/* $OpenBSD: sock.c,v 1.33 2009/10/22 21:41:30 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. */ /* * TODO: * * change f->bufsz to contain only socket-side buffer, * because it's less error prone */ #include #include #include #include "abuf.h" #include "aproc.h" #include "conf.h" #include "dev.h" #include "midi.h" #include "opt.h" #include "sock.h" int sock_attach(struct sock *, int); int sock_read(struct sock *); int sock_write(struct sock *); int sock_execmsg(struct sock *); void sock_reset(struct sock *); struct fileops sock_ops = { "sock", sizeof(struct sock), pipe_close, pipe_read, pipe_write, NULL, /* start */ NULL, /* stop */ pipe_nfds, pipe_pollfd, pipe_revents }; void rsock_done(struct aproc *p) { struct sock *f = (struct sock *)p->u.io.file; if (f == NULL) return; sock_reset(f); f->pipe.file.rproc = NULL; if (f->pipe.file.wproc) { if (dev_midi && f->slot >= 0) ctl_slotdel(dev_midi, f->slot); aproc_del(f->pipe.file.wproc); file_del(&f->pipe.file); } p->u.io.file = NULL; } int rsock_in(struct aproc *p, struct abuf *ibuf_dummy) { struct sock *f = (struct sock *)p->u.io.file; struct abuf *obuf; if (!sock_read(f)) return 0; obuf = LIST_FIRST(&p->obuflist); if (obuf) { if (!abuf_flush(obuf)) return 0; } return 1; } int rsock_out(struct aproc *p, struct abuf *obuf) { struct sock *f = (struct sock *)p->u.io.file; if (f->pipe.file.state & FILE_RINUSE) return 0; /* * When calling sock_read(), we may receive a ``STOP'' command, * and detach ``obuf''. In this case, there's no more caller and * we'll stop processing further messages, resulting in a deadlock. * The solution is to iterate over sock_read() in order to * consume all messages(). */ for (;;) { if (!sock_read(f)) return 0; } return 1; } void rsock_eof(struct aproc *p, struct abuf *ibuf_dummy) { aproc_del(p); } void rsock_hup(struct aproc *p, struct abuf *ibuf) { aproc_del(p); } void rsock_opos(struct aproc *p, struct abuf *obuf, int delta) { struct sock *f = (struct sock *)p->u.io.file; if (f->mode & AMSG_REC) return; f->delta += delta; f->tickpending++; for (;;) { if (!sock_write(f)) break; } } struct aproc_ops rsock_ops = { "rsock", rsock_in, rsock_out, rsock_eof, rsock_hup, NULL, /* newin */ NULL, /* newout */ NULL, /* ipos */ rsock_opos, rsock_done }; void wsock_done(struct aproc *p) { struct sock *f = (struct sock *)p->u.io.file; if (f == NULL) return; sock_reset(f); f->pipe.file.wproc = NULL; if (f->pipe.file.rproc) { if (dev_midi && f->slot >= 0) ctl_slotdel(dev_midi, f->slot); aproc_del(f->pipe.file.rproc); file_del(&f->pipe.file); } p->u.io.file = NULL; } int wsock_in(struct aproc *p, struct abuf *ibuf) { struct sock *f = (struct sock *)p->u.io.file; if (f->pipe.file.state & FILE_WINUSE) return 0; /* * See remark in rsock_out(). */ for (;;) { if (!sock_write(f)) return 0; } return 1; } int wsock_out(struct aproc *p, struct abuf *obuf_dummy) { struct abuf *ibuf = LIST_FIRST(&p->ibuflist); struct sock *f = (struct sock *)p->u.io.file; if (ibuf) { if (!abuf_fill(ibuf)) return 0; } if (!sock_write(f)) return 0; return 1; } void wsock_eof(struct aproc *p, struct abuf *obuf) { aproc_del(p); } void wsock_hup(struct aproc *p, struct abuf *obuf_dummy) { aproc_del(p); } void wsock_ipos(struct aproc *p, struct abuf *obuf, int delta) { struct sock *f = (struct sock *)p->u.io.file; if (!(f->mode & AMSG_REC)) return; f->delta += delta; f->tickpending++; for (;;) { if (!sock_write(f)) break; } } struct aproc_ops wsock_ops = { "wsock", wsock_in, wsock_out, wsock_eof, wsock_hup, NULL, /* newin */ NULL, /* newout */ wsock_ipos, NULL, /* opos */ wsock_done }; /* * Initialise socket in the SOCK_HELLO state with default * parameters. */ struct sock * sock_new(struct fileops *ops, int fd) { struct aproc *rproc, *wproc; struct sock *f; f = (struct sock *)pipe_new(ops, fd, "sock"); if (f == NULL) return NULL; f->pstate = SOCK_HELLO; f->mode = 0; f->opt = opt_byname("default"); if (f->opt) { if (dev_sub) f->wpar = f->opt->wpar; if (dev_mix) f->rpar = f->opt->rpar; } f->xrun = AMSG_IGNORE; f->bufsz = dev_bufsz; f->round = dev_round; f->delta = 0; f->tickpending = 0; f->vol = f->lastvol = MIDI_MAXCTL; f->slot = -1; wproc = aproc_new(&wsock_ops, f->pipe.file.name); wproc->u.io.file = &f->pipe.file; f->pipe.file.wproc = wproc; f->wstate = SOCK_WIDLE; f->wtodo = 0xdeadbeef; rproc = aproc_new(&rsock_ops, f->pipe.file.name); rproc->u.io.file = &f->pipe.file; f->pipe.file.rproc = rproc; f->rstate = SOCK_RMSG; f->rtodo = sizeof(struct amsg); return f; } /* * Free buffers. */ void sock_freebuf(struct sock *f) { struct abuf *rbuf, *wbuf; f->pstate = SOCK_INIT; rbuf = LIST_FIRST(&f->pipe.file.rproc->obuflist); if (rbuf) abuf_eof(rbuf); wbuf = LIST_FIRST(&f->pipe.file.wproc->ibuflist); if (wbuf) abuf_hup(wbuf); f->tickpending = 0; } /* * Allocate buffers, so client can start filling write-end. */ void sock_allocbuf(struct sock *f) { struct abuf *rbuf = NULL, *wbuf = NULL; if (f->mode & AMSG_PLAY) { rbuf = abuf_new(f->bufsz, &f->rpar); aproc_setout(f->pipe.file.rproc, rbuf); } if (f->mode & AMSG_REC) { wbuf = abuf_new(f->bufsz, &f->wpar); aproc_setin(f->pipe.file.wproc, wbuf); } f->delta = 0; f->tickpending = 0; f->pstate = SOCK_START; if (!(f->mode & AMSG_PLAY)) (void)sock_attach(f, 0); } /* * Set volume. Callback invoked when volume is modified externally */ void sock_setvol(void *arg, unsigned vol) { struct sock *f = (struct sock *)arg; struct abuf *rbuf; f->vol = vol; rbuf = LIST_FIRST(&f->pipe.file.rproc->obuflist); if (!rbuf) { return; } dev_setvol(rbuf, MIDI_TO_ADATA(vol)); } /* * Attach play and/or record buffers to dev_mix and/or dev_sub. */ int sock_attach(struct sock *f, int force) { struct abuf *rbuf, *wbuf; rbuf = LIST_FIRST(&f->pipe.file.rproc->obuflist); wbuf = LIST_FIRST(&f->pipe.file.wproc->ibuflist); /* * If in SOCK_START state, dont attach until * the buffer isn't completely filled. */ if (!force && rbuf && ABUF_WOK(rbuf)) return 0; f->pstate = SOCK_RUN; /* * Attach them to the device. */ dev_attach(f->pipe.file.name, (f->mode & AMSG_PLAY) ? rbuf : NULL, &f->rpar, f->xrun, (f->mode & AMSG_REC) ? wbuf : NULL, &f->wpar, f->xrun, f->opt->maxweight); if (f->mode & AMSG_PLAY) dev_setvol(rbuf, MIDI_TO_ADATA(f->vol)); /* * Send the initial position, if needed. */ for (;;) { if (!sock_write(f)) break; } return 1; } void sock_reset(struct sock *f) { switch (f->pstate) { case SOCK_START: (void)sock_attach(f, 1); f->pstate = SOCK_RUN; /* PASSTHROUGH */ case SOCK_RUN: sock_freebuf(f); f->pstate = SOCK_INIT; /* PASSTHROUGH */ case SOCK_INIT: /* nothing yet */ break; } } /* * Read a message from the file descriptor, return 1 if done, 0 * otherwise. The message is stored in f->rmsg. */ int sock_rmsg(struct sock *f) { unsigned count; unsigned char *data; while (f->rtodo > 0) { if (!(f->pipe.file.state & FILE_ROK)) { return 0; } data = (unsigned char *)&f->rmsg; data += sizeof(struct amsg) - f->rtodo; count = file_read(&f->pipe.file, data, f->rtodo); if (count == 0) return 0; f->rtodo -= count; } return 1; } /* * Write a message to the file descriptor, return 1 if done, 0 * otherwise. The "m" argument is f->rmsg or f->wmsg, and the "ptodo" * points to the f->rtodo or f->wtodo respectively. */ int sock_wmsg(struct sock *f, struct amsg *m, unsigned *ptodo) { unsigned count; unsigned char *data; while (*ptodo > 0) { if (!(f->pipe.file.state & FILE_WOK)) { return 0; } data = (unsigned char *)m; data += sizeof(struct amsg) - *ptodo; count = file_write(&f->pipe.file, data, *ptodo); if (count == 0) return 0; *ptodo -= count; } return 1; } /* * Read data chunk from the file descriptor, return 1 if at least one * byte was read, 0 if the file blocked. */ int sock_rdata(struct sock *f) { struct aproc *p; struct abuf *obuf; unsigned char *data; unsigned count, n; p = f->pipe.file.rproc; obuf = LIST_FIRST(&p->obuflist); if (obuf == NULL) return 0; if (ABUF_FULL(obuf) || !(f->pipe.file.state & FILE_ROK)) return 0; data = abuf_wgetblk(obuf, &count, 0); if (f->pstate != SOCK_MIDI && count > f->rtodo) count = f->rtodo; n = file_read(&f->pipe.file, data, count); if (n == 0) return 0; abuf_wcommit(obuf, n); if (f->pstate != SOCK_MIDI) f->rtodo -= n; return 1; } /* * Write data chunk to the file descriptor, return 1 if at least one * byte was written, 0 if the file blocked. */ int sock_wdata(struct sock *f) { struct aproc *p; struct abuf *ibuf; unsigned char *data; unsigned count, n; #define ZERO_MAX 0x1000 static char zero[ZERO_MAX]; if (!(f->pipe.file.state & FILE_WOK)) return 0; p = f->pipe.file.wproc; ibuf = LIST_FIRST(&p->ibuflist); if (ibuf) { if (ABUF_EMPTY(ibuf)) return 0; data = abuf_rgetblk(ibuf, &count, 0); if (f->pstate != SOCK_MIDI && count > f->wtodo) count = f->wtodo; n = file_write(&f->pipe.file, data, count); if (n == 0) return 0; abuf_rdiscard(ibuf, n); if (f->pstate != SOCK_MIDI) f->wtodo -= n; } else { if (f->pstate == SOCK_MIDI) return 0; /* * There's no dev_detach() routine yet, * so now we abruptly destroy the buffer. * Until we implement dev_detach, complete * the packet with zeros... */ count = ZERO_MAX; if (count > f->wtodo) count = f->wtodo; n = file_write(&f->pipe.file, zero, count); if (n == 0) return 0; f->wtodo -= n; } return 1; } int sock_setpar(struct sock *f) { struct amsg_par *p = &f->rmsg.u.par; unsigned min, max, rate; if (AMSG_ISSET(p->bits)) { if (p->bits < BITS_MIN || p->bits > BITS_MAX) { return 0; } if (AMSG_ISSET(p->bps)) { if (p->bps < ((p->bits + 7) / 8) || p->bps > 4) { return 0; } } else p->bps = APARAMS_BPS(p->bits); f->rpar.bits = f->wpar.bits = p->bits; f->rpar.bps = f->wpar.bps = p->bps; } if (AMSG_ISSET(p->sig)) f->rpar.sig = f->wpar.sig = p->sig ? 1 : 0; if (AMSG_ISSET(p->le)) f->rpar.le = f->wpar.le = p->le ? 1 : 0; if (AMSG_ISSET(p->msb)) f->rpar.msb = f->wpar.msb = p->msb ? 1 : 0; if (AMSG_ISSET(p->rchan) && (f->mode & AMSG_REC)) { if (p->rchan < 1) p->rchan = 1; if (p->rchan > NCHAN_MAX) p->rchan = NCHAN_MAX; f->wpar.cmin = f->opt->wpar.cmin; f->wpar.cmax = f->opt->wpar.cmin + p->rchan - 1; if (f->wpar.cmax > f->opt->wpar.cmax) f->wpar.cmax = f->opt->wpar.cmax; } if (AMSG_ISSET(p->pchan) && (f->mode & AMSG_PLAY)) { if (p->pchan < 1) p->pchan = 1; if (p->pchan > NCHAN_MAX) p->pchan = NCHAN_MAX; f->rpar.cmin = f->opt->rpar.cmin; f->rpar.cmax = f->opt->rpar.cmin + p->pchan - 1; if (f->rpar.cmax > f->opt->rpar.cmax) f->rpar.cmax = f->opt->rpar.cmax; } if (AMSG_ISSET(p->rate)) { if (p->rate < RATE_MIN) p->rate = RATE_MIN; if (p->rate > RATE_MAX) p->rate = RATE_MAX; f->round = dev_roundof(p->rate); f->rpar.rate = f->wpar.rate = p->rate; if (!AMSG_ISSET(p->appbufsz)) { p->appbufsz = dev_bufsz / dev_round * f->round; } } if (AMSG_ISSET(p->xrun)) { if (p->xrun != AMSG_IGNORE && p->xrun != AMSG_SYNC && p->xrun != AMSG_ERROR) { return 0; } f->xrun = p->xrun; } if (AMSG_ISSET(p->bufsz)) { /* * XXX: bufsz will become read-only, but for now * allow old library to properly work */ min = (dev_bufsz / dev_round) * f->round; if (p->bufsz < min) p->bufsz = min; p->appbufsz = p->bufsz - min; } if (AMSG_ISSET(p->appbufsz)) { rate = (f->mode & AMSG_PLAY) ? f->rpar.rate : f->wpar.rate; min = 1; max = 1 + rate / dev_round; min *= f->round; max *= f->round; p->appbufsz += f->round - 1; p->appbufsz -= p->appbufsz % f->round; if (p->appbufsz < min) p->appbufsz = min; if (p->appbufsz > max) p->appbufsz = max; f->bufsz = p->appbufsz; } return 1; } /* * allocate buffers, so client can start filling write-end. */ void sock_midiattach(struct sock *f, unsigned mode) { struct abuf *rbuf = NULL, *wbuf = NULL; if (mode & AMSG_MIDIOUT) { rbuf = abuf_new(MIDI_BUFSZ, &aparams_none); aproc_setout(f->pipe.file.rproc, rbuf); } if (mode & AMSG_MIDIIN) { wbuf = abuf_new(MIDI_BUFSZ, &aparams_none); aproc_setin(f->pipe.file.wproc, wbuf); } dev_midiattach(rbuf, wbuf); } int sock_hello(struct sock *f) { struct amsg_hello *p = &f->rmsg.u.hello; if (p->version != AMSG_VERSION) { return 0; } /* * XXX : dev_midi can no longer be NULL, right ? */ if (dev_midi && (p->proto & (AMSG_MIDIIN | AMSG_MIDIOUT))) { if (p->proto & ~(AMSG_MIDIIN | AMSG_MIDIOUT)) { return 0; } f->mode = p->proto; f->pstate = SOCK_MIDI; sock_midiattach(f, p->proto); return 1; } f->opt = opt_byname(p->opt); if (f->opt == NULL) return 0; if (dev_sub) f->wpar = f->opt->wpar; if (dev_mix) f->rpar = f->opt->rpar; if ((p->proto & ~(AMSG_PLAY | AMSG_REC)) != 0 || (p->proto & (AMSG_PLAY | AMSG_REC)) == 0) { return 0; } f->mode = 0; if (p->proto & AMSG_PLAY) { if (!dev_mix) { return 0; } f->mode |= AMSG_PLAY; } if (p->proto & AMSG_REC) { if (!dev_sub) { return 0; } f->mode |= AMSG_REC; } if (dev_midi) { f->slot = ctl_slotnew(dev_midi, p->who, sock_setvol, f); if (f->slot < 0) { return 0; } } f->pstate = SOCK_INIT; return 1; } /* * Execute message in f->rmsg and change the state accordingly; return 1 * on success, and 0 on failure, in which case the socket is destroyed. */ int sock_execmsg(struct sock *f) { struct amsg *m = &f->rmsg; switch (m->cmd) { case AMSG_DATA: if (f->pstate != SOCK_RUN && f->pstate != SOCK_START) { aproc_del(f->pipe.file.rproc); return 0; } if (!(f->mode & AMSG_PLAY)) { aproc_del(f->pipe.file.rproc); return 0; } f->rstate = SOCK_RDATA; f->rtodo = m->u.data.size; if (f->rtodo == 0) { aproc_del(f->pipe.file.rproc); return 0; } break; case AMSG_START: if (f->pstate != SOCK_INIT) { aproc_del(f->pipe.file.rproc); return 0; } sock_allocbuf(f); f->rstate = SOCK_RMSG; f->rtodo = sizeof(struct amsg); break; case AMSG_STOP: if (f->pstate != SOCK_RUN && f->pstate != SOCK_START) { aproc_del(f->pipe.file.rproc); return 0; } if (f->pstate == SOCK_START) (void)sock_attach(f, 1); sock_freebuf(f); AMSG_INIT(m); m->cmd = AMSG_ACK; f->rstate = SOCK_RRET; f->rtodo = sizeof(struct amsg); break; case AMSG_SETPAR: if (f->pstate != SOCK_INIT) { aproc_del(f->pipe.file.rproc); return 0; } if (!sock_setpar(f)) { aproc_del(f->pipe.file.rproc); return 0; } f->rtodo = sizeof(struct amsg); f->rstate = SOCK_RMSG; break; case AMSG_GETPAR: if (f->pstate != SOCK_INIT) { aproc_del(f->pipe.file.rproc); return 0; } AMSG_INIT(m); m->cmd = AMSG_GETPAR; m->u.par.legacy_mode = f->mode; m->u.par.bits = f->rpar.bits; m->u.par.bps = f->rpar.bps; m->u.par.sig = f->rpar.sig; m->u.par.le = f->rpar.le; m->u.par.msb = f->rpar.msb; m->u.par.rate = f->rpar.rate; m->u.par.rchan = f->wpar.cmax - f->wpar.cmin + 1; m->u.par.pchan = f->rpar.cmax - f->rpar.cmin + 1; m->u.par.appbufsz = f->bufsz; m->u.par.bufsz = f->bufsz + (dev_bufsz / dev_round) * f->round; m->u.par.round = f->round; f->rstate = SOCK_RRET; f->rtodo = sizeof(struct amsg); break; case AMSG_GETCAP: if (f->pstate != SOCK_INIT) { aproc_del(f->pipe.file.rproc); return 0; } AMSG_INIT(m); m->cmd = AMSG_GETCAP; m->u.cap.rate = dev_rate; m->u.cap.pchan = dev_mix ? (f->opt->rpar.cmax - f->opt->rpar.cmin + 1) : 0; m->u.cap.rchan = dev_sub ? (f->opt->wpar.cmax - f->opt->wpar.cmin + 1) : 0; m->u.cap.bits = sizeof(short) * 8; m->u.cap.bps = sizeof(short); f->rstate = SOCK_RRET; f->rtodo = sizeof(struct amsg); break; case AMSG_SETVOL: if (f->pstate != SOCK_RUN && f->pstate != SOCK_START && f->pstate != SOCK_INIT) { aproc_del(f->pipe.file.rproc); return 0; } if (m->u.vol.ctl > MIDI_MAXCTL) { aproc_del(f->pipe.file.rproc); return 0; } sock_setvol(f, m->u.vol.ctl); if (dev_midi && f->slot >= 0) ctl_slotvol(dev_midi, f->slot, m->u.vol.ctl); f->rtodo = sizeof(struct amsg); f->rstate = SOCK_RMSG; break; case AMSG_HELLO: if (f->pstate != SOCK_HELLO) { aproc_del(f->pipe.file.rproc); return 0; } if (!sock_hello(f)) { aproc_del(f->pipe.file.rproc); return 0; } AMSG_INIT(m); m->cmd = AMSG_ACK; f->rstate = SOCK_RRET; f->rtodo = sizeof(struct amsg); break; case AMSG_BYE: if (f->pstate != SOCK_INIT) { } aproc_del(f->pipe.file.rproc); return 0; default: aproc_del(f->pipe.file.rproc); return 0; } if (f->rstate == SOCK_RRET) { if (f->wstate != SOCK_WIDLE || !sock_wmsg(f, &f->rmsg, &f->rtodo)) return 0; if (f->pstate == SOCK_MIDI && (f->mode & AMSG_MIDIOUT)) { f->rstate = SOCK_RDATA; f->rtodo = 0; } else { f->rstate = SOCK_RMSG; f->rtodo = sizeof(struct amsg); } } return 1; } /* * Create a new data/pos message. */ int sock_buildmsg(struct sock *f) { struct aproc *p; struct abuf *ibuf; if (f->pstate == SOCK_MIDI) { f->wstate = SOCK_WDATA; f->wtodo = 0; return 1; } /* * If pos changed, build a MOVE message. */ if (f->tickpending) { AMSG_INIT(&f->wmsg); f->wmsg.cmd = AMSG_MOVE; f->wmsg.u.ts.delta = f->delta; f->wtodo = sizeof(struct amsg); f->wstate = SOCK_WMSG; f->delta = 0; f->tickpending = 0; return 1; } /* * if volume changed build a SETVOL message */ if (f->pstate >= SOCK_START && f->vol != f->lastvol) { AMSG_INIT(&f->wmsg); f->wmsg.cmd = AMSG_SETVOL; f->wmsg.u.vol.ctl = f->vol; f->wtodo = sizeof(struct amsg); f->wstate = SOCK_WMSG; f->lastvol = f->vol; return 1; } /* * If data available, build a DATA message. */ p = f->pipe.file.wproc; ibuf = LIST_FIRST(&p->ibuflist); if (ibuf && ABUF_ROK(ibuf)) { AMSG_INIT(&f->wmsg); f->wmsg.cmd = AMSG_DATA; f->wmsg.u.data.size = ibuf->used - (ibuf->used % ibuf->bpf); if (f->wmsg.u.data.size > AMSG_DATAMAX) f->wmsg.u.data.size = AMSG_DATAMAX - (AMSG_DATAMAX % ibuf->bpf); f->wtodo = sizeof(struct amsg); f->wstate = SOCK_WMSG; return 1; } f->wstate = SOCK_WIDLE; return 0; } /* * Read from the socket file descriptor, fill input buffer and update * the state. Return 1 if at least one message or 1 data byte was * processed, 0 if something blocked. */ int sock_read(struct sock *f) { switch (f->rstate) { case SOCK_RMSG: if (!sock_rmsg(f)) return 0; if (!sock_execmsg(f)) return 0; break; case SOCK_RDATA: if (!sock_rdata(f)) return 0; if (f->pstate != SOCK_MIDI && f->rtodo == 0) { f->rstate = SOCK_RMSG; f->rtodo = sizeof(struct amsg); } if (f->pstate == SOCK_START) (void)sock_attach(f, 0); break; case SOCK_RRET: return 0; } return 1; } /* * Process messages to return. */ int sock_return(struct sock *f) { struct aproc *rp; while (f->rstate == SOCK_RRET) { if (!sock_wmsg(f, &f->rmsg, &f->rtodo)) return 0; if (f->pstate == SOCK_MIDI && (f->mode & AMSG_MIDIOUT)) { f->rstate = SOCK_RDATA; f->rtodo = 0; } else { f->rstate = SOCK_RMSG; f->rtodo = sizeof(struct amsg); } if (f->pipe.file.state & FILE_RINUSE) break; f->pipe.file.state |= FILE_RINUSE; for (;;) { /* * in() may trigger rsock_done and destroy the * wsock. */ rp = f->pipe.file.rproc; if (!rp || !rp->ops->in(rp, NULL)) break; } f->pipe.file.state &= ~FILE_RINUSE; if (f->pipe.file.wproc == NULL) return 0; } return 1; } /* * Write messages and data on the socket file descriptor. Return 1 if * at least one message or one data byte was processed, 0 if something * blocked. */ int sock_write(struct sock *f) { switch (f->wstate) { case SOCK_WMSG: if (!sock_wmsg(f, &f->wmsg, &f->wtodo)) return 0; if (f->wmsg.cmd != AMSG_DATA) { f->wstate = SOCK_WIDLE; f->wtodo = 0xdeadbeef; break; } f->wstate = SOCK_WDATA; f->wtodo = f->wmsg.u.data.size; /* PASSTHROUGH */ case SOCK_WDATA: if (!sock_wdata(f)) return 0; if (f->pstate == SOCK_MIDI || f->wtodo > 0) break; f->wstate = SOCK_WIDLE; f->wtodo = 0xdeadbeef; /* PASSTHROUGH */ case SOCK_WIDLE: if (!sock_return(f)) return 0; if (!sock_buildmsg(f)) return 0; break; } return 1; }