//===- AMDGPUBaseInfo.h - Top level definitions for AMDGPU ------*- 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_LIB_TARGET_AMDGPU_UTILS_AMDGPUBASEINFO_H #define LLVM_LIB_TARGET_AMDGPU_UTILS_AMDGPUBASEINFO_H #include "SIDefines.h" #include "llvm/IR/CallingConv.h" #include "llvm/Support/Alignment.h" struct amd_kernel_code_t; namespace llvm { struct Align; class Argument; class Function; class GCNSubtarget; class GlobalValue; class MCRegisterClass; class MCRegisterInfo; class MCSubtargetInfo; class StringRef; class Triple; namespace amdhsa { struct kernel_descriptor_t; } namespace AMDGPU { struct IsaVersion; /// \returns HSA OS ABI Version identification. Optional getHsaAbiVersion(const MCSubtargetInfo *STI); /// \returns True if HSA OS ABI Version identification is 2, /// false otherwise. bool isHsaAbiVersion2(const MCSubtargetInfo *STI); /// \returns True if HSA OS ABI Version identification is 3, /// false otherwise. bool isHsaAbiVersion3(const MCSubtargetInfo *STI); /// \returns True if HSA OS ABI Version identification is 4, /// false otherwise. bool isHsaAbiVersion4(const MCSubtargetInfo *STI); /// \returns True if HSA OS ABI Version identification is 5, /// false otherwise. bool isHsaAbiVersion5(const MCSubtargetInfo *STI); /// \returns True if HSA OS ABI Version identification is 3 or 4, /// false otherwise. bool isHsaAbiVersion3AndAbove(const MCSubtargetInfo *STI); struct GcnBufferFormatInfo { unsigned Format; unsigned BitsPerComp; unsigned NumComponents; unsigned NumFormat; unsigned DataFormat; }; #define GET_MIMGBaseOpcode_DECL #define GET_MIMGDim_DECL #define GET_MIMGEncoding_DECL #define GET_MIMGLZMapping_DECL #define GET_MIMGMIPMapping_DECL #define GET_MIMGBiASMapping_DECL #include "AMDGPUGenSearchableTables.inc" namespace IsaInfo { enum { // The closed Vulkan driver sets 96, which limits the wave count to 8 but // doesn't spill SGPRs as much as when 80 is set. FIXED_NUM_SGPRS_FOR_INIT_BUG = 96, TRAP_NUM_SGPRS = 16 }; enum class TargetIDSetting { Unsupported, Any, Off, On }; class AMDGPUTargetID { private: const MCSubtargetInfo &STI; TargetIDSetting XnackSetting; TargetIDSetting SramEccSetting; public: explicit AMDGPUTargetID(const MCSubtargetInfo &STI); ~AMDGPUTargetID() = default; /// \return True if the current xnack setting is not "Unsupported". bool isXnackSupported() const { return XnackSetting != TargetIDSetting::Unsupported; } /// \returns True if the current xnack setting is "On" or "Any". bool isXnackOnOrAny() const { return XnackSetting == TargetIDSetting::On || XnackSetting == TargetIDSetting::Any; } /// \returns True if current xnack setting is "On" or "Off", /// false otherwise. bool isXnackOnOrOff() const { return getXnackSetting() == TargetIDSetting::On || getXnackSetting() == TargetIDSetting::Off; } /// \returns The current xnack TargetIDSetting, possible options are /// "Unsupported", "Any", "Off", and "On". TargetIDSetting getXnackSetting() const { return XnackSetting; } /// Sets xnack setting to \p NewXnackSetting. void setXnackSetting(TargetIDSetting NewXnackSetting) { XnackSetting = NewXnackSetting; } /// \return True if the current sramecc setting is not "Unsupported". bool isSramEccSupported() const { return SramEccSetting != TargetIDSetting::Unsupported; } /// \returns True if the current sramecc setting is "On" or "Any". bool isSramEccOnOrAny() const { return SramEccSetting == TargetIDSetting::On || SramEccSetting == TargetIDSetting::Any; } /// \returns True if current sramecc setting is "On" or "Off", /// false otherwise. bool isSramEccOnOrOff() const { return getSramEccSetting() == TargetIDSetting::On || getSramEccSetting() == TargetIDSetting::Off; } /// \returns The current sramecc TargetIDSetting, possible options are /// "Unsupported", "Any", "Off", and "On". TargetIDSetting getSramEccSetting() const { return SramEccSetting; } /// Sets sramecc setting to \p NewSramEccSetting. void setSramEccSetting(TargetIDSetting NewSramEccSetting) { SramEccSetting = NewSramEccSetting; } void setTargetIDFromFeaturesString(StringRef FS); void setTargetIDFromTargetIDStream(StringRef TargetID); /// \returns String representation of an object. std::string toString() const; }; /// \returns Wavefront size for given subtarget \p STI. unsigned getWavefrontSize(const MCSubtargetInfo *STI); /// \returns Local memory size in bytes for given subtarget \p STI. unsigned getLocalMemorySize(const MCSubtargetInfo *STI); /// \returns Number of execution units per compute unit for given subtarget \p /// STI. unsigned getEUsPerCU(const MCSubtargetInfo *STI); /// \returns Maximum number of work groups per compute unit for given subtarget /// \p STI and limited by given \p FlatWorkGroupSize. unsigned getMaxWorkGroupsPerCU(const MCSubtargetInfo *STI, unsigned FlatWorkGroupSize); /// \returns Minimum number of waves per execution unit for given subtarget \p /// STI. unsigned getMinWavesPerEU(const MCSubtargetInfo *STI); /// \returns Maximum number of waves per execution unit for given subtarget \p /// STI without any kind of limitation. unsigned getMaxWavesPerEU(const MCSubtargetInfo *STI); /// \returns Number of waves per execution unit required to support the given \p /// FlatWorkGroupSize. unsigned getWavesPerEUForWorkGroup(const MCSubtargetInfo *STI, unsigned FlatWorkGroupSize); /// \returns Minimum flat work group size for given subtarget \p STI. unsigned getMinFlatWorkGroupSize(const MCSubtargetInfo *STI); /// \returns Maximum flat work group size for given subtarget \p STI. unsigned getMaxFlatWorkGroupSize(const MCSubtargetInfo *STI); /// \returns Number of waves per work group for given subtarget \p STI and /// \p FlatWorkGroupSize. unsigned getWavesPerWorkGroup(const MCSubtargetInfo *STI, unsigned FlatWorkGroupSize); /// \returns SGPR allocation granularity for given subtarget \p STI. unsigned getSGPRAllocGranule(const MCSubtargetInfo *STI); /// \returns SGPR encoding granularity for given subtarget \p STI. unsigned getSGPREncodingGranule(const MCSubtargetInfo *STI); /// \returns Total number of SGPRs for given subtarget \p STI. unsigned getTotalNumSGPRs(const MCSubtargetInfo *STI); /// \returns Addressable number of SGPRs for given subtarget \p STI. unsigned getAddressableNumSGPRs(const MCSubtargetInfo *STI); /// \returns Minimum number of SGPRs that meets the given number of waves per /// execution unit requirement for given subtarget \p STI. unsigned getMinNumSGPRs(const MCSubtargetInfo *STI, unsigned WavesPerEU); /// \returns Maximum number of SGPRs that meets the given number of waves per /// execution unit requirement for given subtarget \p STI. unsigned getMaxNumSGPRs(const MCSubtargetInfo *STI, unsigned WavesPerEU, bool Addressable); /// \returns Number of extra SGPRs implicitly required by given subtarget \p /// STI when the given special registers are used. unsigned getNumExtraSGPRs(const MCSubtargetInfo *STI, bool VCCUsed, bool FlatScrUsed, bool XNACKUsed); /// \returns Number of extra SGPRs implicitly required by given subtarget \p /// STI when the given special registers are used. XNACK is inferred from /// \p STI. unsigned getNumExtraSGPRs(const MCSubtargetInfo *STI, bool VCCUsed, bool FlatScrUsed); /// \returns Number of SGPR blocks needed for given subtarget \p STI when /// \p NumSGPRs are used. \p NumSGPRs should already include any special /// register counts. unsigned getNumSGPRBlocks(const MCSubtargetInfo *STI, unsigned NumSGPRs); /// \returns VGPR allocation granularity for given subtarget \p STI. /// /// For subtargets which support it, \p EnableWavefrontSize32 should match /// the ENABLE_WAVEFRONT_SIZE32 kernel descriptor field. unsigned getVGPRAllocGranule(const MCSubtargetInfo *STI, Optional EnableWavefrontSize32 = None); /// \returns VGPR encoding granularity for given subtarget \p STI. /// /// For subtargets which support it, \p EnableWavefrontSize32 should match /// the ENABLE_WAVEFRONT_SIZE32 kernel descriptor field. unsigned getVGPREncodingGranule(const MCSubtargetInfo *STI, Optional EnableWavefrontSize32 = None); /// \returns Total number of VGPRs for given subtarget \p STI. unsigned getTotalNumVGPRs(const MCSubtargetInfo *STI); /// \returns Addressable number of VGPRs for given subtarget \p STI. unsigned getAddressableNumVGPRs(const MCSubtargetInfo *STI); /// \returns Minimum number of VGPRs that meets given number of waves per /// execution unit requirement for given subtarget \p STI. unsigned getMinNumVGPRs(const MCSubtargetInfo *STI, unsigned WavesPerEU); /// \returns Maximum number of VGPRs that meets given number of waves per /// execution unit requirement for given subtarget \p STI. unsigned getMaxNumVGPRs(const MCSubtargetInfo *STI, unsigned WavesPerEU); /// \returns Number of VGPR blocks needed for given subtarget \p STI when /// \p NumVGPRs are used. /// /// For subtargets which support it, \p EnableWavefrontSize32 should match the /// ENABLE_WAVEFRONT_SIZE32 kernel descriptor field. unsigned getNumVGPRBlocks(const MCSubtargetInfo *STI, unsigned NumSGPRs, Optional EnableWavefrontSize32 = None); } // end namespace IsaInfo LLVM_READONLY int16_t getNamedOperandIdx(uint16_t Opcode, uint16_t NamedIdx); LLVM_READONLY int getSOPPWithRelaxation(uint16_t Opcode); struct MIMGBaseOpcodeInfo { MIMGBaseOpcode BaseOpcode; bool Store; bool Atomic; bool AtomicX2; bool Sampler; bool Gather4; uint8_t NumExtraArgs; bool Gradients; bool G16; bool Coordinates; bool LodOrClampOrMip; bool HasD16; bool MSAA; bool BVH; }; LLVM_READONLY const MIMGBaseOpcodeInfo *getMIMGBaseOpcode(unsigned Opc); LLVM_READONLY const MIMGBaseOpcodeInfo *getMIMGBaseOpcodeInfo(unsigned BaseOpcode); struct MIMGDimInfo { MIMGDim Dim; uint8_t NumCoords; uint8_t NumGradients; bool MSAA; bool DA; uint8_t Encoding; const char *AsmSuffix; }; LLVM_READONLY const MIMGDimInfo *getMIMGDimInfo(unsigned DimEnum); LLVM_READONLY const MIMGDimInfo *getMIMGDimInfoByEncoding(uint8_t DimEnc); LLVM_READONLY const MIMGDimInfo *getMIMGDimInfoByAsmSuffix(StringRef AsmSuffix); struct MIMGLZMappingInfo { MIMGBaseOpcode L; MIMGBaseOpcode LZ; }; struct MIMGMIPMappingInfo { MIMGBaseOpcode MIP; MIMGBaseOpcode NONMIP; }; struct MIMGBiasMappingInfo { MIMGBaseOpcode Bias; MIMGBaseOpcode NoBias; }; struct MIMGOffsetMappingInfo { MIMGBaseOpcode Offset; MIMGBaseOpcode NoOffset; }; struct MIMGG16MappingInfo { MIMGBaseOpcode G; MIMGBaseOpcode G16; }; LLVM_READONLY const MIMGLZMappingInfo *getMIMGLZMappingInfo(unsigned L); LLVM_READONLY const MIMGMIPMappingInfo *getMIMGMIPMappingInfo(unsigned MIP); LLVM_READONLY const MIMGBiasMappingInfo *getMIMGBiasMappingInfo(unsigned Bias); LLVM_READONLY const MIMGOffsetMappingInfo *getMIMGOffsetMappingInfo(unsigned Offset); LLVM_READONLY const MIMGG16MappingInfo *getMIMGG16MappingInfo(unsigned G); LLVM_READONLY int getMIMGOpcode(unsigned BaseOpcode, unsigned MIMGEncoding, unsigned VDataDwords, unsigned VAddrDwords); LLVM_READONLY int getMaskedMIMGOp(unsigned Opc, unsigned NewChannels); LLVM_READONLY unsigned getAddrSizeMIMGOp(const MIMGBaseOpcodeInfo *BaseOpcode, const MIMGDimInfo *Dim, bool IsA16, bool IsG16Supported); struct MIMGInfo { uint16_t Opcode; uint16_t BaseOpcode; uint8_t MIMGEncoding; uint8_t VDataDwords; uint8_t VAddrDwords; }; LLVM_READONLY const MIMGInfo *getMIMGInfo(unsigned Opc); LLVM_READONLY int getMTBUFBaseOpcode(unsigned Opc); LLVM_READONLY int getMTBUFOpcode(unsigned BaseOpc, unsigned Elements); LLVM_READONLY int getMTBUFElements(unsigned Opc); LLVM_READONLY bool getMTBUFHasVAddr(unsigned Opc); LLVM_READONLY bool getMTBUFHasSrsrc(unsigned Opc); LLVM_READONLY bool getMTBUFHasSoffset(unsigned Opc); LLVM_READONLY int getMUBUFBaseOpcode(unsigned Opc); LLVM_READONLY int getMUBUFOpcode(unsigned BaseOpc, unsigned Elements); LLVM_READONLY int getMUBUFElements(unsigned Opc); LLVM_READONLY bool getMUBUFHasVAddr(unsigned Opc); LLVM_READONLY bool getMUBUFHasSrsrc(unsigned Opc); LLVM_READONLY bool getMUBUFHasSoffset(unsigned Opc); LLVM_READONLY bool getMUBUFIsBufferInv(unsigned Opc); LLVM_READONLY bool getSMEMIsBuffer(unsigned Opc); LLVM_READONLY bool getVOP1IsSingle(unsigned Opc); LLVM_READONLY bool getVOP2IsSingle(unsigned Opc); LLVM_READONLY bool getVOP3IsSingle(unsigned Opc); LLVM_READONLY const GcnBufferFormatInfo *getGcnBufferFormatInfo(uint8_t BitsPerComp, uint8_t NumComponents, uint8_t NumFormat, const MCSubtargetInfo &STI); LLVM_READONLY const GcnBufferFormatInfo *getGcnBufferFormatInfo(uint8_t Format, const MCSubtargetInfo &STI); LLVM_READONLY int getMCOpcode(uint16_t Opcode, unsigned Gen); void initDefaultAMDKernelCodeT(amd_kernel_code_t &Header, const MCSubtargetInfo *STI); amdhsa::kernel_descriptor_t getDefaultAmdhsaKernelDescriptor( const MCSubtargetInfo *STI); bool isGroupSegment(const GlobalValue *GV); bool isGlobalSegment(const GlobalValue *GV); bool isReadOnlySegment(const GlobalValue *GV); /// \returns True if constants should be emitted to .text section for given /// target triple \p TT, false otherwise. bool shouldEmitConstantsToTextSection(const Triple &TT); /// \returns Integer value requested using \p F's \p Name attribute. /// /// \returns \p Default if attribute is not present. /// /// \returns \p Default and emits error if requested value cannot be converted /// to integer. int getIntegerAttribute(const Function &F, StringRef Name, int Default); /// \returns A pair of integer values requested using \p F's \p Name attribute /// in "first[,second]" format ("second" is optional unless \p OnlyFirstRequired /// is false). /// /// \returns \p Default if attribute is not present. /// /// \returns \p Default and emits error if one of the requested values cannot be /// converted to integer, or \p OnlyFirstRequired is false and "second" value is /// not present. std::pair getIntegerPairAttribute(const Function &F, StringRef Name, std::pair Default, bool OnlyFirstRequired = false); /// Represents the counter values to wait for in an s_waitcnt instruction. /// /// Large values (including the maximum possible integer) can be used to /// represent "don't care" waits. struct Waitcnt { unsigned VmCnt = ~0u; unsigned ExpCnt = ~0u; unsigned LgkmCnt = ~0u; unsigned VsCnt = ~0u; Waitcnt() {} Waitcnt(unsigned VmCnt, unsigned ExpCnt, unsigned LgkmCnt, unsigned VsCnt) : VmCnt(VmCnt), ExpCnt(ExpCnt), LgkmCnt(LgkmCnt), VsCnt(VsCnt) {} static Waitcnt allZero(bool HasVscnt) { return Waitcnt(0, 0, 0, HasVscnt ? 0 : ~0u); } static Waitcnt allZeroExceptVsCnt() { return Waitcnt(0, 0, 0, ~0u); } bool hasWait() const { return VmCnt != ~0u || ExpCnt != ~0u || LgkmCnt != ~0u || VsCnt != ~0u; } bool hasWaitExceptVsCnt() const { return VmCnt != ~0u || ExpCnt != ~0u || LgkmCnt != ~0u; } bool hasWaitVsCnt() const { return VsCnt != ~0u; } bool dominates(const Waitcnt &Other) const { return VmCnt <= Other.VmCnt && ExpCnt <= Other.ExpCnt && LgkmCnt <= Other.LgkmCnt && VsCnt <= Other.VsCnt; } Waitcnt combined(const Waitcnt &Other) const { return Waitcnt(std::min(VmCnt, Other.VmCnt), std::min(ExpCnt, Other.ExpCnt), std::min(LgkmCnt, Other.LgkmCnt), std::min(VsCnt, Other.VsCnt)); } }; /// \returns Vmcnt bit mask for given isa \p Version. unsigned getVmcntBitMask(const IsaVersion &Version); /// \returns Expcnt bit mask for given isa \p Version. unsigned getExpcntBitMask(const IsaVersion &Version); /// \returns Lgkmcnt bit mask for given isa \p Version. unsigned getLgkmcntBitMask(const IsaVersion &Version); /// \returns Waitcnt bit mask for given isa \p Version. unsigned getWaitcntBitMask(const IsaVersion &Version); /// \returns Decoded Vmcnt from given \p Waitcnt for given isa \p Version. unsigned decodeVmcnt(const IsaVersion &Version, unsigned Waitcnt); /// \returns Decoded Expcnt from given \p Waitcnt for given isa \p Version. unsigned decodeExpcnt(const IsaVersion &Version, unsigned Waitcnt); /// \returns Decoded Lgkmcnt from given \p Waitcnt for given isa \p Version. unsigned decodeLgkmcnt(const IsaVersion &Version, unsigned Waitcnt); /// Decodes Vmcnt, Expcnt and Lgkmcnt from given \p Waitcnt for given isa /// \p Version, and writes decoded values into \p Vmcnt, \p Expcnt and /// \p Lgkmcnt respectively. /// /// \details \p Vmcnt, \p Expcnt and \p Lgkmcnt are decoded as follows: /// \p Vmcnt = \p Waitcnt[3:0] (pre-gfx9 only) /// \p Vmcnt = \p Waitcnt[3:0] | \p Waitcnt[15:14] (gfx9+ only) /// \p Expcnt = \p Waitcnt[6:4] /// \p Lgkmcnt = \p Waitcnt[11:8] (pre-gfx10 only) /// \p Lgkmcnt = \p Waitcnt[13:8] (gfx10+ only) void decodeWaitcnt(const IsaVersion &Version, unsigned Waitcnt, unsigned &Vmcnt, unsigned &Expcnt, unsigned &Lgkmcnt); Waitcnt decodeWaitcnt(const IsaVersion &Version, unsigned Encoded); /// \returns \p Waitcnt with encoded \p Vmcnt for given isa \p Version. unsigned encodeVmcnt(const IsaVersion &Version, unsigned Waitcnt, unsigned Vmcnt); /// \returns \p Waitcnt with encoded \p Expcnt for given isa \p Version. unsigned encodeExpcnt(const IsaVersion &Version, unsigned Waitcnt, unsigned Expcnt); /// \returns \p Waitcnt with encoded \p Lgkmcnt for given isa \p Version. unsigned encodeLgkmcnt(const IsaVersion &Version, unsigned Waitcnt, unsigned Lgkmcnt); /// Encodes \p Vmcnt, \p Expcnt and \p Lgkmcnt into Waitcnt for given isa /// \p Version. /// /// \details \p Vmcnt, \p Expcnt and \p Lgkmcnt are encoded as follows: /// Waitcnt[3:0] = \p Vmcnt (pre-gfx9 only) /// Waitcnt[3:0] = \p Vmcnt[3:0] (gfx9+ only) /// Waitcnt[6:4] = \p Expcnt /// Waitcnt[11:8] = \p Lgkmcnt (pre-gfx10 only) /// Waitcnt[13:8] = \p Lgkmcnt (gfx10+ only) /// Waitcnt[15:14] = \p Vmcnt[5:4] (gfx9+ only) /// /// \returns Waitcnt with encoded \p Vmcnt, \p Expcnt and \p Lgkmcnt for given /// isa \p Version. unsigned encodeWaitcnt(const IsaVersion &Version, unsigned Vmcnt, unsigned Expcnt, unsigned Lgkmcnt); unsigned encodeWaitcnt(const IsaVersion &Version, const Waitcnt &Decoded); namespace Hwreg { LLVM_READONLY int64_t getHwregId(const StringRef Name); LLVM_READNONE bool isValidHwreg(int64_t Id, const MCSubtargetInfo &STI); LLVM_READNONE bool isValidHwreg(int64_t Id); LLVM_READNONE bool isValidHwregOffset(int64_t Offset); LLVM_READNONE bool isValidHwregWidth(int64_t Width); LLVM_READNONE uint64_t encodeHwreg(uint64_t Id, uint64_t Offset, uint64_t Width); LLVM_READNONE StringRef getHwreg(unsigned Id, const MCSubtargetInfo &STI); void decodeHwreg(unsigned Val, unsigned &Id, unsigned &Offset, unsigned &Width); } // namespace Hwreg namespace Exp { bool getTgtName(unsigned Id, StringRef &Name, int &Index); LLVM_READONLY unsigned getTgtId(const StringRef Name); LLVM_READNONE bool isSupportedTgtId(unsigned Id, const MCSubtargetInfo &STI); } // namespace Exp namespace MTBUFFormat { LLVM_READNONE int64_t encodeDfmtNfmt(unsigned Dfmt, unsigned Nfmt); void decodeDfmtNfmt(unsigned Format, unsigned &Dfmt, unsigned &Nfmt); int64_t getDfmt(const StringRef Name); StringRef getDfmtName(unsigned Id); int64_t getNfmt(const StringRef Name, const MCSubtargetInfo &STI); StringRef getNfmtName(unsigned Id, const MCSubtargetInfo &STI); bool isValidDfmtNfmt(unsigned Val, const MCSubtargetInfo &STI); bool isValidNfmt(unsigned Val, const MCSubtargetInfo &STI); int64_t getUnifiedFormat(const StringRef Name); StringRef getUnifiedFormatName(unsigned Id); bool isValidUnifiedFormat(unsigned Val); int64_t convertDfmtNfmt2Ufmt(unsigned Dfmt, unsigned Nfmt); bool isValidFormatEncoding(unsigned Val, const MCSubtargetInfo &STI); unsigned getDefaultFormatEncoding(const MCSubtargetInfo &STI); } // namespace MTBUFFormat namespace SendMsg { LLVM_READONLY int64_t getMsgId(const StringRef Name); LLVM_READONLY int64_t getMsgOpId(int64_t MsgId, const StringRef Name); LLVM_READNONE StringRef getMsgName(int64_t MsgId); LLVM_READNONE StringRef getMsgOpName(int64_t MsgId, int64_t OpId); LLVM_READNONE bool isValidMsgId(int64_t MsgId, const MCSubtargetInfo &STI, bool Strict = true); LLVM_READNONE bool isValidMsgOp(int64_t MsgId, int64_t OpId, const MCSubtargetInfo &STI, bool Strict = true); LLVM_READNONE bool isValidMsgStream(int64_t MsgId, int64_t OpId, int64_t StreamId, const MCSubtargetInfo &STI, bool Strict = true); LLVM_READNONE bool msgRequiresOp(int64_t MsgId); LLVM_READNONE bool msgSupportsStream(int64_t MsgId, int64_t OpId); void decodeMsg(unsigned Val, uint16_t &MsgId, uint16_t &OpId, uint16_t &StreamId); LLVM_READNONE uint64_t encodeMsg(uint64_t MsgId, uint64_t OpId, uint64_t StreamId); } // namespace SendMsg unsigned getInitialPSInputAddr(const Function &F); bool getHasColorExport(const Function &F); bool getHasDepthExport(const Function &F); LLVM_READNONE bool isShader(CallingConv::ID CC); LLVM_READNONE bool isGraphics(CallingConv::ID CC); LLVM_READNONE bool isCompute(CallingConv::ID CC); LLVM_READNONE bool isEntryFunctionCC(CallingConv::ID CC); // These functions are considered entrypoints into the current module, i.e. they // are allowed to be called from outside the current module. This is different // from isEntryFunctionCC, which is only true for functions that are entered by // the hardware. Module entry points include all entry functions but also // include functions that can be called from other functions inside or outside // the current module. Module entry functions are allowed to allocate LDS. LLVM_READNONE bool isModuleEntryFunctionCC(CallingConv::ID CC); // FIXME: Remove this when calling conventions cleaned up LLVM_READNONE inline bool isKernel(CallingConv::ID CC) { switch (CC) { case CallingConv::AMDGPU_KERNEL: case CallingConv::SPIR_KERNEL: return true; default: return false; } } bool hasXNACK(const MCSubtargetInfo &STI); bool hasSRAMECC(const MCSubtargetInfo &STI); bool hasMIMG_R128(const MCSubtargetInfo &STI); bool hasGFX10A16(const MCSubtargetInfo &STI); bool hasG16(const MCSubtargetInfo &STI); bool hasPackedD16(const MCSubtargetInfo &STI); bool isSI(const MCSubtargetInfo &STI); bool isCI(const MCSubtargetInfo &STI); bool isVI(const MCSubtargetInfo &STI); bool isGFX9(const MCSubtargetInfo &STI); bool isGFX9Plus(const MCSubtargetInfo &STI); bool isGFX10(const MCSubtargetInfo &STI); bool isGFX10Plus(const MCSubtargetInfo &STI); bool isGCN3Encoding(const MCSubtargetInfo &STI); bool isGFX10_AEncoding(const MCSubtargetInfo &STI); bool isGFX10_BEncoding(const MCSubtargetInfo &STI); bool hasGFX10_3Insts(const MCSubtargetInfo &STI); bool isGFX90A(const MCSubtargetInfo &STI); bool hasArchitectedFlatScratch(const MCSubtargetInfo &STI); /// Is Reg - scalar register bool isSGPR(unsigned Reg, const MCRegisterInfo* TRI); /// Is there any intersection between registers bool isRegIntersect(unsigned Reg0, unsigned Reg1, const MCRegisterInfo* TRI); /// If \p Reg is a pseudo reg, return the correct hardware register given /// \p STI otherwise return \p Reg. unsigned getMCReg(unsigned Reg, const MCSubtargetInfo &STI); /// Convert hardware register \p Reg to a pseudo register LLVM_READNONE unsigned mc2PseudoReg(unsigned Reg); /// Can this operand also contain immediate values? bool isSISrcOperand(const MCInstrDesc &Desc, unsigned OpNo); /// Is this floating-point operand? bool isSISrcFPOperand(const MCInstrDesc &Desc, unsigned OpNo); /// Does this operand support only inlinable literals? bool isSISrcInlinableOperand(const MCInstrDesc &Desc, unsigned OpNo); /// Get the size in bits of a register from the register class \p RC. unsigned getRegBitWidth(unsigned RCID); /// Get the size in bits of a register from the register class \p RC. unsigned getRegBitWidth(const MCRegisterClass &RC); /// Get size of register operand unsigned getRegOperandSize(const MCRegisterInfo *MRI, const MCInstrDesc &Desc, unsigned OpNo); LLVM_READNONE inline unsigned getOperandSize(const MCOperandInfo &OpInfo) { switch (OpInfo.OperandType) { case AMDGPU::OPERAND_REG_IMM_INT32: case AMDGPU::OPERAND_REG_IMM_FP32: case AMDGPU::OPERAND_REG_IMM_FP32_DEFERRED: case AMDGPU::OPERAND_REG_INLINE_C_INT32: case AMDGPU::OPERAND_REG_INLINE_C_FP32: case AMDGPU::OPERAND_REG_INLINE_AC_INT32: case AMDGPU::OPERAND_REG_INLINE_AC_FP32: case AMDGPU::OPERAND_REG_IMM_V2INT32: case AMDGPU::OPERAND_REG_IMM_V2FP32: case AMDGPU::OPERAND_REG_INLINE_C_V2INT32: case AMDGPU::OPERAND_REG_INLINE_C_V2FP32: case AMDGPU::OPERAND_KIMM32: case AMDGPU::OPERAND_KIMM16: // mandatory literal is always size 4 return 4; case AMDGPU::OPERAND_REG_IMM_INT64: case AMDGPU::OPERAND_REG_IMM_FP64: case AMDGPU::OPERAND_REG_INLINE_C_INT64: case AMDGPU::OPERAND_REG_INLINE_C_FP64: case AMDGPU::OPERAND_REG_INLINE_AC_FP64: return 8; case AMDGPU::OPERAND_REG_IMM_INT16: case AMDGPU::OPERAND_REG_IMM_FP16: case AMDGPU::OPERAND_REG_IMM_FP16_DEFERRED: case AMDGPU::OPERAND_REG_INLINE_C_INT16: case AMDGPU::OPERAND_REG_INLINE_C_FP16: case AMDGPU::OPERAND_REG_INLINE_C_V2INT16: case AMDGPU::OPERAND_REG_INLINE_C_V2FP16: case AMDGPU::OPERAND_REG_INLINE_AC_INT16: case AMDGPU::OPERAND_REG_INLINE_AC_FP16: case AMDGPU::OPERAND_REG_INLINE_AC_V2INT16: case AMDGPU::OPERAND_REG_INLINE_AC_V2FP16: case AMDGPU::OPERAND_REG_IMM_V2INT16: case AMDGPU::OPERAND_REG_IMM_V2FP16: return 2; default: llvm_unreachable("unhandled operand type"); } } LLVM_READNONE inline unsigned getOperandSize(const MCInstrDesc &Desc, unsigned OpNo) { return getOperandSize(Desc.OpInfo[OpNo]); } /// Is this literal inlinable, and not one of the values intended for floating /// point values. LLVM_READNONE inline bool isInlinableIntLiteral(int64_t Literal) { return Literal >= -16 && Literal <= 64; } /// Is this literal inlinable LLVM_READNONE bool isInlinableLiteral64(int64_t Literal, bool HasInv2Pi); LLVM_READNONE bool isInlinableLiteral32(int32_t Literal, bool HasInv2Pi); LLVM_READNONE bool isInlinableLiteral16(int16_t Literal, bool HasInv2Pi); LLVM_READNONE bool isInlinableLiteralV216(int32_t Literal, bool HasInv2Pi); LLVM_READNONE bool isInlinableIntLiteralV216(int32_t Literal); LLVM_READNONE bool isFoldableLiteralV216(int32_t Literal, bool HasInv2Pi); bool isArgPassedInSGPR(const Argument *Arg); LLVM_READONLY bool isLegalSMRDEncodedUnsignedOffset(const MCSubtargetInfo &ST, int64_t EncodedOffset); LLVM_READONLY bool isLegalSMRDEncodedSignedOffset(const MCSubtargetInfo &ST, int64_t EncodedOffset, bool IsBuffer); /// Convert \p ByteOffset to dwords if the subtarget uses dword SMRD immediate /// offsets. uint64_t convertSMRDOffsetUnits(const MCSubtargetInfo &ST, uint64_t ByteOffset); /// \returns The encoding that will be used for \p ByteOffset in the /// SMRD offset field, or None if it won't fit. On GFX9 and GFX10 /// S_LOAD instructions have a signed offset, on other subtargets it is /// unsigned. S_BUFFER has an unsigned offset for all subtargets. Optional getSMRDEncodedOffset(const MCSubtargetInfo &ST, int64_t ByteOffset, bool IsBuffer); /// \return The encoding that can be used for a 32-bit literal offset in an SMRD /// instruction. This is only useful on CI.s Optional getSMRDEncodedLiteralOffset32(const MCSubtargetInfo &ST, int64_t ByteOffset); /// For FLAT segment the offset must be positive; /// MSB is ignored and forced to zero. /// /// \return The number of bits available for the offset field in flat /// instructions. unsigned getNumFlatOffsetBits(const MCSubtargetInfo &ST, bool Signed); /// \returns true if this offset is small enough to fit in the SMRD /// offset field. \p ByteOffset should be the offset in bytes and /// not the encoded offset. bool isLegalSMRDImmOffset(const MCSubtargetInfo &ST, int64_t ByteOffset); bool splitMUBUFOffset(uint32_t Imm, uint32_t &SOffset, uint32_t &ImmOffset, const GCNSubtarget *Subtarget, Align Alignment = Align(4)); LLVM_READNONE inline bool isLegal64BitDPPControl(unsigned DC) { return DC >= DPP::ROW_NEWBCAST_FIRST && DC <= DPP::ROW_NEWBCAST_LAST; } /// \returns true if the intrinsic is divergent bool isIntrinsicSourceOfDivergence(unsigned IntrID); // Track defaults for fields in the MODE registser. struct SIModeRegisterDefaults { /// Floating point opcodes that support exception flag gathering quiet and /// propagate signaling NaN inputs per IEEE 754-2008. Min_dx10 and max_dx10 /// become IEEE 754- 2008 compliant due to signaling NaN propagation and /// quieting. bool IEEE : 1; /// Used by the vector ALU to force DX10-style treatment of NaNs: when set, /// clamp NaN to zero; otherwise, pass NaN through. bool DX10Clamp : 1; /// If this is set, neither input or output denormals are flushed for most f32 /// instructions. bool FP32InputDenormals : 1; bool FP32OutputDenormals : 1; /// If this is set, neither input or output denormals are flushed for both f64 /// and f16/v2f16 instructions. bool FP64FP16InputDenormals : 1; bool FP64FP16OutputDenormals : 1; SIModeRegisterDefaults() : IEEE(true), DX10Clamp(true), FP32InputDenormals(true), FP32OutputDenormals(true), FP64FP16InputDenormals(true), FP64FP16OutputDenormals(true) {} SIModeRegisterDefaults(const Function &F); static SIModeRegisterDefaults getDefaultForCallingConv(CallingConv::ID CC) { SIModeRegisterDefaults Mode; Mode.IEEE = !AMDGPU::isShader(CC); return Mode; } bool operator ==(const SIModeRegisterDefaults Other) const { return IEEE == Other.IEEE && DX10Clamp == Other.DX10Clamp && FP32InputDenormals == Other.FP32InputDenormals && FP32OutputDenormals == Other.FP32OutputDenormals && FP64FP16InputDenormals == Other.FP64FP16InputDenormals && FP64FP16OutputDenormals == Other.FP64FP16OutputDenormals; } bool allFP32Denormals() const { return FP32InputDenormals && FP32OutputDenormals; } bool allFP64FP16Denormals() const { return FP64FP16InputDenormals && FP64FP16OutputDenormals; } /// Get the encoding value for the FP_DENORM bits of the mode register for the /// FP32 denormal mode. uint32_t fpDenormModeSPValue() const { if (FP32InputDenormals && FP32OutputDenormals) return FP_DENORM_FLUSH_NONE; if (FP32InputDenormals) return FP_DENORM_FLUSH_OUT; if (FP32OutputDenormals) return FP_DENORM_FLUSH_IN; return FP_DENORM_FLUSH_IN_FLUSH_OUT; } /// Get the encoding value for the FP_DENORM bits of the mode register for the /// FP64/FP16 denormal mode. uint32_t fpDenormModeDPValue() const { if (FP64FP16InputDenormals && FP64FP16OutputDenormals) return FP_DENORM_FLUSH_NONE; if (FP64FP16InputDenormals) return FP_DENORM_FLUSH_OUT; if (FP64FP16OutputDenormals) return FP_DENORM_FLUSH_IN; return FP_DENORM_FLUSH_IN_FLUSH_OUT; } /// Returns true if a flag is compatible if it's enabled in the callee, but /// disabled in the caller. static bool oneWayCompatible(bool CallerMode, bool CalleeMode) { return CallerMode == CalleeMode || (!CallerMode && CalleeMode); } // FIXME: Inlining should be OK for dx10-clamp, since the caller's mode should // be able to override. bool isInlineCompatible(SIModeRegisterDefaults CalleeMode) const { if (DX10Clamp != CalleeMode.DX10Clamp) return false; if (IEEE != CalleeMode.IEEE) return false; // Allow inlining denormals enabled into denormals flushed functions. return oneWayCompatible(FP64FP16InputDenormals, CalleeMode.FP64FP16InputDenormals) && oneWayCompatible(FP64FP16OutputDenormals, CalleeMode.FP64FP16OutputDenormals) && oneWayCompatible(FP32InputDenormals, CalleeMode.FP32InputDenormals) && oneWayCompatible(FP32OutputDenormals, CalleeMode.FP32OutputDenormals); } }; } // end namespace AMDGPU raw_ostream &operator<<(raw_ostream &OS, const AMDGPU::IsaInfo::TargetIDSetting S); } // end namespace llvm #endif // LLVM_LIB_TARGET_AMDGPU_UTILS_AMDGPUBASEINFO_H