//===- DbiModuleList.cpp - PDB module information list --------------------===// // // 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 // //===----------------------------------------------------------------------===// #include "llvm/DebugInfo/PDB/Native/DbiModuleList.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/iterator_range.h" #include "llvm/DebugInfo/PDB/Native/RawError.h" #include "llvm/Support/BinaryStreamReader.h" #include "llvm/Support/Error.h" #include #include #include #include using namespace llvm; using namespace llvm::pdb; DbiModuleSourceFilesIterator::DbiModuleSourceFilesIterator( const DbiModuleList &Modules, uint32_t Modi, uint16_t Filei) : Modules(&Modules), Modi(Modi), Filei(Filei) { setValue(); } bool DbiModuleSourceFilesIterator:: operator==(const DbiModuleSourceFilesIterator &R) const { // incompatible iterators are never equal if (!isCompatible(R)) return false; // If they're compatible, and they're both ends, then they're equal. if (isEnd() && R.isEnd()) return true; // If one is an end and the other is not, they're not equal. if (isEnd() != R.isEnd()) return false; // Now we know: // - They're compatible // - They're not *both* end iterators // - Their endness is the same. // Thus, they're compatible iterators pointing to a valid file on the same // module. All we need to check are the file indices. assert(Modules == R.Modules); assert(Modi == R.Modi); assert(!isEnd()); assert(!R.isEnd()); return (Filei == R.Filei); } bool DbiModuleSourceFilesIterator:: operator<(const DbiModuleSourceFilesIterator &R) const { assert(isCompatible(R)); // It's not sufficient to compare the file indices, because default // constructed iterators could be equal to iterators with valid indices. To // account for this, early-out if they're equal. if (*this == R) return false; return Filei < R.Filei; } std::ptrdiff_t DbiModuleSourceFilesIterator:: operator-(const DbiModuleSourceFilesIterator &R) const { assert(isCompatible(R)); assert(!(*this < R)); // If they're both end iterators, the distance is 0. if (isEnd() && R.isEnd()) return 0; assert(!R.isEnd()); // At this point, R cannot be end, but *this can, which means that *this // might be a universal end iterator with none of its fields set. So in that // case have to rely on R as the authority to figure out how many files there // are to compute the distance. uint32_t Thisi = Filei; if (isEnd()) { uint32_t RealModi = R.Modi; Thisi = R.Modules->getSourceFileCount(RealModi); } assert(Thisi >= R.Filei); return Thisi - R.Filei; } DbiModuleSourceFilesIterator &DbiModuleSourceFilesIterator:: operator+=(std::ptrdiff_t N) { assert(!isEnd()); Filei += N; assert(Filei <= Modules->getSourceFileCount(Modi)); setValue(); return *this; } DbiModuleSourceFilesIterator &DbiModuleSourceFilesIterator:: operator-=(std::ptrdiff_t N) { // Note that we can subtract from an end iterator, but not a universal end // iterator. assert(!isUniversalEnd()); assert(N <= Filei); Filei -= N; return *this; } void DbiModuleSourceFilesIterator::setValue() { if (isEnd()) { ThisValue = ""; return; } uint32_t Off = Modules->ModuleInitialFileIndex[Modi] + Filei; auto ExpectedValue = Modules->getFileName(Off); if (!ExpectedValue) { consumeError(ExpectedValue.takeError()); Filei = Modules->getSourceFileCount(Modi); } else ThisValue = *ExpectedValue; } bool DbiModuleSourceFilesIterator::isEnd() const { if (isUniversalEnd()) return true; assert(Modules); assert(Modi <= Modules->getModuleCount()); assert(Filei <= Modules->getSourceFileCount(Modi)); if (Modi == Modules->getModuleCount()) return true; if (Filei == Modules->getSourceFileCount(Modi)) return true; return false; } bool DbiModuleSourceFilesIterator::isUniversalEnd() const { return !Modules; } bool DbiModuleSourceFilesIterator::isCompatible( const DbiModuleSourceFilesIterator &R) const { // Universal iterators are compatible with any other iterator. if (isUniversalEnd() || R.isUniversalEnd()) return true; // At this point, neither iterator is a universal end iterator, although one // or both might be non-universal end iterators. Regardless, the module index // is valid, so they are compatible if and only if they refer to the same // module. return Modi == R.Modi; } Error DbiModuleList::initialize(BinaryStreamRef ModInfo, BinaryStreamRef FileInfo) { if (auto EC = initializeModInfo(ModInfo)) return EC; if (auto EC = initializeFileInfo(FileInfo)) return EC; return Error::success(); } Error DbiModuleList::initializeModInfo(BinaryStreamRef ModInfo) { ModInfoSubstream = ModInfo; if (ModInfo.getLength() == 0) return Error::success(); BinaryStreamReader Reader(ModInfo); if (auto EC = Reader.readArray(Descriptors, ModInfo.getLength())) return EC; return Error::success(); } Error DbiModuleList::initializeFileInfo(BinaryStreamRef FileInfo) { FileInfoSubstream = FileInfo; if (FileInfo.getLength() == 0) return Error::success(); BinaryStreamReader FISR(FileInfo); if (auto EC = FISR.readObject(FileInfoHeader)) return EC; // First is an array of `NumModules` module indices. This does not seem to be // used for anything meaningful, so we ignore it. FixedStreamArray ModuleIndices; if (auto EC = FISR.readArray(ModuleIndices, FileInfoHeader->NumModules)) return EC; if (auto EC = FISR.readArray(ModFileCountArray, FileInfoHeader->NumModules)) return EC; // Compute the real number of source files. We can't trust the value in // `FileInfoHeader->NumSourceFiles` because it is a unit16, and the sum of all // source file counts might be larger than a unit16. So we compute the real // count by summing up the individual counts. uint32_t NumSourceFiles = 0; for (auto Count : ModFileCountArray) NumSourceFiles += Count; // In the reference implementation, this array is where the pointer documented // at the definition of ModuleInfoHeader::FileNameOffs points to. Note that // although the field in ModuleInfoHeader is ignored this array is not, as it // is the authority on where each filename begins in the names buffer. if (auto EC = FISR.readArray(FileNameOffsets, NumSourceFiles)) return EC; if (auto EC = FISR.readStreamRef(NamesBuffer)) return EC; auto DescriptorIter = Descriptors.begin(); uint32_t NextFileIndex = 0; ModuleInitialFileIndex.resize(FileInfoHeader->NumModules); ModuleDescriptorOffsets.resize(FileInfoHeader->NumModules); for (size_t I = 0; I < FileInfoHeader->NumModules; ++I) { assert(DescriptorIter != Descriptors.end()); ModuleInitialFileIndex[I] = NextFileIndex; ModuleDescriptorOffsets[I] = DescriptorIter.offset(); NextFileIndex += ModFileCountArray[I]; ++DescriptorIter; } assert(DescriptorIter == Descriptors.end()); assert(NextFileIndex == NumSourceFiles); return Error::success(); } uint32_t DbiModuleList::getModuleCount() const { return FileInfoHeader->NumModules; } uint32_t DbiModuleList::getSourceFileCount() const { return FileNameOffsets.size(); } uint16_t DbiModuleList::getSourceFileCount(uint32_t Modi) const { return ModFileCountArray[Modi]; } DbiModuleDescriptor DbiModuleList::getModuleDescriptor(uint32_t Modi) const { assert(Modi < getModuleCount()); uint32_t Offset = ModuleDescriptorOffsets[Modi]; auto Iter = Descriptors.at(Offset); assert(Iter != Descriptors.end()); return *Iter; } iterator_range DbiModuleList::source_files(uint32_t Modi) const { return make_range( DbiModuleSourceFilesIterator(*this, Modi, 0), DbiModuleSourceFilesIterator()); } Expected DbiModuleList::getFileName(uint32_t Index) const { BinaryStreamReader Names(NamesBuffer); if (Index >= getSourceFileCount()) return make_error(raw_error_code::index_out_of_bounds); uint32_t FileOffset = FileNameOffsets[Index]; Names.setOffset(FileOffset); StringRef Name; if (auto EC = Names.readCString(Name)) return std::move(EC); return Name; }