/* FluidSynth - A Software Synthesizer * * Copyright (C) 2003 Peter Hanappe and others. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public License * as published by the Free Software Foundation; either version 2 of * the License, or (at your option) any later version. * * This library 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the Free * Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA * 02110-1301, USA */ #include "fluid_midi.h" #include "fluid_sys.h" #include "fluid_synth.h" #include "fluid_settings.h" static int fluid_midi_event_length(unsigned char event); /* Read the entire contents of a file into memory, allocating enough memory * for the file, and returning the length and the buffer. * Note: This rewinds the file to the start before reading. * Returns NULL if there was an error reading or allocating memory. */ static char* fluid_file_read_full(fluid_file fp, size_t* length); #define READ_FULL_INITIAL_BUFLEN 1024 #if 0 // disable file I/O with Ardour /*************************************************************** * * MIDIFILE */ /** * Return a new MIDI file handle for parsing an already-loaded MIDI file. * @internal * @param buffer Pointer to full contents of MIDI file (borrows the pointer). * The caller must not free buffer until after the fluid_midi_file is deleted. * @param length Size of the buffer in bytes. * @return New MIDI file handle or NULL on error. */ fluid_midi_file * new_fluid_midi_file(const char* buffer, size_t length) { fluid_midi_file *mf; mf = FLUID_NEW(fluid_midi_file); if (mf == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); return NULL; } FLUID_MEMSET(mf, 0, sizeof(fluid_midi_file)); mf->c = -1; mf->running_status = -1; mf->buffer = buffer; mf->buf_len = length; mf->buf_pos = 0; mf->eof = FALSE; if (fluid_midi_file_read_mthd(mf) != FLUID_OK) { FLUID_FREE(mf); return NULL; } return mf; } static char* fluid_file_read_full(fluid_file fp, size_t* length) { size_t buflen; char* buffer; size_t n; /* Work out the length of the file in advance */ if (FLUID_FSEEK(fp, 0, SEEK_END) != 0) { FLUID_LOG(FLUID_ERR, "File load: Could not seek within file"); return NULL; } buflen = ftell(fp); if (FLUID_FSEEK(fp, 0, SEEK_SET) != 0) { FLUID_LOG(FLUID_ERR, "File load: Could not seek within file"); return NULL; } FLUID_LOG(FLUID_DBG, "File load: Allocating %d bytes", buflen); buffer = FLUID_MALLOC(buflen); if (buffer == NULL) { FLUID_LOG(FLUID_PANIC, "Out of memory"); return NULL; } n = FLUID_FREAD(buffer, 1, buflen, fp); if (n != buflen) { FLUID_LOG(FLUID_ERR, "Only read %d bytes; expected %d", n, buflen); FLUID_FREE(buffer); return NULL; }; *length = n; return buffer; } /** * Delete a MIDI file handle. * @internal * @param mf MIDI file handle to close and free. */ void delete_fluid_midi_file (fluid_midi_file *mf) { if (mf == NULL) { return; } FLUID_FREE(mf); return; } /* * Gets the next byte in a MIDI file, taking into account previous running status. * * returns FLUID_FAILED if EOF or read error */ int fluid_midi_file_getc (fluid_midi_file *mf) { unsigned char c; if (mf->c >= 0) { c = mf->c; mf->c = -1; } else { if (mf->buf_pos >= mf->buf_len) { mf->eof = TRUE; return FLUID_FAILED; } c = mf->buffer[mf->buf_pos++]; mf->trackpos++; } return (int) c; } /* * Saves a byte to be returned the next time fluid_midi_file_getc() is called, * when it is necessary according to running status. */ int fluid_midi_file_push(fluid_midi_file *mf, int c) { mf->c = c; return FLUID_OK; } /* * fluid_midi_file_read */ int fluid_midi_file_read(fluid_midi_file *mf, void *buf, int len) { int num = len < mf->buf_len - mf->buf_pos ? len : mf->buf_len - mf->buf_pos; if (num != len) { mf->eof = TRUE; } if (num < 0) { num = 0; } /* Note: Read bytes, even if there aren't enough, but only increment * trackpos if successful (emulates old behaviour of fluid_midi_file_read) */ FLUID_MEMCPY(buf, mf->buffer+mf->buf_pos, num); mf->buf_pos += num; if (num == len) mf->trackpos += num; #if DEBUG else FLUID_LOG(FLUID_DBG, "Could not read the requested number of bytes"); #endif return (num != len) ? FLUID_FAILED : FLUID_OK; } /* * fluid_midi_file_skip */ int fluid_midi_file_skip (fluid_midi_file *mf, int skip) { int new_pos = mf->buf_pos + skip; /* Mimic the behaviour of fseek: Error to seek past the start of file, but * OK to seek past end (this just puts it into the EOF state). */ if (new_pos < 0) { FLUID_LOG(FLUID_ERR, "Failed to seek position in file"); return FLUID_FAILED; } /* Clear the EOF flag, even if moved past the end of the file (this is * consistent with the behaviour of fseek). */ mf->eof = FALSE; mf->buf_pos = new_pos; return FLUID_OK; } /* * fluid_midi_file_eof */ int fluid_midi_file_eof(fluid_midi_file* mf) { /* Note: This does not simply test whether the file read pointer is past * the end of the file. It mimics the behaviour of feof by actually * testing the stateful EOF condition, which is set to TRUE if getc or * fread have attempted to read past the end (but not if they have * precisely reached the end), but reset to FALSE upon a successful seek. */ return mf->eof; } /* * fluid_midi_file_read_mthd */ int fluid_midi_file_read_mthd(fluid_midi_file *mf) { char mthd[15]; if (fluid_midi_file_read(mf, mthd, 14) != FLUID_OK) { return FLUID_FAILED; } if ((FLUID_STRNCMP(mthd, "MThd", 4) != 0) || (mthd[7] != 6) || (mthd[9] > 2)) { FLUID_LOG(FLUID_ERR, "Doesn't look like a MIDI file: invalid MThd header"); return FLUID_FAILED; } mf->type = mthd[9]; mf->ntracks = (unsigned) mthd[11]; mf->ntracks += (unsigned int) (mthd[10]) << 16; if ((mthd[12]) < 0) { mf->uses_smpte = 1; mf->smpte_fps = -mthd[12]; mf->smpte_res = (unsigned) mthd[13]; FLUID_LOG(FLUID_ERR, "File uses SMPTE timing -- Not implemented yet"); return FLUID_FAILED; } else { mf->uses_smpte = 0; mf->division = (mthd[12] << 8) | (mthd[13] & 0xff); FLUID_LOG(FLUID_DBG, "Division=%d", mf->division); } return FLUID_OK; } /* * fluid_midi_file_load_tracks */ int fluid_midi_file_load_tracks(fluid_midi_file *mf, fluid_player_t *player) { int i; for (i = 0; i < mf->ntracks; i++) { if (fluid_midi_file_read_track(mf, player, i) != FLUID_OK) { return FLUID_FAILED; } } return FLUID_OK; } /* * fluid_isasciistring */ int fluid_isasciistring(char *s) { int i; int len = (int) FLUID_STRLEN(s); for (i = 0; i < len; i++) { if (!fluid_isascii(s[i])) { return 0; } } return 1; } /* * fluid_getlength */ long fluid_getlength(unsigned char *s) { long i = 0; i = s[3] | (s[2] << 8) | (s[1] << 16) | (s[0] << 24); return i; } /* * fluid_midi_file_read_tracklen */ int fluid_midi_file_read_tracklen(fluid_midi_file *mf) { unsigned char length[5]; if (fluid_midi_file_read(mf, length, 4) != FLUID_OK) { return FLUID_FAILED; } mf->tracklen = fluid_getlength(length); mf->trackpos = 0; mf->eot = 0; return FLUID_OK; } /* * fluid_midi_file_eot */ int fluid_midi_file_eot(fluid_midi_file *mf) { #if DEBUG if (mf->trackpos > mf->tracklen) { printf("track overrun: %d > %d\n", mf->trackpos, mf->tracklen); } #endif return mf->eot || (mf->trackpos >= mf->tracklen); } /* * fluid_midi_file_read_track */ int fluid_midi_file_read_track(fluid_midi_file *mf, fluid_player_t *player, int num) { fluid_track_t *track; unsigned char id[5], length[5]; int found_track = 0; int skip; if (fluid_midi_file_read(mf, id, 4) != FLUID_OK) { return FLUID_FAILED; } id[4] = '\0'; mf->dtime = 0; while (!found_track) { if (fluid_isasciistring((char *) id) == 0) { FLUID_LOG(FLUID_ERR, "An non-ascii track header found, corrupt file"); return FLUID_FAILED; } else if (strcmp((char *) id, "MTrk") == 0) { found_track = 1; if (fluid_midi_file_read_tracklen(mf) != FLUID_OK) { return FLUID_FAILED; } track = new_fluid_track(num); if (track == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); return FLUID_FAILED; } while (!fluid_midi_file_eot(mf)) { if (fluid_midi_file_read_event(mf, track) != FLUID_OK) { delete_fluid_track(track); return FLUID_FAILED; } } /* Skip remaining track data, if any */ if (mf->trackpos < mf->tracklen) { if (fluid_midi_file_skip(mf, mf->tracklen - mf->trackpos) != FLUID_OK) { delete_fluid_track(track); return FLUID_FAILED; } } if (fluid_player_add_track(player, track) != FLUID_OK) { delete_fluid_track(track); return FLUID_FAILED; } } else { found_track = 0; if (fluid_midi_file_read(mf, length, 4) != FLUID_OK) { return FLUID_FAILED; } skip = fluid_getlength(length); /* fseek(mf->fp, skip, SEEK_CUR); */ if (fluid_midi_file_skip(mf, skip) != FLUID_OK) { return FLUID_FAILED; } } } if (fluid_midi_file_eof(mf)) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } return FLUID_OK; } /* * fluid_midi_file_read_varlen */ int fluid_midi_file_read_varlen(fluid_midi_file *mf) { int i; int c; mf->varlen = 0; for (i = 0;; i++) { if (i == 4) { FLUID_LOG(FLUID_ERR, "Invalid variable length number"); return FLUID_FAILED; } c = fluid_midi_file_getc(mf); if (c < 0) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } if (c & 0x80) { mf->varlen |= (int) (c & 0x7F); mf->varlen <<= 7; } else { mf->varlen += c; break; } } return FLUID_OK; } /* * fluid_midi_file_read_event */ int fluid_midi_file_read_event(fluid_midi_file *mf, fluid_track_t *track) { int status; int type; int tempo; unsigned char *metadata = NULL; unsigned char *dyn_buf = NULL; unsigned char static_buf[256]; int nominator, denominator, clocks, notes; fluid_midi_event_t *evt; int channel = 0; int param1 = 0; int param2 = 0; int size; /* read the delta-time of the event */ if (fluid_midi_file_read_varlen(mf) != FLUID_OK) { return FLUID_FAILED; } mf->dtime += mf->varlen; /* read the status byte */ status = fluid_midi_file_getc(mf); if (status < 0) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } /* not a valid status byte: use the running status instead */ if ((status & 0x80) == 0) { if ((mf->running_status & 0x80) == 0) { FLUID_LOG(FLUID_ERR, "Undefined status and invalid running status"); return FLUID_FAILED; } fluid_midi_file_push(mf, status); status = mf->running_status; } /* check what message we have */ mf->running_status = status; if ((status == MIDI_SYSEX)) { /* system exclusif */ /* read the length of the message */ if (fluid_midi_file_read_varlen(mf) != FLUID_OK) { return FLUID_FAILED; } if (mf->varlen) { FLUID_LOG(FLUID_DBG, "%s: %d: alloc metadata, len = %d", __FILE__, __LINE__, mf->varlen); metadata = FLUID_MALLOC(mf->varlen + 1); if (metadata == NULL) { FLUID_LOG(FLUID_PANIC, "Out of memory"); return FLUID_FAILED; } /* read the data of the message */ if (fluid_midi_file_read(mf, metadata, mf->varlen) != FLUID_OK) { FLUID_FREE (metadata); return FLUID_FAILED; } evt = new_fluid_midi_event(); if (evt == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); FLUID_FREE (metadata); return FLUID_FAILED; } evt->dtime = mf->dtime; size = mf->varlen; if (metadata[mf->varlen - 1] == MIDI_EOX) size--; /* Add SYSEX event and indicate that its dynamically allocated and should be freed with event */ fluid_midi_event_set_sysex(evt, metadata, size, TRUE); fluid_track_add_event(track, evt); mf->dtime = 0; } return FLUID_OK; } else if (status == MIDI_META_EVENT) { /* meta events */ int result = FLUID_OK; /* get the type of the meta message */ type = fluid_midi_file_getc(mf); if (type < 0) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } /* get the length of the data part */ if (fluid_midi_file_read_varlen(mf) != FLUID_OK) { return FLUID_FAILED; } if (mf->varlen < 255) { metadata = &static_buf[0]; } else { FLUID_LOG(FLUID_DBG, "%s: %d: alloc metadata, len = %d", __FILE__, __LINE__, mf->varlen); dyn_buf = FLUID_MALLOC(mf->varlen + 1); if (dyn_buf == NULL) { FLUID_LOG(FLUID_PANIC, "Out of memory"); return FLUID_FAILED; } metadata = dyn_buf; } /* read the data */ if (mf->varlen) { if (fluid_midi_file_read(mf, metadata, mf->varlen) != FLUID_OK) { if (dyn_buf) { FLUID_FREE(dyn_buf); } return FLUID_FAILED; } } /* handle meta data */ switch (type) { case MIDI_COPYRIGHT: metadata[mf->varlen] = 0; break; case MIDI_TRACK_NAME: metadata[mf->varlen] = 0; fluid_track_set_name(track, (char *) metadata); break; case MIDI_INST_NAME: metadata[mf->varlen] = 0; break; case MIDI_LYRIC: break; case MIDI_MARKER: break; case MIDI_CUE_POINT: break; /* don't care much for text events */ case MIDI_EOT: if (mf->varlen != 0) { FLUID_LOG(FLUID_ERR, "Invalid length for EndOfTrack event"); result = FLUID_FAILED; break; } mf->eot = 1; evt = new_fluid_midi_event(); if (evt == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); result = FLUID_FAILED; break; } evt->dtime = mf->dtime; evt->type = MIDI_EOT; fluid_track_add_event(track, evt); mf->dtime = 0; break; case MIDI_SET_TEMPO: if (mf->varlen != 3) { FLUID_LOG(FLUID_ERR, "Invalid length for SetTempo meta event"); result = FLUID_FAILED; break; } tempo = (metadata[0] << 16) + (metadata[1] << 8) + metadata[2]; evt = new_fluid_midi_event(); if (evt == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); result = FLUID_FAILED; break; } evt->dtime = mf->dtime; evt->type = MIDI_SET_TEMPO; evt->channel = 0; evt->param1 = tempo; evt->param2 = 0; fluid_track_add_event(track, evt); mf->dtime = 0; break; case MIDI_SMPTE_OFFSET: if (mf->varlen != 5) { FLUID_LOG(FLUID_ERR, "Invalid length for SMPTE Offset meta event"); result = FLUID_FAILED; break; } break; /* we don't use smtp */ case MIDI_TIME_SIGNATURE: if (mf->varlen != 4) { FLUID_LOG(FLUID_ERR, "Invalid length for TimeSignature meta event"); result = FLUID_FAILED; break; } nominator = metadata[0]; denominator = pow(2.0, (double) metadata[1]); clocks = metadata[2]; notes = metadata[3]; FLUID_LOG(FLUID_DBG, "signature=%d/%d, metronome=%d, 32nd-notes=%d", nominator, denominator, clocks, notes); break; case MIDI_KEY_SIGNATURE: if (mf->varlen != 2) { FLUID_LOG(FLUID_ERR, "Invalid length for KeySignature meta event"); result = FLUID_FAILED; break; } /* We don't care about key signatures anyway */ /* sf = metadata[0]; mi = metadata[1]; */ break; case MIDI_SEQUENCER_EVENT: break; default: break; } if (dyn_buf) { FLUID_LOG(FLUID_DBG, "%s: %d: free metadata", __FILE__, __LINE__); FLUID_FREE(dyn_buf); } return result; } else { /* channel messages */ type = status & 0xf0; channel = status & 0x0f; /* all channel message have at least 1 byte of associated data */ if ((param1 = fluid_midi_file_getc(mf)) < 0) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } switch (type) { case NOTE_ON: if ((param2 = fluid_midi_file_getc(mf)) < 0) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } break; case NOTE_OFF: if ((param2 = fluid_midi_file_getc(mf)) < 0) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } break; case KEY_PRESSURE: if ((param2 = fluid_midi_file_getc(mf)) < 0) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } break; case CONTROL_CHANGE: if ((param2 = fluid_midi_file_getc(mf)) < 0) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } break; case PROGRAM_CHANGE: break; case CHANNEL_PRESSURE: break; case PITCH_BEND: if ((param2 = fluid_midi_file_getc(mf)) < 0) { FLUID_LOG(FLUID_ERR, "Unexpected end of file"); return FLUID_FAILED; } param1 = ((param2 & 0x7f) << 7) | (param1 & 0x7f); param2 = 0; break; default: /* Can't possibly happen !? */ FLUID_LOG(FLUID_ERR, "Unrecognized MIDI event"); return FLUID_FAILED; } evt = new_fluid_midi_event(); if (evt == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); return FLUID_FAILED; } evt->dtime = mf->dtime; evt->type = type; evt->channel = channel; evt->param1 = param1; evt->param2 = param2; fluid_track_add_event(track, evt); mf->dtime = 0; } return FLUID_OK; } /* * fluid_midi_file_get_division */ int fluid_midi_file_get_division(fluid_midi_file *midifile) { return midifile->division; } #endif /****************************************************** * * fluid_track_t */ /** * Create a MIDI event structure. * @return New MIDI event structure or NULL when out of memory. */ fluid_midi_event_t * new_fluid_midi_event () { fluid_midi_event_t* evt; evt = FLUID_NEW(fluid_midi_event_t); if (evt == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); return NULL; } evt->dtime = 0; evt->type = 0; evt->channel = 0; evt->param1 = 0; evt->param2 = 0; evt->next = NULL; evt->paramptr = NULL; return evt; } /** * Delete MIDI event structure. * @param evt MIDI event structure * @return Always returns #FLUID_OK */ int delete_fluid_midi_event(fluid_midi_event_t *evt) { fluid_midi_event_t *temp; while (evt) { temp = evt->next; /* Dynamic SYSEX event? - free (param2 indicates if dynamic) */ if (evt->type == MIDI_SYSEX && evt->paramptr && evt->param2) FLUID_FREE (evt->paramptr); FLUID_FREE(evt); evt = temp; } return FLUID_OK; } /** * Get the event type field of a MIDI event structure. * @param evt MIDI event structure * @return Event type field (MIDI status byte without channel) */ int fluid_midi_event_get_type(fluid_midi_event_t *evt) { return evt->type; } /** * Set the event type field of a MIDI event structure. * @param evt MIDI event structure * @param type Event type field (MIDI status byte without channel) * @return Always returns #FLUID_OK */ int fluid_midi_event_set_type(fluid_midi_event_t *evt, int type) { evt->type = type; return FLUID_OK; } /** * Get the channel field of a MIDI event structure. * @param evt MIDI event structure * @return Channel field */ int fluid_midi_event_get_channel(fluid_midi_event_t *evt) { return evt->channel; } /** * Set the channel field of a MIDI event structure. * @param evt MIDI event structure * @param chan MIDI channel field * @return Always returns #FLUID_OK */ int fluid_midi_event_set_channel(fluid_midi_event_t *evt, int chan) { evt->channel = chan; return FLUID_OK; } /** * Get the key field of a MIDI event structure. * @param evt MIDI event structure * @return MIDI note number (0-127) */ int fluid_midi_event_get_key(fluid_midi_event_t *evt) { return evt->param1; } /** * Set the key field of a MIDI event structure. * @param evt MIDI event structure * @param v MIDI note number (0-127) * @return Always returns #FLUID_OK */ int fluid_midi_event_set_key(fluid_midi_event_t *evt, int v) { evt->param1 = v; return FLUID_OK; } /** * Get the velocity field of a MIDI event structure. * @param evt MIDI event structure * @return MIDI velocity number (0-127) */ int fluid_midi_event_get_velocity(fluid_midi_event_t *evt) { return evt->param2; } /** * Set the velocity field of a MIDI event structure. * @param evt MIDI event structure * @param v MIDI velocity value * @return Always returns #FLUID_OK */ int fluid_midi_event_set_velocity(fluid_midi_event_t *evt, int v) { evt->param2 = v; return FLUID_OK; } /** * Get the control number of a MIDI event structure. * @param evt MIDI event structure * @return MIDI control number */ int fluid_midi_event_get_control(fluid_midi_event_t *evt) { return evt->param1; } /** * Set the control field of a MIDI event structure. * @param evt MIDI event structure * @param v MIDI control number * @return Always returns #FLUID_OK */ int fluid_midi_event_set_control(fluid_midi_event_t *evt, int v) { evt->param1 = v; return FLUID_OK; } /** * Get the value field from a MIDI event structure. * @param evt MIDI event structure * @return Value field */ int fluid_midi_event_get_value(fluid_midi_event_t *evt) { return evt->param2; } /** * Set the value field of a MIDI event structure. * @param evt MIDI event structure * @param v Value to assign * @return Always returns #FLUID_OK */ int fluid_midi_event_set_value(fluid_midi_event_t *evt, int v) { evt->param2 = v; return FLUID_OK; } /** * Get the program field of a MIDI event structure. * @param evt MIDI event structure * @return MIDI program number (0-127) */ int fluid_midi_event_get_program(fluid_midi_event_t *evt) { return evt->param1; } /** * Set the program field of a MIDI event structure. * @param evt MIDI event structure * @param val MIDI program number (0-127) * @return Always returns #FLUID_OK */ int fluid_midi_event_set_program(fluid_midi_event_t *evt, int val) { evt->param1 = val; return FLUID_OK; } /** * Get the pitch field of a MIDI event structure. * @param evt MIDI event structure * @return Pitch value (14 bit value, 0-16383, 8192 is center) */ int fluid_midi_event_get_pitch(fluid_midi_event_t *evt) { return evt->param1; } /** * Set the pitch field of a MIDI event structure. * @param evt MIDI event structure * @param val Pitch value (14 bit value, 0-16383, 8192 is center) * @return Always returns FLUID_OK */ int fluid_midi_event_set_pitch(fluid_midi_event_t *evt, int val) { evt->param1 = val; return FLUID_OK; } /** * Assign sysex data to a MIDI event structure. * @param evt MIDI event structure * @param data Pointer to SYSEX data * @param size Size of SYSEX data * @param dynamic TRUE if the SYSEX data has been dynamically allocated and * should be freed when the event is freed (only applies if event gets destroyed * with delete_fluid_midi_event()) * @return Always returns #FLUID_OK * * NOTE: Unlike the other event assignment functions, this one sets evt->type. */ int fluid_midi_event_set_sysex(fluid_midi_event_t *evt, void *data, int size, int dynamic) { evt->type = MIDI_SYSEX; evt->paramptr = data; evt->param1 = size; evt->param2 = dynamic; return FLUID_OK; } /****************************************************** * * fluid_track_t */ #if 0 // disable fluid file player in Ardour /* * new_fluid_track */ fluid_track_t * new_fluid_track(int num) { fluid_track_t *track; track = FLUID_NEW(fluid_track_t); if (track == NULL) { return NULL; } track->name = NULL; track->num = num; track->first = NULL; track->cur = NULL; track->last = NULL; track->ticks = 0; return track; } /* * delete_fluid_track */ int delete_fluid_track(fluid_track_t *track) { if (track->name != NULL) { FLUID_FREE(track->name); } if (track->first != NULL) { delete_fluid_midi_event(track->first); } FLUID_FREE(track); return FLUID_OK; } /* * fluid_track_set_name */ int fluid_track_set_name(fluid_track_t *track, char *name) { int len; if (track->name != NULL) { FLUID_FREE(track->name); } if (name == NULL) { track->name = NULL; return FLUID_OK; } len = FLUID_STRLEN(name); track->name = FLUID_MALLOC(len + 1); if (track->name == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); return FLUID_FAILED; } FLUID_STRCPY(track->name, name); return FLUID_OK; } /* * fluid_track_get_name */ char * fluid_track_get_name(fluid_track_t *track) { return track->name; } /* * fluid_track_get_duration */ int fluid_track_get_duration(fluid_track_t *track) { int time = 0; fluid_midi_event_t *evt = track->first; while (evt != NULL) { time += evt->dtime; evt = evt->next; } return time; } /* * fluid_track_count_events */ static int fluid_track_count_events(fluid_track_t *track, int *on, int *off) { fluid_midi_event_t *evt = track->first; while (evt != NULL) { if (evt->type == NOTE_ON) { (*on)++; } else if (evt->type == NOTE_OFF) { (*off)++; } evt = evt->next; } return FLUID_OK; } /* * fluid_track_add_event */ int fluid_track_add_event(fluid_track_t *track, fluid_midi_event_t *evt) { evt->next = NULL; if (track->first == NULL) { track->first = evt; track->cur = evt; track->last = evt; } else { track->last->next = evt; track->last = evt; } return FLUID_OK; } /* * fluid_track_first_event */ fluid_midi_event_t * fluid_track_first_event(fluid_track_t *track) { track->cur = track->first; return track->cur; } /* * fluid_track_next_event */ fluid_midi_event_t * fluid_track_next_event(fluid_track_t *track) { if (track->cur != NULL) { track->cur = track->cur->next; } return track->cur; } /* * fluid_track_reset */ int fluid_track_reset(fluid_track_t *track) { track->ticks = 0; track->cur = track->first; return FLUID_OK; } /* * fluid_track_send_events */ int fluid_track_send_events(fluid_track_t *track, fluid_synth_t *synth, fluid_player_t *player, unsigned int ticks) { int status = FLUID_OK; fluid_midi_event_t *event; while (1) { event = track->cur; if (event == NULL) { return status; } /* printf("track=%02d\tticks=%05u\ttrack=%05u\tdtime=%05u\tnext=%05u\n", */ /* track->num, */ /* ticks, */ /* track->ticks, */ /* event->dtime, */ /* track->ticks + event->dtime); */ if (track->ticks + event->dtime > ticks) { return status; } track->ticks += event->dtime; if (!player || event->type == MIDI_EOT) { } else if (event->type == MIDI_SET_TEMPO) { fluid_player_set_midi_tempo(player, event->param1); } else { if (player->playback_callback) player->playback_callback(player->playback_userdata, event); } fluid_track_next_event(track); } return status; } /****************************************************** * * fluid_player */ /** * Create a new MIDI player. * @param synth Fluid synthesizer instance to create player for * @return New MIDI player instance or NULL on error (out of memory) */ fluid_player_t * new_fluid_player(fluid_synth_t *synth) { int i; fluid_player_t *player; player = FLUID_NEW(fluid_player_t); if (player == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); return NULL; } player->status = FLUID_PLAYER_READY; player->loop = 1; player->ntracks = 0; for (i = 0; i < MAX_NUMBER_OF_TRACKS; i++) { player->track[i] = NULL; } player->synth = synth; player->system_timer = NULL; player->sample_timer = NULL; player->playlist = NULL; player->currentfile = NULL; player->division = 0; player->send_program_change = 1; player->miditempo = 480000; player->deltatime = 4.0; player->cur_msec = 0; player->cur_ticks = 0; fluid_player_set_playback_callback(player, fluid_synth_handle_midi_event, synth); player->use_system_timer = fluid_settings_str_equal(synth->settings, "player.timing-source", "system"); fluid_settings_getint(synth->settings, "player.reset-synth", &i); player->reset_synth_between_songs = i; return player; } /** * Delete a MIDI player instance. * @param player MIDI player instance * @return Always returns #FLUID_OK */ int delete_fluid_player(fluid_player_t *player) { fluid_list_t *q; fluid_playlist_item* pi; if (player == NULL) { return FLUID_OK; } fluid_player_stop(player); fluid_player_reset(player); while (player->playlist != NULL) { q = player->playlist->next; pi = (fluid_playlist_item*) player->playlist->data; FLUID_FREE(pi->filename); FLUID_FREE(pi->buffer); FLUID_FREE(pi); delete1_fluid_list(player->playlist); player->playlist = q; } FLUID_FREE(player); return FLUID_OK; } /** * Registers settings related to the MIDI player */ void fluid_player_settings(fluid_settings_t *settings) { /* player.timing-source can be either "system" (use system timer) or "sample" (use timer based on number of written samples) */ fluid_settings_register_str(settings, "player.timing-source", "sample", 0, NULL, NULL); fluid_settings_add_option(settings, "player.timing-source", "sample"); fluid_settings_add_option(settings, "player.timing-source", "system"); /* Selects whether the player should reset the synth between songs, or not. */ fluid_settings_register_int(settings, "player.reset-synth", 1, 0, 1, FLUID_HINT_TOGGLED, NULL, NULL); } int fluid_player_reset(fluid_player_t *player) { int i; for (i = 0; i < MAX_NUMBER_OF_TRACKS; i++) { if (player->track[i] != NULL) { delete_fluid_track(player->track[i]); player->track[i] = NULL; } } /* player->current_file = NULL; */ /* player->status = FLUID_PLAYER_READY; */ /* player->loop = 1; */ player->ntracks = 0; player->division = 0; player->send_program_change = 1; player->miditempo = 480000; player->deltatime = 4.0; return 0; } /* * fluid_player_add_track */ int fluid_player_add_track(fluid_player_t *player, fluid_track_t *track) { if (player->ntracks < MAX_NUMBER_OF_TRACKS) { player->track[player->ntracks++] = track; return FLUID_OK; } else { return FLUID_FAILED; } } /* * fluid_player_count_tracks */ int fluid_player_count_tracks(fluid_player_t *player) { return player->ntracks; } /* * fluid_player_get_track */ fluid_track_t * fluid_player_get_track(fluid_player_t *player, int i) { if ((i >= 0) && (i < MAX_NUMBER_OF_TRACKS)) { return player->track[i]; } else { return NULL; } } /** * Change the MIDI callback function. This is usually set to * fluid_synth_handle_midi_event, but can optionally be changed * to a user-defined function instead, for intercepting all MIDI * messages sent to the synth. You can also use a midi router as * the callback function to modify the MIDI messages before sending * them to the synth. * @param player MIDI player instance * @param handler Pointer to callback function * @param handler_data Parameter sent to the callback function * @returns FLUID_OK * @since 1.1.4 */ int fluid_player_set_playback_callback(fluid_player_t* player, handle_midi_event_func_t handler, void* handler_data) { player->playback_callback = handler; player->playback_userdata = handler_data; return FLUID_OK; } /** * Add a MIDI file to a player queue. * @param player MIDI player instance * @param midifile File name of the MIDI file to add * @return #FLUID_OK or #FLUID_FAILED */ int fluid_player_add(fluid_player_t *player, const char *midifile) { fluid_playlist_item *pi = FLUID_MALLOC(sizeof(fluid_playlist_item)); char* f = FLUID_STRDUP(midifile); if (!pi || !f) { FLUID_FREE(pi); FLUID_FREE(f); FLUID_LOG(FLUID_PANIC, "Out of memory"); return FLUID_FAILED; } pi->filename = f; pi->buffer = NULL; pi->buffer_len = 0; player->playlist = fluid_list_append(player->playlist, pi); return FLUID_OK; } /** * Add a MIDI file to a player queue, from a buffer in memory. * @param player MIDI player instance * @param buffer Pointer to memory containing the bytes of a complete MIDI * file. The data is copied, so the caller may free or modify it immediately * without affecting the playlist. * @param len Length of the buffer, in bytes. * @return #FLUID_OK or #FLUID_FAILED */ int fluid_player_add_mem(fluid_player_t* player, const void *buffer, size_t len) { /* Take a copy of the buffer, so the caller can free immediately. */ fluid_playlist_item *pi = FLUID_MALLOC(sizeof(fluid_playlist_item)); void *buf_copy = FLUID_MALLOC(len); if (!pi || !buf_copy) { FLUID_FREE(pi); FLUID_FREE(buf_copy); FLUID_LOG(FLUID_PANIC, "Out of memory"); return FLUID_FAILED; } FLUID_MEMCPY(buf_copy, buffer, len); pi->filename = NULL; pi->buffer = buf_copy; pi->buffer_len = len; player->playlist = fluid_list_append(player->playlist, pi); return FLUID_OK; } /* * fluid_player_load */ int fluid_player_load(fluid_player_t *player, fluid_playlist_item *item) { fluid_midi_file *midifile; char* buffer; size_t buffer_length; int buffer_owned; if (item->filename != NULL) { fluid_file fp; /* This file is specified by filename; load the file from disk */ FLUID_LOG(FLUID_DBG, "%s: %d: Loading midifile %s", __FILE__, __LINE__, item->filename); /* Read the entire contents of the file into the buffer */ fp = FLUID_FOPEN(item->filename, "rb"); if (fp == NULL) { FLUID_LOG(FLUID_ERR, "Couldn't open the MIDI file"); return FLUID_FAILED; } buffer = fluid_file_read_full(fp, &buffer_length); if (buffer == NULL) { FLUID_FCLOSE(fp); return FLUID_FAILED; } buffer_owned = 1; FLUID_FCLOSE(fp); } else { /* This file is specified by a pre-loaded buffer; load from memory */ FLUID_LOG(FLUID_DBG, "%s: %d: Loading midifile from memory (%p)", __FILE__, __LINE__, item->buffer); buffer = (char *) item->buffer; buffer_length = item->buffer_len; /* Do not free the buffer (it is owned by the playlist) */ buffer_owned = 0; } midifile = new_fluid_midi_file(buffer, buffer_length); if (midifile == NULL) { if (buffer_owned) { FLUID_FREE(buffer); } return FLUID_FAILED; } player->division = fluid_midi_file_get_division(midifile); fluid_player_set_midi_tempo(player, player->miditempo); // Update deltatime /*FLUID_LOG(FLUID_DBG, "quarter note division=%d\n", player->division); */ if (fluid_midi_file_load_tracks(midifile, player) != FLUID_OK) { if (buffer_owned) { FLUID_FREE(buffer); } delete_fluid_midi_file(midifile); return FLUID_FAILED; } delete_fluid_midi_file(midifile); if (buffer_owned) { FLUID_FREE(buffer); } return FLUID_OK; } static void fluid_player_advancefile(fluid_player_t *player) { if (player->playlist == NULL) { return; /* No files to play */ } if (player->currentfile != NULL) { player->currentfile = fluid_list_next(player->currentfile); } if (player->currentfile == NULL) { if (player->loop == 0) { return; /* We're done playing */ } if (player->loop > 0) { player->loop--; } player->currentfile = player->playlist; } } static void fluid_player_playlist_load(fluid_player_t *player, unsigned int msec) { fluid_playlist_item* current_playitem; int i; do { fluid_player_advancefile(player); if (player->currentfile == NULL) { /* Failed to find next song, probably since we're finished */ player->status = FLUID_PLAYER_DONE; return; } fluid_player_reset(player); current_playitem = (fluid_playlist_item *) player->currentfile->data; } while (fluid_player_load(player, current_playitem) != FLUID_OK); /* Successfully loaded midi file */ player->begin_msec = msec; player->start_msec = msec; player->start_ticks = 0; player->cur_ticks = 0; if (player->reset_synth_between_songs) { fluid_synth_system_reset(player->synth); } for (i = 0; i < player->ntracks; i++) { if (player->track[i] != NULL) { fluid_track_reset(player->track[i]); } } } /* * fluid_player_callback */ int fluid_player_callback(void *data, unsigned int msec) { int i; int loadnextfile; int status = FLUID_PLAYER_DONE; fluid_player_t *player; fluid_synth_t *synth; player = (fluid_player_t *) data; synth = player->synth; loadnextfile = player->currentfile == NULL ? 1 : 0; do { if (loadnextfile) { loadnextfile = 0; fluid_player_playlist_load(player, msec); if (player->currentfile == NULL) { return 0; } } player->cur_msec = msec; player->cur_ticks = (player->start_ticks + (int) ((double) (player->cur_msec - player->start_msec) / player->deltatime)); for (i = 0; i < player->ntracks; i++) { if (!fluid_track_eot(player->track[i])) { status = FLUID_PLAYER_PLAYING; if (fluid_track_send_events(player->track[i], synth, player, player->cur_ticks) != FLUID_OK) { /* */ } } } if (status == FLUID_PLAYER_DONE) { FLUID_LOG(FLUID_DBG, "%s: %d: Duration=%.3f sec", __FILE__, __LINE__, (msec - player->begin_msec) / 1000.0); loadnextfile = 1; } } while (loadnextfile); player->status = status; return 1; } /** * Activates play mode for a MIDI player if not already playing. * @param player MIDI player instance * @return #FLUID_OK on success, #FLUID_FAILED otherwise */ int fluid_player_play(fluid_player_t *player) { if (player->status == FLUID_PLAYER_PLAYING) { return FLUID_OK; } if (player->playlist == NULL) { return FLUID_OK; } player->status = FLUID_PLAYER_PLAYING; if (player->use_system_timer) { player->system_timer = new_fluid_timer((int) player->deltatime, fluid_player_callback, (void *) player, TRUE, FALSE, TRUE); if (player->system_timer == NULL) { return FLUID_FAILED; } } else { player->sample_timer = new_fluid_sample_timer(player->synth, fluid_player_callback, (void *) player); if (player->sample_timer == NULL) { return FLUID_FAILED; } } return FLUID_OK; } /** * Stops a MIDI player. * @param player MIDI player instance * @return Always returns #FLUID_OK */ int fluid_player_stop(fluid_player_t *player) { if (player->system_timer != NULL) { delete_fluid_timer(player->system_timer); } if (player->sample_timer != NULL) { delete_fluid_sample_timer(player->synth, player->sample_timer); } player->status = FLUID_PLAYER_DONE; player->sample_timer = NULL; player->system_timer = NULL; return FLUID_OK; } /** * Get MIDI player status. * @param player MIDI player instance * @return Player status (#fluid_player_status) * @since 1.1.0 */ int fluid_player_get_status(fluid_player_t *player) { return player->status; } /** * Enable looping of a MIDI player * @param player MIDI player instance * @param loop Times left to loop the playlist. -1 means loop infinitely. * @return Always returns #FLUID_OK * @since 1.1.0 * * For example, if you want to loop the playlist twice, set loop to 2 * and call this function before you start the player. */ int fluid_player_set_loop(fluid_player_t *player, int loop) { player->loop = loop; return FLUID_OK; } /** * Set the tempo of a MIDI player. * @param player MIDI player instance * @param tempo Tempo to set playback speed to (in microseconds per quarter note, as per MIDI file spec) * @return Always returns #FLUID_OK */ int fluid_player_set_midi_tempo(fluid_player_t *player, int tempo) { player->miditempo = tempo; player->deltatime = (double) tempo / player->division / 1000.0; /* in milliseconds */ player->start_msec = player->cur_msec; player->start_ticks = player->cur_ticks; FLUID_LOG(FLUID_DBG, "tempo=%d, tick time=%f msec, cur time=%d msec, cur tick=%d", tempo, player->deltatime, player->cur_msec, player->cur_ticks); return FLUID_OK; } /** * Set the tempo of a MIDI player in beats per minute. * @param player MIDI player instance * @param bpm Tempo in beats per minute * @return Always returns #FLUID_OK */ int fluid_player_set_bpm(fluid_player_t *player, int bpm) { return fluid_player_set_midi_tempo(player, (int) ((double) 60 * 1e6 / bpm)); } /** * Wait for a MIDI player to terminate (when done playing). * @param player MIDI player instance * @return #FLUID_OK on success, #FLUID_FAILED otherwise */ int fluid_player_join(fluid_player_t *player) { if (player->system_timer) { return fluid_timer_join(player->system_timer); } else if (player->sample_timer) { /* Busy-wait loop, since there's no thread to wait for... */ while (player->status != FLUID_PLAYER_DONE) { #if defined(WIN32) Sleep(10); #else usleep(10000); #endif } } return FLUID_OK; } /************************************************************************ * MIDI PARSER * */ /* * new_fluid_midi_parser */ fluid_midi_parser_t * new_fluid_midi_parser () { fluid_midi_parser_t *parser; parser = FLUID_NEW(fluid_midi_parser_t); if (parser == NULL) { FLUID_LOG(FLUID_ERR, "Out of memory"); return NULL; } parser->status = 0; /* As long as the status is 0, the parser won't do anything -> no need to initialize all the fields. */ return parser; } /* * delete_fluid_midi_parser */ int delete_fluid_midi_parser(fluid_midi_parser_t *parser) { FLUID_FREE(parser); return FLUID_OK; } /** * Parse a MIDI stream one character at a time. * @param parser Parser instance * @param c Next character in MIDI stream * @return A parsed MIDI event or NULL if none. Event is internal and should * not be modified or freed and is only valid until next call to this function. */ fluid_midi_event_t * fluid_midi_parser_parse(fluid_midi_parser_t *parser, unsigned char c) { fluid_midi_event_t *event; /* Real-time messages (0xF8-0xFF) can occur anywhere, even in the middle * of another message. */ if (c >= 0xF8) { if (c == MIDI_SYSTEM_RESET) { parser->event.type = c; parser->status = 0; /* clear the status */ return &parser->event; } return NULL; } /* Status byte? - If previous message not yet complete, it is discarded (re-sync). */ if (c & 0x80) { /* Any status byte terminates SYSEX messages (not just 0xF7) */ if (parser->status == MIDI_SYSEX && parser->nr_bytes > 0) { event = &parser->event; fluid_midi_event_set_sysex(event, parser->data, parser->nr_bytes, FALSE); } else event = NULL; if (c < 0xF0) /* Voice category message? */ { parser->channel = c & 0x0F; parser->status = c & 0xF0; /* The event consumes x bytes of data... (subtract 1 for the status byte) */ parser->nr_bytes_total = fluid_midi_event_length(parser->status) - 1; parser->nr_bytes = 0; /* 0 bytes read so far */ } else if (c == MIDI_SYSEX) { parser->status = MIDI_SYSEX; parser->nr_bytes = 0; } else parser->status = 0; /* Discard other system messages (0xF1-0xF7) */ return event; /* Return SYSEX event or NULL */ } /* Data/parameter byte */ /* Discard data bytes for events we don't care about */ if (parser->status == 0) return NULL; /* Max data size exceeded? (SYSEX messages only really) */ if (parser->nr_bytes == FLUID_MIDI_PARSER_MAX_DATA_SIZE) { parser->status = 0; /* Discard the rest of the message */ return NULL; } /* Store next byte */ parser->data[parser->nr_bytes++] = c; /* Do we still need more data to get this event complete? */ if (parser->nr_bytes < parser->nr_bytes_total) return NULL; /* Event is complete, return it. * Running status byte MIDI feature is also handled here. */ parser->event.type = parser->status; parser->event.channel = parser->channel; parser->nr_bytes = 0; /* Reset data size, in case there are additional running status messages */ switch (parser->status) { case NOTE_OFF: case NOTE_ON: case KEY_PRESSURE: case CONTROL_CHANGE: case PROGRAM_CHANGE: case CHANNEL_PRESSURE: parser->event.param1 = parser->data[0]; /* For example key number */ parser->event.param2 = parser->data[1]; /* For example velocity */ break; case PITCH_BEND: /* Pitch-bend is transmitted with 14-bit precision. */ parser->event.param1 = (parser->data[1] << 7) | parser->data[0]; break; default: /* Unlikely */ return NULL; } return &parser->event; } /* Purpose: * Returns the length of a MIDI message. */ static int fluid_midi_event_length(unsigned char event) { switch (event & 0xF0) { case NOTE_OFF: case NOTE_ON: case KEY_PRESSURE: case CONTROL_CHANGE: case PITCH_BEND: return 3; case PROGRAM_CHANGE: case CHANNEL_PRESSURE: return 2; } switch (event) { case MIDI_TIME_CODE: case MIDI_SONG_SELECT: case 0xF4: case 0xF5: return 2; case MIDI_TUNE_REQUEST: return 1; case MIDI_SONG_POSITION: return 3; } return 1; } #endif