//===----------- TargetParser.cpp - Target Parser -------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "llvm/ADT/STLExtras.h" #include "llvm/Support/ARMBuildAttributes.h" #include "llvm/Support/TargetParser.h" #include "gtest/gtest.h" #include using namespace llvm; namespace { static const unsigned kHWDivKinds[] = { #define ARM_HW_DIV_NAME(NAME, ID) ID, #include "llvm/Support/ARMTargetParser.def" #undef ARM_HW_DIV_NAME }; static const unsigned kARMArchExtKinds[] = { #define ARM_ARCH_EXT_NAME(NAME, ID, FEATURE, NEGFEATURE) ID, #include "llvm/Support/ARMTargetParser.def" #undef ARM_ARCH_EXT_NAME }; static const unsigned kAArch64ArchExtKinds[] = { #define AARCH64_ARCH_EXT_NAME(NAME, ID, FEATURE, NEGFEATURE) ID, #include "llvm/Support/AArch64TargetParser.def" #undef AARCH64_ARCH_EXT_NAME }; template struct ArchNames { const char *Name; unsigned DefaultFPU; unsigned ArchBaseExtensions; T ID; ARMBuildAttrs::CPUArch ArchAttr; }; ArchNames kAArch64ARCHNames[] = { #define AARCH64_ARCH(NAME, ID, CPU_ATTR, SUB_ARCH, ARCH_ATTR, ARCH_FPU, \ ARCH_BASE_EXT) \ {NAME, ARM::ARCH_FPU, ARCH_BASE_EXT, AArch64::ArchKind::ID, ARCH_ATTR}, #include "llvm/Support/AArch64TargetParser.def" #undef AARCH64_ARCH }; ArchNames kARMARCHNames[] = { #define ARM_ARCH(NAME, ID, CPU_ATTR, SUB_ARCH, ARCH_ATTR, ARCH_FPU, \ ARCH_BASE_EXT) \ {NAME, ARM::ARCH_FPU, ARCH_BASE_EXT, ARM::ID, ARCH_ATTR}, #include "llvm/Support/ARMTargetParser.def" #undef ARM_ARCH }; template struct CpuNames { const char *Name; T ID; unsigned DefaultFPU; unsigned DefaultExt; }; CpuNames kAArch64CPUNames[] = { #define AARCH64_CPU_NAME(NAME, ID, DEFAULT_FPU, IS_DEFAULT, DEFAULT_EXT) \ {NAME, AArch64::ArchKind::ID, ARM::DEFAULT_FPU, DEFAULT_EXT}, #include "llvm/Support/AArch64TargetParser.def" #undef AARCH64_CPU_NAME }; CpuNames kARMCPUNames[] = { #define ARM_CPU_NAME(NAME, ID, DEFAULT_FPU, IS_DEFAULT, DEFAULT_EXT) \ {NAME, ARM::ID, ARM::DEFAULT_FPU, DEFAULT_EXT}, #include "llvm/Support/ARMTargetParser.def" #undef ARM_CPU_NAME }; const char *ARMArch[] = { "armv2", "armv2a", "armv3", "armv3m", "armv4", "armv4t", "armv5", "armv5t", "armv5e", "armv5te", "armv5tej", "armv6", "armv6j", "armv6k", "armv6hl", "armv6t2", "armv6kz", "armv6z", "armv6zk", "armv6-m", "armv6m", "armv6sm", "armv6s-m", "armv7-a", "armv7", "armv7a", "armv7hl", "armv7l", "armv7-r", "armv7r", "armv7-m", "armv7m", "armv7k", "armv7s", "armv7e-m", "armv7em", "armv8-a", "armv8", "armv8a", "armv8.1-a", "armv8.1a", "armv8.2-a", "armv8.2a", "armv8-m.base", "armv8m.base", "armv8-m.main", "armv8m.main", "iwmmxt", "iwmmxt2", "xscale"}; template bool contains(const T (&array)[N], const T element) { return std::find(std::begin(array), std::end(array), element) != std::end(array); } TEST(TargetParserTest, ARMArchName) { for (ARM::ArchKind AK = static_cast(0); AK <= ARM::ArchKind::AK_LAST; AK = static_cast(static_cast(AK) + 1)) EXPECT_TRUE(AK == ARM::AK_LAST ? ARM::getArchName(AK).empty() : !ARM::getArchName(AK).empty()); } TEST(TargetParserTest, ARMCPUAttr) { for (ARM::ArchKind AK = static_cast(0); AK <= ARM::ArchKind::AK_LAST; AK = static_cast(static_cast(AK) + 1)) EXPECT_TRUE((AK == ARM::AK_INVALID || AK == ARM::AK_LAST) ? ARM::getCPUAttr(AK).empty() : !ARM::getCPUAttr(AK).empty()); } TEST(TargetParserTest, ARMSubArch) { for (ARM::ArchKind AK = static_cast(0); AK <= ARM::ArchKind::AK_LAST; AK = static_cast(static_cast(AK) + 1)) EXPECT_TRUE((AK == ARM::AK_INVALID || AK == ARM::AK_IWMMXT || AK == ARM::AK_IWMMXT2 || AK == ARM::AK_LAST) ? ARM::getSubArch(AK).empty() : !ARM::getSubArch(AK).empty()); } TEST(TargetParserTest, ARMFPUName) { for (ARM::FPUKind FK = static_cast(0); FK <= ARM::FPUKind::FK_LAST; FK = static_cast(static_cast(FK) + 1)) EXPECT_TRUE(FK == ARM::FK_LAST ? ARM::getFPUName(FK).empty() : !ARM::getFPUName(FK).empty()); } TEST(TargetParserTest, ARMFPUVersion) { for (ARM::FPUKind FK = static_cast(0); FK <= ARM::FPUKind::FK_LAST; FK = static_cast(static_cast(FK) + 1)) if (FK == ARM::FK_LAST) EXPECT_EQ(0, ARM::getFPUVersion(FK)); else EXPECT_LE(0, ARM::getFPUVersion(FK)); } TEST(TargetParserTest, ARMFPUNeonSupportLevel) { for (ARM::FPUKind FK = static_cast(0); FK <= ARM::FPUKind::FK_LAST; FK = static_cast(static_cast(FK) + 1)) if (FK == ARM::FK_LAST) EXPECT_EQ(0, ARM::getFPUNeonSupportLevel(FK)); else EXPECT_LE(0, ARM::getFPUNeonSupportLevel(FK)); } TEST(TargetParserTest, ARMFPURestriction) { for (ARM::FPUKind FK = static_cast(0); FK <= ARM::FPUKind::FK_LAST; FK = static_cast(static_cast(FK) + 1)) if (FK == ARM::FK_LAST) EXPECT_EQ(0, ARM::getFPURestriction(FK)); else EXPECT_LE(0, ARM::getFPURestriction(FK)); } TEST(TargetParserTest, ARMDefaultFPU) { for (ARM::ArchKind AK = static_cast(0); AK < ARM::ArchKind::AK_LAST; AK = static_cast(static_cast(AK) + 1)) EXPECT_EQ(kARMARCHNames[AK].DefaultFPU, ARM::getDefaultFPU(StringRef("generic"), AK)); for (const auto &ARMCPUName : kARMCPUNames) EXPECT_EQ(ARMCPUName.DefaultFPU, ARM::getDefaultFPU(ARMCPUName.Name, 0)); } TEST(TargetParserTest, ARMDefaultExtensions) { for (ARM::ArchKind AK = static_cast(0); AK < ARM::ArchKind::AK_LAST; AK = static_cast(static_cast(AK) + 1)) EXPECT_EQ(kARMARCHNames[AK].ArchBaseExtensions, ARM::getDefaultExtensions(StringRef("generic"), AK)); for (const auto &ARMCPUName : kARMCPUNames) { unsigned DefaultExt = kARMARCHNames[ARMCPUName.ID].ArchBaseExtensions | ARMCPUName.DefaultExt; EXPECT_EQ(DefaultExt, ARM::getDefaultExtensions(ARMCPUName.Name, 0)); } } TEST(TargetParserTest, ARMExtensionFeatures) { std::vector Features; unsigned Extensions = ARM::AEK_CRC | ARM::AEK_CRYPTO | ARM::AEK_DSP | ARM::AEK_HWDIVARM | ARM::AEK_HWDIV | ARM::AEK_MP | ARM::AEK_SEC | ARM::AEK_VIRT | ARM::AEK_RAS; for (unsigned i = 0; i <= Extensions; i++) EXPECT_TRUE(i == 0 ? !ARM::getExtensionFeatures(i, Features) : ARM::getExtensionFeatures(i, Features)); } TEST(TargetParserTest, ARMFPUFeatures) { std::vector Features; for (ARM::FPUKind FK = static_cast(0); FK <= ARM::FPUKind::FK_LAST; FK = static_cast(static_cast(FK) + 1)) EXPECT_TRUE((FK == ARM::FK_INVALID || FK >= ARM::FK_LAST) ? !ARM::getFPUFeatures(FK, Features) : ARM::getFPUFeatures(FK, Features)); } TEST(TargetParserTest, ARMArchAttr) { for (ARM::ArchKind AK = static_cast(0); AK <= ARM::ArchKind::AK_LAST; AK = static_cast(static_cast(AK) + 1)) EXPECT_TRUE(AK == ARM::AK_LAST ? (ARMBuildAttrs::CPUArch::Pre_v4 == ARM::getArchAttr(AK)) : (kARMARCHNames[AK].ArchAttr == ARM::getArchAttr(AK))); } TEST(TargetParserTest, ARMArchExtName) { for (ARM::ArchExtKind AEK = static_cast(0); AEK <= ARM::ArchExtKind::AEK_XSCALE; AEK = static_cast(static_cast(AEK) + 1)) EXPECT_TRUE(contains(kARMArchExtKinds, static_cast(AEK)) ? !ARM::getArchExtName(AEK).empty() : ARM::getArchExtName(AEK).empty()); } TEST(TargetParserTest, ARMArchExtFeature) { const char *ArchExt[][4] = {{"crc", "nocrc", "+crc", "-crc"}, {"crypto", "nocrypto", "+crypto", "-crypto"}, {"dsp", "nodsp", "+dsp", "-dsp"}, {"fp", "nofp", nullptr, nullptr}, {"idiv", "noidiv", nullptr, nullptr}, {"mp", "nomp", nullptr, nullptr}, {"simd", "nosimd", nullptr, nullptr}, {"sec", "nosec", nullptr, nullptr}, {"virt", "novirt", nullptr, nullptr}, {"fp16", "nofp16", "+fullfp16", "-fullfp16"}, {"ras", "noras", "+ras", "-ras"}, {"os", "noos", nullptr, nullptr}, {"iwmmxt", "noiwmmxt", nullptr, nullptr}, {"iwmmxt2", "noiwmmxt2", nullptr, nullptr}, {"maverick", "maverick", nullptr, nullptr}, {"xscale", "noxscale", nullptr, nullptr}}; for (unsigned i = 0; i < array_lengthof(ArchExt); i++) { EXPECT_EQ(ArchExt[i][2], ARM::getArchExtFeature(ArchExt[i][0])); EXPECT_EQ(ArchExt[i][3], ARM::getArchExtFeature(ArchExt[i][1])); } } TEST(TargetParserTest, ARMHWDivName) { for (ARM::ArchExtKind AEK = static_cast(0); AEK <= ARM::ArchExtKind::AEK_XSCALE; AEK = static_cast(static_cast(AEK) + 1)) EXPECT_TRUE(contains(kHWDivKinds, static_cast(AEK)) ? !ARM::getHWDivName(AEK).empty() : ARM::getHWDivName(AEK).empty()); } TEST(TargetParserTest, ARMDefaultCPU) { for (unsigned i = 0; i < array_lengthof(ARMArch); i++) EXPECT_FALSE(ARM::getDefaultCPU(ARMArch[i]).empty()); } TEST(TargetParserTest, ARMparseHWDiv) { const char *hwdiv[] = {"thumb", "arm", "arm,thumb", "thumb,arm"}; for (unsigned i = 0; i < array_lengthof(hwdiv); i++) EXPECT_NE(ARM::AEK_INVALID, ARM::parseHWDiv((StringRef)hwdiv[i])); } TEST(TargetParserTest, ARMparseFPU) { const char *FPU[] = {"vfp", "vfpv2", "vfp2", "vfpv3", "vfp3", "vfpv3-fp16", "vfpv3-d16", "vfp3-d16", "vfpv3-d16-fp16", "vfpv3xd", "vfpv3xd-fp16", "vfpv4", "vfp4", "vfpv4-d16", "vfp4-d16", "fp4-dp-d16", "fpv4-dp-d16", "fpv4-sp-d16", "fp4-sp-d16", "vfpv4-sp-d16", "fpv5-d16", "fp5-dp-d16", "fpv5-dp-d16", "fpv5-sp-d16", "fp5-sp-d16", "fp-armv8", "neon", "neon-vfpv3", "neon-fp16", "neon-vfpv4", "neon-fp-armv8", "crypto-neon-fp-armv8", "softvfp"}; for (unsigned i = 0; i < array_lengthof(FPU); i++) EXPECT_NE(ARM::FK_INVALID, ARM::parseFPU((StringRef)FPU[i])); } TEST(TargetParserTest, ARMparseArch) { for (unsigned i = 0; i < array_lengthof(ARMArch); i++) EXPECT_NE(ARM::AEK_INVALID, ARM::parseArch(ARMArch[i])); } TEST(TargetParserTest, ARMparseArchExt) { const char *ArchExt[] = {"none", "crc", "crypto", "dsp", "fp", "idiv", "mp", "simd", "sec", "virt", "fp16", "ras", "os", "iwmmxt", "iwmmxt2", "maverick", "xscale"}; for (unsigned i = 0; i < array_lengthof(ArchExt); i++) EXPECT_NE(ARM::AEK_INVALID, ARM::parseArchExt(ArchExt[i])); } TEST(TargetParserTest, ARMparseCPUArch) { const char *CPU[] = { "arm2", "arm3", "arm6", "arm7m", "arm8", "arm810", "strongarm", "strongarm110", "strongarm1100", "strongarm1110", "arm7tdmi", "arm7tdmi-s", "arm710t", "arm720t", "arm9", "arm9tdmi", "arm920", "arm920t", "arm922t", "arm9312", "arm940t", "ep9312", "arm10tdmi", "arm1020t", "arm9e", "arm946e-s", "arm966e-s", "arm968e-s", "arm10e", "arm1020e", "arm1022e", "arm926ej-s", "arm1136j-s", "arm1136jf-s", "arm1136jz-s", "arm1176j-s", "arm1176jz-s", "mpcore", "mpcorenovfp", "arm1176jzf-s", "arm1156t2-s", "arm1156t2f-s", "cortex-m0", "cortex-m0plus", "cortex-m1", "sc000", "cortex-a5", "cortex-a7", "cortex-a8", "cortex-a9", "cortex-a12", "cortex-a15", "cortex-a17", "krait", "cortex-r4", "cortex-r4f", "cortex-r5", "cortex-r7", "cortex-r8", "sc300", "cortex-m3", "cortex-m4", "cortex-m7", "cortex-a32", "cortex-a35", "cortex-a53", "cortex-a57", "cortex-a72", "cortex-a73", "cyclone", "exynos-m1", "iwmmxt", "xscale", "swift"}; for (const auto &ARMCPUName : kARMCPUNames) EXPECT_TRUE(contains(CPU, ARMCPUName.Name) ? (ARM::AK_INVALID != ARM::parseCPUArch(ARMCPUName.Name)) : (ARM::AK_INVALID == ARM::parseCPUArch(ARMCPUName.Name))); } TEST(TargetParserTest, ARMparseArchEndianAndISA) { const char *Arch[] = { "v2", "v2a", "v3", "v3m", "v4", "v4t", "v5", "v5t", "v5e", "v5te", "v5tej", "v6", "v6j", "v6k", "v6hl", "v6t2", "v6kz", "v6z", "v6zk", "v6-m", "v6m", "v6sm", "v6s-m", "v7-a", "v7", "v7a", "v7hl", "v7l", "v7-r", "v7r", "v7-m", "v7m", "v7k", "v7s", "v7e-m", "v7em", "v8-a", "v8", "v8a", "v8.1-a", "v8.1a", "v8.2-a", "v8.2a"}; for (unsigned i = 0; i < array_lengthof(Arch); i++) { std::string arm_1 = "armeb" + (std::string)(Arch[i]); std::string arm_2 = "arm" + (std::string)(Arch[i]) + "eb"; std::string arm_3 = "arm" + (std::string)(Arch[i]); std::string thumb_1 = "thumbeb" + (std::string)(Arch[i]); std::string thumb_2 = "thumb" + (std::string)(Arch[i]) + "eb"; std::string thumb_3 = "thumb" + (std::string)(Arch[i]); EXPECT_EQ(ARM::EK_BIG, ARM::parseArchEndian(arm_1)); EXPECT_EQ(ARM::EK_BIG, ARM::parseArchEndian(arm_2)); EXPECT_EQ(ARM::EK_LITTLE, ARM::parseArchEndian(arm_3)); EXPECT_EQ(ARM::IK_ARM, ARM::parseArchISA(arm_1)); EXPECT_EQ(ARM::IK_ARM, ARM::parseArchISA(arm_2)); EXPECT_EQ(ARM::IK_ARM, ARM::parseArchISA(arm_3)); if (i >= 4) { EXPECT_EQ(ARM::EK_BIG, ARM::parseArchEndian(thumb_1)); EXPECT_EQ(ARM::EK_BIG, ARM::parseArchEndian(thumb_2)); EXPECT_EQ(ARM::EK_LITTLE, ARM::parseArchEndian(thumb_3)); EXPECT_EQ(ARM::IK_THUMB, ARM::parseArchISA(thumb_1)); EXPECT_EQ(ARM::IK_THUMB, ARM::parseArchISA(thumb_2)); EXPECT_EQ(ARM::IK_THUMB, ARM::parseArchISA(thumb_3)); } } EXPECT_EQ(ARM::EK_LITTLE, ARM::parseArchEndian("aarch64")); EXPECT_EQ(ARM::EK_BIG, ARM::parseArchEndian("aarch64_be")); EXPECT_EQ(ARM::IK_AARCH64, ARM::parseArchISA("aarch64")); EXPECT_EQ(ARM::IK_AARCH64, ARM::parseArchISA("aarch64_be")); EXPECT_EQ(ARM::IK_AARCH64, ARM::parseArchISA("arm64")); EXPECT_EQ(ARM::IK_AARCH64, ARM::parseArchISA("arm64_be")); } TEST(TargetParserTest, ARMparseArchProfile) { for (unsigned i = 0; i < array_lengthof(ARMArch); i++) { switch (ARM::parseArch(ARMArch[i])) { case ARM::AK_ARMV6M: case ARM::AK_ARMV7M: case ARM::AK_ARMV7EM: case ARM::AK_ARMV8MMainline: case ARM::AK_ARMV8MBaseline: EXPECT_EQ(ARM::PK_M, ARM::parseArchProfile(ARMArch[i])); continue; case ARM::AK_ARMV7R: EXPECT_EQ(ARM::PK_R, ARM::parseArchProfile(ARMArch[i])); continue; case ARM::AK_ARMV7A: case ARM::AK_ARMV7K: case ARM::AK_ARMV8A: case ARM::AK_ARMV8_1A: case ARM::AK_ARMV8_2A: EXPECT_EQ(ARM::PK_A, ARM::parseArchProfile(ARMArch[i])); continue; } EXPECT_EQ(ARM::PK_INVALID, ARM::parseArchProfile(ARMArch[i])); } } TEST(TargetParserTest, ARMparseArchVersion) { for (unsigned i = 0; i < array_lengthof(ARMArch); i++) if (((std::string)ARMArch[i]).substr(0, 4) == "armv") EXPECT_EQ((ARMArch[i][4] - 48), ARM::parseArchVersion(ARMArch[i])); else EXPECT_EQ(5, ARM::parseArchVersion(ARMArch[i])); } TEST(TargetParserTest, AArch64DefaultFPU) { for (unsigned AK = 0; AK < static_cast(AArch64::ArchKind::AK_LAST); AK++) EXPECT_EQ(kAArch64ARCHNames[AK].DefaultFPU, AArch64::getDefaultFPU(StringRef("generic"), AK)); for (const auto &AArch64CPUName : kAArch64CPUNames) EXPECT_EQ(AArch64CPUName.DefaultFPU, AArch64::getDefaultFPU(AArch64CPUName.Name, static_cast(AArch64CPUName.ID))); } TEST(TargetParserTest, AArch64DefaultExt) { for (unsigned AK = 0; AK < static_cast(AArch64::ArchKind::AK_LAST); AK++) EXPECT_EQ(kAArch64ARCHNames[AK].ArchBaseExtensions, AArch64::getDefaultExtensions(StringRef("generic"), AK)); for (const auto &AArch64CPUName : kAArch64CPUNames) EXPECT_EQ( AArch64CPUName.DefaultExt, AArch64::getDefaultExtensions( AArch64CPUName.Name, static_cast(AArch64CPUName.ID))); } TEST(TargetParserTest, AArch64ExtensionFeatures) { std::vector Features; unsigned Extensions = AArch64::AEK_CRC | AArch64::AEK_CRYPTO | AArch64::AEK_FP | AArch64::AEK_SIMD | AArch64::AEK_FP16 | AArch64::AEK_PROFILE | AArch64::AEK_RAS; for (unsigned i = 0; i <= Extensions; i++) EXPECT_TRUE(i == 0 ? !AArch64::getExtensionFeatures(i, Features) : AArch64::getExtensionFeatures(i, Features)); } TEST(TargetParserTest, AArch64ArchFeatures) { std::vector Features; for (unsigned AK = 0; AK < static_cast(AArch64::ArchKind::AK_LAST); AK++) EXPECT_TRUE((AK == static_cast(AArch64::ArchKind::AK_INVALID) || AK == static_cast(AArch64::ArchKind::AK_LAST)) ? !AArch64::getArchFeatures(AK, Features) : AArch64::getArchFeatures(AK, Features)); } TEST(TargetParserTest, AArch64ArchName) { for (unsigned AK = 0; AK < static_cast(AArch64::ArchKind::AK_LAST); AK++) EXPECT_TRUE(AK == static_cast(AArch64::ArchKind::AK_LAST) ? AArch64::getArchName(AK).empty() : !AArch64::getArchName(AK).empty()); } TEST(TargetParserTest, AArch64CPUAttr) { for (unsigned AK = 0; AK < static_cast(AArch64::ArchKind::AK_LAST); AK++) EXPECT_TRUE((AK == static_cast(AArch64::ArchKind::AK_INVALID) || AK == static_cast(AArch64::ArchKind::AK_LAST)) ? AArch64::getCPUAttr(AK).empty() : !AArch64::getCPUAttr(AK).empty()); } TEST(TargetParserTest, AArch64SubArch) { for (unsigned AK = 0; AK < static_cast(AArch64::ArchKind::AK_LAST); AK++) EXPECT_TRUE((AK == static_cast(AArch64::ArchKind::AK_INVALID) || AK == static_cast(AArch64::ArchKind::AK_LAST)) ? AArch64::getSubArch(AK).empty() : !AArch64::getSubArch(AK).empty()); } TEST(TargetParserTest, AArch64ArchAttr) { for (unsigned AK = 0; AK < static_cast(AArch64::ArchKind::AK_LAST); AK++) EXPECT_TRUE( AK == static_cast(AArch64::ArchKind::AK_LAST) ? (ARMBuildAttrs::CPUArch::v8_A == AArch64::getArchAttr(AK)) : (kAArch64ARCHNames[AK].ArchAttr == AArch64::getArchAttr(AK))); } TEST(TargetParserTest, AArch64ArchExtName) { for (AArch64::ArchExtKind AEK = static_cast(0); AEK <= AArch64::ArchExtKind::AEK_RAS; AEK = static_cast(static_cast(AEK) + 1)) EXPECT_TRUE(contains(kAArch64ArchExtKinds, static_cast(AEK)) ? !AArch64::getArchExtName(AEK).empty() : AArch64::getArchExtName(AEK).empty()); } TEST(TargetParserTest, AArch64ArchExtFeature) { const char *ArchExt[][4] = {{"crc", "nocrc", "+crc", "-crc"}, {"crypto", "nocrypto", "+crypto", "-crypto"}, {"fp", "nofp", "+fp-armv8", "-fp-armv8"}, {"simd", "nosimd", "+neon", "-neon"}, {"fp16", "nofp16", "+fullfp16", "-fullfp16"}, {"profile", "noprofile", "+spe", "-spe"}, {"ras", "noras", "+ras", "-ras"}}; for (unsigned i = 0; i < array_lengthof(ArchExt); i++) { EXPECT_EQ(ArchExt[i][2], AArch64::getArchExtFeature(ArchExt[i][0])); EXPECT_EQ(ArchExt[i][3], AArch64::getArchExtFeature(ArchExt[i][1])); } } TEST(TargetParserTest, AArch64DefaultCPU) { const char *Arch[] = {"armv8a", "armv8-a", "armv8", "armv8.1a", "armv8.1-a", "armv8.2a", "armv8.2-a"}; for (unsigned i = 0; i < array_lengthof(Arch); i++) EXPECT_FALSE(AArch64::getDefaultCPU(Arch[i]).empty()); } TEST(TargetParserTest, AArch64parseArch) { const char *Arch[] = {"armv8", "armv8a", "armv8-a", "armv8.1a", "armv8.1-a", "armv8.2a", "armv8.2-a"}; for (unsigned i = 0; i < array_lengthof(Arch); i++) EXPECT_NE(static_cast(AArch64::ArchKind::AK_INVALID), AArch64::parseArch(Arch[i])); EXPECT_EQ(static_cast(AArch64::ArchKind::AK_INVALID), AArch64::parseArch("aarch64")); EXPECT_EQ(static_cast(AArch64::ArchKind::AK_INVALID), AArch64::parseArch("arm64")); } TEST(TargetParserTest, AArch64parseArchExt) { const char *ArchExt[] = {"none", "crc", "crypto", "fp", "simd", "fp16", "profile", "ras"}; for (unsigned i = 0; i < array_lengthof(ArchExt); i++) EXPECT_NE(AArch64::AEK_INVALID, AArch64::parseArchExt(ArchExt[i])); } TEST(TargetParserTest, AArch64parseCPUArch) { const char *CPU[] = {"cortex-a35", "cortex-a53", "cortex-a57", "cortex-a72", "cortex-a73", "cyclone", "exynos-m1", "kryo", "vulcan"}; for (const auto &AArch64CPUName : kAArch64CPUNames) EXPECT_TRUE(contains(CPU, AArch64CPUName.Name) ? (static_cast(AArch64::ArchKind::AK_INVALID) != AArch64::parseCPUArch(AArch64CPUName.Name)) : (static_cast(AArch64::ArchKind::AK_INVALID) == AArch64::parseCPUArch(AArch64CPUName.Name))); } }