duckstation/dep/cpuinfo/include/cpuinfo.h

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2022-09-09 10:43:06 +00:00
#pragma once
#ifndef CPUINFO_H
#define CPUINFO_H
#ifndef __cplusplus
#include <stdbool.h>
#endif
#ifdef __APPLE__
#include <TargetConditionals.h>
#endif
#include <stdint.h>
/* Identify architecture and define corresponding macro */
#if defined(__i386__) || defined(__i486__) || defined(__i586__) || defined(__i686__) || defined(_M_IX86)
#define CPUINFO_ARCH_X86 1
#endif
#if defined(__x86_64__) || defined(__x86_64) || defined(_M_X64) || defined(_M_AMD64)
#define CPUINFO_ARCH_X86_64 1
#endif
#if defined(__arm__) || defined(_M_ARM)
#define CPUINFO_ARCH_ARM 1
#endif
#if defined(__aarch64__) || defined(_M_ARM64)
#define CPUINFO_ARCH_ARM64 1
#endif
#if defined(__PPC64__) || defined(__powerpc64__) || defined(_ARCH_PPC64)
#define CPUINFO_ARCH_PPC64 1
#endif
#if defined(__asmjs__)
#define CPUINFO_ARCH_ASMJS 1
#endif
#if defined(__wasm__)
#if defined(__wasm_simd128__)
#define CPUINFO_ARCH_WASMSIMD 1
#else
#define CPUINFO_ARCH_WASM 1
#endif
#endif
/* Define other architecture-specific macros as 0 */
#ifndef CPUINFO_ARCH_X86
#define CPUINFO_ARCH_X86 0
#endif
#ifndef CPUINFO_ARCH_X86_64
#define CPUINFO_ARCH_X86_64 0
#endif
#ifndef CPUINFO_ARCH_ARM
#define CPUINFO_ARCH_ARM 0
#endif
#ifndef CPUINFO_ARCH_ARM64
#define CPUINFO_ARCH_ARM64 0
#endif
#ifndef CPUINFO_ARCH_PPC64
#define CPUINFO_ARCH_PPC64 0
#endif
#ifndef CPUINFO_ARCH_ASMJS
#define CPUINFO_ARCH_ASMJS 0
#endif
#ifndef CPUINFO_ARCH_WASM
#define CPUINFO_ARCH_WASM 0
#endif
#ifndef CPUINFO_ARCH_WASMSIMD
#define CPUINFO_ARCH_WASMSIMD 0
#endif
#if CPUINFO_ARCH_X86 && defined(_MSC_VER)
#define CPUINFO_ABI __cdecl
#elif CPUINFO_ARCH_X86 && defined(__GNUC__)
#define CPUINFO_ABI __attribute__((__cdecl__))
#else
#define CPUINFO_ABI
#endif
#define CPUINFO_CACHE_UNIFIED 0x00000001
#define CPUINFO_CACHE_INCLUSIVE 0x00000002
#define CPUINFO_CACHE_COMPLEX_INDEXING 0x00000004
struct cpuinfo_cache {
/** Cache size in bytes */
uint32_t size;
/** Number of ways of associativity */
uint32_t associativity;
/** Number of sets */
uint32_t sets;
/** Number of partitions */
uint32_t partitions;
/** Line size in bytes */
uint32_t line_size;
/**
* Binary characteristics of the cache (unified cache, inclusive cache, cache with complex indexing).
*
* @see CPUINFO_CACHE_UNIFIED, CPUINFO_CACHE_INCLUSIVE, CPUINFO_CACHE_COMPLEX_INDEXING
*/
uint32_t flags;
/** Index of the first logical processor that shares this cache */
uint32_t processor_start;
/** Number of logical processors that share this cache */
uint32_t processor_count;
};
struct cpuinfo_trace_cache {
uint32_t uops;
uint32_t associativity;
};
#define CPUINFO_PAGE_SIZE_4KB 0x1000
#define CPUINFO_PAGE_SIZE_1MB 0x100000
#define CPUINFO_PAGE_SIZE_2MB 0x200000
#define CPUINFO_PAGE_SIZE_4MB 0x400000
#define CPUINFO_PAGE_SIZE_16MB 0x1000000
#define CPUINFO_PAGE_SIZE_1GB 0x40000000
struct cpuinfo_tlb {
uint32_t entries;
uint32_t associativity;
uint64_t pages;
};
/** Vendor of processor core design */
enum cpuinfo_vendor {
/** Processor vendor is not known to the library, or the library failed to get vendor information from the OS. */
cpuinfo_vendor_unknown = 0,
/* Active vendors of modern CPUs */
/**
* Intel Corporation. Vendor of x86, x86-64, IA64, and ARM processor microarchitectures.
*
* Sold its ARM design subsidiary in 2006. The last ARM processor design was released in 2004.
*/
cpuinfo_vendor_intel = 1,
/** Advanced Micro Devices, Inc. Vendor of x86 and x86-64 processor microarchitectures. */
cpuinfo_vendor_amd = 2,
/** ARM Holdings plc. Vendor of ARM and ARM64 processor microarchitectures. */
cpuinfo_vendor_arm = 3,
/** Qualcomm Incorporated. Vendor of ARM and ARM64 processor microarchitectures. */
cpuinfo_vendor_qualcomm = 4,
/** Apple Inc. Vendor of ARM and ARM64 processor microarchitectures. */
cpuinfo_vendor_apple = 5,
/** Samsung Electronics Co., Ltd. Vendir if ARM64 processor microarchitectures. */
cpuinfo_vendor_samsung = 6,
/** Nvidia Corporation. Vendor of ARM64-compatible processor microarchitectures. */
cpuinfo_vendor_nvidia = 7,
/** MIPS Technologies, Inc. Vendor of MIPS processor microarchitectures. */
cpuinfo_vendor_mips = 8,
/** International Business Machines Corporation. Vendor of PowerPC processor microarchitectures. */
cpuinfo_vendor_ibm = 9,
/** Ingenic Semiconductor. Vendor of MIPS processor microarchitectures. */
cpuinfo_vendor_ingenic = 10,
/**
* VIA Technologies, Inc. Vendor of x86 and x86-64 processor microarchitectures.
*
* Processors are designed by Centaur Technology, a subsidiary of VIA Technologies.
*/
cpuinfo_vendor_via = 11,
/** Cavium, Inc. Vendor of ARM64 processor microarchitectures. */
cpuinfo_vendor_cavium = 12,
/** Broadcom, Inc. Vendor of ARM processor microarchitectures. */
cpuinfo_vendor_broadcom = 13,
/** Applied Micro Circuits Corporation (APM). Vendor of ARM64 processor microarchitectures. */
cpuinfo_vendor_apm = 14,
/**
* Huawei Technologies Co., Ltd. Vendor of ARM64 processor microarchitectures.
*
* Processors are designed by HiSilicon, a subsidiary of Huawei.
*/
cpuinfo_vendor_huawei = 15,
/**
* Hygon (Chengdu Haiguang Integrated Circuit Design Co., Ltd), Vendor of x86-64 processor microarchitectures.
*
* Processors are variants of AMD cores.
*/
cpuinfo_vendor_hygon = 16,
/* Active vendors of embedded CPUs */
/** Texas Instruments Inc. Vendor of ARM processor microarchitectures. */
cpuinfo_vendor_texas_instruments = 30,
/** Marvell Technology Group Ltd. Vendor of ARM processor microarchitectures. */
cpuinfo_vendor_marvell = 31,
/** RDC Semiconductor Co., Ltd. Vendor of x86 processor microarchitectures. */
cpuinfo_vendor_rdc = 32,
/** DM&P Electronics Inc. Vendor of x86 processor microarchitectures. */
cpuinfo_vendor_dmp = 33,
/** Motorola, Inc. Vendor of PowerPC and ARM processor microarchitectures. */
cpuinfo_vendor_motorola = 34,
/* Defunct CPU vendors */
/**
* Transmeta Corporation. Vendor of x86 processor microarchitectures.
*
* Now defunct. The last processor design was released in 2004.
* Transmeta processors implemented VLIW ISA and used binary translation to execute x86 code.
*/
cpuinfo_vendor_transmeta = 50,
/**
* Cyrix Corporation. Vendor of x86 processor microarchitectures.
*
* Now defunct. The last processor design was released in 1996.
*/
cpuinfo_vendor_cyrix = 51,
/**
* Rise Technology. Vendor of x86 processor microarchitectures.
*
* Now defunct. The last processor design was released in 1999.
*/
cpuinfo_vendor_rise = 52,
/**
* National Semiconductor. Vendor of x86 processor microarchitectures.
*
* Sold its x86 design subsidiary in 1999. The last processor design was released in 1998.
*/
cpuinfo_vendor_nsc = 53,
/**
* Silicon Integrated Systems. Vendor of x86 processor microarchitectures.
*
* Sold its x86 design subsidiary in 2001. The last processor design was released in 2001.
*/
cpuinfo_vendor_sis = 54,
/**
* NexGen. Vendor of x86 processor microarchitectures.
*
* Now defunct. The last processor design was released in 1994.
* NexGen designed the first x86 microarchitecture which decomposed x86 instructions into simple microoperations.
*/
cpuinfo_vendor_nexgen = 55,
/**
* United Microelectronics Corporation. Vendor of x86 processor microarchitectures.
*
* Ceased x86 in the early 1990s. The last processor design was released in 1991.
* Designed U5C and U5D processors. Both are 486 level.
*/
cpuinfo_vendor_umc = 56,
/**
* Digital Equipment Corporation. Vendor of ARM processor microarchitecture.
*
* Sold its ARM designs in 1997. The last processor design was released in 1997.
*/
cpuinfo_vendor_dec = 57,
};
/**
* Processor microarchitecture
*
* Processors with different microarchitectures often have different instruction performance characteristics,
* and may have dramatically different pipeline organization.
*/
enum cpuinfo_uarch {
/** Microarchitecture is unknown, or the library failed to get information about the microarchitecture from OS */
cpuinfo_uarch_unknown = 0,
/** Pentium and Pentium MMX microarchitecture. */
cpuinfo_uarch_p5 = 0x00100100,
/** Intel Quark microarchitecture. */
cpuinfo_uarch_quark = 0x00100101,
/** Pentium Pro, Pentium II, and Pentium III. */
cpuinfo_uarch_p6 = 0x00100200,
/** Pentium M. */
cpuinfo_uarch_dothan = 0x00100201,
/** Intel Core microarchitecture. */
cpuinfo_uarch_yonah = 0x00100202,
/** Intel Core 2 microarchitecture on 65 nm process. */
cpuinfo_uarch_conroe = 0x00100203,
/** Intel Core 2 microarchitecture on 45 nm process. */
cpuinfo_uarch_penryn = 0x00100204,
/** Intel Nehalem and Westmere microarchitectures (Core i3/i5/i7 1st gen). */
cpuinfo_uarch_nehalem = 0x00100205,
/** Intel Sandy Bridge microarchitecture (Core i3/i5/i7 2nd gen). */
cpuinfo_uarch_sandy_bridge = 0x00100206,
/** Intel Ivy Bridge microarchitecture (Core i3/i5/i7 3rd gen). */
cpuinfo_uarch_ivy_bridge = 0x00100207,
/** Intel Haswell microarchitecture (Core i3/i5/i7 4th gen). */
cpuinfo_uarch_haswell = 0x00100208,
/** Intel Broadwell microarchitecture. */
cpuinfo_uarch_broadwell = 0x00100209,
/** Intel Sky Lake microarchitecture (14 nm, including Kaby/Coffee/Whiskey/Amber/Comet/Cascade/Cooper Lake). */
cpuinfo_uarch_sky_lake = 0x0010020A,
/** DEPRECATED (Intel Kaby Lake microarchitecture). */
cpuinfo_uarch_kaby_lake = 0x0010020A,
/** Intel Palm Cove microarchitecture (10 nm, Cannon Lake). */
cpuinfo_uarch_palm_cove = 0x0010020B,
/** Intel Sunny Cove microarchitecture (10 nm, Ice Lake). */
cpuinfo_uarch_sunny_cove = 0x0010020C,
/** Pentium 4 with Willamette, Northwood, or Foster cores. */
cpuinfo_uarch_willamette = 0x00100300,
/** Pentium 4 with Prescott and later cores. */
cpuinfo_uarch_prescott = 0x00100301,
/** Intel Atom on 45 nm process. */
cpuinfo_uarch_bonnell = 0x00100400,
/** Intel Atom on 32 nm process. */
cpuinfo_uarch_saltwell = 0x00100401,
/** Intel Silvermont microarchitecture (22 nm out-of-order Atom). */
cpuinfo_uarch_silvermont = 0x00100402,
/** Intel Airmont microarchitecture (14 nm out-of-order Atom). */
cpuinfo_uarch_airmont = 0x00100403,
/** Intel Goldmont microarchitecture (Denverton, Apollo Lake). */
cpuinfo_uarch_goldmont = 0x00100404,
/** Intel Goldmont Plus microarchitecture (Gemini Lake). */
cpuinfo_uarch_goldmont_plus = 0x00100405,
/** Intel Knights Ferry HPC boards. */
cpuinfo_uarch_knights_ferry = 0x00100500,
/** Intel Knights Corner HPC boards (aka Xeon Phi). */
cpuinfo_uarch_knights_corner = 0x00100501,
/** Intel Knights Landing microarchitecture (second-gen MIC). */
cpuinfo_uarch_knights_landing = 0x00100502,
/** Intel Knights Hill microarchitecture (third-gen MIC). */
cpuinfo_uarch_knights_hill = 0x00100503,
/** Intel Knights Mill Xeon Phi. */
cpuinfo_uarch_knights_mill = 0x00100504,
/** Intel/Marvell XScale series. */
cpuinfo_uarch_xscale = 0x00100600,
/** AMD K5. */
cpuinfo_uarch_k5 = 0x00200100,
/** AMD K6 and alike. */
cpuinfo_uarch_k6 = 0x00200101,
/** AMD Athlon and Duron. */
cpuinfo_uarch_k7 = 0x00200102,
/** AMD Athlon 64, Opteron 64. */
cpuinfo_uarch_k8 = 0x00200103,
/** AMD Family 10h (Barcelona, Istambul, Magny-Cours). */
cpuinfo_uarch_k10 = 0x00200104,
/**
* AMD Bulldozer microarchitecture
* Zambezi FX-series CPUs, Zurich, Valencia and Interlagos Opteron CPUs.
*/
cpuinfo_uarch_bulldozer = 0x00200105,
/**
* AMD Piledriver microarchitecture
* Vishera FX-series CPUs, Trinity and Richland APUs, Delhi, Seoul, Abu Dhabi Opteron CPUs.
*/
cpuinfo_uarch_piledriver = 0x00200106,
/** AMD Steamroller microarchitecture (Kaveri APUs). */
cpuinfo_uarch_steamroller = 0x00200107,
/** AMD Excavator microarchitecture (Carizzo APUs). */
cpuinfo_uarch_excavator = 0x00200108,
/** AMD Zen microarchitecture (12/14 nm Ryzen and EPYC CPUs). */
cpuinfo_uarch_zen = 0x00200109,
/** AMD Zen 2 microarchitecture (7 nm Ryzen and EPYC CPUs). */
cpuinfo_uarch_zen2 = 0x0020010A,
/** AMD Zen 3 microarchitecture. */
cpuinfo_uarch_zen3 = 0x0020010B,
/** NSC Geode and AMD Geode GX and LX. */
cpuinfo_uarch_geode = 0x00200200,
/** AMD Bobcat mobile microarchitecture. */
cpuinfo_uarch_bobcat = 0x00200201,
/** AMD Jaguar mobile microarchitecture. */
cpuinfo_uarch_jaguar = 0x00200202,
/** AMD Puma mobile microarchitecture. */
cpuinfo_uarch_puma = 0x00200203,
/** ARM7 series. */
cpuinfo_uarch_arm7 = 0x00300100,
/** ARM9 series. */
cpuinfo_uarch_arm9 = 0x00300101,
/** ARM 1136, ARM 1156, ARM 1176, or ARM 11MPCore. */
cpuinfo_uarch_arm11 = 0x00300102,
/** ARM Cortex-A5. */
cpuinfo_uarch_cortex_a5 = 0x00300205,
/** ARM Cortex-A7. */
cpuinfo_uarch_cortex_a7 = 0x00300207,
/** ARM Cortex-A8. */
cpuinfo_uarch_cortex_a8 = 0x00300208,
/** ARM Cortex-A9. */
cpuinfo_uarch_cortex_a9 = 0x00300209,
/** ARM Cortex-A12. */
cpuinfo_uarch_cortex_a12 = 0x00300212,
/** ARM Cortex-A15. */
cpuinfo_uarch_cortex_a15 = 0x00300215,
/** ARM Cortex-A17. */
cpuinfo_uarch_cortex_a17 = 0x00300217,
/** ARM Cortex-A32. */
cpuinfo_uarch_cortex_a32 = 0x00300332,
/** ARM Cortex-A35. */
cpuinfo_uarch_cortex_a35 = 0x00300335,
/** ARM Cortex-A53. */
cpuinfo_uarch_cortex_a53 = 0x00300353,
/** ARM Cortex-A55 revision 0 (restricted dual-issue capabilities compared to revision 1+). */
cpuinfo_uarch_cortex_a55r0 = 0x00300354,
/** ARM Cortex-A55. */
cpuinfo_uarch_cortex_a55 = 0x00300355,
/** ARM Cortex-A57. */
cpuinfo_uarch_cortex_a57 = 0x00300357,
/** ARM Cortex-A65. */
cpuinfo_uarch_cortex_a65 = 0x00300365,
/** ARM Cortex-A72. */
cpuinfo_uarch_cortex_a72 = 0x00300372,
/** ARM Cortex-A73. */
cpuinfo_uarch_cortex_a73 = 0x00300373,
/** ARM Cortex-A75. */
cpuinfo_uarch_cortex_a75 = 0x00300375,
/** ARM Cortex-A76. */
cpuinfo_uarch_cortex_a76 = 0x00300376,
/** ARM Cortex-A77. */
cpuinfo_uarch_cortex_a77 = 0x00300377,
/** ARM Cortex-A78. */
cpuinfo_uarch_cortex_a78 = 0x00300378,
/** ARM Neoverse N1. */
cpuinfo_uarch_neoverse_n1 = 0x00300400,
/** ARM Neoverse E1. */
cpuinfo_uarch_neoverse_e1 = 0x00300401,
/** ARM Cortex-X1. */
cpuinfo_uarch_cortex_x1 = 0x00300500,
/** Qualcomm Scorpion. */
cpuinfo_uarch_scorpion = 0x00400100,
/** Qualcomm Krait. */
cpuinfo_uarch_krait = 0x00400101,
/** Qualcomm Kryo. */
cpuinfo_uarch_kryo = 0x00400102,
/** Qualcomm Falkor. */
cpuinfo_uarch_falkor = 0x00400103,
/** Qualcomm Saphira. */
cpuinfo_uarch_saphira = 0x00400104,
/** Nvidia Denver. */
cpuinfo_uarch_denver = 0x00500100,
/** Nvidia Denver 2. */
cpuinfo_uarch_denver2 = 0x00500101,
/** Nvidia Carmel. */
cpuinfo_uarch_carmel = 0x00500102,
/** Samsung Exynos M1 (Exynos 8890 big cores). */
cpuinfo_uarch_exynos_m1 = 0x00600100,
/** Samsung Exynos M2 (Exynos 8895 big cores). */
cpuinfo_uarch_exynos_m2 = 0x00600101,
/** Samsung Exynos M3 (Exynos 9810 big cores). */
cpuinfo_uarch_exynos_m3 = 0x00600102,
/** Samsung Exynos M4 (Exynos 9820 big cores). */
cpuinfo_uarch_exynos_m4 = 0x00600103,
/** Samsung Exynos M5 (Exynos 9830 big cores). */
cpuinfo_uarch_exynos_m5 = 0x00600104,
/* Deprecated synonym for Cortex-A76 */
cpuinfo_uarch_cortex_a76ae = 0x00300376,
/* Deprecated names for Exynos. */
cpuinfo_uarch_mongoose_m1 = 0x00600100,
cpuinfo_uarch_mongoose_m2 = 0x00600101,
cpuinfo_uarch_meerkat_m3 = 0x00600102,
cpuinfo_uarch_meerkat_m4 = 0x00600103,
/** Apple A6 and A6X processors. */
cpuinfo_uarch_swift = 0x00700100,
/** Apple A7 processor. */
cpuinfo_uarch_cyclone = 0x00700101,
/** Apple A8 and A8X processor. */
cpuinfo_uarch_typhoon = 0x00700102,
/** Apple A9 and A9X processor. */
cpuinfo_uarch_twister = 0x00700103,
/** Apple A10 and A10X processor. */
cpuinfo_uarch_hurricane = 0x00700104,
/** Apple A11 processor (big cores). */
cpuinfo_uarch_monsoon = 0x00700105,
/** Apple A11 processor (little cores). */
cpuinfo_uarch_mistral = 0x00700106,
/** Apple A12 processor (big cores). */
cpuinfo_uarch_vortex = 0x00700107,
/** Apple A12 processor (little cores). */
cpuinfo_uarch_tempest = 0x00700108,
/** Apple A13 processor (big cores). */
cpuinfo_uarch_lightning = 0x00700109,
/** Apple A13 processor (little cores). */
cpuinfo_uarch_thunder = 0x0070010A,
/** Apple M1 processor (big cores). */
cpuinfo_uarch_firestorm = 0x0070010B,
/** Apple M1 processor (little cores). */
cpuinfo_uarch_icestorm = 0x0070010C,
/** Cavium ThunderX. */
cpuinfo_uarch_thunderx = 0x00800100,
/** Cavium ThunderX2 (originally Broadcom Vulkan). */
cpuinfo_uarch_thunderx2 = 0x00800200,
/** Marvell PJ4. */
cpuinfo_uarch_pj4 = 0x00900100,
/** Broadcom Brahma B15. */
cpuinfo_uarch_brahma_b15 = 0x00A00100,
/** Broadcom Brahma B53. */
cpuinfo_uarch_brahma_b53 = 0x00A00101,
/** Applied Micro X-Gene. */
cpuinfo_uarch_xgene = 0x00B00100,
/* Hygon Dhyana (a modification of AMD Zen for Chinese market). */
cpuinfo_uarch_dhyana = 0x01000100,
/** HiSilicon TaiShan v110 (Huawei Kunpeng 920 series processors). */
cpuinfo_uarch_taishan_v110 = 0x00C00100,
};
struct cpuinfo_processor {
/** SMT (hyperthread) ID within a core */
uint32_t smt_id;
/** Core containing this logical processor */
const struct cpuinfo_core* core;
/** Cluster of cores containing this logical processor */
const struct cpuinfo_cluster* cluster;
/** Physical package containing this logical processor */
const struct cpuinfo_package* package;
#if defined(__linux__)
/**
* Linux-specific ID for the logical processor:
* - Linux kernel exposes information about this logical processor in /sys/devices/system/cpu/cpu<linux_id>/
* - Bit <linux_id> in the cpu_set_t identifies this logical processor
*/
int linux_id;
#endif
#if defined(_WIN32) || defined(__CYGWIN__)
/** Windows-specific ID for the group containing the logical processor. */
uint16_t windows_group_id;
/**
* Windows-specific ID of the logical processor within its group:
* - Bit <windows_processor_id> in the KAFFINITY mask identifies this logical processor within its group.
*/
uint16_t windows_processor_id;
#endif
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
/** APIC ID (unique x86-specific ID of the logical processor) */
uint32_t apic_id;
#endif
struct {
/** Level 1 instruction cache */
const struct cpuinfo_cache* l1i;
/** Level 1 data cache */
const struct cpuinfo_cache* l1d;
/** Level 2 unified or data cache */
const struct cpuinfo_cache* l2;
/** Level 3 unified or data cache */
const struct cpuinfo_cache* l3;
/** Level 4 unified or data cache */
const struct cpuinfo_cache* l4;
} cache;
};
struct cpuinfo_core {
/** Index of the first logical processor on this core. */
uint32_t processor_start;
/** Number of logical processors on this core */
uint32_t processor_count;
/** Core ID within a package */
uint32_t core_id;
/** Cluster containing this core */
const struct cpuinfo_cluster* cluster;
/** Physical package containing this core. */
const struct cpuinfo_package* package;
/** Vendor of the CPU microarchitecture for this core */
enum cpuinfo_vendor vendor;
/** CPU microarchitecture for this core */
enum cpuinfo_uarch uarch;
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
/** Value of CPUID leaf 1 EAX register for this core */
uint32_t cpuid;
#elif CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
/** Value of Main ID Register (MIDR) for this core */
uint32_t midr;
#endif
/** Clock rate (non-Turbo) of the core, in Hz */
uint64_t frequency;
};
struct cpuinfo_cluster {
/** Index of the first logical processor in the cluster */
uint32_t processor_start;
/** Number of logical processors in the cluster */
uint32_t processor_count;
/** Index of the first core in the cluster */
uint32_t core_start;
/** Number of cores on the cluster */
uint32_t core_count;
/** Cluster ID within a package */
uint32_t cluster_id;
/** Physical package containing the cluster */
const struct cpuinfo_package* package;
/** CPU microarchitecture vendor of the cores in the cluster */
enum cpuinfo_vendor vendor;
/** CPU microarchitecture of the cores in the cluster */
enum cpuinfo_uarch uarch;
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
/** Value of CPUID leaf 1 EAX register of the cores in the cluster */
uint32_t cpuid;
#elif CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
/** Value of Main ID Register (MIDR) of the cores in the cluster */
uint32_t midr;
#endif
/** Clock rate (non-Turbo) of the cores in the cluster, in Hz */
uint64_t frequency;
};
#define CPUINFO_PACKAGE_NAME_MAX 48
struct cpuinfo_package {
/** SoC or processor chip model name */
char name[CPUINFO_PACKAGE_NAME_MAX];
/** Index of the first logical processor on this physical package */
uint32_t processor_start;
/** Number of logical processors on this physical package */
uint32_t processor_count;
/** Index of the first core on this physical package */
uint32_t core_start;
/** Number of cores on this physical package */
uint32_t core_count;
/** Index of the first cluster of cores on this physical package */
uint32_t cluster_start;
/** Number of clusters of cores on this physical package */
uint32_t cluster_count;
};
struct cpuinfo_uarch_info {
/** Type of CPU microarchitecture */
enum cpuinfo_uarch uarch;
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
/** Value of CPUID leaf 1 EAX register for the microarchitecture */
uint32_t cpuid;
#elif CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
/** Value of Main ID Register (MIDR) for the microarchitecture */
uint32_t midr;
#endif
/** Number of logical processors with the microarchitecture */
uint32_t processor_count;
/** Number of cores with the microarchitecture */
uint32_t core_count;
};
#ifdef __cplusplus
extern "C" {
#endif
bool CPUINFO_ABI cpuinfo_initialize(void);
void CPUINFO_ABI cpuinfo_deinitialize(void);
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
/* This structure is not a part of stable API. Use cpuinfo_has_x86_* functions instead. */
struct cpuinfo_x86_isa {
#if CPUINFO_ARCH_X86
bool rdtsc;
#endif
bool rdtscp;
bool rdpid;
bool sysenter;
#if CPUINFO_ARCH_X86
bool syscall;
#endif
bool msr;
bool clzero;
bool clflush;
bool clflushopt;
bool mwait;
bool mwaitx;
#if CPUINFO_ARCH_X86
bool emmx;
#endif
bool fxsave;
bool xsave;
#if CPUINFO_ARCH_X86
bool fpu;
bool mmx;
bool mmx_plus;
#endif
bool three_d_now;
bool three_d_now_plus;
#if CPUINFO_ARCH_X86
bool three_d_now_geode;
#endif
bool prefetch;
bool prefetchw;
bool prefetchwt1;
#if CPUINFO_ARCH_X86
bool daz;
bool sse;
bool sse2;
#endif
bool sse3;
bool ssse3;
bool sse4_1;
bool sse4_2;
bool sse4a;
bool misaligned_sse;
bool avx;
bool fma3;
bool fma4;
bool xop;
bool f16c;
bool avx2;
bool avx512f;
bool avx512pf;
bool avx512er;
bool avx512cd;
bool avx512dq;
bool avx512bw;
bool avx512vl;
bool avx512ifma;
bool avx512vbmi;
bool avx512vbmi2;
bool avx512bitalg;
bool avx512vpopcntdq;
bool avx512vnni;
bool avx512bf16;
bool avx512vp2intersect;
bool avx512_4vnniw;
bool avx512_4fmaps;
bool hle;
bool rtm;
bool xtest;
bool mpx;
#if CPUINFO_ARCH_X86
bool cmov;
bool cmpxchg8b;
#endif
bool cmpxchg16b;
bool clwb;
bool movbe;
#if CPUINFO_ARCH_X86_64
bool lahf_sahf;
#endif
bool fs_gs_base;
bool lzcnt;
bool popcnt;
bool tbm;
bool bmi;
bool bmi2;
bool adx;
bool aes;
bool vaes;
bool pclmulqdq;
bool vpclmulqdq;
bool gfni;
bool rdrand;
bool rdseed;
bool sha;
bool rng;
bool ace;
bool ace2;
bool phe;
bool pmm;
bool lwp;
};
extern struct cpuinfo_x86_isa cpuinfo_isa;
#endif
static inline bool cpuinfo_has_x86_rdtsc(void) {
#if CPUINFO_ARCH_X86_64
return true;
#elif CPUINFO_ARCH_X86
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.rdtsc;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_rdtscp(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.rdtscp;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_rdpid(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.rdpid;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_clzero(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.clzero;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_mwait(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.mwait;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_mwaitx(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.mwaitx;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_fxsave(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.fxsave;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_xsave(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.xsave;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_fpu(void) {
#if CPUINFO_ARCH_X86_64
return true;
#elif CPUINFO_ARCH_X86
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.fpu;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_mmx(void) {
#if CPUINFO_ARCH_X86_64
return true;
#elif CPUINFO_ARCH_X86
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.mmx;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_mmx_plus(void) {
#if CPUINFO_ARCH_X86_64
return true;
#elif CPUINFO_ARCH_X86
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.mmx_plus;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_3dnow(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.three_d_now;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_3dnow_plus(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.three_d_now_plus;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_3dnow_geode(void) {
#if CPUINFO_ARCH_X86_64
return false;
#elif CPUINFO_ARCH_X86
#if defined(__ANDROID__)
return false;
#else
return cpuinfo_isa.three_d_now_geode;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_prefetch(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.prefetch;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_prefetchw(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.prefetchw;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_prefetchwt1(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.prefetchwt1;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_daz(void) {
#if CPUINFO_ARCH_X86_64
return true;
#elif CPUINFO_ARCH_X86
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.daz;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_sse(void) {
#if CPUINFO_ARCH_X86_64
return true;
#elif CPUINFO_ARCH_X86
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.sse;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_sse2(void) {
#if CPUINFO_ARCH_X86_64
return true;
#elif CPUINFO_ARCH_X86
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.sse2;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_sse3(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.sse3;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_ssse3(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.ssse3;
#endif
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_sse4_1(void) {
#if CPUINFO_ARCH_X86_64
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.sse4_1;
#endif
#elif CPUINFO_ARCH_X86
return cpuinfo_isa.sse4_1;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_sse4_2(void) {
#if CPUINFO_ARCH_X86_64
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.sse4_2;
#endif
#elif CPUINFO_ARCH_X86
return cpuinfo_isa.sse4_2;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_sse4a(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.sse4a;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_misaligned_sse(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.misaligned_sse;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_fma3(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.fma3;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_fma4(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.fma4;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_xop(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.xop;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_f16c(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.f16c;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx2(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx2;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512f(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512f;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512pf(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512pf;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512er(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512er;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512cd(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512cd;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512dq(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512dq;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512bw(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512bw;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512vl(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512vl;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512ifma(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512ifma;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512vbmi(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512vbmi;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512vbmi2(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512vbmi2;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512bitalg(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512bitalg;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512vpopcntdq(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512vpopcntdq;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512vnni(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512vnni;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512bf16(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512bf16;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512vp2intersect(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512vp2intersect;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512_4vnniw(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512_4vnniw;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_avx512_4fmaps(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.avx512_4fmaps;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_hle(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.hle;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_rtm(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.rtm;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_xtest(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.xtest;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_mpx(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.mpx;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_cmov(void) {
#if CPUINFO_ARCH_X86_64
return true;
#elif CPUINFO_ARCH_X86
return cpuinfo_isa.cmov;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_cmpxchg8b(void) {
#if CPUINFO_ARCH_X86_64
return true;
#elif CPUINFO_ARCH_X86
return cpuinfo_isa.cmpxchg8b;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_cmpxchg16b(void) {
#if CPUINFO_ARCH_X86_64
return cpuinfo_isa.cmpxchg16b;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_clwb(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.clwb;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_movbe(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.movbe;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_lahf_sahf(void) {
#if CPUINFO_ARCH_X86
return true;
#elif CPUINFO_ARCH_X86_64
return cpuinfo_isa.lahf_sahf;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_lzcnt(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.lzcnt;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_popcnt(void) {
#if CPUINFO_ARCH_X86_64
#if defined(__ANDROID__)
return true;
#else
return cpuinfo_isa.popcnt;
#endif
#elif CPUINFO_ARCH_X86
return cpuinfo_isa.popcnt;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_tbm(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.tbm;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_bmi(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.bmi;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_bmi2(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.bmi2;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_adx(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.adx;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_aes(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.aes;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_vaes(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.vaes;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_pclmulqdq(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.pclmulqdq;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_vpclmulqdq(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.vpclmulqdq;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_gfni(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.gfni;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_rdrand(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.rdrand;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_rdseed(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.rdseed;
#else
return false;
#endif
}
static inline bool cpuinfo_has_x86_sha(void) {
#if CPUINFO_ARCH_X86 || CPUINFO_ARCH_X86_64
return cpuinfo_isa.sha;
#else
return false;
#endif
}
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
/* This structure is not a part of stable API. Use cpuinfo_has_arm_* functions instead. */
struct cpuinfo_arm_isa {
#if CPUINFO_ARCH_ARM
bool thumb;
bool thumb2;
bool thumbee;
bool jazelle;
bool armv5e;
bool armv6;
bool armv6k;
bool armv7;
bool armv7mp;
bool armv8;
bool idiv;
bool vfpv2;
bool vfpv3;
bool d32;
bool fp16;
bool fma;
bool wmmx;
bool wmmx2;
bool neon;
#endif
#if CPUINFO_ARCH_ARM64
bool atomics;
bool sve;
bool sve2;
#endif
bool rdm;
bool fp16arith;
bool dot;
bool jscvt;
bool fcma;
bool aes;
bool sha1;
bool sha2;
bool pmull;
bool crc32;
};
extern struct cpuinfo_arm_isa cpuinfo_isa;
#endif
static inline bool cpuinfo_has_arm_thumb(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.thumb;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_thumb2(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.thumb2;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_v5e(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.armv5e;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_v6(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.armv6;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_v6k(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.armv6k;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_v7(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.armv7;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_v7mp(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.armv7mp;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_v8(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.armv8;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_idiv(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.idiv;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_vfpv2(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.vfpv2;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_vfpv3(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.vfpv3;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_vfpv3_d32(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.vfpv3 && cpuinfo_isa.d32;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_vfpv3_fp16(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.vfpv3 && cpuinfo_isa.fp16;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_vfpv3_fp16_d32(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.vfpv3 && cpuinfo_isa.fp16 && cpuinfo_isa.d32;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_vfpv4(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.vfpv3 && cpuinfo_isa.fma;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_vfpv4_d32(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.vfpv3 && cpuinfo_isa.fma && cpuinfo_isa.d32;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_wmmx(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.wmmx;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_wmmx2(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.wmmx2;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_neon(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.neon;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_neon_fp16(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.neon && cpuinfo_isa.fp16;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_neon_fma(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.neon && cpuinfo_isa.fma;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_neon_v8(void) {
#if CPUINFO_ARCH_ARM64
return true;
#elif CPUINFO_ARCH_ARM
return cpuinfo_isa.neon && cpuinfo_isa.armv8;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_atomics(void) {
#if CPUINFO_ARCH_ARM64
return cpuinfo_isa.atomics;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_neon_rdm(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.rdm;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_neon_fp16_arith(void) {
#if CPUINFO_ARCH_ARM
return cpuinfo_isa.neon && cpuinfo_isa.fp16arith;
#elif CPUINFO_ARCH_ARM64
return cpuinfo_isa.fp16arith;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_fp16_arith(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.fp16arith;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_neon_dot(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.dot;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_jscvt(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.jscvt;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_fcma(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.fcma;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_aes(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.aes;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_sha1(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.sha1;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_sha2(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.sha2;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_pmull(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.pmull;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_crc32(void) {
#if CPUINFO_ARCH_ARM || CPUINFO_ARCH_ARM64
return cpuinfo_isa.crc32;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_sve(void) {
#if CPUINFO_ARCH_ARM64
return cpuinfo_isa.sve;
#else
return false;
#endif
}
static inline bool cpuinfo_has_arm_sve2(void) {
#if CPUINFO_ARCH_ARM64
return cpuinfo_isa.sve2;
#else
return false;
#endif
}
const struct cpuinfo_processor* CPUINFO_ABI cpuinfo_get_processors(void);
const struct cpuinfo_core* CPUINFO_ABI cpuinfo_get_cores(void);
const struct cpuinfo_cluster* CPUINFO_ABI cpuinfo_get_clusters(void);
const struct cpuinfo_package* CPUINFO_ABI cpuinfo_get_packages(void);
const struct cpuinfo_uarch_info* CPUINFO_ABI cpuinfo_get_uarchs(void);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l1i_caches(void);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l1d_caches(void);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l2_caches(void);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l3_caches(void);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l4_caches(void);
const struct cpuinfo_processor* CPUINFO_ABI cpuinfo_get_processor(uint32_t index);
const struct cpuinfo_core* CPUINFO_ABI cpuinfo_get_core(uint32_t index);
const struct cpuinfo_cluster* CPUINFO_ABI cpuinfo_get_cluster(uint32_t index);
const struct cpuinfo_package* CPUINFO_ABI cpuinfo_get_package(uint32_t index);
const struct cpuinfo_uarch_info* CPUINFO_ABI cpuinfo_get_uarch(uint32_t index);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l1i_cache(uint32_t index);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l1d_cache(uint32_t index);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l2_cache(uint32_t index);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l3_cache(uint32_t index);
const struct cpuinfo_cache* CPUINFO_ABI cpuinfo_get_l4_cache(uint32_t index);
uint32_t CPUINFO_ABI cpuinfo_get_processors_count(void);
uint32_t CPUINFO_ABI cpuinfo_get_cores_count(void);
uint32_t CPUINFO_ABI cpuinfo_get_clusters_count(void);
uint32_t CPUINFO_ABI cpuinfo_get_packages_count(void);
uint32_t CPUINFO_ABI cpuinfo_get_uarchs_count(void);
uint32_t CPUINFO_ABI cpuinfo_get_l1i_caches_count(void);
uint32_t CPUINFO_ABI cpuinfo_get_l1d_caches_count(void);
uint32_t CPUINFO_ABI cpuinfo_get_l2_caches_count(void);
uint32_t CPUINFO_ABI cpuinfo_get_l3_caches_count(void);
uint32_t CPUINFO_ABI cpuinfo_get_l4_caches_count(void);
/**
* Returns upper bound on cache size.
*/
uint32_t CPUINFO_ABI cpuinfo_get_max_cache_size(void);
/**
* Identify the logical processor that executes the current thread.
*
* There is no guarantee that the thread will stay on the same logical processor for any time.
* Callers should treat the result as only a hint, and be prepared to handle NULL return value.
*/
const struct cpuinfo_processor* CPUINFO_ABI cpuinfo_get_current_processor(void);
/**
* Identify the core that executes the current thread.
*
* There is no guarantee that the thread will stay on the same core for any time.
* Callers should treat the result as only a hint, and be prepared to handle NULL return value.
*/
const struct cpuinfo_core* CPUINFO_ABI cpuinfo_get_current_core(void);
/**
* Identify the microarchitecture index of the core that executes the current thread.
* If the system does not support such identification, the function returns 0.
*
* There is no guarantee that the thread will stay on the same type of core for any time.
* Callers should treat the result as only a hint.
*/
uint32_t CPUINFO_ABI cpuinfo_get_current_uarch_index(void);
/**
* Identify the microarchitecture index of the core that executes the current thread.
* If the system does not support such identification, the function returns the user-specified default value.
*
* There is no guarantee that the thread will stay on the same type of core for any time.
* Callers should treat the result as only a hint.
*/
uint32_t CPUINFO_ABI cpuinfo_get_current_uarch_index_with_default(uint32_t default_uarch_index);
#ifdef __cplusplus
} /* extern "C" */
#endif
#endif /* CPUINFO_H */