freebsd-skq/stand/libsa/smbios.c
Emmanuel Vadot 9060f2c392 libsa: smbios: Parse the chassis type and export it as smbios.chassis.type
It can be useful to know what type of machine we are running on for desktop
related thing.
It also allow us to support all the DMI variable that linux driver can fetch.

MFC after:	1 week
Sponsored by:	Sponsored-by: The FreeBSD Foundation
2020-08-20 12:50:49 +00:00

533 lines
14 KiB
C

/*-
* Copyright (c) 2005-2009 Jung-uk Kim <jkim@FreeBSD.org>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
#include <stand.h>
#include <sys/endian.h>
#define PTOV(x) ptov(x)
/*
* Detect SMBIOS and export information about the SMBIOS into the
* environment.
*
* System Management BIOS Reference Specification, v2.6 Final
* http://www.dmtf.org/standards/published_documents/DSP0134_2.6.0.pdf
*/
/*
* 2.1.1 SMBIOS Structure Table Entry Point
*
* "On non-EFI systems, the SMBIOS Entry Point structure, described below, can
* be located by application software by searching for the anchor-string on
* paragraph (16-byte) boundaries within the physical memory address range
* 000F0000h to 000FFFFFh. This entry point encapsulates an intermediate anchor
* string that is used by some existing DMI browsers."
*/
#define SMBIOS_START 0xf0000
#define SMBIOS_LENGTH 0x10000
#define SMBIOS_STEP 0x10
#define SMBIOS_SIG "_SM_"
#define SMBIOS_DMI_SIG "_DMI_"
#define SMBIOS_GET8(base, off) (*(uint8_t *)((base) + (off)))
#define SMBIOS_GET16(base, off) (*(uint16_t *)((base) + (off)))
#define SMBIOS_GET32(base, off) (*(uint32_t *)((base) + (off)))
#define SMBIOS_GETLEN(base) SMBIOS_GET8(base, 0x01)
#define SMBIOS_GETSTR(base) ((base) + SMBIOS_GETLEN(base))
struct smbios_attr {
int probed;
caddr_t addr;
size_t length;
size_t count;
int major;
int minor;
int ver;
const char* bios_vendor;
const char* maker;
const char* product;
uint32_t enabled_memory;
uint32_t old_enabled_memory;
uint8_t enabled_sockets;
uint8_t populated_sockets;
};
static struct smbios_attr smbios;
static uint8_t
smbios_checksum(const caddr_t addr, const uint8_t len)
{
uint8_t sum;
int i;
for (sum = 0, i = 0; i < len; i++)
sum += SMBIOS_GET8(addr, i);
return (sum);
}
static caddr_t
smbios_sigsearch(const caddr_t addr, const uint32_t len)
{
caddr_t cp;
/* Search on 16-byte boundaries. */
for (cp = addr; cp < addr + len; cp += SMBIOS_STEP)
if (strncmp(cp, SMBIOS_SIG, 4) == 0 &&
smbios_checksum(cp, SMBIOS_GET8(cp, 0x05)) == 0 &&
strncmp(cp + 0x10, SMBIOS_DMI_SIG, 5) == 0 &&
smbios_checksum(cp + 0x10, 0x0f) == 0)
return (cp);
return (NULL);
}
static const char*
smbios_getstring(caddr_t addr, const int offset)
{
caddr_t cp;
int i, idx;
idx = SMBIOS_GET8(addr, offset);
if (idx != 0) {
cp = SMBIOS_GETSTR(addr);
for (i = 1; i < idx; i++)
cp += strlen(cp) + 1;
return cp;
}
return (NULL);
}
static void
smbios_setenv(const char *name, caddr_t addr, const int offset)
{
const char* val;
val = smbios_getstring(addr, offset);
if (val != NULL)
setenv(name, val, 1);
}
#ifdef SMBIOS_SERIAL_NUMBERS
#define UUID_SIZE 16
#define UUID_TYPE uint32_t
#define UUID_STEP sizeof(UUID_TYPE)
#define UUID_ALL_BITS (UUID_SIZE / UUID_STEP)
#define UUID_GET(base, off) (*(UUID_TYPE *)((base) + (off)))
static void
smbios_setuuid(const char *name, const caddr_t addr, const int ver)
{
char uuid[37];
int byteorder, i, ones, zeros;
UUID_TYPE n;
uint32_t f1;
uint16_t f2, f3;
for (i = 0, ones = 0, zeros = 0; i < UUID_SIZE; i += UUID_STEP) {
n = UUID_GET(addr, i) + 1;
if (zeros == 0 && n == 0)
ones++;
else if (ones == 0 && n == 1)
zeros++;
else
break;
}
if (ones != UUID_ALL_BITS && zeros != UUID_ALL_BITS) {
/*
* 3.3.2.1 System UUID
*
* "Although RFC 4122 recommends network byte order for all
* fields, the PC industry (including the ACPI, UEFI, and
* Microsoft specifications) has consistently used
* little-endian byte encoding for the first three fields:
* time_low, time_mid, time_hi_and_version. The same encoding,
* also known as wire format, should also be used for the
* SMBIOS representation of the UUID."
*
* Note: We use network byte order for backward compatibility
* unless SMBIOS version is 2.6+ or little-endian is forced.
*/
#if defined(SMBIOS_LITTLE_ENDIAN_UUID)
byteorder = LITTLE_ENDIAN;
#elif defined(SMBIOS_NETWORK_ENDIAN_UUID)
byteorder = BIG_ENDIAN;
#else
byteorder = ver < 0x0206 ? BIG_ENDIAN : LITTLE_ENDIAN;
#endif
if (byteorder != LITTLE_ENDIAN) {
f1 = ntohl(SMBIOS_GET32(addr, 0));
f2 = ntohs(SMBIOS_GET16(addr, 4));
f3 = ntohs(SMBIOS_GET16(addr, 6));
} else {
f1 = le32toh(SMBIOS_GET32(addr, 0));
f2 = le16toh(SMBIOS_GET16(addr, 4));
f3 = le16toh(SMBIOS_GET16(addr, 6));
}
sprintf(uuid,
"%08x-%04x-%04x-%02x%02x-%02x%02x%02x%02x%02x%02x",
f1, f2, f3, SMBIOS_GET8(addr, 8), SMBIOS_GET8(addr, 9),
SMBIOS_GET8(addr, 10), SMBIOS_GET8(addr, 11),
SMBIOS_GET8(addr, 12), SMBIOS_GET8(addr, 13),
SMBIOS_GET8(addr, 14), SMBIOS_GET8(addr, 15));
setenv(name, uuid, 1);
}
}
#undef UUID_SIZE
#undef UUID_TYPE
#undef UUID_STEP
#undef UUID_ALL_BITS
#undef UUID_GET
#endif
static const char *
smbios_parse_chassis_type(caddr_t addr)
{
int type;
type = SMBIOS_GET8(addr, 0x5);
switch (type) {
case 0x1:
return ("Other");
case 0x2:
return ("Unknown");
case 0x3:
return ("Desktop");
case 0x4:
return ("Low Profile Desktop");
case 0x5:
return ("Pizza Box");
case 0x6:
return ("Mini Tower");
case 0x7:
return ("Tower");
case 0x8:
return ("Portable");
case 0x9:
return ("Laptop");
case 0xA:
return ("Notebook");
case 0xB:
return ("Hand Held");
case 0xC:
return ("Docking Station");
case 0xD:
return ("All in One");
case 0xE:
return ("Sub Notebook");
case 0xF:
return ("Lunch Box");
case 0x10:
return ("Space-saving");
case 0x11:
return ("Main Server Chassis");
case 0x12:
return ("Expansion Chassis");
case 0x13:
return ("SubChassis");
case 0x14:
return ("Bus Expansion Chassis");
case 0x15:
return ("Peripheral Chassis");
case 0x16:
return ("RAID Chassis");
case 0x17:
return ("Rack Mount Chassis");
case 0x18:
return ("Sealed-case PC");
case 0x19:
return ("Multi-system chassis");
case 0x1A:
return ("Compact PCI");
case 0x1B:
return ("Advanced TCA");
case 0x1C:
return ("Blade");
case 0x1D:
return ("Blade Enclosure");
case 0x1E:
return ("Tablet");
case 0x1F:
return ("Convertible");
case 0x20:
return ("Detachable");
case 0x21:
return ("IoT Gateway");
case 0x22:
return ("Embedded PC");
case 0x23:
return ("Mini PC");
case 0x24:
return ("Stick PC");
}
return ("Undefined");
}
static caddr_t
smbios_parse_table(const caddr_t addr)
{
caddr_t cp;
int proc, size, osize, type;
type = SMBIOS_GET8(addr, 0); /* 3.1.2 Structure Header Format */
switch(type) {
case 0: /* 3.3.1 BIOS Information (Type 0) */
smbios_setenv("smbios.bios.vendor", addr, 0x04);
smbios_setenv("smbios.bios.version", addr, 0x05);
smbios_setenv("smbios.bios.reldate", addr, 0x08);
break;
case 1: /* 3.3.2 System Information (Type 1) */
smbios_setenv("smbios.system.maker", addr, 0x04);
smbios_setenv("smbios.system.product", addr, 0x05);
smbios_setenv("smbios.system.version", addr, 0x06);
#ifdef SMBIOS_SERIAL_NUMBERS
smbios_setenv("smbios.system.serial", addr, 0x07);
smbios_setuuid("smbios.system.uuid", addr + 0x08, smbios.ver);
#endif
if (smbios.major > 2 ||
(smbios.major == 2 && smbios.minor >= 4)) {
smbios_setenv("smbios.system.sku", addr, 0x19);
smbios_setenv("smbios.system.family", addr, 0x1a);
}
break;
case 2: /* 3.3.3 Base Board (or Module) Information (Type 2) */
smbios_setenv("smbios.planar.maker", addr, 0x04);
smbios_setenv("smbios.planar.product", addr, 0x05);
smbios_setenv("smbios.planar.version", addr, 0x06);
#ifdef SMBIOS_SERIAL_NUMBERS
smbios_setenv("smbios.planar.serial", addr, 0x07);
smbios_setenv("smbios.planar.tag", addr, 0x08);
#endif
smbios_setenv("smbios.planar.location", addr, 0x0a);
break;
case 3: /* 3.3.4 System Enclosure or Chassis (Type 3) */
smbios_setenv("smbios.chassis.maker", addr, 0x04);
setenv("smbios.chassis.type", smbios_parse_chassis_type(addr), 1);
smbios_setenv("smbios.chassis.version", addr, 0x06);
#ifdef SMBIOS_SERIAL_NUMBERS
smbios_setenv("smbios.chassis.serial", addr, 0x07);
smbios_setenv("smbios.chassis.tag", addr, 0x08);
#endif
break;
case 4: /* 3.3.5 Processor Information (Type 4) */
/*
* Offset 18h: Processor Status
*
* Bit 7 Reserved, must be 0
* Bit 6 CPU Socket Populated
* 1 - CPU Socket Populated
* 0 - CPU Socket Unpopulated
* Bit 5:3 Reserved, must be zero
* Bit 2:0 CPU Status
* 0h - Unknown
* 1h - CPU Enabled
* 2h - CPU Disabled by User via BIOS Setup
* 3h - CPU Disabled by BIOS (POST Error)
* 4h - CPU is Idle, waiting to be enabled
* 5-6h - Reserved
* 7h - Other
*/
proc = SMBIOS_GET8(addr, 0x18);
if ((proc & 0x07) == 1)
smbios.enabled_sockets++;
if ((proc & 0x40) != 0)
smbios.populated_sockets++;
break;
case 6: /* 3.3.7 Memory Module Information (Type 6, Obsolete) */
/*
* Offset 0Ah: Enabled Size
*
* Bit 7 Bank connection
* 1 - Double-bank connection
* 0 - Single-bank connection
* Bit 6:0 Size (n), where 2**n is the size in MB
* 7Dh - Not determinable (Installed Size only)
* 7Eh - Module is installed, but no memory
* has been enabled
* 7Fh - Not installed
*/
osize = SMBIOS_GET8(addr, 0x0a) & 0x7f;
if (osize > 0 && osize < 22)
smbios.old_enabled_memory += 1 << (osize + 10);
break;
case 17: /* 3.3.18 Memory Device (Type 17) */
/*
* Offset 0Ch: Size
*
* Bit 15 Granularity
* 1 - Value is in kilobytes units
* 0 - Value is in megabytes units
* Bit 14:0 Size
*/
size = SMBIOS_GET16(addr, 0x0c);
if (size != 0 && size != 0xffff)
smbios.enabled_memory += (size & 0x8000) != 0 ?
(size & 0x7fff) : (size << 10);
break;
default: /* skip other types */
break;
}
/* Find structure terminator. */
cp = SMBIOS_GETSTR(addr);
while (SMBIOS_GET16(cp, 0) != 0)
cp++;
return (cp + 2);
}
static caddr_t
smbios_find_struct(int type)
{
caddr_t dmi;
size_t i;
if (smbios.addr == NULL)
return (NULL);
for (dmi = smbios.addr, i = 0;
dmi < smbios.addr + smbios.length && i < smbios.count; i++) {
if (SMBIOS_GET8(dmi, 0) == type)
return dmi;
/* Find structure terminator. */
dmi = SMBIOS_GETSTR(dmi);
while (SMBIOS_GET16(dmi, 0) != 0)
dmi++;
dmi += 2;
}
return (NULL);
}
static void
smbios_probe(const caddr_t addr)
{
caddr_t saddr, info;
uintptr_t paddr;
if (smbios.probed)
return;
smbios.probed = 1;
/* Search signatures and validate checksums. */
saddr = smbios_sigsearch(addr ? addr : PTOV(SMBIOS_START),
SMBIOS_LENGTH);
if (saddr == NULL)
return;
smbios.length = SMBIOS_GET16(saddr, 0x16); /* Structure Table Length */
paddr = SMBIOS_GET32(saddr, 0x18); /* Structure Table Address */
smbios.count = SMBIOS_GET16(saddr, 0x1c); /* No of SMBIOS Structures */
smbios.ver = SMBIOS_GET8(saddr, 0x1e); /* SMBIOS BCD Revision */
if (smbios.ver != 0) {
smbios.major = smbios.ver >> 4;
smbios.minor = smbios.ver & 0x0f;
if (smbios.major > 9 || smbios.minor > 9)
smbios.ver = 0;
}
if (smbios.ver == 0) {
smbios.major = SMBIOS_GET8(saddr, 0x06);/* SMBIOS Major Version */
smbios.minor = SMBIOS_GET8(saddr, 0x07);/* SMBIOS Minor Version */
}
smbios.ver = (smbios.major << 8) | smbios.minor;
smbios.addr = PTOV(paddr);
/* Get system information from SMBIOS */
info = smbios_find_struct(0x00);
if (info != NULL) {
smbios.bios_vendor = smbios_getstring(info, 0x04);
}
info = smbios_find_struct(0x01);
if (info != NULL) {
smbios.maker = smbios_getstring(info, 0x04);
smbios.product = smbios_getstring(info, 0x05);
}
}
void
smbios_detect(const caddr_t addr)
{
char buf[16];
caddr_t dmi;
size_t i;
smbios_probe(addr);
if (smbios.addr == NULL)
return;
for (dmi = smbios.addr, i = 0;
dmi < smbios.addr + smbios.length && i < smbios.count; i++)
dmi = smbios_parse_table(dmi);
sprintf(buf, "%d.%d", smbios.major, smbios.minor);
setenv("smbios.version", buf, 1);
if (smbios.enabled_memory > 0 || smbios.old_enabled_memory > 0) {
sprintf(buf, "%u", smbios.enabled_memory > 0 ?
smbios.enabled_memory : smbios.old_enabled_memory);
setenv("smbios.memory.enabled", buf, 1);
}
if (smbios.enabled_sockets > 0) {
sprintf(buf, "%u", smbios.enabled_sockets);
setenv("smbios.socket.enabled", buf, 1);
}
if (smbios.populated_sockets > 0) {
sprintf(buf, "%u", smbios.populated_sockets);
setenv("smbios.socket.populated", buf, 1);
}
}
static int
smbios_match_str(const char* s1, const char* s2)
{
return (s1 == NULL || (s2 != NULL && !strcmp(s1, s2)));
}
int
smbios_match(const char* bios_vendor, const char* maker,
const char* product)
{
/* XXXRP currently, only called from non-EFI. */
smbios_probe(NULL);
return (smbios_match_str(bios_vendor, smbios.bios_vendor) &&
smbios_match_str(maker, smbios.maker) &&
smbios_match_str(product, smbios.product));
}