/* $OpenBSD: audio.c,v 1.123 2014/09/14 14:17:24 jsg Exp $ */ /* $NetBSD: audio.c,v 1.119 1999/11/09 16:50:47 augustss Exp $ */ /* * Copyright (c) 1991-1993 Regents of the University of California. * All rights reserved. * * 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. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the Computer Systems * Engineering Group at Lawrence Berkeley Laboratory. * 4. Neither the name of the University nor of the Laboratory may be used * to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS 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 REGENTS 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. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "wskbd.h" /* NWSKBD (mixer tuning using keyboard) */ #ifdef AUDIO_DEBUG #define DPRINTF(x) if (audiodebug) printf x #define DPRINTFN(n,x) if (audiodebug>(n)) printf x int audiodebug = 0; #else #define DPRINTF(x) #define DPRINTFN(n,x) #endif #define ROUNDSIZE(x) x &= -16 /* round to nice boundary */ /* * Initial/default block duration is both configurable and patchable. */ #ifndef AUDIO_BLK_MS #define AUDIO_BLK_MS 50 /* 50 ms */ #endif #ifndef AU_RING_SIZE #define AU_RING_SIZE 65536 #endif #define AUMINBUF 512 #define AUMINBLK 32 #define AUMINNOBLK 2 struct audio_ringbuffer { int bufsize; /* allocated memory */ int blksize; /* I/O block size */ int maxblks; /* no of blocks in ring */ u_char *start; /* start of buffer area */ u_char *end; /* end of buffer area */ u_char *inp; /* input pointer (to buffer) */ u_char *outp; /* output pointer (from buffer) */ int used; /* no of used bytes */ int usedlow; /* start writer when used falls below this */ int usedhigh; /* stop writer when used goes above this */ u_long stamp; /* bytes transferred */ u_long stamp_last; /* old value of bytes transferred */ u_long drops; /* missed samples from over/underrun */ u_long pdrops; /* paused samples */ char pause; /* transfer is paused */ char mmapped; /* device is mmap()-ed */ u_char blkset; /* blksize has been set, for stickiness */ }; #define AUDIO_N_PORTS 4 struct au_mixer_ports { int index; int master; int nports; u_char isenum; u_int allports; u_int aumask[AUDIO_N_PORTS]; u_int misel [AUDIO_N_PORTS]; u_int miport[AUDIO_N_PORTS]; }; /* * Software state, per audio device. */ struct audio_softc { struct device dev; void *hw_hdl; /* Hardware driver handle */ struct audio_hw_if *hw_if; /* Hardware interface */ struct device *sc_dev; /* Hardware device struct */ u_char sc_open; /* single use device */ #define AUOPEN_READ 0x01 #define AUOPEN_WRITE 0x02 u_char sc_mode; /* bitmask for RECORD/PLAY */ struct selinfo sc_wsel; /* write selector */ struct selinfo sc_rsel; /* read selector */ struct proc *sc_async_audio; /* process who wants audio SIGIO */ struct mixer_asyncs { struct mixer_asyncs *next; struct proc *proc; } *sc_async_mixer; /* processes who want mixer SIGIO */ /* Sleep channels for reading and writing. */ int sc_rchan; int sc_wchan; /* Ring buffers, separate for record and play. */ struct audio_ringbuffer sc_rr; /* Record ring */ struct audio_ringbuffer sc_pr; /* Play ring */ u_char *sc_sil_start; /* start of silence in buffer */ int sc_sil_count; /* # of silence bytes */ u_char sc_rbus; /* input dma in progress */ u_char sc_pbus; /* output dma in progress */ u_char sc_rqui; /* input dma quiesced */ u_char sc_pqui; /* output dma quiesced */ struct audio_params sc_pparams; /* play encoding parameters */ struct audio_params sc_rparams; /* record encoding parameters */ int sc_eof; /* EOF, i.e. zero sized write, counter */ u_long sc_wstamp; u_long sc_playdrop; int sc_full_duplex; /* device in full duplex mode */ struct au_mixer_ports sc_inports, sc_outports; int sc_monitor_port; int sc_refcnt; int sc_dying; int sc_quiesce; #define AUDIO_QUIESCE_START 1 #define AUDIO_QUIESCE_SILENT 2 struct task sc_mixer_task; u_char sc_mute; #ifdef AUDIO_INTR_TIME u_long sc_pfirstintr; /* first time we saw a play interrupt */ int sc_pnintr; /* number of interrupts */ u_long sc_plastintr; /* last time we saw a play interrupt */ long sc_pblktime; /* nominal time between interrupts */ u_long sc_rfirstintr; /* first time we saw a rec interrupt */ int sc_rnintr; /* number of interrupts */ u_long sc_rlastintr; /* last time we saw a rec interrupt */ long sc_rblktime; /* nominal time between interrupts */ #endif }; int audio_blk_ms = AUDIO_BLK_MS; int audiosetinfo(struct audio_softc *, struct audio_info *); int audiogetinfo(struct audio_softc *, struct audio_info *); int audiogetbufinfo(struct audio_softc *, struct audio_bufinfo *, int); int audio_open(dev_t, struct audio_softc *, int, int, struct proc *); int audio_close(dev_t, int, int, struct proc *); int audio_read(dev_t, struct uio *, int); int audio_write(dev_t, struct uio *, int); int audio_ioctl(dev_t, u_long, caddr_t, int, struct proc *); int audio_poll(dev_t, int, struct proc *); paddr_t audio_mmap(dev_t, off_t, int); int mixer_open(dev_t, struct audio_softc *, int, int, struct proc *); int mixer_close(dev_t, int, int, struct proc *); int mixer_ioctl(dev_t, u_long, caddr_t, int, struct proc *); static void mixer_remove(struct audio_softc *, struct proc *p); static void mixer_signal(struct audio_softc *); void audio_init_record(struct audio_softc *); void audio_init_play(struct audio_softc *); int audiostartr(struct audio_softc *); int audiostartp(struct audio_softc *); void audio_rint(void *); void audio_pint(void *); int audio_check_params(struct audio_params *); void audio_set_blksize(struct audio_softc *, int, int); void audio_calc_blksize(struct audio_softc *, int); void audio_fill_silence(struct audio_params *, u_char *, u_char *, int); int audio_silence_copyout(struct audio_softc *, int, struct uio *); void audio_init_ringbuffer(struct audio_ringbuffer *); int audio_initbufs(struct audio_softc *); void audio_calcwater(struct audio_softc *); static __inline int audio_sleep_timo(int *, char *, int); static __inline int audio_sleep(int *, char *); static __inline void audio_wake(int *); void audio_selwakeup(struct audio_softc *sc, int play); int audio_drain(struct audio_softc *); void audio_clear(struct audio_softc *); static __inline void audio_pint_silence(struct audio_softc *, struct audio_ringbuffer *, u_char *, int); int audio_quiesce(struct audio_softc *); void audio_wakeup(struct audio_softc *); int audio_alloc_ring(struct audio_softc *, struct audio_ringbuffer *, int, int); void audio_free_ring(struct audio_softc *, struct audio_ringbuffer *); int audioprint(void *, const char *); int audioprobe(struct device *, void *, void *); void audioattach(struct device *, struct device *, void *); int audiodetach(struct device *, int); int audioactivate(struct device *, int); struct portname { char *name; int mask; }; static struct portname itable[] = { { AudioNmicrophone, AUDIO_MICROPHONE }, { AudioNline, AUDIO_LINE_IN }, { AudioNcd, AUDIO_CD }, { 0 } }; static struct portname otable[] = { { AudioNspeaker, AUDIO_SPEAKER }, { AudioNheadphone, AUDIO_HEADPHONE }, { AudioNline, AUDIO_LINE_OUT }, { 0 } }; struct gainpref { char *class, *device; }; static struct gainpref ipreftab[] = { { AudioCinputs, AudioNvolume }, { AudioCinputs, AudioNinput }, { AudioCinputs, AudioNrecord }, { AudioCrecord, AudioNvolume }, { AudioCrecord, AudioNrecord }, { NULL, NULL} }; static struct gainpref opreftab[] = { { AudioCoutputs, AudioNoutput }, { AudioCoutputs, AudioNdac }, { AudioCinputs, AudioNdac }, { AudioCoutputs, AudioNmaster }, { NULL, NULL} }; static struct gainpref mpreftab[] = { { AudioCoutputs, AudioNmonitor }, { AudioCmonitor, AudioNmonitor }, { NULL, NULL} }; void au_gain_match(struct audio_softc *, struct gainpref *, mixer_devinfo_t *, mixer_devinfo_t *, int *, int *); void au_check_ports(struct audio_softc *, struct au_mixer_ports *, mixer_devinfo_t *, mixer_devinfo_t *, char *, char *, struct portname *); int au_set_gain(struct audio_softc *, struct au_mixer_ports *, int, int); void au_get_gain(struct audio_softc *, struct au_mixer_ports *, u_int *, u_char *); int au_set_port(struct audio_softc *, struct au_mixer_ports *, u_int); int au_get_port(struct audio_softc *, struct au_mixer_ports *); int au_set_mute(struct audio_softc *, struct au_mixer_ports *, u_char); int au_get_mute(struct audio_softc *, struct au_mixer_ports *, u_char *); int au_get_lr_value(struct audio_softc *, mixer_ctrl_t *, int *, int *r); int au_set_lr_value(struct audio_softc *, mixer_ctrl_t *, int, int); int au_portof(struct audio_softc *, char *); /* The default audio mode: 8 kHz mono ulaw */ struct audio_params audio_default = { 8000, AUDIO_ENCODING_ULAW, 8, 1, 1, 1, 0, 1 }; struct cfattach audio_ca = { sizeof(struct audio_softc), audioprobe, audioattach, audiodetach, audioactivate }; struct cfdriver audio_cd = { NULL, "audio", DV_DULL }; void filt_audiowdetach(struct knote *); int filt_audiowrite(struct knote *, long); struct filterops audiowrite_filtops = { 1, NULL, filt_audiowdetach, filt_audiowrite}; void filt_audiordetach(struct knote *); int filt_audioread(struct knote *, long); struct filterops audioread_filtops = { 1, NULL, filt_audiordetach, filt_audioread}; #if NWSKBD > 0 /* Mixer manipulation using keyboard */ int wskbd_set_mixervolume(long, long); void wskbd_set_mixervolume_callback(void *, void *); #endif /* * This mutex protects data structures (including registers on the * sound-card) that are manipulated by both the interrupt handler and * syscall code-paths. * * Note that driver methods may sleep (e.g. in malloc); consequently the * audio layer calls them with the mutex unlocked. Driver methods are * responsible for locking the mutex when they manipulate data used by * the interrupt handler and interrupts may occur. * * Similarly, the driver is responsible for locking the mutex in its * interrupt handler and to call the audio layer call-backs (i.e. * audio_{p,r}int()) with the mutex locked. */ struct mutex audio_lock = MUTEX_INITIALIZER(IPL_AUDIO); int audioprobe(struct device *parent, void *match, void *aux) { struct audio_attach_args *sa = aux; DPRINTF(("audioprobe: type=%d sa=%p hw=%p\n", sa->type, sa, sa->hwif)); return (sa->type == AUDIODEV_TYPE_AUDIO) ? 1 : 0; } void audioattach(struct device *parent, struct device *self, void *aux) { struct audio_softc *sc = (void *)self; struct audio_attach_args *sa = aux; struct audio_hw_if *hwp = sa->hwif; void *hdlp = sa->hdl; int error; mixer_devinfo_t mi, cl; int ipref, opref, mpref; printf("\n"); #ifdef DIAGNOSTIC if (hwp == 0 || hwp->open == 0 || hwp->close == 0 || hwp->query_encoding == 0 || hwp->set_params == 0 || (hwp->start_output == 0 && hwp->trigger_output == 0) || (hwp->start_input == 0 && hwp->trigger_input == 0) || hwp->halt_output == 0 || hwp->halt_input == 0 || hwp->getdev == 0 || hwp->set_port == 0 || hwp->get_port == 0 || hwp->query_devinfo == 0 || hwp->get_props == 0) { printf("audio: missing method\n"); sc->hw_if = 0; return; } #endif sc->hw_if = hwp; sc->hw_hdl = hdlp; sc->sc_dev = parent; sc->sc_async_mixer = NULL; error = audio_alloc_ring(sc, &sc->sc_pr, AUMODE_PLAY, AU_RING_SIZE); if (error) { sc->hw_if = 0; printf("audio: could not allocate play buffer\n"); return; } error = audio_alloc_ring(sc, &sc->sc_rr, AUMODE_RECORD, AU_RING_SIZE); if (error) { audio_free_ring(sc, &sc->sc_pr); sc->hw_if = 0; printf("audio: could not allocate record buffer\n"); return; } /* * Set default softc params */ if (hwp->get_default_params) { hwp->get_default_params(hdlp, AUMODE_PLAY, &sc->sc_pparams); hwp->get_default_params(hdlp, AUMODE_RECORD, &sc->sc_rparams); } else { sc->sc_pparams = audio_default; sc->sc_rparams = audio_default; } /* Set up some default values */ sc->sc_rr.blkset = sc->sc_pr.blkset = 0; audio_calc_blksize(sc, AUMODE_RECORD); audio_calc_blksize(sc, AUMODE_PLAY); audio_init_ringbuffer(&sc->sc_rr); audio_init_ringbuffer(&sc->sc_pr); audio_calcwater(sc); ipref = opref = mpref = -1; sc->sc_inports.index = -1; sc->sc_inports.nports = 0; sc->sc_inports.isenum = 0; sc->sc_inports.allports = 0; sc->sc_inports.master = -1; sc->sc_outports.index = -1; sc->sc_outports.nports = 0; sc->sc_outports.isenum = 0; sc->sc_outports.allports = 0; sc->sc_outports.master = -1; sc->sc_monitor_port = -1; for(mi.index = 0; ; mi.index++) { if (hwp->query_devinfo(hdlp, &mi) != 0) break; if (mi.type == AUDIO_MIXER_CLASS) continue; cl.index = mi.mixer_class; if (hwp->query_devinfo(hdlp, &cl) != 0) continue; au_gain_match(sc, ipreftab, &cl, &mi, &sc->sc_inports.master, &ipref); au_gain_match(sc, opreftab, &cl, &mi, &sc->sc_outports.master, &opref); au_gain_match(sc, mpreftab, &cl, &mi, &sc->sc_monitor_port, &mpref); au_check_ports(sc, &sc->sc_inports, &cl, &mi, AudioCrecord, AudioNsource, itable); au_check_ports(sc, &sc->sc_outports, &cl, &mi, AudioCoutputs, AudioNselect, otable); } DPRINTF(("audio_attach: inputs ports=0x%x, output ports=0x%x\n", sc->sc_inports.allports, sc->sc_outports.allports)); #if NWSKBD > 0 task_set(&sc->sc_mixer_task, wskbd_set_mixervolume_callback, NULL, NULL); #endif /* NWSKBD > 0 */ } int audioactivate(struct device *self, int act) { struct audio_softc *sc = (struct audio_softc *)self; switch (act) { case DVACT_DEACTIVATE: sc->sc_dying = 1; break; case DVACT_QUIESCE: audio_quiesce(sc); break; case DVACT_WAKEUP: audio_wakeup(sc); break; } return (0); } int audiodetach(struct device *self, int flags) { struct audio_softc *sc = (struct audio_softc *)self; int maj, mn; DPRINTF(("audio_detach: sc=%p flags=%d\n", sc, flags)); sc->sc_dying = 1; wakeup(&sc->sc_quiesce); wakeup(&sc->sc_wchan); wakeup(&sc->sc_rchan); mtx_enter(&audio_lock); if (--sc->sc_refcnt >= 0) { if (msleep(&sc->sc_refcnt, &audio_lock, PZERO, "auddet", hz * 120)) printf("audiodetach: %s didn't detach\n", sc->dev.dv_xname); } mtx_leave(&audio_lock); /* free resources */ audio_free_ring(sc, &sc->sc_pr); audio_free_ring(sc, &sc->sc_rr); /* locate the major number */ for (maj = 0; maj < nchrdev; maj++) if (cdevsw[maj].d_open == audioopen) break; /* Nuke the vnodes for any open instances (calls close). */ mn = self->dv_unit; vdevgone(maj, mn | SOUND_DEVICE, mn | SOUND_DEVICE, VCHR); vdevgone(maj, mn | AUDIO_DEVICE, mn | AUDIO_DEVICE, VCHR); vdevgone(maj, mn | AUDIOCTL_DEVICE, mn | AUDIOCTL_DEVICE, VCHR); vdevgone(maj, mn | MIXER_DEVICE, mn | MIXER_DEVICE, VCHR); return (0); } int au_portof(struct audio_softc *sc, char *name) { mixer_devinfo_t mi; for(mi.index = 0; sc->hw_if->query_devinfo(sc->hw_hdl, &mi) == 0; mi.index++) if (strcmp(mi.label.name, name) == 0) return mi.index; return -1; } void au_check_ports(struct audio_softc *sc, struct au_mixer_ports *ports, mixer_devinfo_t *cl, mixer_devinfo_t *mi, char *cname, char *mname, struct portname *tbl) { int i, j; if (strcmp(cl->label.name, cname) != 0 || strcmp(mi->label.name, mname) != 0) return; if (mi->type == AUDIO_MIXER_ENUM) { ports->index = mi->index; for(i = 0; tbl[i].name; i++) { for(j = 0; j < mi->un.e.num_mem; j++) { if (strcmp(mi->un.e.member[j].label.name, tbl[i].name) == 0) { ports->aumask[ports->nports] = tbl[i].mask; ports->misel [ports->nports] = mi->un.e.member[j].ord; ports->miport[ports->nports++] = au_portof(sc, mi->un.e.member[j].label.name); ports->allports |= tbl[i].mask; } } } ports->isenum = 1; } else if (mi->type == AUDIO_MIXER_SET) { ports->index = mi->index; for(i = 0; tbl[i].name; i++) { for(j = 0; j < mi->un.s.num_mem; j++) { if (strcmp(mi->un.s.member[j].label.name, tbl[i].name) == 0) { ports->aumask[ports->nports] = tbl[i].mask; ports->misel [ports->nports] = mi->un.s.member[j].mask; ports->miport[ports->nports++] = au_portof(sc, mi->un.s.member[j].label.name); ports->allports |= tbl[i].mask; } } } } } /* * check if the given (class, device) is better * than the current setting (*index), if so, set the * current setting. */ void au_gain_match(struct audio_softc *sc, struct gainpref *tbl, mixer_devinfo_t *cls, mixer_devinfo_t *dev, int *index, int *pref) { int i; for (i = *pref + 1; tbl[i].class != NULL; i++) { if (strcmp(tbl[i].class, cls->label.name) == 0 && strcmp(tbl[i].device, dev->label.name) == 0) { if (*pref < i) { DPRINTF(("au_gain_match: found %s.%s\n", cls->label.name, dev->label.name)); *index = dev->index; *pref = i; } break; } } } /* * Called from hardware driver. This is where the MI audio driver gets * probed/attached to the hardware driver. */ struct device * audio_attach_mi(struct audio_hw_if *ahwp, void *hdlp, struct device *dev) { struct audio_attach_args arg; #ifdef DIAGNOSTIC if (ahwp == NULL) { printf ("audio_attach_mi: NULL\n"); return 0; } #endif arg.type = AUDIODEV_TYPE_AUDIO; arg.hwif = ahwp; arg.hdl = hdlp; return config_found(dev, &arg, audioprint); } int audioprint(void *aux, const char *pnp) { struct audio_attach_args *arg = aux; const char *type; if (pnp != NULL) { switch (arg->type) { case AUDIODEV_TYPE_AUDIO: type = "audio"; break; case AUDIODEV_TYPE_OPL: type = "opl"; break; case AUDIODEV_TYPE_MPU: type = "mpu"; break; default: panic("audioprint: unknown type %d", arg->type); } printf("%s at %s", type, pnp); } return (UNCONF); } #ifdef AUDIO_DEBUG void audio_printsc(struct audio_softc *); void audio_print_params(char *, struct audio_params *); void audio_printsc(struct audio_softc *sc) { printf("hwhandle %p hw_if %p ", sc->hw_hdl, sc->hw_if); printf("open 0x%x mode 0x%x\n", sc->sc_open, sc->sc_mode); printf("rchan 0x%x wchan 0x%x ", sc->sc_rchan, sc->sc_wchan); printf("rring used 0x%x pring used=%d\n", sc->sc_rr.used, sc->sc_pr.used); printf("rbus 0x%x pbus 0x%x ", sc->sc_rbus, sc->sc_pbus); printf("pblksz %d, rblksz %d", sc->sc_pr.blksize, sc->sc_rr.blksize); printf("hiwat %d lowat %d\n", sc->sc_pr.usedhigh, sc->sc_pr.usedlow); } void audio_print_params(char *s, struct audio_params *p) { printf("audio: %s sr=%ld, enc=%d, chan=%d, prec=%d bps=%d\n", s, p->sample_rate, p->encoding, p->channels, p->precision, p->bps); } #endif int audio_alloc_ring(struct audio_softc *sc, struct audio_ringbuffer *r, int direction, int bufsize) { struct audio_hw_if *hw = sc->hw_if; void *hdl = sc->hw_hdl; /* * Alloc DMA play and record buffers */ if (bufsize < AUMINBUF) bufsize = AUMINBUF; ROUNDSIZE(bufsize); if (hw->round_buffersize) bufsize = hw->round_buffersize(hdl, direction, bufsize); r->bufsize = bufsize; if (hw->allocm) r->start = hw->allocm(hdl, direction, r->bufsize, M_DEVBUF, M_WAITOK); else r->start = malloc(bufsize, M_DEVBUF, M_WAITOK); if (r->start == 0) return ENOMEM; return 0; } void audio_free_ring(struct audio_softc *sc, struct audio_ringbuffer *r) { if (sc->hw_if->freem) { sc->hw_if->freem(sc->hw_hdl, r->start, M_DEVBUF); } else { free(r->start, M_DEVBUF, 0); } } int audioopen(dev_t dev, int flags, int ifmt, struct proc *p) { int unit = AUDIOUNIT(dev); struct audio_softc *sc; int error; if (unit >= audio_cd.cd_ndevs || (sc = audio_cd.cd_devs[unit]) == NULL) return ENXIO; if (sc->sc_dying) return (EIO); if (!sc->hw_if) return (ENXIO); sc->sc_refcnt ++; switch (AUDIODEV(dev)) { case SOUND_DEVICE: case AUDIO_DEVICE: case AUDIOCTL_DEVICE: error = audio_open(dev, sc, flags, ifmt, p); break; case MIXER_DEVICE: error = mixer_open(dev, sc, flags, ifmt, p); break; default: error = ENXIO; break; } if (--sc->sc_refcnt < 0) wakeup(&sc->sc_refcnt); return (error); } int audioclose(dev_t dev, int flags, int ifmt, struct proc *p) { switch (AUDIODEV(dev)) { case SOUND_DEVICE: case AUDIO_DEVICE: return (audio_close(dev, flags, ifmt, p)); case MIXER_DEVICE: return (mixer_close(dev, flags, ifmt, p)); case AUDIOCTL_DEVICE: return 0; default: return (ENXIO); } } int audioread(dev_t dev, struct uio *uio, int ioflag) { int unit = AUDIOUNIT(dev); struct audio_softc *sc; int error; if (unit >= audio_cd.cd_ndevs || (sc = audio_cd.cd_devs[unit]) == NULL) return ENXIO; if (sc->sc_dying) return (EIO); sc->sc_refcnt ++; switch (AUDIODEV(dev)) { case SOUND_DEVICE: case AUDIO_DEVICE: error = audio_read(dev, uio, ioflag); break; case AUDIOCTL_DEVICE: case MIXER_DEVICE: error = ENODEV; break; default: error = ENXIO; break; } if (--sc->sc_refcnt < 0) wakeup(&sc->sc_refcnt); return (error); } int audiowrite(dev_t dev, struct uio *uio, int ioflag) { int unit = AUDIOUNIT(dev); struct audio_softc *sc; int error; if (unit >= audio_cd.cd_ndevs || (sc = audio_cd.cd_devs[unit]) == NULL) return ENXIO; if (sc->sc_dying) return (EIO); sc->sc_refcnt ++; switch (AUDIODEV(dev)) { case SOUND_DEVICE: case AUDIO_DEVICE: error = audio_write(dev, uio, ioflag); break; case AUDIOCTL_DEVICE: case MIXER_DEVICE: error = ENODEV; break; default: error = ENXIO; break; } if (--sc->sc_refcnt < 0) wakeup(&sc->sc_refcnt); return (error); } int audioioctl(dev_t dev, u_long cmd, caddr_t addr, int flag, struct proc *p) { int unit = AUDIOUNIT(dev); struct audio_softc *sc; int error; if (unit >= audio_cd.cd_ndevs || (sc = audio_cd.cd_devs[unit]) == NULL) return ENXIO; if (sc->sc_dying) return (EIO); sc->sc_refcnt ++; switch (AUDIODEV(dev)) { case SOUND_DEVICE: case AUDIO_DEVICE: case AUDIOCTL_DEVICE: error = audio_ioctl(dev, cmd, addr, flag, p); break; case MIXER_DEVICE: error = mixer_ioctl(dev, cmd, addr, flag, p); break; default: error = ENXIO; break; } if (--sc->sc_refcnt < 0) wakeup(&sc->sc_refcnt); return (error); } int audiopoll(dev_t dev, int events, struct proc *p) { int unit = AUDIOUNIT(dev); struct audio_softc *sc; int error; if (unit >= audio_cd.cd_ndevs || (sc = audio_cd.cd_devs[unit]) == NULL) return POLLERR; if (sc->sc_dying) return POLLERR; sc->sc_refcnt ++; switch (AUDIODEV(dev)) { case SOUND_DEVICE: case AUDIO_DEVICE: error = audio_poll(dev, events, p); break; case AUDIOCTL_DEVICE: case MIXER_DEVICE: error = 0; break; default: error = 0; break; } if (--sc->sc_refcnt < 0) wakeup(&sc->sc_refcnt); return (error); } paddr_t audiommap(dev_t dev, off_t off, int prot) { int unit = AUDIOUNIT(dev); struct audio_softc *sc; int ret; if (unit >= audio_cd.cd_ndevs || (sc = audio_cd.cd_devs[unit]) == NULL) return (-1); if (sc->sc_dying) return (-1); sc->sc_refcnt ++; switch (AUDIODEV(dev)) { case SOUND_DEVICE: case AUDIO_DEVICE: ret = audio_mmap(dev, off, prot); break; case AUDIOCTL_DEVICE: case MIXER_DEVICE: ret = -1; break; default: ret = -1; break; } if (--sc->sc_refcnt < 0) wakeup(&sc->sc_refcnt); return (ret); } /* * Audio driver */ void audio_init_ringbuffer(struct audio_ringbuffer *rp) { int nblks; int blksize = rp->blksize; if (blksize < AUMINBLK) blksize = AUMINBLK; nblks = rp->bufsize / blksize; if (nblks < AUMINNOBLK) { nblks = AUMINNOBLK; blksize = rp->bufsize / nblks; ROUNDSIZE(blksize); } DPRINTF(("audio_init_ringbuffer: blksize=%d\n", blksize)); rp->blksize = blksize; rp->maxblks = nblks; rp->used = 0; rp->end = rp->start + nblks * blksize; rp->inp = rp->outp = rp->start; rp->stamp = 0; rp->stamp_last = 0; rp->drops = 0; rp->pdrops = 0; rp->mmapped = 0; } int audio_initbufs(struct audio_softc *sc) { struct audio_hw_if *hw = sc->hw_if; int error; DPRINTF(("audio_initbufs: mode=0x%x\n", sc->sc_mode)); audio_init_ringbuffer(&sc->sc_rr); if (hw->init_input && (sc->sc_mode & AUMODE_RECORD)) { error = hw->init_input(sc->hw_hdl, sc->sc_rr.start, sc->sc_rr.end - sc->sc_rr.start); if (error) return error; } audio_init_ringbuffer(&sc->sc_pr); sc->sc_sil_count = 0; if (hw->init_output && (sc->sc_mode & AUMODE_PLAY)) { error = hw->init_output(sc->hw_hdl, sc->sc_pr.start, sc->sc_pr.end - sc->sc_pr.start); if (error) return error; } #ifdef AUDIO_INTR_TIME sc->sc_pnintr = 0; sc->sc_pblktime = (u_long)( (u_long)sc->sc_pr.blksize * 100000 / (u_long)(sc->sc_pparams.bps * sc->sc_pparams.channels * sc->sc_pparams.sample_rate)) * 10; DPRINTF(("audio: play blktime = %lu for %d\n", sc->sc_pblktime, sc->sc_pr.blksize)); sc->sc_rnintr = 0; sc->sc_rblktime = (u_long)( (u_long)sc->sc_rr.blksize * 100000 / (u_long)(sc->sc_rparams.bps * sc->sc_rparams.channels * sc->sc_rparams.sample_rate)) * 10; DPRINTF(("audio: record blktime = %lu for %d\n", sc->sc_rblktime, sc->sc_rr.blksize)); #endif return 0; } void audio_calcwater(struct audio_softc *sc) { int hiwat, lowat; hiwat = (sc->sc_pr.end - sc->sc_pr.start) / sc->sc_pr.blksize; lowat = hiwat * 3 / 4; if (lowat == hiwat) lowat = hiwat - 1; sc->sc_pr.usedhigh = hiwat * sc->sc_pr.blksize; sc->sc_pr.usedlow = lowat * sc->sc_pr.blksize; sc->sc_rr.usedhigh = sc->sc_rr.end - sc->sc_rr.start; sc->sc_rr.usedlow = 0; } static __inline int audio_sleep_timo(int *chan, char *label, int timo) { int st; if (!label) label = "audio"; DPRINTFN(3, ("audio_sleep_timo: chan=%p, label=%s, timo=%d\n", chan, label, timo)); *chan = 1; st = msleep(chan, &audio_lock, PWAIT | PCATCH, label, timo); *chan = 0; #ifdef AUDIO_DEBUG if (st != 0) printf("audio_sleep: woke up st=%d\n", st); #endif return (st); } static __inline int audio_sleep(int *chan, char *label) { return audio_sleep_timo(chan, label, 0); } /* call with audio_lock */ static __inline void audio_wake(int *chan) { DPRINTFN(3, ("audio_wakeup: chan=%p, *chan=%d\n", chan, *chan)); if (*chan) { wakeup(chan); *chan = 0; } } int audio_open(dev_t dev, struct audio_softc *sc, int flags, int ifmt, struct proc *p) { int error; int mode; struct audio_info ai; DPRINTF(("audio_open: dev=0x%x flags=0x%x sc=%p hdl=%p\n", dev, flags, sc, sc->hw_hdl)); if (ISDEVAUDIOCTL(dev)) return 0; if ((sc->sc_open & (AUOPEN_READ|AUOPEN_WRITE)) != 0) return (EBUSY); error = sc->hw_if->open(sc->hw_hdl, flags); if (error) return (error); sc->sc_async_audio = 0; sc->sc_rchan = 0; sc->sc_wchan = 0; sc->sc_sil_count = 0; sc->sc_rbus = 0; sc->sc_pbus = 0; sc->sc_eof = 0; sc->sc_playdrop = 0; sc->sc_full_duplex = 0; /* doesn't always work right on SB. (flags & (FWRITE|FREAD)) == (FWRITE|FREAD) && (sc->hw_if->get_props(sc->hw_hdl) & AUDIO_PROP_FULLDUPLEX); */ mode = 0; if (flags & FREAD) { sc->sc_open |= AUOPEN_READ; mode |= AUMODE_RECORD; } if (flags & FWRITE) { sc->sc_open |= AUOPEN_WRITE; mode |= AUMODE_PLAY | AUMODE_PLAY_ALL; } /* * Multiplex device: /dev/audio (default) and /dev/sound (last) * The /dev/audio is always (re)set to the default parameters. * For the other devices, you get what they were last set to. */ if (ISDEVAUDIO(dev)) { /* /dev/audio */ if (sc->hw_if->get_default_params) { sc->hw_if->get_default_params(sc->hw_hdl, AUMODE_PLAY, &sc->sc_pparams); sc->hw_if->get_default_params(sc->hw_hdl, AUMODE_RECORD, &sc->sc_rparams); } else { sc->sc_rparams = audio_default; sc->sc_pparams = audio_default; } } #ifdef DIAGNOSTIC /* * Sample rate and precision are supposed to be set to proper * default values by the hardware driver, so that it may give * us these values. */ if (sc->sc_rparams.precision == 0 || sc->sc_pparams.precision == 0) { printf("audio_open: 0 precision\n"); error = EINVAL; goto bad; } #endif AUDIO_INITINFO(&ai); ai.record.sample_rate = sc->sc_rparams.sample_rate; ai.record.encoding = sc->sc_rparams.encoding; ai.record.channels = sc->sc_rparams.channels; ai.record.precision = sc->sc_rparams.precision; ai.record.bps = sc->sc_rparams.bps; ai.record.msb = sc->sc_rparams.msb; ai.record.pause = 0; ai.play.sample_rate = sc->sc_pparams.sample_rate; ai.play.encoding = sc->sc_pparams.encoding; ai.play.channels = sc->sc_pparams.channels; ai.play.precision = sc->sc_pparams.precision; ai.play.bps = sc->sc_pparams.bps; ai.play.msb = sc->sc_pparams.msb; ai.play.pause = 0; ai.mode = mode; sc->sc_rr.blkset = sc->sc_pr.blkset = 0; /* Block sizes not set yet */ sc->sc_pr.blksize = sc->sc_rr.blksize = 0; /* force recalculation */ error = audiosetinfo(sc, &ai); if (error) goto bad; DPRINTF(("audio_open: done sc_mode = 0x%x\n", sc->sc_mode)); return 0; bad: sc->hw_if->close(sc->hw_hdl); sc->sc_open = 0; sc->sc_mode = 0; sc->sc_full_duplex = 0; return error; } /* * Must be called from task context. */ void audio_init_record(struct audio_softc *sc) { MUTEX_ASSERT_UNLOCKED(&audio_lock); if (sc->hw_if->speaker_ctl && (!sc->sc_full_duplex || (sc->sc_mode & AUMODE_PLAY) == 0)) sc->hw_if->speaker_ctl(sc->hw_hdl, SPKR_OFF); } /* * Must be called from task context. */ void audio_init_play(struct audio_softc *sc) { MUTEX_ASSERT_UNLOCKED(&audio_lock); sc->sc_wstamp = sc->sc_pr.stamp; if (sc->hw_if->speaker_ctl) sc->hw_if->speaker_ctl(sc->hw_hdl, SPKR_ON); } int audio_drain(struct audio_softc *sc) { int error, drops; struct audio_ringbuffer *cb = &sc->sc_pr; MUTEX_ASSERT_UNLOCKED(&audio_lock); DPRINTF(("audio_drain: enter busy=%d used=%d\n", sc->sc_pbus, sc->sc_pr.used)); if (sc->sc_pr.mmapped || sc->sc_pr.used <= 0) return 0; if (!sc->sc_pbus) { /* We've never started playing, probably because the * block was too short. Pad it and start now. */ int cc; u_char *inp = cb->inp; cc = cb->blksize - (inp - cb->start) % cb->blksize; if (sc->sc_pparams.sw_code) { int ncc = cc / sc->sc_pparams.factor; audio_fill_silence(&sc->sc_pparams, cb->start, inp, ncc); sc->sc_pparams.sw_code(sc->hw_hdl, inp, ncc); } else audio_fill_silence(&sc->sc_pparams, cb->start, inp, cc); inp += cc; if (inp >= cb->end) inp = cb->start; cb->used += cc; cb->inp = inp; error = audiostartp(sc); if (error) return error; } /* * Play until a silence block has been played, then we * know all has been drained. * XXX This should be done some other way to avoid * playing silence. */ mtx_enter(&audio_lock); drops = cb->drops; error = 0; while (cb->drops == drops && !error) { DPRINTF(("audio_drain: used=%d, drops=%ld\n", sc->sc_pr.used, cb->drops)); /* * When the process is exiting, it ignores all signals and * we can't interrupt this sleep, so we set a timeout just in case. */ error = audio_sleep_timo(&sc->sc_wchan, "aud_dr", 30 * hz); if (sc->sc_dying) error = EIO; } mtx_leave(&audio_lock); return error; } int audio_quiesce(struct audio_softc *sc) { sc->sc_quiesce = AUDIO_QUIESCE_START; mtx_enter(&audio_lock); while (sc->sc_pbus && !sc->sc_pqui) audio_sleep(&sc->sc_wchan, "audpqui"); while (sc->sc_rbus && !sc->sc_rqui) audio_sleep(&sc->sc_rchan, "audrqui"); mtx_leave(&audio_lock); sc->sc_quiesce = AUDIO_QUIESCE_SILENT; au_get_mute(sc, &sc->sc_outports, &sc->sc_mute); au_set_mute(sc, &sc->sc_outports, 1); if (sc->sc_pbus) sc->hw_if->halt_output(sc->hw_hdl); if (sc->sc_rbus) sc->hw_if->halt_input(sc->hw_hdl); return 0; } void audio_wakeup(struct audio_softc *sc) { int setmode = 0; sc->sc_pqui = sc->sc_rqui = 0; au_set_mute(sc, &sc->sc_outports, sc->sc_mute); if (sc->sc_pbus) setmode |= AUMODE_PLAY; if (sc->sc_rbus) setmode |= AUMODE_RECORD; if (setmode) { sc->hw_if->set_params(sc->hw_hdl, setmode, sc->sc_mode & (AUMODE_PLAY | AUMODE_RECORD), &sc->sc_pparams, &sc->sc_rparams); } if (sc->sc_pbus) { if (sc->hw_if->trigger_output) sc->hw_if->trigger_output(sc->hw_hdl, sc->sc_pr.start, sc->sc_pr.end, sc->sc_pr.blksize, audio_pint, (void *)sc, &sc->sc_pparams); else sc->hw_if->start_output(sc->hw_hdl, sc->sc_pr.outp, sc->sc_pr.blksize, audio_pint, (void *)sc); } if (sc->sc_rbus) { if (sc->hw_if->trigger_input) sc->hw_if->trigger_input(sc->hw_hdl, sc->sc_rr.start, sc->sc_rr.end, sc->sc_rr.blksize, audio_rint, (void *)sc, &sc->sc_rparams); else sc->hw_if->start_input(sc->hw_hdl, sc->sc_rr.inp, sc->sc_rr.blksize, audio_rint, (void *)sc); } sc->sc_quiesce = 0; wakeup(&sc->sc_quiesce); } /* * Close an audio chip. */ /* ARGSUSED */ int audio_close(dev_t dev, int flags, int ifmt, struct proc *p) { int unit = AUDIOUNIT(dev); struct audio_softc *sc = audio_cd.cd_devs[unit]; struct audio_hw_if *hw = sc->hw_if; DPRINTF(("audio_close: unit=%d flags=0x%x\n", unit, flags)); /* Stop recording. */ if ((flags & FREAD) && sc->sc_rbus) { /* * XXX Some drivers (e.g. SB) use the same routine * to halt input and output so don't halt input if * in full duplex mode. These drivers should be fixed. */ if (!sc->sc_full_duplex || sc->hw_if->halt_input != sc->hw_if->halt_output) { sc->hw_if->halt_input(sc->hw_hdl); } sc->sc_rbus = 0; } /* * If there is pending output, let it drain (unless * the output is paused). */ if ((flags & FWRITE) && sc->sc_pbus) { /* * Block until output drains, but allow ^C interrupt. * XXX: drain is never used, remove it! */ mtx_enter(&audio_lock); /* avoid excessive wakeups */ sc->sc_pr.usedlow = sc->sc_pr.blksize; mtx_leave(&audio_lock); if (!sc->sc_pr.pause) { if (!audio_drain(sc) && hw->drain) (void)hw->drain(sc->hw_hdl); } sc->hw_if->halt_output(sc->hw_hdl); sc->sc_pbus = 0; } hw->close(sc->hw_hdl); /* * If flags has neither read nor write then reset both * directions. Encountered when someone runs revoke(2). */ if ((flags & FREAD) || ((flags & (FREAD|FWRITE)) == 0)) { sc->sc_open &= ~AUOPEN_READ; sc->sc_mode &= ~AUMODE_RECORD; } if ((flags & FWRITE) || ((flags & (FREAD|FWRITE)) == 0)) { sc->sc_open &= ~AUOPEN_WRITE; sc->sc_mode &= ~(AUMODE_PLAY|AUMODE_PLAY_ALL); } sc->sc_async_audio = 0; sc->sc_full_duplex = 0; DPRINTF(("audio_close: done\n")); return (0); } int audio_read(dev_t dev, struct uio *uio, int ioflag) { int unit = AUDIOUNIT(dev); struct audio_softc *sc = audio_cd.cd_devs[unit]; struct audio_ringbuffer *cb = &sc->sc_rr; u_char *outp; int error, cc, n, resid; if (cb->mmapped) return EINVAL; DPRINTFN(1,("audio_read: cc=%ld mode=%d\n", uio->uio_resid, sc->sc_mode)); /* * Block if fully quiesced. Don't block when quiesce * has started, as the buffer position may still need * to advance. */ while (sc->sc_quiesce == AUDIO_QUIESCE_SILENT) tsleep(&sc->sc_quiesce, 0, "aud_qrd", 0); error = 0; /* * If hardware is half-duplex and currently playing, return * silence blocks based on the number of blocks we have output. */ if (!sc->sc_full_duplex && (sc->sc_mode & AUMODE_PLAY)) { while (uio->uio_resid > 0 && !error) { mtx_enter(&audio_lock); for(;;) { cc = sc->sc_pr.stamp - sc->sc_wstamp; if (cc > 0) break; DPRINTF(("audio_read: stamp=%lu, wstamp=%lu\n", sc->sc_pr.stamp, sc->sc_wstamp)); if (ioflag & IO_NDELAY) { mtx_leave(&audio_lock); return EWOULDBLOCK; } error = audio_sleep(&sc->sc_rchan, "aud_hr"); if (sc->sc_dying) error = EIO; if (error) { mtx_leave(&audio_lock); return error; } } mtx_leave(&audio_lock); if (uio->uio_resid < cc / sc->sc_rparams.factor) cc = uio->uio_resid * sc->sc_rparams.factor; DPRINTFN(1, ("audio_read: reading in write mode, cc=%d\n", cc)); error = audio_silence_copyout(sc, cc / sc->sc_rparams.factor, uio); sc->sc_wstamp += cc; } return (error); } while (uio->uio_resid > 0) { mtx_enter(&audio_lock); while (cb->used <= 0) { if (!sc->sc_rbus && !sc->sc_rr.pause) { mtx_leave(&audio_lock); error = audiostartr(sc); if (error) return error; mtx_enter(&audio_lock); continue; } if (ioflag & IO_NDELAY) { mtx_leave(&audio_lock); return (EWOULDBLOCK); } DPRINTFN(2, ("audio_read: sleep used=%d\n", cb->used)); error = audio_sleep(&sc->sc_rchan, "aud_rd"); if (sc->sc_dying) error = EIO; if (error) { mtx_leave(&audio_lock); return error; } } resid = uio->uio_resid * sc->sc_rparams.factor; outp = cb->outp; cc = cb->used - cb->usedlow; /* maximum to read */ n = cb->end - outp; if (cc > n) cc = n; /* don't read beyond end of buffer */ if (cc > resid) cc = resid; /* and no more than we want */ cb->used -= cc; cb->outp += cc; if (cb->outp >= cb->end) cb->outp = cb->start; mtx_leave(&audio_lock); DPRINTFN(1,("audio_read: outp=%p, cc=%d\n", outp, cc)); if (sc->sc_rparams.sw_code) sc->sc_rparams.sw_code(sc->hw_hdl, outp, cc); error = uiomove(outp, cc / sc->sc_rparams.factor, uio); if (error) return error; } return 0; } void audio_clear(struct audio_softc *sc) { MUTEX_ASSERT_UNLOCKED(&audio_lock); if (sc->sc_rbus) { audio_wake(&sc->sc_rchan); sc->hw_if->halt_input(sc->hw_hdl); sc->sc_rbus = 0; } if (sc->sc_pbus) { audio_wake(&sc->sc_wchan); sc->hw_if->halt_output(sc->hw_hdl); sc->sc_pbus = 0; } } void audio_set_blksize(struct audio_softc *sc, int mode, int fpb) { struct audio_hw_if *hw = sc->hw_if; struct audio_params *parm; struct audio_ringbuffer *rb; int bs, fs, maxbs; if (mode == AUMODE_PLAY) { parm = &sc->sc_pparams; rb = &sc->sc_pr; } else { parm = &sc->sc_rparams; rb = &sc->sc_rr; } fs = parm->channels * parm->bps; bs = fpb * fs; maxbs = rb->bufsize / 2; if (bs > maxbs) bs = (maxbs / fs) * fs; ROUNDSIZE(bs); if (hw->round_blocksize) bs = hw->round_blocksize(sc->hw_hdl, bs); rb->blksize = bs; DPRINTF(("audio_set_blksize: %s blksize=%d\n", mode == AUMODE_PLAY ? "play" : "record", bs)); } void audio_calc_blksize(struct audio_softc *sc, int mode) { struct audio_params *param; if (mode == AUMODE_PLAY) { if (sc->sc_pr.blkset) return; param = &sc->sc_pparams; } else { if (sc->sc_rr.blkset) return; param = &sc->sc_rparams; } audio_set_blksize(sc, mode, param->sample_rate * audio_blk_ms / 1000); } void audio_fill_silence(struct audio_params *params, u_char *start, u_char *p, int n) { size_t rounderr; int i, nsamples; u_char auzero[4] = {0, 0, 0, 0}; /* * p may point the middle of a sample; round it to the * beginning of the sample, so we overwrite partially written * ones. */ rounderr = (p - start) % params->bps; p -= rounderr; n += rounderr; nsamples = n / params->bps; switch (params->encoding) { case AUDIO_ENCODING_SLINEAR_LE: case AUDIO_ENCODING_SLINEAR_BE: break; case AUDIO_ENCODING_ULAW: auzero[0] = 0x7f; break; case AUDIO_ENCODING_ALAW: auzero[0] = 0x55; break; case AUDIO_ENCODING_ULINEAR_LE: if (params->msb == 1) auzero[params->bps - 1] = 0x80; else auzero[params->bps - 1] = 1 << ((params->precision + 7) % NBBY); break; case AUDIO_ENCODING_ULINEAR_BE: if (params->msb == 1) auzero[0] = 0x80; else auzero[0] = 1 << ((params->precision + 7) % NBBY); break; case AUDIO_ENCODING_MPEG_L1_STREAM: case AUDIO_ENCODING_MPEG_L1_PACKETS: case AUDIO_ENCODING_MPEG_L1_SYSTEM: case AUDIO_ENCODING_MPEG_L2_STREAM: case AUDIO_ENCODING_MPEG_L2_PACKETS: case AUDIO_ENCODING_MPEG_L2_SYSTEM: case AUDIO_ENCODING_ADPCM: /* is this right XXX */ break; default: DPRINTF(("audio: bad encoding %d\n", params->encoding)); break; } while (--nsamples >= 0) { for (i = 0; i < params->bps; i++) *p++ = auzero[i]; } } int audio_silence_copyout(struct audio_softc *sc, int n, struct uio *uio) { int error; int k; u_char zerobuf[128]; audio_fill_silence(&sc->sc_rparams, zerobuf, zerobuf, sizeof zerobuf); error = 0; while (n > 0 && uio->uio_resid > 0 && !error) { k = min(n, min(uio->uio_resid, sizeof zerobuf)); error = uiomove(zerobuf, k, uio); n -= k; } return (error); } int audio_write(dev_t dev, struct uio *uio, int ioflag) { int unit = AUDIOUNIT(dev); struct audio_softc *sc = audio_cd.cd_devs[unit]; struct audio_ringbuffer *cb = &sc->sc_pr; u_char *inp; int error, n, cc, resid, avail; DPRINTFN(2, ("audio_write: sc=%p(unit=%d) count=%zd used=%d(hi=%d)\n", sc, unit, uio->uio_resid, sc->sc_pr.used, sc->sc_pr.usedhigh)); if (cb->mmapped) return EINVAL; /* * Block if fully quiesced. Don't block when quiesce * has started, as the buffer position may still need * to advance. */ while (sc->sc_quiesce == AUDIO_QUIESCE_SILENT) tsleep(&sc->sc_quiesce, 0, "aud_qwr", 0); if (uio->uio_resid == 0) { sc->sc_eof++; return 0; } /* * If half-duplex and currently recording, throw away data. */ if (!sc->sc_full_duplex && (sc->sc_mode & AUMODE_RECORD)) { uio->uio_offset += uio->uio_resid; uio->uio_resid = 0; DPRINTF(("audio_write: half-dpx read busy\n")); return (0); } if (!(sc->sc_mode & AUMODE_PLAY_ALL) && sc->sc_playdrop > 0) { n = min(sc->sc_playdrop, uio->uio_resid * sc->sc_pparams.factor); DPRINTF(("audio_write: playdrop %d\n", n)); uio->uio_offset += n / sc->sc_pparams.factor; uio->uio_resid -= n / sc->sc_pparams.factor; sc->sc_playdrop -= n; if (uio->uio_resid == 0) return 0; } DPRINTFN(1, ("audio_write: sr=%ld, enc=%d, prec=%d, chan=%d, sw=%p, fact=%d\n", sc->sc_pparams.sample_rate, sc->sc_pparams.encoding, sc->sc_pparams.precision, sc->sc_pparams.channels, sc->sc_pparams.sw_code, sc->sc_pparams.factor)); while (uio->uio_resid > 0) { mtx_enter(&audio_lock); while (cb->used >= cb->usedhigh) { DPRINTFN(2, ("audio_write: sleep used=%d lowat=%d hiwat=%d\n", cb->used, cb->usedlow, cb->usedhigh)); if (ioflag & IO_NDELAY) { mtx_leave(&audio_lock); return (EWOULDBLOCK); } error = audio_sleep(&sc->sc_wchan, "aud_wr"); if (sc->sc_dying) error = EIO; if (error) { mtx_leave(&audio_lock); return error; } } resid = uio->uio_resid * sc->sc_pparams.factor; avail = cb->end - cb->inp; inp = cb->inp; cc = cb->usedhigh - cb->used; if (cc > resid) cc = resid; if (cc > avail) cc = avail; cb->inp += cc; if (cb->inp >= cb->end) cb->inp = cb->start; cb->used += cc; /* * This is a very suboptimal way of keeping track of * silence in the buffer, but it is simple. */ sc->sc_sil_count = 0; if (!sc->sc_pbus && !cb->pause && cb->used >= cb->blksize) { mtx_leave(&audio_lock); error = audiostartp(sc); if (error) return error; } else mtx_leave(&audio_lock); cc /= sc->sc_pparams.factor; DPRINTFN(1, ("audio_write: uiomove cc=%d inp=%p, left=%zd\n", cc, inp, uio->uio_resid)); error = uiomove(inp, cc, uio); if (error) return 0; if (sc->sc_pparams.sw_code) { sc->sc_pparams.sw_code(sc->hw_hdl, inp, cc); DPRINTFN(1, ("audio_write: expanded cc=%d\n", cc)); } } return 0; } int audio_ioctl(dev_t dev, u_long cmd, caddr_t addr, int flag, struct proc *p) { int unit = AUDIOUNIT(dev); struct audio_softc *sc = audio_cd.cd_devs[unit]; struct audio_hw_if *hw = sc->hw_if; struct audio_offset *ao; struct audio_info ai; int error = 0, offs, fd; int rbus, pbus; /* * Block if fully quiesced. Don't block when quiesce * has started, as the buffer position may still need * to advance. An ioctl may be used to determine how * much to read or write. */ while (sc->sc_quiesce == AUDIO_QUIESCE_SILENT) tsleep(&sc->sc_quiesce, 0, "aud_qio", 0); DPRINTF(("audio_ioctl(%ld,'%c',%ld)\n", IOCPARM_LEN(cmd), (int)IOCGROUP(cmd), cmd&0xff)); switch (cmd) { case FIONBIO: /* All handled in the upper FS layer. */ break; case FIOASYNC: if (*(int *)addr) { if (sc->sc_async_audio) return (EBUSY); sc->sc_async_audio = p; DPRINTF(("audio_ioctl: FIOASYNC %p\n", p)); } else sc->sc_async_audio = 0; break; case AUDIO_FLUSH: DPRINTF(("AUDIO_FLUSH\n")); rbus = sc->sc_rbus; pbus = sc->sc_pbus; audio_clear(sc); error = audio_initbufs(sc); if (error) { return error; } sc->sc_rr.pause = 0; sc->sc_pr.pause = 0; if ((sc->sc_mode & AUMODE_PLAY) && !sc->sc_pbus && pbus) error = audiostartp(sc); if (!error && (sc->sc_mode & AUMODE_RECORD) && !sc->sc_rbus && rbus) error = audiostartr(sc); break; /* * Number of read (write) samples dropped. We don't know where or * when they were dropped. * * The audio_ringbuffer->drops count is the number of buffer * sample size bytes. Convert it to userland sample size bytes, * then convert to samples. There is no easy way to get the * buffer sample size, but the userland sample size can be * calculated with userland channels and userland precision. * * original formula: * sc->sc_rr.drops / * sc->sc_rparams.factor / * (sc->sc_rparams.channels * sc->sc_rparams.bps) */ case AUDIO_RERROR: *(int *)addr = sc->sc_rr.drops / (sc->sc_rparams.factor * sc->sc_rparams.channels * sc->sc_rparams.bps); break; case AUDIO_PERROR: *(int *)addr = sc->sc_pr.drops / (sc->sc_pparams.factor * sc->sc_pparams.channels * sc->sc_pparams.bps); break; /* * Offsets into buffer. */ case AUDIO_GETIOFFS: mtx_enter(&audio_lock); /* figure out where next DMA will start */ ao = (struct audio_offset *)addr; ao->samples = sc->sc_rr.stamp / sc->sc_rparams.factor; ao->deltablks = (sc->sc_rr.stamp - sc->sc_rr.stamp_last) / sc->sc_rr.blksize; sc->sc_rr.stamp_last = sc->sc_rr.stamp; ao->offset = (sc->sc_rr.inp - sc->sc_rr.start) / sc->sc_rparams.factor; mtx_leave(&audio_lock); break; case AUDIO_GETOOFFS: mtx_enter(&audio_lock); /* figure out where next DMA will start */ ao = (struct audio_offset *)addr; offs = sc->sc_pr.outp - sc->sc_pr.start + sc->sc_pr.blksize; if (sc->sc_pr.start + offs >= sc->sc_pr.end) offs = 0; ao->samples = sc->sc_pr.stamp / sc->sc_pparams.factor; ao->deltablks = (sc->sc_pr.stamp - sc->sc_pr.stamp_last) / sc->sc_pr.blksize; sc->sc_pr.stamp_last = sc->sc_pr.stamp; ao->offset = offs / sc->sc_pparams.factor; mtx_leave(&audio_lock); break; /* * How many bytes will elapse until mike hears the first * sample of what we write next? */ case AUDIO_WSEEK: *(u_long *)addr = sc->sc_pr.used / sc->sc_pparams.factor; break; case AUDIO_SETINFO: DPRINTF(("AUDIO_SETINFO mode=0x%x\n", sc->sc_mode)); error = audiosetinfo(sc, (struct audio_info *)addr); break; case AUDIO_GETINFO: DPRINTF(("AUDIO_GETINFO\n")); error = audiogetinfo(sc, (struct audio_info *)addr); break; case AUDIO_DRAIN: DPRINTF(("AUDIO_DRAIN\n")); error = audio_drain(sc); if (!error && hw->drain) error = hw->drain(sc->hw_hdl); break; case AUDIO_GETDEV: DPRINTF(("AUDIO_GETDEV\n")); error = hw->getdev(sc->hw_hdl, (audio_device_t *)addr); break; case AUDIO_GETENC: DPRINTF(("AUDIO_GETENC\n")); /* Pass read/write info down to query_encoding */ ((struct audio_encoding *)addr)->flags = sc->sc_open; error = hw->query_encoding(sc->hw_hdl, (struct audio_encoding *)addr); break; case AUDIO_GETFD: DPRINTF(("AUDIO_GETFD\n")); *(int *)addr = sc->sc_full_duplex; break; case AUDIO_SETFD: DPRINTF(("AUDIO_SETFD\n")); fd = *(int *)addr; if (hw->get_props(sc->hw_hdl) & AUDIO_PROP_FULLDUPLEX) { if (hw->setfd) error = hw->setfd(sc->hw_hdl, fd); else error = 0; if (!error) { sc->sc_full_duplex = fd; if (fd) { AUDIO_INITINFO(&ai); ai.mode = sc->sc_mode | (AUMODE_PLAY | AUMODE_RECORD); error = audiosetinfo(sc, &ai); } } } else { if (fd) error = ENOTTY; else error = 0; } break; case AUDIO_GETPROPS: DPRINTF(("AUDIO_GETPROPS\n")); *(int *)addr = hw->get_props(sc->hw_hdl); break; case AUDIO_GETPRINFO: DPRINTF(("AUDIO_GETPRINFO\n")); error = audiogetbufinfo(sc, (struct audio_bufinfo *)addr, AUMODE_PLAY); break; case AUDIO_GETRRINFO: DPRINTF(("AUDIO_GETRRINFO\n")); error = audiogetbufinfo(sc, (struct audio_bufinfo *)addr, AUMODE_RECORD); break; default: DPRINTF(("audio_ioctl: unknown ioctl\n")); error = ENOTTY; break; } DPRINTF(("audio_ioctl(%ld,'%c',%ld) result %d\n", IOCPARM_LEN(cmd), (int)IOCGROUP(cmd), cmd&0xff, error)); return (error); } void audio_selwakeup(struct audio_softc *sc, int play) { struct selinfo *si; si = play? &sc->sc_wsel : &sc->sc_rsel; audio_wake(play? &sc->sc_wchan : &sc->sc_rchan); selwakeup(si); if (sc->sc_async_audio) psignal(sc->sc_async_audio, SIGIO); } #define AUDIO_FILTREAD(sc) ( \ (!sc->sc_full_duplex && (sc->sc_mode & AUMODE_PLAY)) ? \ sc->sc_pr.stamp > sc->sc_wstamp : sc->sc_rr.used > sc->sc_rr.usedlow) #define AUDIO_FILTWRITE(sc) ( \ (!sc->sc_full_duplex && (sc->sc_mode & AUMODE_RECORD)) || \ (!(sc->sc_mode & AUMODE_PLAY_ALL) && sc->sc_playdrop > 0) || \ (sc->sc_pr.used < (sc->sc_pr.usedlow + sc->sc_pr.blksize))) int audio_poll(dev_t dev, int events, struct proc *p) { int unit = AUDIOUNIT(dev); struct audio_softc *sc = audio_cd.cd_devs[unit]; int revents = 0; mtx_enter(&audio_lock); DPRINTF(("audio_poll: events=0x%x mode=%d\n", events, sc->sc_mode)); if (events & (POLLIN | POLLRDNORM)) { if (AUDIO_FILTREAD(sc)) revents |= events & (POLLIN | POLLRDNORM); } if (events & (POLLOUT | POLLWRNORM)) { if (AUDIO_FILTWRITE(sc)) revents |= events & (POLLOUT | POLLWRNORM); } if (revents == 0) { if (events & (POLLIN | POLLRDNORM)) selrecord(p, &sc->sc_rsel); if (events & (POLLOUT | POLLWRNORM)) selrecord(p, &sc->sc_wsel); } mtx_leave(&audio_lock); return (revents); } paddr_t audio_mmap(dev_t dev, off_t off, int prot) { int unit = AUDIOUNIT(dev); struct audio_softc *sc = audio_cd.cd_devs[unit]; struct audio_hw_if *hw = sc->hw_if; struct audio_ringbuffer *cb; DPRINTF(("audio_mmap: off=%lld, prot=%d\n", off, prot)); if (!(hw->get_props(sc->hw_hdl) & AUDIO_PROP_MMAP) || !hw->mappage) return -1; #if 0 /* XXX * The idea here was to use the protection to determine if * we are mapping the read or write buffer, but it fails. * The VM system is broken in (at least) two ways. * 1) If you map memory VM_PROT_WRITE you SIGSEGV * when writing to it, so VM_PROT_READ|VM_PROT_WRITE * has to be used for mmapping the play buffer. * 2) Even if calling mmap() with VM_PROT_READ|VM_PROT_WRITE * audio_mmap will get called at some point with VM_PROT_READ * only. * So, alas, we always map the play buffer for now. */ if (prot == (VM_PROT_READ|VM_PROT_WRITE) || prot == VM_PROT_WRITE) cb = &sc->sc_pr; else if (prot == VM_PROT_READ) cb = &sc->sc_rr; else return -1; #else cb = &sc->sc_pr; #endif if ((u_int)off >= cb->bufsize) return -1; if (!cb->mmapped) { cb->mmapped = 1; if (cb == &sc->sc_pr) { audio_fill_silence(&sc->sc_pparams, cb->start, cb->start, cb->bufsize); if (!sc->sc_pbus && !sc->sc_pr.pause) (void)audiostartp(sc); } else { if (!sc->sc_rbus && !sc->sc_rr.pause) (void)audiostartr(sc); } } return hw->mappage(sc->hw_hdl, cb->start, off, prot); } int audiostartr(struct audio_softc *sc) { int error; MUTEX_ASSERT_UNLOCKED(&audio_lock); DPRINTF(("audiostartr: start=%p used=%d(hi=%d) mmapped=%d\n", sc->sc_rr.start, sc->sc_rr.used, sc->sc_rr.usedhigh, sc->sc_rr.mmapped)); if (sc->hw_if->trigger_input) error = sc->hw_if->trigger_input(sc->hw_hdl, sc->sc_rr.start, sc->sc_rr.end, sc->sc_rr.blksize, audio_rint, (void *)sc, &sc->sc_rparams); else error = sc->hw_if->start_input(sc->hw_hdl, sc->sc_rr.start, sc->sc_rr.blksize, audio_rint, (void *)sc); if (error) { DPRINTF(("audiostartr failed: %d\n", error)); return error; } sc->sc_rbus = 1; return 0; } int audiostartp(struct audio_softc *sc) { int error; MUTEX_ASSERT_UNLOCKED(&audio_lock); DPRINTF(("audiostartp: start=%p used=%d(hi=%d) mmapped=%d\n", sc->sc_pr.start, sc->sc_pr.used, sc->sc_pr.usedhigh, sc->sc_pr.mmapped)); if (!sc->sc_pr.mmapped && sc->sc_pr.used < sc->sc_pr.blksize) return 0; if (sc->hw_if->trigger_output) error = sc->hw_if->trigger_output(sc->hw_hdl, sc->sc_pr.start, sc->sc_pr.end, sc->sc_pr.blksize, audio_pint, (void *)sc, &sc->sc_pparams); else error = sc->hw_if->start_output(sc->hw_hdl, sc->sc_pr.outp, sc->sc_pr.blksize, audio_pint, (void *)sc); if (error) { DPRINTF(("audiostartp failed: %d\n", error)); return error; } sc->sc_pbus = 1; return 0; } /* * When the play interrupt routine finds that the write isn't keeping * the buffer filled it will insert silence in the buffer to make up * for this. The part of the buffer that is filled with silence * is kept track of in a very approximate way: it starts at sc_sil_start * and extends sc_sil_count bytes. If there is already silence in * the requested area nothing is done; so when the whole buffer is * silent nothing happens. When the writer starts again sc_sil_count * is set to 0. */ /* XXX * Putting silence into the output buffer should not really be done * with audio_lock, but there is no softaudio level to do it at yet. */ static __inline void audio_pint_silence(struct audio_softc *sc, struct audio_ringbuffer *cb, u_char *inp, int cc) { u_char *s, *e, *p, *q; if (sc->sc_sil_count > 0) { s = sc->sc_sil_start; /* start of silence */ e = s + sc->sc_sil_count; /* end of silence, may be beyond end */ p = inp; /* adjusted pointer to area to fill */ if (p < s) p += cb->end - cb->start; q = p+cc; /* Check if there is already silence. */ if (!(s <= p && p < e && s <= q && q <= e)) { if (s <= p) sc->sc_sil_count = max(sc->sc_sil_count, q-s); DPRINTFN(5, ("audio_pint_silence: fill cc=%d inp=%p, count=%d size=%d\n", cc, inp, sc->sc_sil_count, (int)(cb->end - cb->start))); if (sc->sc_pparams.sw_code) { int ncc = cc / sc->sc_pparams.factor; audio_fill_silence(&sc->sc_pparams, cb->start, inp, ncc); sc->sc_pparams.sw_code(sc->hw_hdl, inp, ncc); } else audio_fill_silence(&sc->sc_pparams, cb->start, inp, cc); } else { DPRINTFN(5, ("audio_pint_silence: already silent cc=%d inp=%p\n", cc, inp)); } } else { sc->sc_sil_start = inp; sc->sc_sil_count = cc; DPRINTFN(5, ("audio_pint_silence: start fill %p %d\n", inp, cc)); if (sc->sc_pparams.sw_code) { int ncc = cc / sc->sc_pparams.factor; audio_fill_silence(&sc->sc_pparams, cb->start, inp, ncc); sc->sc_pparams.sw_code(sc->hw_hdl, inp, ncc); } else audio_fill_silence(&sc->sc_pparams, cb->start, inp, cc); } } /* * Called from HW driver module on completion of dma output. * Start output of new block, wrap in ring buffer if needed. * If no more buffers to play, output zero instead. * Do a wakeup if necessary. */ void audio_pint(void *v) { struct audio_softc *sc = v; struct audio_hw_if *hw = sc->hw_if; struct audio_ringbuffer *cb = &sc->sc_pr; u_char *inp; int cc; int blksize; int error; MUTEX_ASSERT_LOCKED(&audio_lock); if (!sc->sc_open) return; /* ignore interrupt if not open */ if (sc->sc_pqui) return; blksize = cb->blksize; add_audio_randomness((long)cb); cb->outp += blksize; if (cb->outp >= cb->end) cb->outp = cb->start; cb->stamp += blksize; if (cb->mmapped) { DPRINTFN(5, ("audio_pint: mmapped outp=%p cc=%d inp=%p\n", cb->outp, blksize, cb->inp)); if (!hw->trigger_output) (void)hw->start_output(sc->hw_hdl, cb->outp, blksize, audio_pint, (void *)sc); return; } #ifdef AUDIO_INTR_TIME { struct timeval tv; u_long t; microtime(&tv); t = tv.tv_usec + 1000000 * tv.tv_sec; if (sc->sc_pnintr) { long lastdelta, totdelta; lastdelta = t - sc->sc_plastintr - sc->sc_pblktime; if (lastdelta > sc->sc_pblktime / 3) { printf("audio: play interrupt(%d) off relative by %ld us (%lu)\n", sc->sc_pnintr, lastdelta, sc->sc_pblktime); } totdelta = t - sc->sc_pfirstintr - sc->sc_pblktime * sc->sc_pnintr; if (totdelta > sc->sc_pblktime) { printf("audio: play interrupt(%d) off absolute by %ld us (%lu) (LOST)\n", sc->sc_pnintr, totdelta, sc->sc_pblktime); sc->sc_pnintr++; /* avoid repeated messages */ } } else sc->sc_pfirstintr = t; sc->sc_plastintr = t; sc->sc_pnintr++; } #endif cb->used -= blksize; if (cb->used < blksize) { /* we don't have a full block to use */ inp = cb->inp; cc = blksize - (inp - cb->start) % blksize; if (cb->pause) cb->pdrops += cc; else { cb->drops += cc; sc->sc_playdrop += cc; } audio_pint_silence(sc, cb, inp, cc); inp += cc; if (inp >= cb->end) inp = cb->start; cb->inp = inp; cb->used += cc; /* Clear next block so we keep ahead of the DMA. */ if (cb->used + cc < cb->usedhigh) audio_pint_silence(sc, cb, inp, blksize); } DPRINTFN(5, ("audio_pint: outp=%p cc=%d\n", cb->outp, blksize)); if (!hw->trigger_output) { error = hw->start_output(sc->hw_hdl, cb->outp, blksize, audio_pint, (void *)sc); if (error) { /* XXX does this really help? */ DPRINTF(("audio_pint restart failed: %d\n", error)); } } DPRINTFN(2, ("audio_pint: mode=%d pause=%d used=%d lowat=%d\n", sc->sc_mode, cb->pause, cb->used, cb->usedlow)); if ((sc->sc_mode & AUMODE_PLAY) && !cb->pause && cb->used <= cb->usedlow) audio_selwakeup(sc, 1); /* Possible to return one or more "phantom blocks" now. */ if (!sc->sc_full_duplex && sc->sc_rchan) audio_selwakeup(sc, 0); /* * If quiesce requested, halt output when the ring buffer position * is at the beginning, because when the hardware is resumed, it's * buffer position is reset to the beginning. This will put * hardware and software positions in sync across a suspend cycle. */ if (sc->sc_quiesce == AUDIO_QUIESCE_START && cb->outp == cb->start) { sc->sc_pqui = 1; audio_wake(&sc->sc_wchan); } } /* * Called from HW driver module on completion of dma input. * Mark it as input in the ring buffer (fiddle pointers). * Do a wakeup if necessary. */ void audio_rint(void *v) { struct audio_softc *sc = v; struct audio_hw_if *hw = sc->hw_if; struct audio_ringbuffer *cb = &sc->sc_rr; int blksize; int error; MUTEX_ASSERT_LOCKED(&audio_lock); if (!sc->sc_open) return; /* ignore interrupt if not open */ if (sc->sc_rqui) return; add_audio_randomness((long)cb); blksize = cb->blksize; cb->inp += blksize; if (cb->inp >= cb->end) cb->inp = cb->start; cb->stamp += blksize; if (cb->mmapped) { DPRINTFN(2, ("audio_rint: mmapped inp=%p cc=%d\n", cb->inp, blksize)); if (!hw->trigger_input) (void)hw->start_input(sc->hw_hdl, cb->inp, blksize, audio_rint, (void *)sc); return; } #ifdef AUDIO_INTR_TIME { struct timeval tv; u_long t; microtime(&tv); t = tv.tv_usec + 1000000 * tv.tv_sec; if (sc->sc_rnintr) { long lastdelta, totdelta; lastdelta = t - sc->sc_rlastintr - sc->sc_rblktime; if (lastdelta > sc->sc_rblktime / 5) { printf("audio: record interrupt(%d) off relative by %ld us (%lu)\n", sc->sc_rnintr, lastdelta, sc->sc_rblktime); } totdelta = t - sc->sc_rfirstintr - sc->sc_rblktime * sc->sc_rnintr; if (totdelta > sc->sc_rblktime / 2) { sc->sc_rnintr++; printf("audio: record interrupt(%d) off absolute by %ld us (%lu)\n", sc->sc_rnintr, totdelta, sc->sc_rblktime); sc->sc_rnintr++; /* avoid repeated messages */ } } else sc->sc_rfirstintr = t; sc->sc_rlastintr = t; sc->sc_rnintr++; } #endif cb->used += blksize; if (cb->pause) { DPRINTFN(1, ("audio_rint: pdrops %lu\n", cb->pdrops)); cb->pdrops += blksize; cb->outp += blksize; if (cb->outp >= cb->end) cb->outp = cb->start; cb->used -= blksize; } else if (cb->used >= cb->usedhigh) { DPRINTFN(1, ("audio_rint: drops %lu\n", cb->drops)); cb->drops += blksize; cb->outp += blksize; if (cb->outp >= cb->end) cb->outp = cb->start; cb->used -= blksize; } DPRINTFN(2, ("audio_rint: inp=%p cc=%d used=%d\n", cb->inp, blksize, cb->used)); if (!hw->trigger_input) { error = hw->start_input(sc->hw_hdl, cb->inp, blksize, audio_rint, (void *)sc); if (error) { /* XXX does this really help? */ DPRINTF(("audio_rint: restart failed: %d\n", error)); } } audio_selwakeup(sc, 0); /* * If quiesce requested, halt input when the ring buffer position * is at the beginning, because when the hardware is resumed, it's * buffer position is reset to the beginning. This will put * hardware and software positions in sync across a suspend cycle. */ if (sc->sc_quiesce == AUDIO_QUIESCE_START && cb->inp == cb->start) { sc->sc_rqui = 1; audio_wake(&sc->sc_rchan); } } int audio_check_params(struct audio_params *p) { if (p->channels < 1 || p->channels > 12) return (EINVAL); if (p->precision < 8 || p->precision > 32) return (EINVAL); if (p->encoding == AUDIO_ENCODING_PCM16) { if (p->precision == 8) p->encoding = AUDIO_ENCODING_ULINEAR; else p->encoding = AUDIO_ENCODING_SLINEAR; } else if (p->encoding == AUDIO_ENCODING_PCM8) { if (p->precision == 8) p->encoding = AUDIO_ENCODING_ULINEAR; else return EINVAL; } if (p->encoding == AUDIO_ENCODING_SLINEAR) #if BYTE_ORDER == LITTLE_ENDIAN p->encoding = AUDIO_ENCODING_SLINEAR_LE; #else p->encoding = AUDIO_ENCODING_SLINEAR_BE; #endif if (p->encoding == AUDIO_ENCODING_ULINEAR) #if BYTE_ORDER == LITTLE_ENDIAN p->encoding = AUDIO_ENCODING_ULINEAR_LE; #else p->encoding = AUDIO_ENCODING_ULINEAR_BE; #endif switch (p->encoding) { case AUDIO_ENCODING_ULAW: case AUDIO_ENCODING_ALAW: case AUDIO_ENCODING_ADPCM: if (p->precision != 8) p->precision = 8; break; case AUDIO_ENCODING_SLINEAR_LE: case AUDIO_ENCODING_SLINEAR_BE: case AUDIO_ENCODING_ULINEAR_LE: case AUDIO_ENCODING_ULINEAR_BE: case AUDIO_ENCODING_MPEG_L1_STREAM: case AUDIO_ENCODING_MPEG_L1_PACKETS: case AUDIO_ENCODING_MPEG_L1_SYSTEM: case AUDIO_ENCODING_MPEG_L2_STREAM: case AUDIO_ENCODING_MPEG_L2_PACKETS: case AUDIO_ENCODING_MPEG_L2_SYSTEM: break; default: return (EINVAL); } return (0); } int au_set_lr_value(struct audio_softc *sc, mixer_ctrl_t *ct, int l, int r) { ct->type = AUDIO_MIXER_VALUE; ct->un.value.num_channels = 2; ct->un.value.level[AUDIO_MIXER_LEVEL_LEFT] = l; ct->un.value.level[AUDIO_MIXER_LEVEL_RIGHT] = r; if (sc->hw_if->set_port(sc->hw_hdl, ct) == 0) return 0; ct->un.value.num_channels = 1; ct->un.value.level[AUDIO_MIXER_LEVEL_MONO] = (l+r)/2; return sc->hw_if->set_port(sc->hw_hdl, ct); } int au_get_mute(struct audio_softc *sc, struct au_mixer_ports *ports, u_char *mute) { mixer_devinfo_t mi; mixer_ctrl_t ct; int error; *mute = 0; /* if no master, silently ignore request */ if (ports->master == -1) return 0; mi.index = ports->master; error = sc->hw_if->query_devinfo(sc->hw_hdl, &mi); if (error != 0) return error; /* master mute control should be the next device, if it exists */ if (mi.next < 0) return 0; ct.dev = mi.next; ct.type = AUDIO_MIXER_ENUM; error = sc->hw_if->get_port(sc->hw_hdl, &ct); if (error != 0) return error; *mute = ct.un.ord; return error; } int au_set_mute(struct audio_softc *sc, struct au_mixer_ports *ports, u_char mute) { mixer_devinfo_t mi; mixer_ctrl_t ct; int error; /* if no master, silently ignore request */ if (ports->master == -1) return 0; mi.index = ports->master; error = sc->hw_if->query_devinfo(sc->hw_hdl, &mi); if (error != 0) return error; /* master mute control should be the next device, if it exists */ if (mi.next < 0) return 0; ct.dev = mi.next; ct.type = AUDIO_MIXER_ENUM; error = sc->hw_if->get_port(sc->hw_hdl, &ct); if (error != 0) return error; DPRINTF(("au_set_mute: mute (old): %d, mute (new): %d\n", ct.un.ord, mute)); ct.un.ord = (mute != 0 ? 1 : 0); error = sc->hw_if->set_port(sc->hw_hdl, &ct); if (!error) mixer_signal(sc); return error; } int au_set_gain(struct audio_softc *sc, struct au_mixer_ports *ports, int gain, int balance) { mixer_ctrl_t ct; int i, error; int l, r; u_int mask; int nset; /* XXX silently adjust to within limits or return EINVAL ? */ if (gain > AUDIO_MAX_GAIN) gain = AUDIO_MAX_GAIN; else if (gain < AUDIO_MIN_GAIN) gain = AUDIO_MIN_GAIN; if (balance == AUDIO_MID_BALANCE) { l = r = gain; } else if (balance < AUDIO_MID_BALANCE) { r = gain; l = (balance * gain) / AUDIO_MID_BALANCE; } else { l = gain; r = ((AUDIO_RIGHT_BALANCE - balance) * gain) / AUDIO_MID_BALANCE; } DPRINTF(("au_set_gain: gain=%d balance=%d, l=%d r=%d\n", gain, balance, l, r)); if (ports->index == -1) { usemaster: if (ports->master == -1) return 0; /* just ignore it silently */ ct.dev = ports->master; error = au_set_lr_value(sc, &ct, l, r); } else { ct.dev = ports->index; if (ports->isenum) { ct.type = AUDIO_MIXER_ENUM; error = sc->hw_if->get_port(sc->hw_hdl, &ct); if (error) return error; for(i = 0; i < ports->nports; i++) { if (ports->misel[i] == ct.un.ord) { ct.dev = ports->miport[i]; if (ct.dev == -1 || au_set_lr_value(sc, &ct, l, r)) goto usemaster; else break; } } } else { ct.type = AUDIO_MIXER_SET; error = sc->hw_if->get_port(sc->hw_hdl, &ct); if (error) return error; mask = ct.un.mask; nset = 0; for(i = 0; i < ports->nports; i++) { if (ports->misel[i] & mask) { ct.dev = ports->miport[i]; if (ct.dev != -1 && au_set_lr_value(sc, &ct, l, r) == 0) nset++; } } if (nset == 0) goto usemaster; } } if (!error) mixer_signal(sc); return error; } int au_get_lr_value(struct audio_softc *sc, mixer_ctrl_t *ct, int *l, int *r) { int error; ct->un.value.num_channels = 2; if (sc->hw_if->get_port(sc->hw_hdl, ct) == 0) { *l = ct->un.value.level[AUDIO_MIXER_LEVEL_LEFT]; *r = ct->un.value.level[AUDIO_MIXER_LEVEL_RIGHT]; } else { ct->un.value.num_channels = 1; error = sc->hw_if->get_port(sc->hw_hdl, ct); if (error) return error; *r = *l = ct->un.value.level[AUDIO_MIXER_LEVEL_MONO]; } return 0; } void au_get_gain(struct audio_softc *sc, struct au_mixer_ports *ports, u_int *pgain, u_char *pbalance) { mixer_ctrl_t ct; int i, l, r, n; int lgain = AUDIO_MAX_GAIN/2, rgain = AUDIO_MAX_GAIN/2; if (ports->index == -1) { usemaster: if (ports->master == -1) goto bad; ct.dev = ports->master; ct.type = AUDIO_MIXER_VALUE; if (au_get_lr_value(sc, &ct, &lgain, &rgain)) goto bad; } else { ct.dev = ports->index; if (ports->isenum) { ct.type = AUDIO_MIXER_ENUM; if (sc->hw_if->get_port(sc->hw_hdl, &ct)) goto bad; ct.type = AUDIO_MIXER_VALUE; for(i = 0; i < ports->nports; i++) { if (ports->misel[i] == ct.un.ord) { ct.dev = ports->miport[i]; if (ct.dev == -1 || au_get_lr_value(sc, &ct, &lgain, &rgain)) goto usemaster; else break; } } } else { ct.type = AUDIO_MIXER_SET; if (sc->hw_if->get_port(sc->hw_hdl, &ct)) goto bad; ct.type = AUDIO_MIXER_VALUE; lgain = rgain = n = 0; for(i = 0; i < ports->nports; i++) { if (ports->misel[i] & ct.un.mask) { ct.dev = ports->miport[i]; if (ct.dev == -1 || au_get_lr_value(sc, &ct, &l, &r)) goto usemaster; else { lgain += l; rgain += r; n++; } } } if (n != 0) { lgain /= n; rgain /= n; } } } bad: if (lgain == rgain) { /* handles lgain==rgain==0 */ *pgain = lgain; *pbalance = AUDIO_MID_BALANCE; } else if (lgain < rgain) { *pgain = rgain; *pbalance = (AUDIO_MID_BALANCE * lgain) / rgain; } else /* lgain > rgain */ { *pgain = lgain; *pbalance = AUDIO_RIGHT_BALANCE - (AUDIO_MID_BALANCE * rgain) / lgain; } } int au_set_port(struct audio_softc *sc, struct au_mixer_ports *ports, u_int port) { mixer_ctrl_t ct; int i, error; if (port == 0) /* allow this special case */ return 0; if (ports->index == -1) return EINVAL; ct.dev = ports->index; if (ports->isenum) { if (port & (port-1)) return EINVAL; /* Only one port allowed */ ct.type = AUDIO_MIXER_ENUM; error = EINVAL; for(i = 0; i < ports->nports; i++) if (ports->aumask[i] == port) { ct.un.ord = ports->misel[i]; error = sc->hw_if->set_port(sc->hw_hdl, &ct); break; } } else { ct.type = AUDIO_MIXER_SET; ct.un.mask = 0; for(i = 0; i < ports->nports; i++) if (ports->aumask[i] & port) ct.un.mask |= ports->misel[i]; if (port != 0 && ct.un.mask == 0) error = EINVAL; else error = sc->hw_if->set_port(sc->hw_hdl, &ct); } if (!error) mixer_signal(sc); return error; } int au_get_port(struct audio_softc *sc, struct au_mixer_ports *ports) { mixer_ctrl_t ct; int i, aumask; if (ports->index == -1) return 0; ct.dev = ports->index; ct.type = ports->isenum ? AUDIO_MIXER_ENUM : AUDIO_MIXER_SET; if (sc->hw_if->get_port(sc->hw_hdl, &ct)) return 0; aumask = 0; if (ports->isenum) { for(i = 0; i < ports->nports; i++) if (ct.un.ord == ports->misel[i]) aumask = ports->aumask[i]; } else { for(i = 0; i < ports->nports; i++) if (ct.un.mask & ports->misel[i]) aumask |= ports->aumask[i]; } return aumask; } int audiosetinfo(struct audio_softc *sc, struct audio_info *ai) { struct audio_prinfo *r = &ai->record, *p = &ai->play; int cleared; int setmode, modechange = 0; int error; struct audio_hw_if *hw = sc->hw_if; struct audio_params pp, rp; int np, nr; unsigned int blks; int oldpblksize, oldrblksize; int rbus, pbus; int fpb; int fs; u_int gain; u_char balance; if (hw == 0) /* HW has not attached */ return(ENXIO); rbus = sc->sc_rbus; pbus = sc->sc_pbus; error = 0; cleared = 0; pp = sc->sc_pparams; /* Temporary encoding storage in */ rp = sc->sc_rparams; /* case setting the modes fails. */ nr = np = 0; if (p->sample_rate != ~0) { pp.sample_rate = p->sample_rate; np++; } if (r->sample_rate != ~0) { rp.sample_rate = r->sample_rate; nr++; } if (p->encoding != ~0) { pp.encoding = p->encoding; np++; } if (r->encoding != ~0) { rp.encoding = r->encoding; nr++; } if (p->precision != ~0) { pp.precision = p->precision; np++; } if (r->precision != ~0) { rp.precision = r->precision; nr++; } if (p->bps != ~0) { pp.bps = p->bps; np++; } if (r->bps != ~0) { rp.bps = r->bps; nr++; } if (p->msb != ~0) { pp.msb = p->msb; np++; } if (r->msb != ~0) { rp.msb = r->msb; nr++; } if (p->channels != ~0) { pp.channels = p->channels; np++; } if (r->channels != ~0) { rp.channels = r->channels; nr++; } #ifdef AUDIO_DEBUG if (audiodebug && nr) audio_print_params("Setting record params", &rp); if (audiodebug && np) audio_print_params("Setting play params", &pp); #endif if (nr && (error = audio_check_params(&rp))) return error; if (np && (error = audio_check_params(&pp))) return error; setmode = 0; if (nr) { if (!cleared) audio_clear(sc); modechange = cleared = 1; rp.sw_code = 0; rp.factor = 1; setmode |= AUMODE_RECORD; } if (np) { if (!cleared) audio_clear(sc); modechange = cleared = 1; pp.sw_code = 0; pp.factor = 1; setmode |= AUMODE_PLAY; } if (ai->mode != ~0) { if (!cleared) audio_clear(sc); modechange = cleared = 1; sc->sc_mode = ai->mode; if (sc->sc_mode & AUMODE_PLAY_ALL) sc->sc_mode |= AUMODE_PLAY; if ((sc->sc_mode & AUMODE_PLAY) && !sc->sc_full_duplex) /* Play takes precedence */ sc->sc_mode &= ~AUMODE_RECORD; } if (modechange) { int indep = hw->get_props(sc->hw_hdl) & AUDIO_PROP_INDEPENDENT; if (!indep) { if (setmode == AUMODE_RECORD) pp = rp; else rp = pp; } error = hw->set_params(sc->hw_hdl, setmode, sc->sc_mode & (AUMODE_PLAY | AUMODE_RECORD), &pp, &rp); if (error) return (error); if (!indep) { if (setmode == AUMODE_RECORD) { pp.sample_rate = rp.sample_rate; pp.encoding = rp.encoding; pp.channels = rp.channels; pp.precision = rp.precision; pp.bps = rp.bps; pp.msb = rp.msb; } else if (setmode == AUMODE_PLAY) { rp.sample_rate = pp.sample_rate; rp.encoding = pp.encoding; rp.channels = pp.channels; rp.precision = pp.precision; rp.bps = pp.bps; rp.msb = pp.msb; } } sc->sc_rparams = rp; sc->sc_pparams = pp; } oldpblksize = sc->sc_pr.blksize; oldrblksize = sc->sc_rr.blksize; /* * allow old-style blocksize changes, for compatibility; * individual play/record block sizes have precedence */ if (ai->blocksize != ~0) { if (r->block_size == ~0) r->block_size = ai->blocksize; if (p->block_size == ~0) p->block_size = ai->blocksize; } if (r->block_size != ~0) { sc->sc_rr.blkset = 0; if (!cleared) audio_clear(sc); cleared = 1; nr++; } if (p->block_size != ~0) { sc->sc_pr.blkset = 0; if (!cleared) audio_clear(sc); cleared = 1; np++; } if (nr) { if (r->block_size == ~0 || r->block_size == 0) { fpb = rp.sample_rate * audio_blk_ms / 1000; } else { fs = rp.channels * rp.bps; fpb = (r->block_size * rp.factor) / fs; } if (sc->sc_rr.blkset == 0) audio_set_blksize(sc, AUMODE_RECORD, fpb); } if (np) { if (p->block_size == ~0 || p->block_size == 0) { fpb = pp.sample_rate * audio_blk_ms / 1000; } else { fs = pp.channels * pp.bps; fpb = (p->block_size * pp.factor) / fs; } if (sc->sc_pr.blkset == 0) audio_set_blksize(sc, AUMODE_PLAY, fpb); } if (r->block_size != ~0 && r->block_size != 0) sc->sc_rr.blkset = 1; if (p->block_size != ~0 && p->block_size != 0) sc->sc_pr.blkset = 1; #ifdef AUDIO_DEBUG if (audiodebug > 1 && nr) audio_print_params("After setting record params", &sc->sc_rparams); if (audiodebug > 1 && np) audio_print_params("After setting play params", &sc->sc_pparams); #endif if (p->port != ~0) { if (!cleared) audio_clear(sc); cleared = 1; error = au_set_port(sc, &sc->sc_outports, p->port); if (error) return(error); } if (r->port != ~0) { if (!cleared) audio_clear(sc); cleared = 1; error = au_set_port(sc, &sc->sc_inports, r->port); if (error) return(error); } if (p->gain != ~0) { au_get_gain(sc, &sc->sc_outports, &gain, &balance); error = au_set_gain(sc, &sc->sc_outports, p->gain, balance); if (error) return(error); } if ((r->gain != ~0) && (r->port != 0)) { au_get_gain(sc, &sc->sc_inports, &gain, &balance); error = au_set_gain(sc, &sc->sc_inports, r->gain, balance); if (error) return(error); } if (p->balance != (u_char)~0) { au_get_gain(sc, &sc->sc_outports, &gain, &balance); error = au_set_gain(sc, &sc->sc_outports, gain, p->balance); if (error) return(error); } if ((r->balance != (u_char)~0) && (r->port != 0)) { au_get_gain(sc, &sc->sc_inports, &gain, &balance); error = au_set_gain(sc, &sc->sc_inports, gain, r->balance); if (error) return(error); } if (ai->output_muted != (u_char)~0) { error = au_set_mute(sc, &sc->sc_outports, ai->output_muted); if (error) return(error); } if (ai->monitor_gain != ~0 && sc->sc_monitor_port != -1) { mixer_ctrl_t ct; ct.dev = sc->sc_monitor_port; ct.type = AUDIO_MIXER_VALUE; ct.un.value.num_channels = 1; ct.un.value.level[AUDIO_MIXER_LEVEL_MONO] = ai->monitor_gain; error = sc->hw_if->set_port(sc->hw_hdl, &ct); if (error) return(error); } if (ai->mode != ~0) { if (sc->sc_mode & AUMODE_PLAY) audio_init_play(sc); if (sc->sc_mode & AUMODE_RECORD) audio_init_record(sc); } if (hw->commit_settings) { error = hw->commit_settings(sc->hw_hdl); if (error) return (error); } if (cleared) { error = audio_initbufs(sc); if (error) goto err; if (sc->sc_pr.blksize != oldpblksize || sc->sc_rr.blksize != oldrblksize) audio_calcwater(sc); if ((sc->sc_mode & AUMODE_PLAY) && pbus && !sc->sc_pbus && !sc->sc_pr.pause) error = audiostartp(sc); if (!error && (sc->sc_mode & AUMODE_RECORD) && rbus && !sc->sc_rbus && !sc->sc_rr.pause) error = audiostartr(sc); err: if (error) return error; } /* Change water marks after initializing the buffers. */ if (ai->hiwat != ~0) { blks = ai->hiwat; if (blks > sc->sc_pr.maxblks) blks = sc->sc_pr.maxblks; if (blks < 2) blks = 2; sc->sc_pr.usedhigh = blks * sc->sc_pr.blksize; } if (ai->lowat != ~0) { blks = ai->lowat; if (blks > sc->sc_pr.maxblks - 1) blks = sc->sc_pr.maxblks - 1; sc->sc_pr.usedlow = blks * sc->sc_pr.blksize; } if (ai->hiwat != ~0 || ai->lowat != ~0) { if (sc->sc_pr.usedlow > sc->sc_pr.usedhigh - sc->sc_pr.blksize) sc->sc_pr.usedlow = sc->sc_pr.usedhigh - sc->sc_pr.blksize; } if (p->pause != (u_char)~0) { sc->sc_pr.pause = p->pause; if (!p->pause && !sc->sc_pbus && (sc->sc_mode & AUMODE_PLAY)) { error = audiostartp(sc); if (error) return error; } } if (r->pause != (u_char)~0) { sc->sc_rr.pause = r->pause; if (!r->pause && !sc->sc_rbus && (sc->sc_mode & AUMODE_RECORD)) { error = audiostartr(sc); if (error) return error; } } return (0); } int audiogetinfo(struct audio_softc *sc, struct audio_info *ai) { struct audio_prinfo *r = &ai->record, *p = &ai->play; struct audio_hw_if *hw = sc->hw_if; if (hw == 0) /* HW has not attached */ return(ENXIO); p->sample_rate = sc->sc_pparams.sample_rate; r->sample_rate = sc->sc_rparams.sample_rate; p->channels = sc->sc_pparams.channels; r->channels = sc->sc_rparams.channels; p->precision = sc->sc_pparams.precision; r->precision = sc->sc_rparams.precision; p->bps = sc->sc_pparams.bps; r->bps = sc->sc_rparams.bps; p->msb = sc->sc_pparams.msb; r->msb = sc->sc_rparams.msb; p->encoding = sc->sc_pparams.encoding; r->encoding = sc->sc_rparams.encoding; r->port = au_get_port(sc, &sc->sc_inports); p->port = au_get_port(sc, &sc->sc_outports); r->avail_ports = sc->sc_inports.allports; p->avail_ports = sc->sc_outports.allports; au_get_gain(sc, &sc->sc_inports, &r->gain, &r->balance); au_get_gain(sc, &sc->sc_outports, &p->gain, &p->balance); if (sc->sc_monitor_port != -1) { mixer_ctrl_t ct; ct.dev = sc->sc_monitor_port; ct.type = AUDIO_MIXER_VALUE; ct.un.value.num_channels = 1; if (sc->hw_if->get_port(sc->hw_hdl, &ct)) ai->monitor_gain = 0; else ai->monitor_gain = ct.un.value.level[AUDIO_MIXER_LEVEL_MONO]; } else ai->monitor_gain = 0; au_get_mute(sc, &sc->sc_outports, &ai->output_muted); p->seek = sc->sc_pr.used / sc->sc_pparams.factor; r->seek = sc->sc_rr.used / sc->sc_rparams.factor; p->samples = sc->sc_pr.stamp - sc->sc_pr.drops; r->samples = sc->sc_rr.stamp - sc->sc_rr.drops; p->eof = sc->sc_eof; r->eof = 0; p->pause = sc->sc_pr.pause; r->pause = sc->sc_rr.pause; p->error = sc->sc_pr.drops != 0; r->error = sc->sc_rr.drops != 0; p->waiting = r->waiting = 0; /* open never hangs */ p->open = (sc->sc_open & AUOPEN_WRITE) != 0; r->open = (sc->sc_open & AUOPEN_READ) != 0; p->active = sc->sc_pbus; r->active = sc->sc_rbus; p->buffer_size = sc->sc_pr.bufsize / sc->sc_pparams.factor; r->buffer_size = sc->sc_rr.bufsize / sc->sc_rparams.factor; r->block_size = sc->sc_rr.blksize / sc->sc_rparams.factor; p->block_size = sc->sc_pr.blksize / sc->sc_pparams.factor; if (p->block_size != 0) { ai->hiwat = sc->sc_pr.usedhigh / sc->sc_pr.blksize; ai->lowat = sc->sc_pr.usedlow / sc->sc_pr.blksize; } else { ai->hiwat = ai->lowat = 0; } ai->blocksize = p->block_size; /* for compatibility, remove this */ ai->mode = sc->sc_mode; return (0); } int audiogetbufinfo(struct audio_softc *sc, struct audio_bufinfo *info, int mode) { struct audio_ringbuffer *buf; int factor; factor = 1; if (mode == AUMODE_PLAY) { buf = &sc->sc_pr; factor = sc->sc_pparams.factor; } else { buf = &sc->sc_rr; factor = sc->sc_rparams.factor; } info->seek = buf->used / factor; info->blksize = buf->blksize / factor; if (buf->blksize != 0) { info->hiwat = buf->usedhigh / buf->blksize; info->lowat = buf->usedlow / buf->blksize; } else { info->hiwat = 0; info->lowat = 0; } return (0); } /* * Mixer driver */ int mixer_open(dev_t dev, struct audio_softc *sc, int flags, int ifmt, struct proc *p) { DPRINTF(("mixer_open: dev=0x%x flags=0x%x sc=%p\n", dev, flags, sc)); return (0); } /* * Remove a process from those to be signalled on mixer activity. */ static void mixer_remove(struct audio_softc *sc, struct proc *p) { struct mixer_asyncs **pm, *m; for(pm = &sc->sc_async_mixer; *pm; pm = &(*pm)->next) { if ((*pm)->proc == p) { m = *pm; *pm = m->next; free(m, M_DEVBUF, 0); return; } } } /* * Signal all processes waiting for the mixer. */ static void mixer_signal(struct audio_softc *sc) { struct mixer_asyncs *m; for(m = sc->sc_async_mixer; m; m = m->next) psignal(m->proc, SIGIO); } /* * Close a mixer device */ /* ARGSUSED */ int mixer_close(dev_t dev, int flags, int ifmt, struct proc *p) { int unit = AUDIOUNIT(dev); struct audio_softc *sc = audio_cd.cd_devs[unit]; DPRINTF(("mixer_close: unit %d\n", AUDIOUNIT(dev))); mixer_remove(sc, p); return (0); } int mixer_ioctl(dev_t dev, u_long cmd, caddr_t addr, int flag, struct proc *p) { int unit = AUDIOUNIT(dev); struct audio_softc *sc = audio_cd.cd_devs[unit]; struct audio_hw_if *hw = sc->hw_if; int error = EINVAL; DPRINTF(("mixer_ioctl(%ld,'%c',%ld)\n", IOCPARM_LEN(cmd), (int)IOCGROUP(cmd), cmd & 0xff)); /* Block when fully quiesced. No need to block earlier. */ while (sc->sc_quiesce == AUDIO_QUIESCE_SILENT) tsleep(&sc->sc_quiesce, 0, "aud_qmi", 0); switch (cmd) { case FIOASYNC: mixer_remove(sc, p); /* remove old entry */ if (*(int *)addr) { struct mixer_asyncs *ma; ma = malloc(sizeof (struct mixer_asyncs), M_DEVBUF, M_WAITOK); ma->next = sc->sc_async_mixer; ma->proc = p; sc->sc_async_mixer = ma; } error = 0; break; case AUDIO_GETDEV: DPRINTF(("AUDIO_GETDEV\n")); error = hw->getdev(sc->hw_hdl, (audio_device_t *)addr); break; case AUDIO_MIXER_DEVINFO: DPRINTF(("AUDIO_MIXER_DEVINFO\n")); ((mixer_devinfo_t *)addr)->un.v.delta = 0; /* default */ error = hw->query_devinfo(sc->hw_hdl, (mixer_devinfo_t *)addr); break; case AUDIO_MIXER_READ: DPRINTF(("AUDIO_MIXER_READ\n")); error = hw->get_port(sc->hw_hdl, (mixer_ctrl_t *)addr); break; case AUDIO_MIXER_WRITE: if (!(flag & FWRITE)) return (EACCES); DPRINTF(("AUDIO_MIXER_WRITE\n")); error = hw->set_port(sc->hw_hdl, (mixer_ctrl_t *)addr); if (!error && hw->commit_settings) error = hw->commit_settings(sc->hw_hdl); if (!error) mixer_signal(sc); break; default: error = ENOTTY; break; } DPRINTF(("mixer_ioctl(%ld,'%c',%ld) result %d\n", IOCPARM_LEN(cmd), (int)IOCGROUP(cmd), cmd & 0xff, error)); return (error); } int audiokqfilter(dev_t dev, struct knote *kn) { int unit = AUDIOUNIT(dev); struct audio_softc *sc = audio_cd.cd_devs[unit]; struct klist *klist; switch (kn->kn_filter) { case EVFILT_READ: klist = &sc->sc_rsel.si_note; kn->kn_fop = &audioread_filtops; break; case EVFILT_WRITE: klist = &sc->sc_wsel.si_note; kn->kn_fop = &audiowrite_filtops; break; default: return (EINVAL); } kn->kn_hook = (void *)sc; mtx_enter(&audio_lock); SLIST_INSERT_HEAD(klist, kn, kn_selnext); mtx_leave(&audio_lock); return (0); } void filt_audiordetach(struct knote *kn) { struct audio_softc *sc = (struct audio_softc *)kn->kn_hook; mtx_enter(&audio_lock); SLIST_REMOVE(&sc->sc_rsel.si_note, kn, knote, kn_selnext); mtx_leave(&audio_lock); } int filt_audioread(struct knote *kn, long hint) { struct audio_softc *sc = (struct audio_softc *)kn->kn_hook; return AUDIO_FILTREAD(sc); } void filt_audiowdetach(struct knote *kn) { struct audio_softc *sc = (struct audio_softc *)kn->kn_hook; mtx_enter(&audio_lock); SLIST_REMOVE(&sc->sc_wsel.si_note, kn, knote, kn_selnext); mtx_leave(&audio_lock); } int filt_audiowrite(struct knote *kn, long hint) { struct audio_softc *sc = (struct audio_softc *)kn->kn_hook; return AUDIO_FILTWRITE(sc); } #if NWSKBD > 0 int wskbd_set_mixervolume(long dir, long out) { struct audio_softc *sc; if (audio_cd.cd_ndevs == 0 || (sc = audio_cd.cd_devs[0]) == NULL) { DPRINTF(("wskbd_set_mixervolume: audio_cd\n")); return (ENXIO); } task_del(systq, &sc->sc_mixer_task); task_set(&sc->sc_mixer_task, wskbd_set_mixervolume_callback, (void *)dir, (void *)out); task_add(systq, &sc->sc_mixer_task); return (0); } void wskbd_set_mixervolume_callback(void *arg1, void *arg2) { struct audio_softc *sc; struct au_mixer_ports *ports; mixer_devinfo_t mi; u_char balance, mute; long dir, out; u_int gain; int error; if (audio_cd.cd_ndevs == 0 || (sc = audio_cd.cd_devs[0]) == NULL) { DPRINTF(("%s: audio_cd\n", __func__)); return; } dir = (long)arg1; out = (long)arg2; ports = out ? &sc->sc_outports : &sc->sc_inports; if (ports->master == -1) { DPRINTF(("%s: master == -1\n", __func__)); return; } if (dir == 0) { /* Mute */ error = au_get_mute(sc, ports, &mute); if (error != 0) { DPRINTF(("%s: au_get_mute: %d\n", __func__, error)); return; } mute = !mute; error = au_set_mute(sc, ports, mute); if (error != 0) { DPRINTF(("%s: au_set_mute: %d\n", __func__, error)); return; } } else { /* Raise or lower volume */ mi.index = ports->master; error = sc->hw_if->query_devinfo(sc->hw_hdl, &mi); if (error != 0) { DPRINTF(("%s: query_devinfo: %d\n", __func__, error)); return; } au_get_gain(sc, ports, &gain, &balance); if (dir > 0) gain += mi.un.v.delta; else gain -= mi.un.v.delta; error = au_set_gain(sc, ports, gain, balance); if (error != 0) { DPRINTF(("%s: au_set_gain: %d\n", __func__, error)); return; } } } #endif /* NWSKBD > 0 */