// SPDX-FileCopyrightText: 2002-2024 PCSX2 Dev Team // SPDX-License-Identifier: GPL-3.0+ #include "Timer.h" #include #include #if defined(_WIN32) #include "RedtapeWindows.h" #else #include #endif namespace Common { #ifdef _WIN32 static double s_counter_frequency; static bool s_counter_initialized = false; Timer::Value Timer::GetCurrentValue() { // even if this races, it should still result in the same value.. if (!s_counter_initialized) { LARGE_INTEGER Freq; QueryPerformanceFrequency(&Freq); s_counter_frequency = static_cast(Freq.QuadPart) / 1000000000.0; s_counter_initialized = true; } Timer::Value ReturnValue; QueryPerformanceCounter(reinterpret_cast(&ReturnValue)); return ReturnValue; } double Timer::ConvertValueToNanoseconds(Timer::Value value) { return (static_cast(value) / s_counter_frequency); } double Timer::ConvertValueToMilliseconds(Timer::Value value) { return ((static_cast(value) / s_counter_frequency) / 1000000.0); } double Timer::ConvertValueToSeconds(Timer::Value value) { return ((static_cast(value) / s_counter_frequency) / 1000000000.0); } Timer::Value Timer::ConvertSecondsToValue(double s) { return static_cast((s * 1000000000.0) * s_counter_frequency); } Timer::Value Timer::ConvertMillisecondsToValue(double ms) { return static_cast((ms * 1000000.0) * s_counter_frequency); } Timer::Value Timer::ConvertNanosecondsToValue(double ns) { return static_cast(ns * s_counter_frequency); } #else Timer::Value Timer::GetCurrentValue() { struct timespec tv; clock_gettime(CLOCK_MONOTONIC, &tv); return ((Value)tv.tv_nsec + (Value)tv.tv_sec * 1000000000); } double Timer::ConvertValueToNanoseconds(Timer::Value value) { return static_cast(value); } double Timer::ConvertValueToMilliseconds(Timer::Value value) { return (static_cast(value) / 1000000.0); } double Timer::ConvertValueToSeconds(Timer::Value value) { return (static_cast(value) / 1000000000.0); } Timer::Value Timer::ConvertSecondsToValue(double s) { return static_cast(s * 1000000000.0); } Timer::Value Timer::ConvertMillisecondsToValue(double ms) { return static_cast(ms * 1000000.0); } Timer::Value Timer::ConvertNanosecondsToValue(double ns) { return static_cast(ns); } #endif Timer::Timer() { Reset(); } void Timer::Reset() { m_tvStartValue = GetCurrentValue(); } double Timer::GetTimeSeconds() const { return ConvertValueToSeconds(GetCurrentValue() - m_tvStartValue); } double Timer::GetTimeMilliseconds() const { return ConvertValueToMilliseconds(GetCurrentValue() - m_tvStartValue); } double Timer::GetTimeNanoseconds() const { return ConvertValueToNanoseconds(GetCurrentValue() - m_tvStartValue); } double Timer::GetTimeSecondsAndReset() { const Value value = GetCurrentValue(); const double ret = ConvertValueToSeconds(value - m_tvStartValue); m_tvStartValue = value; return ret; } double Timer::GetTimeMillisecondsAndReset() { const Value value = GetCurrentValue(); const double ret = ConvertValueToMilliseconds(value - m_tvStartValue); m_tvStartValue = value; return ret; } double Timer::GetTimeNanosecondsAndReset() { const Value value = GetCurrentValue(); const double ret = ConvertValueToNanoseconds(value - m_tvStartValue); m_tvStartValue = value; return ret; } bool Timer::ResetIfSecondsPassed(double s) { const Value value = GetCurrentValue(); const double ret = ConvertValueToSeconds(value - m_tvStartValue); if (ret < s) return false; m_tvStartValue = value; return true; } bool Timer::ResetIfMillisecondsPassed(double s) { const Value value = GetCurrentValue(); const double ret = ConvertValueToMilliseconds(value - m_tvStartValue); if (ret < s) return false; m_tvStartValue = value; return true; } bool Timer::ResetIfNanosecondsPassed(double s) { const Value value = GetCurrentValue(); const double ret = ConvertValueToNanoseconds(value - m_tvStartValue); if (ret < s) return false; m_tvStartValue = value; return true; } } // namespace Common