citra/src/core/perf_stats.cpp
GPUCode 48ee112ceb
Add per game configuration options (#6187)
* common: Move settings to common from core.

- Removes a dependency on core and input_common from common.

* code: Wrap settings values

* Port from yuzu to allow per game settings

* citra_qt: Initial per-game settings dialog

* citra_qt: Use new API for read/save of config values

* citra_qt: Per game audio settings

* citra_qt: Per game graphics settings

* citra_qt: Per game system settings

* citra_qt: Per game general settings

* citra_qt: Document and run clang format

* citra_qt: Make icon smaller and centered

* citra_qt: Remove version number

* Not sure how to extract that, can always add it back later

* citra_qt: Wrap UISettings

* citra_qt: Fix unthottled fps setting

* citra_qt: Remove margin in emulation tab

* citra_qt: Implement some suggestions

* Bring back speed switch hotkey

* Allow configuration when game is running

* Rename/adjust UI stuff

* citra_qt: Fix build with separate windows

* citra_qt: Address feedback

* citra_qt: Log per-game settings before launching games

* citra_qt: Add shader cache options

* Also fix android build

* citra_qt: Add DLC menu option

* citra_qt: Run clang-format

* citra_qt: Adjust for time offset

* citra_qt: Implement suggestions

* Run clang-format

Co-authored-by: bunnei <bunneidev@gmail.com>
2022-12-08 13:27:25 +02:00

184 lines
6.1 KiB
C++

// Copyright 2017 Citra Emulator Project
// Licensed under GPLv2 or any later version
// Refer to the license.txt file included.
#include <algorithm>
#include <chrono>
#include <iterator>
#include <mutex>
#include <numeric>
#include <sstream>
#include <thread>
#include <fmt/chrono.h>
#include <fmt/format.h>
#include "common/file_util.h"
#include "common/settings.h"
#include "core/hw/gpu.h"
#include "core/perf_stats.h"
using namespace std::chrono_literals;
using DoubleSecs = std::chrono::duration<double, std::chrono::seconds::period>;
using std::chrono::duration_cast;
using std::chrono::microseconds;
// Purposefully ignore the first five frames, as there's a significant amount of overhead in
// booting that we shouldn't account for
constexpr std::size_t IgnoreFrames = 5;
namespace Core {
PerfStats::PerfStats(u64 title_id) : title_id(title_id) {}
PerfStats::~PerfStats() {
if (!Settings::values.record_frame_times || title_id == 0) {
return;
}
const std::time_t t = std::time(nullptr);
std::ostringstream stream;
std::copy(perf_history.begin() + IgnoreFrames, perf_history.begin() + current_index,
std::ostream_iterator<double>(stream, "\n"));
const std::string& path = FileUtil::GetUserPath(FileUtil::UserPath::LogDir);
// %F Date format expanded is "%Y-%m-%d"
const std::string filename =
fmt::format("{}/{:%F-%H-%M}_{:016X}.csv", path, *std::localtime(&t), title_id);
FileUtil::IOFile file(filename, "w");
file.WriteString(stream.str());
}
void PerfStats::BeginSystemFrame() {
std::lock_guard lock{object_mutex};
frame_begin = Clock::now();
}
void PerfStats::EndSystemFrame() {
std::lock_guard lock{object_mutex};
auto frame_end = Clock::now();
const auto frame_time = frame_end - frame_begin;
if (current_index < perf_history.size()) {
perf_history[current_index++] =
std::chrono::duration<double, std::milli>(frame_time).count();
}
accumulated_frametime += frame_time;
system_frames += 1;
previous_frame_length = frame_end - previous_frame_end;
previous_frame_end = frame_end;
}
void PerfStats::EndGameFrame() {
std::lock_guard lock{object_mutex};
game_frames += 1;
}
double PerfStats::GetMeanFrametime() const {
std::lock_guard lock{object_mutex};
if (current_index <= IgnoreFrames) {
return 0;
}
const double sum = std::accumulate(perf_history.begin() + IgnoreFrames,
perf_history.begin() + current_index, 0.0);
return sum / static_cast<double>(current_index - IgnoreFrames);
}
PerfStats::Results PerfStats::GetAndResetStats(microseconds current_system_time_us) {
std::lock_guard lock(object_mutex);
const auto now = Clock::now();
// Walltime elapsed since stats were reset
const auto interval = duration_cast<DoubleSecs>(now - reset_point).count();
const auto system_us_per_second = (current_system_time_us - reset_point_system_us) / interval;
Results results{};
results.system_fps = static_cast<double>(system_frames) / interval;
results.game_fps = static_cast<double>(game_frames) / interval;
results.frametime = duration_cast<DoubleSecs>(accumulated_frametime).count() /
static_cast<double>(system_frames);
results.emulation_speed = system_us_per_second.count() / 1'000'000.0;
// Reset counters
reset_point = now;
reset_point_system_us = current_system_time_us;
accumulated_frametime = Clock::duration::zero();
system_frames = 0;
game_frames = 0;
return results;
}
double PerfStats::GetLastFrameTimeScale() const {
std::lock_guard lock{object_mutex};
constexpr double FRAME_LENGTH = 1.0 / GPU::SCREEN_REFRESH_RATE;
return duration_cast<DoubleSecs>(previous_frame_length).count() / FRAME_LENGTH;
}
void FrameLimiter::WaitOnce() {
if (frame_advancing_enabled) {
// Frame advancing is enabled: wait on event instead of doing framelimiting
frame_advance_event.Wait();
frame_advance_event.Reset();
}
}
void FrameLimiter::DoFrameLimiting(microseconds current_system_time_us) {
if (frame_advancing_enabled) {
// Frame advancing is enabled: wait on event instead of doing framelimiting
frame_advance_event.Wait();
frame_advance_event.Reset();
return;
}
auto now = Clock::now();
double sleep_scale = Settings::values.frame_limit.GetValue() / 100.0;
if (Settings::values.frame_limit.GetValue() == 0) {
return;
}
// Max lag caused by slow frames. Shouldn't be more than the length of a frame at the current
// speed percent or it will clamp too much and prevent this from properly limiting to that
// percent. High values means it'll take longer after a slow frame to recover and start limiting
const microseconds max_lag_time_us = duration_cast<microseconds>(
std::chrono::duration<double, std::chrono::microseconds::period>(25ms / sleep_scale));
frame_limiting_delta_err += duration_cast<microseconds>(
std::chrono::duration<double, std::chrono::microseconds::period>(
(current_system_time_us - previous_system_time_us) / sleep_scale));
frame_limiting_delta_err -= duration_cast<microseconds>(now - previous_walltime);
frame_limiting_delta_err =
std::clamp(frame_limiting_delta_err, -max_lag_time_us, max_lag_time_us);
if (frame_limiting_delta_err > microseconds::zero()) {
std::this_thread::sleep_for(frame_limiting_delta_err);
auto now_after_sleep = Clock::now();
frame_limiting_delta_err -= duration_cast<microseconds>(now_after_sleep - now);
now = now_after_sleep;
}
previous_system_time_us = current_system_time_us;
previous_walltime = now;
}
bool FrameLimiter::IsFrameAdvancing() const {
return frame_advancing_enabled;
}
void FrameLimiter::SetFrameAdvancing(bool value) {
const bool was_enabled = frame_advancing_enabled.exchange(value);
if (was_enabled && !value) {
// Set the event to let emulation continue
frame_advance_event.Set();
}
}
void FrameLimiter::AdvanceFrame() {
frame_advance_event.Set();
}
} // namespace Core