//===- CoverageMapping.h - Code coverage mapping support --------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // Code coverage mapping data is generated by clang and read by // llvm-cov to show code coverage statistics for a file. // //===----------------------------------------------------------------------===// #ifndef LLVM_PROFILEDATA_COVERAGE_COVERAGEMAPPING_H #define LLVM_PROFILEDATA_COVERAGE_COVERAGEMAPPING_H #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/DenseSet.h" #include "llvm/ADT/Hashing.h" #include "llvm/ADT/None.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/StringSet.h" #include "llvm/ADT/iterator.h" #include "llvm/ADT/iterator_range.h" #include "llvm/ProfileData/InstrProf.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Debug.h" #include "llvm/Support/Endian.h" #include "llvm/Support/Error.h" #include "llvm/Support/raw_ostream.h" #include #include #include #include #include #include #include #include #include namespace llvm { class IndexedInstrProfReader; namespace coverage { class CoverageMappingReader; struct CoverageMappingRecord; enum class coveragemap_error { success = 0, eof, no_data_found, unsupported_version, truncated, malformed }; const std::error_category &coveragemap_category(); inline std::error_code make_error_code(coveragemap_error E) { return std::error_code(static_cast(E), coveragemap_category()); } class CoverageMapError : public ErrorInfo { public: CoverageMapError(coveragemap_error Err) : Err(Err) { assert(Err != coveragemap_error::success && "Not an error"); } std::string message() const override; void log(raw_ostream &OS) const override { OS << message(); } std::error_code convertToErrorCode() const override { return make_error_code(Err); } coveragemap_error get() const { return Err; } static char ID; private: coveragemap_error Err; }; /// A Counter is an abstract value that describes how to compute the /// execution count for a region of code using the collected profile count data. struct Counter { enum CounterKind { Zero, CounterValueReference, Expression }; static const unsigned EncodingTagBits = 2; static const unsigned EncodingTagMask = 0x3; static const unsigned EncodingCounterTagAndExpansionRegionTagBits = EncodingTagBits + 1; private: CounterKind Kind = Zero; unsigned ID = 0; Counter(CounterKind Kind, unsigned ID) : Kind(Kind), ID(ID) {} public: Counter() = default; CounterKind getKind() const { return Kind; } bool isZero() const { return Kind == Zero; } bool isExpression() const { return Kind == Expression; } unsigned getCounterID() const { return ID; } unsigned getExpressionID() const { return ID; } friend bool operator==(const Counter &LHS, const Counter &RHS) { return LHS.Kind == RHS.Kind && LHS.ID == RHS.ID; } friend bool operator!=(const Counter &LHS, const Counter &RHS) { return !(LHS == RHS); } friend bool operator<(const Counter &LHS, const Counter &RHS) { return std::tie(LHS.Kind, LHS.ID) < std::tie(RHS.Kind, RHS.ID); } /// Return the counter that represents the number zero. static Counter getZero() { return Counter(); } /// Return the counter that corresponds to a specific profile counter. static Counter getCounter(unsigned CounterId) { return Counter(CounterValueReference, CounterId); } /// Return the counter that corresponds to a specific addition counter /// expression. static Counter getExpression(unsigned ExpressionId) { return Counter(Expression, ExpressionId); } }; /// A Counter expression is a value that represents an arithmetic operation /// with two counters. struct CounterExpression { enum ExprKind { Subtract, Add }; ExprKind Kind; Counter LHS, RHS; CounterExpression(ExprKind Kind, Counter LHS, Counter RHS) : Kind(Kind), LHS(LHS), RHS(RHS) {} }; /// A Counter expression builder is used to construct the counter expressions. /// It avoids unnecessary duplication and simplifies algebraic expressions. class CounterExpressionBuilder { /// A list of all the counter expressions std::vector Expressions; /// A lookup table for the index of a given expression. DenseMap ExpressionIndices; /// Return the counter which corresponds to the given expression. /// /// If the given expression is already stored in the builder, a counter /// that references that expression is returned. Otherwise, the given /// expression is added to the builder's collection of expressions. Counter get(const CounterExpression &E); /// Represents a term in a counter expression tree. struct Term { unsigned CounterID; int Factor; Term(unsigned CounterID, int Factor) : CounterID(CounterID), Factor(Factor) {} }; /// Gather the terms of the expression tree for processing. /// /// This collects each addition and subtraction referenced by the counter into /// a sequence that can be sorted and combined to build a simplified counter /// expression. void extractTerms(Counter C, int Sign, SmallVectorImpl &Terms); /// Simplifies the given expression tree /// by getting rid of algebraically redundant operations. Counter simplify(Counter ExpressionTree); public: ArrayRef getExpressions() const { return Expressions; } /// Return a counter that represents the expression that adds LHS and RHS. Counter add(Counter LHS, Counter RHS); /// Return a counter that represents the expression that subtracts RHS from /// LHS. Counter subtract(Counter LHS, Counter RHS); }; using LineColPair = std::pair; /// A Counter mapping region associates a source range with a specific counter. struct CounterMappingRegion { enum RegionKind { /// A CodeRegion associates some code with a counter CodeRegion, /// An ExpansionRegion represents a file expansion region that associates /// a source range with the expansion of a virtual source file, such as /// for a macro instantiation or #include file. ExpansionRegion, /// A SkippedRegion represents a source range with code that was skipped /// by a preprocessor or similar means. SkippedRegion, /// A GapRegion is like a CodeRegion, but its count is only set as the /// line execution count when its the only region in the line. GapRegion }; Counter Count; unsigned FileID, ExpandedFileID; unsigned LineStart, ColumnStart, LineEnd, ColumnEnd; RegionKind Kind; CounterMappingRegion(Counter Count, unsigned FileID, unsigned ExpandedFileID, unsigned LineStart, unsigned ColumnStart, unsigned LineEnd, unsigned ColumnEnd, RegionKind Kind) : Count(Count), FileID(FileID), ExpandedFileID(ExpandedFileID), LineStart(LineStart), ColumnStart(ColumnStart), LineEnd(LineEnd), ColumnEnd(ColumnEnd), Kind(Kind) {} static CounterMappingRegion makeRegion(Counter Count, unsigned FileID, unsigned LineStart, unsigned ColumnStart, unsigned LineEnd, unsigned ColumnEnd) { return CounterMappingRegion(Count, FileID, 0, LineStart, ColumnStart, LineEnd, ColumnEnd, CodeRegion); } static CounterMappingRegion makeExpansion(unsigned FileID, unsigned ExpandedFileID, unsigned LineStart, unsigned ColumnStart, unsigned LineEnd, unsigned ColumnEnd) { return CounterMappingRegion(Counter(), FileID, ExpandedFileID, LineStart, ColumnStart, LineEnd, ColumnEnd, ExpansionRegion); } static CounterMappingRegion makeSkipped(unsigned FileID, unsigned LineStart, unsigned ColumnStart, unsigned LineEnd, unsigned ColumnEnd) { return CounterMappingRegion(Counter(), FileID, 0, LineStart, ColumnStart, LineEnd, ColumnEnd, SkippedRegion); } static CounterMappingRegion makeGapRegion(Counter Count, unsigned FileID, unsigned LineStart, unsigned ColumnStart, unsigned LineEnd, unsigned ColumnEnd) { return CounterMappingRegion(Count, FileID, 0, LineStart, ColumnStart, LineEnd, (1U << 31) | ColumnEnd, GapRegion); } inline LineColPair startLoc() const { return LineColPair(LineStart, ColumnStart); } inline LineColPair endLoc() const { return LineColPair(LineEnd, ColumnEnd); } }; /// Associates a source range with an execution count. struct CountedRegion : public CounterMappingRegion { uint64_t ExecutionCount; CountedRegion(const CounterMappingRegion &R, uint64_t ExecutionCount) : CounterMappingRegion(R), ExecutionCount(ExecutionCount) {} }; /// A Counter mapping context is used to connect the counters, expressions /// and the obtained counter values. class CounterMappingContext { ArrayRef Expressions; ArrayRef CounterValues; public: CounterMappingContext(ArrayRef Expressions, ArrayRef CounterValues = None) : Expressions(Expressions), CounterValues(CounterValues) {} void setCounts(ArrayRef Counts) { CounterValues = Counts; } void dump(const Counter &C, raw_ostream &OS) const; void dump(const Counter &C) const { dump(C, dbgs()); } /// Return the number of times that a region of code associated with this /// counter was executed. Expected evaluate(const Counter &C) const; }; /// Code coverage information for a single function. struct FunctionRecord { /// Raw function name. std::string Name; /// Associated files. std::vector Filenames; /// Regions in the function along with their counts. std::vector CountedRegions; /// The number of times this function was executed. uint64_t ExecutionCount; FunctionRecord(StringRef Name, ArrayRef Filenames) : Name(Name), Filenames(Filenames.begin(), Filenames.end()) {} FunctionRecord(FunctionRecord &&FR) = default; FunctionRecord &operator=(FunctionRecord &&) = default; void pushRegion(CounterMappingRegion Region, uint64_t Count) { if (CountedRegions.empty()) ExecutionCount = Count; CountedRegions.emplace_back(Region, Count); } }; /// Iterator over Functions, optionally filtered to a single file. class FunctionRecordIterator : public iterator_facade_base { ArrayRef Records; ArrayRef::iterator Current; StringRef Filename; /// Skip records whose primary file is not \c Filename. void skipOtherFiles(); public: FunctionRecordIterator(ArrayRef Records_, StringRef Filename = "") : Records(Records_), Current(Records.begin()), Filename(Filename) { skipOtherFiles(); } FunctionRecordIterator() : Current(Records.begin()) {} bool operator==(const FunctionRecordIterator &RHS) const { return Current == RHS.Current && Filename == RHS.Filename; } const FunctionRecord &operator*() const { return *Current; } FunctionRecordIterator &operator++() { assert(Current != Records.end() && "incremented past end"); ++Current; skipOtherFiles(); return *this; } }; /// Coverage information for a macro expansion or #included file. /// /// When covered code has pieces that can be expanded for more detail, such as a /// preprocessor macro use and its definition, these are represented as /// expansions whose coverage can be looked up independently. struct ExpansionRecord { /// The abstract file this expansion covers. unsigned FileID; /// The region that expands to this record. const CountedRegion &Region; /// Coverage for the expansion. const FunctionRecord &Function; ExpansionRecord(const CountedRegion &Region, const FunctionRecord &Function) : FileID(Region.ExpandedFileID), Region(Region), Function(Function) {} }; /// The execution count information starting at a point in a file. /// /// A sequence of CoverageSegments gives execution counts for a file in format /// that's simple to iterate through for processing. struct CoverageSegment { /// The line where this segment begins. unsigned Line; /// The column where this segment begins. unsigned Col; /// The execution count, or zero if no count was recorded. uint64_t Count; /// When false, the segment was uninstrumented or skipped. bool HasCount; /// Whether this enters a new region or returns to a previous count. bool IsRegionEntry; /// Whether this enters a gap region. bool IsGapRegion; CoverageSegment(unsigned Line, unsigned Col, bool IsRegionEntry) : Line(Line), Col(Col), Count(0), HasCount(false), IsRegionEntry(IsRegionEntry), IsGapRegion(false) {} CoverageSegment(unsigned Line, unsigned Col, uint64_t Count, bool IsRegionEntry, bool IsGapRegion = false) : Line(Line), Col(Col), Count(Count), HasCount(true), IsRegionEntry(IsRegionEntry), IsGapRegion(IsGapRegion) {} friend bool operator==(const CoverageSegment &L, const CoverageSegment &R) { return std::tie(L.Line, L.Col, L.Count, L.HasCount, L.IsRegionEntry, L.IsGapRegion) == std::tie(R.Line, R.Col, R.Count, R.HasCount, R.IsRegionEntry, R.IsGapRegion); } }; /// An instantiation group contains a \c FunctionRecord list, such that each /// record corresponds to a distinct instantiation of the same function. /// /// Note that it's possible for a function to have more than one instantiation /// (consider C++ template specializations or static inline functions). class InstantiationGroup { friend class CoverageMapping; unsigned Line; unsigned Col; std::vector Instantiations; InstantiationGroup(unsigned Line, unsigned Col, std::vector Instantiations) : Line(Line), Col(Col), Instantiations(std::move(Instantiations)) {} public: InstantiationGroup(const InstantiationGroup &) = delete; InstantiationGroup(InstantiationGroup &&) = default; /// Get the number of instantiations in this group. size_t size() const { return Instantiations.size(); } /// Get the line where the common function was defined. unsigned getLine() const { return Line; } /// Get the column where the common function was defined. unsigned getColumn() const { return Col; } /// Check if the instantiations in this group have a common mangled name. bool hasName() const { for (unsigned I = 1, E = Instantiations.size(); I < E; ++I) if (Instantiations[I]->Name != Instantiations[0]->Name) return false; return true; } /// Get the common mangled name for instantiations in this group. StringRef getName() const { assert(hasName() && "Instantiations don't have a shared name"); return Instantiations[0]->Name; } /// Get the total execution count of all instantiations in this group. uint64_t getTotalExecutionCount() const { uint64_t Count = 0; for (const FunctionRecord *F : Instantiations) Count += F->ExecutionCount; return Count; } /// Get the instantiations in this group. ArrayRef getInstantiations() const { return Instantiations; } }; /// Coverage information to be processed or displayed. /// /// This represents the coverage of an entire file, expansion, or function. It /// provides a sequence of CoverageSegments to iterate through, as well as the /// list of expansions that can be further processed. class CoverageData { friend class CoverageMapping; std::string Filename; std::vector Segments; std::vector Expansions; public: CoverageData() = default; CoverageData(StringRef Filename) : Filename(Filename) {} /// Get the name of the file this data covers. StringRef getFilename() const { return Filename; } /// Get an iterator over the coverage segments for this object. The segments /// are guaranteed to be uniqued and sorted by location. std::vector::const_iterator begin() const { return Segments.begin(); } std::vector::const_iterator end() const { return Segments.end(); } bool empty() const { return Segments.empty(); } /// Expansions that can be further processed. ArrayRef getExpansions() const { return Expansions; } }; /// The mapping of profile information to coverage data. /// /// This is the main interface to get coverage information, using a profile to /// fill out execution counts. class CoverageMapping { DenseMap> RecordProvenance; std::vector Functions; std::vector> FuncHashMismatches; std::vector> FuncCounterMismatches; CoverageMapping() = default; /// Add a function record corresponding to \p Record. Error loadFunctionRecord(const CoverageMappingRecord &Record, IndexedInstrProfReader &ProfileReader); public: CoverageMapping(const CoverageMapping &) = delete; CoverageMapping &operator=(const CoverageMapping &) = delete; /// Load the coverage mapping using the given readers. static Expected> load(ArrayRef> CoverageReaders, IndexedInstrProfReader &ProfileReader); /// Load the coverage mapping from the given object files and profile. If /// \p Arches is non-empty, it must specify an architecture for each object. static Expected> load(ArrayRef ObjectFilenames, StringRef ProfileFilename, ArrayRef Arches = None); /// The number of functions that couldn't have their profiles mapped. /// /// This is a count of functions whose profile is out of date or otherwise /// can't be associated with any coverage information. unsigned getMismatchedCount() const { return FuncHashMismatches.size() + FuncCounterMismatches.size(); } /// A hash mismatch occurs when a profile record for a symbol does not have /// the same hash as a coverage mapping record for the same symbol. This /// returns a list of hash mismatches, where each mismatch is a pair of the /// symbol name and its coverage mapping hash. ArrayRef> getHashMismatches() const { return FuncHashMismatches; } /// A counter mismatch occurs when there is an error when evaluating the /// counter expressions in a coverage mapping record. This returns a list of /// counter mismatches, where each mismatch is a pair of the symbol name and /// the number of valid evaluated counter expressions. ArrayRef> getCounterMismatches() const { return FuncCounterMismatches; } /// Returns a lexicographically sorted, unique list of files that are /// covered. std::vector getUniqueSourceFiles() const; /// Get the coverage for a particular file. /// /// The given filename must be the name as recorded in the coverage /// information. That is, only names returned from getUniqueSourceFiles will /// yield a result. CoverageData getCoverageForFile(StringRef Filename) const; /// Get the coverage for a particular function. CoverageData getCoverageForFunction(const FunctionRecord &Function) const; /// Get the coverage for an expansion within a coverage set. CoverageData getCoverageForExpansion(const ExpansionRecord &Expansion) const; /// Gets all of the functions covered by this profile. iterator_range getCoveredFunctions() const { return make_range(FunctionRecordIterator(Functions), FunctionRecordIterator()); } /// Gets all of the functions in a particular file. iterator_range getCoveredFunctions(StringRef Filename) const { return make_range(FunctionRecordIterator(Functions, Filename), FunctionRecordIterator()); } /// Get the list of function instantiation groups in a particular file. /// /// Every instantiation group in a program is attributed to exactly one file: /// the file in which the definition for the common function begins. std::vector getInstantiationGroups(StringRef Filename) const; }; /// Coverage statistics for a single line. class LineCoverageStats { uint64_t ExecutionCount; bool HasMultipleRegions; bool Mapped; unsigned Line; ArrayRef LineSegments; const CoverageSegment *WrappedSegment; friend class LineCoverageIterator; LineCoverageStats() = default; public: LineCoverageStats(ArrayRef LineSegments, const CoverageSegment *WrappedSegment, unsigned Line); uint64_t getExecutionCount() const { return ExecutionCount; } bool hasMultipleRegions() const { return HasMultipleRegions; } bool isMapped() const { return Mapped; } unsigned getLine() const { return Line; } ArrayRef getLineSegments() const { return LineSegments; } const CoverageSegment *getWrappedSegment() const { return WrappedSegment; } }; /// An iterator over the \c LineCoverageStats objects for lines described by /// a \c CoverageData instance. class LineCoverageIterator : public iterator_facade_base< LineCoverageIterator, std::forward_iterator_tag, LineCoverageStats> { public: LineCoverageIterator(const CoverageData &CD) : LineCoverageIterator(CD, CD.begin()->Line) {} LineCoverageIterator(const CoverageData &CD, unsigned Line) : CD(CD), WrappedSegment(nullptr), Next(CD.begin()), Ended(false), Line(Line), Segments(), Stats() { this->operator++(); } bool operator==(const LineCoverageIterator &R) const { return &CD == &R.CD && Next == R.Next && Ended == R.Ended; } const LineCoverageStats &operator*() const { return Stats; } LineCoverageStats &operator*() { return Stats; } LineCoverageIterator &operator++(); LineCoverageIterator getEnd() const { auto EndIt = *this; EndIt.Next = CD.end(); EndIt.Ended = true; return EndIt; } private: const CoverageData &CD; const CoverageSegment *WrappedSegment; std::vector::const_iterator Next; bool Ended; unsigned Line; SmallVector Segments; LineCoverageStats Stats; }; /// Get a \c LineCoverageIterator range for the lines described by \p CD. static inline iterator_range getLineCoverageStats(const coverage::CoverageData &CD) { auto Begin = LineCoverageIterator(CD); auto End = Begin.getEnd(); return make_range(Begin, End); } // Profile coverage map has the following layout: // [CoverageMapFileHeader] // [ArrayStart] // [CovMapFunctionRecord] // [CovMapFunctionRecord] // ... // [ArrayEnd] // [Encoded Region Mapping Data] LLVM_PACKED_START template struct CovMapFunctionRecordV1 { #define COVMAP_V1 #define COVMAP_FUNC_RECORD(Type, LLVMType, Name, Init) Type Name; #include "llvm/ProfileData/InstrProfData.inc" #undef COVMAP_V1 // Return the structural hash associated with the function. template uint64_t getFuncHash() const { return support::endian::byte_swap(FuncHash); } // Return the coverage map data size for the funciton. template uint32_t getDataSize() const { return support::endian::byte_swap(DataSize); } // Return function lookup key. The value is consider opaque. template IntPtrT getFuncNameRef() const { return support::endian::byte_swap(NamePtr); } // Return the PGO name of the function */ template Error getFuncName(InstrProfSymtab &ProfileNames, StringRef &FuncName) const { IntPtrT NameRef = getFuncNameRef(); uint32_t NameS = support::endian::byte_swap(NameSize); FuncName = ProfileNames.getFuncName(NameRef, NameS); if (NameS && FuncName.empty()) return make_error(coveragemap_error::malformed); return Error::success(); } }; struct CovMapFunctionRecord { #define COVMAP_FUNC_RECORD(Type, LLVMType, Name, Init) Type Name; #include "llvm/ProfileData/InstrProfData.inc" // Return the structural hash associated with the function. template uint64_t getFuncHash() const { return support::endian::byte_swap(FuncHash); } // Return the coverage map data size for the funciton. template uint32_t getDataSize() const { return support::endian::byte_swap(DataSize); } // Return function lookup key. The value is consider opaque. template uint64_t getFuncNameRef() const { return support::endian::byte_swap(NameRef); } // Return the PGO name of the function */ template Error getFuncName(InstrProfSymtab &ProfileNames, StringRef &FuncName) const { uint64_t NameRef = getFuncNameRef(); FuncName = ProfileNames.getFuncName(NameRef); return Error::success(); } }; // Per module coverage mapping data header, i.e. CoverageMapFileHeader // documented above. struct CovMapHeader { #define COVMAP_HEADER(Type, LLVMType, Name, Init) Type Name; #include "llvm/ProfileData/InstrProfData.inc" template uint32_t getNRecords() const { return support::endian::byte_swap(NRecords); } template uint32_t getFilenamesSize() const { return support::endian::byte_swap(FilenamesSize); } template uint32_t getCoverageSize() const { return support::endian::byte_swap(CoverageSize); } template uint32_t getVersion() const { return support::endian::byte_swap(Version); } }; LLVM_PACKED_END enum CovMapVersion { Version1 = 0, // Function's name reference from CovMapFuncRecord is changed from raw // name string pointer to MD5 to support name section compression. Name // section is also compressed. Version2 = 1, // A new interpretation of the columnEnd field is added in order to mark // regions as gap areas. Version3 = 2, // The current version is Version3 CurrentVersion = INSTR_PROF_COVMAP_VERSION }; template struct CovMapTraits { using CovMapFuncRecordType = CovMapFunctionRecord; using NameRefType = uint64_t; }; template struct CovMapTraits { using CovMapFuncRecordType = CovMapFunctionRecordV1; using NameRefType = IntPtrT; }; } // end namespace coverage /// Provide DenseMapInfo for CounterExpression template<> struct DenseMapInfo { static inline coverage::CounterExpression getEmptyKey() { using namespace coverage; return CounterExpression(CounterExpression::ExprKind::Subtract, Counter::getCounter(~0U), Counter::getCounter(~0U)); } static inline coverage::CounterExpression getTombstoneKey() { using namespace coverage; return CounterExpression(CounterExpression::ExprKind::Add, Counter::getCounter(~0U), Counter::getCounter(~0U)); } static unsigned getHashValue(const coverage::CounterExpression &V) { return static_cast( hash_combine(V.Kind, V.LHS.getKind(), V.LHS.getCounterID(), V.RHS.getKind(), V.RHS.getCounterID())); } static bool isEqual(const coverage::CounterExpression &LHS, const coverage::CounterExpression &RHS) { return LHS.Kind == RHS.Kind && LHS.LHS == RHS.LHS && LHS.RHS == RHS.RHS; } }; } // end namespace llvm #endif // LLVM_PROFILEDATA_COVERAGE_COVERAGEMAPPING_H