/* $OpenBSD: dev.c,v 1.13 2008/11/09 16:26:07 ratchov Exp $ */ /* * Copyright (c) 2008 Alexandre Ratchov * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include "dev.h" #include "abuf.h" #include "aproc.h" #include "pipe.h" #include "conf.h" #include "safile.h" unsigned dev_bufsz, dev_round, dev_rate; unsigned dev_rate_div, dev_round_div; struct aparams dev_ipar, dev_opar; struct aproc *dev_mix, *dev_sub, *dev_rec, *dev_play; struct file *dev_file; /* * supported rates */ #define NRATES (sizeof(dev_rates) / sizeof(dev_rates[0])) unsigned dev_rates[] = { 6400, 7200, 8000, 9600, 11025, 12000, 12800, 14400, 16000, 19200, 22050, 24000, 25600, 28800, 32000, 38400, 44100, 48000, 51200, 57600, 64000, 76800, 88200, 96000, 102400, 115200, 128000, 153600, 176400, 192000 }; /* * factors of supported rates */ #define NPRIMES (sizeof(dev_primes) / sizeof(dev_primes[0])) unsigned dev_primes[] = {2, 3, 5, 7}; int dev_setrate(unsigned rate) { unsigned i, r, p; r = 1000 * rate; for (i = 0; i < NRATES; i++) { if (i == NRATES) { fprintf(stderr, "dev_setrate: %u, unsupported\n", rate); return 0; } if (r > 996 * dev_rates[i] && r < 1004 * dev_rates[i]) { dev_rate = dev_rates[i]; break; } } dev_rate_div = dev_rate; dev_round_div = dev_round; for (i = 0; i < NPRIMES; i++) { p = dev_primes[i]; while (dev_rate_div % p == 0 && dev_round_div % p == 0) { dev_rate_div /= p; dev_round_div /= p; } } return 1; } void dev_roundrate(unsigned *newrate, unsigned *newround) { *newrate += dev_rate_div - 1; *newrate -= *newrate % dev_rate_div; *newround = *newrate * dev_round_div / dev_rate_div; } /* * open the device with the given hardware parameters and create a mixer * and a multiplexer connected to it with all necessary conversions * setup */ void dev_init(char *devpath, struct aparams *dipar, struct aparams *dopar, unsigned bufsz, int blkio) { struct aparams ipar, opar; struct aproc *conv; struct abuf *buf; unsigned nfr, ibufsz, obufsz; /* * ask for 1/4 of the buffer for the kernel ring and * limit the block size to 1/4 of the requested buffer */ dev_bufsz = (bufsz + 3) / 4; dev_round = (bufsz + 3) / 4; dev_file = (struct file *)safile_new(&safile_ops, devpath, dipar, dopar, &dev_bufsz, &dev_round, blkio); if (!dev_file) exit(1); if (!dev_setrate(dipar ? dipar->rate : dopar->rate)) exit(1); if (dipar) { dipar->rate = dev_rate; if (debug_level > 0) { fprintf(stderr, "dev_init: hw recording "); aparams_print(dipar); fprintf(stderr, "\n"); } } if (dopar) { dopar->rate = dev_rate; if (debug_level > 0) { fprintf(stderr, "dev_init: hw playing "); aparams_print(dopar); fprintf(stderr, "\n"); } } ibufsz = obufsz = dev_bufsz; bufsz = (bufsz > dev_bufsz) ? bufsz - dev_bufsz : 0; /* * use 1/8 of the buffer for the mixer/converters. Since we * already consumed 1/4 for the device, bufsz represents the * remaining 3/4. So 1/8 is 1/6 of 3/4 */ nfr = (bufsz + 5) / 6; nfr += dev_round - 1; nfr -= nfr % dev_round; if (nfr == 0) nfr = dev_round; /* * create record chain */ if (dipar) { aparams_init(&ipar, dipar->cmin, dipar->cmax, dipar->rate); /* * create the read end */ dev_rec = rpipe_new(dev_file); buf = abuf_new(nfr, dipar); aproc_setout(dev_rec, buf); ibufsz += nfr; /* * append a converter, if needed */ if (!aparams_eqenc(dipar, &ipar)) { conv = dec_new("subin", dipar); aproc_setin(conv, buf); buf = abuf_new(nfr, &ipar); aproc_setout(conv, buf); ibufsz += nfr; } dev_ipar = ipar; /* * append a "sub" to which clients will connect */ dev_sub = sub_new("sub", nfr); aproc_setin(dev_sub, buf); } else { dev_rec = NULL; dev_sub = NULL; } /* * create play chain */ if (dopar) { aparams_init(&opar, dopar->cmin, dopar->cmax, dopar->rate); /* * create the write end */ dev_play = wpipe_new(dev_file); buf = abuf_new(nfr, dopar); aproc_setin(dev_play, buf); obufsz += nfr; /* * append a converter, if needed */ if (!aparams_eqenc(&opar, dopar)) { conv = enc_new("mixout", dopar); aproc_setout(conv, buf); buf = abuf_new(nfr, &opar); aproc_setin(conv, buf); obufsz += nfr; } dev_opar = opar; /* * append a "mix" to which clients will connect */ dev_mix = mix_new("mix", nfr); aproc_setout(dev_mix, buf); } else { dev_play = NULL; dev_mix = NULL; } dev_bufsz = (dopar) ? obufsz : ibufsz; DPRINTF("dev_init: using %u fpb\n", dev_bufsz); dev_start(); } /* * cleanly stop and drain everything and close the device * once both play chain and record chain are gone */ void dev_done(void) { struct file *f; if (dev_mix) { /* * generate EOF on all inputs (but not the device), and * put the mixer in ``autoquit'' state, so once buffers * are drained the mixer will terminate and shutdown the * write-end of the device * * NOTE: since file_eof() can destroy the file and * reorder the file_list, we have to restart the loop * after each call to file_eof() */ restart: LIST_FOREACH(f, &file_list, entry) { if (f != dev_file && f->rproc) { file_eof(f); goto restart; } } if (dev_mix) dev_mix->u.mix.flags |= MIX_AUTOQUIT; /* * wait play chain to terminate */ while (dev_file->wproc != NULL) { if (!file_poll()) break; } dev_mix = 0; } if (dev_sub) { /* * same as above, but for the record chain: generate eof * on the read-end of the device and wait record buffers * to desappear. We must stop the device first, because * play-end will underrun (and xrun correction code will * insert silence on the record-end of the device) */ dev_stop(); file_eof(dev_file); if (dev_sub) dev_sub->u.sub.flags |= SUB_AUTOQUIT; for (;;) { if (!file_poll()) break; } dev_sub = NULL; } } /* * start the (paused) device. By default it's paused */ void dev_start(void) { if (dev_mix) dev_mix->u.mix.flags |= MIX_DROP; if (dev_sub) dev_sub->u.sub.flags |= SUB_DROP; dev_file->ops->start(dev_file); } /* * pause the device */ void dev_stop(void) { dev_file->ops->stop(dev_file); if (dev_mix) dev_mix->u.mix.flags &= ~MIX_DROP; if (dev_sub) dev_sub->u.sub.flags &= ~SUB_DROP; } /* * sync play buffer to rec buffer (for instance when one of * them underruns/overruns) */ void dev_sync(struct abuf *ibuf, struct abuf *obuf) { struct abuf *pbuf, *rbuf; int delta; if (!dev_mix || !dev_sub) return; pbuf = LIST_FIRST(&dev_mix->obuflist); if (!pbuf) return; rbuf = LIST_FIRST(&dev_sub->ibuflist); if (!rbuf) return; for (;;) { if (!ibuf || !ibuf->rproc) { DPRINTF("dev_sync: reader desappeared\n"); return; } if (ibuf->rproc == dev_mix) break; ibuf = LIST_FIRST(&ibuf->rproc->obuflist); } for (;;) { if (!obuf || !obuf->wproc) { DPRINTF("dev_sync: writer desappeared\n"); return; } if (obuf->wproc == dev_sub) break; obuf = LIST_FIRST(&obuf->wproc->ibuflist); } /* * calculate delta, the number of frames the play chain is ahead * of the record chain. It's necessary to schedule silences (or * drops) in order to start playback and record in sync. */ delta = rbuf->bpf * (pbuf->abspos + pbuf->used) - pbuf->bpf * rbuf->abspos; delta /= pbuf->bpf * rbuf->bpf; DPRINTF("dev_sync: delta = %d, ppos = %u, pused = %u, rpos = %u\n", delta, pbuf->abspos, pbuf->used, rbuf->abspos); if (delta > 0) { /* * if the play chain is ahead (most cases) drop some of * the recorded input, to get both in sync */ obuf->drop += delta * obuf->bpf; abuf_ipos(obuf, -delta); } else if (delta < 0) { /* * if record chain is ahead (should never happen, * right?) then insert silence to play */ ibuf->silence += -delta * ibuf->bpf; abuf_opos(ibuf, delta); } else DPRINTF("dev_sync: nothing to do\n"); } /* * attach the given input and output buffers to the mixer and the * multiplexer respectively. The operation is done synchronously, so * both buffers enter in sync. If buffers do not match play * and rec */ void dev_attach(char *name, struct abuf *ibuf, struct aparams *sipar, unsigned underrun, struct abuf *obuf, struct aparams *sopar, unsigned overrun) { struct abuf *pbuf = NULL, *rbuf = NULL; struct aparams ipar, opar; struct aproc *conv; unsigned nfr; if (ibuf) { ipar = *sipar; pbuf = LIST_FIRST(&dev_mix->obuflist); if (!aparams_eqenc(&ipar, &dev_opar)) { nfr = (dev_bufsz + 3) / 4 + dev_round - 1; nfr -= nfr % dev_round; conv = dec_new(name, &ipar); ipar.bps = dev_opar.bps; ipar.bits = dev_opar.bits; ipar.sig = dev_opar.sig; ipar.le = dev_opar.le; ipar.msb = dev_opar.msb; aproc_setin(conv, ibuf); ibuf = abuf_new(nfr, &ipar); aproc_setout(conv, ibuf); } if (!aparams_subset(&ipar, &dev_opar)) { nfr = (dev_bufsz + 3) / 4 + dev_round - 1; nfr -= nfr % dev_round; conv = cmap_new(name, &ipar, &dev_opar); ipar.cmin = dev_opar.cmin; ipar.cmax = dev_opar.cmax; aproc_setin(conv, ibuf); ibuf = abuf_new(nfr, &ipar); aproc_setout(conv, ibuf); } if (!aparams_eqrate(&ipar, &dev_opar)) { nfr = (dev_bufsz + 3) / 4 + dev_round - 1; nfr -= nfr % dev_round; conv = resamp_new(name, &ipar, &dev_opar); ipar.rate = dev_opar.rate; aproc_setin(conv, ibuf); ibuf = abuf_new(nfr, &ipar); aproc_setout(conv, ibuf); } aproc_setin(dev_mix, ibuf); abuf_opos(ibuf, -dev_mix->u.mix.lat); ibuf->xrun = underrun; } if (obuf) { opar = *sopar; rbuf = LIST_FIRST(&dev_sub->ibuflist); if (!aparams_eqenc(&opar, &dev_ipar)) { nfr = (dev_bufsz + 3) / 4 + dev_round - 1; nfr -= nfr % dev_round; conv = enc_new(name, &opar); opar.bps = dev_ipar.bps; opar.bits = dev_ipar.bits; opar.sig = dev_ipar.sig; opar.le = dev_ipar.le; opar.msb = dev_ipar.msb; aproc_setout(conv, obuf); obuf = abuf_new(nfr, &opar); aproc_setin(conv, obuf); } if (!aparams_subset(&opar, &dev_ipar)) { nfr = (dev_bufsz + 3) / 4 + dev_round - 1; nfr -= nfr % dev_round; conv = cmap_new(name, &dev_ipar, &opar); opar.cmin = dev_ipar.cmin; opar.cmax = dev_ipar.cmax; aproc_setout(conv, obuf); obuf = abuf_new(nfr, &opar); aproc_setin(conv, obuf); } if (!aparams_eqrate(&opar, &dev_ipar)) { nfr = (dev_bufsz + 3) / 4 + dev_round - 1; nfr -= nfr % dev_round; conv = resamp_new(name, &dev_ipar, &opar); opar.rate = dev_ipar.rate; aproc_setout(conv, obuf); obuf = abuf_new(nfr, &opar); aproc_setin(conv, obuf); } aproc_setout(dev_sub, obuf); abuf_ipos(obuf, -dev_sub->u.sub.lat); obuf->xrun = overrun; } /* * sync play to record */ if (ibuf && obuf) { ibuf->duplex = obuf; obuf->duplex = ibuf; dev_sync(ibuf, obuf); } } /* * clear buffers of the play and record chains so that when the device * is started, playback and record start in sync */ void dev_clear(void) { struct abuf *buf; if (dev_mix) { if (!LIST_EMPTY(&dev_mix->ibuflist)) { fprintf(stderr, "dev_clear: mixer not idle\n"); abort(); } buf = LIST_FIRST(&dev_mix->obuflist); while (buf) { abuf_clear(buf); buf = LIST_FIRST(&buf->rproc->obuflist); } mix_clear(dev_mix); } if (dev_sub) { if (!LIST_EMPTY(&dev_sub->obuflist)) { fprintf(stderr, "dev_suspend: demux not idle\n"); abort(); } buf = LIST_FIRST(&dev_sub->ibuflist); while (buf) { abuf_clear(buf); buf = LIST_FIRST(&buf->wproc->ibuflist); } sub_clear(dev_sub); } }