//===- DXContainerYAML.cpp - DXContainer YAMLIO implementation ------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file defines classes for handling the YAML representation of // DXContainerYAML. // //===----------------------------------------------------------------------===// #include "llvm/ObjectYAML/DXContainerYAML.h" #include "llvm/ADT/ScopeExit.h" #include "llvm/BinaryFormat/DXContainer.h" #include "llvm/Support/ScopedPrinter.h" namespace llvm { // This assert is duplicated here to leave a breadcrumb of the places that need // to be updated if flags grow past 64-bits. static_assert((uint64_t)dxbc::FeatureFlags::NextUnusedBit <= 1ull << 63, "Shader flag bits exceed enum size."); DXContainerYAML::ShaderFeatureFlags::ShaderFeatureFlags(uint64_t FlagData) { #define SHADER_FEATURE_FLAG(Num, DxilModuleNum, Val, Str) \ Val = (FlagData & (uint64_t)dxbc::FeatureFlags::Val) > 0; #include "llvm/BinaryFormat/DXContainerConstants.def" } uint64_t DXContainerYAML::ShaderFeatureFlags::getEncodedFlags() { uint64_t Flag = 0; #define SHADER_FEATURE_FLAG(Num, DxilModuleNum, Val, Str) \ if (Val) \ Flag |= (uint64_t)dxbc::FeatureFlags::Val; #include "llvm/BinaryFormat/DXContainerConstants.def" return Flag; } DXContainerYAML::ShaderHash::ShaderHash(const dxbc::ShaderHash &Data) : IncludesSource((Data.Flags & static_cast( dxbc::HashFlags::IncludesSource)) != 0), Digest(16, 0) { memcpy(Digest.data(), &Data.Digest[0], 16); } DXContainerYAML::PSVInfo::PSVInfo() : Version(0) { memset(&Info, 0, sizeof(Info)); } DXContainerYAML::PSVInfo::PSVInfo(const dxbc::PSV::v0::RuntimeInfo *P, uint16_t Stage) : Version(0) { memset(&Info, 0, sizeof(Info)); memcpy(&Info, P, sizeof(dxbc::PSV::v0::RuntimeInfo)); assert(Stage < std::numeric_limits::max() && "Stage should be a very small number"); // We need to bring the stage in separately since it isn't part of the v1 data // structure. Info.ShaderStage = static_cast(Stage); } DXContainerYAML::PSVInfo::PSVInfo(const dxbc::PSV::v1::RuntimeInfo *P) : Version(1) { memset(&Info, 0, sizeof(Info)); memcpy(&Info, P, sizeof(dxbc::PSV::v1::RuntimeInfo)); } DXContainerYAML::PSVInfo::PSVInfo(const dxbc::PSV::v2::RuntimeInfo *P) : Version(2) { memset(&Info, 0, sizeof(Info)); memcpy(&Info, P, sizeof(dxbc::PSV::v2::RuntimeInfo)); } DXContainerYAML::PSVInfo::PSVInfo(const dxbc::PSV::v3::RuntimeInfo *P, StringRef StringTable) : Version(3), EntryName(StringTable.substr(P->EntryNameOffset, StringTable.find('\0', P->EntryNameOffset) - P->EntryNameOffset)) { memset(&Info, 0, sizeof(Info)); memcpy(&Info, P, sizeof(dxbc::PSV::v3::RuntimeInfo)); } namespace yaml { void MappingTraits::mapping( IO &IO, DXContainerYAML::VersionTuple &Version) { IO.mapRequired("Major", Version.Major); IO.mapRequired("Minor", Version.Minor); } void MappingTraits::mapping( IO &IO, DXContainerYAML::FileHeader &Header) { IO.mapRequired("Hash", Header.Hash); IO.mapRequired("Version", Header.Version); IO.mapOptional("FileSize", Header.FileSize); IO.mapRequired("PartCount", Header.PartCount); IO.mapOptional("PartOffsets", Header.PartOffsets); } void MappingTraits::mapping( IO &IO, DXContainerYAML::DXILProgram &Program) { IO.mapRequired("MajorVersion", Program.MajorVersion); IO.mapRequired("MinorVersion", Program.MinorVersion); IO.mapRequired("ShaderKind", Program.ShaderKind); IO.mapOptional("Size", Program.Size); IO.mapRequired("DXILMajorVersion", Program.DXILMajorVersion); IO.mapRequired("DXILMinorVersion", Program.DXILMinorVersion); IO.mapOptional("DXILSize", Program.DXILSize); IO.mapOptional("DXIL", Program.DXIL); } void MappingTraits::mapping( IO &IO, DXContainerYAML::ShaderFeatureFlags &Flags) { #define SHADER_FEATURE_FLAG(Num, DxilModuleNum, Val, Str) \ IO.mapRequired(#Val, Flags.Val); #include "llvm/BinaryFormat/DXContainerConstants.def" } void MappingTraits::mapping( IO &IO, DXContainerYAML::ShaderHash &Hash) { IO.mapRequired("IncludesSource", Hash.IncludesSource); IO.mapRequired("Digest", Hash.Digest); } void MappingTraits::mapping( IO &IO, DXContainerYAML::PSVInfo &PSV) { IO.mapRequired("Version", PSV.Version); // Store the PSV version in the YAML context. void *OldContext = IO.getContext(); uint32_t Version = PSV.Version; IO.setContext(&Version); // Restore the YAML context on function exit. auto RestoreContext = make_scope_exit([&]() { IO.setContext(OldContext); }); // Shader stage is only included in binaries for v1 and later, but we always // include it since it simplifies parsing and file construction. IO.mapRequired("ShaderStage", PSV.Info.ShaderStage); PSV.mapInfoForVersion(IO); IO.mapRequired("ResourceStride", PSV.ResourceStride); IO.mapRequired("Resources", PSV.Resources); if (PSV.Version == 0) return; IO.mapRequired("SigInputElements", PSV.SigInputElements); IO.mapRequired("SigOutputElements", PSV.SigOutputElements); IO.mapRequired("SigPatchOrPrimElements", PSV.SigPatchOrPrimElements); Triple::EnvironmentType Stage = dxbc::getShaderStage(PSV.Info.ShaderStage); if (PSV.Info.UsesViewID) { MutableArrayRef> MutableOutMasks( PSV.OutputVectorMasks); IO.mapRequired("OutputVectorMasks", MutableOutMasks); if (Stage == Triple::EnvironmentType::Hull) IO.mapRequired("PatchOrPrimMasks", PSV.PatchOrPrimMasks); } MutableArrayRef> MutableIOMap( PSV.InputOutputMap); IO.mapRequired("InputOutputMap", MutableIOMap); if (Stage == Triple::EnvironmentType::Hull) IO.mapRequired("InputPatchMap", PSV.InputPatchMap); if (Stage == Triple::EnvironmentType::Domain) IO.mapRequired("PatchOutputMap", PSV.PatchOutputMap); } void MappingTraits::mapping( IO &IO, DXContainerYAML::SignatureParameter &S) { IO.mapRequired("Stream", S.Stream); IO.mapRequired("Name", S.Name); IO.mapRequired("Index", S.Index); IO.mapRequired("SystemValue", S.SystemValue); IO.mapRequired("CompType", S.CompType); IO.mapRequired("Register", S.Register); IO.mapRequired("Mask", S.Mask); IO.mapRequired("ExclusiveMask", S.ExclusiveMask); IO.mapRequired("MinPrecision", S.MinPrecision); } void MappingTraits::mapping( IO &IO, DXContainerYAML::Signature &S) { IO.mapRequired("Parameters", S.Parameters); } void MappingTraits::mapping(IO &IO, DXContainerYAML::Part &P) { IO.mapRequired("Name", P.Name); IO.mapRequired("Size", P.Size); IO.mapOptional("Program", P.Program); IO.mapOptional("Flags", P.Flags); IO.mapOptional("Hash", P.Hash); IO.mapOptional("PSVInfo", P.Info); IO.mapOptional("Signature", P.Signature); } void MappingTraits::mapping( IO &IO, DXContainerYAML::Object &Obj) { IO.mapTag("!dxcontainer", true); IO.mapRequired("Header", Obj.Header); IO.mapRequired("Parts", Obj.Parts); } void MappingTraits::mapping( IO &IO, DXContainerYAML::ResourceBindInfo &Res) { IO.mapRequired("Type", Res.Type); IO.mapRequired("Space", Res.Space); IO.mapRequired("LowerBound", Res.LowerBound); IO.mapRequired("UpperBound", Res.UpperBound); const uint32_t *PSVVersion = static_cast(IO.getContext()); if (*PSVVersion < 2) return; IO.mapRequired("Kind", Res.Kind); IO.mapRequired("Flags", Res.Flags); } void MappingTraits::mapping( IO &IO, DXContainerYAML::SignatureElement &El) { IO.mapRequired("Name", El.Name); IO.mapRequired("Indices", El.Indices); IO.mapRequired("StartRow", El.StartRow); IO.mapRequired("Cols", El.Cols); IO.mapRequired("StartCol", El.StartCol); IO.mapRequired("Allocated", El.Allocated); IO.mapRequired("Kind", El.Kind); IO.mapRequired("ComponentType", El.Type); IO.mapRequired("Interpolation", El.Mode); IO.mapRequired("DynamicMask", El.DynamicMask); IO.mapRequired("Stream", El.Stream); } void ScalarEnumerationTraits::enumeration( IO &IO, dxbc::PSV::SemanticKind &Value) { for (const auto &E : dxbc::PSV::getSemanticKinds()) IO.enumCase(Value, E.Name.str().c_str(), E.Value); } void ScalarEnumerationTraits::enumeration( IO &IO, dxbc::PSV::ComponentType &Value) { for (const auto &E : dxbc::PSV::getComponentTypes()) IO.enumCase(Value, E.Name.str().c_str(), E.Value); } void ScalarEnumerationTraits::enumeration( IO &IO, dxbc::PSV::InterpolationMode &Value) { for (const auto &E : dxbc::PSV::getInterpolationModes()) IO.enumCase(Value, E.Name.str().c_str(), E.Value); } void ScalarEnumerationTraits::enumeration( IO &IO, dxbc::D3DSystemValue &Value) { for (const auto &E : dxbc::getD3DSystemValues()) IO.enumCase(Value, E.Name.str().c_str(), E.Value); } void ScalarEnumerationTraits::enumeration( IO &IO, dxbc::SigMinPrecision &Value) { for (const auto &E : dxbc::getSigMinPrecisions()) IO.enumCase(Value, E.Name.str().c_str(), E.Value); } void ScalarEnumerationTraits::enumeration( IO &IO, dxbc::SigComponentType &Value) { for (const auto &E : dxbc::getSigComponentTypes()) IO.enumCase(Value, E.Name.str().c_str(), E.Value); } } // namespace yaml void DXContainerYAML::PSVInfo::mapInfoForVersion(yaml::IO &IO) { dxbc::PipelinePSVInfo &StageInfo = Info.StageInfo; Triple::EnvironmentType Stage = dxbc::getShaderStage(Info.ShaderStage); switch (Stage) { case Triple::EnvironmentType::Pixel: IO.mapRequired("DepthOutput", StageInfo.PS.DepthOutput); IO.mapRequired("SampleFrequency", StageInfo.PS.SampleFrequency); break; case Triple::EnvironmentType::Vertex: IO.mapRequired("OutputPositionPresent", StageInfo.VS.OutputPositionPresent); break; case Triple::EnvironmentType::Geometry: IO.mapRequired("InputPrimitive", StageInfo.GS.InputPrimitive); IO.mapRequired("OutputTopology", StageInfo.GS.OutputTopology); IO.mapRequired("OutputStreamMask", StageInfo.GS.OutputStreamMask); IO.mapRequired("OutputPositionPresent", StageInfo.GS.OutputPositionPresent); break; case Triple::EnvironmentType::Hull: IO.mapRequired("InputControlPointCount", StageInfo.HS.InputControlPointCount); IO.mapRequired("OutputControlPointCount", StageInfo.HS.OutputControlPointCount); IO.mapRequired("TessellatorDomain", StageInfo.HS.TessellatorDomain); IO.mapRequired("TessellatorOutputPrimitive", StageInfo.HS.TessellatorOutputPrimitive); break; case Triple::EnvironmentType::Domain: IO.mapRequired("InputControlPointCount", StageInfo.DS.InputControlPointCount); IO.mapRequired("OutputPositionPresent", StageInfo.DS.OutputPositionPresent); IO.mapRequired("TessellatorDomain", StageInfo.DS.TessellatorDomain); break; case Triple::EnvironmentType::Mesh: IO.mapRequired("GroupSharedBytesUsed", StageInfo.MS.GroupSharedBytesUsed); IO.mapRequired("GroupSharedBytesDependentOnViewID", StageInfo.MS.GroupSharedBytesDependentOnViewID); IO.mapRequired("PayloadSizeInBytes", StageInfo.MS.PayloadSizeInBytes); IO.mapRequired("MaxOutputVertices", StageInfo.MS.MaxOutputVertices); IO.mapRequired("MaxOutputPrimitives", StageInfo.MS.MaxOutputPrimitives); break; case Triple::EnvironmentType::Amplification: IO.mapRequired("PayloadSizeInBytes", StageInfo.AS.PayloadSizeInBytes); break; default: break; } IO.mapRequired("MinimumWaveLaneCount", Info.MinimumWaveLaneCount); IO.mapRequired("MaximumWaveLaneCount", Info.MaximumWaveLaneCount); if (Version == 0) return; IO.mapRequired("UsesViewID", Info.UsesViewID); switch (Stage) { case Triple::EnvironmentType::Geometry: IO.mapRequired("MaxVertexCount", Info.GeomData.MaxVertexCount); break; case Triple::EnvironmentType::Hull: case Triple::EnvironmentType::Domain: IO.mapRequired("SigPatchConstOrPrimVectors", Info.GeomData.SigPatchConstOrPrimVectors); break; case Triple::EnvironmentType::Mesh: IO.mapRequired("SigPrimVectors", Info.GeomData.MeshInfo.SigPrimVectors); IO.mapRequired("MeshOutputTopology", Info.GeomData.MeshInfo.MeshOutputTopology); break; default: break; } IO.mapRequired("SigInputVectors", Info.SigInputVectors); MutableArrayRef Vec(Info.SigOutputVectors); IO.mapRequired("SigOutputVectors", Vec); if (Version == 1) return; IO.mapRequired("NumThreadsX", Info.NumThreadsX); IO.mapRequired("NumThreadsY", Info.NumThreadsY); IO.mapRequired("NumThreadsZ", Info.NumThreadsZ); if (Version == 2) return; IO.mapRequired("EntryName", EntryName); } } // namespace llvm