/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2005 Stepan Moskovchenko * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "plugin.h" #include "guspat.h" #include "midiutil.h" #include "synth.h" void readTextBlock(int file, char * buf) { char c = 0; do { c = readChar(file); } while(c == '\n' || c == ' ' || c=='\t'); rb->lseek(file, -1, SEEK_CUR); int cp = 0; do { c = readChar(file); buf[cp] = c; cp++; } while (c != '\n' && c != ' ' && c != '\t' && !eof(file)); buf[cp-1]=0; rb->lseek(file, -1, SEEK_CUR); } void resetControllers() { int a=0; for(a=0; anumTracks; a++) { unsigned int ts=0; if(mf->tracks[a] == NULL) { midi_debug("NULL TRACK !!!"); rb->splash(HZ*2, "Null Track in loader."); return -1; } for(ts=0; tstracks[a]->numEvents; ts++) { if((getEvent(mf->tracks[a], ts)->status) == (MIDI_NOTE_ON+9)) drumUsed[getEvent(mf->tracks[a], ts)->d1]=1; if( (getEvent(mf->tracks[a], ts)->status & 0xF0) == MIDI_PRGM) patchUsed[getEvent(mf->tracks[a], ts)->d1]=1; } } } else { /* Initialize the whole drum set */ for(a=0; a<128; a++) drumUsed[a]=1; } int file = rb->open(filename, O_RDONLY); if(file < 0) { midi_debug(""); midi_debug("No MIDI patchset found."); midi_debug("Please install the instruments."); midi_debug("See Rockbox page for more info."); rb->splash(HZ*2, "No Instruments"); return -1; } char name[40]; char fn[40]; /* Scan our config file and load the right patches as needed */ int c = 0; name[0] = '\0'; midi_debug("Loading instruments"); for(a=0; a<128; a++) { while(readChar(file)!=' ' && !eof(file)); readTextBlock(file, name); rb->snprintf(fn, 40, ROCKBOX_DIR "/patchset/%s.pat", name); /* midi_debug("\nLOADING: <%s> ", fn); */ if(patchUsed[a]==1) { patchSet[a]=gusload(fn); if(patchSet[a] == NULL) /* There was an error loading it */ return -1; } while((c != '\n')) c = readChar(file); } rb->close(file); file = rb->open(drumConfig, O_RDONLY); if(file < 0) { rb->splash(HZ*2, "Bad drum config. Did you install the patchset?"); return -1; } /* Scan our config file and load the drum data */ int idx=0; char number[30]; midi_debug("Loading drums"); while(!eof(file)) { readTextBlock(file, number); readTextBlock(file, name); rb->snprintf(fn, 40, ROCKBOX_DIR "/patchset/%s.pat", name); idx = rb->atoi(number); if(idx == 0) break; if(drumUsed[idx]==1) { drumSet[idx]=gusload(fn); if(drumSet[idx] == NULL) /* Error loading patch */ return -1; } while((c != '\n') && (c != 255) && (!eof(file))) c = readChar(file); } rb->close(file); return 0; } void setPoint(struct SynthObject * so, int pt) ICODE_ATTR; void setPoint(struct SynthObject * so, int pt) { if(so->ch==9) /* Drums, no ADSR */ { so->curOffset = 1<<27; so->curRate = 1; return; } if(so->wf==NULL) { midi_debug("Crap... null waveform..."); exit(1); } if(so->wf->envRate==NULL) { midi_debug("Waveform has no envelope set"); exit(1); } so->curPoint = pt; int r; int rate = so->wf->envRate[pt]; r=3-((rate>>6) & 0x3); /* Some blatant Timidity code for rate conversion... */ r*=3; r = (rate & 0x3f) << r; /* * Okay. This is the rate shift. Timidity defaults to 9, and sets * it to 10 if you use the fast decay option. Slow decay sounds better * on some files, except on some other files... you get chords that aren't * done decaying yet.. and they dont harmonize with the next chord and it * sounds like utter crap. Yes, even Timitidy does that. So I'm going to * default this to 10, and maybe later have an option to set it to 9 * for longer decays. */ so->curRate = r<<10; /* * Do this here because the patches assume a 44100 sampling rate * We've halved our sampling rate, ergo the ADSR code will be * called half the time. Ergo, double the rate to keep stuff * sounding right. * * Or just move the 1 up one line to optimize a tiny bit. */ /* so->curRate = so->curRate << 1; */ so->targetOffset = so->wf->envOffset[pt]<<(20); if(pt==0) so->curOffset = 0; } static inline void synthVoice(struct SynthObject * so, int32_t * out, unsigned int samples) { struct GWaveform * wf; register int s1; register int s2; register unsigned int cp_temp = so->cp; wf = so->wf; const int16_t *sample_data = wf->data; const unsigned int pan = chPan[so->ch]; const int volscale = so->volscale; const int mode_mask24 = wf->mode&24; const int mode_mask28 = wf->mode&28; const int mode_mask_looprev = wf->mode&LOOP_REVERSE; const unsigned int num_samples = (wf->numSamples-1) << FRACTSIZE; const unsigned int end_loop = wf->endLoop << FRACTSIZE; const unsigned int start_loop = wf->startLoop << FRACTSIZE; const int diff_loop = end_loop-start_loop; bool rampdown = (so->state == STATE_RAMPDOWN); const bool ch_9 = (so->ch == 9); while(LIKELY(samples-- > 0)) { /* Is voice being ramped? */ if(UNLIKELY(rampdown)) { if(so->decay != 0) /* Ramp has been started */ { so->decay = so->decay / 2; if(so->decay < 10 && so->decay > -10) so->isUsed = false; s1 = so->decay; s2 = s1 * pan; s1 = (s1 << 7) -s2; *(out++) += ((s1 << 9) & 0xFFFF0000) | ((s2 >> 7) &0xFFFF); continue; } } else /* OK to advance voice */ { cp_temp += so->delta; } s2 = sample_data[(cp_temp >> FRACTSIZE)+1]; if(LIKELY(mode_mask28)) { /* LOOP_REVERSE|LOOP_PINGPONG = 24 */ if(UNLIKELY(mode_mask24 && so->loopState == STATE_LOOPING && (cp_temp < start_loop))) { if(UNLIKELY(mode_mask_looprev)) { cp_temp += diff_loop; s2 = sample_data[cp_temp >> FRACTSIZE]; } else { so->delta = -so->delta; /* At this point cp_temp is wrong. We need to take a step */ } } if(UNLIKELY(cp_temp >= end_loop)) { so->loopState = STATE_LOOPING; if(UNLIKELY(!mode_mask24)) { cp_temp -= diff_loop; s2 = sample_data[cp_temp >> FRACTSIZE]; } else { so->delta = -so->delta; } } } /* Have we overrun? */ if(UNLIKELY(cp_temp >= num_samples)) { cp_temp -= so->delta; s2 = sample_data[(cp_temp >> FRACTSIZE)+1]; if (!rampdown) /* stop voice */ { rampdown = true; so->decay = 0; } } /* Better, working, linear interpolation */ s1 = sample_data[cp_temp >> FRACTSIZE]; s1 +=((signed)((s2 - s1) * (cp_temp & ((1<>FRACTSIZE); if(UNLIKELY(so->curRate == 0)) { if (!rampdown) /* stop voice */ { rampdown = true; so->decay = 0; } // so->isUsed = false; } if(LIKELY(!ch_9 && !rampdown)) /* Stupid ADSR code... and don't do ADSR for drums */ { if(UNLIKELY(so->curOffset < so->targetOffset)) { so->curOffset += (so->curRate); if(UNLIKELY(so -> curOffset > so->targetOffset && so->curPoint != 2)) { if(UNLIKELY(so->curPoint != 5)) { setPoint(so, so->curPoint+1); } else if (!rampdown) /* stop voice */ { rampdown = true; so->decay = 0; } } } else { so->curOffset -= (so->curRate); if(UNLIKELY(so -> curOffset < so->targetOffset && so->curPoint != 2)) { if(UNLIKELY(so->curPoint != 5)) { setPoint(so, so->curPoint+1); } else if (!rampdown) /* stop voice */ { rampdown = true; so->decay = 0; } } } } if(UNLIKELY(so->curOffset < 0)) { so->curOffset = so->targetOffset; if (!rampdown) { rampdown = true; so->decay = 0; } } s1 = s1 * (so->curOffset >> 22) >> 8; /* Scaling by channel volume and note volume is done in sequencer.c */ /* That saves us some multiplication and pointer operations */ s1 = s1 * volscale >> 14; /* need to set ramp beginning */ if(UNLIKELY(rampdown && so->decay == 0)) { so->decay = s1; if(so->decay == 0) so->decay = 1; /* stupid junk.. */ } s2 = s1 * pan; s1 = (s1 << 7) - s2; *(out++) += ((s1 << 9) & 0xFFFF0000) | ((s2 >> 7) &0xFFFF); } /* store these again */ if (rampdown) so->state = STATE_RAMPDOWN; so->cp = cp_temp; return; } /* buffer to hold all the samples for the current tick, this is a hack neccesary for coldfire targets as pcm_play_data uses the dma which cannot access iram */ int32_t samp_buf[512] IBSS_ATTR; /* synth num_samples samples and write them to the */ /* buffer pointed to by buf_ptr */ void synthSamples(int32_t *buf_ptr, unsigned int num_samples) ICODE_ATTR; void synthSamples(int32_t *buf_ptr, unsigned int num_samples) { if (UNLIKELY(num_samples > 512)) DEBUGF("num_samples is too big!\n"); else { int i; struct SynthObject *voicept; rb->memset(samp_buf, 0, num_samples*4); for(i=0; i < MAX_VOICES; i++) { voicept=&voices[i]; if(voicept->isUsed) { synthVoice(voicept, samp_buf, num_samples); } } rb->memcpy(buf_ptr, samp_buf, num_samples*4); } /* TODO: Automatic Gain Control, anyone? */ /* Or, should this be implemented on the DSP's output volume instead? */ return; /* No more ghetto lowpass filter. Linear interpolation works well. */ }