//===- DXContainerEmitter.cpp - Convert YAML to a DXContainer -------------===// // // 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 /// Binary emitter for yaml to DXContainer binary /// //===----------------------------------------------------------------------===// #include "llvm/BinaryFormat/DXContainer.h" #include "llvm/MC/DXContainerPSVInfo.h" #include "llvm/ObjectYAML/ObjectYAML.h" #include "llvm/ObjectYAML/yaml2obj.h" #include "llvm/Support/Errc.h" #include "llvm/Support/Error.h" #include "llvm/Support/raw_ostream.h" using namespace llvm; namespace { class DXContainerWriter { public: DXContainerWriter(DXContainerYAML::Object &ObjectFile) : ObjectFile(ObjectFile) {} Error write(raw_ostream &OS); private: DXContainerYAML::Object &ObjectFile; Error computePartOffsets(); Error validatePartOffsets(); Error validateSize(uint32_t Computed); void writeHeader(raw_ostream &OS); void writeParts(raw_ostream &OS); }; } // namespace Error DXContainerWriter::validateSize(uint32_t Computed) { if (!ObjectFile.Header.FileSize) ObjectFile.Header.FileSize = Computed; else if (*ObjectFile.Header.FileSize < Computed) return createStringError(errc::result_out_of_range, "File size specified is too small."); return Error::success(); } Error DXContainerWriter::validatePartOffsets() { if (ObjectFile.Parts.size() != ObjectFile.Header.PartOffsets->size()) return createStringError( errc::invalid_argument, "Mismatch between number of parts and part offsets."); uint32_t RollingOffset = sizeof(dxbc::Header) + (ObjectFile.Header.PartCount * sizeof(uint32_t)); for (auto I : llvm::zip(ObjectFile.Parts, *ObjectFile.Header.PartOffsets)) { if (RollingOffset > std::get<1>(I)) return createStringError(errc::invalid_argument, "Offset mismatch, not enough space for data."); RollingOffset = std::get<1>(I) + sizeof(dxbc::PartHeader) + std::get<0>(I).Size; } if (Error Err = validateSize(RollingOffset)) return Err; return Error::success(); } Error DXContainerWriter::computePartOffsets() { if (ObjectFile.Header.PartOffsets) return validatePartOffsets(); uint32_t RollingOffset = sizeof(dxbc::Header) + (ObjectFile.Header.PartCount * sizeof(uint32_t)); ObjectFile.Header.PartOffsets = std::vector(); for (const auto &Part : ObjectFile.Parts) { ObjectFile.Header.PartOffsets->push_back(RollingOffset); RollingOffset += sizeof(dxbc::PartHeader) + Part.Size; } if (Error Err = validateSize(RollingOffset)) return Err; return Error::success(); } void DXContainerWriter::writeHeader(raw_ostream &OS) { dxbc::Header Header; memcpy(Header.Magic, "DXBC", 4); memcpy(Header.FileHash.Digest, ObjectFile.Header.Hash.data(), 16); Header.Version.Major = ObjectFile.Header.Version.Major; Header.Version.Minor = ObjectFile.Header.Version.Minor; Header.FileSize = *ObjectFile.Header.FileSize; Header.PartCount = ObjectFile.Parts.size(); if (sys::IsBigEndianHost) Header.swapBytes(); OS.write(reinterpret_cast(&Header), sizeof(Header)); SmallVector Offsets(ObjectFile.Header.PartOffsets->begin(), ObjectFile.Header.PartOffsets->end()); if (sys::IsBigEndianHost) for (auto &O : Offsets) sys::swapByteOrder(O); OS.write(reinterpret_cast(Offsets.data()), Offsets.size() * sizeof(uint32_t)); } void DXContainerWriter::writeParts(raw_ostream &OS) { uint32_t RollingOffset = sizeof(dxbc::Header) + (ObjectFile.Header.PartCount * sizeof(uint32_t)); for (auto I : llvm::zip(ObjectFile.Parts, *ObjectFile.Header.PartOffsets)) { if (RollingOffset < std::get<1>(I)) { uint32_t PadBytes = std::get<1>(I) - RollingOffset; OS.write_zeros(PadBytes); } DXContainerYAML::Part P = std::get<0>(I); RollingOffset = std::get<1>(I) + sizeof(dxbc::PartHeader); uint32_t PartSize = P.Size; OS.write(P.Name.c_str(), 4); if (sys::IsBigEndianHost) sys::swapByteOrder(P.Size); OS.write(reinterpret_cast(&P.Size), sizeof(uint32_t)); dxbc::PartType PT = dxbc::parsePartType(P.Name); uint64_t DataStart = OS.tell(); switch (PT) { case dxbc::PartType::DXIL: { if (!P.Program) continue; dxbc::ProgramHeader Header; Header.Version = dxbc::ProgramHeader::getVersion(P.Program->MajorVersion, P.Program->MinorVersion); Header.Unused = 0; Header.ShaderKind = P.Program->ShaderKind; memcpy(Header.Bitcode.Magic, "DXIL", 4); Header.Bitcode.MajorVersion = P.Program->DXILMajorVersion; Header.Bitcode.MinorVersion = P.Program->DXILMinorVersion; Header.Bitcode.Unused = 0; // Compute the optional fields if needed... if (P.Program->DXILOffset) Header.Bitcode.Offset = *P.Program->DXILOffset; else Header.Bitcode.Offset = sizeof(dxbc::BitcodeHeader); if (P.Program->DXILSize) Header.Bitcode.Size = *P.Program->DXILSize; else Header.Bitcode.Size = P.Program->DXIL ? P.Program->DXIL->size() : 0; if (P.Program->Size) Header.Size = *P.Program->Size; else Header.Size = sizeof(dxbc::ProgramHeader) + Header.Bitcode.Size; uint32_t BitcodeOffset = Header.Bitcode.Offset; if (sys::IsBigEndianHost) Header.swapBytes(); OS.write(reinterpret_cast(&Header), sizeof(dxbc::ProgramHeader)); if (P.Program->DXIL) { if (BitcodeOffset > sizeof(dxbc::BitcodeHeader)) { uint32_t PadBytes = BitcodeOffset - sizeof(dxbc::BitcodeHeader); OS.write_zeros(PadBytes); } OS.write(reinterpret_cast(P.Program->DXIL->data()), P.Program->DXIL->size()); } break; } case dxbc::PartType::SFI0: { // If we don't have any flags we can continue here and the data will be // zeroed out. if (!P.Flags.has_value()) continue; uint64_t Flags = P.Flags->getEncodedFlags(); if (sys::IsBigEndianHost) sys::swapByteOrder(Flags); OS.write(reinterpret_cast(&Flags), sizeof(uint64_t)); break; } case dxbc::PartType::HASH: { if (!P.Hash.has_value()) continue; dxbc::ShaderHash Hash = {0, {0}}; if (P.Hash->IncludesSource) Hash.Flags |= static_cast(dxbc::HashFlags::IncludesSource); memcpy(&Hash.Digest[0], &P.Hash->Digest[0], 16); if (sys::IsBigEndianHost) Hash.swapBytes(); OS.write(reinterpret_cast(&Hash), sizeof(dxbc::ShaderHash)); break; } case dxbc::PartType::PSV0: { if (!P.Info.has_value()) continue; mcdxbc::PSVRuntimeInfo PSV; memcpy(&PSV.BaseData, &P.Info->Info, sizeof(dxbc::PSV::v3::RuntimeInfo)); PSV.Resources = P.Info->Resources; PSV.EntryName = P.Info->EntryName; for (auto El : P.Info->SigInputElements) PSV.InputElements.push_back(mcdxbc::PSVSignatureElement{ El.Name, El.Indices, El.StartRow, El.Cols, El.StartCol, El.Allocated, El.Kind, El.Type, El.Mode, El.DynamicMask, El.Stream}); for (auto El : P.Info->SigOutputElements) PSV.OutputElements.push_back(mcdxbc::PSVSignatureElement{ El.Name, El.Indices, El.StartRow, El.Cols, El.StartCol, El.Allocated, El.Kind, El.Type, El.Mode, El.DynamicMask, El.Stream}); for (auto El : P.Info->SigPatchOrPrimElements) PSV.PatchOrPrimElements.push_back(mcdxbc::PSVSignatureElement{ El.Name, El.Indices, El.StartRow, El.Cols, El.StartCol, El.Allocated, El.Kind, El.Type, El.Mode, El.DynamicMask, El.Stream}); static_assert(PSV.OutputVectorMasks.size() == PSV.InputOutputMap.size()); for (unsigned I = 0; I < PSV.OutputVectorMasks.size(); ++I) { PSV.OutputVectorMasks[I].insert(PSV.OutputVectorMasks[I].begin(), P.Info->OutputVectorMasks[I].begin(), P.Info->OutputVectorMasks[I].end()); PSV.InputOutputMap[I].insert(PSV.InputOutputMap[I].begin(), P.Info->InputOutputMap[I].begin(), P.Info->InputOutputMap[I].end()); } PSV.PatchOrPrimMasks.insert(PSV.PatchOrPrimMasks.begin(), P.Info->PatchOrPrimMasks.begin(), P.Info->PatchOrPrimMasks.end()); PSV.InputPatchMap.insert(PSV.InputPatchMap.begin(), P.Info->InputPatchMap.begin(), P.Info->InputPatchMap.end()); PSV.PatchOutputMap.insert(PSV.PatchOutputMap.begin(), P.Info->PatchOutputMap.begin(), P.Info->PatchOutputMap.end()); PSV.finalize(static_cast( Triple::Pixel + P.Info->Info.ShaderStage)); PSV.write(OS, P.Info->Version); break; } case dxbc::PartType::ISG1: case dxbc::PartType::OSG1: case dxbc::PartType::PSG1: { mcdxbc::Signature Sig; if (P.Signature.has_value()) { for (const auto &Param : P.Signature->Parameters) { Sig.addParam(Param.Stream, Param.Name, Param.Index, Param.SystemValue, Param.CompType, Param.Register, Param.Mask, Param.ExclusiveMask, Param.MinPrecision); } } Sig.write(OS); break; } case dxbc::PartType::Unknown: break; // Skip any handling for unrecognized parts. } uint64_t BytesWritten = OS.tell() - DataStart; RollingOffset += BytesWritten; if (BytesWritten < PartSize) OS.write_zeros(PartSize - BytesWritten); RollingOffset += PartSize; } } Error DXContainerWriter::write(raw_ostream &OS) { if (Error Err = computePartOffsets()) return Err; writeHeader(OS); writeParts(OS); return Error::success(); } namespace llvm { namespace yaml { bool yaml2dxcontainer(DXContainerYAML::Object &Doc, raw_ostream &Out, ErrorHandler EH) { DXContainerWriter Writer(Doc); if (Error Err = Writer.write(Out)) { handleAllErrors(std::move(Err), [&](const ErrorInfoBase &Err) { EH(Err.message()); }); return false; } return true; } } // namespace yaml } // namespace llvm