//===--- AMDGPUHSAMetadataStreamer.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 /// AMDGPU HSA Metadata Streamer. /// // //===----------------------------------------------------------------------===// #include "AMDGPUHSAMetadataStreamer.h" #include "AMDGPU.h" #include "GCNSubtarget.h" #include "MCTargetDesc/AMDGPUTargetStreamer.h" #include "SIMachineFunctionInfo.h" #include "SIProgramInfo.h" #include "llvm/IR/Module.h" using namespace llvm; static std::pair getArgumentTypeAlign(const Argument &Arg, const DataLayout &DL) { Type *Ty = Arg.getType(); MaybeAlign ArgAlign; if (Arg.hasByRefAttr()) { Ty = Arg.getParamByRefType(); ArgAlign = Arg.getParamAlign(); } if (!ArgAlign) ArgAlign = DL.getABITypeAlign(Ty); return std::make_pair(Ty, *ArgAlign); } namespace llvm { static cl::opt DumpHSAMetadata( "amdgpu-dump-hsa-metadata", cl::desc("Dump AMDGPU HSA Metadata")); static cl::opt VerifyHSAMetadata( "amdgpu-verify-hsa-metadata", cl::desc("Verify AMDGPU HSA Metadata")); namespace AMDGPU { namespace HSAMD { //===----------------------------------------------------------------------===// // HSAMetadataStreamerV2 //===----------------------------------------------------------------------===// void MetadataStreamerV2::dump(StringRef HSAMetadataString) const { errs() << "AMDGPU HSA Metadata:\n" << HSAMetadataString << '\n'; } void MetadataStreamerV2::verify(StringRef HSAMetadataString) const { errs() << "AMDGPU HSA Metadata Parser Test: "; HSAMD::Metadata FromHSAMetadataString; if (fromString(HSAMetadataString, FromHSAMetadataString)) { errs() << "FAIL\n"; return; } std::string ToHSAMetadataString; if (toString(FromHSAMetadataString, ToHSAMetadataString)) { errs() << "FAIL\n"; return; } errs() << (HSAMetadataString == ToHSAMetadataString ? "PASS" : "FAIL") << '\n'; if (HSAMetadataString != ToHSAMetadataString) { errs() << "Original input: " << HSAMetadataString << '\n' << "Produced output: " << ToHSAMetadataString << '\n'; } } AccessQualifier MetadataStreamerV2::getAccessQualifier(StringRef AccQual) const { if (AccQual.empty()) return AccessQualifier::Unknown; return StringSwitch(AccQual) .Case("read_only", AccessQualifier::ReadOnly) .Case("write_only", AccessQualifier::WriteOnly) .Case("read_write", AccessQualifier::ReadWrite) .Default(AccessQualifier::Default); } AddressSpaceQualifier MetadataStreamerV2::getAddressSpaceQualifier( unsigned AddressSpace) const { switch (AddressSpace) { case AMDGPUAS::PRIVATE_ADDRESS: return AddressSpaceQualifier::Private; case AMDGPUAS::GLOBAL_ADDRESS: return AddressSpaceQualifier::Global; case AMDGPUAS::CONSTANT_ADDRESS: return AddressSpaceQualifier::Constant; case AMDGPUAS::LOCAL_ADDRESS: return AddressSpaceQualifier::Local; case AMDGPUAS::FLAT_ADDRESS: return AddressSpaceQualifier::Generic; case AMDGPUAS::REGION_ADDRESS: return AddressSpaceQualifier::Region; default: return AddressSpaceQualifier::Unknown; } } ValueKind MetadataStreamerV2::getValueKind(Type *Ty, StringRef TypeQual, StringRef BaseTypeName) const { if (TypeQual.find("pipe") != StringRef::npos) return ValueKind::Pipe; return StringSwitch(BaseTypeName) .Case("image1d_t", ValueKind::Image) .Case("image1d_array_t", ValueKind::Image) .Case("image1d_buffer_t", ValueKind::Image) .Case("image2d_t", ValueKind::Image) .Case("image2d_array_t", ValueKind::Image) .Case("image2d_array_depth_t", ValueKind::Image) .Case("image2d_array_msaa_t", ValueKind::Image) .Case("image2d_array_msaa_depth_t", ValueKind::Image) .Case("image2d_depth_t", ValueKind::Image) .Case("image2d_msaa_t", ValueKind::Image) .Case("image2d_msaa_depth_t", ValueKind::Image) .Case("image3d_t", ValueKind::Image) .Case("sampler_t", ValueKind::Sampler) .Case("queue_t", ValueKind::Queue) .Default(isa(Ty) ? (Ty->getPointerAddressSpace() == AMDGPUAS::LOCAL_ADDRESS ? ValueKind::DynamicSharedPointer : ValueKind::GlobalBuffer) : ValueKind::ByValue); } std::string MetadataStreamerV2::getTypeName(Type *Ty, bool Signed) const { switch (Ty->getTypeID()) { case Type::IntegerTyID: { if (!Signed) return (Twine('u') + getTypeName(Ty, true)).str(); auto BitWidth = Ty->getIntegerBitWidth(); switch (BitWidth) { case 8: return "char"; case 16: return "short"; case 32: return "int"; case 64: return "long"; default: return (Twine('i') + Twine(BitWidth)).str(); } } case Type::HalfTyID: return "half"; case Type::FloatTyID: return "float"; case Type::DoubleTyID: return "double"; case Type::FixedVectorTyID: { auto VecTy = cast(Ty); auto ElTy = VecTy->getElementType(); auto NumElements = VecTy->getNumElements(); return (Twine(getTypeName(ElTy, Signed)) + Twine(NumElements)).str(); } default: return "unknown"; } } std::vector MetadataStreamerV2::getWorkGroupDimensions(MDNode *Node) const { std::vector Dims; if (Node->getNumOperands() != 3) return Dims; for (auto &Op : Node->operands()) Dims.push_back(mdconst::extract(Op)->getZExtValue()); return Dims; } Kernel::CodeProps::Metadata MetadataStreamerV2::getHSACodeProps(const MachineFunction &MF, const SIProgramInfo &ProgramInfo) const { const GCNSubtarget &STM = MF.getSubtarget(); const SIMachineFunctionInfo &MFI = *MF.getInfo(); HSAMD::Kernel::CodeProps::Metadata HSACodeProps; const Function &F = MF.getFunction(); assert(F.getCallingConv() == CallingConv::AMDGPU_KERNEL || F.getCallingConv() == CallingConv::SPIR_KERNEL); Align MaxKernArgAlign; HSACodeProps.mKernargSegmentSize = STM.getKernArgSegmentSize(F, MaxKernArgAlign); HSACodeProps.mGroupSegmentFixedSize = ProgramInfo.LDSSize; HSACodeProps.mPrivateSegmentFixedSize = ProgramInfo.ScratchSize; HSACodeProps.mKernargSegmentAlign = std::max(MaxKernArgAlign, Align(4)).value(); HSACodeProps.mWavefrontSize = STM.getWavefrontSize(); HSACodeProps.mNumSGPRs = ProgramInfo.NumSGPR; HSACodeProps.mNumVGPRs = ProgramInfo.NumVGPR; HSACodeProps.mMaxFlatWorkGroupSize = MFI.getMaxFlatWorkGroupSize(); HSACodeProps.mIsDynamicCallStack = ProgramInfo.DynamicCallStack; HSACodeProps.mIsXNACKEnabled = STM.isXNACKEnabled(); HSACodeProps.mNumSpilledSGPRs = MFI.getNumSpilledSGPRs(); HSACodeProps.mNumSpilledVGPRs = MFI.getNumSpilledVGPRs(); return HSACodeProps; } Kernel::DebugProps::Metadata MetadataStreamerV2::getHSADebugProps(const MachineFunction &MF, const SIProgramInfo &ProgramInfo) const { return HSAMD::Kernel::DebugProps::Metadata(); } void MetadataStreamerV2::emitVersion() { auto &Version = HSAMetadata.mVersion; Version.push_back(VersionMajor); Version.push_back(VersionMinor); } void MetadataStreamerV2::emitPrintf(const Module &Mod) { auto &Printf = HSAMetadata.mPrintf; auto Node = Mod.getNamedMetadata("llvm.printf.fmts"); if (!Node) return; for (auto Op : Node->operands()) if (Op->getNumOperands()) Printf.push_back( std::string(cast(Op->getOperand(0))->getString())); } void MetadataStreamerV2::emitKernelLanguage(const Function &Func) { auto &Kernel = HSAMetadata.mKernels.back(); // TODO: What about other languages? auto Node = Func.getParent()->getNamedMetadata("opencl.ocl.version"); if (!Node || !Node->getNumOperands()) return; auto Op0 = Node->getOperand(0); if (Op0->getNumOperands() <= 1) return; Kernel.mLanguage = "OpenCL C"; Kernel.mLanguageVersion.push_back( mdconst::extract(Op0->getOperand(0))->getZExtValue()); Kernel.mLanguageVersion.push_back( mdconst::extract(Op0->getOperand(1))->getZExtValue()); } void MetadataStreamerV2::emitKernelAttrs(const Function &Func) { auto &Attrs = HSAMetadata.mKernels.back().mAttrs; if (auto Node = Func.getMetadata("reqd_work_group_size")) Attrs.mReqdWorkGroupSize = getWorkGroupDimensions(Node); if (auto Node = Func.getMetadata("work_group_size_hint")) Attrs.mWorkGroupSizeHint = getWorkGroupDimensions(Node); if (auto Node = Func.getMetadata("vec_type_hint")) { Attrs.mVecTypeHint = getTypeName( cast(Node->getOperand(0))->getType(), mdconst::extract(Node->getOperand(1))->getZExtValue()); } if (Func.hasFnAttribute("runtime-handle")) { Attrs.mRuntimeHandle = Func.getFnAttribute("runtime-handle").getValueAsString().str(); } } void MetadataStreamerV2::emitKernelArgs(const Function &Func) { for (auto &Arg : Func.args()) emitKernelArg(Arg); emitHiddenKernelArgs(Func); } void MetadataStreamerV2::emitKernelArg(const Argument &Arg) { auto Func = Arg.getParent(); auto ArgNo = Arg.getArgNo(); const MDNode *Node; StringRef Name; Node = Func->getMetadata("kernel_arg_name"); if (Node && ArgNo < Node->getNumOperands()) Name = cast(Node->getOperand(ArgNo))->getString(); else if (Arg.hasName()) Name = Arg.getName(); StringRef TypeName; Node = Func->getMetadata("kernel_arg_type"); if (Node && ArgNo < Node->getNumOperands()) TypeName = cast(Node->getOperand(ArgNo))->getString(); StringRef BaseTypeName; Node = Func->getMetadata("kernel_arg_base_type"); if (Node && ArgNo < Node->getNumOperands()) BaseTypeName = cast(Node->getOperand(ArgNo))->getString(); StringRef AccQual; if (Arg.getType()->isPointerTy() && Arg.onlyReadsMemory() && Arg.hasNoAliasAttr()) { AccQual = "read_only"; } else { Node = Func->getMetadata("kernel_arg_access_qual"); if (Node && ArgNo < Node->getNumOperands()) AccQual = cast(Node->getOperand(ArgNo))->getString(); } StringRef TypeQual; Node = Func->getMetadata("kernel_arg_type_qual"); if (Node && ArgNo < Node->getNumOperands()) TypeQual = cast(Node->getOperand(ArgNo))->getString(); const DataLayout &DL = Func->getParent()->getDataLayout(); MaybeAlign PointeeAlign; if (auto PtrTy = dyn_cast(Arg.getType())) { if (PtrTy->getAddressSpace() == AMDGPUAS::LOCAL_ADDRESS) { // FIXME: Should report this for all address spaces PointeeAlign = DL.getValueOrABITypeAlignment(Arg.getParamAlign(), PtrTy->getElementType()); } } Type *ArgTy; Align ArgAlign; std::tie(ArgTy, ArgAlign) = getArgumentTypeAlign(Arg, DL); emitKernelArg(DL, ArgTy, ArgAlign, getValueKind(ArgTy, TypeQual, BaseTypeName), PointeeAlign, Name, TypeName, BaseTypeName, AccQual, TypeQual); } void MetadataStreamerV2::emitKernelArg(const DataLayout &DL, Type *Ty, Align Alignment, ValueKind ValueKind, MaybeAlign PointeeAlign, StringRef Name, StringRef TypeName, StringRef BaseTypeName, StringRef AccQual, StringRef TypeQual) { HSAMetadata.mKernels.back().mArgs.push_back(Kernel::Arg::Metadata()); auto &Arg = HSAMetadata.mKernels.back().mArgs.back(); Arg.mName = std::string(Name); Arg.mTypeName = std::string(TypeName); Arg.mSize = DL.getTypeAllocSize(Ty); Arg.mAlign = Alignment.value(); Arg.mValueKind = ValueKind; Arg.mPointeeAlign = PointeeAlign ? PointeeAlign->value() : 0; if (auto PtrTy = dyn_cast(Ty)) Arg.mAddrSpaceQual = getAddressSpaceQualifier(PtrTy->getAddressSpace()); Arg.mAccQual = getAccessQualifier(AccQual); // TODO: Emit Arg.mActualAccQual. SmallVector SplitTypeQuals; TypeQual.split(SplitTypeQuals, " ", -1, false); for (StringRef Key : SplitTypeQuals) { auto P = StringSwitch(Key) .Case("const", &Arg.mIsConst) .Case("restrict", &Arg.mIsRestrict) .Case("volatile", &Arg.mIsVolatile) .Case("pipe", &Arg.mIsPipe) .Default(nullptr); if (P) *P = true; } } void MetadataStreamerV2::emitHiddenKernelArgs(const Function &Func) { int HiddenArgNumBytes = getIntegerAttribute(Func, "amdgpu-implicitarg-num-bytes", 0); if (!HiddenArgNumBytes) return; auto &DL = Func.getParent()->getDataLayout(); auto Int64Ty = Type::getInt64Ty(Func.getContext()); if (HiddenArgNumBytes >= 8) emitKernelArg(DL, Int64Ty, Align(8), ValueKind::HiddenGlobalOffsetX); if (HiddenArgNumBytes >= 16) emitKernelArg(DL, Int64Ty, Align(8), ValueKind::HiddenGlobalOffsetY); if (HiddenArgNumBytes >= 24) emitKernelArg(DL, Int64Ty, Align(8), ValueKind::HiddenGlobalOffsetZ); auto Int8PtrTy = Type::getInt8PtrTy(Func.getContext(), AMDGPUAS::GLOBAL_ADDRESS); // Emit "printf buffer" argument if printf is used, otherwise emit dummy // "none" argument. if (HiddenArgNumBytes >= 32) { if (Func.getParent()->getNamedMetadata("llvm.printf.fmts")) emitKernelArg(DL, Int8PtrTy, Align(8), ValueKind::HiddenPrintfBuffer); else if (Func.getParent()->getFunction("__ockl_hostcall_internal")) { // The printf runtime binding pass should have ensured that hostcall and // printf are not used in the same module. assert(!Func.getParent()->getNamedMetadata("llvm.printf.fmts")); emitKernelArg(DL, Int8PtrTy, Align(8), ValueKind::HiddenHostcallBuffer); } else emitKernelArg(DL, Int8PtrTy, Align(8), ValueKind::HiddenNone); } // Emit "default queue" and "completion action" arguments if enqueue kernel is // used, otherwise emit dummy "none" arguments. if (HiddenArgNumBytes >= 48) { if (Func.hasFnAttribute("calls-enqueue-kernel")) { emitKernelArg(DL, Int8PtrTy, Align(8), ValueKind::HiddenDefaultQueue); emitKernelArg(DL, Int8PtrTy, Align(8), ValueKind::HiddenCompletionAction); } else { emitKernelArg(DL, Int8PtrTy, Align(8), ValueKind::HiddenNone); emitKernelArg(DL, Int8PtrTy, Align(8), ValueKind::HiddenNone); } } // Emit the pointer argument for multi-grid object. if (HiddenArgNumBytes >= 56) emitKernelArg(DL, Int8PtrTy, Align(8), ValueKind::HiddenMultiGridSyncArg); } bool MetadataStreamerV2::emitTo(AMDGPUTargetStreamer &TargetStreamer) { return TargetStreamer.EmitHSAMetadata(getHSAMetadata()); } void MetadataStreamerV2::begin(const Module &Mod) { emitVersion(); emitPrintf(Mod); } void MetadataStreamerV2::end() { std::string HSAMetadataString; if (toString(HSAMetadata, HSAMetadataString)) return; if (DumpHSAMetadata) dump(HSAMetadataString); if (VerifyHSAMetadata) verify(HSAMetadataString); } void MetadataStreamerV2::emitKernel(const MachineFunction &MF, const SIProgramInfo &ProgramInfo) { auto &Func = MF.getFunction(); if (Func.getCallingConv() != CallingConv::AMDGPU_KERNEL) return; auto CodeProps = getHSACodeProps(MF, ProgramInfo); auto DebugProps = getHSADebugProps(MF, ProgramInfo); HSAMetadata.mKernels.push_back(Kernel::Metadata()); auto &Kernel = HSAMetadata.mKernels.back(); Kernel.mName = std::string(Func.getName()); Kernel.mSymbolName = (Twine(Func.getName()) + Twine("@kd")).str(); emitKernelLanguage(Func); emitKernelAttrs(Func); emitKernelArgs(Func); HSAMetadata.mKernels.back().mCodeProps = CodeProps; HSAMetadata.mKernels.back().mDebugProps = DebugProps; } //===----------------------------------------------------------------------===// // HSAMetadataStreamerV3 //===----------------------------------------------------------------------===// void MetadataStreamerV3::dump(StringRef HSAMetadataString) const { errs() << "AMDGPU HSA Metadata:\n" << HSAMetadataString << '\n'; } void MetadataStreamerV3::verify(StringRef HSAMetadataString) const { errs() << "AMDGPU HSA Metadata Parser Test: "; msgpack::Document FromHSAMetadataString; if (!FromHSAMetadataString.fromYAML(HSAMetadataString)) { errs() << "FAIL\n"; return; } std::string ToHSAMetadataString; raw_string_ostream StrOS(ToHSAMetadataString); FromHSAMetadataString.toYAML(StrOS); errs() << (HSAMetadataString == StrOS.str() ? "PASS" : "FAIL") << '\n'; if (HSAMetadataString != ToHSAMetadataString) { errs() << "Original input: " << HSAMetadataString << '\n' << "Produced output: " << StrOS.str() << '\n'; } } Optional MetadataStreamerV3::getAccessQualifier(StringRef AccQual) const { return StringSwitch>(AccQual) .Case("read_only", StringRef("read_only")) .Case("write_only", StringRef("write_only")) .Case("read_write", StringRef("read_write")) .Default(None); } Optional MetadataStreamerV3::getAddressSpaceQualifier(unsigned AddressSpace) const { switch (AddressSpace) { case AMDGPUAS::PRIVATE_ADDRESS: return StringRef("private"); case AMDGPUAS::GLOBAL_ADDRESS: return StringRef("global"); case AMDGPUAS::CONSTANT_ADDRESS: return StringRef("constant"); case AMDGPUAS::LOCAL_ADDRESS: return StringRef("local"); case AMDGPUAS::FLAT_ADDRESS: return StringRef("generic"); case AMDGPUAS::REGION_ADDRESS: return StringRef("region"); default: return None; } } StringRef MetadataStreamerV3::getValueKind(Type *Ty, StringRef TypeQual, StringRef BaseTypeName) const { if (TypeQual.find("pipe") != StringRef::npos) return "pipe"; return StringSwitch(BaseTypeName) .Case("image1d_t", "image") .Case("image1d_array_t", "image") .Case("image1d_buffer_t", "image") .Case("image2d_t", "image") .Case("image2d_array_t", "image") .Case("image2d_array_depth_t", "image") .Case("image2d_array_msaa_t", "image") .Case("image2d_array_msaa_depth_t", "image") .Case("image2d_depth_t", "image") .Case("image2d_msaa_t", "image") .Case("image2d_msaa_depth_t", "image") .Case("image3d_t", "image") .Case("sampler_t", "sampler") .Case("queue_t", "queue") .Default(isa(Ty) ? (Ty->getPointerAddressSpace() == AMDGPUAS::LOCAL_ADDRESS ? "dynamic_shared_pointer" : "global_buffer") : "by_value"); } std::string MetadataStreamerV3::getTypeName(Type *Ty, bool Signed) const { switch (Ty->getTypeID()) { case Type::IntegerTyID: { if (!Signed) return (Twine('u') + getTypeName(Ty, true)).str(); auto BitWidth = Ty->getIntegerBitWidth(); switch (BitWidth) { case 8: return "char"; case 16: return "short"; case 32: return "int"; case 64: return "long"; default: return (Twine('i') + Twine(BitWidth)).str(); } } case Type::HalfTyID: return "half"; case Type::FloatTyID: return "float"; case Type::DoubleTyID: return "double"; case Type::FixedVectorTyID: { auto VecTy = cast(Ty); auto ElTy = VecTy->getElementType(); auto NumElements = VecTy->getNumElements(); return (Twine(getTypeName(ElTy, Signed)) + Twine(NumElements)).str(); } default: return "unknown"; } } msgpack::ArrayDocNode MetadataStreamerV3::getWorkGroupDimensions(MDNode *Node) const { auto Dims = HSAMetadataDoc->getArrayNode(); if (Node->getNumOperands() != 3) return Dims; for (auto &Op : Node->operands()) Dims.push_back(Dims.getDocument()->getNode( uint64_t(mdconst::extract(Op)->getZExtValue()))); return Dims; } void MetadataStreamerV3::emitVersion() { auto Version = HSAMetadataDoc->getArrayNode(); Version.push_back(Version.getDocument()->getNode(VersionMajor)); Version.push_back(Version.getDocument()->getNode(VersionMinor)); getRootMetadata("amdhsa.version") = Version; } void MetadataStreamerV3::emitPrintf(const Module &Mod) { auto Node = Mod.getNamedMetadata("llvm.printf.fmts"); if (!Node) return; auto Printf = HSAMetadataDoc->getArrayNode(); for (auto Op : Node->operands()) if (Op->getNumOperands()) Printf.push_back(Printf.getDocument()->getNode( cast(Op->getOperand(0))->getString(), /*Copy=*/true)); getRootMetadata("amdhsa.printf") = Printf; } void MetadataStreamerV3::emitKernelLanguage(const Function &Func, msgpack::MapDocNode Kern) { // TODO: What about other languages? auto Node = Func.getParent()->getNamedMetadata("opencl.ocl.version"); if (!Node || !Node->getNumOperands()) return; auto Op0 = Node->getOperand(0); if (Op0->getNumOperands() <= 1) return; Kern[".language"] = Kern.getDocument()->getNode("OpenCL C"); auto LanguageVersion = Kern.getDocument()->getArrayNode(); LanguageVersion.push_back(Kern.getDocument()->getNode( mdconst::extract(Op0->getOperand(0))->getZExtValue())); LanguageVersion.push_back(Kern.getDocument()->getNode( mdconst::extract(Op0->getOperand(1))->getZExtValue())); Kern[".language_version"] = LanguageVersion; } void MetadataStreamerV3::emitKernelAttrs(const Function &Func, msgpack::MapDocNode Kern) { if (auto Node = Func.getMetadata("reqd_work_group_size")) Kern[".reqd_workgroup_size"] = getWorkGroupDimensions(Node); if (auto Node = Func.getMetadata("work_group_size_hint")) Kern[".workgroup_size_hint"] = getWorkGroupDimensions(Node); if (auto Node = Func.getMetadata("vec_type_hint")) { Kern[".vec_type_hint"] = Kern.getDocument()->getNode( getTypeName( cast(Node->getOperand(0))->getType(), mdconst::extract(Node->getOperand(1))->getZExtValue()), /*Copy=*/true); } if (Func.hasFnAttribute("runtime-handle")) { Kern[".device_enqueue_symbol"] = Kern.getDocument()->getNode( Func.getFnAttribute("runtime-handle").getValueAsString().str(), /*Copy=*/true); } } void MetadataStreamerV3::emitKernelArgs(const Function &Func, msgpack::MapDocNode Kern) { unsigned Offset = 0; auto Args = HSAMetadataDoc->getArrayNode(); for (auto &Arg : Func.args()) emitKernelArg(Arg, Offset, Args); emitHiddenKernelArgs(Func, Offset, Args); Kern[".args"] = Args; } void MetadataStreamerV3::emitKernelArg(const Argument &Arg, unsigned &Offset, msgpack::ArrayDocNode Args) { auto Func = Arg.getParent(); auto ArgNo = Arg.getArgNo(); const MDNode *Node; StringRef Name; Node = Func->getMetadata("kernel_arg_name"); if (Node && ArgNo < Node->getNumOperands()) Name = cast(Node->getOperand(ArgNo))->getString(); else if (Arg.hasName()) Name = Arg.getName(); StringRef TypeName; Node = Func->getMetadata("kernel_arg_type"); if (Node && ArgNo < Node->getNumOperands()) TypeName = cast(Node->getOperand(ArgNo))->getString(); StringRef BaseTypeName; Node = Func->getMetadata("kernel_arg_base_type"); if (Node && ArgNo < Node->getNumOperands()) BaseTypeName = cast(Node->getOperand(ArgNo))->getString(); StringRef AccQual; if (Arg.getType()->isPointerTy() && Arg.onlyReadsMemory() && Arg.hasNoAliasAttr()) { AccQual = "read_only"; } else { Node = Func->getMetadata("kernel_arg_access_qual"); if (Node && ArgNo < Node->getNumOperands()) AccQual = cast(Node->getOperand(ArgNo))->getString(); } StringRef TypeQual; Node = Func->getMetadata("kernel_arg_type_qual"); if (Node && ArgNo < Node->getNumOperands()) TypeQual = cast(Node->getOperand(ArgNo))->getString(); const DataLayout &DL = Func->getParent()->getDataLayout(); MaybeAlign PointeeAlign; Type *Ty = Arg.hasByRefAttr() ? Arg.getParamByRefType() : Arg.getType(); // FIXME: Need to distinguish in memory alignment from pointer alignment. if (auto PtrTy = dyn_cast(Ty)) { if (PtrTy->getAddressSpace() == AMDGPUAS::LOCAL_ADDRESS) { PointeeAlign = DL.getValueOrABITypeAlignment(Arg.getParamAlign(), PtrTy->getElementType()); } } // There's no distinction between byval aggregates and raw aggregates. Type *ArgTy; Align ArgAlign; std::tie(ArgTy, ArgAlign) = getArgumentTypeAlign(Arg, DL); emitKernelArg(DL, ArgTy, ArgAlign, getValueKind(ArgTy, TypeQual, BaseTypeName), Offset, Args, PointeeAlign, Name, TypeName, BaseTypeName, AccQual, TypeQual); } void MetadataStreamerV3::emitKernelArg( const DataLayout &DL, Type *Ty, Align Alignment, StringRef ValueKind, unsigned &Offset, msgpack::ArrayDocNode Args, MaybeAlign PointeeAlign, StringRef Name, StringRef TypeName, StringRef BaseTypeName, StringRef AccQual, StringRef TypeQual) { auto Arg = Args.getDocument()->getMapNode(); if (!Name.empty()) Arg[".name"] = Arg.getDocument()->getNode(Name, /*Copy=*/true); if (!TypeName.empty()) Arg[".type_name"] = Arg.getDocument()->getNode(TypeName, /*Copy=*/true); auto Size = DL.getTypeAllocSize(Ty); Arg[".size"] = Arg.getDocument()->getNode(Size); Offset = alignTo(Offset, Alignment); Arg[".offset"] = Arg.getDocument()->getNode(Offset); Offset += Size; Arg[".value_kind"] = Arg.getDocument()->getNode(ValueKind, /*Copy=*/true); if (PointeeAlign) Arg[".pointee_align"] = Arg.getDocument()->getNode(PointeeAlign->value()); if (auto PtrTy = dyn_cast(Ty)) if (auto Qualifier = getAddressSpaceQualifier(PtrTy->getAddressSpace())) Arg[".address_space"] = Arg.getDocument()->getNode(*Qualifier, /*Copy=*/true); if (auto AQ = getAccessQualifier(AccQual)) Arg[".access"] = Arg.getDocument()->getNode(*AQ, /*Copy=*/true); // TODO: Emit Arg[".actual_access"]. SmallVector SplitTypeQuals; TypeQual.split(SplitTypeQuals, " ", -1, false); for (StringRef Key : SplitTypeQuals) { if (Key == "const") Arg[".is_const"] = Arg.getDocument()->getNode(true); else if (Key == "restrict") Arg[".is_restrict"] = Arg.getDocument()->getNode(true); else if (Key == "volatile") Arg[".is_volatile"] = Arg.getDocument()->getNode(true); else if (Key == "pipe") Arg[".is_pipe"] = Arg.getDocument()->getNode(true); } Args.push_back(Arg); } void MetadataStreamerV3::emitHiddenKernelArgs(const Function &Func, unsigned &Offset, msgpack::ArrayDocNode Args) { int HiddenArgNumBytes = getIntegerAttribute(Func, "amdgpu-implicitarg-num-bytes", 0); if (!HiddenArgNumBytes) return; auto &DL = Func.getParent()->getDataLayout(); auto Int64Ty = Type::getInt64Ty(Func.getContext()); if (HiddenArgNumBytes >= 8) emitKernelArg(DL, Int64Ty, Align(8), "hidden_global_offset_x", Offset, Args); if (HiddenArgNumBytes >= 16) emitKernelArg(DL, Int64Ty, Align(8), "hidden_global_offset_y", Offset, Args); if (HiddenArgNumBytes >= 24) emitKernelArg(DL, Int64Ty, Align(8), "hidden_global_offset_z", Offset, Args); auto Int8PtrTy = Type::getInt8PtrTy(Func.getContext(), AMDGPUAS::GLOBAL_ADDRESS); // Emit "printf buffer" argument if printf is used, otherwise emit dummy // "none" argument. if (HiddenArgNumBytes >= 32) { if (Func.getParent()->getNamedMetadata("llvm.printf.fmts")) emitKernelArg(DL, Int8PtrTy, Align(8), "hidden_printf_buffer", Offset, Args); else if (Func.getParent()->getFunction("__ockl_hostcall_internal")) { // The printf runtime binding pass should have ensured that hostcall and // printf are not used in the same module. assert(!Func.getParent()->getNamedMetadata("llvm.printf.fmts")); emitKernelArg(DL, Int8PtrTy, Align(8), "hidden_hostcall_buffer", Offset, Args); } else emitKernelArg(DL, Int8PtrTy, Align(8), "hidden_none", Offset, Args); } // Emit "default queue" and "completion action" arguments if enqueue kernel is // used, otherwise emit dummy "none" arguments. if (HiddenArgNumBytes >= 48) { if (Func.hasFnAttribute("calls-enqueue-kernel")) { emitKernelArg(DL, Int8PtrTy, Align(8), "hidden_default_queue", Offset, Args); emitKernelArg(DL, Int8PtrTy, Align(8), "hidden_completion_action", Offset, Args); } else { emitKernelArg(DL, Int8PtrTy, Align(8), "hidden_none", Offset, Args); emitKernelArg(DL, Int8PtrTy, Align(8), "hidden_none", Offset, Args); } } // Emit the pointer argument for multi-grid object. if (HiddenArgNumBytes >= 56) emitKernelArg(DL, Int8PtrTy, Align(8), "hidden_multigrid_sync_arg", Offset, Args); } msgpack::MapDocNode MetadataStreamerV3::getHSAKernelProps(const MachineFunction &MF, const SIProgramInfo &ProgramInfo) const { const GCNSubtarget &STM = MF.getSubtarget(); const SIMachineFunctionInfo &MFI = *MF.getInfo(); const Function &F = MF.getFunction(); auto Kern = HSAMetadataDoc->getMapNode(); Align MaxKernArgAlign; Kern[".kernarg_segment_size"] = Kern.getDocument()->getNode( STM.getKernArgSegmentSize(F, MaxKernArgAlign)); Kern[".group_segment_fixed_size"] = Kern.getDocument()->getNode(ProgramInfo.LDSSize); Kern[".private_segment_fixed_size"] = Kern.getDocument()->getNode(ProgramInfo.ScratchSize); Kern[".kernarg_segment_align"] = Kern.getDocument()->getNode(std::max(Align(4), MaxKernArgAlign).value()); Kern[".wavefront_size"] = Kern.getDocument()->getNode(STM.getWavefrontSize()); Kern[".sgpr_count"] = Kern.getDocument()->getNode(ProgramInfo.NumSGPR); Kern[".vgpr_count"] = Kern.getDocument()->getNode(ProgramInfo.NumVGPR); Kern[".max_flat_workgroup_size"] = Kern.getDocument()->getNode(MFI.getMaxFlatWorkGroupSize()); Kern[".sgpr_spill_count"] = Kern.getDocument()->getNode(MFI.getNumSpilledSGPRs()); Kern[".vgpr_spill_count"] = Kern.getDocument()->getNode(MFI.getNumSpilledVGPRs()); return Kern; } bool MetadataStreamerV3::emitTo(AMDGPUTargetStreamer &TargetStreamer) { return TargetStreamer.EmitHSAMetadata(*HSAMetadataDoc, true); } void MetadataStreamerV3::begin(const Module &Mod) { emitVersion(); emitPrintf(Mod); getRootMetadata("amdhsa.kernels") = HSAMetadataDoc->getArrayNode(); } void MetadataStreamerV3::end() { std::string HSAMetadataString; raw_string_ostream StrOS(HSAMetadataString); HSAMetadataDoc->toYAML(StrOS); if (DumpHSAMetadata) dump(StrOS.str()); if (VerifyHSAMetadata) verify(StrOS.str()); } void MetadataStreamerV3::emitKernel(const MachineFunction &MF, const SIProgramInfo &ProgramInfo) { auto &Func = MF.getFunction(); auto Kern = getHSAKernelProps(MF, ProgramInfo); assert(Func.getCallingConv() == CallingConv::AMDGPU_KERNEL || Func.getCallingConv() == CallingConv::SPIR_KERNEL); auto Kernels = getRootMetadata("amdhsa.kernels").getArray(/*Convert=*/true); { Kern[".name"] = Kern.getDocument()->getNode(Func.getName()); Kern[".symbol"] = Kern.getDocument()->getNode( (Twine(Func.getName()) + Twine(".kd")).str(), /*Copy=*/true); emitKernelLanguage(Func, Kern); emitKernelAttrs(Func, Kern); emitKernelArgs(Func, Kern); } Kernels.push_back(Kern); } } // end namespace HSAMD } // end namespace AMDGPU } // end namespace llvm