/* * DMI Decode * * Copyright (C) 2000-2002 Alan Cox * Copyright (C) 2002-2010 Jean Delvare * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA * * For the avoidance of doubt the "preferred form" of this code is one which * is in an open unpatent encumbered format. Where cryptographic key signing * forms part of the process of creating an executable the information * including keys needed to generate an equivalently functional executable * are deemed to be part of the source code. * * Unless specified otherwise, all references are aimed at the "System * Management BIOS Reference Specification, Version 2.7.0" 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 */ #include #include #include #include #include #include "version.h" #include "config.h" #include "types.h" #include "util.h" #include "dmidecode.h" #include "dmiopt.h" #include "dmioem.h" #define out_of_spec "" static const char *bad_index = ""; #define SUPPORTED_SMBIOS_VER 0x0207 /* * Type-independant Stuff */ const char *dmi_string(const struct dmi_header *dm, u8 s) { char *bp = (char *)dm->data; size_t i, len; if (s == 0) return "Not Specified"; bp += dm->length; while (s > 1 && *bp) { bp += strlen(bp); bp++; s--; } if (!*bp) return bad_index; if (!(opt.flags & FLAG_DUMP)) { /* ASCII filtering */ len = strlen(bp); for (i = 0; i < len; i++) if (bp[i] < 32 || bp[i] == 127) bp[i] = '.'; } return bp; } static const char *dmi_smbios_structure_type(u8 code) { static const char *type[] = { "BIOS", /* 0 */ "System", "Base Board", "Chassis", "Processor", "Memory Controller", "Memory Module", "Cache", "Port Connector", "System Slots", "On Board Devices", "OEM Strings", "System Configuration Options", "BIOS Language", "Group Associations", "System Event Log", "Physical Memory Array", "Memory Device", "32-bit Memory Error", "Memory Array Mapped Address", "Memory Device Mapped Address", "Built-in Pointing Device", "Portable Battery", "System Reset", "Hardware Security", "System Power Controls", "Voltage Probe", "Cooling Device", "Temperature Probe", "Electrical Current Probe", "Out-of-band Remote Access", "Boot Integrity Services", "System Boot", "64-bit Memory Error", "Management Device", "Management Device Component", "Management Device Threshold Data", "Memory Channel", "IPMI Device", "Power Supply", "Additional Information", "Onboard Device", "Management Controller Host Interface", /* 42 */ }; if (code <= 42) return type[code]; return out_of_spec; } static int dmi_bcd_range(u8 value, u8 low, u8 high) { if (value > 0x99 || (value & 0x0F) > 0x09) return 0; if (value < low || value > high) return 0; return 1; } static void dmi_dump(const struct dmi_header *h, const char *prefix) { int row, i; const char *s; printf("%sHeader and Data:\n", prefix); for (row = 0; row < ((h->length - 1) >> 4) + 1; row++) { printf("%s\t", prefix); for (i = 0; i < 16 && i < h->length - (row << 4); i++) printf("%s%02X", i ? " " : "", (h->data)[(row << 4) + i]); printf("\n"); } if ((h->data)[h->length] || (h->data)[h->length + 1]) { printf("%sStrings:\n", prefix); i = 1; while ((s = dmi_string(h, i++)) != bad_index) { if (opt.flags & FLAG_DUMP) { int j, l = strlen(s) + 1; for (row = 0; row < ((l - 1) >> 4) + 1; row++) { printf("%s\t", prefix); for (j = 0; j < 16 && j < l - (row << 4); j++) printf("%s%02X", j ? " " : "", s[(row << 4) + j]); printf("\n"); } /* String isn't filtered yet so do it now */ printf("%s\t\"", prefix); while (*s) { if (*s < 32 || *s == 127) fputc('.', stdout); else fputc(*s, stdout); s++; } printf("\"\n"); } else printf("%s\t%s\n", prefix, s); } } } /* shift is 0 if the value is in bytes, 1 if it is in kilobytes */ static void dmi_print_memory_size(u64 code, int shift) { unsigned long capacity; u16 split[7]; static const char *unit[8] = { "bytes", "kB", "MB", "GB", "TB", "PB", "EB", "ZB" }; int i; /* * We split the overall size in powers of thousand: EB, PB, TB, GB, * MB, kB and B. In practice, it is expected that only one or two * (consecutive) of these will be non-zero. */ split[0] = code.l & 0x3FFUL; split[1] = (code.l >> 10) & 0x3FFUL; split[2] = (code.l >> 20) & 0x3FFUL; split[3] = ((code.h << 2) & 0x3FCUL) | (code.l >> 30); split[4] = (code.h >> 8) & 0x3FFUL; split[5] = (code.h >> 18) & 0x3FFUL; split[6] = code.h >> 28; /* * Now we find the highest unit with a non-zero value. If the following * is also non-zero, we use that as our base. If the following is zero, * we simply display the highest unit. */ for (i = 6; i > 0; i--) { if (split[i]) break; } if (i > 0 && split[i - 1]) { i--; capacity = split[i] + (split[i + 1] << 10); } else capacity = split[i]; printf(" %lu %s", capacity, unit[i + shift]); } /* * 7.1 BIOS Information (Type 0) */ static void dmi_bios_runtime_size(u32 code) { if (code & 0x000003FF) printf(" %u bytes", code); else printf(" %u kB", code >> 10); } static void dmi_bios_characteristics(u64 code, const char *prefix) { /* 7.1.1 */ static const char *characteristics[] = { "BIOS characteristics not supported", /* 3 */ "ISA is supported", "MCA is supported", "EISA is supported", "PCI is supported", "PC Card (PCMCIA) is supported", "PNP is supported", "APM is supported", "BIOS is upgradeable", "BIOS shadowing is allowed", "VLB is supported", "ESCD support is available", "Boot from CD is supported", "Selectable boot is supported", "BIOS ROM is socketed", "Boot from PC Card (PCMCIA) is supported", "EDD is supported", "Japanese floppy for NEC 9800 1.2 MB is supported (int 13h)", "Japanese floppy for Toshiba 1.2 MB is supported (int 13h)", "5.25\"/360 kB floppy services are supported (int 13h)", "5.25\"/1.2 MB floppy services are supported (int 13h)", "3.5\"/720 kB floppy services are supported (int 13h)", "3.5\"/2.88 MB floppy services are supported (int 13h)", "Print screen service is supported (int 5h)", "8042 keyboard services are supported (int 9h)", "Serial services are supported (int 14h)", "Printer services are supported (int 17h)", "CGA/mono video services are supported (int 10h)", "NEC PC-98" /* 31 */ }; int i; /* * This isn't very clear what this bit is supposed to mean */ if (code.l & (1 << 3)) { printf("%s%s\n", prefix, characteristics[0]); return; } for (i = 4; i <= 31; i++) if (code.l & (1 << i)) printf("%s%s\n", prefix, characteristics[i - 3]); } static void dmi_bios_characteristics_x1(u8 code, const char *prefix) { /* 7.1.2.1 */ static const char *characteristics[] = { "ACPI is supported", /* 0 */ "USB legacy is supported", "AGP is supported", "I2O boot is supported", "LS-120 boot is supported", "ATAPI Zip drive boot is supported", "IEEE 1394 boot is supported", "Smart battery is supported" /* 7 */ }; int i; for (i = 0; i <= 7; i++) if (code & (1 << i)) printf("%s%s\n", prefix, characteristics[i]); } static void dmi_bios_characteristics_x2(u8 code, const char *prefix) { /* 37.1.2.2 */ static const char *characteristics[] = { "BIOS boot specification is supported", /* 0 */ "Function key-initiated network boot is supported", "Targeted content distribution is supported", "UEFI is supported", "System is a virtual machine" /* 4 */ }; int i; for (i = 0; i <= 4; i++) if (code & (1 << i)) printf("%s%s\n", prefix, characteristics[i]); } /* * 7.2 System Information (Type 1) */ static void dmi_system_uuid(const u8 *p, u16 ver) { int only0xFF = 1, only0x00 = 1; int i; for (i = 0; i < 16 && (only0x00 || only0xFF); i++) { if (p[i] != 0x00) only0x00 = 0; if (p[i] != 0xFF) only0xFF = 0; } if (only0xFF) { printf("Not Present"); return; } if (only0x00) { printf("Not Settable"); return; } /* * As of version 2.6 of the SMBIOS specification, the first 3 * fields of the UUID are supposed to be encoded on little-endian. * The specification says that this is the defacto standard, * however I've seen systems following RFC 4122 instead and use * network byte order, so I am reluctant to apply the byte-swapping * for older versions. */ if (ver >= 0x0206) printf("%02X%02X%02X%02X-%02X%02X-%02X%02X-%02X%02X-%02X%02X%02X%02X%02X%02X", p[3], p[2], p[1], p[0], p[5], p[4], p[7], p[6], p[8], p[9], p[10], p[11], p[12], p[13], p[14], p[15]); else printf("%02X%02X%02X%02X-%02X%02X-%02X%02X-%02X%02X-%02X%02X%02X%02X%02X%02X", p[0], p[1], p[2], p[3], p[4], p[5], p[6], p[7], p[8], p[9], p[10], p[11], p[12], p[13], p[14], p[15]); } static const char *dmi_system_wake_up_type(u8 code) { /* 7.2.2 */ static const char *type[] = { "Reserved", /* 0x00 */ "Other", "Unknown", "APM Timer", "Modem Ring", "LAN Remote", "Power Switch", "PCI PME#", "AC Power Restored" /* 0x08 */ }; if (code <= 0x08) return type[code]; return out_of_spec; } /* * 7.3 Base Board Information (Type 2) */ static void dmi_base_board_features(u8 code, const char *prefix) { /* 7.3.1 */ static const char *features[] = { "Board is a hosting board", /* 0 */ "Board requires at least one daughter board", "Board is removable", "Board is replaceable", "Board is hot swappable" /* 4 */ }; if ((code & 0x1F) == 0) printf(" None\n"); else { int i; printf("\n"); for (i = 0; i <= 4; i++) if (code & (1 << i)) printf("%s%s\n", prefix, features[i]); } } static const char *dmi_base_board_type(u8 code) { /* 7.3.2 */ static const char *type[] = { "Unknown", /* 0x01 */ "Other", "Server Blade", "Connectivity Switch", "System Management Module", "Processor Module", "I/O Module", "Memory Module", "Daughter Board", "Motherboard", "Processor+Memory Module", "Processor+I/O Module", "Interconnect Board" /* 0x0D */ }; if (code >= 0x01 && code <= 0x0D) return type[code - 0x01]; return out_of_spec; } static void dmi_base_board_handles(u8 count, const u8 *p, const char *prefix) { int i; printf("%sContained Object Handles: %u\n", prefix, count); for (i = 0; i < count; i++) printf("%s\t0x%04X\n", prefix, WORD(p + sizeof(u16) * i)); } /* * 7.4 Chassis Information (Type 3) */ static const char *dmi_chassis_type(u8 code) { /* 7.4.1 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "Desktop", "Low Profile Desktop", "Pizza Box", "Mini Tower", "Tower", "Portable", "Laptop", "Notebook", "Hand Held", "Docking Station", "All In One", "Sub Notebook", "Space-saving", "Lunch Box", "Main Server Chassis", /* CIM_Chassis.ChassisPackageType says "Main System Chassis" */ "Expansion Chassis", "Sub Chassis", "Bus Expansion Chassis", "Peripheral Chassis", "RAID Chassis", "Rack Mount Chassis", "Sealed-case PC", "Multi-system", "CompactPCI", "AdvancedTCA", "Blade", "Blade Enclosing" /* 0x1D */ }; if (code >= 0x01 && code <= 0x1D) return type[code - 0x01]; return out_of_spec; } static const char *dmi_chassis_lock(u8 code) { static const char *lock[] = { "Not Present", /* 0x00 */ "Present" /* 0x01 */ }; return lock[code]; } static const char *dmi_chassis_state(u8 code) { /* 7.4.2 */ static const char *state[] = { "Other", /* 0x01 */ "Unknown", "Safe", "Warning", "Critical", "Non-recoverable" /* 0x06 */ }; if (code >= 0x01 && code <= 0x06) return state[code - 0x01]; return out_of_spec; } static const char *dmi_chassis_security_status(u8 code) { /* 7.4.3 */ static const char *status[] = { "Other", /* 0x01 */ "Unknown", "None", "External Interface Locked Out", "External Interface Enabled" /* 0x05 */ }; if (code >= 0x01 && code <= 0x05) return status[code - 0x01]; return out_of_spec; } static void dmi_chassis_height(u8 code) { if (code == 0x00) printf(" Unspecified"); else printf(" %u U", code); } static void dmi_chassis_power_cords(u8 code) { if (code == 0x00) printf(" Unspecified"); else printf(" %u", code); } static void dmi_chassis_elements(u8 count, u8 len, const u8 *p, const char *prefix) { int i; printf("%sContained Elements: %u\n", prefix, count); for (i = 0; i < count; i++) { if (len >= 0x03) { printf("%s\t%s (", prefix, p[i * len] & 0x80 ? dmi_smbios_structure_type(p[i * len] & 0x7F) : dmi_base_board_type(p[i * len] & 0x7F)); if (p[1 + i * len] == p[2 + i * len]) printf("%u", p[1 + i * len]); else printf("%u-%u", p[1 + i * len], p[2 + i * len]); printf(")\n"); } } } /* * 7.5 Processor Information (Type 4) */ static const char *dmi_processor_type(u8 code) { /* 7.5.1 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "Central Processor", "Math Processor", "DSP Processor", "Video Processor" /* 0x06 */ }; if (code >= 0x01 && code <= 0x06) return type[code - 0x01]; return out_of_spec; } static const char *dmi_processor_family(const struct dmi_header *h, u16 ver) { const u8 *data = h->data; unsigned int i, low, high; u16 code; /* 7.5.2 */ static struct { int value; const char *name; } family2[] = { { 0x01, "Other" }, { 0x02, "Unknown" }, { 0x03, "8086" }, { 0x04, "80286" }, { 0x05, "80386" }, { 0x06, "80486" }, { 0x07, "8087" }, { 0x08, "80287" }, { 0x09, "80387" }, { 0x0A, "80487" }, { 0x0B, "Pentium" }, { 0x0C, "Pentium Pro" }, { 0x0D, "Pentium II" }, { 0x0E, "Pentium MMX" }, { 0x0F, "Celeron" }, { 0x10, "Pentium II Xeon" }, { 0x11, "Pentium III" }, { 0x12, "M1" }, { 0x13, "M2" }, { 0x14, "Celeron M" }, { 0x15, "Pentium 4 HT" }, { 0x18, "Duron" }, { 0x19, "K5" }, { 0x1A, "K6" }, { 0x1B, "K6-2" }, { 0x1C, "K6-3" }, { 0x1D, "Athlon" }, { 0x1E, "AMD29000" }, { 0x1F, "K6-2+" }, { 0x20, "Power PC" }, { 0x21, "Power PC 601" }, { 0x22, "Power PC 603" }, { 0x23, "Power PC 603+" }, { 0x24, "Power PC 604" }, { 0x25, "Power PC 620" }, { 0x26, "Power PC x704" }, { 0x27, "Power PC 750" }, { 0x28, "Core Duo" }, { 0x29, "Core Duo Mobile" }, { 0x2A, "Core Solo Mobile" }, { 0x2B, "Atom" }, { 0x30, "Alpha" }, { 0x31, "Alpha 21064" }, { 0x32, "Alpha 21066" }, { 0x33, "Alpha 21164" }, { 0x34, "Alpha 21164PC" }, { 0x35, "Alpha 21164a" }, { 0x36, "Alpha 21264" }, { 0x37, "Alpha 21364" }, { 0x38, "Turion II Ultra Dual-Core Mobile M" }, { 0x39, "Turion II Dual-Core Mobile M" }, { 0x3A, "Athlon II Dual-Core M" }, { 0x3B, "Opteron 6100" }, { 0x3C, "Opteron 4100" }, { 0x40, "MIPS" }, { 0x41, "MIPS R4000" }, { 0x42, "MIPS R4200" }, { 0x43, "MIPS R4400" }, { 0x44, "MIPS R4600" }, { 0x45, "MIPS R10000" }, { 0x50, "SPARC" }, { 0x51, "SuperSPARC" }, { 0x52, "MicroSPARC II" }, { 0x53, "MicroSPARC IIep" }, { 0x54, "UltraSPARC" }, { 0x55, "UltraSPARC II" }, { 0x56, "UltraSPARC IIi" }, { 0x57, "UltraSPARC III" }, { 0x58, "UltraSPARC IIIi" }, { 0x60, "68040" }, { 0x61, "68xxx" }, { 0x62, "68000" }, { 0x63, "68010" }, { 0x64, "68020" }, { 0x65, "68030" }, { 0x70, "Hobbit" }, { 0x78, "Crusoe TM5000" }, { 0x79, "Crusoe TM3000" }, { 0x7A, "Efficeon TM8000" }, { 0x80, "Weitek" }, { 0x82, "Itanium" }, { 0x83, "Athlon 64" }, { 0x84, "Opteron" }, { 0x85, "Sempron" }, { 0x86, "Turion 64" }, { 0x87, "Dual-Core Opteron" }, { 0x88, "Athlon 64 X2" }, { 0x89, "Turion 64 X2" }, { 0x8A, "Quad-Core Opteron" }, { 0x8B, "Third-Generation Opteron" }, { 0x8C, "Phenom FX" }, { 0x8D, "Phenom X4" }, { 0x8E, "Phenom X2" }, { 0x8F, "Athlon X2" }, { 0x90, "PA-RISC" }, { 0x91, "PA-RISC 8500" }, { 0x92, "PA-RISC 8000" }, { 0x93, "PA-RISC 7300LC" }, { 0x94, "PA-RISC 7200" }, { 0x95, "PA-RISC 7100LC" }, { 0x96, "PA-RISC 7100" }, { 0xA0, "V30" }, { 0xA1, "Quad-Core Xeon 3200" }, { 0xA2, "Dual-Core Xeon 3000" }, { 0xA3, "Quad-Core Xeon 5300" }, { 0xA4, "Dual-Core Xeon 5100" }, { 0xA5, "Dual-Core Xeon 5000" }, { 0xA6, "Dual-Core Xeon LV" }, { 0xA7, "Dual-Core Xeon ULV" }, { 0xA8, "Dual-Core Xeon 7100" }, { 0xA9, "Quad-Core Xeon 5400" }, { 0xAA, "Quad-Core Xeon" }, { 0xAB, "Dual-Core Xeon 5200" }, { 0xAC, "Dual-Core Xeon 7200" }, { 0xAD, "Quad-Core Xeon 7300" }, { 0xAE, "Quad-Core Xeon 7400" }, { 0xAF, "Multi-Core Xeon 7400" }, { 0xB0, "Pentium III Xeon" }, { 0xB1, "Pentium III Speedstep" }, { 0xB2, "Pentium 4" }, { 0xB3, "Xeon" }, { 0xB4, "AS400" }, { 0xB5, "Xeon MP" }, { 0xB6, "Athlon XP" }, { 0xB7, "Athlon MP" }, { 0xB8, "Itanium 2" }, { 0xB9, "Pentium M" }, { 0xBA, "Celeron D" }, { 0xBB, "Pentium D" }, { 0xBC, "Pentium EE" }, { 0xBD, "Core Solo" }, /* 0xBE handled as a special case */ { 0xBF, "Core 2 Duo" }, { 0xC0, "Core 2 Solo" }, { 0xC1, "Core 2 Extreme" }, { 0xC2, "Core 2 Quad" }, { 0xC3, "Core 2 Extreme Mobile" }, { 0xC4, "Core 2 Duo Mobile" }, { 0xC5, "Core 2 Solo Mobile" }, { 0xC6, "Core i7" }, { 0xC7, "Dual-Core Celeron" }, { 0xC8, "IBM390" }, { 0xC9, "G4" }, { 0xCA, "G5" }, { 0xCB, "ESA/390 G6" }, { 0xCC, "z/Architectur" }, { 0xCD, "Core i5" }, { 0xCE, "Core i3" }, { 0xD2, "C7-M" }, { 0xD3, "C7-D" }, { 0xD4, "C7" }, { 0xD5, "Eden" }, { 0xD6, "Multi-Core Xeon" }, { 0xD7, "Dual-Core Xeon 3xxx" }, { 0xD8, "Quad-Core Xeon 3xxx" }, { 0xD9, "Nano" }, { 0xDA, "Dual-Core Xeon 5xxx" }, { 0xDB, "Quad-Core Xeon 5xxx" }, { 0xDD, "Dual-Core Xeon 7xxx" }, { 0xDE, "Quad-Core Xeon 7xxx" }, { 0xDF, "Multi-Core Xeon 7xxx" }, { 0xE0, "Multi-Core Xeon 3400" }, { 0xE6, "Embedded Opteron Quad-Core" }, { 0xE7, "Phenom Triple-Core" }, { 0xE8, "Turion Ultra Dual-Core Mobile" }, { 0xE9, "Turion Dual-Core Mobile" }, { 0xEA, "Athlon Dual-Core" }, { 0xEB, "Sempron SI" }, { 0xEC, "Phenom II" }, { 0xED, "Athlon II" }, { 0xEE, "Six-Core Opteron" }, { 0xEF, "Sempron M" }, { 0xFA, "i860" }, { 0xFB, "i960" }, { 0x104, "SH-3" }, { 0x105, "SH-4" }, { 0x118, "ARM" }, { 0x119, "StrongARM" }, { 0x12C, "6x86" }, { 0x12D, "MediaGX" }, { 0x12E, "MII" }, { 0x140, "WinChip" }, { 0x15E, "DSP" }, { 0x1F4, "Video Processor" }, }; /* Special case for ambiguous value 0x30 (SMBIOS 2.0 only) */ if (ver == 0x0200 && data[0x06] == 0x30 && h->length >= 0x08) { const char *manufacturer = dmi_string(h, data[0x07]); if (strstr(manufacturer, "Intel") != NULL || strncasecmp(manufacturer, "Intel", 5) == 0) return "Pentium Pro"; } code = (data[0x06] == 0xFE && h->length >= 0x2A) ? WORD(data + 0x28) : data[0x06]; /* Special case for ambiguous value 0xBE */ if (code == 0xBE) { if (h->length >= 0x08) { const char *manufacturer = dmi_string(h, data[0x07]); /* Best bet based on manufacturer string */ if (strstr(manufacturer, "Intel") != NULL || strncasecmp(manufacturer, "Intel", 5) == 0) return "Core 2"; if (strstr(manufacturer, "AMD") != NULL || strncasecmp(manufacturer, "AMD", 3) == 0) return "K7"; } return "Core 2 or K7"; } /* Perform a binary search */ low = 0; high = ARRAY_SIZE(family2) - 1; while (1) { i = (low + high) / 2; if (family2[i].value == code) return family2[i].name; if (low == high) /* Not found */ return out_of_spec; if (code < family2[i].value) high = i; else low = i + 1; } } static void dmi_processor_id(u8 type, const u8 *p, const char *version, const char *prefix) { /* Intel AP-485 revision 36, table 2-4 */ static const char *flags[32] = { "FPU (Floating-point unit on-chip)", /* 0 */ "VME (Virtual mode extension)", "DE (Debugging extension)", "PSE (Page size extension)", "TSC (Time stamp counter)", "MSR (Model specific registers)", "PAE (Physical address extension)", "MCE (Machine check exception)", "CX8 (CMPXCHG8 instruction supported)", "APIC (On-chip APIC hardware supported)", NULL, /* 10 */ "SEP (Fast system call)", "MTRR (Memory type range registers)", "PGE (Page global enable)", "MCA (Machine check architecture)", "CMOV (Conditional move instruction supported)", "PAT (Page attribute table)", "PSE-36 (36-bit page size extension)", "PSN (Processor serial number present and enabled)", "CLFSH (CLFLUSH instruction supported)", NULL, /* 20 */ "DS (Debug store)", "ACPI (ACPI supported)", "MMX (MMX technology supported)", "FXSR (FXSAVE and FXSTOR instructions supported)", "SSE (Streaming SIMD extensions)", "SSE2 (Streaming SIMD extensions 2)", "SS (Self-snoop)", "HTT (Multi-threading)", "TM (Thermal monitor supported)", NULL, /* 30 */ "PBE (Pending break enabled)" /* 31 */ }; /* * Extra flags are now returned in the ECX register when one calls * the CPUID instruction. Their meaning is explained in table 3-5, but * DMI doesn't support this yet. */ u32 eax, edx; int sig = 0; /* * This might help learn about new processors supporting the * CPUID instruction or another form of identification. */ printf("%sID: %02X %02X %02X %02X %02X %02X %02X %02X\n", prefix, p[0], p[1], p[2], p[3], p[4], p[5], p[6], p[7]); if (type == 0x05) /* 80386 */ { u16 dx = WORD(p); /* * 80386 have a different signature. */ printf("%sSignature: Type %u, Family %u, Major Stepping %u, Minor Stepping %u\n", prefix, dx >> 12, (dx >> 8) & 0xF, (dx >> 4) & 0xF, dx & 0xF); return; } if (type == 0x06) /* 80486 */ { u16 dx = WORD(p); /* * Not all 80486 CPU support the CPUID instruction, we have to find * wether the one we have here does or not. Note that this trick * works only because we know that 80486 must be little-endian. */ if ((dx & 0x0F00) == 0x0400 && ((dx & 0x00F0) == 0x0040 || (dx & 0x00F0) >= 0x0070) && ((dx & 0x000F) >= 0x0003)) sig = 1; else { printf("%sSignature: Type %u, Family %u, Model %u, Stepping %u\n", prefix, (dx >> 12) & 0x3, (dx >> 8) & 0xF, (dx >> 4) & 0xF, dx & 0xF); return; } } else if ((type >= 0x0B && type <= 0x15) /* Intel, Cyrix */ || (type >= 0x28 && type <= 0x2B) /* Intel */ || (type >= 0xA1 && type <= 0xB3) /* Intel */ || type == 0xB5 /* Intel */ || (type >= 0xB9 && type <= 0xC7) /* Intel */ || (type >= 0xCD && type <= 0xCE) /* Intel */ || (type >= 0xD2 && type <= 0xDB) /* VIA, Intel */ || (type >= 0xDD && type <= 0xE0)) /* Intel */ sig = 1; else if ((type >= 0x18 && type <= 0x1D) /* AMD */ || type == 0x1F /* AMD */ || (type >= 0x38 && type <= 0x3C) /* AMD */ || (type >= 0x83 && type <= 0x8F) /* AMD */ || (type >= 0xB6 && type <= 0xB7) /* AMD */ || (type >= 0xE6 && type <= 0xEF)) /* AMD */ sig = 2; else if (type == 0x01 || type == 0x02) { /* * Some X86-class CPU have family "Other" or "Unknown". In this case, * we use the version string to determine if they are known to * support the CPUID instruction. */ if (strncmp(version, "Pentium III MMX", 15) == 0 || strncmp(version, "Intel(R) Core(TM)2", 18) == 0 || strncmp(version, "Intel(R) Pentium(R)", 19) == 0 || strcmp(version, "Genuine Intel(R) CPU U1400") == 0) sig = 1; else if (strncmp(version, "AMD Athlon(TM)", 14) == 0 || strncmp(version, "AMD Opteron(tm)", 15) == 0 || strncmp(version, "Dual-Core AMD Opteron(tm)", 25) == 0) sig = 2; else return; } else /* not X86-class */ return; eax = DWORD(p); edx = DWORD(p + 4); switch (sig) { case 1: /* Intel */ printf("%sSignature: Type %u, Family %u, Model %u, Stepping %u\n", prefix, (eax >> 12) & 0x3, ((eax >> 20) & 0xFF) + ((eax >> 8) & 0x0F), ((eax >> 12) & 0xF0) + ((eax >> 4) & 0x0F), eax & 0xF); break; case 2: /* AMD, publication #25481 revision 2.28 */ printf("%sSignature: Family %u, Model %u, Stepping %u\n", prefix, ((eax >> 8) & 0xF) + (((eax >> 8) & 0xF) == 0xF ? (eax >> 20) & 0xFF : 0), ((eax >> 4) & 0xF) | (((eax >> 8) & 0xF) == 0xF ? (eax >> 12) & 0xF0 : 0), eax & 0xF); break; } edx = DWORD(p + 4); printf("%sFlags:", prefix); if ((edx & 0xBFEFFBFF) == 0) printf(" None\n"); else { int i; printf("\n"); for (i = 0; i <= 31; i++) if (flags[i] != NULL && edx & (1 << i)) printf("%s\t%s\n", prefix, flags[i]); } } static void dmi_processor_voltage(u8 code) { /* 7.5.4 */ static const char *voltage[] = { "5.0 V", /* 0 */ "3.3 V", "2.9 V" /* 2 */ }; int i; if (code & 0x80) printf(" %.1f V", (float)(code & 0x7f) / 10); else { for (i = 0; i <= 2; i++) if (code & (1 << i)) printf(" %s", voltage[i]); if (code == 0x00) printf(" Unknown"); } } static void dmi_processor_frequency(const u8 *p) { u16 code = WORD(p); if (code) printf("%u MHz", code); else printf("Unknown"); } /* code is assumed to be a 3-bit value */ static const char *dmi_processor_status(u8 code) { static const char *status[] = { "Unknown", /* 0x00 */ "Enabled", "Disabled By User", "Disabled By BIOS", "Idle", /* 0x04 */ out_of_spec, out_of_spec, "Other" /* 0x07 */ }; return status[code]; } static const char *dmi_processor_upgrade(u8 code) { /* 7.5.5 */ static const char *upgrade[] = { "Other", /* 0x01 */ "Unknown", "Daughter Board", "ZIF Socket", "Replaceable Piggy Back", "None", "LIF Socket", "Slot 1", "Slot 2", "370-pin Socket", "Slot A", "Slot M", "Socket 423", "Socket A (Socket 462)", "Socket 478", "Socket 754", "Socket 940", "Socket 939", "Socket mPGA604", "Socket LGA771", "Socket LGA775", "Socket S1", "Socket AM2", "Socket F (1207)", "Socket LGA1366", "Socket G34", "Socket AM3", "Socket C32", "Socket LGA1156", "Socket LGA1567", "Socket PGA988A", "Socket BGA1288" /* 0x20 */ }; if (code >= 0x01 && code <= 0x20) return upgrade[code - 0x01]; return out_of_spec; } static void dmi_processor_cache(u16 code, const char *level, u16 ver) { if (code == 0xFFFF) { if (ver >= 0x0203) printf(" Not Provided"); else printf(" No %s Cache", level); } else printf(" 0x%04X", code); } static void dmi_processor_characteristics(u16 code, const char *prefix) { /* 7.5.9 */ static const char *characteristics[] = { "64-bit capable", /* 2 */ "Multi-Core", "Hardware Thread", "Execute Protection", "Enhanced Virtualization", "Power/Performance Control" /* 7 */ }; if ((code & 0x00FC) == 0) printf(" None\n"); else { int i; printf("\n"); for (i = 2; i <= 7; i++) if (code & (1 << i)) printf("%s%s\n", prefix, characteristics[i - 2]); } } /* * 7.6 Memory Controller Information (Type 5) */ static const char *dmi_memory_controller_ed_method(u8 code) { /* 7.6.1 */ static const char *method[] = { "Other", /* 0x01 */ "Unknown", "None", "8-bit Parity", "32-bit ECC", "64-bit ECC", "128-bit ECC", "CRC" /* 0x08 */ }; if (code >= 0x01 && code <= 0x08) return method[code - 0x01]; return out_of_spec; } static void dmi_memory_controller_ec_capabilities(u8 code, const char *prefix) { /* 7.6.2 */ static const char *capabilities[] = { "Other", /* 0 */ "Unknown", "None", "Single-bit Error Correcting", "Double-bit Error Correcting", "Error Scrubbing" /* 5 */ }; if ((code & 0x3F) == 0) printf(" None\n"); else { int i; printf("\n"); for (i = 0; i <= 5; i++) if (code & (1 << i)) printf("%s%s\n", prefix, capabilities[i]); } } static const char *dmi_memory_controller_interleave(u8 code) { /* 7.6.3 */ static const char *interleave[] = { "Other", /* 0x01 */ "Unknown", "One-way Interleave", "Two-way Interleave", "Four-way Interleave", "Eight-way Interleave", "Sixteen-way Interleave" /* 0x07 */ }; if (code >= 0x01 && code <= 0x07) return interleave[code - 0x01]; return out_of_spec; } static void dmi_memory_controller_speeds(u16 code, const char *prefix) { /* 7.6.4 */ const char *speeds[] = { "Other", /* 0 */ "Unknown", "70 ns", "60 ns", "50 ns" /* 4 */ }; if ((code & 0x001F) == 0) printf(" None\n"); else { int i; printf("\n"); for (i = 0; i <= 4; i++) if (code & (1 << i)) printf("%s%s\n", prefix, speeds[i]); } } static void dmi_memory_controller_slots(u8 count, const u8 *p, const char *prefix) { int i; printf("%sAssociated Memory Slots: %u\n", prefix, count); for (i = 0; i < count; i++) printf("%s\t0x%04X\n", prefix, WORD(p + sizeof(u16) * i)); } /* * 7.7 Memory Module Information (Type 6) */ static void dmi_memory_module_types(u16 code, const char *sep) { /* 7.7.1 */ static const char *types[] = { "Other", /* 0 */ "Unknown", "Standard", "FPM", "EDO", "Parity", "ECC", "SIMM", "DIMM", "Burst EDO", "SDRAM" /* 10 */ }; if ((code & 0x07FF) == 0) printf(" None"); else { int i; for (i = 0; i <= 10; i++) if (code & (1 << i)) printf("%s%s", sep, types[i]); } } static void dmi_memory_module_connections(u8 code) { if (code == 0xFF) printf(" None"); else { if ((code & 0xF0) != 0xF0) printf(" %u", code >> 4); if ((code & 0x0F) != 0x0F) printf(" %u", code & 0x0F); } } static void dmi_memory_module_speed(u8 code) { if (code == 0) printf(" Unknown"); else printf(" %u ns", code); } static void dmi_memory_module_size(u8 code) { /* 7.7.2 */ switch (code & 0x7F) { case 0x7D: printf(" Not Determinable"); break; case 0x7E: printf(" Disabled"); break; case 0x7F: printf(" Not Installed"); return; default: printf(" %u MB", 1 << (code & 0x7F)); } if (code & 0x80) printf(" (Double-bank Connection)"); else printf(" (Single-bank Connection)"); } static void dmi_memory_module_error(u8 code, const char *prefix) { if (code & (1 << 2)) printf(" See Event Log\n"); else { if ((code & 0x03) == 0) printf(" OK\n"); if (code & (1 << 0)) printf("%sUncorrectable Errors\n", prefix); if (code & (1 << 1)) printf("%sCorrectable Errors\n", prefix); } } /* * 7.8 Cache Information (Type 7) */ static const char *dmi_cache_mode(u8 code) { static const char *mode[] = { "Write Through", /* 0x00 */ "Write Back", "Varies With Memory Address", "Unknown" /* 0x03 */ }; return mode[code]; } /* code is assumed to be a 2-bit value */ static const char *dmi_cache_location(u8 code) { static const char *location[4] = { "Internal", /* 0x00 */ "External", out_of_spec, /* 0x02 */ "Unknown" /* 0x03 */ }; return location[code]; } static void dmi_cache_size(u16 code) { if (code & 0x8000) printf(" %u kB", (code & 0x7FFF) << 6); else printf(" %u kB", code); } static void dmi_cache_types(u16 code, const char *sep) { /* 7.8.2 */ static const char *types[] = { "Other", /* 0 */ "Unknown", "Non-burst", "Burst", "Pipeline Burst", "Synchronous", "Asynchronous" /* 6 */ }; if ((code & 0x007F) == 0) printf(" None"); else { int i; for (i = 0; i <= 6; i++) if (code & (1 << i)) printf("%s%s", sep, types[i]); } } static const char *dmi_cache_ec_type(u8 code) { /* 7.8.3 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "None", "Parity", "Single-bit ECC", "Multi-bit ECC" /* 0x06 */ }; if (code >= 0x01 && code <= 0x06) return type[code - 0x01]; return out_of_spec; } static const char *dmi_cache_type(u8 code) { /* 7.8.4 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "Instruction", "Data", "Unified" /* 0x05 */ }; if (code >= 0x01 && code <= 0x05) return type[code - 0x01]; return out_of_spec; } static const char *dmi_cache_associativity(u8 code) { /* 7.8.5 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "Direct Mapped", "2-way Set-associative", "4-way Set-associative", "Fully Associative", "8-way Set-associative", "16-way Set-associative", "12-way Set-associative", "24-way Set-associative", "32-way Set-associative", "48-way Set-associative", "64-way Set-associative" /* 0x0D */ }; if (code >= 0x01 && code <= 0x0D) return type[code - 0x01]; return out_of_spec; } /* * 7.9 Port Connector Information (Type 8) */ static const char *dmi_port_connector_type(u8 code) { /* 7.9.2 */ static const char *type[] = { "None", /* 0x00 */ "Centronics", "Mini Centronics", "Proprietary", "DB-25 male", "DB-25 female", "DB-15 male", "DB-15 female", "DB-9 male", "DB-9 female", "RJ-11", "RJ-45", "50 Pin MiniSCSI", "Mini DIN", "Micro DIN", "PS/2", "Infrared", "HP-HIL", "Access Bus (USB)", "SSA SCSI", "Circular DIN-8 male", "Circular DIN-8 female", "On Board IDE", "On Board Floppy", "9 Pin Dual Inline (pin 10 cut)", "25 Pin Dual Inline (pin 26 cut)", "50 Pin Dual Inline", "68 Pin Dual Inline", "On Board Sound Input From CD-ROM", "Mini Centronics Type-14", "Mini Centronics Type-26", "Mini Jack (headphones)", "BNC", "IEEE 1394", "SAS/SATA Plug Receptacle" /* 0x22 */ }; static const char *type_0xA0[] = { "PC-98", /* 0xA0 */ "PC-98 Hireso", "PC-H98", "PC-98 Note", "PC-98 Full" /* 0xA4 */ }; if (code <= 0x22) return type[code]; if (code >= 0xA0 && code <= 0xA4) return type_0xA0[code - 0xA0]; if (code == 0xFF) return "Other"; return out_of_spec; } static const char *dmi_port_type(u8 code) { /* 7.9.3 */ static const char *type[] = { "None", /* 0x00 */ "Parallel Port XT/AT Compatible", "Parallel Port PS/2", "Parallel Port ECP", "Parallel Port EPP", "Parallel Port ECP/EPP", "Serial Port XT/AT Compatible", "Serial Port 16450 Compatible", "Serial Port 16550 Compatible", "Serial Port 16550A Compatible", "SCSI Port", "MIDI Port", "Joystick Port", "Keyboard Port", "Mouse Port", "SSA SCSI", "USB", "Firewire (IEEE P1394)", "PCMCIA Type I", "PCMCIA Type II", "PCMCIA Type III", "Cardbus", "Access Bus Port", "SCSI II", "SCSI Wide", "PC-98", "PC-98 Hireso", "PC-H98", "Video Port", "Audio Port", "Modem Port", "Network Port", "SATA", "SAS" /* 0x21 */ }; static const char *type_0xA0[] = { "8251 Compatible", /* 0xA0 */ "8251 FIFO Compatible" /* 0xA1 */ }; if (code <= 0x21) return type[code]; if (code >= 0xA0 && code <= 0xA1) return type_0xA0[code - 0xA0]; if (code == 0xFF) return "Other"; return out_of_spec; } /* * 7.10 System Slots (Type 9) */ static const char *dmi_slot_type(u8 code) { /* 7.10.1 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "ISA", "MCA", "EISA", "PCI", "PC Card (PCMCIA)", "VLB", "Proprietary", "Processor Card", "Proprietary Memory Card", "I/O Riser Card", "NuBus", "PCI-66", "AGP", "AGP 2x", "AGP 4x", "PCI-X", "AGP 8x" /* 0x13 */ }; static const char *type_0xA0[] = { "PC-98/C20", /* 0xA0 */ "PC-98/C24", "PC-98/E", "PC-98/Local Bus", "PC-98/Card", "PCI Express", "PCI Express x1", "PCI Express x2", "PCI Express x4", "PCI Express x8", "PCI Express x16", "PCI Express 2", "PCI Express 2 x1", "PCI Express 2 x2", "PCI Express 2 x4", "PCI Express 2 x8", "PCI Express 2 x16", /* 0xB0 */ }; if (code >= 0x01 && code <= 0x13) return type[code - 0x01]; if (code >= 0xA0 && code <= 0xB0) return type_0xA0[code - 0xA0]; return out_of_spec; } static const char *dmi_slot_bus_width(u8 code) { /* 7.10.2 */ static const char *width[] = { "", /* 0x01, "Other" */ "", /* "Unknown" */ "8-bit ", "16-bit ", "32-bit ", "64-bit ", "128-bit ", "x1 ", "x2 ", "x4 ", "x8 ", "x12 ", "x16 ", "x32 " /* 0x0E */ }; if (code >= 0x01 && code <= 0x0E) return width[code - 0x01]; return out_of_spec; } static const char *dmi_slot_current_usage(u8 code) { /* 7.10.3 */ static const char *usage[] = { "Other", /* 0x01 */ "Unknown", "Available", "In Use" /* 0x04 */ }; if (code >= 0x01 && code <= 0x04) return usage[code - 0x01]; return out_of_spec; } static const char *dmi_slot_length(u8 code) { /* 7.1O.4 */ static const char *length[] = { "Other", /* 0x01 */ "Unknown", "Short", "Long" /* 0x04 */ }; if (code >= 0x01 && code <= 0x04) return length[code - 0x01]; return out_of_spec; } static void dmi_slot_id(u8 code1, u8 code2, u8 type, const char *prefix) { /* 7.10.5 */ switch (type) { case 0x04: /* MCA */ printf("%sID: %u\n", prefix, code1); break; case 0x05: /* EISA */ printf("%sID: %u\n", prefix, code1); break; case 0x06: /* PCI */ case 0x0E: /* PCI */ case 0x0F: /* AGP */ case 0x10: /* AGP */ case 0x11: /* AGP */ case 0x12: /* PCI-X */ case 0x13: /* AGP */ case 0xA5: /* PCI Express */ case 0xA6: /* PCI Express */ case 0xA7: /* PCI Express */ case 0xA8: /* PCI Express */ case 0xA9: /* PCI Express */ case 0xAA: /* PCI Express */ case 0xAB: /* PCI Express 2 */ case 0xAC: /* PCI Express 2 */ case 0xAD: /* PCI Express 2 */ case 0xAE: /* PCI Express 2 */ case 0xAF: /* PCI Express 2 */ case 0xB0: /* PCI Express 2 */ printf("%sID: %u\n", prefix, code1); break; case 0x07: /* PCMCIA */ printf("%sID: Adapter %u, Socket %u\n", prefix, code1, code2); break; } } static void dmi_slot_characteristics(u8 code1, u8 code2, const char *prefix) { /* 7.10.6 */ static const char *characteristics1[] = { "5.0 V is provided", /* 1 */ "3.3 V is provided", "Opening is shared", "PC Card-16 is supported", "Cardbus is supported", "Zoom Video is supported", "Modem ring resume is supported" /* 7 */ }; /* 7.10.7 */ static const char *characteristics2[] = { "PME signal is supported", /* 0 */ "Hot-plug devices are supported", "SMBus signal is supported" /* 2 */ }; if (code1 & (1 << 0)) printf(" Unknown\n"); else if ((code1 & 0xFE) == 0 && (code2 & 0x07) == 0) printf(" None\n"); else { int i; printf("\n"); for (i = 1; i <= 7; i++) if (code1 & (1 << i)) printf("%s%s\n", prefix, characteristics1[i - 1]); for (i = 0; i <= 2; i++) if (code2 & (1 << i)) printf("%s%s\n", prefix, characteristics2[i]); } } static void dmi_slot_segment_bus_func(u16 code1, u8 code2, u8 code3, const char *prefix) { /* 7.10.8 */ if (!(code1 == 0xFFFF && code2 == 0xFF && code3 == 0xFF)) printf("%sBus Address: %04x:%02x:%02x.%x\n", prefix, code1, code2, code3 >> 3, code3 & 0x7); } /* * 7.11 On Board Devices Information (Type 10) */ static const char *dmi_on_board_devices_type(u8 code) { /* 7.11.1 and 7.42.2 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "Video", "SCSI Controller", "Ethernet", "Token Ring", "Sound", "PATA Controller", "SATA Controller", "SAS Controller" /* 0x0A */ }; if (code >= 0x01 && code <= 0x0A) return type[code - 0x01]; return out_of_spec; } static void dmi_on_board_devices(const struct dmi_header *h, const char *prefix) { u8 *p = h->data + 4; u8 count = (h->length - 0x04) / 2; int i; for (i = 0; i < count; i++) { if (count == 1) printf("%sOn Board Device Information\n", prefix); else printf("%sOn Board Device %d Information\n", prefix, i + 1); printf("%s\tType: %s\n", prefix, dmi_on_board_devices_type(p[2 * i] & 0x7F)); printf("%s\tStatus: %s\n", prefix, p[2 * i] & 0x80 ? "Enabled" : "Disabled"); printf("%s\tDescription: %s\n", prefix, dmi_string(h, p[2 * i + 1])); } } /* * 7.12 OEM Strings (Type 11) */ static void dmi_oem_strings(const struct dmi_header *h, const char *prefix) { u8 *p = h->data + 4; u8 count = p[0x00]; int i; for (i = 1; i <= count; i++) printf("%sString %d: %s\n", prefix, i, dmi_string(h, i)); } /* * 7.13 System Configuration Options (Type 12) */ static void dmi_system_configuration_options(const struct dmi_header *h, const char *prefix) { u8 *p = h->data + 4; u8 count = p[0x00]; int i; for (i = 1; i <= count; i++) printf("%sOption %d: %s\n", prefix, i, dmi_string(h, i)); } /* * 7.14 BIOS Language Information (Type 13) */ static void dmi_bios_languages(const struct dmi_header *h, const char *prefix) { u8 *p = h->data + 4; u8 count = p[0x00]; int i; for (i = 1; i <= count; i++) printf("%s%s\n", prefix, dmi_string(h, i)); } static const char *dmi_bios_language_format(u8 code) { if (code & 0x01) return "Abbreviated"; else return "Long"; } /* * 7.15 Group Associations (Type 14) */ static void dmi_group_associations_items(u8 count, const u8 *p, const char *prefix) { int i; for (i = 0; i < count; i++) { printf("%s0x%04X (%s)\n", prefix, WORD(p + 3 * i + 1), dmi_smbios_structure_type(p[3 * i])); } } /* * 7.16 System Event Log (Type 15) */ static const char *dmi_event_log_method(u8 code) { static const char *method[] = { "Indexed I/O, one 8-bit index port, one 8-bit data port", /* 0x00 */ "Indexed I/O, two 8-bit index ports, one 8-bit data port", "Indexed I/O, one 16-bit index port, one 8-bit data port", "Memory-mapped physical 32-bit address", "General-purpose non-volatile data functions" /* 0x04 */ }; if (code <= 0x04) return method[code]; if (code >= 0x80) return "OEM-specific"; return out_of_spec; } static void dmi_event_log_status(u8 code) { static const char *valid[] = { "Invalid", /* 0 */ "Valid" /* 1 */ }; static const char *full[] = { "Not Full", /* 0 */ "Full" /* 1 */ }; printf(" %s, %s", valid[(code >> 0) & 1], full[(code >> 1) & 1]); } static void dmi_event_log_address(u8 method, const u8 *p) { /* 7.16.3 */ switch (method) { case 0x00: case 0x01: case 0x02: printf(" Index 0x%04X, Data 0x%04X", WORD(p), WORD(p + 2)); break; case 0x03: printf(" 0x%08X", DWORD(p)); break; case 0x04: printf(" 0x%04X", WORD(p)); break; default: printf(" Unknown"); } } static const char *dmi_event_log_header_type(u8 code) { static const char *type[] = { "No Header", /* 0x00 */ "Type 1" /* 0x01 */ }; if (code <= 0x01) return type[code]; if (code >= 0x80) return "OEM-specific"; return out_of_spec; } static const char *dmi_event_log_descriptor_type(u8 code) { /* 7.16.6.1 */ static const char *type[] = { NULL, /* 0x00 */ "Single-bit ECC memory error", "Multi-bit ECC memory error", "Parity memory error", "Bus timeout", "I/O channel block", "Software NMI", "POST memory resize", "POST error", "PCI parity error", "PCI system error", "CPU failure", "EISA failsafe timer timeout", "Correctable memory log disabled", "Logging disabled", NULL, /* 0x0F */ "System limit exceeded", "Asynchronous hardware timer expired", "System configuration information", "Hard disk information", "System reconfigured", "Uncorrectable CPU-complex error", "Log area reset/cleared", "System boot" /* 0x17 */ }; if (code <= 0x17 && type[code] != NULL) return type[code]; if (code >= 0x80 && code <= 0xFE) return "OEM-specific"; if (code == 0xFF) return "End of log"; return out_of_spec; } static const char *dmi_event_log_descriptor_format(u8 code) { /* 7.16.6.2 */ static const char *format[] = { "None", /* 0x00 */ "Handle", "Multiple-event", "Multiple-event handle", "POST results bitmap", "System management", "Multiple-event system management" /* 0x06 */ }; if (code <= 0x06) return format[code]; if (code >= 0x80) return "OEM-specific"; return out_of_spec; } static void dmi_event_log_descriptors(u8 count, u8 len, const u8 *p, const char *prefix) { /* 7.16.1 */ int i; for (i = 0; i < count; i++) { if (len >= 0x02) { printf("%sDescriptor %u: %s\n", prefix, i + 1, dmi_event_log_descriptor_type(p[i * len])); printf("%sData Format %u: %s\n", prefix, i + 1, dmi_event_log_descriptor_format(p[i * len + 1])); } } } /* * 7.17 Physical Memory Array (Type 16) */ static const char *dmi_memory_array_location(u8 code) { /* 7.17.1 */ static const char *location[] = { "Other", /* 0x01 */ "Unknown", "System Board Or Motherboard", "ISA Add-on Card", "EISA Add-on Card", "PCI Add-on Card", "MCA Add-on Card", "PCMCIA Add-on Card", "Proprietary Add-on Card", "NuBus" /* 0x0A */ }; static const char *location_0xA0[] = { "PC-98/C20 Add-on Card", /* 0xA0 */ "PC-98/C24 Add-on Card", "PC-98/E Add-on Card", "PC-98/Local Bus Add-on Card" /* 0xA3 */ }; if (code >= 0x01 && code <= 0x0A) return location[code - 0x01]; if (code >= 0xA0 && code <= 0xA3) return location_0xA0[code - 0xA0]; return out_of_spec; } static const char *dmi_memory_array_use(u8 code) { /* 7.17.2 */ static const char *use[] = { "Other", /* 0x01 */ "Unknown", "System Memory", "Video Memory", "Flash Memory", "Non-volatile RAM", "Cache Memory" /* 0x07 */ }; if (code >= 0x01 && code <= 0x07) return use[code - 0x01]; return out_of_spec; } static const char *dmi_memory_array_ec_type(u8 code) { /* 7.17.3 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "None", "Parity", "Single-bit ECC", "Multi-bit ECC", "CRC" /* 0x07 */ }; if (code >= 0x01 && code <= 0x07) return type[code - 0x01]; return out_of_spec; } static void dmi_memory_array_error_handle(u16 code) { if (code == 0xFFFE) printf(" Not Provided"); else if (code == 0xFFFF) printf(" No Error"); else printf(" 0x%04X", code); } /* * 7.18 Memory Device (Type 17) */ static void dmi_memory_device_width(u16 code) { /* * If no memory module is present, width may be 0 */ if (code == 0xFFFF || code == 0) printf(" Unknown"); else printf(" %u bits", code); } static void dmi_memory_device_size(u16 code) { if (code == 0) printf(" No Module Installed"); else if (code == 0xFFFF) printf(" Unknown"); else { if (code & 0x8000) printf(" %u kB", code & 0x7FFF); else printf(" %u MB", code); } } static void dmi_memory_device_extended_size(u32 code) { code &= 0x7FFFFFFFUL; /* Use the most suitable unit depending on size */ if (code & 0x3FFUL) printf(" %lu MB", (unsigned long)code); else if (code & 0xFFFFFUL) printf(" %lu GB", (unsigned long)code >> 10); else printf(" %lu TB", (unsigned long)code >> 20); } static const char *dmi_memory_device_form_factor(u8 code) { /* 7.18.1 */ static const char *form_factor[] = { "Other", /* 0x01 */ "Unknown", "SIMM", "SIP", "Chip", "DIP", "ZIP", "Proprietary Card", "DIMM", "TSOP", "Row Of Chips", "RIMM", "SODIMM", "SRIMM", "FB-DIMM" /* 0x0F */ }; if (code >= 0x01 && code <= 0x0F) return form_factor[code - 0x01]; return out_of_spec; } static void dmi_memory_device_set(u8 code) { if (code == 0) printf(" None"); else if (code == 0xFF) printf(" Unknown"); else printf(" %u", code); } static const char *dmi_memory_device_type(u8 code) { /* 7.18.2 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "DRAM", "EDRAM", "VRAM", "SRAM", "RAM", "ROM", "Flash", "EEPROM", "FEPROM", "EPROM", "CDRAM", "3DRAM", "SDRAM", "SGRAM", "RDRAM", "DDR", "DDR2", "DDR2 FB-DIMM", "Reserved", "Reserved", "Reserved", "DDR3", "FBD2", /* 0x19 */ }; if (code >= 0x01 && code <= 0x19) return type[code - 0x01]; return out_of_spec; } static void dmi_memory_device_type_detail(u16 code) { /* 7.18.3 */ static const char *detail[] = { "Other", /* 1 */ "Unknown", "Fast-paged", "Static Column", "Pseudo-static", "RAMBus", "Synchronous", "CMOS", "EDO", "Window DRAM", "Cache DRAM", "Non-Volatile", "Registered (Buffered)", "Unbuffered (Unregistered)" /* 14 */ }; if ((code & 0x7FFE) == 0) printf(" None"); else { int i; for (i = 1; i <= 14; i++) if (code & (1 << i)) printf(" %s", detail[i - 1]); } } static void dmi_memory_device_speed(u16 code) { if (code == 0) printf(" Unknown"); else printf(" %u MHz", code); } /* * 7.19 32-bit Memory Error Information (Type 18) */ static const char *dmi_memory_error_type(u8 code) { /* 7.19.1 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "OK", "Bad Read", "Parity Error", "Single-bit Error", "Double-bit Error", "Multi-bit Error", "Nibble Error", "Checksum Error", "CRC Error", "Corrected Single-bit Error", "Corrected Error", "Uncorrectable Error" /* 0x0E */ }; if (code >= 0x01 && code <= 0x0E) return type[code - 0x01]; return out_of_spec; } static const char *dmi_memory_error_granularity(u8 code) { /* 7.19.2 */ static const char *granularity[] = { "Other", /* 0x01 */ "Unknown", "Device Level", "Memory Partition Level" /* 0x04 */ }; if (code >= 0x01 && code <= 0x04) return granularity[code - 0x01]; return out_of_spec; } static const char *dmi_memory_error_operation(u8 code) { /* 7.19.3 */ static const char *operation[] = { "Other", /* 0x01 */ "Unknown", "Read", "Write", "Partial Write" /* 0x05 */ }; if (code >= 0x01 && code <= 0x05) return operation[code - 0x01]; return out_of_spec; } static void dmi_memory_error_syndrome(u32 code) { if (code == 0x00000000) printf(" Unknown"); else printf(" 0x%08X", code); } static void dmi_32bit_memory_error_address(u32 code) { if (code == 0x80000000) printf(" Unknown"); else printf(" 0x%08X", code); } /* * 7.20 Memory Array Mapped Address (Type 19) */ static void dmi_mapped_address_size(u32 code) { if (code == 0) printf(" Invalid"); else { u64 size; size.h = 0; size.l = code; dmi_print_memory_size(size, 1); } } static void dmi_mapped_address_extended_size(u64 start, u64 end) { if (start.h == end.h && start.l == end.l) printf(" Invalid"); else dmi_print_memory_size(u64_range(start, end), 0); } /* * 7.21 Memory Device Mapped Address (Type 20) */ static void dmi_mapped_address_row_position(u8 code) { if (code == 0) printf(" %s", out_of_spec); else if (code == 0xFF) printf(" Unknown"); else printf(" %u", code); } static void dmi_mapped_address_interleave_position(u8 code, const char *prefix) { if (code != 0) { printf("%sInterleave Position:", prefix); if (code == 0xFF) printf(" Unknown"); else printf(" %u", code); printf("\n"); } } static void dmi_mapped_address_interleaved_data_depth(u8 code, const char *prefix) { if (code != 0) { printf("%sInterleaved Data Depth:", prefix); if (code == 0xFF) printf(" Unknown"); else printf(" %u", code); printf("\n"); } } /* * 7.22 Built-in Pointing Device (Type 21) */ static const char *dmi_pointing_device_type(u8 code) { /* 7.22.1 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "Mouse", "Track Ball", "Track Point", "Glide Point", "Touch Pad", "Touch Screen", "Optical Sensor" /* 0x09 */ }; if (code >= 0x01 && code <= 0x09) return type[code - 0x01]; return out_of_spec; } static const char *dmi_pointing_device_interface(u8 code) { /* 7.22.2 */ static const char *interface[] = { "Other", /* 0x01 */ "Unknown", "Serial", "PS/2", "Infrared", "HIP-HIL", "Bus Mouse", "ADB (Apple Desktop Bus)" /* 0x08 */ }; static const char *interface_0xA0[] = { "Bus Mouse DB-9", /* 0xA0 */ "Bus Mouse Micro DIN", "USB" /* 0xA2 */ }; if (code >= 0x01 && code <= 0x08) return interface[code - 0x01]; if (code >= 0xA0 && code <= 0xA2) return interface_0xA0[code - 0xA0]; return out_of_spec; } /* * 7.23 Portable Battery (Type 22) */ static const char *dmi_battery_chemistry(u8 code) { /* 7.23.1 */ static const char *chemistry[] = { "Other", /* 0x01 */ "Unknown", "Lead Acid", "Nickel Cadmium", "Nickel Metal Hydride", "Lithium Ion", "Zinc Air", "Lithium Polymer" /* 0x08 */ }; if (code >= 0x01 && code <= 0x08) return chemistry[code - 0x01]; return out_of_spec; } static void dmi_battery_capacity(u16 code, u8 multiplier) { if (code == 0) printf(" Unknown"); else printf(" %u mWh", code * multiplier); } static void dmi_battery_voltage(u16 code) { if (code == 0) printf(" Unknown"); else printf(" %u mV", code); } static void dmi_battery_maximum_error(u8 code) { if (code == 0xFF) printf(" Unknown"); else printf(" %u%%", code); } /* * 7.24 System Reset (Type 23) */ /* code is assumed to be a 2-bit value */ static const char *dmi_system_reset_boot_option(u8 code) { static const char *option[] = { out_of_spec, /* 0x0 */ "Operating System", /* 0x1 */ "System Utilities", "Do Not Reboot" /* 0x3 */ }; return option[code]; } static void dmi_system_reset_count(u16 code) { if (code == 0xFFFF) printf(" Unknown"); else printf(" %u", code); } static void dmi_system_reset_timer(u16 code) { if (code == 0xFFFF) printf(" Unknown"); else printf(" %u min", code); } /* * 7.25 Hardware Security (Type 24) */ static const char *dmi_hardware_security_status(u8 code) { static const char *status[] = { "Disabled", /* 0x00 */ "Enabled", "Not Implemented", "Unknown" /* 0x03 */ }; return status[code]; } /* * 7.26 System Power Controls (Type 25) */ static void dmi_power_controls_power_on(const u8 *p) { /* 7.26.1 */ if (dmi_bcd_range(p[0], 0x01, 0x12)) printf(" %02X", p[0]); else printf(" *"); if (dmi_bcd_range(p[1], 0x01, 0x31)) printf("-%02X", p[1]); else printf("-*"); if (dmi_bcd_range(p[2], 0x00, 0x23)) printf(" %02X", p[2]); else printf(" *"); if (dmi_bcd_range(p[3], 0x00, 0x59)) printf(":%02X", p[3]); else printf(":*"); if (dmi_bcd_range(p[4], 0x00, 0x59)) printf(":%02X", p[4]); else printf(":*"); } /* * 7.27 Voltage Probe (Type 26) */ static const char *dmi_voltage_probe_location(u8 code) { /* 7.27.1 */ static const char *location[] = { "Other", /* 0x01 */ "Unknown", "Processor", "Disk", "Peripheral Bay", "System Management Module", "Motherboard", "Memory Module", "Processor Module", "Power Unit", "Add-in Card" /* 0x0B */ }; if (code >= 0x01 && code <= 0x0B) return location[code - 0x01]; return out_of_spec; } static const char *dmi_probe_status(u8 code) { /* 7.27.1 */ static const char *status[] = { "Other", /* 0x01 */ "Unknown", "OK", "Non-critical", "Critical", "Non-recoverable" /* 0x06 */ }; if (code >= 0x01 && code <= 0x06) return status[code - 0x01]; return out_of_spec; } static void dmi_voltage_probe_value(u16 code) { if (code == 0x8000) printf(" Unknown"); else printf(" %.3f V", (float)(i16)code / 1000); } static void dmi_voltage_probe_resolution(u16 code) { if (code == 0x8000) printf(" Unknown"); else printf(" %.1f mV", (float)code / 10); } static void dmi_probe_accuracy(u16 code) { if (code == 0x8000) printf(" Unknown"); else printf(" %.2f%%", (float)code / 100); } /* * 7.28 Cooling Device (Type 27) */ static const char *dmi_cooling_device_type(u8 code) { /* 7.28.1 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "Fan", "Centrifugal Blower", "Chip Fan", "Cabinet Fan", "Power Supply Fan", "Heat Pipe", "Integrated Refrigeration" /* 0x09 */ }; static const char *type_0x10[] = { "Active Cooling", /* 0x10 */ "Passive Cooling" /* 0x11 */ }; if (code >= 0x01 && code <= 0x09) return type[code - 0x01]; if (code >= 0x10 && code <= 0x11) return type_0x10[code - 0x10]; return out_of_spec; } static void dmi_cooling_device_speed(u16 code) { if (code == 0x8000) printf(" Unknown Or Non-rotating"); else printf(" %u rpm", code); } /* * 7.29 Temperature Probe (Type 28) */ static const char *dmi_temperature_probe_location(u8 code) { /* 7.29.1 */ static const char *location[] = { "Other", /* 0x01 */ "Unknown", "Processor", "Disk", "Peripheral Bay", "System Management Module", "Motherboard", "Memory Module", "Processor Module", "Power Unit", "Add-in Card", "Front Panel Board", "Back Panel Board", "Power System Board", "Drive Back Plane" /* 0x0F */ }; if (code >= 0x01 && code <= 0x0F) return location[code - 0x01]; return out_of_spec; } static void dmi_temperature_probe_value(u16 code) { if (code == 0x8000) printf(" Unknown"); else printf(" %.1f deg C", (float)(i16)code / 10); } static void dmi_temperature_probe_resolution(u16 code) { if (code == 0x8000) printf(" Unknown"); else printf(" %.3f deg C", (float)code / 1000); } /* * 7.30 Electrical Current Probe (Type 29) */ static void dmi_current_probe_value(u16 code) { if (code == 0x8000) printf(" Unknown"); else printf(" %.3f A", (float)(i16)code / 1000); } static void dmi_current_probe_resolution(u16 code) { if (code == 0x8000) printf(" Unknown"); else printf(" %.1f mA", (float)code / 10); } /* * 7.33 System Boot Information (Type 32) */ static const char *dmi_system_boot_status(u8 code) { static const char *status[] = { "No errors detected", /* 0 */ "No bootable media", "Operating system failed to load", "Firmware-detected hardware failure", "Operating system-detected hardware failure", "User-requested boot", "System security violation", "Previously-requested image", "System watchdog timer expired" /* 8 */ }; if (code <= 8) return status[code]; if (code >= 128 && code <= 191) return "OEM-specific"; if (code >= 192) return "Product-specific"; return out_of_spec; } /* * 7.34 64-bit Memory Error Information (Type 33) */ static void dmi_64bit_memory_error_address(u64 code) { if (code.h == 0x80000000 && code.l == 0x00000000) printf(" Unknown"); else printf(" 0x%08X%08X", code.h, code.l); } /* * 7.35 Management Device (Type 34) */ static const char *dmi_management_device_type(u8 code) { /* 7.35.1 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "LM75", "LM78", "LM79", "LM80", "LM81", "ADM9240", "DS1780", "MAX1617", "GL518SM", "W83781D", "HT82H791" /* 0x0D */ }; if (code >= 0x01 && code <= 0x0D) return type[code - 0x01]; return out_of_spec; } static const char *dmi_management_device_address_type(u8 code) { /* 7.35.2 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "I/O Port", "Memory", "SMBus" /* 0x05 */ }; if (code >= 0x01 && code <= 0x05) return type[code - 0x01]; return out_of_spec; } /* * 7.38 Memory Channel (Type 37) */ static const char *dmi_memory_channel_type(u8 code) { /* 7.38.1 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "RamBus", "SyncLink" /* 0x04 */ }; if (code >= 0x01 && code <= 0x04) return type[code - 0x01]; return out_of_spec; } static void dmi_memory_channel_devices(u8 count, const u8 *p, const char *prefix) { int i; for (i = 1; i <= count; i++) { printf("%sDevice %u Load: %u\n", prefix, i, p[3 * i]); if (!(opt.flags & FLAG_QUIET)) printf("%sDevice %u Handle: 0x%04X\n", prefix, i, WORD(p + 3 * i + 1)); } } /* * 7.39 IPMI Device Information (Type 38) */ static const char *dmi_ipmi_interface_type(u8 code) { /* 7.39.1 and IPMI 2.0, appendix C1, table C1-2 */ static const char *type[] = { "Unknown", /* 0x00 */ "KCS (Keyboard Control Style)", "SMIC (Server Management Interface Chip)", "BT (Block Transfer)", "SSIF (SMBus System Interface)" /* 0x04 */ }; if (code <= 0x04) return type[code]; return out_of_spec; } static void dmi_ipmi_base_address(u8 type, const u8 *p, u8 lsb) { if (type == 0x04) /* SSIF */ { printf("0x%02X (SMBus)", (*p) >> 1); } else { u64 address = QWORD(p); printf("0x%08X%08X (%s)", address.h, (address.l & ~1) | lsb, address.l & 1 ? "I/O" : "Memory-mapped"); } } /* code is assumed to be a 2-bit value */ static const char *dmi_ipmi_register_spacing(u8 code) { /* IPMI 2.0, appendix C1, table C1-1 */ static const char *spacing[] = { "Successive Byte Boundaries", /* 0x00 */ "32-bit Boundaries", "16-byte Boundaries", /* 0x02 */ out_of_spec /* 0x03 */ }; return spacing[code]; } /* * 7.40 System Power Supply (Type 39) */ static void dmi_power_supply_power(u16 code) { if (code == 0x8000) printf(" Unknown"); else printf(" %u W", (unsigned int)code); } static const char *dmi_power_supply_type(u8 code) { /* 7.40.1 */ static const char *type[] = { "Other", /* 0x01 */ "Unknown", "Linear", "Switching", "Battery", "UPS", "Converter", "Regulator" /* 0x08 */ }; if (code >= 0x01 && code <= 0x08) return type[code - 0x01]; return out_of_spec; } static const char *dmi_power_supply_status(u8 code) { /* 7.40.1 */ static const char *status[] = { "Other", /* 0x01 */ "Unknown", "OK", "Non-critical", "Critical" /* 0x05 */ }; if (code >= 0x01 && code <= 0x05) return status[code - 0x01]; return out_of_spec; } static const char *dmi_power_supply_range_switching(u8 code) { /* 7.40.1 */ static const char *switching[] = { "Other", /* 0x01 */ "Unknown", "Manual", "Auto-switch", "Wide Range", "N/A" /* 0x06 */ }; if (code >= 0x01 && code <= 0x06) return switching[code - 0x01]; return out_of_spec; } /* * 7.41 Additional Information (Type 40) * * Proper support of this entry type would require redesigning a large part of * the code, so I am waiting to see actual implementations of it to decide * whether it's worth the effort. */ static void dmi_additional_info(const struct dmi_header *h, const char *prefix) { u8 *p = h->data + 4; u8 count = *p++; u8 length; int i, offset = 5; for (i = 0; i < count; i++) { printf("%sAdditional Information %d\n", prefix, i + 1); /* Check for short entries */ if (h->length < offset + 1) break; length = p[0x00]; if (length < 0x05 || h->length < offset + length) break; printf("%s\tReferenced Handle: 0x%04x\n", prefix, WORD(p + 0x01)); printf("%s\tReferenced Offset: 0x%02x\n", prefix, p[0x03]); printf("%s\tString: %s\n", prefix, dmi_string(h, p[0x04])); printf("%s\tValue: ", prefix); switch (length - 0x05) { case 1: printf("0x%02x", p[0x05]); break; case 2: printf("0x%04x", WORD(p + 0x05)); break; case 4: printf("0x%08x", DWORD(p + 0x05)); break; default: printf("Unexpected size"); break; } printf("\n"); p += length; offset += length; } } /* * 7.43 Management Controller Host Interface (Type 42) */ static const char *dmi_management_controller_host_type(u8 code) { /* DMTF DSP0239 (MCTP) version 1.1.0 */ static const char *type[] = { "KCS: Keyboard Controller Style", /* 0x02 */ "8250 UART Register Compatible", "16450 UART Register Compatible", "16550/16550A UART Register Compatible", "16650/16650A UART Register Compatible", "16750/16750A UART Register Compatible", "16850/16850A UART Register Compatible" /* 0x08 */ }; if (code >= 0x02 && code <= 0x08) return type[code - 0x02]; if (code == 0xF0) return "OEM"; return out_of_spec; } /* * Main */ static void dmi_decode(const struct dmi_header *h, u16 ver) { const u8 *data = h->data; /* * Note: DMI types 37, 39 and 40 are untested */ switch (h->type) { case 0: /* 7.1 BIOS Information */ printf("BIOS Information\n"); if (h->length < 0x12) break; printf("\tVendor: %s\n", dmi_string(h, data[0x04])); printf("\tVersion: %s\n", dmi_string(h, data[0x05])); printf("\tRelease Date: %s\n", dmi_string(h, data[0x08])); /* * On IA-64, the BIOS base address will read 0 because * there is no BIOS. Skip the base address and the * runtime size in this case. */ if (WORD(data + 0x06) != 0) { printf("\tAddress: 0x%04X0\n", WORD(data + 0x06)); printf("\tRuntime Size:"); dmi_bios_runtime_size((0x10000 - WORD(data + 0x06)) << 4); printf("\n"); } printf("\tROM Size: %u kB\n", (data[0x09] + 1) << 6); printf("\tCharacteristics:\n"); dmi_bios_characteristics(QWORD(data + 0x0A), "\t\t"); if (h->length < 0x13) break; dmi_bios_characteristics_x1(data[0x12], "\t\t"); if (h->length < 0x14) break; dmi_bios_characteristics_x2(data[0x13], "\t\t"); if (h->length < 0x18) break; if (data[0x14] != 0xFF && data[0x15] != 0xFF) printf("\tBIOS Revision: %u.%u\n", data[0x14], data[0x15]); if (data[0x16] != 0xFF && data[0x17] != 0xFF) printf("\tFirmware Revision: %u.%u\n", data[0x16], data[0x17]); break; case 1: /* 7.2 System Information */ printf("System Information\n"); if (h->length < 0x08) break; printf("\tManufacturer: %s\n", dmi_string(h, data[0x04])); printf("\tProduct Name: %s\n", dmi_string(h, data[0x05])); printf("\tVersion: %s\n", dmi_string(h, data[0x06])); printf("\tSerial Number: %s\n", dmi_string(h, data[0x07])); if (h->length < 0x19) break; printf("\tUUID: "); dmi_system_uuid(data + 0x08, ver); printf("\n"); printf("\tWake-up Type: %s\n", dmi_system_wake_up_type(data[0x18])); if (h->length < 0x1B) break; printf("\tSKU Number: %s\n", dmi_string(h, data[0x19])); printf("\tFamily: %s\n", dmi_string(h, data[0x1A])); break; case 2: /* 7.3 Base Board Information */ printf("Base Board Information\n"); if (h->length < 0x08) break; printf("\tManufacturer: %s\n", dmi_string(h, data[0x04])); printf("\tProduct Name: %s\n", dmi_string(h, data[0x05])); printf("\tVersion: %s\n", dmi_string(h, data[0x06])); printf("\tSerial Number: %s\n", dmi_string(h, data[0x07])); if (h->length < 0x09) break; printf("\tAsset Tag: %s\n", dmi_string(h, data[0x08])); if (h->length < 0x0A) break; printf("\tFeatures:"); dmi_base_board_features(data[0x09], "\t\t"); if (h->length < 0x0E) break; printf("\tLocation In Chassis: %s\n", dmi_string(h, data[0x0A])); if (!(opt.flags & FLAG_QUIET)) printf("\tChassis Handle: 0x%04X\n", WORD(data + 0x0B)); printf("\tType: %s\n", dmi_base_board_type(data[0x0D])); if (h->length < 0x0F) break; if (h->length < 0x0F + data[0x0E] * sizeof(u16)) break; if (!(opt.flags & FLAG_QUIET)) dmi_base_board_handles(data[0x0E], data + 0x0F, "\t"); break; case 3: /* 7.4 Chassis Information */ printf("Chassis Information\n"); if (h->length < 0x09) break; printf("\tManufacturer: %s\n", dmi_string(h, data[0x04])); printf("\tType: %s\n", dmi_chassis_type(data[0x05] & 0x7F)); printf("\tLock: %s\n", dmi_chassis_lock(data[0x05] >> 7)); printf("\tVersion: %s\n", dmi_string(h, data[0x06])); printf("\tSerial Number: %s\n", dmi_string(h, data[0x07])); printf("\tAsset Tag: %s\n", dmi_string(h, data[0x08])); if (h->length < 0x0D) break; printf("\tBoot-up State: %s\n", dmi_chassis_state(data[0x09])); printf("\tPower Supply State: %s\n", dmi_chassis_state(data[0x0A])); printf("\tThermal State: %s\n", dmi_chassis_state(data[0x0B])); printf("\tSecurity Status: %s\n", dmi_chassis_security_status(data[0x0C])); if (h->length < 0x11) break; printf("\tOEM Information: 0x%08X\n", DWORD(data + 0x0D)); if (h->length < 0x13) break; printf("\tHeight:"); dmi_chassis_height(data[0x11]); printf("\n"); printf("\tNumber Of Power Cords:"); dmi_chassis_power_cords(data[0x12]); printf("\n"); if (h->length < 0x15) break; if (h->length < 0x15 + data[0x13] * data[0x14]) break; dmi_chassis_elements(data[0x13], data[0x14], data + 0x15, "\t"); if (h->length < 0x16 + data[0x13] * data[0x14]) break; printf("\tSKU Number: %s\n", dmi_string(h, data[0x15 + data[0x13] * data[0x14]])); break; case 4: /* 7.5 Processor Information */ printf("Processor Information\n"); if (h->length < 0x1A) break; printf("\tSocket Designation: %s\n", dmi_string(h, data[0x04])); printf("\tType: %s\n", dmi_processor_type(data[0x05])); printf("\tFamily: %s\n", dmi_processor_family(h, ver)); printf("\tManufacturer: %s\n", dmi_string(h, data[0x07])); dmi_processor_id(data[0x06], data + 0x08, dmi_string(h, data[0x10]), "\t"); printf("\tVersion: %s\n", dmi_string(h, data[0x10])); printf("\tVoltage:"); dmi_processor_voltage(data[0x11]); printf("\n"); printf("\tExternal Clock: "); dmi_processor_frequency(data + 0x12); printf("\n"); printf("\tMax Speed: "); dmi_processor_frequency(data + 0x14); printf("\n"); printf("\tCurrent Speed: "); dmi_processor_frequency(data + 0x16); printf("\n"); if (data[0x18] & (1 << 6)) printf("\tStatus: Populated, %s\n", dmi_processor_status(data[0x18] & 0x07)); else printf("\tStatus: Unpopulated\n"); printf("\tUpgrade: %s\n", dmi_processor_upgrade(data[0x19])); if (h->length < 0x20) break; if (!(opt.flags & FLAG_QUIET)) { printf("\tL1 Cache Handle:"); dmi_processor_cache(WORD(data + 0x1A), "L1", ver); printf("\n"); printf("\tL2 Cache Handle:"); dmi_processor_cache(WORD(data + 0x1C), "L2", ver); printf("\n"); printf("\tL3 Cache Handle:"); dmi_processor_cache(WORD(data + 0x1E), "L3", ver); printf("\n"); } if (h->length < 0x23) break; printf("\tSerial Number: %s\n", dmi_string(h, data[0x20])); printf("\tAsset Tag: %s\n", dmi_string(h, data[0x21])); printf("\tPart Number: %s\n", dmi_string(h, data[0x22])); if (h->length < 0x28) break; if (data[0x23] != 0) printf("\tCore Count: %u\n", data[0x23]); if (data[0x24] != 0) printf("\tCore Enabled: %u\n", data[0x24]); if (data[0x25] != 0) printf("\tThread Count: %u\n", data[0x25]); printf("\tCharacteristics:"); dmi_processor_characteristics(WORD(data + 0x26), "\t\t"); break; case 5: /* 7.6 Memory Controller Information */ printf("Memory Controller Information\n"); if (h->length < 0x0F) break; printf("\tError Detecting Method: %s\n", dmi_memory_controller_ed_method(data[0x04])); printf("\tError Correcting Capabilities:"); dmi_memory_controller_ec_capabilities(data[0x05], "\t\t"); printf("\tSupported Interleave: %s\n", dmi_memory_controller_interleave(data[0x06])); printf("\tCurrent Interleave: %s\n", dmi_memory_controller_interleave(data[0x07])); printf("\tMaximum Memory Module Size: %u MB\n", 1 << data[0x08]); printf("\tMaximum Total Memory Size: %u MB\n", data[0x0E] * (1 << data[0x08])); printf("\tSupported Speeds:"); dmi_memory_controller_speeds(WORD(data + 0x09), "\t\t"); printf("\tSupported Memory Types:"); dmi_memory_module_types(WORD(data + 0x0B), "\n\t\t"); printf("\n"); printf("\tMemory Module Voltage:"); dmi_processor_voltage(data[0x0D]); printf("\n"); if (h->length < 0x0F + data[0x0E] * sizeof(u16)) break; dmi_memory_controller_slots(data[0x0E], data + 0x0F, "\t"); if (h->length < 0x10 + data[0x0E] * sizeof(u16)) break; printf("\tEnabled Error Correcting Capabilities:"); dmi_memory_controller_ec_capabilities(data[0x0F + data[0x0E] * sizeof(u16)], "\t\t"); break; case 6: /* 7.7 Memory Module Information */ printf("Memory Module Information\n"); if (h->length < 0x0C) break; printf("\tSocket Designation: %s\n", dmi_string(h, data[0x04])); printf("\tBank Connections:"); dmi_memory_module_connections(data[0x05]); printf("\n"); printf("\tCurrent Speed:"); dmi_memory_module_speed(data[0x06]); printf("\n"); printf("\tType:"); dmi_memory_module_types(WORD(data + 0x07), " "); printf("\n"); printf("\tInstalled Size:"); dmi_memory_module_size(data[0x09]); printf("\n"); printf("\tEnabled Size:"); dmi_memory_module_size(data[0x0A]); printf("\n"); printf("\tError Status:"); dmi_memory_module_error(data[0x0B], "\t\t"); break; case 7: /* 7.8 Cache Information */ printf("Cache Information\n"); if (h->length < 0x0F) break; printf("\tSocket Designation: %s\n", dmi_string(h, data[0x04])); printf("\tConfiguration: %s, %s, Level %u\n", WORD(data + 0x05) & 0x0080 ? "Enabled" : "Disabled", WORD(data + 0x05) & 0x0008 ? "Socketed" : "Not Socketed", (WORD(data + 0x05) & 0x0007) + 1); printf("\tOperational Mode: %s\n", dmi_cache_mode((WORD(data + 0x05) >> 8) & 0x0003)); printf("\tLocation: %s\n", dmi_cache_location((WORD(data + 0x05) >> 5) & 0x0003)); printf("\tInstalled Size:"); dmi_cache_size(WORD(data + 0x09)); printf("\n"); printf("\tMaximum Size:"); dmi_cache_size(WORD(data + 0x07)); printf("\n"); printf("\tSupported SRAM Types:"); dmi_cache_types(WORD(data + 0x0B), "\n\t\t"); printf("\n"); printf("\tInstalled SRAM Type:"); dmi_cache_types(WORD(data + 0x0D), " "); printf("\n"); if (h->length < 0x13) break; printf("\tSpeed:"); dmi_memory_module_speed(data[0x0F]); printf("\n"); printf("\tError Correction Type: %s\n", dmi_cache_ec_type(data[0x10])); printf("\tSystem Type: %s\n", dmi_cache_type(data[0x11])); printf("\tAssociativity: %s\n", dmi_cache_associativity(data[0x12])); break; case 8: /* 7.9 Port Connector Information */ printf("Port Connector Information\n"); if (h->length < 0x09) break; printf("\tInternal Reference Designator: %s\n", dmi_string(h, data[0x04])); printf("\tInternal Connector Type: %s\n", dmi_port_connector_type(data[0x05])); printf("\tExternal Reference Designator: %s\n", dmi_string(h, data[0x06])); printf("\tExternal Connector Type: %s\n", dmi_port_connector_type(data[0x07])); printf("\tPort Type: %s\n", dmi_port_type(data[0x08])); break; case 9: /* 7.10 System Slots */ printf("System Slot Information\n"); if (h->length < 0x0C) break; printf("\tDesignation: %s\n", dmi_string(h, data[0x04])); printf("\tType: %s%s\n", dmi_slot_bus_width(data[0x06]), dmi_slot_type(data[0x05])); printf("\tCurrent Usage: %s\n", dmi_slot_current_usage(data[0x07])); printf("\tLength: %s\n", dmi_slot_length(data[0x08])); dmi_slot_id(data[0x09], data[0x0A], data[0x05], "\t"); printf("\tCharacteristics:"); if (h->length < 0x0D) dmi_slot_characteristics(data[0x0B], 0x00, "\t\t"); else dmi_slot_characteristics(data[0x0B], data[0x0C], "\t\t"); if (h->length < 0x11) break; dmi_slot_segment_bus_func(WORD(data + 0x0D), data[0x0F], data[0x10], "\t"); break; case 10: /* 7.11 On Board Devices Information */ dmi_on_board_devices(h, ""); break; case 11: /* 7.12 OEM Strings */ printf("OEM Strings\n"); if (h->length < 0x05) break; dmi_oem_strings(h, "\t"); break; case 12: /* 7.13 System Configuration Options */ printf("System Configuration Options\n"); if (h->length < 0x05) break; dmi_system_configuration_options(h, "\t"); break; case 13: /* 7.14 BIOS Language Information */ printf("BIOS Language Information\n"); if (h->length < 0x16) break; if (ver >= 0x0201) { printf("\tLanguage Description Format: %s\n", dmi_bios_language_format(data[0x05])); } printf("\tInstallable Languages: %u\n", data[0x04]); dmi_bios_languages(h, "\t\t"); printf("\tCurrently Installed Language: %s\n", dmi_string(h, data[0x15])); break; case 14: /* 7.15 Group Associations */ printf("Group Associations\n"); if (h->length < 0x05) break; printf("\tName: %s\n", dmi_string(h, data[0x04])); printf("\tItems: %u\n", (h->length - 0x05) / 3); dmi_group_associations_items((h->length - 0x05) / 3, data + 0x05, "\t\t"); break; case 15: /* 7.16 System Event Log */ printf("System Event Log\n"); if (h->length < 0x14) break; printf("\tArea Length: %u bytes\n", WORD(data + 0x04)); printf("\tHeader Start Offset: 0x%04X\n", WORD(data + 0x06)); if (WORD(data + 0x08) - WORD(data + 0x06)) printf("\tHeader Length: %u byte%s\n", WORD(data + 0x08) - WORD(data + 0x06), WORD(data + 0x08) - WORD(data + 0x06) > 1 ? "s" : ""); printf("\tData Start Offset: 0x%04X\n", WORD(data + 0x08)); printf("\tAccess Method: %s\n", dmi_event_log_method(data[0x0A])); printf("\tAccess Address:"); dmi_event_log_address(data[0x0A], data + 0x10); printf("\n"); printf("\tStatus:"); dmi_event_log_status(data[0x0B]); printf("\n"); printf("\tChange Token: 0x%08X\n", DWORD(data + 0x0C)); if (h->length < 0x17) break; printf("\tHeader Format: %s\n", dmi_event_log_header_type(data[0x14])); printf("\tSupported Log Type Descriptors: %u\n", data[0x15]); if (h->length < 0x17 + data[0x15] * data[0x16]) break; dmi_event_log_descriptors(data[0x15], data[0x16], data + 0x17, "\t"); break; case 16: /* 7.17 Physical Memory Array */ printf("Physical Memory Array\n"); if (h->length < 0x0F) break; printf("\tLocation: %s\n", dmi_memory_array_location(data[0x04])); printf("\tUse: %s\n", dmi_memory_array_use(data[0x05])); printf("\tError Correction Type: %s\n", dmi_memory_array_ec_type(data[0x06])); printf("\tMaximum Capacity:"); if (DWORD(data + 0x07) == 0x80000000) { if (h->length < 0x17) printf(" Unknown"); else dmi_print_memory_size(QWORD(data + 0x0F), 0); } else { u64 capacity; capacity.h = 0; capacity.l = DWORD(data + 0x07); dmi_print_memory_size(capacity, 1); } printf("\n"); if (!(opt.flags & FLAG_QUIET)) { printf("\tError Information Handle:"); dmi_memory_array_error_handle(WORD(data + 0x0B)); printf("\n"); } printf("\tNumber Of Devices: %u\n", WORD(data + 0x0D)); break; case 17: /* 7.18 Memory Device */ printf("Memory Device\n"); if (h->length < 0x15) break; if (!(opt.flags & FLAG_QUIET)) { printf("\tArray Handle: 0x%04X\n", WORD(data + 0x04)); printf("\tError Information Handle:"); dmi_memory_array_error_handle(WORD(data + 0x06)); printf("\n"); } printf("\tTotal Width:"); dmi_memory_device_width(WORD(data + 0x08)); printf("\n"); printf("\tData Width:"); dmi_memory_device_width(WORD(data + 0x0A)); printf("\n"); printf("\tSize:"); if (h->length >= 0x20 && WORD(data + 0x0C) == 0x7FFF) dmi_memory_device_extended_size(DWORD(data + 0x1C)); else dmi_memory_device_size(WORD(data + 0x0C)); printf("\n"); printf("\tForm Factor: %s\n", dmi_memory_device_form_factor(data[0x0E])); printf("\tSet:"); dmi_memory_device_set(data[0x0F]); printf("\n"); printf("\tLocator: %s\n", dmi_string(h, data[0x10])); printf("\tBank Locator: %s\n", dmi_string(h, data[0x11])); printf("\tType: %s\n", dmi_memory_device_type(data[0x12])); printf("\tType Detail:"); dmi_memory_device_type_detail(WORD(data + 0x13)); printf("\n"); if (h->length < 0x17) break; printf("\tSpeed:"); dmi_memory_device_speed(WORD(data + 0x15)); printf("\n"); if (h->length < 0x1B) break; printf("\tManufacturer: %s\n", dmi_string(h, data[0x17])); printf("\tSerial Number: %s\n", dmi_string(h, data[0x18])); printf("\tAsset Tag: %s\n", dmi_string(h, data[0x19])); printf("\tPart Number: %s\n", dmi_string(h, data[0x1A])); if (h->length < 0x1C) break; printf("\tRank: "); if ((data[0x1B] & 0x0F) == 0) printf("Unknown"); else printf("%u", data[0x1B] & 0x0F); printf("\n"); if (h->length < 0x22) break; printf("\tConfigured Clock Speed:"); dmi_memory_device_speed(WORD(data + 0x20)); printf("\n"); break; case 18: /* 7.19 32-bit Memory Error Information */ printf("32-bit Memory Error Information\n"); if (h->length < 0x17) break; printf("\tType: %s\n", dmi_memory_error_type(data[0x04])); printf("\tGranularity: %s\n", dmi_memory_error_granularity(data[0x05])); printf("\tOperation: %s\n", dmi_memory_error_operation(data[0x06])); printf("\tVendor Syndrome:"); dmi_memory_error_syndrome(DWORD(data + 0x07)); printf("\n"); printf("\tMemory Array Address:"); dmi_32bit_memory_error_address(DWORD(data + 0x0B)); printf("\n"); printf("\tDevice Address:"); dmi_32bit_memory_error_address(DWORD(data + 0x0F)); printf("\n"); printf("\tResolution:"); dmi_32bit_memory_error_address(DWORD(data + 0x13)); printf("\n"); break; case 19: /* 7.20 Memory Array Mapped Address */ printf("Memory Array Mapped Address\n"); if (h->length < 0x0F) break; if (h->length >= 0x1F && DWORD(data + 0x04) == 0xFFFFFFFF) { u64 start, end; start = QWORD(data + 0x0F); end = QWORD(data + 0x17); printf("\tStarting Address: 0x%08X%08Xk\n", start.h, start.l); printf("\tEnding Address: 0x%08X%08Xk\n", end.h, end.l); printf("\tRange Size:"); dmi_mapped_address_extended_size(start, end); } else { printf("\tStarting Address: 0x%08X%03X\n", DWORD(data + 0x04) >> 2, (DWORD(data + 0x04) & 0x3) << 10); printf("\tEnding Address: 0x%08X%03X\n", DWORD(data + 0x08) >> 2, ((DWORD(data + 0x08) & 0x3) << 10) + 0x3FF); printf("\tRange Size:"); dmi_mapped_address_size(DWORD(data + 0x08) - DWORD(data + 0x04) + 1); } printf("\n"); if (!(opt.flags & FLAG_QUIET)) printf("\tPhysical Array Handle: 0x%04X\n", WORD(data + 0x0C)); printf("\tPartition Width: %u\n", data[0x0E]); break; case 20: /* 7.21 Memory Device Mapped Address */ printf("Memory Device Mapped Address\n"); if (h->length < 0x13) break; if (h->length >= 0x23 && DWORD(data + 0x04) == 0xFFFFFFFF) { u64 start, end; start = QWORD(data + 0x13); end = QWORD(data + 0x1B); printf("\tStarting Address: 0x%08X%08Xk\n", start.h, start.l); printf("\tEnding Address: 0x%08X%08Xk\n", end.h, end.l); printf("\tRange Size:"); dmi_mapped_address_extended_size(start, end); } else { printf("\tStarting Address: 0x%08X%03X\n", DWORD(data + 0x04) >> 2, (DWORD(data + 0x04) & 0x3) << 10); printf("\tEnding Address: 0x%08X%03X\n", DWORD(data + 0x08) >> 2, ((DWORD(data + 0x08) & 0x3) << 10) + 0x3FF); printf("\tRange Size:"); dmi_mapped_address_size(DWORD(data + 0x08) - DWORD(data + 0x04) + 1); } printf("\n"); if (!(opt.flags & FLAG_QUIET)) { printf("\tPhysical Device Handle: 0x%04X\n", WORD(data + 0x0C)); printf("\tMemory Array Mapped Address Handle: 0x%04X\n", WORD(data + 0x0E)); } printf("\tPartition Row Position:"); dmi_mapped_address_row_position(data[0x10]); printf("\n"); dmi_mapped_address_interleave_position(data[0x11], "\t"); dmi_mapped_address_interleaved_data_depth(data[0x12], "\t"); break; case 21: /* 7.22 Built-in Pointing Device */ printf("Built-in Pointing Device\n"); if (h->length < 0x07) break; printf("\tType: %s\n", dmi_pointing_device_type(data[0x04])); printf("\tInterface: %s\n", dmi_pointing_device_interface(data[0x05])); printf("\tButtons: %u\n", data[0x06]); break; case 22: /* 7.23 Portable Battery */ printf("Portable Battery\n"); if (h->length < 0x10) break; printf("\tLocation: %s\n", dmi_string(h, data[0x04])); printf("\tManufacturer: %s\n", dmi_string(h, data[0x05])); if (data[0x06] || h->length < 0x1A) printf("\tManufacture Date: %s\n", dmi_string(h, data[0x06])); if (data[0x07] || h->length < 0x1A) printf("\tSerial Number: %s\n", dmi_string(h, data[0x07])); printf("\tName: %s\n", dmi_string(h, data[0x08])); if (data[0x09] != 0x02 || h->length < 0x1A) printf("\tChemistry: %s\n", dmi_battery_chemistry(data[0x09])); printf("\tDesign Capacity:"); if (h->length < 0x16) dmi_battery_capacity(WORD(data + 0x0A), 1); else dmi_battery_capacity(WORD(data + 0x0A), data[0x15]); printf("\n"); printf("\tDesign Voltage:"); dmi_battery_voltage(WORD(data + 0x0C)); printf("\n"); printf("\tSBDS Version: %s\n", dmi_string(h, data[0x0E])); printf("\tMaximum Error:"); dmi_battery_maximum_error(data[0x0F]); printf("\n"); if (h->length < 0x1A) break; if (data[0x07] == 0) printf("\tSBDS Serial Number: %04X\n", WORD(data + 0x10)); if (data[0x06] == 0) printf("\tSBDS Manufacture Date: %u-%02u-%02u\n", 1980 + (WORD(data + 0x12) >> 9), (WORD(data + 0x12) >> 5) & 0x0F, WORD(data + 0x12) & 0x1F); if (data[0x09] == 0x02) printf("\tSBDS Chemistry: %s\n", dmi_string(h, data[0x14])); printf("\tOEM-specific Information: 0x%08X\n", DWORD(data + 0x16)); break; case 23: /* 7.24 System Reset */ printf("System Reset\n"); if (h->length < 0x0D) break; printf("\tStatus: %s\n", data[0x04] & (1 << 0) ? "Enabled" : "Disabled"); printf("\tWatchdog Timer: %s\n", data[0x04] & (1 << 5) ? "Present" : "Not Present"); if (!(data[0x04] & (1 << 5))) break; printf("\tBoot Option: %s\n", dmi_system_reset_boot_option((data[0x04] >> 1) & 0x3)); printf("\tBoot Option On Limit: %s\n", dmi_system_reset_boot_option((data[0x04] >> 3) & 0x3)); printf("\tReset Count:"); dmi_system_reset_count(WORD(data + 0x05)); printf("\n"); printf("\tReset Limit:"); dmi_system_reset_count(WORD(data + 0x07)); printf("\n"); printf("\tTimer Interval:"); dmi_system_reset_timer(WORD(data + 0x09)); printf("\n"); printf("\tTimeout:"); dmi_system_reset_timer(WORD(data + 0x0B)); printf("\n"); break; case 24: /* 7.25 Hardware Security */ printf("Hardware Security\n"); if (h->length < 0x05) break; printf("\tPower-On Password Status: %s\n", dmi_hardware_security_status(data[0x04] >> 6)); printf("\tKeyboard Password Status: %s\n", dmi_hardware_security_status((data[0x04] >> 4) & 0x3)); printf("\tAdministrator Password Status: %s\n", dmi_hardware_security_status((data[0x04] >> 2) & 0x3)); printf("\tFront Panel Reset Status: %s\n", dmi_hardware_security_status(data[0x04] & 0x3)); break; case 25: /* 7.26 System Power Controls */ printf("\tSystem Power Controls\n"); if (h->length < 0x09) break; printf("\tNext Scheduled Power-on:"); dmi_power_controls_power_on(data + 0x04); printf("\n"); break; case 26: /* 7.27 Voltage Probe */ printf("Voltage Probe\n"); if (h->length < 0x14) break; printf("\tDescription: %s\n", dmi_string(h, data[0x04])); printf("\tLocation: %s\n", dmi_voltage_probe_location(data[0x05] & 0x1f)); printf("\tStatus: %s\n", dmi_probe_status(data[0x05] >> 5)); printf("\tMaximum Value:"); dmi_voltage_probe_value(WORD(data + 0x06)); printf("\n"); printf("\tMinimum Value:"); dmi_voltage_probe_value(WORD(data + 0x08)); printf("\n"); printf("\tResolution:"); dmi_voltage_probe_resolution(WORD(data + 0x0A)); printf("\n"); printf("\tTolerance:"); dmi_voltage_probe_value(WORD(data + 0x0C)); printf("\n"); printf("\tAccuracy:"); dmi_probe_accuracy(WORD(data + 0x0E)); printf("\n"); printf("\tOEM-specific Information: 0x%08X\n", DWORD(data + 0x10)); if (h->length < 0x16) break; printf("\tNominal Value:"); dmi_voltage_probe_value(WORD(data + 0x14)); printf("\n"); break; case 27: /* 7.28 Cooling Device */ printf("Cooling Device\n"); if (h->length < 0x0C) break; if (!(opt.flags & FLAG_QUIET) && WORD(data + 0x04) != 0xFFFF) printf("\tTemperature Probe Handle: 0x%04X\n", WORD(data + 0x04)); printf("\tType: %s\n", dmi_cooling_device_type(data[0x06] & 0x1f)); printf("\tStatus: %s\n", dmi_probe_status(data[0x06] >> 5)); if (data[0x07] != 0x00) printf("\tCooling Unit Group: %u\n", data[0x07]); printf("\tOEM-specific Information: 0x%08X\n", DWORD(data + 0x08)); if (h->length < 0x0E) break; printf("\tNominal Speed:"); dmi_cooling_device_speed(WORD(data + 0x0C)); printf("\n"); if (h->length < 0x0F) break; printf("\tDescription: %s\n", dmi_string(h, data[0x0E])); break; case 28: /* 7.29 Temperature Probe */ printf("Temperature Probe\n"); if (h->length < 0x14) break; printf("\tDescription: %s\n", dmi_string(h, data[0x04])); printf("\tLocation: %s\n", dmi_temperature_probe_location(data[0x05] & 0x1F)); printf("\tStatus: %s\n", dmi_probe_status(data[0x05] >> 5)); printf("\tMaximum Value:"); dmi_temperature_probe_value(WORD(data + 0x06)); printf("\n"); printf("\tMinimum Value:"); dmi_temperature_probe_value(WORD(data + 0x08)); printf("\n"); printf("\tResolution:"); dmi_temperature_probe_resolution(WORD(data + 0x0A)); printf("\n"); printf("\tTolerance:"); dmi_temperature_probe_value(WORD(data + 0x0C)); printf("\n"); printf("\tAccuracy:"); dmi_probe_accuracy(WORD(data + 0x0E)); printf("\n"); printf("\tOEM-specific Information: 0x%08X\n", DWORD(data + 0x10)); if (h->length < 0x16) break; printf("\tNominal Value:"); dmi_temperature_probe_value(WORD(data + 0x14)); printf("\n"); break; case 29: /* 7.30 Electrical Current Probe */ printf("Electrical Current Probe\n"); if (h->length < 0x14) break; printf("\tDescription: %s\n", dmi_string(h, data[0x04])); printf("\tLocation: %s\n", dmi_voltage_probe_location(data[5] & 0x1F)); printf("\tStatus: %s\n", dmi_probe_status(data[0x05] >> 5)); printf("\tMaximum Value:"); dmi_current_probe_value(WORD(data + 0x06)); printf("\n"); printf("\tMinimum Value:"); dmi_current_probe_value(WORD(data + 0x08)); printf("\n"); printf("\tResolution:"); dmi_current_probe_resolution(WORD(data + 0x0A)); printf("\n"); printf("\tTolerance:"); dmi_current_probe_value(WORD(data + 0x0C)); printf("\n"); printf("\tAccuracy:"); dmi_probe_accuracy(WORD(data + 0x0E)); printf("\n"); printf("\tOEM-specific Information: 0x%08X\n", DWORD(data + 0x10)); if (h->length < 0x16) break; printf("\tNominal Value:"); dmi_current_probe_value(WORD(data + 0x14)); printf("\n"); break; case 30: /* 7.31 Out-of-band Remote Access */ printf("Out-of-band Remote Access\n"); if (h->length < 0x06) break; printf("\tManufacturer Name: %s\n", dmi_string(h, data[0x04])); printf("\tInbound Connection: %s\n", data[0x05] & (1 << 0) ? "Enabled" : "Disabled"); printf("\tOutbound Connection: %s\n", data[0x05] & (1 << 1) ? "Enabled" : "Disabled"); break; case 31: /* 7.32 Boot Integrity Services Entry Point */ printf("Boot Integrity Services Entry Point\n"); if (h->length < 0x1C) break; printf("\tChecksum: %s\n", checksum(data, h->length) ? "OK" : "Invalid"); printf("\t16-bit Entry Point Address: %04X:%04X\n", DWORD(data + 0x08) >> 16, DWORD(data + 0x08) & 0xFFFF); printf("\t32-bit Entry Point Address: 0x%08X\n", DWORD(data + 0x0C)); break; case 32: /* 7.33 System Boot Information */ printf("System Boot Information\n"); if (h->length < 0x0B) break; printf("\tStatus: %s\n", dmi_system_boot_status(data[0x0A])); break; case 33: /* 7.34 64-bit Memory Error Information */ if (h->length < 0x1F) break; printf("64-bit Memory Error Information\n"); printf("\tType: %s\n", dmi_memory_error_type(data[0x04])); printf("\tGranularity: %s\n", dmi_memory_error_granularity(data[0x05])); printf("\tOperation: %s\n", dmi_memory_error_operation(data[0x06])); printf("\tVendor Syndrome:"); dmi_memory_error_syndrome(DWORD(data + 0x07)); printf("\n"); printf("\tMemory Array Address:"); dmi_64bit_memory_error_address(QWORD(data + 0x0B)); printf("\n"); printf("\tDevice Address:"); dmi_64bit_memory_error_address(QWORD(data + 0x13)); printf("\n"); printf("\tResolution:"); dmi_32bit_memory_error_address(DWORD(data + 0x1B)); printf("\n"); break; case 34: /* 7.35 Management Device */ printf("Management Device\n"); if (h->length < 0x0B) break; printf("\tDescription: %s\n", dmi_string(h, data[0x04])); printf("\tType: %s\n", dmi_management_device_type(data[0x05])); printf("\tAddress: 0x%08X\n", DWORD(data + 0x06)); printf("\tAddress Type: %s\n", dmi_management_device_address_type(data[0x0A])); break; case 35: /* 7.36 Management Device Component */ printf("Management Device Component\n"); if (h->length < 0x0B) break; printf("\tDescription: %s\n", dmi_string(h, data[0x04])); if (!(opt.flags & FLAG_QUIET)) { printf("\tManagement Device Handle: 0x%04X\n", WORD(data + 0x05)); printf("\tComponent Handle: 0x%04X\n", WORD(data + 0x07)); if (WORD(data + 0x09) != 0xFFFF) printf("\tThreshold Handle: 0x%04X\n", WORD(data + 0x09)); } break; case 36: /* 7.37 Management Device Threshold Data */ printf("Management Device Threshold Data\n"); if (h->length < 0x10) break; if (WORD(data + 0x04) != 0x8000) printf("\tLower Non-critical Threshold: %d\n", (i16)WORD(data + 0x04)); if (WORD(data + 0x06) != 0x8000) printf("\tUpper Non-critical Threshold: %d\n", (i16)WORD(data + 0x06)); if (WORD(data + 0x08) != 0x8000) printf("\tLower Critical Threshold: %d\n", (i16)WORD(data + 0x08)); if (WORD(data + 0x0A) != 0x8000) printf("\tUpper Critical Threshold: %d\n", (i16)WORD(data + 0x0A)); if (WORD(data + 0x0C) != 0x8000) printf("\tLower Non-recoverable Threshold: %d\n", (i16)WORD(data + 0x0C)); if (WORD(data + 0x0E) != 0x8000) printf("\tUpper Non-recoverable Threshold: %d\n", (i16)WORD(data + 0x0E)); break; case 37: /* 7.38 Memory Channel */ printf("Memory Channel\n"); if (h->length < 0x07) break; printf("\tType: %s\n", dmi_memory_channel_type(data[0x04])); printf("\tMaximal Load: %u\n", data[0x05]); printf("\tDevices: %u\n", data[0x06]); if (h->length < 0x07 + 3 * data[0x06]) break; dmi_memory_channel_devices(data[0x06], data + 0x07, "\t"); break; case 38: /* 7.39 IPMI Device Information */ /* * We use the word "Version" instead of "Revision", conforming to * the IPMI specification. */ printf("IPMI Device Information\n"); if (h->length < 0x10) break; printf("\tInterface Type: %s\n", dmi_ipmi_interface_type(data[0x04])); printf("\tSpecification Version: %u.%u\n", data[0x05] >> 4, data[0x05] & 0x0F); printf("\tI2C Slave Address: 0x%02x\n", data[0x06] >> 1); if (data[0x07] != 0xFF) printf("\tNV Storage Device Address: %u\n", data[0x07]); else printf("\tNV Storage Device: Not Present\n"); printf("\tBase Address: "); dmi_ipmi_base_address(data[0x04], data + 0x08, h->length < 0x11 ? 0 : (data[0x10] >> 4) & 1); printf("\n"); if (h->length < 0x12) break; if (data[0x04] != 0x04) { printf("\tRegister Spacing: %s\n", dmi_ipmi_register_spacing(data[0x10] >> 6)); if (data[0x10] & (1 << 3)) { printf("\tInterrupt Polarity: %s\n", data[0x10] & (1 << 1) ? "Active High" : "Active Low"); printf("\tInterrupt Trigger Mode: %s\n", data[0x10] & (1 << 0) ? "Level" : "Edge"); } } if (data[0x11] != 0x00) { printf("\tInterrupt Number: %x\n", data[0x11]); } break; case 39: /* 7.40 System Power Supply */ printf("System Power Supply\n"); if (h->length < 0x10) break; if (data[0x04] != 0x00) printf("\tPower Unit Group: %u\n", data[0x04]); printf("\tLocation: %s\n", dmi_string(h, data[0x05])); printf("\tName: %s\n", dmi_string(h, data[0x06])); printf("\tManufacturer: %s\n", dmi_string(h, data[0x07])); printf("\tSerial Number: %s\n", dmi_string(h, data[0x08])); printf("\tAsset Tag: %s\n", dmi_string(h, data[0x09])); printf("\tModel Part Number: %s\n", dmi_string(h, data[0x0A])); printf("\tRevision: %s\n", dmi_string(h, data[0x0B])); printf("\tMax Power Capacity:"); dmi_power_supply_power(WORD(data + 0x0C)); printf("\n"); printf("\tStatus:"); if (WORD(data + 0x0E) & (1 << 1)) printf(" Present, %s", dmi_power_supply_status((WORD(data + 0x0E) >> 7) & 0x07)); else printf(" Not Present"); printf("\n"); printf("\tType: %s\n", dmi_power_supply_type((WORD(data + 0x0E) >> 10) & 0x0F)); printf("\tInput Voltage Range Switching: %s\n", dmi_power_supply_range_switching((WORD(data + 0x0E) >> 3) & 0x0F)); printf("\tPlugged: %s\n", WORD(data + 0x0E) & (1 << 2) ? "No" : "Yes"); printf("\tHot Replaceable: %s\n", WORD(data + 0x0E) & (1 << 0) ? "Yes" : "No"); if (h->length < 0x16) break; if (!(opt.flags & FLAG_QUIET)) { if (WORD(data + 0x10) != 0xFFFF) printf("\tInput Voltage Probe Handle: 0x%04X\n", WORD(data + 0x10)); if (WORD(data + 0x12) != 0xFFFF) printf("\tCooling Device Handle: 0x%04X\n", WORD(data + 0x12)); if (WORD(data + 0x14) != 0xFFFF) printf("\tInput Current Probe Handle: 0x%04X\n", WORD(data + 0x14)); } break; case 40: /* 7.41 Additional Information */ if (h->length < 0x0B) break; if (!(opt.flags & FLAG_QUIET)) dmi_additional_info(h, ""); break; case 41: /* 7.42 Onboard Device Extended Information */ printf("Onboard Device\n"); if (h->length < 0x0B) break; printf("\tReference Designation: %s\n", dmi_string(h, data[0x04])); printf("\tType: %s\n", dmi_on_board_devices_type(data[0x05] & 0x7F)); printf("\tStatus: %s\n", data[0x05] & 0x80 ? "Enabled" : "Disabled"); printf("\tType Instance: %u\n", data[0x06]); dmi_slot_segment_bus_func(WORD(data + 0x07), data[0x09], data[0x0A], "\t"); break; case 42: /* 7.43 Management Controller Host Interface */ printf("Management Controller Host Interface\n"); if (h->length < 0x05) break; printf("\tInterface Type: %s\n", dmi_management_controller_host_type(data[0x04])); /* * There you have a type-dependent, variable-length * part in the middle of the structure, with no * length specifier, so no easy way to decode the * common, final part of the structure. What a pity. */ if (h->length < 0x09) break; if (data[0x04] == 0xF0) /* OEM */ { printf("\tVendor ID: 0x%02X%02X%02X%02X\n", data[0x05], data[0x06], data[0x07], data[0x08]); } break; case 126: /* 7.44 Inactive */ printf("Inactive\n"); break; case 127: /* 7.45 End Of Table */ printf("End Of Table\n"); break; default: if (dmi_decode_oem(h)) break; if (opt.flags & FLAG_QUIET) return; printf("%s Type\n", h->type >= 128 ? "OEM-specific" : "Unknown"); dmi_dump(h, "\t"); } printf("\n"); } static void to_dmi_header(struct dmi_header *h, u8 *data) { h->type = data[0]; h->length = data[1]; h->handle = WORD(data + 2); h->data = data; } static void dmi_table_string(const struct dmi_header *h, const u8 *data, u16 ver) { int key; u8 offset = opt.string->offset; if (offset >= h->length) return; key = (opt.string->type << 8) | offset; switch (key) { case 0x108: dmi_system_uuid(data + offset, ver); printf("\n"); break; case 0x305: printf("%s\n", dmi_chassis_type(data[offset])); break; case 0x406: printf("%s\n", dmi_processor_family(h, ver)); break; case 0x416: dmi_processor_frequency(data + offset); printf("\n"); break; default: printf("%s\n", dmi_string(h, data[offset])); } } static void dmi_table_dump(u32 base, u16 len, const char *devmem) { u8 *buf; if ((buf = mem_chunk(base, len, devmem)) == NULL) { fprintf(stderr, "Failed to read table, sorry.\n"); return; } if (!(opt.flags & FLAG_QUIET)) printf("# Writing %d bytes to %s.\n", len, opt.dumpfile); write_dump(32, len, buf, opt.dumpfile, 0); free(buf); } static void dmi_table(u32 base, u16 len, u16 num, u16 ver, const char *devmem) { u8 *buf; u8 *data; int i = 0; if (ver > SUPPORTED_SMBIOS_VER) { printf("# SMBIOS implementations newer than version %u.%u are not\n" "# fully supported by this version of dmidecode.\n", SUPPORTED_SMBIOS_VER >> 8, SUPPORTED_SMBIOS_VER & 0xFF); } if (opt.flags & FLAG_DUMP_BIN) { dmi_table_dump(base, len, devmem); return; } if (!(opt.flags & FLAG_QUIET)) { if (opt.type == NULL) { printf("%u structures occupying %u bytes.\n", num, len); if (!(opt.flags & FLAG_FROM_DUMP)) printf("Table at 0x%08X.\n", base); } printf("\n"); } if ((buf = mem_chunk(base, len, devmem)) == NULL) { fprintf(stderr, "Table is unreachable, sorry." #ifndef USE_MMAP " Try compiling dmidecode with -DUSE_MMAP." #endif "\n"); return; } data = buf; while (i < num && data+4 <= buf + len) /* 4 is the length of an SMBIOS structure header */ { u8 *next; struct dmi_header h; int display; to_dmi_header(&h, data); display = ((opt.type == NULL || opt.type[h.type]) && !((opt.flags & FLAG_QUIET) && (h.type > 39 && h.type <= 127)) && !opt.string); /* * 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 his/her * table is broken. */ if (h.length < 4) { printf("Invalid entry length (%u). DMI table is " "broken! Stop.\n\n", (unsigned int)h.length); opt.flags |= FLAG_QUIET; break; } /* In quiet mode, stop decoding at end of table marker */ if ((opt.flags & FLAG_QUIET) && h.type == 127) break; if (display && (!(opt.flags & FLAG_QUIET) || (opt.flags & FLAG_DUMP))) printf("Handle 0x%04X, DMI type %d, %d bytes\n", h.handle, h.type, h.length); /* assign vendor for vendor-specific decodes later */ if (h.type == 0 && h.length >= 5) dmi_set_vendor(dmi_string(&h, data[0x04])); /* look for the next handle */ next = data + h.length; while (next - buf + 1 < len && (next[0] != 0 || next[1] != 0)) next++; next += 2; if (display) { if (next - buf <= len) { if (opt.flags & FLAG_DUMP) { dmi_dump(&h, "\t"); printf("\n"); } else dmi_decode(&h, ver); } else if (!(opt.flags & FLAG_QUIET)) printf("\t\n\n"); } else if (opt.string != NULL && opt.string->type == h.type) dmi_table_string(&h, data, ver); data = next; i++; } if (!(opt.flags & FLAG_QUIET)) { if (i != num) printf("Wrong DMI structures count: %d announced, " "only %d decoded.\n", num, i); if (data - buf != len) printf("Wrong DMI structures length: %d bytes " "announced, structures occupy %d bytes.\n", len, (unsigned int)(data - buf)); } free(buf); } /* * Build a crafted entry point with table address hard-coded to 32, * as this is where we will put it in the output file. We adjust the * DMI checksum appropriately. The SMBIOS checksum needs no adjustment. */ static void overwrite_dmi_address(u8 *buf) { buf[0x05] += buf[0x08] + buf[0x09] + buf[0x0A] + buf[0x0B] - 32; buf[0x08] = 32; buf[0x09] = 0; buf[0x0A] = 0; buf[0x0B] = 0; } static int smbios_decode(u8 *buf, const char *devmem) { u16 ver; if (!checksum(buf, buf[0x05]) || memcmp(buf + 0x10, "_DMI_", 5) != 0 || !checksum(buf + 0x10, 0x0F)) return 0; ver = (buf[0x06] << 8) + buf[0x07]; /* Some BIOS report weird SMBIOS version, fix that up */ switch (ver) { case 0x021F: case 0x0221: if (!(opt.flags & FLAG_QUIET)) printf("SMBIOS version fixup (2.%d -> 2.%d).\n", ver & 0xFF, 3); ver = 0x0203; break; case 0x0233: if (!(opt.flags & FLAG_QUIET)) printf("SMBIOS version fixup (2.%d -> 2.%d).\n", 51, 6); ver = 0x0206; break; } if (!(opt.flags & FLAG_QUIET)) printf("SMBIOS %u.%u present.\n", ver >> 8, ver & 0xFF); dmi_table(DWORD(buf + 0x18), WORD(buf + 0x16), WORD(buf + 0x1C), ver, devmem); if (opt.flags & FLAG_DUMP_BIN) { u8 crafted[32]; memcpy(crafted, buf, 32); overwrite_dmi_address(crafted + 0x10); if (!(opt.flags & FLAG_QUIET)) printf("# Writing %d bytes to %s.\n", crafted[0x05], opt.dumpfile); write_dump(0, crafted[0x05], crafted, opt.dumpfile, 1); } return 1; } static int legacy_decode(u8 *buf, const char *devmem) { if (!checksum(buf, 0x0F)) return 0; if (!(opt.flags & FLAG_QUIET)) printf("Legacy DMI %u.%u present.\n", buf[0x0E] >> 4, buf[0x0E] & 0x0F); dmi_table(DWORD(buf + 0x08), WORD(buf + 0x06), WORD(buf + 0x0C), ((buf[0x0E] & 0xF0) << 4) + (buf[0x0E] & 0x0F), devmem); if (opt.flags & FLAG_DUMP_BIN) { u8 crafted[16]; memcpy(crafted, buf, 16); overwrite_dmi_address(crafted); printf("# Writing %d bytes to %s.\n", 0x0F, opt.dumpfile); write_dump(0, 0x0F, crafted, opt.dumpfile, 1); } return 1; } /* * Probe for EFI interface */ #define EFI_NOT_FOUND (-1) #define EFI_NO_SMBIOS (-2) static int address_from_efi(size_t *address) { FILE *efi_systab; const char *filename; char linebuf[64]; int ret; *address = 0; /* Prevent compiler warning */ /* * Linux up to 2.6.6: /proc/efi/systab * Linux 2.6.7 and up: /sys/firmware/efi/systab */ if ((efi_systab = fopen(filename = "/sys/firmware/efi/systab", "r")) == NULL && (efi_systab = fopen(filename = "/proc/efi/systab", "r")) == NULL) { /* No EFI interface, fallback to memory scan */ return EFI_NOT_FOUND; } ret = EFI_NO_SMBIOS; while ((fgets(linebuf, sizeof(linebuf) - 1, efi_systab)) != NULL) { char *addrp = strchr(linebuf, '='); *(addrp++) = '\0'; if (strcmp(linebuf, "SMBIOS") == 0) { *address = strtoul(addrp, NULL, 0); if (!(opt.flags & FLAG_QUIET)) printf("# SMBIOS entry point at 0x%08lx\n", (unsigned long)*address); ret = 0; break; } } if (fclose(efi_systab) != 0) perror(filename); if (ret == EFI_NO_SMBIOS) fprintf(stderr, "%s: SMBIOS entry point missing\n", filename); return ret; } int main(int argc, char * const argv[]) { int ret = 0; /* Returned value */ int found = 0; size_t fp; int efi; u8 *buf; if (sizeof(u8) != 1 || sizeof(u16) != 2 || sizeof(u32) != 4 || '\0' != 0) { fprintf(stderr, "%s: compiler incompatibility\n", argv[0]); exit(255); } /* Set default option values */ opt.devmem = DEFAULT_MEM_DEV; opt.flags = 0; if (parse_command_line(argc, argv)<0) { ret = 2; goto exit_free; } if (opt.flags & FLAG_HELP) { print_help(); goto exit_free; } if (opt.flags & FLAG_VERSION) { printf("%s\n", VERSION); goto exit_free; } if (!(opt.flags & FLAG_QUIET)) printf("# dmidecode %s\n", VERSION); /* Read from dump if so instructed */ if (opt.flags & FLAG_FROM_DUMP) { if (!(opt.flags & FLAG_QUIET)) printf("Reading SMBIOS/DMI data from file %s.\n", opt.dumpfile); if ((buf = mem_chunk(0, 0x20, opt.dumpfile)) == NULL) { ret = 1; goto exit_free; } if (memcmp(buf, "_SM_", 4) == 0) { if (smbios_decode(buf, opt.dumpfile)) found++; } else if (memcmp(buf, "_DMI_", 5) == 0) { if (legacy_decode(buf, opt.dumpfile)) found++; } goto done; } /* First try EFI (ia64, Intel-based Mac) */ efi = address_from_efi(&fp); switch (efi) { case EFI_NOT_FOUND: goto memory_scan; case EFI_NO_SMBIOS: ret = 1; goto exit_free; } if ((buf = mem_chunk(fp, 0x20, opt.devmem)) == NULL) { ret = 1; goto exit_free; } if (smbios_decode(buf, opt.devmem)) found++; goto done; memory_scan: /* Fallback to memory scan (x86, x86_64) */ if ((buf = mem_chunk(0xF0000, 0x10000, opt.devmem)) == NULL) { ret = 1; goto exit_free; } for (fp = 0; fp <= 0xFFF0; fp += 16) { if (memcmp(buf + fp, "_SM_", 4) == 0 && fp <= 0xFFE0) { if (smbios_decode(buf+fp, opt.devmem)) { found++; fp += 16; } } else if (memcmp(buf + fp, "_DMI_", 5) == 0) { if (legacy_decode(buf + fp, opt.devmem)) found++; } } done: if (!found && !(opt.flags & FLAG_QUIET)) printf("# No SMBIOS nor DMI entry point found, sorry.\n"); free(buf); exit_free: free(opt.type); return ret; }