#ifndef BENCHMARK_THREAD_MANAGER_H #define BENCHMARK_THREAD_MANAGER_H #include #include "benchmark/benchmark.h" #include "mutex.h" namespace benchmark { namespace internal { class ThreadManager { public: explicit ThreadManager(int num_threads) : alive_threads_(num_threads), start_stop_barrier_(num_threads) {} Mutex& GetBenchmarkMutex() const RETURN_CAPABILITY(benchmark_mutex_) { return benchmark_mutex_; } bool StartStopBarrier() EXCLUDES(end_cond_mutex_) { return start_stop_barrier_.wait(); } void NotifyThreadComplete() EXCLUDES(end_cond_mutex_) { start_stop_barrier_.removeThread(); if (--alive_threads_ == 0) { MutexLock lock(end_cond_mutex_); end_condition_.notify_all(); } } void WaitForAllThreads() EXCLUDES(end_cond_mutex_) { MutexLock lock(end_cond_mutex_); end_condition_.wait(lock.native_handle(), [this]() { return alive_threads_ == 0; }); } struct Result { IterationCount iterations = 0; double real_time_used = 0; double cpu_time_used = 0; double manual_time_used = 0; int64_t complexity_n = 0; std::string report_label_; std::string error_message_; bool has_error_ = false; UserCounters counters; }; GUARDED_BY(GetBenchmarkMutex()) Result results; private: mutable Mutex benchmark_mutex_; std::atomic alive_threads_; Barrier start_stop_barrier_; Mutex end_cond_mutex_; Condition end_condition_; }; } // namespace internal } // namespace benchmark #endif // BENCHMARK_THREAD_MANAGER_H