Zelda64Recomp/src/main/main.cpp

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#include <cstdio>
#include <cassert>
#include <unordered_map>
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#include <vector>
#include <array>
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#include <filesystem>
#include <numeric>
#include <stdexcept>
#include "../../ultramodern/ultra64.h"
#include "../../ultramodern/ultramodern.hpp"
#define SDL_MAIN_HANDLED
#ifdef _WIN32
#include "SDL.h"
#else
#include "SDL2/SDL.h"
#include "SDL2/SDL_syswm.h"
#endif
#include "recomp_ui.h"
#include "recomp_input.h"
#include "recomp_config.h"
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#include "recomp_game.h"
#ifdef _WIN32
#define WIN32_LEAN_AND_MEAN
#include <Windows.h>
#include "SDL_syswm.h"
#endif
extern "C" void init();
/*extern "C"*/ void start(ultramodern::WindowHandle window_handle, const ultramodern::audio_callbacks_t* audio_callbacks, const ultramodern::input_callbacks_t* input_callbacks);
template<typename... Ts>
void exit_error(const char* str, Ts ...args) {
// TODO pop up an error
((void)fprintf(stderr, str, args), ...);
assert(false);
std::quick_exit(EXIT_FAILURE);
}
ultramodern::gfx_callbacks_t::gfx_data_t create_gfx() {
SDL_SetHint(SDL_HINT_WINDOWS_DPI_AWARENESS, "permonitorv2");
SDL_SetHint(SDL_HINT_GAMECONTROLLER_USE_BUTTON_LABELS, "0");
if (SDL_Init(SDL_INIT_VIDEO | SDL_INIT_GAMECONTROLLER) > 0) {
exit_error("Failed to initialize SDL2: %s\n", SDL_GetError());
}
return {};
}
SDL_Window* window;
ultramodern::WindowHandle create_window(ultramodern::gfx_callbacks_t::gfx_data_t) {
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window = SDL_CreateWindow("Zelda 64: Recompiled", SDL_WINDOWPOS_CENTERED, SDL_WINDOWPOS_CENTERED, 1600, 960, SDL_WINDOW_RESIZABLE );
if (window == nullptr) {
exit_error("Failed to create window: %s\n", SDL_GetError());
}
SDL_SysWMinfo wmInfo;
SDL_VERSION(&wmInfo.version);
SDL_GetWindowWMInfo(window, &wmInfo);
#if defined(_WIN32)
return ultramodern::WindowHandle{ wmInfo.info.win.window, GetCurrentThreadId() };
#elif defined(__ANDROID__)
static_assert(false && "Unimplemented");
#elif defined(__linux__)
return ultramodern::WindowHandle{ wmInfo.info.x11.display, wmInfo.info.x11.window };
#else
static_assert(false && "Unimplemented");
#endif
}
void update_gfx(void*) {
recomp::handle_events();
}
static SDL_AudioCVT audio_convert;
static SDL_AudioDeviceID audio_device = 0;
// Samples per channel per second.
static uint32_t sample_rate = 48000;
static uint32_t output_sample_rate = 48000;
// Channel count.
constexpr uint32_t input_channels = 2;
static uint32_t output_channels = 2;
// Terminology: a frame is a collection of samples for each channel. e.g. 2 input samples is one input frame. This is unrelated to graphical frames.
// Number of frames to duplicate for fixing interpolation at the start and end of a chunk.
constexpr uint32_t duplicated_input_frames = 4;
// The number of output frames to skip for playback (to avoid playing duplicate inputs twice).
static uint32_t discarded_output_frames;
void queue_samples(int16_t* audio_data, size_t sample_count) {
// Buffer for holding the output of swapping the audio channels. This is reused across
// calls to reduce runtime allocations.
static std::vector<float> swap_buffer;
static std::array<float, duplicated_input_frames * input_channels> duplicated_sample_buffer;
// Make sure the swap buffer is large enough to hold the audio data, including any extra space needed for resampling.
size_t resampled_sample_count = sample_count + duplicated_input_frames * input_channels;
size_t max_sample_count = std::max(resampled_sample_count, resampled_sample_count * audio_convert.len_mult);
if (max_sample_count > swap_buffer.size()) {
swap_buffer.resize(max_sample_count);
}
// Copy the duplicated frames from last chunk into this chunk
for (size_t i = 0; i < duplicated_input_frames * input_channels; i++) {
swap_buffer[i] = duplicated_sample_buffer[i];
}
// Convert the audio from 16-bit values to floats and swap the audio channels into the
// swap buffer to correct for the address xor caused by endianness handling.
for (size_t i = 0; i < sample_count; i += input_channels) {
swap_buffer[i + 0 + duplicated_input_frames * input_channels] = audio_data[i + 1] * (0.5f / 32768.0f);
swap_buffer[i + 1 + duplicated_input_frames * input_channels] = audio_data[i + 0] * (0.5f / 32768.0f);
}
// TODO handle cases where a chunk is smaller than the duplicated frame count.
assert(sample_count > duplicated_input_frames * input_channels);
// Copy the last converted samples into the duplicated sample buffer to reuse in resampling the next queued chunk.
for (size_t i = 0; i < duplicated_input_frames * input_channels; i++) {
duplicated_sample_buffer[i] = swap_buffer[i + sample_count];
}
audio_convert.buf = reinterpret_cast<Uint8*>(swap_buffer.data());
audio_convert.len = (sample_count + duplicated_input_frames * input_channels) * sizeof(swap_buffer[0]);
int ret = SDL_ConvertAudio(&audio_convert);
if (ret < 0) {
printf("Error using SDL audio converter: %s\n", SDL_GetError());
throw std::runtime_error("Error using SDL audio converter");
}
// Queue the swapped audio data.
// Offset the data start by only half the discarded frame count as the other half of the discarded frames are at the end of the buffer.
SDL_QueueAudio(audio_device, swap_buffer.data() + output_channels * discarded_output_frames / 2,
audio_convert.len_cvt - output_channels * discarded_output_frames * sizeof(swap_buffer[0]));
}
constexpr uint32_t bytes_per_frame = input_channels * sizeof(float);
size_t get_frames_remaining() {
constexpr float buffer_offset_frames = 1.0f;
// Get the number of remaining buffered audio bytes.
uint32_t buffered_byte_count = SDL_GetQueuedAudioSize(audio_device);
// Scale the byte count based on the ratio of sample rates and channel counts.
buffered_byte_count = buffered_byte_count * 2 * sample_rate / output_sample_rate / output_channels;
// Adjust the reported count to be some number of refreshes in the future, which helps ensure that
// there are enough samples even if the audio thread experiences a small amount of lag. This prevents
// audio popping on games that use the buffered audio byte count to determine how many samples
// to generate.
uint32_t frames_per_vi = (sample_rate / 60);
if (buffered_byte_count > (buffer_offset_frames * bytes_per_frame * frames_per_vi)) {
buffered_byte_count -= (buffer_offset_frames * bytes_per_frame * frames_per_vi);
}
else {
buffered_byte_count = 0;
}
// Convert from byte count to sample count.
return buffered_byte_count / bytes_per_frame;
}
void update_audio_converter() {
int ret = SDL_BuildAudioCVT(&audio_convert, AUDIO_F32, input_channels, sample_rate, AUDIO_F32, output_channels, output_sample_rate);
if (ret < 0) {
printf("Error creating SDL audio converter: %s\n", SDL_GetError());
throw std::runtime_error("Error creating SDL audio converter");
}
// Calculate the number of samples to discard based on the sample rate ratio and the duplicate frame count.
discarded_output_frames = duplicated_input_frames * output_sample_rate / sample_rate;
}
void set_frequency(uint32_t freq) {
sample_rate = freq;
update_audio_converter();
}
void reset_audio(uint32_t output_freq) {
SDL_AudioSpec spec_desired{
.freq = (int)output_freq,
.format = AUDIO_F32,
.channels = (Uint8)output_channels,
.silence = 0, // calculated
.samples = 0x100, // Fairly small sample count to reduce the latency of internal buffering
.padding = 0, // unused
.size = 0, // calculated
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.callback = nullptr,
.userdata = nullptr
};
audio_device = SDL_OpenAudioDevice(nullptr, false, &spec_desired, nullptr, 0);
if (audio_device == 0) {
exit_error("SDL error opening audio device: %s\n", SDL_GetError());
}
SDL_PauseAudioDevice(audio_device, 0);
output_sample_rate = output_freq;
update_audio_converter();
}
int main(int argc, char** argv) {
#ifdef _WIN32
// Set up console output to accept UTF-8 on windows
SetConsoleOutputCP(CP_UTF8);
// Change to a font that supports Japanese characters
CONSOLE_FONT_INFOEX cfi;
cfi.cbSize = sizeof cfi;
cfi.nFont = 0;
cfi.dwFontSize.X = 0;
cfi.dwFontSize.Y = 16;
cfi.FontFamily = FF_DONTCARE;
cfi.FontWeight = FW_NORMAL;
wcscpy_s(cfi.FaceName, L"NSimSun");
SetCurrentConsoleFontEx(GetStdHandle(STD_OUTPUT_HANDLE), FALSE, &cfi);
#else
std::setlocale(LC_ALL, "en_US.UTF-8");
#endif
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//printf("Current dir: %ls\n", std::filesystem::current_path().c_str());
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// Initialize SDL audio and set the output frequency.
SDL_InitSubSystem(SDL_INIT_AUDIO);
reset_audio(48000);
recomp::load_config();
ultramodern::gfx_callbacks_t gfx_callbacks{
.create_gfx = create_gfx,
.create_window = create_window,
.update_gfx = update_gfx,
};
ultramodern::audio_callbacks_t audio_callbacks{
.queue_samples = queue_samples,
.get_frames_remaining = get_frames_remaining,
.set_frequency = set_frequency,
};
ultramodern::input_callbacks_t input_callbacks{
.poll_input = recomp::poll_inputs,
.get_input = recomp::get_n64_input,
.set_rumble = recomp::set_rumble,
};
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recomp::start({}, audio_callbacks, input_callbacks, gfx_callbacks);
return EXIT_SUCCESS;
}