/* * The sequencer personality manager. * * Copyright by Hannu Savolainen 1993 * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. 2. * Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ * */ /* * This is the newmidi sequencer driver. This driver handles io against * /dev/sequencer, midi input and output event queues and event transmittion * to and from a midi device or synthesizer. */ #include #include #ifndef DDB #define DDB(x) #endif /* DDB */ #define SND_DEV_SEQ 1 /* Sequencer output /dev/sequencer (FM synthesizer and MIDI output) */ #define SND_DEV_MIDIN 2 /* Raw midi access */ #define SND_DEV_SEQ2 8 /* /dev/sequencer, level 2 interface */ #define MIDIDEV_MODE 0x2000 /* Length of a sequencer event. */ #define EV_SZ 8 #define IEV_SZ 8 /* Return value from seq_playevent and the helpers. */ enum { MORE, TIMERARMED, QUEUEFULL }; /* * These functions goes into seq_op_desc to get called * from sound.c. */ static midi_intr_t seq_intr; static seq_callback_t seq_callback; /* These are the entries to the sequencer driver. */ static d_open_t seq_open; static d_close_t seq_close; static d_ioctl_t seq_ioctl; static d_read_t seq_read; static d_write_t seq_write; static d_poll_t seq_poll; /* * This is the device descriptor for the midi sequencer. */ seqdev_info seq_op_desc = { "midi sequencer", 0, seq_open, seq_close, seq_read, seq_write, seq_ioctl, seq_poll, seq_callback, SEQ_BUFFSIZE, /* Queue Length */ 0, /* XXX This is not an *audio* device! */ }; /* Here is the parameter structure per a device. */ struct seq_softc { seqdev_info *devinfo; /* sequencer device information */ int fflags; /* Access mode */ u_long seq_time; /* The beggining time of this sequence */ u_long prev_event_time; /* The time of the previous event output */ u_long prev_input_time; /* The time of the previous event input */ u_long prev_wakeup_time; /* The time of the previous wakeup */ struct callout_handle timeout_ch; /* Timer callout handler */ long timer_current; /* Current timer value */ int timer_running; /* State of timer */ int midi_open[NMIDI_MAX]; /* State of midi devices. */ int pending_timer; /* Timer change operation */ int output_threshould; /* Sequence output threshould */ int pre_event_timeout; /* Time to wait event input */ int queueout_pending; /* Pending for the output queue */ snd_sync_parm sync_parm; /* AIOSYNC parameter set */ struct proc *sync_proc; /* AIOSYNCing process */ }; typedef struct seq_softc *sc_p; static d_open_t seqopen; static d_close_t seqclose; static d_ioctl_t seqioctl; static d_read_t seqread; static d_write_t seqwrite; static d_poll_t seqpoll; #define CDEV_MAJOR SEQ_CDEV_MAJOR static struct cdevsw seq_cdevsw = { /* open */ seqopen, /* close */ seqclose, /* read */ seqread, /* write */ seqwrite, /* ioctl */ seqioctl, /* poll */ seqpoll, /* mmap */ nommap, /* strategy */ nostrategy, /* name */ "midi", /* XXX */ /* maj */ CDEV_MAJOR, /* dump */ nodump, /* psize */ nopsize, /* flags */ 0, /* bmaj */ -1 }; seqdev_info seq_info[NSEQ_MAX] ; static int seq_info_inited; u_long nseq = NSEQ_MAX; /* total number of sequencers */ /* The followings are the local function. */ static int seq_init(void); static int seq_queue(sc_p scp, u_char *note); static void seq_startplay(sc_p scp); static int seq_playevent(sc_p scp, u_char *event); static u_long seq_gettime(void); static int seq_requesttimer(sc_p scp, int delay); static void seq_stoptimer(sc_p scp); static void seq_midiinput(sc_p scp, mididev_info *md); static int seq_copytoinput(sc_p scp, u_char *event, int len); static int seq_extended(sc_p scp, u_char *event); static int seq_chnvoice(sc_p scp, u_char *event); static int seq_findvoice(mididev_info *md, int chn, int note); static int seq_allocvoice(mididev_info *md, int chn, int note); static int seq_chncommon(sc_p scp, u_char *event); static int seq_timing(sc_p scp, u_char *event); static int seq_local(sc_p scp, u_char *event); static int seq_sysex(sc_p scp, u_char *event); static void seq_timer(void *arg); static int seq_reset(sc_p scp); static int seq_openmidi(sc_p scp, mididev_info *md, int flags, int mode, struct proc *p); static int seq_closemidi(sc_p scp, mididev_info *md, int flags, int mode, struct proc *p); static void seq_panic(sc_p scp); static int seq_sync(sc_p scp); static seqdev_info * get_seqdev_info(dev_t i_dev, int *unit); /* * Here are the main functions to interact to the user process. * These are called from snd* functions in sys/i386/isa/snd/sound.c. */ static int seq_init(void) { int unit; sc_p scp; seqdev_info *devinfo; DEB(printf("seq: initing.\n")); /* Have we already inited? */ if (seq_info_inited) return (1); for (unit = 0 ; unit < nseq ; unit++) { /* Allocate the softc. */ scp = malloc(sizeof(*scp), M_DEVBUF, M_NOWAIT); if (scp == (sc_p)NULL) { printf("seq%d: softc allocation failed.\n", unit); return (1); } bzero(scp, sizeof(*scp)); /* Fill the softc and the seq_info for this unit. */ scp->seq_time = seq_gettime(); scp->prev_event_time = 0; scp->prev_input_time = 0; scp->prev_wakeup_time = scp->seq_time; callout_handle_init(&scp->timeout_ch); scp->timer_current = 0; scp->timer_running = 0; scp->queueout_pending = 0; scp->devinfo = devinfo = &seq_info[unit]; bcopy(&seq_op_desc, devinfo, sizeof(seq_op_desc)); devinfo->unit = unit; devinfo->softc = scp; devinfo->flags = 0; devinfo->midi_dbuf_in.unit_size = devinfo->midi_dbuf_out.unit_size = EV_SZ; midibuf_init(&devinfo->midi_dbuf_in); midibuf_init(&devinfo->midi_dbuf_out); make_dev(&seq_cdevsw, MIDIMKMINOR(unit, SND_DEV_SEQ), UID_ROOT, GID_WHEEL, 0666, "sequencer%d", unit); } /* We have inited. */ seq_info_inited = 1; if (nseq == 1) printf("seq0: Midi sequencer.\n"); else printf("seq0-%lu: Midi sequencers.\n", nseq - 1); DEB(printf("seq: inited.\n")); return (0); } int seq_open(dev_t i_dev, int flags, int mode, struct proc *p) { int unit, s, midiunit; sc_p scp; seqdev_info *sd; mididev_info *md; unit = MIDIUNIT(i_dev); DEB(printf("seq%d: opening.\n", unit)); if (unit >= NSEQ_MAX) { DEB(printf("seq_open: unit %d does not exist.\n", unit)); return (ENXIO); } sd = get_seqdev_info(i_dev, &unit); if (sd == NULL) { DEB(printf("seq_open: unit %d is not configured.\n", unit)); return (ENXIO); } scp = sd->softc; s = splmidi(); /* Mark this device busy. */ if ((sd->flags & SEQ_F_BUSY) != 0) { splx(s); DEB(printf("seq_open: unit %d is busy.\n", unit)); return (EBUSY); } sd->flags |= SEQ_F_BUSY; sd->flags &= ~(SEQ_F_READING | SEQ_F_WRITING); scp->fflags = flags; /* Init the queue. */ midibuf_init(&sd->midi_dbuf_in); midibuf_init(&sd->midi_dbuf_out); /* Init timestamp. */ scp->seq_time = seq_gettime(); scp->prev_event_time = 0; scp->prev_input_time = 0; scp->prev_wakeup_time = scp->seq_time; splx(s); /* Open midi devices. */ for (midiunit = 0 ; midiunit < nmidi + nsynth ; midiunit++) { md = &midi_info[midiunit]; if (MIDICONFED(md)) seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, p); } DEB(printf("seq%d: opened.\n", unit)); return (0); } int seq_close(dev_t i_dev, int flags, int mode, struct proc *p) { int unit, s, i; sc_p scp; seqdev_info *sd; mididev_info *md; unit = MIDIUNIT(i_dev); DEB(printf("seq%d: closing.\n", unit)); if (unit >= NSEQ_MAX) { DEB(printf("seq_close: unit %d does not exist.\n", unit)); return (ENXIO); } sd = get_seqdev_info(i_dev, &unit); if (sd == NULL) { DEB(printf("seq_close: unit %d is not configured.\n", unit)); return (ENXIO); } scp = sd->softc; s = splmidi(); if (!(sd->flags & MIDI_F_NBIO)) seq_sync(scp); /* Stop the timer. */ seq_stoptimer(scp); /* Reset the sequencer. */ seq_reset(scp); seq_sync(scp); /* Clean up the midi device. */ for (i = 0 ; i < nmidi + nsynth ; i++) { md = &midi_info[i]; if (MIDICONFED(md)) seq_closemidi(scp, md, scp->fflags, MIDIDEV_MODE, p); } /* Stop playing and unmark this device busy. */ sd->flags &= ~(SEQ_F_BUSY | SEQ_F_READING | SEQ_F_WRITING); splx(s); DEB(printf("seq%d: closed.\n", unit)); return (0); } int seq_read(dev_t i_dev, struct uio *buf, int flag) { int unit, ret, s, len; sc_p scp; seqdev_info *sd; unit = MIDIUNIT(i_dev); /*DEB(printf("seq%d: reading.\n", unit));*/ if (unit >= NSEQ_MAX) { DEB(printf("seq_read: unit %d does not exist.\n", unit)); return (ENXIO); } sd = get_seqdev_info(i_dev, &unit); if (sd == NULL) { DEB(printf("seq_read: unit %d is not configured.\n", unit)); return (ENXIO); } scp = sd->softc; if ((scp->fflags & FREAD) == 0) { DEB(printf("seq_read: unit %d is not for reading.\n", unit)); return (EIO); } s = splmidi(); /* Begin recording. */ sd->callback(sd, SEQ_CB_START | SEQ_CB_RD); /* Have we got the data to read? */ if ((sd->flags & SEQ_F_NBIO) != 0 && sd->midi_dbuf_in.rl == 0) ret = EAGAIN; else { len = buf->uio_resid; ret = midibuf_uioread(&sd->midi_dbuf_in, buf, len); if (ret < 0) ret = -ret; else ret = 0; } splx(s); return (ret); } int seq_write(dev_t i_dev, struct uio *buf, int flag) { u_char event[EV_SZ], ev_code; int unit, count, countorg, midiunit, ev_size, p, ret, s; sc_p scp; seqdev_info *sd; mididev_info *md; unit = MIDIUNIT(i_dev); /*DEB(printf("seq%d: writing.\n", unit));*/ if (unit >= NSEQ_MAX) { DEB(printf("seq_write: unit %d does not exist.\n", unit)); return (ENXIO); } sd = get_seqdev_info(i_dev, &unit); if (sd == NULL) { DEB(printf("seq_write: unit %d is not configured.\n", unit)); return (ENXIO); } scp = sd->softc; if ((scp->fflags & FWRITE) == 0) { DEB(printf("seq_write: unit %d is not for writing.\n", unit)); return (EIO); } p = 0; countorg = buf->uio_resid; count = countorg; s = splmidi(); /* Begin playing. */ sd->callback(sd, SEQ_CB_START | SEQ_CB_WR); splx(s); /* Pick up an event. */ while (count >= 4) { if (uiomove((caddr_t)event, 4, buf)) printf("seq_write: user memory mangled?\n"); ev_code = event[0]; /* Have a look at the event code. */ if (ev_code == SEQ_FULLSIZE) { /* A long event, these are the patches/samples for a synthesizer. */ midiunit = *(u_short *)&event[2]; if (midiunit < 0 || midiunit >= nmidi + nsynth) return (ENXIO); md = &midi_info[midiunit]; if (!MIDICONFED(md)) return (ENXIO); s = splmidi(); if ((md->flags & MIDI_F_BUSY) == 0 && seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc) != 0) { splx(s); return (ENXIO); } DEB(printf("seq_write: loading a patch to the unit %d.\n", midiunit)); ret = md->synth.loadpatch(md, *(short *)&event[0], buf, p + 4, count, 0); splx(s); return (ret); } if (ev_code >= 128) { /* Some sort of an extended event. The size is eight bytes. */ #if notyet if (scp->seq_mode == SEQ_2 && ev_code == SEQ_EXTENDED) { printf("seq%d: invalid level two event %x.\n", unit, ev_code); return (EINVAL); } #endif /* notyet */ ev_size = 8; if (count < ev_size) { /* No more data. Start playing now. */ s = splmidi(); sd->callback(sd, SEQ_CB_START | SEQ_CB_WR); splx(s); return (0); } if (uiomove((caddr_t)&event[4], 4, buf)) printf("seq_write: user memory mangled?\n"); } else { /* Not an extended event. The size is four bytes. */ #if notyet if (scp->seq_mode == SEQ_2) { printf("seq%d: four byte event in level two mode.\n", unit); return (EINVAL); } #endif /* notyet */ ev_size = 4; } if (ev_code == SEQ_MIDIPUTC) { /* An event passed to the midi device itself. */ midiunit = event[2]; if (midiunit < 0 || midiunit >= nmidi + nsynth) return (ENXIO); md = &midi_info[midiunit]; if (!MIDICONFED(md)) return (ENXIO); if ((md->flags & MIDI_F_BUSY) == 0 && (ret = seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc)) != 0) { seq_reset(scp); return (ret); } } /*DEB(printf("seq_write: queueing event %d.\n", event[0]));*/ /* Now we queue the event. */ switch (seq_queue(scp, event)) { case EAGAIN: s = splmidi(); /* The queue is full. Start playing now. */ sd->callback(sd, SEQ_CB_START | SEQ_CB_WR); splx(s); return (0); case EINTR: return (EINTR); case ERESTART: return (ERESTART); } p += ev_size; count -= ev_size; } /* We have written every single data. Start playing now. */ s = splmidi(); sd->callback(sd, SEQ_CB_START | SEQ_CB_WR); splx(s); return (0); } int seq_ioctl(dev_t i_dev, u_long cmd, caddr_t arg, int mode, struct proc *p) { int unit, midiunit, ret, tmp, s, arg2; sc_p scp; seqdev_info *sd; mididev_info *md; struct synth_info *synthinfo; struct midi_info *midiinfo; struct patmgr_info *patinfo; snd_sync_parm *syncparm; struct seq_event_rec *event; struct snd_size *sndsize; unit = MIDIUNIT(i_dev); DEB(printf("seq%d: ioctlling, cmd 0x%x.\n", unit, (int)cmd)); if (unit >= NSEQ_MAX) { DEB(printf("seq_ioctl: unit %d does not exist.\n", unit)); return (ENXIO); } sd = get_seqdev_info(i_dev, &unit); if (sd == NULL) { DEB(printf("seq_ioctl: unit %d is not configured.\n", unit)); return (ENXIO); } scp = sd->softc; ret = 0; switch (cmd) { /* * we start with the new ioctl interface. */ case AIONWRITE: /* how many bytes can be written ? */ *(int *)arg = sd->midi_dbuf_out.fl; break; case AIOSSIZE: /* set the current blocksize */ sndsize = (struct snd_size *)arg; if (sndsize->play_size <= sd->midi_dbuf_out.unit_size && sndsize->rec_size <= sd->midi_dbuf_in.unit_size) { sd->flags &= ~MIDI_F_HAS_SIZE; sd->midi_dbuf_out.blocksize = sd->midi_dbuf_out.unit_size; sd->midi_dbuf_in.blocksize = sd->midi_dbuf_in.unit_size; } else { if (sndsize->play_size > sd->midi_dbuf_out.bufsize / 4) sndsize->play_size = sd->midi_dbuf_out.bufsize / 4; if (sndsize->rec_size > sd->midi_dbuf_in.bufsize / 4) sndsize->rec_size = sd->midi_dbuf_in.bufsize / 4; /* Round up the size to the multiple of EV_SZ. */ sd->midi_dbuf_out.blocksize = ((sndsize->play_size + sd->midi_dbuf_out.unit_size - 1) / sd->midi_dbuf_out.unit_size) * sd->midi_dbuf_out.unit_size; sd->midi_dbuf_in.blocksize = ((sndsize->rec_size + sd->midi_dbuf_in.unit_size - 1) / sd->midi_dbuf_in.unit_size) * sd->midi_dbuf_in.unit_size; sd->flags |= MIDI_F_HAS_SIZE; } /* FALLTHROUGH */ case AIOGSIZE: /* get the current blocksize */ sndsize = (struct snd_size *)arg; sndsize->play_size = sd->midi_dbuf_out.blocksize; sndsize->rec_size = sd->midi_dbuf_in.blocksize; ret = 0; break; case AIOSTOP: if (*(int *)arg == AIOSYNC_PLAY) { s = splmidi(); /* Stop writing. */ sd->callback(sd, SEQ_CB_ABORT | SEQ_CB_WR); /* Pass the ioctl to the midi devices. */ for (midiunit = 0 ; midiunit < nmidi + nsynth ; midiunit++) { md = &midi_info[midiunit]; if (MIDICONFED(md) && scp->midi_open[midiunit] && (md->flags & MIDI_F_WRITING) != 0) { arg2 = *(int *)arg; midi_ioctl(MIDIMKDEV(major(i_dev), midiunit, SND_DEV_MIDIN), cmd, (caddr_t)&arg2, mode, p); } } *(int *)arg = sd->midi_dbuf_out.rl; splx(s); } else if (*(int *)arg == AIOSYNC_CAPTURE) { s = splmidi(); /* Stop reading. */ sd->callback(sd, SEQ_CB_ABORT | SEQ_CB_RD); /* Pass the ioctl to the midi devices. */ for (midiunit = 0 ; midiunit < nmidi + nsynth ; midiunit++) { md = &midi_info[midiunit]; if (MIDICONFED(md) && scp->midi_open[midiunit] && (md->flags & MIDI_F_WRITING) != 0) { arg2 = *(int *)arg; midi_ioctl(MIDIMKDEV(major(i_dev), midiunit, SND_DEV_MIDIN), cmd, (caddr_t)&arg2, mode, p); } } *(int *)arg = sd->midi_dbuf_in.rl; splx(s); } ret = 0; break; case AIOSYNC: syncparm = (snd_sync_parm *)arg; scp->sync_parm = *syncparm; /* XXX Should select(2) against us watch the blocksize, or sync_parm? */ ret = 0; break; case SNDCTL_TMR_TIMEBASE: case SNDCTL_TMR_TEMPO: case SNDCTL_TMR_START: case SNDCTL_TMR_STOP: case SNDCTL_TMR_CONTINUE: case SNDCTL_TMR_METRONOME: case SNDCTL_TMR_SOURCE: #if notyet if (scp->seq_mode != SEQ_2) { ret = EINVAL; break; } ret = tmr->ioctl(tmr_no, cmd, arg); #endif /* notyet */ break; case SNDCTL_TMR_SELECT: #if notyet if (scp->seq_mode != SEQ_2) { ret = EINVAL; break; } #endif /* notyet */ scp->pending_timer = *(int *)arg; if (scp->pending_timer < 0 || scp->pending_timer >= /*NTIMER*/1) { scp->pending_timer = -1; ret = EINVAL; break; } *(int *)arg = scp->pending_timer; ret = 0; break; case SNDCTL_SEQ_PANIC: seq_panic(scp); ret = 0; break; case SNDCTL_SEQ_SYNC: if (mode == O_RDONLY) { ret = 0; break; } ret = seq_sync(scp); break; case SNDCTL_SEQ_RESET: seq_reset(scp); ret = 0; break; case SNDCTL_SEQ_TESTMIDI: midiunit = *(int *)arg; if (midiunit >= nmidi + nsynth) { ret = ENXIO; break; } md = &midi_info[midiunit]; if (MIDICONFED(md) && !scp->midi_open[midiunit]) { ret = seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc); break; } ret = 0; break; case SNDCTL_SEQ_GETINCOUNT: if (mode == O_WRONLY) *(int *)arg = 0; else *(int *)arg = sd->midi_dbuf_in.rl; ret = 0; break; case SNDCTL_SEQ_GETOUTCOUNT: if (mode == O_RDONLY) *(int *)arg = 0; else *(int *)arg = sd->midi_dbuf_out.fl; ret = 0; break; case SNDCTL_SEQ_CTRLRATE: #if notyet if (scp->seq_mode != SEQ_2) { ret = tmr->ioctl(tmr_no, cmd, arg); break; } #endif /* notyet */ if (*(int *)arg != 0) { ret = EINVAL; break; } *(int *)arg = hz; ret = 0; break; case SNDCTL_SEQ_RESETSAMPLES: midiunit = *(int *)arg; if (midiunit >= nmidi + nsynth) { ret = ENXIO; break; } if (!scp->midi_open[midiunit]) { md = &midi_info[midiunit]; if (MIDICONFED(md)) { ret = seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc); if (ret != 0) break; } else { ret = EBUSY; break; } } ret = midi_ioctl(MIDIMKDEV(major(i_dev), midiunit, SND_DEV_MIDIN), cmd, arg, mode, p); break; case SNDCTL_SEQ_NRSYNTHS: *(int *)arg = nmidi + nsynth; ret = 0; break; case SNDCTL_SEQ_NRMIDIS: *(int *)arg = nmidi + nsynth; ret = 0; break; case SNDCTL_SYNTH_MEMAVL: midiunit = *(int *)arg; if (midiunit >= nmidi + nsynth) { ret = ENXIO; break; } if (!scp->midi_open[midiunit]) { md = &midi_info[midiunit]; if (MIDICONFED(md)) { ret = seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc); if (ret != 0) break; } else { ret = EBUSY; break; } } ret = midi_ioctl(MIDIMKDEV(major(i_dev), midiunit, SND_DEV_MIDIN), cmd, arg, mode, p); break; case SNDCTL_FM_4OP_ENABLE: midiunit = *(int *)arg; if (midiunit >= nmidi + nsynth) { ret = ENXIO; break; } if (!scp->midi_open[midiunit]) { md = &midi_info[midiunit]; if (MIDICONFED(md)) { ret = seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc); if (ret != 0) break; } else { ret = EBUSY; break; } } ret = midi_ioctl(MIDIMKDEV(major(i_dev), midiunit, SND_DEV_MIDIN), cmd, arg, mode, p); break; case SNDCTL_SYNTH_INFO: synthinfo = (struct synth_info *)arg; midiunit = synthinfo->device; if (midiunit >= nmidi + nsynth) { ret = ENXIO; break; } ret = midi_ioctl(MIDIMKDEV(major(i_dev), midiunit, SND_DEV_MIDIN), cmd, arg, mode, p); break; case SNDCTL_SEQ_OUTOFBAND: event = (struct seq_event_rec *)arg; s = splmidi(); ret = seq_playevent(scp, event->arr); splx(s); break; case SNDCTL_MIDI_INFO: midiinfo = (struct midi_info *)arg; midiunit = midiinfo->device; if (midiunit >= nmidi + nsynth) { ret = ENXIO; break; } ret = midi_ioctl(MIDIMKDEV(major(i_dev), midiunit, SND_DEV_MIDIN), cmd, arg, mode, p); break; case SNDCTL_PMGR_IFACE: patinfo = (struct patmgr_info *)arg; midiunit = patinfo->device; if (midiunit >= nmidi + nsynth) { ret = ENXIO; break; } if (!scp->midi_open[midiunit]) { ret = EBUSY; break; } ret = midi_ioctl(MIDIMKDEV(major(i_dev), midiunit, SND_DEV_MIDIN), cmd, arg, mode, p); break; case SNDCTL_PMGR_ACCESS: patinfo = (struct patmgr_info *)arg; midiunit = patinfo->device; if (midiunit >= nmidi + nsynth) { ret = ENXIO; break; } if (!scp->midi_open[midiunit]) { md = &midi_info[midiunit]; if (MIDICONFED(md)) { ret = seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc); if (ret != 0) break; } else { ret = EBUSY; break; } } ret = midi_ioctl(MIDIMKDEV(major(i_dev), midiunit, SND_DEV_MIDIN), cmd, arg, mode, p); break; case SNDCTL_SEQ_THRESHOLD: tmp = *(int *)arg; RANGE(tmp, 1, sd->midi_dbuf_out.bufsize - 1); scp->output_threshould = tmp; ret = 0; break; case SNDCTL_MIDI_PRETIME: tmp = *(int *)arg; if (tmp < 0) tmp = 0; tmp = (hz * tmp) / 10; scp->pre_event_timeout = tmp; ret = 0; break; default: if (scp->fflags == O_RDONLY) { ret = EIO; break; } if (!scp->midi_open[0]) { md = &midi_info[0]; if (MIDICONFED(md)) { ret = seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc); if (ret != 0) break; } else { ret = EBUSY; break; } } ret = midi_ioctl(MIDIMKDEV(major(i_dev), 0, SND_DEV_MIDIN), cmd, arg, mode, p); break; } return (ret); } int seq_poll(dev_t i_dev, int events, struct proc *p) { int unit, ret, s, lim; sc_p scp; seqdev_info *sd; unit = MIDIUNIT(i_dev); DEB(printf("seq%d: polling.\n", unit)); if (unit >= NSEQ_MAX) { DEB(printf("seq_poll: unit %d does not exist.\n", unit)); return (ENXIO); } sd = get_seqdev_info(i_dev, &unit); if (sd == NULL) { DEB(printf("seq_poll: unit %d is not configured.\n", unit)); return (ENXIO); } scp = sd->softc; ret = 0; s = splmidi(); /* Look up the apropriate queue and select it. */ if ((events & (POLLOUT | POLLWRNORM)) != 0) { /* Start playing. */ sd->callback(sd, SEQ_CB_START | SEQ_CB_WR); /* Find out the boundary. */ if ((sd->flags & SEQ_F_HAS_SIZE) != 0) lim = sd->midi_dbuf_out.blocksize; else lim = sd->midi_dbuf_out.unit_size; if (sd->midi_dbuf_out.fl < lim) /* No enough space, record select. */ selrecord(p, &sd->midi_dbuf_out.sel); else /* We can write now. */ ret |= events & (POLLOUT | POLLWRNORM); } if ((events & (POLLIN | POLLRDNORM)) != 0) { /* Start recording. */ sd->callback(sd, SEQ_CB_START | SEQ_CB_RD); /* Find out the boundary. */ if ((sd->flags & SEQ_F_HAS_SIZE) != 0) lim = sd->midi_dbuf_in.blocksize; else lim = sd->midi_dbuf_in.unit_size; if (sd->midi_dbuf_in.rl < lim) /* No data ready, record select. */ selrecord(p, &sd->midi_dbuf_in.sel); else /* We can write now. */ ret |= events & (POLLIN | POLLRDNORM); } splx(s); return (ret); } static void seq_intr(void *p, mididev_info *md) { sc_p scp; seqdev_info *sd; sd = (seqdev_info *)p; scp = sd->softc; /* Restart playing if we have the data to output. */ if (scp->queueout_pending) sd->callback(sd, SEQ_CB_START | SEQ_CB_WR); /* Check the midi device if we are reading. */ if ((sd->flags & SEQ_F_READING) != 0) seq_midiinput(scp, md); } static int seq_callback(seqdev_info *sd, int reason) { int unit; sc_p scp; /*DEB(printf("seq_callback: reason 0x%x.\n", reason));*/ if (sd == NULL) { DEB(printf("seq_callback: device not configured.\n")); return (ENXIO); } scp = sd->softc; unit = sd->unit; switch (reason & SEQ_CB_REASON_MASK) { case SEQ_CB_START: if ((reason & SEQ_CB_RD) != 0 && (sd->flags & SEQ_F_READING) == 0) /* Begin recording. */ sd->flags |= SEQ_F_READING; if ((reason & SEQ_CB_WR) != 0 && (sd->flags & SEQ_F_WRITING) == 0) /* Start playing. */ seq_startplay(scp); break; case SEQ_CB_STOP: case SEQ_CB_ABORT: if ((reason & SEQ_CB_RD) != 0 && (sd->flags & SEQ_F_READING) != 0) { /* Stop the timer. */ scp->seq_time = seq_gettime(); scp->prev_input_time = 0; /* Stop recording. */ sd->flags &= ~SEQ_F_READING; } if ((reason & SEQ_CB_WR) != 0 && (sd->flags & SEQ_F_WRITING) != 0) { /* Stop the timer. */ seq_stoptimer(scp); scp->seq_time = seq_gettime(); scp->prev_event_time = 0; /* Stop Playing. */ sd->flags &= ~SEQ_F_WRITING; scp->queueout_pending = 0; } break; } return (0); } /* * The functions below here are the libraries for the above ones. */ static int seq_queue(sc_p scp, u_char *note) { int unit, err, s; seqdev_info *sd; sd = scp->devinfo; unit = sd->unit; /*DEB(printf("seq%d: queueing.\n", unit));*/ s = splmidi(); /* Start playing if we have some data in the queue. */ if (sd->midi_dbuf_out.rl >= EV_SZ) sd->callback(sd, SEQ_CB_START | SEQ_CB_WR); if (sd->midi_dbuf_out.fl < EV_SZ) { /* We have no space. Start playing if not yet. */ sd->callback(sd, SEQ_CB_START | SEQ_CB_WR); if ((sd->flags & SEQ_F_NBIO) != 0 && sd->midi_dbuf_out.fl < EV_SZ) { /* We would block. */ splx(s); return (EAGAIN); } else while (sd->midi_dbuf_out.fl < EV_SZ) { /* We have no space. Good night. */ err = tsleep(&sd->midi_dbuf_out.tsleep_out, PRIBIO | PCATCH, "seqque", 0); if (err == EINTR) sd->callback(sd, SEQ_CB_STOP | SEQ_CB_WR); if (err == EINTR || err == ERESTART) { splx(s); return (err); } } } /* We now have enough space to write. */ err = midibuf_seqwrite(&sd->midi_dbuf_out, note, EV_SZ); splx(s); if (err < 0) err = -err; else err = 0; return (err); } static void seq_startplay(sc_p scp) { int unit; u_char event[EV_SZ]; seqdev_info *sd; sd = scp->devinfo; unit = sd->unit; /* Dequeue the events to play. */ while (sd->midi_dbuf_out.rl >= EV_SZ) { /* We are playing now. */ sd->flags |= SEQ_F_WRITING; /* We only copy the event, not dequeue. */ midibuf_seqcopy(&sd->midi_dbuf_out, event, EV_SZ); switch (seq_playevent(scp, event)) { case TIMERARMED: /* Dequeue the event. */ midibuf_seqread(&sd->midi_dbuf_out, event, EV_SZ); /* FALLTHRU */ case QUEUEFULL: /* We cannot play further. */ return; case MORE: /* Dequeue the event. */ midibuf_seqread(&sd->midi_dbuf_out, event, EV_SZ); break; } } /* Played every event in the queue. */ sd->flags &= ~SEQ_F_WRITING; } static int seq_playevent(sc_p scp, u_char *event) { int unit, ret; long *delay; seqdev_info *sd; mididev_info *md; sd = scp->devinfo; unit = sd->unit; md = &midi_info[0]; if (!MIDICONFED(md)) return (MORE); switch(event[0]) { case SEQ_NOTEOFF: if ((md->flags & MIDI_F_BUSY) != 0 || seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc) == 0) if (md->synth.killnote(md, event[1], 255, event[3]) == EAGAIN) { ret = QUEUEFULL; break; } ret = MORE; break; case SEQ_NOTEON: if (((md->flags & MIDI_F_BUSY) != 0 || seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc) == 0) && (event[4] < 128 || event[4] == 255)) if (md->synth.startnote(md, event[1], event[2], event[3]) == EAGAIN) { ret = QUEUEFULL; break; } ret = MORE; break; case SEQ_WAIT: /* Extract the delay. */ delay = (long *)event; *delay = (*delay >> 8) & 0xffffff; if (*delay > 0) { /* Arm the timer. */ sd->flags |= SEQ_F_WRITING; scp->prev_event_time = *delay; if (seq_requesttimer(scp, *delay)) { ret = TIMERARMED; break; } } ret = MORE; break; case SEQ_PGMCHANGE: if ((md->flags & MIDI_F_BUSY) != 0 || seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc) == 0) if (md->synth.setinstr(md, event[1], event[2]) == EAGAIN) { ret = QUEUEFULL; break; } ret = MORE; break; case SEQ_SYNCTIMER: /* Reset the timer. */ scp->seq_time = seq_gettime(); scp->prev_input_time = 0; scp->prev_event_time = 0; scp->prev_wakeup_time = scp->seq_time; ret = MORE; break; case SEQ_MIDIPUTC: /* Pass through to the midi device. */ if (event[2] < nmidi + nsynth) { md = &midi_info[event[2]]; if (MIDICONFED(md) && ((md->flags & MIDI_F_BUSY) != 0 || seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc) == 0)) { if (md->synth.writeraw(md, &event[1], sizeof(event[1]), 1) == EAGAIN) { /* The queue was full. Try again later. */ ret = QUEUEFULL; break; } } } ret = MORE; break; case SEQ_ECHO: /* Echo this event back. */ if (seq_copytoinput(scp, event, 4) == EAGAIN) { ret = QUEUEFULL; break; } ret = MORE; break; case SEQ_PRIVATE: if (event[1] < nmidi + nsynth) { md = &midi_info[event[1]]; if (MIDICONFED(md) && md->synth.hwcontrol(md, event) == EAGAIN) { ret = QUEUEFULL; break; } } ret = MORE; break; case SEQ_EXTENDED: ret = seq_extended(scp, event); break; case EV_CHN_VOICE: ret = seq_chnvoice(scp, event); break; case EV_CHN_COMMON: ret = seq_chncommon(scp, event); break; case EV_TIMING: ret = seq_timing(scp, event); break; case EV_SEQ_LOCAL: ret = seq_local(scp, event); break; case EV_SYSEX: ret = seq_sysex(scp, event); break; default: ret = MORE; break; } switch (ret) { case QUEUEFULL: /*DEB(printf("seq_playevent: the queue is full.\n"));*/ /* The queue was full. Try again on the interrupt by the midi device. */ sd->flags |= SEQ_F_WRITING; scp->queueout_pending = 1; break; case TIMERARMED: sd->flags |= SEQ_F_WRITING; /* FALLTHRU */ case MORE: scp->queueout_pending = 0; break; } return (ret); } static u_long seq_gettime(void) { struct timeval timecopy; getmicrotime(&timecopy); return timecopy.tv_usec / (1000000 / hz) + (u_long) timecopy.tv_sec * hz; } static int seq_requesttimer(sc_p scp, int delay) { u_long cur_time, rel_base; /*DEB(printf("seq%d: requested timer at delay of %d.\n", unit, delay));*/ cur_time = seq_gettime(); if (delay < 0) /* Request a new timer. */ delay = -delay; else { rel_base = cur_time - scp->seq_time; if (delay <= rel_base) return 0; delay -= rel_base; } #if notdef /* * Compensate the delay of midi message transmission. * XXX Do we have to consider the accumulation of errors * less than 1/hz second? */ delay -= (cur_time - scp->prev_wakeup_time); if (delay < 1) { printf("sequencer: prev = %lu, cur = %lu, delay = %d, skip sleeping.\n", scp->prev_wakeup_time, cur_time, delay); seq_stoptimer(scp); return 0; } #endif /* notdef */ scp->timeout_ch = timeout(seq_timer, (void *)scp, delay); scp->timer_running = 1; return 1; } static void seq_stoptimer(sc_p scp) { /*DEB(printf("seq%d: stopping timer.\n", unit));*/ if (scp->timer_running) { untimeout(seq_timer, (void *)scp, scp->timeout_ch); scp->timer_running = 0; } } static void seq_midiinput(sc_p scp, mididev_info *md) { int unit, midiunit; u_long tstamp; u_char event[4]; seqdev_info *sd; sd = scp->devinfo; unit = sd->unit; /* Can this midi device interrupt for input? */ midiunit = md->unit; if (scp->midi_open[midiunit] && (md->flags & MIDI_F_READING) != 0 && md->intrarg == sd) /* Read the input data. */ while (md->synth.readraw(md, &event[1], sizeof(event[1]), 1) == 0) { tstamp = seq_gettime() - scp->seq_time; if (tstamp != scp->prev_input_time) { /* Insert a wait between events. */ tstamp = (tstamp << 8) | SEQ_WAIT; seq_copytoinput(scp, (u_char *)&tstamp, 4); scp->prev_input_time = tstamp; } event[0] = SEQ_MIDIPUTC; event[2] = midiunit; event[3] = 0; seq_copytoinput(scp, event, sizeof(event)); } } static int seq_copytoinput(sc_p scp, u_char *event, int len) { seqdev_info *sd; sd = scp->devinfo; if (midibuf_input_intr(&sd->midi_dbuf_in, event, len) == -EAGAIN) return (EAGAIN); return (0); } static int seq_extended(sc_p scp, u_char *event) { int unit; seqdev_info *sd; mididev_info *md; sd = scp->devinfo; unit = sd->unit; if (event[2] >= nmidi + nsynth) return (MORE); md = &midi_info[event[2]]; if (!MIDICONFED(md) && (md->flags & MIDI_F_BUSY) == 0 && seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc) != 0) return (MORE); switch (event[1]) { case SEQ_NOTEOFF: if (md->synth.killnote(md, event[3], event[4], event[5]) == EAGAIN) return (QUEUEFULL); break; case SEQ_NOTEON: if (event[4] < 128 || event[4] == 255) if (md->synth.startnote(md, event[3], event[4], event[5]) == EAGAIN) return (QUEUEFULL); break; case SEQ_PGMCHANGE: if (md->synth.setinstr(md, event[3], event[4]) == EAGAIN) return (QUEUEFULL); break; case SEQ_AFTERTOUCH: if (md->synth.aftertouch(md, event[3], event[4]) == EAGAIN) return (QUEUEFULL); break; case SEQ_BALANCE: if (md->synth.panning(md, event[3], (char)event[4]) == EAGAIN) return (QUEUEFULL); break; case SEQ_CONTROLLER: if (md->synth.controller(md, event[3], event[4], *(short *)&event[5]) == EAGAIN) return (QUEUEFULL); break; case SEQ_VOLMODE: if (md->synth.volumemethod != NULL) if (md->synth.volumemethod(md, event[3]) == EAGAIN) return (QUEUEFULL); break; } return (MORE); } static int seq_chnvoice(sc_p scp, u_char *event) { int voice; seqdev_info *sd; mididev_info *md; u_char dev, cmd, chn, note, parm; voice = -1; dev = event[1]; cmd = event[2]; chn = event[3]; note = event[4]; parm = event[5]; sd = scp->devinfo; if (dev >= nmidi + nsynth) return (MORE); md = &midi_info[dev]; if (!MIDICONFED(md) && (md->flags & MIDI_F_BUSY) == 0 && seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc) != 0) return (MORE); #if notyet if (scp->seq_mode == SEQ_2) { if (md->synth.allocvoice) voice = seq_allocvoice(md, chn, note); } #endif /* notyet */ switch (cmd) { case MIDI_NOTEON: if (note < 128 || note == 255) { #if notyet if (voice == -1 && scp->seq_mode == SEQ_2 && md->synth.allocvoice) /* This is an internal synthesizer. (FM, GUS, etc) */ if ((voice = seq_allocvoice(md, chn, note)) == -EAGAIN) return (QUEUEFULL); #endif /* notyet */ if (voice == -1) voice = chn; #if notyet if (scp->seq_mode == SEQ_2 && dev < nmidi + nsynth && chn == 9) { /* This channel is a percussion. The note number is the patch number. */ if (md->synth.setinstr(md, voice, 128 + note) == EAGAIN) return (QUEUEFULL); note = 60; /* Middle C. */ } if (scp->seq_mode == SEQ_2) if (md->synth.setupvoice(md, voice, chn) == EAGAIN) return (QUEUEFULL); #endif /* notyet */ if (md->synth.startnote(md, voice, note, parm) == EAGAIN) return (QUEUEFULL); } break; case MIDI_NOTEOFF: if (voice == -1) voice = chn; if (md->synth.killnote(md, voice, note, parm) == EAGAIN) return (QUEUEFULL); break; case MIDI_KEY_PRESSURE: if (voice == -1) voice = chn; if (md->synth.aftertouch(md, voice, parm) == EAGAIN) return (QUEUEFULL); break; } return (MORE); } static int seq_findvoice(mididev_info *md, int chn, int note) { int i; u_short key; key = (chn << 8) | (note + 1); for (i = 0 ; i < md->synth.alloc.max_voice ; i++) if (md->synth.alloc.map[i] == key) return (i); return (-1); } static int seq_allocvoice(mididev_info *md, int chn, int note) { int voice; u_short key; key = (chn << 8) | (note + 1); if ((voice = md->synth.allocvoice(md, chn, note, &md->synth.alloc)) == -EAGAIN) return (-EAGAIN); md->synth.alloc.map[voice] = key; md->synth.alloc.alloc_times[voice] = md->synth.alloc.timestamp++; return (voice); } static int seq_chncommon(sc_p scp, u_char *event) { int unit/*, i, val, key*/; u_short w14; u_char dev, cmd, chn, p1; seqdev_info *sd; mididev_info *md; dev = event[1]; cmd = event[2]; chn = event[3]; p1 = event[4]; w14 = *(u_short *)&event[6]; sd = scp->devinfo; unit = sd->unit; if (dev >= nmidi + nsynth) return (MORE); md = &midi_info[dev]; if (!MIDICONFED(md) && (md->flags & MIDI_F_BUSY) == 0 && seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc) != 0) return (MORE); switch (cmd) { case MIDI_PGM_CHANGE: #if notyet if (scp->seq_mode == SEQ_2) { md->synth.chn_info[chn].pgm_num = p1; if (dev < nmidi + nsynth) if (md->synth.setinstr(md, chn, p1) == EAGAIN) return (QUEUEFULL); } else #endif /* notyet */ /* For Mode 1. */ if (md->synth.setinstr(md, chn, p1) == EAGAIN) return (QUEUEFULL); break; case MIDI_CTL_CHANGE: #if notyet if (scp->seq_mode == SEQ_2) { if (chn < 16 && p1 < 128) { md->synth.chn_info[chn].controllers[p1] = w14 & 0x7f; if (p1 < 32) /* We have set the MSB, clear the LSB. */ md->synth.chn_info[chn].controllers[p1 + 32] = 0; if (dev < nmidi + nsynth) { val = w14 & 0x7f; if (p1 < 64) { /* Combine the MSB and the LSB. */ val = ((md->synth.chn_info[chn].controllers[p1 & ~32] & 0x7f) << 7) | (md->synth.chn_info[chn].controllers[p1 | 32] & 0x7f); p1 &= ~32; } /* Handle all of the notes playing on this channel. */ key = ((int)chn << 8); for (i = 0 ; i < md->synth.alloc.max_voice ; i++) if ((md->synth.alloc.map[i] & 0xff00) == key) if (md->synth.controller(md, i, p1, val) == EAGAIN) return (QUEUEFULL); } else if (md->synth.controller(md, chn, p1, w14) == EAGAIN) return (QUEUEFULL); } } else #endif /* notyet */ /* For Mode 1. */ if (md->synth.controller(md, chn, p1, w14) == EAGAIN) return (QUEUEFULL); break; case MIDI_PITCH_BEND: #if notyet if (scp->seq_mode == SEQ_2) { md->synth.chn_info[chn].bender_value = w14; if (dev < nmidi + nsynth) { /* Handle all of the notes playing on this channel. */ key = ((int)chn << 8); for (i = 0 ; i < md->synth.alloc.max_voice ; i++) if ((md->synth.alloc.map[i] & 0xff00) == key) if (md->synth.bender(md, i, w14) == EAGAIN) return (QUEUEFULL); } else if (md->synth.bender(md, chn, w14) == EAGAIN) return (QUEUEFULL); } else #endif /* notyet */ /* For Mode 1. */ if (md->synth.bender(md, chn, w14) == EAGAIN) return (QUEUEFULL); break; } return (MORE); } static int seq_timing(sc_p scp, u_char *event) { int unit/*, ret*/; long parm; seqdev_info *sd; sd = scp->devinfo; unit = sd->unit; parm = *(long *)&event[4]; #if notyet if (scp->seq_mode == SEQ_2 && (ret = tmr->event(tmr_no, event)) == TIMERARMED) return (ret); #endif /* notyet */ switch (event[1]) { case TMR_WAIT_REL: parm += scp->prev_event_time; /* FALLTHRU */ case TMR_WAIT_ABS: if (parm > 0) { sd->flags |= SEQ_F_WRITING; scp->prev_event_time = parm; if (seq_requesttimer(scp, parm)) return (TIMERARMED); } break; case TMR_START: scp->seq_time = seq_gettime(); scp->prev_input_time = 0; scp->prev_event_time = 0; scp->prev_wakeup_time = scp->seq_time; break; case TMR_STOP: break; case TMR_CONTINUE: break; case TMR_TEMPO: break; case TMR_ECHO: #if notyet if (scp->seq_mode == SEQ_2) seq_copytoinput(scp, event, 8); else { #endif /* notyet */ parm = (parm << 8 | SEQ_ECHO); seq_copytoinput(scp, (u_char *)&parm, 4); #if notyet } #endif /* notyet */ break; } return (MORE); } static int seq_local(sc_p scp, u_char *event) { int unit; seqdev_info *sd; sd = scp->devinfo; unit = sd->unit; switch (event[1]) { case LOCL_STARTAUDIO: #if notyet DMAbuf_start_devices(*(u_int *)&event[4]); #endif /* notyet */ break; } return (MORE); } static int seq_sysex(sc_p scp, u_char *event) { int unit, i, l; seqdev_info *sd; mididev_info *md; sd = scp->devinfo; unit = sd->unit; if (event[1] >= nmidi + nsynth) return (MORE); md = &midi_info[event[1]]; if (!MIDICONFED(md) || md->synth.sendsysex == NULL || ((md->flags & MIDI_F_BUSY) == 0 && seq_openmidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc) != 0)) return (MORE); l = 0; for (i = 0 ; i < 6 && event[i + 2] != 0xff ; i++) l = i + 1; if (l > 0) if (md->synth.sendsysex(md, &event[2], l) == EAGAIN) return (QUEUEFULL); return (MORE); } static void seq_timer(void *arg) { sc_p scp; scp = arg; /*DEB(printf("seq_timer: timer fired.\n"));*/ /* Record the current timestamp. */ scp->prev_wakeup_time = seq_gettime(); seq_startplay(scp); } static int seq_openmidi(sc_p scp, mididev_info *md, int flags, int mode, struct proc *p) { int midiunit, s, err; if (md == NULL || !MIDICONFED(md)) { DEB(printf("seq_openmidi: midi device does not exist.\n")); return (ENXIO); } midiunit = md->unit; DEB(printf("seq_openmidi: opening midi unit %d.\n", midiunit)); if (!scp->midi_open[midiunit]) { err = midi_open(MIDIMKDEV(MIDI_CDEV_MAJOR, midiunit, SND_DEV_MIDIN), flags, mode, p); if (err != 0) { printf("seq_openmidi: failed to open midi device %d.\n", midiunit); return (err); } s = splmidi(); scp->midi_open[midiunit] = 1; md->intr = seq_intr; md->intrarg = scp->devinfo; md->synth.prev_out_status = 0; md->synth.sysex_state = 0; splx(s); } return (0); } static int seq_closemidi(sc_p scp, mididev_info *md, int flags, int mode, struct proc *p) { int midiunit, s; if (md == NULL || !MIDICONFED(md)) { DEB(printf("seq_closemidi: midi device does not exist.\n")); return (ENXIO); } midiunit = md->unit; DEB(printf("seq_closemidi: closing midi unit %d.\n", midiunit)); if (scp->midi_open[midiunit]) { midi_close(MIDIMKDEV(MIDI_CDEV_MAJOR, midiunit, SND_DEV_MIDIN), flags, mode, p); s = splmidi(); scp->midi_open[midiunit] = 0; md->intr = NULL; md->intrarg = NULL; splx(s); } return (0); } static void seq_panic(sc_p scp) { seq_reset(scp); } static int seq_reset(sc_p scp) { int unit, i, s, chn; seqdev_info *sd; mididev_info *md; u_char c[3]; sd = scp->devinfo; unit = sd->unit; s = splmidi(); /* Stop reading and writing. */ sd->callback(sd, SEQ_CB_ABORT | SEQ_CB_RD | SEQ_CB_WR); /* Clear the queues. */ midibuf_init(&sd->midi_dbuf_in); midibuf_init(&sd->midi_dbuf_out); #if notyet /* Reset the synthesizers. */ for (i = 0 ; i < nmidi + nsynth ; i++) { md = &midi_info[i]; if (MIDICONFED(md) && scp->midi_open[i]) md->synth.reset(md); } #endif /* notyet */ #if notyet if (scp->seq_mode == SEQ_2) { for (chn = 0 ; chn < 16 ; chn++) for (i = 0 ; i < nmidi + nsynth ; i++) if (midi_open[i]) { md = &midi_info[i]; if (!MIDICONFED(md)) continue; if (md->synth.controller(md, chn, 123, 0) == EAGAIN /* All notes off. */ || md->synth.controller(md, chn, 121, 0) == EAGAIN /* Reset all controllers. */ || md->synth.bender(md, chn, 1 << 13) == EAGAIN) { /* Reset pitch bend. */ splx(s); return (EAGAIN); } } splx(s); } else { #endif /* notyet */ splx(s); for (i = 0 ; i < nmidi + nsynth ; i++) { md = &midi_info[i]; if (!MIDICONFED(md)) continue; /* Send active sensing. */ c[0] = 0xfe; /* Active Sensing. */ if (md->synth.writeraw(md, c, 1, 0) == EAGAIN) return (EAGAIN); /* * We need a sleep to reset a midi device using an active sensing. * SC-88 resets after 420ms... */ tsleep(md, PRIBIO, "seqrst", 500 * hz / 1000); for (chn = 0 ; chn < 16 ; chn++) { c[0] = 0xb0 | (chn & 0x0f); c[1] = (u_char)0x78; /* All sound off */ c[2] = (u_char)0; if (md->synth.writeraw(md, c, 3, 0) == EAGAIN) return (EAGAIN); c[1] = (u_char)0x7b; /* All note off */ if (md->synth.writeraw(md, c, 3, 0) == EAGAIN) return (EAGAIN); c[1] = (u_char)0x79; /* Reset all controller */ if (md->synth.writeraw(md, c, 3, 0) == EAGAIN) return (EAGAIN); } } for (i = 0 ; i < nmidi + nsynth ; i++){ md = &midi_info[i]; if (MIDICONFED(md)) seq_closemidi(scp, md, scp->fflags, MIDIDEV_MODE, curproc); } #if notyet } #endif /* notyet */ return (0); } static int seq_sync(sc_p scp) { int unit, s, i; seqdev_info *sd; sd = scp->devinfo; unit = sd->unit; s = splmidi(); if (sd->midi_dbuf_out.rl >= EV_SZ) sd->callback(sd, SEQ_CB_START | SEQ_CB_WR); while ((sd->flags & SEQ_F_WRITING) != 0 && sd->midi_dbuf_out.rl >= EV_SZ) { i = tsleep(&sd->midi_dbuf_out.tsleep_out, PRIBIO | PCATCH, "seqsnc", 0); if (i == EINTR) sd->callback(sd, SEQ_CB_STOP | SEQ_CB_WR); if (i == EINTR || i == ERESTART) { splx(s); return (i); } } splx(s); return (0); } /* * a small utility function which, given a device number, returns * a pointer to the associated seqdev_info struct, and sets the unit * number. */ static seqdev_info * get_seqdev_info(dev_t i_dev, int *unit) { int u; seqdev_info *d = NULL ; if (MIDIDEV(i_dev) != SND_DEV_SEQ && MIDIDEV(i_dev) != SND_DEV_SEQ2) return NULL; u = MIDIUNIT(i_dev); if (unit) *unit = u ; if (u >= NSEQ_MAX) { DEB(printf("get_seqdev_info: unit %d is not configured.\n", u)); return NULL; } d = &seq_info[u]; return d ; } /* XXX These functions are actually redundant. */ static int seqopen(dev_t i_dev, int flags, int mode, struct proc * p) { switch (MIDIDEV(i_dev)) { case MIDI_DEV_SEQ: return seq_open(i_dev, flags, mode, p); } return (ENXIO); } static int seqclose(dev_t i_dev, int flags, int mode, struct proc * p) { switch (MIDIDEV(i_dev)) { case MIDI_DEV_SEQ: return seq_close(i_dev, flags, mode, p); } return (ENXIO); } static int seqread(dev_t i_dev, struct uio * buf, int flag) { switch (MIDIDEV(i_dev)) { case MIDI_DEV_SEQ: return seq_read(i_dev, buf, flag); } return (ENXIO); } static int seqwrite(dev_t i_dev, struct uio * buf, int flag) { switch (MIDIDEV(i_dev)) { case MIDI_DEV_SEQ: return seq_write(i_dev, buf, flag); } return (ENXIO); } static int seqioctl(dev_t i_dev, u_long cmd, caddr_t arg, int mode, struct proc * p) { switch (MIDIDEV(i_dev)) { case MIDI_DEV_SEQ: return seq_ioctl(i_dev, cmd, arg, mode, p); } return (ENXIO); } static int seqpoll(dev_t i_dev, int events, struct proc * p) { switch (MIDIDEV(i_dev)) { case MIDI_DEV_SEQ: return seq_poll(i_dev, events, p); } return (ENXIO); } static int seq_modevent(module_t mod, int type, void *data) { int retval; retval = 0; switch (type) { case MOD_LOAD: seq_init(); break; case MOD_UNLOAD: printf("sequencer: unload not supported yet.\n"); retval = EOPNOTSUPP; break; default: break; } return retval; } DEV_MODULE(seq, seq_modevent, NULL);