//===--- ARM.cpp - Implement ARM target feature support -------------------===// // // 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 ARM TargetInfo objects. // //===----------------------------------------------------------------------===// #include "ARM.h" #include "clang/Basic/Builtins.h" #include "clang/Basic/Diagnostic.h" #include "clang/Basic/TargetBuiltins.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/StringSwitch.h" using namespace clang; using namespace clang::targets; void ARMTargetInfo::setABIAAPCS() { IsAAPCS = true; DoubleAlign = LongLongAlign = LongDoubleAlign = SuitableAlign = 64; BFloat16Width = BFloat16Align = 16; BFloat16Format = &llvm::APFloat::BFloat(); const llvm::Triple &T = getTriple(); bool IsNetBSD = T.isOSNetBSD(); bool IsOpenBSD = T.isOSOpenBSD(); if (!T.isOSWindows() && !IsNetBSD && !IsOpenBSD) WCharType = UnsignedInt; UseBitFieldTypeAlignment = true; ZeroLengthBitfieldBoundary = 0; // Thumb1 add sp, #imm requires the immediate value be multiple of 4, // so set preferred for small types to 32. if (T.isOSBinFormatMachO()) { resetDataLayout(BigEndian ? "E-m:o-p:32:32-Fi8-i64:64-v128:64:128-a:0:32-n32-S64" : "e-m:o-p:32:32-Fi8-i64:64-v128:64:128-a:0:32-n32-S64", "_"); } else if (T.isOSWindows()) { assert(!BigEndian && "Windows on ARM does not support big endian"); resetDataLayout("e" "-m:w" "-p:32:32" "-Fi8" "-i64:64" "-v128:64:128" "-a:0:32" "-n32" "-S64"); } else if (T.isOSNaCl()) { assert(!BigEndian && "NaCl on ARM does not support big endian"); resetDataLayout("e-m:e-p:32:32-Fi8-i64:64-v128:64:128-a:0:32-n32-S128"); } else { resetDataLayout(BigEndian ? "E-m:e-p:32:32-Fi8-i64:64-v128:64:128-a:0:32-n32-S64" : "e-m:e-p:32:32-Fi8-i64:64-v128:64:128-a:0:32-n32-S64"); } // FIXME: Enumerated types are variable width in straight AAPCS. } void ARMTargetInfo::setABIAPCS(bool IsAAPCS16) { const llvm::Triple &T = getTriple(); IsAAPCS = false; if (IsAAPCS16) DoubleAlign = LongLongAlign = LongDoubleAlign = SuitableAlign = 64; else DoubleAlign = LongLongAlign = LongDoubleAlign = SuitableAlign = 32; BFloat16Width = BFloat16Align = 16; BFloat16Format = &llvm::APFloat::BFloat(); WCharType = SignedInt; // Do not respect the alignment of bit-field types when laying out // structures. This corresponds to PCC_BITFIELD_TYPE_MATTERS in gcc. UseBitFieldTypeAlignment = false; /// gcc forces the alignment to 4 bytes, regardless of the type of the /// zero length bitfield. This corresponds to EMPTY_FIELD_BOUNDARY in /// gcc. ZeroLengthBitfieldBoundary = 32; if (T.isOSBinFormatMachO() && IsAAPCS16) { assert(!BigEndian && "AAPCS16 does not support big-endian"); resetDataLayout("e-m:o-p:32:32-Fi8-i64:64-a:0:32-n32-S128", "_"); } else if (T.isOSBinFormatMachO()) resetDataLayout( BigEndian ? "E-m:o-p:32:32-Fi8-f64:32:64-v64:32:64-v128:32:128-a:0:32-n32-S32" : "e-m:o-p:32:32-Fi8-f64:32:64-v64:32:64-v128:32:128-a:0:32-n32-S32", "_"); else resetDataLayout( BigEndian ? "E-m:e-p:32:32-Fi8-f64:32:64-v64:32:64-v128:32:128-a:0:32-n32-S32" : "e-m:e-p:32:32-Fi8-f64:32:64-v64:32:64-v128:32:128-a:0:32-n32-S32"); // FIXME: Override "preferred align" for double and long long. } void ARMTargetInfo::setArchInfo() { StringRef ArchName = getTriple().getArchName(); ArchISA = llvm::ARM::parseArchISA(ArchName); CPU = std::string(llvm::ARM::getDefaultCPU(ArchName)); llvm::ARM::ArchKind AK = llvm::ARM::parseArch(ArchName); if (AK != llvm::ARM::ArchKind::INVALID) ArchKind = AK; setArchInfo(ArchKind); } void ARMTargetInfo::setArchInfo(llvm::ARM::ArchKind Kind) { StringRef SubArch; // cache TargetParser info ArchKind = Kind; SubArch = llvm::ARM::getSubArch(ArchKind); ArchProfile = llvm::ARM::parseArchProfile(SubArch); ArchVersion = llvm::ARM::parseArchVersion(SubArch); // cache CPU related strings CPUAttr = getCPUAttr(); CPUProfile = getCPUProfile(); } void ARMTargetInfo::setAtomic() { // when triple does not specify a sub arch, // then we are not using inline atomics bool ShouldUseInlineAtomic = (ArchISA == llvm::ARM::ISAKind::ARM && ArchVersion >= 6) || (ArchISA == llvm::ARM::ISAKind::THUMB && ArchVersion >= 7); // Cortex M does not support 8 byte atomics, while general Thumb2 does. if (ArchProfile == llvm::ARM::ProfileKind::M) { MaxAtomicPromoteWidth = 32; if (ShouldUseInlineAtomic) MaxAtomicInlineWidth = 32; } else { MaxAtomicPromoteWidth = 64; if (ShouldUseInlineAtomic) MaxAtomicInlineWidth = 64; } } bool ARMTargetInfo::hasMVE() const { return ArchKind == llvm::ARM::ArchKind::ARMV8_1MMainline && MVE != 0; } bool ARMTargetInfo::hasMVEFloat() const { return hasMVE() && (MVE & MVE_FP); } bool ARMTargetInfo::hasCDE() const { return getARMCDECoprocMask() != 0; } bool ARMTargetInfo::isThumb() const { return ArchISA == llvm::ARM::ISAKind::THUMB; } bool ARMTargetInfo::supportsThumb() const { return CPUAttr.count('T') || ArchVersion >= 6; } bool ARMTargetInfo::supportsThumb2() const { return CPUAttr.equals("6T2") || (ArchVersion >= 7 && !CPUAttr.equals("8M_BASE")); } StringRef ARMTargetInfo::getCPUAttr() const { // For most sub-arches, the build attribute CPU name is enough. // For Cortex variants, it's slightly different. switch (ArchKind) { default: return llvm::ARM::getCPUAttr(ArchKind); case llvm::ARM::ArchKind::ARMV6M: return "6M"; case llvm::ARM::ArchKind::ARMV7S: return "7S"; case llvm::ARM::ArchKind::ARMV7A: return "7A"; case llvm::ARM::ArchKind::ARMV7R: return "7R"; case llvm::ARM::ArchKind::ARMV7M: return "7M"; case llvm::ARM::ArchKind::ARMV7EM: return "7EM"; case llvm::ARM::ArchKind::ARMV7VE: return "7VE"; case llvm::ARM::ArchKind::ARMV8A: return "8A"; case llvm::ARM::ArchKind::ARMV8_1A: return "8_1A"; case llvm::ARM::ArchKind::ARMV8_2A: return "8_2A"; case llvm::ARM::ArchKind::ARMV8_3A: return "8_3A"; case llvm::ARM::ArchKind::ARMV8_4A: return "8_4A"; case llvm::ARM::ArchKind::ARMV8_5A: return "8_5A"; case llvm::ARM::ArchKind::ARMV8_6A: return "8_6A"; case llvm::ARM::ArchKind::ARMV8_7A: return "8_7A"; case llvm::ARM::ArchKind::ARMV8_8A: return "8_8A"; case llvm::ARM::ArchKind::ARMV9A: return "9A"; case llvm::ARM::ArchKind::ARMV9_1A: return "9_1A"; case llvm::ARM::ArchKind::ARMV9_2A: return "9_2A"; case llvm::ARM::ArchKind::ARMV9_3A: return "9_3A"; case llvm::ARM::ArchKind::ARMV8MBaseline: return "8M_BASE"; case llvm::ARM::ArchKind::ARMV8MMainline: return "8M_MAIN"; case llvm::ARM::ArchKind::ARMV8R: return "8R"; case llvm::ARM::ArchKind::ARMV8_1MMainline: return "8_1M_MAIN"; } } StringRef ARMTargetInfo::getCPUProfile() const { switch (ArchProfile) { case llvm::ARM::ProfileKind::A: return "A"; case llvm::ARM::ProfileKind::R: return "R"; case llvm::ARM::ProfileKind::M: return "M"; default: return ""; } } ARMTargetInfo::ARMTargetInfo(const llvm::Triple &Triple, const TargetOptions &Opts) : TargetInfo(Triple), FPMath(FP_Default), IsAAPCS(true), LDREX(0), HW_FP(0) { bool IsOpenBSD = Triple.isOSOpenBSD(); bool IsNetBSD = Triple.isOSNetBSD(); // FIXME: the isOSBinFormatMachO is a workaround for identifying a Darwin-like // environment where size_t is `unsigned long` rather than `unsigned int` PtrDiffType = IntPtrType = (Triple.isOSDarwin() || Triple.isOSBinFormatMachO() || IsOpenBSD || IsNetBSD) ? SignedLong : SignedInt; SizeType = (Triple.isOSDarwin() || Triple.isOSBinFormatMachO() || IsOpenBSD || IsNetBSD) ? UnsignedLong : UnsignedInt; // ptrdiff_t is inconsistent on Darwin if ((Triple.isOSDarwin() || Triple.isOSBinFormatMachO()) && !Triple.isWatchABI()) PtrDiffType = SignedInt; // Cache arch related info. setArchInfo(); // {} in inline assembly are neon specifiers, not assembly variant // specifiers. NoAsmVariants = true; // FIXME: This duplicates code from the driver that sets the -target-abi // option - this code is used if -target-abi isn't passed and should // be unified in some way. if (Triple.isOSBinFormatMachO()) { // The backend is hardwired to assume AAPCS for M-class processors, ensure // the frontend matches that. if (Triple.getEnvironment() == llvm::Triple::EABI || Triple.getOS() == llvm::Triple::UnknownOS || ArchProfile == llvm::ARM::ProfileKind::M) { setABI("aapcs"); } else if (Triple.isWatchABI()) { setABI("aapcs16"); } else { setABI("apcs-gnu"); } } else if (Triple.isOSWindows()) { // FIXME: this is invalid for WindowsCE setABI("aapcs"); } else { // Select the default based on the platform. switch (Triple.getEnvironment()) { case llvm::Triple::Android: case llvm::Triple::GNUEABI: case llvm::Triple::GNUEABIHF: case llvm::Triple::MuslEABI: case llvm::Triple::MuslEABIHF: setABI("aapcs-linux"); break; case llvm::Triple::EABIHF: case llvm::Triple::EABI: setABI("aapcs"); break; case llvm::Triple::GNU: setABI("apcs-gnu"); break; default: if (IsNetBSD) setABI("apcs-gnu"); else if (IsOpenBSD) setABI("aapcs-linux"); else setABI("aapcs"); break; } } // ARM targets default to using the ARM C++ ABI. TheCXXABI.set(TargetCXXABI::GenericARM); // ARM has atomics up to 8 bytes setAtomic(); // Maximum alignment for ARM NEON data types should be 64-bits (AAPCS) // as well the default alignment if (IsAAPCS && !Triple.isAndroid()) DefaultAlignForAttributeAligned = MaxVectorAlign = 64; // Do force alignment of members that follow zero length bitfields. If // the alignment of the zero-length bitfield is greater than the member // that follows it, `bar', `bar' will be aligned as the type of the // zero length bitfield. UseZeroLengthBitfieldAlignment = true; if (Triple.getOS() == llvm::Triple::Linux || Triple.getOS() == llvm::Triple::UnknownOS) this->MCountName = Opts.EABIVersion == llvm::EABI::GNU ? "llvm.arm.gnu.eabi.mcount" : "\01mcount"; SoftFloatABI = llvm::is_contained(Opts.FeaturesAsWritten, "+soft-float-abi"); } StringRef ARMTargetInfo::getABI() const { return ABI; } bool ARMTargetInfo::setABI(const std::string &Name) { ABI = Name; // The defaults (above) are for AAPCS, check if we need to change them. // // FIXME: We need support for -meabi... we could just mangle it into the // name. if (Name == "apcs-gnu" || Name == "aapcs16") { setABIAPCS(Name == "aapcs16"); return true; } if (Name == "aapcs" || Name == "aapcs-vfp" || Name == "aapcs-linux") { setABIAAPCS(); return true; } return false; } bool ARMTargetInfo::isBranchProtectionSupportedArch(StringRef Arch) const { llvm::ARM::ArchKind CPUArch = llvm::ARM::parseCPUArch(Arch); if (CPUArch == llvm::ARM::ArchKind::INVALID) CPUArch = llvm::ARM::parseArch(getTriple().getArchName()); if (CPUArch == llvm::ARM::ArchKind::INVALID) return false; StringRef ArchFeature = llvm::ARM::getArchName(CPUArch); auto a = llvm::Triple(ArchFeature, getTriple().getVendorName(), getTriple().getOSName(), getTriple().getEnvironmentName()); StringRef SubArch = llvm::ARM::getSubArch(CPUArch); llvm::ARM::ProfileKind Profile = llvm::ARM::parseArchProfile(SubArch); return a.isArmT32() && (Profile == llvm::ARM::ProfileKind::M); } bool ARMTargetInfo::validateBranchProtection(StringRef Spec, StringRef Arch, BranchProtectionInfo &BPI, StringRef &Err) const { llvm::ARM::ParsedBranchProtection PBP; if (!llvm::ARM::parseBranchProtection(Spec, PBP, Err)) return false; if (!isBranchProtectionSupportedArch(Arch)) return false; BPI.SignReturnAddr = llvm::StringSwitch(PBP.Scope) .Case("non-leaf", LangOptions::SignReturnAddressScopeKind::NonLeaf) .Case("all", LangOptions::SignReturnAddressScopeKind::All) .Default(LangOptions::SignReturnAddressScopeKind::None); // Don't care for the sign key, beyond issuing a warning. if (PBP.Key == "b_key") Err = "b-key"; BPI.SignKey = LangOptions::SignReturnAddressKeyKind::AKey; BPI.BranchTargetEnforcement = PBP.BranchTargetEnforcement; return true; } // FIXME: This should be based on Arch attributes, not CPU names. bool ARMTargetInfo::initFeatureMap( llvm::StringMap &Features, DiagnosticsEngine &Diags, StringRef CPU, const std::vector &FeaturesVec) const { std::string ArchFeature; std::vector TargetFeatures; llvm::ARM::ArchKind Arch = llvm::ARM::parseArch(getTriple().getArchName()); // Map the base architecture to an appropriate target feature, so we don't // rely on the target triple. llvm::ARM::ArchKind CPUArch = llvm::ARM::parseCPUArch(CPU); if (CPUArch == llvm::ARM::ArchKind::INVALID) CPUArch = Arch; if (CPUArch != llvm::ARM::ArchKind::INVALID) { ArchFeature = ("+" + llvm::ARM::getArchName(CPUArch)).str(); TargetFeatures.push_back(ArchFeature); } // get default FPU features unsigned FPUKind = llvm::ARM::getDefaultFPU(CPU, Arch); llvm::ARM::getFPUFeatures(FPUKind, TargetFeatures); // get default Extension features uint64_t Extensions = llvm::ARM::getDefaultExtensions(CPU, Arch); llvm::ARM::getExtensionFeatures(Extensions, TargetFeatures); for (auto Feature : TargetFeatures) if (Feature[0] == '+') Features[Feature.drop_front(1)] = true; // Enable or disable thumb-mode explicitly per function to enable mixed // ARM and Thumb code generation. if (isThumb()) Features["thumb-mode"] = true; else Features["thumb-mode"] = false; // Convert user-provided arm and thumb GNU target attributes to // [-|+]thumb-mode target features respectively. std::vector UpdatedFeaturesVec; for (const auto &Feature : FeaturesVec) { // Skip soft-float-abi; it's something we only use to initialize a bit of // class state, and is otherwise unrecognized. if (Feature == "+soft-float-abi") continue; StringRef FixedFeature; if (Feature == "+arm") FixedFeature = "-thumb-mode"; else if (Feature == "+thumb") FixedFeature = "+thumb-mode"; else FixedFeature = Feature; UpdatedFeaturesVec.push_back(FixedFeature.str()); } return TargetInfo::initFeatureMap(Features, Diags, CPU, UpdatedFeaturesVec); } bool ARMTargetInfo::handleTargetFeatures(std::vector &Features, DiagnosticsEngine &Diags) { FPU = 0; MVE = 0; CRC = 0; Crypto = 0; SHA2 = 0; AES = 0; DSP = 0; Unaligned = 1; SoftFloat = false; // Note that SoftFloatABI is initialized in our constructor. HWDiv = 0; DotProd = 0; HasMatMul = 0; HasPAC = 0; HasBTI = 0; HasFloat16 = true; ARMCDECoprocMask = 0; HasBFloat16 = false; FPRegsDisabled = false; // This does not diagnose illegal cases like having both // "+vfpv2" and "+vfpv3" or having "+neon" and "-fp64". for (const auto &Feature : Features) { if (Feature == "+soft-float") { SoftFloat = true; } else if (Feature == "+vfp2sp" || Feature == "+vfp2") { FPU |= VFP2FPU; HW_FP |= HW_FP_SP; if (Feature == "+vfp2") HW_FP |= HW_FP_DP; } else if (Feature == "+vfp3sp" || Feature == "+vfp3d16sp" || Feature == "+vfp3" || Feature == "+vfp3d16") { FPU |= VFP3FPU; HW_FP |= HW_FP_SP; if (Feature == "+vfp3" || Feature == "+vfp3d16") HW_FP |= HW_FP_DP; } else if (Feature == "+vfp4sp" || Feature == "+vfp4d16sp" || Feature == "+vfp4" || Feature == "+vfp4d16") { FPU |= VFP4FPU; HW_FP |= HW_FP_SP | HW_FP_HP; if (Feature == "+vfp4" || Feature == "+vfp4d16") HW_FP |= HW_FP_DP; } else if (Feature == "+fp-armv8sp" || Feature == "+fp-armv8d16sp" || Feature == "+fp-armv8" || Feature == "+fp-armv8d16") { FPU |= FPARMV8; HW_FP |= HW_FP_SP | HW_FP_HP; if (Feature == "+fp-armv8" || Feature == "+fp-armv8d16") HW_FP |= HW_FP_DP; } else if (Feature == "+neon") { FPU |= NeonFPU; HW_FP |= HW_FP_SP; } else if (Feature == "+hwdiv") { HWDiv |= HWDivThumb; } else if (Feature == "+hwdiv-arm") { HWDiv |= HWDivARM; } else if (Feature == "+crc") { CRC = 1; } else if (Feature == "+crypto") { Crypto = 1; } else if (Feature == "+sha2") { SHA2 = 1; } else if (Feature == "+aes") { AES = 1; } else if (Feature == "+dsp") { DSP = 1; } else if (Feature == "+fp64") { HW_FP |= HW_FP_DP; } else if (Feature == "+8msecext") { if (CPUProfile != "M" || ArchVersion != 8) { Diags.Report(diag::err_target_unsupported_mcmse) << CPU; return false; } } else if (Feature == "+strict-align") { Unaligned = 0; } else if (Feature == "+fp16") { HW_FP |= HW_FP_HP; } else if (Feature == "+fullfp16") { HasLegalHalfType = true; } else if (Feature == "+dotprod") { DotProd = true; } else if (Feature == "+mve") { MVE |= MVE_INT; } else if (Feature == "+mve.fp") { HasLegalHalfType = true; FPU |= FPARMV8; MVE |= MVE_INT | MVE_FP; HW_FP |= HW_FP_SP | HW_FP_HP; } else if (Feature == "+i8mm") { HasMatMul = 1; } else if (Feature.size() == strlen("+cdecp0") && Feature >= "+cdecp0" && Feature <= "+cdecp7") { unsigned Coproc = Feature.back() - '0'; ARMCDECoprocMask |= (1U << Coproc); } else if (Feature == "+bf16") { HasBFloat16 = true; } else if (Feature == "-fpregs") { FPRegsDisabled = true; } else if (Feature == "+pacbti") { HasPAC = 1; HasBTI = 1; } } switch (ArchVersion) { case 6: if (ArchProfile == llvm::ARM::ProfileKind::M) LDREX = 0; else if (ArchKind == llvm::ARM::ArchKind::ARMV6K) LDREX = LDREX_D | LDREX_W | LDREX_H | LDREX_B; else LDREX = LDREX_W; break; case 7: if (ArchProfile == llvm::ARM::ProfileKind::M) LDREX = LDREX_W | LDREX_H | LDREX_B; else LDREX = LDREX_D | LDREX_W | LDREX_H | LDREX_B; break; case 8: case 9: LDREX = LDREX_D | LDREX_W | LDREX_H | LDREX_B; } if (!(FPU & NeonFPU) && FPMath == FP_Neon) { Diags.Report(diag::err_target_unsupported_fpmath) << "neon"; return false; } if (FPMath == FP_Neon) Features.push_back("+neonfp"); else if (FPMath == FP_VFP) Features.push_back("-neonfp"); return true; } bool ARMTargetInfo::hasFeature(StringRef Feature) const { return llvm::StringSwitch(Feature) .Case("arm", true) .Case("aarch32", true) .Case("softfloat", SoftFloat) .Case("thumb", isThumb()) .Case("neon", (FPU & NeonFPU) && !SoftFloat) .Case("vfp", FPU && !SoftFloat) .Case("hwdiv", HWDiv & HWDivThumb) .Case("hwdiv-arm", HWDiv & HWDivARM) .Case("mve", hasMVE()) .Default(false); } bool ARMTargetInfo::hasBFloat16Type() const { return HasBFloat16 && !SoftFloat; } bool ARMTargetInfo::isValidCPUName(StringRef Name) const { return Name == "generic" || llvm::ARM::parseCPUArch(Name) != llvm::ARM::ArchKind::INVALID; } void ARMTargetInfo::fillValidCPUList(SmallVectorImpl &Values) const { llvm::ARM::fillValidCPUArchList(Values); } bool ARMTargetInfo::setCPU(const std::string &Name) { if (Name != "generic") setArchInfo(llvm::ARM::parseCPUArch(Name)); if (ArchKind == llvm::ARM::ArchKind::INVALID) return false; setAtomic(); CPU = Name; return true; } bool ARMTargetInfo::setFPMath(StringRef Name) { if (Name == "neon") { FPMath = FP_Neon; return true; } else if (Name == "vfp" || Name == "vfp2" || Name == "vfp3" || Name == "vfp4") { FPMath = FP_VFP; return true; } return false; } void ARMTargetInfo::getTargetDefinesARMV81A(const LangOptions &Opts, MacroBuilder &Builder) const { Builder.defineMacro("__ARM_FEATURE_QRDMX", "1"); } void ARMTargetInfo::getTargetDefinesARMV82A(const LangOptions &Opts, MacroBuilder &Builder) const { // Also include the ARMv8.1-A defines getTargetDefinesARMV81A(Opts, Builder); } void ARMTargetInfo::getTargetDefinesARMV83A(const LangOptions &Opts, MacroBuilder &Builder) const { // Also include the ARMv8.2-A defines Builder.defineMacro("__ARM_FEATURE_COMPLEX", "1"); getTargetDefinesARMV82A(Opts, Builder); } void ARMTargetInfo::getTargetDefines(const LangOptions &Opts, MacroBuilder &Builder) const { // Target identification. Builder.defineMacro("__arm"); Builder.defineMacro("__arm__"); // For bare-metal none-eabi. if (getTriple().getOS() == llvm::Triple::UnknownOS && (getTriple().getEnvironment() == llvm::Triple::EABI || getTriple().getEnvironment() == llvm::Triple::EABIHF)) Builder.defineMacro("__ELF__"); // Target properties. Builder.defineMacro("__REGISTER_PREFIX__", ""); // Unfortunately, __ARM_ARCH_7K__ is now more of an ABI descriptor. The CPU // happens to be Cortex-A7 though, so it should still get __ARM_ARCH_7A__. if (getTriple().isWatchABI()) Builder.defineMacro("__ARM_ARCH_7K__", "2"); if (!CPUAttr.empty()) Builder.defineMacro("__ARM_ARCH_" + CPUAttr + "__"); // ACLE 6.4.1 ARM/Thumb instruction set architecture // __ARM_ARCH is defined as an integer value indicating the current ARM ISA Builder.defineMacro("__ARM_ARCH", Twine(ArchVersion)); if (ArchVersion >= 8) { // ACLE 6.5.7 Crypto Extension // The __ARM_FEATURE_CRYPTO is deprecated in favor of finer grained // feature macros for AES and SHA2 if (SHA2 && AES) Builder.defineMacro("__ARM_FEATURE_CRYPTO", "1"); if (SHA2) Builder.defineMacro("__ARM_FEATURE_SHA2", "1"); if (AES) Builder.defineMacro("__ARM_FEATURE_AES", "1"); // ACLE 6.5.8 CRC32 Extension if (CRC) Builder.defineMacro("__ARM_FEATURE_CRC32", "1"); // ACLE 6.5.10 Numeric Maximum and Minimum Builder.defineMacro("__ARM_FEATURE_NUMERIC_MAXMIN", "1"); // ACLE 6.5.9 Directed Rounding Builder.defineMacro("__ARM_FEATURE_DIRECTED_ROUNDING", "1"); } // __ARM_ARCH_ISA_ARM is defined to 1 if the core supports the ARM ISA. It // is not defined for the M-profile. // NOTE that the default profile is assumed to be 'A' if (CPUProfile.empty() || ArchProfile != llvm::ARM::ProfileKind::M) Builder.defineMacro("__ARM_ARCH_ISA_ARM", "1"); // __ARM_ARCH_ISA_THUMB is defined to 1 if the core supports the original // Thumb ISA (including v6-M and v8-M Baseline). It is set to 2 if the // core supports the Thumb-2 ISA as found in the v6T2 architecture and all // v7 and v8 architectures excluding v8-M Baseline. if (supportsThumb2()) Builder.defineMacro("__ARM_ARCH_ISA_THUMB", "2"); else if (supportsThumb()) Builder.defineMacro("__ARM_ARCH_ISA_THUMB", "1"); // __ARM_32BIT_STATE is defined to 1 if code is being generated for a 32-bit // instruction set such as ARM or Thumb. Builder.defineMacro("__ARM_32BIT_STATE", "1"); // ACLE 6.4.2 Architectural Profile (A, R, M or pre-Cortex) // __ARM_ARCH_PROFILE is defined as 'A', 'R', 'M' or 'S', or unset. if (!CPUProfile.empty()) Builder.defineMacro("__ARM_ARCH_PROFILE", "'" + CPUProfile + "'"); // ACLE 6.4.3 Unaligned access supported in hardware if (Unaligned) Builder.defineMacro("__ARM_FEATURE_UNALIGNED", "1"); // ACLE 6.4.4 LDREX/STREX if (LDREX) Builder.defineMacro("__ARM_FEATURE_LDREX", "0x" + Twine::utohexstr(LDREX)); // ACLE 6.4.5 CLZ if (ArchVersion == 5 || (ArchVersion == 6 && CPUProfile != "M") || ArchVersion > 6) Builder.defineMacro("__ARM_FEATURE_CLZ", "1"); // ACLE 6.5.1 Hardware Floating Point if (HW_FP) Builder.defineMacro("__ARM_FP", "0x" + Twine::utohexstr(HW_FP)); // ACLE predefines. Builder.defineMacro("__ARM_ACLE", "200"); // FP16 support (we currently only support IEEE format). Builder.defineMacro("__ARM_FP16_FORMAT_IEEE", "1"); Builder.defineMacro("__ARM_FP16_ARGS", "1"); // ACLE 6.5.3 Fused multiply-accumulate (FMA) if (ArchVersion >= 7 && (FPU & VFP4FPU)) Builder.defineMacro("__ARM_FEATURE_FMA", "1"); // Subtarget options. // FIXME: It's more complicated than this and we don't really support // interworking. // Windows on ARM does not "support" interworking if (5 <= ArchVersion && ArchVersion <= 8 && !getTriple().isOSWindows()) Builder.defineMacro("__THUMB_INTERWORK__"); if (ABI == "aapcs" || ABI == "aapcs-linux" || ABI == "aapcs-vfp") { // Embedded targets on Darwin follow AAPCS, but not EABI. // Windows on ARM follows AAPCS VFP, but does not conform to EABI. if (!getTriple().isOSBinFormatMachO() && !getTriple().isOSWindows()) Builder.defineMacro("__ARM_EABI__"); Builder.defineMacro("__ARM_PCS", "1"); } if ((!SoftFloat && !SoftFloatABI) || ABI == "aapcs-vfp" || ABI == "aapcs16") Builder.defineMacro("__ARM_PCS_VFP", "1"); if (SoftFloat) Builder.defineMacro("__SOFTFP__"); // ACLE position independent code macros. if (Opts.ROPI) Builder.defineMacro("__ARM_ROPI", "1"); if (Opts.RWPI) Builder.defineMacro("__ARM_RWPI", "1"); if (ArchKind == llvm::ARM::ArchKind::XSCALE) Builder.defineMacro("__XSCALE__"); if (isThumb()) { Builder.defineMacro("__THUMBEL__"); Builder.defineMacro("__thumb__"); if (supportsThumb2()) Builder.defineMacro("__thumb2__"); } // ACLE 6.4.9 32-bit SIMD instructions if ((CPUProfile != "M" && ArchVersion >= 6) || (CPUProfile == "M" && DSP)) Builder.defineMacro("__ARM_FEATURE_SIMD32", "1"); // ACLE 6.4.10 Hardware Integer Divide if (((HWDiv & HWDivThumb) && isThumb()) || ((HWDiv & HWDivARM) && !isThumb())) { Builder.defineMacro("__ARM_FEATURE_IDIV", "1"); Builder.defineMacro("__ARM_ARCH_EXT_IDIV__", "1"); } // Note, this is always on in gcc, even though it doesn't make sense. Builder.defineMacro("__APCS_32__"); // __VFP_FP__ means that the floating-point format is VFP, not that a hardware // FPU is present. Moreover, the VFP format is the only one supported by // clang. For these reasons, this macro is always defined. Builder.defineMacro("__VFP_FP__"); if (FPUModeIsVFP((FPUMode)FPU)) { if (FPU & VFP2FPU) Builder.defineMacro("__ARM_VFPV2__"); if (FPU & VFP3FPU) Builder.defineMacro("__ARM_VFPV3__"); if (FPU & VFP4FPU) Builder.defineMacro("__ARM_VFPV4__"); if (FPU & FPARMV8) Builder.defineMacro("__ARM_FPV5__"); } // This only gets set when Neon instructions are actually available, unlike // the VFP define, hence the soft float and arch check. This is subtly // different from gcc, we follow the intent which was that it should be set // when Neon instructions are actually available. if ((FPU & NeonFPU) && !SoftFloat && ArchVersion >= 7) { Builder.defineMacro("__ARM_NEON", "1"); Builder.defineMacro("__ARM_NEON__"); // current AArch32 NEON implementations do not support double-precision // floating-point even when it is present in VFP. Builder.defineMacro("__ARM_NEON_FP", "0x" + Twine::utohexstr(HW_FP & ~HW_FP_DP)); } if (hasMVE()) { Builder.defineMacro("__ARM_FEATURE_MVE", hasMVEFloat() ? "3" : "1"); } if (hasCDE()) { Builder.defineMacro("__ARM_FEATURE_CDE", "1"); Builder.defineMacro("__ARM_FEATURE_CDE_COPROC", "0x" + Twine::utohexstr(getARMCDECoprocMask())); } Builder.defineMacro("__ARM_SIZEOF_WCHAR_T", Twine(Opts.WCharSize ? Opts.WCharSize : 4)); Builder.defineMacro("__ARM_SIZEOF_MINIMAL_ENUM", Opts.ShortEnums ? "1" : "4"); // CMSE if (ArchVersion == 8 && ArchProfile == llvm::ARM::ProfileKind::M) Builder.defineMacro("__ARM_FEATURE_CMSE", Opts.Cmse ? "3" : "1"); if (ArchVersion >= 6 && CPUAttr != "6M" && CPUAttr != "8M_BASE") { Builder.defineMacro("__GCC_HAVE_SYNC_COMPARE_AND_SWAP_1"); Builder.defineMacro("__GCC_HAVE_SYNC_COMPARE_AND_SWAP_2"); Builder.defineMacro("__GCC_HAVE_SYNC_COMPARE_AND_SWAP_4"); Builder.defineMacro("__GCC_HAVE_SYNC_COMPARE_AND_SWAP_8"); } // ACLE 6.4.7 DSP instructions if (DSP) { Builder.defineMacro("__ARM_FEATURE_DSP", "1"); } // ACLE 6.4.8 Saturation instructions bool SAT = false; if ((ArchVersion == 6 && CPUProfile != "M") || ArchVersion > 6) { Builder.defineMacro("__ARM_FEATURE_SAT", "1"); SAT = true; } // ACLE 6.4.6 Q (saturation) flag if (DSP || SAT) Builder.defineMacro("__ARM_FEATURE_QBIT", "1"); if (Opts.UnsafeFPMath) Builder.defineMacro("__ARM_FP_FAST", "1"); // Armv8.2-A FP16 vector intrinsic if ((FPU & NeonFPU) && HasLegalHalfType) Builder.defineMacro("__ARM_FEATURE_FP16_VECTOR_ARITHMETIC", "1"); // Armv8.2-A FP16 scalar intrinsics if (HasLegalHalfType) Builder.defineMacro("__ARM_FEATURE_FP16_SCALAR_ARITHMETIC", "1"); // Armv8.2-A dot product intrinsics if (DotProd) Builder.defineMacro("__ARM_FEATURE_DOTPROD", "1"); if (HasMatMul) Builder.defineMacro("__ARM_FEATURE_MATMUL_INT8", "1"); if (HasPAC) Builder.defineMacro("__ARM_FEATURE_PAUTH", "1"); if (HasBTI) Builder.defineMacro("__ARM_FEATURE_BTI", "1"); if (HasBFloat16) { Builder.defineMacro("__ARM_FEATURE_BF16", "1"); Builder.defineMacro("__ARM_FEATURE_BF16_VECTOR_ARITHMETIC", "1"); Builder.defineMacro("__ARM_BF16_FORMAT_ALTERNATIVE", "1"); } if (Opts.BranchTargetEnforcement) Builder.defineMacro("__ARM_FEATURE_BTI_DEFAULT", "1"); if (Opts.hasSignReturnAddress()) { unsigned Value = 1; if (Opts.isSignReturnAddressScopeAll()) Value |= 1 << 2; Builder.defineMacro("__ARM_FEATURE_PAC_DEFAULT", Twine(Value)); } switch (ArchKind) { default: break; case llvm::ARM::ArchKind::ARMV8_1A: getTargetDefinesARMV81A(Opts, Builder); break; case llvm::ARM::ArchKind::ARMV8_2A: getTargetDefinesARMV82A(Opts, Builder); break; case llvm::ARM::ArchKind::ARMV8_3A: case llvm::ARM::ArchKind::ARMV8_4A: case llvm::ARM::ArchKind::ARMV8_5A: case llvm::ARM::ArchKind::ARMV8_6A: case llvm::ARM::ArchKind::ARMV8_8A: case llvm::ARM::ArchKind::ARMV9A: case llvm::ARM::ArchKind::ARMV9_1A: case llvm::ARM::ArchKind::ARMV9_2A: case llvm::ARM::ArchKind::ARMV9_3A: getTargetDefinesARMV83A(Opts, Builder); break; } } const Builtin::Info ARMTargetInfo::BuiltinInfo[] = { #define BUILTIN(ID, TYPE, ATTRS) \ {#ID, TYPE, ATTRS, nullptr, ALL_LANGUAGES, nullptr}, #define LIBBUILTIN(ID, TYPE, ATTRS, HEADER) \ {#ID, TYPE, ATTRS, HEADER, ALL_LANGUAGES, nullptr}, #include "clang/Basic/BuiltinsNEON.def" #define BUILTIN(ID, TYPE, ATTRS) \ {#ID, TYPE, ATTRS, nullptr, ALL_LANGUAGES, nullptr}, #define LANGBUILTIN(ID, TYPE, ATTRS, LANG) \ {#ID, TYPE, ATTRS, nullptr, LANG, nullptr}, #define LIBBUILTIN(ID, TYPE, ATTRS, HEADER) \ {#ID, TYPE, ATTRS, HEADER, ALL_LANGUAGES, nullptr}, #define TARGET_HEADER_BUILTIN(ID, TYPE, ATTRS, HEADER, LANGS, FEATURE) \ {#ID, TYPE, ATTRS, HEADER, LANGS, FEATURE}, #include "clang/Basic/BuiltinsARM.def" }; ArrayRef ARMTargetInfo::getTargetBuiltins() const { return llvm::makeArrayRef(BuiltinInfo, clang::ARM::LastTSBuiltin - Builtin::FirstTSBuiltin); } bool ARMTargetInfo::isCLZForZeroUndef() const { return false; } TargetInfo::BuiltinVaListKind ARMTargetInfo::getBuiltinVaListKind() const { return IsAAPCS ? AAPCSABIBuiltinVaList : (getTriple().isWatchABI() ? TargetInfo::CharPtrBuiltinVaList : TargetInfo::VoidPtrBuiltinVaList); } const char *const ARMTargetInfo::GCCRegNames[] = { // Integer registers "r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7", "r8", "r9", "r10", "r11", "r12", "sp", "lr", "pc", // Float registers "s0", "s1", "s2", "s3", "s4", "s5", "s6", "s7", "s8", "s9", "s10", "s11", "s12", "s13", "s14", "s15", "s16", "s17", "s18", "s19", "s20", "s21", "s22", "s23", "s24", "s25", "s26", "s27", "s28", "s29", "s30", "s31", // Double registers "d0", "d1", "d2", "d3", "d4", "d5", "d6", "d7", "d8", "d9", "d10", "d11", "d12", "d13", "d14", "d15", "d16", "d17", "d18", "d19", "d20", "d21", "d22", "d23", "d24", "d25", "d26", "d27", "d28", "d29", "d30", "d31", // Quad registers "q0", "q1", "q2", "q3", "q4", "q5", "q6", "q7", "q8", "q9", "q10", "q11", "q12", "q13", "q14", "q15"}; ArrayRef ARMTargetInfo::getGCCRegNames() const { return llvm::makeArrayRef(GCCRegNames); } const TargetInfo::GCCRegAlias ARMTargetInfo::GCCRegAliases[] = { {{"a1"}, "r0"}, {{"a2"}, "r1"}, {{"a3"}, "r2"}, {{"a4"}, "r3"}, {{"v1"}, "r4"}, {{"v2"}, "r5"}, {{"v3"}, "r6"}, {{"v4"}, "r7"}, {{"v5"}, "r8"}, {{"v6", "rfp"}, "r9"}, {{"sl"}, "r10"}, {{"fp"}, "r11"}, {{"ip"}, "r12"}, {{"r13"}, "sp"}, {{"r14"}, "lr"}, {{"r15"}, "pc"}, // The S, D and Q registers overlap, but aren't really aliases; we // don't want to substitute one of these for a different-sized one. }; ArrayRef ARMTargetInfo::getGCCRegAliases() const { return llvm::makeArrayRef(GCCRegAliases); } bool ARMTargetInfo::validateAsmConstraint( const char *&Name, TargetInfo::ConstraintInfo &Info) const { switch (*Name) { default: break; case 'l': // r0-r7 if thumb, r0-r15 if ARM Info.setAllowsRegister(); return true; case 'h': // r8-r15, thumb only if (isThumb()) { Info.setAllowsRegister(); return true; } break; case 's': // An integer constant, but allowing only relocatable values. return true; case 't': // s0-s31, d0-d31, or q0-q15 case 'w': // s0-s15, d0-d7, or q0-q3 case 'x': // s0-s31, d0-d15, or q0-q7 if (FPRegsDisabled) return false; Info.setAllowsRegister(); return true; case 'j': // An immediate integer between 0 and 65535 (valid for MOVW) // only available in ARMv6T2 and above if (CPUAttr.equals("6T2") || ArchVersion >= 7) { Info.setRequiresImmediate(0, 65535); return true; } break; case 'I': if (isThumb()) { if (!supportsThumb2()) Info.setRequiresImmediate(0, 255); else // FIXME: should check if immediate value would be valid for a Thumb2 // data-processing instruction Info.setRequiresImmediate(); } else // FIXME: should check if immediate value would be valid for an ARM // data-processing instruction Info.setRequiresImmediate(); return true; case 'J': if (isThumb() && !supportsThumb2()) Info.setRequiresImmediate(-255, -1); else Info.setRequiresImmediate(-4095, 4095); return true; case 'K': if (isThumb()) { if (!supportsThumb2()) // FIXME: should check if immediate value can be obtained from shifting // a value between 0 and 255 left by any amount Info.setRequiresImmediate(); else // FIXME: should check if immediate value would be valid for a Thumb2 // data-processing instruction when inverted Info.setRequiresImmediate(); } else // FIXME: should check if immediate value would be valid for an ARM // data-processing instruction when inverted Info.setRequiresImmediate(); return true; case 'L': if (isThumb()) { if (!supportsThumb2()) Info.setRequiresImmediate(-7, 7); else // FIXME: should check if immediate value would be valid for a Thumb2 // data-processing instruction when negated Info.setRequiresImmediate(); } else // FIXME: should check if immediate value would be valid for an ARM // data-processing instruction when negated Info.setRequiresImmediate(); return true; case 'M': if (isThumb() && !supportsThumb2()) // FIXME: should check if immediate value is a multiple of 4 between 0 and // 1020 Info.setRequiresImmediate(); else // FIXME: should check if immediate value is a power of two or a integer // between 0 and 32 Info.setRequiresImmediate(); return true; case 'N': // Thumb1 only if (isThumb() && !supportsThumb2()) { Info.setRequiresImmediate(0, 31); return true; } break; case 'O': // Thumb1 only if (isThumb() && !supportsThumb2()) { // FIXME: should check if immediate value is a multiple of 4 between -508 // and 508 Info.setRequiresImmediate(); return true; } break; case 'Q': // A memory address that is a single base register. Info.setAllowsMemory(); return true; case 'T': switch (Name[1]) { default: break; case 'e': // Even general-purpose register case 'o': // Odd general-purpose register Info.setAllowsRegister(); Name++; return true; } break; case 'U': // a memory reference... switch (Name[1]) { case 'q': // ...ARMV4 ldrsb case 'v': // ...VFP load/store (reg+constant offset) case 'y': // ...iWMMXt load/store case 't': // address valid for load/store opaque types wider // than 128-bits case 'n': // valid address for Neon doubleword vector load/store case 'm': // valid address for Neon element and structure load/store case 's': // valid address for non-offset loads/stores of quad-word // values in four ARM registers Info.setAllowsMemory(); Name++; return true; } break; } return false; } std::string ARMTargetInfo::convertConstraint(const char *&Constraint) const { std::string R; switch (*Constraint) { case 'U': // Two-character constraint; add "^" hint for later parsing. case 'T': R = std::string("^") + std::string(Constraint, 2); Constraint++; break; case 'p': // 'p' should be translated to 'r' by default. R = std::string("r"); break; default: return std::string(1, *Constraint); } return R; } bool ARMTargetInfo::validateConstraintModifier( StringRef Constraint, char Modifier, unsigned Size, std::string &SuggestedModifier) const { bool isOutput = (Constraint[0] == '='); bool isInOut = (Constraint[0] == '+'); // Strip off constraint modifiers. while (Constraint[0] == '=' || Constraint[0] == '+' || Constraint[0] == '&') Constraint = Constraint.substr(1); switch (Constraint[0]) { default: break; case 'r': { switch (Modifier) { default: return (isInOut || isOutput || Size <= 64); case 'q': // A register of size 32 cannot fit a vector type. return false; } } } return true; } const char *ARMTargetInfo::getClobbers() const { // FIXME: Is this really right? return ""; } TargetInfo::CallingConvCheckResult ARMTargetInfo::checkCallingConvention(CallingConv CC) const { switch (CC) { case CC_AAPCS: case CC_AAPCS_VFP: case CC_Swift: case CC_SwiftAsync: case CC_OpenCLKernel: return CCCR_OK; default: return CCCR_Warning; } } int ARMTargetInfo::getEHDataRegisterNumber(unsigned RegNo) const { if (RegNo == 0) return 0; if (RegNo == 1) return 1; return -1; } bool ARMTargetInfo::hasSjLjLowering() const { return true; } ARMleTargetInfo::ARMleTargetInfo(const llvm::Triple &Triple, const TargetOptions &Opts) : ARMTargetInfo(Triple, Opts) {} void ARMleTargetInfo::getTargetDefines(const LangOptions &Opts, MacroBuilder &Builder) const { Builder.defineMacro("__ARMEL__"); ARMTargetInfo::getTargetDefines(Opts, Builder); } ARMbeTargetInfo::ARMbeTargetInfo(const llvm::Triple &Triple, const TargetOptions &Opts) : ARMTargetInfo(Triple, Opts) {} void ARMbeTargetInfo::getTargetDefines(const LangOptions &Opts, MacroBuilder &Builder) const { Builder.defineMacro("__ARMEB__"); Builder.defineMacro("__ARM_BIG_ENDIAN"); ARMTargetInfo::getTargetDefines(Opts, Builder); } WindowsARMTargetInfo::WindowsARMTargetInfo(const llvm::Triple &Triple, const TargetOptions &Opts) : WindowsTargetInfo(Triple, Opts), Triple(Triple) { } void WindowsARMTargetInfo::getVisualStudioDefines(const LangOptions &Opts, MacroBuilder &Builder) const { // FIXME: this is invalid for WindowsCE Builder.defineMacro("_M_ARM_NT", "1"); Builder.defineMacro("_M_ARMT", "_M_ARM"); Builder.defineMacro("_M_THUMB", "_M_ARM"); assert((Triple.getArch() == llvm::Triple::arm || Triple.getArch() == llvm::Triple::thumb) && "invalid architecture for Windows ARM target info"); unsigned Offset = Triple.getArch() == llvm::Triple::arm ? 4 : 6; Builder.defineMacro("_M_ARM", Triple.getArchName().substr(Offset)); // TODO map the complete set of values // 31: VFPv3 40: VFPv4 Builder.defineMacro("_M_ARM_FP", "31"); } TargetInfo::BuiltinVaListKind WindowsARMTargetInfo::getBuiltinVaListKind() const { return TargetInfo::CharPtrBuiltinVaList; } TargetInfo::CallingConvCheckResult WindowsARMTargetInfo::checkCallingConvention(CallingConv CC) const { switch (CC) { case CC_X86StdCall: case CC_X86ThisCall: case CC_X86FastCall: case CC_X86VectorCall: return CCCR_Ignore; case CC_C: case CC_OpenCLKernel: case CC_PreserveMost: case CC_PreserveAll: case CC_Swift: case CC_SwiftAsync: return CCCR_OK; default: return CCCR_Warning; } } // Windows ARM + Itanium C++ ABI Target ItaniumWindowsARMleTargetInfo::ItaniumWindowsARMleTargetInfo( const llvm::Triple &Triple, const TargetOptions &Opts) : WindowsARMTargetInfo(Triple, Opts) { TheCXXABI.set(TargetCXXABI::GenericARM); } void ItaniumWindowsARMleTargetInfo::getTargetDefines( const LangOptions &Opts, MacroBuilder &Builder) const { WindowsARMTargetInfo::getTargetDefines(Opts, Builder); if (Opts.MSVCCompat) WindowsARMTargetInfo::getVisualStudioDefines(Opts, Builder); } // Windows ARM, MS (C++) ABI MicrosoftARMleTargetInfo::MicrosoftARMleTargetInfo(const llvm::Triple &Triple, const TargetOptions &Opts) : WindowsARMTargetInfo(Triple, Opts) { TheCXXABI.set(TargetCXXABI::Microsoft); } void MicrosoftARMleTargetInfo::getTargetDefines(const LangOptions &Opts, MacroBuilder &Builder) const { WindowsARMTargetInfo::getTargetDefines(Opts, Builder); WindowsARMTargetInfo::getVisualStudioDefines(Opts, Builder); } MinGWARMTargetInfo::MinGWARMTargetInfo(const llvm::Triple &Triple, const TargetOptions &Opts) : WindowsARMTargetInfo(Triple, Opts) { TheCXXABI.set(TargetCXXABI::GenericARM); } void MinGWARMTargetInfo::getTargetDefines(const LangOptions &Opts, MacroBuilder &Builder) const { WindowsARMTargetInfo::getTargetDefines(Opts, Builder); Builder.defineMacro("_ARM_"); } CygwinARMTargetInfo::CygwinARMTargetInfo(const llvm::Triple &Triple, const TargetOptions &Opts) : ARMleTargetInfo(Triple, Opts) { this->WCharType = TargetInfo::UnsignedShort; TLSSupported = false; DoubleAlign = LongLongAlign = 64; resetDataLayout("e-m:e-p:32:32-Fi8-i64:64-v128:64:128-a:0:32-n32-S64"); } void CygwinARMTargetInfo::getTargetDefines(const LangOptions &Opts, MacroBuilder &Builder) const { ARMleTargetInfo::getTargetDefines(Opts, Builder); Builder.defineMacro("_ARM_"); Builder.defineMacro("__CYGWIN__"); Builder.defineMacro("__CYGWIN32__"); DefineStd(Builder, "unix", Opts); if (Opts.CPlusPlus) Builder.defineMacro("_GNU_SOURCE"); } DarwinARMTargetInfo::DarwinARMTargetInfo(const llvm::Triple &Triple, const TargetOptions &Opts) : DarwinTargetInfo(Triple, Opts) { HasAlignMac68kSupport = true; // iOS always has 64-bit atomic instructions. // FIXME: This should be based off of the target features in // ARMleTargetInfo. MaxAtomicInlineWidth = 64; if (Triple.isWatchABI()) { // Darwin on iOS uses a variant of the ARM C++ ABI. TheCXXABI.set(TargetCXXABI::WatchOS); // BOOL should be a real boolean on the new ABI UseSignedCharForObjCBool = false; } else TheCXXABI.set(TargetCXXABI::iOS); } void DarwinARMTargetInfo::getOSDefines(const LangOptions &Opts, const llvm::Triple &Triple, MacroBuilder &Builder) const { getDarwinDefines(Builder, Opts, Triple, PlatformName, PlatformMinVersion); } RenderScript32TargetInfo::RenderScript32TargetInfo(const llvm::Triple &Triple, const TargetOptions &Opts) : ARMleTargetInfo(llvm::Triple("armv7", Triple.getVendorName(), Triple.getOSName(), Triple.getEnvironmentName()), Opts) { IsRenderScriptTarget = true; LongWidth = LongAlign = 64; } void RenderScript32TargetInfo::getTargetDefines(const LangOptions &Opts, MacroBuilder &Builder) const { Builder.defineMacro("__RENDERSCRIPT__"); ARMleTargetInfo::getTargetDefines(Opts, Builder); }