#![allow(dead_code)]
use memory::VMem;
use mos6502::CPU;
use core::intrinsics::transmute;
pub trait Screen {
fn put(&self, x: u8, y: u8, color: u8);
fn render(&self);
}
#[repr(C, packed)]
#[derive(Copy, Clone)]
struct Sprite {
y: u8, /* is the (actualy y) - 1 */
tile: u8,
attr: u8,
x: u8
}
pub struct PPU<'a> {
scanline: u16,
/* registers */
ppuctl: u8,
ppumask: u8,
ppustatus: u8,
oamaddr: u8,
reg: u8,
x: u8, /* fine x scroll */
v: u16, /* current vram addr */
t: u16, /* temporary vram addr */
w: bool, /* first/second write toggle */
cycle: u16, /* cycle in the current scanline */
/* rendering regs & latches */
/* background registers */
bg_bitmap: [u16; 2],
bg_palette: [u16; 2],
/* background latches */
bg_nt: u8,
bg_attr: u8,
bg_bit_low: u8,
bg_bit_high: u8,
/* sprites */
oam: [Sprite; 64],
oam2: [usize; 8],
sp_bitmap: [[u8; 2]; 8],
sp_idx: [usize; 8],
sp_cnt: [u8; 8],
sp_zero_insight: bool,
rendering: bool,
buffered_read: u8,
early_read: bool,
/* IO */
mem: &'a VMem,
scr: &'a Screen,
}
impl<'a> PPU<'a> {
pub fn write_ctl(&mut self, data: u8) {
self.reg = data;
self.ppuctl = data;
self.t = (self.t & 0x73ff) | ((data as u16 & 3) << 10);
}
pub fn write_mask(&mut self, data: u8) {
self.reg = data;
self.ppumask = data;
}
pub fn read_status(&mut self) -> u8 {
let res = (self.ppustatus & !0x1fu8) | (self.reg & 0x1f);
self.ppustatus &= !PPU::FLAG_VBLANK;
self.w = false;
if self.scanline == 241 && self.cycle == 0 {
self.early_read = true;
}
res
}
pub fn write_oamaddr(&mut self, data: u8) {
self.reg = data;
self.oamaddr = data;
}
pub fn write_oamdata(&mut self, data: u8) {
self.reg = data;
if self.rendering { return }
unsafe {
let oam_raw = transmute::<&mut[Sprite; 64], &mut[u8; 256]>(&mut self.oam);
oam_raw[self.oamaddr as usize] = data;
self.oamaddr = self.oamaddr.wrapping_add(1);
}
}
pub fn read_oamdata(&self) -> u8 {
unsafe {
let oam_raw = transmute::<&[Sprite; 64], &[u8; 256]>(&self.oam);
oam_raw[self.oamaddr as usize]
}
}
pub fn write_scroll(&mut self, data: u8) {
self.reg = data;
let data = data as u16;
match self.w {
false => {
self.t = (self.t & 0x7fe0) | (data >> 3);
self.x = (data & 0x07) as u8;
//assert!(self.x == 0);
self.w = true;
},
true => {
self.t = (self.t & 0x0c1f) | ((data & 0xf8) << 2) | ((data & 0x07) << 12);
self.w = false;
}
}
}
pub fn write_addr(&mut self, data: u8) {
self.reg = data;
let data = data as u16;
match self.w {
false => {
self.t = (self.t & 0x00ff) | ((data & 0x3f) << 8);
self.w = true;
},
true => {
self.t = (self.t & 0xff00) | data;
self.v = self.t;
self.w = false;
}
}
}
pub fn read_data(&mut self) -> u8 {
let data = self.mem.read(self.v);
let res = if self.v & 0x3fff < 0x3f00 {
let prev = self.buffered_read;
self.buffered_read = data;
prev
} else {
self.buffered_read = self.mem.read(self.v - 0x1000);
data
};
self.v = self.v.wrapping_add(match self.get_vram_inc() {
0 => 1,
_ => 32
});
res
}
pub fn write_data(&mut self, data: u8) {
self.reg = data;
self.mem.write(self.v, data);
self.v = self.v.wrapping_add(match self.get_vram_inc() {
0 => 1,
_ => 32
});
}
pub fn write_oamdma(&mut self, data: u8, cpu: &mut CPU) {
self.reg = data;
let mut addr = (data as u16) << 8;
unsafe {
let oam_raw = transmute::<&mut[Sprite; 64], &mut[u8; 256]>(&mut self.oam);
for _ in 0..0x100 {
oam_raw[self.oamaddr as usize] = cpu.mem.read(addr);
addr = addr.wrapping_add(1);
self.oamaddr = self.oamaddr.wrapping_add(1);
}
}
cpu.cycle += 1;
cpu.cycle += cpu.cycle & 1;
cpu.cycle += 512;
}
#[inline(always)] fn get_spritesize(&self) -> u8 {(self.ppuctl >> 5) & 1}
#[inline(always)] fn get_flag_nmi(&self) -> bool { (self.ppuctl >> 7) == 1 }
#[inline(always)] fn get_vram_inc(&self) -> u8 { (self.ppuctl >> 2) & 1}
#[inline(always)] fn get_show_leftmost_bg(&self) -> bool { (self.ppumask >> 1) & 1 == 1}
#[inline(always)] fn get_show_leftmost_sp(&self) -> bool { (self.ppumask >> 2) & 1 == 1}
#[inline(always)] fn get_show_bg(&self) -> bool { (self.ppumask >> 3) & 1 == 1}
#[inline(always)] fn get_show_sp(&self) -> bool { (self.ppumask >> 4) & 1 == 1}
#[inline(always)] pub fn get_flag_vblank(&self) -> bool { (self.ppustatus >> 7) & 1 == 1 }
const FLAG_OVERFLOW: u8 = 1 << 5;
const FLAG_SPRITE_ZERO: u8 = 1 << 6;
const FLAG_VBLANK: u8 = 1 << 7;
#[inline(always)]
fn fetch_nametable_byte(&mut self) {
self.bg_nt = self.mem.read(0x2000 | (self.v & 0x0fff));
}
#[inline(always)]
fn fetch_attrtable_byte(&mut self) {
let v = self.v;
/* the byte representing 4x4 tiles */
let b = self.mem.read(0x23c0 | (v & 0x0c00) |
((v >> 4) & 0x38) | ((v >> 2) & 0x07));
self.bg_attr = (b >> ((v & 2) | ((v & 0x40) >> 4))) & 3;
}
#[inline(always)]
fn fetch_low_bgtile_byte(&mut self) {
/* 0x?000 */
self.bg_bit_low = self.mem.read(((self.ppuctl as u16 & 0x10) << 8) |
/* 0x-??0 */
((self.bg_nt as u16) << 4) |
/* 0x---? (0 - 7) */
((self.v >> 12) & 7) | 0x0);
}
#[inline(always)]
fn fetch_high_bgtile_byte(&mut self) {
/* 0x?000 */
self.bg_bit_high = self.mem.read(((self.ppuctl as u16 & 0x10) << 8) |
/* 0x-??0 */
((self.bg_nt as u16) << 4) |
/* 0x---? (8 - f) */
((self.v >> 12) & 7) | 0x8);
}
#[inline(always)]
fn load_bgtile(&mut self) {
/* load the tile bitmap to high 8 bits of bitmap,
* assume the high 8 bits are zeros */
//if (!(self.bg_bitmap[0] >> 8 == 0 &&
// self.bg_bitmap[1] >> 8 == 0 &&
// self.bg_palette[0] >> 8 == 0 &&
// self.bg_palette[1] >> 8 == 0)) {
// println!("at cycle {} {}", self.scanline, self.cycle) }
assert!(self.bg_bitmap[0] >> 8 == 0 &&
self.bg_bitmap[1] >> 8 == 0 &&
self.bg_palette[0] >> 8 == 0 &&
self.bg_palette[1] >> 8 == 0);
self.bg_bitmap[0] |= (PPU::reverse_byte(self.bg_bit_low) as u16) << 8;
self.bg_bitmap[1] |= (PPU::reverse_byte(self.bg_bit_high) as u16) << 8;
self.bg_palette[0] |= (self.bg_attr & 1) as u16 * 0xff00;
self.bg_palette[1] |= ((self.bg_attr >> 1) & 1) as u16 * 0xff00;
}
#[inline(always)]
fn shift_sprites(&mut self) {
for (i, c) in self.sp_cnt.iter_mut().enumerate() {
if self.sp_idx[i] > 0xff { break }
let c0 = *c;
match c0 {
0 => {
let t = &mut self.sp_bitmap[i];
t[0] = t[0].wrapping_shr(1);
t[1] = t[1].wrapping_shr(1);
},
_ => *c = c0 - 1
}
}
}
#[inline(always)]
fn shift_bgtile(&mut self) {
let t1 = &mut self.bg_bitmap;
let t2 = &mut self.bg_palette;
t1[0] = t1[0].wrapping_shr(1);
t1[1] = t1[1].wrapping_shr(1);
t2[0] = t2[0].wrapping_shr(1);
t2[1] = t2[1].wrapping_shr(1);
}
#[inline(always)]
fn wrapping_inc_cx(&mut self) {
match self.v & 0x001f {
31 => {
self.v &= !0x001fu16; /* reset coarse x */
self.v ^= 0x0400; /* switch horizontal nametable */
}
_ => self.v += 1
}
}
#[inline(always)]
fn wrapping_inc_y(&mut self) {
match (self.v & 0x7000) == 0x7000 {
false => self.v += 0x1000, /* fine y < 7 */
true => {
self.v &= !0x7000u16; /* fine y <- 0 */
let y = match (self.v & 0x03e0) >> 5 {
29 => {self.v ^= 0x0800; 0}, /* at bottom of scanline */
31 => 0, /* do not switch nt */
y => y + 1
};
self.v = (self.v & !0x03e0u16) | (y << 5);
}
}
}
#[inline(always)]
fn reset_cx(&mut self) {
self.v = (self.v & !0x041fu16) | (self.t & 0x041f);
}
#[inline(always)]
fn reset_y(&mut self) {
self.v = (self.v & !0x7be0u16) | (self.t & 0x7be0);
}
#[inline(always)]
fn clear_sprite(&mut self) {
if self.scanline == 261 { return }
self.oam2 = [0x100; 8];
}
fn eval_sprite(&mut self) {
if self.scanline == 261 { return }
/* we use scanline here because s.y is the (actual y) - 1 */
let mut nidx = 0;
let mut n = 0;
let scanline = self.scanline;
let h = match self.get_spritesize() {
0 => 8,
_ => 16
};
for (i, s) in self.oam.iter().enumerate() {
let y = s.y as u16;
if y <= scanline && scanline < y + h {
self.oam2[nidx] = i;
nidx += 1;
if nidx == 8 {
n = i + 1;
break;
}
}
}
if nidx == 8 {
let mut m = 0;
unsafe {
let oam_raw = transmute::<&[Sprite; 64], &[[u8; 4]; 64]>(&self.oam);
while n < 64 {
let y = oam_raw[n][m] as u16;
if y <= scanline && scanline < y + h {
self.ppustatus |= PPU::FLAG_OVERFLOW; /* set overflow */
} else {
m = (m + 1) & 3; /* emulates hardware bug */
}
n += 1;
}
}
}
}
#[inline(always)]
fn reverse_byte(mut x: u8) -> u8 {
x = ((x & 0xaa) >> 1) | ((x & 0x55) << 1);
x = ((x & 0xcc) >> 2) | ((x & 0x33) << 2);
x = ((x & 0xf0) >> 4) | ((x & 0x0f) << 4);
x
}
fn fetch_sprite(&mut self) {
if self.scanline == 261 { return }
/* we use scanline here because s.y is the (actual y) - 1 */
self.sp_idx = [0x100; 8];
for (i, v) in self.oam2.iter().enumerate() {
let j = *v;
if j > 0xff { break }
let s = &self.oam[j];
let vflip = (s.attr & 0x80) == 0x80;
let y0 = self.scanline - s.y as u16;
let (ptable, tidx, y) = match self.get_spritesize() {
0 => {
let y = if vflip {7 - y0 as u8} else {y0 as u8};
((self.ppuctl as u16 & 0x08) << 9, s.tile, y)
},
_ => {
//assert!(false);
let y = if vflip {15 - y0 as u8} else {y0 as u8};
((s.tile as u16 & 1) << 12,
(s.tile & !1u8) | (y >> 3),
y & 0x7)
}
};
self.sp_idx[i] = j;
self.sp_cnt[i] = s.x;
let mut low = self.mem.read(ptable | ((tidx as u16) << 4) | 0x0 | y as u16);
let mut high = self.mem.read(ptable | ((tidx as u16) << 4) | 0x8 | y as u16);
if (s.attr & 0x40) != 0x40 {
low = PPU::reverse_byte(low);
high = PPU::reverse_byte(high);
}
self.sp_bitmap[i][0] = low;
self.sp_bitmap[i][1] = high;
}
}
#[inline(always)]
fn get_bg_pidx(&self) -> u8 {
if self.get_show_bg() {
(((self.bg_bitmap[1] >> self.x) & 1) << 1) as u8 |
((self.bg_bitmap[0] >> self.x) & 1) as u8
} else { 0 }
}
#[inline(always)]
fn get_sp_pidx(&self, i: usize) -> u8 {
if self.get_show_sp() {
((self.sp_bitmap[i][1] & 1) << 1) | (self.sp_bitmap[i][0] & 1)
} else { 0 }
}
fn render_pixel(&mut self) {
let x = self.cycle - 1;
let bg_pidx =
if x >= 8 || self.get_show_leftmost_bg() {self.get_bg_pidx()}
else {0};
let mut sp_pidx = 0x0;
let mut sp_id = 0;
let mut pri = 0x1;
if x >= 8 || self.get_show_leftmost_sp() {
for i in 0..8 {
if self.sp_idx[i] > 0xff { break }
let s = &self.oam[self.sp_idx[i]];
if self.sp_cnt[i] != 0 { continue; } /* not active */
match self.get_sp_pidx(i) {
0x0 => (),
pidx => {
if bg_pidx != 0 && self.sp_idx[i] == 0 && x != 0xff {
assert!(i == 0);
self.ppustatus |= PPU::FLAG_SPRITE_ZERO; /* set sprite zero hit */
}
sp_pidx = pidx;
sp_id = i;
pri = (s.attr >> 5) & 1;
break;
}
}
}
}
assert!(0 < self.cycle && self.cycle < 257);
assert!(self.scanline < 240);
self.scr.put((self.cycle - 1) as u8,
self.scanline as u8,
self.mem.read(if (pri == 0 || bg_pidx == 0) && sp_pidx != 0 {
0x3f10 | ((self.oam[self.sp_idx[sp_id]].attr & 3) << 2) as u16 |
sp_pidx as u16
} else {
0x3f00 | match bg_pidx {
0 => 0,
_ => ((((self.bg_palette[1] >> self.x) & 1) << 3) |
(((self.bg_palette[0] >> self.x) & 1) << 2)) as u16 |
bg_pidx as u16
}
}));
}
pub fn new(mem: &'a VMem, scr: &'a Screen) -> Self {
let ppuctl = 0x00;
let ppumask = 0x00;
let ppustatus = 0xa0;
let oamaddr = 0x00;
let w = false;
let buffered_read = 0x00;
let cycle = 370;
let scanline = 240;
PPU {
scanline,
ppuctl,
ppumask,
ppustatus,
oamaddr,
reg: 0,
x: 0, v: 0, t: 0, w, cycle,
bg_bitmap: [0; 2],
bg_palette: [0; 2],
bg_nt: 0, bg_attr: 0,
bg_bit_low: 0, bg_bit_high: 0,
oam: [Sprite{y: 0, tile: 0, attr: 0, x: 0}; 64],
oam2: [0x100; 8],
sp_idx: [0x100; 8],
sp_bitmap: [[0; 2]; 8],
sp_cnt: [0; 8],
sp_zero_insight: false,
rendering: false,
buffered_read,
early_read: false,
mem, scr
}
}
pub fn reset(&mut self) {
self.ppuctl = 0x00;
self.ppumask = 0x00;
self.ppustatus = self.ppustatus & 0x80;
self.w = false;
self.buffered_read = 0x00;
self.cycle = 370;
self.scanline = 240;
}
pub fn tick(&mut self) -> bool {
let cycle = self.cycle;
if cycle == 0 {
self.cycle = cycle + 1;
return false;
}
let visible_line = self.scanline < 240;
let pre_render = self.scanline == 261;
self.rendering = pre_render || visible_line;
if pre_render && cycle == 1 {
/* clear vblank, sprite zero hit & overflow */
self.ppustatus &= !(PPU::FLAG_VBLANK |
PPU::FLAG_SPRITE_ZERO | PPU::FLAG_OVERFLOW);
} else if self.rendering && (self.get_show_bg() || self.get_show_sp()) {
if pre_render && 279 < cycle && cycle < 305 {
self.reset_y();
} else {
let visible_cycle = 0 < cycle && cycle < 257; /* 1..256 */
let fetch_cycle = visible_cycle || (320 < cycle && cycle < 337);
if fetch_cycle { /* 1..256 and 321..336 */
match cycle & 0x7 {
1 => {
self.load_bgtile();
self.fetch_nametable_byte();
},
3 => self.fetch_attrtable_byte(),
5 => self.fetch_low_bgtile_byte(),
7 => self.fetch_high_bgtile_byte(),
0 => self.wrapping_inc_cx(),
_ => ()
}
match cycle {
1 => self.clear_sprite(), /* clear secondary OAM */
65 => self.eval_sprite(), /* sprite evaluation */
256 => self.wrapping_inc_y(),
_ => ()
}
if visible_line && visible_cycle {
self.render_pixel();
self.shift_sprites();
}
self.shift_bgtile();
} else if cycle > 336 { /* 337..340 */
if cycle & 1 == 1 {
self.fetch_nametable_byte();
}
} else if cycle == 257 {
/* we don't emulate fetch to per cycle precision because all data are fetched
* from the secondary OAM which is not subject to any change during this
* scanline */
self.reset_cx();
self.fetch_sprite();
}
}
} else if self.scanline == 241 && cycle == 1 {
self.scr.render();
if !self.early_read {
self.ppustatus |= PPU::FLAG_VBLANK;
}
self.cycle += 1;
self.early_read = false;
return !self.early_read && self.get_flag_nmi(); /* trigger cpu's NMI */
}
self.cycle += 1;
if self.cycle > 340 {
self.cycle = 0;
self.scanline += 1;
if self.scanline > 261 {
self.scanline = 0;
}
}
false
}
}