Files
clang-p2996/llvm/lib/DebugInfo/PDB/Native/DbiStreamBuilder.cpp
Zachary Turner 6c4bfba8f3 [PDB] Teach libpdb to write DBI Stream ECNames.
Based strictly on the name, this seems to have something to do
width edit & continue.  The goal of this patch has nothing to do
with supporting edit and continue though.  msvc link.exe writes
very basic information into this area even when *not* compiling
with support for E&C, and so the goal here is to bring lld-link
to parity.  Since we cannot know what assumptions standard tools
make about the content of PDB files, we need to be as close as
possible.

This ECNames data structure is a standard PDB string hash table.
link.exe puts a single string into this hash table, which is the
full path to the PDB file on disk.  It then references this string
from the module descriptor for the compiler generated `* Linker *`
module.

With this patch, lld-link will generate the exact same sequence of
bytes as MSVC link for this subsection for a given object file
input (as reported by `llvm-pdbutil bytes -ec`).

llvm-svn: 307356
2017-07-07 05:04:36 +00:00

413 lines
14 KiB
C++

//===- DbiStreamBuilder.cpp - PDB Dbi Stream Creation -----------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "llvm/DebugInfo/PDB/Native/DbiStreamBuilder.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/BinaryFormat/COFF.h"
#include "llvm/DebugInfo/MSF/MSFBuilder.h"
#include "llvm/DebugInfo/MSF/MappedBlockStream.h"
#include "llvm/DebugInfo/PDB/Native/DbiModuleDescriptorBuilder.h"
#include "llvm/DebugInfo/PDB/Native/DbiStream.h"
#include "llvm/DebugInfo/PDB/Native/RawError.h"
#include "llvm/Object/COFF.h"
#include "llvm/Support/BinaryStreamWriter.h"
using namespace llvm;
using namespace llvm::codeview;
using namespace llvm::msf;
using namespace llvm::pdb;
DbiStreamBuilder::DbiStreamBuilder(msf::MSFBuilder &Msf)
: Msf(Msf), Allocator(Msf.getAllocator()), Age(1), BuildNumber(0),
PdbDllVersion(0), PdbDllRbld(0), Flags(0), MachineType(PDB_Machine::x86),
Header(nullptr), DbgStreams((int)DbgHeaderType::Max) {}
DbiStreamBuilder::~DbiStreamBuilder() {}
void DbiStreamBuilder::setVersionHeader(PdbRaw_DbiVer V) { VerHeader = V; }
void DbiStreamBuilder::setAge(uint32_t A) { Age = A; }
void DbiStreamBuilder::setBuildNumber(uint16_t B) { BuildNumber = B; }
void DbiStreamBuilder::setPdbDllVersion(uint16_t V) { PdbDllVersion = V; }
void DbiStreamBuilder::setPdbDllRbld(uint16_t R) { PdbDllRbld = R; }
void DbiStreamBuilder::setFlags(uint16_t F) { Flags = F; }
void DbiStreamBuilder::setMachineType(PDB_Machine M) { MachineType = M; }
void DbiStreamBuilder::setSectionMap(ArrayRef<SecMapEntry> SecMap) {
SectionMap = SecMap;
}
Error DbiStreamBuilder::addDbgStream(pdb::DbgHeaderType Type,
ArrayRef<uint8_t> Data) {
if (DbgStreams[(int)Type].StreamNumber)
return make_error<RawError>(raw_error_code::duplicate_entry,
"The specified stream type already exists");
auto ExpectedIndex = Msf.addStream(Data.size());
if (!ExpectedIndex)
return ExpectedIndex.takeError();
uint32_t Index = std::move(*ExpectedIndex);
DbgStreams[(int)Type].Data = Data;
DbgStreams[(int)Type].StreamNumber = Index;
return Error::success();
}
uint32_t DbiStreamBuilder::addECName(StringRef Name) {
return ECNamesBuilder.insert(Name);
}
uint32_t DbiStreamBuilder::calculateSerializedLength() const {
// For now we only support serializing the header.
return sizeof(DbiStreamHeader) + calculateFileInfoSubstreamSize() +
calculateModiSubstreamSize() + calculateSectionContribsStreamSize() +
calculateSectionMapStreamSize() + calculateDbgStreamsSize() +
ECNamesBuilder.calculateSerializedSize();
}
Expected<DbiModuleDescriptorBuilder &>
DbiStreamBuilder::addModuleInfo(StringRef ModuleName) {
uint32_t Index = ModiList.size();
auto MIB =
llvm::make_unique<DbiModuleDescriptorBuilder>(ModuleName, Index, Msf);
auto M = MIB.get();
auto Result = ModiMap.insert(std::make_pair(ModuleName, std::move(MIB)));
if (!Result.second)
return make_error<RawError>(raw_error_code::duplicate_entry,
"The specified module already exists");
ModiList.push_back(M);
return *M;
}
Error DbiStreamBuilder::addModuleSourceFile(StringRef Module, StringRef File) {
auto ModIter = ModiMap.find(Module);
if (ModIter == ModiMap.end())
return make_error<RawError>(raw_error_code::no_entry,
"The specified module was not found");
return addModuleSourceFile(*ModIter->second, File);
}
Error DbiStreamBuilder::addModuleSourceFile(DbiModuleDescriptorBuilder &Module,
StringRef File) {
uint32_t Index = SourceFileNames.size();
SourceFileNames.insert(std::make_pair(File, Index));
Module.addSourceFile(File);
return Error::success();
}
Expected<uint32_t> DbiStreamBuilder::getSourceFileNameIndex(StringRef File) {
auto NameIter = SourceFileNames.find(File);
if (NameIter == SourceFileNames.end())
return make_error<RawError>(raw_error_code::no_entry,
"The specified source file was not found");
return NameIter->getValue();
}
uint32_t DbiStreamBuilder::calculateModiSubstreamSize() const {
uint32_t Size = 0;
for (const auto &M : ModiList)
Size += M->calculateSerializedLength();
return Size;
}
uint32_t DbiStreamBuilder::calculateSectionContribsStreamSize() const {
if (SectionContribs.empty())
return 0;
return sizeof(enum PdbRaw_DbiSecContribVer) +
sizeof(SectionContribs[0]) * SectionContribs.size();
}
uint32_t DbiStreamBuilder::calculateSectionMapStreamSize() const {
if (SectionMap.empty())
return 0;
return sizeof(SecMapHeader) + sizeof(SecMapEntry) * SectionMap.size();
}
uint32_t DbiStreamBuilder::calculateNamesOffset() const {
uint32_t Offset = 0;
Offset += sizeof(ulittle16_t); // NumModules
Offset += sizeof(ulittle16_t); // NumSourceFiles
Offset += ModiList.size() * sizeof(ulittle16_t); // ModIndices
Offset += ModiList.size() * sizeof(ulittle16_t); // ModFileCounts
uint32_t NumFileInfos = 0;
for (const auto &M : ModiList)
NumFileInfos += M->source_files().size();
Offset += NumFileInfos * sizeof(ulittle32_t); // FileNameOffsets
return Offset;
}
uint32_t DbiStreamBuilder::calculateFileInfoSubstreamSize() const {
uint32_t Size = calculateNamesOffset();
Size += calculateNamesBufferSize();
return alignTo(Size, sizeof(uint32_t));
}
uint32_t DbiStreamBuilder::calculateNamesBufferSize() const {
uint32_t Size = 0;
for (const auto &F : SourceFileNames) {
Size += F.getKeyLength() + 1; // Names[I];
}
return Size;
}
uint32_t DbiStreamBuilder::calculateDbgStreamsSize() const {
return DbgStreams.size() * sizeof(uint16_t);
}
Error DbiStreamBuilder::generateFileInfoSubstream() {
uint32_t Size = calculateFileInfoSubstreamSize();
auto Data = Allocator.Allocate<uint8_t>(Size);
uint32_t NamesOffset = calculateNamesOffset();
FileInfoBuffer = MutableBinaryByteStream(MutableArrayRef<uint8_t>(Data, Size),
llvm::support::little);
WritableBinaryStreamRef MetadataBuffer =
WritableBinaryStreamRef(FileInfoBuffer).keep_front(NamesOffset);
BinaryStreamWriter MetadataWriter(MetadataBuffer);
uint16_t ModiCount = std::min<uint32_t>(UINT16_MAX, ModiList.size());
uint16_t FileCount = std::min<uint32_t>(UINT16_MAX, SourceFileNames.size());
if (auto EC = MetadataWriter.writeInteger(ModiCount)) // NumModules
return EC;
if (auto EC = MetadataWriter.writeInteger(FileCount)) // NumSourceFiles
return EC;
for (uint16_t I = 0; I < ModiCount; ++I) {
if (auto EC = MetadataWriter.writeInteger(I)) // Mod Indices
return EC;
}
for (const auto &MI : ModiList) {
FileCount = static_cast<uint16_t>(MI->source_files().size());
if (auto EC = MetadataWriter.writeInteger(FileCount)) // Mod File Counts
return EC;
}
// Before writing the FileNameOffsets array, write the NamesBuffer array.
// A side effect of this is that this will actually compute the various
// file name offsets, so we can then go back and write the FileNameOffsets
// array to the other substream.
NamesBuffer = WritableBinaryStreamRef(FileInfoBuffer).drop_front(NamesOffset);
BinaryStreamWriter NameBufferWriter(NamesBuffer);
for (auto &Name : SourceFileNames) {
Name.second = NameBufferWriter.getOffset();
if (auto EC = NameBufferWriter.writeCString(Name.getKey()))
return EC;
}
for (const auto &MI : ModiList) {
for (StringRef Name : MI->source_files()) {
auto Result = SourceFileNames.find(Name);
if (Result == SourceFileNames.end())
return make_error<RawError>(raw_error_code::no_entry,
"The source file was not found.");
if (auto EC = MetadataWriter.writeInteger(Result->second))
return EC;
}
}
if (auto EC = NameBufferWriter.padToAlignment(sizeof(uint32_t)))
return EC;
if (NameBufferWriter.bytesRemaining() > 0)
return make_error<RawError>(raw_error_code::invalid_format,
"The names buffer contained unexpected data.");
if (MetadataWriter.bytesRemaining() > sizeof(uint32_t))
return make_error<RawError>(
raw_error_code::invalid_format,
"The metadata buffer contained unexpected data.");
return Error::success();
}
Error DbiStreamBuilder::finalize() {
if (Header)
return Error::success();
for (auto &MI : ModiList)
MI->finalize();
if (auto EC = generateFileInfoSubstream())
return EC;
DbiStreamHeader *H = Allocator.Allocate<DbiStreamHeader>();
::memset(H, 0, sizeof(DbiStreamHeader));
H->VersionHeader = *VerHeader;
H->VersionSignature = -1;
H->Age = Age;
H->BuildNumber = BuildNumber;
H->Flags = Flags;
H->PdbDllRbld = PdbDllRbld;
H->PdbDllVersion = PdbDllVersion;
H->MachineType = static_cast<uint16_t>(MachineType);
H->ECSubstreamSize = ECNamesBuilder.calculateSerializedSize();
H->FileInfoSize = FileInfoBuffer.getLength();
H->ModiSubstreamSize = calculateModiSubstreamSize();
H->OptionalDbgHdrSize = DbgStreams.size() * sizeof(uint16_t);
H->SecContrSubstreamSize = calculateSectionContribsStreamSize();
H->SectionMapSize = calculateSectionMapStreamSize();
H->TypeServerSize = 0;
H->SymRecordStreamIndex = kInvalidStreamIndex;
H->PublicSymbolStreamIndex = kInvalidStreamIndex;
H->MFCTypeServerIndex = kInvalidStreamIndex;
H->GlobalSymbolStreamIndex = kInvalidStreamIndex;
Header = H;
return Error::success();
}
Error DbiStreamBuilder::finalizeMsfLayout() {
for (auto &MI : ModiList) {
if (auto EC = MI->finalizeMsfLayout())
return EC;
}
uint32_t Length = calculateSerializedLength();
if (auto EC = Msf.setStreamSize(StreamDBI, Length))
return EC;
return Error::success();
}
static uint16_t toSecMapFlags(uint32_t Flags) {
uint16_t Ret = 0;
if (Flags & COFF::IMAGE_SCN_MEM_READ)
Ret |= static_cast<uint16_t>(OMFSegDescFlags::Read);
if (Flags & COFF::IMAGE_SCN_MEM_WRITE)
Ret |= static_cast<uint16_t>(OMFSegDescFlags::Write);
if (Flags & COFF::IMAGE_SCN_MEM_EXECUTE)
Ret |= static_cast<uint16_t>(OMFSegDescFlags::Execute);
if (Flags & COFF::IMAGE_SCN_MEM_EXECUTE)
Ret |= static_cast<uint16_t>(OMFSegDescFlags::Execute);
if (!(Flags & COFF::IMAGE_SCN_MEM_16BIT))
Ret |= static_cast<uint16_t>(OMFSegDescFlags::AddressIs32Bit);
// This seems always 1.
Ret |= static_cast<uint16_t>(OMFSegDescFlags::IsSelector);
return Ret;
}
void DbiStreamBuilder::addSectionContrib(DbiModuleDescriptorBuilder *ModuleDbi,
const object::coff_section *SecHdr) {
SectionContrib SC;
memset(&SC, 0, sizeof(SC));
SC.ISect = (uint16_t)~0U; // This represents nil.
SC.Off = SecHdr->PointerToRawData;
SC.Size = SecHdr->SizeOfRawData;
SC.Characteristics = SecHdr->Characteristics;
// Use the module index in the module dbi stream or nil (-1).
SC.Imod = ModuleDbi ? ModuleDbi->getModuleIndex() : (uint16_t)~0U;
SectionContribs.emplace_back(SC);
}
// A utility function to create a Section Map for a given list of COFF sections.
//
// A Section Map seem to be a copy of a COFF section list in other format.
// I don't know why a PDB file contains both a COFF section header and
// a Section Map, but it seems it must be present in a PDB.
std::vector<SecMapEntry> DbiStreamBuilder::createSectionMap(
ArrayRef<llvm::object::coff_section> SecHdrs) {
std::vector<SecMapEntry> Ret;
int Idx = 0;
auto Add = [&]() -> SecMapEntry & {
Ret.emplace_back();
auto &Entry = Ret.back();
memset(&Entry, 0, sizeof(Entry));
Entry.Frame = Idx + 1;
// We don't know the meaning of these fields yet.
Entry.SecName = UINT16_MAX;
Entry.ClassName = UINT16_MAX;
return Entry;
};
for (auto &Hdr : SecHdrs) {
auto &Entry = Add();
Entry.Flags = toSecMapFlags(Hdr.Characteristics);
Entry.SecByteLength = Hdr.VirtualSize;
++Idx;
}
// The last entry is for absolute symbols.
auto &Entry = Add();
Entry.Flags = static_cast<uint16_t>(OMFSegDescFlags::AddressIs32Bit) |
static_cast<uint16_t>(OMFSegDescFlags::IsAbsoluteAddress);
Entry.SecByteLength = UINT32_MAX;
return Ret;
}
Error DbiStreamBuilder::commit(const msf::MSFLayout &Layout,
WritableBinaryStreamRef MsfBuffer) {
if (auto EC = finalize())
return EC;
auto DbiS = WritableMappedBlockStream::createIndexedStream(
Layout, MsfBuffer, StreamDBI, Allocator);
BinaryStreamWriter Writer(*DbiS);
if (auto EC = Writer.writeObject(*Header))
return EC;
for (auto &M : ModiList) {
if (auto EC = M->commit(Writer, Layout, MsfBuffer))
return EC;
}
if (!SectionContribs.empty()) {
if (auto EC = Writer.writeEnum(DbiSecContribVer60))
return EC;
if (auto EC = Writer.writeArray(makeArrayRef(SectionContribs)))
return EC;
}
if (!SectionMap.empty()) {
ulittle16_t Size = static_cast<ulittle16_t>(SectionMap.size());
SecMapHeader SMHeader = {Size, Size};
if (auto EC = Writer.writeObject(SMHeader))
return EC;
if (auto EC = Writer.writeArray(SectionMap))
return EC;
}
if (auto EC = Writer.writeStreamRef(FileInfoBuffer))
return EC;
if (auto EC = ECNamesBuilder.commit(Writer))
return EC;
for (auto &Stream : DbgStreams)
if (auto EC = Writer.writeInteger(Stream.StreamNumber))
return EC;
for (auto &Stream : DbgStreams) {
if (Stream.StreamNumber == kInvalidStreamIndex)
continue;
auto WritableStream = WritableMappedBlockStream::createIndexedStream(
Layout, MsfBuffer, Stream.StreamNumber, Allocator);
BinaryStreamWriter DbgStreamWriter(*WritableStream);
if (auto EC = DbgStreamWriter.writeArray(Stream.Data))
return EC;
}
if (Writer.bytesRemaining() > 0)
return make_error<RawError>(raw_error_code::invalid_format,
"Unexpected bytes found in DBI Stream");
return Error::success();
}