/* $OpenBSD: aproc.c,v 1.70 2012/03/23 11:59:54 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. */ /* * aproc structures are simple audio processing units. They are * interconnected by abuf structures and form a kind of circuit. aproc * structure have call-backs that do the actual processing. * * This module implements the following processing units: * * - rpipe: read end of an unix file (pipe, socket, device...) * * - wpipe: write end of an unix file (pipe, socket, device...) * * - mix: mix N inputs -> 1 output * * - sub: from 1 input -> extract/copy N outputs * * - conv: converts/resamples/remaps a single stream * * - resamp: resample streams in native format * */ #include #include #include #include "abuf.h" #include "aparams.h" #include "aproc.h" #include "conf.h" #include "file.h" #include "midi.h" #ifdef DEBUG #include "dbg.h" #endif /* * Same as ABUF_ROK(), but consider that a buffer is * readable if there's silence pending to be inserted */ #define MIX_ROK(buf) (ABUF_ROK(buf) || (buf)->r.mix.drop < 0) /* * Same as ABUF_WOK(), but consider that a buffer is * writeable if there are samples to drop */ #define SUB_WOK(buf) (ABUF_WOK(buf) || (buf)->w.sub.silence < 0) #ifdef DEBUG void aproc_dbg(struct aproc *p) { dbg_puts(p->ops->name); dbg_puts("("); dbg_puts(p->name); dbg_puts(")"); } int zomb_in(struct aproc *p, struct abuf *ibuf) { aproc_dbg(p); dbg_puts(": in: terminated\n"); dbg_panic(); return 0; } int zomb_out(struct aproc *p, struct abuf *obuf) { aproc_dbg(p); dbg_puts(": out: terminated\n"); dbg_panic(); return 0; } void zomb_eof(struct aproc *p, struct abuf *ibuf) { aproc_dbg(p); dbg_puts(": eof: terminated\n"); dbg_panic(); } void zomb_hup(struct aproc *p, struct abuf *obuf) { aproc_dbg(p); dbg_puts(": hup: terminated\n"); dbg_panic(); } void zomb_newin(struct aproc *p, struct abuf *ibuf) { aproc_dbg(p); dbg_puts(": newin: terminated\n"); dbg_panic(); } void zomb_newout(struct aproc *p, struct abuf *obuf) { aproc_dbg(p); dbg_puts(": newout: terminated\n"); dbg_panic(); } void zomb_ipos(struct aproc *p, struct abuf *ibuf, int delta) { aproc_dbg(p); dbg_puts(": ipos: terminated\n"); dbg_panic(); } void zomb_opos(struct aproc *p, struct abuf *obuf, int delta) { aproc_dbg(p); dbg_puts(": opos: terminated\n"); dbg_panic(); } struct aproc_ops zomb_ops = { "zomb", zomb_in, zomb_out, zomb_eof, zomb_hup, zomb_newin, zomb_newout, zomb_ipos, zomb_opos, NULL }; #endif struct aproc * aproc_new(struct aproc_ops *ops, char *name) { struct aproc *p; p = malloc(sizeof(struct aproc)); if (p == NULL) err(1, "%s", name); LIST_INIT(&p->ins); LIST_INIT(&p->outs); p->name = name; p->ops = ops; p->refs = 0; p->flags = 0; return p; } void aproc_del(struct aproc *p) { struct abuf *i; if (!(p->flags & APROC_ZOMB)) { #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": terminating...\n"); } #endif if (p->ops->done) { #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": done\n"); } #endif p->ops->done(p); } while (!LIST_EMPTY(&p->ins)) { i = LIST_FIRST(&p->ins); abuf_hup(i); } while (!LIST_EMPTY(&p->outs)) { i = LIST_FIRST(&p->outs); abuf_eof(i); } p->flags |= APROC_ZOMB; } if (p->refs > 0) { #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": free delayed\n"); p->ops = &zomb_ops; } #endif return; } #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": freed\n"); } #endif free(p); } void aproc_setin(struct aproc *p, struct abuf *ibuf) { LIST_INSERT_HEAD(&p->ins, ibuf, ient); ibuf->rproc = p; if (p->ops->newin) p->ops->newin(p, ibuf); } void aproc_setout(struct aproc *p, struct abuf *obuf) { LIST_INSERT_HEAD(&p->outs, obuf, oent); obuf->wproc = p; if (p->ops->newout) p->ops->newout(p, obuf); } void aproc_ipos(struct aproc *p, struct abuf *ibuf, int delta) { struct abuf *obuf; LIST_FOREACH(obuf, &p->outs, oent) { abuf_ipos(obuf, delta); } } void aproc_opos(struct aproc *p, struct abuf *obuf, int delta) { struct abuf *ibuf; LIST_FOREACH(ibuf, &p->ins, ient) { abuf_opos(ibuf, delta); } } int aproc_inuse(struct aproc *p) { struct abuf *i; LIST_FOREACH(i, &p->ins, ient) { if (i->inuse) return 1; } LIST_FOREACH(i, &p->outs, oent) { if (i->inuse) return 1; } return 0; } int aproc_depend(struct aproc *p, struct aproc *dep) { struct abuf *i; if (p == dep) return 1; if (p == NULL) return 0; LIST_FOREACH(i, &p->ins, ient) { if (i->wproc && aproc_depend(i->wproc, dep)) return 1; } return 0; } int rfile_do(struct aproc *p, unsigned todo, unsigned *done) { struct abuf *obuf = LIST_FIRST(&p->outs); struct file *f = p->u.io.file; unsigned char *data; unsigned n, count, off; off = p->u.io.partial; data = abuf_wgetblk(obuf, &count, 0); if (count > todo) count = todo; n = file_read(f, data + off, count * obuf->bpf - off); if (n == 0) return 0; n += off; p->u.io.partial = n % obuf->bpf; count = n / obuf->bpf; if (count > 0) abuf_wcommit(obuf, count); if (done) *done = count; return 1; } int rfile_in(struct aproc *p, struct abuf *ibuf_dummy) { struct abuf *obuf = LIST_FIRST(&p->outs); struct file *f = p->u.io.file; if (!ABUF_WOK(obuf) || !(f->state & FILE_ROK)) return 0; if (!rfile_do(p, obuf->len, NULL)) return 0; if (!abuf_flush(obuf)) return 0; return 1; } int rfile_out(struct aproc *p, struct abuf *obuf) { struct file *f = p->u.io.file; if (f->state & FILE_RINUSE) return 0; if (!ABUF_WOK(obuf) || !(f->state & FILE_ROK)) return 0; if (!rfile_do(p, obuf->len, NULL)) return 0; return 1; } void rfile_done(struct aproc *p) { struct file *f = p->u.io.file; struct abuf *obuf; if (f == NULL) return; /* * disconnect from file structure */ f->rproc = NULL; p->u.io.file = NULL; /* * all buffers must be detached before deleting f->wproc, * because otherwise it could trigger this code again */ obuf = LIST_FIRST(&p->outs); if (obuf) abuf_eof(obuf); if (f->wproc) { aproc_del(f->wproc); } else file_del(f); #ifdef DEBUG if (debug_level >= 2 && p->u.io.partial > 0) { aproc_dbg(p); dbg_puts(": "); dbg_putu(p->u.io.partial); dbg_puts(" bytes lost in partial read\n"); } #endif } void rfile_eof(struct aproc *p, struct abuf *ibuf_dummy) { aproc_del(p); } void rfile_hup(struct aproc *p, struct abuf *obuf) { aproc_del(p); } struct aproc_ops rfile_ops = { "rfile", rfile_in, rfile_out, rfile_eof, rfile_hup, NULL, /* newin */ NULL, /* newout */ aproc_ipos, aproc_opos, rfile_done }; struct aproc * rfile_new(struct file *f) { struct aproc *p; p = aproc_new(&rfile_ops, f->name); p->u.io.file = f; p->u.io.partial = 0; f->rproc = p; return p; } void wfile_done(struct aproc *p) { struct file *f = p->u.io.file; struct abuf *ibuf; if (f == NULL) return; /* * disconnect from file structure */ f->wproc = NULL; p->u.io.file = NULL; /* * all buffers must be detached before deleting f->rproc, * because otherwise it could trigger this code again */ ibuf = LIST_FIRST(&p->ins); if (ibuf) abuf_hup(ibuf); if (f->rproc) { aproc_del(f->rproc); } else file_del(f); #ifdef DEBUG if (debug_level >= 2 && p->u.io.partial > 0) { aproc_dbg(p); dbg_puts(": "); dbg_putu(p->u.io.partial); dbg_puts(" bytes lost in partial write\n"); } #endif } int wfile_do(struct aproc *p, unsigned todo, unsigned *done) { struct abuf *ibuf = LIST_FIRST(&p->ins); struct file *f = p->u.io.file; unsigned char *data; unsigned n, count, off; off = p->u.io.partial; data = abuf_rgetblk(ibuf, &count, 0); if (count > todo) count = todo; n = file_write(f, data + off, count * ibuf->bpf - off); if (n == 0) return 0; n += off; p->u.io.partial = n % ibuf->bpf; count = n / ibuf->bpf; if (count > 0) abuf_rdiscard(ibuf, count); if (done) *done = count; return 1; } int wfile_in(struct aproc *p, struct abuf *ibuf) { struct file *f = p->u.io.file; if (f->state & FILE_WINUSE) return 0; if (!ABUF_ROK(ibuf) || !(f->state & FILE_WOK)) return 0; if (!wfile_do(p, ibuf->len, NULL)) return 0; return 1; } int wfile_out(struct aproc *p, struct abuf *obuf_dummy) { struct abuf *ibuf = LIST_FIRST(&p->ins); struct file *f = p->u.io.file; if (!abuf_fill(ibuf)) return 0; if (!ABUF_ROK(ibuf) || !(f->state & FILE_WOK)) return 0; if (!wfile_do(p, ibuf->len, NULL)) return 0; return 1; } void wfile_eof(struct aproc *p, struct abuf *ibuf) { aproc_del(p); } void wfile_hup(struct aproc *p, struct abuf *obuf_dummy) { aproc_del(p); } struct aproc_ops wfile_ops = { "wfile", wfile_in, wfile_out, wfile_eof, wfile_hup, NULL, /* newin */ NULL, /* newout */ aproc_ipos, aproc_opos, wfile_done }; struct aproc * wfile_new(struct file *f) { struct aproc *p; p = aproc_new(&wfile_ops, f->name); p->u.io.file = f; p->u.io.partial = 0; f->wproc = p; return p; } /* * Drop as much as possible samples from the reader end, * negative values mean ``insert silence''. */ void mix_drop(struct abuf *buf, int extra) { unsigned count; buf->r.mix.drop += extra; while (buf->r.mix.drop > 0) { count = buf->r.mix.drop; if (count > buf->used) count = buf->used; if (count == 0) { #ifdef DEBUG if (debug_level >= 4) { abuf_dbg(buf); dbg_puts(": drop: no data\n"); } #endif return; } abuf_rdiscard(buf, count); buf->r.mix.drop -= count; #ifdef DEBUG if (debug_level >= 4) { abuf_dbg(buf); dbg_puts(": dropped "); dbg_putu(count); dbg_puts(", to drop = "); dbg_putu(buf->r.mix.drop); dbg_puts("\n"); } #endif } } /* * Append the necessary amount of silence, in a way * obuf->w.mix.todo doesn't exceed the given value */ void mix_bzero(struct abuf *obuf, unsigned maxtodo) { adata_t *odata; unsigned ocount, todo; if (obuf->w.mix.todo >= maxtodo) return; todo = maxtodo - obuf->w.mix.todo; odata = (adata_t *)abuf_wgetblk(obuf, &ocount, obuf->w.mix.todo); if (ocount > todo) ocount = todo; if (ocount == 0) return; memset(odata, 0, ocount * obuf->bpf); obuf->w.mix.todo += ocount; #ifdef DEBUG if (debug_level >= 4) { abuf_dbg(obuf); dbg_puts(": bzero("); dbg_putu(obuf->w.mix.todo); dbg_puts(")\n"); } #endif } /* * Mix an input block over an output block. */ unsigned mix_badd(struct abuf *ibuf, struct abuf *obuf) { adata_t *idata, *odata; unsigned cmin, cmax; unsigned i, j, cc, istart, inext, onext, ostart; unsigned scount, icount, ocount; int vol, s; #ifdef DEBUG if (debug_level >= 4) { abuf_dbg(ibuf); dbg_puts(": badd: done = "); dbg_putu(ibuf->r.mix.done); dbg_puts("/"); dbg_putu(obuf->w.mix.todo); dbg_puts(", drop = "); dbg_puti(ibuf->r.mix.drop); dbg_puts("\n"); } #endif /* * Insert silence for xrun correction */ while (ibuf->r.mix.drop < 0) { icount = -ibuf->r.mix.drop; mix_bzero(obuf, ibuf->r.mix.done + icount); ocount = obuf->w.mix.todo - ibuf->r.mix.done; if (ocount == 0) return 0; scount = (icount < ocount) ? icount : ocount; ibuf->r.mix.done += scount; ibuf->r.mix.drop += scount; } /* * Calculate the maximum we can read. */ idata = (adata_t *)abuf_rgetblk(ibuf, &icount, 0); if (icount == 0) return 0; /* * Calculate the maximum we can write. */ odata = (adata_t *)abuf_wgetblk(obuf, &ocount, ibuf->r.mix.done); if (ocount == 0) return 0; scount = (icount < ocount) ? icount : ocount; mix_bzero(obuf, scount + ibuf->r.mix.done); vol = ADATA_MUL(ibuf->r.mix.weight, ibuf->r.mix.vol); cmin = obuf->cmin > ibuf->cmin ? obuf->cmin : ibuf->cmin; cmax = obuf->cmax < ibuf->cmax ? obuf->cmax : ibuf->cmax; ostart = cmin - obuf->cmin; istart = cmin - ibuf->cmin; onext = obuf->cmax - cmax + ostart; inext = ibuf->cmax - cmax + istart; cc = cmax - cmin + 1; odata += ostart; idata += istart; for (i = scount; i > 0; i--) { for (j = cc; j > 0; j--) { s = *odata + ADATA_MUL(*idata, vol); if (s >= ADATA_UNIT) s = ADATA_UNIT - 1; else if (s < -ADATA_UNIT) s = -ADATA_UNIT; *odata = s; idata++; odata++; } odata += onext; idata += inext; } abuf_rdiscard(ibuf, scount); ibuf->r.mix.done += scount; #ifdef DEBUG if (debug_level >= 4) { abuf_dbg(ibuf); dbg_puts(": badd: done = "); dbg_putu(ibuf->r.mix.done); dbg_puts("/"); dbg_putu(obuf->w.mix.todo); dbg_puts("\n"); } #endif return scount; } /* * Handle buffer underrun, return 0 if stream died. */ int mix_xrun(struct aproc *p, struct abuf *i) { struct abuf *obuf = LIST_FIRST(&p->outs); unsigned fdrop, remain; if (i->r.mix.done > 0) return 1; if (i->r.mix.xrun == XRUN_ERROR) { abuf_hup(i); return 0; } fdrop = obuf->w.mix.todo; #ifdef DEBUG if (debug_level >= 3) { abuf_dbg(i); dbg_puts(": underrun, dropping "); dbg_putu(fdrop); dbg_puts(" + "); dbg_putu(i->r.mix.drop); dbg_puts("\n"); } #endif i->r.mix.done += fdrop; if (i->r.mix.xrun == XRUN_SYNC) mix_drop(i, fdrop); else { remain = fdrop % p->u.mix.round; if (remain) remain = p->u.mix.round - remain; mix_drop(i, -(int)remain); fdrop += remain; #ifdef DEBUG if (debug_level >= 3) { abuf_dbg(i); dbg_puts(": underrun, adding "); dbg_putu(remain); dbg_puts("\n"); } #endif abuf_opos(i, -(int)fdrop); if (i->duplex) { #ifdef DEBUG if (debug_level >= 3) { abuf_dbg(i->duplex); dbg_puts(": full-duplex resync\n"); } #endif sub_silence(i->duplex, -(int)fdrop); abuf_ipos(i->duplex, -(int)fdrop); } } return 1; } int mix_in(struct aproc *p, struct abuf *ibuf) { struct abuf *i, *inext, *obuf = LIST_FIRST(&p->outs); unsigned odone; unsigned maxwrite; unsigned scount; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": used = "); dbg_putu(ibuf->used); dbg_puts("/"); dbg_putu(ibuf->len); dbg_puts(", done = "); dbg_putu(ibuf->r.mix.done); dbg_puts("/"); dbg_putu(obuf->w.mix.todo); dbg_puts("\n"); } #endif if (!MIX_ROK(ibuf)) return 0; scount = 0; odone = obuf->len; for (i = LIST_FIRST(&p->ins); i != NULL; i = inext) { inext = LIST_NEXT(i, ient); if (i->r.mix.drop >= 0 && !abuf_fill(i)) continue; /* eof */ mix_drop(i, 0); scount += mix_badd(i, obuf); if (odone > i->r.mix.done) odone = i->r.mix.done; } if (LIST_EMPTY(&p->ins) || scount == 0) return 0; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": maxwrite = "); dbg_putu(p->u.mix.maxlat); dbg_puts(" - "); dbg_putu(p->u.mix.lat); dbg_puts(" = "); dbg_putu(p->u.mix.maxlat - p->u.mix.lat); dbg_puts("\n"); } #endif maxwrite = p->u.mix.maxlat - p->u.mix.lat; if (maxwrite > 0) { if (odone > maxwrite) odone = maxwrite; p->u.mix.lat += odone; LIST_FOREACH(i, &p->ins, ient) { i->r.mix.done -= odone; } abuf_wcommit(obuf, odone); obuf->w.mix.todo -= odone; if (APROC_OK(p->u.mix.mon)) mon_snoop(p->u.mix.mon, obuf, obuf->used - odone, odone); if (!abuf_flush(obuf)) return 0; /* hup */ } return 1; } int mix_out(struct aproc *p, struct abuf *obuf) { struct abuf *i, *inext; unsigned odone; unsigned maxwrite; unsigned scount; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": used = "); dbg_putu(obuf->used); dbg_puts("/"); dbg_putu(obuf->len); dbg_puts(", todo = "); dbg_putu(obuf->w.mix.todo); dbg_puts("/"); dbg_putu(obuf->len); dbg_puts("\n"); } #endif if (!ABUF_WOK(obuf)) return 0; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": maxwrite = "); dbg_putu(p->u.mix.maxlat); dbg_puts(" - "); dbg_putu(p->u.mix.lat); dbg_puts(" = "); dbg_putu(p->u.mix.maxlat - p->u.mix.lat); dbg_puts("\n"); } #endif maxwrite = p->u.mix.maxlat - p->u.mix.lat; if (maxwrite > obuf->w.mix.todo) { if ((p->flags & (APROC_QUIT | APROC_DROP)) == APROC_DROP) mix_bzero(obuf, maxwrite); } scount = 0; odone = obuf->len; for (i = LIST_FIRST(&p->ins); i != NULL; i = inext) { inext = LIST_NEXT(i, ient); if (i->r.mix.drop >= 0 && !abuf_fill(i)) continue; /* eof */ mix_drop(i, 0); if (maxwrite > 0 && !MIX_ROK(i)) { if (p->flags & APROC_DROP) { if (!mix_xrun(p, i)) continue; } } else scount += mix_badd(i, obuf); if (odone > i->r.mix.done) odone = i->r.mix.done; } if (LIST_EMPTY(&p->ins) && obuf->w.mix.todo == 0) { if (p->flags & APROC_QUIT) { aproc_del(p); return 0; } if (!(p->flags & APROC_DROP)) return 0; } if (odone > obuf->w.mix.todo) odone = obuf->w.mix.todo; if (odone > maxwrite) odone = maxwrite; if (odone > 0) { p->u.mix.lat += odone; LIST_FOREACH(i, &p->ins, ient) { i->r.mix.done -= odone; } abuf_wcommit(obuf, odone); obuf->w.mix.todo -= odone; if (APROC_OK(p->u.mix.mon)) mon_snoop(p->u.mix.mon, obuf, obuf->used - odone, odone); } if (LIST_EMPTY(&p->ins)) p->u.mix.idle += odone; if (scount == 0) return 0; return 1; } void mix_eof(struct aproc *p, struct abuf *ibuf) { struct abuf *i, *obuf = LIST_FIRST(&p->outs); unsigned odone; mix_setmaster(p); if (!aproc_inuse(p)) { #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": running other streams\n"); } #endif /* * Find a blocked input. */ odone = obuf->len; LIST_FOREACH(i, &p->ins, ient) { /* * abuf_fill() may trigger mix_eof(), do the job * and possibly reorder the list */ if (!abuf_fill(i)) return; if (MIX_ROK(i) && i->r.mix.done < obuf->w.mix.todo) { abuf_run(i); return; } if (odone > i->r.mix.done) odone = i->r.mix.done; } /* * No blocked inputs. Check if output is blocked. */ if (LIST_EMPTY(&p->ins) || odone == obuf->w.mix.todo) abuf_run(obuf); } } void mix_hup(struct aproc *p, struct abuf *obuf) { aproc_del(p); } void mix_newin(struct aproc *p, struct abuf *ibuf) { p->u.mix.idle = 0; ibuf->r.mix.done = 0; ibuf->r.mix.vol = ADATA_UNIT; ibuf->r.mix.weight = ADATA_UNIT; ibuf->r.mix.maxweight = ADATA_UNIT; ibuf->r.mix.xrun = XRUN_IGNORE; ibuf->r.mix.drop = 0; } void mix_newout(struct aproc *p, struct abuf *obuf) { #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": newout, will use "); dbg_putu(obuf->len); dbg_puts(" fr\n"); } #endif obuf->w.mix.todo = 0; } void mix_opos(struct aproc *p, struct abuf *obuf, int delta) { p->u.mix.lat -= delta; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": opos: lat = "); dbg_puti(p->u.mix.lat); dbg_puts("/"); dbg_puti(p->u.mix.maxlat); dbg_puts("\n"); } #endif aproc_opos(p, obuf, delta); if (APROC_OK(p->u.mix.mon)) p->u.mix.mon->ops->ipos(p->u.mix.mon, NULL, delta); } struct aproc_ops mix_ops = { "mix", mix_in, mix_out, mix_eof, mix_hup, mix_newin, mix_newout, aproc_ipos, mix_opos, NULL }; struct aproc * mix_new(char *name, int maxlat, unsigned round, unsigned autovol, unsigned master) { struct aproc *p; p = aproc_new(&mix_ops, name); p->u.mix.idle = 0; p->u.mix.lat = 0; p->u.mix.round = round; p->u.mix.maxlat = maxlat; p->u.mix.mon = NULL; p->u.mix.autovol = autovol; p->u.mix.master = master; return p; } /* * Normalize input levels. */ void mix_setmaster(struct aproc *p) { unsigned n; struct abuf *i, *j; int weight; LIST_FOREACH(i, &p->ins, ient) { weight = ADATA_UNIT; if (p->u.mix.autovol) { /* * count the number of inputs that have * overlapping channel sets */ n = 0; LIST_FOREACH(j, &p->ins, ient) { if (i->cmin <= j->cmax && i->cmax >= j->cmin) n++; } weight /= n; } if (weight > i->r.mix.maxweight) weight = i->r.mix.maxweight; i->r.mix.weight = ADATA_MUL(weight, p->u.mix.master); #ifdef DEBUG if (debug_level >= 3) { abuf_dbg(i); dbg_puts(": setmaster: "); dbg_puti(i->r.mix.weight); dbg_puts("/"); dbg_puti(i->r.mix.maxweight); dbg_puts("\n"); } #endif } } void mix_clear(struct aproc *p) { struct abuf *obuf = LIST_FIRST(&p->outs); p->u.mix.lat = 0; obuf->w.mix.todo = 0; } /* * Gracefully terminate the mixer: raise the APROC_QUIT flag * and let the rest of the code do the job. If there are neither * inputs nor uncommited data, then terminate right away */ void mix_quit(struct aproc *p) { struct abuf *obuf = LIST_FIRST(&p->outs); p->flags |= APROC_QUIT; /* * eof the last input will trigger aproc_del() */ if (!LIST_EMPTY(&p->ins) || obuf->w.mix.todo > 0) return; aproc_del(p); } /* * Append as much as possible silence on the writer end */ void sub_silence(struct abuf *buf, int extra) { unsigned char *data; unsigned count; buf->w.sub.silence += extra; if (buf->w.sub.silence > 0) { data = abuf_wgetblk(buf, &count, 0); if (count >= buf->w.sub.silence) count = buf->w.sub.silence; if (count == 0) { #ifdef DEBUG if (debug_level >= 4) { abuf_dbg(buf); dbg_puts(": no space for silence\n"); } #endif return; } memset(data, 0, count * buf->bpf); abuf_wcommit(buf, count); buf->w.sub.silence -= count; #ifdef DEBUG if (debug_level >= 4) { abuf_dbg(buf); dbg_puts(": appended "); dbg_putu(count); dbg_puts(", remaining silence = "); dbg_putu(buf->w.sub.silence); dbg_puts("\n"); } #endif } } /* * Copy data from ibuf to obuf. */ void sub_bcopy(struct abuf *ibuf, struct abuf *obuf) { adata_t *idata, *odata; unsigned cmin, cmax; unsigned i, j, cc, istart, inext, onext, ostart; unsigned icount, ocount, scount; /* * Drop samples for xrun correction */ if (obuf->w.sub.silence < 0) { scount = -obuf->w.sub.silence; if (scount > ibuf->used) scount = ibuf->used; obuf->w.sub.done += scount; obuf->w.sub.silence += scount; } idata = (adata_t *)abuf_rgetblk(ibuf, &icount, obuf->w.sub.done); if (icount == 0) return; odata = (adata_t *)abuf_wgetblk(obuf, &ocount, 0); if (ocount == 0) return; cmin = obuf->cmin > ibuf->cmin ? obuf->cmin : ibuf->cmin; cmax = obuf->cmax < ibuf->cmax ? obuf->cmax : ibuf->cmax; ostart = cmin - obuf->cmin; istart = cmin - ibuf->cmin; onext = obuf->cmax - cmax; inext = ibuf->cmax - cmax + istart; cc = cmax - cmin + 1; idata += istart; scount = (icount < ocount) ? icount : ocount; for (i = scount; i > 0; i--) { for (j = ostart; j > 0; j--) *odata++ = 0x1111; for (j = cc; j > 0; j--) { *odata = *idata; odata++; idata++; } for (j = onext; j > 0; j--) *odata++ = 0x2222; idata += inext; } abuf_wcommit(obuf, scount); obuf->w.sub.done += scount; #ifdef DEBUG if (debug_level >= 4) { abuf_dbg(obuf); dbg_puts(": bcopy "); dbg_putu(scount); dbg_puts("\n"); } #endif } /* * Handle buffer overruns. Return 0 if the stream died. */ int sub_xrun(struct aproc *p, struct abuf *i) { struct abuf *ibuf = LIST_FIRST(&p->ins); unsigned fdrop, remain; if (i->w.sub.done > 0) return 1; if (i->w.sub.xrun == XRUN_ERROR) { abuf_eof(i); return 0; } fdrop = ibuf->used; #ifdef DEBUG if (debug_level >= 3) { abuf_dbg(i); dbg_puts(": overrun, silence "); dbg_putu(fdrop); dbg_puts(" + "); dbg_putu(i->w.sub.silence); dbg_puts("\n"); } #endif i->w.sub.done += fdrop; if (i->w.sub.xrun == XRUN_SYNC) sub_silence(i, fdrop); else { remain = fdrop % p->u.sub.round; if (remain) remain = p->u.sub.round - remain; sub_silence(i, -(int)remain); fdrop += remain; #ifdef DEBUG if (debug_level >= 3) { abuf_dbg(i); dbg_puts(": overrun, adding "); dbg_putu(remain); dbg_puts("\n"); } #endif abuf_ipos(i, -(int)fdrop); if (i->duplex) { #ifdef DEBUG if (debug_level >= 3) { abuf_dbg(i->duplex); dbg_puts(": full-duplex resync\n"); } #endif mix_drop(i->duplex, -(int)fdrop); abuf_opos(i->duplex, -(int)fdrop); } } return 1; } int sub_in(struct aproc *p, struct abuf *ibuf) { struct abuf *i, *inext; unsigned idone; if (!ABUF_ROK(ibuf)) return 0; idone = ibuf->len; for (i = LIST_FIRST(&p->outs); i != NULL; i = inext) { inext = LIST_NEXT(i, oent); sub_silence(i, 0); if (!SUB_WOK(i)) { if (p->flags & APROC_DROP) { if (!sub_xrun(p, i)) continue; } } else sub_bcopy(ibuf, i); if (idone > i->w.sub.done) idone = i->w.sub.done; if (!abuf_flush(i)) continue; } if (LIST_EMPTY(&p->outs)) { if (p->flags & APROC_QUIT) { aproc_del(p); return 0; } if (!(p->flags & APROC_DROP)) return 0; idone = ibuf->used; p->u.sub.idle += idone; } if (idone == 0) return 0; LIST_FOREACH(i, &p->outs, oent) { i->w.sub.done -= idone; } abuf_rdiscard(ibuf, idone); abuf_opos(ibuf, idone); p->u.sub.lat -= idone; return 1; } int sub_out(struct aproc *p, struct abuf *obuf) { struct abuf *ibuf = LIST_FIRST(&p->ins); struct abuf *i, *inext; unsigned idone; if (!SUB_WOK(obuf)) return 0; if (!abuf_fill(ibuf)) return 0; /* eof */ idone = ibuf->len; for (i = LIST_FIRST(&p->outs); i != NULL; i = inext) { inext = LIST_NEXT(i, oent); sub_silence(i, 0); sub_bcopy(ibuf, i); if (idone > i->w.sub.done) idone = i->w.sub.done; if (!abuf_flush(i)) continue; } if (LIST_EMPTY(&p->outs) || idone == 0) return 0; LIST_FOREACH(i, &p->outs, oent) { i->w.sub.done -= idone; } abuf_rdiscard(ibuf, idone); abuf_opos(ibuf, idone); p->u.sub.lat -= idone; return 1; } void sub_eof(struct aproc *p, struct abuf *ibuf) { aproc_del(p); } void sub_hup(struct aproc *p, struct abuf *obuf) { struct abuf *i, *ibuf = LIST_FIRST(&p->ins); unsigned idone; if (!aproc_inuse(p)) { #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": running other streams\n"); } #endif /* * Find a blocked output. */ idone = ibuf->len; LIST_FOREACH(i, &p->outs, oent) { /* * abuf_flush() may trigger sub_hup(), do the job * and possibly reorder the list */ if (!abuf_flush(i)) return; if (SUB_WOK(i) && i->w.sub.done < ibuf->used) { abuf_run(i); return; } if (idone > i->w.sub.done) idone = i->w.sub.done; } /* * No blocked outputs. Check if input is blocked. */ if (LIST_EMPTY(&p->outs) || idone == ibuf->used) abuf_run(ibuf); } } void sub_newout(struct aproc *p, struct abuf *obuf) { p->u.sub.idle = 0; obuf->w.sub.done = 0; obuf->w.sub.xrun = XRUN_IGNORE; obuf->w.sub.silence = 0; } void sub_ipos(struct aproc *p, struct abuf *ibuf, int delta) { p->u.sub.lat += delta; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": ipos: lat = "); dbg_puti(p->u.sub.lat); dbg_puts("/"); dbg_puti(p->u.sub.maxlat); dbg_puts("\n"); } #endif aproc_ipos(p, ibuf, delta); } struct aproc_ops sub_ops = { "sub", sub_in, sub_out, sub_eof, sub_hup, NULL, sub_newout, sub_ipos, aproc_opos, NULL }; struct aproc * sub_new(char *name, int maxlat, unsigned round) { struct aproc *p; p = aproc_new(&sub_ops, name); p->u.sub.idle = 0; p->u.sub.lat = 0; p->u.sub.round = round; p->u.sub.maxlat = maxlat; return p; } void sub_clear(struct aproc *p) { p->u.sub.lat = 0; } /* * Convert one block. */ void resamp_bcopy(struct aproc *p, struct abuf *ibuf, struct abuf *obuf) { unsigned inch; adata_t *idata; unsigned oblksz; unsigned ifr; unsigned onch; int s, ds, diff; adata_t *odata; unsigned iblksz; unsigned ofr; unsigned c; adata_t *ctxbuf, *ctx; unsigned ctx_start; unsigned icount, ocount; /* * Calculate max frames readable at once from the input buffer. */ idata = (adata_t *)abuf_rgetblk(ibuf, &icount, 0); ifr = icount; odata = (adata_t *)abuf_wgetblk(obuf, &ocount, 0); ofr = ocount; /* * Partially copy structures into local variables, to avoid * unnecessary indirections; this also allows the compiler to * order local variables more "cache-friendly". */ diff = p->u.resamp.diff; inch = ibuf->cmax - ibuf->cmin + 1; iblksz = p->u.resamp.iblksz; onch = obuf->cmax - obuf->cmin + 1; oblksz = p->u.resamp.oblksz; ctxbuf = p->u.resamp.ctx; ctx_start = p->u.resamp.ctx_start; /* * Start conversion. */ #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": starting diff = "); dbg_puti(diff); dbg_puts(", ifr = "); dbg_putu(ifr); dbg_puts(", ofr = "); dbg_putu(ofr); dbg_puts(" fr\n"); } #endif for (;;) { if (diff < 0) { if (ifr == 0) break; ctx_start ^= 1; ctx = ctxbuf + ctx_start; for (c = inch; c > 0; c--) { *ctx = *idata++; ctx += RESAMP_NCTX; } diff += oblksz; ifr--; } else if (diff > 0) { if (ofr == 0) break; ctx = ctxbuf; for (c = onch; c > 0; c--) { s = ctx[ctx_start]; ds = ctx[ctx_start ^ 1] - s; ctx += RESAMP_NCTX; *odata++ = s + ADATA_MULDIV(ds, diff, oblksz); } diff -= iblksz; ofr--; } else { if (ifr == 0 || ofr == 0) break; ctx = ctxbuf + ctx_start; for (c = onch; c > 0; c--) { *odata++ = *ctx; ctx += RESAMP_NCTX; } ctx_start ^= 1; ctx = ctxbuf + ctx_start; for (c = inch; c > 0; c--) { *ctx = *idata++; ctx += RESAMP_NCTX; } diff -= iblksz; diff += oblksz; ifr--; ofr--; } } p->u.resamp.diff = diff; p->u.resamp.ctx_start = ctx_start; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": done delta = "); dbg_puti(diff); dbg_puts(", ifr = "); dbg_putu(ifr); dbg_puts(", ofr = "); dbg_putu(ofr); dbg_puts(" fr\n"); } #endif /* * Update FIFO pointers. */ icount -= ifr; ocount -= ofr; abuf_rdiscard(ibuf, icount); abuf_wcommit(obuf, ocount); } int resamp_in(struct aproc *p, struct abuf *ibuf) { struct abuf *obuf = LIST_FIRST(&p->outs); if (!ABUF_WOK(obuf) || !ABUF_ROK(ibuf)) return 0; resamp_bcopy(p, ibuf, obuf); if (!abuf_flush(obuf)) return 0; return 1; } int resamp_out(struct aproc *p, struct abuf *obuf) { struct abuf *ibuf = LIST_FIRST(&p->ins); if (!abuf_fill(ibuf)) return 0; if (!ABUF_WOK(obuf) || !ABUF_ROK(ibuf)) return 0; resamp_bcopy(p, ibuf, obuf); return 1; } void resamp_eof(struct aproc *p, struct abuf *ibuf) { aproc_del(p); } void resamp_hup(struct aproc *p, struct abuf *obuf) { aproc_del(p); } void resamp_ipos(struct aproc *p, struct abuf *ibuf, int delta) { struct abuf *obuf = LIST_FIRST(&p->outs); long long ipos; ipos = (long long)delta * p->u.resamp.oblksz + p->u.resamp.idelta; p->u.resamp.idelta = ipos % p->u.resamp.iblksz; abuf_ipos(obuf, ipos / (int)p->u.resamp.iblksz); } void resamp_opos(struct aproc *p, struct abuf *obuf, int delta) { struct abuf *ibuf = LIST_FIRST(&p->ins); long long opos; opos = (long long)delta * p->u.resamp.iblksz + p->u.resamp.odelta; p->u.resamp.odelta = opos % p->u.resamp.oblksz; abuf_opos(ibuf, opos / p->u.resamp.oblksz); } struct aproc_ops resamp_ops = { "resamp", resamp_in, resamp_out, resamp_eof, resamp_hup, NULL, NULL, resamp_ipos, resamp_opos, NULL }; struct aproc * resamp_new(char *name, unsigned iblksz, unsigned oblksz) { struct aproc *p; unsigned i; p = aproc_new(&resamp_ops, name); p->u.resamp.iblksz = iblksz; p->u.resamp.oblksz = oblksz; p->u.resamp.diff = 0; p->u.resamp.idelta = 0; p->u.resamp.odelta = 0; p->u.resamp.ctx_start = 0; for (i = 0; i < NCHAN_MAX * RESAMP_NCTX; i++) p->u.resamp.ctx[i] = 0; #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": new "); dbg_putu(iblksz); dbg_puts("/"); dbg_putu(oblksz); dbg_puts("\n"); } #endif return p; } /* * Convert one block. */ void enc_bcopy(struct aproc *p, struct abuf *ibuf, struct abuf *obuf) { unsigned nch, scount, icount, ocount; unsigned f; adata_t *idata; int s; unsigned oshift; int osigbit; unsigned obps; unsigned i; unsigned char *odata; int obnext; int osnext; /* * Calculate max frames readable at once from the input buffer. */ idata = (adata_t *)abuf_rgetblk(ibuf, &icount, 0); if (icount == 0) return; odata = abuf_wgetblk(obuf, &ocount, 0); if (ocount == 0) return; scount = (icount < ocount) ? icount : ocount; nch = ibuf->cmax - ibuf->cmin + 1; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": bcopy "); dbg_putu(scount); dbg_puts(" fr / "); dbg_putu(nch); dbg_puts(" ch\n"); } #endif /* * Partially copy structures into local variables, to avoid * unnecessary indirections; this also allows the compiler to * order local variables more "cache-friendly". */ oshift = p->u.conv.shift; osigbit = p->u.conv.sigbit; obps = p->u.conv.bps; obnext = p->u.conv.bnext; osnext = p->u.conv.snext; /* * Start conversion. */ odata += p->u.conv.bfirst; for (f = scount * nch; f > 0; f--) { s = *idata++; s <<= 32 - ADATA_BITS; s >>= oshift; s ^= osigbit; for (i = obps; i > 0; i--) { *odata = (unsigned char)s; s >>= 8; odata += obnext; } odata += osnext; } /* * Update FIFO pointers. */ abuf_rdiscard(ibuf, scount); abuf_wcommit(obuf, scount); } int enc_in(struct aproc *p, struct abuf *ibuf) { struct abuf *obuf = LIST_FIRST(&p->outs); if (!ABUF_WOK(obuf) || !ABUF_ROK(ibuf)) return 0; enc_bcopy(p, ibuf, obuf); if (!abuf_flush(obuf)) return 0; return 1; } int enc_out(struct aproc *p, struct abuf *obuf) { struct abuf *ibuf = LIST_FIRST(&p->ins); if (!abuf_fill(ibuf)) return 0; if (!ABUF_WOK(obuf) || !ABUF_ROK(ibuf)) return 0; enc_bcopy(p, ibuf, obuf); return 1; } void enc_eof(struct aproc *p, struct abuf *ibuf) { aproc_del(p); } void enc_hup(struct aproc *p, struct abuf *obuf) { aproc_del(p); } struct aproc_ops enc_ops = { "enc", enc_in, enc_out, enc_eof, enc_hup, NULL, NULL, aproc_ipos, aproc_opos, NULL }; struct aproc * enc_new(char *name, struct aparams *par) { struct aproc *p; p = aproc_new(&enc_ops, name); p->u.conv.bps = par->bps; p->u.conv.sigbit = par->sig ? 0 : 1 << (par->bits - 1); if (par->msb) { p->u.conv.shift = 32 - par->bps * 8; } else { p->u.conv.shift = 32 - par->bits; } if (!par->le) { p->u.conv.bfirst = par->bps - 1; p->u.conv.bnext = -1; p->u.conv.snext = 2 * par->bps; } else { p->u.conv.bfirst = 0; p->u.conv.bnext = 1; p->u.conv.snext = 0; } #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": new "); aparams_dbg(par); dbg_puts("\n"); } #endif return p; } /* * Convert one block. */ void dec_bcopy(struct aproc *p, struct abuf *ibuf, struct abuf *obuf) { unsigned nch, scount, icount, ocount; unsigned f; unsigned ibps; unsigned i; int s = 0xdeadbeef; unsigned char *idata; int ibnext; int isnext; int isigbit; unsigned ishift; adata_t *odata; /* * Calculate max frames readable at once from the input buffer. */ idata = abuf_rgetblk(ibuf, &icount, 0); if (icount == 0) return; odata = (adata_t *)abuf_wgetblk(obuf, &ocount, 0); if (ocount == 0) return; scount = (icount < ocount) ? icount : ocount; nch = obuf->cmax - obuf->cmin + 1; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": bcopy "); dbg_putu(scount); dbg_puts(" fr / "); dbg_putu(nch); dbg_puts(" ch\n"); } #endif /* * Partially copy structures into local variables, to avoid * unnecessary indirections; this also allows the compiler to * order local variables more "cache-friendly". */ ibps = p->u.conv.bps; ibnext = p->u.conv.bnext; isigbit = p->u.conv.sigbit; ishift = p->u.conv.shift; isnext = p->u.conv.snext; /* * Start conversion. */ idata += p->u.conv.bfirst; for (f = scount * nch; f > 0; f--) { for (i = ibps; i > 0; i--) { s <<= 8; s |= *idata; idata += ibnext; } idata += isnext; s ^= isigbit; s <<= ishift; s >>= 32 - ADATA_BITS; *odata++ = s; } /* * Update FIFO pointers. */ abuf_rdiscard(ibuf, scount); abuf_wcommit(obuf, scount); } int dec_in(struct aproc *p, struct abuf *ibuf) { struct abuf *obuf = LIST_FIRST(&p->outs); if (!ABUF_WOK(obuf) || !ABUF_ROK(ibuf)) return 0; dec_bcopy(p, ibuf, obuf); if (!abuf_flush(obuf)) return 0; return 1; } int dec_out(struct aproc *p, struct abuf *obuf) { struct abuf *ibuf = LIST_FIRST(&p->ins); if (!abuf_fill(ibuf)) return 0; if (!ABUF_WOK(obuf) || !ABUF_ROK(ibuf)) return 0; dec_bcopy(p, ibuf, obuf); return 1; } void dec_eof(struct aproc *p, struct abuf *ibuf) { aproc_del(p); } void dec_hup(struct aproc *p, struct abuf *obuf) { aproc_del(p); } struct aproc_ops dec_ops = { "dec", dec_in, dec_out, dec_eof, dec_hup, NULL, NULL, aproc_ipos, aproc_opos, NULL }; struct aproc * dec_new(char *name, struct aparams *par) { struct aproc *p; p = aproc_new(&dec_ops, name); p->u.conv.bps = par->bps; p->u.conv.sigbit = par->sig ? 0 : 1 << (par->bits - 1); if (par->msb) { p->u.conv.shift = 32 - par->bps * 8; } else { p->u.conv.shift = 32 - par->bits; } if (par->le) { p->u.conv.bfirst = par->bps - 1; p->u.conv.bnext = -1; p->u.conv.snext = 2 * par->bps; } else { p->u.conv.bfirst = 0; p->u.conv.bnext = 1; p->u.conv.snext = 0; } #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": new "); aparams_dbg(par); dbg_puts("\n"); } #endif return p; } /* * Convert one block. */ void join_bcopy(struct aproc *p, struct abuf *ibuf, struct abuf *obuf) { unsigned h, hops; unsigned inch, inext; adata_t *idata; unsigned onch, onext; adata_t *odata; int scale; unsigned c, f, scount, icount, ocount; /* * Calculate max frames readable at once from the input buffer. */ idata = (adata_t *)abuf_rgetblk(ibuf, &icount, 0); if (icount == 0) return; odata = (adata_t *)abuf_wgetblk(obuf, &ocount, 0); if (ocount == 0) return; scount = icount < ocount ? icount : ocount; inch = ibuf->cmax - ibuf->cmin + 1; onch = obuf->cmax - obuf->cmin + 1; if (2 * inch <= onch) { hops = onch / inch; inext = inch * hops; onext = onch - inext; for (f = scount; f > 0; f--) { h = hops; for (;;) { for (c = inch; c > 0; c--) *odata++ = *idata++; if (--h == 0) break; idata -= inch; } for (c = onext; c > 0; c--) *odata++ = 0; } } else if (inch >= 2 * onch) { hops = inch / onch; inext = inch - onch * hops; scale = ADATA_UNIT / hops; inch -= onch + inext; hops--; for (f = scount; f > 0; f--) { for (c = onch; c > 0; c--) *odata++ = ADATA_MUL(*idata++, scale); for (h = hops; h > 0; h--) { odata -= onch; for (c = onch; c > 0; c--) *odata++ += ADATA_MUL(*idata++, scale); } idata += inext; } } else { #ifdef DEBUG aproc_dbg(p); dbg_puts(": nothing to do\n"); dbg_panic(); #endif } #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": bcopy "); dbg_putu(scount); dbg_puts(" fr\n"); } #endif abuf_rdiscard(ibuf, scount); abuf_wcommit(obuf, scount); } int join_in(struct aproc *p, struct abuf *ibuf) { struct abuf *obuf = LIST_FIRST(&p->outs); if (!ABUF_WOK(obuf) || !ABUF_ROK(ibuf)) return 0; join_bcopy(p, ibuf, obuf); if (!abuf_flush(obuf)) return 0; return 1; } int join_out(struct aproc *p, struct abuf *obuf) { struct abuf *ibuf = LIST_FIRST(&p->ins); if (!abuf_fill(ibuf)) return 0; if (!ABUF_WOK(obuf) || !ABUF_ROK(ibuf)) return 0; join_bcopy(p, ibuf, obuf); return 1; } void join_eof(struct aproc *p, struct abuf *ibuf) { aproc_del(p); } void join_hup(struct aproc *p, struct abuf *obuf) { aproc_del(p); } struct aproc_ops join_ops = { "join", join_in, join_out, join_eof, join_hup, NULL, NULL, aproc_ipos, aproc_opos, NULL }; struct aproc * join_new(char *name) { struct aproc *p; p = aproc_new(&join_ops, name); #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": new\n"); } #endif return p; } /* * Commit and flush part of the output buffer */ void mon_flush(struct aproc *p) { struct abuf *obuf = LIST_FIRST(&p->outs); unsigned count; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": delta = "); dbg_puti(p->u.mon.delta); dbg_puts("/"); dbg_putu(p->u.mon.bufsz); dbg_puts(" pending = "); dbg_puti(p->u.mon.pending); dbg_puts("\n"); } #endif if (p->u.mon.delta <= 0 || p->u.mon.pending == 0) return; count = p->u.mon.delta; if (count > p->u.mon.pending) count = p->u.mon.pending; abuf_wcommit(obuf, count); p->u.mon.pending -= count; p->u.mon.delta -= count; abuf_flush(obuf); } /* * Copy one block. */ void mon_snoop(struct aproc *p, struct abuf *ibuf, unsigned pos, unsigned todo) { struct abuf *obuf = LIST_FIRST(&p->outs); unsigned scount, icount, ocount; adata_t *idata, *odata; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": snooping "); dbg_putu(pos); dbg_puts(".."); dbg_putu(todo); dbg_puts("\n"); } #endif if (!abuf_flush(obuf)) return; while (todo > 0) { /* * Calculate max frames readable at once from the input buffer. */ idata = (adata_t *)abuf_rgetblk(ibuf, &icount, pos); odata = (adata_t *)abuf_wgetblk(obuf, &ocount, p->u.mon.pending); scount = (icount < ocount) ? icount : ocount; #ifdef DEBUG if (debug_level >= 4) { aproc_dbg(p); dbg_puts(": snooping "); dbg_putu(scount); dbg_puts(" fr\n"); } if (scount == 0) { dbg_puts("monitor xrun, not allowed\n"); dbg_panic(); } #endif memcpy(odata, idata, scount * obuf->bpf); p->u.mon.pending += scount; todo -= scount; pos += scount; } mon_flush(p); } int mon_in(struct aproc *p, struct abuf *ibuf) { #ifdef DEBUG dbg_puts("monitor can't have inputs to read\n"); dbg_panic(); #endif return 0; } /* * put the monitor into ``empty'' state */ void mon_clear(struct aproc *p) { p->u.mon.pending = 0; p->u.mon.delta = 0; } int mon_out(struct aproc *p, struct abuf *obuf) { /* * can't trigger monitored stream to produce data */ return 0; } void mon_eof(struct aproc *p, struct abuf *ibuf) { #ifdef DEBUG dbg_puts("monitor can't have inputs to eof\n"); dbg_panic(); #endif } void mon_hup(struct aproc *p, struct abuf *obuf) { aproc_del(p); } void mon_ipos(struct aproc *p, struct abuf *ibuf, int delta) { aproc_ipos(p, ibuf, delta); p->u.mon.delta += delta; mon_flush(p); } struct aproc_ops mon_ops = { "mon", mon_in, mon_out, mon_eof, mon_hup, NULL, NULL, mon_ipos, aproc_opos, NULL }; struct aproc * mon_new(char *name, unsigned bufsz) { struct aproc *p; p = aproc_new(&mon_ops, name); p->u.mon.pending = 0; p->u.mon.delta = 0; p->u.mon.bufsz = bufsz; #ifdef DEBUG if (debug_level >= 3) { aproc_dbg(p); dbg_puts(": new\n"); } #endif return p; }