#if defined(SOKOL_IMPL) && !defined(SOKOL_TIME_IMPL) #define SOKOL_TIME_IMPL #endif #ifndef SOKOL_TIME_INCLUDED /* sokol_time.h -- simple cross-platform time measurement Project URL: https://github.com/floooh/sokol Do this: #define SOKOL_IMPL or #define SOKOL_TIME_IMPL before you include this file in *one* C or C++ file to create the implementation. Optionally provide the following defines with your own implementations: SOKOL_ASSERT(c) - your own assert macro (default: assert(c)) SOKOL_TIME_API_DECL - public function declaration prefix (default: extern) SOKOL_API_DECL - same as SOKOL_TIME_API_DECL SOKOL_API_IMPL - public function implementation prefix (default: -) If sokol_time.h is compiled as a DLL, define the following before including the declaration or implementation: SOKOL_DLL On Windows, SOKOL_DLL will define SOKOL_TIME_API_DECL as __declspec(dllexport) or __declspec(dllimport) as needed. void stm_setup(); Call once before any other functions to initialize sokol_time (this calls for instance QueryPerformanceFrequency on Windows) uint64_t stm_now(); Get current point in time in unspecified 'ticks'. The value that is returned has no relation to the 'wall-clock' time and is not in a specific time unit, it is only useful to compute time differences. uint64_t stm_diff(uint64_t new, uint64_t old); Computes the time difference between new and old. This will always return a positive, non-zero value. uint64_t stm_since(uint64_t start); Takes the current time, and returns the elapsed time since start (this is a shortcut for "stm_diff(stm_now(), start)") uint64_t stm_laptime(uint64_t* last_time); This is useful for measuring frame time and other recurring events. It takes the current time, returns the time difference to the value in last_time, and stores the current time in last_time for the next call. If the value in last_time is 0, the return value will be zero (this usually happens on the very first call). uint64_t stm_round_to_common_refresh_rate(uint64_t duration) This oddly named function takes a measured frame time and returns the closest "nearby" common display refresh rate frame duration in ticks. If the input duration isn't close to any common display refresh rate, the input duration will be returned unchanged as a fallback. The main purpose of this function is to remove jitter/inaccuracies from measured frame times, and instead use the display refresh rate as frame duration. Use the following functions to convert a duration in ticks into useful time units: double stm_sec(uint64_t ticks); double stm_ms(uint64_t ticks); double stm_us(uint64_t ticks); double stm_ns(uint64_t ticks); Converts a tick value into seconds, milliseconds, microseconds or nanoseconds. Note that not all platforms will have nanosecond or even microsecond precision. Uses the following time measurement functions under the hood: Windows: QueryPerformanceFrequency() / QueryPerformanceCounter() MacOS/iOS: mach_absolute_time() emscripten: performance.now() Linux+others: clock_gettime(CLOCK_MONOTONIC) zlib/libpng license Copyright (c) 2018 Andre Weissflog This software is provided 'as-is', without any express or implied warranty. In no event will the authors be held liable for any damages arising from the use of this software. Permission is granted to anyone to use this software for any purpose, including commercial applications, and to alter it and redistribute it freely, subject to the following restrictions: 1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required. 2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software. 3. This notice may not be removed or altered from any source distribution. */ #define SOKOL_TIME_INCLUDED (1) #include #if defined(SOKOL_API_DECL) && !defined(SOKOL_TIME_API_DECL) #define SOKOL_TIME_API_DECL SOKOL_API_DECL #endif #ifndef SOKOL_TIME_API_DECL #if defined(_WIN32) && defined(SOKOL_DLL) && defined(SOKOL_TIME_IMPL) #define SOKOL_TIME_API_DECL __declspec(dllexport) #elif defined(_WIN32) && defined(SOKOL_DLL) #define SOKOL_TIME_API_DECL __declspec(dllimport) #else #define SOKOL_TIME_API_DECL extern #endif #endif #ifdef __cplusplus extern "C" { #endif SOKOL_TIME_API_DECL void stm_setup(void); SOKOL_TIME_API_DECL uint64_t stm_now(void); SOKOL_TIME_API_DECL uint64_t stm_diff(uint64_t new_ticks, uint64_t old_ticks); SOKOL_TIME_API_DECL uint64_t stm_since(uint64_t start_ticks); SOKOL_TIME_API_DECL uint64_t stm_laptime(uint64_t* last_time); SOKOL_TIME_API_DECL uint64_t stm_round_to_common_refresh_rate(uint64_t frame_ticks); SOKOL_TIME_API_DECL double stm_sec(uint64_t ticks); SOKOL_TIME_API_DECL double stm_ms(uint64_t ticks); SOKOL_TIME_API_DECL double stm_us(uint64_t ticks); SOKOL_TIME_API_DECL double stm_ns(uint64_t ticks); #ifdef __cplusplus } /* extern "C" */ #endif #endif // SOKOL_TIME_INCLUDED /*-- IMPLEMENTATION ----------------------------------------------------------*/ #ifdef SOKOL_TIME_IMPL #define SOKOL_TIME_IMPL_INCLUDED (1) #include /* memset */ #ifndef SOKOL_API_IMPL #define SOKOL_API_IMPL #endif #ifndef SOKOL_ASSERT #include #define SOKOL_ASSERT(c) assert(c) #endif #ifndef _SOKOL_PRIVATE #if defined(__GNUC__) || defined(__clang__) #define _SOKOL_PRIVATE __attribute__((unused)) static #else #define _SOKOL_PRIVATE static #endif #endif #if defined(_WIN32) #ifndef WIN32_LEAN_AND_MEAN #define WIN32_LEAN_AND_MEAN #endif #include typedef struct { uint32_t initialized; LARGE_INTEGER freq; LARGE_INTEGER start; } _stm_state_t; #elif defined(__APPLE__) && defined(__MACH__) #include typedef struct { uint32_t initialized; mach_timebase_info_data_t timebase; uint64_t start; } _stm_state_t; #elif defined(__EMSCRIPTEN__) #include typedef struct { uint32_t initialized; double start; } _stm_state_t; #else /* anything else, this will need more care for non-Linux platforms */ #ifdef ESP8266 // On the ESP8266, clock_gettime ignores the first argument and CLOCK_MONOTONIC isn't defined #define CLOCK_MONOTONIC 0 #endif #include typedef struct { uint32_t initialized; uint64_t start; } _stm_state_t; #endif static _stm_state_t _stm; /* prevent 64-bit overflow when computing relative timestamp see https://gist.github.com/jspohr/3dc4f00033d79ec5bdaf67bc46c813e3 */ #if defined(_WIN32) || (defined(__APPLE__) && defined(__MACH__)) _SOKOL_PRIVATE int64_t int64_muldiv(int64_t value, int64_t numer, int64_t denom) { int64_t q = value / denom; int64_t r = value % denom; return q * numer + r * numer / denom; } #endif #if defined(__EMSCRIPTEN__) EM_JS(double, stm_js_perfnow, (void), { return performance.now(); }); #endif SOKOL_API_IMPL void stm_setup(void) { memset(&_stm, 0, sizeof(_stm)); _stm.initialized = 0xABCDABCD; #if defined(_WIN32) QueryPerformanceFrequency(&_stm.freq); QueryPerformanceCounter(&_stm.start); #elif defined(__APPLE__) && defined(__MACH__) mach_timebase_info(&_stm.timebase); _stm.start = mach_absolute_time(); #elif defined(__EMSCRIPTEN__) _stm.start = stm_js_perfnow(); #else struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); _stm.start = (uint64_t)ts.tv_sec*1000000000 + (uint64_t)ts.tv_nsec; #endif } SOKOL_API_IMPL uint64_t stm_now(void) { SOKOL_ASSERT(_stm.initialized == 0xABCDABCD); uint64_t now; #if defined(_WIN32) LARGE_INTEGER qpc_t; QueryPerformanceCounter(&qpc_t); now = int64_muldiv(qpc_t.QuadPart - _stm.start.QuadPart, 1000000000, _stm.freq.QuadPart); #elif defined(__APPLE__) && defined(__MACH__) const uint64_t mach_now = mach_absolute_time() - _stm.start; now = int64_muldiv(mach_now, _stm.timebase.numer, _stm.timebase.denom); #elif defined(__EMSCRIPTEN__) double js_now = stm_js_perfnow() - _stm.start; SOKOL_ASSERT(js_now >= 0.0); now = (uint64_t) (js_now * 1000000.0); #else struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); now = ((uint64_t)ts.tv_sec*1000000000 + (uint64_t)ts.tv_nsec) - _stm.start; #endif return now; } SOKOL_API_IMPL uint64_t stm_diff(uint64_t new_ticks, uint64_t old_ticks) { if (new_ticks > old_ticks) { return new_ticks - old_ticks; } else { return 1; } } SOKOL_API_IMPL uint64_t stm_since(uint64_t start_ticks) { return stm_diff(stm_now(), start_ticks); } SOKOL_API_IMPL uint64_t stm_laptime(uint64_t* last_time) { SOKOL_ASSERT(last_time); uint64_t dt = 0; uint64_t now = stm_now(); if (0 != *last_time) { dt = stm_diff(now, *last_time); } *last_time = now; return dt; } // first number is frame duration in ns, second number is tolerance in ns, // the resulting min/max values must not overlap! static const uint64_t _stm_refresh_rates[][2] = { { 16666667, 1000000 }, // 60 Hz: 16.6667 +- 1ms { 13888889, 250000 }, // 72 Hz: 13.8889 +- 0.25ms { 13333333, 250000 }, // 75 Hz: 13.3333 +- 0.25ms { 11764706, 250000 }, // 85 Hz: 11.7647 +- 0.25 { 11111111, 250000 }, // 90 Hz: 11.1111 +- 0.25ms { 8333333, 500000 }, // 120 Hz: 8.3333 +- 0.5ms { 6944445, 500000 }, // 144 Hz: 6.9445 +- 0.5ms { 4166667, 1000000 }, // 240 Hz: 4.1666 +- 1ms { 0, 0 }, // keep the last element always at zero }; SOKOL_API_IMPL uint64_t stm_round_to_common_refresh_rate(uint64_t ticks) { uint64_t ns; int i = 0; while (0 != (ns = _stm_refresh_rates[i][0])) { uint64_t tol = _stm_refresh_rates[i][1]; if ((ticks > (ns - tol)) && (ticks < (ns + tol))) { return ns; } i++; } // fallthough: didn't fit into any buckets return ticks; } SOKOL_API_IMPL double stm_sec(uint64_t ticks) { return (double)ticks / 1000000000.0; } SOKOL_API_IMPL double stm_ms(uint64_t ticks) { return (double)ticks / 1000000.0; } SOKOL_API_IMPL double stm_us(uint64_t ticks) { return (double)ticks / 1000.0; } SOKOL_API_IMPL double stm_ns(uint64_t ticks) { return (double)ticks; } #endif /* SOKOL_TIME_IMPL */