/* * MIDI file player for ALSA sequencer * (type 0 only!, the library that is used doesn't support merging of tracks) * * Copyright (c) 1998 by Frank van de Pol * * Modified so that this uses alsa-lib * 1999 Jan. by Isaku Yamahata * * 19990604 Takashi Iwai * - use blocking mode * - fix tempo event bug * - add command line options * * 19990827 Takashi Iwai * - use snd_seq_alloc_queue() * * 19990916 Takashi Iwai * - use middle-level sequencer routines and macros * * 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 program 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * */ #include #include #include #include #include #include #include #include #include "midifile.h" /* SMF library header */ #include "midifile.c" /* SMF library code */ #include "../include/asoundlib.h" /* send the real-time time stamps (instead of midi ticks) to the ALSA sequencer */ static int use_realtime = 0; /* control the event buffering by using a blocking mode */ static int use_blocking_mode = 1; /* default destination queue, client and port numbers */ #define DEST_CLIENT_NUMBER 65 #define DEST_PORT_NUMBER 0 /* event pool size */ #define WRITE_POOL_SIZE 200 #define WRITE_POOL_SPACE 10 #define READ_POOL_SIZE 10 /* we need to read the pool only for echoing */ static FILE *F; static snd_seq_t *seq_handle = NULL; static int ppq = 96; static int slave_ppq = 96; static double local_secs = 0; static int local_ticks = 0; static int local_tempo = 500000; static int dest_queue = -1; static int shared_queue = 0; static int tick_offset = 0; static int dest_client = DEST_CLIENT_NUMBER; static int dest_port = DEST_PORT_NUMBER; static int my_port = 0; static int verbose = 0; static int slave = 0; /* allow external sync */ #define VERB_INFO 1 #define VERB_MUCH 2 #define VERB_EVENT 3 static void alsa_start_timer(void); static void alsa_stop_timer(void); static void wait_start(void); static inline double tick2time_dbl(int tick) { return local_secs + ((double) (tick - local_ticks) * (double) local_tempo * 1.0E-6 / (double) ppq); } static void tick2time(snd_seq_real_time_t * tm, int tick) { double secs = tick2time_dbl(tick); tm->tv_sec = secs; tm->tv_nsec = (secs - tm->tv_sec) * 1.0E9; } static void write_ev(snd_seq_event_t *ev) { int rc; if (use_blocking_mode) { rc = snd_seq_event_output(seq_handle, ev); if (rc < 0) { printf("written = %i (%s)\n", rc, snd_strerror(rc)); exit(1); } return; } while ((rc = snd_seq_event_output(seq_handle, ev)) < 0) { int npfds = snd_seq_poll_descriptors_count(seq_handle, POLLOUT); struct pollfd *pfds = alloca(sizeof(*pfds) * npfds); snd_seq_poll_descriptors(seq_handle, pfds, npfds, POLLOUT); if ((rc = poll(pfds, npfds, -1)) < 0) { printf("poll error = %i (%s)\n", rc, snd_strerror(errno)); exit(1); } } } /* read the byte */ static int mygetc(void) { return getc(F); } /* print out the text */ static void mytext(int type ATTRIBUTE_UNUSED, int leng, char *msg) { char *p; char *ep = msg + leng; if (verbose >= VERB_INFO) { for (p = msg; p < ep; p++) putchar(isprint(*p) ? *p : '?'); putchar('\n'); } } static void do_header(int format, int ntracks, int division) { snd_seq_queue_tempo_t *tempo; if (verbose >= VERB_INFO) printf("smf format %d, %d tracks, %d ppq\n", format, ntracks, division); ppq = division; if (format != 0 || ntracks != 1) { printf("This player does not support merging of tracks.\n"); if (! shared_queue) alsa_stop_timer(); exit(1); } /* set the ppq */ snd_seq_queue_tempo_alloca(&tempo); /* ppq must be set before starting the timer */ if (snd_seq_get_queue_tempo(seq_handle, dest_queue, tempo) < 0) { perror("get_queue_tempo"); exit(1); } if ((slave_ppq = snd_seq_queue_tempo_get_ppq(tempo)) != ppq) { snd_seq_queue_tempo_set_ppq(tempo, ppq); if (snd_seq_set_queue_tempo(seq_handle, dest_queue, tempo) < 0) { perror("set_queue_tempo"); if (!slave && !shared_queue) exit(1); else printf("different PPQ %d in SMF from queue PPQ %d\n", ppq, slave_ppq); } else slave_ppq = ppq; if (verbose >= VERB_INFO) printf("ALSA Timer updated, PPQ = %d\n", snd_seq_queue_tempo_get_ppq(tempo)); } /* start playing... */ if (slave) { if (verbose >= VERB_INFO) printf("Wait till timer starts...\n"); wait_start(); if (verbose >= VERB_INFO) printf("Go!\n"); } else if (shared_queue) { snd_seq_queue_status_t *stat; snd_seq_queue_status_alloca(&stat); snd_seq_get_queue_status(seq_handle, dest_queue, stat); tick_offset = snd_seq_queue_status_get_tick_time(stat); fprintf(stderr, "tick offset = %d\n", tick_offset); } else { alsa_start_timer(); tick_offset = 0; } } /* fill the event time */ static void set_event_time(snd_seq_event_t *ev, unsigned int currtime) { if (use_realtime) { snd_seq_real_time_t rtime; if (ppq != slave_ppq) currtime = (currtime * slave_ppq) / ppq; tick2time(&rtime, currtime); snd_seq_ev_schedule_real(ev, dest_queue, 0, &rtime); } else { if (ppq != slave_ppq) currtime = (currtime * slave_ppq) / ppq; currtime += tick_offset; snd_seq_ev_schedule_tick(ev, dest_queue, 0, currtime); } } /* fill the normal event header */ static void set_event_header(snd_seq_event_t *ev) { snd_seq_ev_clear(ev); snd_seq_ev_set_dest(ev, dest_client, dest_port); snd_seq_ev_set_source(ev, my_port); set_event_time(ev, Mf_currtime); } /* start the timer */ static void alsa_start_timer(void) { snd_seq_start_queue(seq_handle, dest_queue, NULL); } /* stop the timer */ static void alsa_stop_timer(void) { snd_seq_event_t ev; set_event_header(&ev); snd_seq_stop_queue(seq_handle, dest_queue, &ev); } /* change the tempo */ static void do_tempo(int us) { snd_seq_event_t ev; if (verbose >= VERB_MUCH) { double bpm; bpm = 60.0E6 / (double) us; printf("Tempo %d us/beat, %.2f bpm\n", us, bpm); } /* store the new tempo and timestamp of the tempo change */ local_secs = tick2time_dbl(Mf_currtime); local_ticks = Mf_currtime; local_tempo = us; set_event_header(&ev); if (!slave) snd_seq_change_queue_tempo(seq_handle, dest_queue, us, &ev); } static void do_noteon(int chan, int pitch, int vol) { snd_seq_event_t ev; if (verbose >= VERB_EVENT) printf("%lu: NoteOn (%d) %d %d\n", Mf_currtime, chan, pitch, vol); set_event_header(&ev); snd_seq_ev_set_noteon(&ev, chan, pitch, vol); write_ev(&ev); } static void do_noteoff(int chan, int pitch, int vol) { snd_seq_event_t ev; if (verbose >= VERB_EVENT) printf("%lu: NoteOff (%d) %d %d\n", Mf_currtime, chan, pitch, vol); set_event_header(&ev); snd_seq_ev_set_noteoff(&ev, chan, pitch, vol); write_ev(&ev); } static void do_program(int chan, int program) { snd_seq_event_t ev; if (verbose >= VERB_EVENT) printf("%lu: Program (%d) %d\n", Mf_currtime, chan, program); set_event_header(&ev); snd_seq_ev_set_pgmchange(&ev, chan, program); write_ev(&ev); } static void do_parameter(int chan, int control, int value) { snd_seq_event_t ev; if (verbose >= VERB_EVENT) printf("%lu: Control (%d) %d %d\n", Mf_currtime, chan, control, value); set_event_header(&ev); snd_seq_ev_set_controller(&ev, chan, control, value); write_ev(&ev); } static void do_pitchbend(int chan, int lsb, int msb) { /* !@#$% lsb & msb are in the wrong order in docs */ snd_seq_event_t ev; if (verbose >= VERB_EVENT) printf("%lu: Pitchbend (%d) %d %d\n", Mf_currtime, chan, lsb, msb); set_event_header(&ev); snd_seq_ev_set_pitchbend(&ev, chan, (lsb + (msb << 7)) - 8192); write_ev(&ev); } static void do_pressure(int chan, int pitch, int pressure) { snd_seq_event_t ev; if (verbose >= VERB_EVENT) printf("%lu: KeyPress (%d) %d %d\n", Mf_currtime, chan, pitch, pressure); set_event_header(&ev); snd_seq_ev_set_keypress(&ev, chan, pitch, pressure); write_ev(&ev); } static void do_chanpressure(int chan, int pressure) { snd_seq_event_t ev; if (verbose >= VERB_EVENT) printf("%lu: ChanPress (%d) %d\n", Mf_currtime, chan, pressure); set_event_header(&ev); snd_seq_ev_set_chanpress(&ev, chan, pressure); write_ev(&ev); } static void do_sysex(int len, char *msg) { snd_seq_event_t ev; if (verbose >= VERB_MUCH) { int c; printf("%lu: Sysex, len=%d\n", Mf_currtime, len); for (c = 0; c < len; c++) { printf(" %02x", (unsigned char)msg[c]); if (c % 16 == 15) putchar('\n'); } if (c % 16 != 15) putchar('\n'); } set_event_header(&ev); snd_seq_ev_set_sysex(&ev, len, msg); write_ev(&ev); } static snd_seq_event_t *wait_for_event(void) { int left; snd_seq_event_t *input_event; if (use_blocking_mode) { /* read the event - blocked until any event is read */ left = snd_seq_event_input(seq_handle, &input_event); } else { /* read the event - using select syscall */ while ((left = snd_seq_event_input(seq_handle, &input_event)) >= 0 && input_event == NULL) { int npfds = snd_seq_poll_descriptors_count(seq_handle, POLLIN); struct pollfd *pfds = alloca(sizeof(*pfds) * npfds); snd_seq_poll_descriptors(seq_handle, pfds, npfds, POLLIN); if ((left = poll(pfds, npfds, -1)) < 0) { printf("poll error = %i (%s)\n", errno, snd_strerror(errno)); exit(1); } } } if (left < 0) { printf("alsa_sync error!:%s\n", snd_strerror(left)); return NULL; } return input_event; } /* synchronize to the end of the event */ static void alsa_sync(void) { /* send the echo event to the self client. */ if (verbose >= VERB_MUCH) printf("alsa_sync syncing...\n"); /* dump the buffer */ snd_seq_drain_output(seq_handle); snd_seq_sync_output_queue(seq_handle); if (verbose >= VERB_MUCH) printf("alsa_sync synced\n"); sleep(1); /* give a time for note releasing.. */ } /* wait for the start of the queue */ static void wait_start(void) { snd_seq_event_t *input_event; /* wait for the start event from the system timer */ for (;;) { input_event = wait_for_event(); if (input_event) { if (verbose >= VERB_MUCH) printf("wait_start got event. type=%d, flags=%d\n", input_event->type, input_event->flags); if (input_event->type == SND_SEQ_EVENT_START && input_event->data.queue.queue == dest_queue) { snd_seq_free_event(input_event); break; } snd_seq_free_event(input_event); } } if (verbose >= VERB_MUCH) printf("start received\n"); } /* print the usage */ static void usage(void) { fprintf(stderr, "usage: playmidi1 [options] [file]\n"); fprintf(stderr, " options:\n"); fprintf(stderr, " -v: verbose mode\n"); fprintf(stderr, " -a client:port : set destination address (default=%d:%d)\n", DEST_CLIENT_NUMBER, DEST_PORT_NUMBER); fprintf(stderr, " -q queue: use the specified queue\n"); fprintf(stderr, " -s queue: slave mode (allow external clock synchronization)\n"); fprintf(stderr, " -r : play on real-time mode\n"); fprintf(stderr, " -b : play on non-blocking mode\n"); } int main(int argc, char *argv[]) { int tmp; int c; snd_seq_addr_t dest_addr; const char *addr = "65:0"; while ((c = getopt(argc, argv, "s:a:p:q:vrb")) != -1) { switch (c) { case 'v': verbose++; break; case 'a': case 'p': addr = optarg; break; case 'q': dest_queue = atoi(optarg); if (dest_queue < 0) { fprintf(stderr, "invalid queue number %d\n", dest_queue); exit(1); } break; case 's': slave = 1; dest_queue = atoi(optarg); if (dest_queue < 0) { fprintf(stderr, "invalid queue number %d\n", dest_queue); exit(1); } break; case 'r': use_realtime = 1; break; case 'b': use_blocking_mode = 0; break; default: usage(); exit(1); } } if (verbose >= VERB_INFO) { if (use_realtime) printf("ALSA MIDI Player, feeding events to real-time queue\n"); else printf("ALSA MIDI Player, feeding events to song queue\n"); } /* open the sequencer device */ /* Here we open the device in read/write for slave mode. */ tmp = snd_seq_open(&seq_handle, "hw", slave ? SND_SEQ_OPEN_DUPLEX : SND_SEQ_OPEN_OUTPUT, 0); if (tmp < 0) { perror("open /dev/snd/seq"); exit(1); } tmp = snd_seq_nonblock(seq_handle, !use_blocking_mode); if (tmp < 0) { perror("block_mode"); exit(1); } /* set the name */ /* set the event filter to receive only the echo event */ /* if running in slave mode, also listen for a START event */ if (slave) snd_seq_set_client_event_filter(seq_handle, SND_SEQ_EVENT_START); snd_seq_set_client_name(seq_handle, "MIDI file player"); /* create the port */ my_port = snd_seq_create_simple_port(seq_handle, "Port 0", SND_SEQ_PORT_CAP_WRITE | SND_SEQ_PORT_CAP_READ, SND_SEQ_PORT_TYPE_MIDI_GENERIC); if (my_port < 0) { perror("create port"); exit(1); } if (snd_seq_parse_address(seq_handle, &dest_addr, addr) < 0) { perror("invalid destination address"); exit(1); } dest_client = dest_addr.client; dest_port = dest_addr.port; /* set the queue */ if (dest_queue >= 0) { shared_queue = 1; if (snd_seq_set_queue_usage(seq_handle, dest_queue, 1) < 0) { perror("use queue"); exit(1); } } else { shared_queue = 0; dest_queue = snd_seq_alloc_queue(seq_handle); if (dest_queue < 0) { perror("alloc queue"); exit(1); } } /* set the subscriber */ tmp = snd_seq_connect_to(seq_handle, my_port, dest_client, dest_port); if (tmp < 0) { perror("subscribe"); exit(1); } /* subscribe for the timer START event */ if (slave) { tmp = snd_seq_connect_from(seq_handle, my_port, SND_SEQ_CLIENT_SYSTEM, dest_queue + 16 /*snd_seq_queue_sync_port(dest_queue)*/); if (tmp < 0) { perror("subscribe"); exit(1); } } /* change the pool size */ if (snd_seq_set_client_pool_output(seq_handle, WRITE_POOL_SIZE) < 0 || snd_seq_set_client_pool_input(seq_handle, READ_POOL_SIZE) < 0 || snd_seq_set_client_pool_output_room(seq_handle, WRITE_POOL_SPACE) < 0) { perror("pool"); exit(1); } if (optind < argc) { F = fopen(argv[optind], "r"); if (F == NULL) { fprintf(stderr, "playmidi1: can't open file %s\n", argv[optind]); exit(1); } } else F = stdin; Mf_header = do_header; Mf_tempo = do_tempo; Mf_getc = mygetc; Mf_text = mytext; Mf_noteon = do_noteon; Mf_noteoff = do_noteoff; Mf_program = do_program; Mf_parameter = do_parameter; Mf_pitchbend = do_pitchbend; Mf_pressure = do_pressure; Mf_chanpressure = do_chanpressure; Mf_sysex = do_sysex; /* go.. go.. go.. */ mfread(); alsa_sync(); if (! shared_queue) alsa_stop_timer(); snd_seq_close(seq_handle); if (verbose >= VERB_INFO) { printf("Stopping at %f s, tick %f\n", tick2time_dbl(Mf_currtime + 1), (double) (Mf_currtime + 1)); } exit(0); }