//===- AMDGPUBaseInfo.cpp - AMDGPU Base encoding information --------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include "AMDGPUBaseInfo.h" #include "AMDGPUTargetTransformInfo.h" #include "AMDGPU.h" #include "SIDefines.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/Triple.h" #include "llvm/BinaryFormat/ELF.h" #include "llvm/CodeGen/MachineMemOperand.h" #include "llvm/IR/Attributes.h" #include "llvm/IR/Constants.h" #include "llvm/IR/Function.h" #include "llvm/IR/GlobalValue.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/LLVMContext.h" #include "llvm/IR/Module.h" #include "llvm/MC/MCContext.h" #include "llvm/MC/MCInstrDesc.h" #include "llvm/MC/MCInstrInfo.h" #include "llvm/MC/MCRegisterInfo.h" #include "llvm/MC/MCSectionELF.h" #include "llvm/MC/MCSubtargetInfo.h" #include "llvm/MC/SubtargetFeature.h" #include "llvm/Support/Casting.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/MathExtras.h" #include #include #include #include #include #include "MCTargetDesc/AMDGPUMCTargetDesc.h" #define GET_INSTRINFO_NAMED_OPS #define GET_INSTRMAP_INFO #include "AMDGPUGenInstrInfo.inc" #undef GET_INSTRMAP_INFO #undef GET_INSTRINFO_NAMED_OPS namespace { /// \returns Bit mask for given bit \p Shift and bit \p Width. unsigned getBitMask(unsigned Shift, unsigned Width) { return ((1 << Width) - 1) << Shift; } /// Packs \p Src into \p Dst for given bit \p Shift and bit \p Width. /// /// \returns Packed \p Dst. unsigned packBits(unsigned Src, unsigned Dst, unsigned Shift, unsigned Width) { Dst &= ~(1 << Shift) & ~getBitMask(Shift, Width); Dst |= (Src << Shift) & getBitMask(Shift, Width); return Dst; } /// Unpacks bits from \p Src for given bit \p Shift and bit \p Width. /// /// \returns Unpacked bits. unsigned unpackBits(unsigned Src, unsigned Shift, unsigned Width) { return (Src & getBitMask(Shift, Width)) >> Shift; } /// \returns Vmcnt bit shift (lower bits). unsigned getVmcntBitShiftLo() { return 0; } /// \returns Vmcnt bit width (lower bits). unsigned getVmcntBitWidthLo() { return 4; } /// \returns Expcnt bit shift. unsigned getExpcntBitShift() { return 4; } /// \returns Expcnt bit width. unsigned getExpcntBitWidth() { return 3; } /// \returns Lgkmcnt bit shift. unsigned getLgkmcntBitShift() { return 8; } /// \returns Lgkmcnt bit width. unsigned getLgkmcntBitWidth() { return 4; } /// \returns Vmcnt bit shift (higher bits). unsigned getVmcntBitShiftHi() { return 14; } /// \returns Vmcnt bit width (higher bits). unsigned getVmcntBitWidthHi() { return 2; } } // end namespace anonymous namespace llvm { namespace AMDGPU { struct MIMGInfo { uint16_t Opcode; uint16_t BaseOpcode; uint8_t MIMGEncoding; uint8_t VDataDwords; uint8_t VAddrDwords; }; #define GET_MIMGBaseOpcodesTable_IMPL #define GET_MIMGDimInfoTable_IMPL #define GET_MIMGInfoTable_IMPL #define GET_MIMGLZMappingTable_IMPL #include "AMDGPUGenSearchableTables.inc" int getMIMGOpcode(unsigned BaseOpcode, unsigned MIMGEncoding, unsigned VDataDwords, unsigned VAddrDwords) { const MIMGInfo *Info = getMIMGOpcodeHelper(BaseOpcode, MIMGEncoding, VDataDwords, VAddrDwords); return Info ? Info->Opcode : -1; } int getMaskedMIMGOp(unsigned Opc, unsigned NewChannels) { const MIMGInfo *OrigInfo = getMIMGInfo(Opc); const MIMGInfo *NewInfo = getMIMGOpcodeHelper(OrigInfo->BaseOpcode, OrigInfo->MIMGEncoding, NewChannels, OrigInfo->VAddrDwords); return NewInfo ? NewInfo->Opcode : -1; } struct MUBUFInfo { uint16_t Opcode; uint16_t BaseOpcode; uint8_t dwords; bool has_vaddr; bool has_srsrc; bool has_soffset; }; #define GET_MUBUFInfoTable_DECL #define GET_MUBUFInfoTable_IMPL #include "AMDGPUGenSearchableTables.inc" int getMUBUFBaseOpcode(unsigned Opc) { const MUBUFInfo *Info = getMUBUFInfoFromOpcode(Opc); return Info ? Info->BaseOpcode : -1; } int getMUBUFOpcode(unsigned BaseOpc, unsigned Dwords) { const MUBUFInfo *Info = getMUBUFInfoFromBaseOpcodeAndDwords(BaseOpc, Dwords); return Info ? Info->Opcode : -1; } int getMUBUFDwords(unsigned Opc) { const MUBUFInfo *Info = getMUBUFOpcodeHelper(Opc); return Info ? Info->dwords : 0; } bool getMUBUFHasVAddr(unsigned Opc) { const MUBUFInfo *Info = getMUBUFOpcodeHelper(Opc); return Info ? Info->has_vaddr : false; } bool getMUBUFHasSrsrc(unsigned Opc) { const MUBUFInfo *Info = getMUBUFOpcodeHelper(Opc); return Info ? Info->has_srsrc : false; } bool getMUBUFHasSoffset(unsigned Opc) { const MUBUFInfo *Info = getMUBUFOpcodeHelper(Opc); return Info ? Info->has_soffset : false; } // Wrapper for Tablegen'd function. enum Subtarget is not defined in any // header files, so we need to wrap it in a function that takes unsigned // instead. int getMCOpcode(uint16_t Opcode, unsigned Gen) { return getMCOpcodeGen(Opcode, static_cast(Gen)); } namespace IsaInfo { void streamIsaVersion(const MCSubtargetInfo *STI, raw_ostream &Stream) { auto TargetTriple = STI->getTargetTriple(); auto Version = getIsaVersion(STI->getCPU()); Stream << TargetTriple.getArchName() << '-' << TargetTriple.getVendorName() << '-' << TargetTriple.getOSName() << '-' << TargetTriple.getEnvironmentName() << '-' << "gfx" << Version.Major << Version.Minor << Version.Stepping; if (hasXNACK(*STI)) Stream << "+xnack"; if (hasSRAMECC(*STI)) Stream << "+sram-ecc"; Stream.flush(); } bool hasCodeObjectV3(const MCSubtargetInfo *STI) { return STI->getTargetTriple().getOS() == Triple::AMDHSA && STI->getFeatureBits().test(FeatureCodeObjectV3); } unsigned getWavefrontSize(const MCSubtargetInfo *STI) { if (STI->getFeatureBits().test(FeatureWavefrontSize16)) return 16; if (STI->getFeatureBits().test(FeatureWavefrontSize32)) return 32; return 64; } unsigned getLocalMemorySize(const MCSubtargetInfo *STI) { if (STI->getFeatureBits().test(FeatureLocalMemorySize32768)) return 32768; if (STI->getFeatureBits().test(FeatureLocalMemorySize65536)) return 65536; return 0; } unsigned getEUsPerCU(const MCSubtargetInfo *STI) { return 4; } unsigned getMaxWorkGroupsPerCU(const MCSubtargetInfo *STI, unsigned FlatWorkGroupSize) { if (!STI->getFeatureBits().test(FeatureGCN)) return 8; unsigned N = getWavesPerWorkGroup(STI, FlatWorkGroupSize); if (N == 1) return 40; N = 40 / N; return std::min(N, 16u); } unsigned getMaxWavesPerCU(const MCSubtargetInfo *STI) { return getMaxWavesPerEU() * getEUsPerCU(STI); } unsigned getMaxWavesPerCU(const MCSubtargetInfo *STI, unsigned FlatWorkGroupSize) { return getWavesPerWorkGroup(STI, FlatWorkGroupSize); } unsigned getMinWavesPerEU(const MCSubtargetInfo *STI) { return 1; } unsigned getMaxWavesPerEU() { // FIXME: Need to take scratch memory into account. return 10; } unsigned getMaxWavesPerEU(const MCSubtargetInfo *STI, unsigned FlatWorkGroupSize) { return alignTo(getMaxWavesPerCU(STI, FlatWorkGroupSize), getEUsPerCU(STI)) / getEUsPerCU(STI); } unsigned getMinFlatWorkGroupSize(const MCSubtargetInfo *STI) { return 1; } unsigned getMaxFlatWorkGroupSize(const MCSubtargetInfo *STI) { return 2048; } unsigned getWavesPerWorkGroup(const MCSubtargetInfo *STI, unsigned FlatWorkGroupSize) { return alignTo(FlatWorkGroupSize, getWavefrontSize(STI)) / getWavefrontSize(STI); } unsigned getSGPRAllocGranule(const MCSubtargetInfo *STI) { IsaVersion Version = getIsaVersion(STI->getCPU()); if (Version.Major >= 8) return 16; return 8; } unsigned getSGPREncodingGranule(const MCSubtargetInfo *STI) { return 8; } unsigned getTotalNumSGPRs(const MCSubtargetInfo *STI) { IsaVersion Version = getIsaVersion(STI->getCPU()); if (Version.Major >= 8) return 800; return 512; } unsigned getAddressableNumSGPRs(const MCSubtargetInfo *STI) { if (STI->getFeatureBits().test(FeatureSGPRInitBug)) return FIXED_NUM_SGPRS_FOR_INIT_BUG; IsaVersion Version = getIsaVersion(STI->getCPU()); if (Version.Major >= 8) return 102; return 104; } unsigned getMinNumSGPRs(const MCSubtargetInfo *STI, unsigned WavesPerEU) { assert(WavesPerEU != 0); if (WavesPerEU >= getMaxWavesPerEU()) return 0; unsigned MinNumSGPRs = getTotalNumSGPRs(STI) / (WavesPerEU + 1); if (STI->getFeatureBits().test(FeatureTrapHandler)) MinNumSGPRs -= std::min(MinNumSGPRs, (unsigned)TRAP_NUM_SGPRS); MinNumSGPRs = alignDown(MinNumSGPRs, getSGPRAllocGranule(STI)) + 1; return std::min(MinNumSGPRs, getAddressableNumSGPRs(STI)); } unsigned getMaxNumSGPRs(const MCSubtargetInfo *STI, unsigned WavesPerEU, bool Addressable) { assert(WavesPerEU != 0); IsaVersion Version = getIsaVersion(STI->getCPU()); unsigned AddressableNumSGPRs = getAddressableNumSGPRs(STI); if (Version.Major >= 8 && !Addressable) AddressableNumSGPRs = 112; unsigned MaxNumSGPRs = getTotalNumSGPRs(STI) / WavesPerEU; if (STI->getFeatureBits().test(FeatureTrapHandler)) MaxNumSGPRs -= std::min(MaxNumSGPRs, (unsigned)TRAP_NUM_SGPRS); MaxNumSGPRs = alignDown(MaxNumSGPRs, getSGPRAllocGranule(STI)); return std::min(MaxNumSGPRs, AddressableNumSGPRs); } unsigned getNumExtraSGPRs(const MCSubtargetInfo *STI, bool VCCUsed, bool FlatScrUsed, bool XNACKUsed) { unsigned ExtraSGPRs = 0; if (VCCUsed) ExtraSGPRs = 2; IsaVersion Version = getIsaVersion(STI->getCPU()); if (Version.Major < 8) { if (FlatScrUsed) ExtraSGPRs = 4; } else { if (XNACKUsed) ExtraSGPRs = 4; if (FlatScrUsed) ExtraSGPRs = 6; } return ExtraSGPRs; } unsigned getNumExtraSGPRs(const MCSubtargetInfo *STI, bool VCCUsed, bool FlatScrUsed) { return getNumExtraSGPRs(STI, VCCUsed, FlatScrUsed, STI->getFeatureBits().test(AMDGPU::FeatureXNACK)); } unsigned getNumSGPRBlocks(const MCSubtargetInfo *STI, unsigned NumSGPRs) { NumSGPRs = alignTo(std::max(1u, NumSGPRs), getSGPREncodingGranule(STI)); // SGPRBlocks is actual number of SGPR blocks minus 1. return NumSGPRs / getSGPREncodingGranule(STI) - 1; } unsigned getVGPRAllocGranule(const MCSubtargetInfo *STI) { return 4; } unsigned getVGPREncodingGranule(const MCSubtargetInfo *STI) { return getVGPRAllocGranule(STI); } unsigned getTotalNumVGPRs(const MCSubtargetInfo *STI) { return 256; } unsigned getAddressableNumVGPRs(const MCSubtargetInfo *STI) { return getTotalNumVGPRs(STI); } unsigned getMinNumVGPRs(const MCSubtargetInfo *STI, unsigned WavesPerEU) { assert(WavesPerEU != 0); if (WavesPerEU >= getMaxWavesPerEU()) return 0; unsigned MinNumVGPRs = alignDown(getTotalNumVGPRs(STI) / (WavesPerEU + 1), getVGPRAllocGranule(STI)) + 1; return std::min(MinNumVGPRs, getAddressableNumVGPRs(STI)); } unsigned getMaxNumVGPRs(const MCSubtargetInfo *STI, unsigned WavesPerEU) { assert(WavesPerEU != 0); unsigned MaxNumVGPRs = alignDown(getTotalNumVGPRs(STI) / WavesPerEU, getVGPRAllocGranule(STI)); unsigned AddressableNumVGPRs = getAddressableNumVGPRs(STI); return std::min(MaxNumVGPRs, AddressableNumVGPRs); } unsigned getNumVGPRBlocks(const MCSubtargetInfo *STI, unsigned NumVGPRs) { NumVGPRs = alignTo(std::max(1u, NumVGPRs), getVGPREncodingGranule(STI)); // VGPRBlocks is actual number of VGPR blocks minus 1. return NumVGPRs / getVGPREncodingGranule(STI) - 1; } } // end namespace IsaInfo void initDefaultAMDKernelCodeT(amd_kernel_code_t &Header, const MCSubtargetInfo *STI) { IsaVersion Version = getIsaVersion(STI->getCPU()); memset(&Header, 0, sizeof(Header)); Header.amd_kernel_code_version_major = 1; Header.amd_kernel_code_version_minor = 2; Header.amd_machine_kind = 1; // AMD_MACHINE_KIND_AMDGPU Header.amd_machine_version_major = Version.Major; Header.amd_machine_version_minor = Version.Minor; Header.amd_machine_version_stepping = Version.Stepping; Header.kernel_code_entry_byte_offset = sizeof(Header); // wavefront_size is specified as a power of 2: 2^6 = 64 threads. Header.wavefront_size = 6; // If the code object does not support indirect functions, then the value must // be 0xffffffff. Header.call_convention = -1; // These alignment values are specified in powers of two, so alignment = // 2^n. The minimum alignment is 2^4 = 16. Header.kernarg_segment_alignment = 4; Header.group_segment_alignment = 4; Header.private_segment_alignment = 4; } amdhsa::kernel_descriptor_t getDefaultAmdhsaKernelDescriptor() { amdhsa::kernel_descriptor_t KD; memset(&KD, 0, sizeof(KD)); AMDHSA_BITS_SET(KD.compute_pgm_rsrc1, amdhsa::COMPUTE_PGM_RSRC1_FLOAT_DENORM_MODE_16_64, amdhsa::FLOAT_DENORM_MODE_FLUSH_NONE); AMDHSA_BITS_SET(KD.compute_pgm_rsrc1, amdhsa::COMPUTE_PGM_RSRC1_ENABLE_DX10_CLAMP, 1); AMDHSA_BITS_SET(KD.compute_pgm_rsrc1, amdhsa::COMPUTE_PGM_RSRC1_ENABLE_IEEE_MODE, 1); AMDHSA_BITS_SET(KD.compute_pgm_rsrc2, amdhsa::COMPUTE_PGM_RSRC2_ENABLE_SGPR_WORKGROUP_ID_X, 1); return KD; } bool isGroupSegment(const GlobalValue *GV) { return GV->getType()->getAddressSpace() == AMDGPUAS::LOCAL_ADDRESS; } bool isGlobalSegment(const GlobalValue *GV) { return GV->getType()->getAddressSpace() == AMDGPUAS::GLOBAL_ADDRESS; } bool isReadOnlySegment(const GlobalValue *GV) { return GV->getType()->getAddressSpace() == AMDGPUAS::CONSTANT_ADDRESS || GV->getType()->getAddressSpace() == AMDGPUAS::CONSTANT_ADDRESS_32BIT; } bool shouldEmitConstantsToTextSection(const Triple &TT) { return TT.getOS() != Triple::AMDHSA; } int getIntegerAttribute(const Function &F, StringRef Name, int Default) { Attribute A = F.getFnAttribute(Name); int Result = Default; if (A.isStringAttribute()) { StringRef Str = A.getValueAsString(); if (Str.getAsInteger(0, Result)) { LLVMContext &Ctx = F.getContext(); Ctx.emitError("can't parse integer attribute " + Name); } } return Result; } std::pair getIntegerPairAttribute(const Function &F, StringRef Name, std::pair Default, bool OnlyFirstRequired) { Attribute A = F.getFnAttribute(Name); if (!A.isStringAttribute()) return Default; LLVMContext &Ctx = F.getContext(); std::pair Ints = Default; std::pair Strs = A.getValueAsString().split(','); if (Strs.first.trim().getAsInteger(0, Ints.first)) { Ctx.emitError("can't parse first integer attribute " + Name); return Default; } if (Strs.second.trim().getAsInteger(0, Ints.second)) { if (!OnlyFirstRequired || !Strs.second.trim().empty()) { Ctx.emitError("can't parse second integer attribute " + Name); return Default; } } return Ints; } unsigned getVmcntBitMask(const IsaVersion &Version) { unsigned VmcntLo = (1 << getVmcntBitWidthLo()) - 1; if (Version.Major < 9) return VmcntLo; unsigned VmcntHi = ((1 << getVmcntBitWidthHi()) - 1) << getVmcntBitWidthLo(); return VmcntLo | VmcntHi; } unsigned getExpcntBitMask(const IsaVersion &Version) { return (1 << getExpcntBitWidth()) - 1; } unsigned getLgkmcntBitMask(const IsaVersion &Version) { return (1 << getLgkmcntBitWidth()) - 1; } unsigned getWaitcntBitMask(const IsaVersion &Version) { unsigned VmcntLo = getBitMask(getVmcntBitShiftLo(), getVmcntBitWidthLo()); unsigned Expcnt = getBitMask(getExpcntBitShift(), getExpcntBitWidth()); unsigned Lgkmcnt = getBitMask(getLgkmcntBitShift(), getLgkmcntBitWidth()); unsigned Waitcnt = VmcntLo | Expcnt | Lgkmcnt; if (Version.Major < 9) return Waitcnt; unsigned VmcntHi = getBitMask(getVmcntBitShiftHi(), getVmcntBitWidthHi()); return Waitcnt | VmcntHi; } unsigned decodeVmcnt(const IsaVersion &Version, unsigned Waitcnt) { unsigned VmcntLo = unpackBits(Waitcnt, getVmcntBitShiftLo(), getVmcntBitWidthLo()); if (Version.Major < 9) return VmcntLo; unsigned VmcntHi = unpackBits(Waitcnt, getVmcntBitShiftHi(), getVmcntBitWidthHi()); VmcntHi <<= getVmcntBitWidthLo(); return VmcntLo | VmcntHi; } unsigned decodeExpcnt(const IsaVersion &Version, unsigned Waitcnt) { return unpackBits(Waitcnt, getExpcntBitShift(), getExpcntBitWidth()); } unsigned decodeLgkmcnt(const IsaVersion &Version, unsigned Waitcnt) { return unpackBits(Waitcnt, getLgkmcntBitShift(), getLgkmcntBitWidth()); } void decodeWaitcnt(const IsaVersion &Version, unsigned Waitcnt, unsigned &Vmcnt, unsigned &Expcnt, unsigned &Lgkmcnt) { Vmcnt = decodeVmcnt(Version, Waitcnt); Expcnt = decodeExpcnt(Version, Waitcnt); Lgkmcnt = decodeLgkmcnt(Version, Waitcnt); } Waitcnt decodeWaitcnt(const IsaVersion &Version, unsigned Encoded) { Waitcnt Decoded; Decoded.VmCnt = decodeVmcnt(Version, Encoded); Decoded.ExpCnt = decodeExpcnt(Version, Encoded); Decoded.LgkmCnt = decodeLgkmcnt(Version, Encoded); return Decoded; } unsigned encodeVmcnt(const IsaVersion &Version, unsigned Waitcnt, unsigned Vmcnt) { Waitcnt = packBits(Vmcnt, Waitcnt, getVmcntBitShiftLo(), getVmcntBitWidthLo()); if (Version.Major < 9) return Waitcnt; Vmcnt >>= getVmcntBitWidthLo(); return packBits(Vmcnt, Waitcnt, getVmcntBitShiftHi(), getVmcntBitWidthHi()); } unsigned encodeExpcnt(const IsaVersion &Version, unsigned Waitcnt, unsigned Expcnt) { return packBits(Expcnt, Waitcnt, getExpcntBitShift(), getExpcntBitWidth()); } unsigned encodeLgkmcnt(const IsaVersion &Version, unsigned Waitcnt, unsigned Lgkmcnt) { return packBits(Lgkmcnt, Waitcnt, getLgkmcntBitShift(), getLgkmcntBitWidth()); } unsigned encodeWaitcnt(const IsaVersion &Version, unsigned Vmcnt, unsigned Expcnt, unsigned Lgkmcnt) { unsigned Waitcnt = getWaitcntBitMask(Version); Waitcnt = encodeVmcnt(Version, Waitcnt, Vmcnt); Waitcnt = encodeExpcnt(Version, Waitcnt, Expcnt); Waitcnt = encodeLgkmcnt(Version, Waitcnt, Lgkmcnt); return Waitcnt; } unsigned encodeWaitcnt(const IsaVersion &Version, const Waitcnt &Decoded) { return encodeWaitcnt(Version, Decoded.VmCnt, Decoded.ExpCnt, Decoded.LgkmCnt); } unsigned getInitialPSInputAddr(const Function &F) { return getIntegerAttribute(F, "InitialPSInputAddr", 0); } bool isShader(CallingConv::ID cc) { switch(cc) { case CallingConv::AMDGPU_VS: case CallingConv::AMDGPU_LS: case CallingConv::AMDGPU_HS: case CallingConv::AMDGPU_ES: case CallingConv::AMDGPU_GS: case CallingConv::AMDGPU_PS: case CallingConv::AMDGPU_CS: return true; default: return false; } } bool isCompute(CallingConv::ID cc) { return !isShader(cc) || cc == CallingConv::AMDGPU_CS; } bool isEntryFunctionCC(CallingConv::ID CC) { switch (CC) { case CallingConv::AMDGPU_KERNEL: case CallingConv::SPIR_KERNEL: case CallingConv::AMDGPU_VS: case CallingConv::AMDGPU_GS: case CallingConv::AMDGPU_PS: case CallingConv::AMDGPU_CS: case CallingConv::AMDGPU_ES: case CallingConv::AMDGPU_HS: case CallingConv::AMDGPU_LS: return true; default: return false; } } bool hasXNACK(const MCSubtargetInfo &STI) { return STI.getFeatureBits()[AMDGPU::FeatureXNACK]; } bool hasSRAMECC(const MCSubtargetInfo &STI) { return STI.getFeatureBits()[AMDGPU::FeatureSRAMECC]; } bool hasMIMG_R128(const MCSubtargetInfo &STI) { return STI.getFeatureBits()[AMDGPU::FeatureMIMG_R128]; } bool hasPackedD16(const MCSubtargetInfo &STI) { return !STI.getFeatureBits()[AMDGPU::FeatureUnpackedD16VMem]; } bool isSI(const MCSubtargetInfo &STI) { return STI.getFeatureBits()[AMDGPU::FeatureSouthernIslands]; } bool isCI(const MCSubtargetInfo &STI) { return STI.getFeatureBits()[AMDGPU::FeatureSeaIslands]; } bool isVI(const MCSubtargetInfo &STI) { return STI.getFeatureBits()[AMDGPU::FeatureVolcanicIslands]; } bool isGFX9(const MCSubtargetInfo &STI) { return STI.getFeatureBits()[AMDGPU::FeatureGFX9]; } bool isGCN3Encoding(const MCSubtargetInfo &STI) { return STI.getFeatureBits()[AMDGPU::FeatureGCN3Encoding]; } bool isSGPR(unsigned Reg, const MCRegisterInfo* TRI) { const MCRegisterClass SGPRClass = TRI->getRegClass(AMDGPU::SReg_32RegClassID); const unsigned FirstSubReg = TRI->getSubReg(Reg, 1); return SGPRClass.contains(FirstSubReg != 0 ? FirstSubReg : Reg) || Reg == AMDGPU::SCC; } bool isRegIntersect(unsigned Reg0, unsigned Reg1, const MCRegisterInfo* TRI) { for (MCRegAliasIterator R(Reg0, TRI, true); R.isValid(); ++R) { if (*R == Reg1) return true; } return false; } #define MAP_REG2REG \ using namespace AMDGPU; \ switch(Reg) { \ default: return Reg; \ CASE_CI_VI(FLAT_SCR) \ CASE_CI_VI(FLAT_SCR_LO) \ CASE_CI_VI(FLAT_SCR_HI) \ CASE_VI_GFX9(TTMP0) \ CASE_VI_GFX9(TTMP1) \ CASE_VI_GFX9(TTMP2) \ CASE_VI_GFX9(TTMP3) \ CASE_VI_GFX9(TTMP4) \ CASE_VI_GFX9(TTMP5) \ CASE_VI_GFX9(TTMP6) \ CASE_VI_GFX9(TTMP7) \ CASE_VI_GFX9(TTMP8) \ CASE_VI_GFX9(TTMP9) \ CASE_VI_GFX9(TTMP10) \ CASE_VI_GFX9(TTMP11) \ CASE_VI_GFX9(TTMP12) \ CASE_VI_GFX9(TTMP13) \ CASE_VI_GFX9(TTMP14) \ CASE_VI_GFX9(TTMP15) \ CASE_VI_GFX9(TTMP0_TTMP1) \ CASE_VI_GFX9(TTMP2_TTMP3) \ CASE_VI_GFX9(TTMP4_TTMP5) \ CASE_VI_GFX9(TTMP6_TTMP7) \ CASE_VI_GFX9(TTMP8_TTMP9) \ CASE_VI_GFX9(TTMP10_TTMP11) \ CASE_VI_GFX9(TTMP12_TTMP13) \ CASE_VI_GFX9(TTMP14_TTMP15) \ CASE_VI_GFX9(TTMP0_TTMP1_TTMP2_TTMP3) \ CASE_VI_GFX9(TTMP4_TTMP5_TTMP6_TTMP7) \ CASE_VI_GFX9(TTMP8_TTMP9_TTMP10_TTMP11) \ CASE_VI_GFX9(TTMP12_TTMP13_TTMP14_TTMP15) \ CASE_VI_GFX9(TTMP0_TTMP1_TTMP2_TTMP3_TTMP4_TTMP5_TTMP6_TTMP7) \ CASE_VI_GFX9(TTMP4_TTMP5_TTMP6_TTMP7_TTMP8_TTMP9_TTMP10_TTMP11) \ CASE_VI_GFX9(TTMP8_TTMP9_TTMP10_TTMP11_TTMP12_TTMP13_TTMP14_TTMP15) \ CASE_VI_GFX9(TTMP0_TTMP1_TTMP2_TTMP3_TTMP4_TTMP5_TTMP6_TTMP7_TTMP8_TTMP9_TTMP10_TTMP11_TTMP12_TTMP13_TTMP14_TTMP15) \ } #define CASE_CI_VI(node) \ assert(!isSI(STI)); \ case node: return isCI(STI) ? node##_ci : node##_vi; #define CASE_VI_GFX9(node) \ case node: return isGFX9(STI) ? node##_gfx9 : node##_vi; unsigned getMCReg(unsigned Reg, const MCSubtargetInfo &STI) { if (STI.getTargetTriple().getArch() == Triple::r600) return Reg; MAP_REG2REG } #undef CASE_CI_VI #undef CASE_VI_GFX9 #define CASE_CI_VI(node) case node##_ci: case node##_vi: return node; #define CASE_VI_GFX9(node) case node##_vi: case node##_gfx9: return node; unsigned mc2PseudoReg(unsigned Reg) { MAP_REG2REG } #undef CASE_CI_VI #undef CASE_VI_GFX9 #undef MAP_REG2REG bool isSISrcOperand(const MCInstrDesc &Desc, unsigned OpNo) { assert(OpNo < Desc.NumOperands); unsigned OpType = Desc.OpInfo[OpNo].OperandType; return OpType >= AMDGPU::OPERAND_SRC_FIRST && OpType <= AMDGPU::OPERAND_SRC_LAST; } bool isSISrcFPOperand(const MCInstrDesc &Desc, unsigned OpNo) { assert(OpNo < Desc.NumOperands); unsigned OpType = Desc.OpInfo[OpNo].OperandType; switch (OpType) { case AMDGPU::OPERAND_REG_IMM_FP32: case AMDGPU::OPERAND_REG_IMM_FP64: case AMDGPU::OPERAND_REG_IMM_FP16: case AMDGPU::OPERAND_REG_INLINE_C_FP32: case AMDGPU::OPERAND_REG_INLINE_C_FP64: case AMDGPU::OPERAND_REG_INLINE_C_FP16: case AMDGPU::OPERAND_REG_INLINE_C_V2FP16: return true; default: return false; } } bool isSISrcInlinableOperand(const MCInstrDesc &Desc, unsigned OpNo) { assert(OpNo < Desc.NumOperands); unsigned OpType = Desc.OpInfo[OpNo].OperandType; return OpType >= AMDGPU::OPERAND_REG_INLINE_C_FIRST && OpType <= AMDGPU::OPERAND_REG_INLINE_C_LAST; } // Avoid using MCRegisterClass::getSize, since that function will go away // (move from MC* level to Target* level). Return size in bits. unsigned getRegBitWidth(unsigned RCID) { switch (RCID) { case AMDGPU::SGPR_32RegClassID: case AMDGPU::VGPR_32RegClassID: case AMDGPU::VS_32RegClassID: case AMDGPU::SReg_32RegClassID: case AMDGPU::SReg_32_XM0RegClassID: return 32; case AMDGPU::SGPR_64RegClassID: case AMDGPU::VS_64RegClassID: case AMDGPU::SReg_64RegClassID: case AMDGPU::VReg_64RegClassID: case AMDGPU::SReg_64_XEXECRegClassID: return 64; case AMDGPU::VReg_96RegClassID: return 96; case AMDGPU::SGPR_128RegClassID: case AMDGPU::SReg_128RegClassID: case AMDGPU::VReg_128RegClassID: return 128; case AMDGPU::SReg_256RegClassID: case AMDGPU::VReg_256RegClassID: return 256; case AMDGPU::SReg_512RegClassID: case AMDGPU::VReg_512RegClassID: return 512; default: llvm_unreachable("Unexpected register class"); } } unsigned getRegBitWidth(const MCRegisterClass &RC) { return getRegBitWidth(RC.getID()); } unsigned getRegOperandSize(const MCRegisterInfo *MRI, const MCInstrDesc &Desc, unsigned OpNo) { assert(OpNo < Desc.NumOperands); unsigned RCID = Desc.OpInfo[OpNo].RegClass; return getRegBitWidth(MRI->getRegClass(RCID)) / 8; } bool isInlinableLiteral64(int64_t Literal, bool HasInv2Pi) { if (Literal >= -16 && Literal <= 64) return true; uint64_t Val = static_cast(Literal); return (Val == DoubleToBits(0.0)) || (Val == DoubleToBits(1.0)) || (Val == DoubleToBits(-1.0)) || (Val == DoubleToBits(0.5)) || (Val == DoubleToBits(-0.5)) || (Val == DoubleToBits(2.0)) || (Val == DoubleToBits(-2.0)) || (Val == DoubleToBits(4.0)) || (Val == DoubleToBits(-4.0)) || (Val == 0x3fc45f306dc9c882 && HasInv2Pi); } bool isInlinableLiteral32(int32_t Literal, bool HasInv2Pi) { if (Literal >= -16 && Literal <= 64) return true; // The actual type of the operand does not seem to matter as long // as the bits match one of the inline immediate values. For example: // // -nan has the hexadecimal encoding of 0xfffffffe which is -2 in decimal, // so it is a legal inline immediate. // // 1065353216 has the hexadecimal encoding 0x3f800000 which is 1.0f in // floating-point, so it is a legal inline immediate. uint32_t Val = static_cast(Literal); return (Val == FloatToBits(0.0f)) || (Val == FloatToBits(1.0f)) || (Val == FloatToBits(-1.0f)) || (Val == FloatToBits(0.5f)) || (Val == FloatToBits(-0.5f)) || (Val == FloatToBits(2.0f)) || (Val == FloatToBits(-2.0f)) || (Val == FloatToBits(4.0f)) || (Val == FloatToBits(-4.0f)) || (Val == 0x3e22f983 && HasInv2Pi); } bool isInlinableLiteral16(int16_t Literal, bool HasInv2Pi) { if (!HasInv2Pi) return false; if (Literal >= -16 && Literal <= 64) return true; uint16_t Val = static_cast(Literal); return Val == 0x3C00 || // 1.0 Val == 0xBC00 || // -1.0 Val == 0x3800 || // 0.5 Val == 0xB800 || // -0.5 Val == 0x4000 || // 2.0 Val == 0xC000 || // -2.0 Val == 0x4400 || // 4.0 Val == 0xC400 || // -4.0 Val == 0x3118; // 1/2pi } bool isInlinableLiteralV216(int32_t Literal, bool HasInv2Pi) { assert(HasInv2Pi); int16_t Lo16 = static_cast(Literal); int16_t Hi16 = static_cast(Literal >> 16); return Lo16 == Hi16 && isInlinableLiteral16(Lo16, HasInv2Pi); } bool isArgPassedInSGPR(const Argument *A) { const Function *F = A->getParent(); // Arguments to compute shaders are never a source of divergence. CallingConv::ID CC = F->getCallingConv(); switch (CC) { case CallingConv::AMDGPU_KERNEL: case CallingConv::SPIR_KERNEL: return true; case CallingConv::AMDGPU_VS: case CallingConv::AMDGPU_LS: case CallingConv::AMDGPU_HS: case CallingConv::AMDGPU_ES: case CallingConv::AMDGPU_GS: case CallingConv::AMDGPU_PS: case CallingConv::AMDGPU_CS: // For non-compute shaders, SGPR inputs are marked with either inreg or byval. // Everything else is in VGPRs. return F->getAttributes().hasParamAttribute(A->getArgNo(), Attribute::InReg) || F->getAttributes().hasParamAttribute(A->getArgNo(), Attribute::ByVal); default: // TODO: Should calls support inreg for SGPR inputs? return false; } } int64_t getSMRDEncodedOffset(const MCSubtargetInfo &ST, int64_t ByteOffset) { if (isGCN3Encoding(ST)) return ByteOffset; return ByteOffset >> 2; } bool isLegalSMRDImmOffset(const MCSubtargetInfo &ST, int64_t ByteOffset) { int64_t EncodedOffset = getSMRDEncodedOffset(ST, ByteOffset); return isGCN3Encoding(ST) ? isUInt<20>(EncodedOffset) : isUInt<8>(EncodedOffset); } // Given Imm, split it into the values to put into the SOffset and ImmOffset // fields in an MUBUF instruction. Return false if it is not possible (due to a // hardware bug needing a workaround). // // The required alignment ensures that individual address components remain // aligned if they are aligned to begin with. It also ensures that additional // offsets within the given alignment can be added to the resulting ImmOffset. bool splitMUBUFOffset(uint32_t Imm, uint32_t &SOffset, uint32_t &ImmOffset, const GCNSubtarget *Subtarget, uint32_t Align) { const uint32_t MaxImm = alignDown(4095, Align); uint32_t Overflow = 0; if (Imm > MaxImm) { if (Imm <= MaxImm + 64) { // Use an SOffset inline constant for 4..64 Overflow = Imm - MaxImm; Imm = MaxImm; } else { // Try to keep the same value in SOffset for adjacent loads, so that // the corresponding register contents can be re-used. // // Load values with all low-bits (except for alignment bits) set into // SOffset, so that a larger range of values can be covered using // s_movk_i32. // // Atomic operations fail to work correctly when individual address // components are unaligned, even if their sum is aligned. uint32_t High = (Imm + Align) & ~4095; uint32_t Low = (Imm + Align) & 4095; Imm = Low; Overflow = High - Align; } } // There is a hardware bug in SI and CI which prevents address clamping in // MUBUF instructions from working correctly with SOffsets. The immediate // offset is unaffected. if (Overflow > 0 && Subtarget->getGeneration() <= AMDGPUSubtarget::SEA_ISLANDS) return false; ImmOffset = Imm; SOffset = Overflow; return true; } namespace { struct SourceOfDivergence { unsigned Intr; }; const SourceOfDivergence *lookupSourceOfDivergence(unsigned Intr); #define GET_SourcesOfDivergence_IMPL #include "AMDGPUGenSearchableTables.inc" } // end anonymous namespace bool isIntrinsicSourceOfDivergence(unsigned IntrID) { return lookupSourceOfDivergence(IntrID); } } // namespace AMDGPU } // namespace llvm