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|
/*
* This file is part of the coreboot project.
*
* Copyright (C) 2002 Linux Networx
* (Written by Eric Biederman <ebiederman@lnxi.com> for Linux Networx)
* Copyright (C) 2004 YingHai Lu
* Copyright (C) 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/io.h>
#include <console/console.h>
#include <cpu/x86/cache.h>
#include <cpu/x86/msr.h>
#include <cpu/x86/mtrr.h>
#include <cpu/x86/tsc.h>
#include <cpu/amd/mtrr.h>
#include <pc80/mc146818rtc.h>
#include <lib.h>
#include <stdlib.h>
#include <string.h>
#include <arch/acpi.h>
#include "amdk8.h"
#include "raminit.h"
#include "f.h"
#include <spd_ddr2.h>
#if IS_ENABLED(CONFIG_HAVE_OPTION_TABLE)
#include "option_table.h"
#endif
#if IS_ENABLED(CONFIG_DEBUG_RAM_SETUP)
#define printk_raminit(args...) printk(BIOS_DEBUG, args)
#else
#define printk_raminit(args...)
#endif
#include <arch/early_variables.h>
struct sys_info sysinfo_car CAR_GLOBAL;
#include "f_pci.c"
/* for PCI_ADDR(0, 0x18, 2, 0x98) index,
and PCI_ADDR(0x, 0x18, 2, 0x9c) data */
/*
index:
[29: 0] DctOffset (Dram Controller Offset)
[30:30] DctAccessWrite (Dram Controller Read/Write Select)
0 = read access
1 = write access
[31:31] DctAccessDone (Dram Controller Access Done)
0 = Access in progress
1 = No access is progress
Data:
[31: 0] DctOffsetData (Dram Controller Offset Data)
Read:
- Write the register num to DctOffset with
DctAccessWrite = 0
- poll the DctAccessDone until it = 1
- Read the data from DctOffsetData
Write:
- Write the data to DctOffsetData
- Write register num to DctOffset with DctAccessWrite = 1
- poll the DctAccessDone until it = 1
*/
void setup_resource_map(const unsigned int *register_values, int max)
{
int i;
for (i = 0; i < max; i += 3) {
pci_devfn_t dev;
unsigned where;
unsigned long reg;
dev = register_values[i] & ~0xff;
where = register_values[i] & 0xff;
reg = pci_read_config32(dev, where);
reg &= register_values[i+1];
reg |= register_values[i+2];
pci_write_config32(dev, where, reg);
}
}
static int controller_present(const struct mem_controller *ctrl)
{
return pci_read_config32(ctrl->f0, 0) == 0x11001022;
}
void sdram_set_registers(const struct mem_controller *ctrl, struct sys_info *sysinfo)
{
static const unsigned int 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.
*/
PCI_ADDR(0, 0x18, 1, 0x44), 0x0000f8f8, 0x00000000,
PCI_ADDR(0, 0x18, 1, 0x4C), 0x0000f8f8, 0x00000001,
PCI_ADDR(0, 0x18, 1, 0x54), 0x0000f8f8, 0x00000002,
PCI_ADDR(0, 0x18, 1, 0x5C), 0x0000f8f8, 0x00000003,
PCI_ADDR(0, 0x18, 1, 0x64), 0x0000f8f8, 0x00000004,
PCI_ADDR(0, 0x18, 1, 0x6C), 0x0000f8f8, 0x00000005,
PCI_ADDR(0, 0x18, 1, 0x74), 0x0000f8f8, 0x00000006,
PCI_ADDR(0, 0x18, 1, 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 = Interleave 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.
*/
PCI_ADDR(0, 0x18, 1, 0x40), 0x0000f8fc, 0x00000000,
PCI_ADDR(0, 0x18, 1, 0x48), 0x0000f8fc, 0x00000000,
PCI_ADDR(0, 0x18, 1, 0x50), 0x0000f8fc, 0x00000000,
PCI_ADDR(0, 0x18, 1, 0x58), 0x0000f8fc, 0x00000000,
PCI_ADDR(0, 0x18, 1, 0x60), 0x0000f8fc, 0x00000000,
PCI_ADDR(0, 0x18, 1, 0x68), 0x0000f8fc, 0x00000000,
PCI_ADDR(0, 0x18, 1, 0x70), 0x0000f8fc, 0x00000000,
PCI_ADDR(0, 0x18, 1, 0x78), 0x0000f8fc, 0x00000000,
/* DRAM CS Base Address i Registers
* F2:0x40 i = 0
* F2:0x44 i = 1
* F2:0x48 i = 2
* F2:0x4C i = 3
* F2:0x50 i = 4
* F2:0x54 i = 5
* F2:0x58 i = 6
* F2:0x5C i = 7
* [ 0: 0] Chip-Select Bank Enable
* 0 = Bank Disabled
* 1 = Bank Enabled
* [ 1: 1] Spare Rank
* [ 2: 2] Memory Test Failed
* [ 4: 3] Reserved
* [13: 5] Base Address (21-13)
* An optimization used when all DIMM are the same size...
* [18:14] Reserved
* [28:19] Base Address (36-27)
* This field defines the top 11 addresses bit of a 40-bit
* address that define the memory address space. These
* bits decode 32-MByte blocks of memory.
* [31:29] Reserved
*/
PCI_ADDR(0, 0x18, 2, 0x40), 0xe007c018, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x44), 0xe007c018, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x48), 0xe007c018, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x4C), 0xe007c018, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x50), 0xe007c018, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x54), 0xe007c018, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x58), 0xe007c018, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x5C), 0xe007c018, 0x00000000,
/* DRAM CS Mask Address i Registers
* F2:0x60 i = 0,1
* F2:0x64 i = 2,3
* F2:0x68 i = 4,5
* F2:0x6C i = 6,7
* Select bits to exclude from comparison with the DRAM Base address register.
* [ 4: 0] Reserved
* [13: 5] Address Mask (21-13)
* Address to be excluded from the optimized case
* [18:14] Reserved
* [28:19] Address Mask (36-27)
* The bits with an address mask of 1 are excluded from address comparison
* [31:29] Reserved
*
*/
PCI_ADDR(0, 0x18, 2, 0x60), 0xe007c01f, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x64), 0xe007c01f, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x68), 0xe007c01f, 0x00000000,
PCI_ADDR(0, 0x18, 2, 0x6C), 0xe007c01f, 0x00000000,
/* DRAM Control Register
* F2:0x78
* [ 3: 0] RdPtrInit (Read Pointer Initial Value)
* 0x03-0x00: reserved
* [ 6: 4] RdPadRcvFifoDly (Read Delay from Pad Receive FIFO)
* 000 = reserved
* 001 = reserved
* 010 = 1.5 Memory Clocks
* 011 = 2 Memory Clocks
* 100 = 2.5 Memory Clocks
* 101 = 3 Memory Clocks
* 110 = 3.5 Memory Clocks
* 111 = Reserved
* [15: 7] Reserved
* [16:16] AltVidC3MemClkTriEn (AltVID Memory Clock Tristate Enable)
* Enables the DDR memory clocks to be tristated when alternate VID
* mode is enabled. This bit has no effect if the DisNbClkRamp bit
* (F3, 0x88) is set
* [17:17] DllTempAdjTime (DLL Temperature Adjust Cycle Time)
* 0 = 5 ms
* 1 = 1 ms
* [18:18] DqsRcvEnTrain (DQS Receiver Enable Training Mode)
* 0 = Normal DQS Receiver enable operation
* 1 = DQS receiver enable training mode
* [31:19] reserved
*/
PCI_ADDR(0, 0x18, 2, 0x78), 0xfff80000, (6<<4)|(6<<0),
/* DRAM Initialization Register
* F2:0x7C
* [15: 0] MrsAddress (Address for MRS/EMRS Commands)
* this field specifies the data driven on the DRAM address pins
* 15-0 for MRS and EMRS commands
* [18:16] MrsBank (Bank Address for MRS/EMRS Commands)
* this files specifies the data driven on the DRAM bank pins for
* the MRS and EMRS commands
* [23:19] reserved
* [24:24] SendPchgAll (Send Precharge All Command)
* Setting this bit causes the DRAM controller to send a precharge
* all command. This bit is cleared by the hardware after the
* command completes
* [25:25] SendAutoRefresh (Send Auto Refresh Command)
* Setting this bit causes the DRAM controller to send an auto
* refresh command. This bit is cleared by the hardware after the
* command completes
* [26:26] SendMrsCmd (Send MRS/EMRS Command)
* Setting this bit causes the DRAM controller to send the MRS or
* EMRS command defined by the MrsAddress and MrsBank fields. This
* bit is cleared by the hardware after the command completes
* [27:27] DeassertMemRstX (De-assert Memory Reset)
* Setting this bit causes the DRAM controller to de-assert the
* memory reset pin. This bit cannot be used to assert the memory
* reset pin
* [28:28] AssertCke (Assert CKE)
* setting this bit causes the DRAM controller to assert the CKE
* pins. This bit cannot be used to de-assert the CKE pins
* [30:29] reserved
* [31:31] EnDramInit (Enable DRAM Initialization)
* Setting this bit puts the DRAM controller in a BIOS controlled
* DRAM initialization mode. BIOS must clear this bit aster DRAM
* initialization is complete.
*/
// PCI_ADDR(0, 0x18, 2, 0x7C), 0x60f80000, 0,
/* DRAM Bank Address Mapping Register
* F2:0x80
* Specify the memory module size
* [ 3: 0] CS1/0
* [ 7: 4] CS3/2
* [11: 8] CS5/4
* [15:12] CS7/6
* [31:16]
row col bank
0: 13 9 2 :128M
1: 13 10 2 :256M
2: 14 10 2 :512M
3: 13 11 2 :512M
4: 13 10 3 :512M
5: 14 10 3 :1G
6: 14 11 2 :1G
7: 15 10 3 :2G
8: 14 11 3 :2G
9: 15 11 3 :4G
10: 16 10 3 :4G
11: 16 11 3 :8G
*/
PCI_ADDR(0, 0x18, 2, 0x80), 0xffff0000, 0x00000000,
/* DRAM Timing Low Register
* F2:0x88
* [ 2: 0] Tcl (Cas# Latency, Cas# to read-data-valid)
* 000 = reserved
* 001 = reserved
* 010 = CL 3
* 011 = CL 4
* 100 = CL 5
* 101 = CL 6
* 110 = reserved
* 111 = reserved
* [ 3: 3] Reserved
* [ 5: 4] Trcd (Ras#-active to Cas# read/write delay)
* 00 = 3 clocks
* 01 = 4 clocks
* 10 = 5 clocks
* 11 = 6 clocks
* [ 7: 6] Reserved
* [ 9: 8] Trp (Row Precharge Time, Precharge-to-Active or Auto-Refresh)
* 00 = 3 clocks
* 01 = 4 clocks
* 10 = 5 clocks
* 11 = 6 clocks
* [10:10] Reserved
* [11:11] Trtp (Read to Precharge Time, read Cas# to precharge time)
* 0 = 2 clocks for Burst Length of 32 Bytes
* 4 clocks for Burst Length of 64 Bytes
* 1 = 3 clocks for Burst Length of 32 Bytes
* 5 clocks for Burst Length of 64 Bytes
* [15:12] Tras (Minimum Ras# Active Time)
* 0000 = reserved
* 0001 = reserved
* 0010 = 5 bus clocks
* ...
* 1111 = 18 bus clocks
* [19:16] Trc (Row Cycle Time, Ras#-active to Ras#-active or auto
* refresh of the same bank)
* 0000 = 11 bus clocks
* 0010 = 12 bus clocks
* ...
* 1110 = 25 bus clocks
* 1111 = 26 bus clocks
* [21:20] Twr (Write Recovery Time, From the last data to precharge,
* writes can go back-to-back)
* 00 = 3 bus clocks
* 01 = 4 bus clocks
* 10 = 5 bus clocks
* 11 = 6 bus clocks
* [23:22] Trrd (Active-to-active(Ras#-to-Ras#) Delay of different banks)
* 00 = 2 bus clocks
* 01 = 3 bus clocks
* 10 = 4 bus clocks
* 11 = 5 bus clocks
* [31:24] MemClkDis (Disable the MEMCLK outputs for DRAM channel A,
* BIOS should set it to reduce the power consumption)
* Bit F(1207) M2 Package S1g1 Package
* 0 N/A MA1_CLK1 N/A
* 1 N/A MA0_CLK1 MA0_CLK1
* 2 MA3_CLK N/A N/A
* 3 MA2_CLK N/A N/A
* 4 MA1_CLK MA1_CLK0 N/A
* 5 MA0_CLK MA0_CLK0 MA0_CLK0
* 6 N/A MA1_CLK2 N/A
* 7 N/A MA0_CLK2 MA0_CLK2
*/
PCI_ADDR(0, 0x18, 2, 0x88), 0x000004c8, 0xff000002 /* 0x03623125 */ ,
/* DRAM Timing High Register
* F2:0x8C
* [ 3: 0] Reserved
* [ 6: 4] TrwtTO (Read-to-Write Turnaround for Data, DQS Contention)
* 000 = 2 bus clocks
* 001 = 3 bus clocks
* 010 = 4 bus clocks
* 011 = 5 bus clocks
* 100 = 6 bus clocks
* 101 = 7 bus clocks
* 110 = 8 bus clocks
* 111 = 9 bus clocks
* [ 7: 7] Reserved
* [ 9: 8] Twtr (Internal DRAM Write-to-Read Command Delay,
* Minimum write-to-read delay when both access the same chip select)
* 00 = Reserved
* 01 = 1 bus clocks
* 10 = 2 bus clocks
* 11 = 3 bus clocks
* [11:10] Twrrd (Write to Read DIMM Termination Turnaround, minimum
* write-to-read delay when accessing two different DIMMs)
* 00 = 0 bus clocks
* 01 = 1 bus clocks
* 10 = 2 bus clocks
* 11 = 3 bus clocks
* [13:12] Twrwr (Write to Write Timing)
* 00 = 1 bus clocks (0 idle cycle on the bus)
* 01 = 2 bus clocks (1 idle cycle on the bus)
* 10 = 3 bus clocks (2 idle cycles on the bus)
* 11 = Reserved
* [15:14] Trdrd (Read to Read Timing)
* 00 = 2 bus clocks (1 idle cycle on the bus)
* 01 = 3 bus clocks (2 idle cycles on the bus)
* 10 = 4 bus clocks (3 idle cycles on the bus)
* 11 = 5 bus clocks (4 idle cycles on the bus)
* [17:16] Tref (Refresh Rate)
* 00 = Undefined behavior
* 01 = Reserved
* 10 = Refresh interval of 7.8 microseconds
* 11 = Refresh interval of 3.9 microseconds
* [19:18] Reserved
* [22:20] Trfc0 (Auto-Refresh Row Cycle Time for the Logical DIMM0,
* based on DRAM density and speed)
* 000 = 75 ns (all speeds, 256Mbit)
* 001 = 105 ns (all speeds, 512Mbit)
* 010 = 127.5 ns (all speeds, 1Gbit)
* 011 = 195 ns (all speeds, 2Gbit)
* 100 = 327.5 ns (all speeds, 4Gbit)
* 101 = reserved
* 110 = reserved
* 111 = reserved
* [25:23] Trfc1 (Auto-Refresh Row Cycle Time for the Logical DIMM1,
* based on DRAM density and speed)
* [28:26] Trfc2 (Auto-Refresh Row Cycle Time for the Logical DIMM2,
* based on DRAM density and speed)
* [31:29] Trfc3 (Auto-Refresh Row Cycle Time for the Logical DIMM3,
* based on DRAM density and speed)
*/
PCI_ADDR(0, 0x18, 2, 0x8c), 0x000c008f, (2 << 16)|(1 << 8),
/* DRAM Config Low Register
* F2:0x90
* [ 0: 0] InitDram (Initialize DRAM)
* 1 = write 1 cause DRAM controller to execute the DRAM
* initialization, when done it read to 0
* [ 1: 1] ExitSelfRef (Exit Self Refresh Command)
* 1 = write 1 causes the DRAM controller to bring the DRAMs out
* for self refresh mode
* [ 3: 2] Reserved
* [ 5: 4] DramTerm (DRAM Termination)
* 00 = On die termination disabled
* 01 = 75 ohms
* 10 = 150 ohms
* 11 = 50 ohms
* [ 6: 6] Reserved
* [ 7: 7] DramDrvWeak (DRAM Drivers Weak Mode)
* 0 = Normal drive strength mode.
* 1 = Weak drive strength mode
* [ 8: 8] ParEn (Parity Enable)
* 1 = Enable address parity computation output, PAR,
* and enables the parity error input, ERR
* [ 9: 9] SelfRefRateEn (Faster Self Refresh Rate Enable)
* 1 = Enable high temperature (two times normal)
* self refresh rate
* [10:10] BurstLength32 (DRAM Burst Length Set for 32 Bytes)
* 0 = 64-byte mode
* 1 = 32-byte mode
* [11:11] Width128 (Width of DRAM interface)
* 0 = the controller DRAM interface is 64-bits wide
* 1 = the controller DRAM interface is 128-bits wide
* [12:12] X4Dimm (DIMM 0 is x4)
* [13:13] X4Dimm (DIMM 1 is x4)
* [14:14] X4Dimm (DIMM 2 is x4)
* [15:15] X4Dimm (DIMM 3 is x4)
* 0 = DIMM is not x4
* 1 = x4 DIMM present
* [16:16] UnBuffDimm (Unbuffered DIMMs)
* 0 = Buffered DIMMs
* 1 = Unbuffered DIMMs
* [18:17] Reserved
* [19:19] DimmEccEn (DIMM ECC Enable)
* 1 = ECC checking is being enabled for all DIMMs on the DRAM
* controller (Through F3 0x44[EccEn])
* [31:20] Reserved
*/
PCI_ADDR(0, 0x18, 2, 0x90), 0xfff6004c, 0x00000010,
/* DRAM Config High Register
* F2:0x94
* [ 0: 2] MemClkFreq (Memory Clock Frequency)
* 000 = 200MHz
* 001 = 266MHz
* 010 = 333MHz
* 011 = reserved
* 1xx = reserved
* [ 3: 3] MemClkFreqVal (Memory Clock Frequency Valid)
* 1 = BIOS need to set the bit when setting up MemClkFreq to
* the proper value
* [ 7: 4] MaxAsyncLat (Maximum Asynchronous Latency)
* 0000 = 0 ns
* ...
* 1111 = 15 ns
* [11: 8] Reserved
* [12:12] RDqsEn (Read DQS Enable) This bit is only be set if x8
* registered DIMMs are present in the system
* 0 = DM pins function as data mask pins
* 1 = DM pins function as read DQS pins
* [13:13] Reserved
* [14:14] DisDramInterface (Disable the DRAM interface) When this bit
* is set, the DRAM controller is disabled, and interface in low power
* state
* 0 = Enabled (default)
* 1 = Disabled
* [15:15] PowerDownEn (Power Down Mode Enable)
* 0 = Disabled (default)
* 1 = Enabled
* [16:16] PowerDown (Power Down Mode)
* 0 = Channel CKE Control
* 1 = Chip Select CKE Control
* [17:17] FourRankSODimm (Four Rank SO-DIMM)
* 1 = this bit is set by BIOS to indicate that a four rank
* SO-DIMM is present
* [18:18] FourRankRDimm (Four Rank Registered DIMM)
* 1 = this bit is set by BIOS to indicate that a four rank
* registered DIMM is present
* [19:19] Reserved
* [20:20] SlowAccessMode (Slow Access Mode (2T Mode))
* 0 = DRAM address and control signals are driven for one
* MEMCLK cycle
* 1 = One additional MEMCLK of setup time is provided on all
* DRAM address and control signals except CS, CKE, and ODT;
* i.e., these signals are driven for two MEMCLK cycles
* rather than one
* [21:21] Reserved
* [22:22] BankSwizzleMode (Bank Swizzle Mode),
* 0 = Disabled (default)
* 1 = Enabled
* [23:23] Reserved
* [27:24] DcqBypassMax (DRAM Controller Queue Bypass Maximum)
* 0000 = No bypass; the oldest request is never bypassed
* 0001 = The oldest request may be bypassed no more than 1 time
* ...
* 1111 = The oldest request may be bypassed no more than 15\
* times
* [31:28] FourActWindow (Four Bank Activate Window) , not more than
* 4 banks in a 8 bank device are activated
* 0000 = No tFAW window restriction
* 0001 = 8 MEMCLK cycles
* 0010 = 9 MEMCLK cycles
* ...
* 1101 = 20 MEMCLK cycles
* 111x = reserved
*/
PCI_ADDR(0, 0x18, 2, 0x94), 0x00a82f00,0x00008000,
/* DRAM Delay Line Register
* F2:0xa0
* [ 0: 0] MemClrStatus (Memory Clear Status) : Readonly
* when set, this bit indicates that the memory clear function
* is complete. Only clear by reset. BIOS should not write or
* read the DRAM until this bit is set by hardware
* [ 1: 1] DisableJitter (Disable Jitter)
* When set the DDR compensation circuit will not change the
* values unless the change is more than one step from the
* current value
* [ 3: 2] RdWrQByp (Read/Write Queue Bypass Count)
* 00 = 2
* 01 = 4
* 10 = 8
* 11 = 16
* [ 4: 4] Mode64BitMux (Mismatched DIMM Support Enable)
* 1 When bit enables support for mismatched DIMMs when using
* 128-bit DRAM interface, the Width128 no effect, only for
* AM2 and s1g1
* [ 5: 5] DCC_EN (Dynamic Idle Cycle Counter Enable)
* When set to 1, indicates that each entry in the page tables
* dynamically adjusts the idle cycle limit based on page
* Conflict/Page Miss (PC/PM) traffic
* [ 8: 6] ILD_lmt (Idle Cycle Limit)
* 000 = 0 cycles
* 001 = 4 cycles
* 010 = 8 cycles
* 011 = 16 cycles
* 100 = 32 cycles
* 101 = 64 cycles
* 110 = 128 cycles
* 111 = 256 cycles
* [ 9: 9] DramEnabled (DRAM Enabled)
* When Set, this bit indicates that the DRAM is enabled, this
* bit is set by hardware after DRAM initialization or on an exit
* from self refresh. The DRAM controller is initialized after the
* hardware-controlled initialization process (initiated by the
* F2 0x90[DramInit]) completes or when the BIOS-controlled
* initialization process completes (F2 0x7c(EnDramInit] is
* written from 1 to 0)
* [23:10] Reserved
* [31:24] MemClkDis (Disable the MEMCLK outputs for DRAM channel B,
* BIOS should set it to reduce the power consumption)
* Bit F(1207) M2 Package S1g1 Package
* 0 N/A MA1_CLK1 N/A
* 1 N/A MA0_CLK1 MA0_CLK1
* 2 MA3_CLK N/A N/A
* 3 MA2_CLK N/A N/A
* 4 MA1_CLK MA1_CLK0 N/A
* 5 MA0_CLK MA0_CLK0 MA0_CLK0
* 6 N/A MA1_CLK2 N/A
* 7 N/A MA0_CLK2 MA0_CLK2
*/
PCI_ADDR(0, 0x18, 2, 0xa0), 0x00fffc00, 0xff000000,
/* DRAM Scrub Control Register
* F3:0x58
* [ 4: 0] DRAM Scrub Rate
* [ 7: 5] reserved
* [12: 8] L2 Scrub Rate
* [15:13] reserved
* [20:16] Dcache Scrub
* [31:21] reserved
* Scrub Rates
* 00000 = Do not scrub
* 00001 = 40.00 ns
* 00010 = 80.00 ns
* 00011 = 160.00 ns
* 00100 = 320.00 ns
* 00101 = 640.00 ns
* 00110 = 1.28 us
* 00111 = 2.56 us
* 01000 = 5.12 us
* 01001 = 10.20 us
* 01011 = 41.00 us
* 01100 = 81.90 us
* 01101 = 163.80 us
* 01110 = 327.70 us
* 01111 = 655.40 us
* 10000 = 1.31 ms
* 10001 = 2.62 ms
* 10010 = 5.24 ms
* 10011 = 10.49 ms
* 10100 = 20.97 ms
* 10101 = 42.00 ms
* 10110 = 84.00 ms
* All Others = Reserved
*/
PCI_ADDR(0, 0x18, 3, 0x58), 0xffe0e0e0, 0x00000000,
/* DRAM Scrub Address Low Register
* F3:0x5C
* [ 0: 0] DRAM Scrubber Redirect Enable
* 0 = Do nothing
* 1 = Scrubber Corrects errors found in normal operation
* [ 5: 1] Reserved
* [31: 6] DRAM Scrub Address 31-6
*/
PCI_ADDR(0, 0x18, 3, 0x5C), 0x0000003e, 0x00000000,
/* DRAM Scrub Address High Register
* F3:0x60
* [ 7: 0] DRAM Scrub Address 39-32
* [31: 8] Reserved
*/
PCI_ADDR(0, 0x18, 3, 0x60), 0xffffff00, 0x00000000,
};
/* for PCI_ADDR(0, 0x18, 2, 0x98) index,
and PCI_ADDR(0x, 0x18, 2, 0x9c) data */
/*
index:
[29: 0] DctOffset (Dram Controller Offset)
[30:30] DctAccessWrite (Dram Controller Read/Write Select)
0 = read access
1 = write access
[31:31] DctAccessDone (Dram Controller Access Done)
0 = Access in progress
1 = No access is progress
Data:
[31: 0] DctOffsetData (Dram Controller Offset Data)
Read:
- Write the register num to DctOffset with DctAccessWrite = 0
- poll the DctAccessDone until it = 1
- Read the data from DctOffsetData
Write:
- Write the data to DctOffsetData
- Write register num to DctOffset with DctAccessWrite = 1
- poll the DctAccessDone until it = 1
*/
int i;
int max;
if (!controller_present(ctrl)) {
sysinfo->ctrl_present[ctrl->node_id] = 0;
return;
}
sysinfo->ctrl_present[ctrl->node_id] = 1;
printk(BIOS_SPEW, "setting up CPU %02x northbridge registers\n", ctrl->node_id);
max = ARRAY_SIZE(register_values);
for (i = 0; i < max; i += 3) {
pci_devfn_t dev;
unsigned where;
unsigned long reg;
dev = (register_values[i] & ~0xff) - PCI_DEV(0, 0x18, 0) + ctrl->f0;
where = register_values[i] & 0xff;
reg = pci_read_config32(dev, where);
reg &= register_values[i+1];
reg |= register_values[i+2];
pci_write_config32(dev, where, reg);
}
printk(BIOS_SPEW, "done.\n");
}
static int is_opteron(const struct mem_controller *ctrl)
{
/* Test to see if I am an Opteron. M2 and S1G1 support dual
* channel, too, but only support unbuffered DIMMs so we need a
* better test for Opterons.
* However, all code uses is_opteron() to find out whether to
* use dual channel, so if we really check for opteron here, we
* need to fix up all code using this function, too.
*/
uint32_t nbcap;
nbcap = pci_read_config32(ctrl->f3, NORTHBRIDGE_CAP);
return !!(nbcap & NBCAP_128Bit);
}
static void spd_get_dimm_size(unsigned device, struct dimm_size *sz)
{
/* Calculate the log base 2 size of a DIMM in bits */
int value;
sz->per_rank = 0;
sz->rows = 0;
sz->col = 0;
sz->rank = 0;
value = spd_read_byte(device, SPD_ROW_NUM); /* rows */
if (value < 0) goto hw_err;
if ((value & 0xff) == 0) goto val_err; /* max is 16 ? */
sz->per_rank += value & 0xff;
sz->rows = value & 0xff;
value = spd_read_byte(device, SPD_COL_NUM); /* columns */
if (value < 0) goto hw_err;
if ((value & 0xff) == 0) goto val_err; /* max is 11 */
sz->per_rank += value & 0xff;
sz->col = value & 0xff;
value = spd_read_byte(device, SPD_BANK_NUM); /* banks */
if (value < 0) goto hw_err;
if ((value & 0xff) == 0) goto val_err;
sz->bank = log2(value & 0xff); // convert 4 to 2, and 8 to 3
sz->per_rank += sz->bank;
/* Get the module data width and convert it to a power of two */
value = spd_read_byte(device, SPD_DATA_WIDTH);
if (value < 0) goto hw_err;
value &= 0xff;
if ((value != 72) && (value != 64)) goto val_err;
sz->per_rank += log2(value) - 3; //64 bit So another 3 lines
/* How many ranks? */
/* number of physical banks */
value = spd_read_byte(device, SPD_MOD_ATTRIB_RANK);
if (value < 0) goto hw_err;
value &= SPD_MOD_ATTRIB_RANK_NUM_MASK;
value += SPD_MOD_ATTRIB_RANK_NUM_BASE; // 0-->1, 1-->2, 3-->4
/*
rank == 1 only one rank or say one side
rank == 2 two side , and two ranks
rank == 4 two side , and four ranks total
Some one side two ranks, because of stacked
*/
if ((value != 1) && (value != 2) && (value != 4)) {
goto val_err;
}
sz->rank = value;
/* verify if per_rank is equal byte 31
it has the DIMM size as a multiple of 128MB.
*/
value = spd_read_byte(device, SPD_RANK_SIZE);
if (value < 0) goto hw_err;
value &= 0xff;
value = log2(value);
if (value <= 4) value += 8; // add back to 1G to high
value += (27-5); // make 128MB to the real lines
if (value != (sz->per_rank)) {
printk(BIOS_ERR, "Bad RANK Size --\n");
goto val_err;
}
goto out;
val_err:
die("Bad SPD value\n");
/* If an hw_error occurs report that I have no memory */
hw_err:
sz->per_rank = 0;
sz->rows = 0;
sz->col = 0;
sz->bank = 0;
sz->rank = 0;
out:
return;
}
static void set_dimm_size(const struct mem_controller *ctrl,
struct dimm_size *sz, unsigned index,
struct mem_info *meminfo)
{
uint32_t base0, base1;
/* For each base register.
* Place the dimm size in 32 MB quantities in the bits 31 - 21.
* The initialize dimm size is in bits.
* Set the base enable bit0.
*/
base0 = base1 = 0;
/* Make certain side1 of the dimm is at least 128MB */
if (sz->per_rank >= 27) {
base0 = (1 << ((sz->per_rank - 27) + 19)) | 1;
}
/* Make certain side2 of the dimm is at least 128MB */
if (sz->rank > 1) { // 2 ranks or 4 ranks
base1 = (1 << ((sz->per_rank - 27) + 19)) | 1;
}
/* Double the size if we are using dual channel memory */
if (meminfo->is_Width128) {
base0 = (base0 << 1) | (base0 & 1);
base1 = (base1 << 1) | (base1 & 1);
}
/* Clear the reserved bits */
base0 &= ~0xe007fffe;
base1 &= ~0xe007fffe;
if (!(meminfo->dimm_mask & 0x0F) && (meminfo->dimm_mask & 0xF0)) { /* channelB only? */
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 4) << 2), base0);
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 5) << 2), base1);
} else {
/* Set the appropriate DIMM base address register */
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 0) << 2), base0);
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 1) << 2), base1);
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
if (sz->rank == 4) {
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 4) << 2), base0);
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 5) << 2), base1);
}
#endif
}
/* Enable the memory clocks for this DIMM by Clear the MemClkDis bit*/
if (base0) {
uint32_t dword;
uint32_t ClkDis0;
#if CONFIG_CPU_SOCKET_TYPE == 0x10 /* L1 */
ClkDis0 = DTL_MemClkDis0;
#elif CONFIG_CPU_SOCKET_TYPE == 0x11 /* AM2 */
ClkDis0 = DTL_MemClkDis0_AM2;
#elif CONFIG_CPU_SOCKET_TYPE == 0x12 /* S1G1 */
ClkDis0 = DTL_MemClkDis0_S1g1;
#endif
if (!(meminfo->dimm_mask & 0x0F) && (meminfo->dimm_mask & 0xF0)) { /* channelB only? */
dword = pci_read_config32(ctrl->f2, DRAM_CTRL_MISC);
dword &= ~(ClkDis0 >> index);
pci_write_config32(ctrl->f2, DRAM_CTRL_MISC, dword);
} else {
dword = pci_read_config32(ctrl->f2, DRAM_TIMING_LOW); //Channel A
dword &= ~(ClkDis0 >> index);
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
if (sz->rank == 4) {
dword &= ~(ClkDis0 >> (index+2));
}
#endif
pci_write_config32(ctrl->f2, DRAM_TIMING_LOW, dword);
if (meminfo->is_Width128) { // ChannelA+B
dword = pci_read_config32(ctrl->f2, DRAM_CTRL_MISC);
dword &= ~(ClkDis0 >> index);
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
if (sz->rank == 4) {
dword &= ~(ClkDis0 >> (index+2));
}
#endif
pci_write_config32(ctrl->f2, DRAM_CTRL_MISC, dword);
}
}
}
}
/* row col bank for 64 bit
0: 13 9 2 :128M
1: 13 10 2 :256M
2: 14 10 2 :512M
3: 13 11 2 :512M
4: 13 10 3 :512M
5: 14 10 3 :1G
6: 14 11 2 :1G
7: 15 10 3 :2G
8: 14 11 3 :2G
9: 15 11 3 :4G
10: 16 10 3 :4G
11: 16 11 3 :8G
*/
static void set_dimm_cs_map(const struct mem_controller *ctrl,
struct dimm_size *sz, unsigned index,
struct mem_info *meminfo)
{
static const uint8_t cs_map_aaa[24] = {
/* (bank=2, row=13, col=9)(3, 16, 11) ---> (0, 0, 0) (1, 3, 2) */
//Bank2
0, 1, 3,
0, 2, 6,
0, 0, 0,
0, 0, 0,
//Bank3
0, 4, 0,
0, 5, 8,
0, 7, 9,
0,10,11,
};
uint32_t map;
if (!(meminfo->dimm_mask & 0x0F) && (meminfo->dimm_mask & 0xF0)) { /* channelB only? */
index += 2;
}
map = pci_read_config32(ctrl->f2, DRAM_BANK_ADDR_MAP);
map &= ~(0xf << (index * 4));
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
if (sz->rank == 4) {
map &= ~(0xf << ((index + 2) * 4));
}
#endif
/* Make certain side1 of the dimm is at least 128MB */
if (sz->per_rank >= 27) {
unsigned temp_map;
temp_map = cs_map_aaa[(sz->bank-2)*3*4 + (sz->rows - 13)*3 + (sz->col - 9) ];
map |= temp_map << (index*4);
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
if (sz->rank == 4) {
map |= temp_map << ((index + 2) * 4);
}
#endif
}
pci_write_config32(ctrl->f2, DRAM_BANK_ADDR_MAP, map);
}
static long spd_set_ram_size(const struct mem_controller *ctrl,
struct mem_info *meminfo)
{
int i;
for (i = 0; i < DIMM_SOCKETS; i++) {
struct dimm_size *sz = &(meminfo->sz[i]);
u32 spd_device = ctrl->channel0[i];
if (!(meminfo->dimm_mask & (1 << i))) {
if (meminfo->dimm_mask & (1 << (DIMM_SOCKETS + i))) { /* channelB only? */
spd_device = ctrl->channel1[i];
} else {
continue;
}
}
spd_get_dimm_size(spd_device, sz);
if (sz->per_rank == 0) {
return -1; /* Report SPD error */
}
set_dimm_size(ctrl, sz, i, meminfo);
set_dimm_cs_map(ctrl, sz, i, meminfo);
}
return meminfo->dimm_mask;
}
static void route_dram_accesses(const struct mem_controller *ctrl,
unsigned long base_k, unsigned long limit_k)
{
/* Route the addresses to the controller node */
unsigned node_id;
unsigned limit;
unsigned base;
unsigned index;
unsigned limit_reg, base_reg;
pci_devfn_t device;
node_id = ctrl->node_id;
index = (node_id << 3);
limit = (limit_k << 2);
limit &= 0xffff0000;
limit -= 0x00010000;
limit |= (0 << 8) | (node_id << 0);
base = (base_k << 2);
base &= 0xffff0000;
base |= (0 << 8) | (1<<1) | (1<<0);
limit_reg = 0x44 + index;
base_reg = 0x40 + index;
for (device = PCI_DEV(0, 0x18, 1); device <= PCI_DEV(0, 0x1f, 1);
device += PCI_DEV(0, 1, 0)) {
pci_write_config32(device, limit_reg, limit);
pci_write_config32(device, base_reg, base);
}
}
static void set_top_mem(unsigned tom_k, unsigned hole_startk)
{
/* Error if I don't have memory */
if (!tom_k) {
die("No memory?");
}
/* Report the amount of memory. */
printk(BIOS_DEBUG, "RAM end at 0x%08x kB\n", tom_k);
/* Now set top of memory */
msr_t msr;
if (tom_k > (4*1024*1024)) {
printk_raminit("Handling memory mapped above 4 GB\n");
printk_raminit("Upper RAM end at 0x%08x kB\n", tom_k);
msr.lo = (tom_k & 0x003fffff) << 10;
msr.hi = (tom_k & 0xffc00000) >> 22;
wrmsr(TOP_MEM2, msr);
printk_raminit("Correcting memory amount mapped below 4 GB\n");
}
/* Leave a 64M hole between TOP_MEM and TOP_MEM2
* so I can see my ROM chip and other I/O devices.
*/
if (tom_k >= 0x003f0000) {
#if CONFIG_HW_MEM_HOLE_SIZEK != 0
if (hole_startk != 0) {
tom_k = hole_startk;
} else
#endif
tom_k = 0x3f0000;
printk_raminit("Adjusting lower RAM end\n");
}
printk_raminit("Lower RAM end at 0x%08x kB\n", tom_k);
msr.lo = (tom_k & 0x003fffff) << 10;
msr.hi = (tom_k & 0xffc00000) >> 22;
wrmsr(TOP_MEM, msr);
}
static unsigned long interleave_chip_selects(const struct mem_controller *ctrl, int is_Width128)
{
/* 35 - 27 */
static const uint8_t csbase_low_f0_shift[] = {
/* 128MB */ (14 - (13-5)),
/* 256MB */ (15 - (13-5)),
/* 512MB */ (15 - (13-5)),
/* 512MB */ (16 - (13-5)),
/* 512MB */ (16 - (13-5)),
/* 1GB */ (16 - (13-5)),
/* 1GB */ (16 - (13-5)),
/* 2GB */ (16 - (13-5)),
/* 2GB */ (17 - (13-5)),
/* 4GB */ (17 - (13-5)),
/* 4GB */ (16 - (13-5)),
/* 8GB */ (17 - (13-5)),
};
/* cs_base_high is not changed */
uint32_t csbase_inc;
int chip_selects, index;
int bits;
unsigned common_size;
unsigned common_cs_mode;
uint32_t csbase, csmask;
/* See if all of the memory chip selects are the same size
* and if so count them.
*/
#if defined(CMOS_VSTART_interleave_chip_selects)
if (read_option(interleave_chip_selects, 1) == 0)
return 0;
#else
#if !defined(CONFIG_INTERLEAVE_CHIP_SELECTS) || !CONFIG_INTERLEAVE_CHIP_SELECTS
return 0;
#endif
#endif
chip_selects = 0;
common_size = 0;
common_cs_mode = 0xff;
for (index = 0; index < 8; index++) {
unsigned size;
unsigned cs_mode;
uint32_t value;
value = pci_read_config32(ctrl->f2, DRAM_CSBASE + (index << 2));
/* Is it enabled? */
if (!(value & 1)) {
continue;
}
chip_selects++;
size = (value >> 19) & 0x3ff;
if (common_size == 0) {
common_size = size;
}
/* The size differed fail */
if (common_size != size) {
return 0;
}
value = pci_read_config32(ctrl->f2, DRAM_BANK_ADDR_MAP);
cs_mode =(value >> ((index>>1)*4)) & 0xf;
if (common_cs_mode == 0xff) {
common_cs_mode = cs_mode;
}
/* The cs_mode differed fail */
if (common_cs_mode != cs_mode) {
return 0;
}
}
/* Chip selects can only be interleaved when there is
* more than one and their is a power of two of them.
*/
bits = log2(chip_selects);
if (((1 << bits) != chip_selects) || (bits < 1) || (bits > 3)) {
//chip_selects max = 8
return 0;
}
/* Find the bits of csbase that we need to interleave on */
csbase_inc = 1 << (csbase_low_f0_shift[common_cs_mode]);
if (is_Width128) {
csbase_inc <<=1;
}
/* Compute the initial values for csbase and csmask.
* In csbase just set the enable bit and the base to zero.
* In csmask set the mask bits for the size and page level interleave.
*/
csbase = 0 | 1;
csmask = (((common_size << bits) - 1) << 19);
csmask |= 0x3fe0 & ~((csbase_inc << bits) - csbase_inc);
for (index = 0; index < 8; index++) {
uint32_t value;
value = pci_read_config32(ctrl->f2, DRAM_CSBASE + (index << 2));
/* Is it enabled? */
if (!(value & 1)) {
continue;
}
pci_write_config32(ctrl->f2, DRAM_CSBASE + (index << 2), csbase);
if ((index & 1) == 0) { //only have 4 CSMASK
pci_write_config32(ctrl->f2, DRAM_CSMASK + ((index>>1) << 2), csmask);
}
csbase += csbase_inc;
}
printk(BIOS_DEBUG, "Interleaved\n");
/* Return the memory size in K */
return common_size << ((27-10) + bits);
}
static unsigned long order_chip_selects(const struct mem_controller *ctrl)
{
unsigned long tom;
/* Remember which registers we have used in the high 8 bits of tom */
tom = 0;
for (;;) {
/* Find the largest remaining candidate */
unsigned index, canidate;
uint32_t csbase, csmask;
unsigned size;
csbase = 0;
canidate = 0;
for (index = 0; index < 8; index++) {
uint32_t value;
value = pci_read_config32(ctrl->f2, DRAM_CSBASE + (index << 2));
/* Is it enabled? */
if (!(value & 1)) {
continue;
}
/* Is it greater? */
if (value <= csbase) {
continue;
}
/* Has it already been selected */
if (tom & (1 << (index + 24))) {
continue;
}
/* I have a new candidate */
csbase = value;
canidate = index;
}
/* See if I have found a new candidate */
if (csbase == 0) {
break;
}
/* Remember the dimm size */
size = csbase >> 19;
/* Remember I have used this register */
tom |= (1 << (canidate + 24));
/* Recompute the cs base register value */
csbase = (tom << 19) | 1;
/* Increment the top of memory */
tom += size;
/* Compute the memory mask */
csmask = ((size -1) << 19);
csmask |= 0x3fe0; /* For now don't optimize */
/* Write the new base register */
pci_write_config32(ctrl->f2, DRAM_CSBASE + (canidate << 2), csbase);
/* Write the new mask register */
if ((canidate & 1) == 0) { //only have 4 CSMASK
pci_write_config32(ctrl->f2, DRAM_CSMASK + ((canidate >> 1) << 2), csmask);
}
}
/* Return the memory size in K */
return (tom & ~0xff000000) << (27-10);
}
static unsigned long memory_end_k(const struct mem_controller *ctrl, int max_node_id)
{
unsigned node_id;
unsigned end_k;
/* Find the last memory address used */
end_k = 0;
for (node_id = 0; node_id < max_node_id; node_id++) {
uint32_t limit, base;
unsigned index;
index = node_id << 3;
base = pci_read_config32(ctrl->f1, 0x40 + index);
/* Only look at the limit if the base is enabled */
if ((base & 3) == 3) {
limit = pci_read_config32(ctrl->f1, 0x44 + index);
end_k = ((limit + 0x00010000) & 0xffff0000) >> 2;
}
}
return end_k;
}
static void order_dimms(const struct mem_controller *ctrl,
struct mem_info *meminfo)
{
unsigned long tom_k, base_k;
tom_k = interleave_chip_selects(ctrl, meminfo->is_Width128);
if (!tom_k) {
printk(BIOS_DEBUG, "Interleaving disabled\n");
tom_k = order_chip_selects(ctrl);
}
/* Compute the memory base address */
base_k = memory_end_k(ctrl, ctrl->node_id);
tom_k += base_k;
route_dram_accesses(ctrl, base_k, tom_k);
set_top_mem(tom_k, 0);
}
static long disable_dimm(const struct mem_controller *ctrl, unsigned index,
struct mem_info *meminfo)
{
printk(BIOS_DEBUG, "disabling dimm %02x\n", index);
if (!(meminfo->dimm_mask & 0x0F) && (meminfo->dimm_mask & 0xF0)) { /* channelB only? */
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 4) << 2), 0);
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 5) << 2), 0);
} else {
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 0) << 2), 0);
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 1) << 2), 0);
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
if (meminfo->sz[index].rank == 4) {
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 4) << 2), 0);
pci_write_config32(ctrl->f2, DRAM_CSBASE + (((index << 1) + 5) << 2), 0);
}
#endif
}
meminfo->dimm_mask &= ~(1 << index);
return meminfo->dimm_mask;
}
static long spd_handle_unbuffered_dimms(const struct mem_controller *ctrl,
struct mem_info *meminfo)
{
int i;
uint32_t registered;
uint32_t dcl;
registered = 0;
for (i = 0; (i < DIMM_SOCKETS); i++) {
int value;
u32 spd_device = ctrl->channel0[i];
if (!(meminfo->dimm_mask & (1 << i))) {
if (meminfo->dimm_mask & (1 << (DIMM_SOCKETS + i))) { /* channelB only? */
spd_device = ctrl->channel1[i];
} else {
continue;
}
}
value = spd_read_byte(spd_device, SPD_DIMM_TYPE);
if (value < 0) {
return -1;
}
/* Registered dimm ? */
value &= 0x3f;
if ((value == SPD_DIMM_TYPE_RDIMM) || (value == SPD_DIMM_TYPE_mRDIMM)) {
//check SPD_MOD_ATTRIB to verify it is SPD_MOD_ATTRIB_REGADC (0x11)?
registered |= (1<<i);
}
}
if (is_opteron(ctrl)) {
}
dcl = pci_read_config32(ctrl->f2, DRAM_CONFIG_LOW);
dcl &= ~DCL_UnBuffDimm;
meminfo->is_registered = 1;
if (!registered) {
dcl |= DCL_UnBuffDimm;
meminfo->is_registered = 0;
}
pci_write_config32(ctrl->f2, DRAM_CONFIG_LOW, dcl);
if (meminfo->is_registered) {
printk(BIOS_SPEW, "Registered\n");
} else {
printk(BIOS_SPEW, "Unbuffered\n");
}
return meminfo->dimm_mask;
}
static unsigned int spd_detect_dimms(const struct mem_controller *ctrl)
{
unsigned dimm_mask;
int i;
dimm_mask = 0;
for (i = 0; i < DIMM_SOCKETS; i++) {
int byte;
unsigned device;
device = ctrl->channel0[i];
printk_raminit("DIMM socket %i, channel 0 SPD device is 0x%02x\n", i, device);
if (device) {
byte = spd_read_byte(ctrl->channel0[i], SPD_MEM_TYPE); /* Type */
if (byte == SPD_MEM_TYPE_SDRAM_DDR2) {
printk_raminit("\tDIMM detected\n");
dimm_mask |= (1 << i);
}
}
device = ctrl->channel1[i];
printk_raminit("DIMM socket %i, channel 1 SPD device is 0x%02x\n", i, device);
if (device) {
byte = spd_read_byte(ctrl->channel1[i], SPD_MEM_TYPE);
if (byte == SPD_MEM_TYPE_SDRAM_DDR2) {
printk_raminit("\tDIMM detected\n");
dimm_mask |= (1 << (i + DIMM_SOCKETS));
}
}
}
return dimm_mask;
}
static long spd_enable_2channels(const struct mem_controller *ctrl, struct mem_info *meminfo)
{
int i;
uint32_t nbcap;
/* SPD addresses to verify are identical */
static const uint8_t addresses[] = {
2, /* Type should be DDR2 SDRAM */
3, /* *Row addresses */
4, /* *Column addresses */
5, /* *Number of DIMM Ranks */
6, /* *Module Data Width*/
11, /* *DIMM Conf Type */
13, /* *Pri SDRAM Width */
17, /* *Logical Banks */
20, /* *DIMM Type Info */
21, /* *SDRAM Module Attributes */
27, /* *tRP Row precharge time */
28, /* *Minimum Row Active to Row Active Delay (tRRD) */
29, /* *tRCD RAS to CAS */
30, /* *tRAS Activate to Precharge */
36, /* *Write recovery time (tWR) */
37, /* *Internal write to read command delay (tRDP) */
38, /* *Internal read to precharge command delay (tRTP) */
40, /* *Extension of Byte 41 tRC and Byte 42 tRFC */
41, /* *Minimum Active to Active/Auto Refresh Time(Trc) */
42, /* *Minimum Auto Refresh Command Time(Trfc) */
/* The SPD addresses 18, 9, 23, 26 need special treatment like
* in spd_set_memclk. Right now they cause many false negatives.
* Keep them at the end to see other mismatches (if any).
*/
18, /* *Supported CAS Latencies */
9, /* *Cycle time at highest CAS Latency CL=X */
23, /* *Cycle time at CAS Latency (CLX - 1) */
25, /* *Cycle time at CAS Latency (CLX - 2) */
};
u32 dcl, dcm;
u8 common_cl;
/* S1G1 and AM2 sockets are Mod64BitMux capable. */
#if CONFIG_CPU_SOCKET_TYPE == 0x11 || CONFIG_CPU_SOCKET_TYPE == 0x12
u8 mux_cap = 1;
#else
u8 mux_cap = 0;
#endif
/* If the dimms are not in pairs do not do dual channels */
if ((meminfo->dimm_mask & ((1 << DIMM_SOCKETS) - 1)) !=
((meminfo->dimm_mask >> DIMM_SOCKETS) & ((1 << DIMM_SOCKETS) - 1))) {
goto single_channel;
}
/* If the CPU is not capable of doing dual channels don't do dual channels */
nbcap = pci_read_config32(ctrl->f3, NORTHBRIDGE_CAP);
if (!(nbcap & NBCAP_128Bit)) {
goto single_channel;
}
for (i = 0; (i < 4) && (ctrl->channel0[i]); i++) {
unsigned device0, device1;
int value0, value1;
int j;
/* If I don't have a dimm skip this one */
if (!(meminfo->dimm_mask & (1 << i))) {
continue;
}
device0 = ctrl->channel0[i];
device1 = ctrl->channel1[i];
/* Abort if the chips don't support a common CAS latency. */
common_cl = spd_read_byte(device0, 18) & spd_read_byte(device1, 18);
if (!common_cl) {
printk(BIOS_DEBUG, "No common CAS latency supported\n");
goto single_channel;
} else {
printk_raminit("Common CAS latency bitfield: 0x%02x\n", common_cl);
}
for (j = 0; j < ARRAY_SIZE(addresses); j++) {
unsigned addr;
addr = addresses[j];
value0 = spd_read_byte(device0, addr);
if (value0 < 0) {
return -1;
}
value1 = spd_read_byte(device1, addr);
if (value1 < 0) {
return -1;
}
if (value0 != value1) {
printk_raminit("SPD values differ between channel 0/1 for byte %i\n", addr);
goto single_channel;
}
}
}
printk(BIOS_SPEW, "Enabling dual channel memory\n");
dcl = pci_read_config32(ctrl->f2, DRAM_CONFIG_LOW);
dcl &= ~DCL_BurstLength32; /* 32byte mode may be preferred in platforms that include graphics controllers that generate a lot of 32-bytes system memory accesses
32byte mode is not supported when the DRAM interface is 128 bits wide, even 32byte mode is set, system still use 64 byte mode */
dcl |= DCL_Width128;
pci_write_config32(ctrl->f2, DRAM_CONFIG_LOW, dcl);
meminfo->is_Width128 = 1;
return meminfo->dimm_mask;
single_channel:
meminfo->is_Width128 = 0;
meminfo->is_64MuxMode = 0;
/* single dimm */
if ((meminfo->dimm_mask & ((1 << DIMM_SOCKETS) - 1)) !=
((meminfo->dimm_mask >> DIMM_SOCKETS) & ((1 << DIMM_SOCKETS) - 1))) {
if (((meminfo->dimm_mask >> DIMM_SOCKETS) & ((1 << DIMM_SOCKETS) - 1))) {
/* mux capable and single dimm in channelB */
if (mux_cap) {
printk(BIOS_SPEW, "Enable 64MuxMode & BurstLength32\n");
dcm = pci_read_config32(ctrl->f2, DRAM_CTRL_MISC);
dcm |= DCM_Mode64BitMux;
pci_write_config32(ctrl->f2, DRAM_CTRL_MISC, dcm);
dcl = pci_read_config32(ctrl->f2, DRAM_CONFIG_LOW);
pci_write_config32(ctrl->f2, DRAM_CONFIG_LOW, dcl);
meminfo->is_64MuxMode = 1;
} else {
meminfo->dimm_mask &= ~((1 << (DIMM_SOCKETS * 2)) - (1 << DIMM_SOCKETS));
}
}
} else { /* unmatched dual dimms ? */
/* unmatched dual dimms not supported by meminit code. Use single channelA dimm. */
meminfo->dimm_mask &= ~((1 << (DIMM_SOCKETS * 2)) - (1 << DIMM_SOCKETS));
printk(BIOS_SPEW, "Unmatched dual dimms. Use single channelA dimm.\n");
}
return meminfo->dimm_mask;
}
struct mem_param {
uint16_t cycle_time;
uint8_t divisor; /* In 1/40 ns increments */
uint8_t TrwtTO;
uint8_t Twrrd;
uint8_t Twrwr;
uint8_t Trdrd;
uint8_t DcqByPassMax;
uint32_t dch_memclk;
char name[9];
};
static const struct mem_param speed[] = {
{
.name = "200MHz",
.cycle_time = 0x500,
.divisor = 200, // how many 1/40ns per clock
.dch_memclk = DCH_MemClkFreq_200MHz, //0
.TrwtTO = 7,
.Twrrd = 2,
.Twrwr = 2,
.Trdrd = 3,
.DcqByPassMax = 4,
},
{
.name = "266MHz",
.cycle_time = 0x375,
.divisor = 150, //????
.dch_memclk = DCH_MemClkFreq_266MHz, //1
.TrwtTO = 7,
.Twrrd = 2,
.Twrwr = 2,
.Trdrd = 3,
.DcqByPassMax = 4,
},
{
.name = "333MHz",
.cycle_time = 0x300,
.divisor = 120,
.dch_memclk = DCH_MemClkFreq_333MHz, //2
.TrwtTO = 7,
.Twrrd = 2,
.Twrwr = 2,
.Trdrd = 3,
.DcqByPassMax = 4,
},
{
.name = "400MHz",
.cycle_time = 0x250,
.divisor = 100,
.dch_memclk = DCH_MemClkFreq_400MHz,//3
.TrwtTO = 7,
.Twrrd = 2,
.Twrwr = 2,
.Trdrd = 3,
.DcqByPassMax = 4,
},
{
.cycle_time = 0x000,
},
};
static const struct mem_param *get_mem_param(unsigned min_cycle_time)
{
const struct mem_param *param;
for (param = &speed[0]; param->cycle_time; param++) {
if (min_cycle_time > (param+1)->cycle_time) {
break;
}
}
if (!param->cycle_time) {
die("min_cycle_time to low");
}
printk(BIOS_SPEW, "%s\n", param->name);
return param;
}
static uint8_t get_exact_divisor(int i, uint8_t divisor)
{
//input divisor could be 200(200), 150(266), 120(333), 100 (400)
static const uint8_t dv_a[] = {
/* 200 266 333 400 */
/*4 */ 250, 250, 250, 250,
/*5 */ 200, 200, 200, 100,
/*6 */ 200, 166, 166, 100,
/*7 */ 200, 171, 142, 100,
/*8 */ 200, 150, 125, 100,
/*9 */ 200, 156, 133, 100,
/*10*/ 200, 160, 120, 100,
/*11*/ 200, 163, 127, 100,
/*12*/ 200, 150, 133, 100,
/*13*/ 200, 153, 123, 100,
/*14*/ 200, 157, 128, 100,
/*15*/ 200, 160, 120, 100,
};
int index;
msr_t msr;
/* Check for FID control support */
struct cpuid_result cpuid1;
cpuid1 = cpuid(0x80000007);
if (cpuid1.edx & 0x02) {
/* Use current FID */
unsigned fid_cur;
msr = rdmsr(0xc0010042);
fid_cur = msr.lo & 0x3f;
index = fid_cur>>1;
} else {
/* Use startup FID */
unsigned fid_start;
msr = rdmsr(0xc0010015);
fid_start = (msr.lo & (0x3f << 24));
index = fid_start>>25;
}
if (index > 12) return divisor;
if (i > 3) return divisor;
return dv_a[index * 4+i];
}
struct spd_set_memclk_result {
const struct mem_param *param;
long dimm_mask;
};
static unsigned convert_to_linear(unsigned value)
{
static const unsigned fraction[] = { 0x25, 0x33, 0x66, 0x75 };
unsigned valuex;
/* We need to convert value to more readable */
if ((value & 0xf) < 10) { //no .25, .33, .66, .75
value <<= 4;
} else {
valuex = ((value & 0xf0) << 4) | fraction [(value & 0xf)-10];
value = valuex;
}
return value;
}
static const uint8_t latency_indicies[] = { 25, 23, 9 };
static int find_optimum_spd_latency(u32 spd_device, unsigned *min_latency, unsigned *min_cycle_time)
{
int new_cycle_time, new_latency;
int index;
int latencies;
int latency;
/* First find the supported CAS latencies
* Byte 18 for DDR SDRAM is interpreted:
* bit 3 == CAS Latency = 3
* bit 4 == CAS Latency = 4
* bit 5 == CAS Latency = 5
* bit 6 == CAS Latency = 6
*/
new_cycle_time = 0x500;
new_latency = 6;
latencies = spd_read_byte(spd_device, SPD_CAS_LAT);
if (latencies <= 0)
return 1;
printk_raminit("\tlatencies: %08x\n", latencies);
/* Compute the lowest cas latency which can be expressed in this
* particular SPD EEPROM. You can store at most settings for 3
* contiguous CAS latencies, so by taking the highest CAS
* latency marked as supported in the SPD and subtracting 2 you
* get the lowest expressible CAS latency. That latency is not
* necessarily supported, but a (maybe invalid) entry exists
* for it.
*/
latency = log2(latencies) - 2;
/* Loop through and find a fast clock with a low latency */
for (index = 0; index < 3; index++, latency++) {
int value;
if ((latency < 3) || (latency > 6) ||
(!(latencies & (1 << latency)))) {
continue;
}
value = spd_read_byte(spd_device, latency_indicies[index]);
if (value < 0) {
return -1;
}
printk_raminit("\tindex: %08x\n", index);
printk_raminit("\t\tlatency: %08x\n", latency);
printk_raminit("\t\tvalue1: %08x\n", value);
value = convert_to_linear(value);
printk_raminit("\t\tvalue2: %08x\n", value);
/* Only increase the latency if we decrease the clock */
if (value >= *min_cycle_time) {
if (value < new_cycle_time) {
new_cycle_time = value;
new_latency = latency;
} else if (value == new_cycle_time) {
if (new_latency > latency) {
new_latency = latency;
}
}
}
printk_raminit("\t\tnew_cycle_time: %08x\n", new_cycle_time);
printk_raminit("\t\tnew_latency: %08x\n", new_latency);
}
if (new_latency > 6) {
return 1;
}
/* Does min_latency need to be increased? */
if (new_cycle_time > *min_cycle_time) {
*min_cycle_time = new_cycle_time;
}
/* Does min_cycle_time need to be increased? */
if (new_latency > *min_latency) {
*min_latency = new_latency;
}
printk_raminit("2 min_cycle_time: %08x\n", *min_cycle_time);
printk_raminit("2 min_latency: %08x\n", *min_latency);
return 0;
}
static struct spd_set_memclk_result spd_set_memclk(const struct mem_controller *ctrl, struct mem_info *meminfo)
{
/* Compute the minimum cycle time for these dimms */
struct spd_set_memclk_result result;
unsigned min_cycle_time, min_latency, bios_cycle_time;
int i;
uint32_t value;
static const uint16_t min_cycle_times[] = { // use full speed to compare
[NBCAP_MEMCLK_NOLIMIT] = 0x250, /*2.5ns */
[NBCAP_MEMCLK_333MHZ] = 0x300, /* 3.0ns */
[NBCAP_MEMCLK_266MHZ] = 0x375, /* 3.75ns */
[NBCAP_MEMCLK_200MHZ] = 0x500, /* 5.0s */
};
value = pci_read_config32(ctrl->f3, NORTHBRIDGE_CAP);
min_cycle_time = min_cycle_times[(value >> NBCAP_MEMCLK_SHIFT) & NBCAP_MEMCLK_MASK];
bios_cycle_time = min_cycle_times[
#ifdef CMOS_VSTART_max_mem_clock
read_option(max_mem_clock, 0)
#else
#if defined(CONFIG_MAX_MEM_CLOCK)
CONFIG_MAX_MEM_CLOCK
#else
0 // use DDR400 as default
#endif
#endif
];
if (bios_cycle_time > min_cycle_time) {
min_cycle_time = bios_cycle_time;
}
min_latency = 3;
printk_raminit("1 min_cycle_time: %08x\n", min_cycle_time);
/* Compute the least latency with the fastest clock supported
* by both the memory controller and the dimms.
*/
for (i = 0; i < DIMM_SOCKETS; i++) {
u32 spd_device;
printk_raminit("1.1 dimm_mask: %08x\n", meminfo->dimm_mask);
printk_raminit("i: %08x\n",i);
if (meminfo->dimm_mask & (1 << i)) {
spd_device = ctrl->channel0[i];
printk_raminit("Channel 0 settings:\n");
switch (find_optimum_spd_latency(spd_device, &min_latency, &min_cycle_time)) {
case -1:
goto hw_error;
break;
case 1:
continue;
}
}
if (meminfo->dimm_mask & (1 << (DIMM_SOCKETS + i))) {
spd_device = ctrl->channel1[i];
printk_raminit("Channel 1 settings:\n");
switch (find_optimum_spd_latency(spd_device, &min_latency, &min_cycle_time)) {
case -1:
goto hw_error;
break;
case 1:
continue;
}
}
}
/* Make a second pass through the dimms and disable
* any that cannot support the selected memclk and cas latency.
*/
printk_raminit("3 min_cycle_time: %08x\n", min_cycle_time);
printk_raminit("3 min_latency: %08x\n", min_latency);
for (i = 0; (i < DIMM_SOCKETS); i++) {
int latencies;
int latency;
int index;
int val;
u32 spd_device = ctrl->channel0[i];
if (!(meminfo->dimm_mask & (1 << i))) {
if (meminfo->dimm_mask & (1 << (DIMM_SOCKETS + i))) { /* channelB only? */
spd_device = ctrl->channel1[i];
} else {
continue;
}
}
latencies = spd_read_byte(spd_device, SPD_CAS_LAT);
if (latencies < 0) goto hw_error;
if (latencies == 0) {
continue;
}
/* Compute the lowest cas latency supported */
latency = log2(latencies) -2;
/* Walk through searching for the selected latency */
for (index = 0; index < 3; index++, latency++) {
if (!(latencies & (1 << latency))) {
continue;
}
if (latency == min_latency)
break;
}
/* If I can't find the latency or my index is bad error */
if ((latency != min_latency) || (index >= 3)) {
goto dimm_err;
}
/* Read the min_cycle_time for this latency */
val = spd_read_byte(spd_device, latency_indicies[index]);
if (val < 0) goto hw_error;
val = convert_to_linear(val);
/* All is good if the selected clock speed
* is what I need or slower.
*/
if (val <= min_cycle_time) {
continue;
}
/* Otherwise I have an error, disable the dimm */
dimm_err:
meminfo->dimm_mask = disable_dimm(ctrl, i, meminfo);
}
printk_raminit("4 min_cycle_time: %08x\n", min_cycle_time);
/* Now that I know the minimum cycle time lookup the memory parameters */
result.param = get_mem_param(min_cycle_time);
/* Update DRAM Config High with our selected memory speed */
value = pci_read_config32(ctrl->f2, DRAM_CONFIG_HIGH);
value &= ~(DCH_MemClkFreq_MASK << DCH_MemClkFreq_SHIFT);
value |= result.param->dch_memclk << DCH_MemClkFreq_SHIFT;
pci_write_config32(ctrl->f2, DRAM_CONFIG_HIGH, value);
printk(BIOS_DEBUG, "%s\n", result.param->name);
/* Update DRAM Timing Low with our selected cas latency */
value = pci_read_config32(ctrl->f2, DRAM_TIMING_LOW);
value &= ~(DTL_TCL_MASK << DTL_TCL_SHIFT);
value |= (min_latency - DTL_TCL_BASE) << DTL_TCL_SHIFT;
pci_write_config32(ctrl->f2, DRAM_TIMING_LOW, value);
result.dimm_mask = meminfo->dimm_mask;
return result;
hw_error:
result.param = (const struct mem_param *)0;
result.dimm_mask = -1;
return result;
}
static unsigned convert_to_1_4(unsigned value)
{
static const uint8_t fraction[] = { 0, 1, 2, 2, 3, 3, 0 };
unsigned valuex;
/* We need to convert value to more readable */
valuex = fraction [value & 0x7];
return valuex;
}
static int get_dimm_Trc_clocks(u32 spd_device, const struct mem_param *param)
{
int value;
int value2;
int clocks;
value = spd_read_byte(spd_device, SPD_TRC);
if (value < 0)
return -1;
printk_raminit("update_dimm_Trc: tRC (41) = %08x\n", value);
value2 = spd_read_byte(spd_device, SPD_TRC -1);
value <<= 2;
value += convert_to_1_4(value2>>4);
value *= 10;
printk_raminit("update_dimm_Trc: tRC final value = %i\n", value);
clocks = CEIL_DIV(value, param->divisor);
printk_raminit("update_dimm_Trc: clocks = %i\n", clocks);
if (clocks < DTL_TRC_MIN) {
// We might want to die here instead or (at least|better) disable this bank.
printk(BIOS_NOTICE, "update_dimm_Trc: Can't refresh fast enough, "
"want %i clocks, minimum is %i clocks.\n", clocks, DTL_TRC_MIN);
clocks = DTL_TRC_MIN;
}
return clocks;
}
static int update_dimm_Trc(const struct mem_controller *ctrl,
const struct mem_param *param,
int i, long dimm_mask)
{
int clocks, old_clocks;
uint32_t dtl;
u32 spd_device = ctrl->channel0[i];
if (!(dimm_mask & (1 << i)) && (dimm_mask & (1 << (DIMM_SOCKETS + i)))) { /* channelB only? */
spd_device = ctrl->channel1[i];
}
clocks = get_dimm_Trc_clocks(spd_device, param);
if (clocks == -1)
return clocks;
if (clocks > DTL_TRC_MAX) {
return 0;
}
printk_raminit("update_dimm_Trc: clocks after adjustment = %i\n", clocks);
dtl = pci_read_config32(ctrl->f2, DRAM_TIMING_LOW);
old_clocks = ((dtl >> DTL_TRC_SHIFT) & DTL_TRC_MASK) + DTL_TRC_BASE;
if (old_clocks >= clocks) { //?? someone did it
// clocks = old_clocks;
return 1;
}
dtl &= ~(DTL_TRC_MASK << DTL_TRC_SHIFT);
dtl |= ((clocks - DTL_TRC_BASE) << DTL_TRC_SHIFT);
pci_write_config32(ctrl->f2, DRAM_TIMING_LOW, dtl);
return 1;
}
static int update_dimm_Trfc(const struct mem_controller *ctrl, const struct mem_param *param, int i, struct mem_info *meminfo)
{
unsigned clocks, old_clocks;
uint32_t dth;
int value;
u8 ch_b = 0;
u32 spd_device = ctrl->channel0[i];
if (!(meminfo->dimm_mask & (1 << i)) && (meminfo->dimm_mask & (1 << (DIMM_SOCKETS + i)))) { /* channelB only? */
spd_device = ctrl->channel1[i];
ch_b = 2; /* offset to channelB trfc setting */
}
//get the cs_size --> logic dimm size
value = spd_read_byte(spd_device, SPD_PRI_WIDTH);
if (value < 0) {
return -1;
}
value = 6 - log2(value); //4-->4, 8-->3, 16-->2
clocks = meminfo->sz[i].per_rank - 27 + 2 - value;
dth = pci_read_config32(ctrl->f2, DRAM_TIMING_HIGH);
old_clocks = ((dth >> (DTH_TRFC0_SHIFT + ((i + ch_b) * 3))) & DTH_TRFC_MASK);
if (old_clocks >= clocks) { // some one did it?
return 1;
}
dth &= ~(DTH_TRFC_MASK << (DTH_TRFC0_SHIFT + ((i + ch_b) * 3)));
dth |= clocks << (DTH_TRFC0_SHIFT + ((i + ch_b) * 3));
pci_write_config32(ctrl->f2, DRAM_TIMING_HIGH, dth);
return 1;
}
static int update_dimm_TT_1_4(const struct mem_controller *ctrl, const struct mem_param *param, int i, long dimm_mask,
unsigned TT_REG,
unsigned SPD_TT, unsigned TT_SHIFT, unsigned TT_MASK, unsigned TT_BASE, unsigned TT_MIN, unsigned TT_MAX)
{
unsigned clocks, old_clocks;
uint32_t dtl;
int value;
u32 spd_device = ctrl->channel0[i];
if (!(dimm_mask & (1 << i)) && (dimm_mask & (1 << (DIMM_SOCKETS + i)))) { /* channelB only? */
spd_device = ctrl->channel1[i];
}
value = spd_read_byte(spd_device, SPD_TT); //already in 1/4 ns
if (value < 0) return -1;
value *=10;
clocks = CEIL_DIV(value, param->divisor);
if (clocks < TT_MIN) {
clocks = TT_MIN;
}
if (clocks > TT_MAX) {
printk(BIOS_INFO, "warning spd byte : %x = %x > TT_MAX: %x, setting TT_MAX", SPD_TT, value, TT_MAX);
clocks = TT_MAX;
}
dtl = pci_read_config32(ctrl->f2, TT_REG);
old_clocks = ((dtl >> TT_SHIFT) & TT_MASK) + TT_BASE;
if (old_clocks >= clocks) { //some one did it?
return 1;
}
dtl &= ~(TT_MASK << TT_SHIFT);
dtl |= ((clocks - TT_BASE) << TT_SHIFT);
pci_write_config32(ctrl->f2, TT_REG, dtl);
return 1;
}
static int update_dimm_Trcd(const struct mem_controller *ctrl,
const struct mem_param *param, int i, long dimm_mask)
{
return update_dimm_TT_1_4(ctrl, param, i, dimm_mask, DRAM_TIMING_LOW, SPD_TRCD, DTL_TRCD_SHIFT, DTL_TRCD_MASK, DTL_TRCD_BASE, DTL_TRCD_MIN, DTL_TRCD_MAX);
}
static int update_dimm_Trrd(const struct mem_controller *ctrl, const struct mem_param *param, int i, long dimm_mask)
{
return update_dimm_TT_1_4(ctrl, param, i, dimm_mask, DRAM_TIMING_LOW, SPD_TRRD, DTL_TRRD_SHIFT, DTL_TRRD_MASK, DTL_TRRD_BASE, DTL_TRRD_MIN, DTL_TRRD_MAX);
}
static int update_dimm_Tras(const struct mem_controller *ctrl, const struct mem_param *param, int i, long dimm_mask)
{
unsigned clocks, old_clocks;
uint32_t dtl;
int value;
u32 spd_device = ctrl->channel0[i];
if (!(dimm_mask & (1 << i)) && (dimm_mask & (1 << (DIMM_SOCKETS + i)))) { /* channelB only? */
spd_device = ctrl->channel1[i];
}
value = spd_read_byte(spd_device, SPD_TRAS); //in 1 ns
if (value < 0) return -1;
printk_raminit("update_dimm_Tras: 0 value= %08x\n", value);
value <<= 2; //convert it to in 1/4ns
value *= 10;
printk_raminit("update_dimm_Tras: 1 value= %08x\n", value);
clocks = CEIL_DIV(value, param->divisor);
printk_raminit("update_dimm_Tras: divisor= %08x\n", param->divisor);
printk_raminit("update_dimm_Tras: clocks= %08x\n", clocks);
if (clocks < DTL_TRAS_MIN) {
clocks = DTL_TRAS_MIN;
}
if (clocks > DTL_TRAS_MAX) {
return 0;
}
dtl = pci_read_config32(ctrl->f2, DRAM_TIMING_LOW);
old_clocks = ((dtl >> DTL_TRAS_SHIFT) & DTL_TRAS_MASK) + DTL_TRAS_BASE;
if (old_clocks >= clocks) { // someone did it?
return 1;
}
dtl &= ~(DTL_TRAS_MASK << DTL_TRAS_SHIFT);
dtl |= ((clocks - DTL_TRAS_BASE) << DTL_TRAS_SHIFT);
pci_write_config32(ctrl->f2, DRAM_TIMING_LOW, dtl);
return 1;
}
static int update_dimm_Trp(const struct mem_controller *ctrl,
const struct mem_param *param, int i, long dimm_mask)
{
return update_dimm_TT_1_4(ctrl, param, i, dimm_mask, DRAM_TIMING_LOW, SPD_TRP, DTL_TRP_SHIFT, DTL_TRP_MASK, DTL_TRP_BASE, DTL_TRP_MIN, DTL_TRP_MAX);
}
static int update_dimm_Trtp(const struct mem_controller *ctrl,
const struct mem_param *param, int i, struct mem_info *meminfo)
{
/* need to figure if it is 32 byte burst or 64 bytes burst */
int offset = 2;
if (!meminfo->is_Width128) {
uint32_t dword;
dword = pci_read_config32(ctrl->f2, DRAM_CONFIG_LOW);
if ((dword & DCL_BurstLength32)) offset = 0;
}
return update_dimm_TT_1_4(ctrl, param, i, meminfo->dimm_mask, DRAM_TIMING_LOW, SPD_TRTP, DTL_TRTP_SHIFT, DTL_TRTP_MASK, DTL_TRTP_BASE+offset, DTL_TRTP_MIN+offset, DTL_TRTP_MAX+offset);
}
static int update_dimm_Twr(const struct mem_controller *ctrl, const struct mem_param *param, int i, long dimm_mask)
{
return update_dimm_TT_1_4(ctrl, param, i, dimm_mask, DRAM_TIMING_LOW, SPD_TWR, DTL_TWR_SHIFT, DTL_TWR_MASK, DTL_TWR_BASE, DTL_TWR_MIN, DTL_TWR_MAX);
}
static int update_dimm_Tref(const struct mem_controller *ctrl,
const struct mem_param *param, int i, long dimm_mask)
{
uint32_t dth, dth_old;
int value;
u32 spd_device = ctrl->channel0[i];
if (!(dimm_mask & (1 << i)) && (dimm_mask & (1 << (DIMM_SOCKETS + i)))) { /* channelB only? */
spd_device = ctrl->channel1[i];
}
value = spd_read_byte(spd_device, SPD_TREF); // 0: 15.625us, 1: 3.9us 2: 7.8 us....
if (value < 0) return -1;
if (value == 1) {
value = 3;
} else {
value = 2;
}
dth = pci_read_config32(ctrl->f2, DRAM_TIMING_HIGH);
dth_old = dth;
dth &= ~(DTH_TREF_MASK << DTH_TREF_SHIFT);
dth |= (value << DTH_TREF_SHIFT);
if (dth_old != dth) {
pci_write_config32(ctrl->f2, DRAM_TIMING_HIGH, dth);
}
return 1;
}
static void set_4RankRDimm(const struct mem_controller *ctrl,
const struct mem_param *param, struct mem_info *meminfo)
{
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
int value;
int i;
long dimm_mask = meminfo->dimm_mask;
if (!(meminfo->is_registered)) return;
value = 0;
for (i = 0; i < DIMM_SOCKETS; i++) {
if (!(dimm_mask & (1 << i))) {
continue;
}
if (meminfo->sz[i].rank == 4) {
value = 1;
break;
}
}
if (value == 1) {
uint32_t dch;
dch = pci_read_config32(ctrl->f2, DRAM_CONFIG_HIGH);
dch |= DCH_FourRankRDimm;
pci_write_config32(ctrl->f2, DRAM_CONFIG_HIGH, dch);
}
#endif
}
static uint32_t get_extra_dimm_mask(const struct mem_controller *ctrl,
struct mem_info *meminfo)
{
int i;
uint32_t mask_x4;
uint32_t mask_x16;
uint32_t mask_single_rank;
uint32_t mask_page_1k;
int value;
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
int rank;
#endif
long dimm_mask = meminfo->dimm_mask;
mask_x4 = 0;
mask_x16 = 0;
mask_single_rank = 0;
mask_page_1k = 0;
for (i = 0; i < DIMM_SOCKETS; i++) {
u32 spd_device = ctrl->channel0[i];
if (!(dimm_mask & (1 << i))) {
if (dimm_mask & (1 << (DIMM_SOCKETS + i))) { /* channelB only? */
spd_device = ctrl->channel1[i];
} else {
continue;
}
}
if (meminfo->sz[i].rank == 1) {
mask_single_rank |= 1<<i;
}
if (meminfo->sz[i].col == 10) {
mask_page_1k |= 1<<i;
}
value = spd_read_byte(spd_device, SPD_PRI_WIDTH);
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
rank = meminfo->sz[i].rank;
#endif
if (value == 4) {
mask_x4 |= (1<<i);
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
if (rank == 4) {
mask_x4 |= 1<<(i+2);
}
#endif
} else if (value == 16) {
mask_x16 |= (1<<i);
#if IS_ENABLED(CONFIG_QRANK_DIMM_SUPPORT)
if (rank == 4) {
mask_x16 |= 1<<(i+2);
}
#endif
}
}
meminfo->x4_mask= mask_x4;
meminfo->x16_mask = mask_x16;
meminfo->single_rank_mask = mask_single_rank;
meminfo->page_1k_mask = mask_page_1k;
return mask_x4;
}
static void set_dimm_x4(const struct mem_controller *ctrl, const struct mem_param *param, struct mem_info *meminfo)
{
uint32_t dcl;
dcl = pci_read_config32(ctrl->f2, DRAM_CONFIG_LOW);
dcl &= ~(DCL_X4Dimm_MASK<<DCL_X4Dimm_SHIFT);
dcl |= ((meminfo->x4_mask) & 0xf) << (DCL_X4Dimm_SHIFT);
pci_write_config32(ctrl->f2, DRAM_CONFIG_LOW, dcl);
}
static int count_ones(uint32_t dimm_mask)
{
int dimms;
unsigned index;
dimms = 0;
for (index = 0; index < (2 * DIMM_SOCKETS); index++, dimm_mask >>= 1) {
if (dimm_mask & 1) {
dimms++;
}
}
return dimms;
}
static void set_DramTerm(const struct mem_controller *ctrl,
const struct mem_param *param, struct mem_info *meminfo)
{
uint32_t dcl;
unsigned odt;
odt = 1; // 75 ohms
if (param->divisor == 100) { //DDR2 800
if (meminfo->is_Width128) {
if (count_ones(meminfo->dimm_mask & 0x0f) == 2) {
odt = 3; //50 ohms
}
}
}
#if CONFIG_DIMM_SUPPORT == 0x0204
odt = 0x2; /* 150 ohms */
#endif
dcl = pci_read_config32(ctrl->f2, DRAM_CONFIG_LOW);
dcl &= ~(DCL_DramTerm_MASK<<DCL_DramTerm_SHIFT);
dcl |= (odt & DCL_DramTerm_MASK) << (DCL_DramTerm_SHIFT);
pci_write_config32(ctrl->f2, DRAM_CONFIG_LOW, dcl);
}
static void set_ecc(const struct mem_controller *ctrl,
const struct mem_param *param, struct mem_info *meminfo)
{
int i;
int value;
uint32_t dcl, nbcap;
nbcap = pci_read_config32(ctrl->f3, NORTHBRIDGE_CAP);
dcl = pci_read_config32(ctrl->f2, DRAM_CONFIG_LOW);
dcl &= ~DCL_DimmEccEn;
if (nbcap & NBCAP_ECC) {
dcl |= DCL_DimmEccEn;
}
#ifdef CMOS_VSTART_ECC_memory
if (read_option(ECC_memory, 1) == 0) {
dcl &= ~DCL_DimmEccEn;
}
#else // CMOS_VSTART_ECC_memory not defined
#if !IS_ENABLED(CONFIG_ECC_MEMORY)
dcl &= ~DCL_DimmEccEn;
#endif
#endif
pci_write_config32(ctrl->f2, DRAM_CONFIG_LOW, dcl);
meminfo->is_ecc = 1;
if (!(dcl & DCL_DimmEccEn)) {
meminfo->is_ecc = 0;
printk(BIOS_DEBUG, "set_ecc: ECC disabled\n");
return; // already disabled the ECC, so don't need to read SPD any more
}
for (i = 0; i < DIMM_SOCKETS; i++) {
u32 spd_device = ctrl->channel0[i];
if (!(meminfo->dimm_mask & (1 << i))) {
if (meminfo->dimm_mask & (1 << (DIMM_SOCKETS + i))) { /* channelB only? */
spd_device = ctrl->channel1[i];
printk(BIOS_DEBUG, "set_ecc spd_device: 0x%x\n", spd_device);
} else {
continue;
}
}
value = spd_read_byte(ctrl->channel0[i], SPD_DIMM_CONF_TYPE);
if (!(value & SPD_DIMM_CONF_TYPE_ECC)) {
dcl &= ~DCL_DimmEccEn;
pci_write_config32(ctrl->f2, DRAM_CONFIG_LOW, dcl);
meminfo->is_ecc = 0;
return;
}
}
}
static int update_dimm_Twtr(const struct mem_controller *ctrl,
const struct mem_param *param, int i, long dimm_mask)
{
return update_dimm_TT_1_4(ctrl, param, i, dimm_mask, DRAM_TIMING_HIGH, SPD_TWTR, DTH_TWTR_SHIFT, DTH_TWTR_MASK, DTH_TWTR_BASE, DTH_TWTR_MIN, DTH_TWTR_MAX);
}
static void set_TT(const struct mem_controller *ctrl,
const struct mem_param *param, unsigned TT_REG, unsigned TT_SHIFT,
unsigned TT_MASK, unsigned TT_BASE, unsigned TT_MIN, unsigned TT_MAX,
unsigned val, const char *str)
{
uint32_t reg;
if ((val < TT_MIN) || (val > TT_MAX)) {
printk(BIOS_ERR, "%s", str);
die(" Unknown\n");
}
reg = pci_read_config32(ctrl->f2, TT_REG);
reg &= ~(TT_MASK << TT_SHIFT);
reg |= ((val - TT_BASE) << TT_SHIFT);
pci_write_config32(ctrl->f2, TT_REG, reg);
return;
}
static void set_TrwtTO(const struct mem_controller *ctrl,
const struct mem_param *param)
{
set_TT(ctrl, param, DRAM_TIMING_HIGH, DTH_TRWTTO_SHIFT, DTH_TRWTTO_MASK,DTH_TRWTTO_BASE, DTH_TRWTTO_MIN, DTH_TRWTTO_MAX, param->TrwtTO, "TrwtTO");
}
static void set_Twrrd(const struct mem_controller *ctrl, const struct mem_param *param)
{
set_TT(ctrl, param, DRAM_TIMING_HIGH, DTH_TWRRD_SHIFT, DTH_TWRRD_MASK,DTH_TWRRD_BASE, DTH_TWRRD_MIN, DTH_TWRRD_MAX, param->Twrrd, "Twrrd");
}
static void set_Twrwr(const struct mem_controller *ctrl, const struct mem_param *param)
{
set_TT(ctrl, param, DRAM_TIMING_HIGH, DTH_TWRWR_SHIFT, DTH_TWRWR_MASK,DTH_TWRWR_BASE, DTH_TWRWR_MIN, DTH_TWRWR_MAX, param->Twrwr, "Twrwr");
}
static void set_Trdrd(const struct mem_controller *ctrl, const struct mem_param *param)
{
set_TT(ctrl, param, DRAM_TIMING_HIGH, DTH_TRDRD_SHIFT, DTH_TRDRD_MASK,DTH_TRDRD_BASE, DTH_TRDRD_MIN, DTH_TRDRD_MAX, param->Trdrd, "Trdrd");
}
static void set_DcqBypassMax(const struct mem_controller *ctrl, const struct mem_param *param)
{
set_TT(ctrl, param, DRAM_CONFIG_HIGH, DCH_DcqBypassMax_SHIFT, DCH_DcqBypassMax_MASK,DCH_DcqBypassMax_BASE, DCH_DcqBypassMax_MIN, DCH_DcqBypassMax_MAX, param->DcqByPassMax, "DcqBypassMax"); // value need to be in CMOS
}
static void set_Tfaw(const struct mem_controller *ctrl, const struct mem_param *param, struct mem_info *meminfo)
{
static const uint8_t faw_1k[] = {8, 10, 13, 14};
static const uint8_t faw_2k[] = {10, 14, 17, 18};
unsigned memclkfreq_index;
unsigned faw;
memclkfreq_index = param->dch_memclk;
if (meminfo->page_1k_mask != 0) { //1k page
faw = faw_1k[memclkfreq_index];
} else {
faw = faw_2k[memclkfreq_index];
}
set_TT(ctrl, param, DRAM_CONFIG_HIGH, DCH_FourActWindow_SHIFT, DCH_FourActWindow_MASK, DCH_FourActWindow_BASE, DCH_FourActWindow_MIN, DCH_FourActWindow_MAX, faw, "FourActWindow");
}
static void set_max_async_latency(const struct mem_controller *ctrl, const struct mem_param *param)
{
uint32_t dch;
unsigned async_lat;
dch = pci_read_config32(ctrl->f2, DRAM_CONFIG_HIGH);
dch &= ~(DCH_MaxAsyncLat_MASK << DCH_MaxAsyncLat_SHIFT);
//FIXME: We need to use Max of DqsRcvEnDelay + 6ns here: After training and get that from index reg 0x10, 0x13, 0x16, 0x19, 0x30, 0x33, 0x36, 0x39
async_lat = 6 + 6;
dch |= ((async_lat - DCH_MaxAsyncLat_BASE) << DCH_MaxAsyncLat_SHIFT);
pci_write_config32(ctrl->f2, DRAM_CONFIG_HIGH, dch);
}
#if (CONFIG_DIMM_SUPPORT & 0x0100) == 0x0000 /* 2T mode only used for unbuffered DIMM */
static void set_SlowAccessMode(const struct mem_controller *ctrl)
{
uint32_t dch;
dch = pci_read_config32(ctrl->f2, DRAM_CONFIG_HIGH);
dch |= (1<<20);
pci_write_config32(ctrl->f2, DRAM_CONFIG_HIGH, dch);
}
#endif
/*
DRAM_OUTPUT_DRV_COMP_CTRL 0, 0x20
DRAM_ADDR_TIMING_CTRL 04, 0x24
*/
static void set_misc_timing(const struct mem_controller *ctrl, struct mem_info *meminfo)
{
uint32_t dword;
uint32_t dwordx;
#if (CONFIG_DIMM_SUPPORT & 0x0100) == 0x0000 /* 2T mode only used for unbuffered DIMM */
unsigned SlowAccessMode = 0;
#endif
#if CONFIG_DIMM_SUPPORT == 0x0104 /* DDR2 and REG */
long dimm_mask = meminfo->dimm_mask & 0x0f;
/* for REG DIMM */
dword = 0x00111222;
dwordx = 0x002f0000;
switch (meminfo->memclk_set) {
case DCH_MemClkFreq_266MHz:
if ((dimm_mask == 0x03) || (dimm_mask == 0x02) || (dimm_mask == 0x01)) {
dwordx = 0x002f2700;
}
break;
case DCH_MemClkFreq_333MHz:
if ((dimm_mask == 0x03) || (dimm_mask == 0x02) || (dimm_mask == 0x01)) {
if ((meminfo->single_rank_mask & 0x03)!=0x03) { //any double rank there?
dwordx = 0x002f2f00;
}
}
break;
case DCH_MemClkFreq_400MHz:
dwordx = 0x002f3300;
break;
}
#endif
#if CONFIG_DIMM_SUPPORT == 0x0204 /* DDR2 and SO-DIMM, S1G1 */
dword = 0x00111222;
dwordx = 0x002F2F00;
switch (meminfo->memclk_set) {
case DCH_MemClkFreq_200MHz: /* nothing to be set here */
break;
case DCH_MemClkFreq_266MHz:
if ((meminfo->single_rank_mask == 0)
&& (meminfo->x4_mask == 0) && (meminfo->x16_mask))
dwordx = 0x002C2C00; /* Double rank x8 */
/* else SRx16, SRx8, DRx16 == 0x002F2F00 */
break;
case DCH_MemClkFreq_333MHz:
if ((meminfo->single_rank_mask == 1)
&& (meminfo->x16_mask == 1)) /* SR x16 */
dwordx = 0x00272700;
else if ((meminfo->x4_mask == 0) && (meminfo->x16_mask == 0)
&& (meminfo->single_rank_mask == 0)) { /* DR x8 */
SlowAccessMode = 1;
dwordx = 0x00002800;
} else { /* SR x8, DR x16 */
dwordx = 0x002A2A00;
}
break;
case DCH_MemClkFreq_400MHz:
if ((meminfo->single_rank_mask == 1)
&& (meminfo->x16_mask == 1)) /* SR x16 */
dwordx = 0x00292900;
else if ((meminfo->x4_mask == 0) && (meminfo->x16_mask == 0)
&& (meminfo->single_rank_mask == 0)) { /* DR x8 */
SlowAccessMode = 1;
dwordx = 0x00002A00;
} else { /* SR x8, DR x16 */
dwordx = 0x002A2A00;
}
break;
}
#endif
#if CONFIG_DIMM_SUPPORT == 0x0004 /* DDR2 and unbuffered */
long dimm_mask = meminfo->dimm_mask & 0x0f;
/* for UNBUF DIMM */
dword = 0x00111222;
dwordx = 0x002f2f00;
switch (meminfo->memclk_set) {
case DCH_MemClkFreq_200MHz:
if (dimm_mask == 0x03) {
SlowAccessMode = 1;
dword = 0x00111322;
}
break;
case DCH_MemClkFreq_266MHz:
if (dimm_mask == 0x03) {
SlowAccessMode = 1;
dword = 0x00111322;
if ((meminfo->x4_mask == 0) && (meminfo->x16_mask == 0)) {
switch (meminfo->single_rank_mask) {
case 0x03:
dwordx = 0x00002f00; //x8 single Rank
break;
case 0x00:
dwordx = 0x00342f00; //x8 double Rank
break;
default:
dwordx = 0x00372f00; //x8 single Rank and double Rank mixed
}
} else if ((meminfo->x4_mask == 0) && (meminfo->x16_mask == 0x01) && (meminfo->single_rank_mask == 0x01)) {
dwordx = 0x00382f00; //x8 Double Rank and x16 single Rank mixed
} else if ((meminfo->x4_mask == 0) && (meminfo->x16_mask == 0x02) && (meminfo->single_rank_mask == 0x02)) {
dwordx = 0x00382f00; //x16 single Rank and x8 double Rank mixed
}
} else {
if ((meminfo->x4_mask == 0) && (meminfo->x16_mask == 0x00) && ((meminfo->single_rank_mask == 0x01)||(meminfo->single_rank_mask == 0x02))) { //x8 single rank
dwordx = 0x002f2f00;
} else {
dwordx = 0x002b2f00;
}
}
break;
case DCH_MemClkFreq_333MHz:
dwordx = 0x00202220;
if (dimm_mask == 0x03) {
SlowAccessMode = 1;
dword = 0x00111322;
if ((meminfo->x4_mask == 0) && (meminfo->x16_mask == 0)) {
switch (meminfo->single_rank_mask) {
case 0x03:
dwordx = 0x00302220; //x8 single Rank
break;
case 0x00:
dwordx = 0x002b2220; //x8 double Rank
break;
default:
dwordx = 0x002a2220; //x8 single Rank and double Rank mixed
}
} else if ((meminfo->x4_mask == 0) && (meminfo->x16_mask == 0x01) && (meminfo->single_rank_mask == 0x01)) {
dwordx = 0x002c2220; //x8 Double Rank and x16 single Rank mixed
} else if ((meminfo->x4_mask == 0) && (meminfo->x16_mask == 0x02) && (meminfo->single_rank_mask == 0x02)) {
dwordx = 0x002c2220; //x16 single Rank and x8 double Rank mixed
}
}
break;
case DCH_MemClkFreq_400MHz:
dwordx = 0x00202520;
SlowAccessMode = 1;
if (dimm_mask == 0x03) {
dword = 0x00113322;
} else {
dword = 0x00113222;
}
break;
}
printk_raminit("\tdimm_mask = %08x\n", meminfo->dimm_mask);
printk_raminit("\tx4_mask = %08x\n", meminfo->x4_mask);
printk_raminit("\tx16_mask = %08x\n", meminfo->x16_mask);
printk_raminit("\tsingle_rank_mask = %08x\n", meminfo->single_rank_mask);
printk_raminit("\tODC = %08x\n", dword);
printk_raminit("\tAddr Timing= %08x\n", dwordx);
#endif
#if (CONFIG_DIMM_SUPPORT & 0x0100) == 0x0000 /* 2T mode only used for unbuffered DIMM */
if (SlowAccessMode) {
set_SlowAccessMode(ctrl);
}
#endif
if (!(meminfo->dimm_mask & 0x0F) && (meminfo->dimm_mask & 0xF0)) { /* channelB only? */
/* Program the Output Driver Compensation Control Registers (Function 2:Offset 0x9c, index 0, 0x20) */
pci_write_config32_index_wait(ctrl->f2, 0x98, 0x20, dword);
/* Program the Address Timing Control Registers (Function 2:Offset 0x9c, index 4, 0x24) */
pci_write_config32_index_wait(ctrl->f2, 0x98, 0x24, dwordx);
} else {
/* Program the Output Driver Compensation Control Registers (Function 2:Offset 0x9c, index 0, 0x20) */
pci_write_config32_index_wait(ctrl->f2, 0x98, 0, dword);
if (meminfo->is_Width128) {
pci_write_config32_index_wait(ctrl->f2, 0x98, 0x20, dword);
}
/* Program the Address Timing Control Registers (Function 2:Offset 0x9c, index 4, 0x24) */
pci_write_config32_index_wait(ctrl->f2, 0x98, 4, dwordx);
if (meminfo->is_Width128) {
pci_write_config32_index_wait(ctrl->f2, 0x98, 0x24, dwordx);
}
}
}
static void set_RDqsEn(const struct mem_controller *ctrl,
const struct mem_param *param, struct mem_info *meminfo)
{
#if CONFIG_CPU_SOCKET_TYPE == 0x10
//only need to set for reg and x8
uint32_t dch;
dch = pci_read_config32(ctrl->f2, DRAM_CONFIG_HIGH);
dch &= ~DCH_RDqsEn;
if ((!meminfo->x4_mask) && (!meminfo->x16_mask)) {
dch |= DCH_RDqsEn;
}
pci_write_config32(ctrl->f2, DRAM_CONFIG_HIGH, dch);
#endif
}
static void set_idle_cycle_limit(const struct mem_controller *ctrl,
const struct mem_param *param)
{
uint32_t dcm;
/* AMD says to Hardcode this */
dcm = pci_read_config32(ctrl->f2, DRAM_CTRL_MISC);
dcm &= ~(DCM_ILD_lmt_MASK << DCM_ILD_lmt_SHIFT);
dcm |= DCM_ILD_lmt_16 << DCM_ILD_lmt_SHIFT;
dcm |= DCM_DCC_EN;
pci_write_config32(ctrl->f2, DRAM_CTRL_MISC, dcm);
}
static void set_RdWrQByp(const struct mem_controller *ctrl,
const struct mem_param *param)
{
set_TT(ctrl, param, DRAM_CTRL_MISC, DCM_RdWrQByp_SHIFT, DCM_RdWrQByp_MASK,0, 0, 3, 2, "RdWrQByp");
}
static long spd_set_dram_timing(const struct mem_controller *ctrl,
const struct mem_param *param,
struct mem_info *meminfo)
{
int i;
for (i = 0; i < DIMM_SOCKETS; i++) {
int rc;
if (!(meminfo->dimm_mask & (1 << i)) &&
!(meminfo->dimm_mask & (1 << (DIMM_SOCKETS + i)))) {
continue;
}
printk_raminit("spd_set_dram_timing dimm socket: %08x\n", i);
/* DRAM Timing Low Register */
printk_raminit("\ttrc\n");
if ((rc = update_dimm_Trc (ctrl, param, i, meminfo->dimm_mask)) <= 0) goto dimm_err;
printk_raminit("\ttrcd\n");
if ((rc = update_dimm_Trcd(ctrl, param, i, meminfo->dimm_mask)) <= 0) goto dimm_err;
printk_raminit("\ttrrd\n");
if ((rc = update_dimm_Trrd(ctrl, param, i, meminfo->dimm_mask)) <= 0) goto dimm_err;
printk_raminit("\ttras\n");
if ((rc = update_dimm_Tras(ctrl, param, i, meminfo->dimm_mask)) <= 0) goto dimm_err;
printk_raminit("\ttrp\n");
if ((rc = update_dimm_Trp (ctrl, param, i, meminfo->dimm_mask)) <= 0) goto dimm_err;
printk_raminit("\ttrtp\n");
if ((rc = update_dimm_Trtp(ctrl, param, i, meminfo)) <= 0) goto dimm_err;
printk_raminit("\ttwr\n");
if ((rc = update_dimm_Twr (ctrl, param, i, meminfo->dimm_mask)) <= 0) goto dimm_err;
/* DRAM Timing High Register */
printk_raminit("\ttref\n");
if ((rc = update_dimm_Tref(ctrl, param, i, meminfo->dimm_mask)) <= 0) goto dimm_err;
printk_raminit("\ttwtr\n");
if ((rc = update_dimm_Twtr(ctrl, param, i, meminfo->dimm_mask)) <= 0) goto dimm_err;
printk_raminit("\ttrfc\n");
if ((rc = update_dimm_Trfc(ctrl, param, i, meminfo)) <= 0) goto dimm_err;
/* DRAM Config Low */
continue;
dimm_err:
printk(BIOS_DEBUG, "spd_set_dram_timing dimm_err!\n");
if (rc < 0) {
return -1;
}
meminfo->dimm_mask = disable_dimm(ctrl, i, meminfo);
}
get_extra_dimm_mask(ctrl, meminfo); // will be used by RDqsEn and dimm_x4
/* DRAM Timing Low Register */
/* DRAM Timing High Register */
set_TrwtTO(ctrl, param);
set_Twrrd (ctrl, param);
set_Twrwr (ctrl, param);
set_Trdrd (ctrl, param);
set_4RankRDimm(ctrl, param, meminfo);
/* DRAM Config High */
set_Tfaw(ctrl, param, meminfo);
set_DcqBypassMax(ctrl, param);
set_max_async_latency(ctrl, param);
set_RDqsEn(ctrl, param, meminfo);
/* DRAM Config Low */
set_ecc(ctrl, param, meminfo);
set_dimm_x4(ctrl, param, meminfo);
set_DramTerm(ctrl, param, meminfo);
/* DRAM Control Misc */
set_idle_cycle_limit(ctrl, param);
set_RdWrQByp(ctrl, param);
return meminfo->dimm_mask;
}
void sdram_set_spd_registers(const struct mem_controller *ctrl,
struct sys_info *sysinfo)
{
struct spd_set_memclk_result result;
const struct mem_param *param;
struct mem_param paramx;
struct mem_info *meminfo;
#if 1
if (!sysinfo->ctrl_present[ctrl->node_id]) {
return;
}
#endif
meminfo = &sysinfo->meminfo[ctrl->node_id];
printk(BIOS_DEBUG, "sdram_set_spd_registers: paramx :%p\n", ¶mx);
activate_spd_rom(ctrl);
meminfo->dimm_mask = spd_detect_dimms(ctrl);
printk_raminit("sdram_set_spd_registers: dimm_mask=0x%x\n", meminfo->dimm_mask);
if (!(meminfo->dimm_mask & ((1 << 2*DIMM_SOCKETS) - 1)))
{
printk(BIOS_DEBUG, "No memory for this cpu\n");
return;
}
meminfo->dimm_mask = spd_enable_2channels(ctrl, meminfo);
printk_raminit("spd_enable_2channels: dimm_mask=0x%x\n", meminfo->dimm_mask);
if (meminfo->dimm_mask == -1)
goto hw_spd_err;
meminfo->dimm_mask = spd_set_ram_size(ctrl, meminfo);
printk_raminit("spd_set_ram_size: dimm_mask=0x%x\n", meminfo->dimm_mask);
if (meminfo->dimm_mask == -1)
goto hw_spd_err;
meminfo->dimm_mask = spd_handle_unbuffered_dimms(ctrl, meminfo);
printk_raminit("spd_handle_unbuffered_dimms: dimm_mask=0x%x\n", meminfo->dimm_mask);
if (meminfo->dimm_mask == -1)
goto hw_spd_err;
result = spd_set_memclk(ctrl, meminfo);
param = result.param;
meminfo->dimm_mask = result.dimm_mask;
printk_raminit("spd_set_memclk: dimm_mask=0x%x\n", meminfo->dimm_mask);
if (meminfo->dimm_mask == -1)
goto hw_spd_err;
//store memclk set to sysinfo, in case we need rebuilt param again
meminfo->memclk_set = param->dch_memclk;
memcpy(¶mx, param, sizeof(paramx));
paramx.divisor = get_exact_divisor(param->dch_memclk, paramx.divisor);
meminfo->dimm_mask = spd_set_dram_timing(ctrl, ¶mx, meminfo);
printk_raminit("spd_set_dram_timing: dimm_mask=0x%x\n", meminfo->dimm_mask);
if (meminfo->dimm_mask == -1)
goto hw_spd_err;
order_dimms(ctrl, meminfo);
return;
hw_spd_err:
/* Unrecoverable error reading SPD data */
die("Unrecoverable error reading SPD data. No qualified DIMMs?");
return;
}
#include "raminit_f_dqs.c"
#if CONFIG_HW_MEM_HOLE_SIZEK != 0
static uint32_t hoist_memory(int controllers, const struct mem_controller *ctrl,unsigned hole_startk, int i)
{
int ii;
uint32_t carry_over;
pci_devfn_t dev;
uint32_t base, limit;
uint32_t basek;
uint32_t hoist;
int j;
carry_over = (4*1024*1024) - hole_startk;
for (ii = controllers - 1; ii > i; ii--) {
base = pci_read_config32(ctrl[0].f1, 0x40 + (ii << 3));
if ((base & ((1<<1)|(1<<0))) != ((1<<1)|(1<<0))) {
continue;
}
limit = pci_read_config32(ctrl[0].f1, 0x44 + (ii << 3));
limit += (carry_over << 2);
base += (carry_over << 2);
for (j = 0; j < controllers; j++) {
pci_write_config32(ctrl[j].f1, 0x44 + (ii << 3), limit);
pci_write_config32(ctrl[j].f1, 0x40 + (ii << 3), base);
}
}
limit = pci_read_config32(ctrl[0].f1, 0x44 + (i << 3));
limit += (carry_over << 2);
for (j = 0; j < controllers; j++) {
pci_write_config32(ctrl[j].f1, 0x44 + (i << 3), limit);
}
dev = ctrl[i].f1;
base = pci_read_config32(dev, 0x40 + (i << 3));
basek = (base & 0xffff0000) >> 2;
if (basek == hole_startk) {
//don't need set memhole here, because hole off set will be 0, overflow
//so need to change base reg instead, new basek will be 4*1024*1024
base &= 0x0000ffff;
base |= (4*1024*1024)<<2;
for (j = 0; j < controllers; j++) {
pci_write_config32(ctrl[j].f1, 0x40 + (i<<3), base);
}
} else {
hoist = /* hole start address */
((hole_startk << 10) & 0xff000000) +
/* hole address to memory controller address */
(((basek + carry_over) >> 6) & 0x0000ff00) +
/* enable */
1;
pci_write_config32(dev, 0xf0, hoist);
}
return carry_over;
}
void set_hw_mem_hole(int controllers, const struct mem_controller *ctrl)
{
uint32_t hole_startk;
int i;
hole_startk = 4*1024*1024 - CONFIG_HW_MEM_HOLE_SIZEK;
printk_raminit("Handling memory hole at 0x%08x (default)\n", hole_startk);
#if IS_ENABLED(CONFIG_HW_MEM_HOLE_SIZE_AUTO_INC)
/* We need to double check if the hole_startk is valid, if it is equal
to basek, we need to decrease it some */
uint32_t basek_pri;
for (i = 0; i < controllers; i++) {
uint32_t base;
unsigned base_k;
base = pci_read_config32(ctrl[0].f1, 0x40 + (i << 3));
if ((base & ((1<<1)|(1<<0))) != ((1<<1)|(1<<0))) {
continue;
}
base_k = (base & 0xffff0000) >> 2;
if (base_k == hole_startk) {
/* decrease mem hole startk to make sure it is
on middle of previous node */
hole_startk -= (base_k - basek_pri) >> 1;
break; //only one hole
}
basek_pri = base_k;
}
printk_raminit("Handling memory hole at 0x%08x (adjusted)\n", hole_startk);
#endif
/* find node index that need do set hole */
for (i = 0; i < controllers; i++) {
uint32_t base, limit;
unsigned base_k, limit_k;
base = pci_read_config32(ctrl[0].f1, 0x40 + (i << 3));
if ((base & ((1 << 1) | (1 << 0))) != ((1 << 1) | (1 << 0))) {
continue;
}
limit = pci_read_config32(ctrl[0].f1, 0x44 + (i << 3));
base_k = (base & 0xffff0000) >> 2;
limit_k = ((limit + 0x00010000) & 0xffff0000) >> 2;
if ((base_k <= hole_startk) && (limit_k > hole_startk)) {
unsigned end_k;
hoist_memory(controllers, ctrl, hole_startk, i);
end_k = memory_end_k(ctrl, controllers);
set_top_mem(end_k, hole_startk);
break; //only one hole
}
}
}
#endif
void sdram_enable(int controllers, const struct mem_controller *ctrl,
struct sys_info *sysinfo)
{
int i;
int suspend = acpi_is_wakeup_s3();
#if K8_REV_F_SUPPORT_F0_F1_WORKAROUND == 1
unsigned cpu_f0_f1[8];
/* FIXME: How about 32 node machine later? */
tsc_t tsc, tsc0[8];
printk(BIOS_DEBUG, "sdram_enable: tsc0[8]: %p", &tsc0[0]);
uint32_t dword;
#endif
/* Error if I don't have memory */
if (memory_end_k(ctrl, controllers) == 0) {
die("No memory\n");
}
/* Before enabling memory start the memory clocks */
for (i = 0; i < controllers; i++) {
uint32_t dch;
if (!sysinfo->ctrl_present[ i ])
continue;
dch = pci_read_config32(ctrl[i].f2, DRAM_CONFIG_HIGH);
/* if no memory installed, disabled the interface */
if (sysinfo->meminfo[i].dimm_mask == 0x00) {
dch |= DCH_DisDramInterface;
pci_write_config32(ctrl[i].f2, DRAM_CONFIG_HIGH, dch);
} else {
dch |= DCH_MemClkFreqVal;
pci_write_config32(ctrl[i].f2, DRAM_CONFIG_HIGH, dch);
/* address timing and Output driver comp Control */
set_misc_timing(ctrl+i, sysinfo->meminfo+i);
}
}
/* We need to wait a minimum of 20 MEMCLKS to enable the InitDram */
memreset(controllers, ctrl);
/* lets override the rest of the routine */
if (suspend) {
printk(BIOS_DEBUG, "Wakeup!\n");
exit_from_self(controllers, ctrl, sysinfo);
printk(BIOS_DEBUG, "Mem running !\n");
return;
}
for (i = 0; i < controllers; i++) {
uint32_t dcl, dch;
if (!sysinfo->ctrl_present[ i ])
continue;
/* Skip everything if I don't have any memory on this controller */
dch = pci_read_config32(ctrl[i].f2, DRAM_CONFIG_HIGH);
if (!(dch & DCH_MemClkFreqVal)) {
continue;
}
/* ChipKill */
dcl = pci_read_config32(ctrl[i].f2, DRAM_CONFIG_LOW);
if (dcl & DCL_DimmEccEn) {
uint32_t mnc;
printk(BIOS_SPEW, "ECC enabled\n");
mnc = pci_read_config32(ctrl[i].f3, MCA_NB_CONFIG);
mnc |= MNC_ECC_EN;
if (dcl & DCL_Width128) {
mnc |= MNC_CHIPKILL_EN;
}
pci_write_config32(ctrl[i].f3, MCA_NB_CONFIG, mnc);
}
#if K8_REV_F_SUPPORT_F0_F1_WORKAROUND == 1
cpu_f0_f1[i] = is_cpu_pre_f2_in_bsp(i);
if (cpu_f0_f1[i]) {
//Rev F0/F1 workaround
#if 1
/* Set the DqsRcvEnTrain bit */
dword = pci_read_config32(ctrl[i].f2, DRAM_CTRL);
dword |= DC_DqsRcvEnTrain;
pci_write_config32(ctrl[i].f2, DRAM_CTRL, dword);
#endif
tsc0[i] = rdtsc();
}
#endif
pci_write_config32(ctrl[i].f2, DRAM_CONFIG_LOW, dcl);
dcl |= DCL_InitDram;
pci_write_config32(ctrl[i].f2, DRAM_CONFIG_LOW, dcl);
}
for (i = 0; i < controllers; i++) {
uint32_t dcl, dcm;
if (!sysinfo->ctrl_present[ i ])
continue;
/* Skip everything if I don't have any memory on this controller */
if (sysinfo->meminfo[i].dimm_mask == 0x00) continue;
printk(BIOS_DEBUG, "Initializing memory: ");
int loops = 0;
do {
dcl = pci_read_config32(ctrl[i].f2, DRAM_CONFIG_LOW);
loops++;
if ((loops & 1023) == 0) {
printk(BIOS_DEBUG, ".");
}
} while (((dcl & DCL_InitDram) != 0) && (loops < TIMEOUT_LOOPS));
if (loops >= TIMEOUT_LOOPS) {
printk(BIOS_DEBUG, " failed\n");
continue;
}
/* Wait until it is safe to touch memory */
do {
dcm = pci_read_config32(ctrl[i].f2, DRAM_CTRL_MISC);
} while (((dcm & DCM_MemClrStatus) == 0) /* || ((dcm & DCM_DramEnabled) == 0)*/);
#if K8_REV_F_SUPPORT_F0_F1_WORKAROUND == 1
if (cpu_f0_f1[i]) {
tsc= rdtsc();
print_debug_dqs_tsc("\nbegin tsc0", i, tsc0[i].hi, tsc0[i].lo, 2);
print_debug_dqs_tsc("end tsc ", i, tsc.hi, tsc.lo, 2);
if (tsc.lo < tsc0[i].lo) {
tsc.hi--;
}
tsc.lo -= tsc0[i].lo;
tsc.hi -= tsc0[i].hi;
tsc0[i].lo = tsc.lo;
tsc0[i].hi = tsc.hi;
print_debug_dqs_tsc(" dtsc0", i, tsc0[i].hi, tsc0[i].lo, 2);
}
#endif
printk(BIOS_DEBUG, " done\n");
}
#if CONFIG_HW_MEM_HOLE_SIZEK != 0
/* init hw mem hole here */
/* DramHoleValid bit only can be set after MemClrStatus is set by Hardware */
set_hw_mem_hole(controllers, ctrl);
#endif
/* store tom to sysinfo, and it will be used by dqs_timing */
{
msr_t msr;
//[1M, TOM)
msr = rdmsr(TOP_MEM);
sysinfo->tom_k = ((msr.hi<<24) | (msr.lo>>8))>>2;
//[4G, TOM2)
msr = rdmsr(TOP_MEM2);
sysinfo->tom2_k = ((msr.hi<<24)| (msr.lo>>8))>>2;
}
for (i = 0; i < controllers; i++) {
sysinfo->mem_trained[i] = 0;
if (!sysinfo->ctrl_present[ i ])
continue;
/* Skip everything if I don't have any memory on this controller */
if (sysinfo->meminfo[i].dimm_mask == 0x00)
continue;
sysinfo->mem_trained[i] = 0x80; // mem need to be trained
}
#if CONFIG_MEM_TRAIN_SEQ == 0
#if K8_REV_F_SUPPORT_F0_F1_WORKAROUND == 1
dqs_timing(controllers, ctrl, tsc0, sysinfo);
#else
dqs_timing(controllers, ctrl, sysinfo);
#endif
#else
#if CONFIG_MEM_TRAIN_SEQ == 2
/* need to enable mtrr, so dqs training could access the test address */
setup_mtrr_dqs(sysinfo->tom_k, sysinfo->tom2_k);
#endif
for (i = 0; i < controllers; i++) {
/* Skip everything if I don't have any memory on this controller */
if (sysinfo->mem_trained[i]!=0x80)
continue;
dqs_timing(i, &ctrl[i], sysinfo, 1);
#if CONFIG_MEM_TRAIN_SEQ == 1
break; // only train the first node with ram
#endif
}
#if CONFIG_MEM_TRAIN_SEQ == 2
clear_mtrr_dqs(sysinfo->tom2_k);
#endif
#endif
#if CONFIG_MEM_TRAIN_SEQ != 1
wait_all_core0_mem_trained(sysinfo);
#endif
}
void fill_mem_ctrl(int controllers, struct mem_controller *ctrl_a,
const uint16_t *spd_addr)
{
int i;
int j;
struct mem_controller *ctrl;
for (i = 0; i < controllers; i++) {
ctrl = &ctrl_a[i];
ctrl->node_id = i;
ctrl->f0 = PCI_DEV(0, 0x18+i, 0);
ctrl->f1 = PCI_DEV(0, 0x18+i, 1);
ctrl->f2 = PCI_DEV(0, 0x18+i, 2);
ctrl->f3 = PCI_DEV(0, 0x18+i, 3);
if (spd_addr == (void *)0) continue;
for (j = 0; j < DIMM_SOCKETS; j++) {
ctrl->channel0[j] = spd_addr[(i*2+0)*DIMM_SOCKETS + j];
ctrl->channel1[j] = spd_addr[(i*2+1)*DIMM_SOCKETS + j];
}
}
}
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