/* TiMidity -- Experimental MIDI to WAVE converter Copyright (C) 1995 Tuukka Toivonen This program is free software; you can redistribute it and/or modify it under the terms of the Perl Artistic License, available in COPYING. */ #include #include #include #include "config.h" #include "common.h" #include "instrum.h" #include "playmidi.h" #include "output.h" #include "ctrlmode.h" #include "tables.h" #include "resample.h" #include "mix.h" /* Returns 1 if envelope runs out */ int recompute_envelope(int v) { int stage; stage = voice[v].envelope_stage; if (stage>5) { /* Envelope ran out. */ int tmp=(voice[v].status == VOICE_DIE); /* Already displayed as dead */ voice[v].status = VOICE_FREE; if(!tmp) ctl->note(v); return 1; } if (voice[v].sample->modes & MODES_ENVELOPE) { if (voice[v].status==VOICE_ON || voice[v].status==VOICE_SUSTAINED) { if (stage>2) { /* Freeze envelope until note turns off. Trumpets want this. */ voice[v].envelope_increment=0; return 0; } } } voice[v].envelope_stage=stage+1; if (voice[v].envelope_volume==voice[v].sample->envelope_offset[stage]) return recompute_envelope(v); voice[v].envelope_target=voice[v].sample->envelope_offset[stage]; voice[v].envelope_increment = voice[v].sample->envelope_rate[stage]; if (voice[v].envelope_targetmodes & MODES_ENVELOPE) { FLOAT_T ev = (FLOAT_T)vol_table[voice[v].envelope_volume>>23]; lramp *= ev; lamp *= ev; ceamp *= ev; ramp *= ev; rramp *= ev; lfeamp *= ev; } la = (int32)FSCALE(lamp,AMP_BITS); ra = (int32)FSCALE(ramp,AMP_BITS); lra = (int32)FSCALE(lramp,AMP_BITS); rra = (int32)FSCALE(rramp,AMP_BITS); cea = (int32)FSCALE(ceamp,AMP_BITS); lfea = (int32)FSCALE(lfeamp,AMP_BITS); if (la>MAX_AMP_VALUE) la=MAX_AMP_VALUE; if (ra>MAX_AMP_VALUE) ra=MAX_AMP_VALUE; if (lra>MAX_AMP_VALUE) lra=MAX_AMP_VALUE; if (rra>MAX_AMP_VALUE) rra=MAX_AMP_VALUE; if (cea>MAX_AMP_VALUE) cea=MAX_AMP_VALUE; if (lfea>MAX_AMP_VALUE) lfea=MAX_AMP_VALUE; voice[v].lr_mix=FINAL_VOLUME(lra); voice[v].left_mix=FINAL_VOLUME(la); voice[v].ce_mix=FINAL_VOLUME(cea); voice[v].right_mix=FINAL_VOLUME(ra); voice[v].rr_mix=FINAL_VOLUME(rra); voice[v].lfe_mix=FINAL_VOLUME(lfea); } else { if (voice[v].tremolo_phase_increment) lamp *= voice[v].tremolo_volume; if (voice[v].sample->modes & MODES_ENVELOPE) lamp *= (FLOAT_T)vol_table[voice[v].envelope_volume>>23]; la = (int32)FSCALE(lamp,AMP_BITS); if (la>MAX_AMP_VALUE) la=MAX_AMP_VALUE; voice[v].left_mix=FINAL_VOLUME(la); } } static int update_envelope(int v) { voice[v].envelope_volume += voice[v].envelope_increment; /* Why is there no ^^ operator?? */ if (((voice[v].envelope_increment < 0) && (voice[v].envelope_volume <= voice[v].envelope_target)) || ((voice[v].envelope_increment > 0) && (voice[v].envelope_volume >= voice[v].envelope_target))) { voice[v].envelope_volume = voice[v].envelope_target; if (recompute_envelope(v)) return 1; } return 0; } static void update_tremolo(int v) { int32 depth=voice[v].sample->tremolo_depth<<7; if (voice[v].tremolo_sweep) { /* Update sweep position */ voice[v].tremolo_sweep_position += voice[v].tremolo_sweep; if (voice[v].tremolo_sweep_position>=(1<>= SWEEP_SHIFT; } } voice[v].tremolo_phase += voice[v].tremolo_phase_increment; /* if (voice[v].tremolo_phase >= (SINE_CYCLE_LENGTH<> RATE_SHIFT) + 1.0) * depth * TREMOLO_AMPLITUDE_TUNING, 17)); /* I'm not sure about the +1.0 there -- it makes tremoloed voices' volumes on average the lower the higher the tremolo amplitude. */ } /* Returns 1 if the note died */ static int update_signal(int v) { if (voice[v].envelope_increment && update_envelope(v)) return 1; if (voice[v].tremolo_phase_increment) update_tremolo(v); apply_envelope_to_amp(v); return 0; } #ifdef LOOKUP_HACK # define MIXATION(a) *lp++ += mixup[(a<<8) | (uint8)s]; #else # define MIXATION(a) *lp++ += (a)*s; #endif #define MIXSKIP lp++ #define MIXMAX(a,b) *lp++ += ((a>b)?a:b) * s #define MIXCENT(a,b) *lp++ += (a/2+b/2) * s #define MIXHALF(a) *lp++ += (a>>1)*s; static void mix_mystery_signal(resample_t *sp, int32 *lp, int v, int count) { Voice *vp = voice + v; final_volume_t left_rear=vp->lr_mix, left=vp->left_mix, center=vp->ce_mix, right=vp->right_mix, right_rear=vp->rr_mix, lfe=vp->lfe_mix; int cc; resample_t s; if (!(cc = vp->control_counter)) { cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left_rear = vp->lr_mix; left = vp->left_mix; center = vp->ce_mix; right = vp->right_mix; right_rear = vp->rr_mix; lfe = vp->lfe_mix; } while (count) if (cc < count) { count -= cc; while (cc--) { s = *sp++; MIXATION(left); MIXATION(right); if (num_ochannels >= 4) { MIXATION(left_rear); MIXATION(right_rear); } if (num_ochannels == 6) { MIXATION(center); MIXATION(lfe); } } cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left_rear = vp->lr_mix; left = vp->left_mix; center = vp->ce_mix; right = vp->right_mix; right_rear = vp->rr_mix; lfe = vp->lfe_mix; } else { vp->control_counter = cc - count; while (count--) { s = *sp++; MIXATION(left); MIXATION(right); if (num_ochannels >= 4) { MIXATION(left_rear); MIXATION(right_rear); } if (num_ochannels == 6) { MIXATION(center); MIXATION(lfe); } } return; } } static void mix_center_signal(resample_t *sp, int32 *lp, int v, int count) { Voice *vp = voice + v; final_volume_t left=vp->left_mix; int cc; resample_t s; if (!(cc = vp->control_counter)) { cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left = vp->left_mix; } while (count) if (cc < count) { count -= cc; while (cc--) { s = *sp++; if (num_ochannels == 2) { MIXATION(left); MIXATION(left); } else if (num_ochannels == 4) { MIXATION(left); MIXSKIP; MIXATION(left); MIXSKIP; } else if (num_ochannels == 6) { MIXSKIP; MIXSKIP; MIXSKIP; MIXSKIP; MIXATION(left); MIXATION(left); } } cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left = vp->left_mix; } else { vp->control_counter = cc - count; while (count--) { s = *sp++; if (num_ochannels == 2) { MIXATION(left); MIXATION(left); } else if (num_ochannels == 4) { MIXATION(left); MIXSKIP; MIXATION(left); MIXSKIP; } else if (num_ochannels == 6) { MIXSKIP; MIXSKIP; MIXSKIP; MIXSKIP; MIXATION(left); MIXATION(left); } } return; } } static void mix_single_left_signal(resample_t *sp, int32 *lp, int v, int count) { Voice *vp = voice + v; final_volume_t left=vp->left_mix; int cc; resample_t s; if (!(cc = vp->control_counter)) { cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left = vp->left_mix; } while (count) if (cc < count) { count -= cc; while (cc--) { s = *sp++; if (num_ochannels == 2) { MIXATION(left); MIXSKIP; } if (num_ochannels >= 4) { MIXHALF(left); MIXSKIP; MIXATION(left); MIXSKIP; } if (num_ochannels == 6) { MIXSKIP; MIXATION(left); } } cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left = vp->left_mix; } else { vp->control_counter = cc - count; while (count--) { s = *sp++; if (num_ochannels == 2) { MIXATION(left); MIXSKIP; } if (num_ochannels >= 4) { MIXHALF(left); MIXSKIP; MIXATION(left); MIXSKIP; } if (num_ochannels == 6) { MIXSKIP; MIXATION(left); } } return; } } static void mix_single_right_signal(resample_t *sp, int32 *lp, int v, int count) { Voice *vp = voice + v; final_volume_t left=vp->left_mix; int cc; resample_t s; if (!(cc = vp->control_counter)) { cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left = vp->left_mix; } while (count) if (cc < count) { count -= cc; while (cc--) { s = *sp++; if (num_ochannels == 2) { MIXSKIP; MIXATION(left); } if (num_ochannels >= 4) { MIXSKIP; MIXHALF(left); MIXSKIP; MIXATION(left); } if (num_ochannels == 6) { MIXSKIP; MIXATION(left); } } cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left = vp->left_mix; } else { vp->control_counter = cc - count; while (count--) { s = *sp++; if (num_ochannels == 2) { MIXSKIP; MIXATION(left); } if (num_ochannels >= 4) { MIXSKIP; MIXHALF(left); MIXSKIP; MIXATION(left); } if (num_ochannels == 6) { MIXSKIP; MIXATION(left); } } return; } } static void mix_mono_signal(resample_t *sp, int32 *lp, int v, int count) { Voice *vp = voice + v; final_volume_t left=vp->left_mix; int cc; resample_t s; if (!(cc = vp->control_counter)) { cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left = vp->left_mix; } while (count) if (cc < count) { count -= cc; while (cc--) { s = *sp++; MIXATION(left); } cc = control_ratio; if (update_signal(v)) return; /* Envelope ran out */ left = vp->left_mix; } else { vp->control_counter = cc - count; while (count--) { s = *sp++; MIXATION(left); } return; } } static void mix_mystery(resample_t *sp, int32 *lp, int v, int count) { final_volume_t left_rear=voice[v].lr_mix, left=voice[v].left_mix, center=voice[v].ce_mix, right=voice[v].right_mix, right_rear=voice[v].rr_mix, lfe=voice[v].lfe_mix; resample_t s; while (count--) { s = *sp++; MIXATION(left); MIXATION(right); if (num_ochannels >= 4) { MIXATION(left_rear); MIXATION(right_rear); } if (num_ochannels == 6) { MIXATION(center); MIXATION(lfe); } } } static void mix_center(resample_t *sp, int32 *lp, int v, int count) { final_volume_t left=voice[v].left_mix; resample_t s; while (count--) { s = *sp++; if (num_ochannels == 2) { MIXATION(left); MIXATION(left); } else if (num_ochannels == 4) { MIXATION(left); MIXATION(left); MIXSKIP; MIXSKIP; } else if (num_ochannels == 6) { MIXSKIP; MIXSKIP; MIXSKIP; MIXSKIP; MIXATION(left); MIXATION(left); } } } static void mix_single_left(resample_t *sp, int32 *lp, int v, int count) { final_volume_t left=voice[v].left_mix; resample_t s; while (count--) { s = *sp++; if (num_ochannels == 2) { MIXATION(left); MIXSKIP; } if (num_ochannels >= 4) { MIXHALF(left); MIXSKIP; MIXATION(left); MIXSKIP; } if (num_ochannels == 6) { MIXSKIP; MIXATION(left); } } } static void mix_single_right(resample_t *sp, int32 *lp, int v, int count) { final_volume_t left=voice[v].left_mix; resample_t s; while (count--) { s = *sp++; if (num_ochannels == 2) { MIXSKIP; MIXATION(left); } if (num_ochannels >= 4) { MIXSKIP; MIXHALF(left); MIXSKIP; MIXATION(left); } if (num_ochannels == 6) { MIXSKIP; MIXATION(left); } } } static void mix_mono(resample_t *sp, int32 *lp, int v, int count) { final_volume_t left=voice[v].left_mix; resample_t s; while (count--) { s = *sp++; MIXATION(left); } } /* Ramp a note out in c samples */ static void ramp_out(resample_t *sp, int32 *lp, int v, int32 c) { /* should be final_volume_t, but uint8 gives trouble. */ int32 left_rear, left, center, right, right_rear, lfe, li, ri; resample_t s = 0; /* silly warning about uninitialized s */ /* Fix by James Caldwell */ if ( c == 0 ) c = 1; left = voice[v].left_mix; li = -(left/c); if (!li) li = -1; /* printf("Ramping out: left=%d, c=%d, li=%d\n", left, c, li); */ if (!(play_mode->encoding & PE_MONO)) { if (voice[v].panned==PANNED_MYSTERY) { left_rear = voice[v].lr_mix; center=voice[v].ce_mix; right=voice[v].right_mix; right_rear = voice[v].rr_mix; lfe = voice[v].lfe_mix; ri=-(right/c); while (c--) { left_rear += li; if (left_rear<0) left_rear=0; left += li; if (left<0) left=0; center += li; if (center<0) center=0; right += ri; if (right<0) right=0; right_rear += ri; if (right_rear<0) right_rear=0; lfe += li; if (lfe<0) lfe=0; s=*sp++; MIXATION(left); MIXATION(right); if (num_ochannels >= 4) { MIXATION(left_rear); MIXATION(right_rear); } if (num_ochannels == 6) { MIXATION(center); MIXATION(lfe); } } } else if (voice[v].panned==PANNED_CENTER) { while (c--) { left += li; if (left<0) return; s=*sp++; if (num_ochannels == 2) { MIXATION(left); MIXATION(left); } else if (num_ochannels == 4) { MIXATION(left); MIXATION(left); MIXSKIP; MIXSKIP; } else if (num_ochannels == 6) { MIXSKIP; MIXSKIP; MIXSKIP; MIXSKIP; MIXATION(left); MIXATION(left); } } } else if (voice[v].panned==PANNED_LEFT) { while (c--) { left += li; if (left<0) return; s=*sp++; MIXATION(left); MIXSKIP; if (num_ochannels >= 4) { MIXATION(left); MIXSKIP; } if (num_ochannels == 6) { MIXATION(left); MIXATION(left); } } } else if (voice[v].panned==PANNED_RIGHT) { while (c--) { left += li; if (left<0) return; s=*sp++; MIXSKIP; MIXATION(left); if (num_ochannels >= 4) { MIXSKIP; MIXATION(left); } if (num_ochannels == 6) { MIXATION(left); MIXATION(left); } } } } else { /* Mono output. */ while (c--) { left += li; if (left<0) return; s=*sp++; MIXATION(left); } } } /**************** interface function ******************/ void mix_voice(int32 *buf, int v, int32 c) { Voice *vp=voice+v; int32 count=c; resample_t *sp; if (c<0) return; if (vp->status==VOICE_DIE) { if (count>=MAX_DIE_TIME) count=MAX_DIE_TIME; sp=resample_voice(v, &count); ramp_out(sp, buf, v, count); vp->status=VOICE_FREE; } else { sp=resample_voice(v, &count); if (count<0) return; if (play_mode->encoding & PE_MONO) { /* Mono output. */ if (vp->envelope_increment || vp->tremolo_phase_increment) mix_mono_signal(sp, buf, v, count); else mix_mono(sp, buf, v, count); } else { if (vp->panned == PANNED_MYSTERY) { if (vp->envelope_increment || vp->tremolo_phase_increment) mix_mystery_signal(sp, buf, v, count); else mix_mystery(sp, buf, v, count); } else if (vp->panned == PANNED_CENTER) { if (vp->envelope_increment || vp->tremolo_phase_increment) mix_center_signal(sp, buf, v, count); else mix_center(sp, buf, v, count); } else { /* It's either full left or full right. In either case, every other sample is 0. Just get the offset right: */ if (vp->envelope_increment || vp->tremolo_phase_increment) { if (vp->panned == PANNED_RIGHT) mix_single_right_signal(sp, buf, v, count); else mix_single_left_signal(sp, buf, v, count); } else { if (vp->panned == PANNED_RIGHT) mix_single_right(sp, buf, v, count); else mix_single_left(sp, buf, v, count); } } } } }