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/*
* This file is part of the coreboot project.
*
* 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
/*
* for rs690 internal graphics device
* device id of internal grphics:
* RS690M/T: 0x791f
* RS690: 0x791e
*/
#include <console/console.h>
#include <device/device.h>
#include <device/pci.h>
#include <device/pci_ids.h>
#include <device/pci_ops.h>
#include <delay.h>
#include "rs690.h"
#define CLK_CNTL_INDEX 0x8
#define CLK_CNTL_DATA 0xC
static u32 clkind_read(device_t dev, u32 index)
{
u32 gfx_bar2 = pci_read_config32(dev, 0x18) & ~0xF;
*(u32*)(gfx_bar2+CLK_CNTL_INDEX) = index & 0x7F;
return *(u32*)(gfx_bar2+CLK_CNTL_DATA);
}
static void clkind_write(device_t dev, u32 index, u32 data)
{
u32 gfx_bar2 = pci_read_config32(dev, 0x18) & ~0xF;
/* printk_info("gfx bar 2 %02x\n", gfx_bar2); */
*(u32*)(gfx_bar2+CLK_CNTL_INDEX) = index | 1<<7;
*(u32*)(gfx_bar2+CLK_CNTL_DATA) = data;
}
/*
* pci_dev_read_resources thinks it is a IO type.
* We have to force it to mem type.
*/
static void rs690_gfx_read_resources(device_t dev)
{
printk_info("rs690_gfx_read_resources.\n");
/* The initial value of 0x24 is 0xFFFFFFFF, which is confusing.
Even if we write 0xFFFFFFFF into it, it will be 0xFFF00000,
which tells us it is a memory address base.
*/
pci_write_config32(dev, 0x24, 0x00000000);
/* Get the normal pci resources of this device */
pci_dev_read_resources(dev);
compact_resources(dev);
}
static void internal_gfx_pci_dev_init(struct device *dev)
{
u16 deviceid, vendorid;
struct southbridge_amd_rs690_config *cfg =
(struct southbridge_amd_rs690_config *)dev->chip_info;
deviceid = pci_read_config16(dev, PCI_DEVICE_ID);
vendorid = pci_read_config16(dev, PCI_VENDOR_ID);
printk_info("internal_gfx_pci_dev_init device=%x, vendor=%x, vga_rom_address=0x%x.\n",
deviceid, vendorid, cfg->vga_rom_address);
#if 0 /* I think these should be done in Config.lb. Please check it. */
dev->on_mainboard = 1;
dev->rom_address = cfg->vga_rom_address; /* 0xfff00000; */
#endif
pci_dev_init(dev);
/* clk ind */
clkind_write(dev, 0x08, 0x01);
clkind_write(dev, 0x0C, 0x22);
clkind_write(dev, 0x0F, 0x0);
clkind_write(dev, 0x11, 0x0);
clkind_write(dev, 0x12, 0x0);
clkind_write(dev, 0x14, 0x0);
clkind_write(dev, 0x15, 0x0);
clkind_write(dev, 0x16, 0x0);
clkind_write(dev, 0x17, 0x0);
clkind_write(dev, 0x18, 0x0);
clkind_write(dev, 0x19, 0x0);
clkind_write(dev, 0x1A, 0x0);
clkind_write(dev, 0x1B, 0x0);
clkind_write(dev, 0x1C, 0x0);
clkind_write(dev, 0x1D, 0x0);
clkind_write(dev, 0x1E, 0x0);
clkind_write(dev, 0x26, 0x0);
clkind_write(dev, 0x27, 0x0);
clkind_write(dev, 0x28, 0x0);
clkind_write(dev, 0x5C, 0x0);
}
/*
* Set registers in RS690 and CPU to enable the internal GFX.
* Please refer to CIM source code and BKDG.
*/
static void rs690_internal_gfx_enable(device_t dev)
{
u32 l_dword;
int i;
device_t k8_f0 = 0, k8_f2 = 0;
device_t nb_dev = dev_find_slot(0, 0);
printk_info("rs690_internal_gfx_enable dev=0x%p, nb_dev=0x%p.\n", dev,
nb_dev);
/* set APERTURE_SIZE, 128M. */
l_dword = pci_read_config32(nb_dev, 0x8c);
printk_info("nb_dev, 0x8c=0x%x\n", l_dword);
l_dword &= 0xffffff8f;
pci_write_config32(nb_dev, 0x8c, l_dword);
/* set TOM */
rs690_set_tom(nb_dev);
/* LPC DMA Deadlock workaround? */
k8_f0 = dev_find_slot(0, PCI_DEVFN(0x18, 0));
l_dword = pci_read_config32(k8_f0, 0x68);
l_dword &= ~(1 << 22);
l_dword |= (1 << 21);
pci_write_config32(k8_f0, 0x68, l_dword);
/* Enable 64bit mode. */
set_nbmc_enable_bits(nb_dev, 0x5f, 0, 1 << 9);
set_nbmc_enable_bits(nb_dev, 0xb0, 0, 1 << 8);
/* 64bit Latency. */
set_nbmc_enable_bits(nb_dev, 0x5f, 0x7c00, 0x800);
/* UMA dual channel control register. */
nbmc_write_index(nb_dev, 0x86, 0x3d);
/* check the setting later!! */
set_htiu_enable_bits(nb_dev, 0x07, 1 << 7, 0);
/* UMA mode, powerdown memory PLL. */
set_nbmc_enable_bits(nb_dev, 0x74, 0, 1 << 31);
/* Copy CPU DDR Controller to NB MC. */
/* Why K8_MC_REG80 is special? */
k8_f2 = dev_find_slot(0, PCI_DEVFN(0x18, 2));
for (i = 0; i <= (0x80 - 0x40) / 4; i++) {
l_dword = pci_read_config32(k8_f2, 0x40 + i * 4);
nbmc_write_index(nb_dev, 0x63 + i, l_dword);
}
/* Set K8 MC for UMA, Family F. */
l_dword = pci_read_config32(k8_f2, 0xa0);
l_dword |= 0x2c;
pci_write_config32(k8_f2, 0xa0, l_dword);
l_dword = pci_read_config32(k8_f2, 0x94);
l_dword &= 0xf0ffffff;
l_dword |= 0x07000000;
pci_write_config32(k8_f2, 0x94, l_dword);
/* set FB size and location. */
nbmc_write_index(nb_dev, 0x1b, 0x00);
l_dword = nbmc_read_index(nb_dev, 0x1c);
l_dword &= 0xffff0;
l_dword |= 0x400 << 20;
l_dword |= 0x4;
nbmc_write_index(nb_dev, 0x1c, l_dword);
l_dword = nbmc_read_index(nb_dev, 0x1d);
l_dword &= 0xfffff000;
l_dword |= 0x0400;
nbmc_write_index(nb_dev, 0x1d, l_dword);
nbmc_write_index(nb_dev, 0x100, 0x3fff3800);
/* Program MC table. */
set_nbmc_enable_bits(nb_dev, 0x00, 0, 1 << 31);
l_dword = nbmc_read_index(nb_dev, 0x91);
l_dword |= 0x5;
nbmc_write_index(nb_dev, 0x91, l_dword);
set_nbmc_enable_bits(nb_dev, 0xb1, 0, 1 << 6);
set_nbmc_enable_bits(nb_dev, 0xc3, 0, 1);
/* TODO: the optimization of voltage and frequency */
}
static struct pci_operations lops_pci = {
.set_subsystem = pci_dev_set_subsystem,
};
static struct device_operations pcie_ops = {
.read_resources = rs690_gfx_read_resources,
.set_resources = pci_dev_set_resources,
.enable_resources = pci_dev_enable_resources,
.init = internal_gfx_pci_dev_init, /* The option ROM initializes the device. rs690_gfx_init, */
.scan_bus = 0,
.enable = rs690_internal_gfx_enable,
.ops_pci = &lops_pci,
};
/*
* The dev id of 690G is 791E, while the id of 690M, 690T is 791F.
* We should list both of them here.
* */
static struct pci_driver pcie_driver_690t __pci_driver = {
.ops = &pcie_ops,
.vendor = PCI_VENDOR_ID_ATI,
.device = PCI_DEVICE_ID_ATI_RS690MT_INT_GFX,
};
static struct pci_driver pcie_driver_690 __pci_driver = {
.ops = &pcie_ops,
.vendor = PCI_VENDOR_ID_ATI,
.device = PCI_DEVICE_ID_ATI_RS690_INT_GFX,
};
/* step 12 ~ step 14 from rpr */
static void single_port_configuration(device_t nb_dev, device_t dev)
{
u8 result, width;
u32 reg32;
struct southbridge_amd_rs690_config *cfg =
(struct southbridge_amd_rs690_config *)nb_dev->chip_info;
printk_info("rs690_gfx_init single_port_configuration.\n");
/* step 12 training, releases hold training for GFX port 0 (device 2) */
set_nbmisc_enable_bits(nb_dev, 0x8, 1 << 4, 0<<4);
PcieReleasePortTraining(nb_dev, dev, 2);
result = PcieTrainPort(nb_dev, dev, 2);
printk_info("rs690_gfx_init single_port_configuration step12.\n");
/* step 13 Power Down Control */
/* step 13.1 Enables powering down transmitter and receiver pads along with PLL macros. */
set_pcie_enable_bits(nb_dev, 0x40, 1 << 0, 1 << 0);
/* step 13.a Link Training was NOT successful */
if (!result) {
set_nbmisc_enable_bits(nb_dev, 0x8, 0, 0x3 << 4); /* prevent from training. */
set_nbmisc_enable_bits(nb_dev, 0xc, 0, 0x3 << 2); /* hide the GFX bridge. */
if (cfg->gfx_tmds)
nbpcie_ind_write_index(nb_dev, 0x65, 0xccf0f0);
else {
nbpcie_ind_write_index(nb_dev, 0x65, 0xffffffff);
set_nbmisc_enable_bits(nb_dev, 0x7, 1 << 3, 1 << 3);
}
} else { /* step 13.b Link Training was successful */
reg32 = nbpcie_p_read_index(dev, 0xa2);
width = (reg32 >> 4) & 0x7;
printk_debug("GFX LC_LINK_WIDTH = 0x%x.\n", width);
switch (width) {
case 1:
case 2:
nbpcie_ind_write_index(nb_dev, 0x65,
cfg->gfx_lane_reversal ? 0x7f7f : 0xccfefe);
break;
case 4:
nbpcie_ind_write_index(nb_dev, 0x65,
cfg->gfx_lane_reversal ? 0x3f3f : 0xccfcfc);
break;
case 8:
nbpcie_ind_write_index(nb_dev, 0x65,
cfg->gfx_lane_reversal ? 0x0f0f : 0xccf0f0);
break;
}
}
printk_info("rs690_gfx_init single_port_configuration step13.\n");
/* step 14 Reset Enumeration Timer, disables the shortening of the enumeration timer */
set_pcie_enable_bits(dev, 0x70, 1 << 19, 0 << 19);
printk_info("rs690_gfx_init single_port_configuration step14.\n");
}
/* step 15 ~ step 18 from rpr */
static void dual_port_configuration(device_t nb_dev, device_t dev)
{
u8 result, width;
u32 reg32;
struct southbridge_amd_rs690_config *cfg =
(struct southbridge_amd_rs690_config *)nb_dev->chip_info;
/* step 15: Training for Device 2 */
set_nbmisc_enable_bits(nb_dev, 0x8, 1 << 4, 0 << 4);
/* Releases hold training for GFX port 0 (device 2) */
PcieReleasePortTraining(nb_dev, dev, 2);
/* PCIE Link Training Sequence */
result = PcieTrainPort(nb_dev, dev, 2);
/* step 16: Power Down Control for Device 2 */
/* step 16.a Link Training was NOT successful */
if (!result) {
/* Powers down all lanes for port A */
nbpcie_ind_write_index(nb_dev, 0x65, 0x0f0f);
} else { /* step 16.b Link Training was successful */
reg32 = nbpcie_p_read_index(dev, 0xa2);
width = (reg32 >> 4) & 0x7;
printk_debug("GFX LC_LINK_WIDTH = 0x%x.\n", width);
switch (width) {
case 1:
case 2:
nbpcie_ind_write_index(nb_dev, 0x65,
cfg->gfx_lane_reversal ? 0x0707 : 0x0e0e);
break;
case 4:
nbpcie_ind_write_index(nb_dev, 0x65,
cfg->gfx_lane_reversal ? 0x0303 : 0x0c0c);
break;
}
}
/* step 17: Training for Device 3 */
set_nbmisc_enable_bits(nb_dev, 0x8, 1 << 5, 0 << 5);
/* Releases hold training for GFX port 0 (device 3) */
PcieReleasePortTraining(nb_dev, dev, 3);
/* PCIE Link Training Sequence */
result = PcieTrainPort(nb_dev, dev, 3);
/*step 18: Power Down Control for Device 3 */
/* step 18.a Link Training was NOT successful */
if (!result) {
/* Powers down all lanes for port B and PLL1 */
nbpcie_ind_write_index(nb_dev, 0x65, 0xccf0f0);
} else { /* step 18.b Link Training was successful */
reg32 = nbpcie_p_read_index(dev, 0xa2);
width = (reg32 >> 4) & 0x7;
printk_debug("GFX LC_LINK_WIDTH = 0x%x.\n", width);
switch (width) {
case 1:
case 2:
nbpcie_ind_write_index(nb_dev, 0x65,
cfg->gfx_lane_reversal ? 0x7070 : 0xe0e0);
break;
case 4:
nbpcie_ind_write_index(nb_dev, 0x65,
cfg->gfx_lane_reversal ? 0x3030 : 0xc0c0);
break;
}
}
}
/* For single port GFX configuration Only
* width:
* 000 = x16
* 001 = x1
* 010 = x2
* 011 = x4
* 100 = x8
* 101 = x12 (not supported)
* 110 = x16
*/
static void dynamic_link_width_control(device_t nb_dev, device_t dev, u8 width)
{
u32 reg32;
device_t sb_dev;
struct southbridge_amd_rs690_config *cfg =
(struct southbridge_amd_rs690_config *)nb_dev->chip_info;
/* step 5.9.1.1 */
reg32 = nbpcie_p_read_index(dev, 0xa2);
/* step 5.9.1.2 */
set_pcie_enable_bits(nb_dev, 0x40, 1 << 0, 1 << 0);
/* step 5.9.1.3 */
set_pcie_enable_bits(dev, 0xa2, 3 << 0, width << 0);
/* step 5.9.1.4 */
set_pcie_enable_bits(dev, 0xa2, 1 << 8, 1 << 8);
/* step 5.9.2.4 */
if (0 == cfg->gfx_reconfiguration)
set_pcie_enable_bits(dev, 0xa2, 1 << 11, 1 << 11);
/* step 5.9.1.5 */
do {
reg32 = nbpcie_p_read_index(dev, 0xa2);
}
while (reg32 & 0x100);
/* step 5.9.1.6 */
sb_dev = dev_find_slot(0, PCI_DEVFN(8, 0));
do {
reg32 = pci_ext_read_config32(nb_dev, sb_dev,
PCIE_VC0_RESOURCE_STATUS);
} while (reg32 & VC_NEGOTIATION_PENDING);
/* step 5.9.1.7 */
reg32 = nbpcie_p_read_index(dev, 0xa2);
if (((reg32 & 0x70) >> 4) != 0x6) {
/* the unused lanes should be powered off. */
}
/* step 5.9.1.8 */
set_pcie_enable_bits(nb_dev, 0x40, 1 << 0, 0 << 0);
}
/*
* GFX Core initialization, dev2, dev3
*/
void rs690_gfx_init(device_t nb_dev, device_t dev, u32 port)
{
u16 reg16;
struct southbridge_amd_rs690_config *cfg =
(struct southbridge_amd_rs690_config *)nb_dev->chip_info;
printk_info("rs690_gfx_init, nb_dev=0x%p, dev=0x%p, port=0x%x.\n",
nb_dev, dev, port);
/* step 0, REFCLK_SEL, skip A11 revision */
set_nbmisc_enable_bits(nb_dev, 0x6a, 1 << 9,
cfg->gfx_dev2_dev3 ? 1 << 9 : 0 << 9);
printk_info("rs690_gfx_init step0.\n");
/* step 1, lane reversal (only need if CMOS option is enabled) */
if (cfg->gfx_lane_reversal) {
set_nbmisc_enable_bits(nb_dev, 0x33, 1 << 2, 1 << 2);
if (cfg->gfx_dual_slot)
set_nbmisc_enable_bits(nb_dev, 0x33, 1 << 3, 1 << 3);
}
printk_info("rs690_gfx_init step1.\n");
/* step 1.1, dual-slot gfx configuration (only need if CMOS option is enabled) */
/* AMD calls the configuration CrossFire */
if (cfg->gfx_dual_slot)
set_nbmisc_enable_bits(nb_dev, 0x0, 0xf << 8, 5 << 8);
printk_info("rs690_gfx_init step2.\n");
/* step 2, TMDS, (only need if CMOS option is enabled) */
if (cfg->gfx_tmds) {
}
/* step 3, GFX overclocking, (only need if CMOS option is enabled) */
/* skip */
/* step 4, reset the GFX link */
/* step 4.1 asserts both calibration reset and global reset */
set_nbmisc_enable_bits(nb_dev, 0x8, 0x3 << 14, 0x3 << 14);
/* step 4.2 de-asserts calibration reset */
set_nbmisc_enable_bits(nb_dev, 0x8, 1 << 14, 0 << 14);
/* step 4.3 wait for at least 200us */
udelay(200);
/* step 4.4 de-asserts global reset */
set_nbmisc_enable_bits(nb_dev, 0x8, 1 << 15, 0 << 15);
/* step 4.5 asserts both calibration reset and global reset */
/* a weird step in RPR, don't do that */
/* set_nbmisc_enable_bits(nb_dev, 0x8, 0x3 << 14, 0x3 << 14); */
/* step 4.6 bring external GFX device out of reset, wait for 1ms */
mdelay(1);
printk_info("rs690_gfx_init step4.\n");
/* step 5 program PCIE memory mapped configuration space */
/* done by enable_pci_bar3() before */
/* step 6 SBIOS compile flags */
/* step 7 compliance state, (only need if CMOS option is enabled) */
/* the compliance stete is just for test. refer to 4.2.5.2 of PCIe specification */
if (cfg->gfx_compliance) {
/* force compliance */
set_nbmisc_enable_bits(nb_dev, 0x32, 1 << 6, 1 << 6);
/* release hold training for device 2. GFX initialization is done. */
set_nbmisc_enable_bits(nb_dev, 0x8, 1 << 4, 0 << 4);
dynamic_link_width_control(nb_dev, dev, cfg->gfx_link_width);
printk_info("rs690_gfx_init step7.\n");
return;
}
/* step 8 common initialization */
/* step 8.1 sets RCB timeout to be 25ms */
set_pcie_enable_bits(dev, 0x70, 7 << 16, 3 << 16);
printk_info("rs690_gfx_init step8.1.\n");
/* step 8.2 disables slave ordering logic */
set_pcie_enable_bits(nb_dev, 0x20, 1 << 8, 1 << 8);
printk_info("rs690_gfx_init step8.2.\n");
/* step 8.3 sets DMA payload size to 64 bytes */
set_pcie_enable_bits(nb_dev, 0x10, 7 << 10, 4 << 10);
printk_info("rs690_gfx_init step8.3.\n");
/* step 8.4 if the LTSSM could not see all 8 TS1 during Polling Active, it can still
* time out and go back to Detect Idle.*/
set_pcie_enable_bits(dev, 0x02, 1 << 14, 1 << 14);
printk_info("rs690_gfx_init step8.4.\n");
/* step 8.5 shortens the enumeration timer */
set_pcie_enable_bits(dev, 0x70, 1 << 19, 1 << 19);
printk_info("rs690_gfx_init step8.5.\n");
/* step 8.6 blocks DMA traffic during C3 state */
set_pcie_enable_bits(dev, 0x10, 1 << 0, 0 << 0);
printk_info("rs690_gfx_init step8.6.\n");
/* step 8.7 Do not gate the electrical idle form the PHY
* step 8.8 Enables the escape from L1L23 */
set_pcie_enable_bits(dev, 0xa0, 3 << 30, 3 << 30);
printk_info("rs690_gfx_init step8.8.\n");
/* step 8.9 Setting this register to 0x1 will workaround a PCI Compliance failure reported by Vista DTM.
* SLOT_IMPLEMENTED@PCIE_CAP */
reg16 = pci_read_config16(dev, 0x5a);
reg16 |= 0x100;
pci_write_config16(dev, 0x5a, reg16);
printk_info("rs690_gfx_init step8.9.\n");
/* step 8.10 Setting this register to 0x1 will hide the Advanced Error Rporting Capabilities in the PCIE Brider.
* This will workaround several failures reported by the PCI Compliance test under Vista DTM. */
set_nbmisc_enable_bits(nb_dev, 0x33, 1 << 31, 0 << 31);
printk_info("rs690_gfx_init step8.10.\n");
/* step 8.11 Sets REGS_DLP_IGNORE_IN_L1_EN to ignore DLLPs during L1 so that txclk can be turned off. */
set_pcie_enable_bits(nb_dev, 0x02, 1 << 0, 1 << 0);
printk_info("rs690_gfx_init step8.11.\n");
/* step 8.12 Sets REGS_LC_DONT_GO_TO_L0S_IF_L1_ARMED to prevent lc to go to from L0 to Rcv_L0s if L1 is armed. */
set_pcie_enable_bits(nb_dev, 0x02, 1 << 6, 1 << 6);
printk_info("rs690_gfx_init step8.12.\n");
/* step 8.13 Sets CMGOOD_OVERRIDE. */
set_nbmisc_enable_bits(nb_dev, 0x6a, 1 << 17, 1 << 17);
printk_info("rs690_gfx_init step8.13.\n");
/* step 9 Enable TLP Flushing, for non-AMD GFX devices and Hot-Plug devices only. */
/* skip */
/* step 10 Optional Features, only needed if CMOS option is enabled. */
/* step 10.a: L0s */
/* enabling L0s in the RS690 GFX port(s) */
set_pcie_enable_bits(nb_dev, 0xF9, 3 << 13, 2 << 13);
set_pcie_enable_bits(dev, 0xA0, 0xf << 8, 8 << 8);
reg16 = pci_read_config16(dev, 0x68);
reg16 |= 1 << 0;
/* L0s is intended as a power saving state */
/* pci_write_config16(dev, 0x68, reg16); */
/* enabling L0s in the External GFX Device(s) */
/* step 10.b: active state power management (ASPM L1) */
/* TO DO */
/* step 10.c: turning off PLL During L1/L23 */
set_pcie_enable_bits(nb_dev, 0x40, 1 << 3, 1 << 3);
set_pcie_enable_bits(nb_dev, 0x40, 1 << 9, 1 << 9);
/* step 10.d: TXCLK clock gating */
set_nbmisc_enable_bits(nb_dev, 0x7, 3, 3);
set_nbmisc_enable_bits(nb_dev, 0x7, 1 << 22, 1 << 22);
set_pcie_enable_bits(nb_dev, 0x11, 0xf << 4, 0xc << 4);
/* step 10.e: LCLK clock gating, done in rs690_config_misc_clk() */
/* step 11 Poll GPIO to determine whether it is single-port or dual-port configuration.
* While details will be added later in the document, for now assue the single-port configuration. */
/* skip */
/* Single-port/Dual-port configureation. */
switch (cfg->gfx_dual_slot) {
case 0:
single_port_configuration(nb_dev, dev);
break;
case 1:
dual_port_configuration(nb_dev, dev);
break;
default:
printk_info("Incorrect configuration of external gfx slot.\n");
break;
}
}
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