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cpu.rs: Make private function names more concise

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John 2023-03-26 18:32:31 -05:00
parent 5520d4ab69
commit a2a44dfd4f
1 changed files with 87 additions and 54 deletions
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141
src/cpu.rs
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@ -227,15 +227,15 @@ impl CPU {
// | 2aaa | Pushes pc onto the stack, then jumps to a
0x2 => self.call(a, bus),
// | 3xbb | Skips next instruction if register X == b
0x3 => self.skip_if_x_equal_byte(x, b),
0x3 => self.skip_equals_immediate(x, b),
// | 4xbb | Skips next instruction if register X != b
0x4 => self.skip_if_x_not_equal_byte(x, b),
0x4 => self.skip_not_equals_immediate(x, b),
// # Performs a register-register comparison
// |opcode| effect |
// |------|------------------------------------|
// | 9XY0 | Skip next instruction if vX == vY |
0x5 => match n {
0x0 => self.skip_if_x_equal_y(x, y),
0x0 => self.skip_equals(x, y),
_ => self.unimplemented(opcode),
},
// 6xbb: Loads immediate byte b into register vX
@ -255,15 +255,15 @@ impl CPU {
// | 8xy7 | X = Y - X; Set vF=carry |
// | 8xyE | X = X << 1 |
0x8 => match n {
0x0 => self.load_y_into_x(x, y),
0x1 => self.x_orequals_y(x, y),
0x2 => self.x_andequals_y(x, y),
0x3 => self.x_xorequals_y(x, y),
0x4 => self.x_addequals_y(x, y),
0x5 => self.x_subequals_y(x, y),
0x6 => self.shift_right_x(x),
0x7 => self.backwards_subtract(x, y),
0xE => self.shift_left_x(x),
0x0 => self.load(x, y),
0x1 => self.or(x, y),
0x2 => self.and(x, y),
0x3 => self.xor(x, y),
0x4 => self.add(x, y),
0x5 => self.sub(x, y),
0x6 => self.shift_right(x, y),
0x7 => self.backwards_sub(x, y),
0xE => self.shift_left(x, y),
_ => self.unimplemented(opcode),
},
// # Performs a register-register comparison
@ -271,11 +271,11 @@ impl CPU {
// |------|------------------------------------|
// | 9XY0 | Skip next instruction if vX != vY |
0x9 => match n {
0 => self.skip_if_x_not_equal_y(x, y),
0 => self.skip_not_equals(x, y),
_ => self.unimplemented(opcode),
},
// Aaaa: Load address #a into register I
0xa => self.load_indirect_register(a),
0xa => self.load_i_immediate(a),
// Baaa: Jump to &adr + v0
0xb => self.jump_indexed(a),
// Cxbb: Stores a random number + the provided byte into vX
@ -286,11 +286,11 @@ impl CPU {
// # Skips instruction on value of keypress
// |opcode| effect |
// |------|------------------------------------|
// | eX9e | Skip next instruction if key == #X |
// | eXa1 | Skip next instruction if key != #X |
// | eX9e | Skip next instruction if key == vX |
// | eXa1 | Skip next instruction if key != vX |
0xe => match b {
0x9e => self.skip_if_key_equals_x(x),
0xa1 => self.skip_if_key_not_x(x),
0x9e => self.skip_key_equals(x),
0xa1 => self.skip_key_not_equals(x),
_ => self.unimplemented(opcode),
},
@ -307,15 +307,15 @@ impl CPU {
// | fX55 | DMA Stor from I to registers 0..X |
// | fX65 | DMA Load from I to registers 0..X |
0xf => match b {
0x07 => self.get_delay_timer(x),
0x07 => self.load_delay_timer(x),
0x0A => self.wait_for_key(x),
0x15 => self.load_delay_timer(x),
0x18 => self.load_sound_timer(x),
0x1E => self.add_to_indirect(x),
0x29 => self.load_sprite_x(x),
0x33 => self.bcd_convert_i(x, bus),
0x55 => self.dma_store(x, bus),
0x65 => self.dma_load(x, bus),
0x15 => self.store_delay_timer(x),
0x18 => self.store_sound_timer(x),
0x1E => self.add_i(x),
0x29 => self.load_sprite(x),
0x33 => self.bcd_convert(x, bus),
0x55 => self.store_dma(x, bus),
0x65 => self.load_dma(x, bus),
_ => self.unimplemented(opcode),
},
_ => unimplemented!("Extracted nibble from byte, got >nibble?"),
@ -398,6 +398,9 @@ impl Default for CPU {
}
}
// Below this point, comments may be duplicated per impl' block,
// since some opcodes handle multiple instructions.
// | 0aaa | Issues a "System call" (ML routine)
//
// |opcode| effect |
@ -460,7 +463,7 @@ impl CPU {
impl CPU {
/// 3xbb: Skips the next instruction if register X == b
#[inline]
fn skip_if_x_equal_byte(&mut self, x: Reg, b: u8) {
fn skip_equals_immediate(&mut self, x: Reg, b: u8) {
if self.v[x] == b {
self.pc = self.pc.wrapping_add(2);
}
@ -471,7 +474,7 @@ impl CPU {
impl CPU {
/// 4xbb: Skips the next instruction if register X != b
#[inline]
fn skip_if_x_not_equal_byte(&mut self, x: Reg, b: u8) {
fn skip_not_equals_immediate(&mut self, x: Reg, b: u8) {
if self.v[x] != b {
self.pc = self.pc.wrapping_add(2);
}
@ -486,7 +489,7 @@ impl CPU {
impl CPU {
/// 5xy0: Skips the next instruction if register X != register Y
#[inline]
fn skip_if_x_equal_y(&mut self, x: Reg, y: Reg) {
fn skip_equals(&mut self, x: Reg, y: Reg) {
if self.v[x] == self.v[y] {
self.pc = self.pc.wrapping_add(2);
}
@ -526,32 +529,44 @@ impl CPU {
// | 8xyE | X = X << 1 |
impl CPU {
/// 8xy0: Loads the value of y into x
///
/// # Authenticity
/// The original chip-8 interpreter will clobber vF for any 8-series instruction
#[inline]
fn load_y_into_x(&mut self, x: Reg, y: Reg) {
fn load(&mut self, x: Reg, y: Reg) {
self.v[x] = self.v[y];
if self.flags.authentic {
self.v[0xf] = 0;
}
}
/// 8xy1: Performs bitwise or of vX and vY, and stores the result in vX
///
/// # Authenticity
/// The original chip-8 interpreter will clobber vF for any 8-series instruction
#[inline]
fn x_orequals_y(&mut self, x: Reg, y: Reg) {
fn or(&mut self, x: Reg, y: Reg) {
self.v[x] |= self.v[y];
if self.flags.authentic {
self.v[0xf] = 0;
}
}
/// 8xy2: Performs bitwise and of vX and vY, and stores the result in vX
///
/// # Authenticity
/// The original chip-8 interpreter will clobber vF for any 8-series instruction
#[inline]
fn x_andequals_y(&mut self, x: Reg, y: Reg) {
fn and(&mut self, x: Reg, y: Reg) {
self.v[x] &= self.v[y];
if self.flags.authentic {
self.v[0xf] = 0;
}
}
/// 8xy3: Performs bitwise xor of vX and vY, and stores the result in vX
///
/// # Authenticity
/// The original chip-8 interpreter will clobber vF for any 8-series instruction
#[inline]
fn x_xorequals_y(&mut self, x: Reg, y: Reg) {
fn xor(&mut self, x: Reg, y: Reg) {
self.v[x] ^= self.v[y];
if self.flags.authentic {
self.v[0xf] = 0;
@ -559,37 +574,47 @@ impl CPU {
}
/// 8xy4: Performs addition of vX and vY, and stores the result in vX
#[inline]
fn x_addequals_y(&mut self, x: Reg, y: Reg) {
fn add(&mut self, x: Reg, y: Reg) {
let carry;
(self.v[x], carry) = self.v[x].overflowing_add(self.v[y]);
self.v[0xf] = carry.into();
}
/// 8xy5: Performs subtraction of vX and vY, and stores the result in vX
#[inline]
fn x_subequals_y(&mut self, x: Reg, y: Reg) {
fn sub(&mut self, x: Reg, y: Reg) {
let carry;
(self.v[x], carry) = self.v[x].overflowing_sub(self.v[y]);
self.v[0xf] = (!carry).into();
}
/// 8xy6: Performs bitwise right shift of vX
///
/// # Authenticity
/// On the original chip-8 interpreter, this would perform the operation on vY
/// and store the result in vX. This behavior was left out, for now.
#[inline]
fn shift_right_x(&mut self, x: Reg) {
let shift_out = self.v[x] & 1;
self.v[x] >>= 1;
fn shift_right(&mut self, x: Reg, y: Reg) {
let src: Reg = if self.flags.authentic {y} else {x};
let shift_out = self.v[src] & 1;
self.v[x] = self.v[src] >> 1;
self.v[0xf] = shift_out;
}
/// 8xy7: Performs subtraction of vY and vX, and stores the result in vX
#[inline]
fn backwards_subtract(&mut self, x: Reg, y: Reg) {
fn backwards_sub(&mut self, x: Reg, y: Reg) {
let carry;
(self.v[x], carry) = self.v[y].overflowing_sub(self.v[x]);
self.v[0xf] = (!carry).into();
}
/// 8X_E: Performs bitwise left shift of vX
///
/// # Authenticity
/// On the original chip-8 interpreter, this would perform the operation on vY
/// and store the result in vX. This behavior was left out, for now.
#[inline]
fn shift_left_x(&mut self, x: Reg) {
let shift_out: u8 = self.v[x] >> 7;
self.v[x] <<= 1;
fn shift_left(&mut self, x: Reg, y: Reg) {
let src: Reg = if self.flags.authentic {y} else {x};
let shift_out: u8 = self.v[src] >> 7;
self.v[x] = self.v[src] << 1;
self.v[0xf] = shift_out;
}
}
@ -602,7 +627,7 @@ impl CPU {
impl CPU {
/// 9xy0: Skip next instruction if X != y
#[inline]
fn skip_if_x_not_equal_y(&mut self, x: Reg, y: Reg) {
fn skip_not_equals(&mut self, x: Reg, y: Reg) {
if self.v[x] != self.v[y] {
self.pc = self.pc.wrapping_add(2);
}
@ -613,7 +638,7 @@ impl CPU {
impl CPU {
/// Aadr: Load address #adr into register I
#[inline]
fn load_indirect_register(&mut self, a: Adr) {
fn load_i_immediate(&mut self, a: Adr) {
self.i = a;
}
}
@ -675,7 +700,7 @@ impl CPU {
impl CPU {
/// Ex9E: Skip next instruction if key == #X
#[inline]
fn skip_if_key_equals_x(&mut self, x: Reg) {
fn skip_key_equals(&mut self, x: Reg) {
let x = self.v[x] as usize;
if self.keys[x] {
self.pc += 2;
@ -683,7 +708,7 @@ impl CPU {
}
/// ExaE: Skip next instruction if key != #X
#[inline]
fn skip_if_key_not_x(&mut self, x: Reg) {
fn skip_key_not_equals(&mut self, x: Reg) {
let x = self.v[x] as usize;
if !self.keys[x] {
self.pc += 2;
@ -710,7 +735,7 @@ impl CPU {
/// vX = DT
/// ```
#[inline]
fn get_delay_timer(&mut self, x: Reg) {
fn load_delay_timer(&mut self, x: Reg) {
self.v[x] = self.delay;
}
/// Fx0A: Wait for key, then vX = K
@ -733,7 +758,7 @@ impl CPU {
/// DT = vX
/// ```
#[inline]
fn load_delay_timer(&mut self, x: Reg) {
fn store_delay_timer(&mut self, x: Reg) {
self.delay = self.v[x];
}
/// Fx18: Load vX into ST
@ -741,7 +766,7 @@ impl CPU {
/// ST = vX;
/// ```
#[inline]
fn load_sound_timer(&mut self, x: Reg) {
fn store_sound_timer(&mut self, x: Reg) {
self.sound = self.v[x];
}
/// Fx1e: Add vX to I,
@ -749,7 +774,7 @@ impl CPU {
/// I += vX;
/// ```
#[inline]
fn add_to_indirect(&mut self, x: Reg) {
fn add_i(&mut self, x: Reg) {
self.i += self.v[x] as u16;
}
/// Fx29: Load sprite for character x into I
@ -757,20 +782,24 @@ impl CPU {
/// I = sprite(X);
/// ```
#[inline]
fn load_sprite_x(&mut self, x: Reg) {
fn load_sprite(&mut self, x: Reg) {
self.i = self.font + (5 * (self.v[x] as Adr % 0x10));
}
/// Fx33: BCD convert X into I`[0..3]`
#[inline]
fn bcd_convert_i(&mut self, x: Reg, bus: &mut Bus) {
fn bcd_convert(&mut self, x: Reg, bus: &mut Bus) {
let x = self.v[x];
bus.write(self.i.wrapping_add(2), x % 10);
bus.write(self.i.wrapping_add(1), x / 10 % 10);
bus.write(self.i, x / 100 % 10);
}
/// Fx55: DMA Stor from I to registers 0..X
///
/// # Authenticity
/// The original chip-8 interpreter uses I to directly index memory,
/// with the side effect of leaving I as I+X+1 after the transfer is done.
#[inline]
fn dma_store(&mut self, x: Reg, bus: &mut Bus) {
fn store_dma(&mut self, x: Reg, bus: &mut Bus) {
let i = self.i as usize;
for (reg, value) in bus
.get_mut(i..=i + x)
@ -785,8 +814,12 @@ impl CPU {
}
}
/// Fx65: DMA Load from I to registers 0..X
///
/// # Authenticity
/// The original chip-8 interpreter uses I to directly index memory,
/// with the side effect of leaving I as I+X+1 after the transfer is done.
#[inline]
fn dma_load(&mut self, x: Reg, bus: &mut Bus) {
fn load_dma(&mut self, x: Reg, bus: &mut Bus) {
let i = self.i as usize;
for (reg, value) in bus
.get(i + 0..=i + x)