auto APU::DMC::start() -> void { if(length_counter == 0) { read_addr = 0x4000 + (addr_latch << 6); length_counter = (length_latch << 4) + 1; } } auto APU::DMC::stop() -> void { length_counter = 0; dma_delay_counter = 0; cpu.rdyLine(1); cpu.rdyAddr(false); } auto APU::DMC::clock() -> uint8 { uint8 result = dac_latch; if(dma_delay_counter > 0) { dma_delay_counter--; if(dma_delay_counter == 1) { cpu.rdyAddr(true, 0x8000 | read_addr); } else if(dma_delay_counter == 0) { cpu.rdyLine(1); cpu.rdyAddr(false); dma_buffer = cpu.mdr(); have_dma_buffer = true; length_counter--; read_addr++; if(length_counter == 0) { if(loop_mode) { start(); } else if(irq_enable) { irq_pending = true; apu.set_irq_line(); } } } } if(--period_counter == 0) { if(have_sample) { int delta = (((sample >> bit_counter) & 1) << 2) - 2; uint data = dac_latch + delta; if((data & 0x80) == 0) dac_latch = data; } if(++bit_counter == 0) { if(have_dma_buffer) { have_sample = true; sample = dma_buffer; have_dma_buffer = false; } else { have_sample = false; } } period_counter = ntsc_dmc_period_table[period]; } if(length_counter > 0 && have_dma_buffer == false && dma_delay_counter == 0) { cpu.rdyLine(0); dma_delay_counter = 4; } return result; } auto APU::DMC::power() -> void { } auto APU::DMC::reset() -> void { length_counter = 0; irq_pending = 0; period = 0; period_counter = ntsc_dmc_period_table[0]; irq_enable = 0; loop_mode = 0; dac_latch = 0; addr_latch = 0; length_latch = 0; read_addr = 0; dma_delay_counter = 0; bit_counter = 0; have_dma_buffer = 0; dma_buffer = 0; have_sample = 0; sample = 0; } auto APU::DMC::serialize(serializer& s) -> void { s.integer(length_counter); s.integer(irq_pending); s.integer(period); s.integer(period_counter); s.integer(irq_enable); s.integer(loop_mode); s.integer(dac_latch); s.integer(addr_latch); s.integer(length_latch); s.integer(read_addr); s.integer(dma_delay_counter); s.integer(bit_counter); s.integer(have_dma_buffer); s.integer(dma_buffer); s.integer(have_sample); s.integer(sample); }