/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include static int smbios_cpu_vendor(u8 *start) { if (cpu_have_cpuid()) { u32 tmp[4]; const struct cpuid_result res = cpuid(0); tmp[0] = res.ebx; tmp[1] = res.edx; tmp[2] = res.ecx; tmp[3] = 0; return smbios_add_string(start, (const char *)tmp); } else { return smbios_add_string(start, "Unknown"); } } static int smbios_processor_name(u8 *start) { u32 tmp[13]; const char *str = "Unknown Processor Name"; if (cpu_have_cpuid()) { int i; struct cpuid_result res; if (cpu_cpuid_extended_level() >= 0x80000004) { int j = 0; for (i = 0; i < 3; i++) { res = cpuid(0x80000002 + i); tmp[j++] = res.eax; tmp[j++] = res.ebx; tmp[j++] = res.ecx; tmp[j++] = res.edx; } tmp[12] = 0; str = (const char *)tmp; } } return smbios_add_string(start, str); } static int get_socket_type(void) { if (CONFIG(CPU_INTEL_SLOT_1)) return PROCESSOR_UPGRADE_SLOT_1; if (CONFIG(CPU_INTEL_SOCKET_MPGA604)) return PROCESSOR_UPGRADE_SOCKET_MPGA604; if (CONFIG(CPU_INTEL_SOCKET_LGA775)) return PROCESSOR_UPGRADE_SOCKET_LGA775; if (CONFIG(SOC_INTEL_ALDERLAKE)) return PROCESSOR_UPGRADE_SOCKET_LGA1700; if (CONFIG(SOC_INTEL_METEORLAKE)) return PROCESSOR_UPGRADE_OTHER; if (CONFIG(SOC_INTEL_SKYLAKE_SP)) return PROCESSOR_UPGRADE_SOCKET_LGA3647_1; if (CONFIG(SOC_INTEL_COOPERLAKE_SP)) return PROCESSOR_UPGRADE_SOCKET_LGA4189; if (CONFIG(SOC_INTEL_SAPPHIRERAPIDS_SP)) return PROCESSOR_UPGRADE_SOCKET_LGA4677; return PROCESSOR_UPGRADE_UNKNOWN; } unsigned int __weak smbios_processor_family(struct cpuid_result res) { return (res.eax > 0) ? 0x0c : 0x6; } static size_t get_number_of_caches(size_t max_logical_cpus_sharing_cache) { size_t number_of_cpus_per_package = 0; size_t max_logical_cpus_per_package = 0; struct cpuid_result res; if (!cpu_have_cpuid()) return 1; res = cpuid(1); max_logical_cpus_per_package = (res.ebx >> 16) & 0xff; /* Check if it's last level cache */ if (max_logical_cpus_sharing_cache == max_logical_cpus_per_package) return 1; if (cpuid_get_max_func() >= 0xb) { res = cpuid_ext(0xb, 1); number_of_cpus_per_package = res.ebx & 0xff; } else { number_of_cpus_per_package = max_logical_cpus_per_package; } return number_of_cpus_per_package / max_logical_cpus_sharing_cache; } #define MAX_CPUS_ENABLED (CONFIG_MAX_CPUS > 0xff ? 0xff : CONFIG_MAX_CPUS) int smbios_write_type4(unsigned long *current, int handle) { unsigned int cpu_voltage; struct cpuid_result res; uint16_t characteristics = 0; static unsigned int cnt = 0; char buf[8]; /* Provide sane defaults even for CPU without CPUID */ res.eax = res.edx = 0; res.ebx = 0x10000; if (cpu_have_cpuid()) res = cpuid(1); struct smbios_type4 *t = smbios_carve_table(*current, SMBIOS_PROCESSOR_INFORMATION, sizeof(*t), handle); snprintf(buf, sizeof(buf), "CPU%d", cnt++); t->socket_designation = smbios_add_string(t->eos, buf); t->processor_id[0] = res.eax; t->processor_id[1] = res.edx; t->processor_manufacturer = smbios_cpu_vendor(t->eos); t->processor_version = smbios_processor_name(t->eos); t->processor_family = smbios_processor_family(res); t->processor_type = 3; /* System Processor */ /* * If CPUID leaf 11 is available, calculate "core count" by dividing * SMT_ID (logical processors in a core) by Core_ID (number of cores). * This seems to be the way to arrive to a number of cores mentioned on * ark.intel.com. */ if (cpu_have_cpuid() && cpuid_get_max_func() >= 0xb) { uint32_t leaf_b_cores = 0, leaf_b_threads = 0; res = cpuid_ext(0xb, 1); leaf_b_cores = res.ebx; res = cpuid_ext(0xb, 0); leaf_b_threads = res.ebx; /* if hyperthreading is not available, pretend this is 1 */ if (leaf_b_threads == 0) leaf_b_threads = 1; t->core_count2 = leaf_b_cores / leaf_b_threads; t->core_count = t->core_count2 > 0xff ? 0xff : t->core_count2; t->thread_count2 = leaf_b_cores; t->thread_count = t->thread_count2 > 0xff ? 0xff : t->thread_count2; } else { t->core_count = (res.ebx >> 16) & 0xff; t->core_count2 = t->core_count; t->thread_count2 = t->core_count2; t->thread_count = t->thread_count2; } /* Assume we enable all the cores always, capped only by MAX_CPUS */ t->core_enabled = MIN(t->core_count, MAX_CPUS_ENABLED); t->core_enabled2 = MIN(t->core_count2, CONFIG_MAX_CPUS); t->l1_cache_handle = 0xffff; t->l2_cache_handle = 0xffff; t->l3_cache_handle = 0xffff; t->serial_number = smbios_add_string(t->eos, smbios_processor_serial_number()); t->status = SMBIOS_PROCESSOR_STATUS_CPU_ENABLED | SMBIOS_PROCESSOR_STATUS_POPULATED; t->processor_upgrade = get_socket_type(); if (cpu_have_cpuid() && cpuid_get_max_func() >= 0x16) { t->current_speed = cpuid_eax(0x16); /* base frequency */ t->external_clock = cpuid_ecx(0x16); } else { t->current_speed = smbios_cpu_get_current_speed_mhz(); t->external_clock = smbios_processor_external_clock(); } /* This field identifies a capability for the system, not the processor itself. */ t->max_speed = smbios_cpu_get_max_speed_mhz(); if (cpu_have_cpuid()) { res = cpuid(1); if ((res.ecx) & BIT(5)) characteristics |= BIT(6); /* BIT6: Enhanced Virtualization */ if ((res.edx) & BIT(28)) characteristics |= BIT(4); /* BIT4: Hardware Thread */ if (((cpuid_eax(0x80000000) - 0x80000000) + 1) > 2) { res = cpuid(0x80000001); if ((res.edx) & BIT(20)) characteristics |= BIT(5); /* BIT5: Execute Protection */ } } t->processor_characteristics = characteristics | smbios_processor_characteristics(); cpu_voltage = smbios_cpu_get_voltage(); if (cpu_voltage > 0) t->voltage = 0x80 | cpu_voltage; const int len = smbios_full_table_len(&t->header, t->eos); *current += len; return len; } /* * Parse the "Deterministic Cache Parameters" as provided by Intel in * leaf 4 or AMD in extended leaf 0x8000001d. * * @param current Pointer to memory address to write the tables to * @param handle Pointer to handle for the tables * @param max_struct_size Pointer to maximum struct size * @param type4 Pointer to SMBIOS type 4 structure */ int smbios_write_type7_cache_parameters(unsigned long *current, int *handle, int *max_struct_size, struct smbios_type4 *type4) { unsigned int cnt = CACHE_L1D; int len = 0; if (!cpu_have_cpuid()) return len; enum cpu_type dcache_cpuid = cpu_check_deterministic_cache_cpuid_supported(); if (dcache_cpuid == CPUID_TYPE_INVALID || dcache_cpuid == CPUID_COMMAND_UNSUPPORTED) { printk(BIOS_DEBUG, "SMBIOS: Unknown CPU or CPU doesn't support Deterministic " "Cache CPUID leaf\n"); return len; } while (1) { enum smbios_cache_associativity associativity; enum smbios_cache_type type; struct cpu_cache_info info; if (!fill_cpu_cache_info(cnt++, &info)) continue; const u8 cache_type = info.type; const u8 level = info.level; const size_t assoc = info.num_ways; const size_t cache_share = info.num_cores_shared; const size_t cache_size = info.size * get_number_of_caches(cache_share); if (!cache_type) /* No more caches in the system */ break; switch (cache_type) { case 1: type = SMBIOS_CACHE_TYPE_DATA; break; case 2: type = SMBIOS_CACHE_TYPE_INSTRUCTION; break; case 3: type = SMBIOS_CACHE_TYPE_UNIFIED; break; default: type = SMBIOS_CACHE_TYPE_UNKNOWN; break; } if (info.fully_associative) associativity = SMBIOS_CACHE_ASSOCIATIVITY_FULL; else associativity = smbios_cache_associativity(assoc); const int h = (*handle)++; update_max(len, *max_struct_size, smbios_write_type7(current, h, level, smbios_cache_sram_type(), associativity, type, cache_size, cache_size)); if (type4) { switch (level) { case 1: type4->l1_cache_handle = h; break; case 2: type4->l2_cache_handle = h; break; case 3: type4->l3_cache_handle = h; break; } } }; return len; }