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chromium / chromiumos / third_party / u-boot / bebc36526bdda60901dbfb540b6815c953cd8b0f / . / arch / x86 / lib / coreboot / cb_sysinfo.c
blob: 748fa4ee53bbd02c132dfa2668e250a50e95cdf0 [file] [log] [blame]
// SPDX-License-Identifier: BSD-3-Clause
/*
* This file is part of the libpayload project.
*
* Copyright (C) 2008 Advanced Micro Devices, Inc.
* Copyright (C) 2009 coresystems GmbH
*/
#include <common.h>
#include <asm/cb_sysinfo.h>
#include <init.h>
#include <mapmem.h>
#include <net.h>
#include <asm/global_data.h>
DECLARE_GLOBAL_DATA_PTR;
/*
* This needs to be in the .data section so that it's copied over during
* relocation. By default it's put in the .bss section which is simply filled
* with zeroes when transitioning from "ROM", which is really RAM, to other
* RAM.
*/
struct sysinfo_t lib_sysinfo __section(".data");
/*
* Some of this is x86 specific, and the rest of it is generic. Right now,
* since we only support x86, we'll avoid trying to make lots of infrastructure
* we don't need. If in the future, we want to use coreboot on some other
* architecture, then take out the generic parsing code and move it elsewhere.
*/
/* === Parsing code === */
/* This is the generic parsing code */
static void cb_parse_memory(unsigned char *ptr, struct sysinfo_t *info)
{
struct cb_memory *mem = (struct cb_memory *)ptr;
int count = MEM_RANGE_COUNT(mem);
int i;
if (count > SYSINFO_MAX_MEM_RANGES)
count = SYSINFO_MAX_MEM_RANGES;
info->n_memranges = 0;
for (i = 0; i < count; i++) {
struct cb_memory_range *range =
(struct cb_memory_range *)MEM_RANGE_PTR(mem, i);
info->memrange[info->n_memranges].base =
UNPACK_CB64(range->start);
info->memrange[info->n_memranges].size =
UNPACK_CB64(range->size);
info->memrange[info->n_memranges].type = range->type;
info->n_memranges++;
}
}
static void cb_parse_serial(unsigned char *ptr, struct sysinfo_t *info)
{
struct cb_serial *ser = (struct cb_serial *)ptr;
info->serial = ser;
}
static void cb_parse_vboot_handoff(unsigned char *ptr, struct sysinfo_t *info)
{
struct lb_range *vbho = (struct lb_range *)ptr;
info->vboot_handoff = (void *)(uintptr_t)vbho->range_start;
info->vboot_handoff_size = vbho->range_size;
}
static void cb_parse_vbnv(unsigned char *ptr, struct sysinfo_t *info)
{
struct lb_range *vbnv = (struct lb_range *)ptr;
info->vbnv_start = vbnv->range_start;
info->vbnv_size = vbnv->range_size;
}
static void cb_parse_cbmem_entry(unsigned char *ptr, struct sysinfo_t *info)
{
struct cb_cbmem_entry *entry = (struct cb_cbmem_entry *)ptr;
if (entry->id != CBMEM_ID_SMBIOS)
return;
info->smbios_start = entry->address;
info->smbios_size = entry->entry_size;
}
static void cb_parse_gpios(unsigned char *ptr, struct sysinfo_t *info)
{
int i;
struct cb_gpios *gpios = (struct cb_gpios *)ptr;
info->num_gpios = (gpios->count < SYSINFO_MAX_GPIOS) ?
(gpios->count) : SYSINFO_MAX_GPIOS;
for (i = 0; i < info->num_gpios; i++)
info->gpios[i] = gpios->gpios[i];
}
static void cb_parse_vdat(unsigned char *ptr, struct sysinfo_t *info)
{
struct lb_range *vdat = (struct lb_range *)ptr;
info->vdat_addr = map_sysmem(vdat->range_start, vdat->range_size);
info->vdat_size = vdat->range_size;
}
static void cb_parse_mac_addresses(unsigned char *ptr,
struct sysinfo_t *info)
{
struct cb_macs *macs = (struct cb_macs *)ptr;
int i;
info->num_macs = (macs->count < ARRAY_SIZE(info->macs)) ?
macs->count : ARRAY_SIZE(info->macs);
for (i = 0; i < info->num_macs; i++)
info->macs[i] = macs->mac_addrs[i];
}
static void cb_parse_tstamp(void *ptr, struct sysinfo_t *info)
{
struct cb_cbmem_tab *const cbmem = ptr;
info->tstamp_table = map_sysmem(cbmem->cbmem_tab, 0);
}
static void cb_parse_cbmem_cons(void *ptr, struct sysinfo_t *info)
{
struct cb_cbmem_tab *const cbmem = ptr;
info->cbmem_cons = map_sysmem(cbmem->cbmem_tab, 0);
}
static void cb_parse_acpi_gnvs(unsigned char *ptr, struct sysinfo_t *info)
{
struct cb_cbmem_tab *const cbmem = (struct cb_cbmem_tab *)ptr;
info->acpi_gnvs = map_sysmem(cbmem->cbmem_tab, 0);
}
static void cb_parse_board_id(unsigned char *ptr, struct sysinfo_t *info)
{
struct cb_board_id *const cbbid = (struct cb_board_id *)ptr;
info->board_id = cbbid->board_id;
}
static void cb_parse_ram_code(unsigned char *ptr, struct sysinfo_t *info)
{
struct cb_ram_code *const ram_code = (struct cb_ram_code *)ptr;
info->ram_code = ram_code->ram_code;
}
static void cb_parse_optiontable(void *ptr, struct sysinfo_t *info)
{
/* ptr points to a coreboot table entry and is already virtual */
info->option_table = ptr;
}
static void cb_parse_checksum(void *ptr, struct sysinfo_t *info)
{
struct cb_cmos_checksum *cmos_cksum = ptr;
info->cmos_range_start = cmos_cksum->range_start;
info->cmos_range_end = cmos_cksum->range_end;
info->cmos_checksum_location = cmos_cksum->location;
}
static void cb_parse_framebuffer(void *ptr, struct sysinfo_t *info)
{
/* ptr points to a coreboot table entry and is already virtual */
info->framebuffer = ptr;
}
static void cb_parse_string(unsigned char *ptr, char **info)
{
*info = (char *)((struct cb_string *)ptr)->string;
}
static void cb_parse_wifi_calibration(void *ptr, struct sysinfo_t *info)
{
struct cb_cbmem_tab *const cbmem = (struct cb_cbmem_tab *)ptr;
info->wifi_calibration = map_sysmem(cbmem->cbmem_tab, 0);
}
static void cb_parse_ramoops(void *ptr, struct sysinfo_t *info)
{
struct lb_range *ramoops = (struct lb_range *)ptr;
info->ramoops_buffer = ramoops->range_start;
info->ramoops_buffer_size = ramoops->range_size;
}
static void cb_parse_mtc(void *ptr, struct sysinfo_t *info)
{
struct lb_range *mtc = (struct lb_range *)ptr;
info->mtc_start = mtc->range_start;
info->mtc_size = mtc->range_size;
}
static void cb_parse_spi_flash(void *ptr, struct sysinfo_t *info)
{
struct cb_spi_flash *flash = (struct cb_spi_flash *)ptr;
info->spi_flash.size = flash->flash_size;
info->spi_flash.sector_size = flash->sector_size;
info->spi_flash.erase_cmd = flash->erase_cmd;
}
static void cb_parse_boot_media_params(unsigned char *ptr,
struct sysinfo_t *info)
{
struct cb_boot_media_params *const bmp =
(struct cb_boot_media_params *)ptr;
info->fmap_offset = bmp->fmap_offset;
info->cbfs_offset = bmp->cbfs_offset;
info->cbfs_size = bmp->cbfs_size;
info->boot_media_size = bmp->boot_media_size;
}
static void cb_parse_vpd(void *ptr, struct sysinfo_t *info)
{
struct cb_cbmem_tab *const cbmem = (struct cb_cbmem_tab *)ptr;
info->chromeos_vpd = map_sysmem(cbmem->cbmem_tab, 0);
}
static void cb_parse_tsc_info(void *ptr, struct sysinfo_t *info)
{
const struct cb_tsc_info *tsc_info = ptr;
if (tsc_info->freq_khz == 0)
return;
/* Honor the TSC frequency passed to the payload */
info->cpu_khz = tsc_info->freq_khz;
}
static void cb_parse_x86_rom_var_mtrr(void *ptr, struct sysinfo_t *info)
{
struct cb_x86_rom_mtrr *rom_mtrr = ptr;
info->x86_rom_var_mtrr_index = rom_mtrr->index;
}
static void cb_parse_mrc_cache(void *ptr, struct sysinfo_t *info)
{
struct cb_cbmem_tab *const cbmem = (struct cb_cbmem_tab *)ptr;
info->mrc_cache = map_sysmem(cbmem->cbmem_tab, 0);
}
__weak void cb_parse_unhandled(u32 tag, unsigned char *ptr)
{
}
static int cb_parse_header(void *addr, int len, struct sysinfo_t *info)
{
unsigned char *ptr = addr;
struct cb_header *header;
int i;
header = (struct cb_header *)ptr;
if (!header->table_bytes)
return 0;
/* Make sure the checksums match */
if (!ip_checksum_ok(header, sizeof(*header)))
return -1;
if (compute_ip_checksum(ptr + sizeof(*header), header->table_bytes) !=
header->table_checksum)
return -1;
info->header = header;
/*
* Board straps represented by numerical values are small numbers.
* Preset them to an invalid value in case the firmware does not
* supply the info.
*/
info->board_id = ~0;
info->ram_code = ~0;
/* Now, walk the tables */
ptr += header->header_bytes;
/* Inintialize some fields to sentinel values */
info->vbnv_start = info->vbnv_size = (uint32_t)(-1);
for (i = 0; i < header->table_entries; i++) {
struct cb_record *rec = (struct cb_record *)ptr;
/* We only care about a few tags here (maybe more later) */
switch (rec->tag) {
case CB_TAG_FORWARD:
return cb_parse_header(
(void *)(unsigned long)
((struct cb_forward *)rec)->forward,
len, info);
continue;
case CB_TAG_MEMORY:
cb_parse_memory(ptr, info);
break;
case CB_TAG_SERIAL:
cb_parse_serial(ptr, info);
break;
case CB_TAG_VERSION:
cb_parse_string(ptr, &info->cb_version);
break;
case CB_TAG_EXTRA_VERSION:
cb_parse_string(ptr, &info->extra_version);
break;
case CB_TAG_BUILD:
cb_parse_string(ptr, &info->build);
break;
case CB_TAG_COMPILE_TIME:
cb_parse_string(ptr, &info->compile_time);
break;
case CB_TAG_COMPILE_BY:
cb_parse_string(ptr, &info->compile_by);
break;
case CB_TAG_COMPILE_HOST:
cb_parse_string(ptr, &info->compile_host);
break;
case CB_TAG_COMPILE_DOMAIN:
cb_parse_string(ptr, &info->compile_domain);
break;
case CB_TAG_COMPILER:
cb_parse_string(ptr, &info->compiler);
break;
case CB_TAG_LINKER:
cb_parse_string(ptr, &info->linker);
break;
case CB_TAG_ASSEMBLER:
cb_parse_string(ptr, &info->assembler);
break;
case CB_TAG_CMOS_OPTION_TABLE:
cb_parse_optiontable(ptr, info);
break;
case CB_TAG_OPTION_CHECKSUM:
cb_parse_checksum(ptr, info);
break;
/*
* FIXME we should warn on serial if coreboot set up a
* framebuffer buf the payload does not know about it.
*/
case CB_TAG_FRAMEBUFFER:
cb_parse_framebuffer(ptr, info);
break;
case CB_TAG_MAINBOARD:
info->mainboard = (struct cb_mainboard *)ptr;
break;
case CB_TAG_GPIO:
cb_parse_gpios(ptr, info);
break;
case CB_TAG_VDAT:
cb_parse_vdat(ptr, info);
break;
case CB_TAG_VBNV:
cb_parse_vbnv(ptr, info);
break;
case CB_TAG_VBOOT_HANDOFF:
cb_parse_vboot_handoff(ptr, info);
break;
case CB_TAG_MAC_ADDRS:
cb_parse_mac_addresses(ptr, info);
break;
case CB_TAG_SERIALNO:
cb_parse_string(ptr, &info->serialno);
break;
case CB_TAG_TIMESTAMPS:
cb_parse_tstamp(ptr, info);
break;
case CB_TAG_CBMEM_CONSOLE:
cb_parse_cbmem_cons(ptr, info);
break;
case CB_TAG_ACPI_GNVS:
cb_parse_acpi_gnvs(ptr, info);
break;
case CB_TAG_CBMEM_ENTRY:
cb_parse_cbmem_entry(ptr, info);
break;
case CB_TAG_BOARD_ID:
cb_parse_board_id(ptr, info);
break;
case CB_TAG_RAM_CODE:
cb_parse_ram_code(ptr, info);
break;
case CB_TAG_WIFI_CALIBRATION:
cb_parse_wifi_calibration(ptr, info);
break;
case CB_TAG_RAM_OOPS:
cb_parse_ramoops(ptr, info);
break;
case CB_TAG_SPI_FLASH:
cb_parse_spi_flash(ptr, info);
break;
case CB_TAG_MTC:
cb_parse_mtc(ptr, info);
break;
case CB_TAG_BOOT_MEDIA_PARAMS:
cb_parse_boot_media_params(ptr, info);
break;
case CB_TAG_TSC_INFO:
cb_parse_tsc_info(ptr, info);
break;
case CB_TAG_VPD:
cb_parse_vpd(ptr, info);
break;
case CB_TAG_X86_ROM_MTRR:
cb_parse_x86_rom_var_mtrr(rec, info);
break;
case CB_TAG_MRC_CACHE:
cb_parse_mrc_cache(rec, info);
break;
default:
cb_parse_unhandled(rec->tag, ptr);
break;
}
ptr += rec->size;
}
return 1;
}
/* == Architecture specific == */
/* This is the x86 specific stuff */
int get_coreboot_info(struct sysinfo_t *info)
{
long addr;
int ret;
addr = locate_coreboot_table();
if (addr < 0)
return addr;
ret = cb_parse_header((void *)addr, 0x1000, info);
if (!ret)
return -ENOENT;
gd->arch.coreboot_table = addr;
gd->flags |= GD_FLG_SKIP_LL_INIT;
return 0;
}
const struct sysinfo_t *cb_get_sysinfo(void)
{
if (!ll_boot_init())
return &lib_sysinfo;
return NULL;
}