ref: 42dfac6916ebbdac65cbec8b3e1a80c3ee41423c
dir: /emu/port/qio.c/
#include "dat.h" #include "fns.h" #include "error.h" #define QDEBUG if(0) /* * IO queues */ struct Queue { Lock l; Block* bfirst; /* buffer */ Block* blast; int len; /* bytes allocated to queue */ int dlen; /* data bytes in queue */ int limit; /* max bytes in queue */ int inilim; /* initial limit */ int state; int noblock; /* true if writes return immediately when q full */ int eof; /* number of eofs read by user */ void (*kick)(void*); /* restart output */ void (*bypass)(void*, Block*); /* bypass queue altogether */ void* arg; /* argument to kick */ QLock rlock; /* mutex for reading processes */ Rendez rr; /* process waiting to read */ QLock wlock; /* mutex for writing processes */ Rendez wr; /* process waiting to write */ char err[ERRMAX]; int want; }; enum { Maxatomic = 32*1024 }; uint qiomaxatomic = Maxatomic; void checkb(Block *b, char *msg) { if(b->base > b->lim) panic("checkb 0 %s %lux %lux", msg, b->base, b->lim); if(b->rp < b->base) panic("checkb 1 %s %lux %lux", msg, b->base, b->rp); if(b->wp < b->base) panic("checkb 2 %s %lux %lux", msg, b->base, b->wp); if(b->rp > b->lim) panic("checkb 3 %s %lux %lux", msg, b->rp, b->lim); if(b->wp > b->lim) panic("checkb 4 %s %lux %lux", msg, b->wp, b->lim); } void freeb(Block *b) { if(b == nil) return; /* * drivers which perform non cache coherent DMA manage their own buffer * pool of uncached buffers and provide their own free routine. */ if(b->free) { b->free(b); return; } /* poison the block in case someone is still holding onto it */ b->next = (void*)0xdeadbabe; b->rp = (void*)0xdeadbabe; b->wp = (void*)0xdeadbabe; b->lim = (void*)0xdeadbabe; b->base = (void*)0xdeadbabe; free(b); } /* * free a list of blocks */ void freeblist(Block *b) { Block *next; for(; b != 0; b = next){ next = b->next; b->next = 0; freeb(b); } } ulong padblockoverhead; /* * pad a block to the front (or the back if size is negative) */ Block* padblock(Block *bp, int size) { int n; Block *nbp; if(size >= 0){ if(bp->rp - bp->base >= size){ bp->rp -= size; return bp; } if(bp->next) panic("padblock 0x%luX", getcallerpc(&bp)); n = BLEN(bp); padblockoverhead += n; nbp = allocb(size+n); nbp->rp += size; nbp->wp = nbp->rp; memmove(nbp->wp, bp->rp, n); nbp->wp += n; freeb(bp); nbp->rp -= size; } else { size = -size; if(bp->next) panic("padblock 0x%luX", getcallerpc(&bp)); if(bp->lim - bp->wp >= size) return bp; n = BLEN(bp); padblockoverhead += n; nbp = allocb(size+n); memmove(nbp->wp, bp->rp, n); nbp->wp += n; freeb(bp); } return nbp; } /* * return count of bytes in a string of blocks */ int blocklen(Block *bp) { int len; len = 0; while(bp) { len += BLEN(bp); bp = bp->next; } return len; } /* * return count of space in blocks */ int blockalloclen(Block *bp) { int len; len = 0; while(bp) { len += BALLOC(bp); bp = bp->next; } return len; } /* * copy the string of blocks into * a single block and free the string */ Block* concatblock(Block *bp) { int len; Block *nb, *f; if(bp->next == 0) return bp; nb = allocb(blocklen(bp)); for(f = bp; f; f = f->next) { len = BLEN(f); memmove(nb->wp, f->rp, len); nb->wp += len; } freeblist(bp); return nb; } /* * make sure the first block has at least n bytes. If we started with * less than n bytes, make sure we have exactly n bytes. devssl.c depends * on this. */ Block* pullupblock(Block *bp, int n) { int i; Block *nbp; /* * this should almost always be true, the rest it * just to avoid every caller checking. */ if(BLEN(bp) >= n) return bp; /* * if not enough room in the first block, * add another to the front of the list. */ if(bp->lim - bp->rp < n){ nbp = allocb(n); nbp->next = bp; bp = nbp; } /* * copy bytes from the trailing blocks into the first */ n -= BLEN(bp); while(nbp = bp->next){ i = BLEN(nbp); if(i > n) { memmove(bp->wp, nbp->rp, n); bp->wp += n; nbp->rp += n; return bp; } else { memmove(bp->wp, nbp->rp, i); bp->wp += i; bp->next = nbp->next; nbp->next = 0; freeb(nbp); n -= i; if(n == 0) return bp; } } freeblist(bp); return 0; } /* * make sure the first block has at least n bytes */ Block* pullupqueue(Queue *q, int n) { Block *b; if(BLEN(q->bfirst) >= n) return q->bfirst; q->bfirst = pullupblock(q->bfirst, n); for(b = q->bfirst; b != nil && b->next != nil; b = b->next) ; q->blast = b; return q->bfirst; } /* * trim to len bytes starting at offset */ Block * trimblock(Block *bp, int offset, int len) { ulong l; Block *nb, *startb; if(blocklen(bp) < offset+len) { freeblist(bp); return nil; } while((l = BLEN(bp)) < offset) { offset -= l; nb = bp->next; bp->next = nil; freeb(bp); bp = nb; } startb = bp; bp->rp += offset; while((l = BLEN(bp)) < len) { len -= l; bp = bp->next; } bp->wp -= (BLEN(bp) - len); if(bp->next) { freeblist(bp->next); bp->next = nil; } return startb; } /* * copy 'count' bytes into a new block */ Block* copyblock(Block *bp, int count) { int l; Block *nbp; nbp = allocb(count); for(; count > 0 && bp != 0; bp = bp->next){ l = BLEN(bp); if(l > count) l = count; memmove(nbp->wp, bp->rp, l); nbp->wp += l; count -= l; } if(count > 0){ memset(nbp->wp, 0, count); nbp->wp += count; } return nbp; } Block* adjustblock(Block* bp, int len) { int n; Block *nbp; if(len < 0){ freeb(bp); return nil; } if(bp->rp+len > bp->lim){ nbp = copyblock(bp, len); freeblist(bp); QDEBUG checkb(nbp, "adjustblock 1"); return nbp; } n = BLEN(bp); if(len > n) memset(bp->wp, 0, len-n); bp->wp = bp->rp+len; QDEBUG checkb(bp, "adjustblock 2"); return bp; } /* * throw away up to count bytes from a * list of blocks. Return count of bytes * thrown away. */ int pullblock(Block **bph, int count) { Block *bp; int n, bytes; bytes = 0; if(bph == nil) return 0; while(*bph != nil && count != 0) { bp = *bph; n = BLEN(bp); if(count < n) n = count; bytes += n; count -= n; bp->rp += n; if(BLEN(bp) == 0) { *bph = bp->next; bp->next = nil; freeb(bp); } } return bytes; } /* * allocate queues and blocks (round data base address to 64 bit boundary) */ Block* iallocb(int size) { Block *b; ulong addr; b = kmalloc(sizeof(Block)+size); if(b == 0) return 0; memset(b, 0, sizeof(Block)); addr = (ulong)b + sizeof(Block); b->base = (uchar*)addr; b->lim = b->base + size; b->rp = b->base; b->wp = b->rp; return b; } /* * call error if iallocb fails */ Block* allocb(int size) { Block *b; b = iallocb(size); if(b == 0) exhausted("allocb"); return b; } /* * get next block from a queue, return null if nothing there */ Block* qget(Queue *q) { int dowakeup; Block *b; /* sync with qwrite */ lock(&q->l); b = q->bfirst; if(b == 0){ q->state |= Qstarve; unlock(&q->l); return 0; } q->bfirst = b->next; b->next = 0; q->len -= BALLOC(b); q->dlen -= BLEN(b); QDEBUG checkb(b, "qget"); /* if writer flow controlled, restart */ if((q->state & Qflow) && q->len < q->limit/2){ q->state &= ~Qflow; dowakeup = 1; } else dowakeup = 0; unlock(&q->l); if(dowakeup) Wakeup(&q->wr); return b; } /* * throw away the next 'len' bytes in the queue */ int qdiscard(Queue *q, int len) { Block *b; int dowakeup, n, sofar; lock(&q->l); for(sofar = 0; sofar < len; sofar += n){ b = q->bfirst; if(b == nil) break; QDEBUG checkb(b, "qdiscard"); n = BLEN(b); if(n <= len - sofar){ q->bfirst = b->next; b->next = 0; q->len -= BALLOC(b); q->dlen -= BLEN(b); freeb(b); } else { n = len - sofar; b->rp += n; q->dlen -= n; } } /* if writer flow controlled, restart */ if((q->state & Qflow) && q->len < q->limit){ q->state &= ~Qflow; dowakeup = 1; } else dowakeup = 0; unlock(&q->l); if(dowakeup) Wakeup(&q->wr); return sofar; } /* * Interrupt level copy out of a queue, return # bytes copied. */ int qconsume(Queue *q, void *vp, int len) { Block *b; int n, dowakeup; uchar *p = vp; Block *tofree = nil; /* sync with qwrite */ lock(&q->l); for(;;) { b = q->bfirst; if(b == 0){ q->state |= Qstarve; unlock(&q->l); return -1; } QDEBUG checkb(b, "qconsume 1"); n = BLEN(b); if(n > 0) break; q->bfirst = b->next; q->len -= BALLOC(b); /* remember to free this */ b->next = tofree; tofree = b; } if(n < len) len = n; memmove(p, b->rp, len); if((q->state & Qmsg) || len == n) q->bfirst = b->next; b->rp += len; q->dlen -= len; /* discard the block if we're done with it */ if((q->state & Qmsg) || len == n){ b->next = 0; q->len -= BALLOC(b); q->dlen -= BLEN(b); /* remember to free this */ b->next = tofree; tofree = b; } /* if writer flow controlled, restart */ if((q->state & Qflow) && q->len < q->limit/2){ q->state &= ~Qflow; dowakeup = 1; } else dowakeup = 0; unlock(&q->l); if(dowakeup) Wakeup(&q->wr); if(tofree != nil) freeblist(tofree); return len; } int qpass(Queue *q, Block *b) { int dlen, len, dowakeup; /* sync with qread */ dowakeup = 0; lock(&q->l); if(q->len >= q->limit){ unlock(&q->l); freeblist(b); return -1; } if(q->state & Qclosed){ unlock(&q->l); len = blocklen(b); freeblist(b); return len; } /* add buffer to queue */ if(q->bfirst) q->blast->next = b; else q->bfirst = b; len = BALLOC(b); dlen = BLEN(b); QDEBUG checkb(b, "qpass"); while(b->next){ b = b->next; QDEBUG checkb(b, "qpass"); len += BALLOC(b); dlen += BLEN(b); } q->blast = b; q->len += len; q->dlen += dlen; if(q->len >= q->limit/2) q->state |= Qflow; if(q->state & Qstarve){ q->state &= ~Qstarve; dowakeup = 1; } unlock(&q->l); if(dowakeup) Wakeup(&q->rr); return len; } int qpassnolim(Queue *q, Block *b) { int dlen, len, dowakeup; /* sync with qread */ dowakeup = 0; lock(&q->l); len = BALLOC(b); if(q->state & Qclosed){ unlock(&q->l); freeblist(b); return len; } /* add buffer to queue */ if(q->bfirst) q->blast->next = b; else q->bfirst = b; dlen = BLEN(b); QDEBUG checkb(b, "qpass"); while(b->next){ b = b->next; QDEBUG checkb(b, "qpass"); len += BALLOC(b); dlen += BLEN(b); } q->blast = b; q->len += len; q->dlen += dlen; if(q->len >= q->limit/2) q->state |= Qflow; if(q->state & Qstarve){ q->state &= ~Qstarve; dowakeup = 1; } unlock(&q->l); if(dowakeup) Wakeup(&q->rr); return len; } /* * if the allocated space is way out of line with the used * space, reallocate to a smaller block */ Block* packblock(Block *bp) { Block **l, *nbp; int n; for(l = &bp; *l; l = &(*l)->next){ nbp = *l; n = BLEN(nbp); if((n<<2) < BALLOC(nbp)){ *l = allocb(n); memmove((*l)->wp, nbp->rp, n); (*l)->wp += n; (*l)->next = nbp->next; freeb(nbp); } } return bp; } int qproduce(Queue *q, void *vp, int len) { Block *b; int dowakeup; uchar *p = vp; /* sync with qread */ dowakeup = 0; lock(&q->l); if(q->state & Qclosed){ unlock(&q->l); return -1; } /* no waiting receivers, room in buffer? */ if(q->len >= q->limit){ q->state |= Qflow; unlock(&q->l); return -1; } /* save in buffer */ b = iallocb(len); if(b == 0){ unlock(&q->l); print("qproduce: iallocb failed\n"); return -1; } memmove(b->wp, p, len); b->wp += len; if(q->bfirst) q->blast->next = b; else q->bfirst = b; q->blast = b; /* b->next = 0; done by allocb() */ q->len += BALLOC(b); q->dlen += BLEN(b); QDEBUG checkb(b, "qproduce"); if(q->state & Qstarve){ q->state &= ~Qstarve; dowakeup = 1; } if(q->len >= q->limit) q->state |= Qflow; unlock(&q->l); if(dowakeup) Wakeup(&q->rr); return len; } /* * copy from offset in the queue */ Block* qcopy(Queue *q, int len, ulong offset) { int sofar; int n; Block *b, *nb; uchar *p; nb = allocb(len); lock(&q->l); /* go to offset */ b = q->bfirst; for(sofar = 0; ; sofar += n){ if(b == nil){ unlock(&q->l); return nb; } n = BLEN(b); if(sofar + n > offset){ p = b->rp + offset - sofar; n -= offset - sofar; break; } b = b->next; } /* copy bytes from there */ for(sofar = 0; sofar < len;){ if(n > len - sofar) n = len - sofar; memmove(nb->wp, p, n); sofar += n; nb->wp += n; b = b->next; if(b == nil) break; n = BLEN(b); p = b->rp; } unlock(&q->l); return nb; } /* * called by non-interrupt code */ Queue* qopen(int limit, int msg, void (*kick)(void*), void *arg) { Queue *q; q = kmalloc(sizeof(Queue)); if(q == 0) return 0; q->limit = q->inilim = limit; q->kick = kick; q->arg = arg; q->state = msg; q->state |= Qstarve; q->eof = 0; q->noblock = 0; return q; } /* open a queue to be bypassed */ Queue* qbypass(void (*bypass)(void*, Block*), void *arg) { Queue *q; q = malloc(sizeof(Queue)); if(q == 0) return 0; q->limit = 0; q->arg = arg; q->bypass = bypass; q->state = 0; return q; } static int notempty(void *a) { Queue *q = a; return (q->state & Qclosed) || q->bfirst != 0; } /* * wait for the queue to be non-empty or closed. * called with q ilocked. */ static int qwait(Queue *q) { /* wait for data */ for(;;){ if(q->bfirst != nil) break; if(q->state & Qclosed){ if(++q->eof > 3) return -1; if(*q->err && strcmp(q->err, Ehungup) != 0) return -1; return 0; } q->state |= Qstarve; /* flag requesting producer to wake me */ unlock(&q->l); Sleep(&q->rr, notempty, q); lock(&q->l); } return 1; } /* * add a block list to a queue */ void qaddlist(Queue *q, Block *b) { /* queue the block */ if(q->bfirst) q->blast->next = b; else q->bfirst = b; q->len += blockalloclen(b); q->dlen += blocklen(b); while(b->next) b = b->next; q->blast = b; } /* * called with q locked */ Block* qremove(Queue *q) { Block *b; b = q->bfirst; if(b == nil) return nil; q->bfirst = b->next; b->next = nil; q->dlen -= BLEN(b); q->len -= BALLOC(b); QDEBUG checkb(b, "qremove"); return b; } /* * copy the contents of a string of blocks into * memory. emptied blocks are freed. return * pointer to first unconsumed block. */ Block* bl2mem(uchar *p, Block *b, int n) { int i; Block *next; for(; b != nil; b = next){ i = BLEN(b); if(i > n){ memmove(p, b->rp, n); b->rp += n; return b; } memmove(p, b->rp, i); n -= i; p += i; b->rp += i; next = b->next; freeb(b); } return nil; } /* * copy the contents of memory into a string of blocks. * return nil on error. */ Block* mem2bl(uchar *p, int len) { int n; Block *b, *first, **l; first = nil; l = &first; if(waserror()){ freeblist(first); nexterror(); } do { n = len; if(n > Maxatomic) n = Maxatomic; *l = b = allocb(n); setmalloctag(b, (up->text[0]<<24)|(up->text[1]<<16)|(up->text[2]<<8)|up->text[3]); memmove(b->wp, p, n); b->wp += n; p += n; len -= n; l = &b->next; } while(len > 0); poperror(); return first; } /* * put a block back to the front of the queue * called with q ilocked */ void qputback(Queue *q, Block *b) { b->next = q->bfirst; if(q->bfirst == nil) q->blast = b; q->bfirst = b; q->len += BALLOC(b); q->dlen += BLEN(b); } /* * flow control, get producer going again * called with q locked */ static void qwakeup_unlock(Queue *q) { int dowakeup = 0; /* if writer flow controlled, restart */ if((q->state & Qflow) && q->len < q->limit/2){ q->state &= ~Qflow; dowakeup = 1; } unlock(&q->l); /* wakeup flow controlled writers */ if(dowakeup){ if(q->kick) q->kick(q->arg); Wakeup(&q->wr); } } /* * get next block from a queue (up to a limit) */ Block* qbread(Queue *q, int len) { Block *b, *nb; int n; qlock(&q->rlock); if(waserror()){ qunlock(&q->rlock); nexterror(); } lock(&q->l); switch(qwait(q)){ case 0: /* queue closed */ unlock(&q->l); poperror(); qunlock(&q->rlock); return nil; case -1: /* multiple reads on a closed queue */ unlock(&q->l); error(q->err); } /* if we get here, there's at least one block in the queue */ b = qremove(q); n = BLEN(b); /* split block if it's too big and this is not a message oriented queue */ nb = b; if(n > len){ if((q->state&Qmsg) == 0){ n -= len; b = allocb(n); memmove(b->wp, nb->rp+len, n); b->wp += n; qputback(q, b); } nb->wp = nb->rp + len; } /* restart producer */ qwakeup_unlock(q); poperror(); qunlock(&q->rlock); return nb; } /* * read a queue. if no data is queued, wait on its Rendez */ long qread(Queue *q, void *vp, int len) { Block *b, *first, **l; int m, n; qlock(&q->rlock); if(waserror()){ qunlock(&q->rlock); nexterror(); } lock(&q->l); again: switch(qwait(q)){ case 0: /* queue closed */ unlock(&q->l); poperror(); qunlock(&q->rlock); return 0; case -1: /* multiple reads on a closed queue */ unlock(&q->l); error(q->err); } /* if we get here, there's at least one block in the queue */ if(q->state & Qcoalesce){ /* when coalescing, 0 length blocks just go away */ b = q->bfirst; if(BLEN(b) <= 0){ freeb(qremove(q)); goto again; } /* grab the first block plus as many * following blocks as will completely * fit in the read. */ n = 0; l = &first; m = BLEN(b); for(;;) { *l = qremove(q); l = &b->next; n += m; b = q->bfirst; if(b == nil) break; m = BLEN(b); if(n+m > len) break; } } else { first = qremove(q); n = BLEN(first); } /* copy to user space outside of the ilock */ unlock(&q->l); b = bl2mem(vp, first, len); lock(&q->l); /* take care of any left over partial block */ if(b != nil){ n -= BLEN(b); if(q->state & Qmsg) freeb(b); else qputback(q, b); } /* restart producer */ qwakeup_unlock(q); poperror(); qunlock(&q->rlock); return n; } static int qnotfull(void *a) { Queue *q = a; return q->len < q->limit || (q->state & Qclosed); } /* * add a block to a queue obeying flow control */ long qbwrite(Queue *q, Block *b) { int n, dowakeup; volatile struct {Block *b;} cb; dowakeup = 0; n = BLEN(b); if(q->bypass){ (*q->bypass)(q->arg, b); return n; } cb.b = b; qlock(&q->wlock); if(waserror()){ if(cb.b != nil) freeb(cb.b); qunlock(&q->wlock); nexterror(); } lock(&q->l); /* give up if the queue is closed */ if(q->state & Qclosed){ unlock(&q->l); error(q->err); } /* if nonblocking, don't queue over the limit */ if(q->len >= q->limit){ if(q->noblock){ unlock(&q->l); freeb(b); poperror(); qunlock(&q->wlock); return n; } } /* queue the block */ if(q->bfirst) q->blast->next = b; else q->bfirst = b; q->blast = b; b->next = 0; q->len += BALLOC(b); q->dlen += n; QDEBUG checkb(b, "qbwrite"); cb.b = nil; if(q->state & Qstarve){ q->state &= ~Qstarve; dowakeup = 1; } unlock(&q->l); /* get output going again */ if(q->kick && (dowakeup || (q->state&Qkick))) q->kick(q->arg); if(dowakeup) Wakeup(&q->rr); /* * flow control, wait for queue to get below the limit * before allowing the process to continue and queue * more. We do this here so that postnote can only * interrupt us after the data has been queued. This * means that things like 9p flushes and ssl messages * will not be disrupted by software interrupts. * * Note - this is moderately dangerous since a process * that keeps getting interrupted and rewriting will * queue infinite crud. */ for(;;){ if(q->noblock || qnotfull(q)) break; lock(&q->l); q->state |= Qflow; unlock(&q->l); Sleep(&q->wr, qnotfull, q); } qunlock(&q->wlock); poperror(); return n; } /* * write to a queue. only Maxatomic bytes at a time is atomic. */ int qwrite(Queue *q, void *vp, int len) { int n, sofar; Block *b; uchar *p = vp; sofar = 0; do { n = len-sofar; if(n > Maxatomic) n = Maxatomic; b = allocb(n); setmalloctag(b, getcallerpc(&q)); if(waserror()){ freeb(b); nexterror(); } memmove(b->wp, p+sofar, n); poperror(); b->wp += n; qbwrite(q, b); sofar += n; } while(sofar < len && (q->state & Qmsg) == 0); return len; } /* * used by print() to write to a queue. Since we may be splhi or not in * a process, don't qlock. */ int qiwrite(Queue *q, void *vp, int len) { int n, sofar, dowakeup; Block *b; uchar *p = vp; dowakeup = 0; sofar = 0; do { n = len-sofar; if(n > Maxatomic) n = Maxatomic; b = iallocb(n); if (b == 0) { print("qiwrite: iallocb failed\n"); break; } memmove(b->wp, p+sofar, n); b->wp += n; lock(&q->l); QDEBUG checkb(b, "qiwrite"); if(q->bfirst) q->blast->next = b; else q->bfirst = b; q->blast = b; q->len += BALLOC(b); q->dlen += n; if(q->state & Qstarve){ q->state &= ~Qstarve; dowakeup = 1; } unlock(&q->l); if(dowakeup){ if(q->kick) q->kick(q->arg); Wakeup(&q->rr); } sofar += n; } while(sofar < len && (q->state & Qmsg) == 0); return sofar; } /* * be extremely careful when calling this, * as there is no reference accounting */ void qfree(Queue *q) { qclose(q); free(q); } /* * Mark a queue as closed. No further IO is permitted. * All blocks are released. */ void qclose(Queue *q) { Block *bfirst; if(q == nil) return; /* mark it */ lock(&q->l); q->state |= Qclosed; q->state &= ~(Qflow|Qstarve); strcpy(q->err, Ehungup); bfirst = q->bfirst; q->bfirst = 0; q->len = 0; q->dlen = 0; q->noblock = 0; unlock(&q->l); /* free queued blocks */ freeblist(bfirst); /* wake up readers/writers */ Wakeup(&q->rr); Wakeup(&q->wr); } /* * Mark a queue as closed. Wakeup any readers. Don't remove queued * blocks. */ void qhangup(Queue *q, char *msg) { /* mark it */ lock(&q->l); q->state |= Qclosed; if(msg == 0 || *msg == 0) strcpy(q->err, Ehungup); else kstrcpy(q->err, msg, sizeof q->err); unlock(&q->l); /* wake up readers/writers */ Wakeup(&q->rr); Wakeup(&q->wr); } /* * return non-zero if the q is hungup */ int qisclosed(Queue *q) { return q->state & Qclosed; } /* * mark a queue as no longer hung up */ void qreopen(Queue *q) { lock(&q->l); q->state &= ~Qclosed; q->state |= Qstarve; q->eof = 0; q->limit = q->inilim; unlock(&q->l); } /* * return bytes queued */ int qlen(Queue *q) { return q->dlen; } /* * return space remaining before flow control */ int qwindow(Queue *q) { int l; l = q->limit - q->len; if(l < 0) l = 0; return l; } /* * return true if we can read without blocking */ int qcanread(Queue *q) { return q->bfirst!=0; } /* * change queue limit */ void qsetlimit(Queue *q, int limit) { q->limit = limit; } /* * set blocking/nonblocking */ void qnoblock(Queue *q, int onoff) { q->noblock = onoff; } /* * flush the output queue */ void qflush(Queue *q) { Block *bfirst; /* mark it */ lock(&q->l); bfirst = q->bfirst; q->bfirst = 0; q->len = 0; q->dlen = 0; unlock(&q->l); /* free queued blocks */ freeblist(bfirst); /* wake up readers/writers */ Wakeup(&q->wr); } int qfull(Queue *q) { return q->state & Qflow; } int qstate(Queue *q) { return q->state; } int qclosed(Queue *q) { return q->state & Qclosed; }