use super::cartridge::Cartridge; use super::ppu::PPU; #[derive(Debug, Clone)] pub struct Bus { boot: Option<[u8; 256]>, // Boot ROM is 256b long cartridge: Option, ppu: PPU, } impl Default for Bus { fn default() -> Self { Self { boot: Some(include_bytes!("../bin/DMG_ROM.bin").to_owned()), cartridge: None, ppu: Default::default(), } } } impl Bus { pub fn with_boot() -> Self { Default::default() } pub fn without_boot() -> Self { Self { boot: None, ..Default::default() } } pub fn load_cartridge(&mut self, path: &str) { self.cartridge = Some(Cartridge::new(path).unwrap()); } } impl Bus { pub fn read_byte(&self, addr: u16) -> u8 { match addr { 0x0000..=0x3FFF => { // 16KB ROM bank 00 if addr <= 0x00FF && self.boot.is_some() { let boot = self.boot.unwrap(); boot[addr as usize] } else { match &self.cartridge { Some(cart) => cart.read_byte(addr), None => panic!("Tried to read from a non-existant cartridge"), } } } 0x4000..=0x7FFF => match &self.cartridge { // 16KB ROM Bank 01 -> NN (switchable via MB) Some(cart) => cart.read_byte(addr), None => panic!("Tried to read from a non-existant cartridge"), }, 0x8000..=0x9FFF => { // 8KB Video RAM self.ppu.vram[(addr - 0x8000) as usize] } 0xA000..=0xBFFF => { // 8KB External RAM unimplemented!("Unable to read {:#06X} in Extermal RAM", addr); } 0xC000..=0xCFFF => { // 4KB Work RAM Bank 0 unimplemented!("Unable to read {:#06X} in Work RAM Bank 0", addr); } 0xD000..=0xDFFF => { // 4KB Work RAM Bank 1 -> N unimplemented!("Unable to read {:#06X} in Work RAM Bank N", addr); } 0xE000..=0xFDFF => { // Mirror of 0xC000 to 0xDDFF unimplemented!("Unable to read {:#06X} in Restricted Mirror", addr); } 0xFE00..=0xFE9F => { // Sprite Attrbute Table unimplemented!("Unable to read {:#06X} in the Sprite Attribute Table", addr); } 0xFEA0..=0xFEFF => unimplemented!("{:#06X} is not allowed to be used", addr), 0xFF00..=0xFF7F => { // IO Registers unimplemented!("Unable to read {:#06X} in I/O Registers", addr); } 0xFF80..=0xFFFE => { // High RAM unimplemented!("Unable to read {:#06X} in High RAM", addr); } 0xFFFF => { // Interupts Enable Register unimplemented!("Unable to read IE Register {:#06X} ", addr); } } } pub fn write_byte(&mut self, addr: u16, byte: u8) { match addr { 0x0000..=0x3FFF => { // 16KB ROM bank 00 panic!("Tried to write to {:#06X} in ROM Bank 00", addr); } 0x4000..=0x7FFF => { // 16KB ROM Bank 01 -> NN (switchable via MB) panic!("Tried to write to {:#06X} in ROM Bank 01 -> NN", addr); } 0x8000..=0x9FFF => { // 8KB Video RAM self.ppu.vram[(addr - 0x8000) as usize] = byte; } 0xA000..=0xBFFF => { // 8KB External RAM unimplemented!("Unable to write to {:#06X} in Extermal RAM", addr); } 0xC000..=0xCFFF => { // 4KB Work RAM Bank 0 unimplemented!("Unable to write to {:#06X} in Work RAM Bank 0", addr); } 0xD000..=0xDFFF => { // 4KB Work RAM Bank 1 -> N unimplemented!("Unable to write to {:#06X} in Work RAM Bank N", addr); } 0xE000..=0xFDFF => { // Mirror of 0xC000 to 0xDDFF unimplemented!("Unable to write to {:#06X} in Restricted Mirror", addr); } 0xFE00..=0xFE9F => { // Sprite Attrbute Table unimplemented!( "Unable to write to {:#06X} in the Sprite Attribute Table", addr ); } 0xFEA0..=0xFEFF => unimplemented!("{:#06X} is not allowed to be used", addr), 0xFF00..=0xFF7F => { // IO Registers unimplemented!("Unable to write to {:#06X} in I/O Registers", addr); } 0xFF80..=0xFFFE => { // High RAM unimplemented!("Unable to write to {:#06X} in High RAM", addr); } 0xFFFF => { // Interupts Enable Register unimplemented!("Unable to write to IE Register {:#06X} ", addr); } } } 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); } }