src/benchmark_api_internal.cc - external/github.com/google/benchmark - Git at Google

 #include "benchmark_api_internal.h"

 #include <cinttypes>

 #include "check.h"
 #include "string_util.h"

 DECLARE_bool(benchmark_enable_random_interleaving);

 namespace benchmark {
 namespace internal {

 BenchmarkInstance::BenchmarkInstance(Benchmark* benchmark,
                                      const std::vector<int64_t>& args,
                                      int thread_count)
     : benchmark_(*benchmark),
       aggregation_report_mode_(benchmark_.aggregation_report_mode_),
       args_(args),
       time_unit_(benchmark_.time_unit_),
       measure_process_cpu_time_(benchmark_.measure_process_cpu_time_),
       use_real_time_(benchmark_.use_real_time_),
       use_manual_time_(benchmark_.use_manual_time_),
       complexity_(benchmark_.complexity_),
       complexity_lambda_(benchmark_.complexity_lambda_),
       statistics_(benchmark_.statistics_),
       repetitions_(benchmark_.repetitions_),
       min_time_(!IsZero(benchmark_.min_time_) ? benchmark_.min_time_
                                               : GetMinTime()),
       iterations_(benchmark_.iterations_),
       threads_(thread_count) {
   CHECK(!IsZero(min_time_)) << "min_time must be non-zero.";

   name_.function_name = benchmark_.name_;

   size_t arg_i = 0;
   for (const auto& arg : args) {
     if (!name_.args.empty()) {
       name_.args += '/';
     }

     if (arg_i < benchmark->arg_names_.size()) {
       const auto& arg_name = benchmark_.arg_names_[arg_i];
       if (!arg_name.empty()) {
         name_.args += StrFormat("%s:", arg_name.c_str());
       }
     }

     name_.args += StrFormat("%" PRId64, arg);
     ++arg_i;
   }

   if (!IsZero(benchmark->min_time_)) {
     name_.min_time = StrFormat("min_time:%0.3f", benchmark_.min_time_);
   }

   if (benchmark_.iterations_ != 0) {
     name_.iterations = StrFormat(
         "iterations:%lu", static_cast<unsigned long>(benchmark_.iterations_));
   }

   if (benchmark_.repetitions_ != 0) {
     name_.repetitions = StrFormat("repeats:%d", benchmark_.repetitions_);
   }

   if (benchmark_.measure_process_cpu_time_) {
     name_.time_type = "process_time";
   }

   if (benchmark_.use_manual_time_) {
     if (!name_.time_type.empty()) {
       name_.time_type += '/';
     }
     name_.time_type += "manual_time";
   } else if (benchmark_.use_real_time_) {
     if (!name_.time_type.empty()) {
       name_.time_type += '/';
     }
     name_.time_type += "real_time";
   }

   if (!benchmark_.thread_counts_.empty()) {
     name_.threads = StrFormat("threads:%d", threads_);
   }
 }

 double BenchmarkInstance::MinTime() const {
   if (FLAGS_benchmark_enable_random_interleaving) {
     // Random Interleaving will automatically adjust
     // random_interleaving_repetitions(). Dividing
     // total execution time by random_interleaving_repetitions() gives
     // the adjusted min_time per repetition.
     return min_time_ * GetRepetitions() / RandomInterleavingRepetitions();
   }
   return min_time_;
 }

 int BenchmarkInstance::RandomInterleavingRepetitions() const {
   return random_interleaving_repetitions_ < 0
              ? GetRepetitions()
              : random_interleaving_repetitions_;
 }

 bool BenchmarkInstance::RandomInterleavingRepetitionsInitialized() const {
   return random_interleaving_repetitions_ >= 0;
 }

 void BenchmarkInstance::InitRandomInterleavingRepetitions(
     int reps) const {
   random_interleaving_repetitions_ = reps;
 }

 State BenchmarkInstance::Run(
     IterationCount iters, int thread_id, internal::ThreadTimer* timer,
     internal::ThreadManager* manager,
     internal::PerfCountersMeasurement* perf_counters_measurement) const {
   State st(iters, args_, thread_id, threads_, timer, manager,
            perf_counters_measurement);
   benchmark_.Run(st);
   return st;
 }

 }  // namespace internal
 }  // namespace benchmark
	#include "benchmark_api_internal.h"

	#include <cinttypes>

	#include "check.h"
	#include "string_util.h"

	DECLARE_bool(benchmark_enable_random_interleaving);

	namespace benchmark {
	namespace internal {

	BenchmarkInstance::BenchmarkInstance(Benchmark* benchmark,
	const std::vector<int64_t>& args,
	int thread_count)
	: benchmark_(*benchmark),
	aggregation_report_mode_(benchmark_.aggregation_report_mode_),
	args_(args),
	time_unit_(benchmark_.time_unit_),
	measure_process_cpu_time_(benchmark_.measure_process_cpu_time_),
	use_real_time_(benchmark_.use_real_time_),
	use_manual_time_(benchmark_.use_manual_time_),
	complexity_(benchmark_.complexity_),
	complexity_lambda_(benchmark_.complexity_lambda_),
	statistics_(benchmark_.statistics_),
	repetitions_(benchmark_.repetitions_),
	min_time_(!IsZero(benchmark_.min_time_) ? benchmark_.min_time_
	: GetMinTime()),
	iterations_(benchmark_.iterations_),
	threads_(thread_count) {
	CHECK(!IsZero(min_time_)) << "min_time must be non-zero.";

	name_.function_name = benchmark_.name_;

	size_t arg_i = 0;
	for (const auto& arg : args) {
	if (!name_.args.empty()) {
	name_.args += '/';
	}

	if (arg_i < benchmark->arg_names_.size()) {
	const auto& arg_name = benchmark_.arg_names_[arg_i];
	if (!arg_name.empty()) {
	name_.args += StrFormat("%s:", arg_name.c_str());
	}
	}

	name_.args += StrFormat("%" PRId64, arg);
	++arg_i;
	}

	if (!IsZero(benchmark->min_time_)) {
	name_.min_time = StrFormat("min_time:%0.3f", benchmark_.min_time_);
	}

	if (benchmark_.iterations_ != 0) {
	name_.iterations = StrFormat(
	"iterations:%lu", static_cast<unsigned long>(benchmark_.iterations_));
	}

	if (benchmark_.repetitions_ != 0) {
	name_.repetitions = StrFormat("repeats:%d", benchmark_.repetitions_);
	}

	if (benchmark_.measure_process_cpu_time_) {
	name_.time_type = "process_time";
	}

	if (benchmark_.use_manual_time_) {
	if (!name_.time_type.empty()) {
	name_.time_type += '/';
	}
	name_.time_type += "manual_time";
	} else if (benchmark_.use_real_time_) {
	if (!name_.time_type.empty()) {
	name_.time_type += '/';
	}
	name_.time_type += "real_time";
	}

	if (!benchmark_.thread_counts_.empty()) {
	name_.threads = StrFormat("threads:%d", threads_);
	}
	}

	double BenchmarkInstance::MinTime() const {
	if (FLAGS_benchmark_enable_random_interleaving) {
	// Random Interleaving will automatically adjust
	// random_interleaving_repetitions(). Dividing
	// total execution time by random_interleaving_repetitions() gives
	// the adjusted min_time per repetition.
	return min_time_ * GetRepetitions() / RandomInterleavingRepetitions();
	}
	return min_time_;
	}

	int BenchmarkInstance::RandomInterleavingRepetitions() const {
	return random_interleaving_repetitions_ < 0
	? GetRepetitions()
	: random_interleaving_repetitions_;
	}

	bool BenchmarkInstance::RandomInterleavingRepetitionsInitialized() const {
	return random_interleaving_repetitions_ >= 0;
	}

	void BenchmarkInstance::InitRandomInterleavingRepetitions(
	int reps) const {
	random_interleaving_repetitions_ = reps;
	}

	State BenchmarkInstance::Run(
	IterationCount iters, int thread_id, internal::ThreadTimer* timer,
	internal::ThreadManager* manager,
	internal::PerfCountersMeasurement* perf_counters_measurement) const {
	State st(iters, args_, thread_id, threads_, timer, manager,
	perf_counters_measurement);
	benchmark_.Run(st);
	return st;
	}

	} // namespace internal
	} // namespace benchmark