/*- * Copyright (c) 2005-2009 Ariff Abdullah * Portions Copyright (c) Ryan Beasley - GSoC 2006 * Copyright (c) 1999 Cameron Grant * 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. * * 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. */ #ifdef HAVE_KERNEL_OPTION_HEADERS #include "opt_snd.h" #endif #include #include #include #include #include #include #include #include #include #include SND_DECLARE_FILE("$FreeBSD: head/sys/dev/sound/pcm/dsp.c 274035 2014-11-03 11:11:45Z bapt $"); static int dsp_mmap_allow_prot_exec = 0; SYSCTL_INT(_hw_snd, OID_AUTO, compat_linux_mmap, CTLFLAG_RW, &dsp_mmap_allow_prot_exec, 0, "linux mmap compatibility (-1=force disable 0=auto 1=force enable)"); struct dsp_cdevinfo { struct pcm_channel *rdch, *wrch; struct pcm_channel *volch; int busy, simplex; TAILQ_ENTRY(dsp_cdevinfo) link; }; #define PCM_RDCH(x) (((struct dsp_cdevinfo *)(x)->si_drv1)->rdch) #define PCM_WRCH(x) (((struct dsp_cdevinfo *)(x)->si_drv1)->wrch) #define PCM_VOLCH(x) (((struct dsp_cdevinfo *)(x)->si_drv1)->volch) #define PCM_SIMPLEX(x) (((struct dsp_cdevinfo *)(x)->si_drv1)->simplex) #define DSP_CDEVINFO_CACHESIZE 8 #define DSP_REGISTERED(x, y) (PCM_REGISTERED(x) && \ (y) != NULL && (y)->si_drv1 != NULL) #define OLDPCM_IOCTL static d_open_t dsp_open; static d_close_t dsp_close; static d_read_t dsp_read; static d_write_t dsp_write; static d_ioctl_t dsp_ioctl; static d_kqfilter_t dsp_kqfilter; static d_mmap_t dsp_mmap; static d_mmap_single_t dsp_mmap_single; static void dsp_filter_detach(struct knote *); static int dsp_filter_read(struct knote *, long); static int dsp_filter_write(struct knote *, long); struct dev_ops dsp_ops = { .d_open = dsp_open, .d_close = dsp_close, .d_read = dsp_read, .d_write = dsp_write, .d_ioctl = dsp_ioctl, .d_kqfilter = dsp_kqfilter, .d_mmap = dsp_mmap, .d_mmap_single = dsp_mmap_single, }; static eventhandler_tag dsp_ehtag = NULL; static int dsp_umax = -1; static int dsp_cmax = -1; static int dsp_oss_syncgroup(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_syncgroup *group); static int dsp_oss_syncstart(int sg_id); static int dsp_oss_policy(struct pcm_channel *wrch, struct pcm_channel *rdch, int policy); static int dsp_oss_cookedmode(struct pcm_channel *wrch, struct pcm_channel *rdch, int enabled); static int dsp_oss_getchnorder(struct pcm_channel *wrch, struct pcm_channel *rdch, unsigned long long *map); static int dsp_oss_setchnorder(struct pcm_channel *wrch, struct pcm_channel *rdch, unsigned long long *map); static int dsp_oss_getchannelmask(struct pcm_channel *wrch, struct pcm_channel *rdch, int *mask); #ifdef OSSV4_EXPERIMENT static int dsp_oss_getlabel(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_label_t *label); static int dsp_oss_setlabel(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_label_t *label); static int dsp_oss_getsong(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_longname_t *song); static int dsp_oss_setsong(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_longname_t *song); static int dsp_oss_setname(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_longname_t *name); #endif static struct snddev_info * dsp_get_info(struct cdev *dev) { return (devclass_get_softc(pcm_devclass, PCMUNIT(dev))); } static uint32_t dsp_get_flags(struct cdev *dev) { device_t bdev; bdev = devclass_get_device(pcm_devclass, PCMUNIT(dev)); return ((bdev != NULL) ? pcm_getflags(bdev) : 0xffffffff); } static void dsp_set_flags(struct cdev *dev, uint32_t flags) { device_t bdev; bdev = devclass_get_device(pcm_devclass, PCMUNIT(dev)); if (bdev != NULL) pcm_setflags(bdev, flags); } /* * return the channels associated with an open device instance. * lock channels specified. */ static int getchns(struct cdev *dev, struct pcm_channel **rdch, struct pcm_channel **wrch, uint32_t prio) { struct snddev_info *d; struct pcm_channel *ch; uint32_t flags; if (PCM_SIMPLEX(dev) != 0) { d = dsp_get_info(dev); if (!PCM_REGISTERED(d)) return (ENXIO); PCM_LOCK(d); PCM_WAIT(d); PCM_ACQUIRE(d); /* * Note: order is important - * pcm flags -> prio query flags -> wild guess */ ch = NULL; flags = dsp_get_flags(dev); if (flags & SD_F_PRIO_WR) { ch = PCM_RDCH(dev); PCM_RDCH(dev) = NULL; } else if (flags & SD_F_PRIO_RD) { ch = PCM_WRCH(dev); PCM_WRCH(dev) = NULL; } else if (prio & SD_F_PRIO_WR) { ch = PCM_RDCH(dev); PCM_RDCH(dev) = NULL; flags |= SD_F_PRIO_WR; } else if (prio & SD_F_PRIO_RD) { ch = PCM_WRCH(dev); PCM_WRCH(dev) = NULL; flags |= SD_F_PRIO_RD; } else if (PCM_WRCH(dev) != NULL) { ch = PCM_RDCH(dev); PCM_RDCH(dev) = NULL; flags |= SD_F_PRIO_WR; } else if (PCM_RDCH(dev) != NULL) { ch = PCM_WRCH(dev); PCM_WRCH(dev) = NULL; flags |= SD_F_PRIO_RD; } PCM_SIMPLEX(dev) = 0; dsp_set_flags(dev, flags); if (ch != NULL) { CHN_LOCK(ch); pcm_chnref(ch, -1); pcm_chnrelease(ch); } PCM_RELEASE(d); PCM_UNLOCK(d); } *rdch = PCM_RDCH(dev); *wrch = PCM_WRCH(dev); if (*rdch != NULL && (prio & SD_F_PRIO_RD)) CHN_LOCK(*rdch); if (*wrch != NULL && (prio & SD_F_PRIO_WR)) CHN_LOCK(*wrch); return (0); } /* unlock specified channels */ static void relchns(struct cdev *dev, struct pcm_channel *rdch, struct pcm_channel *wrch, uint32_t prio) { if (wrch != NULL && (prio & SD_F_PRIO_WR)) CHN_UNLOCK(wrch); if (rdch != NULL && (prio & SD_F_PRIO_RD)) CHN_UNLOCK(rdch); } static void dsp_cdevinfo_alloc(struct cdev *dev, struct pcm_channel *rdch, struct pcm_channel *wrch, struct pcm_channel *volch) { struct snddev_info *d; struct dsp_cdevinfo *cdi; int simplex; d = dsp_get_info(dev); KASSERT(PCM_REGISTERED(d) && dev != NULL && dev->si_drv1 == NULL && ((rdch == NULL && wrch == NULL) || rdch != wrch), ("bogus %s(), what are you trying to accomplish here?", __func__)); PCM_BUSYASSERT(d); PCM_LOCKASSERT(d); simplex = (dsp_get_flags(dev) & SD_F_SIMPLEX) ? 1 : 0; /* * Scan for free instance entry and put it into the end of list. * Create new one if necessary. */ TAILQ_FOREACH(cdi, &d->dsp_cdevinfo_pool, link) { if (cdi->busy != 0) break; cdi->rdch = rdch; cdi->wrch = wrch; cdi->volch = volch; cdi->simplex = simplex; cdi->busy = 1; TAILQ_REMOVE(&d->dsp_cdevinfo_pool, cdi, link); TAILQ_INSERT_TAIL(&d->dsp_cdevinfo_pool, cdi, link); dev->si_drv1 = cdi; return; } PCM_UNLOCK(d); cdi = kmalloc(sizeof(*cdi), M_DEVBUF, M_WAITOK | M_ZERO); PCM_LOCK(d); cdi->rdch = rdch; cdi->wrch = wrch; cdi->volch = volch; cdi->simplex = simplex; cdi->busy = 1; TAILQ_INSERT_TAIL(&d->dsp_cdevinfo_pool, cdi, link); dev->si_drv1 = cdi; } static void dsp_cdevinfo_free(struct cdev *dev) { struct snddev_info *d; struct dsp_cdevinfo *cdi, *tmp; uint32_t flags; int i; d = dsp_get_info(dev); KASSERT(PCM_REGISTERED(d) && dev != NULL && dev->si_drv1 != NULL && PCM_RDCH(dev) == NULL && PCM_WRCH(dev) == NULL && PCM_VOLCH(dev) == NULL, ("bogus %s(), what are you trying to accomplish here?", __func__)); PCM_BUSYASSERT(d); PCM_LOCKASSERT(d); cdi = dev->si_drv1; dev->si_drv1 = NULL; cdi->rdch = NULL; cdi->wrch = NULL; cdi->volch = NULL; cdi->simplex = 0; cdi->busy = 0; /* * Once it is free, move it back to the beginning of list for * faster new entry allocation. */ TAILQ_REMOVE(&d->dsp_cdevinfo_pool, cdi, link); TAILQ_INSERT_HEAD(&d->dsp_cdevinfo_pool, cdi, link); /* * Scan the list, cache free entries up to DSP_CDEVINFO_CACHESIZE. * Reset simplex flags. */ flags = dsp_get_flags(dev) & ~SD_F_PRIO_SET; i = DSP_CDEVINFO_CACHESIZE; TAILQ_FOREACH_MUTABLE(cdi, &d->dsp_cdevinfo_pool, link, tmp) { if (cdi->busy != 0) { if (cdi->simplex == 0) { if (cdi->rdch != NULL) flags |= SD_F_PRIO_RD; if (cdi->wrch != NULL) flags |= SD_F_PRIO_WR; } } else { if (i == 0) { TAILQ_REMOVE(&d->dsp_cdevinfo_pool, cdi, link); kfree(cdi, M_DEVBUF); } else i--; } } dsp_set_flags(dev, flags); } void dsp_cdevinfo_init(struct snddev_info *d) { struct dsp_cdevinfo *cdi; int i; KASSERT(d != NULL, ("NULL snddev_info")); PCM_BUSYASSERT(d); PCM_UNLOCKASSERT(d); TAILQ_INIT(&d->dsp_cdevinfo_pool); for (i = 0; i < DSP_CDEVINFO_CACHESIZE; i++) { cdi = kmalloc(sizeof(*cdi), M_DEVBUF, M_WAITOK | M_ZERO); TAILQ_INSERT_HEAD(&d->dsp_cdevinfo_pool, cdi, link); } } void dsp_cdevinfo_flush(struct snddev_info *d) { struct dsp_cdevinfo *cdi, *tmp; KASSERT(d != NULL, ("NULL snddev_info")); PCM_BUSYASSERT(d); PCM_UNLOCKASSERT(d); cdi = TAILQ_FIRST(&d->dsp_cdevinfo_pool); while (cdi != NULL) { tmp = TAILQ_NEXT(cdi, link); kfree(cdi, M_DEVBUF); cdi = tmp; } TAILQ_INIT(&d->dsp_cdevinfo_pool); } /* duplex / simplex cdev type */ enum { DSP_CDEV_TYPE_RDONLY, /* simplex read-only (record) */ DSP_CDEV_TYPE_WRONLY, /* simplex write-only (play) */ DSP_CDEV_TYPE_RDWR /* duplex read, write, or both */ }; enum { DSP_CDEV_VOLCTL_NONE, DSP_CDEV_VOLCTL_READ, DSP_CDEV_VOLCTL_WRITE }; #define DSP_F_VALID(x) ((x) & (FREAD | FWRITE)) #define DSP_F_DUPLEX(x) (((x) & (FREAD | FWRITE)) == (FREAD | FWRITE)) #define DSP_F_SIMPLEX(x) (!DSP_F_DUPLEX(x)) #define DSP_F_READ(x) ((x) & FREAD) #define DSP_F_WRITE(x) ((x) & FWRITE) static const struct { int type; char *name; char *sep; char *alias; int use_sep; int hw; int max; int volctl; uint32_t fmt, spd; int query; } dsp_cdevs[] = { { SND_DEV_DSP, "dsp", ".", NULL, 0, 0, 0, 0, SND_FORMAT(AFMT_U8, 1, 0), DSP_DEFAULT_SPEED, DSP_CDEV_TYPE_RDWR }, { SND_DEV_AUDIO, "audio", ".", NULL, 0, 0, 0, 0, SND_FORMAT(AFMT_MU_LAW, 1, 0), DSP_DEFAULT_SPEED, DSP_CDEV_TYPE_RDWR }, { SND_DEV_DSP16, "dspW", ".", NULL, 0, 0, 0, 0, SND_FORMAT(AFMT_S16_LE, 1, 0), DSP_DEFAULT_SPEED, DSP_CDEV_TYPE_RDWR }, { SND_DEV_DSPHW_PLAY, "dsp", ".p", NULL, 1, 1, SND_MAXHWCHAN, 1, SND_FORMAT(AFMT_S16_LE, 2, 0), 48000, DSP_CDEV_TYPE_WRONLY }, { SND_DEV_DSPHW_VPLAY, "dsp", ".vp", NULL, 1, 1, SND_MAXVCHANS, 1, SND_FORMAT(AFMT_S16_LE, 2, 0), 48000, DSP_CDEV_TYPE_WRONLY }, { SND_DEV_DSPHW_REC, "dsp", ".r", NULL, 1, 1, SND_MAXHWCHAN, 1, SND_FORMAT(AFMT_S16_LE, 2, 0), 48000, DSP_CDEV_TYPE_RDONLY }, { SND_DEV_DSPHW_VREC, "dsp", ".vr", NULL, 1, 1, SND_MAXVCHANS, 1, SND_FORMAT(AFMT_S16_LE, 2, 0), 48000, DSP_CDEV_TYPE_RDONLY }, { SND_DEV_DSPHW_CD, "dspcd", ".", NULL, 0, 0, 0, 0, SND_FORMAT(AFMT_S16_LE, 2, 0), 44100, DSP_CDEV_TYPE_RDWR }, /* Low priority, OSSv4 aliases. */ { SND_DEV_DSP, "dsp_ac3", ".", "dsp", 0, 0, 0, 0, SND_FORMAT(AFMT_U8, 1, 0), DSP_DEFAULT_SPEED, DSP_CDEV_TYPE_RDWR }, { SND_DEV_DSP, "dsp_mmap", ".", "dsp", 0, 0, 0, 0, SND_FORMAT(AFMT_U8, 1, 0), DSP_DEFAULT_SPEED, DSP_CDEV_TYPE_RDWR }, { SND_DEV_DSP, "dsp_multich", ".", "dsp", 0, 0, 0, 0, SND_FORMAT(AFMT_U8, 1, 0), DSP_DEFAULT_SPEED, DSP_CDEV_TYPE_RDWR }, { SND_DEV_DSP, "dsp_spdifout", ".", "dsp", 0, 0, 0, 0, SND_FORMAT(AFMT_U8, 1, 0), DSP_DEFAULT_SPEED, DSP_CDEV_TYPE_RDWR }, { SND_DEV_DSP, "dsp_spdifin", ".", "dsp", 0, 0, 0, 0, SND_FORMAT(AFMT_U8, 1, 0), DSP_DEFAULT_SPEED, DSP_CDEV_TYPE_RDWR }, }; #define DSP_FIXUP_ERROR() do { \ prio = dsp_get_flags(i_dev); \ if (!DSP_F_VALID(flags)) \ error = EINVAL; \ if (!DSP_F_DUPLEX(flags) && \ ((DSP_F_READ(flags) && d->reccount == 0) || \ (DSP_F_WRITE(flags) && d->playcount == 0))) \ error = ENOTSUP; \ else if (!DSP_F_DUPLEX(flags) && (prio & SD_F_SIMPLEX) && \ ((DSP_F_READ(flags) && (prio & SD_F_PRIO_WR)) || \ (DSP_F_WRITE(flags) && (prio & SD_F_PRIO_RD)))) \ error = EBUSY; \ else if (DSP_REGISTERED(d, i_dev)) \ error = EBUSY; \ } while (0) static int dsp_open(struct dev_open_args *ap) { struct cdev *i_dev = ap->a_head.a_dev; int flags = ap->a_oflags; struct pcm_channel *rdch, *wrch; struct snddev_info *d; uint32_t fmt, spd, prio, volctl; int i, error, rderror, wrerror, devtype, wdevunit, rdevunit; /* Kind of impossible.. */ if (i_dev == NULL) return (ENODEV); d = dsp_get_info(i_dev); if (!PCM_REGISTERED(d)) return (EBADF); PCM_GIANT_ENTER(d); /* Lock snddev so nobody else can monkey with it. */ PCM_LOCK(d); PCM_WAIT(d); /* * Try to acquire cloned device before someone else pick it. * ENODEV means this is not a cloned droids. */ error = snd_clone_acquire(i_dev); if (!(error == 0 || error == ENODEV)) { DSP_FIXUP_ERROR(); PCM_UNLOCK(d); PCM_GIANT_EXIT(d); return (error); } error = 0; DSP_FIXUP_ERROR(); if (error != 0) { (void)snd_clone_release(i_dev); PCM_UNLOCK(d); PCM_GIANT_EXIT(d); return (error); } /* * That is just enough. Acquire and unlock pcm lock so * the other will just have to wait until we finish doing * everything. */ PCM_ACQUIRE(d); PCM_UNLOCK(d); devtype = PCMDEV(i_dev); wdevunit = -1; rdevunit = -1; fmt = 0; spd = 0; volctl = DSP_CDEV_VOLCTL_NONE; for (i = 0; i < (sizeof(dsp_cdevs) / sizeof(dsp_cdevs[0])); i++) { if (devtype != dsp_cdevs[i].type || dsp_cdevs[i].alias != NULL) continue; /* * Volume control only valid for DSPHW devices, * and it must be opened in opposite direction be it * simplex or duplex. Anything else will be handled * as usual. */ if (dsp_cdevs[i].query == DSP_CDEV_TYPE_WRONLY) { if (dsp_cdevs[i].volctl != 0 && DSP_F_READ(flags)) { volctl = DSP_CDEV_VOLCTL_WRITE; flags &= ~FREAD; flags |= FWRITE; } if (DSP_F_READ(flags)) { (void)snd_clone_release(i_dev); PCM_RELEASE_QUICK(d); PCM_GIANT_EXIT(d); return (ENOTSUP); } wdevunit = dev2unit(i_dev); } else if (dsp_cdevs[i].query == DSP_CDEV_TYPE_RDONLY) { if (dsp_cdevs[i].volctl != 0 && DSP_F_WRITE(flags)) { volctl = DSP_CDEV_VOLCTL_READ; flags &= ~FWRITE; flags |= FREAD; } if (DSP_F_WRITE(flags)) { (void)snd_clone_release(i_dev); PCM_RELEASE_QUICK(d); PCM_GIANT_EXIT(d); return (ENOTSUP); } rdevunit = dev2unit(i_dev); } fmt = dsp_cdevs[i].fmt; spd = dsp_cdevs[i].spd; break; } rdch = NULL; wrch = NULL; rderror = 0; wrerror = 0; /* * if we get here, the open request is valid- either: * * we were previously not open * * we were open for play xor record and the opener wants * the non-open direction */ if (DSP_F_READ(flags)) { /* open for read */ rderror = pcm_chnalloc(d, &rdch, PCMDIR_REC, curproc->p_pid, curproc->p_comm, rdevunit); if (rderror == 0 && chn_reset(rdch, fmt, spd) != 0) rderror = ENXIO; if (volctl == DSP_CDEV_VOLCTL_READ) rderror = 0; if (rderror != 0) { if (rdch != NULL) pcm_chnrelease(rdch); if (!DSP_F_DUPLEX(flags)) { (void)snd_clone_release(i_dev); PCM_RELEASE_QUICK(d); PCM_GIANT_EXIT(d); return (rderror); } rdch = NULL; } else if (volctl == DSP_CDEV_VOLCTL_READ) { if (rdch != NULL) { pcm_chnref(rdch, 1); pcm_chnrelease(rdch); } } else { if (flags & O_NONBLOCK) rdch->flags |= CHN_F_NBIO; if (flags & O_EXCL) rdch->flags |= CHN_F_EXCLUSIVE; pcm_chnref(rdch, 1); if (volctl == DSP_CDEV_VOLCTL_NONE) chn_vpc_reset(rdch, SND_VOL_C_PCM, 0); CHN_UNLOCK(rdch); } } if (DSP_F_WRITE(flags)) { /* open for write */ wrerror = pcm_chnalloc(d, &wrch, PCMDIR_PLAY, curproc->p_pid, curproc->p_comm, wdevunit); if (wrerror == 0 && chn_reset(wrch, fmt, spd) != 0) wrerror = ENXIO; if (volctl == DSP_CDEV_VOLCTL_WRITE) wrerror = 0; if (wrerror != 0) { if (wrch != NULL) pcm_chnrelease(wrch); if (!DSP_F_DUPLEX(flags)) { if (rdch != NULL) { /* * Lock, deref and release previously * created record channel */ CHN_LOCK(rdch); pcm_chnref(rdch, -1); pcm_chnrelease(rdch); } (void)snd_clone_release(i_dev); PCM_RELEASE_QUICK(d); PCM_GIANT_EXIT(d); return (wrerror); } wrch = NULL; } else if (volctl == DSP_CDEV_VOLCTL_WRITE) { if (wrch != NULL) { pcm_chnref(wrch, 1); pcm_chnrelease(wrch); } } else { if (flags & O_NONBLOCK) wrch->flags |= CHN_F_NBIO; if (flags & O_EXCL) wrch->flags |= CHN_F_EXCLUSIVE; pcm_chnref(wrch, 1); if (volctl == DSP_CDEV_VOLCTL_NONE) chn_vpc_reset(wrch, SND_VOL_C_PCM, 0); CHN_UNLOCK(wrch); } } PCM_LOCK(d); /* * We're done. Allocate channels information for this cdev. */ switch (volctl) { case DSP_CDEV_VOLCTL_READ: KASSERT(wrch == NULL, ("wrch=%p not null!", wrch)); dsp_cdevinfo_alloc(i_dev, NULL, NULL, rdch); break; case DSP_CDEV_VOLCTL_WRITE: KASSERT(rdch == NULL, ("rdch=%p not null!", rdch)); dsp_cdevinfo_alloc(i_dev, NULL, NULL, wrch); break; case DSP_CDEV_VOLCTL_NONE: default: if (wrch == NULL && rdch == NULL) { (void)snd_clone_release(i_dev); PCM_RELEASE(d); PCM_UNLOCK(d); PCM_GIANT_EXIT(d); if (wrerror != 0) return (wrerror); if (rderror != 0) return (rderror); return (EINVAL); } dsp_cdevinfo_alloc(i_dev, rdch, wrch, NULL); if (rdch != NULL) CHN_INSERT_HEAD(d, rdch, channels.pcm.opened); if (wrch != NULL) CHN_INSERT_HEAD(d, wrch, channels.pcm.opened); break; } /* * Increase clone refcount for its automatic garbage collector. */ (void)snd_clone_ref(i_dev); PCM_RELEASE(d); PCM_UNLOCK(d); PCM_GIANT_LEAVE(d); return (0); } static int dsp_close(struct dev_close_args *ap) { struct cdev *i_dev = ap->a_head.a_dev; struct pcm_channel *rdch, *wrch, *volch; struct snddev_info *d; int sg_ids, rdref, wdref; d = dsp_get_info(i_dev); if (!DSP_REGISTERED(d, i_dev)) return (EBADF); PCM_GIANT_ENTER(d); PCM_LOCK(d); PCM_WAIT(d); PCM_ACQUIRE(d); rdch = PCM_RDCH(i_dev); wrch = PCM_WRCH(i_dev); volch = PCM_VOLCH(i_dev); PCM_RDCH(i_dev) = NULL; PCM_WRCH(i_dev) = NULL; PCM_VOLCH(i_dev) = NULL; rdref = -1; wdref = -1; if (volch != NULL) { if (volch == rdch) rdref--; else if (volch == wrch) wdref--; else { CHN_LOCK(volch); pcm_chnref(volch, -1); CHN_UNLOCK(volch); } } if (rdch != NULL) CHN_REMOVE(d, rdch, channels.pcm.opened); if (wrch != NULL) CHN_REMOVE(d, wrch, channels.pcm.opened); if (rdch != NULL || wrch != NULL) { PCM_UNLOCK(d); if (rdch != NULL) { /* * The channel itself need not be locked because: * a) Adding a channel to a syncgroup happens only * in dsp_ioctl(), which cannot run concurrently * to dsp_close(). * b) The syncmember pointer (sm) is protected by * the global syncgroup list lock. * c) A channel can't just disappear, invalidating * pointers, unless it's closed/dereferenced * first. */ PCM_SG_LOCK(); sg_ids = chn_syncdestroy(rdch); PCM_SG_UNLOCK(); if (sg_ids != 0) free_unr(pcmsg_unrhdr, sg_ids); CHN_LOCK(rdch); pcm_chnref(rdch, rdref); chn_abort(rdch); /* won't sleep */ rdch->flags &= ~(CHN_F_RUNNING | CHN_F_MMAP | CHN_F_DEAD | CHN_F_EXCLUSIVE); chn_reset(rdch, 0, 0); pcm_chnrelease(rdch); } if (wrch != NULL) { /* * Please see block above. */ PCM_SG_LOCK(); sg_ids = chn_syncdestroy(wrch); PCM_SG_UNLOCK(); if (sg_ids != 0) free_unr(pcmsg_unrhdr, sg_ids); CHN_LOCK(wrch); pcm_chnref(wrch, wdref); chn_flush(wrch); /* may sleep */ wrch->flags &= ~(CHN_F_RUNNING | CHN_F_MMAP | CHN_F_DEAD | CHN_F_EXCLUSIVE); chn_reset(wrch, 0, 0); pcm_chnrelease(wrch); } PCM_LOCK(d); } dsp_cdevinfo_free(i_dev); /* * Release clone busy state and unref it so the automatic * garbage collector will get the hint and do the remaining * cleanup process. */ (void)snd_clone_release(i_dev); /* * destroy_dev() might sleep, so release pcm lock * here and rely on pcm cv serialization. */ PCM_UNLOCK(d); (void)snd_clone_unref(i_dev); PCM_LOCK(d); PCM_RELEASE(d); PCM_UNLOCK(d); PCM_GIANT_LEAVE(d); return (0); } static __inline int dsp_io_ops(struct cdev *i_dev, struct uio *buf) { struct snddev_info *d; struct pcm_channel **ch, *rdch, *wrch; int (*chn_io)(struct pcm_channel *, struct uio *); int prio, ret; pid_t runpid; KASSERT(i_dev != NULL && buf != NULL && (buf->uio_rw == UIO_READ || buf->uio_rw == UIO_WRITE), ("%s(): io train wreck!", __func__)); d = dsp_get_info(i_dev); if (!DSP_REGISTERED(d, i_dev)) return (EBADF); PCM_GIANT_ENTER(d); switch (buf->uio_rw) { case UIO_READ: prio = SD_F_PRIO_RD; ch = &rdch; chn_io = chn_read; break; case UIO_WRITE: prio = SD_F_PRIO_WR; ch = &wrch; chn_io = chn_write; break; default: panic("invalid/corrupted uio direction: %d", buf->uio_rw); break; } rdch = NULL; wrch = NULL; runpid = buf->uio_td->td_proc->p_pid; getchns(i_dev, &rdch, &wrch, prio); if (*ch == NULL || !((*ch)->flags & CHN_F_BUSY)) { PCM_GIANT_EXIT(d); return (EBADF); } if (((*ch)->flags & (CHN_F_MMAP | CHN_F_DEAD)) || (((*ch)->flags & CHN_F_RUNNING) && (*ch)->pid != runpid)) { relchns(i_dev, rdch, wrch, prio); PCM_GIANT_EXIT(d); return (EINVAL); } else if (!((*ch)->flags & CHN_F_RUNNING)) { (*ch)->flags |= CHN_F_RUNNING; (*ch)->pid = runpid; } /* * chn_read/write must give up channel lock in order to copy bytes * from/to userland, so up the "in progress" counter to make sure * someone else doesn't come along and muss up the buffer. */ ++(*ch)->inprog; ret = chn_io(*ch, buf); --(*ch)->inprog; CHN_BROADCAST(&(*ch)->cv); relchns(i_dev, rdch, wrch, prio); PCM_GIANT_LEAVE(d); return (ret); } static int dsp_read(struct dev_read_args *ap) { struct cdev *i_dev = ap->a_head.a_dev; struct uio *buf = ap->a_uio; return (dsp_io_ops(i_dev, buf)); } static int dsp_write(struct dev_write_args *ap) { struct cdev *i_dev = ap->a_head.a_dev; struct uio *buf = ap->a_uio; return (dsp_io_ops(i_dev, buf)); } static int dsp_get_volume_channel(struct cdev *dev, struct pcm_channel **volch) { struct snddev_info *d; struct pcm_channel *c; int unit; KASSERT(dev != NULL && volch != NULL, ("%s(): NULL query dev=%p volch=%p", __func__, dev, volch)); d = dsp_get_info(dev); if (!PCM_REGISTERED(d)) { *volch = NULL; return (EINVAL); } PCM_UNLOCKASSERT(d); *volch = NULL; c = PCM_VOLCH(dev); if (c != NULL) { if (!(c->feederflags & (1 << FEEDER_VOLUME))) return (-1); *volch = c; return (0); } PCM_LOCK(d); PCM_WAIT(d); PCM_ACQUIRE(d); unit = dev2unit(dev); CHN_FOREACH(c, d, channels.pcm) { CHN_LOCK(c); if (c->unit != unit) { CHN_UNLOCK(c); continue; } *volch = c; pcm_chnref(c, 1); PCM_VOLCH(dev) = c; CHN_UNLOCK(c); PCM_RELEASE(d); PCM_UNLOCK(d); return ((c->feederflags & (1 << FEEDER_VOLUME)) ? 0 : -1); } PCM_RELEASE(d); PCM_UNLOCK(d); return (EINVAL); } static int dsp_ioctl_channel(struct cdev *dev, struct pcm_channel *volch, u_long cmd, caddr_t arg) { struct snddev_info *d; struct pcm_channel *rdch, *wrch; int j, devtype, ret; d = dsp_get_info(dev); if (!PCM_REGISTERED(d) || !(dsp_get_flags(dev) & SD_F_VPC)) return (-1); PCM_UNLOCKASSERT(d); j = cmd & 0xff; rdch = PCM_RDCH(dev); wrch = PCM_WRCH(dev); /* No specific channel, look into cache */ if (volch == NULL) volch = PCM_VOLCH(dev); /* Look harder */ if (volch == NULL) { if (j == SOUND_MIXER_RECLEV && rdch != NULL) volch = rdch; else if (j == SOUND_MIXER_PCM && wrch != NULL) volch = wrch; } devtype = PCMDEV(dev); /* Look super harder */ if (volch == NULL && (devtype == SND_DEV_DSPHW_PLAY || devtype == SND_DEV_DSPHW_VPLAY || devtype == SND_DEV_DSPHW_REC || devtype == SND_DEV_DSPHW_VREC)) { ret = dsp_get_volume_channel(dev, &volch); if (ret != 0) return (ret); if (volch == NULL) return (EINVAL); } /* Final validation */ if (volch != NULL) { CHN_LOCK(volch); if (!(volch->feederflags & (1 << FEEDER_VOLUME))) { CHN_UNLOCK(volch); return (-1); } if (volch->direction == PCMDIR_PLAY) wrch = volch; else rdch = volch; } ret = EINVAL; if (volch != NULL && ((j == SOUND_MIXER_PCM && volch->direction == PCMDIR_PLAY) || (j == SOUND_MIXER_RECLEV && volch->direction == PCMDIR_REC))) { if ((cmd & ~0xff) == MIXER_WRITE(0)) { int left, right, center; left = *(int *)arg & 0x7f; right = ((*(int *)arg) >> 8) & 0x7f; center = (left + right) >> 1; chn_setvolume_multi(volch, SND_VOL_C_PCM, left, right, center); } else if ((cmd & ~0xff) == MIXER_READ(0)) { *(int *)arg = CHN_GETVOLUME(volch, SND_VOL_C_PCM, SND_CHN_T_FL); *(int *)arg |= CHN_GETVOLUME(volch, SND_VOL_C_PCM, SND_CHN_T_FR) << 8; } ret = 0; } else if (rdch != NULL || wrch != NULL) { switch (j) { case SOUND_MIXER_DEVMASK: case SOUND_MIXER_CAPS: case SOUND_MIXER_STEREODEVS: if ((cmd & ~0xff) == MIXER_READ(0)) { *(int *)arg = 0; if (rdch != NULL) *(int *)arg |= SOUND_MASK_RECLEV; if (wrch != NULL) *(int *)arg |= SOUND_MASK_PCM; } ret = 0; break; case SOUND_MIXER_RECMASK: case SOUND_MIXER_RECSRC: if ((cmd & ~0xff) == MIXER_READ(0)) *(int *)arg = 0; ret = 0; break; default: break; } } if (volch != NULL) CHN_UNLOCK(volch); return (ret); } static int dsp_ioctl(struct dev_ioctl_args *ap) { struct cdev *i_dev = ap->a_head.a_dev; u_long cmd = ap->a_cmd; caddr_t arg = ap->a_data; struct pcm_channel *chn, *rdch, *wrch; struct snddev_info *d; u_long xcmd; int *arg_i, ret, tmp; d = dsp_get_info(i_dev); if (!DSP_REGISTERED(d, i_dev)) return (EBADF); PCM_GIANT_ENTER(d); arg_i = (int *)arg; ret = 0; xcmd = 0; chn = NULL; if (IOCGROUP(cmd) == 'M') { if (cmd == OSS_GETVERSION) { *arg_i = SOUND_VERSION; PCM_GIANT_EXIT(d); return (0); } ret = dsp_ioctl_channel(i_dev, PCM_VOLCH(i_dev), cmd, arg); if (ret != -1) { PCM_GIANT_EXIT(d); return (ret); } if (d->mixer_dev != NULL) { PCM_ACQUIRE_QUICK(d); ret = mixer_ioctl_cmd(d->mixer_dev, cmd, arg, -1, MIXER_CMD_DIRECT); PCM_RELEASE_QUICK(d); } else ret = EBADF; PCM_GIANT_EXIT(d); return (ret); } /* * Certain ioctls may be made on any type of device (audio, mixer, * and MIDI). Handle those special cases here. */ if (IOCGROUP(cmd) == 'X') { PCM_ACQUIRE_QUICK(d); switch(cmd) { case SNDCTL_SYSINFO: sound_oss_sysinfo((oss_sysinfo *)arg); break; case SNDCTL_CARDINFO: ret = sound_oss_card_info((oss_card_info *)arg); break; case SNDCTL_AUDIOINFO: case SNDCTL_AUDIOINFO_EX: case SNDCTL_ENGINEINFO: ret = dsp_oss_audioinfo(i_dev, (oss_audioinfo *)arg); break; case SNDCTL_MIXERINFO: ret = mixer_oss_mixerinfo(i_dev, (oss_mixerinfo *)arg); break; default: ret = EINVAL; } PCM_RELEASE_QUICK(d); PCM_GIANT_EXIT(d); return (ret); } getchns(i_dev, &rdch, &wrch, 0); if (wrch != NULL && (wrch->flags & CHN_F_DEAD)) wrch = NULL; if (rdch != NULL && (rdch->flags & CHN_F_DEAD)) rdch = NULL; if (wrch == NULL && rdch == NULL) { PCM_GIANT_EXIT(d); return (EINVAL); } switch(cmd) { #ifdef OLDPCM_IOCTL /* * we start with the new ioctl interface. */ case AIONWRITE: /* how many bytes can write ? */ if (wrch) { CHN_LOCK(wrch); /* if (wrch && wrch->bufhard.dl) while (chn_wrfeed(wrch) == 0); */ *arg_i = sndbuf_getfree(wrch->bufsoft); CHN_UNLOCK(wrch); } else { *arg_i = 0; ret = EINVAL; } break; case AIOSSIZE: /* set the current blocksize */ { struct snd_size *p = (struct snd_size *)arg; p->play_size = 0; p->rec_size = 0; PCM_ACQUIRE_QUICK(d); if (wrch) { CHN_LOCK(wrch); chn_setblocksize(wrch, 2, p->play_size); p->play_size = sndbuf_getblksz(wrch->bufsoft); CHN_UNLOCK(wrch); } if (rdch) { CHN_LOCK(rdch); chn_setblocksize(rdch, 2, p->rec_size); p->rec_size = sndbuf_getblksz(rdch->bufsoft); CHN_UNLOCK(rdch); } PCM_RELEASE_QUICK(d); } break; case AIOGSIZE: /* get the current blocksize */ { struct snd_size *p = (struct snd_size *)arg; if (wrch) { CHN_LOCK(wrch); p->play_size = sndbuf_getblksz(wrch->bufsoft); CHN_UNLOCK(wrch); } if (rdch) { CHN_LOCK(rdch); p->rec_size = sndbuf_getblksz(rdch->bufsoft); CHN_UNLOCK(rdch); } } break; case AIOSFMT: case AIOGFMT: { snd_chan_param *p = (snd_chan_param *)arg; if (cmd == AIOSFMT && ((p->play_format != 0 && p->play_rate == 0) || (p->rec_format != 0 && p->rec_rate == 0))) { ret = EINVAL; break; } PCM_ACQUIRE_QUICK(d); if (wrch) { CHN_LOCK(wrch); if (cmd == AIOSFMT && p->play_format != 0) { chn_setformat(wrch, SND_FORMAT(p->play_format, AFMT_CHANNEL(wrch->format), AFMT_EXTCHANNEL(wrch->format))); chn_setspeed(wrch, p->play_rate); } p->play_rate = wrch->speed; p->play_format = AFMT_ENCODING(wrch->format); CHN_UNLOCK(wrch); } else { p->play_rate = 0; p->play_format = 0; } if (rdch) { CHN_LOCK(rdch); if (cmd == AIOSFMT && p->rec_format != 0) { chn_setformat(rdch, SND_FORMAT(p->rec_format, AFMT_CHANNEL(rdch->format), AFMT_EXTCHANNEL(rdch->format))); chn_setspeed(rdch, p->rec_rate); } p->rec_rate = rdch->speed; p->rec_format = AFMT_ENCODING(rdch->format); CHN_UNLOCK(rdch); } else { p->rec_rate = 0; p->rec_format = 0; } PCM_RELEASE_QUICK(d); } break; case AIOGCAP: /* get capabilities */ { snd_capabilities *p = (snd_capabilities *)arg; struct pcmchan_caps *pcaps = NULL, *rcaps = NULL; struct cdev *pdev; PCM_LOCK(d); if (rdch) { CHN_LOCK(rdch); rcaps = chn_getcaps(rdch); } if (wrch) { CHN_LOCK(wrch); pcaps = chn_getcaps(wrch); } p->rate_min = max(rcaps? rcaps->minspeed : 0, pcaps? pcaps->minspeed : 0); p->rate_max = min(rcaps? rcaps->maxspeed : 1000000, pcaps? pcaps->maxspeed : 1000000); p->bufsize = min(rdch? sndbuf_getsize(rdch->bufsoft) : 1000000, wrch? sndbuf_getsize(wrch->bufsoft) : 1000000); /* XXX bad on sb16 */ p->formats = (rdch? chn_getformats(rdch) : 0xffffffff) & (wrch? chn_getformats(wrch) : 0xffffffff); if (rdch && wrch) p->formats |= (dsp_get_flags(i_dev) & SD_F_SIMPLEX)? 0 : AFMT_FULLDUPLEX; pdev = d->mixer_dev; p->mixers = 1; /* default: one mixer */ p->inputs = pdev->si_drv1? mix_getdevs(pdev->si_drv1) : 0; p->left = p->right = 100; if (wrch) CHN_UNLOCK(wrch); if (rdch) CHN_UNLOCK(rdch); PCM_UNLOCK(d); } break; case AIOSTOP: if (*arg_i == AIOSYNC_PLAY && wrch) { CHN_LOCK(wrch); *arg_i = chn_abort(wrch); CHN_UNLOCK(wrch); } else if (*arg_i == AIOSYNC_CAPTURE && rdch) { CHN_LOCK(rdch); *arg_i = chn_abort(rdch); CHN_UNLOCK(rdch); } else { kprintf("AIOSTOP: bad channel 0x%x\n", *arg_i); *arg_i = 0; } break; case AIOSYNC: kprintf("AIOSYNC chan 0x%03lx pos %lu unimplemented\n", ((snd_sync_parm *)arg)->chan, ((snd_sync_parm *)arg)->pos); break; #endif /* * here follow the standard ioctls (filio.h etc.) */ case FIONREAD: /* get # bytes to read */ if (rdch) { CHN_LOCK(rdch); /* if (rdch && rdch->bufhard.dl) while (chn_rdfeed(rdch) == 0); */ *arg_i = sndbuf_getready(rdch->bufsoft); CHN_UNLOCK(rdch); } else { *arg_i = 0; ret = EINVAL; } break; case FIOASYNC: /*set/clear async i/o */ DEB( kprintf("FIOASYNC\n") ; ) break; case SNDCTL_DSP_NONBLOCK: /* set non-blocking i/o */ case FIONBIO: /* set/clear non-blocking i/o */ if (rdch) { CHN_LOCK(rdch); if (cmd == SNDCTL_DSP_NONBLOCK || *arg_i) rdch->flags |= CHN_F_NBIO; else rdch->flags &= ~CHN_F_NBIO; CHN_UNLOCK(rdch); } if (wrch) { CHN_LOCK(wrch); if (cmd == SNDCTL_DSP_NONBLOCK || *arg_i) wrch->flags |= CHN_F_NBIO; else wrch->flags &= ~CHN_F_NBIO; CHN_UNLOCK(wrch); } break; /* * Finally, here is the linux-compatible ioctl interface */ #define THE_REAL_SNDCTL_DSP_GETBLKSIZE _IOWR('P', 4, int) case THE_REAL_SNDCTL_DSP_GETBLKSIZE: case SNDCTL_DSP_GETBLKSIZE: chn = wrch ? wrch : rdch; if (chn) { CHN_LOCK(chn); *arg_i = sndbuf_getblksz(chn->bufsoft); CHN_UNLOCK(chn); } else { *arg_i = 0; ret = EINVAL; } break; case SNDCTL_DSP_SETBLKSIZE: RANGE(*arg_i, 16, 65536); PCM_ACQUIRE_QUICK(d); if (wrch) { CHN_LOCK(wrch); chn_setblocksize(wrch, 2, *arg_i); CHN_UNLOCK(wrch); } if (rdch) { CHN_LOCK(rdch); chn_setblocksize(rdch, 2, *arg_i); CHN_UNLOCK(rdch); } PCM_RELEASE_QUICK(d); break; case SNDCTL_DSP_RESET: DEB(kprintf("dsp reset\n")); if (wrch) { CHN_LOCK(wrch); chn_abort(wrch); chn_resetbuf(wrch); CHN_UNLOCK(wrch); } if (rdch) { CHN_LOCK(rdch); chn_abort(rdch); chn_resetbuf(rdch); CHN_UNLOCK(rdch); } break; case SNDCTL_DSP_SYNC: DEB(kprintf("dsp sync\n")); /* chn_sync may sleep */ if (wrch) { CHN_LOCK(wrch); chn_sync(wrch, 0); CHN_UNLOCK(wrch); } break; case SNDCTL_DSP_SPEED: /* chn_setspeed may sleep */ tmp = 0; PCM_ACQUIRE_QUICK(d); if (wrch) { CHN_LOCK(wrch); ret = chn_setspeed(wrch, *arg_i); tmp = wrch->speed; CHN_UNLOCK(wrch); } if (rdch && ret == 0) { CHN_LOCK(rdch); ret = chn_setspeed(rdch, *arg_i); if (tmp == 0) tmp = rdch->speed; CHN_UNLOCK(rdch); } PCM_RELEASE_QUICK(d); *arg_i = tmp; break; case SOUND_PCM_READ_RATE: chn = wrch ? wrch : rdch; if (chn) { CHN_LOCK(chn); *arg_i = chn->speed; CHN_UNLOCK(chn); } else { *arg_i = 0; ret = EINVAL; } break; case SNDCTL_DSP_STEREO: tmp = -1; *arg_i = (*arg_i)? 2 : 1; PCM_ACQUIRE_QUICK(d); if (wrch) { CHN_LOCK(wrch); ret = chn_setformat(wrch, SND_FORMAT(wrch->format, *arg_i, 0)); tmp = (AFMT_CHANNEL(wrch->format) > 1)? 1 : 0; CHN_UNLOCK(wrch); } if (rdch && ret == 0) { CHN_LOCK(rdch); ret = chn_setformat(rdch, SND_FORMAT(rdch->format, *arg_i, 0)); if (tmp == -1) tmp = (AFMT_CHANNEL(rdch->format) > 1)? 1 : 0; CHN_UNLOCK(rdch); } PCM_RELEASE_QUICK(d); *arg_i = tmp; break; case SOUND_PCM_WRITE_CHANNELS: /* case SNDCTL_DSP_CHANNELS: ( == SOUND_PCM_WRITE_CHANNELS) */ if (*arg_i < 0) { *arg_i = 0; ret = EINVAL; break; } if (*arg_i != 0) { struct pcmchan_matrix *m; uint32_t ext; tmp = 0; if (*arg_i > SND_CHN_MAX) *arg_i = SND_CHN_MAX; m = feeder_matrix_default_channel_map(*arg_i); if (m != NULL) ext = m->ext; else ext = 0; PCM_ACQUIRE_QUICK(d); if (wrch) { CHN_LOCK(wrch); ret = chn_setformat(wrch, SND_FORMAT(wrch->format, *arg_i, ext)); tmp = AFMT_CHANNEL(wrch->format); CHN_UNLOCK(wrch); } if (rdch && ret == 0) { CHN_LOCK(rdch); ret = chn_setformat(rdch, SND_FORMAT(rdch->format, *arg_i, ext)); if (tmp == 0) tmp = AFMT_CHANNEL(rdch->format); CHN_UNLOCK(rdch); } PCM_RELEASE_QUICK(d); *arg_i = tmp; } else { chn = wrch ? wrch : rdch; CHN_LOCK(chn); *arg_i = AFMT_CHANNEL(chn->format); CHN_UNLOCK(chn); } break; case SOUND_PCM_READ_CHANNELS: chn = wrch ? wrch : rdch; if (chn) { CHN_LOCK(chn); *arg_i = AFMT_CHANNEL(chn->format); CHN_UNLOCK(chn); } else { *arg_i = 0; ret = EINVAL; } break; case SNDCTL_DSP_GETFMTS: /* returns a mask of supported fmts */ chn = wrch ? wrch : rdch; if (chn) { CHN_LOCK(chn); *arg_i = chn_getformats(chn); CHN_UNLOCK(chn); } else { *arg_i = 0; ret = EINVAL; } break; case SNDCTL_DSP_SETFMT: /* sets _one_ format */ if (*arg_i != AFMT_QUERY) { tmp = 0; PCM_ACQUIRE_QUICK(d); if (wrch) { CHN_LOCK(wrch); ret = chn_setformat(wrch, SND_FORMAT(*arg_i, AFMT_CHANNEL(wrch->format), AFMT_EXTCHANNEL(wrch->format))); tmp = wrch->format; CHN_UNLOCK(wrch); } if (rdch && ret == 0) { CHN_LOCK(rdch); ret = chn_setformat(rdch, SND_FORMAT(*arg_i, AFMT_CHANNEL(rdch->format), AFMT_EXTCHANNEL(rdch->format))); if (tmp == 0) tmp = rdch->format; CHN_UNLOCK(rdch); } PCM_RELEASE_QUICK(d); *arg_i = AFMT_ENCODING(tmp); } else { chn = wrch ? wrch : rdch; CHN_LOCK(chn); *arg_i = AFMT_ENCODING(chn->format); CHN_UNLOCK(chn); } break; case SNDCTL_DSP_SETFRAGMENT: DEB(kprintf("SNDCTL_DSP_SETFRAGMENT 0x%08x\n", *(int *)arg)); { uint32_t fragln = (*arg_i) & 0x0000ffff; uint32_t maxfrags = ((*arg_i) & 0xffff0000) >> 16; uint32_t fragsz; uint32_t r_maxfrags, r_fragsz; RANGE(fragln, 4, 16); fragsz = 1 << fragln; if (maxfrags == 0) maxfrags = CHN_2NDBUFMAXSIZE / fragsz; if (maxfrags < 2) maxfrags = 2; if (maxfrags * fragsz > CHN_2NDBUFMAXSIZE) maxfrags = CHN_2NDBUFMAXSIZE / fragsz; DEB(kprintf("SNDCTL_DSP_SETFRAGMENT %d frags, %d sz\n", maxfrags, fragsz)); PCM_ACQUIRE_QUICK(d); if (rdch) { CHN_LOCK(rdch); ret = chn_setblocksize(rdch, maxfrags, fragsz); r_maxfrags = sndbuf_getblkcnt(rdch->bufsoft); r_fragsz = sndbuf_getblksz(rdch->bufsoft); CHN_UNLOCK(rdch); } else { r_maxfrags = maxfrags; r_fragsz = fragsz; } if (wrch && ret == 0) { CHN_LOCK(wrch); ret = chn_setblocksize(wrch, maxfrags, fragsz); maxfrags = sndbuf_getblkcnt(wrch->bufsoft); fragsz = sndbuf_getblksz(wrch->bufsoft); CHN_UNLOCK(wrch); } else { /* use whatever came from the read channel */ maxfrags = r_maxfrags; fragsz = r_fragsz; } PCM_RELEASE_QUICK(d); fragln = 0; while (fragsz > 1) { fragln++; fragsz >>= 1; } *arg_i = (maxfrags << 16) | fragln; } break; case SNDCTL_DSP_GETISPACE: /* return the size of data available in the input queue */ { audio_buf_info *a = (audio_buf_info *)arg; if (rdch) { struct snd_dbuf *bs = rdch->bufsoft; CHN_LOCK(rdch); a->bytes = sndbuf_getready(bs); a->fragments = a->bytes / sndbuf_getblksz(bs); a->fragstotal = sndbuf_getblkcnt(bs); a->fragsize = sndbuf_getblksz(bs); CHN_UNLOCK(rdch); } else ret = EINVAL; } break; case SNDCTL_DSP_GETOSPACE: /* return space available in the output queue */ { audio_buf_info *a = (audio_buf_info *)arg; if (wrch) { struct snd_dbuf *bs = wrch->bufsoft; CHN_LOCK(wrch); /* XXX abusive DMA update: chn_wrupdate(wrch); */ a->bytes = sndbuf_getfree(bs); a->fragments = a->bytes / sndbuf_getblksz(bs); a->fragstotal = sndbuf_getblkcnt(bs); a->fragsize = sndbuf_getblksz(bs); CHN_UNLOCK(wrch); } else ret = EINVAL; } break; case SNDCTL_DSP_GETIPTR: { count_info *a = (count_info *)arg; if (rdch) { struct snd_dbuf *bs = rdch->bufsoft; CHN_LOCK(rdch); /* XXX abusive DMA update: chn_rdupdate(rdch); */ a->bytes = sndbuf_gettotal(bs); a->blocks = sndbuf_getblocks(bs) - rdch->blocks; a->ptr = sndbuf_getfreeptr(bs); rdch->blocks = sndbuf_getblocks(bs); CHN_UNLOCK(rdch); } else ret = EINVAL; } break; case SNDCTL_DSP_GETOPTR: { count_info *a = (count_info *)arg; if (wrch) { struct snd_dbuf *bs = wrch->bufsoft; CHN_LOCK(wrch); /* XXX abusive DMA update: chn_wrupdate(wrch); */ a->bytes = sndbuf_gettotal(bs); a->blocks = sndbuf_getblocks(bs) - wrch->blocks; a->ptr = sndbuf_getreadyptr(bs); wrch->blocks = sndbuf_getblocks(bs); CHN_UNLOCK(wrch); } else ret = EINVAL; } break; case SNDCTL_DSP_GETCAPS: PCM_LOCK(d); *arg_i = PCM_CAP_REALTIME | PCM_CAP_MMAP | PCM_CAP_TRIGGER; if (rdch && wrch && !(dsp_get_flags(i_dev) & SD_F_SIMPLEX)) *arg_i |= PCM_CAP_DUPLEX; PCM_UNLOCK(d); break; case SOUND_PCM_READ_BITS: chn = wrch ? wrch : rdch; if (chn) { CHN_LOCK(chn); if (chn->format & AFMT_8BIT) *arg_i = 8; else if (chn->format & AFMT_16BIT) *arg_i = 16; else if (chn->format & AFMT_24BIT) *arg_i = 24; else if (chn->format & AFMT_32BIT) *arg_i = 32; else ret = EINVAL; CHN_UNLOCK(chn); } else { *arg_i = 0; ret = EINVAL; } break; case SNDCTL_DSP_SETTRIGGER: if (rdch) { CHN_LOCK(rdch); rdch->flags &= ~CHN_F_NOTRIGGER; if (*arg_i & PCM_ENABLE_INPUT) chn_start(rdch, 1); else { chn_abort(rdch); chn_resetbuf(rdch); rdch->flags |= CHN_F_NOTRIGGER; } CHN_UNLOCK(rdch); } if (wrch) { CHN_LOCK(wrch); wrch->flags &= ~CHN_F_NOTRIGGER; if (*arg_i & PCM_ENABLE_OUTPUT) chn_start(wrch, 1); else { chn_abort(wrch); chn_resetbuf(wrch); wrch->flags |= CHN_F_NOTRIGGER; } CHN_UNLOCK(wrch); } break; case SNDCTL_DSP_GETTRIGGER: *arg_i = 0; if (wrch) { CHN_LOCK(wrch); if (wrch->flags & CHN_F_TRIGGERED) *arg_i |= PCM_ENABLE_OUTPUT; CHN_UNLOCK(wrch); } if (rdch) { CHN_LOCK(rdch); if (rdch->flags & CHN_F_TRIGGERED) *arg_i |= PCM_ENABLE_INPUT; CHN_UNLOCK(rdch); } break; case SNDCTL_DSP_GETODELAY: if (wrch) { struct snd_dbuf *bs = wrch->bufsoft; CHN_LOCK(wrch); /* XXX abusive DMA update: chn_wrupdate(wrch); */ *arg_i = sndbuf_getready(bs); CHN_UNLOCK(wrch); } else ret = EINVAL; break; case SNDCTL_DSP_POST: if (wrch) { CHN_LOCK(wrch); wrch->flags &= ~CHN_F_NOTRIGGER; chn_start(wrch, 1); CHN_UNLOCK(wrch); } break; case SNDCTL_DSP_SETDUPLEX: /* * switch to full-duplex mode if card is in half-duplex * mode and is able to work in full-duplex mode */ PCM_LOCK(d); if (rdch && wrch && (dsp_get_flags(i_dev) & SD_F_SIMPLEX)) dsp_set_flags(i_dev, dsp_get_flags(i_dev)^SD_F_SIMPLEX); PCM_UNLOCK(d); break; /* * The following four ioctls are simple wrappers around mixer_ioctl * with no further processing. xcmd is short for "translated * command". */ case SNDCTL_DSP_GETRECVOL: if (xcmd == 0) { xcmd = SOUND_MIXER_READ_RECLEV; chn = rdch; } /* FALLTHROUGH */ case SNDCTL_DSP_SETRECVOL: if (xcmd == 0) { xcmd = SOUND_MIXER_WRITE_RECLEV; chn = rdch; } /* FALLTHROUGH */ case SNDCTL_DSP_GETPLAYVOL: if (xcmd == 0) { xcmd = SOUND_MIXER_READ_PCM; chn = wrch; } /* FALLTHROUGH */ case SNDCTL_DSP_SETPLAYVOL: if (xcmd == 0) { xcmd = SOUND_MIXER_WRITE_PCM; chn = wrch; } ret = dsp_ioctl_channel(i_dev, chn, xcmd, arg); if (ret != -1) { PCM_GIANT_EXIT(d); return (ret); } if (d->mixer_dev != NULL) { PCM_ACQUIRE_QUICK(d); ret = mixer_ioctl_cmd(d->mixer_dev, xcmd, arg, -1, MIXER_CMD_DIRECT); PCM_RELEASE_QUICK(d); } else ret = ENOTSUP; break; case SNDCTL_DSP_GET_RECSRC_NAMES: case SNDCTL_DSP_GET_RECSRC: case SNDCTL_DSP_SET_RECSRC: if (d->mixer_dev != NULL) { PCM_ACQUIRE_QUICK(d); ret = mixer_ioctl_cmd(d->mixer_dev, cmd, arg, -1, MIXER_CMD_DIRECT); PCM_RELEASE_QUICK(d); } else ret = ENOTSUP; break; /* * The following 3 ioctls aren't very useful at the moment. For * now, only a single channel is associated with a cdev (/dev/dspN * instance), so there's only a single output routing to use (i.e., * the wrch bound to this cdev). */ case SNDCTL_DSP_GET_PLAYTGT_NAMES: { oss_mixer_enuminfo *ei; ei = (oss_mixer_enuminfo *)arg; ei->dev = 0; ei->ctrl = 0; ei->version = 0; /* static for now */ ei->strindex[0] = 0; if (wrch != NULL) { ei->nvalues = 1; strlcpy(ei->strings, wrch->name, sizeof(ei->strings)); } else { ei->nvalues = 0; ei->strings[0] = '\0'; } } break; case SNDCTL_DSP_GET_PLAYTGT: case SNDCTL_DSP_SET_PLAYTGT: /* yes, they are the same for now */ /* * Re: SET_PLAYTGT * OSSv4: "The value that was accepted by the device will * be returned back in the variable pointed by the * argument." */ if (wrch != NULL) *arg_i = 0; else ret = EINVAL; break; case SNDCTL_DSP_SILENCE: /* * Flush the software (pre-feed) buffer, but try to minimize playback * interruption. (I.e., record unplayed samples with intent to * restore by SNDCTL_DSP_SKIP.) Intended for application "pause" * functionality. */ if (wrch == NULL) ret = EINVAL; else { struct snd_dbuf *bs; CHN_LOCK(wrch); while (wrch->inprog != 0) cv_wait(&wrch->cv, wrch->lock); bs = wrch->bufsoft; if ((bs->shadbuf != NULL) && (sndbuf_getready(bs) > 0)) { bs->sl = sndbuf_getready(bs); sndbuf_dispose(bs, bs->shadbuf, sndbuf_getready(bs)); sndbuf_fillsilence(bs); chn_start(wrch, 0); } CHN_UNLOCK(wrch); } break; case SNDCTL_DSP_SKIP: /* * OSSv4 docs: "This ioctl call discards all unplayed samples in the * playback buffer by moving the current write position immediately * before the point where the device is currently reading the samples." */ if (wrch == NULL) ret = EINVAL; else { struct snd_dbuf *bs; CHN_LOCK(wrch); while (wrch->inprog != 0) cv_wait(&wrch->cv, wrch->lock); bs = wrch->bufsoft; if ((bs->shadbuf != NULL) && (bs->sl > 0)) { sndbuf_softreset(bs); sndbuf_acquire(bs, bs->shadbuf, bs->sl); bs->sl = 0; chn_start(wrch, 0); } CHN_UNLOCK(wrch); } break; case SNDCTL_DSP_CURRENT_OPTR: case SNDCTL_DSP_CURRENT_IPTR: /** * @note Changing formats resets the buffer counters, which differs * from the 4Front drivers. However, I don't expect this to be * much of a problem. * * @note In a test where @c CURRENT_OPTR is called immediately after write * returns, this driver is about 32K samples behind whereas * 4Front's is about 8K samples behind. Should determine source * of discrepancy, even if only out of curiosity. * * @todo Actually test SNDCTL_DSP_CURRENT_IPTR. */ chn = (cmd == SNDCTL_DSP_CURRENT_OPTR) ? wrch : rdch; if (chn == NULL) ret = EINVAL; else { struct snd_dbuf *bs; /* int tmp; */ oss_count_t *oc = (oss_count_t *)arg; CHN_LOCK(chn); bs = chn->bufsoft; #if 0 tmp = (sndbuf_getsize(b) + chn_getptr(chn) - sndbuf_gethwptr(b)) % sndbuf_getsize(b); oc->samples = (sndbuf_gettotal(b) + tmp) / sndbuf_getalign(b); oc->fifo_samples = (sndbuf_getready(b) - tmp) / sndbuf_getalign(b); #else oc->samples = sndbuf_gettotal(bs) / sndbuf_getalign(bs); oc->fifo_samples = sndbuf_getready(bs) / sndbuf_getalign(bs); #endif CHN_UNLOCK(chn); } break; case SNDCTL_DSP_HALT_OUTPUT: case SNDCTL_DSP_HALT_INPUT: chn = (cmd == SNDCTL_DSP_HALT_OUTPUT) ? wrch : rdch; if (chn == NULL) ret = EINVAL; else { CHN_LOCK(chn); chn_abort(chn); CHN_UNLOCK(chn); } break; case SNDCTL_DSP_LOW_WATER: /* * Set the number of bytes required to attract attention by * select/poll. */ if (wrch != NULL) { CHN_LOCK(wrch); wrch->lw = (*arg_i > 1) ? *arg_i : 1; CHN_UNLOCK(wrch); } if (rdch != NULL) { CHN_LOCK(rdch); rdch->lw = (*arg_i > 1) ? *arg_i : 1; CHN_UNLOCK(rdch); } break; case SNDCTL_DSP_GETERROR: /* * OSSv4 docs: "All errors and counters will automatically be * cleared to zeroes after the call so each call will return only * the errors that occurred after the previous invocation. ... The * play_underruns and rec_overrun fields are the only useful fields * returned by OSS 4.0." */ { audio_errinfo *ei = (audio_errinfo *)arg; bzero((void *)ei, sizeof(*ei)); if (wrch != NULL) { CHN_LOCK(wrch); ei->play_underruns = wrch->xruns; wrch->xruns = 0; CHN_UNLOCK(wrch); } if (rdch != NULL) { CHN_LOCK(rdch); ei->rec_overruns = rdch->xruns; rdch->xruns = 0; CHN_UNLOCK(rdch); } } break; case SNDCTL_DSP_SYNCGROUP: PCM_ACQUIRE_QUICK(d); ret = dsp_oss_syncgroup(wrch, rdch, (oss_syncgroup *)arg); PCM_RELEASE_QUICK(d); break; case SNDCTL_DSP_SYNCSTART: PCM_ACQUIRE_QUICK(d); ret = dsp_oss_syncstart(*arg_i); PCM_RELEASE_QUICK(d); break; case SNDCTL_DSP_POLICY: PCM_ACQUIRE_QUICK(d); ret = dsp_oss_policy(wrch, rdch, *arg_i); PCM_RELEASE_QUICK(d); break; case SNDCTL_DSP_COOKEDMODE: PCM_ACQUIRE_QUICK(d); if (!(dsp_get_flags(i_dev) & SD_F_BITPERFECT)) ret = dsp_oss_cookedmode(wrch, rdch, *arg_i); PCM_RELEASE_QUICK(d); break; case SNDCTL_DSP_GET_CHNORDER: PCM_ACQUIRE_QUICK(d); ret = dsp_oss_getchnorder(wrch, rdch, (unsigned long long *)arg); PCM_RELEASE_QUICK(d); break; case SNDCTL_DSP_SET_CHNORDER: PCM_ACQUIRE_QUICK(d); ret = dsp_oss_setchnorder(wrch, rdch, (unsigned long long *)arg); PCM_RELEASE_QUICK(d); break; case SNDCTL_DSP_GETCHANNELMASK: /* XXX vlc */ PCM_ACQUIRE_QUICK(d); ret = dsp_oss_getchannelmask(wrch, rdch, (int *)arg); PCM_RELEASE_QUICK(d); break; case SNDCTL_DSP_BIND_CHANNEL: /* XXX what?!? */ ret = EINVAL; break; #ifdef OSSV4_EXPERIMENT /* * XXX The following ioctls are not yet supported and just return * EINVAL. */ case SNDCTL_DSP_GETOPEAKS: case SNDCTL_DSP_GETIPEAKS: chn = (cmd == SNDCTL_DSP_GETOPEAKS) ? wrch : rdch; if (chn == NULL) ret = EINVAL; else { oss_peaks_t *op = (oss_peaks_t *)arg; int lpeak, rpeak; CHN_LOCK(chn); ret = chn_getpeaks(chn, &lpeak, &rpeak); if (ret == -1) ret = EINVAL; else { (*op)[0] = lpeak; (*op)[1] = rpeak; } CHN_UNLOCK(chn); } break; /* * XXX Once implemented, revisit this for proper cv protection * (if necessary). */ case SNDCTL_GETLABEL: ret = dsp_oss_getlabel(wrch, rdch, (oss_label_t *)arg); break; case SNDCTL_SETLABEL: ret = dsp_oss_setlabel(wrch, rdch, (oss_label_t *)arg); break; case SNDCTL_GETSONG: ret = dsp_oss_getsong(wrch, rdch, (oss_longname_t *)arg); break; case SNDCTL_SETSONG: ret = dsp_oss_setsong(wrch, rdch, (oss_longname_t *)arg); break; case SNDCTL_SETNAME: ret = dsp_oss_setname(wrch, rdch, (oss_longname_t *)arg); break; #if 0 /** * @note The S/PDIF interface ioctls, @c SNDCTL_DSP_READCTL and * @c SNDCTL_DSP_WRITECTL have been omitted at the suggestion of * 4Front Technologies. */ case SNDCTL_DSP_READCTL: case SNDCTL_DSP_WRITECTL: ret = EINVAL; break; #endif /* !0 (explicitly omitted ioctls) */ #endif /* !OSSV4_EXPERIMENT */ case SNDCTL_DSP_MAPINBUF: case SNDCTL_DSP_MAPOUTBUF: case SNDCTL_DSP_SETSYNCRO: /* undocumented */ case SNDCTL_DSP_SUBDIVIDE: case SOUND_PCM_WRITE_FILTER: case SOUND_PCM_READ_FILTER: /* dunno what these do, don't sound important */ default: DEB(kprintf("default ioctl fn 0x%08lx fail\n", cmd)); ret = EINVAL; break; } PCM_GIANT_LEAVE(d); return (ret); } static struct filterops dsp_read_filtops = { FILTEROP_ISFD, NULL, dsp_filter_detach, dsp_filter_read }; static struct filterops dsp_write_filtops = { FILTEROP_ISFD, NULL, dsp_filter_detach, dsp_filter_write }; static int /*dsp_poll(struct cdev *i_dev, int events, struct thread *td)*/ dsp_kqfilter(struct dev_kqfilter_args *ap) { struct knote *kn = ap->a_kn; struct klist *klist; struct cdev *i_dev = ap->a_head.a_dev; struct snddev_info *d; struct pcm_channel *wrch, *rdch; struct snd_dbuf *bs = NULL; int ret; d = dsp_get_info(i_dev); if (!DSP_REGISTERED(d, i_dev)) return (EBADF); PCM_GIANT_ENTER(d); wrch = NULL; rdch = NULL; ret = 0; getchns(i_dev, &rdch, &wrch, SD_F_PRIO_RD | SD_F_PRIO_WR); switch (kn->kn_filter) { case EVFILT_READ: if (rdch) { kn->kn_fop = &dsp_read_filtops; kn->kn_hook = (caddr_t)rdch; bs = rdch->bufsoft; ap->a_result = 0; } break; case EVFILT_WRITE: if (wrch) { kn->kn_fop = &dsp_write_filtops; kn->kn_hook = (caddr_t)wrch; bs = wrch->bufsoft; ap->a_result = 0; } break; default: ap->a_result = EOPNOTSUPP; break; } if (ap->a_result == 0) { klist = &sndbuf_getkq(bs)->ki_note; knote_insert(klist, kn); } relchns(i_dev, rdch, wrch, SD_F_PRIO_RD | SD_F_PRIO_WR); PCM_GIANT_LEAVE(d); return (ret); } static void dsp_filter_detach(struct knote *kn) { struct pcm_channel *ch = (struct pcm_channel *)kn->kn_hook; struct snd_dbuf *bs = ch->bufsoft; struct klist *klist; CHN_LOCK(ch); klist = &sndbuf_getkq(bs)->ki_note; knote_remove(klist, kn); CHN_UNLOCK(ch); } static int dsp_filter_read(struct knote *kn, long hint) { struct pcm_channel *rdch = (struct pcm_channel *)kn->kn_hook; struct thread *td = curthread; int ready; CHN_LOCK(rdch); ready = chn_poll(rdch, 1, td); CHN_UNLOCK(rdch); return (ready); } static int dsp_filter_write(struct knote *kn, long hint) { struct pcm_channel *wrch = (struct pcm_channel *)kn->kn_hook; struct thread *td = curthread; int ready; CHN_LOCK(wrch); ready = chn_poll(wrch, 1, td); CHN_UNLOCK(wrch); return (ready); } static int dsp_mmap(struct dev_mmap_args *ap) { vm_offset_t offset = ap->a_offset; /* XXX memattr is not honored */ ap->a_result = vtophys(offset); return (0); } static int dsp_mmap_single(struct dev_mmap_single_args *ap) { struct cdev *i_dev = ap->a_head.a_dev; vm_ooffset_t *offset = ap->a_offset; vm_size_t size = ap->a_size; struct vm_object **object = ap->a_object; int nprot = ap->a_nprot; struct snddev_info *d; struct pcm_channel *wrch, *rdch, *c; /* * Reject PROT_EXEC by default. It just doesn't makes sense. * Unfortunately, we have to give up this one due to linux_mmap * changes. * * http://lists.freebsd.org/pipermail/freebsd-emulation/2007-June/003698.html * */ #ifdef SV_ABI_LINUX if ((nprot & PROT_EXEC) && (dsp_mmap_allow_prot_exec < 0 || (dsp_mmap_allow_prot_exec == 0 && SV_CURPROC_ABI() != SV_ABI_LINUX))) #else if ((nprot & PROT_EXEC) && dsp_mmap_allow_prot_exec < 1) #endif return (EINVAL); /* * PROT_READ (alone) selects the input buffer. * PROT_WRITE (alone) selects the output buffer. * PROT_WRITE|PROT_READ together select the output buffer. */ if ((nprot & (PROT_READ | PROT_WRITE)) == 0) return (EINVAL); d = dsp_get_info(i_dev); if (!DSP_REGISTERED(d, i_dev)) return (EINVAL); PCM_GIANT_ENTER(d); getchns(i_dev, &rdch, &wrch, SD_F_PRIO_RD | SD_F_PRIO_WR); c = ((nprot & PROT_WRITE) != 0) ? wrch : rdch; if (c == NULL || (c->flags & CHN_F_MMAP_INVALID) || (*offset + size) > sndbuf_getsize(c->bufsoft) || (wrch != NULL && (wrch->flags & CHN_F_MMAP_INVALID)) || (rdch != NULL && (rdch->flags & CHN_F_MMAP_INVALID))) { relchns(i_dev, rdch, wrch, SD_F_PRIO_RD | SD_F_PRIO_WR); PCM_GIANT_EXIT(d); return (EINVAL); } if (wrch != NULL) wrch->flags |= CHN_F_MMAP; if (rdch != NULL) rdch->flags |= CHN_F_MMAP; *offset = (uintptr_t)sndbuf_getbufofs(c->bufsoft, *offset); relchns(i_dev, rdch, wrch, SD_F_PRIO_RD | SD_F_PRIO_WR); *object = dev_pager_alloc(i_dev, size, nprot, *offset); PCM_GIANT_LEAVE(d); if (*object == NULL) return (EINVAL); return (0); } /* So much for dev_stdclone() */ static int dsp_stdclone(const char *name, char *namep, char *sep, int use_sep, int *u, int *c) { size_t len; len = strlen(namep); if (bcmp(name, namep, len) != 0) return (ENODEV); name += len; if (isdigit(*name) == 0) return (ENODEV); len = strlen(sep); if (*name == '0' && !(name[1] == '\0' || bcmp(name + 1, sep, len) == 0)) return (ENODEV); for (*u = 0; isdigit(*name) != 0; name++) { *u *= 10; *u += *name - '0'; if (*u > dsp_umax) return (ENODEV); } if (*name == '\0') return ((use_sep == 0) ? 0 : ENODEV); if (bcmp(name, sep, len) != 0 || isdigit(name[len]) == 0) return (ENODEV); name += len; if (*name == '0' && name[1] != '\0') return (ENODEV); for (*c = 0; isdigit(*name) != 0; name++) { *c *= 10; *c += *name - '0'; if (*c > dsp_cmax) return (ENODEV); } if (*name != '\0') return (ENODEV); return (0); } /* * for i = 0 to channels of device N * if dspN.i isn't busy and in the right dir, create a dev_t and return it */ int dsp_clone(struct dev_clone_args *ap) { struct cdev *i_dev = ap->a_head.a_dev; const char *name = ap->a_name; struct snddev_info *d; struct snd_clone_entry *ce; struct pcm_channel *c; int i, unit, udcmask, cunit, devtype, devhw, devcmax, tumax; char *devname, *devcmp, *devsep; int err = EBUSY; static struct cdev *dev; KASSERT(dsp_umax >= 0 && dsp_cmax >= 0, ("Uninitialized unit!")); d = dsp_get_info(i_dev); if (d != NULL) { return (ENODEV); } unit = -1; cunit = -1; devtype = -1; devhw = 0; devcmax = -1; tumax = -1; devname = NULL; devsep = NULL; for (i = 0; unit == -1 && i < (sizeof(dsp_cdevs) / sizeof(dsp_cdevs[0])); i++) { devtype = dsp_cdevs[i].type; devcmp = dsp_cdevs[i].name; devsep = dsp_cdevs[i].sep; devname = dsp_cdevs[i].alias; if (devname == NULL) devname = devcmp; devhw = dsp_cdevs[i].hw; devcmax = dsp_cdevs[i].max - 1; if (strcmp(name, devcmp) == 0) unit = snd_unit; else if (dsp_stdclone(name, devcmp, devsep, dsp_cdevs[i].use_sep, &unit, &cunit) != 0) { unit = -1; cunit = -1; } } d = devclass_get_softc(pcm_devclass, unit); if (!PCM_REGISTERED(d) || d->clones == NULL) { return (ENODEV); } /* XXX Need Giant magic entry ??? */ PCM_LOCK(d); if (snd_clone_disabled(d->clones)) { PCM_UNLOCK(d); return (ENODEV); } PCM_WAIT(d); PCM_ACQUIRE(d); PCM_UNLOCK(d); udcmask = snd_u2unit(unit) | snd_d2unit(devtype); if (devhw != 0) { KASSERT(devcmax <= dsp_cmax, ("overflow: devcmax=%d, dsp_cmax=%d", devcmax, dsp_cmax)); if (cunit > devcmax) { PCM_RELEASE_QUICK(d); return (ENODEV); } udcmask |= snd_c2unit(cunit); CHN_FOREACH(c, d, channels.pcm) { CHN_LOCK(c); if (c->unit != udcmask) { CHN_UNLOCK(c); continue; } CHN_UNLOCK(c); udcmask &= ~snd_c2unit(cunit); /* * Temporarily increase clone maxunit to overcome * vchan flexibility. * * # sysctl dev.pcm.0.play.vchans=256 * dev.pcm.0.play.vchans: 1 -> 256 * # cat /dev/zero > /dev/dsp0.vp255 & * [1] 17296 * # sysctl dev.pcm.0.play.vchans=0 * dev.pcm.0.play.vchans: 256 -> 1 * # fg * [1] + running cat /dev/zero > /dev/dsp0.vp255 * ^C * # cat /dev/zero > /dev/dsp0.vp255 * zsh: operation not supported: /dev/dsp0.vp255 */ tumax = snd_clone_getmaxunit(d->clones); if (cunit > tumax) snd_clone_setmaxunit(d->clones, cunit); else tumax = -1; goto dsp_clone_alloc; } /* * Ok, so we're requesting unallocated vchan, but still * within maximum vchan limit. */ if (((devtype == SND_DEV_DSPHW_VPLAY && d->pvchancount > 0) || (devtype == SND_DEV_DSPHW_VREC && d->rvchancount > 0)) && cunit < snd_maxautovchans) { udcmask &= ~snd_c2unit(cunit); tumax = snd_clone_getmaxunit(d->clones); if (cunit > tumax) snd_clone_setmaxunit(d->clones, cunit); else tumax = -1; goto dsp_clone_alloc; } PCM_RELEASE_QUICK(d); return (err); } dsp_clone_alloc: ce = snd_clone_alloc(d->clones, &dev, &cunit, udcmask); if (tumax != -1) snd_clone_setmaxunit(d->clones, tumax); if (ce != NULL) { udcmask |= snd_c2unit(cunit); dev = make_only_dev(&dsp_ops, PCMMINOR(udcmask), UID_ROOT, GID_WHEEL, 0666, "%s%d%s%d", devname, unit, devsep, cunit); snd_clone_register(ce, dev); err = 0; } PCM_RELEASE_QUICK(d); #if 0 if (*dev != NULL) dev_ref(*dev); #endif return (err); } static void dsp_sysinit(void *p) { if (dsp_ehtag != NULL) return; /* initialize unit numbering */ snd_unit_init(); dsp_umax = PCMMAXUNIT; dsp_cmax = PCMMAXCHAN; dsp_ehtag = EVENTHANDLER_REGISTER(dev_clone, dsp_clone, 0, 1000); } static void dsp_sysuninit(void *p) { if (dsp_ehtag == NULL) return; EVENTHANDLER_DEREGISTER(dev_clone, dsp_ehtag); dsp_ehtag = NULL; } SYSINIT(dsp_sysinit, SI_SUB_DRIVERS, SI_ORDER_MIDDLE, dsp_sysinit, NULL); SYSUNINIT(dsp_sysuninit, SI_SUB_DRIVERS, SI_ORDER_MIDDLE, dsp_sysuninit, NULL); char * dsp_unit2name(char *buf, size_t len, int unit) { int i, dtype; KASSERT(buf != NULL && len != 0, ("bogus buf=%p len=%ju", buf, (uintmax_t)len)); dtype = snd_unit2d(unit); for (i = 0; i < (sizeof(dsp_cdevs) / sizeof(dsp_cdevs[0])); i++) { if (dtype != dsp_cdevs[i].type || dsp_cdevs[i].alias != NULL) continue; ksnprintf(buf, len, "%s%d%s%d", dsp_cdevs[i].name, snd_unit2u(unit), dsp_cdevs[i].sep, snd_unit2c(unit)); return (buf); } return (NULL); } /** * @brief Handler for SNDCTL_AUDIOINFO. * * Gathers information about the audio device specified in ai->dev. If * ai->dev == -1, then this function gathers information about the current * device. If the call comes in on a non-audio device and ai->dev == -1, * return EINVAL. * * This routine is supposed to go practically straight to the hardware, * getting capabilities directly from the sound card driver, side-stepping * the intermediate channel interface. * * Note, however, that the usefulness of this command is significantly * decreased when requesting info about any device other than the one serving * the request. While each snddev_channel refers to a specific device node, * the converse is *not* true. Currently, when a sound device node is opened, * the sound subsystem scans for an available audio channel (or channels, if * opened in read+write) and then assigns them to the si_drv[12] private * data fields. As a result, any information returned linking a channel to * a specific character device isn't necessarily accurate. * * @note * Calling threads must not hold any snddev_info or pcm_channel locks. * * @param dev device on which the ioctl was issued * @param ai ioctl request data container * * @retval 0 success * @retval EINVAL ai->dev specifies an invalid device * * @todo Verify correctness of Doxygen tags. ;) */ int dsp_oss_audioinfo(struct cdev *i_dev, oss_audioinfo *ai) { struct pcmchan_caps *caps; struct pcm_channel *ch; struct snddev_info *d; uint32_t fmts; int i, nchan, *rates, minch, maxch; char *devname, buf[CHN_NAMELEN]; /* * If probing the device that received the ioctl, make sure it's a * DSP device. (Users may use this ioctl with /dev/mixer and * /dev/midi.) */ if (ai->dev == -1 && i_dev->si_ops != &dsp_ops) return (EINVAL); ch = NULL; devname = NULL; nchan = 0; bzero(buf, sizeof(buf)); /* * Search for the requested audio device (channel). Start by * iterating over pcm devices. */ for (i = 0; pcm_devclass != NULL && i < devclass_get_maxunit(pcm_devclass); i++) { d = devclass_get_softc(pcm_devclass, i); if (!PCM_REGISTERED(d)) continue; /* XXX Need Giant magic entry ??? */ /* See the note in function docblock */ PCM_UNLOCKASSERT(d); PCM_LOCK(d); CHN_FOREACH(ch, d, channels.pcm) { CHN_UNLOCKASSERT(ch); CHN_LOCK(ch); if (ai->dev == -1) { if (DSP_REGISTERED(d, i_dev) && (ch == PCM_RDCH(i_dev) || /* record ch */ ch == PCM_WRCH(i_dev))) { /* playback ch */ devname = dsp_unit2name(buf, sizeof(buf), ch->unit); } } else if (ai->dev == nchan) { devname = dsp_unit2name(buf, sizeof(buf), ch->unit); } if (devname != NULL) break; CHN_UNLOCK(ch); ++nchan; } if (devname != NULL) { /* * At this point, the following synchronization stuff * has happened: * - a specific PCM device is locked. * - a specific audio channel has been locked, so be * sure to unlock when exiting; */ caps = chn_getcaps(ch); /* * With all handles collected, zero out the user's * container and begin filling in its fields. */ bzero((void *)ai, sizeof(oss_audioinfo)); ai->dev = nchan; strlcpy(ai->name, ch->name, sizeof(ai->name)); if ((ch->flags & CHN_F_BUSY) == 0) ai->busy = 0; else ai->busy = (ch->direction == PCMDIR_PLAY) ? OPEN_WRITE : OPEN_READ; /** * @note * @c cmd - OSSv4 docs: "Only supported under Linux at * this moment." Cop-out, I know, but I'll save * running around in the process table for later. * Is there a risk of leaking information? */ ai->pid = ch->pid; /* * These flags stolen from SNDCTL_DSP_GETCAPS handler. * Note, however, that a single channel operates in * only one direction, so PCM_CAP_DUPLEX is out. */ /** * @todo @c SNDCTL_AUDIOINFO::caps - Make drivers keep * these in pcmchan::caps? */ ai->caps = PCM_CAP_REALTIME | PCM_CAP_MMAP | PCM_CAP_TRIGGER | ((ch->direction == PCMDIR_PLAY) ? PCM_CAP_OUTPUT : PCM_CAP_INPUT); /* * Collect formats supported @b natively by the * device. Also determine min/max channels. (I.e., * mono, stereo, or both?) * * If any channel is stereo, maxch = 2; * if all channels are stereo, minch = 2, too; * if any channel is mono, minch = 1; * and if all channels are mono, maxch = 1. */ minch = 0; maxch = 0; fmts = 0; for (i = 0; caps->fmtlist[i]; i++) { fmts |= caps->fmtlist[i]; if (AFMT_CHANNEL(caps->fmtlist[i]) > 1) { minch = (minch == 0) ? 2 : minch; maxch = 2; } else { minch = 1; maxch = (maxch == 0) ? 1 : maxch; } } if (ch->direction == PCMDIR_PLAY) ai->oformats = fmts; else ai->iformats = fmts; /** * @note * @c magic - OSSv4 docs: "Reserved for internal use * by OSS." * * @par * @c card_number - OSSv4 docs: "Number of the sound * card where this device belongs or -1 if this * information is not available. Applications * should normally not use this field for any * purpose." */ ai->card_number = -1; /** * @todo @c song_name - depends first on * SNDCTL_[GS]ETSONG @todo @c label - depends * on SNDCTL_[GS]ETLABEL * @todo @c port_number - routing information? */ ai->port_number = -1; ai->mixer_dev = (d->mixer_dev != NULL) ? PCMUNIT(d->mixer_dev) : -1; /** * @note * @c real_device - OSSv4 docs: "Obsolete." */ ai->real_device = -1; strlcpy(ai->devnode, "/dev/", sizeof(ai->devnode)); strlcat(ai->devnode, devname, sizeof(ai->devnode)); ai->enabled = device_is_attached(d->dev) ? 1 : 0; /** * @note * @c flags - OSSv4 docs: "Reserved for future use." * * @note * @c binding - OSSv4 docs: "Reserved for future use." * * @todo @c handle - haven't decided how to generate * this yet; bus, vendor, device IDs? */ ai->min_rate = caps->minspeed; ai->max_rate = caps->maxspeed; ai->min_channels = minch; ai->max_channels = maxch; ai->nrates = chn_getrates(ch, &rates); if (ai->nrates > OSS_MAX_SAMPLE_RATES) ai->nrates = OSS_MAX_SAMPLE_RATES; for (i = 0; i < ai->nrates; i++) ai->rates[i] = rates[i]; ai->next_play_engine = 0; ai->next_rec_engine = 0; CHN_UNLOCK(ch); } PCM_UNLOCK(d); if (devname != NULL) return (0); } /* Exhausted the search -- nothing is locked, so return. */ return (EINVAL); } /** * @brief Assigns a PCM channel to a sync group. * * Sync groups are used to enable audio operations on multiple devices * simultaneously. They may be used with any number of devices and may * span across applications. Devices are added to groups with * the SNDCTL_DSP_SYNCGROUP ioctl, and operations are triggered with the * SNDCTL_DSP_SYNCSTART ioctl. * * If the @c id field of the @c group parameter is set to zero, then a new * sync group is created. Otherwise, wrch and rdch (if set) are added to * the group specified. * * @todo As far as memory allocation, should we assume that things are * okay and allocate with M_WAITOK before acquiring channel locks, * freeing later if not? * * @param wrch output channel associated w/ device (if any) * @param rdch input channel associated w/ device (if any) * @param group Sync group parameters * * @retval 0 success * @retval non-zero error to be propagated upstream */ static int dsp_oss_syncgroup(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_syncgroup *group) { struct pcmchan_syncmember *smrd, *smwr; struct pcmchan_syncgroup *sg; int ret, sg_ids[3]; smrd = NULL; smwr = NULL; sg = NULL; ret = 0; /* * Free_unr() may sleep, so store released syncgroup IDs until after * all locks are released. */ sg_ids[0] = sg_ids[1] = sg_ids[2] = 0; PCM_SG_LOCK(); /* * - Insert channel(s) into group's member list. * - Set CHN_F_NOTRIGGER on channel(s). * - Stop channel(s). */ /* * If device's channels are already mapped to a group, unmap them. */ if (wrch) { CHN_LOCK(wrch); sg_ids[0] = chn_syncdestroy(wrch); } if (rdch) { CHN_LOCK(rdch); sg_ids[1] = chn_syncdestroy(rdch); } /* * Verify that mode matches character device properites. * - Bail if PCM_ENABLE_OUTPUT && wrch == NULL. * - Bail if PCM_ENABLE_INPUT && rdch == NULL. */ if (((wrch == NULL) && (group->mode & PCM_ENABLE_OUTPUT)) || ((rdch == NULL) && (group->mode & PCM_ENABLE_INPUT))) { ret = EINVAL; goto out; } /* * An id of zero indicates the user wants to create a new * syncgroup. */ if (group->id == 0) { sg = (struct pcmchan_syncgroup *)kmalloc(sizeof(*sg), M_DEVBUF, M_NOWAIT); if (sg != NULL) { SLIST_INIT(&sg->members); sg->id = alloc_unr(pcmsg_unrhdr); group->id = sg->id; SLIST_INSERT_HEAD(&snd_pcm_syncgroups, sg, link); } else ret = ENOMEM; } else { SLIST_FOREACH(sg, &snd_pcm_syncgroups, link) { if (sg->id == group->id) break; } if (sg == NULL) ret = EINVAL; } /* Couldn't create or find a syncgroup. Fail. */ if (sg == NULL) goto out; /* * Allocate a syncmember, assign it and a channel together, and * insert into syncgroup. */ if (group->mode & PCM_ENABLE_INPUT) { smrd = (struct pcmchan_syncmember *)kmalloc(sizeof(*smrd), M_DEVBUF, M_NOWAIT); if (smrd == NULL) { ret = ENOMEM; goto out; } SLIST_INSERT_HEAD(&sg->members, smrd, link); smrd->parent = sg; smrd->ch = rdch; chn_abort(rdch); rdch->flags |= CHN_F_NOTRIGGER; rdch->sm = smrd; } if (group->mode & PCM_ENABLE_OUTPUT) { smwr = (struct pcmchan_syncmember *)kmalloc(sizeof(*smwr), M_DEVBUF, M_NOWAIT); if (smwr == NULL) { ret = ENOMEM; goto out; } SLIST_INSERT_HEAD(&sg->members, smwr, link); smwr->parent = sg; smwr->ch = wrch; chn_abort(wrch); wrch->flags |= CHN_F_NOTRIGGER; wrch->sm = smwr; } out: if (ret != 0) { if (smrd != NULL) kfree(smrd, M_DEVBUF); if ((sg != NULL) && SLIST_EMPTY(&sg->members)) { sg_ids[2] = sg->id; SLIST_REMOVE(&snd_pcm_syncgroups, sg, pcmchan_syncgroup, link); kfree(sg, M_DEVBUF); } if (wrch) wrch->sm = NULL; if (rdch) rdch->sm = NULL; } if (wrch) CHN_UNLOCK(wrch); if (rdch) CHN_UNLOCK(rdch); PCM_SG_UNLOCK(); if (sg_ids[0]) free_unr(pcmsg_unrhdr, sg_ids[0]); if (sg_ids[1]) free_unr(pcmsg_unrhdr, sg_ids[1]); if (sg_ids[2]) free_unr(pcmsg_unrhdr, sg_ids[2]); return (ret); } /** * @brief Launch a sync group into action * * Sync groups are established via SNDCTL_DSP_SYNCGROUP. This function * iterates over all members, triggering them along the way. * * @note Caller must not hold any channel locks. * * @param sg_id sync group identifier * * @retval 0 success * @retval non-zero error worthy of propagating upstream to user */ static int dsp_oss_syncstart(int sg_id) { struct pcmchan_syncmember *sm, *sm_tmp; struct pcmchan_syncgroup *sg; struct pcm_channel *c; int ret, needlocks; /* Get the synclists lock */ PCM_SG_LOCK(); do { ret = 0; needlocks = 0; /* Search for syncgroup by ID */ SLIST_FOREACH(sg, &snd_pcm_syncgroups, link) { if (sg->id == sg_id) break; } /* Return EINVAL if not found */ if (sg == NULL) { ret = EINVAL; break; } /* Any removals resulting in an empty group should've handled this */ KASSERT(!SLIST_EMPTY(&sg->members), ("found empty syncgroup")); /* * Attempt to lock all member channels - if any are already * locked, unlock those acquired, sleep for a bit, and try * again. */ SLIST_FOREACH(sm, &sg->members, link) { if (CHN_TRYLOCK(sm->ch) == 0) { int timo = hz * 5/1000; if (timo < 1) timo = 1; /* Release all locked channels so far, retry */ SLIST_FOREACH(sm_tmp, &sg->members, link) { /* sm is the member already locked */ if (sm == sm_tmp) break; CHN_UNLOCK(sm_tmp->ch); } /** @todo Is PRIBIO correct/ */ ret = lksleep(sm, &snd_pcm_syncgroups_mtx, PCATCH, "pcmsg", timo); if (ret == EINTR || ret == ERESTART) break; needlocks = 1; ret = 0; /* Assumes ret == EAGAIN... */ } } } while (needlocks && ret == 0); /* Proceed only if no errors encountered. */ if (ret == 0) { /* Launch channels */ while ((sm = SLIST_FIRST(&sg->members)) != NULL) { SLIST_REMOVE_HEAD(&sg->members, link); c = sm->ch; c->sm = NULL; chn_start(c, 1); c->flags &= ~CHN_F_NOTRIGGER; CHN_UNLOCK(c); kfree(sm, M_DEVBUF); } SLIST_REMOVE(&snd_pcm_syncgroups, sg, pcmchan_syncgroup, link); kfree(sg, M_DEVBUF); } PCM_SG_UNLOCK(); /* * Free_unr() may sleep, so be sure to give up the syncgroup lock * first. */ if (ret == 0) free_unr(pcmsg_unrhdr, sg_id); return (ret); } /** * @brief Handler for SNDCTL_DSP_POLICY * * The SNDCTL_DSP_POLICY ioctl is a simpler interface to control fragment * size and count like with SNDCTL_DSP_SETFRAGMENT. Instead of the user * specifying those two parameters, s/he simply selects a number from 0..10 * which corresponds to a buffer size. Smaller numbers request smaller * buffers with lower latencies (at greater overhead from more frequent * interrupts), while greater numbers behave in the opposite manner. * * The 4Front spec states that a value of 5 should be the default. However, * this implementation deviates slightly by using a linear scale without * consulting drivers. I.e., even though drivers may have different default * buffer sizes, a policy argument of 5 will have the same result across * all drivers. * * See http://manuals.opensound.com/developer/SNDCTL_DSP_POLICY.html for * more information. * * @todo When SNDCTL_DSP_COOKEDMODE is supported, it'll be necessary to * work with hardware drivers directly. * * @note PCM channel arguments must not be locked by caller. * * @param wrch Pointer to opened playback channel (optional; may be NULL) * @param rdch " recording channel (optional; may be NULL) * @param policy Integer from [0:10] * * @retval 0 constant (for now) */ static int dsp_oss_policy(struct pcm_channel *wrch, struct pcm_channel *rdch, int policy) { int ret; if (policy < CHN_POLICY_MIN || policy > CHN_POLICY_MAX) return (EIO); /* Default: success */ ret = 0; if (rdch) { CHN_LOCK(rdch); ret = chn_setlatency(rdch, policy); CHN_UNLOCK(rdch); } if (wrch && ret == 0) { CHN_LOCK(wrch); ret = chn_setlatency(wrch, policy); CHN_UNLOCK(wrch); } if (ret) ret = EIO; return (ret); } /** * @brief Enable or disable "cooked" mode * * This is a handler for @c SNDCTL_DSP_COOKEDMODE. When in cooked mode, which * is the default, the sound system handles rate and format conversions * automatically (ex: user writing 11025Hz/8 bit/unsigned but card only * operates with 44100Hz/16bit/signed samples). * * Disabling cooked mode is intended for applications wanting to mmap() * a sound card's buffer space directly, bypassing the FreeBSD 2-stage * feeder architecture, presumably to gain as much control over audio * hardware as possible. * * See @c http://manuals.opensound.com/developer/SNDCTL_DSP_COOKEDMODE.html * for more details. * * @param wrch playback channel (optional; may be NULL) * @param rdch recording channel (optional; may be NULL) * @param enabled 0 = raw mode, 1 = cooked mode * * @retval EINVAL Operation not yet supported. */ static int dsp_oss_cookedmode(struct pcm_channel *wrch, struct pcm_channel *rdch, int enabled) { /* * XXX I just don't get it. Why don't they call it * "BITPERFECT" ~ SNDCTL_DSP_BITPERFECT !?!?. * This is just plain so confusing, incoherent, * . */ if (!(enabled == 1 || enabled == 0)) return (EINVAL); /* * I won't give in. I'm inverting its logic here and now. * Brag all you want, but "BITPERFECT" should be the better * term here. */ enabled ^= 0x00000001; if (wrch != NULL) { CHN_LOCK(wrch); wrch->flags &= ~CHN_F_BITPERFECT; wrch->flags |= (enabled != 0) ? CHN_F_BITPERFECT : 0x00000000; CHN_UNLOCK(wrch); } if (rdch != NULL) { CHN_LOCK(rdch); rdch->flags &= ~CHN_F_BITPERFECT; rdch->flags |= (enabled != 0) ? CHN_F_BITPERFECT : 0x00000000; CHN_UNLOCK(rdch); } return (0); } /** * @brief Retrieve channel interleaving order * * This is the handler for @c SNDCTL_DSP_GET_CHNORDER. * * See @c http://manuals.opensound.com/developer/SNDCTL_DSP_GET_CHNORDER.html * for more details. * * @note As the ioctl definition is still under construction, FreeBSD * does not currently support SNDCTL_DSP_GET_CHNORDER. * * @param wrch playback channel (optional; may be NULL) * @param rdch recording channel (optional; may be NULL) * @param map channel map (result will be stored there) * * @retval EINVAL Operation not yet supported. */ static int dsp_oss_getchnorder(struct pcm_channel *wrch, struct pcm_channel *rdch, unsigned long long *map) { struct pcm_channel *ch; int ret; ch = (wrch != NULL) ? wrch : rdch; if (ch != NULL) { CHN_LOCK(ch); ret = chn_oss_getorder(ch, map); CHN_UNLOCK(ch); } else ret = EINVAL; return (ret); } /** * @brief Specify channel interleaving order * * This is the handler for @c SNDCTL_DSP_SET_CHNORDER. * * @note As the ioctl definition is still under construction, FreeBSD * does not currently support @c SNDCTL_DSP_SET_CHNORDER. * * @param wrch playback channel (optional; may be NULL) * @param rdch recording channel (optional; may be NULL) * @param map channel map * * @retval EINVAL Operation not yet supported. */ static int dsp_oss_setchnorder(struct pcm_channel *wrch, struct pcm_channel *rdch, unsigned long long *map) { int ret; ret = 0; if (wrch != NULL) { CHN_LOCK(wrch); ret = chn_oss_setorder(wrch, map); CHN_UNLOCK(wrch); } if (ret == 0 && rdch != NULL) { CHN_LOCK(rdch); ret = chn_oss_setorder(rdch, map); CHN_UNLOCK(rdch); } return (ret); } static int dsp_oss_getchannelmask(struct pcm_channel *wrch, struct pcm_channel *rdch, int *mask) { struct pcm_channel *ch; uint32_t chnmask; int ret; chnmask = 0; ch = (wrch != NULL) ? wrch : rdch; if (ch != NULL) { CHN_LOCK(ch); ret = chn_oss_getmask(ch, &chnmask); CHN_UNLOCK(ch); } else ret = EINVAL; if (ret == 0) *mask = chnmask; return (ret); } #ifdef OSSV4_EXPERIMENT /** * @brief Retrieve an audio device's label * * This is a handler for the @c SNDCTL_GETLABEL ioctl. * * See @c http://manuals.opensound.com/developer/SNDCTL_GETLABEL.html * for more details. * * From Hannu@4Front: "For example ossxmix (just like some HW mixer * consoles) can show variable "labels" for certain controls. By default * the application name (say quake) is shown as the label but * applications may change the labels themselves." * * @note As the ioctl definition is still under construction, FreeBSD * does not currently support @c SNDCTL_GETLABEL. * * @param wrch playback channel (optional; may be NULL) * @param rdch recording channel (optional; may be NULL) * @param label label gets copied here * * @retval EINVAL Operation not yet supported. */ static int dsp_oss_getlabel(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_label_t *label) { return (EINVAL); } /** * @brief Specify an audio device's label * * This is a handler for the @c SNDCTL_SETLABEL ioctl. Please see the * comments for @c dsp_oss_getlabel immediately above. * * See @c http://manuals.opensound.com/developer/SNDCTL_GETLABEL.html * for more details. * * @note As the ioctl definition is still under construction, FreeBSD * does not currently support SNDCTL_SETLABEL. * * @param wrch playback channel (optional; may be NULL) * @param rdch recording channel (optional; may be NULL) * @param label label gets copied from here * * @retval EINVAL Operation not yet supported. */ static int dsp_oss_setlabel(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_label_t *label) { return (EINVAL); } /** * @brief Retrieve name of currently played song * * This is a handler for the @c SNDCTL_GETSONG ioctl. Audio players could * tell the system the name of the currently playing song, which would be * visible in @c /dev/sndstat. * * See @c http://manuals.opensound.com/developer/SNDCTL_GETSONG.html * for more details. * * @note As the ioctl definition is still under construction, FreeBSD * does not currently support SNDCTL_GETSONG. * * @param wrch playback channel (optional; may be NULL) * @param rdch recording channel (optional; may be NULL) * @param song song name gets copied here * * @retval EINVAL Operation not yet supported. */ static int dsp_oss_getsong(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_longname_t *song) { return (EINVAL); } /** * @brief Retrieve name of currently played song * * This is a handler for the @c SNDCTL_SETSONG ioctl. Audio players could * tell the system the name of the currently playing song, which would be * visible in @c /dev/sndstat. * * See @c http://manuals.opensound.com/developer/SNDCTL_SETSONG.html * for more details. * * @note As the ioctl definition is still under construction, FreeBSD * does not currently support SNDCTL_SETSONG. * * @param wrch playback channel (optional; may be NULL) * @param rdch recording channel (optional; may be NULL) * @param song song name gets copied from here * * @retval EINVAL Operation not yet supported. */ static int dsp_oss_setsong(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_longname_t *song) { return (EINVAL); } /** * @brief Rename a device * * This is a handler for the @c SNDCTL_SETNAME ioctl. * * See @c http://manuals.opensound.com/developer/SNDCTL_SETNAME.html for * more details. * * From Hannu@4Front: "This call is used to change the device name * reported in /dev/sndstat and ossinfo. So instead of using some generic * 'OSS loopback audio (MIDI) driver' the device may be given a meaningfull * name depending on the current context (for example 'OSS virtual wave table * synth' or 'VoIP link to London')." * * @note As the ioctl definition is still under construction, FreeBSD * does not currently support SNDCTL_SETNAME. * * @param wrch playback channel (optional; may be NULL) * @param rdch recording channel (optional; may be NULL) * @param name new device name gets copied from here * * @retval EINVAL Operation not yet supported. */ static int dsp_oss_setname(struct pcm_channel *wrch, struct pcm_channel *rdch, oss_longname_t *name) { return (EINVAL); } #endif /* !OSSV4_EXPERIMENT */