llvm-6502/include/llvm/ProfileData/CoverageMapping.h
Justin Bogner 1476756523 InstrProf: Don't keep a large sparse list around just to zero it
The Terms vector here represented a polynomial of of all possible
counters, and is used to simplify expressions when generating coverage
mapping. There are a few problems with this:

1. Keeping the vector as a member is wasteful, since we clear it every
   time we use it.
2. Most expressions refer to a subset of the counters, so we end up
   iterating over a large number of zeros doing nothing a lot of the
   time.

This updates the user of the vector to store the terms locally, and
uses a sort and combine approach so that we only operate on counters
that are actually used in a given expression. For small cases this
makes very little difference, but in cases with a very large number of
counted regions this is a significant performance fix.

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@218879 91177308-0d34-0410-b5e6-96231b3b80d8
2014-10-02 16:04:03 +00:00

376 lines
13 KiB
C++

//=-- 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_COVERAGEMAPPING_H_
#define LLVM_PROFILEDATA_COVERAGEMAPPING_H_
#include "llvm/ADT/ArrayRef.h"
#include "llvm/Support/ErrorOr.h"
#include "llvm/Support/raw_ostream.h"
#include <system_error>
namespace llvm {
class IndexedInstrProfReader;
namespace coverage {
class ObjectFileCoverageMappingReader;
class CoverageMapping;
struct CounterExpressions;
enum CoverageMappingVersion { CoverageMappingVersion1 };
/// \brief 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;
unsigned ID;
Counter(CounterKind Kind, unsigned ID) : Kind(Kind), ID(ID) {}
public:
Counter() : Kind(Zero), ID(0) {}
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; }
bool operator==(const Counter &Other) const {
return Kind == Other.Kind && ID == Other.ID;
}
friend bool operator<(const Counter &LHS, const Counter &RHS) {
return std::tie(LHS.Kind, LHS.ID) < std::tie(RHS.Kind, RHS.ID);
}
/// \brief Return the counter that represents the number zero.
static Counter getZero() { return Counter(); }
/// \brief Return the counter that corresponds to a specific profile counter.
static Counter getCounter(unsigned CounterId) {
return Counter(CounterValueReference, CounterId);
}
/// \brief Return the counter that corresponds to a specific
/// addition counter expression.
static Counter getExpression(unsigned ExpressionId) {
return Counter(Expression, ExpressionId);
}
};
/// \brief 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) {}
bool operator==(const CounterExpression &Other) const {
return Kind == Other.Kind && LHS == Other.LHS && RHS == Other.RHS;
}
};
/// \brief A Counter expression builder is used to construct the
/// counter expressions. It avoids unecessary duplication
/// and simplifies algebraic expressions.
class CounterExpressionBuilder {
/// \brief A list of all the counter expressions
llvm::SmallVector<CounterExpression, 16> Expressions;
/// \brief 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);
/// \brief 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<std::pair<unsigned, int>> &Terms);
/// \brief Simplifies the given expression tree
/// by getting rid of algebraically redundant operations.
Counter simplify(Counter ExpressionTree);
public:
ArrayRef<CounterExpression> getExpressions() const { return Expressions; }
/// \brief Return a counter that represents the expression
/// that adds LHS and RHS.
Counter add(Counter LHS, Counter RHS);
/// \brief Return a counter that represents the expression
/// that subtracts RHS from LHS.
Counter subtract(Counter LHS, Counter RHS);
};
/// \brief A Counter mapping region associates a source range with
/// a specific counter.
struct CounterMappingRegion {
enum RegionKind {
/// \brief A CodeRegion associates some code with a counter
CodeRegion,
/// \brief 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,
/// \brief A SkippedRegion represents a source range with code that
/// was skipped by a preprocessor or similar means.
SkippedRegion
};
static const unsigned EncodingHasCodeBeforeBits = 1;
Counter Count;
unsigned FileID, ExpandedFileID;
unsigned LineStart, ColumnStart, LineEnd, ColumnEnd;
RegionKind Kind;
/// \brief A flag that is set to true when there is already code before
/// this region on the same line.
/// This is useful to accurately compute the execution counts for a line.
bool HasCodeBefore;
CounterMappingRegion(Counter Count, unsigned FileID, unsigned LineStart,
unsigned ColumnStart, unsigned LineEnd,
unsigned ColumnEnd, bool HasCodeBefore = false,
RegionKind Kind = CodeRegion)
: Count(Count), FileID(FileID), ExpandedFileID(0), LineStart(LineStart),
ColumnStart(ColumnStart), LineEnd(LineEnd), ColumnEnd(ColumnEnd),
Kind(Kind), HasCodeBefore(HasCodeBefore) {}
inline std::pair<unsigned, unsigned> startLoc() const {
return std::pair<unsigned, unsigned>(LineStart, ColumnStart);
}
inline std::pair<unsigned, unsigned> endLoc() const {
return std::pair<unsigned, unsigned>(LineEnd, ColumnEnd);
}
bool operator<(const CounterMappingRegion &Other) const {
if (FileID != Other.FileID)
return FileID < Other.FileID;
return startLoc() < Other.startLoc();
}
bool contains(const CounterMappingRegion &Other) const {
if (FileID != Other.FileID)
return false;
if (startLoc() > Other.startLoc())
return false;
if (endLoc() < Other.endLoc())
return false;
return true;
}
};
/// \brief 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) {}
};
/// \brief A Counter mapping context is used to connect the counters,
/// expressions and the obtained counter values.
class CounterMappingContext {
ArrayRef<CounterExpression> Expressions;
ArrayRef<uint64_t> CounterValues;
public:
CounterMappingContext(ArrayRef<CounterExpression> Expressions,
ArrayRef<uint64_t> CounterValues = ArrayRef<uint64_t>())
: Expressions(Expressions), CounterValues(CounterValues) {}
void dump(const Counter &C, llvm::raw_ostream &OS) const;
void dump(const Counter &C) const { dump(C, llvm::outs()); }
/// \brief Return the number of times that a region of code associated with
/// this counter was executed.
ErrorOr<int64_t> evaluate(const Counter &C) const;
};
/// \brief Code coverage information for a single function.
struct FunctionRecord {
/// \brief Raw function name.
std::string Name;
/// \brief Associated files.
std::vector<std::string> Filenames;
/// \brief Regions in the function along with their counts.
std::vector<CountedRegion> CountedRegions;
/// \brief The number of times this function was executed.
uint64_t ExecutionCount;
FunctionRecord(StringRef Name, ArrayRef<StringRef> Filenames,
uint64_t ExecutionCount)
: Name(Name), Filenames(Filenames.begin(), Filenames.end()),
ExecutionCount(ExecutionCount) {}
};
/// \brief 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 {
/// \brief The abstract file this expansion covers.
unsigned FileID;
/// \brief The region that expands to this record.
const CountedRegion &Region;
/// \brief Coverage for the expansion.
const FunctionRecord &Function;
ExpansionRecord(const CountedRegion &Region,
const FunctionRecord &Function)
: FileID(Region.ExpandedFileID), Region(Region), Function(Function) {}
};
/// \brief 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 {
/// \brief The line where this segment begins.
unsigned Line;
/// \brief The column where this segment begins.
unsigned Col;
/// \brief The execution count, or zero if no count was recorded.
uint64_t Count;
/// \brief When false, the segment was uninstrumented or skipped.
bool HasCount;
/// \brief Whether this enters a new region or returns to a previous count.
bool IsRegionEntry;
CoverageSegment(unsigned Line, unsigned Col, bool IsRegionEntry)
: Line(Line), Col(Col), Count(0), HasCount(false),
IsRegionEntry(IsRegionEntry) {}
void setCount(uint64_t NewCount) {
Count = NewCount;
HasCount = true;
}
void addCount(uint64_t NewCount) { setCount(Count + NewCount); }
};
/// \brief 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 {
std::string Filename;
std::vector<CoverageSegment> Segments;
std::vector<ExpansionRecord> Expansions;
friend class CoverageMapping;
public:
CoverageData() {}
CoverageData(StringRef Filename) : Filename(Filename) {}
CoverageData(CoverageData &&RHS)
: Filename(std::move(RHS.Filename)), Segments(std::move(RHS.Segments)),
Expansions(std::move(RHS.Expansions)) {}
/// \brief Get the name of the file this data covers.
StringRef getFilename() { return Filename; }
std::vector<CoverageSegment>::iterator begin() { return Segments.begin(); }
std::vector<CoverageSegment>::iterator end() { return Segments.end(); }
bool empty() { return Segments.empty(); }
/// \brief Expansions that can be further processed.
std::vector<ExpansionRecord> getExpansions() { return Expansions; }
};
/// \brief 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 {
std::vector<FunctionRecord> Functions;
unsigned MismatchedFunctionCount;
CoverageMapping() : MismatchedFunctionCount(0) {}
public:
/// \brief Load the coverage mapping using the given readers.
static ErrorOr<std::unique_ptr<CoverageMapping>>
load(ObjectFileCoverageMappingReader &CoverageReader,
IndexedInstrProfReader &ProfileReader);
/// \brief Load the coverage mapping from the given files.
static ErrorOr<std::unique_ptr<CoverageMapping>>
load(StringRef ObjectFilename, StringRef ProfileFilename);
/// \brief 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() { return MismatchedFunctionCount; }
/// \brief Returns the list of files that are covered.
std::vector<StringRef> getUniqueSourceFiles();
/// \brief 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);
/// \brief Gets all of the functions covered by this profile.
ArrayRef<FunctionRecord> getCoveredFunctions() {
return ArrayRef<FunctionRecord>(Functions.data(), Functions.size());
}
/// \brief Get the list of function instantiations in the file.
///
/// Fucntions that are instantiated more than once, such as C++ template
/// specializations, have distinct coverage records for each instantiation.
std::vector<const FunctionRecord *> getInstantiations(StringRef Filename);
/// \brief Get the coverage for a particular function.
CoverageData getCoverageForFunction(const FunctionRecord &Function);
/// \brief Get the coverage for an expansion within a coverage set.
CoverageData getCoverageForExpansion(const ExpansionRecord &Expansion);
};
} // end namespace coverage
} // end namespace llvm
#endif // LLVM_PROFILEDATA_COVERAGEMAPPING_H_