gb-emu/src/main.rs

384 lines
9.9 KiB
Rust
Raw Normal View History

#![feature(exclusive_range_pattern)]
2023-01-16 12:13:53 +11:00
mod processor;
2023-01-22 12:13:02 +11:00
use clap::{ArgGroup, Parser};
2023-02-03 09:15:30 +11:00
use minifb::{Window, WindowOptions};
2023-01-16 12:13:53 +11:00
use processor::CPU;
2023-01-18 12:46:15 +11:00
use std::{
fs,
io::{self, stdout, Write},
2023-01-22 12:13:02 +11:00
sync::RwLock,
2023-01-18 12:46:15 +11:00
};
use crate::processor::Registers;
2023-02-01 17:18:08 +11:00
2023-01-22 12:13:02 +11:00
#[macro_export]
macro_rules! verbose_println {
($($tts:tt)*) => {
if crate::is_verbose() {
println!($($tts)*);
}
};
}
#[macro_export]
macro_rules! verbose_print {
($($tts:tt)*) => {
if crate::is_verbose() {
print!($($tts)*);
}
};
}
/// Simple program to greet a person
#[derive(Parser, Debug)]
#[command(author, version, about, long_about = None)]
2023-01-22 12:13:02 +11:00
#[command(group(ArgGroup::new("prints").args(["verbose","cycle_count"])))]
struct Args {
/// ROM path
#[arg(short, long)]
rom: String,
2023-01-16 11:34:36 +11:00
/// BootROM path
#[arg(short, long)]
bootrom: String,
2023-01-16 14:43:11 +11:00
/// Just run BootROM
#[arg(long)]
run_bootrom: bool,
2023-01-17 08:58:37 +11:00
2023-01-22 12:13:02 +11:00
/// Verbose print
#[arg(short, long)]
verbose: bool,
/// Show cycle count
#[arg(short, long)]
cycle_count: bool,
2023-01-17 08:58:37 +11:00
/// Step emulation by...
#[arg(long)]
step_by: Option<usize>,
}
2023-01-15 21:05:28 +11:00
type Address = u16;
type ROM = Vec<u8>;
#[allow(dead_code)]
2023-01-16 12:13:53 +11:00
pub struct Memory {
2023-01-18 12:46:15 +11:00
bootrom: ROM,
bootrom_enabled: bool,
rom: ROM,
2023-01-15 20:34:44 +11:00
vram: [u8; 8192],
ram: [u8; 8192],
2023-01-16 19:28:11 +11:00
switchable_ram: [u8; 8192],
cpu_ram: [u8; 128],
2023-01-17 09:39:05 +11:00
oam: [u8; 160],
2023-01-18 13:58:53 +11:00
interrupts: u8,
2023-01-17 09:45:49 +11:00
ime: bool,
2023-02-02 10:54:16 +11:00
ime_scheduled: u8,
2023-01-18 12:46:15 +11:00
io: [u8; 76],
}
impl Memory {
2023-01-18 12:46:15 +11:00
fn init(bootrom: ROM, bootrom_enabled: bool, rom: ROM) -> Self {
2023-01-15 20:34:44 +11:00
Self {
2023-01-18 12:46:15 +11:00
bootrom,
bootrom_enabled,
2023-01-15 20:34:44 +11:00
rom,
vram: [0x0; 8192],
ram: [0x0; 8192],
2023-01-16 19:28:11 +11:00
switchable_ram: [0x0; 8192],
cpu_ram: [0x0; 128],
2023-01-17 09:39:05 +11:00
oam: [0x0; 160],
2023-01-18 13:58:53 +11:00
interrupts: 0x0,
2023-01-17 09:45:49 +11:00
ime: false,
2023-02-02 10:54:16 +11:00
ime_scheduled: 0x0,
io: [0xFF; 76],
2023-01-15 20:34:44 +11:00
}
}
2023-01-15 21:05:28 +11:00
fn get(&self, address: Address) -> u8 {
match address {
0x0..0x8000 => {
// rom access
// todo - switchable rom banks
2023-02-06 14:24:04 +11:00
if self.bootrom_enabled && ((address as usize) < self.bootrom.len()) {
2023-01-18 12:46:15 +11:00
return self.bootrom[address as usize];
} else {
2023-01-22 09:33:18 +11:00
return self.rom[address as usize];
}
}
0x8000..0xA000 => {
2023-01-15 20:34:44 +11:00
return self.vram[(address - 0x8000) as usize];
}
2023-01-22 09:33:18 +11:00
0xA000..0xC000 => 0xFF,
0xC000..0xE000 => {
2023-01-15 20:34:44 +11:00
return self.ram[(address - 0xC000) as usize];
}
0xE000..0xFE00 => {
2023-01-16 11:34:36 +11:00
return self.ram[(address - 0xE000) as usize];
}
0xFE00..0xFEA0 => {
2023-01-17 09:39:05 +11:00
return self.oam[(address - 0xFE00) as usize];
}
0xFEA0..0xFF00 => {
2023-01-18 12:46:15 +11:00
return 0x0;
}
0xFF00..0xFF4C => {
2023-02-06 14:24:04 +11:00
if address == 0xFF00 {
return 0xFF;
}
2023-01-18 12:46:15 +11:00
return self.io[(address - 0xFF00) as usize];
}
0xFF4C..0xFF80 => {
2023-01-18 12:46:15 +11:00
// println!("empty space 2 read");
return 0xFF;
}
0xFF80..0xFFFF => {
2023-01-16 19:28:11 +11:00
return self.cpu_ram[(address - 0xFF80) as usize];
}
0xFFFF => {
2023-01-18 13:58:53 +11:00
return self.interrupts;
}
}
}
fn set(&mut self, address: Address, data: u8) {
2023-02-05 22:37:49 +11:00
// verbose_println!("write addr: {:#X}, data: {:#X}", address, data);
2023-01-22 12:13:02 +11:00
match address {
0x0..0x8000 => {
2023-01-16 16:01:50 +11:00
// change this with MBC code...
2023-01-18 12:46:15 +11:00
// println!("tried to write {:#5X} at {:#X}", data, address);
}
0x8000..0xA000 => {
self.vram[(address - 0x8000) as usize] = data;
}
0xA000..0xC000 => {
// panic!("switchable write");
// self.switchable_ram[(address - 0xA000) as usize] = data;
}
0xC000..0xE000 => {
self.ram[(address - 0xC000) as usize] = data;
}
0xE000..0xFE00 => {
self.ram[(address - 0xE000) as usize] = data;
}
0xFE00..0xFEA0 => {
2023-01-17 09:39:05 +11:00
self.oam[(address - 0xFE00) as usize] = data;
}
0xFEA0..0xFF00 => {
2023-01-18 12:46:15 +11:00
// println!("empty space write: {:#X} to addr {:#X}", data, address);
}
0xFF00..0xFF4C => {
2023-02-05 22:37:49 +11:00
// verbose_print!("writing to addr {:#X}\r", address);
2023-01-18 13:58:53 +11:00
stdout().flush().unwrap();
2023-01-18 12:46:15 +11:00
if address == 0xFF02 && data == 0x81 {
print!("{}", self.get(0xFF01) as char);
stdout().flush().unwrap();
}
self.io[(address - 0xFF00) as usize] = data;
}
2023-02-06 12:37:35 +11:00
0xFF50 => {
self.bootrom_enabled = false;
}
0xFF4C..0xFF50 | 0xFF51..0xFF80 => {
2023-01-18 12:46:15 +11:00
// println!("empty space 2 write: {:#X} to addr {:#X}", data, address);
}
0xFF80..0xFFFF => {
2023-01-16 19:28:11 +11:00
self.cpu_ram[(address - 0xFF80) as usize] = data;
}
2023-01-18 13:58:53 +11:00
0xFFFF => {
2023-01-22 12:13:02 +11:00
verbose_println!("interrupts set to {:#b}", data);
verbose_println!(" / {:#X}", data);
2023-01-18 13:58:53 +11:00
self.interrupts = data;
}
}
}
}
2023-01-22 09:33:18 +11:00
fn cpu_ram_init(cpu: &mut CPU) {
cpu.memory.set(0xFF10, 0x80);
cpu.memory.set(0xFF11, 0xBF);
cpu.memory.set(0xFF12, 0xF3);
cpu.memory.set(0xFF14, 0xBF);
cpu.memory.set(0xFF16, 0x3F);
cpu.memory.set(0xFF19, 0xBF);
cpu.memory.set(0xFF1A, 0x7F);
cpu.memory.set(0xFF1B, 0xFF);
cpu.memory.set(0xFF1C, 0x9F);
cpu.memory.set(0xFF1E, 0xBF);
cpu.memory.set(0xFF20, 0xFF);
cpu.memory.set(0xFF23, 0xBF);
cpu.memory.set(0xFF24, 0x77);
cpu.memory.set(0xFF25, 0xF3);
cpu.memory.set(0xFF26, 0xF1);
cpu.memory.set(0xFF40, 0x91);
cpu.memory.set(0xFF47, 0xFC);
cpu.memory.set(0xFF48, 0xFF);
cpu.memory.set(0xFF49, 0xFF);
}
#[allow(dead_code)]
fn swap_rom_endian(rom: &ROM) -> ROM {
rom.chunks(2)
.map(|l| {
let mut m = l.to_owned();
m.reverse();
m
})
.flatten()
.collect()
}
static mut PAUSE_ENABLED: bool = false;
static mut PAUSE_QUEUED: bool = false;
2023-01-22 12:13:02 +11:00
// static mut VERBOSE: bool = false;
static VERBOSE: RwLock<bool> = RwLock::new(false);
2023-02-03 09:15:30 +11:00
const WIDTH: usize = 160;
const HEIGHT: usize = 144;
2023-02-05 22:56:18 +11:00
const FACTOR: usize = 3;
2023-02-03 09:15:30 +11:00
fn main() {
let args = Args::parse();
2023-01-22 12:13:02 +11:00
{
let mut v = VERBOSE.write().unwrap();
*v = args.verbose;
}
let mut window = Window::new(
2023-02-05 22:56:18 +11:00
"Gameboy",
WIDTH * FACTOR,
HEIGHT * FACTOR,
WindowOptions::default(),
)
.unwrap_or_else(|e| {
panic!("{}", e);
});
2023-02-03 09:15:30 +11:00
2023-02-06 12:44:58 +11:00
window.set_position(500, 50);
2023-02-05 18:46:55 +11:00
window.topmost(true);
2023-02-03 09:15:30 +11:00
let rom: ROM = fs::read(args.rom).expect("Could not load ROM");
2023-01-16 14:43:11 +11:00
let bootrom: ROM = fs::read(args.bootrom).expect("Could not load BootROM");
let mut cpu = CPU::new(Memory::init(bootrom, args.run_bootrom, rom), window);
if !args.run_bootrom {
cpu.reg.pc = 0x0100;
cpu_ram_init(&mut cpu);
}
2023-01-18 12:46:15 +11:00
let mut cycle_num = 0;
let mut instructions_seen = vec![];
2023-02-01 17:18:08 +11:00
let mut last_state = cpu.reg.clone();
2023-01-22 12:13:02 +11:00
let mut next_state = last_state;
2023-01-27 11:12:38 +11:00
verbose_println!("\n\n Begin execution...\n");
2023-01-17 08:58:37 +11:00
match args.step_by {
Some(step_size) => loop {
for _ in 0..step_size {
2023-01-18 12:46:15 +11:00
cycle_num += 1;
2023-01-22 12:13:02 +11:00
if args.cycle_count {
print_cycles(&cycle_num);
}
run_cycle(
&mut cpu,
&mut next_state,
&mut last_state,
&mut instructions_seen,
2023-01-18 12:46:15 +11:00
);
}
print!(
" ...{} cycles - press enter to continue\r",
cycle_num
);
stdout().flush().unwrap();
2023-01-22 12:13:02 +11:00
pause_once();
2023-01-17 08:58:37 +11:00
},
None => loop {
2023-01-18 12:46:15 +11:00
cycle_num += 1;
2023-01-22 12:13:02 +11:00
if args.cycle_count {
print_cycles(&cycle_num);
}
2023-01-22 12:13:02 +11:00
run_cycle(
&mut cpu,
&mut next_state,
&mut last_state,
&mut instructions_seen,
);
2023-01-17 08:58:37 +11:00
},
}
}
2023-01-15 21:05:28 +11:00
2023-01-22 12:13:02 +11:00
fn run_cycle(
cpu: &mut CPU,
2023-02-01 17:18:08 +11:00
next_state: &mut Registers,
last_state: &mut Registers,
2023-01-22 12:13:02 +11:00
instructions_seen: &mut Vec<u8>,
) {
let will_pause;
unsafe {
will_pause = PAUSE_QUEUED.clone();
}
cpu.exec_next();
unsafe {
2023-02-01 17:18:08 +11:00
*next_state = cpu.reg;
2023-01-22 12:13:02 +11:00
if !PAUSE_ENABLED {
2023-02-01 17:18:08 +11:00
if next_state.pc >= 0x100 {
2023-01-22 12:13:02 +11:00
PAUSE_ENABLED = true;
}
}
*last_state = *next_state;
if will_pause {
pause();
}
}
match instructions_seen.contains(&cpu.last_instruction) {
true => {}
false => {
// println!("new instruction enountered: {:#X}", cpu.last_instruction);
instructions_seen.push(cpu.last_instruction);
}
}
}
2023-01-16 11:34:36 +11:00
fn pause() {
unsafe {
if PAUSE_ENABLED {
let line = &mut String::new();
io::stdin().read_line(line).unwrap();
PAUSE_QUEUED = !line.contains("continue");
}
}
2023-01-15 21:05:28 +11:00
}
2023-01-27 11:26:33 +11:00
2023-01-22 12:13:02 +11:00
fn pause_once() {
2023-02-06 12:44:58 +11:00
println!("paused...");
2023-01-22 12:13:02 +11:00
io::stdin().read_line(&mut String::new()).unwrap();
}
2023-01-18 12:46:15 +11:00
fn print_cycles(cycles: &i32) {
2023-02-02 19:01:04 +11:00
if *cycles % 45678 != 0 {
2023-01-18 12:46:15 +11:00
return;
}
let instructions_per_second = 400000;
print!(
"cycle {} - approx {} seconds on real hardware\r",
cycles,
cycles / instructions_per_second
);
stdout().flush().unwrap();
}
2023-01-22 12:13:02 +11:00
fn is_verbose() -> bool {
match VERBOSE.read() {
Ok(v) => *v,
Err(_) => false,
}
}