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cos / mirrors / cros / chromiumos / third_party / coreboot / 9bd1310153914c9cc5bcdb9a18ad8c11b94d40b3 / . / src / northbridge / intel / x4x / raminit.c
blob: b4366fb00535c703bededf264b3d47405c723910 [file] [log] [blame]
/* SPDX-License-Identifier: GPL-2.0-or-later */
#include <device/pci_ops.h>
#include <device/smbus_host.h>
#include <cbmem.h>
#include <cf9_reset.h>
#include <console/console.h>
#include <arch/cpu.h>
#include <spd.h>
#include <string.h>
#include <device/dram/ddr2.h>
#include <device/dram/ddr3.h>
#include <mrc_cache.h>
#include <timestamp.h>
#include <types.h>
#include "raminit.h"
#include "x4x.h"
#define MRC_CACHE_VERSION 0
static u16 ddr2_get_crc(u8 device, u8 len)
{
u8 raw_spd[128] = {};
i2c_eeprom_read(device, 64, 9, &raw_spd[64]);
i2c_eeprom_read(device, 93, 6, &raw_spd[93]);
return spd_ddr2_calc_unique_crc(raw_spd, len);
}
static u16 ddr3_get_crc(u8 device, u8 len)
{
u8 raw_spd[256] = {};
i2c_eeprom_read(device, 117, 11, &raw_spd[117]);
return spd_ddr3_calc_unique_crc(raw_spd, len);
}
static enum cb_err verify_spds(const u8 *spd_map, const struct sysinfo *ctrl_cached)
{
int i;
u16 crc;
for (i = 0; i < TOTAL_DIMMS; i++) {
if (!(spd_map[i]))
continue;
int len = smbus_read_byte(spd_map[i], 0);
if (len < 0 && ctrl_cached->dimms[i].card_type == RAW_CARD_UNPOPULATED)
continue;
if (len > 0 && ctrl_cached->dimms[i].card_type == RAW_CARD_UNPOPULATED)
return CB_ERR;
if (ctrl_cached->spd_type == DDR2)
crc = ddr2_get_crc(spd_map[i], len);
else
crc = ddr3_get_crc(spd_map[i], len);
if (crc != ctrl_cached->dimms[i].spd_crc)
return CB_ERR;
}
return CB_SUCCESS;
}
struct abs_timings {
u32 min_tclk;
u32 min_tRAS;
u32 min_tRP;
u32 min_tRCD;
u32 min_tWR;
u32 min_tRFC;
u32 min_tWTR;
u32 min_tRRD;
u32 min_tRTP;
u32 min_tAA;
u32 min_tCLK_cas[8];
u32 cas_supported;
};
#define CTRL_MIN_TCLK_DDR2 TCK_400MHZ
static void select_cas_dramfreq_ddr2(struct sysinfo *s, const struct abs_timings *saved_timings)
{
u8 try_cas;
/* Currently only these CAS are supported */
u8 cas_mask = SPD_CAS_LATENCY_DDR2_5 | SPD_CAS_LATENCY_DDR2_6;
cas_mask &= saved_timings->cas_supported;
try_cas = spd_get_msbs(cas_mask);
while (cas_mask & (1 << try_cas) && try_cas > 0) {
s->selected_timings.CAS = try_cas;
s->selected_timings.tclk = saved_timings->min_tCLK_cas[try_cas];
if (s->selected_timings.tclk >= CTRL_MIN_TCLK_DDR2 &&
saved_timings->min_tCLK_cas[try_cas] !=
saved_timings->min_tCLK_cas[try_cas - 1])
break;
try_cas--;
}
if ((s->selected_timings.CAS < 3) || (s->selected_timings.tclk == 0))
die("Could not find common memory frequency and CAS\n");
switch (s->selected_timings.tclk) {
case TCK_200MHZ:
case TCK_266MHZ:
/* FIXME: this works on vendor BIOS */
die("Selected dram frequency not supported\n");
case TCK_333MHZ:
s->selected_timings.mem_clk = MEM_CLOCK_667MHz;
break;
case TCK_400MHZ:
s->selected_timings.mem_clk = MEM_CLOCK_800MHz;
break;
}
}
static void mchinfo_ddr2(struct sysinfo *s)
{
const u32 eax = cpuid_ext(0x04, 0).eax;
printk(BIOS_WARNING, "%d CPU cores\n", ((eax >> 26) & 0x3f) + 1);
u32 capid = pci_read_config16(HOST_BRIDGE, 0xe8);
if (!(capid & (1<<(79-64))))
printk(BIOS_WARNING, "iTPM enabled\n");
capid = pci_read_config32(HOST_BRIDGE, 0xe4);
if (!(capid & (1<<(57-32))))
printk(BIOS_WARNING, "ME enabled\n");
if (!(capid & (1<<(56-32))))
printk(BIOS_WARNING, "AMT enabled\n");
if (!(capid & (1<<(48-32))))
printk(BIOS_WARNING, "VT-d enabled\n");
}
static enum cb_err ddr2_save_dimminfo(u8 dimm_idx, u8 *raw_spd,
struct abs_timings *saved_timings, struct sysinfo *s)
{
struct dimm_attr_ddr2_st decoded_dimm;
int i;
if (spd_decode_ddr2(&decoded_dimm, raw_spd) != SPD_STATUS_OK) {
printk(BIOS_DEBUG, "Problems decoding SPD\n");
return CB_ERR;
}
if (CONFIG(DEBUG_RAM_SETUP))
dram_print_spd_ddr2(&decoded_dimm);
if (!(decoded_dimm.width & (0x08 | 0x10))) {
printk(BIOS_ERR, "DIMM%d Unsupported width: x%d. Disabling dimm\n",
dimm_idx, s->dimms[dimm_idx].width);
return CB_ERR;
}
s->dimms[dimm_idx].width = (decoded_dimm.width >> 3) - 1;
/*
* This boils down to:
* "Except for the x16 configuration, all DDR2 devices have a
* 1KB page size. For the x16 configuration, the page size is 2KB
* for all densities except the 256Mb device, which has a 1KB page
* size." Micron, 'TN-47-16 Designing for High-Density DDR2 Memory'
* The formula is pagesize in KiB = width * 2^col_bits / 8.
*/
s->dimms[dimm_idx].page_size = decoded_dimm.width * (1 << decoded_dimm.col_bits) / 8;
switch (decoded_dimm.banks) {
case 4:
s->dimms[dimm_idx].n_banks = N_BANKS_4;
break;
case 8:
s->dimms[dimm_idx].n_banks = N_BANKS_8;
break;
default:
printk(BIOS_ERR, "DIMM%d Unsupported #banks: x%d. Disabling dimm\n",
dimm_idx, decoded_dimm.banks);
return CB_ERR;
}
s->dimms[dimm_idx].ranks = decoded_dimm.ranks;
s->dimms[dimm_idx].rows = decoded_dimm.row_bits;
s->dimms[dimm_idx].cols = decoded_dimm.col_bits;
saved_timings->cas_supported &= decoded_dimm.cas_supported;
saved_timings->min_tRAS = MAX(saved_timings->min_tRAS, decoded_dimm.tRAS);
saved_timings->min_tRP = MAX(saved_timings->min_tRP, decoded_dimm.tRP);
saved_timings->min_tRCD = MAX(saved_timings->min_tRCD, decoded_dimm.tRCD);
saved_timings->min_tWR = MAX(saved_timings->min_tWR, decoded_dimm.tWR);
saved_timings->min_tRFC = MAX(saved_timings->min_tRFC, decoded_dimm.tRFC);
saved_timings->min_tWTR = MAX(saved_timings->min_tWTR, decoded_dimm.tWTR);
saved_timings->min_tRRD = MAX(saved_timings->min_tRRD, decoded_dimm.tRRD);
saved_timings->min_tRTP = MAX(saved_timings->min_tRTP, decoded_dimm.tRTP);
for (i = 0; i < 8; i++) {
if (!(saved_timings->cas_supported & (1 << i)))
saved_timings->min_tCLK_cas[i] = 0;
else
saved_timings->min_tCLK_cas[i] =
MAX(saved_timings->min_tCLK_cas[i],
decoded_dimm.cycle_time[i]);
}
s->dimms[dimm_idx].spd_crc = spd_ddr2_calc_unique_crc(raw_spd,
spd_decode_spd_size_ddr2(raw_spd[0]));
return CB_SUCCESS;
}
static void normalize_tCLK(u32 *tCLK)
{
if (*tCLK <= TCK_666MHZ)
*tCLK = TCK_666MHZ;
else if (*tCLK <= TCK_533MHZ)
*tCLK = TCK_533MHZ;
else if (*tCLK <= TCK_400MHZ)
*tCLK = TCK_400MHZ;
else
*tCLK = 0;
}
static void select_cas_dramfreq_ddr3(struct sysinfo *s, struct abs_timings *saved_timings)
{
/*
* various constraints must be fulfilled:
* CAS * tCK < 20ns == 160MTB
* tCK_max >= tCK >= tCK_min
* CAS >= roundup(tAA_min/tCK)
* CAS supported
* AND BTW: Clock(MT) = 2000 / tCK(ns) - intel uses MTs but calls them MHz
*/
u32 min_tCLK;
u8 try_CAS;
u16 capid = (pci_read_config16(HOST_BRIDGE, 0xea) >> 4) & 0x3f;
switch (s->max_fsb) {
default:
case FSB_CLOCK_800MHz:
min_tCLK = TCK_400MHZ;
break;
case FSB_CLOCK_1066MHz:
min_tCLK = TCK_533MHZ;
break;
case FSB_CLOCK_1333MHz:
min_tCLK = TCK_666MHZ;
break;
}
switch (capid >> 3) {
default: /* Should not happen */
min_tCLK = TCK_400MHZ;
break;
case 1:
min_tCLK = MAX(min_tCLK, TCK_400MHZ);
break;
case 2:
min_tCLK = MAX(min_tCLK, TCK_533MHZ);
break;
case 3: /* Only on P45 */
case 0:
min_tCLK = MAX(min_tCLK, TCK_666MHZ);
break;
}
min_tCLK = MAX(min_tCLK, saved_timings->min_tclk);
if (min_tCLK == 0) {
printk(BIOS_ERR,
"DRAM frequency is under lowest supported frequency (400 MHz).\n"
"Increasing to 400 MHz as last resort.\n");
min_tCLK = TCK_400MHZ;
}
while (1) {
normalize_tCLK(&min_tCLK);
if (min_tCLK == 0)
die("Couldn't find compatible clock / CAS settings.\n");
try_CAS = DIV_ROUND_UP(saved_timings->min_tAA, min_tCLK);
printk(BIOS_SPEW, "Trying CAS %u, tCK %u.\n", try_CAS, min_tCLK);
for (; try_CAS <= DDR3_MAX_CAS; try_CAS++) {
/*
* cas_supported is encoded like the SPD which starts
* at CAS=4.
*/
if ((saved_timings->cas_supported << 4) & (1 << try_CAS))
break;
}
if ((try_CAS <= DDR3_MAX_CAS) && (try_CAS * min_tCLK < 20 * 256)) {
/* Found good CAS. */
printk(BIOS_SPEW, "Found compatible tCLK / CAS pair: %u / %u.\n",
min_tCLK, try_CAS);
break;
}
/*
* If no valid tCLK / CAS pair could be found for a tCLK
* increase it after which it gets normalised. This means
* that a lower frequency gets tried.
*/
min_tCLK++;
}
s->selected_timings.tclk = min_tCLK;
s->selected_timings.CAS = try_CAS;
switch (s->selected_timings.tclk) {
case TCK_400MHZ:
s->selected_timings.mem_clk = MEM_CLOCK_800MHz;
break;
case TCK_533MHZ:
s->selected_timings.mem_clk = MEM_CLOCK_1066MHz;
break;
case TCK_666MHZ:
s->selected_timings.mem_clk = MEM_CLOCK_1333MHz;
break;
}
}
/* With DDR3 and 533MHz mem clock and an enabled internal gfx device the display
is not usable in non stacked mode, so select stacked mode accordingly */
static void workaround_stacked_mode(struct sysinfo *s)
{
u32 deven;
/* Only a problem on DDR3 */
if (s->spd_type == DDR2)
return;
/* Does not matter if only one channel is populated */
if (!CHANNEL_IS_POPULATED(s->dimms, 0) || !CHANNEL_IS_POPULATED(s->dimms, 1))
return;
if (s->selected_timings.mem_clk != MEM_CLOCK_1066MHz)
return;
/* IGD0EN gets disabled if not present before this code runs */
deven = pci_read_config32(HOST_BRIDGE, D0F0_DEVEN);
if (deven & IGD0EN)
s->stacked_mode = 1;
}
static enum cb_err ddr3_save_dimminfo(u8 dimm_idx, u8 *raw_spd,
struct abs_timings *saved_timings, struct sysinfo *s)
{
struct dimm_attr_ddr3_st decoded_dimm;
if (spd_decode_ddr3(&decoded_dimm, raw_spd) != SPD_STATUS_OK)
return CB_ERR;
if (CONFIG(DEBUG_RAM_SETUP))
dram_print_spd_ddr3(&decoded_dimm);
/* x4 DIMMs are not supported (true for both ddr2 and ddr3) */
if (!(decoded_dimm.width & (0x8 | 0x10))) {
printk(BIOS_ERR, "DIMM%d Unsupported width: x%d. Disabling dimm\n",
dimm_idx, s->dimms[dimm_idx].width);
return CB_ERR;
}
s->dimms[dimm_idx].width = (decoded_dimm.width >> 3) - 1;
/*
* This boils down to:
* "Except for the x16 configuration, all DDR3 devices have a
* 1KB page size. For the x16 configuration, the page size is 2KB
* for all densities except the 256Mb device, which has a 1KB page size."
* Micron, 'TN-47-16 Designing for High-Density DDR2 Memory'
*/
s->dimms[dimm_idx].page_size = decoded_dimm.width * (1 << decoded_dimm.col_bits) / 8;
s->dimms[dimm_idx].n_banks = N_BANKS_8; /* Always 8 banks on ddr3?? */
s->dimms[dimm_idx].ranks = decoded_dimm.ranks;
s->dimms[dimm_idx].rows = decoded_dimm.row_bits;
s->dimms[dimm_idx].cols = decoded_dimm.col_bits;
saved_timings->min_tRAS = MAX(saved_timings->min_tRAS, decoded_dimm.tRAS);
saved_timings->min_tRP = MAX(saved_timings->min_tRP, decoded_dimm.tRP);
saved_timings->min_tRCD = MAX(saved_timings->min_tRCD, decoded_dimm.tRCD);
saved_timings->min_tWR = MAX(saved_timings->min_tWR, decoded_dimm.tWR);
saved_timings->min_tRFC = MAX(saved_timings->min_tRFC, decoded_dimm.tRFC);
saved_timings->min_tWTR = MAX(saved_timings->min_tWTR, decoded_dimm.tWTR);
saved_timings->min_tRRD = MAX(saved_timings->min_tRRD, decoded_dimm.tRRD);
saved_timings->min_tRTP = MAX(saved_timings->min_tRTP, decoded_dimm.tRTP);
saved_timings->min_tAA = MAX(saved_timings->min_tAA, decoded_dimm.tAA);
saved_timings->cas_supported &= decoded_dimm.cas_supported;
s->dimms[dimm_idx].spd_crc = spd_ddr3_calc_unique_crc(raw_spd, raw_spd[0]);
s->dimms[dimm_idx].mirrored = decoded_dimm.flags.pins_mirrored;
return CB_SUCCESS;
}
static void select_discrete_timings(struct sysinfo *s, const struct abs_timings *timings)
{
s->selected_timings.tRAS = DIV_ROUND_UP(timings->min_tRAS, s->selected_timings.tclk);
s->selected_timings.tRP = DIV_ROUND_UP(timings->min_tRP, s->selected_timings.tclk);
s->selected_timings.tRCD = DIV_ROUND_UP(timings->min_tRCD, s->selected_timings.tclk);
s->selected_timings.tWR = DIV_ROUND_UP(timings->min_tWR, s->selected_timings.tclk);
s->selected_timings.tRFC = DIV_ROUND_UP(timings->min_tRFC, s->selected_timings.tclk);
s->selected_timings.tWTR = DIV_ROUND_UP(timings->min_tWTR, s->selected_timings.tclk);
s->selected_timings.tRRD = DIV_ROUND_UP(timings->min_tRRD, s->selected_timings.tclk);
s->selected_timings.tRTP = DIV_ROUND_UP(timings->min_tRTP, s->selected_timings.tclk);
}
static void print_selected_timings(struct sysinfo *s)
{
printk(BIOS_DEBUG, "Selected timings:\n");
printk(BIOS_DEBUG, "\tFSB: %dMHz\n", fsb_to_mhz(s->selected_timings.fsb_clk));
printk(BIOS_DEBUG, "\tDDR: %dMHz\n", ddr_to_mhz(s->selected_timings.mem_clk));
printk(BIOS_DEBUG, "\tCAS: %d\n", s->selected_timings.CAS);
printk(BIOS_DEBUG, "\ttRAS: %d\n", s->selected_timings.tRAS);
printk(BIOS_DEBUG, "\ttRP: %d\n", s->selected_timings.tRP);
printk(BIOS_DEBUG, "\ttRCD: %d\n", s->selected_timings.tRCD);
printk(BIOS_DEBUG, "\ttWR: %d\n", s->selected_timings.tWR);
printk(BIOS_DEBUG, "\ttRFC: %d\n", s->selected_timings.tRFC);
printk(BIOS_DEBUG, "\ttWTR: %d\n", s->selected_timings.tWTR);
printk(BIOS_DEBUG, "\ttRRD: %d\n", s->selected_timings.tRRD);
printk(BIOS_DEBUG, "\ttRTP: %d\n", s->selected_timings.tRTP);
}
static void find_fsb_speed(struct sysinfo *s)
{
switch ((mchbar_read32(CLKCFG_MCHBAR) & CLKCFG_FSBCLK_MASK) >> CLKCFG_FSBCLK_SHIFT) {
case 0x0:
s->max_fsb = FSB_CLOCK_1066MHz;
break;
case 0x2:
s->max_fsb = FSB_CLOCK_800MHz;
break;
case 0x4:
s->max_fsb = FSB_CLOCK_1333MHz;
break;
default:
s->max_fsb = FSB_CLOCK_800MHz;
printk(BIOS_WARNING, "Can't detect FSB, setting 800MHz\n");
break;
}
s->selected_timings.fsb_clk = s->max_fsb;
}
static void decode_spd_select_timings(struct sysinfo *s)
{
unsigned int device;
u8 dram_type_mask = (1 << DDR2) | (1 << DDR3);
u8 dimm_mask = 0;
u8 raw_spd[256];
int i, j;
struct abs_timings saved_timings;
memset(&saved_timings, 0, sizeof(saved_timings));
saved_timings.cas_supported = UINT32_MAX;
FOR_EACH_DIMM(i) {
s->dimms[i].card_type = RAW_CARD_POPULATED;
device = s->spd_map[i];
if (!device) {
s->dimms[i].card_type = RAW_CARD_UNPOPULATED;
continue;
}
switch (smbus_read_byte(s->spd_map[i], SPD_MEMORY_TYPE)) {
case DDR2SPD:
dram_type_mask &= 1 << DDR2;
s->spd_type = DDR2;
break;
case DDR3SPD:
dram_type_mask &= 1 << DDR3;
s->spd_type = DDR3;
break;
default:
s->dimms[i].card_type = RAW_CARD_UNPOPULATED;
continue;
}
if (!dram_type_mask)
die("Mixing up dimm types is not supported!\n");
printk(BIOS_DEBUG, "Decoding dimm %d\n", i);
if (i2c_eeprom_read(device, 0, 128, raw_spd) != 128) {
printk(BIOS_DEBUG,
"i2c block operation failed, trying smbus byte operation.\n");
for (j = 0; j < 128; j++)
raw_spd[j] = smbus_read_byte(device, j);
}
if (s->spd_type == DDR2){
if (ddr2_save_dimminfo(i, raw_spd, &saved_timings, s)) {
printk(BIOS_WARNING,
"Encountered problems with SPD, skipping this DIMM.\n");
s->dimms[i].card_type = RAW_CARD_UNPOPULATED;
continue;
}
} else { /* DDR3 */
if (ddr3_save_dimminfo(i, raw_spd, &saved_timings, s)) {
printk(BIOS_WARNING,
"Encountered problems with SPD, skipping this DIMM.\n");
/* something in decoded SPD was unsupported */
s->dimms[i].card_type = RAW_CARD_UNPOPULATED;
continue;
}
}
dimm_mask |= (1 << i);
}
if (!dimm_mask)
die("No memory installed.\n");
if (s->spd_type == DDR2)
select_cas_dramfreq_ddr2(s, &saved_timings);
else
select_cas_dramfreq_ddr3(s, &saved_timings);
select_discrete_timings(s, &saved_timings);
workaround_stacked_mode(s);
}
static void find_dimm_config(struct sysinfo *s)
{
int chan, i;
FOR_EACH_POPULATED_CHANNEL(s->dimms, chan) {
FOR_EACH_POPULATED_DIMM_IN_CHANNEL(s->dimms, chan, i) {
int dimm_config;
if (s->dimms[i].ranks == 1) {
if (s->dimms[i].width == 0) /* x8 */
dimm_config = 1;
else /* x16 */
dimm_config = 3;
} else {
if (s->dimms[i].width == 0) /* x8 */
dimm_config = 2;
else
die("Dual-rank x16 not supported\n");
}
s->dimm_config[chan] |= dimm_config << (i % DIMMS_PER_CHANNEL) * 2;
}
printk(BIOS_DEBUG, " Config[CH%d] : %d\n", chan, s->dimm_config[chan]);
}
}
static void checkreset_ddr2(int boot_path)
{
u8 pmcon2;
u32 pmsts;
if (boot_path >= 1) {
pmsts = mchbar_read32(PMSTS_MCHBAR);
if (!(pmsts & 1))
printk(BIOS_DEBUG, "Channel 0 possibly not in self refresh\n");
if (!(pmsts & 2))
printk(BIOS_DEBUG, "Channel 1 possibly not in self refresh\n");
}
pmcon2 = pci_read_config8(PCI_DEV(0, 0x1f, 0), 0xa2);
if (pmcon2 & 0x80) {
pmcon2 &= ~0x80;
pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, pmcon2);
/* do magic 0xf0 thing. */
pci_and_config8(HOST_BRIDGE, 0xf0, ~(1 << 2));
pci_or_config8(HOST_BRIDGE, 0xf0, (1 << 2));
full_reset();
}
pmcon2 |= 0x80;
pci_write_config8(PCI_DEV(0, 0x1f, 0), 0xa2, pmcon2);
}
/**
* @param boot_path: 0 = normal, 1 = reset, 2 = resume from s3
*/
void sdram_initialize(int boot_path, const u8 *spd_map)
{
struct sysinfo s, *ctrl_cached;
u8 reg8;
int fast_boot, cbmem_was_inited;
size_t mrc_size;
timestamp_add_now(TS_INITRAM_START);
printk(BIOS_DEBUG, "Setting up RAM controller.\n");
pci_write_config8(HOST_BRIDGE, 0xdf, 0xff);
memset(&s, 0, sizeof(struct sysinfo));
ctrl_cached = mrc_cache_current_mmap_leak(MRC_TRAINING_DATA,
MRC_CACHE_VERSION,
&mrc_size);
if (!ctrl_cached || mrc_size < sizeof(s)) {
if (boot_path == BOOT_PATH_RESUME) {
/* Failed S3 resume, reset to come up cleanly */
system_reset();
} else if (boot_path == BOOT_PATH_WARM_RESET) {
/* On warm reset some of dram calibrations fail
and therefore requiring valid cached settings */
full_reset();
}
}
/* verify MRC cache for fast boot */
if (boot_path != BOOT_PATH_RESUME && ctrl_cached) {
/* check SPD checksum to make sure the DIMMs haven't been replaced */
fast_boot = verify_spds(spd_map, ctrl_cached) == CB_SUCCESS;
if (!fast_boot) {
printk(BIOS_DEBUG,
"SPD checksums don't match, dimm's have been replaced\n");
} else {
find_fsb_speed(&s);
fast_boot = s.max_fsb == ctrl_cached->max_fsb;
if (!fast_boot)
printk(BIOS_DEBUG,
"CPU FSB does not match and has been replaced\n");
}
} else {
fast_boot = boot_path == BOOT_PATH_RESUME;
}
if (fast_boot) {
printk(BIOS_DEBUG, "Using cached raminit settings\n");
memcpy(&s, ctrl_cached, sizeof(s));
s.boot_path = boot_path;
mchinfo_ddr2(&s);
print_selected_timings(&s);
} else {
s.boot_path = boot_path;
s.spd_map[0] = spd_map[0];
s.spd_map[1] = spd_map[1];
s.spd_map[2] = spd_map[2];
s.spd_map[3] = spd_map[3];
checkreset_ddr2(s.boot_path);
/* Detect dimms per channel */
reg8 = pci_read_config8(HOST_BRIDGE, 0xe9);
printk(BIOS_DEBUG, "Dimms per channel: %d\n", (reg8 & 0x10) ? 1 : 2);
mchinfo_ddr2(&s);
find_fsb_speed(&s);
decode_spd_select_timings(&s);
print_selected_timings(&s);
find_dimm_config(&s);
}
do_raminit(&s, fast_boot);
pci_and_config8(PCI_DEV(0, 0x1f, 0), 0xa2, (u8)~0x80);
pci_or_config8(HOST_BRIDGE, 0xf4, 1);
timestamp_add_now(TS_INITRAM_END);
printk(BIOS_DEBUG, "RAM initialization finished.\n");
int s3resume = boot_path == BOOT_PATH_RESUME;
cbmem_was_inited = !cbmem_recovery(s3resume);
if (!fast_boot)
mrc_cache_stash_data(MRC_TRAINING_DATA, MRC_CACHE_VERSION, &s, sizeof(s));
if (s3resume && !cbmem_was_inited) {
/* Failed S3 resume, reset to come up cleanly */
system_reset();
}
printk(BIOS_DEBUG, "Memory initialized\n");
}