use super::cartridge::Cartridge; use super::high_ram::HighRam; use super::instruction::Cycle; use super::interrupt::{Interrupt, InterruptFlag}; use super::joypad::Joypad; use super::ppu::Ppu; use super::serial::Serial; use super::sound::Sound; use super::timer::Timer; use super::work_ram::{VariableWorkRam, WorkRam}; use std::{fs::File, io::Read}; const BOOT_ROM_SIZE: usize = 0x100; #[derive(Debug, Clone)] pub struct Bus { boot: Option<[u8; BOOT_ROM_SIZE]>, // Boot ROM is 256b long cartridge: Option, pub ppu: Ppu, work_ram: WorkRam, var_ram: VariableWorkRam, timer: Timer, int: Interrupt, sound: Sound, high_ram: HighRam, serial: Serial, pub joypad: Joypad, } impl Default for Bus { fn default() -> Self { Self { boot: None, cartridge: None, ppu: Default::default(), work_ram: Default::default(), var_ram: Default::default(), timer: Default::default(), int: Default::default(), sound: Default::default(), high_ram: Default::default(), serial: Default::default(), joypad: Default::default(), } } } impl Bus { pub fn with_boot(path: &str) -> anyhow::Result { let mut file = File::open(path)?; let mut boot_rom = [0u8; 256]; file.read_exact(&mut boot_rom)?; Ok(Self { boot: Some(boot_rom), ..Default::default() }) } pub fn load_cartridge(&mut self, path: &str) -> std::io::Result<()> { self.cartridge = Some(Cartridge::new(path)?); Ok(()) } pub fn rom_title(&self) -> Option<&str> { self.cartridge.as_ref()?.title() } pub fn step(&mut self, cycles: Cycle) { self.ppu.step(cycles); self.timer.step(cycles); self.sound.step(cycles); } } impl Bus { pub fn read_byte(&self, addr: u16) -> u8 { match addr { 0x0000..=0x3FFF => { // 16KB ROM bank 00 if addr < 0x100 { if let Some(boot) = self.boot { return boot[addr as usize]; } } match self.cartridge.as_ref() { Some(cart) => cart.read_byte(addr), None => panic!("Tried to read from a non-existent cartridge"), } } 0x4000..=0x7FFF => match self.cartridge.as_ref() { // 16KB ROM Bank 01 -> NN (switchable via MB) Some(cart) => cart.read_byte(addr), None => panic!("Tried to read from a non-existent cartridge"), }, 0x8000..=0x9FFF => { // 8KB Video RAM self.ppu.read_byte(addr) } 0xA000..=0xBFFF => match self.cartridge.as_ref() { // 8KB External RAM Some(cart) => cart.read_byte(addr), None => panic!("Tried to read from a non-existent cartridge"), }, 0xC000..=0xCFFF => { // 4KB Work RAM Bank 0 self.work_ram.read_byte(addr) } 0xD000..=0xDFFF => { // 4KB Work RAM Bank 1 -> N self.var_ram.read_byte(addr) } 0xE000..=0xFDFF => { // Mirror of 0xC000 to 0xDDFF // ECHO RAM match addr { 0xE000..=0xEFFF => { // 4KB Work RAM Bank 0 self.work_ram.read_byte(addr) } 0xF000..=0xFDFF => { // 4KB Work RAM Bank 1 -> N self.var_ram.read_byte(addr) } _ => unreachable!("{:#06X} was incorrectly handled by ECHO RAM", addr), } } 0xFE00..=0xFE9F => { // Sprite Attribute Table self.ppu.oam.read_byte(addr) } 0xFEA0..=0xFEFF => { // eprintln!("Read from {:#06X}, which is prohibited", addr); // TODO: Properly Emulate what can happen here 0x00 } 0xFF00..=0xFF7F => { // IO Registers match addr { 0xFF00 => self.joypad.status.into(), 0xFF01 => self.serial.next, 0xFF02 => self.serial.control.into(), 0xFF04 => (self.timer.divider >> 8) as u8, 0xFF05 => self.timer.counter, 0xFF06 => self.timer.modulo, 0xFF07 => self.timer.control.into(), 0xFF0F => self.interrupt_flag().into(), 0xFF11 => self.sound.ch1.sound_duty.into(), 0xFF12 => self.sound.ch1.vol_envelope.into(), 0xFF14 => self.sound.ch1.freq_hi.into(), 0xFF24 => self.sound.control.channel.into(), 0xFF25 => self.sound.control.output.into(), 0xFF26 => self.sound.control.status.into(), 0xFF40 => self.ppu.control.into(), 0xFF41 => self.ppu.stat.into(), 0xFF42 => self.ppu.pos.scroll_y, 0xFF43 => self.ppu.pos.scroll_x, 0xFF44 => self.ppu.pos.line_y, 0xFF45 => self.ppu.pos.ly_compare as u8, 0xFF47 => self.ppu.monochrome.bg_palette.into(), 0xFF48 => self.ppu.monochrome.obj_palette_0.into(), 0xFF49 => self.ppu.monochrome.obj_palette_1.into(), 0xFF4A => self.ppu.pos.window_y, 0xFF4B => self.ppu.pos.window_x, 0xFF4D => 0x00, // Reading from this address is useful on the CGB only 0xFF7F => 0x00, // Don't think this address is used for anything _ => unimplemented!("Unable to read {:#06X} in I/O Registers", addr), } } 0xFF80..=0xFFFE => { // High RAM self.high_ram.read_byte(addr) } 0xFFFF => { // Interrupts Enable Register self.int.enable.into() } } } pub fn write_byte(&mut self, addr: u16, byte: u8) { match addr { 0x0000..=0x3FFF => { // 16KB ROM bank 00 match self.cartridge.as_mut() { Some(cart) => cart.write_byte(addr, byte), None => panic!("Tried to write into non-existent cartridge"), } } 0x4000..=0x7FFF => { // 16KB ROM Bank 01 -> NN (switchable via MB) match self.cartridge.as_mut() { Some(cart) => cart.write_byte(addr, byte), None => panic!("Tried to write into non-existent cartridge"), } } 0x8000..=0x9FFF => { // 8KB Video RAM self.ppu.write_byte(addr, byte); } 0xA000..=0xBFFF => { // 8KB External RAM match self.cartridge.as_mut() { Some(cart) => cart.write_byte(addr, byte), None => panic!("Tried to write into non-existent cartridge"), } } 0xC000..=0xCFFF => { // 4KB Work RAM Bank 0 self.work_ram.write_byte(addr, byte); } 0xD000..=0xDFFF => { // 4KB Work RAM Bank 1 -> N self.var_ram.write_byte(addr, byte); } 0xE000..=0xFDFF => { // Mirror of 0xC000 to 0xDDFF // ECHO RAM match addr { 0xE000..=0xEFFF => { // 4KB Work RAM Bank 0 self.work_ram.write_byte(addr, byte); } 0xF000..=0xFDFF => { // 4KB Work RAM Bank 1 -> N self.var_ram.write_byte(addr, byte); } _ => unreachable!("{:#06X} was incorrectly handled by ECHO RAM", addr), } } 0xFE00..=0xFE9F => { // Sprite Attribute Table self.ppu.oam.write_byte(addr, byte); } 0xFEA0..=0xFEFF => { // eprintln!("Wrote {:#04X} to {:#06X}, which is prohibited", byte, addr); // TODO: Properly emulate what can happen here } 0xFF00..=0xFF7F => { // IO Registers match addr { 0xFF00 => self.joypad.status = byte.into(), 0xFF01 => self.serial.next = byte, 0xFF02 => self.serial.control = byte.into(), 0xFF04 => self.timer.divider = 0x00, 0xFF05 => self.timer.counter = byte, 0xFF06 => self.timer.modulo = byte, 0xFF07 => self.timer.control = byte.into(), 0xFF0F => self.set_interrupt_flag(byte), 0xFF11 => self.sound.ch1.sound_duty = byte.into(), 0xFF12 => self.sound.ch1.vol_envelope = byte.into(), 0xFF13 => self.sound.ch1.freq_lo = byte.into(), 0xFF14 => self.sound.ch1.freq_hi = byte.into(), 0xFF24 => self.sound.control.channel = byte.into(), 0xFF25 => self.sound.control.output = byte.into(), 0xFF26 => self.sound.control.status = byte.into(), // FIXME: Should we control which bytes are written to here? 0xFF40 => self.ppu.control = byte.into(), 0xFF41 => self.ppu.stat = byte.into(), 0xFF42 => self.ppu.pos.scroll_y = byte, 0xFF43 => self.ppu.pos.scroll_x = byte, 0xFF44 => self.ppu.pos.line_y = byte, 0xFF45 => { // Update LYC self.ppu.pos.ly_compare = byte; // Update Coincidence Flag if self.ppu.stat.coincidence_int() { let are_equal = self.ppu.pos.line_y == byte; self.ppu.stat.set_coincidence(are_equal); } } 0xFF47 => self.ppu.monochrome.bg_palette = byte.into(), 0xFF48 => self.ppu.monochrome.obj_palette_0 = byte.into(), 0xFF49 => self.ppu.monochrome.obj_palette_1 = byte.into(), 0xFF4A => self.ppu.pos.window_y = byte, 0xFF4B => self.ppu.pos.window_x = byte, 0xFF4D => {} // Writing to this address is useful on the CGB only 0xFF50 => { // Disable Boot ROM if byte != 0 { self.boot = None; } } 0xFF7F => {} // Don't think this address is used for anything _ => unimplemented!("Unable to write to {:#06X} in I/O Registers", addr), }; } 0xFF80..=0xFFFE => { // High RAM self.high_ram.write_byte(addr, byte); } 0xFFFF => { // Interrupts Enable Register self.int.enable = byte.into(); } } } pub fn read_word(&self, addr: u16) -> u16 { (self.read_byte(addr + 1) as u16) << 8 | self.read_byte(addr) as u16 } pub fn write_word(&mut self, addr: u16, word: u16) { self.write_byte(addr + 1, (word >> 8) as u8); self.write_byte(addr, (word & 0x00FF) as u8); } } impl Bus { fn interrupt_flag(&self) -> InterruptFlag { // Read the current interrupt information from the PPU let vblank = self.ppu.int.vblank(); let lcd_stat = self.ppu.int.lcd_stat(); // Read the current interrupt information from the Joypad let joypad = self.joypad.interrupt(); // Read the current interrupt information from the Timer let timer = self.timer.interrupt(); // Copy the Interrupt Flag register 0xFF0F let mut flag = self.int.flag; // Update the flag to have the most accurate information flag.set_vblank(vblank); flag.set_lcd_stat(lcd_stat); flag.set_joypad(joypad); flag.set_timer(timer); flag } fn set_interrupt_flag(&mut self, byte: u8) { // Update the Interrupt register 0xFF0F self.int.flag = byte.into(); let vblank = self.int.flag.vblank(); let lcd_stat = self.int.flag.lcd_stat(); let joypad = self.int.flag.joypad(); let timer = self.int.flag.timer(); // Update the PPU's instance of the following interrupts self.ppu.int.set_vblank(vblank); self.ppu.int.set_lcd_stat(lcd_stat); // Update the Joypad's instance of the following interrupts self.joypad.set_interrupt(joypad); // Update the Timer's instance of the following interrupts self.timer.set_interrupt(timer); } pub fn boot_enabled(&self) -> bool { self.boot.is_some() } }