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u-boot/lib/smbios.c
Raymond Mao 41b7a09d24 smbios: add support for dynamic generation of Type 19 table 
This commit implements SMBIOS Type 19 (Memory Array Mapped Address)
generation with a hybrid approach supporting both:

1. Explicit definition via Device Tree 'smbios' node:
   Child node under '/smbios/smbios/memory-array-mapped-address' will be
   used to populate as individual Type 19 structure directly.
   - Properties follow SMBIOS field names with lowercase letters and
     hyphen-separated words (e.g., 'starting-address', 'ending-address',
     'partition-width', etc.).
   - This method supports precise platform-defined overrides and system
     descriptions.

2. Fallback to automatic DT-based discovery:
   If child node under '/smbios/smbios/memory-array-mapped-address' does
   not exist, the implementation will:
   - Scan all top-level 'memory@' nodes to populate Type 19 structure with
     inferred size and location data.
   - Scan nodes named or marked as 'memory-controller' and parse
     associated 'dimm@' subnodes (if present) to extract DIMM sizes and
     map them accordingly.

This dual-mode support enables flexible firmware SMBIOS reporting while
aligning with spec-compliant naming and runtime-detected memory topology.

Type 19 support is under GENERATE_SMBIOS_TABLE_VERBOSE to avoid
increasing rom size for those platforms which only require basic SMBIOS
support.

Signed-off-by: Raymond Mao <raymondmaoca@gmail.com>
Tested-by: Ilias Apalodimas <ilias.apalodimas@linaro.org>
2026-02-18 08:27:51 -06:00

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// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (C) 2015, Bin Meng <bmeng.cn@gmail.com>
*
* Adapted from coreboot src/arch/x86/smbios.c
*/
#define LOG_CATEGORY LOGC_BOARD
#include <display_options.h>
#include <dm.h>
#include <env.h>
#include <linux/stringify.h>
#include <linux/string.h>
#include <mapmem.h>
#include <smbios.h>
#include <sysinfo.h>
#include <tables_csum.h>
#include <version.h>
#include <malloc.h>
#include <dm/ofnode.h>
#ifdef CONFIG_CPU
#include <cpu.h>
#include <dm/uclass-internal.h>
#endif
#include <linux/sizes.h>
/* Safeguard for checking that U_BOOT_VERSION_NUM macros are compatible with U_BOOT_DMI */
#if U_BOOT_VERSION_NUM < 2000 || U_BOOT_VERSION_NUM > 2099 || \
U_BOOT_VERSION_NUM_PATCH < 1 || U_BOOT_VERSION_NUM_PATCH > 12
#error U_BOOT_VERSION_NUM macros are not compatible with DMI, fix U_BOOT_DMI macros
#endif
/*
* U_BOOT_DMI_DATE contains BIOS Release Date in format mm/dd/yyyy.
* BIOS Release Date is calculated from U-Boot version and fixed day 01.
* So for U-Boot version 2021.04 it is calculated as "04/01/2021".
* BIOS Release Date should contain date when code was released
* and not when it was built or compiled.
*/
#if U_BOOT_VERSION_NUM_PATCH < 10
#define U_BOOT_DMI_MONTH "0" __stringify(U_BOOT_VERSION_NUM_PATCH)
#else
#define U_BOOT_DMI_MONTH __stringify(U_BOOT_VERSION_NUM_PATCH)
#endif
#define U_BOOT_DMI_DAY "01"
#define U_BOOT_DMI_YEAR __stringify(U_BOOT_VERSION_NUM)
#define U_BOOT_DMI_DATE U_BOOT_DMI_MONTH "/" U_BOOT_DMI_DAY "/" U_BOOT_DMI_YEAR
DECLARE_GLOBAL_DATA_PTR;
/**
* struct map_sysinfo - Mapping of sysinfo strings to DT
*
* @si_str: sysinfo string
* @dt_str: DT string
* @max: Max index of the tokenized string to pick. Counting starts from 0
*
*/
struct map_sysinfo {
const char *si_node;
const char *si_str;
const char *dt_str;
int max;
};
static const struct map_sysinfo sysinfo_to_dt[] = {
{ .si_node = "system", .si_str = "product", .dt_str = "model", 2 },
{ .si_node = "system", .si_str = "manufacturer",
.dt_str = "compatible", 1 },
{ .si_node = "baseboard", .si_str = "product",
.dt_str = "model", 2 },
{ .si_node = "baseboard", .si_str = "manufacturer",
.dt_str = "compatible", 1 },
{ .si_node = "system-slot", .si_str = "slot-type",
.dt_str = "device_type", 0},
{ .si_node = "system-slot", .si_str = "segment-group-number",
.dt_str = "linux,pci-domain", 0},
};
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
static const struct pci_attr_lookup_table pci_attr[] = {
{ "pci-host-ecam-generic", SMBIOS_SYSSLOT_TYPE_PCIE,
SMBIOS_SYSSLOT_WIDTH_8X, SMBIOS_SYSSLOT_LENG_LONG,
SMBIOS_SYSSLOT_CHAR_3_3V, SMBIOS_SYSSLOT_CHAR_PCIPME },
{ "pci-host-cam-generic", SMBIOS_SYSSLOT_TYPE_PCI,
SMBIOS_SYSSLOT_WIDTH_32BIT, SMBIOS_SYSSLOT_LENG_SHORT,
SMBIOS_SYSSLOT_CHAR_5V | SMBIOS_SYSSLOT_CHAR_3_3V,
SMBIOS_SYSSLOT_CHAR_PCIPME },
{ "pci-host-thunder-ecam", SMBIOS_SYSSLOT_TYPE_PCIEGEN3,
SMBIOS_SYSSLOT_WIDTH_8X, SMBIOS_SYSSLOT_LENG_LONG,
SMBIOS_SYSSLOT_CHAR_3_3V,
SMBIOS_SYSSLOT_CHAR_PCIPME | SMBIOS_SYSSLOT_CHAR_HOTPLUG },
{ "pci-host-octeontx-ecam", SMBIOS_SYSSLOT_TYPE_PCIEGEN3X16,
SMBIOS_SYSSLOT_WIDTH_16X, SMBIOS_SYSSLOT_LENG_LONG,
SMBIOS_SYSSLOT_CHAR_3_3V,
SMBIOS_SYSSLOT_CHAR_PCIPME | SMBIOS_SYSSLOT_CHAR_HOTPLUG },
{ "pci-host-thunder-pem", SMBIOS_SYSSLOT_TYPE_PCIEGEN4X8,
SMBIOS_SYSSLOT_WIDTH_8X, SMBIOS_SYSSLOT_LENG_LONG,
SMBIOS_SYSSLOT_CHAR_3_3V,
SMBIOS_SYSSLOT_CHAR_PCIPME | SMBIOS_SYSSLOT_CHAR_HOTPLUG },
{ "pci-host-octeontx2-pem", SMBIOS_SYSSLOT_TYPE_PCIEGEN4X16,
SMBIOS_SYSSLOT_WIDTH_16X, SMBIOS_SYSSLOT_LENG_LONG,
SMBIOS_SYSSLOT_CHAR_3_3V,
SMBIOS_SYSSLOT_CHAR_PCIPME | SMBIOS_SYSSLOT_CHAR_HOTPLUG |
SMBIOS_SYSSLOT_CHAR_PCIBIF },
};
#endif
/**
* struct smbios_ctx - context for writing SMBIOS tables
*
* @node: node containing the information to write (ofnode_null()
* if none)
* @dev: sysinfo device to use (NULL if none)
* @subnode_name: sysinfo subnode_name. Used for DT fallback
* @eos: end-of-string pointer for the table being processed.
* This is set up when we start processing a table
* @next_ptr: pointer to the start of the next string to be added.
* When the table is not empty, this points to the byte
* after the \0 of the previous string.
* @last_str: points to the last string that was written to the table,
* or NULL if none
*/
struct smbios_ctx {
ofnode node;
struct udevice *dev;
const char *subnode_name;
char *eos;
char *next_ptr;
char *last_str;
};
typedef int (*smbios_write_subnode)(ulong *current, int handle,
struct smbios_ctx *ctx, int idx,
int type);
typedef int (*smbios_write_memnode)(ulong *current, int handle,
struct smbios_ctx *ctx, int idx,
int type);
typedef int (*smbios_write_memctrlnode)(ulong *current, int handle,
struct smbios_ctx *ctx, int idx,
u64 base, u64 sz);
/**
* Function prototype to write a specific type of SMBIOS structure
*
* @addr: start address to write the structure
* @handle: the structure's handle, a unique 16-bit number
* @ctx: context for writing the tables
* Return: size of the structure
*/
typedef int (*smbios_write_type)(ulong *addr, int *handle,
struct smbios_ctx *ctx);
/**
* struct smbios_write_method - Information about a table-writing function
*
* @write: Function to call
* @subnode_name: Name of subnode which has the information for this function,
* NULL if none
*/
struct smbios_write_method {
smbios_write_type write;
const char *subnode_name;
};
static const struct map_sysinfo *convert_sysinfo_to_dt(const char *node, const char *si)
{
int i;
for (i = 0; i < ARRAY_SIZE(sysinfo_to_dt); i++) {
if (node && !strcmp(node, sysinfo_to_dt[i].si_node) &&
!strcmp(si, sysinfo_to_dt[i].si_str))
return &sysinfo_to_dt[i];
}
return NULL;
}
/**
* smbios_add_string() - add a string to the string area
*
* This adds a string to the string area which is appended directly after
* the formatted portion of an SMBIOS structure.
*
* @ctx: SMBIOS context
* @str: string to add
* Return: string number in the string area. 0 if str is NULL.
*/
static int smbios_add_string(struct smbios_ctx *ctx, const char *str)
{
int i = 1;
char *p = ctx->eos;
if (!str)
return 0;
for (;;) {
if (!*p) {
ctx->last_str = p;
strcpy(p, str);
p += strlen(str);
*p++ = '\0';
ctx->next_ptr = p;
*p++ = '\0';
return i;
}
if (!strcmp(p, str)) {
ctx->last_str = p;
return i;
}
p += strlen(p) + 1;
i++;
}
}
/**
* get_str_from_dt - Get a substring from a DT property.
* After finding the property in the DT, the function
* will parse comma-separated values and return the value.
* If nprop->max exceeds the number of comma-separated
* elements, the last non NULL value will be returned.
* Counting starts from zero.
*
* @nprop: sysinfo property to use
* @str: pointer to fill with data
* @size: str buffer length
*/
static
void get_str_from_dt(const struct map_sysinfo *nprop, char *str, size_t size)
{
const char *dt_str;
int cnt = 0;
char *token;
memset(str, 0, size);
if (!nprop || !nprop->max)
return;
dt_str = ofnode_read_string(ofnode_root(), nprop->dt_str);
if (!dt_str)
return;
memcpy(str, dt_str, size);
token = strtok(str, ",");
while (token && cnt < nprop->max) {
strlcpy(str, token, strlen(token) + 1);
token = strtok(NULL, ",");
cnt++;
}
}
/**
* smbios_get_val_si() - Get value from the devicetree or sysinfo
*
* @ctx: context of SMBIOS
* @prop: property to read
* @sysinfo_id: unique identifier for the value to be read
* @val_def: Default value
* Return: Valid value from sysinfo or device tree, otherwise val_def.
*/
static int smbios_get_val_si(struct smbios_ctx * __maybe_unused ctx,
const char * __maybe_unused prop,
int __maybe_unused sysinfo_id, int val_def)
{
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
int val;
const struct map_sysinfo *nprop;
if (!ctx->dev)
return val_def;
if (!sysinfo_get_int(ctx->dev, sysinfo_id, &val))
return val;
if (!IS_ENABLED(CONFIG_OF_CONTROL) || !prop)
return val_def;
if (ofnode_valid(ctx->node) && !ofnode_read_u32(ctx->node, prop, &val))
return val;
/*
* If the node or property is not valid fallback and try the root
*/
if (!ofnode_read_u32(ofnode_root(), prop, &val))
return val;
/* If the node is still missing, try with the mapping values */
nprop = convert_sysinfo_to_dt(ctx->subnode_name, prop);
if (!ofnode_read_u32(ofnode_root(), nprop->dt_str, &val))
return val;
#endif
return val_def;
}
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
static u64 smbios_get_u64_si(struct smbios_ctx * __maybe_unused ctx,
const char * __maybe_unused prop,
int __maybe_unused sysinfo_id, u64 val_def)
{
size_t len;
void *data;
const fdt32_t *prop_val;
int prop_len;
u64 val = 0;
if (!ctx->dev)
return val_def;
if (!sysinfo_get_data(ctx->dev, sysinfo_id, &data, &len))
return *((u64 *)data);
if (!IS_ENABLED(CONFIG_OF_CONTROL) || !prop || !ofnode_valid(ctx->node))
return val_def;
prop_val = ofnode_read_prop(ctx->node, prop, &prop_len);
if (!prop_val || prop_len < sizeof(fdt32_t) ||
prop_len % sizeof(fdt32_t)) {
/*
* If the node or property is not valid fallback and try the root
*/
prop_val = ofnode_read_prop(ofnode_root(), prop, &prop_len);
if (!prop_val || prop_len < sizeof(fdt32_t) ||
prop_len % sizeof(fdt32_t))
return val_def;
}
/* 64-bit: <hi lo> or 32-bit */
if (prop_len >= sizeof(fdt32_t) * 2) {
val = ((u64)fdt32_to_cpu(prop_val[0]) << 32) |
fdt32_to_cpu(prop_val[1]);
} else {
val = fdt32_to_cpu(prop_val[0]);
}
return val;
}
#endif
/**
* smbios_add_prop_si() - Add a property from the devicetree or sysinfo
*
* Sysinfo is used if available, with a fallback to devicetree
*
* @ctx: context for writing the tables
* @prop: property to write
* @sysinfo_id: unique identifier for the string value to be read
* @dval: Default value to use if the string is not found or is empty
* Return: 0 if not found, else SMBIOS string number (1 or more)
*/
static int smbios_add_prop_si(struct smbios_ctx *ctx, const char *prop,
int sysinfo_id, const char *dval)
{
int ret;
if (!dval || !*dval)
dval = NULL;
if (sysinfo_id && ctx->dev) {
char val[SMBIOS_STR_MAX];
ret = sysinfo_get_str(ctx->dev, sysinfo_id, sizeof(val), val);
if (!ret)
return smbios_add_string(ctx, val);
}
if (!prop)
return smbios_add_string(ctx, dval);
if (IS_ENABLED(CONFIG_OF_CONTROL)) {
const char *str = NULL;
char str_dt[128] = { 0 };
/*
* If the node is not valid fallback and try the entire DT
* so we can at least fill in manufacturer and board type
*/
if (ofnode_valid(ctx->node)) {
str = ofnode_read_string(ctx->node, prop);
} else {
const struct map_sysinfo *nprop;
nprop = convert_sysinfo_to_dt(ctx->subnode_name, prop);
get_str_from_dt(nprop, str_dt, sizeof(str_dt));
str = (const char *)str_dt;
}
ret = smbios_add_string(ctx, str && *str ? str : dval);
return ret;
}
return 0;
}
/**
* smbios_add_prop() - Add a property from the devicetree
*
* @prop: property to write. The default string will be written if
* prop is NULL
* @dval: Default value to use if the string is not found or is empty
* Return: 0 if not found, else SMBIOS string number (1 or more)
*/
static int smbios_add_prop(struct smbios_ctx *ctx, const char *prop,
const char *dval)
{
return smbios_add_prop_si(ctx, prop, SYSID_NONE, dval);
}
static void smbios_set_eos(struct smbios_ctx *ctx, char *eos)
{
ctx->eos = eos;
ctx->next_ptr = eos;
ctx->last_str = NULL;
}
int smbios_update_version(const char *version)
{
char *ptr = gd->smbios_version;
uint old_len, len;
if (!ptr)
return log_ret(-ENOENT);
/*
* This string is supposed to have at least enough bytes and is
* padded with spaces. Update it, taking care not to move the
* \0 terminator, so that other strings in the string table
* are not disturbed. See smbios_add_string()
*/
old_len = strnlen(ptr, SMBIOS_STR_MAX);
len = strnlen(version, SMBIOS_STR_MAX);
if (len > old_len)
return log_ret(-ENOSPC);
log_debug("Replacing SMBIOS type 0 version string '%s'\n", ptr);
memcpy(ptr, version, len);
#ifdef LOG_DEBUG
print_buffer((ulong)ptr, ptr, 1, old_len + 1, 0);
#endif
return 0;
}
/**
* smbios_string_table_len() - compute the string area size
*
* This computes the size of the string area including the string terminator.
*
* @ctx: SMBIOS context
* Return: string area size
*/
static int smbios_string_table_len(const struct smbios_ctx *ctx)
{
/* In case no string is defined we have to return two \0 */
if (ctx->next_ptr == ctx->eos)
return 2;
/* Allow for the final \0 after all strings */
return (ctx->next_ptr + 1) - ctx->eos;
}
static int smbios_write_type0(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
struct smbios_type0 *t;
int len = sizeof(*t);
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_BIOS_INFORMATION, len, *handle);
smbios_set_eos(ctx, t->eos);
t->vendor = smbios_add_prop_si(ctx, NULL, SYSID_SM_BIOS_VENDOR,
"U-Boot");
t->bios_ver = smbios_add_prop_si(ctx, "version", SYSID_SM_BIOS_VER,
PLAIN_VERSION);
if (t->bios_ver)
gd->smbios_version = ctx->last_str;
log_debug("smbios_version = %p: '%s'\n", gd->smbios_version,
gd->smbios_version);
#ifdef LOG_DEBUG
print_buffer((ulong)gd->smbios_version, gd->smbios_version,
1, strlen(gd->smbios_version) + 1, 0);
#endif
t->bios_release_date = smbios_add_prop_si(ctx, NULL,
SYSID_SM_BIOS_REL_DATE,
U_BOOT_DMI_DATE);
#ifdef CONFIG_ROM_SIZE
if (CONFIG_ROM_SIZE < SZ_16M) {
t->bios_rom_size = (CONFIG_ROM_SIZE / 65536) - 1;
} else {
/* CONFIG_ROM_SIZE < 8 GiB */
t->bios_rom_size = 0xff;
t->extended_bios_rom_size = CONFIG_ROM_SIZE >> 20;
}
#endif
t->bios_characteristics = BIOS_CHARACTERISTICS_PCI_SUPPORTED |
BIOS_CHARACTERISTICS_SELECTABLE_BOOT |
BIOS_CHARACTERISTICS_UPGRADEABLE;
#ifdef CONFIG_GENERATE_ACPI_TABLE
t->bios_characteristics_ext1 = BIOS_CHARACTERISTICS_EXT1_ACPI;
#endif
#ifdef CONFIG_EFI_LOADER
t->bios_characteristics_ext2 |= BIOS_CHARACTERISTICS_EXT2_UEFI;
#endif
t->bios_characteristics_ext2 |= BIOS_CHARACTERISTICS_EXT2_TARGET;
/* bios_major_release has only one byte, so drop century */
t->bios_major_release = U_BOOT_VERSION_NUM % 100;
t->bios_minor_release = U_BOOT_VERSION_NUM_PATCH;
t->ec_major_release = 0xff;
t->ec_minor_release = 0xff;
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_write_type1(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
struct smbios_type1 *t;
int len = sizeof(*t);
char *serial_str = env_get("serial#");
size_t uuid_len;
void *uuid;
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_SYSTEM_INFORMATION, len, *handle);
smbios_set_eos(ctx, t->eos);
t->manufacturer = smbios_add_prop_si(ctx, "manufacturer",
SYSID_SM_SYSTEM_MANUFACTURER,
NULL);
t->product_name = smbios_add_prop_si(ctx, "product",
SYSID_SM_SYSTEM_PRODUCT, NULL);
t->version = smbios_add_prop_si(ctx, "version", SYSID_SM_SYSTEM_VERSION,
NULL);
if (serial_str) {
t->serial_number = smbios_add_prop(ctx, NULL, serial_str);
strlcpy((char *)t->uuid, serial_str, sizeof(t->uuid));
} else {
t->serial_number = smbios_add_prop_si(ctx, "serial",
SYSID_SM_SYSTEM_SERIAL,
NULL);
}
if (!sysinfo_get_data(ctx->dev, SYSID_SM_SYSTEM_UUID, &uuid,
&uuid_len) &&
uuid_len == sizeof(t->uuid))
memcpy(t->uuid, uuid, sizeof(t->uuid));
t->wakeup_type = smbios_get_val_si(ctx, "wakeup-type",
SYSID_SM_SYSTEM_WAKEUP,
SMBIOS_WAKEUP_TYPE_UNKNOWN);
t->sku_number = smbios_add_prop_si(ctx, "sku", SYSID_SM_SYSTEM_SKU,
NULL);
t->family = smbios_add_prop_si(ctx, "family", SYSID_SM_SYSTEM_FAMILY,
NULL);
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_write_type2(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
struct smbios_type2 *t;
int len = sizeof(*t);
u8 *eos_addr;
/*
* reserve the space for the dynamic bytes of contained object handles.
* TODO: len += <obj_handle_num> * SMBIOS_TYPE2_CON_OBJ_HANDLE_SIZE
* obj_handle_num can be from DT node "baseboard" or sysinfo driver.
*/
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_BOARD_INFORMATION, len, *handle);
/* eos is at the end of the structure */
eos_addr = (u8 *)t + len - sizeof(t->eos);
smbios_set_eos(ctx, eos_addr);
t->manufacturer = smbios_add_prop_si(ctx, "manufacturer",
SYSID_SM_BASEBOARD_MANUFACTURER,
NULL);
t->product_name = smbios_add_prop_si(ctx, "product",
SYSID_SM_BASEBOARD_PRODUCT, NULL);
t->version = smbios_add_prop_si(ctx, "version",
SYSID_SM_BASEBOARD_VERSION, NULL);
t->serial_number = smbios_add_prop_si(ctx, "serial",
SYSID_SM_BASEBOARD_SERIAL, NULL);
t->asset_tag_number = smbios_add_prop_si(ctx, "asset-tag",
SYSID_SM_BASEBOARD_ASSET_TAG,
NULL);
t->feature_flags = smbios_get_val_si(ctx, "feature-flags",
SYSID_SM_BASEBOARD_FEATURE, 0);
t->chassis_location =
smbios_add_prop_si(ctx, "chassis-location",
SYSID_SM_BASEBOARD_CHASSIS_LOCAT, NULL);
t->board_type = smbios_get_val_si(ctx, "board-type",
SYSID_SM_BASEBOARD_TYPE,
SMBIOS_BOARD_TYPE_UNKNOWN);
/*
* TODO:
* Populate the Contained Object Handles if they exist
* t->number_contained_objects = <obj_handle_num>;
*/
t->chassis_handle = *handle + 1;
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_write_type3(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
struct smbios_type3 *t;
int len = sizeof(*t);
u8 *eos_addr;
size_t elem_size = 0;
__maybe_unused u8 *elem_addr;
__maybe_unused u8 *sku_num_addr;
/*
* reserve the space for the dynamic bytes of contained elements.
* TODO: elem_size = <element_count> * <element_record_length>
* element_count and element_record_length can be from DT node
* "chassis" or sysinfo driver.
*/
len += elem_size;
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_SYSTEM_ENCLOSURE, len, *handle);
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
elem_addr = (u8 *)t + offsetof(struct smbios_type3, sku_number);
sku_num_addr = elem_addr + elem_size;
#endif
/* eos is at the end of the structure */
eos_addr = (u8 *)t + len - sizeof(t->eos);
smbios_set_eos(ctx, eos_addr);
t->manufacturer = smbios_add_prop_si(ctx, "manufacturer",
SYSID_SM_ENCLOSURE_MANUFACTURER,
NULL);
t->chassis_type = smbios_get_val_si(ctx, "chassis-type",
SYSID_SM_ENCLOSURE_TYPE,
SMBIOS_ENCLOSURE_UNKNOWN);
t->bootup_state = smbios_get_val_si(ctx, "bootup-state",
SYSID_SM_ENCLOSURE_BOOTUP,
SMBIOS_STATE_UNKNOWN);
t->power_supply_state = smbios_get_val_si(ctx, "power-supply-state",
SYSID_SM_ENCLOSURE_POW,
SMBIOS_STATE_UNKNOWN);
t->thermal_state = smbios_get_val_si(ctx, "thermal-state",
SYSID_SM_ENCLOSURE_THERMAL,
SMBIOS_STATE_UNKNOWN);
t->security_status = smbios_get_val_si(ctx, "security-status",
SYSID_SM_ENCLOSURE_SECURITY,
SMBIOS_SECURITY_UNKNOWN);
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
t->version = smbios_add_prop_si(ctx, "version",
SYSID_SM_ENCLOSURE_VERSION, NULL);
t->serial_number = smbios_add_prop_si(ctx, "serial",
SYSID_SM_ENCLOSURE_SERIAL, NULL);
t->asset_tag_number = smbios_add_prop_si(ctx, "asset-tag",
SYSID_SM_BASEBOARD_ASSET_TAG,
NULL);
t->oem_defined = smbios_get_val_si(ctx, "oem-defined",
SYSID_SM_ENCLOSURE_OEM, 0);
t->height = smbios_get_val_si(ctx, "height",
SYSID_SM_ENCLOSURE_HEIGHT, 0);
t->number_of_power_cords =
smbios_get_val_si(ctx, "number-of-power-cords",
SYSID_SM_ENCLOSURE_POWCORE_NUM, 0);
/*
* TODO: Populate the Contained Element Record if they exist
* t->element_count = <element_num>;
* t->element_record_length = <element_len>;
*/
*sku_num_addr = smbios_add_prop_si(ctx, "sku", SYSID_SM_ENCLOSURE_SKU,
NULL);
#endif
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static void smbios_write_type4_dm(struct smbios_type4 *t,
struct smbios_ctx *ctx)
{
u16 processor_family = SMBIOS_PROCESSOR_FAMILY_UNKNOWN;
const char *vendor = NULL;
const char *name = NULL;
__maybe_unused void *id_data = NULL;
__maybe_unused size_t id_size = 0;
#ifdef CONFIG_CPU
char processor_name[49];
char vendor_name[49];
struct udevice *cpu = NULL;
uclass_find_first_device(UCLASS_CPU, &cpu);
if (cpu) {
struct cpu_plat *plat = dev_get_parent_plat(cpu);
if (plat->family)
processor_family = plat->family;
t->processor_id[0] = plat->id[0];
t->processor_id[1] = plat->id[1];
if (!cpu_get_vendor(cpu, vendor_name, sizeof(vendor_name)))
vendor = vendor_name;
if (!cpu_get_desc(cpu, processor_name, sizeof(processor_name)))
name = processor_name;
}
#endif
if (processor_family == SMBIOS_PROCESSOR_FAMILY_UNKNOWN)
processor_family =
smbios_get_val_si(ctx, "family",
SYSID_SM_PROCESSOR_FAMILY,
SMBIOS_PROCESSOR_FAMILY_UNKNOWN);
if (processor_family == SMBIOS_PROCESSOR_FAMILY_EXT)
t->processor_family2 =
smbios_get_val_si(ctx, "family2",
SYSID_SM_PROCESSOR_FAMILY2,
SMBIOS_PROCESSOR_FAMILY_UNKNOWN);
t->processor_family = processor_family;
t->processor_manufacturer =
smbios_add_prop_si(ctx, "manufacturer",
SYSID_SM_PROCESSOR_MANUFACT, vendor);
t->processor_version = smbios_add_prop_si(ctx, "version",
SYSID_SM_PROCESSOR_VERSION,
name);
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
if (t->processor_id[0] || t->processor_id[1] ||
sysinfo_get_data(ctx->dev, SYSID_SM_PROCESSOR_ID, &id_data,
&id_size))
return;
if (id_data && id_size == sizeof(t->processor_id))
memcpy((u8 *)t->processor_id, id_data, id_size);
#endif
}
static int smbios_write_type4(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
struct smbios_type4 *t;
int len = sizeof(*t);
__maybe_unused void *hdl;
__maybe_unused size_t hdl_size;
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_PROCESSOR_INFORMATION, len, *handle);
smbios_set_eos(ctx, t->eos);
t->socket_design = smbios_add_prop_si(ctx, "socket-design",
SYSID_SM_PROCESSOR_SOCKET, NULL);
t->processor_type = smbios_get_val_si(ctx, "processor-type",
SYSID_SM_PROCESSOR_TYPE,
SMBIOS_PROCESSOR_TYPE_UNKNOWN);
smbios_write_type4_dm(t, ctx);
t->status = smbios_get_val_si(ctx, "processor-status",
SYSID_SM_PROCESSOR_STATUS,
SMBIOS_PROCESSOR_STATUS_UNKNOWN);
t->processor_upgrade =
smbios_get_val_si(ctx, "upgrade", SYSID_SM_PROCESSOR_UPGRADE,
SMBIOS_PROCESSOR_UPGRADE_UNKNOWN);
t->l1_cache_handle = SMBIOS_CACHE_HANDLE_NONE;
t->l2_cache_handle = SMBIOS_CACHE_HANDLE_NONE;
t->l3_cache_handle = SMBIOS_CACHE_HANDLE_NONE;
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
t->voltage = smbios_get_val_si(ctx, "voltage",
SYSID_SM_PROCESSOR_VOLTAGE, 0);
t->external_clock = smbios_get_val_si(ctx, "external-clock",
SYSID_SM_PROCESSOR_EXT_CLOCK, 0);
t->max_speed = smbios_get_val_si(ctx, "max-speed",
SYSID_SM_PROCESSOR_MAX_SPEED, 0);
t->current_speed = smbios_get_val_si(ctx, "current-speed",
SYSID_SM_PROCESSOR_CUR_SPEED, 0);
/* Read the cache handles */
if (!sysinfo_get_data(ctx->dev, SYSID_SM_CACHE_HANDLE, &hdl,
&hdl_size) &&
(hdl_size == SYSINFO_CACHE_LVL_MAX * sizeof(u16))) {
u16 *handle = (u16 *)hdl;
if (*handle)
t->l1_cache_handle = *handle;
handle++;
if (*handle)
t->l2_cache_handle = *handle;
handle++;
if (*handle)
t->l3_cache_handle = *handle;
}
t->serial_number = smbios_add_prop_si(ctx, "serial",
SYSID_SM_PROCESSOR_SN, NULL);
t->asset_tag = smbios_add_prop_si(ctx, "asset-tag",
SYSID_SM_PROCESSOR_ASSET_TAG, NULL);
t->part_number = smbios_add_prop_si(ctx, "part-number",
SYSID_SM_PROCESSOR_PN, NULL);
t->core_count = smbios_get_val_si(ctx, "core-count",
SYSID_SM_PROCESSOR_CORE_CNT, 0);
t->core_enabled = smbios_get_val_si(ctx, "core-enabled",
SYSID_SM_PROCESSOR_CORE_EN, 0);
t->thread_count = smbios_get_val_si(ctx, "thread-count",
SYSID_SM_PROCESSOR_THREAD_CNT, 0);
t->processor_characteristics =
smbios_get_val_si(ctx, "characteristics",
SYSID_SM_PROCESSOR_CHARA,
SMBIOS_PROCESSOR_UND);
t->core_count2 = smbios_get_val_si(ctx, "core-count2",
SYSID_SM_PROCESSOR_CORE_CNT2, 0);
t->core_enabled2 = smbios_get_val_si(ctx, "core-enabled2",
SYSID_SM_PROCESSOR_CORE_EN2, 0);
t->thread_count2 = smbios_get_val_si(ctx, "thread-count2",
SYSID_SM_PROCESSOR_THREAD_CNT2, 0);
t->thread_enabled = smbios_get_val_si(ctx, "thread-enabled",
SYSID_SM_PROCESSOR_THREAD_EN, 0);
#endif
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
static int smbios_write_type7_1level(ulong *current, int handle,
struct smbios_ctx *ctx, int level)
{
struct smbios_type7 *t;
int len = sizeof(*t);
void *hdl;
size_t hdl_size;
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_CACHE_INFORMATION, len, handle);
smbios_set_eos(ctx, t->eos);
t->socket_design = smbios_add_prop_si(ctx, "socket-design",
SYSID_SM_CACHE_SOCKET + level,
NULL);
t->config.data = smbios_get_val_si(ctx, "config",
SYSID_SM_CACHE_CONFIG + level,
(level - 1) | SMBIOS_CACHE_OP_UND);
t->max_size.data = smbios_get_val_si(ctx, "max-size",
SYSID_SM_CACHE_MAX_SIZE + level,
0);
t->inst_size.data = smbios_get_val_si(ctx, "installed-size",
SYSID_SM_CACHE_INST_SIZE + level,
0);
t->supp_sram_type.data =
smbios_get_val_si(ctx, "supported-sram-type",
SYSID_SM_CACHE_SUPSRAM_TYPE + level,
SMBIOS_CACHE_SRAM_TYPE_UNKNOWN);
t->curr_sram_type.data =
smbios_get_val_si(ctx, "current-sram-type",
SYSID_SM_CACHE_CURSRAM_TYPE + level,
SMBIOS_CACHE_SRAM_TYPE_UNKNOWN);
t->speed = smbios_get_val_si(ctx, "speed", SYSID_SM_CACHE_SPEED + level,
0);
t->err_corr_type = smbios_get_val_si(ctx, "error-correction-type",
SYSID_SM_CACHE_ERRCOR_TYPE + level,
SMBIOS_CACHE_ERRCORR_UNKNOWN);
t->sys_cache_type =
smbios_get_val_si(ctx, "system-cache-type",
SYSID_SM_CACHE_SCACHE_TYPE + level,
SMBIOS_CACHE_SYSCACHE_TYPE_UNKNOWN);
t->associativity = smbios_get_val_si(ctx, "associativity",
SYSID_SM_CACHE_ASSOC + level,
SMBIOS_CACHE_ASSOC_UNKNOWN);
t->max_size2.data = smbios_get_val_si(ctx, "max-size2",
SYSID_SM_CACHE_MAX_SIZE2 + level,
0);
t->inst_size2.data =
smbios_get_val_si(ctx, "installed-size2",
SYSID_SM_CACHE_INST_SIZE2 + level, 0);
/* Save the cache handles */
if (!sysinfo_get_data(ctx->dev, SYSID_SM_CACHE_HANDLE, &hdl,
&hdl_size)) {
if (hdl_size == SYSINFO_CACHE_LVL_MAX * sizeof(u16))
*((u16 *)hdl + level) = handle;
}
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_write_type7(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
int len = 0;
int i, level;
ofnode parent = ctx->node;
struct smbios_ctx ctx_bak;
int hdl_base = *handle;
memcpy(&ctx_bak, ctx, sizeof(ctx_bak));
/* Get the number of level */
level = smbios_get_val_si(ctx, NULL, SYSID_SM_CACHE_LEVEL, 0);
if (level >= SYSINFO_CACHE_LVL_MAX) /* Error, return 0-length */
return 0;
for (i = 0; i <= level; i++) {
char buf[9] = "";
if (!snprintf(buf, sizeof(buf), "l%d-cache", i + 1))
return 0;
ctx->subnode_name = buf;
ctx->node = ofnode_find_subnode(parent, ctx->subnode_name);
*handle = hdl_base + i;
len += smbios_write_type7_1level(current, *handle, ctx, i);
memcpy(ctx, &ctx_bak, sizeof(*ctx));
}
return len;
}
static int smbios_scan_subnodes(ulong *current, struct smbios_ctx *ctx,
int *handle, smbios_write_subnode cb, int type)
{
ofnode child;
int i;
int hdl_base = *handle;
int len = 0;
struct smbios_ctx ctx_bak;
memcpy(&ctx_bak, ctx, sizeof(ctx_bak));
for (i = 0, child = ofnode_first_subnode(ctx->node);
ofnode_valid(child); child = ofnode_next_subnode(child), i++) {
ctx->node = child;
*handle = hdl_base + i;
len += cb(current, *handle, ctx, i, type);
memcpy(ctx, &ctx_bak, sizeof(*ctx));
}
return len;
}
static void smbios_lookup_pci_attr(struct smbios_ctx *ctx,
struct smbios_type9 *t)
{
const char *compatible;
u32 addr_cells, size_cells, total_cells;
const fdt32_t *reg;
int reglen;
int i;
/* default attributes */
t->slot_type = SMBIOS_SYSSLOT_TYPE_PCI;
t->slot_data_bus_width = SMBIOS_SYSSLOT_WIDTH_UNKNOWN;
t->slot_characteristics_1 = SMBIOS_SYSSLOT_CHAR_UND;
t->current_usage = SMBIOS_SYSSLOT_USAGE_UNKNOWN;
t->slot_length = SMBIOS_SYSSLOT_LENG_UNKNOWN;
t->segment_group_number = smbios_get_val_si(ctx, "segment-group-number",
SYSID_NONE,
SMBIOS_SYSSLOT_SGGNUM_UND);
/*
* Get #address-cells and #size-cells dynamically
* Default 3 for #address-cells and 2 for #size-cells
*/
addr_cells = ofnode_read_u32_default(ctx->node, "#address-cells", 3);
size_cells = ofnode_read_u32_default(ctx->node, "#size-cells", 2);
total_cells = addr_cells + size_cells;
/* Read property 'reg' from the node */
reg = ofnode_read_prop(ctx->node, "reg", &reglen);
if (reg && reglen > addr_cells * sizeof(*reg)) {
/* First address-cell: Bus Number */
if (addr_cells >= 1)
t->bus_number = fdt32_to_cpu(reg[0]);
/* Second address-cell: Device/Function */
if (addr_cells >= 2)
t->device_function_number.data = fdt32_to_cpu(reg[1]);
/*
* Third address-cell 'Register Offset' and the following
* size-cell bytes are not useful for SMBIOS type 9, just
* ignore them.
*/
/*
* As neither PCI IRQ Routing Table ($PIRQ) nor FDT
* property to represent a Slot ID, try to derive a
* Slot ID programmatically.
*/
t->slot_id = t->device_function_number.fields.dev_num |
(t->bus_number << 5);
}
/* Read 'compatible' property */
compatible = ofnode_read_string(ctx->node, "compatible");
if (!compatible)
return;
for (i = 0; i < ARRAY_SIZE(pci_attr); i++) {
if (strstr(compatible, pci_attr[i].str)) {
t->slot_type = pci_attr[i].slot_type;
t->slot_data_bus_width = pci_attr[i].data_bus_width;
t->slot_length = pci_attr[i].slot_length;
t->slot_characteristics_1 = pci_attr[i].chara1;
t->slot_characteristics_2 = pci_attr[i].chara2;
/* mark it as in-use arbitrarily */
t->current_usage = SMBIOS_SYSSLOT_USAGE_INUSE;
return;
}
}
}
static void smbios_write_type9_fields(struct smbios_ctx *ctx,
struct smbios_type9 *t)
{
t->slot_type = smbios_get_val_si(ctx, "slot-type", SYSID_NONE,
SMBIOS_SYSSLOT_TYPE_UNKNOWN);
t->slot_data_bus_width =
smbios_get_val_si(ctx, "data-bus-width",
SYSID_NONE, SMBIOS_SYSSLOT_WIDTH_UNKNOWN);
t->current_usage = smbios_get_val_si(ctx, "current-usage", SYSID_NONE,
SMBIOS_SYSSLOT_USAGE_UNKNOWN);
t->slot_length = smbios_get_val_si(ctx, "slot-length", SYSID_NONE,
SMBIOS_SYSSLOT_LENG_UNKNOWN);
t->slot_id = smbios_get_val_si(ctx, "slot-id", SYSID_NONE, 0);
t->slot_characteristics_1 =
smbios_get_val_si(ctx, "slot-characteristics-1", SYSID_NONE,
SMBIOS_SYSSLOT_CHAR_UND);
t->slot_characteristics_2 = smbios_get_val_si(ctx,
"slot-characteristics-2",
SYSID_NONE, 0);
t->segment_group_number = smbios_get_val_si(ctx, "segment-group-number",
SYSID_NONE, 0);
t->bus_number = smbios_get_val_si(ctx, "bus-number", SYSID_NONE, 0);
t->device_function_number.data =
smbios_get_val_si(ctx, "device-function-number", SYSID_NONE, 0);
}
static int smbios_write_type9_1slot(ulong *current, int handle,
struct smbios_ctx *ctx,
int __maybe_unused idx, int devtype)
{
struct smbios_type9 *t;
int len = sizeof(*t);
u8 pgroups_cnt;
u8 *eos_addr;
size_t pgroups_size;
void *wp;
pgroups_cnt = smbios_get_val_si(ctx, "peer-grouping-count",
SYSID_NONE, 0);
pgroups_size = pgroups_cnt * SMBIOS_TYPE9_PGROUP_SIZE;
/*
* reserve the space for the dynamic bytes of peer_groups.
* TODO:
* peer_groups = <peer_grouping_count> * SMBIOS_TYPE9_PGROUP_SIZE
*/
len += pgroups_size;
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_SYSTEM_SLOTS, len, handle);
/* eos is at the end of the structure */
eos_addr = (u8 *)t + len - sizeof(t->eos);
smbios_set_eos(ctx, eos_addr);
/* Write the general fields */
t->peer_grouping_count = pgroups_cnt;
t->socket_design = smbios_add_prop_si(ctx, "socket-design", SYSID_NONE,
NULL);
t->electrical_bus_width = smbios_get_val_si(ctx, "data-bus-width",
SYSID_NONE, 0);
/* skip the reserved peer groups and write the following fields from eos */
/* t->slot_height */
wp = eos_addr - sizeof(t->slot_height);
*((u8 *)wp) = smbios_get_val_si(ctx, "slot-height", SYSID_NONE, 0);
/* t->slot_pitch */
wp -= sizeof(t->slot_pitch);
*((u16 *)wp) = smbios_get_val_si(ctx, "slot-pitch", SYSID_NONE, 0);
/* t->slot_physical_width */
wp -= sizeof(t->slot_physical_width);
*((u8 *)wp) = smbios_get_val_si(ctx, "slot-physical-width", SYSID_NONE, 0);
/* t->slot_information */
wp -= sizeof(t->slot_information);
*((u8 *)wp) = smbios_get_val_si(ctx, "slot-information", SYSID_NONE, 0);
/* For PCI, some fields can be extracted from FDT node */
if (devtype == SMBIOS_SYSSLOT_TYPE_PCI)
/* Populate PCI attributes from existing PCI properties */
smbios_lookup_pci_attr(ctx, t);
else if (devtype == SMBIOS_SYSSLOT_TYPE_UNKNOWN) {
/* Properties that expected in smbios subnode 'system-slot' */
smbios_write_type9_fields(ctx, t);
}
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_scan_slot_type(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
int i = 0;
struct smbios_ctx ctx_bak;
ofnode child;
const struct map_sysinfo *prop;
int hdl_base = *handle;
int len = 0;
memcpy(&ctx_bak, ctx, sizeof(ctx_bak));
prop = convert_sysinfo_to_dt(ctx->subnode_name, "slot-type");
for (child = ofnode_first_subnode(ofnode_root()); ofnode_valid(child);
child = ofnode_next_subnode(child)) {
const char *dev_type_str;
u8 dev_type = SMBIOS_SYSSLOT_TYPE_UNKNOWN;
dev_type_str = ofnode_read_string(child, prop->dt_str);
if (!dev_type_str)
continue;
if (!strcmp(dev_type_str, "pci"))
dev_type = SMBIOS_SYSSLOT_TYPE_PCI;
else if (!strcmp(dev_type_str, "isa"))
dev_type = SMBIOS_SYSSLOT_TYPE_ISA;
else if (!strcmp(dev_type_str, "pcmcia"))
dev_type = SMBIOS_SYSSLOT_TYPE_PCMCIA;
else
continue;
*handle = hdl_base + i;
ctx->node = child;
len += smbios_write_type9_1slot(current, *handle, ctx, 0,
dev_type);
memcpy(ctx, &ctx_bak, sizeof(*ctx));
i++;
}
return len;
}
static int smbios_write_type9(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
int len;
/* TODO: Get system slot information via pci subsystem */
if (!IS_ENABLED(CONFIG_OF_CONTROL))
return 0; /* Error, return 0-length */
len = smbios_scan_subnodes(current, ctx, handle,
smbios_write_type9_1slot,
SMBIOS_SYSSLOT_TYPE_UNKNOWN);
if (len)
return len;
/* if no subnode under 'system-slot', try scan the entire FDT */
len = smbios_scan_slot_type(current, handle, ctx);
return len;
}
static u64 smbios_pop_size_from_memory_node(ofnode node)
{
const fdt32_t *reg;
int len;
u64 size_bytes;
/* Read property 'reg' from the node */
reg = ofnode_read_prop(node, "reg", &len);
if (!reg || len < sizeof(fdt32_t) * 4 || len % sizeof(fdt32_t))
return 0;
/* Combine hi/lo for size (typically 64-bit) */
size_bytes = ((u64)fdt32_to_cpu(reg[2]) << 32) | fdt32_to_cpu(reg[3]);
return size_bytes;
}
static int
smbios_write_type16_sum_memory_nodes(ulong *current, int handle,
struct smbios_ctx *ctx, u16 cnt, u64 size)
{
struct smbios_type16 *t;
int len = sizeof(*t);
u8 *eos_addr;
void *hdl;
size_t hdl_size;
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_PHYS_MEMORY_ARRAY, len, handle);
/* eos is at the end of the structure */
eos_addr = (u8 *)t + len - sizeof(t->eos);
smbios_set_eos(ctx, eos_addr);
/* default attributes */
t->location = SMBIOS_MA_LOCATION_MOTHERBOARD;
t->use = SMBIOS_MA_USE_SYSTEM;
t->mem_err_corr = SMBIOS_MA_ERRCORR_UNKNOWN;
t->mem_err_info_hdl = SMBIOS_MA_ERRINFO_NONE;
t->num_of_mem_dev = cnt;
/* Use extended field */
t->max_cap = cpu_to_le32(0x80000000);
t->ext_max_cap = cpu_to_le64(size >> 10); /* In KB */
/* Save the memory array handles */
if (!sysinfo_get_data(ctx->dev, SYSID_SM_MEMARRAY_HANDLE, &hdl,
&hdl_size) &&
hdl_size == SYSINFO_MEM_HANDLE_MAX * sizeof(u16))
*((u16 *)hdl) = handle;
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static void
smbios_pop_type16_from_memcontroller_node(ofnode node, struct smbios_type16 *t)
{
ofnode child;
int count = 0;
u64 total = 0;
/* default attributes */
t->location = SMBIOS_MA_LOCATION_MOTHERBOARD;
t->use = SMBIOS_MA_USE_SYSTEM;
t->mem_err_info_hdl = SMBIOS_MA_ERRINFO_NONE;
/* Check custom property 'ecc-enabled' */
if (ofnode_read_bool(node, "ecc-enabled"))
t->mem_err_corr = SMBIOS_MA_ERRCORR_SBITECC;
else
t->mem_err_corr = SMBIOS_MA_ERRCORR_UNKNOWN;
/* Read subnodes with 'size' property */
for (child = ofnode_first_subnode(node); ofnode_valid(child);
child = ofnode_next_subnode(child)) {
u64 sz = 0;
const fdt32_t *size;
int len;
size = ofnode_read_prop(child, "size", &len);
if (!size || len < sizeof(fdt32_t) || len % sizeof(fdt32_t))
continue;
/* 64-bit size: <hi lo> or 32-bit size */
if (len >= sizeof(fdt32_t) * 2)
sz = ((u64)fdt32_to_cpu(size[0]) << 32) |
fdt32_to_cpu(size[1]);
else
sz = fdt32_to_cpu(size[0]);
count++;
total += sz;
}
/*
* Number of memory devices associated with this array
* (i.e., how many Type17 entries link to this Type16 array)
*/
t->num_of_mem_dev = count;
/* Use extended field */
t->max_cap = cpu_to_le32(0x80000000);
t->ext_max_cap = cpu_to_le64(total >> 10); /* In KB */
}
static void smbios_pop_type16_si(struct smbios_ctx *ctx,
struct smbios_type16 *t)
{
t->location = smbios_get_val_si(ctx, "location", SYSID_NONE,
SMBIOS_MA_LOCATION_UNKNOWN);
t->use = smbios_get_val_si(ctx, "use", SYSID_NONE,
SMBIOS_MA_USE_UNKNOWN);
t->mem_err_corr = smbios_get_val_si(ctx, "memory-error-correction", SYSID_NONE,
SMBIOS_MA_ERRCORR_UNKNOWN);
t->max_cap = smbios_get_val_si(ctx, "maximum-capacity", SYSID_NONE, 0);
t->mem_err_info_hdl = smbios_get_val_si(ctx, "memory-error-information-handle",
SYSID_NONE, SMBIOS_MA_ERRINFO_NONE);
t->num_of_mem_dev = smbios_get_val_si(ctx, "number-of-memory-devices", SYSID_NONE, 1);
t->ext_max_cap = smbios_get_u64_si(ctx, "extended-maximum-capacity", SYSID_NONE, 0);
}
static int smbios_write_type16_1array(ulong *current, int handle,
struct smbios_ctx *ctx, int idx,
int type)
{
struct smbios_type16 *t;
int len = sizeof(*t);
u8 *eos_addr;
void *hdl;
size_t hdl_size;
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_PHYS_MEMORY_ARRAY, len, handle);
/* eos is at the end of the structure */
eos_addr = (u8 *)t + len - sizeof(t->eos);
smbios_set_eos(ctx, eos_addr);
if (type == SMBIOS_MEM_CUSTOM)
smbios_pop_type16_si(ctx, t);
else if (type == SMBIOS_MEM_FDT_MEMCON_NODE)
smbios_pop_type16_from_memcontroller_node(ctx->node, t);
/* Save the memory array handles */
if (!sysinfo_get_data(ctx->dev, SYSID_SM_MEMARRAY_HANDLE, &hdl,
&hdl_size) &&
hdl_size == SYSINFO_MEM_HANDLE_MAX * sizeof(u16))
*((u16 *)hdl + idx) = handle;
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_write_type16(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
int len;
struct smbios_ctx ctx_bak;
ofnode child;
int idx;
u64 total = 0;
int count = 0;
int hdl_base = *handle;
if (!IS_ENABLED(CONFIG_OF_CONTROL))
return 0; /* Error, return 0-length */
/* Step 1: Scan any subnode exists under 'memory-array' */
len = smbios_scan_subnodes(current, ctx, handle,
smbios_write_type16_1array,
SMBIOS_MEM_CUSTOM);
if (len)
return len;
/* Step 2: Scan 'memory' node from the entire FDT */
for (child = ofnode_first_subnode(ofnode_root());
ofnode_valid(child); child = ofnode_next_subnode(child)) {
const char *str;
/* Look up for 'device_type = "memory"' */
str = ofnode_read_string(child, "device_type");
if (str && !strcmp(str, "memory")) {
count++;
total += smbios_pop_size_from_memory_node(child);
}
}
/*
* Generate one type16 instance for all 'memory' nodes,
* use idx=0 implicitly
*/
if (count)
len += smbios_write_type16_sum_memory_nodes(current, *handle,
ctx, count, total);
/* Step 3: Scan 'memory-controller' node from the entire FDT */
/* idx starts from 1 */
memcpy(&ctx_bak, ctx, sizeof(ctx_bak));
for (idx = 1, child = ofnode_first_subnode(ofnode_root());
ofnode_valid(child); child = ofnode_next_subnode(child)) {
const char *compat;
const char *name;
/*
* Look up for node with name or property 'compatible'
* containing 'memory-controller'.
*/
name = ofnode_get_name(child);
compat = ofnode_read_string(child, "compatible");
if ((!compat || !strstr(compat, "memory-controller")) &&
(!name || !strstr(name, "memory-controller")))
continue;
*handle = hdl_base + idx;
ctx->node = child;
/*
* Generate one type16 instance for each 'memory-controller'
* node, sum the 'size' of all subnodes.
*/
len += smbios_write_type16_1array(current, *handle, ctx, idx,
SMBIOS_MEM_FDT_MEMCON_NODE);
idx++;
memcpy(ctx, &ctx_bak, sizeof(*ctx));
}
return len;
}
static void smbios_pop_type17_general_si(struct smbios_ctx *ctx,
struct smbios_type17 *t)
{
t->mem_err_info_hdl =
smbios_get_val_si(ctx, "memory-error-information-handle",
SYSID_NONE, SMBIOS_MD_ERRINFO_NONE);
t->total_width = smbios_get_val_si(ctx, "total-width", SYSID_NONE, 0);
t->data_width = smbios_get_val_si(ctx, "data-width", SYSID_NONE, 0);
t->form_factor = smbios_get_val_si(ctx, "form-factor",
SYSID_NONE, SMBIOS_MD_FF_UNKNOWN);
t->dev_set = smbios_get_val_si(ctx, "device-set", SYSID_NONE,
SMBIOS_MD_DEVSET_UNKNOWN);
t->dev_locator = smbios_add_prop_si(ctx, "device-locator", SYSID_NONE,
NULL);
t->bank_locator = smbios_add_prop_si(ctx, "bank-locator", SYSID_NONE,
NULL);
t->mem_type = smbios_get_val_si(ctx, "memory-type",
SYSID_NONE, SMBIOS_MD_TYPE_UNKNOWN);
t->type_detail = smbios_get_val_si(ctx, "type-detail",
SYSID_NONE, SMBIOS_MD_TD_UNKNOWN);
t->speed = smbios_get_val_si(ctx, "speed", SYSID_NONE,
SMBIOS_MD_SPEED_UNKNOWN);
t->manufacturer = smbios_add_prop_si(ctx, "manufacturer", SYSID_NONE,
NULL);
t->serial_number = smbios_add_prop_si(ctx, "serial-number", SYSID_NONE,
NULL);
t->asset_tag = smbios_add_prop_si(ctx, "asset-tag", SYSID_NONE, NULL);
t->part_number = smbios_add_prop_si(ctx, "part-number", SYSID_NONE,
NULL);
t->attributes = smbios_get_val_si(ctx, "attributes", SYSID_NONE,
SMBIOS_MD_ATTR_RANK_UNKNOWN);
t->config_mem_speed = smbios_get_val_si(ctx, "configured-memory-speed",
SYSID_NONE,
SMBIOS_MD_CONFSPEED_UNKNOWN);
t->min_voltage = smbios_get_val_si(ctx, "minimum-voltage", SYSID_NONE,
SMBIOS_MD_VOLTAGE_UNKNOWN);
t->max_voltage = smbios_get_val_si(ctx, "maximum-voltage", SYSID_NONE,
SMBIOS_MD_VOLTAGE_UNKNOWN);
t->config_voltage = smbios_get_val_si(ctx, "configured-voltage",
SYSID_NONE,
SMBIOS_MD_VOLTAGE_UNKNOWN);
t->mem_tech = smbios_get_val_si(ctx, "memory-technology",
SYSID_NONE, SMBIOS_MD_TECH_UNKNOWN);
t->mem_op_mode_cap =
smbios_get_val_si(ctx, "memory-operating-mode-capability",
SYSID_NONE, SMBIOS_MD_OPMC_UNKNOWN);
t->fw_ver = smbios_add_prop_si(ctx, "firmware-version", SYSID_NONE,
NULL);
t->module_man_id = smbios_get_val_si(ctx, "module-manufacturer-id",
SYSID_NONE, 0);
t->module_prod_id = smbios_get_val_si(ctx, "module-product-id",
SYSID_NONE, 0);
t->mem_subsys_con_man_id =
smbios_get_val_si(ctx,
"memory-subsystem-controller-manufacturer-id",
SYSID_NONE, 0);
t->mem_subsys_con_prod_id =
smbios_get_val_si(ctx,
"memory-subsystem-controller-product-id",
SYSID_NONE, 0);
t->nonvolatile_size = smbios_get_u64_si(ctx, "non-volatile-size",
SYSID_NONE,
SMBIOS_MS_PORT_SIZE_UNKNOWN);
t->volatile_size = smbios_get_u64_si(ctx, "volatile-size",
SYSID_NONE,
SMBIOS_MS_PORT_SIZE_UNKNOWN);
t->cache_size = smbios_get_u64_si(ctx, "cache-size",
SYSID_NONE,
SMBIOS_MS_PORT_SIZE_UNKNOWN);
t->logical_size = smbios_get_u64_si(ctx, "logical-size",
SYSID_NONE,
SMBIOS_MS_PORT_SIZE_UNKNOWN);
t->ext_speed = smbios_get_val_si(ctx, "extended-speed", SYSID_NONE, 0);
t->ext_config_mem_speed =
smbios_get_val_si(ctx, "extended-configured-memory-speed",
SYSID_NONE, 0);
t->pmic0_man_id = smbios_get_val_si(ctx, "pmic0-manufacturer-id",
SYSID_NONE, 0);
t->pmic0_rev_num = smbios_get_val_si(ctx, "pmic0-revision-number",
SYSID_NONE, 0);
t->rcd_man_id = smbios_get_val_si(ctx, "rcd-manufacturer-id",
SYSID_NONE, 0);
t->rcd_rev_num = smbios_get_val_si(ctx, "rcd-revision-number",
SYSID_NONE, 0);
}
static void
smbios_pop_type17_size_from_memory_node(ofnode node, struct smbios_type17 *t)
{
const fdt32_t *reg;
int len;
u64 sz;
u32 size_mb;
/* Read property 'reg' from the node */
reg = ofnode_read_prop(node, "reg", &len);
if (!reg || len < sizeof(fdt32_t) * 4 || len % sizeof(fdt32_t))
return;
/* Combine hi/lo for size (typically 64-bit) */
sz = ((u64)fdt32_to_cpu(reg[2]) << 32) | fdt32_to_cpu(reg[3]);
/* Convert size to MB */
size_mb = (u32)(sz >> 20); /* 1 MB = 2^20 */
if (size_mb < SMBIOS_MD_SIZE_EXT) {
t->size = cpu_to_le16(size_mb);
t->ext_size = 0;
return;
}
t->size = cpu_to_le16(SMBIOS_MD_SIZE_EXT); /* Signal extended used */
t->ext_size = cpu_to_le32((u32)(sz >> 10)); /* In KB */
}
static void smbios_pop_type17_size_si(struct smbios_ctx *ctx,
struct smbios_type17 *t)
{
t->size = smbios_get_val_si(ctx, "size", SYSID_NONE,
SMBIOS_MD_SIZE_UNKNOWN);
t->ext_size = smbios_get_val_si(ctx, "extended-size", SYSID_NONE, 0);
}
static int
smbios_scan_memctrl_subnode(ulong *current, int *handle, struct smbios_ctx *ctx,
int idx, smbios_write_memctrlnode cb)
{
int total_len = 0;
ofnode child;
int i = 0;
int hdl_base = *handle;
u64 base = 0;
/*
* Enumerate all subnodes of 'memory-controller' that contain 'size'
* property and generate one instance for each.
*/
for (child = ofnode_first_subnode(ctx->node); ofnode_valid(child);
child = ofnode_next_subnode(child)) {
u64 sz = 0;
const fdt32_t *size;
int proplen;
size = ofnode_read_prop(child, "size", &proplen);
if (!size || proplen < sizeof(fdt32_t) ||
proplen % sizeof(fdt32_t))
continue;
/* 64-bit size: <hi lo> or 32-bit size */
if (proplen >= sizeof(fdt32_t) * 2)
sz = ((u64)fdt32_to_cpu(size[0]) << 32) |
fdt32_to_cpu(size[1]);
else
sz = fdt32_to_cpu(size[0]);
*handle = hdl_base + i;
total_len += cb(current, *handle, ctx, idx, base, sz);
base += sz;
i++;
}
return total_len;
}
static int
smbios_write_type17_from_memctrl_node(ulong *current, int handle,
struct smbios_ctx *ctx, int idx,
u64 __maybe_unused base, u64 sz)
{
struct smbios_type17 *t;
int len;
u8 *eos_addr;
u32 size_mb;
void *hdl;
size_t hdl_size;
len = sizeof(*t);
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_MEMORY_DEVICE, len, handle);
/* eos is at the end of the structure */
eos_addr = (u8 *)t + len - sizeof(t->eos);
smbios_set_eos(ctx, eos_addr);
/* Read the memory array handles */
if (!sysinfo_get_data(ctx->dev, SYSID_SM_MEMARRAY_HANDLE, &hdl,
&hdl_size) &&
hdl_size == SYSINFO_MEM_HANDLE_MAX * sizeof(u16))
t->phy_mem_array_hdl = *((u16 *)hdl + idx);
/* Convert to MB */
size_mb = (u32)(sz >> 20);
if (size_mb < SMBIOS_MD_SIZE_EXT) {
/* Use 16-bit size field */
t->size = cpu_to_le16(size_mb); /* In MB */
t->ext_size = cpu_to_le32(0);
} else {
/* Signal use of extended size field */
t->size = cpu_to_le16(SMBIOS_MD_SIZE_EXT);
t->ext_size = cpu_to_le32((u32)(sz >> 10)); /* In KB */
}
/* Write other general fields */
smbios_pop_type17_general_si(ctx, t);
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_write_type17_mem(ulong *current, int handle,
struct smbios_ctx *ctx, int idx,
int type)
{
struct smbios_type17 *t;
int len;
u8 *eos_addr;
void *hdl;
size_t hdl_size;
len = sizeof(*t);
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_MEMORY_DEVICE, len, handle);
/* eos is at the end of the structure */
eos_addr = (u8 *)t + len - sizeof(t->eos);
smbios_set_eos(ctx, eos_addr);
if (type == SMBIOS_MEM_CUSTOM) {
smbios_pop_type17_size_si(ctx, t);
t->phy_mem_array_hdl =
smbios_get_val_si(ctx, "physical-memory-array-handle",
SYSID_NONE, 0);
} else if (type == SMBIOS_MEM_FDT_MEM_NODE) {
smbios_pop_type17_size_from_memory_node(ctx->node, t);
/* Read the memory array handles */
if (!sysinfo_get_data(ctx->dev, SYSID_SM_MEMARRAY_HANDLE, &hdl,
&hdl_size) &&
hdl_size == SYSINFO_MEM_HANDLE_MAX * sizeof(u16))
t->phy_mem_array_hdl = *((u16 *)hdl + idx);
}
/* Write other general fields */
smbios_pop_type17_general_si(ctx, t);
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_scan_mem_nodes(ulong *current, int *handle,
struct smbios_ctx *ctx,
smbios_write_memnode mem_cb,
int *idx)
{
int len = 0;
struct smbios_ctx ctx_bak;
ofnode child;
int hdl_base = *handle;
memcpy(&ctx_bak, ctx, sizeof(ctx_bak));
for (child = ofnode_first_subnode(ofnode_root());
ofnode_valid(child); child = ofnode_next_subnode(child)) {
const char *str;
/* Look up for 'device_type = "memory"' */
str = ofnode_read_string(child, "device_type");
if (!str || strcmp(str, "memory"))
continue;
ctx->node = child;
*handle = hdl_base + *idx;
/* Generate one instance for each 'memory' node */
len += mem_cb(current, *handle, ctx, *idx,
SMBIOS_MEM_FDT_MEM_NODE);
memcpy(ctx, &ctx_bak, sizeof(*ctx));
(*idx)++;
}
return len;
}
static int smbios_scan_mctrl_subnodes(ulong *current, int *handle,
struct smbios_ctx *ctx,
smbios_write_memctrlnode mctrl_wcb,
int *idx)
{
int len = 0;
struct smbios_ctx ctx_bak;
ofnode child;
memcpy(&ctx_bak, ctx, sizeof(ctx_bak));
for (child = ofnode_first_subnode(ofnode_root());
ofnode_valid(child); child = ofnode_next_subnode(child)) {
const char *compat;
const char *name;
/*
* Look up for node with name or property 'compatible'
* containing 'memory-controller'.
*/
name = ofnode_get_name(child);
compat = ofnode_read_string(child, "compatible");
if ((!compat || !strstr(compat, "memory-controller")) &&
(!name || !strstr(name, "memory-controller")))
continue;
(*handle)++;
ctx->node = child;
/*
* Generate one instance for each subnode of
* 'memory-controller' which contains property 'size'.
*/
len += smbios_scan_memctrl_subnode(current, handle, ctx,
*idx, mctrl_wcb);
memcpy(ctx, &ctx_bak, sizeof(*ctx));
(*idx)++;
}
return len;
}
static int smbios_write_type1719(ulong *current, int *handle,
struct smbios_ctx *ctx,
smbios_write_memnode mem_cb,
smbios_write_memctrlnode mctrl_wcb)
{
int len = 0;
int idx;
if (!IS_ENABLED(CONFIG_OF_CONTROL))
return 0; /* Error, return 0-length */
/* Step 1: Scan any subnode exists */
len = smbios_scan_subnodes(current, ctx, handle, mem_cb,
SMBIOS_MEM_CUSTOM);
if (len)
return len;
/* Step 2: Scan 'memory' node from the entire FDT */
idx = 0;
len += smbios_scan_mem_nodes(current, handle, ctx, mem_cb, &idx);
/* Step 3: Scan 'memory-controller' node from the entire FDT */
len += smbios_scan_mctrl_subnodes(current, handle, ctx, mctrl_wcb, &idx);
return len;
}
static int smbios_write_type17(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
return smbios_write_type1719(current, handle, ctx,
smbios_write_type17_mem,
smbios_write_type17_from_memctrl_node);
}
static void smbios_pop_type19_general_si(struct smbios_ctx *ctx,
struct smbios_type19 *t)
{
t->partition_wid =
smbios_get_val_si(ctx, "partition-width ",
SYSID_NONE, SMBIOS_MAMA_PW_DEF);
}
static void smbios_pop_type19_addr_si(struct smbios_ctx *ctx,
struct smbios_type19 *t)
{
t->start_addr = smbios_get_val_si(ctx, "starting-address", SYSID_NONE,
0);
t->end_addr = smbios_get_val_si(ctx, "ending-address", SYSID_NONE, 0);
t->ext_start_addr = smbios_get_u64_si(ctx, "extended-starting-address",
SYSID_NONE, 0);
t->ext_end_addr = smbios_get_u64_si(ctx, "extended-ending-address",
SYSID_NONE, 0);
}
static void
smbios_pop_type19_addr_from_memory_node(ofnode node, struct smbios_type19 *t)
{
const fdt32_t *reg;
int len;
u64 sz;
u64 addr;
/* Read property 'reg' from the node */
reg = ofnode_read_prop(node, "reg", &len);
if (!reg || len < sizeof(fdt32_t) * 4 || len % sizeof(fdt32_t))
return;
/* Combine hi/lo for size and address (typically 64-bit) */
sz = ((u64)fdt32_to_cpu(reg[2]) << 32) | fdt32_to_cpu(reg[3]);
addr = ((u64)fdt32_to_cpu(reg[0]) << 32) | fdt32_to_cpu(reg[1]);
t->ext_start_addr = cpu_to_le64(addr);
t->ext_end_addr = cpu_to_le64(addr + sz - 1);
/* If address range fits in 32-bit, populate legacy fields */
if ((addr + sz - 1) <= 0xFFFFFFFFULL) {
t->start_addr = cpu_to_le32((u32)addr);
t->end_addr = cpu_to_le32((u32)(addr + sz - 1));
} else {
t->start_addr = cpu_to_le32(0xFFFFFFFF);
t->end_addr = cpu_to_le32(0xFFFFFFFF);
}
}
static int
smbios_write_type19_from_memctrl_node(ulong *current, int handle,
struct smbios_ctx *ctx, int idx,
u64 base, u64 sz)
{
struct smbios_type19 *t;
int len;
u8 *eos_addr;
void *hdl;
size_t hdl_size;
len = sizeof(*t);
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_MEMORY_ARRAY_MAPPED_ADDRESS, len, handle);
/* eos is at the end of the structure */
eos_addr = (u8 *)t + len - sizeof(t->eos);
smbios_set_eos(ctx, eos_addr);
/* Read the memory array handles */
if (!sysinfo_get_data(ctx->dev, SYSID_SM_MEMARRAY_HANDLE, &hdl,
&hdl_size) &&
hdl_size == SYSINFO_MEM_HANDLE_MAX * sizeof(u16))
t->mem_array_hdl = *((u16 *)hdl + idx);
t->ext_start_addr = cpu_to_le64(base);
t->ext_end_addr = cpu_to_le64(base + sz - 1);
if ((base + sz - 1) <= 0xFFFFFFFFULL) {
t->start_addr = cpu_to_le32((u32)base);
t->end_addr = cpu_to_le32((u32)(base + sz - 1));
} else {
t->start_addr = cpu_to_le32(0xFFFFFFFF);
t->end_addr = cpu_to_le32(0xFFFFFFFF);
}
/* Write other general fields */
smbios_pop_type19_general_si(ctx, t);
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_write_type19_mem(ulong *current, int handle,
struct smbios_ctx *ctx, int idx,
int type)
{
struct smbios_type19 *t;
int len;
u8 *eos_addr;
void *hdl;
size_t hdl_size;
len = sizeof(*t);
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_MEMORY_ARRAY_MAPPED_ADDRESS, len, handle);
/* eos is at the end of the structure */
eos_addr = (u8 *)t + len - sizeof(t->eos);
smbios_set_eos(ctx, eos_addr);
if (type == SMBIOS_MEM_CUSTOM) {
smbios_pop_type19_addr_si(ctx, t);
t->mem_array_hdl = smbios_get_val_si(ctx, "memory-array-handle",
SYSID_NONE, 0);
} else if (type == SMBIOS_MEM_FDT_MEM_NODE) {
smbios_pop_type19_addr_from_memory_node(ctx->node, t);
/* Read the memory array handles */
if (!sysinfo_get_data(ctx->dev, SYSID_SM_MEMARRAY_HANDLE, &hdl,
&hdl_size) &&
hdl_size == SYSINFO_MEM_HANDLE_MAX * sizeof(u16))
t->mem_array_hdl = *((u16 *)hdl + idx);
}
/* Write other general fields */
smbios_pop_type19_general_si(ctx, t);
len = t->hdr.length + smbios_string_table_len(ctx);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_write_type19(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
return smbios_write_type1719(current, handle, ctx,
smbios_write_type19_mem,
smbios_write_type19_from_memctrl_node);
}
#endif /* #if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE) */
static int smbios_write_type32(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
struct smbios_type32 *t;
int len = sizeof(*t);
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_SYSTEM_BOOT_INFORMATION, len, *handle);
smbios_set_eos(ctx, t->eos);
*current += len;
unmap_sysmem(t);
return len;
}
static int smbios_write_type127(ulong *current, int *handle,
struct smbios_ctx *ctx)
{
struct smbios_type127 *t;
int len = sizeof(*t);
t = map_sysmem(*current, len);
memset(t, 0, len);
fill_smbios_header(t, SMBIOS_END_OF_TABLE, len, *handle);
*current += len;
unmap_sysmem(t);
return len;
}
static struct smbios_write_method smbios_write_funcs[] = {
{ smbios_write_type0, "bios", },
{ smbios_write_type1, "system", },
{ smbios_write_type2, "baseboard", },
/* Type 3 must immediately follow type 2 due to chassis handle. */
{ smbios_write_type3, "chassis", },
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
/* Type 7 must ahead of type 4 to get cache handles. */
{ smbios_write_type7, "cache", },
#endif
{ smbios_write_type4, "processor"},
#if IS_ENABLED(CONFIG_GENERATE_SMBIOS_TABLE_VERBOSE)
{ smbios_write_type9, "system-slot"},
{ smbios_write_type16, "memory-array"},
{ smbios_write_type17, "memory-device"},
{ smbios_write_type19, "memory-array-mapped-address"},
#endif
{ smbios_write_type32, },
{ smbios_write_type127 },
};
ulong write_smbios_table(ulong addr)
{
ofnode parent_node = ofnode_null();
ulong table_addr, start_addr;
struct smbios3_entry *se;
struct smbios_ctx ctx;
ulong tables;
int len = 0;
int handle = 0;
int i;
ctx.node = ofnode_null();
if (CONFIG_IS_ENABLED(SYSINFO)) {
uclass_first_device(UCLASS_SYSINFO, &ctx.dev);
if (ctx.dev) {
int ret;
parent_node = dev_read_subnode(ctx.dev, "smbios");
ret = sysinfo_detect(ctx.dev);
/*
* ignore the error since many boards don't implement
* this and we can still use the info in the devicetree
*/
ret = log_msg_ret("sys", ret);
}
} else {
ctx.dev = NULL;
}
start_addr = addr;
/* move past the (so-far-unwritten) header to start writing structs */
addr = ALIGN(addr + sizeof(struct smbios3_entry), 16);
tables = addr;
/* populate minimum required tables */
for (i = 0; i < ARRAY_SIZE(smbios_write_funcs); i++) {
const struct smbios_write_method *method;
method = &smbios_write_funcs[i];
ctx.subnode_name = NULL;
if (method->subnode_name) {
ctx.subnode_name = method->subnode_name;
if (ofnode_valid(parent_node))
ctx.node = ofnode_find_subnode(parent_node,
method->subnode_name);
}
len += method->write((ulong *)&addr, &handle, &ctx);
handle++;
}
/*
* We must use a pointer here so things work correctly on sandbox. The
* user of this table is not aware of the mapping of addresses to
* sandbox's DRAM buffer.
*/
table_addr = (ulong)map_sysmem(tables, 0);
/* now go back and write the SMBIOS3 header */
se = map_sysmem(start_addr, sizeof(struct smbios3_entry));
memset(se, '\0', sizeof(struct smbios3_entry));
memcpy(se->anchor, "_SM3_", 5);
se->length = sizeof(struct smbios3_entry);
se->major_ver = SMBIOS_MAJOR_VER;
se->minor_ver = SMBIOS_MINOR_VER;
se->doc_rev = 0;
se->entry_point_rev = 1;
se->table_maximum_size = len;
se->struct_table_address = table_addr;
se->checksum = table_compute_checksum(se, sizeof(struct smbios3_entry));
unmap_sysmem(se);
return addr;
}
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