//===-- llvm/TargetParser/Triple.h - Target triple helper class--*- 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 // //===----------------------------------------------------------------------===// #ifndef LLVM_TARGETPARSER_TRIPLE_H #define LLVM_TARGETPARSER_TRIPLE_H #include "llvm/ADT/Twine.h" #include "llvm/Support/VersionTuple.h" // Some system headers or GCC predefined macros conflict with identifiers in // this file. Undefine them here. #undef NetBSD #undef mips #undef sparc namespace llvm { /// Triple - Helper class for working with autoconf configuration names. For /// historical reasons, we also call these 'triples' (they used to contain /// exactly three fields). /// /// Configuration names are strings in the canonical form: /// ARCHITECTURE-VENDOR-OPERATING_SYSTEM /// or /// ARCHITECTURE-VENDOR-OPERATING_SYSTEM-ENVIRONMENT /// /// This class is used for clients which want to support arbitrary /// configuration names, but also want to implement certain special /// behavior for particular configurations. This class isolates the mapping /// from the components of the configuration name to well known IDs. /// /// At its core the Triple class is designed to be a wrapper for a triple /// string; the constructor does not change or normalize the triple string. /// Clients that need to handle the non-canonical triples that users often /// specify should use the normalize method. /// /// See autoconf/config.guess for a glimpse into what configuration names /// look like in practice. class Triple { public: enum ArchType { UnknownArch, arm, // ARM (little endian): arm, armv.*, xscale armeb, // ARM (big endian): armeb aarch64, // AArch64 (little endian): aarch64 aarch64_be, // AArch64 (big endian): aarch64_be aarch64_32, // AArch64 (little endian) ILP32: aarch64_32 arc, // ARC: Synopsys ARC avr, // AVR: Atmel AVR microcontroller bpfel, // eBPF or extended BPF or 64-bit BPF (little endian) bpfeb, // eBPF or extended BPF or 64-bit BPF (big endian) csky, // CSKY: csky dxil, // DXIL 32-bit DirectX bytecode hexagon, // Hexagon: hexagon loongarch32, // LoongArch (32-bit): loongarch32 loongarch64, // LoongArch (64-bit): loongarch64 m68k, // M68k: Motorola 680x0 family mips, // MIPS: mips, mipsallegrex, mipsr6 mipsel, // MIPSEL: mipsel, mipsallegrexe, mipsr6el mips64, // MIPS64: mips64, mips64r6, mipsn32, mipsn32r6 mips64el, // MIPS64EL: mips64el, mips64r6el, mipsn32el, mipsn32r6el msp430, // MSP430: msp430 ppc, // PPC: powerpc ppcle, // PPCLE: powerpc (little endian) ppc64, // PPC64: powerpc64, ppu ppc64le, // PPC64LE: powerpc64le r600, // R600: AMD GPUs HD2XXX - HD6XXX amdgcn, // AMDGCN: AMD GCN GPUs riscv32, // RISC-V (32-bit): riscv32 riscv64, // RISC-V (64-bit): riscv64 sparc, // Sparc: sparc sparcv9, // Sparcv9: Sparcv9 sparcel, // Sparc: (endianness = little). NB: 'Sparcle' is a CPU variant systemz, // SystemZ: s390x tce, // TCE (http://tce.cs.tut.fi/): tce tcele, // TCE little endian (http://tce.cs.tut.fi/): tcele thumb, // Thumb (little endian): thumb, thumbv.* thumbeb, // Thumb (big endian): thumbeb x86, // X86: i[3-9]86 x86_64, // X86-64: amd64, x86_64 xcore, // XCore: xcore xtensa, // Tensilica: Xtensa nvptx, // NVPTX: 32-bit nvptx64, // NVPTX: 64-bit le32, // le32: generic little-endian 32-bit CPU (PNaCl) le64, // le64: generic little-endian 64-bit CPU (PNaCl) amdil, // AMDIL amdil64, // AMDIL with 64-bit pointers hsail, // AMD HSAIL hsail64, // AMD HSAIL with 64-bit pointers spir, // SPIR: standard portable IR for OpenCL 32-bit version spir64, // SPIR: standard portable IR for OpenCL 64-bit version spirv32, // SPIR-V with 32-bit pointers spirv64, // SPIR-V with 64-bit pointers kalimba, // Kalimba: generic kalimba shave, // SHAVE: Movidius vector VLIW processors lanai, // Lanai: Lanai 32-bit wasm32, // WebAssembly with 32-bit pointers wasm64, // WebAssembly with 64-bit pointers renderscript32, // 32-bit RenderScript renderscript64, // 64-bit RenderScript ve, // NEC SX-Aurora Vector Engine LastArchType = ve }; enum SubArchType { NoSubArch, ARMSubArch_v9_4a, ARMSubArch_v9_3a, ARMSubArch_v9_2a, ARMSubArch_v9_1a, ARMSubArch_v9, ARMSubArch_v8_9a, ARMSubArch_v8_8a, ARMSubArch_v8_7a, ARMSubArch_v8_6a, ARMSubArch_v8_5a, ARMSubArch_v8_4a, ARMSubArch_v8_3a, ARMSubArch_v8_2a, ARMSubArch_v8_1a, ARMSubArch_v8, ARMSubArch_v8r, ARMSubArch_v8m_baseline, ARMSubArch_v8m_mainline, ARMSubArch_v8_1m_mainline, ARMSubArch_v7, ARMSubArch_v7em, ARMSubArch_v7m, ARMSubArch_v7s, ARMSubArch_v7k, ARMSubArch_v7ve, ARMSubArch_v6, ARMSubArch_v6m, ARMSubArch_v6k, ARMSubArch_v6t2, ARMSubArch_v5, ARMSubArch_v5te, ARMSubArch_v4t, AArch64SubArch_arm64e, AArch64SubArch_arm64ec, KalimbaSubArch_v3, KalimbaSubArch_v4, KalimbaSubArch_v5, MipsSubArch_r6, PPCSubArch_spe, // SPIR-V sub-arch corresponds to its version. SPIRVSubArch_v10, SPIRVSubArch_v11, SPIRVSubArch_v12, SPIRVSubArch_v13, SPIRVSubArch_v14, SPIRVSubArch_v15, }; enum VendorType { UnknownVendor, Apple, PC, SCEI, Freescale, IBM, ImaginationTechnologies, MipsTechnologies, NVIDIA, CSR, Myriad, AMD, Mesa, SUSE, OpenEmbedded, LastVendorType = OpenEmbedded }; enum OSType { UnknownOS, Ananas, CloudABI, Darwin, DragonFly, FreeBSD, Fuchsia, IOS, KFreeBSD, Linux, Lv2, // PS3 MacOSX, NetBSD, OpenBSD, Solaris, Win32, ZOS, Haiku, Minix, RTEMS, NaCl, // Native Client AIX, CUDA, // NVIDIA CUDA NVCL, // NVIDIA OpenCL AMDHSA, // AMD HSA Runtime PS4, PS5, ELFIAMCU, TvOS, // Apple tvOS WatchOS, // Apple watchOS DriverKit, // Apple DriverKit Mesa3D, Contiki, AMDPAL, // AMD PAL Runtime HermitCore, // HermitCore Unikernel/Multikernel Hurd, // GNU/Hurd WASI, // Experimental WebAssembly OS Emscripten, ShaderModel, // DirectX ShaderModel LastOSType = ShaderModel }; enum EnvironmentType { UnknownEnvironment, GNU, GNUABIN32, GNUABI64, GNUEABI, GNUEABIHF, GNUF32, GNUF64, GNUSF, GNUX32, GNUILP32, CODE16, EABI, EABIHF, Android, Musl, MuslEABI, MuslEABIHF, MuslX32, MSVC, Itanium, Cygnus, CoreCLR, Simulator, // Simulator variants of other systems, e.g., Apple's iOS MacABI, // Mac Catalyst variant of Apple's iOS deployment target. // Shader Stages // The order of these values matters, and must be kept in sync with the // language options enum in Clang. The ordering is enforced in // static_asserts in Triple.cpp and in Clang. Pixel, Vertex, Geometry, Hull, Domain, Compute, Library, RayGeneration, Intersection, AnyHit, ClosestHit, Miss, Callable, Mesh, Amplification, LastEnvironmentType = Amplification }; enum ObjectFormatType { UnknownObjectFormat, COFF, DXContainer, ELF, GOFF, MachO, SPIRV, Wasm, XCOFF, }; private: std::string Data; /// The parsed arch type. ArchType Arch{}; /// The parsed subarchitecture type. SubArchType SubArch{}; /// The parsed vendor type. VendorType Vendor{}; /// The parsed OS type. OSType OS{}; /// The parsed Environment type. EnvironmentType Environment{}; /// The object format type. ObjectFormatType ObjectFormat{}; public: /// @name Constructors /// @{ /// Default constructor is the same as an empty string and leaves all /// triple fields unknown. Triple() = default; explicit Triple(const Twine &Str); Triple(const Twine &ArchStr, const Twine &VendorStr, const Twine &OSStr); Triple(const Twine &ArchStr, const Twine &VendorStr, const Twine &OSStr, const Twine &EnvironmentStr); bool operator==(const Triple &Other) const { return Arch == Other.Arch && SubArch == Other.SubArch && Vendor == Other.Vendor && OS == Other.OS && Environment == Other.Environment && ObjectFormat == Other.ObjectFormat; } bool operator!=(const Triple &Other) const { return !(*this == Other); } /// @} /// @name Normalization /// @{ /// Turn an arbitrary machine specification into the canonical triple form (or /// something sensible that the Triple class understands if nothing better can /// reasonably be done). In particular, it handles the common case in which /// otherwise valid components are in the wrong order. static std::string normalize(StringRef Str); /// Return the normalized form of this triple's string. std::string normalize() const { return normalize(Data); } /// @} /// @name Typed Component Access /// @{ /// Get the parsed architecture type of this triple. ArchType getArch() const { return Arch; } /// get the parsed subarchitecture type for this triple. SubArchType getSubArch() const { return SubArch; } /// Get the parsed vendor type of this triple. VendorType getVendor() const { return Vendor; } /// Get the parsed operating system type of this triple. OSType getOS() const { return OS; } /// Does this triple have the optional environment (fourth) component? bool hasEnvironment() const { return getEnvironmentName() != ""; } /// Get the parsed environment type of this triple. EnvironmentType getEnvironment() const { return Environment; } /// Parse the version number from the OS name component of the /// triple, if present. /// /// For example, "fooos1.2.3" would return (1, 2, 3). VersionTuple getEnvironmentVersion() const; /// Get the object format for this triple. ObjectFormatType getObjectFormat() const { return ObjectFormat; } /// Parse the version number from the OS name component of the triple, if /// present. /// /// For example, "fooos1.2.3" would return (1, 2, 3). VersionTuple getOSVersion() const; /// Return just the major version number, this is specialized because it is a /// common query. unsigned getOSMajorVersion() const { return getOSVersion().getMajor(); } /// Parse the version number as with getOSVersion and then translate generic /// "darwin" versions to the corresponding OS X versions. This may also be /// called with IOS triples but the OS X version number is just set to a /// constant 10.4.0 in that case. Returns true if successful. bool getMacOSXVersion(VersionTuple &Version) const; /// Parse the version number as with getOSVersion. This should only be called /// with IOS or generic triples. VersionTuple getiOSVersion() const; /// Parse the version number as with getOSVersion. This should only be called /// with WatchOS or generic triples. VersionTuple getWatchOSVersion() const; /// Parse the version number as with getOSVersion. VersionTuple getDriverKitVersion() const; /// @} /// @name Direct Component Access /// @{ const std::string &str() const { return Data; } const std::string &getTriple() const { return Data; } /// Get the architecture (first) component of the triple. StringRef getArchName() const; /// Get the architecture name based on Kind and SubArch. StringRef getArchName(ArchType Kind, SubArchType SubArch = NoSubArch) const; /// Get the vendor (second) component of the triple. StringRef getVendorName() const; /// Get the operating system (third) component of the triple. StringRef getOSName() const; /// Get the optional environment (fourth) component of the triple, or "" if /// empty. StringRef getEnvironmentName() const; /// Get the operating system and optional environment components as a single /// string (separated by a '-' if the environment component is present). StringRef getOSAndEnvironmentName() const; /// @} /// @name Convenience Predicates /// @{ /// Test whether the architecture is 64-bit /// /// Note that this tests for 64-bit pointer width, and nothing else. Note /// that we intentionally expose only three predicates, 64-bit, 32-bit, and /// 16-bit. The inner details of pointer width for particular architectures /// is not summed up in the triple, and so only a coarse grained predicate /// system is provided. bool isArch64Bit() const; /// Test whether the architecture is 32-bit /// /// Note that this tests for 32-bit pointer width, and nothing else. bool isArch32Bit() const; /// Test whether the architecture is 16-bit /// /// Note that this tests for 16-bit pointer width, and nothing else. bool isArch16Bit() const; /// Helper function for doing comparisons against version numbers included in /// the target triple. bool isOSVersionLT(unsigned Major, unsigned Minor = 0, unsigned Micro = 0) const { if (Minor == 0) { return getOSVersion() < VersionTuple(Major); } if (Micro == 0) { return getOSVersion() < VersionTuple(Major, Minor); } return getOSVersion() < VersionTuple(Major, Minor, Micro); } bool isOSVersionLT(const Triple &Other) const { return getOSVersion() < Other.getOSVersion(); } /// Comparison function for checking OS X version compatibility, which handles /// supporting skewed version numbering schemes used by the "darwin" triples. bool isMacOSXVersionLT(unsigned Major, unsigned Minor = 0, unsigned Micro = 0) const; /// Is this a Mac OS X triple. For legacy reasons, we support both "darwin" /// and "osx" as OS X triples. bool isMacOSX() const { return getOS() == Triple::Darwin || getOS() == Triple::MacOSX; } /// Is this an iOS triple. /// Note: This identifies tvOS as a variant of iOS. If that ever /// changes, i.e., if the two operating systems diverge or their version /// numbers get out of sync, that will need to be changed. /// watchOS has completely different version numbers so it is not included. bool isiOS() const { return getOS() == Triple::IOS || isTvOS(); } /// Is this an Apple tvOS triple. bool isTvOS() const { return getOS() == Triple::TvOS; } /// Is this an Apple watchOS triple. bool isWatchOS() const { return getOS() == Triple::WatchOS; } bool isWatchABI() const { return getSubArch() == Triple::ARMSubArch_v7k; } /// Is this an Apple DriverKit triple. bool isDriverKit() const { return getOS() == Triple::DriverKit; } bool isOSzOS() const { return getOS() == Triple::ZOS; } /// Is this a "Darwin" OS (macOS, iOS, tvOS, watchOS, or DriverKit). bool isOSDarwin() const { return isMacOSX() || isiOS() || isWatchOS() || isDriverKit(); } bool isSimulatorEnvironment() const { return getEnvironment() == Triple::Simulator; } bool isMacCatalystEnvironment() const { return getEnvironment() == Triple::MacABI; } /// Returns true for targets that run on a macOS machine. bool isTargetMachineMac() const { return isMacOSX() || (isOSDarwin() && (isSimulatorEnvironment() || isMacCatalystEnvironment())); } bool isOSNetBSD() const { return getOS() == Triple::NetBSD; } bool isOSOpenBSD() const { return getOS() == Triple::OpenBSD; } bool isOSFreeBSD() const { return getOS() == Triple::FreeBSD; } bool isOSFuchsia() const { return getOS() == Triple::Fuchsia; } bool isOSDragonFly() const { return getOS() == Triple::DragonFly; } bool isOSSolaris() const { return getOS() == Triple::Solaris; } bool isOSIAMCU() const { return getOS() == Triple::ELFIAMCU; } bool isOSUnknown() const { return getOS() == Triple::UnknownOS; } bool isGNUEnvironment() const { EnvironmentType Env = getEnvironment(); return Env == Triple::GNU || Env == Triple::GNUABIN32 || Env == Triple::GNUABI64 || Env == Triple::GNUEABI || Env == Triple::GNUEABIHF || Env == Triple::GNUF32 || Env == Triple::GNUF64 || Env == Triple::GNUSF || Env == Triple::GNUX32; } bool isOSContiki() const { return getOS() == Triple::Contiki; } /// Tests whether the OS is Haiku. bool isOSHaiku() const { return getOS() == Triple::Haiku; } /// Tests whether the OS is Windows. bool isOSWindows() const { return getOS() == Triple::Win32; } /// Checks if the environment is MSVC. bool isKnownWindowsMSVCEnvironment() const { return isOSWindows() && getEnvironment() == Triple::MSVC; } /// Checks if the environment could be MSVC. bool isWindowsMSVCEnvironment() const { return isKnownWindowsMSVCEnvironment() || (isOSWindows() && getEnvironment() == Triple::UnknownEnvironment); } // Checks if we're using the Windows Arm64EC ABI. bool isWindowsArm64EC() const { return getArch() == Triple::aarch64 && getSubArch() == Triple::AArch64SubArch_arm64ec; } bool isWindowsCoreCLREnvironment() const { return isOSWindows() && getEnvironment() == Triple::CoreCLR; } bool isWindowsItaniumEnvironment() const { return isOSWindows() && getEnvironment() == Triple::Itanium; } bool isWindowsCygwinEnvironment() const { return isOSWindows() && getEnvironment() == Triple::Cygnus; } bool isWindowsGNUEnvironment() const { return isOSWindows() && getEnvironment() == Triple::GNU; } /// Tests for either Cygwin or MinGW OS bool isOSCygMing() const { return isWindowsCygwinEnvironment() || isWindowsGNUEnvironment(); } /// Is this a "Windows" OS targeting a "MSVCRT.dll" environment. bool isOSMSVCRT() const { return isWindowsMSVCEnvironment() || isWindowsGNUEnvironment() || isWindowsItaniumEnvironment(); } /// Tests whether the OS is NaCl (Native Client) bool isOSNaCl() const { return getOS() == Triple::NaCl; } /// Tests whether the OS is Linux. bool isOSLinux() const { return getOS() == Triple::Linux; } /// Tests whether the OS is kFreeBSD. bool isOSKFreeBSD() const { return getOS() == Triple::KFreeBSD; } /// Tests whether the OS is Hurd. bool isOSHurd() const { return getOS() == Triple::Hurd; } /// Tests whether the OS is WASI. bool isOSWASI() const { return getOS() == Triple::WASI; } /// Tests whether the OS is Emscripten. bool isOSEmscripten() const { return getOS() == Triple::Emscripten; } /// Tests whether the OS uses glibc. bool isOSGlibc() const { return (getOS() == Triple::Linux || getOS() == Triple::KFreeBSD || getOS() == Triple::Hurd) && !isAndroid(); } /// Tests whether the OS is AIX. bool isOSAIX() const { return getOS() == Triple::AIX; } /// Tests whether the OS uses the ELF binary format. bool isOSBinFormatELF() const { return getObjectFormat() == Triple::ELF; } /// Tests whether the OS uses the COFF binary format. bool isOSBinFormatCOFF() const { return getObjectFormat() == Triple::COFF; } /// Tests whether the OS uses the GOFF binary format. bool isOSBinFormatGOFF() const { return getObjectFormat() == Triple::GOFF; } /// Tests whether the environment is MachO. bool isOSBinFormatMachO() const { return getObjectFormat() == Triple::MachO; } /// Tests whether the OS uses the Wasm binary format. bool isOSBinFormatWasm() const { return getObjectFormat() == Triple::Wasm; } /// Tests whether the OS uses the XCOFF binary format. bool isOSBinFormatXCOFF() const { return getObjectFormat() == Triple::XCOFF; } /// Tests whether the OS uses the DXContainer binary format. bool isOSBinFormatDXContainer() const { return getObjectFormat() == Triple::DXContainer; } /// Tests whether the target is the PS4 platform. bool isPS4() const { return getArch() == Triple::x86_64 && getVendor() == Triple::SCEI && getOS() == Triple::PS4; } /// Tests whether the target is the PS5 platform. bool isPS5() const { return getArch() == Triple::x86_64 && getVendor() == Triple::SCEI && getOS() == Triple::PS5; } /// Tests whether the target is the PS4 or PS5 platform. bool isPS() const { return isPS4() || isPS5(); } /// Tests whether the target is Android bool isAndroid() const { return getEnvironment() == Triple::Android; } bool isAndroidVersionLT(unsigned Major) const { assert(isAndroid() && "Not an Android triple!"); VersionTuple Version = getEnvironmentVersion(); // 64-bit targets did not exist before API level 21 (Lollipop). if (isArch64Bit() && Version.getMajor() < 21) return VersionTuple(21) < VersionTuple(Major); return Version < VersionTuple(Major); } /// Tests whether the environment is musl-libc bool isMusl() const { return getEnvironment() == Triple::Musl || getEnvironment() == Triple::MuslEABI || getEnvironment() == Triple::MuslEABIHF || getEnvironment() == Triple::MuslX32; } /// Tests whether the target is DXIL. bool isDXIL() const { return getArch() == Triple::dxil; } /// Tests whether the target is SPIR (32- or 64-bit). bool isSPIR() const { return getArch() == Triple::spir || getArch() == Triple::spir64; } /// Tests whether the target is SPIR-V (32/64-bit). bool isSPIRV() const { return getArch() == Triple::spirv32 || getArch() == Triple::spirv64; } /// Tests whether the target is NVPTX (32- or 64-bit). bool isNVPTX() const { return getArch() == Triple::nvptx || getArch() == Triple::nvptx64; } /// Tests whether the target is AMDGCN bool isAMDGCN() const { return getArch() == Triple::amdgcn; } bool isAMDGPU() const { return getArch() == Triple::r600 || getArch() == Triple::amdgcn; } /// Tests whether the target is Thumb (little and big endian). bool isThumb() const { return getArch() == Triple::thumb || getArch() == Triple::thumbeb; } /// Tests whether the target is ARM (little and big endian). bool isARM() const { return getArch() == Triple::arm || getArch() == Triple::armeb; } /// Tests whether the target supports the EHABI exception /// handling standard. bool isTargetEHABICompatible() const { return (isARM() || isThumb()) && (getEnvironment() == Triple::EABI || getEnvironment() == Triple::GNUEABI || getEnvironment() == Triple::MuslEABI || getEnvironment() == Triple::EABIHF || getEnvironment() == Triple::GNUEABIHF || getEnvironment() == Triple::MuslEABIHF || isAndroid()) && isOSBinFormatELF(); } /// Tests whether the target is T32. bool isArmT32() const { switch (getSubArch()) { case Triple::ARMSubArch_v8m_baseline: case Triple::ARMSubArch_v7s: case Triple::ARMSubArch_v7k: case Triple::ARMSubArch_v7ve: case Triple::ARMSubArch_v6: case Triple::ARMSubArch_v6m: case Triple::ARMSubArch_v6k: case Triple::ARMSubArch_v6t2: case Triple::ARMSubArch_v5: case Triple::ARMSubArch_v5te: case Triple::ARMSubArch_v4t: return false; default: return true; } } /// Tests whether the target is an M-class. bool isArmMClass() const { switch (getSubArch()) { case Triple::ARMSubArch_v6m: case Triple::ARMSubArch_v7m: case Triple::ARMSubArch_v7em: case Triple::ARMSubArch_v8m_mainline: case Triple::ARMSubArch_v8m_baseline: case Triple::ARMSubArch_v8_1m_mainline: return true; default: return false; } } /// Tests whether the target is AArch64 (little and big endian). bool isAArch64() const { return getArch() == Triple::aarch64 || getArch() == Triple::aarch64_be || getArch() == Triple::aarch64_32; } /// Tests whether the target is AArch64 and pointers are the size specified by /// \p PointerWidth. bool isAArch64(int PointerWidth) const { assert(PointerWidth == 64 || PointerWidth == 32); if (!isAArch64()) return false; return getArch() == Triple::aarch64_32 || getEnvironment() == Triple::GNUILP32 ? PointerWidth == 32 : PointerWidth == 64; } /// Tests whether the target is LoongArch (32- and 64-bit). bool isLoongArch() const { return getArch() == Triple::loongarch32 || getArch() == Triple::loongarch64; } /// Tests whether the target is MIPS 32-bit (little and big endian). bool isMIPS32() const { return getArch() == Triple::mips || getArch() == Triple::mipsel; } /// Tests whether the target is MIPS 64-bit (little and big endian). bool isMIPS64() const { return getArch() == Triple::mips64 || getArch() == Triple::mips64el; } /// Tests whether the target is MIPS (little and big endian, 32- or 64-bit). bool isMIPS() const { return isMIPS32() || isMIPS64(); } /// Tests whether the target is PowerPC (32- or 64-bit LE or BE). bool isPPC() const { return getArch() == Triple::ppc || getArch() == Triple::ppc64 || getArch() == Triple::ppcle || getArch() == Triple::ppc64le; } /// Tests whether the target is 32-bit PowerPC (little and big endian). bool isPPC32() const { return getArch() == Triple::ppc || getArch() == Triple::ppcle; } /// Tests whether the target is 64-bit PowerPC (little and big endian). bool isPPC64() const { return getArch() == Triple::ppc64 || getArch() == Triple::ppc64le; } /// Tests whether the target 64-bit PowerPC big endian ABI is ELFv2. bool isPPC64ELFv2ABI() const { return (getArch() == Triple::ppc64 && ((getOS() == Triple::FreeBSD && (getOSMajorVersion() >= 13 || getOSVersion().empty())) || getOS() == Triple::OpenBSD || isMusl())); } /// Tests whether the target is 32-bit RISC-V. bool isRISCV32() const { return getArch() == Triple::riscv32; } /// Tests whether the target is 64-bit RISC-V. bool isRISCV64() const { return getArch() == Triple::riscv64; } /// Tests whether the target is RISC-V (32- and 64-bit). bool isRISCV() const { return isRISCV32() || isRISCV64(); } /// Tests whether the target is 32-bit SPARC (little and big endian). bool isSPARC32() const { return getArch() == Triple::sparc || getArch() == Triple::sparcel; } /// Tests whether the target is 64-bit SPARC (big endian). bool isSPARC64() const { return getArch() == Triple::sparcv9; } /// Tests whether the target is SPARC. bool isSPARC() const { return isSPARC32() || isSPARC64(); } /// Tests whether the target is SystemZ. bool isSystemZ() const { return getArch() == Triple::systemz; } /// Tests whether the target is x86 (32- or 64-bit). bool isX86() const { return getArch() == Triple::x86 || getArch() == Triple::x86_64; } /// Tests whether the target is VE bool isVE() const { return getArch() == Triple::ve; } /// Tests whether the target is wasm (32- and 64-bit). bool isWasm() const { return getArch() == Triple::wasm32 || getArch() == Triple::wasm64; } // Tests whether the target is CSKY bool isCSKY() const { return getArch() == Triple::csky; } /// Tests whether the target is the Apple "arm64e" AArch64 subarch. bool isArm64e() const { return getArch() == Triple::aarch64 && getSubArch() == Triple::AArch64SubArch_arm64e; } /// Tests whether the target is X32. bool isX32() const { EnvironmentType Env = getEnvironment(); return Env == Triple::GNUX32 || Env == Triple::MuslX32; } /// Tests whether the target is eBPF. bool isBPF() const { return getArch() == Triple::bpfel || getArch() == Triple::bpfeb; } /// Tests whether the target supports comdat bool supportsCOMDAT() const { return !(isOSBinFormatMachO() || isOSBinFormatXCOFF() || isOSBinFormatDXContainer()); } /// Tests whether the target uses emulated TLS as default. bool hasDefaultEmulatedTLS() const { return isAndroid() || isOSOpenBSD() || isWindowsCygwinEnvironment(); } /// Tests whether the target uses -data-sections as default. bool hasDefaultDataSections() const { return isOSBinFormatXCOFF() || isWasm(); } /// Tests if the environment supports dllimport/export annotations. bool hasDLLImportExport() const { return isOSWindows() || isPS(); } /// @} /// @name Mutators /// @{ /// Set the architecture (first) component of the triple to a known type. void setArch(ArchType Kind, SubArchType SubArch = NoSubArch); /// Set the vendor (second) component of the triple to a known type. void setVendor(VendorType Kind); /// Set the operating system (third) component of the triple to a known type. void setOS(OSType Kind); /// Set the environment (fourth) component of the triple to a known type. void setEnvironment(EnvironmentType Kind); /// Set the object file format. void setObjectFormat(ObjectFormatType Kind); /// Set all components to the new triple \p Str. void setTriple(const Twine &Str); /// Set the architecture (first) component of the triple by name. void setArchName(StringRef Str); /// Set the vendor (second) component of the triple by name. void setVendorName(StringRef Str); /// Set the operating system (third) component of the triple by name. void setOSName(StringRef Str); /// Set the optional environment (fourth) component of the triple by name. void setEnvironmentName(StringRef Str); /// Set the operating system and optional environment components with a single /// string. void setOSAndEnvironmentName(StringRef Str); /// @} /// @name Helpers to build variants of a particular triple. /// @{ /// Form a triple with a 32-bit variant of the current architecture. /// /// This can be used to move across "families" of architectures where useful. /// /// \returns A new triple with a 32-bit architecture or an unknown /// architecture if no such variant can be found. llvm::Triple get32BitArchVariant() const; /// Form a triple with a 64-bit variant of the current architecture. /// /// This can be used to move across "families" of architectures where useful. /// /// \returns A new triple with a 64-bit architecture or an unknown /// architecture if no such variant can be found. llvm::Triple get64BitArchVariant() const; /// Form a triple with a big endian variant of the current architecture. /// /// This can be used to move across "families" of architectures where useful. /// /// \returns A new triple with a big endian architecture or an unknown /// architecture if no such variant can be found. llvm::Triple getBigEndianArchVariant() const; /// Form a triple with a little endian variant of the current architecture. /// /// This can be used to move across "families" of architectures where useful. /// /// \returns A new triple with a little endian architecture or an unknown /// architecture if no such variant can be found. llvm::Triple getLittleEndianArchVariant() const; /// Tests whether the target triple is little endian. /// /// \returns true if the triple is little endian, false otherwise. bool isLittleEndian() const; /// Test whether target triples are compatible. bool isCompatibleWith(const Triple &Other) const; /// Merge target triples. std::string merge(const Triple &Other) const; /// Some platforms have different minimum supported OS versions that /// varies by the architecture specified in the triple. This function /// returns the minimum supported OS version for this triple if one an exists, /// or an invalid version tuple if this triple doesn't have one. VersionTuple getMinimumSupportedOSVersion() const; /// @} /// @name Static helpers for IDs. /// @{ /// Get the canonical name for the \p Kind architecture. static StringRef getArchTypeName(ArchType Kind); /// Get the "prefix" canonical name for the \p Kind architecture. This is the /// prefix used by the architecture specific builtins, and is suitable for /// passing to \see Intrinsic::getIntrinsicForClangBuiltin(). /// /// \return - The architecture prefix, or 0 if none is defined. static StringRef getArchTypePrefix(ArchType Kind); /// Get the canonical name for the \p Kind vendor. static StringRef getVendorTypeName(VendorType Kind); /// Get the canonical name for the \p Kind operating system. static StringRef getOSTypeName(OSType Kind); /// Get the canonical name for the \p Kind environment. static StringRef getEnvironmentTypeName(EnvironmentType Kind); /// @} /// @name Static helpers for converting alternate architecture names. /// @{ /// The canonical type for the given LLVM architecture name (e.g., "x86"). static ArchType getArchTypeForLLVMName(StringRef Str); /// @} /// Returns a canonicalized OS version number for the specified OS. static VersionTuple getCanonicalVersionForOS(OSType OSKind, const VersionTuple &Version); }; } // End llvm namespace #endif