//===- CoverageMappingWriter.cpp - Code coverage mapping writer -----------===// // // 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 contains support for writing coverage mapping data for // instrumentation based coverage. // //===----------------------------------------------------------------------===// #include "llvm/ProfileData/Coverage/CoverageMappingWriter.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ProfileData/InstrProf.h" #include "llvm/Support/Compression.h" #include "llvm/Support/LEB128.h" #include "llvm/Support/raw_ostream.h" #include #include #include #include using namespace llvm; using namespace coverage; CoverageFilenamesSectionWriter::CoverageFilenamesSectionWriter( ArrayRef Filenames) : Filenames(Filenames) { #ifndef NDEBUG StringSet<> NameSet; for (StringRef Name : Filenames) assert(NameSet.insert(Name).second && "Duplicate filename"); #endif } void CoverageFilenamesSectionWriter::write(raw_ostream &OS, bool Compress) { std::string FilenamesStr; { raw_string_ostream FilenamesOS{FilenamesStr}; for (const auto &Filename : Filenames) { encodeULEB128(Filename.size(), FilenamesOS); FilenamesOS << Filename; } } SmallVector CompressedStr; bool doCompression = Compress && compression::zlib::isAvailable() && DoInstrProfNameCompression; if (doCompression) compression::zlib::compress(arrayRefFromStringRef(FilenamesStr), CompressedStr, compression::zlib::BestSizeCompression); // ::= // // // ( | ) encodeULEB128(Filenames.size(), OS); encodeULEB128(FilenamesStr.size(), OS); encodeULEB128(doCompression ? CompressedStr.size() : 0U, OS); OS << (doCompression ? toStringRef(CompressedStr) : StringRef(FilenamesStr)); } namespace { /// Gather only the expressions that are used by the mapping /// regions in this function. class CounterExpressionsMinimizer { ArrayRef Expressions; SmallVector UsedExpressions; std::vector AdjustedExpressionIDs; public: CounterExpressionsMinimizer(ArrayRef Expressions, ArrayRef MappingRegions) : Expressions(Expressions) { AdjustedExpressionIDs.resize(Expressions.size(), 0); for (const auto &I : MappingRegions) { mark(I.Count); mark(I.FalseCount); } for (const auto &I : MappingRegions) { gatherUsed(I.Count); gatherUsed(I.FalseCount); } } void mark(Counter C) { if (!C.isExpression()) return; unsigned ID = C.getExpressionID(); AdjustedExpressionIDs[ID] = 1; mark(Expressions[ID].LHS); mark(Expressions[ID].RHS); } void gatherUsed(Counter C) { if (!C.isExpression() || !AdjustedExpressionIDs[C.getExpressionID()]) return; AdjustedExpressionIDs[C.getExpressionID()] = UsedExpressions.size(); const auto &E = Expressions[C.getExpressionID()]; UsedExpressions.push_back(E); gatherUsed(E.LHS); gatherUsed(E.RHS); } ArrayRef getExpressions() const { return UsedExpressions; } /// Adjust the given counter to correctly transition from the old /// expression ids to the new expression ids. Counter adjust(Counter C) const { if (C.isExpression()) C = Counter::getExpression(AdjustedExpressionIDs[C.getExpressionID()]); return C; } }; } // end anonymous namespace /// Encode the counter. /// /// The encoding uses the following format: /// Low 2 bits - Tag: /// Counter::Zero(0) - A Counter with kind Counter::Zero /// Counter::CounterValueReference(1) - A counter with kind /// Counter::CounterValueReference /// Counter::Expression(2) + CounterExpression::Subtract(0) - /// A counter with kind Counter::Expression and an expression /// with kind CounterExpression::Subtract /// Counter::Expression(2) + CounterExpression::Add(1) - /// A counter with kind Counter::Expression and an expression /// with kind CounterExpression::Add /// Remaining bits - Counter/Expression ID. static unsigned encodeCounter(ArrayRef Expressions, Counter C) { unsigned Tag = unsigned(C.getKind()); if (C.isExpression()) Tag += Expressions[C.getExpressionID()].Kind; unsigned ID = C.getCounterID(); assert(ID <= (std::numeric_limits::max() >> Counter::EncodingTagBits)); return Tag | (ID << Counter::EncodingTagBits); } static void writeCounter(ArrayRef Expressions, Counter C, raw_ostream &OS) { encodeULEB128(encodeCounter(Expressions, C), OS); } void CoverageMappingWriter::write(raw_ostream &OS) { // Check that we don't have any bogus regions. assert(all_of(MappingRegions, [](const CounterMappingRegion &CMR) { return CMR.startLoc() <= CMR.endLoc(); }) && "Source region does not begin before it ends"); // Sort the regions in an ascending order by the file id and the starting // location. Sort by region kinds to ensure stable order for tests. llvm::stable_sort(MappingRegions, [](const CounterMappingRegion &LHS, const CounterMappingRegion &RHS) { if (LHS.FileID != RHS.FileID) return LHS.FileID < RHS.FileID; if (LHS.startLoc() != RHS.startLoc()) return LHS.startLoc() < RHS.startLoc(); // Put `Decision` before `Expansion`. auto getKindKey = [](CounterMappingRegion::RegionKind Kind) { return (Kind == CounterMappingRegion::MCDCDecisionRegion ? 2 * CounterMappingRegion::ExpansionRegion - 1 : 2 * Kind); }; return getKindKey(LHS.Kind) < getKindKey(RHS.Kind); }); // Write out the fileid -> filename mapping. encodeULEB128(VirtualFileMapping.size(), OS); for (const auto &FileID : VirtualFileMapping) encodeULEB128(FileID, OS); // Write out the expressions. CounterExpressionsMinimizer Minimizer(Expressions, MappingRegions); auto MinExpressions = Minimizer.getExpressions(); encodeULEB128(MinExpressions.size(), OS); for (const auto &E : MinExpressions) { writeCounter(MinExpressions, Minimizer.adjust(E.LHS), OS); writeCounter(MinExpressions, Minimizer.adjust(E.RHS), OS); } // Write out the mapping regions. // Split the regions into subarrays where each region in a // subarray has a fileID which is the index of that subarray. unsigned PrevLineStart = 0; unsigned CurrentFileID = ~0U; for (auto I = MappingRegions.begin(), E = MappingRegions.end(); I != E; ++I) { if (I->FileID != CurrentFileID) { // Ensure that all file ids have at least one mapping region. assert(I->FileID == (CurrentFileID + 1)); // Find the number of regions with this file id. unsigned RegionCount = 1; for (auto J = I + 1; J != E && I->FileID == J->FileID; ++J) ++RegionCount; // Start a new region sub-array. encodeULEB128(RegionCount, OS); CurrentFileID = I->FileID; PrevLineStart = 0; } Counter Count = Minimizer.adjust(I->Count); Counter FalseCount = Minimizer.adjust(I->FalseCount); switch (I->Kind) { case CounterMappingRegion::CodeRegion: case CounterMappingRegion::GapRegion: writeCounter(MinExpressions, Count, OS); break; case CounterMappingRegion::ExpansionRegion: { assert(Count.isZero()); assert(I->ExpandedFileID <= (std::numeric_limits::max() >> Counter::EncodingCounterTagAndExpansionRegionTagBits)); // Mark an expansion region with a set bit that follows the counter tag, // and pack the expanded file id into the remaining bits. unsigned EncodedTagExpandedFileID = (1 << Counter::EncodingTagBits) | (I->ExpandedFileID << Counter::EncodingCounterTagAndExpansionRegionTagBits); encodeULEB128(EncodedTagExpandedFileID, OS); break; } case CounterMappingRegion::SkippedRegion: assert(Count.isZero()); encodeULEB128(unsigned(I->Kind) << Counter::EncodingCounterTagAndExpansionRegionTagBits, OS); break; case CounterMappingRegion::BranchRegion: encodeULEB128(unsigned(I->Kind) << Counter::EncodingCounterTagAndExpansionRegionTagBits, OS); writeCounter(MinExpressions, Count, OS); writeCounter(MinExpressions, FalseCount, OS); break; case CounterMappingRegion::MCDCBranchRegion: encodeULEB128(unsigned(I->Kind) << Counter::EncodingCounterTagAndExpansionRegionTagBits, OS); writeCounter(MinExpressions, Count, OS); writeCounter(MinExpressions, FalseCount, OS); encodeULEB128(unsigned(I->MCDCParams.ID), OS); encodeULEB128(unsigned(I->MCDCParams.TrueID), OS); encodeULEB128(unsigned(I->MCDCParams.FalseID), OS); break; case CounterMappingRegion::MCDCDecisionRegion: encodeULEB128(unsigned(I->Kind) << Counter::EncodingCounterTagAndExpansionRegionTagBits, OS); encodeULEB128(unsigned(I->MCDCParams.BitmapIdx), OS); encodeULEB128(unsigned(I->MCDCParams.NumConditions), OS); break; } assert(I->LineStart >= PrevLineStart); encodeULEB128(I->LineStart - PrevLineStart, OS); encodeULEB128(I->ColumnStart, OS); assert(I->LineEnd >= I->LineStart); encodeULEB128(I->LineEnd - I->LineStart, OS); encodeULEB128(I->ColumnEnd, OS); PrevLineStart = I->LineStart; } // Ensure that all file ids have at least one mapping region. assert(CurrentFileID == (VirtualFileMapping.size() - 1)); } void TestingFormatWriter::write(raw_ostream &OS, TestingFormatVersion Version) { auto ByteSwap = [](uint64_t N) { return support::endian::byte_swap(N); }; // Output a 64bit magic number. auto Magic = ByteSwap(TestingFormatMagic); OS.write(reinterpret_cast(&Magic), sizeof(Magic)); // Output a 64bit version field. auto VersionLittle = ByteSwap(uint64_t(Version)); OS.write(reinterpret_cast(&VersionLittle), sizeof(VersionLittle)); // Output the ProfileNames data. encodeULEB128(ProfileNamesData.size(), OS); encodeULEB128(ProfileNamesAddr, OS); OS << ProfileNamesData; // Version2 adds an extra field to indicate the size of the // CoverageMappingData. if (Version == TestingFormatVersion::Version2) encodeULEB128(CoverageMappingData.size(), OS); // Coverage mapping data is expected to have an alignment of 8. for (unsigned Pad = offsetToAlignment(OS.tell(), Align(8)); Pad; --Pad) OS.write(uint8_t(0)); OS << CoverageMappingData; // Coverage records data is expected to have an alignment of 8. for (unsigned Pad = offsetToAlignment(OS.tell(), Align(8)); Pad; --Pad) OS.write(uint8_t(0)); OS << CoverageRecordsData; }