llvm-for-llvmta/tools/llvm-cov/CoverageExporterLcov.cpp

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//===- CoverageExporterLcov.cpp - Code coverage export --------------------===//
//
// 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 export of code coverage data to lcov trace file format.
//
//===----------------------------------------------------------------------===//
//===----------------------------------------------------------------------===//
//
// The trace file code coverage export follows the following format (see also
// https://linux.die.net/man/1/geninfo). Each quoted string appears on its own
// line; the indentation shown here is only for documentation purposes.
//
// - for each source file:
// - "SF:<absolute path to source file>"
// - for each function:
// - "FN:<line number of function start>,<function name>"
// - for each function:
// - "FNDA:<execution count>,<function name>"
// - "FNF:<number of functions found>"
// - "FNH:<number of functions hit>"
// - for each instrumented line:
// - "DA:<line number>,<execution count>[,<checksum>]
// - for each branch:
// - "BRDA:<line number>,<branch pair id>,<branch id>,<count>"
// - "BRF:<number of branches found>"
// - "BRH:<number of branches hit>"
// - "LH:<number of lines with non-zero execution count>"
// - "LF:<number of instrumented lines>"
// - "end_of_record"
//
// If the user is exporting summary information only, then the FN, FNDA, and DA
// lines will not be present.
//
//===----------------------------------------------------------------------===//
#include "CoverageExporterLcov.h"
#include "CoverageReport.h"
using namespace llvm;
namespace {
void renderFunctionSummary(raw_ostream &OS,
const FileCoverageSummary &Summary) {
OS << "FNF:" << Summary.FunctionCoverage.getNumFunctions() << '\n'
<< "FNH:" << Summary.FunctionCoverage.getExecuted() << '\n';
}
void renderFunctions(
raw_ostream &OS,
const iterator_range<coverage::FunctionRecordIterator> &Functions) {
for (const auto &F : Functions) {
auto StartLine = F.CountedRegions.front().LineStart;
OS << "FN:" << StartLine << ',' << F.Name << '\n';
}
for (const auto &F : Functions)
OS << "FNDA:" << F.ExecutionCount << ',' << F.Name << '\n';
}
void renderLineExecutionCounts(raw_ostream &OS,
const coverage::CoverageData &FileCoverage) {
coverage::LineCoverageIterator LCI{FileCoverage, 1};
coverage::LineCoverageIterator LCIEnd = LCI.getEnd();
for (; LCI != LCIEnd; ++LCI) {
const coverage::LineCoverageStats &LCS = *LCI;
if (LCS.isMapped()) {
OS << "DA:" << LCS.getLine() << ',' << LCS.getExecutionCount() << '\n';
}
}
}
std::vector<llvm::coverage::CountedRegion>
collectNestedBranches(const coverage::CoverageMapping &Coverage,
ArrayRef<llvm::coverage::ExpansionRecord> Expansions,
int ViewDepth = 0, int SrcLine = 0) {
std::vector<llvm::coverage::CountedRegion> Branches;
for (const auto &Expansion : Expansions) {
auto ExpansionCoverage = Coverage.getCoverageForExpansion(Expansion);
// If we're at the top level, set the corresponding source line.
if (ViewDepth == 0)
SrcLine = Expansion.Region.LineStart;
// Recursively collect branches from nested expansions.
auto NestedExpansions = ExpansionCoverage.getExpansions();
auto NestedExBranches = collectNestedBranches(Coverage, NestedExpansions,
ViewDepth + 1, SrcLine);
Branches.insert(Branches.end(), NestedExBranches.begin(),
NestedExBranches.end());
// Add branches from this level of expansion.
auto ExBranches = ExpansionCoverage.getBranches();
for (auto B : ExBranches)
if (B.FileID == Expansion.FileID) {
B.LineStart = SrcLine;
Branches.push_back(B);
}
}
return Branches;
}
bool sortLine(llvm::coverage::CountedRegion I,
llvm::coverage::CountedRegion J) {
return (I.LineStart < J.LineStart) ||
((I.LineStart == J.LineStart) && (I.ColumnStart < J.ColumnStart));
}
void renderBranchExecutionCounts(raw_ostream &OS,
const coverage::CoverageMapping &Coverage,
const coverage::CoverageData &FileCoverage) {
std::vector<llvm::coverage::CountedRegion> Branches =
FileCoverage.getBranches();
// Recursively collect branches for all file expansions.
std::vector<llvm::coverage::CountedRegion> ExBranches =
collectNestedBranches(Coverage, FileCoverage.getExpansions());
// Append Expansion Branches to Source Branches.
Branches.insert(Branches.end(), ExBranches.begin(), ExBranches.end());
// Sort branches based on line number to ensure branches corresponding to the
// same source line are counted together.
llvm::sort(Branches, sortLine);
auto NextBranch = Branches.begin();
auto EndBranch = Branches.end();
// Branches with the same source line are enumerated individually
// (BranchIndex) as well as based on True/False pairs (PairIndex).
while (NextBranch != EndBranch) {
unsigned CurrentLine = NextBranch->LineStart;
unsigned PairIndex = 0;
unsigned BranchIndex = 0;
while (NextBranch != EndBranch && CurrentLine == NextBranch->LineStart) {
if (!NextBranch->Folded) {
unsigned BC1 = NextBranch->ExecutionCount;
unsigned BC2 = NextBranch->FalseExecutionCount;
bool BranchNotExecuted = (BC1 == 0 && BC2 == 0);
for (int I = 0; I < 2; I++, BranchIndex++) {
OS << "BRDA:" << CurrentLine << ',' << PairIndex << ','
<< BranchIndex;
if (BranchNotExecuted)
OS << ',' << '-' << '\n';
else
OS << ',' << (I == 0 ? BC1 : BC2) << '\n';
}
PairIndex++;
}
NextBranch++;
}
}
}
void renderLineSummary(raw_ostream &OS, const FileCoverageSummary &Summary) {
OS << "LF:" << Summary.LineCoverage.getNumLines() << '\n'
<< "LH:" << Summary.LineCoverage.getCovered() << '\n';
}
void renderBranchSummary(raw_ostream &OS, const FileCoverageSummary &Summary) {
OS << "BRF:" << Summary.BranchCoverage.getNumBranches() << '\n'
<< "BFH:" << Summary.BranchCoverage.getCovered() << '\n';
}
void renderFile(raw_ostream &OS, const coverage::CoverageMapping &Coverage,
const std::string &Filename,
const FileCoverageSummary &FileReport, bool ExportSummaryOnly,
bool SkipFunctions) {
OS << "SF:" << Filename << '\n';
if (!ExportSummaryOnly && !SkipFunctions) {
renderFunctions(OS, Coverage.getCoveredFunctions(Filename));
}
renderFunctionSummary(OS, FileReport);
if (!ExportSummaryOnly) {
// Calculate and render detailed coverage information for given file.
auto FileCoverage = Coverage.getCoverageForFile(Filename);
renderLineExecutionCounts(OS, FileCoverage);
renderBranchExecutionCounts(OS, Coverage, FileCoverage);
}
renderBranchSummary(OS, FileReport);
renderLineSummary(OS, FileReport);
OS << "end_of_record\n";
}
void renderFiles(raw_ostream &OS, const coverage::CoverageMapping &Coverage,
ArrayRef<std::string> SourceFiles,
ArrayRef<FileCoverageSummary> FileReports,
bool ExportSummaryOnly, bool SkipFunctions) {
for (unsigned I = 0, E = SourceFiles.size(); I < E; ++I)
renderFile(OS, Coverage, SourceFiles[I], FileReports[I], ExportSummaryOnly,
SkipFunctions);
}
} // end anonymous namespace
void CoverageExporterLcov::renderRoot(const CoverageFilters &IgnoreFilters) {
std::vector<std::string> SourceFiles;
for (StringRef SF : Coverage.getUniqueSourceFiles()) {
if (!IgnoreFilters.matchesFilename(SF))
SourceFiles.emplace_back(SF);
}
renderRoot(SourceFiles);
}
void CoverageExporterLcov::renderRoot(ArrayRef<std::string> SourceFiles) {
FileCoverageSummary Totals = FileCoverageSummary("Totals");
auto FileReports = CoverageReport::prepareFileReports(Coverage, Totals,
SourceFiles, Options);
renderFiles(OS, Coverage, SourceFiles, FileReports, Options.ExportSummaryOnly,
Options.SkipFunctions);
}