If I'm understanding your question, and if you know all of the different time resolutions at compile-time, then the following will do what you want. You can figure out the correct tick period by using
common_type on all of your different time resolutions as shown below:
typedef std::uint64_t rep;
std::chrono::duration<rep, std::ratio<1, 50>>,
std::chrono::duration<rep, std::ratio<1, 30>>,
std::chrono::duration<rep, std::ratio<1001, 30000>>
typedef duration::period period;
typedef std::chrono::time_point<clock> time_point;
static const bool is_steady = true;
static time_point now()
// just as an example
using namespace std::chrono;
This will compute at compile-time the largest tick period which will exactly represent each of your specified resolutions. For example with this clock one can exactly represent:
- 1/50 with 600 ticks.
- 1/30 with 1000 ticks.
- 1001/30000 with 1001 ticks.
The code below exercises this
clock and uses the "chrono_io" facility described here to print out not only the run-time number of ticks of your clock, but also the compile-time units of your clock-tick:
auto t0 = clock::now();
auto t1 = clock::now();
std::cout << (t1-t0) << '\n';
For me this prints out:
Meaning: There were 633 clock ticks between calls to
now() and the unit of each tick is 1/30000 of a second. If you don't want to be beholden to "chrono_io" you can inspect the units of your clock with
If your different time resolutions are not compile-time information, then your current solution with
boost::rational is probably best.