//===-- X86TargetParser - Parser for X86 features ---------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file implements a target parser to recognise X86 hardware features. // //===----------------------------------------------------------------------===// #include "llvm/TargetParser/X86TargetParser.h" #include "llvm/ADT/Bitset.h" #include "llvm/ADT/StringSwitch.h" #include using namespace llvm; using namespace llvm::X86; namespace { using FeatureBitset = Bitset; struct ProcInfo { StringLiteral Name; X86::CPUKind Kind; unsigned KeyFeature; FeatureBitset Features; char Mangling; bool OnlyForCPUDispatchSpecific; }; struct FeatureInfo { StringLiteral NameWithPlus; FeatureBitset ImpliedFeatures; StringRef getName(bool WithPlus = false) const { assert(NameWithPlus[0] == '+' && "Expected string to start with '+'"); if (WithPlus) return NameWithPlus; return NameWithPlus.drop_front(); } }; } // end anonymous namespace #define X86_FEATURE(ENUM, STRING) \ constexpr FeatureBitset Feature##ENUM = {X86::FEATURE_##ENUM}; #include "llvm/TargetParser/X86TargetParser.def" // Pentium with MMX. constexpr FeatureBitset FeaturesPentiumMMX = FeatureX87 | FeatureCMPXCHG8B | FeatureMMX; // Pentium 2 and 3. constexpr FeatureBitset FeaturesPentium2 = FeatureX87 | FeatureCMPXCHG8B | FeatureMMX | FeatureFXSR | FeatureCMOV; constexpr FeatureBitset FeaturesPentium3 = FeaturesPentium2 | FeatureSSE; // Pentium 4 CPUs constexpr FeatureBitset FeaturesPentium4 = FeaturesPentium3 | FeatureSSE2; constexpr FeatureBitset FeaturesPrescott = FeaturesPentium4 | FeatureSSE3; constexpr FeatureBitset FeaturesNocona = FeaturesPrescott | Feature64BIT | FeatureCMPXCHG16B; // Basic 64-bit capable CPU. constexpr FeatureBitset FeaturesX86_64 = FeaturesPentium4 | Feature64BIT; constexpr FeatureBitset FeaturesX86_64_V2 = FeaturesX86_64 | FeatureSAHF | FeaturePOPCNT | FeatureCRC32 | FeatureSSE4_2 | FeatureCMPXCHG16B; constexpr FeatureBitset FeaturesX86_64_V3 = FeaturesX86_64_V2 | FeatureAVX2 | FeatureBMI | FeatureBMI2 | FeatureF16C | FeatureFMA | FeatureLZCNT | FeatureMOVBE | FeatureXSAVE; constexpr FeatureBitset FeaturesX86_64_V4 = FeaturesX86_64_V3 | FeatureEVEX512 | FeatureAVX512BW | FeatureAVX512CD | FeatureAVX512DQ | FeatureAVX512VL; // Intel Core CPUs constexpr FeatureBitset FeaturesCore2 = FeaturesNocona | FeatureSAHF | FeatureSSSE3; constexpr FeatureBitset FeaturesPenryn = FeaturesCore2 | FeatureSSE4_1; constexpr FeatureBitset FeaturesNehalem = FeaturesPenryn | FeaturePOPCNT | FeatureCRC32 | FeatureSSE4_2; constexpr FeatureBitset FeaturesWestmere = FeaturesNehalem | FeaturePCLMUL; constexpr FeatureBitset FeaturesSandyBridge = FeaturesWestmere | FeatureAVX | FeatureXSAVE | FeatureXSAVEOPT; constexpr FeatureBitset FeaturesIvyBridge = FeaturesSandyBridge | FeatureF16C | FeatureFSGSBASE | FeatureRDRND; constexpr FeatureBitset FeaturesHaswell = FeaturesIvyBridge | FeatureAVX2 | FeatureBMI | FeatureBMI2 | FeatureFMA | FeatureINVPCID | FeatureLZCNT | FeatureMOVBE; constexpr FeatureBitset FeaturesBroadwell = FeaturesHaswell | FeatureADX | FeaturePRFCHW | FeatureRDSEED; // Intel Knights Landing and Knights Mill // Knights Landing has feature parity with Broadwell. constexpr FeatureBitset FeaturesKNL = FeaturesBroadwell | FeatureAES | FeatureAVX512F | FeatureEVEX512 | FeatureAVX512CD; constexpr FeatureBitset FeaturesKNM = FeaturesKNL | FeatureAVX512VPOPCNTDQ; // Intel Skylake processors. constexpr FeatureBitset FeaturesSkylakeClient = FeaturesBroadwell | FeatureAES | FeatureCLFLUSHOPT | FeatureXSAVEC | FeatureXSAVES | FeatureSGX; // SkylakeServer inherits all SkylakeClient features except SGX. // FIXME: That doesn't match gcc. constexpr FeatureBitset FeaturesSkylakeServer = (FeaturesSkylakeClient & ~FeatureSGX) | FeatureAVX512F | FeatureEVEX512 | FeatureAVX512CD | FeatureAVX512DQ | FeatureAVX512BW | FeatureAVX512VL | FeatureCLWB | FeaturePKU; constexpr FeatureBitset FeaturesCascadeLake = FeaturesSkylakeServer | FeatureAVX512VNNI; constexpr FeatureBitset FeaturesCooperLake = FeaturesCascadeLake | FeatureAVX512BF16; // Intel 10nm processors. constexpr FeatureBitset FeaturesCannonlake = FeaturesSkylakeClient | FeatureAVX512F | FeatureEVEX512 | FeatureAVX512CD | FeatureAVX512DQ | FeatureAVX512BW | FeatureAVX512VL | FeatureAVX512IFMA | FeatureAVX512VBMI | FeaturePKU | FeatureSHA; constexpr FeatureBitset FeaturesICLClient = FeaturesCannonlake | FeatureAVX512BITALG | FeatureAVX512VBMI2 | FeatureAVX512VNNI | FeatureAVX512VPOPCNTDQ | FeatureGFNI | FeatureRDPID | FeatureVAES | FeatureVPCLMULQDQ; constexpr FeatureBitset FeaturesRocketlake = FeaturesICLClient & ~FeatureSGX; constexpr FeatureBitset FeaturesICLServer = FeaturesICLClient | FeatureCLWB | FeaturePCONFIG | FeatureWBNOINVD; constexpr FeatureBitset FeaturesTigerlake = FeaturesICLClient | FeatureAVX512VP2INTERSECT | FeatureMOVDIR64B | FeatureCLWB | FeatureMOVDIRI | FeatureSHSTK | FeatureKL | FeatureWIDEKL; constexpr FeatureBitset FeaturesSapphireRapids = FeaturesICLServer | FeatureAMX_BF16 | FeatureAMX_INT8 | FeatureAMX_TILE | FeatureAVX512BF16 | FeatureAVX512FP16 | FeatureAVXVNNI | FeatureCLDEMOTE | FeatureENQCMD | FeatureMOVDIR64B | FeatureMOVDIRI | FeaturePTWRITE | FeatureSERIALIZE | FeatureSHSTK | FeatureTSXLDTRK | FeatureUINTR | FeatureWAITPKG; constexpr FeatureBitset FeaturesGraniteRapids = FeaturesSapphireRapids | FeatureAMX_FP16 | FeaturePREFETCHI; // Intel Atom processors. // Bonnell has feature parity with Core2 and adds MOVBE. constexpr FeatureBitset FeaturesBonnell = FeaturesCore2 | FeatureMOVBE; // Silvermont has parity with Westmere and Bonnell plus PRFCHW and RDRND. constexpr FeatureBitset FeaturesSilvermont = FeaturesBonnell | FeaturesWestmere | FeaturePRFCHW | FeatureRDRND; constexpr FeatureBitset FeaturesGoldmont = FeaturesSilvermont | FeatureAES | FeatureCLFLUSHOPT | FeatureFSGSBASE | FeatureRDSEED | FeatureSHA | FeatureXSAVE | FeatureXSAVEC | FeatureXSAVEOPT | FeatureXSAVES; constexpr FeatureBitset FeaturesGoldmontPlus = FeaturesGoldmont | FeaturePTWRITE | FeatureRDPID | FeatureSGX; constexpr FeatureBitset FeaturesTremont = FeaturesGoldmontPlus | FeatureCLWB | FeatureGFNI; constexpr FeatureBitset FeaturesAlderlake = FeaturesTremont | FeatureADX | FeatureBMI | FeatureBMI2 | FeatureF16C | FeatureFMA | FeatureINVPCID | FeatureLZCNT | FeaturePCONFIG | FeaturePKU | FeatureSERIALIZE | FeatureSHSTK | FeatureVAES | FeatureVPCLMULQDQ | FeatureCLDEMOTE | FeatureMOVDIR64B | FeatureMOVDIRI | FeatureWAITPKG | FeatureAVXVNNI | FeatureHRESET | FeatureWIDEKL; constexpr FeatureBitset FeaturesSierraforest = FeaturesAlderlake | FeatureCMPCCXADD | FeatureAVXIFMA | FeatureUINTR | FeatureENQCMD | FeatureAVXNECONVERT | FeatureAVXVNNIINT8; constexpr FeatureBitset FeaturesArrowlakeS = FeaturesSierraforest | FeatureAVXVNNIINT16 | FeatureSHA512 | FeatureSM3 | FeatureSM4; constexpr FeatureBitset FeaturesPantherlake = FeaturesArrowlakeS | FeaturePREFETCHI; constexpr FeatureBitset FeaturesClearwaterforest = FeaturesArrowlakeS | FeatureUSERMSR | FeaturePREFETCHI; // Geode Processor. constexpr FeatureBitset FeaturesGeode = FeatureX87 | FeatureCMPXCHG8B | FeatureMMX | FeaturePRFCHW; // K6 processor. constexpr FeatureBitset FeaturesK6 = FeatureX87 | FeatureCMPXCHG8B | FeatureMMX; // K7 and K8 architecture processors. constexpr FeatureBitset FeaturesAthlon = FeatureX87 | FeatureCMPXCHG8B | FeatureMMX | FeaturePRFCHW; constexpr FeatureBitset FeaturesAthlonXP = FeaturesAthlon | FeatureFXSR | FeatureSSE; constexpr FeatureBitset FeaturesK8 = FeaturesAthlonXP | FeatureSSE2 | Feature64BIT; constexpr FeatureBitset FeaturesK8SSE3 = FeaturesK8 | FeatureSSE3; constexpr FeatureBitset FeaturesAMDFAM10 = FeaturesK8SSE3 | FeatureCMPXCHG16B | FeatureLZCNT | FeaturePOPCNT | FeaturePRFCHW | FeatureSAHF | FeatureSSE4_A; // Bobcat architecture processors. constexpr FeatureBitset FeaturesBTVER1 = FeatureX87 | FeatureCMPXCHG8B | FeatureCMPXCHG16B | Feature64BIT | FeatureFXSR | FeatureLZCNT | FeatureMMX | FeaturePOPCNT | FeaturePRFCHW | FeatureSSE | FeatureSSE2 | FeatureSSE3 | FeatureSSSE3 | FeatureSSE4_A | FeatureSAHF; constexpr FeatureBitset FeaturesBTVER2 = FeaturesBTVER1 | FeatureAES | FeatureAVX | FeatureBMI | FeatureCRC32 | FeatureF16C | FeatureMOVBE | FeaturePCLMUL | FeatureXSAVE | FeatureXSAVEOPT; // AMD Bulldozer architecture processors. constexpr FeatureBitset FeaturesBDVER1 = FeatureX87 | FeatureAES | FeatureAVX | FeatureCMPXCHG8B | FeatureCMPXCHG16B | FeatureCRC32 | Feature64BIT | FeatureFMA4 | FeatureFXSR | FeatureLWP | FeatureLZCNT | FeatureMMX | FeaturePCLMUL | FeaturePOPCNT | FeaturePRFCHW | FeatureSAHF | FeatureSSE | FeatureSSE2 | FeatureSSE3 | FeatureSSSE3 | FeatureSSE4_1 | FeatureSSE4_2 | FeatureSSE4_A | FeatureXOP | FeatureXSAVE; constexpr FeatureBitset FeaturesBDVER2 = FeaturesBDVER1 | FeatureBMI | FeatureFMA | FeatureF16C | FeatureTBM; constexpr FeatureBitset FeaturesBDVER3 = FeaturesBDVER2 | FeatureFSGSBASE | FeatureXSAVEOPT; constexpr FeatureBitset FeaturesBDVER4 = FeaturesBDVER3 | FeatureAVX2 | FeatureBMI2 | FeatureMOVBE | FeatureMWAITX | FeatureRDRND; // AMD Zen architecture processors. constexpr FeatureBitset FeaturesZNVER1 = FeatureX87 | FeatureADX | FeatureAES | FeatureAVX | FeatureAVX2 | FeatureBMI | FeatureBMI2 | FeatureCLFLUSHOPT | FeatureCLZERO | FeatureCMPXCHG8B | FeatureCMPXCHG16B | FeatureCRC32 | Feature64BIT | FeatureF16C | FeatureFMA | FeatureFSGSBASE | FeatureFXSR | FeatureLZCNT | FeatureMMX | FeatureMOVBE | FeatureMWAITX | FeaturePCLMUL | FeaturePOPCNT | FeaturePRFCHW | FeatureRDRND | FeatureRDSEED | FeatureSAHF | FeatureSHA | FeatureSSE | FeatureSSE2 | FeatureSSE3 | FeatureSSSE3 | FeatureSSE4_1 | FeatureSSE4_2 | FeatureSSE4_A | FeatureXSAVE | FeatureXSAVEC | FeatureXSAVEOPT | FeatureXSAVES; constexpr FeatureBitset FeaturesZNVER2 = FeaturesZNVER1 | FeatureCLWB | FeatureRDPID | FeatureRDPRU | FeatureWBNOINVD; static constexpr FeatureBitset FeaturesZNVER3 = FeaturesZNVER2 | FeatureINVPCID | FeaturePKU | FeatureVAES | FeatureVPCLMULQDQ; static constexpr FeatureBitset FeaturesZNVER4 = FeaturesZNVER3 | FeatureAVX512F | FeatureEVEX512 | FeatureAVX512CD | FeatureAVX512DQ | FeatureAVX512BW | FeatureAVX512VL | FeatureAVX512IFMA | FeatureAVX512VBMI | FeatureAVX512VBMI2 | FeatureAVX512VNNI | FeatureAVX512BITALG | FeatureAVX512VPOPCNTDQ | FeatureAVX512BF16 | FeatureGFNI | FeatureSHSTK; static constexpr FeatureBitset FeaturesZNVER5 = FeaturesZNVER4 | FeatureAVXVNNI | FeatureMOVDIRI | FeatureMOVDIR64B | FeatureAVX512VP2INTERSECT | FeaturePREFETCHI | FeatureAVXVNNI; // D151696 tranplanted Mangling and OnlyForCPUDispatchSpecific from // X86TargetParser.def to here. They are assigned by following ways: // 1. Copy the mangling from the original CPU_SPEICIFC MACROs. If no, assign // to '\0' by default, which means not support cpu_specific/dispatch feature. // 2. set OnlyForCPUDispatchSpecific as true if this cpu name was not // listed here before, which means it doesn't support -march, -mtune and so on. // FIXME: Remove OnlyForCPUDispatchSpecific after all CPUs here support both // cpu_dispatch/specific() feature and -march, -mtune, and so on. // clang-format off constexpr ProcInfo Processors[] = { // Empty processor. Include X87 and CMPXCHG8 for backwards compatibility. { {""}, CK_None, ~0U, FeatureX87 | FeatureCMPXCHG8B, '\0', false }, { {"generic"}, CK_None, ~0U, FeatureX87 | FeatureCMPXCHG8B | Feature64BIT, 'A', true }, // i386-generation processors. { {"i386"}, CK_i386, ~0U, FeatureX87, '\0', false }, // i486-generation processors. { {"i486"}, CK_i486, ~0U, FeatureX87, '\0', false }, { {"winchip-c6"}, CK_WinChipC6, ~0U, FeaturesPentiumMMX, '\0', false }, { {"winchip2"}, CK_WinChip2, ~0U, FeaturesPentiumMMX | FeaturePRFCHW, '\0', false }, { {"c3"}, CK_C3, ~0U, FeaturesPentiumMMX | FeaturePRFCHW, '\0', false }, // i586-generation processors, P5 microarchitecture based. { {"i586"}, CK_i586, ~0U, FeatureX87 | FeatureCMPXCHG8B, '\0', false }, { {"pentium"}, CK_Pentium, ~0U, FeatureX87 | FeatureCMPXCHG8B, 'B', false }, { {"pentium-mmx"}, CK_PentiumMMX, ~0U, FeaturesPentiumMMX, '\0', false }, { {"pentium_mmx"}, CK_PentiumMMX, ~0U, FeaturesPentiumMMX, 'D', true }, // i686-generation processors, P6 / Pentium M microarchitecture based. { {"pentiumpro"}, CK_PentiumPro, ~0U, FeatureCMOV | FeatureX87 | FeatureCMPXCHG8B, 'C', false }, { {"pentium_pro"}, CK_PentiumPro, ~0U, FeatureCMOV | FeatureX87 | FeatureCMPXCHG8B, 'C', true }, { {"i686"}, CK_i686, ~0U, FeatureCMOV | FeatureX87 | FeatureCMPXCHG8B, '\0', false }, { {"pentium2"}, CK_Pentium2, ~0U, FeaturesPentium2, 'E', false }, { {"pentium_ii"}, CK_Pentium2, ~0U, FeaturesPentium2, 'E', true }, { {"pentium3"}, CK_Pentium3, ~0U, FeaturesPentium3, 'H', false }, { {"pentium3m"}, CK_Pentium3, ~0U, FeaturesPentium3, 'H', false }, { {"pentium_iii"}, CK_Pentium3, ~0U, FeaturesPentium3, 'H', true }, { {"pentium_iii_no_xmm_regs"}, CK_Pentium3, ~0U, FeaturesPentium3, 'H', true }, { {"pentium-m"}, CK_PentiumM, ~0U, FeaturesPentium4, '\0', false }, { {"pentium_m"}, CK_PentiumM, ~0U, FeaturesPentium4, 'K', true }, { {"c3-2"}, CK_C3_2, ~0U, FeaturesPentium3, '\0', false }, { {"yonah"}, CK_Yonah, ~0U, FeaturesPrescott, 'L', false }, // Netburst microarchitecture based processors. { {"pentium4"}, CK_Pentium4, ~0U, FeaturesPentium4, 'J', false }, { {"pentium4m"}, CK_Pentium4, ~0U, FeaturesPentium4, 'J', false }, { {"pentium_4"}, CK_Pentium4, ~0U, FeaturesPentium4, 'J', true }, { {"pentium_4_sse3"}, CK_Prescott, ~0U, FeaturesPrescott, 'L', true }, { {"prescott"}, CK_Prescott, ~0U, FeaturesPrescott, 'L', false }, { {"nocona"}, CK_Nocona, ~0U, FeaturesNocona, 'L', false }, // Core microarchitecture based processors. { {"core2"}, CK_Core2, FEATURE_SSSE3, FeaturesCore2, 'M', false }, { {"core_2_duo_ssse3"}, CK_Core2, ~0U, FeaturesCore2, 'M', true }, { {"penryn"}, CK_Penryn, ~0U, FeaturesPenryn, 'N', false }, { {"core_2_duo_sse4_1"}, CK_Penryn, ~0U, FeaturesPenryn, 'N', true }, // Atom processors { {"bonnell"}, CK_Bonnell, FEATURE_SSSE3, FeaturesBonnell, 'O', false }, { {"atom"}, CK_Bonnell, FEATURE_SSSE3, FeaturesBonnell, 'O', false }, { {"silvermont"}, CK_Silvermont, FEATURE_SSE4_2, FeaturesSilvermont, 'c', false }, { {"slm"}, CK_Silvermont, FEATURE_SSE4_2, FeaturesSilvermont, 'c', false }, { {"atom_sse4_2"}, CK_Nehalem, FEATURE_SSE4_2, FeaturesNehalem, 'c', true }, { {"atom_sse4_2_movbe"}, CK_Goldmont, FEATURE_SSE4_2, FeaturesGoldmont, 'd', true }, { {"goldmont"}, CK_Goldmont, FEATURE_SSE4_2, FeaturesGoldmont, 'i', false }, { {"goldmont-plus"}, CK_GoldmontPlus, FEATURE_SSE4_2, FeaturesGoldmontPlus, '\0', false }, { {"goldmont_plus"}, CK_GoldmontPlus, FEATURE_SSE4_2, FeaturesGoldmontPlus, 'd', true }, { {"tremont"}, CK_Tremont, FEATURE_SSE4_2, FeaturesTremont, 'd', false }, // Nehalem microarchitecture based processors. { {"nehalem"}, CK_Nehalem, FEATURE_SSE4_2, FeaturesNehalem, 'P', false }, { {"core_i7_sse4_2"}, CK_Nehalem, FEATURE_SSE4_2, FeaturesNehalem, 'P', true }, { {"corei7"}, CK_Nehalem, FEATURE_SSE4_2, FeaturesNehalem, 'P', false }, // Westmere microarchitecture based processors. { {"westmere"}, CK_Westmere, FEATURE_PCLMUL, FeaturesWestmere, 'Q', false }, { {"core_aes_pclmulqdq"}, CK_Nehalem, FEATURE_SSE4_2, FeaturesNehalem, 'Q', true }, // Sandy Bridge microarchitecture based processors. { {"sandybridge"}, CK_SandyBridge, FEATURE_AVX, FeaturesSandyBridge, 'R', false }, { {"core_2nd_gen_avx"}, CK_SandyBridge, FEATURE_AVX, FeaturesSandyBridge, 'R', true }, { {"corei7-avx"}, CK_SandyBridge, FEATURE_AVX, FeaturesSandyBridge, '\0', false }, // Ivy Bridge microarchitecture based processors. { {"ivybridge"}, CK_IvyBridge, FEATURE_AVX, FeaturesIvyBridge, 'S', false }, { {"core_3rd_gen_avx"}, CK_IvyBridge, FEATURE_AVX, FeaturesIvyBridge, 'S', true }, { {"core-avx-i"}, CK_IvyBridge, FEATURE_AVX, FeaturesIvyBridge, '\0', false }, // Haswell microarchitecture based processors. { {"haswell"}, CK_Haswell, FEATURE_AVX2, FeaturesHaswell, 'V', false }, { {"core-avx2"}, CK_Haswell, FEATURE_AVX2, FeaturesHaswell, '\0', false }, { {"core_4th_gen_avx"}, CK_Haswell, FEATURE_AVX2, FeaturesHaswell, 'V', true }, { {"core_4th_gen_avx_tsx"}, CK_Haswell, FEATURE_AVX2, FeaturesHaswell, 'W', true }, // Broadwell microarchitecture based processors. { {"broadwell"}, CK_Broadwell, FEATURE_AVX2, FeaturesBroadwell, 'X', false }, { {"core_5th_gen_avx"}, CK_Broadwell, FEATURE_AVX2, FeaturesBroadwell, 'X', true }, { {"core_5th_gen_avx_tsx"}, CK_Broadwell, FEATURE_AVX2, FeaturesBroadwell, 'Y', true }, // Skylake client microarchitecture based processors. { {"skylake"}, CK_SkylakeClient, FEATURE_AVX2, FeaturesSkylakeClient, 'b', false }, // Skylake server microarchitecture based processors. { {"skylake-avx512"}, CK_SkylakeServer, FEATURE_AVX512F, FeaturesSkylakeServer, '\0', false }, { {"skx"}, CK_SkylakeServer, FEATURE_AVX512F, FeaturesSkylakeServer, 'a', false }, { {"skylake_avx512"}, CK_SkylakeServer, FEATURE_AVX512F, FeaturesSkylakeServer, 'a', true }, // Cascadelake Server microarchitecture based processors. { {"cascadelake"}, CK_Cascadelake, FEATURE_AVX512VNNI, FeaturesCascadeLake, 'o', false }, // Cooperlake Server microarchitecture based processors. { {"cooperlake"}, CK_Cooperlake, FEATURE_AVX512BF16, FeaturesCooperLake, 'f', false }, // Cannonlake client microarchitecture based processors. { {"cannonlake"}, CK_Cannonlake, FEATURE_AVX512VBMI, FeaturesCannonlake, 'e', false }, // Icelake client microarchitecture based processors. { {"icelake-client"}, CK_IcelakeClient, FEATURE_AVX512VBMI2, FeaturesICLClient, '\0', false }, { {"icelake_client"}, CK_IcelakeClient, FEATURE_AVX512VBMI2, FeaturesICLClient, 'k', true }, // Rocketlake microarchitecture based processors. { {"rocketlake"}, CK_Rocketlake, FEATURE_AVX512VBMI2, FeaturesRocketlake, 'k', false }, // Icelake server microarchitecture based processors. { {"icelake-server"}, CK_IcelakeServer, FEATURE_AVX512VBMI2, FeaturesICLServer, '\0', false }, { {"icelake_server"}, CK_IcelakeServer, FEATURE_AVX512VBMI2, FeaturesICLServer, 'k', true }, // Tigerlake microarchitecture based processors. { {"tigerlake"}, CK_Tigerlake, FEATURE_AVX512VP2INTERSECT, FeaturesTigerlake, 'l', false }, // Sapphire Rapids microarchitecture based processors. { {"sapphirerapids"}, CK_SapphireRapids, FEATURE_AVX512FP16, FeaturesSapphireRapids, 'n', false }, // Alderlake microarchitecture based processors. { {"alderlake"}, CK_Alderlake, FEATURE_AVX2, FeaturesAlderlake, 'p', false }, // Raptorlake microarchitecture based processors. { {"raptorlake"}, CK_Raptorlake, FEATURE_AVX2, FeaturesAlderlake, 'p', false }, // Meteorlake microarchitecture based processors. { {"meteorlake"}, CK_Meteorlake, FEATURE_AVX2, FeaturesAlderlake, 'p', false }, // Arrowlake microarchitecture based processors. { {"arrowlake"}, CK_Arrowlake, FEATURE_AVX2, FeaturesSierraforest, 'p', false }, { {"arrowlake-s"}, CK_ArrowlakeS, FEATURE_AVX2, FeaturesArrowlakeS, '\0', false }, { {"arrowlake_s"}, CK_ArrowlakeS, FEATURE_AVX2, FeaturesArrowlakeS, 'p', true }, // Lunarlake microarchitecture based processors. { {"lunarlake"}, CK_Lunarlake, FEATURE_AVX2, FeaturesArrowlakeS, 'p', false }, // Gracemont microarchitecture based processors. { {"gracemont"}, CK_Gracemont, FEATURE_AVX2, FeaturesAlderlake, 'p', false }, // Pantherlake microarchitecture based processors. { {"pantherlake"}, CK_Lunarlake, FEATURE_AVX2, FeaturesPantherlake, 'p', false }, // Sierraforest microarchitecture based processors. { {"sierraforest"}, CK_Sierraforest, FEATURE_AVX2, FeaturesSierraforest, 'p', false }, // Grandridge microarchitecture based processors. { {"grandridge"}, CK_Grandridge, FEATURE_AVX2, FeaturesSierraforest, 'p', false }, // Granite Rapids microarchitecture based processors. { {"graniterapids"}, CK_Graniterapids, FEATURE_AVX512FP16, FeaturesGraniteRapids, 'n', false }, // Granite Rapids D microarchitecture based processors. { {"graniterapids-d"}, CK_GraniterapidsD, FEATURE_AVX512FP16, FeaturesGraniteRapids | FeatureAMX_COMPLEX, '\0', false }, { {"graniterapids_d"}, CK_GraniterapidsD, FEATURE_AVX512FP16, FeaturesGraniteRapids | FeatureAMX_COMPLEX, 'n', true }, // Emerald Rapids microarchitecture based processors. { {"emeraldrapids"}, CK_Emeraldrapids, FEATURE_AVX512FP16, FeaturesSapphireRapids, 'n', false }, // Clearwaterforest microarchitecture based processors. { {"clearwaterforest"}, CK_Lunarlake, FEATURE_AVX2, FeaturesClearwaterforest, 'p', false }, // Knights Landing processor. { {"knl"}, CK_KNL, FEATURE_AVX512F, FeaturesKNL, 'Z', false }, { {"mic_avx512"}, CK_KNL, FEATURE_AVX512F, FeaturesKNL, 'Z', true }, // Knights Mill processor. { {"knm"}, CK_KNM, FEATURE_AVX5124FMAPS, FeaturesKNM, 'j', false }, // Lakemont microarchitecture based processors. { {"lakemont"}, CK_Lakemont, ~0U, FeatureCMPXCHG8B, '\0', false }, // K6 architecture processors. { {"k6"}, CK_K6, ~0U, FeaturesK6, '\0', false }, { {"k6-2"}, CK_K6_2, ~0U, FeaturesK6 | FeaturePRFCHW, '\0', false }, { {"k6-3"}, CK_K6_3, ~0U, FeaturesK6 | FeaturePRFCHW, '\0', false }, // K7 architecture processors. { {"athlon"}, CK_Athlon, ~0U, FeaturesAthlon, '\0', false }, { {"athlon-tbird"}, CK_Athlon, ~0U, FeaturesAthlon, '\0', false }, { {"athlon-xp"}, CK_AthlonXP, ~0U, FeaturesAthlonXP, '\0', false }, { {"athlon-mp"}, CK_AthlonXP, ~0U, FeaturesAthlonXP, '\0', false }, { {"athlon-4"}, CK_AthlonXP, ~0U, FeaturesAthlonXP, '\0', false }, // K8 architecture processors. { {"k8"}, CK_K8, ~0U, FeaturesK8, '\0', false }, { {"athlon64"}, CK_K8, ~0U, FeaturesK8, '\0', false }, { {"athlon-fx"}, CK_K8, ~0U, FeaturesK8, '\0', false }, { {"opteron"}, CK_K8, ~0U, FeaturesK8, '\0', false }, { {"k8-sse3"}, CK_K8SSE3, ~0U, FeaturesK8SSE3, '\0', false }, { {"athlon64-sse3"}, CK_K8SSE3, ~0U, FeaturesK8SSE3, '\0', false }, { {"opteron-sse3"}, CK_K8SSE3, ~0U, FeaturesK8SSE3, '\0', false }, { {"amdfam10"}, CK_AMDFAM10, FEATURE_SSE4_A, FeaturesAMDFAM10, '\0', false }, { {"barcelona"}, CK_AMDFAM10, FEATURE_SSE4_A, FeaturesAMDFAM10, '\0', false }, // Bobcat architecture processors. { {"btver1"}, CK_BTVER1, FEATURE_SSE4_A, FeaturesBTVER1, '\0', false }, { {"btver2"}, CK_BTVER2, FEATURE_BMI, FeaturesBTVER2, '\0', false }, // Bulldozer architecture processors. { {"bdver1"}, CK_BDVER1, FEATURE_XOP, FeaturesBDVER1, '\0', false }, { {"bdver2"}, CK_BDVER2, FEATURE_FMA, FeaturesBDVER2, '\0', false }, { {"bdver3"}, CK_BDVER3, FEATURE_FMA, FeaturesBDVER3, '\0', false }, { {"bdver4"}, CK_BDVER4, FEATURE_AVX2, FeaturesBDVER4, '\0', false }, // Zen architecture processors. { {"znver1"}, CK_ZNVER1, FEATURE_AVX2, FeaturesZNVER1, '\0', false }, { {"znver2"}, CK_ZNVER2, FEATURE_AVX2, FeaturesZNVER2, '\0', false }, { {"znver3"}, CK_ZNVER3, FEATURE_AVX2, FeaturesZNVER3, '\0', false }, { {"znver4"}, CK_ZNVER4, FEATURE_AVX512VBMI2, FeaturesZNVER4, '\0', false }, { {"znver5"}, CK_ZNVER5, FEATURE_AVX512VP2INTERSECT, FeaturesZNVER5, '\0', false }, // Generic 64-bit processor. { {"x86-64"}, CK_x86_64, FEATURE_SSE2 , FeaturesX86_64, '\0', false }, { {"x86-64-v2"}, CK_x86_64_v2, FEATURE_SSE4_2 , FeaturesX86_64_V2, '\0', false }, { {"x86-64-v3"}, CK_x86_64_v3, FEATURE_AVX2, FeaturesX86_64_V3, '\0', false }, { {"x86-64-v4"}, CK_x86_64_v4, FEATURE_AVX512VL, FeaturesX86_64_V4, '\0', false }, // Geode processors. { {"geode"}, CK_Geode, ~0U, FeaturesGeode, '\0', false }, }; // clang-format on constexpr const char *NoTuneList[] = {"x86-64-v2", "x86-64-v3", "x86-64-v4"}; X86::CPUKind llvm::X86::parseArchX86(StringRef CPU, bool Only64Bit) { for (const auto &P : Processors) if (!P.OnlyForCPUDispatchSpecific && P.Name == CPU && (P.Features[FEATURE_64BIT] || !Only64Bit)) return P.Kind; return CK_None; } X86::CPUKind llvm::X86::parseTuneCPU(StringRef CPU, bool Only64Bit) { if (llvm::is_contained(NoTuneList, CPU)) return CK_None; return parseArchX86(CPU, Only64Bit); } void llvm::X86::fillValidCPUArchList(SmallVectorImpl &Values, bool Only64Bit) { for (const auto &P : Processors) if (!P.OnlyForCPUDispatchSpecific && !P.Name.empty() && (P.Features[FEATURE_64BIT] || !Only64Bit)) Values.emplace_back(P.Name); } void llvm::X86::fillValidTuneCPUList(SmallVectorImpl &Values, bool Only64Bit) { for (const ProcInfo &P : Processors) if (!P.OnlyForCPUDispatchSpecific && !P.Name.empty() && (P.Features[FEATURE_64BIT] || !Only64Bit) && !llvm::is_contained(NoTuneList, P.Name)) Values.emplace_back(P.Name); } ProcessorFeatures llvm::X86::getKeyFeature(X86::CPUKind Kind) { // FIXME: Can we avoid a linear search here? The table might be sorted by // CPUKind so we could binary search? for (const auto &P : Processors) { if (P.Kind == Kind) { assert(P.KeyFeature != ~0U && "Processor does not have a key feature."); return static_cast(P.KeyFeature); } } llvm_unreachable("Unable to find CPU kind!"); } // Features with no dependencies. constexpr FeatureBitset ImpliedFeatures64BIT = {}; constexpr FeatureBitset ImpliedFeaturesADX = {}; constexpr FeatureBitset ImpliedFeaturesBMI = {}; constexpr FeatureBitset ImpliedFeaturesBMI2 = {}; constexpr FeatureBitset ImpliedFeaturesCLDEMOTE = {}; constexpr FeatureBitset ImpliedFeaturesCLFLUSHOPT = {}; constexpr FeatureBitset ImpliedFeaturesCLWB = {}; constexpr FeatureBitset ImpliedFeaturesCLZERO = {}; constexpr FeatureBitset ImpliedFeaturesCMOV = {}; constexpr FeatureBitset ImpliedFeaturesCMPXCHG16B = {}; constexpr FeatureBitset ImpliedFeaturesCMPXCHG8B = {}; constexpr FeatureBitset ImpliedFeaturesCRC32 = {}; constexpr FeatureBitset ImpliedFeaturesENQCMD = {}; constexpr FeatureBitset ImpliedFeaturesFSGSBASE = {}; constexpr FeatureBitset ImpliedFeaturesFXSR = {}; constexpr FeatureBitset ImpliedFeaturesINVPCID = {}; constexpr FeatureBitset ImpliedFeaturesLWP = {}; constexpr FeatureBitset ImpliedFeaturesLZCNT = {}; constexpr FeatureBitset ImpliedFeaturesMMX = {}; constexpr FeatureBitset ImpliedFeaturesMWAITX = {}; constexpr FeatureBitset ImpliedFeaturesMOVBE = {}; constexpr FeatureBitset ImpliedFeaturesMOVDIR64B = {}; constexpr FeatureBitset ImpliedFeaturesMOVDIRI = {}; constexpr FeatureBitset ImpliedFeaturesPCONFIG = {}; constexpr FeatureBitset ImpliedFeaturesPOPCNT = {}; constexpr FeatureBitset ImpliedFeaturesPKU = {}; constexpr FeatureBitset ImpliedFeaturesPRFCHW = {}; constexpr FeatureBitset ImpliedFeaturesPTWRITE = {}; constexpr FeatureBitset ImpliedFeaturesRDPID = {}; constexpr FeatureBitset ImpliedFeaturesRDPRU = {}; constexpr FeatureBitset ImpliedFeaturesRDRND = {}; constexpr FeatureBitset ImpliedFeaturesRDSEED = {}; constexpr FeatureBitset ImpliedFeaturesRTM = {}; constexpr FeatureBitset ImpliedFeaturesSAHF = {}; constexpr FeatureBitset ImpliedFeaturesSERIALIZE = {}; constexpr FeatureBitset ImpliedFeaturesSGX = {}; constexpr FeatureBitset ImpliedFeaturesSHSTK = {}; constexpr FeatureBitset ImpliedFeaturesTBM = {}; constexpr FeatureBitset ImpliedFeaturesTSXLDTRK = {}; constexpr FeatureBitset ImpliedFeaturesUINTR = {}; constexpr FeatureBitset ImpliedFeaturesUSERMSR = {}; constexpr FeatureBitset ImpliedFeaturesWAITPKG = {}; constexpr FeatureBitset ImpliedFeaturesWBNOINVD = {}; constexpr FeatureBitset ImpliedFeaturesVZEROUPPER = {}; constexpr FeatureBitset ImpliedFeaturesX87 = {}; constexpr FeatureBitset ImpliedFeaturesXSAVE = {}; constexpr FeatureBitset ImpliedFeaturesDUMMYFEATURE1 = {}; constexpr FeatureBitset ImpliedFeaturesDUMMYFEATURE2 = {}; // Not really CPU features, but need to be in the table because clang uses // target features to communicate them to the backend. constexpr FeatureBitset ImpliedFeaturesRETPOLINE_EXTERNAL_THUNK = {}; constexpr FeatureBitset ImpliedFeaturesRETPOLINE_INDIRECT_BRANCHES = {}; constexpr FeatureBitset ImpliedFeaturesRETPOLINE_INDIRECT_CALLS = {}; constexpr FeatureBitset ImpliedFeaturesLVI_CFI = {}; constexpr FeatureBitset ImpliedFeaturesLVI_LOAD_HARDENING = {}; // XSAVE features are dependent on basic XSAVE. constexpr FeatureBitset ImpliedFeaturesXSAVEC = FeatureXSAVE; constexpr FeatureBitset ImpliedFeaturesXSAVEOPT = FeatureXSAVE; constexpr FeatureBitset ImpliedFeaturesXSAVES = FeatureXSAVE; // SSE/AVX/AVX512F chain. constexpr FeatureBitset ImpliedFeaturesSSE = {}; constexpr FeatureBitset ImpliedFeaturesSSE2 = FeatureSSE; constexpr FeatureBitset ImpliedFeaturesSSE3 = FeatureSSE2; constexpr FeatureBitset ImpliedFeaturesSSSE3 = FeatureSSE3; constexpr FeatureBitset ImpliedFeaturesSSE4_1 = FeatureSSSE3; constexpr FeatureBitset ImpliedFeaturesSSE4_2 = FeatureSSE4_1; constexpr FeatureBitset ImpliedFeaturesAVX = FeatureSSE4_2; constexpr FeatureBitset ImpliedFeaturesAVX2 = FeatureAVX; constexpr FeatureBitset ImpliedFeaturesEVEX512 = {}; constexpr FeatureBitset ImpliedFeaturesAVX512F = FeatureAVX2 | FeatureF16C | FeatureFMA; // Vector extensions that build on SSE or AVX. constexpr FeatureBitset ImpliedFeaturesAES = FeatureSSE2; constexpr FeatureBitset ImpliedFeaturesF16C = FeatureAVX; constexpr FeatureBitset ImpliedFeaturesFMA = FeatureAVX; constexpr FeatureBitset ImpliedFeaturesGFNI = FeatureSSE2; constexpr FeatureBitset ImpliedFeaturesPCLMUL = FeatureSSE2; constexpr FeatureBitset ImpliedFeaturesSHA = FeatureSSE2; constexpr FeatureBitset ImpliedFeaturesVAES = FeatureAES | FeatureAVX2; constexpr FeatureBitset ImpliedFeaturesVPCLMULQDQ = FeatureAVX | FeaturePCLMUL; constexpr FeatureBitset ImpliedFeaturesSM3 = FeatureAVX; constexpr FeatureBitset ImpliedFeaturesSM4 = FeatureAVX2; // AVX512 features. constexpr FeatureBitset ImpliedFeaturesAVX512CD = FeatureAVX512F; constexpr FeatureBitset ImpliedFeaturesAVX512BW = FeatureAVX512F; constexpr FeatureBitset ImpliedFeaturesAVX512DQ = FeatureAVX512F; constexpr FeatureBitset ImpliedFeaturesAVX512VL = FeatureAVX512F; constexpr FeatureBitset ImpliedFeaturesAVX512BF16 = FeatureAVX512BW; constexpr FeatureBitset ImpliedFeaturesAVX512BITALG = FeatureAVX512BW; constexpr FeatureBitset ImpliedFeaturesAVX512IFMA = FeatureAVX512F; constexpr FeatureBitset ImpliedFeaturesAVX512VNNI = FeatureAVX512F; constexpr FeatureBitset ImpliedFeaturesAVX512VPOPCNTDQ = FeatureAVX512F; constexpr FeatureBitset ImpliedFeaturesAVX512VBMI = FeatureAVX512BW; constexpr FeatureBitset ImpliedFeaturesAVX512VBMI2 = FeatureAVX512BW; constexpr FeatureBitset ImpliedFeaturesAVX512VP2INTERSECT = FeatureAVX512F; // FIXME: These two aren't really implemented and just exist in the feature // list for __builtin_cpu_supports. So omit their dependencies. constexpr FeatureBitset ImpliedFeaturesAVX5124FMAPS = {}; constexpr FeatureBitset ImpliedFeaturesAVX5124VNNIW = {}; // SSE4_A->FMA4->XOP chain. constexpr FeatureBitset ImpliedFeaturesSSE4_A = FeatureSSE3; constexpr FeatureBitset ImpliedFeaturesFMA4 = FeatureAVX | FeatureSSE4_A; constexpr FeatureBitset ImpliedFeaturesXOP = FeatureFMA4; // AMX Features constexpr FeatureBitset ImpliedFeaturesAMX_TILE = {}; constexpr FeatureBitset ImpliedFeaturesAMX_BF16 = FeatureAMX_TILE; constexpr FeatureBitset ImpliedFeaturesAMX_FP16 = FeatureAMX_TILE; constexpr FeatureBitset ImpliedFeaturesAMX_INT8 = FeatureAMX_TILE; constexpr FeatureBitset ImpliedFeaturesAMX_COMPLEX = FeatureAMX_TILE; constexpr FeatureBitset ImpliedFeaturesHRESET = {}; constexpr FeatureBitset ImpliedFeaturesPREFETCHI = {}; constexpr FeatureBitset ImpliedFeaturesCMPCCXADD = {}; constexpr FeatureBitset ImpliedFeaturesRAOINT = {}; constexpr FeatureBitset ImpliedFeaturesAVXVNNIINT16 = FeatureAVX2; constexpr FeatureBitset ImpliedFeaturesAVXVNNIINT8 = FeatureAVX2; constexpr FeatureBitset ImpliedFeaturesAVXIFMA = FeatureAVX2; constexpr FeatureBitset ImpliedFeaturesAVXNECONVERT = FeatureAVX2; constexpr FeatureBitset ImpliedFeaturesSHA512 = FeatureAVX2; constexpr FeatureBitset ImpliedFeaturesAVX512FP16 = FeatureAVX512BW | FeatureAVX512DQ | FeatureAVX512VL; // Key Locker Features constexpr FeatureBitset ImpliedFeaturesKL = FeatureSSE2; constexpr FeatureBitset ImpliedFeaturesWIDEKL = FeatureKL; // AVXVNNI Features constexpr FeatureBitset ImpliedFeaturesAVXVNNI = FeatureAVX2; // AVX10 Features constexpr FeatureBitset ImpliedFeaturesAVX10_1 = FeatureAVX512CD | FeatureAVX512VBMI | FeatureAVX512IFMA | FeatureAVX512VNNI | FeatureAVX512BF16 | FeatureAVX512VPOPCNTDQ | FeatureAVX512VBMI2 | FeatureAVX512BITALG | FeatureVAES | FeatureVPCLMULQDQ | FeatureAVX512FP16; constexpr FeatureBitset ImpliedFeaturesAVX10_1_512 = FeatureAVX10_1 | FeatureEVEX512; // APX Features constexpr FeatureBitset ImpliedFeaturesEGPR = {}; constexpr FeatureBitset ImpliedFeaturesPush2Pop2 = {}; constexpr FeatureBitset ImpliedFeaturesPPX = {}; constexpr FeatureBitset ImpliedFeaturesNDD = {}; constexpr FeatureBitset ImpliedFeaturesCCMP = {}; constexpr FeatureBitset ImpliedFeaturesNF = {}; constexpr FeatureBitset ImpliedFeaturesCF = {}; constexpr FeatureBitset ImpliedFeaturesZU = {}; constexpr FeatureInfo FeatureInfos[X86::CPU_FEATURE_MAX] = { #define X86_FEATURE(ENUM, STR) {{"+" STR}, ImpliedFeatures##ENUM}, #include "llvm/TargetParser/X86TargetParser.def" }; void llvm::X86::getFeaturesForCPU(StringRef CPU, SmallVectorImpl &EnabledFeatures, bool NeedPlus) { auto I = llvm::find_if(Processors, [&](const ProcInfo &P) { return P.Name == CPU; }); assert(I != std::end(Processors) && "Processor not found!"); FeatureBitset Bits = I->Features; // Remove the 64-bit feature which we only use to validate if a CPU can // be used with 64-bit mode. Bits &= ~Feature64BIT; // Add the string version of all set bits. for (unsigned i = 0; i != CPU_FEATURE_MAX; ++i) if (Bits[i] && !FeatureInfos[i].getName(NeedPlus).empty()) EnabledFeatures.push_back(FeatureInfos[i].getName(NeedPlus)); } // For each feature that is (transitively) implied by this feature, set it. static void getImpliedEnabledFeatures(FeatureBitset &Bits, const FeatureBitset &Implies) { // Fast path: Implies is often empty. if (!Implies.any()) return; FeatureBitset Prev; Bits |= Implies; do { Prev = Bits; for (unsigned i = CPU_FEATURE_MAX; i;) if (Bits[--i]) Bits |= FeatureInfos[i].ImpliedFeatures; } while (Prev != Bits); } /// Create bit vector of features that are implied disabled if the feature /// passed in Value is disabled. static void getImpliedDisabledFeatures(FeatureBitset &Bits, unsigned Value) { // Check all features looking for any dependent on this feature. If we find // one, mark it and recursively find any feature that depend on it. FeatureBitset Prev; Bits.set(Value); do { Prev = Bits; for (unsigned i = 0; i != CPU_FEATURE_MAX; ++i) if ((FeatureInfos[i].ImpliedFeatures & Bits).any()) Bits.set(i); } while (Prev != Bits); } void llvm::X86::updateImpliedFeatures( StringRef Feature, bool Enabled, StringMap &Features) { auto I = llvm::find_if(FeatureInfos, [&](const FeatureInfo &FI) { return FI.getName() == Feature; }); if (I == std::end(FeatureInfos)) { // FIXME: This shouldn't happen, but may not have all features in the table // yet. return; } FeatureBitset ImpliedBits; if (Enabled) getImpliedEnabledFeatures(ImpliedBits, I->ImpliedFeatures); else getImpliedDisabledFeatures(ImpliedBits, std::distance(std::begin(FeatureInfos), I)); // Update the map entry for all implied features. for (unsigned i = 0; i != CPU_FEATURE_MAX; ++i) if (ImpliedBits[i] && !FeatureInfos[i].getName().empty()) Features[FeatureInfos[i].getName()] = Enabled; } char llvm::X86::getCPUDispatchMangling(StringRef CPU) { auto I = llvm::find_if(Processors, [&](const ProcInfo &P) { return P.Name == CPU; }); assert(I != std::end(Processors) && "Processor not found!"); assert(I->Mangling != '\0' && "Processor dooesn't support function multiversion!"); return I->Mangling; } bool llvm::X86::validateCPUSpecificCPUDispatch(StringRef Name) { auto I = llvm::find_if(Processors, [&](const ProcInfo &P) { return P.Name == Name; }); return I != std::end(Processors); } std::array llvm::X86::getCpuSupportsMask(ArrayRef FeatureStrs) { // Processor features and mapping to processor feature value. std::array FeatureMask{}; for (StringRef FeatureStr : FeatureStrs) { unsigned Feature = StringSwitch(FeatureStr) #define X86_FEATURE_COMPAT(ENUM, STR, PRIORITY) \ .Case(STR, llvm::X86::FEATURE_##ENUM) #define X86_MICROARCH_LEVEL(ENUM, STR, PRIORITY) \ .Case(STR, llvm::X86::FEATURE_##ENUM) #include "llvm/TargetParser/X86TargetParser.def" ; assert(Feature / 32 < FeatureMask.size()); FeatureMask[Feature / 32] |= 1U << (Feature % 32); } return FeatureMask; } unsigned llvm::X86::getFeaturePriority(ProcessorFeatures Feat) { #ifndef NDEBUG // Check that priorities are set properly in the .def file. We expect that // "compat" features are assigned non-duplicate consecutive priorities // starting from one (1, ..., 37) and multiple zeros. #define X86_FEATURE_COMPAT(ENUM, STR, PRIORITY) PRIORITY, unsigned Priorities[] = { #include "llvm/TargetParser/X86TargetParser.def" }; std::array HelperList; const size_t MaxPriority = 37; std::iota(HelperList.begin(), HelperList.begin() + MaxPriority + 1, 0); for (size_t i = MaxPriority + 1; i != std::size(Priorities); ++i) HelperList[i] = 0; assert(std::is_permutation(HelperList.begin(), HelperList.end(), std::begin(Priorities), std::end(Priorities)) && "Priorities don't form consecutive range!"); #endif switch (Feat) { #define X86_FEATURE_COMPAT(ENUM, STR, PRIORITY) \ case X86::FEATURE_##ENUM: \ return PRIORITY; #include "llvm/TargetParser/X86TargetParser.def" default: llvm_unreachable("No Feature Priority for non-CPUSupports Features"); } }