//===- SampleProfWriter.cpp - Write LLVM sample profile data --------------===// // // 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 implements the class that writes LLVM sample profiles. It // supports two file formats: text and binary. The textual representation // is useful for debugging and testing purposes. The binary representation // is more compact, resulting in smaller file sizes. However, they can // both be used interchangeably. // // See lib/ProfileData/SampleProfReader.cpp for documentation on each of the // supported formats. // //===----------------------------------------------------------------------===// #include "llvm/ProfileData/SampleProfWriter.h" #include "llvm/ADT/StringRef.h" #include "llvm/ProfileData/ProfileCommon.h" #include "llvm/ProfileData/SampleProf.h" #include "llvm/Support/Compression.h" #include "llvm/Support/Endian.h" #include "llvm/Support/EndianStream.h" #include "llvm/Support/ErrorOr.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/LEB128.h" #include "llvm/Support/MD5.h" #include "llvm/Support/raw_ostream.h" #include #include #include #include #include #include #include #include #define DEBUG_TYPE "llvm-profdata" using namespace llvm; using namespace sampleprof; namespace llvm { namespace support { namespace endian { namespace { // Adapter class to llvm::support::endian::Writer for pwrite(). struct SeekableWriter { raw_pwrite_stream &OS; endianness Endian; SeekableWriter(raw_pwrite_stream &OS, endianness Endian) : OS(OS), Endian(Endian) {} template void pwrite(ValueType Val, size_t Offset) { std::string StringBuf; raw_string_ostream SStream(StringBuf); Writer(SStream, Endian).write(Val); OS.pwrite(StringBuf.data(), StringBuf.size(), Offset); } }; } // namespace } // namespace endian } // namespace support } // namespace llvm DefaultFunctionPruningStrategy::DefaultFunctionPruningStrategy( SampleProfileMap &ProfileMap, size_t OutputSizeLimit) : FunctionPruningStrategy(ProfileMap, OutputSizeLimit) { sortFuncProfiles(ProfileMap, SortedFunctions); } void DefaultFunctionPruningStrategy::Erase(size_t CurrentOutputSize) { double D = (double)OutputSizeLimit / CurrentOutputSize; size_t NewSize = (size_t)round(ProfileMap.size() * D * D); size_t NumToRemove = ProfileMap.size() - NewSize; if (NumToRemove < 1) NumToRemove = 1; assert(NumToRemove <= SortedFunctions.size()); for (const NameFunctionSamples &E : llvm::drop_begin(SortedFunctions, SortedFunctions.size() - NumToRemove)) ProfileMap.erase(E.first); SortedFunctions.resize(SortedFunctions.size() - NumToRemove); } std::error_code SampleProfileWriter::writeWithSizeLimitInternal( SampleProfileMap &ProfileMap, size_t OutputSizeLimit, FunctionPruningStrategy *Strategy) { if (OutputSizeLimit == 0) return write(ProfileMap); size_t OriginalFunctionCount = ProfileMap.size(); std::unique_ptr OriginalOutputStream; OutputStream.swap(OriginalOutputStream); size_t IterationCount = 0; size_t TotalSize; SmallVector StringBuffer; do { StringBuffer.clear(); OutputStream.reset(new raw_svector_ostream(StringBuffer)); if (std::error_code EC = write(ProfileMap)) return EC; TotalSize = StringBuffer.size(); // On Windows every "\n" is actually written as "\r\n" to disk but not to // memory buffer, this difference should be added when considering the total // output size. #ifdef _WIN32 if (Format == SPF_Text) TotalSize += LineCount; #endif if (TotalSize <= OutputSizeLimit) break; Strategy->Erase(TotalSize); IterationCount++; } while (ProfileMap.size() != 0); if (ProfileMap.size() == 0) return sampleprof_error::too_large; OutputStream.swap(OriginalOutputStream); OutputStream->write(StringBuffer.data(), StringBuffer.size()); LLVM_DEBUG(dbgs() << "Profile originally has " << OriginalFunctionCount << " functions, reduced to " << ProfileMap.size() << " in " << IterationCount << " iterations\n"); // Silence warning on Release build. (void)OriginalFunctionCount; (void)IterationCount; return sampleprof_error::success; } std::error_code SampleProfileWriter::writeFuncProfiles(const SampleProfileMap &ProfileMap) { std::vector V; sortFuncProfiles(ProfileMap, V); for (const auto &I : V) { if (std::error_code EC = writeSample(*I.second)) return EC; } return sampleprof_error::success; } std::error_code SampleProfileWriter::write(const SampleProfileMap &ProfileMap) { if (std::error_code EC = writeHeader(ProfileMap)) return EC; if (std::error_code EC = writeFuncProfiles(ProfileMap)) return EC; return sampleprof_error::success; } /// Return the current position and prepare to use it as the start /// position of a section given the section type \p Type and its position /// \p LayoutIdx in SectionHdrLayout. uint64_t SampleProfileWriterExtBinaryBase::markSectionStart(SecType Type, uint32_t LayoutIdx) { uint64_t SectionStart = OutputStream->tell(); assert(LayoutIdx < SectionHdrLayout.size() && "LayoutIdx out of range"); const auto &Entry = SectionHdrLayout[LayoutIdx]; assert(Entry.Type == Type && "Unexpected section type"); // Use LocalBuf as a temporary output for writting data. if (hasSecFlag(Entry, SecCommonFlags::SecFlagCompress)) LocalBufStream.swap(OutputStream); return SectionStart; } std::error_code SampleProfileWriterExtBinaryBase::compressAndOutput() { if (!llvm::compression::zlib::isAvailable()) return sampleprof_error::zlib_unavailable; std::string &UncompressedStrings = static_cast(LocalBufStream.get())->str(); if (UncompressedStrings.size() == 0) return sampleprof_error::success; auto &OS = *OutputStream; SmallVector CompressedStrings; compression::zlib::compress(arrayRefFromStringRef(UncompressedStrings), CompressedStrings, compression::zlib::BestSizeCompression); encodeULEB128(UncompressedStrings.size(), OS); encodeULEB128(CompressedStrings.size(), OS); OS << toStringRef(CompressedStrings); UncompressedStrings.clear(); return sampleprof_error::success; } /// Add a new section into section header table given the section type /// \p Type, its position \p LayoutIdx in SectionHdrLayout and the /// location \p SectionStart where the section should be written to. std::error_code SampleProfileWriterExtBinaryBase::addNewSection( SecType Type, uint32_t LayoutIdx, uint64_t SectionStart) { assert(LayoutIdx < SectionHdrLayout.size() && "LayoutIdx out of range"); const auto &Entry = SectionHdrLayout[LayoutIdx]; assert(Entry.Type == Type && "Unexpected section type"); if (hasSecFlag(Entry, SecCommonFlags::SecFlagCompress)) { LocalBufStream.swap(OutputStream); if (std::error_code EC = compressAndOutput()) return EC; } SecHdrTable.push_back({Type, Entry.Flags, SectionStart - FileStart, OutputStream->tell() - SectionStart, LayoutIdx}); return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::write(const SampleProfileMap &ProfileMap) { // When calling write on a different profile map, existing states should be // cleared. NameTable.clear(); CSNameTable.clear(); SecHdrTable.clear(); if (std::error_code EC = writeHeader(ProfileMap)) return EC; std::string LocalBuf; LocalBufStream = std::make_unique(LocalBuf); if (std::error_code EC = writeSections(ProfileMap)) return EC; if (std::error_code EC = writeSecHdrTable()) return EC; return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeContextIdx( const SampleContext &Context) { if (Context.hasContext()) return writeCSNameIdx(Context); else return SampleProfileWriterBinary::writeNameIdx(Context.getFunction()); } std::error_code SampleProfileWriterExtBinaryBase::writeCSNameIdx(const SampleContext &Context) { const auto &Ret = CSNameTable.find(Context); if (Ret == CSNameTable.end()) return sampleprof_error::truncated_name_table; encodeULEB128(Ret->second, *OutputStream); return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeSample(const FunctionSamples &S) { uint64_t Offset = OutputStream->tell(); auto &Context = S.getContext(); FuncOffsetTable[Context] = Offset - SecLBRProfileStart; encodeULEB128(S.getHeadSamples(), *OutputStream); return writeBody(S); } std::error_code SampleProfileWriterExtBinaryBase::writeFuncOffsetTable() { auto &OS = *OutputStream; // Write out the table size. encodeULEB128(FuncOffsetTable.size(), OS); // Write out FuncOffsetTable. auto WriteItem = [&](const SampleContext &Context, uint64_t Offset) { if (std::error_code EC = writeContextIdx(Context)) return EC; encodeULEB128(Offset, OS); return (std::error_code)sampleprof_error::success; }; if (FunctionSamples::ProfileIsCS) { // Sort the contexts before writing them out. This is to help fast load all // context profiles for a function as well as their callee contexts which // can help profile-guided importing for ThinLTO. std::map OrderedFuncOffsetTable( FuncOffsetTable.begin(), FuncOffsetTable.end()); for (const auto &Entry : OrderedFuncOffsetTable) { if (std::error_code EC = WriteItem(Entry.first, Entry.second)) return EC; } addSectionFlag(SecFuncOffsetTable, SecFuncOffsetFlags::SecFlagOrdered); } else { for (const auto &Entry : FuncOffsetTable) { if (std::error_code EC = WriteItem(Entry.first, Entry.second)) return EC; } } FuncOffsetTable.clear(); return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeFuncMetadata( const FunctionSamples &FunctionProfile) { auto &OS = *OutputStream; if (std::error_code EC = writeContextIdx(FunctionProfile.getContext())) return EC; if (FunctionSamples::ProfileIsProbeBased) encodeULEB128(FunctionProfile.getFunctionHash(), OS); if (FunctionSamples::ProfileIsCS || FunctionSamples::ProfileIsPreInlined) { encodeULEB128(FunctionProfile.getContext().getAllAttributes(), OS); } if (!FunctionSamples::ProfileIsCS) { // Recursively emit attributes for all callee samples. uint64_t NumCallsites = 0; for (const auto &J : FunctionProfile.getCallsiteSamples()) NumCallsites += J.second.size(); encodeULEB128(NumCallsites, OS); for (const auto &J : FunctionProfile.getCallsiteSamples()) { for (const auto &FS : J.second) { LineLocation Loc = J.first; encodeULEB128(Loc.LineOffset, OS); encodeULEB128(Loc.Discriminator, OS); if (std::error_code EC = writeFuncMetadata(FS.second)) return EC; } } } return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeFuncMetadata( const SampleProfileMap &Profiles) { if (!FunctionSamples::ProfileIsProbeBased && !FunctionSamples::ProfileIsCS && !FunctionSamples::ProfileIsPreInlined) return sampleprof_error::success; for (const auto &Entry : Profiles) { if (std::error_code EC = writeFuncMetadata(Entry.second)) return EC; } return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeNameTable() { if (!UseMD5) return SampleProfileWriterBinary::writeNameTable(); auto &OS = *OutputStream; std::set V; stablizeNameTable(NameTable, V); // Write out the MD5 name table. We wrote unencoded MD5 so reader can // retrieve the name using the name index without having to read the // whole name table. encodeULEB128(NameTable.size(), OS); support::endian::Writer Writer(OS, llvm::endianness::little); for (auto N : V) Writer.write(N.getHashCode()); return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeNameTableSection( const SampleProfileMap &ProfileMap) { for (const auto &I : ProfileMap) { addContext(I.second.getContext()); addNames(I.second); } // If NameTable contains ".__uniq." suffix, set SecFlagUniqSuffix flag // so compiler won't strip the suffix during profile matching after // seeing the flag in the profile. // Original names are unavailable if using MD5, so this option has no use. if (!UseMD5) { for (const auto &I : NameTable) { if (I.first.stringRef().contains(FunctionSamples::UniqSuffix)) { addSectionFlag(SecNameTable, SecNameTableFlags::SecFlagUniqSuffix); break; } } } if (auto EC = writeNameTable()) return EC; return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeCSNameTableSection() { // Sort the names to make CSNameTable deterministic. std::set OrderedContexts; for (const auto &I : CSNameTable) OrderedContexts.insert(I.first); assert(OrderedContexts.size() == CSNameTable.size() && "Unmatched ordered and unordered contexts"); uint64_t I = 0; for (auto &Context : OrderedContexts) CSNameTable[Context] = I++; auto &OS = *OutputStream; encodeULEB128(OrderedContexts.size(), OS); support::endian::Writer Writer(OS, llvm::endianness::little); for (auto Context : OrderedContexts) { auto Frames = Context.getContextFrames(); encodeULEB128(Frames.size(), OS); for (auto &Callsite : Frames) { if (std::error_code EC = writeNameIdx(Callsite.Func)) return EC; encodeULEB128(Callsite.Location.LineOffset, OS); encodeULEB128(Callsite.Location.Discriminator, OS); } } return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeProfileSymbolListSection() { if (ProfSymList && ProfSymList->size() > 0) if (std::error_code EC = ProfSymList->write(*OutputStream)) return EC; return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeOneSection( SecType Type, uint32_t LayoutIdx, const SampleProfileMap &ProfileMap) { // The setting of SecFlagCompress should happen before markSectionStart. if (Type == SecProfileSymbolList && ProfSymList && ProfSymList->toCompress()) setToCompressSection(SecProfileSymbolList); if (Type == SecFuncMetadata && FunctionSamples::ProfileIsProbeBased) addSectionFlag(SecFuncMetadata, SecFuncMetadataFlags::SecFlagIsProbeBased); if (Type == SecFuncMetadata && (FunctionSamples::ProfileIsCS || FunctionSamples::ProfileIsPreInlined)) addSectionFlag(SecFuncMetadata, SecFuncMetadataFlags::SecFlagHasAttribute); if (Type == SecProfSummary && FunctionSamples::ProfileIsCS) addSectionFlag(SecProfSummary, SecProfSummaryFlags::SecFlagFullContext); if (Type == SecProfSummary && FunctionSamples::ProfileIsPreInlined) addSectionFlag(SecProfSummary, SecProfSummaryFlags::SecFlagIsPreInlined); if (Type == SecProfSummary && FunctionSamples::ProfileIsFS) addSectionFlag(SecProfSummary, SecProfSummaryFlags::SecFlagFSDiscriminator); uint64_t SectionStart = markSectionStart(Type, LayoutIdx); switch (Type) { case SecProfSummary: computeSummary(ProfileMap); if (auto EC = writeSummary()) return EC; break; case SecNameTable: if (auto EC = writeNameTableSection(ProfileMap)) return EC; break; case SecCSNameTable: if (auto EC = writeCSNameTableSection()) return EC; break; case SecLBRProfile: SecLBRProfileStart = OutputStream->tell(); if (std::error_code EC = writeFuncProfiles(ProfileMap)) return EC; break; case SecFuncOffsetTable: if (auto EC = writeFuncOffsetTable()) return EC; break; case SecFuncMetadata: if (std::error_code EC = writeFuncMetadata(ProfileMap)) return EC; break; case SecProfileSymbolList: if (auto EC = writeProfileSymbolListSection()) return EC; break; default: if (auto EC = writeCustomSection(Type)) return EC; break; } if (std::error_code EC = addNewSection(Type, LayoutIdx, SectionStart)) return EC; return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinary::writeDefaultLayout( const SampleProfileMap &ProfileMap) { // The const indices passed to writeOneSection below are specifying the // positions of the sections in SectionHdrLayout. Look at // initSectionHdrLayout to find out where each section is located in // SectionHdrLayout. if (auto EC = writeOneSection(SecProfSummary, 0, ProfileMap)) return EC; if (auto EC = writeOneSection(SecNameTable, 1, ProfileMap)) return EC; if (auto EC = writeOneSection(SecCSNameTable, 2, ProfileMap)) return EC; if (auto EC = writeOneSection(SecLBRProfile, 4, ProfileMap)) return EC; if (auto EC = writeOneSection(SecProfileSymbolList, 5, ProfileMap)) return EC; if (auto EC = writeOneSection(SecFuncOffsetTable, 3, ProfileMap)) return EC; if (auto EC = writeOneSection(SecFuncMetadata, 6, ProfileMap)) return EC; return sampleprof_error::success; } static void splitProfileMapToTwo(const SampleProfileMap &ProfileMap, SampleProfileMap &ContextProfileMap, SampleProfileMap &NoContextProfileMap) { for (const auto &I : ProfileMap) { if (I.second.getCallsiteSamples().size()) ContextProfileMap.insert({I.first, I.second}); else NoContextProfileMap.insert({I.first, I.second}); } } std::error_code SampleProfileWriterExtBinary::writeCtxSplitLayout( const SampleProfileMap &ProfileMap) { SampleProfileMap ContextProfileMap, NoContextProfileMap; splitProfileMapToTwo(ProfileMap, ContextProfileMap, NoContextProfileMap); if (auto EC = writeOneSection(SecProfSummary, 0, ProfileMap)) return EC; if (auto EC = writeOneSection(SecNameTable, 1, ProfileMap)) return EC; if (auto EC = writeOneSection(SecLBRProfile, 3, ContextProfileMap)) return EC; if (auto EC = writeOneSection(SecFuncOffsetTable, 2, ContextProfileMap)) return EC; // Mark the section to have no context. Note section flag needs to be set // before writing the section. addSectionFlag(5, SecCommonFlags::SecFlagFlat); if (auto EC = writeOneSection(SecLBRProfile, 5, NoContextProfileMap)) return EC; // Mark the section to have no context. Note section flag needs to be set // before writing the section. addSectionFlag(4, SecCommonFlags::SecFlagFlat); if (auto EC = writeOneSection(SecFuncOffsetTable, 4, NoContextProfileMap)) return EC; if (auto EC = writeOneSection(SecProfileSymbolList, 6, ProfileMap)) return EC; if (auto EC = writeOneSection(SecFuncMetadata, 7, ProfileMap)) return EC; return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinary::writeSections( const SampleProfileMap &ProfileMap) { std::error_code EC; if (SecLayout == DefaultLayout) EC = writeDefaultLayout(ProfileMap); else if (SecLayout == CtxSplitLayout) EC = writeCtxSplitLayout(ProfileMap); else llvm_unreachable("Unsupported layout"); return EC; } /// Write samples to a text file. /// /// Note: it may be tempting to implement this in terms of /// FunctionSamples::print(). Please don't. The dump functionality is intended /// for debugging and has no specified form. /// /// The format used here is more structured and deliberate because /// it needs to be parsed by the SampleProfileReaderText class. std::error_code SampleProfileWriterText::writeSample(const FunctionSamples &S) { auto &OS = *OutputStream; if (FunctionSamples::ProfileIsCS) OS << "[" << S.getContext().toString() << "]:" << S.getTotalSamples(); else OS << S.getFunction() << ":" << S.getTotalSamples(); if (Indent == 0) OS << ":" << S.getHeadSamples(); OS << "\n"; LineCount++; SampleSorter SortedSamples(S.getBodySamples()); for (const auto &I : SortedSamples.get()) { LineLocation Loc = I->first; const SampleRecord &Sample = I->second; OS.indent(Indent + 1); if (Loc.Discriminator == 0) OS << Loc.LineOffset << ": "; else OS << Loc.LineOffset << "." << Loc.Discriminator << ": "; OS << Sample.getSamples(); for (const auto &J : Sample.getSortedCallTargets()) OS << " " << J.first << ":" << J.second; OS << "\n"; LineCount++; } SampleSorter SortedCallsiteSamples( S.getCallsiteSamples()); Indent += 1; for (const auto &I : SortedCallsiteSamples.get()) for (const auto &FS : I->second) { LineLocation Loc = I->first; const FunctionSamples &CalleeSamples = FS.second; OS.indent(Indent); if (Loc.Discriminator == 0) OS << Loc.LineOffset << ": "; else OS << Loc.LineOffset << "." << Loc.Discriminator << ": "; if (std::error_code EC = writeSample(CalleeSamples)) return EC; } Indent -= 1; if (FunctionSamples::ProfileIsProbeBased) { OS.indent(Indent + 1); OS << "!CFGChecksum: " << S.getFunctionHash() << "\n"; LineCount++; } if (S.getContext().getAllAttributes()) { OS.indent(Indent + 1); OS << "!Attributes: " << S.getContext().getAllAttributes() << "\n"; LineCount++; } return sampleprof_error::success; } std::error_code SampleProfileWriterBinary::writeContextIdx(const SampleContext &Context) { assert(!Context.hasContext() && "cs profile is not supported"); return writeNameIdx(Context.getFunction()); } std::error_code SampleProfileWriterBinary::writeNameIdx(FunctionId FName) { auto &NTable = getNameTable(); const auto &Ret = NTable.find(FName); if (Ret == NTable.end()) return sampleprof_error::truncated_name_table; encodeULEB128(Ret->second, *OutputStream); return sampleprof_error::success; } void SampleProfileWriterBinary::addName(FunctionId FName) { auto &NTable = getNameTable(); NTable.insert(std::make_pair(FName, 0)); } void SampleProfileWriterBinary::addContext(const SampleContext &Context) { addName(Context.getFunction()); } void SampleProfileWriterBinary::addNames(const FunctionSamples &S) { // Add all the names in indirect call targets. for (const auto &I : S.getBodySamples()) { const SampleRecord &Sample = I.second; for (const auto &J : Sample.getCallTargets()) addName(J.first); } // Recursively add all the names for inlined callsites. for (const auto &J : S.getCallsiteSamples()) for (const auto &FS : J.second) { const FunctionSamples &CalleeSamples = FS.second; addName(CalleeSamples.getFunction()); addNames(CalleeSamples); } } void SampleProfileWriterExtBinaryBase::addContext( const SampleContext &Context) { if (Context.hasContext()) { for (auto &Callsite : Context.getContextFrames()) SampleProfileWriterBinary::addName(Callsite.Func); CSNameTable.insert(std::make_pair(Context, 0)); } else { SampleProfileWriterBinary::addName(Context.getFunction()); } } void SampleProfileWriterBinary::stablizeNameTable( MapVector &NameTable, std::set &V) { // Sort the names to make NameTable deterministic. for (const auto &I : NameTable) V.insert(I.first); int i = 0; for (const FunctionId &N : V) NameTable[N] = i++; } std::error_code SampleProfileWriterBinary::writeNameTable() { auto &OS = *OutputStream; std::set V; stablizeNameTable(NameTable, V); // Write out the name table. encodeULEB128(NameTable.size(), OS); for (auto N : V) { OS << N; encodeULEB128(0, OS); } return sampleprof_error::success; } std::error_code SampleProfileWriterBinary::writeMagicIdent(SampleProfileFormat Format) { auto &OS = *OutputStream; // Write file magic identifier. encodeULEB128(SPMagic(Format), OS); encodeULEB128(SPVersion(), OS); return sampleprof_error::success; } std::error_code SampleProfileWriterBinary::writeHeader(const SampleProfileMap &ProfileMap) { // When calling write on a different profile map, existing names should be // cleared. NameTable.clear(); writeMagicIdent(Format); computeSummary(ProfileMap); if (auto EC = writeSummary()) return EC; // Generate the name table for all the functions referenced in the profile. for (const auto &I : ProfileMap) { addContext(I.second.getContext()); addNames(I.second); } writeNameTable(); return sampleprof_error::success; } void SampleProfileWriterExtBinaryBase::setToCompressAllSections() { for (auto &Entry : SectionHdrLayout) addSecFlag(Entry, SecCommonFlags::SecFlagCompress); } void SampleProfileWriterExtBinaryBase::setToCompressSection(SecType Type) { addSectionFlag(Type, SecCommonFlags::SecFlagCompress); } void SampleProfileWriterExtBinaryBase::allocSecHdrTable() { support::endian::Writer Writer(*OutputStream, llvm::endianness::little); Writer.write(static_cast(SectionHdrLayout.size())); SecHdrTableOffset = OutputStream->tell(); for (uint32_t i = 0; i < SectionHdrLayout.size(); i++) { Writer.write(static_cast(-1)); Writer.write(static_cast(-1)); Writer.write(static_cast(-1)); Writer.write(static_cast(-1)); } } std::error_code SampleProfileWriterExtBinaryBase::writeSecHdrTable() { assert(SecHdrTable.size() == SectionHdrLayout.size() && "SecHdrTable entries doesn't match SectionHdrLayout"); SmallVector IndexMap(SecHdrTable.size(), -1); for (uint32_t TableIdx = 0; TableIdx < SecHdrTable.size(); TableIdx++) { IndexMap[SecHdrTable[TableIdx].LayoutIndex] = TableIdx; } // Write the section header table in the order specified in // SectionHdrLayout. SectionHdrLayout specifies the sections // order in which profile reader expect to read, so the section // header table should be written in the order in SectionHdrLayout. // Note that the section order in SecHdrTable may be different // from the order in SectionHdrLayout, for example, SecFuncOffsetTable // needs to be computed after SecLBRProfile (the order in SecHdrTable), // but it needs to be read before SecLBRProfile (the order in // SectionHdrLayout). So we use IndexMap above to switch the order. support::endian::SeekableWriter Writer( static_cast(*OutputStream), llvm::endianness::little); for (uint32_t LayoutIdx = 0; LayoutIdx < SectionHdrLayout.size(); LayoutIdx++) { assert(IndexMap[LayoutIdx] < SecHdrTable.size() && "Incorrect LayoutIdx in SecHdrTable"); auto Entry = SecHdrTable[IndexMap[LayoutIdx]]; Writer.pwrite(static_cast(Entry.Type), SecHdrTableOffset + 4 * LayoutIdx * sizeof(uint64_t)); Writer.pwrite(static_cast(Entry.Flags), SecHdrTableOffset + (4 * LayoutIdx + 1) * sizeof(uint64_t)); Writer.pwrite(static_cast(Entry.Offset), SecHdrTableOffset + (4 * LayoutIdx + 2) * sizeof(uint64_t)); Writer.pwrite(static_cast(Entry.Size), SecHdrTableOffset + (4 * LayoutIdx + 3) * sizeof(uint64_t)); } return sampleprof_error::success; } std::error_code SampleProfileWriterExtBinaryBase::writeHeader( const SampleProfileMap &ProfileMap) { auto &OS = *OutputStream; FileStart = OS.tell(); writeMagicIdent(Format); allocSecHdrTable(); return sampleprof_error::success; } std::error_code SampleProfileWriterBinary::writeSummary() { auto &OS = *OutputStream; encodeULEB128(Summary->getTotalCount(), OS); encodeULEB128(Summary->getMaxCount(), OS); encodeULEB128(Summary->getMaxFunctionCount(), OS); encodeULEB128(Summary->getNumCounts(), OS); encodeULEB128(Summary->getNumFunctions(), OS); ArrayRef Entries = Summary->getDetailedSummary(); encodeULEB128(Entries.size(), OS); for (auto Entry : Entries) { encodeULEB128(Entry.Cutoff, OS); encodeULEB128(Entry.MinCount, OS); encodeULEB128(Entry.NumCounts, OS); } return sampleprof_error::success; } std::error_code SampleProfileWriterBinary::writeBody(const FunctionSamples &S) { auto &OS = *OutputStream; if (std::error_code EC = writeContextIdx(S.getContext())) return EC; encodeULEB128(S.getTotalSamples(), OS); // Emit all the body samples. encodeULEB128(S.getBodySamples().size(), OS); for (const auto &I : S.getBodySamples()) { LineLocation Loc = I.first; const SampleRecord &Sample = I.second; encodeULEB128(Loc.LineOffset, OS); encodeULEB128(Loc.Discriminator, OS); encodeULEB128(Sample.getSamples(), OS); encodeULEB128(Sample.getCallTargets().size(), OS); for (const auto &J : Sample.getSortedCallTargets()) { FunctionId Callee = J.first; uint64_t CalleeSamples = J.second; if (std::error_code EC = writeNameIdx(Callee)) return EC; encodeULEB128(CalleeSamples, OS); } } // Recursively emit all the callsite samples. uint64_t NumCallsites = 0; for (const auto &J : S.getCallsiteSamples()) NumCallsites += J.second.size(); encodeULEB128(NumCallsites, OS); for (const auto &J : S.getCallsiteSamples()) for (const auto &FS : J.second) { LineLocation Loc = J.first; const FunctionSamples &CalleeSamples = FS.second; encodeULEB128(Loc.LineOffset, OS); encodeULEB128(Loc.Discriminator, OS); if (std::error_code EC = writeBody(CalleeSamples)) return EC; } return sampleprof_error::success; } /// Write samples of a top-level function to a binary file. /// /// \returns true if the samples were written successfully, false otherwise. std::error_code SampleProfileWriterBinary::writeSample(const FunctionSamples &S) { encodeULEB128(S.getHeadSamples(), *OutputStream); return writeBody(S); } /// Create a sample profile file writer based on the specified format. /// /// \param Filename The file to create. /// /// \param Format Encoding format for the profile file. /// /// \returns an error code indicating the status of the created writer. ErrorOr> SampleProfileWriter::create(StringRef Filename, SampleProfileFormat Format) { std::error_code EC; std::unique_ptr OS; if (Format == SPF_Binary || Format == SPF_Ext_Binary) OS.reset(new raw_fd_ostream(Filename, EC, sys::fs::OF_None)); else OS.reset(new raw_fd_ostream(Filename, EC, sys::fs::OF_TextWithCRLF)); if (EC) return EC; return create(OS, Format); } /// Create a sample profile stream writer based on the specified format. /// /// \param OS The output stream to store the profile data to. /// /// \param Format Encoding format for the profile file. /// /// \returns an error code indicating the status of the created writer. ErrorOr> SampleProfileWriter::create(std::unique_ptr &OS, SampleProfileFormat Format) { std::error_code EC; std::unique_ptr Writer; // Currently only Text and Extended Binary format are supported for CSSPGO. if ((FunctionSamples::ProfileIsCS || FunctionSamples::ProfileIsProbeBased) && Format == SPF_Binary) return sampleprof_error::unsupported_writing_format; if (Format == SPF_Binary) Writer.reset(new SampleProfileWriterRawBinary(OS)); else if (Format == SPF_Ext_Binary) Writer.reset(new SampleProfileWriterExtBinary(OS)); else if (Format == SPF_Text) Writer.reset(new SampleProfileWriterText(OS)); else if (Format == SPF_GCC) EC = sampleprof_error::unsupported_writing_format; else EC = sampleprof_error::unrecognized_format; if (EC) return EC; Writer->Format = Format; return std::move(Writer); } void SampleProfileWriter::computeSummary(const SampleProfileMap &ProfileMap) { SampleProfileSummaryBuilder Builder(ProfileSummaryBuilder::DefaultCutoffs); Summary = Builder.computeSummaryForProfiles(ProfileMap); }