gb-emu/src/main.rs

#![feature(exclusive_range_pattern)]

mod processor;

use clap::Parser;
use processor::CPU;
use std::{fs, io};

/// Simple program to greet a person
#[derive(Parser, Debug)]
#[command(author, version, about, long_about = None)]
struct Args {
    /// ROM path
    #[arg(short, long)]
    rom: String,

    /// BootROM path
    #[arg(short, long)]
    bootrom: String,

    /// Just run BootROM
    #[arg(long)]
    run_bootrom: bool,

    /// Step emulation by...
    #[arg(long)]
    step_by: Option<usize>,
}

type Address = u16;
type ROM = Vec<u8>;

#[derive(Clone, Copy)]
struct Inner {
    left: u8,
    right: u8,
}

#[derive(Clone, Copy)]
union Register {
    as_u8s: Inner,
    as_u16: u16,
}

pub struct Memory {
    rom: ROM,
    vram: [u8; 8192],
    ram: [u8; 8192],
    switchable_ram: [u8; 8192],
    cpu_ram: [u8; 128],
}

impl Memory {
    fn init(rom: ROM) -> Self {
        Self {
            rom,
            vram: [0x0; 8192],
            ram: [0x0; 8192],
            switchable_ram: [0x0; 8192],
            cpu_ram: [0x0; 128],
        }
    }

    fn get(&self, address: Address) -> u8 {
        match address {
            0x0..0x8000 => {
                // rom access
                // todo - switchable rom banks
                return self.rom[address as usize];
            }
            0x8000..0xA000 => {
                return self.vram[(address - 0x8000) as usize];
            }
            0xA000..0xC000 => {
                return self.switchable_ram[(address - 0xA000) as usize];
            }
            0xC000..0xE000 => {
                return self.ram[(address - 0xC000) as usize];
            }
            0xE000..0xFE00 => {
                return self.ram[(address - 0xE000) as usize];
            }
            0xFE00..0xFEA0 => {
                panic!("sprite attrib memory read");
            }
            0xFEA0..0xFF00 => {
                panic!("empty space read")
            }
            0xFF00..0xFF4C => {
                panic!("I/O read");
            }
            0xFF4C..0xFF80 => {
                panic!("empty space 2 read");
            }
            0xFF80..0xFFFF => {
                return self.cpu_ram[(address - 0xFF80) as usize];
            }
            0xFFFF => {
                panic!("interrupt enable register memory read???");
            }
        }
    }

    fn set(&mut self, address: Address, data: u8) {
        match address {
            0x0..0x8000 => {
                // change this with MBC code...
                println!("tried to write {:#5X} at {:#X}", data, address);
            }
            0x8000..0xA000 => {
                self.vram[(address - 0x8000) as usize] = data;
            }
            0xA000..0xC000 => {
                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 => {
                panic!("sprite attrib memory write");
            }
            0xFEA0..0xFF00 => {
                panic!("empty space write")
            }
            0xFF00..0xFF4C => {
                panic!("I/O write");
            }
            0xFF4C..0xFF80 => {
                panic!("empty space 2 write");
            }
            0xFF80..0xFFFF => {
                self.cpu_ram[(address - 0xFF80) as usize] = data;
            }
            0xFFFF => {
                panic!("interrupt enable register memory write???");
            }
        }
    }
}

pub struct State {
    af: Register,
    bc: Register,
    de: Register,
    hl: Register,
    sp: Register,
    pc: Register,
}

impl Default for State {
    fn default() -> Self {
        // default post-bootrom values
        Self {
            af: Register { as_u16: 0x01B0 },
            bc: Register { as_u16: 0x0013 },
            de: Register { as_u16: 0x00D8 },
            hl: Register { as_u16: 0x014D },
            sp: Register { as_u16: 0xFFFE },
            pc: Register { as_u16: 0x0100 },
        }
    }
}

fn main() {
    let args = Args::parse();

    let rom: ROM = fs::read(args.rom).expect("Could not load ROM");
    let bootrom: ROM = fs::read(args.bootrom).expect("Could not load BootROM");
    let mut state = State::default();
    let run_rom = if args.run_bootrom {
        state.pc = Register { as_u16: 0x0 };
        bootrom
    } else {
        rom
    };

    let mut cpu = CPU {
        memory: Memory::init(run_rom),
        state,
        ime: false,
    };
    match args.step_by {
        Some(step_size) => loop {
            for _ in 0..step_size {
                cpu.exec_next();
            }
            pause();
        },
        None => loop {
            cpu.exec_next()
        },
    }
}

#[allow(dead_code)]
fn pause() {
    io::stdin().read_line(&mut String::new()).unwrap();
}
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`#![feature(exclusive_range_pattern)]`

split processor to module 2023-01-16 12:13:53 +11:00			`mod processor;`

initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`use clap::Parser;`
split processor to module 2023-01-16 12:13:53 +11:00			`use processor::CPU;`
fix unused 2023-01-16 11:35:07 +11:00			`use std::{fs, io};`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00
			`/// Simple program to greet a person`
			`#[derive(Parser, Debug)]`
			`#[command(author, version, about, long_about = None)]`
			`struct Args {`
			`/// ROM path`
			`#[arg(short, long)]`
			`rom: String,`
new register impl & stepping execution 2023-01-16 11:34:36 +11:00
			`/// BootROM path`
			`#[arg(short, long)]`
			`bootrom: String,`
allow booting bootrom 2023-01-16 14:43:11 +11:00
			`/// Just run BootROM`
			`#[arg(long)]`
			`run_bootrom: bool,`
add step by 2023-01-17 08:58:37 +11:00
			`/// Step emulation by...`
			`#[arg(long)]`
			`step_by: Option<usize>,`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`

starting to implement opcodes... 2023-01-15 21:05:28 +11:00			`type Address = u16;`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`type ROM = Vec<u8>;`

new register impl & stepping execution 2023-01-16 11:34:36 +11:00			`#[derive(Clone, Copy)]`
			`struct Inner {`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00			`left: u8,`
fixes etc 2023-01-16 19:28:11 +11:00			`right: u8,`
new register impl & stepping execution 2023-01-16 11:34:36 +11:00			`}`

more opcodes & opcode refactoring 2023-01-16 14:23:06 +11:00			`#[derive(Clone, Copy)]`
new register impl & stepping execution 2023-01-16 11:34:36 +11:00			`union Register {`
			`as_u8s: Inner,`
			`as_u16: u16,`
			`}`

split processor to module 2023-01-16 12:13:53 +11:00			`pub struct Memory {`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`rom: ROM,`
cpu struct & more on memory 2023-01-15 20:34:44 +11:00			`vram: [u8; 8192],`
			`ram: [u8; 8192],`
fixes etc 2023-01-16 19:28:11 +11:00			`switchable_ram: [u8; 8192],`
			`cpu_ram: [u8; 128],`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`

			`impl Memory {`
cpu struct & more on memory 2023-01-15 20:34:44 +11:00			`fn init(rom: ROM) -> Self {`
			`Self {`
			`rom,`
			`vram: [0x0; 8192],`
			`ram: [0x0; 8192],`
fixes etc 2023-01-16 19:28:11 +11:00			`switchable_ram: [0x0; 8192],`
			`cpu_ram: [0x0; 128],`
cpu struct & more on memory 2023-01-15 20:34:44 +11:00			`}`
			`}`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00
starting to implement opcodes... 2023-01-15 21:05:28 +11:00			`fn get(&self, address: Address) -> u8 {`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`match address {`
			`0x0..0x8000 => {`
			`// rom access`
			`// todo - switchable rom banks`
			`return self.rom[address as usize];`
			`}`
			`0x8000..0xA000 => {`
cpu struct & more on memory 2023-01-15 20:34:44 +11:00			`return self.vram[(address - 0x8000) as usize];`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`0xA000..0xC000 => {`
fixes etc 2023-01-16 19:28:11 +11:00			`return self.switchable_ram[(address - 0xA000) as usize];`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`0xC000..0xE000 => {`
cpu struct & more on memory 2023-01-15 20:34:44 +11:00			`return self.ram[(address - 0xC000) as usize];`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`0xE000..0xFE00 => {`
new register impl & stepping execution 2023-01-16 11:34:36 +11:00			`return self.ram[(address - 0xE000) as usize];`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`0xFE00..0xFEA0 => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("sprite attrib memory read");`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`0xFEA0..0xFF00 => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("empty space read")`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`0xFF00..0xFF4C => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("I/O read");`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`0xFF4C..0xFF80 => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("empty space 2 read");`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`0xFF80..0xFFFF => {`
fixes etc 2023-01-16 19:28:11 +11:00			`return self.cpu_ram[(address - 0xFF80) as usize];`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`0xFFFF => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("interrupt enable register memory read???");`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`}`
			`}`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00
			`fn set(&mut self, address: Address, data: u8) {`
			`match address {`
			`0x0..0x8000 => {`
fix write to rom errors... for now 2023-01-16 16:01:50 +11:00			`// change this with MBC code...`
fixes etc 2023-01-16 19:28:11 +11:00			`println!("tried to write {:#5X} at {:#X}", data, address);`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00			`}`
			`0x8000..0xA000 => {`
			`self.vram[(address - 0x8000) as usize] = data;`
			`}`
			`0xA000..0xC000 => {`
fixes etc 2023-01-16 19:28:11 +11:00			`self.switchable_ram[(address - 0xA000) as usize] = data;`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00			`}`
			`0xC000..0xE000 => {`
			`self.ram[(address - 0xC000) as usize] = data;`
			`}`
			`0xE000..0xFE00 => {`
			`self.ram[(address - 0xE000) as usize] = data;`
			`}`
			`0xFE00..0xFEA0 => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("sprite attrib memory write");`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00			`}`
			`0xFEA0..0xFF00 => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("empty space write")`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00			`}`
			`0xFF00..0xFF4C => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("I/O write");`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00			`}`
			`0xFF4C..0xFF80 => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("empty space 2 write");`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00			`}`
			`0xFF80..0xFFFF => {`
fixes etc 2023-01-16 19:28:11 +11:00			`self.cpu_ram[(address - 0xFF80) as usize] = data;`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00			`}`
			`0xFFFF => {`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`panic!("interrupt enable register memory write???");`
memory setting, byte ordering, more opcodes 2023-01-16 12:10:21 +11:00			`}`
			`}`
			`}`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`

split processor to module 2023-01-16 12:13:53 +11:00			`pub struct State {`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`af: Register,`
			`bc: Register,`
			`de: Register,`
			`hl: Register,`
			`sp: Register,`
			`pc: Register,`
			`}`

			`impl Default for State {`
			`fn default() -> Self {`
cpu struct & more on memory 2023-01-15 20:34:44 +11:00			`// default post-bootrom values`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`Self {`
new register impl & stepping execution 2023-01-16 11:34:36 +11:00			`af: Register { as_u16: 0x01B0 },`
			`bc: Register { as_u16: 0x0013 },`
			`de: Register { as_u16: 0x00D8 },`
			`hl: Register { as_u16: 0x014D },`
			`sp: Register { as_u16: 0xFFFE },`
			`pc: Register { as_u16: 0x0100 },`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`}`
			`}`

			`fn main() {`
			`let args = Args::parse();`

			`let rom: ROM = fs::read(args.rom).expect("Could not load ROM");`
allow booting bootrom 2023-01-16 14:43:11 +11:00			`let bootrom: ROM = fs::read(args.bootrom).expect("Could not load BootROM");`
			`let mut state = State::default();`
			`let run_rom = if args.run_bootrom {`
			`state.pc = Register { as_u16: 0x0 };`
			`bootrom`
			`} else {`
			`rom`
			`};`

cpu struct & more on memory 2023-01-15 20:34:44 +11:00			`let mut cpu = CPU {`
allow booting bootrom 2023-01-16 14:43:11 +11:00			`memory: Memory::init(run_rom),`
			`state,`
ime & daa (maybe) instruction 2023-01-17 09:30:42 +11:00			`ime: false,`
cpu struct & more on memory 2023-01-15 20:34:44 +11:00			`};`
add step by 2023-01-17 08:58:37 +11:00			`match args.step_by {`
			`Some(step_size) => loop {`
			`for _ in 0..step_size {`
			`cpu.exec_next();`
			`}`
			`pause();`
			`},`
			`None => loop {`
			`cpu.exec_next()`
			`},`
initial: memory and cpu state, rom load path 2023-01-15 19:53:15 +11:00			`}`
			`}`
starting to implement opcodes... 2023-01-15 21:05:28 +11:00
ld_immediate_word 2023-01-16 11:46:00 +11:00			`#[allow(dead_code)]`
new register impl & stepping execution 2023-01-16 11:34:36 +11:00			`fn pause() {`
			`io::stdin().read_line(&mut String::new()).unwrap();`
starting to implement opcodes... 2023-01-15 21:05:28 +11:00			`}`