#![allow(dead_code)] use mos6502::CPU_FREQ; use memory::CPUBus; use utils::Sampler; use core::mem::size_of; use utils::{Read, Write, load_prefix, save_prefix}; #[repr(C)] struct LPFilter { prev_out: i16 } const AUDIO_LEVEL_MAX: i32 = 32768; const LP_FACTOR: i32 = (0.815686 * AUDIO_LEVEL_MAX as f32) as i32; const HP_FACTOR1: i32 = (0.996039 * AUDIO_LEVEL_MAX as f32) as i32; const HP_FACTOR2: i32 = (0.999835 * AUDIO_LEVEL_MAX as f32) as i32; fn cutoff(mut x: i32) -> i16 { if x < -32768 { x = -32768 } else if x > 32767 { x = 32767 } x as i16 } impl LPFilter { fn new() -> Self { LPFilter { prev_out: 0 } } fn load(&mut self, reader: &mut Read) -> bool { load_prefix(self, 0, reader) } fn save(&self, writer: &mut Write) -> bool { save_prefix(self, 0, writer) } fn output(&mut self, input: i16) -> i16 { let out = cutoff(self.prev_out as i32 + (input as i32 - self.prev_out as i32) * LP_FACTOR / AUDIO_LEVEL_MAX); self.prev_out = out; out } } #[repr(C)] struct HPFilter { prev_in: i16, prev_out: i16, hp_factor: i32 } impl HPFilter { fn new(hp_factor: i32) -> Self { HPFilter { prev_in: 0, prev_out: 0, hp_factor } } fn load(&mut self, reader: &mut Read) -> bool { load_prefix(self, 0, reader) } fn save(&self, writer: &mut Write) -> bool { save_prefix(self, 0, writer) } fn output(&mut self, input: i16) -> i16 { let out = cutoff( self.prev_out as i32 * self.hp_factor / AUDIO_LEVEL_MAX + input as i32 - self.prev_in as i32); self.prev_in = input; self.prev_out = out; out } } pub trait Speaker { fn queue(&mut self, sample: i16); } const QUARTER_FRAME_FREQ: u32 = 240; pub const AUDIO_SAMPLE_FREQ: u32 = 44100; const TRI_SEQ_TABLE: [u8; 32] = [ 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 ]; const LEN_TABLE: [u8; 32] = [ 10, 254, 20, 2, 40, 4, 80, 6, 160, 8, 60, 10, 14, 12, 26, 14, 12, 16, 24, 18, 48, 20, 96, 22, 192, 24, 72, 26, 16, 28, 32, 30, ]; const DUTY_TABLE: [u8; 4] = [ 0b00000010, 0b00000110, 0b00011110, 0b11111001, ]; const PULSE_TABLE: [u16; 31] = [ 0x0000, 0x02f8, 0x05df, 0x08b4, 0x0b78, 0x0e2b, 0x10cf, 0x1363, 0x15e9, 0x1860, 0x1ac9, 0x1d25, 0x1f75, 0x21b7, 0x23ee, 0x2618, 0x2837, 0x2a4c, 0x2c55, 0x2e54, 0x3049, 0x3234, 0x3416, 0x35ee, 0x37be, 0x3985, 0x3b43, 0x3cf9, 0x3ea7, 0x404d, 0x41ec ]; const NOISE_PERIOD_TABLE: [u16; 16] = [ 4, 8, 16, 32, 64, 96, 128, 160, 202, 254, 380, 508, 762, 1016, 2034, 4068 ]; const DMC_TABLE: [u16; 16] = [ 214, 190, 170, 160, 143, 127, 113, 107, 95, 80, 71, 64, 53, 42, 36, 27, ]; const TND_TABLE: [u16; 203] = [ 0x0000, 0x01b7, 0x036a, 0x051a, 0x06c6, 0x086f, 0x0a15, 0x0bb7, 0x0d56, 0x0ef2, 0x108a, 0x121f, 0x13b1, 0x1540, 0x16cc, 0x1855, 0x19da, 0x1b5d, 0x1cdd, 0x1e59, 0x1fd3, 0x214a, 0x22be, 0x2430, 0x259e, 0x270a, 0x2874, 0x29da, 0x2b3e, 0x2c9f, 0x2dfe, 0x2f5a, 0x30b4, 0x320b, 0x335f, 0x34b2, 0x3601, 0x374f, 0x389a, 0x39e2, 0x3b29, 0x3c6d, 0x3dae, 0x3eee, 0x402b, 0x4166, 0x429f, 0x43d6, 0x450a, 0x463d, 0x476d, 0x489c, 0x49c8, 0x4af2, 0x4c1b, 0x4d41, 0x4e65, 0x4f87, 0x50a8, 0x51c6, 0x52e3, 0x53fe, 0x5517, 0x562e, 0x5743, 0x5856, 0x5968, 0x5a78, 0x5b86, 0x5c93, 0x5d9d, 0x5ea6, 0x5fae, 0x60b3, 0x61b7, 0x62ba, 0x63bb, 0x64ba, 0x65b7, 0x66b3, 0x67ae, 0x68a7, 0x699e, 0x6a94, 0x6b88, 0x6c7b, 0x6d6d, 0x6e5d, 0x6f4b, 0x7038, 0x7124, 0x720e, 0x72f7, 0x73de, 0x74c4, 0x75a9, 0x768c, 0x776e, 0x784f, 0x792e, 0x7a0d, 0x7ae9, 0x7bc5, 0x7c9f, 0x7d78, 0x7e50, 0x7f26, 0x7ffc, 0x80d0, 0x81a3, 0x8274, 0x8345, 0x8414, 0x84e2, 0x85af, 0x867b, 0x8746, 0x880f, 0x88d8, 0x899f, 0x8a65, 0x8b2b, 0x8bef, 0x8cb2, 0x8d74, 0x8e35, 0x8ef4, 0x8fb3, 0x9071, 0x912e, 0x91ea, 0x92a4, 0x935e, 0x9417, 0x94cf, 0x9586, 0x963c, 0x96f0, 0x97a4, 0x9857, 0x990a, 0x99bb, 0x9a6b, 0x9b1a, 0x9bc9, 0x9c76, 0x9d23, 0x9dcf, 0x9e7a, 0x9f24, 0x9fcd, 0xa075, 0xa11c, 0xa1c3, 0xa269, 0xa30e, 0xa3b2, 0xa455, 0xa4f7, 0xa599, 0xa63a, 0xa6da, 0xa779, 0xa818, 0xa8b5, 0xa952, 0xa9ef, 0xaa8a, 0xab25, 0xabbe, 0xac58, 0xacf0, 0xad88, 0xae1f, 0xaeb5, 0xaf4a, 0xafdf, 0xb073, 0xb107, 0xb199, 0xb22b, 0xb2bd, 0xb34d, 0xb3dd, 0xb46c, 0xb4fb, 0xb589, 0xb616, 0xb6a3, 0xb72f, 0xb7ba, 0xb845, 0xb8cf, 0xb958, 0xb9e1, 0xba69, 0xbaf1, 0xbb78, 0xbbfe, 0xbc84, 0xbd09, 0xbd8d, 0xbe11 ]; #[repr(C)] pub struct Pulse { /* envelope */ env_period: u8, env_lvl: u8, decay_lvl: u8, env_start: bool, env_loop: bool, env_const: bool, env_vol: u8, /* sweep */ swp_count: u8, swp_period: u8, swp_lvl: u8, swp_en: bool, swp_neg: bool, swp_rld: bool, muted: bool, /* length counter */ len_lvl: u8, /* timer */ timer_period: u16, timer_lvl: u16, /* sequencer */ seq_wave: u8, seq_cnt: u8, /* channel */ enabled: bool, comple: bool, } impl Pulse { pub fn new(comple: bool) -> Self { Pulse {env_period: 0, env_lvl: 0, decay_lvl: 0, env_start: false, env_loop: false, env_const: false, env_vol: 0, swp_count: 0, swp_period: 0, swp_lvl: 0, swp_en: false, swp_neg: false, swp_rld: false, muted: false, len_lvl: 0, timer_period: 0, timer_lvl: 0, seq_wave: 0, seq_cnt: 0, enabled: false, comple} } fn load(&mut self, reader: &mut Read) -> bool { load_prefix(self, 0, reader) } fn save(&self, writer: &mut Write) -> bool { save_prefix(self, 0, writer) } pub fn write_reg1(&mut self, data: u8) { self.seq_wave = DUTY_TABLE[(data >> 6) as usize]; self.env_loop = data & 0x20 == 0x20; self.env_const = data & 0x10 == 0x10; self.env_period = data & 0xf; self.env_vol = data & 0xf; } pub fn write_reg2(&mut self, data: u8) { self.swp_en = (data >> 7) == 1; self.swp_period = (data >> 4) & 7; self.swp_neg = data & 0x8 == 0x8; self.swp_count = data & 7; self.swp_rld = true; } pub fn write_reg3(&mut self, data: u8) { let p = (self.timer_period & 0xff00) | data as u16; self.set_timer_period(p); } pub fn write_reg4(&mut self, data: u8) { self.set_len(data >> 3); let p = (self.timer_period & 0x00ff) | ((data as u16 & 7) << 8); self.set_timer_period(p); self.seq_cnt = 0; self.decay_lvl = 0xf; } pub fn output(&self) -> u8 { let env = if self.env_const { self.env_vol } else { self.decay_lvl }; let swp = !self.muted; let seq = (self.seq_wave >> self.seq_cnt) & 1 == 1; let len = self.len_lvl > 0; if self.enabled && swp && seq && len { env } else { 0 } } fn tick_env(&mut self) { if !self.env_start { if self.env_lvl == 0 { self.env_lvl = self.env_period; if self.decay_lvl == 0 { if self.env_loop { self.decay_lvl = 0xf; } } else { self.decay_lvl -= 1; } } else { self.env_lvl -= 1; } } else { self.decay_lvl = 0xf; self.env_start = false; self.env_lvl = self.env_period; } } fn tick_sweep(&mut self) { let mut reload = self.swp_rld; if self.swp_lvl == 0 { reload = true; if self.swp_en { let mut p: u16 = self.timer_period; let mut delta = p >> self.swp_count; if self.swp_neg { delta = !delta; if self.comple { delta += 1; } /* two's complement */ } p = p.wrapping_add(delta); self.muted = p < 8 || (p >> 11 != 0); if !self.muted && self.swp_count != 0 { self.timer_period = p; } } } else { self.swp_lvl -= 1; } if reload { self.swp_lvl = self.swp_period; self.swp_rld = false; } } fn tick_length(&mut self) { if self.len_lvl > 0 && !self.env_loop { self.len_lvl -= 1 } } fn tick_timer(&mut self) { if self.timer_lvl == 0 { self.timer_lvl = self.timer_period; if self.seq_cnt == 7 { self.seq_cnt = 0 } else { self.seq_cnt += 1 } } else { self.timer_lvl -= 1 } } #[inline(always)] fn disable(&mut self) { self.len_lvl = 0; self.enabled = false; } #[inline(always)] fn enable(&mut self) { self.enabled = true } #[inline(always)] fn get_len(&self) -> u8 { self.len_lvl } #[inline(always)] fn set_len(&mut self, d: u8) { if self.enabled { self.len_lvl = LEN_TABLE[d as usize] } } #[inline(always)] fn set_timer_period(&mut self, p: u16) { self.muted = p < 8; self.timer_period = p; } } #[repr(C)] pub struct Triangle { /* linear counter */ cnt_rld: bool, cnt_lvl: u8, cnt_rld_val: u8, /* length counter */ len_lvl: u8, /* timer */ timer_period: u16, timer_lvl: u16, /* sequencer */ seq_cnt: u8, enabled: bool, /* misc */ ctrl: bool } impl Triangle { fn new() -> Self { Triangle { cnt_rld: false, cnt_lvl: 0, cnt_rld_val: 0, len_lvl: 0, timer_period: 0, timer_lvl: 0, seq_cnt: 0, enabled: false, ctrl: false } } fn load(&mut self, reader: &mut Read) -> bool { load_prefix(self, 0, reader) } fn save(&self, writer: &mut Write) -> bool { save_prefix(self, 0, writer) } pub fn write_reg1(&mut self, data: u8) { self.cnt_rld_val = data & 0x7f; self.ctrl = data >> 7 == 1; } pub fn write_reg3(&mut self, data: u8) { self.timer_period = (self.timer_period & 0xff00) | data as u16; } pub fn write_reg4(&mut self, data: u8) { self.set_len(data >> 3); self.timer_period = (self.timer_period & 0x00ff) | ((data as u16 & 7) << 8); self.timer_lvl = self.timer_period; self.cnt_rld = true; } pub fn output(&self) -> u8 { if self.enabled && self.timer_period >= 2 { TRI_SEQ_TABLE[self.seq_cnt as usize] } else { 0 } } fn tick_counter(&mut self) { if self.cnt_rld { self.cnt_lvl = self.cnt_rld_val } else if self.cnt_lvl > 0 { self.cnt_lvl -= 1 } if !self.ctrl { self.cnt_rld = false } } fn tick_length(&mut self) { if self.len_lvl > 0 && !self.ctrl { self.len_lvl -= 1 } } fn tick_timer(&mut self) { if self.len_lvl > 0 && self.cnt_lvl > 0 { if self.timer_lvl == 0 { self.timer_lvl = self.timer_period; if self.seq_cnt == 31 { self.seq_cnt = 0 } else { self.seq_cnt += 1 } } else { self.timer_lvl -= 1 } } } #[inline(always)] fn disable(&mut self) { self.len_lvl = 0; self.enabled = false; } #[inline(always)] fn enable(&mut self) { self.enabled = true } #[inline(always)] fn get_len(&self) -> u8 { self.len_lvl } #[inline(always)] fn set_len(&mut self, d: u8) { if self.enabled { self.len_lvl = LEN_TABLE[d as usize] } } } #[repr(C)] pub struct Noise { /* envelope */ env_period: u8, env_lvl: u8, decay_lvl: u8, env_start: bool, env_loop: bool, env_const: bool, env_vol: u8, /* length counter */ len_lvl: u8, /* timer */ timer_period: u16, timer_lvl: u16, /* rng */ shift_reg: u16, loop_noise: bool, /* channel */ enabled: bool, } impl Noise { pub fn new() -> Self { Noise {env_period: 0, env_lvl: 0, decay_lvl: 0, env_start: false, env_loop: false, env_const: false, env_vol: 0, len_lvl: 0, timer_period: 0, timer_lvl: 0, shift_reg: 1, loop_noise: false, enabled: false} } fn load(&mut self, reader: &mut Read) -> bool { load_prefix(self, 0, reader) } fn save(&self, writer: &mut Write) -> bool { save_prefix(self, 0, writer) } pub fn write_reg1(&mut self, data: u8) { self.env_loop = data & 0x20 == 0x20; self.env_const = data & 0x10 == 0x10; self.env_period = data & 0xf; self.env_vol = data & 0xf; } pub fn write_reg3(&mut self, data: u8) { self.loop_noise = (data >> 7) == 1; self.timer_period = NOISE_PERIOD_TABLE[data as usize & 0xf]; } pub fn write_reg4(&mut self, data: u8) { self.set_len(data >> 3); self.decay_lvl = 0xf; } pub fn output(&self) -> u8 { let env = if self.env_const { self.env_vol } else { self.decay_lvl }; let len = self.len_lvl > 0; let shift = self.shift_reg & 1 == 0; if self.enabled && shift && len { env } else { 0 } } fn tick_env(&mut self) { if !self.env_start { if self.env_lvl == 0 { self.env_lvl = self.env_period; if self.decay_lvl == 0 { if self.env_loop { self.decay_lvl = 0xf; } } else { self.decay_lvl -= 1; } } else { self.env_lvl -= 1; } } else { self.decay_lvl = 0xf; self.env_start = false; self.env_lvl = self.env_period; } } fn tick_length(&mut self) { if self.len_lvl > 0 && !self.env_loop { self.len_lvl -= 1 } } fn tick_timer(&mut self) { if self.timer_lvl == 0 { self.timer_lvl = self.timer_period; /* shift register is clocked */ let bit = if self.loop_noise {6} else {1}; let feedback = (self.shift_reg & 1) ^ ((self.shift_reg >> bit) & 1); self.shift_reg = (self.shift_reg >> 1) | (feedback << 14); } else { self.timer_lvl -= 1 } } #[inline(always)] fn disable(&mut self) { self.len_lvl = 0; self.enabled = false; } #[inline(always)] fn enable(&mut self) { self.enabled = true } #[inline(always)] fn get_len(&self) -> u8 { self.len_lvl } #[inline(always)] fn set_len(&mut self, d: u8) { if self.enabled { self.len_lvl = LEN_TABLE[d as usize] } } } #[repr(C)] pub struct DMC { dmc_loop: bool, dmc_cnt: u8, irq_enabled: bool, sample_addr: u16, sample_len: u16, shift_reg: u8, cur_addr: u16, rem_len: u16, level: u8, /* timer */ timer_lvl: u16, timer_period: u16, /* channel */ enabled: bool } impl DMC { pub fn new() -> Self { DMC { dmc_loop: false, dmc_cnt: 8, irq_enabled: false, sample_addr: 0, sample_len: 0, shift_reg: 0, cur_addr: 0, rem_len: 0, level: 0, timer_lvl: 0, timer_period: 0, enabled: false } } fn load(&mut self, reader: &mut Read) -> bool { load_prefix(self, 0, reader) } fn save(&self, writer: &mut Write) -> bool { save_prefix(self, 0, writer) } pub fn write_reg1(&mut self, data: u8) { self.irq_enabled = (data >> 7) == 1; self.dmc_loop = data & 0x40 == 0x40; self.timer_period = DMC_TABLE[(data & 0xf) as usize]; } pub fn write_reg2(&mut self, data: u8) { self.level = data & 0x7f } pub fn write_reg3(&mut self, data: u8) { self.sample_addr = 0xc000 | ((data as u16) << 6) } pub fn write_reg4(&mut self, data: u8) { self.sample_len = ((data as u16) << 4) | 0x1 } fn restart(&mut self) { self.cur_addr = self.sample_addr; self.rem_len = self.sample_len; } fn try_refill(&mut self, bus: &CPUBus) { if self.rem_len > 0 && self.dmc_cnt == 0 { bus.cpu_stall(4); self.shift_reg = bus.get_cpu().mem.read_without_tick(self.cur_addr); self.dmc_cnt = 8; self.cur_addr = self.cur_addr.wrapping_add(1); if self.cur_addr == 0x0 { self.cur_addr = 0x8000 } self.rem_len -= 1; if self.rem_len == 0 { if self.dmc_loop { self.restart() } else if self.irq_enabled { bus.get_cpu().trigger_irq() } } } } fn shift(&mut self) { if self.dmc_cnt == 0 { return } if self.shift_reg & 1 == 1 { if self.level < 126 { self.level += 2 } } else { if self.level > 1 { self.level -= 2 } } self.shift_reg >>= 1; self.dmc_cnt -= 1; } fn tick_timer(&mut self, bus: &CPUBus) { if !self.enabled { return } self.try_refill(bus); if self.timer_lvl == 0 { self.timer_lvl = self.timer_period; self.shift(); } else { self.timer_lvl -= 1 } } #[inline(always)] fn get_len(&self) -> u16 { self.rem_len } #[inline(always)] fn disable(&mut self) { self.enabled = false; self.rem_len = 0; } #[inline(always)] fn enable(&mut self) { self.enabled = true; if self.rem_len == 0 { self.restart() } } #[inline(always)] fn output(&self) -> u8 { self.level } } #[repr(C)] pub struct APU<'a> { /*-- begin state --*/ frame_lvl: u8, frame_mode: bool, /* true for 5-step mode */ frame_inh: bool, frame_int: bool, cycle_even: bool, /*-- end state --*/ /*-- begin sub-state --*/ pub pulse1: Pulse, pub pulse2: Pulse, pub triangle: Triangle, pub noise: Noise, pub dmc: DMC, lp_filter: LPFilter, hp_filter1: HPFilter, hp_filter2: HPFilter, frame_sampler: Sampler, audio_sampler: Sampler, /*-- end sub-state --*/ spkr: &'a mut Speaker, } macro_rules! APU_IGNORED_SIZE { () => (size_of::() + size_of::() + size_of::() + size_of::() + size_of::() + size_of::() + size_of::() + size_of::() + size_of::() + size_of::() + size_of::<&Speaker>()) } impl<'a> APU<'a> { pub fn new(spkr: &'a mut Speaker) -> Self { APU { pulse1: Pulse::new(false), pulse2: Pulse::new(true), triangle: Triangle::new(), noise: Noise::new(), dmc: DMC::new(), frame_lvl: 0, frame_mode: false, frame_int: false, frame_inh: true, frame_sampler: Sampler::new(CPU_FREQ, QUARTER_FRAME_FREQ), audio_sampler: Sampler::new(CPU_FREQ, AUDIO_SAMPLE_FREQ), cycle_even: false, spkr, lp_filter: LPFilter::new(), hp_filter1: HPFilter::new(HP_FACTOR1), hp_filter2: HPFilter::new(HP_FACTOR2) } } pub fn load(&mut self, reader: &mut Read) -> bool { load_prefix(self, APU_IGNORED_SIZE!(), reader) && self.pulse1.load(reader) && self.pulse2.load(reader) && self.triangle.load(reader) && self.noise.load(reader) && self.dmc.load(reader) && self.lp_filter.load(reader) && self.hp_filter1.load(reader) && self.hp_filter2.load(reader) && self.frame_sampler.load(reader) && self.audio_sampler.load(reader) } pub fn save(&self, writer: &mut Write) -> bool { save_prefix(self, APU_IGNORED_SIZE!(), writer) && self.pulse1.save(writer) && self.pulse2.save(writer) && self.triangle.save(writer) && self.noise.save(writer) && self.dmc.save(writer) && self.lp_filter.save(writer) && self.hp_filter1.save(writer) && self.hp_filter2.save(writer) && self.frame_sampler.save(writer) && self.audio_sampler.save(writer) } pub fn tick(&mut self, bus: &CPUBus) -> bool { let mut irq = false; if self.frame_sampler.tick() { irq = self.tick_frame_counter(); } if self.audio_sampler.tick() { let sample = self.output(); self.spkr.queue(sample); } self.tick_timer(bus); self.cycle_even = !self.cycle_even; irq } pub fn output(&mut self) -> i16 { let pulse_out = PULSE_TABLE[(self.pulse1.output() + self.pulse2.output()) as usize]; let tnd_out = TND_TABLE[(self.triangle.output() * 3 + self.noise.output() * 2 + self.dmc.output()) as usize]; //(pulse_out + tnd_out).wrapping_sub(0x8000) as i16 self.lp_filter.output( self.hp_filter2.output( self.hp_filter1.output( (pulse_out + tnd_out).wrapping_sub(0x8000) as i16))) } pub fn read_status(&mut self) -> u8 { let res = if self.pulse1.get_len() > 0 { 1 } else { 0 } | (if self.pulse2.get_len() > 0 { 1 } else { 0 }) << 1 | (if self.triangle.get_len() > 0 { 1 } else { 0 }) << 2 | (if self.noise.get_len() > 0 { 1 } else { 0 }) << 3 | (if self.dmc.get_len() > 0 { 1 } else { 0 }) << 4 | (if self.frame_int { 1 } else { 0 }) << 6; if self.frame_lvl != 3 { self.frame_int = false; /* clear interrupt flag */ } res } pub fn write_status(&mut self, data: u8) { match data & 0x1 { 0 => self.pulse1.disable(), _ => self.pulse1.enable() } match data & 0x2 { 0 => self.pulse2.disable(), _ => self.pulse2.enable() } match data & 0x4 { 0 => self.triangle.disable(), _ => self.triangle.enable() } match data & 0x8 { 0 => self.noise.disable(), _ => self.noise.enable() } match data & 0x10 { 0 => self.dmc.disable(), _ => self.dmc.enable() } } pub fn write_frame_counter(&mut self, data: u8) { self.frame_inh = data & 0x40 == 0x40; self.frame_mode = data >> 7 == 1; if self.frame_mode { self.tick_env_cnt(); self.tick_len_swp(); } } fn tick_timer(&mut self, bus: &CPUBus) { if self.cycle_even { self.pulse1.tick_timer(); self.pulse2.tick_timer(); self.noise.tick_timer(); self.dmc.tick_timer(bus); } self.triangle.tick_timer(); } fn tick_env_cnt(&mut self) { self.pulse1.tick_env(); self.pulse2.tick_env(); self.triangle.tick_counter(); self.noise.tick_env(); } fn tick_len_swp(&mut self) { self.pulse1.tick_length(); self.pulse1.tick_sweep(); self.pulse2.tick_length(); self.pulse2.tick_sweep(); self.triangle.tick_length(); self.noise.tick_length(); } fn tick_frame_counter(&mut self) -> bool { /* println!("{} {} {} {} {} {} {} {} {} {} {} {}", self.pulse1.output(), self.pulse2.output(), self.pulse1.seq_wave, self.pulse2.seq_wave, self.pulse1.timer_period, self.pulse2.timer_period, self.pulse1.timer_lvl, self.pulse2.timer_lvl, self.pulse1.env_period, self.pulse2.env_period, self.pulse1.env_lvl, self.pulse2.env_lvl ); */ let f = self.frame_lvl; match self.frame_mode { false => { self.frame_lvl = if f == 3 { 0 } else { f + 1 }; match self.frame_lvl { 1 | 3 => self.tick_env_cnt(), 2 => { self.tick_env_cnt(); self.tick_len_swp(); }, _ => { self.tick_env_cnt(); self.tick_len_swp(); if !self.frame_inh { self.frame_int = true; } }, }; }, true => { self.frame_lvl = if f == 4 { 0 } else { f + 1 }; match self.frame_lvl { 1 | 3 => self.tick_env_cnt(), 0 | 2 => { self.tick_env_cnt(); self.tick_len_swp(); }, _ => () } } } self.frame_int } }