If you want to measure FPS only for the sake of printing it, you may use std::chrono
as it measures wall clock. Using std::clock()
results in a more accurate value than std::chrono
since it measures processing time, but maybe you don't want to print FPS with such a high precision.
The solution below uses std::chrono
to calculate a program's uptime and increments a frame counter after each frame update. Dividing the frame counter by the program's uptime gives you the FPS.
#include <chrono>
#include <iostream>
#include <thread>
using namespace std::chrono;
steady_clock::time_point first_tp;
unsigned long frame_count = 0;
duration<double> uptime()
{
if (first_tp == steady_clock::time_point{})
return duration<double>{ 0 };
return steady_clock::now() - first_tp;
}
double fps()
{
const double uptime_sec = uptime().count();
if (uptime_sec == 0)
return 0;
return frame_count / uptime_sec;
}
void time_consuming_function()
{
std::this_thread::sleep_for(milliseconds{ 100 });
}
void run_forever()
{
std::cout << "fps at first: " << fps() << '\n';
first_tp = std::chrono::steady_clock::now();
while (true)
{
std::cout << "fps: " << fps() << '\n';
time_consuming_function();
frame_count++;
}
}
int main()
{
run_forever();
}
Running it on my machine produces:
$ ./measure_fps
fps at first: 0
fps: 0
fps: 9.99108
fps: 9.99025
fps: 9.98997
fps: 9.98984
Whereas adapting it to std::clock()
gives
$ ./measure_fps
fps at first: 0
fps: 0
fps: 37037
fps: 25316.5
fps: 23622
fps: 22346.4