blob: 337bb3faa7fb3b041e3b9006b50e2d8afb87e4d2 [file] [log] [blame]
// Copyright 2015 Google Inc. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "benchmark/benchmark.h"
#include "benchmark_api_internal.h"
#include "benchmark_runner.h"
#include "internal_macros.h"
#ifndef BENCHMARK_OS_WINDOWS
#if !defined(BENCHMARK_OS_FUCHSIA) && !defined(BENCHMARK_OS_QURT)
#include <sys/resource.h>
#endif
#include <sys/time.h>
#include <unistd.h>
#endif
#include <algorithm>
#include <atomic>
#include <condition_variable>
#include <cstdio>
#include <cstdlib>
#include <fstream>
#include <iostream>
#include <limits>
#include <map>
#include <memory>
#include <random>
#include <string>
#include <thread>
#include <utility>
#include "check.h"
#include "colorprint.h"
#include "commandlineflags.h"
#include "complexity.h"
#include "counter.h"
#include "internal_macros.h"
#include "log.h"
#include "mutex.h"
#include "perf_counters.h"
#include "re.h"
#include "statistics.h"
#include "string_util.h"
#include "thread_manager.h"
#include "thread_timer.h"
namespace benchmark {
// Print a list of benchmarks. This option overrides all other options.
BM_DEFINE_bool(benchmark_list_tests, false);
// A regular expression that specifies the set of benchmarks to execute. If
// this flag is empty, or if this flag is the string \"all\", all benchmarks
// linked into the binary are run.
BM_DEFINE_string(benchmark_filter, "");
// Specification of how long to run the benchmark.
//
// It can be either an exact number of iterations (specified as `<integer>x`),
// or a minimum number of seconds (specified as `<float>s`). If the latter
// format (ie., min seconds) is used, the system may run the benchmark longer
// until the results are considered significant.
//
// For backward compatibility, the `s` suffix may be omitted, in which case,
// the specified number is interpreted as the number of seconds.
//
// For cpu-time based tests, this is the lower bound
// on the total cpu time used by all threads that make up the test. For
// real-time based tests, this is the lower bound on the elapsed time of the
// benchmark execution, regardless of number of threads.
BM_DEFINE_string(benchmark_min_time, kDefaultMinTimeStr);
// Minimum number of seconds a benchmark should be run before results should be
// taken into account. This e.g can be necessary for benchmarks of code which
// needs to fill some form of cache before performance is of interest.
// Note: results gathered within this period are discarded and not used for
// reported result.
BM_DEFINE_double(benchmark_min_warmup_time, 0.0);
// The number of runs of each benchmark. If greater than 1, the mean and
// standard deviation of the runs will be reported.
BM_DEFINE_int32(benchmark_repetitions, 1);
// If set, enable random interleaving of repetitions of all benchmarks.
// See http://github.com/google/benchmark/issues/1051 for details.
BM_DEFINE_bool(benchmark_enable_random_interleaving, false);
// Report the result of each benchmark repetitions. When 'true' is specified
// only the mean, standard deviation, and other statistics are reported for
// repeated benchmarks. Affects all reporters.
BM_DEFINE_bool(benchmark_report_aggregates_only, false);
// Display the result of each benchmark repetitions. When 'true' is specified
// only the mean, standard deviation, and other statistics are displayed for
// repeated benchmarks. Unlike benchmark_report_aggregates_only, only affects
// the display reporter, but *NOT* file reporter, which will still contain
// all the output.
BM_DEFINE_bool(benchmark_display_aggregates_only, false);
// The format to use for console output.
// Valid values are 'console', 'json', or 'csv'.
BM_DEFINE_string(benchmark_format, "console");
// The format to use for file output.
// Valid values are 'console', 'json', or 'csv'.
BM_DEFINE_string(benchmark_out_format, "json");
// The file to write additional output to.
BM_DEFINE_string(benchmark_out, "");
// Whether to use colors in the output. Valid values:
// 'true'/'yes'/1, 'false'/'no'/0, and 'auto'. 'auto' means to use colors if
// the output is being sent to a terminal and the TERM environment variable is
// set to a terminal type that supports colors.
BM_DEFINE_string(benchmark_color, "auto");
// Whether to use tabular format when printing user counters to the console.
// Valid values: 'true'/'yes'/1, 'false'/'no'/0. Defaults to false.
BM_DEFINE_bool(benchmark_counters_tabular, false);
// List of additional perf counters to collect, in libpfm format. For more
// information about libpfm: https://man7.org/linux/man-pages/man3/libpfm.3.html
BM_DEFINE_string(benchmark_perf_counters, "");
// Extra context to include in the output formatted as comma-separated key-value
// pairs. Kept internal as it's only used for parsing from env/command line.
BM_DEFINE_kvpairs(benchmark_context, {});
// Set the default time unit to use for reports
// Valid values are 'ns', 'us', 'ms' or 's'
BM_DEFINE_string(benchmark_time_unit, "");
// The level of verbose logging to output
BM_DEFINE_int32(v, 0);
namespace internal {
std::map<std::string, std::string>* global_context = nullptr;
BENCHMARK_EXPORT std::map<std::string, std::string>*& GetGlobalContext() {
return global_context;
}
static void const volatile* volatile global_force_escape_pointer;
// FIXME: Verify if LTO still messes this up?
void UseCharPointer(char const volatile* const v) {
// We want to escape the pointer `v` so that the compiler can not eliminate
// computations that produced it. To do that, we escape the pointer by storing
// it into a volatile variable, since generally, volatile store, is not
// something the compiler is allowed to elide.
global_force_escape_pointer = reinterpret_cast<void const volatile*>(v);
}
} // namespace internal
State::State(std::string name, IterationCount max_iters,
const std::vector<int64_t>& ranges, int thread_i, int n_threads,
internal::ThreadTimer* timer, internal::ThreadManager* manager,
internal::PerfCountersMeasurement* perf_counters_measurement)
: total_iterations_(0),
batch_leftover_(0),
max_iterations(max_iters),
started_(false),
finished_(false),
skipped_(internal::NotSkipped),
range_(ranges),
complexity_n_(0),
name_(std::move(name)),
thread_index_(thread_i),
threads_(n_threads),
timer_(timer),
manager_(manager),
perf_counters_measurement_(perf_counters_measurement) {
BM_CHECK(max_iterations != 0) << "At least one iteration must be run";
BM_CHECK_LT(thread_index_, threads_)
<< "thread_index must be less than threads";
// Add counters with correct flag now. If added with `counters[name]` in
// `PauseTiming`, a new `Counter` will be inserted the first time, which
// won't have the flag. Inserting them now also reduces the allocations
// during the benchmark.
if (perf_counters_measurement_) {
for (const std::string& counter_name :
perf_counters_measurement_->names()) {
counters[counter_name] = Counter(0.0, Counter::kAvgIterations);
}
}
// Note: The use of offsetof below is technically undefined until C++17
// because State is not a standard layout type. However, all compilers
// currently provide well-defined behavior as an extension (which is
// demonstrated since constexpr evaluation must diagnose all undefined
// behavior). However, GCC and Clang also warn about this use of offsetof,
// which must be suppressed.
#if defined(__INTEL_COMPILER)
#pragma warning push
#pragma warning(disable : 1875)
#elif defined(__GNUC__)
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Winvalid-offsetof"
#endif
#if defined(__NVCC__)
#pragma nv_diagnostic push
#pragma nv_diag_suppress 1427
#endif
#if defined(__NVCOMPILER)
#pragma diagnostic push
#pragma diag_suppress offset_in_non_POD_nonstandard
#endif
// Offset tests to ensure commonly accessed data is on the first cache line.
const int cache_line_size = 64;
static_assert(
offsetof(State, skipped_) <= (cache_line_size - sizeof(skipped_)), "");
#if defined(__INTEL_COMPILER)
#pragma warning pop
#elif defined(__GNUC__)
#pragma GCC diagnostic pop
#endif
#if defined(__NVCC__)
#pragma nv_diagnostic pop
#endif
#if defined(__NVCOMPILER)
#pragma diagnostic pop
#endif
}
void State::PauseTiming() {
// Add in time accumulated so far
BM_CHECK(started_ && !finished_ && !skipped());
timer_->StopTimer();
if (perf_counters_measurement_) {
std::vector<std::pair<std::string, double>> measurements;
if (!perf_counters_measurement_->Stop(measurements)) {
BM_CHECK(false) << "Perf counters read the value failed.";
}
for (const auto& name_and_measurement : measurements) {
const std::string& name = name_and_measurement.first;
const double measurement = name_and_measurement.second;
// Counter was inserted with `kAvgIterations` flag by the constructor.
assert(counters.find(name) != counters.end());
counters[name].value += measurement;
}
}
}
void State::ResumeTiming() {
BM_CHECK(started_ && !finished_ && !skipped());
timer_->StartTimer();
if (perf_counters_measurement_) {
perf_counters_measurement_->Start();
}
}
void State::SkipWithMessage(const std::string& msg) {
skipped_ = internal::SkippedWithMessage;
{
MutexLock l(manager_->GetBenchmarkMutex());
if (internal::NotSkipped == manager_->results.skipped_) {
manager_->results.skip_message_ = msg;
manager_->results.skipped_ = skipped_;
}
}
total_iterations_ = 0;
if (timer_->running()) timer_->StopTimer();
}
void State::SkipWithError(const std::string& msg) {
skipped_ = internal::SkippedWithError;
{
MutexLock l(manager_->GetBenchmarkMutex());
if (internal::NotSkipped == manager_->results.skipped_) {
manager_->results.skip_message_ = msg;
manager_->results.skipped_ = skipped_;
}
}
total_iterations_ = 0;
if (timer_->running()) timer_->StopTimer();
}
void State::SetIterationTime(double seconds) {
timer_->SetIterationTime(seconds);
}
void State::SetLabel(const std::string& label) {
MutexLock l(manager_->GetBenchmarkMutex());
manager_->results.report_label_ = label;
}
void State::StartKeepRunning() {
BM_CHECK(!started_ && !finished_);
started_ = true;
total_iterations_ = skipped() ? 0 : max_iterations;
manager_->StartStopBarrier();
if (!skipped()) ResumeTiming();
}
void State::FinishKeepRunning() {
BM_CHECK(started_ && (!finished_ || skipped()));
if (!skipped()) {
PauseTiming();
}
// Total iterations has now wrapped around past 0. Fix this.
total_iterations_ = 0;
finished_ = true;
manager_->StartStopBarrier();
}
namespace internal {
namespace {
// Flushes streams after invoking reporter methods that write to them. This
// ensures users get timely updates even when streams are not line-buffered.
void FlushStreams(BenchmarkReporter* reporter) {
if (!reporter) return;
std::flush(reporter->GetOutputStream());
std::flush(reporter->GetErrorStream());
}
// Reports in both display and file reporters.
void Report(BenchmarkReporter* display_reporter,
BenchmarkReporter* file_reporter, const RunResults& run_results) {
auto report_one = [](BenchmarkReporter* reporter, bool aggregates_only,
const RunResults& results) {
assert(reporter);
// If there are no aggregates, do output non-aggregates.
aggregates_only &= !results.aggregates_only.empty();
if (!aggregates_only) reporter->ReportRuns(results.non_aggregates);
if (!results.aggregates_only.empty())
reporter->ReportRuns(results.aggregates_only);
};
report_one(display_reporter, run_results.display_report_aggregates_only,
run_results);
if (file_reporter)
report_one(file_reporter, run_results.file_report_aggregates_only,
run_results);
FlushStreams(display_reporter);
FlushStreams(file_reporter);
}
void RunBenchmarks(const std::vector<BenchmarkInstance>& benchmarks,
BenchmarkReporter* display_reporter,
BenchmarkReporter* file_reporter) {
// Note the file_reporter can be null.
BM_CHECK(display_reporter != nullptr);
// Determine the width of the name field using a minimum width of 10.
bool might_have_aggregates = FLAGS_benchmark_repetitions > 1;
size_t name_field_width = 10;
size_t stat_field_width = 0;
for (const BenchmarkInstance& benchmark : benchmarks) {
name_field_width =
std::max<size_t>(name_field_width, benchmark.name().str().size());
might_have_aggregates |= benchmark.repetitions() > 1;
for (const auto& Stat : benchmark.statistics())
stat_field_width = std::max<size_t>(stat_field_width, Stat.name_.size());
}
if (might_have_aggregates) name_field_width += 1 + stat_field_width;
// Print header here
BenchmarkReporter::Context context;
context.name_field_width = name_field_width;
// Keep track of running times of all instances of each benchmark family.
std::map<int /*family_index*/, BenchmarkReporter::PerFamilyRunReports>
per_family_reports;
if (display_reporter->ReportContext(context) &&
(!file_reporter || file_reporter->ReportContext(context))) {
FlushStreams(display_reporter);
FlushStreams(file_reporter);
size_t num_repetitions_total = 0;
// This perfcounters object needs to be created before the runners vector
// below so it outlasts their lifetime.
PerfCountersMeasurement perfcounters(
StrSplit(FLAGS_benchmark_perf_counters, ','));
// Vector of benchmarks to run
std::vector<internal::BenchmarkRunner> runners;
runners.reserve(benchmarks.size());
// Count the number of benchmarks with threads to warn the user in case
// performance counters are used.
int benchmarks_with_threads = 0;
// Loop through all benchmarks
for (const BenchmarkInstance& benchmark : benchmarks) {
BenchmarkReporter::PerFamilyRunReports* reports_for_family = nullptr;
if (benchmark.complexity() != oNone)
reports_for_family = &per_family_reports[benchmark.family_index()];
benchmarks_with_threads += (benchmark.threads() > 1);
runners.emplace_back(benchmark, &perfcounters, reports_for_family);
int num_repeats_of_this_instance = runners.back().GetNumRepeats();
num_repetitions_total +=
static_cast<size_t>(num_repeats_of_this_instance);
if (reports_for_family)
reports_for_family->num_runs_total += num_repeats_of_this_instance;
}
assert(runners.size() == benchmarks.size() && "Unexpected runner count.");
// The use of performance counters with threads would be unintuitive for
// the average user so we need to warn them about this case
if ((benchmarks_with_threads > 0) && (perfcounters.num_counters() > 0)) {
GetErrorLogInstance()
<< "***WARNING*** There are " << benchmarks_with_threads
<< " benchmarks with threads and " << perfcounters.num_counters()
<< " performance counters were requested. Beware counters will "
"reflect the combined usage across all "
"threads.\n";
}
std::vector<size_t> repetition_indices;
repetition_indices.reserve(num_repetitions_total);
for (size_t runner_index = 0, num_runners = runners.size();
runner_index != num_runners; ++runner_index) {
const internal::BenchmarkRunner& runner = runners[runner_index];
std::fill_n(std::back_inserter(repetition_indices),
runner.GetNumRepeats(), runner_index);
}
assert(repetition_indices.size() == num_repetitions_total &&
"Unexpected number of repetition indexes.");
if (FLAGS_benchmark_enable_random_interleaving) {
std::random_device rd;
std::mt19937 g(rd());
std::shuffle(repetition_indices.begin(), repetition_indices.end(), g);
}
for (size_t repetition_index : repetition_indices) {
internal::BenchmarkRunner& runner = runners[repetition_index];
runner.DoOneRepetition();
if (runner.HasRepeatsRemaining()) continue;
// FIXME: report each repetition separately, not all of them in bulk.
display_reporter->ReportRunsConfig(
runner.GetMinTime(), runner.HasExplicitIters(), runner.GetIters());
if (file_reporter)
file_reporter->ReportRunsConfig(
runner.GetMinTime(), runner.HasExplicitIters(), runner.GetIters());
RunResults run_results = runner.GetResults();
// Maybe calculate complexity report
if (const auto* reports_for_family = runner.GetReportsForFamily()) {
if (reports_for_family->num_runs_done ==
reports_for_family->num_runs_total) {
auto additional_run_stats = ComputeBigO(reports_for_family->Runs);
run_results.aggregates_only.insert(run_results.aggregates_only.end(),
additional_run_stats.begin(),
additional_run_stats.end());
per_family_reports.erase(
static_cast<int>(reports_for_family->Runs.front().family_index));
}
}
Report(display_reporter, file_reporter, run_results);
}
}
display_reporter->Finalize();
if (file_reporter) file_reporter->Finalize();
FlushStreams(display_reporter);
FlushStreams(file_reporter);
}
// Disable deprecated warnings temporarily because we need to reference
// CSVReporter but don't want to trigger -Werror=-Wdeprecated-declarations
BENCHMARK_DISABLE_DEPRECATED_WARNING
std::unique_ptr<BenchmarkReporter> CreateReporter(
std::string const& name, ConsoleReporter::OutputOptions output_opts) {
typedef std::unique_ptr<BenchmarkReporter> PtrType;
if (name == "console") {
return PtrType(new ConsoleReporter(output_opts));
}
if (name == "json") {
return PtrType(new JSONReporter());
}
if (name == "csv") {
return PtrType(new CSVReporter());
}
std::cerr << "Unexpected format: '" << name << "'\n";
std::exit(1);
}
BENCHMARK_RESTORE_DEPRECATED_WARNING
} // end namespace
bool IsZero(double n) {
return std::abs(n) < std::numeric_limits<double>::epsilon();
}
ConsoleReporter::OutputOptions GetOutputOptions(bool force_no_color) {
int output_opts = ConsoleReporter::OO_Defaults;
auto is_benchmark_color = [force_no_color]() -> bool {
if (force_no_color) {
return false;
}
if (FLAGS_benchmark_color == "auto") {
return IsColorTerminal();
}
return IsTruthyFlagValue(FLAGS_benchmark_color);
};
if (is_benchmark_color()) {
output_opts |= ConsoleReporter::OO_Color;
} else {
output_opts &= ~ConsoleReporter::OO_Color;
}
if (FLAGS_benchmark_counters_tabular) {
output_opts |= ConsoleReporter::OO_Tabular;
} else {
output_opts &= ~ConsoleReporter::OO_Tabular;
}
return static_cast<ConsoleReporter::OutputOptions>(output_opts);
}
} // end namespace internal
BenchmarkReporter* CreateDefaultDisplayReporter() {
static auto default_display_reporter =
internal::CreateReporter(FLAGS_benchmark_format,
internal::GetOutputOptions())
.release();
return default_display_reporter;
}
size_t RunSpecifiedBenchmarks() {
return RunSpecifiedBenchmarks(nullptr, nullptr, FLAGS_benchmark_filter);
}
size_t RunSpecifiedBenchmarks(std::string spec) {
return RunSpecifiedBenchmarks(nullptr, nullptr, std::move(spec));
}
size_t RunSpecifiedBenchmarks(BenchmarkReporter* display_reporter) {
return RunSpecifiedBenchmarks(display_reporter, nullptr,
FLAGS_benchmark_filter);
}
size_t RunSpecifiedBenchmarks(BenchmarkReporter* display_reporter,
std::string spec) {
return RunSpecifiedBenchmarks(display_reporter, nullptr, std::move(spec));
}
size_t RunSpecifiedBenchmarks(BenchmarkReporter* display_reporter,
BenchmarkReporter* file_reporter) {
return RunSpecifiedBenchmarks(display_reporter, file_reporter,
FLAGS_benchmark_filter);
}
size_t RunSpecifiedBenchmarks(BenchmarkReporter* display_reporter,
BenchmarkReporter* file_reporter,
std::string spec) {
if (spec.empty() || spec == "all")
spec = "."; // Regexp that matches all benchmarks
// Setup the reporters
std::ofstream output_file;
std::unique_ptr<BenchmarkReporter> default_display_reporter;
std::unique_ptr<BenchmarkReporter> default_file_reporter;
if (!display_reporter) {
default_display_reporter.reset(CreateDefaultDisplayReporter());
display_reporter = default_display_reporter.get();
}
auto& Out = display_reporter->GetOutputStream();
auto& Err = display_reporter->GetErrorStream();
std::string const& fname = FLAGS_benchmark_out;
if (fname.empty() && file_reporter) {
Err << "A custom file reporter was provided but "
"--benchmark_out=<file> was not specified."
<< std::endl;
Out.flush();
Err.flush();
std::exit(1);
}
if (!fname.empty()) {
output_file.open(fname);
if (!output_file.is_open()) {
Err << "invalid file name: '" << fname << "'" << std::endl;
Out.flush();
Err.flush();
std::exit(1);
}
if (!file_reporter) {
default_file_reporter = internal::CreateReporter(
FLAGS_benchmark_out_format, FLAGS_benchmark_counters_tabular
? ConsoleReporter::OO_Tabular
: ConsoleReporter::OO_None);
file_reporter = default_file_reporter.get();
}
file_reporter->SetOutputStream(&output_file);
file_reporter->SetErrorStream(&output_file);
}
std::vector<internal::BenchmarkInstance> benchmarks;
if (!FindBenchmarksInternal(spec, &benchmarks, &Err)) {
Out.flush();
Err.flush();
return 0;
}
if (benchmarks.empty()) {
Err << "Failed to match any benchmarks against regex: " << spec << "\n";
Out.flush();
Err.flush();
return 0;
}
if (FLAGS_benchmark_list_tests) {
for (auto const& benchmark : benchmarks)
Out << benchmark.name().str() << "\n";
} else {
internal::RunBenchmarks(benchmarks, display_reporter, file_reporter);
}
Out.flush();
Err.flush();
return benchmarks.size();
}
namespace {
// stores the time unit benchmarks use by default
TimeUnit default_time_unit = kNanosecond;
} // namespace
TimeUnit GetDefaultTimeUnit() { return default_time_unit; }
void SetDefaultTimeUnit(TimeUnit unit) { default_time_unit = unit; }
std::string GetBenchmarkFilter() { return FLAGS_benchmark_filter; }
void SetBenchmarkFilter(std::string value) {
FLAGS_benchmark_filter = std::move(value);
}
int32_t GetBenchmarkVerbosity() { return FLAGS_v; }
void RegisterMemoryManager(MemoryManager* manager) {
internal::memory_manager = manager;
}
void AddCustomContext(const std::string& key, const std::string& value) {
if (internal::global_context == nullptr) {
internal::global_context = new std::map<std::string, std::string>();
}
if (!internal::global_context->emplace(key, value).second) {
std::cerr << "Failed to add custom context \"" << key << "\" as it already "
<< "exists with value \"" << value << "\"\n";
}
}
namespace internal {
void (*HelperPrintf)();
void PrintUsageAndExit() {
HelperPrintf();
exit(0);
}
void SetDefaultTimeUnitFromFlag(const std::string& time_unit_flag) {
if (time_unit_flag == "s") {
return SetDefaultTimeUnit(kSecond);
}
if (time_unit_flag == "ms") {
return SetDefaultTimeUnit(kMillisecond);
}
if (time_unit_flag == "us") {
return SetDefaultTimeUnit(kMicrosecond);
}
if (time_unit_flag == "ns") {
return SetDefaultTimeUnit(kNanosecond);
}
if (!time_unit_flag.empty()) {
PrintUsageAndExit();
}
}
void ParseCommandLineFlags(int* argc, char** argv) {
using namespace benchmark;
BenchmarkReporter::Context::executable_name =
(argc && *argc > 0) ? argv[0] : "unknown";
for (int i = 1; argc && i < *argc; ++i) {
if (ParseBoolFlag(argv[i], "benchmark_list_tests",
&FLAGS_benchmark_list_tests) ||
ParseStringFlag(argv[i], "benchmark_filter", &FLAGS_benchmark_filter) ||
ParseStringFlag(argv[i], "benchmark_min_time",
&FLAGS_benchmark_min_time) ||
ParseDoubleFlag(argv[i], "benchmark_min_warmup_time",
&FLAGS_benchmark_min_warmup_time) ||
ParseInt32Flag(argv[i], "benchmark_repetitions",
&FLAGS_benchmark_repetitions) ||
ParseBoolFlag(argv[i], "benchmark_enable_random_interleaving",
&FLAGS_benchmark_enable_random_interleaving) ||
ParseBoolFlag(argv[i], "benchmark_report_aggregates_only",
&FLAGS_benchmark_report_aggregates_only) ||
ParseBoolFlag(argv[i], "benchmark_display_aggregates_only",
&FLAGS_benchmark_display_aggregates_only) ||
ParseStringFlag(argv[i], "benchmark_format", &FLAGS_benchmark_format) ||
ParseStringFlag(argv[i], "benchmark_out", &FLAGS_benchmark_out) ||
ParseStringFlag(argv[i], "benchmark_out_format",
&FLAGS_benchmark_out_format) ||
ParseStringFlag(argv[i], "benchmark_color", &FLAGS_benchmark_color) ||
ParseBoolFlag(argv[i], "benchmark_counters_tabular",
&FLAGS_benchmark_counters_tabular) ||
ParseStringFlag(argv[i], "benchmark_perf_counters",
&FLAGS_benchmark_perf_counters) ||
ParseKeyValueFlag(argv[i], "benchmark_context",
&FLAGS_benchmark_context) ||
ParseStringFlag(argv[i], "benchmark_time_unit",
&FLAGS_benchmark_time_unit) ||
ParseInt32Flag(argv[i], "v", &FLAGS_v)) {
for (int j = i; j != *argc - 1; ++j) argv[j] = argv[j + 1];
--(*argc);
--i;
} else if (IsFlag(argv[i], "help")) {
PrintUsageAndExit();
}
}
for (auto const* flag :
{&FLAGS_benchmark_format, &FLAGS_benchmark_out_format}) {
if (*flag != "console" && *flag != "json" && *flag != "csv") {
PrintUsageAndExit();
}
}
SetDefaultTimeUnitFromFlag(FLAGS_benchmark_time_unit);
if (FLAGS_benchmark_color.empty()) {
PrintUsageAndExit();
}
for (const auto& kv : FLAGS_benchmark_context) {
AddCustomContext(kv.first, kv.second);
}
}
int InitializeStreams() {
static std::ios_base::Init init;
return 0;
}
} // end namespace internal
std::string GetBenchmarkVersion() {
#ifdef BENCHMARK_VERSION
return {BENCHMARK_VERSION};
#else
return {""};
#endif
}
void PrintDefaultHelp() {
fprintf(stdout,
"benchmark"
" [--benchmark_list_tests={true|false}]\n"
" [--benchmark_filter=<regex>]\n"
" [--benchmark_min_time=`<integer>x` OR `<float>s` ]\n"
" [--benchmark_min_warmup_time=<min_warmup_time>]\n"
" [--benchmark_repetitions=<num_repetitions>]\n"
" [--benchmark_enable_random_interleaving={true|false}]\n"
" [--benchmark_report_aggregates_only={true|false}]\n"
" [--benchmark_display_aggregates_only={true|false}]\n"
" [--benchmark_format=<console|json|csv>]\n"
" [--benchmark_out=<filename>]\n"
" [--benchmark_out_format=<json|console|csv>]\n"
" [--benchmark_color={auto|true|false}]\n"
" [--benchmark_counters_tabular={true|false}]\n"
#if defined HAVE_LIBPFM
" [--benchmark_perf_counters=<counter>,...]\n"
#endif
" [--benchmark_context=<key>=<value>,...]\n"
" [--benchmark_time_unit={ns|us|ms|s}]\n"
" [--v=<verbosity>]\n");
}
void Initialize(int* argc, char** argv, void (*HelperPrintf)()) {
internal::HelperPrintf = HelperPrintf;
internal::ParseCommandLineFlags(argc, argv);
internal::LogLevel() = FLAGS_v;
}
void Shutdown() { delete internal::global_context; }
bool ReportUnrecognizedArguments(int argc, char** argv) {
for (int i = 1; i < argc; ++i) {
fprintf(stderr, "%s: error: unrecognized command-line flag: %s\n", argv[0],
argv[i]);
}
return argc > 1;
}
} // end namespace benchmark