/* * Decoding of OEM-specific entries * This file is part of the dmidecode project. * * Copyright (C) 2007-2025 Jean Delvare * Copyright (C) 2017-2025 Jerry Hoemann * * 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 */ #include #include #include "types.h" #include "util.h" #include "dmidecode.h" #include "dmioem.h" #include "dmiopt.h" #include "dmioutput.h" /* * Globals for vendor-specific decodes */ enum DMI_VENDORS { VENDOR_UNKNOWN, VENDOR_ACER, VENDOR_DELL, VENDOR_HP, VENDOR_HPE, VENDOR_IBM, VENDOR_LENOVO, }; static enum DMI_VENDORS dmi_vendor = VENDOR_UNKNOWN; static const char *dmi_product = NULL; /* * Remember the system vendor for later use. We only actually store the * value if we know how to decode at least one specific entry type for * that vendor. */ void dmi_set_vendor(const char *v, const char *p) { const struct { const char *str; enum DMI_VENDORS id; } vendor[] = { { "Acer", VENDOR_ACER }, { "Dell Computer Corporation", VENDOR_DELL }, { "Dell Inc.", VENDOR_DELL }, { "HP", VENDOR_HP }, { "Hewlett-Packard", VENDOR_HP }, { "HPE", VENDOR_HPE }, { "Hewlett Packard Enterprise", VENDOR_HPE }, { "IBM", VENDOR_IBM }, { "LENOVO", VENDOR_LENOVO }, }; unsigned int i; size_t len; /* * Often DMI strings have trailing spaces. Ignore these * when checking for known vendor names. */ len = v ? strlen(v) : 0; while (len && v[len - 1] == ' ') len--; for (i = 0; i < ARRAY_SIZE(vendor); i++) { if (strlen(vendor[i].str) == len && strncmp(v, vendor[i].str, len) == 0) { dmi_vendor = vendor[i].id; break; } } dmi_product = p; } /* * Acer-specific data structures are decoded here. */ static int dmi_decode_acer(const struct dmi_header *h) { u8 *data = h->data; u16 cap; switch (h->type) { case 170: /* * Vendor Specific: Acer Hotkey Function * * Source: acer-wmi kernel driver * * Probably applies to some laptop models of other * brands, including Fujitsu-Siemens, Medion, Lenovo, * and eMachines. */ pr_handle_name("Acer Hotkey Function"); if (h->length < 0x0F) break; cap = WORD(data + 0x04); pr_attr("Function bitmap for Communication Button", "0x%04hx", cap); pr_subattr("WiFi", "%s", cap & 0x0001 ? "Yes" : "No"); pr_subattr("3G", "%s", cap & 0x0040 ? "Yes" : "No"); pr_subattr("WiMAX", "%s", cap & 0x0080 ? "Yes" : "No"); pr_subattr("Bluetooth", "%s", cap & 0x0800 ? "Yes" : "No"); pr_attr("Function bitmap for Application Button", "0x%04hx", WORD(data + 0x06)); pr_attr("Function bitmap for Media Button", "0x%04hx", WORD(data + 0x08)); pr_attr("Function bitmap for Display Button", "0x%04hx", WORD(data + 0x0A)); pr_attr("Function bitmap for Others Button", "0x%04hx", WORD(data + 0x0C)); pr_attr("Communication Function Key Number", "%d", data[0x0E]); break; default: return 0; } return 1; } /* * Dell-specific data structures are decoded here. */ static void dmi_dell_bios_flags(u64 flags) { /* * TODO: The meaning of the other bits is unknown. */ pr_attr("ACPI WMI Supported", "%s", (flags & (1ULL << 1)) ? "Yes" : "No"); } static void dmi_dell_hotkeys(const struct dmi_header *h) { int count = (h->length - 0x04) / 0x04; u8 *hotkey = h->data + 0x04; int i; if (!count) return; pr_list_start("Hotkey Mappings", NULL); for (i = 0; i < count; i++) { pr_list_item("Scancode 0x%04hx -> Keycode 0x%04hx", WORD(hotkey + 0x00), WORD(hotkey + 0x02)); hotkey += 0x04; } pr_list_end(); } static void dmi_dell_indexed_io_access(const struct dmi_header *h) { static const char *checksum_types[] = { "Word Checksum", "Byte Checksum", "CRC Checksum", "Negative Word Checksum", /* 0x03 */ }; int tokens = (h->length - 0x0C) / 0x05; const char *str = out_of_spec; u8 *data = h->data; u8 *token; u8 type; int i; pr_attr("Index Port", "0x%04hx", WORD(data + 0x04)); pr_attr("Data Port", "0x%04hx", WORD(data + 0x06)); type = data[0x08]; if (type < ARRAY_SIZE(checksum_types)) str = checksum_types[type]; pr_attr("Type", "%s", str); pr_attr("Checked Range Start Index", "0x%02hhx", data[0x09]); pr_attr("Checked Range End Index", "0x%02hhx", data[0x0a]); pr_attr("Check Value Index", "0x%02hhx", data[0x0b]); /* * Final token seems to be a terminator, so we ignore it. */ if (tokens <= 1) return; pr_list_start("Tokens", NULL); for (i = 0; i < tokens - 1; i++) { token = data + 0x0C + 0x05 * i; pr_list_item("0x%04hx (location 0x%02hhx, AND mask 0x%02hhx, OR mask 0x%02hhx)", WORD(token + 0x00), token[0x02], token[0x03], token[0x04]); } pr_list_end(); } static void dmi_dell_token_interface(const struct dmi_header *h) { int tokens = (h->length - 0x0B) / 0x06; u8 *data = h->data; u8 *token; int i; pr_attr("Command I/O Address", "0x%04x", WORD(data + 0x04)); pr_attr("Command I/O Code", "0x%02x", data[0x06]); pr_attr("Supported Command Classes Bitmap", "0x%08x", DWORD(data + 0x07)); /* * Final token is a terminator, so we ignore it. */ if (tokens <= 1) return; pr_list_start("Tokens", NULL); for (i = 0; i < tokens - 1; i++) { token = data + 0x0B + 0x06 * i; pr_list_item("0x%04hx (location 0x%04hx, value 0x%04hx)", WORD(token + 0x00), WORD(token + 0x02), WORD(token + 0x04)); } pr_list_end(); } static int dmi_decode_dell(const struct dmi_header *h) { u8 *data = h->data; switch (h->type) { case 177: pr_handle_name("Dell BIOS Flags"); if (h->length < 0x0C) break; dmi_dell_bios_flags(QWORD(data + 0x04)); break; case 178: pr_handle_name("Dell Hotkeys"); dmi_dell_hotkeys(h); break; case 212: pr_handle_name("Dell Indexed I/O Access"); if (h->length < 0x0C) break; dmi_dell_indexed_io_access(h); break; case 218: pr_handle_name("Dell Token Interface"); if (h->length < 0x0B) break; dmi_dell_token_interface(h); break; default: return 0; } return 1; } /* * HPE-specific data structures are decoded here. * * Code contributed by John Cagle and Tyler Bell. */ static void dmi_print_hp_net_iface_rec(u8 id, u8 bus, u8 dev, const u8 *mac) { /* Some systems do not provide an id. nic_ctr provides an artificial * id, and assumes the records will be provided "in order". Also, * using 0xFF marker is not future proof. 256 NICs is a lot, but * 640K ought to be enough for anybody(said no one, ever). * */ static u8 nic_ctr; char attr[8]; if (id == 0xFF) id = ++nic_ctr; sprintf(attr, "NIC %hhu", id); if (dev == 0x00 && bus == 0x00) pr_attr(attr, "Disabled"); else if (dev == 0xFF && bus == 0xFF) pr_attr(attr, "Not Installed"); else { pr_attr(attr, "PCI device %02x:%02x.%x, " "MAC address %02X:%02X:%02X:%02X:%02X:%02X", bus, dev >> 3, dev & 7, mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]); } } typedef enum { G6 = 6, G7, G8, G9, G10, G10P, G11, G12 } dmi_hpegen_t; static int dmi_hpegen(const char *s) { struct { const char *name; dmi_hpegen_t gen; } table[] = { { "Gen12", G12 }, { "Gen11", G11 }, { "Gen10 Plus", G10P }, { "Gen10", G10 }, { "Gen9", G9 }, { "Gen8", G8 }, { "G7", G7 }, { "G6", G6 }, }; unsigned int i; if (!strstr(s, "ProLiant") && !strstr(s, "Apollo") && !strstr(s, "Synergy") && !strstr(s, "Edgeline")) return -1; for (i = 0; i < ARRAY_SIZE(table); i++) { if (strstr(s, table[i].name)) return(table[i].gen); } return (dmi_vendor == VENDOR_HPE) ? G10P : G6; } static void dmi_hp_197_qdf(const u8 *qdf) { char str[7]; int i, j, len = 6; if (!is_printable(qdf, len)) return; for (i = 0, j = 0; i < len; i++) { if (qdf[i] != ' ') str[j++] = qdf[i]; } str[j] = '\0'; pr_attr("QDF/S-SPEC", "%s", str); } static void dmi_hp_203_assoc_hndl(const char *fname, u16 num) { if (opt.flags & FLAG_QUIET) return; if (num == 0xFFFE) pr_attr(fname, "N/A"); else pr_attr(fname, "0x%04X", num); } static void dmi_hp_203_bayenc(const char *fname, u8 num) { switch (num) { case 0x00: pr_attr(fname, "Unknown"); break; case 0xff: pr_attr(fname, "Do Not Display"); break; default: pr_attr(fname, "%d", num); } } static void dmi_hp_203_devtyp(const char *fname, unsigned int code) { const char *str = "Reserved"; static const char *type[] = { "Unknown", /* 0x00 */ "Reserved", "Reserved", "Flexible LOM", "Embedded LOM", "NIC in a Slot", "Storage Controller", "Smart Array Storage Controller", "USB Hard Disk", "Other PCI Device", "RAM Disk", "Firmware Volume", "UEFI Shell", "Generic UEFI USB Boot Entry", "Dynamic Smart Array Controller", "File", "NVME Hard Drive", "NVDIMM", /* 0x11 */ "Embedded GPU" }; if (code < ARRAY_SIZE(type)) str = type[code]; pr_attr(fname, "%s", str); } static void dmi_hp_203_devloc(const char *fname, unsigned int code) { const char *str = "Reserved"; static const char *location[] = { "Unknown", /* 0x00 */ "Embedded", "iLO Virtual Media", "Front USB Port", "Rear USB Port", "Internal USB", "Internal SD Card", "Internal Virtual USB (Embedded NAND)", "Embedded SATA Port", "Embedded Smart Array", "PCI Slot", "RAM Memory", "USB", "Dynamic Smart Array Controller", "URL", "NVMe Drive Bay", /* 0x0F */ "NVDIMM Processor", "NVDIMM Board", "NVMe Riser", "NVDIMM Name Space", "VROC SATA", "VROC NVMe", /* 0x15 */ }; if (code < ARRAY_SIZE(location)) str = location[code]; pr_attr(fname, "%s", str); } static void dmi_hp_216_fw_type(u16 code) { const char *str = "Reserved"; static const char * const type[] = { "Reserved", /* 0x00 */ "System ROM", "Redundant System ROM", "System ROM Bootblock", "Power Management Controller Firmware", "Power Management Controller Firmware Bootloader", "SL Chassis Firmware", "SL Chassis Firmware Bootloader", "Hardware PAL/CPLD", "SPS Firmware (ME Firmware)", "SL Chassis PAL/CPLD", "Compatibility Support Module (CSM)", "APML", "Smart Storage Battery (Megacell) Firmware", "Trusted Module (TPM or TCM) Firmware Version", "NVMe Backplane Firmware", "Intelligent Provisioning", "SPI Descriptor Version", "Innovation Engine Firmware (IE Firmware)", "UMB Backplane Firmware", "Embedded Diagnostics", "Reserved", /* 0x15 */ "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", /* 0x1F */ "EL Chassis Abstraction Revision", "EL Chassis Firmware Revision", "EL Chassis PAL/CPLD", "EL Cartride Abstraction Revision", "Reserved", /* 0x24 */ "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", "Reserved", /* 0x2F */ "Embedded Video Controller", "PCIe Riser Programmable Logic Device", "PCIe cards that contain a CPLD", "Intel NVMe VROC", "Intel SATA VROC", "Intel SPS Firmware", "Secondary System Programmable Logic Device", "CPU Mezzanine Board CPLD", /* 0x37 */ "Intel Artic Sound -M Accelerator Models Firmware", "Ampere System Control Processor (SCP - PMPro+SMPro)", "Intel CFR information", /* 0x3A */ "OCP cards", "DC-SCM CPLD", "Power Distribution Board CPLD", "PCIe Switch Board CPLD", "Sideband Board CPLD", "PCIe Riser MCU Firmware", /* 0x40 */ "PCIe Switch Board Firmware", "Power Supply Firmware", "BMC Firmware", }; if (code < ARRAY_SIZE(type)) str = type[code]; pr_attr("Firmware Type", "%s", str); } static void dmi_hp_216_version(u8 format, u8 *data) { const char * const name = "Version Data"; const char * const reserved = "Reserved"; int gen; gen = dmi_hpegen(dmi_product); switch (format) { case 0: pr_attr(name, "No Version Data"); break; case 1: if (data[0] >> 7) pr_attr(name, "0x%02X B.0x%02X", data[1] & 0x7F, data[0] & 0x7F); else pr_attr(name, "0x%02X", data[1] & 0x7F); break; case 2: pr_attr(name, "%d.%d", data[0] >> 4, data[0] & 0x0f); break; case 4: pr_attr(name, "%d.%d.%d", data[0] >> 4, data[0] & 0x0f, data[1] & 0x7f); break; case 5: if (gen == G9) { pr_attr(name, "%d.%d.%d", data[0] >> 4, data[0] & 0x0f, data[1] & 0x7f); } else if (gen == G10 || gen == G10P) { pr_attr(name, "%d.%d.%d.%d", data[1] & 0x0f, data[3] & 0x0f, data[5] & 0x0f, data[6] & 0x0f); } else { pr_attr(name, "%s", reserved); } break; case 6: pr_attr(name, "%d.%d", data[1], data[0]); break; case 7: pr_attr(name, "v%d.%.2d (%.2d/%.2d/%d)", data[0], data[1], data[2], data[3], WORD(data + 4)); break; case 8: pr_attr(name, "%d.%d", WORD(data + 4), WORD(data)); break; case 9: pr_attr(name, "%d.%d.%d", data[0], data[1], WORD(data + 2)); break; case 10: pr_attr(name, "%d.%d.%d Build %d", data[0], data[1], data[2], data[3]); break; case 11: pr_attr(name, "%d.%d %d", WORD(data + 2), WORD(data), DWORD(data + 4)); break; case 12: pr_attr(name, "%d.%d.%d.%d", WORD(data), WORD(data + 2), WORD(data + 4), WORD(data + 6)); break; case 13: pr_attr(name, "%d", data[0]); break; case 14: pr_attr(name, "%d.%d.%d.%d", data[0], data[1], data[2], WORD(data+3)); break; case 15: pr_attr(name, "%d.%d.%d.%d (%.2d/%.2d/%d)", WORD(data), WORD(data + 2), WORD(data + 4), WORD(data + 6), data[8], data[9], WORD(data + 10)); break; case 16: pr_attr(name, "%c%c%c%c.%d%d", data[0], data[1], data[2], data[3], data[4], data[5]); break; case 17: pr_attr(name, "%08X", DWORD(data)); break; case 18: pr_attr(name, "%d.%02d", data[0], data[1]); break; case 19: pr_attr(name, "0x%02x.0x%02x.0x%02x", data[0], data[1], data[2]); break; case 20: pr_attr(name, "%d.%d.%d.%d", data[0], data[1], data[2], data[3]); break; case 3: /* fall through */ default: pr_attr(name, "%s", reserved); } } static int dmi_hp_224_status(u8 code) { static const char * const present[] = { "Not Present", /* 0x00 */ "Present/Enabled", "Present/Disabled", "Reserved" /* 0x03 */ }; pr_attr("Status", "%s", present[code & 0x03]); if ((code & 0x03) == 0x00) return 0; pr_attr("Option ROM Measuring", "%s", (code & (1 << 2)) ? "Yes" : "No"); pr_attr("Hidden", "%s", (code & (1 << 3)) ? "Yes" : "No"); return 1; } static void dmi_hp_224_ex_status(u8 status, u8 code) { const char *str = "Reserved"; static const char * const disable_reason[] = { "Not Specified", /* 0x00 */ "User Disabled", "Error Condition", "Reserved" /* 0x03 */ }; static const char * const error_condition[] = { "Not Specified", /* 0x00 */ "Self-Test", /* 0x01 */ }; if ((status & 0x03) == 0x02) pr_attr("Disable Reason", "%s", disable_reason[code & 0x03]); if ((code & 0x03) == 0x02) { u8 error = (code >> 2) & 0x0f; if (error < ARRAY_SIZE(error_condition)) str = error_condition[error]; pr_attr("Error Condition", "%s", str); } } static void dmi_hp_224_module_type(u8 code) { const char *str = "Reserved"; static const char * const type[] = { "Not Specified", /* 0x00 */ "TPM 1.2", "TPM 2.0", "Intel PTT fTPM" /* 0x03 */ }; if ((code & 0x0f) < ARRAY_SIZE(type)) str = type[code & 0x0f]; pr_attr("Type", "%s", str); pr_attr("Standard Algorithm Supported", "%s", (code & (1 << 4)) ? "Yes" : "No"); pr_attr("Chinese Algorithm Supported", "%s", (code & (1 << 5)) ? "Yes" : "No"); } static void dmi_hp_224_module_attr(u8 code) { static const char * const phys_attr[] = { "Not Specified", /* 0x00 */ "Pluggable and Optional", "Pluggable but Standard", "Soldered Down on System Board" /* 0x03 */ }; static const char * const fips_attr[] = { "Not Specified", /* 0x00 */ "Not FIPS Certified", "FIPS Certified", "Reserved" /* 0x03 */ }; pr_attr("Trusted Module Attributes", "%s", phys_attr[code & 0x3]); pr_attr("FIPS Certification", "%s", fips_attr[((code >> 2) & 0x03)]); } static void dmi_hp_224_chipid(u16 code) { const char *str = "Reserved"; static const char * const chipid[] = { "None", /* 0x00 */ "STMicroGen10 TPM", "Intel firmware TPM (PTT)", "Nationz TPM", "STMicroGen10 Plus TPM", "STMicroGen11 TPM", /* 0x05 */ "STMicroGen12 TPM", }; if ((code & 0xff) < ARRAY_SIZE(chipid)) str = chipid[code & 0xff]; pr_attr("Chip Identifier", "%s", str); } static void dmi_hp_230_method_bus_seg_addr(u8 code, u8 bus_seg, u8 addr) { const char *str = "Reserved"; static const char * const method[] = { "Not Available", /* 0x00 */ "IPMI I2C", "iLO", "Chassis Manager", /* 0x03 */ }; if (code < ARRAY_SIZE(method)) str = method[code]; pr_attr("Access Method", "%s", str); if (code == 0 || code >= ARRAY_SIZE(method)) return; if (bus_seg != 0xFF) { if (code == 2) pr_attr("I2C Segment Number", "%d", bus_seg); else pr_attr("I2C Bus Number", "%d", bus_seg); } if (addr != 0xFF) pr_attr("I2C Address", "0x%02x", addr >> 1); } static void dmi_hp_232_encrypt(u8 code) { const char *str = "Reserved"; static const char * const status[] = { "Not Encrypted", "Encrypted", "Unknown", "Not Supported", }; if (code < ARRAY_SIZE(status)) str = status[code]; pr_attr("Encryption Status", "%s", str); } static void dmi_hp_238_loc(const char *fname, unsigned int code) { const char *str = "Reserved"; static const char *location[] = { "Internal", /* 0x00 */ "Front of Server", "Rear of Server", "Embedded internal SD Card", "iLO USB", "USB Hub for NAND Controller", "Reserved", "Debug Port", /* 0x07 */ "Reserved", "OCP USB", /* 0x09 */ }; if (code < ARRAY_SIZE(location)) str = location[code]; pr_attr(fname, "%s", str); } static void dmi_hp_238_flags(const char *fname, unsigned int code) { const char *str = "Reserved"; static const char *flags[] = { "Not Shared", /* 0x00 */ "Shared with physical switch", "Shared with automatic control", /* 0x02 */ }; if (code < ARRAY_SIZE(flags)) str = flags[code]; pr_attr(fname, "%s", str); } static void dmi_hp_238_speed(const char *fname, unsigned int code) { const char *str = "Reserved"; static const char *speed[] = { "Reserved", /* 0x00 */ "USB 1.1 Full Speed", "USB 2.0 High Speed", "USB 3.0 Super Speed" /* 0x03 */ }; if (code < ARRAY_SIZE(speed)) str = speed[code]; pr_attr(fname, "%s", str); } static void dmi_hp_239_usb_device(u8 class, u8 subclass, u8 protocol) { /* https://www.usb.org/defined-class-codes */ /* https://www.usb.org/sites/default/files/Mass_Storage_Specification_Overview_v1.4_2-19-2010.pdf */ const char *str = "Reserved"; if (class == 0x08) { static const char * const sub_class_name[] = { "SCSI command set not reported", /* 0x00 */ "RBC", "ATAPI", "Obsolete", "UFI", "Obsolete", "SCSI", "LSD FS", "IEEE 1667" /* 0x08 */ }; pr_attr("USB Class", "%s", "Mass Storage"); if (subclass == 0xFF) { str = "Vendor Specific"; } else if (subclass < ARRAY_SIZE(sub_class_name)) { str = sub_class_name[subclass]; } pr_attr("USB SubClass", "%s", str); switch (protocol) { case 0x00: str = "CBI w/ completion interrupt"; break; case 0x01: str = "CBI w/o completion interrupt"; break; case 0x02: str = "Obsolete"; break; case 0x50: str = "Bulk-Only"; break; case 0x62: str = "UAS"; break; case 0xFF: str = "Vendor Specific"; break; default: str = "Reserved"; } pr_attr("USB Protocol", "%s", str); } else if (class == 0x09 && subclass == 0) { pr_attr("USB Class", "%s", "HUB"); switch (protocol) { case 0: str = "Full Speed"; break; case 1: str = "Hi-Speed w/ single TT"; break; case 2: str = "Hi-Speed w/ multiple TT"; break; default: str = "Reserved"; } pr_attr("USB Protocol", str); } else { pr_attr("USB Class", "0x%02x", class); pr_attr("USB SubClass", "0x%02x", subclass); pr_attr("USB Protocol", "0x%02x", protocol); } } static void dmi_hp_240_attr(u64 defined, u64 set) { static const char *attributes[] = { "Updatable", "Reset Required", "Authentication Required", "In Use", "UEFI Image", }; unsigned int i; pr_list_start("Attributes Defined/Set", NULL); for (i = 0; i < ARRAY_SIZE(attributes); i++) { if (!(defined & (1ULL << i))) continue; pr_list_item("%s: %s", attributes[i], set & (1ULL << i) ? "Yes" : "No"); } pr_list_end(); } static void dmi_hp_242_hdd_type(u8 code) { const char *str = "Reserved"; static const char * const type[] = { "Undetermined", /* 0x00 */ "NVMe SSD", "SATA", "SAS", "SATA SSD", "NVMe Manged by VROC/VMD", /* 0x05 */ }; if (code < ARRAY_SIZE(type)) str = type[code]; pr_attr("Hard Drive Type", "%s", str); } static void dmi_hp_242_form_factor(u8 code) { const char *str = "Reserved"; static const char * const form[] = { "Reserved", /* 0x00 */ "Reserved", "3.5\" form factor", "2.5\" form factor", "1.8\" form factor", "Less than 1.8\" form factor", "mSATA", "M.2", "MicroSSD", "CFast", /* 0x09 */ }; static const char * const form2[] = { "EDSFF Unknown", /* 0x20 */ "EDSFF 1U Short", "EDSFF 1U Long", "EDSFF E3 Short", "EDSFF E3 Long", /* 0x24 */ }; if (code < ARRAY_SIZE(form)) str = form[code]; else if (code >= 0x20 && code < 0x20 + ARRAY_SIZE(form2)) str = form2[code - 0x20]; pr_attr("Form Factor", "%s", str); } static void dmi_hp_242_speed(const char *attr, u16 speed) { if (speed) pr_attr(attr, "%hu Gbit/s", speed); else pr_attr(attr, "%s", "Unknown"); } static void dmi_hp_244_health(u8 code) { const char *str = "Reserved"; static const char * const health[] = { "Healthy", /* 0x00 */ "DIMM Missing", "Config Inactive", "SPA Missing", "New Goal", "Locked", /* 0x05 */ }; if (code < ARRAY_SIZE(health)) str = health[code]; pr_attr("Interleave Set Health", "%s", str); } static void dmi_hp_245_pcie_riser(const struct dmi_header *h) { const char *str = "Reserved"; u8 *data = h->data; pr_attr("Board Type", "PCIe Riser"); if (h->length < 0x09) return; switch (data[0x05]) { case 1: str = "Primary"; break; case 2: str = "Secondary"; break; case 3: str = "Tertiary"; break; case 4: str = "Quaternary"; break; case 10: str = "Front"; break; } pr_attr("Riser Position", "%s", str); pr_attr("Riser ID", "%d", data[0x06]); if (data[0x07]) { str = (data[0x07] >> 7) ? "B." : ""; pr_attr("CPLD Version", "%s0x%02X", str, (data[0x07] & 0x7F)); } pr_attr("Riser Name", dmi_string(h, data[0x08])); } static void dmi_hp_245_pcie_mhs_riser(const struct dmi_header *h) { u8 *data = h->data; u8 i, count; int len = h->length; pr_attr("Board Type", "PCIe Riser (MHS Platform)"); if (h->length < 0x0B) return; pr_attr("Riser ID", "%d", data[0x05]); if (data[0x06]) pr_attr("Firmware Version", "%x.%x", data[0x06], data[0x07]); pr_attr("Downgradable", "%s", data[0x08] & 0x01 ? "Yes" : "No"); pr_attr("Riser Name", dmi_string(h, data[0x09])); count = data[0x0A]; pr_attr("Slot Count", "%d", count); pr_list_start("Slot IDs", NULL); for (i = 0; (i < count) && ((0x0B + i) < len); i++) pr_list_item("0x%x", data[0x0B + i]); pr_list_end(); } static int dmi_decode_hp(const struct dmi_header *h, u16 ver) { u8 *data = h->data; int nic, ptr, i; u32 feat; const char *company = (dmi_vendor == VENDOR_HP) ? "HP" : "HPE"; int gen; gen = dmi_hpegen(dmi_product); if (gen < 0) return 0; switch (h->type) { case 193: /* * Vendor Specific: Other ROM Info * * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xC1, ROM Structure Indicator * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | ROM | BYTE | 01: Redundant ROM installed * 0x05 | ROM vers | STRING| Version of the Redundant ROM * 0x06 | Reserved | BYTE | Reserved in Gen9 forward * 0x07 | OEM ROM | STRING| If not blank, OEM ROM binary file name * 0x08 | OEM Date | STRING| If not blank, OEM ROM binary build date */ if (gen < G9) return 0; pr_handle_name("%s ProLiant Other ROM Info", company); if (h->length < 0x09) break; if ((gen < G12) && (data[0x04] & 0x01)) pr_attr("Redundant ROM Version", "%s", dmi_string(h, data[0x05])); if (data[0x07]) { const char *str = dmi_string(h, data[0x07]); if (strncmp(str, " ", 2)) { pr_attr("OEM ROM Binary Filename", "%s", str); pr_attr("OEM ROM Binary Build Date", "%s", dmi_string(h, data[0x08])); } } break; case 194: /* * Vendor Specific: Super IO Enable/Disable Features * * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xC2, Super IO Enable/Disable Indicator * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Dev Status | BYTE | Device Status */ pr_handle_name("%s ProLiant Super IO Enable/Disable Indicator", company); if (h->length < 0x05) break; feat = data[0x04]; pr_attr("Serial Port A", "%s", feat & (1 << 0) ? "Enabled" : "Disabled"); pr_attr("Serial Port B", "%s", feat & (1 << 1) ? "Enabled" : "Disabled"); pr_attr("Parallel Port", "%s", feat & (1 << 2) ? "Enabled" : "Disabled"); pr_attr("Floppy Disk Port", "%s", feat & (1 << 3) ? "Enabled" : "Disabled"); pr_attr("Virtual Serial Port", "%s", feat & (1 << 4) ? "Enabled" : "Disabled"); break; case 195: /* * Vendor Specific: Server System ID * * Offset | Name | Width | Description * ---------------------------------------------- * 0x00 | Type | BYTE | 0xC3, Server System ID * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | System ID | STRING| Server System ID * 0x05 | Platform ID| BYTE | Low byte of Platform ID from XREG in CPLD * 0x06 | Platform ID| BYTE | High byte of Platform ID from XREG in CPLD * 0x07 | GUID |16 BYTE| RESERVED: Deprecated Gen 11 and later. * * This structure exists to define a unique system ID that replaces the * old system EISA ID. It is to be used in systems where the system * EISA ID port is not present. * * It also exposes the Platform ID from the CPLD Xregister. This value is * used by iLO to identify the platform and will be used for identification * and matching of certain flash deliverables. */ pr_handle_name("%s ProLiant Server System ID", company); if (h->length < 0x05) break; pr_attr("Server System ID", "%s", dmi_string(h, data[0x04])); if (h->length < 0x07) break; /* Display byte order is uncertain, to be confirmed */ pr_attr("Platform ID", "%d:%d", data[0x05], data[0x06]); break; case 197: /* * Vendor Specific: HPE Processor Specific Information * * Processor Information structure (Type 197) for each possibly installed * physical processor to go along with each standard Processor Info * Record (Type 4). The Type 197 record will be ignored for Processor * slots that are empty (specified in the Type 4 records). * * Processor Wattage value will be filled in with information gotten from * the CPUID instruction or possibly estimated based on CPU Family/Type. * * Designator bytes will be 0FFh if the location of the processor does not * use it. If a system has processor slots, but no sockets, then the value * in the Socket Designator will be 0FFh. A system would have one or the * other, or both. * * Offset | Name | Width | Description * -------+------------+-------+------------- * 0x00 | Type | BYTE | 0xC5, Processor Information * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Assoc Dev | WORD | Handle of Associated Type 4 Record * 0x06 | APIC ID | BYTE | Processor local APIC ID * 0x07 | OEM Status | BYTE | Bits: 0: BSP, 1: x2APIC, 2: Therm Margining * 0x08 | Phys Slot | BYTE | Matches silk screen * 0x09 | Phys Socket| BYTE | Matches silk screen * 0x0A | Max Wattage| WORD | Rated max wattage of the processor * 0x0C | x2APIC ID | DWORD | Processor x2APIC (if OEM Status -> x2APIC) * 0x10 | Proc UUID | QWORD | Processor Unique Identifier * 0x18 | Conn Speed | WORD | Interconnect speed in MT/s * 0x1A | QDF/S-SPEC |6 BYTES| Processor QDF/S-SPEC Numbers (Intel only) * 0x20 | Reserved | DWORD | Gen11 Reserved */ pr_handle_name("%s Processor Specific Information", company); if (h->length < 0x0A) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x04)); pr_attr("APIC ID", "%u", data[0x06]); feat = data[0x07]; pr_attr("BSP", "%s", feat & 0x01 ? "Yes" : "No"); pr_attr("x2APIC", "%s", feat & 0x02 ? "Yes" : "No"); pr_attr("Advanced Thermal Margining", "%s", feat & 0x04 ? "Yes" : "No"); if (data[0x08] != 0xFF) pr_attr("Physical Slot", "%d", data[0x08]); if (data[0x09] != 0xFF) pr_attr("Physical Socket", "%d", data[0x09]); if (h->length < 0x0C) break; if (WORD(data + 0x0A)) pr_attr("Maximum Power", "%d W", WORD(data + 0x0A)); if (h->length < 0x10) break; if (feat & 0x02) pr_attr("x2APIC ID", "0x%08x", DWORD(data + 0x0C)); if (h->length < 0x18) break; if (DWORD(data + 0x10) || DWORD(data + 0x14)) pr_attr("UUID", "0x%08x%08x", DWORD(data + 0x14), DWORD(data + 0x10)); if (h->length < 0x1A) break; if (WORD(data + 0x18)) pr_attr("Interconnect Speed", "%d MT/s", WORD(data + 0x18)); if (h->length < 0x20) break; dmi_hp_197_qdf(data + 0x1A); break; case 199: /* * Vendor Specific: CPU Microcode Patch * * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xC7, CPU Microcode Patch * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Patch Info | Varies| { ...} */ if (gen < G9) return 0; pr_handle_name("%s ProLiant CPU Microcode Patch Support Info", company); for (ptr = 0x4; ptr + 12 <= h->length; ptr += 12) { u8 cpuid[4]; u32 date; memcpy(cpuid, data + ptr + 2 * 4, 4); /* AMD omits BaseFamily. Reconstruction valid on family >= 15. */ if (cpuid_type == cpuid_x86_amd) { cpuid[3] = cpuid[2] & 0x0f; cpuid[2] = cpuid[1]; cpuid[1] = 0x0f; } dmi_print_cpuid(pr_attr, "CPU ID", cpuid_type, cpuid); date = DWORD(data + ptr + 4); pr_subattr("Date", "%04x-%02x-%02x", date & 0xffff, (date >> 24) & 0xff, (date >> 16) & 0xff); pr_subattr("Patch", "0x%X", DWORD(data + ptr)); } break; case 202: /* * Vendor Specific: HPE DIMM Location Record * * This record allows software to correlate a Type 17 Memory Device Record * with a specific DIMM (DIMM, Board, and/or Processor number if appropriate). * * There will be one Record Type 202 for each DIMM socket possible in the system. * A system will include a record for each DIMM socket even if that DIMM socket * is on a memory board which is not currently installed. * * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xCA, DIMM Location Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Assoc Record | WORD | Handle of Associated Type 17 Memory Record * 0x06 | Board Number | BYTE | 1-based Memory Board number. 0FFh: DIMM on system board * 0x07 | DIMM Number | BYTE | 1-based DIMM number * 0x08 | Proc Number | BYTE | 1-based procssor number. 0FFh don't display * 0x09 | Log DIMM Num | BYTE | 1-based Logical DIMM number mapping to ACPI numbering * 0x0A | UEFI Dev Path| STRING| String number for UEFI Device Path * 0x0B | UEFI Dev Name| STRING| String number for UEFI Device Structured Name * 0x0C | Device Name | STRING| String number for Device Name * 0x0D | Mem Cntrl Num| BYTE | 1-based Memory controller number * 0x0E | Mem Chan Num | BYTE | 1-based memory channel number (matches silk screen) * 0x0F | IE DIMM Num | BYTE | 0-based DIMM number repored by IE. FF -> not supported * | Reserved G12 or later * 0x10 | IE PLDM ID | BYTE | IE PLDM Sensor ID. FF -> not supported * | Reserved G12 or later * 0x11 | Vendor ID | WORD | Module manufacturers ID code as read by SPD * 0x13 | Device ID | WORD | (NVDIMM only) Module product ID code from SPD * 0x15 | Sub Cntrl Ven| WORD | (NVDIMM only) Controller manufacturer ID from SPD * 0x17 | Sub Cntrl Dev| WORD | (NVDIMM only) Controller product ID from SPD * 0x19 | Interleave | BYTE | 1-based unique interleave set within Procssor Number * 0x1A | Part Number | STRING| String number for HPE part number from OEM SPD * 0x1B | DIMM Index | BYTE | 0-based DIMM Index Per Channel */ if (gen < G9) return 0; pr_handle_name("%s DIMM Location Record", company); if (h->length < 0x09) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Memory Record", "0x%04X", WORD(data + 0x04)); if (data[0x06] == 0xFF) pr_attr("Board Number", "%s", "System Board"); else pr_attr("Board Number", "%d", data[0x06]); pr_attr("DIMM Number", "%d", data[0x07]); if (data[0x08] != 0xFF) pr_attr("Processor Number", "%d", data[0x08]); if (h->length < 0x0A) break; pr_attr("Logical DIMM Number", "%d", data[0x09]); if (h->length < 0x0D) break; if (data[0x0A]) pr_attr("UEFI Device Path", "%s", dmi_string(h, data[0x0A])); if (data[0x0B]) pr_attr("UEFI Device Name", "%s", dmi_string(h, data[0x0B])); if (data[0x0C]) pr_attr("Device Name", "%s", dmi_string(h, data[0x0C])); if (h->length < 0x19) break; if (data[0x0D]) pr_attr("Memory Controller Number", "%d", data[0x0D]); if (data[0x0E]) pr_attr("Memory Channel Number", "%d", data[0x0E]); if (gen < G12 && data[0x0F] != 0xFF) pr_attr("IE DIMM Number", "%d", data[0x0F]); if (gen < G12 && data[0x10] != 0xFF) pr_attr("IE PLDM ID", "%d", data[0x10]); if (data[0x11] || data[0x12]) pr_attr("Vendor ID", "0x%04X", WORD(data + 0x11)); if (data[0x13] || data[0x14]) pr_attr("Device ID", "0x%04X", WORD(data + 0x13)); if (data[0x15] || data[0x16]) dmi_memory_manufacturer_id("Controller Manufacturer ID", WORD(data + 0x15)); if (data[0x17] || data[0x18]) dmi_memory_product_id("Controller Product ID", WORD(data + 0x17)); if (h->length < 0x1A) break; if (data[0x19]) pr_attr("Best Interleave", "%d", data[0x19]); if (h->length < 0x1B) break; pr_attr("Part Number", "%s", dmi_string(h, data[0x1A])); if (h->length < 0x1C) break; pr_attr("DIMM Index", "%d", data[0x1B]); break; case 203: /* * Vendor Specific: HP Device Correlation Record * * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xCB, Correlation Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Assoc Device | WORD | Handle of Associated Type 9 or Type 41 Record * 0x06 | Assoc SMBus | WORD | Handle of Associated Type 228 SMBus Segment Record * 0x08 | PCI Vendor ID| WORD | PCI Vendor ID of device 0xFFFF -> not present * 0x0A | PCI Device ID| WORD | PCI Device ID of device 0xFFFF -> not present * 0x0C | PCI SubVendor| WORD | PCI Sub Vendor ID of device 0xFFFF -> not present * 0x0E | PCI SubDevice| WORD | PCI Sub Device ID of device 0xFFFF -> not present * 0x10 | Class Code | BYTE | PCI Class Code of Endpoint. 0xFF if device not present. * 0x11 | Class SubCode| BYTE | PCI Sub Class Code of Endpoint. 0xFF if device not present. * 0x12 | Parent Handle| WORD | * 0x14 | Flags | WORD | * 0x16 | Device Type | BYTE | UEFI only * 0x17 | Device Loc | BYTE | Device Location * 0x18 | Dev Instance | BYTE | Device Instance * 0x19 | Sub Instance | BYTE | NIC Port # or NVMe Drive Bay * 0x1A | Bay | BYTE | * 0x1B | Enclosure | BYTE | * 0x1C | UEFI Dev Path| STRING| String number for UEFI Device Path * 0x1D | Struct Name | STRING| String number for UEFI Device Structured Name * 0x1E | Device Name | STRING| String number for UEFI Device Name * 0x1F | UEFI Location| STRING| String number for UEFI Location * 0x20 | Assoc Handle | WORD | Type 9 Handle. Defined if Flags[0] == 1. * 0x22 | Part Number | STRING| PCI Device Part Number * 0x23 | Serial Number| STRING| PCI Device Serial Number * 0x24 | Seg Number | WORD | Segment Group number. 0 -> Single group topology * 0x26 | Bus Number | BYTE | PCI Device Bus Number * 0x27 | Func Number | BTYE | PCI Device and Function Number */ if (gen < G9) return 0; pr_handle_name("%s Device Correlation Record", company); if (h->length < 0x1F) break; dmi_hp_203_assoc_hndl("Associated Device Record", WORD(data + 0x04)); dmi_hp_203_assoc_hndl("Associated SMBus Record", WORD(data + 0x06)); if (WORD(data + 0x08) == 0xffff && WORD(data + 0x0A) == 0xffff && WORD(data + 0x0C) == 0xffff && WORD(data + 0x0E) == 0xffff && data[0x10] == 0xFF && data[0x11] == 0xFF) { pr_attr("PCI Device Info", "Device Not Present"); } else { pr_attr("PCI Vendor ID", "0x%04x", WORD(data + 0x08)); pr_attr("PCI Device ID", "0x%04x", WORD(data + 0x0A)); pr_attr("PCI Sub Vendor ID", "0x%04x", WORD(data + 0x0C)); pr_attr("PCI Sub Device ID", "0x%04x", WORD(data + 0x0E)); pr_attr("PCI Class Code", "0x%02x", data[0x10]); pr_attr("PCI Sub Class Code", "0x%02x", data[0x11]); } dmi_hp_203_assoc_hndl("Parent Handle", WORD(data + 0x12)); pr_attr("Flags", "0x%04X", WORD(data + 0x14)); if (WORD(data + 0x14) & 0x01) pr_subattr("Peer Bifurcated Device", "Yes"); if (WORD(data + 0x14) & 0x02) pr_subattr("Upstream Device", "Yes"); dmi_hp_203_devtyp("Device Type", data[0x16]); dmi_hp_203_devloc("Device Location", data[0x17]); pr_attr("Device Instance", "%d", data[0x18]); pr_attr("Device Sub-Instance", "%d", data[0x19]); dmi_hp_203_bayenc("Bay", data[0x1A]); dmi_hp_203_bayenc("Enclosure", data[0x1B]); pr_attr("Device Path", "%s", dmi_string(h, data[0x1C])); pr_attr("Structured Name", "%s", dmi_string(h, data[0x1D])); pr_attr("Device Name", "%s", dmi_string(h, data[0x1E])); if (h->length < 0x22) break; pr_attr("UEFI Location", "%s", dmi_string(h, data[0x1F])); if (!(opt.flags & FLAG_QUIET)) { if (WORD(data + 0x14) & 1) pr_attr("Associated Real/Phys Handle", "0x%04X", WORD(data + 0x20)); else pr_attr("Associated Real/Phys Handle", "N/A"); } if (h->length < 0x24) break; pr_attr("PCI Part Number", "%s", dmi_string(h, data[0x22])); pr_attr("Serial Number", "%s", dmi_string(h, data[0x23])); if (h->length < 0x28) break; pr_attr("Segment Group Number", "0x%04x", WORD(data + 0x24)); pr_attr("PCI Device", "%02x:%02x.%x", data[0x26], data[0x27] >> 3, data[0x27] & 7); break; case 204: /* * Vendor Specific: HPE ProLiant System/Rack Locator */ pr_handle_name("%s ProLiant System/Rack Locator", company); if (h->length < 0x0B) break; pr_attr("Rack Name", "%s", dmi_string(h, data[0x04])); pr_attr("Enclosure Name", "%s", dmi_string(h, data[0x05])); pr_attr("Enclosure Model", "%s", dmi_string(h, data[0x06])); pr_attr("Enclosure Serial", "%s", dmi_string(h, data[0x0A])); pr_attr("Enclosure Bays", "%d", data[0x08]); pr_attr("Server Bay", "%s", dmi_string(h, data[0x07])); pr_attr("Bays Filled", "%d", data[0x09]); break; case 209: case 221: /* * Vendor Specific: HPE ProLiant NIC MAC Information * * This prints the BIOS NIC number, * PCI bus/device/function, and MAC address * * Type 209: * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xD1, MAC Info * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Dev No | BYTE | PCI Device/Function No * 0x05 | Bus No | BYTE | PCI Bus * 0x06 | MAC | 6B | MAC addr * 0x0C | NIC #2 | 8B | Repeat 0x04-0x0B * * Type 221: is deprecated in the latest docs */ if (gen >= G8 && h->type == 221) return 0; pr_handle_name("%s %s", company, h->type == 221 ? "BIOS iSCSI NIC PCI and MAC Information" : "BIOS PXE NIC PCI and MAC Information"); nic = 1; ptr = 4; while (h->length >= ptr + 8) { dmi_print_hp_net_iface_rec(nic, data[ptr + 0x01], data[ptr], &data[ptr + 0x02]); nic++; ptr += 8; } break; case 211: /* * Vendor Specific: HPE ProLiant Processor TControl Information * * Provides information about the Tcontrol value for each installed * processor. This information is utilized to optimize the thermal fan * control systems on the system. For some systems, this can be handled * totally by the System ROM (systems with 7463 fan controllers). For * systems that utilize TAFI, the Health Driver handles fan control. * The Health Driver must know the value for Tcontrol for all processors * to be able to customize the fan control for the installed processors. * * Tcontrol is a value programmed into each processor by Intel that * indicates the processors thermal properties. The value is based on * how "leaky" the particular processor's transistors are. A more "leaky" * processor will get hotter for a given power input and thus will have a * higher Tcontrol value. Intel officially suggests keeping a processor * below the Tcontrol value for reliability reasons. HP is using Tcontrol * as the point at which we begin spinning up the fans. * * Software must check the corresponding Record Type 4 to determine if the * processor is installed. If the processor is not installed, the * corresponding Record Type 211 should not be utilized. Record Type 197 * must be used to correlate Type 211 Record to the processor's APIC ID. * This must be done to know which TAFI controller must be programmed with * a particular Tcontrol value. Type 197 Record has an identifier which * relates it to a Type 4 Record, so it is possible to correlate a * Type 211 Record with a Type 197 Record. * * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xD3, TControl Info * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Handle | WORD | Handle of Corresponding Type 4 Processor Record * 0x06 |Tcontrol| BYTE | Processor Tcontrol Value. 00 -> Value N/A. */ pr_handle_name("%s ProLiant TControl Information", company); if (h->length < 0x07) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Processor Handle", "0x%04X", WORD(data + 0x04)); if (data[0x06]) pr_attr("TControl Value", "%d", data[0x06]); else pr_attr("TControl Value", "%s", "N/A"); break; case 212: /* * Vendor Specific: HPE 64-bit CRU Information * * Source: hpwdt kernel driver */ if (gen >= G9) return 0; pr_handle_name("%s 64-bit CRU Information", company); if (h->length < 0x18) break; if (is_printable(data + 0x04, 4)) pr_attr("Signature", "0x%08x (%c%c%c%c)", DWORD(data + 0x04), data[0x04], data[0x05], data[0x06], data[0x07]); else pr_attr("Signature", "0x%08x", DWORD(data + 0x04)); if (DWORD(data + 0x04) == 0x55524324) { u64 paddr = QWORD(data + 0x08); paddr += DWORD(data + 0x14); pr_attr("Physical Address", "0x%016llx", paddr); pr_attr("Length", "0x%08x", DWORD(data + 0x10)); } break; case 216: /* * Vendor Specific: Version Indicator Record * * This record is used to allow determining Firmware and CPLD revisions for * components in the system. The goal of this record is to provide a * flexible method to communicate to software and firmware the revisions * of these components. This record replaces much of the functionality of * Record Type 193. OEM SMBIOS Record Type 193 was not scaling well with * the large number of potential CPLD devices, power management controllers, * etc. This record is flexible such that each instance of Type 216 * defines one firmware component. This record also includes the string * name for which software should refer to the component. The record * includes both data bytes to indicate the revision and a string value. A * firmware component can implement either or both. If both are supported, * it allows easy display of the revision, but prevents the need for * software/firmware to parse strings when doing comparisons on revisions. * As there is one Type 216 Record per firmware component, the Handle for * the Record can be used to tie firmware components with other OEM SMBIOS * Records in the future if needed (similar to how SMBIOS Type 17 is tied * to other Record Types related to DIMMs) * * Offset | Name | Width | Description * ------------------------------------------ * 0x00 | Type | BYTE | 0xD8, Version Indicator Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | FW Type | WORD | Type of Firmware * 0x06 | FW Name | STRING | Name of Firmware * 0x07 | FW Version | STRING | Firmware Version * 0x08 | Data Format| BYTE | Format of the Version Data * 0x09 |Version Data|12 BYTES| Version Data in Format from field 0x08 * 0x15 | Unique ID | WORD | Unique ID for Firmware flash */ if (gen < G8) return 0; pr_handle_name("%s Version Indicator", company); if (h->length < 23) break; dmi_hp_216_fw_type(WORD(data + 0x04)); pr_attr("Firmware Name String", "%s", dmi_string(h, data[0x06])); pr_attr("Firmware Version String", "%s", dmi_string(h, data[0x07])); dmi_hp_216_version(data[0x08], data + 0x09); if (WORD(data + 0x15)) pr_attr("Unique ID", "0x%04x", WORD(data + 0x15)); break; case 219: /* * Vendor Specific: HPE ProLiant Information * * Source: hpwdt kernel driver */ pr_handle_name("%s ProLiant Information", company); if (h->length < 0x08) break; pr_attr("Power Features", "0x%08x", DWORD(data + 0x04)); if (h->length < 0x0C) break; pr_attr("Omega Features", "0x%08x", DWORD(data + 0x08)); if (h->length < 0x14) break; feat = DWORD(data + 0x10); pr_attr("Misc. Features", "0x%08x", feat); pr_subattr("iCRU", "%s", feat & 0x0001 ? "Yes" : "No"); pr_subattr("UEFI", "%s", feat & 0x1400 ? "Yes" : "No"); break; case 224: /* * Vendor Specific: Trusted Module (TPM or TCM) Status * * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xE0, Trusted Module (TPM or TCM) Status * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Status | BYTE | Status Flag Byte * 0x05 | Ex Stat| BYTE | TPM Extended Status * 0x06 | Type | BYTE | Trusted Module Type * 0x07 | Attrib | BYTE | Trusted Module Attributes * 0x08 | Handle | WORD | Handle to map to Type 216 * 0x0A | Chip ID| WORD | Chip Identifier Values */ pr_handle_name("%s Trusted Module (TPM or TCM) Status", company); if (h->length < 0x05) break; if (!dmi_hp_224_status(data[0x04])) break; if (h->length < 0x0a) break; dmi_hp_224_ex_status(data[0x04], data[0x05]); dmi_hp_224_module_type(data[0x06]); dmi_hp_224_module_attr(data[0x07]); if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x8)); if (h->length < 0x0c) break; dmi_hp_224_chipid(WORD(data + 0x0a)); break; case 226: /* * Vendor Specific: Physical Attribute Information * * This structure exists to store physical attributes for which virtual * attributes have been stored in the industry standard SMBIOS fields * which would normally store these physical attributes. This OEM SMBIOS * Record was initially defined for the SYNERGY project where it was * required that a virtual serial number and UUID be applied to the * system. These virtual values must be stored in the standard SMBIOS * fields so that industry standard software would detect these virtual * values, allowing a workload to transition from one physical piece of * hardware to another. This Record was created because a place was needed * to store the physical attributes (serial number and UUID) for use in * asset tracking and warranty events. * * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xE2, Physical Attribute * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | UUID |16 BYTE| if !0 => Physical Universal Unique ID Number * 0x14 | SN | STRING| Physical Serial Number. Match Record Type 1 */ pr_handle_name("%s Physical Attribute Information", company); if (h->length < 0x15) break; if (QWORD(data + 0x0C) || QWORD(data + 0x04)) dmi_system_uuid(pr_attr, "UUID", data + 0x04, ver); pr_attr("Serial Number", "%s", dmi_string(h, data[0x14])); break; case 229: /* * Vendor Specific: Reserved Memory Location * * This OEM SMBIOS Record is used to communicate the physical address * location of memory regions reserved during POST by System Firmware. * These memory regions will be reserved for various purposes. It is * intended that this OEM SMBIOS Record be expandable to support any * future POST reserved memory requirements. The regions reserved by * POST will typically be reported by INT15h E820h as reserved memory. * This record was initially defined to communicate to iLO FW and Smart * Array Storage FW the location of a memory buffer reserved for passing * information between the Smart Array Controller and iLO FW for providing * hard drive temperatures to iLO FW fan control. * * Note: Multiple Type 229 Records may exist in the SMBIOS Table because * each SMBIOS Record has a maximum length of 256 bytes and it is possible * that there eventually would be enough reserved memory locations such * that a single record could exceed this limit (each reserved memory * location utilizes 16 bytes). Software utilizing the Type 229 Record * should be written to handle the possibility of multiple records. * * Offset| Name | Width | Description * ----------------------------------------- * 0x00 | Type | BYTE | 0xE5, Reserved Memory Location * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Signature | DWORD | Enumerated value that indicates the type * | of memory described by this Reserved * | Memory Location * 0x08 | Phys Addr | QWORD | 64-Bit physical memory address * 0x10 | Size of Loc | DWORD | Bit[30:0] - Size of the Memory Location * | Bit[31] - Indicates whether the size field in * | Bits[30:0] is in 1 byte or 1 Kbyte granularity * | 0 = Byte Granularity * | 1 = Kbyte Granularity * 0x14 | Mem Entries | 16 Bytes per Reserved Memory Entry */ pr_handle_name("%s Reserved Memory Location", company); for (ptr = 0x04, i = 1; ptr + 16 <= h->length; ptr += 16, i++) { pr_attr("Memory Location", "%d", i); pr_subattr("Signature", "%.4s", data + ptr); pr_subattr("Physical Address", "0x%016llX", QWORD(data + ptr + 0x04)); feat = DWORD(data + ptr + 0x0C); dmi_print_memory_size(pr_subattr, "Size", feat & 0x7fffffff, feat >> 31); } break; case 230: /* * Vendor Specific: Power Supply Information OEM SMBIOS Record * * This record is used to communicate additional Power Supply Information * beyond the Industry Standard System Power Supply (Type 39) Record. * * Offset| Name | Width | Description * ----------------------------------------- * 0x00 | Type | BYTE | 0xE6, Power Supply Information Indicator * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Assoc Handle| WORD | Associated Handle (Type 39) * 0x06 | Manufacturer| STRING| Actual third party manufacturer * 0x07 | Revision | STRING| Power Supply Revision Level * 0x08 | FRU Access | BYTE | Power Supply FRU Access Method * 0x09 | I2C Bus Num | BYTE | I2C Bus #. Value based upon context * 0x0A | I2C Address | BYTE | I2C Address */ pr_handle_name("%s Power Supply Information", company); if (h->length < 0x0B) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x4)); pr_attr("Manufacturer", "%s", dmi_string(h, data[0x06])); pr_attr("Revision", "%s", dmi_string(h, data[0x07])); dmi_hp_230_method_bus_seg_addr(data[0x08], data[0x09], data[0x0A]); break; case 232: /* * Vendor Specific: DIMM Attributes Record * * This record is used to communicate information about DIMMs that is not * available via Industry Standard SMBIOS Records. * * There will be one Record Type 232 for each DIMM socket possible in the * system (just like Type 17 Records). * * Offset| Name | Width | Description * ----------------------------------------- * 0x00 | Type | BYTE | 0xE8, DIMM Attributes Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Assoc Handle| WORD | Associated Handle (Type 17) * 0x06 | DIMM Attr | DWORD | Attributes Bitfield (Defined in code) * 0x0A | Min Voltage | WORD | Minimum operating voltage in millivolts * 0x0C | Cfg Voltage | WORD | Configured operating voltage in millivolts * 0x0E | RESERVED | * .... | RESERVED | * 0x21 | RESERVED | * 0x22 | Map-Out | BYTE | Bit Field reason for DIMM being mapped out * 0x23 | Encryption | BYTE | Encryption status */ if (gen < G9) return 0; pr_handle_name("%s DIMM Attributes Record", company); if (h->length < 0x0E) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x04)); feat = DWORD(data + 0x06); pr_attr("Attributes", "0x%08X", feat); /* Bit [1:0] HP SmartMemory */ pr_subattr("HPE Smart Memory", (feat & 0x03) == 0 ? "No" : (feat & 0x03) == 1 ? "Yes" : "Unknown"); /* Bit [3:2] Indicator if DIMM is Load Reduced (LR) */ /* Bit [2]: 1 = Field Supported */ if (feat & (1 << 2)) pr_subattr("Load Reduced DIMM installed", (feat & (1 << 3)) ? "Yes" : "No"); /* Bit [5:4] HP Standard DIMM Indicator */ /* Bit [4]: 1 = Field Supported */ if (feat & (1 << 4)) pr_subattr("HPE Standard Memory Installed", (feat & (1 << 5)) ? "Yes" : "No"); if (WORD(data + 0x0A)) pr_attr("Minimum Voltage", "%d mV", WORD(data + 0x0A)); else pr_attr("Minimum Voltage", "Unknown"); if (WORD(data + 0x0C)) pr_attr("Configured Voltage", "%d mV", WORD(data + 0x0C)); else pr_attr("Configured Voltage", "Unknown"); if (h->length < 0x23) break; feat = data[0x22]; if (feat) { pr_attr("Map-Out Reason", "0x%0X", feat); pr_subattr("Configuration Error", (feat & 0x01) ? "Yes" : "No"); pr_subattr("Training Error", (feat & 0x02) ? "Yes" : "No"); } if (h->length < 0x24) break; dmi_hp_232_encrypt(data[0x23]); break; case 233: /* * Vendor Specific: HPE ProLiant NIC MAC Information * * This prints the BIOS NIC number, * PCI bus/device/function, and MAC address * * Offset | Name | Width | Description * ------------------------------------- * 0x00 | Type | BYTE | 0xE9, NIC structure * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Grp No | WORD | 0 for single segment * 0x06 | Bus No | BYTE | PCI Bus * 0x07 | Dev No | BYTE | PCI Device/Function No * 0x08 | MAC | 32B | MAC addr padded w/ 0s * 0x28 | Port No| BYTE | Each NIC maps to a Port * 0x29 | DevPath| STRING| UEFI Device Path of network port */ pr_handle_name("%s BIOS PXE NIC PCI and MAC Information", company); if (h->length < 0x0E) break; /* If the record isn't long enough, we don't have an ID * use 0xFF to use the internal counter. * */ nic = h->length > 0x28 ? data[0x28] : 0xFF; dmi_print_hp_net_iface_rec(nic, data[0x06], data[0x07], &data[0x08]); if (h->length < 0x2A) break; pr_attr("UEFI Device Path", "%s", dmi_string(h, data[0x29])); break; case 236: /* * Vendor Specific: HPE ProLiant HDD Backplane * * Offset | Name | Width | Description * --------------------------------------- * 0x00 | Type | BYTE | 0xEC, HDD Backplane * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | I2C Address| BYTE | Backplane FRU I2C Address * 0x05 | Box Number | WORD | Backplane Box Number * 0x07 | NVRAM ID | WORD | Backplane NVRAM ID * 0x09 | WWID | QWORD | SAS Expander WWID * 0x11 | Total Bays | BYTE | Total SAS Bays * 0x12 | A0 Bays | BYTE | (deprecated) Number of SAS drive bays behind port 0xA0 * 0x13 | A2 Bays | BYTE | (deprecated) Number of SAS drive bays behind port 0xA2 * 0x14 | Name | STRING| (deprecated) Backplane Name */ if (gen >= G11) return 0; pr_handle_name("%s HDD Backplane FRU Information", company); if (h->length < 0x08) break; pr_attr("FRU I2C Address", "0x%X raw(0x%X)", data[0x4] >> 1, data[0x4]); pr_attr("Box Number", "%d", WORD(data + 0x5)); pr_attr("NVRAM ID", "0x%X", WORD(data + 0x7)); if (h->length < 0x11) break; pr_attr("SAS Expander WWID", "0x%X", QWORD(data + 0x9)); if (h->length < 0x12) break; pr_attr("Total SAS Bays", "%d", data[0x11]); if (h->length < 0x15) break; if (gen < G10P) { pr_attr("A0 Bay Count", "%d", data[0x12]); pr_attr("A2 Bay Count", "%d", data[0x13]); pr_attr("Backplane Name", "%s", dmi_string(h, data[0x14])); } break; case 237: /* * Vendor Specific: HPE DIMM Vendor Part Number Information * * Offset | Name | Width | Description * --------------------------------------- * 0x00 | Type | BYTE | 0xED, DIMM Vendor Part Number information record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Hand Assoc | WORD | Handle to map to Type 17 * 0x06 | Manufacture|STRING | DIMM Manufacturer * 0x07 | Part Number|STRING | DIMM Manufacturer's Part Number * 0x08 | Serial Num |STRING | DIMM Vendor Serial Number * 0x09 | Man Date | BYTE | DIMM Manufacture Date (YEAR) in BCD * 0x0A | Man Date | BYTE | DIMM Manufacture Date (WEEK) in BCD */ if (gen < G9) return 0; pr_handle_name("%s DIMM Vendor Information", company); if (h->length < 0x08) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x4)); pr_attr("DIMM Manufacturer", "%s", dmi_string(h, data[0x06])); pr_attr("DIMM Manufacturer Part Number", "%s", dmi_string(h, data[0x07])); if (h->length < 0x09) break; pr_attr("DIMM Vendor Serial Number", "%s", dmi_string(h, data[0x08])); if (h->length < 0x0B) break; if (WORD(data + 0x09)) pr_attr("DIMM Manufacture Date", "20%02x-W%02x", data[0x09], data[0x0A]); break; case 238: /* * Vendor Specific: HPE USB Port Connector Correlation Record * * Offset | Name | Width | Description * --------------------------------------- * 0x00 | Type | BYTE | 0xEE, HP Device Correlation Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Hand Assoc | WORD | Handle to map to Type 8 * 0x06 | Parent Bus | BYTE | PCI Bus number of USB controller of this port * 0x07 | Par Dev/Fun| BYTE | PCI Dev/Fun of USB Controller of this port * 0x08 | Location | BYTE | Enumerated value of location of USB port * 0x09 | Flags | WORD | USB Shared Management Port * 0x0B | Port Inst | BYTE | Instance number for this type of USB port * 0x0C | Parent Hub | BYTE | Instance number of internal Hub * 0x0D | Port Speed | BYTE | Enumerated value of speed configured by BIOS * 0x0E | Device Path| STRING| UEFI Device Path of USB endpoint * 0x0F | PCI Seg | WORD | PCI Segment number of the USB controller */ if (gen < G9) return 0; pr_handle_name("%s ProLiant USB Port Connector Correlation Record", company); if (h->length < 0x0F) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x4)); if (h->length < 0x11) pr_attr("PCI Device", "%02x:%02x.%x", data[0x6], data[0x7] >> 3, data[0x7] & 0x7); else pr_attr("PCI Device", "%04x:%02x:%02x.%x", WORD(data + 0xF), data[0x6], data[0x7] >> 3, data[0x7] & 0x7); dmi_hp_238_loc("Location", data[0x8]); dmi_hp_238_flags("Management Port", WORD(data + 0x9)); pr_attr("Port Instance", "%d", data[0xB]); if (data[0xC] != 0xFE) pr_attr("Parent Hub Port Instance", "%d", data[0xC]); else pr_attr("Parent Hub Port Instance", "N/A"); dmi_hp_238_speed("Port Speed Capability", data[0xD]); pr_attr("Device Path", "%s", dmi_string(h, data[0xE])); break; case 239: /* * Vendor Specific: HPE USB Device Correlation Record * * This record provides a mechanism for software to correlate USB device * information provided in SMBIOS record Type 8 and Type 238. It * additionally provides device specific data that is typically not * available in SMBIOS to allow HP tools to understand how these device * entries correlate to both UEFI and Legacy USB Boot entries. This record * will only contain information for a device detected by the BIOS during * POST and does not comprehend a hot plug event after the system has * booted. This record will only be supported on UEFI Based systems. * * Offset | Name | Width | Description * -------+------------+-------+------------ * 0x00 | Type | BYTE | 0xEF, HP Device Correlation Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Hand Assoc | WORD | Handle to map to Type 238 * 0x06 | Vendor ID | WORD | Vendor ID of detected USB Device * 0x08 | Flags | WORD | Bit[0] - Indicates presence of SD card * 0x0A | Class | BYTE | USB Device Class per USB HID Dev Spec * 0x0B | Sub Class | BYTE | USB Device SubClass per USB HID Dev Spec * 0x0C | Protocol | BYTE | Device Protocol per USB HID Dev Spec * 0x0D | Product ID | WORD | USB Product ID * 0x0F | Capacity | DWORD | USB Device Capacity (if apropos) in Mbytes * 0x13 | Device Path| STRING| UEFI Device Path * 0x14 | Device Name| STRING| UEFI Device Structured Name * 0x15 | UEFI Name | STRING| Device Name * 0x16 | Location | STRING| USB Device Location */ if (gen < G9) return 0; pr_handle_name("%s USB Device Correlation Record", company); if (h->length < 0x17) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x04)); pr_attr("USB Vendor ID", "0x%04x", WORD(data + 0x06)); pr_attr("Embedded SD Card", "%s", data[0x08] & 0x01 ? "Present" : "Empty"); dmi_hp_239_usb_device(data[0x0A], data[0x0B], data[0x0C]); pr_attr("USB Product ID", "0x%04x", WORD(data + 0x0D)); if (DWORD(data + 0x0F)) pr_attr("USB Capacity", "%u MB", DWORD(data + 0x0F)); pr_attr("UEFI Device Path", "%s", dmi_string(h, data[0x13])); pr_attr("UEFI Device Name", "%s", dmi_string(h, data[0x14])); pr_attr("Device Name", "%s", dmi_string(h, data[0x15])); pr_attr("Device Location", "%s", dmi_string(h, data[0x16])); break; case 240: /* * Vendor Specific: HPE ProLiant Inventory Record * * Reports firmware version information for devices that report their * firmware using their UEFI drivers. Additionally provides association * with other SMBIOS records, such as Type 203 (which in turn is * associated with Types 9, 41, and 228). * * Offset | Name | Width | Description * --------------------------------------- * 0x00 | Type | BYTE | 0xF0, HP Firmware Inventory Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Hndl Assoc | WORD | Handle to map to Type 203 * 0x06 | Pkg Vers | DWORD | FW Vers Release of All FW in Device * 0x0A | Ver String | STRING| FW Version String * 0x0B | Image Size | QWORD | FW image size (bytes) * 0x13 | Attributes | QWORD | Bitfield: Is attribute defined? * 0x1B | Attr Set | QWORD | BitField: If defined, is attribute set? * 0x23 | Version | DWORD | Lowest supported version. */ pr_handle_name("%s ProLiant Inventory Record", company); if (h->length < 0x27) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x4)); pr_attr("Package Version", "0x%08X", DWORD(data + 0x6)); pr_attr("Version String", "%s", dmi_string(h, data[0x0A])); if (DWORD(data + 0x0B)) dmi_print_memory_size(pr_attr, "Image Size", QWORD(data + 0xB), 0); else pr_attr("Image Size", "Not Available"); dmi_hp_240_attr(QWORD(data + 0x13), QWORD(data + 0x1B)); if (DWORD(data + 0x23)) pr_attr("Lowest Supported Version", "0x%08X", DWORD(data + 0x23)); else pr_attr("Lowest Supported Version", "Not Available"); break; case 242: /* * Vendor Specific: HPE Hard Drive Inventory Record * * This record provides a mechanism for software to gather information for * NVMe and SATA drives that are directly attached to the system. This * record does not contain drive information for drives attached to a HBA * (i.e. a SmartArray controller). This record will only contain information * for a hard drive detected by the BIOS during POST and does not * comprehend a hot plug event after the system has booted. * * Offset | Name | Width | Description * --------------------------------------- * 0x00 | Type | BYTE | 0xF2, HPE Hard Drive Inventory Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Hndl Assoc | WORD | Handle to map to Type 203 * 0x06 | HDD Type | BYTE | Hard drive type * 0x07 | HDD Uniq ID| QWORD | SATA-> WWID. NVMe -> IEEE Ext Uniq ID. * 0x0F | Capacity | DWORD | Drive Capacity in Mbytes * 0x13 | Hours | 16BYTE| Number of poweron hours * 0x23 | Reserved | BYTE | Reserved * 0x24 | Power | BTYE | Wattage * 0x25 | Form Factor| BYTE | HDD Form Factor * 0x26 | Health | BYTE | Hard Drive Health Status * 0x27 | Serial Num | STRING| NVMe/SATA Serial Number * 0x28 | Model Num | STRING| NVMe/SATA Model Number * 0x29 | FW Rev | STRING| Firmware revision * 0x2A | Location | STRING| Drive location * 0x2B | Crypt Stat | BYTE | Drive encryption status from BIOS * 0x2C | Capacity | QWORD | Hard Drive capacity in bytes * 0x34 | Block Size | DWORD | Logical Block Size in bytes * 0x38 | Rot Speed | WORD | Nominal Rotational Speed (RPM) * 0x3A | Neg Speed | WORD | Current negotiated bus speed * 0x3C | Cap Speed | WORD | Fastest Capable Bus Speed of drive */ if (gen < G10) return 0; pr_handle_name("%s ProLiant Hard Drive Inventory Record", company); if (h->length < 0x2A) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x4)); dmi_hp_242_hdd_type(data[0x06]); pr_attr("ID", "%llx", QWORD(data + 0x07)); if (h->length < 0x3E) dmi_print_storage_size("Capacity", DWORD(data + 0x0F), 2); else dmi_print_storage_size("Capacity", QWORD(data + 0x2C), 0); /* NB: Poweron low QWORD good for 2,104,351,365,926,255 years */ pr_attr("Poweron", "%ld hours", QWORD(data + 0x13)); if (data[0x24]) pr_attr("Power Wattage", "%hhu W", data[0x24]); else pr_attr("Power Wattage", "%s", "Unknown"); dmi_hp_242_form_factor(data[0x25]); feat = data[0x26]; pr_attr("Health Status", "%s", (feat == 0x00) ? "OK" : (feat == 0x01) ? "Warning" : (feat == 0x02) ? "Critical" : (feat == 0xFF) ? "Unknown" : "Reserved"); pr_attr("Serial Number", dmi_string(h, data[0x27])); pr_attr("Model Number", dmi_string(h, data[0x28])); pr_attr("Firmware Revision", dmi_string(h, data[0x29])); if (h->length < 0x2C) break; pr_attr("Location", dmi_string(h, data[0x2A])); feat = data[0x2B]; pr_attr("Encryption Status", "%s", (feat == 0) ? "Not Encrypted" : (feat == 1) ? "Encrypted" : (feat == 2) ? "Unknown" : (feat == 3) ? "Not Supported" : "Reserved"); if (h->length < 0x3E) break; pr_attr("Block Size", "%u bytes", DWORD(data + 0x34)); /* Rotational Speed: 0 -> Not Reported, 1 -> N/A (SSD) */ if (data[0x38] > 1) pr_attr("Rotational Speed", "%hhu RPM", data[0x38]); dmi_hp_242_speed("Negotiated Speed", WORD(data + 0x3A)); dmi_hp_242_speed("Capable Speed", WORD(data + 0x3C)); break; case 244: /* * Vendor Specific: HPE DIMM Current Configuration Record * * This record is used to communicate information about the currently * configured memory regions on DIMMs installed in the system. * * There will be at least one Type 244 Record for each DIMM installed * in the system with configured non-volatile or volatile memory. * * The number of DIMM Configuration Records for each DIMM is specified by * the Configured Region Count field in its corresponding Type 232 DIMM * Capabilities record. Each record represents a memory region on the * DIMM, labeled by its Region ID. The Memory Type field can be used to * determine the currently configured memory type for the region. When * set to Volatile, the data on the memory region is lost on a power * cycle. When set to Byte Accessible Persistent, the data on * the memory region is retained through a reset. The Region Memory Size * field contains the size of the configured region in MiB. * * The Passphrase State specifies the enable/disable state of the * Passphrase requirement and is only applicable when the DIMM region is * configured as Byte Accessible Persistent. The Interleave Set Index * specifies which interleave set the DIMM region belongs to, if any. * Regions with identical interleave set indices mean the DIMM regions * are interleaved. These indices should match what is found in the DIMM's * PCAT Interleave Information tables. Interleave set indices are * 1-based. This will be a unique value per interleave set. If the DIMM * region is not interleaved, the interleave set index will * still be a unique value. * * Offset | Name | Width | Description * --------------------------------------- * 0x00 | Type | BYTE | 0xF4, DIMM Current Configuration Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Hndl Assoc | WORD | Handle of corresponding Type 17 record * 0x06 | Region ID | BYTE | Unique ID of memory region on DIMM * 0x07 | Region Type| WORD | Persistence Type. Bit Field: See code * 0x09 | Region Size| QWORD | Size of memory region in MiB * 0x11 | Passphrase | BYTE | Current state of Passphrase. See code * 0x12 | Set Index | WORD | Interleave set index. Region w/ same index * | are part of same interleave set. * 0x14 | DIMM Count | BYTE | Number of DIMMs in interleave set * 0x15 | Health | BYTE | Health of Interleave set defined in code */ pr_handle_name("%s DIMM Current Configuration", company); if (h->length < 0x14) break; if (!(opt.flags & FLAG_QUIET)) pr_attr("Associated Handle", "0x%04X", WORD(data + 0x04)); pr_attr("Region ID", "%hhu", data[0x06]); feat = WORD(data + 0x07); pr_attr("Persistence Type", "%s", (feat & 0x01) ? "Volatile" : ((feat >> 1) & 0x01) ? "Byte Accessible" : ((feat >> 2) & 0x01) ? "Block I/O" : "Reserved"); dmi_print_memory_size(pr_attr, "Size", QWORD(data + 0x09), 2); pr_attr("Passphrase Enabled", "%s", data[0x11] ? "Yes" : "No"); feat = WORD(data + 0x12); if (feat) pr_attr("Interleave Set Index", "%u", feat); if (h->length < 0x15) break; if (feat) pr_attr("Interleave DIMM Count", "%hhu", data[0x14]); if (h->length < 0x16) break; if (feat) dmi_hp_244_health(data[0x15]); break; case 245: /* * Vendor Specific: HPE Extension Board Inventory Record * * This record provides a mechanism for software to retrieve installed * Extension Boards in system, such as Riser Cards, etc. Each extension * board discovered at system boot time has a corresponding record * produced in SMBIOS Type 245. This record is currently applicable * for ML, DL and Alletra series servers in Gen11 and will be backward * compatible with next generations * * This is a variant record. Definition of fields 0x05 ... vary based * upon field 0x04 Board Type. * * Offset | Name | Width | Description * --------------------------------------- * 0x00 | Type | BYTE | 0xF5, Extension Board Inventory Record * 0x01 | Length | BYTE | Length of structure * 0x02 | Handle | WORD | Unique handle * 0x04 | Board Type | WORD | See below * * If Board Type == 0 * 0x05 | Riser Pos | WORD | * 0x06 | Riser ID | BYTE | * 0x07 | CPLD Vers | BTYE | 0-> No CPLD. Bits [7][6:0] Release:Vers * 0x08 | Riser Name | STRING| * * If Board Type == 1 * 0x05 | Riser ID | BYTE | * 0x06 | Riser FW Major | BYTE | * 0x07 | Riser FW Minor | BYTE | * 0x08 | Misc Attr | BYTE | * 0x09 | Riser Name | STRING| * 0x0A | Slot Count | BYTE | * 0x0B | Slot ID | Varies| One per slot */ pr_handle_name("%s ProLiant Extension Board Inventory Record", company); if (h->length < 0x05) break; switch (data[0x04]) { case 0: dmi_hp_245_pcie_riser(h); break; case 1: dmi_hp_245_pcie_mhs_riser(h); break; } break; default: return 0; } return 1; } static int dmi_decode_ibm_lenovo(const struct dmi_header *h) { u8 *data = h->data; switch (h->type) { case 131: /* * Vendor Specific: ThinkVantage Technologies feature bits * * Source: Compal hel81 Service Manual Software Specification, * documented under "System Management BIOS(SM BIOS) * version 2.4 or greater" * * Offset | Name | Width | Description * ---------------------------------------------- * 0x00 | Type | BYTE | 0x83 * 0x01 | Length | BYTE | 0x16 * 0x02 | Handle | WORD | Varies * 0x04 | Version | BYTE | 0x01 * 0x05 | TVT Structure | BYTEx16 | Each of the 128 bits represents a TVT feature: * | | | - bit 127 means diagnostics (PC Doctor) is available * | | | (http://www.pc-doctor.com/company/pr-articles/45-lenovo-introduces-thinkvantage-toolbox) * | | | - the rest (126-0) are reserved/unknown * * It must also be followed by a string containing * "TVT-Enablement". There exist other type 131 records * with different length and a different string, for * other purposes. */ if (h->length != 0x16 || strcmp(dmi_string(h, 1), "TVT-Enablement") != 0) return 0; pr_handle_name("ThinkVantage Technologies"); pr_attr("Version", "%u", data[0x04]); pr_attr("Diagnostics", "%s", data[0x14] & 0x80 ? "Available" : "No"); break; case 135: /* * Vendor Specific: Device Presence Detection bits * * Source: Compal hel81 Service Manual Software Specification, * documented as "SMBIOS Type 135: Bulk for Lenovo * Mobile PC Unique OEM Data" under appendix D. * * Offset | Name | Width | Description * --------------------------------------------------- * 0x00 | Type | BYTE | 0x87 * 0x01 | Length | BYTE | 0x0A * 0x02 | Handle | WORD | Varies * 0x04 | Signature | WORD | 0x5054 (ASCII for "TP") * 0x06 | OEM struct offset | BYTE | 0x07 * 0x07 | OEM struct number | BYTE | 0x03, for this structure * 0x08 | OEM struct revision | BYTE | 0x01, for this format * 0x09 | Device presence bits | BYTE | Each of the 8 bits indicates device presence: * | | | - bit 0 indicates the presence of a fingerprint reader * | | | - the rest (7-1) are reserved/unknown * * Other OEM struct number+rev combinations have been * seen in the wild but we don't know how to decode * them. */ if (h->length < 0x0A || data[0x04] != 'T' || data[0x05] != 'P') return 0; /* Bail out if not the expected format */ if (data[0x06] != 0x07 || data[0x07] != 0x03 || data[0x08] != 0x01) return 0; pr_handle_name("ThinkPad Device Presence Detection"); pr_attr("Fingerprint Reader", "%s", data[0x09] & 0x01 ? "Present" : "No"); break; case 140: /* * Vendor Specific: ThinkPad Embedded Controller Program * * Source: some guesswork, and publicly available information; * Lenovo's BIOS update READMEs often contain the ECP IDs * which match the first string in this type. * * Offset | Name | Width | Description * ---------------------------------------------------- * 0x00 | Type | BYTE | 0x8C * 0x01 | Length | BYTE | * 0x02 | Handle | WORD | Varies * 0x04 | Signature | BYTEx6 | ASCII for "LENOVO" * 0x0A | OEM struct offset | BYTE | 0x0B * 0x0B | OEM struct number | BYTE | 0x07, for this structure * 0x0C | OEM struct revision | BYTE | 0x01, for this format * 0x0D | ECP version ID | STRING | * 0x0E | ECP release date | STRING | */ if (h->length < 0x0F || memcmp(data + 4, "LENOVO", 6) != 0) return 0; /* Bail out if not the expected format */ if (data[0x0A] != 0x0B || data[0x0B] != 0x07 || data[0x0C] != 0x01) return 0; pr_handle_name("ThinkPad Embedded Controller Program"); pr_attr("Version ID", "%s", dmi_string(h, 1)); pr_attr("Release Date", "%s", dmi_string(h, 2)); break; default: return 0; } return 1; } /* * Dispatch vendor-specific entries decoding * Return 1 if decoding was successful, 0 otherwise */ int dmi_decode_oem(const struct dmi_header *h, u16 ver) { switch (dmi_vendor) { case VENDOR_HP: case VENDOR_HPE: return dmi_decode_hp(h, ver); case VENDOR_ACER: return dmi_decode_acer(h); case VENDOR_DELL: return dmi_decode_dell(h); case VENDOR_IBM: case VENDOR_LENOVO: return dmi_decode_ibm_lenovo(h); default: return 0; } }