- val >>= 8;
- val &= ~(0xFFFF);
- val |= (((~val) & 0xFFFF) + 1);
- dword += val;
- }
- reg = 0x114;
- val = dword;
- Set_NB32(dev, reg, val);
-
- reg = 0x110;
- val |= 3; /* Set F2x110[DctSelHiRngEn], F2x110[DctSelHi] */
- Set_NB32(dev, reg, val);
- print_tx("AfterStitch DCT1 only: DRAM Controller Select Low Register = ", val);
- print_tx("AfterStitch DCT1 only: DRAM Controller Select High Register = ", dword);
- }
- }
- } else {
- pDCTstat->NodeSysLimit += pDCTstat->DCTSysLimit;
- }
- print_tx("AfterStitch pDCTstat->NodeSysBase = ", pDCTstat->NodeSysBase);
- print_tx("mct_AfterStitchMemory: pDCTstat->NodeSysLimit ", pDCTstat->NodeSysLimit);
-}
-
-
-static u8 mct_DIMMPresence(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 ret;
-
- if (dct == 0)
- ret = DIMMPresence_D(pMCTstat, pDCTstat);
- else
- ret = pDCTstat->ErrCode;
-
- return ret;
-}
-
-
-/* mct_BeforeGetDIMMAddress inline in C */
-
-
-static void mct_OtherTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (pDCTstat->NodePresent) {
- if (pDCTstat->DIMMValidDCT[0]) {
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[0];
- Set_OtherTiming(pMCTstat, pDCTstat, 0);
- }
- if (pDCTstat->DIMMValidDCT[1] && !pDCTstat->GangedMode) {
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[1];
- Set_OtherTiming(pMCTstat, pDCTstat, 1);
- }
- } /* Node is present*/
- } /* while Node */
-}
-
-
-static void Set_OtherTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 reg;
- u32 reg_off = 0x100 * dct;
- u32 val;
- u32 dword;
- u32 dev = pDCTstat->dev_dct;
-
- Get_Trdrd(pMCTstat, pDCTstat, dct);
- Get_Twrwr(pMCTstat, pDCTstat, dct);
- Get_Twrrd(pMCTstat, pDCTstat, dct);
- Get_TrwtTO(pMCTstat, pDCTstat, dct);
- Get_TrwtWB(pMCTstat, pDCTstat);
-
- reg = 0x8C + reg_off; /* Dram Timing Hi */
- val = Get_NB32(dev, reg);
- val &= 0xffff0300;
- dword = pDCTstat->TrwtTO; //0x07
- val |= dword << 4;
- dword = pDCTstat->Twrrd; //0x03
- val |= dword << 10;
- dword = pDCTstat->Twrwr; //0x03
- val |= dword << 12;
- dword = pDCTstat->Trdrd; //0x03
- val |= dword << 14;
- dword = pDCTstat->TrwtWB; //0x07
- val |= dword;
- val = OtherTiming_A_D(pDCTstat, val);
- Set_NB32(dev, reg, val);
-
-}
-
-
-static void Get_Trdrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 Trdrd;
- u8 byte;
- u32 dword;
- u32 val;
- u32 index_reg = 0x98 + 0x100 * dct;
- u32 dev = pDCTstat->dev_dct;
-
- if ((pDCTstat->Dimmx4Present != 0) && (pDCTstat->Dimmx8Present != 0)) {
- /* mixed (x4 or x8) DIMM types
- the largest DqsRcvEnGrossDelay of any DIMM minus the DqsRcvEnGrossDelay
- of any other DIMM is equal to the Critical Gross Delay Difference (CGDD) for Trdrd.*/
- byte = Get_DqsRcvEnGross_Diff(pDCTstat, dev, index_reg);
- if (byte == 0)
- Trdrd = 1;
- else
- Trdrd = 2;
-
- } else {
- /*
- Trdrd with non-mixed DIMM types
- RdDqsTime are the same for all DIMMs and DqsRcvEn difference between
- any two DIMMs is less than half of a MEMCLK, BIOS should program Trdrd to 0000b,
- else BIOS should program Trdrd to 0001b.
-
- RdDqsTime are the same for all DIMMs
- DDR400~DDR667 only use one set register
- DDR800 have two set register for DIMM0 and DIMM1 */
- Trdrd = 1;
- if (pDCTstat->Speed > 3) {
- /* DIMM0+DIMM1 exist */ //NOTE it should be 5
- val = bsf(pDCTstat->DIMMValid);
- dword = bsr(pDCTstat->DIMMValid);
- if (dword != val && dword != 0) {
- /* DCT Read DQS Timing Control - DIMM0 - Low */
- dword = Get_NB32_index_wait(dev, index_reg, 0x05);
- /* DCT Read DQS Timing Control - DIMM1 - Low */
- val = Get_NB32_index_wait(dev, index_reg, 0x105);
- if (val != dword)
- goto Trdrd_1;
-
- /* DCT Read DQS Timing Control - DIMM0 - High */
- dword = Get_NB32_index_wait(dev, index_reg, 0x06);
- /* DCT Read DQS Timing Control - DIMM1 - High */
- val = Get_NB32_index_wait(dev, index_reg, 0x106);
- if (val != dword)
- goto Trdrd_1;
- }
- }
-
- /* DqsRcvEn difference between any two DIMMs is
- less than half of a MEMCLK */
- /* DqsRcvEn byte 1,0*/
- if (Check_DqsRcvEn_Diff(pDCTstat, dct, dev, index_reg, 0x10))
- goto Trdrd_1;
- /* DqsRcvEn byte 3,2*/
- if (Check_DqsRcvEn_Diff(pDCTstat, dct, dev, index_reg, 0x11))
- goto Trdrd_1;
- /* DqsRcvEn byte 5,4*/
- if (Check_DqsRcvEn_Diff(pDCTstat, dct, dev, index_reg, 0x20))
- goto Trdrd_1;
- /* DqsRcvEn byte 7,6*/
- if (Check_DqsRcvEn_Diff(pDCTstat, dct, dev, index_reg, 0x21))
- goto Trdrd_1;
- /* DqsRcvEn ECC*/
- if (Check_DqsRcvEn_Diff(pDCTstat, dct, dev, index_reg, 0x12))
- goto Trdrd_1;
- Trdrd = 0;
- Trdrd_1:
- ;
- }
- pDCTstat->Trdrd = Trdrd;
-
-}
-
-
-static void Get_Twrwr(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 Twrwr = 0;
- u32 index_reg = 0x98 + 0x100 * dct;
- u32 dev = pDCTstat->dev_dct;
- u32 val;
- u32 dword;
-
- /* WrDatGrossDlyByte only use one set register when DDR400~DDR667
- DDR800 have two set register for DIMM0 and DIMM1 */
- if (pDCTstat->Speed > 3) {
- val = bsf(pDCTstat->DIMMValid);
- dword = bsr(pDCTstat->DIMMValid);
- if (dword != val && dword != 0) {
- /*the largest WrDatGrossDlyByte of any DIMM minus the
- WrDatGrossDlyByte of any other DIMM is equal to CGDD */
- val = Get_WrDatGross_Diff(pDCTstat, dct, dev, index_reg);
- }
- if (val == 0)
- Twrwr = 2;
- else
- Twrwr = 3;
- }
- pDCTstat->Twrwr = Twrwr;
-}
-
-
-static void Get_Twrrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 byte, bytex, val;
- u32 index_reg = 0x98 + 0x100 * dct;
- u32 dev = pDCTstat->dev_dct;
-
- /* On any given byte lane, the largest WrDatGrossDlyByte delay of
- any DIMM minus the DqsRcvEnGrossDelay delay of any other DIMM is
- equal to the Critical Gross Delay Difference (CGDD) for Twrrd.*/
-
- /* WrDatGrossDlyByte only use one set register when DDR400~DDR667
- DDR800 have two set register for DIMM0 and DIMM1 */
- if (pDCTstat->Speed > 3) {
- val = Get_WrDatGross_Diff(pDCTstat, dct, dev, index_reg);
- } else {
- val = Get_WrDatGross_MaxMin(pDCTstat, dct, dev, index_reg, 1); /* WrDatGrossDlyByte byte 0,1,2,3 for DIMM0 */
- pDCTstat->WrDatGrossH = (u8) val; /* low byte = max value */
- }
-
- Get_DqsRcvEnGross_Diff(pDCTstat, dev, index_reg);
-
- bytex = pDCTstat->DqsRcvEnGrossL;
- byte = pDCTstat->WrDatGrossH;
- if (byte > bytex) {
- byte -= bytex;
- if (byte == 1)
- bytex = 1;
- else
- bytex = 2;
- } else {
- bytex = 0;
- }
- pDCTstat->Twrrd = bytex;
-}
-
-
-static void Get_TrwtTO(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 byte, bytex;
- u32 index_reg = 0x98 + 0x100 * dct;
- u32 dev = pDCTstat->dev_dct;
-
- /* On any given byte lane, the largest WrDatGrossDlyByte delay of
- any DIMM minus the DqsRcvEnGrossDelay delay of any other DIMM is
- equal to the Critical Gross Delay Difference (CGDD) for TrwtTO. */
- Get_DqsRcvEnGross_Diff(pDCTstat, dev, index_reg);
- Get_WrDatGross_Diff(pDCTstat, dct, dev, index_reg);
- bytex = pDCTstat->DqsRcvEnGrossL;
- byte = pDCTstat->WrDatGrossH;
- if (bytex > byte) {
- bytex -= byte;
- if ((bytex == 1) || (bytex == 2))
- bytex = 3;
- else
- bytex = 4;
- } else {
- byte -= bytex;
- if ((byte == 0) || (byte == 1))
- bytex = 2;
- else
- bytex = 1;
- }
-
- pDCTstat->TrwtTO = bytex;
-}
-
-
-static void Get_TrwtWB(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* TrwtWB ensures read-to-write data-bus turnaround.
- This value should be one more than the programmed TrwtTO.*/
- pDCTstat->TrwtWB = pDCTstat->TrwtTO + 1;
-}
-
-
-static u8 Check_DqsRcvEn_Diff(struct DCTStatStruc *pDCTstat,
- u8 dct, u32 dev, u32 index_reg,
- u32 index)
-{
- u8 Smallest_0, Largest_0, Smallest_1, Largest_1;
- u8 i;
- u32 val;
- u8 byte;
- u8 ecc_reg = 0;
-
- Smallest_0 = 0xFF;
- Smallest_1 = 0xFF;
- Largest_0 = 0;
- Largest_1 = 0;
-
- if (index == 0x12)
- ecc_reg = 1;
-
- for (i = 0; i < 8; i+=2) {
- if (pDCTstat->DIMMValid & (1 << i)) {
- val = Get_NB32_index_wait(dev, index_reg, index);
- byte = val & 0xFF;
- if (byte < Smallest_0)
- Smallest_0 = byte;
- if (byte > Largest_0)
- Largest_0 = byte;
- if (!(ecc_reg)) {
- byte = (val >> 16) & 0xFF;
- if (byte < Smallest_1)
- Smallest_1 = byte;
- if (byte > Largest_1)
- Largest_1 = byte;
- }
- }
- index += 3;
- } /* while ++i */
-
- /* check if total DqsRcvEn delay difference between any
- two DIMMs is less than half of a MEMCLK */
- if ((Largest_0 - Smallest_0) > 31)
- return 1;
- if (!(ecc_reg))
- if ((Largest_1 - Smallest_1) > 31)
- return 1;
- return 0;
-}
-
-
-static u8 Get_DqsRcvEnGross_Diff(struct DCTStatStruc *pDCTstat,
- u32 dev, u32 index_reg)
-{
- u8 Smallest, Largest;
- u32 val;
- u8 byte, bytex;
-
- /* The largest DqsRcvEnGrossDelay of any DIMM minus the
- DqsRcvEnGrossDelay of any other DIMM is equal to the Critical
- Gross Delay Difference (CGDD) */
- /* DqsRcvEn byte 1,0 */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, index_reg, 0x10);
- Largest = val & 0xFF;
- Smallest = (val >> 8) & 0xFF;
-
- /* DqsRcvEn byte 3,2 */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, index_reg, 0x11);
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
-
- /* DqsRcvEn byte 5,4 */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, index_reg, 0x20);
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
-
- /* DqsRcvEn byte 7,6 */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, index_reg, 0x21);
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
-
- if (pDCTstat->DimmECCPresent> 0) {
- /*DqsRcvEn Ecc */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, index_reg, 0x12);
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
- }
-
- pDCTstat->DqsRcvEnGrossL = Largest;
- return Largest - Smallest;
-}
-
-
-static u8 Get_WrDatGross_Diff(struct DCTStatStruc *pDCTstat,
- u8 dct, u32 dev, u32 index_reg)
-{
- u8 Smallest, Largest;
- u32 val;
- u8 byte, bytex;
-
- /* The largest WrDatGrossDlyByte of any DIMM minus the
- WrDatGrossDlyByte of any other DIMM is equal to CGDD */
- val = Get_WrDatGross_MaxMin(pDCTstat, dct, dev, index_reg, 0x01); /* WrDatGrossDlyByte byte 0,1,2,3 for DIMM0 */
- Largest = val & 0xFF;
- Smallest = (val >> 8) & 0xFF;
- val = Get_WrDatGross_MaxMin(pDCTstat, dct, dev, index_reg, 0x101); /* WrDatGrossDlyByte byte 0,1,2,3 for DIMM1 */
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
-
- // FIXME: Add Cx support.
-
- pDCTstat->WrDatGrossH = Largest;
- return Largest - Smallest;
-}
-
-static u16 Get_DqsRcvEnGross_MaxMin(struct DCTStatStruc *pDCTstat,
- u32 dev, u32 index_reg,
- u32 index)
-{
- u8 Smallest, Largest;
- u8 i;
- u8 byte;
- u32 val;
- u16 word;
- u8 ecc_reg = 0;
-
- Smallest = 7;
- Largest = 0;
-
- if (index == 0x12)
- ecc_reg = 1;
-
- for (i = 0; i < 8; i+=2) {
- if (pDCTstat->DIMMValid & (1 << i)) {
- val = Get_NB32_index_wait(dev, index_reg, index);
- val &= 0x00E000E0;
- byte = (val >> 5) & 0xFF;
- if (byte < Smallest)
- Smallest = byte;
- if (byte > Largest)
- Largest = byte;
- if (!(ecc_reg)) {
- byte = (val >> (16 + 5)) & 0xFF;
- if (byte < Smallest)
- Smallest = byte;
- if (byte > Largest)
- Largest = byte;
- }
- }
- index += 3;
- } /* while ++i */
-
- word = Smallest;
- word <<= 8;
- word |= Largest;
-
- return word;
-}
-
-static u16 Get_WrDatGross_MaxMin(struct DCTStatStruc *pDCTstat,
- u8 dct, u32 dev, u32 index_reg,
- u32 index)
-{
- u8 Smallest, Largest;
- u8 i, j;
- u32 val;
- u8 byte;
- u16 word;
-
- Smallest = 3;
- Largest = 0;
- for (i = 0; i < 2; i++) {
- val = Get_NB32_index_wait(dev, index_reg, index);
- val &= 0x60606060;
- val >>= 5;
- for (j = 0; j < 4; j++) {
- byte = val & 0xFF;
- if (byte < Smallest)
- Smallest = byte;
- if (byte > Largest)
- Largest = byte;
- val >>= 8;
- } /* while ++j */
- index++;
- } /*while ++i*/
-
- if (pDCTstat->DimmECCPresent > 0) {
- index++;
- val = Get_NB32_index_wait(dev, index_reg, index);
- val &= 0x00000060;
- val >>= 5;
- byte = val & 0xFF;
- if (byte < Smallest)
- Smallest = byte;
- if (byte > Largest)
- Largest = byte;
- }
-
- word = Smallest;
- word <<= 8;
- word |= Largest;
-
- return word;
-}
-
-
-
-static void mct_FinalMCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- print_t("\tmct_FinalMCT_D: Clr Cl, Wb\n");
-
-
- /* ClrClToNB_D postponed until we're done executing from ROM */
- mct_ClrWbEnhWsbDis_D(pMCTstat, pDCTstat);
-}
-
-
-static void mct_InitialMCT_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat)
-{
- print_t("\tmct_InitialMCT_D: Set Cl, Wb\n");
- mct_SetClToNB_D(pMCTstat, pDCTstat);
- mct_SetWbEnhWsbDis_D(pMCTstat, pDCTstat);
-}
-
-
-static u32 mct_NodePresent_D(void)
-{
- u32 val;
- val = 0x12001022;
- return val;
-}
-
-
-static void mct_init(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 lo, hi;
- u32 addr;
-
- pDCTstat->GangedMode = 0;
- pDCTstat->DRPresent = 1;
-
- /* enable extend PCI configuration access */
- addr = NB_CFG_MSR;
- _RDMSR(addr, &lo, &hi);
- if (hi & (1 << (46-32))) {
- pDCTstat->Status |= 1 << SB_ExtConfig;
- } else {
- hi |= 1 << (46-32);
- _WRMSR(addr, lo, hi);
- }
-}
-
-
-static void clear_legacy_Mode(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 reg;
- u32 val;
- u32 dev = pDCTstat->dev_dct;
-
- /* Clear Legacy BIOS Mode bit */
- reg = 0x94;
- val = Get_NB32(dev, reg);
- val &= ~(1<<LegacyBiosMode);
- Set_NB32(dev, reg, val);
-}
-
-
-static void mct_HTMemMapExt(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u32 Drambase, Dramlimit;
- u32 val;
- u32 reg;
- u32 dev;
- u32 devx;
- u32 dword;
- struct DCTStatStruc *pDCTstat;
-
- pDCTstat = pDCTstatA + 0;
- dev = pDCTstat->dev_map;
-
- /* Copy dram map from F1x40/44,F1x48/4c,
- to F1x120/124(Node0),F1x120/124(Node1),...*/
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
- devx = pDCTstat->dev_map;
-
- /* get base/limit from Node0 */
- reg = 0x40 + (Node << 3); /* Node0/Dram Base 0 */
- val = Get_NB32(dev, reg);
- Drambase = val >> (16 + 3);
-
- reg = 0x44 + (Node << 3); /* Node0/Dram Base 0 */
- val = Get_NB32(dev, reg);
- Dramlimit = val >> (16 + 3);
-
- /* set base/limit to F1x120/124 per Node */
- if (pDCTstat->NodePresent) {
- reg = 0x120; /* F1x120,DramBase[47:27] */
- val = Get_NB32(devx, reg);
- val &= 0xFFE00000;
- val |= Drambase;
- Set_NB32(devx, reg, val);
-
- reg = 0x124;
- val = Get_NB32(devx, reg);
- val &= 0xFFE00000;
- val |= Dramlimit;
- Set_NB32(devx, reg, val);
-
- if (pMCTstat->GStatus & (1 << GSB_HWHole)) {
- reg = 0xF0;
- val = Get_NB32(devx, reg);
- val |= (1 << DramMemHoistValid);
- val &= ~(0xFF << 24);
- dword = (pMCTstat->HoleBase >> (24 - 8)) & 0xFF;
- dword <<= 24;
- val |= dword;
- Set_NB32(devx, reg, val);
- }
-
- }
- }
-}
-
-static void SetCSTriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 dev = pDCTstat->dev_dct;
- u32 index_reg = 0x98 + 0x100 * dct;
- u8 cs;
- u32 index;
- u16 word;
-
- /* Tri-state unused chipselects when motherboard
- termination is available */
-
- // FIXME: skip for Ax
-
- word = pDCTstat->CSPresent;
- if (pDCTstat->Status & (1 << SB_Registered)) {
- for (cs = 0; cs < 8; cs++) {
- if (word & (1 << cs)) {
- if (!(cs & 1))
- word |= 1 << (cs + 1);
- }
- }
- }
- word = (~word) & 0xFF;
- index = 0x0c;
- val = Get_NB32_index_wait(dev, index_reg, index);
- val |= word;
- Set_NB32_index_wait(dev, index_reg, index, val);
-}
-
-
-#ifdef UNUSED_CODE
-static void SetCKETriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 dev;
- u32 index_reg = 0x98 + 0x100 * dct;
- u8 cs;
- u32 index;
- u16 word;
-
- /* Tri-state unused CKEs when motherboard termination is available */
-
- // FIXME: skip for Ax
-
- dev = pDCTstat->dev_dct;
- word = 0x101;
- for (cs = 0; cs < 8; cs++) {
- if (pDCTstat->CSPresent & (1 << cs)) {
- if (!(cs & 1))
- word &= 0xFF00;
- else
- word &= 0x00FF;
- }
- }
-
- index = 0x0c;
- val = Get_NB32_index_wait(dev, index_reg, index);
- if ((word & 0x00FF) == 1)
- val |= 1 << 12;
- else
- val &= ~(1 << 12);
-
- if ((word >> 8) == 1)
- val |= 1 << 13;
- else
- val &= ~(1 << 13);
-
- Set_NB32_index_wait(dev, index_reg, index, val);
-}
-#endif
-
-static void SetODTTriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 dev;
- u32 index_reg = 0x98 + 0x100 * dct;
- u8 cs;
- u32 index;
- u8 odt;
- u8 max_dimms;
-
- // FIXME: skip for Ax
-
- dev = pDCTstat->dev_dct;
-
- /* Tri-state unused ODTs when motherboard termination is available */
- max_dimms = (u8) mctGet_NVbits(NV_MAX_DIMMS);
- odt = 0x0F; /* tristate all the pins then clear the used ones. */
-
- for (cs = 0; cs < 8; cs += 2) {
- if (pDCTstat->CSPresent & (1 << cs)) {
- odt &= ~(1 << (cs / 2));
-
- /* if quad-rank capable platform clear additional pins */
- if (max_dimms != MAX_CS_SUPPORTED) {
- if (pDCTstat->CSPresent & (1 << (cs + 1)))
- odt &= ~(4 << (cs / 2));
- }
- }
- }
-
- index = 0x0C;
- val = Get_NB32_index_wait(dev, index_reg, index);
- val |= (odt << 8);
- Set_NB32_index_wait(dev, index_reg, index, val);
-
-}
-
-
-static void InitPhyCompensation(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 i;
- u32 index_reg = 0x98 + 0x100 * dct;
- u32 dev = pDCTstat->dev_dct;
- u32 val;
- u32 valx = 0;
- u32 dword;
- const u8 *p;
-
- val = Get_NB32_index_wait(dev, index_reg, 0x00);
- dword = 0;
- for (i = 0; i < 6; i++) {
- switch (i) {
- case 0:
- case 4:
- p = Table_Comp_Rise_Slew_15x;
- valx = p[(val >> 16) & 3];
- break;
- case 1:
- case 5:
- p = Table_Comp_Fall_Slew_15x;
- valx = p[(val >> 16) & 3];
- break;
- case 2:
- p = Table_Comp_Rise_Slew_20x;
- valx = p[(val >> 8) & 3];
- break;
- case 3:
- p = Table_Comp_Fall_Slew_20x;
- valx = p[(val >> 8) & 3];
- break;
-
- }
- dword |= valx << (5 * i);
- }
-
- /* Override/Exception */
- if (!pDCTstat->GangedMode) {
- i = 0; /* use i for the dct setting required */
- if (pDCTstat->MAdimms[0] < 4)
- i = 1;
- if (((pDCTstat->Speed == 2) || (pDCTstat->Speed == 3)) && (pDCTstat->MAdimms[i] == 4)) {
- dword &= 0xF18FFF18;
- index_reg = 0x98; /* force dct = 0 */
- }
- }
-
- Set_NB32_index_wait(dev, index_reg, 0x0a, dword);
-}
-
-
-static void WaitRoutine_D(u32 time)
-{
- while (time) {
- _EXECFENCE;
- time--;
- }
-}
-
-
-static void mct_EarlyArbEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 reg;
- u32 val;
- u32 dev = pDCTstat->dev_dct;
-
- /* GhEnhancement #18429 modified by askar: For low NB CLK :
- * Memclk ratio, the DCT may need to arbitrate early to avoid
- * unnecessary bubbles.
- * bit 19 of F2x[1,0]78 Dram Control Register, set this bit only when
- * NB CLK : Memclk ratio is between 3:1 (inclusive) to 4:5 (inclusive)
- */
-
- reg = 0x78;
- val = Get_NB32(dev, reg);
-
- //FIXME: check for Cx
- if (CheckNBCOFEarlyArbEn(pMCTstat, pDCTstat))
- val |= (1 << EarlyArbEn);
-
- Set_NB32(dev, reg, val);
-
-}
-
-
-static u8 CheckNBCOFEarlyArbEn(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 reg;
- u32 val;
- u32 tmp;
- u32 rem;
- u32 dev = pDCTstat->dev_dct;
- u32 hi, lo;
- u8 NbDid = 0;
-
- /* Check if NB COF >= 4*Memclk, if it is not, return a fatal error
- */
-
- /* 3*(Fn2xD4[NBFid]+4)/(2^NbDid)/(3+Fn2x94[MemClkFreq]) */
- _RDMSR(MSR_COFVID_STS, &lo, &hi);
- if (lo & (1 << 22))
- NbDid |= 1;
-
-
- reg = 0x94;
- val = Get_NB32(dev, reg);
- if (!(val & (1 << MemClkFreqVal)))
- val = Get_NB32(dev, reg * 0x100); /* get the DCT1 value */
-
- val &= 0x07;
- val += 3;
- if (NbDid)
- val <<= 1;
- tmp = val;
-
- dev = pDCTstat->dev_nbmisc;
- reg = 0xD4;
- val = Get_NB32(dev, reg);
- val &= 0x1F;
- val += 3;
- val *= 3;
- val = val / tmp;
- rem = val % tmp;
- tmp >>= 1;
-
- // Yes this could be nicer but this was how the asm was....
- if (val < 3) { /* NClk:MemClk < 3:1 */
- return 0;
- } else if (val > 4) { /* NClk:MemClk >= 5:1 */
- return 0;
- } else if ((val == 4) && (rem > tmp)) { /* NClk:MemClk > 4.5:1 */
- return 0;
- } else {
- return 1; /* 3:1 <= NClk:MemClk <= 4.5:1*/
- }
-}
-
-
-static void mct_ResetDataStruct_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- struct DCTStatStruc *pDCTstat;
-
- /* Initialize Data structures by clearing all entries to 0 */
- memset(pMCTstat, 0x00, sizeof(*pMCTstat));
-
- for (Node = 0; Node < 8; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- /* Clear all entries except persistentData */
- memset(pDCTstat, 0x00, sizeof(*pDCTstat) - sizeof(pDCTstat->persistentData));
- }
-}
-
-
-static void mct_BeforeDramInit_Prod_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 i;
- u32 reg_off;
- u32 dev = pDCTstat->dev_dct;
-
- // FIXME: skip for Ax
- if ((pDCTstat->Speed == 3) || (pDCTstat->Speed == 2)) { // MemClkFreq = 667MHz or 533MHz
- for (i = 0; i < 2; i++) {
- reg_off = 0x100 * i;
- Set_NB32(dev, 0x98 + reg_off, 0x0D000030);
- Set_NB32(dev, 0x9C + reg_off, 0x00000806);
- Set_NB32(dev, 0x98 + reg_off, 0x4D040F30);
- }
- }
-}
-
-
-void mct_AdjustDelayRange_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 *dqs_pos)
-{
- // FIXME: Skip for Ax
- if ((pDCTstat->Speed == 3) || (pDCTstat->Speed == 2)) { // MemClkFreq = 667MHz or 533MHz
- *dqs_pos = 32;
- }
-}
-
-static u32 mct_DisDllShutdownSR(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 DramConfigLo, u8 dct)
-{
- u32 reg_off = 0x100 * dct;
- u32 dev = pDCTstat->dev_dct;
-
- /* Write 0000_07D0h to register F2x[1, 0]98_x4D0FE006 */
- if (pDCTstat->LogicalCPUID & (AMD_DA_C2 | AMD_RB_C3)) {
- Set_NB32(dev, 0x9C + reg_off, 0x7D0);
- Set_NB32(dev, 0x98 + reg_off, 0x4D0FE006);
- Set_NB32(dev, 0x9C + reg_off, 0x190);
- Set_NB32(dev, 0x98 + reg_off, 0x4D0FE007);
- }
-
- return DramConfigLo | /* DisDllShutdownSR */ 1 << 27;
-}
-
-static void mct_EnDllShutdownSR(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 reg_off = 0x100 * dct;
- u32 dev = pDCTstat->dev_dct, val;
-
- /* Write 0000_07D0h to register F2x[1, 0]98_x4D0FE006 */
- if (pDCTstat->LogicalCPUID & (AMD_DA_C2 | AMD_RB_C3)) {
- Set_NB32(dev, 0x9C + reg_off, 0x1C);
- Set_NB32(dev, 0x98 + reg_off, 0x4D0FE006);
- Set_NB32(dev, 0x9C + reg_off, 0x13D);
- Set_NB32(dev, 0x98 + reg_off, 0x4D0FE007);
-
- val = Get_NB32(dev, 0x90 + reg_off);
- val &= ~(1 << 27/* DisDllShutdownSR */);
- Set_NB32(dev, 0x90 + reg_off, val);
- }
-}
-
-void mct_SetClToNB_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 lo, hi;
- u32 msr;
-
- // FIXME: Maybe check the CPUID? - not for now.
- // pDCTstat->LogicalCPUID;
-
- msr = BU_CFG2_MSR;
- _RDMSR(msr, &lo, &hi);
- lo |= 1 << ClLinesToNbDis;
- _WRMSR(msr, lo, hi);
-}
-
-
-void mct_ClrClToNB_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
-
- u32 lo, hi;
- u32 msr;
-
- // FIXME: Maybe check the CPUID? - not for now.
- // pDCTstat->LogicalCPUID;
-
- msr = BU_CFG2_MSR;
- _RDMSR(msr, &lo, &hi);
- if (!pDCTstat->ClToNB_flag)
- lo &= ~(1 << ClLinesToNbDis);
- _WRMSR(msr, lo, hi);
-
-}
-
-
-void mct_SetWbEnhWsbDis_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 lo, hi;
- u32 msr;
-
- // FIXME: Maybe check the CPUID? - not for now.
- // pDCTstat->LogicalCPUID;
-
- msr = BU_CFG_MSR;
- _RDMSR(msr, &lo, &hi);
- hi |= (1 << WbEnhWsbDis_D);
- _WRMSR(msr, lo, hi);
-}
-
-
-void mct_ClrWbEnhWsbDis_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 lo, hi;
- u32 msr;
-
- // FIXME: Maybe check the CPUID? - not for now.
- // pDCTstat->LogicalCPUID;
-
- msr = BU_CFG_MSR;
- _RDMSR(msr, &lo, &hi);
- hi &= ~(1 << WbEnhWsbDis_D);
- _WRMSR(msr, lo, hi);
-}
-
-
-void mct_SetDramConfigHi_D(struct DCTStatStruc *pDCTstat, u32 dct,
- u32 DramConfigHi)
-{
- /* Bug#15114: Comp. update interrupted by Freq. change can cause
- * subsequent update to be invalid during any MemClk frequency change:
- * Solution: From the bug report:
- * 1. A software-initiated frequency change should be wrapped into the
- * following sequence :
- * a) Disable Compensation (F2[1, 0]9C_x08[30])
- * b) Reset the Begin Compensation bit (D3CMP->COMP_CONFIG[0]) in
- * all the compensation engines
- * c) Do frequency change
- * d) Enable Compensation (F2[1, 0]9C_x08[30])
- * 2. A software-initiated Disable Compensation should always be
- * followed by step b) of the above steps.
- * Silicon Status: Fixed In Rev B0
- *
- * Errata#177: DRAM Phy Automatic Compensation Updates May Be Invalid
- * Solution: BIOS should disable the phy automatic compensation prior
- * to initiating a memory clock frequency change as follows:
- * 1. Disable PhyAutoComp by writing 1'b1 to F2x[1, 0]9C_x08[30]
- * 2. Reset the Begin Compensation bits by writing 32'h0 to
- * F2x[1, 0]9C_x4D004F00
- * 3. Perform frequency change
- * 4. Enable PhyAutoComp by writing 1'b0 to F2x[1, 0]9C_08[30]
- * In addition, any time software disables the automatic phy
- * compensation it should reset the begin compensation bit per step 2.
- * Silicon Status: Fixed in DR-B0
- */
-
- u32 dev = pDCTstat->dev_dct;
- u32 index_reg = 0x98 + 0x100 * dct;
- u32 index;
-
- u32 val;
-
- index = 0x08;
- val = Get_NB32_index_wait(dev, index_reg, index);
- Set_NB32_index_wait(dev, index_reg, index, val | (1 << DisAutoComp));
-
- //FIXME: check for Bx Cx CPU
- // if Ax mct_SetDramConfigHi_Samp_D
-
- /* errata#177 */
- index = 0x4D014F00; /* F2x[1, 0]9C_x[D0FFFFF:D000000] DRAM Phy Debug Registers */
- index |= 1 << DctAccessWrite;
- val = 0;
- Set_NB32_index_wait(dev, index_reg, index, val);
-
- Set_NB32(dev, 0x94 + 0x100 * dct, DramConfigHi);
-
- index = 0x08;
- val = Get_NB32_index_wait(dev, index_reg, index);
- Set_NB32_index_wait(dev, index_reg, index, val & (~(1 << DisAutoComp)));
-}
-
-static void mct_BeforeDQSTrain_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- struct DCTStatStruc *pDCTstat;
-
- /* Errata 178
- *
- * Bug#15115: Uncertainty In The Sync Chain Leads To Setup Violations
- * In TX FIFO
- * Solution: BIOS should program DRAM Control Register[RdPtrInit] =
- * 5h, (F2x[1, 0]78[3:0] = 5h).
- * Silicon Status: Fixed In Rev B0
- *
- * Bug#15880: Determine validity of reset settings for DDR PHY timing.
- * Solution: At least, set WrDqs fine delay to be 0 for DDR2 training.
- */
-
- for (Node = 0; Node < 8; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- mct_BeforeDQSTrain_Samp_D(pMCTstat, pDCTstat);
- mct_ResetDLL_D(pMCTstat, pDCTstat, 0);
- mct_ResetDLL_D(pMCTstat, pDCTstat, 1);
- }
- }
-}
-
-static void mct_ResetDLL_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 Receiver;
- u32 dev = pDCTstat->dev_dct;
- u32 reg_off = 0x100 * dct;
- u32 addr;
- u32 lo, hi;
- u8 wrap32dis = 0;
- u8 valid = 0;
-
- /* Skip reset DLL for B3 */
- if (pDCTstat->LogicalCPUID & AMD_DR_B3) {
- return;
- }
-
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- if (lo & (1<<17)) { /* save the old value */
- wrap32dis = 1;
- }
- lo |= (1<<17); /* HWCR.wrap32dis */
- lo &= ~(1<<15); /* SSEDIS */
- /* Setting wrap32dis allows 64-bit memory references in 32bit mode */
- _WRMSR(addr, lo, hi);
-
-
- pDCTstat->Channel = dct;
- Receiver = mct_InitReceiver_D(pDCTstat, dct);
- /* there are four receiver pairs, loosely associated with chipselects.*/
- for (; Receiver < 8; Receiver += 2) {
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, Receiver)) {
- addr = mct_GetRcvrSysAddr_D(pMCTstat, pDCTstat, dct, Receiver, &valid);
- if (valid) {
- mct_Read1LTestPattern_D(pMCTstat, pDCTstat, addr); /* cache fills */
-
- /* Write 0000_8000h to register F2x[1,0]9C_xD080F0C */
- Set_NB32_index_wait(dev, 0x98 + reg_off, 0x4D080F0C, 0x00008000);
- mct_Wait(80); /* wait >= 300ns */
-
- /* Write 0000_0000h to register F2x[1,0]9C_xD080F0C */
- Set_NB32_index_wait(dev, 0x98 + reg_off, 0x4D080F0C, 0x00000000);
- mct_Wait(800); /* wait >= 2us */
- break;
- }
- }
- }
- if (!wrap32dis) {
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(addr, lo, hi);
- }
-}
-
-
-void mct_EnableDatIntlv_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 val;
-
- /* Enable F2x110[DctDatIntlv] */
- // Call back not required mctHookBeforeDatIntlv_D()
- // FIXME Skip for Ax
- if (!pDCTstat->GangedMode) {
- val = Get_NB32(dev, 0x110);
- val |= 1 << 5; // DctDatIntlv
- Set_NB32(dev, 0x110, val);
-
- // FIXME Skip for Cx
- dev = pDCTstat->dev_nbmisc;
- val = Get_NB32(dev, 0x8C); // NB Configuration Hi
- val |= 1 << (36-32); // DisDatMask
- Set_NB32(dev, 0x8C, val);
- }
-}
-
-#ifdef UNUSED_CODE
-static void mct_SetupSync_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* set F2x78[ChSetupSync] when F2x[1, 0]9C_x04[AddrCmdSetup, CsOdtSetup,
- * CkeSetup] setups for one DCT are all 0s and at least one of the setups,
- * F2x[1, 0]9C_x04[AddrCmdSetup, CsOdtSetup, CkeSetup], of the other
- * controller is 1
- */
- u32 cha, chb;
- u32 dev = pDCTstat->dev_dct;
- u32 val;
-
- cha = pDCTstat->CH_ADDR_TMG[0] & 0x0202020;
- chb = pDCTstat->CH_ADDR_TMG[1] & 0x0202020;
-
- if ((cha != chb) && ((cha == 0) || (chb == 0))) {
- val = Get_NB32(dev, 0x78);
- val |= ChSetupSync;
- Set_NB32(dev, 0x78, val);
- }
-}
-#endif
-
-static void AfterDramInit_D(struct DCTStatStruc *pDCTstat, u8 dct) {
-
- u32 val;
- u32 reg_off = 0x100 * dct;
- u32 dev = pDCTstat->dev_dct;
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_B2 | AMD_DR_B3)) {
- mct_Wait(10000); /* Wait 50 us*/
- val = Get_NB32(dev, 0x110);
- if (val & (1 << DramEnabled)) {
- /* If 50 us expires while DramEnable =0 then do the following */
- val = Get_NB32(dev, 0x90 + reg_off);
- val &= ~(1 << Width128); /* Program Width128 = 0 */
- Set_NB32(dev, 0x90 + reg_off, val);
-
- val = Get_NB32_index_wait(dev, 0x98 + reg_off, 0x05); /* Perform dummy CSR read to F2x09C_x05 */
-
- if (pDCTstat->GangedMode) {
- val = Get_NB32(dev, 0x90 + reg_off);
- val |= 1 << Width128; /* Program Width128 = 0 */
- Set_NB32(dev, 0x90 + reg_off, val);
- }
- }
- }
-}
-
-
-/* ==========================================================
- * 6-bit Bank Addressing Table
- * RR = rows-13 binary
- * B = Banks-2 binary
- * CCC = Columns-9 binary
- * ==========================================================
- * DCT CCCBRR Rows Banks Columns 64-bit CS Size
- * Encoding
- * 0000 000000 13 2 9 128MB
- * 0001 001000 13 2 10 256MB
- * 0010 001001 14 2 10 512MB
- * 0011 010000 13 2 11 512MB
- * 0100 001100 13 3 10 512MB
- * 0101 001101 14 3 10 1GB
- * 0110 010001 14 2 11 1GB
- * 0111 001110 15 3 10 2GB
- * 1000 010101 14 3 11 2GB
- * 1001 010110 15 3 11 4GB
- * 1010 001111 16 3 10 4GB
- * 1011 010111 16 3 11 8GB
- */
diff --git a/src/northbridge/amd/amdmct/mct/mct_d.h b/src/northbridge/amd/amdmct/mct/mct_d.h
deleted file mode 100644
index b985137987..0000000000
--- a/src/northbridge/amd/amdmct/mct/mct_d.h
+++ /dev/null
@@ -1,804 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015-2017 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/*
- * Description: Include file for all generic DDR 2 MCT files.
- */
-#ifndef MCT_D_H
-#define MCT_D_H
-
-#define DQS_TRAIN_DEBUG 0
-
-#include <stdint.h>
-#include <northbridge/amd/amdfam10/debug.h>
-#include <northbridge/amd/amdfam10/raminit.h>
-
-#include "mct_d_gcc.h"
-
-extern const u8 Table_DQSRcvEn_Offset[];
-extern const u32 TestPattern0_D[];
-extern const u32 TestPattern1_D[];
-extern const u32 TestPattern2_D[];
-
-/*===========================================================================
- CPU - K8/FAM10
-===========================================================================*/
-#define PT_L1 0 /* CPU Package Type */
-#define PT_M2 1
-#define PT_S1 2
-#define PT_GR 3
-
-#define J_MIN 0 /* j loop constraint. 1 = CL 2.0 T*/
-#define J_MAX 5 /* j loop constraint. 5 = CL 7.0 T*/
-#define K_MIN 1 /* k loop constraint. 1 = 200 MHz*/
-#define K_MAX 5 /* k loop constraint. 5 = 533 MHz*/
-#define CL_DEF 2 /* Default value for failsafe operation. 2 = CL 4.0 T*/
-#define T_DEF 1 /* Default value for failsafe operation. 1 = 5ns (cycle time)*/
-
-#define BSCRate 1 /* reg bit field = rate of dram scrubber for ecc*/
- /* memory initialization (ecc and check-bits).*/
- /* 1 = 40 ns/64 bytes.*/
-#define FirstPass 1 /* First pass through RcvEn training*/
-#define SecondPass 2 /* Second pass through Rcven training*/
-
-#define RCVREN_MARGIN 6 /* number of DLL taps to delay beyond first passing position*/
-#define MAXASYNCLATCTL_2 2 /* Max Async Latency Control value*/
-#define MAXASYNCLATCTL_3 3 /* Max Async Latency Control value*/
-
-#define DQS_FAIL 1
-#define DQS_PASS 0
-#define DQS_WRITEDIR 1
-#define DQS_READDIR 0
-#define MIN_DQS_WNDW 3
-#define secPassOffset 6
-#define Pass1MemClkDly 0x20 /* Add 1/2 Memlock delay */
-#define MAX_RD_LAT 0x3FF
-#define MIN_FENCE 14
-#define MAX_FENCE 20
-#define MIN_DQS_WR_FENCE 14
-#define MAX_DQS_WR_FENCE 20
-#define FenceTrnFinDlySeed 19
-#define EarlyArbEn 19
-
-#define PA_HOST(Node) ((((0x18+Node) << 3)+0) << 12) /* Node 0 Host Bus function PCI Address bits [15:0]*/
-#define PA_MAP(Node) ((((0x18+Node) << 3)+1) << 12) /* Node 0 MAP function PCI Address bits [15:0]*/
-#define PA_DCT(Node) ((((0x18+Node) << 3)+2) << 12) /* Node 0 DCT function PCI Address bits [15:0]*/
-//#define PA_EXT_DCT (((00 << 3)+4) << 8) /*Node 0 DCT extended configuration registers*/
-//#define PA_DCTADDL (((00 << 3)+2) << 8) /*Node x DCT function, Additional Registers PCI Address bits [15:0]*/
-//#define PA_EXT_DCTADDL (((00 << 3)+5) << 8) /*Node x DCT function, Additional Registers PCI Address bits [15:0]*/
-
-#define PA_NBMISC(Node) ((((0x18+Node) << 3)+3) << 12) /*Node 0 Misc PCI Address bits [15:0]*/
-//#define PA_NBDEVOP (((00 << 3)+3) << 8) /*Node 0 Misc PCI Address bits [15:0]*/
-
-#define DCC_EN 1 /* X:2:0x94[19]*/
-#define ILD_Lmt 3 /* X:2:0x94[18:16]*/
-
-#define EncodedTSPD 0x00191709 /* encodes which SPD byte to get T from*/
- /* versus CL X, CL X-.5, and CL X-1*/
-
-#define Bias_TrpT 3 /* bias to convert bus clocks to bit field value*/
-#define Bias_TrrdT 2
-#define Bias_TrcdT 3
-#define Bias_TrasT 3
-#define Bias_TrcT 11
-#define Bias_TrtpT 2
-#define Bias_TwrT 3
-#define Bias_TwtrT 0
-#define Bias_TfawT 7
-
-#define Min_TrpT 3 /* min programmable value in busclocks*/
-#define Max_TrpT 6 /* max programmable value in busclocks*/
-#define Min_TrrdT 2
-#define Max_TrrdT 5
-#define Min_TrcdT 3
-#define Max_TrcdT 6
-#define Min_TrasT 5
-#define Max_TrasT 18
-#define Min_TrcT 11
-#define Max_TrcT 26
-#define Min_TrtpT 2
-#define Max_TrtpT 3
-#define Min_TwrT 3
-#define Max_TwrT 6
-#define Min_TwtrT 1
-#define Max_TwtrT 3
-
-/*DDR2-1066 support*/
-#define Bias_TrcdT_1066 5
-#define Bias_TrasT_1066 15
-#define Bias_TrrdT_1066 4
-#define Bias_TwrT_1066 4
-#define Bias_TrpT_1066 5
-#define Bias_TwtrT_1066 4
-#define Bias_TfawT_1066 15
-
-#define Min_TrcdT_1066 5
-#define Max_TrcdT_1066 12
-#define Min_TrasT_1066 15
-#define Max_TrasT_1066 30
-#define Min_TrcT_1066 11
-#define Max_TrcT_1066 42
-#define Min_TrrdT_1066 4
-#define Max_TrrdT_1066 7
-#define Min_TwrT_1066 5
-#define Max_TwrT_1066 8
-#define Min_TrpT_1066 5
-#define Max_TrpT_1066 12
-#define Min_TwtrT_1066 4
-#define Max_TwtrT_1066 7
-
-/*common register bit names*/
-#define DramHoleValid 0 /* func 1, offset F0h, bit 0*/
-#define DramMemHoistValid 1 /* func 1, offset F0h, bit 1*/
-#define CSEnable 0 /* func 2, offset 40h-5C, bit 0*/
-#define Spare 1 /* func 2, offset 40h-5C, bit 1*/
-#define TestFail 2 /* func 2, offset 40h-5C, bit 2*/
-#define DqsRcvEnTrain 18 /* func 2, offset 78h, bit 18*/
-#define EnDramInit 31 /* func 2, offset 7Ch, bit 31*/
-#define DisAutoRefresh 18 /* func 2, offset 8Ch, bit 18*/
-#define InitDram 0 /* func 2, offset 90h, bit 0*/
-#define BurstLength32 10 /* func 2, offset 90h, bit 10*/
-#define Width128 11 /* func 2, offset 90h, bit 11*/
-#define X4Dimm 12 /* func 2, offset 90h, bit 12*/
-#define UnBuffDimm 16 /* func 2, offset 90h, bit 16*/
-#define DimmEcEn 19 /* func 2, offset 90h, bit 19*/
-#define MemClkFreqVal 3 /* func 2, offset 94h, bit 3*/
-#define RDqsEn 12 /* func 2, offset 94h, bit 12*/
-#define DisDramInterface 14 /* func 2, offset 94h, bit 14*/
-#define DctAccessWrite 30 /* func 2, offset 98h, bit 30*/
-#define DctAccessDone 31 /* func 2, offset 98h, bit 31*/
-#define MemClrStatus 0 /* func 2, offset A0h, bit 0*/
-#define PwrSavingsEn 10 /* func 2, offset A0h, bit 10*/
-#define Mod64BitMux 4 /* func 2, offset A0h, bit 4*/
-#define DisableJitter 1 /* func 2, offset A0h, bit 1*/
-#define MemClrDis 1 /* func 3, offset F8h, FNC 4, bit 1*/
-#define SyncOnUcEccEn 2 /* func 3, offset 44h, bit 2*/
-#define Dr_MemClrStatus 10 /* func 3, offset 110h, bit 10*/
-#define MemClrBusy 9 /* func 3, offset 110h, bit 9*/
-#define DctGangEn 4 /* func 3, offset 110h, bit 4*/
-#define MemClrInit 3 /* func 3, offset 110h, bit 3*/
-#define AssertCke 28 /* func 2, offset 7Ch, bit 28*/
-#define DeassertMemRstX 27 /* func 2, offset 7Ch, bit 27*/
-#define SendMrsCmd 26 /* func 2, offset 7Ch, bit 26*/
-#define SendAutoRefresh 25 /* func 2, offset 7Ch, bit 25*/
-#define SendPchgAll 24 /* func 2, offset 7Ch, bit 24*/
-#define DisDqsBar 6 /* func 2, offset 90h, bit 6*/
-#define DramEnabled 8 /* func 2, offset 110h, bit 8*/
-#define LegacyBiosMode 9 /* func 2, offset 94h, bit 9*/
-#define PrefDramTrainMode 28 /* func 2, offset 11Ch, bit 28*/
-#define FlushWr 30 /* func 2, offset 11Ch, bit 30*/
-#define DisAutoComp 30 /* func 2, offset 9Ch, Index 8, bit 30*/
-#define DqsRcvTrEn 13 /* func 2, offset 9Ch, Index 8, bit 13*/
-#define ForceAutoPchg 23 /* func 2, offset 90h, bit 23*/
-#define ClLinesToNbDis 15 /* Bu_CFG2, bit 15*/
-#define WbEnhWsbDis_D (48-32)
-#define PhyFenceTrEn 3 /* func 2, offset 9Ch, Index 8, bit 3 */
-#define ParEn 8 /* func 2, offset 90h, bit 8 */
-#define DcqArbBypassEn 19 /* func 2, offset 94h, bit 19 */
-#define ActiveCmdAtRst 1 /* func 2, offset A8H, bit 1 */
-#define FlushWrOnStpGnt 29 /* func 2, offset 11Ch, bit 29 */
-#define BankSwizzleMode 22 /* func 2, offset 94h, bit 22 */
-#define ChSetupSync 15 /* func 2, offset 78h, bit 15 */
-
-
-
-/*=============================================================================
- SW Initialization
-============================================================================*/
-#define DLL_Enable 1
-#define OCD_Default 2
-#define OCD_Exit 3
-
-
-
-/*=============================================================================
- Jedec DDR II
-=============================================================================*/
-#define SPD_TYPE 2 /*SPD byte read location*/
- #define JED_DDRSDRAM 0x07 /*Jedec defined bit field*/
- #define JED_DDR2SDRAM 0x08 /*Jedec defined bit field*/
-
-#define SPD_DIMMTYPE 20
-#define SPD_ATTRIB 21
- #define JED_DIFCKMSK 0x20 /*Differential Clock Input*/
- #define JED_REGADCMSK 0x11 /*Registered Address/Control*/
- #define JED_PROBEMSK 0x40 /*Analysis Probe installed*/
-#define SPD_DEVATTRIB 22
-#define SPD_EDCTYPE 11
- #define JED_ECC 0x02
- #define JED_ADRCPAR 0x04
-#define SPD_ROWSZ 3
-#define SPD_COLSZ 4
-#define SPD_LBANKS 17 /*number of [logical] banks on each device*/
-#define SPD_DMBANKS 5 /*number of physical banks on dimm*/
- #define SPDPLBit 4 /* Dram package bit*/
-#define SPD_BANKSZ 31 /*capacity of physical bank*/
-#define SPD_DEVWIDTH 13
-#define SPD_CASLAT 18
-#define SPD_TRP 27
-#define SPD_TRRD 28
-#define SPD_TRCD 29
-#define SPD_TRAS 30
-#define SPD_TWR 36
-#define SPD_TWTR 37
-#define SPD_TRTP 38
-#define SPD_TRCRFC 40
-#define SPD_TRC 41
-#define SPD_TRFC 42
-
-#define SPD_MANID_START 64
-#define SPD_PARTN_START 73
-#define SPD_PARTN_LENGTH 18
-#define SPD_REVNO_START 91
-
-#define SPD_MANDATEYR 93 /*Module Manufacturing Year (BCD)*/
-
-#define SPD_MANDATEWK 94 /*Module Manufacturing Week (BCD)*/
-
-#define SPD_SERIAL_START 95
-
-/*-----------------------------
- Jedec DDR II related equates
------------------------------*/
-#define MYEAR06 6 /* Manufacturing Year BCD encoding of 2006 - 06d*/
-#define MWEEK24 0x24 /* Manufacturing Week BCD encoding of June - 24d*/
-
-/*=============================================================================
- Macros
-=============================================================================*/
-
-#define _2GB_RJ8 (2<<(30-8))
-#define _4GB_RJ8 (4<<(30-8))
-#define _4GB_RJ4 (4<<(30-4))
-
-#define BigPagex8_RJ8 (1<<(17+3-8)) /*128KB * 8 >> 8 */
-
-/*=============================================================================
- Global MCT Status Structure
-=============================================================================*/
-struct MCTStatStruc {
- u32 GStatus; /* Global Status bitfield*/
- u32 HoleBase; /* If not zero, BASE[39:8] (system address)
- of sub 4GB dram hole for HW remapping.*/
- u32 Sub4GCacheTop; /* If not zero, the 32-bit top of cacheable memory.*/
- u32 SysLimit; /* LIMIT[39:8] (system address)*/
-} __packed;
-
-/*=============================================================================
- Global MCT Configuration Status Word (GStatus)
-=============================================================================*/
-/*These should begin at bit 0 of GStatus[31:0]*/
-#define GSB_MTRRshort 0 /* Ran out of MTRRs while mapping memory*/
-#define GSB_ECCDIMMs 1 /* All banks of all Nodes are ECC capable*/
-#define GSB_DramECCDis 2 /* Dram ECC requested but not enabled.*/
-#define GSB_SoftHole 3 /* A Node Base gap was created*/
-#define GSB_HWHole 4 /* A HW dram remap was created*/
-#define GSB_NodeIntlv 5 /* Node Memory interleaving was enabled*/
-#define GSB_SpIntRemapHole 16 /* Special condition for Node Interleave and HW remapping*/
-#define GSB_EnDIMMSpareNW 17 /* Indicates that DIMM Spare can be used without a warm reset */
- /* NOTE: This is a local bit used by memory code */
-
-
-/*===============================================================================
- Local DCT Status structure (a structure for each DCT)
-===============================================================================*/
-
-struct DCTPersistentStatStruc {
- u8 CH_D_DIR_B_DQS[2][4][2][9]; /* [A/B] [DIMM1-4] [R/W] [DQS] */
- /* CHA DIMM0 Byte 0 - 7 and Check Write DQS Delay*/
- /* CHA DIMM0 Byte 0 - 7 and Check Read DQS Delay*/
- /* CHA DIMM1 Byte 0 - 7 and Check Write DQS Delay*/
- /* CHA DIMM1 Byte 0 - 7 and Check Read DQS Delay*/
- /* CHB DIMM0 Byte 0 - 7 and Check Write DQS Delay*/
- /* CHB DIMM0 Byte 0 - 7 and Check Read DQS Delay*/
- /* CHB DIMM1 Byte 0 - 7 and Check Write DQS Delay*/
- /* CHB DIMM1 Byte 0 - 7 and Check Read DQS Delay*/
- u8 CH_D_B_RCVRDLY[2][4][8]; /* [A/B] [DIMM0-3] [DQS] */
- /* CHA DIMM 0 Receiver Enable Delay*/
- /* CHA DIMM 1 Receiver Enable Delay*/
- /* CHA DIMM 2 Receiver Enable Delay*/
- /* CHA DIMM 3 Receiver Enable Delay*/
-
- /* CHB DIMM 0 Receiver Enable Delay*/
- /* CHB DIMM 1 Receiver Enable Delay*/
- /* CHB DIMM 2 Receiver Enable Delay*/
- /* CHB DIMM 3 Receiver Enable Delay*/
- u8 CH_D_BC_RCVRDLY[2][4];
- /* CHA DIMM 0 - 4 Check Byte Receiver Enable Delay*/
- /* CHB DIMM 0 - 4 Check Byte Receiver Enable Delay*/
- u16 HostBiosSrvc1; /* Word sized general purpose field for use by host BIOS. Scratch space.*/
- u32 HostBiosSrvc2; /* Dword sized general purpose field for use by host BIOS. Scratch space.*/
-} __packed;
-
-
-struct DCTStatStruc { /* A per Node structure*/
-/* DCTStatStruct_F - start */
- u8 Node_ID; /* Node ID of current controller*/
- uint8_t Internal_Node_ID; /* Internal Node ID of the current controller */
- uint8_t Dual_Node_Package; /* 1 = Dual node package (G34) */
- uint8_t stopDCT; /* Set if the DCT will be stopped */
- u8 ErrCode; /* Current error condition of Node
- 0= no error
- 1= Variance Error, DCT is running but not in an optimal configuration.
- 2= Stop Error, DCT is NOT running
- 3= Fatal Error, DCT/MCT initialization has been halted.*/
- u32 ErrStatus; /* Error Status bit Field */
- u32 Status; /* Status bit Field*/
- u8 DIMMAddr[8]; /* SPD address of DIMM controlled by MA0_CS_L[0,1]*/
- /* SPD address of..MB0_CS_L[0,1]*/
- /* SPD address of..MA1_CS_L[0,1]*/
- /* SPD address of..MB1_CS_L[0,1]*/
- /* SPD address of..MA2_CS_L[0,1]*/
- /* SPD address of..MB2_CS_L[0,1]*/
- /* SPD address of..MA3_CS_L[0,1]*/
- /* SPD address of..MB3_CS_L[0,1]*/
- u16 DIMMPresent; /*For each bit n 0..7, 1 = DIMM n is present.
- DIMM# Select Signal
- 0 MA0_CS_L[0,1]
- 1 MB0_CS_L[0,1]
- 2 MA1_CS_L[0,1]
- 3 MB1_CS_L[0,1]
- 4 MA2_CS_L[0,1]
- 5 MB2_CS_L[0,1]
- 6 MA3_CS_L[0,1]
- 7 MB3_CS_L[0,1]*/
- u16 DIMMValid; /* For each bit n 0..7, 1 = DIMM n is valid and is/will be configured*/
- u16 DIMMMismatch; /* For each bit n 0..7, 1 = DIMM n is mismatched, channel B is always considered the mismatch */
- u16 DIMMSPDCSE; /* For each bit n 0..7, 1 = DIMM n SPD checksum error*/
- u16 DimmECCPresent; /* For each bit n 0..7, 1 = DIMM n is ECC capable.*/
- u16 DimmPARPresent; /* For each bit n 0..7, 1 = DIMM n is ADR/CMD Parity capable.*/
- u16 Dimmx4Present; /* For each bit n 0..7, 1 = DIMM n contains x4 data devices.*/
- u16 Dimmx8Present; /* For each bit n 0..7, 1 = DIMM n contains x8 data devices.*/
- u16 Dimmx16Present; /* For each bit n 0..7, 1 = DIMM n contains x16 data devices.*/
- u16 DIMM2Kpage; /* For each bit n 0..7, 1 = DIMM n contains 1K page devices.*/
- u8 MAload[2]; /* Number of devices loading MAA bus*/
- /* Number of devices loading MAB bus*/
- u8 MAdimms[2]; /*Number of DIMMs loading CH A*/
- /* Number of DIMMs loading CH B*/
- u8 DATAload[2]; /*Number of ranks loading CH A DATA*/
- /* Number of ranks loading CH B DATA*/
- u8 DIMMAutoSpeed; /*Max valid Mfg. Speed of DIMMs
- 1 = 200MHz
- 2 = 266MHz
- 3 = 333MHz
- 4 = 400MHz
- 5 = 533MHz*/
- u8 DIMMCASL; /* Min valid Mfg. CL bitfield
- 0 = 2.0
- 1 = 3.0
- 2 = 4.0
- 3 = 5.0
- 4 = 6.0 */
- u16 DIMMTrcd; /* Minimax Trcd*40 (ns) of DIMMs*/
- u16 DIMMTrp; /* Minimax Trp*40 (ns) of DIMMs*/
- u16 DIMMTrtp; /* Minimax Trtp*40 (ns) of DIMMs*/
- u16 DIMMTras; /* Minimax Tras*40 (ns) of DIMMs*/
- u16 DIMMTrc; /* Minimax Trc*40 (ns) of DIMMs*/
- u16 DIMMTwr; /* Minimax Twr*40 (ns) of DIMMs*/
- u16 DIMMTrrd; /* Minimax Trrd*40 (ns) of DIMMs*/
- u16 DIMMTwtr; /* Minimax Twtr*40 (ns) of DIMMs*/
- u8 Speed; /* Bus Speed (to set Controller)
- 1 = 200MHz
- 2 = 266MHz
- 3 = 333MHz
- 4 = 400MHz */
- u8 CASL; /* CAS latency DCT setting
- 0 = 2.0
- 1 = 3.0
- 2 = 4.0
- 3 = 5.0
- 4 = 6.0 */
- u8 Trcd; /* DCT Trcd (busclocks) */
- u8 Trp; /* DCT Trp (busclocks) */
- u8 Trtp; /* DCT Trtp (busclocks) */
- u8 Tras; /* DCT Tras (busclocks) */
- u8 Trc; /* DCT Trc (busclocks) */
- u8 Twr; /* DCT Twr (busclocks) */
- u8 Trrd; /* DCT Trrd (busclocks) */
- u8 Twtr; /* DCT Twtr (busclocks) */
- u8 Trfc[4]; /* DCT Logical DIMM0 Trfc
- 0 = 75ns (for 256Mb devs)
- 1 = 105ns (for 512Mb devs)
- 2 = 127.5ns (for 1Gb devs)
- 3 = 195ns (for 2Gb devs)
- 4 = 327.5ns (for 4Gb devs) */
- /* DCT Logical DIMM1 Trfc (see Trfc0 for format) */
- /* DCT Logical DIMM2 Trfc (see Trfc0 for format) */
- /* DCT Logical DIMM3 Trfc (see Trfc0 for format) */
- u16 CSPresent; /* For each bit n 0..7, 1 = Chip-select n is present */
- u16 CSTestFail; /* For each bit n 0..7, 1 = Chip-select n is present but disabled */
- u32 DCTSysBase; /* BASE[39:8] (system address) of this Node's DCTs. */
- u32 DCTHoleBase; /* If not zero, BASE[39:8] (system address) of dram hole for HW remapping. Dram hole exists on this Node's DCTs. */
- u32 DCTSysLimit; /* LIMIT[39:8] (system address) of this Node's DCTs */
- u16 PresetmaxFreq; /* Maximum OEM defined DDR frequency
- 200 = 200MHz (DDR400)
- 266 = 266MHz (DDR533)
- 333 = 333MHz (DDR667)
- 400 = 400MHz (DDR800) */
- u8 _2Tmode; /* 1T or 2T CMD mode (slow access mode)
- 1 = 1T
- 2 = 2T */
- u8 TrwtTO; /* DCT TrwtTO (busclocks)*/
- u8 Twrrd; /* DCT Twrrd (busclocks)*/
- u8 Twrwr; /* DCT Twrwr (busclocks)*/
- u8 Trdrd; /* DCT Trdrd (busclocks)*/
- u32 CH_ODC_CTL[2]; /* Output Driver Strength (see BKDG FN2:Offset 9Ch, index 00h*/
- u32 CH_ADDR_TMG[2]; /* Address Bus Timing (see BKDG FN2:Offset 9Ch, index 04h*/
- /* Output Driver Strength (see BKDG FN2:Offset 9Ch, index 20h*/
- /* Address Bus Timing (see BKDG FN2:Offset 9Ch, index 24h*/
- u16 CH_EccDQSLike[2]; /* CHA DQS ECC byte like...*/
- u8 CH_EccDQSScale[2]; /* CHA DQS ECC byte scale*/
- /* CHA DQS ECC byte like...*/
- /* CHA DQS ECC byte scale*/
- u8 MaxAsyncLat; /* Max Asynchronous Latency (ns)*/
- // NOTE: Not used in Barcelona - u8 CH_D_RCVRDLY[2][4];
- /* CHA DIMM 0 - 4 Receiver Enable Delay*/
- /* CHB DIMM 0 - 4 Receiver Enable Delay */
- // NOTE: Not used in Barcelona - u8 CH_D_B_DQS[2][2][8];
- /* CHA Byte 0-7 Write DQS Delay */
- /* CHA Byte 0-7 Read DQS Delay */
- /* CHB Byte 0-7 Write DQS Delay */
- /* CHB Byte 0-7 Read DQS Delay */
- u32 PtrPatternBufA; /* Ptr on stack to aligned DQS testing pattern*/
- u32 PtrPatternBufB; /* Ptr on stack to aligned DQS testing pattern*/
- u8 Channel; /* Current Channel (0= CH A, 1 = CH B)*/
- u8 ByteLane; /* Current Byte Lane (0..7)*/
- u8 Direction; /* Current DQS-DQ training write direction (0 = read, 1 = write)*/
- u8 Pattern; /* Current pattern*/
- u8 DQSDelay; /* Current DQS delay value*/
- u32 TrainErrors; /* Current Training Errors*/
-
- u32 AMC_TSC_DeltaLo; /* Time Stamp Counter measurement of AMC, Low dword*/
- u32 AMC_TSC_DeltaHi; /* Time Stamp Counter measurement of AMC, High dword*/
- // NOTE: Not used in Barcelona - u8 CH_D_DIR_MaxMin_B_Dly[2][4][2][2][8];
- /* CH A byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH A byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- /* CH A byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH A byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- uint64_t LogicalCPUID; /* The logical CPUID of the node*/
- u16 DimmQRPresent; /* QuadRank DIMM present?*/
- u16 DimmTrainFail; /* Bitmap showing which dimms failed training*/
- u16 CSTrainFail; /* Bitmap showing which chipselects failed training*/
- u16 DimmYr06; /* Bitmap indicating which Dimms have a manufactur's year code <= 2006*/
- u16 DimmWk2406; /* Bitmap indicating which Dimms have a manufactur's week code <= 24 of 2006 (June)*/
- u16 DimmDRPresent; /* Bitmap indicating that Dual Rank Dimms are present*/
- u16 DimmPlPresent; /* Bitmap indicating that Planar (1) or Stacked (0) Dimms are present.*/
- u16 ChannelTrainFai; /* Bitmap showing the channel information about failed Chip Selects
- 0 in any bit field indicates Channel 0
- 1 in any bit field indicates Channel 1 */
- u16 CSUsrTestFail; /* Chip selects excluded by user */
-/* DCTStatStruct_F - end */
-
- u16 CH_MaxRdLat[2]; /* Max Read Latency (ns) for DCT 0*/
- /* Max Read Latency (ns) for DCT 1*/
- u8 DIMMValidDCT[2]; /* DIMM# in DCT0*/
- /* DIMM# in DCT1*/
- u8 MaxDCTs; /* Max number of DCTs in system*/
- // NOTE: removed u8 DCT. Use ->dev_ for pci R/W; /*DCT pointer*/
- u8 GangedMode; /* Ganged mode enabled, 0 = disabled, 1 = enabled*/
- u8 DRPresent; /* Family 10 present flag, 0 = not Fam10, 1 = Fam10*/
- u32 NodeSysLimit; /* BASE[39:8],for DCT0+DCT1 system address*/
- u8 WrDatGrossH;
- u8 DqsRcvEnGrossL;
- // NOTE: Not used - u8 NodeSpeed /* Bus Speed (to set Controller)
- /* 1 = 200MHz */
- /* 2 = 266MHz */
- /* 3 = 333MHz */
- // NOTE: Not used - u8 NodeCASL /* CAS latency DCT setting
- /* 0 = 2.0 */
- /* 1 = 3.0 */
- /* 2 = 4.0 */
- /* 3 = 5.0 */
- /* 4 = 6.0 */
- u8 TrwtWB;
- u8 CurrRcvrCHADelay; /* for keep current RcvrEnDly of chA*/
- u16 T1000; /* get the T1000 figure (cycle time (ns)*1K)*/
- u8 DqsRcvEn_Pass; /* for TrainRcvrEn byte lane pass flag*/
- u8 DqsRcvEn_Saved; /* for TrainRcvrEn byte lane saved flag*/
- u8 SeedPass1Remainder; /* for Phy assisted DQS receiver enable training*/
-
- /* for second pass - Second pass should never run for Fam10*/
- // NOTE: Not used for Barcelona - u8 CH_D_B_RCVRDLY_1[2][4][8]; /* CHA DIMM 0 Receiver Enable Delay*/
- /* CHA DIMM 1 Receiver Enable Delay*/
- /* CHA DIMM 2 Receiver Enable Delay*/
- /* CHA DIMM 3 Receiver Enable Delay*/
-
- /* CHB DIMM 0 Receiver Enable Delay*/
- /* CHB DIMM 1 Receiver Enable Delay*/
- /* CHB DIMM 2 Receiver Enable Delay*/
- /* CHB DIMM 3 Receiver Enable Delay*/
-
- u8 ClToNB_flag; /* is used to restore ClLinesToNbDis bit after memory */
- u32 NodeSysBase; /* for channel interleave usage */
-
-/* New for LB Support */
- u8 NodePresent;
- u32 dev_host;
- u32 dev_map;
- u32 dev_dct;
- u32 dev_nbmisc;
-
- uint8_t DimmRows[MAX_DIMMS_SUPPORTED];
- uint8_t DimmCols[MAX_DIMMS_SUPPORTED];
- uint8_t DimmRanks[MAX_DIMMS_SUPPORTED];
- uint8_t DimmBanks[MAX_DIMMS_SUPPORTED];
- uint8_t DimmWidth[MAX_DIMMS_SUPPORTED];
- uint8_t DimmRegistered[MAX_DIMMS_SUPPORTED];
-
- uint64_t DimmManufacturerID[MAX_DIMMS_SUPPORTED];
- char DimmPartNumber[MAX_DIMMS_SUPPORTED][SPD_PARTN_LENGTH+1];
- uint16_t DimmRevisionNumber[MAX_DIMMS_SUPPORTED];
- uint32_t DimmSerialNumber[MAX_DIMMS_SUPPORTED];
-
- /* NOTE: This must remain the last entry in this structure */
- struct DCTPersistentStatStruc persistentData;
-} __packed;
-
-/*===============================================================================
- Local Error Status Codes (DCTStatStruc.ErrCode)
-===============================================================================*/
-#define SC_RunningOK 0
-#define SC_VarianceErr 1 /* Running non-optimally*/
-#define SC_StopError 2 /* Not Running*/
-#define SC_FatalErr 3 /* Fatal Error, MCTB has exited immediately*/
-
-/*===============================================================================
- Local Error Status (DCTStatStruc.ErrStatus[31:0])
-===============================================================================*/
-#define SB_NoDimms 0
-#define SB_DIMMChkSum 1
-#define SB_DimmMismatchM 2 /* dimm module type(buffer) mismatch*/
-#define SB_DimmMismatchT 3 /* dimm CL/T mismatch*/
-#define SB_DimmMismatchO 4 /* dimm organization mismatch (128-bit)*/
-#define SB_NoTrcTrfc 5 /* SPD missing Trc or Trfc info*/
-#define SB_NoCycTime 6 /* SPD missing byte 23 or 25*/
-#define SB_BkIntDis 7 /* Bank interleave requested but not enabled*/
-#define SB_DramECCDis 8 /* Dram ECC requested but not enabled*/
-#define SB_SpareDis 9 /* Online spare requested but not enabled*/
-#define SB_MinimumMode 10 /* Running in Minimum Mode*/
-#define SB_NORCVREN 11 /* No DQS Receiver Enable pass window found*/
-#define SB_CHA2BRCVREN 12 /* DQS Rcvr En pass window CHA to CH B too large*/
-#define SB_SmallRCVR 13 /* DQS Rcvr En pass window too small (far right of dynamic range)*/
-#define SB_NODQSPOS 14 /* No DQS-DQ passing positions*/
-#define SB_SMALLDQS 15 /* DQS-DQ passing window too small*/
-#define SB_DCBKScrubDis 16 /* DCache scrub requested but not enabled */
-
-/*===============================================================================
- Local Configuration Status (DCTStatStruc.Status[31:0])
-===============================================================================*/
-#define SB_Registered 0 /* All DIMMs are Registered*/
-#define SB_ECCDIMMs 1 /* All banks ECC capable*/
-#define SB_PARDIMMs 2 /* All banks Addr/CMD Parity capable*/
-#define SB_DiagClks 3 /* Jedec ALL slots clock enable diag mode*/
-#define SB_128bitmode 4 /* DCT in 128-bit mode operation*/
-#define SB_64MuxedMode 5 /* DCT in 64-bit mux'ed mode.*/
-#define SB_2TMode 6 /* 2T CMD timing mode is enabled.*/
-#define SB_SWNodeHole 7 /* Remapping of Node Base on this Node to create a gap.*/
-#define SB_HWHole 8 /* Memory Hole created on this Node using HW remapping.*/
-#define SB_Over400MHz 9 /* DCT freq >= 400MHz flag*/
-#define SB_DQSPos_Pass2 10 /* Using for TrainDQSPos DIMM0/1, when freq >= 400MHz*/
-#define SB_DQSRcvLimit 11 /* Using for DQSRcvEnTrain to know we have reached to upper bound.*/
-#define SB_ExtConfig 12 /* Indicator the default setting for extend PCI configuration support*/
-
-
-
-
-/*===============================================================================
- NVRAM/run-time-configurable Items
-===============================================================================*/
-/*Platform Configuration*/
-#define NV_PACK_TYPE 0 /* CPU Package Type (2-bits)
- 0 = NPT L1
- 1 = NPT M2
- 2 = NPT S1*/
-#define NV_MAX_NODES 1 /* Number of Nodes/Sockets (4-bits)*/
-#define NV_MAX_DIMMS 2 /* Number of DIMM slots for the specified Node ID (4-bits)*/
-#define NV_MAX_MEMCLK 3 /* Maximum platform demonstrated Memclock (10-bits)
- 200 = 200MHz (DDR400)
- 266 = 266MHz (DDR533)
- 333 = 333MHz (DDR667)
- 400 = 400MHz (DDR800)*/
-#define NV_MIN_MEMCLK 4 /* Minimum platform demonstrated Memclock (10-bits) */
-#define NV_ECC_CAP 5 /* Bus ECC capable (1-bits)
- 0 = Platform not capable
- 1 = Platform is capable*/
-#define NV_4RANKType 6 /* Quad Rank DIMM slot type (2-bits)
- 0 = Normal
- 1 = R4 (4-Rank Registered DIMMs in AMD server configuration)
- 2 = S4 (Unbuffered SO-DIMMs)*/
-#define NV_BYPMAX 7 /* Value to set DcqBypassMax field (See Function 2, Offset 94h, [27:24] of BKDG for field definition).
- 4 = 4 times bypass (normal for non-UMA systems)
- 7 = 7 times bypass (normal for UMA systems)*/
-#define NV_RDWRQBYP 8 /* Value to set RdWrQByp field (See Function 2, Offset A0h, [3:2] of BKDG for field definition).
- 2 = 8 times (normal for non-UMA systems)
- 3 = 16 times (normal for UMA systems)*/
-
-
-/*Dram Timing*/
-#define NV_MCTUSRTMGMODE 10 /* User Memclock Mode (2-bits)
- 0 = Auto, no user limit
- 1 = Auto, user limit provided in NV_MemCkVal
- 2 = Manual, user value provided in NV_MemCkVal*/
-#define NV_MemCkVal 11 /* Memory Clock Value (2-bits)
- 0 = 200MHz
- 1 = 266MHz
- 2 = 333MHz
- 3 = 400MHz*/
-
-/*Dram Configuration*/
-#define NV_BankIntlv 20 /* Dram Bank (chip-select) Interleaving (1-bits)
- 0 = disable
- 1 = enable*/
-#define NV_AllMemClks 21 /* Turn on All DIMM clocks (1-bits)
- 0 = normal
- 1 = enable all memclocks*/
-#define NV_SPDCHK_RESTRT 22 /* SPD Check control bitmap (1-bits)
- 0 = Exit current node init if any DIMM has SPD checksum error
- 1 = Ignore faulty SPD checksums (Note: DIMM cannot be enabled)*/
-#define NV_DQSTrainCTL 23 /* DQS Signal Timing Training Control
- 0 = skip DQS training
- 1 = perform DQS training*/
-#define NV_NodeIntlv 24 /* Node Memory Interleaving (1-bits)
- 0 = disable
- 1 = enable*/
-#define NV_BurstLen32 25 /* BurstLength32 for 64-bit mode (1-bits)
- 0 = disable (normal)
- 1 = enable (4 beat burst when width is 64-bits)*/
-
-/*Dram Power*/
-#define NV_CKE_PDEN 30 /* CKE based power down mode (1-bits)
- 0 = disable
- 1 = enable*/
-#define NV_CKE_CTL 31 /* CKE based power down control (1-bits)
- 0 = per Channel control
- 1 = per Chip select control*/
-#define NV_CLKHZAltVidC3 32 /* Memclock tri-stating during C3 and Alt VID (1-bits)
- 0 = disable
- 1 = enable*/
-
-/*Memory Map/Mgt.*/
-#define NV_BottomIO 40 /* Bottom of 32-bit IO space (8-bits)
- NV_BottomIO[7:0]=Addr[31:24]*/
-#define NV_BottomUMA 41 /* Bottom of shared graphics dram (8-bits)
- NV_BottomUMA[7:0]=Addr[31:24]*/
-#define NV_MemHole 42 /* Memory Hole Remapping (1-bits)
- 0 = disable
- 1 = enable */
-
-/*ECC*/
-#define NV_ECC 50 /* Dram ECC enable*/
-#define NV_NBECC 52 /* ECC MCE enable*/
-#define NV_ChipKill 53 /* Chip-Kill ECC Mode enable*/
-#define NV_ECCRedir 54 /* Dram ECC Redirection enable*/
-#define NV_DramBKScrub 55 /* Dram ECC Background Scrubber CTL*/
-#define NV_L2BKScrub 56 /* L2 ECC Background Scrubber CTL*/
-#define NV_L3BKScrub 57 /* L3 ECC Background Scrubber CTL*/
-#define NV_DCBKScrub 58 /* DCache ECC Background Scrubber CTL*/
-#define NV_CS_SpareCTL 59 /* Chip Select Spare Control bit 0:
- 0 = disable Spare
- 1 = enable Spare */
- /* Chip Select Spare Control bit 1-4:
- Reserved, must be zero*/
-#define NV_SyncOnUnEccEn 61 /* SyncOnUnEccEn control
- 0 = disable
- 1 = enable*/
-#define NV_Unganged 62
-
-#define NV_ChannelIntlv 63 /* Channel Interleaving (3-bits)
- xx0b = disable
- yy1b = enable with DctSelIntLvAddr set to yyb */
-
-#define NV_MAX_DIMMS_PER_CH 64 /* Maximum number of DIMMs per channel */
-
-#include <northbridge/amd/amdfam10/amdfam10.h>
-
-/*===============================================================================
- CBMEM storage
-===============================================================================*/
-struct amdmct_memory_info {
- struct MCTStatStruc mct_stat;
- struct DCTStatStruc dct_stat[MAX_NODES_SUPPORTED];
- uint16_t ecc_enabled;
- uint16_t ecc_scrub_rate;
-} __packed;
-
-u32 Get_NB32(u32 dev, u32 reg);
-void Set_NB32(u32 dev, u32 reg, u32 val);
-u32 Get_NB32_index(u32 dev, u32 index_reg, u32 index);
-void Set_NB32_index(u32 dev, u32 index_reg, u32 index, u32 data);
-u32 Get_NB32_index_wait(u32 dev, u32 index_reg, u32 index);
-void Set_NB32_index_wait(u32 dev, u32 index_reg, u32 index, u32 data);
-u32 OtherTiming_A_D(struct DCTStatStruc *pDCTstat, u32 val);
-void mct_ForceAutoPrecharge_D(struct DCTStatStruc *pDCTstat, u32 dct);
-u32 Modify_D3CMP(struct DCTStatStruc *pDCTstat, u32 dct, u32 value);
-u8 mct_checkNumberOfDqsRcvEn_1Pass(u8 pass);
-u32 SetupDqsPattern_1PassA(u8 Pass);
-u32 SetupDqsPattern_1PassB(u8 Pass);
-u8 mct_Get_Start_RcvrEnDly_1Pass(u8 Pass);
-u8 mct_Average_RcvrEnDly_Pass(struct DCTStatStruc *pDCTstat, u8 RcvrEnDly, u8 RcvrEnDlyLimit, u8 Channel, u8 Receiver, u8 Pass);
-void CPUMemTyping_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void UMAMemTyping_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-uint64_t mctGetLogicalCPUID(u32 Node);
-u8 ECCInit_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void TrainReceiverEn_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA, u8 Pass);
-void mct_TrainDQSPos_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mctSetEccDQSRcvrEn_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void TrainMaxReadLatency_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mct_EndDQSTraining_D(struct MCTStatStruc *pMCTstat,struct DCTStatStruc *pDCTstatA);
-void mct_SetRcvrEnDly_D(struct DCTStatStruc *pDCTstat, u8 RcvrEnDly, u8 FinalValue, u8 Channel, u8 Receiver, u32 dev, u32 index_reg, u8 Addl_Index, u8 Pass);
-void SetEccDQSRcvrEn_D(struct DCTStatStruc *pDCTstat, u8 Channel);
-void mctGet_PS_Cfg_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u32 dct);
-void InterleaveBanks_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 dct);
-void mct_SetDramConfigHi_D(struct DCTStatStruc *pDCTstat, u32 dct, u32 DramConfigHi);
-void mct_DramInit_Hw_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 dct);
-void SyncSetting(struct DCTStatStruc *pDCTstat);
-void mct_SetClToNB_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void mct_SetWbEnhWsbDis_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void mct_TrainRcvrEn_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 Pass);
-void mct_EnableDimmEccEn_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 _DisableDramECC);
-u32 procOdtWorkaround(struct DCTStatStruc *pDCTstat, u32 dct, u32 val);
-void mct_BeforeDramInit_D(struct DCTStatStruc *pDCTstat, u32 dct);
-void InterleaveNodes_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void InterleaveChannels_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mct_BeforeDQSTrain_Samp_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void StoreDQSDatStrucVal_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 ChipSel);
-void phyAssistedMemFnceTraining(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-u8 mct_SaveRcvEnDly_D_1Pass(struct DCTStatStruc *pDCTstat, u8 pass);
-u32 CheckNBCOFAutoPrechg(struct DCTStatStruc *pDCTstat, u32 dct);
-u8 mct_AdjustDQSPosDelay_D(struct DCTStatStruc *pDCTstat, u8 dly);
-void mct_AdjustScrub_D(struct DCTStatStruc *pDCTstat, u16 *scrub_request);
-u8 mct_InitReceiver_D(struct DCTStatStruc *pDCTstat, u8 dct);
-void mct_Wait(u32 cycles);
-u8 mct_RcvrRankEnabled_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 Channel, u8 ChipSel);
-u32 mct_GetRcvrSysAddr_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 channel, u8 receiver, u8 *valid);
-void mct_Read1LTestPattern_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u32 addr);
-void EarlySampleSupport_D(void);
-
-void mctAutoInitMCT_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mct_AdjustDelayRange_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 *dqs_pos);
-void mct_EnableDatIntlv_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void MCTMemClrSync_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-void beforeInterleaveChannels_D(struct DCTStatStruc *pDCTstatA, u8 *enabled);
-u8 mct_checkFenceHoleAdjust_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 DQSDelay,
- u8 ChipSel, u8 *result);
-void proc_IOCLFLUSH_D(u32 addr_hi);
-void mct_Write1LTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr, u8 pattern);
-u8 NodePresent_D(u8 Node);
-void DCTMemClr_Init_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void MCTMemClr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-void print_debug_dqs(const char *str, u32 val, u8 level);
-void print_debug_dqs_pair(const char *str, u32 val, const char *str2, u32 val2, u8 level);
-u8 mct_DisableDimmEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void ResetDCTWrPtr_D(u32 dev, u32 index_reg, u32 index);
-void SetTargetWTIO_D(u32 TestAddr);
-void ResetTargetWTIO_D(void);
-u32 mct_GetMCTSysAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel,
- u8 receiver, u8 *valid);
-#endif
diff --git a/src/northbridge/amd/amdmct/mct/mct_d_gcc.c b/src/northbridge/amd/amdmct/mct/mct_d_gcc.c
deleted file mode 100644
index d826fed96d..0000000000
--- a/src/northbridge/amd/amdmct/mct/mct_d_gcc.c
+++ /dev/null
@@ -1,351 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "mct_d_gcc.h"
-
-inline void _WRMSR(u32 addr, u32 lo, u32 hi)
-{
- __asm__ volatile (
- "wrmsr"
- :
- :"c"(addr),"a"(lo), "d" (hi)
- );
-}
-
-
-inline void _RDMSR(u32 addr, u32 *lo, u32 *hi)
-{
- __asm__ volatile (
- "rdmsr"
- :"=a"(*lo), "=d" (*hi)
- :"c"(addr)
- );
-}
-
-
-inline void _RDTSC(u32 *lo, u32 *hi)
-{
- __asm__ volatile (
- "rdtsc"
- : "=a" (*lo), "=d"(*hi)
- );
-}
-
-
-inline void _cpu_id(u32 addr, u32 *val)
-{
- __asm__ volatile(
- "cpuid"
- : "=a" (val[0]),
- "=b" (val[1]),
- "=c" (val[2]),
- "=d" (val[3])
- : "0" (addr));
-
-}
-
-
-u32 bsr(u32 x)
-{
- u8 i;
- u32 ret = 0;
-
- for (i = 31; i > 0; i--) {
- if (x & (1<<i)) {
- ret = i;
- break;
- }
- }
-
- return ret;
-
-}
-
-
-u32 bsf(u32 x)
-{
- u8 i;
- u32 ret = 32;
-
- for (i = 0; i < 32; i++) {
- if (x & (1<<i)) {
- ret = i;
- break;
- }
- }
-
- return ret;
-}
-
-#define _MFENCE asm volatile ("mfence")
-
-#define _SFENCE asm volatile ("sfence")
-
-/* prevent speculative execution of following instructions */
-#define _EXECFENCE asm volatile ("outb %al, $0xed")
-
-#include <cpu/x86/cr.h>
-
-void proc_CLFLUSH(u32 addr_hi)
-{
- SetUpperFSbase(addr_hi);
-
- __asm__ volatile (
- /* clflush fs:[eax] */
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "clflush %%fs:(%0)\n\t"
- "mfence\n\t"
- ::"a" (addr_hi<<8)
- );
-}
-
-
-void WriteLNTestPattern(u32 addr_lo, u8 *buf_a, u32 line_num)
-{
- __asm__ volatile (
- /*prevent speculative execution of following instructions*/
- /* FIXME: needed ? */
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "1:\n\t"
- "movdqa (%3), %%xmm0\n\t"
- "movntdq %%xmm0, %%fs:(%0)\n\t" /* xmm0 is 128 bit */
- "addl %1, %0\n\t"
- "addl %1, %3\n\t"
- "loop 1b\n\t"
- "mfence\n\t"
-
- :: "a" (addr_lo), "d" (16), "c" (line_num * 4), "b"(buf_a)
- );
-
-}
-
-
-u32 read32_fs(u32 addr_lo)
-{
- u32 value;
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "movl %%fs:(%1), %0\n\t"
- :"=b"(value): "a" (addr_lo)
- );
- return value;
-}
-
-#ifdef UNUSED_CODE
-static u8 read8_fs(u32 addr_lo)
-{
- u8 byte;
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "movb %%fs:(%1), %b0\n\t"
- "mfence\n\t"
- :"=b"(byte): "a" (addr_lo)
- );
- return byte;
-}
-#endif
-
-void FlushDQSTestPattern_L9(u32 addr_lo)
-{
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "clflush %%fs:-128(%%ecx)\n\t"
- "clflush %%fs:-64(%%ecx)\n\t"
- "clflush %%fs:(%%ecx)\n\t"
- "clflush %%fs:64(%%ecx)\n\t"
-
- "clflush %%fs:-128(%%eax)\n\t"
- "clflush %%fs:-64(%%eax)\n\t"
- "clflush %%fs:(%%eax)\n\t"
- "clflush %%fs:64(%%eax)\n\t"
-
- "clflush %%fs:-128(%%ebx)\n\t"
-
- :: "b" (addr_lo+128+8*64), "c"(addr_lo+128),
- "a"(addr_lo+128+4*64)
- );
-
-}
-
-
-__attribute__((noinline)) void FlushDQSTestPattern_L18(u32 addr_lo)
-{
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "clflush %%fs:-128(%%eax)\n\t"
- "clflush %%fs:-64(%%eax)\n\t"
- "clflush %%fs:(%%eax)\n\t"
- "clflush %%fs:64(%%eax)\n\t"
-
- "clflush %%fs:-128(%%edi)\n\t"
- "clflush %%fs:-64(%%edi)\n\t"
- "clflush %%fs:(%%edi)\n\t"
- "clflush %%fs:64(%%edi)\n\t"
-
- "clflush %%fs:-128(%%ebx)\n\t"
- "clflush %%fs:-64(%%ebx)\n\t"
- "clflush %%fs:(%%ebx)\n\t"
- "clflush %%fs:64(%%ebx)\n\t"
-
- "clflush %%fs:-128(%%ecx)\n\t"
- "clflush %%fs:-64(%%ecx)\n\t"
- "clflush %%fs:(%%ecx)\n\t"
- "clflush %%fs:64(%%ecx)\n\t"
-
- "clflush %%fs:-128(%%edx)\n\t"
- "clflush %%fs:-64(%%edx)\n\t"
-
- :: "b" (addr_lo+128+8*64), "c" (addr_lo+128+12*64),
- "d" (addr_lo +128+16*64), "a"(addr_lo+128),
- "D"(addr_lo+128+4*64)
- );
-}
-
-void ReadL18TestPattern(u32 addr_lo)
-{
- // set fs and use fs prefix to access the mem
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "movl %%fs:-128(%%esi), %%eax\n\t" //TestAddr cache line
- "movl %%fs:-64(%%esi), %%eax\n\t" //+1
- "movl %%fs:(%%esi), %%eax\n\t" //+2
- "movl %%fs:64(%%esi), %%eax\n\t" //+3
-
- "movl %%fs:-128(%%edi), %%eax\n\t" //+4
- "movl %%fs:-64(%%edi), %%eax\n\t" //+5
- "movl %%fs:(%%edi), %%eax\n\t" //+6
- "movl %%fs:64(%%edi), %%eax\n\t" //+7
-
- "movl %%fs:-128(%%ebx), %%eax\n\t" //+8
- "movl %%fs:-64(%%ebx), %%eax\n\t" //+9
- "movl %%fs:(%%ebx), %%eax\n\t" //+10
- "movl %%fs:64(%%ebx), %%eax\n\t" //+11
-
- "movl %%fs:-128(%%ecx), %%eax\n\t" //+12
- "movl %%fs:-64(%%ecx), %%eax\n\t" //+13
- "movl %%fs:(%%ecx), %%eax\n\t" //+14
- "movl %%fs:64(%%ecx), %%eax\n\t" //+15
-
- "movl %%fs:-128(%%edx), %%eax\n\t" //+16
- "movl %%fs:-64(%%edx), %%eax\n\t" //+17
- "mfence\n\t"
-
- :: "a"(0), "b" (addr_lo+128+8*64), "c" (addr_lo+128+12*64),
- "d" (addr_lo +128+16*64), "S"(addr_lo+128),
- "D"(addr_lo+128+4*64)
- );
-
-}
-
-void ReadL9TestPattern(u32 addr_lo)
-{
-
- // set fs and use fs prefix to access the mem
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
-
- "movl %%fs:-128(%%ecx), %%eax\n\t" //TestAddr cache line
- "movl %%fs:-64(%%ecx), %%eax\n\t" //+1
- "movl %%fs:(%%ecx), %%eax\n\t" //+2
- "movl %%fs:64(%%ecx), %%eax\n\t" //+3
-
- "movl %%fs:-128(%%edx), %%eax\n\t" //+4
- "movl %%fs:-64(%%edx), %%eax\n\t" //+5
- "movl %%fs:(%%edx), %%eax\n\t" //+6
- "movl %%fs:64(%%edx), %%eax\n\t" //+7
-
- "movl %%fs:-128(%%ebx), %%eax\n\t" //+8
- "mfence\n\t"
-
- :: "a"(0), "b" (addr_lo+128+8*64), "c"(addr_lo+128),
- "d"(addr_lo+128+4*64)
- );
-
-}
-
-void ReadMaxRdLat1CLTestPattern_D(u32 addr)
-{
- SetUpperFSbase(addr);
-
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "movl %%fs:-128(%%esi), %%eax\n\t" //TestAddr cache line
- "movl %%fs:-64(%%esi), %%eax\n\t" //+1
- "movl %%fs:(%%esi), %%eax\n\t" //+2
- "mfence\n\t"
- :: "a"(0), "S"((addr<<8)+128)
- );
-
-}
-
-void WriteMaxRdLat1CLTestPattern_D(u32 buf, u32 addr)
-{
- SetUpperFSbase(addr);
-
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "1:\n\t"
- "movdqa (%3), %%xmm0\n\t"
- "movntdq %%xmm0, %%fs:(%0)\n\t" /* xmm0 is 128 bit */
- "addl %1, %0\n\t"
- "addl %1, %3\n\t"
- "loop 1b\n\t"
- "mfence\n\t"
-
- :: "a" (addr<<8), "d" (16), "c" (3 * 4), "b"(buf)
- );
-}
-
-void FlushMaxRdLatTestPattern_D(u32 addr)
-{
- /* Flush a pattern of 72 bit times (per DQ) from cache.
- * This procedure is used to ensure cache miss on the next read training.
- */
-
- SetUpperFSbase(addr);
-
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "clflush %%fs:-128(%%esi)\n\t" //TestAddr cache line
- "clflush %%fs:-64(%%esi)\n\t" //+1
- "clflush %%fs:(%%esi)\n\t" //+2
- "mfence\n\t"
-
- :: "S"((addr<<8)+128)
- );
-}
-
-u32 stream_to_int(u8 const *p)
-{
- int i;
- u32 val;
- u32 valx;
-
- val = 0;
-
- for (i = 3; i >= 0; i--) {
- val <<= 8;
- valx = *(p+i);
- val |= valx;
- }
-
- return val;
-}
-
-u8 oemNodePresent_D(u8 Node, u8 *ret)
-{
- *ret = 0;
- return 0;
-}
diff --git a/src/northbridge/amd/amdmct/mct/mct_d_gcc.h b/src/northbridge/amd/amdmct/mct/mct_d_gcc.h
deleted file mode 100644
index 993aa21d74..0000000000
--- a/src/northbridge/amd/amdmct/mct/mct_d_gcc.h
+++ /dev/null
@@ -1,48 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef MCT_D_GCC_H
-#define MCT_D_GCC_H
-
-#include <stdint.h>
-
-void _WRMSR(u32 addr, u32 lo, u32 hi);
-void _RDMSR(u32 addr, u32 *lo, u32 *hi);
-void _RDTSC(u32 *lo, u32 *hi);
-void _cpu_id(u32 addr, u32 *val);
-u32 bsr(u32 x);
-u32 bsf(u32 x);
-
-#define _MFENCE asm volatile ("mfence")
-#define _SFENCE asm volatile ("sfence")
-
-/* prevent speculative execution of following instructions */
-#define _EXECFENCE asm volatile ("outb %al, $0xed")
-
-u32 SetUpperFSbase(u32 addr_hi);
-void proc_CLFLUSH(u32 addr_hi);
-void WriteLNTestPattern(u32 addr_lo, u8 *buf_a, u32 line_num);
-u32 read32_fs(u32 addr_lo);
-void FlushDQSTestPattern_L9(u32 addr_lo);
-__attribute__((noinline)) void FlushDQSTestPattern_L18(u32 addr_lo);
-void ReadL18TestPattern(u32 addr_lo);
-void ReadL9TestPattern(u32 addr_lo);
-void ReadMaxRdLat1CLTestPattern_D(u32 addr);
-void WriteMaxRdLat1CLTestPattern_D(u32 buf, u32 addr);
-void FlushMaxRdLatTestPattern_D(u32 addr);
-u32 stream_to_int(u8 const *p);
-u8 oemNodePresent_D(u8 Node, u8 *ret);
-
-#endif
diff --git a/src/northbridge/amd/amdmct/mct/mctardk3.c b/src/northbridge/amd/amdmct/mct/mctardk3.c
deleted file mode 100644
index c36ba8ea7a..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctardk3.c
+++ /dev/null
@@ -1,179 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include "mct_d.h"
-
-static void Get_ChannelPS_Cfg0_D(u8 MAAdimms, u8 Speed, u8 MAAload,
- u8 DATAAload, u32 *AddrTmgCTL, u32 *ODC_CTL);
-
-
-void mctGet_PS_Cfg_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 dct)
-{
- u16 val, valx;
-
- print_tx("dct: ", dct);
- print_tx("Speed: ", pDCTstat->Speed);
-
- Get_ChannelPS_Cfg0_D(pDCTstat->MAdimms[dct], pDCTstat->Speed,
- pDCTstat->MAload[dct], pDCTstat->DATAload[dct],
- &(pDCTstat->CH_ADDR_TMG[dct]), &(pDCTstat->CH_ODC_CTL[dct]));
-
-
- if (pDCTstat->MAdimms[dct] == 1)
- pDCTstat->CH_ODC_CTL[dct] |= 0x20000000; /* 75ohms */
- else
- pDCTstat->CH_ODC_CTL[dct] |= 0x10000000; /* 150ohms */
-
- pDCTstat->_2Tmode = 1;
-
- /* use byte lane 4 delay for ECC lane */
- pDCTstat->CH_EccDQSLike[0] = 0x0504;
- pDCTstat->CH_EccDQSScale[0] = 0; /* 100% byte lane 4 */
- pDCTstat->CH_EccDQSLike[1] = 0x0504;
- pDCTstat->CH_EccDQSScale[1] = 0; /* 100% byte lane 4 */
-
-
- /*
- Overrides and/or exceptions
- */
-
- /* 1) QRx4 needs to adjust CS/ODT setup time */
- // FIXME: Add Ax support?
- if (mctGet_NVbits(NV_MAX_DIMMS) == 4) {
- if (pDCTstat->DimmQRPresent != 0) {
- pDCTstat->CH_ADDR_TMG[dct] &= 0xFF00FFFF;
- pDCTstat->CH_ADDR_TMG[dct] |= 0x00000000;
- if (pDCTstat->MAdimms[dct] == 4) {
- pDCTstat->CH_ADDR_TMG[dct] &= 0xFF00FFFF;
- pDCTstat->CH_ADDR_TMG[dct] |= 0x002F0000;
- if (pDCTstat->Speed == 3 || pDCTstat->Speed == 4) {
- pDCTstat->CH_ADDR_TMG[dct] &= 0xFF00FFFF;
- pDCTstat->CH_ADDR_TMG[dct] |= 0x00002F00;
- if (pDCTstat->MAdimms[dct] == 4)
- pDCTstat->CH_ODC_CTL[dct] = 0x00331222;
- }
- }
- }
- }
-
-
- /* 2) DRx4 (R/C-J) @ DDR667 needs to adjust CS/ODT setup time */
- if (pDCTstat->Speed == 3 || pDCTstat->Speed == 4) {
- val = pDCTstat->Dimmx4Present;
- if (dct == 0) {
- val &= 0x55;
- } else {
- val &= 0xAA;
- val >>= 1;
- }
- val &= pDCTstat->DIMMValid;
- if (val) {
- //FIXME: skip for Ax
- valx = pDCTstat->DimmDRPresent;
- if (dct == 0) {
- valx &= 0x55;
- } else {
- valx &= 0xAA;
- valx >>= 1;
- }
- val &= valx;
- if (val != 0) {
- if (mctGet_NVbits(NV_MAX_DIMMS) == 8 ||
- pDCTstat->Speed == 3) {
- pDCTstat->CH_ADDR_TMG[dct] &= 0xFFFF00FF;
- pDCTstat->CH_ADDR_TMG[dct] |= 0x00002F00;
- }
- }
- }
- }
-
-
- pDCTstat->CH_ODC_CTL[dct] = procOdtWorkaround(pDCTstat, dct, pDCTstat->CH_ODC_CTL[dct]);
-
- print_tx("CH_ODC_CTL: ", pDCTstat->CH_ODC_CTL[dct]);
- print_tx("CH_ADDR_TMG: ", pDCTstat->CH_ADDR_TMG[dct]);
-
-
-}
-
-
-/*===============================================================================
- * Vendor is responsible for correct settings.
- * M2/Unbuffered 4 Slot - AMD Design Guideline.
- *===============================================================================
- * #1, BYTE, Speed (DCTStatstruc.Speed) (Secondary Key)
- * #2, BYTE, number of Address bus loads on the Channel. (Tershery Key)
- * These must be listed in ascending order.
- * FFh (0xFE) has special meaning of 'any', and must be listed first for each speed grade.
- * #3, DWORD, Address Timing Control Register Value
- * #4, DWORD, Output Driver Compensation Control Register Value
- * #5, BYTE, Number of DIMMs (Primary Key)
- */
-static const u8 Table_ATC_ODC_8D_D[] = {
- 0xFE, 0xFF, 0x00, 0x00, 0x00, 0x00, 0x22, 0x12, 0x11, 0x00, 1,
- 0xFE, 0xFF, 0x00, 0x00, 0x37, 0x00, 0x22, 0x12, 0x11, 0x00, 2,
- 1, 0xFF, 0x00, 0x00, 0x2F, 0x00, 0x22, 0x12, 0x11, 0x00, 3,
- 2, 0xFF, 0x00, 0x00, 0x2F, 0x00, 0x22, 0x12, 0x11, 0x00, 3,
- 3, 0xFF, 0x2F, 0x00, 0x2F, 0x00, 0x22, 0x12, 0x11, 0x00, 3,
- 4, 0xFF, 0x2F, 0x00, 0x2F, 0x00, 0x22, 0x12, 0x33, 0x00, 3,
- 1, 0xFF, 0x00, 0x00, 0x2F, 0x00, 0x22, 0x12, 0x11, 0x00, 4,
- 2, 0xFF, 0x00, 0x00, 0x2F, 0x00, 0x22, 0x12, 0x11, 0x00, 4,
- 3, 0xFF, 0x2F, 0x00, 0x2F, 0x00, 0x22, 0x12, 0x33, 0x00, 4,
- 4, 0xFF, 0x2F, 0x00, 0x2F, 0x00, 0x22, 0x12, 0x33, 0x00, 4,
- 0xFF
-};
-
-static const u8 Table_ATC_ODC_4D_D[] = {
- 0xFE, 0xFF, 0x00, 0x00, 0x00, 0x00, 0x22, 0x12, 0x11, 0x00, 1,
- 0xFE, 0xFF, 0x00, 0x00, 0x37, 0x00, 0x22, 0x12, 0x11, 0x00, 2,
- 0xFE, 0xFF, 0x00, 0x00, 0x00, 0x00, 0x22, 0x12, 0x11, 0x00, 3,
- 0xFE, 0xFF, 0x00, 0x00, 0x00, 0x00, 0x22, 0x12, 0x11, 0x00, 4,
- 0xFF
-};
-
-
-static void Get_ChannelPS_Cfg0_D(u8 MAAdimms, u8 Speed, u8 MAAload,
- u8 DATAAload, u32 *AddrTmgCTL, u32 *ODC_CTL)
-{
- const u8 *p;
-
- *AddrTmgCTL = 0;
- *ODC_CTL = 0;
-
- if (mctGet_NVbits(NV_MAX_DIMMS) == 8) {
- /* 8 DIMM Table */
- p = Table_ATC_ODC_8D_D;
- //FIXME Add Ax support
- } else {
- /* 4 DIMM Table*/
- p = Table_ATC_ODC_4D_D;
- //FIXME Add Ax support
- }
-
- while (*p != 0xFF) {
- if ((MAAdimms == *(p+10)) || (*(p+10) == 0xFE)) {
- if ((*p == Speed) || (*p == 0xFE)) {
- if (MAAload <= *(p+1)) {
- *AddrTmgCTL = stream_to_int((u8*)(p+2));
- *ODC_CTL = stream_to_int((u8*)(p+6));
- break;
- }
- }
- }
- p+=11;
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctardk4.c b/src/northbridge/amd/amdmct/mct/mctardk4.c
deleted file mode 100644
index c700593740..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctardk4.c
+++ /dev/null
@@ -1,149 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include "mct_d.h"
-
-static void Get_ChannelPS_Cfg0_D(u8 MAAdimms, u8 Speed, u8 MAAload,
- u8 DATAAload, u32 *AddrTmgCTL, u32 *ODC_CTL,
- u8 *CMDmode);
-
-
-void mctGet_PS_Cfg_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 dct)
-{
- print_tx("dct: ", dct);
- print_tx("Speed: ", pDCTstat->Speed);
-
- Get_ChannelPS_Cfg0_D(pDCTstat->MAdimms[dct], pDCTstat->Speed,
- pDCTstat->MAload[dct], pDCTstat->DATAload[dct],
- &(pDCTstat->CH_ADDR_TMG[dct]), &(pDCTstat->CH_ODC_CTL[dct]),
- &pDCTstat->_2Tmode);
-
- if (pDCTstat->MAdimms[dct] == 1)
- pDCTstat->CH_ODC_CTL[dct] |= 0x20000000; /* 75ohms */
- else
- pDCTstat->CH_ODC_CTL[dct] |= 0x10000000; /* 150ohms */
-
-
- /*
- * Overrides and/or workarounds
- */
- pDCTstat->CH_ODC_CTL[dct] = procOdtWorkaround(pDCTstat, dct, pDCTstat->CH_ODC_CTL[dct]);
-
- print_tx("4 CH_ODC_CTL: ", pDCTstat->CH_ODC_CTL[dct]);
- print_tx("4 CH_ADDR_TMG: ", pDCTstat->CH_ADDR_TMG[dct]);
-}
-
-/*=============================================================================
- * Vendor is responsible for correct settings.
- * M2/Unbuffered 4 Slot - AMD Design Guideline.
- *=============================================================================
- * #1, BYTE, Speed (DCTStatstruc.Speed)
- * #2, BYTE, number of Address bus loads on the Channel.
- * These must be listed in ascending order.
- * FFh (-1) has special meaning of 'any', and must be listed first for
- * each speed grade.
- * #3, DWORD, Address Timing Control Register Value
- * #4, DWORD, Output Driver Compensation Control Register Value
- */
-
-static const u8 Table_ATC_ODC_D_Bx[] = {
- 1, 0xFF, 0x00, 0x2F, 0x2F, 0x0, 0x22, 0x13, 0x11, 0x0,
- 2, 12, 0x00, 0x2F, 0x2F, 0x0, 0x22, 0x13, 0x11, 0x0,
- 2, 16, 0x00, 0x2F, 0x00, 0x0, 0x22, 0x13, 0x11, 0x0,
- 2, 20, 0x00, 0x2F, 0x38, 0x0, 0x22, 0x13, 0x11, 0x0,
- 2, 24, 0x00, 0x2F, 0x37, 0x0, 0x22, 0x13, 0x11, 0x0,
- 2, 32, 0x00, 0x2F, 0x34, 0x0, 0x22, 0x13, 0x11, 0x0,
- 3, 12, 0x20, 0x22, 0x20, 0x0, 0x22, 0x13, 0x11, 0x0,
- 3, 16, 0x20, 0x22, 0x30, 0x0, 0x22, 0x13, 0x11, 0x0,
- 3, 20, 0x20, 0x22, 0x2C, 0x0, 0x22, 0x13, 0x11, 0x0,
- 3, 24, 0x20, 0x22, 0x2A, 0x0, 0x22, 0x13, 0x11, 0x0,
- 3, 32, 0x20, 0x22, 0x2B, 0x0, 0x22, 0x13, 0x11, 0x0,
- 4, 0xFF, 0x20, 0x25, 0x20, 0x0, 0x22, 0x33, 0x11, 0x0,
- 5, 0xFF, 0x20, 0x20, 0x2F, 0x0, 0x22, 0x32, 0x11, 0x0,
- 0xFF
-};
-
-
-static void Get_ChannelPS_Cfg0_D(u8 MAAdimms, u8 Speed, u8 MAAload,
- u8 DATAAload, u32 *AddrTmgCTL, u32 *ODC_CTL,
- u8 *CMDmode)
-{
- u8 const *p;
-
- *AddrTmgCTL = 0;
- *ODC_CTL = 0;
- *CMDmode = 1;
-
- // FIXME: add Ax support
- if (MAAdimms == 0) {
- *ODC_CTL = 0x00111222;
- if (Speed == 3)
- *AddrTmgCTL = 0x00202220;
- else if (Speed == 2)
- *AddrTmgCTL = 0x002F2F00;
- else if (Speed == 1)
- *AddrTmgCTL = 0x002F2F00;
- else if (Speed == 4)
- *AddrTmgCTL = 0x00202520;
- else if (Speed == 5)
- *AddrTmgCTL = 0x002F2020;
- else
- *AddrTmgCTL = 0x002F2F2F;
- } else if (MAAdimms == 1) {
- if (Speed == 4) {
- *CMDmode = 2;
- *AddrTmgCTL = 0x00202520;
- *ODC_CTL = 0x00113222;
- } else if (Speed == 5) {
- *CMDmode = 2;
- *AddrTmgCTL = 0x002F2020;
- *ODC_CTL = 0x00113222;
- } else {
- *CMDmode = 1;
- *ODC_CTL = 0x00111222;
- if (Speed == 3) {
- *AddrTmgCTL = 0x00202220;
- } else if (Speed == 2) {
- if (MAAload == 4)
- *AddrTmgCTL = 0x002B2F00;
- else if (MAAload == 16)
- *AddrTmgCTL = 0x002B2F00;
- else if (MAAload == 8)
- *AddrTmgCTL = 0x002F2F00;
- else
- *AddrTmgCTL = 0x002F2F00;
- } else if (Speed == 1) {
- *AddrTmgCTL = 0x002F2F00;
- } else {
- *AddrTmgCTL = 0x002F2F2F;
- }
- }
- } else {
- *CMDmode = 2;
- p = Table_ATC_ODC_D_Bx;
- do {
- if (Speed == *p) {
- if (MAAload <= *(p+1)) {
- *AddrTmgCTL = stream_to_int(p+2);
- *ODC_CTL = stream_to_int(p+6);
- break;
- }
- }
- p+=10;
- } while (*p == 0xff);
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctchi_d.c b/src/northbridge/amd/amdmct/mct/mctchi_d.c
deleted file mode 100644
index d2acc15118..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctchi_d.c
+++ /dev/null
@@ -1,125 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "mct_d.h"
-
-void InterleaveChannels_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
-
- u8 Node;
- u32 DramBase, DctSelBase;
- u8 DctSelIntLvAddr, DctSelHi;
- u8 HoleValid = 0;
- u32 HoleSize, HoleBase = 0;
- u32 val, tmp;
- u32 dct0_size, dct1_size;
- u8 enabled;
- struct DCTStatStruc *pDCTstat;
-
- /* HoleValid - indicates whether the current Node contains hole.
- * HoleSize - indicates whether there is IO hole in the whole system
- * memory.
- */
-
- /* call back to wrapper not needed ManualChannelInterleave_D(); */
- /* call back - DctSelIntLvAddr = mctGet_NVbits(NV_ChannelIntlv);*/ /* override interleave */
- // FIXME: Check for Cx
- DctSelIntLvAddr = mctGet_NVbits(NV_ChannelIntlv); /* typ = 5: Hash*: exclusive OR of address bits[20:16, 6]. */
- beforeInterleaveChannels_D(pDCTstatA, &enabled);
-
- if (DctSelIntLvAddr & 1) {
- DctSelIntLvAddr >>= 1;
- HoleSize = 0;
- if ((pMCTstat->GStatus & (1 << GSB_SoftHole)) ||
- (pMCTstat->GStatus & (1 << GSB_HWHole))) {
- if (pMCTstat->HoleBase) {
- HoleBase = pMCTstat->HoleBase >> 8;
- HoleSize = HoleBase & 0xFFFF0000;
- HoleSize |= ((~HoleBase) + 1) & 0xFFFF;
- }
- }
- Node = 0;
- while (Node < MAX_NODES_SUPPORTED) {
- pDCTstat = pDCTstatA + Node;
- val = Get_NB32(pDCTstat->dev_map, 0xF0);
- if (val & (1 << DramHoleValid))
- HoleValid = 1;
- if (!pDCTstat->GangedMode && pDCTstat->DIMMValidDCT[0] && pDCTstat->DIMMValidDCT[1]) {
- DramBase = pDCTstat->NodeSysBase >> 8;
- dct1_size = ((pDCTstat->NodeSysLimit) + 2) >> 8;
- dct0_size = Get_NB32(pDCTstat->dev_dct, 0x114);
- if (dct0_size >= 0x10000) {
- dct0_size -= HoleSize;
- }
-
- dct0_size -= DramBase;
- dct1_size -= dct0_size;
- DctSelHi = 0x05; /* DctSelHiRngEn = 1, DctSelHi = 0 */
- if (dct1_size == dct0_size) {
- dct1_size = 0;
- DctSelHi = 0x04; /* DctSelHiRngEn = 0 */
- } else if (dct1_size > dct0_size) {
- dct1_size = dct0_size;
- DctSelHi = 0x07; /* DctSelHiRngEn = 1, DctSelHi = 1 */
- }
- dct0_size = dct1_size;
- dct0_size += DramBase;
- dct0_size += dct1_size;
- if (dct0_size >= HoleBase) /* if DctSelBaseAddr > HoleBase */
- dct0_size += HoleSize;
- DctSelBase = dct0_size;
-
- if (dct1_size == 0)
- dct0_size = 0;
- dct0_size -= dct1_size; /* DctSelBaseOffset = DctSelBaseAddr - Interleaved region */
- Set_NB32(pDCTstat->dev_dct, 0x114, dct0_size);
-
- if (dct1_size == 0)
- dct1_size = DctSelBase;
- val = Get_NB32(pDCTstat->dev_dct, 0x110);
- val &= 0x7F8;
- val |= dct1_size;
- val |= DctSelHi;
- val |= (DctSelIntLvAddr << 6) & 0xFF;
- Set_NB32(pDCTstat->dev_dct, 0x110, val);
- print_tx("InterleaveChannels: F2x110 DRAM Controller Select Low Register = ", val);
-
- if (HoleValid) {
- tmp = DramBase;
- val = DctSelBase;
- if (val < HoleBase) { /* DctSelBaseAddr < DramHoleBase */
- val -= DramBase;
- val >>= 1;
- tmp += val;
- }
- tmp += HoleSize;
- val = Get_NB32(pDCTstat->dev_map, 0xF0); /* DramHoleOffset */
- val &= 0xFFFF007F;
- val |= (tmp & ~0xFFFF007F);
- Set_NB32(pDCTstat->dev_map, 0xF0, val);
- print_tx("InterleaveChannels: F1xF0 DRAM Hole Address Register = ", val);
-
- }
- }
- print_tx("InterleaveChannels_D: Node ", Node);
- print_tx("InterleaveChannels_D: Status ", pDCTstat->Status);
- print_tx("InterleaveChannels_D: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("InterleaveChannels_D: ErrCode ", pDCTstat->ErrCode);
- Node++;
- }
- }
- print_t("InterleaveChannels_D: Done\n");
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctcsi_d.c b/src/northbridge/amd/amdmct/mct/mctcsi_d.c
deleted file mode 100644
index 6a19788ab3..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctcsi_d.c
+++ /dev/null
@@ -1,140 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "mct_d.h"
-
-/* Low swap bit vs bank size encoding (physical, not logical address bit)
- * ;To calculate the number by hand, add the number of Bank address bits
- * ;(2 or 3) to the number of column address bits, plus 3 (the logical
- * ;page size), and subtract 8.
- */
-static const u8 Tab_int_D[] = { 6,7,7,8,8,8,8,8,9,9,8,9 };
-
-void InterleaveBanks_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 ChipSel, EnChipSels;
- u32 AddrLoMask, AddrHiMask;
- u32 AddrLoMaskN, AddrHiMaskN, MemSize = 0;
- u8 DoIntlv, _CsIntCap;
- u32 BitDelta, BankEncd = 0;
-
- u32 dev;
- u32 reg;
- u32 reg_off;
- u32 val;
- u32 val_lo, val_hi;
-
- DoIntlv = mctGet_NVbits(NV_BankIntlv);
- _CsIntCap = 0;
- EnChipSels = 0;
-
- dev = pDCTstat->dev_dct;
- reg_off = 0x100 * dct;
-
- ChipSel = 0; /* Find out if current configuration is capable */
- while (DoIntlv && (ChipSel < MAX_CS_SUPPORTED)) {
- reg = 0x40+(ChipSel << 2) + reg_off; /* Dram CS Base 0 */
- val = Get_NB32(dev, reg);
- if (val & (1 << CSEnable)) {
- EnChipSels++;
- reg = 0x60+((ChipSel >> 1) << 2)+reg_off; /*Dram CS Mask 0 */
- val = Get_NB32(dev, reg);
- val >>= 19;
- val &= 0x3ff;
- val++;
- if (EnChipSels == 1)
- MemSize = val;
- else
- /*If mask sizes not same then skip */
- if (val != MemSize)
- break;
- reg = 0x80 + reg_off; /*Dram Bank Addressing */
- val = Get_NB32(dev, reg);
- val >>= (ChipSel >> 1) << 2;
- val &= 0x0f;
- if (EnChipSels == 1)
- BankEncd = val;
- else
- /*If number of Rows/Columns not equal, skip */
- if (val != BankEncd)
- break;
- }
- ChipSel++;
- }
- if (ChipSel == MAX_CS_SUPPORTED) {
- if ((EnChipSels == 2) || (EnChipSels == 4) || (EnChipSels == 8))
- _CsIntCap = 1;
- }
-
- if (DoIntlv) {
- if (!_CsIntCap) {
- pDCTstat->ErrStatus |= 1 << SB_BkIntDis;
- DoIntlv = 0;
- }
- }
-
- if (DoIntlv) {
- val = Tab_int_D[BankEncd];
- if (pDCTstat->Status & (1 << SB_128bitmode))
- val++;
-
- AddrLoMask = (EnChipSels - 1) << val;
- AddrLoMaskN = ~AddrLoMask;
-
- val = bsf(MemSize) + 19;
- AddrHiMask = (EnChipSels -1) << val;
- AddrHiMaskN = ~AddrHiMask;
-
- BitDelta = bsf(AddrHiMask) - bsf(AddrLoMask);
-
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel++) {
- reg = 0x40+(ChipSel << 2) + reg_off; /*Dram CS Base 0 */
- val = Get_NB32(dev, reg);
- if (val & 3) {
- val_lo = val & AddrLoMask;
- val_hi = val & AddrHiMask;
- val &= AddrLoMaskN;
- val &= AddrHiMaskN;
- val_lo <<= BitDelta;
- val_hi >>= BitDelta;
- val |= val_lo;
- val |= val_hi;
- Set_NB32(dev, reg, val);
-
- if (ChipSel & 1)
- continue;
-
- reg = 0x60 + ((ChipSel >> 1) << 2) + reg_off; /*Dram CS Mask 0 */
- val = Get_NB32(dev, reg);
- val_lo = val & AddrLoMask;
- val_hi = val & AddrHiMask;
- val &= AddrLoMaskN;
- val &= AddrHiMaskN;
- val_lo <<= BitDelta;
- val_hi >>= BitDelta;
- val |= val_lo;
- val |= val_hi;
- Set_NB32(dev, reg, val);
- }
- }
- print_t("InterleaveBanks_D: Banks Interleaved ");
- } /* DoIntlv */
-
- print_tx("InterleaveBanks_D: Status ", pDCTstat->Status);
- print_tx("InterleaveBanks_D: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("InterleaveBanks_D: ErrCode ", pDCTstat->ErrCode);
- print_t("InterleaveBanks_D: Done\n");
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctdqs_d.c b/src/northbridge/amd/amdmct/mct/mctdqs_d.c
deleted file mode 100644
index 2e52a39619..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctdqs_d.c
+++ /dev/null
@@ -1,1207 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <console/console.h>
-#include <cpu/x86/cr.h>
-#include <cpu/amd/msr.h>
-#include <cpu/amd/mtrr.h>
-
-#include "mct_d.h"
-
-static void CalcEccDQSPos_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u16 like,
- u8 scale, u8 ChipSel);
-static void GetDQSDatStrucVal_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel);
-static u8 MiddleDQS_D(u8 min, u8 max);
-static void TrainReadDQS_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 cs_start);
-static void TrainWriteDQS_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 cs_start);
-static void WriteDQSTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo);
-static void WriteL18TestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo);
-static void WriteL9TestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo);
-static u8 CompareDQSTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 addr_lo);
-static void FlushDQSTestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 addr_lo);
-static void ReadDQSTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo);
-static void mct_SetDQSDelayCSR_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 ChipSel);
-static void mct_SetDQSDelayAllCSR_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 cs_start);
-static void SetupDqsPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 *buffer);
-
-void print_debug_dqs(const char *str, u32 val, u8 level)
-{
-#if DQS_TRAIN_DEBUG > 0
- if (DQS_TRAIN_DEBUG >= level) {
- printk(BIOS_DEBUG, "%s%x\n", str, val);
- }
-#endif
-}
-
-void print_debug_dqs_pair(const char *str, u32 val, const char *str2, u32 val2, u8 level)
-{
-#if DQS_TRAIN_DEBUG > 0
- if (DQS_TRAIN_DEBUG >= level) {
- printk(BIOS_DEBUG, "%s%08x%s%08x\n", str, val, str2, val2);
- }
-#endif
-}
-
-/*Warning: These must be located so they do not cross a logical 16-bit segment boundary!*/
-static const u32 TestPatternJD1a_D[] = {
- 0x00000000,0x00000000,0xFFFFFFFF,0xFFFFFFFF, /* QW0-1, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW2-3, ALL-EVEN */
- 0x00000000,0x00000000,0xFFFFFFFF,0xFFFFFFFF, /* QW4-5, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW6-7, ALL-EVEN */
- 0xFeFeFeFe,0xFeFeFeFe,0x01010101,0x01010101, /* QW0-1, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0x01010101,0x01010101, /* QW2-3, DQ0-ODD */
- 0x01010101,0x01010101,0xFeFeFeFe,0xFeFeFeFe, /* QW4-5, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0x01010101,0x01010101, /* QW6-7, DQ0-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW0-1, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd, /* QW2-3, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0x02020202,0x02020202, /* QW4-5, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW6-7, DQ1-ODD */
- 0x04040404,0x04040404,0xfBfBfBfB,0xfBfBfBfB, /* QW0-1, DQ2-ODD */
- 0x04040404,0x04040404,0x04040404,0x04040404, /* QW2-3, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW4-5, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW6-7, DQ2-ODD */
- 0x08080808,0x08080808,0xF7F7F7F7,0xF7F7F7F7, /* QW0-1, DQ3-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW2-3, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0x08080808,0x08080808, /* QW4-5, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW6-7, DQ3-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW0-1, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0x10101010,0x10101010, /* QW2-3, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW4-5, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0x10101010,0x10101010, /* QW6-7, DQ4-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW0-1, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0x20202020,0x20202020, /* QW2-3, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW4-5, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW6-7, DQ5-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW0-1, DQ6-ODD */
- 0x40404040,0x40404040,0xBfBfBfBf,0xBfBfBfBf, /* QW2-3, DQ6-ODD */
- 0x40404040,0x40404040,0xBfBfBfBf,0xBfBfBfBf, /* QW4-5, DQ6-ODD */
- 0x40404040,0x40404040,0xBfBfBfBf,0xBfBfBfBf, /* QW6-7, DQ6-ODD */
- 0x80808080,0x80808080,0x7F7F7F7F,0x7F7F7F7F, /* QW0-1, DQ7-ODD */
- 0x80808080,0x80808080,0x7F7F7F7F,0x7F7F7F7F, /* QW2-3, DQ7-ODD */
- 0x80808080,0x80808080,0x7F7F7F7F,0x7F7F7F7F, /* QW4-5, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080 /* QW6-7, DQ7-ODD */
-};
-static const u32 TestPatternJD1b_D[] = {
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW0,CHA-B, ALL-EVEN */
- 0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF, /* QW1,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW2,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW3,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW4,CHA-B, ALL-EVEN */
- 0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF, /* QW5,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW6,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW7,CHA-B, ALL-EVEN */
- 0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe, /* QW0,CHA-B, DQ0-ODD */
- 0x01010101,0x01010101,0x01010101,0x01010101, /* QW1,CHA-B, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe, /* QW2,CHA-B, DQ0-ODD */
- 0x01010101,0x01010101,0x01010101,0x01010101, /* QW3,CHA-B, DQ0-ODD */
- 0x01010101,0x01010101,0x01010101,0x01010101, /* QW4,CHA-B, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe, /* QW5,CHA-B, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe, /* QW6,CHA-B, DQ0-ODD */
- 0x01010101,0x01010101,0x01010101,0x01010101, /* QW7,CHA-B, DQ0-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW0,CHA-B, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW1,CHA-B, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd, /* QW2,CHA-B, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd, /* QW3,CHA-B, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd, /* QW4,CHA-B, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW5,CHA-B, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW6,CHA-B, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW7,CHA-B, DQ1-ODD */
- 0x04040404,0x04040404,0x04040404,0x04040404, /* QW0,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW1,CHA-B, DQ2-ODD */
- 0x04040404,0x04040404,0x04040404,0x04040404, /* QW2,CHA-B, DQ2-ODD */
- 0x04040404,0x04040404,0x04040404,0x04040404, /* QW3,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW4,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW5,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW6,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW7,CHA-B, DQ2-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW0,CHA-B, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW1,CHA-B, DQ3-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW2,CHA-B, DQ3-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW3,CHA-B, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW4,CHA-B, DQ3-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW5,CHA-B, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW6,CHA-B, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW7,CHA-B, DQ3-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW0,CHA-B, DQ4-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW1,CHA-B, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW2,CHA-B, DQ4-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW3,CHA-B, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW4,CHA-B, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW5,CHA-B, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW6,CHA-B, DQ4-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW7,CHA-B, DQ4-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW0,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW1,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW2,CHA-B, DQ5-ODD */
- 0x20202020,0x20202020,0x20202020,0x20202020, /* QW3,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW4,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW5,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW6,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW7,CHA-B, DQ5-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW0,CHA-B, DQ6-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW1,CHA-B, DQ6-ODD */
- 0x40404040,0x40404040,0x40404040,0x40404040, /* QW2,CHA-B, DQ6-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW3,CHA-B, DQ6-ODD */
- 0x40404040,0x40404040,0x40404040,0x40404040, /* QW4,CHA-B, DQ6-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW5,CHA-B, DQ6-ODD */
- 0x40404040,0x40404040,0x40404040,0x40404040, /* QW6,CHA-B, DQ6-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW7,CHA-B, DQ6-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080, /* QW0,CHA-B, DQ7-ODD */
- 0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F, /* QW1,CHA-B, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080, /* QW2,CHA-B, DQ7-ODD */
- 0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F, /* QW3,CHA-B, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080, /* QW4,CHA-B, DQ7-ODD */
- 0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F, /* QW5,CHA-B, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080, /* QW6,CHA-B, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080 /* QW7,CHA-B, DQ7-ODD */
-};
-
-void TrainReceiverEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA, u8 Pass)
-{
- u8 Node;
- struct DCTStatStruc *pDCTstat;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
-
-/*FIXME: needed? if (!pDCTstat->NodePresent)
- break;
-*/
- if (pDCTstat->DCTSysLimit) {
- mct_TrainRcvrEn_D(pMCTstat, pDCTstat, Pass);
- }
- }
-}
-
-
-static void SetEccDQSRdWrPos_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel)
-{
- u8 channel;
- u8 direction;
-
- for (channel = 0; channel < 2; channel++) {
- for (direction = 0; direction < 2; direction++) {
- pDCTstat->Channel = channel; /* Channel A or B */
- pDCTstat->Direction = direction; /* Read or write */
- CalcEccDQSPos_D(pMCTstat, pDCTstat, pDCTstat->CH_EccDQSLike[channel], pDCTstat->CH_EccDQSScale[channel], ChipSel);
- print_debug_dqs_pair("\t\tSetEccDQSRdWrPos: channel ", channel, direction == DQS_READDIR? " R dqs_delay":" W dqs_delay", pDCTstat->DQSDelay, 2);
- pDCTstat->ByteLane = 8;
- StoreDQSDatStrucVal_D(pMCTstat, pDCTstat, ChipSel);
- mct_SetDQSDelayCSR_D(pMCTstat, pDCTstat, ChipSel);
- }
- }
-}
-
-
-
-static void CalcEccDQSPos_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u16 like, u8 scale, u8 ChipSel)
-{
- u8 DQSDelay0, DQSDelay1;
- u16 DQSDelay;
-
- pDCTstat->ByteLane = like & 0xff;
- GetDQSDatStrucVal_D(pMCTstat, pDCTstat, ChipSel);
- DQSDelay0 = pDCTstat->DQSDelay;
-
- pDCTstat->ByteLane = (like >> 8) & 0xff;
- GetDQSDatStrucVal_D(pMCTstat, pDCTstat, ChipSel);
- DQSDelay1 = pDCTstat->DQSDelay;
-
- if (DQSDelay0 > DQSDelay1) {
- DQSDelay = DQSDelay0 - DQSDelay1;
- } else {
- DQSDelay = DQSDelay1 - DQSDelay0;
- }
-
- DQSDelay = DQSDelay * (~scale);
-
- DQSDelay += 0x80; // round it
-
- DQSDelay >>= 8; // /256
-
- if (DQSDelay0 > DQSDelay1) {
- DQSDelay = DQSDelay1 - DQSDelay;
- } else {
- DQSDelay += DQSDelay1;
- }
-
- pDCTstat->DQSDelay = (u8)DQSDelay;
-}
-
-
-static void TrainDQSRdWrPos_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 cs_start)
-{
- u32 Errors;
- u8 Channel, DQSWrDelay;
- u8 _DisableDramECC = 0;
- u32 PatternBuffer[292];
- u8 _Wrap32Dis = 0, _SSE2 = 0;
- u8 dqsWrDelay_end;
-
- u32 addr;
- CRx_TYPE cr4;
- u32 lo, hi;
-
- print_debug_dqs("\nTrainDQSRdWrPos: Node_ID ", pDCTstat->Node_ID, 0);
- cr4 = read_cr4();
- if (cr4 & (1<<9)) {
- _SSE2 = 1;
- }
- cr4 |= (1<<9); /* OSFXSR enable SSE2 */
- write_cr4(cr4);
-
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- if (lo & (1<<17)) {
- _Wrap32Dis = 1;
- }
- lo |= (1<<17); /* HWCR.wrap32dis */
- _WRMSR(addr, lo, hi); /* allow 64-bit memory references in real mode */
-
- /* Disable ECC correction of reads on the dram bus. */
- _DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
-
- SetupDqsPattern_D(pMCTstat, pDCTstat, PatternBuffer);
-
- /* mct_BeforeTrainDQSRdWrPos_D */
- dqsWrDelay_end = 0x20;
-
- Errors = 0;
- for (Channel = 0; Channel < 2; Channel++) {
- print_debug_dqs("\tTrainDQSRdWrPos: 1 Channel ",Channel, 1);
- pDCTstat->Channel = Channel;
-
- if (pDCTstat->DIMMValidDCT[Channel] == 0) /* mct_BeforeTrainDQSRdWrPos_D */
- continue;
-
- for (DQSWrDelay = 0; DQSWrDelay < dqsWrDelay_end; DQSWrDelay++) {
- pDCTstat->DQSDelay = DQSWrDelay;
- pDCTstat->Direction = DQS_WRITEDIR;
- mct_SetDQSDelayAllCSR_D(pMCTstat, pDCTstat, cs_start);
-
- print_debug_dqs("\t\tTrainDQSRdWrPos: 21 DQSWrDelay ", DQSWrDelay, 2);
- TrainReadDQS_D(pMCTstat, pDCTstat, cs_start);
-
- print_debug_dqs("\t\tTrainDQSRdWrPos: 22 TrainErrors ",pDCTstat->TrainErrors, 2);
- if (pDCTstat->TrainErrors == 0) {
- break;
- }
- Errors |= pDCTstat->TrainErrors;
- }
- if (DQSWrDelay < dqsWrDelay_end) {
- Errors = 0;
-
- print_debug_dqs("\tTrainDQSRdWrPos: 231 DQSWrDelay ", DQSWrDelay, 1);
- TrainWriteDQS_D(pMCTstat, pDCTstat, cs_start);
- }
- print_debug_dqs("\tTrainDQSRdWrPos: 232 Errors ", Errors, 1);
- pDCTstat->ErrStatus |= Errors;
- }
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 val;
- u8 i;
- u8 Channel, Receiver, Dir;
- u8 *p;
-
- for (Dir = 0; Dir < 2; Dir++) {
- if (Dir == 0) {
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: CH_D_DIR_B_DQS WR:\n");
- } else {
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: CH_D_DIR_B_DQS RD:\n");
- }
- for (Channel = 0; Channel < 2; Channel++) {
- printk(BIOS_DEBUG, "Channel: %02x\n", Channel);
- for (Receiver = cs_start; Receiver < (cs_start + 2); Receiver += 2) {
- printk(BIOS_DEBUG, "\t\tReceiver: %02x: ", Receiver);
- p = pDCTstat->persistentData.CH_D_DIR_B_DQS[Channel][Receiver >> 1][Dir];
- for (i = 0; i < 8; i++) {
- val = p[i];
- printk(BIOS_DEBUG, "%02x ", val);
- }
- printk(BIOS_DEBUG, "\n");
- }
- }
- }
-
- }
-#endif
-
- if (_DisableDramECC) {
- mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
- }
- if (!_Wrap32Dis) {
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(addr, lo, hi);
- }
- if (!_SSE2) {
- cr4 = read_cr4();
- cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
- write_cr4(cr4);
- }
-
- print_tx("TrainDQSRdWrPos: Status ", pDCTstat->Status);
- print_tx("TrainDQSRdWrPos: TrainErrors ", pDCTstat->TrainErrors);
- print_tx("TrainDQSRdWrPos: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("TrainDQSRdWrPos: ErrCode ", pDCTstat->ErrCode);
- print_t("TrainDQSRdWrPos: Done\n");
-}
-
-
-static void SetupDqsPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 *buffer)
-{
- /* 1. Set the Pattern type (0 or 1) in DCTStatstruc.Pattern
- * 2. Copy the pattern from ROM to Cache, aligning on 16 byte boundary
- * 3. Set the ptr to Cacheable copy in DCTStatstruc.PtrPatternBufA
- */
-
- u32 *buf;
- u16 i;
-
- buf = (u32 *)(((u32)buffer + 0x10) & (0xfffffff0));
- if (pDCTstat->Status & (1 << SB_128bitmode)) {
- pDCTstat->Pattern = 1; /* 18 cache lines, alternating qwords */
- for (i = 0; i < 16*18; i++)
- buf[i] = TestPatternJD1b_D[i];
- } else {
- pDCTstat->Pattern = 0; /* 9 cache lines, sequential qwords */
- for (i = 0; i < 16*9; i++)
- buf[i] = TestPatternJD1a_D[i];
- }
- pDCTstat->PtrPatternBufA = (u32)buf;
-}
-
-
-static void TrainDQSPos_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 cs_start)
-{
- u32 Errors;
- u8 ChipSel, DQSDelay;
- u8 RnkDlySeqPassMin,RnkDlySeqPassMax, RnkDlyFilterMin, RnkDlyFilterMax;
- u8 LastTest;
- u32 TestAddr;
- u8 ByteLane;
- u8 MutualCSPassW[64];
- u8 BanksPresent;
- u8 dqsDelay_end;
- u8 tmp, valid;
-
-
- /* MutualCSPassW: each byte represents a bitmap of pass/fail per
- * ByteLane. The indext within MutualCSPassW is the delay value
- * given the results.
- */
-
-
- print_debug_dqs("\t\t\tTrainDQSPos begin ", 0, 3);
-
- Errors = 0;
- BanksPresent = 0;
-
- if (pDCTstat->Direction == DQS_READDIR) {
- dqsDelay_end = 64;
- mct_AdjustDelayRange_D(pMCTstat, pDCTstat, &dqsDelay_end);
- } else {
- dqsDelay_end = 32;
- }
-
- /* Bitmapped status per delay setting, 0xff = All positions
- * passing (1= PASS). Set the entire array.
- */
- for (DQSDelay = 0; DQSDelay < 64; DQSDelay++) {
- MutualCSPassW[DQSDelay] = 0xFF;
- }
-
- for (ChipSel = cs_start; ChipSel < (cs_start + 2); ChipSel++) { /* logical register chipselects 0..7 */
- print_debug_dqs("\t\t\t\tTrainDQSPos: 11 ChipSel ", ChipSel, 4);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, pDCTstat->Channel, ChipSel)) {
- print_debug_dqs("\t\t\t\tmct_RcvrRankEnabled_D CS not enabled ", ChipSel, 4);
- continue;
- }
-
- BanksPresent = 1; /* flag for at least one bank is present */
- TestAddr = mct_GetMCTSysAddr_D(pMCTstat, pDCTstat, pDCTstat->Channel, ChipSel, &valid);
- if (!valid) {
- print_debug_dqs("\t\t\t\tAddress not supported on current CS ", TestAddr, 4);
- continue;
- }
-
- print_debug_dqs("\t\t\t\tTrainDQSPos: 12 TestAddr ", TestAddr, 4);
- SetUpperFSbase(TestAddr); /* fs:eax = far ptr to target */
-
- if (pDCTstat->Direction == DQS_READDIR) {
- print_debug_dqs("\t\t\t\tTrainDQSPos: 13 for read ", 0, 4);
- WriteDQSTestPattern_D(pMCTstat, pDCTstat, TestAddr << 8);
- }
-
- for (DQSDelay = 0; DQSDelay < dqsDelay_end; DQSDelay++) {
- print_debug_dqs("\t\t\t\t\tTrainDQSPos: 141 DQSDelay ", DQSDelay, 5);
- if (MutualCSPassW[DQSDelay] == 0)
- continue; //skip current delay value if other chipselects have failed all 8 bytelanes
- pDCTstat->DQSDelay = DQSDelay;
- mct_SetDQSDelayAllCSR_D(pMCTstat, pDCTstat, cs_start);
- print_debug_dqs("\t\t\t\t\tTrainDQSPos: 142 MutualCSPassW ", MutualCSPassW[DQSDelay], 5);
-
- if (pDCTstat->Direction == DQS_WRITEDIR) {
- print_debug_dqs("\t\t\t\t\tTrainDQSPos: 143 for write", 0, 5);
- WriteDQSTestPattern_D(pMCTstat, pDCTstat, TestAddr << 8);
- }
-
- print_debug_dqs("\t\t\t\t\tTrainDQSPos: 144 Pattern ", pDCTstat->Pattern, 5);
- ReadDQSTestPattern_D(pMCTstat, pDCTstat, TestAddr << 8);
- /* print_debug_dqs("\t\t\t\t\tTrainDQSPos: 145 MutualCSPassW ", MutualCSPassW[DQSDelay], 5); */
- tmp = CompareDQSTestPattern_D(pMCTstat, pDCTstat, TestAddr << 8); /* 0 = fail, 1 = pass */
-
- if (mct_checkFenceHoleAdjust_D(pMCTstat, pDCTstat, DQSDelay, ChipSel, &tmp)) {
- goto skipLocMiddle;
- }
-
- MutualCSPassW[DQSDelay] &= tmp;
- print_debug_dqs("\t\t\t\t\tTrainDQSPos: 146\tMutualCSPassW ", MutualCSPassW[DQSDelay], 5);
-
- SetTargetWTIO_D(TestAddr);
- FlushDQSTestPattern_D(pDCTstat, TestAddr << 8);
- ResetTargetWTIO_D();
- }
-
- }
-
- if (BanksPresent) {
- for (ByteLane = 0; ByteLane < 8; ByteLane++) {
- print_debug_dqs("\t\t\t\tTrainDQSPos: 31 ByteLane ",ByteLane, 4);
- pDCTstat->ByteLane = ByteLane;
- LastTest = DQS_FAIL; /* Analyze the results */
- RnkDlySeqPassMin = 0;
- RnkDlySeqPassMax = 0;
- RnkDlyFilterMax = 0;
- RnkDlyFilterMin = 0;
- for (DQSDelay = 0; DQSDelay < dqsDelay_end; DQSDelay++) {
- if (MutualCSPassW[DQSDelay] & (1 << ByteLane)) {
- print_debug_dqs("\t\t\t\t\tTrainDQSPos: 321 DQSDelay ", DQSDelay, 5);
- print_debug_dqs("\t\t\t\t\tTrainDQSPos: 322 MutualCSPassW ", MutualCSPassW[DQSDelay], 5);
-
- RnkDlySeqPassMax = DQSDelay;
- if (LastTest == DQS_FAIL) {
- RnkDlySeqPassMin = DQSDelay; //start sequential run
- }
- if ((RnkDlySeqPassMax - RnkDlySeqPassMin)>(RnkDlyFilterMax-RnkDlyFilterMin)) {
- RnkDlyFilterMin = RnkDlySeqPassMin;
- RnkDlyFilterMax = RnkDlySeqPassMax;
- }
- LastTest = DQS_PASS;
- } else {
- LastTest = DQS_FAIL;
- }
- }
- print_debug_dqs("\t\t\t\tTrainDQSPos: 33 RnkDlySeqPassMax ", RnkDlySeqPassMax, 4);
- if (RnkDlySeqPassMax == 0) {
- Errors |= 1 << SB_NODQSPOS; /* no passing window */
- } else {
- print_debug_dqs_pair("\t\t\t\tTrainDQSPos: 34 RnkDlyFilter: ", RnkDlyFilterMin, " ", RnkDlyFilterMax, 4);
- if (((RnkDlyFilterMax - RnkDlyFilterMin) < MIN_DQS_WNDW)) {
- Errors |= 1 << SB_SMALLDQS;
- } else {
- u8 middle_dqs;
- /* mctEngDQSwindow_Save_D Not required for arrays */
- middle_dqs = MiddleDQS_D(RnkDlyFilterMin, RnkDlyFilterMax);
- pDCTstat->DQSDelay = middle_dqs;
- mct_SetDQSDelayCSR_D(pMCTstat, pDCTstat, cs_start); /* load the register with the value */
- StoreDQSDatStrucVal_D(pMCTstat, pDCTstat, cs_start); /* store the value into the data structure */
- print_debug_dqs("\t\t\t\tTrainDQSPos: 42 middle_dqs : ",middle_dqs, 4);
- }
- }
- }
- }
-skipLocMiddle:
- pDCTstat->TrainErrors = Errors;
-
- print_debug_dqs("\t\t\tTrainDQSPos: Errors ", Errors, 3);
-
-}
-
-
-void StoreDQSDatStrucVal_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel)
-{
- /* Store the DQSDelay value, found during a training sweep, into the DCT
- * status structure for this node
- */
-
-
- /* When 400, 533, 667, it will support dimm0/1/2/3,
- * and set conf for dimm0, hw will copy to dimm1/2/3
- * set for dimm1, hw will copy to dimm3
- * Rev A/B only support DIMM0/1 when 800MHz and above + 0x100 to next dimm
- * Rev C support DIMM0/1/2/3 when 800MHz and above + 0x100 to next dimm
- */
-
- /* FindDQSDatDimmVal_D is not required since we use an array */
- u8 dn = 0;
-
- if (pDCTstat->Status & (1 << SB_Over400MHz))
- dn = ChipSel>>1; /* if odd or even logical DIMM */
-
- pDCTstat->persistentData.CH_D_DIR_B_DQS[pDCTstat->Channel][dn][pDCTstat->Direction][pDCTstat->ByteLane] =
- pDCTstat->DQSDelay;
-}
-
-
-static void GetDQSDatStrucVal_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel)
-{
- u8 dn = 0;
-
-
- /* When 400, 533, 667, it will support dimm0/1/2/3,
- * and set conf for dimm0, hw will copy to dimm1/2/3
- * set for dimm1, hw will copy to dimm3
- * Rev A/B only support DIMM0/1 when 800MHz and above + 0x100 to next dimm
- * Rev C support DIMM0/1/2/3 when 800MHz and above + 0x100 to next dimm
- */
-
- /* FindDQSDatDimmVal_D is not required since we use an array */
- if (pDCTstat->Status & (1<<SB_Over400MHz))
- dn = ChipSel >> 1; /*if odd or even logical DIMM */
-
- pDCTstat->DQSDelay =
- pDCTstat->persistentData.CH_D_DIR_B_DQS[pDCTstat->Channel][dn][pDCTstat->Direction][pDCTstat->ByteLane];
-}
-
-
-/* FindDQSDatDimmVal_D is not required since we use an array */
-
-
-static u8 MiddleDQS_D(u8 min, u8 max)
-{
- u8 size;
- size = max-min;
- if (size % 2)
- size++; // round up if the size isn't even.
- return (min + (size >> 1));
-}
-
-
-static void TrainReadDQS_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 cs_start)
-{
- print_debug_dqs("\t\tTrainReadPos ", 0, 2);
- pDCTstat->Direction = DQS_READDIR;
- TrainDQSPos_D(pMCTstat, pDCTstat, cs_start);
-}
-
-
-static void TrainWriteDQS_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 cs_start)
-{
- pDCTstat->Direction = DQS_WRITEDIR;
- print_debug_dqs("\t\tTrainWritePos", 0, 2);
- TrainDQSPos_D(pMCTstat, pDCTstat, cs_start);
-}
-
-
-void proc_IOCLFLUSH_D(u32 addr_hi)
-{
- SetTargetWTIO_D(addr_hi);
- proc_CLFLUSH(addr_hi);
- ResetTargetWTIO_D();
-}
-
-
-static u8 ChipSelPresent_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 ChipSel)
-{
- u32 val;
- u32 reg;
- u32 dev = pDCTstat->dev_dct;
- u32 reg_off;
- u8 ret = 0;
-
- if (!pDCTstat->GangedMode) {
- reg_off = 0x100 * Channel;
- } else {
- reg_off = 0;
- }
-
- if (ChipSel < MAX_CS_SUPPORTED) {
- reg = 0x40 + (ChipSel << 2) + reg_off;
- val = Get_NB32(dev, reg);
- if (val & (1 << 0))
- ret = 1;
- }
-
- return ret;
-}
-
-
-/* proc_CLFLUSH_D located in mct_gcc.h */
-
-
-static void WriteDQSTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo)
-{
- /* Write a pattern of 72 bit times (per DQ), to test dram functionality.
- * The pattern is a stress pattern which exercises both ISI and
- * crosstalk. The number of cache lines to fill is dependent on DCT
- * width mode and burstlength.
- * Mode BL Lines Pattern no.
- * ----+---+-------------------
- * 64 4 9 0
- * 64 8 9 0
- * 64M 4 9 0
- * 64M 8 9 0
- * 128 4 18 1
- * 128 8 N/A -
- */
-
- if (pDCTstat->Pattern == 0)
- WriteL9TestPattern_D(pDCTstat, TestAddr_lo);
- else
- WriteL18TestPattern_D(pDCTstat, TestAddr_lo);
-}
-
-
-static void WriteL18TestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo)
-{
- u8 *buf;
-
- buf = (u8 *)pDCTstat->PtrPatternBufA;
- WriteLNTestPattern(TestAddr_lo, buf, 18);
-
-}
-
-
-static void WriteL9TestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo)
-{
- u8 *buf;
-
- buf = (u8 *)pDCTstat->PtrPatternBufA;
- WriteLNTestPattern(TestAddr_lo, buf, 9);
-}
-
-
-
-static u8 CompareDQSTestPattern_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u32 addr_lo)
-{
- /* Compare a pattern of 72 bit times (per DQ), to test dram functionality.
- * The pattern is a stress pattern which exercises both ISI and
- * crosstalk. The number of cache lines to fill is dependent on DCT
- * width mode and burstlength.
- * Mode BL Lines Pattern no.
- * ----+---+-------------------
- * 64 4 9 0
- * 64 8 9 0
- * 64M 4 9 0
- * 64M 8 9 0
- * 128 4 18 1
- * 128 8 N/A -
- */
-
- u32 *test_buf;
- u8 bitmap;
- u8 bytelane;
- u8 i;
- u32 value;
- u8 j;
- u32 value_test;
- u8 pattern, channel;
-
- pattern = pDCTstat->Pattern;
- channel = pDCTstat->Channel;
- test_buf = (u32 *)pDCTstat->PtrPatternBufA;
-
- if (pattern && channel) {
- addr_lo += 8; //second channel
- test_buf += 2;
- }
-
- bytelane = 0; /* bytelane counter */
- bitmap = 0xFF; /* bytelane test bitmap, 1 = pass */
- for (i = 0; i < (9 * 64 / 4); i++) { /* sizeof testpattern. /4 due to next loop */
- value = read32_fs(addr_lo);
- value_test = *test_buf;
-
- print_debug_dqs_pair("\t\t\t\t\t\ttest_buf = ", (u32)test_buf, " value = ", value_test, 7);
- print_debug_dqs_pair("\t\t\t\t\t\ttaddr_lo = ", addr_lo, " value = ", value, 7);
-
- for (j = 0; j < (4 * 8); j += 8) { /* go through a 32bit data, on 1 byte step. */
- if (((value >> j) & 0xff) != ((value_test >> j) & 0xff)) {
- bitmap &= ~(1 << bytelane);
- }
-
- bytelane++;
- bytelane &= 0x7;
- }
-
- print_debug_dqs("\t\t\t\t\t\tbitmap = ", bitmap, 7);
-
- if (!bitmap)
- break;
-
- if (bytelane == 0) {
- if (pattern == 1) { //dual channel
- addr_lo += 8; //skip over other channel's data
- test_buf += 2;
- }
- }
- addr_lo += 4;
- test_buf += 1;
- }
-
- return bitmap;
-}
-
-
-static void FlushDQSTestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 addr_lo)
-{
- /* Flush functions in mct_gcc.h */
- if (pDCTstat->Pattern == 0) {
- FlushDQSTestPattern_L9(addr_lo);
- } else {
- FlushDQSTestPattern_L18(addr_lo);
- }
-}
-
-void SetTargetWTIO_D(u32 TestAddr)
-{
- u32 lo, hi;
- hi = TestAddr >> 24;
- lo = TestAddr << 8;
- _WRMSR(MTRR_IORR0_BASE, lo, hi); /* IORR0 Base */
- hi = 0xFF;
- lo = 0xFC000800; /* 64MB Mask */
- _WRMSR(MTRR_IORR0_MASK, lo, hi); /* IORR0 Mask */
-}
-
-
-void ResetTargetWTIO_D(void)
-{
- u32 lo, hi;
-
- hi = 0;
- lo = 0;
- _WRMSR(MTRR_IORR0_MASK, lo, hi); // IORR0 Mask
-}
-
-
-static void ReadDQSTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo)
-{
- /* Read a pattern of 72 bit times (per DQ), to test dram functionality.
- * The pattern is a stress pattern which exercises both ISI and
- * crosstalk. The number of cache lines to fill is dependent on DCT
- * width mode and burstlength.
- * Mode BL Lines Pattern no.
- * ----+---+-------------------
- * 64 4 9 0
- * 64 8 9 0
- * 64M 4 9 0
- * 64M 8 9 0
- * 128 4 18 1
- * 128 8 N/A -
- */
- if (pDCTstat->Pattern == 0)
- ReadL9TestPattern(TestAddr_lo);
- else
- ReadL18TestPattern(TestAddr_lo);
- _MFENCE;
-}
-
-
-u32 SetUpperFSbase(u32 addr_hi)
-{
- /* Set the upper 32-bits of the Base address, 4GB aligned) for the
- * FS selector.
- */
-
- u32 lo, hi;
- u32 addr;
- lo = 0;
- hi = addr_hi>>24;
- addr = FS_Base;
- _WRMSR(addr, lo, hi);
- return addr_hi << 8;
-}
-
-
-void ResetDCTWrPtr_D(u32 dev, u32 index_reg, u32 index)
-{
- u32 val;
-
- val = Get_NB32_index_wait(dev, index_reg, index);
- Set_NB32_index_wait(dev, index_reg, index, val);
-}
-
-
-/* mctEngDQSwindow_Save_D not required with arrays */
-
-
-void mct_TrainDQSPos_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u8 ChipSel;
- struct DCTStatStruc *pDCTstat;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
- if (pDCTstat->DCTSysLimit) {
- /* when DCT speed >= 400MHz, we only support 2 DIMMs
- * and we have two sets registers for DIMM0 and DIMM1 so
- * here we must traning DQSRd/WrPos for DIMM0 and DIMM1
- */
- if (pDCTstat->Speed >= 4) {
- pDCTstat->Status |= (1 << SB_Over400MHz);
- }
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel += 2) {
- TrainDQSRdWrPos_D(pMCTstat, pDCTstat, ChipSel);
- SetEccDQSRdWrPos_D(pMCTstat, pDCTstat, ChipSel);
- }
- }
- }
-}
-
-
-/* mct_BeforeTrainDQSRdWrPos_D
- * Function is inline.
- */
-
-u8 mct_DisableDimmEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 _DisableDramECC = 0;
- u32 val;
- u32 reg;
- u32 dev;
-
- /*Disable ECC correction of reads on the dram bus. */
-
- dev = pDCTstat->dev_dct;
- reg = 0x90;
- val = Get_NB32(dev, reg);
- if (val & (1<<DimmEcEn)) {
- _DisableDramECC |= 0x01;
- val &= ~(1<<DimmEcEn);
- Set_NB32(dev, reg, val);
- }
- if (!pDCTstat->GangedMode) {
- reg = 0x190;
- val = Get_NB32(dev, reg);
- if (val & (1<<DimmEcEn)) {
- _DisableDramECC |= 0x02;
- val &= ~(1<<DimmEcEn);
- Set_NB32(dev, reg, val);
- }
- }
- return _DisableDramECC;
-}
-
-
-
-void mct_EnableDimmEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 _DisableDramECC)
-{
-
- u32 val;
- u32 reg;
- u32 dev;
-
- /* Enable ECC correction if it was previously disabled */
-
- dev = pDCTstat->dev_dct;
-
- if ((_DisableDramECC & 0x01) == 0x01) {
- reg = 0x90;
- val = Get_NB32(dev, reg);
- val |= (1<<DimmEcEn);
- Set_NB32(dev, reg, val);
- }
- if ((_DisableDramECC & 0x02) == 0x02) {
- reg = 0x190;
- val = Get_NB32(dev, reg);
- val |= (1<<DimmEcEn);
- Set_NB32(dev, reg, val);
- }
-}
-
-
-static void mct_SetDQSDelayCSR_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel)
-{
- u8 ByteLane;
- u32 val;
- u32 index_reg = 0x98 + 0x100 * pDCTstat->Channel;
- u8 shift;
- u32 dqs_delay = (u32)pDCTstat->DQSDelay;
- u32 dev = pDCTstat->dev_dct;
- u32 index;
-
- ByteLane = pDCTstat->ByteLane;
-
- /* Channel is offset */
- if (ByteLane < 4) {
- index = 1;
- } else if (ByteLane <8) {
- index = 2;
- } else {
- index = 3;
- }
-
- if (pDCTstat->Direction == DQS_READDIR) {
- index += 4;
- }
-
- /* get the proper register index */
- shift = ByteLane % 4;
- shift <<= 3; /* get bit position of bytelane, 8 bit */
-
- if (pDCTstat->Status & (1 << SB_Over400MHz)) {
- index += (ChipSel >> 1) * 0x100; /* if logical DIMM1/DIMM3 */
- }
-
- val = Get_NB32_index_wait(dev, index_reg, index);
- val &= ~(0x7f << shift);
- val |= (dqs_delay << shift);
- Set_NB32_index_wait(dev, index_reg, index, val);
-}
-
-
-static void mct_SetDQSDelayAllCSR_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 cs_start)
-{
- u8 ByteLane;
- u8 ChipSel = cs_start;
-
-
- for (ChipSel = cs_start; ChipSel < (cs_start + 2); ChipSel++) {
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, pDCTstat->Channel, ChipSel)) {
- for (ByteLane = 0; ByteLane < 8; ByteLane++) {
- pDCTstat->ByteLane = ByteLane;
- mct_SetDQSDelayCSR_D(pMCTstat, pDCTstat, ChipSel);
- }
- }
- }
-}
-
-
-u8 mct_RcvrRankEnabled_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 ChipSel)
-{
- u8 ret;
-
- ret = ChipSelPresent_D(pMCTstat, pDCTstat, Channel, ChipSel);
- return ret;
-}
-
-
-u32 mct_GetRcvrSysAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 channel, u8 receiver, u8 *valid)
-{
- return mct_GetMCTSysAddr_D(pMCTstat, pDCTstat, channel, receiver, valid);
-}
-
-
-u32 mct_GetMCTSysAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 receiver, u8 *valid)
-{
- u32 val;
- u32 reg_off = 0;
- u32 reg;
- u32 dword;
- u32 dev = pDCTstat->dev_dct;
-
- *valid = 0;
-
-
- if (!pDCTstat->GangedMode) {
- reg_off = 0x100 * Channel;
- }
-
- /* get the local base addr of the chipselect */
- reg = 0x40 + (receiver << 2) + reg_off;
- val = Get_NB32(dev, reg);
-
- val &= ~0x0F;
-
- /* unganged mode DCT0+DCT1, sys addr of DCT1 = node
- * base+DctSelBaseAddr+local ca base*/
- if ((Channel) && (pDCTstat->GangedMode == 0) && (pDCTstat->DIMMValidDCT[0] > 0)) {
- reg = 0x110;
- dword = Get_NB32(dev, reg);
- dword &= 0xfffff800;
- dword <<= 8; /* scale [47:27] of F2x110[31:11] to [39:8]*/
- val += dword;
-
- /* if DCTSelBaseAddr < Hole, and eax > HoleBase, then add Hole size to test address */
- if ((val >= pDCTstat->DCTHoleBase) && (pDCTstat->DCTHoleBase > dword)) {
- dword = (~(pDCTstat->DCTHoleBase >> (24 - 8)) + 1) & 0xFF;
- dword <<= (24 - 8);
- val += dword;
- }
- } else {
- /* sys addr = node base+local cs base */
- val += pDCTstat->DCTSysBase;
-
- /* New stuff */
- if (pDCTstat->DCTHoleBase && (val >= pDCTstat->DCTHoleBase)) {
- val -= pDCTstat->DCTSysBase;
- dword = Get_NB32(pDCTstat->dev_map, 0xF0); /* get Hole Offset */
- val += (dword & 0x0000ff00) << (24-8-8);
- }
- }
-
- /* New stuff */
- val += ((1 << 21) >> 8); /* Add 2MB offset to avoid compat area */
- if (val >= MCT_TRNG_KEEPOUT_START) {
- while (val < MCT_TRNG_KEEPOUT_END)
- val += (1 << (15-8)); /* add 32K */
- }
-
- /* Add a node seed */
- val += (((1 * pDCTstat->Node_ID) << 20) >> 8); /* Add 1MB per node to avoid aliases */
-
- /* HW remap disabled? */
- if (!(pDCTstat->Status & (1 << SB_HWHole))) {
- if (!(pDCTstat->Status & (1 << SB_SWNodeHole))) {
- /* SW memhole disabled */
- u32 lo, hi;
- _RDMSR(TOP_MEM, &lo, &hi);
- lo >>= 8;
- if ((val >= lo) && (val < _4GB_RJ8)) {
- val = 0;
- *valid = 0;
- goto exitGetAddr;
- } else {
- *valid = 1;
- goto exitGetAddrWNoError;
- }
- } else {
- *valid = 1;
- goto exitGetAddrWNoError;
- }
- } else {
- *valid = 1;
- goto exitGetAddrWNoError;
- }
-
-exitGetAddrWNoError:
-
- /* Skip if Address is in UMA region */
- dword = pMCTstat->Sub4GCacheTop;
- dword >>= 8;
- if (dword != 0) {
- if ((val >= dword) && (val < _4GB_RJ8)) {
- val = 0;
- *valid = 0;
- } else {
- *valid = 1;
- }
- }
- print_debug_dqs("mct_GetMCTSysAddr_D: receiver ", receiver, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: Channel ", Channel, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: base_addr ", val, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: valid ", *valid, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: status ", pDCTstat->Status, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: HoleBase ", pDCTstat->DCTHoleBase, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: Cachetop ", pMCTstat->Sub4GCacheTop, 2);
-
-exitGetAddr:
- return val;
-}
-
-
-void mct_Write1LTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr, u8 pattern)
-{
-
- u8 *buf;
-
- /* Issue the stream of writes. When F2x11C[MctWrLimit] is reached
- * (or when F2x11C[FlushWr] is set again), all the writes are written
- * to DRAM.
- */
-
- SetUpperFSbase(TestAddr);
-
- if (pattern)
- buf = (u8 *)pDCTstat->PtrPatternBufB;
- else
- buf = (u8 *)pDCTstat->PtrPatternBufA;
-
- WriteLNTestPattern(TestAddr << 8, buf, 1);
-}
-
-
-void mct_Read1LTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 addr)
-{
- /* BIOS issues the remaining (Ntrain - 2) reads after checking that
- * F2x11C[PrefDramTrainMode] is cleared. These reads must be to
- * consecutive cache lines (i.e., 64 bytes apart) and must not cross
- * a naturally aligned 4KB boundary. These reads hit the prefetches and
- * read the data from the prefetch buffer.
- */
-
- /* get data from DIMM */
- SetUpperFSbase(addr);
-
- /* 1st move causes read fill (to exclusive or shared)*/
- read32_fs(addr << 8);
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctecc_d.c b/src/northbridge/amd/amdmct/mct/mctecc_d.c
deleted file mode 100644
index 8eb7bf54b7..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctecc_d.c
+++ /dev/null
@@ -1,314 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-
-#include "mct_d.h"
-
-static void setSyncOnUnEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-#ifdef UNUSED_CODE
-static u32 GetScrubAddr_D(u32 Node);
-#endif
-static u8 isDramECCEn_D(struct DCTStatStruc *pDCTstat);
-
-
-/* Initialize ECC modes of Integrated Dram+Memory Controllers of a network of
- * Hammer processors. Use Dram background scrubber to fast initialize ECC bits
- * of all dram.
- *
- * Notes:
- *
- * Order that items are set:
- * 1. eccen bit in NB
- * 2. Scrub Base
- * 3. Temp Node Base
- * 4. Temp Node Limit
- * 5. Redir bit in NB
- * 6. Scrub CTL
- *
- * Conditions for setting background scrubber.
- * 1. node is present
- * 2. node has dram functioning (WE = RE = 1)
- * 3. all eccdimms (or bit 17 of offset 90,fn 2)
- * 4. no chip-select gap exists
- *
- * The dram background scrubber is used under very controlled circumstances to
- * initialize all the ECC bits on the DIMMs of the entire dram address map
- * (including hidden or lost dram and dram above 4GB). We will turn the scrub
- * rate up to maximum, which should clear 4GB of dram in about 2.7 seconds.
- * We will activate the scrubbers of all nodes with ecc dram and let them run in
- * parallel, thereby reducing even further the time required to condition dram.
- * Finally, we will go through each node and either disable background scrubber,
- * or set the scrub rate to the user setup specified rate.
- *
- * To allow the NB to scrub, we need to wait a time period long enough to
- * guarantee that the NB scrubs the entire dram on its node. Do do this, we
- * simply sample the scrub ADDR once, for an initial value, then we sample and poll until the polled value of scrub ADDR
- * has wrapped around at least once: Scrub ADDRi+1 < Scrub ADDRi. Since we let all
- * Nodes run in parallel, we need to guarantee that all nodes have wrapped. To do
- * this efficiently, we need only to sample one of the nodes, the node with the
- * largest ammount of dram populated is the one which will take the longest amount
- * of time (the scrub rate is set to max, the same rate, on all nodes). So,
- * during setup of scrub Base, we determine how much memory and which node has
- * the largest memory installed.
- *
- * Scrubbing should not ordinarily be enabled on a Node with a chip-select gap
- * (aka SW memhole, cs hoisting, etc..).To init ECC memory on this node, the
- * scrubber is used in two steps. First, the Dram Limit for the node is adjusted
- * down to the bottom of the gap, and that ECC dram is initialized. Second, the
- * original Limit is restored, the Scrub base is set to 4GB, and scrubber is
- * allowed to run until the Scrub Addr wraps around to zero.
- */
-u8 ECCInit_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u8 AllECC;
- u16 OB_NBECC;
- u32 curBase;
- u16 OB_ECCRedir;
- u32 LDramECC;
- u32 OF_ScrubCTL;
- u8 MemClrECC;
-
- u32 dev;
- u32 reg;
- u32 val;
- u16 nvbits;
-
- mctHookBeforeECC();
-
- /* Construct these booleans, based on setup options, for easy handling
- later in this procedure */
- OB_NBECC = mctGet_NVbits(NV_NBECC); /* MCA ECC (MCE) enable bit */
-
- OB_ECCRedir = mctGet_NVbits(NV_ECCRedir); /* ECC Redirection */
-
- mctGet_NVbits(NV_ChipKill); /* ECC Chip-kill mode */
-
- OF_ScrubCTL = 0; /* Scrub CTL for Dcache, L2, and dram */
- nvbits = mctGet_NVbits(NV_DCBKScrub);
- mct_AdjustScrub_D(pDCTstatA, &nvbits);
- OF_ScrubCTL |= (u32) nvbits << 16;
-
- nvbits = mctGet_NVbits(NV_L2BKScrub);
- OF_ScrubCTL |= (u32) nvbits << 8;
-
- nvbits = mctGet_NVbits(NV_DramBKScrub);
- OF_ScrubCTL |= nvbits;
-
- AllECC = 1;
- MemClrECC = 0;
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- LDramECC = 0;
- if (NodePresent_D(Node)) { /*If Node is present */
- dev = pDCTstat->dev_map;
- reg = 0x40+(Node << 3); /* Dram Base Node 0 + index */
- val = Get_NB32(dev, reg);
-
- /* WE/RE is checked */
- if ((val & 3) == 3) { /* Node has dram populated */
- /* Negate 'all nodes/dimms ECC' flag if non ecc
- memory populated */
- if (pDCTstat->Status & (1 << SB_ECCDIMMs)) {
- LDramECC = isDramECCEn_D(pDCTstat);
- if (pDCTstat->ErrCode != SC_RunningOK) {
- pDCTstat->Status &= ~(1 << SB_ECCDIMMs);
- if (!OB_NBECC) {
- pDCTstat->ErrStatus |= (1 << SB_DramECCDis);
- }
- AllECC = 0;
- LDramECC =0;
- }
- } else {
- AllECC = 0;
- }
- if (LDramECC) { /* if ECC is enabled on this dram */
- if (OB_NBECC) {
- mct_EnableDatIntlv_D(pMCTstat, pDCTstat);
- dev = pDCTstat->dev_nbmisc;
- reg =0x44; /* MCA NB Configuration */
- val = Get_NB32(dev, reg);
- val |= 1 << 22; /* EccEn */
- Set_NB32(dev, reg, val);
- DCTMemClr_Init_D(pMCTstat, pDCTstat);
- MemClrECC = 1;
- print_tx(" ECC enabled on node: ", Node);
- }
- } /* this node has ECC enabled dram */
- } else {
- LDramECC = 0;
- } /* Node has Dram */
-
- if (MemClrECC) {
- MCTMemClrSync_D(pMCTstat, pDCTstatA);
- }
- } /* if Node present */
- }
-
- if (AllECC)
- pMCTstat->GStatus |= 1 << GSB_ECCDIMMs;
- else
- pMCTstat->GStatus &= ~(1 << GSB_ECCDIMMs);
-
- /* Program the Dram BKScrub CTL to the proper (user selected) value.*/
- /* Reset MC4_STS. */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- LDramECC = 0;
- if (NodePresent_D(Node)) { /* If Node is present */
- reg = 0x40+(Node << 3); /* Dram Base Node 0 + index */
- val = Get_NB32(pDCTstat->dev_map, reg);
- curBase = val & 0xffff0000;
- /*WE/RE is checked because memory config may have been */
- if ((val & 3) == 3) { /* Node has dram populated */
- if (isDramECCEn_D(pDCTstat)) { /* if ECC is enabled on this dram */
- dev = pDCTstat->dev_nbmisc;
- val = curBase << 8;
- if (OB_ECCRedir) {
- val |= (1<<0); /* enable redirection */
- }
- Set_NB32(dev, 0x5C, val); /* Dram Scrub Addr Low */
- val = curBase >> 24;
- Set_NB32(dev, 0x60, val); /* Dram Scrub Addr High */
- Set_NB32(dev, 0x58, OF_ScrubCTL); /*Scrub Control */
-
- /* Divisor should not be set deeper than
- * divide by 16 when Dcache scrubber or
- * L2 scrubber is enabled.
- */
- if ((OF_ScrubCTL & (0x1F << 16)) || (OF_ScrubCTL & (0x1F << 8))) {
- val = Get_NB32(dev, 0x84);
- if ((val & 0xE0000000) > 0x80000000) { /* Get F3x84h[31:29]ClkDivisor for C1 */
- val &= 0x1FFFFFFF; /* If ClkDivisor is deeper than divide-by-16 */
- val |= 0x80000000; /* set it to divide-by-16 */
- Set_NB32(dev, 0x84, val);
- }
- }
- } /* this node has ECC enabled dram */
- } /*Node has Dram */
- } /*if Node present */
- }
-
- if (mctGet_NVbits(NV_SyncOnUnEccEn))
- setSyncOnUnEccEn_D(pMCTstat, pDCTstatA);
-
- mctHookAfterECC();
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (NodePresent_D(Node)) {
- print_tx("ECCInit: Node ", Node);
- print_tx("ECCInit: Status ", pDCTstat->Status);
- print_tx("ECCInit: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("ECCInit: ErrCode ", pDCTstat->ErrCode);
- print_t("ECCInit: Done\n");
- }
- }
- return MemClrECC;
-}
-
-
-static void setSyncOnUnEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u32 Node;
- u32 reg;
- u32 dev;
- u32 val;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (NodePresent_D(Node)) { /* If Node is present*/
- reg = 0x40+(Node << 3); /* Dram Base Node 0 + index*/
- val = Get_NB32(pDCTstat->dev_map, reg);
- /*WE/RE is checked because memory config may have been*/
- if ((val & 3) == 3) { /* Node has dram populated*/
- if (isDramECCEn_D(pDCTstat)) {
- /*if ECC is enabled on this dram*/
- dev = pDCTstat->dev_nbmisc;
- reg = 0x44; /* MCA NB Configuration*/
- val = Get_NB32(dev, reg);
- val |= (1 << SyncOnUcEccEn);
- Set_NB32(dev, reg, val);
- }
- } /* Node has Dram*/
- } /* if Node present*/
- }
-}
-
-#ifdef UNUSED_CODE
-static u32 GetScrubAddr_D(u32 Node)
-{
- /* Get the current 40-bit Scrub ADDR address, scaled to 32-bits,
- * of the specified Node.
- */
-
- u32 reg;
- u32 regx;
- u32 lo, hi;
- u32 val;
- u32 dev = PA_NBMISC(Node);
-
-
- reg = 0x60; /* Scrub Addr High */
- hi = Get_NB32(dev, reg);
-
- regx = 0x5C; /* Scrub Addr Low */
- lo = Get_NB32(dev, regx);
- /* Scrub Addr High again, detect 32-bit wrap */
- val = Get_NB32(dev, reg);
- if (val != hi) {
- hi = val; /* Scrub Addr Low again, if wrap occurred */
- lo = Get_NB32(dev, regx);
- }
-
- val = hi << 24;
- val |= lo >> 8;
-
- return val; /* ScrubAddr[39:8] */
-}
-#endif
-
-static u8 isDramECCEn_D(struct DCTStatStruc *pDCTstat)
-{
- u32 reg;
- u32 val;
- u8 i;
- u32 dev = pDCTstat->dev_dct;
- u8 ch_end;
- u8 isDimmECCEn = 0;
-
- if (pDCTstat->GangedMode) {
- ch_end = 1;
- } else {
- ch_end = 2;
- }
- for (i = 0; i < ch_end; i++) {
- if (pDCTstat->DIMMValidDCT[i] > 0) {
- reg = 0x90 + i * 0x100; /* Dram Config Low */
- val = Get_NB32(dev, reg);
- if (val & (1 << DimmEcEn)) {
- /* set local flag 'dram ecc capable' */
- isDimmECCEn = 1;
- break;
- }
- }
- }
- return isDimmECCEn;
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctgr.c b/src/northbridge/amd/amdmct/mct/mctgr.c
deleted file mode 100644
index 41a479b21e..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctgr.c
+++ /dev/null
@@ -1,84 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-
-static const u8 Tab_GRCLKDis[] = { 8,0,8,8,0,0,8,0 };
-
-
-u32 mct_AdjustMemClkDis_GR(struct DCTStatStruc *pDCTstat, u32 dct,
- u32 DramTimingLo)
-{
- /* Greayhound format -> Griffin format */
- u32 NewDramTimingLo;
- u32 dev = pDCTstat->dev_dct;
- u32 reg;
- u32 reg_off = 0x100 * dct;
- u32 val;
- int i;
-
- DramTimingLo = val;
- /* Dram Timing Low (owns Clock Enable bits) */
- NewDramTimingLo = Get_NB32(dev, 0x88 + reg_off);
- if (mctGet_NVbits(NV_AllMemClks) == 0) {
- /*Special Jedec SPD diagnostic bit - "enable all clocks"*/
- if (!(pDCTstat->Status & (1<<SB_DiagClks))) {
- for (i = 0; i < MAX_DIMMS_SUPPORTED; i++) {
- val = Tab_GRCLKDis[i];
- if (val < 8) {
- if (!(pDCTstat->DIMMValidDCT[dct] & (1<<val))) {
- /* disable memclk */
- NewDramTimingLo |= (1<<(i+1));
- }
- }
- }
- }
- }
- DramTimingLo &= ~(0xff<<24);
- DramTimingLo |= NewDramTimingLo & (0xff<<24);
- DramTimingLo &= (0x4d<<24); /* FIXME - enable all MemClks for now */
-
- return DramTimingLo;
-}
-
-
-u32 mct_AdjustDramConfigLo_GR(struct DCTStatStruc *pDCTstat, u32 dct, u32 val)
-{
- /* Greayhound format -> Griffin format */
- /*FIXME - BurstLength32 must be 0 when F3x44[DramEccEn]=1. */
-/*
- ; mov cx,PA_NBMISC+44h ;MCA NB Configuration
- ; call Get_NB32n_D
- ; bt eax,22 ;EccEn
- ; .if (CARRY?)
- ; btr eax,BurstLength32
- ; .endif
-*/
- return val;
-}
-
-
-void mct_AdjustMemHoist_GR(struct DCTStatStruc *pDCTstat, u32 base, u32 HoleSize)
-{
- u32 val;
- if (base >= pDCTstat->DCTHoleBase) {
- u32 dev = pDCTstat->dev_dct;
- base += HoleSize;
- base >>= 27 - 8;
- val = Get_NB32(dev, 0x110);
- val &= ~(0xfff<<11);
- val |= (base & 0xfff)<<11;
- Set_NB32(dev, 0x110, val);
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct/mcthdi.c b/src/northbridge/amd/amdmct/mct/mcthdi.c
deleted file mode 100644
index b67282ef60..0000000000
--- a/src/northbridge/amd/amdmct/mct/mcthdi.c
+++ /dev/null
@@ -1,30 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "mct_d.h"
-
-void mct_DramInit_Hw_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 reg;
- u32 dev = pDCTstat->dev_dct;
-
- /*flag for selecting HW/SW DRAM Init HW DRAM Init */
- reg = 0x90 + 0x100 * dct; /*DRAM Configuration Low */
- val = Get_NB32(dev, reg);
- val |= (1<<InitDram);
- Set_NB32(dev, reg, val);
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctmtr_d.c b/src/northbridge/amd/amdmct/mct/mctmtr_d.c
deleted file mode 100644
index 883ab651cc..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctmtr_d.c
+++ /dev/null
@@ -1,254 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "mct_d.h"
-#include <cpu/amd/mtrr.h>
-#include <cpu/x86/mtrr.h>
-
-static void SetMTRRrangeWB_D(u32 Base, u32 *pLimit, u32 *pMtrrAddr);
-static void SetMTRRrange_D(u32 Base, u32 *pLimit, u32 *pMtrrAddr, u16 MtrrType);
-
-void CPUMemTyping_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /* BSP only. Set the fixed MTRRs for common legacy ranges.
- * Set TOP_MEM and TOM2.
- * Set some variable MTRRs with WB Uncacheable type.
- */
-
- u32 Bottom32bIO, Bottom40bIO, Cache32bTOP;
- u32 val;
- u32 addr;
- u32 lo, hi;
-
- /* Set temporary top of memory from Node structure data.
- * Adjust temp top of memory down to accommodate 32-bit IO space.
- * Bottom40bIO = top of memory, right justified 8 bits
- * (defines dram versus IO space type)
- * Bottom32bIO = sub 4GB top of memory, right justified 8 bits
- * (defines dram versus IO space type)
- * Cache32bTOP = sub 4GB top of WB cacheable memory,
- * right justified 8 bits
- */
-
- val = mctGet_NVbits(NV_BottomIO);
- if (val == 0)
- val++;
-
- Bottom32bIO = val << (24-8);
-
- val = pMCTstat->SysLimit + 1;
- if (val <= _4GB_RJ8) {
- Bottom40bIO = 0;
- if (Bottom32bIO >= val)
- Bottom32bIO = val;
- } else {
- Bottom40bIO = val;
- }
-
- Cache32bTOP = Bottom32bIO;
-
- /*======================================================================
- Set default values for CPU registers
- ======================================================================*/
-
- /* NOTE : For coreboot, we don't need to set mtrr enables here because
- they are still enable from cache_as_ram.inc */
-
- addr = MTRR_FIX_64K_00000;
- lo = 0x1E1E1E1E;
- hi = lo;
- _WRMSR(addr, lo, hi); /* 0 - 512K = WB Mem */
- addr = MTRR_FIX_16K_80000;
- _WRMSR(addr, lo, hi); /* 512K - 640K = WB Mem */
-
- /*======================================================================
- Set variable MTRR values
- ======================================================================*/
- /* NOTE: for coreboot change from 0x200 to 0x204: coreboot is using
- 0x200, 0x201 for [1M, CONFIG_TOP_MEM)
- 0x202, 0x203 for ROM Caching
- */
- addr = MTRR_PHYS_BASE(2); /* MTRR phys base 2*/
- /* use TOP_MEM as limit*/
- /* Limit = TOP_MEM|TOM2*/
- /* Base = 0*/
- print_tx("\t CPUMemTyping: Cache32bTOP:", Cache32bTOP);
- SetMTRRrangeWB_D(0, &Cache32bTOP, &addr);
- /* Base */
- /* Limit */
- /* MtrrAddr */
- if (addr == -1) /* ran out of MTRRs?*/
- pMCTstat->GStatus |= 1<<GSB_MTRRshort;
-
- pMCTstat->Sub4GCacheTop = Cache32bTOP<<8;
-
- /*======================================================================
- Set TOP_MEM and TOM2 CPU registers
- ======================================================================*/
- addr = TOP_MEM;
- lo = Bottom32bIO<<8;
- hi = Bottom32bIO>>24;
- _WRMSR(addr, lo, hi);
- print_tx("\t CPUMemTyping: Bottom32bIO:", Bottom32bIO);
- print_tx("\t CPUMemTyping: Bottom40bIO:", Bottom40bIO);
- if (Bottom40bIO) {
- hi = Bottom40bIO >> 24;
- lo = Bottom40bIO << 8;
- if (mctSetNodeBoundary_D())
- lo &= 0xC0000000;
- addr += 3; /* TOM2 */
- _WRMSR(addr, lo, hi);
- }
- addr = SYSCFG_MSR; /* SYS_CFG */
- _RDMSR(addr, &lo, &hi);
- if (Bottom40bIO) {
- lo |= SYSCFG_MSR_TOM2En; /* MtrrTom2En = 1 */
- lo |= SYSCFG_MSR_TOM2WB; /* Tom2ForceMemTypeWB */
- } else {
- lo &= ~SYSCFG_MSR_TOM2En; /* MtrrTom2En = 0 */
- lo &= ~SYSCFG_MSR_TOM2WB; /* Tom2ForceMemTypeWB */
- }
- _WRMSR(addr, lo, hi);
-}
-
-
-static void SetMTRRrangeWB_D(u32 Base, u32 *pLimit, u32 *pMtrrAddr)
-{
- /*set WB type*/
- SetMTRRrange_D(Base, pLimit, pMtrrAddr, 6);
-}
-
-
-static void SetMTRRrange_D(u32 Base, u32 *pLimit, u32 *pMtrrAddr, u16 MtrrType)
-{
- /* Program MTRRs to describe given range as given cache type.
- * Use MTRR pairs starting with the given MTRRphys Base address,
- * and use as many as is required up to (excluding) MSR 020C, which
- * is reserved for OS.
- *
- * "Limit" in the context of this procedure is not the numerically
- * correct limit, but rather the Last address+1, for purposes of coding
- * efficiency and readability. Size of a region is then Limit-Base.
- *
- * 1. Size of each range must be a power of two
- * 2. Each range must be naturally aligned (Base is same as size)
- *
- * There are two code paths: the ascending path and descending path
- * (analogous to bsf and bsr), where the next limit is a function of the
- * next set bit in a forward or backward sequence of bits (as a function
- * of the Limit). We start with the ascending path, to ensure that
- * regions are naturally aligned, then we switch to the descending path
- * to maximize MTRR usage efficiency. Base = 0 is a special case where we
- * start with the descending path. Correct Mask for region is
- * 2comp(Size-1)-1, which is 2comp(Limit-Base-1)-1
- */
-
- u32 curBase, curLimit, curSize;
- u32 val, valx;
- u32 addr;
-
- val = curBase = Base;
- curLimit = *pLimit;
- addr = *pMtrrAddr;
- while ((addr >= 0x200) && (addr < 0x20C) && (val < *pLimit)) {
- /* start with "ascending" code path */
- /* alignment (largest block size)*/
- valx = 1 << bsf(curBase);
- curSize = valx;
-
- /* largest legal limit, given current non-zero range Base*/
- valx += curBase;
- if ((curBase == 0) || (*pLimit < valx)) {
- /* flop direction to "descending" code path*/
- valx = 1<<bsr(*pLimit - curBase);
- curSize = valx;
- valx += curBase;
- }
- curLimit = valx; /*eax = curBase, edx = curLimit*/
- valx = val>>24;
- val <<= 8;
-
- /* now program the MTRR */
- val |= MtrrType; /* set cache type (UC or WB)*/
- _WRMSR(addr, val, valx); /* prog. MTRR with current region Base*/
- val = ((~(curSize - 1))+1) - 1; /* Size-1*/ /*Mask = 2comp(Size-1)-1*/
- valx = (val >> 24) | (0xff00); /* GH have 48 bits addr */
- val <<= 8;
- val |= (1 << 11); /* set MTRR valid*/
- addr++;
- _WRMSR(addr, val, valx); /* prog. MTRR with current region Mask*/
- val = curLimit;
- curBase = val; /* next Base = current Limit (loop exit)*/
- addr++; /* next MTRR pair addr */
- }
- if (val < *pLimit) {
- *pLimit = val;
- addr = -1;
- }
- *pMtrrAddr = addr;
-}
-
-void UMAMemTyping_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA)
-{
-/* UMA memory size may need splitting the MTRR configuration into two
- Before training use NB_BottomIO or the physical memory size to set the MTRRs.
- After training, add UMAMemTyping function to reconfigure the MTRRs based on
- NV_BottomUMA (for UMA systems only).
- This two-step process allows all memory to be cached for training
-*/
- u32 Bottom32bIO, Cache32bTOP;
- u32 val;
- u32 addr;
- u32 lo, hi;
-
- /*======================================================================
- * Adjust temp top of memory down to accommodate UMA memory start
- *======================================================================*/
- /* Bottom32bIO = sub 4GB top of memory, right justified 8 bits
- * (defines dram versus IO space type)
- * Cache32bTOP = sub 4GB top of WB cacheable memory, right justified 8 bits */
-
- Bottom32bIO = pMCTstat->Sub4GCacheTop >> 8;
-
- val = mctGet_NVbits(NV_BottomUMA);
- if (val == 0)
- val++;
-
- val <<= (24-8);
- if (val < Bottom32bIO) {
- Cache32bTOP = val;
- pMCTstat->Sub4GCacheTop = val;
-
- /*======================================================================
- * Clear variable MTRR values
- *======================================================================*/
- addr = MTRR_PHYS_BASE(0);
- lo = 0;
- hi = lo;
- while (addr < MTRR_PHYS_BASE(6)) {
- _WRMSR(addr, lo, hi); /* prog. MTRR with current region Mask */
- addr++; /* next MTRR pair addr */
- }
-
- /*======================================================================
- * Set variable MTRR values
- *======================================================================*/
- print_tx("\t UMAMemTyping_D: Cache32bTOP:", Cache32bTOP);
- SetMTRRrangeWB_D(0, &Cache32bTOP, &addr);
- if (addr == -1) /* ran out of MTRRs?*/
- pMCTstat->GStatus |= 1<<GSB_MTRRshort;
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctndi_d.c b/src/northbridge/amd/amdmct/mct/mctndi_d.c
deleted file mode 100644
index 3f09f4a472..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctndi_d.c
+++ /dev/null
@@ -1,234 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "mct_d.h"
-
-void InterleaveNodes_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
-
- /* Applies Node memory interleaving if enabled and if all criteria are met. */
- u8 Node;
- u32 Base;
- u32 MemSize, MemSize0 = 0;
- u32 Dct0MemSize = 0, DctSelBase, DctSelBaseOffset = 0;
- u8 Nodes;
- u8 NodesWmem;
- u8 DoIntlv;
- u8 _NdIntCap;
- u8 _SWHole;
- u32 HWHoleSz;
- u32 DramHoleAddrReg;
- u32 HoleBase;
- u32 dev0;
- u32 reg0;
- u32 val;
- u8 i;
- struct DCTStatStruc *pDCTstat;
-
- DoIntlv = mctGet_NVbits(NV_NodeIntlv);
-
- _NdIntCap = 0;
- HWHoleSz = 0; /*For HW remapping, NOT Node hoisting. */
-
- pDCTstat = pDCTstatA + 0;
- dev0 = pDCTstat->dev_host;
- Nodes = ((Get_NB32(dev0, 0x60) >> 4) & 0x7) + 1;
-
-
- dev0 = pDCTstat->dev_map;
- reg0 = 0x40;
-
- NodesWmem = 0;
- Node = 0;
-
- while (DoIntlv && (Node < Nodes)) {
- pDCTstat = pDCTstatA + Node;
- if (pMCTstat->GStatus & (1 << GSB_SpIntRemapHole)) {
- pMCTstat->GStatus |= 1 << GSB_HWHole;
- _SWHole = 0;
- } else if (pDCTstat->Status & (1 << SB_SWNodeHole)) {
- _SWHole = 1;
- } else {
- _SWHole = 0;
- }
-
- if (!_SWHole) {
- Base = Get_NB32(dev0, reg0);
- if (Base & 1) {
- NodesWmem++;
- Base &= 0xFFFF0000; /* Base[39:8] */
-
- if (pDCTstat->Status & (1 << SB_HWHole)) {
-
- /* to get true amount of dram,
- * subtract out memory hole if HW dram remapping */
- DramHoleAddrReg = Get_NB32(pDCTstat->dev_map, 0xF0);
- HWHoleSz = DramHoleAddrReg >> 16;
- HWHoleSz = (((~HWHoleSz) + 1) & 0xFF);
- HWHoleSz <<= 24-8;
- }
- /* check to see if the amount of memory on each channel
- * are the same on all nodes */
-
- DctSelBase = Get_NB32(pDCTstat->dev_dct, 0x114);
- if (DctSelBase) {
- DctSelBase <<= 8;
- if (pDCTstat->Status & (1 << SB_HWHole)) {
- if (DctSelBase >= 0x1000000) {
- DctSelBase -= HWHoleSz;
- }
- }
- DctSelBaseOffset -= Base;
- if (Node == 0) {
- Dct0MemSize = DctSelBase;
- } else if (DctSelBase != Dct0MemSize) {
- break;
- }
- }
-
- MemSize = Get_NB32(dev0, reg0 + 4);
- MemSize &= 0xFFFF0000;
- MemSize += 0x00010000;
- MemSize -= Base;
- if (pDCTstat->Status & (1 << SB_HWHole)) {
- MemSize -= HWHoleSz;
- }
- if (Node == 0) {
- MemSize0 = MemSize;
- } else if (MemSize0 != MemSize) {
- break;
- }
- } else {
- break;
- }
- } else {
- break;
- }
- Node++;
- reg0 += 8;
- }
-
- if (Node == Nodes) {
- /* if all nodes have memory and no Node had SW memhole */
- if (Nodes == 2 || Nodes == 4 || Nodes == 8)
- _NdIntCap = 1;
- }
-
- if (!_NdIntCap)
- DoIntlv = 0;
-
-
- if (pMCTstat->GStatus & 1 << (GSB_SpIntRemapHole)) {
- HWHoleSz = pMCTstat->HoleBase;
- if (HWHoleSz == 0) {
- HWHoleSz = mctGet_NVbits(NV_BottomIO) & 0xFF;
- HWHoleSz <<= 24-8;
- }
- HWHoleSz = ((~HWHoleSz) + 1) & 0x00FF0000;
- }
-
- if (DoIntlv) {
- MCTMemClr_D(pMCTstat,pDCTstatA);
- /* Program Interleaving enabled on Node 0 map only.*/
- MemSize0 <<= bsf(Nodes); /* MemSize = MemSize*2 (or 4, or 8) */
- Dct0MemSize <<= bsf(Nodes);
- MemSize0 += HWHoleSz;
- Base = ((Nodes - 1) << 8) | 3;
- reg0 = 0x40;
- Node = 0;
- while (Node < Nodes) {
- Set_NB32(dev0, reg0, Base);
- MemSize = MemSize0;
- MemSize--;
- MemSize &= 0xFFFF0000;
- MemSize |= Node << 8; /* set IntlvSel[2:0] field */
- MemSize |= Node; /* set DstNode[2:0] field */
- Set_NB32(dev0, reg0 + 4, MemSize0);
- reg0 += 8;
- Node++;
- }
-
- /* set base/limit to F1x120/124 per Node */
- Node = 0;
- while (Node < Nodes) {
- pDCTstat = pDCTstatA + Node;
- pDCTstat->NodeSysBase = 0;
- MemSize = MemSize0;
- MemSize -= HWHoleSz;
- MemSize--;
- pDCTstat->NodeSysLimit = MemSize;
- Set_NB32(pDCTstat->dev_map, 0x120, Node << 21);
- MemSize = MemSize0;
- MemSize--;
- MemSize >>= 19;
- val = Base;
- val &= 0x700;
- val <<= 13;
- val |= MemSize;
- Set_NB32(pDCTstat->dev_map, 0x124, val);
-
- if (pMCTstat->GStatus & (1 << GSB_HWHole)) {
- HoleBase = pMCTstat->HoleBase;
- if (Dct0MemSize >= HoleBase) {
- val = HWHoleSz;
- if (Node == 0) {
- val += Dct0MemSize;
- }
- } else {
- val = HWHoleSz + Dct0MemSize;
- }
-
- val >>= 8; /* DramHoleOffset */
- HoleBase <<= 8; /* DramHoleBase */
- val |= HoleBase;
- val |= 1 << DramMemHoistValid;
- val |= 1 << DramHoleValid;
- Set_NB32(pDCTstat->dev_map, 0xF0, val);
- }
-
-
- Set_NB32(pDCTstat->dev_dct, 0x114, Dct0MemSize >> 8); /* DctSelBaseOffset */
- val = Get_NB32(pDCTstat->dev_dct, 0x110);
- val &= 0x7FF;
- val |= Dct0MemSize >> 8;
- Set_NB32(pDCTstat->dev_dct, 0x110, val); /* DctSelBaseAddr */
- print_tx("InterleaveNodes: DRAM Controller Select Low Register = ", val);
- Node++;
- }
-
-
- /* Copy Node 0 into other Nodes' CSRs */
- Node = 1;
- while (Node < Nodes) {
- pDCTstat = pDCTstatA + Node;
-
- for (i = 0x40; i <= 0x80; i++) {
- val = Get_NB32(dev0, i);
- Set_NB32(pDCTstat->dev_map, i, val);
- }
-
- val = Get_NB32(dev0, 0xF0);
- Set_NB32(pDCTstat->dev_map, 0xF0, val);
- Node++;
- }
- pMCTstat->GStatus = (1 << GSB_NodeIntlv);
- }
- print_tx("InterleaveNodes_D: Status ", pDCTstat->Status);
- print_tx("InterleaveNodes_D: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("InterleaveNodes_D: ErrCode ", pDCTstat->ErrCode);
- print_t("InterleaveNodes_D: Done\n");
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctpro_d.c b/src/northbridge/amd/amdmct/mct/mctpro_d.c
deleted file mode 100644
index 83937330f8..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctpro_d.c
+++ /dev/null
@@ -1,396 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "mct_d.h"
-
-void EarlySampleSupport_D(void)
-{
-}
-
-u32 procOdtWorkaround(struct DCTStatStruc *pDCTstat, u32 dct, u32 val)
-{
- uint64_t tmp;
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
- val &= 0x0FFFFFFF;
- if (pDCTstat->MAdimms[dct] > 1)
- val |= 0x10000000;
- }
-
- return val;
-}
-
-
-u32 OtherTiming_A_D(struct DCTStatStruc *pDCTstat, u32 val)
-{
- /* Bug#10695:One MEMCLK Bubble Writes Don't Do X4 X8 Switching Correctly
- * Solution: BIOS should set DRAM Timing High[Twrwr] > 00b
- * (F2x[1, 0]8C[1:0] > 00b). Silicon Status: Fixed in Rev B
- * FIXME: check if this is still required.
- */
- uint64_t tmp;
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
- if (!(val & (3<<12)))
- val |= 1<<12;
- }
- return val;
-}
-
-
-void mct_ForceAutoPrecharge_D(struct DCTStatStruc *pDCTstat, u32 dct)
-{
- uint64_t tmp;
- u32 reg;
- u32 reg_off;
- u32 dev;
- u32 val;
-
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
- if (CheckNBCOFAutoPrechg(pDCTstat, dct)) {
- dev = pDCTstat->dev_dct;
- reg_off = 0x100 * dct;
- reg = 0x90 + reg_off; /* Dram Configuration Lo */
- val = Get_NB32(dev, reg);
- val |= 1<<ForceAutoPchg;
- if (!pDCTstat->GangedMode)
- val |= 1<<BurstLength32;
- Set_NB32(dev, reg, val);
-
- reg = 0x88 + reg_off; /* cx = Dram Timing Lo */
- val = Get_NB32(dev, reg);
- val |= 0x000F0000; /* Trc = 0Fh */
- Set_NB32(dev, reg, val);
- }
- }
-}
-
-
-void mct_EndDQSTraining_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /* Bug#13341: Prefetch is getting killed when the limit is reached in
- * PrefDramTrainMode
- * Solution: Explicitly clear the PrefDramTrainMode bit after training
- * sequence in order to ensure resumption of normal HW prefetch
- * behavior.
- * NOTE -- this has been documented with a note at the end of this
- * section in the BKDG (although, admittedly, the note does not really
- * stand out).
- * Silicon Status: Fixed in Rev B (confirm)
- * FIXME: check this.
- */
-
- uint64_t tmp;
- u32 dev;
- u32 reg;
- u32 val;
- u32 Node;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (!pDCTstat->NodePresent) break;
-
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
- dev = pDCTstat->dev_dct;
- reg = 0x11c;
- val = Get_NB32(dev, reg);
- val &= ~(1<<PrefDramTrainMode);
- Set_NB32(dev, reg, val);
- }
- }
-}
-
-
-
-
-void mct_BeforeDQSTrain_Samp_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Bug#15115: Uncertainty In The Sync Chain Leads To Setup Violations
- * In TX FIFO
- * Solution: BIOS should program DRAM Control Register[RdPtrInit] = 5h,
- * (F2x[1, 0]78[3:0] = 5h).
- * Silicon Status: Fixed In Rev B0
- */
-
- /* Bug#15880: Determine validity of reset settings for DDR PHY timing
- * regi..
- * Solution: At least, set WrDqs fine delay to be 0 for DDR2 training.
- */
-
- u32 dev;
- u32 reg_off;
- u32 index_reg;
- u32 index;
- u32 reg;
- u32 val;
- uint64_t tmp;
- u32 Channel;
-
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
-
- dev = pDCTstat->dev_dct;
- index = 0;
-
- for (Channel = 0; Channel < 2; Channel++) {
- index_reg = 0x98 + 0x100 * Channel;
- val = Get_NB32_index_wait(dev, index_reg, 0x0d004007);
- val |= 0x3ff;
- Set_NB32_index_wait(dev, index_reg, 0x0d0f4f07, val);
- }
-
- for (Channel = 0; Channel < 2; Channel++) {
- if (pDCTstat->GangedMode && Channel)
- break;
- reg_off = 0x100 * Channel;
- reg = 0x78 + reg_off;
- val = Get_NB32(dev, reg);
- val &= ~(0x07);
- val |= 5;
- Set_NB32(dev, reg, val);
- }
-
- for (Channel = 0; Channel < 2; Channel++) {
- reg_off = 0x100 * Channel;
- val = 0;
- index_reg = 0x98 + reg_off;
- for (index = 0x30; index < (0x45 + 1); index++) {
- Set_NB32_index_wait(dev, index_reg, index, val);
- }
- }
-
- }
-}
-
-
-u32 Modify_D3CMP(struct DCTStatStruc *pDCTstat, u32 dct, u32 value)
-{
- /* Errata#189: Reads To Phy Driver Calibration Register and Phy
- * Predriver Calibration Register Do Not Return Bit 27.
- * Solution: See #41322 for details.
- * BIOS can modify bit 27 of the Phy Driver Calibration register
- * as follows:
- * 1. Read F2x[1, 0]9C_x09
- * 2. Read F2x[1, 0]9C_x0D004201
- * 3. Set F2x[1, 0]9C_x09[27] = F2x[1, 0]9C_x0D004201[10]
- * BIOS can modify bit 27 of the Phy Predriver Calibration register
- * as follows:
- * 1. Read F2x[1, 0]9C_x0A
- * 2. Read F2x[1, 0]9C_x0D004209
- * 3. Set F2x[1, 0]9C_x0A[27] = F2x[1, 0]9C_x0D004209[10]
- * Silicon Status: Fixed planned for DR-B0
- */
-
- u32 dev;
- u32 index_reg;
- u32 index;
- u32 val;
- uint64_t tmp;
-
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
- dev = pDCTstat->dev_dct;
- index_reg = 0x98 + 0x100 * dct;
- index = 0x0D004201;
- val = Get_NB32_index_wait(dev, index_reg, index);
- value &= ~(1<<27);
- value |= ((val >> 10) & 1) << 27;
- }
- return value;
-}
-
-
-void SyncSetting(struct DCTStatStruc *pDCTstat)
-{
- /* Errata#198: AddrCmdSetup, CsOdtSetup, and CkeSetup Require Identical
- * Programming For Both Channels in Ganged Mode
- * Solution: The BIOS must program the following DRAM timing parameters
- * the same for both channels:
- * 1. F2x[1, 0]9C_x04[21] (AddrCmdSetup)
- * 2. F2x[1, 0]9C_x04[15] (CsOdtSetup)
- * 3. F2x[1, 0]9C_x04[5]) (CkeSetup)
- * That is, if the AddrCmdSetup, CsOdtSetup, or CkeSetup is
- * set to 1'b1 for one of the controllers, then the corresponding
- * AddrCmdSetup, CsOdtSetup, or CkeSetup must be set to 1'b1 for the
- * other controller.
- * Silicon Status: Fix TBD
- */
-
- uint64_t tmp;
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
- pDCTstat->CH_ODC_CTL[1] = pDCTstat->CH_ODC_CTL[0];
- pDCTstat->CH_ADDR_TMG[1] = pDCTstat->CH_ADDR_TMG[0];
- }
-}
-
-
-u32 CheckNBCOFAutoPrechg(struct DCTStatStruc *pDCTstat, u32 dct)
-{
- u32 ret = 0;
- u32 lo, hi;
- u32 msr;
- u32 val;
- u32 valx, valy;
- u32 NbDid;
-
- /* 3 * (Fn2xD4[NBFid]+4)/(2^NbDid)/(3+Fn2x94[MemClkFreq]) */
- msr = 0xC0010071;
- _RDMSR(msr, &lo, &hi);
- NbDid = (lo >> 22) & 1;
-
- val = Get_NB32(pDCTstat->dev_dct, 0x94 + 0x100 * dct);
- valx = ((val & 0x07) + 3) << NbDid;
- print_tx("MemClk:", valx >> NbDid);
-
- val = Get_NB32(pDCTstat->dev_nbmisc, 0xd4);
- valy = ((val & 0x1f) + 4) * 3;
- print_tx("NB COF:", valy >> NbDid);
-
- val = valy/valx;
- if ((val == 3) && (valy % valx)) /* 3 < NClk/MemClk < 4 */
- ret = 1;
-
- return ret;
-}
-
-
-void mct_BeforeDramInit_D(struct DCTStatStruc *pDCTstat, u32 dct)
-{
- uint64_t tmp;
- u32 Speed;
- u32 ch, ch_start, ch_end;
- u32 index_reg;
- u32 dev;
- u32 val;
-
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
- Speed = pDCTstat->Speed;
- /* MemClkFreq = 333MHz or 533MHz */
- if ((Speed == 3) || (Speed == 2)) {
- if (pDCTstat->GangedMode) {
- ch_start = 0;
- ch_end = 2;
- } else {
- ch_start = dct;
- ch_end = dct+1;
- }
- dev = pDCTstat->dev_dct;
-
- for (ch = ch_start; ch < ch_end; ch++) {
- index_reg = 0x98 + 0x100 * ch;
- val = Get_NB32_index(dev, index_reg, 0x0D00E001);
- val &= ~(0xf0);
- val |= 0x80;
- Set_NB32_index(dev, index_reg, 0x0D01E001, val);
- }
- }
-
- }
-}
-
-#ifdef UNUSED_CODE
-/* Callback not required */
-static u8 mct_AdjustDelay_D(struct DCTStatStruc *pDCTstat, u8 dly)
-{
- u8 skip = 0;
- dly &= 0x1f;
- if ((dly >= MIN_FENCE) && (dly <= MAX_FENCE))
- skip = 1;
-
- return skip;
-}
-#endif
-
-u8 mct_checkFenceHoleAdjust_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 DQSDelay,
- u8 ChipSel, u8 *result)
-{
- u8 ByteLane;
- uint64_t tmp;
-
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
- if (pDCTstat->Direction == DQS_WRITEDIR) {
- if ((pDCTstat->Speed == 2) || (pDCTstat->Speed == 3)) {
- if (DQSDelay == 13) {
- if (*result == 0xFF) {
- for (ByteLane = 0; ByteLane < 8; ByteLane++) {
- pDCTstat->DQSDelay = 13;
- pDCTstat->ByteLane = ByteLane;
- /* store the value into the data structure */
- StoreDQSDatStrucVal_D(pMCTstat, pDCTstat, ChipSel);
- }
- return 1;
- }
- }
- }
- if (mct_AdjustDQSPosDelay_D(pDCTstat, DQSDelay)) {
- *result = 0;
- }
- }
- }
- return 0;
-}
-
-
-u8 mct_AdjustDQSPosDelay_D(struct DCTStatStruc *pDCTstat, u8 dly)
-{
- u8 skip = 0;
-
- dly &= 0x1f;
- if ((dly >= MIN_DQS_WR_FENCE) && (dly <= MAX_DQS_WR_FENCE))
- skip = 1;
-
- return skip;
-
-}
-
-#ifdef UNUSED_CODE
-static u8 mctDoAxRdPtrInit_D(struct DCTStatStruc *pDCTstat, u8 *Rdtr)
-{
- u32 tmp;
-
- tmp = pDCTstat->LogicalCPUID;
- if ((tmp == AMD_DR_A0A) || (tmp == AMD_DR_A1B) || (tmp == AMD_DR_A2)) {
- *Rdtr = 5;
- return 1;
- }
- return 0;
-}
-#endif
-
-void mct_AdjustScrub_D(struct DCTStatStruc *pDCTstat, u16 *scrub_request) {
-
- /* Erratum #202: disable DCache scrubber for Ax parts */
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_Ax)) {
- *scrub_request = 0;
- pDCTstat->ErrStatus |= 1 << SB_DCBKScrubDis;
- }
-}
-
-void beforeInterleaveChannels_D(struct DCTStatStruc *pDCTstatA, u8 *enabled) {
- if (pDCTstatA->LogicalCPUID & (AMD_DR_Ax))
- *enabled = 0;
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctsrc.c b/src/northbridge/amd/amdmct/mct/mctsrc.c
deleted file mode 100644
index 406547e0f8..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctsrc.c
+++ /dev/null
@@ -1,1090 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; either version 2 of the License, or
- * (at your option) any later version.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <console/console.h>
-#include <cpu/x86/cr.h>
-#include <cpu/amd/msr.h>
-
-#include "mct_d.h"
-
-/******************************************************************************
- Description: Receiver En and DQS Timing Training feature for DDR 2 MCT
-******************************************************************************/
-
-static void dqsTrainRcvrEn_SW(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Pass);
-static u8 mct_SavePassRcvEnDly_D(struct DCTStatStruc *pDCTstat,
- u8 rcvrEnDly, u8 Channel,
- u8 receiver, u8 Pass);
-static u8 mct_CompareTestPatternQW0_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 addr, u8 channel,
- u8 pattern, u8 Pass);
-static void mct_InitDQSPos4RcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void InitDQSPos4RcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel);
-static void CalcEccDQSRcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel);
-static void mct_SetFinalRcvrEnDly_D(struct DCTStatStruc *pDCTstat,
- u8 RcvrEnDly, u8 where,
- u8 Channel, u8 Receiver,
- u32 dev, u32 index_reg,
- u8 Addl_Index, u8 Pass);
-static void mct_SetMaxLatency_D(struct DCTStatStruc *pDCTstat, u8 Channel, u8 DQSRcvEnDly);
-static void fenceDynTraining_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_DisableDQSRcvEn_D(struct DCTStatStruc *pDCTstat);
-
-/* Warning: These must be located so they do not cross a logical 16-bit
- segment boundary! */
-const u32 TestPattern0_D[] = {
- 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa,
- 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa,
- 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa,
- 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa,
-};
-const u32 TestPattern1_D[] = {
- 0x55555555, 0x55555555, 0x55555555, 0x55555555,
- 0x55555555, 0x55555555, 0x55555555, 0x55555555,
- 0x55555555, 0x55555555, 0x55555555, 0x55555555,
- 0x55555555, 0x55555555, 0x55555555, 0x55555555,
-};
-const u32 TestPattern2_D[] = {
- 0x12345678, 0x87654321, 0x23456789, 0x98765432,
- 0x59385824, 0x30496724, 0x24490795, 0x99938733,
- 0x40385642, 0x38465245, 0x29432163, 0x05067894,
- 0x12349045, 0x98723467, 0x12387634, 0x34587623,
-};
-
-static void SetupRcvrPattern(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 *buffer, u8 pass)
-{
- /*
- * 1. Copy the alpha and Beta patterns from ROM to Cache,
- * aligning on 16 byte boundary
- * 2. Set the ptr to DCTStatstruc.PtrPatternBufA for Alpha
- * 3. Set the ptr to DCTStatstruc.PtrPatternBufB for Beta
- */
-
- u32 *buf_a;
- u32 *buf_b;
- u32 *p_A;
- u32 *p_B;
- u8 i;
-
- buf_a = (u32 *)(((u32)buffer + 0x10) & (0xfffffff0));
- buf_b = buf_a + 32; //??
- p_A = (u32 *)SetupDqsPattern_1PassB(pass);
- p_B = (u32 *)SetupDqsPattern_1PassA(pass);
-
- for (i = 0; i < 16; i++) {
- buf_a[i] = p_A[i];
- buf_b[i] = p_B[i];
- }
-
- pDCTstat->PtrPatternBufA = (u32)buf_a;
- pDCTstat->PtrPatternBufB = (u32)buf_b;
-}
-
-
-void mct_TrainRcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Pass)
-{
- if (mct_checkNumberOfDqsRcvEn_1Pass(Pass))
- dqsTrainRcvrEn_SW(pMCTstat, pDCTstat, Pass);
-}
-
-
-static void dqsTrainRcvrEn_SW(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Pass)
-{
- u8 Channel, RcvrEnDly, RcvrEnDlyRmin;
- u8 Test0, Test1, CurrTest, CurrTestSide0, CurrTestSide1;
- u8 CTLRMaxDelay, _2Ranks, PatternA, PatternB;
- u8 Addl_Index = 0;
- u8 Receiver;
- u8 _DisableDramECC = 0, _Wrap32Dis = 0, _SSE2 = 0;
- u8 RcvrEnDlyLimit, Final_Value, MaxDelay_CH[2];
- u32 TestAddr0, TestAddr1, TestAddr0B, TestAddr1B;
- u32 PatternBuffer[64+4]; /* FIXME: need increase 8? */
- u32 Errors;
-
- u32 val;
- u32 reg;
- u32 dev;
- u32 index_reg;
- u32 ch_start, ch_end, ch;
- u32 msr;
- CRx_TYPE cr4;
- u32 lo, hi;
-
- u8 valid;
- u32 tmp;
- u8 LastTest;
-
- print_debug_dqs("\nTrainRcvEn: Node", pDCTstat->Node_ID, 0);
- print_debug_dqs("TrainRcvEn: Pass", Pass, 0);
-
-
- dev = pDCTstat->dev_dct;
- ch_start = 0;
- if (!pDCTstat->GangedMode) {
- ch_end = 2;
- } else {
- ch_end = 1;
- }
-
- for (ch = ch_start; ch < ch_end; ch++) {
- reg = 0x78 + (0x100 * ch);
- val = Get_NB32(dev, reg);
- val &= ~(0x3ff << 22);
- val |= (0x0c8 << 22); /* Max Rd Lat */
- Set_NB32(dev, reg, val);
- }
-
- Final_Value = 1;
- if (Pass == FirstPass) {
- mct_InitDQSPos4RcvrEn_D(pMCTstat, pDCTstat);
- } else {
- pDCTstat->DimmTrainFail = 0;
- pDCTstat->CSTrainFail = ~pDCTstat->CSPresent;
- }
- print_t("TrainRcvrEn: 1\n");
-
- cr4 = read_cr4();
- if (cr4 & (1 << 9)) { /* save the old value */
- _SSE2 = 1;
- }
- cr4 |= (1 << 9); /* OSFXSR enable SSE2 */
- write_cr4(cr4);
- print_t("TrainRcvrEn: 2\n");
-
- msr = HWCR_MSR;
- _RDMSR(msr, &lo, &hi);
- //FIXME: Why use SSEDIS
- if (lo & (1 << 17)) { /* save the old value */
- _Wrap32Dis = 1;
- }
- lo |= (1 << 17); /* HWCR.wrap32dis */
- lo &= ~(1 << 15); /* SSEDIS */
- _WRMSR(msr, lo, hi); /* Setting wrap32dis allows 64-bit memory references in real mode */
- print_t("TrainRcvrEn: 3\n");
-
- _DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
-
-
- if (pDCTstat->Speed == 1) {
- pDCTstat->T1000 = 5000; /* get the T1000 figure (cycle time (ns)*1K */
- } else if (pDCTstat->Speed == 2) {
- pDCTstat->T1000 = 3759;
- } else if (pDCTstat->Speed == 3) {
- pDCTstat->T1000 = 3003;
- } else if (pDCTstat->Speed == 4) {
- pDCTstat->T1000 = 2500;
- } else if (pDCTstat->Speed == 5) {
- pDCTstat->T1000 = 1876;
- } else {
- pDCTstat->T1000 = 0;
- }
-
- SetupRcvrPattern(pMCTstat, pDCTstat, PatternBuffer, Pass);
- print_t("TrainRcvrEn: 4\n");
-
- Errors = 0;
- dev = pDCTstat->dev_dct;
- CTLRMaxDelay = 0;
-
- for (Channel = 0; Channel < 2; Channel++) {
- print_debug_dqs("\tTrainRcvEn51: Node ", pDCTstat->Node_ID, 1);
- print_debug_dqs("\tTrainRcvEn51: Channel ", Channel, 1);
- pDCTstat->Channel = Channel;
-
- MaxDelay_CH[Channel] = 0;
- index_reg = 0x98 + 0x100 * Channel;
-
- Receiver = mct_InitReceiver_D(pDCTstat, Channel);
- /* There are four receiver pairs, loosely associated with chipselects. */
- for (; Receiver < 8; Receiver += 2) {
- Addl_Index = (Receiver >> 1) * 3 + 0x10;
- LastTest = DQS_FAIL;
-
- /* mct_ModifyIndex_D */
- RcvrEnDlyRmin = RcvrEnDlyLimit = 0xff;
-
- print_debug_dqs("\t\tTrainRcvEnd52: index ", Addl_Index, 2);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, Receiver)) {
- print_t("\t\t\tRank not enabled_D\n");
- continue;
- }
-
- TestAddr0 = mct_GetRcvrSysAddr_D(pMCTstat, pDCTstat, Channel, Receiver, &valid);
- if (!valid) { /* Address not supported on current CS */
- print_t("\t\t\tAddress not supported on current CS\n");
- continue;
- }
-
- TestAddr0B = TestAddr0 + (BigPagex8_RJ8 << 3);
-
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, Receiver+1)) {
- TestAddr1 = mct_GetRcvrSysAddr_D(pMCTstat, pDCTstat, Channel, Receiver+1, &valid);
- if (!valid) { /* Address not supported on current CS */
- print_t("\t\t\tAddress not supported on current CS+1\n");
- continue;
- }
- TestAddr1B = TestAddr1 + (BigPagex8_RJ8 << 3);
- _2Ranks = 1;
- } else {
- _2Ranks = TestAddr1 = TestAddr1B = 0;
- }
-
- print_debug_dqs("\t\tTrainRcvEn53: TestAddr0 ", TestAddr0, 2);
- print_debug_dqs("\t\tTrainRcvEn53: TestAddr0B ", TestAddr0B, 2);
- print_debug_dqs("\t\tTrainRcvEn53: TestAddr1 ", TestAddr1, 2);
- print_debug_dqs("\t\tTrainRcvEn53: TestAddr1B ", TestAddr1B, 2);
-
- /*
- * Get starting RcvrEnDly value
- */
- RcvrEnDly = mct_Get_Start_RcvrEnDly_1Pass(Pass);
-
- /* mct_GetInitFlag_D*/
- if (Pass == FirstPass) {
- pDCTstat->DqsRcvEn_Pass = 0;
- } else {
- pDCTstat->DqsRcvEn_Pass = 0xFF;
- }
- pDCTstat->DqsRcvEn_Saved = 0;
-
-
- while (RcvrEnDly < RcvrEnDlyLimit) { /* sweep Delay value here */
- print_debug_dqs("\t\t\tTrainRcvEn541: RcvrEnDly ", RcvrEnDly, 3);
-
- /* callback not required
- if (mct_AdjustDelay_D(pDCTstat, RcvrEnDly))
- goto skipDly;
- */
-
- /* Odd steps get another pattern such that even
- and odd steps alternate. The pointers to the
- patterns will be swaped at the end of the loop
- so that they correspond. */
- if (RcvrEnDly & 1) {
- PatternA = 1;
- PatternB = 0;
- } else {
- /* Even step */
- PatternA = 0;
- PatternB = 1;
- }
-
- mct_Write1LTestPattern_D(pMCTstat, pDCTstat, TestAddr0, PatternA); /* rank 0 of DIMM, testpattern 0 */
- mct_Write1LTestPattern_D(pMCTstat, pDCTstat, TestAddr0B, PatternB); /* rank 0 of DIMM, testpattern 1 */
- if (_2Ranks) {
- mct_Write1LTestPattern_D(pMCTstat, pDCTstat, TestAddr1, PatternA); /*rank 1 of DIMM, testpattern 0 */
- mct_Write1LTestPattern_D(pMCTstat, pDCTstat, TestAddr1B, PatternB); /*rank 1 of DIMM, testpattern 1 */
- }
-
- mct_SetRcvrEnDly_D(pDCTstat, RcvrEnDly, 0, Channel, Receiver, dev, index_reg, Addl_Index, Pass);
-
- CurrTest = DQS_FAIL;
- CurrTestSide0 = DQS_FAIL;
- CurrTestSide1 = DQS_FAIL;
-
- mct_Read1LTestPattern_D(pMCTstat, pDCTstat, TestAddr0); /*cache fills */
- Test0 = mct_CompareTestPatternQW0_D(pMCTstat, pDCTstat, TestAddr0, Channel, PatternA, Pass);/* ROM vs cache compare */
- proc_IOCLFLUSH_D(TestAddr0);
- ResetDCTWrPtr_D(dev, index_reg, Addl_Index);
-
- print_debug_dqs("\t\t\tTrainRcvEn542: Test0 result ", Test0, 3);
-
- // != 0x00 mean pass
-
- if (Test0 == DQS_PASS) {
- mct_Read1LTestPattern_D(pMCTstat, pDCTstat, TestAddr0B); /*cache fills */
- /* ROM vs cache compare */
- Test1 = mct_CompareTestPatternQW0_D(pMCTstat, pDCTstat, TestAddr0B, Channel, PatternB, Pass);
- proc_IOCLFLUSH_D(TestAddr0B);
- ResetDCTWrPtr_D(dev, index_reg, Addl_Index);
-
- print_debug_dqs("\t\t\tTrainRcvEn543: Test1 result ", Test1, 3);
-
- if (Test1 == DQS_PASS) {
- CurrTestSide0 = DQS_PASS;
- }
- }
- if (_2Ranks) {
- mct_Read1LTestPattern_D(pMCTstat, pDCTstat, TestAddr1); /*cache fills */
- /* ROM vs cache compare */
- Test0 = mct_CompareTestPatternQW0_D(pMCTstat, pDCTstat, TestAddr1, Channel, PatternA, Pass);
- proc_IOCLFLUSH_D(TestAddr1);
- ResetDCTWrPtr_D(dev, index_reg, Addl_Index);
-
- print_debug_dqs("\t\t\tTrainRcvEn544: Test0 result ", Test0, 3);
-
- if (Test0 == DQS_PASS) {
- mct_Read1LTestPattern_D(pMCTstat, pDCTstat, TestAddr1B); /*cache fills */
- /* ROM vs cache compare */
- Test1 = mct_CompareTestPatternQW0_D(pMCTstat, pDCTstat, TestAddr1B, Channel, PatternB, Pass);
- proc_IOCLFLUSH_D(TestAddr1B);
- ResetDCTWrPtr_D(dev, index_reg, Addl_Index);
-
- print_debug_dqs("\t\t\tTrainRcvEn545: Test1 result ", Test1, 3);
- if (Test1 == DQS_PASS) {
- CurrTestSide1 = DQS_PASS;
- }
- }
- }
-
- if (_2Ranks) {
- if ((CurrTestSide0 == DQS_PASS) && (CurrTestSide1 == DQS_PASS)) {
- CurrTest = DQS_PASS;
- }
- } else if (CurrTestSide0 == DQS_PASS) {
- CurrTest = DQS_PASS;
- }
-
-
- /* record first pass DqsRcvEn to stack */
- valid = mct_SavePassRcvEnDly_D(pDCTstat, RcvrEnDly, Channel, Receiver, Pass);
-
- /* Break(1:RevF,2:DR) or not(0) FIXME: This comment deosn't make sense */
- if (valid == 2 || (LastTest == DQS_FAIL && valid == 1)) {
- RcvrEnDlyRmin = RcvrEnDly;
- break;
- }
-
- LastTest = CurrTest;
-
- /* swap the rank 0 pointers */
- tmp = TestAddr0;
- TestAddr0 = TestAddr0B;
- TestAddr0B = tmp;
-
- /* swap the rank 1 pointers */
- tmp = TestAddr1;
- TestAddr1 = TestAddr1B;
- TestAddr1B = tmp;
-
- print_debug_dqs("\t\t\tTrainRcvEn56: RcvrEnDly ", RcvrEnDly, 3);
-
- RcvrEnDly++;
-
- } /* while RcvrEnDly */
-
- print_debug_dqs("\t\tTrainRcvEn61: RcvrEnDly ", RcvrEnDly, 2);
- print_debug_dqs("\t\tTrainRcvEn61: RcvrEnDlyRmin ", RcvrEnDlyRmin, 3);
- print_debug_dqs("\t\tTrainRcvEn61: RcvrEnDlyLimit ", RcvrEnDlyLimit, 3);
- if (RcvrEnDlyRmin == RcvrEnDlyLimit) {
- /* no passing window */
- pDCTstat->ErrStatus |= 1 << SB_NORCVREN;
- Errors |= 1 << SB_NORCVREN;
- pDCTstat->ErrCode = SC_FatalErr;
- }
-
- if (RcvrEnDly > (RcvrEnDlyLimit - 1)) {
- /* passing window too narrow, too far delayed*/
- pDCTstat->ErrStatus |= 1 << SB_SmallRCVR;
- Errors |= 1 << SB_SmallRCVR;
- pDCTstat->ErrCode = SC_FatalErr;
- RcvrEnDly = RcvrEnDlyLimit - 1;
- pDCTstat->CSTrainFail |= 1 << Receiver;
- pDCTstat->DimmTrainFail |= 1 << (Receiver + Channel);
- }
-
- // CHB_D0_B0_RCVRDLY set in mct_Average_RcvrEnDly_Pass
- mct_Average_RcvrEnDly_Pass(pDCTstat, RcvrEnDly, RcvrEnDlyLimit, Channel, Receiver, Pass);
-
- mct_SetFinalRcvrEnDly_D(pDCTstat, RcvrEnDly, Final_Value, Channel, Receiver, dev, index_reg, Addl_Index, Pass);
-
- if (pDCTstat->ErrStatus & (1 << SB_SmallRCVR)) {
- Errors |= 1 << SB_SmallRCVR;
- }
-
- RcvrEnDly += Pass1MemClkDly;
- if (RcvrEnDly > CTLRMaxDelay) {
- CTLRMaxDelay = RcvrEnDly;
- }
-
- } /* while Receiver */
-
- MaxDelay_CH[Channel] = CTLRMaxDelay;
- } /* for Channel */
-
- CTLRMaxDelay = MaxDelay_CH[0];
- if (MaxDelay_CH[1] > CTLRMaxDelay)
- CTLRMaxDelay = MaxDelay_CH[1];
-
- for (Channel = 0; Channel < 2; Channel++) {
- mct_SetMaxLatency_D(pDCTstat, Channel, CTLRMaxDelay); /* program Ch A/B MaxAsyncLat to correspond with max delay */
- }
-
- ResetDCTWrPtr_D(dev, index_reg, Addl_Index);
-
- if (_DisableDramECC) {
- mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
- }
-
- if (Pass == FirstPass) {
- /*Disable DQSRcvrEn training mode */
- print_t("TrainRcvrEn: mct_DisableDQSRcvEn_D\n");
- mct_DisableDQSRcvEn_D(pDCTstat);
- }
-
- if (!_Wrap32Dis) {
- msr = HWCR_MSR;
- _RDMSR(msr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(msr, lo, hi);
- }
- if (!_SSE2) {
- cr4 = read_cr4();
- cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
- write_cr4(cr4);
- }
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 Channel;
- printk(BIOS_DEBUG, "TrainRcvrEn: CH_MaxRdLat:\n");
- for (Channel = 0; Channel < 2; Channel++) {
- printk(BIOS_DEBUG, "Channel: %02x: %02x\n", Channel, pDCTstat->CH_MaxRdLat[Channel]);
- }
- }
-#endif
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 val;
- u8 Channel, Receiver;
- u8 i;
- u8 *p;
-
- printk(BIOS_DEBUG, "TrainRcvrEn: CH_D_B_RCVRDLY:\n");
- for (Channel = 0; Channel < 2; Channel++) {
- printk(BIOS_DEBUG, "Channel: %02x\n", Channel);
- for (Receiver = 0; Receiver < 8; Receiver+=2) {
- printk(BIOS_DEBUG, "\t\tReceiver: %02x: ", Receiver);
- p = pDCTstat->persistentData.CH_D_B_RCVRDLY[Channel][Receiver>>1];
- for (i = 0; i < 8; i++) {
- val = p[i];
- printk(BIOS_DEBUG, "%02x ", val);
- }
- printk(BIOS_DEBUG, "\n");
- }
- }
- }
-#endif
-
- print_tx("TrainRcvrEn: Status ", pDCTstat->Status);
- print_tx("TrainRcvrEn: ErrStatus ", pDCTstat->ErrStatus);
- print_tx("TrainRcvrEn: ErrCode ", pDCTstat->ErrCode);
- print_t("TrainRcvrEn: Done\n");
-}
-
-
-u8 mct_InitReceiver_D(struct DCTStatStruc *pDCTstat, u8 dct)
-{
- if (pDCTstat->DIMMValidDCT[dct] == 0) {
- return 8;
- } else {
- return 0;
- }
-}
-
-
-static void mct_SetFinalRcvrEnDly_D(struct DCTStatStruc *pDCTstat, u8 RcvrEnDly, u8 where, u8 Channel, u8 Receiver, u32 dev, u32 index_reg, u8 Addl_Index, u8 Pass/*, u8 *p*/)
-{
- /*
- * Program final DqsRcvEnDly to additional index for DQS receiver
- * enabled delay
- */
- mct_SetRcvrEnDly_D(pDCTstat, RcvrEnDly, where, Channel, Receiver, dev, index_reg, Addl_Index, Pass);
-}
-
-
-static void mct_DisableDQSRcvEn_D(struct DCTStatStruc *pDCTstat)
-{
- u8 ch_end, ch;
- u32 reg;
- u32 dev;
- u32 val;
-
- dev = pDCTstat->dev_dct;
- if (pDCTstat->GangedMode) {
- ch_end = 1;
- } else {
- ch_end = 2;
- }
-
- for (ch = 0; ch < ch_end; ch++) {
- reg = 0x78 + 0x100 * ch;
- val = Get_NB32(dev, reg);
- val &= ~(1 << DqsRcvEnTrain);
- Set_NB32(dev, reg, val);
- }
-}
-
-
-/* mct_ModifyIndex_D
- * Function only used once so it was inlined.
- */
-
-
-/* mct_GetInitFlag_D
- * Function only used once so it was inlined.
- */
-
-
-void mct_SetRcvrEnDly_D(struct DCTStatStruc *pDCTstat, u8 RcvrEnDly,
- u8 FinalValue, u8 Channel, u8 Receiver, u32 dev,
- u32 index_reg, u8 Addl_Index, u8 Pass)
-{
- u32 index;
- u8 i;
- u8 *p;
- u32 val;
-
- if (RcvrEnDly == 0xFE) {
- /*set the boudary flag */
- pDCTstat->Status |= 1 << SB_DQSRcvLimit;
- }
-
- /* DimmOffset not needed for CH_D_B_RCVRDLY array */
-
-
- for (i = 0; i < 8; i++) {
- if (FinalValue) {
- /*calculate dimm offset */
- p = pDCTstat->persistentData.CH_D_B_RCVRDLY[Channel][Receiver >> 1];
- RcvrEnDly = p[i];
- }
-
- /* if flag = 0, set DqsRcvEn value to reg. */
- /* get the register index from table */
- index = Table_DQSRcvEn_Offset[i >> 1];
- index += Addl_Index; /* DIMMx DqsRcvEn byte0 */
- val = Get_NB32_index_wait(dev, index_reg, index);
- if (i & 1) {
- /* odd byte lane */
- val &= ~(0xFF << 16);
- val |= (RcvrEnDly << 16);
- } else {
- /* even byte lane */
- val &= ~0xFF;
- val |= RcvrEnDly;
- }
- Set_NB32_index_wait(dev, index_reg, index, val);
- }
-
-}
-
-static void mct_SetMaxLatency_D(struct DCTStatStruc *pDCTstat, u8 Channel, u8 DQSRcvEnDly)
-{
- u32 dev;
- u32 reg;
- u16 SubTotal;
- u32 index_reg;
- u32 reg_off;
- u32 val;
- u32 valx;
-
- if (pDCTstat->GangedMode)
- Channel = 0;
-
- dev = pDCTstat->dev_dct;
- reg_off = 0x100 * Channel;
- index_reg = 0x98 + reg_off;
-
- /* Multiply the CAS Latency by two to get a number of 1/2 MEMCLKs units.*/
- val = Get_NB32(dev, 0x88 + reg_off);
- SubTotal = ((val & 0x0f) + 1) << 1; /* SubTotal is 1/2 Memclk unit */
-
- /* If registered DIMMs are being used then
- * add 1 MEMCLK to the sub-total.
- */
- val = Get_NB32(dev, 0x90 + reg_off);
- if (!(val & (1 << UnBuffDimm)))
- SubTotal += 2;
-
- /* If the address prelaunch is setup for 1/2 MEMCLKs then
- * add 1, else add 2 to the sub-total.
- * if (AddrCmdSetup || CsOdtSetup || CkeSetup) then K := K + 2;
- */
- val = Get_NB32_index_wait(dev, index_reg, 0x04);
- if (!(val & 0x00202020))
- SubTotal += 1;
- else
- SubTotal += 2;
-
- /* If the F2x[1, 0]78[RdPtrInit] field is 4, 5, 6 or 7 MEMCLKs,
- * then add 4, 3, 2, or 1 MEMCLKs, respectively to the sub-total. */
- val = Get_NB32(dev, 0x78 + reg_off);
- SubTotal += 8 - (val & 0x0f);
-
- /* Convert bits 7-5 (also referred to as the course delay) of
- * the current (or worst case) DQS receiver enable delay to
- * 1/2 MEMCLKs units, rounding up, and add this to the sub-total.
- */
- SubTotal += DQSRcvEnDly >> 5; /*BOZO-no rounding up */
-
- /* Add 5.5 to the sub-total. 5.5 represents part of the
- * processor specific constant delay value in the DRAM
- * clock domain.
- */
- SubTotal <<= 1; /*scale 1/2 MemClk to 1/4 MemClk */
- SubTotal += 11; /*add 5.5 1/2MemClk */
-
- /* Convert the sub-total (in 1/2 MEMCLKs) to northbridge
- * clocks (NCLKs) as follows (assuming DDR400 and assuming
- * that no P-state or link speed changes have occurred).
- */
-
- /* New formula:
- * SubTotal *= 3*(Fn2xD4[NBFid]+4)/(3+Fn2x94[MemClkFreq])/2 */
- val = Get_NB32(dev, 0x94 + reg_off);
-
- /* SubTotal div 4 to scale 1/4 MemClk back to MemClk */
- val &= 7;
- if (val == 4) {
- val++; /* adjust for DDR2-1066 */
- }
- valx = (val + 3) << 2;
-
- val = Get_NB32(pDCTstat->dev_nbmisc, 0xD4);
- SubTotal *= ((val & 0x1f) + 4) * 3;
-
- SubTotal /= valx;
- if (SubTotal % valx) { /* round up */
- SubTotal++;
- }
-
- /* Add 5 NCLKs to the sub-total. 5 represents part of the
- * processor specific constant value in the northbridge
- * clock domain.
- */
- SubTotal += 5;
-
- pDCTstat->CH_MaxRdLat[Channel] = SubTotal;
- if (pDCTstat->GangedMode) {
- pDCTstat->CH_MaxRdLat[1] = SubTotal;
- }
-
- /* Program the F2x[1, 0]78[MaxRdLatency] register with
- * the total delay value (in NCLKs).
- */
-
- reg = 0x78 + reg_off;
- val = Get_NB32(dev, reg);
- val &= ~(0x3ff << 22);
- val |= (SubTotal & 0x3ff) << 22;
-
- /* program MaxRdLatency to correspond with current delay */
- Set_NB32(dev, reg, val);
-}
-
-
-static u8 mct_SavePassRcvEnDly_D(struct DCTStatStruc *pDCTstat,
- u8 rcvrEnDly, u8 Channel,
- u8 receiver, u8 Pass)
-{
- u8 i;
- u8 mask_Saved, mask_Pass;
- u8 *p;
-
- /* calculate dimm offset
- * not needed for CH_D_B_RCVRDLY array
- */
-
- /* cmp if there has new DqsRcvEnDly to be recorded */
- mask_Pass = pDCTstat->DqsRcvEn_Pass;
-
- if (Pass == SecondPass) {
- mask_Pass = ~mask_Pass;
- }
-
- mask_Saved = pDCTstat->DqsRcvEn_Saved;
- if (mask_Pass != mask_Saved) {
-
- /* find desired stack offset according to channel/dimm/byte */
- if (Pass == SecondPass) {
- // FIXME: SecondPass is never used for Barcelona p = pDCTstat->persistentData.CH_D_B_RCVRDLY_1[Channel][receiver>>1];
- p = 0; // Keep the compiler happy.
- } else {
- mask_Saved &= mask_Pass;
- p = pDCTstat->persistentData.CH_D_B_RCVRDLY[Channel][receiver>>1];
- }
- for (i = 0; i < 8; i++) {
- /* cmp per byte lane */
- if (mask_Pass & (1 << i)) {
- if (!(mask_Saved & (1 << i))) {
- /* save RcvEnDly to stack, according to
- the related Dimm/byte lane */
- p[i] = (u8)rcvrEnDly;
- mask_Saved |= 1 << i;
- }
- }
- }
- pDCTstat->DqsRcvEn_Saved = mask_Saved;
- }
- return mct_SaveRcvEnDly_D_1Pass(pDCTstat, Pass);
-}
-
-
-static u8 mct_CompareTestPatternQW0_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 addr, u8 channel,
- u8 pattern, u8 Pass)
-{
- /* Compare only the first beat of data. Since target addrs are cache
- * line aligned, the Channel parameter is used to determine which
- * cache QW to compare.
- */
-
- u8 *test_buf;
- u8 i;
- u8 result;
- u8 value;
-
-
- if (Pass == FirstPass) {
- if (pattern == 1) {
- test_buf = (u8 *)TestPattern1_D;
- } else {
- test_buf = (u8 *)TestPattern0_D;
- }
- } else { // Second Pass
- test_buf = (u8 *)TestPattern2_D;
- }
-
- SetUpperFSbase(addr);
- addr <<= 8;
-
- if ((pDCTstat->Status & (1<<SB_128bitmode)) && channel) {
- addr += 8; /* second channel */
- test_buf += 8;
- }
-
- print_debug_dqs_pair("\t\t\t\t\t\t test_buf = ", (u32)test_buf, " | addr_lo = ", addr, 4);
- for (i = 0; i < 8; i++) {
- value = read32_fs(addr);
- print_debug_dqs_pair("\t\t\t\t\t\t\t\t ", test_buf[i], " | ", value, 4);
-
- if (value == test_buf[i]) {
- pDCTstat->DqsRcvEn_Pass |= (1<<i);
- } else {
- pDCTstat->DqsRcvEn_Pass &= ~(1<<i);
- }
- }
-
- result = DQS_FAIL;
-
- if (Pass == FirstPass) {
- /* if first pass, at least one byte lane pass
- * ,then DQS_PASS = 1 and will set to related reg.
- */
- if (pDCTstat->DqsRcvEn_Pass != 0) {
- result = DQS_PASS;
- } else {
- result = DQS_FAIL;
- }
-
- } else {
- /* if second pass, at least one byte lane fail
- * ,then DQS_FAIL = 1 and will set to related reg.
- */
- if (pDCTstat->DqsRcvEn_Pass != 0xFF) {
- result = DQS_FAIL;
- } else {
- result = DQS_PASS;
- }
- }
-
- /* if second pass, we can't find the fail until FFh,
- * then let it fail to save the final delay
- */
- if ((Pass == SecondPass) && (pDCTstat->Status & (1 << SB_DQSRcvLimit))) {
- result = DQS_FAIL;
- pDCTstat->DqsRcvEn_Pass = 0;
- }
-
- /* second pass needs to be inverted
- * FIXME? this could be inverted in the above code to start with...
- */
- if (Pass == SecondPass) {
- if (result == DQS_PASS) {
- result = DQS_FAIL;
- } else if (result == DQS_FAIL) { /* FIXME: doesn't need to be else if */
- result = DQS_PASS;
- }
- }
-
-
- return result;
-}
-
-
-
-static void mct_InitDQSPos4RcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Initialize the DQS Positions in preparation for
- * Receiver Enable Training.
- * Write Position is 1/2 Memclock Delay
- * Read Position is 1/2 Memclock Delay
- */
- u8 i;
- for (i = 0; i < 2; i++) {
- InitDQSPos4RcvrEn_D(pMCTstat, pDCTstat, i);
- }
-}
-
-
-static void InitDQSPos4RcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel)
-{
- /* Initialize the DQS Positions in preparation for
- * Receiver Enable Training.
- * Write Position is no Delay
- * Read Position is 1/2 Memclock Delay
- */
-
- u8 i, j;
- u32 dword;
- u8 dn = 2; // TODO: Rev C could be 4
- u32 dev = pDCTstat->dev_dct;
- u32 index_reg = 0x98 + 0x100 * Channel;
-
-
- // FIXME: add Cx support
- dword = 0x00000000;
- for (i = 1; i <= 3; i++) {
- for (j = 0; j < dn; j++)
- /* DIMM0 Write Data Timing Low */
- /* DIMM0 Write ECC Timing */
- Set_NB32_index_wait(dev, index_reg, i + 0x100 * j, dword);
- }
-
- /* errata #180 */
- dword = 0x2f2f2f2f;
- for (i = 5; i <= 6; i++) {
- for (j = 0; j < dn; j++)
- /* DIMM0 Read DQS Timing Control Low */
- Set_NB32_index_wait(dev, index_reg, i + 0x100 * j, dword);
- }
-
- dword = 0x0000002f;
- for (j = 0; j < dn; j++)
- /* DIMM0 Read DQS ECC Timing Control */
- Set_NB32_index_wait(dev, index_reg, 7 + 0x100 * j, dword);
-}
-
-
-void SetEccDQSRcvrEn_D(struct DCTStatStruc *pDCTstat, u8 Channel)
-{
- u32 dev;
- u32 index_reg;
- u32 index;
- u8 ChipSel;
- u8 *p;
- u32 val;
-
- dev = pDCTstat->dev_dct;
- index_reg = 0x98 + Channel * 0x100;
- index = 0x12;
- p = pDCTstat->persistentData.CH_D_BC_RCVRDLY[Channel];
- print_debug_dqs("\t\tSetEccDQSRcvrPos: Channel ", Channel, 2);
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel += 2) {
- val = p[ChipSel>>1];
- Set_NB32_index_wait(dev, index_reg, index, val);
- print_debug_dqs_pair("\t\tSetEccDQSRcvrPos: ChipSel ",
- ChipSel, " rcvr_delay ", val, 2);
- index += 3;
- }
-}
-
-
-static void CalcEccDQSRcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel)
-{
- u8 ChipSel;
- u16 EccDQSLike;
- u8 EccDQSScale;
- u32 val, val0, val1;
-
- EccDQSLike = pDCTstat->CH_EccDQSLike[Channel];
- EccDQSScale = pDCTstat->CH_EccDQSScale[Channel];
-
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel += 2) {
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, ChipSel)) {
- u8 *p;
- p = pDCTstat->persistentData.CH_D_B_RCVRDLY[Channel][ChipSel>>1];
-
- /* DQS Delay Value of Data Bytelane
- * most like ECC byte lane */
- val0 = p[EccDQSLike & 0x07];
- /* DQS Delay Value of Data Bytelane
- * 2nd most like ECC byte lane */
- val1 = p[(EccDQSLike>>8) & 0x07];
-
- if (val0 > val1) {
- val = val0 - val1;
- } else {
- val = val1 - val0;
- }
-
- val *= ~EccDQSScale;
- val >>= 8; // /256
-
- if (val0 > val1) {
- val -= val1;
- } else {
- val += val0;
- }
-
- pDCTstat->persistentData.CH_D_BC_RCVRDLY[Channel][ChipSel>>1] = val;
- }
- }
- SetEccDQSRcvrEn_D(pDCTstat, Channel);
-}
-
-void mctSetEccDQSRcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u8 i;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (!pDCTstat->NodePresent)
- break;
- if (pDCTstat->DCTSysLimit) {
- for (i = 0; i < 2; i++)
- CalcEccDQSRcvrEn_D(pMCTstat, pDCTstat, i);
- }
- }
-}
-
-
-void phyAssistedMemFnceTraining(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
-
- u8 Node = 0;
- struct DCTStatStruc *pDCTstat;
-
- // FIXME: skip for Ax
- while (Node < MAX_NODES_SUPPORTED) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->DCTSysLimit) {
- fenceDynTraining_D(pMCTstat, pDCTstat, 0);
- fenceDynTraining_D(pMCTstat, pDCTstat, 1);
- }
- Node++;
- }
-}
-
-
-static void fenceDynTraining_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u16 avRecValue;
- u32 val;
- u32 dev;
- u32 index_reg = 0x98 + 0x100 * dct;
- u32 index;
-
- /* BIOS first programs a seed value to the phase recovery engine
- * (recommended 19) registers.
- * Dram Phase Recovery Control Register (F2x[1,0]9C_x[51:50] and
- * F2x[1,0]9C_x52.) .
- */
-
- dev = pDCTstat->dev_dct;
- for (index = 0x50; index <= 0x52; index ++) {
- val = (FenceTrnFinDlySeed & 0x1F);
- if (index != 0x52) {
- val |= val << 8 | val << 16 | val << 24;
- }
- Set_NB32_index_wait(dev, index_reg, index, val);
- }
-
-
- /* Set F2x[1,0]9C_x08[PhyFenceTrEn]=1. */
- val = Get_NB32_index_wait(dev, index_reg, 0x08);
- val |= 1 << PhyFenceTrEn;
- Set_NB32_index_wait(dev, index_reg, 0x08, val);
-
- /* Wait 200 MEMCLKs. */
- mct_Wait(50000); /* wait 200us */
-
- /* Clear F2x[1,0]9C_x08[PhyFenceTrEn]=0. */
- val = Get_NB32_index_wait(dev, index_reg, 0x08);
- val &= ~(1 << PhyFenceTrEn);
- Set_NB32_index_wait(dev, index_reg, 0x08, val);
-
- /* BIOS reads the phase recovery engine registers
- * F2x[1,0]9C_x[51:50] and F2x[1,0]9C_x52. */
- avRecValue = 0;
- for (index = 0x50; index <= 0x52; index ++) {
- val = Get_NB32_index_wait(dev, index_reg, index);
- avRecValue += val & 0x7F;
- if (index != 0x52) {
- avRecValue += (val >> 8) & 0x7F;
- avRecValue += (val >> 16) & 0x7F;
- avRecValue += (val >> 24) & 0x7F;
- }
- }
-
- val = avRecValue / 9;
- if (avRecValue % 9)
- val++;
- avRecValue = val;
-
- /* Write the (averaged value -8) to F2x[1,0]9C_x0C[PhyFence]. */
- avRecValue -= 8;
- val = Get_NB32_index_wait(dev, index_reg, 0x0C);
- val &= ~(0x1F << 16);
- val |= (avRecValue & 0x1F) << 16;
- Set_NB32_index_wait(dev, index_reg, 0x0C, val);
-
- /* Rewrite F2x[1,0]9C_x04-DRAM Address/Command Timing Control Register
- * delays (both channels). */
- val = Get_NB32_index_wait(dev, index_reg, 0x04);
- Set_NB32_index_wait(dev, index_reg, 0x04, val);
-}
-
-
-void mct_Wait(u32 cycles)
-{
- u32 saved;
- u32 hi, lo, msr;
-
- /* Wait # of 50ns cycles
- This seems like a hack to me... */
-
- cycles <<= 3; /* x8 (number of 1.25ns ticks) */
-
- msr = 0x10; /* TSC */
- _RDMSR(msr, &lo, &hi);
- saved = lo;
- do {
- _RDMSR(msr, &lo, &hi);
- } while (lo - saved < cycles);
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctsrc1p.c b/src/northbridge/amd/amdmct/mct/mctsrc1p.c
deleted file mode 100644
index 8ae60253ab..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctsrc1p.c
+++ /dev/null
@@ -1,91 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "mct_d.h"
-
-u8 mct_checkNumberOfDqsRcvEn_1Pass(u8 pass)
-{
- u8 ret = 1;
- if (pass == SecondPass)
- ret = 0;
-
- return ret;
-}
-
-
-u32 SetupDqsPattern_1PassA(u8 pass)
-{
- return (u32) TestPattern1_D;
-}
-
-
-u32 SetupDqsPattern_1PassB(u8 pass)
-{
- return (u32) TestPattern0_D;
-}
-
-u8 mct_Get_Start_RcvrEnDly_1Pass(u8 pass)
-{
- return 0;
-}
-
-static u8 mct_Average_RcvrEnDly_1Pass(struct DCTStatStruc *pDCTstat, u8 Channel, u8 Receiver,
- u8 Pass)
-{
- u8 i, MaxValue;
- u8 *p;
- u8 val;
-
- MaxValue = 0;
- p = pDCTstat->persistentData.CH_D_B_RCVRDLY[Channel][Receiver >> 1];
-
- for (i = 0; i < 8; i++) {
- /* get left value from DCTStatStruc.CHA_D0_B0_RCVRDLY*/
- val = p[i];
- /* get right value from DCTStatStruc.CHA_D0_B0_RCVRDLY_1*/
- val += Pass1MemClkDly;
- /* write back the value to stack */
- if (val > MaxValue)
- MaxValue = val;
-
- p[i] = val;
- }
-
- return MaxValue;
-}
-
-#ifdef UNUSED_CODE
-static u8 mct_AdjustFinalDQSRcvValue_1Pass(u8 val_1p, u8 val_2p)
-{
- return (val_1p & 0xff) + ((val_2p & 0xff)<<8);
-}
-#endif
-
-u8 mct_SaveRcvEnDly_D_1Pass(struct DCTStatStruc *pDCTstat, u8 pass)
-{
- u8 ret;
- ret = 0;
- if ((pDCTstat->DqsRcvEn_Pass == 0xff) && (pass== FirstPass))
- ret = 2;
- return ret;
-}
-
-u8 mct_Average_RcvrEnDly_Pass(struct DCTStatStruc *pDCTstat,
- u8 RcvrEnDly, u8 RcvrEnDlyLimit,
- u8 Channel, u8 Receiver, u8 Pass)
-
-{
- return mct_Average_RcvrEnDly_1Pass(pDCTstat, Channel, Receiver, Pass);
-}
diff --git a/src/northbridge/amd/amdmct/mct/mctsrc2p.c b/src/northbridge/amd/amdmct/mct/mctsrc2p.c
deleted file mode 100644
index ab278e9199..0000000000
--- a/src/northbridge/amd/amdmct/mct/mctsrc2p.c
+++ /dev/null
@@ -1,130 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; either version 2 of the License, or
- * (at your option) any later version.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-
-u8 mct_checkNumberOfDqsRcvEn_Pass(u8 pass)
-{
- return 1;
-}
-
-
-u32 SetupDqsPattern_PassA(u8 Pass)
-{
- u32 ret;
- if (Pass == FirstPass)
- ret = (u32) TestPattern1_D;
- else
- ret = (u32) TestPattern2_D;
-
- return ret;
-}
-
-
-u32 SetupDqsPattern_PassB(u8 Pass)
-{
- u32 ret;
- if (Pass == FirstPass)
- ret = (u32) TestPattern0_D;
- else
- ret = (u32) TestPattern2_D;
-
- return ret;
-}
-
-
-u8 mct_Get_Start_RcvrEnDly_Pass(struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 Receiver,
- u8 Pass)
-{
- u8 RcvrEnDly;
-
- if (Pass == FirstPass)
- RcvrEnDly = 0;
- else {
- u8 max = 0;
- u8 val;
- u8 i;
- u8 *p = pDCTstat->persistentData.CH_D_B_RCVRDLY[Channel][Receiver>>1];
- u8 bn;
- bn = 8;
-
- for (i = 0; i < bn; i++) {
- val = p[i];
- if (val > max) {
- max = val;
- }
- }
- RcvrEnDly = max;
-// while (1) {; }
-// RcvrEnDly += secPassOffset; //FIXME Why
- }
-
- return RcvrEnDly;
-}
-
-
-
-u8 mct_Average_RcvrEnDly_Pass(struct DCTStatStruc *pDCTstat,
- u8 RcvrEnDly, u8 RcvrEnDlyLimit,
- u8 Channel, u8 Receiver, u8 Pass)
-{
- u8 i;
- u8 *p;
- u8 *p_1;
- u8 val;
- u8 val_1;
- u8 valid = 1;
- u8 bn;
-
- bn = 8;
-
- p = pDCTstat->persistentData.CH_D_B_RCVRDLY[Channel][Receiver>>1];
-
- if (Pass == SecondPass) { /* second pass must average values */
- //FIXME: which byte?
- p_1 = pDCTstat->B_RCVRDLY_1;
-// p_1 = pDCTstat->persistentData.CH_D_B_RCVRDLY_1[Channel][Receiver>>1];
- for (i = 0; i < bn; i++) {
- val = p[i];
- /* left edge */
- if (val != (RcvrEnDlyLimit - 1)) {
- val -= Pass1MemClkDly;
- val_1 = p_1[i];
- val += val_1;
- val >>= 1;
- p[i] = val;
- } else {
- valid = 0;
- break;
- }
- }
- if (!valid) {
- pDCTstat->ErrStatus |= 1<<SB_NORCVREN;
- } else {
- pDCTstat->DimmTrainFail &= ~(1<<(Receiver + Channel));
- }
- } else {
- for (i = 0; i < bn; i++) {
- val = p[i];
- /* Add 1/2 Memlock delay */
- val += 0x5; // NOTE: middle value with DQSRCVEN_SAVED_GOOD_TIMES
- p[i] = val;
- pDCTstat->DimmTrainFail &= ~(1<<(Receiver + Channel));
- }
- }
-
- return RcvrEnDly;
-}
diff --git a/src/northbridge/amd/amdmct/mct/mcttmrl.c b/src/northbridge/amd/amdmct/mct/mcttmrl.c
deleted file mode 100644
index 6ec4d648d8..0000000000
--- a/src/northbridge/amd/amdmct/mct/mcttmrl.c
+++ /dev/null
@@ -1,409 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <console/console.h>
-#include <cpu/x86/cr.h>
-#include <cpu/amd/msr.h>
-
-#include "mct_d.h"
-
-/*
- * Description: Max Read Latency Training feature for DDR 2 MCT
- */
-
-static u8 CompareMaxRdLatTestPattern_D(u32 pattern_buf, u32 addr);
-static u32 GetMaxRdLatTestAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel,
- u8 *MaxRcvrEnDly, u8 *valid);
-u8 mct_GetStartMaxRdLat_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel,
- u8 DQSRcvEnDly, u32 *Margin);
-static void maxRdLatencyTrain_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_setMaxRdLatTrnVal_D(struct DCTStatStruc *pDCTstat, u8 Channel,
- u16 MaxRdLatVal);
-
-/*Warning: These must be located so they do not cross a logical 16-bit
- segment boundary!*/
-static const u32 TestMaxRdLAtPattern_D[] = {
- 0x6E0E3FAC, 0x0C3CFF52,
- 0x4A688181, 0x49C5B613,
- 0x7C780BA6, 0x5C1650E3,
- 0x0C4F9D76, 0x0C6753E6,
- 0x205535A5, 0xBABFB6CA,
- 0x610E6E5F, 0x0C5F1C87,
- 0x488493CE, 0x14C9C383,
- 0xF5B9A5CD, 0x9CE8F615,
-
- 0xAAD714B5, 0xC38F1B4C,
- 0x72ED647C, 0x669F7562,
- 0x5233F802, 0x4A898B30,
- 0x10A40617, 0x3326B465,
- 0x55386E04, 0xC807E3D3,
- 0xAB49E193, 0x14B4E63A,
- 0x67DF2495, 0xEA517C45,
- 0x7624CE51, 0xF8140C51,
-
- 0x4824BD23, 0xB61DD0C9,
- 0x072BCFBE, 0xE8F3807D,
- 0x919EA373, 0x25E30C47,
- 0xFEB12958, 0x4DA80A5A,
- 0xE9A0DDF8, 0x792B0076,
- 0xE81C73DC, 0xF025B496,
- 0x1DB7E627, 0x808594FE,
- 0x82668268, 0x655C7783,
-};
-
-
-static u32 SetupMaxRdPattern(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 *buffer)
-{
- /* 1. Copy the alpha and Beta patterns from ROM to Cache,
- * aligning on 16 byte boundary
- * 2. Set the ptr to Cacheable copy in DCTStatstruc.PtrPatternBufA
- * for Alpha
- * 3. Set the ptr to Cacheable copy in DCTStatstruc.PtrPatternBufB
- * for Beta
- */
-
- u32 *buf;
- u8 i;
-
- buf = (u32 *)(((u32)buffer + 0x10) & (0xfffffff0));
-
- for (i = 0; i < (16 * 3); i++) {
- buf[i] = TestMaxRdLAtPattern_D[i];
- }
-
- return (u32)buf;
-
-}
-
-
-void TrainMaxReadLatency_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (!pDCTstat->NodePresent)
- break;
-
- if (pDCTstat->DCTSysLimit)
- maxRdLatencyTrain_D(pMCTstat, pDCTstat);
- }
-}
-
-
-static void maxRdLatencyTrain_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 Channel;
- u32 TestAddr0;
- u8 _DisableDramECC = 0, _Wrap32Dis = 0, _SSE2 = 0;
- u16 MaxRdLatDly;
- u8 RcvrEnDly = 0;
- u32 PatternBuffer[60]; // FIXME: why not 48 + 4
- u32 Margin;
- u32 addr;
- CRx_TYPE cr4;
- u32 lo, hi;
-
- u8 valid;
- u32 pattern_buf;
-
- cr4 = read_cr4();
- if (cr4 & (1<<9)) { /* save the old value */
- _SSE2 = 1;
- }
- cr4 |= (1<<9); /* OSFXSR enable SSE2 */
- write_cr4(cr4);
-
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- if (lo & (1<<17)) { /* save the old value */
- _Wrap32Dis = 1;
- }
- lo |= (1<<17); /* HWCR.wrap32dis */
- lo &= ~(1<<15); /* SSEDIS */
- /* Setting wrap32dis allows 64-bit memory references in
- real mode */
- _WRMSR(addr, lo, hi);
-
- _DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
-
- pattern_buf = SetupMaxRdPattern(pMCTstat, pDCTstat, PatternBuffer);
-
- for (Channel = 0; Channel < 2; Channel++) {
- print_debug_dqs("\tMaxRdLatencyTrain51: Channel ",Channel, 1);
- pDCTstat->Channel = Channel;
-
- if ((pDCTstat->Status & (1 << SB_128bitmode)) && Channel)
- break; /*if ganged mode, skip DCT 1 */
-
- TestAddr0 = GetMaxRdLatTestAddr_D(pMCTstat, pDCTstat, Channel, &RcvrEnDly, &valid);
- if (!valid) /* Address not supported on current CS */
- continue;
- /* rank 1 of DIMM, testpattern 0 */
- WriteMaxRdLat1CLTestPattern_D(pattern_buf, TestAddr0);
-
- MaxRdLatDly = mct_GetStartMaxRdLat_D(pMCTstat, pDCTstat, Channel, RcvrEnDly, &Margin);
- print_debug_dqs("\tMaxRdLatencyTrain52: MaxRdLatDly start ", MaxRdLatDly, 2);
- print_debug_dqs("\tMaxRdLatencyTrain52: MaxRdLatDly Margin ", Margin, 2);
- while (MaxRdLatDly < MAX_RD_LAT) { /* sweep Delay value here */
- mct_setMaxRdLatTrnVal_D(pDCTstat, Channel, MaxRdLatDly);
- ReadMaxRdLat1CLTestPattern_D(TestAddr0);
- if (CompareMaxRdLatTestPattern_D(pattern_buf, TestAddr0) == DQS_PASS)
- break;
- SetTargetWTIO_D(TestAddr0);
- FlushMaxRdLatTestPattern_D(TestAddr0);
- ResetTargetWTIO_D();
- MaxRdLatDly++;
- }
- print_debug_dqs("\tMaxRdLatencyTrain53: MaxRdLatDly end ", MaxRdLatDly, 2);
- mct_setMaxRdLatTrnVal_D(pDCTstat, Channel, MaxRdLatDly + Margin);
- }
-
- if (_DisableDramECC) {
- mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
- }
-
- if (!_Wrap32Dis) {
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(addr, lo, hi);
- }
- if (!_SSE2) {
- cr4 = read_cr4();
- cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
- write_cr4(cr4);
- }
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 Channel;
- printk(BIOS_DEBUG, "maxRdLatencyTrain: CH_MaxRdLat:\n");
- for (Channel = 0; Channel < 2; Channel++) {
- printk(BIOS_DEBUG, "Channel: %02x: %02x\n", Channel, pDCTstat->CH_MaxRdLat[Channel]);
- }
- }
-#endif
-
-}
-
-static void mct_setMaxRdLatTrnVal_D(struct DCTStatStruc *pDCTstat,
- u8 Channel, u16 MaxRdLatVal)
-{
- u8 i;
- u32 reg;
- u32 dev;
- u32 val;
-
- if (pDCTstat->GangedMode) {
- Channel = 0; // for safe
- for (i = 0; i < 2; i++)
- pDCTstat->CH_MaxRdLat[i] = MaxRdLatVal;
- } else {
- pDCTstat->CH_MaxRdLat[Channel] = MaxRdLatVal;
- }
-
- dev = pDCTstat->dev_dct;
- reg = 0x78 + Channel * 0x100;
- val = Get_NB32(dev, reg);
- val &= ~(0x3ff<<22);
- val |= MaxRdLatVal << 22;
- /* program MaxRdLatency to correspond with current delay */
- Set_NB32(dev, reg, val);
-
-}
-
-
-static u8 CompareMaxRdLatTestPattern_D(u32 pattern_buf, u32 addr)
-{
- /* Compare only the first beat of data. Since target addrs are cache
- * line aligned, the Channel parameter is used to determine which cache
- * QW to compare.
- */
-
- u32 *test_buf = (u32 *)pattern_buf;
- u32 addr_lo;
- u32 val, val_test;
- int i;
- u8 ret = DQS_PASS;
-
- SetUpperFSbase(addr);
- addr_lo = addr << 8;
-
- _EXECFENCE;
- for (i = 0; i < (16*3); i++) {
- val = read32_fs(addr_lo);
- val_test = test_buf[i];
-
- print_debug_dqs_pair("\t\t\t\t\t\ttest_buf = ", (u32)test_buf, " value = ", val_test, 5);
- print_debug_dqs_pair("\t\t\t\t\t\ttaddr_lo = ", addr_lo, " value = ", val, 5);
- if (val != val_test) {
- ret = DQS_FAIL;
- break;
- }
- addr_lo += 4;
- }
-
- return ret;
-}
-
-static u32 GetMaxRdLatTestAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 *MaxRcvrEnDly,
- u8 *valid)
-{
- u8 Max = 0;
-
- u8 Channel_Max = 0;
- u8 d;
- u8 d_Max = 0;
-
- u8 Byte;
- u32 TestAddr0 = 0;
- u8 ch, ch_start, ch_end;
- u8 bn;
-
- bn = 8;
-
- if (pDCTstat->Status & (1 << SB_128bitmode)) {
- ch_start = 0;
- ch_end = 2;
- } else {
- ch_start = Channel;
- ch_end = Channel + 1;
- }
-
- *valid = 0;
-
- for (ch = ch_start; ch < ch_end; ch++) {
- for (d = 0; d < 4; d++) {
- for (Byte = 0; Byte < bn; Byte++) {
- u8 tmp;
- tmp = pDCTstat->persistentData.CH_D_B_RCVRDLY[ch][d][Byte];
- if (tmp > Max) {
- Max = tmp;
- Channel_Max = Channel;
- d_Max = d;
- }
- }
- }
- }
-
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel_Max, d_Max << 1)) {
- TestAddr0 = mct_GetMCTSysAddr_D(pMCTstat, pDCTstat, Channel_Max, d_Max << 1, valid);
- }
-
- if (*valid)
- *MaxRcvrEnDly = Max;
-
- return TestAddr0;
-
-}
-
-u8 mct_GetStartMaxRdLat_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 DQSRcvEnDly, u32 *Margin)
-{
- u32 SubTotal;
- u32 val;
- u32 valx;
- u32 valxx;
- u32 index_reg;
- u32 reg_off;
- u32 dev;
-
- if (pDCTstat->GangedMode)
- Channel = 0;
-
- index_reg = 0x98 + 0x100 * Channel;
-
- reg_off = 0x100 * Channel;
- dev = pDCTstat->dev_dct;
-
- /* Multiply the CAS Latency by two to get a number of 1/2 MEMCLKs units.*/
- val = Get_NB32(dev, 0x88 + reg_off);
- SubTotal = ((val & 0x0f) + 1) << 1; /* SubTotal is 1/2 Memclk unit */
-
- /* If registered DIMMs are being used then add 1 MEMCLK to the sub-total*/
- val = Get_NB32(dev, 0x90 + reg_off);
- if (!(val & (1 << UnBuffDimm)))
- SubTotal += 2;
-
- /*If the address prelaunch is setup for 1/2 MEMCLKs then add 1,
- * else add 2 to the sub-total. if (AddrCmdSetup || CsOdtSetup
- * || CkeSetup) then K := K + 2; */
- val = Get_NB32_index_wait(dev, index_reg, 0x04);
- if (!(val & 0x00202020))
- SubTotal += 1;
- else
- SubTotal += 2;
-
- /* If the F2x[1, 0]78[RdPtrInit] field is 4, 5, 6 or 7 MEMCLKs,
- * then add 4, 3, 2, or 1 MEMCLKs, respectively to the sub-total. */
- val = Get_NB32(dev, 0x78 + reg_off);
- SubTotal += 8 - (val & 0x0f);
-
- /* Convert bits 7-5 (also referred to as the course delay) of the current
- * (or worst case) DQS receiver enable delay to 1/2 MEMCLKs units,
- * rounding up, and add this to the sub-total. */
- SubTotal += DQSRcvEnDly >> 5; /*BOZO-no rounding up */
-
- SubTotal <<= 1; /*scale 1/2 MemClk to 1/4 MemClk */
-
- /* Convert the sub-total (in 1/2 MEMCLKs) to northbridge clocks (NCLKs)
- * as follows (assuming DDR400 and assuming that no P-state or link speed
- * changes have occurred). */
-
- /*New formula:
- SubTotal *= 3*(Fn2xD4[NBFid]+4)/(3+Fn2x94[MemClkFreq])/2 */
- val = Get_NB32(dev, 0x94 + reg_off);
- /* SubTotal div 4 to scale 1/4 MemClk back to MemClk */
- val &= 7;
- if (val == 4) {
- val++; /* adjust for DDR2-1066 */
- }
- valx = (val + 3) << 2; /* SubTotal div 4 to scale 1/4 MemClk back to MemClk */
-
-
- val = Get_NB32(pDCTstat->dev_nbmisc, 0xD4);
- val = ((val & 0x1f) + 4) * 3;
-
- /* Calculate 1 MemClk + 1 NCLK delay in NCLKs for margin */
- valxx = val << 2;
- valxx /= valx;
- if (valxx % valx)
- valxx++; /* round up */
- valxx++; /* add 1NCLK */
- *Margin = valxx; /* one MemClk delay in NCLKs and one additional NCLK */
-
- val *= SubTotal;
-
- val /= valx;
- if (val % valx)
- val++; /* round up */
-
-
-
- return val;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/Makefile.inc b/src/northbridge/amd/amdmct/mct_ddr3/Makefile.inc
deleted file mode 100644
index 65c146a662..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/Makefile.inc
+++ /dev/null
@@ -1,31 +0,0 @@
-ifeq ($(CONFIG_NORTHBRIDGE_AMD_AMDFAM10),y)
-
-# DDR3
-romstage-$(CONFIG_HAVE_ACPI_RESUME) += s3utils.c
-romstage-y += mct_d.c mctmtr_d.c mctcsi_d.c mctecc_d.c mctdqs_d.c mctsrc.c
-romstage-y += mctsdi.c mctprod.c mctproc.c mctprob.c mcthwl.c mctwl.c
-romstage-y += mport_d.c mutilc_d.c modtrdim.c mhwlc_d.c mctrci.c mctsrc1p.c
-romstage-y += mcttmrl.c mcthdi.c mctndi_d.c mctchi_d.c modtrd.c mct_d_gcc.c
-
-ifeq ($(CONFIG_CPU_SOCKET_TYPE), 0x11)
-romstage-y += mctardk5.c
-endif
-ifeq ($(CONFIG_CPU_SOCKET_TYPE), 0x13)
-romstage-y += mctardk5.c
-endif
-ifeq ($(CONFIG_CPU_SOCKET_TYPE), 0x14)
-romstage-y += mctardk5.c
-endif
-ifeq ($(CONFIG_CPU_SOCKET_TYPE), 0x15)
-romstage-y += mctardk5.c
-endif
-ifeq ($(CONFIG_CPU_SOCKET_TYPE), 0x16)
-romstage-y += mctardk5.c
-endif
-ifeq ($(CONFIG_CPU_SOCKET_TYPE), 0x12)
-romstage-y += mctardk6.c
-endif
-
-ramstage-$(CONFIG_HAVE_ACPI_RESUME) += s3utils.c
-
-endif
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mct_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mct_d.c
deleted file mode 100644
index fa8c71447b..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mct_d.c
+++ /dev/null
@@ -1,8220 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015-2017 Raptor Engineering, LLC
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* Description: Main memory controller system configuration for DDR 3 */
-
-/* KNOWN ISSUES - ERRATA
- *
- * Trtp is not calculated correctly when the controller is in 64-bit mode, it
- * is 1 busclock off. No fix planned. The controller is not ordinarily in
- * 64-bit mode.
- *
- * 32 Byte burst not supported. No fix planned. The controller is not
- * ordinarily in 64-bit mode.
- *
- * Trc precision does not use extra Jedec defined fractional component.
- * InsteadTrc (course) is rounded up to nearest 1 ns.
- *
- * Mini and Micro DIMM not supported. Only RDIMM, UDIMM, SO-DIMM defined types
- * supported.
- */
-
-#include <console/console.h>
-#include <northbridge/amd/amdfam10/debug.h>
-#include <northbridge/amd/amdfam10/raminit.h>
-#include <northbridge/amd/amdfam10/amdfam10.h>
-#include <southbridge/amd/common/reset.h>
-#include <cpu/x86/msr.h>
-#include <cpu/amd/msr.h>
-#include <cpu/x86/mtrr.h>
-#include <device/pci_ops.h>
-#include <arch/acpi.h>
-#include <string.h>
-#include <types.h>
-#include <device/dram/ddr3.h>
-
-#include "s3utils.h"
-#include "mct_d_gcc.h"
-#include "mct_d.h"
-
-static u8 ReconfigureDIMMspare_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void DQSTiming_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA,
- uint8_t allow_config_restore);
-static void LoadDQSSigTmgRegs_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void HTMemMapInit_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void SyncDCTsReady_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void ClearDCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 AutoCycTiming_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void GetPresetmaxF_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void SPDGetTCL_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 AutoConfig_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void SPDSetBanks_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void StitchMemory_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u16 Get_Fk_D(u8 k);
-static u8 Get_DIMMAddress_D(struct DCTStatStruc *pDCTstat, u8 i);
-static void mct_preInitDCT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_initDCT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_DramInit(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_SyncDCTsReady(struct DCTStatStruc *pDCTstat);
-static void Get_Trdrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_AfterGetCLT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 mct_SPDCalcWidth(struct MCTStatStruc *pMCTstat,\
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_AfterStitchMemory(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u8 mct_DIMMPresence(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Set_OtherTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Get_Twrwr(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Get_Twrrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Get_TrwtTO(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void Get_TrwtWB(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void Get_DqsRcvEnGross_Diff(struct DCTStatStruc *pDCTstat,
- u32 dev, uint8_t dct, u32 index_reg);
-static void Get_WrDatGross_Diff(struct DCTStatStruc *pDCTstat, u8 dct,
- u32 dev, u32 index_reg);
-static u16 Get_DqsRcvEnGross_MaxMin(struct DCTStatStruc *pDCTstat,
- u32 dev, uint8_t dct, u32 index_reg, u32 index);
-static void mct_FinalMCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static u16 Get_WrDatGross_MaxMin(struct DCTStatStruc *pDCTstat, u8 dct,
- u32 dev, u32 index_reg, u32 index);
-static void mct_InitialMCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_init(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void clear_legacy_Mode(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_HTMemMapExt(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void SetCSTriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void SetCKETriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void SetODTTriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void InitDDRPhy(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u32 mct_NodePresent_D(void);
-static void mct_OtherTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void mct_ResetDataStruct_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void mct_EarlyArbEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_BeforeDramInit_Prod_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_ProgramODT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-void mct_ClrClToNB_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static u8 CheckNBCOFEarlyArbEn(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void mct_ClrWbEnhWsbDis_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_BeforeDQSTrain_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static void AfterDramInit_D(struct DCTStatStruc *pDCTstat, u8 dct);
-static void mct_ResetDLL_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static u32 mct_DisDllShutdownSR(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 DramConfigLo, u8 dct);
-static void mct_EnDllShutdownSR(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-void ChangeMemClk(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-
-static u8 Get_Latency_Diff(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-static void SyncSetting(struct DCTStatStruc *pDCTstat);
-static uint8_t crcCheck(struct DCTStatStruc *pDCTstat, uint8_t dimm);
-
-uint8_t is_ecc_enabled(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-
-/*See mctAutoInitMCT header for index relationships to CL and T*/
-static const u16 Table_F_k[] = {00,200,266,333,400,533 };
-static const u8 Tab_BankAddr[] = {0x3F,0x01,0x09,0x3F,0x3F,0x11,0x0A,0x19,0x12,0x1A,0x21,0x22,0x23};
-const u8 Table_DQSRcvEn_Offset[] = {0x00,0x01,0x10,0x11,0x2};
-
-/****************************************************************************
- Describe how platform maps MemClk pins to logical DIMMs. The MemClk pins
- are identified based on BKDG definition of Fn2x88[MemClkDis] bitmap.
- AGESA will base on this value to disable unused MemClk to save power.
-
- If MEMCLK_MAPPING or MEMCLK_MAPPING contains all zeroes, AGESA will use
- default MemClkDis setting based on package type.
-
- Example:
- BKDG definition of Fn2x88[MemClkDis] bitmap for AM3 package is like below:
- Bit AM3/S1g3 pin name
- 0 M[B,A]_CLK_H/L[0]
- 1 M[B,A]_CLK_H/L[1]
- 2 M[B,A]_CLK_H/L[2]
- 3 M[B,A]_CLK_H/L[3]
- 4 M[B,A]_CLK_H/L[4]
- 5 M[B,A]_CLK_H/L[5]
- 6 M[B,A]_CLK_H/L[6]
- 7 M[B,A]_CLK_H/L[7]
-
- And platform has the following routing:
- CS0 M[B,A]_CLK_H/L[4]
- CS1 M[B,A]_CLK_H/L[2]
- CS2 M[B,A]_CLK_H/L[3]
- CS3 M[B,A]_CLK_H/L[5]
-
- Then:
- ; CS0 CS1 CS2 CS3 CS4 CS5 CS6 CS7
- MEMCLK_MAPPING EQU 00010000b, 00000100b, 00001000b, 00100000b, 00000000b, 00000000b, 00000000b, 00000000b
-*/
-
-/* ==========================================================================================
- * Set up clock pin to DIMM mappings,
- * NOTE: If you are not sure about the pin mappings, you can keep all MemClk signals active,
- * just set all entries in the relevant table(s) to 0xff.
- * ==========================================================================================
- */
-static const u8 Tab_L1CLKDis[] = {0x20, 0x20, 0x10, 0x10, 0x08, 0x08, 0x04, 0x04};
-static const u8 Tab_AM3CLKDis[] = {0xFF, 0xFF, 0xFF, 0xFF, 0x00, 0x00, 0x00, 0x00};
-static const u8 Tab_S1CLKDis[] = {0xA2, 0xA2, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
-
-/* C32: Enable CS0 - CS3 clocks (DIMM0 - DIMM1) */
-static const u8 Tab_C32CLKDis[] = {0xFF, 0xFF, 0xFF, 0xFF, 0x00, 0x00, 0x00, 0x00};
-
-/* G34: Enable CS0 - CS3 clocks (DIMM0 - DIMM1) */
-static const u8 Tab_G34CLKDis[] = {0xFF, 0xFF, 0xFF, 0xFF, 0x00, 0x00, 0x00, 0x00};
-
-/* FM2: Enable all the clocks for the dimms */
-static const u8 Tab_FM2CLKDis[] = {0xFF, 0xFF, 0xFF, 0xFF, 0x00, 0x00, 0x00, 0x00};
-
-static const u8 Tab_ManualCLKDis[]= {0x10, 0x04, 0x08, 0x20, 0x00, 0x00, 0x00, 0x00};
-/* ========================================================================================== */
-
-static const u8 Table_Comp_Rise_Slew_20x[] = {7, 3, 2, 2, 0xFF};
-static const u8 Table_Comp_Rise_Slew_15x[] = {7, 7, 3, 2, 0xFF};
-static const u8 Table_Comp_Fall_Slew_20x[] = {7, 5, 3, 2, 0xFF};
-static const u8 Table_Comp_Fall_Slew_15x[] = {7, 7, 5, 3, 0xFF};
-
-uint8_t dct_ddr_voltage_index(struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- uint8_t dimm;
- uint8_t ddr_voltage_index = 0;
-
- /* If no DIMMs are present on this DCT, report 1.5V operation and skip checking the hardware */
- if (pDCTstat->DIMMValidDCT[dct] == 0)
- return 0x1;
-
- /* Find current DDR supply voltage for this DCT */
- for (dimm = 0; dimm < MAX_DIMMS_SUPPORTED; dimm++) {
- if (pDCTstat->DIMMValidDCT[dct] & (1 << dimm))
- ddr_voltage_index |= pDCTstat->DimmConfiguredVoltage[dimm];
- }
- if (ddr_voltage_index > 0x7) {
- printk(BIOS_DEBUG, "%s: Insufficient DDR supply voltage indicated! Configuring processor for 1.25V operation, but this attempt may fail...\n", __func__);
- ddr_voltage_index = 0x4;
- }
- if (ddr_voltage_index == 0x0) {
- printk(BIOS_DEBUG, "%s: No DDR supply voltage indicated! Configuring processor for 1.5V operation, but this attempt may fail...\n", __func__);
- ddr_voltage_index = 0x1;
- }
-
- return ddr_voltage_index;
-}
-
-static uint16_t fam15h_mhz_to_memclk_config(uint16_t freq)
-{
- uint16_t fam15h_freq_tab[] = {0, 0, 0, 0, 333, 0, 400, 0, 0, 0, 533, 0, 0, 0, 667, 0, 0, 0, 800, 0, 0, 0, 933};
- uint16_t iter;
-
- /* Compute the index value for the given frequency */
- for (iter = 0; iter <= 0x16; iter++) {
- if (fam15h_freq_tab[iter] == freq) {
- freq = iter;
- break;
- }
- }
- if (freq == 0)
- freq = 0x4;
-
- return freq;
-}
-
-static uint16_t fam10h_mhz_to_memclk_config(uint16_t freq)
-{
- uint16_t fam10h_freq_tab[] = {0, 0, 0, 400, 533, 667, 800};
- uint16_t iter;
-
- /* Compute the index value for the given frequency */
- for (iter = 0; iter <= 0x6; iter++) {
- if (fam10h_freq_tab[iter] == freq) {
- freq = iter;
- break;
- }
- }
- if (freq == 0)
- freq = 0x3;
-
- return freq;
-}
-
-static inline uint8_t is_model10_1f(void)
-{
- uint8_t model101f = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0x0ff000) >> 12);
-
- if (family >= 0x10 && family <= 0x1f)
- /* Model 0x10 to 0x1f */
- model101f = 1;
-
- return model101f;
-}
-
-uint8_t is_ecc_enabled(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat)
-{
- uint8_t ecc_enabled = 1;
-
- if (!pMCTstat->try_ecc)
- ecc_enabled = 0;
-
- if (pDCTstat->NodePresent && (pDCTstat->DIMMValidDCT[0] || pDCTstat->DIMMValidDCT[1]))
- if (!(pDCTstat->Status & (1 << SB_ECCDIMMs)))
- ecc_enabled = 0;
-
- return !!ecc_enabled;
-}
-
-uint8_t get_available_lane_count(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat)
-{
- if (is_ecc_enabled(pMCTstat, pDCTstat))
- return 9;
- else
- return 8;
-}
-
-uint16_t mhz_to_memclk_config(uint16_t freq)
-{
- if (is_fam15h())
- return fam15h_mhz_to_memclk_config(freq);
- else
- return fam10h_mhz_to_memclk_config(freq) + 1;
-}
-
-uint32_t fam10h_address_timing_compensation_code(struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- uint8_t package_type;
- uint32_t calibration_code = 0;
-
- package_type = mctGet_NVbits(NV_PACK_TYPE);
- uint16_t MemClkFreq = (Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x7) + 1;
-
- /* Obtain number of DIMMs on channel */
- uint8_t dimm_count = pDCTstat->MAdimms[dct];
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
-
- if (package_type == PT_GR) {
- /* Socket G34 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam10h BKDG Rev. 3.62 section 2.8.9.5.8 Tables 60 - 61 */
- if (MaxDimmsInstallable == 1) {
- if (MemClkFreq == 0x4) {
- /* DDR3-800 */
- calibration_code = 0x00000000;
- } else if (MemClkFreq == 0x5) {
- /* DDR3-1066 */
- calibration_code = 0x003c3c3c;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-1333 */
- calibration_code = 0x003a3a3a;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if (MemClkFreq == 0x4) {
- /* DDR3-800 */
- calibration_code = 0x00000000;
- } else if (MemClkFreq == 0x5) {
- /* DDR3-1066 */
- calibration_code = 0x003c3c3c;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-1333 */
- calibration_code = 0x003a3a3a;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- if (MemClkFreq == 0x4) {
- /* DDR3-800 */
- calibration_code = 0x00000000;
- } else if (MemClkFreq == 0x5) {
- /* DDR3-1066 */
- calibration_code = 0x003a3c3a;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-1333 */
- calibration_code = 0x00383a38;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else {
- /* UDIMM */
- /* Fam10h BKDG Rev. 3.62 section 2.8.9.5.8 Table 56 */
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-800 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0x5) {
- /* DDR3-1066 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x00380000;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-1333 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x00360000;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-800 */
- calibration_code = 0x00390039;
- } else if (MemClkFreq == 0x5) {
- /* DDR3-1066 */
- calibration_code = 0x00350037;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-1333 */
- calibration_code = 0x00000035;
- }
- }
- }
- } else {
- /* TODO
- * Other socket support unimplemented
- */
- }
-
- return calibration_code;
-}
-
-static uint32_t fam15h_phy_predriver_calibration_code(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t drive_strength)
-{
- uint8_t lrdimm = 0;
- uint8_t package_type;
- uint8_t ddr_voltage_index;
- uint32_t calibration_code = 0;
- uint16_t MemClkFreq = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
-
- ddr_voltage_index = dct_ddr_voltage_index(pDCTstat, dct);
- package_type = mctGet_NVbits(NV_PACK_TYPE);
-
- if (!lrdimm) {
- /* Not an LRDIMM */
- if ((package_type == PT_M2) || (package_type == PT_GR)) {
- /* Socket AM3 or G34 */
- if (ddr_voltage_index & 0x4) {
- /* 1.25V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 43 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x2)
- calibration_code = 0x924;
- else if (drive_strength == 0x3)
- calibration_code = 0x6db;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xfff;
- else if (drive_strength == 0x2)
- calibration_code = 0xdb6;
- else if (drive_strength == 0x3)
- calibration_code = 0x924;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xfff;
- else if (drive_strength == 0x2)
- calibration_code = 0xfff;
- else if (drive_strength == 0x3)
- calibration_code = 0xfff;
- }
- } else if (ddr_voltage_index & 0x2) {
- /* 1.35V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 42 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0x924;
- else if (drive_strength == 0x2)
- calibration_code = 0x6db;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xdb6;
- else if (drive_strength == 0x2)
- calibration_code = 0xbd6;
- else if (drive_strength == 0x3)
- calibration_code = 0x6db;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xfff;
- else if (drive_strength == 0x2)
- calibration_code = 0xfff;
- else if (drive_strength == 0x3)
- calibration_code = 0xdb6;
- }
- } else if (ddr_voltage_index & 0x1) {
- /* 1.5V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 41 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x1)
- calibration_code = 0x6db;
- else if (drive_strength == 0x2)
- calibration_code = 0x492;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0x924;
- else if (drive_strength == 0x2)
- calibration_code = 0x6db;
- else if (drive_strength == 0x3)
- calibration_code = 0x6db;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xfff;
- else if (drive_strength == 0x2)
- calibration_code = 0xfff;
- else if (drive_strength == 0x3)
- calibration_code = 0xb6d;
- }
- }
- } else if (package_type == PT_C3) {
- /* Socket C32 */
- if (ddr_voltage_index & 0x4) {
- /* 1.25V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 46 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x2)
- calibration_code = 0x924;
- else if (drive_strength == 0x3)
- calibration_code = 0x6db;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xfff;
- else if (drive_strength == 0x2)
- calibration_code = 0xdb6;
- else if (drive_strength == 0x3)
- calibration_code = 0x924;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x1)
- calibration_code = 0x6db;
- else if (drive_strength == 0x2)
- calibration_code = 0x492;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xfff;
- else if (drive_strength == 0x2)
- calibration_code = 0xfff;
- else if (drive_strength == 0x3)
- calibration_code = 0xfff;
- }
- } else if (ddr_voltage_index & 0x2) {
- /* 1.35V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 45 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0x924;
- else if (drive_strength == 0x2)
- calibration_code = 0x6db;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xdb6;
- else if (drive_strength == 0x2)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x3)
- calibration_code = 0x6db;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0x924;
- else if (drive_strength == 0x2)
- calibration_code = 0x6db;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xfff;
- else if (drive_strength == 0x2)
- calibration_code = 0xfff;
- else if (drive_strength == 0x3)
- calibration_code = 0xdb6;
- }
- } else if (ddr_voltage_index & 0x1) {
- /* 1.5V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 44 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x1)
- calibration_code = 0x6db;
- else if (drive_strength == 0x2)
- calibration_code = 0x492;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0x924;
- else if (drive_strength == 0x2)
- calibration_code = 0x6db;
- else if (drive_strength == 0x3)
- calibration_code = 0x6db;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x1)
- calibration_code = 0x6db;
- else if (drive_strength == 0x2)
- calibration_code = 0x492;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xfff;
- else if (drive_strength == 0x1)
- calibration_code = 0xfff;
- else if (drive_strength == 0x2)
- calibration_code = 0xfff;
- else if (drive_strength == 0x3)
- calibration_code = 0xb6d;
- }
- }
- } else if (package_type == PT_FM2) {
- /* Socket FM2 */
- if (ddr_voltage_index & 0x1) {
- /* 1.5V */
- /* Fam15h BKDG Rev. 3.12 section 2.9.5.4.4 Table 22 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- calibration_code = 0xb24;
- } else if (MemClkFreq >= 0xa) {
- /* DDR3-1066 or higher */
- calibration_code = 0xff6;
- }
- }
- }
- } else {
- /* LRDIMM */
-
- /* TODO
- * Implement LRDIMM support
- * See Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Tables 47 - 49
- */
- }
-
- return calibration_code;
-}
-
-static uint32_t fam15h_phy_predriver_cmd_addr_calibration_code(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t drive_strength)
-{
- uint8_t ddr_voltage_index;
- uint32_t calibration_code = 0;
- uint16_t MemClkFreq = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
-
- ddr_voltage_index = dct_ddr_voltage_index(pDCTstat, dct);
-
- if (ddr_voltage_index & 0x4) {
- /* 1.25V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 52 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0x492;
- else if (drive_strength == 0x1)
- calibration_code = 0x492;
- else if (drive_strength == 0x2)
- calibration_code = 0x492;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xdad;
- else if (drive_strength == 0x1)
- calibration_code = 0x924;
- else if (drive_strength == 0x2)
- calibration_code = 0x6db;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xff6;
- else if (drive_strength == 0x1)
- calibration_code = 0xdad;
- else if (drive_strength == 0x2)
- calibration_code = 0xb64;
- else if (drive_strength == 0x3)
- calibration_code = 0xb64;
- }
- } else if (ddr_voltage_index & 0x2) {
- /* 1.35V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 51 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0x492;
- else if (drive_strength == 0x1)
- calibration_code = 0x492;
- else if (drive_strength == 0x2)
- calibration_code = 0x492;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0x924;
- else if (drive_strength == 0x1)
- calibration_code = 0x6db;
- else if (drive_strength == 0x2)
- calibration_code = 0x6db;
- else if (drive_strength == 0x3)
- calibration_code = 0x6db;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x1)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x2)
- calibration_code = 0x924;
- else if (drive_strength == 0x3)
- calibration_code = 0x924;
- }
- } else if (ddr_voltage_index & 0x1) {
- /* 1.5V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 50 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0x492;
- else if (drive_strength == 0x1)
- calibration_code = 0x492;
- else if (drive_strength == 0x2)
- calibration_code = 0x492;
- else if (drive_strength == 0x3)
- calibration_code = 0x492;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0x6db;
- else if (drive_strength == 0x1)
- calibration_code = 0x6db;
- else if (drive_strength == 0x2)
- calibration_code = 0x6db;
- else if (drive_strength == 0x3)
- calibration_code = 0x6db;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x1)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x2)
- calibration_code = 0xb6d;
- else if (drive_strength == 0x3)
- calibration_code = 0xb6d;
- }
- }
-
- return calibration_code;
-}
-
-static uint32_t fam15h_phy_predriver_clk_calibration_code(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t drive_strength)
-{
- uint8_t ddr_voltage_index;
- uint32_t calibration_code = 0;
- uint16_t MemClkFreq = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
-
- ddr_voltage_index = dct_ddr_voltage_index(pDCTstat, dct);
-
- if (ddr_voltage_index & 0x4) {
- /* 1.25V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 55 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0xdad;
- else if (drive_strength == 0x1)
- calibration_code = 0xdad;
- else if (drive_strength == 0x2)
- calibration_code = 0x924;
- else if (drive_strength == 0x3)
- calibration_code = 0x924;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xff6;
- else if (drive_strength == 0x1)
- calibration_code = 0xff6;
- else if (drive_strength == 0x2)
- calibration_code = 0xff6;
- else if (drive_strength == 0x3)
- calibration_code = 0xff6;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xff6;
- else if (drive_strength == 0x1)
- calibration_code = 0xff6;
- else if (drive_strength == 0x2)
- calibration_code = 0xff6;
- else if (drive_strength == 0x3)
- calibration_code = 0xff6;
- }
- } else if (ddr_voltage_index & 0x2) {
- /* 1.35V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 54 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0xdad;
- else if (drive_strength == 0x1)
- calibration_code = 0xdad;
- else if (drive_strength == 0x2)
- calibration_code = 0x924;
- else if (drive_strength == 0x3)
- calibration_code = 0x924;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xff6;
- else if (drive_strength == 0x1)
- calibration_code = 0xff6;
- else if (drive_strength == 0x2)
- calibration_code = 0xff6;
- else if (drive_strength == 0x3)
- calibration_code = 0xdad;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xff6;
- else if (drive_strength == 0x1)
- calibration_code = 0xff6;
- else if (drive_strength == 0x2)
- calibration_code = 0xff6;
- else if (drive_strength == 0x3)
- calibration_code = 0xdad;
- }
- } else if (ddr_voltage_index & 0x1) {
- /* 1.5V */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 53 */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (drive_strength == 0x0)
- calibration_code = 0x924;
- else if (drive_strength == 0x1)
- calibration_code = 0x924;
- else if (drive_strength == 0x2)
- calibration_code = 0x924;
- else if (drive_strength == 0x3)
- calibration_code = 0x924;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (drive_strength == 0x0)
- calibration_code = 0xff6;
- else if (drive_strength == 0x1)
- calibration_code = 0xff6;
- else if (drive_strength == 0x2)
- calibration_code = 0xff6;
- else if (drive_strength == 0x3)
- calibration_code = 0xb6d;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (drive_strength == 0x0)
- calibration_code = 0xff6;
- else if (drive_strength == 0x1)
- calibration_code = 0xff6;
- else if (drive_strength == 0x2)
- calibration_code = 0xff6;
- else if (drive_strength == 0x3)
- calibration_code = 0xff6;
- }
- }
-
- return calibration_code;
-}
-
-uint32_t fam15h_output_driver_compensation_code(struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- uint8_t package_type;
- uint32_t calibration_code = 0;
-
- package_type = mctGet_NVbits(NV_PACK_TYPE);
- uint16_t MemClkFreq = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
-
- /* Obtain number of DIMMs on channel */
- uint8_t dimm_count = pDCTstat->MAdimms[dct];
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
-
- if (package_type == PT_GR) {
- /* Socket G34 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 74 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x20112222;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- calibration_code = 0x30112222;
- } else if (MemClkFreq == 0x16) {
- /* DDR3-1866 */
- calibration_code = 0x30332222;
- }
-
- if (rank_count_dimm0 == 4) {
- calibration_code &= ~(0xff << 16);
- calibration_code |= 0x22 << 16;
- }
- } else if (MaxDimmsInstallable == 2) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x20112222;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- calibration_code = 0x30112222;
- }
-
- if ((rank_count_dimm0 == 4) || (rank_count_dimm1 == 4)) {
- calibration_code &= ~(0xff << 16);
- calibration_code |= 0x22 << 16;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x10222222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x20222222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x30222222;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x30222222;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- calibration_code = 0x30222222;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
- /* TODO
- * LRDIMM support unimplemented
- */
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 73 */
- if (MaxDimmsInstallable == 1) {
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x20112222;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- calibration_code = 0x30112222;
- } else if (MemClkFreq == 0x16) {
- /* DDR3-1866 */
- calibration_code = 0x30332222;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x20112222;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- calibration_code = 0x30112222;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x10222222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x20222222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x30222222;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x30222222;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- calibration_code = 0x30222222;
- else
- calibration_code = 0x30112222;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_C3) {
- /* Socket C32 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 77 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x20112222;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- calibration_code = 0x30112222;
- }
-
- if (rank_count_dimm0 == 4) {
- calibration_code &= ~(0xff << 16);
- calibration_code |= 0x22 << 16;
- }
- } else if (MaxDimmsInstallable == 2) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x20112222;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- calibration_code = 0x30112222;
- }
-
- if ((rank_count_dimm0 == 4) || (rank_count_dimm1 == 4)) {
- calibration_code &= ~(0xff << 16);
- calibration_code |= 0x22 << 16;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x10222222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x20222222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x30222222;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x30222222;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- calibration_code = 0x30222222;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
- /* TODO
- * LRDIMM support unimplemented
- */
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 73 */
- if (MaxDimmsInstallable == 1) {
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x20112222;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- calibration_code = 0x30112222;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x20112222;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- calibration_code = 0x30112222;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x10222222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x20222222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x30222222;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x30222222;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- calibration_code = 0x30222222;
- else
- calibration_code = 0x30112222;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_FM2) {
- /* Socket FM2 */
- /* Assume UDIMM */
- /* Fam15h Model10h BKDG Rev. 3.12 section 2.9.5.6.6 Table 32 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x20112222;
- } else if (MemClkFreq >= 0xe) {
- /* DDR3-1333 or higher */
- calibration_code = 0x30112222;
- }
- } else if (MaxDimmsInstallable == 2) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 or DDR3-800 */
- calibration_code = 0x00112222;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x10112222;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x20112222;
- } else if (MemClkFreq >= 0x12) {
- /* DDR3-1600 or higher */
- calibration_code = 0x30112222;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x10222322;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x20222322;
- } else if (MemClkFreq >= 0xa) {
- /* DDR3-1066 or higher */
- calibration_code = 0x30222322;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else {
- /* TODO
- * Other socket support unimplemented
- */
- }
-
- return calibration_code;
-}
-
-uint32_t fam15h_address_timing_compensation_code(struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- uint8_t package_type;
- uint32_t calibration_code = 0;
-
- package_type = mctGet_NVbits(NV_PACK_TYPE);
- uint16_t MemClkFreq = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
-
- /* Obtain number of DIMMs on channel */
- uint8_t dimm_count = pDCTstat->MAdimms[dct];
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
-
- if (package_type == PT_GR) {
- /* Socket G34 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 74 */
- if (MaxDimmsInstallable == 1) {
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- calibration_code = 0x00000000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x003c3c3c;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x003a3a3a;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- calibration_code = 0x00393939;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- calibration_code = 0x00000000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x00393c39;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00373a37;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- calibration_code = 0x00363936;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- calibration_code = 0x00000000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x003a3c3a;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00383a38;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- calibration_code = 0x00353935;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
- /* TODO
- * LRDIMM support unimplemented
- */
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 76 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x00383837;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00363635;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00353533;
- else
- calibration_code = 0x00003533;
- } else if (MemClkFreq == 0x16) {
- /* DDR3-1866 */
- calibration_code = 0x00333330;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x00383837;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00363635;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00353533;
- else
- calibration_code = 0x00003533;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00390039;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x00390039;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x003a3a3a;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00003939;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- calibration_code = 0x00003738;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_C3) {
- /* Socket C32 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 77 */
- if (MaxDimmsInstallable == 1) {
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- calibration_code = 0x00000000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x003c3c3c;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x003a3a3a;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- calibration_code = 0x00393939;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- calibration_code = 0x00000000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x00393c39;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00373a37;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- calibration_code = 0x00363936;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- calibration_code = 0x00000000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x003a3c3a;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00383a38;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- calibration_code = 0x00353935;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
- /* TODO
- * LRDIMM support unimplemented
- */
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 76 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x00383837;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00363635;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00353533;
- else
- calibration_code = 0x00003533;
- } else if (MemClkFreq == 0x16) {
- /* DDR3-1866 */
- calibration_code = 0x00333330;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x00383837;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00363635;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00353533;
- else
- calibration_code = 0x00003533;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (MemClkFreq == 0x4) {
- /* DDR3-667 */
- calibration_code = 0x00390039;
- } else if (MemClkFreq == 0x6) {
- /* DDR3-800 */
- calibration_code = 0x00390039;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x003a3a3a;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00003939;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- calibration_code = 0x00003738;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_FM2) {
- /* Socket FM2 */
- /* Assume UDIMM */
- /* Fam15h Model10h BKDG Rev. 3.12 section 2.9.5.6.6 Table 32 */
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 or DDR3-800 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x003b0000;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x00380000;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- if (rank_count_dimm0 == 1)
- calibration_code = 0x00000000;
- else
- calibration_code = 0x00360000;
- } else if (MemClkFreq >= 0x12) {
- /* DDR3-1600 or higher */
- calibration_code = 0x00000000;
- }
-
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 or DDR3-800 */
- calibration_code = 0x00390039;
- } else if (MemClkFreq == 0xa) {
- /* DDR3-1066 */
- calibration_code = 0x00350037;
- } else if (MemClkFreq == 0xe) {
- /* DDR3-1333 */
- calibration_code = 0x00000035;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- calibration_code = 0x0000002b;
- } else if (MemClkFreq > 0x12) {
- /* DDR3-1866 or greater */
- calibration_code = 0x00000031;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else {
- /* TODO
- * Other socket support unimplemented
- */
- }
-
- return calibration_code;
-}
-
-uint8_t fam15h_slow_access_mode(struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- uint8_t package_type;
- uint32_t slow_access = 0;
-
- package_type = mctGet_NVbits(NV_PACK_TYPE);
- uint16_t MemClkFreq = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
-
- /* Obtain number of DIMMs on channel */
- uint8_t dimm_count = pDCTstat->MAdimms[dct];
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
-
- if (package_type == PT_GR) {
- /* Socket G34 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 74 */
- slow_access = 0;
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 75 */
- slow_access = 0;
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 73 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)
- || (MemClkFreq == 0xa) | (MemClkFreq == 0xe)) {
- /* DDR3-667 - DDR3-1333 */
- slow_access = 0;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (rank_count_dimm0 == 1)
- slow_access = 0;
- else
- slow_access = 1;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)
- || (MemClkFreq == 0xa) | (MemClkFreq == 0xe)) {
- /* DDR3-667 - DDR3-1333 */
- slow_access = 0;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if (rank_count_dimm0 == 1)
- slow_access = 0;
- else
- slow_access = 1;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)
- || (MemClkFreq == 0xa)) {
- /* DDR3-667 - DDR3-1066 */
- slow_access = 0;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- slow_access = 1;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_C3) {
- /* Socket C32 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 77 */
- slow_access = 0;
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 78 */
- slow_access = 0;
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 Table 76 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)
- || (MemClkFreq == 0xa) | (MemClkFreq == 0xe)) {
- /* DDR3-667 - DDR3-1333 */
- slow_access = 0;
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- if (rank_count_dimm0 == 1)
- slow_access = 0;
- else
- slow_access = 1;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)
- || (MemClkFreq == 0xa) | (MemClkFreq == 0xe)) {
- /* DDR3-667 - DDR3-1333 */
- slow_access = 0;
- } else if (MemClkFreq == 0x12) {
- /* DDR3-1600 */
- if (rank_count_dimm0 == 1)
- slow_access = 0;
- else
- slow_access = 1;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)
- || (MemClkFreq == 0xa)) {
- /* DDR3-667 - DDR3-1066 */
- slow_access = 0;
- } else if ((MemClkFreq == 0xe) || (MemClkFreq == 0x12)) {
- /* DDR3-1333 - DDR3-1600 */
- slow_access = 1;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_FM2) {
- /* Socket FM2 */
- /* UDIMM */
- /* Fam15h Model10 BKDG Rev. 3.12 section 2.9.5.6.6 Table 32 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)
- || (MemClkFreq == 0xa) | (MemClkFreq == 0xe)) {
- /* DDR3-667 - DDR3-1333 */
- slow_access = 0;
- } else if (MemClkFreq >= 0x12) {
- /* DDR3-1600 or higher */
- if (rank_count_dimm0 == 1)
- slow_access = 0;
- else
- slow_access = 1;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)
- || (MemClkFreq == 0xa) | (MemClkFreq == 0xe)) {
- /* DDR3-667 - DDR3-1333 */
- slow_access = 0;
- } else if (MemClkFreq >= 0x12) {
- /* DDR3-1600 or higher */
- if (rank_count_dimm0 == 1)
- slow_access = 0;
- else
- slow_access = 1;
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)
- || (MemClkFreq == 0xa)) {
- /* DDR3-667 - DDR3-1066 */
- slow_access = 0;
- } else if (MemClkFreq >= 0xe) {
- /* DDR3-1333 or higher */
- slow_access = 1;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else {
- /* TODO
- * Other socket support unimplemented
- */
- }
-
- return slow_access;
-}
-
-static uint8_t fam15h_odt_tristate_enable_code(struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- uint8_t package_type;
- uint8_t odt_tristate_code = 0;
-
- package_type = mctGet_NVbits(NV_PACK_TYPE);
-
- /* Obtain number of DIMMs on channel */
- uint8_t dimm_count = pDCTstat->MAdimms[dct];
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
-
- if (package_type == PT_GR) {
- /* Socket G34 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 104 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- odt_tristate_code = 0xe;
- else
- odt_tristate_code = 0xa;
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm1 == 1)
- odt_tristate_code = 0xd;
- else
- odt_tristate_code = 0x5;
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- odt_tristate_code = 0xc;
- else if ((rank_count_dimm0 == 1) && (rank_count_dimm1 >= 2))
- odt_tristate_code = 0x4;
- else if ((rank_count_dimm0 >= 2) && (rank_count_dimm1 == 1))
- odt_tristate_code = 0x8;
- else
- odt_tristate_code = 0x0;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
-
- /* TODO
- * Implement LRDIMM support
- * See Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 105
- */
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 103 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- odt_tristate_code = 0xe;
- else
- odt_tristate_code = 0xa;
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- odt_tristate_code = 0xd;
- else
- odt_tristate_code = 0x5;
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- odt_tristate_code = 0xc;
- else if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 2))
- odt_tristate_code = 0x4;
- else if ((rank_count_dimm0 == 2) && (rank_count_dimm1 == 1))
- odt_tristate_code = 0x8;
- else
- odt_tristate_code = 0x0;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_C3) {
- /* Socket C32 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 107 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- odt_tristate_code = 0xe;
- else
- odt_tristate_code = 0xa;
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm1 == 1)
- odt_tristate_code = 0xd;
- else
- odt_tristate_code = 0x5;
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- odt_tristate_code = 0xc;
- else if ((rank_count_dimm0 == 1) && (rank_count_dimm1 >= 2))
- odt_tristate_code = 0x4;
- else if ((rank_count_dimm0 >= 2) && (rank_count_dimm1 == 1))
- odt_tristate_code = 0x8;
- else
- odt_tristate_code = 0x0;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
-
- /* TODO
- * Implement LRDIMM support
- * See Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 108
- */
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 106 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- odt_tristate_code = 0xe;
- else
- odt_tristate_code = 0xa;
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- odt_tristate_code = 0xd;
- else
- odt_tristate_code = 0x5;
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- odt_tristate_code = 0xc;
- else if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 2))
- odt_tristate_code = 0x4;
- else if ((rank_count_dimm0 == 2) && (rank_count_dimm1 == 1))
- odt_tristate_code = 0x8;
- else
- odt_tristate_code = 0x0;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_FM2) {
- /* Socket FM2 */
- /* UDIMM */
- odt_tristate_code = 0x0;
- } else {
- /* TODO
- * Other socket support unimplemented
- */
- }
-
- return odt_tristate_code;
-}
-
-static uint8_t fam15h_cs_tristate_enable_code(struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- uint8_t package_type;
- uint8_t cs_tristate_code = 0;
-
- package_type = mctGet_NVbits(NV_PACK_TYPE);
-
- /* Obtain number of DIMMs on channel */
- uint8_t dimm_count = pDCTstat->MAdimms[dct];
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
-
- if (package_type == PT_GR) {
- /* Socket G34 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 104 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 < 4)
- cs_tristate_code = 0xfc;
- else
- cs_tristate_code = 0xcc;
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm1 < 4)
- cs_tristate_code = 0xf3;
- else
- cs_tristate_code = 0x33;
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- cs_tristate_code = 0xf0;
- else if ((rank_count_dimm0 < 4) && (rank_count_dimm1 == 4))
- cs_tristate_code = 0x30;
- else if ((rank_count_dimm0 == 4) && (rank_count_dimm1 < 4))
- cs_tristate_code = 0xc0;
- else
- cs_tristate_code = 0x0;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
-
- /* TODO
- * Implement LRDIMM support
- * See Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 105
- */
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 103 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- cs_tristate_code = 0xfe;
- else
- cs_tristate_code = 0xfc;
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- cs_tristate_code = 0xfb;
- else
- cs_tristate_code = 0xf3;
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- cs_tristate_code = 0xfa;
- else if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 2))
- cs_tristate_code = 0xf2;
- else if ((rank_count_dimm0 == 2) && (rank_count_dimm1 == 1))
- cs_tristate_code = 0xf8;
- else
- cs_tristate_code = 0xf0;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_C3) {
- /* Socket C32 */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 107 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 < 4)
- cs_tristate_code = 0xfc;
- else
- cs_tristate_code = 0xcc;
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm1 < 4)
- cs_tristate_code = 0xf3;
- else
- cs_tristate_code = 0x33;
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- cs_tristate_code = 0xf0;
- else if ((rank_count_dimm0 < 4) && (rank_count_dimm1 == 4))
- cs_tristate_code = 0x30;
- else if ((rank_count_dimm0 == 4) && (rank_count_dimm1 < 4))
- cs_tristate_code = 0xc0;
- else
- cs_tristate_code = 0x0;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
-
- /* TODO
- * Implement LRDIMM support
- * See Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 108
- */
- } else {
- /* UDIMM */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.10.1 Table 106 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- cs_tristate_code = 0xfe;
- else
- cs_tristate_code = 0xfc;
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if (rank_count_dimm0 == 1)
- cs_tristate_code = 0xfb;
- else
- cs_tristate_code = 0xf3;
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 1))
- cs_tristate_code = 0xfa;
- else if ((rank_count_dimm0 == 1) && (rank_count_dimm1 == 2))
- cs_tristate_code = 0xf2;
- else if ((rank_count_dimm0 == 2) && (rank_count_dimm1 == 1))
- cs_tristate_code = 0xf8;
- else
- cs_tristate_code = 0xf0;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- }
- } else if (package_type == PT_FM2) {
- /* Socket FM2 */
- /* UDIMM */
- cs_tristate_code = 0x0;
- } else {
- /* TODO
- * Other socket support unimplemented
- */
- }
-
- return cs_tristate_code;
-}
-
-void set_2t_configuration(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- uint32_t dev;
- uint32_t reg;
- uint32_t dword;
-
- uint8_t enable_slow_access_mode = 0;
- dev = pDCTstat->dev_dct;
-
- if (is_fam15h()) {
- if (pDCTstat->_2Tmode)
- enable_slow_access_mode = 1;
- } else {
- if (pDCTstat->_2Tmode == 2)
- enable_slow_access_mode = 1;
- }
-
- reg = 0x94; /* DRAM Configuration High */
- dword = Get_NB32_DCT(dev, dct, reg);
- if (enable_slow_access_mode)
- dword |= (0x1 << 20); /* Set 2T CMD mode */
- else
- dword &= ~(0x1 << 20); /* Clear 2T CMD mode */
- Set_NB32_DCT(dev, dct, reg, dword);
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-void precise_ndelay_fam15(struct MCTStatStruc *pMCTstat, uint32_t nanoseconds) {
- msr_t tsc_msr;
- uint64_t cycle_count = (((uint64_t)pMCTstat->TSCFreq) * nanoseconds) / 1000;
- uint64_t start_timestamp;
- uint64_t current_timestamp;
-
- tsc_msr = rdmsr(TSC_MSR);
- start_timestamp = (((uint64_t)tsc_msr.hi) << 32) | tsc_msr.lo;
- do {
- tsc_msr = rdmsr(TSC_MSR);
- current_timestamp = (((uint64_t)tsc_msr.hi) << 32) | tsc_msr.lo;
- } while ((current_timestamp - start_timestamp) < cycle_count);
-}
-
-void precise_memclk_delay_fam15(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, uint8_t dct, uint32_t clocks) {
- uint16_t memclk_freq;
- uint32_t delay_ns;
- uint16_t fam15h_freq_tab[] = {0, 0, 0, 0, 333, 0, 400, 0, 0, 0, 533, 0, 0, 0, 667, 0, 0, 0, 800, 0, 0, 0, 933};
-
- memclk_freq = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
-
- if (fam15h_freq_tab[memclk_freq] == 0) {
- printk(BIOS_DEBUG, "ERROR: precise_memclk_delay_fam15 for DCT %d (delay %d clocks) failed to obtain valid memory frequency!"
- " (pDCTstat: %p pDCTstat->dev_dct: %08x memclk_freq: %02x)\n", dct, clocks, pDCTstat, pDCTstat->dev_dct, memclk_freq);
- }
- delay_ns = (((uint64_t)clocks * 1000) / fam15h_freq_tab[memclk_freq]);
- precise_ndelay_fam15(pMCTstat, delay_ns);
-}
-
-static void read_spd_bytes(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dimm)
-{
- uint8_t addr;
- uint16_t byte;
-
- addr = Get_DIMMAddress_D(pDCTstat, dimm);
- pDCTstat->spd_data.spd_address[dimm] = addr;
-
- for (byte = 0; byte < 256; byte++) {
- pDCTstat->spd_data.spd_bytes[dimm][byte] = mctRead_SPD(addr, byte);
- }
-}
-
-#ifdef DEBUG_DIMM_SPD
-static void dump_spd_bytes(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dimm)
-{
- uint16_t byte;
-
- printk(BIOS_DEBUG, "SPD dump for DIMM %d\n ", dimm);
- for (byte = 0; byte < 16; byte++) {
- printk(BIOS_DEBUG, "%02x ", byte);
- }
- for (byte = 0; byte < 256; byte++) {
- if ((byte & 0xf) == 0x0) {
- printk(BIOS_DEBUG, "\n%02x ", byte >> 4);
- }
- printk(BIOS_DEBUG, "%02x ", pDCTstat->spd_data.spd_bytes[dimm][byte]);
- }
- printk(BIOS_DEBUG, "\n");
-}
-#endif
-
-static void set_up_cc6_storage_fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t num_nodes)
-{
- uint8_t interleaved;
- uint8_t destination_node;
- int8_t range;
- int8_t max_range;
- uint8_t max_node;
- uint64_t max_range_limit;
- uint8_t byte;
- uint32_t dword;
- uint32_t dword2;
- uint64_t qword;
-
- interleaved = 0;
- if (pMCTstat->GStatus & (1 << GSB_NodeIntlv))
- interleaved = 1;
-
- printk(BIOS_INFO,
- "%s: Initializing CC6 DRAM storage area for node %d"
- " (interleaved: %d)\n",
- __func__, pDCTstat->Node_ID, interleaved);
-
- /* Find highest DRAM range (DramLimitAddr) */
- max_node = 0;
- max_range = -1;
- max_range_limit = 0;
- for (range = 0; range < 8; range++) {
- dword = Get_NB32(pDCTstat->dev_map, 0x40 + (range * 0x8));
- if (!(dword & 0x3))
- continue;
-
- dword = Get_NB32(pDCTstat->dev_map, 0x44 + (range * 0x8));
- dword2 = Get_NB32(pDCTstat->dev_map, 0x144 + (range * 0x8));
- qword = 0xffffff;
- qword |= ((((uint64_t)dword) >> 16) & 0xffff) << 24;
- qword |= (((uint64_t)dword2) & 0xff) << 40;
-
- if (qword > max_range_limit) {
- max_range = range;
- max_range_limit = qword;
- max_node = dword & 0x7;
- }
- }
-
- if (max_range >= 0) {
- printk(BIOS_INFO,
- "%s:\toriginal (node %d) max_range_limit: %16llx DRAM"
- " limit: %16llx\n",
- __func__, max_node, max_range_limit,
- (((uint64_t)(Get_NB32(pDCTstat->dev_map, 0x124)
- & 0x1fffff)) << 27) | 0x7ffffff);
-
- if (interleaved)
- /* Move upper limit down by 16M * the number of nodes */
- max_range_limit -= (0x1000000ULL * num_nodes);
- else
- /* Move upper limit down by 16M */
- max_range_limit -= 0x1000000ULL;
-
- printk(BIOS_INFO, "%s:\tnew max_range_limit: %16llx\n",
- __func__, max_range_limit);
-
- /* Disable the range */
- dword = Get_NB32(pDCTstat->dev_map, 0x40 + (max_range * 0x8));
- byte = dword & 0x3;
- dword &= ~(0x3);
- Set_NB32(pDCTstat->dev_map, 0x40 + (max_range * 0x8), dword);
-
- /* Store modified range */
- dword = Get_NB32(pDCTstat->dev_map, 0x44 + (max_range * 0x8));
- dword &= ~(0xffff << 16); /* DramLimit[39:24] = max_range_limit[39:24] */
- dword |= ((max_range_limit >> 24) & 0xffff) << 16;
- Set_NB32(pDCTstat->dev_map, 0x44 + (max_range * 0x8), dword);
-
- dword = Get_NB32(pDCTstat->dev_map, 0x144 + (max_range * 0x8));
- dword &= ~0xff; /* DramLimit[47:40] = max_range_limit[47:40] */
- dword |= (max_range_limit >> 40) & 0xff;
- Set_NB32(pDCTstat->dev_map, 0x144 + (max_range * 0x8), dword);
-
- /* Reenable the range */
- dword = Get_NB32(pDCTstat->dev_map, 0x40 + (max_range * 0x8));
- dword |= byte;
- Set_NB32(pDCTstat->dev_map, 0x40 + (max_range * 0x8), dword);
- }
-
- /* Determine save state destination node */
- if (interleaved)
- destination_node = Get_NB32(pDCTstat->dev_host, 0x60) & 0x7;
- else
- destination_node = max_node;
-
- /* Set save state destination node */
- dword = Get_NB32(pDCTstat->dev_link, 0x128);
- dword &= ~(0x3f << 12); /* CoreSaveStateDestNode = destination_node */
- dword |= (destination_node & 0x3f) << 12;
- Set_NB32(pDCTstat->dev_link, 0x128, dword);
-
- printk(BIOS_INFO, "%s:\tTarget node: %d\n", __func__, destination_node);
-
- printk(BIOS_INFO, "%s:\tDone\n", __func__);
-}
-
-static void lock_dram_config(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- uint32_t dword;
-
- dword = Get_NB32(pDCTstat->dev_dct, 0x118);
- dword |= 0x1 << 19; /* LockDramCfg = 1 */
- Set_NB32(pDCTstat->dev_dct, 0x118, dword);
-}
-
-static void set_cc6_save_enable(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t enable)
-{
- uint32_t dword;
-
- dword = Get_NB32(pDCTstat->dev_dct, 0x118);
- dword &= ~(0x1 << 18); /* CC6SaveEn = enable */
- dword |= (enable & 0x1) << 18;
- Set_NB32(pDCTstat->dev_dct, 0x118, dword);
-}
-
-void mctAutoInitMCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /*
- * Memory may be mapped contiguously all the way up to 4GB (depending on setup
- * options). It is the responsibility of PCI subsystem to create an uncacheable
- * IO region below 4GB and to adjust TOP_MEM downward prior to any IO mapping or
- * accesses. It is the same responsibility of the CPU sub-system prior to
- * accessing LAPIC.
- *
- * Slot Number is an external convention, and is determined by OEM with accompanying
- * silk screening. OEM may choose to use Slot number convention which is consistent
- * with DIMM number conventions. All AMD engineering platforms do.
- *
- * Build Requirements:
- * 1. MCT_SEG0_START and MCT_SEG0_END macros to begin and end the code segment,
- * defined in mcti.inc.
- *
- * Run-Time Requirements:
- * 1. Complete Hypertransport Bus Configuration
- * 2. SMBus Controller Initialized
- * 1. BSP in Big Real Mode
- * 2. Stack at SS:SP, located somewhere between A000:0000 and F000:FFFF
- * 3. Checksummed or Valid NVRAM bits
- * 4. MCG_CTL = -1, MC4_CTL_EN = 0 for all CPUs
- * 5. MCi_STS from shutdown/warm reset recorded (if desired) prior to entry
- * 6. All var MTRRs reset to zero
- * 7. State of NB_CFG.DisDatMsk set properly on all CPUs
- * 8. All CPUs at 2GHz Speed (unless DQS training is not installed).
- * 9. All cHT links at max Speed/Width (unless DQS training is not installed).
- *
- *
- * Global relationship between index values and item values:
- *
- * pDCTstat.CASL pDCTstat.Speed
- * j CL(j) k F(k)
- * --------------------------
- * 0 2.0 - -
- * 1 3.0 1 200 MHz
- * 2 4.0 2 266 MHz
- * 3 5.0 3 333 MHz
- * 4 6.0 4 400 MHz
- * 5 7.0 5 533 MHz
- * 6 8.0 6 667 MHz
- * 7 9.0 7 800 MHz
- */
- u8 Node, NodesWmem;
- u32 node_sys_base;
- uint8_t dimm;
- uint8_t nvram;
- uint8_t enable_cc6;
- uint8_t ecc_enabled;
- uint8_t allow_config_restore;
-
- uint8_t s3resume = acpi_is_wakeup_s3();
-
-restartinit:
-
- if (!mctGet_NVbits(NV_ECC_CAP) || !mctGet_NVbits(NV_ECC))
- pMCTstat->try_ecc = 0;
- else
- pMCTstat->try_ecc = 1;
-
- mctInitMemGPIOs_A_D(); /* Set any required GPIOs*/
- if (s3resume) {
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: mct_ForceNBPState0_En_Fam15\n");
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- mct_ForceNBPState0_En_Fam15(pMCTstat, pDCTstat);
- }
-
-#if CONFIG(HAVE_ACPI_RESUME)
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: Restoring DCT configuration from NVRAM\n");
- if (restore_mct_information_from_nvram(0) != 0)
- printk(BIOS_CRIT, "%s: ERROR: Unable to restore DCT configuration from NVRAM\n", __func__);
- pMCTstat->GStatus |= 1 << GSB_ConfigRestored;
-#endif
-
- if (is_fam15h()) {
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: mct_ForceNBPState0_Dis_Fam15\n");
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- mct_ForceNBPState0_Dis_Fam15(pMCTstat, pDCTstat);
- }
- }
- } else {
- NodesWmem = 0;
- node_sys_base = 0;
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- /* Zero out data structures to avoid false detection of DIMMs */
- memset(pDCTstat, 0, sizeof(struct DCTStatStruc));
-
- /* Initialize data structures */
- pDCTstat->Node_ID = Node;
- pDCTstat->dev_host = PA_HOST(Node);
- pDCTstat->dev_map = PA_MAP(Node);
- pDCTstat->dev_dct = PA_DCT(Node);
- pDCTstat->dev_nbmisc = PA_NBMISC(Node);
- pDCTstat->dev_link = PA_LINK(Node);
- pDCTstat->dev_nbctl = PA_NBCTL(Node);
- pDCTstat->NodeSysBase = node_sys_base;
-
- if (mctGet_NVbits(NV_PACK_TYPE) == PT_GR) {
- uint32_t dword;
- pDCTstat->Dual_Node_Package = 1;
-
- /* Get the internal node number */
- dword = Get_NB32(pDCTstat->dev_nbmisc, 0xe8);
- dword = (dword >> 30) & 0x3;
- pDCTstat->Internal_Node_ID = dword;
- } else {
- pDCTstat->Dual_Node_Package = 0;
- }
-
- printk(BIOS_DEBUG, "%s: mct_init Node %d\n", __func__, Node);
- mct_init(pMCTstat, pDCTstat);
- mctNodeIDDebugPort_D();
- pDCTstat->NodePresent = NodePresent_D(Node);
- if (pDCTstat->NodePresent) {
- pDCTstat->LogicalCPUID = mctGetLogicalCPUID_D(Node);
-
- printk(BIOS_DEBUG, "%s: mct_InitialMCT_D\n", __func__);
- mct_InitialMCT_D(pMCTstat, pDCTstat);
-
- printk(BIOS_DEBUG, "%s: mctSMBhub_Init\n", __func__);
- mctSMBhub_Init(Node); /* Switch SMBUS crossbar to proper node */
-
- printk(BIOS_DEBUG, "%s: mct_preInitDCT\n", __func__);
- mct_preInitDCT(pMCTstat, pDCTstat);
- }
- node_sys_base = pDCTstat->NodeSysBase;
- node_sys_base += (pDCTstat->NodeSysLimit + 2) & ~0x0F;
- }
-
- /* If the boot fails make sure training is attempted after reset */
- nvram = 0;
- set_option("allow_spd_nvram_cache_restore", &nvram);
-
-#if CONFIG(DIMM_VOLTAGE_SET_SUPPORT)
- printk(BIOS_DEBUG, "%s: DIMMSetVoltage\n", __func__);
- DIMMSetVoltages(pMCTstat, pDCTstatA); /* Set the DIMM voltages (mainboard specific) */
-#endif
- if (!CONFIG(DIMM_VOLTAGE_SET_SUPPORT)) {
- /* Assume 1.5V operation */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (!pDCTstat->NodePresent)
- continue;
-
- for (dimm = 0; dimm < MAX_DIMMS_SUPPORTED; dimm++) {
- if (pDCTstat->DIMMValid & (1 << dimm))
- pDCTstat->DimmConfiguredVoltage[dimm] = 0x1;
- }
- }
- }
-
- /* If DIMM configuration has not changed since last boot restore training values */
- allow_config_restore = 1;
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent)
- if (!pDCTstat->spd_data.nvram_spd_match)
- allow_config_restore = 0;
- }
-
- /* FIXME
- * Stability issues have arisen on multiple Family 15h systems
- * when configuration restoration is enabled. In all cases these
- * stability issues resolved by allowing the RAM to go through a
- * full training cycle.
- *
- * Debug and reenable this!
- */
- allow_config_restore = 0;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- printk(BIOS_DEBUG, "%s: mctSMBhub_Init\n", __func__);
- mctSMBhub_Init(Node); /* Switch SMBUS crossbar to proper node*/
-
- printk(BIOS_DEBUG, "%s: mct_initDCT\n", __func__);
- mct_initDCT(pMCTstat, pDCTstat);
- if (pDCTstat->ErrCode == SC_FatalErr) {
- goto fatalexit; /* any fatal errors?*/
- } else if (pDCTstat->ErrCode < SC_StopError) {
- NodesWmem++;
- }
- }
- }
- if (NodesWmem == 0) {
- printk(BIOS_ALERT, "Unable to detect valid memory on any nodes. Halting!\n");
- goto fatalexit;
- }
-
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: SyncDCTsReady_D\n");
- SyncDCTsReady_D(pMCTstat, pDCTstatA); /* Make sure DCTs are ready for accesses.*/
-
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: HTMemMapInit_D\n");
- HTMemMapInit_D(pMCTstat, pDCTstatA); /* Map local memory into system address space.*/
- mctHookAfterHTMap();
-
- if (!is_fam15h()) {
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: CPUMemTyping_D\n");
- CPUMemTyping_D(pMCTstat, pDCTstatA); /* Map dram into WB/UC CPU cacheability */
- }
-
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: mctHookAfterCPU\n");
- mctHookAfterCPU(); /* Setup external northbridge(s) */
-
- /* FIXME
- * Previous training values should only be used if the current desired
- * speed is the same as the speed used in the previous boot.
- * How to get the desired speed at this point in the code?
- */
-
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: DQSTiming_D\n");
- DQSTiming_D(pMCTstat, pDCTstatA, allow_config_restore); /* Get Receiver Enable and DQS signal timing*/
-
- if (!is_fam15h()) {
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: UMAMemTyping_D\n");
- UMAMemTyping_D(pMCTstat, pDCTstatA); /* Fix up for UMA sizing */
- }
-
- if (!allow_config_restore) {
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: :OtherTiming\n");
- mct_OtherTiming(pMCTstat, pDCTstatA);
- }
-
- if (ReconfigureDIMMspare_D(pMCTstat, pDCTstatA)) { /* RESET# if 1st pass of DIMM spare enabled*/
- goto restartinit;
- }
-
- InterleaveNodes_D(pMCTstat, pDCTstatA);
- InterleaveChannels_D(pMCTstat, pDCTstatA);
-
- ecc_enabled = 1;
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent)
- if (!is_ecc_enabled(pMCTstat, pDCTstat))
- ecc_enabled = 0;
- }
-
- if (ecc_enabled) {
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: ECCInit_D\n");
- if (!ECCInit_D(pMCTstat, pDCTstatA)) { /* Setup ECC control and ECC check-bits*/
- /* Memory was not cleared during ECC setup */
- /* mctDoWarmResetMemClr_D(); */
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: MCTMemClr_D\n");
- MCTMemClr_D(pMCTstat,pDCTstatA);
- }
- }
-
- if (is_fam15h()) {
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: CPUMemTyping_D\n");
- CPUMemTyping_D(pMCTstat, pDCTstatA); /* Map dram into WB/UC CPU cacheability */
-
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: UMAMemTyping_D\n");
- UMAMemTyping_D(pMCTstat, pDCTstatA); /* Fix up for UMA sizing */
-
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: mct_ForceNBPState0_Dis_Fam15\n");
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- mct_ForceNBPState0_Dis_Fam15(pMCTstat, pDCTstat);
- }
- }
-
- if (is_fam15h()) {
- enable_cc6 = 0;
- if (get_option(&nvram, "cpu_cc6_state") == CB_SUCCESS)
- enable_cc6 = !!nvram;
-
- if (enable_cc6) {
- uint8_t num_nodes;
-
- num_nodes = 0;
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent)
- num_nodes++;
- }
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent)
- set_up_cc6_storage_fam15(pMCTstat, pDCTstat, num_nodes);
- }
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- set_cc6_save_enable(pMCTstat, pDCTstat, 1);
- lock_dram_config(pMCTstat, pDCTstat);
- }
- }
- }
- }
-
- mct_FinalMCT_D(pMCTstat, pDCTstatA);
- printk(BIOS_DEBUG, "mctAutoInitMCT_D Done: Global Status: %x\n", pMCTstat->GStatus);
- }
-
- return;
-
-fatalexit:
- die("mct_d: fatalexit");
-}
-
-void initialize_mca(uint8_t bsp, uint8_t suppress_errors) {
- uint8_t node;
- uint32_t mc4_status_high;
- uint32_t mc4_status_low;
-
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- if (bsp && (node > 0))
- break;
-
- mc4_status_high = pci_read_config32(PCI_DEV(0, 0x18 + node, 3), 0x4c);
- mc4_status_low = pci_read_config32(PCI_DEV(0, 0x18 + node, 3), 0x48);
- if ((mc4_status_high & (0x1 << 31)) && (mc4_status_high != 0xffffffff)) {
- if (!suppress_errors)
- printk(BIOS_WARNING, "WARNING: MC4 Machine Check Exception detected on node %d!\n"
- "Signature: %08x%08x\n", node, mc4_status_high, mc4_status_low);
-
- /* Clear MC4 error status */
- pci_write_config32(PCI_DEV(0, 0x18 + node, 3), 0x48, 0x0);
- pci_write_config32(PCI_DEV(0, 0x18 + node, 3), 0x4c, 0x0);
- }
- }
-}
-
-static u8 ReconfigureDIMMspare_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 ret;
-
- if (mctGet_NVbits(NV_CS_SpareCTL)) {
- if (MCT_DIMM_SPARE_NO_WARM) {
- /* Do no warm-reset DIMM spare */
- if (pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW)) {
- LoadDQSSigTmgRegs_D(pMCTstat, pDCTstatA);
- ret = 0;
- } else {
- mct_ResetDataStruct_D(pMCTstat, pDCTstatA);
- pMCTstat->GStatus |= 1 << GSB_EnDIMMSpareNW;
- ret = 1;
- }
- } else {
- /* Do warm-reset DIMM spare */
- if (mctGet_NVbits(NV_DQSTrainCTL))
- mctWarmReset_D();
- ret = 0;
- }
- } else {
- ret = 0;
- }
-
- return ret;
-}
-
-/* Enable or disable phy-assisted training mode
- * Phy-assisted training mode applies to the follow DRAM training procedures:
- * Write Levelization Training (2.10.5.8.1)
- * DQS Receiver Enable Training (2.10.5.8.2)
- */
-void fam15EnableTrainingMode(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t enable)
-{
- uint8_t index;
- uint32_t dword;
- uint32_t index_reg = 0x98;
- uint32_t dev = pDCTstat->dev_dct;
-
- if (enable) {
- /* Enable training mode */
- dword = Get_NB32_DCT(dev, dct, 0x78); /* DRAM Control */
- dword &= ~(0x1 << 17); /* AddrCmdTriEn = 0 */
- Set_NB32_DCT(dev, dct, 0x78, dword); /* DRAM Control */
-
- dword = Get_NB32_DCT(dev, dct, 0x8c); /* DRAM Timing High */
- dword |= (0x1 << 18); /* DisAutoRefresh = 1 */
- Set_NB32_DCT(dev, dct, 0x8c, dword); /* DRAM Timing High */
-
- dword = Get_NB32_DCT(dev, dct, 0x94); /* DRAM Configuration High */
- dword &= ~(0xf << 24); /* DcqBypassMax = 0 */
- dword &= ~(0x1 << 22); /* BankSwizzleMode = 0 */
- dword &= ~(0x1 << 15); /* PowerDownEn = 0 */
- dword &= ~(0x3 << 10); /* ZqcsInterval = 0 */
- Set_NB32_DCT(dev, dct, 0x94, dword); /* DRAM Configuration High */
-
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000d);
- dword &= ~(0xf << 16); /* RxMaxDurDllNoLock = 0 */
- dword &= ~(0xf); /* TxMaxDurDllNoLock = 0 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000d, dword);
-
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0010 | (index << 8));
- dword &= ~(0x1 << 12); /* EnRxPadStandby = 0 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0010 | (index << 8), dword);
- }
-
- dword = Get_NB32_DCT(dev, dct, 0xa4); /* DRAM Controller Temperature Throttle */
- dword &= ~(0x1 << 11); /* BwCapEn = 0 */
- dword &= ~(0x1 << 8); /* ODTSEn = 0 */
- Set_NB32_DCT(dev, dct, 0xa4, dword); /* DRAM Controller Temperature Throttle */
-
- dword = Get_NB32_DCT(dev, dct, 0x110); /* DRAM Controller Select Low */
- dword &= ~(0x1 << 2); /* DctSelIntLvEn = 0 */
- Set_NB32_DCT(dev, dct, 0x110, dword); /* DRAM Controller Select Low */
-
- dword = Get_NB32_DCT(pDCTstat->dev_nbmisc, dct, 0x58); /* Scrub Rate Control */
- dword &= ~(0x1f << 24); /* L3Scrub = 0 */
- dword &= ~(0x1f); /* DramScrub = 0 */
- Set_NB32_DCT(pDCTstat->dev_nbmisc, dct, 0x58, dword); /* Scrub Rate Control */
-
- dword = Get_NB32_DCT(pDCTstat->dev_nbmisc, dct, 0x5c); /* DRAM Scrub Address Low */
- dword &= ~(0x1); /* ScrubReDirEn = 0 */
- Set_NB32_DCT(pDCTstat->dev_nbmisc, dct, 0x5c, dword); /* DRAM Scrub Address Low */
-
- dword = Get_NB32_DCT(pDCTstat->dev_nbmisc, dct, 0x1b8); /* L3 Control 1 */
- dword |= (0x1 << 4); /* L3ScrbRedirDis = 1 */
- Set_NB32_DCT(pDCTstat->dev_nbmisc, dct, 0x1b8, dword); /* L3 Control 1 */
-
- /* Fam15h BKDG section 2.10.5.5.1 */
- dword = Get_NB32_DCT(dev, dct, 0x218); /* DRAM Timing 5 */
- dword &= ~(0xf << 24); /* TrdrdSdSc = 0xb */
- dword |= (0xb << 24);
- dword &= ~(0xf << 16); /* TrdrdSdDc = 0xb */
- dword |= (0xb << 16);
- dword &= ~(0xf); /* TrdrdDd = 0xb */
- dword |= 0xb;
- Set_NB32_DCT(dev, dct, 0x218, dword); /* DRAM Timing 5 */
-
- /* Fam15h BKDG section 2.10.5.5.2 */
- dword = Get_NB32_DCT(dev, dct, 0x214); /* DRAM Timing 4 */
- dword &= ~(0xf << 16); /* TwrwrSdSc = 0xb */
- dword |= (0xb << 16);
- dword &= ~(0xf << 8); /* TwrwrSdDc = 0xb */
- dword |= (0xb << 8);
- dword &= ~(0xf); /* TwrwrDd = 0xb */
- dword |= 0xb;
- Set_NB32_DCT(dev, dct, 0x214, dword); /* DRAM Timing 4 */
-
- /* Fam15h BKDG section 2.10.5.5.3 */
- dword = Get_NB32_DCT(dev, dct, 0x218); /* DRAM Timing 5 */
- dword &= ~(0xf << 8); /* Twrrd = 0xb */
- dword |= (0xb << 8);
- Set_NB32_DCT(dev, dct, 0x218, dword); /* DRAM Timing 5 */
-
- /* Fam15h BKDG section 2.10.5.5.4 */
- dword = Get_NB32_DCT(dev, dct, 0x21c); /* DRAM Timing 6 */
- dword &= ~(0x1f << 8); /* TrwtTO = 0x16 */
- dword |= (0x16 << 8);
- dword &= ~(0x1f << 16); /* TrwtWB = TrwtTO + 1 */
- dword |= ((((dword >> 8) & 0x1f) + 1) << 16);
- Set_NB32_DCT(dev, dct, 0x21c, dword); /* DRAM Timing 6 */
- } else {
- /* Disable training mode */
- uint8_t lane;
- uint8_t dimm;
- int16_t max_cdd_we_delta;
- int16_t cdd_trwtto_we_delta;
- uint8_t receiver;
- uint8_t lane_count;
- uint8_t x4_present = 0;
- uint8_t x8_present = 0;
- uint8_t memclk_index;
- uint8_t interleave_channels = 0;
- uint16_t trdrdsddc;
- uint16_t trdrddd;
- uint16_t cdd_trdrddd;
- uint16_t twrwrsddc;
- uint16_t twrwrdd;
- uint16_t cdd_twrwrdd;
- uint16_t twrrd;
- uint16_t cdd_twrrd;
- uint16_t cdd_trwtto;
- uint16_t trwtto;
- uint8_t first_dimm;
- uint16_t delay;
- uint16_t delay2;
- uint8_t min_value;
- uint8_t write_early;
- uint8_t read_odt_delay;
- uint8_t write_odt_delay;
- uint8_t buffer_data_delay;
- int16_t latency_difference;
- uint16_t difference;
- uint16_t current_total_delay_1[MAX_BYTE_LANES];
- uint16_t current_total_delay_2[MAX_BYTE_LANES];
- uint8_t ddr_voltage_index;
- uint8_t max_dimms_installable;
-
- /* FIXME
- * This should be platform configurable
- */
- uint8_t dimm_event_l_pin_support = 0;
-
- ddr_voltage_index = dct_ddr_voltage_index(pDCTstat, dct);
- max_dimms_installable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- if (pDCTstat->Dimmx4Present & ((dct)?0xaa:0x55))
- x4_present = 1;
- if (pDCTstat->Dimmx8Present & ((dct)?0xaa:0x55))
- x8_present = 1;
- memclk_index = Get_NB32_DCT(dev, dct, 0x94) & 0x1f;
-
- if (pDCTstat->DIMMValidDCT[0] && pDCTstat->DIMMValidDCT[1] && mctGet_NVbits(NV_Unganged))
- interleave_channels = 1;
-
- dword = Get_NB32_DCT(dev, dct, 0x240);
- delay = (dword >> 4) & 0xf;
- if (delay > 6)
- read_odt_delay = delay - 6;
- else
- read_odt_delay = 0;
- delay = (dword >> 12) & 0x7;
- if (delay > 6)
- write_odt_delay = delay - 6;
- else
- write_odt_delay = 0;
-
- dword = (Get_NB32_DCT(dev, dct, 0xa8) >> 24) & 0x3;
- write_early = dword / 2;
-
- latency_difference = Get_NB32_DCT(dev, dct, 0x200) & 0x1f;
- dword = Get_NB32_DCT(dev, dct, 0x20c) & 0x1f;
- latency_difference -= dword;
-
- if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
-
- /* TODO
- * Implement LRDIMM support
- * See Fam15h BKDG Rev. 3.14 section 2.10.5.5
- */
- } else {
- buffer_data_delay = 0;
- }
-
- /* TODO:
- * Adjust trdrdsddc if four-rank DIMMs are installed per
- * section 2.10.5.5.1 of the Family 15h BKDG.
- * cdd_trdrdsddc will also need to be calculated in that process.
- */
- trdrdsddc = 3;
-
- /* Calculate the Critical Delay Difference for TrdrdDd */
- cdd_trdrddd = 0;
- first_dimm = 1;
- for (receiver = 0; receiver < 8; receiver += 2) {
- dimm = (receiver >> 1);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, receiver))
- continue;
-
- read_dqs_receiver_enable_control_registers(current_total_delay_2, dev, dct, dimm, index_reg);
-
- if (first_dimm) {
- memcpy(current_total_delay_1, current_total_delay_2, sizeof(current_total_delay_1));
- first_dimm = 0;
- }
-
- for (lane = 0; lane < lane_count; lane++) {
- if (current_total_delay_1[lane] > current_total_delay_2[lane])
- difference = current_total_delay_1[lane] - current_total_delay_2[lane];
- else
- difference = current_total_delay_2[lane] - current_total_delay_1[lane];
-
- if (difference > cdd_trdrddd)
- cdd_trdrddd = difference;
- }
- }
-
- /* Convert the difference to MEMCLKs */
- cdd_trdrddd = (((cdd_trdrddd + (1 << 6) - 1) >> 6) & 0xf);
-
- /* Calculate Trdrddd */
- delay = (read_odt_delay + 3) * 2;
- delay2 = cdd_trdrddd + 7;
- if (delay2 > delay)
- delay = delay2;
- trdrddd = (delay + 1) / 2; /* + 1 is equivalent to ceiling function here */
- if (trdrdsddc > trdrddd)
- trdrddd = trdrdsddc;
-
- /* TODO:
- * Adjust twrwrsddc if four-rank DIMMs are installed per
- * section 2.10.5.5.1 of the Family 15h BKDG.
- * cdd_twrwrsddc will also need to be calculated in that process.
- */
- twrwrsddc = 4;
-
- /* Calculate the Critical Delay Difference for TwrwrDd */
- cdd_twrwrdd = 0;
- first_dimm = 1;
- for (receiver = 0; receiver < 8; receiver += 2) {
- dimm = (receiver >> 1);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, receiver))
- continue;
-
- read_dqs_write_timing_control_registers(current_total_delay_2, dev, dct, dimm, index_reg);
-
- if (first_dimm) {
- memcpy(current_total_delay_1, current_total_delay_2, sizeof(current_total_delay_1));
- first_dimm = 0;
- }
-
- for (lane = 0; lane < lane_count; lane++) {
- if (current_total_delay_1[lane] > current_total_delay_2[lane])
- difference = current_total_delay_1[lane] - current_total_delay_2[lane];
- else
- difference = current_total_delay_2[lane] - current_total_delay_1[lane];
-
- if (difference > cdd_twrwrdd)
- cdd_twrwrdd = difference;
- }
- }
-
- /* Convert the difference to MEMCLKs */
- cdd_twrwrdd = (((cdd_twrwrdd + (1 << 6) - 1) >> 6) & 0xf);
-
- /* Calculate Twrwrdd */
- delay = (write_odt_delay + 3) * 2;
- delay2 = cdd_twrwrdd + 7;
- if (delay2 > delay)
- delay = delay2;
- twrwrdd = (delay + 1) / 2; /* + 1 is equivalent to ceiling function here */
- if (twrwrsddc > twrwrdd)
- twrwrdd = twrwrsddc;
-
- dword = Get_NB32_DCT(dev, dct, 0x78); /* DRAM Control */
- dword |= (0x1 << 17); /* AddrCmdTriEn = 1 */
- Set_NB32_DCT(dev, dct, 0x78, dword); /* DRAM Control */
-
- dword = Get_NB32_DCT(dev, dct, 0x8c); /* DRAM Timing High */
- dword &= ~(0x1 << 18); /* DisAutoRefresh = 0 */
- Set_NB32_DCT(dev, dct, 0x8c, dword); /* DRAM Timing High */
-
- /* Configure power saving options */
- dword = Get_NB32_DCT(dev, dct, 0xa8); /* Dram Miscellaneous 2 */
- dword |= (0x1 << 22); /* PrtlChPDEnhEn = 0x1 */
- dword |= (0x1 << 21); /* AggrPDEn = 0x1 */
- Set_NB32_DCT(dev, dct, 0xa8, dword); /* Dram Miscellaneous 2 */
-
- /* Configure partial power down delay */
- dword = Get_NB32(dev, 0x244); /* DRAM Controller Miscellaneous 3 */
- dword &= ~0xf; /* PrtlChPDDynDly = 0x2 */
- dword |= 0x2;
- Set_NB32(dev, 0x244, dword); /* DRAM Controller Miscellaneous 3 */
-
- /* Configure power save delays */
- delay = 0xa;
- delay2 = 0x3;
-
- /* Family 15h BKDG Table 214 */
- if ((pDCTstat->Status & (1 << SB_Registered))
- || (pDCTstat->Status & (1 << SB_LoadReduced))) {
- if (memclk_index <= 0x6) {
- if (ddr_voltage_index < 0x4)
- /* 1.5 or 1.35V */
- delay2 = 0x3;
- else
- /* 1.25V */
- delay2 = 0x4;
- }
- else if ((memclk_index == 0xa)
- || (memclk_index == 0xe))
- delay2 = 0x4;
- else if (memclk_index == 0x12)
- delay2 = 0x5;
- else if (memclk_index == 0x16)
- delay2 = 0x6;
- } else {
- if (memclk_index <= 0x6)
- delay2 = 0x3;
- else if ((memclk_index == 0xa)
- || (memclk_index == 0xe))
- delay2 = 0x4;
- else if (memclk_index == 0x12)
- delay2 = 0x5;
- else if (memclk_index == 0x16)
- delay2 = 0x6;
- }
-
- /* Family 15h BKDG Table 215 */
- if (memclk_index <= 0x6)
- delay = 0xa;
- else if (memclk_index == 0xa)
- delay = 0xd;
- else if (memclk_index == 0xe)
- delay = 0x10;
- else if (memclk_index == 0x12)
- delay = 0x14;
- else if (memclk_index == 0x16)
- delay = 0x17;
-
- dword = Get_NB32_DCT(dev, dct, 0x248); /* Dram Power Management 0 */
- dword &= ~(0x3f << 24); /* AggrPDDelay = 0x0 */
- dword &= ~(0x3f << 16); /* PchgPDEnDelay = 0x1 */
- dword |= (0x1 << 16);
- dword &= ~(0x1f << 8); /* Txpdll = delay */
- dword |= ((delay & 0x1f) << 8);
- dword &= ~0xf; /* Txp = delay2 */
- dword |= delay2 & 0xf;
- Set_NB32_DCT(dev, dct, 0x248, dword); /* Dram Power Management 0 */
-
- /* Family 15h BKDG Table 216 */
- if (memclk_index <= 0x6) {
- delay = 0x5;
- delay2 = 0x3;
- } else if (memclk_index == 0xa) {
- delay = 0x6;
- delay2 = 0x3;
- } else if (memclk_index == 0xe) {
- delay = 0x7;
- delay2 = 0x4;
- } else if (memclk_index == 0x12) {
- delay = 0x8;
- delay2 = 0x4;
- } else if (memclk_index == 0x16) {
- delay = 0xa;
- delay2 = 0x5;
- }
-
- dword = Get_NB32_DCT(dev, dct, 0x24c); /* Dram Power Management 1 */
- dword &= ~(0x3f << 24); /* Tcksrx = delay */
- dword |= ((delay & 0x3f) << 24);
- dword &= ~(0x3f << 16); /* Tcksre = delay */
- dword |= ((delay & 0x3f) << 16);
- dword &= ~(0x3f << 8); /* Tckesr = delay2 + 1 */
- dword |= (((delay2 + 1) & 0x3f) << 8);
- dword &= ~0xf; /* Tpd = delay2 */
- dword |= delay2 & 0xf;
- Set_NB32_DCT(dev, dct, 0x24c, dword); /* Dram Power Management 1 */
-
- dword = Get_NB32_DCT(dev, dct, 0x94); /* DRAM Configuration High */
- dword |= (0xf << 24); /* DcqBypassMax = 0xf */
- dword |= (0x1 << 22); /* BankSwizzleMode = 1 */
- dword |= (0x1 << 15); /* PowerDownEn = 1 */
- dword &= ~(0x3 << 10); /* ZqcsInterval = 0x2 */
- dword |= (0x2 << 10);
- Set_NB32_DCT(dev, dct, 0x94, dword); /* DRAM Configuration High */
-
- if (x4_present && x8_present) {
- /* Mixed channel of 4x and 8x DIMMs */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000d);
- dword &= ~(0x3 << 24); /* RxDLLWakeupTime = 0 */
- dword &= ~(0x7 << 20); /* RxCPUpdPeriod = 0 */
- dword &= ~(0xf << 16); /* RxMaxDurDllNoLock = 0 */
- dword &= ~(0x3 << 8); /* TxDLLWakeupTime = 0 */
- dword &= ~(0x7 << 4); /* TxCPUpdPeriod = 0 */
- dword &= ~(0xf); /* TxMaxDurDllNoLock = 0 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000d, dword);
- } else {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000d);
- dword &= ~(0x3 << 24); /* RxDLLWakeupTime = 3 */
- dword |= (0x3 << 24);
- dword &= ~(0x7 << 20); /* RxCPUpdPeriod = 3 */
- dword |= (0x3 << 20);
- dword &= ~(0xf << 16); /* RxMaxDurDllNoLock = 7 */
- dword |= (0x7 << 16);
- dword &= ~(0x3 << 8); /* TxDLLWakeupTime = 3 */
- dword |= (0x3 << 8);
- dword &= ~(0x7 << 4); /* TxCPUpdPeriod = 3 */
- dword |= (0x3 << 4);
- dword &= ~(0xf); /* TxMaxDurDllNoLock = 7 */
- dword |= 0x7;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000d, dword);
- }
-
- if ((memclk_index <= 0x12) && (x4_present != x8_present)) {
- /* MemClkFreq <= 800MHz
- * Not a mixed channel of x4 and x8 DIMMs
- */
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0010 | (index << 8));
- dword |= (0x1 << 12); /* EnRxPadStandby = 1 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0010 | (index << 8), dword);
- }
- } else {
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0010 | (index << 8));
- dword &= ~(0x1 << 12); /* EnRxPadStandby = 0 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0010 | (index << 8), dword);
- }
- }
-
- /* Calculate the Critical Delay Difference for Twrrd */
- cdd_twrrd = 0;
- for (receiver = 0; receiver < 8; receiver += 2) {
- dimm = (receiver >> 1);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, receiver))
- continue;
-
- read_dqs_write_timing_control_registers(current_total_delay_1, dev, dct, dimm, index_reg);
- read_dqs_receiver_enable_control_registers(current_total_delay_2, dev, dct, dimm, index_reg);
-
- for (lane = 0; lane < lane_count; lane++) {
- if (current_total_delay_1[lane] > current_total_delay_2[lane])
- difference = current_total_delay_1[lane] - current_total_delay_2[lane];
- else
- difference = current_total_delay_2[lane] - current_total_delay_1[lane];
-
- if (difference > cdd_twrrd)
- cdd_twrrd = difference;
- }
- }
-
- /* Convert the difference to MEMCLKs */
- cdd_twrrd = (((cdd_twrrd + (1 << 6) - 1) >> 6) & 0xf);
-
- /* Fam15h BKDG section 2.10.5.5.3 */
- if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* LRDIMM */
-
- /* TODO
- * Implement LRDIMM support
- * See Fam15h BKDG Rev. 3.14 section 2.10.5.5
- */
- twrrd = 0xb;
- } else {
- max_cdd_we_delta = (((int16_t)cdd_twrrd + 1 - ((int16_t)write_early * 2)) + 1) / 2;
- if (max_cdd_we_delta < 0)
- max_cdd_we_delta = 0;
- if (((uint16_t)max_cdd_we_delta) > write_odt_delay)
- dword = max_cdd_we_delta;
- else
- dword = write_odt_delay;
- dword += 3;
- if (latency_difference < dword) {
- dword -= latency_difference;
- if (dword < 1)
- twrrd = 1;
- else
- twrrd = dword;
- } else {
- twrrd = 1;
- }
- }
-
- /* Calculate the Critical Delay Difference for TrwtTO */
- cdd_trwtto = 0;
- for (receiver = 0; receiver < 8; receiver += 2) {
- dimm = (receiver >> 1);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, receiver))
- continue;
-
- read_dqs_receiver_enable_control_registers(current_total_delay_1, dev, dct, dimm, index_reg);
- read_dqs_write_timing_control_registers(current_total_delay_2, dev, dct, dimm, index_reg);
-
- for (lane = 0; lane < lane_count; lane++) {
- if (current_total_delay_1[lane] > current_total_delay_2[lane])
- difference = current_total_delay_1[lane] - current_total_delay_2[lane];
- else
- difference = current_total_delay_2[lane] - current_total_delay_1[lane];
-
- if (difference > cdd_trwtto)
- cdd_trwtto = difference;
- }
- }
-
- /* Convert the difference to MEMCLKs */
- cdd_trwtto = (((cdd_trwtto + (1 << 6) - 1) >> 6) & 0xf);
-
- /* Fam15h BKDG section 2.10.5.5.4 */
- if (max_dimms_installable == 1)
- min_value = 0;
- else
- min_value = read_odt_delay + buffer_data_delay;
- cdd_trwtto_we_delta = (((int16_t)cdd_trwtto - 1 + ((int16_t)write_early * 2)) + 1) / 2;
- cdd_trwtto_we_delta += latency_difference + 3;
- if (cdd_trwtto_we_delta < 0)
- cdd_trwtto_we_delta = 0;
- if ((cdd_trwtto_we_delta) > min_value)
- trwtto = cdd_trwtto_we_delta;
- else
- trwtto = min_value;
-
- dword = Get_NB32_DCT(dev, dct, 0xa4); /* DRAM Controller Temperature Throttle */
- dword &= ~(0x1 << 11); /* BwCapEn = 0 */
- dword &= ~(0x1 << 8); /* ODTSEn = dimm_event_l_pin_support */
- dword |= (dimm_event_l_pin_support & 0x1) << 8;
- Set_NB32_DCT(dev, dct, 0xa4, dword); /* DRAM Controller Temperature Throttle */
-
- dword = Get_NB32_DCT(dev, dct, 0x110); /* DRAM Controller Select Low */
- dword &= ~(0x1 << 2); /* DctSelIntLvEn = interleave_channels */
- dword |= (interleave_channels & 0x1) << 2;
- dword |= (0x3 << 6); /* DctSelIntLvAddr = 0x3 */
- Set_NB32_DCT(dev, dct, 0x110, dword); /* DRAM Controller Select Low */
-
- /* NOTE
- * ECC-related setup is performed as part of ECCInit_D and must not be located here,
- * otherwise semi-random lockups will occur due to misconfigured scrubbing hardware!
- */
-
- /* Fam15h BKDG section 2.10.5.5.2 */
- dword = Get_NB32_DCT(dev, dct, 0x214); /* DRAM Timing 4 */
- dword &= ~(0xf << 16); /* TwrwrSdSc = 0x1 */
- dword |= (0x1 << 16);
- dword &= ~(0xf << 8); /* TwrwrSdDc = twrwrsddc */
- dword |= ((twrwrsddc & 0xf) << 8);
- dword &= ~(0xf); /* TwrwrDd = twrwrdd */
- dword |= (twrwrdd & 0xf);
- Set_NB32_DCT(dev, dct, 0x214, dword); /* DRAM Timing 4 */
-
- /* Fam15h BKDG section 2.10.5.5.3 */
- dword = Get_NB32_DCT(dev, dct, 0x218); /* DRAM Timing 5 */
- dword &= ~(0xf << 24); /* TrdrdSdSc = 0x1 */
- dword |= (0x1 << 24);
- dword &= ~(0xf << 16); /* TrdrdSdDc = trdrdsddc */
- dword |= ((trdrdsddc & 0xf) << 16);
- dword &= ~(0xf << 8); /* Twrrd = twrrd */
- dword |= ((twrrd & 0xf) << 8);
- dword &= ~(0xf); /* TrdrdDd = trdrddd */
- dword |= (trdrddd & 0xf);
- Set_NB32_DCT(dev, dct, 0x218, dword); /* DRAM Timing 5 */
-
- /* Fam15h BKDG section 2.10.5.5.4 */
- dword = Get_NB32_DCT(dev, dct, 0x21c); /* DRAM Timing 6 */
- dword &= ~(0x1f << 8); /* TrwtTO = trwtto */
- dword |= ((trwtto & 0x1f) << 8);
- dword &= ~(0x1f << 16); /* TrwtWB = TrwtTO + 1 */
- dword |= ((((dword >> 8) & 0x1f) + 1) << 16);
- Set_NB32_DCT(dev, dct, 0x21c, dword); /* DRAM Timing 6 */
-
- /* Enable prefetchers */
- dword = Get_NB32(dev, 0x11c); /* Memory Controller Configuration High */
- dword &= ~(0x1 << 13); /* PrefIoDis = 0 */
- dword &= ~(0x1 << 12); /* PrefCpuDis = 0 */
- Set_NB32(dev, 0x11c, dword); /* Memory Controller Configuration High */
- }
-}
-
-static void exit_training_mode_fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- uint8_t node;
- uint8_t dct;
-
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + node;
-
- if (pDCTstat->NodePresent)
- for (dct = 0; dct < 2; dct++)
- fam15EnableTrainingMode(pMCTstat, pDCTstat, dct, 0);
- }
-}
-
-static void DQSTiming_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA, uint8_t allow_config_restore)
-{
- uint8_t Node;
- u8 nv_DQSTrainCTL;
- uint8_t retry_requested;
-
- if (pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW)) {
- return;
- }
-
- /* Set initial TCWL offset to zero */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- uint8_t dct;
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- for (dct = 0; dct < 2; dct++)
- pDCTstat->tcwl_delay[dct] = 0;
- }
-
-retry_dqs_training_and_levelization:
- nv_DQSTrainCTL = !allow_config_restore;
-
- mct_BeforeDQSTrain_D(pMCTstat, pDCTstatA);
- phyAssistedMemFnceTraining(pMCTstat, pDCTstatA, -1);
-
- if (is_fam15h()) {
- struct DCTStatStruc *pDCTstat;
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
- if (pDCTstat->NodePresent) {
- if (pDCTstat->DIMMValidDCT[0])
- InitPhyCompensation(pMCTstat, pDCTstat, 0);
- if (pDCTstat->DIMMValidDCT[1])
- InitPhyCompensation(pMCTstat, pDCTstat, 1);
- }
- }
- }
-
- mctHookBeforeAnyTraining(pMCTstat, pDCTstatA);
- if (!is_fam15h()) {
- /* TODO: should be in mctHookBeforeAnyTraining */
- _WRMSR(MTRR_FIX_4K_E0000, 0x04040404, 0x04040404);
- _WRMSR(MTRR_FIX_4K_E8000, 0x04040404, 0x04040404);
- _WRMSR(MTRR_FIX_4K_F0000, 0x04040404, 0x04040404);
- _WRMSR(MTRR_FIX_4K_F8000, 0x04040404, 0x04040404);
- }
-
- if (nv_DQSTrainCTL) {
- mct_WriteLevelization_HW(pMCTstat, pDCTstatA, FirstPass);
-
- if (is_fam15h()) {
- /* Receiver Enable Training Pass 1 */
- TrainReceiverEn_D(pMCTstat, pDCTstatA, FirstPass);
- }
-
- mct_WriteLevelization_HW(pMCTstat, pDCTstatA, SecondPass);
-
- if (is_fam15h()) {
-
- /* TODO:
- * Determine why running TrainReceiverEn_D in SecondPass
- * mode yields less stable training values than when run
- * in FirstPass mode as in the HACK below.
- */
- TrainReceiverEn_D(pMCTstat, pDCTstatA, FirstPass);
- } else {
- TrainReceiverEn_D(pMCTstat, pDCTstatA, FirstPass);
- }
-
- mct_TrainDQSPos_D(pMCTstat, pDCTstatA);
-
- /* Determine if DQS training requested a retrain attempt */
- retry_requested = 0;
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- if (pDCTstat->TrainErrors & (1 << SB_FatalError)) {
- printk(BIOS_ERR, "DIMM training FAILED! Restarting system...");
- soft_reset();
- }
- if (pDCTstat->TrainErrors & (1 << SB_RetryConfigTrain)) {
- retry_requested = 1;
-
- /* Clear previous errors */
- pDCTstat->TrainErrors &= ~(1 << SB_RetryConfigTrain);
- pDCTstat->TrainErrors &= ~(1 << SB_NODQSPOS);
- pDCTstat->ErrStatus &= ~(1 << SB_RetryConfigTrain);
- pDCTstat->ErrStatus &= ~(1 << SB_NODQSPOS);
- }
- }
- }
-
- /* Retry training and levelization if requested */
- if (retry_requested) {
- printk(BIOS_DEBUG, "%s: Restarting training on algorithm request\n", __func__);
- /* Reset frequency to minimum */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (pDCTstat->NodePresent) {
- uint8_t original_target_freq = pDCTstat->TargetFreq;
- uint8_t original_auto_speed = pDCTstat->DIMMAutoSpeed;
- pDCTstat->TargetFreq = mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK));
- pDCTstat->Speed = pDCTstat->DIMMAutoSpeed = pDCTstat->TargetFreq;
- SetTargetFreq(pMCTstat, pDCTstatA, Node);
- pDCTstat->TargetFreq = original_target_freq;
- pDCTstat->DIMMAutoSpeed = original_auto_speed;
- }
- }
- /* Apply any DIMM timing changes */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (pDCTstat->NodePresent) {
- AutoCycTiming_D(pMCTstat, pDCTstat, 0);
- if (!pDCTstat->GangedMode)
- if (pDCTstat->DIMMValidDCT[1] > 0)
- AutoCycTiming_D(pMCTstat, pDCTstat, 1);
- }
- }
- goto retry_dqs_training_and_levelization;
- }
-
- TrainMaxRdLatency_En_D(pMCTstat, pDCTstatA);
-
- if (is_fam15h())
- exit_training_mode_fam15(pMCTstat, pDCTstatA);
- else
- mctSetEccDQSRcvrEn_D(pMCTstat, pDCTstatA);
- } else {
- mct_WriteLevelization_HW(pMCTstat, pDCTstatA, FirstPass);
-
- mct_WriteLevelization_HW(pMCTstat, pDCTstatA, SecondPass);
-
-#if CONFIG(HAVE_ACPI_RESUME)
- printk(BIOS_DEBUG, "mctAutoInitMCT_D: Restoring DIMM training configuration from NVRAM\n");
- if (restore_mct_information_from_nvram(1) != 0)
- printk(BIOS_CRIT, "%s: ERROR: Unable to restore DCT configuration from NVRAM\n", __func__);
-#endif
-
- if (is_fam15h())
- exit_training_mode_fam15(pMCTstat, pDCTstatA);
-
- pMCTstat->GStatus |= 1 << GSB_ConfigRestored;
- }
-
- if (is_fam15h()) {
- struct DCTStatStruc *pDCTstat;
-
- /* Switch DCT control register to DCT 0 per Erratum 505 */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
- if (pDCTstat->NodePresent) {
- fam15h_switch_dct(pDCTstat->dev_map, 0);
- }
- }
- }
-
- /* FIXME - currently uses calculated value TrainMaxReadLatency_D(pMCTstat, pDCTstatA); */
- mctHookAfterAnyTraining();
-}
-
-static void LoadDQSSigTmgRegs_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node, Receiver, Channel, Dir, DIMM;
- u32 dev;
- u32 index_reg;
- u32 reg;
- u32 index;
- u32 val;
- u8 ByteLane;
- u8 txdqs;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->DCTSysLimit) {
- dev = pDCTstat->dev_dct;
- for (Channel = 0;Channel < 2; Channel++) {
- /* there are four receiver pairs,
- loosely associated with chipselects.*/
- index_reg = 0x98;
- for (Receiver = 0; Receiver < 8; Receiver += 2) {
- /* Set Receiver Enable Values */
- mct_SetRcvrEnDly_D(pDCTstat,
- 0, /* RcvrEnDly */
- 1, /* FinalValue, From stack */
- Channel,
- Receiver,
- dev, index_reg,
- (Receiver >> 1) * 3 + 0x10, /* Addl_Index */
- 2); /* Pass Second Pass ? */
- /* Restore Write levelization training data */
- for (ByteLane = 0; ByteLane < 9; ByteLane ++) {
- txdqs = pDCTstat->persistentData.CH_D_B_TxDqs[Channel][Receiver >> 1][ByteLane];
- index = Table_DQSRcvEn_Offset[ByteLane >> 1];
- index += (Receiver >> 1) * 3 + 0x10 + 0x20; /* Addl_Index */
- val = Get_NB32_index_wait_DCT(dev, Channel, 0x98, index);
- if (ByteLane & 1) { /* odd byte lane */
- val &= ~(0xFF << 16);
- val |= txdqs << 16;
- } else {
- val &= ~0xFF;
- val |= txdqs;
- }
- Set_NB32_index_wait_DCT(dev, Channel, 0x98, index, val);
- }
- }
- }
- for (Channel = 0; Channel < 2; Channel++) {
- SetEccDQSRcvrEn_D(pDCTstat, Channel);
- }
-
- for (Channel = 0; Channel < 2; Channel++) {
- u8 *p;
- index_reg = 0x98;
-
- /* NOTE:
- * when 400, 533, 667, it will support dimm0/1/2/3,
- * and set conf for dimm0, hw will copy to dimm1/2/3
- * set for dimm1, hw will copy to dimm3
- * Rev A/B only support DIMM0/1 when 800MHz and above
- * + 0x100 to next dimm
- * Rev C support DIMM0/1/2/3 when 800MHz and above
- * + 0x100 to next dimm
- */
- for (DIMM = 0; DIMM < 4; DIMM++) {
- if (DIMM == 0) {
- index = 0; /* CHA Write Data Timing Low */
- } else {
- if (pDCTstat->Speed >= mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK))) {
- index = 0x100 * DIMM;
- } else {
- break;
- }
- }
- for (Dir = 0; Dir < 2; Dir++) {/* RD/WR */
- p = pDCTstat->CH_D_DIR_B_DQS[Channel][DIMM][Dir];
- val = stream_to_int(p); /* CHA Read Data Timing High */
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, index+1, val);
- val = stream_to_int(p+4); /* CHA Write Data Timing High */
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, index+2, val);
- val = *(p+8); /* CHA Write ECC Timing */
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, index+3, val);
- index += 4;
- }
- }
- }
-
- for (Channel = 0; Channel < 2; Channel++) {
- reg = 0x78;
- val = Get_NB32_DCT(dev, Channel, reg);
- val &= ~(0x3ff<<22);
- val |= ((u32) pDCTstat->CH_MaxRdLat[Channel][0] << 22);
- val &= ~(1<<DqsRcvEnTrain);
- Set_NB32_DCT(dev, Channel, reg, val); /* program MaxRdLatency to correspond with current delay*/
- }
- }
- }
-}
-
-static void HTMemMapInit_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u32 NextBase, BottomIO;
- u8 _MemHoleRemap, DramHoleBase;
- u32 HoleSize, DramSelBaseAddr;
-
- u32 val;
- u32 base;
- u32 limit;
- u32 dev, devx;
- struct DCTStatStruc *pDCTstat;
-
- _MemHoleRemap = mctGet_NVbits(NV_MemHole);
-
- if (pMCTstat->HoleBase == 0) {
- DramHoleBase = mctGet_NVbits(NV_BottomIO);
- } else {
- DramHoleBase = pMCTstat->HoleBase >> (24-8);
- }
-
- BottomIO = DramHoleBase << (24-8);
-
- NextBase = 0;
- pDCTstat = pDCTstatA + 0;
- dev = pDCTstat->dev_map;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
- devx = pDCTstat->dev_map;
- DramSelBaseAddr = 0;
- if (!pDCTstat->GangedMode) {
- DramSelBaseAddr = pDCTstat->NodeSysLimit - pDCTstat->DCTSysLimit;
- /*In unganged mode, we must add DCT0 and DCT1 to DCTSysLimit */
- val = pDCTstat->NodeSysLimit;
- if ((val & 0xFF) == 0xFE) {
- DramSelBaseAddr++;
- val++;
- }
- pDCTstat->DCTSysLimit = val;
- }
-
- base = pDCTstat->DCTSysBase;
- limit = pDCTstat->DCTSysLimit;
- if (limit > base) {
- base += NextBase;
- limit += NextBase;
- DramSelBaseAddr += NextBase;
- printk(BIOS_DEBUG, " Node: %02x base: %02x limit: %02x BottomIO: %02x\n", Node, base, limit, BottomIO);
-
- if (_MemHoleRemap) {
- if ((base < BottomIO) && (limit >= BottomIO)) {
- /* HW Dram Remap */
- pDCTstat->Status |= 1 << SB_HWHole;
- pMCTstat->GStatus |= 1 << GSB_HWHole;
- pDCTstat->DCTSysBase = base;
- pDCTstat->DCTSysLimit = limit;
- pDCTstat->DCTHoleBase = BottomIO;
- pMCTstat->HoleBase = BottomIO;
- HoleSize = _4GB_RJ8 - BottomIO; /* HoleSize[39:8] */
- if ((DramSelBaseAddr > 0) && (DramSelBaseAddr < BottomIO))
- base = DramSelBaseAddr;
- val = ((base + HoleSize) >> (24-8)) & 0xFF;
- val <<= 8; /* shl 16, rol 24 */
- val |= DramHoleBase << 24;
- val |= 1 << DramHoleValid;
- Set_NB32(devx, 0xF0, val); /* Dram Hole Address Reg */
- pDCTstat->DCTSysLimit += HoleSize;
- base = pDCTstat->DCTSysBase;
- limit = pDCTstat->DCTSysLimit;
- } else if (base == BottomIO) {
- /* SW Node Hoist */
- pMCTstat->GStatus |= 1<<GSB_SpIntRemapHole;
- pDCTstat->Status |= 1<<SB_SWNodeHole;
- pMCTstat->GStatus |= 1<<GSB_SoftHole;
- pMCTstat->HoleBase = base;
- limit -= base;
- base = _4GB_RJ8;
- limit += base;
- pDCTstat->DCTSysBase = base;
- pDCTstat->DCTSysLimit = limit;
- } else {
- /* No Remapping. Normal Contiguous mapping */
- pDCTstat->DCTSysBase = base;
- pDCTstat->DCTSysLimit = limit;
- }
- } else {
- /*No Remapping. Normal Contiguous mapping*/
- pDCTstat->DCTSysBase = base;
- pDCTstat->DCTSysLimit = limit;
- }
- base |= 3; /* set WE,RE fields*/
- pMCTstat->SysLimit = limit;
- }
- Set_NB32(dev, 0x40 + (Node << 3), base); /* [Node] + Dram Base 0 */
-
- val = limit & 0xFFFF0000;
- val |= Node;
- Set_NB32(dev, 0x44 + (Node << 3), val); /* set DstNode */
-
- printk(BIOS_DEBUG, " Node: %02x base: %02x limit: %02x\n", Node, base, limit);
- limit = pDCTstat->DCTSysLimit;
- if (limit) {
- NextBase = (limit & 0xFFFF0000) + 0x10000;
- }
- }
-
- /* Copy dram map from Node 0 to Node 1-7 */
- for (Node = 1; Node < MAX_NODES_SUPPORTED; Node++) {
- u32 reg;
- pDCTstat = pDCTstatA + Node;
- devx = pDCTstat->dev_map;
-
- if (pDCTstat->NodePresent) {
- printk(BIOS_DEBUG, " Copy dram map from Node 0 to Node %02x\n", Node);
- reg = 0x40; /*Dram Base 0*/
- do {
- val = Get_NB32(dev, reg);
- Set_NB32(devx, reg, val);
- reg += 4;
- } while (reg < 0x80);
- } else {
- break; /* stop at first absent Node */
- }
- }
-
- /*Copy dram map to F1x120/124*/
- mct_HTMemMapExt(pMCTstat, pDCTstatA);
-}
-
-void MCTMemClr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
-
- /* Initiates a memory clear operation for all node. The mem clr
- * is done in parallel. After the memclr is complete, all processors
- * status are checked to ensure that memclr has completed.
- */
- u8 Node;
- uint32_t dword;
- struct DCTStatStruc *pDCTstat;
-
- if (!mctGet_NVbits(NV_DQSTrainCTL)) {
- /* FIXME: callback to wrapper: mctDoWarmResetMemClr_D */
- } else { /* NV_DQSTrainCTL == 1 */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- DCTMemClr_Init_D(pMCTstat, pDCTstat);
- }
- }
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- DCTMemClr_Sync_D(pMCTstat, pDCTstat);
- }
- }
- }
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- /* Enable prefetchers */
- dword = Get_NB32(pDCTstat->dev_dct, 0x11c); /* Memory Controller Configuration High */
- dword &= ~(0x1 << 13); /* PrefIoDis = 0 */
- dword &= ~(0x1 << 12); /* PrefCpuDis = 0 */
- Set_NB32(pDCTstat->dev_dct, 0x11c, dword); /* Memory Controller Configuration High */
- }
-}
-
-void DCTMemClr_Init_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 val;
- u32 dev;
- uint32_t dword;
-
- /* Initiates a memory clear operation on one node */
- if (pDCTstat->DCTSysLimit) {
- dev = pDCTstat->dev_dct;
-
- /* Disable prefetchers */
- dword = Get_NB32(dev, 0x11c); /* Memory Controller Configuration High */
- dword |= 0x1 << 13; /* PrefIoDis = 1 */
- dword |= 0x1 << 12; /* PrefCpuDis = 1 */
- Set_NB32(dev, 0x11c, dword); /* Memory Controller Configuration High */
-
- do {
- val = Get_NB32(dev, 0x110);
- } while (val & (1 << MemClrBusy));
-
- val |= (1 << MemClrInit);
- Set_NB32(dev, 0x110, val);
- }
-}
-
-void DCTMemClr_Sync_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- uint32_t dword;
- uint32_t dev = pDCTstat->dev_dct;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- /* Ensure that a memory clear operation has completed on one node */
- if (pDCTstat->DCTSysLimit) {
- printk(BIOS_DEBUG, "%s: Waiting for memory clear to complete", __func__);
- do {
- dword = Get_NB32(dev, 0x110);
-
- printk(BIOS_DEBUG, ".");
- } while (dword & (1 << MemClrBusy));
-
- printk(BIOS_DEBUG, "\n");
- do {
- printk(BIOS_DEBUG, ".");
- dword = Get_NB32(dev, 0x110);
- } while (!(dword & (1 << Dr_MemClrStatus)));
- printk(BIOS_DEBUG, "\n");
- }
-
- /* Enable prefetchers */
- dword = Get_NB32(dev, 0x11c); /* Memory Controller Configuration High */
- dword &= ~(0x1 << 13); /* PrefIoDis = 0 */
- dword &= ~(0x1 << 12); /* PrefCpuDis = 0 */
- Set_NB32(dev, 0x11c, dword); /* Memory Controller Configuration High */
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-u8 NodePresent_D(u8 Node)
-{
- /*
- * Determine if a single Hammer Node exists within the network.
- */
- u32 dev;
- u32 val;
- u32 dword;
- u8 ret = 0;
-
- dev = PA_HOST(Node); /*test device/vendor id at host bridge */
- val = Get_NB32(dev, 0);
- dword = mct_NodePresent_D(); /* FIXME: BOZO -11001022h rev for F */
- if (val == dword) { /* AMD Hammer Family CPU HT Configuration */
- if (oemNodePresent_D(Node, &ret))
- goto finish;
- /* Node ID register */
- val = Get_NB32(dev, 0x60);
- val &= 0x07;
- dword = Node;
- if (val == dword) /* current nodeID = requested nodeID ? */
- ret = 1;
- }
-finish:
- return ret;
-}
-
-static void DCTPreInit_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /*
- * Run DCT pre-initialization tasks
- */
- uint32_t dword;
-
- /* Reset DCT registers */
- ClearDCT_D(pMCTstat, pDCTstat, dct);
- pDCTstat->stopDCT[dct] = 1; /* preload flag with 'disable' */
-
- if (!is_fam15h()) {
- /* Enable DDR3 support */
- dword = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94);
- dword |= 1 << Ddr3Mode;
- Set_NB32_DCT(pDCTstat->dev_dct, dct, 0x94, dword);
- }
-
- /* Read the SPD information into the data structures */
- if (mct_DIMMPresence(pMCTstat, pDCTstat, dct) < SC_StopError) {
- printk(BIOS_DEBUG, "\t\tDCTPreInit_D: mct_DIMMPresence Done\n");
- }
-}
-
-static void DCTInit_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /*
- * Initialize DRAM on single Athlon 64/Opteron Node.
- */
- uint32_t dword;
-
- if (!is_fam15h()) {
- /* (Re)-enable DDR3 support */
- dword = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94);
- dword |= 1 << Ddr3Mode;
- Set_NB32_DCT(pDCTstat->dev_dct, dct, 0x94, dword);
- }
-
- if (mct_SPDCalcWidth(pMCTstat, pDCTstat, dct) < SC_StopError) {
- printk(BIOS_DEBUG, "\t\tDCTInit_D: mct_SPDCalcWidth Done\n");
- if (AutoCycTiming_D(pMCTstat, pDCTstat, dct) < SC_StopError) {
- printk(BIOS_DEBUG, "\t\tDCTInit_D: AutoCycTiming_D Done\n");
-
- /* SkewMemClk must be set before MemClkFreqVal is set
- * This relies on DCTInit_D being called for DCT 1 after
- * it has already been called for DCT 0...
- */
- if (is_fam15h()) {
- /* Set memory clock skew if needed */
- if (dct == 1) {
- if (!pDCTstat->stopDCT[0]) {
- printk(BIOS_DEBUG, "\t\tDCTInit_D: enabling intra-channel clock skew\n");
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 0x0d0fe00a);
- dword |= (0x1 << 4); /* SkewMemClk = 1 */
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 0x0d0fe00a, dword);
- }
- }
- }
-
- if (AutoConfig_D(pMCTstat, pDCTstat, dct) < SC_StopError) {
- printk(BIOS_DEBUG, "\t\tDCTInit_D: AutoConfig_D Done\n");
- if (PlatformSpec_D(pMCTstat, pDCTstat, dct) < SC_StopError) {
- printk(BIOS_DEBUG, "\t\tDCTInit_D: PlatformSpec_D Done\n");
- pDCTstat->stopDCT[dct] = 0;
- }
- }
- }
- }
-}
-
-static void DCTFinalInit_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 dct)
-{
- uint32_t dword;
-
- /* Finalize DRAM init on a single node */
- if (!pDCTstat->stopDCT[dct]) {
- if (!(pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW))) {
- printk(BIOS_DEBUG, "\t\tDCTFinalInit_D: StartupDCT_D Start\n");
- StartupDCT_D(pMCTstat, pDCTstat, dct);
- printk(BIOS_DEBUG, "\t\tDCTFinalInit_D: StartupDCT_D Done\n");
- }
- }
-
- if (pDCTstat->stopDCT[dct]) {
- dword = 1 << DisDramInterface;
- Set_NB32_DCT(pDCTstat->dev_dct, dct, 0x94, dword);
-
- dword = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x90);
- dword &= ~(1 << ParEn);
- Set_NB32_DCT(pDCTstat->dev_dct, dct, 0x90, dword);
-
- /* To maximize power savings when DisDramInterface = 1b,
- * all of the MemClkDis bits should also be set.
- */
- Set_NB32_DCT(pDCTstat->dev_dct, dct, 0x88, 0xff000000);
- } else {
- mct_EnDllShutdownSR(pMCTstat, pDCTstat, dct);
- }
-}
-
-static void SyncDCTsReady_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /* Wait (and block further access to dram) for all DCTs to be ready,
- * by polling all InitDram bits and waiting for possible memory clear
- * operations to be complete. Read MemClkFreqVal bit to see if
- * the DIMMs are present in this node.
- */
- u8 Node;
- u32 val;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- mct_SyncDCTsReady(pDCTstat);
- }
-
- if (!is_fam15h()) {
- /* v6.1.3 */
- /* re-enable phy compensation engine when dram init is completed on all nodes. */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (pDCTstat->NodePresent) {
- if (pDCTstat->DIMMValidDCT[0] > 0 || pDCTstat->DIMMValidDCT[1] > 0) {
- /* re-enable phy compensation engine when dram init on both DCTs is completed. */
- val = Get_NB32_index_wait(pDCTstat->dev_dct, 0x98, 0x8);
- val &= ~(1 << DisAutoComp);
- Set_NB32_index_wait(pDCTstat->dev_dct, 0x98, 0x8, val);
- }
- }
- }
- }
-
- /* wait 750us before any memory access can be made. */
- mct_Wait(15000);
-}
-
-void StartupDCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Read MemClkFreqVal bit to see if the DIMMs are present in this node.
- * If the DIMMs are present then set the DRAM Enable bit for this node.
- *
- * Setting dram init starts up the DCT state machine, initializes the
- * dram devices with MRS commands, and kicks off any
- * HW memory clear process that the chip is capable of. The sooner
- * that dram init is set for all nodes, the faster the memory system
- * initialization can complete. Thus, the init loop is unrolled into
- * two loops so as to start the processes for non BSP nodes sooner.
- * This procedure will not wait for the process to finish.
- * Synchronization is handled elsewhere.
- */
- u32 val;
- u32 dev;
-
- dev = pDCTstat->dev_dct;
- val = Get_NB32_DCT(dev, dct, 0x94);
- if (val & (1<<MemClkFreqVal)) {
- mctHookBeforeDramInit(); /* generalized Hook */
- if (!(pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW)))
- mct_DramInit(pMCTstat, pDCTstat, dct);
- AfterDramInit_D(pDCTstat, dct);
- mctHookAfterDramInit(); /* generalized Hook*/
- }
-}
-
-static void ClearDCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 reg_end;
- u32 dev = pDCTstat->dev_dct;
- u32 reg = 0x40;
- u32 val = 0;
-
- if (pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW)) {
- reg_end = 0x78;
- } else {
- reg_end = 0xA4;
- }
-
- while (reg < reg_end) {
- if ((reg & 0xFF) == 0x84) {
- if (is_fam15h()) {
- val = Get_NB32_DCT(dev, dct, reg);
- val &= ~(0x1 << 23); /* Clear PchgPDModeSel */
- val &= ~0x3; /* Clear BurstCtrl */
- }
- }
- if ((reg & 0xFF) == 0x90) {
- if (pDCTstat->LogicalCPUID & AMD_DR_Dx) {
- val = Get_NB32_DCT(dev, dct, reg); /* get DRAMConfigLow */
- val |= 0x08000000; /* preserve value of DisDllShutdownSR for only Rev.D */
- }
- }
- Set_NB32_DCT(dev, dct, reg, val);
- val = 0;
- reg += 4;
- }
-
- val = 0;
- dev = pDCTstat->dev_map;
- reg = 0xF0;
- Set_NB32(dev, reg, val);
-}
-
-void SPD2ndTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 i;
- u16 Twr, Trtp;
- u16 Trp, Trrd, Trcd, Tras, Trc;
- u8 Trfc[4];
- u16 Tfaw;
- u16 Tcwl; /* Fam15h only */
- u32 DramTimingLo, DramTimingHi;
- u8 tCK16x;
- u16 Twtr;
- uint8_t Etr[2];
- u8 LDIMM;
- u8 MTB16x;
- u8 byte;
- u32 dword;
- u32 dev;
- u32 val;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- /* Gather all DIMM mini-max values for cycle timing data */
- Trp = 0;
- Trrd = 0;
- Trcd = 0;
- Trtp = 0;
- Tras = 0;
- Trc = 0;
- Twr = 0;
- Twtr = 0;
- for (i = 0; i < 2; i++)
- Etr[i] = 0;
- for (i = 0; i < 4; i++)
- Trfc[i] = 0;
- Tfaw = 0;
-
- for (i = 0; i< MAX_DIMMS_SUPPORTED; i++) {
- LDIMM = i >> 1;
- if (pDCTstat->DIMMValid & (1 << i)) {
- val = pDCTstat->spd_data.spd_bytes[dct + i][SPD_MTBDivisor]; /* MTB = Dividend/Divisor */
- MTB16x = ((pDCTstat->spd_data.spd_bytes[dct + i][SPD_MTBDividend] & 0xff) << 4);
- MTB16x /= val; /* transfer to MTB*16 */
-
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_tRPmin];
- val = byte * MTB16x;
- if (Trp < val)
- Trp = val;
-
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_tRRDmin];
- val = byte * MTB16x;
- if (Trrd < val)
- Trrd = val;
-
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_tRCDmin];
- val = byte * MTB16x;
- if (Trcd < val)
- Trcd = val;
-
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_tRTPmin];
- val = byte * MTB16x;
- if (Trtp < val)
- Trtp = val;
-
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_tWRmin];
- val = byte * MTB16x;
- if (Twr < val)
- Twr = val;
-
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_tWTRmin];
- val = byte * MTB16x;
- if (Twtr < val)
- Twtr = val;
-
- val = pDCTstat->spd_data.spd_bytes[dct + i][SPD_Upper_tRAS_tRC] & 0xff;
- val >>= 4;
- val <<= 8;
- val |= pDCTstat->spd_data.spd_bytes[dct + i][SPD_tRCmin] & 0xff;
- val *= MTB16x;
- if (Trc < val)
- Trc = val;
-
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_Density] & 0xf;
- if (Trfc[LDIMM] < byte)
- Trfc[LDIMM] = byte;
-
- val = pDCTstat->spd_data.spd_bytes[dct + i][SPD_Upper_tRAS_tRC] & 0xf;
- val <<= 8;
- val |= (pDCTstat->spd_data.spd_bytes[dct + i][SPD_tRASmin] & 0xff);
- val *= MTB16x;
- if (Tras < val)
- Tras = val;
-
- val = pDCTstat->spd_data.spd_bytes[dct + i][SPD_Upper_tFAW] & 0xf;
- val <<= 8;
- val |= pDCTstat->spd_data.spd_bytes[dct + i][SPD_tFAWmin] & 0xff;
- val *= MTB16x;
- if (Tfaw < val)
- Tfaw = val;
-
- /* Determine if the DIMMs on this channel support 95°C ETR */
- if (pDCTstat->spd_data.spd_bytes[dct + i][SPD_Thermal] & 0x1)
- Etr[dct] = 1;
- } /* Dimm Present */
- }
-
- /* Convert DRAM CycleTiming values and store into DCT structure */
- byte = pDCTstat->DIMMAutoSpeed;
- if (is_fam15h()) {
- if (byte == 0x16)
- tCK16x = 17;
- else if (byte == 0x12)
- tCK16x = 20;
- else if (byte == 0xe)
- tCK16x = 24;
- else if (byte == 0xa)
- tCK16x = 30;
- else if (byte == 0x6)
- tCK16x = 40;
- else
- tCK16x = 48;
- } else {
- if (byte == 7)
- tCK16x = 20;
- else if (byte == 6)
- tCK16x = 24;
- else if (byte == 5)
- tCK16x = 30;
- else
- tCK16x = 40;
- }
-
- /* Notes:
- 1. All secondary time values given in SPDs are in binary with units of ns.
- 2. Some time values are scaled by 16, in order to have least count of 0.25 ns
- (more accuracy). JEDEC SPD spec. shows which ones are x1 and x4.
- 3. Internally to this SW, cycle time, tCK16x, is scaled by 16 to match time values
- */
-
- /* Tras */
- pDCTstat->DIMMTras = (u16)Tras;
- val = Tras / tCK16x;
- if (Tras % tCK16x) { /* round up number of busclocks */
- val++;
- }
- if (val < Min_TrasT)
- val = Min_TrasT;
- else if (val > Max_TrasT)
- val = Max_TrasT;
- pDCTstat->Tras = val;
-
- /* Trp */
- pDCTstat->DIMMTrp = Trp;
- val = Trp / tCK16x;
- if (Trp % tCK16x) { /* round up number of busclocks */
- val++;
- }
- if (val < Min_TrpT)
- val = Min_TrpT;
- else if (val > Max_TrpT)
- val = Max_TrpT;
- pDCTstat->Trp = val;
-
- /* Trrd */
- pDCTstat->DIMMTrrd = Trrd;
- val = Trrd / tCK16x;
- if (Trrd % tCK16x) { /* round up number of busclocks */
- val++;
- }
- if (val < Min_TrrdT)
- val = Min_TrrdT;
- else if (val > Max_TrrdT)
- val = Max_TrrdT;
- pDCTstat->Trrd = val;
-
- /* Trcd */
- pDCTstat->DIMMTrcd = Trcd;
- val = Trcd / tCK16x;
- if (Trcd % tCK16x) { /* round up number of busclocks */
- val++;
- }
- if (val < Min_TrcdT)
- val = Min_TrcdT;
- else if (val > Max_TrcdT)
- val = Max_TrcdT;
- pDCTstat->Trcd = val;
-
- /* Trc */
- pDCTstat->DIMMTrc = Trc;
- val = Trc / tCK16x;
- if (Trc % tCK16x) { /* round up number of busclocks */
- val++;
- }
- if (val < Min_TrcT)
- val = Min_TrcT;
- else if (val > Max_TrcT)
- val = Max_TrcT;
- pDCTstat->Trc = val;
-
- /* Trtp */
- pDCTstat->DIMMTrtp = Trtp;
- val = Trtp / tCK16x;
- if (Trtp % tCK16x) {
- val ++;
- }
- if (val < Min_TrtpT)
- val = Min_TrtpT;
- else if (val > Max_TrtpT)
- val = Max_TrtpT;
- pDCTstat->Trtp = val;
-
- /* Twr */
- pDCTstat->DIMMTwr = Twr;
- val = Twr / tCK16x;
- if (Twr % tCK16x) { /* round up number of busclocks */
- val++;
- }
- if (val < Min_TwrT)
- val = Min_TwrT;
- else if (val > Max_TwrT)
- val = Max_TwrT;
- pDCTstat->Twr = val;
-
- /* Twtr */
- pDCTstat->DIMMTwtr = Twtr;
- val = Twtr / tCK16x;
- if (Twtr % tCK16x) { /* round up number of busclocks */
- val++;
- }
- if (val < Min_TwtrT)
- val = Min_TwtrT;
- else if (val > Max_TwtrT)
- val = Max_TwtrT;
- pDCTstat->Twtr = val;
-
- /* Trfc0-Trfc3 */
- for (i = 0; i < 4; i++)
- pDCTstat->Trfc[i] = Trfc[i];
-
- /* Tfaw */
- pDCTstat->DIMMTfaw = Tfaw;
- val = Tfaw / tCK16x;
- if (Tfaw % tCK16x) { /* round up number of busclocks */
- val++;
- }
- if (val < Min_TfawT)
- val = Min_TfawT;
- else if (val > Max_TfawT)
- val = Max_TfawT;
- pDCTstat->Tfaw = val;
-
- mctAdjustAutoCycTmg_D();
-
- if (is_fam15h()) {
- /* Compute Tcwl (Fam15h BKDG v3.14 Table 203) */
- if (pDCTstat->Speed <= 0x6)
- Tcwl = 0x5;
- else if (pDCTstat->Speed == 0xa)
- Tcwl = 0x6;
- else if (pDCTstat->Speed == 0xe)
- Tcwl = 0x7;
- else if (pDCTstat->Speed == 0x12)
- Tcwl = 0x8;
- else if (pDCTstat->Speed == 0x16)
- Tcwl = 0x9;
- else
- Tcwl = 0x5; /* Power-on default */
-
- /* Apply offset */
- Tcwl += pDCTstat->tcwl_delay[dct];
- }
-
- /* Program DRAM Timing values */
- if (is_fam15h()) {
- dev = pDCTstat->dev_dct;
-
- dword = Get_NB32_DCT(dev, dct, 0x8c); /* DRAM Timing High */
- if (Etr[dct])
- val = 3; /* Tref = 3.9us */
- else
- val = 2; /* Tref = 7.8us */
- dword &= ~(0x3 << 16);
- dword |= (val & 0x3) << 16;
- Set_NB32_DCT(dev, dct, 0x8c, dword); /* DRAM Timing High */
-
- dword = Get_NB32_DCT(dev, dct, 0x200); /* DRAM Timing 0 */
- dword &= ~(0x3f1f1f1f);
- dword |= (pDCTstat->Tras & 0x3f) << 24; /* Tras */
- val = pDCTstat->Trp;
- val = mct_AdjustSPDTimings(pMCTstat, pDCTstat, val);
- dword |= (val & 0x1f) << 16; /* Trp */
- dword |= (pDCTstat->Trcd & 0x1f) << 8; /* Trcd */
- dword |= (pDCTstat->CASL & 0x1f); /* Tcl */
- Set_NB32_DCT(dev, dct, 0x200, dword); /* DRAM Timing 0 */
-
- dword = Get_NB32_DCT(dev, dct, 0x204); /* DRAM Timing 1 */
- dword &= ~(0x0f3f0f3f);
- dword |= (pDCTstat->Trtp & 0xf) << 24; /* Trtp */
- if (pDCTstat->Tfaw != 0) {
- val = pDCTstat->Tfaw;
- val = mct_AdjustSPDTimings(pMCTstat, pDCTstat, val);
- if ((val > 0x5) && (val < 0x2b))
- dword |= (val & 0x3f) << 16; /* FourActWindow */
- }
- dword |= (pDCTstat->Trrd & 0xf) << 8; /* Trrd */
- dword |= (pDCTstat->Trc & 0x3f); /* Trc */
- Set_NB32_DCT(dev, dct, 0x204, dword); /* DRAM Timing 1 */
-
- /* Trfc0-Trfc3 */
- for (i = 0; i < 4; i++)
- if (pDCTstat->Trfc[i] == 0x0)
- pDCTstat->Trfc[i] = 0x1;
- dword = Get_NB32_DCT(dev, dct, 0x208); /* DRAM Timing 2 */
- dword &= ~(0x07070707);
- dword |= (pDCTstat->Trfc[3] & 0x7) << 24; /* Trfc3 */
- dword |= (pDCTstat->Trfc[2] & 0x7) << 16; /* Trfc2 */
- dword |= (pDCTstat->Trfc[1] & 0x7) << 8; /* Trfc1 */
- dword |= (pDCTstat->Trfc[0] & 0x7); /* Trfc0 */
- Set_NB32_DCT(dev, dct, 0x208, dword); /* DRAM Timing 2 */
-
- dword = Get_NB32_DCT(dev, dct, 0x20c); /* DRAM Timing 3 */
- dword &= ~(0x00000f00);
- dword |= (pDCTstat->Twtr & 0xf) << 8; /* Twtr */
- dword &= ~(0x0000001f);
- dword |= (Tcwl & 0x1f); /* Tcwl */
- Set_NB32_DCT(dev, dct, 0x20c, dword); /* DRAM Timing 3 */
-
- dword = Get_NB32_DCT(dev, dct, 0x22c); /* DRAM Timing 10 */
- dword &= ~(0x0000001f);
- dword |= (pDCTstat->Twr & 0x1f); /* Twr */
- Set_NB32_DCT(dev, dct, 0x22c, dword); /* DRAM Timing 10 */
-
- if (pDCTstat->Speed > mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK))) {
- /* Enable phy-assisted training mode */
- fam15EnableTrainingMode(pMCTstat, pDCTstat, dct, 1);
- }
-
- /* Other setup (not training specific) */
- dword = Get_NB32_DCT(dev, dct, 0x90); /* DRAM Configuration Low */
- dword &= ~(0x1 << 23); /* ForceAutoPchg = 0 */
- dword &= ~(0x1 << 20); /* DynPageCloseEn = 0 */
- Set_NB32_DCT(dev, dct, 0x90, dword); /* DRAM Configuration Low */
-
- Set_NB32_DCT(dev, dct, 0x228, 0x14141414); /* DRAM Timing 9 */
- } else {
- DramTimingLo = 0; /* Dram Timing Low init */
- val = pDCTstat->CASL - 4; /* pDCTstat.CASL to reg. definition */
- DramTimingLo |= val;
-
- val = pDCTstat->Trcd - Bias_TrcdT;
- DramTimingLo |= val<<4;
-
- val = pDCTstat->Trp - Bias_TrpT;
- val = mct_AdjustSPDTimings(pMCTstat, pDCTstat, val);
- DramTimingLo |= val<<7;
-
- val = pDCTstat->Trtp - Bias_TrtpT;
- DramTimingLo |= val<<10;
-
- val = pDCTstat->Tras - Bias_TrasT;
- DramTimingLo |= val<<12;
-
- val = pDCTstat->Trc - Bias_TrcT;
- DramTimingLo |= val<<16;
-
- val = pDCTstat->Trrd - Bias_TrrdT;
- DramTimingLo |= val<<22;
-
- DramTimingHi = 0; /* Dram Timing High init */
- val = pDCTstat->Twtr - Bias_TwtrT;
- DramTimingHi |= val<<8;
-
- val = 2; /* Tref = 7.8us */
- DramTimingHi |= val<<16;
-
- val = 0;
- for (i = 4; i > 0; i--) {
- val <<= 3;
- val |= Trfc[i-1];
- }
- DramTimingHi |= val << 20;
-
- dev = pDCTstat->dev_dct;
- /* Twr */
- val = pDCTstat->Twr;
- if (val == 10)
- val = 9;
- else if (val == 12)
- val = 10;
- val = mct_AdjustSPDTimings(pMCTstat, pDCTstat, val);
- val -= Bias_TwrT;
- val <<= 4;
- dword = Get_NB32_DCT(dev, dct, 0x84);
- dword &= ~0x70;
- dword |= val;
- Set_NB32_DCT(dev, dct, 0x84, dword);
-
- /* Tfaw */
- val = pDCTstat->Tfaw;
- val = mct_AdjustSPDTimings(pMCTstat, pDCTstat, val);
- val -= Bias_TfawT;
- val >>= 1;
- val <<= 28;
- dword = Get_NB32_DCT(dev, dct, 0x94);
- dword &= ~0xf0000000;
- dword |= val;
- Set_NB32_DCT(dev, dct, 0x94, dword);
-
- /* dev = pDCTstat->dev_dct; */
-
- if (pDCTstat->Speed > mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK))) {
- val = Get_NB32_DCT(dev, dct, 0x88);
- val &= 0xFF000000;
- DramTimingLo |= val;
- }
- Set_NB32_DCT(dev, dct, 0x88, DramTimingLo); /*DCT Timing Low*/
-
- if (pDCTstat->Speed > mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK))) {
- DramTimingHi |= 1 << DisAutoRefresh;
- }
- DramTimingHi |= 0x000018FF;
- Set_NB32_DCT(dev, dct, 0x8c, DramTimingHi); /*DCT Timing Hi*/
- }
-
- /* dump_pci_device(PCI_DEV(0, 0x18+pDCTstat->Node_ID, 2)); */
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-static u8 AutoCycTiming_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- /* Initialize DCT Timing registers as per DIMM SPD.
- * For primary timing (T, CL) use best case T value.
- * For secondary timing params., use most aggressive settings
- * of slowest DIMM.
- *
- * There are three components to determining "maximum frequency":
- * SPD component, Bus load component, and "Preset" max frequency
- * component.
- *
- * The SPD component is a function of the min cycle time specified
- * by each DIMM, and the interaction of cycle times from all DIMMs
- * in conjunction with CAS latency. The SPD component only applies
- * when user timing mode is 'Auto'.
- *
- * The Bus load component is a limiting factor determined by electrical
- * characteristics on the bus as a result of varying number of device
- * loads. The Bus load component is specific to each platform but may
- * also be a function of other factors. The bus load component only
- * applies when user timing mode is 'Auto'.
- *
- * The Preset component is subdivided into three items and is
- * the minimum of the set: Silicon revision, user limit
- * setting when user timing mode is 'Auto' and memclock mode
- * is 'Limit', OEM build specification of the maximum
- * frequency. The Preset component is only applies when user
- * timing mode is 'Auto'.
- */
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- /* Get primary timing (CAS Latency and Cycle Time) */
- if (pDCTstat->Speed == 0) {
- mctGet_MaxLoadFreq(pDCTstat);
-
- /* and Factor in presets (setup options, Si cap, etc.) */
- GetPresetmaxF_D(pMCTstat, pDCTstat);
-
- /* Go get best T and CL as specified by DIMM mfgs. and OEM */
- SPDGetTCL_D(pMCTstat, pDCTstat, dct);
-
- /* skip callback mctForce800to1067_D */
- pDCTstat->Speed = pDCTstat->DIMMAutoSpeed;
- pDCTstat->CASL = pDCTstat->DIMMCASL;
-
- }
- mct_AfterGetCLT(pMCTstat, pDCTstat, dct);
-
- SPD2ndTiming(pMCTstat, pDCTstat, dct);
-
- printk(BIOS_DEBUG, "AutoCycTiming: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "AutoCycTiming: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "AutoCycTiming: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "AutoCycTiming: Done\n\n");
-
- mctHookAfterAutoCycTmg();
-
- return pDCTstat->ErrCode;
-}
-
-static void GetPresetmaxF_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Get max frequency from OEM platform definition, from any user
- * override (limiting) of max frequency, and from any Si Revision
- * Specific information. Return the least of these three in
- * DCTStatStruc.PresetmaxFreq.
- */
- /* TODO: Set the proper max frequency in wrappers/mcti_d.c. */
- u16 proposedFreq;
- u16 word;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- /* Get CPU Si Revision defined limit (NPT) */
- if (is_fam15h())
- proposedFreq = 933;
- else
- proposedFreq = 800; /* Rev F0 programmable max memclock is */
-
- /*Get User defined limit if "limit" mode */
- if (mctGet_NVbits(NV_MCTUSRTMGMODE) == 1) {
- word = Get_Fk_D(mctGet_NVbits(NV_MemCkVal) + 1);
- if (word < proposedFreq)
- proposedFreq = word;
-
- /* Get Platform defined limit */
- word = mctGet_NVbits(NV_MAX_MEMCLK);
- if (word < proposedFreq)
- proposedFreq = word;
-
- word = pDCTstat->PresetmaxFreq;
- if (word > proposedFreq)
- word = proposedFreq;
-
- pDCTstat->PresetmaxFreq = word;
- }
- /* Check F3xE8[DdrMaxRate] for maximum DRAM data rate support */
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-static void SPDGetTCL_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- /* Find the best T and CL primary timing parameter pair, per Mfg.,
- * for the given set of DIMMs, and store into DCTStatStruc
- * (.DIMMAutoSpeed and .DIMMCASL). See "Global relationship between
- * index values and item values" for definition of CAS latency
- * index (j) and Frequency index (k).
- */
- u8 i, CASLatLow, CASLatHigh;
- u16 tAAmin16x;
- u8 MTB16x;
- u16 tCKmin16x;
- u16 tCKproposed16x;
- u8 CLactual, CLdesired, CLT_Fail;
- uint16_t min_frequency_tck16x;
-
- u8 byte = 0, bytex = 0;
-
- CASLatLow = 0xFF;
- CASLatHigh = 0xFF;
- tAAmin16x = 0;
- tCKmin16x = 0;
- CLT_Fail = 0;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- if (is_fam15h()) {
- uint16_t minimum_frequency_mhz = mctGet_NVbits(NV_MIN_MEMCLK);
- if (minimum_frequency_mhz == 0)
- minimum_frequency_mhz = 333;
- min_frequency_tck16x = 16000 / minimum_frequency_mhz;
- } else {
- min_frequency_tck16x = 40;
- }
-
- for (i = 0; i < MAX_DIMMS_SUPPORTED; i++) {
- if (pDCTstat->DIMMValid & (1 << i)) {
- /* Step 1: Determine the common set of supported CAS Latency
- * values for all modules on the memory channel using the CAS
- * Latencies Supported in SPD bytes 14 and 15.
- */
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_CASLow];
- CASLatLow &= byte;
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_CASHigh];
- CASLatHigh &= byte;
- /* Step 2: Determine tAAmin(all) which is the largest tAAmin
- value for all modules on the memory channel (SPD byte 16). */
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_MTBDivisor];
-
- MTB16x = ((pDCTstat->spd_data.spd_bytes[dct + i][SPD_MTBDividend] & 0xFF)<<4);
- MTB16x /= byte; /* transfer to MTB*16 */
-
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_tAAmin];
- if (tAAmin16x < byte * MTB16x)
- tAAmin16x = byte * MTB16x;
- /* Step 3: Determine tCKmin(all) which is the largest tCKmin
- value for all modules on the memory channel (SPD byte 12). */
- byte = pDCTstat->spd_data.spd_bytes[dct + i][SPD_tCKmin];
-
- if (tCKmin16x < byte * MTB16x)
- tCKmin16x = byte * MTB16x;
- }
- }
- /* calculate tCKproposed16x (proposed clock period in ns * 16) */
- tCKproposed16x = 16000 / pDCTstat->PresetmaxFreq;
- if (tCKmin16x > tCKproposed16x)
- tCKproposed16x = tCKmin16x;
-
- /* TODO: get user manual tCK16x(Freq.) and overwrite current tCKproposed16x if manual. */
- if (is_fam15h()) {
- if (tCKproposed16x == 17)
- pDCTstat->TargetFreq = 0x16;
- else if (tCKproposed16x <= 20) {
- pDCTstat->TargetFreq = 0x12;
- tCKproposed16x = 20;
- } else if (tCKproposed16x <= 24) {
- pDCTstat->TargetFreq = 0xe;
- tCKproposed16x = 24;
- } else if (tCKproposed16x <= 30) {
- pDCTstat->TargetFreq = 0xa;
- tCKproposed16x = 30;
- } else if (tCKproposed16x <= 40) {
- pDCTstat->TargetFreq = 0x6;
- tCKproposed16x = 40;
- } else {
- pDCTstat->TargetFreq = 0x4;
- tCKproposed16x = 48;
- }
- } else {
- if (tCKproposed16x == 20)
- pDCTstat->TargetFreq = 7;
- else if (tCKproposed16x <= 24) {
- pDCTstat->TargetFreq = 6;
- tCKproposed16x = 24;
- } else if (tCKproposed16x <= 30) {
- pDCTstat->TargetFreq = 5;
- tCKproposed16x = 30;
- } else {
- pDCTstat->TargetFreq = 4;
- tCKproposed16x = 40;
- }
- }
- /* Running through this loop twice:
- - First time find tCL at target frequency
- - Second time find tCL at 400MHz */
-
- for (;;) {
- CLT_Fail = 0;
- /* Step 4: For a proposed tCK value (tCKproposed) between tCKmin(all) and tCKmax,
- determine the desired CAS Latency. If tCKproposed is not a standard JEDEC
- value (2.5, 1.875, 1.5, or 1.25 ns) then tCKproposed must be adjusted to the
- next lower standard tCK value for calculating CLdesired.
- CLdesired = ceiling (tAAmin(all) / tCKproposed)
- where tAAmin is defined in Byte 16. The ceiling function requires that the
- quotient be rounded up always. */
- CLdesired = tAAmin16x / tCKproposed16x;
- if (tAAmin16x % tCKproposed16x)
- CLdesired ++;
- /* Step 5: Chose an actual CAS Latency (CLactual) that is greather than or equal
- to CLdesired and is supported by all modules on the memory channel as
- determined in step 1. If no such value exists, choose a higher tCKproposed
- value and repeat steps 4 and 5 until a solution is found. */
- for (i = 0, CLactual = 4; i < 15; i++, CLactual++) {
- if ((CASLatHigh << 8 | CASLatLow) & (1 << i)) {
- if (CLdesired <= CLactual)
- break;
- }
- }
- if (i == 15)
- CLT_Fail = 1;
- /* Step 6: Once the calculation of CLactual is completed, the BIOS must also
- verify that this CAS Latency value does not exceed tAAmax, which is 20 ns
- for all DDR3 speed grades, by multiplying CLactual times tCKproposed. If
- not, choose a lower CL value and repeat steps 5 and 6 until a solution is found. */
- if (CLactual * tCKproposed16x > 320)
- CLT_Fail = 1;
- /* get CL and T */
- if (!CLT_Fail) {
- bytex = CLactual;
- if (is_fam15h()) {
- if (tCKproposed16x == 17)
- byte = 0x16;
- else if (tCKproposed16x == 20)
- byte = 0x12;
- else if (tCKproposed16x == 24)
- byte = 0xe;
- else if (tCKproposed16x == 30)
- byte = 0xa;
- else if (tCKproposed16x == 40)
- byte = 0x6;
- else
- byte = 0x4;
- } else {
- if (tCKproposed16x == 20)
- byte = 7;
- else if (tCKproposed16x == 24)
- byte = 6;
- else if (tCKproposed16x == 30)
- byte = 5;
- else
- byte = 4;
- }
- } else {
- /* mctHookManualCLOverride */
- /* TODO: */
- }
-
- if (tCKproposed16x != min_frequency_tck16x) {
- if (pMCTstat->GStatus & (1 << GSB_EnDIMMSpareNW)) {
- pDCTstat->DIMMAutoSpeed = byte;
- pDCTstat->DIMMCASL = bytex;
- break;
- } else {
- pDCTstat->TargetCASL = bytex;
- tCKproposed16x = min_frequency_tck16x;
- }
- } else {
- pDCTstat->DIMMAutoSpeed = byte;
- pDCTstat->DIMMCASL = bytex;
- break;
- }
- }
-
- printk(BIOS_DEBUG, "SPDGetTCL_D: DIMMCASL %x\n", pDCTstat->DIMMCASL);
- printk(BIOS_DEBUG, "SPDGetTCL_D: DIMMAutoSpeed %x\n", pDCTstat->DIMMAutoSpeed);
-
- printk(BIOS_DEBUG, "SPDGetTCL_D: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "SPDGetTCL_D: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "SPDGetTCL_D: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "SPDGetTCL_D: Done\n\n");
-}
-
-u8 PlatformSpec_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- if (!is_fam15h()) {
- mctGet_PS_Cfg_D(pMCTstat, pDCTstat, dct);
-
- if (pDCTstat->GangedMode == 1) {
- mctGet_PS_Cfg_D(pMCTstat, pDCTstat, 1);
- mct_BeforePlatformSpec(pMCTstat, pDCTstat, 1);
- }
-
- set_2t_configuration(pMCTstat, pDCTstat, dct);
-
- mct_BeforePlatformSpec(pMCTstat, pDCTstat, dct);
- mct_PlatformSpec(pMCTstat, pDCTstat, dct);
- if (pDCTstat->DIMMAutoSpeed == mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK)))
- InitPhyCompensation(pMCTstat, pDCTstat, dct);
- }
- mctHookAfterPSCfg();
-
- return pDCTstat->ErrCode;
-}
-
-static u8 AutoConfig_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 DramControl, DramTimingLo, Status;
- u32 DramConfigLo, DramConfigHi, DramConfigMisc, DramConfigMisc2;
- u32 val;
- u32 dev;
- u16 word;
- u32 dword;
- u8 byte;
- uint32_t offset;
-
- DramConfigLo = 0;
- DramConfigHi = 0;
- DramConfigMisc = 0;
- DramConfigMisc2 = 0;
-
- /* set bank addressing and Masks, plus CS pops */
- SPDSetBanks_D(pMCTstat, pDCTstat, dct);
- if (pDCTstat->ErrCode == SC_StopError)
- goto AutoConfig_exit;
-
- /* map chip-selects into local address space */
- StitchMemory_D(pMCTstat, pDCTstat, dct);
- InterleaveBanks_D(pMCTstat, pDCTstat, dct);
-
- /* temp image of status (for convenience). RO usage! */
- Status = pDCTstat->Status;
-
- dev = pDCTstat->dev_dct;
-
- /* Build Dram Control Register Value */
- DramConfigMisc2 = Get_NB32_DCT(dev, dct, 0xa8); /* Dram Miscellaneous 2 */
- DramControl = Get_NB32_DCT(dev, dct, 0x78); /* Dram Control */
-
- /* FIXME: Skip mct_checkForDxSupport */
- /* REV_CALL mct_DoRdPtrInit if not Dx */
- if (pDCTstat->LogicalCPUID & AMD_DR_Bx)
- val = 5;
- else
- val = 6;
- DramControl &= ~0xFF;
- DramControl |= val; /* RdPtrInit = 6 for Cx CPU */
-
- if (mctGet_NVbits(NV_CLKHZAltVidC3))
- DramControl |= 1<<16; /* check */
-
- DramControl |= 0x00002A00;
-
- /* FIXME: Skip for Ax versions */
- /* callback not required - if (!mctParityControl_D()) */
- if (Status & (1 << SB_128bitmode))
- DramConfigLo |= 1 << Width128; /* 128-bit mode (normal) */
-
- word = dct;
- dword = X4Dimm;
- while (word < 8) {
- if (pDCTstat->Dimmx4Present & (1 << word))
- DramConfigLo |= 1 << dword; /* X4Dimm[3:0] */
- word++;
- word++;
- dword++;
- }
-
- if (Status & (1 << SB_Registered)) {
- /* Registered DIMMs */
- if (!is_fam15h()) {
- DramConfigLo |= 1 << ParEn;
- }
- } else {
- /* Unbuffered DIMMs */
- DramConfigLo |= 1 << UnBuffDimm;
- }
-
- if (mctGet_NVbits(NV_ECC_CAP))
- if (Status & (1 << SB_ECCDIMMs))
- if (mctGet_NVbits(NV_ECC))
- DramConfigLo |= 1 << DimmEcEn;
-
- DramConfigLo = mct_DisDllShutdownSR(pMCTstat, pDCTstat, DramConfigLo, dct);
-
- /* Build Dram Config Hi Register Value */
- if (is_fam15h())
- offset = 0x0;
- else
- offset = 0x1;
- dword = pDCTstat->Speed;
- DramConfigHi |= dword - offset; /* get MemClk encoding */
- DramConfigHi |= 1 << MemClkFreqVal;
-
- if (!is_fam15h())
- if (Status & (1 << SB_Registered))
- if ((pDCTstat->Dimmx4Present != 0) && (pDCTstat->Dimmx8Present != 0))
- /* set only if x8 Registered DIMMs in System*/
- DramConfigHi |= 1 << RDqsEn;
-
- if (pDCTstat->LogicalCPUID & AMD_FAM15_ALL) {
- DramConfigLo |= 1 << 25; /* PendRefPaybackS3En = 1 */
- DramConfigLo |= 1 << 24; /* StagRefEn = 1 */
- DramConfigHi |= 1 << 16; /* PowerDownMode = 1 */
- } else {
- if (mctGet_NVbits(NV_CKE_CTL))
- /*Chip Select control of CKE*/
- DramConfigHi |= 1 << 16;
- }
-
- if (!is_fam15h()) {
- /* Control Bank Swizzle */
- if (0) /* call back not needed mctBankSwizzleControl_D()) */
- DramConfigHi &= ~(1 << BankSwizzleMode);
- else
- DramConfigHi |= 1 << BankSwizzleMode; /* recommended setting (default) */
- }
-
- /* Check for Quadrank DIMM presence */
- if (pDCTstat->DimmQRPresent != 0) {
- byte = mctGet_NVbits(NV_4RANKType);
- if (byte == 2)
- DramConfigHi |= 1 << 17; /* S4 (4-Rank SO-DIMMs) */
- else if (byte == 1)
- DramConfigHi |= 1 << 18; /* R4 (4-Rank Registered DIMMs) */
- }
-
- if (0) /* call back not needed mctOverrideDcqBypMax_D) */
- val = mctGet_NVbits(NV_BYPMAX);
- else
- val = 0x0f; /* recommended setting (default) */
- DramConfigHi |= val << 24;
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_Dx | AMD_DR_Cx | AMD_DR_Bx | AMD_FAM15_ALL))
- DramConfigHi |= 1 << DcqArbBypassEn;
-
- /* Build MemClkDis Value from Dram Timing Lo and
- Dram Config Misc Registers
- 1. We will assume that MemClkDis field has been preset prior to this
- point.
- 2. We will only set MemClkDis bits if a DIMM is NOT present AND if:
- NV_AllMemClks <>0 AND SB_DiagClks == 0 */
-
- /* Dram Timing Low (owns Clock Enable bits) */
- DramTimingLo = Get_NB32_DCT(dev, dct, 0x88);
- if (mctGet_NVbits(NV_AllMemClks) == 0) {
- /* Special Jedec SPD diagnostic bit - "enable all clocks" */
- if (!(pDCTstat->Status & (1<<SB_DiagClks))) {
- const u8 *p;
- p = Tab_ManualCLKDis;
-
- byte = mctGet_NVbits(NV_PACK_TYPE);
- if (byte == PT_L1)
- p = Tab_L1CLKDis;
- else if (byte == PT_M2 || byte == PT_AS)
- p = Tab_AM3CLKDis;
- else if (byte == PT_C3)
- p = Tab_C32CLKDis;
- else if (byte == PT_GR)
- p = Tab_G34CLKDis;
- else if (byte == PT_FM2)
- p = Tab_FM2CLKDis;
- else
- p = Tab_S1CLKDis;
-
- dword = 0;
- byte = 0xFF;
- while (dword < MAX_CS_SUPPORTED) {
- if (pDCTstat->CSPresent & (1<<dword)) {
- /* re-enable clocks for the enabled CS */
- val = p[dword];
- byte &= ~val;
- }
- dword++;
- }
- DramTimingLo &= ~(0xff << 24);
- DramTimingLo |= byte << 24;
- }
- }
-
- DramConfigMisc2 = mct_SetDramConfigMisc2(pDCTstat, dct, DramConfigMisc2, DramControl);
-
- printk(BIOS_DEBUG, "AutoConfig_D: DramControl: %08x\n", DramControl);
- printk(BIOS_DEBUG, "AutoConfig_D: DramTimingLo: %08x\n", DramTimingLo);
- printk(BIOS_DEBUG, "AutoConfig_D: DramConfigMisc: %08x\n", DramConfigMisc);
- printk(BIOS_DEBUG, "AutoConfig_D: DramConfigMisc2: %08x\n", DramConfigMisc2);
- printk(BIOS_DEBUG, "AutoConfig_D: DramConfigLo: %08x\n", DramConfigLo);
- printk(BIOS_DEBUG, "AutoConfig_D: DramConfigHi: %08x\n", DramConfigHi);
-
- /* Write Values to the registers */
- Set_NB32_DCT(dev, dct, 0x78, DramControl);
- Set_NB32_DCT(dev, dct, 0x88, DramTimingLo);
- Set_NB32_DCT(dev, dct, 0xa0, DramConfigMisc);
- Set_NB32_DCT(dev, dct, 0xa8, DramConfigMisc2);
- Set_NB32_DCT(dev, dct, 0x90, DramConfigLo);
- ProgDramMRSReg_D(pMCTstat, pDCTstat, dct);
-
- if (is_fam15h())
- InitDDRPhy(pMCTstat, pDCTstat, dct);
-
- /* Write the DRAM Configuration High register, including memory frequency change */
- dword = Get_NB32_DCT(dev, dct, 0x94);
- DramConfigHi |= dword;
- mct_SetDramConfigHi_D(pMCTstat, pDCTstat, dct, DramConfigHi);
- mct_EarlyArbEn_D(pMCTstat, pDCTstat, dct);
- mctHookAfterAutoCfg();
-
- /* dump_pci_device(PCI_DEV(0, 0x18+pDCTstat->Node_ID, 2)); */
-
- printk(BIOS_DEBUG, "AutoConfig: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "AutoConfig: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "AutoConfig: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "AutoConfig: Done\n\n");
-
-AutoConfig_exit:
- return pDCTstat->ErrCode;
-}
-
-static void SPDSetBanks_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Set bank addressing, program Mask values and build a chip-select
- * population map. This routine programs PCI 0:24N:2x80 config register
- * and PCI 0:24N:2x60,64,68,6C config registers (CS Mask 0-3).
- */
- u8 ChipSel, Rows, Cols, Ranks, Banks;
- u32 BankAddrReg, csMask;
-
- u32 val;
- u32 reg;
- u32 dev;
- u8 byte;
- u16 word;
- u32 dword;
-
- dev = pDCTstat->dev_dct;
-
- BankAddrReg = 0;
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel+=2) {
- byte = ChipSel;
- if ((pDCTstat->Status & (1 << SB_64MuxedMode)) && ChipSel >=4)
- byte -= 3;
-
- if (pDCTstat->DIMMValid & (1<<byte)) {
- byte = pDCTstat->spd_data.spd_bytes[ChipSel + dct][SPD_Addressing];
- Rows = (byte >> 3) & 0x7; /* Rows:0b = 12-bit,... */
- Cols = byte & 0x7; /* Cols:0b = 9-bit,... */
-
- byte = pDCTstat->spd_data.spd_bytes[ChipSel + dct][SPD_Density];
- Banks = (byte >> 4) & 7; /* Banks:0b = 3-bit,... */
-
- byte = pDCTstat->spd_data.spd_bytes[ChipSel + dct][SPD_Organization];
- Ranks = ((byte >> 3) & 7) + 1;
-
- /* Configure Bank encoding
- * Use a 6-bit key into a lookup table.
- * Key (index) = RRRBCC, where CC is the number of Columns minus 9,
- * RRR is the number of Rows minus 12, and B is the number of banks
- * minus 3.
- */
- byte = Cols;
- if (Banks == 1)
- byte |= 4;
-
- byte |= Rows << 3; /* RRRBCC internal encode */
-
- for (dword = 0; dword < 13; dword++) {
- if (byte == Tab_BankAddr[dword])
- break;
- }
-
- if (dword > 12)
- continue;
-
- /* bit no. of CS field in address mapping reg.*/
- dword <<= (ChipSel<<1);
- BankAddrReg |= dword;
-
- /* Mask value=(2pow(rows+cols+banks+3)-1)>>8,
- or 2pow(rows+cols+banks-5)-1*/
- csMask = 0;
-
- byte = Rows + Cols; /* cl = rows+cols*/
- byte += 21; /* row:12+col:9 */
- byte -= 2; /* 3 banks - 5 */
-
- if (pDCTstat->Status & (1 << SB_128bitmode))
- byte++; /* double mask size if in 128-bit mode*/
-
- csMask |= 1 << byte;
- csMask--;
-
- /*set ChipSelect population indicator even bits*/
- pDCTstat->CSPresent |= (1<<ChipSel);
- if (Ranks >= 2)
- /*set ChipSelect population indicator odd bits*/
- pDCTstat->CSPresent |= 1 << (ChipSel + 1);
-
- reg = 0x60+(ChipSel<<1); /*Dram CS Mask Register */
- val = csMask;
- val &= 0x1FF83FE0; /* Mask out reserved bits.*/
- Set_NB32_DCT(dev, dct, reg, val);
- } else {
- if (pDCTstat->DIMMSPDCSE & (1<<ChipSel))
- pDCTstat->CSTestFail |= (1<<ChipSel);
- } /* if DIMMValid*/
- } /* while ChipSel*/
-
- SetCSTriState(pMCTstat, pDCTstat, dct);
- SetCKETriState(pMCTstat, pDCTstat, dct);
- SetODTTriState(pMCTstat, pDCTstat, dct);
-
- if (pDCTstat->Status & (1 << SB_128bitmode)) {
- SetCSTriState(pMCTstat, pDCTstat, 1); /* force dct1) */
- SetCKETriState(pMCTstat, pDCTstat, 1); /* force dct1) */
- SetODTTriState(pMCTstat, pDCTstat, 1); /* force dct1) */
- }
-
- word = pDCTstat->CSPresent;
- mctGetCS_ExcludeMap(); /* mask out specified chip-selects */
- word ^= pDCTstat->CSPresent;
- pDCTstat->CSTestFail |= word; /* enable ODT to disabled DIMMs */
- if (!pDCTstat->CSPresent)
- pDCTstat->ErrCode = SC_StopError;
-
- reg = 0x80; /* Bank Addressing Register */
- Set_NB32_DCT(dev, dct, reg, BankAddrReg);
-
- pDCTstat->CSPresent_DCT[dct] = pDCTstat->CSPresent;
- /* dump_pci_device(PCI_DEV(0, 0x18+pDCTstat->Node_ID, 2)); */
-
- printk(BIOS_DEBUG, "SPDSetBanks: CSPresent %x\n", pDCTstat->CSPresent_DCT[dct]);
- printk(BIOS_DEBUG, "SPDSetBanks: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "SPDSetBanks: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "SPDSetBanks: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "SPDSetBanks: Done\n\n");
-}
-
-static void SPDCalcWidth_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Per SPDs, check the symmetry of DIMM pairs (DIMM on Channel A
- * matching with DIMM on Channel B), the overall DIMM population,
- * and determine the width mode: 64-bit, 64-bit muxed, 128-bit.
- */
- u8 i;
- u8 byte, byte1;
-
- /* Check Symmetry of Channel A and Channel B DIMMs
- (must be matched for 128-bit mode).*/
- for (i = 0; i < MAX_DIMMS_SUPPORTED; i += 2) {
- if ((pDCTstat->DIMMValid & (1 << i)) && (pDCTstat->DIMMValid & (1<<(i+1)))) {
- byte = pDCTstat->spd_data.spd_bytes[i][SPD_Addressing] & 0x7;
- byte1 = pDCTstat->spd_data.spd_bytes[i + 1][SPD_Addressing] & 0x7;
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1<<SB_DimmMismatchO);
- break;
- }
-
- byte = pDCTstat->spd_data.spd_bytes[i][SPD_Density] & 0x0f;
- byte1 = pDCTstat->spd_data.spd_bytes[i + 1][SPD_Density] & 0x0f;
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1<<SB_DimmMismatchO);
- break;
- }
-
- byte = pDCTstat->spd_data.spd_bytes[i][SPD_Organization] & 0x7;
- byte1 = pDCTstat->spd_data.spd_bytes[i + 1][SPD_Organization] & 0x7;
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1<<SB_DimmMismatchO);
- break;
- }
-
- byte = (pDCTstat->spd_data.spd_bytes[i][SPD_Organization] >> 3) & 0x7;
- byte1 = (pDCTstat->spd_data.spd_bytes[i + 1][SPD_Organization] >> 3) & 0x7;
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1<<SB_DimmMismatchO);
- break;
- }
-
- byte = pDCTstat->spd_data.spd_bytes[i][SPD_DMBANKS] & 7; /* #ranks-1 */
- byte1 = pDCTstat->spd_data.spd_bytes[i + 1][SPD_DMBANKS] & 7; /* #ranks-1 */
- if (byte != byte1) {
- pDCTstat->ErrStatus |= (1<<SB_DimmMismatchO);
- break;
- }
-
- }
- }
-
-}
-
-static void StitchMemory_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Requires that Mask values for each bank be programmed first and that
- * the chip-select population indicator is correctly set.
- */
- u8 b = 0;
- u32 nxtcsBase, curcsBase;
- u8 p, q;
- u32 BiggestBank;
- u8 _DSpareEn;
-
- u16 word;
- u32 dev;
- u32 reg;
- u32 val;
-
- dev = pDCTstat->dev_dct;
-
- _DSpareEn = 0;
-
- /* CS Sparing 1 = enabled, 0 = disabled */
- if (mctGet_NVbits(NV_CS_SpareCTL) & 1) {
- if (MCT_DIMM_SPARE_NO_WARM) {
- /* Do no warm-reset DIMM spare */
- if (pMCTstat->GStatus & 1 << GSB_EnDIMMSpareNW) {
- word = pDCTstat->CSPresent;
- val = bsf(word);
- word &= ~(1<<val);
- if (word)
- /* Make sure at least two chip-selects are available */
- _DSpareEn = 1;
- else
- pDCTstat->ErrStatus |= 1 << SB_SpareDis;
- }
- } else {
- if (!mctGet_NVbits(NV_DQSTrainCTL)) { /*DQS Training 1 = enabled, 0 = disabled */
- word = pDCTstat->CSPresent;
- val = bsf(word);
- word &= ~(1 << val);
- if (word)
- /* Make sure at least two chip-selects are available */
- _DSpareEn = 1;
- else
- pDCTstat->ErrStatus |= 1 << SB_SpareDis;
- }
- }
- }
-
- nxtcsBase = 0; /* Next available cs base ADDR[39:8] */
- for (p = 0; p < MAX_DIMMS_SUPPORTED; p++) {
- BiggestBank = 0;
- for (q = 0; q < MAX_CS_SUPPORTED; q++) { /* from DIMMS to CS */
- if (pDCTstat->CSPresent & (1 << q)) { /* bank present? */
- reg = 0x40 + (q << 2); /* Base[q] reg.*/
- val = Get_NB32_DCT(dev, dct, reg);
- if (!(val & 3)) { /* (CSEnable|Spare == 1)bank is enabled already? */
- reg = 0x60 + (q << 1); /*Mask[q] reg.*/
- val = Get_NB32_DCT(dev, dct, reg);
- val >>= 19;
- val++;
- val <<= 19;
- if (val > BiggestBank) {
- /*Bingo! possibly Map this chip-select next! */
- BiggestBank = val;
- b = q;
- }
- }
- } /*if bank present */
- } /* while q */
- if (BiggestBank !=0) {
- curcsBase = nxtcsBase; /* curcsBase = nxtcsBase*/
- /* DRAM CS Base b Address Register offset */
- reg = 0x40 + (b << 2);
- if (_DSpareEn) {
- BiggestBank = 0;
- val = 1 << Spare; /* Spare Enable*/
- } else {
- val = curcsBase;
- val |= 1 << CSEnable; /* Bank Enable */
- }
- if (((reg - 0x40) >> 2) & 1) {
- if (!(pDCTstat->Status & (1 << SB_Registered))) {
- u16 dimValid;
- dimValid = pDCTstat->DIMMValid;
- if (dct & 1)
- dimValid <<= 1;
- if ((dimValid & pDCTstat->MirrPresU_NumRegR) != 0) {
- val |= 1 << onDimmMirror;
- }
- }
- }
- Set_NB32_DCT(dev, dct, reg, val);
- if (_DSpareEn)
- _DSpareEn = 0;
- else
- /* let nxtcsBase+=Size[b] */
- nxtcsBase += BiggestBank;
- }
-
- /* bank present but disabled?*/
- if (pDCTstat->CSTestFail & (1 << p)) {
- /* DRAM CS Base b Address Register offset */
- reg = (p << 2) + 0x40;
- val = 1 << TestFail;
- Set_NB32_DCT(dev, dct, reg, val);
- }
- }
-
- if (nxtcsBase) {
- pDCTstat->DCTSysLimit = nxtcsBase - 1;
- mct_AfterStitchMemory(pMCTstat, pDCTstat, dct);
- }
-
- /* dump_pci_device(PCI_DEV(0, 0x18+pDCTstat->Node_ID, 2)); */
-
- printk(BIOS_DEBUG, "StitchMemory: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "StitchMemory: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "StitchMemory: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "StitchMemory: Done\n\n");
-}
-
-static u16 Get_Fk_D(u8 k)
-{
- return Table_F_k[k]; /* FIXME: k or k<<1 ? */
-}
-
-static u8 DIMMPresence_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Check DIMMs present, verify checksum, flag SDRAM type,
- * build population indicator bitmaps, and preload bus loading
- * of DIMMs into DCTStatStruc.
- * MAAload = number of devices on the "A" bus.
- * MABload = number of devices on the "B" bus.
- * MAAdimms = number of DIMMs on the "A" bus slots.
- * MABdimms = number of DIMMs on the "B" bus slots.
- * DATAAload = number of ranks on the "A" bus slots.
- * DATABload = number of ranks on the "B" bus slots.
- */
- u16 i, j, k;
- u8 smbaddr;
- u8 SPDCtrl;
- u16 RegDIMMPresent, LRDIMMPresent, MaxDimms;
- u8 devwidth;
- u16 DimmSlots;
- u8 byte = 0, bytex;
- uint8_t crc_status;
-
- /* preload data structure with addrs */
- mctGet_DIMMAddr(pDCTstat, pDCTstat->Node_ID);
-
- DimmSlots = MaxDimms = mctGet_NVbits(NV_MAX_DIMMS);
-
- SPDCtrl = mctGet_NVbits(NV_SPDCHK_RESTRT);
-
- RegDIMMPresent = 0;
- LRDIMMPresent = 0;
- pDCTstat->DimmQRPresent = 0;
-
- for (i = 0; i < MAX_DIMMS_SUPPORTED; i++) {
- if (i >= MaxDimms)
- break;
-
- if ((pDCTstat->DimmQRPresent & (1 << i)) || (i < DimmSlots)) {
- int status;
- smbaddr = Get_DIMMAddress_D(pDCTstat, i);
- status = mctRead_SPD(smbaddr, SPD_ByteUse);
- if (status >= 0) {
- /* Verify result */
- status = mctRead_SPD(smbaddr, SPD_ByteUse);
- }
- if (status >= 0) { /* SPD access is ok */
- pDCTstat->DIMMPresent |= 1 << i;
- read_spd_bytes(pMCTstat, pDCTstat, i);
-#ifdef DEBUG_DIMM_SPD
- dump_spd_bytes(pMCTstat, pDCTstat, i);
-#endif
- crc_status = crcCheck(pDCTstat, i);
- if (!crc_status) {
- /* Try again in case there was a transient glitch */
- read_spd_bytes(pMCTstat, pDCTstat, i);
- crc_status = crcCheck(pDCTstat, i);
- }
- if ((crc_status) || (SPDCtrl == 2)) { /* CRC is OK */
- byte = pDCTstat->spd_data.spd_bytes[i][SPD_TYPE];
- if (byte == JED_DDR3SDRAM) {
- /*Dimm is 'Present'*/
- pDCTstat->DIMMValid |= 1 << i;
- }
- } else {
- printk(BIOS_WARNING, "Node %d DIMM %d: SPD checksum invalid\n", pDCTstat->Node_ID, i);
- pDCTstat->DIMMSPDCSE = 1 << i;
- if (SPDCtrl == 0) {
- pDCTstat->ErrStatus |= 1 << SB_DIMMChkSum;
- pDCTstat->ErrCode = SC_StopError;
- } else {
- /*if NV_SPDCHK_RESTRT is set to 1, ignore faulty SPD checksum*/
- pDCTstat->ErrStatus |= 1<<SB_DIMMChkSum;
- byte = pDCTstat->spd_data.spd_bytes[i][SPD_TYPE];
- if (byte == JED_DDR3SDRAM)
- pDCTstat->DIMMValid |= 1 << i;
- }
- }
-
- /* Zero DIMM SPD data cache if DIMM not present / valid */
- if (!(pDCTstat->DIMMValid & (1 << i)))
- memset(pDCTstat->spd_data.spd_bytes[i], 0, sizeof(pDCTstat->spd_data.spd_bytes[i]));
-
- /* Get module information for SMBIOS */
- if (pDCTstat->DIMMValid & (1 << i)) {
- pDCTstat->DimmManufacturerID[i] = 0;
- for (k = 0; k < 8; k++)
- pDCTstat->DimmManufacturerID[i] |= ((uint64_t)pDCTstat->spd_data.spd_bytes[i][SPD_MANID_START + k]) << (k * 8);
- for (k = 0; k < SPD_PARTN_LENGTH; k++)
- pDCTstat->DimmPartNumber[i][k] = pDCTstat->spd_data.spd_bytes[i][SPD_PARTN_START + k];
- pDCTstat->DimmPartNumber[i][SPD_PARTN_LENGTH] = 0;
- pDCTstat->DimmRevisionNumber[i] = 0;
- for (k = 0; k < 2; k++)
- pDCTstat->DimmRevisionNumber[i] |= ((uint16_t)pDCTstat->spd_data.spd_bytes[i][SPD_REVNO_START + k]) << (k * 8);
- pDCTstat->DimmSerialNumber[i] = 0;
- for (k = 0; k < 4; k++)
- pDCTstat->DimmSerialNumber[i] |= ((uint32_t)pDCTstat->spd_data.spd_bytes[i][SPD_SERIAL_START + k]) << (k * 8);
- pDCTstat->DimmRows[i] = (pDCTstat->spd_data.spd_bytes[i][SPD_Addressing] & 0x38) >> 3;
- pDCTstat->DimmCols[i] = pDCTstat->spd_data.spd_bytes[i][SPD_Addressing] & 0x7;
- pDCTstat->DimmRanks[i] = ((pDCTstat->spd_data.spd_bytes[i][SPD_Organization] & 0x38) >> 3) + 1;
- pDCTstat->DimmBanks[i] = 1ULL << (((pDCTstat->spd_data.spd_bytes[i][SPD_Density] & 0x70) >> 4) + 3);
- pDCTstat->DimmWidth[i] = 1ULL << ((pDCTstat->spd_data.spd_bytes[i][SPD_BusWidth] & 0x7) + 3);
- pDCTstat->DimmChipSize[i] = 1ULL << ((pDCTstat->spd_data.spd_bytes[i][SPD_Density] & 0xf) + 28);
- pDCTstat->DimmChipWidth[i] = 1ULL << ((pDCTstat->spd_data.spd_bytes[i][SPD_Organization] & 0x7) + 2);
- }
- /* Check supported voltage(s) */
- pDCTstat->DimmSupportedVoltages[i] = pDCTstat->spd_data.spd_bytes[i][SPD_Voltage] & 0x7;
- pDCTstat->DimmSupportedVoltages[i] ^= 0x1; /* Invert LSB to convert from SPD format to internal bitmap format */
- /* Check module type */
- byte = pDCTstat->spd_data.spd_bytes[i][SPD_DIMMTYPE] & 0x7;
- if (byte == JED_RDIMM || byte == JED_MiniRDIMM) {
- RegDIMMPresent |= 1 << i;
- pDCTstat->DimmRegistered[i] = 1;
- } else {
- pDCTstat->DimmRegistered[i] = 0;
- }
- if (byte == JED_LRDIMM) {
- LRDIMMPresent |= 1 << i;
- pDCTstat->DimmLoadReduced[i] = 1;
- } else {
- pDCTstat->DimmLoadReduced[i] = 0;
- }
- /* Check ECC capable */
- byte = pDCTstat->spd_data.spd_bytes[i][SPD_BusWidth];
- if (byte & JED_ECC) {
- /* DIMM is ECC capable */
- pDCTstat->DimmECCPresent |= 1 << i;
- }
- /* Check if x4 device */
- devwidth = pDCTstat->spd_data.spd_bytes[i][SPD_Organization] & 0x7; /* 0:x4,1:x8,2:x16 */
- if (devwidth == 0) {
- /* DIMM is made with x4 or x16 drams */
- pDCTstat->Dimmx4Present |= 1 << i;
- } else if (devwidth == 1) {
- pDCTstat->Dimmx8Present |= 1 << i;
- } else if (devwidth == 2) {
- pDCTstat->Dimmx16Present |= 1 << i;
- }
-
- byte = (pDCTstat->spd_data.spd_bytes[i][SPD_Organization] >> 3);
- byte &= 7;
- if (byte == 3) { /* 4ranks */
- /* if any DIMMs are QR, we have to make two passes through DIMMs*/
- if (pDCTstat->DimmQRPresent == 0) {
- MaxDimms <<= 1;
- }
- if (i < DimmSlots) {
- pDCTstat->DimmQRPresent |= (1 << i) | (1 << (i+4));
- } else {
- pDCTstat->MAdimms[i & 1] --;
- }
- byte = 1; /* upper two ranks of QR DIMM will be counted on another DIMM number iteration*/
- } else if (byte == 1) { /* 2ranks */
- pDCTstat->DimmDRPresent |= 1 << i;
- }
- bytex = devwidth;
- if (devwidth == 0)
- bytex = 16;
- else if (devwidth == 1)
- bytex = 8;
- else if (devwidth == 2)
- bytex = 4;
-
- byte++; /* al+1 = rank# */
- if (byte == 2)
- bytex <<= 1; /*double Addr bus load value for dual rank DIMMs*/
-
- j = i & (1<<0);
- pDCTstat->DATAload[j] += byte; /*number of ranks on DATA bus*/
- pDCTstat->MAload[j] += bytex; /*number of devices on CMD/ADDR bus*/
- pDCTstat->MAdimms[j]++; /*number of DIMMs on A bus */
-
- /* check address mirror support for unbuffered dimm */
- /* check number of registers on a dimm for registered dimm */
- byte = pDCTstat->spd_data.spd_bytes[i][SPD_AddressMirror];
- if (RegDIMMPresent & (1 << i)) {
- if ((byte & 3) > 1)
- pDCTstat->MirrPresU_NumRegR |= 1 << i;
- } else {
- if ((byte & 1) == 1)
- pDCTstat->MirrPresU_NumRegR |= 1 << i;
- }
- /* Get byte62: Reference Raw Card information. We dont need it now. */
- /* byte = pDCTstat->spd_data.spd_bytes[i][SPD_RefRawCard]; */
- /* Get Byte65/66 for register manufacture ID code */
- if ((0x97 == pDCTstat->spd_data.spd_bytes[i][SPD_RegManufactureID_H]) &&
- (0x80 == pDCTstat->spd_data.spd_bytes[i][SPD_RegManufactureID_L])) {
- if (0x16 == pDCTstat->spd_data.spd_bytes[i][SPD_RegManRevID])
- pDCTstat->RegMan2Present |= 1 << i;
- else
- pDCTstat->RegMan1Present |= 1 << i;
- }
- /* Get control word value for RC3 */
- byte = pDCTstat->spd_data.spd_bytes[i][70];
- pDCTstat->CtrlWrd3 |= ((byte >> 4) & 0xf) << (i << 2); /* RC3 = SPD byte 70 [7:4] */
- /* Get control word values for RC4 and RC5 */
- byte = pDCTstat->spd_data.spd_bytes[i][71];
- pDCTstat->CtrlWrd4 |= (byte & 0xf) << (i << 2); /* RC4 = SPD byte 71 [3:0] */
- pDCTstat->CtrlWrd5 |= ((byte >> 4) & 0xf) << (i << 2); /* RC5 = SPD byte 71 [7:4] */
- }
- }
- }
- printk(BIOS_DEBUG, "\t DIMMPresence: DIMMValid=%x\n", pDCTstat->DIMMValid);
- printk(BIOS_DEBUG, "\t DIMMPresence: DIMMPresent=%x\n", pDCTstat->DIMMPresent);
- printk(BIOS_DEBUG, "\t DIMMPresence: RegDIMMPresent=%x\n", RegDIMMPresent);
- printk(BIOS_DEBUG, "\t DIMMPresence: LRDIMMPresent=%x\n", LRDIMMPresent);
- printk(BIOS_DEBUG, "\t DIMMPresence: DimmECCPresent=%x\n", pDCTstat->DimmECCPresent);
- printk(BIOS_DEBUG, "\t DIMMPresence: DimmPARPresent=%x\n", pDCTstat->DimmPARPresent);
- printk(BIOS_DEBUG, "\t DIMMPresence: Dimmx4Present=%x\n", pDCTstat->Dimmx4Present);
- printk(BIOS_DEBUG, "\t DIMMPresence: Dimmx8Present=%x\n", pDCTstat->Dimmx8Present);
- printk(BIOS_DEBUG, "\t DIMMPresence: Dimmx16Present=%x\n", pDCTstat->Dimmx16Present);
- printk(BIOS_DEBUG, "\t DIMMPresence: DimmPlPresent=%x\n", pDCTstat->DimmPlPresent);
- printk(BIOS_DEBUG, "\t DIMMPresence: DimmDRPresent=%x\n", pDCTstat->DimmDRPresent);
- printk(BIOS_DEBUG, "\t DIMMPresence: DimmQRPresent=%x\n", pDCTstat->DimmQRPresent);
- printk(BIOS_DEBUG, "\t DIMMPresence: DATAload[0]=%x\n", pDCTstat->DATAload[0]);
- printk(BIOS_DEBUG, "\t DIMMPresence: MAload[0]=%x\n", pDCTstat->MAload[0]);
- printk(BIOS_DEBUG, "\t DIMMPresence: MAdimms[0]=%x\n", pDCTstat->MAdimms[0]);
- printk(BIOS_DEBUG, "\t DIMMPresence: DATAload[1]=%x\n", pDCTstat->DATAload[1]);
- printk(BIOS_DEBUG, "\t DIMMPresence: MAload[1]=%x\n", pDCTstat->MAload[1]);
- printk(BIOS_DEBUG, "\t DIMMPresence: MAdimms[1]=%x\n", pDCTstat->MAdimms[1]);
-
- if (pDCTstat->DIMMValid != 0) { /* If any DIMMs are present...*/
- if (RegDIMMPresent != 0) {
- if ((RegDIMMPresent ^ pDCTstat->DIMMValid) !=0) {
- /* module type DIMM mismatch (reg'ed, unbuffered) */
- pDCTstat->ErrStatus |= 1<<SB_DimmMismatchM;
- pDCTstat->ErrCode = SC_StopError;
- } else{
- /* all DIMMs are registered */
- pDCTstat->Status |= 1<<SB_Registered;
- }
- }
- if (LRDIMMPresent != 0) {
- if ((LRDIMMPresent ^ pDCTstat->DIMMValid) !=0) {
- /* module type DIMM mismatch (reg'ed, unbuffered) */
- pDCTstat->ErrStatus |= 1<<SB_DimmMismatchM;
- pDCTstat->ErrCode = SC_StopError;
- } else{
- /* all DIMMs are registered */
- pDCTstat->Status |= 1<<SB_LoadReduced;
- }
- }
- if (pDCTstat->DimmECCPresent != 0) {
- if ((pDCTstat->DimmECCPresent ^ pDCTstat->DIMMValid) == 0) {
- /* all DIMMs are ECC capable */
- pDCTstat->Status |= 1<<SB_ECCDIMMs;
- }
- }
- if (pDCTstat->DimmPARPresent != 0) {
- if ((pDCTstat->DimmPARPresent ^ pDCTstat->DIMMValid) == 0) {
- /*all DIMMs are Parity capable */
- pDCTstat->Status |= 1<<SB_PARDIMMs;
- }
- }
- } else {
- /* no DIMMs present or no DIMMs that qualified. */
- pDCTstat->ErrStatus |= 1<<SB_NoDimms;
- pDCTstat->ErrCode = SC_StopError;
- }
-
- printk(BIOS_DEBUG, "\t DIMMPresence: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "\t DIMMPresence: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "\t DIMMPresence: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "\t DIMMPresence: Done\n\n");
-
- mctHookAfterDIMMpre();
-
- return pDCTstat->ErrCode;
-}
-
-static u8 Get_DIMMAddress_D(struct DCTStatStruc *pDCTstat, u8 i)
-{
- u8 *p;
-
- p = pDCTstat->DIMMAddr;
- /* mct_BeforeGetDIMMAddress(); */
- return p[i];
-}
-
-static void mct_preInitDCT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 err_code;
- uint8_t nvram;
- uint8_t allow_config_restore;
-
- /* Preconfigure DCT0 */
- DCTPreInit_D(pMCTstat, pDCTstat, 0);
-
- /* Configure DCT1 if unganged and enabled*/
- if (!pDCTstat->GangedMode) {
- if (pDCTstat->DIMMValidDCT[1] > 0) {
- err_code = pDCTstat->ErrCode; /* save DCT0 errors */
- pDCTstat->ErrCode = 0;
- DCTPreInit_D(pMCTstat, pDCTstat, 1);
- if (pDCTstat->ErrCode == 2) /* DCT1 is not Running */
- pDCTstat->ErrCode = err_code; /* Using DCT0 Error code to update pDCTstat.ErrCode */
- }
- }
-
-#if CONFIG(HAVE_ACPI_RESUME)
- calculate_and_store_spd_hashes(pMCTstat, pDCTstat);
-
- if (load_spd_hashes_from_nvram(pMCTstat, pDCTstat) < 0) {
- pDCTstat->spd_data.nvram_spd_match = 0;
- } else {
- compare_nvram_spd_hashes(pMCTstat, pDCTstat);
- }
-#else
- pDCTstat->spd_data.nvram_spd_match = 0;
-#endif
-
- /* Check to see if restoration of SPD data from NVRAM is allowed */
- allow_config_restore = 0;
- if (get_option(&nvram, "allow_spd_nvram_cache_restore") == CB_SUCCESS)
- allow_config_restore = !!nvram;
-
-#if CONFIG(HAVE_ACPI_RESUME)
- if (pMCTstat->nvram_checksum != calculate_nvram_mct_hash())
- allow_config_restore = 0;
-#else
- allow_config_restore = 0;
-#endif
-
- if (!allow_config_restore)
- pDCTstat->spd_data.nvram_spd_match = 0;
-}
-
-static void mct_initDCT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 val;
- u8 err_code;
-
- /* Config. DCT0 for Ganged or unganged mode */
- DCTInit_D(pMCTstat, pDCTstat, 0);
- DCTFinalInit_D(pMCTstat, pDCTstat, 0);
- if (pDCTstat->ErrCode == SC_FatalErr) {
- /* Do nothing goto exitDCTInit; any fatal errors? */
- } else {
- /* Configure DCT1 if unganged and enabled */
- if (!pDCTstat->GangedMode) {
- if (pDCTstat->DIMMValidDCT[1] > 0) {
- err_code = pDCTstat->ErrCode; /* save DCT0 errors */
- pDCTstat->ErrCode = 0;
- DCTInit_D(pMCTstat, pDCTstat, 1);
- DCTFinalInit_D(pMCTstat, pDCTstat, 1);
- if (pDCTstat->ErrCode == 2) /* DCT1 is not Running */
- pDCTstat->ErrCode = err_code; /* Using DCT0 Error code to update pDCTstat.ErrCode */
- } else {
- val = 1 << DisDramInterface;
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x94, val);
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x90);
- val &= ~(1 << ParEn);
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x90, val);
-
- /* To maximize power savings when DisDramInterface = 1b,
- * all of the MemClkDis bits should also be set.
- */
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x88, 0xff000000);
- }
- }
- }
-}
-
-static void mct_DramInit(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- mct_BeforeDramInit_Prod_D(pMCTstat, pDCTstat, dct);
- mct_DramInit_Sw_D(pMCTstat, pDCTstat, dct);
- /* mct_DramInit_Hw_D(pMCTstat, pDCTstat, dct); */
-}
-
-static u8 mct_setMode(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 byte;
- u8 bytex;
- u32 val;
- u32 reg;
-
- byte = bytex = pDCTstat->DIMMValid;
- bytex &= 0x55; /* CHA DIMM pop */
- pDCTstat->DIMMValidDCT[0] = bytex;
-
- byte &= 0xAA; /* CHB DIMM popa */
- byte >>= 1;
- pDCTstat->DIMMValidDCT[1] = byte;
-
- if (byte != bytex) {
- pDCTstat->ErrStatus &= ~(1 << SB_DimmMismatchO);
- } else {
- byte = mctGet_NVbits(NV_Unganged);
- if (byte)
- pDCTstat->ErrStatus |= (1 << SB_DimmMismatchO); /* Set temp. to avoid setting of ganged mode */
-
- if ((!(pDCTstat->ErrStatus & (1 << SB_DimmMismatchO))) && (pDCTstat->LogicalCPUID & AMD_FAM10_ALL)) {
- /* Ganged channel mode not supported on Family 15h or higher */
- pDCTstat->GangedMode = 1;
- /* valid 128-bit mode population. */
- pDCTstat->Status |= 1 << SB_128bitmode;
- reg = 0x110;
- val = Get_NB32(pDCTstat->dev_dct, reg);
- val |= 1 << DctGangEn;
- Set_NB32(pDCTstat->dev_dct, reg, val);
- }
- if (byte) /* NV_Unganged */
- pDCTstat->ErrStatus &= ~(1 << SB_DimmMismatchO); /* Clear so that there is no DIMM mismatch error */
- }
-
- return pDCTstat->ErrCode;
-}
-
-u32 Get_NB32(u32 dev, u32 reg)
-{
- return pci_read_config32(dev, reg);
-}
-
-void Set_NB32(u32 dev, u32 reg, u32 val)
-{
- pci_write_config32(dev, reg, val);
-}
-
-
-u32 Get_NB32_index(u32 dev, u32 index_reg, u32 index)
-{
- u32 dword;
-
- Set_NB32(dev, index_reg, index);
- dword = Get_NB32(dev, index_reg+0x4);
-
- return dword;
-}
-
-void Set_NB32_index(u32 dev, u32 index_reg, u32 index, u32 data)
-{
- Set_NB32(dev, index_reg, index);
- Set_NB32(dev, index_reg + 0x4, data);
-}
-
-u32 Get_NB32_index_wait(u32 dev, u32 index_reg, u32 index)
-{
- u32 dword;
-
- index &= ~(1 << DctAccessWrite);
- Set_NB32(dev, index_reg, index);
- do {
- dword = Get_NB32(dev, index_reg);
- } while (!(dword & (1 << DctAccessDone)));
- dword = Get_NB32(dev, index_reg + 0x4);
-
- return dword;
-}
-
-void Set_NB32_index_wait(u32 dev, u32 index_reg, u32 index, u32 data)
-{
- u32 dword;
-
- Set_NB32(dev, index_reg + 0x4, data);
- index |= (1 << DctAccessWrite);
- Set_NB32(dev, index_reg, index);
- do {
- dword = Get_NB32(dev, index_reg);
- } while (!(dword & (1 << DctAccessDone)));
-
-}
-
-u8 mct_BeforePlatformSpec(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- /* mct_checkForCxDxSupport_D */
- if (pDCTstat->LogicalCPUID & AMD_DR_GT_Bx) {
- /* Family 10h Errata 322: Address and Command Fine Delay Values May Be Incorrect */
- /* 1. Write 00000000h to F2x[1,0]9C_xD08E000 */
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, dct, 0x98, 0x0D08E000, 0);
- /* 2. If DRAM Configuration Register[MemClkFreq] (F2x[1,0]94[2:0]) is
- greater than or equal to 011b (DDR-800 and higher),
- then write 00000080h to F2x[1,0]9C_xD02E001,
- else write 00000090h to F2x[1,0]9C_xD02E001. */
- if (pDCTstat->Speed >= mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK)))
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, dct, 0x98, 0x0D02E001, 0x80);
- else
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, dct, 0x98, 0x0D02E001, 0x90);
- }
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-
- return pDCTstat->ErrCode;
-}
-
-u8 mct_PlatformSpec(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- /* Get platform specific config/timing values from the interface layer
- * and program them into DCT.
- */
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- u32 dev = pDCTstat->dev_dct;
- u32 index_reg;
- u8 i, i_start, i_end;
-
- if (pDCTstat->GangedMode) {
- SyncSetting(pDCTstat);
- /* mct_SetupSync_D */
- i_start = 0;
- i_end = 2;
- } else {
- i_start = dct;
- i_end = dct + 1;
- }
- for (i = i_start; i < i_end; i++) {
- index_reg = 0x98;
- Set_NB32_index_wait_DCT(dev, i, index_reg, 0x00, pDCTstat->CH_ODC_CTL[i]); /* Channel A/B Output Driver Compensation Control */
- Set_NB32_index_wait_DCT(dev, i, index_reg, 0x04, pDCTstat->CH_ADDR_TMG[i]); /* Channel A/B Output Driver Compensation Control */
- printk(BIOS_SPEW, "Programmed DCT %d timing/termination pattern %08x %08x\n", dct, pDCTstat->CH_ADDR_TMG[i], pDCTstat->CH_ODC_CTL[i]);
- }
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-
- return pDCTstat->ErrCode;
-}
-
-static void mct_SyncDCTsReady(struct DCTStatStruc *pDCTstat)
-{
- u32 dev;
- u32 val;
-
- if (pDCTstat->NodePresent) {
- dev = pDCTstat->dev_dct;
-
- if ((pDCTstat->DIMMValidDCT[0]) || (pDCTstat->DIMMValidDCT[1])) {
- /* This Node has DRAM */
- do {
- val = Get_NB32(dev, 0x110);
- } while (!(val & (1 << DramEnabled)));
- }
- } /* Node is present */
-}
-
-static void mct_AfterGetCLT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- if (!pDCTstat->GangedMode) {
- if (dct == 0) {
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[dct];
- if (pDCTstat->DIMMValidDCT[dct] == 0)
- pDCTstat->ErrCode = SC_StopError;
- } else {
- pDCTstat->CSPresent = 0;
- pDCTstat->CSTestFail = 0;
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[dct];
- if (pDCTstat->DIMMValidDCT[dct] == 0)
- pDCTstat->ErrCode = SC_StopError;
- }
- }
-}
-
-static u8 mct_SPDCalcWidth(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 ret;
- u32 val;
-
- if (dct == 0) {
- SPDCalcWidth_D(pMCTstat, pDCTstat);
- ret = mct_setMode(pMCTstat, pDCTstat);
- } else {
- ret = pDCTstat->ErrCode;
- }
-
- if (pDCTstat->DIMMValidDCT[0] == 0) {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x94);
- val |= 1 << DisDramInterface;
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x94, val);
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x90);
- val &= ~(1 << ParEn);
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x90, val);
- }
- if (pDCTstat->DIMMValidDCT[1] == 0) {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x94);
- val |= 1 << DisDramInterface;
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x94, val);
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x90);
- val &= ~(1 << ParEn);
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x90, val);
- }
-
- printk(BIOS_DEBUG, "SPDCalcWidth: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "SPDCalcWidth: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "SPDCalcWidth: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "SPDCalcWidth: Done\n");
- /* Disable dram interface before DRAM init */
-
- return ret;
-}
-
-static void mct_AfterStitchMemory(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 dword;
- u32 dev;
- u32 reg;
- u8 _MemHoleRemap;
- u32 DramHoleBase;
-
- _MemHoleRemap = mctGet_NVbits(NV_MemHole);
- DramHoleBase = mctGet_NVbits(NV_BottomIO);
- DramHoleBase <<= 8;
- /* Increase hole size so;[31:24]to[31:16]
- * it has granularity of 128MB shl eax,8
- * Set 'effective' bottom IOmov DramHoleBase,eax
- */
- pMCTstat->HoleBase = (DramHoleBase & 0xFFFFF800) << 8;
-
- /* In unganged mode, we must add DCT0 and DCT1 to DCTSysLimit */
- if (!pDCTstat->GangedMode) {
- dev = pDCTstat->dev_dct;
- pDCTstat->NodeSysLimit += pDCTstat->DCTSysLimit;
- /* if DCT0 and DCT1 both exist, set DctSelBaseAddr[47:27] to the top of DCT0 */
- if (dct == 0) {
- if (pDCTstat->DIMMValidDCT[1] > 0) {
- dword = pDCTstat->DCTSysLimit + 1;
- dword += pDCTstat->NodeSysBase;
- dword >>= 8; /* scale [39:8] to [47:27],and to F2x110[31:11] */
- if ((dword >= DramHoleBase) && _MemHoleRemap) {
- pMCTstat->HoleBase = (DramHoleBase & 0xFFFFF800) << 8;
- val = pMCTstat->HoleBase;
- val >>= 16;
- val = (((~val) & 0xFF) + 1);
- val <<= 8;
- dword += val;
- }
- reg = 0x110;
- val = Get_NB32(dev, reg);
- val &= 0x7F;
- val |= dword;
- val |= 3; /* Set F2x110[DctSelHiRngEn], F2x110[DctSelHi] */
- Set_NB32(dev, reg, val);
-
- reg = 0x114;
- val = dword;
- Set_NB32(dev, reg, val);
- }
- } else {
- /* Program the DctSelBaseAddr value to 0
- if DCT 0 is disabled */
- if (pDCTstat->DIMMValidDCT[0] == 0) {
- dword = pDCTstat->NodeSysBase;
- dword >>= 8;
- if ((dword >= DramHoleBase) && _MemHoleRemap) {
- pMCTstat->HoleBase = (DramHoleBase & 0xFFFFF800) << 8;
- val = pMCTstat->HoleBase;
- val >>= 8;
- val &= ~(0xFFFF);
- val |= (((~val) & 0xFFFF) + 1);
- dword += val;
- }
- reg = 0x114;
- val = dword;
- Set_NB32(dev, reg, val);
-
- reg = 0x110;
- val |= 3; /* Set F2x110[DctSelHiRngEn], F2x110[DctSelHi] */
- Set_NB32(dev, reg, val);
- }
- }
- } else {
- pDCTstat->NodeSysLimit += pDCTstat->DCTSysLimit;
- }
- printk(BIOS_DEBUG, "AfterStitch pDCTstat->NodeSysBase = %x\n", pDCTstat->NodeSysBase);
- printk(BIOS_DEBUG, "mct_AfterStitchMemory: pDCTstat->NodeSysLimit = %x\n", pDCTstat->NodeSysLimit);
-}
-
-static u8 mct_DIMMPresence(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 ret;
-
- if (dct == 0)
- ret = DIMMPresence_D(pMCTstat, pDCTstat);
- else
- ret = pDCTstat->ErrCode;
-
- return ret;
-}
-
-/* mct_BeforeGetDIMMAddress inline in C */
-
-static void mct_OtherTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (pDCTstat->NodePresent) {
- if (pDCTstat->DIMMValidDCT[0]) {
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[0];
- Set_OtherTiming(pMCTstat, pDCTstat, 0);
- }
- if (pDCTstat->DIMMValidDCT[1] && !pDCTstat->GangedMode) {
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[1];
- Set_OtherTiming(pMCTstat, pDCTstat, 1);
- }
- } /* Node is present*/
- } /* while Node */
-}
-
-static void Set_OtherTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 reg;
- u32 val;
- u32 dword;
- u32 dev = pDCTstat->dev_dct;
-
- Get_DqsRcvEnGross_Diff(pDCTstat, dev, dct, 0x98);
- Get_WrDatGross_Diff(pDCTstat, dct, dev, 0x98);
- Get_Trdrd(pMCTstat, pDCTstat, dct);
- Get_Twrwr(pMCTstat, pDCTstat, dct);
- Get_Twrrd(pMCTstat, pDCTstat, dct);
- Get_TrwtTO(pMCTstat, pDCTstat, dct);
- Get_TrwtWB(pMCTstat, pDCTstat);
-
- if (!is_fam15h()) {
- reg = 0x8c; /* Dram Timing Hi */
- val = Get_NB32_DCT(dev, dct, reg);
- val &= 0xffff0300;
- dword = pDCTstat->TrwtTO;
- val |= dword << 4;
- dword = pDCTstat->Twrrd & 3;
- val |= dword << 10;
- dword = pDCTstat->Twrwr & 3;
- val |= dword << 12;
- dword = (pDCTstat->Trdrd - 0x3) & 3;
- val |= dword << 14;
- dword = pDCTstat->TrwtWB;
- val |= dword;
- Set_NB32_DCT(dev, dct, reg, val);
-
- reg = 0x78;
- val = Get_NB32_DCT(dev, dct, reg);
- val &= 0xffffc0ff;
- dword = pDCTstat->Twrrd >> 2;
- val |= dword << 8;
- dword = pDCTstat->Twrwr >> 2;
- val |= dword << 10;
- dword = (pDCTstat->Trdrd - 0x3) >> 2;
- val |= dword << 12;
- Set_NB32_DCT(dev, dct, reg, val);
- }
-}
-
-static void Get_Trdrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- int8_t Trdrd;
-
- Trdrd = ((int8_t)(pDCTstat->DqsRcvEnGrossMax - pDCTstat->DqsRcvEnGrossMin) >> 1) + 1;
- if (Trdrd > 8)
- Trdrd = 8;
- if (Trdrd < 3)
- Trdrd = 3;
- pDCTstat->Trdrd = Trdrd;
-}
-
-static void Get_Twrwr(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- int8_t Twrwr = 0;
-
- Twrwr = ((int8_t)(pDCTstat->WrDatGrossMax - pDCTstat->WrDatGrossMin) >> 1) + 2;
-
- if (Twrwr < 2)
- Twrwr = 2;
- else if (Twrwr > 9)
- Twrwr = 9;
-
- pDCTstat->Twrwr = Twrwr;
-}
-
-static void Get_Twrrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 LDplus1;
- int8_t Twrrd;
-
- LDplus1 = Get_Latency_Diff(pMCTstat, pDCTstat, dct);
-
- Twrrd = ((int8_t)(pDCTstat->WrDatGrossMax - pDCTstat->DqsRcvEnGrossMin) >> 1) + 4 - LDplus1;
-
- if (Twrrd < 2)
- Twrrd = 2;
- else if (Twrrd > 10)
- Twrrd = 10;
- pDCTstat->Twrrd = Twrrd;
-}
-
-static void Get_TrwtTO(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 LDplus1;
- int8_t TrwtTO;
-
- LDplus1 = Get_Latency_Diff(pMCTstat, pDCTstat, dct);
-
- TrwtTO = ((int8_t)(pDCTstat->DqsRcvEnGrossMax - pDCTstat->WrDatGrossMin) >> 1) + LDplus1;
-
- pDCTstat->TrwtTO = TrwtTO;
-}
-
-static void Get_TrwtWB(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* TrwtWB ensures read-to-write data-bus turnaround.
- This value should be one more than the programmed TrwtTO.*/
- pDCTstat->TrwtWB = pDCTstat->TrwtTO;
-}
-
-static u8 Get_Latency_Diff(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 val1, val2;
-
- val1 = Get_NB32_DCT(dev, dct, 0x88) & 0xF;
- val2 = (Get_NB32_DCT(dev, dct, 0x84) >> 20) & 7;
-
- return val1 - val2;
-}
-
-static void Get_DqsRcvEnGross_Diff(struct DCTStatStruc *pDCTstat,
- u32 dev, uint8_t dct, u32 index_reg)
-{
- u8 Smallest, Largest;
- u32 val;
- u8 byte, bytex;
-
- /* The largest DqsRcvEnGrossDelay of any DIMM minus the
- DqsRcvEnGrossDelay of any other DIMM is equal to the Critical
- Gross Delay Difference (CGDD) */
- /* DqsRcvEn byte 1,0 */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, dct, index_reg, 0x10);
- Largest = val & 0xFF;
- Smallest = (val >> 8) & 0xFF;
-
- /* DqsRcvEn byte 3,2 */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, dct, index_reg, 0x11);
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
-
- /* DqsRcvEn byte 5,4 */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, dct, index_reg, 0x20);
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
-
- /* DqsRcvEn byte 7,6 */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, dct, index_reg, 0x21);
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
-
- if (pDCTstat->DimmECCPresent> 0) {
- /*DqsRcvEn Ecc */
- val = Get_DqsRcvEnGross_MaxMin(pDCTstat, dev, dct, index_reg, 0x12);
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
- }
-
- pDCTstat->DqsRcvEnGrossMax = Largest;
- pDCTstat->DqsRcvEnGrossMin = Smallest;
-}
-
-static void Get_WrDatGross_Diff(struct DCTStatStruc *pDCTstat,
- u8 dct, u32 dev, u32 index_reg)
-{
- u8 Smallest = 0, Largest = 0;
- u32 val;
- u8 byte, bytex;
-
- /* The largest WrDatGrossDlyByte of any DIMM minus the
- WrDatGrossDlyByte of any other DIMM is equal to CGDD */
- if (pDCTstat->DIMMValid & (1 << 0)) {
- val = Get_WrDatGross_MaxMin(pDCTstat, dct, dev, index_reg, 0x01); /* WrDatGrossDlyByte byte 0,1,2,3 for DIMM0 */
- Largest = val & 0xFF;
- Smallest = (val >> 8) & 0xFF;
- }
- if (pDCTstat->DIMMValid & (1 << 2)) {
- val = Get_WrDatGross_MaxMin(pDCTstat, dct, dev, index_reg, 0x101); /* WrDatGrossDlyByte byte 0,1,2,3 for DIMM1 */
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
- }
-
- /* If Cx, 2 more dimm need to be checked to find out the largest and smallest */
- if (pDCTstat->LogicalCPUID & AMD_DR_Cx) {
- if (pDCTstat->DIMMValid & (1 << 4)) {
- val = Get_WrDatGross_MaxMin(pDCTstat, dct, dev, index_reg, 0x201); /* WrDatGrossDlyByte byte 0,1,2,3 for DIMM2 */
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
- }
- if (pDCTstat->DIMMValid & (1 << 6)) {
- val = Get_WrDatGross_MaxMin(pDCTstat, dct, dev, index_reg, 0x301); /* WrDatGrossDlyByte byte 0,1,2,3 for DIMM2 */
- byte = val & 0xFF;
- bytex = (val >> 8) & 0xFF;
- if (bytex < Smallest)
- Smallest = bytex;
- if (byte > Largest)
- Largest = byte;
- }
- }
-
- pDCTstat->WrDatGrossMax = Largest;
- pDCTstat->WrDatGrossMin = Smallest;
-}
-
-static u16 Get_DqsRcvEnGross_MaxMin(struct DCTStatStruc *pDCTstat,
- u32 dev, uint8_t dct, u32 index_reg,
- u32 index)
-{
- u8 Smallest, Largest;
- u8 i;
- u8 byte;
- u32 val;
- u16 word;
- u8 ecc_reg = 0;
-
- Smallest = 7;
- Largest = 0;
-
- if (index == 0x12)
- ecc_reg = 1;
-
- for (i = 0; i < 8; i+=2) {
- if (pDCTstat->DIMMValid & (1 << i)) {
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, index);
- val &= 0x00E000E0;
- byte = (val >> 5) & 0xFF;
- if (byte < Smallest)
- Smallest = byte;
- if (byte > Largest)
- Largest = byte;
- if (!(ecc_reg)) {
- byte = (val >> (16 + 5)) & 0xFF;
- if (byte < Smallest)
- Smallest = byte;
- if (byte > Largest)
- Largest = byte;
- }
- }
- index += 3;
- } /* while ++i */
-
- word = Smallest;
- word <<= 8;
- word |= Largest;
-
- return word;
-}
-
-static u16 Get_WrDatGross_MaxMin(struct DCTStatStruc *pDCTstat,
- u8 dct, u32 dev, u32 index_reg,
- u32 index)
-{
- u8 Smallest, Largest;
- u8 i, j;
- u32 val;
- u8 byte;
- u16 word;
-
- Smallest = 3;
- Largest = 0;
- for (i = 0; i < 2; i++) {
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, index);
- val &= 0x60606060;
- val >>= 5;
- for (j = 0; j < 4; j++) {
- byte = val & 0xFF;
- if (byte < Smallest)
- Smallest = byte;
- if (byte > Largest)
- Largest = byte;
- val >>= 8;
- } /* while ++j */
- index++;
- } /*while ++i*/
-
- if (pDCTstat->DimmECCPresent > 0) {
- index++;
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, index);
- val &= 0x00000060;
- val >>= 5;
- byte = val & 0xFF;
- if (byte < Smallest)
- Smallest = byte;
- if (byte > Largest)
- Largest = byte;
- }
-
- word = Smallest;
- word <<= 8;
- word |= Largest;
-
- return word;
-}
-
-static void mct_PhyController_Config(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- uint8_t index;
- uint32_t dword;
- u32 index_reg = 0x98;
- u32 dev = pDCTstat->dev_dct;
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_DAC2_OR_C3 | AMD_RB_C3 | AMD_FAM15_ALL)) {
- if (is_fam15h()) {
- /* Set F2x[1, 0]98_x0D0F0F13 DllDisEarlyU and DllDisEarlyL to save power */
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0013 | (index << 8));
- dword |= (0x1 << 1); /* DllDisEarlyU = 1 */
- dword |= 0x1; /* DllDisEarlyL = 1 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0013 | (index << 8), dword);
- }
- }
-
- if (pDCTstat->Dimmx4Present == 0) {
- /* Set bit7 RxDqsUDllPowerDown to register F2x[1, 0]98_x0D0F0F13 for
- * additional power saving when x4 DIMMs are not present.
- */
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0013 | (index << 8));
- dword |= (0x1 << 7); /* RxDqsUDllPowerDown = 1 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0013 | (index << 8), dword);
- }
- }
- }
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_DAC2_OR_C3 | AMD_FAM15_ALL)) {
- if (pDCTstat->DimmECCPresent == 0) {
- /* Set bit4 PwrDn to register F2x[1, 0]98_x0D0F0830 for power saving */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0830);
- dword |= 1 << 4; /* BIOS should set this bit if ECC DIMMs are not present */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0830, dword);
- }
- }
-
-}
-
-static void mct_FinalMCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- struct DCTStatStruc *pDCTstat;
- u32 val;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- mct_PhyController_Config(pMCTstat, pDCTstat, 0);
- mct_PhyController_Config(pMCTstat, pDCTstat, 1);
-
- if (!is_fam15h()) {
- /* Family 10h CPUs */
- mct_ExtMCTConfig_Cx(pDCTstat);
- mct_ExtMCTConfig_Bx(pDCTstat);
- mct_ExtMCTConfig_Dx(pDCTstat);
- } else {
- /* Family 15h CPUs */
- uint8_t nvram;
- uint8_t enable_experimental_memory_speed_boost;
-
- /* Check to see if cache partitioning is allowed */
- enable_experimental_memory_speed_boost = 0;
- if (get_option(&nvram, "experimental_memory_speed_boost") == CB_SUCCESS)
- enable_experimental_memory_speed_boost = !!nvram;
-
- val = 0x0ce00f00; /* FlushWrOnStpGnt = 0x0 */
- val |= 0x10 << 2; /* MctWrLimit = 0x10 */
- val |= 0x1; /* DctWrLimit = 0x1 */
- Set_NB32(pDCTstat->dev_dct, 0x11c, val);
-
- val = Get_NB32(pDCTstat->dev_dct, 0x1b0);
- val &= ~0x3; /* AdapPrefMissRatio = 0x1 */
- val |= 0x1;
- val &= ~(0x3 << 2); /* AdapPrefPositiveStep = 0x0 */
- val &= ~(0x3 << 4); /* AdapPrefNegativeStep = 0x0 */
- val &= ~(0x7 << 8); /* CohPrefPrbLmt = 0x1 */
- val |= (0x1 << 8);
- val |= (0x1 << 12); /* EnSplitDctLimits = 0x1 */
- if (enable_experimental_memory_speed_boost)
- val |= (0x1 << 20); /* DblPrefEn = 0x1 */
- val |= (0x7 << 22); /* PrefFourConf = 0x7 */
- val |= (0x7 << 25); /* PrefFiveConf = 0x7 */
- val &= ~(0xf << 28); /* DcqBwThrotWm = 0x0 */
- Set_NB32(pDCTstat->dev_dct, 0x1b0, val);
-
- uint8_t wm1;
- uint8_t wm2;
-
- switch (pDCTstat->Speed) {
- case 0x4:
- wm1 = 0x3;
- wm2 = 0x4;
- break;
- case 0x6:
- wm1 = 0x3;
- wm2 = 0x5;
- break;
- case 0xa:
- wm1 = 0x4;
- wm2 = 0x6;
- break;
- case 0xe:
- wm1 = 0x5;
- wm2 = 0x8;
- break;
- case 0x12:
- wm1 = 0x6;
- wm2 = 0x9;
- break;
- default:
- wm1 = 0x7;
- wm2 = 0xa;
- break;
- }
-
- val = Get_NB32(pDCTstat->dev_dct, 0x1b4);
- val &= ~(0x3ff);
- val |= ((wm2 & 0x1f) << 5);
- val |= (wm1 & 0x1f);
- Set_NB32(pDCTstat->dev_dct, 0x1b4, val);
- }
- }
- }
-
- /* ClrClToNB_D postponed until we're done executing from ROM */
- mct_ClrWbEnhWsbDis_D(pMCTstat, pDCTstat);
-
- /* set F3x8C[DisFastTprWr] on all DR, if L3Size = 0 */
- if (pDCTstat->LogicalCPUID & AMD_DR_ALL) {
- if (!(cpuid_edx(0x80000006) & 0xFFFC0000)) {
- val = Get_NB32(pDCTstat->dev_nbmisc, 0x8C);
- val |= 1 << 24;
- Set_NB32(pDCTstat->dev_nbmisc, 0x8C, val);
- }
- }
-}
-
-void mct_ForceNBPState0_En_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Force the NB P-state to P0 */
- uint32_t dword;
- uint32_t dword2;
-
- dword = Get_NB32(pDCTstat->dev_nbctl, 0x174);
- if (!(dword & 0x1)) {
- dword = Get_NB32(pDCTstat->dev_nbctl, 0x170);
- pDCTstat->SwNbPstateLoDis = (dword >> 14) & 0x1;
- pDCTstat->NbPstateDisOnP0 = (dword >> 13) & 0x1;
- pDCTstat->NbPstateThreshold = (dword >> 9) & 0x7;
- pDCTstat->NbPstateHi = (dword >> 6) & 0x3;
- dword &= ~(0x1 << 14); /* SwNbPstateLoDis = 0 */
- dword &= ~(0x1 << 13); /* NbPstateDisOnP0 = 0 */
- dword &= ~(0x7 << 9); /* NbPstateThreshold = 0 */
- dword &= ~(0x3 << 3); /* NbPstateLo = NbPstateMaxVal */
- dword |= ((dword & 0x3) << 3);
- Set_NB32(pDCTstat->dev_nbctl, 0x170, dword);
-
- if (!is_model10_1f()) {
- /* Wait until CurNbPState == NbPstateLo */
- do {
- dword2 = Get_NB32(pDCTstat->dev_nbctl, 0x174);
- } while (((dword2 >> 19) & 0x7) != (dword & 0x3));
- }
- dword = Get_NB32(pDCTstat->dev_nbctl, 0x170);
- dword &= ~(0x3 << 6); /* NbPstateHi = 0 */
- dword |= (0x3 << 14); /* SwNbPstateLoDis = 1 */
- Set_NB32(pDCTstat->dev_nbctl, 0x170, dword);
-
- if (!is_model10_1f()) {
- /* Wait until CurNbPState == 0 */
- do {
- dword2 = Get_NB32(pDCTstat->dev_nbctl, 0x174);
- } while (((dword2 >> 19) & 0x7) != 0);
- }
- }
-}
-
-void mct_ForceNBPState0_Dis_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Restore normal NB P-state functionailty */
- uint32_t dword;
-
- dword = Get_NB32(pDCTstat->dev_nbctl, 0x174);
- if (!(dword & 0x1)) {
- dword = Get_NB32(pDCTstat->dev_nbctl, 0x170);
- dword &= ~(0x1 << 14); /* SwNbPstateLoDis*/
- dword |= ((pDCTstat->SwNbPstateLoDis & 0x1) << 14);
- dword &= ~(0x1 << 13); /* NbPstateDisOnP0 */
- dword |= ((pDCTstat->NbPstateDisOnP0 & 0x1) << 13);
- dword &= ~(0x7 << 9); /* NbPstateThreshold */
- dword |= ((pDCTstat->NbPstateThreshold & 0x7) << 9);
- dword &= ~(0x3 << 6); /* NbPstateHi */
- dword |= ((pDCTstat->NbPstateHi & 0x3) << 3);
- Set_NB32(pDCTstat->dev_nbctl, 0x170, dword);
- }
-}
-
-static void mct_InitialMCT_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat)
-{
- if (is_fam15h()) {
- msr_t p0_state_msr;
- uint8_t cpu_fid;
- uint8_t cpu_did;
- uint32_t cpu_divisor;
- uint8_t boost_states;
-
- /* Retrieve the number of boost states */
- boost_states = (Get_NB32(pDCTstat->dev_link, 0x15c) >> 2) & 0x7;
-
- /* Retrieve and store the TSC frequency (P0 COF) */
- p0_state_msr = rdmsr(PSTATE_0_MSR + boost_states);
- cpu_fid = p0_state_msr.lo & 0x3f;
- cpu_did = (p0_state_msr.lo >> 6) & 0x7;
- cpu_divisor = (0x1 << cpu_did);
- pMCTstat->TSCFreq = (100 * (cpu_fid + 0x10)) / cpu_divisor;
-
- printk(BIOS_DEBUG, "mct_InitialMCT_D: mct_ForceNBPState0_En_Fam15\n");
- mct_ForceNBPState0_En_Fam15(pMCTstat, pDCTstat);
- } else {
- /* K10 BKDG v3.62 section 2.8.9.2 */
- printk(BIOS_DEBUG, "mct_InitialMCT_D: clear_legacy_Mode\n");
- clear_legacy_Mode(pMCTstat, pDCTstat);
-
- /* Northbridge configuration */
- mct_SetClToNB_D(pMCTstat, pDCTstat);
- mct_SetWbEnhWsbDis_D(pMCTstat, pDCTstat);
- }
-}
-
-static u32 mct_NodePresent_D(void)
-{
- u32 val;
- if (is_fam15h()) {
- if (is_model10_1f()) {
- val = 0x14001022;
- } else {
- val = 0x16001022;
- }
- } else {
- val = 0x12001022;
- }
- return val;
-}
-
-static void mct_init(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 lo, hi;
- u32 addr;
-
- pDCTstat->GangedMode = 0;
- pDCTstat->DRPresent = 1;
-
- /* enable extend PCI configuration access */
- addr = NB_CFG_MSR;
- _RDMSR(addr, &lo, &hi);
- if (hi & (1 << (46-32))) {
- pDCTstat->Status |= 1 << SB_ExtConfig;
- } else {
- hi |= 1 << (46-32);
- _WRMSR(addr, lo, hi);
- }
-}
-
-static void clear_legacy_Mode(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 reg;
- u32 val;
- u32 dev = pDCTstat->dev_dct;
-
- /* Clear Legacy BIOS Mode bit */
- reg = 0x94;
- val = Get_NB32_DCT(dev, 0, reg);
- val &= ~(1<<LegacyBiosMode);
- Set_NB32_DCT(dev, 0, reg, val);
-
- val = Get_NB32_DCT(dev, 1, reg);
- val &= ~(1<<LegacyBiosMode);
- Set_NB32_DCT(dev, 1, reg, val);
-}
-
-static void mct_HTMemMapExt(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u32 Drambase, Dramlimit;
- u32 val;
- u32 reg;
- u32 dev;
- u32 devx;
- u32 dword;
- struct DCTStatStruc *pDCTstat;
-
- pDCTstat = pDCTstatA + 0;
- dev = pDCTstat->dev_map;
-
- /* Copy dram map from F1x40/44,F1x48/4c,
- to F1x120/124(Node0),F1x120/124(Node1),...*/
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
- devx = pDCTstat->dev_map;
-
- /* get base/limit from Node0 */
- reg = 0x40 + (Node << 3); /* Node0/Dram Base 0 */
- val = Get_NB32(dev, reg);
- Drambase = val >> (16 + 3);
-
- reg = 0x44 + (Node << 3); /* Node0/Dram Base 0 */
- val = Get_NB32(dev, reg);
- Dramlimit = val >> (16 + 3);
-
- /* set base/limit to F1x120/124 per Node */
- if (pDCTstat->NodePresent) {
- reg = 0x120; /* F1x120,DramBase[47:27] */
- val = Get_NB32(devx, reg);
- val &= 0xFFE00000;
- val |= Drambase;
- Set_NB32(devx, reg, val);
-
- reg = 0x124;
- val = Get_NB32(devx, reg);
- val &= 0xFFE00000;
- val |= Dramlimit;
- Set_NB32(devx, reg, val);
-
- if (pMCTstat->GStatus & (1 << GSB_HWHole)) {
- reg = 0xF0;
- val = Get_NB32(devx, reg);
- val |= (1 << DramMemHoistValid);
- val &= ~(0xFF << 24);
- dword = (pMCTstat->HoleBase >> (24 - 8)) & 0xFF;
- dword <<= 24;
- val |= dword;
- Set_NB32(devx, reg, val);
- }
-
- }
- }
-}
-
-static void SetCSTriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 dev = pDCTstat->dev_dct;
- u32 index_reg = 0x98;
- u16 word;
-
- if (is_fam15h()) {
- word = fam15h_cs_tristate_enable_code(pDCTstat, dct);
- } else {
- /* Tri-state unused chipselects when motherboard
- termination is available */
-
- /* FIXME: skip for Ax */
-
- word = pDCTstat->CSPresent;
- if (pDCTstat->Status & (1 << SB_Registered)) {
- word |= (word & 0x55) << 1;
- }
- word = (~word) & 0xff;
- }
-
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c);
- val &= ~0xff;
- val |= word;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c, val);
-}
-
-static void SetCKETriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 dev;
- u32 index_reg = 0x98;
- u16 word;
-
- /* Tri-state unused CKEs when motherboard termination is available */
-
- /* FIXME: skip for Ax */
-
- dev = pDCTstat->dev_dct;
- word = pDCTstat->CSPresent;
-
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c);
- val &= ~(0x3 << 12);
- if ((word & 0x55) == 0)
- val |= 1 << 12;
- if ((word & 0xaa) == 0)
- val |= 1 << 13;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c, val);
-}
-
-static void SetODTTriState(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 dev;
- u32 index_reg = 0x98;
- u8 cs;
- u8 odt;
-
- dev = pDCTstat->dev_dct;
-
- if (is_fam15h()) {
- odt = fam15h_odt_tristate_enable_code(pDCTstat, dct);
- } else {
- /* FIXME: skip for Ax */
-
- /* Tri-state unused ODTs when motherboard termination is available */
- odt = 0x0f; /* ODT tri-state setting */
-
- if (pDCTstat->Status & (1 <<SB_Registered)) {
- for (cs = 0; cs < 8; cs += 2) {
- if (pDCTstat->CSPresent & (1 << cs)) {
- odt &= ~(1 << (cs / 2));
- if (mctGet_NVbits(NV_4RANKType) != 0) { /* quad-rank capable platform */
- if (pDCTstat->CSPresent & (1 << (cs + 1)))
- odt &= ~(4 << (cs / 2));
- }
- }
- }
- } else { /* AM3 package */
- val = ~(pDCTstat->CSPresent);
- odt = val & 9; /* swap bits 1 and 2 */
- if (val & (1 << 1))
- odt |= 1 << 2;
- if (val & (1 << 2))
- odt |= 1 << 1;
- }
- }
-
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c);
- val &= ~(0xf << 8); /* ODTTri = odt */
- val |= (odt & 0xf) << 8;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c, val);
-}
-
-/* Family 15h */
-static void InitDDRPhy(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- uint8_t index;
- uint32_t dword;
- uint8_t ddr_voltage_index;
- uint8_t amd_voltage_level_index = 0;
- uint32_t index_reg = 0x98;
- uint32_t dev = pDCTstat->dev_dct;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- /* Find current DDR supply voltage for this DCT */
- ddr_voltage_index = dct_ddr_voltage_index(pDCTstat, dct);
-
- /* Fam15h BKDG v3.14 section 2.10.5.3
- * The remainder of the Phy Initialization algorithm picks up in phyAssistedMemFnceTraining
- */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000b, 0x80000000);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fe013, 0x00000118);
-
- /* Program desired VDDIO level */
- if (ddr_voltage_index & 0x4) {
- /* 1.25V */
- amd_voltage_level_index = 0x2;
- } else if (ddr_voltage_index & 0x2) {
- /* 1.35V */
- amd_voltage_level_index = 0x1;
- } else if (ddr_voltage_index & 0x1) {
- /* 1.50V */
- amd_voltage_level_index = 0x0;
- }
-
- /* D18F2x9C_x0D0F_0[F,8:0]1F_dct[1:0][RxVioLvl] */
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f001f | (index << 8));
- dword &= ~(0x3 << 3);
- dword |= (amd_voltage_level_index << 3);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f001f | (index << 8), dword);
- }
-
- /* D18F2x9C_x0D0F_[C,8,2][2:0]1F_dct[1:0][RxVioLvl] */
- for (index = 0; index < 0x3; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f201f | (index << 8));
- dword &= ~(0x3 << 3);
- dword |= (amd_voltage_level_index << 3);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f201f | (index << 8), dword);
- }
- for (index = 0; index < 0x2; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f801f | (index << 8));
- dword &= ~(0x3 << 3);
- dword |= (amd_voltage_level_index << 3);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f801f | (index << 8), dword);
- }
- for (index = 0; index < 0x1; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc01f | (index << 8));
- dword &= ~(0x3 << 3);
- dword |= (amd_voltage_level_index << 3);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc01f | (index << 8), dword);
- }
-
- /* D18F2x9C_x0D0F_4009_dct[1:0][CmpVioLvl, ComparatorAdjust] */
- /* NOTE: CmpVioLvl and ComparatorAdjust only take effect when set on DCT 0 */
- dword = Get_NB32_index_wait_DCT(dev, 0, index_reg, 0x0d0f4009);
- dword &= ~(0x0000c00c);
- dword |= (amd_voltage_level_index << 14);
- dword |= (amd_voltage_level_index << 2);
- Set_NB32_index_wait_DCT(dev, 0, index_reg, 0x0d0f4009, dword);
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-void InitPhyCompensation(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 i;
- u32 index_reg = 0x98;
- u32 dev = pDCTstat->dev_dct;
- u32 valx = 0;
- uint8_t index;
- uint32_t dword;
- const u8 *p;
-
- printk(BIOS_DEBUG, "%s: DCT %d: Start\n", __func__, dct);
-
- if (is_fam15h()) {
- /* Algorithm detailed in the Fam15h BKDG Rev. 3.14 section 2.10.5.3.4 */
- uint32_t tx_pre;
- uint32_t drive_strength;
-
- /* Program D18F2x9C_x0D0F_E003_dct[1:0][DisAutoComp] */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fe003);
- dword |= (0x1 << 14);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fe003, dword);
-
- /* Program D18F2x9C_x0D0F_E003_dct[1:0][DisablePredriverCal] */
- /* NOTE: DisablePredriverCal only takes effect when set on DCT 0 */
- dword = Get_NB32_index_wait_DCT(dev, 0, index_reg, 0x0d0fe003);
- dword |= (0x1 << 13);
- Set_NB32_index_wait_DCT(dev, 0, index_reg, 0x0d0fe003, dword);
-
- /* Determine TxPreP/TxPreN for data lanes (Stage 1) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000000);
- drive_strength = (dword >> 20) & 0x7; /* DqsDrvStren */
- tx_pre = fam15h_phy_predriver_calibration_code(pDCTstat, dct, drive_strength);
-
- /* Program TxPreP/TxPreN for data lanes (Stage 1) */
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0006 | (index << 8));
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0006 | (index << 8), dword);
- }
-
- /* Determine TxPreP/TxPreN for data lanes (Stage 2) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000000);
- drive_strength = (dword >> 16) & 0x7; /* DataDrvStren */
- tx_pre = fam15h_phy_predriver_calibration_code(pDCTstat, dct, drive_strength);
-
- /* Program TxPreP/TxPreN for data lanes (Stage 2) */
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f000a | (index << 8));
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f000a | (index << 8), dword);
- }
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0002 | (index << 8));
- dword &= ~(0xffff);
- dword |= (0x8000 | tx_pre);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0002 | (index << 8), dword);
- }
-
- /* Determine TxPreP/TxPreN for command/address lines (Stage 1) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000000);
- drive_strength = (dword >> 4) & 0x7; /* CsOdtDrvStren */
- tx_pre = fam15h_phy_predriver_cmd_addr_calibration_code(pDCTstat, dct, drive_strength);
-
- /* Program TxPreP/TxPreN for command/address lines (Stage 1) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8006);
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8006, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f800a);
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f800a, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8002);
- dword &= ~(0xffff);
- dword |= (0x8000 | tx_pre);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8002, dword);
-
- /* Determine TxPreP/TxPreN for command/address lines (Stage 2) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000000);
- drive_strength = (dword >> 8) & 0x7; /* AddrCmdDrvStren */
- tx_pre = fam15h_phy_predriver_cmd_addr_calibration_code(pDCTstat, dct, drive_strength);
-
- /* Program TxPreP/TxPreN for command/address lines (Stage 2) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8106);
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8106, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f810a);
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f810a, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc006);
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc006, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc00a);
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc00a, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc00e);
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc00e, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc012);
- dword &= ~(0xffff);
- dword |= tx_pre;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc012, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8102);
- dword &= ~(0xffff);
- dword |= (0x8000 | tx_pre);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8102, dword);
-
- /* Determine TxPreP/TxPreN for command/address lines (Stage 3) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000000);
- drive_strength = (dword >> 0) & 0x7; /* CkeDrvStren */
- tx_pre = fam15h_phy_predriver_cmd_addr_calibration_code(pDCTstat, dct, drive_strength);
-
- /* Program TxPreP/TxPreN for command/address lines (Stage 3) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc002);
- dword &= ~(0xffff);
- dword |= (0x8000 | tx_pre);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc002, dword);
-
- /* Determine TxPreP/TxPreN for clock lines */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000000);
- drive_strength = (dword >> 12) & 0x7; /* ClkDrvStren */
- tx_pre = fam15h_phy_predriver_clk_calibration_code(pDCTstat, dct, drive_strength);
-
- /* Program TxPreP/TxPreN for clock lines */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f2002);
- dword &= ~(0xffff);
- dword |= (0x8000 | tx_pre);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f2002, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f2102);
- dword &= ~(0xffff);
- dword |= (0x8000 | tx_pre);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f2102, dword);
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f2202);
- dword &= ~(0xffff);
- dword |= (0x8000 | tx_pre);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f2202, dword);
-
- if (!is_model10_1f()) {
- /* Be extra safe and wait for the predriver calibration
- * to be applied to the hardware. The BKDG does not
- * require this, but it does take some time for the
- * data to propagate, so it's probably a good idea.
- */
- uint8_t predriver_cal_pending = 1;
- printk(BIOS_DEBUG, "Waiting for predriver calibration to be applied...");
- while (predriver_cal_pending) {
- predriver_cal_pending = 0;
- for (index = 0; index < 0x9; index++) {
- if (Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0002 | (index << 8)) & 0x8000)
- predriver_cal_pending = 1;
- }
- }
- printk(BIOS_DEBUG, "done!\n");
- }
- } else {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00);
- dword = 0;
- for (i = 0; i < 6; i++) {
- switch (i) {
- case 0:
- case 4:
- p = Table_Comp_Rise_Slew_15x;
- valx = p[(dword >> 16) & 3];
- break;
- case 1:
- case 5:
- p = Table_Comp_Fall_Slew_15x;
- valx = p[(dword >> 16) & 3];
- break;
- case 2:
- p = Table_Comp_Rise_Slew_20x;
- valx = p[(dword >> 8) & 3];
- break;
- case 3:
- p = Table_Comp_Fall_Slew_20x;
- valx = p[(dword >> 8) & 3];
- break;
- }
- dword |= valx << (5 * i);
- }
-
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0a, dword);
- }
-
- printk(BIOS_DEBUG, "%s: DCT %d: Done\n", __func__, dct);
-}
-
-static void mct_EarlyArbEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- if (!is_fam15h()) {
- u32 reg;
- u32 val;
- u32 dev = pDCTstat->dev_dct;
-
- /* GhEnhancement #18429 modified by askar: For low NB CLK :
- * Memclk ratio, the DCT may need to arbitrate early to avoid
- * unnecessary bubbles.
- * bit 19 of F2x[1,0]78 Dram Control Register, set this bit only when
- * NB CLK : Memclk ratio is between 3:1 (inclusive) to 4:5 (inclusive)
- */
- reg = 0x78;
- val = Get_NB32_DCT(dev, dct, reg);
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_Cx | AMD_DR_Dx))
- val |= (1 << EarlyArbEn);
- else if (CheckNBCOFEarlyArbEn(pMCTstat, pDCTstat))
- val |= (1 << EarlyArbEn);
-
- Set_NB32_DCT(dev, dct, reg, val);
- }
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-static u8 CheckNBCOFEarlyArbEn(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 reg;
- u32 val;
- u32 tmp;
- u32 rem;
- u32 dev = pDCTstat->dev_dct;
- u32 hi, lo;
- u8 NbDid = 0;
-
- /* Check if NB COF >= 4*Memclk, if it is not, return a fatal error
- */
-
- /* 3*(Fn2xD4[NBFid]+4)/(2^NbDid)/(3+Fn2x94[MemClkFreq]) */
- _RDMSR(MSR_COFVID_STS, &lo, &hi);
- if (lo & (1 << 22))
- NbDid |= 1;
-
- reg = 0x94;
- val = Get_NB32_DCT(dev, 0, reg);
- if (!(val & (1 << MemClkFreqVal)))
- val = Get_NB32_DCT(dev, 1, reg); /* get the DCT1 value */
-
- val &= 0x07;
- val += 3;
- if (NbDid)
- val <<= 1;
- tmp = val;
-
- dev = pDCTstat->dev_nbmisc;
- reg = 0xD4;
- val = Get_NB32(dev, reg);
- val &= 0x1F;
- val += 3;
- val *= 3;
- val = val / tmp;
- rem = val % tmp;
- tmp >>= 1;
-
- /* Yes this could be nicer but this was how the asm was.... */
- if (val < 3) { /* NClk:MemClk < 3:1 */
- return 0;
- } else if (val > 4) { /* NClk:MemClk >= 5:1 */
- return 0;
- } else if ((val == 4) && (rem > tmp)) { /* NClk:MemClk > 4.5:1 */
- return 0;
- } else {
- return 1; /* 3:1 <= NClk:MemClk <= 4.5:1*/
- }
-}
-
-static void mct_ResetDataStruct_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- uint8_t Node;
- struct DCTStatStruc *pDCTstat;
-
- /* Initialize Data structures by clearing all entries to 0 */
- memset(pMCTstat, 0, sizeof(*pMCTstat));
-
- for (Node = 0; Node < 8; Node++) {
- pDCTstat = pDCTstatA + Node;
- memset(pDCTstat, 0, sizeof(*pDCTstat) - sizeof(pDCTstat->persistentData));
- }
-}
-
-static void mct_BeforeDramInit_Prod_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- mct_ProgramODT_D(pMCTstat, pDCTstat, dct);
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-static void mct_ProgramODT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 i;
- u32 dword;
- u32 dev = pDCTstat->dev_dct;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- if (is_fam15h()) {
- /* Obtain number of DIMMs on channel */
- uint8_t dimm_count = pDCTstat->MAdimms[dct];
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
- uint32_t odt_pattern_0;
- uint32_t odt_pattern_1;
- uint32_t odt_pattern_2;
- uint32_t odt_pattern_3;
- uint8_t write_odt_duration;
- uint8_t read_odt_duration;
- uint8_t write_odt_delay;
- uint8_t read_odt_delay;
-
- /* NOTE
- * Rank count per DIMM and DCT is encoded by pDCTstat->DimmRanks[(<dimm number> * 2) + dct]
- */
-
- /* Select appropriate ODT pattern for installed DIMMs
- * Refer to the Fam15h BKDG Rev. 3.14, page 149 onwards
- */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
- if (rank_count_dimm1 == 1) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00020000;
- } else if (rank_count_dimm1 == 2) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x08020000;
- } else if (rank_count_dimm1 == 4) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x020a0000;
- odt_pattern_3 = 0x080a0000;
- } else {
- /* Fallback */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x08020000;
- }
- } else {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4)) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x01010202;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x09030603;
- } else if ((rank_count_dimm0 < 4) && (rank_count_dimm1 == 4)) {
- odt_pattern_0 = 0x01010000;
- odt_pattern_1 = 0x01010a0a;
- odt_pattern_2 = 0x01090000;
- odt_pattern_3 = 0x01030e0b;
- } else if ((rank_count_dimm0 == 4) && (rank_count_dimm1 < 4)) {
- odt_pattern_0 = 0x00000202;
- odt_pattern_1 = 0x05050202;
- odt_pattern_2 = 0x00000206;
- odt_pattern_3 = 0x0d070203;
- } else if ((rank_count_dimm0 == 4) && (rank_count_dimm1 == 4)) {
- odt_pattern_0 = 0x05050a0a;
- odt_pattern_1 = 0x05050a0a;
- odt_pattern_2 = 0x050d0a0e;
- odt_pattern_3 = 0x05070a0b;
- } else {
- /* Fallback */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00000000;
- }
- }
- } else {
- /* FIXME
- * 3 DIMMs per channel UNIMPLEMENTED
- */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00000000;
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* TODO
- * Load reduced dimms UNIMPLEMENTED
- */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00000000;
- } else {
- if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
- if (rank_count_dimm1 == 1) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00020000;
- } else if (rank_count_dimm1 == 2) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x08020000;
- } else {
- /* Fallback */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x08020000;
- }
- } else {
- /* 2 DIMMs detected */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x01010202;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x09030603;
- }
- } else {
- /* FIXME
- * 3 DIMMs per channel UNIMPLEMENTED
- */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00000000;
- }
- }
-
- if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* TODO
- * Load reduced dimms UNIMPLEMENTED
- */
- write_odt_duration = 0x0;
- read_odt_duration = 0x0;
- write_odt_delay = 0x0;
- read_odt_delay = 0x0;
- } else {
- uint8_t tcl;
- uint8_t tcwl;
- tcl = Get_NB32_DCT(dev, dct, 0x200) & 0x1f;
- tcwl = Get_NB32_DCT(dev, dct, 0x20c) & 0x1f;
-
- write_odt_duration = 0x6;
- read_odt_duration = 0x6;
- write_odt_delay = 0x0;
- if (tcl > tcwl)
- read_odt_delay = tcl - tcwl;
- else
- read_odt_delay = 0x0;
- }
-
- /* Program ODT pattern */
- Set_NB32_DCT(dev, dct, 0x230, odt_pattern_1);
- Set_NB32_DCT(dev, dct, 0x234, odt_pattern_0);
- Set_NB32_DCT(dev, dct, 0x238, odt_pattern_3);
- Set_NB32_DCT(dev, dct, 0x23c, odt_pattern_2);
- dword = Get_NB32_DCT(dev, dct, 0x240);
- dword &= ~(0x7 << 12); /* WrOdtOnDuration = write_odt_duration */
- dword |= (write_odt_duration & 0x7) << 12;
- dword &= ~(0x7 << 8); /* WrOdtTrnOnDly = write_odt_delay */
- dword |= (write_odt_delay & 0x7) << 8;
- dword &= ~(0xf << 4); /* RdOdtOnDuration = read_odt_duration */
- dword |= (read_odt_duration & 0xf) << 4;
- dword &= ~(0xf); /* RdOdtTrnOnDly = read_odt_delay */
- dword |= (read_odt_delay & 0xf);
- Set_NB32_DCT(dev, dct, 0x240, dword);
-
- printk(BIOS_SPEW, "Programmed DCT %d ODT pattern %08x %08x %08x %08x\n", dct, odt_pattern_0, odt_pattern_1, odt_pattern_2, odt_pattern_3);
- } else if (pDCTstat->LogicalCPUID & AMD_DR_Dx) {
- if (pDCTstat->Speed == 3)
- dword = 0x00000800;
- else
- dword = 0x00000000;
- for (i = 0; i < 2; i++) {
- Set_NB32_DCT(dev, i, 0x98, 0x0D000030);
- Set_NB32_DCT(dev, i, 0x9C, dword);
- Set_NB32_DCT(dev, i, 0x98, 0x4D040F30);
-
- /* Obtain number of DIMMs on channel */
- uint8_t dimm_count = pDCTstat->MAdimms[i];
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
- uint32_t odt_pattern_0;
- uint32_t odt_pattern_1;
- uint32_t odt_pattern_2;
- uint32_t odt_pattern_3;
-
- /* Select appropriate ODT pattern for installed DIMMs
- * Refer to the Fam10h BKDG Rev. 3.62, page 120 onwards
- */
- if (pDCTstat->Status & (1 << SB_Registered)) {
- if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + i];
- if (rank_count_dimm1 == 1) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00020000;
- } else if (rank_count_dimm1 == 2) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x02080000;
- } else if (rank_count_dimm1 == 4) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x020a0000;
- odt_pattern_3 = 0x080a0000;
- } else {
- /* Fallback */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00000000;
- }
- } else {
- /* 2 DIMMs detected */
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + i];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + i];
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4)) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x01010202;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x09030603;
- } else if ((rank_count_dimm0 < 4) && (rank_count_dimm1 == 4)) {
- odt_pattern_0 = 0x01010000;
- odt_pattern_1 = 0x01010a0a;
- odt_pattern_2 = 0x01090000;
- odt_pattern_3 = 0x01030e0b;
- } else if ((rank_count_dimm0 == 4) && (rank_count_dimm1 < 4)) {
- odt_pattern_0 = 0x00000202;
- odt_pattern_1 = 0x05050202;
- odt_pattern_2 = 0x00000206;
- odt_pattern_3 = 0x0d070203;
- } else if ((rank_count_dimm0 == 4) && (rank_count_dimm1 == 4)) {
- odt_pattern_0 = 0x05050a0a;
- odt_pattern_1 = 0x05050a0a;
- odt_pattern_2 = 0x050d0a0e;
- odt_pattern_3 = 0x05070a0b;
- } else {
- /* Fallback */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00000000;
- }
- }
- } else {
- /* FIXME
- * 3 DIMMs per channel UNIMPLEMENTED
- */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00000000;
- }
- } else {
- if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + i];
- if (rank_count_dimm1 == 1) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00020000;
- } else if (rank_count_dimm1 == 2) {
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x02080000;
- } else {
- /* Fallback */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00000000;
- }
- } else {
- /* 2 DIMMs detected */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x01010202;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x09030603;
- }
- } else {
- /* FIXME
- * 3 DIMMs per channel UNIMPLEMENTED
- */
- odt_pattern_0 = 0x00000000;
- odt_pattern_1 = 0x00000000;
- odt_pattern_2 = 0x00000000;
- odt_pattern_3 = 0x00000000;
- }
- }
-
- /* Program ODT pattern */
- Set_NB32_index_wait_DCT(dev, i, 0xf0, 0x180, odt_pattern_1);
- Set_NB32_index_wait_DCT(dev, i, 0xf0, 0x181, odt_pattern_0);
- Set_NB32_index_wait_DCT(dev, i, 0xf0, 0x182, odt_pattern_3);
- Set_NB32_index_wait_DCT(dev, i, 0xf0, 0x183, odt_pattern_2);
-
- printk(BIOS_SPEW, "Programmed ODT pattern %08x %08x %08x %08x\n", odt_pattern_0, odt_pattern_1, odt_pattern_2, odt_pattern_3);
- }
- }
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-static void mct_EnDllShutdownSR(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 dev = pDCTstat->dev_dct, val;
-
- /* Write 0000_07D0h to register F2x[1, 0]98_x4D0FE006 */
- if (pDCTstat->LogicalCPUID & (AMD_DR_DAC2_OR_C3)) {
- Set_NB32_DCT(dev, dct, 0x9C, 0x1C);
- Set_NB32_DCT(dev, dct, 0x98, 0x4D0FE006);
- Set_NB32_DCT(dev, dct, 0x9C, 0x13D);
- Set_NB32_DCT(dev, dct, 0x98, 0x4D0FE007);
-
- val = Get_NB32_DCT(dev, dct, 0x90);
- val &= ~(1 << 27/* DisDllShutdownSR */);
- Set_NB32_DCT(dev, dct, 0x90, val);
- }
-}
-
-static u32 mct_DisDllShutdownSR(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 DramConfigLo, u8 dct)
-{
- u32 dev = pDCTstat->dev_dct;
-
- /* Write 0000_07D0h to register F2x[1, 0]98_x4D0FE006 */
- if (pDCTstat->LogicalCPUID & (AMD_DR_DAC2_OR_C3)) {
- Set_NB32_DCT(dev, dct, 0x9C, 0x7D0);
- Set_NB32_DCT(dev, dct, 0x98, 0x4D0FE006);
- Set_NB32_DCT(dev, dct, 0x9C, 0x190);
- Set_NB32_DCT(dev, dct, 0x98, 0x4D0FE007);
-
- DramConfigLo |= /* DisDllShutdownSR */ 1 << 27;
- }
-
- return DramConfigLo;
-}
-
-void mct_SetClToNB_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 lo, hi;
- u32 msr;
-
- /* FIXME: Maybe check the CPUID? - not for now. */
- /* pDCTstat->LogicalCPUID; */
-
- msr = BU_CFG2_MSR;
- _RDMSR(msr, &lo, &hi);
- lo |= 1 << ClLinesToNbDis;
- _WRMSR(msr, lo, hi);
-}
-
-void mct_ClrClToNB_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
-
- u32 lo, hi;
- u32 msr;
-
- /* FIXME: Maybe check the CPUID? - not for now. */
- /* pDCTstat->LogicalCPUID; */
-
- msr = BU_CFG2_MSR;
- _RDMSR(msr, &lo, &hi);
- if (!pDCTstat->ClToNB_flag)
- lo &= ~(1<<ClLinesToNbDis);
- _WRMSR(msr, lo, hi);
-
-}
-
-void mct_SetWbEnhWsbDis_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 lo, hi;
- u32 msr;
-
- /* FIXME: Maybe check the CPUID? - not for now. */
- /* pDCTstat->LogicalCPUID; */
-
- msr = BU_CFG_MSR;
- _RDMSR(msr, &lo, &hi);
- hi |= (1 << WbEnhWsbDis_D);
- _WRMSR(msr, lo, hi);
-}
-
-void mct_ClrWbEnhWsbDis_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 lo, hi;
- u32 msr;
-
- /* FIXME: Maybe check the CPUID? - not for now. */
- /* pDCTstat->LogicalCPUID; */
-
- msr = BU_CFG_MSR;
- _RDMSR(msr, &lo, &hi);
- hi &= ~(1 << WbEnhWsbDis_D);
- _WRMSR(msr, lo, hi);
-}
-
-void ProgDramMRSReg_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 DramMRS, dword;
- u8 byte;
-
- DramMRS = 0;
-
- /* Set chip select CKE control mode */
- if (mctGet_NVbits(NV_CKE_CTL)) {
- if (pDCTstat->CSPresent == 3) {
- u16 word;
- word = pDCTstat->DIMMSPDCSE;
- if (dct == 0)
- word &= 0b01010100;
- else
- word &= 0b10101000;
- if (word == 0)
- DramMRS |= 1 << 23;
- }
- }
-
- if (is_fam15h()) {
- DramMRS |= (0x1 << 23); /* PchgPDModeSel = 1 */
- } else {
- /*
- DRAM MRS Register
- DrvImpCtrl: drive impedance control.01b(34 ohm driver; Ron34 = Rzq/7)
- */
- DramMRS |= 1 << 2;
- /* Dram nominal termination: */
- byte = pDCTstat->MAdimms[dct];
- if (!(pDCTstat->Status & (1 << SB_Registered))) {
- DramMRS |= 1 << 7; /* 60 ohms */
- if (byte & 2) {
- if (pDCTstat->Speed < 6)
- DramMRS |= 1 << 8; /* 40 ohms */
- else
- DramMRS |= 1 << 9; /* 30 ohms */
- }
- }
- /* Dram dynamic termination: Disable(1DIMM), 120ohm(>=2DIMM) */
- if (!(pDCTstat->Status & (1 << SB_Registered))) {
- if (byte >= 2) {
- if (pDCTstat->Speed == 7)
- DramMRS |= 1 << 10;
- else
- DramMRS |= 1 << 11;
- }
- } else {
- DramMRS |= mct_DramTermDyn_RDimm(pMCTstat, pDCTstat, byte);
- }
-
- /* Qoff = 0, output buffers enabled */
- /* Tcwl */
- DramMRS |= (pDCTstat->Speed - 4) << 20;
- /* ASR = 1, auto self refresh */
- /* SRT = 0 */
- DramMRS |= 1 << 18;
- }
-
- /* burst length control */
- if (pDCTstat->Status & (1 << SB_128bitmode))
- DramMRS |= 1 << 1;
-
- dword = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x84);
- if (is_fam15h()) {
- dword &= ~0x00800003;
- dword |= DramMRS;
- } else {
- dword &= ~0x00fc2f8f;
- dword |= DramMRS;
- }
- Set_NB32_DCT(pDCTstat->dev_dct, dct, 0x84, dword);
-}
-
-void mct_SetDramConfigHi_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 dct, u32 DramConfigHi)
-{
- /* Bug#15114: Comp. update interrupted by Freq. change can cause
- * subsequent update to be invalid during any MemClk frequency change:
- * Solution: From the bug report:
- * 1. A software-initiated frequency change should be wrapped into the
- * following sequence :
- * a) Disable Compensation (F2[1, 0]9C_x08[30])
- * b) Reset the Begin Compensation bit (D3CMP->COMP_CONFIG[0]) in
- * all the compensation engines
- * c) Do frequency change
- * d) Enable Compensation (F2[1, 0]9C_x08[30])
- * 2. A software-initiated Disable Compensation should always be
- * followed by step b) of the above steps.
- * Silicon Status: Fixed In Rev B0
- *
- * Errata#177: DRAM Phy Automatic Compensation Updates May Be Invalid
- * Solution: BIOS should disable the phy automatic compensation prior
- * to initiating a memory clock frequency change as follows:
- * 1. Disable PhyAutoComp by writing 1'b1 to F2x[1, 0]9C_x08[30]
- * 2. Reset the Begin Compensation bits by writing 32'h0 to
- * F2x[1, 0]9C_x4D004F00
- * 3. Perform frequency change
- * 4. Enable PhyAutoComp by writing 1'b0 to F2x[1, 0]9C_08[30]
- * In addition, any time software disables the automatic phy
- * compensation it should reset the begin compensation bit per step 2.
- * Silicon Status: Fixed in DR-B0
- */
-
- u32 dev = pDCTstat->dev_dct;
- u32 index_reg = 0x98;
- u32 index;
-
- uint32_t dword;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- if (is_fam15h()) {
- /* Initial setup for frequency change
- * 9C_x0000_0004 must be configured before MemClkFreqVal is set
- */
-
- /* Program D18F2x9C_x0D0F_E006_dct[1:0][PllLockTime] = 0x190 */
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, dct, index_reg, 0x0d0fe006);
- dword &= ~(0x0000ffff);
- dword |= 0x00000190;
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, dct, index_reg, 0x0d0fe006, dword);
-
- dword = Get_NB32_DCT(dev, dct, 0x94);
- dword &= ~(1 << MemClkFreqVal);
- Set_NB32_DCT(dev, dct, 0x94, dword);
-
- dword = DramConfigHi;
- dword &= ~(1 << MemClkFreqVal);
- Set_NB32_DCT(dev, dct, 0x94, dword);
-
- mctGet_PS_Cfg_D(pMCTstat, pDCTstat, dct);
- set_2t_configuration(pMCTstat, pDCTstat, dct);
- mct_BeforePlatformSpec(pMCTstat, pDCTstat, dct);
- mct_PlatformSpec(pMCTstat, pDCTstat, dct);
- } else {
- index = 0x08;
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, index);
- if (!(dword & (1 << DisAutoComp)))
- Set_NB32_index_wait_DCT(dev, dct, index_reg, index, dword | (1 << DisAutoComp));
-
- mct_Wait(100);
- }
-
- printk(BIOS_DEBUG, "mct_SetDramConfigHi_D: DramConfigHi: %08x\n", DramConfigHi);
-
- /* Program the DRAM Configuration High register */
- Set_NB32_DCT(dev, dct, 0x94, DramConfigHi);
-
- if (is_fam15h()) {
- /* Wait until F2x[1, 0]94[FreqChgInProg]=0. */
- do {
- printk(BIOS_DEBUG, "*");
- dword = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94);
- } while (dword & (1 << FreqChgInProg));
- printk(BIOS_DEBUG, "\n");
-
- /* Program D18F2x9C_x0D0F_E006_dct[1:0][PllLockTime] = 0xf */
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, dct, index_reg, 0x0d0fe006);
- dword &= ~(0x0000ffff);
- dword |= 0x0000000f;
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, dct, index_reg, 0x0d0fe006, dword);
- }
-
- /* Clear MC4 error status */
- pci_write_config32(pDCTstat->dev_nbmisc, 0x48, 0x0);
- pci_write_config32(pDCTstat->dev_nbmisc, 0x4c, 0x0);
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-static void mct_BeforeDQSTrain_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- if (!is_fam15h()) {
- u8 Node;
- struct DCTStatStruc *pDCTstat;
-
- /* Errata 178
- *
- * Bug#15115: Uncertainty In The Sync Chain Leads To Setup Violations
- * In TX FIFO
- * Solution: BIOS should program DRAM Control Register[RdPtrInit] =
- * 5h, (F2x[1, 0]78[3:0] = 5h).
- * Silicon Status: Fixed In Rev B0
- *
- * Bug#15880: Determine validity of reset settings for DDR PHY timing.
- * Solution: At least, set WrDqs fine delay to be 0 for DDR3 training.
- */
- for (Node = 0; Node < 8; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- mct_BeforeDQSTrainSamp(pDCTstat); /* only Bx */
- mct_ResetDLL_D(pMCTstat, pDCTstat, 0);
- mct_ResetDLL_D(pMCTstat, pDCTstat, 1);
- }
- }
- }
-}
-
-/* Erratum 350 */
-static void mct_ResetDLL_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 Receiver;
- u32 dev = pDCTstat->dev_dct;
- u32 addr;
- u32 lo, hi;
- u8 wrap32dis = 0;
- u8 valid = 0;
-
- /* Skip reset DLL for B3 */
- if (pDCTstat->LogicalCPUID & AMD_DR_B3) {
- return;
- }
-
- /* Skip reset DLL for Family 15h */
- if (is_fam15h()) {
- return;
- }
-
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- if (lo & (1<<17)) { /* save the old value */
- wrap32dis = 1;
- }
- lo |= (1<<17); /* HWCR.wrap32dis */
- /* Setting wrap32dis allows 64-bit memory references in 32bit mode */
- _WRMSR(addr, lo, hi);
-
- pDCTstat->Channel = dct;
- Receiver = mct_InitReceiver_D(pDCTstat, dct);
- /* there are four receiver pairs, loosely associated with chipselects.*/
- for (; Receiver < 8; Receiver += 2) {
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, Receiver)) {
- addr = mct_GetRcvrSysAddr_D(pMCTstat, pDCTstat, dct, Receiver, &valid);
- if (valid) {
- mct_Read1LTestPattern_D(pMCTstat, pDCTstat, addr); /* cache fills */
-
- /* Write 0000_8000h to register F2x[1,0]9C_xD080F0C */
- Set_NB32_index_wait_DCT(dev, dct, 0x98, 0xD080F0C, 0x00008000);
- mct_Wait(80); /* wait >= 300ns */
-
- /* Write 0000_0000h to register F2x[1,0]9C_xD080F0C */
- Set_NB32_index_wait_DCT(dev, dct, 0x98, 0xD080F0C, 0x00000000);
- mct_Wait(800); /* wait >= 2us */
- break;
- }
- }
- }
-
- if (!wrap32dis) {
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(addr, lo, hi);
- }
-}
-
-void mct_EnableDatIntlv_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 val;
-
- /* Enable F2x110[DctDatIntlv] */
- /* Call back not required mctHookBeforeDatIntlv_D() */
- /* FIXME Skip for Ax */
- if (!pDCTstat->GangedMode) {
- val = Get_NB32(dev, 0x110);
- val |= 1 << 5; /* DctDatIntlv */
- Set_NB32(dev, 0x110, val);
-
- /* FIXME Skip for Cx */
- dev = pDCTstat->dev_nbmisc;
- val = Get_NB32(dev, 0x8C); /* NB Configuration Hi */
- val |= 1 << (36-32); /* DisDatMask */
- Set_NB32(dev, 0x8C, val);
- }
-}
-
-void SetDllSpeedUp_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- if (!is_fam15h()) {
- u32 val;
- u32 dev = pDCTstat->dev_dct;
-
- if (pDCTstat->Speed >= mhz_to_memclk_config(800)) { /* DDR1600 and above */
- /* Set bit13 PowerDown to register F2x[1, 0]98_x0D080F10 */
- Set_NB32_DCT(dev, dct, 0x98, 0x0D080F10);
- val = Get_NB32_DCT(dev, dct, 0x9C);
- val |= 1 < 13;
- Set_NB32_DCT(dev, dct, 0x9C, val);
- Set_NB32_DCT(dev, dct, 0x98, 0x4D080F10);
-
- /* Set bit13 PowerDown to register F2x[1, 0]98_x0D080F11 */
- Set_NB32_DCT(dev, dct, 0x98, 0x0D080F11);
- val = Get_NB32_DCT(dev, dct, 0x9C);
- val |= 1 < 13;
- Set_NB32_DCT(dev, dct, 0x9C, val);
- Set_NB32_DCT(dev, dct, 0x98, 0x4D080F11);
-
- /* Set bit13 PowerDown to register F2x[1, 0]98_x0D088F30 */
- Set_NB32_DCT(dev, dct, 0x98, 0x0D088F30);
- val = Get_NB32_DCT(dev, dct, 0x9C);
- val |= 1 < 13;
- Set_NB32_DCT(dev, dct, 0x9C, val);
- Set_NB32_DCT(dev, dct, 0x98, 0x4D088F30);
-
- /* Set bit13 PowerDown to register F2x[1, 0]98_x0D08CF30 */
- Set_NB32_DCT(dev, dct, 0x98, 0x0D08CF30);
- val = Get_NB32_DCT(dev, dct, 0x9C);
- val |= 1 < 13;
- Set_NB32_DCT(dev, dct, 0x9C, val);
- Set_NB32_DCT(dev, dct, 0x98, 0x4D08CF30);
- }
- }
-}
-
-static void SyncSetting(struct DCTStatStruc *pDCTstat)
-{
- /* set F2x78[ChSetupSync] when F2x[1, 0]9C_x04[AddrCmdSetup, CsOdtSetup,
- * CkeSetup] setups for one DCT are all 0s and at least one of the setups,
- * F2x[1, 0]9C_x04[AddrCmdSetup, CsOdtSetup, CkeSetup], of the other
- * controller is 1
- */
- u32 cha, chb;
- u32 dev = pDCTstat->dev_dct;
- u32 val;
-
- cha = pDCTstat->CH_ADDR_TMG[0] & 0x0202020;
- chb = pDCTstat->CH_ADDR_TMG[1] & 0x0202020;
-
- if ((cha != chb) && ((cha == 0) || (chb == 0))) {
- val = Get_NB32(dev, 0x78);
- val |= 1 << ChSetupSync;
- Set_NB32(dev, 0x78, val);
- }
-}
-
-static void AfterDramInit_D(struct DCTStatStruc *pDCTstat, u8 dct) {
-
- u32 val;
- u32 dev = pDCTstat->dev_dct;
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_B2 | AMD_DR_B3)) {
- mct_Wait(10000); /* Wait 50 us*/
- val = Get_NB32(dev, 0x110);
- if (!(val & (1 << DramEnabled))) {
- /* If 50 us expires while DramEnable =0 then do the following */
- val = Get_NB32_DCT(dev, dct, 0x90);
- val &= ~(1 << Width128); /* Program Width128 = 0 */
- Set_NB32_DCT(dev, dct, 0x90, val);
-
- val = Get_NB32_index_wait_DCT(dev, dct, 0x98, 0x05); /* Perform dummy CSR read to F2x09C_x05 */
-
- if (pDCTstat->GangedMode) {
- val = Get_NB32_DCT(dev, dct, 0x90);
- val |= 1 << Width128; /* Program Width128 = 0 */
- Set_NB32_DCT(dev, dct, 0x90, val);
- }
- }
- }
-}
-
-/* ==========================================================
- * 6-bit Bank Addressing Table
- * RR = rows-13 binary
- * B = Banks-2 binary
- * CCC = Columns-9 binary
- * ==========================================================
- * DCT CCCBRR Rows Banks Columns 64-bit CS Size
- * Encoding
- * 0000 000000 13 2 9 128MB
- * 0001 001000 13 2 10 256MB
- * 0010 001001 14 2 10 512MB
- * 0011 010000 13 2 11 512MB
- * 0100 001100 13 3 10 512MB
- * 0101 001101 14 3 10 1GB
- * 0110 010001 14 2 11 1GB
- * 0111 001110 15 3 10 2GB
- * 1000 010101 14 3 11 2GB
- * 1001 010110 15 3 11 4GB
- * 1010 001111 16 3 10 4GB
- * 1011 010111 16 3 11 8GB
- */
-uint8_t crcCheck(struct DCTStatStruc *pDCTstat, uint8_t dimm)
-{
- u16 crc_calc = spd_ddr3_calc_crc(pDCTstat->spd_data.spd_bytes[dimm],
- sizeof(pDCTstat->spd_data.spd_bytes[dimm]));
- u16 checksum_spd = pDCTstat->spd_data.spd_bytes[dimm][SPD_byte_127] << 8
- | pDCTstat->spd_data.spd_bytes[dimm][SPD_byte_126];
-
- return crc_calc == checksum_spd;
-}
-
-int32_t abs(int32_t val)
-{
- if (val < 0)
- return -val;
- return val;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mct_d.h b/src/northbridge/amd/amdmct/mct_ddr3/mct_d.h
deleted file mode 100644
index 952a66f71a..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mct_d.h
+++ /dev/null
@@ -1,1165 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015-2017 Raptor Engineering, LLC
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/*
- * Description: Include file for all generic DDR 3 MCT files.
- */
-#ifndef MCT_D_H
-#define MCT_D_H
-
-#define DQS_TRAIN_DEBUG 0
-
-#include <stdint.h>
-#include <northbridge/amd/amdfam10/raminit.h>
-
-/*===========================================================================
- CPU - K8/FAM10
-===========================================================================*/
-#define PT_L1 0 /* CPU Package Type */
-#define PT_M2 1
-#define PT_S1 2
-#define PT_GR 3
-#define PT_AS 4
-#define PT_C3 5
-#define PT_FM2 6
-
-#define J_MIN 0 /* j loop constraint. 1 = CL 2.0 T*/
-#define J_MAX 5 /* j loop constraint. 5 = CL 7.0 T*/
-#define K_MIN 1 /* k loop constraint. 1 = 200 MHz*/
-#define K_MAX 5 /* k loop constraint. 5 = 533 MHz*/
-#define CL_DEF 2 /* Default value for failsafe operation. 2 = CL 4.0 T*/
-#define T_DEF 1 /* Default value for failsafe operation. 1 = 5ns (cycle time)*/
-
-#define BSCRate 1 /* reg bit field = rate of dram scrubber for ecc*/
- /* memory initialization (ecc and check-bits).*/
- /* 1 = 40 ns/64 bytes.*/
-#define FirstPass 1 /* First pass through RcvEn training*/
-#define SecondPass 2 /* Second pass through Rcven training*/
-
-#define RCVREN_MARGIN 6 /* number of DLL taps to delay beyond first passing position*/
-#define MAXASYNCLATCTL_2 2 /* Max Async Latency Control value*/
-#define MAXASYNCLATCTL_3 3 /* Max Async Latency Control value*/
-
-#define DQS_FAIL 1
-#define DQS_PASS 0
-#define DQS_WRITEDIR 1
-#define DQS_READDIR 0
-#define MIN_DQS_WNDW 3
-#define secPassOffset 6
-#define Pass1MemClkDly 0x20 /* Add 1/2 Memlock delay */
-#define MAX_RD_LAT 0x3FF
-#define MIN_FENCE 14
-#define MAX_FENCE 20
-#define MIN_DQS_WR_FENCE 14
-#define MAX_DQS_WR_FENCE 20
-#define FenceTrnFinDlySeed 19
-#define EarlyArbEn 19
-
-#define PA_HOST(Node) ((((0x18+Node) << 3)+0) << 12) /* Node 0 Host Bus function PCI Address bits [15:0]*/
-#define PA_MAP(Node) ((((0x18+Node) << 3)+1) << 12) /* Node 0 MAP function PCI Address bits [15:0]*/
-#define PA_DCT(Node) ((((0x18+Node) << 3)+2) << 12) /* Node 0 DCT function PCI Address bits [15:0]*/
-/* #define PA_EXT_DCT (((00 << 3)+4) << 8) */ /*Node 0 DCT extended configuration registers*/
-/* #define PA_DCTADDL (((00 << 3)+2) << 8) */ /*Node x DCT function, Additional Registers PCI Address bits [15:0]*/
-/* #define PA_EXT_DCTADDL (((00 << 3)+5) << 8) */ /*Node x DCT function, Additional Registers PCI Address bits [15:0]*/
-
-#define PA_NBMISC(Node) ((((0x18+Node) << 3)+3) << 12) /*Node 0 Misc PCI Address bits [15:0]*/
-#define PA_LINK(Node) ((((0x18+Node) << 3)+4) << 12) /*Node 0 Link Control bits [15:0]*/
-#define PA_NBCTL(Node) ((((0x18+Node) << 3)+5) << 12) /*Node 0 NB Control PCI Address bits [15:0]*/
-/* #define PA_NBDEVOP (((00 << 3)+3) << 8) */ /*Node 0 Misc PCI Address bits [15:0]*/
-
-#define DCC_EN 1 /* X:2:0x94[19]*/
-#define ILD_Lmt 3 /* X:2:0x94[18:16]*/
-
-#define EncodedTSPD 0x00191709 /* encodes which SPD byte to get T from*/
- /* versus CL X, CL X-.5, and CL X-1*/
-
-#define Bias_TrpT 5 /* bias to convert bus clocks to bit field value*/
-#define Bias_TrrdT 4
-#define Bias_TrcdT 5
-#define Bias_TrasT 15
-#define Bias_TrcT 11
-#define Bias_TrtpT 4
-#define Bias_TwrT 4
-#define Bias_TwtrT 4
-#define Bias_TfawT 14
-
-#define Min_TrpT 5 /* min programmable value in busclocks */
-#define Max_TrpT 12 /* max programmable value in busclocks */
-#define Min_TrrdT 4
-#define Max_TrrdT 7
-#define Min_TrcdT 5
-#define Max_TrcdT 12
-#define Min_TrasT 15
-#define Max_TrasT 30
-#define Min_TrcT 11
-#define Max_TrcT 42
-#define Min_TrtpT 4
-#define Max_TrtpT 7
-#define Min_TwrT 5
-#define Max_TwrT 12
-#define Min_TwtrT 4
-#define Max_TwtrT 7
-#define Min_TfawT 16
-#define Max_TfawT 32
-
-/*common register bit names*/
-#define DramHoleValid 0 /* func 1, offset F0h, bit 0*/
-#define DramMemHoistValid 1 /* func 1, offset F0h, bit 1*/
-#define CSEnable 0 /* func 2, offset 40h-5C, bit 0*/
-#define Spare 1 /* func 2, offset 40h-5C, bit 1*/
-#define TestFail 2 /* func 2, offset 40h-5C, bit 2*/
-#define DqsRcvEnTrain 18 /* func 2, offset 78h, bit 18*/
-#define EnDramInit 31 /* func 2, offset 7Ch, bit 31*/
-#define PchgPDModeSel 23 /* func 2, offset 84h, bit 23 */
-#define DisAutoRefresh 18 /* func 2, offset 8Ch, bit 18*/
-#define InitDram 0 /* func 2, offset 90h, bit 0*/
-#define BurstLength32 10 /* func 2, offset 90h, bit 10*/
-#define Width128 11 /* func 2, offset 90h, bit 11*/
-#define X4Dimm 12 /* func 2, offset 90h, bit 12*/
-#define UnBuffDimm 16 /* func 2, offset 90h, bit 16*/
-#define DimmEcEn 19 /* func 2, offset 90h, bit 19*/
-#define MemClkFreqVal ((is_fam15h())?7:3) /* func 2, offset 94h, bit 3 or 7*/
-#define RDqsEn 12 /* func 2, offset 94h, bit 12*/
-#define DisDramInterface 14 /* func 2, offset 94h, bit 14*/
-#define PowerDownEn 15 /* func 2, offset 94h, bit 15*/
-#define DctAccessWrite 30 /* func 2, offset 98h, bit 30*/
-#define DctAccessDone 31 /* func 2, offset 98h, bit 31*/
-#define MemClrStatus 0 /* func 2, offset A0h, bit 0*/
-#define PwrSavingsEn 10 /* func 2, offset A0h, bit 10*/
-#define Mod64BitMux 4 /* func 2, offset A0h, bit 4*/
-#define DisableJitter 1 /* func 2, offset A0h, bit 1*/
-#define MemClrDis 1 /* func 3, offset F8h, FNC 4, bit 1*/
-#define SyncOnUcEccEn 2 /* func 3, offset 44h, bit 2*/
-#define Dr_MemClrStatus 10 /* func 3, offset 110h, bit 10*/
-#define MemClrBusy 9 /* func 3, offset 110h, bit 9*/
-#define DctGangEn 4 /* func 3, offset 110h, bit 4*/
-#define MemClrInit 3 /* func 3, offset 110h, bit 3*/
-#define SendZQCmd 29 /* func 2, offset 7Ch, bit 29 */
-#define AssertCke 28 /* func 2, offset 7Ch, bit 28*/
-#define DeassertMemRstX 27 /* func 2, offset 7Ch, bit 27*/
-#define SendMrsCmd 26 /* func 2, offset 7Ch, bit 26*/
-#define SendAutoRefresh 25 /* func 2, offset 7Ch, bit 25*/
-#define SendPchgAll 24 /* func 2, offset 7Ch, bit 24*/
-#define DisDqsBar 6 /* func 2, offset 90h, bit 6*/
-#define DramEnabled 8 /* func 2, offset 110h, bit 8*/
-#define LegacyBiosMode 9 /* func 2, offset 94h, bit 9*/
-#define PrefDramTrainMode 28 /* func 2, offset 11Ch, bit 28*/
-#define FlushWr 30 /* func 2, offset 11Ch, bit 30*/
-#define DisAutoComp 30 /* func 2, offset 9Ch, Index 8, bit 30*/
-#define DqsRcvTrEn 13 /* func 2, offset 9Ch, Index 8, bit 13*/
-#define ForceAutoPchg 23 /* func 2, offset 90h, bit 23*/
-#define ClLinesToNbDis 15 /* Bu_CFG2, bit 15*/
-#define WbEnhWsbDis_D (48-32)
-#define PhyFenceTrEn 3 /* func 2, offset 9Ch, Index 8, bit 3 */
-#define ParEn 8 /* func 2, offset 90h, bit 8 */
-#define DcqArbBypassEn 19 /* func 2, offset 94h, bit 19 */
-#define ActiveCmdAtRst 1 /* func 2, offset A8H, bit 1 */
-#define FlushWrOnStpGnt 29 /* func 2, offset 11Ch, bit 29 */
-#define BankSwizzleMode 22 /* func 2, offset 94h, bit 22 */
-#define ChSetupSync 15 /* func 2, offset 78h, bit 15 */
-
-#define Ddr3Mode 8 /* func 2, offset 94h, bit 8 */
-#define EnterSelfRef 17 /* func 2, offset 90h, bit 17 */
-#define onDimmMirror 3 /* func 2, offset 5C:40h, bit 3 */
-#define OdtSwizzle 6 /* func 2, offset A8h, bit 6 */
-#define FreqChgInProg 21 /* func 2, offset 94h, bit 21 */
-#define ExitSelfRef 1 /* func 2, offset 90h, bit 1 */
-
-#define SubMemclkRegDly 5 /* func 2, offset A8h, bit 5 */
-#define Ddr3FourSocketCh 2 /* func 2, offset A8h, bit 2 */
-#define SendControlWord 30 /* func 2, offset 7Ch, bit 30 */
-
-#define NB_GfxNbPstateDis 62 /* MSRC001_001F Northbridge Configuration Register (NB_CFG) bit 62 GfxNbPstateDis disable northbridge p-state transitions */
-/*=============================================================================
- SW Initialization
-============================================================================*/
-#define DLL_Enable 1
-#define OCD_Default 2
-#define OCD_Exit 3
-
-/*=============================================================================
- Jedec DDR II
-=============================================================================*/
-#define SPD_ByteUse 0
-#define SPD_TYPE 2 /*SPD byte read location*/
- #define JED_DDRSDRAM 0x07 /*Jedec defined bit field*/
- #define JED_DDR2SDRAM 0x08 /*Jedec defined bit field*/
- #define JED_DDR3SDRAM 0x0B /* Jedec defined bit field*/
-
-#define SPD_DIMMTYPE 3
-#define SPD_ATTRIB 21
- #define JED_DIFCKMSK 0x20 /*Differential Clock Input*/
- #define JED_REGADCMSK 0x11 /*Registered Address/Control*/
- #define JED_PROBEMSK 0x40 /*Analysis Probe installed*/
- #define JED_RDIMM 0x1 /* RDIMM */
- #define JED_MiniRDIMM 0x5 /* Mini-RDIMM */
- #define JED_LRDIMM 0xb /* Load-reduced DIMM */
-#define SPD_Density 4 /* Bank address bits,SDRAM capacity */
-#define SPD_Addressing 5 /* Row/Column address bits */
-#define SPD_Voltage 6 /* Supported voltage bitfield */
-#define SPD_Organization 7 /* rank#,Device width */
-#define SPD_BusWidth 8 /* ECC, Bus width */
- #define JED_ECC 8 /* ECC capability */
-
-#define SPD_MTBDividend 10
-#define SPD_MTBDivisor 11
-#define SPD_tCKmin 12
-#define SPD_CASLow 14
-#define SPD_CASHigh 15
-#define SPD_tAAmin 16
-
-#define SPD_DEVATTRIB 22
-#define SPD_EDCTYPE 11
- #define JED_ADRCPAR 0x04
-
-#define SPD_tWRmin 17
-#define SPD_tRCDmin 18
-#define SPD_tRRDmin 19
-#define SPD_tRPmin 20
-#define SPD_Upper_tRAS_tRC 21
-#define SPD_tRASmin 22
-#define SPD_tRCmin 23
-#define SPD_tWTRmin 26
-#define SPD_tRTPmin 27
-#define SPD_Upper_tFAW 28
-#define SPD_tFAWmin 29
-#define SPD_Thermal 31
-
-#define SPD_RefRawCard 62
-#define SPD_AddressMirror 63
-#define SPD_RegManufactureID_L 65 /* not used */
-#define SPD_RegManufactureID_H 66 /* not used */
-#define SPD_RegManRevID 67 /* not used */
-
-#define SPD_byte_126 126
-#define SPD_byte_127 127
-
-#define SPD_ROWSZ 3
-#define SPD_COLSZ 4
-#define SPD_LBANKS 17 /*number of [logical] banks on each device*/
-#define SPD_DMBANKS 5 /*number of physical banks on dimm*/
- #define SPDPLBit 4 /* Dram package bit*/
-#define SPD_BANKSZ 31 /*capacity of physical bank*/
-#define SPD_DEVWIDTH 13
-#define SPD_CASLAT 18
-#define SPD_TRP 27
-#define SPD_TRRD 28
-#define SPD_TRCD 29
-#define SPD_TRAS 30
-#define SPD_TWR 36
-#define SPD_TWTR 37
-#define SPD_TRTP 38
-#define SPD_TRCRFC 40
-#define SPD_TRC 41
-#define SPD_TRFC 42
-
-#define SPD_MANDATEYR 93 /*Module Manufacturing Year (BCD)*/
-
-#define SPD_MANDATEWK 94 /*Module Manufacturing Week (BCD)*/
-
-#define SPD_MANID_START 117
-#define SPD_SERIAL_START 122
-#define SPD_PARTN_START 128
-#define SPD_PARTN_LENGTH 18
-#define SPD_REVNO_START 146
-
-/*-----------------------------
- Jedec DDR II related equates
------------------------------*/
-#define MYEAR06 6 /* Manufacturing Year BCD encoding of 2006 - 06d*/
-#define MWEEK24 0x24 /* Manufacturing Week BCD encoding of June - 24d*/
-
-/*=============================================================================
- Macros
-=============================================================================*/
-
-#define _2GB_RJ8 (2<<(30-8))
-#define _4GB_RJ8 (4<<(30-8))
-#define _4GB_RJ4 (4<<(30-4))
-
-#define BigPagex8_RJ8 (1<<(17+3-8)) /*128KB * 8 >> 8 */
-
-/*=============================================================================
- Global MCT Status Structure
-=============================================================================*/
-struct MCTStatStruc {
- u32 GStatus; /* Global Status bitfield*/
- u32 HoleBase; /* If not zero, BASE[39:8] (system address)
- of sub 4GB dram hole for HW remapping.*/
- u32 Sub4GCacheTop; /* If not zero, the 32-bit top of cacheable memory.*/
- u32 SysLimit; /* LIMIT[39:8] (system address)*/
- uint32_t TSCFreq;
- uint16_t nvram_checksum;
- uint8_t try_ecc;
-} __attribute__((packed, aligned(4)));
-
-/*=============================================================================
- Global MCT Configuration Status Word (GStatus)
-=============================================================================*/
-/*These should begin at bit 0 of GStatus[31:0]*/
-#define GSB_MTRRshort 0 /* Ran out of MTRRs while mapping memory*/
-#define GSB_ECCDIMMs 1 /* All banks of all Nodes are ECC capable*/
-#define GSB_DramECCDis 2 /* Dram ECC requested but not enabled.*/
-#define GSB_SoftHole 3 /* A Node Base gap was created*/
-#define GSB_HWHole 4 /* A HW dram remap was created*/
-#define GSB_NodeIntlv 5 /* Node Memory interleaving was enabled*/
-#define GSB_SpIntRemapHole 16 /* Special condition for Node Interleave and HW remapping*/
-#define GSB_EnDIMMSpareNW 17 /* Indicates that DIMM Spare can be used without a warm reset */
- /* NOTE: This is a local bit used by memory code */
-#define GSB_ConfigRestored 18 /* Training configuration was restored from NVRAM */
-
-/*===============================================================================
- Local DCT Status structure (a structure for each DCT)
-===============================================================================*/
-#include "mwlc_d.h" /* I have to */
-
-struct amd_spd_node_data {
- uint8_t spd_bytes[MAX_DIMMS_SUPPORTED][256]; /* [DIMM][byte] */
- uint8_t spd_address[MAX_DIMMS_SUPPORTED]; /* [DIMM] */
- uint64_t spd_hash[MAX_DIMMS_SUPPORTED]; /* [DIMM] */
- uint64_t nvram_spd_hash[MAX_DIMMS_SUPPORTED]; /* [DIMM] */
- uint8_t nvram_spd_match;
- uint8_t nvram_memclk[2]; /* [channel] */
-} __attribute__((packed, aligned(4)));
-
-struct DCTPersistentStatStruc {
- u8 CH_D_B_TxDqs[2][4][9]; /* [A/B] [DIMM1-4] [DQS] */
- /* CHA DIMM0 Byte 0 - 7 TxDqs */
- /* CHA DIMM0 Byte 0 - 7 TxDqs */
- /* CHA DIMM1 Byte 0 - 7 TxDqs */
- /* CHA DIMM1 Byte 0 - 7 TxDqs */
- /* CHB DIMM0 Byte 0 - 7 TxDqs */
- /* CHB DIMM0 Byte 0 - 7 TxDqs */
- /* CHB DIMM1 Byte 0 - 7 TxDqs */
- /* CHB DIMM1 Byte 0 - 7 TxDqs */
- u16 HostBiosSrvc1; /* Word sized general purpose field for use by host BIOS. Scratch space.*/
- u32 HostBiosSrvc2; /* Dword sized general purpose field for use by host BIOS. Scratch space.*/
-} __attribute__((packed, aligned(4)));
-
-struct DCTStatStruc { /* A per Node structure*/
-/* DCTStatStruct_F - start */
- u8 Node_ID; /* Node ID of current controller */
- uint8_t Internal_Node_ID; /* Internal Node ID of the current controller */
- uint8_t Dual_Node_Package; /* 1 = Dual node package (G34) */
- uint8_t stopDCT[2]; /* Set if the DCT will be stopped */
- u8 ErrCode; /* Current error condition of Node
- 0= no error
- 1= Variance Error, DCT is running but not in an optimal configuration.
- 2= Stop Error, DCT is NOT running
- 3= Fatal Error, DCT/MCT initialization has been halted.*/
- u32 ErrStatus; /* Error Status bit Field */
- u32 Status; /* Status bit Field*/
- u8 DIMMAddr[8]; /* SPD address of DIMM controlled by MA0_CS_L[0,1]*/
- /* SPD address of..MB0_CS_L[0,1]*/
- /* SPD address of..MA1_CS_L[0,1]*/
- /* SPD address of..MB1_CS_L[0,1]*/
- /* SPD address of..MA2_CS_L[0,1]*/
- /* SPD address of..MB2_CS_L[0,1]*/
- /* SPD address of..MA3_CS_L[0,1]*/
- /* SPD address of..MB3_CS_L[0,1]*/
- u16 DIMMPresent; /*For each bit n 0..7, 1 = DIMM n is present.
- DIMM# Select Signal
- 0 MA0_CS_L[0,1]
- 1 MB0_CS_L[0,1]
- 2 MA1_CS_L[0,1]
- 3 MB1_CS_L[0,1]
- 4 MA2_CS_L[0,1]
- 5 MB2_CS_L[0,1]
- 6 MA3_CS_L[0,1]
- 7 MB3_CS_L[0,1]*/
- u16 DIMMValid; /* For each bit n 0..7, 1 = DIMM n is valid and is/will be configured*/
- u16 DIMMMismatch; /* For each bit n 0..7, 1 = DIMM n is mismatched, channel B is always considered the mismatch */
- u16 DIMMSPDCSE; /* For each bit n 0..7, 1 = DIMM n SPD checksum error*/
- u16 DimmECCPresent; /* For each bit n 0..7, 1 = DIMM n is ECC capable.*/
- u16 DimmPARPresent; /* For each bit n 0..7, 1 = DIMM n is ADR/CMD Parity capable.*/
- u16 Dimmx4Present; /* For each bit n 0..7, 1 = DIMM n contains x4 data devices.*/
- u16 Dimmx8Present; /* For each bit n 0..7, 1 = DIMM n contains x8 data devices.*/
- u16 Dimmx16Present; /* For each bit n 0..7, 1 = DIMM n contains x16 data devices.*/
- u16 DIMM2Kpage; /* For each bit n 0..7, 1 = DIMM n contains 1K page devices.*/
- u8 MAload[2]; /* Number of devices loading MAA bus*/
- /* Number of devices loading MAB bus*/
- u8 MAdimms[2]; /*Number of DIMMs loading CH A*/
- /* Number of DIMMs loading CH B*/
- u8 DATAload[2]; /*Number of ranks loading CH A DATA*/
- /* Number of ranks loading CH B DATA*/
- u8 DIMMAutoSpeed; /*Max valid Mfg. Speed of DIMMs
- 1 = 200MHz
- 2 = 266MHz
- 3 = 333MHz
- 4 = 400MHz
- 5 = 533MHz*/
- u8 DIMMCASL; /* Min valid Mfg. CL bitfield
- 0 = 2.0
- 1 = 3.0
- 2 = 4.0
- 3 = 5.0
- 4 = 6.0 */
- u16 DIMMTrcd; /* Minimax Trcd*40 (ns) of DIMMs*/
- u16 DIMMTrp; /* Minimax Trp*40 (ns) of DIMMs*/
- u16 DIMMTrtp; /* Minimax Trtp*40 (ns) of DIMMs*/
- u16 DIMMTras; /* Minimax Tras*40 (ns) of DIMMs*/
- u16 DIMMTrc; /* Minimax Trc*40 (ns) of DIMMs*/
- u16 DIMMTwr; /* Minimax Twr*40 (ns) of DIMMs*/
- u16 DIMMTrrd; /* Minimax Trrd*40 (ns) of DIMMs*/
- u16 DIMMTwtr; /* Minimax Twtr*40 (ns) of DIMMs*/
- u8 Speed; /* Bus Speed (to set Controller)
- 1 = 200MHz
- 2 = 266MHz
- 3 = 333MHz
- 4 = 400MHz */
- u8 CASL; /* CAS latency DCT setting
- 0 = 2.0
- 1 = 3.0
- 2 = 4.0
- 3 = 5.0
- 4 = 6.0 */
- u8 Trcd; /* DCT Trcd (busclocks) */
- u8 Trp; /* DCT Trp (busclocks) */
- u8 Trtp; /* DCT Trtp (busclocks) */
- u8 Tras; /* DCT Tras (busclocks) */
- u8 Trc; /* DCT Trc (busclocks) */
- u8 Twr; /* DCT Twr (busclocks) */
- u8 Trrd; /* DCT Trrd (busclocks) */
- u8 Twtr; /* DCT Twtr (busclocks) */
- u8 Trfc[4]; /* DCT Logical DIMM0 Trfc
- 0 = 75ns (for 256Mb devs)
- 1 = 105ns (for 512Mb devs)
- 2 = 127.5ns (for 1Gb devs)
- 3 = 195ns (for 2Gb devs)
- 4 = 327.5ns (for 4Gb devs) */
- /* DCT Logical DIMM1 Trfc (see Trfc0 for format) */
- /* DCT Logical DIMM2 Trfc (see Trfc0 for format) */
- /* DCT Logical DIMM3 Trfc (see Trfc0 for format) */
- u16 CSPresent; /* For each bit n 0..7, 1 = Chip-select n is present */
- u16 CSTestFail; /* For each bit n 0..7, 1 = Chip-select n is present but disabled */
- u32 DCTSysBase; /* BASE[39:8] (system address) of this Node's DCTs. */
- u32 DCTHoleBase; /* If not zero, BASE[39:8] (system address) of dram hole for HW remapping. Dram hole exists on this Node's DCTs. */
- u32 DCTSysLimit; /* LIMIT[39:8] (system address) of this Node's DCTs */
- u16 PresetmaxFreq; /* Maximum OEM defined DDR frequency
- 200 = 200MHz (DDR400)
- 266 = 266MHz (DDR533)
- 333 = 333MHz (DDR667)
- 400 = 400MHz (DDR800) */
- u8 _2Tmode; /* 1T or 2T CMD mode (slow access mode)
- 1 = 1T
- 2 = 2T */
- u8 TrwtTO; /* DCT TrwtTO (busclocks)*/
- u8 Twrrd; /* DCT Twrrd (busclocks)*/
- u8 Twrwr; /* DCT Twrwr (busclocks)*/
- u8 Trdrd; /* DCT Trdrd (busclocks)*/
- u32 CH_ODC_CTL[2]; /* Output Driver Strength (see BKDG FN2:Offset 9Ch, index 00h*/
- u32 CH_ADDR_TMG[2]; /* Address Bus Timing (see BKDG FN2:Offset 9Ch, index 04h*/
- /* Output Driver Strength (see BKDG FN2:Offset 9Ch, index 20h*/
- /* Address Bus Timing (see BKDG FN2:Offset 9Ch, index 24h*/
- u16 CH_EccDQSLike[2]; /* CHA DQS ECC byte like...*/
- u8 CH_EccDQSScale[2]; /* CHA DQS ECC byte scale*/
- /* CHA DQS ECC byte like...*/
- /* CHA DQS ECC byte scale*/
- u8 MaxAsyncLat; /* Max Asynchronous Latency (ns)*/
- /* NOTE: Not used in Barcelona - u8 CH_D_RCVRDLY[2][4]; */
- /* CHA DIMM 0 - 4 Receiver Enable Delay*/
- /* CHB DIMM 0 - 4 Receiver Enable Delay */
- /* NOTE: Not used in Barcelona - u8 CH_D_B_DQS[2][2][8]; */
- /* CHA Byte 0-7 Write DQS Delay */
- /* CHA Byte 0-7 Read DQS Delay */
- /* CHB Byte 0-7 Write DQS Delay */
- /* CHB Byte 0-7 Read DQS Delay */
- u32 PtrPatternBufA; /* Ptr on stack to aligned DQS testing pattern*/
- u32 PtrPatternBufB; /* Ptr on stack to aligned DQS testing pattern*/
- u8 Channel; /* Current Channel (0= CH A, 1 = CH B)*/
- u8 ByteLane; /* Current Byte Lane (0..7)*/
- u8 Direction; /* Current DQS-DQ training write direction (0 = read, 1 = write)*/
- u8 Pattern; /* Current pattern*/
- u8 DQSDelay; /* Current DQS delay value*/
- u32 TrainErrors; /* Current Training Errors*/
-
- u32 AMC_TSC_DeltaLo; /* Time Stamp Counter measurement of AMC, Low dword*/
- u32 AMC_TSC_DeltaHi; /* Time Stamp Counter measurement of AMC, High dword*/
- /* NOTE: Not used in Barcelona - */
- u8 CH_D_DIR_MaxMin_B_Dly[2][2][2][8];
- /* CH A byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH A byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- /* CH A byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH A byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 minimum filtered window passing DQS delay value*/
- /* CH B byte lane 0 - 7 maximum filtered window passing DQS delay value*/
- uint64_t LogicalCPUID; /* The logical CPUID of the node*/
- u16 DimmQRPresent; /* QuadRank DIMM present?*/
- u16 DimmTrainFail; /* Bitmap showing which dimms failed training*/
- u16 CSTrainFail; /* Bitmap showing which chipselects failed training*/
- u16 DimmYr06; /* Bitmap indicating which Dimms have a manufactur's year code <= 2006*/
- u16 DimmWk2406; /* Bitmap indicating which Dimms have a manufactur's week code <= 24 of 2006 (June)*/
- u16 DimmDRPresent; /* Bitmap indicating that Dual Rank Dimms are present*/
- u16 DimmPlPresent; /* Bitmap indicating that Planar (1) or Stacked (0) Dimms are present.*/
- u16 ChannelTrainFai; /* Bitmap showing the channel information about failed Chip Selects
- 0 in any bit field indicates Channel 0
- 1 in any bit field indicates Channel 1 */
- u16 DIMMTfaw; /* Minimax Tfaw*16 (ns) of DIMMs */
- u8 Tfaw; /* DCT Tfaw (busclocks) */
- u16 CSUsrTestFail; /* Chip selects excluded by user */
-/* DCTStatStruct_F - end */
-
- u16 CH_MaxRdLat[2][2]; /* Max Read Latency (nclks) [dct][pstate] */
- /* Max Read Latency (ns) for DCT 1*/
- u8 CH_D_DIR_B_DQS[2][4][2][9]; /* [A/B] [DIMM1-4] [R/W] [DQS] */
- /* CHA DIMM0 Byte 0 - 7 and Check Write DQS Delay*/
- /* CHA DIMM0 Byte 0 - 7 and Check Read DQS Delay*/
- /* CHA DIMM1 Byte 0 - 7 and Check Write DQS Delay*/
- /* CHA DIMM1 Byte 0 - 7 and Check Read DQS Delay*/
- /* CHB DIMM0 Byte 0 - 7 and Check Write DQS Delay*/
- /* CHB DIMM0 Byte 0 - 7 and Check Read DQS Delay*/
- /* CHB DIMM1 Byte 0 - 7 and Check Write DQS Delay*/
- /* CHB DIMM1 Byte 0 - 7 and Check Read DQS Delay*/
- u16 CH_D_B_RCVRDLY[2][4][8]; /* [A/B] [DIMM0-3] [DQS] */
- /* CHA DIMM 0 Receiver Enable Delay*/
- /* CHA DIMM 1 Receiver Enable Delay*/
- /* CHA DIMM 2 Receiver Enable Delay*/
- /* CHA DIMM 3 Receiver Enable Delay*/
-
- /* CHB DIMM 0 Receiver Enable Delay*/
- /* CHB DIMM 1 Receiver Enable Delay*/
- /* CHB DIMM 2 Receiver Enable Delay*/
- /* CHB DIMM 3 Receiver Enable Delay*/
- u16 CH_D_BC_RCVRDLY[2][4];
- /* CHA DIMM 0 - 4 Check Byte Receiver Enable Delay*/
- /* CHB DIMM 0 - 4 Check Byte Receiver Enable Delay*/
- u8 DIMMValidDCT[2]; /* DIMM# in DCT0*/
- /* DIMM# in DCT1*/
- u16 CSPresent_DCT[2]; /* DCT# CS mapping */
- u16 MirrPresU_NumRegR; /* Address mapping from edge connect to DIMM present for unbuffered dimm
- Number of registers on the dimm for registered dimm */
- u8 MaxDCTs; /* Max number of DCTs in system*/
- /* NOTE: removed u8 DCT. Use ->dev_ for pci R/W; */ /*DCT pointer*/
- u8 GangedMode; /* Ganged mode enabled, 0 = disabled, 1 = enabled*/
- u8 DRPresent; /* Family 10 present flag, 0 = not Fam10, 1 = Fam10*/
- u32 NodeSysLimit; /* BASE[39:8],for DCT0+DCT1 system address*/
- u8 WrDatGrossH;
- u8 DqsRcvEnGrossL;
- /* NOTE: Not used - u8 NodeSpeed */ /* Bus Speed (to set Controller) */
- /* 1 = 200MHz */
- /* 2 = 266MHz */
- /* 3 = 333MHz */
- /* NOTE: Not used - u8 NodeCASL */ /* CAS latency DCT setting */
- /* 0 = 2.0 */
- /* 1 = 3.0 */
- /* 2 = 4.0 */
- /* 3 = 5.0 */
- /* 4 = 6.0 */
- u8 TrwtWB;
- u8 CurrRcvrCHADelay; /* for keep current RcvrEnDly of chA*/
- u16 T1000; /* get the T1000 figure (cycle time (ns)*1K)*/
- u8 DqsRcvEn_Pass; /* for TrainRcvrEn byte lane pass flag*/
- u8 DqsRcvEn_Saved; /* for TrainRcvrEn byte lane saved flag*/
- u8 SeedPass1Remainder; /* for Phy assisted DQS receiver enable training*/
-
- /* for second pass - Second pass should never run for Fam10*/
- /* NOTE: Not used for Barcelona - u8 CH_D_B_RCVRDLY_1[2][4][8]; */ /* CHA DIMM 0 Receiver Enable Delay */
- /* CHA DIMM 1 Receiver Enable Delay*/
- /* CHA DIMM 2 Receiver Enable Delay*/
- /* CHA DIMM 3 Receiver Enable Delay*/
-
- /* CHB DIMM 0 Receiver Enable Delay*/
- /* CHB DIMM 1 Receiver Enable Delay*/
- /* CHB DIMM 2 Receiver Enable Delay*/
- /* CHB DIMM 3 Receiver Enable Delay*/
-
- u8 ClToNB_flag; /* is used to restore ClLinesToNbDis bit after memory */
- u32 NodeSysBase; /* for channel interleave usage */
-
- /* Fam15h specific backup variables */
- uint8_t SwNbPstateLoDis;
- uint8_t NbPstateDisOnP0;
- uint8_t NbPstateThreshold;
- uint8_t NbPstateHi;
-
- /* New for LB Support */
- u8 NodePresent;
- u32 dev_host;
- u32 dev_map;
- u32 dev_dct;
- u32 dev_nbmisc;
- u32 dev_link;
- u32 dev_nbctl;
- u8 TargetFreq;
- u8 TargetCASL;
- uint32_t CtrlWrd3;
- uint32_t CtrlWrd4;
- uint32_t CtrlWrd5;
- u8 DqsRdWrPos_Saved;
- u8 DqsRcvEnGrossMax;
- u8 DqsRcvEnGrossMin;
- u8 WrDatGrossMax;
- u8 WrDatGrossMin;
- uint8_t tcwl_delay[2];
-
- u16 RegMan1Present; /* DIMM present bitmap of Register manufacture 1 */
- u16 RegMan2Present; /* DIMM present bitmap of Register manufacture 2 */
-
- struct _sMCTStruct *C_MCTPtr;
- struct _sDCTStruct *C_DCTPtr[2];
- /* struct _sDCTStruct *C_DCT1Ptr; */
-
- struct _sMCTStruct s_C_MCTPtr;
- struct _sDCTStruct s_C_DCTPtr[2];
- /* struct _sDCTStruct s_C_DCT1Ptr[8]; */
-
- /* DIMM supported voltage bitmap ([2:0]: 1.25V, 1.35V, 1.5V) */
- uint8_t DimmSupportedVoltages[MAX_DIMMS_SUPPORTED];
- uint32_t DimmConfiguredVoltage[MAX_DIMMS_SUPPORTED]; /* mV */
-
- uint8_t DimmRows[MAX_DIMMS_SUPPORTED];
- uint8_t DimmCols[MAX_DIMMS_SUPPORTED];
- uint8_t DimmRanks[MAX_DIMMS_SUPPORTED];
- uint8_t DimmBanks[MAX_DIMMS_SUPPORTED];
- uint8_t DimmWidth[MAX_DIMMS_SUPPORTED];
- uint64_t DimmChipSize[MAX_DIMMS_SUPPORTED];
- uint32_t DimmChipWidth[MAX_DIMMS_SUPPORTED];
- uint8_t DimmRegistered[MAX_DIMMS_SUPPORTED];
- uint8_t DimmLoadReduced[MAX_DIMMS_SUPPORTED];
-
- uint64_t DimmManufacturerID[MAX_DIMMS_SUPPORTED];
- char DimmPartNumber[MAX_DIMMS_SUPPORTED][SPD_PARTN_LENGTH+1];
- uint16_t DimmRevisionNumber[MAX_DIMMS_SUPPORTED];
- uint32_t DimmSerialNumber[MAX_DIMMS_SUPPORTED];
-
- struct amd_spd_node_data spd_data;
-
- /* NOTE: This must remain the last entry in this structure */
- struct DCTPersistentStatStruc persistentData;
-} __attribute__((packed, aligned(4)));
-
-struct amd_s3_persistent_mct_channel_data {
- /* Stage 1 (1 dword) */
- uint32_t f2x110;
-
- /* Stage 2 (88 dwords) */
- uint32_t f1x40;
- uint32_t f1x44;
- uint32_t f1x48;
- uint32_t f1x4c;
- uint32_t f1x50;
- uint32_t f1x54;
- uint32_t f1x58;
- uint32_t f1x5c;
- uint32_t f1x60;
- uint32_t f1x64;
- uint32_t f1x68;
- uint32_t f1x6c;
- uint32_t f1x70;
- uint32_t f1x74;
- uint32_t f1x78;
- uint32_t f1x7c;
- uint32_t f1xf0;
- uint32_t f1x120;
- uint32_t f1x124;
- uint32_t f2x10c;
- uint32_t f2x114;
- uint32_t f2x118;
- uint32_t f2x11c;
- uint32_t f2x1b0;
- uint32_t f3x44;
- uint64_t msr0000020[16];
- uint64_t msr00000250;
- uint64_t msr00000258;
- uint64_t msr0000026[8];
- uint64_t msr000002ff;
- uint64_t msrc0010010;
- uint64_t msrc001001a;
- uint64_t msrc001001d;
- uint64_t msrc001001f;
-
- /* Stage 3 (21 dwords) */
- uint32_t f2x40;
- uint32_t f2x44;
- uint32_t f2x48;
- uint32_t f2x4c;
- uint32_t f2x50;
- uint32_t f2x54;
- uint32_t f2x58;
- uint32_t f2x5c;
- uint32_t f2x60;
- uint32_t f2x64;
- uint32_t f2x68;
- uint32_t f2x6c;
- uint32_t f2x78;
- uint32_t f2x7c;
- uint32_t f2x80;
- uint32_t f2x84;
- uint32_t f2x88;
- uint32_t f2x8c;
- uint32_t f2x90;
- uint32_t f2xa4;
- uint32_t f2xa8;
-
- /* Stage 4 (1 dword) */
- uint32_t f2x94;
-
- /* Stage 6 (33 dwords) */
- uint32_t f2x9cx0d0f0_f_8_0_0_8_4_0[9][3]; /* [lane][setting] */
- uint32_t f2x9cx00;
- uint32_t f2x9cx0a;
- uint32_t f2x9cx0c;
-
- /* Stage 7 (1 dword) */
- uint32_t f2x9cx04;
-
- /* Stage 9 (2 dwords) */
- uint32_t f2x9cx0d0fe006;
- uint32_t f2x9cx0d0fe007;
-
- /* Stage 10 (78 dwords) */
- uint32_t f2x9cx10[12];
- uint32_t f2x9cx20[12];
- uint32_t f2x9cx3_0_0_3_1[4][3]; /* [dimm][setting] */
- uint32_t f2x9cx3_0_0_7_5[4][3]; /* [dimm][setting] */
- uint32_t f2x9cx0d;
- uint32_t f2x9cx0d0f0_f_0_13[9]; /* [lane] */
- uint32_t f2x9cx0d0f0_f_0_30[9]; /* [lane] */
- uint32_t f2x9cx0d0f2_f_0_30[4]; /* [pad select] */
- uint32_t f2x9cx0d0f8_8_4_0[2][3]; /* [offset][pad select] */
- uint32_t f2x9cx0d0f812f;
-
- /* Stage 11 (24 dwords) */
- uint32_t f2x9cx30[12];
- uint32_t f2x9cx40[12];
-
- /* Other (3 dwords) */
- uint32_t f3x58;
- uint32_t f3x5c;
- uint32_t f3x60;
-
- /* Family 15h-specific registers (91 dwords) */
- uint32_t f2x200;
- uint32_t f2x204;
- uint32_t f2x208;
- uint32_t f2x20c;
- uint32_t f2x210[4]; /* [nb pstate] */
- uint32_t f2x214;
- uint32_t f2x218;
- uint32_t f2x21c;
- uint32_t f2x22c;
- uint32_t f2x230;
- uint32_t f2x234;
- uint32_t f2x238;
- uint32_t f2x23c;
- uint32_t f2x240;
- uint32_t f2x9cx0d0fe003;
- uint32_t f2x9cx0d0fe013;
- uint32_t f2x9cx0d0f0_8_0_1f[9]; /* [lane]*/
- uint32_t f2x9cx0d0f201f;
- uint32_t f2x9cx0d0f211f;
- uint32_t f2x9cx0d0f221f;
- uint32_t f2x9cx0d0f801f;
- uint32_t f2x9cx0d0f811f;
- uint32_t f2x9cx0d0f821f;
- uint32_t f2x9cx0d0fc01f;
- uint32_t f2x9cx0d0fc11f;
- uint32_t f2x9cx0d0fc21f;
- uint32_t f2x9cx0d0f4009;
- uint32_t f2x9cx0d0f0_8_0_02[9]; /* [lane]*/
- uint32_t f2x9cx0d0f0_8_0_06[9]; /* [lane]*/
- uint32_t f2x9cx0d0f0_8_0_0a[9]; /* [lane]*/
- uint32_t f2x9cx0d0f2002;
- uint32_t f2x9cx0d0f2102;
- uint32_t f2x9cx0d0f2202;
- uint32_t f2x9cx0d0f8002;
- uint32_t f2x9cx0d0f8006;
- uint32_t f2x9cx0d0f800a;
- uint32_t f2x9cx0d0f8102;
- uint32_t f2x9cx0d0f8106;
- uint32_t f2x9cx0d0f810a;
- uint32_t f2x9cx0d0fc002;
- uint32_t f2x9cx0d0fc006;
- uint32_t f2x9cx0d0fc00a;
- uint32_t f2x9cx0d0fc00e;
- uint32_t f2x9cx0d0fc012;
- uint32_t f2x9cx0d0f2031;
- uint32_t f2x9cx0d0f2131;
- uint32_t f2x9cx0d0f2231;
- uint32_t f2x9cx0d0f8031;
- uint32_t f2x9cx0d0f8131;
- uint32_t f2x9cx0d0f8231;
- uint32_t f2x9cx0d0fc031;
- uint32_t f2x9cx0d0fc131;
- uint32_t f2x9cx0d0fc231;
- uint32_t f2x9cx0d0f0_0_f_31[9]; /* [lane] */
- uint32_t f2x9cx0d0f8021;
- uint32_t f2x9cx0d0fe00a;
-
- /* TOTAL: 343 dwords */
-} __attribute__((packed, aligned(4)));
-
-struct amd_s3_persistent_node_data {
- uint32_t node_present;
- uint64_t spd_hash[MAX_DIMMS_SUPPORTED];
- uint8_t memclk[2];
- struct amd_s3_persistent_mct_channel_data channel[2];
-} __attribute__((packed, aligned(4)));
-
-struct amd_s3_persistent_data {
- struct amd_s3_persistent_node_data node[MAX_NODES_SUPPORTED];
- uint16_t nvram_checksum;
-} __attribute__((packed, aligned(4)));
-
-/*===============================================================================
- Local Error Status Codes (DCTStatStruc.ErrCode)
-===============================================================================*/
-#define SC_RunningOK 0
-#define SC_VarianceErr 1 /* Running non-optimally*/
-#define SC_StopError 2 /* Not Running*/
-#define SC_FatalErr 3 /* Fatal Error, MCTB has exited immediately*/
-
-/*===============================================================================
- Local Error Status (DCTStatStruc.ErrStatus[31:0])
-===============================================================================*/
-#define SB_NoDimms 0
-#define SB_DIMMChkSum 1
-#define SB_DimmMismatchM 2 /* dimm module type(buffer) mismatch*/
-#define SB_DimmMismatchT 3 /* dimm CL/T mismatch*/
-#define SB_DimmMismatchO 4 /* dimm organization mismatch (128-bit)*/
-#define SB_NoTrcTrfc 5 /* SPD missing Trc or Trfc info*/
-#define SB_NoCycTime 6 /* SPD missing byte 23 or 25*/
-#define SB_BkIntDis 7 /* Bank interleave requested but not enabled*/
-#define SB_DramECCDis 8 /* Dram ECC requested but not enabled*/
-#define SB_SpareDis 9 /* Online spare requested but not enabled*/
-#define SB_MinimumMode 10 /* Running in Minimum Mode*/
-#define SB_NORCVREN 11 /* No DQS Receiver Enable pass window found*/
-#define SB_CHA2BRCVREN 12 /* DQS Rcvr En pass window CHA to CH B too large*/
-#define SB_SmallRCVR 13 /* DQS Rcvr En pass window too small (far right of dynamic range)*/
-#define SB_NODQSPOS 14 /* No DQS-DQ passing positions*/
-#define SB_SMALLDQS 15 /* DQS-DQ passing window too small*/
-#define SB_DCBKScrubDis 16 /* DCache scrub requested but not enabled */
-#define SB_RetryConfigTrain 17 /* Retry configuration and training */
-#define SB_FatalError 18 /* Fatal training error detected */
-
-/*===============================================================================
- Local Configuration Status (DCTStatStruc.Status[31:0])
-===============================================================================*/
-#define SB_Registered 0 /* All DIMMs are Registered*/
-#define SB_LoadReduced 1 /* All DIMMs are Load-Reduced*/
-#define SB_ECCDIMMs 2 /* All banks ECC capable*/
-#define SB_PARDIMMs 3 /* All banks Addr/CMD Parity capable*/
-#define SB_DiagClks 4 /* Jedec ALL slots clock enable diag mode*/
-#define SB_128bitmode 5 /* DCT in 128-bit mode operation*/
-#define SB_64MuxedMode 6 /* DCT in 64-bit mux'ed mode.*/
-#define SB_2TMode 7 /* 2T CMD timing mode is enabled.*/
-#define SB_SWNodeHole 8 /* Remapping of Node Base on this Node to create a gap.*/
-#define SB_HWHole 9 /* Memory Hole created on this Node using HW remapping.*/
-#define SB_Over400MHz 10 /* DCT freq >= 400MHz flag*/
-#define SB_DQSPos_Pass2 11 /* Using for TrainDQSPos DIMM0/1, when freq >= 400MHz*/
-#define SB_DQSRcvLimit 12 /* Using for DQSRcvEnTrain to know we have reached to upper bound.*/
-#define SB_ExtConfig 13 /* Indicator the default setting for extend PCI configuration support*/
-
-
-/*===============================================================================
- NVRAM/run-time-configurable Items
-===============================================================================*/
-/*Platform Configuration*/
-#define NV_PACK_TYPE 0 /* CPU Package Type (2-bits)
- 0 = NPT L1
- 1 = NPT M2
- 2 = NPT S1*/
-#define NV_MAX_NODES 1 /* Number of Nodes/Sockets (4-bits)*/
-#define NV_MAX_DIMMS 2 /* Number of DIMM slots for the specified Node ID (4-bits)*/
-#define NV_MAX_MEMCLK 3 /* Maximum platform demonstrated Memclock (10-bits)
- 200 = 200MHz (DDR400)
- 266 = 266MHz (DDR533)
- 333 = 333MHz (DDR667)
- 400 = 400MHz (DDR800)*/
-#define NV_MIN_MEMCLK 4 /* Minimum platform demonstrated Memclock (10-bits) */
-#define NV_ECC_CAP 5 /* Bus ECC capable (1-bits)
- 0 = Platform not capable
- 1 = Platform is capable*/
-#define NV_4RANKType 6 /* Quad Rank DIMM slot type (2-bits)
- 0 = Normal
- 1 = R4 (4-Rank Registered DIMMs in AMD server configuration)
- 2 = S4 (Unbuffered SO-DIMMs)*/
-#define NV_BYPMAX 7 /* Value to set DcqBypassMax field (See Function 2, Offset 94h, [27:24] of BKDG for field definition).
- 4 = 4 times bypass (normal for non-UMA systems)
- 7 = 7 times bypass (normal for UMA systems)*/
-#define NV_RDWRQBYP 8 /* Value to set RdWrQByp field (See Function 2, Offset A0h, [3:2] of BKDG for field definition).
- 2 = 8 times (normal for non-UMA systems)
- 3 = 16 times (normal for UMA systems)*/
-
-
-/*Dram Timing*/
-#define NV_MCTUSRTMGMODE 10 /* User Memclock Mode (2-bits)
- 0 = Auto, no user limit
- 1 = Auto, user limit provided in NV_MemCkVal
- 2 = Manual, user value provided in NV_MemCkVal*/
-#define NV_MemCkVal 11 /* Memory Clock Value (2-bits)
- 0 = 200MHz
- 1 = 266MHz
- 2 = 333MHz
- 3 = 400MHz*/
-
-/*Dram Configuration*/
-#define NV_BankIntlv 20 /* Dram Bank (chip-select) Interleaving (1-bits)
- 0 = disable
- 1 = enable*/
-#define NV_AllMemClks 21 /* Turn on All DIMM clocks (1-bits)
- 0 = normal
- 1 = enable all memclocks*/
-#define NV_SPDCHK_RESTRT 22 /* SPD Check control bitmap (1-bits)
- 0 = Exit current node init if any DIMM has SPD checksum error
- 1 = Ignore faulty SPD checksums (Note: DIMM cannot be enabled)*/
-#define NV_DQSTrainCTL 23 /* DQS Signal Timing Training Control
- 0 = skip DQS training
- 1 = perform DQS training*/
-#define NV_NodeIntlv 24 /* Node Memory Interleaving (1-bits)
- 0 = disable
- 1 = enable*/
-#define NV_BurstLen32 25 /* BurstLength32 for 64-bit mode (1-bits)
- 0 = disable (normal)
- 1 = enable (4 beat burst when width is 64-bits)*/
-
-/*Dram Power*/
-#define NV_CKE_PDEN 30 /* CKE based power down mode (1-bits)
- 0 = disable
- 1 = enable*/
-#define NV_CKE_CTL 31 /* CKE based power down control (1-bits)
- 0 = per Channel control
- 1 = per Chip select control*/
-#define NV_CLKHZAltVidC3 32 /* Memclock tri-stating during C3 and Alt VID (1-bits)
- 0 = disable
- 1 = enable*/
-
-/*Memory Map/Mgt.*/
-#define NV_BottomIO 40 /* Bottom of 32-bit IO space (8-bits)
- NV_BottomIO[7:0]=Addr[31:24]*/
-#define NV_BottomUMA 41 /* Bottom of shared graphics dram (8-bits)
- NV_BottomUMA[7:0]=Addr[31:24]*/
-#define NV_MemHole 42 /* Memory Hole Remapping (1-bits)
- 0 = disable
- 1 = enable */
-
-/*ECC*/
-#define NV_ECC 50 /* Dram ECC enable*/
-#define NV_NBECC 52 /* ECC MCE enable*/
-#define NV_ChipKill 53 /* Chip-Kill ECC Mode enable*/
-#define NV_ECCRedir 54 /* Dram ECC Redirection enable*/
-#define NV_DramBKScrub 55 /* Dram ECC Background Scrubber CTL*/
-#define NV_L2BKScrub 56 /* L2 ECC Background Scrubber CTL*/
-#define NV_L3BKScrub 57 /* L3 ECC Background Scrubber CTL*/
-#define NV_DCBKScrub 58 /* DCache ECC Background Scrubber CTL*/
-#define NV_CS_SpareCTL 59 /* Chip Select Spare Control bit 0:
- 0 = disable Spare
- 1 = enable Spare */
- /* Chip Select Spare Control bit 1-4:
- Reserved, must be zero*/
-#define NV_SyncOnUnEccEn 61 /* SyncOnUnEccEn control
- 0 = disable
- 1 = enable*/
-#define NV_Unganged 62
-
-#define NV_ChannelIntlv 63 /* Channel Interleaving (3-bits)
- xx0b = disable
- yy1b = enable with DctSelIntLvAddr set to yyb */
-
-#define NV_MAX_DIMMS_PER_CH 64 /* Maximum number of DIMMs per channel */
-
-/*===============================================================================
- CBMEM storage
-===============================================================================*/
-struct amdmct_memory_info {
- struct MCTStatStruc mct_stat;
- struct DCTStatStruc dct_stat[MAX_NODES_SUPPORTED];
- uint16_t ecc_enabled;
- uint16_t ecc_scrub_rate;
-} __attribute__((packed, aligned(4)));
-
-extern const u8 Table_DQSRcvEn_Offset[];
-extern const u32 TestPattern0_D[];
-extern const u32 TestPattern1_D[];
-extern const u32 TestPattern2_D[];
-
-u32 Get_NB32(u32 dev, u32 reg);
-void Set_NB32(u32 dev, u32 reg, u32 val);
-u32 Get_NB32_index(u32 dev, u32 index_reg, u32 index);
-void Set_NB32_index(u32 dev, u32 index_reg, u32 index, u32 data);
-u32 Get_NB32_index_wait(u32 dev, u32 index_reg, u32 index);
-void Set_NB32_index_wait(u32 dev, u32 index_reg, u32 index, u32 data);
-u32 OtherTiming_A_D(struct DCTStatStruc *pDCTstat, u32 val);
-void mct_ForceAutoPrecharge_D(struct DCTStatStruc *pDCTstat, u32 dct);
-u32 Modify_D3CMP(struct DCTStatStruc *pDCTstat, u32 dct, u32 value);
-u8 mct_checkNumberOfDqsRcvEn_1Pass(u8 pass);
-u32 SetupDqsPattern_1PassA(u8 Pass);
-u32 SetupDqsPattern_1PassB(u8 Pass);
-u8 mct_Get_Start_RcvrEnDly_1Pass(u8 Pass);
-u16 mct_Average_RcvrEnDly_Pass(struct DCTStatStruc *pDCTstat, u16 RcvrEnDly, u16 RcvrEnDlyLimit, u8 Channel, u8 Receiver, u8 Pass);
-void initialize_mca(uint8_t bsp, uint8_t suppress_errors);
-void CPUMemTyping_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void UMAMemTyping_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-uint64_t mctGetLogicalCPUID(u32 Node);
-u8 ECCInit_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void TrainReceiverEn_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA, u8 Pass);
-void TrainMaxRdLatency_En_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mct_TrainDQSPos_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mctSetEccDQSRcvrEn_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void TrainMaxReadLatency_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mct_EndDQSTraining_D(struct MCTStatStruc *pMCTstat,struct DCTStatStruc *pDCTstatA);
-void mct_SetRcvrEnDly_D(struct DCTStatStruc *pDCTstat, u16 RcvrEnDly, u8 FinalValue, u8 Channel, u8 Receiver, u32 dev, u32 index_reg, u8 Addl_Index, u8 Pass);
-void SetEccDQSRcvrEn_D(struct DCTStatStruc *pDCTstat, u8 Channel);
-void mctGet_PS_Cfg_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u32 dct);
-void InterleaveBanks_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 dct);
-void mct_SetDramConfigHi_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u32 dct, u32 DramConfigHi);
-void mct_DramInit_Hw_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 dct);
-void mct_SetClToNB_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void mct_SetWbEnhWsbDis_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void mct_ForceNBPState0_En_Fam15(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void mct_ForceNBPState0_Dis_Fam15(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void mct_TrainRcvrEn_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 Pass);
-void mct_EnableDimmEccEn_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 _DisableDramECC);
-u32 procOdtWorkaround(struct DCTStatStruc *pDCTstat, u32 dct, u32 val);
-void mct_BeforeDramInit_D(struct DCTStatStruc *pDCTstat, u32 dct);
-void DIMMSetVoltages(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void InterleaveNodes_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void InterleaveChannels_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mct_BeforeDQSTrain_Samp_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-
-void phyAssistedMemFnceTraining(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA, int16_t Node);
-u8 mct_SaveRcvEnDly_D_1Pass(struct DCTStatStruc *pDCTstat, u8 pass);
-u8 mct_InitReceiver_D(struct DCTStatStruc *pDCTstat, u8 dct);
-void mct_Wait(u32 cycles);
-u8 mct_RcvrRankEnabled_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 Channel, u8 ChipSel);
-u32 mct_GetRcvrSysAddr_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 channel, u8 receiver, u8 *valid);
-void mct_Read1LTestPattern_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u32 addr);
-void mctAutoInitMCT_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void calculate_spd_hash(uint8_t *spd_data, uint64_t *spd_hash);
-int8_t load_spd_hashes_from_nvram(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-int8_t restore_mct_information_from_nvram(uint8_t training_only);
-uint16_t calculate_nvram_mct_hash(void);
-
-uint32_t fam10h_address_timing_compensation_code(struct DCTStatStruc *pDCTstat, uint8_t dct);
-uint32_t fam15h_output_driver_compensation_code(struct DCTStatStruc *pDCTstat, uint8_t dct);
-uint32_t fam15h_address_timing_compensation_code(struct DCTStatStruc *pDCTstat, uint8_t dct);
-uint8_t fam15h_slow_access_mode(struct DCTStatStruc *pDCTstat, uint8_t dct);
-void precise_memclk_delay_fam15(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, uint8_t dct, uint32_t clocks);
-void mct_EnableDatIntlv_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void SetDllSpeedUp_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-uint8_t get_available_lane_count(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void read_dqs_receiver_enable_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg);
-void read_dqs_write_timing_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg);
-void fam15EnableTrainingMode(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t enable);
-void read_dqs_read_data_timing_registers(uint16_t *delay, uint32_t dev,
- uint8_t dct, uint8_t dimm, uint32_t index_reg);
-void write_dqs_read_data_timing_registers(uint16_t *delay, uint32_t dev,
- uint8_t dct, uint8_t dimm, uint32_t index_reg);
-void dqsTrainMaxRdLatency_SW_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void proc_IOCLFLUSH_D(u32 addr_hi);
-u8 ChipSelPresent_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 ChipSel);
-void mct_Write1LTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr, u8 pattern);
-u8 NodePresent_D(u8 Node);
-void DCTMemClr_Init_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void DCTMemClr_Sync_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void SPD2ndTiming(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-void ProgDramMRSReg_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-u8 PlatformSpec_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-void StartupDCT_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-uint16_t mhz_to_memclk_config(uint16_t freq);
-void SetTargetFreq(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA, uint8_t Node);
-void mct_WriteLevelization_HW(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA, uint8_t Pass);
-uint8_t AgesaHwWlPhase1(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u8 dimm, u8 pass);
-uint8_t AgesaHwWlPhase2(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t pass);
-uint8_t AgesaHwWlPhase3(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u8 dimm, u8 pass);
-void EnableZQcalibration(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void DisableZQcalibration(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void PrepareC_MCT(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void PrepareC_DCT(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 dct);
-void Restore_OnDimmMirror(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void Clear_OnDimmMirror(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat);
-void MCTMemClr_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mct_BeforeDQSTrainSamp(struct DCTStatStruc *pDCTstat);
-void mct_ExtMCTConfig_Bx(struct DCTStatStruc *pDCTstat);
-void mct_ExtMCTConfig_Cx(struct DCTStatStruc *pDCTstat);
-void mct_ExtMCTConfig_Dx(struct DCTStatStruc *pDCTstat);
-u32 mct_SetDramConfigMisc2(struct DCTStatStruc *pDCTstat,
- uint8_t dct, uint32_t misc2, uint32_t DramControl);
-
-uint8_t dct_ddr_voltage_index(struct DCTStatStruc *pDCTstat, uint8_t dct);
-void mct_DramControlReg_Init_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct);
-void precise_ndelay_fam15(struct MCTStatStruc *pMCTstat, uint32_t nanoseconds);
-void FreqChgCtrlWrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct);
-u32 mct_MR1Odt_RDimm(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u32 MrsChipSel);
-void mct_DramInit_Sw_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-void print_debug_dqs(const char *str, u32 val, u8 level);
-void print_debug_dqs_pair(const char *str, u32 val, const char *str2, u32 val2, u8 level);
-u8 mct_DisableDimmEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void ResetDCTWrPtr_D(u32 dev, uint8_t dct, u32 index_reg, u32 index);
-void Calc_SetMaxRdLatency_D_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t calc_min);
-void write_dram_dqs_training_pattern_fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct,
- uint8_t Receiver, uint8_t lane, uint8_t stop_on_error);
-void read_dram_dqs_training_pattern_fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct,
- uint8_t Receiver, uint8_t lane, uint8_t stop_on_error);
-void write_dqs_receiver_enable_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg);
-
-uint32_t fenceDynTraining_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct);
-int32_t abs(int32_t val);
-void SetTargetWTIO_D(u32 TestAddr);
-void ResetTargetWTIO_D(void);
-u32 mct_GetMCTSysAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 receiver, u8 *valid);
-void set_2t_configuration(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-u8 mct_BeforePlatformSpec(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-u8 mct_PlatformSpec(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-void InitPhyCompensation(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct);
-u32 mct_MR1(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u32 MrsChipSel);
-u32 mct_MR2(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u32 MrsChipSel);
-uint8_t fam15_rttwr(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t rank, uint8_t package_type);
-uint8_t fam15_rttnom(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t rank, uint8_t package_type);
-uint8_t fam15_dimm_dic(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t rank, uint8_t package_type);
-u32 mct_DramTermDyn_RDimm(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dimm);
-
-void restore_mct_data_from_save_variable(struct amd_s3_persistent_data* persistent_data, uint8_t training_only);
-#endif
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mct_d_gcc.c b/src/northbridge/amd/amdmct/mct_ddr3/mct_d_gcc.c
deleted file mode 100644
index ccea732709..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mct_d_gcc.c
+++ /dev/null
@@ -1,296 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include "mct_d_gcc.h"
-#include <stdint.h>
-#include <arch/cpu.h>
-
-void _WRMSR(u32 addr, u32 lo, u32 hi)
-{
- __asm__ volatile (
- "wrmsr"
- :
- :"c"(addr),"a"(lo), "d" (hi)
- );
-}
-
-void _RDMSR(u32 addr, u32 *lo, u32 *hi)
-{
- __asm__ volatile (
- "rdmsr"
- :"=a"(*lo), "=d" (*hi)
- :"c"(addr)
- );
-}
-
-void _RDTSC(u32 *lo, u32 *hi)
-{
- __asm__ volatile (
- "rdtsc"
- : "=a" (*lo), "=d"(*hi)
- );
-}
-
-void _cpu_id(u32 addr, u32 *val)
-{
- __asm__ volatile(
- "cpuid"
- : "=a" (val[0]),
- "=b" (val[1]),
- "=c" (val[2]),
- "=d" (val[3])
- : "0" (addr));
-
-}
-
-u32 bsr(u32 x)
-{
- u8 i;
- u32 ret = 0;
-
- for (i = 31; i > 0; i--) {
- if (x & (1<<i)) {
- ret = i;
- break;
- }
- }
-
- return ret;
-
-}
-
-u32 bsf(u32 x)
-{
- u8 i;
- u32 ret = 32;
-
- for (i = 0; i < 32; i++) {
- if (x & (1<<i)) {
- ret = i;
- break;
- }
- }
-
- return ret;
-}
-
-void proc_MFENCE(void)
-{
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "mfence\n\t"
- :::"memory"
- );
-}
-
-void proc_CLFLUSH(u32 addr_hi)
-{
- SetUpperFSbase(addr_hi);
-
- __asm__ volatile (
- /* clflush fs:[eax] */
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "clflush %%fs:(%0)\n\t"
- "mfence\n\t"
- ::"a" (addr_hi<<8)
- );
-}
-
-
-void WriteLNTestPattern(u32 addr_lo, u8 *buf_a, u32 line_num)
-{
- uint32_t step = 16;
- uint32_t count = line_num * 4;
-
- __asm__ volatile (
- /*prevent speculative execution of following instructions*/
- /* FIXME: needed ? */
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "1:\n\t"
- "movdqa (%3), %%xmm0\n\t"
- "movntdq %%xmm0, %%fs:(%0)\n\t" /* xmm0 is 128 bit */
- "addl %1, %0\n\t"
- "addl %1, %3\n\t"
- "loop 1b\n\t"
- "mfence\n\t"
-
- : "+a" (addr_lo), "+d" (step), "+c" (count), "+b" (buf_a) : :
- );
-
-}
-
-u32 read32_fs(u32 addr_lo)
-{
- u32 value;
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "movl %%fs:(%1), %0\n\t"
- :"=b"(value): "a" (addr_lo)
- );
- return value;
-}
-
-uint64_t read64_fs(uint32_t addr_lo)
-{
- uint64_t value = 0;
- uint32_t value_lo;
- uint32_t value_hi;
-
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "mfence\n\t"
- "movl %%fs:(%2), %0\n\t"
- "movl %%fs:(%3), %1\n\t"
- :"=c"(value_lo), "=d"(value_hi): "a" (addr_lo), "b" (addr_lo + 4) : "memory"
- );
- value |= value_lo;
- value |= ((uint64_t)value_hi) << 32;
- return value;
-}
-
-void FlushDQSTestPattern_L9(u32 addr_lo)
-{
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "clflush %%fs:-128(%%ecx)\n\t"
- "clflush %%fs:-64(%%ecx)\n\t"
- "clflush %%fs:(%%ecx)\n\t"
- "clflush %%fs:64(%%ecx)\n\t"
-
- "clflush %%fs:-128(%%eax)\n\t"
- "clflush %%fs:-64(%%eax)\n\t"
- "clflush %%fs:(%%eax)\n\t"
- "clflush %%fs:64(%%eax)\n\t"
-
- "clflush %%fs:-128(%%ebx)\n\t"
-
- :: "b" (addr_lo+128+8*64), "c"(addr_lo+128),
- "a"(addr_lo+128+4*64)
- );
-
-}
-
-__attribute__((noinline)) void FlushDQSTestPattern_L18(u32 addr_lo)
-{
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "clflush %%fs:-128(%%eax)\n\t"
- "clflush %%fs:-64(%%eax)\n\t"
- "clflush %%fs:(%%eax)\n\t"
- "clflush %%fs:64(%%eax)\n\t"
-
- "clflush %%fs:-128(%%edi)\n\t"
- "clflush %%fs:-64(%%edi)\n\t"
- "clflush %%fs:(%%edi)\n\t"
- "clflush %%fs:64(%%edi)\n\t"
-
- "clflush %%fs:-128(%%ebx)\n\t"
- "clflush %%fs:-64(%%ebx)\n\t"
- "clflush %%fs:(%%ebx)\n\t"
- "clflush %%fs:64(%%ebx)\n\t"
-
- "clflush %%fs:-128(%%ecx)\n\t"
- "clflush %%fs:-64(%%ecx)\n\t"
- "clflush %%fs:(%%ecx)\n\t"
- "clflush %%fs:64(%%ecx)\n\t"
-
- "clflush %%fs:-128(%%edx)\n\t"
- "clflush %%fs:-64(%%edx)\n\t"
-
- :: "b" (addr_lo+128+8*64), "c" (addr_lo+128+12*64),
- "d" (addr_lo +128+16*64), "a"(addr_lo+128),
- "D"(addr_lo+128+4*64)
- );
-}
-
-void ReadMaxRdLat1CLTestPattern_D(u32 addr)
-{
- SetUpperFSbase(addr);
-
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "movl %%fs:-128(%%esi), %%eax\n\t" /* TestAddr cache line */
- "movl %%fs:-64(%%esi), %%eax\n\t" /* +1 */
- "movl %%fs:(%%esi), %%eax\n\t" /* +2 */
- "mfence\n\t"
- :: "a"(0), "S"((addr<<8)+128)
- );
-
-}
-
-void WriteMaxRdLat1CLTestPattern_D(u32 buf, u32 addr)
-{
- uint32_t addr_phys = addr << 8;
- uint32_t step = 16;
- uint32_t count = 3 * 4;
-
- SetUpperFSbase(addr);
-
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "1:\n\t"
- "movdqa (%3), %%xmm0\n\t"
- "movntdq %%xmm0, %%fs:(%0)\n\t" /* xmm0 is 128 bit */
- "addl %1, %0\n\t"
- "addl %1, %3\n\t"
- "loop 1b\n\t"
- "mfence\n\t"
-
- : "+a" (addr_phys), "+d" (step), "+c" (count), "+b" (buf) : :
- );
-}
-
-void FlushMaxRdLatTestPattern_D(u32 addr)
-{
- /* Flush a pattern of 72 bit times (per DQ) from cache.
- * This procedure is used to ensure cache miss on the next read training.
- */
-
- SetUpperFSbase(addr);
-
- __asm__ volatile (
- "outb %%al, $0xed\n\t" /* _EXECFENCE */
- "clflush %%fs:-128(%%esi)\n\t" /* TestAddr cache line */
- "clflush %%fs:-64(%%esi)\n\t" /* +1 */
- "clflush %%fs:(%%esi)\n\t" /* +2 */
- "mfence\n\t"
-
- :: "S"((addr<<8)+128)
- );
-}
-
-u32 stream_to_int(u8 *p)
-{
- int i;
- u32 val;
- u32 valx;
-
- val = 0;
-
- for (i = 3; i >= 0; i--) {
- val <<= 8;
- valx = *(p+i);
- val |= valx;
- }
-
- return val;
-}
-
-u8 oemNodePresent_D(u8 Node, u8 *ret)
-{
- *ret = 0;
- return 0;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mct_d_gcc.h b/src/northbridge/amd/amdmct/mct_ddr3/mct_d_gcc.h
deleted file mode 100644
index 629e6e639b..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mct_d_gcc.h
+++ /dev/null
@@ -1,50 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-#ifndef MCT_D_GCC_H
-#define MCT_D_GCC_H
-
-#include <stdint.h>
-#include <cpu/x86/cr.h>
-
-void _WRMSR(u32 addr, u32 lo, u32 hi);
-void _RDMSR(u32 addr, u32 *lo, u32 *hi);
-void _RDTSC(u32 *lo, u32 *hi);
-void _cpu_id(u32 addr, u32 *val);
-u32 bsr(u32 x);
-u32 bsf(u32 x);
-#define _MFENCE asm volatile ("mfence")
-#define _SFENCE asm volatile ("sfence")
-
-/* prevent speculative execution of following instructions */
-#define _EXECFENCE asm volatile ("outb %al, $0xed")
-
-u32 SetUpperFSbase(u32 addr_hi);
-
-void proc_MFENCE(void);
-void proc_CLFLUSH(u32 addr_hi);
-void WriteLNTestPattern(u32 addr_lo, u8 *buf_a, u32 line_num);
-u32 read32_fs(u32 addr_lo);
-uint64_t read64_fs(uint32_t addr_lo);
-void FlushDQSTestPattern_L9(u32 addr_lo);
-__attribute__((noinline)) void FlushDQSTestPattern_L18(u32 addr_lo);
-void ReadMaxRdLat1CLTestPattern_D(u32 addr);
-void WriteMaxRdLat1CLTestPattern_D(u32 buf, u32 addr);
-void FlushMaxRdLatTestPattern_D(u32 addr);
-u32 stream_to_int(u8 *p);
-u8 oemNodePresent_D(u8 Node, u8 *ret);
-
-#endif
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctardk5.c b/src/northbridge/amd/amdmct/mct_ddr3/mctardk5.c
deleted file mode 100644
index e8116340c4..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctardk5.c
+++ /dev/null
@@ -1,100 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* AM3/ASB2/C32/G34 DDR3 */
-
-#include <arch/cpu.h>
-#include <stdint.h>
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-static void Get_ChannelPS_Cfg0_D(u8 MAAdimms, u8 Speed, u8 MAAload,
- u32 *ODC_CTL,
- u8 *CMDmode);
-
-void mctGet_PS_Cfg_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 dct)
-{
- if (is_fam15h()) {
- pDCTstat->CH_ADDR_TMG[dct] = fam15h_address_timing_compensation_code(pDCTstat, dct);
- pDCTstat->CH_ODC_CTL[dct] = fam15h_output_driver_compensation_code(pDCTstat, dct);
- pDCTstat->_2Tmode = fam15h_slow_access_mode(pDCTstat, dct);
- } else {
- Get_ChannelPS_Cfg0_D(pDCTstat->MAdimms[dct], pDCTstat->Speed,
- pDCTstat->MAload[dct],
- &(pDCTstat->CH_ODC_CTL[dct]),
- &pDCTstat->_2Tmode);
-
- if (pDCTstat->Status & (1 << SB_Registered)) {
- pDCTstat->_2Tmode = 1; /* Disable slow access mode */
- }
- pDCTstat->CH_ADDR_TMG[dct] = fam10h_address_timing_compensation_code(pDCTstat, dct);
-
- pDCTstat->CH_ODC_CTL[dct] |= 0x20000000; /* 60ohms */
- }
-
- pDCTstat->CH_EccDQSLike[0] = 0x0403;
- pDCTstat->CH_EccDQSScale[0] = 0x70;
- pDCTstat->CH_EccDQSLike[1] = 0x0403;
- pDCTstat->CH_EccDQSScale[1] = 0x70;
-}
-
-/*
- * In: MAAdimms - number of DIMMs on the channel
- * : Speed - Speed (see DCTStatstruc.Speed for definition)
- * : MAAload - number of address bus loads on the channel
- * Out: AddrTmgCTL - Address Timing Control Register Value
- * : ODC_CTL - Output Driver Compensation Control Register Value
- * : CMDmode - CMD mode
- */
-static void Get_ChannelPS_Cfg0_D(u8 MAAdimms, u8 Speed, u8 MAAload,
- u32 *ODC_CTL,
- u8 *CMDmode)
-{
- *ODC_CTL = 0;
- *CMDmode = 1;
-
- if (MAAdimms == 1) {
- *ODC_CTL = 0x00113222;
- *CMDmode = 1;
- } else /* if (MAAdimms == 0) */ {
- if (Speed == 4) {
- *CMDmode = 1;
- } else if (Speed == 5) {
- *CMDmode = 1;
- } else if (Speed == 6) {
- *CMDmode = 2;
- } else {
- *CMDmode = 2;
- }
- *ODC_CTL = 0x00223323;
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctardk6.c b/src/northbridge/amd/amdmct/mct_ddr3/mctardk6.c
deleted file mode 100644
index d6480ab91a..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctardk6.c
+++ /dev/null
@@ -1,114 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* The socket type Fr2, G (1207) are not tested.
- */
-
-static void Get_ChannelPS_Cfg0_D(u8 MAAdimms, u8 Speed, u8 MAAload,
- u8 DATAAload, u32 *AddrTmgCTL, u32 *ODC_CTL,
- u8 *CMDmode);
-
-
-void mctGet_PS_Cfg_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 dct)
-{
- Get_ChannelPS_Cfg0_D(pDCTstat->MAdimms[dct], pDCTstat->Speed,
- pDCTstat->MAload[dct], pDCTstat->DATAload[dct],
- &(pDCTstat->CH_ADDR_TMG[dct]), &(pDCTstat->CH_ODC_CTL[dct]),
- &pDCTstat->_2Tmode);
-
- if (pDCTstat->GangedMode == 1 && dct == 0)
- Get_ChannelPS_Cfg0_D(pDCTstat->MAdimms[1], pDCTstat->Speed,
- pDCTstat->MAload[1], pDCTstat->DATAload[1],
- &(pDCTstat->CH_ADDR_TMG[1]), &(pDCTstat->CH_ODC_CTL[1]),
- &pDCTstat->_2Tmode);
-
- pDCTstat->CH_EccDQSLike[0] = 0x0302;
- pDCTstat->CH_EccDQSLike[1] = 0x0302;
-
-}
-
-/*
- * In: MAAdimms - number of DIMMs on the channel
- * : Speed - Speed (see DCTStatstruc.Speed for definition)
- * : MAAload - number of address bus loads on the channel
- * : DATAAload - number of ranks on the channel
- * Out: AddrTmgCTL - Address Timing Control Register Value
- * : ODC_CTL - Output Driver Compensation Control Register Value
- * : CMDmode - CMD mode
- */
-static void Get_ChannelPS_Cfg0_D(u8 MAAdimms, u8 Speed, u8 MAAload,
- u8 DATAAload, u32 *AddrTmgCTL, u32 *ODC_CTL,
- u8 *CMDmode)
-{
- *AddrTmgCTL = 0;
- *ODC_CTL = 0;
- *CMDmode = 1;
-
- if (mctGet_NVbits(NV_MAX_DIMMS) == 4) {
- if (Speed == 4) {
- *AddrTmgCTL = 0x00000000;
- } else if (Speed == 5) {
- *AddrTmgCTL = 0x003C3C3C;
- if (MAAdimms > 1)
- *AddrTmgCTL = 0x003A3C3A;
- } else if (Speed == 6) {
- if (MAAdimms == 1)
- *AddrTmgCTL = 0x003A3A3A;
- else
- *AddrTmgCTL = 0x00383A38;
- } else {
- if (MAAdimms == 1)
- *AddrTmgCTL = 0x00373937;
- else
- *AddrTmgCTL = 0x00353935;
- }
- } else {
- if (Speed == 4) {
- *AddrTmgCTL = 0x00000000;
- if (MAAdimms == 3)
- *AddrTmgCTL = 0x00380038;
- } else if (Speed == 5) {
- if (MAAdimms == 1)
- *AddrTmgCTL = 0x003C3C3C;
- else if (MAAdimms == 2)
- *AddrTmgCTL = 0x003A3C3A;
- else
- *AddrTmgCTL = 0x00373C37;
- } else if (Speed == 6) {
- if (MAAdimms == 1)
- *AddrTmgCTL = 0x003A3A3A;
- else if (MAAdimms == 2)
- *AddrTmgCTL = 0x00383A38;
- else
- *AddrTmgCTL = 0x00343A34;
- } else {
- if (MAAdimms == 1)
- *AddrTmgCTL = 0x00393939;
- else if (MAAdimms == 2)
- *AddrTmgCTL = 0x00363936;
- else
- *AddrTmgCTL = 0x00303930;
- }
- }
-
- if ((MAAdimms == 1) && (MAAload < 4))
- *ODC_CTL = 0x20113222;
- else
- *ODC_CTL = 0x20223222;
-
- *CMDmode = 1;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctchi_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mctchi_d.c
deleted file mode 100644
index d458f3a48e..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctchi_d.c
+++ /dev/null
@@ -1,123 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-#include <console/console.h>
-
-void InterleaveChannels_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
-
- u8 Node;
- u32 DramBase, DctSelBase;
- u8 DctSelIntLvAddr, DctSelHi;
- u8 HoleValid = 0;
- u32 HoleSize, HoleBase = 0;
- u32 val, tmp;
- u32 dct0_size, dct1_size;
- struct DCTStatStruc *pDCTstat;
-
- /* HoleValid - indicates whether the current Node contains hole.
- * HoleSize - indicates whether there is IO hole in the whole system
- * memory.
- */
-
- /* call back to wrapper not needed ManualChannelInterleave_D(); */
- /* call back - DctSelIntLvAddr = mctGet_NVbits(NV_ChannelIntlv);*/ /* override interleave */
- /* Manually set: typ = 5, otherwise typ = 7. */
- DctSelIntLvAddr = mctGet_NVbits(NV_ChannelIntlv); /* typ = 5: Hash*: exclusive OR of address bits[20:16, 6]. */
-
- if (DctSelIntLvAddr & 1) {
- DctSelIntLvAddr >>= 1;
- HoleSize = 0;
- if ((pMCTstat->GStatus & (1 << GSB_SoftHole)) ||
- (pMCTstat->GStatus & (1 << GSB_HWHole))) {
- if (pMCTstat->HoleBase) {
- HoleBase = pMCTstat->HoleBase >> 8;
- HoleSize = HoleBase & 0xFFFF0000;
- HoleSize |= ((~HoleBase) + 1) & 0xFFFF;
- }
- }
- Node = 0;
- while (Node < MAX_NODES_SUPPORTED) {
- pDCTstat = pDCTstatA + Node;
- val = Get_NB32(pDCTstat->dev_map, 0xF0);
- if (val & (1 << DramHoleValid))
- HoleValid = 1;
- if (!pDCTstat->GangedMode && pDCTstat->DIMMValidDCT[0] && pDCTstat->DIMMValidDCT[1]) {
- DramBase = pDCTstat->NodeSysBase >> 8;
- dct1_size = ((pDCTstat->NodeSysLimit) + 2) >> 8;
- dct0_size = Get_NB32(pDCTstat->dev_dct, 0x114);
- if (dct0_size >= 0x10000) {
- dct0_size -= HoleSize;
- }
-
- dct0_size -= DramBase;
- dct1_size -= dct0_size;
- DctSelHi = 0x05; /* DctSelHiRngEn = 1, DctSelHi = 0 */
- if (dct1_size == dct0_size) {
- dct1_size = 0;
- DctSelHi = 0x04; /* DctSelHiRngEn = 0 */
- } else if (dct1_size > dct0_size) {
- dct1_size = dct0_size;
- DctSelHi = 0x07; /* DctSelHiRngEn = 1, DctSelHi = 1 */
- }
- dct0_size = dct1_size;
- dct0_size += DramBase;
- dct0_size += dct1_size;
- if (dct0_size >= HoleBase) /* if DctSelBaseAddr > HoleBase */
- dct0_size += HoleSize;
- DctSelBase = dct0_size;
-
- if (dct1_size == 0)
- dct0_size = 0;
- dct0_size -= dct1_size; /* DctSelBaseOffset = DctSelBaseAddr - Interleaved region */
- Set_NB32(pDCTstat->dev_dct, 0x114, dct0_size);
-
- if (dct1_size == 0)
- dct1_size = DctSelBase;
- val = Get_NB32(pDCTstat->dev_dct, 0x110);
- val &= 0x7F8;
- val |= dct1_size;
- val |= DctSelHi;
- val |= (DctSelIntLvAddr << 6) & 0xFF;
- Set_NB32(pDCTstat->dev_dct, 0x110, val);
-
- if (HoleValid) {
- tmp = DramBase;
- val = DctSelBase;
- if (val < HoleBase) { /* DctSelBaseAddr < DramHoleBase */
- val -= DramBase;
- val >>= 1;
- tmp += val;
- }
- tmp += HoleSize;
- val = Get_NB32(pDCTstat->dev_map, 0xF0); /* DramHoleOffset */
- val &= 0xFFFF007F;
- val |= (tmp & ~0xFFFF007F);
- Set_NB32(pDCTstat->dev_map, 0xF0, val);
- }
- }
- printk(BIOS_DEBUG, "InterleaveChannels_D: Node %x\n", Node);
- printk(BIOS_DEBUG, "InterleaveChannels_D: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "InterleaveChannels_D: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "InterleaveChannels_D: ErrCode %x\n", pDCTstat->ErrCode);
- Node++;
- }
- }
- printk(BIOS_DEBUG, "InterleaveChannels_D: Done\n\n");
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctcsi_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mctcsi_d.c
deleted file mode 100644
index 85e7930b24..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctcsi_d.c
+++ /dev/null
@@ -1,144 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* Low swap bit vs bank size encoding (physical, not logical address bit)
- * ;To calculate the number by hand, add the number of Bank address bits
- * ;(2 or 3) to the number of column address bits, plus 3 (the logical
- * ;page size), and subtract 8.
- */
-
-#include <stdint.h>
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-#include <console/console.h>
-
-static const u8 Tab_int_D[] = {6,7,7,8,8,8,8,8,9,9,8,9};
-
-void InterleaveBanks_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 ChipSel, EnChipSels;
- u32 AddrLoMask, AddrHiMask;
- u32 AddrLoMaskN, AddrHiMaskN, MemSize = 0;
- u8 DoIntlv, _CsIntCap;
- u32 BitDelta, BankEncd = 0;
-
- u32 dev;
- u32 reg;
- u32 val;
- u32 val_lo, val_hi;
-
- DoIntlv = mctGet_NVbits(NV_BankIntlv);
- _CsIntCap = 0;
- EnChipSels = 0;
-
- dev = pDCTstat->dev_dct;
-
- ChipSel = 0; /* Find out if current configuration is capable */
- while (DoIntlv && (ChipSel < MAX_CS_SUPPORTED)) {
- reg = 0x40+(ChipSel<<2); /* Dram CS Base 0 */
- val = Get_NB32_DCT(dev, dct, reg);
- if (val & (1<<CSEnable)) {
- EnChipSels++;
- reg = 0x60+((ChipSel>>1)<<2); /*Dram CS Mask 0 */
- val = Get_NB32_DCT(dev, dct, reg);
- val >>= 19;
- val &= 0x3ff;
- val++;
- if (EnChipSels == 1)
- MemSize = val;
- else
- /*If mask sizes not same then skip */
- if (val != MemSize)
- break;
- reg = 0x80; /*Dram Bank Addressing */
- val = Get_NB32_DCT(dev, dct, reg);
- val >>= (ChipSel>>1)<<2;
- val &= 0x0f;
- if (EnChipSels == 1)
- BankEncd = val;
- else
- /*If number of Rows/Columns not equal, skip */
- if (val != BankEncd)
- break;
- }
- ChipSel++;
- }
- if (ChipSel == MAX_CS_SUPPORTED) {
- if ((EnChipSels == 2) || (EnChipSels == 4) || (EnChipSels == 8))
- _CsIntCap = 1;
- }
-
- if (DoIntlv) {
- if (!_CsIntCap) {
- pDCTstat->ErrStatus |= 1<<SB_BkIntDis;
- DoIntlv = 0;
- }
- }
-
- if (DoIntlv) {
- val = Tab_int_D[BankEncd];
- if (pDCTstat->Status & (1<<SB_128bitmode))
- val++;
-
- AddrLoMask = (EnChipSels - 1) << val;
- AddrLoMaskN = ~AddrLoMask;
-
- val = bsf(MemSize) + 19;
- AddrHiMask = (EnChipSels -1) << val;
- AddrHiMaskN = ~AddrHiMask;
-
- BitDelta = bsf(AddrHiMask) - bsf(AddrLoMask);
-
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel++) {
- reg = 0x40 + (ChipSel<<2); /* Dram CS Base 0 */
- val = Get_NB32_DCT(dev, dct, reg);
- if (val & 3) {
- val_lo = val & AddrLoMask;
- val_hi = val & AddrHiMask;
- val &= AddrLoMaskN;
- val &= AddrHiMaskN;
- val_lo <<= BitDelta;
- val_hi >>= BitDelta;
- val |= val_lo;
- val |= val_hi;
- Set_NB32_DCT(dev, dct, reg, val);
-
- if (ChipSel & 1)
- continue;
-
- reg = 0x60 + ((ChipSel>>1)<<2); /* Dram CS Mask 0 */
- val = Get_NB32_DCT(dev, dct, reg);
- val_lo = val & AddrLoMask;
- val_hi = val & AddrHiMask;
- val &= AddrLoMaskN;
- val &= AddrHiMaskN;
- val_lo <<= BitDelta;
- val_hi >>= BitDelta;
- val |= val_lo;
- val |= val_hi;
- Set_NB32_DCT(dev, dct, reg, val);
- }
- }
- } /* DoIntlv */
-
- /* dump_pci_device(PCI_DEV(0, 0x18+pDCTstat->Node_ID, 2)); */
-
- printk(BIOS_DEBUG, "InterleaveBanks_D: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "InterleaveBanks_D: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "InterleaveBanks_D: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "InterleaveBanks_D: Done\n\n");
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctdqs_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mctdqs_d.c
deleted file mode 100644
index d34b2dc2ba..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctdqs_d.c
+++ /dev/null
@@ -1,2493 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 - 2016 Raptor Engineering, LLC
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include <console/console.h>
-#include <cpu/x86/cr.h>
-#include <string.h>
-#include <arch/cpu.h>
-#include <cpu/amd/msr.h>
-#include <cpu/amd/mtrr.h>
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static void CalcEccDQSPos_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u16 like,
- u8 scale, u8 ChipSel);
-static void GetDQSDatStrucVal_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel);
-static void WriteDQSTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo);
-static void WriteL18TestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo);
-static void WriteL9TestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo);
-static u16 CompareDQSTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 addr_lo);
-static void FlushDQSTestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 addr_lo);
-static void mct_SetDQSDelayCSR_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 ChipSel);
-static void SetupDqsPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 *buffer);
-
-static void StoreDQSDatStrucVal_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u8 ChipSel);
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-#define DQS_TRAIN_DEBUG 0
-// #define PRINT_PASS_FAIL_BITMAPS 1
-
-void print_debug_dqs(const char *str, u32 val, u8 level)
-{
-#if DQS_TRAIN_DEBUG > 0
- if (DQS_TRAIN_DEBUG >= level) {
- printk(BIOS_DEBUG, "%s%x\n", str, val);
- }
-#endif
-}
-
-void print_debug_dqs_pair(const char *str, u32 val, const char *str2, u32 val2, u8 level)
-{
-#if DQS_TRAIN_DEBUG > 0
- if (DQS_TRAIN_DEBUG >= level) {
- printk(BIOS_DEBUG, "%s%08x%s%08x\n", str, val, str2, val2);
- }
-#endif
-}
-
-/*Warning: These must be located so they do not cross a logical 16-bit segment boundary!*/
-static const u32 TestPatternJD1a_D[] = {
- 0x00000000,0x00000000,0xFFFFFFFF,0xFFFFFFFF, /* QW0-1, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW2-3, ALL-EVEN */
- 0x00000000,0x00000000,0xFFFFFFFF,0xFFFFFFFF, /* QW4-5, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW6-7, ALL-EVEN */
- 0xFeFeFeFe,0xFeFeFeFe,0x01010101,0x01010101, /* QW0-1, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0x01010101,0x01010101, /* QW2-3, DQ0-ODD */
- 0x01010101,0x01010101,0xFeFeFeFe,0xFeFeFeFe, /* QW4-5, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0x01010101,0x01010101, /* QW6-7, DQ0-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW0-1, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd, /* QW2-3, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0x02020202,0x02020202, /* QW4-5, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW6-7, DQ1-ODD */
- 0x04040404,0x04040404,0xfBfBfBfB,0xfBfBfBfB, /* QW0-1, DQ2-ODD */
- 0x04040404,0x04040404,0x04040404,0x04040404, /* QW2-3, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW4-5, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW6-7, DQ2-ODD */
- 0x08080808,0x08080808,0xF7F7F7F7,0xF7F7F7F7, /* QW0-1, DQ3-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW2-3, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0x08080808,0x08080808, /* QW4-5, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW6-7, DQ3-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW0-1, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0x10101010,0x10101010, /* QW2-3, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW4-5, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0x10101010,0x10101010, /* QW6-7, DQ4-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW0-1, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0x20202020,0x20202020, /* QW2-3, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW4-5, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW6-7, DQ5-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW0-1, DQ6-ODD */
- 0x40404040,0x40404040,0xBfBfBfBf,0xBfBfBfBf, /* QW2-3, DQ6-ODD */
- 0x40404040,0x40404040,0xBfBfBfBf,0xBfBfBfBf, /* QW4-5, DQ6-ODD */
- 0x40404040,0x40404040,0xBfBfBfBf,0xBfBfBfBf, /* QW6-7, DQ6-ODD */
- 0x80808080,0x80808080,0x7F7F7F7F,0x7F7F7F7F, /* QW0-1, DQ7-ODD */
- 0x80808080,0x80808080,0x7F7F7F7F,0x7F7F7F7F, /* QW2-3, DQ7-ODD */
- 0x80808080,0x80808080,0x7F7F7F7F,0x7F7F7F7F, /* QW4-5, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080 /* QW6-7, DQ7-ODD */
-};
-static const u32 TestPatternJD1b_D[] = {
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW0,CHA-B, ALL-EVEN */
- 0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF, /* QW1,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW2,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW3,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW4,CHA-B, ALL-EVEN */
- 0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF,0xFFFFFFFF, /* QW5,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW6,CHA-B, ALL-EVEN */
- 0x00000000,0x00000000,0x00000000,0x00000000, /* QW7,CHA-B, ALL-EVEN */
- 0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe, /* QW0,CHA-B, DQ0-ODD */
- 0x01010101,0x01010101,0x01010101,0x01010101, /* QW1,CHA-B, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe, /* QW2,CHA-B, DQ0-ODD */
- 0x01010101,0x01010101,0x01010101,0x01010101, /* QW3,CHA-B, DQ0-ODD */
- 0x01010101,0x01010101,0x01010101,0x01010101, /* QW4,CHA-B, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe, /* QW5,CHA-B, DQ0-ODD */
- 0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe,0xFeFeFeFe, /* QW6,CHA-B, DQ0-ODD */
- 0x01010101,0x01010101,0x01010101,0x01010101, /* QW7,CHA-B, DQ0-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW0,CHA-B, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW1,CHA-B, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd, /* QW2,CHA-B, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd, /* QW3,CHA-B, DQ1-ODD */
- 0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd,0xFdFdFdFd, /* QW4,CHA-B, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW5,CHA-B, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW6,CHA-B, DQ1-ODD */
- 0x02020202,0x02020202,0x02020202,0x02020202, /* QW7,CHA-B, DQ1-ODD */
- 0x04040404,0x04040404,0x04040404,0x04040404, /* QW0,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW1,CHA-B, DQ2-ODD */
- 0x04040404,0x04040404,0x04040404,0x04040404, /* QW2,CHA-B, DQ2-ODD */
- 0x04040404,0x04040404,0x04040404,0x04040404, /* QW3,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW4,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW5,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW6,CHA-B, DQ2-ODD */
- 0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB,0xfBfBfBfB, /* QW7,CHA-B, DQ2-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW0,CHA-B, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW1,CHA-B, DQ3-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW2,CHA-B, DQ3-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW3,CHA-B, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW4,CHA-B, DQ3-ODD */
- 0x08080808,0x08080808,0x08080808,0x08080808, /* QW5,CHA-B, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW6,CHA-B, DQ3-ODD */
- 0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7,0xF7F7F7F7, /* QW7,CHA-B, DQ3-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW0,CHA-B, DQ4-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW1,CHA-B, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW2,CHA-B, DQ4-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW3,CHA-B, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW4,CHA-B, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW5,CHA-B, DQ4-ODD */
- 0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF,0xeFeFeFeF, /* QW6,CHA-B, DQ4-ODD */
- 0x10101010,0x10101010,0x10101010,0x10101010, /* QW7,CHA-B, DQ4-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW0,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW1,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW2,CHA-B, DQ5-ODD */
- 0x20202020,0x20202020,0x20202020,0x20202020, /* QW3,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW4,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW5,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW6,CHA-B, DQ5-ODD */
- 0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF,0xdFdFdFdF, /* QW7,CHA-B, DQ5-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW0,CHA-B, DQ6-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW1,CHA-B, DQ6-ODD */
- 0x40404040,0x40404040,0x40404040,0x40404040, /* QW2,CHA-B, DQ6-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW3,CHA-B, DQ6-ODD */
- 0x40404040,0x40404040,0x40404040,0x40404040, /* QW4,CHA-B, DQ6-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW5,CHA-B, DQ6-ODD */
- 0x40404040,0x40404040,0x40404040,0x40404040, /* QW6,CHA-B, DQ6-ODD */
- 0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf,0xBfBfBfBf, /* QW7,CHA-B, DQ6-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080, /* QW0,CHA-B, DQ7-ODD */
- 0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F, /* QW1,CHA-B, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080, /* QW2,CHA-B, DQ7-ODD */
- 0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F, /* QW3,CHA-B, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080, /* QW4,CHA-B, DQ7-ODD */
- 0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F,0x7F7F7F7F, /* QW5,CHA-B, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080, /* QW6,CHA-B, DQ7-ODD */
- 0x80808080,0x80808080,0x80808080,0x80808080 /* QW7,CHA-B, DQ7-ODD */
-};
-
-void TrainReceiverEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA, u8 Pass)
-{
- u8 Node;
- struct DCTStatStruc *pDCTstat;
- u32 val;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->DCTSysLimit) {
- if (!is_fam15h()) {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x78);
- val |= 1 <<DqsRcvEnTrain;
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x78, val);
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x78);
- val |= 1 <<DqsRcvEnTrain;
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x78, val);
- }
- mct_TrainRcvrEn_D(pMCTstat, pDCTstat, Pass);
- }
- }
-}
-
-void TrainMaxRdLatency_En_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- uint8_t node;
- struct DCTStatStruc *pDCTstat;
-
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- pDCTstat = pDCTstatA + node;
-
- if (pDCTstat->DCTSysLimit) {
- if (is_fam15h()) {
- dqsTrainMaxRdLatency_SW_Fam15(pMCTstat, pDCTstat);
- } else {
- /* FIXME
- * Implement Family 10h MaxRdLatency training
- */
- }
- }
- }
-}
-
-static void SetEccDQSRdWrPos_D_Fam10(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel)
-{
- u8 channel;
- u8 direction;
-
- for (channel = 0; channel < 2; channel++) {
- for (direction = 0; direction < 2; direction++) {
- pDCTstat->Channel = channel; /* Channel A or B */
- pDCTstat->Direction = direction; /* Read or write */
- CalcEccDQSPos_D(pMCTstat, pDCTstat, pDCTstat->CH_EccDQSLike[channel], pDCTstat->CH_EccDQSScale[channel], ChipSel);
- print_debug_dqs_pair("\t\tSetEccDQSRdWrPos: channel ", channel, direction == DQS_READDIR? " R dqs_delay":" W dqs_delay", pDCTstat->DQSDelay, 2);
- pDCTstat->ByteLane = 8;
- StoreDQSDatStrucVal_D(pMCTstat, pDCTstat, ChipSel);
- mct_SetDQSDelayCSR_D(pMCTstat, pDCTstat, ChipSel);
- }
- }
-}
-
-static void CalcEccDQSPos_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u16 like, u8 scale, u8 ChipSel)
-{
- uint8_t DQSDelay0, DQSDelay1;
- int16_t delay_differential;
- uint16_t DQSDelay;
-
- if (pDCTstat->Status & (1 << SB_Registered)) {
- pDCTstat->ByteLane = 0x2;
- GetDQSDatStrucVal_D(pMCTstat, pDCTstat, ChipSel);
- DQSDelay0 = pDCTstat->DQSDelay;
-
- pDCTstat->ByteLane = 0x3;
- GetDQSDatStrucVal_D(pMCTstat, pDCTstat, ChipSel);
- DQSDelay1 = pDCTstat->DQSDelay;
-
- if (pDCTstat->Direction == DQS_READDIR) {
- DQSDelay = DQSDelay1;
- } else {
- delay_differential = (int16_t)DQSDelay1 - (int16_t)DQSDelay0;
- delay_differential += (int16_t)DQSDelay1;
-
- DQSDelay = delay_differential;
- }
- } else {
- pDCTstat->ByteLane = like & 0xff;
- GetDQSDatStrucVal_D(pMCTstat, pDCTstat, ChipSel);
- DQSDelay0 = pDCTstat->DQSDelay;
-
- pDCTstat->ByteLane = (like >> 8) & 0xff;
- GetDQSDatStrucVal_D(pMCTstat, pDCTstat, ChipSel);
- DQSDelay1 = pDCTstat->DQSDelay;
-
- if (DQSDelay0 > DQSDelay1) {
- DQSDelay = DQSDelay0 - DQSDelay1;
- } else {
- DQSDelay = DQSDelay1 - DQSDelay0;
- }
-
- DQSDelay = DQSDelay * (~scale);
-
- DQSDelay += 0x80; /* round it */
-
- DQSDelay >>= 8; /* 256 */
-
- if (DQSDelay0 > DQSDelay1) {
- DQSDelay = DQSDelay1 - DQSDelay;
- } else {
- DQSDelay += DQSDelay1;
- }
- }
-
- pDCTstat->DQSDelay = (u8)DQSDelay;
-}
-
-static void read_dqs_write_data_timing_registers(uint16_t *delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint32_t dword;
- uint32_t mask;
-
- if (is_fam15h())
- mask = 0xff;
- else
- mask = 0x7f;
-
- /* Lanes 0 - 3 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x1 | (dimm << 8));
- delay[3] = (dword >> 24) & mask;
- delay[2] = (dword >> 16) & mask;
- delay[1] = (dword >> 8) & mask;
- delay[0] = dword & mask;
-
- /* Lanes 4 - 7 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x2 | (dimm << 8));
- delay[7] = (dword >> 24) & mask;
- delay[6] = (dword >> 16) & mask;
- delay[5] = (dword >> 8) & mask;
- delay[4] = dword & mask;
-
- /* Lane 8 (ECC) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x3 | (dimm << 8));
- delay[8] = dword & mask;
-}
-
-static void write_dqs_write_data_timing_registers(uint16_t *delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint32_t dword;
- uint32_t mask;
-
- if (is_fam15h())
- mask = 0xff;
- else
- mask = 0x7f;
-
- /* Lanes 0 - 3 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x1 | (dimm << 8));
- dword &= ~(mask << 24);
- dword &= ~(mask << 16);
- dword &= ~(mask << 8);
- dword &= ~mask;
- dword |= (delay[3] & mask) << 24;
- dword |= (delay[2] & mask) << 16;
- dword |= (delay[1] & mask) << 8;
- dword |= delay[0] & mask;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x1 | (dimm << 8), dword);
-
- /* Lanes 4 - 7 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x2 | (dimm << 8));
- dword &= ~(mask << 24);
- dword &= ~(mask << 16);
- dword &= ~(mask << 8);
- dword &= ~mask;
- dword |= (delay[7] & mask) << 24;
- dword |= (delay[6] & mask) << 16;
- dword |= (delay[5] & mask) << 8;
- dword |= delay[4] & mask;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x2 | (dimm << 8), dword);
-
- /* Lane 8 (ECC) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x3 | (dimm << 8));
- dword &= ~mask;
- dword |= delay[8] & mask;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x3 | (dimm << 8), dword);
-}
-
-/* DQS Position Training
- * Algorithm detailed in the Fam10h BKDG Rev. 3.62 section 2.8.9.9.3
- */
-static void TrainDQSRdWrPos_D_Fam10(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 Errors;
- u8 Channel;
- u8 Receiver;
- u8 _DisableDramECC = 0;
- u32 PatternBuffer[304]; /* 288 + 16 */
- u8 _Wrap32Dis = 0, _SSE2 = 0;
-
- u32 dev;
- u32 addr;
- u8 valid;
- CRx_TYPE cr4;
- u32 lo, hi;
- u32 index_reg;
- uint32_t TestAddr;
-
- uint8_t dual_rank;
- uint8_t iter;
- uint8_t lane;
- uint16_t bytelane_test_results;
- uint16_t current_write_dqs_delay[MAX_BYTE_LANES];
- uint16_t current_read_dqs_delay[MAX_BYTE_LANES];
- uint16_t write_dqs_delay_stepping_done[MAX_BYTE_LANES];
- uint8_t dqs_read_results_array[2][MAX_BYTE_LANES][64]; /* [rank][lane][step] */
- uint8_t dqs_write_results_array[2][MAX_BYTE_LANES][128]; /* [rank][lane][step] */
-
- uint8_t last_pos = 0;
- uint8_t cur_count = 0;
- uint8_t best_pos = 0;
- uint8_t best_count = 0;
-
- print_debug_dqs("\nTrainDQSRdWrPos: Node_ID ", pDCTstat->Node_ID, 0);
- cr4 = read_cr4();
- if (cr4 & (1<<9)) {
- _SSE2 = 1;
- }
- cr4 |= (1<<9); /* OSFXSR enable SSE2 */
- write_cr4(cr4);
-
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- if (lo & (1<<17)) {
- _Wrap32Dis = 1;
- }
- lo |= (1<<17); /* HWCR.wrap32dis */
- _WRMSR(addr, lo, hi); /* allow 64-bit memory references in real mode */
-
- /* Disable ECC correction of reads on the dram bus. */
- _DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
-
- SetupDqsPattern_D(pMCTstat, pDCTstat, PatternBuffer);
-
- /* mct_BeforeTrainDQSRdWrPos_D */
-
- dev = pDCTstat->dev_dct;
- pDCTstat->Direction = DQS_READDIR;
-
- /* 2.8.9.9.3 (2)
- * Loop over each channel, lane, and rank
- */
-
- /* NOTE
- * The BKDG originally stated to iterate over lane, then rank, however this process is quite slow
- * compared to an equivalent loop over rank, then lane as the latter allows multiple lanes to be
- * tested simultaneously, thus improving performance by around 8x.
- */
-
- Errors = 0;
- for (Channel = 0; Channel < 2; Channel++) {
- print_debug_dqs("\tTrainDQSRdWrPos: 1 Channel ", Channel, 1);
- pDCTstat->Channel = Channel;
-
- if (pDCTstat->DIMMValidDCT[Channel] == 0) /* mct_BeforeTrainDQSRdWrPos_D */
- continue;
-
- index_reg = 0x98;
-
- dual_rank = 0;
- Receiver = mct_InitReceiver_D(pDCTstat, Channel);
- /* There are four receiver pairs, loosely associated with chipselects.
- * This is essentially looping over each rank of each DIMM.
- */
- for (; Receiver < 8; Receiver++) {
- if ((Receiver & 0x1) == 0) {
- /* Even rank of DIMM */
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, Receiver+1))
- dual_rank = 1;
- else
- dual_rank = 0;
- }
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, Receiver)) {
- continue;
- }
-
- /* Select the base test address for the current rank */
- TestAddr = mct_GetMCTSysAddr_D(pMCTstat, pDCTstat, Channel, Receiver, &valid);
- if (!valid) { /* Address not supported on current CS */
- continue;
- }
-
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 14 TestAddr ", TestAddr, 4);
- SetUpperFSbase(TestAddr); /* fs:eax = far ptr to target */
-
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 12 Receiver ", Receiver, 2);
-
- /* 2.8.9.9.3 (DRAM Write Data Timing Loop)
- * Iterate over all possible DQS delay values (0x0 - 0x7f)
- */
- uint8_t test_write_dqs_delay = 0;
- uint8_t test_read_dqs_delay = 0;
- uint8_t passing_dqs_delay_found[MAX_BYTE_LANES];
-
- /* Initialize variables */
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- current_write_dqs_delay[lane] = 0;
- passing_dqs_delay_found[lane] = 0;
- write_dqs_delay_stepping_done[lane] = 0;
- }
-
- for (test_write_dqs_delay = 0; test_write_dqs_delay < 128; test_write_dqs_delay++) {
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 16 test_write_dqs_delay ", test_write_dqs_delay, 6);
-
- /* Break out of loop if passing window already found, */
- if (write_dqs_delay_stepping_done[0] && write_dqs_delay_stepping_done[1]
- && write_dqs_delay_stepping_done[2] && write_dqs_delay_stepping_done[3]
- && write_dqs_delay_stepping_done[4] && write_dqs_delay_stepping_done[5]
- && write_dqs_delay_stepping_done[6] && write_dqs_delay_stepping_done[7])
- break;
-
- /* Commit the current Write Data Timing settings to the hardware registers */
- write_dqs_write_data_timing_registers(current_write_dqs_delay, dev, Channel, (Receiver >> 1), index_reg);
-
- /* Write the DRAM training pattern to the base test address */
- WriteDQSTestPattern_D(pMCTstat, pDCTstat, TestAddr << 8);
-
- /* 2.8.9.9.3 (DRAM Read DQS Timing Control Loop)
- * Iterate over all possible DQS delay values (0x0 - 0x3f)
- */
- for (test_read_dqs_delay = 0; test_read_dqs_delay < 64; test_read_dqs_delay++) {
- print_debug_dqs("\t\t\t\t\tTrainDQSRdWrPos: 161 test_read_dqs_delay ", test_read_dqs_delay, 6);
-
- /* Initialize Read DQS Timing Control settings for this iteration */
- for (lane = 0; lane < MAX_BYTE_LANES; lane++)
- if (!write_dqs_delay_stepping_done[lane])
- current_read_dqs_delay[lane] = test_read_dqs_delay;
-
- /* Commit the current Read DQS Timing Control settings to the hardware registers */
- write_dqs_read_data_timing_registers(current_read_dqs_delay, dev, Channel, (Receiver >> 1), index_reg);
-
- /* Initialize test result variable */
- bytelane_test_results = 0xff;
-
- /* Read the DRAM training pattern from the base test address three times
- * NOTE
- * While the BKDG states to read three times this is probably excessive!
- * Decrease training time by only reading the test pattern once per iteration
- */
- for (iter = 0; iter < 1; iter++) {
- /* Flush caches */
- SetTargetWTIO_D(TestAddr);
- FlushDQSTestPattern_D(pDCTstat, TestAddr << 8);
- ResetTargetWTIO_D();
-
- /* Read and compare pattern */
- bytelane_test_results &= (CompareDQSTestPattern_D(pMCTstat, pDCTstat, TestAddr << 8) & 0xff); /* [Lane 7 :: Lane 0] 0 = fail, 1 = pass */
-
- /* If all lanes have already failed testing bypass remaining re-read attempt(s) */
- if (bytelane_test_results == 0x0)
- break;
- }
-
- /* Store any lanes that passed testing for later use */
- for (lane = 0; lane < 8; lane++)
- if (!write_dqs_delay_stepping_done[lane])
- dqs_read_results_array[Receiver & 0x1][lane][test_read_dqs_delay] = (!!(bytelane_test_results & (1 << lane)));
-
- print_debug_dqs("\t\t\t\t\tTrainDQSRdWrPos: 162 bytelane_test_results ", bytelane_test_results, 6);
- }
-
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- if (write_dqs_delay_stepping_done[lane])
- continue;
-
- /* Determine location and length of longest consecutive string of passing values
- * Output is stored in best_pos and best_count
- */
- last_pos = 0;
- cur_count = 0;
- best_pos = 0;
- best_count = 0;
- for (iter = 0; iter < 64; iter++) {
- if ((dqs_read_results_array[Receiver & 0x1][lane][iter]) && (iter < 63)) {
- /* Pass */
- cur_count++;
- } else {
- /* Failure or end of loop */
- if (cur_count > best_count) {
- best_count = cur_count;
- best_pos = last_pos;
- }
- cur_count = 0;
- last_pos = iter;
- }
- }
-
- if (best_count > 2) {
- /* Exit the DRAM Write Data Timing Loop after programming the Read DQS Timing Control
- * register with the center of the passing window
- */
- current_read_dqs_delay[lane] = (best_pos + (best_count / 2));
- passing_dqs_delay_found[lane] = 1;
-
- /* Commit the current Read DQS Timing Control settings to the hardware registers */
- write_dqs_read_data_timing_registers(current_read_dqs_delay, dev, Channel, (Receiver >> 1), index_reg);
-
- /* Exit the DRAM Write Data Timing Loop */
- write_dqs_delay_stepping_done[lane] = 1;
-
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 142 largest passing region ", best_count, 4);
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 143 largest passing region start ", best_pos, 4);
- }
-
- /* Increment the DQS Write Delay value if needed for the next DRAM Write Data Timing Loop iteration */
- if (!write_dqs_delay_stepping_done[lane])
- current_write_dqs_delay[lane]++;
- }
- }
-
- /* Flag failure(s) if present */
- for (lane = 0; lane < 8; lane++) {
- if (!passing_dqs_delay_found[lane]) {
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 121 Unable to find passing region for lane ", lane, 2);
-
- /* Flag absence of passing window */
- Errors |= 1 << SB_NODQSPOS;
- }
- }
-
- /* Iterate over all possible Write Data Timing values (0x0 - 0x7f)
- * Note that the Read DQS Timing Control was calibrated / centered in the prior nested loop
- */
- for (test_write_dqs_delay = 0; test_write_dqs_delay < 128; test_write_dqs_delay++) {
- /* Initialize Write Data Timing settings for this iteration */
- for (lane = 0; lane < MAX_BYTE_LANES; lane++)
- current_write_dqs_delay[lane] = test_write_dqs_delay;
-
- /* Commit the current Write Data Timing settings to the hardware registers */
- write_dqs_write_data_timing_registers(current_write_dqs_delay, dev, Channel, (Receiver >> 1), index_reg);
-
- /* Write the DRAM training pattern to the base test address */
- WriteDQSTestPattern_D(pMCTstat, pDCTstat, TestAddr << 8);
-
- /* Flush caches */
- SetTargetWTIO_D(TestAddr);
- FlushDQSTestPattern_D(pDCTstat, TestAddr << 8);
- ResetTargetWTIO_D();
-
- /* Read and compare pattern from the base test address */
- bytelane_test_results = (CompareDQSTestPattern_D(pMCTstat, pDCTstat, TestAddr << 8) & 0xff); /* [Lane 7 :: Lane 0] 0 = fail, 1 = pass */
-
- /* Store any lanes that passed testing for later use */
- for (lane = 0; lane < 8; lane++)
- dqs_write_results_array[Receiver & 0x1][lane][test_write_dqs_delay] = (!!(bytelane_test_results & (1 << lane)));
- }
-
- for (lane = 0; lane < 8; lane++) {
- if ((!dual_rank) || (dual_rank && (Receiver & 0x1))) {
-
-#ifdef PRINT_PASS_FAIL_BITMAPS
- for (iter = 0; iter < 64; iter++) {
- if (dqs_read_results_array[0][lane][iter])
- printk(BIOS_DEBUG, "+");
- else
- printk(BIOS_DEBUG, ".");
- }
- printk(BIOS_DEBUG, "\n");
- for (iter = 0; iter < 64; iter++) {
- if (dqs_read_results_array[1][lane][iter])
- printk(BIOS_DEBUG, "+");
- else
- printk(BIOS_DEBUG, ".");
- }
- printk(BIOS_DEBUG, "\n\n");
- for (iter = 0; iter < 128; iter++) {
- if (dqs_write_results_array[0][lane][iter])
- printk(BIOS_DEBUG, "+");
- else
- printk(BIOS_DEBUG, ".");
- }
- printk(BIOS_DEBUG, "\n");
- for (iter = 0; iter < 128; iter++) {
- if (dqs_write_results_array[1][lane][iter])
- printk(BIOS_DEBUG, "+");
- else
- printk(BIOS_DEBUG, ".");
- }
- printk(BIOS_DEBUG, "\n\n");
-#endif
-
- /* Base rank of single-rank DIMM, or odd rank of dual-rank DIMM */
- if (dual_rank) {
- /* Intersect the passing windows of both ranks */
- for (iter = 0; iter < 64; iter++)
- if (!dqs_read_results_array[1][lane][iter])
- dqs_read_results_array[0][lane][iter] = 0;
- for (iter = 0; iter < 128; iter++)
- if (!dqs_write_results_array[1][lane][iter])
- dqs_write_results_array[0][lane][iter] = 0;
- }
-
- /* Determine location and length of longest consecutive string of passing values for read DQS timing
- * Output is stored in best_pos and best_count
- */
- last_pos = 0;
- cur_count = 0;
- best_pos = 0;
- best_count = 0;
- for (iter = 0; iter < 64; iter++) {
- if ((dqs_read_results_array[0][lane][iter]) && (iter < 63)) {
- /* Pass */
- cur_count++;
- } else {
- /* Failure or end of loop */
- if (cur_count > best_count) {
- best_count = cur_count;
- best_pos = last_pos;
- }
- cur_count = 0;
- last_pos = iter;
- }
- }
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 144 largest read passing region ", best_count, 4);
- if (best_count > 0) {
- if (best_count < MIN_DQS_WNDW) {
- /* Flag excessively small passing window */
- Errors |= 1 << SB_SMALLDQS;
- }
-
- /* Find the center of the passing window */
- current_read_dqs_delay[lane] = (best_pos + (best_count / 2));
-
- /* Commit the current Read DQS Timing Control settings to the hardware registers */
- write_dqs_read_data_timing_registers(current_read_dqs_delay, dev, Channel, (Receiver >> 1), index_reg);
-
- /* Save the final Read DQS Timing Control settings for later use */
- pDCTstat->CH_D_DIR_B_DQS[Channel][Receiver >> 1][DQS_READDIR][lane] = current_read_dqs_delay[lane];
- } else {
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 122 Unable to find read passing region for lane ", lane, 2);
-
- /* Flag absence of passing window */
- Errors |= 1 << SB_NODQSPOS;
- }
-
- /* Determine location and length of longest consecutive string of passing values for write DQS timing
- * Output is stored in best_pos and best_count
- */
- last_pos = 0;
- cur_count = 0;
- best_pos = 0;
- best_count = 0;
- for (iter = 0; iter < 128; iter++) {
- if ((dqs_write_results_array[0][lane][iter]) && (iter < 127)) {
- /* Pass */
- cur_count++;
- } else {
- /* Failure or end of loop */
- if (cur_count > best_count) {
- best_count = cur_count;
- best_pos = last_pos;
- }
- cur_count = 0;
- last_pos = iter;
- }
- }
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 145 largest write passing region ", best_count, 4);
- if (best_count > 0) {
- if (best_count < MIN_DQS_WNDW) {
- /* Flag excessively small passing window */
- Errors |= 1 << SB_SMALLDQS;
- }
-
- /* Find the center of the passing window */
- current_write_dqs_delay[lane] = (best_pos + (best_count / 2));
-
- /* Commit the current Write Data Timing settings to the hardware registers */
- write_dqs_write_data_timing_registers(current_write_dqs_delay, dev, Channel, (Receiver >> 1), index_reg);
-
- /* Save the final Write Data Timing settings for later use */
- pDCTstat->CH_D_DIR_B_DQS[Channel][Receiver >> 1][DQS_WRITEDIR][lane] = current_write_dqs_delay[lane];
- } else {
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 123 Unable to find write passing region for lane ", lane, 2);
-
- /* Flag absence of passing window */
- Errors |= 1 << SB_NODQSPOS;
- }
- }
- }
-
- }
- }
-
- pDCTstat->TrainErrors |= Errors;
- pDCTstat->ErrStatus |= Errors;
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 val;
- u8 i;
- u8 ChannelDTD, ReceiverDTD, Dir;
- u8 *p;
-
- for (Dir = 0; Dir < 2; Dir++) {
- if (Dir == 1) {
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: CH_D_DIR_B_DQS WR:\n");
- } else {
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: CH_D_DIR_B_DQS RD:\n");
- }
- for (ChannelDTD = 0; ChannelDTD < 2; ChannelDTD++) {
- printk(BIOS_DEBUG, "Channel: %02x\n", ChannelDTD);
- for (ReceiverDTD = 0; ReceiverDTD < MAX_CS_SUPPORTED; ReceiverDTD += 2) {
- printk(BIOS_DEBUG, "\t\tReceiver: %02x:", ReceiverDTD);
- p = pDCTstat->CH_D_DIR_B_DQS[ChannelDTD][ReceiverDTD >> 1][Dir];
- for (i = 0; i < 8; i++) {
- val = p[i];
- printk(BIOS_DEBUG, " %02x", val);
- }
- printk(BIOS_DEBUG, "\n");
- }
- }
- }
-
- }
-#endif
- if (_DisableDramECC) {
- mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
- }
- if (!_Wrap32Dis) {
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(addr, lo, hi);
- }
- if (!_SSE2) {
- cr4 = read_cr4();
- cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
- write_cr4(cr4);
- }
-
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: TrainErrors %x\n", pDCTstat->TrainErrors);
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: Done\n\n");
-}
-
-/* Calcuate and set MaxRdLatency
- * Algorithm detailed in the Fam15h BKDG Rev. 3.14 section 2.10.5.8.5
- */
-void Calc_SetMaxRdLatency_D_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t calc_min)
-{
- uint8_t dimm;
- uint8_t lane;
- uint32_t dword;
- uint32_t dword2;
- uint32_t max_delay;
- uint8_t mem_clk = 0;
- uint8_t nb_pstate;
- uint32_t nb_clk;
- uint32_t p = 0;
- uint32_t n = 0;
- uint32_t t = 0;
- uint16_t current_phy_phase_delay[MAX_BYTE_LANES];
- uint16_t current_read_dqs_delay[MAX_BYTE_LANES];
-
- uint32_t index_reg = 0x98;
- uint32_t dev = pDCTstat->dev_dct;
- uint16_t fam15h_freq_tab[] = {0, 0, 0, 0, 333, 0, 400, 0, 0, 0, 533, 0, 0, 0, 667, 0, 0, 0, 800, 0, 0, 0, 933};
-
-#if DQS_TRAIN_DEBUG > 0
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-#endif
-
- uint8_t lane_count;
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- mem_clk = Get_NB32_DCT(dev, dct, 0x94) & 0x1f;
- if (fam15h_freq_tab[mem_clk] == 0) {
- pDCTstat->CH_MaxRdLat[dct][0] = 0x55;
- pDCTstat->CH_MaxRdLat[dct][1] = 0x55;
- return;
- }
-
- /* P is specified in PhyCLKs (1/2 MEMCLKs) */
- for (nb_pstate = 0; nb_pstate < 2; nb_pstate++) {
- /* 2.10.5.8.5 (2) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000004);
- if ((!(dword & (0x1 << 21))) && (!(dword & (0x1 << 13))) && (!(dword & (0x1 << 5))))
- p += 1;
- else
- p += 2;
-
- /* 2.10.5.8.5 (3) */
- dword = Get_NB32_DCT_NBPstate(dev, dct, nb_pstate, 0x210) & 0xf; /* Retrieve RdPtrInit */
- p += (9 - dword);
-
- /* 2.10.5.8.5 (4) */
- if (!calc_min)
- p += 5;
-
- /* 2.10.5.8.5 (5) */
- dword = Get_NB32_DCT(dev, dct, 0xa8);
- dword2 = Get_NB32_DCT(dev, dct, 0x90);
- if ((!(dword & (0x1 << 5))) && (!(dword2 & (0x1 << 16))))
- p += 2;
-
- /* 2.10.5.8.5 (6) */
- dword = Get_NB32_DCT(dev, dct, 0x200) & 0x1f; /* Retrieve Tcl */
- p += (2 * (dword - 1));
-
- /* 2.10.5.8.5 (7) */
- max_delay = 0;
- for (dimm = 0; dimm < 4; dimm++) {
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, dimm * 2))
- continue;
-
- read_dqs_receiver_enable_control_registers(current_phy_phase_delay, dev, dct, dimm, index_reg);
- read_dqs_read_data_timing_registers(current_read_dqs_delay, dev, dct, dimm, index_reg);
- for (lane = 0; lane < lane_count; lane++)
- if ((current_phy_phase_delay[lane] + current_read_dqs_delay[lane]) > max_delay)
- max_delay = (current_phy_phase_delay[lane] + current_read_dqs_delay[lane]);
- }
- p += (max_delay >> 5);
-
- /* 2.10.5.8.5 (8) */
- if (!calc_min)
- p += 5;
-
- /* 2.10.5.8.5 (9) */
- t += 800;
-
- /* 2.10.5.8.5 (10) */
- dword = Get_NB32(pDCTstat->dev_nbctl, (0x160 + (nb_pstate * 4))); /* Retrieve NbDid, NbFid */
- nb_clk = (200 * (((dword >> 1) & 0x1f) + 0x4)) / (((dword >> 7) & 0x1)?2:1);
- n = (((((uint64_t)p * 1000000000000ULL)/(((uint64_t)fam15h_freq_tab[mem_clk] * 1000000ULL) * 2)) + ((uint64_t)t)) * ((uint64_t)nb_clk * 1000)) / 1000000000ULL;
-
- /* 2.10.5.8.5 (11) */
- if (!calc_min)
- n -= 1;
-
- /* 2.10.5.8.5 (12) */
- if (!calc_min) {
- dword = Get_NB32_DCT_NBPstate(dev, dct, nb_pstate, 0x210);
- dword &= ~(0x3ff << 22);
- dword |= (((n - 1) & 0x3ff) << 22);
- Set_NB32_DCT_NBPstate(dev, dct, nb_pstate, 0x210, dword);
- }
-
- /* Save result for later use */
- pDCTstat->CH_MaxRdLat[dct][nb_pstate] = n - 1;
-
-#if DQS_TRAIN_DEBUG > 0
- printk(BIOS_DEBUG, "%s: CH_MaxRdLat[%d][%d]: %03x\n", __func__, dct, nb_pstate, pDCTstat->CH_MaxRdLat[dct][nb_pstate]);
-#endif
- }
-
-#if DQS_TRAIN_DEBUG > 0
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-#endif
-}
-
-static void start_dram_dqs_training_pattern_fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t Receiver)
-{
- uint32_t dword;
- uint32_t dev = pDCTstat->dev_dct;
-
- /* 2.10.5.7.1.1
- * It appears that the DCT only supports 8-beat burst length mode,
- * so do nothing here...
- */
-
- /* Wait for CmdSendInProg == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x250);
- } while (dword & (0x1 << 12));
-
- /* Set CmdTestEnable = 1 */
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword |= (0x1 << 2);
- Set_NB32_DCT(dev, dct, 0x250, dword);
-
- /* 2.10.5.8.6.1.1 Send Activate Command (Target A) */
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- dword &= ~(0xff << 22); /* CmdChipSelect = Receiver */
- dword |= ((0x1 << Receiver) << 22);
- dword &= ~(0x7 << 19); /* CmdBank = 0 */
- dword &= ~(0x3ffff); /* CmdAddress = 0 */
- dword |= (0x1 << 31); /* SendActCmd = 1 */
- Set_NB32_DCT(dev, dct, 0x28c, dword);
-
- /* Wait for SendActCmd == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- } while (dword & (0x1 << 31));
-
- /* Wait 75 MEMCLKs. */
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 75);
-
- /* 2.10.5.8.6.1.1 Send Activate Command (Target B) */
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- dword &= ~(0xff << 22); /* CmdChipSelect = Receiver */
- dword |= ((0x1 << Receiver) << 22);
- dword &= ~(0x7 << 19); /* CmdBank = 1 */
- dword |= (0x1 << 19);
- dword &= ~(0x3ffff); /* CmdAddress = 0 */
- dword |= (0x1 << 31); /* SendActCmd = 1 */
- Set_NB32_DCT(dev, dct, 0x28c, dword);
-
- /* Wait for SendActCmd == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- } while (dword & (0x1 << 31));
-
- /* Wait 75 MEMCLKs. */
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 75);
-}
-
-static void stop_dram_dqs_training_pattern_fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t Receiver)
-{
- uint32_t dword;
- uint32_t dev = pDCTstat->dev_dct;
-
- /* 2.10.5.8.6.1.1 Send Precharge Command */
- /* Wait 25 MEMCLKs. */
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 25);
-
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- dword &= ~(0xff << 22); /* CmdChipSelect = Receiver */
- dword |= ((0x1 << Receiver) << 22);
- dword &= ~(0x7 << 19); /* CmdBank = 0 */
- dword &= ~(0x3ffff); /* CmdAddress = 0x400 */
- dword |= 0x400;
- dword |= (0x1 << 30); /* SendPchgCmd = 1 */
- Set_NB32_DCT(dev, dct, 0x28c, dword);
-
- /* Wait for SendPchgCmd == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- } while (dword & (0x1 << 30));
-
- /* Wait 25 MEMCLKs. */
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 25);
-
- /* Set CmdTestEnable = 0 */
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword &= ~(0x1 << 2);
- Set_NB32_DCT(dev, dct, 0x250, dword);
-}
-
-void read_dram_dqs_training_pattern_fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct,
- uint8_t Receiver, uint8_t lane, uint8_t stop_on_error)
-{
- uint32_t dword;
- uint32_t dev = pDCTstat->dev_dct;
-
- start_dram_dqs_training_pattern_fam15(pMCTstat, pDCTstat, dct, Receiver);
-
- /* 2.10.5.8.6.1.2 */
- /* Configure DQMask */
- if (lane < 4) {
- Set_NB32_DCT(dev, dct, 0x274, ~(0xff << (lane * 8)));
- Set_NB32_DCT(dev, dct, 0x278, ~0x0);
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- dword |= 0xff; /* EccMask = 0xff */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- } else if (lane < 8) {
- Set_NB32_DCT(dev, dct, 0x274, ~0x0);
- Set_NB32_DCT(dev, dct, 0x278, ~(0xff << ((lane - 4) * 8)));
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- dword |= 0xff; /* EccMask = 0xff */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- } else if (lane == 8) {
- Set_NB32_DCT(dev, dct, 0x274, ~0x0);
- Set_NB32_DCT(dev, dct, 0x278, ~0x0);
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- dword &= ~(0xff); /* EccMask = 0x0 */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- } else if (lane == 0xff) {
- Set_NB32_DCT(dev, dct, 0x274, ~0xffffffff);
- Set_NB32_DCT(dev, dct, 0x278, ~0xffffffff);
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- if (get_available_lane_count(pMCTstat, pDCTstat) < 9)
- dword |= 0xff; /* EccMask = 0xff */
- else
- dword &= ~(0xff); /* EccMask = 0x0 */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- } else {
- Set_NB32_DCT(dev, dct, 0x274, ~0x0);
- Set_NB32_DCT(dev, dct, 0x278, ~0x0);
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- dword |= 0xff; /* EccMask = 0xff */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- }
-
- dword = Get_NB32_DCT(dev, dct, 0x270);
- dword &= ~(0x7ffff); /* DataPrbsSeed = 55555 */
-// dword |= (0x55555);
- dword |= (0x44443); /* Use AGESA seed */
- Set_NB32_DCT(dev, dct, 0x270, dword);
-
- /* 2.10.5.8.4 */
- dword = Get_NB32_DCT(dev, dct, 0x260);
- dword &= ~(0x1fffff); /* CmdCount = 256 */
- dword |= 256;
- Set_NB32_DCT(dev, dct, 0x260, dword);
-
- /* Configure Target A */
- dword = Get_NB32_DCT(dev, dct, 0x254);
- dword &= ~(0x7 << 24); /* TgtChipSelect = Receiver */
- dword |= (Receiver & 0x7) << 24;
- dword &= ~(0x7 << 21); /* TgtBank = 0 */
- dword &= ~(0x3ff); /* TgtAddress = 0 */
- Set_NB32_DCT(dev, dct, 0x254, dword);
-
- /* Configure Target B */
- dword = Get_NB32_DCT(dev, dct, 0x258);
- dword &= ~(0x7 << 24); /* TgtChipSelect = Receiver */
- dword |= (Receiver & 0x7) << 24;
- dword &= ~(0x7 << 21); /* TgtBank = 1 */
- dword |= (0x1 << 21);
- dword &= ~(0x3ff); /* TgtAddress = 0 */
- Set_NB32_DCT(dev, dct, 0x258, dword);
-
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword |= (0x1 << 3); /* ResetAllErr = 1 */
- dword &= ~(0x1 << 4); /* StopOnErr = stop_on_error */
- dword |= (stop_on_error & 0x1) << 4;
- dword &= ~(0x3 << 8); /* CmdTgt = 1 (Alternate between Target A and Target B) */
- dword |= (0x1 << 8);
- dword &= ~(0x7 << 5); /* CmdType = 0 (Read) */
- dword |= (0x1 << 11); /* SendCmd = 1 */
- Set_NB32_DCT(dev, dct, 0x250, dword);
-
- /* 2.10.5.8.6.1.2 Wait for TestStatus == 1 and CmdSendInProg == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x250);
- } while ((dword & (0x1 << 12)) || (!(dword & (0x1 << 10))));
-
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword &= ~(0x1 << 11); /* SendCmd = 0 */
- Set_NB32_DCT(dev, dct, 0x250, dword);
-
- stop_dram_dqs_training_pattern_fam15(pMCTstat, pDCTstat, dct, Receiver);
-}
-
-void write_dram_dqs_training_pattern_fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct,
- uint8_t Receiver, uint8_t lane, uint8_t stop_on_error)
-{
- uint32_t dword;
- uint32_t dev = pDCTstat->dev_dct;
-
- start_dram_dqs_training_pattern_fam15(pMCTstat, pDCTstat, dct, Receiver);
-
- /* 2.10.5.8.6.1.2 */
- /* Configure DQMask */
- if (lane < 4) {
- Set_NB32_DCT(dev, dct, 0x274, ~(0xff << (lane * 8)));
- Set_NB32_DCT(dev, dct, 0x278, ~0x0);
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- dword |= 0xff; /* EccMask = 0xff */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- } else if (lane < 8) {
- Set_NB32_DCT(dev, dct, 0x274, ~0x0);
- Set_NB32_DCT(dev, dct, 0x278, ~(0xff << ((lane - 4) * 8)));
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- dword |= 0xff; /* EccMask = 0xff */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- } else if (lane == 8) {
- Set_NB32_DCT(dev, dct, 0x274, ~0x0);
- Set_NB32_DCT(dev, dct, 0x278, ~0x0);
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- dword &= ~(0xff); /* EccMask = 0x0 */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- } else if (lane == 0xff) {
- Set_NB32_DCT(dev, dct, 0x274, ~0xffffffff);
- Set_NB32_DCT(dev, dct, 0x278, ~0xffffffff);
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- if (get_available_lane_count(pMCTstat, pDCTstat) < 9)
- dword |= 0xff; /* EccMask = 0xff */
- else
- dword &= ~(0xff); /* EccMask = 0x0 */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- } else {
- Set_NB32_DCT(dev, dct, 0x274, ~0x0);
- Set_NB32_DCT(dev, dct, 0x278, ~0x0);
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- dword |= 0xff; /* EccMask = 0xff */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
- }
-
- dword = Get_NB32_DCT(dev, dct, 0x270);
- dword &= ~(0x7ffff); /* DataPrbsSeed = 55555 */
-// dword |= (0x55555);
- dword |= (0x44443); /* Use AGESA seed */
- Set_NB32_DCT(dev, dct, 0x270, dword);
-
- /* 2.10.5.8.4 */
- dword = Get_NB32_DCT(dev, dct, 0x260);
- dword &= ~(0x1fffff); /* CmdCount = 256 */
- dword |= 256;
- Set_NB32_DCT(dev, dct, 0x260, dword);
-
- /* Configure Target A */
- dword = Get_NB32_DCT(dev, dct, 0x254);
- dword &= ~(0x7 << 24); /* TgtChipSelect = Receiver */
- dword |= (Receiver & 0x7) << 24;
- dword &= ~(0x7 << 21); /* TgtBank = 0 */
- dword &= ~(0x3ff); /* TgtAddress = 0 */
- Set_NB32_DCT(dev, dct, 0x254, dword);
-
- /* Configure Target B */
- dword = Get_NB32_DCT(dev, dct, 0x258);
- dword &= ~(0x7 << 24); /* TgtChipSelect = Receiver */
- dword |= (Receiver & 0x7) << 24;
- dword &= ~(0x7 << 21); /* TgtBank = 1 */
- dword |= (0x1 << 21);
- dword &= ~(0x3ff); /* TgtAddress = 0 */
- Set_NB32_DCT(dev, dct, 0x258, dword);
-
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword |= (0x1 << 3); /* ResetAllErr = 1 */
- dword &= ~(0x1 << 4); /* StopOnErr = stop_on_error */
- dword |= (stop_on_error & 0x1) << 4;
- dword &= ~(0x3 << 8); /* CmdTgt = 1 (Alternate between Target A and Target B) */
- dword |= (0x1 << 8);
- dword &= ~(0x7 << 5); /* CmdType = 1 (Write) */
- dword |= (0x1 << 5);
- dword |= (0x1 << 11); /* SendCmd = 1 */
- Set_NB32_DCT(dev, dct, 0x250, dword);
-
- /* 2.10.5.8.6.1.2 Wait for TestStatus == 1 and CmdSendInProg == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x250);
- } while ((dword & (0x1 << 12)) || (!(dword & (0x1 << 10))));
-
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword &= ~(0x1 << 11); /* SendCmd = 0 */
- Set_NB32_DCT(dev, dct, 0x250, dword);
-
- stop_dram_dqs_training_pattern_fam15(pMCTstat, pDCTstat, dct, Receiver);
-}
-
-#define LANE_DIFF 1
-
-/* DQS Position Training
- * Algorithm detailed in the Fam15h BKDG Rev. 3.14 section 2.10.5.8.4
- */
-static uint8_t TrainDQSRdWrPos_D_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- uint8_t dct, uint8_t receiver_start,
- uint8_t receiver_end, uint8_t lane_start)
-{
- uint8_t dimm;
- uint8_t lane;
- uint32_t dword;
- uint32_t Errors;
- uint8_t Receiver;
- uint8_t dual_rank;
- uint8_t write_iter;
- uint8_t read_iter;
- uint8_t check_antiphase;
- uint8_t passing_read_dqs_delay_found;
- uint8_t passing_write_dqs_delay_found;
- uint16_t initial_write_dqs_delay[MAX_BYTE_LANES];
- uint16_t initial_read_dqs_delay[MAX_BYTE_LANES];
- uint16_t initial_write_data_timing[MAX_BYTE_LANES];
- uint16_t current_write_data_delay[MAX_BYTE_LANES];
- uint16_t current_read_dqs_delay[MAX_BYTE_LANES];
- uint16_t current_write_dqs_delay[MAX_BYTE_LANES];
- uint8_t passing_dqs_delay_found[MAX_BYTE_LANES];
- /* [rank][lane][write step][read step + 16] */
- uint8_t dqs_results_array[2][LANE_DIFF][32][48];
-
- uint8_t last_pos = 0;
- uint8_t cur_count = 0;
- uint8_t best_pos = 0;
- uint8_t best_count = 0;
-
- uint32_t index_reg = 0x98;
- uint32_t dev = pDCTstat->dev_dct;
-
- uint8_t lane_end = lane_start + LANE_DIFF;
-
- uint8_t lane_count;
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- /* Calculate and program MaxRdLatency */
- Calc_SetMaxRdLatency_D_Fam15(pMCTstat, pDCTstat, dct, 0);
-
- Errors = 0;
- dual_rank = 0;
-
- /* There are four receiver pairs, loosely associated with chipselects.
- * This is essentially looping over each rank within each DIMM.
- */
- for (Receiver = receiver_start; Receiver < receiver_end; Receiver++) {
- dimm = (Receiver >> 1);
- if ((Receiver & 0x1) == 0) {
- /* Even rank of DIMM */
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, Receiver+1))
- dual_rank = 1;
- else
- dual_rank = 0;
- }
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, Receiver)) {
- continue;
- }
-
-#if DQS_TRAIN_DEBUG > 0
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: Training DQS read/write position for receiver %d (DIMM %d)\n", Receiver, dimm);
-#endif
-
- /* Initialize variables */
- for (lane = lane_start; lane < lane_end; lane++) {
- passing_dqs_delay_found[lane] = 0;
- }
- if ((Receiver & 0x1) == 0) {
- /* Even rank of DIMM */
- memset(dqs_results_array, 0, sizeof(dqs_results_array));
-
- /* Read initial read / write DQS delays */
- read_dqs_write_timing_control_registers(initial_write_dqs_delay, dev, dct, dimm, index_reg);
- read_dqs_read_data_timing_registers(initial_read_dqs_delay, dev, dct, dimm, index_reg);
-
- /* Read current settings of other (previously trained) lanes */
- read_dqs_write_data_timing_registers(initial_write_data_timing, dev, dct, dimm, index_reg);
- }
-
- /* Initialize iterators */
- memcpy(current_write_data_delay, initial_write_data_timing, sizeof(current_write_data_delay));
-
- for (lane = lane_start; lane < lane_end; lane++) {
- passing_read_dqs_delay_found = 0;
- passing_write_dqs_delay_found = 0;
-
- /* 2.10.5.8.4 (2)
- * For each Write Data Delay value from Write DQS Delay to Write DQS Delay + 1 UI
- */
- for (current_write_data_delay[lane] = initial_write_dqs_delay[lane]; current_write_data_delay[lane] < (initial_write_dqs_delay[lane] + 0x20); current_write_data_delay[lane]++) {
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 16 current_write_data_delay[lane] ", current_write_data_delay[lane], 6);
-
- /* 2.10.5.8.4 (2 A)
- * Commit the current Write Data Timing settings to the hardware registers
- */
- write_dqs_write_data_timing_registers(current_write_data_delay, dev, dct, dimm, index_reg);
-
- /* 2.10.5.8.4 (2 B)
- * Write the DRAM training pattern to the test address
- */
- write_dram_dqs_training_pattern_fam15(pMCTstat, pDCTstat, dct, Receiver, lane, 0);
-
- /* Read current settings of other (previously trained) lanes */
- read_dqs_read_data_timing_registers(current_read_dqs_delay, dev, dct, dimm, index_reg);
-
- /* 2.10.5.8.4 (2 C)
- * For each Read DQS Delay value from 0 to 1 UI
- */
- for (current_read_dqs_delay[lane] = 0; current_read_dqs_delay[lane] < 0x20; current_read_dqs_delay[lane]++) {
- print_debug_dqs("\t\t\t\t\tTrainDQSRdWrPos: 161 current_read_dqs_delay[lane] ", current_read_dqs_delay[lane], 6);
-
- if (current_read_dqs_delay[lane] >= (32 - 16)) {
- check_antiphase = 1;
- } else {
- check_antiphase = 0;
- }
-
- /* 2.10.5.8.4 (2 A i)
- * Commit the current Read DQS Timing Control settings to the hardware registers
- */
- write_dqs_read_data_timing_registers(current_read_dqs_delay, dev, dct, dimm, index_reg);
-
- /* 2.10.5.8.4 (2 A ii)
- * Read the DRAM training pattern from the test address
- */
- read_dram_dqs_training_pattern_fam15(pMCTstat, pDCTstat, dct, Receiver, lane, ((check_antiphase == 0)?1:0));
-
- if (check_antiphase == 0) {
- /* Check for early abort before analyzing per-nibble status */
- dword = Get_NB32_DCT(dev, dct, 0x264);
- if ((dword & 0x1ffffff) != 0) {
- print_debug_dqs("\t\t\t\t\tTrainDQSRdWrPos: 162 early abort: F2x264 ", dword, 6);
- dqs_results_array[Receiver & 0x1][lane - lane_start][current_write_data_delay[lane] - initial_write_dqs_delay[lane]][current_read_dqs_delay[lane] + 16] = 0; /* Fail */
- continue;
- }
- }
-
- /* 2.10.5.8.4 (2 A iii)
- * Record pass / fail status
- */
- dword = Get_NB32_DCT(dev, dct, 0x268) & 0x3ffff;
- print_debug_dqs("\t\t\t\t\tTrainDQSRdWrPos: 163 read results: F2x268 ", dword, 6);
- if (dword & (0x3 << (lane * 2)))
- dqs_results_array[Receiver & 0x1][lane - lane_start][current_write_data_delay[lane] - initial_write_dqs_delay[lane]][current_read_dqs_delay[lane] + 16] = 0; /* Fail */
- else
- dqs_results_array[Receiver & 0x1][lane - lane_start][current_write_data_delay[lane] - initial_write_dqs_delay[lane]][current_read_dqs_delay[lane] + 16] = 1; /* Pass */
- if (check_antiphase == 1) {
- /* Check antiphase results */
- dword = Get_NB32_DCT(dev, dct, 0x26c) & 0x3ffff;
- if (dword & (0x3 << (lane * 2)))
- dqs_results_array[Receiver & 0x1][lane - lane_start][current_write_data_delay[lane] - initial_write_dqs_delay[lane]][16 - (32 - current_read_dqs_delay[lane])] = 0; /* Fail */
- else
- dqs_results_array[Receiver & 0x1][lane - lane_start][current_write_data_delay[lane] - initial_write_dqs_delay[lane]][16 - (32 - current_read_dqs_delay[lane])] = 1; /* Pass */
- }
- }
- }
-
- if (dual_rank && (Receiver & 0x1)) {
- /* Overlay the previous rank test results with the current rank */
- for (write_iter = 0; write_iter < 32; write_iter++) {
- for (read_iter = 0; read_iter < 48; read_iter++) {
- if ((dqs_results_array[0][lane - lane_start][write_iter][read_iter])
- && (dqs_results_array[1][lane - lane_start][write_iter][read_iter]))
- dqs_results_array[1][lane - lane_start][write_iter][read_iter] = 1;
- else
- dqs_results_array[1][lane - lane_start][write_iter][read_iter] = 0;
- }
- }
- }
-
- /* Determine location and length of longest consecutive string of read passing values
- * Output is stored in best_pos and best_count
- */
- last_pos = 0;
- cur_count = 0;
- best_pos = 0;
- best_count = 0;
- for (write_iter = 0; write_iter < 32; write_iter++) {
- for (read_iter = 0; read_iter < 48; read_iter++) {
- if ((dqs_results_array[Receiver & 0x1][lane - lane_start][write_iter][read_iter]) && (read_iter < 47)) {
- /* Pass */
- cur_count++;
- } else {
- /* Failure or end of loop */
- if (cur_count > best_count) {
- best_count = cur_count;
- best_pos = last_pos;
- }
- cur_count = 0;
- last_pos = read_iter + 1;
- }
- }
- last_pos = 0;
- }
-
- if (best_count > 2) {
- uint16_t region_center = (best_pos + (best_count / 2));
-
- if (region_center < 16) {
- printk(BIOS_WARNING, "TrainDQSRdWrPos: negative DQS recovery delay detected!"
- " Attempting to continue but your system may be unstable...\n");
- region_center = 0;
- } else {
- region_center -= 16;
- }
-
- /* Restore current settings of other (previously trained) lanes to the active array */
- memcpy(current_read_dqs_delay, initial_read_dqs_delay, sizeof(current_read_dqs_delay));
-
- /* Program the Read DQS Timing Control register with the center of the passing window */
- current_read_dqs_delay[lane] = region_center;
- passing_dqs_delay_found[lane] = 1;
-
- /* Commit the current Read DQS Timing Control settings to the hardware registers */
- write_dqs_read_data_timing_registers(current_read_dqs_delay, dev, dct, dimm, index_reg);
-
- /* Save the final Read DQS Timing Control settings for later use */
- pDCTstat->CH_D_DIR_B_DQS[dct][Receiver >> 1][DQS_READDIR][lane] = current_read_dqs_delay[lane];
-
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 142 largest read passing region ", best_count, 4);
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 143 largest read passing region start ", best_pos, 4);
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 144 largest read passing region center (raw hardware value) ", region_center, 4);
- } else {
- /* Restore current settings of other (previously trained) lanes to the active array */
- memcpy(current_read_dqs_delay, initial_read_dqs_delay, sizeof(current_read_dqs_delay));
-
- /* Reprogram the Read DQS Timing Control register with the original settings */
- write_dqs_read_data_timing_registers(initial_read_dqs_delay, dev, dct, dimm, index_reg);
- }
-
- /* Determine location and length of longest consecutive string of write passing values
- * Output is stored in best_pos and best_count
- */
- last_pos = 0;
- cur_count = 0;
- best_pos = 0;
- best_count = 0;
- for (read_iter = 0; read_iter < 48; read_iter++) {
- for (write_iter = 0; write_iter < 32; write_iter++) {
- if ((dqs_results_array[Receiver & 0x1][lane - lane_start][write_iter][read_iter]) && (write_iter < 31)) {
- /* Pass */
- cur_count++;
- } else {
- /* Failure or end of loop */
- if (cur_count > best_count) {
- best_count = cur_count;
- best_pos = last_pos;
- }
- cur_count = 0;
- last_pos = write_iter + 1;
- }
- }
- last_pos = 0;
- }
-
- if (best_count > 2) {
- /* Restore current settings of other (previously trained) lanes to the active array */
- memcpy(current_write_dqs_delay, initial_write_data_timing, sizeof(current_write_data_delay));
-
- /* Program the Write DQS Timing Control register with the optimal region within the passing window */
- if (pDCTstat->Status & (1 << SB_LoadReduced))
- current_write_dqs_delay[lane] = ((best_pos + initial_write_dqs_delay[lane]) + (best_count / 3));
- else
- current_write_dqs_delay[lane] = ((best_pos + initial_write_dqs_delay[lane]) + (best_count / 2));
- passing_write_dqs_delay_found = 1;
-
- /* Commit the current Write DQS Timing Control settings to the hardware registers */
- write_dqs_write_data_timing_registers(current_write_dqs_delay, dev, dct, dimm, index_reg);
-
- /* Save the final Write Data Timing settings for later use */
- pDCTstat->CH_D_DIR_B_DQS[dct][Receiver >> 1][DQS_WRITEDIR][lane] = current_write_dqs_delay[lane];
-
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 145 largest write passing region ", best_count, 4);
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 146 largest write passing region start ", best_pos, 4);
- } else {
- /* Restore current settings of other (previously trained) lanes to the active array */
- memcpy(current_write_dqs_delay, initial_write_data_timing, sizeof(current_write_data_delay));
-
- /* Reprogram the Write DQS Timing Control register with the original settings */
- write_dqs_write_data_timing_registers(current_write_dqs_delay, dev, dct, dimm, index_reg);
- }
-
- if (passing_read_dqs_delay_found && passing_write_dqs_delay_found)
- passing_dqs_delay_found[lane] = 1;
- }
-
-#ifdef PRINT_PASS_FAIL_BITMAPS
- for (lane = lane_start; lane < lane_end; lane++) {
- for (write_iter = 0; write_iter < 32; write_iter++) {
- for (read_iter = 0; read_iter < 48; read_iter++) {
- if (dqs_results_array[Receiver & 0x1][lane - lane_start][write_iter][read_iter]) {
- printk(BIOS_DEBUG, "+");
- } else {
- if (read_iter < 16)
- printk(BIOS_DEBUG, ":");
- else
- printk(BIOS_DEBUG, ".");
- }
- }
- printk(BIOS_DEBUG, "\n");
- }
- printk(BIOS_DEBUG, "\n\n");
- }
-#endif
-
- /* Flag failure(s) if present */
- for (lane = lane_start; lane < lane_end; lane++) {
- if (!passing_dqs_delay_found[lane]) {
- print_debug_dqs("\t\t\t\tTrainDQSRdWrPos: 121 Unable to find passing region for lane ", lane, 2);
-
- /* Flag absence of passing window */
- Errors |= 1 << SB_NODQSPOS;
- }
- }
-
- pDCTstat->TrainErrors |= Errors;
- pDCTstat->ErrStatus |= Errors;
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 val;
- u8 i;
- u8 ChannelDTD, ReceiverDTD, Dir;
- u8 *p;
-
- for (Dir = 0; Dir < 2; Dir++) {
- if (Dir == 1) {
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: CH_D_DIR_B_DQS WR:\n");
- } else {
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: CH_D_DIR_B_DQS RD:\n");
- }
- for (ChannelDTD = 0; ChannelDTD < 2; ChannelDTD++) {
- printk(BIOS_DEBUG, "Channel: %02x\n", ChannelDTD);
- for (ReceiverDTD = 0; ReceiverDTD < MAX_CS_SUPPORTED; ReceiverDTD += 2) {
- printk(BIOS_DEBUG, "\t\tReceiver: %02x:", ReceiverDTD);
- p = pDCTstat->CH_D_DIR_B_DQS[ChannelDTD][ReceiverDTD >> 1][Dir];
- for (i = 0; i < 8; i++) {
- val = p[i];
- printk(BIOS_DEBUG, " %02x", val);
- }
- printk(BIOS_DEBUG, "\n");
- }
- }
- }
-
- }
-#endif
- }
-
- /* Return 1 on success, 0 on failure */
- return !Errors;
-}
-
-/* DQS Receiver Enable Cycle Training
- * Algorithm detailed in the Fam15h BKDG Rev. 3.14 section 2.10.5.8.3
- */
-static void TrainDQSReceiverEnCyc_D_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 Errors;
- u8 Receiver;
- u8 _DisableDramECC = 0;
- u8 _Wrap32Dis = 0, _SSE2 = 0;
-
- u32 addr;
- CRx_TYPE cr4;
- u32 lo, hi;
-
- uint8_t dct;
- uint8_t prev;
- uint8_t dimm;
- uint8_t lane;
- uint32_t dword;
- uint32_t rx_en_offset;
- uint8_t internal_lane;
- uint8_t dct_training_success;
- uint8_t lane_success_count;
- uint16_t initial_phy_phase_delay[MAX_BYTE_LANES];
- uint16_t current_phy_phase_delay[MAX_BYTE_LANES];
- uint16_t current_read_dqs_delay[MAX_BYTE_LANES];
- uint8_t lane_training_success[MAX_BYTE_LANES];
- uint8_t dqs_results_array[1024];
-
- uint16_t ren_step = 0x40;
- uint32_t index_reg = 0x98;
- uint32_t dev = pDCTstat->dev_dct;
-
- uint8_t lane_count;
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- print_debug_dqs("\nTrainDQSReceiverEnCyc: Node_ID ", pDCTstat->Node_ID, 0);
- cr4 = read_cr4();
- if (cr4 & (1<<9)) {
- _SSE2 = 1;
- }
- cr4 |= (1<<9); /* OSFXSR enable SSE2 */
- write_cr4(cr4);
-
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- if (lo & (1<<17)) {
- _Wrap32Dis = 1;
- }
- lo |= (1<<17); /* HWCR.wrap32dis */
- _WRMSR(addr, lo, hi); /* allow 64-bit memory references in real mode */
-
- /* Disable ECC correction of reads on the dram bus. */
- _DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
-
- Errors = 0;
-
- for (dct = 0; dct < 2; dct++) {
- /* Program D18F2x9C_x0D0F_E003_dct[1:0][DisAutoComp, DisablePredriverCal] */
- /* NOTE: DisablePredriverCal only takes effect when set on DCT 0 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fe003);
- dword &= ~(0x3 << 13);
- dword |= (0x1 << 13);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fe003, dword);
- }
-
- for (dct = 0; dct < 2; dct++) {
- /* 2.10.5.6 */
- fam15EnableTrainingMode(pMCTstat, pDCTstat, dct, 1);
-
- /* 2.10.5.8.3 */
- Receiver = mct_InitReceiver_D(pDCTstat, dct);
-
- /* Indicate success unless training the DCT explicitly fails */
- dct_training_success = 1;
-
- /* There are four receiver pairs, loosely associated with chipselects.
- * This is essentially looping over each DIMM.
- */
- for (; Receiver < 8; Receiver += 2) {
- dimm = (Receiver >> 1);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, dct, Receiver)) {
- continue;
- }
-
- /* Initialize variables */
- memset(lane_training_success, 0, sizeof(lane_training_success));
- memset(current_phy_phase_delay, 0, sizeof(current_phy_phase_delay));
-
- /* 2.10.5.8.3 (2) */
- read_dqs_receiver_enable_control_registers(initial_phy_phase_delay, dev, dct, dimm, index_reg);
-
- /* Reset the read data timing registers to 1UI before calculating MaxRdLatency */
- for (internal_lane = 0; internal_lane < MAX_BYTE_LANES; internal_lane++)
- current_read_dqs_delay[internal_lane] = 0x20;
- write_dqs_read_data_timing_registers(current_read_dqs_delay, dev, dct, dimm, index_reg);
-
- for (lane = 0; lane < lane_count; lane++) {
- /* Initialize variables */
- memset(dqs_results_array, 0, sizeof(dqs_results_array));
- lane_success_count = 0;
-
- /* 2.10.5.8.3 (1) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0030 | (lane << 8));
- dword |= (0x1 << 8); /* BlockRxDqsLock = 1 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0030 | (lane << 8), dword);
-
- /* 2.10.5.8.3 (3) */
- rx_en_offset = (initial_phy_phase_delay[lane] + 0x10) % 0x40;
-
- /* 2.10.5.8.3 (4) */
-#if DQS_TRAIN_DEBUG > 0
- printk(BIOS_DEBUG, "TrainDQSReceiverEnCyc_D_Fam15 Receiver %d lane %d initial phy delay %04x: iterating from %04x to %04x\n", Receiver, lane, initial_phy_phase_delay[lane], rx_en_offset, 0x3ff);
-#endif
- for (current_phy_phase_delay[lane] = rx_en_offset; current_phy_phase_delay[lane] < 0x3ff; current_phy_phase_delay[lane] += ren_step) {
-#if DQS_TRAIN_DEBUG > 0
- printk(BIOS_DEBUG, "%s: Receiver %d lane %d current phy delay: %04x\n", __func__, Receiver, lane, current_phy_phase_delay[lane]);
-#endif
-
- /* 2.10.5.8.3 (4 A) */
- write_dqs_receiver_enable_control_registers(current_phy_phase_delay, dev, dct, dimm, index_reg);
-
- /* Calculate and program MaxRdLatency */
- Calc_SetMaxRdLatency_D_Fam15(pMCTstat, pDCTstat, dct, 0);
-
- /* 2.10.5.8.3 (4 B) */
- dqs_results_array[current_phy_phase_delay[lane]] =
- TrainDQSRdWrPos_D_Fam15(pMCTstat, pDCTstat, dct,
- Receiver, Receiver + 2,
- lane);
-
- if (dqs_results_array[current_phy_phase_delay[lane]])
- lane_success_count++;
-
- /* Don't bother testing larger values if the end of the passing window was already found */
- if (!dqs_results_array[current_phy_phase_delay[lane]] && (lane_success_count > 1))
- break;
- }
-
- uint16_t phase_delay;
- for (phase_delay = 0; phase_delay < 0x3ff; phase_delay++)
- if (dqs_results_array[phase_delay])
- lane_training_success[lane] = 1;
-
- if (!lane_training_success[lane]) {
- if (pDCTstat->tcwl_delay[dct] >= 1) {
- Errors |= 1 << SB_FatalError;
- printk(BIOS_ERR, "%s: lane %d failed to train! "
- "Training for receiver %d on DCT %d aborted\n",
- __func__, lane, Receiver, dct);
- }
-
- /* Restore BlockRxDqsLock setting to normal operation in preparation for retraining */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0030 | (lane << 8));
- dword &= ~(0x1 << 8); /* BlockRxDqsLock = 0 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0030 | (lane << 8), dword);
-
- break;
- }
-
-#ifdef PRINT_PASS_FAIL_BITMAPS
- for (phase_delay = 0; phase_delay < 0x3ff; phase_delay++) {
- if (dqs_results_array[phase_delay])
- printk(BIOS_DEBUG, "+");
- else
- printk(BIOS_DEBUG, ".");
- }
- printk(BIOS_DEBUG, "\n");
-#endif
-
- /* 2.10.5.8.3 (5) */
- prev = dqs_results_array[rx_en_offset];
- for (current_phy_phase_delay[lane] = rx_en_offset + ren_step; current_phy_phase_delay[lane] < 0x3ff; current_phy_phase_delay[lane] += ren_step) {
- if ((dqs_results_array[current_phy_phase_delay[lane]] == 0) && (prev == 1)) {
- /* Restore last known good delay */
- current_phy_phase_delay[lane] -= ren_step;
-
- /* 2.10.5.8.3 (5 A B) */
- if (current_phy_phase_delay[lane] < 0x10)
- current_phy_phase_delay[lane] = 0x0;
- else
- current_phy_phase_delay[lane] -= 0x10;
-
- /* Update hardware registers with final values */
- write_dqs_receiver_enable_control_registers(current_phy_phase_delay, dev, dct, dimm, index_reg);
- TrainDQSRdWrPos_D_Fam15(pMCTstat, pDCTstat, dct,
- Receiver, Receiver + 2,
- lane);
- break;
- }
- prev = dqs_results_array[current_phy_phase_delay[lane]];
- }
-
- /* 2.10.5.8.3 (6) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0030 | (lane << 8));
- dword &= ~(0x1 << 8); /* BlockRxDqsLock = 0 */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0030 | (lane << 8), dword);
- }
-
- for (lane = 0; lane < lane_count; lane++) {
- if (!lane_training_success[lane]) {
- dct_training_success = 0;
- Errors |= 1 << SB_NODQSPOS;
- }
- }
-
-#if DQS_TRAIN_DEBUG > 0
- printk(BIOS_DEBUG, "TrainDQSReceiverEnCyc_D_Fam15 DQS receiver enable timing: ");
- for (lane = 0; lane < lane_count; lane++) {
- printk(BIOS_DEBUG, " %03x", current_phy_phase_delay[lane]);
- }
- printk(BIOS_DEBUG, "\n");
-#endif
- }
-
- if (!dct_training_success) {
- if (pDCTstat->tcwl_delay[dct] < 1) {
- /* Increase TCWL */
- pDCTstat->tcwl_delay[dct]++;
- /* Request retraining */
- Errors |= 1 << SB_RetryConfigTrain;
- }
- }
- }
-
- pDCTstat->TrainErrors |= Errors;
- pDCTstat->ErrStatus |= Errors;
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 val;
- u8 i;
- u8 ChannelDTD, ReceiverDTD, Dir;
- u8 *p;
-
- for (Dir = 0; Dir < 2; Dir++) {
- if (Dir == 1) {
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: CH_D_DIR_B_DQS WR:\n");
- } else {
- printk(BIOS_DEBUG, "TrainDQSRdWrPos: CH_D_DIR_B_DQS RD:\n");
- }
- for (ChannelDTD = 0; ChannelDTD < 2; ChannelDTD++) {
- printk(BIOS_DEBUG, "Channel: %02x\n", ChannelDTD);
- for (ReceiverDTD = 0; ReceiverDTD < MAX_CS_SUPPORTED; ReceiverDTD += 2) {
- printk(BIOS_DEBUG, "\t\tReceiver: %02x:", ReceiverDTD);
- p = pDCTstat->CH_D_DIR_B_DQS[ChannelDTD][ReceiverDTD >> 1][Dir];
- for (i = 0; i < 8; i++) {
- val = p[i];
- printk(BIOS_DEBUG, " %02x", val);
- }
- printk(BIOS_DEBUG, "\n");
- }
- }
- }
-
- }
-#endif
- if (_DisableDramECC) {
- mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
- }
- if (!_Wrap32Dis) {
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(addr, lo, hi);
- }
- if (!_SSE2) {
- cr4 = read_cr4();
- cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
- write_cr4(cr4);
- }
-
- printk(BIOS_DEBUG, "TrainDQSReceiverEnCyc: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "TrainDQSReceiverEnCyc: TrainErrors %x\n", pDCTstat->TrainErrors);
- printk(BIOS_DEBUG, "TrainDQSReceiverEnCyc: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "TrainDQSReceiverEnCyc: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "TrainDQSReceiverEnCyc: Done\n\n");
-}
-
-static void SetupDqsPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 *buffer)
-{
- /* 1. Set the Pattern type (0 or 1) in DCTStatstruc.Pattern
- * 2. Copy the pattern from ROM to Cache, aligning on 16 byte boundary
- * 3. Set the ptr to Cacheable copy in DCTStatstruc.PtrPatternBufA
- */
-
- u32 *buf;
- u16 i;
-
- buf = (u32 *)(((u32)buffer + 0x10) & (0xfffffff0));
- if (pDCTstat->Status & (1<<SB_128bitmode)) {
- pDCTstat->Pattern = 1; /* 18 cache lines, alternating qwords */
- for (i = 0; i < 16*18; i++)
- buf[i] = TestPatternJD1b_D[i];
- } else {
- pDCTstat->Pattern = 0; /* 9 cache lines, sequential qwords */
- for (i = 0; i < 16*9; i++)
- buf[i] = TestPatternJD1a_D[i];
- }
- pDCTstat->PtrPatternBufA = (u32)buf;
-}
-
-static void StoreDQSDatStrucVal_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel)
-{
- /* Store the DQSDelay value, found during a training sweep, into the DCT
- * status structure for this node
- */
-
- /* When 400, 533, 667, it will support dimm0/1/2/3,
- * and set conf for dimm0, hw will copy to dimm1/2/3
- * set for dimm1, hw will copy to dimm3
- * Rev A/B only support DIMM0/1 when 800MHz and above + 0x100 to next dimm
- * Rev C support DIMM0/1/2/3 when 800MHz and above + 0x100 to next dimm
- */
-
- /* FindDQSDatDimmVal_D is not required since we use an array */
- u8 dn = 0;
-
- dn = ChipSel>>1; /* if odd or even logical DIMM */
-
- pDCTstat->CH_D_DIR_B_DQS[pDCTstat->Channel][dn][pDCTstat->Direction][pDCTstat->ByteLane] =
- pDCTstat->DQSDelay;
-}
-
-static void GetDQSDatStrucVal_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel)
-{
- u8 dn = 0;
-
- /* When 400, 533, 667, it will support dimm0/1/2/3,
- * and set conf for dimm0, hw will copy to dimm1/2/3
- * set for dimm1, hw will copy to dimm3
- * Rev A/B only support DIMM0/1 when 800MHz and above + 0x100 to next dimm
- * Rev C support DIMM0/1/2/3 when 800MHz and above + 0x100 to next dimm
- */
-
- /* FindDQSDatDimmVal_D is not required since we use an array */
- dn = ChipSel >> 1; /*if odd or even logical DIMM */
-
- pDCTstat->DQSDelay =
- pDCTstat->CH_D_DIR_B_DQS[pDCTstat->Channel][dn][pDCTstat->Direction][pDCTstat->ByteLane];
-}
-
-/* FindDQSDatDimmVal_D is not required since we use an array */
-
-void proc_IOCLFLUSH_D(u32 addr_hi)
-{
- SetTargetWTIO_D(addr_hi);
- proc_CLFLUSH(addr_hi);
- ResetTargetWTIO_D();
-}
-
-u8 ChipSelPresent_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 ChipSel)
-{
- u32 val;
- u32 reg;
- u32 dev = pDCTstat->dev_dct;
- uint8_t dct = 0;
- u8 ret = 0;
-
- if (!pDCTstat->GangedMode)
- dct = Channel;
- else
- dct = 0;
-
- if (ChipSel < MAX_CS_SUPPORTED) {
- reg = 0x40 + (ChipSel << 2);
- val = Get_NB32_DCT(dev, dct, reg);
- if (val & (1 << 0))
- ret = 1;
- }
-
- return ret;
-}
-
-/* proc_CLFLUSH_D located in mct_gcc.h */
-
-static void WriteDQSTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo)
-{
- /* Write a pattern of 72 bit times (per DQ), to test dram functionality.
- * The pattern is a stress pattern which exercises both ISI and
- * crosstalk. The number of cache lines to fill is dependent on DCT
- * width mode and burstlength.
- * Mode BL Lines Pattern no.
- * ----+---+-------------------
- * 64 4 9 0
- * 64 8 9 0
- * 64M 4 9 0
- * 64M 8 9 0
- * 128 4 18 1
- * 128 8 N/A -
- */
- if (pDCTstat->Pattern == 0)
- WriteL9TestPattern_D(pDCTstat, TestAddr_lo);
- else
- WriteL18TestPattern_D(pDCTstat, TestAddr_lo);
-}
-
-static void WriteL18TestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo)
-{
- u8 *buf;
-
- buf = (u8 *)pDCTstat->PtrPatternBufA;
- WriteLNTestPattern(TestAddr_lo, buf, 18);
-
-}
-
-static void WriteL9TestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 TestAddr_lo)
-{
- u8 *buf;
-
- buf = (u8 *)pDCTstat->PtrPatternBufA;
- WriteLNTestPattern(TestAddr_lo, buf, 9);
-}
-
-static u16 CompareDQSTestPattern_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, u32 addr_lo)
-{
- /* Compare a pattern of 72 bit times (per DQ), to test dram functionality.
- * The pattern is a stress pattern which exercises both ISI and
- * crosstalk. The number of cache lines to fill is dependent on DCT
- * width mode and burstlength.
- * Mode BL Lines Pattern no.
- * ----+---+-------------------
- * 64 4 9 0
- * 64 8 9 0
- * 64M 4 9 0
- * 64M 8 9 0
- * 128 4 18 1
- * 128 8 N/A -
- */
-
- u32 *test_buf;
- u16 MEn1Results, bitmap;
- u8 bytelane;
- u8 i;
- u32 value;
- u8 j;
- u32 value_test;
- u32 value_r = 0, value_r_test = 0;
- u8 pattern, channel, BeatCnt;
- struct DCTStatStruc *ptrAddr;
-
- ptrAddr = pDCTstat;
- pattern = pDCTstat->Pattern;
- channel = pDCTstat->Channel;
- test_buf = (u32 *)pDCTstat->PtrPatternBufA;
-
- if (pattern && channel) {
- addr_lo += 8; /* second channel */
- test_buf += 2;
- }
-
- bytelane = 0; /* bytelane counter */
- bitmap = 0xFFFF; /* bytelane test bitmap, 1 = pass */
- MEn1Results = 0xFFFF;
- BeatCnt = 0;
- for (i = 0; i < (9 * 64 / 4); i++) { /* sizeof testpattern. /4 due to next loop */
- value = read32_fs(addr_lo);
- value_test = *test_buf;
-
- print_debug_dqs_pair("\t\t\t\t\t\ttest_buf = ", (u32)test_buf, " value = ", value_test, 7);
- print_debug_dqs_pair("\t\t\t\t\t\ttaddr_lo = ", addr_lo, " value = ", value, 7);
-
- if (pDCTstat->Direction == DQS_READDIR) {
- if (BeatCnt != 0) {
- value_r = *test_buf;
- if (pattern) /* if multi-channel */
- value_r_test = read32_fs(addr_lo - 16);
- else
- value_r_test = read32_fs(addr_lo - 8);
- }
- print_debug_dqs_pair("\t\t\t\t\t\t\ttest_buf = ", (u32)test_buf, " value_r_test = ", value_r, 7);
- print_debug_dqs_pair("\t\t\t\t\t\t\ttaddr_lo = ", addr_lo, " value_r = ", value_r_test, 7);
- }
-
- for (j = 0; j < (4 * 8); j += 8) { /* go through a 32bit data, on 1 byte step. */
- if (((value >> j) & 0xff) != ((value_test >> j) & 0xff)) {
- bitmap &= ~(1 << bytelane);
- }
-
- if (pDCTstat->Direction == DQS_READDIR) {
- if (BeatCnt != 0) {
- if (((value_r >> j) & 0xff) != ((value_r_test >> j) & 0xff)) {
- MEn1Results &= ~(1 << bytelane);
- }
- }
- }
- bytelane++;
- bytelane &= 0x7;
- }
-
- print_debug_dqs("\t\t\t\t\t\tbitmap = ", bitmap, 7);
- print_debug_dqs("\t\t\t\t\t\tMEn1Results = ", MEn1Results, 7);
-
- if (!bitmap)
- break;
-
- if (bytelane == 0) {
- BeatCnt += 4;
- if (!(pDCTstat->Status & (1 << SB_128bitmode))) {
- if (BeatCnt == 8) BeatCnt = 0; /* 8 beat burst */
- } else {
- if (BeatCnt == 4) BeatCnt = 0; /* 4 beat burst */
- }
- if (pattern == 1) { /* dual channel */
- addr_lo += 8; /* skip over other channel's data */
- test_buf += 2;
- }
- }
- addr_lo += 4;
- test_buf += 1;
- }
-
- if (pDCTstat->Direction == DQS_READDIR) {
- bitmap &= 0xFF;
- bitmap |= MEn1Results << 8;
- }
-
- print_debug_dqs("\t\t\t\t\t\tbitmap = ", bitmap, 6);
-
- return bitmap;
-}
-
-static void FlushDQSTestPattern_D(struct DCTStatStruc *pDCTstat,
- u32 addr_lo)
-{
- /* Flush functions in mct_gcc.h */
- if (pDCTstat->Pattern == 0) {
- FlushDQSTestPattern_L9(addr_lo);
- } else {
- FlushDQSTestPattern_L18(addr_lo);
- }
-}
-
-void SetTargetWTIO_D(u32 TestAddr)
-{
- u32 lo, hi;
- hi = TestAddr >> 24;
- lo = TestAddr << 8;
- _WRMSR(MTRR_IORR0_BASE, lo, hi); /* IORR0 Base */
- hi = 0xFF;
- lo = 0xFC000800; /* 64MB Mask */
- _WRMSR(MTRR_IORR0_MASK, lo, hi); /* IORR0 Mask */
-}
-
-void ResetTargetWTIO_D(void)
-{
- u32 lo, hi;
-
- hi = 0;
- lo = 0;
- _WRMSR(MTRR_IORR0_MASK, lo, hi); /* IORR0 Mask */
-}
-
-u32 SetUpperFSbase(u32 addr_hi)
-{
- /* Set the upper 32-bits of the Base address, 4GB aligned) for the
- * FS selector.
- */
- u32 lo, hi;
- u32 addr;
- lo = 0;
- hi = addr_hi>>24;
- addr = FS_Base;
- _WRMSR(addr, lo, hi);
- return addr_hi << 8;
-}
-
-void ResetDCTWrPtr_D(u32 dev, uint8_t dct, u32 index_reg, u32 index)
-{
- u32 val;
-
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, index);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, index, val);
-}
-
-void mct_TrainDQSPos_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u8 ChipSel;
- struct DCTStatStruc *pDCTstat;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- pDCTstat = pDCTstatA + Node;
- if (pDCTstat->DCTSysLimit) {
- if (is_fam15h()) {
- TrainDQSReceiverEnCyc_D_Fam15(pMCTstat, pDCTstat);
- } else {
- TrainDQSRdWrPos_D_Fam10(pMCTstat, pDCTstat);
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel += 2) {
- SetEccDQSRdWrPos_D_Fam10(pMCTstat, pDCTstat, ChipSel);
- }
- }
- }
- }
-}
-
-/* mct_BeforeTrainDQSRdWrPos_D
- * Function is inline.
- */
-u8 mct_DisableDimmEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 _DisableDramECC = 0;
- u32 val;
- u32 reg;
- u32 dev;
-
- /*Disable ECC correction of reads on the dram bus. */
-
- dev = pDCTstat->dev_dct;
- reg = 0x90;
- val = Get_NB32_DCT(dev, 0, reg);
- if (val & (1<<DimmEcEn)) {
- _DisableDramECC |= 0x01;
- val &= ~(1<<DimmEcEn);
- Set_NB32_DCT(dev, 0, reg, val);
- }
- if (!pDCTstat->GangedMode) {
- val = Get_NB32_DCT(dev, 1, reg);
- if (val & (1<<DimmEcEn)) {
- _DisableDramECC |= 0x02;
- val &= ~(1<<DimmEcEn);
- Set_NB32_DCT(dev, 1, reg, val);
- }
- }
- return _DisableDramECC;
-}
-
-void mct_EnableDimmEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 _DisableDramECC)
-{
- u32 val;
- u32 dev;
-
- /* Enable ECC correction if it was previously disabled */
- dev = pDCTstat->dev_dct;
-
- if ((_DisableDramECC & 0x01) == 0x01) {
- val = Get_NB32_DCT(dev, 0, 0x90);
- val |= (1<<DimmEcEn);
- Set_NB32_DCT(dev, 0, 0x90, val);
- }
- if ((_DisableDramECC & 0x02) == 0x02) {
- val = Get_NB32_DCT(dev, 1, 0x90);
- val |= (1<<DimmEcEn);
- Set_NB32_DCT(dev, 1, 0x90, val);
- }
-}
-
-/*
- * Set DQS delay value to related register
- */
-static void mct_SetDQSDelayCSR_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 ChipSel)
-{
- u8 ByteLane;
- u32 val;
- u32 index_reg = 0x98;
- u8 shift;
- u32 dqs_delay = (u32)pDCTstat->DQSDelay;
- u32 dev = pDCTstat->dev_dct;
- u32 index;
-
- ByteLane = pDCTstat->ByteLane;
-
- if (!(pDCTstat->DqsRdWrPos_Saved & (1 << ByteLane))) {
- /* Channel is offset */
- if (ByteLane < 4) {
- index = 1;
- } else if (ByteLane <8) {
- index = 2;
- } else {
- index = 3;
- }
-
- if (pDCTstat->Direction == DQS_READDIR) {
- index += 4;
- }
-
- /* get the proper register index */
- shift = ByteLane % 4;
- shift <<= 3; /* get bit position of bytelane, 8 bit */
-
- index += (ChipSel>>1) << 8;
-
- val = Get_NB32_index_wait_DCT(dev, pDCTstat->Channel, index_reg, index);
- if (ByteLane < 8) {
- if (pDCTstat->Direction == DQS_WRITEDIR) {
- dqs_delay += pDCTstat->persistentData.CH_D_B_TxDqs[pDCTstat->Channel][ChipSel>>1][ByteLane];
- } else {
- dqs_delay <<= 1;
- }
- }
- val &= ~(0x7f << shift);
- val |= (dqs_delay << shift);
- Set_NB32_index_wait_DCT(dev, pDCTstat->Channel, index_reg, index, val);
- }
-}
-
-u8 mct_RcvrRankEnabled_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 ChipSel)
-{
- u8 ret;
-
- ret = ChipSelPresent_D(pMCTstat, pDCTstat, Channel, ChipSel);
- return ret;
-}
-
-u32 mct_GetRcvrSysAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 channel, u8 receiver, u8 *valid)
-{
- return mct_GetMCTSysAddr_D(pMCTstat, pDCTstat, channel, receiver, valid);
-}
-
-u32 mct_GetMCTSysAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 receiver, u8 *valid)
-{
- u32 val;
- uint8_t dct = 0;
- u32 reg;
- u32 dword;
- u32 dev = pDCTstat->dev_dct;
-
- *valid = 0;
-
-
- if (!pDCTstat->GangedMode) {
- dct = Channel;
- }
-
- /* get the local base addr of the chipselect */
- reg = 0x40 + (receiver << 2);
- val = Get_NB32_DCT(dev, dct, reg);
-
- val &= ~0xe007c01f;
-
- /* unganged mode DCT0+DCT1, sys addr of DCT1 = node
- * base+DctSelBaseAddr+local ca base*/
- if ((Channel) && (pDCTstat->GangedMode == 0) && (pDCTstat->DIMMValidDCT[0] > 0)) {
- reg = 0x110;
- dword = Get_NB32(dev, reg);
- dword &= 0xfffff800;
- dword <<= 8; /* scale [47:27] of F2x110[31:11] to [39:8]*/
- val += dword;
-
- /* if DCTSelBaseAddr < Hole, and eax > HoleBase, then add Hole size to test address */
- if ((val >= pDCTstat->DCTHoleBase) && (pDCTstat->DCTHoleBase > dword)) {
- dword = (~(pDCTstat->DCTHoleBase >> (24 - 8)) + 1) & 0xFF;
- dword <<= (24 - 8);
- val += dword;
- }
- } else {
- /* sys addr = node base+local cs base */
- val += pDCTstat->DCTSysBase;
-
- /* New stuff */
- if (pDCTstat->DCTHoleBase && (val >= pDCTstat->DCTHoleBase)) {
- val -= pDCTstat->DCTSysBase;
- dword = Get_NB32(pDCTstat->dev_map, 0xF0); /* get Hole Offset */
- val += (dword & 0x0000ff00) << (24-8-8);
- }
- }
-
- /* New stuff */
- val += ((1 << 21) >> 8); /* Add 2MB offset to avoid compat area */
- if (val >= MCT_TRNG_KEEPOUT_START) {
- while (val < MCT_TRNG_KEEPOUT_END)
- val += (1 << (15-8)); /* add 32K */
- }
-
- /* Add a node seed */
- val += (((1 * pDCTstat->Node_ID) << 20) >> 8); /* Add 1MB per node to avoid aliases */
-
- /* HW remap disabled? */
- if (!(pDCTstat->Status & (1 << SB_HWHole))) {
- if (!(pDCTstat->Status & (1 << SB_SWNodeHole))) {
- /* SW memhole disabled */
- u32 lo, hi;
- _RDMSR(TOP_MEM, &lo, &hi);
- lo >>= 8;
- if ((val >= lo) && (val < _4GB_RJ8)) {
- val = 0;
- *valid = 0;
- goto exitGetAddr;
- } else {
- *valid = 1;
- goto exitGetAddrWNoError;
- }
- } else {
- *valid = 1;
- goto exitGetAddrWNoError;
- }
- } else {
- *valid = 1;
- goto exitGetAddrWNoError;
- }
-
-exitGetAddrWNoError:
-
- /* Skip if Address is in UMA region */
- dword = pMCTstat->Sub4GCacheTop;
- dword >>= 8;
- if (dword != 0) {
- if ((val >= dword) && (val < _4GB_RJ8)) {
- val = 0;
- *valid = 0;
- } else {
- *valid = 1;
- }
- }
- print_debug_dqs("mct_GetMCTSysAddr_D: receiver ", receiver, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: Channel ", Channel, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: base_addr ", val, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: valid ", *valid, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: status ", pDCTstat->Status, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: SysBase ", pDCTstat->DCTSysBase, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: HoleBase ", pDCTstat->DCTHoleBase, 2);
- print_debug_dqs("mct_GetMCTSysAddr_D: Cachetop ", pMCTstat->Sub4GCacheTop, 2);
-
-exitGetAddr:
- return val;
-}
-
-void mct_Write1LTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 TestAddr, u8 pattern)
-{
-
- u8 *buf;
-
- /* Issue the stream of writes. When F2x11C[MctWrLimit] is reached
- * (or when F2x11C[FlushWr] is set again), all the writes are written
- * to DRAM.
- */
-
- SetUpperFSbase(TestAddr);
-
- if (pattern)
- buf = (u8 *)pDCTstat->PtrPatternBufB;
- else
- buf = (u8 *)pDCTstat->PtrPatternBufA;
-
- WriteLNTestPattern(TestAddr << 8, buf, 1);
-}
-
-void mct_Read1LTestPattern_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 addr)
-{
- u32 value;
-
- /* BIOS issues the remaining (Ntrain - 2) reads after checking that
- * F2x11C[PrefDramTrainMode] is cleared. These reads must be to
- * consecutive cache lines (i.e., 64 bytes apart) and must not cross
- * a naturally aligned 4KB boundary. These reads hit the prefetches and
- * read the data from the prefetch buffer.
- */
-
- /* get data from DIMM */
- SetUpperFSbase(addr);
-
- /* 1st move causes read fill (to exclusive or shared)*/
- value = read32_fs(addr << 8);
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctecc_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mctecc_d.c
deleted file mode 100644
index 4c33b9e4b6..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctecc_d.c
+++ /dev/null
@@ -1,389 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 - 2016 Raptor Engineering, LLC
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/cpu.h>
-#include <stdint.h>
-#include <console/console.h>
-#include <device/pci_ops.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static void setSyncOnUnEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA);
-static u8 isDramECCEn_D(struct DCTStatStruc *pDCTstat);
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-/* Initialize ECC modes of Integrated Dram+Memory Controllers of a network of
- * Hammer processors. Use Dram background scrubber to fast initialize ECC bits
- * of all dram.
- *
- * Notes:
- *
- * Order that items are set:
- * 1. eccen bit in NB
- * 2. Scrub Base
- * 3. Temp Node Base
- * 4. Temp Node Limit
- * 5. Redir bit in NB
- * 6. Scrub CTL
- *
- * Conditions for setting background scrubber.
- * 1. node is present
- * 2. node has dram functioning (WE = RE = 1)
- * 3. all eccdimms (or bit 17 of offset 90,fn 2)
- * 4. no chip-select gap exists
- *
- * The dram background scrubber is used under very controlled circumstances to
- * initialize all the ECC bits on the DIMMs of the entire dram address map
- * (including hidden or lost dram and dram above 4GB). We will turn the scrub
- * rate up to maximum, which should clear 4GB of dram in about 2.7 seconds.
- * We will activate the scrubbers of all nodes with ecc dram and let them run in
- * parallel, thereby reducing even further the time required to condition dram.
- * Finally, we will go through each node and either disable background scrubber,
- * or set the scrub rate to the user setup specified rate.
- *
- * To allow the NB to scrub, we need to wait a time period long enough to
- * guarantee that the NB scrubs the entire dram on its node. Do do this, we
- * simply sample the scrub ADDR once, for an initial value, then we sample and poll until the polled value of scrub ADDR
- * has wrapped around at least once: Scrub ADDRi+1 < Scrub ADDRi. Since we let all
- * Nodes run in parallel, we need to guarantee that all nodes have wrapped. To do
- * this efficiently, we need only to sample one of the nodes, the node with the
- * largest ammount of dram populated is the one which will take the longest amount
- * of time (the scrub rate is set to max, the same rate, on all nodes). So,
- * during setup of scrub Base, we determine how much memory and which node has
- * the largest memory installed.
- *
- * Scrubbing should not ordinarily be enabled on a Node with a chip-select gap
- * (aka SW memhole, cs hoisting, etc..).To init ECC memory on this node, the
- * scrubber is used in two steps. First, the Dram Limit for the node is adjusted
- * down to the bottom of the gap, and that ECC dram is initialized. Second, the
- * original Limit is restored, the Scrub base is set to 4GB, and scrubber is
- * allowed to run until the Scrub Addr wraps around to zero.
- */
-u8 ECCInit_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u8 AllECC;
- u16 OB_NBECC;
- u32 curBase;
- u16 OB_ECCRedir;
- u32 LDramECC;
- u32 OF_ScrubCTL;
- u16 OB_ChipKill;
- u8 MemClrECC;
-
- u32 dev;
- u32 reg;
- u32 val;
- u16 nvbits;
-
- uint32_t dword;
- uint8_t sync_flood_on_dram_err[MAX_NODES_SUPPORTED];
- uint8_t sync_flood_on_any_uc_err[MAX_NODES_SUPPORTED];
-
- mctHookBeforeECC();
-
- /* Construct these booleans, based on setup options, for easy handling
- later in this procedure */
- OB_NBECC = mctGet_NVbits(NV_NBECC); /* MCA ECC (MCE) enable bit */
-
- OB_ECCRedir = mctGet_NVbits(NV_ECCRedir); /* ECC Redirection */
-
- OB_ChipKill = mctGet_NVbits(NV_ChipKill); /* ECC Chip-kill mode */
- OF_ScrubCTL = 0; /* Scrub CTL for Dcache, L2, and dram */
-
- if (!is_fam15h()) {
- nvbits = mctGet_NVbits(NV_DCBKScrub);
- /* mct_AdjustScrub_D(pDCTstatA, &nvbits); */ /* Need not adjust */
- OF_ScrubCTL |= (u32) nvbits << 16;
-
- nvbits = mctGet_NVbits(NV_L2BKScrub);
- OF_ScrubCTL |= (u32) nvbits << 8;
- }
-
- nvbits = mctGet_NVbits(NV_L3BKScrub);
- OF_ScrubCTL |= (nvbits & 0x1f) << 24; /* L3Scrub = NV_L3BKScrub */
-
- nvbits = mctGet_NVbits(NV_DramBKScrub);
- OF_ScrubCTL |= nvbits; /* DramScrub = NV_DramBKScrub */
-
- /* Prevent lockups on DRAM errors during ECC init */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (NodePresent_D(Node)) {
- dword = Get_NB32(pDCTstat->dev_nbmisc, 0x44);
- sync_flood_on_dram_err[Node] = (dword >> 30) & 0x1;
- sync_flood_on_any_uc_err[Node] = (dword >> 21) & 0x1;
- dword &= ~(0x1 << 30);
- dword &= ~(0x1 << 21);
- Set_NB32(pDCTstat->dev_nbmisc, 0x44, dword);
-
- uint32_t mc4_status_high = pci_read_config32(pDCTstat->dev_nbmisc, 0x4c);
- uint32_t mc4_status_low = pci_read_config32(pDCTstat->dev_nbmisc, 0x48);
- if ((mc4_status_high & (0x1 << 31)) && (mc4_status_high != 0xffffffff)) {
- printk(BIOS_WARNING, "WARNING: MC4 Machine Check Exception detected!\n"
- "Signature: %08x%08x\n", mc4_status_high, mc4_status_low);
- }
-
- /* Clear MC4 error status */
- pci_write_config32(pDCTstat->dev_nbmisc, 0x48, 0x0);
- pci_write_config32(pDCTstat->dev_nbmisc, 0x4c, 0x0);
- }
- }
-
- AllECC = 1;
- MemClrECC = 0;
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- LDramECC = 0;
- if (NodePresent_D(Node)) { /*If Node is present */
- dev = pDCTstat->dev_map;
- reg = 0x40+(Node << 3); /* Dram Base Node 0 + index */
- val = Get_NB32(dev, reg);
-
- /* WE/RE is checked */
- if ((val & 3) == 3) { /* Node has dram populated */
- /* Negate 'all nodes/dimms ECC' flag if non ecc
- memory populated */
- if (pDCTstat->Status & (1 << SB_ECCDIMMs)) {
- LDramECC = isDramECCEn_D(pDCTstat);
- if (pDCTstat->ErrCode != SC_RunningOK) {
- pDCTstat->Status &= ~(1 << SB_ECCDIMMs);
- if (!OB_NBECC) {
- pDCTstat->ErrStatus |= (1 << SB_DramECCDis);
- }
- AllECC = 0;
- LDramECC = 0;
- }
- } else {
- AllECC = 0;
- }
- if (LDramECC) { /* if ECC is enabled on this dram */
- if (OB_NBECC) {
- mct_EnableDatIntlv_D(pMCTstat, pDCTstat);
- val = Get_NB32(pDCTstat->dev_dct, 0x110);
- val |= 1 << 5; /* DctDatIntLv = 1 */
- Set_NB32(pDCTstat->dev_dct, 0x110, val);
- dev = pDCTstat->dev_nbmisc;
- reg = 0x44; /* MCA NB Configuration */
- val = Get_NB32(dev, reg);
- val |= 1 << 22; /* EccEn */
- Set_NB32(dev, reg, val);
- DCTMemClr_Init_D(pMCTstat, pDCTstat);
- MemClrECC = 1;
- printk(BIOS_DEBUG, " ECC enabled on node: %02x\n", Node);
- }
- } /* this node has ECC enabled dram */
-
- if (MemClrECC) {
- DCTMemClr_Sync_D(pMCTstat, pDCTstat);
- }
- } else {
- LDramECC = 0;
- } /* Node has Dram */
- } /* if Node present */
- }
-
- if (AllECC)
- pMCTstat->GStatus |= 1 << GSB_ECCDIMMs;
- else
- pMCTstat->GStatus &= ~(1 << GSB_ECCDIMMs);
-
- /* Program the Dram BKScrub CTL to the proper (user selected) value.*/
- /* Reset MC4_STS. */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- LDramECC = 0;
- if (NodePresent_D(Node)) { /* If Node is present */
- reg = 0x40+(Node << 3); /* Dram Base Node 0 + index */
- val = Get_NB32(pDCTstat->dev_map, reg);
- curBase = val & 0xffff0000;
- /*WE/RE is checked because memory config may have been */
- if ((val & 3) == 3) { /* Node has dram populated */
- if (isDramECCEn_D(pDCTstat)) { /* if ECC is enabled on this dram */
- dev = pDCTstat->dev_nbmisc;
- val = curBase << 8;
- if (OB_ECCRedir) {
- val |= (1 << 0); /* Enable redirection */
- }
- Set_NB32(dev, 0x5c, val); /* Dram Scrub Addr Low */
- val = curBase >> 24;
- Set_NB32(dev, 0x60, val); /* Dram Scrub Addr High */
-
- /* Set scrub rate controls */
- if (is_fam15h()) {
- /* Erratum 505 */
- fam15h_switch_dct(pDCTstat->dev_map, 0);
- }
- Set_NB32(dev, 0x58, OF_ScrubCTL); /* Scrub Control */
- if (is_fam15h()) {
- fam15h_switch_dct(pDCTstat->dev_map, 1); /* Erratum 505 */
- Set_NB32(dev, 0x58, OF_ScrubCTL); /* Scrub Control */
- fam15h_switch_dct(pDCTstat->dev_map, 0); /* Erratum 505 */
- }
-
- if (!is_fam15h()) {
- /* Divisor should not be set deeper than
- * divide by 16 when Dcache scrubber or
- * L2 scrubber is enabled.
- */
- if ((OF_ScrubCTL & (0x1F << 16)) || (OF_ScrubCTL & (0x1F << 8))) {
- val = Get_NB32(dev, 0x84);
- if ((val & 0xE0000000) > 0x80000000) { /* Get F3x84h[31:29]ClkDivisor for C1 */
- val &= 0x1FFFFFFF; /* If ClkDivisor is deeper than divide-by-16 */
- val |= 0x80000000; /* set it to divide-by-16 */
- Set_NB32(dev, 0x84, val);
- }
- }
- }
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_GT_D0 | AMD_FAM15_ALL)) {
- /* Set up message triggered C1E */
- val = pci_read_config32(pDCTstat->dev_nbmisc, 0xd4);
- val &= ~(0x1 << 15); /* StutterScrubEn = DRAM scrub enabled */
- val |= (mctGet_NVbits(NV_DramBKScrub)?1:0) << 15;
- pci_write_config32(pDCTstat->dev_nbmisc, 0xd4, val);
- }
- } /* this node has ECC enabled dram */
- } /*Node has Dram */
- } /*if Node present */
- }
-
- /* Restore previous MCA error handling settings */
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (NodePresent_D(Node)) {
- dev = pDCTstat->dev_map;
- reg = 0x40 + (Node << 3); /* Dram Base Node 0 + index */
- val = Get_NB32(dev, reg);
-
- /* WE/RE is checked */
- if ((val & 0x3) == 0x3) { /* Node has dram populated */
- uint32_t mc4_status_high = pci_read_config32(pDCTstat->dev_nbmisc, 0x4c);
- uint32_t mc4_status_low = pci_read_config32(pDCTstat->dev_nbmisc, 0x48);
- if ((mc4_status_high & (0x1 << 31)) && (mc4_status_high != 0xffffffff)) {
- printk(BIOS_WARNING, "WARNING: MC4 Machine Check Exception detected!\n"
- "Signature: %08x%08x\n", mc4_status_high, mc4_status_low);
- }
-
- /* Clear MC4 error status */
- pci_write_config32(pDCTstat->dev_nbmisc, 0x48, 0x0);
- pci_write_config32(pDCTstat->dev_nbmisc, 0x4c, 0x0);
-
- /* Restore previous MCA error handling settings */
- dword = Get_NB32(pDCTstat->dev_nbmisc, 0x44);
- dword |= (sync_flood_on_dram_err[Node] & 0x1) << 30;
- dword |= (sync_flood_on_any_uc_err[Node] & 0x1) << 21;
- Set_NB32(pDCTstat->dev_nbmisc, 0x44, dword);
- }
- }
- }
-
- if (mctGet_NVbits(NV_SyncOnUnEccEn))
- setSyncOnUnEccEn_D(pMCTstat, pDCTstatA);
-
- mctHookAfterECC();
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (NodePresent_D(Node)) {
- printk(BIOS_DEBUG, "ECCInit: Node %02x\n", Node);
- printk(BIOS_DEBUG, "ECCInit: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "ECCInit: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "ECCInit: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "ECCInit: Done\n");
- }
- }
- return MemClrECC;
-}
-
-static void setSyncOnUnEccEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u32 Node;
- u32 reg;
- u32 dev;
- u32 val;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (NodePresent_D(Node)) { /* If Node is present*/
- reg = 0x40+(Node << 3); /* Dram Base Node 0 + index*/
- val = Get_NB32(pDCTstat->dev_map, reg);
- /*WE/RE is checked because memory config may have been*/
- if ((val & 3) == 3) { /* Node has dram populated*/
- if (isDramECCEn_D(pDCTstat)) {
- /*if ECC is enabled on this dram*/
- dev = pDCTstat->dev_nbmisc;
- reg = 0x44; /* MCA NB Configuration*/
- val = Get_NB32(dev, reg);
- val |= (1 << SyncOnUcEccEn);
- Set_NB32(dev, reg, val);
- }
- } /* Node has Dram*/
- } /* if Node present*/
- }
-}
-
-static u8 isDramECCEn_D(struct DCTStatStruc *pDCTstat)
-{
- u32 reg;
- u32 val;
- u8 i;
- u32 dev = pDCTstat->dev_dct;
- u8 ch_end;
- u8 isDimmECCEn = 0;
-
- if (pDCTstat->GangedMode) {
- ch_end = 1;
- } else {
- ch_end = 2;
- }
- for (i = 0; i < ch_end; i++) {
- if (pDCTstat->DIMMValidDCT[i] > 0) {
- reg = 0x90; /* Dram Config Low */
- val = Get_NB32_DCT(dev, i, reg);
- if (val & (1 << DimmEcEn)) {
- /* set local flag 'dram ecc capable' */
- isDimmECCEn = 1;
- break;
- }
- }
- }
- return isDimmECCEn;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mcthdi.c b/src/northbridge/amd/amdmct/mct_ddr3/mcthdi.c
deleted file mode 100644
index c821ec0628..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mcthdi.c
+++ /dev/null
@@ -1,33 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-void mct_DramInit_Hw_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 val;
- u32 reg;
- u32 dev = pDCTstat->dev_dct;
-
- /*flag for selecting HW/SW DRAM Init HW DRAM Init */
- reg = 0x90; /*DRAM Configuration Low */
- val = Get_NB32_DCT(dev, dct, reg);
- val |= (1<<InitDram);
- Set_NB32_DCT(dev, dct, reg, val);
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mcthwl.c b/src/northbridge/amd/amdmct/mct_ddr3/mcthwl.c
deleted file mode 100644
index 1ee10608b9..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mcthwl.c
+++ /dev/null
@@ -1,305 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/cpu.h>
-#include <stdint.h>
-#include <console/console.h>
-#include <string.h>
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-static void SetEccWrDQS_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat)
-{
- u8 ByteLane, DimmNum, OddByte, Addl_Index, Channel;
- u8 EccRef1, EccRef2, EccDQSScale;
- u32 val;
- u16 word;
-
- for (Channel = 0; Channel < 2; Channel ++) {
- for (DimmNum = 0; DimmNum < C_MAX_DIMMS; DimmNum ++) { /* we use DimmNum instead of DimmNumx3 */
- for (ByteLane = 0; ByteLane < 9; ByteLane ++) {
- /* Get RxEn initial value from WrDqs */
- if (ByteLane & 1)
- OddByte = 1;
- else
- OddByte = 0;
- if (ByteLane < 2)
- Addl_Index = 0x30;
- else if (ByteLane < 4)
- Addl_Index = 0x31;
- else if (ByteLane < 6)
- Addl_Index = 0x40;
- else if (ByteLane < 8)
- Addl_Index = 0x41;
- else
- Addl_Index = 0x32;
- Addl_Index += DimmNum * 3;
-
- val = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, Channel, 0x98, Addl_Index);
- if (OddByte)
- val >>= 16;
- /* Save WrDqs to stack for later usage */
- pDCTstat->persistentData.CH_D_B_TxDqs[Channel][DimmNum][ByteLane] = val & 0xFF;
- EccDQSScale = pDCTstat->CH_EccDQSScale[Channel];
- word = pDCTstat->CH_EccDQSLike[Channel];
- if ((word & 0xFF) == ByteLane) EccRef1 = val & 0xFF;
- if (((word >> 8) & 0xFF) == ByteLane) EccRef2 = val & 0xFF;
- }
- }
- }
-}
-
-static void EnableAutoRefresh_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat)
-{
- u32 val;
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x8C);
- val &= ~(1 << DisAutoRefresh);
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x8C, val);
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x8C);
- val &= ~(1 << DisAutoRefresh);
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x8C, val);
-}
-
-static void DisableAutoRefresh_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 val;
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x8C);
- val |= 1 << DisAutoRefresh;
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x8C, val);
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x8C);
- val |= 1 << DisAutoRefresh;
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x8C, val);
-}
-
-
-static uint8_t PhyWLPass1(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 dimm;
- u16 DIMMValid;
- uint8_t status = 0;
- void *DCTPtr;
-
- dct &= 1;
-
- DCTPtr = (void *)(pDCTstat->C_DCTPtr[dct]);
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[dct];
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[dct];
-
- if (pDCTstat->GangedMode & 1)
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[0];
-
- if (pDCTstat->DIMMValid) {
- DIMMValid = pDCTstat->DIMMValid;
- PrepareC_DCT(pMCTstat, pDCTstat, dct);
- for (dimm = 0; dimm < MAX_DIMMS_SUPPORTED; dimm ++) {
- if (DIMMValid & (1 << (dimm << 1))) {
- status |= AgesaHwWlPhase1(pMCTstat, pDCTstat, dct, dimm, FirstPass);
- status |= AgesaHwWlPhase2(pMCTstat, pDCTstat, dct, dimm, FirstPass);
- status |= AgesaHwWlPhase3(pMCTstat, pDCTstat, dct, dimm, FirstPass);
- }
- }
- }
-
- return status;
-}
-
-static uint8_t PhyWLPass2(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t final)
-{
- u8 dimm;
- u16 DIMMValid;
- uint8_t status = 0;
- void *DCTPtr;
-
- dct &= 1;
-
- DCTPtr = (void *)&(pDCTstat->C_DCTPtr[dct]); /* todo: */
- pDCTstat->DIMMValid = pDCTstat->DIMMValidDCT[dct];
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[dct];
-
- if (pDCTstat->GangedMode & 1)
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[0];
-
- if (pDCTstat->DIMMValid) {
- DIMMValid = pDCTstat->DIMMValid;
- PrepareC_DCT(pMCTstat, pDCTstat, dct);
- pDCTstat->Speed = pDCTstat->DIMMAutoSpeed = pDCTstat->TargetFreq;
- pDCTstat->CASL = pDCTstat->DIMMCASL = pDCTstat->TargetCASL;
- SPD2ndTiming(pMCTstat, pDCTstat, dct);
- if (!is_fam15h()) {
- ProgDramMRSReg_D(pMCTstat, pDCTstat, dct);
- PlatformSpec_D(pMCTstat, pDCTstat, dct);
- fenceDynTraining_D(pMCTstat, pDCTstat, dct);
- }
- Restore_OnDimmMirror(pMCTstat, pDCTstat);
- StartupDCT_D(pMCTstat, pDCTstat, dct);
- Clear_OnDimmMirror(pMCTstat, pDCTstat);
- SetDllSpeedUp_D(pMCTstat, pDCTstat, dct);
- DisableAutoRefresh_D(pMCTstat, pDCTstat);
- for (dimm = 0; dimm < MAX_DIMMS_SUPPORTED; dimm ++) {
- if (DIMMValid & (1 << (dimm << 1))) {
- status |= AgesaHwWlPhase1(pMCTstat, pDCTstat, dct, dimm, SecondPass);
- status |= AgesaHwWlPhase2(pMCTstat, pDCTstat, dct, dimm, SecondPass);
- status |= AgesaHwWlPhase3(pMCTstat, pDCTstat, dct, dimm, SecondPass);
- }
- }
- }
-
- return status;
-}
-
-static uint16_t fam15h_next_highest_memclk_freq(uint16_t memclk_freq)
-{
- uint16_t fam15h_next_highest_freq_tab[] = {0, 0, 0, 0, 0x6, 0, 0xa, 0, 0, 0, 0xe, 0, 0, 0, 0x12, 0, 0, 0, 0x16, 0, 0, 0, 0x16};
- return fam15h_next_highest_freq_tab[memclk_freq];
-}
-
-/* Write Levelization Training
- * Algorithm detailed in the Fam10h BKDG Rev. 3.62 section 2.8.9.9.1
- */
-static void WriteLevelization_HW(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA, uint8_t Node, uint8_t Pass)
-{
- uint8_t status;
- uint8_t timeout;
- uint16_t final_target_freq;
-
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- pDCTstat->C_MCTPtr = &(pDCTstat->s_C_MCTPtr);
- pDCTstat->C_DCTPtr[0] = &(pDCTstat->s_C_DCTPtr[0]);
- pDCTstat->C_DCTPtr[1] = &(pDCTstat->s_C_DCTPtr[1]);
-
- /* Disable auto refresh by configuring F2x[1, 0]8C[DisAutoRefresh] = 1 */
- DisableAutoRefresh_D(pMCTstat, pDCTstat);
-
- /* Disable ZQ calibration short command by F2x[1,0]94[ZqcsInterval]=00b */
- DisableZQcalibration(pMCTstat, pDCTstat);
- PrepareC_MCT(pMCTstat, pDCTstat);
-
- if (pDCTstat->GangedMode & (1 << 0)) {
- pDCTstat->DIMMValidDCT[1] = pDCTstat->DIMMValidDCT[0];
- }
-
- if (Pass == FirstPass) {
- timeout = 0;
- do {
- status = 0;
- timeout++;
- status |= PhyWLPass1(pMCTstat, pDCTstat, 0);
- status |= PhyWLPass1(pMCTstat, pDCTstat, 1);
- if (status)
- printk(BIOS_INFO,
- "%s: Retrying write levelling due to invalid value(s) detected in first phase\n",
- __func__);
- } while (status && (timeout < 8));
- if (status)
- printk(BIOS_INFO,
- "%s: Uncorrectable invalid value(s) detected in first phase of write levelling\n",
- __func__);
- }
-
- if (Pass == SecondPass) {
- if (pDCTstat->TargetFreq > mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK))) {
- /* 8.Prepare the memory subsystem for the target MEMCLK frequency.
- * NOTE: BIOS must program both DCTs to the same frequency.
- * NOTE: Fam15h steps the frequency, Fam10h slams the frequency.
- */
- uint8_t global_phy_training_status = 0;
- final_target_freq = pDCTstat->TargetFreq;
-
- while (pDCTstat->Speed != final_target_freq) {
- if (is_fam15h())
- pDCTstat->TargetFreq = fam15h_next_highest_memclk_freq(pDCTstat->Speed);
- else
- pDCTstat->TargetFreq = final_target_freq;
- SetTargetFreq(pMCTstat, pDCTstatA, Node);
- timeout = 0;
- do {
- status = 0;
- timeout++;
- status |= PhyWLPass2(pMCTstat, pDCTstat, 0, (pDCTstat->TargetFreq == final_target_freq));
- status |= PhyWLPass2(pMCTstat, pDCTstat, 1, (pDCTstat->TargetFreq == final_target_freq));
- if (status)
- printk(BIOS_INFO,
- "%s: Retrying write levelling due to invalid value(s) detected in last phase\n",
- __func__);
- } while (status && (timeout < 8));
- global_phy_training_status |= status;
- }
-
- pDCTstat->TargetFreq = final_target_freq;
-
- if (global_phy_training_status)
- printk(BIOS_WARNING,
- "%s: Uncorrectable invalid value(s) detected in second phase of write levelling; "
- "continuing but system may be unstable!\n",
- __func__);
-
- uint8_t dct;
- for (dct = 0; dct < 2; dct++) {
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- memcpy(pDCTData->WLGrossDelayFinalPass, pDCTData->WLGrossDelayPrevPass, sizeof(pDCTData->WLGrossDelayPrevPass));
- memcpy(pDCTData->WLFineDelayFinalPass, pDCTData->WLFineDelayPrevPass, sizeof(pDCTData->WLFineDelayPrevPass));
- pDCTData->WLCriticalGrossDelayFinalPass = pDCTData->WLCriticalGrossDelayPrevPass;
- }
- }
- }
-
- SetEccWrDQS_D(pMCTstat, pDCTstat);
- EnableAutoRefresh_D(pMCTstat, pDCTstat);
- EnableZQcalibration(pMCTstat, pDCTstat);
-}
-
-void mct_WriteLevelization_HW(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA, uint8_t Pass)
-{
- u8 Node;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (pDCTstat->NodePresent) {
- mctSMBhub_Init(Node);
- Clear_OnDimmMirror(pMCTstat, pDCTstat);
- WriteLevelization_HW(pMCTstat, pDCTstatA, Node, Pass);
- Restore_OnDimmMirror(pMCTstat, pDCTstat);
- }
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctmtr_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mctmtr_d.c
deleted file mode 100644
index 73370e715b..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctmtr_d.c
+++ /dev/null
@@ -1,256 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include <console/console.h>
-#include <cpu/amd/mtrr.h>
-#include <cpu/x86/mtrr.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static void SetMTRRrangeWB_D(u32 Base, u32 *pLimit, u32 *pMtrrAddr);
-static void SetMTRRrange_D(u32 Base, u32 *pLimit, u32 *pMtrrAddr, u16 MtrrType);
-
-void CPUMemTyping_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /* BSP only. Set the fixed MTRRs for common legacy ranges.
- * Set TOP_MEM and TOM2.
- * Set some variable MTRRs with WB Uncacheable type.
- */
-
- u32 Bottom32bIO, Bottom40bIO, Cache32bTOP;
- u32 val;
- u32 addr;
- u32 lo, hi;
-
- /* Set temporary top of memory from Node structure data.
- * Adjust temp top of memory down to accommodate 32-bit IO space.
- * Bottom40bIO = top of memory, right justified 8 bits
- * (defines dram versus IO space type)
- * Bottom32bIO = sub 4GB top of memory, right justified 8 bits
- * (defines dram versus IO space type)
- * Cache32bTOP = sub 4GB top of WB cacheable memory,
- * right justified 8 bits
- */
-
- val = mctGet_NVbits(NV_BottomIO);
- if (val == 0)
- val++;
-
- Bottom32bIO = val << (24-8);
-
- val = pMCTstat->SysLimit + 1;
- if (val <= _4GB_RJ8) {
- Bottom40bIO = 0;
- if (Bottom32bIO >= val)
- Bottom32bIO = val;
- } else {
- Bottom40bIO = val;
- }
-
- Cache32bTOP = Bottom32bIO;
-
- /*======================================================================
- Set default values for CPU registers
- ======================================================================*/
-
- /* NOTE : For coreboot, we don't need to set mtrr enables here because
- they are still enable from cache_as_ram.inc */
-
- addr = MTRR_FIX_64K_00000;
- lo = 0x1E1E1E1E;
- hi = lo;
- _WRMSR(addr, lo, hi); /* 0 - 512K = WB Mem */
- addr = MTRR_FIX_16K_80000;
- _WRMSR(addr, lo, hi); /* 512K - 640K = WB Mem */
-
- /*======================================================================
- Set variable MTRR values
- ======================================================================*/
- /* NOTE: for coreboot change from 0x200 to 0x204: coreboot is using
- 0x200, 0x201 for [1M, CONFIG_TOP_MEM)
- 0x202, 0x203 for ROM Caching
- */
- addr = MTRR_PHYS_BASE(2); /* MTRR phys base 2*/
- /* use TOP_MEM as limit*/
- /* Limit = TOP_MEM|TOM2*/
- /* Base = 0*/
- printk(BIOS_DEBUG, "\t CPUMemTyping: Cache32bTOP:%x\n", Cache32bTOP);
- SetMTRRrangeWB_D(0, &Cache32bTOP, &addr);
- /* Base */
- /* Limit */
- /* MtrrAddr */
- if (addr == -1) /* ran out of MTRRs?*/
- pMCTstat->GStatus |= 1<<GSB_MTRRshort;
-
- pMCTstat->Sub4GCacheTop = Cache32bTOP<<8;
-
- /*======================================================================
- Set TOP_MEM and TOM2 CPU registers
- ======================================================================*/
- addr = TOP_MEM;
- lo = Bottom32bIO<<8;
- hi = Bottom32bIO>>24;
- _WRMSR(addr, lo, hi);
- printk(BIOS_DEBUG, "\t CPUMemTyping: Bottom32bIO:%x\n", Bottom32bIO);
- printk(BIOS_DEBUG, "\t CPUMemTyping: Bottom40bIO:%x\n", Bottom40bIO);
- if (Bottom40bIO) {
- hi = Bottom40bIO >> 24;
- lo = Bottom40bIO << 8;
- addr += 3; /* TOM2 */
- _WRMSR(addr, lo, hi);
- }
- addr = SYSCFG_MSR; /* SYS_CFG */
- _RDMSR(addr, &lo, &hi);
- if (Bottom40bIO) {
- lo |= SYSCFG_MSR_TOM2En; /* MtrrTom2En = 1 */
- lo |= SYSCFG_MSR_TOM2WB; /* Tom2ForceMemTypeWB */
- } else {
- lo &= ~SYSCFG_MSR_TOM2En; /* MtrrTom2En = 0 */
- lo &= ~SYSCFG_MSR_TOM2WB; /* Tom2ForceMemTypeWB */
- }
- _WRMSR(addr, lo, hi);
-}
-
-static void SetMTRRrangeWB_D(u32 Base, u32 *pLimit, u32 *pMtrrAddr)
-{
- /*set WB type*/
- SetMTRRrange_D(Base, pLimit, pMtrrAddr, 6);
-}
-
-static void SetMTRRrange_D(u32 Base, u32 *pLimit, u32 *pMtrrAddr, u16 MtrrType)
-{
- /* Program MTRRs to describe given range as given cache type.
- * Use MTRR pairs starting with the given MTRRphys Base address,
- * and use as many as is required up to (excluding) MSR 020C, which
- * is reserved for OS.
- *
- * "Limit" in the context of this procedure is not the numerically
- * correct limit, but rather the Last address+1, for purposes of coding
- * efficiency and readability. Size of a region is then Limit-Base.
- *
- * 1. Size of each range must be a power of two
- * 2. Each range must be naturally aligned (Base is same as size)
- *
- * There are two code paths: the ascending path and descending path
- * (analogous to bsf and bsr), where the next limit is a function of the
- * next set bit in a forward or backward sequence of bits (as a function
- * of the Limit). We start with the ascending path, to ensure that
- * regions are naturally aligned, then we switch to the descending path
- * to maximize MTRR usage efficiency. Base = 0 is a special case where we
- * start with the descending path. Correct Mask for region is
- * 2comp(Size-1)-1, which is 2comp(Limit-Base-1)-1
- */
-
- u32 curBase, curLimit, curSize;
- u32 val, valx;
- u32 addr;
-
- val = curBase = Base;
- curLimit = *pLimit;
- addr = *pMtrrAddr;
- while ((addr >= 0x200) && (addr < 0x20C) && (val < *pLimit)) {
- /* start with "ascending" code path */
- /* alignment (largest block size)*/
- valx = 1 << bsf(curBase);
- curSize = valx;
-
- /* largest legal limit, given current non-zero range Base*/
- valx += curBase;
- if ((curBase == 0) || (*pLimit < valx)) {
- /* flop direction to "descending" code path*/
- valx = 1<<bsr(*pLimit - curBase);
- curSize = valx;
- valx += curBase;
- }
- curLimit = valx; /*eax = curBase, edx = curLimit*/
- valx = val>>24;
- val <<= 8;
-
- /* now program the MTRR */
- val |= MtrrType; /* set cache type (UC or WB)*/
- _WRMSR(addr, val, valx); /* prog. MTRR with current region Base*/
- val = ((~(curSize - 1))+1) - 1; /* Size-1*/ /*Mask = 2comp(Size-1)-1*/
- valx = (val >> 24) | (0xff00); /* GH have 48 bits addr */
- val <<= 8;
- val |= (1 << 11); /* set MTRR valid*/
- addr++;
- _WRMSR(addr, val, valx); /* prog. MTRR with current region Mask*/
- val = curLimit;
- curBase = val; /* next Base = current Limit (loop exit)*/
- addr++; /* next MTRR pair addr */
- }
- if (val < *pLimit) {
- *pLimit = val;
- addr = -1;
- }
- *pMtrrAddr = addr;
-}
-
-void UMAMemTyping_D(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA)
-{
- /* UMA memory size may need splitting the MTRR configuration into two
- * Before training use NB_BottomIO or the physical memory size to set the MTRRs.
- * After training, add UMAMemTyping function to reconfigure the MTRRs based on
- * NV_BottomUMA (for UMA systems only).
- * This two-step process allows all memory to be cached for training
- */
-
- u32 Bottom32bIO, Cache32bTOP;
- u32 val;
- u32 addr;
- u32 lo, hi;
-
- /*======================================================================
- * Adjust temp top of memory down to accommodate UMA memory start
- *======================================================================*/
- /* Bottom32bIO = sub 4GB top of memory, right justified 8 bits
- * (defines dram versus IO space type)
- * Cache32bTOP = sub 4GB top of WB cacheable memory, right justified 8 bits */
-
- Bottom32bIO = pMCTstat->Sub4GCacheTop >> 8;
-
- val = mctGet_NVbits(NV_BottomUMA);
- if (val == 0)
- val++;
-
- val <<= (24-8);
- if (val < Bottom32bIO) {
- Cache32bTOP = val;
- pMCTstat->Sub4GCacheTop = val;
-
- /*======================================================================
- * Clear variable MTRR values
- *======================================================================*/
- addr = MTRR_PHYS_BASE(0);
- lo = 0;
- hi = lo;
- while (addr < MTRR_PHYS_BASE(6)) {
- _WRMSR(addr, lo, hi); /* prog. MTRR with current region Mask */
- addr++; /* next MTRR pair addr */
- }
-
- /*======================================================================
- * Set variable MTRR values
- *======================================================================*/
- printk(BIOS_DEBUG, "\t UMAMemTyping_D: Cache32bTOP:%x\n", Cache32bTOP);
- SetMTRRrangeWB_D(0, &Cache32bTOP, &addr);
- if (addr == -1) /* ran out of MTRRs?*/
- pMCTstat->GStatus |= 1<<GSB_MTRRshort;
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctndi_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mctndi_d.c
deleted file mode 100644
index 29949e02d4..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctndi_d.c
+++ /dev/null
@@ -1,233 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include <console/console.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-void InterleaveNodes_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- /* Applies Node memory interleaving if enabled and if all criteria are met. */
- u8 Node;
- u32 Base;
- u32 MemSize, MemSize0 = 0;
- u32 Dct0MemSize = 0, DctSelBase, DctSelBaseOffset = 0;
- u8 Nodes;
- u8 NodesWmem;
- u8 DoIntlv;
- u8 _NdIntCap;
- u8 _SWHole;
- u32 HWHoleSz;
- u32 DramHoleAddrReg;
- u32 HoleBase;
- u32 dev0;
- u32 reg0;
- u32 val;
- u8 i;
- struct DCTStatStruc *pDCTstat;
-
- DoIntlv = mctGet_NVbits(NV_NodeIntlv);
-
- _NdIntCap = 0;
- HWHoleSz = 0; /*For HW remapping, NOT Node hoisting. */
-
- pDCTstat = pDCTstatA + 0;
- dev0 = pDCTstat->dev_host;
- Nodes = ((Get_NB32(dev0, 0x60) >> 4) & 0x7) + 1;
-
- dev0 = pDCTstat->dev_map;
- reg0 = 0x40;
-
- NodesWmem = 0;
- Node = 0;
-
- while (DoIntlv && (Node < Nodes)) {
- pDCTstat = pDCTstatA + Node;
- if (pMCTstat->GStatus & (1 << GSB_SpIntRemapHole)) {
- pMCTstat->GStatus |= 1 << GSB_HWHole;
- _SWHole = 0;
- } else if (pDCTstat->Status & (1 << SB_SWNodeHole)) {
- _SWHole = 1;
- } else {
- _SWHole = 0;
- }
-
- if (!_SWHole) {
- Base = Get_NB32(dev0, reg0);
- if (Base & 1) {
- NodesWmem++;
- Base &= 0xFFFF0000; /* Base[39:8] */
-
- if (pDCTstat->Status & (1 << SB_HWHole)) {
-
- /* to get true amount of dram,
- * subtract out memory hole if HW dram remapping */
- DramHoleAddrReg = Get_NB32(pDCTstat->dev_map, 0xF0);
- HWHoleSz = DramHoleAddrReg >> 16;
- HWHoleSz = (((~HWHoleSz) + 1) & 0xFF);
- HWHoleSz <<= 24-8;
- }
- /* check to see if the amount of memory on each channel
- * are the same on all nodes */
-
- DctSelBase = Get_NB32(pDCTstat->dev_dct, 0x114);
- if (DctSelBase) {
- DctSelBase <<= 8;
- if (pDCTstat->Status & (1 << SB_HWHole)) {
- if (DctSelBase >= 0x1000000) {
- DctSelBase -= HWHoleSz;
- }
- }
- DctSelBaseOffset -= Base;
- if (Node == 0) {
- Dct0MemSize = DctSelBase;
- } else if (DctSelBase != Dct0MemSize) {
- break;
- }
- }
-
- MemSize = Get_NB32(dev0, reg0 + 4);
- MemSize &= 0xFFFF0000;
- MemSize += 0x00010000;
- MemSize -= Base;
- if (pDCTstat->Status & (1 << SB_HWHole)) {
- MemSize -= HWHoleSz;
- }
- if (Node == 0) {
- MemSize0 = MemSize;
- } else if (MemSize0 != MemSize) {
- break;
- }
- } else {
- break;
- }
- } else {
- break;
- }
- Node++;
- reg0 += 8;
- }
-
- if (Node == Nodes) {
- /* if all nodes have memory and no Node had SW memhole */
- if (Nodes == 2 || Nodes == 4 || Nodes == 8)
- _NdIntCap = 1;
- }
-
- if (!_NdIntCap)
- DoIntlv = 0;
-
- if (pMCTstat->GStatus & 1 << (GSB_SpIntRemapHole)) {
- HWHoleSz = pMCTstat->HoleBase;
- if (HWHoleSz == 0) {
- HWHoleSz = mctGet_NVbits(NV_BottomIO) & 0xFF;
- HWHoleSz <<= 24-8;
- }
- HWHoleSz = ((~HWHoleSz) + 1) & 0x00FF0000;
- }
-
- if (DoIntlv) {
- MCTMemClr_D(pMCTstat, pDCTstatA);
- /* Program Interleaving enabled on Node 0 map only.*/
- MemSize0 <<= bsf(Nodes); /* MemSize = MemSize*2 (or 4, or 8) */
- Dct0MemSize <<= bsf(Nodes);
- MemSize0 += HWHoleSz;
- Base = ((Nodes - 1) << 8) | 3;
- reg0 = 0x40;
- Node = 0;
- while (Node < Nodes) {
- Set_NB32(dev0, reg0, Base);
- MemSize = MemSize0;
- MemSize--;
- MemSize &= 0xFFFF0000;
- MemSize |= Node << 8; /* set IntlvSel[2:0] field */
- MemSize |= Node; /* set DstNode[2:0] field */
- Set_NB32(dev0, reg0 + 4, MemSize0);
- reg0 += 8;
- Node++;
- }
-
- /* set base/limit to F1x120/124 per Node */
- Node = 0;
- while (Node < Nodes) {
- pDCTstat = pDCTstatA + Node;
- pDCTstat->NodeSysBase = 0;
- MemSize = MemSize0;
- MemSize -= HWHoleSz;
- MemSize--;
- pDCTstat->NodeSysLimit = MemSize;
- Set_NB32(pDCTstat->dev_map, 0x120, Node << 21);
- MemSize = MemSize0;
- MemSize--;
- MemSize >>= 19;
- val = Base;
- val &= 0x700;
- val <<= 13;
- val |= MemSize;
- Set_NB32(pDCTstat->dev_map, 0x124, val);
-
- if (pMCTstat->GStatus & (1 << GSB_HWHole)) {
- HoleBase = pMCTstat->HoleBase;
- if (Dct0MemSize >= HoleBase) {
- val = HWHoleSz;
- if (Node == 0) {
- val += Dct0MemSize;
- }
- } else {
- val = HWHoleSz + Dct0MemSize;
- }
-
- val >>= 8; /* DramHoleOffset */
- HoleBase <<= 8; /* DramHoleBase */
- val |= HoleBase;
- val |= 1 << DramMemHoistValid;
- val |= 1 << DramHoleValid;
- Set_NB32(pDCTstat->dev_map, 0xF0, val);
- }
-
- Set_NB32(pDCTstat->dev_dct, 0x114, Dct0MemSize >> 8); /* DctSelBaseOffset */
- val = Get_NB32(pDCTstat->dev_dct, 0x110);
- val &= 0x7FF;
- val |= Dct0MemSize >> 8;
- Set_NB32(pDCTstat->dev_dct, 0x110, val); /* DctSelBaseAddr */
- printk(BIOS_DEBUG, "InterleaveNodes: DRAM Controller Select Low Register = %x\n", val);
- Node++;
- }
-
- /* Copy Node 0 into other Nodes' CSRs */
- Node = 1;
- while (Node < Nodes) {
- pDCTstat = pDCTstatA + Node;
-
- for (i = 0x40; i <= 0x80; i++) {
- val = Get_NB32(dev0, i);
- Set_NB32(pDCTstat->dev_map, i, val);
- }
-
- val = Get_NB32(dev0, 0xF0);
- Set_NB32(pDCTstat->dev_map, 0xF0, val);
- Node++;
- }
- pMCTstat->GStatus = (1 << GSB_NodeIntlv);
- }
- printk(BIOS_DEBUG, "InterleaveNodes_D: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "InterleaveNodes_D: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "InterleaveNodes_D: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "InterleaveNodes_D: Done\n\n");
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctprob.c b/src/northbridge/amd/amdmct/mct_ddr3/mctprob.c
deleted file mode 100644
index 3cb75675df..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctprob.c
+++ /dev/null
@@ -1,45 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-void mct_BeforeDQSTrainSamp(struct DCTStatStruc *pDCTstat)
-{
- u32 val;
-
- if (pDCTstat->LogicalCPUID & AMD_DR_Bx) {
- Set_NB32(pDCTstat->dev_dct, 0x98, 0x0D004007);
- val = Get_NB32(pDCTstat->dev_dct, 0x9C);
- val |= 0x3FF;
- Set_NB32(pDCTstat->dev_dct, 0x9C, val);
- Set_NB32(pDCTstat->dev_dct, 0x98, 0x4D0F4F07);
-
- Set_NB32(pDCTstat->dev_dct, 0x198, 0x0D004007);
- val = Get_NB32(pDCTstat->dev_dct, 0x19C);
- val |= 0x3FF;
- Set_NB32(pDCTstat->dev_dct, 0x19C, val);
- Set_NB32(pDCTstat->dev_dct, 0x198, 0x4D0F4F07);
- }
-}
-
-void mct_ExtMCTConfig_Bx(struct DCTStatStruc *pDCTstat)
-{
- if (pDCTstat->LogicalCPUID & (AMD_DR_Bx)) {
- Set_NB32(pDCTstat->dev_dct, 0x11C, 0x0FE40FC0 | 1 << 29/* FlushWrOnStpGnt */);
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctproc.c b/src/northbridge/amd/amdmct/mct_ddr3/mctproc.c
deleted file mode 100644
index ddaaaab8d5..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctproc.c
+++ /dev/null
@@ -1,113 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-/* mct_SetDramConfigMisc2_Cx & mct_SetDramConfigMisc2_Dx */
-u32 mct_SetDramConfigMisc2(struct DCTStatStruc *pDCTstat,
- uint8_t dct, uint32_t misc2, uint32_t DramControl)
-{
- u32 val;
-
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- if (pDCTstat->LogicalCPUID & AMD_FAM15_ALL) {
- uint8_t cs_mux_45;
- uint8_t cs_mux_67;
- uint32_t f2x80;
-
- misc2 &= ~(0x1 << 28); /* FastSelfRefEntryDis = 0x0 */
- if (MaxDimmsInstallable == 3) {
- /* FIXME 3 DIMMS per channel unimplemented */
- cs_mux_45 = 0;
- } else {
- uint32_t f2x60 = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x60);
- f2x80 = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x80);
- if ((((f2x80 & 0xf) == 0x7) || ((f2x80 & 0xf) == 0x9))
- && ((f2x60 & 0x3) == 0x3))
- cs_mux_45 = 1;
- else if ((((f2x80 & 0xf) == 0xa) || ((f2x80 & 0xf) == 0xb))
- && ((f2x60 & 0x3) > 0x1))
- cs_mux_45 = 1;
- else
- cs_mux_45 = 0;
- }
-
- if (MaxDimmsInstallable == 1) {
- cs_mux_67 = 0;
- } else if (MaxDimmsInstallable == 2) {
- uint32_t f2x64 = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x64);
- f2x80 = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x80);
- if (((((f2x80 >> 4) & 0xf) == 0x7) || (((f2x80 >> 4) & 0xf) == 0x9))
- && ((f2x64 & 0x3) == 0x3))
- cs_mux_67 = 1;
- else if (((((f2x80 >> 4) & 0xf) == 0xa) || (((f2x80 >> 4) & 0xf) == 0xb))
- && ((f2x64 & 0x3) > 0x1))
- cs_mux_67 = 1;
- else
- cs_mux_67 = 0;
- } else {
- /* FIXME 3 DIMMS per channel unimplemented */
- cs_mux_67 = 0;
- }
-
- misc2 &= ~(0x1 << 27); /* CsMux67 = cs_mux_67 */
- misc2 |= ((cs_mux_67 & 0x1) << 27);
- misc2 &= ~(0x1 << 26); /* CsMux45 = cs_mux_45 */
- misc2 |= ((cs_mux_45 & 0x1) << 26);
- } else if (pDCTstat->LogicalCPUID & (AMD_DR_Dx | AMD_DR_Cx)) {
- if (pDCTstat->Status & (1 << SB_Registered)) {
- misc2 |= 1 << SubMemclkRegDly;
- if (mctGet_NVbits(NV_MAX_DIMMS) == 8)
- misc2 |= 1 << Ddr3FourSocketCh;
- else
- misc2 &= ~(1 << Ddr3FourSocketCh);
- }
-
- if (pDCTstat->LogicalCPUID & AMD_DR_Cx)
- misc2 |= 1 << OdtSwizzle;
-
- val = DramControl;
- val &= 7;
- val = ((~val) & 0xff) + 1;
- val += 6;
- val &= 0x7;
- misc2 &= 0xfff8ffff;
- misc2 |= val << 16; /* DataTxFifoWrDly */
- if (pDCTstat->LogicalCPUID & AMD_DR_Dx)
- misc2 |= 1 << 7; /* ProgOdtEn */
- }
- return misc2;
-}
-
-void mct_ExtMCTConfig_Cx(struct DCTStatStruc *pDCTstat)
-{
- u32 val;
-
- if (pDCTstat->LogicalCPUID & (AMD_DR_Cx)) {
- /* Revision C */
- Set_NB32(pDCTstat->dev_dct, 0x11c, 0x0ce00fc0 | 1 << 29/* FlushWrOnStpGnt */);
-
- val = Get_NB32(pDCTstat->dev_dct, 0x1b0);
- val &= ~0x73f;
- val |= 0x101; /* BKDG recommended settings */
-
- Set_NB32(pDCTstat->dev_dct, 0x1b0, val);
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctprod.c b/src/northbridge/amd/amdmct/mct_ddr3/mctprod.c
deleted file mode 100644
index b203942058..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctprod.c
+++ /dev/null
@@ -1,66 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-void mct_ExtMCTConfig_Dx(struct DCTStatStruc *pDCTstat)
-{
- uint32_t dword;
-
- if (pDCTstat->LogicalCPUID & AMD_DR_Dx) {
- dword = 0x0ce00f00 | 0x1 << 29; /* FlushWrOnStpGnt */
- if (!(pDCTstat->GangedMode))
- dword |= 0x18 << 2; /* MctWrLimit = 0x18 for unganged mode */
- else
- dword |= 0x10 << 2; /* MctWrLimit = 0x10 for ganged mode */
- Set_NB32(pDCTstat->dev_dct, 0x11c, dword);
-
- dword = Get_NB32(pDCTstat->dev_dct, 0x1b0);
- dword &= ~0x3; /* AdapPrefMissRatio = 0x1 */
- dword |= 0x1;
- dword &= ~(0x3 << 2); /* AdapPrefPositiveStep = 0x0 */
- dword &= ~(0x3 << 4); /* AdapPrefNegativeStep = 0x0 */
- dword &= ~(0x7 << 8); /* CohPrefPrbLmt = 0x1 */
- dword |= (0x1 << 8);
- dword |= (0x7 << 22); /* PrefFourConf = 0x7 */
- dword |= (0x7 << 25); /* PrefFiveConf = 0x7 */
-
- if (!(pDCTstat->GangedMode))
- dword |= (0x1 << 12); /* EnSplitDctLimits = 0x1 */
- else
- dword &= ~(0x1 << 12); /* EnSplitDctLimits = 0x0 */
-
- dword &= ~(0xf << 28); /* DcqBwThrotWm = ... */
- switch (pDCTstat->Speed) {
- case 4:
- dword |= (0x5 << 28); /* ...5 for DDR800 */
- break;
- case 5:
- dword |= (0x6 << 28); /* ...6 for DDR1066 */
- break;
- case 6:
- dword |= (0x8 << 28); /* ...8 for DDR800 */
- break;
- default:
- dword |= (0x9 << 28); /* ...9 for DDR1600 */
- break;
- }
- Set_NB32(pDCTstat->dev_dct, 0x1b0, dword);
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctrci.c b/src/northbridge/amd/amdmct/mct_ddr3/mctrci.c
deleted file mode 100644
index 93cfb4bf1b..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctrci.c
+++ /dev/null
@@ -1,474 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 - 2016 Raptor Engineering, LLC
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/cpu.h>
-#include <stdint.h>
-#include <console/console.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-static uint8_t fam15h_rdimm_rc2_ibt_code(struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- uint8_t package_type;
- uint8_t control_code = 0;
-
- package_type = mctGet_NVbits(NV_PACK_TYPE);
- uint16_t MemClkFreq = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
-
- /* Obtain number of DIMMs on channel */
- uint8_t dimm_count = pDCTstat->MAdimms[dct];
-
- /* FIXME
- * Assume there is only one register on the RDIMM for now
- */
- uint8_t num_registers = 1;
-
- if (package_type == PT_GR) {
- /* Socket G34 */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.7.1.2.1 Table 85 */
- if (MaxDimmsInstallable == 1) {
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- control_code = 0x1;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (num_registers == 1) {
- control_code = 0x0;
- } else {
- control_code = 0x1;
- }
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- control_code = 0x0;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- control_code = 0x1;
- } else if ((MemClkFreq >= 0xa) && (MemClkFreq <= 0x12)) {
- /* DDR3-1066 - DDR3-1600 */
- if (num_registers == 1) {
- control_code = 0x0;
- } else {
- control_code = 0x1;
- }
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- if (num_registers == 1) {
- control_code = 0x1;
- } else {
- control_code = 0x8;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (package_type == PT_C3) {
- /* Socket C32 */
- /* Fam15h BKDG Rev. 3.14 section 2.10.5.7.1.2.1 Table 86 */
- if (MaxDimmsInstallable == 1) {
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- control_code = 0x1;
- } else if ((MemClkFreq == 0xa) || (MemClkFreq == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (num_registers == 1) {
- control_code = 0x0;
- } else {
- control_code = 0x1;
- }
- } else if ((MemClkFreq == 0x12) || (MemClkFreq == 0x16)) {
- /* DDR3-1600 - DDR3-1866 */
- control_code = 0x0;
- }
- } else if (MaxDimmsInstallable == 2) {
- if (dimm_count == 1) {
- /* 1 DIMM detected */
- if ((MemClkFreq == 0x4) || (MemClkFreq == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- control_code = 0x1;
- } else if ((MemClkFreq >= 0xa) && (MemClkFreq <= 0x12)) {
- /* DDR3-1066 - DDR3-1600 */
- if (num_registers == 1) {
- control_code = 0x0;
- } else {
- control_code = 0x1;
- }
- }
- } else if (dimm_count == 2) {
- /* 2 DIMMs detected */
- if (num_registers == 1) {
- control_code = 0x1;
- } else {
- control_code = 0x8;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else {
- /* TODO
- * Other socket support unimplemented
- */
- }
-
- printk(BIOS_SPEW, "%s: DCT %d IBT code: %01x\n", __func__, dct, control_code);
- return control_code;
-}
-
-static uint16_t memclk_to_freq(uint16_t memclk) {
- uint16_t fam10h_freq_tab[] = {0, 0, 0, 400, 533, 667, 800};
- uint16_t fam15h_freq_tab[] = {0, 0, 0, 0, 333, 0, 400, 0, 0, 0, 533, 0, 0, 0, 667, 0, 0, 0, 800, 0, 0, 0, 933};
-
- uint16_t mem_freq = 0;
-
- if (is_fam15h()) {
- if (memclk < 0x17) {
- mem_freq = fam15h_freq_tab[memclk];
- }
- } else {
- if ((memclk > 0x0) && (memclk < 0x8)) {
- mem_freq = fam10h_freq_tab[memclk - 1];
- }
- }
-
- return mem_freq;
-}
-
-static uint8_t rc_word_chip_select_lower_bit(void) {
- if (is_fam15h()) {
- return 21;
- } else {
- return 20;
- }
-}
-
-static uint32_t rc_word_address_to_ctl_bits(uint32_t address) {
- if (is_fam15h()) {
- return (((address >> 3) & 0x1) << 2) << 18 | (address & 0x7);
- } else {
- return (((address >> 3) & 0x1) << 2) << 16 | (address & 0x7);
- }
-}
-
-static uint32_t rc_word_value_to_ctl_bits(uint32_t value) {
- if (is_fam15h()) {
- return ((value >> 2) & 0x3) << 18 | ((value & 0x3) << 3);
- } else {
- return ((value >> 2) & 0x3) << 16 | ((value & 0x3) << 3);
- }
-}
-
-static u32 mct_ControlRC(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, u32 MrsChipSel, u32 CtrlWordNum)
-{
- u8 Dimms, DimmNum;
- u32 val;
- uint8_t ddr_voltage_index;
- uint16_t mem_freq;
- uint8_t package_type = mctGet_NVbits(NV_PACK_TYPE);
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- DimmNum = (MrsChipSel >> rc_word_chip_select_lower_bit()) & 0x7;
-
- if (dct == 1)
- DimmNum++;
-
- mem_freq = memclk_to_freq(pDCTstat->DIMMAutoSpeed);
- Dimms = pDCTstat->MAdimms[dct];
-
- ddr_voltage_index = dct_ddr_voltage_index(pDCTstat, dct);
-
- val = 0;
- if (CtrlWordNum == 0)
- val = 0x2;
- else if (CtrlWordNum == 1) {
- if (!((pDCTstat->DimmDRPresent | pDCTstat->DimmQRPresent) & (1 << DimmNum)))
- val = 0xc; /* if single rank, set DBA1 and DBA0 */
- } else if (CtrlWordNum == 2) {
- if (is_fam15h()) {
- val = (fam15h_rdimm_rc2_ibt_code(pDCTstat, dct) & 0x1) << 2;
- } else {
- if (package_type == PT_GR) {
- /* Socket G34 */
- if (MaxDimmsInstallable == 2) {
- if (Dimms > 1)
- val = 0x4;
- }
- }
- else if (package_type == PT_C3) {
- /* Socket C32 */
- if (MaxDimmsInstallable == 2) {
- if (Dimms > 1)
- val = 0x4;
- }
- }
- }
- } else if (CtrlWordNum == 3) {
- val = (pDCTstat->CtrlWrd3 >> (DimmNum << 2)) & 0xff;
- } else if (CtrlWordNum == 4) {
- val = (pDCTstat->CtrlWrd4 >> (DimmNum << 2)) & 0xff;
- } else if (CtrlWordNum == 5) {
- val = (pDCTstat->CtrlWrd5 >> (DimmNum << 2)) & 0xff;
- } else if (CtrlWordNum == 6) {
- val = ((pDCTstat->spd_data.spd_bytes[DimmNum][72] & 0xf) >> (DimmNum << 2)) & 0xff;
- } else if (CtrlWordNum == 7) {
- val = (((pDCTstat->spd_data.spd_bytes[DimmNum][72] >> 4) & 0xf) >> (DimmNum << 2)) & 0xff;
- } else if (CtrlWordNum == 8) {
- if (is_fam15h()) {
- val = (fam15h_rdimm_rc2_ibt_code(pDCTstat, dct) & 0xe) >> 1;
- } else {
- if (package_type == PT_GR) {
- /* Socket G34 */
- if (MaxDimmsInstallable == 2) {
- val = 0x0;
- }
- }
- else if (package_type == PT_C3) {
- /* Socket C32 */
- if (MaxDimmsInstallable == 2) {
- val = 0x0;
- }
- }
- }
- } else if (CtrlWordNum == 9) {
- val = 0xd; /* DBA1, DBA0, DA3 = 0 */
- } else if (CtrlWordNum == 10) {
- val = 0x0; /* Lowest operating frequency */
- } else if (CtrlWordNum == 11) {
- if (ddr_voltage_index & 0x4)
- val = 0x2; /* 1.25V */
- else if (ddr_voltage_index & 0x2)
- val = 0x1; /* 1.35V */
- else
- val = 0x0; /* 1.5V */
- } else if (CtrlWordNum == 12) {
- val = ((pDCTstat->spd_data.spd_bytes[DimmNum][75] & 0xf) >> (DimmNum << 2)) & 0xff;
- } else if (CtrlWordNum == 13) {
- val = (((pDCTstat->spd_data.spd_bytes[DimmNum][75] >> 4) & 0xf) >> (DimmNum << 2)) & 0xff;
- } else if (CtrlWordNum == 14) {
- val = ((pDCTstat->spd_data.spd_bytes[DimmNum][76] & 0xf) >> (DimmNum << 2)) & 0xff;
- } else if (CtrlWordNum == 15) {
- val = (((pDCTstat->spd_data.spd_bytes[DimmNum][76] >> 4) & 0xf) >> (DimmNum << 2)) & 0xff;
- }
- val &= 0xf;
-
- printk(BIOS_SPEW, "%s: Preparing to send DCT %d DIMM %d RC%d: %02x\n", __func__, dct, DimmNum >> 1, CtrlWordNum, val);
-
- val = MrsChipSel | rc_word_value_to_ctl_bits(val);
- val |= rc_word_address_to_ctl_bits(CtrlWordNum);
-
- return val;
-}
-
-static void mct_SendCtrlWrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint32_t val)
-{
- u32 dev = pDCTstat->dev_dct;
-
- val |= Get_NB32_DCT(dev, dct, 0x7c) & ~0xffffff;
- val |= 1 << SendControlWord;
- Set_NB32_DCT(dev, dct, 0x7c, val);
-
- do {
- val = Get_NB32_DCT(dev, dct, 0x7c);
- } while (val & (1 << SendControlWord));
-}
-
-void mct_DramControlReg_Init_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- u8 MrsChipSel;
- u32 dev = pDCTstat->dev_dct;
- u32 val, cw;
-
- printk(BIOS_SPEW, "%s: Start\n", __func__);
-
- if (!is_fam15h()) {
- mct_Wait(1600);
- mct_Wait(1200);
- }
-
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[dct];
- if (pDCTstat->GangedMode & 1)
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[0];
-
- for (MrsChipSel = 0; MrsChipSel < 8; MrsChipSel += 2) {
- if (pDCTstat->CSPresent & (1 << MrsChipSel)) {
- val = Get_NB32_DCT(dev, dct, 0xa8);
- val &= ~(0xff << 8);
-
- switch (MrsChipSel) {
- case 0:
- case 1:
- val |= 3 << 8;
- break;
- case 2:
- case 3:
- val |= (3 << 2) << 8;
- break;
- case 4:
- case 5:
- val |= (3 << 4) << 8;
- break;
- case 6:
- case 7:
- val |= (3 << 6) << 8;
- break;
- }
- Set_NB32_DCT(dev, dct, 0xa8, val);
- printk(BIOS_SPEW, "%s: F2xA8: %08x\n", __func__, val);
-
- if (is_fam15h()) {
- for (cw = 0; cw <=15; cw ++) {
- val = mct_ControlRC(pMCTstat, pDCTstat, dct, MrsChipSel << rc_word_chip_select_lower_bit(), cw);
- mct_SendCtrlWrd(pMCTstat, pDCTstat, dct, val);
- if ((cw == 2) || (cw == 8) || (cw == 10))
- precise_ndelay_fam15(pMCTstat, 6000);
- }
- } else {
- for (cw = 0; cw <=15; cw ++) {
- mct_Wait(1600);
- val = mct_ControlRC(pMCTstat, pDCTstat, dct, MrsChipSel << rc_word_chip_select_lower_bit(), cw);
- mct_SendCtrlWrd(pMCTstat, pDCTstat, dct, val);
- }
- }
- }
- }
-
- mct_Wait(1200);
-
- printk(BIOS_SPEW, "%s: Done\n", __func__);
-}
-
-void FreqChgCtrlWrd(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- u32 SaveSpeed = pDCTstat->DIMMAutoSpeed;
- u32 MrsChipSel;
- u32 dev = pDCTstat->dev_dct;
- u32 val;
- uint16_t mem_freq;
-
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[dct];
- if (pDCTstat->GangedMode & 1)
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[0];
-
- pDCTstat->DIMMAutoSpeed = pDCTstat->TargetFreq;
- mem_freq = memclk_to_freq(pDCTstat->TargetFreq);
- for (MrsChipSel = 0; MrsChipSel < 8; MrsChipSel += 2) {
- if (pDCTstat->CSPresent & (1 << MrsChipSel)) {
- /* 2. Program F2x[1, 0]A8[CtrlWordCS]=bit mask for target chip selects. */
- val = Get_NB32_DCT(dev, dct, 0xa8);
- val &= ~(0xff << 8);
-
- switch (MrsChipSel) {
- case 0:
- case 1:
- val |= 3 << 8;
- break;
- case 2:
- case 3:
- val |= (3 << 2) << 8;
- break;
- case 4:
- case 5:
- val |= (3 << 4) << 8;
- break;
- case 6:
- case 7:
- val |= (3 << 6) << 8;
- break;
- }
- Set_NB32_DCT(dev, dct, 0xa8, val);
-
- /* Resend control word 10 */
- uint8_t freq_ctl_val = 0;
- mct_Wait(1600);
- switch (mem_freq) {
- case 333:
- case 400:
- freq_ctl_val = 0x0;
- break;
- case 533:
- freq_ctl_val = 0x1;
- break;
- case 667:
- freq_ctl_val = 0x2;
- break;
- case 800:
- freq_ctl_val = 0x3;
- break;
- case 933:
- freq_ctl_val = 0x4;
- break;
- }
-
- printk(BIOS_SPEW, "Preparing to send DCT %d DIMM %d RC%d: %02x (F2xA8: %08x)\n", dct, MrsChipSel >> 1, 10, freq_ctl_val, val);
-
- mct_SendCtrlWrd(pMCTstat, pDCTstat, dct, (MrsChipSel << rc_word_chip_select_lower_bit()) | rc_word_address_to_ctl_bits(10) | rc_word_value_to_ctl_bits(freq_ctl_val));
-
- if (is_fam15h())
- precise_ndelay_fam15(pMCTstat, 6000);
- else
- mct_Wait(1600);
-
- /* Resend control word 2 */
- val = mct_ControlRC(pMCTstat, pDCTstat, dct, MrsChipSel << rc_word_chip_select_lower_bit(), 2);
- mct_SendCtrlWrd(pMCTstat, pDCTstat, dct, val);
-
- if (is_fam15h())
- precise_ndelay_fam15(pMCTstat, 6000);
- else
- mct_Wait(1600);
-
- /* Resend control word 8 */
- val = mct_ControlRC(pMCTstat, pDCTstat, dct, MrsChipSel << rc_word_chip_select_lower_bit(), 8);
- mct_SendCtrlWrd(pMCTstat, pDCTstat, dct, val);
-
- if (is_fam15h())
- precise_ndelay_fam15(pMCTstat, 6000);
- else
- mct_Wait(1600);
- }
- }
- pDCTstat->DIMMAutoSpeed = SaveSpeed;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctsdi.c b/src/northbridge/amd/amdmct/mct_ddr3/mctsdi.c
deleted file mode 100644
index f215695580..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctsdi.c
+++ /dev/null
@@ -1,1210 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/cpu.h>
-#include <stdint.h>
-#include <console/console.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-uint8_t fam15_dimm_dic(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t rank, uint8_t package_type)
-{
- uint8_t dic;
-
- /* Calculate DIC based on recommendations in MR1_dct[1:0] */
- if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* TODO
- * LRDIMM unimplemented
- */
- dic = 0x0;
- } else {
- dic = 0x1;
- }
-
- return dic;
-}
-
-uint8_t fam15_rttwr(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t rank, uint8_t package_type)
-{
- uint8_t term = 0;
- uint8_t number_of_dimms = pDCTstat->MAdimms[dct];
- uint8_t frequency_index;
- uint8_t rank_count = pDCTstat->DimmRanks[(dimm * 2) + dct];
-
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
- uint8_t rank_count_dimm2;
-
- if (is_fam15h())
- frequency_index = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
- else
- frequency_index = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x7;
-
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- if (is_fam15h()) {
- if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* TODO
- * LRDIMM unimplemented
- */
- } else if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- if (package_type == PT_GR) {
- /* Socket G34: Fam15h BKDG v3.14 Table 57 */
- if (MaxDimmsInstallable == 1) {
- if ((frequency_index == 0x4) || (frequency_index == 0x6)
- || (frequency_index == 0xa) || (frequency_index == 0xe)) {
- /* DDR3-667 - DDR3-1333 */
- if (rank_count < 3)
- term = 0x0;
- else
- term = 0x2;
- } else {
- /* DDR3-1600 */
- term = 0x0;
- }
- } else if (MaxDimmsInstallable == 2) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((frequency_index == 0x4) || (frequency_index == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if ((number_of_dimms == 1) && ((rank_count_dimm0 < 4)
- && (rank_count_dimm1 < 4)))
- term = 0x0;
- else
- term = 0x2;
- } else if (frequency_index == 0xa) {
- /* DDR3-1066 */
- if (number_of_dimms == 1) {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- term = 0x0;
- else
- term = 0x2;
- } else {
- term = 0x1;
- }
- } else if (frequency_index == 0xe) {
- /* DDR3-1333 */
- term = 0x2;
- } else {
- /* DDR3-1600 */
- if (number_of_dimms == 1)
- term = 0x0;
- else
- term = 0x1;
- }
- } else if (MaxDimmsInstallable == 3) {
- rank_count_dimm2 = pDCTstat->DimmRanks[(2 * 2) + dct];
-
- if ((frequency_index == 0xa) || (frequency_index == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (rank_count_dimm2 < 4)
- term = 0x1;
- else
- term = 0x2;
- } else if (frequency_index == 0x12) {
- /* DDR3-1600 */
- term = 0x1;
- } else {
- term = 0x2;
- }
- }
- } else if (package_type == PT_C3) {
- /* Socket C32: Fam15h BKDG v3.14 Table 60 */
- if (MaxDimmsInstallable == 1) {
- if ((frequency_index == 0x4) || (frequency_index == 0x6)
- || (frequency_index == 0xa) || (frequency_index == 0xe)) {
- /* DDR3-667 - DDR3-1333 */
- if (rank_count < 3)
- term = 0x0;
- else
- term = 0x2;
- } else {
- /* DDR3-1600 */
- term = 0x0;
- }
- } else if (MaxDimmsInstallable == 2) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((frequency_index == 0x4) || (frequency_index == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if ((number_of_dimms == 1) && ((rank_count_dimm0 < 4)
- && (rank_count_dimm1 < 4)))
- term = 0x0;
- else
- term = 0x2;
- } else if (frequency_index == 0xa) {
- /* DDR3-1066 */
- if (number_of_dimms == 1) {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- term = 0x0;
- else
- term = 0x2;
- } else {
- term = 0x1;
- }
- } else if (frequency_index == 0xe) {
- /* DDR3-1333 */
- term = 0x2;
- } else {
- /* DDR3-1600 */
- if (number_of_dimms == 1)
- term = 0x0;
- else
- term = 0x1;
- }
- } else if (MaxDimmsInstallable == 3) {
- rank_count_dimm2 = pDCTstat->DimmRanks[(2 * 2) + dct];
-
- if ((frequency_index == 0xa) || (frequency_index == 0xe)) {
- /* DDR3-1066 - DDR3-1333 */
- if (rank_count_dimm2 < 4)
- term = 0x1;
- else
- term = 0x2;
- } else if (frequency_index == 0x12) {
- /* DDR3-1600 */
- term = 0x1;
- } else {
- term = 0x2;
- }
- }
- } else {
- /* TODO
- * Other sockets unimplemented
- */
- }
- } else {
- /* UDIMM */
- if (package_type == PT_GR) {
- /* Socket G34: Fam15h BKDG v3.14 Table 56 */
- if (MaxDimmsInstallable == 1) {
- term = 0x0;
- } else if (MaxDimmsInstallable == 2) {
- if ((number_of_dimms == 2) && (frequency_index == 0x12)) {
- term = 0x1;
- } else if (number_of_dimms == 1) {
- term = 0x0;
- } else {
- term = 0x2;
- }
- } else if (MaxDimmsInstallable == 3) {
- if (number_of_dimms == 1) {
- if (frequency_index <= 0xa) {
- term = 0x2;
- } else {
- if (rank_count < 3) {
- term = 0x1;
- } else {
- term = 0x2;
- }
- }
- } else if (number_of_dimms == 2) {
- term = 0x2;
- }
- }
- } else if (package_type == PT_C3) {
- /* Socket C32: Fam15h BKDG v3.14 Table 59 */
- if (MaxDimmsInstallable == 1) {
- term = 0x0;
- } else if (MaxDimmsInstallable == 2) {
- if ((number_of_dimms == 2) && (frequency_index == 0x12)) {
- term = 0x1;
- } else if (number_of_dimms == 1) {
- term = 0x0;
- } else {
- term = 0x2;
- }
- } else if (MaxDimmsInstallable == 3) {
- if (number_of_dimms == 1) {
- if (frequency_index <= 0xa) {
- term = 0x2;
- } else {
- if (rank_count < 3) {
- term = 0x1;
- } else {
- term = 0x2;
- }
- }
- } else if (number_of_dimms == 2) {
- term = 0x2;
- }
- }
- } else if (package_type == PT_FM2) {
- /* Socket FM2: Fam15h Model10 BKDG 3.12 Table 32 */
- if (MaxDimmsInstallable == 1) {
- term = 0x0;
- } else if (MaxDimmsInstallable == 2) {
- if ((number_of_dimms == 2) && (frequency_index >= 0x12)) {
- term = 0x1;
- } else if (number_of_dimms == 1) {
- term = 0x0;
- } else {
- term = 0x2;
- }
- }
- } else {
- /* TODO
- * Other sockets unimplemented
- */
- }
- }
- }
-
- printk(BIOS_INFO, "DIMM %d RttWr: %01x\n", dimm, term);
-
- return term;
-}
-
-uint8_t fam15_rttnom(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t rank, uint8_t package_type)
-{
- uint8_t term = 0;
- uint8_t number_of_dimms = pDCTstat->MAdimms[dct];
- uint8_t frequency_index;
-
- uint8_t rank_count_dimm0;
- uint8_t rank_count_dimm1;
-
- if (is_fam15h())
- frequency_index = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x1f;
- else
- frequency_index = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0x94) & 0x7;
-
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- if (is_fam15h()) {
- if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- /* TODO
- * LRDIMM unimplemented
- */
- } else if (pDCTstat->Status & (1 << SB_Registered)) {
- /* RDIMM */
- if (package_type == PT_GR) {
- /* Socket G34: Fam15h BKDG v3.14 Table 57 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
-
- if ((frequency_index == 0x4) || (frequency_index == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (rank_count_dimm0 < 4) {
- term = 0x2;
- } else {
- if (!rank)
- term = 0x2;
- else
- term = 0x0;
- }
- } else if (frequency_index == 0xa) {
- /* DDR3-1066 */
- term = 0x1;
- } else if (frequency_index == 0xe) {
- /* DDR3-1333 */
- if (rank_count_dimm0 < 4) {
- term = 0x1;
- } else {
- if (!rank)
- term = 0x3;
- else
- term = 0x0;
- }
- } else {
- term = 0x3;
- }
- } else if (MaxDimmsInstallable == 2) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((frequency_index == 0x4) || (frequency_index == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (number_of_dimms == 1) {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- term = 0x2;
- else if (rank)
- term = 0x0;
- else
- term = 0x2;
- } else {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4)) {
- term = 0x3;
- } else {
- if (rank_count_dimm0 == 4) {
- if (rank_count_dimm1 == 1)
- term = 0x5;
- else
- term = 0x1;
- } else if (rank_count_dimm1 == 4) {
- if (rank_count_dimm0 == 1)
- term = 0x5;
- else
- term = 0x1;
- }
- if (rank)
- term = 0x0;
- }
- }
- } else if (frequency_index == 0xa) {
- /* DDR3-1066 */
- if (number_of_dimms == 1) {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- term = 0x1;
- else if (rank)
- term = 0x0;
- else
- term = 0x1;
- } else {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4)) {
- term = 0x3;
- } else {
- if (rank_count_dimm0 == 4) {
- if (rank_count_dimm1 == 1)
- term = 0x5;
- else
- term = 0x1;
- } else if (rank_count_dimm1 == 4) {
- if (rank_count_dimm0 == 1)
- term = 0x5;
- else
- term = 0x1;
- }
- if (rank)
- term = 0x0;
- }
- }
- } else if (frequency_index == 0xe) {
- /* DDR3-1333 */
- if (number_of_dimms == 1) {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- term = 0x1;
- else if (rank)
- term = 0x0;
- else
- term = 0x3;
- } else {
- term = 0x5;
- }
- } else {
- /* DDR3-1600 */
- if (number_of_dimms == 1)
- term = 0x3;
- else
- term = 0x4;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else if (package_type == PT_C3) {
- /* Socket C32: Fam15h BKDG v3.14 Table 60 */
- if (MaxDimmsInstallable == 1) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
-
- if ((frequency_index == 0x4) || (frequency_index == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (rank_count_dimm0 < 4) {
- term = 0x2;
- } else {
- if (!rank)
- term = 0x2;
- else
- term = 0x0;
- }
- } else if (frequency_index == 0xa) {
- /* DDR3-1066 */
- term = 0x1;
- } else if (frequency_index == 0xe) {
- /* DDR3-1333 */
- if (rank_count_dimm0 < 4) {
- term = 0x1;
- } else {
- if (!rank)
- term = 0x3;
- else
- term = 0x0;
- }
- } else {
- term = 0x3;
- }
- } else if (MaxDimmsInstallable == 2) {
- rank_count_dimm0 = pDCTstat->DimmRanks[(0 * 2) + dct];
- rank_count_dimm1 = pDCTstat->DimmRanks[(1 * 2) + dct];
-
- if ((frequency_index == 0x4) || (frequency_index == 0x6)) {
- /* DDR3-667 - DDR3-800 */
- if (number_of_dimms == 1) {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- term = 0x2;
- else if (rank)
- term = 0x0;
- else
- term = 0x2;
- } else {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4)) {
- term = 0x3;
- } else {
- if (rank_count_dimm0 == 4) {
- if (rank_count_dimm1 == 1)
- term = 0x5;
- else
- term = 0x1;
- } else if (rank_count_dimm1 == 4) {
- if (rank_count_dimm0 == 1)
- term = 0x5;
- else
- term = 0x1;
- }
- if (rank)
- term = 0x0;
- }
- }
- } else if (frequency_index == 0xa) {
- /* DDR3-1066 */
- if (number_of_dimms == 1) {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- term = 0x1;
- else if (rank)
- term = 0x0;
- else
- term = 0x1;
- } else {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4)) {
- term = 0x3;
- } else {
- if (rank_count_dimm0 == 4) {
- if (rank_count_dimm1 == 1)
- term = 0x5;
- else
- term = 0x1;
- } else if (rank_count_dimm1 == 4) {
- if (rank_count_dimm0 == 1)
- term = 0x5;
- else
- term = 0x1;
- }
- if (rank)
- term = 0x0;
- }
- }
- } else if (frequency_index == 0xe) {
- /* DDR3-1333 */
- if (number_of_dimms == 1) {
- if ((rank_count_dimm0 < 4) && (rank_count_dimm1 < 4))
- term = 0x1;
- else if (rank)
- term = 0x0;
- else
- term = 0x3;
- } else {
- term = 0x5;
- }
- } else {
- /* DDR3-1600 */
- if (number_of_dimms == 1)
- term = 0x3;
- else
- term = 0x4;
- }
- } else if (MaxDimmsInstallable == 3) {
- /* TODO
- * 3 DIMM/channel support unimplemented
- */
- }
- } else {
- /* TODO
- * Other sockets unimplemented
- */
- }
- } else {
- /* UDIMM */
- if (package_type == PT_GR) {
- /* Socket G34: Fam15h BKDG v3.14 Table 56 */
- if (MaxDimmsInstallable == 1) {
- if ((frequency_index == 0x4) || (frequency_index == 0x6))
- term = 0x2;
- else if ((frequency_index == 0xa) || (frequency_index == 0xe))
- term = 0x1;
- else
- term = 0x3;
- }
- if (MaxDimmsInstallable == 2) {
- if (number_of_dimms == 1) {
- if (frequency_index <= 0x6) {
- term = 0x2;
- } else if (frequency_index <= 0xe) {
- term = 0x1;
- } else {
- term = 0x3;
- }
- } else {
- if (frequency_index <= 0xa) {
- term = 0x3;
- } else if (frequency_index <= 0xe) {
- term = 0x5;
- } else {
- term = 0x4;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- if (number_of_dimms == 1) {
- term = 0x0;
- } else if (number_of_dimms == 2) {
- if (frequency_index <= 0xa) {
- if (rank == 1) {
- term = 0x0;
- } else {
- term = 0x3;
- }
- } else if (frequency_index <= 0xe) {
- if (rank == 1) {
- term = 0x0;
- } else {
- term = 0x5;
- }
- }
- }
- }
- } else if (package_type == PT_C3) {
- /* Socket C32: Fam15h BKDG v3.14 Table 62 */
- if (MaxDimmsInstallable == 1) {
- if ((frequency_index == 0x4) || (frequency_index == 0x6))
- term = 0x2;
- else if ((frequency_index == 0xa) || (frequency_index == 0xe))
- term = 0x1;
- else
- term = 0x3;
- }
- if (MaxDimmsInstallable == 2) {
- if (number_of_dimms == 1) {
- if (frequency_index <= 0x6) {
- term = 0x2;
- } else if (frequency_index <= 0xe) {
- term = 0x1;
- } else {
- term = 0x3;
- }
- } else {
- if (frequency_index <= 0xa) {
- term = 0x3;
- } else if (frequency_index <= 0xe) {
- term = 0x5;
- } else {
- term = 0x4;
- }
- }
- } else if (MaxDimmsInstallable == 3) {
- if (number_of_dimms == 1) {
- term = 0x0;
- } else if (number_of_dimms == 2) {
- if (frequency_index <= 0xa) {
- if (rank == 1) {
- term = 0x0;
- } else {
- term = 0x3;
- }
- } else if (frequency_index <= 0xe) {
- if (rank == 1) {
- term = 0x0;
- } else {
- term = 0x5;
- }
- }
- }
- }
- } else if (package_type == PT_FM2) {
- /* Socket FM2: Fam15h Model10 BKDG 3.12 Table 32 */
- if (MaxDimmsInstallable == 1) {
- if ((frequency_index == 0x4)
- || (frequency_index == 0x6)
- || (frequency_index == 0xa))
- term = 0x4;
- else if (frequency_index == 0xe)
- term = 0x3;
- else if (frequency_index >= 0x12)
- term = 0x2;
- }
- if (MaxDimmsInstallable == 2) {
- if (number_of_dimms == 1) {
- if (frequency_index <= 0xa) {
- term = 0x4;
- } else if (frequency_index <= 0xe) {
- term = 0x3;
- } else {
- term = 0x2;
- }
- } else {
- if (frequency_index <= 0xa) {
- term = 0x2;
- } else if (frequency_index <= 0xe) {
- term = 0x1;
- } else {
- term = 0x0;
- }
- }
- }
- } else {
- /* TODO
- * Other sockets unimplemented
- */
- }
- }
- }
-
- printk(BIOS_INFO, "DIMM %d RttNom: %01x\n", dimm, term);
- return term;
-}
-
-static void mct_DCTAccessDone(struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 val;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- do {
- val = Get_NB32_DCT(dev, dct, 0x98);
- } while (!(val & (1 << DctAccessDone)));
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-static u32 swapAddrBits(struct DCTStatStruc *pDCTstat, u32 MR_register_setting, u8 MrsChipSel, u8 dct)
-{
- u16 word;
- u32 ret;
-
- if (!(pDCTstat->Status & (1 << SB_Registered))) {
- word = pDCTstat->MirrPresU_NumRegR;
- if (dct == 0) {
- word &= 0x55;
- word <<= 1;
- } else
- word &= 0xAA;
-
- if (word & (1 << MrsChipSel)) {
- /* A3<->A4,A5<->A6,A7<->A8,BA0<->BA1 */
- ret = 0;
- if (MR_register_setting & (1 << 3)) ret |= 1 << 4;
- if (MR_register_setting & (1 << 4)) ret |= 1 << 3;
- if (MR_register_setting & (1 << 5)) ret |= 1 << 6;
- if (MR_register_setting & (1 << 6)) ret |= 1 << 5;
- if (MR_register_setting & (1 << 7)) ret |= 1 << 8;
- if (MR_register_setting & (1 << 8)) ret |= 1 << 7;
- if (is_fam15h()) {
- if (MR_register_setting & (1 << 18)) ret |= 1 << 19;
- if (MR_register_setting & (1 << 19)) ret |= 1 << 18;
- MR_register_setting &= ~0x000c01f8;
- } else {
- if (MR_register_setting & (1 << 16)) ret |= 1 << 17;
- if (MR_register_setting & (1 << 17)) ret |= 1 << 16;
- MR_register_setting &= ~0x000301f8;
- }
- MR_register_setting |= ret;
- }
- }
- return MR_register_setting;
-}
-
-static void mct_SendMrsCmd(struct DCTStatStruc *pDCTstat, u8 dct, u32 EMRS)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 val;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- val = Get_NB32_DCT(dev, dct, 0x7c);
- val &= ~0x00ffffff;
- val |= EMRS;
- val |= 1 << SendMrsCmd;
- Set_NB32_DCT(dev, dct, 0x7c, val);
-
- do {
- val = Get_NB32_DCT(dev, dct, 0x7c);
- } while (val & (1 << SendMrsCmd));
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-u32 mct_MR2(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u32 MrsChipSel)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 dword, ret;
-
- /* The formula for chip select number is: CS = dimm*2+rank */
- uint8_t dimm = MrsChipSel / 2;
- uint8_t rank = MrsChipSel % 2;
-
- if (is_fam15h()) {
- uint8_t package_type = mctGet_NVbits(NV_PACK_TYPE);
-
- /* FIXME: These parameters should be configurable
- * For now, err on the side of caution and enable automatic 2x refresh
- * when the DDR temperature rises above the internal limits
- */
- uint8_t force_2x_self_refresh = 0; /* ASR */
- uint8_t auto_2x_self_refresh = 1; /* SRT */
-
- ret = 0x80000;
- ret |= (MrsChipSel << 21);
-
- /* Set self refresh parameters */
- ret |= (force_2x_self_refresh << 6);
- ret |= (auto_2x_self_refresh << 7);
-
- /* Obtain Tcwl, adjust, and set CWL with the adjusted value */
- dword = Get_NB32_DCT(dev, dct, 0x20c) & 0x1f;
- dword -= pDCTstat->tcwl_delay[dct];
- ret |= ((dword - 5) << 3);
-
- /* Obtain and set RttWr */
- ret |= (fam15_rttwr(pDCTstat, dct, dimm, rank, package_type) << 9);
- } else {
- ret = 0x20000;
- ret |= (MrsChipSel << 20);
-
- /* program MrsAddress[5:3]=CAS write latency (CWL):
- * based on F2x[1,0]84[Tcwl] */
- dword = Get_NB32_DCT(dev, dct, 0x84);
- dword = mct_AdjustSPDTimings(pMCTstat, pDCTstat, dword);
-
- ret |= ((dword >> 20) & 7) << 3;
-
- /* program MrsAddress[6]=auto self refresh method (ASR):
- * based on F2x[1,0]84[ASR]
- * program MrsAddress[7]=self refresh temperature range (SRT):
- * based on F2x[1,0]84[ASR and SRT]
- */
- ret |= ((dword >> 18) & 3) << 6;
-
- /* program MrsAddress[10:9]=dynamic termination during writes (RTT_WR)
- * based on F2x[1,0]84[DramTermDyn]
- */
- ret |= ((dword >> 10) & 3) << 9;
- }
-
- printk(BIOS_SPEW, "Going to send DCT %d DIMM %d rank %d MR2 control word %08x\n", dct, dimm, rank, ret);
-
- return ret;
-}
-
-static u32 mct_MR3(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u32 MrsChipSel)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 dword, ret;
-
- /* The formula for chip select number is: CS = dimm*2+rank */
- uint8_t dimm = MrsChipSel / 2;
- uint8_t rank = MrsChipSel % 2;
-
- if (is_fam15h()) {
- ret = 0xc0000;
- ret |= (MrsChipSel << 21);
-
- /* Program MPR and MPRLoc to 0 */
- // ret |= 0x0; /* MPR */
- // ret |= (0x0 << 2); /* MPRLoc */
- } else {
- ret = 0x30000;
- ret |= (MrsChipSel << 20);
-
- /* program MrsAddress[1:0]=multi purpose register address location
- * (MPR Location):based on F2x[1,0]84[MprLoc]
- * program MrsAddress[2]=multi purpose register
- * (MPR):based on F2x[1,0]84[MprEn]
- */
- dword = Get_NB32_DCT(dev, dct, 0x84);
- ret |= (dword >> 24) & 7;
- }
-
- printk(BIOS_SPEW, "Going to send DCT %d DIMM %d rank %d MR3 control word %08x\n", dct, dimm, rank, ret);
-
- return ret;
-}
-
-u32 mct_MR1(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u32 MrsChipSel)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 dword, ret;
-
- /* The formula for chip select number is: CS = dimm*2+rank */
- uint8_t dimm = MrsChipSel / 2;
- uint8_t rank = MrsChipSel % 2;
-
- if (is_fam15h()) {
- uint8_t package_type = mctGet_NVbits(NV_PACK_TYPE);
-
- /* Set defaults */
- uint8_t qoff = 0; /* Enable output buffers */
- uint8_t wrlvl = 0; /* Disable write levelling */
- uint8_t tqds = 0;
- uint8_t rttnom = 0;
- uint8_t dic = 0;
- uint8_t additive_latency = 0;
- uint8_t dll_enable = 0;
-
- ret = 0x40000;
- ret |= (MrsChipSel << 21);
-
- /* Determine if TQDS should be set */
- if ((pDCTstat->Dimmx8Present & (1 << dimm))
- && (((dimm & 0x1)?(pDCTstat->Dimmx4Present&0x55):(pDCTstat->Dimmx4Present&0xaa)) != 0x0)
- && (pDCTstat->Status & (1 << SB_LoadReduced)))
- tqds = 1;
-
- /* Obtain RttNom */
- rttnom = fam15_rttnom(pDCTstat, dct, dimm, rank, package_type);
-
- /* Obtain DIC */
- dic = fam15_dimm_dic(pDCTstat, dct, dimm, rank, package_type);
-
- /* Load data into MRS word */
- ret |= (qoff & 0x1) << 12;
- ret |= (tqds & 0x1) << 11;
- ret |= ((rttnom & 0x4) >> 2) << 9;
- ret |= ((rttnom & 0x2) >> 1) << 6;
- ret |= ((rttnom & 0x1) >> 0) << 2;
- ret |= (wrlvl & 0x1) << 7;
- ret |= ((dic & 0x2) >> 1) << 5;
- ret |= ((dic & 0x1) >> 0) << 1;
- ret |= (additive_latency & 0x3) << 3;
- ret |= (dll_enable & 0x1);
- } else {
- ret = 0x10000;
- ret |= (MrsChipSel << 20);
-
- /* program MrsAddress[5,1]=output driver impedance control (DIC):
- * based on F2x[1,0]84[DrvImpCtrl]
- */
- dword = Get_NB32_DCT(dev, dct, 0x84);
- if (dword & (1 << 3))
- ret |= 1 << 5;
- if (dword & (1 << 2))
- ret |= 1 << 1;
-
- /* program MrsAddress[9,6,2]=nominal termination resistance of ODT (RTT):
- * based on F2x[1,0]84[DramTerm]
- */
- if (!(pDCTstat->Status & (1 << SB_Registered))) {
- if (dword & (1 << 9))
- ret |= 1 << 9;
- if (dword & (1 << 8))
- ret |= 1 << 6;
- if (dword & (1 << 7))
- ret |= 1 << 2;
- } else {
- ret |= mct_MR1Odt_RDimm(pMCTstat, pDCTstat, dct, MrsChipSel);
- }
-
- /* program MrsAddress[11]=TDQS: based on F2x[1,0]94[RDqsEn] */
- if (Get_NB32_DCT(dev, dct, 0x94) & (1 << RDqsEn)) {
- u8 bit;
- /* Set TDQS = 1b for x8 DIMM, TDQS = 0b for x4 DIMM, when mixed x8 & x4 */
- bit = (ret >> 21) << 1;
- if ((dct & 1) != 0)
- bit ++;
- if (pDCTstat->Dimmx8Present & (1 << bit))
- ret |= 1 << 11;
- }
-
- /* program MrsAddress[12]=QOFF: based on F2x[1,0]84[Qoff] */
- if (dword & (1 << 13))
- ret |= 1 << 12;
- }
-
- printk(BIOS_SPEW, "Going to send DCT %d DIMM %d rank %d MR1 control word %08x\n", dct, dimm, rank, ret);
-
- return ret;
-}
-
-static u32 mct_MR0(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u32 MrsChipSel)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 dword, ret, dword2;
-
- /* The formula for chip select number is: CS = dimm*2+rank */
- uint8_t dimm = MrsChipSel / 2;
- uint8_t rank = MrsChipSel % 2;
-
- if (is_fam15h()) {
- ret = 0x00000;
- ret |= (MrsChipSel << 21);
-
- /* Set defaults */
- uint8_t ppd = 0;
- uint8_t wr_ap = 0;
- uint8_t dll_reset = 1;
- uint8_t test_mode = 0;
- uint8_t cas_latency = 0;
- uint8_t read_burst_type = 1;
- uint8_t burst_length = 0;
-
- /* Obtain PchgPDModeSel */
- dword = Get_NB32_DCT(dev, dct, 0x84);
- ppd = (dword >> 23) & 0x1;
-
- /* Obtain Twr */
- dword = Get_NB32_DCT(dev, dct, 0x22c) & 0x1f;
-
- /* Calculate wr_ap (Fam15h BKDG v3.14 Table 82) */
- if (dword == 0x10)
- wr_ap = 0x0;
- else if (dword == 0x5)
- wr_ap = 0x1;
- else if (dword == 0x6)
- wr_ap = 0x2;
- else if (dword == 0x7)
- wr_ap = 0x3;
- else if (dword == 0x8)
- wr_ap = 0x4;
- else if (dword == 0xa)
- wr_ap = 0x5;
- else if (dword == 0xc)
- wr_ap = 0x6;
- else if (dword == 0xe)
- wr_ap = 0x7;
-
- /* Obtain Tcl */
- dword = Get_NB32_DCT(dev, dct, 0x200) & 0x1f;
-
- /* Calculate cas_latency (Fam15h BKDG v3.14 Table 83) */
- if (dword == 0x5)
- cas_latency = 0x2;
- else if (dword == 0x6)
- cas_latency = 0x4;
- else if (dword == 0x7)
- cas_latency = 0x6;
- else if (dword == 0x8)
- cas_latency = 0x8;
- else if (dword == 0x9)
- cas_latency = 0xa;
- else if (dword == 0xa)
- cas_latency = 0xc;
- else if (dword == 0xb)
- cas_latency = 0xe;
- else if (dword == 0xc)
- cas_latency = 0x1;
- else if (dword == 0xd)
- cas_latency = 0x3;
- else if (dword == 0xe)
- cas_latency = 0x5;
- else if (dword == 0xf)
- cas_latency = 0x7;
- else if (dword == 0x10)
- cas_latency = 0x9;
-
- /* Obtain BurstCtrl */
- burst_length = Get_NB32_DCT(dev, dct, 0x84) & 0x3;
-
- /* Load data into MRS word */
- ret |= (ppd & 0x1) << 12;
- ret |= (wr_ap & 0x7) << 9;
- ret |= (dll_reset & 0x1) << 8;
- ret |= (test_mode & 0x1) << 7;
- ret |= ((cas_latency & 0xe) >> 1) << 4;
- ret |= ((cas_latency & 0x1) >> 0) << 2;
- ret |= (read_burst_type & 0x1) << 3;
- ret |= (burst_length & 0x3);
- } else {
- ret = 0x00000;
- ret |= (MrsChipSel << 20);
-
- /* program MrsAddress[1:0]=burst length and control method
- (BL):based on F2x[1,0]84[BurstCtrl] */
- dword = Get_NB32_DCT(dev, dct, 0x84);
- ret |= dword & 3;
-
- /* program MrsAddress[3]=1 (BT):interleaved */
- ret |= 1 << 3;
-
- /* program MrsAddress[6:4,2]=read CAS latency
- (CL):based on F2x[1,0]88[Tcl] */
- dword2 = Get_NB32_DCT(dev, dct, 0x88);
- ret |= (dword2 & 0x7) << 4; /* F2x88[2:0] to MrsAddress[6:4] */
- ret |= ((dword2 & 0x8) >> 3) << 2; /* F2x88[3] to MrsAddress[2] */
-
- /* program MrsAddress[12]=0 (PPD):slow exit */
- if (dword & (1 << 23))
- ret |= 1 << 12;
-
- /* program MrsAddress[11:9]=write recovery for auto-precharge
- (WR):based on F2x[1,0]84[Twr] */
- ret |= ((dword >> 4) & 7) << 9;
-
- /* program MrsAddress[8]=1 (DLL):DLL reset
- just issue DLL reset at first time */
- ret |= 1 << 8;
- }
-
- printk(BIOS_SPEW, "Going to send DCT %d DIMM %d rank %d MR0 control word %08x\n", dct, dimm, rank, ret);
-
- return ret;
-}
-
-static void mct_SendZQCmd(struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u32 dev = pDCTstat->dev_dct;
- u32 dword;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- /*1.Program MrsAddress[10]=1
- 2.Set SendZQCmd = 1
- */
- dword = Get_NB32_DCT(dev, dct, 0x7C);
- dword &= ~0xFFFFFF;
- dword |= 1 << 10;
- dword |= 1 << SendZQCmd;
- Set_NB32_DCT(dev, dct, 0x7C, dword);
-
- /* Wait for SendZQCmd = 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x7C);
- } while (dword & (1 << SendZQCmd));
-
- /* 4.Wait 512 MEMCLKs */
- mct_Wait(300);
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-void mct_DramInit_Sw_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 MrsChipSel;
- u32 dword;
- u32 dev = pDCTstat->dev_dct;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- if (pDCTstat->DIMMAutoSpeed == mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK))) {
- /* 3.Program F2x[1,0]7C[EnDramInit]=1 */
- dword = Get_NB32_DCT(dev, dct, 0x7c);
- dword |= 1 << EnDramInit;
- Set_NB32_DCT(dev, dct, 0x7c, dword);
- mct_DCTAccessDone(pDCTstat, dct);
-
- /* 4.wait 200us */
- mct_Wait(40000);
-
- /* 5.Program F2x[1, 0]7C[DeassertMemRstX] = 1. */
- dword = Get_NB32_DCT(dev, dct, 0x7c);
- dword |= 1 << DeassertMemRstX;
- Set_NB32_DCT(dev, dct, 0x7c, dword);
-
- /* 6.wait 500us */
- mct_Wait(200000);
-
- /* 7.Program F2x[1,0]7C[AssertCke]=1 */
- dword = Get_NB32_DCT(dev, dct, 0x7c);
- dword |= 1 << AssertCke;
- Set_NB32_DCT(dev, dct, 0x7c, dword);
-
- /* 8.wait 360ns */
- mct_Wait(80);
-
- /* Set up address parity */
- if ((pDCTstat->Status & (1 << SB_Registered))
- || (pDCTstat->Status & (1 << SB_LoadReduced))) {
- if (is_fam15h()) {
- dword = Get_NB32_DCT(dev, dct, 0x90);
- dword |= 1 << ParEn;
- Set_NB32_DCT(dev, dct, 0x90, dword);
- }
- }
-
- /* The following steps are performed with registered DIMMs only and
- * must be done for each chip select pair */
- if (pDCTstat->Status & (1 << SB_Registered))
- mct_DramControlReg_Init_D(pMCTstat, pDCTstat, dct);
-
- /* The following steps are performed with load reduced DIMMs only and
- * must be done for each DIMM */
- // if (pDCTstat->Status & (1 << SB_LoadReduced))
- /* TODO
- * Implement LRDIMM configuration
- */
- }
-
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[dct];
- if (pDCTstat->GangedMode & 1)
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[0];
-
- /* The following steps are performed once for unbuffered DIMMs and once for each
- * chip select on registered DIMMs: */
- for (MrsChipSel = 0; MrsChipSel < 8; MrsChipSel++) {
- if (pDCTstat->CSPresent & (1 << MrsChipSel)) {
- u32 EMRS;
- /* 13.Send EMRS(2) */
- EMRS = mct_MR2(pMCTstat, pDCTstat, dct, MrsChipSel);
- EMRS = swapAddrBits(pDCTstat, EMRS, MrsChipSel, dct);
- mct_SendMrsCmd(pDCTstat, dct, EMRS);
- /* 14.Send EMRS(3). Ordinarily at this time, MrsAddress[2:0]=000b */
- EMRS= mct_MR3(pMCTstat, pDCTstat, dct, MrsChipSel);
- EMRS = swapAddrBits(pDCTstat, EMRS, MrsChipSel, dct);
- mct_SendMrsCmd(pDCTstat, dct, EMRS);
- /* 15.Send EMRS(1) */
- EMRS= mct_MR1(pMCTstat, pDCTstat, dct, MrsChipSel);
- EMRS = swapAddrBits(pDCTstat, EMRS, MrsChipSel, dct);
- mct_SendMrsCmd(pDCTstat, dct, EMRS);
- /* 16.Send MRS with MrsAddress[8]=1(reset the DLL) */
- EMRS= mct_MR0(pMCTstat, pDCTstat, dct, MrsChipSel);
- EMRS = swapAddrBits(pDCTstat, EMRS, MrsChipSel, dct);
- mct_SendMrsCmd(pDCTstat, dct, EMRS);
-
- if (pDCTstat->DIMMAutoSpeed == mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK)))
- if (!(pDCTstat->Status & (1 << SB_Registered)))
- break; /* For UDIMM, only send MR commands once per channel */
- }
- if (pDCTstat->LogicalCPUID & (AMD_DR_Bx/* | AMD_RB_C0 */)) /* TODO: We dont support RB_C0 now. need to be added and tested. */
- if (!(pDCTstat->Status & (1 << SB_Registered)))
- MrsChipSel ++;
- }
-
- if (pDCTstat->DIMMAutoSpeed == mhz_to_memclk_config(mctGet_NVbits(NV_MIN_MEMCLK))) {
- /* 17.Send two ZQCL commands */
- mct_SendZQCmd(pDCTstat, dct);
- mct_SendZQCmd(pDCTstat, dct);
-
- /* 18.Program F2x[1,0]7C[EnDramInit]=0 */
- dword = Get_NB32_DCT(dev, dct, 0x7C);
- dword &= ~(1 << EnDramInit);
- Set_NB32_DCT(dev, dct, 0x7C, dword);
- mct_DCTAccessDone(pDCTstat, dct);
- }
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctsrc.c b/src/northbridge/amd/amdmct/mct_ddr3/mctsrc.c
deleted file mode 100644
index dbb989fe3d..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctsrc.c
+++ /dev/null
@@ -1,2438 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 - 2016 Raptor Engineering, LLC
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; either version 2 of the License, or
- * (at your option) any later version.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/******************************************************************************
- Description: Receiver En and DQS Timing Training feature for DDR 3 MCT
-******************************************************************************/
-
-#include <arch/cpu.h>
-#include <stdint.h>
-#include <console/console.h>
-#include <cpu/x86/cr.h>
-#include <string.h>
-#include <cpu/x86/msr.h>
-#include <cpu/amd/msr.h>
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static void dqsTrainRcvrEn_SW_Fam10(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Pass);
-static void dqsTrainRcvrEn_SW_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Pass);
-static void mct_InitDQSPos4RcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void InitDQSPos4RcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel);
-static void CalcEccDQSRcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel);
-static void mct_SetMaxLatency_D(struct DCTStatStruc *pDCTstat, u8 Channel, u16 DQSRcvEnDly);
-static void mct_DisableDQSRcvEn_D(struct DCTStatStruc *pDCTstat);
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-/* Warning: These must be located so they do not cross a logical 16-bit
- segment boundary! */
-const u32 TestPattern0_D[] = {
- 0x55555555, 0x55555555, 0x55555555, 0x55555555,
- 0x55555555, 0x55555555, 0x55555555, 0x55555555,
- 0x55555555, 0x55555555, 0x55555555, 0x55555555,
- 0x55555555, 0x55555555, 0x55555555, 0x55555555,
-};
-const u32 TestPattern1_D[] = {
- 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa,
- 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa,
- 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa,
- 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa, 0xaaaaaaaa,
-};
-const u32 TestPattern2_D[] = {
- 0x12345678, 0x87654321, 0x23456789, 0x98765432,
- 0x59385824, 0x30496724, 0x24490795, 0x99938733,
- 0x40385642, 0x38465245, 0x29432163, 0x05067894,
- 0x12349045, 0x98723467, 0x12387634, 0x34587623,
-};
-
-static void SetupRcvrPattern(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u32 *buffer, u8 pass)
-{
- /*
- * 1. Copy the alpha and Beta patterns from ROM to Cache,
- * aligning on 16 byte boundary
- * 2. Set the ptr to DCTStatstruc.PtrPatternBufA for Alpha
- * 3. Set the ptr to DCTStatstruc.PtrPatternBufB for Beta
- */
- u32 *buf_a;
- u32 *buf_b;
- u32 *p_A;
- u32 *p_B;
- u8 i;
-
- buf_a = (u32 *)(((u32)buffer + 0x10) & (0xfffffff0));
- buf_b = buf_a + 32; /* ?? */
- p_A = (u32 *)SetupDqsPattern_1PassB(pass);
- p_B = (u32 *)SetupDqsPattern_1PassA(pass);
-
- for (i = 0; i < 16; i++) {
- buf_a[i] = p_A[i];
- buf_b[i] = p_B[i];
- }
-
- pDCTstat->PtrPatternBufA = (u32)buf_a;
- pDCTstat->PtrPatternBufB = (u32)buf_b;
-}
-
-void mct_TrainRcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Pass)
-{
- if (mct_checkNumberOfDqsRcvEn_1Pass(Pass)) {
- if (is_fam15h())
- dqsTrainRcvrEn_SW_Fam15(pMCTstat, pDCTstat, Pass);
- else
- dqsTrainRcvrEn_SW_Fam10(pMCTstat, pDCTstat, Pass);
- }
-}
-
-static uint16_t fam15_receiver_enable_training_seed(struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t rank, uint8_t package_type)
-{
- uint32_t dword;
- uint16_t seed = 0;
-
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- uint8_t channel = dct;
- if (package_type == PT_GR) {
- /* Get the internal node number */
- dword = Get_NB32(pDCTstat->dev_nbmisc, 0xe8);
- dword = (dword >> 30) & 0x3;
- if (dword == 1) {
- channel += 2;
- }
- }
-
- if (pDCTstat->Status & (1 << SB_Registered)) {
- if (package_type == PT_GR) {
- /* Socket G34: Fam15h BKDG v3.14 Table 99 */
- if (MaxDimmsInstallable == 1) {
- if (channel == 0)
- seed = 0x43;
- else if (channel == 1)
- seed = 0x3f;
- else if (channel == 2)
- seed = 0x3a;
- else if (channel == 3)
- seed = 0x35;
- } else if (MaxDimmsInstallable == 2) {
- if (channel == 0)
- seed = 0x54;
- else if (channel == 1)
- seed = 0x4d;
- else if (channel == 2)
- seed = 0x45;
- else if (channel == 3)
- seed = 0x40;
- } else if (MaxDimmsInstallable == 3) {
- if (channel == 0)
- seed = 0x6b;
- else if (channel == 1)
- seed = 0x5e;
- else if (channel == 2)
- seed = 0x4b;
- else if (channel == 3)
- seed = 0x3d;
- }
- } else if (package_type == PT_C3) {
- /* Socket C32: Fam15h BKDG v3.14 Table 100 */
- if ((MaxDimmsInstallable == 1) || (MaxDimmsInstallable == 2)) {
- if (channel == 0)
- seed = 0x3f;
- else if (channel == 1)
- seed = 0x3e;
- } else if (MaxDimmsInstallable == 3) {
- if (channel == 0)
- seed = 0x47;
- else if (channel == 1)
- seed = 0x38;
- }
- }
- } else if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- if (package_type == PT_GR) {
- /* Socket G34: Fam15h BKDG v3.14 Table 99 */
- if (MaxDimmsInstallable == 1) {
- if (channel == 0)
- seed = 0x123;
- else if (channel == 1)
- seed = 0x122;
- else if (channel == 2)
- seed = 0x112;
- else if (channel == 3)
- seed = 0x102;
- }
- } else if (package_type == PT_C3) {
- /* Socket C32: Fam15h BKDG v3.14 Table 100 */
- if (channel == 0)
- seed = 0x132;
- else if (channel == 1)
- seed = 0x122;
- }
- } else {
- if (package_type == PT_GR) {
- /* Socket G34: Fam15h BKDG v3.14 Table 99 */
- if (MaxDimmsInstallable == 1) {
- if (channel == 0)
- seed = 0x3e;
- else if (channel == 1)
- seed = 0x38;
- else if (channel == 2)
- seed = 0x37;
- else if (channel == 3)
- seed = 0x31;
- } else if (MaxDimmsInstallable == 2) {
- if (channel == 0)
- seed = 0x51;
- else if (channel == 1)
- seed = 0x4a;
- else if (channel == 2)
- seed = 0x46;
- else if (channel == 3)
- seed = 0x3f;
- } else if (MaxDimmsInstallable == 3) {
- if (channel == 0)
- seed = 0x5e;
- else if (channel == 1)
- seed = 0x52;
- else if (channel == 2)
- seed = 0x48;
- else if (channel == 3)
- seed = 0x3c;
- }
- } else if (package_type == PT_C3) {
- /* Socket C32: Fam15h BKDG v3.14 Table 100 */
- if ((MaxDimmsInstallable == 1) || (MaxDimmsInstallable == 2)) {
- if (channel == 0)
- seed = 0x39;
- else if (channel == 1)
- seed = 0x32;
- } else if (MaxDimmsInstallable == 3) {
- if (channel == 0)
- seed = 0x45;
- else if (channel == 1)
- seed = 0x37;
- }
- } else if (package_type == PT_M2) {
- /* Socket AM3: Fam15h BKDG v3.14 Table 101 */
- seed = 0x3a;
- } else if (package_type == PT_FM2) {
- /* Socket FM2: Fam15h Model10 BKDG 3.12 Table 43 */
- seed = 0x32;
- }
- }
-
- printk(BIOS_DEBUG, "%s: using seed: %04x\n", __func__, seed);
-
- return seed;
-}
-
-void read_dqs_write_timing_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint8_t lane;
- uint32_t dword;
-
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- uint32_t wdt_reg;
- if ((lane == 0) || (lane == 1))
- wdt_reg = 0x30;
- if ((lane == 2) || (lane == 3))
- wdt_reg = 0x31;
- if ((lane == 4) || (lane == 5))
- wdt_reg = 0x40;
- if ((lane == 6) || (lane == 7))
- wdt_reg = 0x41;
- if (lane == 8)
- wdt_reg = 0x32;
- wdt_reg += dimm * 3;
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, wdt_reg);
- if ((lane == 7) || (lane == 5) || (lane == 3) || (lane == 1))
- current_total_delay[lane] = (dword & 0x00ff0000) >> 16;
- if ((lane == 8) || (lane == 6) || (lane == 4) || (lane == 2) || (lane == 0))
- current_total_delay[lane] = dword & 0x000000ff;
- }
-}
-
-#ifdef UNUSED_CODE
-static void write_dqs_write_timing_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint8_t lane;
- uint32_t dword;
-
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- uint32_t ret_reg;
- if ((lane == 0) || (lane == 1))
- ret_reg = 0x30;
- if ((lane == 2) || (lane == 3))
- ret_reg = 0x31;
- if ((lane == 4) || (lane == 5))
- ret_reg = 0x40;
- if ((lane == 6) || (lane == 7))
- ret_reg = 0x41;
- if (lane == 8)
- ret_reg = 0x32;
- ret_reg += dimm * 3;
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, ret_reg);
- if ((lane == 7) || (lane == 5) || (lane == 3) || (lane == 1)) {
- dword &= ~(0xff << 16);
- dword |= (current_total_delay[lane] & 0xff) << 16;
- }
- if ((lane == 8) || (lane == 6) || (lane == 4) || (lane == 2) || (lane == 0)) {
- dword &= ~0xff;
- dword |= current_total_delay[lane] & 0xff;
- }
- Set_NB32_index_wait_DCT(dev, dct, index_reg, ret_reg, dword);
- }
-}
-#endif
-
-static void write_write_data_timing_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint8_t lane;
- uint32_t dword;
-
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- uint32_t wdt_reg;
-
- /* Calculate Write Data Timing register location */
- if ((lane == 0) || (lane == 1) || (lane == 2) || (lane == 3))
- wdt_reg = 0x1;
- if ((lane == 4) || (lane == 5) || (lane == 6) || (lane == 7))
- wdt_reg = 0x2;
- if (lane == 8)
- wdt_reg = 0x3;
- wdt_reg |= (dimm << 8);
-
- /* Set Write Data Timing register values */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, wdt_reg);
- if ((lane == 7) || (lane == 3)) {
- dword &= ~(0x7f << 24);
- dword |= (current_total_delay[lane] & 0x7f) << 24;
- }
- if ((lane == 6) || (lane == 2)) {
- dword &= ~(0x7f << 16);
- dword |= (current_total_delay[lane] & 0x7f) << 16;
- }
- if ((lane == 5) || (lane == 1)) {
- dword &= ~(0x7f << 8);
- dword |= (current_total_delay[lane] & 0x7f) << 8;
- }
- if ((lane == 8) || (lane == 4) || (lane == 0)) {
- dword &= ~0x7f;
- dword |= current_total_delay[lane] & 0x7f;
- }
- Set_NB32_index_wait_DCT(dev, dct, index_reg, wdt_reg, dword);
- }
-}
-
-void read_dqs_receiver_enable_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint8_t lane;
- uint32_t mask;
- uint32_t dword;
-
- if (is_fam15h())
- mask = 0x3ff;
- else
- mask = 0x1ff;
-
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- uint32_t ret_reg;
- if ((lane == 0) || (lane == 1))
- ret_reg = 0x10;
- if ((lane == 2) || (lane == 3))
- ret_reg = 0x11;
- if ((lane == 4) || (lane == 5))
- ret_reg = 0x20;
- if ((lane == 6) || (lane == 7))
- ret_reg = 0x21;
- if (lane == 8)
- ret_reg = 0x12;
- ret_reg += dimm * 3;
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, ret_reg);
- if ((lane == 7) || (lane == 5) || (lane == 3) || (lane == 1)) {
- current_total_delay[lane] = (dword & (mask << 16)) >> 16;
- }
- if ((lane == 8) || (lane == 6) || (lane == 4) || (lane == 2) || (lane == 0)) {
- current_total_delay[lane] = dword & mask;
- }
- }
-}
-
-void write_dqs_receiver_enable_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint8_t lane;
- uint32_t mask;
- uint32_t dword;
-
- if (is_fam15h())
- mask = 0x3ff;
- else
- mask = 0x1ff;
-
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- uint32_t ret_reg;
- if ((lane == 0) || (lane == 1))
- ret_reg = 0x10;
- if ((lane == 2) || (lane == 3))
- ret_reg = 0x11;
- if ((lane == 4) || (lane == 5))
- ret_reg = 0x20;
- if ((lane == 6) || (lane == 7))
- ret_reg = 0x21;
- if (lane == 8)
- ret_reg = 0x12;
- ret_reg += dimm * 3;
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, ret_reg);
- if ((lane == 7) || (lane == 5) || (lane == 3) || (lane == 1)) {
- dword &= ~(mask << 16);
- dword |= (current_total_delay[lane] & mask) << 16;
- }
- if ((lane == 8) || (lane == 6) || (lane == 4) || (lane == 2) || (lane == 0)) {
- dword &= ~mask;
- dword |= current_total_delay[lane] & mask;
- }
- Set_NB32_index_wait_DCT(dev, dct, index_reg, ret_reg, dword);
- }
-}
-
-static void read_dram_phase_recovery_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint8_t lane;
- uint32_t dword;
-
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- uint32_t prc_reg;
-
- /* Calculate DRAM Phase Recovery Control register location */
- if ((lane == 0) || (lane == 1) || (lane == 2) || (lane == 3))
- prc_reg = 0x50;
- if ((lane == 4) || (lane == 5) || (lane == 6) || (lane == 7))
- prc_reg = 0x51;
- if (lane == 8)
- prc_reg = 0x52;
-
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, prc_reg);
- if ((lane == 7) || (lane == 3)) {
- current_total_delay[lane] = (dword >> 24) & 0x7f;
- }
- if ((lane == 6) || (lane == 2)) {
- current_total_delay[lane] = (dword >> 16) & 0x7f;
- }
- if ((lane == 5) || (lane == 1)) {
- current_total_delay[lane] = (dword >> 8) & 0x7f;
- }
- if ((lane == 8) || (lane == 4) || (lane == 0)) {
- current_total_delay[lane] = dword & 0x7f;
- }
- }
-}
-
-static void write_dram_phase_recovery_control_registers(uint16_t *current_total_delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint8_t lane;
- uint32_t dword;
-
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- uint32_t prc_reg;
-
- /* Calculate DRAM Phase Recovery Control register location */
- if ((lane == 0) || (lane == 1) || (lane == 2) || (lane == 3))
- prc_reg = 0x50;
- if ((lane == 4) || (lane == 5) || (lane == 6) || (lane == 7))
- prc_reg = 0x51;
- if (lane == 8)
- prc_reg = 0x52;
-
- /* Set DRAM Phase Recovery Control register values */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, prc_reg);
- if ((lane == 7) || (lane == 3)) {
- dword &= ~(0x7f << 24);
- dword |= (current_total_delay[lane] & 0x7f) << 24;
- }
- if ((lane == 6) || (lane == 2)) {
- dword &= ~(0x7f << 16);
- dword |= (current_total_delay[lane] & 0x7f) << 16;
- }
- if ((lane == 5) || (lane == 1)) {
- dword &= ~(0x7f << 8);
- dword |= (current_total_delay[lane] & 0x7f) << 8;
- }
- if ((lane == 8) || (lane == 4) || (lane == 0)) {
- dword &= ~0x7f;
- dword |= current_total_delay[lane] & 0x7f;
- }
- Set_NB32_index_wait_DCT(dev, dct, index_reg, prc_reg, dword);
- }
-}
-
-void read_dqs_read_data_timing_registers(uint16_t *delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint8_t shift;
- uint32_t dword;
- uint32_t mask;
-
- if (is_fam15h()) {
- mask = 0x3e;
- shift = 1;
- }
- else {
- mask = 0x3f;
- shift = 0;
- }
-
- /* Lanes 0 - 3 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x5 | (dimm << 8));
- delay[3] = ((dword >> 24) & mask) >> shift;
- delay[2] = ((dword >> 16) & mask) >> shift;
- delay[1] = ((dword >> 8) & mask) >> shift;
- delay[0] = (dword & mask) >> shift;
-
- /* Lanes 4 - 7 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x6 | (dimm << 8));
- delay[7] = ((dword >> 24) & mask) >> shift;
- delay[6] = ((dword >> 16) & mask) >> shift;
- delay[5] = ((dword >> 8) & mask) >> shift;
- delay[4] = (dword & mask) >> shift;
-
- /* Lane 8 (ECC) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x7 | (dimm << 8));
- delay[8] = (dword & mask) >> shift;
-}
-
-void write_dqs_read_data_timing_registers(uint16_t *delay, uint32_t dev, uint8_t dct, uint8_t dimm, uint32_t index_reg)
-{
- uint8_t shift;
- uint32_t dword;
- uint32_t mask;
-
- if (is_fam15h()) {
- mask = 0x3e;
- shift = 1;
- }
- else {
- mask = 0x3f;
- shift = 0;
- }
-
- /* Lanes 0 - 3 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x5 | (dimm << 8));
- dword &= ~(mask << 24);
- dword &= ~(mask << 16);
- dword &= ~(mask << 8);
- dword &= ~mask;
- dword |= ((delay[3] << shift) & mask) << 24;
- dword |= ((delay[2] << shift) & mask) << 16;
- dword |= ((delay[1] << shift) & mask) << 8;
- dword |= (delay[0] << shift) & mask;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x5 | (dimm << 8), dword);
-
- /* Lanes 4 - 7 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x6 | (dimm << 8));
- dword &= ~(mask << 24);
- dword &= ~(mask << 16);
- dword &= ~(mask << 8);
- dword &= ~mask;
- dword |= ((delay[7] << shift) & mask) << 24;
- dword |= ((delay[6] << shift) & mask) << 16;
- dword |= ((delay[5] << shift) & mask) << 8;
- dword |= (delay[4] << shift) & mask;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x6 | (dimm << 8), dword);
-
- /* Lane 8 (ECC) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x7 | (dimm << 8));
- dword &= ~mask;
- dword |= (delay[8] << shift) & mask;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x7 | (dimm << 8), dword);
-}
-
-static uint32_t convert_testaddr_and_channel_to_address(struct DCTStatStruc *pDCTstat, uint32_t testaddr, uint8_t channel)
-{
- SetUpperFSbase(testaddr);
- testaddr <<= 8;
-
- if ((pDCTstat->Status & (1<<SB_128bitmode)) && channel) {
- testaddr += 8; /* second channel */
- }
-
- return testaddr;
-}
-
-/* DQS Receiver Enable Training (Family 10h)
- * Algorithm detailed in:
- * The Fam10h BKDG Rev. 3.62 section 2.8.9.9.2
- */
-static void dqsTrainRcvrEn_SW_Fam10(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Pass)
-{
- u8 Channel;
- u8 _2Ranks;
- u8 Addl_Index = 0;
- u8 Receiver;
- u8 _DisableDramECC = 0, _Wrap32Dis = 0, _SSE2 = 0;
- u16 CTLRMaxDelay;
- u16 MaxDelay_CH[2];
- u32 TestAddr0, TestAddr1, TestAddr0B, TestAddr1B;
- u32 PatternBuffer[64+4]; /* FIXME: need increase 8? */
- u32 Errors;
-
- u32 val;
- u32 reg;
- u32 dev;
- u32 index_reg;
- u32 ch_start, ch_end, ch;
- msr_t msr;
- CRx_TYPE cr4;
-
- uint32_t dword;
- uint8_t dimm;
- uint8_t rank;
- uint8_t lane;
- uint16_t current_total_delay[MAX_BYTE_LANES];
- uint16_t candidate_total_delay[8];
- uint8_t data_test_pass_sr[2][8]; /* [rank][lane] */
- uint8_t data_test_pass[8]; /* [lane] */
- uint8_t data_test_pass_prev[8]; /* [lane] */
- uint8_t window_det_toggle[8];
- uint8_t trained[8];
- uint64_t result_qword1;
- uint64_t result_qword2;
-
- u8 valid;
-
- print_debug_dqs("\nTrainRcvEn: Node", pDCTstat->Node_ID, 0);
- print_debug_dqs("TrainRcvEn: Pass", Pass, 0);
-
- dev = pDCTstat->dev_dct;
- ch_start = 0;
- if (!pDCTstat->GangedMode) {
- ch_end = 2;
- } else {
- ch_end = 1;
- }
-
- for (ch = ch_start; ch < ch_end; ch++) {
- reg = 0x78;
- val = Get_NB32_DCT(dev, ch, reg);
- val &= ~(0x3ff << 22);
- val |= (0x0c8 << 22); /* MaxRdLatency = 0xc8 */
- Set_NB32_DCT(dev, ch, reg, val);
- }
-
- if (Pass == FirstPass) {
- mct_InitDQSPos4RcvrEn_D(pMCTstat, pDCTstat);
- } else {
- pDCTstat->DimmTrainFail = 0;
- pDCTstat->CSTrainFail = ~pDCTstat->CSPresent;
- }
-
- cr4 = read_cr4();
- if (cr4 & (1 << 9)) { /* save the old value */
- _SSE2 = 1;
- }
- cr4 |= (1 << 9); /* OSFXSR enable SSE2 */
- write_cr4(cr4);
-
- msr = rdmsr(HWCR_MSR);
- /* FIXME: Why use SSEDIS */
- if (msr.lo & (1 << 17)) { /* save the old value */
- _Wrap32Dis = 1;
- }
- msr.lo |= (1 << 17); /* HWCR.wrap32dis */
- msr.lo &= ~(1 << 15); /* SSEDIS */
- wrmsr(HWCR_MSR, msr); /* Setting wrap32dis allows 64-bit memory
- references in real mode */
-
- _DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
-
- SetupRcvrPattern(pMCTstat, pDCTstat, PatternBuffer, Pass);
-
- Errors = 0;
- dev = pDCTstat->dev_dct;
-
- for (Channel = 0; Channel < 2; Channel++) {
- print_debug_dqs("\tTrainRcvEn51: Node ", pDCTstat->Node_ID, 1);
- print_debug_dqs("\tTrainRcvEn51: Channel ", Channel, 1);
- pDCTstat->Channel = Channel;
-
- CTLRMaxDelay = 0;
- MaxDelay_CH[Channel] = 0;
- index_reg = 0x98;
-
- Receiver = mct_InitReceiver_D(pDCTstat, Channel);
- /* There are four receiver pairs, loosely associated with chipselects.
- * This is essentially looping over each DIMM.
- */
- for (; Receiver < 8; Receiver += 2) {
- Addl_Index = (Receiver >> 1) * 3 + 0x10;
- dimm = (Receiver >> 1);
-
- print_debug_dqs("\t\tTrainRcvEnd52: index ", Addl_Index, 2);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, Receiver)) {
- continue;
- }
-
- /* Clear data structures */
- for (lane = 0; lane < 8; lane++) {
- data_test_pass_prev[lane] = 0;
- trained[lane] = 0;
- }
-
- /* 2.8.9.9.2 (1, 6)
- * Retrieve gross and fine timing fields from write DQS registers
- */
- read_dqs_write_timing_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
-
- /* 2.8.9.9.2 (1)
- * Program the Write Data Timing and Write ECC Timing register to
- * the values stored in the DQS Write Timing Control register
- * for each lane
- */
- write_write_data_timing_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
-
- /* 2.8.9.9.2 (2)
- * Program the Read DQS Timing Control and the Read DQS ECC Timing Control registers
- * to 1/2 MEMCLK for all lanes
- */
- for (lane = 0; lane < MAX_BYTE_LANES; lane++) {
- uint32_t rdt_reg;
- if ((lane == 0) || (lane == 1) || (lane == 2) || (lane == 3))
- rdt_reg = 0x5;
- if ((lane == 4) || (lane == 5) || (lane == 6) || (lane == 7))
- rdt_reg = 0x6;
- if (lane == 8)
- rdt_reg = 0x7;
- rdt_reg |= (dimm << 8);
- if (lane == 8)
- dword = 0x0000003f;
- else
- dword = 0x3f3f3f3f;
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, rdt_reg, dword);
- }
-
- /* 2.8.9.9.2 (3)
- * Select two test addresses for each rank present
- */
- TestAddr0 = mct_GetRcvrSysAddr_D(pMCTstat, pDCTstat, Channel, Receiver, &valid);
- if (!valid) { /* Address not supported on current CS */
- continue;
- }
-
- TestAddr0B = TestAddr0 + (BigPagex8_RJ8 << 3);
-
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, Receiver+1)) {
- TestAddr1 = mct_GetRcvrSysAddr_D(pMCTstat, pDCTstat, Channel, Receiver+1, &valid);
- if (!valid) { /* Address not supported on current CS */
- continue;
- }
- TestAddr1B = TestAddr1 + (BigPagex8_RJ8 << 3);
- _2Ranks = 1;
- } else {
- _2Ranks = TestAddr1 = TestAddr1B = 0;
- }
-
- print_debug_dqs("\t\tTrainRcvEn53: TestAddr0 ", TestAddr0, 2);
- print_debug_dqs("\t\tTrainRcvEn53: TestAddr0B ", TestAddr0B, 2);
- print_debug_dqs("\t\tTrainRcvEn53: TestAddr1 ", TestAddr1, 2);
- print_debug_dqs("\t\tTrainRcvEn53: TestAddr1B ", TestAddr1B, 2);
-
- /* 2.8.9.9.2 (4, 5)
- * Write 1 cache line of the appropriate test pattern to each test address
- */
- mct_Write1LTestPattern_D(pMCTstat, pDCTstat, TestAddr0, 0); /* rank 0 of DIMM, testpattern 0 */
- mct_Write1LTestPattern_D(pMCTstat, pDCTstat, TestAddr0B, 1); /* rank 0 of DIMM, testpattern 1 */
- if (_2Ranks) {
- mct_Write1LTestPattern_D(pMCTstat, pDCTstat, TestAddr1, 0); /*rank 1 of DIMM, testpattern 0 */
- mct_Write1LTestPattern_D(pMCTstat, pDCTstat, TestAddr1B, 1); /*rank 1 of DIMM, testpattern 1 */
- }
-
-#if DQS_TRAIN_DEBUG > 0
- for (lane = 0; lane < 8; lane++) {
- print_debug_dqs("\t\tTrainRcvEn54: lane: ", lane, 2);
- print_debug_dqs("\t\tTrainRcvEn54: current_total_delay ", current_total_delay[lane], 2);
- }
-#endif
-
- /* 2.8.9.9.2 (6)
- * Write gross and fine timing fields to read DQS registers
- */
- write_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
-
- /* 2.8.9.9.2 (7)
- * Loop over all delay values up to 1 MEMCLK (0x40 delay steps) from the initial delay values
- *
- * FIXME
- * It is not clear if training should be discontinued if any test failures occur in the first
- * 1 MEMCLK window, or if it should be discontinued if no successes occur in the first 1 MEMCLK
- * window. Therefore, loop over up to 2 MEMCLK (0x80 delay steps) to be on the safe side.
- */
- uint16_t current_delay_step;
-
- for (current_delay_step = 0; current_delay_step < 0x80; current_delay_step++) {
- print_debug_dqs("\t\t\tTrainRcvEn541: current_delay_step ", current_delay_step, 3);
-
- /* 2.8.9.9.2 (7 D)
- * Terminate if all lanes are trained
- */
- uint8_t all_lanes_trained = 1;
- for (lane = 0; lane < 8; lane++)
- if (!trained[lane])
- all_lanes_trained = 0;
-
- if (all_lanes_trained)
- break;
-
- /* 2.8.9.9.2 (7 A)
- * Loop over all ranks
- */
- for (rank = 0; rank < (_2Ranks + 1); rank++) {
- /* 2.8.9.9.2 (7 A a-d)
- * Read the first test address of the current rank
- * Store the first data beat for analysis
- * Reset read pointer in the DRAM controller FIFO
- * Read the second test address of the current rank
- * Store the first data beat for analysis
- * Reset read pointer in the DRAM controller FIFO
- */
- if (rank & 1) {
- /* 2.8.9.9.2 (7 D)
- * Invert read instructions to alternate data read order on the bus
- */
- proc_IOCLFLUSH_D((rank == 0)?TestAddr0B:TestAddr1B);
- result_qword2 = read64_fs(convert_testaddr_and_channel_to_address(pDCTstat, (rank == 0)?TestAddr0B:TestAddr1B, Channel));
- write_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
- proc_IOCLFLUSH_D((rank == 0)?TestAddr0:TestAddr1);
- result_qword1 = read64_fs(convert_testaddr_and_channel_to_address(pDCTstat, (rank == 0)?TestAddr0:TestAddr1, Channel));
- write_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
- } else {
- proc_IOCLFLUSH_D((rank == 0)?TestAddr0:TestAddr1);
- result_qword1 = read64_fs(convert_testaddr_and_channel_to_address(pDCTstat, (rank == 0)?TestAddr0:TestAddr1, Channel));
- write_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
- proc_IOCLFLUSH_D((rank == 0)?TestAddr0B:TestAddr1B);
- result_qword2 = read64_fs(convert_testaddr_and_channel_to_address(pDCTstat, (rank == 0)?TestAddr0B:TestAddr1B, Channel));
- write_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
- }
- /* 2.8.9.9.2 (7 A e)
- * Compare both read patterns and flag passing ranks/lanes
- */
- uint8_t result_lane_byte1;
- uint8_t result_lane_byte2;
- for (lane = 0; lane < 8; lane++) {
- if (trained[lane] == 1) {
-#if DQS_TRAIN_DEBUG > 0
- print_debug_dqs("\t\t\t\t\t\t\t\t lane already trained: ", lane, 4);
-#endif
- continue;
- }
-
- result_lane_byte1 = (result_qword1 >> (lane * 8)) & 0xff;
- result_lane_byte2 = (result_qword2 >> (lane * 8)) & 0xff;
- if ((result_lane_byte1 == 0x55) && (result_lane_byte2 == 0xaa))
- data_test_pass_sr[rank][lane] = 1;
- else
- data_test_pass_sr[rank][lane] = 0;
-#if DQS_TRAIN_DEBUG > 0
- print_debug_dqs_pair("\t\t\t\t\t\t\t\t ", 0x55, " | ", result_lane_byte1, 4);
- print_debug_dqs_pair("\t\t\t\t\t\t\t\t ", 0xaa, " | ", result_lane_byte2, 4);
-#endif
- }
- }
-
- /* 2.8.9.9.2 (7 B)
- * If DIMM is dual rank, only use delays that pass testing for both ranks
- */
- for (lane = 0; lane < 8; lane++) {
- if (_2Ranks) {
- if ((data_test_pass_sr[0][lane]) && (data_test_pass_sr[1][lane]))
- data_test_pass[lane] = 1;
- else
- data_test_pass[lane] = 0;
- } else {
- data_test_pass[lane] = data_test_pass_sr[0][lane];
- }
- }
-
- /* 2.8.9.9.2 (7 E)
- * For each lane, update the DQS receiver delay setting in support of next iteration
- */
- for (lane = 0; lane < 8; lane++) {
- if (trained[lane] == 1)
- continue;
-
- /* 2.8.9.9.2 (7 C a)
- * Save the total delay of the first success after a failure for later use
- */
- if ((data_test_pass[lane] == 1) && (data_test_pass_prev[lane] == 0)) {
- candidate_total_delay[lane] = current_total_delay[lane];
- window_det_toggle[lane] = 0;
- }
-
- /* 2.8.9.9.2 (7 C b)
- * If the current delay failed testing add 1/8 UI to the current delay
- */
- if (data_test_pass[lane] == 0)
- current_total_delay[lane] += 0x4;
-
- /* 2.8.9.9.2 (7 C c)
- * If the current delay passed testing alternately add either 1/32 UI or 1/4 UI to the current delay
- * If 1.25 UI of delay have been added with no failures the lane is considered trained
- */
- if (data_test_pass[lane] == 1) {
- /* See if lane is trained */
- if ((current_total_delay[lane] - candidate_total_delay[lane]) >= 0x28) {
- trained[lane] = 1;
-
- /* Calculate and set final lane delay value
- * The final delay is the candidate delay + 7/8 UI
- */
- current_total_delay[lane] = candidate_total_delay[lane] + 0x1c;
- } else {
- if (window_det_toggle[lane] == 0) {
- current_total_delay[lane] += 0x1;
- window_det_toggle[lane] = 1;
- } else {
- current_total_delay[lane] += 0x8;
- window_det_toggle[lane] = 0;
- }
- }
- }
- }
-
- /* Update delays in hardware */
- write_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
-
- /* Save previous results for comparison in the next iteration */
- for (lane = 0; lane < 8; lane++)
- data_test_pass_prev[lane] = data_test_pass[lane];
- }
-
-#if DQS_TRAIN_DEBUG > 0
- for (lane = 0; lane < 8; lane++)
- print_debug_dqs_pair("\t\tTrainRcvEn55: Lane ", lane, " current_total_delay ", current_total_delay[lane], 2);
-#endif
-
- /* Find highest delay value and save for later use */
- for (lane = 0; lane < 8; lane++)
- if (current_total_delay[lane] > CTLRMaxDelay)
- CTLRMaxDelay = current_total_delay[lane];
-
- /* See if any lanes failed training, and set error flags appropriately
- * For all trained lanes, save delay values for later use
- */
- for (lane = 0; lane < 8; lane++) {
- if (trained[lane]) {
- pDCTstat->CH_D_B_RCVRDLY[Channel][Receiver >> 1][lane] = current_total_delay[lane];
- } else {
- printk(BIOS_WARNING, "TrainRcvrEn: WARNING: Lane %d of receiver %d on channel %d failed training!\n", lane, Receiver, Channel);
-
- /* Set error flags */
- pDCTstat->ErrStatus |= 1 << SB_NORCVREN;
- Errors |= 1 << SB_NORCVREN;
- pDCTstat->ErrCode = SC_FatalErr;
- pDCTstat->CSTrainFail |= 1 << Receiver;
- pDCTstat->DimmTrainFail |= 1 << (Receiver + Channel);
- }
- }
-
- /* 2.8.9.9.2 (8)
- * Flush the receiver FIFO
- * Write one full cache line of non-0x55/0xaa data to one of the test addresses, then read it back to flush the FIFO
- */
- /* FIXME
- * This does not seem to be needed, and has a tendency to lock up the
- * boot process while attempting to write the test pattern.
- */
- }
- MaxDelay_CH[Channel] = CTLRMaxDelay;
- }
-
- CTLRMaxDelay = MaxDelay_CH[0];
- if (MaxDelay_CH[1] > CTLRMaxDelay)
- CTLRMaxDelay = MaxDelay_CH[1];
-
- for (Channel = 0; Channel < 2; Channel++) {
- mct_SetMaxLatency_D(pDCTstat, Channel, CTLRMaxDelay); /* program Ch A/B MaxAsyncLat to correspond with max delay */
- }
-
- for (Channel = 0; Channel < 2; Channel++) {
- ResetDCTWrPtr_D(dev, Channel, index_reg, Addl_Index);
- }
-
- if (_DisableDramECC) {
- mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
- }
-
- if (Pass == FirstPass) {
- /*Disable DQSRcvrEn training mode */
- mct_DisableDQSRcvEn_D(pDCTstat);
- }
-
- if (!_Wrap32Dis) {
- msr = rdmsr(HWCR_MSR);
- msr.lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- wrmsr(HWCR_MSR, msr);
- }
- if (!_SSE2) {
- cr4 = read_cr4();
- cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
- write_cr4(cr4);
- }
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 ChannelDTD;
- printk(BIOS_DEBUG, "TrainRcvrEn: CH_MaxRdLat:\n");
- for (ChannelDTD = 0; ChannelDTD < 2; ChannelDTD++) {
- printk(BIOS_DEBUG, "Channel:%x: %x\n",
- ChannelDTD, pDCTstat->CH_MaxRdLat[ChannelDTD][0]);
- }
- }
-#endif
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u16 valDTD;
- u8 ChannelDTD, ReceiverDTD;
- u8 i;
- u16 *p;
-
- printk(BIOS_DEBUG, "TrainRcvrEn: CH_D_B_RCVRDLY:\n");
- for (ChannelDTD = 0; ChannelDTD < 2; ChannelDTD++) {
- printk(BIOS_DEBUG, "Channel:%x\n", ChannelDTD);
- for (ReceiverDTD = 0; ReceiverDTD < 8; ReceiverDTD+=2) {
- printk(BIOS_DEBUG, "\t\tReceiver:%x:", ReceiverDTD);
- p = pDCTstat->CH_D_B_RCVRDLY[ChannelDTD][ReceiverDTD>>1];
- for (i = 0; i < 8; i++) {
- valDTD = p[i];
- printk(BIOS_DEBUG, " %03x", valDTD);
- }
- printk(BIOS_DEBUG, "\n");
- }
- }
- }
-#endif
-
- printk(BIOS_DEBUG, "TrainRcvrEn: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "TrainRcvrEn: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "TrainRcvrEn: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "TrainRcvrEn: Done\n\n");
-}
-
-/* DQS Receiver Enable Training Pattern Generation (Family 15h)
- * Algorithm detailed in:
- * The Fam15h BKDG Rev. 3.14 section 2.10.5.8.2 (4)
- */
-static void generate_dram_receiver_enable_training_pattern_fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t Receiver)
-{
- uint32_t dword;
- uint32_t dev = pDCTstat->dev_dct;
-
- /* 2.10.5.7.1.1
- * It appears that the DCT only supports 8-beat burst length mode,
- * so do nothing here...
- */
-
- /* Wait for CmdSendInProg == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x250);
- } while (dword & (0x1 << 12));
-
- /* Set CmdTestEnable = 1 */
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword |= (0x1 << 2);
- Set_NB32_DCT(dev, dct, 0x250, dword);
-
- /* 2.10.5.8.6.1.1 Send Activate Command */
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- dword &= ~(0xff << 22); /* CmdChipSelect = Receiver */
- dword |= ((0x1 << Receiver) << 22);
- dword &= ~(0x7 << 19); /* CmdBank = 0 */
- dword &= ~(0x3ffff); /* CmdAddress = 0 */
- dword |= (0x1 << 31); /* SendActCmd = 1 */
- Set_NB32_DCT(dev, dct, 0x28c, dword);
-
- /* Wait for SendActCmd == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- } while (dword & (0x1 << 31));
-
- /* Wait 75 MEMCLKs. */
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 75);
-
- /* 2.10.5.8.6.1.2 */
- Set_NB32_DCT(dev, dct, 0x274, 0x0); /* DQMask = 0 */
- Set_NB32_DCT(dev, dct, 0x278, 0x0);
-
- dword = Get_NB32_DCT(dev, dct, 0x27c);
- dword &= ~(0xff); /* EccMask = 0 */
- if (pDCTstat->DimmECCPresent == 0)
- dword |= 0xff; /* EccMask = 0xff */
- Set_NB32_DCT(dev, dct, 0x27c, dword);
-
- /* 2.10.5.8.6.1.2 */
- dword = Get_NB32_DCT(dev, dct, 0x270);
- dword &= ~(0x7ffff); /* DataPrbsSeed = 55555 */
- dword |= (0x44443); /* Use AGESA seed */
- Set_NB32_DCT(dev, dct, 0x270, dword);
-
- /* 2.10.5.8.2 (4) */
- dword = Get_NB32_DCT(dev, dct, 0x260);
- dword &= ~(0x1fffff); /* CmdCount = 192 */
- dword |= 192;
- Set_NB32_DCT(dev, dct, 0x260, dword);
-
- /* Configure Target A */
- dword = Get_NB32_DCT(dev, dct, 0x254);
- dword &= ~(0x7 << 24); /* TgtChipSelect = Receiver */
- dword |= (Receiver & 0x7) << 24;
- dword &= ~(0x7 << 21); /* TgtBank = 0 */
- dword &= ~(0x3ff); /* TgtAddress = 0 */
- Set_NB32_DCT(dev, dct, 0x254, dword);
-
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword |= (0x1 << 3); /* ResetAllErr = 1 */
- dword &= ~(0x1 << 4); /* StopOnErr = 0 */
- dword &= ~(0x3 << 8); /* CmdTgt = 0 (Target A) */
- dword &= ~(0x7 << 5); /* CmdType = 0 (Read) */
- dword |= (0x1 << 11); /* SendCmd = 1 */
- Set_NB32_DCT(dev, dct, 0x250, dword);
-
- /* 2.10.5.8.6.1.2 Wait for TestStatus == 1 and CmdSendInProg == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x250);
- } while ((dword & (0x1 << 12)) || (!(dword & (0x1 << 10))));
-
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword &= ~(0x1 << 11); /* SendCmd = 0 */
- Set_NB32_DCT(dev, dct, 0x250, dword);
-
- /* 2.10.5.8.6.1.1 Send Precharge Command */
- /* Wait 25 MEMCLKs. */
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 25);
-
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- dword &= ~(0xff << 22); /* CmdChipSelect = Receiver */
- dword |= ((0x1 << Receiver) << 22);
- dword &= ~(0x7 << 19); /* CmdBank = 0 */
- dword &= ~(0x3ffff); /* CmdAddress = 0x400 */
- dword |= 0x400;
- dword |= (0x1 << 30); /* SendPchgCmd = 1 */
- Set_NB32_DCT(dev, dct, 0x28c, dword);
-
- /* Wait for SendPchgCmd == 0 */
- do {
- dword = Get_NB32_DCT(dev, dct, 0x28c);
- } while (dword & (0x1 << 30));
-
- /* Wait 25 MEMCLKs. */
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 25);
-
- /* Set CmdTestEnable = 0 */
- dword = Get_NB32_DCT(dev, dct, 0x250);
- dword &= ~(0x1 << 2);
- Set_NB32_DCT(dev, dct, 0x250, dword);
-}
-
-/* DQS Receiver Enable Training (Family 15h)
- * Algorithm detailed in:
- * The Fam15h BKDG Rev. 3.14 section 2.10.5.8.2
- * This algorithm runs once at the lowest supported MEMCLK,
- * then once again at the highest supported MEMCLK.
- */
-static void dqsTrainRcvrEn_SW_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Pass)
-{
- u8 Channel;
- u8 _2Ranks;
- u8 Addl_Index = 0;
- u8 Receiver;
- u8 _DisableDramECC = 0, _Wrap32Dis = 0, _SSE2 = 0;
- u32 Errors;
-
- u32 val;
- u32 dev;
- u32 index_reg;
- u32 ch_start, ch_end, ch;
- u32 msr;
- CRx_TYPE cr4;
- u32 lo, hi;
-
- uint32_t dword;
- uint8_t dimm;
- uint8_t rank;
- uint8_t lane;
- uint8_t nibble;
- uint8_t mem_clk;
- uint16_t min_mem_clk;
- uint16_t initial_seed;
- uint8_t train_both_nibbles;
- uint16_t current_total_delay[MAX_BYTE_LANES];
- uint16_t nibble0_current_total_delay[MAX_BYTE_LANES];
- uint16_t dqs_ret_pass1_total_delay[MAX_BYTE_LANES];
- uint16_t rank0_current_total_delay[MAX_BYTE_LANES];
- uint16_t phase_recovery_delays[MAX_BYTE_LANES];
- uint16_t seed[MAX_BYTE_LANES];
- uint16_t seed_gross[MAX_BYTE_LANES];
- uint16_t seed_fine[MAX_BYTE_LANES];
- uint16_t seed_pre_gross[MAX_BYTE_LANES];
-
- uint8_t package_type = mctGet_NVbits(NV_PACK_TYPE);
- uint16_t fam15h_freq_tab[] = {0, 0, 0, 0, 333, 0, 400, 0, 0, 0, 533, 0, 0, 0, 667, 0, 0, 0, 800, 0, 0, 0, 933};
-
- uint8_t lane_count;
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- print_debug_dqs("\nTrainRcvEn: Node", pDCTstat->Node_ID, 0);
- print_debug_dqs("TrainRcvEn: Pass", Pass, 0);
-
- min_mem_clk = mctGet_NVbits(NV_MIN_MEMCLK);
-
- train_both_nibbles = 0;
- if (pDCTstat->Dimmx4Present)
- if (is_fam15h())
- train_both_nibbles = 1;
-
- dev = pDCTstat->dev_dct;
- index_reg = 0x98;
- ch_start = 0;
- ch_end = 2;
-
- for (ch = ch_start; ch < ch_end; ch++) {
- uint8_t max_rd_latency = 0x55;
- uint8_t p_state;
-
- /* 2.10.5.6 */
- fam15EnableTrainingMode(pMCTstat, pDCTstat, ch, 1);
-
- /* 2.10.5.2 */
- for (p_state = 0; p_state < 3; p_state++) {
- val = Get_NB32_DCT_NBPstate(dev, ch, p_state, 0x210);
- val &= ~(0x3ff << 22); /* MaxRdLatency = max_rd_latency */
- val |= (max_rd_latency & 0x3ff) << 22;
- Set_NB32_DCT_NBPstate(dev, ch, p_state, 0x210, val);
- }
- }
-
- if (Pass != FirstPass) {
- pDCTstat->DimmTrainFail = 0;
- pDCTstat->CSTrainFail = ~pDCTstat->CSPresent;
- }
-
- cr4 = read_cr4();
- if (cr4 & (1 << 9)) { /* save the old value */
- _SSE2 = 1;
- }
- cr4 |= (1 << 9); /* OSFXSR enable SSE2 */
- write_cr4(cr4);
-
- msr = HWCR_MSR;
- _RDMSR(msr, &lo, &hi);
- /* FIXME: Why use SSEDIS */
- if (lo & (1 << 17)) { /* save the old value */
- _Wrap32Dis = 1;
- }
- lo |= (1 << 17); /* HWCR.wrap32dis */
- lo &= ~(1 << 15); /* SSEDIS */
- _WRMSR(msr, lo, hi); /* Setting wrap32dis allows 64-bit memory references in real mode */
-
- _DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
-
- Errors = 0;
- dev = pDCTstat->dev_dct;
-
- for (Channel = 0; Channel < 2; Channel++) {
- print_debug_dqs("\tTrainRcvEn51: Node ", pDCTstat->Node_ID, 1);
- print_debug_dqs("\tTrainRcvEn51: Channel ", Channel, 1);
- pDCTstat->Channel = Channel;
-
- mem_clk = Get_NB32_DCT(dev, Channel, 0x94) & 0x1f;
-
- Receiver = mct_InitReceiver_D(pDCTstat, Channel);
- /* There are four receiver pairs, loosely associated with chipselects.
- * This is essentially looping over each DIMM.
- */
- for (; Receiver < 8; Receiver += 2) {
- Addl_Index = (Receiver >> 1) * 3 + 0x10;
- dimm = (Receiver >> 1);
-
- print_debug_dqs("\t\tTrainRcvEnd52: index ", Addl_Index, 2);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, Receiver)) {
- continue;
- }
-
- /* Retrieve the total delay values from pass 1 of DQS receiver enable training */
- if (Pass != FirstPass) {
- read_dqs_receiver_enable_control_registers(dqs_ret_pass1_total_delay, dev, Channel, dimm, index_reg);
- }
-
- /* 2.10.5.8.2
- * Loop over all ranks
- */
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, Receiver+1))
- _2Ranks = 1;
- else
- _2Ranks = 0;
- for (rank = 0; rank < (_2Ranks + 1); rank++) {
- for (nibble = 0; nibble < (train_both_nibbles + 1); nibble++) {
- /* 2.10.5.8.2 (1)
- * Specify the target DIMM and nibble to be trained
- */
- dword = Get_NB32_index_wait_DCT(dev, Channel, index_reg, 0x00000008);
- dword &= ~(0x3 << 4); /* TrDimmSel = dimm */
- dword |= ((dimm & 0x3) << 4);
- dword &= ~(0x1 << 2); /* TrNibbleSel = nibble */
- dword |= ((nibble & 0x1) << 2);
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, 0x00000008, dword);
-
- /* 2.10.5.8.2 (2)
- * Retrieve gross and fine timing fields from write DQS registers
- */
- read_dqs_write_timing_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
-
- /* 2.10.5.8.2.1
- * Generate the DQS Receiver Enable Training Seed Values
- */
- if (Pass == FirstPass) {
- initial_seed = fam15_receiver_enable_training_seed(pDCTstat, Channel, dimm, rank, package_type);
-
- /* Adjust seed for the minimum platform supported frequency */
- initial_seed = (uint16_t) (((((uint64_t) initial_seed) *
- fam15h_freq_tab[mem_clk] * 100) / (min_mem_clk * 100)));
-
- for (lane = 0; lane < lane_count; lane++) {
- uint16_t wl_pass1_delay;
- wl_pass1_delay = current_total_delay[lane];
-
- seed[lane] = initial_seed + wl_pass1_delay;
- }
- } else {
- uint8_t addr_prelaunch = 0; /* TODO: Fetch the correct value from RC2[0] */
- uint16_t register_delay;
- int16_t seed_prescaling;
-
- memcpy(current_total_delay, dqs_ret_pass1_total_delay, sizeof(current_total_delay));
- if ((pDCTstat->Status & (1 << SB_Registered))) {
- if (addr_prelaunch)
- register_delay = 0x30;
- else
- register_delay = 0x20;
- } else if ((pDCTstat->Status & (1 << SB_LoadReduced))) {
- /* TODO
- * Load reduced DIMM support unimplemented
- */
- register_delay = 0x0;
- } else {
- register_delay = 0x0;
- }
-
- for (lane = 0; lane < lane_count; lane++) {
- seed_prescaling = current_total_delay[lane] - register_delay - 0x20;
- seed[lane] = (uint16_t) (register_delay + ((((uint64_t) seed_prescaling) * fam15h_freq_tab[mem_clk] * 100) / (min_mem_clk * 100)));
- }
- }
-
- for (lane = 0; lane < lane_count; lane++) {
- seed_gross[lane] = (seed[lane] >> 5) & 0x1f;
- seed_fine[lane] = seed[lane] & 0x1f;
-
- /*if (seed_gross[lane] == 0)
- seed_pre_gross[lane] = 0;
- else */if (seed_gross[lane] & 0x1)
- seed_pre_gross[lane] = 1;
- else
- seed_pre_gross[lane] = 2;
-
- /* Calculate phase recovery delays */
- phase_recovery_delays[lane] = ((seed_pre_gross[lane] & 0x1f) << 5) | (seed_fine[lane] & 0x1f);
-
- /* Set the gross delay.
- * NOTE: While the BKDG states to only program DqsRcvEnGrossDelay, this appears
- * to have been a misprint as DqsRcvEnFineDelay should be set to zero as well.
- */
- current_total_delay[lane] = ((seed_gross[lane] & 0x1f) << 5);
- }
-
- /* 2.10.5.8.2 (2) / 2.10.5.8.2.1 (5 6)
- * Program PhRecFineDly and PhRecGrossDly
- */
- write_dram_phase_recovery_control_registers(phase_recovery_delays, dev, Channel, dimm, index_reg);
-
- /* 2.10.5.8.2 (2) / 2.10.5.8.2.1 (7)
- * Program the DQS Receiver Enable delay values for each lane
- */
- write_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
-
- /* 2.10.5.8.2 (3)
- * Program DqsRcvTrEn = 1
- */
- dword = Get_NB32_index_wait_DCT(dev, Channel, index_reg, 0x00000008);
- dword |= (0x1 << 13);
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, 0x00000008, dword);
-
- /* 2.10.5.8.2 (4)
- * Issue 192 read requests to the target rank
- */
- generate_dram_receiver_enable_training_pattern_fam15(pMCTstat, pDCTstat, Channel, Receiver + (rank & 0x1));
-
- /* 2.10.5.8.2 (5)
- * Program DqsRcvTrEn = 0
- */
- dword = Get_NB32_index_wait_DCT(dev, Channel, index_reg, 0x00000008);
- dword &= ~(0x1 << 13);
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, 0x00000008, dword);
-
- /* 2.10.5.8.2 (6)
- * Read PhRecGrossDly, PhRecFineDly
- */
- read_dram_phase_recovery_control_registers(phase_recovery_delays, dev, Channel, dimm, index_reg);
-
- /* 2.10.5.8.2 (7)
- * Calculate and program the DQS Receiver Enable delay values
- */
- for (lane = 0; lane < lane_count; lane++) {
- current_total_delay[lane] = (phase_recovery_delays[lane] & 0x1f);
- current_total_delay[lane] |= ((seed_gross[lane] + ((phase_recovery_delays[lane] >> 5) & 0x1f) - seed_pre_gross[lane] + 1) << 5);
- if (nibble == 1) {
- /* 2.10.5.8.2 (1)
- * Average the trained values of both nibbles on x4 DIMMs
- */
- current_total_delay[lane] = (nibble0_current_total_delay[lane] + current_total_delay[lane]) / 2;
- }
- }
-
-#if DQS_TRAIN_DEBUG > 1
- for (lane = 0; lane < 8; lane++)
- printk(BIOS_DEBUG, "\t\tTrainRcvEn55: Channel: %d dimm: %d nibble: %d lane %d current_total_delay: %04x CH_D_B_RCVRDLY: %04x\n",
- Channel, dimm, nibble, lane, current_total_delay[lane], pDCTstat->CH_D_B_RCVRDLY[Channel][dimm][lane]);
-#endif
- write_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
-
- if (nibble == 0) {
- /* Back up the Nibble 0 delays for later use */
- memcpy(nibble0_current_total_delay, current_total_delay, sizeof(current_total_delay));
- }
-
- /* Exit nibble training if current DIMM is not x4 */
- if ((pDCTstat->Dimmx4Present & (1 << (dimm + Channel))) == 0)
- break;
- }
-
- if (_2Ranks) {
- if (rank == 0) {
- /* Back up the Rank 0 delays for later use */
- memcpy(rank0_current_total_delay, current_total_delay, sizeof(current_total_delay));
- }
- if (rank == 1) {
- /* 2.10.5.8.2 (8)
- * Compute the average delay across both ranks and program the result into
- * the DQS Receiver Enable delay registers
- */
- for (lane = 0; lane < lane_count; lane++) {
- current_total_delay[lane] = (rank0_current_total_delay[lane] + current_total_delay[lane]) / 2;
- if (lane == 8)
- pDCTstat->CH_D_BC_RCVRDLY[Channel][dimm] = current_total_delay[lane];
- else
- pDCTstat->CH_D_B_RCVRDLY[Channel][dimm][lane] = current_total_delay[lane];
- }
- write_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
- }
- } else {
- /* Save the current delay for later use by other routines */
- for (lane = 0; lane < lane_count; lane++) {
- if (lane == 8)
- pDCTstat->CH_D_BC_RCVRDLY[Channel][dimm] = current_total_delay[lane];
- else
- pDCTstat->CH_D_B_RCVRDLY[Channel][dimm][lane] = current_total_delay[lane];
- }
- }
- }
-
-#if DQS_TRAIN_DEBUG > 0
- for (lane = 0; lane < 8; lane++)
- print_debug_dqs_pair("\t\tTrainRcvEn56: Lane ", lane, " current_total_delay ", current_total_delay[lane], 2);
-#endif
- }
- }
-
- /* Calculate and program MaxRdLatency for both channels */
- Calc_SetMaxRdLatency_D_Fam15(pMCTstat, pDCTstat, 0, 0);
- Calc_SetMaxRdLatency_D_Fam15(pMCTstat, pDCTstat, 1, 0);
-
- if (_DisableDramECC) {
- mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
- }
-
- if (Pass == FirstPass) {
- /*Disable DQSRcvrEn training mode */
- mct_DisableDQSRcvEn_D(pDCTstat);
- }
-
- if (!_Wrap32Dis) {
- msr = HWCR_MSR;
- _RDMSR(msr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(msr, lo, hi);
- }
- if (!_SSE2) {
- cr4 = read_cr4();
- cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
- write_cr4(cr4);
- }
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 ChannelDTD;
- printk(BIOS_DEBUG, "TrainRcvrEn: CH_MaxRdLat:\n");
- for (ChannelDTD = 0; ChannelDTD < 2; ChannelDTD++) {
- printk(BIOS_DEBUG, "Channel:%x: %x\n",
- ChannelDTD, pDCTstat->CH_MaxRdLat[ChannelDTD][0]);
- }
- }
-#endif
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u16 valDTD;
- u8 ChannelDTD, ReceiverDTD;
- u8 i;
- u16 *p;
-
- printk(BIOS_DEBUG, "TrainRcvrEn: CH_D_B_RCVRDLY:\n");
- for (ChannelDTD = 0; ChannelDTD < 2; ChannelDTD++) {
- printk(BIOS_DEBUG, "Channel:%x\n", ChannelDTD);
- for (ReceiverDTD = 0; ReceiverDTD < 8; ReceiverDTD+=2) {
- printk(BIOS_DEBUG, "\t\tReceiver:%x:", ReceiverDTD);
- p = pDCTstat->CH_D_B_RCVRDLY[ChannelDTD][ReceiverDTD>>1];
- for (i = 0; i < 8; i++) {
- valDTD = p[i];
- printk(BIOS_DEBUG, " %03x", valDTD);
- }
- printk(BIOS_DEBUG, "\n");
- }
- }
- }
-#endif
-
- printk(BIOS_DEBUG, "TrainRcvrEn: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "TrainRcvrEn: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "TrainRcvrEn: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "TrainRcvrEn: Done\n\n");
-}
-
-static void write_max_read_latency_to_registers(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct, uint16_t *latency)
-{
- uint32_t dword;
- uint8_t nb_pstate;
-
- for (nb_pstate = 0; nb_pstate < 2; nb_pstate++) {
- dword = Get_NB32_DCT_NBPstate(pDCTstat->dev_dct, dct, nb_pstate, 0x210);
- dword &= ~(0x3ff << 22);
- dword |= ((latency[nb_pstate] & 0x3ff) << 22);
- Set_NB32_DCT_NBPstate(pDCTstat->dev_dct, dct, nb_pstate, 0x210, dword);
- }
-}
-
-/* DQS MaxRdLatency Training (Family 15h)
- * Algorithm detailed in:
- * The Fam15h BKDG Rev. 3.14 section 2.10.5.8.5.1
- * This algorithm runs at the highest supported MEMCLK.
- */
-void dqsTrainMaxRdLatency_SW_Fam15(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 Channel;
- u8 Receiver;
- u8 _DisableDramECC = 0, _Wrap32Dis = 0, _SSE2 = 0;
- u32 Errors;
-
- u32 dev;
- u32 index_reg;
- u32 ch_start, ch_end;
- u32 msr;
- CRx_TYPE cr4;
- u32 lo, hi;
-
- uint32_t dword;
- uint8_t dimm;
- uint8_t lane;
- uint8_t mem_clk;
- uint32_t nb_clk;
- uint8_t nb_pstate;
- uint16_t current_total_delay[MAX_BYTE_LANES];
- uint16_t current_rdqs_total_delay[MAX_BYTE_LANES];
- uint8_t current_worst_case_total_delay_dimm;
- uint16_t current_worst_case_total_delay_value;
-
- uint8_t lane_count;
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- uint16_t fam15h_freq_tab[] = {0, 0, 0, 0, 333, 0, 400, 0, 0, 0, 533, 0, 0, 0, 667, 0, 0, 0, 800, 0, 0, 0, 933};
-
- print_debug_dqs("\nTrainMaxRdLatency: Node", pDCTstat->Node_ID, 0);
-
- dev = pDCTstat->dev_dct;
- index_reg = 0x98;
- ch_start = 0;
- ch_end = 2;
-
- cr4 = read_cr4();
- if (cr4 & (1 << 9)) { /* save the old value */
- _SSE2 = 1;
- }
- cr4 |= (1 << 9); /* OSFXSR enable SSE2 */
- write_cr4(cr4);
-
- msr = HWCR_MSR;
- _RDMSR(msr, &lo, &hi);
- /* FIXME: Why use SSEDIS */
- if (lo & (1 << 17)) { /* save the old value */
- _Wrap32Dis = 1;
- }
- lo |= (1 << 17); /* HWCR.wrap32dis */
- lo &= ~(1 << 15); /* SSEDIS */
- _WRMSR(msr, lo, hi); /* Setting wrap32dis allows 64-bit memory references in real mode */
-
- _DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
-
- Errors = 0;
- dev = pDCTstat->dev_dct;
-
- for (Channel = 0; Channel < 2; Channel++) {
- print_debug_dqs("\tTrainMaxRdLatency51: Node ", pDCTstat->Node_ID, 1);
- print_debug_dqs("\tTrainMaxRdLatency51: Channel ", Channel, 1);
- pDCTstat->Channel = Channel;
-
- if (pDCTstat->DIMMValidDCT[Channel] == 0)
- continue;
-
- mem_clk = Get_NB32_DCT(dev, Channel, 0x94) & 0x1f;
-
- Receiver = mct_InitReceiver_D(pDCTstat, Channel);
-
- /* Find DIMM with worst case receiver enable delays */
- current_worst_case_total_delay_dimm = 0;
- current_worst_case_total_delay_value = 0;
-
- /* There are four receiver pairs, loosely associated with chipselects.
- * This is essentially looping over each DIMM.
- */
- for (; Receiver < 8; Receiver += 2) {
- dimm = (Receiver >> 1);
-
- print_debug_dqs("\t\tTrainMaxRdLatency52: Receiver ", Receiver, 2);
-
- if (!mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, Receiver)) {
- continue;
- }
-
- /* Retrieve the total delay values from pass 1 of DQS receiver enable training */
- read_dqs_receiver_enable_control_registers(current_total_delay, dev, Channel, dimm, index_reg);
- read_dqs_read_data_timing_registers(current_rdqs_total_delay, dev, Channel, dimm, index_reg);
-
- for (lane = 0; lane < lane_count; lane++) {
- current_total_delay[lane] += current_rdqs_total_delay[lane];
- if (current_total_delay[lane] > current_worst_case_total_delay_value) {
- current_worst_case_total_delay_dimm = dimm;
- current_worst_case_total_delay_value = current_total_delay[lane];
- }
- }
-
-#if DQS_TRAIN_DEBUG > 0
- for (lane = 0; lane < lane_count; lane++)
- print_debug_dqs_pair("\t\tTrainMaxRdLatency56: Lane ", lane, " current_total_delay ", current_total_delay[lane], 2);
-#endif
- }
-
- /* 2.10.5.8.5.1.1 */
- Calc_SetMaxRdLatency_D_Fam15(pMCTstat, pDCTstat, Channel, 1);
-
- /* 2.10.5.8.5.1.[2,3]
- * Write the DRAM training pattern to the test address
- */
- write_dram_dqs_training_pattern_fam15(pMCTstat, pDCTstat, Channel, current_worst_case_total_delay_dimm << 1, 0xff, 0);
-
- /* 2.10.5.8.5.1.4
- * Incrementally test each MaxRdLatency candidate
- */
- for (; pDCTstat->CH_MaxRdLat[Channel][0] < 0x3ff; pDCTstat->CH_MaxRdLat[Channel][0]++) {
- write_max_read_latency_to_registers(pMCTstat, pDCTstat, Channel, pDCTstat->CH_MaxRdLat[Channel]);
- read_dram_dqs_training_pattern_fam15(pMCTstat, pDCTstat, Channel, current_worst_case_total_delay_dimm << 1, 0xff, 0);
- dword = Get_NB32_DCT(dev, Channel, 0x268) & 0x3ffff;
- if (!dword)
- break;
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, 0x00000050, 0x13131313);
- }
- dword = Get_NB32_DCT(dev, Channel, 0x268) & 0x3ffff;
- if (dword)
- printk(BIOS_ERR, "WARNING: MaxRdLatency training FAILED! Attempting to continue but your system may be unstable...\n");
-
- /* 2.10.5.8.5.1.5 */
- nb_pstate = 0;
- mem_clk = Get_NB32_DCT(dev, Channel, 0x94) & 0x1f;
- if (fam15h_freq_tab[mem_clk] == 0) {
- return;
- }
- dword = Get_NB32(pDCTstat->dev_nbctl, (0x160 + (nb_pstate * 4))); /* Retrieve NbDid, NbFid */
- nb_clk = (200 * (((dword >> 1) & 0x1f) + 0x4)) / (((dword >> 7) & 0x1)?2:1);
-
- pDCTstat->CH_MaxRdLat[Channel][0]++;
- pDCTstat->CH_MaxRdLat[Channel][0] += ((((uint64_t)15 * 100000000000ULL) / ((uint64_t)fam15h_freq_tab[mem_clk] * 1000000ULL))
- * ((uint64_t)nb_clk * 1000)) / 1000000000ULL;
-
- write_max_read_latency_to_registers(pMCTstat, pDCTstat, Channel, pDCTstat->CH_MaxRdLat[Channel]);
- }
-
- if (_DisableDramECC) {
- mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
- }
-
- if (!_Wrap32Dis) {
- msr = HWCR_MSR;
- _RDMSR(msr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(msr, lo, hi);
- }
- if (!_SSE2) {
- cr4 = read_cr4();
- cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
- write_cr4(cr4);
- }
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 ChannelDTD;
- printk(BIOS_DEBUG, "TrainMaxRdLatency: CH_MaxRdLat:\n");
- for (ChannelDTD = 0; ChannelDTD < 2; ChannelDTD++) {
- printk(BIOS_DEBUG, "Channel:%x: %x\n",
- ChannelDTD, pDCTstat->CH_MaxRdLat[ChannelDTD][0]);
- }
- }
-#endif
-
- printk(BIOS_DEBUG, "TrainMaxRdLatency: Status %x\n", pDCTstat->Status);
- printk(BIOS_DEBUG, "TrainMaxRdLatency: ErrStatus %x\n", pDCTstat->ErrStatus);
- printk(BIOS_DEBUG, "TrainMaxRdLatency: ErrCode %x\n", pDCTstat->ErrCode);
- printk(BIOS_DEBUG, "TrainMaxRdLatency: Done\n\n");
-}
-
-u8 mct_InitReceiver_D(struct DCTStatStruc *pDCTstat, u8 dct)
-{
- if (pDCTstat->DIMMValidDCT[dct] == 0) {
- return 8;
- } else {
- return 0;
- }
-}
-
-static void mct_DisableDQSRcvEn_D(struct DCTStatStruc *pDCTstat)
-{
- u8 ch_end, ch;
- u32 reg;
- u32 dev;
- u32 val;
-
- dev = pDCTstat->dev_dct;
- if (pDCTstat->GangedMode) {
- ch_end = 1;
- } else {
- ch_end = 2;
- }
-
- for (ch = 0; ch < ch_end; ch++) {
- reg = 0x78;
- val = Get_NB32_DCT(dev, ch, reg);
- val &= ~(1 << DqsRcvEnTrain);
- Set_NB32_DCT(dev, ch, reg, val);
- }
-}
-
-/* mct_ModifyIndex_D
- * Function only used once so it was inlined.
- */
-
-/* mct_GetInitFlag_D
- * Function only used once so it was inlined.
- */
-
-/* Set F2x[1, 0]9C_x[2B:10] DRAM DQS Receiver Enable Timing Control Registers
- * See BKDG Rev. 3.62 page 268 for more information
- */
-void mct_SetRcvrEnDly_D(struct DCTStatStruc *pDCTstat, u16 RcvrEnDly,
- u8 FinalValue, u8 Channel, u8 Receiver, u32 dev,
- u32 index_reg, u8 Addl_Index, u8 Pass)
-{
- u32 index;
- u8 i;
- u16 *p;
- u32 val;
-
- if (RcvrEnDly == 0x1fe) {
- /*set the boundary flag */
- pDCTstat->Status |= 1 << SB_DQSRcvLimit;
- }
-
- /* DimmOffset not needed for CH_D_B_RCVRDLY array */
- for (i = 0; i < 8; i++) {
- if (FinalValue) {
- /*calculate dimm offset */
- p = pDCTstat->CH_D_B_RCVRDLY[Channel][Receiver >> 1];
- RcvrEnDly = p[i];
- }
-
- /* if flag = 0, set DqsRcvEn value to reg. */
- /* get the register index from table */
- index = Table_DQSRcvEn_Offset[i >> 1];
- index += Addl_Index; /* DIMMx DqsRcvEn byte0 */
- val = Get_NB32_index_wait_DCT(dev, Channel, index_reg, index);
- if (i & 1) {
- /* odd byte lane */
- val &= ~(0x1ff << 16);
- val |= ((RcvrEnDly & 0x1ff) << 16);
- } else {
- /* even byte lane */
- val &= ~0x1ff;
- val |= (RcvrEnDly & 0x1ff);
- }
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, index, val);
- }
-
-}
-
-/* Calculate MaxRdLatency
- * Algorithm detailed in the Fam10h BKDG Rev. 3.62 section 2.8.9.9.5
- */
-static void mct_SetMaxLatency_D(struct DCTStatStruc *pDCTstat, u8 Channel, u16 DQSRcvEnDly)
-{
- u32 dev;
- u32 reg;
- u32 SubTotal;
- u32 index_reg;
- u32 val;
-
- uint8_t cpu_val_n;
- uint8_t cpu_val_p;
-
- u16 freq_tab[] = {400, 533, 667, 800};
-
- /* Set up processor-dependent values */
- if (pDCTstat->LogicalCPUID & AMD_DR_Dx) {
- /* Revision D and above */
- cpu_val_n = 4;
- cpu_val_p = 29;
- } else if (pDCTstat->LogicalCPUID & AMD_DR_Cx) {
- /* Revision C */
- uint8_t package_type = mctGet_NVbits(NV_PACK_TYPE);
- if ((package_type == PT_L1) /* Socket F (1207) */
- || (package_type == PT_M2) /* Socket AM3 */
- || (package_type == PT_S1)) { /* Socket S1g <x> */
- cpu_val_n = 10;
- cpu_val_p = 11;
- } else {
- cpu_val_n = 4;
- cpu_val_p = 29;
- }
- } else {
- /* Revision B and below */
- cpu_val_n = 10;
- cpu_val_p = 11;
- }
-
- if (pDCTstat->GangedMode)
- Channel = 0;
-
- dev = pDCTstat->dev_dct;
- index_reg = 0x98;
-
- /* Multiply the CAS Latency by two to get a number of 1/2 MEMCLKs units.*/
- val = Get_NB32_DCT(dev, Channel, 0x88);
- SubTotal = ((val & 0x0f) + 4) << 1; /* SubTotal is 1/2 Memclk unit */
-
- /* If registered DIMMs are being used then
- * add 1 MEMCLK to the sub-total.
- */
- val = Get_NB32_DCT(dev, Channel, 0x90);
- if (!(val & (1 << UnBuffDimm)))
- SubTotal += 2;
-
- /* If the address prelaunch is setup for 1/2 MEMCLKs then
- * add 1, else add 2 to the sub-total.
- * if (AddrCmdSetup || CsOdtSetup || CkeSetup) then K := K + 2;
- */
- val = Get_NB32_index_wait_DCT(dev, Channel, index_reg, 0x04);
- if (!(val & 0x00202020))
- SubTotal += 1;
- else
- SubTotal += 2;
-
- /* If the F2x[1, 0]78[RdPtrInit] field is 4, 5, 6 or 7 MEMCLKs,
- * then add 4, 3, 2, or 1 MEMCLKs, respectively to the sub-total. */
- val = Get_NB32_DCT(dev, Channel, 0x78);
- SubTotal += 8 - (val & 0x0f);
-
- /* Convert bits 7-5 (also referred to as the coarse delay) of
- * the current (or worst case) DQS receiver enable delay to
- * 1/2 MEMCLKs units, rounding up, and add this to the sub-total.
- */
- SubTotal += DQSRcvEnDly >> 5; /* Retrieve gross delay portion of value */
-
- /* Add "P" to the sub-total. "P" represents part of the
- * processor specific constant delay value in the DRAM
- * clock domain.
- */
- SubTotal <<= 1; /*scale 1/2 MemClk to 1/4 MemClk */
- SubTotal += cpu_val_p; /*add "P" 1/2MemClk */
- SubTotal >>= 1; /*scale 1/4 MemClk back to 1/2 MemClk */
-
- /* Convert the sub-total (in 1/2 MEMCLKs) to northbridge
- * clocks (NCLKs)
- */
- SubTotal *= 200 * ((Get_NB32(pDCTstat->dev_nbmisc, 0xd4) & 0x1f) + 4);
- SubTotal /= freq_tab[((Get_NB32_DCT(pDCTstat->dev_dct, Channel, 0x94) & 0x7) - 3)];
- SubTotal = (SubTotal + (2 - 1)) / 2; /* Round up */
-
- /* Add "N" NCLKs to the sub-total. "N" represents part of the
- * processor specific constant value in the northbridge
- * clock domain.
- */
- SubTotal += (cpu_val_n) / 2;
-
- pDCTstat->CH_MaxRdLat[Channel][0] = SubTotal;
- if (pDCTstat->GangedMode) {
- pDCTstat->CH_MaxRdLat[1][0] = SubTotal;
- }
-
- /* Program the F2x[1, 0]78[MaxRdLatency] register with
- * the total delay value (in NCLKs).
- */
- reg = 0x78;
- val = Get_NB32_DCT(dev, Channel, reg);
- val &= ~(0x3ff << 22);
- val |= (SubTotal & 0x3ff) << 22;
-
- /* program MaxRdLatency to correspond with current delay */
- Set_NB32_DCT(dev, Channel, reg, val);
-}
-
-static void mct_InitDQSPos4RcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- /* Initialize the DQS Positions in preparation for
- * Receiver Enable Training.
- * Write Position is 1/2 Memclock Delay
- * Read Position is 1/2 Memclock Delay
- */
- u8 i;
- for (i = 0; i < 2; i++) {
- InitDQSPos4RcvrEn_D(pMCTstat, pDCTstat, i);
- }
-}
-
-static void InitDQSPos4RcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel)
-{
- /* Initialize the DQS Positions in preparation for
- * Receiver Enable Training.
- * Write Position is no Delay
- * Read Position is 1/2 Memclock Delay
- */
-
- u8 i, j;
- u32 dword;
- u8 dn = 4; /* TODO: Rev C could be 4 */
- u32 dev = pDCTstat->dev_dct;
- u32 index_reg = 0x98;
-
- /* FIXME: add Cx support */
- dword = 0x00000000;
- for (i = 1; i <= 3; i++) {
- for (j = 0; j < dn; j++)
- /* DIMM0 Write Data Timing Low */
- /* DIMM0 Write ECC Timing */
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, i + 0x100 * j, dword);
- }
-
- /* errata #180 */
- dword = 0x2f2f2f2f;
- for (i = 5; i <= 6; i++) {
- for (j = 0; j < dn; j++)
- /* DIMM0 Read DQS Timing Control Low */
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, i + 0x100 * j, dword);
- }
-
- dword = 0x0000002f;
- for (j = 0; j < dn; j++)
- /* DIMM0 Read DQS ECC Timing Control */
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, 7 + 0x100 * j, dword);
-}
-
-void SetEccDQSRcvrEn_D(struct DCTStatStruc *pDCTstat, u8 Channel)
-{
- u32 dev;
- u32 index_reg;
- u32 index;
- u8 ChipSel;
- u16 *p;
- u32 val;
-
- dev = pDCTstat->dev_dct;
- index_reg = 0x98;
- index = 0x12;
- p = pDCTstat->CH_D_BC_RCVRDLY[Channel];
- print_debug_dqs("\t\tSetEccDQSRcvrPos: Channel ", Channel, 2);
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel += 2) {
- val = p[ChipSel>>1];
- Set_NB32_index_wait_DCT(dev, Channel, index_reg, index, val);
- print_debug_dqs_pair("\t\tSetEccDQSRcvrPos: ChipSel ",
- ChipSel, " rcvr_delay ", val, 2);
- index += 3;
- }
-}
-
-static void CalcEccDQSRcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel)
-{
- u8 ChipSel;
- u16 EccDQSLike;
- u8 EccDQSScale;
- u32 val, val0, val1;
- int16_t delay_differential;
-
- EccDQSLike = pDCTstat->CH_EccDQSLike[Channel];
- EccDQSScale = pDCTstat->CH_EccDQSScale[Channel];
-
- for (ChipSel = 0; ChipSel < MAX_CS_SUPPORTED; ChipSel += 2) {
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel, ChipSel)) {
- u16 *p;
- p = pDCTstat->CH_D_B_RCVRDLY[Channel][ChipSel>>1];
-
- if (pDCTstat->Status & (1 << SB_Registered)) {
- val0 = p[0x2];
- val1 = p[0x3];
-
- delay_differential = (int16_t)val1 - (int16_t)val0;
- delay_differential += (int16_t)val1;
-
- val = delay_differential;
- } else {
- /* DQS Delay Value of Data Bytelane
- * most like ECC byte lane */
- val0 = p[EccDQSLike & 0x07];
- /* DQS Delay Value of Data Bytelane
- * 2nd most like ECC byte lane */
- val1 = p[(EccDQSLike>>8) & 0x07];
-
- if (val0 > val1) {
- val = val0 - val1;
- } else {
- val = val1 - val0;
- }
-
- val *= ~EccDQSScale;
- val >>= 8; /* /256 */
-
- if (val0 > val1) {
- val -= val1;
- } else {
- val += val0;
- }
- }
-
- pDCTstat->CH_D_BC_RCVRDLY[Channel][ChipSel>>1] = val;
- }
- }
- SetEccDQSRcvrEn_D(pDCTstat, Channel);
-}
-
-/* 2.8.9.9.4
- * ECC Byte Lane Training
- * DQS Receiver Enable Delay
- */
-void mctSetEccDQSRcvrEn_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
- u8 i;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
- if (!pDCTstat->NodePresent)
- break;
- if (pDCTstat->DCTSysLimit) {
- for (i = 0; i < 2; i++)
- CalcEccDQSRcvrEn_D(pMCTstat, pDCTstat, i);
- }
- }
-}
-
-void phyAssistedMemFnceTraining(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA, int16_t single_node_number)
-{
- u8 Node = 0;
- struct DCTStatStruc *pDCTstat;
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- uint8_t start_node = 0;
- uint8_t end_node = MAX_NODES_SUPPORTED;
-
- if (single_node_number >= 0) {
- start_node = single_node_number;
- end_node = single_node_number + 1;
- }
-
- /* FIXME: skip for Ax */
- for (Node = start_node; Node < end_node; Node++) {
- pDCTstat = pDCTstatA + Node;
- if (!pDCTstat->NodePresent)
- continue;
-
- if (pDCTstat->DCTSysLimit) {
- if (is_fam15h()) {
- /* Fam15h BKDG v3.14 section 2.10.5.3.3
- * This picks up where InitDDRPhy left off
- */
- uint8_t dct;
- uint8_t index;
- uint32_t dword;
- uint32_t datc_backup;
- uint32_t training_dword;
- uint32_t fence2_config_dword;
- uint32_t fence_tx_pad_config_dword;
- uint32_t index_reg = 0x98;
- uint32_t dev = pDCTstat->dev_dct;
-
- for (dct = 0; dct < 2; dct++) {
- if (!pDCTstat->DIMMValidDCT[dct])
- continue;
-
- printk(BIOS_SPEW, "%s: training node %d DCT %d\n", __func__, Node, dct);
-
- /* Back up D18F2x9C_x0000_0004_dct[1:0] */
- datc_backup = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000004);
-
- /* FenceTrSel = 0x2 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000008);
- dword &= ~(0x3 << 6);
- dword |= (0x2 << 6);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000008, dword);
-
- /* Set phase recovery seed values */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000050, 0x13131313);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000051, 0x13131313);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000052, 0x00000013);
-
- training_dword = fenceDynTraining_D(pMCTstat, pDCTstat, dct);
-
- /* Save calculated fence value to the TX DLL */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c);
- dword &= ~(0x1f << 26);
- dword |= ((training_dword & 0x1f) << 26);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c, dword);
-
- /* D18F2x9C_x0D0F_0[F,8:0]0F_dct[1:0][AlwaysEnDllClks]=0x1 */
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f000f | (index << 8));
- dword &= ~(0x7 << 12);
- dword |= (0x1 << 12);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f000f | (index << 8), dword);
- }
-
- /* FenceTrSel = 0x1 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000008);
- dword &= ~(0x3 << 6);
- dword |= (0x1 << 6);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000008, dword);
-
- /* Set phase recovery seed values */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000050, 0x13131313);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000051, 0x13131313);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000052, 0x00000013);
-
- training_dword = fenceDynTraining_D(pMCTstat, pDCTstat, dct);
-
- /* Save calculated fence value to the RX DLL */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c);
- dword &= ~(0x1f << 21);
- dword |= ((training_dword & 0x1f) << 21);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c, dword);
-
- /* D18F2x9C_x0D0F_0[F,8:0]0F_dct[1:0][AlwaysEnDllClks]=0x0 */
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f000f | (index << 8));
- dword &= ~(0x7 << 12);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f000f | (index << 8), dword);
- }
-
- /* FenceTrSel = 0x3 */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000008);
- dword &= ~(0x3 << 6);
- dword |= (0x3 << 6);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000008, dword);
-
- /* Set phase recovery seed values */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000050, 0x13131313);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000051, 0x13131313);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000052, 0x00000013);
-
- fence_tx_pad_config_dword = fenceDynTraining_D(pMCTstat, pDCTstat, dct);
-
- /* Save calculated fence value to the TX Pad */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c);
- dword &= ~(0x1f << 16);
- dword |= ((fence_tx_pad_config_dword & 0x1f) << 16);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c, dword);
-
- /* Program D18F2x9C_x0D0F_[C,8,2][2:0]31_dct[1:0] */
- training_dword = fence_tx_pad_config_dword;
- if (fence_tx_pad_config_dword < 16)
- training_dword |= (0x1 << 4);
- else
- training_dword = 0;
- for (index = 0; index < 0x3; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f2031 | (index << 8));
- dword &= ~(0x1f);
- dword |= (training_dword & 0x1f);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f2031 | (index << 8), dword);
- }
- for (index = 0; index < 0x3; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8031 | (index << 8));
- dword &= ~(0x1f);
- dword |= (training_dword & 0x1f);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f8031 | (index << 8), dword);
- }
- for (index = 0; index < 0x3; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc031 | (index << 8));
- dword &= ~(0x1f);
- dword |= (training_dword & 0x1f);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0fc031 | (index << 8), dword);
- }
-
- /* Assemble Fence2 configuration word (Fam15h BKDG v3.14 page 331) */
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0000000c);
- fence2_config_dword = 0;
-
- /* TxPad */
- training_dword = (dword >> 16) & 0x1f;
- if (training_dword < 16)
- training_dword |= 0x10;
- else
- training_dword = 0;
- fence2_config_dword |= training_dword;
-
- /* RxDll */
- training_dword = (dword >> 21) & 0x1f;
- if (training_dword < 16)
- training_dword |= 0x10;
- else
- training_dword = 0;
- fence2_config_dword |= (training_dword << 10);
-
- /* TxDll */
- training_dword = (dword >> 26) & 0x1f;
- if (training_dword < 16)
- training_dword |= 0x10;
- else
- training_dword = 0;
- fence2_config_dword |= (training_dword << 5);
-
- /* Program D18F2x9C_x0D0F_0[F,8:0]31_dct[1:0] */
- for (index = 0; index < 0x9; index++) {
- dword = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0031 | (index << 8));
- dword &= ~(0x7fff);
- dword |= fence2_config_dword;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0d0f0031 | (index << 8), dword);
- }
-
- /* Restore D18F2x9C_x0000_0004_dct[1:0] */
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x00000004, datc_backup);
-
- printk(BIOS_SPEW, "%s: done training node %d DCT %d\n", __func__, Node, dct);
- }
- } else {
- fenceDynTraining_D(pMCTstat, pDCTstat, 0);
- fenceDynTraining_D(pMCTstat, pDCTstat, 1);
- }
- }
- }
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-uint32_t fenceDynTraining_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, uint8_t dct)
-{
- u16 avRecValue;
- u32 val;
- u32 dev;
- u32 index_reg = 0x98;
- u32 index;
-
- dev = pDCTstat->dev_dct;
-
- if (is_fam15h()) {
- /* Set F2x[1,0]9C_x08[PhyFenceTrEn] */
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x08);
- val |= 1 << PhyFenceTrEn;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x08, val);
-
- /* Wait 2000 MEMCLKs */
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 2000);
-
- /* Clear F2x[1,0]9C_x08[PhyFenceTrEn] */
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x08);
- val &= ~(1 << PhyFenceTrEn);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x08, val);
-
- /* BIOS reads the phase recovery engine registers
- * F2x[1,0]9C_x[51:50] and F2x[1,0]9C_x52.
- * Average the fine delay components only.
- */
- avRecValue = 0;
- for (index = 0x50; index <= 0x52; index++) {
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, index);
- avRecValue += val & 0x1f;
- if (index != 0x52) {
- avRecValue += (val >> 8) & 0x1f;
- avRecValue += (val >> 16) & 0x1f;
- avRecValue += (val >> 24) & 0x1f;
- }
- }
-
- val = avRecValue / 9;
- if (avRecValue % 9)
- val++;
- avRecValue = val;
-
- if (avRecValue < 6)
- avRecValue = 0;
- else
- avRecValue -= 6;
-
- return avRecValue;
- } else {
- /* BIOS first programs a seed value to the phase recovery engine
- * (recommended 19) registers.
- * Dram Phase Recovery Control Register (F2x[1,0]9C_x[51:50] and
- * F2x[1,0]9C_x52.) .
- */
- for (index = 0x50; index <= 0x52; index ++) {
- val = (FenceTrnFinDlySeed & 0x1F);
- if (index != 0x52) {
- val |= val << 8 | val << 16 | val << 24;
- }
- Set_NB32_index_wait_DCT(dev, dct, index_reg, index, val);
- }
-
- /* Set F2x[1,0]9C_x08[PhyFenceTrEn]=1. */
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x08);
- val |= 1 << PhyFenceTrEn;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x08, val);
-
- /* Wait 200 MEMCLKs. */
- mct_Wait(50000); /* wait 200us */
-
- /* Clear F2x[1,0]9C_x08[PhyFenceTrEn]=0. */
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x08);
- val &= ~(1 << PhyFenceTrEn);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x08, val);
-
- /* BIOS reads the phase recovery engine registers
- * F2x[1,0]9C_x[51:50] and F2x[1,0]9C_x52. */
- avRecValue = 0;
- for (index = 0x50; index <= 0x52; index ++) {
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, index);
- avRecValue += val & 0x7F;
- if (index != 0x52) {
- avRecValue += (val >> 8) & 0x7F;
- avRecValue += (val >> 16) & 0x7F;
- avRecValue += (val >> 24) & 0x7F;
- }
- }
-
- val = avRecValue / 9;
- if (avRecValue % 9)
- val++;
- avRecValue = val;
-
- /* Write the (averaged value -8) to F2x[1,0]9C_x0C[PhyFence]. */
- /* inlined mct_AdjustFenceValue() */
- /* TODO: The RBC0 is not supported. */
- /* if (pDCTstat->LogicalCPUID & AMD_RB_C0)
- avRecValue -= 3;
- else
- */
- if (pDCTstat->LogicalCPUID & AMD_DR_Dx)
- avRecValue -= 8;
- else if (pDCTstat->LogicalCPUID & AMD_DR_Cx)
- avRecValue -= 8;
- else if (pDCTstat->LogicalCPUID & AMD_DR_Bx)
- avRecValue -= 8;
-
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x0C);
- val &= ~(0x1F << 16);
- val |= (avRecValue & 0x1F) << 16;
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x0C, val);
-
- /* Rewrite F2x[1,0]9C_x04-DRAM Address/Command Timing Control Register
- * delays (both channels).
- */
- val = Get_NB32_index_wait_DCT(dev, dct, index_reg, 0x04);
- Set_NB32_index_wait_DCT(dev, dct, index_reg, 0x04, val);
-
- return avRecValue;
- }
-}
-
-void mct_Wait(u32 cycles)
-{
- u32 saved;
- u32 hi, lo, msr;
-
- /* Wait # of 50ns cycles
- This seems like a hack to me... */
-
- cycles <<= 3; /* x8 (number of 1.25ns ticks) */
-
- msr = TSC_MSR; /* TSC */
- _RDMSR(msr, &lo, &hi);
- saved = lo;
- do {
- _RDMSR(msr, &lo, &hi);
- } while (lo - saved < cycles);
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctsrc1p.c b/src/northbridge/amd/amdmct/mct_ddr3/mctsrc1p.c
deleted file mode 100644
index 98aadddc6c..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctsrc1p.c
+++ /dev/null
@@ -1,104 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/cpu.h>
-#include <stdint.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-u8 mct_checkNumberOfDqsRcvEn_1Pass(u8 pass)
-{
- u8 ret = 1;
-
- if (is_fam15h()) {
- /* Fam15h needs two passes */
- ret = 1;
- } else {
- if (pass == SecondPass)
- ret = 0;
- }
-
- return ret;
-}
-
-u32 SetupDqsPattern_1PassA(u8 pass)
-{
- return (u32) TestPattern1_D;
-}
-
-u32 SetupDqsPattern_1PassB(u8 pass)
-{
- return (u32) TestPattern0_D;
-}
-
-static u16 mct_Average_RcvrEnDly_1Pass(struct DCTStatStruc *pDCTstat, u8 Channel, u8 Receiver,
- u8 Pass)
-{
- u16 i, MaxValue;
- u16 *p;
- u16 val;
-
- MaxValue = 0;
- p = pDCTstat->CH_D_B_RCVRDLY[Channel][Receiver >> 1];
-
- for (i = 0; i < 8; i++) {
- /* get left value from DCTStatStruc.CHA_D0_B0_RCVRDLY*/
- val = p[i];
- /* get right value from DCTStatStruc.CHA_D0_B0_RCVRDLY_1*/
- val += Pass1MemClkDly;
- /* write back the value to stack */
- if (val > MaxValue)
- MaxValue = val;
-
- p[i] = val;
- }
- /* pDCTstat->DimmTrainFail &= ~(1<<Receiver+Channel); */
-
- return MaxValue;
-}
-
-u8 mct_SaveRcvEnDly_D_1Pass(struct DCTStatStruc *pDCTstat, u8 pass)
-{
- u8 ret;
- ret = 0;
- if ((pDCTstat->DqsRcvEn_Pass == 0xff) && (pass== FirstPass))
- ret = 2;
- return ret;
-}
-
-u16 mct_Average_RcvrEnDly_Pass(struct DCTStatStruc *pDCTstat,
- u16 RcvrEnDly, u16 RcvrEnDlyLimit,
- u8 Channel, u8 Receiver, u8 Pass)
-
-{
- return mct_Average_RcvrEnDly_1Pass(pDCTstat, Channel, Receiver, Pass);
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctsrc2p.c b/src/northbridge/amd/amdmct/mct_ddr3/mctsrc2p.c
deleted file mode 100644
index 8eeb93ff78..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctsrc2p.c
+++ /dev/null
@@ -1,126 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; either version 2 of the License, or
- * (at your option) any later version.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-u8 mct_checkNumberOfDqsRcvEn_Pass(u8 pass)
-{
- return 1;
-}
-
-u32 SetupDqsPattern_PassA(u8 Pass)
-{
- u32 ret;
- if (Pass == FirstPass)
- ret = (u32) TestPattern1_D;
- else
- ret = (u32) TestPattern2_D;
-
- return ret;
-}
-
-u32 SetupDqsPattern_PassB(u8 Pass)
-{
- u32 ret;
- if (Pass == FirstPass)
- ret = (u32) TestPattern0_D;
- else
- ret = (u32) TestPattern2_D;
-
- return ret;
-}
-
-u8 mct_Get_Start_RcvrEnDly_Pass(struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 Receiver,
- u8 Pass)
-{
- u8 RcvrEnDly;
-
- if (Pass == FirstPass)
- RcvrEnDly = 0;
- else {
- u8 max = 0;
- u8 val;
- u8 i;
- u8 *p = pDCTstat->persistentData.CH_D_B_RCVRDLY[Channel][Receiver>>1];
- u8 bn;
- bn = 8;
-
- for (i = 0; i < bn; i++) {
- val = p[i];
-
- if (val > max) {
- max = val;
- }
- }
- RcvrEnDly = max;
- }
-
- return RcvrEnDly;
-}
-
-u16 mct_Average_RcvrEnDly_Pass(struct DCTStatStruc *pDCTstat,
- u16 RcvrEnDly, u16 RcvrEnDlyLimit,
- u8 Channel, u8 Receiver, u8 Pass)
-{
- u8 i;
- u16 *p;
- u16 *p_1;
- u16 val;
- u16 val_1;
- u8 valid = 1;
- u8 bn;
-
- bn = 8;
-
- p = pDCTstat->persistentData.CH_D_B_RCVRDLY[Channel][Receiver>>1];
-
- if (Pass == SecondPass) { /* second pass must average values */
- /* FIXME: which byte? */
- p_1 = pDCTstat->B_RCVRDLY_1;
- /* p_1 = pDCTstat->persistentData.CH_D_B_RCVRDLY_1[Channel][Receiver>>1]; */
- for (i = 0; i < bn; i++) {
- val = p[i];
- /* left edge */
- if (val != (RcvrEnDlyLimit - 1)) {
- val -= Pass1MemClkDly;
- val_1 = p_1[i];
- val += val_1;
- val >>= 1;
- p[i] = val;
- } else {
- valid = 0;
- break;
- }
- }
- if (!valid) {
- pDCTstat->ErrStatus |= 1<<SB_NORCVREN;
- } else {
- pDCTstat->DimmTrainFail &= ~(1<<(Receiver + Channel));
- }
- } else {
- for (i = 0; i < bn; i++) {
- val = p[i];
- /* Add 1/2 Memlock delay */
- /* val += Pass1MemClkDly; */
- val += 0x5; /* NOTE: middle value with DQSRCVEN_SAVED_GOOD_TIMES */
- /* val += 0x02; */
- p[i] = val;
- pDCTstat->DimmTrainFail &= ~(1<<(Receiver + Channel));
- }
- }
-
- return RcvrEnDly;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mcttmrl.c b/src/northbridge/amd/amdmct/mct_ddr3/mcttmrl.c
deleted file mode 100644
index b6ab65e2f8..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mcttmrl.c
+++ /dev/null
@@ -1,398 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/*
- * Description: Max Read Latency Training feature for DDR 3 MCT
- */
-
-#include <stdint.h>
-#include <console/console.h>
-#include <cpu/amd/msr.h>
-#include <cpu/x86/cr.h>
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static u8 CompareMaxRdLatTestPattern_D(u32 pattern_buf, u32 addr);
-static u32 GetMaxRdLatTestAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel,
- u8 *MaxRcvrEnDly, u8 *valid);
-u8 mct_GetStartMaxRdLat_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 Channel,
- u8 DQSRcvEnDly, u32 *Margin);
-static void maxRdLatencyTrain_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-static void mct_setMaxRdLatTrnVal_D(struct DCTStatStruc *pDCTstat, u8 Channel,
- u16 MaxRdLatVal);
-
-/*Warning: These must be located so they do not cross a logical 16-bit
- segment boundary!*/
-static const u32 TestMaxRdLAtPattern_D[] = {
- 0x6E0E3FAC, 0x0C3CFF52,
- 0x4A688181, 0x49C5B613,
- 0x7C780BA6, 0x5C1650E3,
- 0x0C4F9D76, 0x0C6753E6,
- 0x205535A5, 0xBABFB6CA,
- 0x610E6E5F, 0x0C5F1C87,
- 0x488493CE, 0x14C9C383,
- 0xF5B9A5CD, 0x9CE8F615,
-
- 0xAAD714B5, 0xC38F1B4C,
- 0x72ED647C, 0x669F7562,
- 0x5233F802, 0x4A898B30,
- 0x10A40617, 0x3326B465,
- 0x55386E04, 0xC807E3D3,
- 0xAB49E193, 0x14B4E63A,
- 0x67DF2495, 0xEA517C45,
- 0x7624CE51, 0xF8140C51,
-
- 0x4824BD23, 0xB61DD0C9,
- 0x072BCFBE, 0xE8F3807D,
- 0x919EA373, 0x25E30C47,
- 0xFEB12958, 0x4DA80A5A,
- 0xE9A0DDF8, 0x792B0076,
- 0xE81C73DC, 0xF025B496,
- 0x1DB7E627, 0x808594FE,
- 0x82668268, 0x655C7783,
-};
-
-static u32 SetupMaxRdPattern(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u32 *buffer)
-{
- /* 1. Copy the alpha and Beta patterns from ROM to Cache,
- * aligning on 16 byte boundary
- * 2. Set the ptr to Cacheable copy in DCTStatstruc.PtrPatternBufA
- * for Alpha
- * 3. Set the ptr to Cacheable copy in DCTStatstruc.PtrPatternBufB
- * for Beta
- */
- u32 *buf;
- u8 i;
-
- buf = (u32 *)(((u32)buffer + 0x10) & (0xfffffff0));
-
- for (i = 0; i < (16 * 3); i++) {
- buf[i] = TestMaxRdLAtPattern_D[i];
- }
-
- return (u32)buf;
-}
-
-void TrainMaxReadLatency_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA)
-{
- u8 Node;
-
- for (Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- if (!pDCTstat->NodePresent)
- break;
-
- if (pDCTstat->DCTSysLimit)
- maxRdLatencyTrain_D(pMCTstat, pDCTstat);
- }
-}
-
-static void maxRdLatencyTrain_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 Channel;
- u32 TestAddr0;
- u8 _DisableDramECC = 0, _Wrap32Dis = 0, _SSE2 = 0;
- u16 MaxRdLatDly;
- u8 RcvrEnDly = 0;
- u32 PatternBuffer[60]; /* FIXME: why not 48 + 4 */
- u32 Margin;
- u32 addr;
- CRx_TYPE cr4;
- u32 lo, hi;
-
- u8 valid;
- u32 pattern_buf;
-
- cr4 = read_cr4();
- if (cr4 & (1<<9)) { /* save the old value */
- _SSE2 = 1;
- }
- cr4 |= (1<<9); /* OSFXSR enable SSE2 */
- write_cr4(cr4);
-
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- if (lo & (1<<17)) { /* save the old value */
- _Wrap32Dis = 1;
- }
- lo |= (1<<17); /* HWCR.wrap32dis */
- lo &= ~(1<<15); /* SSEDIS */
- /* Setting wrap32dis allows 64-bit memory references in
- real mode */
- _WRMSR(addr, lo, hi);
-
- _DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
-
- pattern_buf = SetupMaxRdPattern(pMCTstat, pDCTstat, PatternBuffer);
-
- for (Channel = 0; Channel < 2; Channel++) {
- print_debug_dqs("\tMaxRdLatencyTrain51: Channel ",Channel, 1);
- pDCTstat->Channel = Channel;
-
- if ((pDCTstat->Status & (1 << SB_128bitmode)) && Channel)
- break; /*if ganged mode, skip DCT 1 */
-
- TestAddr0 = GetMaxRdLatTestAddr_D(pMCTstat, pDCTstat, Channel, &RcvrEnDly, &valid);
- if (!valid) /* Address not supported on current CS */
- continue;
- /* rank 1 of DIMM, testpattern 0 */
- WriteMaxRdLat1CLTestPattern_D(pattern_buf, TestAddr0);
-
- MaxRdLatDly = mct_GetStartMaxRdLat_D(pMCTstat, pDCTstat, Channel, RcvrEnDly, &Margin);
- print_debug_dqs("\tMaxRdLatencyTrain52: MaxRdLatDly start ", MaxRdLatDly, 2);
- print_debug_dqs("\tMaxRdLatencyTrain52: MaxRdLatDly Margin ", Margin, 2);
- while (MaxRdLatDly < MAX_RD_LAT) { /* sweep Delay value here */
- mct_setMaxRdLatTrnVal_D(pDCTstat, Channel, MaxRdLatDly);
- ReadMaxRdLat1CLTestPattern_D(TestAddr0);
- if (CompareMaxRdLatTestPattern_D(pattern_buf, TestAddr0) == DQS_PASS)
- break;
- SetTargetWTIO_D(TestAddr0);
- FlushMaxRdLatTestPattern_D(TestAddr0);
- ResetTargetWTIO_D();
- MaxRdLatDly++;
- }
- print_debug_dqs("\tMaxRdLatencyTrain53: MaxRdLatDly end ", MaxRdLatDly, 2);
- mct_setMaxRdLatTrnVal_D(pDCTstat, Channel, MaxRdLatDly + Margin);
- }
-
- if (_DisableDramECC) {
- mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
- }
-
- if (!_Wrap32Dis) {
- addr = HWCR_MSR;
- _RDMSR(addr, &lo, &hi);
- lo &= ~(1<<17); /* restore HWCR.wrap32dis */
- _WRMSR(addr, lo, hi);
- }
- if (!_SSE2) {
- cr4 = read_cr4();
- cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
- write_cr4(cr4);
- }
-
-#if DQS_TRAIN_DEBUG > 0
- {
- u8 ChannelDTD;
- printk(BIOS_DEBUG, "maxRdLatencyTrain: CH_MaxRdLat:\n");
- for (ChannelDTD = 0; ChannelDTD < 2; ChannelDTD++) {
- printk(BIOS_DEBUG, "Channel: %02x: %02x\n", ChannelDTD, pDCTstat->CH_MaxRdLat[ChannelDTD][0]);
- }
- }
-#endif
-}
-
-static void mct_setMaxRdLatTrnVal_D(struct DCTStatStruc *pDCTstat,
- u8 Channel, u16 MaxRdLatVal)
-{
- u8 i;
- u32 reg;
- u32 dev;
- u32 val;
-
- if (pDCTstat->GangedMode) {
- Channel = 0; /* for safe */
- for (i = 0; i < 2; i++)
- pDCTstat->CH_MaxRdLat[i][0] = MaxRdLatVal;
- } else {
- pDCTstat->CH_MaxRdLat[Channel][0] = MaxRdLatVal;
- }
-
- dev = pDCTstat->dev_dct;
- reg = 0x78;
- val = Get_NB32_DCT(dev, Channel, reg);
- val &= ~(0x3ff<<22);
- val |= MaxRdLatVal<<22;
- /* program MaxRdLatency to correspond with current delay */
- Set_NB32_DCT(dev, Channel, reg, val);
-}
-
-static u8 CompareMaxRdLatTestPattern_D(u32 pattern_buf, u32 addr)
-{
- /* Compare only the first beat of data. Since target addrs are cache
- * line aligned, the Channel parameter is used to determine which cache
- * QW to compare.
- */
-
- u32 *test_buf = (u32 *)pattern_buf;
- u32 addr_lo;
- u32 val, val_test;
- int i;
- u8 ret = DQS_PASS;
-
- SetUpperFSbase(addr);
- addr_lo = addr<<8;
-
- _EXECFENCE;
- for (i = 0; i < 16*3; i++) {
- val = read32_fs(addr_lo);
- val_test = test_buf[i];
-
- print_debug_dqs_pair("\t\t\t\t\t\ttest_buf = ", (u32)test_buf, " value = ", val_test, 5);
- print_debug_dqs_pair("\t\t\t\t\t\ttaddr_lo = ", addr_lo, " value = ", val, 5);
- if (val != val_test) {
- ret = DQS_FAIL;
- break;
- }
- addr_lo += 4;
- }
-
- return ret;
-}
-
-static u32 GetMaxRdLatTestAddr_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 *MaxRcvrEnDly,
- u8 *valid)
-{
- u8 Max = 0;
-
- u8 Channel_Max = 0;
- u8 d;
- u8 d_Max = 0;
-
- u8 Byte;
- u32 TestAddr0 = 0;
- u8 ch, ch_start, ch_end;
- u8 bn;
-
- bn = 8;
-
- if (pDCTstat->Status & (1 << SB_128bitmode)) {
- ch_start = 0;
- ch_end = 2;
- } else {
- ch_start = Channel;
- ch_end = Channel + 1;
- }
-
- *valid = 0;
-
- for (ch = ch_start; ch < ch_end; ch++) {
- for (d = 0; d < 4; d++) {
- for (Byte = 0; Byte < bn; Byte++) {
- u8 tmp;
- tmp = pDCTstat->CH_D_B_RCVRDLY[ch][d][Byte];
- if (tmp > Max) {
- Max = tmp;
- Channel_Max = Channel;
- d_Max = d;
- }
- }
- }
- }
-
- if (mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel_Max, d_Max << 1)) {
- TestAddr0 = mct_GetMCTSysAddr_D(pMCTstat, pDCTstat, Channel_Max, d_Max << 1, valid);
- }
-
- if (*valid)
- *MaxRcvrEnDly = Max;
-
- return TestAddr0;
-}
-
-u8 mct_GetStartMaxRdLat_D(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat,
- u8 Channel, u8 DQSRcvEnDly, u32 *Margin)
-{
- u32 SubTotal;
- u32 val;
- u32 valx;
- u32 valxx;
- u32 index_reg;
- u32 dev;
-
- if (pDCTstat->GangedMode)
- Channel = 0;
-
- index_reg = 0x98;
-
- dev = pDCTstat->dev_dct;
-
- /* Multiply the CAS Latency by two to get a number of 1/2 MEMCLKs units.*/
- val = Get_NB32_DCT(dev, Channel, 0x88);
- SubTotal = ((val & 0x0f) + 1) << 1; /* SubTotal is 1/2 Memclk unit */
-
- /* If registered DIMMs are being used then add 1 MEMCLK to the sub-total*/
- val = Get_NB32_DCT(dev, Channel, 0x90);
- if (!(val & (1 << UnBuffDimm)))
- SubTotal += 2;
-
- /*If the address prelaunch is setup for 1/2 MEMCLKs then add 1,
- * else add 2 to the sub-total. if (AddrCmdSetup || CsOdtSetup
- * || CkeSetup) then K := K + 2; */
- val = Get_NB32_index_wait_DCT(dev, Channel, index_reg, 0x04);
- if (!(val & 0x00202020))
- SubTotal += 1;
- else
- SubTotal += 2;
-
- /* If the F2x[1, 0]78[RdPtrInit] field is 4, 5, 6 or 7 MEMCLKs,
- * then add 4, 3, 2, or 1 MEMCLKs, respectively to the sub-total. */
- val = Get_NB32_DCT(dev, Channel, 0x78);
- SubTotal += 8 - (val & 0x0f);
-
- /* Convert bits 7-5 (also referred to as the course delay) of the current
- * (or worst case) DQS receiver enable delay to 1/2 MEMCLKs units,
- * rounding up, and add this to the sub-total. */
- SubTotal += DQSRcvEnDly >> 5; /*BOZO-no rounding up */
-
- SubTotal <<= 1; /*scale 1/2 MemClk to 1/4 MemClk */
-
- /* Convert the sub-total (in 1/2 MEMCLKs) to northbridge clocks (NCLKs)
- * as follows (assuming DDR400 and assuming that no P-state or link speed
- * changes have occurred). */
-
- /*New formula:
- SubTotal *= 3*(Fn2xD4[NBFid]+4)/(3+Fn2x94[MemClkFreq])/2 */
- val = Get_NB32_DCT(dev, Channel, 0x94);
- /* SubTotal div 4 to scale 1/4 MemClk back to MemClk */
- val &= 7;
- if (val >= 3) {
- val <<= 1;
- } else
- val += 3;
- valx = (val) << 2; /* SubTotal div 4 to scale 1/4 MemClk back to MemClk */
-
- val = Get_NB32(pDCTstat->dev_nbmisc, 0xD4);
- val = ((val & 0x1f) + 4) * 3;
-
- /* Calculate 1 MemClk + 1 NCLK delay in NCLKs for margin */
- valxx = val << 2;
- valxx /= valx;
- if (valxx % valx)
- valxx++; /* round up */
- valxx++; /* add 1NCLK */
- *Margin = valxx; /* one MemClk delay in NCLKs and one additional NCLK */
-
- val *= SubTotal;
-
- val /= valx;
- if (val % valx)
- val++; /* round up */
-
- return val;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mctwl.c b/src/northbridge/amd/amdmct/mct_ddr3/mctwl.c
deleted file mode 100644
index 82523e01b8..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mctwl.c
+++ /dev/null
@@ -1,509 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 - 2016 Raptor Engineering, LLC
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/cpu.h>
-#include <stdint.h>
-#include <console/console.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-static void AgesaDelay(u32 msec)
-{
- mct_Wait(msec*10);
-}
-
-void PrepareC_MCT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- pDCTstat->C_MCTPtr->AgesaDelay = AgesaDelay;
-}
-
-void PrepareC_DCT(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct)
-{
- u8 dimm;
- u16 DimmValid;
- u16 Dimmx8Present;
-
- dct &= 1;
-
- pDCTstat->C_DCTPtr[dct]->DctTrain = dct;
-
- if (dct == 1) {
- Dimmx8Present = pDCTstat->Dimmx8Present >> 1;
- } else
- Dimmx8Present = pDCTstat->Dimmx8Present;
- Dimmx8Present &= 0x55;
-
- pDCTstat->C_DCTPtr[dct]->MaxDimmsInstalled = pDCTstat->MAdimms[dct];
- DimmValid = pDCTstat->DIMMValidDCT[dct];
-
- pDCTstat->C_DCTPtr[dct]->NodeId = pDCTstat->Node_ID;
- pDCTstat->C_DCTPtr[dct]->LogicalCPUID = pDCTstat->LogicalCPUID;
-
- for (dimm = 0; dimm < MAX_DIMMS; dimm++) {
- if (DimmValid & (1 << (dimm << 1)))
- pDCTstat->C_DCTPtr[dct]->DimmPresent[dimm] = 1;
- if (Dimmx8Present & (1 << (dimm << 1)))
- pDCTstat->C_DCTPtr[dct]->DimmX8Present[dimm] = 1;
- }
-
- if (pDCTstat->GangedMode & (1 << 0))
- pDCTstat->C_DCTPtr[dct]->CurrDct = 0;
- else
- pDCTstat->C_DCTPtr[dct]->CurrDct = dct;
-
- pDCTstat->C_DCTPtr[dct]->DctCSPresent = pDCTstat->CSPresent_DCT[dct];
- if (!(pDCTstat->GangedMode & (1 << 0)) && (dct == 1))
- pDCTstat->C_DCTPtr[dct]->DctCSPresent = pDCTstat->CSPresent_DCT[0];
-
- if (pDCTstat->Status & (1 << SB_Registered)) {
- pDCTstat->C_DCTPtr[dct]->Status[DCT_STATUS_REGISTERED] = 1;
- pDCTstat->C_DCTPtr[dct]->Status[DCT_STATUS_OnDimmMirror] = 0;
- } else {
- if (pDCTstat->MirrPresU_NumRegR > 0)
- pDCTstat->C_DCTPtr[dct]->Status[DCT_STATUS_OnDimmMirror] = 1;
- pDCTstat->C_DCTPtr[dct]->Status[DCT_STATUS_REGISTERED] = 0;
- }
-
- if (pDCTstat->Status & (1 << SB_LoadReduced)) {
- pDCTstat->C_DCTPtr[dct]->Status[DCT_STATUS_LOAD_REDUCED] = 1;
- } else {
- pDCTstat->C_DCTPtr[dct]->Status[DCT_STATUS_LOAD_REDUCED] = 0;
- }
-
- pDCTstat->C_DCTPtr[dct]->RegMan1Present = pDCTstat->RegMan1Present;
-
- for (dimm = 0; dimm < MAX_TOTAL_DIMMS; dimm++) {
- u8 DimmRanks;
- if (DimmValid & (1 << (dimm << 1))) {
- DimmRanks = 1;
- if (pDCTstat->DimmDRPresent & (1 << ((dimm << 1) + dct)))
- DimmRanks = 2;
- else if (pDCTstat->DimmQRPresent & (1 << ((dimm << 1) + dct)))
- DimmRanks = 4;
- } else
- DimmRanks = 0;
- pDCTstat->C_DCTPtr[dct]->DimmRanks[dimm] = DimmRanks;
- }
-}
-
-void EnableZQcalibration(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat)
-{
- u32 val;
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x94);
- val |= 1 << 11;
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x94, val);
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x94);
- val |= 1 << 11;
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x94, val);
-}
-
-void DisableZQcalibration(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u32 val;
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x94);
- val &= ~(1 << 11);
- val &= ~(1 << 10);
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x94, val);
-
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x94);
- val &= ~(1 << 11);
- val &= ~(1 << 10);
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x94, val);
-}
-
-static void EnterSelfRefresh(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 DCT0Present, DCT1Present;
- u32 val;
-
- DCT0Present = pDCTstat->DIMMValidDCT[0];
- if (pDCTstat->GangedMode)
- DCT1Present = 0;
- else
- DCT1Present = pDCTstat->DIMMValidDCT[1];
-
- /* Program F2x[1, 0]90[EnterSelfRefresh]=1. */
- if (DCT0Present) {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x90);
- val |= 1 << EnterSelfRef;
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x90, val);
- }
- if (DCT1Present) {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x90);
- val |= 1 << EnterSelfRef;
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x90, val);
- }
- /* Wait until the hardware resets F2x[1, 0]90[EnterSelfRefresh]=0. */
- if (DCT0Present)
- do {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x90);
- } while (val & (1 <<EnterSelfRef));
- if (DCT1Present)
- do {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x90);
- } while (val & (1 <<EnterSelfRef));
-}
-
-/*
- * Change memclk for write levelization pass 2
- */
-static void ChangeMemClk(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- uint8_t DCT0Present;
- uint8_t DCT1Present;
- uint32_t dword;
- uint32_t mask;
- uint32_t offset;
-
- DCT0Present = pDCTstat->DIMMValidDCT[0];
- if (pDCTstat->GangedMode)
- DCT1Present = 0;
- else
- DCT1Present = pDCTstat->DIMMValidDCT[1];
-
- if (is_fam15h()) {
- /* Program D18F2x9C_x0D0F_E006_dct[1:0][PllLockTime] = 0x190 */
- if (DCT0Present) {
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 0x0d0fe006);
- dword &= ~(0x0000ffff);
- dword |= 0x00000190;
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 0x0d0fe006, dword);
- }
- if (DCT1Present) {
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, 1, 0x98, 0x0d0fe006);
- dword &= ~(0x0000ffff);
- dword |= 0x00000190;
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, 1, 0x98, 0x0d0fe006, dword);
- }
- } else {
- /* Program F2x[1, 0]9C[DisAutoComp]=1. */
- if (DCT0Present) {
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 8);
- dword |= 1 << DisAutoComp;
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 8, dword);
- mct_Wait(100); /* Wait for 5us */
- }
- if (DCT1Present) {
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, 1, 0x98, 8);
- dword |= 1 << DisAutoComp;
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, 1, 0x98, 8, dword);
- mct_Wait(100); /* Wait for 5us */
- }
- }
-
- /* Program F2x[1, 0]94[MemClkFreqVal] = 0. */
- if (DCT0Present) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x94);
- dword &= ~(1 << MemClkFreqVal);
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x94, dword);
- }
- if (DCT1Present) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x94);
- dword &= ~(1 << MemClkFreqVal);
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x94, dword);
- }
-
- /* Program F2x[1, 0]94[MemClkFreq] to specify the target MEMCLK frequency. */
- if (is_fam15h()) {
- offset = 0x0;
- mask = 0x1f;
- } else {
- offset = 0x1;
- mask = 0x7;
- }
- if (DCT0Present) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x94);
- dword &= ~mask;
- dword |= (pDCTstat->TargetFreq - offset) & mask;
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x94, dword);
- }
- if (DCT1Present) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x94);
- dword &= ~mask;
- dword |= (pDCTstat->TargetFreq - offset) & mask;
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x94, dword);
- }
-
- if (is_fam15h()) {
- if (DCT0Present) {
- mctGet_PS_Cfg_D(pMCTstat, pDCTstat, 0);
- set_2t_configuration(pMCTstat, pDCTstat, 0);
- mct_BeforePlatformSpec(pMCTstat, pDCTstat, 0);
- mct_PlatformSpec(pMCTstat, pDCTstat, 0);
- }
- if (DCT1Present) {
- mctGet_PS_Cfg_D(pMCTstat, pDCTstat, 1);
- set_2t_configuration(pMCTstat, pDCTstat, 1);
- mct_BeforePlatformSpec(pMCTstat, pDCTstat, 1);
- mct_PlatformSpec(pMCTstat, pDCTstat, 1);
- }
- }
-
- /* Program F2x[1, 0]94[MemClkFreqVal] = 1. */
- if (DCT0Present) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x94);
- dword |= 1 << MemClkFreqVal;
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x94, dword);
- }
- if (DCT1Present) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x94);
- dword |= 1 << MemClkFreqVal;
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x94, dword);
- }
-
- /* Wait until F2x[1, 0]94[FreqChgInProg]=0. */
- if (DCT0Present)
- do {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x94);
- } while (dword & (1 << FreqChgInProg));
- if (DCT1Present)
- do {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x94);
- } while (dword & (1 << FreqChgInProg));
-
- if (is_fam15h()) {
- /* Program D18F2x9C_x0D0F_E006_dct[1:0][PllLockTime] = 0xf */
- if (DCT0Present) {
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 0x0d0fe006);
- dword &= ~(0x0000ffff);
- dword |= 0x0000000f;
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 0x0d0fe006, dword);
- }
- if (DCT1Present) {
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, 1, 0x98, 0x0d0fe006);
- dword &= ~(0x0000ffff);
- dword |= 0x0000000f;
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, 1, 0x98, 0x0d0fe006, dword);
- }
- } else {
- /* Program F2x[1, 0]9C[DisAutoComp] = 0. */
- if (DCT0Present) {
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 8);
- dword &= ~(1 << DisAutoComp);
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, 0, 0x98, 8, dword);
- mct_Wait(15000); /* Wait for 750us */
- }
- if (DCT1Present) {
- dword = Get_NB32_index_wait_DCT(pDCTstat->dev_dct, 1, 0x98, 8);
- dword &= ~(1 << DisAutoComp);
- Set_NB32_index_wait_DCT(pDCTstat->dev_dct, 1, 0x98, 8, dword);
- mct_Wait(15000); /* Wait for 750us */
- }
- }
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-/*
- * the DRAM controller to bring the DRAMs out of self refresh mode.
- */
-static void ExitSelfRefresh(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- u8 DCT0Present, DCT1Present;
- u32 val;
-
- DCT0Present = pDCTstat->DIMMValidDCT[0];
- if (pDCTstat->GangedMode)
- DCT1Present = 0;
- else
- DCT1Present = pDCTstat->DIMMValidDCT[1];
-
- /* Program F2x[1, 0]90[ExitSelfRef]=1 for both DCTs. */
- if (DCT0Present) {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x90);
- val |= 1 << ExitSelfRef;
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x90, val);
- }
- if (DCT1Present) {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x90);
- val |= 1 << ExitSelfRef;
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x90, val);
- }
- /* Wait until the hardware resets F2x[1, 0]90[ExitSelfRef]=0. */
- if (DCT0Present)
- do {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x90);
- } while (val & (1 << ExitSelfRef));
- if (DCT1Present)
- do {
- val = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x90);
- } while (val & (1 << ExitSelfRef));
-}
-
-void SetTargetFreq(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstatA, uint8_t Node)
-{
- uint32_t dword;
- uint8_t package_type = mctGet_NVbits(NV_PACK_TYPE);
-
- printk(BIOS_DEBUG, "%s: Start\n", __func__);
-
- struct DCTStatStruc *pDCTstat;
- pDCTstat = pDCTstatA + Node;
-
- printk(BIOS_DEBUG, "%s: Node %d: New frequency code: %04x\n", __func__, Node, pDCTstat->TargetFreq);
-
- if (is_fam15h()) {
- /* Program F2x[1, 0]90[DisDllShutDownSR]=1. */
- if (pDCTstat->DIMMValidDCT[0]) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x90);
- dword |= (0x1 << 27);
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x90, dword);
- }
- if (pDCTstat->DIMMValidDCT[1]) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x90);
- dword |= (0x1 << 27);
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x90, dword);
- }
- }
-
- /* Program F2x[1,0]90[EnterSelfRefresh]=1.
- * Wait until the hardware resets F2x[1,0]90[EnterSelfRefresh]=0.
- */
- EnterSelfRefresh(pMCTstat, pDCTstat);
-
- /*
- * Program F2x[1,0]9C_x08[DisAutoComp]=1
- * Program F2x[1,0]94[MemClkFreqVal] = 0.
- * Program F2x[1,0]94[MemClkFreq] to specify the target MEMCLK frequency.
- * Program F2x[1,0]94[MemClkFreqVal] = 1.
- * Wait until F2x[1,0]94[FreqChgInProg]=0.
- * Program F2x[1,0]9C_x08[DisAutoComp]=0
- */
- ChangeMemClk(pMCTstat, pDCTstat);
-
- if (is_fam15h()) {
- uint8_t dct;
- for (dct = 0; dct < 2; dct++) {
- if (pDCTstat->DIMMValidDCT[dct]) {
- phyAssistedMemFnceTraining(pMCTstat, pDCTstatA, Node);
- InitPhyCompensation(pMCTstat, pDCTstat, dct);
- }
- }
- }
-
- /* Program F2x[1,0]90[ExitSelfRef]=1 for both DCTs.
- * Wait until the hardware resets F2x[1, 0]90[ExitSelfRef]=0.
- */
- ExitSelfRefresh(pMCTstat, pDCTstat);
-
- if (is_fam15h()) {
- if ((package_type == PT_C3) || (package_type == PT_GR)) {
- /* Socket C32 or G34 */
- /* Program F2x[1, 0]90[DisDllShutDownSR]=0. */
- if (pDCTstat->DIMMValidDCT[0]) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 0, 0x90);
- dword &= ~(0x1 << 27);
- Set_NB32_DCT(pDCTstat->dev_dct, 0, 0x90, dword);
- }
- if (pDCTstat->DIMMValidDCT[1]) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, 1, 0x90);
- dword &= ~(0x1 << 27);
- Set_NB32_DCT(pDCTstat->dev_dct, 1, 0x90, dword);
- }
- }
- }
-
- /* wait for 500 MCLKs after ExitSelfRef, 500*2.5ns = 1250ns */
- mct_Wait(250);
-
- if (pDCTstat->Status & (1 << SB_Registered)) {
- u8 DCT0Present, DCT1Present;
-
- DCT0Present = pDCTstat->DIMMValidDCT[0];
- if (pDCTstat->GangedMode)
- DCT1Present = 0;
- else
- DCT1Present = pDCTstat->DIMMValidDCT[1];
-
- if (!DCT1Present)
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[0];
- else if (pDCTstat->GangedMode)
- pDCTstat->CSPresent = 0;
- else
- pDCTstat->CSPresent = pDCTstat->CSPresent_DCT[1];
-
- if (pDCTstat->DIMMValidDCT[0]) {
- FreqChgCtrlWrd(pMCTstat, pDCTstat, 0);
- }
- if (pDCTstat->DIMMValidDCT[1]) {
- FreqChgCtrlWrd(pMCTstat, pDCTstat, 1);
- }
- }
-
- printk(BIOS_DEBUG, "%s: Done\n", __func__);
-}
-
-static void Modify_OnDimmMirror(struct DCTStatStruc *pDCTstat, u8 dct, u8 set)
-{
- u32 val;
- u32 reg = 0x44;
- while (reg < 0x60) {
- val = Get_NB32_DCT(pDCTstat->dev_dct, dct, reg);
- if (val & (1 << CSEnable))
- set ? (val |= 1 << onDimmMirror) : (val &= ~(1<<onDimmMirror));
- Set_NB32_DCT(pDCTstat->dev_dct, dct, reg, val);
- reg += 8;
- }
-}
-
-void Restore_OnDimmMirror(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- if (pDCTstat->LogicalCPUID & (AMD_DR_Bx /* | AMD_RB_C0 */)) { /* We dont support RB-C0 now */
- if (pDCTstat->MirrPresU_NumRegR & 0x55)
- Modify_OnDimmMirror(pDCTstat, 0, 1); /* dct = 0, set */
- if (pDCTstat->MirrPresU_NumRegR & 0xAA)
- Modify_OnDimmMirror(pDCTstat, 1, 1); /* dct = 1, set */
- }
-}
-void Clear_OnDimmMirror(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- if (pDCTstat->LogicalCPUID & (AMD_DR_Bx /* | AMD_RB_C0 */)) { /* We dont support RB-C0 now */
- if (pDCTstat->MirrPresU_NumRegR & 0x55)
- Modify_OnDimmMirror(pDCTstat, 0, 0); /* dct = 0, clear */
- if (pDCTstat->MirrPresU_NumRegR & 0xAA)
- Modify_OnDimmMirror(pDCTstat, 1, 0); /* dct = 1, clear */
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mhwlc_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mhwlc_d.c
deleted file mode 100644
index 353aa7a1cf..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mhwlc_d.c
+++ /dev/null
@@ -1,1519 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 - 2016 Raptor Engineering, LLC
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-#include <assert.h>
-#include <console/console.h>
-#include <northbridge/amd/amdfam10/amdfam10.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-#include "mwlc_d.h"
-
-u32 swapAddrBits_wl(struct DCTStatStruc *pDCTstat, uint8_t dct, uint32_t MRSValue);
-u32 swapBankBits(struct DCTStatStruc *pDCTstat, uint8_t dct, uint32_t MRSValue);
-void prepareDimms(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat,
- u8 dct, u8 dimm, BOOL wl);
-void programODT(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, uint8_t dct, u8 dimm);
-void procConfig(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t pass, uint8_t nibble);
-void setWLByteDelay(struct DCTStatStruc *pDCTstat, uint8_t dct, u8 ByteLane, u8 dimm, u8 targetAddr, uint8_t pass, uint8_t lane_count);
-void getWLByteDelay(struct DCTStatStruc *pDCTstat, uint8_t dct, u8 ByteLane, u8 dimm, uint8_t pass, uint8_t nibble, uint8_t lane_count);
-
-#define MAX_LANE_COUNT 9
-
-/*-----------------------------------------------------------------------------
- * uint8_t AgesaHwWlPhase1(SPDStruct *SPDData,MCTStruct *MCTData, DCTStruct *DCTData,
- * u8 Dimm, u8 Pass)
- *
- * Description:
- * This function initialized Hardware based write levelization phase 1
- *
- * Parameters:
- * IN OUT *SPDData - Pointer to buffer with information about each DIMMs
- * SPD information
- * *MCTData - Pointer to buffer with runtime parameters,
- * *DCTData - Pointer to buffer with information about each DCT
- *
- * IN DIMM - Logical DIMM number
- * Pass - First or Second Pass
- * OUT
- *-----------------------------------------------------------------------------
- */
-uint8_t AgesaHwWlPhase1(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat,
- u8 dct, u8 dimm, u8 pass)
-{
- u8 ByteLane;
- u32 Value, Addr;
- uint8_t nibble = 0;
- uint8_t train_both_nibbles;
- u16 Addl_Data_Offset, Addl_Data_Port;
- sMCTStruct *pMCTData = pDCTstat->C_MCTPtr;
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- uint8_t lane_count;
-
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- pDCTData->WLPass = pass;
- /* 1. Specify the target DIMM that is to be trained by programming
- * F2x[1, 0]9C_x08[TrDimmSel].
- */
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_ADD_DCT_PHY_CONTROL_REG, TrDimmSelStart,
- TrDimmSelEnd, (u32)dimm);
-
- train_both_nibbles = 0;
- if (pDCTstat->Dimmx4Present)
- if (is_fam15h())
- train_both_nibbles = 1;
-
- for (nibble = 0; nibble < (train_both_nibbles + 1); nibble++) {
- printk(BIOS_SPEW, "AgesaHwWlPhase1: training nibble %d\n", nibble);
-
- if (is_fam15h()) {
- /* Program F2x[1, 0]9C_x08[WrtLvTrEn]=0 */
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_ADD_DCT_PHY_CONTROL_REG, WrtLvTrEn, WrtLvTrEn, 0);
-
- /* Set TrNibbleSel */
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_ADD_DCT_PHY_CONTROL_REG, 2,
- 2, (uint32_t)nibble);
- }
-
- /* 2. Prepare the DIMMs for write levelization using DDR3-defined
- * MR commands. */
- prepareDimms(pMCTstat, pDCTstat, dct, dimm, TRUE);
-
- /* 3. After the DIMMs are configured, BIOS waits 40 MEMCLKs to
- * satisfy DDR3-defined internal DRAM timing.
- */
- if (is_fam15h())
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 40);
- else
- pMCTData->AgesaDelay(40);
-
- /* 4. Configure the processor's DDR phy for write levelization training: */
- procConfig(pMCTstat, pDCTstat, dct, dimm, pass, nibble);
-
- /* 5. Begin write levelization training:
- * Program F2x[1, 0]9C_x08[WrtLvTrEn]=1. */
- if (pDCTData->LogicalCPUID & (AMD_DR_Cx | AMD_DR_Dx | AMD_FAM15_ALL))
- {
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_ADD_DCT_PHY_CONTROL_REG, WrtLvTrEn, WrtLvTrEn, 1);
- }
- else
- {
- /* Broadcast write to all D3Dbyte chipset register offset 0xc
- * Set bit 0 (wrTrain)
- * Program bit 4 to nibble being trained (only matters for x4dimms)
- * retain value of 3:2 (Trdimmsel)
- * reset bit 5 (FrzPR)
- */
- if (dct)
- {
- Addl_Data_Offset = 0x198;
- Addl_Data_Port = 0x19C;
- }
- else
- {
- Addl_Data_Offset = 0x98;
- Addl_Data_Port = 0x9C;
- }
- Addr = 0x0D00000C;
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+(pDCTData->NodeId),FUN_DCT,Addl_Data_Offset), 31, 0, &Addr);
- while ((get_Bits(pDCTData,FUN_DCT,pDCTData->NodeId, FUN_DCT, Addl_Data_Offset,
- DctAccessDone, DctAccessDone)) == 0);
- AmdMemPCIReadBits(MAKE_SBDFO(0,0,24+(pDCTData->NodeId),FUN_DCT,Addl_Data_Port), 31, 0, &Value);
- Value = bitTestSet(Value, 0); /* enable WL training */
- Value = bitTestReset(Value, 4); /* for x8 only */
- Value = bitTestReset(Value, 5); /* for hardware WL training */
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+(pDCTData->NodeId),FUN_DCT,Addl_Data_Port), 31, 0, &Value);
- Addr = 0x4D030F0C;
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+(pDCTData->NodeId),FUN_DCT,Addl_Data_Offset), 31, 0, &Addr);
- while ((get_Bits(pDCTData,FUN_DCT,pDCTData->NodeId, FUN_DCT, Addl_Data_Offset,
- DctAccessDone, DctAccessDone)) == 0);
- }
-
- if (is_fam15h())
- proc_MFENCE();
-
- /* Wait 200 MEMCLKs. If executing pass 2, wait 32 MEMCLKs. */
- if (is_fam15h())
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 200);
- else
- pMCTData->AgesaDelay(140);
-
- /* Program F2x[1, 0]9C_x08[WrtLevelTrEn]=0. */
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_ADD_DCT_PHY_CONTROL_REG, WrtLvTrEn, WrtLvTrEn, 0);
-
- /* Read from registers F2x[1, 0]9C_x[51:50] and F2x[1, 0]9C_x52
- * to get the gross and fine delay settings
- * for the target DIMM and save these values. */
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- getWLByteDelay(pDCTstat, dct, ByteLane, dimm, pass, nibble, lane_count);
- }
-
- pDCTData->WLCriticalGrossDelayPrevPass = 0x0;
-
- /* Exit nibble training if current DIMM is not x4 */
- if ((pDCTstat->Dimmx4Present & (1 << (dimm + dct))) == 0)
- break;
- }
-
- return 0;
-}
-
-uint8_t AgesaHwWlPhase2(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat,
- uint8_t dct, uint8_t dimm, uint8_t pass)
-{
- u8 ByteLane;
- uint8_t status = 0;
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- uint8_t lane_count;
-
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- assert(lane_count <= MAX_LANE_COUNT);
-
- if (is_fam15h()) {
- int32_t gross_diff[MAX_LANE_COUNT];
- int32_t cgd = pDCTData->WLCriticalGrossDelayPrevPass;
- uint8_t index = (uint8_t)(lane_count * dimm);
-
- printk(BIOS_SPEW, "\toriginal critical gross delay: %d\n", cgd);
-
- /* FIXME
- * For now, disable CGD adjustment as it seems to interfere with registered DIMM training
- */
-
- /* Calculate the Critical Gross Delay */
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- /* Calculate the gross delay differential for this lane */
- gross_diff[ByteLane] = pDCTData->WLSeedGrossDelay[index+ByteLane] + pDCTData->WLGrossDelay[index+ByteLane];
- gross_diff[ByteLane] -= pDCTData->WLSeedPreGrossDelay[index+ByteLane];
-
- /* WrDqDqsEarly values greater than 2 are reserved */
- if (gross_diff[ByteLane] < -2)
- gross_diff[ByteLane] = -2;
-
- /* Update the Critical Gross Delay */
- if (gross_diff[ByteLane] < cgd)
- cgd = gross_diff[ByteLane];
- }
-
- printk(BIOS_SPEW, "\tnew critical gross delay: %d\n", cgd);
-
- pDCTData->WLCriticalGrossDelayPrevPass = cgd;
-
- if (pDCTstat->Speed != pDCTstat->TargetFreq) {
- /* FIXME
- * Using the Pass 1 training values causes major phy training problems on
- * all Family 15h processors I tested (Pass 1 values are randomly too high,
- * and Pass 2 cannot lock).
- * Figure out why this is and fix it, then remove the bypass code below...
- */
- if (pass == FirstPass) {
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- pDCTData->WLGrossDelay[index+ByteLane] = pDCTData->WLSeedGrossDelay[index+ByteLane];
- pDCTData->WLFineDelay[index+ByteLane] = pDCTData->WLSeedFineDelay[index+ByteLane];
- }
- return 0;
- }
- }
-
- /* Compensate for occasional noise/instability causing sporadic training failure */
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- uint8_t faulty_value_detected = 0;
- uint16_t total_delay_seed = ((pDCTData->WLSeedGrossDelay[index+ByteLane] & 0x1f) << 5) | (pDCTData->WLSeedFineDelay[index+ByteLane] & 0x1f);
- uint16_t total_delay_phy = ((pDCTData->WLGrossDelay[index+ByteLane] & 0x1f) << 5) | (pDCTData->WLFineDelay[index+ByteLane] & 0x1f);
- if (pass == FirstPass) {
- /* Allow a somewhat higher step threshold on the first pass
- * For the most part, as long as the phy isn't stepping
- * several clocks at once the values are probably valid.
- */
- if (abs(total_delay_phy - total_delay_seed) > 0x30)
- faulty_value_detected = 1;
- } else {
- /* Stepping memory clocks between adjacent allowed frequencies
- * should not yield large phy value differences...
- */
-
- if (abs(total_delay_phy - total_delay_seed) > 0x20)
- faulty_value_detected = 1;
- }
- if (faulty_value_detected) {
- printk(BIOS_INFO, "%s: overriding faulty phy value (seed: %04x phy: %04x step: %04x)\n", __func__,
- total_delay_seed, total_delay_phy, abs(total_delay_phy - total_delay_seed));
- pDCTData->WLGrossDelay[index+ByteLane] = pDCTData->WLSeedGrossDelay[index+ByteLane];
- pDCTData->WLFineDelay[index+ByteLane] = pDCTData->WLSeedFineDelay[index+ByteLane];
- status = 1;
- }
- }
- }
-
- return status;
-}
-
-uint8_t AgesaHwWlPhase3(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat,
- u8 dct, u8 dimm, u8 pass)
-{
- u8 ByteLane;
- sMCTStruct *pMCTData = pDCTstat->C_MCTPtr;
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- uint8_t lane_count;
-
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- assert(lane_count <= MAX_LANE_COUNT);
-
- if (is_fam15h()) {
- uint32_t dword;
- int32_t gross_diff[MAX_LANE_COUNT];
- int32_t cgd = pDCTData->WLCriticalGrossDelayPrevPass;
- uint8_t index = (uint8_t)(lane_count * dimm);
-
- /* Apply offset(s) if needed */
- if (cgd < 0) {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0xa8);
- dword &= ~(0x3 << 24); /* WrDqDqsEarly = abs(cgd) */
- dword |= ((abs(cgd) & 0x3) << 24);
- Set_NB32_DCT(pDCTstat->dev_dct, dct, 0xa8, dword);
-
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- /* Calculate the gross delay differential for this lane */
- gross_diff[ByteLane] = pDCTData->WLSeedGrossDelay[index+ByteLane] + pDCTData->WLGrossDelay[index+ByteLane];
- gross_diff[ByteLane] -= pDCTData->WLSeedPreGrossDelay[index+ByteLane];
-
- /* Prevent underflow in the presence of noise / instability */
- if (gross_diff[ByteLane] < cgd)
- gross_diff[ByteLane] = cgd;
-
- pDCTData->WLGrossDelay[index+ByteLane] = (gross_diff[ByteLane] + (abs(cgd) & 0x3));
- }
- } else {
- dword = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0xa8);
- dword &= ~(0x3 << 24); /* WrDqDqsEarly = pDCTData->WrDqsGrossDlyBaseOffset */
- dword |= ((pDCTData->WrDqsGrossDlyBaseOffset & 0x3) << 24);
- Set_NB32_DCT(pDCTstat->dev_dct, dct, 0xa8, dword);
- }
- }
-
- /* Write the adjusted gross and fine delay settings
- * to the target DIMM. */
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- setWLByteDelay(pDCTstat, dct, ByteLane, dimm, 1, pass, lane_count);
- }
-
- /* 6. Configure DRAM Phy Control Register so that the phy stops driving
- * write levelization ODT. */
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_ADD_DCT_PHY_CONTROL_REG, WrLvOdtEn, WrLvOdtEn, 0);
-
- if (is_fam15h())
- proc_MFENCE();
-
- /* Wait 10 MEMCLKs to allow for ODT signal settling. */
- if (is_fam15h())
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 10);
- else
- pMCTData->AgesaDelay(10);
-
- /* 7. Program the target DIMM back to normal operation by configuring
- * the following (See section 2.8.5.4.1.1
- * [Phy Assisted Write Levelization] on page 97 pass 1, step #2):
- * Configure all ranks of the target DIMM for normal operation.
- * Enable the output drivers of all ranks of the target DIMM.
- * For a two DIMM system, program the Rtt value for the target DIMM
- * to the normal operating termination:
- */
- prepareDimms(pMCTstat, pDCTstat, dct, dimm, FALSE);
-
- return 0;
-}
-
-/*----------------------------------------------------------------------------
- * LOCAL FUNCTIONS
- *
- *----------------------------------------------------------------------------
- */
-
-/*-----------------------------------------------------------------------------
- * u32 swapAddrBits_wl(struct DCTStatStruc *pDCTstat, uint8_t dct, u32 MRSValue)
- *
- * Description:
- * This function swaps the bits in MSR register value
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * IN u32: MRS value
- * OUT u32: Swapped BANK BITS
- *
- * ----------------------------------------------------------------------------
- */
-u32 swapAddrBits_wl(struct DCTStatStruc *pDCTstat, uint8_t dct, uint32_t MRSValue)
-{
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- u32 tempW, tempW1;
-
- if (is_fam15h())
- tempW1 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsChipSelStartFam15, MrsChipSelEndFam15);
- else
- tempW1 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsChipSelStartFam10, MrsChipSelEndFam10);
- if (tempW1 & 1)
- {
- if ((pDCTData->Status[DCT_STATUS_OnDimmMirror]))
- {
- /* swap A3/A4,A5/A6,A7/A8 */
- tempW = MRSValue;
- tempW1 = MRSValue;
- tempW &= 0x0A8;
- tempW1 &= 0x0150;
- MRSValue &= 0xFE07;
- MRSValue |= (tempW << 1);
- MRSValue |= (tempW1 >> 1);
- }
- }
- return MRSValue;
-}
-
-/*-----------------------------------------------------------------------------
- * u32 swapBankBits(struct DCTStatStruc *pDCTstat, uint8_t dct, u32 MRSValue)
- *
- * Description:
- * This function swaps the bits in MSR register value
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * IN u32: MRS value
- * OUT u32: Swapped BANK BITS
- *
- * ----------------------------------------------------------------------------
- */
-u32 swapBankBits(struct DCTStatStruc *pDCTstat, uint8_t dct, u32 MRSValue)
-{
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- u32 tempW, tempW1;
-
- if (is_fam15h())
- tempW1 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsChipSelStartFam15, MrsChipSelEndFam15);
- else
- tempW1 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsChipSelStartFam10, MrsChipSelEndFam10);
- if (tempW1 & 1)
- {
- if ((pDCTData->Status[DCT_STATUS_OnDimmMirror]))
- {
- /* swap BA0/BA1 */
- tempW = MRSValue;
- tempW1 = MRSValue;
- tempW &= 0x01;
- tempW1 &= 0x02;
- MRSValue = 0;
- MRSValue |= (tempW << 1);
- MRSValue |= (tempW1 >> 1);
- }
- }
- return MRSValue;
-}
-
-static uint16_t unbuffered_dimm_nominal_termination_emrs(uint8_t number_of_dimms, uint8_t frequency_index, uint8_t rank_count, uint8_t rank)
-{
- uint16_t term;
-
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- if (number_of_dimms == 1) {
- if (MaxDimmsInstallable < 3) {
- term = 0x04; /* Rtt_Nom = RZQ/4 = 60 Ohm */
- } else {
- if (rank_count == 1) {
- term = 0x04; /* Rtt_Nom = RZQ/4 = 60 Ohm */
- } else {
- if (rank == 0)
- term = 0x04; /* Rtt_Nom = RZQ/4 = 60 Ohm */
- else
- term = 0x00; /* Rtt_Nom = OFF */
- }
- }
- } else {
- if (frequency_index < 5)
- term = 0x0044; /* Rtt_Nom = RZQ/6 = 40 Ohm */
- else
- term = 0x0204; /* Rtt_Nom = RZQ/8 = 30 Ohm */
- }
-
- return term;
-}
-
-static uint16_t unbuffered_dimm_dynamic_termination_emrs(uint8_t number_of_dimms, uint8_t frequency_index, uint8_t rank_count)
-{
- uint16_t term;
-
- uint8_t MaxDimmsInstallable = mctGet_NVbits(NV_MAX_DIMMS_PER_CH);
-
- if (number_of_dimms == 1) {
- if (MaxDimmsInstallable < 3) {
- term = 0x00; /* Rtt_WR = off */
- } else {
- if (rank_count == 1)
- term = 0x00; /* Rtt_WR = off */
- else
- term = 0x200; /* Rtt_WR = RZQ/4 = 60 Ohm */
- }
- } else {
- term = 0x400; /* Rtt_WR = RZQ/2 = 120 Ohm */
- }
-
- return term;
-}
-
-/*-----------------------------------------------------------------------------
- * void prepareDimms(sMCTStruct *pMCTData, sDCTStruct *DCTData, u8 Dimm, BOOL WL)
- *
- * Description:
- * This function prepares DIMMS for training
- * Fam10h: BKDG Rev. 3.62 section 2.8.9.9.1
- * Fam15h: BKDG Rev. 3.14 section 2.10.5.8.1
- * ----------------------------------------------------------------------------
- */
-void prepareDimms(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat,
- u8 dct, u8 dimm, BOOL wl)
-{
- u32 tempW, tempW1, tempW2, MrsBank;
- u8 rank, currDimm, MemClkFreq;
- sMCTStruct *pMCTData = pDCTstat->C_MCTPtr;
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- uint8_t package_type = mctGet_NVbits(NV_PACK_TYPE);
- uint8_t number_of_dimms = pDCTData->MaxDimmsInstalled;
-
- if (is_fam15h()) {
- MemClkFreq = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_CONFIG_HIGH, 0, 4);
- } else {
- MemClkFreq = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_CONFIG_HIGH, 0, 2);
- }
- /* Configure the DCT to send initialization MR commands to the target DIMM
- * by programming the F2x[1,0]7C register using the following steps.
- */
- rank = 0;
- while ((rank < pDCTData->DimmRanks[dimm]) && (rank < 2))
- {
- /* Program F2x[1, 0]7C[MrsChipSel[2:0]] for the current rank to be trained. */
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsChipSelStartFam15, MrsChipSelEndFam15, dimm*2+rank);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsChipSelStartFam10, MrsChipSelEndFam10, dimm*2+rank);
-
- /* Program F2x[1, 0]7C[MrsBank[2:0]] for the appropriate internal DRAM
- * register that defines the required DDR3-defined function for write
- * levelization.
- */
- MrsBank = swapBankBits(pDCTstat, dct, 1);
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsBankStartFam15, MrsBankEndFam15, MrsBank);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsBankStartFam10, MrsBankEndFam10, MrsBank);
-
- /* Program F2x[1, 0]7C[MrsAddress[15:0]] to the required DDR3-defined function
- * for write levelization.
- */
- tempW = 0;/* DLL_DIS = 0, DIC = 0, AL = 0, TDQS = 0 */
-
- /* Retrieve normal settings of the MRS control word and clear Rtt_Nom */
- if (is_fam15h()) {
- tempW = mct_MR1(pMCTstat, pDCTstat, dct, dimm*2+rank) & 0xffff;
- tempW &= ~(0x0244);
- } else {
- /* Set TDQS = 1b for x8 DIMM, TDQS = 0b for x4 DIMM, when mixed x8 & x4 */
- tempW2 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_CONFIG_HIGH, RDqsEn, RDqsEn);
- if (tempW2)
- {
- if (pDCTData->DimmX8Present[dimm])
- tempW |= 0x800;
- }
- }
-
- /* determine Rtt_Nom for WL & Normal mode */
- if (is_fam15h()) {
- if (wl) {
- if (number_of_dimms > 1) {
- if (rank == 0) {
- /* Get Rtt_WR for the current DIMM and rank */
- tempW2 = fam15_rttwr(pDCTstat, dct, dimm, rank, package_type);
- } else {
- tempW2 = fam15_rttnom(pDCTstat, dct, dimm, rank, package_type);
- }
- } else {
- tempW2 = fam15_rttnom(pDCTstat, dct, dimm, rank, package_type);
- }
- } else {
- tempW2 = fam15_rttnom(pDCTstat, dct, dimm, rank, package_type);
- }
- tempW1 = 0;
- tempW1 |= ((tempW2 & 0x4) >> 2) << 9;
- tempW1 |= ((tempW2 & 0x2) >> 1) << 6;
- tempW1 |= ((tempW2 & 0x1) >> 0) << 2;
- } else {
- if (pDCTData->Status[DCT_STATUS_REGISTERED]) {
- tempW1 = RttNomTargetRegDimm(pMCTData, pDCTData, dimm, wl, MemClkFreq, rank);
- } else {
- if (wl) {
- if (number_of_dimms > 1) {
- if (rank == 0) {
- /* Get Rtt_WR for the current DIMM and rank */
- uint16_t dynamic_term = unbuffered_dimm_dynamic_termination_emrs(pDCTData->MaxDimmsInstalled, MemClkFreq, pDCTData->DimmRanks[dimm]);
-
- /* Convert dynamic termination code to corresponding nominal termination code */
- if (dynamic_term == 0x200)
- tempW1 = 0x04;
- else if (dynamic_term == 0x400)
- tempW1 = 0x40;
- else
- tempW1 = 0x0;
- } else {
- tempW1 = unbuffered_dimm_nominal_termination_emrs(pDCTData->MaxDimmsInstalled, MemClkFreq, pDCTData->DimmRanks[dimm], rank);
- }
- } else {
- tempW1 = unbuffered_dimm_nominal_termination_emrs(pDCTData->MaxDimmsInstalled, MemClkFreq, pDCTData->DimmRanks[dimm], rank);
- }
- } else {
- tempW1 = unbuffered_dimm_nominal_termination_emrs(pDCTData->MaxDimmsInstalled, MemClkFreq, pDCTData->DimmRanks[dimm], rank);
- }
- }
- }
-
- /* Apply Rtt_Nom to the MRS control word */
- tempW = tempW|tempW1;
-
- /* All ranks of the target DIMM are set to write levelization mode. */
- if (wl)
- {
- tempW1 = bitTestSet(tempW, MRS_Level);
- if (rank == 0)
- {
- /* Enable the output driver of the first rank of the target DIMM. */
- tempW = tempW1;
- }
- else
- {
- /* Disable the output drivers of all other ranks for
- * the target DIMM.
- */
- tempW = bitTestSet(tempW1, Qoff);
- }
- }
-
- /* Program MrsAddress[5,1]=output driver impedance control (DIC) */
- if (is_fam15h()) {
- tempW1 = fam15_dimm_dic(pDCTstat, dct, dimm, rank, package_type);
- } else {
- /* Read DIC from F2x[1,0]84[DrvImpCtrl] */
- tempW1 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_MRS_REGISTER, DrvImpCtrlStart, DrvImpCtrlEnd);
- }
-
- /* Apply DIC to the MRS control word */
- if (bitTest(tempW1, 1))
- tempW = bitTestSet(tempW, 5);
- if (bitTest(tempW1, 0))
- tempW = bitTestSet(tempW, 1);
-
- tempW = swapAddrBits_wl(pDCTstat, dct, tempW);
-
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsAddressStartFam15, MrsAddressEndFam15, tempW);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsAddressStartFam10, MrsAddressEndFam10, tempW);
-
- /* Program F2x[1, 0]7C[SendMrsCmd]=1 to initiate the command to
- * the specified DIMM.
- */
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, SendMrsCmd, SendMrsCmd, 1);
- /* Wait for F2x[1, 0]7C[SendMrsCmd] to be cleared by hardware. */
- while ((get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, SendMrsCmd, SendMrsCmd)) == 0x1)
- {
- }
-
- /* Program F2x[1, 0]7C[MrsBank[2:0]] for the appropriate internal DRAM
- * register that defines the required DDR3-defined function for Rtt_WR.
- */
- MrsBank = swapBankBits(pDCTstat, dct, 2);
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsBankStartFam15, MrsBankEndFam15, MrsBank);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsBankStartFam10, MrsBankEndFam10, MrsBank);
-
- /* Program F2x[1, 0]7C[MrsAddress[15:0]] to the required DDR3-defined function
- * for Rtt_WR (DRAMTermDyn).
- */
- tempW = 0;/* PASR = 0,*/
-
- /* Retrieve normal settings of the MRS control word and clear Rtt_WR */
- if (is_fam15h()) {
- tempW = mct_MR2(pMCTstat, pDCTstat, dct, dimm*2+rank) & 0xffff;
- tempW &= ~(0x0600);
- } else {
- /* program MrsAddress[7,6,5:3]=SRT,ASR,CWL,
- * based on F2x[1,0]84[19,18,22:20]=,SRT,ASR,Tcwl */
- tempW1 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_MRS_REGISTER, PCI_MIN_LOW, PCI_MAX_HIGH);
- if (bitTest(tempW1,19))
- {tempW = bitTestSet(tempW, 7);}
- if (bitTest(tempW1,18))
- {tempW = bitTestSet(tempW, 6);}
- /* tempW = tempW|(((tempW1 >> 20) & 0x7)<< 3); */
- tempW = tempW|((tempW1&0x00700000) >> 17);
- /* workaround for DR-B0 */
- if ((pDCTData->LogicalCPUID & AMD_DR_Bx) && (pDCTData->Status[DCT_STATUS_REGISTERED]))
- tempW+=0x8;
- }
-
- /* determine Rtt_WR for WL & Normal mode */
- if (is_fam15h()) {
- tempW1 = (fam15_rttwr(pDCTstat, dct, dimm, rank, package_type) << 9);
- } else {
- if (pDCTData->Status[DCT_STATUS_REGISTERED])
- tempW1 = RttWrRegDimm(pMCTData, pDCTData, dimm, wl, MemClkFreq, rank);
- else
- tempW1 = unbuffered_dimm_dynamic_termination_emrs(pDCTData->MaxDimmsInstalled, MemClkFreq, pDCTData->DimmRanks[dimm]);
- }
-
- /* Apply Rtt_WR to the MRS control word */
- tempW = tempW|tempW1;
- tempW = swapAddrBits_wl(pDCTstat, dct, tempW);
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsAddressStartFam15, MrsAddressEndFam15, tempW);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsAddressStartFam10, MrsAddressEndFam10, tempW);
-
- /* Program F2x[1, 0]7C[SendMrsCmd]=1 to initiate the command to
- the specified DIMM.*/
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, SendMrsCmd, SendMrsCmd, 1);
-
- /* Wait for F2x[1, 0]7C[SendMrsCmd] to be cleared by hardware. */
- while ((get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, SendMrsCmd, SendMrsCmd)) == 0x1)
- {
- }
-
- rank++;
- }
-
- /* Configure the non-target DIMM normally. */
- currDimm = 0;
- while (currDimm < MAX_LDIMMS)
- {
- if (pDCTData->DimmPresent[currDimm])
- {
- if (currDimm != dimm)
- {
- rank = 0;
- while ((rank < pDCTData->DimmRanks[currDimm]) && (rank < 2))
- {
- /* Program F2x[1, 0]7C[MrsChipSel[2:0]] for the current rank
- * to be trained.
- */
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsChipSelStartFam15, MrsChipSelEndFam15, currDimm*2+rank);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsChipSelStartFam10, MrsChipSelEndFam10, currDimm*2+rank);
-
- /* Program F2x[1, 0]7C[MrsBank[2:0]] for the appropriate internal
- * DRAM register that defines the required DDR3-defined function
- * for write levelization.
- */
- MrsBank = swapBankBits(pDCTstat, dct, 1);
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsBankStartFam15, MrsBankEndFam15, MrsBank);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsBankStartFam10, MrsBankEndFam10, MrsBank);
-
- /* Program F2x[1, 0]7C[MrsAddress[15:0]] to the required
- * DDR3-defined function for write levelization.
- */
- tempW = 0;/* DLL_DIS = 0, DIC = 0, AL = 0, TDQS = 0, Level = 0, Qoff = 0 */
-
- /* Retrieve normal settings of the MRS control word and clear Rtt_Nom */
- if (is_fam15h()) {
- tempW = mct_MR1(pMCTstat, pDCTstat, dct, currDimm*2+rank) & 0xffff;
- tempW &= ~(0x0244);
- } else {
- /* Set TDQS = 1b for x8 DIMM, TDQS = 0b for x4 DIMM, when mixed x8 & x4 */
- tempW2 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_CONFIG_HIGH, RDqsEn, RDqsEn);
- if (tempW2)
- {
- if (pDCTData->DimmX8Present[currDimm])
- tempW |= 0x800;
- }
- }
-
- /* determine Rtt_Nom for WL & Normal mode */
- if (is_fam15h()) {
- tempW2 = fam15_rttnom(pDCTstat, dct, dimm, rank, package_type);
- tempW1 = 0;
- tempW1 |= ((tempW2 & 0x4) >> 2) << 9;
- tempW1 |= ((tempW2 & 0x2) >> 1) << 6;
- tempW1 |= ((tempW2 & 0x1) >> 0) << 2;
- } else {
- if (pDCTData->Status[DCT_STATUS_REGISTERED])
- tempW1 = RttNomNonTargetRegDimm(pMCTData, pDCTData, currDimm, wl, MemClkFreq, rank);
- else
- tempW1 = unbuffered_dimm_nominal_termination_emrs(pDCTData->MaxDimmsInstalled, MemClkFreq, pDCTData->DimmRanks[currDimm], rank);
- }
-
- /* Apply Rtt_Nom to the MRS control word */
- tempW = tempW|tempW1;
-
- /* Program MrsAddress[5,1]=output driver impedance control (DIC) */
- if (is_fam15h()) {
- tempW1 = fam15_dimm_dic(pDCTstat, dct, dimm, rank, package_type);
- } else {
- /* Read DIC from F2x[1,0]84[DrvImpCtrl] */
- tempW1 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_MRS_REGISTER, DrvImpCtrlStart, DrvImpCtrlEnd);
- }
-
- /* Apply DIC to the MRS control word */
- if (bitTest(tempW1,1))
- {tempW = bitTestSet(tempW, 5);}
- if (bitTest(tempW1,0))
- {tempW = bitTestSet(tempW, 1);}
-
- tempW = swapAddrBits_wl(pDCTstat, dct, tempW);
-
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsAddressStartFam15, MrsAddressEndFam15, tempW);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, MrsAddressStartFam10, MrsAddressEndFam10, tempW);
-
- /* Program F2x[1, 0]7C[SendMrsCmd]=1 to initiate the command
- * to the specified DIMM.
- */
- set_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, SendMrsCmd, SendMrsCmd, 1);
-
- /* Wait for F2x[1, 0]7C[SendMrsCmd] to be cleared by hardware. */
- while ((get_Bits(pDCTData, dct,
- pDCTData->NodeId, FUN_DCT, DRAM_INIT,
- SendMrsCmd, SendMrsCmd)) == 1);
-
- /* Program F2x[1, 0]7C[MrsBank[2:0]] for the appropriate internal DRAM
- * register that defines the required DDR3-defined function for Rtt_WR.
- */
- MrsBank = swapBankBits(pDCTstat, dct, 2);
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsBankStartFam15, MrsBankEndFam15, MrsBank);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsBankStartFam10, MrsBankEndFam10, MrsBank);
-
- /* Program F2x[1, 0]7C[MrsAddress[15:0]] to the required DDR3-defined function
- * for Rtt_WR (DRAMTermDyn).
- */
- tempW = 0;/* PASR = 0,*/
-
- /* Retrieve normal settings of the MRS control word and clear Rtt_WR */
- if (is_fam15h()) {
- tempW = mct_MR2(pMCTstat, pDCTstat, dct, currDimm*2+rank) & 0xffff;
- tempW &= ~(0x0600);
- } else {
- /* program MrsAddress[7,6,5:3]=SRT,ASR,CWL,
- * based on F2x[1,0]84[19,18,22:20]=,SRT,ASR,Tcwl */
- tempW1 = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_MRS_REGISTER, PCI_MIN_LOW, PCI_MAX_HIGH);
- if (bitTest(tempW1,19))
- {tempW = bitTestSet(tempW, 7);}
- if (bitTest(tempW1,18))
- {tempW = bitTestSet(tempW, 6);}
- /* tempW = tempW|(((tempW1 >> 20) & 0x7) << 3); */
- tempW = tempW|((tempW1&0x00700000) >> 17);
- /* workaround for DR-B0 */
- if ((pDCTData->LogicalCPUID & AMD_DR_Bx) && (pDCTData->Status[DCT_STATUS_REGISTERED]))
- tempW+=0x8;
- }
-
- /* determine Rtt_WR for WL & Normal mode */
- if (is_fam15h()) {
- tempW1 = (fam15_rttwr(pDCTstat, dct, dimm, rank, package_type) << 9);
- } else {
- if (pDCTData->Status[DCT_STATUS_REGISTERED])
- tempW1 = RttWrRegDimm(pMCTData, pDCTData, currDimm, wl, MemClkFreq, rank);
- else
- tempW1 = unbuffered_dimm_dynamic_termination_emrs(pDCTData->MaxDimmsInstalled, MemClkFreq, pDCTData->DimmRanks[currDimm]);
- }
-
- /* Apply Rtt_WR to the MRS control word */
- tempW = tempW|tempW1;
- tempW = swapAddrBits_wl(pDCTstat, dct, tempW);
- if (is_fam15h())
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsAddressStartFam15, MrsAddressEndFam15, tempW);
- else
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, MrsAddressStartFam10, MrsAddressEndFam10, tempW);
-
- /* Program F2x[1, 0]7C[SendMrsCmd]=1 to initiate the command to
- the specified DIMM.*/
- set_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_INIT, SendMrsCmd, SendMrsCmd, 1);
-
- /* Wait for F2x[1, 0]7C[SendMrsCmd] to be cleared by hardware. */
- while ((get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_INIT, SendMrsCmd, SendMrsCmd)) == 0x1)
- {
- }
- rank++;
- }
- }
- }
- currDimm++;
- }
-}
-
-/*-----------------------------------------------------------------------------
- * void programODT(sMCTStruct *pMCTData, DCTStruct *DCTData, u8 dimm)
- *
- * Description:
- * This function programs the ODT values for the NB
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * IN
- * OUT
- * ----------------------------------------------------------------------------
- */
-void programODT(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm)
-{
- sMCTStruct *pMCTData = pDCTstat->C_MCTPtr;
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
-
- u8 WrLvOdt1 = 0;
-
- if (is_fam15h()) {
- /* On Family15h processors, the value for the specific CS being targeted
- * is taken from F2x238 / F2x23C as appropriate, then loaded into F2x9C_x0000_0008
- */
-
- /* Convert DIMM number to CS */
- uint32_t dword;
- uint8_t cs;
- uint8_t rank = 0;
-
- cs = (dimm * 2) + rank;
-
- /* Fetch preprogammed ODT pattern from configuration registers */
- dword = Get_NB32_DCT(pDCTstat->dev_dct, dct, ((cs > 3)?0x23c:0x238));
- if ((cs == 7) || (cs == 3))
- WrLvOdt1 = ((dword >> 24) & 0xf);
- else if ((cs == 6) || (cs == 2))
- WrLvOdt1 = ((dword >> 16) & 0xf);
- else if ((cs == 5) || (cs == 1))
- WrLvOdt1 = ((dword >> 8) & 0xf);
- else if ((cs == 4) || (cs == 0))
- WrLvOdt1 = (dword & 0xf);
- } else {
- if (pDCTData->Status[DCT_STATUS_REGISTERED]) {
- WrLvOdt1 = WrLvOdtRegDimm(pMCTData, pDCTData, dimm);
- } else {
- if ((pDCTData->DctCSPresent & 0x05) == 0x05) {
- WrLvOdt1 = 0x03;
- } else if (bitTest((u32)pDCTData->DctCSPresent,(u8)(dimm*2+1))) {
- WrLvOdt1 = (u8)bitTestSet(WrLvOdt1, dimm+2);
- } else {
- WrLvOdt1 = (u8)bitTestSet(WrLvOdt1, dimm);
- }
- }
- }
-
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_ADD_DCT_PHY_CONTROL_REG, 8, 11, (u32)WrLvOdt1);
-
- printk(BIOS_SPEW, "Programmed DCT %d write levelling ODT pattern %08x from DIMM %d data\n", dct, WrLvOdt1, dimm);
-
-}
-
-#ifdef UNUSED_CODE
-static uint16_t fam15h_next_lowest_memclk_freq(uint16_t memclk_freq)
-{
- uint16_t fam15h_next_lowest_freq_tab[] = {0, 0, 0, 0, 0x4, 0, 0x4, 0, 0, 0, 0x6, 0, 0, 0, 0xa, 0, 0, 0, 0xe, 0, 0, 0, 0x12};
- return fam15h_next_lowest_freq_tab[memclk_freq];
-}
-#endif
-
-/*-----------------------------------------------------------------------------
- * void procConfig(MCTStruct *MCTData,DCTStruct *DCTData, u8 Dimm, u8 Pass, u8 Nibble)
- *
- * Description:
- * This function programs the ODT values for the NB
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * *MCTData - Pointer to buffer with runtime parameters,
- * IN Dimm - Logical DIMM
- * Pass - First of Second Pass
- * OUT
- * ----------------------------------------------------------------------------
- */
-void procConfig(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat, uint8_t dct, uint8_t dimm, uint8_t pass, uint8_t nibble)
-{
- u8 ByteLane, MemClkFreq;
- int32_t Seed_Gross;
- int32_t Seed_Fine;
- uint8_t Seed_PreGross;
- u32 Value, Addr;
- uint32_t dword;
- u16 Addl_Data_Offset, Addl_Data_Port;
- sMCTStruct *pMCTData = pDCTstat->C_MCTPtr;
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- uint16_t fam10h_freq_tab[] = {0, 0, 0, 400, 533, 667, 800};
- uint16_t fam15h_freq_tab[] = {0, 0, 0, 0, 333, 0, 400, 0, 0, 0, 533, 0, 0, 0, 667, 0, 0, 0, 800, 0, 0, 0, 933};
- uint8_t lane_count;
-
- lane_count = get_available_lane_count(pMCTstat, pDCTstat);
-
- assert(lane_count <= MAX_LANE_COUNT);
-
- if (is_fam15h()) {
- /* MemClkFreq: 0x4: 333MHz; 0x6: 400MHz; 0xa: 533MHz; 0xe: 667MHz; 0x12: 800MHz; 0x16: 933MHz */
- MemClkFreq = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_CONFIG_HIGH, 0, 4);
- } else {
- /* MemClkFreq: 3: 400MHz; 4: 533MHz; 5: 667MHz; 6: 800MHz */
- MemClkFreq = get_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, DRAM_CONFIG_HIGH, 0, 2);
- }
-
- /* Program F2x[1, 0]9C_x08[WrLvOdt[3:0]] to the proper ODT settings for the
- * current memory subsystem configuration.
- */
- programODT(pMCTstat, pDCTstat, dct, dimm);
-
- /* Program F2x[1,0]9C_x08[WrLvOdtEn]=1 */
- if (pDCTData->LogicalCPUID & (AMD_DR_Cx | AMD_DR_Dx | AMD_FAM15_ALL)) {
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_ADD_DCT_PHY_CONTROL_REG, WrLvOdtEn, WrLvOdtEn, (u32)1);
- }
- else
- {
- /* Program WrLvOdtEn = 1 through set bit 12 of D3CSODT reg offset 0 for Rev.B */
- if (dct)
- {
- Addl_Data_Offset = 0x198;
- Addl_Data_Port = 0x19C;
- }
- else
- {
- Addl_Data_Offset = 0x98;
- Addl_Data_Port = 0x9C;
- }
- Addr = 0x0D008000;
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+(pDCTData->NodeId),FUN_DCT,Addl_Data_Offset), 31, 0, &Addr);
- while ((get_Bits(pDCTData,FUN_DCT,pDCTData->NodeId, FUN_DCT, Addl_Data_Offset,
- DctAccessDone, DctAccessDone)) == 0);
- AmdMemPCIReadBits(MAKE_SBDFO(0,0,24+(pDCTData->NodeId),FUN_DCT,Addl_Data_Port), 31, 0, &Value);
- Value = bitTestSet(Value, 12);
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+(pDCTData->NodeId),FUN_DCT,Addl_Data_Port), 31, 0, &Value);
- Addr = 0x4D088F00;
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+(pDCTData->NodeId),FUN_DCT,Addl_Data_Offset), 31, 0, &Addr);
- while ((get_Bits(pDCTData,FUN_DCT,pDCTData->NodeId, FUN_DCT, Addl_Data_Offset,
- DctAccessDone, DctAccessDone)) == 0);
- }
-
- if (is_fam15h())
- proc_MFENCE();
-
- /* Wait 10 MEMCLKs to allow for ODT signal settling. */
- if (is_fam15h())
- precise_memclk_delay_fam15(pMCTstat, pDCTstat, dct, 10);
- else
- pMCTData->AgesaDelay(10);
-
- /* Program write levelling seed values */
- if (pass == 1)
- {
- /* Pass 1 */
- if (is_fam15h()) {
- uint8_t AddrCmdPrelaunch = 0; /* TODO: Fetch the correct value from RC2[0] */
- uint8_t package_type = mctGet_NVbits(NV_PACK_TYPE);
- uint16_t Seed_Total = 0;
- pDCTData->WrDqsGrossDlyBaseOffset = 0x0;
- if (package_type == PT_GR) {
- /* Socket G34: Fam15h BKDG v3.14 Table 96 */
- if (pDCTData->Status[DCT_STATUS_REGISTERED]) {
- /* TODO
- * Implement mainboard-specific seed and
- * WrDqsGrossDly base overrides.
- * 0x41 and 0x0 are the "stock" values
- */
- Seed_Total = 0x41;
- pDCTData->WrDqsGrossDlyBaseOffset = 0x2;
- } else if (pDCTData->Status[DCT_STATUS_LOAD_REDUCED]) {
- Seed_Total = 0x0;
- } else {
- Seed_Total = 0xf;
- }
- } else if (package_type == PT_C3) {
- /* Socket C32: Fam15h BKDG v3.14 Table 97 */
- if (pDCTData->Status[DCT_STATUS_REGISTERED]) {
- Seed_Total = 0x3e;
- } else if (pDCTData->Status[DCT_STATUS_LOAD_REDUCED]) {
- Seed_Total = 0x0;
- } else {
- Seed_Total = 0x12;
- }
- } else if (package_type == PT_M2) {
- /* Socket AM3: Fam15h BKDG v3.14 Table 98 */
- Seed_Total = 0xf;
- } else if (package_type == PT_FM2) {
- /* Socket FM2: Fam15h M10 BKDG 3.12 Table 42 */
- Seed_Total = 0x15;
- }
- if (pDCTData->Status[DCT_STATUS_REGISTERED])
- Seed_Total += ((AddrCmdPrelaunch)?0x10:0x0);
-
- /* Adjust seed for the minimum platform supported frequency */
- Seed_Total = (int32_t) (((((int64_t) Seed_Total) *
- fam15h_freq_tab[MemClkFreq] * 100) / (mctGet_NVbits(NV_MIN_MEMCLK) * 100)));
-
- Seed_Gross = (Seed_Total >> 5) & 0x1f;
- Seed_Fine = Seed_Total & 0x1f;
-
- /* Save seed values for later use */
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- pDCTData->WLSeedGrossDelay[lane_count*dimm+ByteLane] = Seed_Gross;
- pDCTData->WLSeedFineDelay[lane_count*dimm+ByteLane] = Seed_Fine;
-
- if (Seed_Gross == 0)
- Seed_PreGross = 0;
- else if (Seed_Gross & 0x1)
- Seed_PreGross = 1;
- else
- Seed_PreGross = 2;
-
- pDCTData->WLSeedPreGrossDelay[lane_count*dimm+ByteLane] = Seed_PreGross;
- }
- } else {
- if (pDCTData->Status[DCT_STATUS_REGISTERED]) {
- uint8_t AddrCmdPrelaunch = 0; /* TODO: Fetch the correct value from RC2[0] */
-
- /* The seed values below assume Pass 1 utilizes a 400MHz clock frequency (DDR3-800) */
- if (AddrCmdPrelaunch == 0) {
- Seed_Gross = 0x02;
- Seed_Fine = 0x01;
- } else {
- Seed_Gross = 0x02;
- Seed_Fine = 0x11;
- }
- } else {
- if (MemClkFreq == 6) {
- /* DDR-800 */
- Seed_Gross = 0x00;
- Seed_Fine = 0x1a;
- } else {
- /* Use settings for DDR-400 (interpolated from BKDG) */
- Seed_Gross = 0x00;
- Seed_Fine = 0x0d;
- }
- }
- }
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++)
- {
- /* Program an initialization value to registers F2x[1, 0]9C_x[51:50] and
- * F2x[1, 0]9C_x52 to set the gross and fine delay for all the byte lane fields
- * If the target frequency is different than 400MHz, BIOS must
- * execute two training passes for each DIMM.
- * For pass 1 at a 400MHz MEMCLK frequency, use an initial total delay value
- * of 01Fh. This represents a 1UI (UI=.5MEMCLK) delay and is determined
- * by design.
- */
- pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] = Seed_Gross;
- pDCTData->WLFineDelay[lane_count*dimm+ByteLane] = Seed_Fine;
- printk(BIOS_SPEW, "\tLane %02x initial seed: %04x\n", ByteLane, ((Seed_Gross & 0x1f) << 5) | (Seed_Fine & 0x1f));
- }
- } else {
- if (nibble == 0) {
- /* Pass 2 */
- /* From BKDG, Write Leveling Seed Value. */
- if (is_fam15h()) {
- uint32_t RegisterDelay;
- int32_t SeedTotal[MAX_LANE_COUNT];
- int32_t SeedTotalPreScaling[MAX_LANE_COUNT];
- uint32_t WrDqDqsEarly;
- uint8_t AddrCmdPrelaunch = 0; /* TODO: Fetch the correct value from RC2[0] */
-
- if (pDCTData->Status[DCT_STATUS_REGISTERED]) {
- if (AddrCmdPrelaunch)
- RegisterDelay = 0x30;
- else
- RegisterDelay = 0x20;
- } else {
- RegisterDelay = 0;
- }
-
- /* Retrieve WrDqDqsEarly */
- dword = Get_NB32_DCT(pDCTstat->dev_dct, dct, 0xa8);
- WrDqDqsEarly = (dword >> 24) & 0x3;
-
- /* FIXME
- * Ignore WrDqDqsEarly for now to work around training issues
- */
- WrDqDqsEarly = 0;
-
- /* Generate new seed values */
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- /* Calculate adjusted seed values */
- SeedTotal[ByteLane] = (pDCTData->WLFineDelayPrevPass[lane_count*dimm+ByteLane] & 0x1f) |
- ((pDCTData->WLGrossDelayPrevPass[lane_count*dimm+ByteLane] & 0x1f) << 5);
- SeedTotalPreScaling[ByteLane] = (SeedTotal[ByteLane] - RegisterDelay - (0x20 * WrDqDqsEarly));
- SeedTotal[ByteLane] = (int32_t) (RegisterDelay + ((((int64_t) SeedTotalPreScaling[ByteLane]) *
- fam15h_freq_tab[MemClkFreq] * 100) / (fam15h_freq_tab[pDCTData->WLPrevMemclkFreq[dimm]] * 100)));
- }
-
- /* Generate register values from seeds */
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- printk(BIOS_SPEW, "\tLane %02x scaled delay: %04x\n", ByteLane, SeedTotal[ByteLane]);
-
- if (SeedTotal[ByteLane] >= 0) {
- Seed_Gross = SeedTotal[ByteLane] / 32;
- Seed_Fine = SeedTotal[ByteLane] % 32;
- } else {
- Seed_Gross = (SeedTotal[ByteLane] / 32) - 1;
- Seed_Fine = (SeedTotal[ByteLane] % 32) + 32;
- }
-
- /* The BKDG-recommended algorithm causes problems with registered DIMMs on some systems
- * due to the long register delays causing premature total delay wrap-around.
- * Attempt to work around this...
- */
- Seed_PreGross = Seed_Gross;
-
- /* Save seed values for later use */
- pDCTData->WLSeedGrossDelay[lane_count*dimm+ByteLane] = Seed_Gross;
- pDCTData->WLSeedFineDelay[lane_count*dimm+ByteLane] = Seed_Fine;
- pDCTData->WLSeedPreGrossDelay[lane_count*dimm+ByteLane] = Seed_PreGross;
-
- pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] = Seed_PreGross;
- pDCTData->WLFineDelay[lane_count*dimm+ByteLane] = Seed_Fine;
-
- printk(BIOS_SPEW, "\tLane %02x new seed: %04x\n", ByteLane, ((pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] & 0x1f) << 5) | (pDCTData->WLFineDelay[lane_count*dimm+ByteLane] & 0x1f));
- }
- } else {
- uint32_t RegisterDelay;
- uint32_t SeedTotalPreScaling;
- uint32_t SeedTotal;
- uint8_t AddrCmdPrelaunch = 0; /* TODO: Fetch the correct value from RC2[0] */
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++)
- {
- if (pDCTData->Status[DCT_STATUS_REGISTERED]) {
- if (AddrCmdPrelaunch == 0)
- RegisterDelay = 0x20;
- else
- RegisterDelay = 0x30;
- } else {
- RegisterDelay = 0;
- }
- SeedTotalPreScaling = ((pDCTData->WLFineDelay[lane_count*dimm+ByteLane] & 0x1f) |
- (pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] << 5)) - RegisterDelay;
- /* SeedTotalPreScaling = (the total delay value in F2x[1, 0]9C_x[4A:30] from pass 1 of write levelization
- training) - RegisterDelay. */
- SeedTotal = (uint16_t) ((((uint64_t) SeedTotalPreScaling) *
- fam10h_freq_tab[MemClkFreq] * 100) / (fam10h_freq_tab[3] * 100));
- Seed_Gross = SeedTotal / 32;
- Seed_Fine = SeedTotal & 0x1f;
- if (Seed_Gross == 0)
- Seed_Gross = 0;
- else if (Seed_Gross & 0x1)
- Seed_Gross = 1;
- else
- Seed_Gross = 2;
-
- /* The BKDG-recommended algorithm causes problems with registered DIMMs on some systems
- * due to the long register delays causing premature total delay wrap-around.
- * Attempt to work around this...
- */
- SeedTotal = ((Seed_Gross & 0x1f) << 5) | (Seed_Fine & 0x1f);
- SeedTotal += RegisterDelay;
- Seed_Gross = SeedTotal / 32;
- Seed_Fine = SeedTotal & 0x1f;
-
- pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] = Seed_Gross;
- pDCTData->WLFineDelay[lane_count*dimm+ByteLane] = Seed_Fine;
-
- printk(BIOS_SPEW, "\tLane %02x new seed: %04x\n", ByteLane, ((pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] & 0x1f) << 5) | (pDCTData->WLFineDelay[lane_count*dimm+ByteLane] & 0x1f));
- }
- }
-
- /* Save initial seeds for upper nibble pass */
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- pDCTData->WLSeedPreGrossPrevNibble[lane_count*dimm+ByteLane] = pDCTData->WLSeedPreGrossDelay[lane_count*dimm+ByteLane];
- pDCTData->WLSeedGrossPrevNibble[lane_count*dimm+ByteLane] = pDCTData->WLGrossDelay[lane_count*dimm+ByteLane];
- pDCTData->WLSeedFinePrevNibble[lane_count*dimm+ByteLane] = pDCTData->WLFineDelay[lane_count*dimm+ByteLane];
- }
- } else {
- /* Restore seed values from lower nibble pass */
- if (is_fam15h()) {
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- pDCTData->WLSeedGrossDelay[lane_count*dimm+ByteLane] = pDCTData->WLSeedGrossPrevNibble[lane_count*dimm+ByteLane];
- pDCTData->WLSeedFineDelay[lane_count*dimm+ByteLane] = pDCTData->WLSeedFinePrevNibble[lane_count*dimm+ByteLane];
- pDCTData->WLSeedPreGrossDelay[lane_count*dimm+ByteLane] = pDCTData->WLSeedPreGrossPrevNibble[lane_count*dimm+ByteLane];
-
- pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] = pDCTData->WLSeedPreGrossPrevNibble[lane_count*dimm+ByteLane];
- pDCTData->WLFineDelay[lane_count*dimm+ByteLane] = pDCTData->WLSeedFinePrevNibble[lane_count*dimm+ByteLane];
-
- printk(BIOS_SPEW, "\tLane %02x new seed: %04x\n", ByteLane, ((pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] & 0x1f) << 5) | (pDCTData->WLFineDelay[lane_count*dimm+ByteLane] & 0x1f));
- }
- } else {
- for (ByteLane = 0; ByteLane < lane_count; ByteLane++) {
- pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] = pDCTData->WLSeedGrossPrevNibble[lane_count*dimm+ByteLane];
- pDCTData->WLFineDelay[lane_count*dimm+ByteLane] = pDCTData->WLSeedFinePrevNibble[lane_count*dimm+ByteLane];
-
- printk(BIOS_SPEW, "\tLane %02x new seed: %04x\n", ByteLane, ((pDCTData->WLGrossDelay[lane_count*dimm+ByteLane] & 0x1f) << 5) | (pDCTData->WLFineDelay[lane_count*dimm+ByteLane] & 0x1f));
- }
- }
- }
- }
-
- pDCTData->WLPrevMemclkFreq[dimm] = MemClkFreq;
- setWLByteDelay(pDCTstat, dct, ByteLane, dimm, 0, pass, lane_count);
-}
-
-/*-----------------------------------------------------------------------------
- * void setWLByteDelay(struct DCTStatStruc *pDCTstat, uint8_t dct, u8 ByteLane, u8 Dimm, uint8_t lane_count){
- *
- * Description:
- * This function writes the write levelization byte delay for the Phase
- * Recovery control registers
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * IN Dimm - Dimm Number
- * DCTData->WLGrossDelay[index+ByteLane] - gross write delay for each
- * logical DIMM
- * DCTData->WLFineDelay[index+ByteLane] - fine write delay for each
- * logical DIMM
- * ByteLane - target byte lane to write
- * targetAddr - 0: write to DRAM phase recovery control register
- * 1: write to DQS write register
- * OUT
- *
- *-----------------------------------------------------------------------------
- */
-void setWLByteDelay(struct DCTStatStruc *pDCTstat, uint8_t dct, u8 ByteLane, u8 dimm, u8 targetAddr, uint8_t pass, uint8_t lane_count)
-{
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- u8 fineStartLoc, fineEndLoc, grossStartLoc, grossEndLoc, tempB, index, offsetAddr;
- u32 addr, fineDelayValue, grossDelayValue, ValueLow, ValueHigh, EccValue, tempW;
-
- if (targetAddr == 0)
- {
- index = (u8)(lane_count * dimm);
- ValueLow = 0;
- ValueHigh = 0;
- ByteLane = 0;
- EccValue = 0;
- while (ByteLane < lane_count)
- {
- /* This subtract 0xC workaround might be temporary. */
- if ((pDCTData->WLPass == 2) && (pDCTData->RegMan1Present & (1 << (dimm*2+dct)))) {
- tempW = (pDCTData->WLGrossDelay[index+ByteLane] << 5) | pDCTData->WLFineDelay[index+ByteLane];
- tempW -= 0xC;
- pDCTData->WLGrossDelay[index+ByteLane] = (u8)(tempW >> 5);
- pDCTData->WLFineDelay[index+ByteLane] = (u8)(tempW & 0x1F);
- }
- grossDelayValue = pDCTData->WLGrossDelay[index+ByteLane];
- /* Adjust seed gross delay overflow (greater than 3):
- * - Program seed gross delay as 2 (gross is 4 or 6) or 1 (gross is 5).
- * - Keep original seed gross delay for later reference.
- */
- if (grossDelayValue >= 3)
- grossDelayValue = (grossDelayValue&1)? 1 : 2;
- fineDelayValue = pDCTData->WLFineDelay[index+ByteLane];
- if (ByteLane < 4)
- ValueLow |= ((grossDelayValue << 5) | fineDelayValue) << 8*ByteLane;
- else if (ByteLane < 8)
- ValueHigh |= ((grossDelayValue << 5) | fineDelayValue) << 8*(ByteLane-4);
- else
- EccValue = ((grossDelayValue << 5) | fineDelayValue);
- ByteLane++;
- }
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_CONT_ADD_PHASE_REC_CTRL_LOW, 0, 31, (u32)ValueLow);
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_CONT_ADD_PHASE_REC_CTRL_HIGH, 0, 31, (u32)ValueHigh);
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- DRAM_CONT_ADD_ECC_PHASE_REC_CTRL, 0, 31, (u32)EccValue);
- }
- else
- {
- /* Fam10h BKDG: Rev. 3.62 2.8.9.9.1 (6)
- * Fam15h BKDG: Rev. 3.14 2.10.5.8.1
- */
- index = (u8)(lane_count * dimm);
- grossDelayValue = pDCTData->WLGrossDelay[index+ByteLane];
- fineDelayValue = pDCTData->WLFineDelay[index+ByteLane];
-
- tempB = 0;
- offsetAddr = (u8)(3 * dimm);
- if (ByteLane < 2) {
- tempB = (u8)(16 * ByteLane);
- addr = DRAM_CONT_ADD_DQS_TIMING_CTRL_BL_01;
- } else if (ByteLane <4) {
- tempB = (u8)(16 * ByteLane);
- addr = DRAM_CONT_ADD_DQS_TIMING_CTRL_BL_01 + 1;
- } else if (ByteLane <6) {
- tempB = (u8)(16 * ByteLane);
- addr = DRAM_CONT_ADD_DQS_TIMING_CTRL_BL_45;
- } else if (ByteLane <8) {
- tempB = (u8)(16 * ByteLane);
- addr = DRAM_CONT_ADD_DQS_TIMING_CTRL_BL_45 + 1;
- } else {
- tempB = 0;
- addr = DRAM_CONT_ADD_DQS_TIMING_CTRL_BL_01 + 2;
- }
- addr += offsetAddr;
-
- fineStartLoc = (u8)(tempB % 32);
- fineEndLoc = (u8)(fineStartLoc + 4);
- grossStartLoc = (u8)(fineEndLoc + 1);
- grossEndLoc = (u8)(grossStartLoc + 2);
-
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- (u16)addr, fineStartLoc, fineEndLoc,(u32)fineDelayValue);
- set_DCT_ADDR_Bits(pDCTData, dct, pDCTData->NodeId, FUN_DCT,
- (u16)addr, grossStartLoc, grossEndLoc, (u32)grossDelayValue);
-
- pDCTData->WLFineDelayPrevPass[index+ByteLane] = fineDelayValue;
- pDCTData->WLGrossDelayPrevPass[index+ByteLane] = grossDelayValue;
- if (pass == FirstPass) {
- pDCTData->WLFineDelayFirstPass[index+ByteLane] = fineDelayValue;
- pDCTData->WLGrossDelayFirstPass[index+ByteLane] = grossDelayValue;
- pDCTData->WLCriticalGrossDelayFirstPass = pDCTData->WLCriticalGrossDelayPrevPass;
- }
- }
-
-}
-
-/*-----------------------------------------------------------------------------
- * void getWLByteDelay(struct DCTStatStruc *pDCTstat, uint8_t dct, u8 ByteLane, u8 Dimm, u8 Nibble, uint8_t lane_count)
- *
- * Description:
- * This function reads the write levelization byte delay from the Phase
- * Recovery control registers
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * IN Dimm - Dimm Number
- * ByteLane - target byte lane to read
- * OUT
- * DCTData->WLGrossDelay[index+ByteLane] - gross write delay for current
- * byte for logical DIMM
- * DCTData->WLFineDelay[index+ByteLane] - fine write delay for current
- * byte for logical DIMM
- *
- *-----------------------------------------------------------------------------
- */
-void getWLByteDelay(struct DCTStatStruc *pDCTstat, uint8_t dct, u8 ByteLane, u8 dimm, uint8_t pass, uint8_t nibble, uint8_t lane_count)
-{
- sDCTStruct *pDCTData = pDCTstat->C_DCTPtr[dct];
- u8 fineStartLoc, fineEndLoc, grossStartLoc, grossEndLoc, tempB, tempB1, index;
- u32 addr, fine, gross;
- tempB = 0;
- index = (u8)(lane_count*dimm);
- if (ByteLane < 4) {
- tempB = (u8)(8 * ByteLane);
- addr = DRAM_CONT_ADD_PHASE_REC_CTRL_LOW;
- } else if (ByteLane < 8) {
- tempB1 = (u8)(ByteLane - 4);
- tempB = (u8)(8 * tempB1);
- addr = DRAM_CONT_ADD_PHASE_REC_CTRL_HIGH;
- } else {
- tempB = 0;
- addr = DRAM_CONT_ADD_ECC_PHASE_REC_CTRL;
- }
- fineStartLoc = tempB;
- fineEndLoc = (u8)(fineStartLoc + 4);
- grossStartLoc = (u8)(fineEndLoc + 1);
- grossEndLoc = (u8)(grossStartLoc + 1);
-
- fine = get_ADD_DCT_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, (u16)addr, fineStartLoc, fineEndLoc);
- gross = get_ADD_DCT_Bits(pDCTData, dct, pDCTData->NodeId,
- FUN_DCT, (u16)addr, grossStartLoc, grossEndLoc);
-
- printk(BIOS_SPEW, "\tLane %02x nibble %01x raw readback: %04x\n", ByteLane, nibble, ((gross & 0x1f) << 5) | (fine & 0x1f));
-
- /* Adjust seed gross delay overflow (greater than 3):
- * - Adjust the trained gross delay to the original seed gross delay.
- */
- if (pDCTData->WLGrossDelay[index+ByteLane] >= 3)
- {
- gross += pDCTData->WLGrossDelay[index+ByteLane];
- if (pDCTData->WLGrossDelay[index+ByteLane] & 1)
- gross -= 1;
- else
- gross -= 2;
- }
- else if ((pDCTData->WLGrossDelay[index+ByteLane] == 0) && (gross == 3))
- {
- /* If seed gross delay is 0 but PRE result gross delay is 3, it is negative.
- * We will then round the negative number to 0.
- */
- gross = 0;
- fine = 0;
- }
- printk(BIOS_SPEW, "\tLane %02x nibble %01x adjusted value (pre nibble): %04x\n", ByteLane, nibble, ((gross & 0x1f) << 5) | (fine & 0x1f));
-
- /* Nibble adjustments */
- if (nibble == 0) {
- pDCTData->WLFineDelay[index+ByteLane] = (uint8_t)fine;
- pDCTData->WLGrossDelay[index+ByteLane] = (uint8_t)gross;
- } else {
- uint32_t WLTotalDelay = ((pDCTData->WLGrossDelay[index+ByteLane] & 0x1f) << 5) | (pDCTData->WLFineDelay[index+ByteLane] & 0x1f);
- WLTotalDelay += ((gross & 0x1f) << 5) | (fine & 0x1f);
- WLTotalDelay /= 2;
- pDCTData->WLFineDelay[index+ByteLane] = (uint8_t)(WLTotalDelay & 0x1f);
- pDCTData->WLGrossDelay[index+ByteLane] = (uint8_t)((WLTotalDelay >> 5) & 0x1f);
- }
- printk(BIOS_SPEW, "\tLane %02x nibble %01x adjusted value (post nibble): %04x\n", ByteLane, nibble, ((pDCTData->WLGrossDelay[index+ByteLane] & 0x1f) << 5) | (pDCTData->WLFineDelay[index+ByteLane] & 0x1f));
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/modtrd.c b/src/northbridge/amd/amdmct/mct_ddr3/modtrd.c
deleted file mode 100644
index 954dd6f2ef..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/modtrd.c
+++ /dev/null
@@ -1,95 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <stdint.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-u32 mct_MR1Odt_RDimm(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dct, u32 MrsChipSel)
-{
- u8 Speed = pDCTstat->Speed;
- u32 ret;
- u8 DimmsInstalled, DimmNum, ChipSelect;
-
- ChipSelect = (MrsChipSel >> 20) & 0xF;
- DimmNum = ChipSelect & 0xFE;
- DimmsInstalled = pDCTstat->MAdimms[dct];
- if (dct == 1)
- DimmNum ++;
- ret = 0;
-
- if (mctGet_NVbits(NV_MAX_DIMMS) == 4) {
- if (DimmsInstalled == 1)
- ret |= 1 << 2;
- else {
- if (pDCTstat->CSPresent & 0xF0) {
- if (pDCTstat->DimmQRPresent & (1 << DimmNum)) {
- if (!(ChipSelect & 1))
- ret |= 1 << 2;
- } else
- ret |= 0x204;
- } else {
- if (Speed < 6)
- ret |= 0x44;
- else
- ret |= 0x204;
- }
- }
- } else if (DimmsInstalled == 1)
- ret |= 1 << 2;
- else if (Speed < 6)
- ret |= 0x44;
- else
- ret |= 0x204;
-
- //ret = 0;
- return ret;
-}
-
-u32 mct_DramTermDyn_RDimm(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat, u8 dimm)
-{
- u8 DimmsInstalled = dimm;
- u32 DramTermDyn = 0;
- u8 Speed = pDCTstat->Speed;
-
- if (mctGet_NVbits(NV_MAX_DIMMS) == 4) {
- if (pDCTstat->CSPresent & 0xF0) {
- if (DimmsInstalled == 1)
- if (Speed == 7)
- DramTermDyn |= 1 << 10;
- else
- DramTermDyn |= 1 << 11;
- else
- if (Speed == 4)
- DramTermDyn |= 1 << 11;
- else
- DramTermDyn |= 1 << 10;
- } else {
- if (DimmsInstalled != 1) {
- if (Speed == 7)
- DramTermDyn |= 1 << 10;
- else
- DramTermDyn |= 1 << 11;
- }
- }
- } else {
- if (DimmsInstalled != 1)
- DramTermDyn |= 1 << 11;
- }
- return DramTermDyn;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/modtrdim.c b/src/northbridge/amd/amdmct/mct_ddr3/modtrdim.c
deleted file mode 100644
index 06bfdba84f..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/modtrdim.c
+++ /dev/null
@@ -1,262 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* This file contains functions for odt setting on registered DDR3 dimms */
-
-#include <stdint.h>
-#include <console/console.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-/**
- *
- *
- * This function set Rtt_Nom for registered DDR3 dimms on targeted dimm.
- *
- * @param *pMCTData
- * @param[in] *pDCTData - Pointer to buffer with information about each DCT
- * @param dimm - targeted dimm
- * @param wl - current mode, either write levelization mode or normal mode
- * @param MemClkFreq - current frequency
- * @param rank
- *
- * @return tempW1 - Rtt_Nom
- */
-u32 RttNomTargetRegDimm (sMCTStruct *pMCTData, sDCTStruct *pDCTData, u8 dimm, BOOL wl, u8 MemClkFreq, u8 rank)
-{
- u32 tempW1;
- tempW1 = 0;
- if (wl) {
- switch (mctGet_NVbits(NV_MAX_DIMMS_PER_CH)) {
- case 2:
- /* 2 dimms per channel */
- if (pDCTData->MaxDimmsInstalled == 1) {
- if ((pDCTData->DimmRanks[dimm] == 2) && (rank == 0)) {
- tempW1 = 0x00; /* Rtt_Nom = OFF */
- } else if (pDCTData->DimmRanks[dimm] == 4) {
- if (rank == 1) {
- tempW1 = 0x00; /* Rtt_Nom = OFF on second and forth rank of QR dimm */
- } else {
- if (MemClkFreq == 6) {
- tempW1 = 0x04; /* Rtt_Nom = 60 ohms */
- } else {
- tempW1 = 0x40; /* Rtt_Nom = 120 ohms */
- }
- }
- } else {
- tempW1 = 0x04; /* Rtt_Nom = 60 ohms */
- }
- } else if (pDCTData->MaxDimmsInstalled == 2) {
- if (((pDCTData->DimmRanks[dimm] == 2) || (pDCTData->DimmRanks[dimm] == 4)) && (rank == 1)) {
- tempW1 = 0x00; /* Rtt_Nom = OFF */
- } else if ((pDCTData->DimmRanks[dimm] == 4) || (pDCTData->DctCSPresent & 0xF0)) {
- if (MemClkFreq == 3) {
- tempW1 = 0x40; /* Rtt_Nom = 120 ohms */
- } else {
- tempW1 = 0x04; /* Rtt_Nom = 60 ohms */
- }
- } else {
- if (MemClkFreq == 6) {
- tempW1 = 0x04; /* Rtt_Nom = 60 ohms */
- } else {
- tempW1 = 0x40; /* Rtt_Nom = 120 ohms */
- }
- }
- }
- break;
- case 3:
- /* 3 dimms per channel */
- /* QR not supported in this case on L1 package. */
- if (pDCTData->MaxDimmsInstalled == 1) {
- if ((pDCTData->DimmRanks[dimm] == 2) && (rank == 1)) {
- tempW1 = 0x00; /* Rtt_Nom = OFF */
- } else {
- tempW1 = 0x04; /* Rtt_Nom = 60 ohms */
- }
- } else {
- tempW1 = 0x40; /* Rtt_Nom = 120 ohms */
- }
- break;
- default:
- die("modtrdim.c: WTF?");
- }
- } else {
- switch (mctGet_NVbits(NV_MAX_DIMMS_PER_CH)) {
- case 2:
- /* 2 dimms per channel */
- if ((pDCTData->DimmRanks[dimm] == 4) && (rank == 1)) {
- tempW1 = 0x00; /* Rtt_Nom = OFF */
- } else if ((pDCTData->MaxDimmsInstalled == 1) || (pDCTData->DimmRanks[dimm] == 4)) {
- tempW1 = 0x04; /* Rtt_Nom = 60 ohms */
- } else {
- if (pDCTData->DctCSPresent & 0xF0) {
- tempW1 = 0x0204; /* Rtt_Nom = 30 ohms */
- } else {
- if (MemClkFreq < 5) {
- tempW1 = 0x44; /* Rtt_Nom = 40 ohms */
- } else {
- tempW1 = 0x0204; /* Rtt_Nom = 30 ohms */
- }
- }
- }
- break;
- case 3:
- /* 3 dimms per channel */
- /* L1 package does not support QR dimms this case. */
- if (rank == 1) {
- tempW1 = 0x00; /* Rtt_Nom = OFF */
- } else if (pDCTData->MaxDimmsInstalled == 1) {
- tempW1 = 0x04; /* Rtt_Nom = 60 ohms */
- } else if ((MemClkFreq < 5) || (pDCTData->MaxDimmsInstalled == 3)) {
- tempW1 = 0x44; /* Rtt_Nom = 40 ohms */
- } else {
- tempW1 = 0x0204; /* Rtt_Nom = 30 ohms */
- }
- break;
- default:
- die("modtrdim.c: WTF?");
- }
- }
- return tempW1;
-}
-
-/* -----------------------------------------------------------------------------*/
-/**
- *
- *
- * This function set Rtt_Nom for registered DDR3 dimms on non-targeted dimm.
- *
- * @param *pMCTData
- * @param[in] *pDCTData - Pointer to buffer with information about each DCT
- * @param dimm - non-targeted dimm
- * @param wl - current mode, either write levelization mode or normal mode
- * @param MemClkFreq - current frequency
- * @param rank
- *
- * @return tempW1 - Rtt_Nom
- */
-u32 RttNomNonTargetRegDimm (sMCTStruct *pMCTData, sDCTStruct *pDCTData, u8 dimm, BOOL wl, u8 MemClkFreq, u8 rank)
-{
- if ((wl) && (mctGet_NVbits(NV_MAX_DIMMS_PER_CH) == 2) && (pDCTData->DimmRanks[dimm] == 2) && (rank == 1)) {
- return 0x00; /* for non-target dimm during WL, the second rank of a DR dimm need to have Rtt_Nom = OFF */
- } else {
- return RttNomTargetRegDimm (pMCTData, pDCTData, dimm, FALSE, MemClkFreq, rank); /* otherwise, the same as target dimm in normal mode. */
- }
-}
-
-/* -----------------------------------------------------------------------------*/
-/**
- *
- *
- * This function set Rtt_Wr for registered DDR3 dimms.
- *
- * @param pMCTData
- * @param[in] *pDCTData - Pointer to buffer with information about each DCT
- * @param dimm - targeted dimm
- * @param wl - current mode, either write levelization mode or normal mode
- * @param MemClkFreq - current frequency
- * @param rank
- *
- * @return tempW1 - Rtt_Wr
- */
-
-u32 RttWrRegDimm (sMCTStruct *pMCTData, sDCTStruct *pDCTData, u8 dimm, BOOL wl, u8 MemClkFreq, u8 rank)
-{
- u32 tempW1;
- tempW1 = 0;
- if (wl) {
- tempW1 = 0x00; /* Rtt_WR = OFF */
- } else {
- switch (mctGet_NVbits(NV_MAX_DIMMS_PER_CH)) {
- case 2:
- if (pDCTData->MaxDimmsInstalled == 1) {
- if (pDCTData->DimmRanks[dimm] != 4) {
- tempW1 = 0x00;
- } else {
- if (MemClkFreq == 6) {
- tempW1 = 0x200; /* Rtt_WR = 60 ohms */
- } else {
- tempW1 = 0x400; /* Rtt_WR = 120 ohms */
- }
- }
- } else {
- if ((pDCTData->DimmRanks[dimm] == 4) || (pDCTData->DctCSPresent & 0xF0)) {
- if (MemClkFreq == 3) {
- tempW1 = 0x400; /* Rtt_WR = 120 ohms */
- } else {
- tempW1 = 0x200; /* Rtt_WR = 60 ohms */
- }
- } else {
- if (MemClkFreq == 6) {
- tempW1 = 0x200; /* Rtt_WR = 60 ohms */
- } else {
- tempW1 = 0x400; /* Rtt_Nom = 120 ohms */
- }
- }
- }
- break;
- case 3:
- if (pDCTData->MaxDimmsInstalled == 1) {
- tempW1 = 0x00; /* Rtt_WR = OFF */
- } else {
- tempW1 = 0x400; /* Rtt_Nom = 120 ohms */
- }
- break;
- default:
- die("modtrdim.c: WTF?");
- }
- }
- return tempW1;
-}
-
-/* -----------------------------------------------------------------------------*/
-/**
- *
- *
- * This function set WrLvOdt for registered DDR3 dimms.
- *
- * @param *pMCTData
- * @param[in] *pDCTData - Pointer to buffer with information about each DCT
- * @param dimm - targeted dimm
- *
- * @return WrLvOdt
- */
-u8 WrLvOdtRegDimm (sMCTStruct *pMCTData, sDCTStruct *pDCTData, u8 dimm)
-{
- u8 WrLvOdt1, i;
- WrLvOdt1 = 0;
- i = 0;
- while (i < 8) {
- if (pDCTData->DctCSPresent & (1 << i)) {
- WrLvOdt1 = (u8)bitTestSet(WrLvOdt1, i/2);
- }
- i += 2;
- }
- if (mctGet_NVbits(NV_MAX_DIMMS_PER_CH) == 2) {
- if ((pDCTData->DimmRanks[dimm] == 4) && (pDCTData->MaxDimmsInstalled != 1)) {
- if (dimm >= 2) {
- WrLvOdt1 = (u8)bitTestReset (WrLvOdt1, (dimm - 2));
- } else {
- WrLvOdt1 = (u8)bitTestReset (WrLvOdt1, (dimm + 2));
- }
- } else if ((pDCTData->DimmRanks[dimm] == 2) && (pDCTData->MaxDimmsInstalled == 1)) {
- /* the case for one DR on a 2 dimms per channel is special */
- WrLvOdt1 = 0x8;
- }
- }
- return WrLvOdt1;
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mport_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mport_d.c
deleted file mode 100644
index 999cb94f24..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mport_d.c
+++ /dev/null
@@ -1,42 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <arch/io.h>
-#include <stdint.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-#include "mwlc_d.h"
-
-void AmdMemPCIRead(SBDFO loc, u32 *Value)
-{
- /* Convert SBDFO into a CF8 Address */
- loc = (loc >> 4 & 0xFFFFFF00) | (loc & 0xFF) | ((loc & 0xF00) << 16);
- loc |= 0x80000000;
-
- outl(loc, 0xCF8);
-
- *Value = inl(0xCFC);
-}
-
-void AmdMemPCIWrite(SBDFO loc, u32 *Value)
-{
- /* Convert SBDFO into a CF8 Address */
- loc = (loc >> 4 & 0xFFFFFF00) | (loc & 0xFF) | ((loc & 0xF00) << 16);
- loc |= 0x80000000;
-
- outl(loc, 0xCF8);
- outl(*Value, 0xCFC);
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mutilc_d.c b/src/northbridge/amd/amdmct/mct_ddr3/mutilc_d.c
deleted file mode 100644
index 0420b660b9..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mutilc_d.c
+++ /dev/null
@@ -1,374 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* This file contains functions for common utility functions */
-
-#include <arch/cpu.h>
-#include <stdint.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-#include "mwlc_d.h"
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-void AmdMemPCIReadBits(SBDFO loc, u8 highbit, u8 lowbit, u32 *pValue)
-{
- /* ASSERT(highbit < 32 && lowbit < 32 && highbit >= lowbit && (loc & 3) == 0); */
-
- AmdMemPCIRead(loc, pValue);
- *pValue = *pValue >> lowbit; /* Shift */
-
- /* A 1<<32 == 1<<0 due to x86 SHL instruction, so skip if that is the case */
- if ((highbit-lowbit) != 31)
- *pValue &= (((u32)1 << (highbit-lowbit+1))-1);
-}
-
-void AmdMemPCIWriteBits(SBDFO loc, u8 highbit, u8 lowbit, u32 *pValue)
-{
- u32 temp, mask;
-
- /* ASSERT(highbit < 32 && lowbit < 32 && highbit >= lowbit && (loc & 3) == 0); */
-
- /* A 1<<32 == 1<<0 due to x86 SHL instruction, so skip if that is the case */
- if ((highbit-lowbit) != 31)
- mask = (((u32)1 << (highbit-lowbit+1))-1);
- else
- mask = (u32)0xFFFFFFFF;
-
- AmdMemPCIRead(loc, &temp);
- temp &= ~(mask << lowbit);
- temp |= (*pValue & mask) << lowbit;
- AmdMemPCIWrite(loc, &temp);
-}
-
-/*-----------------------------------------------------------------------------
- * u32 bitTestSet(u32 csMask,u32 tempD)
- *
- * Description:
- * This routine sets a bit in a u32
- *
- * Parameters:
- * IN csMask = Target value in which the bit will be set
- * IN tempD = Bit that will be set
- * OUT value = Target value with the bit set
- *-----------------------------------------------------------------------------
- */
-u32 bitTestSet(u32 csMask,u32 tempD)
-{
- u32 localTemp;
- /* ASSERT(tempD < 32); */
- localTemp = 1;
- csMask |= localTemp << tempD;
- return csMask;
-}
-
-/*-----------------------------------------------------------------------------
- * u32 bitTestReset(u32 csMask,u32 tempD)
- *
- * Description:
- * This routine re-sets a bit in a u32
- *
- * Parameters:
- * IN csMask = Target value in which the bit will be re-set
- * IN tempD = Bit that will be re-set
- * OUT value = Target value with the bit re-set
- *-----------------------------------------------------------------------------
- */
-u32 bitTestReset(u32 csMask,u32 tempD)
-{
- u32 temp, localTemp;
- /* ASSERT(tempD < 32); */
- localTemp = 1;
- temp = localTemp << tempD;
- temp = ~temp;
- csMask &= temp;
- return csMask;
-}
-
-/*-----------------------------------------------------------------------------
- * u32 get_Bits(DCTStruct *DCTData, u8 DCT, u8 Node, u8 func, u16 offset,
- * u8 low, u8 high)
- *
- * Description:
- * This routine Gets the PCT bits from the specified Node, DCT and PCI address
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * IN DCT - DCT number
- * - 1 indicates DCT 1
- * - 0 indicates DCT 0
- * - 2 both DCTs
- * Node - Node number
- * Func - PCI Function number
- * Offset - PCI register number
- * Low - Low bit of the bit field
- * High - High bit of the bit field
- *
- * OUT value = Value read from PCI space
- *-----------------------------------------------------------------------------
- */
-u32 get_Bits(sDCTStruct *pDCTData,
- u8 dct, u8 node, u8 func,
- u16 offset, u8 low, u8 high)
-{
- u32 temp;
- uint32_t dword;
-
- /* ASSERT(node < MAX_NODES); */
- if (dct == BOTH_DCTS)
- {
- /* Registers exist on DCT0 only */
- if (is_fam15h())
- {
- /* Select DCT 0 */
- AmdMemPCIRead(MAKE_SBDFO(0,0,24+node,1,0x10c), &dword);
- dword &= ~0x1;
- AmdMemPCIWrite(MAKE_SBDFO(0,0,24+node,1,0x10c), &dword);
- }
-
- AmdMemPCIReadBits(MAKE_SBDFO(0,0,24+node,func,offset), high, low, &temp);
- }
- else
- {
- if (is_fam15h())
- {
- /* Select DCT */
- AmdMemPCIRead(MAKE_SBDFO(0,0,24+node,1,0x10c), &dword);
- dword &= ~0x1;
- dword |= (dct & 0x1);
- AmdMemPCIWrite(MAKE_SBDFO(0,0,24+node,1,0x10c), &dword);
-
- /* Read from the selected DCT */
- AmdMemPCIReadBits(MAKE_SBDFO(0,0,24+node,func,offset), high, low, &temp);
- }
- else
- {
- if (dct == 1)
- {
- /* Read from dct 1 */
- offset += 0x100;
- AmdMemPCIReadBits(MAKE_SBDFO(0,0,24+node,func,offset), high, low, &temp);
- }
- else
- {
- /* Read from dct 0 */
- AmdMemPCIReadBits(MAKE_SBDFO(0,0,24+node,func,offset), high, low, &temp);
- }
- }
- }
- return temp;
-}
-
-/*-----------------------------------------------------------------------------
- * void set_Bits(DCTStruct *DCTData,u8 DCT,u8 Node,u8 func, u16 offset,
- * u8 low, u8 high, u32 value)
- *
- * Description:
- * This routine Sets the PCT bits from the specified Node, DCT and PCI address
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * IN DCT - DCT number
- * - 1 indicates DCT 1
- * - 0 indicates DCT 0
- * - 2 both DCTs
- * Node - Node number
- * Func - PCI Function number
- * Offset - PCI register number
- * Low - Low bit of the bit field
- * High - High bit of the bit field
- *
- * OUT
- *-----------------------------------------------------------------------------
- */
-void set_Bits(sDCTStruct *pDCTData,
- u8 dct, u8 node, u8 func,
- u16 offset, u8 low, u8 high, u32 value)
-{
- u32 temp;
- uint32_t dword;
-
- temp = value;
-
- if (dct == BOTH_DCTS)
- {
- /* Registers exist on DCT0 only */
- if (is_fam15h())
- {
- /* Select DCT 0 */
- AmdMemPCIRead(MAKE_SBDFO(0,0,24+node,1,0x10c), &dword);
- dword &= ~0x1;
- AmdMemPCIWrite(MAKE_SBDFO(0,0,24+node,1,0x10c), &dword);
- }
-
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+node,func,offset), high, low, &temp);
- }
- else
- {
- if (is_fam15h())
- {
- /* Select DCT */
- AmdMemPCIRead(MAKE_SBDFO(0,0,24+node,1,0x10c), &dword);
- dword &= ~0x1;
- dword |= (dct & 0x1);
- AmdMemPCIWrite(MAKE_SBDFO(0,0,24+node,1,0x10c), &dword);
-
- /* Write to the selected DCT */
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+node,func,offset), high, low, &temp);
- }
- else
- {
- if (dct == 1)
- {
- /* Write to dct 1 */
- offset += 0x100;
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+node,func,offset), high, low, &temp);
- }
- else
- {
- /* Write to dct 0 */
- AmdMemPCIWriteBits(MAKE_SBDFO(0,0,24+node,func,offset), high, low, &temp);
- }
- }
- }
-}
-
-/*-------------------------------------------------
- * u32 get_ADD_DCT_Bits(DCTStruct *DCTData,u8 DCT,u8 Node,u8 func,
- * u16 offset,u8 low, u8 high)
- *
- * Description:
- * This routine gets the Additional PCT register from Function 2 by specified
- * Node, DCT and PCI address
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * IN DCT - DCT number
- * - 1 indicates DCT 1
- * - 0 indicates DCT 0
- * - 2 both DCTs
- * Node - Node number
- * Func - PCI Function number
- * Offset - Additional PCI register number
- * Low - Low bit of the bit field
- * High - High bit of the bit field
- *
- * OUT
- *-------------------------------------------------
- */
-u32 get_ADD_DCT_Bits(sDCTStruct *pDCTData,
- u8 dct, u8 node, u8 func,
- u16 offset, u8 low, u8 high)
-{
- u32 tempD;
- tempD = offset;
- tempD = bitTestReset(tempD,DctAccessWrite);
- set_Bits(pDCTData, dct, node, FUN_DCT, DRAM_CONTROLLER_ADD_DATA_OFFSET_REG,
- PCI_MIN_LOW, PCI_MAX_HIGH, offset);
- while ((get_Bits(pDCTData,dct, node, FUN_DCT, DRAM_CONTROLLER_ADD_DATA_OFFSET_REG,
- DctAccessDone, DctAccessDone)) == 0);
- return (get_Bits(pDCTData, dct, node, FUN_DCT, DRAM_CONTROLLER_ADD_DATA_PORT_REG,
- low, high));
-}
-
-/*-------------------------------------------------
- * void set_DCT_ADDR_Bits(DCTStruct *DCTData, u8 DCT,u8 Node,u8 func,
- * u16 offset,u8 low, u8 high, u32 value)
- *
- * Description:
- * This routine sets the Additional PCT register from Function 2 by specified
- * Node, DCT and PCI address
- *
- * Parameters:
- * IN OUT *DCTData - Pointer to buffer with information about each DCT
- * IN DCT - DCT number
- * - 1 indicates DCT 1
- * - 0 indicates DCT 0
- * - 2 both DCTs
- * Node - Node number
- * Func - PCI Function number
- * Offset - Additional PCI register number
- * Low - Low bit of the bit field
- * High - High bit of the bit field
- *
- * OUT
- *-------------------------------------------------
- */
-void set_DCT_ADDR_Bits(sDCTStruct *pDCTData,
- u8 dct, u8 node, u8 func,
- u16 offset, u8 low, u8 high, u32 value)
-{
- u32 tempD;
-
- set_Bits(pDCTData, dct, node, FUN_DCT, DRAM_CONTROLLER_ADD_DATA_OFFSET_REG,
- PCI_MIN_LOW, PCI_MAX_HIGH, offset);
- while ((get_Bits(pDCTData,dct, node, FUN_DCT, DRAM_CONTROLLER_ADD_DATA_OFFSET_REG,
- DctAccessDone, DctAccessDone)) == 0);
-
- set_Bits(pDCTData, dct, node, FUN_DCT, DRAM_CONTROLLER_ADD_DATA_PORT_REG,
- low, high, value);
- tempD = offset;
- tempD = bitTestSet(tempD,DctAccessWrite);
- set_Bits(pDCTData, dct, node, FUN_DCT,DRAM_CONTROLLER_ADD_DATA_OFFSET_REG,
- PCI_MIN_LOW, PCI_MAX_HIGH, tempD);
- while ((get_Bits(pDCTData,dct, pDCTData->NodeId, FUN_DCT,
- DRAM_CONTROLLER_ADD_DATA_OFFSET_REG, DctAccessDone,
- DctAccessDone)) == 0);
-}
-
-/*-------------------------------------------------
- * BOOL bitTest(u32 value, u8 bitLoc)
- *
- * Description:
- * This routine tests the value to determine if the bitLoc is set
- *
- * Parameters:
- * IN Value - value to be tested
- * bitLoc - bit location to be tested
- * OUT TRUE - bit is set
- * FALSE - bit is clear
- *-------------------------------------------------
- */
-BOOL bitTest(u32 value, u8 bitLoc)
-{
- u32 tempD, compD;
- tempD = value;
- compD = 0;
- compD = bitTestSet(compD,bitLoc);
- tempD &= compD;
- if (compD == tempD)
- {
- return TRUE;
- }
- else
- {
- return FALSE;
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/mwlc_d.h b/src/northbridge/amd/amdmct/mct_ddr3/mwlc_d.h
deleted file mode 100644
index aa0446f090..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/mwlc_d.h
+++ /dev/null
@@ -1,192 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2010 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-/* IBV defined Structure */ /* IBV Specific Options */
-#ifndef MWLC_D_H
-#define MWLC_D_H
-
-#include <northbridge/amd/amdht/porting.h>
-
-#define MAX_TOTAL_DIMMS 8 /* Maximum Number of DIMMs in systems */
- /* (DCT0 + DCT1) */
-#define MAX_DIMMS 4 /* Maximum Number of DIMMs on each DCT */
-#define MAX_LDIMMS 4 /* Maximum number of Logical DIMMs per DCT */
-
-/*MCT Max variables */
-#define MAX_ERRORS 32 /* Maximum number of Errors Reported */
-#define MAX_STATUS 32 /* Maximum number of Status variables*/
-#define MAX_BYTE_LANES (8+1) /* Maximum number of Byte Lanes - include ECC */
-
-#define C_MAX_DIMMS 4 /* Maximum Number of DIMMs on each DCT */
-
-/* STATUS Definition */
-#define DCT_STATUS_REGISTERED 3 /* Registered DIMMs support */
-#define DCT_STATUS_LOAD_REDUCED 4 /* Load-Reduced DIMMs support */
-#define DCT_STATUS_OnDimmMirror 24 /* OnDimmMirror support */
-
-/* PCI Definitions */
-#define FUN_HT 0 /* Function 0 Access */
-#define FUN_MAP 1 /* Function 1 Access */
-#define FUN_DCT 2 /* Function 2 Access */
-#define FUN_MISC 3 /* Function 3 Access */
-#define FUN_ADD_DCT 0xF /* Function 2 Additional Register Access */
-#define BOTH_DCTS 2 /* The access is independent of DCTs */
-#define PCI_MIN_LOW 0 /* Lowest possible PCI register location */
-#define PCI_MAX_HIGH 31 /* Highest possible PCI register location */
-
-/*Function 2 */
-/* #define DRAM_INIT 0x7C */
-#define DRAM_MRS_REGISTER 0x84
-#define DRAM_CONFIG_HIGH 0x94
-#define DRAM_CONTROLLER_ADD_DATA_OFFSET_REG 0x98
-#define DRAM_CONTROLLER_ADD_DATA_PORT_REG 0x9C
-
-/*Function 2 Additional DRAM control registers */
-#define DRAM_ADD_DCT_PHY_CONTROL_REG 0x8
-#define DRAM_CONT_ADD_DQS_TIMING_CTRL_BL_01 0x30
-#define DRAM_CONT_ADD_DQS_TIMING_CTRL_BL_45 0x40
-#define DRAM_CONT_ADD_PHASE_REC_CTRL_LOW 0x50
-#define DRAM_CONT_ADD_PHASE_REC_CTRL_HIGH 0x51
-#define DRAM_CONT_ADD_ECC_PHASE_REC_CTRL 0x52
-#define DRAM_CONT_ADD_WRITE_LEV_ERROR_REG 0x53
-
-/* CPU Register definitions */
-
-/* Register Bit Location */
-#define DctAccessDone 31
-#define DctAccessWrite 30
-#define RDqsEn 12
-#define TrDimmSelStart 4
-#define TrDimmSelEnd 5
-#define WrLvTrMode 1
-#define TrNibbleSel 2
-#define WrLvOdtEn 12
-#define WrLvErrStart 0
-#define WrLvErrEnd 8
-#define SendMrsCmd 26
-#define Qoff 12
-#define MRS_Level 7
-#define MrsAddressStartFam10 0
-#define MrsAddressEndFam10 15
-#define MrsAddressStartFam15 0
-#define MrsAddressEndFam15 17
-#define MrsBankStartFam10 16
-#define MrsBankEndFam10 18
-#define MrsBankStartFam15 18
-#define MrsBankEndFam15 20
-#define MrsChipSelStartFam10 20
-#define MrsChipSelEndFam10 22
-#define MrsChipSelStartFam15 21
-#define MrsChipSelEndFam15 23
-#define ASR 18
-#define SRT 19
-#define DramTermDynStart 10
-#define DramTermDynEnd 11
-#define WrtLvTrMode 1
-#define TrNibbleSel 2
-#define TrDimmSelStart 4
-#define TrDimmSelEnd 5
-#define WrtLvTrEn 0
-#define DrvImpCtrlStart 2
-#define DrvImpCtrlEnd 3
-#define DramTermNbStart 7
-#define DramTermNbEnd 9
-#define onDimmMirror 3
-
-typedef struct _sMCTStruct
-{
- void (*AgesaDelay)(u32 delayval); /* IBV defined Delay Function */
-} __attribute__((packed, aligned(4))) sMCTStruct;
-
-/* DCT 0 and DCT 1 Data structure */
-typedef struct _sDCTStruct
-{
- u8 NodeId; /* Node ID */
- u8 DctTrain; /* Current DCT being trained */
- u8 CurrDct; /* Current DCT number (0 or 1) */
- u8 DctCSPresent; /* Current DCT CS mapping */
- uint8_t WrDqsGrossDlyBaseOffset;
- int32_t WLSeedGrossDelay[MAX_BYTE_LANES*MAX_LDIMMS]; /* Write Levelization Seed Gross Delay */
- /* per byte Lane Per Logical DIMM*/
- int32_t WLSeedFineDelay[MAX_BYTE_LANES*MAX_LDIMMS]; /* Write Levelization Seed Fine Delay */
- /* per byte Lane Per Logical DIMM*/
- int32_t WLSeedPreGrossDelay[MAX_BYTE_LANES*MAX_LDIMMS]; /* Write Levelization Seed Pre-Gross Delay */
- /* per byte Lane Per Logical DIMM*/
- uint8_t WLSeedPreGrossPrevNibble[MAX_BYTE_LANES*MAX_LDIMMS];
- uint8_t WLSeedGrossPrevNibble[MAX_BYTE_LANES*MAX_LDIMMS];
- uint8_t WLSeedFinePrevNibble[MAX_BYTE_LANES*MAX_LDIMMS];
- /* per byte Lane Per Logical DIMM*/
- u8 WLGrossDelay[MAX_BYTE_LANES*MAX_LDIMMS]; /* Write Levelization Gross Delay */
- /* per byte Lane Per Logical DIMM*/
- u8 WLFineDelay[MAX_BYTE_LANES*MAX_LDIMMS]; /* Write Levelization Fine Delay */
- /* per byte Lane Per Logical DIMM*/
- u8 WLGrossDelayFirstPass[MAX_BYTE_LANES*MAX_LDIMMS]; /* First-Pass Write Levelization Gross Delay */
- /* per byte Lane Per Logical DIMM*/
- u8 WLFineDelayFirstPass[MAX_BYTE_LANES*MAX_LDIMMS]; /* First-Pass Write Levelization Fine Delay */
- /* per byte Lane Per Logical DIMM*/
- u8 WLGrossDelayPrevPass[MAX_BYTE_LANES*MAX_LDIMMS]; /* Previous Pass Write Levelization Gross Delay */
- /* per byte Lane Per Logical DIMM*/
- u8 WLFineDelayPrevPass[MAX_BYTE_LANES*MAX_LDIMMS]; /* Previous Pass Write Levelization Fine Delay */
- /* per byte Lane Per Logical DIMM*/
- u8 WLGrossDelayFinalPass[MAX_BYTE_LANES*MAX_LDIMMS]; /* Final-Pass Write Levelization Gross Delay */
- /* per byte Lane Per Logical DIMM*/
- u8 WLFineDelayFinalPass[MAX_BYTE_LANES*MAX_LDIMMS]; /* Final-Pass Write Levelization Fine Delay */
- /* per byte Lane Per Logical DIMM*/
- int32_t WLCriticalGrossDelayFirstPass;
- int32_t WLCriticalGrossDelayPrevPass;
- int32_t WLCriticalGrossDelayFinalPass;
- uint16_t WLPrevMemclkFreq[MAX_TOTAL_DIMMS];
- u16 RegMan1Present;
- u8 DimmPresent[MAX_TOTAL_DIMMS];/* Indicates which DIMMs are present */
- /* from Total Number of DIMMs(per Node)*/
- u8 DimmX8Present[MAX_TOTAL_DIMMS]; /* Which DIMMs x8 devices */
- u8 Status[MAX_STATUS]; /* Status for DCT0 and 1 */
- u8 ErrCode[MAX_ERRORS]; /* Major Error codes for DCT0 and 1 */
- u8 ErrStatus[MAX_ERRORS]; /* Minor Error codes for DCT0 and 1 */
- u8 DimmValid[MAX_TOTAL_DIMMS]; /* Indicates which DIMMs are valid for */
- /* Total Number of DIMMs(per Node) */
- u8 WLTotalDelay[MAX_BYTE_LANES];/* Write Levelization Total Delay */
- /* per byte lane */
- u8 MaxDimmsInstalled; /* Max Dimms Installed for current DCT */
- u8 DimmRanks[MAX_TOTAL_DIMMS]; /* Total Number of Ranks(per Dimm) */
- uint64_t LogicalCPUID;
- u8 WLPass;
-} __attribute__((packed, aligned(4))) sDCTStruct;
-
-void set_DCT_ADDR_Bits(sDCTStruct *pDCTData,
- u8 dct, u8 node, u8 func,
- u16 offset, u8 low, u8 high, u32 value);
-void AmdMemPCIWriteBits(SBDFO loc, u8 highbit, u8 lowbit, u32 *pValue);
-u32 get_Bits(sDCTStruct *pDCTData,
- u8 dct, u8 node, u8 func,
- u16 offset, u8 low, u8 high);
-void AmdMemPCIReadBits(SBDFO loc, u8 highbit, u8 lowbit, u32 *pValue);
-u32 bitTestSet(u32 csMask,u32 tempD);
-u32 bitTestReset(u32 csMask,u32 tempD);
-void set_Bits(sDCTStruct *pDCTData,
- u8 dct, u8 node, u8 func,
- u16 offset, u8 low, u8 high, u32 value);
-BOOL bitTest(u32 value, u8 bitLoc);
-u32 RttNomNonTargetRegDimm (sMCTStruct *pMCTData, sDCTStruct *pDCTData, u8 dimm, BOOL wl, u8 MemClkFreq, u8 rank);
-u32 RttNomTargetRegDimm (sMCTStruct *pMCTData, sDCTStruct *pDCTData, u8 dimm, BOOL wl, u8 MemClkFreq, u8 rank);
-u32 RttWrRegDimm (sMCTStruct *pMCTData, sDCTStruct *pDCTData, u8 dimm, BOOL wl, u8 MemClkFreq, u8 rank);
-u8 WrLvOdtRegDimm (sMCTStruct *pMCTData, sDCTStruct *pDCTData, u8 dimm);
-u32 get_ADD_DCT_Bits(sDCTStruct *pDCTData,
- u8 dct, u8 node, u8 func,
- u16 offset, u8 low, u8 high);
-void AmdMemPCIRead(SBDFO loc, u32 *Value);
-void AmdMemPCIWrite(SBDFO loc, u32 *Value);
-
-#endif
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/s3utils.c b/src/northbridge/amd/amdmct/mct_ddr3/s3utils.c
deleted file mode 100644
index 52032e9362..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/s3utils.c
+++ /dev/null
@@ -1,1237 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#include <string.h>
-#include <arch/cpu.h>
-#include <arch/acpi.h>
-#include <cpu/x86/msr.h>
-#include <cpu/amd/msr.h>
-#include <cpu/x86/mtrr.h>
-#include <cpu/amd/mtrr.h>
-#include <device/device.h>
-#include <device/pci_def.h>
-#include <device/pci_ops.h>
-#include <console/console.h>
-#include <cbfs.h>
-#include <cbmem.h>
-#include <spi-generic.h>
-#include <spi_flash.h>
-#include <pc80/mc146818rtc.h>
-#include <stdint.h>
-#include <types.h>
-
-#include "mct_d.h"
-#include "mct_d_gcc.h"
-
-#include "s3utils.h"
-
-#define S3NV_FILE_NAME "s3nv"
-
-static uint8_t is_fam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-static ssize_t get_s3nv_file_offset(void);
-
-ssize_t get_s3nv_file_offset(void)
-{
- struct region_device s3nv_region;
- struct cbfsf s3nv_cbfs_file;
- if (cbfs_boot_locate(&s3nv_cbfs_file, S3NV_FILE_NAME, NULL)) {
- printk(BIOS_DEBUG, "S3 state file not found in CBFS: %s\n", S3NV_FILE_NAME);
- return -1;
- }
- cbfs_file_data(&s3nv_region, &s3nv_cbfs_file);
-
- return s3nv_region.region.offset;
-}
-
-#if ENV_PCI_SIMPLE_DEVICE
-static uint32_t read_config32_dct(pci_devfn_t dev, uint8_t node, uint8_t dct,
- uint32_t reg)
-#else
-static uint32_t read_config32_dct(struct device *dev, uint8_t node, uint8_t dct,
- uint32_t reg)
-#endif
-{
- if (is_fam15h()) {
- uint32_t dword;
-#if ENV_PCI_SIMPLE_DEVICE
- pci_devfn_t dev_fn1 = PCI_DEV(0, 0x18 + node, 1);
-#else
- struct device *dev_fn1 = pcidev_on_root(0x18 + node, 1);
-#endif
-
- /* Select DCT */
- dword = pci_read_config32(dev_fn1, 0x10c);
- dword &= ~0x1;
- dword |= (dct & 0x1);
- pci_write_config32(dev_fn1, 0x10c, dword);
- } else {
- /* Apply offset */
- reg += dct * 0x100;
- }
-
- return pci_read_config32(dev, reg);
-}
-
-#if ENV_PCI_SIMPLE_DEVICE
-static void write_config32_dct(pci_devfn_t dev, uint8_t node, uint8_t dct,
- uint32_t reg, uint32_t value)
-#else
-static void write_config32_dct(struct device *dev, uint8_t node, uint8_t dct,
- uint32_t reg, uint32_t value)
-#endif
-{
- if (is_fam15h()) {
- uint32_t dword;
-#if ENV_PCI_SIMPLE_DEVICE
- pci_devfn_t dev_fn1 = PCI_DEV(0, 0x18 + node, 1);
-#else
- struct device *dev_fn1 = pcidev_on_root(0x18 + node, 1);
-#endif
-
- /* Select DCT */
- dword = pci_read_config32(dev_fn1, 0x10c);
- dword &= ~0x1;
- dword |= (dct & 0x1);
- pci_write_config32(dev_fn1, 0x10c, dword);
- } else {
- /* Apply offset */
- reg += dct * 0x100;
- }
-
- pci_write_config32(dev, reg, value);
-}
-
-#if ENV_PCI_SIMPLE_DEVICE
-static uint32_t read_amd_dct_index_register(pci_devfn_t dev,
- uint32_t index_ctl_reg, uint32_t index)
-#else
-static uint32_t read_amd_dct_index_register(struct device *dev,
- uint32_t index_ctl_reg, uint32_t index)
-#endif
-{
- uint32_t dword;
-
- index &= ~(1 << 30);
- pci_write_config32(dev, index_ctl_reg, index);
- do {
- dword = pci_read_config32(dev, index_ctl_reg);
- } while (!(dword & (1 << 31)));
- dword = pci_read_config32(dev, index_ctl_reg + 0x04);
-
- return dword;
-}
-
-#if ENV_PCI_SIMPLE_DEVICE
-static uint32_t read_amd_dct_index_register_dct(pci_devfn_t dev, uint8_t node,
- uint8_t dct, uint32_t index_ctl_reg, uint32_t index)
-#else
-static uint32_t read_amd_dct_index_register_dct(struct device *dev,
- uint8_t node, uint8_t dct, uint32_t index_ctl_reg,
- uint32_t index)
-#endif
-{
- if (is_fam15h()) {
- uint32_t dword;
-#if ENV_PCI_SIMPLE_DEVICE
- pci_devfn_t dev_fn1 = PCI_DEV(0, 0x18 + node, 1);
-#else
- struct device *dev_fn1 = pcidev_on_root(0x18 + node, 1);
-#endif
-
- /* Select DCT */
- dword = pci_read_config32(dev_fn1, 0x10c);
- dword &= ~0x1;
- dword |= (dct & 0x1);
- pci_write_config32(dev_fn1, 0x10c, dword);
- } else {
- /* Apply offset */
- index_ctl_reg += dct * 0x100;
- }
-
- return read_amd_dct_index_register(dev, index_ctl_reg, index);
-}
-
-/* Non-cryptographic 64-bit hash function taken from Stack Overflow:
- * http://stackoverflow.com/a/13326345
- * Any 64-bit hash with sufficiently low collision potential
- * could be used instead.
- */
-void calculate_spd_hash(uint8_t *spd_data, uint64_t *spd_hash)
-{
- const unsigned long long prime = 2654435789ULL;
- uint16_t byte;
- *spd_hash = 104395301;
-
- for (byte = 0; byte < 256; byte++)
- *spd_hash += (spd_data[byte] * prime) ^ (*spd_hash >> 23);
-
- *spd_hash = *spd_hash ^ (*spd_hash << 37);
-}
-
-uint16_t calculate_nvram_mct_hash(void)
-{
- uint32_t nvram;
- uint16_t ret;
-
- ret = 0;
- if (get_option(&nvram, "max_mem_clock") == CB_SUCCESS)
- ret |= nvram & 0xf;
- if (get_option(&nvram, "minimum_memory_voltage") == CB_SUCCESS)
- ret |= (nvram & 0x3) << 4;
- if (get_option(&nvram, "ECC_memory") == CB_SUCCESS)
- ret |= (nvram & 0x1) << 6;
- if (get_option(&nvram, "ECC_redirection") == CB_SUCCESS)
- ret |= (nvram & 0x1) << 7;
- if (get_option(&nvram, "ecc_scrub_rate") == CB_SUCCESS)
- ret |= (nvram & 0x1) << 8;
- if (get_option(&nvram, "interleave_chip_selects") == CB_SUCCESS)
- ret |= (nvram & 0x1) << 9;
- if (get_option(&nvram, "interleave_nodes") == CB_SUCCESS)
- ret |= (nvram & 0x1) << 10;
- if (get_option(&nvram, "interleave_memory_channels") == CB_SUCCESS)
- ret |= (nvram & 0x1) << 11;
- if (get_option(&nvram, "cpu_c_states") == CB_SUCCESS)
- ret |= (nvram & 0x1) << 12;
- if (get_option(&nvram, "cpu_cc6_state") == CB_SUCCESS)
- ret |= (nvram & 0x1) << 13;
-
- return ret;
-}
-
-static struct amd_s3_persistent_data *map_s3nv_in_nvram(void)
-{
- ssize_t s3nv_offset;
- ssize_t s3nv_file_offset;
- void *s3nv_cbfs_file_ptr;
- struct amd_s3_persistent_data *persistent_data;
-
- /* Obtain CBFS file offset */
- s3nv_offset = get_s3nv_file_offset();
- if (s3nv_offset == -1)
- return NULL;
-
- /* Align flash pointer to nearest boundary */
- s3nv_file_offset = s3nv_offset;
- s3nv_offset &= ~(CONFIG_S3_DATA_SIZE-1);
- s3nv_offset += CONFIG_S3_DATA_SIZE;
- s3nv_file_offset = s3nv_offset - s3nv_file_offset;
-
- /* Map data structure in CBFS and restore settings */
- s3nv_cbfs_file_ptr = cbfs_boot_map_with_leak(S3NV_FILE_NAME, CBFS_TYPE_RAW, NULL);
- if (!s3nv_cbfs_file_ptr) {
- printk(BIOS_DEBUG, "S3 state file could not be mapped: %s\n", S3NV_FILE_NAME);
- return NULL;
- }
- persistent_data = (s3nv_cbfs_file_ptr + s3nv_file_offset);
-
- return persistent_data;
-}
-
-int8_t load_spd_hashes_from_nvram(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstat)
-{
- struct amd_s3_persistent_data *persistent_data;
-
- persistent_data = map_s3nv_in_nvram();
- if (!persistent_data)
- return -1;
-
- memcpy(pDCTstat->spd_data.nvram_spd_hash, persistent_data->node[pDCTstat->Node_ID].spd_hash, sizeof(pDCTstat->spd_data.nvram_spd_hash));
- memcpy(pDCTstat->spd_data.nvram_memclk, persistent_data->node[pDCTstat->Node_ID].memclk, sizeof(pDCTstat->spd_data.nvram_memclk));
-
- pMCTstat->nvram_checksum = persistent_data->nvram_checksum;
-
- return 0;
-}
-
-static uint64_t rdmsr_uint64_t(unsigned long index) {
- msr_t msr = rdmsr(index);
- return (((uint64_t)msr.hi) << 32) | ((uint64_t)msr.lo);
-}
-
-static void wrmsr_uint64_t(unsigned long index, uint64_t value)
-{
- msr_t msr;
- msr.hi = (value & 0xffffffff00000000ULL) >> 32;
- msr.lo = (value & 0xffffffff);
- wrmsr(index, msr);
-}
-
-static uint32_t read_config32_dct_nbpstate(struct device *dev, uint8_t node,
- uint8_t dct, uint8_t nb_pstate,
- uint32_t reg)
-{
- uint32_t dword;
- struct device *dev_fn1 = pcidev_on_root(0x18 + node, 1);
-
- /* Select DCT */
- dword = pci_read_config32(dev_fn1, 0x10c);
- dword &= ~0x1;
- dword |= (dct & 0x1);
- pci_write_config32(dev_fn1, 0x10c, dword);
-
- /* Select NB Pstate index */
- dword = pci_read_config32(dev_fn1, 0x10c);
- dword &= ~(0x3 << 4);
- dword |= (nb_pstate & 0x3) << 4;
- pci_write_config32(dev_fn1, 0x10c, dword);
-
- return pci_read_config32(dev, reg);
-}
-
-static void copy_cbmem_spd_data_to_save_variable(struct amd_s3_persistent_data *persistent_data, uint8_t *restored)
-{
- uint8_t node;
- uint8_t dimm;
- uint8_t channel;
- struct amdmct_memory_info *mem_info;
- mem_info = cbmem_find(CBMEM_ID_AMDMCT_MEMINFO);
- if (mem_info == NULL) {
- /* can't find amdmct information in cbmem */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++)
- for (dimm = 0; dimm < MAX_DIMMS_SUPPORTED; dimm++)
- persistent_data->node[node].spd_hash[dimm] = 0xffffffffffffffffULL;
-
- return;
- }
-
- for (node = 0; node < MAX_NODES_SUPPORTED; node++)
- for (dimm = 0; dimm < MAX_DIMMS_SUPPORTED; dimm++)
- calculate_spd_hash(mem_info->dct_stat[node].spd_data.spd_bytes[dimm], &persistent_data->node[node].spd_hash[dimm]);
-
- for (node = 0; node < MAX_NODES_SUPPORTED; node++)
- for (channel = 0; channel < 2; channel++)
- persistent_data->node[node].memclk[channel] = mem_info->dct_stat[node].Speed;
-
- persistent_data->nvram_checksum = calculate_nvram_mct_hash();
-
- if (restored) {
- if (mem_info->mct_stat.GStatus & (1 << GSB_ConfigRestored))
- *restored = 1;
- else
- *restored = 0;
- }
-}
-
-void copy_mct_data_to_save_variable(struct amd_s3_persistent_data *persistent_data)
-{
- uint8_t i;
- uint8_t j;
- uint8_t node;
- uint8_t channel;
-
- /* Zero out data structure */
- memset(persistent_data, 0, sizeof(struct amd_s3_persistent_data));
-
- /* Load data from DCTs into data structure */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- struct device *dev_fn1 = pcidev_on_root(0x18 + node, 1);
- struct device *dev_fn2 = pcidev_on_root(0x18 + node, 2);
- struct device *dev_fn3 = pcidev_on_root(0x18 + node, 3);
- /* Test for node presence */
- if ((!dev_fn1) || (pci_read_config32(dev_fn1, PCI_VENDOR_ID) == 0xffffffff)) {
- persistent_data->node[node].node_present = 0;
- continue;
- }
- persistent_data->node[node].node_present = 1;
-
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
-
- /* Stage 1 */
- data->f2x110 = pci_read_config32(dev_fn2, 0x110);
-
- /* Stage 2 */
- data->f1x40 = read_config32_dct(dev_fn1, node, channel, 0x40);
- data->f1x44 = read_config32_dct(dev_fn1, node, channel, 0x44);
- data->f1x48 = read_config32_dct(dev_fn1, node, channel, 0x48);
- data->f1x4c = read_config32_dct(dev_fn1, node, channel, 0x4c);
- data->f1x50 = read_config32_dct(dev_fn1, node, channel, 0x50);
- data->f1x54 = read_config32_dct(dev_fn1, node, channel, 0x54);
- data->f1x58 = read_config32_dct(dev_fn1, node, channel, 0x58);
- data->f1x5c = read_config32_dct(dev_fn1, node, channel, 0x5c);
- data->f1x60 = read_config32_dct(dev_fn1, node, channel, 0x60);
- data->f1x64 = read_config32_dct(dev_fn1, node, channel, 0x64);
- data->f1x68 = read_config32_dct(dev_fn1, node, channel, 0x68);
- data->f1x6c = read_config32_dct(dev_fn1, node, channel, 0x6c);
- data->f1x70 = read_config32_dct(dev_fn1, node, channel, 0x70);
- data->f1x74 = read_config32_dct(dev_fn1, node, channel, 0x74);
- data->f1x78 = read_config32_dct(dev_fn1, node, channel, 0x78);
- data->f1x7c = read_config32_dct(dev_fn1, node, channel, 0x7c);
- data->f1xf0 = pci_read_config32(dev_fn1, 0xf0);
- data->f1x120 = pci_read_config32(dev_fn1, 0x120);
- data->f1x124 = pci_read_config32(dev_fn1, 0x124);
- data->f2x10c = pci_read_config32(dev_fn2, 0x10c);
- data->f2x114 = pci_read_config32(dev_fn2, 0x114);
- data->f2x118 = pci_read_config32(dev_fn2, 0x118);
- data->f2x11c = pci_read_config32(dev_fn2, 0x11c);
- data->f2x1b0 = pci_read_config32(dev_fn2, 0x1b0);
- data->f3x44 = pci_read_config32(dev_fn3, 0x44);
- for (i = 0; i < 16; i++) {
- data->msr0000020[i] =
- rdmsr_uint64_t(MTRR_PHYS_BASE(0) | i);
- }
- data->msr00000250 = rdmsr_uint64_t(MTRR_FIX_64K_00000);
- data->msr00000258 = rdmsr_uint64_t(MTRR_FIX_16K_80000);
- for (i = 0; i < 8; i++)
- data->msr0000026[i] = rdmsr_uint64_t(0x00000260 | (i + 8));
- data->msr000002ff = rdmsr_uint64_t(MTRR_DEF_TYPE_MSR);
- data->msrc0010010 = rdmsr_uint64_t(SYSCFG_MSR);
- data->msrc001001a = rdmsr_uint64_t(TOP_MEM);
- data->msrc001001d = rdmsr_uint64_t(TOP_MEM2);
- data->msrc001001f = rdmsr_uint64_t(NB_CFG_MSR);
-
- /* Stage 3 */
- data->f2x40 = read_config32_dct(dev_fn2, node, channel, 0x40);
- data->f2x44 = read_config32_dct(dev_fn2, node, channel, 0x44);
- data->f2x48 = read_config32_dct(dev_fn2, node, channel, 0x48);
- data->f2x4c = read_config32_dct(dev_fn2, node, channel, 0x4c);
- data->f2x50 = read_config32_dct(dev_fn2, node, channel, 0x50);
- data->f2x54 = read_config32_dct(dev_fn2, node, channel, 0x54);
- data->f2x58 = read_config32_dct(dev_fn2, node, channel, 0x58);
- data->f2x5c = read_config32_dct(dev_fn2, node, channel, 0x5c);
- data->f2x60 = read_config32_dct(dev_fn2, node, channel, 0x60);
- data->f2x64 = read_config32_dct(dev_fn2, node, channel, 0x64);
- data->f2x68 = read_config32_dct(dev_fn2, node, channel, 0x68);
- data->f2x6c = read_config32_dct(dev_fn2, node, channel, 0x6c);
- data->f2x78 = read_config32_dct(dev_fn2, node, channel, 0x78);
- data->f2x7c = read_config32_dct(dev_fn2, node, channel, 0x7c);
- data->f2x80 = read_config32_dct(dev_fn2, node, channel, 0x80);
- data->f2x84 = read_config32_dct(dev_fn2, node, channel, 0x84);
- data->f2x88 = read_config32_dct(dev_fn2, node, channel, 0x88);
- data->f2x8c = read_config32_dct(dev_fn2, node, channel, 0x8c);
- data->f2x90 = read_config32_dct(dev_fn2, node, channel, 0x90);
- data->f2xa4 = read_config32_dct(dev_fn2, node, channel, 0xa4);
- data->f2xa8 = read_config32_dct(dev_fn2, node, channel, 0xa8);
-
- /* Family 15h-specific configuration */
- if (is_fam15h()) {
- data->f2x200 = read_config32_dct(dev_fn2, node, channel, 0x200);
- data->f2x204 = read_config32_dct(dev_fn2, node, channel, 0x204);
- data->f2x208 = read_config32_dct(dev_fn2, node, channel, 0x208);
- data->f2x20c = read_config32_dct(dev_fn2, node, channel, 0x20c);
- for (i = 0; i < 4; i++)
- data->f2x210[i] = read_config32_dct_nbpstate(dev_fn2, node, channel, i, 0x210);
- data->f2x214 = read_config32_dct(dev_fn2, node, channel, 0x214);
- data->f2x218 = read_config32_dct(dev_fn2, node, channel, 0x218);
- data->f2x21c = read_config32_dct(dev_fn2, node, channel, 0x21c);
- data->f2x22c = read_config32_dct(dev_fn2, node, channel, 0x22c);
- data->f2x230 = read_config32_dct(dev_fn2, node, channel, 0x230);
- data->f2x234 = read_config32_dct(dev_fn2, node, channel, 0x234);
- data->f2x238 = read_config32_dct(dev_fn2, node, channel, 0x238);
- data->f2x23c = read_config32_dct(dev_fn2, node, channel, 0x23c);
- data->f2x240 = read_config32_dct(dev_fn2, node, channel, 0x240);
-
- data->f2x9cx0d0fe003 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fe003);
- data->f2x9cx0d0fe013 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fe013);
- for (i = 0; i < 9; i++)
- data->f2x9cx0d0f0_8_0_1f[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f001f | (i << 8));
- data->f2x9cx0d0f201f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f201f);
- data->f2x9cx0d0f211f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f211f);
- data->f2x9cx0d0f221f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f221f);
- data->f2x9cx0d0f801f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f801f);
- data->f2x9cx0d0f811f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f811f);
- data->f2x9cx0d0f821f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f821f);
- data->f2x9cx0d0fc01f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc01f);
- data->f2x9cx0d0fc11f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc11f);
- data->f2x9cx0d0fc21f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc21f);
- data->f2x9cx0d0f4009 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f4009);
- for (i = 0; i < 9; i++)
- data->f2x9cx0d0f0_8_0_02[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f0002 | (i << 8));
- for (i = 0; i < 9; i++)
- data->f2x9cx0d0f0_8_0_06[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f0006 | (i << 8));
- for (i = 0; i < 9; i++)
- data->f2x9cx0d0f0_8_0_0a[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f000a | (i << 8));
-
- data->f2x9cx0d0f2002 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f2002);
- data->f2x9cx0d0f2102 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f2102);
- data->f2x9cx0d0f2202 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f2202);
- data->f2x9cx0d0f8002 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f8002);
- data->f2x9cx0d0f8006 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f8006);
- data->f2x9cx0d0f800a = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f800a);
- data->f2x9cx0d0f8102 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f8102);
- data->f2x9cx0d0f8106 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f8106);
- data->f2x9cx0d0f810a = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f810a);
- data->f2x9cx0d0fc002 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc002);
- data->f2x9cx0d0fc006 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc006);
- data->f2x9cx0d0fc00a = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc00a);
- data->f2x9cx0d0fc00e = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc00e);
- data->f2x9cx0d0fc012 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc012);
-
- data->f2x9cx0d0f2031 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f2031);
- data->f2x9cx0d0f2131 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f2131);
- data->f2x9cx0d0f2231 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f2231);
- data->f2x9cx0d0f8031 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f8031);
- data->f2x9cx0d0f8131 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f8131);
- data->f2x9cx0d0f8231 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f8231);
- data->f2x9cx0d0fc031 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc031);
- data->f2x9cx0d0fc131 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc131);
- data->f2x9cx0d0fc231 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fc231);
- for (i = 0; i < 9; i++)
- data->f2x9cx0d0f0_0_f_31[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f0031 | (i << 8));
-
- data->f2x9cx0d0f8021 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f8021);
-
- if (channel == 1)
- data->f2x9cx0d0fe00a = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fe00a);
- }
-
- /* Stage 4 */
- data->f2x94 = read_config32_dct(dev_fn2, node, channel, 0x94);
-
- /* Stage 6 */
- for (i = 0; i < 9; i++)
- for (j = 0; j < 3; j++)
- data->f2x9cx0d0f0_f_8_0_0_8_4_0[i][j] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f0000 | (i << 8) | (j * 4));
- data->f2x9cx00 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x00);
- data->f2x9cx0a = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0a);
- data->f2x9cx0c = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0c);
-
- /* Stage 7 */
- data->f2x9cx04 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x04);
-
- /* Stage 9 */
- data->f2x9cx0d0fe006 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fe006);
- data->f2x9cx0d0fe007 = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0fe007);
-
- /* Stage 10 */
- for (i = 0; i < 12; i++)
- data->f2x9cx10[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x10 + i);
- for (i = 0; i < 12; i++)
- data->f2x9cx20[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x20 + i);
- for (i = 0; i < 4; i++)
- for (j = 0; j < 3; j++)
- data->f2x9cx3_0_0_3_1[i][j] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, (0x01 + i) + (0x100 * j));
- for (i = 0; i < 4; i++)
- for (j = 0; j < 3; j++)
- data->f2x9cx3_0_0_7_5[i][j] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, (0x05 + i) + (0x100 * j));
- data->f2x9cx0d = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d);
- for (i = 0; i < 9; i++)
- data->f2x9cx0d0f0_f_0_13[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f0013 | (i << 8));
- for (i = 0; i < 9; i++)
- data->f2x9cx0d0f0_f_0_30[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f0030 | (i << 8));
- for (i = 0; i < 4; i++)
- data->f2x9cx0d0f2_f_0_30[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f2030 | (i << 8));
- for (i = 0; i < 2; i++)
- for (j = 0; j < 3; j++)
- data->f2x9cx0d0f8_8_4_0[i][j] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f0000 | (i << 8) | (j * 4));
- data->f2x9cx0d0f812f = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x0d0f812f);
-
- /* Stage 11 */
- if (CONFIG(DIMM_DDR3)) {
- for (i = 0; i < 12; i++)
- data->f2x9cx30[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x30 + i);
- for (i = 0; i < 12; i++)
- data->f2x9cx40[i] = read_amd_dct_index_register_dct(dev_fn2, node, channel, 0x98, 0x40 + i);
- }
-
- /* Other */
- /* ECC scrub rate control */
- data->f3x58 = read_config32_dct(dev_fn3, node, 0, 0x58);
-
- /* ECC scrub location */
- write_config32_dct(dev_fn3, node, 0, 0x58, 0x0); /* Disable sequential scrub to work around non-atomic location read */
- data->f3x5c = read_config32_dct(dev_fn3, node, 0, 0x5c);
- data->f3x60 = read_config32_dct(dev_fn3, node, 0, 0x60);
- write_config32_dct(dev_fn3, node, 0, 0x58, data->f3x58); /* Re-enable sequential scrub */
- }
- }
-}
-
-static void write_config32_dct_nbpstate(pci_devfn_t dev, uint8_t node,
- uint8_t dct, uint8_t nb_pstate,
- uint32_t reg, uint32_t value)
-{
- uint32_t dword;
- pci_devfn_t dev_fn1 = PCI_DEV(0, 0x18 + node, 1);
-
- /* Select DCT */
- dword = pci_read_config32(dev_fn1, 0x10c);
- dword &= ~0x1;
- dword |= (dct & 0x1);
- pci_write_config32(dev_fn1, 0x10c, dword);
-
- /* Select NB Pstate index */
- dword = pci_read_config32(dev_fn1, 0x10c);
- dword &= ~(0x3 << 4);
- dword |= (nb_pstate & 0x3) << 4;
- pci_write_config32(dev_fn1, 0x10c, dword);
-
- pci_write_config32(dev, reg, value);
-}
-
-static void write_amd_dct_index_register(pci_devfn_t dev,
- uint32_t index_ctl_reg, uint32_t index,
- uint32_t value)
-{
- uint32_t dword;
-
- pci_write_config32(dev, index_ctl_reg + 0x04, value);
- index |= (1 << 30);
- pci_write_config32(dev, index_ctl_reg, index);
- do {
- dword = pci_read_config32(dev, index_ctl_reg);
- } while (!(dword & (1 << 31)));
-}
-
-static void write_amd_dct_index_register_dct(pci_devfn_t dev, uint8_t node,
- uint8_t dct,
- uint32_t index_ctl_reg,
- uint32_t index, uint32_t value)
-{
- if (is_fam15h()) {
- uint32_t dword;
- pci_devfn_t dev_fn1 = PCI_DEV(0, 0x18 + node, 1);
-
- /* Select DCT */
- dword = pci_read_config32(dev_fn1, 0x10c);
- dword &= ~0x1;
- dword |= (dct & 0x1);
- pci_write_config32(dev_fn1, 0x10c, dword);
- } else {
- /* Apply offset */
- index_ctl_reg += dct * 0x100;
- }
-
- return write_amd_dct_index_register(dev, index_ctl_reg, index, value);
-}
-
-void restore_mct_data_from_save_variable(struct amd_s3_persistent_data *persistent_data, uint8_t training_only)
-{
- uint8_t i;
- uint8_t j;
- uint8_t node;
- uint8_t channel;
- uint8_t ganged;
- uint8_t dct_enabled;
- uint32_t dword;
-
- if (training_only) {
- /* Only restore the Receiver Enable and DQS training registers */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- /* Restore training parameters */
- for (i = 0; i < 4; i++)
- for (j = 0; j < 3; j++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, (0x01 + i) + (0x100 * j), data->f2x9cx3_0_0_3_1[i][j]);
- for (i = 0; i < 4; i++)
- for (j = 0; j < 3; j++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, (0x05 + i) + (0x100 * j), data->f2x9cx3_0_0_7_5[i][j]);
-
- for (i = 0; i < 12; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x10 + i, data->f2x9cx10[i]);
- for (i = 0; i < 12; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x20 + i, data->f2x9cx20[i]);
-
- if (CONFIG(DIMM_DDR3)) {
- for (i = 0; i < 12; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x30 + i, data->f2x9cx30[i]);
- for (i = 0; i < 12; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x40 + i, data->f2x9cx40[i]);
- }
-
- /* Restore MaxRdLatency */
- if (is_fam15h()) {
- for (i = 0; i < 4; i++)
- write_config32_dct_nbpstate(PCI_DEV(0, 0x18 + node, 2), node, channel, i, 0x210, data->f2x210[i]);
- } else {
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x78, data->f2x78);
- }
-
- /* Other timing control registers */
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x8c, data->f2x8c);
- }
- }
-
- return;
- }
-
- /* Load data from data structure into DCTs */
- /* Stage 1 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- pci_write_config32(PCI_DEV(0, 0x18 + node, 2), 0x110, data->f2x110);
- }
- }
-
- /* Stage 2 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x40, data->f1x40);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x44, data->f1x44);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x48, data->f1x48);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x4c, data->f1x4c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x50, data->f1x50);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x54, data->f1x54);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x58, data->f1x58);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x5c, data->f1x5c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x60, data->f1x60);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x64, data->f1x64);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x68, data->f1x68);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x6c, data->f1x6c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x70, data->f1x70);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x74, data->f1x74);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x78, data->f1x78);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x7c, data->f1x7c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0xf0, data->f1xf0);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x120, data->f1x120);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 1), node, channel, 0x124, data->f1x124);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x10c, data->f2x10c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x114, data->f2x114);
- if (is_fam15h())
- /* Do not set LockDramCfg or CC6SaveEn at this time */
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x118, data->f2x118 & ~(0x3 << 18));
- else
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x118, data->f2x118);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x11c, data->f2x11c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x1b0, data->f2x1b0);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 3), node, channel, 0x44, data->f3x44);
- for (i = 0; i < 16; i++) {
- wrmsr_uint64_t(MTRR_PHYS_BASE(0) | i,
- data->msr0000020[i]);
- }
- wrmsr_uint64_t(MTRR_FIX_64K_00000, data->msr00000250);
- wrmsr_uint64_t(MTRR_FIX_16K_80000, data->msr00000258);
- /* FIXME
- * Restoring these MSRs causes a hang on resume due to
- * destroying CAR while still executing from CAR!
- * For now, skip restoration...
- */
- // for (i = 0; i < 8; i++)
- // wrmsr_uint64_t(0x00000260 | (i + 8), data->msr0000026[i]);
- wrmsr_uint64_t(MTRR_DEF_TYPE_MSR, data->msr000002ff);
- wrmsr_uint64_t(SYSCFG_MSR, data->msrc0010010);
- wrmsr_uint64_t(TOP_MEM, data->msrc001001a);
- wrmsr_uint64_t(TOP_MEM2, data->msrc001001d);
- wrmsr_uint64_t(NB_CFG_MSR, data->msrc001001f);
- }
- }
-
- /* Stage 3 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- if (is_fam15h())
- ganged = 0;
- else
- ganged = !!(data->f2x110 & 0x10);
- if ((ganged == 1) && (channel > 0))
- continue;
-
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x40, data->f2x40);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x44, data->f2x44);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x48, data->f2x48);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x4c, data->f2x4c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x50, data->f2x50);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x54, data->f2x54);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x58, data->f2x58);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x5c, data->f2x5c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x60, data->f2x60);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x64, data->f2x64);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x68, data->f2x68);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x6c, data->f2x6c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x78, data->f2x78);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x7c, data->f2x7c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x80, data->f2x80);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x84, data->f2x84);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x88, data->f2x88);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x8c, data->f2x8c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x90, data->f2x90);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0xa4, data->f2xa4);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0xa8, data->f2xa8);
- }
- }
-
- /* Family 15h-specific configuration */
- if (is_fam15h()) {
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- /* Initialize DCT */
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0000000b, 0x80000000);
- dword = read_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe013);
- dword &= ~0xffff;
- dword |= 0x118;
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe013, dword);
-
- /* Restore values */
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x200, data->f2x200);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x204, data->f2x204);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x208, data->f2x208);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x20c, data->f2x20c);
- for (i = 0; i < 4; i++)
- write_config32_dct_nbpstate(PCI_DEV(0, 0x18 + node, 2), node, channel, i, 0x210, data->f2x210[i]);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x214, data->f2x214);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x218, data->f2x218);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x21c, data->f2x21c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x22c, data->f2x22c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x230, data->f2x230);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x234, data->f2x234);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x238, data->f2x238);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x23c, data->f2x23c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x240, data->f2x240);
-
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe013, data->f2x9cx0d0fe013);
- for (i = 0; i < 9; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f001f | (i << 8), data->f2x9cx0d0f0_8_0_1f[i]);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f201f, data->f2x9cx0d0f201f);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f211f, data->f2x9cx0d0f211f);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f221f, data->f2x9cx0d0f221f);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f801f, data->f2x9cx0d0f801f);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f811f, data->f2x9cx0d0f811f);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f821f, data->f2x9cx0d0f821f);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc01f, data->f2x9cx0d0fc01f);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc11f, data->f2x9cx0d0fc11f);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc21f, data->f2x9cx0d0fc21f);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f4009, data->f2x9cx0d0f4009);
-
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f2031, data->f2x9cx0d0f2031);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f2131, data->f2x9cx0d0f2131);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f2231, data->f2x9cx0d0f2231);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f8031, data->f2x9cx0d0f8031);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f8131, data->f2x9cx0d0f8131);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f8231, data->f2x9cx0d0f8231);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc031, data->f2x9cx0d0fc031);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc131, data->f2x9cx0d0fc131);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc231, data->f2x9cx0d0fc231);
- for (i = 0; i < 9; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f0031 | (i << 8), data->f2x9cx0d0f0_0_f_31[i]);
-
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f8021, data->f2x9cx0d0f8021);
-
- if (channel == 1)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe00a, data->f2x9cx0d0fe00a);
- }
- }
- }
-
- /* Stage 4 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- if (is_fam15h())
- ganged = 0;
- else
- ganged = !!(data->f2x110 & 0x10);
- if ((ganged == 1) && (channel > 0))
- continue;
-
- if (is_fam15h()) {
- /* Program PllLockTime = 0x190 */
- dword = read_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe006);
- dword &= ~0xffff;
- dword |= 0x190;
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe006, dword);
-
- /* Program MemClkFreqVal = 0 */
- dword = read_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x94);
- dword &= (0x1 << 7);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x94, dword);
-
- /* Restore DRAM Address/Timing Control Register */
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x04, data->f2x9cx04);
- } else {
- /* Disable PHY auto-compensation engine */
- dword = read_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x08);
- if (!(dword & (1 << 30))) {
- dword |= (1 << 30);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x08, dword);
-
- /* Wait for 5us */
- mct_Wait(100);
- }
- }
-
- /* Restore DRAM Configuration High Register */
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x94, data->f2x94);
- }
- }
-
- /* Stage 5 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- if (is_fam15h())
- ganged = 0;
- else
- ganged = !!(data->f2x110 & 0x10);
- if ((ganged == 1) && (channel > 0))
- continue;
-
- dct_enabled = !(data->f2x94 & (1 << 14));
- if (!dct_enabled)
- continue;
-
- /* Wait for any pending PHY frequency changes to complete */
- do {
- dword = read_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x94);
- } while (dword & (1 << 21));
-
- if (is_fam15h()) {
- /* Program PllLockTime = 0xf */
- dword = read_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe006);
- dword &= ~0xffff;
- dword |= 0xf;
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe006, dword);
- } else {
- /* Enable PHY auto-compensation engine */
- dword = read_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x08);
- dword &= ~(1 << 30);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x08, dword);
- }
- }
- }
-
- /* Wait for 750us */
- mct_Wait(15000);
-
- /* Stage 6 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- for (i = 0; i < 9; i++)
- for (j = 0; j < 3; j++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f0000 | (i << 8) | (j * 4), data->f2x9cx0d0f0_f_8_0_0_8_4_0[i][j]);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x00, data->f2x9cx00);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0a, data->f2x9cx0a);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0c, data->f2x9cx0c);
- }
- }
-
- /* Family 15h-specific configuration */
- if (is_fam15h()) {
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- dword = read_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe003);
- dword |= (0x3 << 13); /* DisAutoComp, DisablePredriverCal = 1 */
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe003, dword);
-
- for (i = 0; i < 9; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f0006 | (i << 8), data->f2x9cx0d0f0_8_0_06[i]);
- for (i = 0; i < 9; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f000a | (i << 8), data->f2x9cx0d0f0_8_0_0a[i]);
- for (i = 0; i < 9; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f0002 | (i << 8), (0x8000 | data->f2x9cx0d0f0_8_0_02[i]));
-
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f8006, data->f2x9cx0d0f8006);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f800a, data->f2x9cx0d0f800a);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f8106, data->f2x9cx0d0f8106);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f810a, data->f2x9cx0d0f810a);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc006, data->f2x9cx0d0fc006);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc00a, data->f2x9cx0d0fc00a);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc00e, data->f2x9cx0d0fc00e);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc012, data->f2x9cx0d0fc012);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f8002, (0x8000 | data->f2x9cx0d0f8002));
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f8102, (0x8000 | data->f2x9cx0d0f8102));
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fc002, (0x8000 | data->f2x9cx0d0fc002));
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f2002, (0x8000 | data->f2x9cx0d0f2002));
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f2102, (0x8000 | data->f2x9cx0d0f2102));
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f2202, (0x8000 | data->f2x9cx0d0f2202));
-
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe003, data->f2x9cx0d0fe003);
- }
- }
- }
-
- /* Stage 7 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- if (is_fam15h())
- ganged = 0;
- else
- ganged = !!(data->f2x110 & 0x10);
- if ((ganged == 1) && (channel > 0))
- continue;
-
- if (!is_fam15h())
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x04, data->f2x9cx04);
- }
- }
-
- /* Stage 8 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- dct_enabled = !(data->f2x94 & (1 << 14));
- if (!dct_enabled)
- continue;
-
- if (is_fam15h())
- ganged = 0;
- else
- ganged = !!(data->f2x110 & 0x10);
- if ((ganged == 1) && (channel > 0))
- continue;
-
- printk(BIOS_SPEW, "Taking DIMMs out of self refresh node: %d channel: %d\n", node, channel);
-
- /* Exit self refresh mode */
- dword = read_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x90);
- dword |= (1 << 1);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x90, dword);
- }
- }
-
- /* Stage 9 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- dct_enabled = !(data->f2x94 & (1 << 14));
- if (!dct_enabled)
- continue;
-
- printk(BIOS_SPEW, "Waiting for DIMMs to exit self refresh node: %d channel: %d\n", node, channel);
-
- /* Wait for transition from self refresh mode to complete */
- do {
- dword = read_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x90);
- } while (dword & (1 << 1));
-
- /* Restore registers */
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe006, data->f2x9cx0d0fe006);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0fe007, data->f2x9cx0d0fe007);
- }
- }
-
- /* Stage 10 */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- for (i = 0; i < 12; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x10 + i, data->f2x9cx10[i]);
- for (i = 0; i < 12; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x20 + i, data->f2x9cx20[i]);
- for (i = 0; i < 4; i++)
- for (j = 0; j < 3; j++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, (0x01 + i) + (0x100 * j), data->f2x9cx3_0_0_3_1[i][j]);
- for (i = 0; i < 4; i++)
- for (j = 0; j < 3; j++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, (0x05 + i) + (0x100 * j), data->f2x9cx3_0_0_7_5[i][j]);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d, data->f2x9cx0d);
- for (i = 0; i < 9; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f0013 | (i << 8), data->f2x9cx0d0f0_f_0_13[i]);
- for (i = 0; i < 9; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f0030 | (i << 8), data->f2x9cx0d0f0_f_0_30[i]);
- for (i = 0; i < 4; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f2030 | (i << 8), data->f2x9cx0d0f2_f_0_30[i]);
- for (i = 0; i < 2; i++)
- for (j = 0; j < 3; j++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f0000 | (i << 8) | (j * 4), data->f2x9cx0d0f8_8_4_0[i][j]);
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x0d0f812f, data->f2x9cx0d0f812f);
- }
- }
-
- /* Stage 11 */
- if (CONFIG(DIMM_DDR3)) {
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- for (i = 0; i < 12; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x30 + i, data->f2x9cx30[i]);
- for (i = 0; i < 12; i++)
- write_amd_dct_index_register_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x98, 0x40 + i, data->f2x9cx40[i]);
- }
- }
- }
-
- /* Other */
- for (node = 0; node < MAX_NODES_SUPPORTED; node++) {
- for (channel = 0; channel < 2; channel++) {
- struct amd_s3_persistent_mct_channel_data *data = &persistent_data->node[node].channel[channel];
- if (!persistent_data->node[node].node_present)
- continue;
-
- /* ECC scrub location */
- write_config32_dct(PCI_DEV(0, 0x18 + node, 3), node, 0, 0x5c, data->f3x5c);
- write_config32_dct(PCI_DEV(0, 0x18 + node, 3), node, 0, 0x60, data->f3x60);
-
- /* ECC scrub rate control */
- write_config32_dct(PCI_DEV(0, 0x18 + node, 3), node, 0, 0x58, data->f3x58);
-
- if (is_fam15h())
- /* Set LockDramCfg and CC6SaveEn */
- write_config32_dct(PCI_DEV(0, 0x18 + node, 2), node, channel, 0x118, data->f2x118);
- }
- }
-}
-
-int8_t save_mct_information_to_nvram(void)
-{
- uint8_t nvram;
- uint8_t restored = 0;
-
- if (acpi_is_wakeup_s3())
- return 0;
-
- printk(BIOS_DEBUG, "Writing AMD DCT configuration to Flash\n");
-
- struct spi_flash flash;
- ssize_t s3nv_offset;
- struct amd_s3_persistent_data *persistent_data;
-
- /* Allocate temporary data structures */
- persistent_data = malloc(sizeof(struct amd_s3_persistent_data));
- if (!persistent_data) {
- printk(BIOS_DEBUG, "Could not allocate S3 data structure in RAM\n");
- return -1;
- }
-
- /* Obtain MCT configuration data */
- copy_mct_data_to_save_variable(persistent_data);
-
- /* Save RAM SPD data at the same time */
- copy_cbmem_spd_data_to_save_variable(persistent_data, &restored);
-
- if (restored) {
- /* Allow training bypass if DIMM configuration is unchanged on next boot */
- nvram = 1;
- set_option("allow_spd_nvram_cache_restore", &nvram);
-
- printk(BIOS_DEBUG, "Hardware configuration unchanged since last boot; skipping write\n");
- free(persistent_data);
- return 0;
- }
-
- /* Obtain CBFS file offset */
- s3nv_offset = get_s3nv_file_offset();
- if (s3nv_offset == -1) {
- free(persistent_data);
- return -1;
- }
-
- /* Align flash pointer to nearest boundary */
- s3nv_offset &= ~(CONFIG_S3_DATA_SIZE-1);
- s3nv_offset += CONFIG_S3_DATA_SIZE;
-
- /* Initialize SPI and detect devices */
- spi_init();
- if (spi_flash_probe(0, 0, &flash)) {
- printk(BIOS_DEBUG, "Could not find SPI device\n");
- return -1;
- }
-
- spi_flash_volatile_group_begin(&flash);
-
- /* Erase and write data structure */
- spi_flash_erase(&flash, s3nv_offset, CONFIG_S3_DATA_SIZE);
- spi_flash_write(&flash, s3nv_offset,
- sizeof(struct amd_s3_persistent_data), persistent_data);
-
- /* Deallocate temporary data structures */
- free(persistent_data);
-
- spi_flash_volatile_group_end(&flash);
-
- /* Allow training bypass if DIMM configuration is unchanged on next boot */
- nvram = 1;
- set_option("allow_spd_nvram_cache_restore", &nvram);
-
- return 0;
-}
-
-int8_t restore_mct_information_from_nvram(uint8_t training_only)
-{
- struct amd_s3_persistent_data *persistent_data;
-
- persistent_data = map_s3nv_in_nvram();
- if (!persistent_data)
- return -1;
-
- restore_mct_data_from_save_variable(persistent_data, training_only);
-
- return 0;
-}
-
-void calculate_and_store_spd_hashes(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- uint8_t dimm;
-
- for (dimm = 0; dimm < MAX_DIMMS_SUPPORTED; dimm++) {
- calculate_spd_hash(pDCTstat->spd_data.spd_bytes[dimm], &pDCTstat->spd_data.spd_hash[dimm]);
- }
-}
-
-void compare_nvram_spd_hashes(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat)
-{
- uint8_t dimm;
-
- pDCTstat->spd_data.nvram_spd_match = 1;
- for (dimm = 0; dimm < MAX_DIMMS_SUPPORTED; dimm++) {
- if (pDCTstat->spd_data.spd_hash[dimm] != pDCTstat->spd_data.nvram_spd_hash[dimm])
- pDCTstat->spd_data.nvram_spd_match = 0;
- }
-}
diff --git a/src/northbridge/amd/amdmct/mct_ddr3/s3utils.h b/src/northbridge/amd/amdmct/mct_ddr3/s3utils.h
deleted file mode 100644
index d13cb23c80..0000000000
--- a/src/northbridge/amd/amdmct/mct_ddr3/s3utils.h
+++ /dev/null
@@ -1,31 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-#ifndef S3UTILS_H
-#define S3UTILS_H
-
-#include "../wrappers/mcti.h"
-#include "mct_d.h"
-
-#ifdef __RAMSTAGE__
-int8_t save_mct_information_to_nvram(void);
-void copy_mct_data_to_save_variable(struct amd_s3_persistent_data* persistent_data);
-#endif
-
-void calculate_and_store_spd_hashes(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-void compare_nvram_spd_hashes(struct MCTStatStruc *pMCTstat,
- struct DCTStatStruc *pDCTstat);
-
-#endif
diff --git a/src/northbridge/amd/amdmct/wrappers/Makefile.inc b/src/northbridge/amd/amdmct/wrappers/Makefile.inc
deleted file mode 100644
index 5773067138..0000000000
--- a/src/northbridge/amd/amdmct/wrappers/Makefile.inc
+++ /dev/null
@@ -1,5 +0,0 @@
-ifeq ($(CONFIG_NORTHBRIDGE_AMD_AMDFAM10),y)
-
-romstage-y += mcti_d.c
-
-endif
diff --git a/src/northbridge/amd/amdmct/wrappers/mcti.h b/src/northbridge/amd/amdmct/wrappers/mcti.h
deleted file mode 100644
index cc0e1b29b2..0000000000
--- a/src/northbridge/amd/amdmct/wrappers/mcti.h
+++ /dev/null
@@ -1,153 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2007 Advanced Micro Devices, Inc.
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2016 Damien Zammit <damien@zamaudio.com>
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-#ifndef MCTI_H
-#define MCTI_H
-
-#include <stdint.h>
-#include <stdlib.h>
-#include <pc80/mc146818rtc.h>
-
-struct DCTStatStruc;
-struct MCTStatStruc;
-
-#define SERVER 0
-#define DESKTOP 1
-//#define MOBILE 2
-#define REV_F 0
-#define REV_DR 1
-#define REV_FDR 2
-
-/*----------------------------------------------------------------------------
-COMMENT OUT ALL BUT 1
-----------------------------------------------------------------------------*/
-//#define BUILD_VERSION REV_F /*BIOS supports rev F only*/
-//#define BUILD_VERSION REV_DR /*BIOS supports rev 10 only*/
-//#define BUILD_VERSION REV_FDR /*BIOS supports both rev F and 10*/
-
-/*----------------------------------------------------------------------------
-COMMENT OUT ALL BUT 1
-----------------------------------------------------------------------------*/
-#ifndef SYSTEM_TYPE
-#define SYSTEM_TYPE SERVER
-//#define SYSTEM_TYPE DESKTOP
-//#define SYSTEM_TYPE MOBILE
-#endif
-
-/*----------------------------------------------------------------------------
-UPDATE AS NEEDED
-----------------------------------------------------------------------------*/
-#ifndef MAX_NODES_SUPPORTED
-#define MAX_NODES_SUPPORTED 8
-#endif
-
-#ifndef MAX_DIMMS_SUPPORTED
-#if CONFIG(DIMM_DDR3)
- #define MAX_DIMMS_SUPPORTED 6
-#else
- #define MAX_DIMMS_SUPPORTED 8
-#endif
-#endif
-
-#ifndef MAX_CS_SUPPORTED
-#define MAX_CS_SUPPORTED 8
-#endif
-
-#ifndef MCT_DIMM_SPARE_NO_WARM
-#define MCT_DIMM_SPARE_NO_WARM 0
-#endif
-
-#ifndef MEM_MAX_LOAD_FREQ
-#if CONFIG(DIMM_DDR3)
- #define MEM_MAX_LOAD_FREQ 933
- #define MEM_MIN_PLATFORM_FREQ_FAM10 400
- #define MEM_MIN_PLATFORM_FREQ_FAM15 333
-#else /* AMD_FAM10_DDR2 */
- #define MEM_MAX_LOAD_FREQ 400
- #define MEM_MIN_PLATFORM_FREQ_FAM10 200
- /* DDR2 not available on Family 15h */
- #define MEM_MIN_PLATFORM_FREQ_FAM15 0
-#endif
-#endif
-
-#define MCT_TRNG_KEEPOUT_START 0x00000C00
-#define MCT_TRNG_KEEPOUT_END 0x00000CFF
-
-#define NVRAM_DDR2_800 0
-#define NVRAM_DDR2_667 1
-#define NVRAM_DDR2_533 2
-#define NVRAM_DDR2_400 3
-
-#define NVRAM_DDR3_1600 0
-#define NVRAM_DDR3_1333 1
-#define NVRAM_DDR3_1066 2
-#define NVRAM_DDR3_800 3
-
-/* The recommended maximum GFX Upper Memory Area
- * size is 256M, however, to be on the safe side
- * move TOM down by 512M.
- */
-#define MAXIMUM_GFXUMA_SIZE 0x20000000
-
-/* Do not allow less than 16M of DRAM in 32-bit space.
- * This number is not hardware constrained and can be
- * changed as needed.
- */
-#define MINIMUM_DRAM_BELOW_4G 0x1000000
-
-static const uint16_t ddr2_limits[4] = {400, 333, 266, 200};
-static const uint16_t ddr3_limits[16] = {933, 800, 666, 533, 400, 333, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
-
-#if CONFIG(DIMM_DDR3)
- #include <northbridge/amd/amdmct/mct_ddr3/mct_d.h>
-#else
- #include <northbridge/amd/amdmct/mct/mct_d.h>
-#endif
-
-#if CONFIG(DIMM_DDR2)
-void mctSaveDQSSigTmg_D(void);
-void mctGetDQSSigTmg_D(void);
-u8 mctSetNodeBoundary_D(void);
-#endif
-u16 mctGet_NVbits(u8 index);
-void mctHookAfterDIMMpre(void);
-void mctGet_MaxLoadFreq(struct DCTStatStruc *pDCTstat);
-void mctAdjustAutoCycTmg_D(void);
-void mctHookAfterAutoCycTmg(void);
-void mctGetCS_ExcludeMap(void);
-void mctHookBeforeECC(void);
-void mctHookAfterECC(void);
-void mctHookAfterAutoCfg(void);
-void mctHookAfterPSCfg(void);
-void mctHookAfterHTMap(void);
-void mctHookAfterCPU(void);
-void mctInitMemGPIOs_A_D(void);
-void mctNodeIDDebugPort_D(void);
-void mctWarmReset_D(void);
-void mctHookBeforeDramInit(void);
-void mctHookAfterDramInit(void);
-void mctHookBeforeAnyTraining(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA);
-void mctHookAfterAnyTraining(void);
-uint64_t mctGetLogicalCPUID_D(u8 node);
-
-#if CONFIG(DIMM_DDR3)
-void vErratum372(struct DCTStatStruc *pDCTstat);
-void vErratum414(struct DCTStatStruc *pDCTstat);
-u32 mct_AdjustSPDTimings(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA, u32 val);
-#endif
-
-#endif
diff --git a/src/northbridge/amd/amdmct/wrappers/mcti_d.c b/src/northbridge/amd/amdmct/wrappers/mcti_d.c
deleted file mode 100644
index b8042fe46d..0000000000
--- a/src/northbridge/amd/amdmct/wrappers/mcti_d.c
+++ /dev/null
@@ -1,543 +0,0 @@
-/*
- * This file is part of the coreboot project.
- *
- * Copyright (C) 2015 Timothy Pearson <tpearson@raptorengineeringinc.com>, Raptor Engineering
- * Copyright (C) 2007-2008 Advanced Micro Devices, Inc.
- *
- * This program is free software; you can redistribute it and/or modify
- * it under the terms of the GNU General Public License as published by
- * the Free Software Foundation; version 2 of the License.
- *
- * This program is distributed in the hope that it will be useful,
- * but WITHOUT ANY WARRANTY; without even the implied warranty of
- * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
- * GNU General Public License for more details.
- */
-
-/* Call-backs */
-
-#include <arch/cpu.h>
-#include <cpu/amd/msr.h>
-#include <console/console.h>
-#include <types.h>
-
-#include "mcti.h"
-
-#define NVRAM_DDR2_800 0
-#define NVRAM_DDR2_667 1
-#define NVRAM_DDR2_533 2
-#define NVRAM_DDR2_400 3
-
-#define NVRAM_DDR3_1600 0
-#define NVRAM_DDR3_1333 1
-#define NVRAM_DDR3_1066 2
-#define NVRAM_DDR3_800 3
-
-static inline uint8_t isfam15h(void)
-{
- uint8_t fam15h = 0;
- uint32_t family;
-
- family = cpuid_eax(0x80000001);
- family = ((family & 0xf00000) >> 16) | ((family & 0xf00) >> 8);
-
- if (family >= 0x6f)
- /* Family 15h or later */
- fam15h = 1;
-
- return fam15h;
-}
-
-/* The recommended maximum GFX Upper Memory Area
- * size is 256M, however, to be on the safe side
- * move TOM down by 512M.
- */
-#define MAXIMUM_GFXUMA_SIZE 0x20000000
-
-/* Do not allow less than 16M of DRAM in 32-bit space.
- * This number is not hardware constrained and can be
- * changed as needed.
- */
-#define MINIMUM_DRAM_BELOW_4G 0x1000000
-
-u16 mctGet_NVbits(u8 index)
-{
- u16 val = 0;
- int nvram;
-
- switch (index) {
- case NV_PACK_TYPE:
-#if CONFIG_CPU_SOCKET_TYPE == 0x10 /* Socket F */
- val = 0;
-#elif CONFIG_CPU_SOCKET_TYPE == 0x11 /* AM3 */
- val = 1;
-#elif CONFIG_CPU_SOCKET_TYPE == 0x13 /* ASB2 */
- val = 4;
-#elif CONFIG_CPU_SOCKET_TYPE == 0x14 /* C32 */
- val = 5;
-#elif CONFIG_CPU_SOCKET_TYPE == 0x15 /* G34 */
- val = 3;
-#elif CONFIG_CPU_SOCKET_TYPE == 0x16 /* FM2 */
- val = 6;
-//#elif SYSTEM_TYPE == MOBILE
-// val = 2;
-#endif
- break;
- case NV_MAX_NODES:
- val = MAX_NODES_SUPPORTED;
- break;
- case NV_MAX_DIMMS:
- val = MAX_DIMMS_SUPPORTED;
- //val = 8;
- break;
- case NV_MAX_DIMMS_PER_CH:
- /* FIXME
- * Mainboards need to be able to specify the maximum number of DIMMs installable per channel
- * For now assume a maximum of 2 DIMMs per channel can be installed
- */
- val = 2;
- break;
- case NV_MAX_MEMCLK:
- /* Maximum platform supported memclk */
- val = MEM_MAX_LOAD_FREQ;
-
- if (get_option(&nvram, "max_mem_clock") == CB_SUCCESS) {
- int limit = val;
- if (CONFIG(DIMM_DDR3))
- limit = ddr3_limits[nvram & 0xf];
- else if (CONFIG(DIMM_DDR2))
- limit = ddr2_limits[nvram & 0x3];
- val = min(limit, val);
- }
- break;
- case NV_MIN_MEMCLK:
- /* Minimum platform supported memclk */
- if (isfam15h())
- val = MEM_MIN_PLATFORM_FREQ_FAM15;
- else
- val = MEM_MIN_PLATFORM_FREQ_FAM10;
- break;
- case NV_ECC_CAP:
-#if SYSTEM_TYPE == SERVER
- val = 1; /* memory bus ECC capable */
-#else
- val = 0; /* memory bus ECC not capable */
-#endif
- break;
- case NV_4RANKType:
- /* Quad Rank DIMM slot type */
- val = 0; /* normal */
- //val = 1; /* R4 (registered DIMMs in AMD server configuration) */
- //val = 2; /* S4 (Unbuffered SO-DIMMS) */
- break;
- case NV_BYPMAX:
-#if !CONFIG(GFXUMA)
- val = 4;
-#elif CONFIG(GFXUMA)
- val = 7;
-#endif
- break;
- case NV_RDWRQBYP:
-#if !CONFIG(GFXUMA)
- val = 2;
-#elif CONFIG(GFXUMA)
- val = 3;
-#endif
- break;
- case NV_MCTUSRTMGMODE:
- val = 0; /* Automatic (recommended) */
- //val = 1; /* Limited */
- //val = 2; /* Manual */
- break;
- case NV_MemCkVal:
- //val = 0; /* 200MHz */
- //val = 1; /* 266MHz */
- val = 2; /* 333MHz */
- break;
- case NV_BankIntlv:
- /* Bank (chip select) interleaving */
- //val = 0; /* disabled */
- val = 1; /* enabled (recommended) */
-
- if (get_option(&nvram, "interleave_chip_selects") == CB_SUCCESS)
- val = !!nvram;
- break;
- case NV_MemHole:
- //val = 0; /* Disabled */
- val = 1; /* Enabled (recommended) */
- break;
- case NV_AllMemClks:
- val = 0; /* Normal (only to slots that have enabled DIMMs) */
- //val = 1; /* Enable all memclocks */
- break;
- case NV_SPDCHK_RESTRT:
- val = 0; /* Exit current node initialization if any DIMM has SPD checksum error */
- //val = 1; /* Ignore faulty SPD checksum (DIMM will still be disabled), continue current node initialization */
- //val = 2; /* Override faulty SPD checksum (DIMM will be enabled), continue current node initialization */
-
- if (get_option(&nvram, "dimm_spd_checksum") == CB_SUCCESS)
- val = nvram & 0x3;
-
- if (val > 2)
- val = 2;
-
- break;
- case NV_DQSTrainCTL:
- //val = 0; /*Skip dqs training */
- val = 1; /* Perform dqs training */
- break;
- case NV_NodeIntlv:
- val = 0; /* Disabled (recommended) */
- //val = 1; /* Enable */
-
- if (get_option(&nvram, "interleave_nodes") == CB_SUCCESS)
- val = !!nvram;
- break;
- case NV_BurstLen32:
-#if !CONFIG(GFXUMA)
- val = 0; /* 64 byte mode */
-#elif CONFIG(GFXUMA)
- val = 1; /* 32 byte mode */
-#endif
- break;
- case NV_CKE_PDEN:
- //val = 0; /* Disable */
- val = 1; /* Enable */
- break;
- case NV_CKE_CTL:
- val = 0; /* per channel control */
- //val = 1; /* per chip select control */
- break;
- case NV_CLKHZAltVidC3:
- val = 0; /* disable */
- //val = 1; /* enable */
- break;
- case NV_BottomIO:
- case NV_BottomUMA:
- /* address bits [31:24] */
-#if !CONFIG(GFXUMA)
- val = (CONFIG_MMCONF_BASE_ADDRESS >> 24);
-#elif CONFIG(GFXUMA)
- #if (CONFIG_MMCONF_BASE_ADDRESS < (MAXIMUM_GFXUMA_SIZE + MINIMUM_DRAM_BELOW_4G))
- #error "MMCONF_BASE_ADDRESS is too small"
- #endif
- val = ((CONFIG_MMCONF_BASE_ADDRESS - MAXIMUM_GFXUMA_SIZE) >> 24);
-#endif
- break;
- case NV_ECC:
-#if (SYSTEM_TYPE == SERVER)
- val = 1; /* Enable */
-#else
- val = 0; /* Disable */
-#endif
-
- if (get_option(&nvram, "ECC_memory") == CB_SUCCESS)
- val = !!nvram;
- break;
- case NV_NBECC:
-#if (SYSTEM_TYPE == SERVER)
- val = 1; /* Enable */
-#else
- val = 0; /* Disable */
-#endif
- break;
- case NV_ChipKill:
-#if (SYSTEM_TYPE == SERVER)
- val = 1; /* Enable */
-#else
- val = 0; /* Disable */
-#endif
- break;
- case NV_ECCRedir:
- /*
- * 0: Disable
- * 1: Enable
- */
- val = 0;
-
- if (get_option(&nvram, "ECC_redirection") == CB_SUCCESS)
- val = !!nvram;
- break;
- case NV_DramBKScrub:
- /*
- * 0x00: Disabled
- * 0x01: 40ns
- * 0x02: 80ns
- * 0x03: 160ns
- * 0x04: 320ns
- * 0x05: 640ns
- * 0x06: 1.28us
- * 0x07: 2.56us
- * 0x08: 5.12us
- * 0x09: 10.2us
- * 0x0a: 20.5us
- * 0x0b: 41us
- * 0x0c: 81.9us
- * 0x0d: 163.8us
- * 0x0e: 327.7us
- * 0x0f: 655.4us
- * 0x10: 1.31ms
- * 0x11: 2.62ms
- * 0x12: 5.24ms
- * 0x13: 10.49ms
- * 0x14: 20.97sms
- * 0x15: 42ms
- * 0x16: 84ms
- */
- val = 0;
-
- if ((get_option(&nvram, "ecc_scrub_rate") == CB_SUCCESS) && (nvram <= 0x16))
- val = nvram;
- break;
- case NV_L2BKScrub:
- val = 0; /* Disabled - See L2Scrub in BKDG */
- break;
- case NV_L3BKScrub:
- val = 0; /* Disabled - See L3Scrub in BKDG */
- break;
- case NV_DCBKScrub:
- val = 0; /* Disabled - See DcacheScrub in BKDG */
- break;
- case NV_CS_SpareCTL:
- val = 0; /* Disabled */
- //val = 1; /* Enabled */
- break;
- case NV_SyncOnUnEccEn:
- val = 0; /* Disabled */
- //val = 1; /* Enabled */
- break;
- case NV_Unganged:
- /* channel interleave is better performance than ganged mode at this time */
- val = 1; /* Enabled */
- //val = 0; /* Disabled */
-
- if (get_option(&nvram, "interleave_memory_channels") == CB_SUCCESS)
- val = !!nvram;
- break;
- case NV_ChannelIntlv:
- val = 5; /* Not currently checked in mctchi_d.c */
- /* Bit 0 = 0 - Disable
- * 1 - Enable
- * Bits[2:1] = 00b - Address bits 6
- * 01b - Address bits 1
- * 10b - Hash*, XOR of address bits [20:16, 6]
- * 11b - Hash*, XOR of address bits [20:16, 9]
- */
- break;
- }
-
- return val;
-}
-
-
-void mctHookAfterDIMMpre(void)
-{
-}
-
-
-void mctGet_MaxLoadFreq(struct DCTStatStruc *pDCTstat)
-{
- pDCTstat->PresetmaxFreq = mctGet_NVbits(NV_MAX_MEMCLK);
-
- /* Determine the number of installed DIMMs */
- int ch1_count = 0;
- int ch2_count = 0;
- uint8_t ch1_registered = 0;
- uint8_t ch2_registered = 0;
- uint8_t ch1_voltage = 0;
- uint8_t ch2_voltage = 0;
- uint8_t highest_rank_count[2];
- uint8_t dimm;
- int i;
- for (i = 0; i < 15; i = i + 2) {
- if (pDCTstat->DIMMValid & (1 << i))
- ch1_count++;
- if (pDCTstat->DIMMValid & (1 << (i + 1)))
- ch2_count++;
- }
- for (i = 0; i < MAX_DIMMS_SUPPORTED; i = i + 2) {
- if (pDCTstat->DimmRegistered[i])
- ch1_registered = 1;
- if (pDCTstat->DimmRegistered[i + 1])
- ch2_registered = 1;
- }
- if (CONFIG(DEBUG_RAM_SETUP)) {
- printk(BIOS_DEBUG, "mctGet_MaxLoadFreq: Channel 1: %d DIMM(s) detected\n", ch1_count);
- printk(BIOS_DEBUG, "mctGet_MaxLoadFreq: Channel 2: %d DIMM(s) detected\n", ch2_count);
- }
-
-#if CONFIG(DIMM_DDR3)
- for (i = 0; i < MAX_DIMMS_SUPPORTED; i = i + 2) {
- if (pDCTstat->DIMMValid & (1 << i))
- ch1_voltage |= pDCTstat->DimmConfiguredVoltage[i];
- if (pDCTstat->DIMMValid & (1 << (i + 1)))
- ch2_voltage |= pDCTstat->DimmConfiguredVoltage[i + 1];
- }
-#endif
-
- for (i = 0; i < 2; i++) {
- highest_rank_count[i] = 0x0;
- for (dimm = 0; dimm < MAX_DIMMS_SUPPORTED; dimm++) {
- if (pDCTstat->DimmRanks[dimm] > highest_rank_count[i])
- highest_rank_count[i] = pDCTstat->DimmRanks[dimm];
- }
- }
-
- /* Set limits if needed */
- pDCTstat->PresetmaxFreq = mct_MaxLoadFreq(max(ch1_count, ch2_count), max(highest_rank_count[0], highest_rank_count[1]), (ch1_registered || ch2_registered), (ch1_voltage | ch2_voltage), pDCTstat->PresetmaxFreq);
-}
-
-void mctAdjustAutoCycTmg_D(void)
-{
-}
-
-
-void mctHookAfterAutoCycTmg(void)
-{
-}
-
-
-void mctGetCS_ExcludeMap(void)
-{
-}
-
-
-void mctHookAfterAutoCfg(void)
-{
-}
-
-
-void mctHookAfterPSCfg(void)
-{
-}
-
-
-void mctHookAfterHTMap(void)
-{
-}
-
-
-void mctHookAfterCPU(void)
-{
-}
-
-
-#if CONFIG(DIMM_DDR2)
-void mctSaveDQSSigTmg_D(void)
-{
-}
-
-void mctGetDQSSigTmg_D(void)
-{
-}
-#endif
-
-void mctHookBeforeECC(void)
-{
-}
-
-void mctHookAfterECC(void)
-{
-}
-
-#ifdef UNUSED_CODE
-void mctInitMemGPIOs_A(void)
-{
-}
-#endif
-
-
-void mctInitMemGPIOs_A_D(void)
-{
-}
-
-
-void mctNodeIDDebugPort_D(void)
-{
-}
-
-
-void mctWarmReset_D(void)
-{
-}
-
-
-void mctHookBeforeDramInit(void)
-{
-}
-
-
-void mctHookAfterDramInit(void)
-{
-}
-
-#if CONFIG(DIMM_DDR3)
-void vErratum372(struct DCTStatStruc *pDCTstat)
-{
- msr_t msr = rdmsr(NB_CFG_MSR);
-
- int nbPstate1supported = !(msr.hi & (1 << (NB_GfxNbPstateDis -32)));
-
- // is this the right way to check for NB pstate 1 or DDR3-1333 ?
- if (((pDCTstat->PresetmaxFreq == 1333)||(nbPstate1supported))
- && (!pDCTstat->GangedMode)) {
- /* DisableCf8ExtCfg */
- msr.hi &= ~(3 << (51 - 32));
- wrmsr(NB_CFG_MSR, msr);
- }
-}
-
-void vErratum414(struct DCTStatStruc *pDCTstat)
-{
- int dct = 0;
- for (; dct < 2 ; dct++) {
- int dRAMConfigHi = Get_NB32(pDCTstat->dev_dct,0x94 + (0x100 * dct));
- int powerDown = dRAMConfigHi & (1 << PowerDownEn);
- int ddr3 = dRAMConfigHi & (1 << Ddr3Mode);
- int dRAMMRS = Get_NB32(pDCTstat->dev_dct,0x84 + (0x100 * dct));
- int pchgPDModeSel = dRAMMRS & (1 << PchgPDModeSel);
- if (powerDown && ddr3 && pchgPDModeSel)
- Set_NB32(pDCTstat->dev_dct,0x84 + (0x100 * dct), dRAMMRS & ~(1 << PchgPDModeSel));
- }
-}
-#endif
-
-
-void mctHookBeforeAnyTraining(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA)
-{
-#if CONFIG(DIMM_DDR3)
- /* FIXME : as of 25.6.2010 errata 350 and 372 should apply to ((RB|BL|DA)-C[23])|(HY-D[01])|(PH-E0) but I don't find constants for all of them */
- if (pDCTstatA->LogicalCPUID & (AMD_DRBH_Cx | AMD_DR_Dx)) {
- vErratum372(pDCTstatA);
- vErratum414(pDCTstatA);
- }
-#endif
-}
-
-#if CONFIG(DIMM_DDR3)
-u32 mct_AdjustSPDTimings(struct MCTStatStruc *pMCTstat, struct DCTStatStruc *pDCTstatA, u32 val)
-{
- if (pDCTstatA->LogicalCPUID & AMD_DR_Bx) {
- if (pDCTstatA->Status & (1 << SB_Registered)) {
- val ++;
- }
- }
- return val;
-}
-#endif
-
-void mctHookAfterAnyTraining(void)
-{
-}
-
-uint64_t mctGetLogicalCPUID_D(u8 node)
-{
- return mctGetLogicalCPUID(node);
-}
-
-#if CONFIG(DIMM_DDR2)
-u8 mctSetNodeBoundary_D(void)
-{
- return 0;
-}
-#endif