//===- AMDGPULegalizerInfo.cpp -----------------------------------*- 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 // //===----------------------------------------------------------------------===// /// \file /// This file implements the targeting of the Machinelegalizer class for /// AMDGPU. /// \todo This should be generated by TableGen. //===----------------------------------------------------------------------===// #include "AMDGPULegalizerInfo.h" #include "AMDGPU.h" #include "AMDGPUGlobalISelUtils.h" #include "AMDGPUInstrInfo.h" #include "AMDGPUTargetMachine.h" #include "SIMachineFunctionInfo.h" #include "Utils/AMDGPUBaseInfo.h" #include "llvm/ADT/ScopeExit.h" #include "llvm/BinaryFormat/ELF.h" #include "llvm/CodeGen/GlobalISel/LegalizerHelper.h" #include "llvm/CodeGen/GlobalISel/MIPatternMatch.h" #include "llvm/CodeGen/GlobalISel/MachineIRBuilder.h" #include "llvm/IR/DiagnosticInfo.h" #include "llvm/IR/IntrinsicsAMDGPU.h" #include "llvm/IR/IntrinsicsR600.h" #define DEBUG_TYPE "amdgpu-legalinfo" using namespace llvm; using namespace LegalizeActions; using namespace LegalizeMutations; using namespace LegalityPredicates; using namespace MIPatternMatch; // Hack until load/store selection patterns support any tuple of legal types. static cl::opt EnableNewLegality( "amdgpu-global-isel-new-legality", cl::desc("Use GlobalISel desired legality, rather than try to use" "rules compatible with selection patterns"), cl::init(false), cl::ReallyHidden); static constexpr unsigned MaxRegisterSize = 1024; // Round the number of elements to the next power of two elements static LLT getPow2VectorType(LLT Ty) { unsigned NElts = Ty.getNumElements(); unsigned Pow2NElts = 1 << Log2_32_Ceil(NElts); return Ty.changeElementCount(ElementCount::getFixed(Pow2NElts)); } // Round the number of bits to the next power of two bits static LLT getPow2ScalarType(LLT Ty) { unsigned Bits = Ty.getSizeInBits(); unsigned Pow2Bits = 1 << Log2_32_Ceil(Bits); return LLT::scalar(Pow2Bits); } /// \returns true if this is an odd sized vector which should widen by adding an /// additional element. This is mostly to handle <3 x s16> -> <4 x s16>. This /// excludes s1 vectors, which should always be scalarized. static LegalityPredicate isSmallOddVector(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[TypeIdx]; if (!Ty.isVector()) return false; const LLT EltTy = Ty.getElementType(); const unsigned EltSize = EltTy.getSizeInBits(); return Ty.getNumElements() % 2 != 0 && EltSize > 1 && EltSize < 32 && Ty.getSizeInBits() % 32 != 0; }; } static LegalityPredicate sizeIsMultipleOf32(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[TypeIdx]; return Ty.getSizeInBits() % 32 == 0; }; } static LegalityPredicate isWideVec16(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[TypeIdx]; const LLT EltTy = Ty.getScalarType(); return EltTy.getSizeInBits() == 16 && Ty.getNumElements() > 2; }; } static LegalizeMutation oneMoreElement(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[TypeIdx]; const LLT EltTy = Ty.getElementType(); return std::make_pair(TypeIdx, LLT::fixed_vector(Ty.getNumElements() + 1, EltTy)); }; } static LegalizeMutation fewerEltsToSize64Vector(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[TypeIdx]; const LLT EltTy = Ty.getElementType(); unsigned Size = Ty.getSizeInBits(); unsigned Pieces = (Size + 63) / 64; unsigned NewNumElts = (Ty.getNumElements() + 1) / Pieces; return std::make_pair( TypeIdx, LLT::scalarOrVector(ElementCount::getFixed(NewNumElts), EltTy)); }; } // Increase the number of vector elements to reach the next multiple of 32-bit // type. static LegalizeMutation moreEltsToNext32Bit(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[TypeIdx]; const LLT EltTy = Ty.getElementType(); const int Size = Ty.getSizeInBits(); const int EltSize = EltTy.getSizeInBits(); const int NextMul32 = (Size + 31) / 32; assert(EltSize < 32); const int NewNumElts = (32 * NextMul32 + EltSize - 1) / EltSize; return std::make_pair(TypeIdx, LLT::fixed_vector(NewNumElts, EltTy)); }; } static LLT getBitcastRegisterType(const LLT Ty) { const unsigned Size = Ty.getSizeInBits(); if (Size <= 32) { // <2 x s8> -> s16 // <4 x s8> -> s32 return LLT::scalar(Size); } return LLT::scalarOrVector(ElementCount::getFixed(Size / 32), 32); } static LegalizeMutation bitcastToRegisterType(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[TypeIdx]; return std::make_pair(TypeIdx, getBitcastRegisterType(Ty)); }; } static LegalizeMutation bitcastToVectorElement32(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[TypeIdx]; unsigned Size = Ty.getSizeInBits(); assert(Size % 32 == 0); return std::make_pair( TypeIdx, LLT::scalarOrVector(ElementCount::getFixed(Size / 32), 32)); }; } static LegalityPredicate vectorSmallerThan(unsigned TypeIdx, unsigned Size) { return [=](const LegalityQuery &Query) { const LLT QueryTy = Query.Types[TypeIdx]; return QueryTy.isVector() && QueryTy.getSizeInBits() < Size; }; } static LegalityPredicate vectorWiderThan(unsigned TypeIdx, unsigned Size) { return [=](const LegalityQuery &Query) { const LLT QueryTy = Query.Types[TypeIdx]; return QueryTy.isVector() && QueryTy.getSizeInBits() > Size; }; } static LegalityPredicate numElementsNotEven(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT QueryTy = Query.Types[TypeIdx]; return QueryTy.isVector() && QueryTy.getNumElements() % 2 != 0; }; } static bool isRegisterSize(unsigned Size) { return Size % 32 == 0 && Size <= MaxRegisterSize; } static bool isRegisterVectorElementType(LLT EltTy) { const int EltSize = EltTy.getSizeInBits(); return EltSize == 16 || EltSize % 32 == 0; } static bool isRegisterVectorType(LLT Ty) { const int EltSize = Ty.getElementType().getSizeInBits(); return EltSize == 32 || EltSize == 64 || (EltSize == 16 && Ty.getNumElements() % 2 == 0) || EltSize == 128 || EltSize == 256; } static bool isRegisterType(LLT Ty) { if (!isRegisterSize(Ty.getSizeInBits())) return false; if (Ty.isVector()) return isRegisterVectorType(Ty); return true; } // Any combination of 32 or 64-bit elements up the maximum register size, and // multiples of v2s16. static LegalityPredicate isRegisterType(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { return isRegisterType(Query.Types[TypeIdx]); }; } static LegalityPredicate elementTypeIsLegal(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT QueryTy = Query.Types[TypeIdx]; if (!QueryTy.isVector()) return false; const LLT EltTy = QueryTy.getElementType(); return EltTy == LLT::scalar(16) || EltTy.getSizeInBits() >= 32; }; } // If we have a truncating store or an extending load with a data size larger // than 32-bits, we need to reduce to a 32-bit type. static LegalityPredicate isWideScalarExtLoadTruncStore(unsigned TypeIdx) { return [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[TypeIdx]; return !Ty.isVector() && Ty.getSizeInBits() > 32 && Query.MMODescrs[0].MemoryTy.getSizeInBits() < Ty.getSizeInBits(); }; } // TODO: Should load to s16 be legal? Most loads extend to 32-bits, but we // handle some operations by just promoting the register during // selection. There are also d16 loads on GFX9+ which preserve the high bits. static unsigned maxSizeForAddrSpace(const GCNSubtarget &ST, unsigned AS, bool IsLoad) { switch (AS) { case AMDGPUAS::PRIVATE_ADDRESS: // FIXME: Private element size. return ST.enableFlatScratch() ? 128 : 32; case AMDGPUAS::LOCAL_ADDRESS: return ST.useDS128() ? 128 : 64; case AMDGPUAS::GLOBAL_ADDRESS: case AMDGPUAS::CONSTANT_ADDRESS: case AMDGPUAS::CONSTANT_ADDRESS_32BIT: // Treat constant and global as identical. SMRD loads are sometimes usable for // global loads (ideally constant address space should be eliminated) // depending on the context. Legality cannot be context dependent, but // RegBankSelect can split the load as necessary depending on the pointer // register bank/uniformity and if the memory is invariant or not written in a // kernel. return IsLoad ? 512 : 128; default: // Flat addresses may contextually need to be split to 32-bit parts if they // may alias scratch depending on the subtarget. return 128; } } static bool isLoadStoreSizeLegal(const GCNSubtarget &ST, const LegalityQuery &Query) { const LLT Ty = Query.Types[0]; // Handle G_LOAD, G_ZEXTLOAD, G_SEXTLOAD const bool IsLoad = Query.Opcode != AMDGPU::G_STORE; unsigned RegSize = Ty.getSizeInBits(); uint64_t MemSize = Query.MMODescrs[0].MemoryTy.getSizeInBits(); uint64_t AlignBits = Query.MMODescrs[0].AlignInBits; unsigned AS = Query.Types[1].getAddressSpace(); // All of these need to be custom lowered to cast the pointer operand. if (AS == AMDGPUAS::CONSTANT_ADDRESS_32BIT) return false; // Do not handle extending vector loads. if (Ty.isVector() && MemSize != RegSize) return false; // TODO: We should be able to widen loads if the alignment is high enough, but // we also need to modify the memory access size. #if 0 // Accept widening loads based on alignment. if (IsLoad && MemSize < Size) MemSize = std::max(MemSize, Align); #endif // Only 1-byte and 2-byte to 32-bit extloads are valid. if (MemSize != RegSize && RegSize != 32) return false; if (MemSize > maxSizeForAddrSpace(ST, AS, IsLoad)) return false; switch (MemSize) { case 8: case 16: case 32: case 64: case 128: break; case 96: if (!ST.hasDwordx3LoadStores()) return false; break; case 256: case 512: // These may contextually need to be broken down. break; default: return false; } assert(RegSize >= MemSize); if (AlignBits < MemSize) { const SITargetLowering *TLI = ST.getTargetLowering(); if (!TLI->allowsMisalignedMemoryAccessesImpl(MemSize, AS, Align(AlignBits / 8))) return false; } return true; } // The current selector can't handle <6 x s16>, <8 x s16>, s96, s128 etc, so // workaround this. Eventually it should ignore the type for loads and only care // about the size. Return true in cases where we will workaround this for now by // bitcasting. static bool loadStoreBitcastWorkaround(const LLT Ty) { if (EnableNewLegality) return false; const unsigned Size = Ty.getSizeInBits(); if (Size <= 64) return false; if (!Ty.isVector()) return true; LLT EltTy = Ty.getElementType(); if (EltTy.isPointer()) return true; unsigned EltSize = EltTy.getSizeInBits(); return EltSize != 32 && EltSize != 64; } static bool isLoadStoreLegal(const GCNSubtarget &ST, const LegalityQuery &Query) { const LLT Ty = Query.Types[0]; return isRegisterType(Ty) && isLoadStoreSizeLegal(ST, Query) && !loadStoreBitcastWorkaround(Ty); } /// Return true if a load or store of the type should be lowered with a bitcast /// to a different type. static bool shouldBitcastLoadStoreType(const GCNSubtarget &ST, const LLT Ty, const LLT MemTy) { const unsigned MemSizeInBits = MemTy.getSizeInBits(); const unsigned Size = Ty.getSizeInBits(); if (Size != MemSizeInBits) return Size <= 32 && Ty.isVector(); if (loadStoreBitcastWorkaround(Ty) && isRegisterType(Ty)) return true; // Don't try to handle bitcasting vector ext loads for now. return Ty.isVector() && (!MemTy.isVector() || MemTy == Ty) && (Size <= 32 || isRegisterSize(Size)) && !isRegisterVectorElementType(Ty.getElementType()); } /// Return true if we should legalize a load by widening an odd sized memory /// access up to the alignment. Note this case when the memory access itself /// changes, not the size of the result register. static bool shouldWidenLoad(const GCNSubtarget &ST, LLT MemoryTy, uint64_t AlignInBits, unsigned AddrSpace, unsigned Opcode) { unsigned SizeInBits = MemoryTy.getSizeInBits(); // We don't want to widen cases that are naturally legal. if (isPowerOf2_32(SizeInBits)) return false; // If we have 96-bit memory operations, we shouldn't touch them. Note we may // end up widening these for a scalar load during RegBankSelect, since there // aren't 96-bit scalar loads. if (SizeInBits == 96 && ST.hasDwordx3LoadStores()) return false; if (SizeInBits >= maxSizeForAddrSpace(ST, AddrSpace, Opcode)) return false; // A load is known dereferenceable up to the alignment, so it's legal to widen // to it. // // TODO: Could check dereferenceable for less aligned cases. unsigned RoundedSize = NextPowerOf2(SizeInBits); if (AlignInBits < RoundedSize) return false; // Do not widen if it would introduce a slow unaligned load. const SITargetLowering *TLI = ST.getTargetLowering(); bool Fast = false; return TLI->allowsMisalignedMemoryAccessesImpl( RoundedSize, AddrSpace, Align(AlignInBits / 8), MachineMemOperand::MOLoad, &Fast) && Fast; } static bool shouldWidenLoad(const GCNSubtarget &ST, const LegalityQuery &Query, unsigned Opcode) { if (Query.MMODescrs[0].Ordering != AtomicOrdering::NotAtomic) return false; return shouldWidenLoad(ST, Query.MMODescrs[0].MemoryTy, Query.MMODescrs[0].AlignInBits, Query.Types[1].getAddressSpace(), Opcode); } AMDGPULegalizerInfo::AMDGPULegalizerInfo(const GCNSubtarget &ST_, const GCNTargetMachine &TM) : ST(ST_) { using namespace TargetOpcode; auto GetAddrSpacePtr = [&TM](unsigned AS) { return LLT::pointer(AS, TM.getPointerSizeInBits(AS)); }; const LLT S1 = LLT::scalar(1); const LLT S8 = LLT::scalar(8); const LLT S16 = LLT::scalar(16); const LLT S32 = LLT::scalar(32); const LLT S64 = LLT::scalar(64); const LLT S128 = LLT::scalar(128); const LLT S256 = LLT::scalar(256); const LLT S512 = LLT::scalar(512); const LLT MaxScalar = LLT::scalar(MaxRegisterSize); const LLT V2S8 = LLT::fixed_vector(2, 8); const LLT V2S16 = LLT::fixed_vector(2, 16); const LLT V4S16 = LLT::fixed_vector(4, 16); const LLT V2S32 = LLT::fixed_vector(2, 32); const LLT V3S32 = LLT::fixed_vector(3, 32); const LLT V4S32 = LLT::fixed_vector(4, 32); const LLT V5S32 = LLT::fixed_vector(5, 32); const LLT V6S32 = LLT::fixed_vector(6, 32); const LLT V7S32 = LLT::fixed_vector(7, 32); const LLT V8S32 = LLT::fixed_vector(8, 32); const LLT V9S32 = LLT::fixed_vector(9, 32); const LLT V10S32 = LLT::fixed_vector(10, 32); const LLT V11S32 = LLT::fixed_vector(11, 32); const LLT V12S32 = LLT::fixed_vector(12, 32); const LLT V13S32 = LLT::fixed_vector(13, 32); const LLT V14S32 = LLT::fixed_vector(14, 32); const LLT V15S32 = LLT::fixed_vector(15, 32); const LLT V16S32 = LLT::fixed_vector(16, 32); const LLT V32S32 = LLT::fixed_vector(32, 32); const LLT V2S64 = LLT::fixed_vector(2, 64); const LLT V3S64 = LLT::fixed_vector(3, 64); const LLT V4S64 = LLT::fixed_vector(4, 64); const LLT V5S64 = LLT::fixed_vector(5, 64); const LLT V6S64 = LLT::fixed_vector(6, 64); const LLT V7S64 = LLT::fixed_vector(7, 64); const LLT V8S64 = LLT::fixed_vector(8, 64); const LLT V16S64 = LLT::fixed_vector(16, 64); std::initializer_list AllS32Vectors = {V2S32, V3S32, V4S32, V5S32, V6S32, V7S32, V8S32, V9S32, V10S32, V11S32, V12S32, V13S32, V14S32, V15S32, V16S32, V32S32}; std::initializer_list AllS64Vectors = {V2S64, V3S64, V4S64, V5S64, V6S64, V7S64, V8S64, V16S64}; const LLT GlobalPtr = GetAddrSpacePtr(AMDGPUAS::GLOBAL_ADDRESS); const LLT ConstantPtr = GetAddrSpacePtr(AMDGPUAS::CONSTANT_ADDRESS); const LLT Constant32Ptr = GetAddrSpacePtr(AMDGPUAS::CONSTANT_ADDRESS_32BIT); const LLT LocalPtr = GetAddrSpacePtr(AMDGPUAS::LOCAL_ADDRESS); const LLT RegionPtr = GetAddrSpacePtr(AMDGPUAS::REGION_ADDRESS); const LLT FlatPtr = GetAddrSpacePtr(AMDGPUAS::FLAT_ADDRESS); const LLT PrivatePtr = GetAddrSpacePtr(AMDGPUAS::PRIVATE_ADDRESS); const LLT CodePtr = FlatPtr; const std::initializer_list AddrSpaces64 = { GlobalPtr, ConstantPtr, FlatPtr }; const std::initializer_list AddrSpaces32 = { LocalPtr, PrivatePtr, Constant32Ptr, RegionPtr }; const std::initializer_list FPTypesBase = { S32, S64 }; const std::initializer_list FPTypes16 = { S32, S64, S16 }; const std::initializer_list FPTypesPK16 = { S32, S64, S16, V2S16 }; const LLT MinScalarFPTy = ST.has16BitInsts() ? S16 : S32; // s1 for VCC branches, s32 for SCC branches. getActionDefinitionsBuilder(G_BRCOND).legalFor({S1, S32}); // TODO: All multiples of 32, vectors of pointers, all v2s16 pairs, more // elements for v3s16 getActionDefinitionsBuilder(G_PHI) .legalFor({S32, S64, V2S16, S16, V4S16, S1, S128, S256}) .legalFor(AllS32Vectors) .legalFor(AllS64Vectors) .legalFor(AddrSpaces64) .legalFor(AddrSpaces32) .legalIf(isPointer(0)) .clampScalar(0, S16, S256) .widenScalarToNextPow2(0, 32) .clampMaxNumElements(0, S32, 16) .moreElementsIf(isSmallOddVector(0), oneMoreElement(0)) .scalarize(0); if (ST.hasVOP3PInsts() && ST.hasAddNoCarry() && ST.hasIntClamp()) { // Full set of gfx9 features. getActionDefinitionsBuilder({G_ADD, G_SUB}) .legalFor({S32, S16, V2S16}) .clampMaxNumElementsStrict(0, S16, 2) .scalarize(0) .minScalar(0, S16) .widenScalarToNextMultipleOf(0, 32) .maxScalar(0, S32); getActionDefinitionsBuilder(G_MUL) .legalFor({S32, S16, V2S16}) .clampMaxNumElementsStrict(0, S16, 2) .scalarize(0) .minScalar(0, S16) .widenScalarToNextMultipleOf(0, 32) .custom(); assert(ST.hasMad64_32()); getActionDefinitionsBuilder({G_UADDSAT, G_USUBSAT, G_SADDSAT, G_SSUBSAT}) .legalFor({S32, S16, V2S16}) // Clamp modifier .minScalarOrElt(0, S16) .clampMaxNumElementsStrict(0, S16, 2) .scalarize(0) .widenScalarToNextPow2(0, 32) .lower(); } else if (ST.has16BitInsts()) { getActionDefinitionsBuilder({G_ADD, G_SUB}) .legalFor({S32, S16}) .minScalar(0, S16) .widenScalarToNextMultipleOf(0, 32) .maxScalar(0, S32) .scalarize(0); getActionDefinitionsBuilder(G_MUL) .legalFor({S32, S16}) .scalarize(0) .minScalar(0, S16) .widenScalarToNextMultipleOf(0, 32) .custom(); assert(ST.hasMad64_32()); // Technically the saturating operations require clamp bit support, but this // was introduced at the same time as 16-bit operations. getActionDefinitionsBuilder({G_UADDSAT, G_USUBSAT}) .legalFor({S32, S16}) // Clamp modifier .minScalar(0, S16) .scalarize(0) .widenScalarToNextPow2(0, 16) .lower(); // We're just lowering this, but it helps get a better result to try to // coerce to the desired type first. getActionDefinitionsBuilder({G_SADDSAT, G_SSUBSAT}) .minScalar(0, S16) .scalarize(0) .lower(); } else { getActionDefinitionsBuilder({G_ADD, G_SUB}) .legalFor({S32}) .widenScalarToNextMultipleOf(0, 32) .clampScalar(0, S32, S32) .scalarize(0); auto &Mul = getActionDefinitionsBuilder(G_MUL) .legalFor({S32}) .scalarize(0) .minScalar(0, S32) .widenScalarToNextMultipleOf(0, 32); if (ST.hasMad64_32()) Mul.custom(); else Mul.maxScalar(0, S32); if (ST.hasIntClamp()) { getActionDefinitionsBuilder({G_UADDSAT, G_USUBSAT}) .legalFor({S32}) // Clamp modifier. .scalarize(0) .minScalarOrElt(0, S32) .lower(); } else { // Clamp bit support was added in VI, along with 16-bit operations. getActionDefinitionsBuilder({G_UADDSAT, G_USUBSAT}) .minScalar(0, S32) .scalarize(0) .lower(); } // FIXME: DAG expansion gets better results. The widening uses the smaller // range values and goes for the min/max lowering directly. getActionDefinitionsBuilder({G_SADDSAT, G_SSUBSAT}) .minScalar(0, S32) .scalarize(0) .lower(); } getActionDefinitionsBuilder( {G_SDIV, G_UDIV, G_SREM, G_UREM, G_SDIVREM, G_UDIVREM}) .customFor({S32, S64}) .clampScalar(0, S32, S64) .widenScalarToNextPow2(0, 32) .scalarize(0); auto &Mulh = getActionDefinitionsBuilder({G_UMULH, G_SMULH}) .legalFor({S32}) .maxScalar(0, S32); if (ST.hasVOP3PInsts()) { Mulh .clampMaxNumElements(0, S8, 2) .lowerFor({V2S8}); } Mulh .scalarize(0) .lower(); // Report legal for any types we can handle anywhere. For the cases only legal // on the SALU, RegBankSelect will be able to re-legalize. getActionDefinitionsBuilder({G_AND, G_OR, G_XOR}) .legalFor({S32, S1, S64, V2S32, S16, V2S16, V4S16}) .clampScalar(0, S32, S64) .moreElementsIf(isSmallOddVector(0), oneMoreElement(0)) .fewerElementsIf(vectorWiderThan(0, 64), fewerEltsToSize64Vector(0)) .widenScalarToNextPow2(0) .scalarize(0); getActionDefinitionsBuilder({G_UADDO, G_USUBO, G_UADDE, G_SADDE, G_USUBE, G_SSUBE}) .legalFor({{S32, S1}, {S32, S32}}) .minScalar(0, S32) .scalarize(0) .lower(); getActionDefinitionsBuilder(G_BITCAST) // Don't worry about the size constraint. .legalIf(all(isRegisterType(0), isRegisterType(1))) .lower(); getActionDefinitionsBuilder(G_CONSTANT) .legalFor({S1, S32, S64, S16, GlobalPtr, LocalPtr, ConstantPtr, PrivatePtr, FlatPtr }) .legalIf(isPointer(0)) .clampScalar(0, S32, S64) .widenScalarToNextPow2(0); getActionDefinitionsBuilder(G_FCONSTANT) .legalFor({S32, S64, S16}) .clampScalar(0, S16, S64); getActionDefinitionsBuilder({G_IMPLICIT_DEF, G_FREEZE}) .legalIf(isRegisterType(0)) // s1 and s16 are special cases because they have legal operations on // them, but don't really occupy registers in the normal way. .legalFor({S1, S16}) .moreElementsIf(isSmallOddVector(0), oneMoreElement(0)) .clampScalarOrElt(0, S32, MaxScalar) .widenScalarToNextPow2(0, 32) .clampMaxNumElements(0, S32, 16); getActionDefinitionsBuilder(G_FRAME_INDEX).legalFor({PrivatePtr}); // If the amount is divergent, we have to do a wave reduction to get the // maximum value, so this is expanded during RegBankSelect. getActionDefinitionsBuilder(G_DYN_STACKALLOC) .legalFor({{PrivatePtr, S32}}); getActionDefinitionsBuilder(G_GLOBAL_VALUE) .customIf(typeIsNot(0, PrivatePtr)); getActionDefinitionsBuilder(G_BLOCK_ADDR).legalFor({CodePtr}); auto &FPOpActions = getActionDefinitionsBuilder( { G_FADD, G_FMUL, G_FMA, G_FCANONICALIZE}) .legalFor({S32, S64}); auto &TrigActions = getActionDefinitionsBuilder({G_FSIN, G_FCOS}) .customFor({S32, S64}); auto &FDIVActions = getActionDefinitionsBuilder(G_FDIV) .customFor({S32, S64}); if (ST.has16BitInsts()) { if (ST.hasVOP3PInsts()) FPOpActions.legalFor({S16, V2S16}); else FPOpActions.legalFor({S16}); TrigActions.customFor({S16}); FDIVActions.customFor({S16}); } auto &MinNumMaxNum = getActionDefinitionsBuilder({ G_FMINNUM, G_FMAXNUM, G_FMINNUM_IEEE, G_FMAXNUM_IEEE}); if (ST.hasVOP3PInsts()) { MinNumMaxNum.customFor(FPTypesPK16) .moreElementsIf(isSmallOddVector(0), oneMoreElement(0)) .clampMaxNumElements(0, S16, 2) .clampScalar(0, S16, S64) .scalarize(0); } else if (ST.has16BitInsts()) { MinNumMaxNum.customFor(FPTypes16) .clampScalar(0, S16, S64) .scalarize(0); } else { MinNumMaxNum.customFor(FPTypesBase) .clampScalar(0, S32, S64) .scalarize(0); } if (ST.hasVOP3PInsts()) FPOpActions.clampMaxNumElementsStrict(0, S16, 2); FPOpActions .scalarize(0) .clampScalar(0, ST.has16BitInsts() ? S16 : S32, S64); TrigActions .scalarize(0) .clampScalar(0, ST.has16BitInsts() ? S16 : S32, S64); FDIVActions .scalarize(0) .clampScalar(0, ST.has16BitInsts() ? S16 : S32, S64); getActionDefinitionsBuilder({G_FNEG, G_FABS}) .legalFor(FPTypesPK16) .clampMaxNumElementsStrict(0, S16, 2) .scalarize(0) .clampScalar(0, S16, S64); if (ST.has16BitInsts()) { getActionDefinitionsBuilder({G_FSQRT, G_FFLOOR}) .legalFor({S32, S64, S16}) .scalarize(0) .clampScalar(0, S16, S64); } else { getActionDefinitionsBuilder(G_FSQRT) .legalFor({S32, S64}) .scalarize(0) .clampScalar(0, S32, S64); if (ST.hasFractBug()) { getActionDefinitionsBuilder(G_FFLOOR) .customFor({S64}) .legalFor({S32, S64}) .scalarize(0) .clampScalar(0, S32, S64); } else { getActionDefinitionsBuilder(G_FFLOOR) .legalFor({S32, S64}) .scalarize(0) .clampScalar(0, S32, S64); } } getActionDefinitionsBuilder(G_FPTRUNC) .legalFor({{S32, S64}, {S16, S32}}) .scalarize(0) .lower(); getActionDefinitionsBuilder(G_FPEXT) .legalFor({{S64, S32}, {S32, S16}}) .narrowScalarFor({{S64, S16}}, changeTo(0, S32)) .scalarize(0); auto &FSubActions = getActionDefinitionsBuilder(G_FSUB); if (ST.has16BitInsts()) { FSubActions // Use actual fsub instruction .legalFor({S32, S16}) // Must use fadd + fneg .lowerFor({S64, V2S16}); } else { FSubActions // Use actual fsub instruction .legalFor({S32}) // Must use fadd + fneg .lowerFor({S64, S16, V2S16}); } FSubActions .scalarize(0) .clampScalar(0, S32, S64); // Whether this is legal depends on the floating point mode for the function. auto &FMad = getActionDefinitionsBuilder(G_FMAD); if (ST.hasMadF16() && ST.hasMadMacF32Insts()) FMad.customFor({S32, S16}); else if (ST.hasMadMacF32Insts()) FMad.customFor({S32}); else if (ST.hasMadF16()) FMad.customFor({S16}); FMad.scalarize(0) .lower(); auto &FRem = getActionDefinitionsBuilder(G_FREM); if (ST.has16BitInsts()) { FRem.customFor({S16, S32, S64}); } else { FRem.minScalar(0, S32) .customFor({S32, S64}); } FRem.scalarize(0); // TODO: Do we need to clamp maximum bitwidth? getActionDefinitionsBuilder(G_TRUNC) .legalIf(isScalar(0)) .legalFor({{V2S16, V2S32}}) .clampMaxNumElements(0, S16, 2) // Avoid scalarizing in cases that should be truly illegal. In unresolvable // situations (like an invalid implicit use), we don't want to infinite loop // in the legalizer. .fewerElementsIf(elementTypeIsLegal(0), LegalizeMutations::scalarize(0)) .alwaysLegal(); getActionDefinitionsBuilder({G_SEXT, G_ZEXT, G_ANYEXT}) .legalFor({{S64, S32}, {S32, S16}, {S64, S16}, {S32, S1}, {S64, S1}, {S16, S1}}) .scalarize(0) .clampScalar(0, S32, S64) .widenScalarToNextPow2(1, 32); // TODO: Split s1->s64 during regbankselect for VALU. auto &IToFP = getActionDefinitionsBuilder({G_SITOFP, G_UITOFP}) .legalFor({{S32, S32}, {S64, S32}, {S16, S32}}) .lowerIf(typeIs(1, S1)) .customFor({{S32, S64}, {S64, S64}}); if (ST.has16BitInsts()) IToFP.legalFor({{S16, S16}}); IToFP.clampScalar(1, S32, S64) .minScalar(0, S32) .scalarize(0) .widenScalarToNextPow2(1); auto &FPToI = getActionDefinitionsBuilder({G_FPTOSI, G_FPTOUI}) .legalFor({{S32, S32}, {S32, S64}, {S32, S16}}) .customFor({{S64, S32}, {S64, S64}}) .narrowScalarFor({{S64, S16}}, changeTo(0, S32)); if (ST.has16BitInsts()) FPToI.legalFor({{S16, S16}}); else FPToI.minScalar(1, S32); FPToI.minScalar(0, S32) .widenScalarToNextPow2(0, 32) .scalarize(0) .lower(); getActionDefinitionsBuilder(G_INTRINSIC_FPTRUNC_ROUND) .customFor({S16, S32}) .scalarize(0) .lower(); // Lower roundeven into G_FRINT getActionDefinitionsBuilder({G_INTRINSIC_ROUND, G_INTRINSIC_ROUNDEVEN}) .scalarize(0) .lower(); if (ST.has16BitInsts()) { getActionDefinitionsBuilder({G_INTRINSIC_TRUNC, G_FCEIL, G_FRINT}) .legalFor({S16, S32, S64}) .clampScalar(0, S16, S64) .scalarize(0); } else if (ST.getGeneration() >= AMDGPUSubtarget::SEA_ISLANDS) { getActionDefinitionsBuilder({G_INTRINSIC_TRUNC, G_FCEIL, G_FRINT}) .legalFor({S32, S64}) .clampScalar(0, S32, S64) .scalarize(0); } else { getActionDefinitionsBuilder({G_INTRINSIC_TRUNC, G_FCEIL, G_FRINT}) .legalFor({S32}) .customFor({S64}) .clampScalar(0, S32, S64) .scalarize(0); } getActionDefinitionsBuilder(G_PTR_ADD) .legalIf(all(isPointer(0), sameSize(0, 1))) .scalarize(0) .scalarSameSizeAs(1, 0); getActionDefinitionsBuilder(G_PTRMASK) .legalIf(all(sameSize(0, 1), typeInSet(1, {S64, S32}))) .scalarSameSizeAs(1, 0) .scalarize(0); auto &CmpBuilder = getActionDefinitionsBuilder(G_ICMP) // The compare output type differs based on the register bank of the output, // so make both s1 and s32 legal. // // Scalar compares producing output in scc will be promoted to s32, as that // is the allocatable register type that will be needed for the copy from // scc. This will be promoted during RegBankSelect, and we assume something // before that won't try to use s32 result types. // // Vector compares producing an output in vcc/SGPR will use s1 in VCC reg // bank. .legalForCartesianProduct( {S1}, {S32, S64, GlobalPtr, LocalPtr, ConstantPtr, PrivatePtr, FlatPtr}) .legalForCartesianProduct( {S32}, {S32, S64, GlobalPtr, LocalPtr, ConstantPtr, PrivatePtr, FlatPtr}); if (ST.has16BitInsts()) { CmpBuilder.legalFor({{S1, S16}}); } CmpBuilder .widenScalarToNextPow2(1) .clampScalar(1, S32, S64) .scalarize(0) .legalIf(all(typeInSet(0, {S1, S32}), isPointer(1))); getActionDefinitionsBuilder(G_FCMP) .legalForCartesianProduct({S1}, ST.has16BitInsts() ? FPTypes16 : FPTypesBase) .widenScalarToNextPow2(1) .clampScalar(1, S32, S64) .scalarize(0); // FIXME: fpow has a selection pattern that should move to custom lowering. auto &Exp2Ops = getActionDefinitionsBuilder({G_FEXP2, G_FLOG2}); if (ST.has16BitInsts()) Exp2Ops.legalFor({S32, S16}); else Exp2Ops.legalFor({S32}); Exp2Ops.clampScalar(0, MinScalarFPTy, S32); Exp2Ops.scalarize(0); auto &ExpOps = getActionDefinitionsBuilder({G_FEXP, G_FLOG, G_FLOG10, G_FPOW}); if (ST.has16BitInsts()) ExpOps.customFor({{S32}, {S16}}); else ExpOps.customFor({S32}); ExpOps.clampScalar(0, MinScalarFPTy, S32) .scalarize(0); getActionDefinitionsBuilder(G_FPOWI) .clampScalar(0, MinScalarFPTy, S32) .lower(); // The 64-bit versions produce 32-bit results, but only on the SALU. getActionDefinitionsBuilder(G_CTPOP) .legalFor({{S32, S32}, {S32, S64}}) .clampScalar(0, S32, S32) .widenScalarToNextPow2(1, 32) .clampScalar(1, S32, S64) .scalarize(0) .widenScalarToNextPow2(0, 32); // The hardware instructions return a different result on 0 than the generic // instructions expect. The hardware produces -1, but these produce the // bitwidth. getActionDefinitionsBuilder({G_CTLZ, G_CTTZ}) .scalarize(0) .clampScalar(0, S32, S32) .clampScalar(1, S32, S64) .widenScalarToNextPow2(0, 32) .widenScalarToNextPow2(1, 32) .custom(); // The 64-bit versions produce 32-bit results, but only on the SALU. getActionDefinitionsBuilder({G_CTLZ_ZERO_UNDEF, G_CTTZ_ZERO_UNDEF}) .legalFor({{S32, S32}, {S32, S64}}) .clampScalar(0, S32, S32) .clampScalar(1, S32, S64) .scalarize(0) .widenScalarToNextPow2(0, 32) .widenScalarToNextPow2(1, 32); // S64 is only legal on SALU, and needs to be broken into 32-bit elements in // RegBankSelect. getActionDefinitionsBuilder(G_BITREVERSE) .legalFor({S32, S64}) .clampScalar(0, S32, S64) .scalarize(0) .widenScalarToNextPow2(0); if (ST.has16BitInsts()) { getActionDefinitionsBuilder(G_BSWAP) .legalFor({S16, S32, V2S16}) .clampMaxNumElementsStrict(0, S16, 2) // FIXME: Fixing non-power-of-2 before clamp is workaround for // narrowScalar limitation. .widenScalarToNextPow2(0) .clampScalar(0, S16, S32) .scalarize(0); if (ST.hasVOP3PInsts()) { getActionDefinitionsBuilder({G_SMIN, G_SMAX, G_UMIN, G_UMAX, G_ABS}) .legalFor({S32, S16, V2S16}) .moreElementsIf(isSmallOddVector(0), oneMoreElement(0)) .clampMaxNumElements(0, S16, 2) .minScalar(0, S16) .widenScalarToNextPow2(0) .scalarize(0) .lower(); } else { getActionDefinitionsBuilder({G_SMIN, G_SMAX, G_UMIN, G_UMAX, G_ABS}) .legalFor({S32, S16}) .widenScalarToNextPow2(0) .minScalar(0, S16) .scalarize(0) .lower(); } } else { // TODO: Should have same legality without v_perm_b32 getActionDefinitionsBuilder(G_BSWAP) .legalFor({S32}) .lowerIf(scalarNarrowerThan(0, 32)) // FIXME: Fixing non-power-of-2 before clamp is workaround for // narrowScalar limitation. .widenScalarToNextPow2(0) .maxScalar(0, S32) .scalarize(0) .lower(); getActionDefinitionsBuilder({G_SMIN, G_SMAX, G_UMIN, G_UMAX, G_ABS}) .legalFor({S32}) .minScalar(0, S32) .widenScalarToNextPow2(0) .scalarize(0) .lower(); } getActionDefinitionsBuilder(G_INTTOPTR) // List the common cases .legalForCartesianProduct(AddrSpaces64, {S64}) .legalForCartesianProduct(AddrSpaces32, {S32}) .scalarize(0) // Accept any address space as long as the size matches .legalIf(sameSize(0, 1)) .widenScalarIf(smallerThan(1, 0), [](const LegalityQuery &Query) { return std::make_pair(1, LLT::scalar(Query.Types[0].getSizeInBits())); }) .narrowScalarIf(largerThan(1, 0), [](const LegalityQuery &Query) { return std::make_pair(1, LLT::scalar(Query.Types[0].getSizeInBits())); }); getActionDefinitionsBuilder(G_PTRTOINT) // List the common cases .legalForCartesianProduct(AddrSpaces64, {S64}) .legalForCartesianProduct(AddrSpaces32, {S32}) .scalarize(0) // Accept any address space as long as the size matches .legalIf(sameSize(0, 1)) .widenScalarIf(smallerThan(0, 1), [](const LegalityQuery &Query) { return std::make_pair(0, LLT::scalar(Query.Types[1].getSizeInBits())); }) .narrowScalarIf( largerThan(0, 1), [](const LegalityQuery &Query) { return std::make_pair(0, LLT::scalar(Query.Types[1].getSizeInBits())); }); getActionDefinitionsBuilder(G_ADDRSPACE_CAST) .scalarize(0) .custom(); const auto needToSplitMemOp = [=](const LegalityQuery &Query, bool IsLoad) -> bool { const LLT DstTy = Query.Types[0]; // Split vector extloads. unsigned MemSize = Query.MMODescrs[0].MemoryTy.getSizeInBits(); if (DstTy.isVector() && DstTy.getSizeInBits() > MemSize) return true; const LLT PtrTy = Query.Types[1]; unsigned AS = PtrTy.getAddressSpace(); if (MemSize > maxSizeForAddrSpace(ST, AS, IsLoad)) return true; // Catch weird sized loads that don't evenly divide into the access sizes // TODO: May be able to widen depending on alignment etc. unsigned NumRegs = (MemSize + 31) / 32; if (NumRegs == 3) { if (!ST.hasDwordx3LoadStores()) return true; } else { // If the alignment allows, these should have been widened. if (!isPowerOf2_32(NumRegs)) return true; } return false; }; unsigned GlobalAlign32 = ST.hasUnalignedBufferAccessEnabled() ? 0 : 32; unsigned GlobalAlign16 = ST.hasUnalignedBufferAccessEnabled() ? 0 : 16; unsigned GlobalAlign8 = ST.hasUnalignedBufferAccessEnabled() ? 0 : 8; // TODO: Refine based on subtargets which support unaligned access or 128-bit // LDS // TODO: Unsupported flat for SI. for (unsigned Op : {G_LOAD, G_STORE}) { const bool IsStore = Op == G_STORE; auto &Actions = getActionDefinitionsBuilder(Op); // Explicitly list some common cases. // TODO: Does this help compile time at all? Actions.legalForTypesWithMemDesc({{S32, GlobalPtr, S32, GlobalAlign32}, {V2S32, GlobalPtr, V2S32, GlobalAlign32}, {V4S32, GlobalPtr, V4S32, GlobalAlign32}, {S64, GlobalPtr, S64, GlobalAlign32}, {V2S64, GlobalPtr, V2S64, GlobalAlign32}, {V2S16, GlobalPtr, V2S16, GlobalAlign32}, {S32, GlobalPtr, S8, GlobalAlign8}, {S32, GlobalPtr, S16, GlobalAlign16}, {S32, LocalPtr, S32, 32}, {S64, LocalPtr, S64, 32}, {V2S32, LocalPtr, V2S32, 32}, {S32, LocalPtr, S8, 8}, {S32, LocalPtr, S16, 16}, {V2S16, LocalPtr, S32, 32}, {S32, PrivatePtr, S32, 32}, {S32, PrivatePtr, S8, 8}, {S32, PrivatePtr, S16, 16}, {V2S16, PrivatePtr, S32, 32}, {S32, ConstantPtr, S32, GlobalAlign32}, {V2S32, ConstantPtr, V2S32, GlobalAlign32}, {V4S32, ConstantPtr, V4S32, GlobalAlign32}, {S64, ConstantPtr, S64, GlobalAlign32}, {V2S32, ConstantPtr, V2S32, GlobalAlign32}}); Actions.legalIf( [=](const LegalityQuery &Query) -> bool { return isLoadStoreLegal(ST, Query); }); // Constant 32-bit is handled by addrspacecasting the 32-bit pointer to // 64-bits. // // TODO: Should generalize bitcast action into coerce, which will also cover // inserting addrspacecasts. Actions.customIf(typeIs(1, Constant32Ptr)); // Turn any illegal element vectors into something easier to deal // with. These will ultimately produce 32-bit scalar shifts to extract the // parts anyway. // // For odd 16-bit element vectors, prefer to split those into pieces with // 16-bit vector parts. Actions.bitcastIf( [=](const LegalityQuery &Query) -> bool { return shouldBitcastLoadStoreType(ST, Query.Types[0], Query.MMODescrs[0].MemoryTy); }, bitcastToRegisterType(0)); if (!IsStore) { // Widen suitably aligned loads by loading extra bytes. The standard // legalization actions can't properly express widening memory operands. Actions.customIf([=](const LegalityQuery &Query) -> bool { return shouldWidenLoad(ST, Query, G_LOAD); }); } // FIXME: load/store narrowing should be moved to lower action Actions .narrowScalarIf( [=](const LegalityQuery &Query) -> bool { return !Query.Types[0].isVector() && needToSplitMemOp(Query, Op == G_LOAD); }, [=](const LegalityQuery &Query) -> std::pair { const LLT DstTy = Query.Types[0]; const LLT PtrTy = Query.Types[1]; const unsigned DstSize = DstTy.getSizeInBits(); unsigned MemSize = Query.MMODescrs[0].MemoryTy.getSizeInBits(); // Split extloads. if (DstSize > MemSize) return std::make_pair(0, LLT::scalar(MemSize)); unsigned MaxSize = maxSizeForAddrSpace(ST, PtrTy.getAddressSpace(), Op == G_LOAD); if (MemSize > MaxSize) return std::make_pair(0, LLT::scalar(MaxSize)); uint64_t Align = Query.MMODescrs[0].AlignInBits; return std::make_pair(0, LLT::scalar(Align)); }) .fewerElementsIf( [=](const LegalityQuery &Query) -> bool { return Query.Types[0].isVector() && needToSplitMemOp(Query, Op == G_LOAD); }, [=](const LegalityQuery &Query) -> std::pair { const LLT DstTy = Query.Types[0]; const LLT PtrTy = Query.Types[1]; LLT EltTy = DstTy.getElementType(); unsigned MaxSize = maxSizeForAddrSpace(ST, PtrTy.getAddressSpace(), Op == G_LOAD); // FIXME: Handle widened to power of 2 results better. This ends // up scalarizing. // FIXME: 3 element stores scalarized on SI // Split if it's too large for the address space. unsigned MemSize = Query.MMODescrs[0].MemoryTy.getSizeInBits(); if (MemSize > MaxSize) { unsigned NumElts = DstTy.getNumElements(); unsigned EltSize = EltTy.getSizeInBits(); if (MaxSize % EltSize == 0) { return std::make_pair( 0, LLT::scalarOrVector( ElementCount::getFixed(MaxSize / EltSize), EltTy)); } unsigned NumPieces = MemSize / MaxSize; // FIXME: Refine when odd breakdowns handled // The scalars will need to be re-legalized. if (NumPieces == 1 || NumPieces >= NumElts || NumElts % NumPieces != 0) return std::make_pair(0, EltTy); return std::make_pair( 0, LLT::fixed_vector(NumElts / NumPieces, EltTy)); } // FIXME: We could probably handle weird extending loads better. if (DstTy.getSizeInBits() > MemSize) return std::make_pair(0, EltTy); unsigned EltSize = EltTy.getSizeInBits(); unsigned DstSize = DstTy.getSizeInBits(); if (!isPowerOf2_32(DstSize)) { // We're probably decomposing an odd sized store. Try to split // to the widest type. TODO: Account for alignment. As-is it // should be OK, since the new parts will be further legalized. unsigned FloorSize = PowerOf2Floor(DstSize); return std::make_pair( 0, LLT::scalarOrVector( ElementCount::getFixed(FloorSize / EltSize), EltTy)); } // May need relegalization for the scalars. return std::make_pair(0, EltTy); }) .minScalar(0, S32) .narrowScalarIf(isWideScalarExtLoadTruncStore(0), changeTo(0, S32)) .widenScalarToNextPow2(0) .moreElementsIf(vectorSmallerThan(0, 32), moreEltsToNext32Bit(0)) .lower(); } // FIXME: Unaligned accesses not lowered. auto &ExtLoads = getActionDefinitionsBuilder({G_SEXTLOAD, G_ZEXTLOAD}) .legalForTypesWithMemDesc({{S32, GlobalPtr, S8, 8}, {S32, GlobalPtr, S16, 2 * 8}, {S32, LocalPtr, S8, 8}, {S32, LocalPtr, S16, 16}, {S32, PrivatePtr, S8, 8}, {S32, PrivatePtr, S16, 16}, {S32, ConstantPtr, S8, 8}, {S32, ConstantPtr, S16, 2 * 8}}) .legalIf( [=](const LegalityQuery &Query) -> bool { return isLoadStoreLegal(ST, Query); }); if (ST.hasFlatAddressSpace()) { ExtLoads.legalForTypesWithMemDesc( {{S32, FlatPtr, S8, 8}, {S32, FlatPtr, S16, 16}}); } // Constant 32-bit is handled by addrspacecasting the 32-bit pointer to // 64-bits. // // TODO: Should generalize bitcast action into coerce, which will also cover // inserting addrspacecasts. ExtLoads.customIf(typeIs(1, Constant32Ptr)); ExtLoads.clampScalar(0, S32, S32) .widenScalarToNextPow2(0) .lower(); auto &Atomics = getActionDefinitionsBuilder( {G_ATOMICRMW_XCHG, G_ATOMICRMW_ADD, G_ATOMICRMW_SUB, G_ATOMICRMW_AND, G_ATOMICRMW_OR, G_ATOMICRMW_XOR, G_ATOMICRMW_MAX, G_ATOMICRMW_MIN, G_ATOMICRMW_UMAX, G_ATOMICRMW_UMIN}) .legalFor({{S32, GlobalPtr}, {S32, LocalPtr}, {S64, GlobalPtr}, {S64, LocalPtr}, {S32, RegionPtr}, {S64, RegionPtr}}); if (ST.hasFlatAddressSpace()) { Atomics.legalFor({{S32, FlatPtr}, {S64, FlatPtr}}); } auto &Atomic = getActionDefinitionsBuilder(G_ATOMICRMW_FADD); if (ST.hasLDSFPAtomicAdd()) { Atomic.legalFor({{S32, LocalPtr}, {S32, RegionPtr}}); if (ST.hasGFX90AInsts()) Atomic.legalFor({{S64, LocalPtr}}); if (ST.hasGFX940Insts()) Atomic.legalFor({{V2S16, LocalPtr}}); } if (ST.hasAtomicFaddInsts()) Atomic.legalFor({{S32, GlobalPtr}}); if (ST.hasGFX90AInsts()) { // These are legal with some caveats, and should have undergone expansion in // the IR in most situations // TODO: Move atomic expansion into legalizer // TODO: Also supports <2 x f16> Atomic.legalFor({ {S32, GlobalPtr}, {S64, GlobalPtr}, {S64, FlatPtr} }); } // BUFFER/FLAT_ATOMIC_CMP_SWAP on GCN GPUs needs input marshalling, and output // demarshalling getActionDefinitionsBuilder(G_ATOMIC_CMPXCHG) .customFor({{S32, GlobalPtr}, {S64, GlobalPtr}, {S32, FlatPtr}, {S64, FlatPtr}}) .legalFor({{S32, LocalPtr}, {S64, LocalPtr}, {S32, RegionPtr}, {S64, RegionPtr}}); // TODO: Pointer types, any 32-bit or 64-bit vector // Condition should be s32 for scalar, s1 for vector. getActionDefinitionsBuilder(G_SELECT) .legalForCartesianProduct({S32, S64, S16, V2S32, V2S16, V4S16, GlobalPtr, LocalPtr, FlatPtr, PrivatePtr, LLT::fixed_vector(2, LocalPtr), LLT::fixed_vector(2, PrivatePtr)}, {S1, S32}) .clampScalar(0, S16, S64) .scalarize(1) .moreElementsIf(isSmallOddVector(0), oneMoreElement(0)) .fewerElementsIf(numElementsNotEven(0), scalarize(0)) .clampMaxNumElements(0, S32, 2) .clampMaxNumElements(0, LocalPtr, 2) .clampMaxNumElements(0, PrivatePtr, 2) .scalarize(0) .widenScalarToNextPow2(0) .legalIf(all(isPointer(0), typeInSet(1, {S1, S32}))); // TODO: Only the low 4/5/6 bits of the shift amount are observed, so we can // be more flexible with the shift amount type. auto &Shifts = getActionDefinitionsBuilder({G_SHL, G_LSHR, G_ASHR}) .legalFor({{S32, S32}, {S64, S32}}); if (ST.has16BitInsts()) { if (ST.hasVOP3PInsts()) { Shifts.legalFor({{S16, S16}, {V2S16, V2S16}}) .clampMaxNumElements(0, S16, 2); } else Shifts.legalFor({{S16, S16}}); // TODO: Support 16-bit shift amounts for all types Shifts.widenScalarIf( [=](const LegalityQuery &Query) { // Use 16-bit shift amounts for any 16-bit shift. Otherwise we want a // 32-bit amount. const LLT ValTy = Query.Types[0]; const LLT AmountTy = Query.Types[1]; return ValTy.getSizeInBits() <= 16 && AmountTy.getSizeInBits() < 16; }, changeTo(1, S16)); Shifts.maxScalarIf(typeIs(0, S16), 1, S16); Shifts.clampScalar(1, S32, S32); Shifts.widenScalarToNextPow2(0, 16); Shifts.clampScalar(0, S16, S64); getActionDefinitionsBuilder({G_SSHLSAT, G_USHLSAT}) .minScalar(0, S16) .scalarize(0) .lower(); } else { // Make sure we legalize the shift amount type first, as the general // expansion for the shifted type will produce much worse code if it hasn't // been truncated already. Shifts.clampScalar(1, S32, S32); Shifts.widenScalarToNextPow2(0, 32); Shifts.clampScalar(0, S32, S64); getActionDefinitionsBuilder({G_SSHLSAT, G_USHLSAT}) .minScalar(0, S32) .scalarize(0) .lower(); } Shifts.scalarize(0); for (unsigned Op : {G_EXTRACT_VECTOR_ELT, G_INSERT_VECTOR_ELT}) { unsigned VecTypeIdx = Op == G_EXTRACT_VECTOR_ELT ? 1 : 0; unsigned EltTypeIdx = Op == G_EXTRACT_VECTOR_ELT ? 0 : 1; unsigned IdxTypeIdx = 2; getActionDefinitionsBuilder(Op) .customIf([=](const LegalityQuery &Query) { const LLT EltTy = Query.Types[EltTypeIdx]; const LLT VecTy = Query.Types[VecTypeIdx]; const LLT IdxTy = Query.Types[IdxTypeIdx]; const unsigned EltSize = EltTy.getSizeInBits(); return (EltSize == 32 || EltSize == 64) && VecTy.getSizeInBits() % 32 == 0 && VecTy.getSizeInBits() <= MaxRegisterSize && IdxTy.getSizeInBits() == 32; }) .bitcastIf(all(sizeIsMultipleOf32(VecTypeIdx), scalarOrEltNarrowerThan(VecTypeIdx, 32)), bitcastToVectorElement32(VecTypeIdx)) //.bitcastIf(vectorSmallerThan(1, 32), bitcastToScalar(1)) .bitcastIf( all(sizeIsMultipleOf32(VecTypeIdx), scalarOrEltWiderThan(VecTypeIdx, 64)), [=](const LegalityQuery &Query) { // For > 64-bit element types, try to turn this into a 64-bit // element vector since we may be able to do better indexing // if this is scalar. If not, fall back to 32. const LLT EltTy = Query.Types[EltTypeIdx]; const LLT VecTy = Query.Types[VecTypeIdx]; const unsigned DstEltSize = EltTy.getSizeInBits(); const unsigned VecSize = VecTy.getSizeInBits(); const unsigned TargetEltSize = DstEltSize % 64 == 0 ? 64 : 32; return std::make_pair( VecTypeIdx, LLT::fixed_vector(VecSize / TargetEltSize, TargetEltSize)); }) .clampScalar(EltTypeIdx, S32, S64) .clampScalar(VecTypeIdx, S32, S64) .clampScalar(IdxTypeIdx, S32, S32) .clampMaxNumElements(VecTypeIdx, S32, 32) // TODO: Clamp elements for 64-bit vectors? // It should only be necessary with variable indexes. // As a last resort, lower to the stack .lower(); } getActionDefinitionsBuilder(G_EXTRACT_VECTOR_ELT) .unsupportedIf([=](const LegalityQuery &Query) { const LLT &EltTy = Query.Types[1].getElementType(); return Query.Types[0] != EltTy; }); for (unsigned Op : {G_EXTRACT, G_INSERT}) { unsigned BigTyIdx = Op == G_EXTRACT ? 1 : 0; unsigned LitTyIdx = Op == G_EXTRACT ? 0 : 1; // FIXME: Doesn't handle extract of illegal sizes. getActionDefinitionsBuilder(Op) .lowerIf(all(typeIs(LitTyIdx, S16), sizeIs(BigTyIdx, 32))) .lowerIf([=](const LegalityQuery &Query) { // Sub-vector(or single element) insert and extract. // TODO: verify immediate offset here since lower only works with // whole elements. const LLT BigTy = Query.Types[BigTyIdx]; return BigTy.isVector(); }) // FIXME: Multiples of 16 should not be legal. .legalIf([=](const LegalityQuery &Query) { const LLT BigTy = Query.Types[BigTyIdx]; const LLT LitTy = Query.Types[LitTyIdx]; return (BigTy.getSizeInBits() % 32 == 0) && (LitTy.getSizeInBits() % 16 == 0); }) .widenScalarIf( [=](const LegalityQuery &Query) { const LLT BigTy = Query.Types[BigTyIdx]; return (BigTy.getScalarSizeInBits() < 16); }, LegalizeMutations::widenScalarOrEltToNextPow2(BigTyIdx, 16)) .widenScalarIf( [=](const LegalityQuery &Query) { const LLT LitTy = Query.Types[LitTyIdx]; return (LitTy.getScalarSizeInBits() < 16); }, LegalizeMutations::widenScalarOrEltToNextPow2(LitTyIdx, 16)) .moreElementsIf(isSmallOddVector(BigTyIdx), oneMoreElement(BigTyIdx)) .widenScalarToNextPow2(BigTyIdx, 32); } auto &BuildVector = getActionDefinitionsBuilder(G_BUILD_VECTOR) .legalForCartesianProduct(AllS32Vectors, {S32}) .legalForCartesianProduct(AllS64Vectors, {S64}) .clampNumElements(0, V16S32, V32S32) .clampNumElements(0, V2S64, V16S64) .fewerElementsIf(isWideVec16(0), changeTo(0, V2S16)); if (ST.hasScalarPackInsts()) { BuildVector // FIXME: Should probably widen s1 vectors straight to s32 .minScalarOrElt(0, S16) // Widen source elements and produce a G_BUILD_VECTOR_TRUNC .minScalar(1, S32); getActionDefinitionsBuilder(G_BUILD_VECTOR_TRUNC) .legalFor({V2S16, S32}) .lower(); BuildVector.minScalarOrElt(0, S32); } else { BuildVector.customFor({V2S16, S16}); BuildVector.minScalarOrElt(0, S32); getActionDefinitionsBuilder(G_BUILD_VECTOR_TRUNC) .customFor({V2S16, S32}) .lower(); } BuildVector.legalIf(isRegisterType(0)); // FIXME: Clamp maximum size getActionDefinitionsBuilder(G_CONCAT_VECTORS) .legalIf(all(isRegisterType(0), isRegisterType(1))) .clampMaxNumElements(0, S32, 32) .clampMaxNumElements(1, S16, 2) // TODO: Make 4? .clampMaxNumElements(0, S16, 64); // TODO: Don't fully scalarize v2s16 pieces? Or combine out those // pre-legalize. if (ST.hasVOP3PInsts()) { getActionDefinitionsBuilder(G_SHUFFLE_VECTOR) .customFor({V2S16, V2S16}) .lower(); } else getActionDefinitionsBuilder(G_SHUFFLE_VECTOR).lower(); // Merge/Unmerge for (unsigned Op : {G_MERGE_VALUES, G_UNMERGE_VALUES}) { unsigned BigTyIdx = Op == G_MERGE_VALUES ? 0 : 1; unsigned LitTyIdx = Op == G_MERGE_VALUES ? 1 : 0; auto notValidElt = [=](const LegalityQuery &Query, unsigned TypeIdx) { const LLT Ty = Query.Types[TypeIdx]; if (Ty.isVector()) { const LLT &EltTy = Ty.getElementType(); if (EltTy.getSizeInBits() < 8 || EltTy.getSizeInBits() > 512) return true; if (!isPowerOf2_32(EltTy.getSizeInBits())) return true; } return false; }; auto &Builder = getActionDefinitionsBuilder(Op) .legalIf(all(isRegisterType(0), isRegisterType(1))) .lowerFor({{S16, V2S16}}) .lowerIf([=](const LegalityQuery &Query) { const LLT BigTy = Query.Types[BigTyIdx]; return BigTy.getSizeInBits() == 32; }) // Try to widen to s16 first for small types. // TODO: Only do this on targets with legal s16 shifts .minScalarOrEltIf(scalarNarrowerThan(LitTyIdx, 16), LitTyIdx, S16) .widenScalarToNextPow2(LitTyIdx, /*Min*/ 16) .moreElementsIf(isSmallOddVector(BigTyIdx), oneMoreElement(BigTyIdx)) .fewerElementsIf(all(typeIs(0, S16), vectorWiderThan(1, 32), elementTypeIs(1, S16)), changeTo(1, V2S16)) // Clamp the little scalar to s8-s256 and make it a power of 2. It's not // worth considering the multiples of 64 since 2*192 and 2*384 are not // valid. .clampScalar(LitTyIdx, S32, S512) .widenScalarToNextPow2(LitTyIdx, /*Min*/ 32) // Break up vectors with weird elements into scalars .fewerElementsIf( [=](const LegalityQuery &Query) { return notValidElt(Query, LitTyIdx); }, scalarize(0)) .fewerElementsIf( [=](const LegalityQuery &Query) { return notValidElt(Query, BigTyIdx); }, scalarize(1)) .clampScalar(BigTyIdx, S32, MaxScalar); if (Op == G_MERGE_VALUES) { Builder.widenScalarIf( // TODO: Use 16-bit shifts if legal for 8-bit values? [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[LitTyIdx]; return Ty.getSizeInBits() < 32; }, changeTo(LitTyIdx, S32)); } Builder.widenScalarIf( [=](const LegalityQuery &Query) { const LLT Ty = Query.Types[BigTyIdx]; return !isPowerOf2_32(Ty.getSizeInBits()) && Ty.getSizeInBits() % 16 != 0; }, [=](const LegalityQuery &Query) { // Pick the next power of 2, or a multiple of 64 over 128. // Whichever is smaller. const LLT &Ty = Query.Types[BigTyIdx]; unsigned NewSizeInBits = 1 << Log2_32_Ceil(Ty.getSizeInBits() + 1); if (NewSizeInBits >= 256) { unsigned RoundedTo = alignTo<64>(Ty.getSizeInBits() + 1); if (RoundedTo < NewSizeInBits) NewSizeInBits = RoundedTo; } return std::make_pair(BigTyIdx, LLT::scalar(NewSizeInBits)); }) // Any vectors left are the wrong size. Scalarize them. .scalarize(0) .scalarize(1); } // S64 is only legal on SALU, and needs to be broken into 32-bit elements in // RegBankSelect. auto &SextInReg = getActionDefinitionsBuilder(G_SEXT_INREG) .legalFor({{S32}, {S64}}); if (ST.hasVOP3PInsts()) { SextInReg.lowerFor({{V2S16}}) // Prefer to reduce vector widths for 16-bit vectors before lowering, to // get more vector shift opportunities, since we'll get those when // expanded. .clampMaxNumElementsStrict(0, S16, 2); } else if (ST.has16BitInsts()) { SextInReg.lowerFor({{S32}, {S64}, {S16}}); } else { // Prefer to promote to s32 before lowering if we don't have 16-bit // shifts. This avoid a lot of intermediate truncate and extend operations. SextInReg.lowerFor({{S32}, {S64}}); } SextInReg .scalarize(0) .clampScalar(0, S32, S64) .lower(); getActionDefinitionsBuilder({G_ROTR, G_ROTL}) .scalarize(0) .lower(); // TODO: Only Try to form v2s16 with legal packed instructions. getActionDefinitionsBuilder(G_FSHR) .legalFor({{S32, S32}}) .lowerFor({{V2S16, V2S16}}) .clampMaxNumElementsStrict(0, S16, 2) .scalarize(0) .lower(); if (ST.hasVOP3PInsts()) { getActionDefinitionsBuilder(G_FSHL) .lowerFor({{V2S16, V2S16}}) .clampMaxNumElementsStrict(0, S16, 2) .scalarize(0) .lower(); } else { getActionDefinitionsBuilder(G_FSHL) .scalarize(0) .lower(); } getActionDefinitionsBuilder(G_READCYCLECOUNTER) .legalFor({S64}); getActionDefinitionsBuilder(G_FENCE) .alwaysLegal(); getActionDefinitionsBuilder({G_SMULO, G_UMULO}) .scalarize(0) .minScalar(0, S32) .lower(); getActionDefinitionsBuilder({G_SBFX, G_UBFX}) .legalFor({{S32, S32}, {S64, S32}}) .clampScalar(1, S32, S32) .clampScalar(0, S32, S64) .widenScalarToNextPow2(0) .scalarize(0); getActionDefinitionsBuilder({ // TODO: Verify V_BFI_B32 is generated from expanded bit ops G_FCOPYSIGN, G_ATOMIC_CMPXCHG_WITH_SUCCESS, G_ATOMICRMW_NAND, G_ATOMICRMW_FSUB, G_READ_REGISTER, G_WRITE_REGISTER, G_SADDO, G_SSUBO, // TODO: Implement G_FMINIMUM, G_FMAXIMUM}).lower(); getActionDefinitionsBuilder({G_MEMCPY, G_MEMCPY_INLINE, G_MEMMOVE, G_MEMSET}) .lower(); getActionDefinitionsBuilder({G_VASTART, G_VAARG, G_BRJT, G_JUMP_TABLE, G_INDEXED_LOAD, G_INDEXED_SEXTLOAD, G_INDEXED_ZEXTLOAD, G_INDEXED_STORE}) .unsupported(); getLegacyLegalizerInfo().computeTables(); verify(*ST.getInstrInfo()); } bool AMDGPULegalizerInfo::legalizeCustom(LegalizerHelper &Helper, MachineInstr &MI) const { MachineIRBuilder &B = Helper.MIRBuilder; MachineRegisterInfo &MRI = *B.getMRI(); switch (MI.getOpcode()) { case TargetOpcode::G_ADDRSPACE_CAST: return legalizeAddrSpaceCast(MI, MRI, B); case TargetOpcode::G_FRINT: return legalizeFrint(MI, MRI, B); case TargetOpcode::G_FCEIL: return legalizeFceil(MI, MRI, B); case TargetOpcode::G_FREM: return legalizeFrem(MI, MRI, B); case TargetOpcode::G_INTRINSIC_TRUNC: return legalizeIntrinsicTrunc(MI, MRI, B); case TargetOpcode::G_SITOFP: return legalizeITOFP(MI, MRI, B, true); case TargetOpcode::G_UITOFP: return legalizeITOFP(MI, MRI, B, false); case TargetOpcode::G_FPTOSI: return legalizeFPTOI(MI, MRI, B, true); case TargetOpcode::G_FPTOUI: return legalizeFPTOI(MI, MRI, B, false); case TargetOpcode::G_FMINNUM: case TargetOpcode::G_FMAXNUM: case TargetOpcode::G_FMINNUM_IEEE: case TargetOpcode::G_FMAXNUM_IEEE: return legalizeMinNumMaxNum(Helper, MI); case TargetOpcode::G_EXTRACT_VECTOR_ELT: return legalizeExtractVectorElt(MI, MRI, B); case TargetOpcode::G_INSERT_VECTOR_ELT: return legalizeInsertVectorElt(MI, MRI, B); case TargetOpcode::G_SHUFFLE_VECTOR: return legalizeShuffleVector(MI, MRI, B); case TargetOpcode::G_FSIN: case TargetOpcode::G_FCOS: return legalizeSinCos(MI, MRI, B); case TargetOpcode::G_GLOBAL_VALUE: return legalizeGlobalValue(MI, MRI, B); case TargetOpcode::G_LOAD: case TargetOpcode::G_SEXTLOAD: case TargetOpcode::G_ZEXTLOAD: return legalizeLoad(Helper, MI); case TargetOpcode::G_FMAD: return legalizeFMad(MI, MRI, B); case TargetOpcode::G_FDIV: return legalizeFDIV(MI, MRI, B); case TargetOpcode::G_UDIV: case TargetOpcode::G_UREM: case TargetOpcode::G_UDIVREM: return legalizeUnsignedDIV_REM(MI, MRI, B); case TargetOpcode::G_SDIV: case TargetOpcode::G_SREM: case TargetOpcode::G_SDIVREM: return legalizeSignedDIV_REM(MI, MRI, B); case TargetOpcode::G_ATOMIC_CMPXCHG: return legalizeAtomicCmpXChg(MI, MRI, B); case TargetOpcode::G_FLOG: return legalizeFlog(MI, B, numbers::ln2f); case TargetOpcode::G_FLOG10: return legalizeFlog(MI, B, numbers::ln2f / numbers::ln10f); case TargetOpcode::G_FEXP: return legalizeFExp(MI, B); case TargetOpcode::G_FPOW: return legalizeFPow(MI, B); case TargetOpcode::G_FFLOOR: return legalizeFFloor(MI, MRI, B); case TargetOpcode::G_BUILD_VECTOR: return legalizeBuildVector(MI, MRI, B); case TargetOpcode::G_MUL: return legalizeMul(Helper, MI); case TargetOpcode::G_CTLZ: case TargetOpcode::G_CTTZ: return legalizeCTLZ_CTTZ(MI, MRI, B); case TargetOpcode::G_INTRINSIC_FPTRUNC_ROUND: return legalizeFPTruncRound(MI, B); default: return false; } llvm_unreachable("expected switch to return"); } Register AMDGPULegalizerInfo::getSegmentAperture( unsigned AS, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { MachineFunction &MF = B.getMF(); const GCNSubtarget &ST = MF.getSubtarget(); const LLT S32 = LLT::scalar(32); assert(AS == AMDGPUAS::LOCAL_ADDRESS || AS == AMDGPUAS::PRIVATE_ADDRESS); if (ST.hasApertureRegs()) { // FIXME: Use inline constants (src_{shared, private}_base) instead of // getreg. unsigned Offset = AS == AMDGPUAS::LOCAL_ADDRESS ? AMDGPU::Hwreg::OFFSET_SRC_SHARED_BASE : AMDGPU::Hwreg::OFFSET_SRC_PRIVATE_BASE; unsigned WidthM1 = AS == AMDGPUAS::LOCAL_ADDRESS ? AMDGPU::Hwreg::WIDTH_M1_SRC_SHARED_BASE : AMDGPU::Hwreg::WIDTH_M1_SRC_PRIVATE_BASE; unsigned Encoding = AMDGPU::Hwreg::ID_MEM_BASES << AMDGPU::Hwreg::ID_SHIFT_ | Offset << AMDGPU::Hwreg::OFFSET_SHIFT_ | WidthM1 << AMDGPU::Hwreg::WIDTH_M1_SHIFT_; Register GetReg = MRI.createVirtualRegister(&AMDGPU::SReg_32RegClass); B.buildInstr(AMDGPU::S_GETREG_B32) .addDef(GetReg) .addImm(Encoding); MRI.setType(GetReg, S32); auto ShiftAmt = B.buildConstant(S32, WidthM1 + 1); return B.buildShl(S32, GetReg, ShiftAmt).getReg(0); } // TODO: can we be smarter about machine pointer info? MachinePointerInfo PtrInfo(AMDGPUAS::CONSTANT_ADDRESS); Register LoadAddr = MRI.createGenericVirtualRegister( LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64)); // For code object version 5, private_base and shared_base are passed through // implicit kernargs. if (AMDGPU::getAmdhsaCodeObjectVersion() == 5) { AMDGPUTargetLowering::ImplicitParameter Param = AS == AMDGPUAS::LOCAL_ADDRESS ? AMDGPUTargetLowering::SHARED_BASE : AMDGPUTargetLowering::PRIVATE_BASE; uint64_t Offset = ST.getTargetLowering()->getImplicitParameterOffset(B.getMF(), Param); Register KernargPtrReg = MRI.createGenericVirtualRegister( LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64)); if (!loadInputValue(KernargPtrReg, B, AMDGPUFunctionArgInfo::KERNARG_SEGMENT_PTR)) return Register(); MachineMemOperand *MMO = MF.getMachineMemOperand( PtrInfo, MachineMemOperand::MOLoad | MachineMemOperand::MODereferenceable | MachineMemOperand::MOInvariant, LLT::scalar(32), commonAlignment(Align(64), Offset)); // Pointer address B.buildPtrAdd(LoadAddr, KernargPtrReg, B.buildConstant(LLT::scalar(64), Offset).getReg(0)); // Load address return B.buildLoad(S32, LoadAddr, *MMO).getReg(0); } Register QueuePtr = MRI.createGenericVirtualRegister( LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64)); if (!loadInputValue(QueuePtr, B, AMDGPUFunctionArgInfo::QUEUE_PTR)) return Register(); // Offset into amd_queue_t for group_segment_aperture_base_hi / // private_segment_aperture_base_hi. uint32_t StructOffset = (AS == AMDGPUAS::LOCAL_ADDRESS) ? 0x40 : 0x44; MachineMemOperand *MMO = MF.getMachineMemOperand( PtrInfo, MachineMemOperand::MOLoad | MachineMemOperand::MODereferenceable | MachineMemOperand::MOInvariant, LLT::scalar(32), commonAlignment(Align(64), StructOffset)); B.buildPtrAdd(LoadAddr, QueuePtr, B.buildConstant(LLT::scalar(64), StructOffset).getReg(0)); return B.buildLoad(S32, LoadAddr, *MMO).getReg(0); } /// Return true if the value is a known valid address, such that a null check is /// not necessary. static bool isKnownNonNull(Register Val, MachineRegisterInfo &MRI, const AMDGPUTargetMachine &TM, unsigned AddrSpace) { MachineInstr *Def = MRI.getVRegDef(Val); switch (Def->getOpcode()) { case AMDGPU::G_FRAME_INDEX: case AMDGPU::G_GLOBAL_VALUE: case AMDGPU::G_BLOCK_ADDR: return true; case AMDGPU::G_CONSTANT: { const ConstantInt *CI = Def->getOperand(1).getCImm(); return CI->getSExtValue() != TM.getNullPointerValue(AddrSpace); } default: return false; } return false; } bool AMDGPULegalizerInfo::legalizeAddrSpaceCast( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { MachineFunction &MF = B.getMF(); const LLT S32 = LLT::scalar(32); Register Dst = MI.getOperand(0).getReg(); Register Src = MI.getOperand(1).getReg(); LLT DstTy = MRI.getType(Dst); LLT SrcTy = MRI.getType(Src); unsigned DestAS = DstTy.getAddressSpace(); unsigned SrcAS = SrcTy.getAddressSpace(); // TODO: Avoid reloading from the queue ptr for each cast, or at least each // vector element. assert(!DstTy.isVector()); const AMDGPUTargetMachine &TM = static_cast(MF.getTarget()); if (TM.isNoopAddrSpaceCast(SrcAS, DestAS)) { MI.setDesc(B.getTII().get(TargetOpcode::G_BITCAST)); return true; } if (SrcAS == AMDGPUAS::FLAT_ADDRESS && (DestAS == AMDGPUAS::LOCAL_ADDRESS || DestAS == AMDGPUAS::PRIVATE_ADDRESS)) { if (isKnownNonNull(Src, MRI, TM, SrcAS)) { // Extract low 32-bits of the pointer. B.buildExtract(Dst, Src, 0); MI.eraseFromParent(); return true; } unsigned NullVal = TM.getNullPointerValue(DestAS); auto SegmentNull = B.buildConstant(DstTy, NullVal); auto FlatNull = B.buildConstant(SrcTy, 0); // Extract low 32-bits of the pointer. auto PtrLo32 = B.buildExtract(DstTy, Src, 0); auto CmpRes = B.buildICmp(CmpInst::ICMP_NE, LLT::scalar(1), Src, FlatNull.getReg(0)); B.buildSelect(Dst, CmpRes, PtrLo32, SegmentNull.getReg(0)); MI.eraseFromParent(); return true; } if (DestAS == AMDGPUAS::FLAT_ADDRESS && (SrcAS == AMDGPUAS::LOCAL_ADDRESS || SrcAS == AMDGPUAS::PRIVATE_ADDRESS)) { if (!ST.hasFlatAddressSpace()) return false; Register ApertureReg = getSegmentAperture(SrcAS, MRI, B); if (!ApertureReg.isValid()) return false; // Coerce the type of the low half of the result so we can use merge_values. Register SrcAsInt = B.buildPtrToInt(S32, Src).getReg(0); // TODO: Should we allow mismatched types but matching sizes in merges to // avoid the ptrtoint? auto BuildPtr = B.buildMerge(DstTy, {SrcAsInt, ApertureReg}); if (isKnownNonNull(Src, MRI, TM, SrcAS)) { B.buildCopy(Dst, BuildPtr); MI.eraseFromParent(); return true; } auto SegmentNull = B.buildConstant(SrcTy, TM.getNullPointerValue(SrcAS)); auto FlatNull = B.buildConstant(DstTy, TM.getNullPointerValue(DestAS)); auto CmpRes = B.buildICmp(CmpInst::ICMP_NE, LLT::scalar(1), Src, SegmentNull.getReg(0)); B.buildSelect(Dst, CmpRes, BuildPtr, FlatNull); MI.eraseFromParent(); return true; } if (DestAS == AMDGPUAS::CONSTANT_ADDRESS_32BIT && SrcTy.getSizeInBits() == 64) { // Truncate. B.buildExtract(Dst, Src, 0); MI.eraseFromParent(); return true; } if (SrcAS == AMDGPUAS::CONSTANT_ADDRESS_32BIT && DstTy.getSizeInBits() == 64) { const SIMachineFunctionInfo *Info = MF.getInfo(); uint32_t AddrHiVal = Info->get32BitAddressHighBits(); // FIXME: This is a bit ugly due to creating a merge of 2 pointers to // another. Merge operands are required to be the same type, but creating an // extra ptrtoint would be kind of pointless. auto HighAddr = B.buildConstant( LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS_32BIT, 32), AddrHiVal); B.buildMerge(Dst, {Src, HighAddr}); MI.eraseFromParent(); return true; } DiagnosticInfoUnsupported InvalidAddrSpaceCast( MF.getFunction(), "invalid addrspacecast", B.getDebugLoc()); LLVMContext &Ctx = MF.getFunction().getContext(); Ctx.diagnose(InvalidAddrSpaceCast); B.buildUndef(Dst); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFrint( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register Src = MI.getOperand(1).getReg(); LLT Ty = MRI.getType(Src); assert(Ty.isScalar() && Ty.getSizeInBits() == 64); APFloat C1Val(APFloat::IEEEdouble(), "0x1.0p+52"); APFloat C2Val(APFloat::IEEEdouble(), "0x1.fffffffffffffp+51"); auto C1 = B.buildFConstant(Ty, C1Val); auto CopySign = B.buildFCopysign(Ty, C1, Src); // TODO: Should this propagate fast-math-flags? auto Tmp1 = B.buildFAdd(Ty, Src, CopySign); auto Tmp2 = B.buildFSub(Ty, Tmp1, CopySign); auto C2 = B.buildFConstant(Ty, C2Val); auto Fabs = B.buildFAbs(Ty, Src); auto Cond = B.buildFCmp(CmpInst::FCMP_OGT, LLT::scalar(1), Fabs, C2); B.buildSelect(MI.getOperand(0).getReg(), Cond, Src, Tmp2); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFceil( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { const LLT S1 = LLT::scalar(1); const LLT S64 = LLT::scalar(64); Register Src = MI.getOperand(1).getReg(); assert(MRI.getType(Src) == S64); // result = trunc(src) // if (src > 0.0 && src != result) // result += 1.0 auto Trunc = B.buildIntrinsicTrunc(S64, Src); const auto Zero = B.buildFConstant(S64, 0.0); const auto One = B.buildFConstant(S64, 1.0); auto Lt0 = B.buildFCmp(CmpInst::FCMP_OGT, S1, Src, Zero); auto NeTrunc = B.buildFCmp(CmpInst::FCMP_ONE, S1, Src, Trunc); auto And = B.buildAnd(S1, Lt0, NeTrunc); auto Add = B.buildSelect(S64, And, One, Zero); // TODO: Should this propagate fast-math-flags? B.buildFAdd(MI.getOperand(0).getReg(), Trunc, Add); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFrem( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register DstReg = MI.getOperand(0).getReg(); Register Src0Reg = MI.getOperand(1).getReg(); Register Src1Reg = MI.getOperand(2).getReg(); auto Flags = MI.getFlags(); LLT Ty = MRI.getType(DstReg); auto Div = B.buildFDiv(Ty, Src0Reg, Src1Reg, Flags); auto Trunc = B.buildIntrinsicTrunc(Ty, Div, Flags); auto Neg = B.buildFNeg(Ty, Trunc, Flags); B.buildFMA(DstReg, Neg, Src1Reg, Src0Reg, Flags); MI.eraseFromParent(); return true; } static MachineInstrBuilder extractF64Exponent(Register Hi, MachineIRBuilder &B) { const unsigned FractBits = 52; const unsigned ExpBits = 11; LLT S32 = LLT::scalar(32); auto Const0 = B.buildConstant(S32, FractBits - 32); auto Const1 = B.buildConstant(S32, ExpBits); auto ExpPart = B.buildIntrinsic(Intrinsic::amdgcn_ubfe, {S32}, false) .addUse(Hi) .addUse(Const0.getReg(0)) .addUse(Const1.getReg(0)); return B.buildSub(S32, ExpPart, B.buildConstant(S32, 1023)); } bool AMDGPULegalizerInfo::legalizeIntrinsicTrunc( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { const LLT S1 = LLT::scalar(1); const LLT S32 = LLT::scalar(32); const LLT S64 = LLT::scalar(64); Register Src = MI.getOperand(1).getReg(); assert(MRI.getType(Src) == S64); // TODO: Should this use extract since the low half is unused? auto Unmerge = B.buildUnmerge({S32, S32}, Src); Register Hi = Unmerge.getReg(1); // Extract the upper half, since this is where we will find the sign and // exponent. auto Exp = extractF64Exponent(Hi, B); const unsigned FractBits = 52; // Extract the sign bit. const auto SignBitMask = B.buildConstant(S32, UINT32_C(1) << 31); auto SignBit = B.buildAnd(S32, Hi, SignBitMask); const auto FractMask = B.buildConstant(S64, (UINT64_C(1) << FractBits) - 1); const auto Zero32 = B.buildConstant(S32, 0); // Extend back to 64-bits. auto SignBit64 = B.buildMerge(S64, {Zero32, SignBit}); auto Shr = B.buildAShr(S64, FractMask, Exp); auto Not = B.buildNot(S64, Shr); auto Tmp0 = B.buildAnd(S64, Src, Not); auto FiftyOne = B.buildConstant(S32, FractBits - 1); auto ExpLt0 = B.buildICmp(CmpInst::ICMP_SLT, S1, Exp, Zero32); auto ExpGt51 = B.buildICmp(CmpInst::ICMP_SGT, S1, Exp, FiftyOne); auto Tmp1 = B.buildSelect(S64, ExpLt0, SignBit64, Tmp0); B.buildSelect(MI.getOperand(0).getReg(), ExpGt51, Src, Tmp1); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeITOFP( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B, bool Signed) const { Register Dst = MI.getOperand(0).getReg(); Register Src = MI.getOperand(1).getReg(); const LLT S64 = LLT::scalar(64); const LLT S32 = LLT::scalar(32); assert(MRI.getType(Src) == S64); auto Unmerge = B.buildUnmerge({S32, S32}, Src); auto ThirtyTwo = B.buildConstant(S32, 32); if (MRI.getType(Dst) == S64) { auto CvtHi = Signed ? B.buildSITOFP(S64, Unmerge.getReg(1)) : B.buildUITOFP(S64, Unmerge.getReg(1)); auto CvtLo = B.buildUITOFP(S64, Unmerge.getReg(0)); auto LdExp = B.buildIntrinsic(Intrinsic::amdgcn_ldexp, {S64}, false) .addUse(CvtHi.getReg(0)) .addUse(ThirtyTwo.getReg(0)); // TODO: Should this propagate fast-math-flags? B.buildFAdd(Dst, LdExp, CvtLo); MI.eraseFromParent(); return true; } assert(MRI.getType(Dst) == S32); auto One = B.buildConstant(S32, 1); MachineInstrBuilder ShAmt; if (Signed) { auto ThirtyOne = B.buildConstant(S32, 31); auto X = B.buildXor(S32, Unmerge.getReg(0), Unmerge.getReg(1)); auto OppositeSign = B.buildAShr(S32, X, ThirtyOne); auto MaxShAmt = B.buildAdd(S32, ThirtyTwo, OppositeSign); auto LS = B.buildIntrinsic(Intrinsic::amdgcn_sffbh, {S32}, /*HasSideEffects=*/false) .addUse(Unmerge.getReg(1)); auto LS2 = B.buildSub(S32, LS, One); ShAmt = B.buildUMin(S32, LS2, MaxShAmt); } else ShAmt = B.buildCTLZ(S32, Unmerge.getReg(1)); auto Norm = B.buildShl(S64, Src, ShAmt); auto Unmerge2 = B.buildUnmerge({S32, S32}, Norm); auto Adjust = B.buildUMin(S32, One, Unmerge2.getReg(0)); auto Norm2 = B.buildOr(S32, Unmerge2.getReg(1), Adjust); auto FVal = Signed ? B.buildSITOFP(S32, Norm2) : B.buildUITOFP(S32, Norm2); auto Scale = B.buildSub(S32, ThirtyTwo, ShAmt); B.buildIntrinsic(Intrinsic::amdgcn_ldexp, ArrayRef{Dst}, /*HasSideEffects=*/false) .addUse(FVal.getReg(0)) .addUse(Scale.getReg(0)); MI.eraseFromParent(); return true; } // TODO: Copied from DAG implementation. Verify logic and document how this // actually works. bool AMDGPULegalizerInfo::legalizeFPTOI(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B, bool Signed) const { Register Dst = MI.getOperand(0).getReg(); Register Src = MI.getOperand(1).getReg(); const LLT S64 = LLT::scalar(64); const LLT S32 = LLT::scalar(32); const LLT SrcLT = MRI.getType(Src); assert((SrcLT == S32 || SrcLT == S64) && MRI.getType(Dst) == S64); unsigned Flags = MI.getFlags(); // The basic idea of converting a floating point number into a pair of 32-bit // integers is illustrated as follows: // // tf := trunc(val); // hif := floor(tf * 2^-32); // lof := tf - hif * 2^32; // lof is always positive due to floor. // hi := fptoi(hif); // lo := fptoi(lof); // auto Trunc = B.buildIntrinsicTrunc(SrcLT, Src, Flags); MachineInstrBuilder Sign; if (Signed && SrcLT == S32) { // However, a 32-bit floating point number has only 23 bits mantissa and // it's not enough to hold all the significant bits of `lof` if val is // negative. To avoid the loss of precision, We need to take the absolute // value after truncating and flip the result back based on the original // signedness. Sign = B.buildAShr(S32, Src, B.buildConstant(S32, 31)); Trunc = B.buildFAbs(S32, Trunc, Flags); } MachineInstrBuilder K0, K1; if (SrcLT == S64) { K0 = B.buildFConstant(S64, BitsToDouble(UINT64_C(/*2^-32*/ 0x3df0000000000000))); K1 = B.buildFConstant(S64, BitsToDouble(UINT64_C(/*-2^32*/ 0xc1f0000000000000))); } else { K0 = B.buildFConstant(S32, BitsToFloat(UINT32_C(/*2^-32*/ 0x2f800000))); K1 = B.buildFConstant(S32, BitsToFloat(UINT32_C(/*-2^32*/ 0xcf800000))); } auto Mul = B.buildFMul(SrcLT, Trunc, K0, Flags); auto FloorMul = B.buildFFloor(SrcLT, Mul, Flags); auto Fma = B.buildFMA(SrcLT, FloorMul, K1, Trunc, Flags); auto Hi = (Signed && SrcLT == S64) ? B.buildFPTOSI(S32, FloorMul) : B.buildFPTOUI(S32, FloorMul); auto Lo = B.buildFPTOUI(S32, Fma); if (Signed && SrcLT == S32) { // Flip the result based on the signedness, which is either all 0s or 1s. Sign = B.buildMerge(S64, {Sign, Sign}); // r := xor({lo, hi}, sign) - sign; B.buildSub(Dst, B.buildXor(S64, B.buildMerge(S64, {Lo, Hi}), Sign), Sign); } else B.buildMerge(Dst, {Lo, Hi}); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeMinNumMaxNum(LegalizerHelper &Helper, MachineInstr &MI) const { MachineFunction &MF = Helper.MIRBuilder.getMF(); const SIMachineFunctionInfo *MFI = MF.getInfo(); const bool IsIEEEOp = MI.getOpcode() == AMDGPU::G_FMINNUM_IEEE || MI.getOpcode() == AMDGPU::G_FMAXNUM_IEEE; // With ieee_mode disabled, the instructions have the correct behavior // already for G_FMINNUM/G_FMAXNUM if (!MFI->getMode().IEEE) return !IsIEEEOp; if (IsIEEEOp) return true; return Helper.lowerFMinNumMaxNum(MI) == LegalizerHelper::Legalized; } bool AMDGPULegalizerInfo::legalizeExtractVectorElt( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { // TODO: Should move some of this into LegalizerHelper. // TODO: Promote dynamic indexing of s16 to s32 // FIXME: Artifact combiner probably should have replaced the truncated // constant before this, so we shouldn't need // getIConstantVRegValWithLookThrough. Optional MaybeIdxVal = getIConstantVRegValWithLookThrough(MI.getOperand(2).getReg(), MRI); if (!MaybeIdxVal) // Dynamic case will be selected to register indexing. return true; const int64_t IdxVal = MaybeIdxVal->Value.getSExtValue(); Register Dst = MI.getOperand(0).getReg(); Register Vec = MI.getOperand(1).getReg(); LLT VecTy = MRI.getType(Vec); LLT EltTy = VecTy.getElementType(); assert(EltTy == MRI.getType(Dst)); if (IdxVal < VecTy.getNumElements()) { auto Unmerge = B.buildUnmerge(EltTy, Vec); B.buildCopy(Dst, Unmerge.getReg(IdxVal)); } else { B.buildUndef(Dst); } MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeInsertVectorElt( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { // TODO: Should move some of this into LegalizerHelper. // TODO: Promote dynamic indexing of s16 to s32 // FIXME: Artifact combiner probably should have replaced the truncated // constant before this, so we shouldn't need // getIConstantVRegValWithLookThrough. Optional MaybeIdxVal = getIConstantVRegValWithLookThrough(MI.getOperand(3).getReg(), MRI); if (!MaybeIdxVal) // Dynamic case will be selected to register indexing. return true; int64_t IdxVal = MaybeIdxVal->Value.getSExtValue(); Register Dst = MI.getOperand(0).getReg(); Register Vec = MI.getOperand(1).getReg(); Register Ins = MI.getOperand(2).getReg(); LLT VecTy = MRI.getType(Vec); LLT EltTy = VecTy.getElementType(); assert(EltTy == MRI.getType(Ins)); (void)Ins; unsigned NumElts = VecTy.getNumElements(); if (IdxVal < NumElts) { SmallVector SrcRegs; for (unsigned i = 0; i < NumElts; ++i) SrcRegs.push_back(MRI.createGenericVirtualRegister(EltTy)); B.buildUnmerge(SrcRegs, Vec); SrcRegs[IdxVal] = MI.getOperand(2).getReg(); B.buildMerge(Dst, SrcRegs); } else { B.buildUndef(Dst); } MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeShuffleVector( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { const LLT V2S16 = LLT::fixed_vector(2, 16); Register Dst = MI.getOperand(0).getReg(); Register Src0 = MI.getOperand(1).getReg(); LLT DstTy = MRI.getType(Dst); LLT SrcTy = MRI.getType(Src0); if (SrcTy == V2S16 && DstTy == V2S16 && AMDGPU::isLegalVOP3PShuffleMask(MI.getOperand(3).getShuffleMask())) return true; MachineIRBuilder HelperBuilder(MI); GISelObserverWrapper DummyObserver; LegalizerHelper Helper(B.getMF(), DummyObserver, HelperBuilder); return Helper.lowerShuffleVector(MI) == LegalizerHelper::Legalized; } bool AMDGPULegalizerInfo::legalizeSinCos( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register DstReg = MI.getOperand(0).getReg(); Register SrcReg = MI.getOperand(1).getReg(); LLT Ty = MRI.getType(DstReg); unsigned Flags = MI.getFlags(); Register TrigVal; auto OneOver2Pi = B.buildFConstant(Ty, 0.5 * numbers::inv_pi); if (ST.hasTrigReducedRange()) { auto MulVal = B.buildFMul(Ty, SrcReg, OneOver2Pi, Flags); TrigVal = B.buildIntrinsic(Intrinsic::amdgcn_fract, {Ty}, false) .addUse(MulVal.getReg(0)) .setMIFlags(Flags).getReg(0); } else TrigVal = B.buildFMul(Ty, SrcReg, OneOver2Pi, Flags).getReg(0); Intrinsic::ID TrigIntrin = MI.getOpcode() == AMDGPU::G_FSIN ? Intrinsic::amdgcn_sin : Intrinsic::amdgcn_cos; B.buildIntrinsic(TrigIntrin, makeArrayRef(DstReg), false) .addUse(TrigVal) .setMIFlags(Flags); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::buildPCRelGlobalAddress(Register DstReg, LLT PtrTy, MachineIRBuilder &B, const GlobalValue *GV, int64_t Offset, unsigned GAFlags) const { assert(isInt<32>(Offset + 4) && "32-bit offset is expected!"); // In order to support pc-relative addressing, SI_PC_ADD_REL_OFFSET is lowered // to the following code sequence: // // For constant address space: // s_getpc_b64 s[0:1] // s_add_u32 s0, s0, $symbol // s_addc_u32 s1, s1, 0 // // s_getpc_b64 returns the address of the s_add_u32 instruction and then // a fixup or relocation is emitted to replace $symbol with a literal // constant, which is a pc-relative offset from the encoding of the $symbol // operand to the global variable. // // For global address space: // s_getpc_b64 s[0:1] // s_add_u32 s0, s0, $symbol@{gotpc}rel32@lo // s_addc_u32 s1, s1, $symbol@{gotpc}rel32@hi // // s_getpc_b64 returns the address of the s_add_u32 instruction and then // fixups or relocations are emitted to replace $symbol@*@lo and // $symbol@*@hi with lower 32 bits and higher 32 bits of a literal constant, // which is a 64-bit pc-relative offset from the encoding of the $symbol // operand to the global variable. // // What we want here is an offset from the value returned by s_getpc // (which is the address of the s_add_u32 instruction) to the global // variable, but since the encoding of $symbol starts 4 bytes after the start // of the s_add_u32 instruction, we end up with an offset that is 4 bytes too // small. This requires us to add 4 to the global variable offset in order to // compute the correct address. Similarly for the s_addc_u32 instruction, the // encoding of $symbol starts 12 bytes after the start of the s_add_u32 // instruction. LLT ConstPtrTy = LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64); Register PCReg = PtrTy.getSizeInBits() != 32 ? DstReg : B.getMRI()->createGenericVirtualRegister(ConstPtrTy); MachineInstrBuilder MIB = B.buildInstr(AMDGPU::SI_PC_ADD_REL_OFFSET) .addDef(PCReg); MIB.addGlobalAddress(GV, Offset + 4, GAFlags); if (GAFlags == SIInstrInfo::MO_NONE) MIB.addImm(0); else MIB.addGlobalAddress(GV, Offset + 12, GAFlags + 1); B.getMRI()->setRegClass(PCReg, &AMDGPU::SReg_64RegClass); if (PtrTy.getSizeInBits() == 32) B.buildExtract(DstReg, PCReg, 0); return true; } bool AMDGPULegalizerInfo::legalizeGlobalValue( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register DstReg = MI.getOperand(0).getReg(); LLT Ty = MRI.getType(DstReg); unsigned AS = Ty.getAddressSpace(); const GlobalValue *GV = MI.getOperand(1).getGlobal(); MachineFunction &MF = B.getMF(); SIMachineFunctionInfo *MFI = MF.getInfo(); if (AS == AMDGPUAS::LOCAL_ADDRESS || AS == AMDGPUAS::REGION_ADDRESS) { if (!MFI->isModuleEntryFunction() && !GV->getName().equals("llvm.amdgcn.module.lds")) { const Function &Fn = MF.getFunction(); DiagnosticInfoUnsupported BadLDSDecl( Fn, "local memory global used by non-kernel function", MI.getDebugLoc(), DS_Warning); Fn.getContext().diagnose(BadLDSDecl); // We currently don't have a way to correctly allocate LDS objects that // aren't directly associated with a kernel. We do force inlining of // functions that use local objects. However, if these dead functions are // not eliminated, we don't want a compile time error. Just emit a warning // and a trap, since there should be no callable path here. B.buildIntrinsic(Intrinsic::trap, ArrayRef(), true); B.buildUndef(DstReg); MI.eraseFromParent(); return true; } // TODO: We could emit code to handle the initialization somewhere. // We ignore the initializer for now and legalize it to allow selection. // The initializer will anyway get errored out during assembly emission. const SITargetLowering *TLI = ST.getTargetLowering(); if (!TLI->shouldUseLDSConstAddress(GV)) { MI.getOperand(1).setTargetFlags(SIInstrInfo::MO_ABS32_LO); return true; // Leave in place; } if (AS == AMDGPUAS::LOCAL_ADDRESS && GV->hasExternalLinkage()) { Type *Ty = GV->getValueType(); // HIP uses an unsized array `extern __shared__ T s[]` or similar // zero-sized type in other languages to declare the dynamic shared // memory which size is not known at the compile time. They will be // allocated by the runtime and placed directly after the static // allocated ones. They all share the same offset. if (B.getDataLayout().getTypeAllocSize(Ty).isZero()) { // Adjust alignment for that dynamic shared memory array. MFI->setDynLDSAlign(B.getDataLayout(), *cast(GV)); LLT S32 = LLT::scalar(32); auto Sz = B.buildIntrinsic(Intrinsic::amdgcn_groupstaticsize, {S32}, false); B.buildIntToPtr(DstReg, Sz); MI.eraseFromParent(); return true; } } B.buildConstant(DstReg, MFI->allocateLDSGlobal(B.getDataLayout(), *cast(GV))); MI.eraseFromParent(); return true; } const SITargetLowering *TLI = ST.getTargetLowering(); if (TLI->shouldEmitFixup(GV)) { buildPCRelGlobalAddress(DstReg, Ty, B, GV, 0); MI.eraseFromParent(); return true; } if (TLI->shouldEmitPCReloc(GV)) { buildPCRelGlobalAddress(DstReg, Ty, B, GV, 0, SIInstrInfo::MO_REL32); MI.eraseFromParent(); return true; } LLT PtrTy = LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64); Register GOTAddr = MRI.createGenericVirtualRegister(PtrTy); LLT LoadTy = Ty.getSizeInBits() == 32 ? PtrTy : Ty; MachineMemOperand *GOTMMO = MF.getMachineMemOperand( MachinePointerInfo::getGOT(MF), MachineMemOperand::MOLoad | MachineMemOperand::MODereferenceable | MachineMemOperand::MOInvariant, LoadTy, Align(8)); buildPCRelGlobalAddress(GOTAddr, PtrTy, B, GV, 0, SIInstrInfo::MO_GOTPCREL32); if (Ty.getSizeInBits() == 32) { // Truncate if this is a 32-bit constant address. auto Load = B.buildLoad(PtrTy, GOTAddr, *GOTMMO); B.buildExtract(DstReg, Load, 0); } else B.buildLoad(DstReg, GOTAddr, *GOTMMO); MI.eraseFromParent(); return true; } static LLT widenToNextPowerOf2(LLT Ty) { if (Ty.isVector()) return Ty.changeElementCount( ElementCount::getFixed(PowerOf2Ceil(Ty.getNumElements()))); return LLT::scalar(PowerOf2Ceil(Ty.getSizeInBits())); } bool AMDGPULegalizerInfo::legalizeLoad(LegalizerHelper &Helper, MachineInstr &MI) const { MachineIRBuilder &B = Helper.MIRBuilder; MachineRegisterInfo &MRI = *B.getMRI(); GISelChangeObserver &Observer = Helper.Observer; Register PtrReg = MI.getOperand(1).getReg(); LLT PtrTy = MRI.getType(PtrReg); unsigned AddrSpace = PtrTy.getAddressSpace(); if (AddrSpace == AMDGPUAS::CONSTANT_ADDRESS_32BIT) { LLT ConstPtr = LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64); auto Cast = B.buildAddrSpaceCast(ConstPtr, PtrReg); Observer.changingInstr(MI); MI.getOperand(1).setReg(Cast.getReg(0)); Observer.changedInstr(MI); return true; } if (MI.getOpcode() != AMDGPU::G_LOAD) return false; Register ValReg = MI.getOperand(0).getReg(); LLT ValTy = MRI.getType(ValReg); MachineMemOperand *MMO = *MI.memoperands_begin(); const unsigned ValSize = ValTy.getSizeInBits(); const LLT MemTy = MMO->getMemoryType(); const Align MemAlign = MMO->getAlign(); const unsigned MemSize = MemTy.getSizeInBits(); const uint64_t AlignInBits = 8 * MemAlign.value(); // Widen non-power-of-2 loads to the alignment if needed if (shouldWidenLoad(ST, MemTy, AlignInBits, AddrSpace, MI.getOpcode())) { const unsigned WideMemSize = PowerOf2Ceil(MemSize); // This was already the correct extending load result type, so just adjust // the memory type. if (WideMemSize == ValSize) { MachineFunction &MF = B.getMF(); MachineMemOperand *WideMMO = MF.getMachineMemOperand(MMO, 0, WideMemSize / 8); Observer.changingInstr(MI); MI.setMemRefs(MF, {WideMMO}); Observer.changedInstr(MI); return true; } // Don't bother handling edge case that should probably never be produced. if (ValSize > WideMemSize) return false; LLT WideTy = widenToNextPowerOf2(ValTy); Register WideLoad; if (!WideTy.isVector()) { WideLoad = B.buildLoadFromOffset(WideTy, PtrReg, *MMO, 0).getReg(0); B.buildTrunc(ValReg, WideLoad).getReg(0); } else { // Extract the subvector. if (isRegisterType(ValTy)) { // If this a case where G_EXTRACT is legal, use it. // (e.g. <3 x s32> -> <4 x s32>) WideLoad = B.buildLoadFromOffset(WideTy, PtrReg, *MMO, 0).getReg(0); B.buildExtract(ValReg, WideLoad, 0); } else { // For cases where the widened type isn't a nice register value, unmerge // from a widened register (e.g. <3 x s16> -> <4 x s16>) WideLoad = B.buildLoadFromOffset(WideTy, PtrReg, *MMO, 0).getReg(0); B.buildDeleteTrailingVectorElements(ValReg, WideLoad); } } MI.eraseFromParent(); return true; } return false; } bool AMDGPULegalizerInfo::legalizeFMad( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { LLT Ty = MRI.getType(MI.getOperand(0).getReg()); assert(Ty.isScalar()); MachineFunction &MF = B.getMF(); const SIMachineFunctionInfo *MFI = MF.getInfo(); // TODO: Always legal with future ftz flag. // FIXME: Do we need just output? if (Ty == LLT::scalar(32) && !MFI->getMode().allFP32Denormals()) return true; if (Ty == LLT::scalar(16) && !MFI->getMode().allFP64FP16Denormals()) return true; MachineIRBuilder HelperBuilder(MI); GISelObserverWrapper DummyObserver; LegalizerHelper Helper(MF, DummyObserver, HelperBuilder); return Helper.lowerFMad(MI) == LegalizerHelper::Legalized; } bool AMDGPULegalizerInfo::legalizeAtomicCmpXChg( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register DstReg = MI.getOperand(0).getReg(); Register PtrReg = MI.getOperand(1).getReg(); Register CmpVal = MI.getOperand(2).getReg(); Register NewVal = MI.getOperand(3).getReg(); assert(AMDGPU::isFlatGlobalAddrSpace(MRI.getType(PtrReg).getAddressSpace()) && "this should not have been custom lowered"); LLT ValTy = MRI.getType(CmpVal); LLT VecTy = LLT::fixed_vector(2, ValTy); Register PackedVal = B.buildBuildVector(VecTy, { NewVal, CmpVal }).getReg(0); B.buildInstr(AMDGPU::G_AMDGPU_ATOMIC_CMPXCHG) .addDef(DstReg) .addUse(PtrReg) .addUse(PackedVal) .setMemRefs(MI.memoperands()); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFlog( MachineInstr &MI, MachineIRBuilder &B, double Log2BaseInverted) const { Register Dst = MI.getOperand(0).getReg(); Register Src = MI.getOperand(1).getReg(); LLT Ty = B.getMRI()->getType(Dst); unsigned Flags = MI.getFlags(); auto Log2Operand = B.buildFLog2(Ty, Src, Flags); auto Log2BaseInvertedOperand = B.buildFConstant(Ty, Log2BaseInverted); B.buildFMul(Dst, Log2Operand, Log2BaseInvertedOperand, Flags); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFExp(MachineInstr &MI, MachineIRBuilder &B) const { Register Dst = MI.getOperand(0).getReg(); Register Src = MI.getOperand(1).getReg(); unsigned Flags = MI.getFlags(); LLT Ty = B.getMRI()->getType(Dst); auto K = B.buildFConstant(Ty, numbers::log2e); auto Mul = B.buildFMul(Ty, Src, K, Flags); B.buildFExp2(Dst, Mul, Flags); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFPow(MachineInstr &MI, MachineIRBuilder &B) const { Register Dst = MI.getOperand(0).getReg(); Register Src0 = MI.getOperand(1).getReg(); Register Src1 = MI.getOperand(2).getReg(); unsigned Flags = MI.getFlags(); LLT Ty = B.getMRI()->getType(Dst); const LLT S16 = LLT::scalar(16); const LLT S32 = LLT::scalar(32); if (Ty == S32) { auto Log = B.buildFLog2(S32, Src0, Flags); auto Mul = B.buildIntrinsic(Intrinsic::amdgcn_fmul_legacy, {S32}, false) .addUse(Log.getReg(0)) .addUse(Src1) .setMIFlags(Flags); B.buildFExp2(Dst, Mul, Flags); } else if (Ty == S16) { // There's no f16 fmul_legacy, so we need to convert for it. auto Log = B.buildFLog2(S16, Src0, Flags); auto Ext0 = B.buildFPExt(S32, Log, Flags); auto Ext1 = B.buildFPExt(S32, Src1, Flags); auto Mul = B.buildIntrinsic(Intrinsic::amdgcn_fmul_legacy, {S32}, false) .addUse(Ext0.getReg(0)) .addUse(Ext1.getReg(0)) .setMIFlags(Flags); B.buildFExp2(Dst, B.buildFPTrunc(S16, Mul), Flags); } else return false; MI.eraseFromParent(); return true; } // Find a source register, ignoring any possible source modifiers. static Register stripAnySourceMods(Register OrigSrc, MachineRegisterInfo &MRI) { Register ModSrc = OrigSrc; if (MachineInstr *SrcFNeg = getOpcodeDef(AMDGPU::G_FNEG, ModSrc, MRI)) { ModSrc = SrcFNeg->getOperand(1).getReg(); if (MachineInstr *SrcFAbs = getOpcodeDef(AMDGPU::G_FABS, ModSrc, MRI)) ModSrc = SrcFAbs->getOperand(1).getReg(); } else if (MachineInstr *SrcFAbs = getOpcodeDef(AMDGPU::G_FABS, ModSrc, MRI)) ModSrc = SrcFAbs->getOperand(1).getReg(); return ModSrc; } bool AMDGPULegalizerInfo::legalizeFFloor(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { const LLT S1 = LLT::scalar(1); const LLT S64 = LLT::scalar(64); Register Dst = MI.getOperand(0).getReg(); Register OrigSrc = MI.getOperand(1).getReg(); unsigned Flags = MI.getFlags(); assert(ST.hasFractBug() && MRI.getType(Dst) == S64 && "this should not have been custom lowered"); // V_FRACT is buggy on SI, so the F32 version is never used and (x-floor(x)) // is used instead. However, SI doesn't have V_FLOOR_F64, so the most // efficient way to implement it is using V_FRACT_F64. The workaround for the // V_FRACT bug is: // fract(x) = isnan(x) ? x : min(V_FRACT(x), 0.99999999999999999) // // Convert floor(x) to (x - fract(x)) auto Fract = B.buildIntrinsic(Intrinsic::amdgcn_fract, {S64}, false) .addUse(OrigSrc) .setMIFlags(Flags); // Give source modifier matching some assistance before obscuring a foldable // pattern. // TODO: We can avoid the neg on the fract? The input sign to fract // shouldn't matter? Register ModSrc = stripAnySourceMods(OrigSrc, MRI); auto Const = B.buildFConstant(S64, BitsToDouble(0x3fefffffffffffff)); Register Min = MRI.createGenericVirtualRegister(S64); // We don't need to concern ourselves with the snan handling difference, so // use the one which will directly select. const SIMachineFunctionInfo *MFI = B.getMF().getInfo(); if (MFI->getMode().IEEE) B.buildFMinNumIEEE(Min, Fract, Const, Flags); else B.buildFMinNum(Min, Fract, Const, Flags); Register CorrectedFract = Min; if (!MI.getFlag(MachineInstr::FmNoNans)) { auto IsNan = B.buildFCmp(CmpInst::FCMP_ORD, S1, ModSrc, ModSrc, Flags); CorrectedFract = B.buildSelect(S64, IsNan, ModSrc, Min, Flags).getReg(0); } auto NegFract = B.buildFNeg(S64, CorrectedFract, Flags); B.buildFAdd(Dst, OrigSrc, NegFract, Flags); MI.eraseFromParent(); return true; } // Turn an illegal packed v2s16 build vector into bit operations. // TODO: This should probably be a bitcast action in LegalizerHelper. bool AMDGPULegalizerInfo::legalizeBuildVector( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register Dst = MI.getOperand(0).getReg(); const LLT S32 = LLT::scalar(32); assert(MRI.getType(Dst) == LLT::fixed_vector(2, 16)); Register Src0 = MI.getOperand(1).getReg(); Register Src1 = MI.getOperand(2).getReg(); assert(MRI.getType(Src0) == LLT::scalar(16)); auto Merge = B.buildMerge(S32, {Src0, Src1}); B.buildBitcast(Dst, Merge); MI.eraseFromParent(); return true; } // Build a big integer multiply or multiply-add using MAD_64_32 instructions. // // Source and accumulation registers must all be 32-bits. // // TODO: When the multiply is uniform, we should produce a code sequence // that is better suited to instruction selection on the SALU. Instead of // the outer loop going over parts of the result, the outer loop should go // over parts of one of the factors. This should result in instruction // selection that makes full use of S_ADDC_U32 instructions. void AMDGPULegalizerInfo::buildMultiply( LegalizerHelper &Helper, MutableArrayRef Accum, ArrayRef Src0, ArrayRef Src1, bool UsePartialMad64_32, bool SeparateOddAlignedProducts) const { // Use (possibly empty) vectors of S1 registers to represent the set of // carries from one pair of positions to the next. using Carry = SmallVector; MachineIRBuilder &B = Helper.MIRBuilder; const LLT S1 = LLT::scalar(1); const LLT S32 = LLT::scalar(32); const LLT S64 = LLT::scalar(64); Register Zero32; Register Zero64; auto getZero32 = [&]() -> Register { if (!Zero32) Zero32 = B.buildConstant(S32, 0).getReg(0); return Zero32; }; auto getZero64 = [&]() -> Register { if (!Zero64) Zero64 = B.buildConstant(S64, 0).getReg(0); return Zero64; }; // Merge the given carries into the 32-bit LocalAccum, which is modified // in-place. // // Returns the carry-out, which is a single S1 register or null. auto mergeCarry = [&](Register &LocalAccum, const Carry &CarryIn) -> Register { if (CarryIn.empty()) return Register(); bool HaveCarryOut = true; Register CarryAccum; if (CarryIn.size() == 1) { if (!LocalAccum) { LocalAccum = B.buildZExt(S32, CarryIn[0]).getReg(0); return Register(); } CarryAccum = getZero32(); } else { CarryAccum = B.buildZExt(S32, CarryIn[0]).getReg(0); for (unsigned i = 1; i + 1 < CarryIn.size(); ++i) { CarryAccum = B.buildUAdde(S32, S1, CarryAccum, getZero32(), CarryIn[i]) .getReg(0); } if (!LocalAccum) { LocalAccum = getZero32(); HaveCarryOut = false; } } auto Add = B.buildUAdde(S32, S1, CarryAccum, LocalAccum, CarryIn.back()); LocalAccum = Add.getReg(0); return HaveCarryOut ? Add.getReg(1) : Register(); }; // Build a multiply-add chain to compute // // LocalAccum + (partial products at DstIndex) // + (opportunistic subset of CarryIn) // // LocalAccum is an array of one or two 32-bit registers that are updated // in-place. The incoming registers may be null. // // In some edge cases, carry-ins can be consumed "for free". In that case, // the consumed carry bits are removed from CarryIn in-place. auto buildMadChain = [&](MutableArrayRef LocalAccum, unsigned DstIndex, Carry &CarryIn) -> Carry { assert((DstIndex + 1 < Accum.size() && LocalAccum.size() == 2) || (DstIndex + 1 >= Accum.size() && LocalAccum.size() == 1)); Carry CarryOut; unsigned j0 = 0; // Use plain 32-bit multiplication for the most significant part of the // result by default. if (LocalAccum.size() == 1 && (!UsePartialMad64_32 || !CarryIn.empty())) { do { unsigned j1 = DstIndex - j0; auto Mul = B.buildMul(S32, Src0[j0], Src1[j1]); if (!LocalAccum[0]) { LocalAccum[0] = Mul.getReg(0); } else { if (CarryIn.empty()) { LocalAccum[0] = B.buildAdd(S32, LocalAccum[0], Mul).getReg(0); } else { LocalAccum[0] = B.buildUAdde(S32, S1, LocalAccum[0], Mul, CarryIn.back()) .getReg(0); CarryIn.pop_back(); } } ++j0; } while (j0 <= DstIndex && (!UsePartialMad64_32 || !CarryIn.empty())); } // Build full 64-bit multiplies. if (j0 <= DstIndex) { bool HaveSmallAccum = false; Register Tmp; if (LocalAccum[0]) { if (LocalAccum.size() == 1) { Tmp = B.buildAnyExt(S64, LocalAccum[0]).getReg(0); HaveSmallAccum = true; } else if (LocalAccum[1]) { Tmp = B.buildMerge(S64, LocalAccum).getReg(0); HaveSmallAccum = false; } else { Tmp = B.buildZExt(S64, LocalAccum[0]).getReg(0); HaveSmallAccum = true; } } else { assert(LocalAccum.size() == 1 || !LocalAccum[1]); Tmp = getZero64(); HaveSmallAccum = true; } do { unsigned j1 = DstIndex - j0; auto Mad = B.buildInstr(AMDGPU::G_AMDGPU_MAD_U64_U32, {S64, S1}, {Src0[j0], Src1[j1], Tmp}); Tmp = Mad.getReg(0); if (!HaveSmallAccum) CarryOut.push_back(Mad.getReg(1)); HaveSmallAccum = false; ++j0; } while (j0 <= DstIndex); auto Unmerge = B.buildUnmerge(S32, Tmp); LocalAccum[0] = Unmerge.getReg(0); if (LocalAccum.size() > 1) LocalAccum[1] = Unmerge.getReg(1); } return CarryOut; }; // Outer multiply loop, iterating over destination parts from least // significant to most significant parts. // // The columns of the following diagram correspond to the destination parts // affected by one iteration of the outer loop (ignoring boundary // conditions). // // Dest index relative to 2 * i: 1 0 -1 // ------ // Carries from previous iteration: e o // Even-aligned partial product sum: E E . // Odd-aligned partial product sum: O O // // 'o' is OddCarry, 'e' is EvenCarry. // EE and OO are computed from partial products via buildMadChain and use // accumulation where possible and appropriate. // Register SeparateOddCarry; Carry EvenCarry; Carry OddCarry; for (unsigned i = 0; i <= Accum.size() / 2; ++i) { Carry OddCarryIn = std::move(OddCarry); Carry EvenCarryIn = std::move(EvenCarry); OddCarry.clear(); EvenCarry.clear(); // Partial products at offset 2 * i. if (2 * i < Accum.size()) { auto LocalAccum = Accum.drop_front(2 * i).take_front(2); EvenCarry = buildMadChain(LocalAccum, 2 * i, EvenCarryIn); } // Partial products at offset 2 * i - 1. if (i > 0) { if (!SeparateOddAlignedProducts) { auto LocalAccum = Accum.drop_front(2 * i - 1).take_front(2); OddCarry = buildMadChain(LocalAccum, 2 * i - 1, OddCarryIn); } else { bool IsHighest = 2 * i >= Accum.size(); Register SeparateOddOut[2]; auto LocalAccum = makeMutableArrayRef(SeparateOddOut) .take_front(IsHighest ? 1 : 2); OddCarry = buildMadChain(LocalAccum, 2 * i - 1, OddCarryIn); MachineInstr *Lo; if (i == 1) { if (!IsHighest) Lo = B.buildUAddo(S32, S1, Accum[2 * i - 1], SeparateOddOut[0]); else Lo = B.buildAdd(S32, Accum[2 * i - 1], SeparateOddOut[0]); } else { Lo = B.buildUAdde(S32, S1, Accum[2 * i - 1], SeparateOddOut[0], SeparateOddCarry); } Accum[2 * i - 1] = Lo->getOperand(0).getReg(); if (!IsHighest) { auto Hi = B.buildUAdde(S32, S1, Accum[2 * i], SeparateOddOut[1], Lo->getOperand(1).getReg()); Accum[2 * i] = Hi.getReg(0); SeparateOddCarry = Hi.getReg(1); } } } // Add in the carries from the previous iteration if (i > 0) { if (Register CarryOut = mergeCarry(Accum[2 * i - 1], OddCarryIn)) EvenCarryIn.push_back(CarryOut); if (2 * i < Accum.size()) { if (Register CarryOut = mergeCarry(Accum[2 * i], EvenCarryIn)) OddCarry.push_back(CarryOut); } } } } // Custom narrowing of wide multiplies using wide multiply-add instructions. // // TODO: If the multiply is followed by an addition, we should attempt to // integrate it to make better use of V_MAD_U64_U32's multiply-add capabilities. bool AMDGPULegalizerInfo::legalizeMul(LegalizerHelper &Helper, MachineInstr &MI) const { assert(ST.hasMad64_32()); assert(MI.getOpcode() == TargetOpcode::G_MUL); MachineIRBuilder &B = Helper.MIRBuilder; MachineRegisterInfo &MRI = *B.getMRI(); Register DstReg = MI.getOperand(0).getReg(); Register Src0 = MI.getOperand(1).getReg(); Register Src1 = MI.getOperand(2).getReg(); LLT Ty = MRI.getType(DstReg); assert(Ty.isScalar()); unsigned Size = Ty.getSizeInBits(); unsigned NumParts = Size / 32; assert((Size % 32) == 0); assert(NumParts >= 2); // Whether to use MAD_64_32 for partial products whose high half is // discarded. This avoids some ADD instructions but risks false dependency // stalls on some subtargets in some cases. const bool UsePartialMad64_32 = ST.getGeneration() < AMDGPUSubtarget::GFX10; // Whether to compute odd-aligned partial products separately. This is // advisable on subtargets where the accumulator of MAD_64_32 must be placed // in an even-aligned VGPR. const bool SeparateOddAlignedProducts = ST.hasFullRate64Ops(); LLT S32 = LLT::scalar(32); SmallVector Src0Parts, Src1Parts; for (unsigned i = 0; i < NumParts; ++i) { Src0Parts.push_back(MRI.createGenericVirtualRegister(S32)); Src1Parts.push_back(MRI.createGenericVirtualRegister(S32)); } B.buildUnmerge(Src0Parts, Src0); B.buildUnmerge(Src1Parts, Src1); SmallVector AccumRegs(NumParts); buildMultiply(Helper, AccumRegs, Src0Parts, Src1Parts, UsePartialMad64_32, SeparateOddAlignedProducts); B.buildMerge(DstReg, AccumRegs); MI.eraseFromParent(); return true; } // Legalize ctlz/cttz to ffbh/ffbl instead of the default legalization to // ctlz/cttz_zero_undef. This allows us to fix up the result for the zero input // case with a single min instruction instead of a compare+select. bool AMDGPULegalizerInfo::legalizeCTLZ_CTTZ(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register Dst = MI.getOperand(0).getReg(); Register Src = MI.getOperand(1).getReg(); LLT DstTy = MRI.getType(Dst); LLT SrcTy = MRI.getType(Src); unsigned NewOpc = MI.getOpcode() == AMDGPU::G_CTLZ ? AMDGPU::G_AMDGPU_FFBH_U32 : AMDGPU::G_AMDGPU_FFBL_B32; auto Tmp = B.buildInstr(NewOpc, {DstTy}, {Src}); B.buildUMin(Dst, Tmp, B.buildConstant(DstTy, SrcTy.getSizeInBits())); MI.eraseFromParent(); return true; } // Check that this is a G_XOR x, -1 static bool isNot(const MachineRegisterInfo &MRI, const MachineInstr &MI) { if (MI.getOpcode() != TargetOpcode::G_XOR) return false; auto ConstVal = getIConstantVRegSExtVal(MI.getOperand(2).getReg(), MRI); return ConstVal && *ConstVal == -1; } // Return the use branch instruction, otherwise null if the usage is invalid. static MachineInstr * verifyCFIntrinsic(MachineInstr &MI, MachineRegisterInfo &MRI, MachineInstr *&Br, MachineBasicBlock *&UncondBrTarget, bool &Negated) { Register CondDef = MI.getOperand(0).getReg(); if (!MRI.hasOneNonDBGUse(CondDef)) return nullptr; MachineBasicBlock *Parent = MI.getParent(); MachineInstr *UseMI = &*MRI.use_instr_nodbg_begin(CondDef); if (isNot(MRI, *UseMI)) { Register NegatedCond = UseMI->getOperand(0).getReg(); if (!MRI.hasOneNonDBGUse(NegatedCond)) return nullptr; // We're deleting the def of this value, so we need to remove it. eraseInstr(*UseMI, MRI); UseMI = &*MRI.use_instr_nodbg_begin(NegatedCond); Negated = true; } if (UseMI->getParent() != Parent || UseMI->getOpcode() != AMDGPU::G_BRCOND) return nullptr; // Make sure the cond br is followed by a G_BR, or is the last instruction. MachineBasicBlock::iterator Next = std::next(UseMI->getIterator()); if (Next == Parent->end()) { MachineFunction::iterator NextMBB = std::next(Parent->getIterator()); if (NextMBB == Parent->getParent()->end()) // Illegal intrinsic use. return nullptr; UncondBrTarget = &*NextMBB; } else { if (Next->getOpcode() != AMDGPU::G_BR) return nullptr; Br = &*Next; UncondBrTarget = Br->getOperand(0).getMBB(); } return UseMI; } bool AMDGPULegalizerInfo::loadInputValue(Register DstReg, MachineIRBuilder &B, const ArgDescriptor *Arg, const TargetRegisterClass *ArgRC, LLT ArgTy) const { MCRegister SrcReg = Arg->getRegister(); assert(Register::isPhysicalRegister(SrcReg) && "Physical register expected"); assert(DstReg.isVirtual() && "Virtual register expected"); Register LiveIn = getFunctionLiveInPhysReg(B.getMF(), B.getTII(), SrcReg, *ArgRC, B.getDebugLoc(), ArgTy); if (Arg->isMasked()) { // TODO: Should we try to emit this once in the entry block? const LLT S32 = LLT::scalar(32); const unsigned Mask = Arg->getMask(); const unsigned Shift = countTrailingZeros(Mask); Register AndMaskSrc = LiveIn; // TODO: Avoid clearing the high bits if we know workitem id y/z are always // 0. if (Shift != 0) { auto ShiftAmt = B.buildConstant(S32, Shift); AndMaskSrc = B.buildLShr(S32, LiveIn, ShiftAmt).getReg(0); } B.buildAnd(DstReg, AndMaskSrc, B.buildConstant(S32, Mask >> Shift)); } else { B.buildCopy(DstReg, LiveIn); } return true; } bool AMDGPULegalizerInfo::loadInputValue( Register DstReg, MachineIRBuilder &B, AMDGPUFunctionArgInfo::PreloadedValue ArgType) const { const SIMachineFunctionInfo *MFI = B.getMF().getInfo(); const ArgDescriptor *Arg; const TargetRegisterClass *ArgRC; LLT ArgTy; std::tie(Arg, ArgRC, ArgTy) = MFI->getPreloadedValue(ArgType); if (!Arg) { if (ArgType == AMDGPUFunctionArgInfo::KERNARG_SEGMENT_PTR) { // The intrinsic may appear when we have a 0 sized kernarg segment, in which // case the pointer argument may be missing and we use null. B.buildConstant(DstReg, 0); return true; } // It's undefined behavior if a function marked with the amdgpu-no-* // attributes uses the corresponding intrinsic. B.buildUndef(DstReg); return true; } if (!Arg->isRegister() || !Arg->getRegister().isValid()) return false; // TODO: Handle these return loadInputValue(DstReg, B, Arg, ArgRC, ArgTy); } bool AMDGPULegalizerInfo::legalizePreloadedArgIntrin( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B, AMDGPUFunctionArgInfo::PreloadedValue ArgType) const { if (!loadInputValue(MI.getOperand(0).getReg(), B, ArgType)) return false; MI.eraseFromParent(); return true; } static bool replaceWithConstant(MachineIRBuilder &B, MachineInstr &MI, int64_t C) { B.buildConstant(MI.getOperand(0).getReg(), C); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeWorkitemIDIntrinsic( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B, unsigned Dim, AMDGPUFunctionArgInfo::PreloadedValue ArgType) const { unsigned MaxID = ST.getMaxWorkitemID(B.getMF().getFunction(), Dim); if (MaxID == 0) return replaceWithConstant(B, MI, 0); const SIMachineFunctionInfo *MFI = B.getMF().getInfo(); const ArgDescriptor *Arg; const TargetRegisterClass *ArgRC; LLT ArgTy; std::tie(Arg, ArgRC, ArgTy) = MFI->getPreloadedValue(ArgType); Register DstReg = MI.getOperand(0).getReg(); if (!Arg) { // It's undefined behavior if a function marked with the amdgpu-no-* // attributes uses the corresponding intrinsic. B.buildUndef(DstReg); MI.eraseFromParent(); return true; } if (Arg->isMasked()) { // Don't bother inserting AssertZext for packed IDs since we're emitting the // masking operations anyway. // // TODO: We could assert the top bit is 0 for the source copy. if (!loadInputValue(DstReg, B, ArgType)) return false; } else { Register TmpReg = MRI.createGenericVirtualRegister(LLT::scalar(32)); if (!loadInputValue(TmpReg, B, ArgType)) return false; B.buildAssertZExt(DstReg, TmpReg, 32 - countLeadingZeros(MaxID)); } MI.eraseFromParent(); return true; } Register AMDGPULegalizerInfo::getKernargParameterPtr(MachineIRBuilder &B, int64_t Offset) const { LLT PtrTy = LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64); Register KernArgReg = B.getMRI()->createGenericVirtualRegister(PtrTy); // TODO: If we passed in the base kernel offset we could have a better // alignment than 4, but we don't really need it. if (!loadInputValue(KernArgReg, B, AMDGPUFunctionArgInfo::KERNARG_SEGMENT_PTR)) llvm_unreachable("failed to find kernarg segment ptr"); auto COffset = B.buildConstant(LLT::scalar(64), Offset); // TODO: Should get nuw return B.buildPtrAdd(PtrTy, KernArgReg, COffset).getReg(0); } /// Legalize a value that's loaded from kernel arguments. This is only used by /// legacy intrinsics. bool AMDGPULegalizerInfo::legalizeKernargMemParameter(MachineInstr &MI, MachineIRBuilder &B, uint64_t Offset, Align Alignment) const { Register DstReg = MI.getOperand(0).getReg(); assert(B.getMRI()->getType(DstReg) == LLT::scalar(32) && "unexpected kernarg parameter type"); Register Ptr = getKernargParameterPtr(B, Offset); MachinePointerInfo PtrInfo(AMDGPUAS::CONSTANT_ADDRESS); B.buildLoad(DstReg, Ptr, PtrInfo, Align(4), MachineMemOperand::MODereferenceable | MachineMemOperand::MOInvariant); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFDIV(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register Dst = MI.getOperand(0).getReg(); LLT DstTy = MRI.getType(Dst); LLT S16 = LLT::scalar(16); LLT S32 = LLT::scalar(32); LLT S64 = LLT::scalar(64); if (DstTy == S16) return legalizeFDIV16(MI, MRI, B); if (DstTy == S32) return legalizeFDIV32(MI, MRI, B); if (DstTy == S64) return legalizeFDIV64(MI, MRI, B); return false; } void AMDGPULegalizerInfo::legalizeUnsignedDIV_REM32Impl(MachineIRBuilder &B, Register DstDivReg, Register DstRemReg, Register X, Register Y) const { const LLT S1 = LLT::scalar(1); const LLT S32 = LLT::scalar(32); // See AMDGPUCodeGenPrepare::expandDivRem32 for a description of the // algorithm used here. // Initial estimate of inv(y). auto FloatY = B.buildUITOFP(S32, Y); auto RcpIFlag = B.buildInstr(AMDGPU::G_AMDGPU_RCP_IFLAG, {S32}, {FloatY}); auto Scale = B.buildFConstant(S32, BitsToFloat(0x4f7ffffe)); auto ScaledY = B.buildFMul(S32, RcpIFlag, Scale); auto Z = B.buildFPTOUI(S32, ScaledY); // One round of UNR. auto NegY = B.buildSub(S32, B.buildConstant(S32, 0), Y); auto NegYZ = B.buildMul(S32, NegY, Z); Z = B.buildAdd(S32, Z, B.buildUMulH(S32, Z, NegYZ)); // Quotient/remainder estimate. auto Q = B.buildUMulH(S32, X, Z); auto R = B.buildSub(S32, X, B.buildMul(S32, Q, Y)); // First quotient/remainder refinement. auto One = B.buildConstant(S32, 1); auto Cond = B.buildICmp(CmpInst::ICMP_UGE, S1, R, Y); if (DstDivReg) Q = B.buildSelect(S32, Cond, B.buildAdd(S32, Q, One), Q); R = B.buildSelect(S32, Cond, B.buildSub(S32, R, Y), R); // Second quotient/remainder refinement. Cond = B.buildICmp(CmpInst::ICMP_UGE, S1, R, Y); if (DstDivReg) B.buildSelect(DstDivReg, Cond, B.buildAdd(S32, Q, One), Q); if (DstRemReg) B.buildSelect(DstRemReg, Cond, B.buildSub(S32, R, Y), R); } // Build integer reciprocal sequence around V_RCP_IFLAG_F32 // // Return lo, hi of result // // %cvt.lo = G_UITOFP Val.lo // %cvt.hi = G_UITOFP Val.hi // %mad = G_FMAD %cvt.hi, 2**32, %cvt.lo // %rcp = G_AMDGPU_RCP_IFLAG %mad // %mul1 = G_FMUL %rcp, 0x5f7ffffc // %mul2 = G_FMUL %mul1, 2**(-32) // %trunc = G_INTRINSIC_TRUNC %mul2 // %mad2 = G_FMAD %trunc, -(2**32), %mul1 // return {G_FPTOUI %mad2, G_FPTOUI %trunc} static std::pair emitReciprocalU64(MachineIRBuilder &B, Register Val) { const LLT S32 = LLT::scalar(32); auto Unmerge = B.buildUnmerge(S32, Val); auto CvtLo = B.buildUITOFP(S32, Unmerge.getReg(0)); auto CvtHi = B.buildUITOFP(S32, Unmerge.getReg(1)); auto Mad = B.buildFMAD(S32, CvtHi, // 2**32 B.buildFConstant(S32, BitsToFloat(0x4f800000)), CvtLo); auto Rcp = B.buildInstr(AMDGPU::G_AMDGPU_RCP_IFLAG, {S32}, {Mad}); auto Mul1 = B.buildFMul(S32, Rcp, B.buildFConstant(S32, BitsToFloat(0x5f7ffffc))); // 2**(-32) auto Mul2 = B.buildFMul(S32, Mul1, B.buildFConstant(S32, BitsToFloat(0x2f800000))); auto Trunc = B.buildIntrinsicTrunc(S32, Mul2); // -(2**32) auto Mad2 = B.buildFMAD(S32, Trunc, B.buildFConstant(S32, BitsToFloat(0xcf800000)), Mul1); auto ResultLo = B.buildFPTOUI(S32, Mad2); auto ResultHi = B.buildFPTOUI(S32, Trunc); return {ResultLo.getReg(0), ResultHi.getReg(0)}; } void AMDGPULegalizerInfo::legalizeUnsignedDIV_REM64Impl(MachineIRBuilder &B, Register DstDivReg, Register DstRemReg, Register Numer, Register Denom) const { const LLT S32 = LLT::scalar(32); const LLT S64 = LLT::scalar(64); const LLT S1 = LLT::scalar(1); Register RcpLo, RcpHi; std::tie(RcpLo, RcpHi) = emitReciprocalU64(B, Denom); auto Rcp = B.buildMerge(S64, {RcpLo, RcpHi}); auto Zero64 = B.buildConstant(S64, 0); auto NegDenom = B.buildSub(S64, Zero64, Denom); auto MulLo1 = B.buildMul(S64, NegDenom, Rcp); auto MulHi1 = B.buildUMulH(S64, Rcp, MulLo1); auto UnmergeMulHi1 = B.buildUnmerge(S32, MulHi1); Register MulHi1_Lo = UnmergeMulHi1.getReg(0); Register MulHi1_Hi = UnmergeMulHi1.getReg(1); auto Add1_Lo = B.buildUAddo(S32, S1, RcpLo, MulHi1_Lo); auto Add1_Hi = B.buildUAdde(S32, S1, RcpHi, MulHi1_Hi, Add1_Lo.getReg(1)); auto Add1 = B.buildMerge(S64, {Add1_Lo, Add1_Hi}); auto MulLo2 = B.buildMul(S64, NegDenom, Add1); auto MulHi2 = B.buildUMulH(S64, Add1, MulLo2); auto UnmergeMulHi2 = B.buildUnmerge(S32, MulHi2); Register MulHi2_Lo = UnmergeMulHi2.getReg(0); Register MulHi2_Hi = UnmergeMulHi2.getReg(1); auto Zero32 = B.buildConstant(S32, 0); auto Add2_Lo = B.buildUAddo(S32, S1, Add1_Lo, MulHi2_Lo); auto Add2_Hi = B.buildUAdde(S32, S1, Add1_Hi, MulHi2_Hi, Add2_Lo.getReg(1)); auto Add2 = B.buildMerge(S64, {Add2_Lo, Add2_Hi}); auto UnmergeNumer = B.buildUnmerge(S32, Numer); Register NumerLo = UnmergeNumer.getReg(0); Register NumerHi = UnmergeNumer.getReg(1); auto MulHi3 = B.buildUMulH(S64, Numer, Add2); auto Mul3 = B.buildMul(S64, Denom, MulHi3); auto UnmergeMul3 = B.buildUnmerge(S32, Mul3); Register Mul3_Lo = UnmergeMul3.getReg(0); Register Mul3_Hi = UnmergeMul3.getReg(1); auto Sub1_Lo = B.buildUSubo(S32, S1, NumerLo, Mul3_Lo); auto Sub1_Hi = B.buildUSube(S32, S1, NumerHi, Mul3_Hi, Sub1_Lo.getReg(1)); auto Sub1_Mi = B.buildSub(S32, NumerHi, Mul3_Hi); auto Sub1 = B.buildMerge(S64, {Sub1_Lo, Sub1_Hi}); auto UnmergeDenom = B.buildUnmerge(S32, Denom); Register DenomLo = UnmergeDenom.getReg(0); Register DenomHi = UnmergeDenom.getReg(1); auto CmpHi = B.buildICmp(CmpInst::ICMP_UGE, S1, Sub1_Hi, DenomHi); auto C1 = B.buildSExt(S32, CmpHi); auto CmpLo = B.buildICmp(CmpInst::ICMP_UGE, S1, Sub1_Lo, DenomLo); auto C2 = B.buildSExt(S32, CmpLo); auto CmpEq = B.buildICmp(CmpInst::ICMP_EQ, S1, Sub1_Hi, DenomHi); auto C3 = B.buildSelect(S32, CmpEq, C2, C1); // TODO: Here and below portions of the code can be enclosed into if/endif. // Currently control flow is unconditional and we have 4 selects after // potential endif to substitute PHIs. // if C3 != 0 ... auto Sub2_Lo = B.buildUSubo(S32, S1, Sub1_Lo, DenomLo); auto Sub2_Mi = B.buildUSube(S32, S1, Sub1_Mi, DenomHi, Sub1_Lo.getReg(1)); auto Sub2_Hi = B.buildUSube(S32, S1, Sub2_Mi, Zero32, Sub2_Lo.getReg(1)); auto Sub2 = B.buildMerge(S64, {Sub2_Lo, Sub2_Hi}); auto One64 = B.buildConstant(S64, 1); auto Add3 = B.buildAdd(S64, MulHi3, One64); auto C4 = B.buildSExt(S32, B.buildICmp(CmpInst::ICMP_UGE, S1, Sub2_Hi, DenomHi)); auto C5 = B.buildSExt(S32, B.buildICmp(CmpInst::ICMP_UGE, S1, Sub2_Lo, DenomLo)); auto C6 = B.buildSelect( S32, B.buildICmp(CmpInst::ICMP_EQ, S1, Sub2_Hi, DenomHi), C5, C4); // if (C6 != 0) auto Add4 = B.buildAdd(S64, Add3, One64); auto Sub3_Lo = B.buildUSubo(S32, S1, Sub2_Lo, DenomLo); auto Sub3_Mi = B.buildUSube(S32, S1, Sub2_Mi, DenomHi, Sub2_Lo.getReg(1)); auto Sub3_Hi = B.buildUSube(S32, S1, Sub3_Mi, Zero32, Sub3_Lo.getReg(1)); auto Sub3 = B.buildMerge(S64, {Sub3_Lo, Sub3_Hi}); // endif C6 // endif C3 if (DstDivReg) { auto Sel1 = B.buildSelect( S64, B.buildICmp(CmpInst::ICMP_NE, S1, C6, Zero32), Add4, Add3); B.buildSelect(DstDivReg, B.buildICmp(CmpInst::ICMP_NE, S1, C3, Zero32), Sel1, MulHi3); } if (DstRemReg) { auto Sel2 = B.buildSelect( S64, B.buildICmp(CmpInst::ICMP_NE, S1, C6, Zero32), Sub3, Sub2); B.buildSelect(DstRemReg, B.buildICmp(CmpInst::ICMP_NE, S1, C3, Zero32), Sel2, Sub1); } } bool AMDGPULegalizerInfo::legalizeUnsignedDIV_REM(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register DstDivReg, DstRemReg; switch (MI.getOpcode()) { default: llvm_unreachable("Unexpected opcode!"); case AMDGPU::G_UDIV: { DstDivReg = MI.getOperand(0).getReg(); break; } case AMDGPU::G_UREM: { DstRemReg = MI.getOperand(0).getReg(); break; } case AMDGPU::G_UDIVREM: { DstDivReg = MI.getOperand(0).getReg(); DstRemReg = MI.getOperand(1).getReg(); break; } } const LLT S64 = LLT::scalar(64); const LLT S32 = LLT::scalar(32); const unsigned FirstSrcOpIdx = MI.getNumExplicitDefs(); Register Num = MI.getOperand(FirstSrcOpIdx).getReg(); Register Den = MI.getOperand(FirstSrcOpIdx + 1).getReg(); LLT Ty = MRI.getType(MI.getOperand(0).getReg()); if (Ty == S32) legalizeUnsignedDIV_REM32Impl(B, DstDivReg, DstRemReg, Num, Den); else if (Ty == S64) legalizeUnsignedDIV_REM64Impl(B, DstDivReg, DstRemReg, Num, Den); else return false; MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeSignedDIV_REM(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { const LLT S64 = LLT::scalar(64); const LLT S32 = LLT::scalar(32); LLT Ty = MRI.getType(MI.getOperand(0).getReg()); if (Ty != S32 && Ty != S64) return false; const unsigned FirstSrcOpIdx = MI.getNumExplicitDefs(); Register LHS = MI.getOperand(FirstSrcOpIdx).getReg(); Register RHS = MI.getOperand(FirstSrcOpIdx + 1).getReg(); auto SignBitOffset = B.buildConstant(S32, Ty.getSizeInBits() - 1); auto LHSign = B.buildAShr(Ty, LHS, SignBitOffset); auto RHSign = B.buildAShr(Ty, RHS, SignBitOffset); LHS = B.buildAdd(Ty, LHS, LHSign).getReg(0); RHS = B.buildAdd(Ty, RHS, RHSign).getReg(0); LHS = B.buildXor(Ty, LHS, LHSign).getReg(0); RHS = B.buildXor(Ty, RHS, RHSign).getReg(0); Register DstDivReg, DstRemReg, TmpDivReg, TmpRemReg; switch (MI.getOpcode()) { default: llvm_unreachable("Unexpected opcode!"); case AMDGPU::G_SDIV: { DstDivReg = MI.getOperand(0).getReg(); TmpDivReg = MRI.createGenericVirtualRegister(Ty); break; } case AMDGPU::G_SREM: { DstRemReg = MI.getOperand(0).getReg(); TmpRemReg = MRI.createGenericVirtualRegister(Ty); break; } case AMDGPU::G_SDIVREM: { DstDivReg = MI.getOperand(0).getReg(); DstRemReg = MI.getOperand(1).getReg(); TmpDivReg = MRI.createGenericVirtualRegister(Ty); TmpRemReg = MRI.createGenericVirtualRegister(Ty); break; } } if (Ty == S32) legalizeUnsignedDIV_REM32Impl(B, TmpDivReg, TmpRemReg, LHS, RHS); else legalizeUnsignedDIV_REM64Impl(B, TmpDivReg, TmpRemReg, LHS, RHS); if (DstDivReg) { auto Sign = B.buildXor(Ty, LHSign, RHSign).getReg(0); auto SignXor = B.buildXor(Ty, TmpDivReg, Sign).getReg(0); B.buildSub(DstDivReg, SignXor, Sign); } if (DstRemReg) { auto Sign = LHSign.getReg(0); // Remainder sign is the same as LHS auto SignXor = B.buildXor(Ty, TmpRemReg, Sign).getReg(0); B.buildSub(DstRemReg, SignXor, Sign); } MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFastUnsafeFDIV(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register Res = MI.getOperand(0).getReg(); Register LHS = MI.getOperand(1).getReg(); Register RHS = MI.getOperand(2).getReg(); uint16_t Flags = MI.getFlags(); LLT ResTy = MRI.getType(Res); const MachineFunction &MF = B.getMF(); bool AllowInaccurateRcp = MF.getTarget().Options.UnsafeFPMath || MI.getFlag(MachineInstr::FmAfn); if (!AllowInaccurateRcp) return false; if (auto CLHS = getConstantFPVRegVal(LHS, MRI)) { // 1 / x -> RCP(x) if (CLHS->isExactlyValue(1.0)) { B.buildIntrinsic(Intrinsic::amdgcn_rcp, Res, false) .addUse(RHS) .setMIFlags(Flags); MI.eraseFromParent(); return true; } // -1 / x -> RCP( FNEG(x) ) if (CLHS->isExactlyValue(-1.0)) { auto FNeg = B.buildFNeg(ResTy, RHS, Flags); B.buildIntrinsic(Intrinsic::amdgcn_rcp, Res, false) .addUse(FNeg.getReg(0)) .setMIFlags(Flags); MI.eraseFromParent(); return true; } } // x / y -> x * (1.0 / y) auto RCP = B.buildIntrinsic(Intrinsic::amdgcn_rcp, {ResTy}, false) .addUse(RHS) .setMIFlags(Flags); B.buildFMul(Res, LHS, RCP, Flags); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFastUnsafeFDIV64(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register Res = MI.getOperand(0).getReg(); Register X = MI.getOperand(1).getReg(); Register Y = MI.getOperand(2).getReg(); uint16_t Flags = MI.getFlags(); LLT ResTy = MRI.getType(Res); const MachineFunction &MF = B.getMF(); bool AllowInaccurateRcp = MF.getTarget().Options.UnsafeFPMath || MI.getFlag(MachineInstr::FmAfn); if (!AllowInaccurateRcp) return false; auto NegY = B.buildFNeg(ResTy, Y); auto One = B.buildFConstant(ResTy, 1.0); auto R = B.buildIntrinsic(Intrinsic::amdgcn_rcp, {ResTy}, false) .addUse(Y) .setMIFlags(Flags); auto Tmp0 = B.buildFMA(ResTy, NegY, R, One); R = B.buildFMA(ResTy, Tmp0, R, R); auto Tmp1 = B.buildFMA(ResTy, NegY, R, One); R = B.buildFMA(ResTy, Tmp1, R, R); auto Ret = B.buildFMul(ResTy, X, R); auto Tmp2 = B.buildFMA(ResTy, NegY, Ret, X); B.buildFMA(Res, Tmp2, R, Ret); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFDIV16(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { if (legalizeFastUnsafeFDIV(MI, MRI, B)) return true; Register Res = MI.getOperand(0).getReg(); Register LHS = MI.getOperand(1).getReg(); Register RHS = MI.getOperand(2).getReg(); uint16_t Flags = MI.getFlags(); LLT S16 = LLT::scalar(16); LLT S32 = LLT::scalar(32); auto LHSExt = B.buildFPExt(S32, LHS, Flags); auto RHSExt = B.buildFPExt(S32, RHS, Flags); auto RCP = B.buildIntrinsic(Intrinsic::amdgcn_rcp, {S32}, false) .addUse(RHSExt.getReg(0)) .setMIFlags(Flags); auto QUOT = B.buildFMul(S32, LHSExt, RCP, Flags); auto RDst = B.buildFPTrunc(S16, QUOT, Flags); B.buildIntrinsic(Intrinsic::amdgcn_div_fixup, Res, false) .addUse(RDst.getReg(0)) .addUse(RHS) .addUse(LHS) .setMIFlags(Flags); MI.eraseFromParent(); return true; } // Enable or disable FP32 denorm mode. When 'Enable' is true, emit instructions // to enable denorm mode. When 'Enable' is false, disable denorm mode. static void toggleSPDenormMode(bool Enable, MachineIRBuilder &B, const GCNSubtarget &ST, AMDGPU::SIModeRegisterDefaults Mode) { // Set SP denorm mode to this value. unsigned SPDenormMode = Enable ? FP_DENORM_FLUSH_NONE : Mode.fpDenormModeSPValue(); if (ST.hasDenormModeInst()) { // Preserve default FP64FP16 denorm mode while updating FP32 mode. uint32_t DPDenormModeDefault = Mode.fpDenormModeDPValue(); uint32_t NewDenormModeValue = SPDenormMode | (DPDenormModeDefault << 2); B.buildInstr(AMDGPU::S_DENORM_MODE) .addImm(NewDenormModeValue); } else { // Select FP32 bit field in mode register. unsigned SPDenormModeBitField = AMDGPU::Hwreg::ID_MODE | (4 << AMDGPU::Hwreg::OFFSET_SHIFT_) | (1 << AMDGPU::Hwreg::WIDTH_M1_SHIFT_); B.buildInstr(AMDGPU::S_SETREG_IMM32_B32) .addImm(SPDenormMode) .addImm(SPDenormModeBitField); } } bool AMDGPULegalizerInfo::legalizeFDIV32(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { if (legalizeFastUnsafeFDIV(MI, MRI, B)) return true; Register Res = MI.getOperand(0).getReg(); Register LHS = MI.getOperand(1).getReg(); Register RHS = MI.getOperand(2).getReg(); const SIMachineFunctionInfo *MFI = B.getMF().getInfo(); AMDGPU::SIModeRegisterDefaults Mode = MFI->getMode(); uint16_t Flags = MI.getFlags(); LLT S32 = LLT::scalar(32); LLT S1 = LLT::scalar(1); auto One = B.buildFConstant(S32, 1.0f); auto DenominatorScaled = B.buildIntrinsic(Intrinsic::amdgcn_div_scale, {S32, S1}, false) .addUse(LHS) .addUse(RHS) .addImm(0) .setMIFlags(Flags); auto NumeratorScaled = B.buildIntrinsic(Intrinsic::amdgcn_div_scale, {S32, S1}, false) .addUse(LHS) .addUse(RHS) .addImm(1) .setMIFlags(Flags); auto ApproxRcp = B.buildIntrinsic(Intrinsic::amdgcn_rcp, {S32}, false) .addUse(DenominatorScaled.getReg(0)) .setMIFlags(Flags); auto NegDivScale0 = B.buildFNeg(S32, DenominatorScaled, Flags); // FIXME: Doesn't correctly model the FP mode switch, and the FP operations // aren't modeled as reading it. if (!Mode.allFP32Denormals()) toggleSPDenormMode(true, B, ST, Mode); auto Fma0 = B.buildFMA(S32, NegDivScale0, ApproxRcp, One, Flags); auto Fma1 = B.buildFMA(S32, Fma0, ApproxRcp, ApproxRcp, Flags); auto Mul = B.buildFMul(S32, NumeratorScaled, Fma1, Flags); auto Fma2 = B.buildFMA(S32, NegDivScale0, Mul, NumeratorScaled, Flags); auto Fma3 = B.buildFMA(S32, Fma2, Fma1, Mul, Flags); auto Fma4 = B.buildFMA(S32, NegDivScale0, Fma3, NumeratorScaled, Flags); if (!Mode.allFP32Denormals()) toggleSPDenormMode(false, B, ST, Mode); auto Fmas = B.buildIntrinsic(Intrinsic::amdgcn_div_fmas, {S32}, false) .addUse(Fma4.getReg(0)) .addUse(Fma1.getReg(0)) .addUse(Fma3.getReg(0)) .addUse(NumeratorScaled.getReg(1)) .setMIFlags(Flags); B.buildIntrinsic(Intrinsic::amdgcn_div_fixup, Res, false) .addUse(Fmas.getReg(0)) .addUse(RHS) .addUse(LHS) .setMIFlags(Flags); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFDIV64(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { if (legalizeFastUnsafeFDIV64(MI, MRI, B)) return true; Register Res = MI.getOperand(0).getReg(); Register LHS = MI.getOperand(1).getReg(); Register RHS = MI.getOperand(2).getReg(); uint16_t Flags = MI.getFlags(); LLT S64 = LLT::scalar(64); LLT S1 = LLT::scalar(1); auto One = B.buildFConstant(S64, 1.0); auto DivScale0 = B.buildIntrinsic(Intrinsic::amdgcn_div_scale, {S64, S1}, false) .addUse(LHS) .addUse(RHS) .addImm(0) .setMIFlags(Flags); auto NegDivScale0 = B.buildFNeg(S64, DivScale0.getReg(0), Flags); auto Rcp = B.buildIntrinsic(Intrinsic::amdgcn_rcp, {S64}, false) .addUse(DivScale0.getReg(0)) .setMIFlags(Flags); auto Fma0 = B.buildFMA(S64, NegDivScale0, Rcp, One, Flags); auto Fma1 = B.buildFMA(S64, Rcp, Fma0, Rcp, Flags); auto Fma2 = B.buildFMA(S64, NegDivScale0, Fma1, One, Flags); auto DivScale1 = B.buildIntrinsic(Intrinsic::amdgcn_div_scale, {S64, S1}, false) .addUse(LHS) .addUse(RHS) .addImm(1) .setMIFlags(Flags); auto Fma3 = B.buildFMA(S64, Fma1, Fma2, Fma1, Flags); auto Mul = B.buildFMul(S64, DivScale1.getReg(0), Fma3, Flags); auto Fma4 = B.buildFMA(S64, NegDivScale0, Mul, DivScale1.getReg(0), Flags); Register Scale; if (!ST.hasUsableDivScaleConditionOutput()) { // Workaround a hardware bug on SI where the condition output from div_scale // is not usable. LLT S32 = LLT::scalar(32); auto NumUnmerge = B.buildUnmerge(S32, LHS); auto DenUnmerge = B.buildUnmerge(S32, RHS); auto Scale0Unmerge = B.buildUnmerge(S32, DivScale0); auto Scale1Unmerge = B.buildUnmerge(S32, DivScale1); auto CmpNum = B.buildICmp(ICmpInst::ICMP_EQ, S1, NumUnmerge.getReg(1), Scale1Unmerge.getReg(1)); auto CmpDen = B.buildICmp(ICmpInst::ICMP_EQ, S1, DenUnmerge.getReg(1), Scale0Unmerge.getReg(1)); Scale = B.buildXor(S1, CmpNum, CmpDen).getReg(0); } else { Scale = DivScale1.getReg(1); } auto Fmas = B.buildIntrinsic(Intrinsic::amdgcn_div_fmas, {S64}, false) .addUse(Fma4.getReg(0)) .addUse(Fma3.getReg(0)) .addUse(Mul.getReg(0)) .addUse(Scale) .setMIFlags(Flags); B.buildIntrinsic(Intrinsic::amdgcn_div_fixup, makeArrayRef(Res), false) .addUse(Fmas.getReg(0)) .addUse(RHS) .addUse(LHS) .setMIFlags(Flags); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFDIVFastIntrin(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Register Res = MI.getOperand(0).getReg(); Register LHS = MI.getOperand(2).getReg(); Register RHS = MI.getOperand(3).getReg(); uint16_t Flags = MI.getFlags(); LLT S32 = LLT::scalar(32); LLT S1 = LLT::scalar(1); auto Abs = B.buildFAbs(S32, RHS, Flags); const APFloat C0Val(1.0f); auto C0 = B.buildConstant(S32, 0x6f800000); auto C1 = B.buildConstant(S32, 0x2f800000); auto C2 = B.buildConstant(S32, FloatToBits(1.0f)); auto CmpRes = B.buildFCmp(CmpInst::FCMP_OGT, S1, Abs, C0, Flags); auto Sel = B.buildSelect(S32, CmpRes, C1, C2, Flags); auto Mul0 = B.buildFMul(S32, RHS, Sel, Flags); auto RCP = B.buildIntrinsic(Intrinsic::amdgcn_rcp, {S32}, false) .addUse(Mul0.getReg(0)) .setMIFlags(Flags); auto Mul1 = B.buildFMul(S32, LHS, RCP, Flags); B.buildFMul(Res, Sel, Mul1, Flags); MI.eraseFromParent(); return true; } // Expand llvm.amdgcn.rsq.clamp on targets that don't support the instruction. // FIXME: Why do we handle this one but not other removed instructions? // // Reciprocal square root. The clamp prevents infinite results, clamping // infinities to max_float. D.f = 1.0 / sqrt(S0.f), result clamped to // +-max_float. bool AMDGPULegalizerInfo::legalizeRsqClampIntrinsic(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { if (ST.getGeneration() < AMDGPUSubtarget::VOLCANIC_ISLANDS) return true; Register Dst = MI.getOperand(0).getReg(); Register Src = MI.getOperand(2).getReg(); auto Flags = MI.getFlags(); LLT Ty = MRI.getType(Dst); const fltSemantics *FltSemantics; if (Ty == LLT::scalar(32)) FltSemantics = &APFloat::IEEEsingle(); else if (Ty == LLT::scalar(64)) FltSemantics = &APFloat::IEEEdouble(); else return false; auto Rsq = B.buildIntrinsic(Intrinsic::amdgcn_rsq, {Ty}, false) .addUse(Src) .setMIFlags(Flags); // We don't need to concern ourselves with the snan handling difference, since // the rsq quieted (or not) so use the one which will directly select. const SIMachineFunctionInfo *MFI = B.getMF().getInfo(); const bool UseIEEE = MFI->getMode().IEEE; auto MaxFlt = B.buildFConstant(Ty, APFloat::getLargest(*FltSemantics)); auto ClampMax = UseIEEE ? B.buildFMinNumIEEE(Ty, Rsq, MaxFlt, Flags) : B.buildFMinNum(Ty, Rsq, MaxFlt, Flags); auto MinFlt = B.buildFConstant(Ty, APFloat::getLargest(*FltSemantics, true)); if (UseIEEE) B.buildFMaxNumIEEE(Dst, ClampMax, MinFlt, Flags); else B.buildFMaxNum(Dst, ClampMax, MinFlt, Flags); MI.eraseFromParent(); return true; } static unsigned getDSFPAtomicOpcode(Intrinsic::ID IID) { switch (IID) { case Intrinsic::amdgcn_ds_fadd: return AMDGPU::G_ATOMICRMW_FADD; case Intrinsic::amdgcn_ds_fmin: return AMDGPU::G_AMDGPU_ATOMIC_FMIN; case Intrinsic::amdgcn_ds_fmax: return AMDGPU::G_AMDGPU_ATOMIC_FMAX; default: llvm_unreachable("not a DS FP intrinsic"); } } bool AMDGPULegalizerInfo::legalizeDSAtomicFPIntrinsic(LegalizerHelper &Helper, MachineInstr &MI, Intrinsic::ID IID) const { GISelChangeObserver &Observer = Helper.Observer; Observer.changingInstr(MI); MI.setDesc(ST.getInstrInfo()->get(getDSFPAtomicOpcode(IID))); // The remaining operands were used to set fields in the MemOperand on // construction. for (int I = 6; I > 3; --I) MI.removeOperand(I); MI.removeOperand(1); // Remove the intrinsic ID. Observer.changedInstr(MI); return true; } bool AMDGPULegalizerInfo::getImplicitArgPtr(Register DstReg, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { uint64_t Offset = ST.getTargetLowering()->getImplicitParameterOffset( B.getMF(), AMDGPUTargetLowering::FIRST_IMPLICIT); LLT DstTy = MRI.getType(DstReg); LLT IdxTy = LLT::scalar(DstTy.getSizeInBits()); Register KernargPtrReg = MRI.createGenericVirtualRegister(DstTy); if (!loadInputValue(KernargPtrReg, B, AMDGPUFunctionArgInfo::KERNARG_SEGMENT_PTR)) return false; // FIXME: This should be nuw B.buildPtrAdd(DstReg, KernargPtrReg, B.buildConstant(IdxTy, Offset).getReg(0)); return true; } bool AMDGPULegalizerInfo::legalizeImplicitArgPtr(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { const SIMachineFunctionInfo *MFI = B.getMF().getInfo(); if (!MFI->isEntryFunction()) { return legalizePreloadedArgIntrin(MI, MRI, B, AMDGPUFunctionArgInfo::IMPLICIT_ARG_PTR); } Register DstReg = MI.getOperand(0).getReg(); if (!getImplicitArgPtr(DstReg, MRI, B)) return false; MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::getLDSKernelId(Register DstReg, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { Function &F = B.getMF().getFunction(); Optional KnownSize = AMDGPUMachineFunction::getLDSKernelIdMetadata(F); if (KnownSize.has_value()) B.buildConstant(DstReg, KnownSize.value()); return false; } bool AMDGPULegalizerInfo::legalizeLDSKernelId(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { const SIMachineFunctionInfo *MFI = B.getMF().getInfo(); if (!MFI->isEntryFunction()) { return legalizePreloadedArgIntrin(MI, MRI, B, AMDGPUFunctionArgInfo::LDS_KERNEL_ID); } Register DstReg = MI.getOperand(0).getReg(); if (!getLDSKernelId(DstReg, MRI, B)) return false; MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeIsAddrSpace(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B, unsigned AddrSpace) const { Register ApertureReg = getSegmentAperture(AddrSpace, MRI, B); auto Unmerge = B.buildUnmerge(LLT::scalar(32), MI.getOperand(2).getReg()); Register Hi32 = Unmerge.getReg(1); B.buildICmp(ICmpInst::ICMP_EQ, MI.getOperand(0), Hi32, ApertureReg); MI.eraseFromParent(); return true; } // The raw.(t)buffer and struct.(t)buffer intrinsics have two offset args: // offset (the offset that is included in bounds checking and swizzling, to be // split between the instruction's voffset and immoffset fields) and soffset // (the offset that is excluded from bounds checking and swizzling, to go in // the instruction's soffset field). This function takes the first kind of // offset and figures out how to split it between voffset and immoffset. std::pair AMDGPULegalizerInfo::splitBufferOffsets(MachineIRBuilder &B, Register OrigOffset) const { const unsigned MaxImm = 4095; Register BaseReg; unsigned ImmOffset; const LLT S32 = LLT::scalar(32); MachineRegisterInfo &MRI = *B.getMRI(); std::tie(BaseReg, ImmOffset) = AMDGPU::getBaseWithConstantOffset(MRI, OrigOffset); // If BaseReg is a pointer, convert it to int. if (MRI.getType(BaseReg).isPointer()) BaseReg = B.buildPtrToInt(MRI.getType(OrigOffset), BaseReg).getReg(0); // If the immediate value is too big for the immoffset field, put the value // and -4096 into the immoffset field so that the value that is copied/added // for the voffset field is a multiple of 4096, and it stands more chance // of being CSEd with the copy/add for another similar load/store. // However, do not do that rounding down to a multiple of 4096 if that is a // negative number, as it appears to be illegal to have a negative offset // in the vgpr, even if adding the immediate offset makes it positive. unsigned Overflow = ImmOffset & ~MaxImm; ImmOffset -= Overflow; if ((int32_t)Overflow < 0) { Overflow += ImmOffset; ImmOffset = 0; } if (Overflow != 0) { if (!BaseReg) { BaseReg = B.buildConstant(S32, Overflow).getReg(0); } else { auto OverflowVal = B.buildConstant(S32, Overflow); BaseReg = B.buildAdd(S32, BaseReg, OverflowVal).getReg(0); } } if (!BaseReg) BaseReg = B.buildConstant(S32, 0).getReg(0); return std::make_pair(BaseReg, ImmOffset); } /// Update \p MMO based on the offset inputs to a raw/struct buffer intrinsic. void AMDGPULegalizerInfo::updateBufferMMO(MachineMemOperand *MMO, Register VOffset, Register SOffset, unsigned ImmOffset, Register VIndex, MachineRegisterInfo &MRI) const { Optional MaybeVOffsetVal = getIConstantVRegValWithLookThrough(VOffset, MRI); Optional MaybeSOffsetVal = getIConstantVRegValWithLookThrough(SOffset, MRI); Optional MaybeVIndexVal = getIConstantVRegValWithLookThrough(VIndex, MRI); // If the combined VOffset + SOffset + ImmOffset + strided VIndex is constant, // update the MMO with that offset. The stride is unknown so we can only do // this if VIndex is constant 0. if (MaybeVOffsetVal && MaybeSOffsetVal && MaybeVIndexVal && MaybeVIndexVal->Value == 0) { uint64_t TotalOffset = MaybeVOffsetVal->Value.getZExtValue() + MaybeSOffsetVal->Value.getZExtValue() + ImmOffset; MMO->setOffset(TotalOffset); } else { // We don't have a constant combined offset to use in the MMO. Give up. MMO->setValue((Value *)nullptr); } } /// Handle register layout difference for f16 images for some subtargets. Register AMDGPULegalizerInfo::handleD16VData(MachineIRBuilder &B, MachineRegisterInfo &MRI, Register Reg, bool ImageStore) const { const LLT S16 = LLT::scalar(16); const LLT S32 = LLT::scalar(32); LLT StoreVT = MRI.getType(Reg); assert(StoreVT.isVector() && StoreVT.getElementType() == S16); if (ST.hasUnpackedD16VMem()) { auto Unmerge = B.buildUnmerge(S16, Reg); SmallVector WideRegs; for (int I = 0, E = Unmerge->getNumOperands() - 1; I != E; ++I) WideRegs.push_back(B.buildAnyExt(S32, Unmerge.getReg(I)).getReg(0)); int NumElts = StoreVT.getNumElements(); return B.buildBuildVector(LLT::fixed_vector(NumElts, S32), WideRegs) .getReg(0); } if (ImageStore && ST.hasImageStoreD16Bug()) { if (StoreVT.getNumElements() == 2) { SmallVector PackedRegs; Reg = B.buildBitcast(S32, Reg).getReg(0); PackedRegs.push_back(Reg); PackedRegs.resize(2, B.buildUndef(S32).getReg(0)); return B.buildBuildVector(LLT::fixed_vector(2, S32), PackedRegs) .getReg(0); } if (StoreVT.getNumElements() == 3) { SmallVector PackedRegs; auto Unmerge = B.buildUnmerge(S16, Reg); for (int I = 0, E = Unmerge->getNumOperands() - 1; I != E; ++I) PackedRegs.push_back(Unmerge.getReg(I)); PackedRegs.resize(6, B.buildUndef(S16).getReg(0)); Reg = B.buildBuildVector(LLT::fixed_vector(6, S16), PackedRegs).getReg(0); return B.buildBitcast(LLT::fixed_vector(3, S32), Reg).getReg(0); } if (StoreVT.getNumElements() == 4) { SmallVector PackedRegs; Reg = B.buildBitcast(LLT::fixed_vector(2, S32), Reg).getReg(0); auto Unmerge = B.buildUnmerge(S32, Reg); for (int I = 0, E = Unmerge->getNumOperands() - 1; I != E; ++I) PackedRegs.push_back(Unmerge.getReg(I)); PackedRegs.resize(4, B.buildUndef(S32).getReg(0)); return B.buildBuildVector(LLT::fixed_vector(4, S32), PackedRegs) .getReg(0); } llvm_unreachable("invalid data type"); } if (StoreVT == LLT::fixed_vector(3, S16)) { Reg = B.buildPadVectorWithUndefElements(LLT::fixed_vector(4, S16), Reg) .getReg(0); } return Reg; } Register AMDGPULegalizerInfo::fixStoreSourceType( MachineIRBuilder &B, Register VData, bool IsFormat) const { MachineRegisterInfo *MRI = B.getMRI(); LLT Ty = MRI->getType(VData); const LLT S16 = LLT::scalar(16); // Fixup illegal register types for i8 stores. if (Ty == LLT::scalar(8) || Ty == S16) { Register AnyExt = B.buildAnyExt(LLT::scalar(32), VData).getReg(0); return AnyExt; } if (Ty.isVector()) { if (Ty.getElementType() == S16 && Ty.getNumElements() <= 4) { if (IsFormat) return handleD16VData(B, *MRI, VData); } } return VData; } bool AMDGPULegalizerInfo::legalizeBufferStore(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B, bool IsTyped, bool IsFormat) const { Register VData = MI.getOperand(1).getReg(); LLT Ty = MRI.getType(VData); LLT EltTy = Ty.getScalarType(); const bool IsD16 = IsFormat && (EltTy.getSizeInBits() == 16); const LLT S32 = LLT::scalar(32); VData = fixStoreSourceType(B, VData, IsFormat); Register RSrc = MI.getOperand(2).getReg(); MachineMemOperand *MMO = *MI.memoperands_begin(); const int MemSize = MMO->getSize(); unsigned ImmOffset; // The typed intrinsics add an immediate after the registers. const unsigned NumVIndexOps = IsTyped ? 8 : 7; // The struct intrinsic variants add one additional operand over raw. const bool HasVIndex = MI.getNumOperands() == NumVIndexOps; Register VIndex; int OpOffset = 0; if (HasVIndex) { VIndex = MI.getOperand(3).getReg(); OpOffset = 1; } else { VIndex = B.buildConstant(S32, 0).getReg(0); } Register VOffset = MI.getOperand(3 + OpOffset).getReg(); Register SOffset = MI.getOperand(4 + OpOffset).getReg(); unsigned Format = 0; if (IsTyped) { Format = MI.getOperand(5 + OpOffset).getImm(); ++OpOffset; } unsigned AuxiliaryData = MI.getOperand(5 + OpOffset).getImm(); std::tie(VOffset, ImmOffset) = splitBufferOffsets(B, VOffset); updateBufferMMO(MMO, VOffset, SOffset, ImmOffset, VIndex, MRI); unsigned Opc; if (IsTyped) { Opc = IsD16 ? AMDGPU::G_AMDGPU_TBUFFER_STORE_FORMAT_D16 : AMDGPU::G_AMDGPU_TBUFFER_STORE_FORMAT; } else if (IsFormat) { Opc = IsD16 ? AMDGPU::G_AMDGPU_BUFFER_STORE_FORMAT_D16 : AMDGPU::G_AMDGPU_BUFFER_STORE_FORMAT; } else { switch (MemSize) { case 1: Opc = AMDGPU::G_AMDGPU_BUFFER_STORE_BYTE; break; case 2: Opc = AMDGPU::G_AMDGPU_BUFFER_STORE_SHORT; break; default: Opc = AMDGPU::G_AMDGPU_BUFFER_STORE; break; } } auto MIB = B.buildInstr(Opc) .addUse(VData) // vdata .addUse(RSrc) // rsrc .addUse(VIndex) // vindex .addUse(VOffset) // voffset .addUse(SOffset) // soffset .addImm(ImmOffset); // offset(imm) if (IsTyped) MIB.addImm(Format); MIB.addImm(AuxiliaryData) // cachepolicy, swizzled buffer(imm) .addImm(HasVIndex ? -1 : 0) // idxen(imm) .addMemOperand(MMO); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeBufferLoad(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B, bool IsFormat, bool IsTyped) const { // FIXME: Verifier should enforce 1 MMO for these intrinsics. MachineMemOperand *MMO = *MI.memoperands_begin(); const LLT MemTy = MMO->getMemoryType(); const LLT S32 = LLT::scalar(32); Register Dst = MI.getOperand(0).getReg(); Register RSrc = MI.getOperand(2).getReg(); // The typed intrinsics add an immediate after the registers. const unsigned NumVIndexOps = IsTyped ? 8 : 7; // The struct intrinsic variants add one additional operand over raw. const bool HasVIndex = MI.getNumOperands() == NumVIndexOps; Register VIndex; int OpOffset = 0; if (HasVIndex) { VIndex = MI.getOperand(3).getReg(); OpOffset = 1; } else { VIndex = B.buildConstant(S32, 0).getReg(0); } Register VOffset = MI.getOperand(3 + OpOffset).getReg(); Register SOffset = MI.getOperand(4 + OpOffset).getReg(); unsigned Format = 0; if (IsTyped) { Format = MI.getOperand(5 + OpOffset).getImm(); ++OpOffset; } unsigned AuxiliaryData = MI.getOperand(5 + OpOffset).getImm(); unsigned ImmOffset; LLT Ty = MRI.getType(Dst); LLT EltTy = Ty.getScalarType(); const bool IsD16 = IsFormat && (EltTy.getSizeInBits() == 16); const bool Unpacked = ST.hasUnpackedD16VMem(); std::tie(VOffset, ImmOffset) = splitBufferOffsets(B, VOffset); updateBufferMMO(MMO, VOffset, SOffset, ImmOffset, VIndex, MRI); unsigned Opc; if (IsTyped) { Opc = IsD16 ? AMDGPU::G_AMDGPU_TBUFFER_LOAD_FORMAT_D16 : AMDGPU::G_AMDGPU_TBUFFER_LOAD_FORMAT; } else if (IsFormat) { Opc = IsD16 ? AMDGPU::G_AMDGPU_BUFFER_LOAD_FORMAT_D16 : AMDGPU::G_AMDGPU_BUFFER_LOAD_FORMAT; } else { switch (MemTy.getSizeInBits()) { case 8: Opc = AMDGPU::G_AMDGPU_BUFFER_LOAD_UBYTE; break; case 16: Opc = AMDGPU::G_AMDGPU_BUFFER_LOAD_USHORT; break; default: Opc = AMDGPU::G_AMDGPU_BUFFER_LOAD; break; } } Register LoadDstReg; bool IsExtLoad = (!IsD16 && MemTy.getSizeInBits() < 32) || (IsD16 && !Ty.isVector()); LLT UnpackedTy = Ty.changeElementSize(32); if (IsExtLoad) LoadDstReg = B.getMRI()->createGenericVirtualRegister(S32); else if (Unpacked && IsD16 && Ty.isVector()) LoadDstReg = B.getMRI()->createGenericVirtualRegister(UnpackedTy); else LoadDstReg = Dst; auto MIB = B.buildInstr(Opc) .addDef(LoadDstReg) // vdata .addUse(RSrc) // rsrc .addUse(VIndex) // vindex .addUse(VOffset) // voffset .addUse(SOffset) // soffset .addImm(ImmOffset); // offset(imm) if (IsTyped) MIB.addImm(Format); MIB.addImm(AuxiliaryData) // cachepolicy, swizzled buffer(imm) .addImm(HasVIndex ? -1 : 0) // idxen(imm) .addMemOperand(MMO); if (LoadDstReg != Dst) { B.setInsertPt(B.getMBB(), ++B.getInsertPt()); // Widen result for extending loads was widened. if (IsExtLoad) B.buildTrunc(Dst, LoadDstReg); else { // Repack to original 16-bit vector result // FIXME: G_TRUNC should work, but legalization currently fails auto Unmerge = B.buildUnmerge(S32, LoadDstReg); SmallVector Repack; for (unsigned I = 0, N = Unmerge->getNumOperands() - 1; I != N; ++I) Repack.push_back(B.buildTrunc(EltTy, Unmerge.getReg(I)).getReg(0)); B.buildMerge(Dst, Repack); } } MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeAtomicIncDec(MachineInstr &MI, MachineIRBuilder &B, bool IsInc) const { unsigned Opc = IsInc ? AMDGPU::G_AMDGPU_ATOMIC_INC : AMDGPU::G_AMDGPU_ATOMIC_DEC; B.buildInstr(Opc) .addDef(MI.getOperand(0).getReg()) .addUse(MI.getOperand(2).getReg()) .addUse(MI.getOperand(3).getReg()) .cloneMemRefs(MI); MI.eraseFromParent(); return true; } static unsigned getBufferAtomicPseudo(Intrinsic::ID IntrID) { switch (IntrID) { case Intrinsic::amdgcn_raw_buffer_atomic_swap: case Intrinsic::amdgcn_struct_buffer_atomic_swap: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_SWAP; case Intrinsic::amdgcn_raw_buffer_atomic_add: case Intrinsic::amdgcn_struct_buffer_atomic_add: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_ADD; case Intrinsic::amdgcn_raw_buffer_atomic_sub: case Intrinsic::amdgcn_struct_buffer_atomic_sub: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_SUB; case Intrinsic::amdgcn_raw_buffer_atomic_smin: case Intrinsic::amdgcn_struct_buffer_atomic_smin: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_SMIN; case Intrinsic::amdgcn_raw_buffer_atomic_umin: case Intrinsic::amdgcn_struct_buffer_atomic_umin: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_UMIN; case Intrinsic::amdgcn_raw_buffer_atomic_smax: case Intrinsic::amdgcn_struct_buffer_atomic_smax: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_SMAX; case Intrinsic::amdgcn_raw_buffer_atomic_umax: case Intrinsic::amdgcn_struct_buffer_atomic_umax: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_UMAX; case Intrinsic::amdgcn_raw_buffer_atomic_and: case Intrinsic::amdgcn_struct_buffer_atomic_and: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_AND; case Intrinsic::amdgcn_raw_buffer_atomic_or: case Intrinsic::amdgcn_struct_buffer_atomic_or: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_OR; case Intrinsic::amdgcn_raw_buffer_atomic_xor: case Intrinsic::amdgcn_struct_buffer_atomic_xor: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_XOR; case Intrinsic::amdgcn_raw_buffer_atomic_inc: case Intrinsic::amdgcn_struct_buffer_atomic_inc: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_INC; case Intrinsic::amdgcn_raw_buffer_atomic_dec: case Intrinsic::amdgcn_struct_buffer_atomic_dec: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_DEC; case Intrinsic::amdgcn_raw_buffer_atomic_cmpswap: case Intrinsic::amdgcn_struct_buffer_atomic_cmpswap: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_CMPSWAP; case Intrinsic::amdgcn_raw_buffer_atomic_fadd: case Intrinsic::amdgcn_struct_buffer_atomic_fadd: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_FADD; case Intrinsic::amdgcn_raw_buffer_atomic_fmin: case Intrinsic::amdgcn_struct_buffer_atomic_fmin: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_FMIN; case Intrinsic::amdgcn_raw_buffer_atomic_fmax: case Intrinsic::amdgcn_struct_buffer_atomic_fmax: return AMDGPU::G_AMDGPU_BUFFER_ATOMIC_FMAX; default: llvm_unreachable("unhandled atomic opcode"); } } bool AMDGPULegalizerInfo::legalizeBufferAtomic(MachineInstr &MI, MachineIRBuilder &B, Intrinsic::ID IID) const { const bool IsCmpSwap = IID == Intrinsic::amdgcn_raw_buffer_atomic_cmpswap || IID == Intrinsic::amdgcn_struct_buffer_atomic_cmpswap; const bool HasReturn = MI.getNumExplicitDefs() != 0; Register Dst; int OpOffset = 0; if (HasReturn) { // A few FP atomics do not support return values. Dst = MI.getOperand(0).getReg(); } else { OpOffset = -1; } Register VData = MI.getOperand(2 + OpOffset).getReg(); Register CmpVal; if (IsCmpSwap) { CmpVal = MI.getOperand(3 + OpOffset).getReg(); ++OpOffset; } Register RSrc = MI.getOperand(3 + OpOffset).getReg(); const unsigned NumVIndexOps = (IsCmpSwap ? 8 : 7) + HasReturn; // The struct intrinsic variants add one additional operand over raw. const bool HasVIndex = MI.getNumOperands() == NumVIndexOps; Register VIndex; if (HasVIndex) { VIndex = MI.getOperand(4 + OpOffset).getReg(); ++OpOffset; } else { VIndex = B.buildConstant(LLT::scalar(32), 0).getReg(0); } Register VOffset = MI.getOperand(4 + OpOffset).getReg(); Register SOffset = MI.getOperand(5 + OpOffset).getReg(); unsigned AuxiliaryData = MI.getOperand(6 + OpOffset).getImm(); MachineMemOperand *MMO = *MI.memoperands_begin(); unsigned ImmOffset; std::tie(VOffset, ImmOffset) = splitBufferOffsets(B, VOffset); updateBufferMMO(MMO, VOffset, SOffset, ImmOffset, VIndex, *B.getMRI()); auto MIB = B.buildInstr(getBufferAtomicPseudo(IID)); if (HasReturn) MIB.addDef(Dst); MIB.addUse(VData); // vdata if (IsCmpSwap) MIB.addReg(CmpVal); MIB.addUse(RSrc) // rsrc .addUse(VIndex) // vindex .addUse(VOffset) // voffset .addUse(SOffset) // soffset .addImm(ImmOffset) // offset(imm) .addImm(AuxiliaryData) // cachepolicy, swizzled buffer(imm) .addImm(HasVIndex ? -1 : 0) // idxen(imm) .addMemOperand(MMO); MI.eraseFromParent(); return true; } /// Turn a set of s16 typed registers in \p AddrRegs into a dword sized /// vector with s16 typed elements. static void packImage16bitOpsToDwords(MachineIRBuilder &B, MachineInstr &MI, SmallVectorImpl &PackedAddrs, unsigned ArgOffset, const AMDGPU::ImageDimIntrinsicInfo *Intr, bool IsA16, bool IsG16) { const LLT S16 = LLT::scalar(16); const LLT V2S16 = LLT::fixed_vector(2, 16); auto EndIdx = Intr->VAddrEnd; for (unsigned I = Intr->VAddrStart; I < EndIdx; I++) { MachineOperand &SrcOp = MI.getOperand(ArgOffset + I); if (!SrcOp.isReg()) continue; // _L to _LZ may have eliminated this. Register AddrReg = SrcOp.getReg(); if ((I < Intr->GradientStart) || (I >= Intr->GradientStart && I < Intr->CoordStart && !IsG16) || (I >= Intr->CoordStart && !IsA16)) { if ((I < Intr->GradientStart) && IsA16 && (B.getMRI()->getType(AddrReg) == S16)) { assert(I == Intr->BiasIndex && "Got unexpected 16-bit extra argument"); // Special handling of bias when A16 is on. Bias is of type half but // occupies full 32-bit. PackedAddrs.push_back( B.buildBuildVector(V2S16, {AddrReg, B.buildUndef(S16).getReg(0)}) .getReg(0)); } else { assert((!IsA16 || Intr->NumBiasArgs == 0 || I != Intr->BiasIndex) && "Bias needs to be converted to 16 bit in A16 mode"); // Handle any gradient or coordinate operands that should not be packed AddrReg = B.buildBitcast(V2S16, AddrReg).getReg(0); PackedAddrs.push_back(AddrReg); } } else { // Dz/dh, dz/dv and the last odd coord are packed with undef. Also, in 1D, // derivatives dx/dh and dx/dv are packed with undef. if (((I + 1) >= EndIdx) || ((Intr->NumGradients / 2) % 2 == 1 && (I == static_cast(Intr->GradientStart + (Intr->NumGradients / 2) - 1) || I == static_cast(Intr->GradientStart + Intr->NumGradients - 1))) || // Check for _L to _LZ optimization !MI.getOperand(ArgOffset + I + 1).isReg()) { PackedAddrs.push_back( B.buildBuildVector(V2S16, {AddrReg, B.buildUndef(S16).getReg(0)}) .getReg(0)); } else { PackedAddrs.push_back( B.buildBuildVector( V2S16, {AddrReg, MI.getOperand(ArgOffset + I + 1).getReg()}) .getReg(0)); ++I; } } } } /// Convert from separate vaddr components to a single vector address register, /// and replace the remaining operands with $noreg. static void convertImageAddrToPacked(MachineIRBuilder &B, MachineInstr &MI, int DimIdx, int NumVAddrs) { const LLT S32 = LLT::scalar(32); SmallVector AddrRegs; for (int I = 0; I != NumVAddrs; ++I) { MachineOperand &SrcOp = MI.getOperand(DimIdx + I); if (SrcOp.isReg()) { AddrRegs.push_back(SrcOp.getReg()); assert(B.getMRI()->getType(SrcOp.getReg()) == S32); } } int NumAddrRegs = AddrRegs.size(); if (NumAddrRegs != 1) { // Above 8 elements round up to next power of 2 (i.e. 16). if (NumAddrRegs > 8 && !isPowerOf2_32(NumAddrRegs)) { const int RoundedNumRegs = NextPowerOf2(NumAddrRegs); auto Undef = B.buildUndef(S32); AddrRegs.append(RoundedNumRegs - NumAddrRegs, Undef.getReg(0)); NumAddrRegs = RoundedNumRegs; } auto VAddr = B.buildBuildVector(LLT::fixed_vector(NumAddrRegs, 32), AddrRegs); MI.getOperand(DimIdx).setReg(VAddr.getReg(0)); } for (int I = 1; I != NumVAddrs; ++I) { MachineOperand &SrcOp = MI.getOperand(DimIdx + I); if (SrcOp.isReg()) MI.getOperand(DimIdx + I).setReg(AMDGPU::NoRegister); } } /// Rewrite image intrinsics to use register layouts expected by the subtarget. /// /// Depending on the subtarget, load/store with 16-bit element data need to be /// rewritten to use the low half of 32-bit registers, or directly use a packed /// layout. 16-bit addresses should also sometimes be packed into 32-bit /// registers. /// /// We don't want to directly select image instructions just yet, but also want /// to exposes all register repacking to the legalizer/combiners. We also don't /// want a selected instruction entering RegBankSelect. In order to avoid /// defining a multitude of intermediate image instructions, directly hack on /// the intrinsic's arguments. In cases like a16 addresses, this requires /// padding now unnecessary arguments with $noreg. bool AMDGPULegalizerInfo::legalizeImageIntrinsic( MachineInstr &MI, MachineIRBuilder &B, GISelChangeObserver &Observer, const AMDGPU::ImageDimIntrinsicInfo *Intr) const { const unsigned NumDefs = MI.getNumExplicitDefs(); const unsigned ArgOffset = NumDefs + 1; bool IsTFE = NumDefs == 2; // We are only processing the operands of d16 image operations on subtargets // that use the unpacked register layout, or need to repack the TFE result. // TODO: Do we need to guard against already legalized intrinsics? const AMDGPU::MIMGBaseOpcodeInfo *BaseOpcode = AMDGPU::getMIMGBaseOpcodeInfo(Intr->BaseOpcode); MachineRegisterInfo *MRI = B.getMRI(); const LLT S32 = LLT::scalar(32); const LLT S16 = LLT::scalar(16); const LLT V2S16 = LLT::fixed_vector(2, 16); unsigned DMask = 0; Register VData = MI.getOperand(NumDefs == 0 ? 1 : 0).getReg(); LLT Ty = MRI->getType(VData); // Check for 16 bit addresses and pack if true. LLT GradTy = MRI->getType(MI.getOperand(ArgOffset + Intr->GradientStart).getReg()); LLT AddrTy = MRI->getType(MI.getOperand(ArgOffset + Intr->CoordStart).getReg()); const bool IsG16 = GradTy == S16; const bool IsA16 = AddrTy == S16; const bool IsD16 = Ty.getScalarType() == S16; int DMaskLanes = 0; if (!BaseOpcode->Atomic) { DMask = MI.getOperand(ArgOffset + Intr->DMaskIndex).getImm(); if (BaseOpcode->Gather4) { DMaskLanes = 4; } else if (DMask != 0) { DMaskLanes = countPopulation(DMask); } else if (!IsTFE && !BaseOpcode->Store) { // If dmask is 0, this is a no-op load. This can be eliminated. B.buildUndef(MI.getOperand(0)); MI.eraseFromParent(); return true; } } Observer.changingInstr(MI); auto ChangedInstr = make_scope_exit([&] { Observer.changedInstr(MI); }); const unsigned StoreOpcode = IsD16 ? AMDGPU::G_AMDGPU_INTRIN_IMAGE_STORE_D16 : AMDGPU::G_AMDGPU_INTRIN_IMAGE_STORE; const unsigned LoadOpcode = IsD16 ? AMDGPU::G_AMDGPU_INTRIN_IMAGE_LOAD_D16 : AMDGPU::G_AMDGPU_INTRIN_IMAGE_LOAD; unsigned NewOpcode = NumDefs == 0 ? StoreOpcode : LoadOpcode; // Track that we legalized this MI.setDesc(B.getTII().get(NewOpcode)); // Expecting to get an error flag since TFC is on - and dmask is 0 Force // dmask to be at least 1 otherwise the instruction will fail if (IsTFE && DMask == 0) { DMask = 0x1; DMaskLanes = 1; MI.getOperand(ArgOffset + Intr->DMaskIndex).setImm(DMask); } if (BaseOpcode->Atomic) { Register VData0 = MI.getOperand(2).getReg(); LLT Ty = MRI->getType(VData0); // TODO: Allow atomic swap and bit ops for v2s16/v4s16 if (Ty.isVector()) return false; if (BaseOpcode->AtomicX2) { Register VData1 = MI.getOperand(3).getReg(); // The two values are packed in one register. LLT PackedTy = LLT::fixed_vector(2, Ty); auto Concat = B.buildBuildVector(PackedTy, {VData0, VData1}); MI.getOperand(2).setReg(Concat.getReg(0)); MI.getOperand(3).setReg(AMDGPU::NoRegister); } } unsigned CorrectedNumVAddrs = Intr->NumVAddrs; // Rewrite the addressing register layout before doing anything else. if (BaseOpcode->Gradients && !ST.hasG16() && (IsA16 != IsG16)) { // 16 bit gradients are supported, but are tied to the A16 control // so both gradients and addresses must be 16 bit return false; } if (IsA16 && !ST.hasA16()) { // A16 not supported return false; } if (IsA16 || IsG16) { if (Intr->NumVAddrs > 1) { SmallVector PackedRegs; packImage16bitOpsToDwords(B, MI, PackedRegs, ArgOffset, Intr, IsA16, IsG16); // See also below in the non-a16 branch const bool UseNSA = ST.hasNSAEncoding() && PackedRegs.size() >= 3 && PackedRegs.size() <= ST.getNSAMaxSize(); if (!UseNSA && PackedRegs.size() > 1) { LLT PackedAddrTy = LLT::fixed_vector(2 * PackedRegs.size(), 16); auto Concat = B.buildConcatVectors(PackedAddrTy, PackedRegs); PackedRegs[0] = Concat.getReg(0); PackedRegs.resize(1); } const unsigned NumPacked = PackedRegs.size(); for (unsigned I = Intr->VAddrStart; I < Intr->VAddrEnd; I++) { MachineOperand &SrcOp = MI.getOperand(ArgOffset + I); if (!SrcOp.isReg()) { assert(SrcOp.isImm() && SrcOp.getImm() == 0); continue; } assert(SrcOp.getReg() != AMDGPU::NoRegister); if (I - Intr->VAddrStart < NumPacked) SrcOp.setReg(PackedRegs[I - Intr->VAddrStart]); else SrcOp.setReg(AMDGPU::NoRegister); } } } else { // If the register allocator cannot place the address registers contiguously // without introducing moves, then using the non-sequential address encoding // is always preferable, since it saves VALU instructions and is usually a // wash in terms of code size or even better. // // However, we currently have no way of hinting to the register allocator // that MIMG addresses should be placed contiguously when it is possible to // do so, so force non-NSA for the common 2-address case as a heuristic. // // SIShrinkInstructions will convert NSA encodings to non-NSA after register // allocation when possible. // // TODO: we can actually allow partial NSA where the final register is a // contiguous set of the remaining addresses. // This could help where there are more addresses than supported. const bool UseNSA = ST.hasNSAEncoding() && CorrectedNumVAddrs >= 3 && CorrectedNumVAddrs <= ST.getNSAMaxSize(); if (!UseNSA && Intr->NumVAddrs > 1) convertImageAddrToPacked(B, MI, ArgOffset + Intr->VAddrStart, Intr->NumVAddrs); } int Flags = 0; if (IsA16) Flags |= 1; if (IsG16) Flags |= 2; MI.addOperand(MachineOperand::CreateImm(Flags)); if (BaseOpcode->Store) { // No TFE for stores? // TODO: Handle dmask trim if (!Ty.isVector() || !IsD16) return true; Register RepackedReg = handleD16VData(B, *MRI, VData, true); if (RepackedReg != VData) { MI.getOperand(1).setReg(RepackedReg); } return true; } Register DstReg = MI.getOperand(0).getReg(); const LLT EltTy = Ty.getScalarType(); const int NumElts = Ty.isVector() ? Ty.getNumElements() : 1; // Confirm that the return type is large enough for the dmask specified if (NumElts < DMaskLanes) return false; if (NumElts > 4 || DMaskLanes > 4) return false; const unsigned AdjustedNumElts = DMaskLanes == 0 ? 1 : DMaskLanes; const LLT AdjustedTy = Ty.changeElementCount(ElementCount::getFixed(AdjustedNumElts)); // The raw dword aligned data component of the load. The only legal cases // where this matters should be when using the packed D16 format, for // s16 -> <2 x s16>, and <3 x s16> -> <4 x s16>, LLT RoundedTy; // S32 vector to to cover all data, plus TFE result element. LLT TFETy; // Register type to use for each loaded component. Will be S32 or V2S16. LLT RegTy; if (IsD16 && ST.hasUnpackedD16VMem()) { RoundedTy = LLT::scalarOrVector(ElementCount::getFixed(AdjustedNumElts), 32); TFETy = LLT::fixed_vector(AdjustedNumElts + 1, 32); RegTy = S32; } else { unsigned EltSize = EltTy.getSizeInBits(); unsigned RoundedElts = (AdjustedTy.getSizeInBits() + 31) / 32; unsigned RoundedSize = 32 * RoundedElts; RoundedTy = LLT::scalarOrVector( ElementCount::getFixed(RoundedSize / EltSize), EltSize); TFETy = LLT::fixed_vector(RoundedSize / 32 + 1, S32); RegTy = !IsTFE && EltSize == 16 ? V2S16 : S32; } // The return type does not need adjustment. // TODO: Should we change s16 case to s32 or <2 x s16>? if (!IsTFE && (RoundedTy == Ty || !Ty.isVector())) return true; Register Dst1Reg; // Insert after the instruction. B.setInsertPt(*MI.getParent(), ++MI.getIterator()); // TODO: For TFE with d16, if we used a TFE type that was a multiple of <2 x // s16> instead of s32, we would only need 1 bitcast instead of multiple. const LLT LoadResultTy = IsTFE ? TFETy : RoundedTy; const int ResultNumRegs = LoadResultTy.getSizeInBits() / 32; Register NewResultReg = MRI->createGenericVirtualRegister(LoadResultTy); MI.getOperand(0).setReg(NewResultReg); // In the IR, TFE is supposed to be used with a 2 element struct return // type. The instruction really returns these two values in one contiguous // register, with one additional dword beyond the loaded data. Rewrite the // return type to use a single register result. if (IsTFE) { Dst1Reg = MI.getOperand(1).getReg(); if (MRI->getType(Dst1Reg) != S32) return false; // TODO: Make sure the TFE operand bit is set. MI.removeOperand(1); // Handle the easy case that requires no repack instructions. if (Ty == S32) { B.buildUnmerge({DstReg, Dst1Reg}, NewResultReg); return true; } } // Now figure out how to copy the new result register back into the old // result. SmallVector ResultRegs(ResultNumRegs, Dst1Reg); const int NumDataRegs = IsTFE ? ResultNumRegs - 1 : ResultNumRegs; if (ResultNumRegs == 1) { assert(!IsTFE); ResultRegs[0] = NewResultReg; } else { // We have to repack into a new vector of some kind. for (int I = 0; I != NumDataRegs; ++I) ResultRegs[I] = MRI->createGenericVirtualRegister(RegTy); B.buildUnmerge(ResultRegs, NewResultReg); // Drop the final TFE element to get the data part. The TFE result is // directly written to the right place already. if (IsTFE) ResultRegs.resize(NumDataRegs); } // For an s16 scalar result, we form an s32 result with a truncate regardless // of packed vs. unpacked. if (IsD16 && !Ty.isVector()) { B.buildTrunc(DstReg, ResultRegs[0]); return true; } // Avoid a build/concat_vector of 1 entry. if (Ty == V2S16 && NumDataRegs == 1 && !ST.hasUnpackedD16VMem()) { B.buildBitcast(DstReg, ResultRegs[0]); return true; } assert(Ty.isVector()); if (IsD16) { // For packed D16 results with TFE enabled, all the data components are // S32. Cast back to the expected type. // // TODO: We don't really need to use load s32 elements. We would only need one // cast for the TFE result if a multiple of v2s16 was used. if (RegTy != V2S16 && !ST.hasUnpackedD16VMem()) { for (Register &Reg : ResultRegs) Reg = B.buildBitcast(V2S16, Reg).getReg(0); } else if (ST.hasUnpackedD16VMem()) { for (Register &Reg : ResultRegs) Reg = B.buildTrunc(S16, Reg).getReg(0); } } auto padWithUndef = [&](LLT Ty, int NumElts) { if (NumElts == 0) return; Register Undef = B.buildUndef(Ty).getReg(0); for (int I = 0; I != NumElts; ++I) ResultRegs.push_back(Undef); }; // Pad out any elements eliminated due to the dmask. LLT ResTy = MRI->getType(ResultRegs[0]); if (!ResTy.isVector()) { padWithUndef(ResTy, NumElts - ResultRegs.size()); B.buildBuildVector(DstReg, ResultRegs); return true; } assert(!ST.hasUnpackedD16VMem() && ResTy == V2S16); const int RegsToCover = (Ty.getSizeInBits() + 31) / 32; // Deal with the one annoying legal case. const LLT V3S16 = LLT::fixed_vector(3, 16); if (Ty == V3S16) { if (IsTFE) { if (ResultRegs.size() == 1) { NewResultReg = ResultRegs[0]; } else if (ResultRegs.size() == 2) { LLT V4S16 = LLT::fixed_vector(4, 16); NewResultReg = B.buildConcatVectors(V4S16, ResultRegs).getReg(0); } else { return false; } } if (MRI->getType(DstReg).getNumElements() < MRI->getType(NewResultReg).getNumElements()) { B.buildDeleteTrailingVectorElements(DstReg, NewResultReg); } else { B.buildPadVectorWithUndefElements(DstReg, NewResultReg); } return true; } padWithUndef(ResTy, RegsToCover - ResultRegs.size()); B.buildConcatVectors(DstReg, ResultRegs); return true; } bool AMDGPULegalizerInfo::legalizeSBufferLoad( LegalizerHelper &Helper, MachineInstr &MI) const { MachineIRBuilder &B = Helper.MIRBuilder; GISelChangeObserver &Observer = Helper.Observer; Register Dst = MI.getOperand(0).getReg(); LLT Ty = B.getMRI()->getType(Dst); unsigned Size = Ty.getSizeInBits(); MachineFunction &MF = B.getMF(); Observer.changingInstr(MI); if (shouldBitcastLoadStoreType(ST, Ty, LLT::scalar(Size))) { Ty = getBitcastRegisterType(Ty); Helper.bitcastDst(MI, Ty, 0); Dst = MI.getOperand(0).getReg(); B.setInsertPt(B.getMBB(), MI); } // FIXME: We don't really need this intermediate instruction. The intrinsic // should be fixed to have a memory operand. Since it's readnone, we're not // allowed to add one. MI.setDesc(B.getTII().get(AMDGPU::G_AMDGPU_S_BUFFER_LOAD)); MI.removeOperand(1); // Remove intrinsic ID // FIXME: When intrinsic definition is fixed, this should have an MMO already. // TODO: Should this use datalayout alignment? const unsigned MemSize = (Size + 7) / 8; const Align MemAlign(4); MachineMemOperand *MMO = MF.getMachineMemOperand( MachinePointerInfo(), MachineMemOperand::MOLoad | MachineMemOperand::MODereferenceable | MachineMemOperand::MOInvariant, MemSize, MemAlign); MI.addMemOperand(MF, MMO); // There are no 96-bit result scalar loads, but widening to 128-bit should // always be legal. We may need to restore this to a 96-bit result if it turns // out this needs to be converted to a vector load during RegBankSelect. if (!isPowerOf2_32(Size)) { if (Ty.isVector()) Helper.moreElementsVectorDst(MI, getPow2VectorType(Ty), 0); else Helper.widenScalarDst(MI, getPow2ScalarType(Ty), 0); } Observer.changedInstr(MI); return true; } // TODO: Move to selection bool AMDGPULegalizerInfo::legalizeTrapIntrinsic(MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { if (!ST.isTrapHandlerEnabled() || ST.getTrapHandlerAbi() != GCNSubtarget::TrapHandlerAbi::AMDHSA) return legalizeTrapEndpgm(MI, MRI, B); if (Optional HsaAbiVer = AMDGPU::getHsaAbiVersion(&ST)) { switch (*HsaAbiVer) { case ELF::ELFABIVERSION_AMDGPU_HSA_V2: case ELF::ELFABIVERSION_AMDGPU_HSA_V3: return legalizeTrapHsaQueuePtr(MI, MRI, B); case ELF::ELFABIVERSION_AMDGPU_HSA_V4: case ELF::ELFABIVERSION_AMDGPU_HSA_V5: return ST.supportsGetDoorbellID() ? legalizeTrapHsa(MI, MRI, B) : legalizeTrapHsaQueuePtr(MI, MRI, B); } } llvm_unreachable("Unknown trap handler"); } bool AMDGPULegalizerInfo::legalizeTrapEndpgm( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { B.buildInstr(AMDGPU::S_ENDPGM).addImm(0); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeTrapHsaQueuePtr( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { MachineFunction &MF = B.getMF(); const LLT S64 = LLT::scalar(64); Register SGPR01(AMDGPU::SGPR0_SGPR1); // For code object version 5, queue_ptr is passed through implicit kernarg. if (AMDGPU::getAmdhsaCodeObjectVersion() == 5) { AMDGPUTargetLowering::ImplicitParameter Param = AMDGPUTargetLowering::QUEUE_PTR; uint64_t Offset = ST.getTargetLowering()->getImplicitParameterOffset(B.getMF(), Param); Register KernargPtrReg = MRI.createGenericVirtualRegister( LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64)); if (!loadInputValue(KernargPtrReg, B, AMDGPUFunctionArgInfo::KERNARG_SEGMENT_PTR)) return false; // TODO: can we be smarter about machine pointer info? MachinePointerInfo PtrInfo(AMDGPUAS::CONSTANT_ADDRESS); MachineMemOperand *MMO = MF.getMachineMemOperand( PtrInfo, MachineMemOperand::MOLoad | MachineMemOperand::MODereferenceable | MachineMemOperand::MOInvariant, LLT::scalar(64), commonAlignment(Align(64), Offset)); // Pointer address Register LoadAddr = MRI.createGenericVirtualRegister( LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64)); B.buildPtrAdd(LoadAddr, KernargPtrReg, B.buildConstant(LLT::scalar(64), Offset).getReg(0)); // Load address Register Temp = B.buildLoad(S64, LoadAddr, *MMO).getReg(0); B.buildCopy(SGPR01, Temp); B.buildInstr(AMDGPU::S_TRAP) .addImm(static_cast(GCNSubtarget::TrapID::LLVMAMDHSATrap)) .addReg(SGPR01, RegState::Implicit); MI.eraseFromParent(); return true; } // Pass queue pointer to trap handler as input, and insert trap instruction // Reference: https://llvm.org/docs/AMDGPUUsage.html#trap-handler-abi Register LiveIn = MRI.createGenericVirtualRegister(LLT::pointer(AMDGPUAS::CONSTANT_ADDRESS, 64)); if (!loadInputValue(LiveIn, B, AMDGPUFunctionArgInfo::QUEUE_PTR)) return false; B.buildCopy(SGPR01, LiveIn); B.buildInstr(AMDGPU::S_TRAP) .addImm(static_cast(GCNSubtarget::TrapID::LLVMAMDHSATrap)) .addReg(SGPR01, RegState::Implicit); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeTrapHsa( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { B.buildInstr(AMDGPU::S_TRAP) .addImm(static_cast(GCNSubtarget::TrapID::LLVMAMDHSATrap)); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeDebugTrapIntrinsic( MachineInstr &MI, MachineRegisterInfo &MRI, MachineIRBuilder &B) const { // Is non-HSA path or trap-handler disabled? Then, report a warning // accordingly if (!ST.isTrapHandlerEnabled() || ST.getTrapHandlerAbi() != GCNSubtarget::TrapHandlerAbi::AMDHSA) { DiagnosticInfoUnsupported NoTrap(B.getMF().getFunction(), "debugtrap handler not supported", MI.getDebugLoc(), DS_Warning); LLVMContext &Ctx = B.getMF().getFunction().getContext(); Ctx.diagnose(NoTrap); } else { // Insert debug-trap instruction B.buildInstr(AMDGPU::S_TRAP) .addImm(static_cast(GCNSubtarget::TrapID::LLVMAMDHSADebugTrap)); } MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeBVHIntrinsic(MachineInstr &MI, MachineIRBuilder &B) const { MachineRegisterInfo &MRI = *B.getMRI(); const LLT S16 = LLT::scalar(16); const LLT S32 = LLT::scalar(32); const LLT V2S16 = LLT::fixed_vector(2, 16); const LLT V3S32 = LLT::fixed_vector(3, 32); Register DstReg = MI.getOperand(0).getReg(); Register NodePtr = MI.getOperand(2).getReg(); Register RayExtent = MI.getOperand(3).getReg(); Register RayOrigin = MI.getOperand(4).getReg(); Register RayDir = MI.getOperand(5).getReg(); Register RayInvDir = MI.getOperand(6).getReg(); Register TDescr = MI.getOperand(7).getReg(); if (!ST.hasGFX10_AEncoding()) { DiagnosticInfoUnsupported BadIntrin(B.getMF().getFunction(), "intrinsic not supported on subtarget", MI.getDebugLoc()); B.getMF().getFunction().getContext().diagnose(BadIntrin); return false; } const bool IsGFX11Plus = AMDGPU::isGFX11Plus(ST); const bool IsA16 = MRI.getType(RayDir).getElementType().getSizeInBits() == 16; const bool Is64 = MRI.getType(NodePtr).getSizeInBits() == 64; const unsigned NumVDataDwords = 4; const unsigned NumVAddrDwords = IsA16 ? (Is64 ? 9 : 8) : (Is64 ? 12 : 11); const unsigned NumVAddrs = IsGFX11Plus ? (IsA16 ? 4 : 5) : NumVAddrDwords; const bool UseNSA = ST.hasNSAEncoding() && NumVAddrs <= ST.getNSAMaxSize(); const unsigned BaseOpcodes[2][2] = { {AMDGPU::IMAGE_BVH_INTERSECT_RAY, AMDGPU::IMAGE_BVH_INTERSECT_RAY_a16}, {AMDGPU::IMAGE_BVH64_INTERSECT_RAY, AMDGPU::IMAGE_BVH64_INTERSECT_RAY_a16}}; int Opcode; if (UseNSA) { Opcode = AMDGPU::getMIMGOpcode(BaseOpcodes[Is64][IsA16], IsGFX11Plus ? AMDGPU::MIMGEncGfx11NSA : AMDGPU::MIMGEncGfx10NSA, NumVDataDwords, NumVAddrDwords); } else { Opcode = AMDGPU::getMIMGOpcode( BaseOpcodes[Is64][IsA16], IsGFX11Plus ? AMDGPU::MIMGEncGfx11Default : AMDGPU::MIMGEncGfx10Default, NumVDataDwords, PowerOf2Ceil(NumVAddrDwords)); } assert(Opcode != -1); SmallVector Ops; if (UseNSA && IsGFX11Plus) { auto packLanes = [&Ops, &S32, &V3S32, &B](Register Src) { auto Unmerge = B.buildUnmerge({S32, S32, S32}, Src); auto Merged = B.buildMerge( V3S32, {Unmerge.getReg(0), Unmerge.getReg(1), Unmerge.getReg(2)}); Ops.push_back(Merged.getReg(0)); }; Ops.push_back(NodePtr); Ops.push_back(RayExtent); packLanes(RayOrigin); if (IsA16) { auto UnmergeRayDir = B.buildUnmerge({S16, S16, S16}, RayDir); auto UnmergeRayInvDir = B.buildUnmerge({S16, S16, S16}, RayInvDir); auto MergedDir = B.buildMerge( V3S32, {B.buildBitcast(S32, B.buildMerge(V2S16, {UnmergeRayInvDir.getReg(0), UnmergeRayDir.getReg(0)})) .getReg(0), B.buildBitcast(S32, B.buildMerge(V2S16, {UnmergeRayInvDir.getReg(1), UnmergeRayDir.getReg(1)})) .getReg(0), B.buildBitcast(S32, B.buildMerge(V2S16, {UnmergeRayInvDir.getReg(2), UnmergeRayDir.getReg(2)})) .getReg(0)}); Ops.push_back(MergedDir.getReg(0)); } else { packLanes(RayDir); packLanes(RayInvDir); } } else { if (Is64) { auto Unmerge = B.buildUnmerge({S32, S32}, NodePtr); Ops.push_back(Unmerge.getReg(0)); Ops.push_back(Unmerge.getReg(1)); } else { Ops.push_back(NodePtr); } Ops.push_back(RayExtent); auto packLanes = [&Ops, &S32, &B](Register Src) { auto Unmerge = B.buildUnmerge({S32, S32, S32}, Src); Ops.push_back(Unmerge.getReg(0)); Ops.push_back(Unmerge.getReg(1)); Ops.push_back(Unmerge.getReg(2)); }; packLanes(RayOrigin); if (IsA16) { auto UnmergeRayDir = B.buildUnmerge({S16, S16, S16}, RayDir); auto UnmergeRayInvDir = B.buildUnmerge({S16, S16, S16}, RayInvDir); Register R1 = MRI.createGenericVirtualRegister(S32); Register R2 = MRI.createGenericVirtualRegister(S32); Register R3 = MRI.createGenericVirtualRegister(S32); B.buildMerge(R1, {UnmergeRayDir.getReg(0), UnmergeRayDir.getReg(1)}); B.buildMerge(R2, {UnmergeRayDir.getReg(2), UnmergeRayInvDir.getReg(0)}); B.buildMerge(R3, {UnmergeRayInvDir.getReg(1), UnmergeRayInvDir.getReg(2)}); Ops.push_back(R1); Ops.push_back(R2); Ops.push_back(R3); } else { packLanes(RayDir); packLanes(RayInvDir); } } if (!UseNSA) { // Build a single vector containing all the operands so far prepared. LLT OpTy = LLT::fixed_vector(Ops.size(), 32); Register MergedOps = B.buildMerge(OpTy, Ops).getReg(0); Ops.clear(); Ops.push_back(MergedOps); } auto MIB = B.buildInstr(AMDGPU::G_AMDGPU_INTRIN_BVH_INTERSECT_RAY) .addDef(DstReg) .addImm(Opcode); for (Register R : Ops) { MIB.addUse(R); } MIB.addUse(TDescr) .addImm(IsA16 ? 1 : 0) .cloneMemRefs(MI); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeFPTruncRound(MachineInstr &MI, MachineIRBuilder &B) const { unsigned Opc; int RoundMode = MI.getOperand(2).getImm(); if (RoundMode == (int)RoundingMode::TowardPositive) Opc = AMDGPU::G_FPTRUNC_ROUND_UPWARD; else if (RoundMode == (int)RoundingMode::TowardNegative) Opc = AMDGPU::G_FPTRUNC_ROUND_DOWNWARD; else return false; B.buildInstr(Opc) .addDef(MI.getOperand(0).getReg()) .addUse(MI.getOperand(1).getReg()); MI.eraseFromParent(); return true; } bool AMDGPULegalizerInfo::legalizeIntrinsic(LegalizerHelper &Helper, MachineInstr &MI) const { MachineIRBuilder &B = Helper.MIRBuilder; MachineRegisterInfo &MRI = *B.getMRI(); // Replace the use G_BRCOND with the exec manipulate and branch pseudos. auto IntrID = MI.getIntrinsicID(); switch (IntrID) { case Intrinsic::amdgcn_if: case Intrinsic::amdgcn_else: { MachineInstr *Br = nullptr; MachineBasicBlock *UncondBrTarget = nullptr; bool Negated = false; if (MachineInstr *BrCond = verifyCFIntrinsic(MI, MRI, Br, UncondBrTarget, Negated)) { const SIRegisterInfo *TRI = static_cast(MRI.getTargetRegisterInfo()); Register Def = MI.getOperand(1).getReg(); Register Use = MI.getOperand(3).getReg(); MachineBasicBlock *CondBrTarget = BrCond->getOperand(1).getMBB(); if (Negated) std::swap(CondBrTarget, UncondBrTarget); B.setInsertPt(B.getMBB(), BrCond->getIterator()); if (IntrID == Intrinsic::amdgcn_if) { B.buildInstr(AMDGPU::SI_IF) .addDef(Def) .addUse(Use) .addMBB(UncondBrTarget); } else { B.buildInstr(AMDGPU::SI_ELSE) .addDef(Def) .addUse(Use) .addMBB(UncondBrTarget); } if (Br) { Br->getOperand(0).setMBB(CondBrTarget); } else { // The IRTranslator skips inserting the G_BR for fallthrough cases, but // since we're swapping branch targets it needs to be reinserted. // FIXME: IRTranslator should probably not do this B.buildBr(*CondBrTarget); } MRI.setRegClass(Def, TRI->getWaveMaskRegClass()); MRI.setRegClass(Use, TRI->getWaveMaskRegClass()); MI.eraseFromParent(); BrCond->eraseFromParent(); return true; } return false; } case Intrinsic::amdgcn_loop: { MachineInstr *Br = nullptr; MachineBasicBlock *UncondBrTarget = nullptr; bool Negated = false; if (MachineInstr *BrCond = verifyCFIntrinsic(MI, MRI, Br, UncondBrTarget, Negated)) { const SIRegisterInfo *TRI = static_cast(MRI.getTargetRegisterInfo()); MachineBasicBlock *CondBrTarget = BrCond->getOperand(1).getMBB(); Register Reg = MI.getOperand(2).getReg(); if (Negated) std::swap(CondBrTarget, UncondBrTarget); B.setInsertPt(B.getMBB(), BrCond->getIterator()); B.buildInstr(AMDGPU::SI_LOOP) .addUse(Reg) .addMBB(UncondBrTarget); if (Br) Br->getOperand(0).setMBB(CondBrTarget); else B.buildBr(*CondBrTarget); MI.eraseFromParent(); BrCond->eraseFromParent(); MRI.setRegClass(Reg, TRI->getWaveMaskRegClass()); return true; } return false; } case Intrinsic::amdgcn_kernarg_segment_ptr: if (!AMDGPU::isKernel(B.getMF().getFunction().getCallingConv())) { // This only makes sense to call in a kernel, so just lower to null. B.buildConstant(MI.getOperand(0).getReg(), 0); MI.eraseFromParent(); return true; } return legalizePreloadedArgIntrin( MI, MRI, B, AMDGPUFunctionArgInfo::KERNARG_SEGMENT_PTR); case Intrinsic::amdgcn_implicitarg_ptr: return legalizeImplicitArgPtr(MI, MRI, B); case Intrinsic::amdgcn_workitem_id_x: return legalizeWorkitemIDIntrinsic(MI, MRI, B, 0, AMDGPUFunctionArgInfo::WORKITEM_ID_X); case Intrinsic::amdgcn_workitem_id_y: return legalizeWorkitemIDIntrinsic(MI, MRI, B, 1, AMDGPUFunctionArgInfo::WORKITEM_ID_Y); case Intrinsic::amdgcn_workitem_id_z: return legalizeWorkitemIDIntrinsic(MI, MRI, B, 2, AMDGPUFunctionArgInfo::WORKITEM_ID_Z); case Intrinsic::amdgcn_workgroup_id_x: return legalizePreloadedArgIntrin(MI, MRI, B, AMDGPUFunctionArgInfo::WORKGROUP_ID_X); case Intrinsic::amdgcn_workgroup_id_y: return legalizePreloadedArgIntrin(MI, MRI, B, AMDGPUFunctionArgInfo::WORKGROUP_ID_Y); case Intrinsic::amdgcn_workgroup_id_z: return legalizePreloadedArgIntrin(MI, MRI, B, AMDGPUFunctionArgInfo::WORKGROUP_ID_Z); case Intrinsic::amdgcn_lds_kernel_id: return legalizePreloadedArgIntrin(MI, MRI, B, AMDGPUFunctionArgInfo::LDS_KERNEL_ID); case Intrinsic::amdgcn_dispatch_ptr: return legalizePreloadedArgIntrin(MI, MRI, B, AMDGPUFunctionArgInfo::DISPATCH_PTR); case Intrinsic::amdgcn_queue_ptr: return legalizePreloadedArgIntrin(MI, MRI, B, AMDGPUFunctionArgInfo::QUEUE_PTR); case Intrinsic::amdgcn_implicit_buffer_ptr: return legalizePreloadedArgIntrin( MI, MRI, B, AMDGPUFunctionArgInfo::IMPLICIT_BUFFER_PTR); case Intrinsic::amdgcn_dispatch_id: return legalizePreloadedArgIntrin(MI, MRI, B, AMDGPUFunctionArgInfo::DISPATCH_ID); case Intrinsic::r600_read_ngroups_x: // TODO: Emit error for hsa return legalizeKernargMemParameter(MI, B, SI::KernelInputOffsets::NGROUPS_X); case Intrinsic::r600_read_ngroups_y: return legalizeKernargMemParameter(MI, B, SI::KernelInputOffsets::NGROUPS_Y); case Intrinsic::r600_read_ngroups_z: return legalizeKernargMemParameter(MI, B, SI::KernelInputOffsets::NGROUPS_Z); case Intrinsic::r600_read_local_size_x: // TODO: Could insert G_ASSERT_ZEXT from s16 return legalizeKernargMemParameter(MI, B, SI::KernelInputOffsets::LOCAL_SIZE_X); case Intrinsic::r600_read_local_size_y: // TODO: Could insert G_ASSERT_ZEXT from s16 return legalizeKernargMemParameter(MI, B, SI::KernelInputOffsets::LOCAL_SIZE_Y); // TODO: Could insert G_ASSERT_ZEXT from s16 case Intrinsic::r600_read_local_size_z: return legalizeKernargMemParameter(MI, B, SI::KernelInputOffsets::LOCAL_SIZE_Z); case Intrinsic::r600_read_global_size_x: return legalizeKernargMemParameter(MI, B, SI::KernelInputOffsets::GLOBAL_SIZE_X); case Intrinsic::r600_read_global_size_y: return legalizeKernargMemParameter(MI, B, SI::KernelInputOffsets::GLOBAL_SIZE_Y); case Intrinsic::r600_read_global_size_z: return legalizeKernargMemParameter(MI, B, SI::KernelInputOffsets::GLOBAL_SIZE_Z); case Intrinsic::amdgcn_fdiv_fast: return legalizeFDIVFastIntrin(MI, MRI, B); case Intrinsic::amdgcn_is_shared: return legalizeIsAddrSpace(MI, MRI, B, AMDGPUAS::LOCAL_ADDRESS); case Intrinsic::amdgcn_is_private: return legalizeIsAddrSpace(MI, MRI, B, AMDGPUAS::PRIVATE_ADDRESS); case Intrinsic::amdgcn_wavefrontsize: { B.buildConstant(MI.getOperand(0), ST.getWavefrontSize()); MI.eraseFromParent(); return true; } case Intrinsic::amdgcn_s_buffer_load: return legalizeSBufferLoad(Helper, MI); case Intrinsic::amdgcn_raw_buffer_store: case Intrinsic::amdgcn_struct_buffer_store: return legalizeBufferStore(MI, MRI, B, false, false); case Intrinsic::amdgcn_raw_buffer_store_format: case Intrinsic::amdgcn_struct_buffer_store_format: return legalizeBufferStore(MI, MRI, B, false, true); case Intrinsic::amdgcn_raw_tbuffer_store: case Intrinsic::amdgcn_struct_tbuffer_store: return legalizeBufferStore(MI, MRI, B, true, true); case Intrinsic::amdgcn_raw_buffer_load: case Intrinsic::amdgcn_struct_buffer_load: return legalizeBufferLoad(MI, MRI, B, false, false); case Intrinsic::amdgcn_raw_buffer_load_format: case Intrinsic::amdgcn_struct_buffer_load_format: return legalizeBufferLoad(MI, MRI, B, true, false); case Intrinsic::amdgcn_raw_tbuffer_load: case Intrinsic::amdgcn_struct_tbuffer_load: return legalizeBufferLoad(MI, MRI, B, true, true); case Intrinsic::amdgcn_raw_buffer_atomic_swap: case Intrinsic::amdgcn_struct_buffer_atomic_swap: case Intrinsic::amdgcn_raw_buffer_atomic_add: case Intrinsic::amdgcn_struct_buffer_atomic_add: case Intrinsic::amdgcn_raw_buffer_atomic_sub: case Intrinsic::amdgcn_struct_buffer_atomic_sub: case Intrinsic::amdgcn_raw_buffer_atomic_smin: case Intrinsic::amdgcn_struct_buffer_atomic_smin: case Intrinsic::amdgcn_raw_buffer_atomic_umin: case Intrinsic::amdgcn_struct_buffer_atomic_umin: case Intrinsic::amdgcn_raw_buffer_atomic_smax: case Intrinsic::amdgcn_struct_buffer_atomic_smax: case Intrinsic::amdgcn_raw_buffer_atomic_umax: case Intrinsic::amdgcn_struct_buffer_atomic_umax: case Intrinsic::amdgcn_raw_buffer_atomic_and: case Intrinsic::amdgcn_struct_buffer_atomic_and: case Intrinsic::amdgcn_raw_buffer_atomic_or: case Intrinsic::amdgcn_struct_buffer_atomic_or: case Intrinsic::amdgcn_raw_buffer_atomic_xor: case Intrinsic::amdgcn_struct_buffer_atomic_xor: case Intrinsic::amdgcn_raw_buffer_atomic_inc: case Intrinsic::amdgcn_struct_buffer_atomic_inc: case Intrinsic::amdgcn_raw_buffer_atomic_dec: case Intrinsic::amdgcn_struct_buffer_atomic_dec: case Intrinsic::amdgcn_raw_buffer_atomic_cmpswap: case Intrinsic::amdgcn_struct_buffer_atomic_cmpswap: case Intrinsic::amdgcn_raw_buffer_atomic_fmin: case Intrinsic::amdgcn_struct_buffer_atomic_fmin: case Intrinsic::amdgcn_raw_buffer_atomic_fmax: case Intrinsic::amdgcn_struct_buffer_atomic_fmax: return legalizeBufferAtomic(MI, B, IntrID); case Intrinsic::amdgcn_raw_buffer_atomic_fadd: case Intrinsic::amdgcn_struct_buffer_atomic_fadd: { Register DstReg = MI.getOperand(0).getReg(); if (!MRI.use_empty(DstReg) && !AMDGPU::hasAtomicFaddRtnForTy(ST, MRI.getType(DstReg))) { Function &F = B.getMF().getFunction(); DiagnosticInfoUnsupported NoFpRet( F, "return versions of fp atomics not supported", B.getDebugLoc(), DS_Error); F.getContext().diagnose(NoFpRet); B.buildUndef(DstReg); MI.eraseFromParent(); return true; } return legalizeBufferAtomic(MI, B, IntrID); } case Intrinsic::amdgcn_atomic_inc: return legalizeAtomicIncDec(MI, B, true); case Intrinsic::amdgcn_atomic_dec: return legalizeAtomicIncDec(MI, B, false); case Intrinsic::trap: return legalizeTrapIntrinsic(MI, MRI, B); case Intrinsic::debugtrap: return legalizeDebugTrapIntrinsic(MI, MRI, B); case Intrinsic::amdgcn_rsq_clamp: return legalizeRsqClampIntrinsic(MI, MRI, B); case Intrinsic::amdgcn_ds_fadd: case Intrinsic::amdgcn_ds_fmin: case Intrinsic::amdgcn_ds_fmax: return legalizeDSAtomicFPIntrinsic(Helper, MI, IntrID); case Intrinsic::amdgcn_image_bvh_intersect_ray: return legalizeBVHIntrinsic(MI, B); default: { if (const AMDGPU::ImageDimIntrinsicInfo *ImageDimIntr = AMDGPU::getImageDimIntrinsicInfo(IntrID)) return legalizeImageIntrinsic(MI, B, Helper.Observer, ImageDimIntr); return true; } } return true; }