/* vfs_bio.c 4.25 82/01/17 */ #include "../h/param.h" #include "../h/systm.h" #include "../h/dir.h" #include "../h/user.h" #include "../h/buf.h" #include "../h/conf.h" #include "../h/proc.h" #include "../h/seg.h" #include "../h/pte.h" #include "../h/vm.h" #include "../h/trace.h" /* * The following several routines allocate and free * buffers with various side effects. In general the * arguments to an allocate routine are a device and * a block number, and the value is a pointer to * to the buffer header; the buffer is marked "busy" * so that no one else can touch it. If the block was * already in core, no I/O need be done; if it is * already busy, the process waits until it becomes free. * The following routines allocate a buffer: * getblk * bread * breada * baddr (if it is incore) * Eventually the buffer must be released, possibly with the * side effect of writing it out, by using one of * bwrite * bdwrite * bawrite * brelse */ struct buf bfreelist[BQUEUES]; struct buf bswlist, *bclnlist; #define BUFHSZ 63 struct bufhd bufhash[BUFHSZ]; #define BUFHASH(dev, dblkno) \ ((struct buf *)&bufhash[((int)(dev)+(int)(dblkno)) % BUFHSZ]) /* * Initialize hash links for buffers. */ bhinit() { register int i; register struct bufhd *bp; for (bp = bufhash, i = 0; i < BUFHSZ; i++, bp++) bp->b_forw = bp->b_back = (struct buf *)bp; } /* #define DISKMON 1 */ #ifdef DISKMON struct { int nbuf; long nread; long nreada; long ncache; long nwrite; long bufcount[64]; } io_info; #endif /* * Swap IO headers - * They contain the necessary information for the swap I/O. * At any given time, a swap header can be in three * different lists. When free it is in the free list, * when allocated and the I/O queued, it is on the swap * device list, and finally, if the operation was a dirty * page push, when the I/O completes, it is inserted * in a list of cleaned pages to be processed by the pageout daemon. */ struct buf *swbuf; short *swsize; /* CAN WE JUST USE B_BCOUNT? */ int *swpf; #ifndef UNFAST #define notavail(bp) \ { \ int s = spl6(); \ (bp)->av_back->av_forw = (bp)->av_forw; \ (bp)->av_forw->av_back = (bp)->av_back; \ (bp)->b_flags |= B_BUSY; \ splx(s); \ } #endif /* * Read in (if necessary) the block and return a buffer pointer. */ struct buf * bread(dev, blkno) dev_t dev; daddr_t blkno; { register struct buf *bp; bp = getblk(dev, blkno); if (bp->b_flags&B_DONE) { #ifdef TRACE trace(TR_BREADHIT, dev, blkno); #endif #ifdef DISKMON io_info.ncache++; #endif return(bp); } bp->b_flags |= B_READ; bp->b_bcount = BSIZE; (*bdevsw[major(dev)].d_strategy)(bp); #ifdef TRACE trace(TR_BREADMISS, dev, blkno); #endif #ifdef DISKMON io_info.nread++; #endif u.u_vm.vm_inblk++; /* pay for read */ iowait(bp); return(bp); } /* * Read in the block, like bread, but also start I/O on the * read-ahead block (which is not allocated to the caller) */ struct buf * breada(dev, blkno, rablkno) dev_t dev; daddr_t blkno, rablkno; { register struct buf *bp, *rabp; bp = NULL; if (!incore(dev, blkno)) { bp = getblk(dev, blkno); if ((bp->b_flags&B_DONE) == 0) { bp->b_flags |= B_READ; bp->b_bcount = BSIZE; (*bdevsw[major(dev)].d_strategy)(bp); #ifdef TRACE trace(TR_BREADMISS, dev, blkno); #endif #ifdef DISKMON io_info.nread++; #endif u.u_vm.vm_inblk++; /* pay for read */ } #ifdef TRACE else trace(TR_BREADHIT, dev, blkno); #endif } if (rablkno && !incore(dev, rablkno)) { rabp = getblk(dev, rablkno); if (rabp->b_flags & B_DONE) { brelse(rabp); #ifdef TRACE trace(TR_BREADHITRA, dev, blkno); #endif } else { rabp->b_flags |= B_READ|B_ASYNC; rabp->b_bcount = BSIZE; (*bdevsw[major(dev)].d_strategy)(rabp); #ifdef TRACE trace(TR_BREADMISSRA, dev, rablock); #endif #ifdef DISKMON io_info.nreada++; #endif u.u_vm.vm_inblk++; /* pay in advance */ } } if(bp == NULL) return(bread(dev, blkno)); iowait(bp); return(bp); } /* * Write the buffer, waiting for completion. * Then release the buffer. */ bwrite(bp) register struct buf *bp; { register flag; flag = bp->b_flags; bp->b_flags &= ~(B_READ | B_DONE | B_ERROR | B_DELWRI | B_AGE); bp->b_bcount = BSIZE; #ifdef DISKMON io_info.nwrite++; #endif if ((flag&B_DELWRI) == 0) u.u_vm.vm_oublk++; /* noone paid yet */ #ifdef TRACE trace(TR_BWRITE, bp->b_dev, bp->b_blkno); #endif (*bdevsw[major(bp->b_dev)].d_strategy)(bp); if ((flag&B_ASYNC) == 0) { iowait(bp); brelse(bp); } else if (flag & B_DELWRI) bp->b_flags |= B_AGE; else geterror(bp); } /* * Release the buffer, marking it so that if it is grabbed * for another purpose it will be written out before being * given up (e.g. when writing a partial block where it is * assumed that another write for the same block will soon follow). * This can't be done for magtape, since writes must be done * in the same order as requested. */ bdwrite(bp) register struct buf *bp; { register int flags; if ((bp->b_flags&B_DELWRI) == 0) u.u_vm.vm_oublk++; /* noone paid yet */ flags = bdevsw[major(bp->b_dev)].d_flags; if(flags & B_TAPE) bawrite(bp); else { bp->b_flags |= B_DELWRI | B_DONE; brelse(bp); } } /* * Release the buffer, start I/O on it, but don't wait for completion. */ bawrite(bp) register struct buf *bp; { bp->b_flags |= B_ASYNC; bwrite(bp); } /* * release the buffer, with no I/O implied. */ brelse(bp) register struct buf *bp; { register struct buf *flist; register s; if (bp->b_flags&B_WANTED) wakeup((caddr_t)bp); if (bfreelist[0].b_flags&B_WANTED) { bfreelist[0].b_flags &= ~B_WANTED; wakeup((caddr_t)bfreelist); } if (bp->b_flags&B_ERROR) if (bp->b_flags & B_LOCKED) bp->b_flags &= ~B_ERROR; /* try again later */ else bp->b_dev = NODEV; /* no assoc */ s = spl6(); if (bp->b_flags & (B_ERROR|B_INVAL)) { /* block has no info ... put at front of most free list */ flist = &bfreelist[BQUEUES-1]; flist->av_forw->av_back = bp; bp->av_forw = flist->av_forw; flist->av_forw = bp; bp->av_back = flist; } else { if (bp->b_flags & B_LOCKED) flist = &bfreelist[BQ_LOCKED]; else if (bp->b_flags & B_AGE) flist = &bfreelist[BQ_AGE]; else flist = &bfreelist[BQ_LRU]; flist->av_back->av_forw = bp; bp->av_back = flist->av_back; flist->av_back = bp; bp->av_forw = flist; } bp->b_flags &= ~(B_WANTED|B_BUSY|B_ASYNC|B_AGE); splx(s); } /* * See if the block is associated with some buffer * (mainly to avoid getting hung up on a wait in breada) */ incore(dev, blkno) dev_t dev; daddr_t blkno; { register struct buf *bp; register struct buf *dp; register int dblkno = fsbtodb(blkno); dp = BUFHASH(dev, dblkno); for (bp = dp->b_forw; bp != dp; bp = bp->b_forw) if (bp->b_blkno == dblkno && bp->b_dev == dev && !(bp->b_flags & B_INVAL)) return (1); return (0); } struct buf * baddr(dev, blkno) dev_t dev; daddr_t blkno; { if (incore(dev, blkno)) return (bread(dev, blkno)); return (0); } /* * Assign a buffer for the given block. If the appropriate * block is already associated, return it; otherwise search * for the oldest non-busy buffer and reassign it. * * We use splx here because this routine may be called * on the interrupt stack during a dump, and we don't * want to lower the ipl back to 0. */ struct buf * getblk(dev, blkno) dev_t dev; daddr_t blkno; { register struct buf *bp, *dp, *ep; register int dblkno = fsbtodb(blkno); #ifdef DISKMON register int i; #endif int s; if ((unsigned)blkno >= 1 << (sizeof(int)*NBBY-PGSHIFT)) blkno = 1 << ((sizeof(int)*NBBY-PGSHIFT) + 1); dblkno = fsbtodb(blkno); dp = BUFHASH(dev, dblkno); loop: for (bp = dp->b_forw; bp != dp; bp = bp->b_forw) { if (bp->b_blkno != dblkno || bp->b_dev != dev || bp->b_flags&B_INVAL) continue; s = spl6(); if (bp->b_flags&B_BUSY) { bp->b_flags |= B_WANTED; sleep((caddr_t)bp, PRIBIO+1); splx(s); goto loop; } splx(s); #ifdef DISKMON i = 0; dp = bp->av_forw; while ((dp->b_flags & B_HEAD) == 0) { i++; dp = dp->av_forw; } if (i<64) io_info.bufcount[i]++; #endif notavail(bp); bp->b_flags |= B_CACHE; return(bp); } if (major(dev) >= nblkdev) panic("blkdev"); s = spl6(); for (ep = &bfreelist[BQUEUES-1]; ep > bfreelist; ep--) if (ep->av_forw != ep) break; if (ep == bfreelist) { /* no free blocks at all */ ep->b_flags |= B_WANTED; sleep((caddr_t)ep, PRIBIO+1); splx(s); goto loop; } splx(s); bp = ep->av_forw; notavail(bp); if (bp->b_flags & B_DELWRI) { bp->b_flags |= B_ASYNC; bwrite(bp); goto loop; } #ifdef TRACE trace(TR_BRELSE, bp->b_dev, bp->b_blkno); #endif bp->b_flags = B_BUSY; bp->b_back->b_forw = bp->b_forw; bp->b_forw->b_back = bp->b_back; bp->b_forw = dp->b_forw; bp->b_back = dp; dp->b_forw->b_back = bp; dp->b_forw = bp; bp->b_dev = dev; bp->b_blkno = dblkno; return(bp); } /* * get an empty block, * not assigned to any particular device */ struct buf * geteblk() { register struct buf *bp, *dp; int s; loop: s = spl6(); for (dp = &bfreelist[BQUEUES-1]; dp > bfreelist; dp--) if (dp->av_forw != dp) break; if (dp == bfreelist) { /* no free blocks */ dp->b_flags |= B_WANTED; sleep((caddr_t)dp, PRIBIO+1); goto loop; } splx(s); bp = dp->av_forw; notavail(bp); if (bp->b_flags & B_DELWRI) { bp->b_flags |= B_ASYNC; bwrite(bp); goto loop; } #ifdef TRACE trace(TR_BRELSE, bp->b_dev, bp->b_blkno); #endif bp->b_flags = B_BUSY|B_INVAL; bp->b_back->b_forw = bp->b_forw; bp->b_forw->b_back = bp->b_back; bp->b_forw = dp->b_forw; bp->b_back = dp; dp->b_forw->b_back = bp; dp->b_forw = bp; bp->b_dev = (dev_t)NODEV; return(bp); } /* * Wait for I/O completion on the buffer; return errors * to the user. */ iowait(bp) register struct buf *bp; { int s; s = spl6(); while ((bp->b_flags&B_DONE)==0) sleep((caddr_t)bp, PRIBIO); splx(s); geterror(bp); } #ifdef UNFAST /* * Unlink a buffer from the available list and mark it busy. * (internal interface) */ notavail(bp) register struct buf *bp; { register s; s = spl6(); bp->av_back->av_forw = bp->av_forw; bp->av_forw->av_back = bp->av_back; bp->b_flags |= B_BUSY; splx(s); } #endif /* * Mark I/O complete on a buffer. If the header * indicates a dirty page push completion, the * header is inserted into the ``cleaned'' list * to be processed by the pageout daemon. Otherwise * release it if I/O is asynchronous, and wake * up anyone waiting for it. */ iodone(bp) register struct buf *bp; { register int s; if (bp->b_flags & B_DONE) panic("dup iodone"); bp->b_flags |= B_DONE; if (bp->b_flags & B_DIRTY) { if (bp->b_flags & B_ERROR) panic("IO err in push"); s = spl6(); bp->av_forw = bclnlist; bp->b_bcount = swsize[bp - swbuf]; bp->b_pfcent = swpf[bp - swbuf]; cnt.v_pgout++; cnt.v_pgpgout += bp->b_bcount / NBPG; bclnlist = bp; if (bswlist.b_flags & B_WANTED) wakeup((caddr_t)&proc[2]); splx(s); return; } if (bp->b_flags&B_ASYNC) brelse(bp); else { bp->b_flags &= ~B_WANTED; wakeup((caddr_t)bp); } } /* * Zero the core associated with a buffer. */ clrbuf(bp) struct buf *bp; { register *p; register c; p = bp->b_un.b_words; c = BSIZE/sizeof(int); do *p++ = 0; while (--c); bp->b_resid = 0; } /* * swap I/O - * * If the flag indicates a dirty page push initiated * by the pageout daemon, we map the page into the i th * virtual page of process 2 (the daemon itself) where i is * the index of the swap header that has been allocated. * We simply initialize the header and queue the I/O but * do not wait for completion. When the I/O completes, * iodone() will link the header to a list of cleaned * pages to be processed by the pageout daemon. */ swap(p, dblkno, addr, nbytes, rdflg, flag, dev, pfcent) struct proc *p; swblk_t dblkno; caddr_t addr; int flag, nbytes; dev_t dev; unsigned pfcent; { register struct buf *bp; register int c; int p2dp; register struct pte *dpte, *vpte; int s; s = spl6(); while (bswlist.av_forw == NULL) { bswlist.b_flags |= B_WANTED; sleep((caddr_t)&bswlist, PSWP+1); } bp = bswlist.av_forw; bswlist.av_forw = bp->av_forw; splx(s); bp->b_flags = B_BUSY | B_PHYS | rdflg | flag; if ((bp->b_flags & (B_DIRTY|B_PGIN)) == 0) if (rdflg == B_READ) sum.v_pswpin += btoc(nbytes); else sum.v_pswpout += btoc(nbytes); bp->b_proc = p; if (flag & B_DIRTY) { p2dp = ((bp - swbuf) * CLSIZE) * KLMAX; dpte = dptopte(&proc[2], p2dp); vpte = vtopte(p, btop(addr)); for (c = 0; c < nbytes; c += NBPG) { if (vpte->pg_pfnum == 0 || vpte->pg_fod) panic("swap bad pte"); *dpte++ = *vpte++; } bp->b_un.b_addr = (caddr_t)ctob(p2dp); } else bp->b_un.b_addr = addr; while (nbytes > 0) { c = imin(ctob(120), nbytes); bp->b_bcount = c; bp->b_blkno = dblkno; bp->b_dev = dev; if (flag & B_DIRTY) { swpf[bp - swbuf] = pfcent; swsize[bp - swbuf] = nbytes; } #ifdef TRACE trace(TR_SWAPIO, dev, bp->b_blkno); #endif (*bdevsw[major(dev)].d_strategy)(bp); if (flag & B_DIRTY) { if (c < nbytes) panic("big push"); return; } s = spl6(); while((bp->b_flags&B_DONE)==0) sleep((caddr_t)bp, PSWP); splx(s); bp->b_un.b_addr += c; bp->b_flags &= ~B_DONE; if (bp->b_flags & B_ERROR) { if ((flag & (B_UAREA|B_PAGET)) || rdflg == B_WRITE) panic("hard IO err in swap"); swkill(p, (char *)0); } nbytes -= c; dblkno += btoc(c); } s = spl6(); bp->b_flags &= ~(B_BUSY|B_WANTED|B_PHYS|B_PAGET|B_UAREA|B_DIRTY); bp->av_forw = bswlist.av_forw; bswlist.av_forw = bp; if (bswlist.b_flags & B_WANTED) { bswlist.b_flags &= ~B_WANTED; wakeup((caddr_t)&bswlist); wakeup((caddr_t)&proc[2]); } splx(s); } /* * If rout == 0 then killed on swap error, else * rout is the name of the routine where we ran out of * swap space. */ swkill(p, rout) struct proc *p; char *rout; { char *mesg; printf("pid %d: ", p->p_pid); if (rout) printf(mesg = "killed due to no swap space\n"); else printf(mesg = "killed on swap error\n"); uprintf("sorry, pid %d was %s", p->p_pid, mesg); /* * To be sure no looping (e.g. in vmsched trying to * swap out) mark process locked in core (as though * done by user) after killing it so noone will try * to swap it out. */ psignal(p, SIGKILL); p->p_flag |= SULOCK; } /* * make sure all write-behind blocks * on dev (or NODEV for all) * are flushed out. * (from umount and update) */ bflush(dev) dev_t dev; { register struct buf *bp; register struct buf *flist; int s; loop: s = spl6(); for (flist = bfreelist; flist < &bfreelist[BQUEUES]; flist++) for (bp = flist->av_forw; bp != flist; bp = bp->av_forw) { if (bp->b_flags&B_DELWRI && (dev == NODEV||dev==bp->b_dev)) { bp->b_flags |= B_ASYNC; notavail(bp); bwrite(bp); goto loop; } } splx(s); } /* * Raw I/O. The arguments are * The strategy routine for the device * A buffer, which will always be a special buffer * header owned exclusively by the device for this purpose * The device number * Read/write flag * Essentially all the work is computing physical addresses and * validating them. * If the user has the proper access privilidges, the process is * marked 'delayed unlock' and the pages involved in the I/O are * faulted and locked. After the completion of the I/O, the above pages * are unlocked. */ physio(strat, bp, dev, rw, mincnt) int (*strat)(); register struct buf *bp; unsigned (*mincnt)(); { register int c; char *a; int s; if (useracc(u.u_base,u.u_count,rw==B_READ?B_WRITE:B_READ) == NULL) { u.u_error = EFAULT; return; } s = spl6(); while (bp->b_flags&B_BUSY) { bp->b_flags |= B_WANTED; sleep((caddr_t)bp, PRIBIO+1); } bp->b_error = 0; bp->b_proc = u.u_procp; bp->b_un.b_addr = u.u_base; while (u.u_count != 0) { bp->b_flags = B_BUSY | B_PHYS | rw; bp->b_dev = dev; bp->b_blkno = u.u_offset >> PGSHIFT; bp->b_bcount = u.u_count; (*mincnt)(bp); c = bp->b_bcount; u.u_procp->p_flag |= SPHYSIO; vslock(a = bp->b_un.b_addr, c); (*strat)(bp); (void) spl6(); while ((bp->b_flags&B_DONE) == 0) sleep((caddr_t)bp, PRIBIO); vsunlock(a, c, rw); u.u_procp->p_flag &= ~SPHYSIO; if (bp->b_flags&B_WANTED) wakeup((caddr_t)bp); splx(s); bp->b_un.b_addr += c; u.u_count -= c; u.u_offset += c; if (bp->b_flags&B_ERROR) break; } bp->b_flags &= ~(B_BUSY|B_WANTED|B_PHYS); u.u_count = bp->b_resid; geterror(bp); } /*ARGSUSED*/ unsigned minphys(bp) struct buf *bp; { if (bp->b_bcount > 60 * 1024) bp->b_bcount = 60 * 1024; } /* * Pick up the device's error number and pass it to the user; * if there is an error but the number is 0 set a generalized * code. Actually the latter is always true because devices * don't yet return specific errors. */ geterror(bp) register struct buf *bp; { if (bp->b_flags&B_ERROR) if ((u.u_error = bp->b_error)==0) u.u_error = EIO; } /* * Invalidate in core blocks belonging to closed or umounted filesystem * * This is not nicely done at all - the buffer ought to be removed from the * hash chains & have its dev/blkno fields clobbered, but unfortunately we * can't do that here, as it is quite possible that the block is still * being used for i/o. Eventually, all disc drivers should be forced to * have a close routine, which ought ensure that the queue is empty, then * properly flush the queues. Until that happy day, this suffices for * correctness. ... kre */ binval(dev) dev_t dev; { register struct buf *bp; register struct bufhd *hp; #define dp ((struct buf *)hp) for (hp = bufhash; hp < &bufhash[BUFHSZ]; hp++) for (bp = dp->b_forw; bp != dp; bp = bp->b_forw) if (bp->b_dev == dev) bp->b_flags |= B_INVAL; }