// Nes_Snd_Emu 0.1.7. http://www.slack.net/~ant/ #include "Nes_Vrc6_Apu.h" /* Copyright (C) 2003-2006 Shay Green. This module is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This module is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this module; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "blargg_source.h" Nes_Vrc6_Apu::Nes_Vrc6_Apu() { output( NULL ); volume( 1.0 ); reset(); } Nes_Vrc6_Apu::~Nes_Vrc6_Apu() { } void Nes_Vrc6_Apu::reset() { last_time = 0; for ( int i = 0; i < osc_count; i++ ) { Vrc6_Osc& osc = oscs [i]; for ( int j = 0; j < reg_count; j++ ) osc.regs [j] = 0; osc.delay = 0; osc.last_amp = 0; osc.phase = 1; osc.amp = 0; } } void Nes_Vrc6_Apu::output( Blip_Buffer* buf ) { for ( int i = 0; i < osc_count; i++ ) osc_output( i, buf ); } void Nes_Vrc6_Apu::run_until( nes_time_t time ) { run_square( oscs [0], time ); run_square( oscs [1], time ); run_saw( time ); last_time = time; } void Nes_Vrc6_Apu::write_osc( nes_time_t time, int osc_index, int reg, int data ) { run_until( time ); oscs [osc_index].regs [reg] = data; } void Nes_Vrc6_Apu::end_frame( nes_time_t time ) { if ( time > last_time ) run_until( time ); last_time -= time; } void Nes_Vrc6_Apu::save_state( vrc6_apu_state_t* out ) const { out->saw_amp = oscs [2].amp; for ( int i = 0; i < osc_count; i++ ) { Vrc6_Osc const& osc = oscs [i]; for ( int r = 0; r < reg_count; r++ ) out->regs [i] [r] = osc.regs [r]; out->delays [i] = osc.delay; out->phases [i] = osc.phase; } } void Nes_Vrc6_Apu::load_state( vrc6_apu_state_t const& in ) { reset(); oscs [2].amp = in.saw_amp; for ( int i = 0; i < osc_count; i++ ) { Vrc6_Osc& osc = oscs [i]; for ( int r = 0; r < reg_count; r++ ) osc.regs [r] = in.regs [i] [r]; osc.delay = in.delays [i]; osc.phase = in.phases [i]; } if ( !oscs [2].phase ) oscs [2].phase = 1; //Run sound channels for 0 cycles for clean audio after loading state this->run_until(this->last_time); } void Nes_Vrc6_Apu::run_square( Vrc6_Osc& osc, nes_time_t end_time ) { Blip_Buffer* output = osc.output; if ( !output ) return; int volume = osc.regs [0] & 15; if ( !(osc.regs [2] & 0x80) ) volume = 0; int gate = osc.regs [0] & 0x80; int duty = ((osc.regs [0] >> 4) & 7) + 1; int delta = ((gate || osc.phase < duty) ? volume : 0) - osc.last_amp; nes_time_t time = last_time; if ( delta ) { osc.last_amp += delta; square_synth.offset( time, delta, output ); } time += osc.delay; osc.delay = 0; int period = osc.period(); if ( volume && !gate && period > 4 ) { if ( time < end_time ) { int phase = osc.phase; do { phase++; if ( phase == 16 ) { phase = 0; osc.last_amp = volume; square_synth.offset( time, volume, output ); } if ( phase == duty ) { osc.last_amp = 0; square_synth.offset( time, -volume, output ); } time += period; } while ( time < end_time ); osc.phase = phase; } osc.delay = time - end_time; } } void Nes_Vrc6_Apu::run_saw( nes_time_t end_time ) { Vrc6_Osc& osc = oscs [2]; Blip_Buffer* output = osc.output; if ( !output ) return; int amp = osc.amp; int amp_step = osc.regs [0] & 0x3F; nes_time_t time = last_time; int last_amp = osc.last_amp; if ( !(osc.regs [2] & 0x80) || !(amp_step | amp) ) { osc.delay = 0; int delta = (amp >> 3) - last_amp; last_amp = amp >> 3; saw_synth.offset( time, delta, output ); } else { time += osc.delay; if ( time < end_time ) { int period = osc.period() * 2; int phase = osc.phase; do { if ( --phase == 0 ) { phase = 7; amp = 0; } int delta = (amp >> 3) - last_amp; if ( delta ) { last_amp = amp >> 3; saw_synth.offset( time, delta, output ); } time += period; amp = (amp + amp_step) & 0xFF; } while ( time < end_time ); osc.phase = phase; osc.amp = amp; } osc.delay = time - end_time; } osc.last_amp = last_amp; }