use std::cell::RefCell; use std::rc::Rc; use super::arm7tdmi::{Addr, Bus}; use super::gba::IoDevices; use super::keypad; use super::sysbus::BoxedMemory; pub mod consts { use super::*; pub const IO_BASE: Addr = 0x0400_0000; // LCD I/O Registers pub const REG_DISPCNT: Addr = IO_BASE + 0x_0000; // 2 R/W LCD Control pub const REG_DISPSTAT: Addr = IO_BASE + 0x_0004; // 2 R/W General LCD Status (STAT,LYC) pub const REG_VCOUNT: Addr = IO_BASE + 0x_0006; // 2 R Vertical Counter (LY) pub const REG_BG0CNT: Addr = IO_BASE + 0x_0008; // 2 R/W BG0 Control pub const REG_BG1CNT: Addr = IO_BASE + 0x_000A; // 2 R/W BG1 Control pub const REG_BG2CNT: Addr = IO_BASE + 0x_000C; // 2 R/W BG2 Control pub const REG_BG3CNT: Addr = IO_BASE + 0x_000E; // 2 R/W BG3 Control pub const REG_BG0HOFS: Addr = IO_BASE + 0x_0010; // 2 W BG0 X-Offset pub const REG_BG0VOFS: Addr = IO_BASE + 0x_0012; // 2 W BG0 Y-Offset pub const REG_BG1HOFS: Addr = IO_BASE + 0x_0014; // 2 W BG1 X-Offset pub const REG_BG1VOFS: Addr = IO_BASE + 0x_0016; // 2 W BG1 Y-Offset pub const REG_BG2HOFS: Addr = IO_BASE + 0x_0018; // 2 W BG2 X-Offset pub const REG_BG2VOFS: Addr = IO_BASE + 0x_001A; // 2 W BG2 Y-Offset pub const REG_BG3HOFS: Addr = IO_BASE + 0x_001C; // 2 W BG3 X-Offset pub const REG_BG3VOFS: Addr = IO_BASE + 0x_001E; // 2 W BG3 Y-Offset pub const REG_BG2PA: Addr = IO_BASE + 0x_0020; // 2 W BG2 Rotation/Scaling Parameter A (dx) pub const REG_BG2PB: Addr = IO_BASE + 0x_0022; // 2 W BG2 Rotation/Scaling Parameter B (dmx) pub const REG_BG2PC: Addr = IO_BASE + 0x_0024; // 2 W BG2 Rotation/Scaling Parameter C (dy) pub const REG_BG2PD: Addr = IO_BASE + 0x_0026; // 2 W BG2 Rotation/Scaling Parameter D (dmy) pub const REG_BG2X_L: Addr = IO_BASE + 0x_0028; // 4 W BG2 Reference Point X-Coordinate, lower 16 bit pub const REG_BG2X_H: Addr = IO_BASE + 0x_002A; // 4 W BG2 Reference Point X-Coordinate, upper 16 bit pub const REG_BG2Y_L: Addr = IO_BASE + 0x_002C; // 4 W BG2 Reference Point Y-Coordinate, lower 16 bit pub const REG_BG2Y_H: Addr = IO_BASE + 0x_002E; // 4 W BG2 Reference Point Y-Coordinate, upper 16 bit pub const REG_BG3PA: Addr = IO_BASE + 0x_0030; // 2 W BG3 Rotation/Scaling Parameter A (dx) pub const REG_BG3PB: Addr = IO_BASE + 0x_0032; // 2 W BG3 Rotation/Scaling Parameter B (dmx) pub const REG_BG3PC: Addr = IO_BASE + 0x_0034; // 2 W BG3 Rotation/Scaling Parameter C (dy) pub const REG_BG3PD: Addr = IO_BASE + 0x_0036; // 2 W BG3 Rotation/Scaling Parameter D (dmy) pub const REG_BG3X_L: Addr = IO_BASE + 0x_0038; // 4 W BG3 Reference Point X-Coordinate, lower 16 bit pub const REG_BG3X_H: Addr = IO_BASE + 0x_003A; // 4 W BG3 Reference Point X-Coordinate, upper 16 bit pub const REG_BG3Y_L: Addr = IO_BASE + 0x_003C; // 4 W BG3 Reference Point Y-Coordinate, lower 16 bit pub const REG_BG3Y_H: Addr = IO_BASE + 0x_003E; // 4 W BG3 Reference Point Y-Coordinate, upper 16 bit pub const REG_WIN0H: Addr = IO_BASE + 0x_0040; // 2 W Window 0 Horizontal Dimensions pub const REG_WIN1H: Addr = IO_BASE + 0x_0042; // 2 W Window 1 Horizontal Dimensions pub const REG_WIN0V: Addr = IO_BASE + 0x_0044; // 2 W Window 0 Vertical Dimensions pub const REG_WIN1V: Addr = IO_BASE + 0x_0046; // 2 W Window 1 Vertical Dimensions pub const REG_WININ: Addr = IO_BASE + 0x_0048; // 2 R/W Inside of Window 0 and 1 pub const REG_WINOUT: Addr = IO_BASE + 0x_004A; // 2 R/W Inside of OBJ Window & Outside of Windows pub const REG_MOSAIC: Addr = IO_BASE + 0x_004C; // 2 W Mosaic Size pub const REG_BLDCNT: Addr = IO_BASE + 0x_0050; // 2 R/W Color Special Effects Selection pub const REG_BLDALPHA: Addr = IO_BASE + 0x_0052; // 2 R/W Alpha Blending Coefficients pub const REG_BLDY: Addr = IO_BASE + 0x_0054; // 2 W Brightness (Fade-In/Out) Coefficient // Sound Registers pub const REG_SOUND1CNT_L: Addr = IO_BASE + 0x_0060; // 2 R/W Channel 1 Sweep register (NR10) pub const REG_SOUND1CNT_H: Addr = IO_BASE + 0x_0062; // 2 R/W Channel 1 Duty/Length/Envelope (NR11, NR12) pub const REG_SOUND1CNT_X: Addr = IO_BASE + 0x_0064; // 2 R/W Channel 1 Frequency/Control (NR13, NR14) pub const REG_SOUND2CNT_L: Addr = IO_BASE + 0x_0068; // 2 R/W Channel 2 Duty/Length/Envelope (NR21, NR22) pub const REG_SOUND2CNT_H: Addr = IO_BASE + 0x_006C; // 2 R/W Channel 2 Frequency/Control (NR23, NR24) pub const REG_SOUND3CNT_L: Addr = IO_BASE + 0x_0070; // 2 R/W Channel 3 Stop/Wave RAM select (NR30) pub const REG_SOUND3CNT_H: Addr = IO_BASE + 0x_0072; // 2 R/W Channel 3 Length/Volume (NR31, NR32) pub const REG_SOUND3CNT_X: Addr = IO_BASE + 0x_0074; // 2 R/W Channel 3 Frequency/Control (NR33, NR34) pub const REG_SOUND4CNT_L: Addr = IO_BASE + 0x_0078; // 2 R/W Channel 4 Length/Envelope (NR41, NR42) pub const REG_SOUND4CNT_H: Addr = IO_BASE + 0x_007C; // 2 R/W Channel 4 Frequency/Control (NR43, NR44) pub const REG_SOUNDCNT_L: Addr = IO_BASE + 0x_0080; // 2 R/W Control Stereo/Volume/Enable (NR50, NR51) pub const REG_SOUNDCNT_H: Addr = IO_BASE + 0x_0082; // 2 R/W Control Mixing/DMA Control pub const REG_SOUNDCNT_X: Addr = IO_BASE + 0x_0084; // 2 R/W Control Sound on/off (NR52) pub const REG_SOUNDBIAS: Addr = IO_BASE + 0x_0088; // 2 BIOS Sound PWM Control pub const REG_WAVE_RAM: Addr = IO_BASE + 0x_0090; // Channel 3 Wave Pattern RAM (2 banks!!) pub const REG_FIFO_A: Addr = IO_BASE + 0x_00A0; // 4 W Channel A FIFO, Data 0-3 pub const REG_FIFO_B: Addr = IO_BASE + 0x_00A4; // 4 W Channel B FIFO, Data 0-3 // DMA Transfer Channels pub const REG_DMA0SAD: Addr = IO_BASE + 0x_00B0; // 4 W DMA 0 Source Address pub const REG_DMA0DAD: Addr = IO_BASE + 0x_00B4; // 4 W DMA 0 Destination Address pub const REG_DMA0CNT_L: Addr = IO_BASE + 0x_00B8; // 2 W DMA 0 Word Count pub const REG_DMA0CNT_H: Addr = IO_BASE + 0x_00BA; // 2 R/W DMA 0 Control pub const REG_DMA1SAD: Addr = IO_BASE + 0x_00BC; // 4 W DMA 1 Source Address pub const REG_DMA1DAD: Addr = IO_BASE + 0x_00C0; // 4 W DMA 1 Destination Address pub const REG_DMA1CNT_L: Addr = IO_BASE + 0x_00C4; // 2 W DMA 1 Word Count pub const REG_DMA1CNT_H: Addr = IO_BASE + 0x_00C6; // 2 R/W DMA 1 Control pub const REG_DMA2SAD: Addr = IO_BASE + 0x_00C8; // 4 W DMA 2 Source Address pub const REG_DMA2DAD: Addr = IO_BASE + 0x_00CC; // 4 W DMA 2 Destination Address pub const REG_DMA2CNT_L: Addr = IO_BASE + 0x_00D0; // 2 W DMA 2 Word Count pub const REG_DMA2CNT_H: Addr = IO_BASE + 0x_00D2; // 2 R/W DMA 2 Control pub const REG_DMA3SAD: Addr = IO_BASE + 0x_00D4; // 4 W DMA 3 Source Address pub const REG_DMA3DAD: Addr = IO_BASE + 0x_00D8; // 4 W DMA 3 Destination Address pub const REG_DMA3CNT_L: Addr = IO_BASE + 0x_00DC; // 2 W DMA 3 Word Count pub const REG_DMA3CNT_H: Addr = IO_BASE + 0x_00DE; // 2 R/W DMA 3 Control // Timer Registers pub const REG_TM0CNT_L: Addr = IO_BASE + 0x_0100; // 2 R/W Timer 0 Counter/Reload pub const REG_TM0CNT_H: Addr = IO_BASE + 0x_0102; // 2 R/W Timer 0 Control pub const REG_TM1CNT_L: Addr = IO_BASE + 0x_0104; // 2 R/W Timer 1 Counter/Reload pub const REG_TM1CNT_H: Addr = IO_BASE + 0x_0106; // 2 R/W Timer 1 Control pub const REG_TM2CNT_L: Addr = IO_BASE + 0x_0108; // 2 R/W Timer 2 Counter/Reload pub const REG_TM2CNT_H: Addr = IO_BASE + 0x_010A; // 2 R/W Timer 2 Control pub const REG_TM3CNT_L: Addr = IO_BASE + 0x_010C; // 2 R/W Timer 3 Counter/Reload pub const REG_TM3CNT_H: Addr = IO_BASE + 0x_010E; // 2 R/W Timer 3 Control // Serial Communication (1) pub const REG_SIODATA32: Addr = IO_BASE + 0x_0120; // 4 R/W SIO Data (Normal-32bit Mode; shared with below) pub const REG_SIOMULTI0: Addr = IO_BASE + 0x_0120; // 2 R/W SIO Data 0 (Parent) (Multi-Player Mode) pub const REG_SIOMULTI1: Addr = IO_BASE + 0x_0122; // 2 R/W SIO Data 1 (1st Child) (Multi-Player Mode) pub const REG_SIOMULTI2: Addr = IO_BASE + 0x_0124; // 2 R/W SIO Data 2 (2nd Child) (Multi-Player Mode) pub const REG_SIOMULTI3: Addr = IO_BASE + 0x_0126; // 2 R/W SIO Data 3 (3rd Child) (Multi-Player Mode) pub const REG_SIOCNT: Addr = IO_BASE + 0x_0128; // 2 R/W SIO Control Register pub const REG_SIOMLT_SEND: Addr = IO_BASE + 0x_012A; // 2 R/W SIO Data (Local of MultiPlayer; shared below) pub const REG_SIODATA8: Addr = IO_BASE + 0x_012A; // 2 R/W SIO Data (Normal-8bit and UART Mode) // Keypad Input pub const REG_KEYINPUT: Addr = IO_BASE + 0x_0130; // 2 R Key Status pub const REG_KEYCNT: Addr = IO_BASE + 0x_0132; // 2 R/W Key Interrupt Control // Serial Communication (2) pub const REG_RCNT: Addr = IO_BASE + 0x_0134; // 2 R/W SIO Mode Select/General Purpose Data pub const REG_IR: Addr = IO_BASE + 0x_0136; // - - Ancient - Infrared Register (Prototypes only) pub const REG_JOYCNT: Addr = IO_BASE + 0x_0140; // 2 R/W SIO JOY Bus Control pub const REG_JOY_RECV: Addr = IO_BASE + 0x_0150; // 4 R/W SIO JOY Bus Receive Data pub const REG_JOY_TRANS: Addr = IO_BASE + 0x_0154; // 4 R/W SIO JOY Bus Transmit Data pub const REG_JOYSTAT: Addr = IO_BASE + 0x_0158; // 2 R/? SIO JOY Bus Receive Status // Interrupt, Waitstate, and Power-Down Control pub const REG_IE: Addr = IO_BASE + 0x_0200; // 2 R/W Interrupt Enable Register pub const REG_IF: Addr = IO_BASE + 0x_0202; // 2 R/W Interrupt Request Flags / IRQ Acknowledge pub const REG_WAITCNT: Addr = IO_BASE + 0x_0204; // 2 R/W Game Pak Waitstate Control pub const REG_IME: Addr = IO_BASE + 0x_0208; // 2 R/W Interrupt Master Enable Register pub const REG_POSTFLG: Addr = IO_BASE + 0x_0300; // 1 R/W Undocumented - Post Boot Flag pub const REG_HALTCNT: Addr = IO_BASE + 0x_0301; // 1 W Undocumented - Power Down Control } use consts::*; #[derive(Debug)] pub struct IoRegs { mem: BoxedMemory, pub io: Rc>, pub keyinput: u16, pub post_boot_flag: bool, pub waitcnt: WaitControl, // TODO also implement 4000800 } impl IoRegs { pub fn new(io: Rc>) -> IoRegs { IoRegs { mem: BoxedMemory::new(vec![0; 0x400].into_boxed_slice(), 0x3ff), io: io, post_boot_flag: false, keyinput: keypad::KEYINPUT_ALL_RELEASED, waitcnt: WaitControl(0), } } } impl Bus for IoRegs { fn read_32(&self, addr: Addr) -> u32 { (self.read_16(addr + 2) as u32) << 16 | (self.read_16(addr) as u32) } fn read_16(&self, addr: Addr) -> u16 { let io = self.io.borrow(); match addr + IO_BASE { REG_DISPCNT => io.gpu.dispcnt.0, REG_DISPSTAT => io.gpu.dispstat.0, REG_VCOUNT => io.gpu.current_scanline as u16, REG_BG0CNT => io.gpu.bg[0].bgcnt.0, REG_BG1CNT => io.gpu.bg[1].bgcnt.0, REG_BG2CNT => io.gpu.bg[2].bgcnt.0, REG_BG3CNT => io.gpu.bg[3].bgcnt.0, REG_WIN0H => io.gpu.win0h, REG_WIN1H => io.gpu.win1h, REG_WIN0V => io.gpu.win0v, REG_WIN1V => io.gpu.win1v, REG_WININ => io.gpu.winin, REG_WINOUT => io.gpu.winout, REG_BLDCNT => io.gpu.bldcnt.0, REG_BLDALPHA => io.gpu.bldalpha.0, REG_IME => io.intc.interrupt_master_enable as u16, REG_IE => io.intc.interrupt_enable.0 as u16, REG_IF => io.intc.interrupt_flags.0 as u16, REG_TM0CNT_L => io.timers[0].timer_data, REG_TM0CNT_H => io.timers[0].timer_ctl.0, REG_TM1CNT_L => io.timers[1].timer_data, REG_TM1CNT_H => io.timers[1].timer_ctl.0, REG_TM2CNT_L => io.timers[2].timer_data, REG_TM2CNT_H => io.timers[2].timer_ctl.0, REG_TM3CNT_L => io.timers[3].timer_data, REG_TM3CNT_H => io.timers[3].timer_ctl.0, REG_WAITCNT => self.waitcnt.0, REG_POSTFLG => self.post_boot_flag as u16, REG_HALTCNT => 0, REG_KEYINPUT => self.keyinput as u16, _ => self.mem.read_16(addr), } } fn read_8(&self, addr: Addr) -> u8 { self.read_16(addr) as u8 } fn write_32(&mut self, addr: Addr, value: u32) { self.write_16(addr, (value & 0xffff) as u16); self.write_16(addr + 2, (value >> 16) as u16); } fn write_16(&mut self, addr: Addr, value: u16) { let mut io = self.io.borrow_mut(); match addr + IO_BASE { REG_DISPCNT => io.gpu.dispcnt.0 |= value, REG_DISPSTAT => io.gpu.dispstat.0 |= value, REG_BG0CNT => io.gpu.bg[0].bgcnt.0 |= value, REG_BG1CNT => io.gpu.bg[1].bgcnt.0 |= value, REG_BG2CNT => io.gpu.bg[2].bgcnt.0 |= value, REG_BG3CNT => io.gpu.bg[3].bgcnt.0 |= value, REG_BG0HOFS => io.gpu.bg[0].bghofs = value & 0x1ff, REG_BG0VOFS => io.gpu.bg[0].bgvofs = value & 0x1ff, REG_BG1HOFS => io.gpu.bg[1].bghofs = value & 0x1ff, REG_BG1VOFS => io.gpu.bg[1].bgvofs = value & 0x1ff, REG_BG2HOFS => io.gpu.bg[2].bghofs = value & 0x1ff, REG_BG2VOFS => io.gpu.bg[2].bgvofs = value & 0x1ff, REG_BG3HOFS => io.gpu.bg[3].bghofs = value & 0x1ff, REG_BG3VOFS => io.gpu.bg[3].bgvofs = value & 0x1ff, REG_BG2X_L => io.gpu.bg_aff[0].x |= (value as u32) as i32, REG_BG2X_H => io.gpu.bg_aff[0].x |= ((value as u32) << 16) as i32, REG_BG2Y_L => io.gpu.bg_aff[0].y |= (value as u32) as i32, REG_BG2Y_H => io.gpu.bg_aff[0].y |= ((value as u32) << 16) as i32, REG_BG3X_L => io.gpu.bg_aff[1].x |= (value as u32) as i32, REG_BG3X_H => io.gpu.bg_aff[1].x |= ((value as u32) << 16) as i32, REG_BG3Y_L => io.gpu.bg_aff[1].y |= (value as u32) as i32, REG_BG3Y_H => io.gpu.bg_aff[1].y |= ((value as u32) << 16) as i32, REG_BG2PA => io.gpu.bg_aff[0].pa = value as i16, REG_BG2PB => io.gpu.bg_aff[0].pb = value as i16, REG_BG2PC => io.gpu.bg_aff[0].pc = value as i16, REG_BG2PD => io.gpu.bg_aff[0].pd = value as i16, REG_BG3PA => io.gpu.bg_aff[1].pa = value as i16, REG_BG3PB => io.gpu.bg_aff[1].pb = value as i16, REG_BG3PC => io.gpu.bg_aff[1].pc = value as i16, REG_BG3PD => io.gpu.bg_aff[1].pd = value as i16, REG_WIN0H => io.gpu.win0h = value, REG_WIN1H => io.gpu.win1h = value, REG_WIN0V => io.gpu.win0v = value, REG_WIN1V => io.gpu.win1v = value, REG_WININ => io.gpu.winin = value, REG_WINOUT => io.gpu.winout = value, REG_MOSAIC => io.gpu.mosaic.0 = value, REG_BLDCNT => io.gpu.bldcnt.0 = value, REG_BLDALPHA => io.gpu.bldalpha.0 = value, REG_BLDY => io.gpu.bldy = value & 0b11111, REG_IME => io.intc.interrupt_master_enable = value != 0, REG_IE => io.intc.interrupt_enable.0 = value, REG_IF => io.intc.interrupt_flags.0 &= !value, REG_TM0CNT_L => { io.timers[0].timer_data = value; io.timers[0].initial_data = value; } REG_TM0CNT_H => io.timers[0].timer_ctl.0 = value, REG_TM1CNT_L => { io.timers[1].timer_data = value; io.timers[1].initial_data = value; } REG_TM1CNT_H => io.timers[1].timer_ctl.0 = value, REG_TM2CNT_L => { io.timers[2].timer_data = value; io.timers[2].initial_data = value; } REG_TM2CNT_H => io.timers[2].timer_ctl.0 = value, REG_TM3CNT_L => { io.timers[3].timer_data = value; io.timers[3].initial_data = value; } REG_TM3CNT_H => io.timers[3].timer_ctl.0 = value, REG_WAITCNT => self.waitcnt.0 = value, REG_POSTFLG => self.post_boot_flag = value != 0, REG_HALTCNT => {} _ => { self.mem.write_16(addr, value); } } } fn write_8(&mut self, addr: Addr, value: u8) { if addr & 1 != 0 { let addr = addr & !1; let t = self.read_16(addr); let upper = (value as u16); let lower = t & 0xff; self.write_16(addr, (upper << 8) | lower); } else { let t = self.read_16(addr); let upper = t << 8; let lower = (value as u16); self.write_16(addr, (upper << 8) | lower); } } } bitfield! { #[derive(Default, Copy, Clone, PartialEq)] pub struct WaitControl(u16); impl Debug; u16; sram_wait_control, _: 1, 0; pub ws0_first_access, _: 3, 2; pub ws0_second_access, _: 4, 4; pub ws1_first_access, _: 6, 5; pub ws1_second_access, _: 7, 7; pub ws2_first_access, _: 9, 8; pub ws2_second_access, _: 10, 10; #[allow(non_snake_case)] PHI_terminal_output, _: 12, 11; prefetch, _: 14; }