Zelda64Recomp/ultramodern/ultramodern.hpp
2023-12-13 02:06:56 -05:00

140 lines
3.9 KiB
C++

#ifndef __ultramodern_HPP__
#define __ultramodern_HPP__
#include <thread>
#include <atomic>
#include <mutex>
#include <algorithm>
#include "ultra64.h"
#if defined(_WIN32)
# define WIN32_LEAN_AND_MEAN
# include <Windows.h>
#elif defined(__ANDROID__)
# include "android/native_window.h"
#elif defined(__linux__)
# include "X11/Xlib.h"
# undef None
# undef Status
# undef LockMask
#endif
struct UltraThreadContext {
std::thread host_thread;
std::atomic_bool running;
std::atomic_bool initialized;
};
namespace ultramodern {
#if defined(_WIN32)
// Native HWND handle to the target window.
struct WindowHandle {
HWND window;
DWORD thread_id = (DWORD)-1;
auto operator<=>(const WindowHandle&) const = default;
};
#elif defined(__ANDROID__)
using WindowHandle = ANativeWindow*;
#elif defined(__linux__)
struct WindowHandle {
Display* display;
Window window;
auto operator<=>(const WindowHandle&) const = default;
};
#endif
// We need a place in rdram to hold the PI handles, so pick an address in extended rdram
constexpr int32_t cart_handle = 0x80800000;
constexpr int32_t flash_handle = (int32_t)(cart_handle + sizeof(OSPiHandle));
constexpr uint32_t save_size = 1024 * 1024 / 8; // Maximum save size, 1Mbit for flash
void preinit(uint8_t* rdram, uint8_t* rom, WindowHandle window_handle);
void save_init();
void init_scheduler();
void init_events(uint8_t* rdram, uint8_t* rom, WindowHandle window_handle);
void init_timers(RDRAM_ARG1);
void set_self_paused(RDRAM_ARG1);
void yield_self(RDRAM_ARG1);
void block_self(RDRAM_ARG1);
void unblock_thread(OSThread* t);
void wait_for_resumed(RDRAM_ARG1);
void swap_to_thread(RDRAM_ARG OSThread *to);
void pause_thread_impl(OSThread *t);
void resume_thread_impl(OSThread* t);
void schedule_running_thread(OSThread *t);
void pause_self(RDRAM_ARG1);
void halt_self(RDRAM_ARG1);
void stop_thread(OSThread *t);
void cleanup_thread(OSThread *t);
enum class ThreadPriority {
Low,
Normal,
High,
VeryHigh,
Critical
};
void set_native_thread_name(const std::string& name);
void set_native_thread_priority(ThreadPriority pri);
PTR(OSThread) this_thread();
void disable_preemption();
void enable_preemption();
void notify_scheduler();
void reprioritize_thread(OSThread *t, OSPri pri);
void set_main_thread();
bool is_game_thread();
void submit_rsp_task(RDRAM_ARG PTR(OSTask) task);
void send_si_message();
uint32_t get_speed_multiplier();
std::chrono::system_clock::time_point get_start();
std::chrono::system_clock::duration time_since_start();
// Audio
void init_audio();
void set_audio_frequency(uint32_t freq);
void queue_audio_buffer(RDRAM_ARG PTR(s16) audio_data, uint32_t byte_count);
uint32_t get_remaining_audio_bytes();
struct audio_callbacks_t {
using queue_samples_t = void(int16_t*, size_t);
using get_samples_remaining_t = size_t();
using set_frequency_t = void(uint32_t);
queue_samples_t* queue_samples;
get_samples_remaining_t* get_frames_remaining;
set_frequency_t* set_frequency;
};
// Input
struct input_callbacks_t {
using poll_input_t = void(void);
using get_input_t = void(uint16_t*, float*, float*);
poll_input_t* poll_input;
get_input_t* get_input;
};
struct gfx_callbacks_t {
using gfx_data_t = void*;
using create_gfx_t = gfx_data_t();
using create_window_t = WindowHandle(gfx_data_t);
using update_gfx_t = void(gfx_data_t);
create_gfx_t* create_gfx;
create_window_t* create_window;
update_gfx_t* update_gfx;
};
void start(WindowHandle window_handle, const audio_callbacks_t& audio_callbacks, const input_callbacks_t& input_callbacks, const gfx_callbacks_t& gfx_callbacks);
void start_game(int game);
bool is_game_started();
void quit();
void join_event_threads();
} // namespace ultramodern
#define MIN(a, b) ((a) < (b) ? (a) : (b))
#define debug_printf(...)
//#define debug_printf(...) printf(__VA_ARGS__);
#endif