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llvm-mirror/tools/llvm-cov/CodeCoverage.cpp
Alexandre Ganea ae05eb086d [Support] On Windows, ensure hardware_concurrency() extends to all CPU sockets and all NUMA groups
The goal of this patch is to maximize CPU utilization on multi-socket or high core count systems, so that parallel computations such as LLD/ThinLTO can use all hardware threads in the system. Before this patch, on Windows, a maximum of 64 hardware threads could be used at most, in some cases dispatched only on one CPU socket.

== Background ==
Windows doesn't have a flat cpu_set_t like Linux. Instead, it projects hardware CPUs (or NUMA nodes) to applications through a concept of "processor groups". A "processor" is the smallest unit of execution on a CPU, that is, an hyper-thread if SMT is active; a core otherwise. There's a limit of 32-bit processors on older 32-bit versions of Windows, which later was raised to 64-processors with 64-bit versions of Windows. This limit comes from the affinity mask, which historically is represented by the sizeof(void*). Consequently, the concept of "processor groups" was introduced for dealing with systems with more than 64 hyper-threads.

By default, the Windows OS assigns only one "processor group" to each starting application, in a round-robin manner. If the application wants to use more processors, it needs to programmatically enable it, by assigning threads to other "processor groups". This also means that affinity cannot cross "processor group" boundaries; one can only specify a "preferred" group on start-up, but the application is free to allocate more groups if it wants to.

This creates a peculiar situation, where newer CPUs like the AMD EPYC 7702P (64-cores, 128-hyperthreads) are projected by the OS as two (2) "processor groups". This means that by default, an application can only use half of the cores. This situation could only get worse in the years to come, as dies with more cores will appear on the market.

== The problem ==
The heavyweight_hardware_concurrency() API was introduced so that only *one hardware thread per core* was used. Once that API returns, that original intention is lost, only the number of threads is retained. Consider a situation, on Windows, where the system has 2 CPU sockets, 18 cores each, each core having 2 hyper-threads, for a total of 72 hyper-threads. Both heavyweight_hardware_concurrency() and hardware_concurrency() currently return 36, because on Windows they are simply wrappers over std:🧵:hardware_concurrency() -- which can only return processors from the current "processor group".

== The changes in this patch ==
To solve this situation, we capture (and retain) the initial intention until the point of usage, through a new ThreadPoolStrategy class. The number of threads to use is deferred as late as possible, until the moment where the std::threads are created (ThreadPool in the case of ThinLTO).

When using hardware_concurrency(), setting ThreadCount to 0 now means to use all the possible hardware CPU (SMT) threads. Providing a ThreadCount above to the maximum number of threads will have no effect, the maximum will be used instead.
The heavyweight_hardware_concurrency() is similar to hardware_concurrency(), except that only one thread per hardware *core* will be used.

When LLVM_ENABLE_THREADS is OFF, the threading APIs will always return 1, to ensure any caller loops will be exercised at least once.

Differential Revision: https://reviews.llvm.org/D71775
2020-02-14 10:24:22 -05:00

1080 lines
38 KiB
C++

//===- CodeCoverage.cpp - Coverage tool based on profiling instrumentation-===//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// The 'CodeCoverageTool' class implements a command line tool to analyze and
// report coverage information using the profiling instrumentation and code
// coverage mapping.
//
//===----------------------------------------------------------------------===//
#include "CoverageExporterJson.h"
#include "CoverageExporterLcov.h"
#include "CoverageFilters.h"
#include "CoverageReport.h"
#include "CoverageSummaryInfo.h"
#include "CoverageViewOptions.h"
#include "RenderingSupport.h"
#include "SourceCoverageView.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/Triple.h"
#include "llvm/ProfileData/Coverage/CoverageMapping.h"
#include "llvm/ProfileData/InstrProfReader.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/FileSystem.h"
#include "llvm/Support/Format.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/Process.h"
#include "llvm/Support/Program.h"
#include "llvm/Support/ScopedPrinter.h"
#include "llvm/Support/ThreadPool.h"
#include "llvm/Support/Threading.h"
#include "llvm/Support/ToolOutputFile.h"
#include "llvm/Support/VirtualFileSystem.h"
#include <functional>
#include <map>
#include <system_error>
using namespace llvm;
using namespace coverage;
void exportCoverageDataToJson(const coverage::CoverageMapping &CoverageMapping,
const CoverageViewOptions &Options,
raw_ostream &OS);
namespace {
/// The implementation of the coverage tool.
class CodeCoverageTool {
public:
enum Command {
/// The show command.
Show,
/// The report command.
Report,
/// The export command.
Export
};
int run(Command Cmd, int argc, const char **argv);
private:
/// Print the error message to the error output stream.
void error(const Twine &Message, StringRef Whence = "");
/// Print the warning message to the error output stream.
void warning(const Twine &Message, StringRef Whence = "");
/// Convert \p Path into an absolute path and append it to the list
/// of collected paths.
void addCollectedPath(const std::string &Path);
/// If \p Path is a regular file, collect the path. If it's a
/// directory, recursively collect all of the paths within the directory.
void collectPaths(const std::string &Path);
/// Return a memory buffer for the given source file.
ErrorOr<const MemoryBuffer &> getSourceFile(StringRef SourceFile);
/// Create source views for the expansions of the view.
void attachExpansionSubViews(SourceCoverageView &View,
ArrayRef<ExpansionRecord> Expansions,
const CoverageMapping &Coverage);
/// Create the source view of a particular function.
std::unique_ptr<SourceCoverageView>
createFunctionView(const FunctionRecord &Function,
const CoverageMapping &Coverage);
/// Create the main source view of a particular source file.
std::unique_ptr<SourceCoverageView>
createSourceFileView(StringRef SourceFile, const CoverageMapping &Coverage);
/// Load the coverage mapping data. Return nullptr if an error occurred.
std::unique_ptr<CoverageMapping> load();
/// Create a mapping from files in the Coverage data to local copies
/// (path-equivalence).
void remapPathNames(const CoverageMapping &Coverage);
/// Remove input source files which aren't mapped by \p Coverage.
void removeUnmappedInputs(const CoverageMapping &Coverage);
/// If a demangler is available, demangle all symbol names.
void demangleSymbols(const CoverageMapping &Coverage);
/// Write out a source file view to the filesystem.
void writeSourceFileView(StringRef SourceFile, CoverageMapping *Coverage,
CoveragePrinter *Printer, bool ShowFilenames);
typedef llvm::function_ref<int(int, const char **)> CommandLineParserType;
int doShow(int argc, const char **argv,
CommandLineParserType commandLineParser);
int doReport(int argc, const char **argv,
CommandLineParserType commandLineParser);
int doExport(int argc, const char **argv,
CommandLineParserType commandLineParser);
std::vector<StringRef> ObjectFilenames;
CoverageViewOptions ViewOpts;
CoverageFiltersMatchAll Filters;
CoverageFilters IgnoreFilenameFilters;
/// The path to the indexed profile.
std::string PGOFilename;
/// A list of input source files.
std::vector<std::string> SourceFiles;
/// In -path-equivalence mode, this maps the absolute paths from the coverage
/// mapping data to the input source files.
StringMap<std::string> RemappedFilenames;
/// The coverage data path to be remapped from, and the source path to be
/// remapped to, when using -path-equivalence.
Optional<std::pair<std::string, std::string>> PathRemapping;
/// The architecture the coverage mapping data targets.
std::vector<StringRef> CoverageArches;
/// A cache for demangled symbols.
DemangleCache DC;
/// A lock which guards printing to stderr.
std::mutex ErrsLock;
/// A container for input source file buffers.
std::mutex LoadedSourceFilesLock;
std::vector<std::pair<std::string, std::unique_ptr<MemoryBuffer>>>
LoadedSourceFiles;
/// Whitelist from -name-whitelist to be used for filtering.
std::unique_ptr<SpecialCaseList> NameWhitelist;
};
}
static std::string getErrorString(const Twine &Message, StringRef Whence,
bool Warning) {
std::string Str = (Warning ? "warning" : "error");
Str += ": ";
if (!Whence.empty())
Str += Whence.str() + ": ";
Str += Message.str() + "\n";
return Str;
}
void CodeCoverageTool::error(const Twine &Message, StringRef Whence) {
std::unique_lock<std::mutex> Guard{ErrsLock};
ViewOpts.colored_ostream(errs(), raw_ostream::RED)
<< getErrorString(Message, Whence, false);
}
void CodeCoverageTool::warning(const Twine &Message, StringRef Whence) {
std::unique_lock<std::mutex> Guard{ErrsLock};
ViewOpts.colored_ostream(errs(), raw_ostream::RED)
<< getErrorString(Message, Whence, true);
}
void CodeCoverageTool::addCollectedPath(const std::string &Path) {
SmallString<128> EffectivePath(Path);
if (std::error_code EC = sys::fs::make_absolute(EffectivePath)) {
error(EC.message(), Path);
return;
}
sys::path::remove_dots(EffectivePath, /*remove_dot_dots=*/true);
if (!IgnoreFilenameFilters.matchesFilename(EffectivePath))
SourceFiles.emplace_back(EffectivePath.str());
}
void CodeCoverageTool::collectPaths(const std::string &Path) {
llvm::sys::fs::file_status Status;
llvm::sys::fs::status(Path, Status);
if (!llvm::sys::fs::exists(Status)) {
if (PathRemapping)
addCollectedPath(Path);
else
warning("Source file doesn't exist, proceeded by ignoring it.", Path);
return;
}
if (llvm::sys::fs::is_regular_file(Status)) {
addCollectedPath(Path);
return;
}
if (llvm::sys::fs::is_directory(Status)) {
std::error_code EC;
for (llvm::sys::fs::recursive_directory_iterator F(Path, EC), E;
F != E; F.increment(EC)) {
auto Status = F->status();
if (!Status) {
warning(Status.getError().message(), F->path());
continue;
}
if (Status->type() == llvm::sys::fs::file_type::regular_file)
addCollectedPath(F->path());
}
}
}
ErrorOr<const MemoryBuffer &>
CodeCoverageTool::getSourceFile(StringRef SourceFile) {
// If we've remapped filenames, look up the real location for this file.
std::unique_lock<std::mutex> Guard{LoadedSourceFilesLock};
if (!RemappedFilenames.empty()) {
auto Loc = RemappedFilenames.find(SourceFile);
if (Loc != RemappedFilenames.end())
SourceFile = Loc->second;
}
for (const auto &Files : LoadedSourceFiles)
if (sys::fs::equivalent(SourceFile, Files.first))
return *Files.second;
auto Buffer = MemoryBuffer::getFile(SourceFile);
if (auto EC = Buffer.getError()) {
error(EC.message(), SourceFile);
return EC;
}
LoadedSourceFiles.emplace_back(std::string(SourceFile),
std::move(Buffer.get()));
return *LoadedSourceFiles.back().second;
}
void CodeCoverageTool::attachExpansionSubViews(
SourceCoverageView &View, ArrayRef<ExpansionRecord> Expansions,
const CoverageMapping &Coverage) {
if (!ViewOpts.ShowExpandedRegions)
return;
for (const auto &Expansion : Expansions) {
auto ExpansionCoverage = Coverage.getCoverageForExpansion(Expansion);
if (ExpansionCoverage.empty())
continue;
auto SourceBuffer = getSourceFile(ExpansionCoverage.getFilename());
if (!SourceBuffer)
continue;
auto SubViewExpansions = ExpansionCoverage.getExpansions();
auto SubView =
SourceCoverageView::create(Expansion.Function.Name, SourceBuffer.get(),
ViewOpts, std::move(ExpansionCoverage));
attachExpansionSubViews(*SubView, SubViewExpansions, Coverage);
View.addExpansion(Expansion.Region, std::move(SubView));
}
}
std::unique_ptr<SourceCoverageView>
CodeCoverageTool::createFunctionView(const FunctionRecord &Function,
const CoverageMapping &Coverage) {
auto FunctionCoverage = Coverage.getCoverageForFunction(Function);
if (FunctionCoverage.empty())
return nullptr;
auto SourceBuffer = getSourceFile(FunctionCoverage.getFilename());
if (!SourceBuffer)
return nullptr;
auto Expansions = FunctionCoverage.getExpansions();
auto View = SourceCoverageView::create(DC.demangle(Function.Name),
SourceBuffer.get(), ViewOpts,
std::move(FunctionCoverage));
attachExpansionSubViews(*View, Expansions, Coverage);
return View;
}
std::unique_ptr<SourceCoverageView>
CodeCoverageTool::createSourceFileView(StringRef SourceFile,
const CoverageMapping &Coverage) {
auto SourceBuffer = getSourceFile(SourceFile);
if (!SourceBuffer)
return nullptr;
auto FileCoverage = Coverage.getCoverageForFile(SourceFile);
if (FileCoverage.empty())
return nullptr;
auto Expansions = FileCoverage.getExpansions();
auto View = SourceCoverageView::create(SourceFile, SourceBuffer.get(),
ViewOpts, std::move(FileCoverage));
attachExpansionSubViews(*View, Expansions, Coverage);
if (!ViewOpts.ShowFunctionInstantiations)
return View;
for (const auto &Group : Coverage.getInstantiationGroups(SourceFile)) {
// Skip functions which have a single instantiation.
if (Group.size() < 2)
continue;
for (const FunctionRecord *Function : Group.getInstantiations()) {
std::unique_ptr<SourceCoverageView> SubView{nullptr};
StringRef Funcname = DC.demangle(Function->Name);
if (Function->ExecutionCount > 0) {
auto SubViewCoverage = Coverage.getCoverageForFunction(*Function);
auto SubViewExpansions = SubViewCoverage.getExpansions();
SubView = SourceCoverageView::create(
Funcname, SourceBuffer.get(), ViewOpts, std::move(SubViewCoverage));
attachExpansionSubViews(*SubView, SubViewExpansions, Coverage);
}
unsigned FileID = Function->CountedRegions.front().FileID;
unsigned Line = 0;
for (const auto &CR : Function->CountedRegions)
if (CR.FileID == FileID)
Line = std::max(CR.LineEnd, Line);
View->addInstantiation(Funcname, Line, std::move(SubView));
}
}
return View;
}
static bool modifiedTimeGT(StringRef LHS, StringRef RHS) {
sys::fs::file_status Status;
if (sys::fs::status(LHS, Status))
return false;
auto LHSTime = Status.getLastModificationTime();
if (sys::fs::status(RHS, Status))
return false;
auto RHSTime = Status.getLastModificationTime();
return LHSTime > RHSTime;
}
std::unique_ptr<CoverageMapping> CodeCoverageTool::load() {
for (StringRef ObjectFilename : ObjectFilenames)
if (modifiedTimeGT(ObjectFilename, PGOFilename))
warning("profile data may be out of date - object is newer",
ObjectFilename);
auto CoverageOrErr =
CoverageMapping::load(ObjectFilenames, PGOFilename, CoverageArches);
if (Error E = CoverageOrErr.takeError()) {
error("Failed to load coverage: " + toString(std::move(E)),
join(ObjectFilenames.begin(), ObjectFilenames.end(), ", "));
return nullptr;
}
auto Coverage = std::move(CoverageOrErr.get());
unsigned Mismatched = Coverage->getMismatchedCount();
if (Mismatched) {
warning(Twine(Mismatched) + " functions have mismatched data");
if (ViewOpts.Debug) {
for (const auto &HashMismatch : Coverage->getHashMismatches())
errs() << "hash-mismatch: "
<< "No profile record found for '" << HashMismatch.first << "'"
<< " with hash = 0x" << Twine::utohexstr(HashMismatch.second)
<< '\n';
}
}
remapPathNames(*Coverage);
if (!SourceFiles.empty())
removeUnmappedInputs(*Coverage);
demangleSymbols(*Coverage);
return Coverage;
}
void CodeCoverageTool::remapPathNames(const CoverageMapping &Coverage) {
if (!PathRemapping)
return;
// Convert remapping paths to native paths with trailing seperators.
auto nativeWithTrailing = [](StringRef Path) -> std::string {
if (Path.empty())
return "";
SmallString<128> NativePath;
sys::path::native(Path, NativePath);
if (!sys::path::is_separator(NativePath.back()))
NativePath += sys::path::get_separator();
return NativePath.c_str();
};
std::string RemapFrom = nativeWithTrailing(PathRemapping->first);
std::string RemapTo = nativeWithTrailing(PathRemapping->second);
// Create a mapping from coverage data file paths to local paths.
for (StringRef Filename : Coverage.getUniqueSourceFiles()) {
SmallString<128> NativeFilename;
sys::path::native(Filename, NativeFilename);
if (NativeFilename.startswith(RemapFrom)) {
RemappedFilenames[Filename] =
RemapTo + NativeFilename.substr(RemapFrom.size()).str();
}
}
// Convert input files from local paths to coverage data file paths.
StringMap<std::string> InvRemappedFilenames;
for (const auto &RemappedFilename : RemappedFilenames)
InvRemappedFilenames[RemappedFilename.getValue()] =
std::string(RemappedFilename.getKey());
for (std::string &Filename : SourceFiles) {
SmallString<128> NativeFilename;
sys::path::native(Filename, NativeFilename);
auto CovFileName = InvRemappedFilenames.find(NativeFilename);
if (CovFileName != InvRemappedFilenames.end())
Filename = CovFileName->second;
}
}
void CodeCoverageTool::removeUnmappedInputs(const CoverageMapping &Coverage) {
std::vector<StringRef> CoveredFiles = Coverage.getUniqueSourceFiles();
auto UncoveredFilesIt = SourceFiles.end();
// The user may have specified source files which aren't in the coverage
// mapping. Filter these files away.
UncoveredFilesIt = std::remove_if(
SourceFiles.begin(), SourceFiles.end(), [&](const std::string &SF) {
return !std::binary_search(CoveredFiles.begin(), CoveredFiles.end(),
SF);
});
SourceFiles.erase(UncoveredFilesIt, SourceFiles.end());
}
void CodeCoverageTool::demangleSymbols(const CoverageMapping &Coverage) {
if (!ViewOpts.hasDemangler())
return;
// Pass function names to the demangler in a temporary file.
int InputFD;
SmallString<256> InputPath;
std::error_code EC =
sys::fs::createTemporaryFile("demangle-in", "list", InputFD, InputPath);
if (EC) {
error(InputPath, EC.message());
return;
}
ToolOutputFile InputTOF{InputPath, InputFD};
unsigned NumSymbols = 0;
for (const auto &Function : Coverage.getCoveredFunctions()) {
InputTOF.os() << Function.Name << '\n';
++NumSymbols;
}
InputTOF.os().close();
// Use another temporary file to store the demangler's output.
int OutputFD;
SmallString<256> OutputPath;
EC = sys::fs::createTemporaryFile("demangle-out", "list", OutputFD,
OutputPath);
if (EC) {
error(OutputPath, EC.message());
return;
}
ToolOutputFile OutputTOF{OutputPath, OutputFD};
OutputTOF.os().close();
// Invoke the demangler.
std::vector<StringRef> ArgsV;
for (StringRef Arg : ViewOpts.DemanglerOpts)
ArgsV.push_back(Arg);
Optional<StringRef> Redirects[] = {InputPath.str(), OutputPath.str(), {""}};
std::string ErrMsg;
int RC = sys::ExecuteAndWait(ViewOpts.DemanglerOpts[0], ArgsV,
/*env=*/None, Redirects, /*secondsToWait=*/0,
/*memoryLimit=*/0, &ErrMsg);
if (RC) {
error(ErrMsg, ViewOpts.DemanglerOpts[0]);
return;
}
// Parse the demangler's output.
auto BufOrError = MemoryBuffer::getFile(OutputPath);
if (!BufOrError) {
error(OutputPath, BufOrError.getError().message());
return;
}
std::unique_ptr<MemoryBuffer> DemanglerBuf = std::move(*BufOrError);
SmallVector<StringRef, 8> Symbols;
StringRef DemanglerData = DemanglerBuf->getBuffer();
DemanglerData.split(Symbols, '\n', /*MaxSplit=*/NumSymbols,
/*KeepEmpty=*/false);
if (Symbols.size() != NumSymbols) {
error("Demangler did not provide expected number of symbols");
return;
}
// Cache the demangled names.
unsigned I = 0;
for (const auto &Function : Coverage.getCoveredFunctions())
// On Windows, lines in the demangler's output file end with "\r\n".
// Splitting by '\n' keeps '\r's, so cut them now.
DC.DemangledNames[Function.Name] = std::string(Symbols[I++].rtrim());
}
void CodeCoverageTool::writeSourceFileView(StringRef SourceFile,
CoverageMapping *Coverage,
CoveragePrinter *Printer,
bool ShowFilenames) {
auto View = createSourceFileView(SourceFile, *Coverage);
if (!View) {
warning("The file '" + SourceFile + "' isn't covered.");
return;
}
auto OSOrErr = Printer->createViewFile(SourceFile, /*InToplevel=*/false);
if (Error E = OSOrErr.takeError()) {
error("Could not create view file!", toString(std::move(E)));
return;
}
auto OS = std::move(OSOrErr.get());
View->print(*OS.get(), /*Wholefile=*/true,
/*ShowSourceName=*/ShowFilenames,
/*ShowTitle=*/ViewOpts.hasOutputDirectory());
Printer->closeViewFile(std::move(OS));
}
int CodeCoverageTool::run(Command Cmd, int argc, const char **argv) {
cl::opt<std::string> CovFilename(
cl::Positional, cl::desc("Covered executable or object file."));
cl::list<std::string> CovFilenames(
"object", cl::desc("Coverage executable or object file"), cl::ZeroOrMore,
cl::CommaSeparated);
cl::list<std::string> InputSourceFiles(
cl::Positional, cl::desc("<Source files>"), cl::ZeroOrMore);
cl::opt<bool> DebugDumpCollectedPaths(
"dump-collected-paths", cl::Optional, cl::Hidden,
cl::desc("Show the collected paths to source files"));
cl::opt<std::string, true> PGOFilename(
"instr-profile", cl::Required, cl::location(this->PGOFilename),
cl::desc(
"File with the profile data obtained after an instrumented run"));
cl::list<std::string> Arches(
"arch", cl::desc("architectures of the coverage mapping binaries"));
cl::opt<bool> DebugDump("dump", cl::Optional,
cl::desc("Show internal debug dump"));
cl::opt<CoverageViewOptions::OutputFormat> Format(
"format", cl::desc("Output format for line-based coverage reports"),
cl::values(clEnumValN(CoverageViewOptions::OutputFormat::Text, "text",
"Text output"),
clEnumValN(CoverageViewOptions::OutputFormat::HTML, "html",
"HTML output"),
clEnumValN(CoverageViewOptions::OutputFormat::Lcov, "lcov",
"lcov tracefile output")),
cl::init(CoverageViewOptions::OutputFormat::Text));
cl::opt<std::string> PathRemap(
"path-equivalence", cl::Optional,
cl::desc("<from>,<to> Map coverage data paths to local source file "
"paths"));
cl::OptionCategory FilteringCategory("Function filtering options");
cl::list<std::string> NameFilters(
"name", cl::Optional,
cl::desc("Show code coverage only for functions with the given name"),
cl::ZeroOrMore, cl::cat(FilteringCategory));
cl::list<std::string> NameFilterFiles(
"name-whitelist", cl::Optional,
cl::desc("Show code coverage only for functions listed in the given "
"file"),
cl::ZeroOrMore, cl::cat(FilteringCategory));
cl::list<std::string> NameRegexFilters(
"name-regex", cl::Optional,
cl::desc("Show code coverage only for functions that match the given "
"regular expression"),
cl::ZeroOrMore, cl::cat(FilteringCategory));
cl::list<std::string> IgnoreFilenameRegexFilters(
"ignore-filename-regex", cl::Optional,
cl::desc("Skip source code files with file paths that match the given "
"regular expression"),
cl::ZeroOrMore, cl::cat(FilteringCategory));
cl::opt<double> RegionCoverageLtFilter(
"region-coverage-lt", cl::Optional,
cl::desc("Show code coverage only for functions with region coverage "
"less than the given threshold"),
cl::cat(FilteringCategory));
cl::opt<double> RegionCoverageGtFilter(
"region-coverage-gt", cl::Optional,
cl::desc("Show code coverage only for functions with region coverage "
"greater than the given threshold"),
cl::cat(FilteringCategory));
cl::opt<double> LineCoverageLtFilter(
"line-coverage-lt", cl::Optional,
cl::desc("Show code coverage only for functions with line coverage less "
"than the given threshold"),
cl::cat(FilteringCategory));
cl::opt<double> LineCoverageGtFilter(
"line-coverage-gt", cl::Optional,
cl::desc("Show code coverage only for functions with line coverage "
"greater than the given threshold"),
cl::cat(FilteringCategory));
cl::opt<cl::boolOrDefault> UseColor(
"use-color", cl::desc("Emit colored output (default=autodetect)"),
cl::init(cl::BOU_UNSET));
cl::list<std::string> DemanglerOpts(
"Xdemangler", cl::desc("<demangler-path>|<demangler-option>"));
cl::opt<bool> RegionSummary(
"show-region-summary", cl::Optional,
cl::desc("Show region statistics in summary table"),
cl::init(true));
cl::opt<bool> InstantiationSummary(
"show-instantiation-summary", cl::Optional,
cl::desc("Show instantiation statistics in summary table"));
cl::opt<bool> SummaryOnly(
"summary-only", cl::Optional,
cl::desc("Export only summary information for each source file"));
cl::opt<unsigned> NumThreads(
"num-threads", cl::init(0),
cl::desc("Number of merge threads to use (default: autodetect)"));
cl::alias NumThreadsA("j", cl::desc("Alias for --num-threads"),
cl::aliasopt(NumThreads));
auto commandLineParser = [&, this](int argc, const char **argv) -> int {
cl::ParseCommandLineOptions(argc, argv, "LLVM code coverage tool\n");
ViewOpts.Debug = DebugDump;
if (!CovFilename.empty())
ObjectFilenames.emplace_back(CovFilename);
for (const std::string &Filename : CovFilenames)
ObjectFilenames.emplace_back(Filename);
if (ObjectFilenames.empty()) {
errs() << "No filenames specified!\n";
::exit(1);
}
ViewOpts.Format = Format;
switch (ViewOpts.Format) {
case CoverageViewOptions::OutputFormat::Text:
ViewOpts.Colors = UseColor == cl::BOU_UNSET
? sys::Process::StandardOutHasColors()
: UseColor == cl::BOU_TRUE;
break;
case CoverageViewOptions::OutputFormat::HTML:
if (UseColor == cl::BOU_FALSE)
errs() << "Color output cannot be disabled when generating html.\n";
ViewOpts.Colors = true;
break;
case CoverageViewOptions::OutputFormat::Lcov:
if (UseColor == cl::BOU_TRUE)
errs() << "Color output cannot be enabled when generating lcov.\n";
ViewOpts.Colors = false;
break;
}
// If path-equivalence was given and is a comma seperated pair then set
// PathRemapping.
auto EquivPair = StringRef(PathRemap).split(',');
if (!(EquivPair.first.empty() && EquivPair.second.empty()))
PathRemapping = {std::string(EquivPair.first),
std::string(EquivPair.second)};
// If a demangler is supplied, check if it exists and register it.
if (!DemanglerOpts.empty()) {
auto DemanglerPathOrErr = sys::findProgramByName(DemanglerOpts[0]);
if (!DemanglerPathOrErr) {
error("Could not find the demangler!",
DemanglerPathOrErr.getError().message());
return 1;
}
DemanglerOpts[0] = *DemanglerPathOrErr;
ViewOpts.DemanglerOpts.swap(DemanglerOpts);
}
// Read in -name-whitelist files.
if (!NameFilterFiles.empty()) {
std::string SpecialCaseListErr;
NameWhitelist = SpecialCaseList::create(
NameFilterFiles, *vfs::getRealFileSystem(), SpecialCaseListErr);
if (!NameWhitelist)
error(SpecialCaseListErr);
}
// Create the function filters
if (!NameFilters.empty() || NameWhitelist || !NameRegexFilters.empty()) {
auto NameFilterer = std::make_unique<CoverageFilters>();
for (const auto &Name : NameFilters)
NameFilterer->push_back(std::make_unique<NameCoverageFilter>(Name));
if (NameWhitelist)
NameFilterer->push_back(
std::make_unique<NameWhitelistCoverageFilter>(*NameWhitelist));
for (const auto &Regex : NameRegexFilters)
NameFilterer->push_back(
std::make_unique<NameRegexCoverageFilter>(Regex));
Filters.push_back(std::move(NameFilterer));
}
if (RegionCoverageLtFilter.getNumOccurrences() ||
RegionCoverageGtFilter.getNumOccurrences() ||
LineCoverageLtFilter.getNumOccurrences() ||
LineCoverageGtFilter.getNumOccurrences()) {
auto StatFilterer = std::make_unique<CoverageFilters>();
if (RegionCoverageLtFilter.getNumOccurrences())
StatFilterer->push_back(std::make_unique<RegionCoverageFilter>(
RegionCoverageFilter::LessThan, RegionCoverageLtFilter));
if (RegionCoverageGtFilter.getNumOccurrences())
StatFilterer->push_back(std::make_unique<RegionCoverageFilter>(
RegionCoverageFilter::GreaterThan, RegionCoverageGtFilter));
if (LineCoverageLtFilter.getNumOccurrences())
StatFilterer->push_back(std::make_unique<LineCoverageFilter>(
LineCoverageFilter::LessThan, LineCoverageLtFilter));
if (LineCoverageGtFilter.getNumOccurrences())
StatFilterer->push_back(std::make_unique<LineCoverageFilter>(
RegionCoverageFilter::GreaterThan, LineCoverageGtFilter));
Filters.push_back(std::move(StatFilterer));
}
// Create the ignore filename filters.
for (const auto &RE : IgnoreFilenameRegexFilters)
IgnoreFilenameFilters.push_back(
std::make_unique<NameRegexCoverageFilter>(RE));
if (!Arches.empty()) {
for (const std::string &Arch : Arches) {
if (Triple(Arch).getArch() == llvm::Triple::ArchType::UnknownArch) {
error("Unknown architecture: " + Arch);
return 1;
}
CoverageArches.emplace_back(Arch);
}
if (CoverageArches.size() != ObjectFilenames.size()) {
error("Number of architectures doesn't match the number of objects");
return 1;
}
}
// IgnoreFilenameFilters are applied even when InputSourceFiles specified.
for (const std::string &File : InputSourceFiles)
collectPaths(File);
if (DebugDumpCollectedPaths) {
for (const std::string &SF : SourceFiles)
outs() << SF << '\n';
::exit(0);
}
ViewOpts.ShowRegionSummary = RegionSummary;
ViewOpts.ShowInstantiationSummary = InstantiationSummary;
ViewOpts.ExportSummaryOnly = SummaryOnly;
ViewOpts.NumThreads = NumThreads;
return 0;
};
switch (Cmd) {
case Show:
return doShow(argc, argv, commandLineParser);
case Report:
return doReport(argc, argv, commandLineParser);
case Export:
return doExport(argc, argv, commandLineParser);
}
return 0;
}
int CodeCoverageTool::doShow(int argc, const char **argv,
CommandLineParserType commandLineParser) {
cl::OptionCategory ViewCategory("Viewing options");
cl::opt<bool> ShowLineExecutionCounts(
"show-line-counts", cl::Optional,
cl::desc("Show the execution counts for each line"), cl::init(true),
cl::cat(ViewCategory));
cl::opt<bool> ShowRegions(
"show-regions", cl::Optional,
cl::desc("Show the execution counts for each region"),
cl::cat(ViewCategory));
cl::opt<bool> ShowBestLineRegionsCounts(
"show-line-counts-or-regions", cl::Optional,
cl::desc("Show the execution counts for each line, or the execution "
"counts for each region on lines that have multiple regions"),
cl::cat(ViewCategory));
cl::opt<bool> ShowExpansions("show-expansions", cl::Optional,
cl::desc("Show expanded source regions"),
cl::cat(ViewCategory));
cl::opt<bool> ShowInstantiations("show-instantiations", cl::Optional,
cl::desc("Show function instantiations"),
cl::init(true), cl::cat(ViewCategory));
cl::opt<std::string> ShowOutputDirectory(
"output-dir", cl::init(""),
cl::desc("Directory in which coverage information is written out"));
cl::alias ShowOutputDirectoryA("o", cl::desc("Alias for --output-dir"),
cl::aliasopt(ShowOutputDirectory));
cl::opt<uint32_t> TabSize(
"tab-size", cl::init(2),
cl::desc(
"Set tab expansion size for html coverage reports (default = 2)"));
cl::opt<std::string> ProjectTitle(
"project-title", cl::Optional,
cl::desc("Set project title for the coverage report"));
auto Err = commandLineParser(argc, argv);
if (Err)
return Err;
if (ViewOpts.Format == CoverageViewOptions::OutputFormat::Lcov) {
error("Lcov format should be used with 'llvm-cov export'.");
return 1;
}
ViewOpts.ShowLineNumbers = true;
ViewOpts.ShowLineStats = ShowLineExecutionCounts.getNumOccurrences() != 0 ||
!ShowRegions || ShowBestLineRegionsCounts;
ViewOpts.ShowRegionMarkers = ShowRegions || ShowBestLineRegionsCounts;
ViewOpts.ShowExpandedRegions = ShowExpansions;
ViewOpts.ShowFunctionInstantiations = ShowInstantiations;
ViewOpts.ShowOutputDirectory = ShowOutputDirectory;
ViewOpts.TabSize = TabSize;
ViewOpts.ProjectTitle = ProjectTitle;
if (ViewOpts.hasOutputDirectory()) {
if (auto E = sys::fs::create_directories(ViewOpts.ShowOutputDirectory)) {
error("Could not create output directory!", E.message());
return 1;
}
}
sys::fs::file_status Status;
if (sys::fs::status(PGOFilename, Status)) {
error("profdata file error: can not get the file status. \n");
return 1;
}
auto ModifiedTime = Status.getLastModificationTime();
std::string ModifiedTimeStr = to_string(ModifiedTime);
size_t found = ModifiedTimeStr.rfind(':');
ViewOpts.CreatedTimeStr = (found != std::string::npos)
? "Created: " + ModifiedTimeStr.substr(0, found)
: "Created: " + ModifiedTimeStr;
auto Coverage = load();
if (!Coverage)
return 1;
auto Printer = CoveragePrinter::create(ViewOpts);
if (SourceFiles.empty())
// Get the source files from the function coverage mapping.
for (StringRef Filename : Coverage->getUniqueSourceFiles()) {
if (!IgnoreFilenameFilters.matchesFilename(Filename))
SourceFiles.push_back(std::string(Filename));
}
// Create an index out of the source files.
if (ViewOpts.hasOutputDirectory()) {
if (Error E = Printer->createIndexFile(SourceFiles, *Coverage, Filters)) {
error("Could not create index file!", toString(std::move(E)));
return 1;
}
}
if (!Filters.empty()) {
// Build the map of filenames to functions.
std::map<llvm::StringRef, std::vector<const FunctionRecord *>>
FilenameFunctionMap;
for (const auto &SourceFile : SourceFiles)
for (const auto &Function : Coverage->getCoveredFunctions(SourceFile))
if (Filters.matches(*Coverage.get(), Function))
FilenameFunctionMap[SourceFile].push_back(&Function);
// Only print filter matching functions for each file.
for (const auto &FileFunc : FilenameFunctionMap) {
StringRef File = FileFunc.first;
const auto &Functions = FileFunc.second;
auto OSOrErr = Printer->createViewFile(File, /*InToplevel=*/false);
if (Error E = OSOrErr.takeError()) {
error("Could not create view file!", toString(std::move(E)));
return 1;
}
auto OS = std::move(OSOrErr.get());
bool ShowTitle = ViewOpts.hasOutputDirectory();
for (const auto *Function : Functions) {
auto FunctionView = createFunctionView(*Function, *Coverage);
if (!FunctionView) {
warning("Could not read coverage for '" + Function->Name + "'.");
continue;
}
FunctionView->print(*OS.get(), /*WholeFile=*/false,
/*ShowSourceName=*/true, ShowTitle);
ShowTitle = false;
}
Printer->closeViewFile(std::move(OS));
}
return 0;
}
// Show files
bool ShowFilenames =
(SourceFiles.size() != 1) || ViewOpts.hasOutputDirectory() ||
(ViewOpts.Format == CoverageViewOptions::OutputFormat::HTML);
auto NumThreads = ViewOpts.NumThreads;
// If NumThreads is not specified, auto-detect a good default.
if (NumThreads == 0)
NumThreads = SourceFiles.size();
if (!ViewOpts.hasOutputDirectory() || NumThreads == 1) {
for (const std::string &SourceFile : SourceFiles)
writeSourceFileView(SourceFile, Coverage.get(), Printer.get(),
ShowFilenames);
} else {
// In -output-dir mode, it's safe to use multiple threads to print files.
ThreadPool Pool(heavyweight_hardware_concurrency(NumThreads));
for (const std::string &SourceFile : SourceFiles)
Pool.async(&CodeCoverageTool::writeSourceFileView, this, SourceFile,
Coverage.get(), Printer.get(), ShowFilenames);
Pool.wait();
}
return 0;
}
int CodeCoverageTool::doReport(int argc, const char **argv,
CommandLineParserType commandLineParser) {
cl::opt<bool> ShowFunctionSummaries(
"show-functions", cl::Optional, cl::init(false),
cl::desc("Show coverage summaries for each function"));
auto Err = commandLineParser(argc, argv);
if (Err)
return Err;
if (ViewOpts.Format == CoverageViewOptions::OutputFormat::HTML) {
error("HTML output for summary reports is not yet supported.");
return 1;
} else if (ViewOpts.Format == CoverageViewOptions::OutputFormat::Lcov) {
error("Lcov format should be used with 'llvm-cov export'.");
return 1;
}
auto Coverage = load();
if (!Coverage)
return 1;
CoverageReport Report(ViewOpts, *Coverage.get());
if (!ShowFunctionSummaries) {
if (SourceFiles.empty())
Report.renderFileReports(llvm::outs(), IgnoreFilenameFilters);
else
Report.renderFileReports(llvm::outs(), SourceFiles);
} else {
if (SourceFiles.empty()) {
error("Source files must be specified when -show-functions=true is "
"specified");
return 1;
}
Report.renderFunctionReports(SourceFiles, DC, llvm::outs());
}
return 0;
}
int CodeCoverageTool::doExport(int argc, const char **argv,
CommandLineParserType commandLineParser) {
cl::OptionCategory ExportCategory("Exporting options");
cl::opt<bool> SkipExpansions("skip-expansions", cl::Optional,
cl::desc("Don't export expanded source regions"),
cl::cat(ExportCategory));
cl::opt<bool> SkipFunctions("skip-functions", cl::Optional,
cl::desc("Don't export per-function data"),
cl::cat(ExportCategory));
auto Err = commandLineParser(argc, argv);
if (Err)
return Err;
ViewOpts.SkipExpansions = SkipExpansions;
ViewOpts.SkipFunctions = SkipFunctions;
if (ViewOpts.Format != CoverageViewOptions::OutputFormat::Text &&
ViewOpts.Format != CoverageViewOptions::OutputFormat::Lcov) {
error("Coverage data can only be exported as textual JSON or an "
"lcov tracefile.");
return 1;
}
auto Coverage = load();
if (!Coverage) {
error("Could not load coverage information");
return 1;
}
std::unique_ptr<CoverageExporter> Exporter;
switch (ViewOpts.Format) {
case CoverageViewOptions::OutputFormat::Text:
Exporter = std::make_unique<CoverageExporterJson>(*Coverage.get(),
ViewOpts, outs());
break;
case CoverageViewOptions::OutputFormat::HTML:
// Unreachable because we should have gracefully terminated with an error
// above.
llvm_unreachable("Export in HTML is not supported!");
case CoverageViewOptions::OutputFormat::Lcov:
Exporter = std::make_unique<CoverageExporterLcov>(*Coverage.get(),
ViewOpts, outs());
break;
}
if (SourceFiles.empty())
Exporter->renderRoot(IgnoreFilenameFilters);
else
Exporter->renderRoot(SourceFiles);
return 0;
}
int showMain(int argc, const char *argv[]) {
CodeCoverageTool Tool;
return Tool.run(CodeCoverageTool::Show, argc, argv);
}
int reportMain(int argc, const char *argv[]) {
CodeCoverageTool Tool;
return Tool.run(CodeCoverageTool::Report, argc, argv);
}
int exportMain(int argc, const char *argv[]) {
CodeCoverageTool Tool;
return Tool.run(CodeCoverageTool::Export, argc, argv);
}