/* SPDX-License-Identifier: GPL-2.0-or-later */ /* * System Memory information * * Copyright (C) 2000-2002 Alan Cox * Copyright (C) 2002-2020 Jean Delvare * Copyright (C) 2020 Bastien Nocera * * Unless specified otherwise, all references are aimed at the "System * Management BIOS Reference Specification, Version 3.2.0" document, * available from http://www.dmtf.org/standards/smbios. * * Note to contributors: * Please reference every value you add or modify, especially if the * information does not come from the above mentioned specification. * * Additional references: * - Intel AP-485 revision 36 * "Intel Processor Identification and the CPUID Instruction" * http://www.intel.com/support/processors/sb/cs-009861.htm * - DMTF Common Information Model * CIM Schema version 2.19.1 * http://www.dmtf.org/standards/cim/ * - IPMI 2.0 revision 1.0 * "Intelligent Platform Management Interface Specification" * http://developer.intel.com/design/servers/ipmi/spec.htm * - AMD publication #25481 revision 2.28 * "CPUID Specification" * http://www.amd.com/us-en/assets/content_type/white_papers_and_tech_docs/25481.pdf * - BIOS Integrity Services Application Programming Interface version 1.0 * http://www.intel.com/design/archives/wfm/downloads/bisspec.htm * - DMTF DSP0239 version 1.1.0 * "Management Component Transport Protocol (MCTP) IDs and Codes" * http://www.dmtf.org/standards/pmci * - "TPM Main, Part 2 TPM Structures" * Specification version 1.2, level 2, revision 116 * https://trustedcomputinggroup.org/tpm-main-specification/ * - "PC Client Platform TPM Profile (PTP) Specification" * Family "2.0", Level 00, Revision 00.43, January 26, 2015 * https://trustedcomputinggroup.org/pc-client-platform-tpm-profile-ptp-specification/ * - "RedFish Host Interface Specification" (DMTF DSP0270) * https://www.dmtf.org/sites/default/files/DSP0270_1.0.1.pdf */ #include #include "alloc-util.h" #include "fileio.h" #include "main-func.h" #include "string-util.h" #include "udev-util.h" #include "unaligned.h" #include "version.h" #define SUPPORTED_SMBIOS_VER 0x030300 #define OUT_OF_SPEC_STR "" #define SYS_FIRMWARE_DIR "/sys/firmware/dmi/tables" #define SYS_ENTRY_FILE SYS_FIRMWARE_DIR "/smbios_entry_point" #define SYS_TABLE_FILE SYS_FIRMWARE_DIR "/DMI" /* * Per SMBIOS v2.8.0 and later, all structures assume a little-endian * ordering convention. */ #define WORD(x) (unaligned_read_le16(x)) #define DWORD(x) (unaligned_read_le32(x)) #define QWORD(x) (unaligned_read_le64(x)) struct dmi_header { uint8_t type; uint8_t length; uint16_t handle; const uint8_t *data; }; static const char *arg_source_file = NULL; static bool verify_checksum(const uint8_t *buf, size_t len) { uint8_t sum = 0; for (size_t a = 0; a < len; a++) sum += buf[a]; return sum == 0; } /* * Type-independant Stuff */ static const char *dmi_string(const struct dmi_header *dm, uint8_t s) { const char *bp = (const char *) dm->data; if (s == 0) return "Not Specified"; bp += dm->length; for (;s > 1 && !isempty(bp); s--) bp += strlen(bp) + 1; if (isempty(bp)) return ""; return bp; } typedef enum { MEMORY_SIZE_UNIT_BYTES, MEMORY_SIZE_UNIT_KB } MemorySizeUnit; static void dmi_print_memory_size( const char *attr_prefix, const char *attr_suffix, int slot_num, uint64_t code, MemorySizeUnit unit) { if (unit == MEMORY_SIZE_UNIT_KB) code <<= 10; if (slot_num >= 0) printf("%s_%u_%s=%"PRIu64"\n", attr_prefix, slot_num, attr_suffix, code); else printf("%s_%s=%"PRIu64"\n", attr_prefix, attr_suffix, code); } /* * 7.17 Physical Memory Array (Type 16) */ static void dmi_memory_array_location(uint8_t code) { /* 7.17.1 */ static const char *location[] = { [0x01] = "Other", [0x02] = "Unknown", [0x03] = "System Board Or Motherboard", [0x04] = "ISA Add-on Card", [0x05] = "EISA Add-on Card", [0x06] = "PCI Add-on Card", [0x07] = "MCA Add-on Card", [0x08] = "PCMCIA Add-on Card", [0x09] = "Proprietary Add-on Card", [0x0A] = "NuBus", }; static const char *location_0xA0[] = { [0x00] = "PC-98/C20 Add-on Card", /* 0xA0 */ [0x01] = "PC-98/C24 Add-on Card", /* 0xA1 */ [0x02] = "PC-98/E Add-on Card", /* 0xA2 */ [0x03] = "PC-98/Local Bus Add-on Card", /* 0xA3 */ [0x04] = "CXL Flexbus 1.0", /* 0xA4 */ }; const char *str = OUT_OF_SPEC_STR; if (code < ELEMENTSOF(location) && location[code]) str = location[code]; else if (code >= 0xA0 && code < (ELEMENTSOF(location_0xA0) + 0xA0)) str = location_0xA0[code - 0xA0]; printf("MEMORY_ARRAY_LOCATION=%s\n", str); } static void dmi_memory_array_ec_type(uint8_t code) { /* 7.17.3 */ static const char *type[] = { [0x01] = "Other", [0x02] = "Unknown", [0x03] = "None", [0x04] = "Parity", [0x05] = "Single-bit ECC", [0x06] = "Multi-bit ECC", [0x07] = "CRC", }; if (code != 0x03) /* Do not print "None". */ printf("MEMORY_ARRAY_EC_TYPE=%s\n", code < ELEMENTSOF(type) && type[code] ? type[code] : OUT_OF_SPEC_STR); } /* * 7.18 Memory Device (Type 17) */ static void dmi_memory_device_string( const char *attr_suffix, unsigned slot_num, const struct dmi_header *h, uint8_t s) { char *str; str = strdupa_safe(dmi_string(h, s)); str = strstrip(str); if (!isempty(str)) printf("MEMORY_DEVICE_%u_%s=%s\n", slot_num, attr_suffix, str); } static void dmi_memory_device_width( const char *attr_suffix, unsigned slot_num, uint16_t code) { /* If no memory module is present, width may be 0 */ if (!IN_SET(code, 0, 0xFFFF)) printf("MEMORY_DEVICE_%u_%s=%u\n", slot_num, attr_suffix, code); } static void dmi_memory_device_size(unsigned slot_num, uint16_t code) { if (code == 0) return (void) printf("MEMORY_DEVICE_%u_PRESENT=0\n", slot_num); if (code == 0xFFFF) return; uint64_t s = code & 0x7FFF; if (!(code & 0x8000)) s <<= 10; dmi_print_memory_size("MEMORY_DEVICE", "SIZE", slot_num, s, MEMORY_SIZE_UNIT_KB); } static void dmi_memory_device_extended_size(unsigned slot_num, uint32_t code) { uint64_t capacity = (uint64_t) code * 1024 * 1024; printf("MEMORY_DEVICE_%u_SIZE=%"PRIu64"\n", slot_num, capacity); } static void dmi_memory_device_rank(unsigned slot_num, uint8_t code) { code &= 0x0F; if (code != 0) printf("MEMORY_DEVICE_%u_RANK=%u\n", slot_num, code); } static void dmi_memory_device_voltage_value( const char *attr_suffix, unsigned slot_num, uint16_t code) { if (code == 0) return; if (code % 100 != 0) printf("MEMORY_DEVICE_%u_%s=%g\n", slot_num, attr_suffix, (double)code / 1000); else printf("MEMORY_DEVICE_%u_%s=%.1g\n", slot_num, attr_suffix, (double)code / 1000); } static void dmi_memory_device_form_factor(unsigned slot_num, uint8_t code) { /* 7.18.1 */ static const char *form_factor[] = { [0x01] = "Other", [0x02] = "Unknown", [0x03] = "SIMM", [0x04] = "SIP", [0x05] = "Chip", [0x06] = "DIP", [0x07] = "ZIP", [0x08] = "Proprietary Card", [0x09] = "DIMM", [0x0A] = "TSOP", [0x0B] = "Row Of Chips", [0x0C] = "RIMM", [0x0D] = "SODIMM", [0x0E] = "SRIMM", [0x0F] = "FB-DIMM", [0x10] = "Die", }; printf("MEMORY_DEVICE_%u_FORM_FACTOR=%s\n", slot_num, code < ELEMENTSOF(form_factor) && form_factor[code] ? form_factor[code] : OUT_OF_SPEC_STR); } static void dmi_memory_device_set(unsigned slot_num, uint8_t code) { if (code == 0xFF) printf("MEMORY_DEVICE_%u_SET=%s\n", slot_num, "Unknown"); else if (code != 0) printf("MEMORY_DEVICE_%u_SET=%"PRIu8"\n", slot_num, code); } static void dmi_memory_device_type(unsigned slot_num, uint8_t code) { /* 7.18.2 */ static const char *type[] = { [0x01] = "Other", [0x02] = "Unknown", [0x03] = "DRAM", [0x04] = "EDRAM", [0x05] = "VRAM", [0x06] = "SRAM", [0x07] = "RAM", [0x08] = "ROM", [0x09] = "Flash", [0x0A] = "EEPROM", [0x0B] = "FEPROM", [0x0C] = "EPROM", [0x0D] = "CDRAM", [0x0E] = "3DRAM", [0x0F] = "SDRAM", [0x10] = "SGRAM", [0x11] = "RDRAM", [0x12] = "DDR", [0x13] = "DDR2", [0x14] = "DDR2 FB-DIMM", [0x15] = "Reserved", [0x16] = "Reserved", [0x17] = "Reserved", [0x18] = "DDR3", [0x19] = "FBD2", [0x1A] = "DDR4", [0x1B] = "LPDDR", [0x1C] = "LPDDR2", [0x1D] = "LPDDR3", [0x1E] = "LPDDR4", [0x1F] = "Logical non-volatile device", [0x20] = "HBM", [0x21] = "HBM2", }; printf("MEMORY_DEVICE_%u_TYPE=%s\n", slot_num, code < ELEMENTSOF(type) && type[code] ? type[code] : OUT_OF_SPEC_STR); } static void dmi_memory_device_type_detail(unsigned slot_num, uint16_t code) { /* 7.18.3 */ static const char *detail[] = { [1] = "Other", [2] = "Unknown", [3] = "Fast-paged", [4] = "Static Column", [5] = "Pseudo-static", [6] = "RAMBus", [7] = "Synchronous", [8] = "CMOS", [9] = "EDO", [10] = "Window DRAM", [11] = "Cache DRAM", [12] = "Non-Volatile", [13] = "Registered (Buffered)", [14] = "Unbuffered (Unregistered)", [15] = "LRDIMM", }; if ((code & 0xFFFE) == 0) printf("MEMORY_DEVICE_%u_TYPE_DETAIL=%s\n", slot_num, "None"); else { bool first_element = true; printf("MEMORY_DEVICE_%u_TYPE_DETAIL=", slot_num); for (size_t i = 1; i < ELEMENTSOF(detail); i++) if (code & (1 << i)) { printf("%s%s", first_element ? "" : " ", detail[i]); first_element = false; } printf("\n"); } } static void dmi_memory_device_speed( const char *attr_suffix, unsigned slot_num, uint16_t code) { if (code != 0) printf("MEMORY_DEVICE_%u_%s=%u\n", slot_num, attr_suffix, code); } static void dmi_memory_device_technology(unsigned slot_num, uint8_t code) { /* 7.18.6 */ static const char * const technology[] = { [0x01] = "Other", [0x02] = "Unknown", [0x03] = "DRAM", [0x04] = "NVDIMM-N", [0x05] = "NVDIMM-F", [0x06] = "NVDIMM-P", [0x07] = "Intel Optane DC persistent memory", }; printf("MEMORY_DEVICE_%u_MEMORY_TECHNOLOGY=%s\n", slot_num, code < ELEMENTSOF(technology) && technology[code] ? technology[code] : OUT_OF_SPEC_STR); } static void dmi_memory_device_operating_mode_capability(unsigned slot_num, uint16_t code) { /* 7.18.7 */ static const char * const mode[] = { [1] = "Other", [2] = "Unknown", [3] = "Volatile memory", [4] = "Byte-accessible persistent memory", [5] = "Block-accessible persistent memory", }; if ((code & 0xFFFE) != 0) { bool first_element = true; printf("MEMORY_DEVICE_%u_MEMORY_OPERATING_MODE_CAPABILITY=", slot_num); for (size_t i = 1; i < ELEMENTSOF(mode); i++) if (code & (1 << i)) { printf("%s%s", first_element ? "" : " ", mode[i]); first_element = false; } printf("\n"); } } static void dmi_memory_device_manufacturer_id( const char *attr_suffix, unsigned slot_num, uint16_t code) { /* 7.18.8 */ /* 7.18.10 */ /* LSB is 7-bit Odd Parity number of continuation codes */ if (code != 0) printf("MEMORY_DEVICE_%u_%s=Bank %d, Hex 0x%02X\n", slot_num, attr_suffix, (code & 0x7F) + 1, code >> 8); } static void dmi_memory_device_product_id( const char *attr_suffix, unsigned slot_num, uint16_t code) { /* 7.18.9 */ /* 7.18.11 */ if (code != 0) printf("MEMORY_DEVICE_%u_%s=0x%04X\n", slot_num, attr_suffix, code); } static void dmi_memory_device_size_detail( const char *attr_suffix, unsigned slot_num, uint64_t code) { /* 7.18.12 */ /* 7.18.13 */ if (!IN_SET(code, 0x0LU, 0xFFFFFFFFFFFFFFFFLU)) dmi_print_memory_size("MEMORY_DEVICE", attr_suffix, slot_num, code, MEMORY_SIZE_UNIT_BYTES); } static void dmi_decode(const struct dmi_header *h, unsigned *next_slot_num) { const uint8_t *data = h->data; unsigned slot_num; /* * Note: DMI types 37 and 42 are untested */ switch (h->type) { case 16: /* 7.17 Physical Memory Array */ log_debug("Physical Memory Array"); if (h->length < 0x0F) break; if (data[0x05] != 0x03) /* 7.17.2, Use == "System Memory" */ break; log_debug("Use: System Memory"); dmi_memory_array_location(data[0x04]); dmi_memory_array_ec_type(data[0x06]); if (DWORD(data + 0x07) != 0x80000000) dmi_print_memory_size("MEMORY_ARRAY", "MAX_CAPACITY", -1, DWORD(data + 0x07), MEMORY_SIZE_UNIT_KB); else if (h->length >= 0x17) dmi_print_memory_size("MEMORY_ARRAY", "MAX_CAPACITY", -1, QWORD(data + 0x0F), MEMORY_SIZE_UNIT_BYTES); break; case 17: /* 7.18 Memory Device */ slot_num = *next_slot_num; *next_slot_num = slot_num + 1; log_debug("Memory Device: %u", slot_num); if (h->length < 0x15) break; dmi_memory_device_width("TOTAL_WIDTH", slot_num, WORD(data + 0x08)); dmi_memory_device_width("DATA_WIDTH", slot_num, WORD(data + 0x0A)); if (h->length >= 0x20 && WORD(data + 0x0C) == 0x7FFF) dmi_memory_device_extended_size(slot_num, DWORD(data + 0x1C)); else dmi_memory_device_size(slot_num, WORD(data + 0x0C)); dmi_memory_device_form_factor(slot_num, data[0x0E]); dmi_memory_device_set(slot_num, data[0x0F]); dmi_memory_device_string("LOCATOR", slot_num, h, data[0x10]); dmi_memory_device_string("BANK_LOCATOR", slot_num, h, data[0x11]); dmi_memory_device_type(slot_num, data[0x12]); dmi_memory_device_type_detail(slot_num, WORD(data + 0x13)); if (h->length < 0x17) break; dmi_memory_device_speed("SPEED_MTS", slot_num, WORD(data + 0x15)); if (h->length < 0x1B) break; dmi_memory_device_string("MANUFACTURER", slot_num, h, data[0x17]); dmi_memory_device_string("SERIAL_NUMBER", slot_num, h, data[0x18]); dmi_memory_device_string("ASSET_TAG", slot_num, h, data[0x19]); dmi_memory_device_string("PART_NUMBER", slot_num, h, data[0x1A]); if (h->length < 0x1C) break; dmi_memory_device_rank(slot_num, data[0x1B]); if (h->length < 0x22) break; dmi_memory_device_speed("CONFIGURED_SPEED_MTS", slot_num, WORD(data + 0x20)); if (h->length < 0x28) break; dmi_memory_device_voltage_value("MINIMUM_VOLTAGE", slot_num, WORD(data + 0x22)); dmi_memory_device_voltage_value("MAXIMUM_VOLTAGE", slot_num, WORD(data + 0x24)); dmi_memory_device_voltage_value("CONFIGURED_VOLTAGE", slot_num, WORD(data + 0x26)); if (h->length < 0x34) break; dmi_memory_device_technology(slot_num, data[0x28]); dmi_memory_device_operating_mode_capability(slot_num, WORD(data + 0x29)); dmi_memory_device_string("FIRMWARE_VERSION", slot_num, h, data[0x2B]); dmi_memory_device_manufacturer_id("MODULE_MANUFACTURER_ID", slot_num, WORD(data + 0x2C)); dmi_memory_device_product_id("MODULE_PRODUCT_ID", slot_num, WORD(data + 0x2E)); dmi_memory_device_manufacturer_id("MEMORY_SUBSYSTEM_CONTROLLER_MANUFACTURER_ID", slot_num, WORD(data + 0x30)); dmi_memory_device_product_id("MEMORY_SUBSYSTEM_CONTROLLER_PRODUCT_ID", slot_num, WORD(data + 0x32)); if (h->length < 0x3C) break; dmi_memory_device_size_detail("NON_VOLATILE_SIZE", slot_num, QWORD(data + 0x34)); if (h->length < 0x44) break; dmi_memory_device_size_detail("VOLATILE_SIZE", slot_num, QWORD(data + 0x3C)); if (h->length < 0x4C) break; dmi_memory_device_size_detail("CACHE_SIZE", slot_num, QWORD(data + 0x44)); if (h->length < 0x54) break; dmi_memory_device_size_detail("LOGICAL_SIZE", slot_num, QWORD(data + 0x4C)); break; } } static void dmi_table_decode(const uint8_t *buf, size_t len, uint16_t num) { const uint8_t *data = buf; unsigned next_slot_num = 0; /* 4 is the length of an SMBIOS structure header */ for (uint16_t i = 0; (i < num || num == 0) && data + 4 <= buf + len; i++) { struct dmi_header h = (struct dmi_header) { .type = data[0], .length = data[1], .handle = WORD(data + 2), .data = data, }; bool display = !IN_SET(h.type, 126, 127); const uint8_t *next; /* If a short entry is found (less than 4 bytes), not only it * is invalid, but we cannot reliably locate the next entry. * Better stop at this point, and let the user know their * table is broken. */ if (h.length < 4) break; /* In quiet mode, stop decoding at end of table marker */ if (h.type == 127) break; /* Look for the next handle */ next = data + h.length; while ((size_t)(next - buf + 1) < len && (next[0] != 0 || next[1] != 0)) next++; next += 2; /* Make sure the whole structure fits in the table */ if ((size_t)(next - buf) > len) break; if (display) dmi_decode(&h, &next_slot_num); data = next; } if (next_slot_num > 0) printf("MEMORY_ARRAY_NUM_DEVICES=%u\n", next_slot_num); } static int dmi_table(int64_t base, uint32_t len, uint16_t num, const char *devmem, bool no_file_offset) { _cleanup_free_ uint8_t *buf = NULL; size_t size; int r; /* * When reading from sysfs or from a dump file, the file may be * shorter than announced. For SMBIOS v3 this is expected, as we * only know the maximum table size, not the actual table size. * For older implementations (and for SMBIOS v3 too), this * would be the result of the kernel truncating the table on * parse error. */ r = read_full_file_full(AT_FDCWD, devmem, no_file_offset ? 0 : base, len, 0, NULL, (char **) &buf, &size); if (r < 0) return log_error_errno(r, "Failed to read table: %m"); dmi_table_decode(buf, size, num); return 0; } /* Same thing for SMBIOS3 entry points */ static int smbios3_decode(const uint8_t *buf, const char *devmem, bool no_file_offset) { uint64_t offset; /* Don't let checksum run beyond the buffer */ if (buf[0x06] > 0x20) return log_error_errno(SYNTHETIC_ERRNO(EINVAL), "Entry point length too large (%"PRIu8" bytes, expected %u).", buf[0x06], 0x18U); if (!verify_checksum(buf, buf[0x06])) return log_error_errno(SYNTHETIC_ERRNO(EINVAL), "Failed to verify checksum."); offset = QWORD(buf + 0x10); #if __SIZEOF_SIZE_T__ != 8 if (!no_file_offset && (offset >> 32) != 0) return log_error_errno(SYNTHETIC_ERRNO(EINVAL), "64-bit addresses not supported on 32-bit systems."); #endif return dmi_table(offset, DWORD(buf + 0x0C), 0, devmem, no_file_offset); } static int smbios_decode(const uint8_t *buf, const char *devmem, bool no_file_offset) { /* Don't let checksum run beyond the buffer */ if (buf[0x05] > 0x20) return log_error_errno(SYNTHETIC_ERRNO(EINVAL), "Entry point length too large (%"PRIu8" bytes, expected %u).", buf[0x05], 0x1FU); if (!verify_checksum(buf, buf[0x05]) || memcmp(buf + 0x10, "_DMI_", 5) != 0 || !verify_checksum(buf + 0x10, 0x0F)) return log_error_errno(SYNTHETIC_ERRNO(EINVAL), "Failed to verify checksum."); return dmi_table(DWORD(buf + 0x18), WORD(buf + 0x16), WORD(buf + 0x1C), devmem, no_file_offset); } static int legacy_decode(const uint8_t *buf, const char *devmem, bool no_file_offset) { if (!verify_checksum(buf, 0x0F)) return log_error_errno(SYNTHETIC_ERRNO(EINVAL), "Failed to verify checksum."); return dmi_table(DWORD(buf + 0x08), WORD(buf + 0x06), WORD(buf + 0x0C), devmem, no_file_offset); } static int help(void) { printf("Usage: %s [options]\n" " -F,--from-dump FILE read DMI information from a binary file\n" " -h,--help print this help text\n\n", program_invocation_short_name); return 0; } static int parse_argv(int argc, char * const *argv) { static const struct option options[] = { { "from-dump", required_argument, NULL, 'F' }, { "version", no_argument, NULL, 'V' }, { "help", no_argument, NULL, 'h' }, {} }; int c; while ((c = getopt_long(argc, argv, "F:hV", options, NULL)) >= 0) switch (c) { case 'F': arg_source_file = optarg; break; case 'V': printf("%s\n", GIT_VERSION); return 0; case 'h': return help(); case '?': return -EINVAL; default: assert_not_reached(); } return 1; } static int run(int argc, char* const* argv) { _cleanup_free_ uint8_t *buf = NULL; bool no_file_offset = false; size_t size; int r; log_set_target(LOG_TARGET_AUTO); udev_parse_config(); log_parse_environment(); log_open(); r = parse_argv(argc, argv); if (r <= 0) return r; /* Read from dump if so instructed */ r = read_full_file_full(AT_FDCWD, arg_source_file ?: SYS_ENTRY_FILE, 0, 0x20, 0, NULL, (char **) &buf, &size); if (r < 0) return log_full_errno(!arg_source_file && r == -ENOENT ? LOG_DEBUG : LOG_ERR, r, "Reading \"%s\" failed: %m", arg_source_file ?: SYS_ENTRY_FILE); if (!arg_source_file) { arg_source_file = SYS_TABLE_FILE; no_file_offset = true; } if (size >= 24 && memory_startswith(buf, size, "_SM3_")) return smbios3_decode(buf, arg_source_file, no_file_offset); if (size >= 31 && memory_startswith(buf, size, "_SM_")) return smbios_decode(buf, arg_source_file, no_file_offset); if (size >= 15 && memory_startswith(buf, size, "_DMI_")) return legacy_decode(buf, arg_source_file, no_file_offset); return -EINVAL; } DEFINE_MAIN_FUNCTION(run);