/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define CPUID_PROCESSOR_FREQUENCY 0X16 #define CPUID_HYBRID_INFORMATION 0x1a /* Structured Extended Feature Flags */ #define HYBRID_FEATURE BIT(15) /* * Set PERF_CTL MSR (0x199) P_Req with * Turbo Ratio which is the Maximum Ratio. */ void cpu_set_max_ratio(void) { /* Check for configurable TDP option */ if (get_turbo_state() == TURBO_ENABLED) cpu_set_p_state_to_turbo_ratio(); } /* * Get the TDP Nominal Ratio from MSR 0x648 Bits 7:0. */ u8 cpu_get_tdp_nominal_ratio(void) { u8 nominal_ratio; msr_t msr; msr = rdmsr(MSR_CONFIG_TDP_NOMINAL); nominal_ratio = msr.lo & 0xff; return nominal_ratio; } /* * Read PLATFORM_INFO MSR (0xCE). * Return Value of Bit 34:33 (CONFIG_TDP_LEVELS). * * Possible values of Bit 34:33 are - * 00 : Config TDP not supported * 01 : One Additional TDP level supported * 10 : Two Additional TDP level supported * 11 : Reserved */ int cpu_config_tdp_levels(void) { msr_t platform_info; /* Bits 34:33 indicate how many levels supported */ platform_info = rdmsr(MSR_PLATFORM_INFO); return (platform_info.hi >> 1) & 3; } static void set_perf_control_msr(msr_t msr) { wrmsr(IA32_PERF_CTL, msr); printk(BIOS_DEBUG, "CPU: frequency set to %d MHz\n", ((msr.lo >> 8) & 0xff) * CONFIG_CPU_BCLK_MHZ); } /* * TURBO_RATIO_LIMIT MSR (0x1AD) Bits 31:0 indicates the * factory configured values for of 1-core, 2-core, 3-core * and 4-core turbo ratio limits for all processors. * * 7:0 - MAX_TURBO_1_CORE * 15:8 - MAX_TURBO_2_CORES * 23:16 - MAX_TURBO_3_CORES * 31:24 - MAX_TURBO_4_CORES * * Set PERF_CTL MSR (0x199) P_Req with that value. */ void cpu_set_p_state_to_turbo_ratio(void) { msr_t msr, perf_ctl; msr = rdmsr(MSR_TURBO_RATIO_LIMIT); perf_ctl.lo = (msr.lo & 0xff) << 8; perf_ctl.hi = 0; set_perf_control_msr(perf_ctl); } /* * CONFIG_TDP_NOMINAL MSR (0x648) Bits 7:0 tells Nominal * TDP level ratio to be used for specific processor (in units * of 100MHz). * * Set PERF_CTL MSR (0x199) P_Req with that value. */ void cpu_set_p_state_to_nominal_tdp_ratio(void) { msr_t msr, perf_ctl; msr = rdmsr(MSR_CONFIG_TDP_NOMINAL); perf_ctl.lo = (msr.lo & 0xff) << 8; perf_ctl.hi = 0; set_perf_control_msr(perf_ctl); } /* * PLATFORM_INFO MSR (0xCE) Bits 15:8 tells * MAX_NON_TURBO_LIM_RATIO. * * Set PERF_CTL MSR (0x199) P_Req with that value. */ void cpu_set_p_state_to_max_non_turbo_ratio(void) { msr_t perf_ctl; /* Platform Info bits 15:8 give max ratio */ perf_ctl.lo = (cpu_get_max_non_turbo_ratio() << 8) & 0xff00; perf_ctl.hi = 0; set_perf_control_msr(perf_ctl); } /* * Set PERF_CTL MSR (0x199) P_Req with the value * for maximum efficiency. This value is reported in PLATFORM_INFO MSR (0xCE) * in Bits 47:40 and is extracted with cpu_get_min_ratio(). */ void cpu_set_p_state_to_min_clock_ratio(void) { uint32_t min_ratio; msr_t perf_ctl; /* Read the minimum ratio for the best efficiency. */ min_ratio = cpu_get_min_ratio(); perf_ctl.lo = (min_ratio << 8) & 0xff00; perf_ctl.hi = 0; set_perf_control_msr(perf_ctl); } /* * Get the Burst/Turbo Mode State from MSR IA32_MISC_ENABLE 0x1A0 * Bit 38 - TURBO_MODE_DISABLE Bit to get state ENABLED / DISABLED. * Also check for the cpuid 0x6 to check whether Burst mode unsupported. */ int cpu_get_burst_mode_state(void) { msr_t msr; unsigned int eax; int burst_en, burst_cap, burst_state = BURST_MODE_UNKNOWN; eax = cpuid_eax(0x6); burst_cap = eax & 0x2; msr = rdmsr(IA32_MISC_ENABLE); burst_en = !(msr.hi & BURST_MODE_DISABLE); if (!burst_cap && burst_en) { burst_state = BURST_MODE_UNAVAILABLE; } else if (burst_cap && !burst_en) { burst_state = BURST_MODE_DISABLED; } else if (burst_cap && burst_en) { burst_state = BURST_MODE_ENABLED; } return burst_state; } bool cpu_is_hybrid_supported(void) { struct cpuid_result cpuid_regs; /* CPUID.(EAX=07H, ECX=00H):EDX[15] indicates CPU is hybrid CPU or not*/ cpuid_regs = cpuid_ext(CPUID_STRUCT_EXTENDED_FEATURE_FLAGS, 0); return !!(cpuid_regs.edx & HYBRID_FEATURE); } /* * The function must be called if CPU is hybrid. If CPU is hybrid, the CPU type * information is available in the Hybrid Information Enumeration Leaf(EAX=0x1A, ECX=0). */ uint8_t cpu_get_cpu_type(void) { union cpuid_nat_model_id_and_core_type { struct { u32 native_mode_id:24; u32 core_type:8; } bits; u32 hybrid_info; }; union cpuid_nat_model_id_and_core_type eax; eax.hybrid_info = cpuid_eax(CPUID_HYBRID_INFORMATION); return (u8)eax.bits.core_type; } /* It gets CPU bus frequency in MHz */ uint32_t cpu_get_bus_frequency(void) { return cpuid_ecx(CPUID_PROCESSOR_FREQUENCY); } /* * Program CPU Burst mode * true = Enable Burst mode. * false = Disable Burst mode. */ void cpu_burst_mode(bool burst_mode_status) { msr_t msr; msr = rdmsr(IA32_MISC_ENABLE); if (burst_mode_status) msr.hi &= ~BURST_MODE_DISABLE; else msr.hi |= BURST_MODE_DISABLE; wrmsr(IA32_MISC_ENABLE, msr); } /* * Program Enhanced Intel Speed Step Technology * true = Enable EIST. * false = Disable EIST. */ void cpu_set_eist(bool eist_status) { msr_t msr; msr = rdmsr(IA32_MISC_ENABLE); if (eist_status) msr.lo |= (1 << 16); else msr.lo &= ~(1 << 16); wrmsr(IA32_MISC_ENABLE, msr); } /* * This function fills in the number of Cores(physical) and Threads(virtual) * of the CPU in the function arguments. It also returns if the number of cores * and number of threads are equal. */ int cpu_read_topology(unsigned int *num_phys, unsigned int *num_virt) { msr_t msr; msr = rdmsr(MSR_CORE_THREAD_COUNT); *num_virt = (msr.lo >> 0) & 0xffff; *num_phys = (msr.lo >> 16) & 0xffff; return (*num_virt == *num_phys); } int cpu_get_coord_type(void) { return HW_ALL; } uint32_t cpu_get_min_ratio(void) { msr_t msr; /* Get bus ratio limits and calculate clock speeds */ msr = rdmsr(MSR_PLATFORM_INFO); return ((msr.hi >> 8) & 0xff); /* Max Efficiency Ratio */ } uint32_t cpu_get_max_ratio(void) { msr_t msr; uint32_t ratio_max; if (cpu_config_tdp_levels()) { /* Set max ratio to nominal TDP ratio */ msr = rdmsr(MSR_CONFIG_TDP_NOMINAL); ratio_max = msr.lo & 0xff; } else { msr = rdmsr(MSR_PLATFORM_INFO); /* Max Non-Turbo Ratio */ ratio_max = (msr.lo >> 8) & 0xff; } return ratio_max; } uint8_t cpu_get_max_non_turbo_ratio(void) { msr_t msr; /* * PLATFORM_INFO(0xCE) MSR Bits[15:8] tells * MAX_NON_TURBO_LIM_RATIO */ msr = rdmsr(MSR_PLATFORM_INFO); return ((msr.lo >> 8) & 0xff); } void configure_tcc_thermal_target(void) { const config_t *conf = config_of_soc(); msr_t msr; if (!conf->tcc_offset) return; /* Set TCC activation offset */ msr = rdmsr(MSR_PLATFORM_INFO); if ((msr.lo & BIT(30))) { msr = rdmsr(MSR_TEMPERATURE_TARGET); msr.lo &= ~(0xf << 24); msr.lo |= (conf->tcc_offset & 0xf) << 24; wrmsr(MSR_TEMPERATURE_TARGET, msr); } /* * SoCs prior to Comet Lake/Cannon Lake do not support the time window * bits, so return early. */ if (CONFIG(SOC_INTEL_APOLLOLAKE) || CONFIG(SOC_INTEL_SKYLAKE) || CONFIG(SOC_INTEL_KABYLAKE) || CONFIG(SOC_INTEL_BRASWELL) || CONFIG(SOC_INTEL_BROADWELL)) return; /* Time Window Tau Bits [6:0] */ msr = rdmsr(MSR_TEMPERATURE_TARGET); msr.lo &= ~0x7f; msr.lo |= 0xe6; /* setting 100ms thermal time window */ wrmsr(MSR_TEMPERATURE_TARGET, msr); } uint32_t cpu_get_bus_clock(void) { /* CPU bus clock is set by default here to 100MHz. * This function returns the bus clock in KHz. */ return CONFIG_CPU_BCLK_MHZ * KHz; } uint32_t cpu_get_power_max(void) { msr_t msr; int power_unit; msr = rdmsr(MSR_PKG_POWER_SKU_UNIT); power_unit = 2 << ((msr.lo & 0xf) - 1); msr = rdmsr(MSR_PKG_POWER_SKU); return (msr.lo & 0x7fff) * 1000 / power_unit; } uint32_t cpu_get_max_turbo_ratio(void) { msr_t msr; msr = rdmsr(MSR_TURBO_RATIO_LIMIT); return msr.lo & 0xff; } void mca_configure(void) { int i; const unsigned int num_banks = mca_get_bank_count(); printk(BIOS_DEBUG, "Clearing out pending MCEs\n"); mca_clear_status(); for (i = 0; i < num_banks; i++) { /* Initialize machine checks */ wrmsr(IA32_MC_CTL(i), (msr_t) {.lo = 0xffffffff, .hi = 0xffffffff}); } } void cpu_lt_lock_memory(void) { msr_set(MSR_LT_CONTROL, LT_CONTROL_LOCK); } bool is_sgx_supported(void) { struct cpuid_result cpuid_regs; msr_t msr; /* EBX[2] is feature capability */ cpuid_regs = cpuid_ext(CPUID_STRUCT_EXTENDED_FEATURE_FLAGS, 0x0); msr = rdmsr(MTRR_CAP_MSR); /* Bit 12 is PRMRR enablement */ return ((cpuid_regs.ebx & SGX_SUPPORTED) && (msr.lo & MTRR_CAP_PRMRR)); } static bool is_sgx_configured_and_supported(void) { return CONFIG(SOC_INTEL_COMMON_BLOCK_SGX_ENABLE) && is_sgx_supported(); } bool is_keylocker_supported(void) { struct cpuid_result cpuid_regs; msr_t msr; /* ECX[23] is feature capability */ cpuid_regs = cpuid_ext(CPUID_STRUCT_EXTENDED_FEATURE_FLAGS, 0x0); msr = rdmsr(MTRR_CAP_MSR); /* Bit 12 is PRMRR enablement */ return ((cpuid_regs.ecx & KEYLOCKER_SUPPORTED) && (msr.lo & MTRR_CAP_PRMRR)); } static bool is_keylocker_configured_and_supported(void) { return CONFIG(INTEL_KEYLOCKER) && is_keylocker_supported(); } static bool check_prm_features_enabled(void) { /* * Key Locker and SGX are the features that need PRM. * If either of them are enabled return true, otherwise false * */ return is_sgx_configured_and_supported() || is_keylocker_configured_and_supported(); } int get_valid_prmrr_size(void) { msr_t msr; int i; int valid_size; /* If none of the features that need PRM are enabled then return 0 */ if (!check_prm_features_enabled()) return 0; if (!CONFIG_SOC_INTEL_COMMON_BLOCK_PRMRR_SIZE) return 0; msr = rdmsr(MSR_PRMRR_VALID_CONFIG); if (!msr.lo) { printk(BIOS_WARNING, "PRMRR not supported.\n"); return 0; } printk(BIOS_DEBUG, "MSR_PRMRR_VALID_CONFIG = 0x%08x\n", msr.lo); /* find the first (greatest) value that is lower than or equal to the selected size */ for (i = 8; i >= 0; i--) { valid_size = msr.lo & (1 << i); if (valid_size && valid_size <= CONFIG_SOC_INTEL_COMMON_BLOCK_PRMRR_SIZE) break; else if (i == 0) valid_size = 0; } if (!valid_size) { printk(BIOS_WARNING, "Unsupported PRMRR size of %i MiB, check your config!\n", CONFIG_SOC_INTEL_COMMON_BLOCK_PRMRR_SIZE); return 0; } printk(BIOS_DEBUG, "PRMRR size set to %i MiB\n", valid_size); valid_size *= MiB; return valid_size; } static void sync_core_prmrr(void) { static msr_t msr_base, msr_mask; if (boot_cpu()) { msr_base = rdmsr(MSR_PRMRR_BASE_0); msr_mask = rdmsr(MSR_PRMRR_PHYS_MASK); } else if (!intel_ht_sibling()) { wrmsr(MSR_PRMRR_BASE_0, msr_base); wrmsr(MSR_PRMRR_PHYS_MASK, msr_mask); } } void init_core_prmrr(void) { msr_t msr = rdmsr(MTRR_CAP_MSR); if (msr.lo & MTRR_CAP_PRMRR) sync_core_prmrr(); } void set_tme_core_activate(void) { msr_t msr = { .lo = 0, .hi = 0 }; wrmsr(MSR_CORE_MKTME_ACTIVATION, msr); } /* Provide the max turbo frequency of the CPU */ unsigned int smbios_cpu_get_max_speed_mhz(void) { return cpu_get_max_turbo_ratio() * CONFIG_CPU_BCLK_MHZ; } void disable_three_strike_error(void) { msr_t msr; msr = rdmsr(MSR_PREFETCH_CTL); msr.lo = msr.lo | DISABLE_CPU_ERROR; wrmsr(MSR_PREFETCH_CTL, msr); } void disable_signaling_three_strike_event(void) { msr_t msr; msr = rdmsr(MSR_DISABLE_SIGNALING_THREE_STRIKE_EVENT); msr.lo = msr.lo | THREE_STRIKE_COUNT; wrmsr(MSR_DISABLE_SIGNALING_THREE_STRIKE_EVENT, msr); }