/*
* This file is part of the coreboot project.
*
* Copyright (C) 2011 Google Inc.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#include <console/console.h>
#include <console/usb.h>
#include <bootmode.h>
#include <cf9_reset.h>
#include <string.h>
#include <device/pci_ops.h>
#include <arch/cpu.h>
#include <cbmem.h>
#include <arch/cbfs.h>
#include <cbfs.h>
#include <ip_checksum.h>
#include <pc80/mc146818rtc.h>
#include <device/pci_def.h>
#include <lib.h>
#include <mrc_cache.h>
#include <timestamp.h>
#include "raminit.h"
#include "pei_data.h"
#include "sandybridge.h"
#include "chip.h"
#include <security/vboot/vboot_common.h>
#include <southbridge/intel/bd82x6x/pch.h>
/* Management Engine is in the southbridge */
#include <southbridge/intel/bd82x6x/me.h>
/*
* MRC scrambler seed offsets should be reserved in
* mainboard cmos.layout and not covered by checksum.
*/
#if CONFIG(USE_OPTION_TABLE)
#include "option_table.h"
#define CMOS_OFFSET_MRC_SEED (CMOS_VSTART_mrc_scrambler_seed >> 3)
#define CMOS_OFFSET_MRC_SEED_S3 (CMOS_VSTART_mrc_scrambler_seed_s3 >> 3)
#define CMOS_OFFSET_MRC_SEED_CHK (CMOS_VSTART_mrc_scrambler_seed_chk >> 3)
#else
#define CMOS_OFFSET_MRC_SEED 152
#define CMOS_OFFSET_MRC_SEED_S3 156
#define CMOS_OFFSET_MRC_SEED_CHK 160
#endif
#define MRC_CACHE_VERSION 0
void save_mrc_data(struct pei_data *pei_data)
{
u16 c1, c2, checksum;
/* Save the MRC S3 restore data to cbmem */
mrc_cache_stash_data(MRC_TRAINING_DATA, MRC_CACHE_VERSION,
pei_data->mrc_output,
pei_data->mrc_output_len);
/* Save the MRC seed values to CMOS */
cmos_write32(CMOS_OFFSET_MRC_SEED, pei_data->scrambler_seed);
printk(BIOS_DEBUG, "Save scrambler seed 0x%08x to CMOS 0x%02x\n",
pei_data->scrambler_seed, CMOS_OFFSET_MRC_SEED);
cmos_write32(CMOS_OFFSET_MRC_SEED_S3, pei_data->scrambler_seed_s3);
printk(BIOS_DEBUG, "Save s3 scrambler seed 0x%08x to CMOS 0x%02x\n",
pei_data->scrambler_seed_s3, CMOS_OFFSET_MRC_SEED_S3);
/* Save a simple checksum of the seed values */
c1 = compute_ip_checksum((u8*)&pei_data->scrambler_seed,
sizeof(u32));
c2 = compute_ip_checksum((u8*)&pei_data->scrambler_seed_s3,
sizeof(u32));
checksum = add_ip_checksums(sizeof(u32), c1, c2);
cmos_write(checksum & 0xff, CMOS_OFFSET_MRC_SEED_CHK);
cmos_write((checksum >> 8) & 0xff, CMOS_OFFSET_MRC_SEED_CHK+1);
}
static void prepare_mrc_cache(struct pei_data *pei_data)
{
struct region_device rdev;
u16 c1, c2, checksum, seed_checksum;
// preset just in case there is an error
pei_data->mrc_input = NULL;
pei_data->mrc_input_len = 0;
/* Read scrambler seeds from CMOS */
pei_data->scrambler_seed = cmos_read32(CMOS_OFFSET_MRC_SEED);
printk(BIOS_DEBUG, "Read scrambler seed 0x%08x from CMOS 0x%02x\n",
pei_data->scrambler_seed, CMOS_OFFSET_MRC_SEED);
pei_data->scrambler_seed_s3 = cmos_read32(CMOS_OFFSET_MRC_SEED_S3);
printk(BIOS_DEBUG, "Read S3 scrambler seed 0x%08x from CMOS 0x%02x\n",
pei_data->scrambler_seed_s3, CMOS_OFFSET_MRC_SEED_S3);
/* Compute seed checksum and compare */
c1 = compute_ip_checksum((u8*)&pei_data->scrambler_seed,
sizeof(u32));
c2 = compute_ip_checksum((u8*)&pei_data->scrambler_seed_s3,
sizeof(u32));
checksum = add_ip_checksums(sizeof(u32), c1, c2);
seed_checksum = cmos_read(CMOS_OFFSET_MRC_SEED_CHK);
seed_checksum |= cmos_read(CMOS_OFFSET_MRC_SEED_CHK+1) << 8;
if (checksum != seed_checksum) {
printk(BIOS_ERR, "%s: invalid seed checksum\n", __func__);
pei_data->scrambler_seed = 0;
pei_data->scrambler_seed_s3 = 0;
return;
}
if (mrc_cache_get_current(MRC_TRAINING_DATA, MRC_CACHE_VERSION,
&rdev)) {
/* error message printed in find_current_mrc_cache */
return;
}
pei_data->mrc_input = rdev_mmap_full(&rdev);
pei_data->mrc_input_len = region_device_sz(&rdev);
printk(BIOS_DEBUG, "%s: at %p, size %x\n",
__func__, pei_data->mrc_input, pei_data->mrc_input_len);
}
static const char *ecc_decoder[] = {
"inactive",
"active on IO",
"disabled on IO",
"active"
};
/*
* Dump in the log memory controller configuration as read from the memory
* controller registers.
*/
static void report_memory_config(void)
{
u32 addr_decoder_common, addr_decode_ch[2];
int i;
addr_decoder_common = MCHBAR32(0x5000);
addr_decode_ch[0] = MCHBAR32(0x5004);
addr_decode_ch[1] = MCHBAR32(0x5008);
printk(BIOS_DEBUG, "memcfg DDR3 clock %d MHz\n",
(MCHBAR32(0x5e04) * 13333 * 2 + 50)/100);
printk(BIOS_DEBUG, "memcfg channel assignment: A: %d, B % d, C % d\n",
addr_decoder_common & 3,
(addr_decoder_common >> 2) & 3,
(addr_decoder_common >> 4) & 3);
for (i = 0; i < ARRAY_SIZE(addr_decode_ch); i++) {
u32 ch_conf = addr_decode_ch[i];
printk(BIOS_DEBUG, "memcfg channel[%d] config (%8.8x):\n",
i, ch_conf);
printk(BIOS_DEBUG, " ECC %s\n",
ecc_decoder[(ch_conf >> 24) & 3]);
printk(BIOS_DEBUG, " enhanced interleave mode %s\n",
((ch_conf >> 22) & 1) ? "on" : "off");
printk(BIOS_DEBUG, " rank interleave %s\n",
((ch_conf >> 21) & 1) ? "on" : "off");
printk(BIOS_DEBUG, " DIMMA %d MB width x%d %s rank%s\n",
((ch_conf >> 0) & 0xff) * 256,
((ch_conf >> 19) & 1) ? 16 : 8,
((ch_conf >> 17) & 1) ? "dual" : "single",
((ch_conf >> 16) & 1) ? "" : ", selected");
printk(BIOS_DEBUG, " DIMMB %d MB width x%d %s rank%s\n",
((ch_conf >> 8) & 0xff) * 256,
((ch_conf >> 20) & 1) ? 16 : 8,
((ch_conf >> 18) & 1) ? "dual" : "single",
((ch_conf >> 16) & 1) ? ", selected" : "");
}
}
/**
* Find PEI executable in coreboot filesystem and execute it.
*
* @param pei_data: configuration data for UEFI PEI reference code
*/
void sdram_initialize(struct pei_data *pei_data)
{
struct sys_info sysinfo;
int (*entry) (struct pei_data *pei_data) __attribute__((regparm(1)));
/* Wait for ME to be ready */
intel_early_me_init();
intel_early_me_uma_size();
printk(BIOS_DEBUG, "Starting UEFI PEI System Agent\n");
memset(&sysinfo, 0, sizeof(sysinfo));
sysinfo.boot_path = pei_data->boot_mode;
/*
* Do not pass MRC data in for recovery mode boot,
* Always pass it in for S3 resume.
*/
if (!vboot_recovery_mode_enabled() || pei_data->boot_mode == 2)
prepare_mrc_cache(pei_data);
/* If MRC data is not found we cannot continue S3 resume. */
if (pei_data->boot_mode == 2 && !pei_data->mrc_input) {
printk(BIOS_DEBUG, "Giving up in sdram_initialize: No MRC data\n");
system_reset();
}
/* Pass console handler in pei_data */
pei_data->tx_byte = do_putchar;
/* Locate and call UEFI System Agent binary. */
entry = cbfs_boot_map_with_leak("mrc.bin", CBFS_TYPE_MRC, NULL);
if (entry) {
int rv;
rv = entry (pei_data);
if (rv) {
switch (rv) {
case -1:
printk(BIOS_ERR, "PEI version mismatch.\n");
break;
case -2:
printk(BIOS_ERR, "Invalid memory frequency.\n");
break;
default:
printk(BIOS_ERR, "MRC returned %x.\n", rv);
}
die_with_post_code(POST_INVALID_VENDOR_BINARY,
"Nonzero MRC return value.\n");
}
} else {
die("UEFI PEI System Agent not found.\n");
}
/* mrc.bin reconfigures USB, so reinit it to have debug */
if (CONFIG(USBDEBUG_IN_PRE_RAM))
usbdebug_hw_init(true);
/* For reference print the System Agent version
* after executing the UEFI PEI stage.
*/
u32 version = MCHBAR32(0x5034);
printk(BIOS_DEBUG, "System Agent Version %d.%d.%d Build %d\n",
version >> 24, (version >> 16) & 0xff,
(version >> 8) & 0xff, version & 0xff);
/* Send ME init done for SandyBridge here. This is done
* inside the SystemAgent binary on IvyBridge. */
if (BASE_REV_SNB ==
(pci_read_config16(PCI_CPU_DEVICE, PCI_DEVICE_ID) & BASE_REV_MASK))
intel_early_me_init_done(ME_INIT_STATUS_SUCCESS);
else
intel_early_me_status();
report_memory_config();
}
/* These are the location and structure of MRC_VAR data in CAR.
The CAR region looks like this:
+------------------+ -> DCACHE_RAM_BASE
| |
| |
| COREBOOT STACK |
| |
| |
+------------------+ -> DCACHE_RAM_BASE + DCACHE_RAM_SIZE
| |
| MRC HEAP |
| size = 0x5000 |
| |
+------------------+
| |
| MRC VAR |
| size = 0x4000 |
| |
+------------------+ -> DACHE_RAM_BASE + DACHE_RAM_SIZE
+ DCACHE_RAM_MRC_VAR_SIZE
*/
#define DCACHE_RAM_MRC_VAR_BASE \
(CONFIG_DCACHE_RAM_BASE + CONFIG_DCACHE_RAM_SIZE + \
CONFIG_DCACHE_RAM_MRC_VAR_SIZE - 0x4000)
struct mrc_var_data {
u32 acpi_timer_flag;
u32 pool_used;
u32 pool_base;
u32 tx_byte;
u32 reserved[4];
} __packed;
static void northbridge_fill_pei_data(struct pei_data *pei_data)
{
pei_data->mchbar = (uintptr_t)DEFAULT_MCHBAR;
pei_data->dmibar = (uintptr_t)DEFAULT_DMIBAR;
pei_data->epbar = DEFAULT_EPBAR;
pei_data->pciexbar = CONFIG_MMCONF_BASE_ADDRESS;
pei_data->hpet_address = CONFIG_HPET_ADDRESS;
pei_data->thermalbase = 0xfed08000;
pei_data->system_type = get_platform_type() == PLATFORM_MOBILE ? 0 : 1;
pei_data->tseg_size = CONFIG_SMM_TSEG_SIZE;
if ((cpu_get_cpuid() & 0xffff0) == 0x306a0) {
const struct device *dev = pcidev_on_root(1, 0);
pei_data->pcie_init = dev && dev->enabled;
} else {
pei_data->pcie_init = 0;
}
}
static void southbridge_fill_pei_data(struct pei_data *pei_data)
{
const struct device *dev = pcidev_on_root(0x19, 0);
pei_data->smbusbar = SMBUS_IO_BASE;
pei_data->wdbbar = 0x4000000;
pei_data->wdbsize = 0x1000;
pei_data->rcba = (uintptr_t)DEFAULT_RCBABASE;
pei_data->pmbase = DEFAULT_PMBASE;
pei_data->gpiobase = DEFAULT_GPIOBASE;
pei_data->gbe_enable = dev && dev->enabled;
}
static void devicetree_fill_pei_data(struct pei_data *pei_data)
{
const struct northbridge_intel_sandybridge_config *cfg;
const struct device *dev = pcidev_on_root(0, 0);
if (!dev || !dev->chip_info)
return;
cfg = dev->chip_info;
switch (cfg->max_mem_clock_mhz) {
/* MRC only supports fixed numbers of frequencies */
default:
printk(BIOS_WARNING, "RAMINIT: Limiting DDR3 clock to 800 Mhz\n");
/* fallthrough */
case 400:
pei_data->max_ddr3_freq = 800;
break;
case 533:
pei_data->max_ddr3_freq = 1066;
break;
case 666:
pei_data->max_ddr3_freq = 1333;
break;
case 800:
pei_data->max_ddr3_freq = 1600;
break;
}
memcpy(pei_data->spd_addresses, cfg->spd_addresses,
sizeof(pei_data->spd_addresses));
memcpy(pei_data->ts_addresses, cfg->ts_addresses,
sizeof(pei_data->ts_addresses));
pei_data->ec_present = cfg->ec_present;
pei_data->ddr3lv_support = cfg->ddr3lv_support;
pei_data->nmode = cfg->nmode;
pei_data->ddr_refresh_rate_config = cfg->ddr_refresh_rate_config;
memcpy(pei_data->usb_port_config, cfg->usb_port_config,
sizeof(pei_data->usb_port_config));
pei_data->usb3.mode = cfg->usb3.mode;
pei_data->usb3.hs_port_switch_mask = cfg->usb3.hs_port_switch_mask;
pei_data->usb3.preboot_support = cfg->usb3.preboot_support;
pei_data->usb3.xhci_streams = cfg->usb3.xhci_streams;
}
void perform_raminit(int s3resume)
{
int cbmem_was_initted;
struct pei_data pei_data;
struct mrc_var_data *mrc_var;
/* Prepare USB controller early in S3 resume */
if (!mainboard_should_reset_usb(s3resume))
enable_usb_bar();
memset(&pei_data, 0, sizeof(pei_data));
pei_data.pei_version = PEI_VERSION,
northbridge_fill_pei_data(&pei_data);
southbridge_fill_pei_data(&pei_data);
devicetree_fill_pei_data(&pei_data);
mainboard_fill_pei_data(&pei_data);
post_code(0x3a);
/* Fill after mainboard_fill_pei_data as it might provide spd_data */
pei_data.dimm_channel0_disabled =
(!pei_data.spd_addresses[0] && !pei_data.spd_data[0][0]) +
(!pei_data.spd_addresses[1] && !pei_data.spd_data[1][0]) * 2;
pei_data.dimm_channel1_disabled =
(!pei_data.spd_addresses[2] && !pei_data.spd_data[2][0]) +
(!pei_data.spd_addresses[3] && !pei_data.spd_data[3][0]) * 2;
/* Fix spd_data. MRC only uses spd_data[0] and ignores the other */
for (size_t i = 1; i < ARRAY_SIZE(pei_data.spd_data); i++) {
if (pei_data.spd_data[i][0] && !pei_data.spd_data[0][0]) {
memcpy(pei_data.spd_data[0], pei_data.spd_data[i],
sizeof(pei_data.spd_data[0]));
} else if (pei_data.spd_data[i][0] && pei_data.spd_data[0][0]) {
if (memcmp(pei_data.spd_data[i], pei_data.spd_data[0],
sizeof(pei_data.spd_data[0])) != 0)
die("Onboard SPDs must match each other");
}
}
pei_data.boot_mode = s3resume ? 2 : 0;
timestamp_add_now(TS_BEFORE_INITRAM);
sdram_initialize(&pei_data);
mrc_var = (void *)DCACHE_RAM_MRC_VAR_BASE;
/* Sanity check mrc_var location by verifying a known field. */
if (mrc_var->tx_byte == (uintptr_t)pei_data.tx_byte) {
printk(BIOS_DEBUG, "MRC_VAR pool occupied [%08x,%08x]\n",
mrc_var->pool_base,
mrc_var->pool_base + mrc_var->pool_used);
} else {
printk(BIOS_ERR, "Could not parse MRC_VAR data\n");
hexdump32(BIOS_ERR, mrc_var, sizeof(*mrc_var)/sizeof(u32));
}
cbmem_was_initted = !cbmem_recovery(s3resume);
if (!s3resume)
save_mrc_data(&pei_data);
if (s3resume && !cbmem_was_initted) {
/* Failed S3 resume, reset to come up cleanly */
system_reset();
}
}