一 需求:

测试cpu计算性能

二 方法:

1.使用一定规模方阵执行乘法运算,不需要保存结果。

2.根据CPU核数开启线程执行乘法运算

3.事先将线程执行任务放入线程对应的任务容器,然后开启线程,统计时间

4.采用cpu绑定,程序没有加锁,几乎没有系统开销。

三 代码

1.cpu_binding.hpp

#ifndef CPU_BINDING_HPP_
#define CPU_BINDING_HPP_
#include <pthread.h>
#include <thread>
using namespace std;
class cpu_binding {
public:
  static cpu_binding &get_instance() {
    static cpu_binding cpu_binding_;
    return cpu_binding_;
  }
  inline int get_cpu_num() const {
    return cpu_num_;
  }
  bool binding(int cpu) {
    if (cpu < 0) {
      return false;
    }
    cpu = (cpu + 1) % cpu_num_;
    if (0 == cpu) {
      return true;
    }
    cpu_set_t cpu_set = {0};
    CPU_SET(cpu, &cpu_set);
    return pthread_setaffinity_np(pthread_self(), sizeof(cpu_set), &cpu_set) >= 0;
  }
private:
  cpu_binding() {
    cpu_num_ = thread::hardware_concurrency();
  }
  virtual ~cpu_binding() = default;
private:
  int cpu_num_;
};

#endif /* CPU_BINDING_HPP_ */

2.cpu_performance_test.hpp

#ifndef CPU_PERFORMANCE_TEST_HPP_
#define CPU_PERFORMANCE_TEST_HPP_
#include <iostream>
#include <vector>
#include <random>
#include <chrono>
#include <functional>
#include "cpu_binding.hpp"
using namespace std;
struct coordinate {
  coordinate(int a = 0, int b = 0) : row(a), col(b) {
  }
  int row;
  int col;
};
class cpu_performance_test {
public:
  static inline cpu_performance_test &get_instance() {
    static cpu_performance_test test;
    return test;
  }
  inline void set_matrix_dimension(int d) {
    matrix_dimension_ = d;
  }
  void init() {
    init_square_matrix(square_matrix0_);
    init_square_matrix(square_matrix1_);
    init_coordinate_array();
    init_threads();
  }
private:
  cpu_performance_test() {
    thread_num_ = thread::hardware_concurrency();
    matrix_dimension_ = 100;
  }
  cpu_performance_test(const cpu_performance_test &) = delete;
  cpu_performance_test & operator = (const cpu_performance_test &) = delete;
  virtual ~cpu_performance_test() {
    join_threads();
  }
private:
  void init_square_matrix(vector<vector<int> >&square_matrix) {
    int number = 0;
    vector<int>matrix_line;
    random_device rd;
    matrix_line.reserve(matrix_dimension_);
    cout << "square matrix as following:" << endl;
    cout << "===============================================" << endl;
    for (int i = 0;i < matrix_dimension_;i++) {
      for (int j = 0;j < matrix_dimension_;j++) {
        number = rd() % 1888;
        matrix_line.emplace_back(number);
        cout << number << " ";
      }
      square_matrix.emplace_back(matrix_line);
      matrix_line.clear();
      cout << endl;
    }
    cout << "===============================================" << endl;
  }
  void init_coordinate_array() {
    corrdinate_array_.resize(thread_num_);
    int loop = 0;
    for (int i = 0;i < matrix_dimension_;i++) {
      for (int j = 0;j < matrix_dimension_;j++) {
        corrdinate_array_[loop].emplace_back(coordinate(i, j));
        cout << "thread id = " << loop << endl;
        cout << "thread task data is " << "(" << i << "," << j << ")" << endl;
        loop = (loop + 1) % thread_num_;
 
      }
    }
  }
  void init_threads() {
    cout << "thread number = " << thread_num_ << endl;
    threads_.resize(thread_num_);
    int thread_id = 0;
    now_ = std::chrono::steady_clock::now();
    for (auto &thread_obj : threads_) {
      thread_obj = thread(bind(&cpu_performance_test::thread_compute, this, thread_id++));
    }
  }
  void join_threads() {
    for (auto &thread_obj : threads_) {
      if (thread_obj.joinable()) {
        thread_obj.join();
      }
    }
    auto end_time = chrono::steady_clock::now();
    chrono::duration<double>time_span = chrono::duration_cast<chrono::duration<double>>(end_time - now_);
    cout << "elapse time = " << time_span.count() << " seconds." << endl;
  }
  void thread_compute(int thread_id) {
    cpu_binding::get_instance().binding(thread_id);
    const auto vec = corrdinate_array_[thread_id];
    int sum = 0;
    for (auto &coordinate_obj : vec) {
      for (int i = 0;i < matrix_dimension_;i++) {
        sum += square_matrix0_[coordinate_obj.row][i] * square_matrix1_[i][coordinate_obj.col];
      }
      sum = 0;
    }
  }
private:
  int thread_num_;
  int matrix_dimension_;
private:
  vector<vector<int> >square_matrix0_;
  vector<vector<int> >square_matrix1_;
  vector<vector<coordinate>>corrdinate_array_;
  vector<thread>threads_;
private:
  chrono::steady_clock::time_point now_;
};
 
#endif /* CPU_PERFORMANCE_TEST_HPP_ */

3.main.cpp

#include "cpu_performance_test.hpp"
int main() {
  cpu_performance_test::get_instance().init();

  return 0;
}

4.make.sh

g++ -std=c++17 -g -o Test main.cpp cpu_performance_test.hpp cpu_binding.hpp -pthread