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coreboot-kgpe-d16/src/arch/x86/smbios.c
Tim Chu 13ab1d7879 arch/x86/smbios: Add support for wake-up type in smbios type 1 
Add system wake-up type in smbios type 1 - system information.

TESTED=On S9S, can override original value and show expected result
using "dmidecode -t 1".

Signed-off-by: Tim Chu <Tim.Chu@quantatw.com>
Change-Id: If79ba65426f1f18ebb55a0f3ef022bee83c1a93b
Reviewed-on: https://review.coreboot.org/c/coreboot/+/58436
Tested-by: build bot (Jenkins) <no-reply@coreboot.org>
Reviewed-by: Angel Pons <th3fanbus@gmail.com>
Reviewed-by: Jonathan Zhang <jonzhang@fb.com>
2021-10-21 20:06:59 +00:00

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/* SPDX-License-Identifier: GPL-2.0-only */
#include <assert.h>
#include <string.h>
#include <smbios.h>
#include <console/console.h>
#include <version.h>
#include <device/device.h>
#include <device/dram/spd.h>
#include <arch/cpu.h>
#include <cpu/x86/name.h>
#include <elog.h>
#include <endian.h>
#include <memory_info.h>
#include <spd.h>
#include <cbmem.h>
#include <commonlib/helpers.h>
#include <device/pci_ids.h>
#include <device/pci_def.h>
#include <device/pci.h>
#include <drivers/vpd/vpd.h>
#include <stdlib.h>
#define update_max(len, max_len, stmt) \
do { \
int tmp = stmt; \
\
max_len = MAX(max_len, tmp); \
len += tmp; \
} while (0)
static u8 smbios_checksum(u8 *p, u32 length)
{
u8 ret = 0;
while (length--)
ret += *p++;
return -ret;
}
int smbios_add_string(u8 *start, const char *str)
{
int i = 1;
char *p = (char *)start;
/*
* Return 0 as required for empty strings.
* See Section 6.1.3 "Text Strings" of the SMBIOS specification.
*/
if (*str == '\0')
return 0;
for (;;) {
if (!*p) {
strcpy(p, str);
p += strlen(str);
*p++ = '\0';
*p++ = '\0';
return i;
}
if (!strcmp(p, str))
return i;
p += strlen(p)+1;
i++;
}
}
int smbios_string_table_len(u8 *start)
{
char *p = (char *)start;
int i, len = 0;
while (*p) {
i = strlen(p) + 1;
p += i;
len += i;
}
if (!len)
return 2;
return len + 1;
}
int smbios_full_table_len(struct smbios_header *header, u8 *str_table_start)
{
return header->length + smbios_string_table_len(str_table_start);
}
void *smbios_carve_table(unsigned long start, u8 type, u8 length, u16 handle)
{
struct smbios_header *t = (struct smbios_header *)start;
assert(length >= sizeof(*t));
memset(t, 0, length);
t->type = type;
t->length = length - 2;
t->handle = handle;
return t;
}
static int smbios_cpu_vendor(u8 *start)
{
if (cpu_have_cpuid()) {
u32 tmp[4];
const struct cpuid_result res = cpuid(0);
tmp[0] = res.ebx;
tmp[1] = res.edx;
tmp[2] = res.ecx;
tmp[3] = 0;
return smbios_add_string(start, (const char *)tmp);
} else {
return smbios_add_string(start, "Unknown");
}
}
static int smbios_processor_name(u8 *start)
{
u32 tmp[13];
const char *str = "Unknown Processor Name";
if (cpu_have_cpuid()) {
int i;
struct cpuid_result res = cpuid(0x80000000);
if (res.eax >= 0x80000004) {
int j = 0;
for (i = 0; i < 3; i++) {
res = cpuid(0x80000002 + i);
tmp[j++] = res.eax;
tmp[j++] = res.ebx;
tmp[j++] = res.ecx;
tmp[j++] = res.edx;
}
tmp[12] = 0;
str = (const char *)tmp;
}
}
return smbios_add_string(start, str);
}
/* this function will fill the corresponding manufacturer */
void smbios_fill_dimm_manufacturer_from_id(uint16_t mod_id, struct smbios_type17 *t)
{
const char *const manufacturer = spd_manufacturer_name(mod_id);
if (manufacturer) {
t->manufacturer = smbios_add_string(t->eos, manufacturer);
} else {
char string_buffer[256];
snprintf(string_buffer, sizeof(string_buffer), "Unknown (%x)", mod_id);
t->manufacturer = smbios_add_string(t->eos, string_buffer);
}
}
static void trim_trailing_whitespace(char *buffer, size_t buffer_size)
{
size_t len = strnlen(buffer, buffer_size);
if (len == 0)
return;
for (char *p = buffer + len - 1; p >= buffer; --p) {
if (*p == ' ')
*p = 0;
else
break;
}
}
/** This function will fill the corresponding part number */
static void smbios_fill_dimm_part_number(const char *part_number, struct smbios_type17 *t)
{
int invalid;
size_t i, len;
char trimmed_part_number[DIMM_INFO_PART_NUMBER_SIZE];
strncpy(trimmed_part_number, part_number, sizeof(trimmed_part_number));
trimmed_part_number[sizeof(trimmed_part_number) - 1] = '\0';
/*
* SPD mandates that unused characters be represented with a ' '.
* We don't want to publish the whitespace in the SMBIOS tables.
*/
trim_trailing_whitespace(trimmed_part_number, sizeof(trimmed_part_number));
len = strlen(trimmed_part_number);
invalid = 0; /* assume valid */
for (i = 0; i < len; i++) {
if (trimmed_part_number[i] < ' ') {
invalid = 1;
trimmed_part_number[i] = '*';
}
}
if (len == 0) {
/* Null String in Part Number will have "None" instead. */
t->part_number = smbios_add_string(t->eos, "None");
} else if (invalid) {
char string_buffer[sizeof(trimmed_part_number) + 10];
snprintf(string_buffer, sizeof(string_buffer), "Invalid (%s)",
trimmed_part_number);
t->part_number = smbios_add_string(t->eos, string_buffer);
} else {
t->part_number = smbios_add_string(t->eos, trimmed_part_number);
}
}
/* Encodes the SPD serial number into hex */
static void smbios_fill_dimm_serial_number(const struct dimm_info *dimm,
struct smbios_type17 *t)
{
char serial[9];
snprintf(serial, sizeof(serial), "%02hhx%02hhx%02hhx%02hhx",
dimm->serial[0], dimm->serial[1], dimm->serial[2], dimm->serial[3]);
t->serial_number = smbios_add_string(t->eos, serial);
}
static int create_smbios_type17_for_dimm(struct dimm_info *dimm,
unsigned long *current, int *handle,
int type16_handle)
{
struct smbios_type17 *t = smbios_carve_table(*current, SMBIOS_MEMORY_DEVICE,
sizeof(*t), *handle);
t->memory_type = dimm->ddr_type;
if (dimm->configured_speed_mts != 0)
t->clock_speed = dimm->configured_speed_mts;
else
t->clock_speed = dimm->ddr_frequency;
if (dimm->max_speed_mts != 0)
t->speed = dimm->max_speed_mts;
else
t->speed = dimm->ddr_frequency;
if (dimm->dimm_size < 0x7fff) {
t->size = dimm->dimm_size;
} else {
t->size = 0x7fff;
t->extended_size = dimm->dimm_size & 0x7fffffff;
}
t->data_width = 8 * (1 << (dimm->bus_width & 0x7));
t->total_width = t->data_width + 8 * ((dimm->bus_width & 0x18) >> 3);
switch (dimm->mod_type) {
case SPD_RDIMM:
case SPD_MINI_RDIMM:
t->form_factor = MEMORY_FORMFACTOR_RIMM;
break;
case SPD_UDIMM:
case SPD_MICRO_DIMM:
case SPD_MINI_UDIMM:
t->form_factor = MEMORY_FORMFACTOR_DIMM;
break;
case SPD_SODIMM:
t->form_factor = MEMORY_FORMFACTOR_SODIMM;
break;
default:
t->form_factor = MEMORY_FORMFACTOR_UNKNOWN;
break;
}
smbios_fill_dimm_manufacturer_from_id(dimm->mod_id, t);
smbios_fill_dimm_serial_number(dimm, t);
smbios_fill_dimm_asset_tag(dimm, t);
smbios_fill_dimm_locator(dimm, t);
/* put '\0' in the end of data */
dimm->module_part_number[DIMM_INFO_PART_NUMBER_SIZE - 1] = '\0';
smbios_fill_dimm_part_number((char *)dimm->module_part_number, t);
/* Voltage Levels */
t->configured_voltage = dimm->vdd_voltage;
t->minimum_voltage = dimm->vdd_voltage;
t->maximum_voltage = dimm->vdd_voltage;
/* Fill in type detail */
switch (dimm->mod_type) {
case SPD_RDIMM:
case SPD_MINI_RDIMM:
t->type_detail = MEMORY_TYPE_DETAIL_REGISTERED;
break;
case SPD_UDIMM:
case SPD_MINI_UDIMM:
t->type_detail = MEMORY_TYPE_DETAIL_UNBUFFERED;
break;
default:
t->type_detail = MEMORY_TYPE_DETAIL_UNKNOWN;
break;
}
/* Synchronous = 1 */
t->type_detail |= MEMORY_TYPE_DETAIL_SYNCHRONOUS;
/* no handle for error information */
t->memory_error_information_handle = 0xFFFE;
t->attributes = dimm->rank_per_dimm;
t->phys_memory_array_handle = type16_handle;
*handle += 1;
return smbios_full_table_len(&t->header, t->eos);
}
#define VERSION_VPD "firmware_version"
static const char *vpd_get_bios_version(void)
{
int size;
const char *s;
char *version;
s = vpd_find(VERSION_VPD, &size, VPD_RO);
if (!s) {
printk(BIOS_ERR, "Find version from VPD %s failed\n", VERSION_VPD);
return NULL;
}
version = malloc(size + 1);
if (!version) {
printk(BIOS_ERR, "Failed to malloc %d bytes for VPD version\n", size + 1);
return NULL;
}
memcpy(version, s, size);
version[size] = '\0';
printk(BIOS_DEBUG, "Firmware version %s from VPD %s\n", version, VERSION_VPD);
return version;
}
static const char *get_bios_version(void)
{
const char *s;
#define SPACES \
" "
if (CONFIG(CHROMEOS))
return SPACES;
if (CONFIG(VPD_SMBIOS_VERSION)) {
s = vpd_get_bios_version();
if (s != NULL)
return s;
}
s = smbios_mainboard_bios_version();
if (s != NULL)
return s;
if (strlen(CONFIG_LOCALVERSION) != 0) {
printk(BIOS_DEBUG, "BIOS version set to CONFIG_LOCALVERSION: '%s'\n",
CONFIG_LOCALVERSION);
return CONFIG_LOCALVERSION;
}
printk(BIOS_DEBUG, "SMBIOS firmware version is set to coreboot_version: '%s'\n",
coreboot_version);
return coreboot_version;
}
static int smbios_write_type0(unsigned long *current, int handle)
{
struct smbios_type0 *t = smbios_carve_table(*current, SMBIOS_BIOS_INFORMATION,
sizeof(*t), handle);
t->vendor = smbios_add_string(t->eos, "coreboot");
t->bios_release_date = smbios_add_string(t->eos, coreboot_dmi_date);
if (CONFIG(CHROMEOS_NVS)) {
uintptr_t version_address = (uintptr_t)t->eos;
/* SMBIOS offsets start at 1 rather than 0 */
version_address += (u32)smbios_string_table_len(t->eos) - 1;
smbios_type0_bios_version(version_address);
}
t->bios_version = smbios_add_string(t->eos, get_bios_version());
uint32_t rom_size = CONFIG_ROM_SIZE;
rom_size = MIN(CONFIG_ROM_SIZE, 16 * MiB);
t->bios_rom_size = (rom_size / 65535) - 1;
if (CONFIG_ROM_SIZE >= 1 * GiB) {
t->extended_bios_rom_size = DIV_ROUND_UP(CONFIG_ROM_SIZE, GiB) | (1 << 14);
} else {
t->extended_bios_rom_size = DIV_ROUND_UP(CONFIG_ROM_SIZE, MiB);
}
t->system_bios_major_release = coreboot_major_revision;
t->system_bios_minor_release = coreboot_minor_revision;
smbios_ec_revision(&t->ec_major_release, &t->ec_minor_release);
t->bios_characteristics =
BIOS_CHARACTERISTICS_PCI_SUPPORTED |
BIOS_CHARACTERISTICS_SELECTABLE_BOOT |
BIOS_CHARACTERISTICS_UPGRADEABLE;
if (CONFIG(CARDBUS_PLUGIN_SUPPORT))
t->bios_characteristics |= BIOS_CHARACTERISTICS_PC_CARD;
if (CONFIG(HAVE_ACPI_TABLES))
t->bios_characteristics_ext1 = BIOS_EXT1_CHARACTERISTICS_ACPI;
t->bios_characteristics_ext2 = BIOS_EXT2_CHARACTERISTICS_TARGET;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
return len;
}
static int get_socket_type(void)
{
if (CONFIG(CPU_INTEL_SLOT_1))
return 0x08;
if (CONFIG(CPU_INTEL_SOCKET_MPGA604))
return 0x13;
if (CONFIG(CPU_INTEL_SOCKET_LGA775))
return 0x15;
if (CONFIG(XEON_SP_COMMON_BASE))
return 0x36;
return 0x02; /* Unknown */
}
unsigned int __weak smbios_processor_external_clock(void)
{
return 0; /* Unknown */
}
unsigned int __weak smbios_processor_characteristics(void)
{
return 0;
}
unsigned int __weak smbios_processor_family(struct cpuid_result res)
{
return (res.eax > 0) ? 0x0c : 0x6;
}
unsigned int __weak smbios_cache_error_correction_type(u8 level)
{
return SMBIOS_CACHE_ERROR_CORRECTION_UNKNOWN;
}
unsigned int __weak smbios_cache_sram_type(void)
{
return SMBIOS_CACHE_SRAM_TYPE_UNKNOWN;
}
unsigned int __weak smbios_cache_conf_operation_mode(u8 level)
{
return SMBIOS_CACHE_OP_MODE_UNKNOWN; /* Unknown */
}
/* Returns the processor voltage in 100mV units */
unsigned int __weak smbios_cpu_get_voltage(void)
{
return 0; /* Unknown */
}
static size_t get_number_of_caches(size_t max_logical_cpus_sharing_cache)
{
size_t number_of_cpus_per_package = 0;
size_t max_logical_cpus_per_package = 0;
struct cpuid_result res;
if (!cpu_have_cpuid())
return 1;
res = cpuid(1);
max_logical_cpus_per_package = (res.ebx >> 16) & 0xff;
/* Check if it's last level cache */
if (max_logical_cpus_sharing_cache == max_logical_cpus_per_package)
return 1;
if (cpuid_get_max_func() >= 0xb) {
res = cpuid_ext(0xb, 1);
number_of_cpus_per_package = res.ebx & 0xff;
} else {
number_of_cpus_per_package = max_logical_cpus_per_package;
}
return number_of_cpus_per_package / max_logical_cpus_sharing_cache;
}
static int smbios_write_type1(unsigned long *current, int handle)
{
struct smbios_type1 *t = smbios_carve_table(*current, SMBIOS_SYSTEM_INFORMATION,
sizeof(*t), handle);
t->manufacturer = smbios_add_string(t->eos, smbios_system_manufacturer());
t->product_name = smbios_add_string(t->eos, smbios_system_product_name());
t->serial_number = smbios_add_string(t->eos, smbios_system_serial_number());
t->wakeup_type = smbios_system_wakeup_type();
t->sku = smbios_add_string(t->eos, smbios_system_sku());
t->version = smbios_add_string(t->eos, smbios_system_version());
#ifdef CONFIG_MAINBOARD_FAMILY
t->family = smbios_add_string(t->eos, CONFIG_MAINBOARD_FAMILY);
#endif
smbios_system_set_uuid(t->uuid);
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
return len;
}
static int smbios_write_type2(unsigned long *current, int handle, const int chassis_handle)
{
struct smbios_type2 *t = smbios_carve_table(*current, SMBIOS_BOARD_INFORMATION,
sizeof(*t), handle);
t->manufacturer = smbios_add_string(t->eos, smbios_mainboard_manufacturer());
t->product_name = smbios_add_string(t->eos, smbios_mainboard_product_name());
t->serial_number = smbios_add_string(t->eos, smbios_mainboard_serial_number());
t->version = smbios_add_string(t->eos, smbios_mainboard_version());
t->asset_tag = smbios_add_string(t->eos, smbios_mainboard_asset_tag());
t->feature_flags = smbios_mainboard_feature_flags();
t->location_in_chassis = smbios_add_string(t->eos,
smbios_mainboard_location_in_chassis());
t->board_type = smbios_mainboard_board_type();
t->chassis_handle = chassis_handle;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
return len;
}
static int smbios_write_type3(unsigned long *current, int handle)
{
struct smbios_type3 *t = smbios_carve_table(*current, SMBIOS_SYSTEM_ENCLOSURE,
sizeof(*t), handle);
t->manufacturer = smbios_add_string(t->eos, smbios_system_manufacturer());
t->bootup_state = SMBIOS_STATE_SAFE;
t->power_supply_state = SMBIOS_STATE_SAFE;
t->thermal_state = SMBIOS_STATE_SAFE;
t->_type = smbios_mainboard_enclosure_type();
t->security_status = SMBIOS_STATE_SAFE;
t->number_of_power_cords = smbios_chassis_power_cords();
t->asset_tag_number = smbios_add_string(t->eos, smbios_mainboard_asset_tag());
t->version = smbios_add_string(t->eos, smbios_chassis_version());
t->serial_number = smbios_add_string(t->eos, smbios_chassis_serial_number());
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
return len;
}
static int smbios_write_type4(unsigned long *current, int handle)
{
unsigned int cpu_voltage;
struct cpuid_result res;
uint16_t characteristics = 0;
static unsigned int cnt = 0;
char buf[8];
/* Provide sane defaults even for CPU without CPUID */
res.eax = res.edx = 0;
res.ebx = 0x10000;
if (cpu_have_cpuid())
res = cpuid(1);
struct smbios_type4 *t = smbios_carve_table(*current, SMBIOS_PROCESSOR_INFORMATION,
sizeof(*t), handle);
snprintf(buf, sizeof(buf), "CPU%d", cnt++);
t->socket_designation = smbios_add_string(t->eos, buf);
t->processor_id[0] = res.eax;
t->processor_id[1] = res.edx;
t->processor_manufacturer = smbios_cpu_vendor(t->eos);
t->processor_version = smbios_processor_name(t->eos);
t->processor_family = smbios_processor_family(res);
t->processor_type = 3; /* System Processor */
/*
* If CPUID leaf 11 is available, calculate "core count" by dividing
* SMT_ID (logical processors in a core) by Core_ID (number of cores).
* This seems to be the way to arrive to a number of cores mentioned on
* ark.intel.com.
*/
if (cpu_have_cpuid() && cpuid_get_max_func() >= 0xb) {
uint32_t leaf_b_cores = 0, leaf_b_threads = 0;
res = cpuid_ext(0xb, 1);
leaf_b_cores = res.ebx;
res = cpuid_ext(0xb, 0);
leaf_b_threads = res.ebx;
/* if hyperthreading is not available, pretend this is 1 */
if (leaf_b_threads == 0) {
leaf_b_threads = 1;
}
t->core_count2 = leaf_b_cores / leaf_b_threads;
t->core_count = t->core_count2 > 0xff ? 0xff : t->core_count2;
t->thread_count2 = leaf_b_cores;
t->thread_count = t->thread_count2 > 0xff ? 0xff : t->thread_count2;
} else {
t->core_count = (res.ebx >> 16) & 0xff;
t->core_count2 = t->core_count;
t->thread_count2 = t->core_count2;
t->thread_count = t->thread_count2;
}
/* Assume we enable all the cores always, capped only by MAX_CPUS */
t->core_enabled = MIN(t->core_count, CONFIG_MAX_CPUS);
t->core_enabled2 = MIN(t->core_count2, CONFIG_MAX_CPUS);
t->l1_cache_handle = 0xffff;
t->l2_cache_handle = 0xffff;
t->l3_cache_handle = 0xffff;
t->serial_number = smbios_add_string(t->eos, smbios_processor_serial_number());
t->status = SMBIOS_PROCESSOR_STATUS_CPU_ENABLED | SMBIOS_PROCESSOR_STATUS_POPULATED;
t->processor_upgrade = get_socket_type();
if (cpu_have_cpuid() && cpuid_get_max_func() >= 0x16) {
t->current_speed = cpuid_eax(0x16); /* base frequency */
t->external_clock = cpuid_ecx(0x16);
} else {
t->current_speed = smbios_cpu_get_current_speed_mhz();
t->external_clock = smbios_processor_external_clock();
}
/* This field identifies a capability for the system, not the processor itself. */
t->max_speed = smbios_cpu_get_max_speed_mhz();
if (cpu_have_cpuid()) {
res = cpuid(1);
if ((res.ecx) & BIT(5))
characteristics |= BIT(6); /* BIT6: Enhanced Virtualization */
if ((res.edx) & BIT(28))
characteristics |= BIT(4); /* BIT4: Hardware Thread */
if (((cpuid_eax(0x80000000) - 0x80000000) + 1) > 2) {
res = cpuid(0x80000001);
if ((res.edx) & BIT(20))
characteristics |= BIT(5); /* BIT5: Execute Protection */
}
}
t->processor_characteristics = characteristics | smbios_processor_characteristics();
cpu_voltage = smbios_cpu_get_voltage();
if (cpu_voltage > 0)
t->voltage = 0x80 | cpu_voltage;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
return len;
}
/*
* Write SMBIOS type 7.
* Fill in some fields with constant values, as gathering the information
* from CPUID is impossible.
*/
static int smbios_write_type7(unsigned long *current,
const int handle,
const u8 level,
const u8 sram_type,
const enum smbios_cache_associativity associativity,
const enum smbios_cache_type type,
const size_t max_cache_size,
const size_t cache_size)
{
char buf[8];
struct smbios_type7 *t = smbios_carve_table(*current, SMBIOS_CACHE_INFORMATION,
sizeof(*t), handle);
snprintf(buf, sizeof(buf), "CACHE%x", level);
t->socket_designation = smbios_add_string(t->eos, buf);
t->cache_configuration = SMBIOS_CACHE_CONF_LEVEL(level) |
SMBIOS_CACHE_CONF_LOCATION(0) | /* Internal */
SMBIOS_CACHE_CONF_ENABLED(1) | /* Enabled */
SMBIOS_CACHE_CONF_OPERATION_MODE(smbios_cache_conf_operation_mode(level));
if (max_cache_size < (SMBIOS_CACHE_SIZE_MASK * KiB)) {
t->max_cache_size = max_cache_size / KiB;
t->max_cache_size2 = t->max_cache_size;
t->max_cache_size |= SMBIOS_CACHE_SIZE_UNIT_1KB;
t->max_cache_size2 |= SMBIOS_CACHE_SIZE2_UNIT_1KB;
} else {
if (max_cache_size < (SMBIOS_CACHE_SIZE_MASK * 64 * KiB))
t->max_cache_size = max_cache_size / (64 * KiB);
else
t->max_cache_size = SMBIOS_CACHE_SIZE_OVERFLOW;
t->max_cache_size2 = max_cache_size / (64 * KiB);
t->max_cache_size |= SMBIOS_CACHE_SIZE_UNIT_64KB;
t->max_cache_size2 |= SMBIOS_CACHE_SIZE2_UNIT_64KB;
}
if (cache_size < (SMBIOS_CACHE_SIZE_MASK * KiB)) {
t->installed_size = cache_size / KiB;
t->installed_size2 = t->installed_size;
t->installed_size |= SMBIOS_CACHE_SIZE_UNIT_1KB;
t->installed_size2 |= SMBIOS_CACHE_SIZE2_UNIT_1KB;
} else {
if (cache_size < (SMBIOS_CACHE_SIZE_MASK * 64 * KiB))
t->installed_size = cache_size / (64 * KiB);
else
t->installed_size = SMBIOS_CACHE_SIZE_OVERFLOW;
t->installed_size2 = cache_size / (64 * KiB);
t->installed_size |= SMBIOS_CACHE_SIZE_UNIT_64KB;
t->installed_size2 |= SMBIOS_CACHE_SIZE2_UNIT_64KB;
}
t->associativity = associativity;
t->supported_sram_type = sram_type;
t->current_sram_type = sram_type;
t->cache_speed = 0; /* Unknown */
t->error_correction_type = smbios_cache_error_correction_type(level);
t->system_cache_type = type;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
return len;
}
/* Convert the associativity as integer to the SMBIOS enum if available */
static enum smbios_cache_associativity smbios_cache_associativity(const u8 num)
{
switch (num) {
case 1:
return SMBIOS_CACHE_ASSOCIATIVITY_DIRECT;
case 2:
return SMBIOS_CACHE_ASSOCIATIVITY_2WAY;
case 4:
return SMBIOS_CACHE_ASSOCIATIVITY_4WAY;
case 8:
return SMBIOS_CACHE_ASSOCIATIVITY_8WAY;
case 12:
return SMBIOS_CACHE_ASSOCIATIVITY_12WAY;
case 16:
return SMBIOS_CACHE_ASSOCIATIVITY_16WAY;
case 20:
return SMBIOS_CACHE_ASSOCIATIVITY_20WAY;
case 24:
return SMBIOS_CACHE_ASSOCIATIVITY_24WAY;
case 32:
return SMBIOS_CACHE_ASSOCIATIVITY_32WAY;
case 48:
return SMBIOS_CACHE_ASSOCIATIVITY_48WAY;
case 64:
return SMBIOS_CACHE_ASSOCIATIVITY_64WAY;
case 0xff:
return SMBIOS_CACHE_ASSOCIATIVITY_FULL;
default:
return SMBIOS_CACHE_ASSOCIATIVITY_UNKNOWN;
};
}
/*
* Parse the "Deterministic Cache Parameters" as provided by Intel in
* leaf 4 or AMD in extended leaf 0x8000001d.
*
* @param current Pointer to memory address to write the tables to
* @param handle Pointer to handle for the tables
* @param max_struct_size Pointer to maximum struct size
* @param type4 Pointer to SMBIOS type 4 structure
*/
static int smbios_write_type7_cache_parameters(unsigned long *current,
int *handle,
int *max_struct_size,
struct smbios_type4 *type4)
{
unsigned int cnt = CACHE_L1D;
int len = 0;
if (!cpu_have_cpuid())
return len;
enum cpu_type dcache_cpuid = cpu_check_deterministic_cache_cpuid_supported();
if (dcache_cpuid == CPUID_TYPE_INVALID || dcache_cpuid == CPUID_COMMAND_UNSUPPORTED) {
printk(BIOS_DEBUG, "SMBIOS: Unknown CPU or CPU doesn't support Deterministic "
"Cache CPUID leaf\n");
return len;
}
while (1) {
enum smbios_cache_associativity associativity;
enum smbios_cache_type type;
struct cpu_cache_info info;
if (!fill_cpu_cache_info(cnt++, &info))
continue;
const u8 cache_type = info.type;
const u8 level = info.level;
const size_t assoc = info.num_ways;
const size_t cache_share = info.num_cores_shared;
const size_t cache_size = info.size * get_number_of_caches(cache_share);
if (!cache_type)
/* No more caches in the system */
break;
switch (cache_type) {
case 1:
type = SMBIOS_CACHE_TYPE_DATA;
break;
case 2:
type = SMBIOS_CACHE_TYPE_INSTRUCTION;
break;
case 3:
type = SMBIOS_CACHE_TYPE_UNIFIED;
break;
default:
type = SMBIOS_CACHE_TYPE_UNKNOWN;
break;
}
if (info.fully_associative)
associativity = SMBIOS_CACHE_ASSOCIATIVITY_FULL;
else
associativity = smbios_cache_associativity(assoc);
const int h = (*handle)++;
update_max(len, *max_struct_size, smbios_write_type7(current, h,
level, smbios_cache_sram_type(), associativity,
type, cache_size, cache_size));
if (type4) {
switch (level) {
case 1:
type4->l1_cache_handle = h;
break;
case 2:
type4->l2_cache_handle = h;
break;
case 3:
type4->l3_cache_handle = h;
break;
}
}
};
return len;
}
int smbios_write_type8(unsigned long *current, int *handle,
const struct port_information *port,
size_t num_ports)
{
unsigned int totallen = 0, i;
for (i = 0; i < num_ports; i++, port++) {
struct smbios_type8 *t = smbios_carve_table(*current,
SMBIOS_PORT_CONNECTOR_INFORMATION,
sizeof(*t), *handle);
t->internal_reference_designator =
smbios_add_string(t->eos, port->internal_reference_designator);
t->internal_connector_type = port->internal_connector_type;
t->external_reference_designator =
smbios_add_string(t->eos, port->external_reference_designator);
t->external_connector_type = port->external_connector_type;
t->port_type = port->port_type;
*handle += 1;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
totallen += len;
}
return totallen;
}
int smbios_write_type9(unsigned long *current, int *handle,
const char *name, const enum misc_slot_type type,
const enum slot_data_bus_bandwidth bandwidth,
const enum misc_slot_usage usage,
const enum misc_slot_length length,
const u16 id, u8 slot_char1, u8 slot_char2, u8 bus, u8 dev_func)
{
struct smbios_type9 *t = smbios_carve_table(*current, SMBIOS_SYSTEM_SLOTS,
sizeof(*t), *handle);
t->slot_designation = smbios_add_string(t->eos, name ? name : "SLOT");
t->slot_type = type;
/* TODO add slot_id supoort, will be "_SUN" for ACPI devices */
t->slot_id = id;
t->slot_data_bus_width = bandwidth;
t->current_usage = usage;
t->slot_length = length;
t->slot_characteristics_1 = slot_char1;
t->slot_characteristics_2 = slot_char2;
t->segment_group_number = 0;
t->bus_number = bus;
t->device_function_number = dev_func;
t->data_bus_width = SlotDataBusWidthOther;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
*handle += 1;
return len;
}
static int smbios_write_type11(unsigned long *current, int *handle)
{
struct device *dev;
struct smbios_type11 *t = smbios_carve_table(*current, SMBIOS_OEM_STRINGS,
sizeof(*t), *handle);
for (dev = all_devices; dev; dev = dev->next) {
if (dev->ops && dev->ops->get_smbios_strings)
dev->ops->get_smbios_strings(dev, t);
}
if (t->count == 0) {
memset(t, 0, sizeof(*t));
return 0;
}
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
(*handle)++;
return len;
}
static int smbios_write_type16(unsigned long *current, int *handle)
{
int i;
uint64_t max_capacity;
struct memory_info *meminfo;
meminfo = cbmem_find(CBMEM_ID_MEMINFO);
if (meminfo == NULL)
return 0; /* can't find mem info in cbmem */
printk(BIOS_INFO, "Create SMBIOS type 16\n");
if (meminfo->max_capacity_mib == 0 || meminfo->number_of_devices == 0) {
/* Fill in defaults if not provided */
meminfo->number_of_devices = 0;
meminfo->max_capacity_mib = 0;
for (i = 0; i < meminfo->dimm_cnt && i < ARRAY_SIZE(meminfo->dimm); i++) {
meminfo->max_capacity_mib += meminfo->dimm[i].dimm_size;
meminfo->number_of_devices += !!meminfo->dimm[i].dimm_size;
}
}
struct smbios_type16 *t = smbios_carve_table(*current, SMBIOS_PHYS_MEMORY_ARRAY,
sizeof(*t), *handle);
t->location = MEMORY_ARRAY_LOCATION_SYSTEM_BOARD;
t->use = MEMORY_ARRAY_USE_SYSTEM;
t->memory_error_correction = meminfo->ecc_type;
/* no error information handle available */
t->memory_error_information_handle = 0xFFFE;
max_capacity = meminfo->max_capacity_mib;
if (max_capacity * (MiB / KiB) < SMBIOS_USE_EXTENDED_MAX_CAPACITY)
t->maximum_capacity = max_capacity * (MiB / KiB);
else {
t->maximum_capacity = SMBIOS_USE_EXTENDED_MAX_CAPACITY;
t->extended_maximum_capacity = max_capacity * MiB;
}
t->number_of_memory_devices = meminfo->number_of_devices;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
(*handle)++;
return len;
}
static int smbios_write_type17(unsigned long *current, int *handle, int type16)
{
int totallen = 0;
int i;
struct memory_info *meminfo;
meminfo = cbmem_find(CBMEM_ID_MEMINFO);
if (meminfo == NULL)
return 0; /* can't find mem info in cbmem */
printk(BIOS_INFO, "Create SMBIOS type 17\n");
for (i = 0; i < meminfo->dimm_cnt && i < ARRAY_SIZE(meminfo->dimm); i++) {
struct dimm_info *dimm;
dimm = &meminfo->dimm[i];
/*
* Windows 10 GetPhysicallyInstalledSystemMemory functions reads SMBIOS tables
* type 16 and type 17. The type 17 tables need to point to a type 16 table.
* Otherwise, the physical installed memory size is guessed from the system
* memory map, which results in a slightly smaller value than the actual size.
*/
const int len = create_smbios_type17_for_dimm(dimm, current, handle, type16);
*current += len;
totallen += len;
}
return totallen;
}
static int smbios_write_type19(unsigned long *current, int *handle, int type16)
{
int i;
struct memory_info *meminfo;
meminfo = cbmem_find(CBMEM_ID_MEMINFO);
if (meminfo == NULL)
return 0; /* can't find mem info in cbmem */
struct smbios_type19 *t = smbios_carve_table(*current,
SMBIOS_MEMORY_ARRAY_MAPPED_ADDRESS,
sizeof(*t), *handle);
t->memory_array_handle = type16;
for (i = 0; i < meminfo->dimm_cnt && i < ARRAY_SIZE(meminfo->dimm); i++) {
if (meminfo->dimm[i].dimm_size > 0) {
t->extended_ending_address += meminfo->dimm[i].dimm_size;
t->partition_width++;
}
}
t->extended_ending_address *= MiB;
/* Check if it fits into regular address */
if (t->extended_ending_address >= KiB &&
t->extended_ending_address < 0x40000000000ULL) {
/*
* FIXME: The starting address is SoC specific, but SMBIOS tables are only
* exported on x86 where it's always 0.
*/
t->starting_address = 0;
t->ending_address = t->extended_ending_address / KiB - 1;
t->extended_starting_address = ~0;
t->extended_ending_address = ~0;
} else {
t->starting_address = ~0;
t->ending_address = ~0;
t->extended_starting_address = 0;
t->extended_ending_address--;
}
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
*handle += 1;
return len;
}
static int smbios_write_type20_table(unsigned long *current, int *handle, u32 addr_start,
u32 addr_end, int type17_handle, int type19_handle)
{
struct smbios_type20 *t = smbios_carve_table(*current, SMBIOS_MEMORY_DEVICE_MAPPED_ADDRESS,
sizeof(*t), *handle);
t->memory_device_handle = type17_handle;
t->memory_array_mapped_address_handle = type19_handle;
t->addr_start = addr_start;
t->addr_end = addr_end;
t->partition_row_pos = 0xff;
t->interleave_pos = 0xff;
t->interleave_depth = 0xff;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
*handle += 1;
return len;
}
static int smbios_write_type20(unsigned long *current, int *handle,
int type17_handle, int type19_handle)
{
u32 start_addr = 0;
int totallen = 0;
int i;
struct memory_info *meminfo;
meminfo = cbmem_find(CBMEM_ID_MEMINFO);
if (meminfo == NULL)
return 0; /* can't find mem info in cbmem */
printk(BIOS_INFO, "Create SMBIOS type 20\n");
for (i = 0; i < meminfo->dimm_cnt && i < ARRAY_SIZE(meminfo->dimm); i++) {
struct dimm_info *dimm;
dimm = &meminfo->dimm[i];
u32 end_addr = start_addr + (dimm->dimm_size << 10) - 1;
totallen += smbios_write_type20_table(current, handle, start_addr, end_addr,
type17_handle, type19_handle);
start_addr = end_addr + 1;
}
return totallen;
}
static int smbios_write_type32(unsigned long *current, int handle)
{
struct smbios_type32 *t = smbios_carve_table(*current, SMBIOS_SYSTEM_BOOT_INFORMATION,
sizeof(*t), handle);
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
return len;
}
int smbios_write_type38(unsigned long *current, int *handle,
const enum smbios_bmc_interface_type interface_type,
const u8 ipmi_rev, const u8 i2c_addr, const u8 nv_addr,
const u64 base_addr, const u8 base_modifier,
const u8 irq)
{
struct smbios_type38 *t = smbios_carve_table(*current, SMBIOS_IPMI_DEVICE_INFORMATION,
sizeof(*t), *handle);
t->interface_type = interface_type;
t->ipmi_rev = ipmi_rev;
t->i2c_slave_addr = i2c_addr;
t->nv_storage_addr = nv_addr;
t->base_address = base_addr;
t->base_address_modifier = base_modifier;
t->irq = irq;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
*handle += 1;
return len;
}
int smbios_write_type41(unsigned long *current, int *handle,
const char *name, u8 instance, u16 segment,
u8 bus, u8 device, u8 function, u8 device_type)
{
struct smbios_type41 *t = smbios_carve_table(*current,
SMBIOS_ONBOARD_DEVICES_EXTENDED_INFORMATION,
sizeof(*t), *handle);
t->reference_designation = smbios_add_string(t->eos, name);
t->device_type = device_type;
t->device_status = 1;
t->device_type_instance = instance;
t->segment_group_number = segment;
t->bus_number = bus;
t->device_number = device;
t->function_number = function;
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
*handle += 1;
return len;
}
static int smbios_write_type127(unsigned long *current, int handle)
{
struct smbios_type127 *t = smbios_carve_table(*current, SMBIOS_END_OF_TABLE,
sizeof(*t), handle);
const int len = smbios_full_table_len(&t->header, t->eos);
*current += len;
return len;
}
/* Get the device type 41 from the dev struct */
static u8 smbios_get_device_type_from_dev(struct device *dev)
{
u16 pci_basesubclass = (dev->class >> 8) & 0xFFFF;
switch (pci_basesubclass) {
case PCI_CLASS_NOT_DEFINED:
return SMBIOS_DEVICE_TYPE_OTHER;
case PCI_CLASS_DISPLAY_VGA:
case PCI_CLASS_DISPLAY_XGA:
case PCI_CLASS_DISPLAY_3D:
case PCI_CLASS_DISPLAY_OTHER:
return SMBIOS_DEVICE_TYPE_VIDEO;
case PCI_CLASS_STORAGE_SCSI:
return SMBIOS_DEVICE_TYPE_SCSI;
case PCI_CLASS_NETWORK_ETHERNET:
return SMBIOS_DEVICE_TYPE_ETHERNET;
case PCI_CLASS_NETWORK_TOKEN_RING:
return SMBIOS_DEVICE_TYPE_TOKEN_RING;
case PCI_CLASS_MULTIMEDIA_VIDEO:
case PCI_CLASS_MULTIMEDIA_AUDIO:
case PCI_CLASS_MULTIMEDIA_PHONE:
case PCI_CLASS_MULTIMEDIA_OTHER:
return SMBIOS_DEVICE_TYPE_SOUND;
case PCI_CLASS_STORAGE_ATA:
return SMBIOS_DEVICE_TYPE_PATA;
case PCI_CLASS_STORAGE_SATA:
return SMBIOS_DEVICE_TYPE_SATA;
case PCI_CLASS_STORAGE_SAS:
return SMBIOS_DEVICE_TYPE_SAS;
default:
return SMBIOS_DEVICE_TYPE_UNKNOWN;
}
}
static int smbios_generate_type41_from_devtree(struct device *dev, int *handle,
unsigned long *current)
{
static u8 type41_inst_cnt[SMBIOS_DEVICE_TYPE_COUNT + 1] = {};
if (dev->path.type != DEVICE_PATH_PCI)
return 0;
if (!dev->on_mainboard)
return 0;
u8 device_type = smbios_get_device_type_from_dev(dev);
if (device_type == SMBIOS_DEVICE_TYPE_OTHER ||
device_type == SMBIOS_DEVICE_TYPE_UNKNOWN)
return 0;
if (device_type > SMBIOS_DEVICE_TYPE_COUNT)
return 0;
const char *name = get_pci_subclass_name(dev);
return smbios_write_type41(current, handle,
name, // name
type41_inst_cnt[device_type]++, // inst
0, // segment
dev->bus->secondary, //bus
PCI_SLOT(dev->path.pci.devfn), // device
PCI_FUNC(dev->path.pci.devfn), // func
device_type);
}
static int smbios_generate_type9_from_devtree(struct device *dev, int *handle,
unsigned long *current)
{
enum misc_slot_usage usage;
enum slot_data_bus_bandwidth bandwidth;
enum misc_slot_type type;
enum misc_slot_length length;
if (dev->path.type != DEVICE_PATH_PCI)
return 0;
if (!dev->smbios_slot_type && !dev->smbios_slot_data_width &&
!dev->smbios_slot_designation && !dev->smbios_slot_length)
return 0;
if (dev_is_active_bridge(dev))
usage = SlotUsageInUse;
else if (dev->enabled)
usage = SlotUsageAvailable;
else
usage = SlotUsageUnknown;
if (dev->smbios_slot_data_width)
bandwidth = dev->smbios_slot_data_width;
else
bandwidth = SlotDataBusWidthUnknown;
if (dev->smbios_slot_type)
type = dev->smbios_slot_type;
else
type = SlotTypeUnknown;
if (dev->smbios_slot_length)
length = dev->smbios_slot_length;
else
length = SlotLengthUnknown;
return smbios_write_type9(current, handle,
dev->smbios_slot_designation,
type,
bandwidth,
usage,
length,
0,
1,
0,
dev->bus->secondary,
dev->path.pci.devfn);
}
int get_smbios_data(struct device *dev, int *handle, unsigned long *current)
{
int len = 0;
len += smbios_generate_type9_from_devtree(dev, handle, current);
len += smbios_generate_type41_from_devtree(dev, handle, current);
return len;
}
static int smbios_walk_device_tree(struct device *tree, int *handle, unsigned long *current)
{
struct device *dev;
int len = 0;
for (dev = tree; dev; dev = dev->next) {
if (!dev->enabled)
continue;
if (dev->ops && dev->ops->get_smbios_data) {
printk(BIOS_INFO, "%s (%s)\n", dev_path(dev), dev_name(dev));
len += dev->ops->get_smbios_data(dev, handle, current);
} else {
len += get_smbios_data(dev, handle, current);
}
}
return len;
}
unsigned long smbios_write_tables(unsigned long current)
{
struct smbios_entry *se;
struct smbios_entry30 *se3;
unsigned long tables;
int len = 0;
int max_struct_size = 0;
int handle = 0;
current = ALIGN_UP(current, 16);
printk(BIOS_DEBUG, "%s: %08lx\n", __func__, current);
se = (struct smbios_entry *)current;
current += sizeof(*se);
current = ALIGN_UP(current, 16);
se3 = (struct smbios_entry30 *)current;
current += sizeof(*se3);
current = ALIGN_UP(current, 16);
tables = current;
update_max(len, max_struct_size, smbios_write_type0(&current, handle++));
update_max(len, max_struct_size, smbios_write_type1(&current, handle++));
/* The chassis handle is the next one */
update_max(len, max_struct_size, smbios_write_type2(&current, handle, handle + 1));
handle++;
update_max(len, max_struct_size, smbios_write_type3(&current, handle++));
struct smbios_type4 *type4 = (struct smbios_type4 *)current;
update_max(len, max_struct_size, smbios_write_type4(&current, handle++));
len += smbios_write_type7_cache_parameters(&current, &handle, &max_struct_size, type4);
update_max(len, max_struct_size, smbios_write_type11(&current, &handle));
if (CONFIG(ELOG))
update_max(len, max_struct_size,
elog_smbios_write_type15(&current, handle++));
const int type16 = handle;
update_max(len, max_struct_size, smbios_write_type16(&current, &handle));
const int type17 = handle;
update_max(len, max_struct_size, smbios_write_type17(&current, &handle, type16));
const int type19 = handle;
update_max(len, max_struct_size, smbios_write_type19(&current, &handle, type16));
update_max(len, max_struct_size,
smbios_write_type20(&current, &handle, type17, type19));
update_max(len, max_struct_size, smbios_write_type32(&current, handle++));
update_max(len, max_struct_size, smbios_walk_device_tree(all_devices,
&handle, &current));
update_max(len, max_struct_size, smbios_write_type127(&current, handle++));
/* Install SMBIOS 2.1 entry point */
memset(se, 0, sizeof(*se));
memcpy(se->anchor, "_SM_", 4);
se->length = sizeof(*se);
se->major_version = 3;
se->minor_version = 0;
se->max_struct_size = max_struct_size;
se->struct_count = handle;
memcpy(se->intermediate_anchor_string, "_DMI_", 5);
se->struct_table_address = (u32)tables;
se->struct_table_length = len;
se->intermediate_checksum = smbios_checksum((u8 *)se + 0x10, sizeof(*se) - 0x10);
se->checksum = smbios_checksum((u8 *)se, sizeof(*se));
/* Install SMBIOS 3.0 entry point */
memset(se3, 0, sizeof(*se3));
memcpy(se3->anchor, "_SM3_", 5);
se3->length = sizeof(*se3);
se3->major_version = 3;
se3->minor_version = 0;
se3->struct_table_address = (u64)tables;
se3->struct_table_length = len;
se3->checksum = smbios_checksum((u8 *)se3, sizeof(*se3));
return current;
}
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