[unix-history] / usr / src / sys / kern / kern_physio.c

/*	kern_physio.c	3.4	%H%	*/

#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"

/*
 * 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
 */

#define	BUFHSZ	63
#define	BUFHASH(blkno)	(blkno % BUFHSZ)
short	bufhash[BUFHSZ];

/*
 * Initialize hash links for buffers.
 */
bhinit()
{
	register int i;

	for (i = 0; i < BUFHSZ; i++)
		bufhash[i] = -1;
}

/* #define	DISKMON	1 */

#ifdef	DISKMON
struct {
	int	nbuf;
	long	nread;
	long	nreada;
	long	ncache;
	long	nwrite;
	long	bufcount[NBUF];
} 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[NSWBUF];
short	swsize[NSWBUF];		/* CAN WE JUST USE B_BCOUNT? */
int	swpf[NSWBUF];


#ifdef	FASTVAX
#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	DISKMON
		io_info.ncache++;
#endif
		return(bp);
	}
	bp->b_flags |= B_READ;
	bp->b_bcount = BSIZE;
	(*bdevsw[major(dev)].d_strategy)(bp);
#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	DISKMON
			io_info.nread++;
#endif
			u.u_vm.vm_inblk++;		/* pay for read */
		}
	}
	if (rablkno && !incore(dev, rablkno)) {
		rabp = getblk(dev, rablkno);
		if (rabp->b_flags & B_DONE)
			brelse(rabp);
		else {
			rabp->b_flags |= B_READ|B_ASYNC;
			rabp->b_bcount = BSIZE;
			(*bdevsw[major(dev)].d_strategy)(rabp);
#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 */
	(*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 struct buf *dp;

	if ((bp->b_flags&B_DELWRI) == 0)
		u.u_vm.vm_oublk++;		/* noone paid yet */
	dp = bdevsw[major(bp->b_dev)].d_tab;
	if(dp->b_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 **backp;
	register s;

	if (bp->b_flags&B_WANTED)
		wakeup((caddr_t)bp);
	if (bfreelist.b_flags&B_WANTED) {
		bfreelist.b_flags &= ~B_WANTED;
		wakeup((caddr_t)&bfreelist);
	}
	if ((bp->b_flags&B_ERROR) && bp->b_dev != NODEV) {
		bunhash(bp);
		bp->b_dev = NODEV;  /* no assoc. on error */
	}
	s = spl6();
	if(bp->b_flags & (B_AGE|B_ERROR)) {
		backp = &bfreelist.av_forw;
		(*backp)->av_back = bp;
		bp->av_forw = *backp;
		*backp = bp;
		bp->av_back = &bfreelist;
	} else {
		backp = &bfreelist.av_back;
		(*backp)->av_forw = bp;
		bp->av_back = *backp;
		*backp = bp;
		bp->av_forw = &bfreelist;
	}
	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 int dblkno = fsbtodb(blkno);

	for (bp = &buf[bufhash[BUFHASH(blkno)]]; bp != &buf[-1];
	    bp = &buf[bp->b_hlink])
		if (bp->b_blkno == dblkno && bp->b_dev == dev)
			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.
 */
struct buf *
getblk(dev, blkno)
dev_t dev;
daddr_t blkno;
{
	register struct buf *bp, *dp, *ep;
	register int i, x;
	register int dblkno = fsbtodb(blkno);

    loop:
	(void) spl0();
	for (bp = &buf[bufhash[BUFHASH(blkno)]]; bp != &buf[-1];
	    bp = &buf[bp->b_hlink]) {
		if (bp->b_blkno != dblkno || bp->b_dev != dev)
			continue;
		(void) spl6();
		if (bp->b_flags&B_BUSY) {
			bp->b_flags |= B_WANTED;
			sleep((caddr_t)bp, PRIBIO+1);
			goto loop;
		}
		(void) spl0();
#ifdef	DISKMON
		i = 0;
		dp = bp->av_forw;
		while (dp != &bfreelist) {
			i++;
			dp = dp->av_forw;
		}
		if (i<NBUF)
			io_info.bufcount[i]++;
#endif
		notavail(bp);
		bp->b_flags |= B_CACHE;
		return(bp);
	}
	if (major(dev) >= nblkdev)
		panic("blkdev");
	dp = bdevsw[major(dev)].d_tab;
	if (dp == NULL)
		panic("devtab");
	(void) spl6();
	if (bfreelist.av_forw == &bfreelist) {
		bfreelist.b_flags |= B_WANTED;
		sleep((caddr_t)&bfreelist, PRIBIO+1);
		goto loop;
	}
	spl0();
	bp = bfreelist.av_forw;
	notavail(bp);
	if (bp->b_flags & B_DELWRI) {
		bp->b_flags |= B_ASYNC;
		bwrite(bp);
		goto loop;
	}
	if (bp->b_dev == NODEV)
		goto done;
	/* INLINE EXPANSION OF bunhash(bp) */
	i = BUFHASH(dbtofsb(bp->b_blkno));
	x = bp - buf;
	if (bufhash[i] == x) {
		bufhash[i] = bp->b_hlink;
	} else {
		for (ep = &buf[bufhash[i]]; ep != &buf[-1];
		    ep = &buf[ep->b_hlink])
			if (ep->b_hlink == x) {
				ep->b_hlink = bp->b_hlink;
				goto done;
			}
		panic("getblk");
	}
done:
	/* END INLINE EXPANSION */
	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;
	i = BUFHASH(blkno);
	bp->b_hlink = bufhash[i];
	bufhash[i] = bp - buf;
	return(bp);
}

/*
 * get an empty block,
 * not assigned to any particular device
 */
struct buf *
geteblk()
{
	register struct buf *bp, *dp, *ep;
	register int i, x;

loop:
	(void) spl6();
	while (bfreelist.av_forw == &bfreelist) {
		bfreelist.b_flags |= B_WANTED;
		sleep((caddr_t)&bfreelist, PRIBIO+1);
	}
	(void) spl0();
	dp = &bfreelist;
	bp = bfreelist.av_forw;
	notavail(bp);
	if (bp->b_flags & B_DELWRI) {
		bp->b_flags |= B_ASYNC;
		bwrite(bp);
		goto loop;
	}
	if (bp->b_dev != NODEV)
		bunhash(bp);
	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_t)NODEV;
	bp->b_hlink = -1;
	return(bp);
}

bunhash(bp)
	register struct buf *bp;
{
	register struct buf *ep;
	register int i, x;

	if (bp->b_dev == NODEV)
		return;
	i = BUFHASH(dbtofsb(bp->b_blkno));
	x = bp - buf;
	if (bufhash[i] == x) {
		bufhash[i] = bp->b_hlink;
		return;
	}
	for (ep = &buf[bufhash[i]]; ep != &buf[-1];
	    ep = &buf[ep->b_hlink])
		if (ep->b_hlink == x) {
			ep->b_hlink = bp->b_hlink;
			return;
		}
	panic("bunhash");
}

/*
 * Wait for I/O completion on the buffer; return errors
 * to the user.
 */
iowait(bp)
register struct buf *bp;
{

	(void) spl6();
	while ((bp->b_flags&B_DONE)==0)
		sleep((caddr_t)bp, PRIBIO);
	(void) spl0();
	geterror(bp);
}

#ifndef FASTVAX
/*
 * 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;

	bp->b_flags |= B_DONE;
	if (bp->b_flags & B_DIRTY) {
		if (bp->b_flags & B_ERROR)
			panic("IO err in push");
		s = spl6();
		cnt.v_pgout++;
		bp->av_forw = bclnlist;
		bp->b_bcount = swsize[bp - swbuf];
		bp->b_pfcent = swpf[bp - swbuf];
		bclnlist = bp;
		if (bswlist.b_flags & B_WANTED)
			wakeup((caddr_t)&proc[2]);
		splx(s);
	}
	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;

	(void) 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;
	(void) spl0();

	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 (dev == swapdev)
			bp->b_blkno += swplo;
		(*bdevsw[major(dev)].d_strategy)(bp);
		if (flag & B_DIRTY) {
			if (c < nbytes)
				panic("big push");
			swsize[bp - swbuf] = nbytes;
			swpf[bp - swbuf] = pfcent;
			return;
		}
		(void) spl6();
		while((bp->b_flags&B_DONE)==0)
			sleep((caddr_t)bp, PSWP);
		(void) spl0();
		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);
	}
	(void) 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]);
	}
	(void) spl0();
}

/*
 * 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;
{

	printf("%d: ", p->p_pid);
	if (rout)
		printf("out of swap space in %s\n", rout);
	else
		printf("killed on swap error\n");
	/*
	 * 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, SIGKIL);
	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;

loop:
	(void) spl6();
	for (bp = bfreelist.av_forw; bp != &bfreelist; 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;
		}
	}
	(void) spl0();
}

/*
 * 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;

	if (useracc(u.u_base,u.u_count,rw==B_READ?B_WRITE:B_READ) == NULL) {
		u.u_error = EFAULT;
		return;
	}
	(void) 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_error==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);
		(void) spl0();
		bp->b_un.b_addr += c;
		u.u_count -= c;
		u.u_offset += c;
	}
	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;
}
Commit	Line	Data
81263dba	1	/* kern_physio.c 3.4 %H% */
663dbc72 BJ	2
	3	#include "../h/param.h"
	4	#include "../h/systm.h"
	5	#include "../h/dir.h"
	6	#include "../h/user.h"
	7	#include "../h/buf.h"
	8	#include "../h/conf.h"
	9	#include "../h/proc.h"
	10	#include "../h/seg.h"
	11	#include "../h/pte.h"
	12	#include "../h/vm.h"
	13
5603d07d BJ	14	/*
	15	* The following several routines allocate and free
	16	* buffers with various side effects. In general the
	17	* arguments to an allocate routine are a device and
	18	* a block number, and the value is a pointer to
	19	* to the buffer header; the buffer is marked "busy"
	20	* so that no one else can touch it. If the block was
	21	* already in core, no I/O need be done; if it is
	22	* already busy, the process waits until it becomes free.
	23	* The following routines allocate a buffer:
	24	* getblk
	25	* bread
	26	* breada
	27	* baddr (if it is incore)
	28	* Eventually the buffer must be released, possibly with the
	29	* side effect of writing it out, by using one of
	30	* bwrite
	31	* bdwrite
	32	* bawrite
	33	* brelse
	34	*/
	35
	36	#define BUFHSZ 63
	37	#define BUFHASH(blkno) (blkno % BUFHSZ)
	38	short bufhash[BUFHSZ];
	39
	40	/*
	41	* Initialize hash links for buffers.
	42	*/
	43	bhinit()
	44	{
	45	register int i;
	46
	47	for (i = 0; i < BUFHSZ; i++)
	48	bufhash[i] = -1;
	49	}
	50
663dbc72 BJ	51	/* #define DISKMON 1 */
	52
	53	#ifdef DISKMON
	54	struct {
	55	int nbuf;
	56	long nread;
	57	long nreada;
	58	long ncache;
	59	long nwrite;
	60	long bufcount[NBUF];
	61	} io_info;
	62	#endif
	63
	64	/*
	65	* Swap IO headers -
	66	* They contain the necessary information for the swap I/O.
	67	* At any given time, a swap header can be in three
	68	* different lists. When free it is in the free list,
	69	* when allocated and the I/O queued, it is on the swap
	70	* device list, and finally, if the operation was a dirty
	71	* page push, when the I/O completes, it is inserted
	72	* in a list of cleaned pages to be processed by the pageout daemon.
	73	*/
	74	struct buf swbuf[NSWBUF];
	75	short swsize[NSWBUF]; /* CAN WE JUST USE B_BCOUNT? */
	76	int swpf[NSWBUF];
	77
663dbc72 BJ	78
	79	#ifdef FASTVAX
	80	#define notavail(bp) \
	81	{ \
	82	int s = spl6(); \
	83	(bp)->av_back->av_forw = (bp)->av_forw; \
	84	(bp)->av_forw->av_back = (bp)->av_back; \
	85	(bp)->b_flags \|= B_BUSY; \
	86	splx(s); \
	87	}
	88	#endif
	89
	90	/*
	91	* Read in (if necessary) the block and return a buffer pointer.
	92	*/
	93	struct buf *
	94	bread(dev, blkno)
	95	dev_t dev;
	96	daddr_t blkno;
	97	{
	98	register struct buf *bp;
	99
	100	bp = getblk(dev, blkno);
	101	if (bp->b_flags&B_DONE) {
	102	#ifdef DISKMON
	103	io_info.ncache++;
	104	#endif
	105	return(bp);
	106	}
	107	bp->b_flags \|= B_READ;
	108	bp->b_bcount = BSIZE;
	109	(*bdevsw[major(dev)].d_strategy)(bp);
	110	#ifdef DISKMON
	111	io_info.nread++;
	112	#endif
	113	u.u_vm.vm_inblk++; /* pay for read */
	114	iowait(bp);
	115	return(bp);
	116	}
	117
	118	/*
	119	* Read in the block, like bread, but also start I/O on the
	120	* read-ahead block (which is not allocated to the caller)
	121	*/
	122	struct buf *
	123	breada(dev, blkno, rablkno)
	124	dev_t dev;
	125	daddr_t blkno, rablkno;
	126	{
	127	register struct buf bp, rabp;
	128
	129	bp = NULL;
	130	if (!incore(dev, blkno)) {
	131	bp = getblk(dev, blkno);
	132	if ((bp->b_flags&B_DONE) == 0) {
	133	bp->b_flags \|= B_READ;
	134	bp->b_bcount = BSIZE;
	135	(*bdevsw[major(dev)].d_strategy)(bp);
	136	#ifdef DISKMON
	137	io_info.nread++;
	138	#endif
	139	u.u_vm.vm_inblk++; /* pay for read */
	140	}
	141	}
142	if (rablkno && !incore(dev, rablkno)) {
143	rabp = getblk(dev, rablkno);
144	if (rabp->b_flags & B_DONE)
145	brelse(rabp);
146	else {
147	rabp->b_flags \|= B_READ\|B_ASYNC;
148	rabp->b_bcount = BSIZE;
149	(*bdevsw[major(dev)].d_strategy)(rabp);
150	#ifdef DISKMON
151	io_info.nreada++;
152	#endif
153	u.u_vm.vm_inblk++; /* pay in advance */
154	}
155	}
156	if(bp == NULL)
157	return(bread(dev, blkno));
158	iowait(bp);
159	return(bp);
160	}
161
162	/*
163	* Write the buffer, waiting for completion.
164	* Then release the buffer.
165	*/
166	bwrite(bp)
167	register struct buf *bp;
168	{
169	register flag;
170
171	flag = bp->b_flags;
172	bp->b_flags &= ~(B_READ \| B_DONE \| B_ERROR \| B_DELWRI \| B_AGE);
173	bp->b_bcount = BSIZE;
174	#ifdef DISKMON
175	io_info.nwrite++;
176	#endif
177	if ((flag&B_DELWRI) == 0)
178	u.u_vm.vm_oublk++; /* noone paid yet */
179	(*bdevsw[major(bp->b_dev)].d_strategy)(bp);
180	if ((flag&B_ASYNC) == 0) {
181	iowait(bp);
182	brelse(bp);
183	} else if (flag & B_DELWRI)
184	bp->b_flags \|= B_AGE;
185	else
186	geterror(bp);
187	}
188
189	/*
190	* Release the buffer, marking it so that if it is grabbed
191	* for another purpose it will be written out before being
192	* given up (e.g. when writing a partial block where it is
193	* assumed that another write for the same block will soon follow).
194	* This can't be done for magtape, since writes must be done
195	* in the same order as requested.
196	*/
197	bdwrite(bp)
198	register struct buf *bp;
199	{
200	register struct buf *dp;
201
202	if ((bp->b_flags&B_DELWRI) == 0)
203	u.u_vm.vm_oublk++; /* noone paid yet */
204	dp = bdevsw[major(bp->b_dev)].d_tab;
205	if(dp->b_flags & B_TAPE)
206	bawrite(bp);
207	else {
208	bp->b_flags \|= B_DELWRI \| B_DONE;
209	brelse(bp);
210	}
211	}
212
213	/*
214	* Release the buffer, start I/O on it, but don't wait for completion.
215	*/
216	bawrite(bp)
217	register struct buf *bp;
218	{
219
220	bp->b_flags \|= B_ASYNC;
221	bwrite(bp);
222	}
223
224	/*
225	* release the buffer, with no I/O implied.
226	*/
227	brelse(bp)
228	register struct buf *bp;
229	{
230	register struct buf **backp;
231	register s;
232
233	if (bp->b_flags&B_WANTED)
234	wakeup((caddr_t)bp);
235	if (bfreelist.b_flags&B_WANTED) {
236	bfreelist.b_flags &= ~B_WANTED;
237	wakeup((caddr_t)&bfreelist);
238	}
5603d07d BJ	239	if ((bp->b_flags&B_ERROR) && bp->b_dev != NODEV) {
5603d07d BJ	240	bunhash(bp);
663dbc72	241	bp->b_dev = NODEV; /* no assoc. on error */
5603d07d	242	}
663dbc72 BJ	243	s = spl6();
	244	if(bp->b_flags & (B_AGE\|B_ERROR)) {
	245	backp = &bfreelist.av_forw;
	246	(*backp)->av_back = bp;
	247	bp->av_forw = *backp;
	248	*backp = bp;
	249	bp->av_back = &bfreelist;
	250	} else {
	251	backp = &bfreelist.av_back;
	252	(*backp)->av_forw = bp;
	253	bp->av_back = *backp;
	254	*backp = bp;
	255	bp->av_forw = &bfreelist;
	256	}
	257	bp->b_flags &= ~(B_WANTED\|B_BUSY\|B_ASYNC\|B_AGE);
	258	splx(s);
	259	}
	260
	261	/*
	262	* See if the block is associated with some buffer
	263	* (mainly to avoid getting hung up on a wait in breada)
	264	*/
	265	incore(dev, blkno)
	266	dev_t dev;
	267	daddr_t blkno;
	268	{
	269	register struct buf *bp;
663dbc72 BJ	270	register int dblkno = fsbtodb(blkno);
663dbc72 BJ	271
5603d07d BJ	272	for (bp = &buf[bufhash[BUFHASH(blkno)]]; bp != &buf[-1];
5603d07d BJ	273	bp = &buf[bp->b_hlink])
fe8987fb	274	if (bp->b_blkno == dblkno && bp->b_dev == dev)
5603d07d	275	return (1);
5603d07d	276	return (0);
663dbc72 BJ	277	}
	278
	279	struct buf *
	280	baddr(dev, blkno)
	281	dev_t dev;
	282	daddr_t blkno;
	283	{
	284
	285	if (incore(dev, blkno))
	286	return (bread(dev, blkno));
	287	return (0);
	288	}
	289
	290	/*
	291	* Assign a buffer for the given block. If the appropriate
	292	* block is already associated, return it; otherwise search
	293	* for the oldest non-busy buffer and reassign it.
	294	*/
	295	struct buf *
	296	getblk(dev, blkno)
	297	dev_t dev;
	298	daddr_t blkno;
	299	{
5603d07d BJ	300	register struct buf bp, dp, *ep;
5603d07d BJ	301	register int i, x;
663dbc72 BJ	302	register int dblkno = fsbtodb(blkno);
663dbc72 BJ	303
663dbc72	304	loop:
81263dba	305	(void) spl0();
5603d07d BJ	306	for (bp = &buf[bufhash[BUFHASH(blkno)]]; bp != &buf[-1];
	307	bp = &buf[bp->b_hlink]) {
	308	if (bp->b_blkno != dblkno \|\| bp->b_dev != dev)
663dbc72	309	continue;
81263dba	310	(void) spl6();
663dbc72 BJ	311	if (bp->b_flags&B_BUSY) {
	312	bp->b_flags \|= B_WANTED;
	313	sleep((caddr_t)bp, PRIBIO+1);
	314	goto loop;
	315	}
81263dba	316	(void) spl0();
663dbc72 BJ	317	#ifdef DISKMON
	318	i = 0;
	319	dp = bp->av_forw;
	320	while (dp != &bfreelist) {
	321	i++;
	322	dp = dp->av_forw;
	323	}
	324	if (i<NBUF)
	325	io_info.bufcount[i]++;
	326	#endif
	327	notavail(bp);
	328	bp->b_flags \|= B_CACHE;
	329	return(bp);
	330	}
5603d07d BJ	331	if (major(dev) >= nblkdev)
	332	panic("blkdev");
	333	dp = bdevsw[major(dev)].d_tab;
	334	if (dp == NULL)
	335	panic("devtab");
81263dba	336	(void) spl6();
663dbc72 BJ	337	if (bfreelist.av_forw == &bfreelist) {
	338	bfreelist.b_flags \|= B_WANTED;
	339	sleep((caddr_t)&bfreelist, PRIBIO+1);
	340	goto loop;
	341	}
	342	spl0();
	343	bp = bfreelist.av_forw;
	344	notavail(bp);
	345	if (bp->b_flags & B_DELWRI) {
	346	bp->b_flags \|= B_ASYNC;
	347	bwrite(bp);
	348	goto loop;
	349	}
5603d07d BJ	350	if (bp->b_dev == NODEV)
	351	goto done;
	352	/* INLINE EXPANSION OF bunhash(bp) */
	353	i = BUFHASH(dbtofsb(bp->b_blkno));
	354	x = bp - buf;
	355	if (bufhash[i] == x) {
	356	bufhash[i] = bp->b_hlink;
	357	} else {
	358	for (ep = &buf[bufhash[i]]; ep != &buf[-1];
	359	ep = &buf[ep->b_hlink])
	360	if (ep->b_hlink == x) {
	361	ep->b_hlink = bp->b_hlink;
	362	goto done;
	363	}
	364	panic("getblk");
	365	}
	366	done:
	367	/* END INLINE EXPANSION */
663dbc72 BJ	368	bp->b_flags = B_BUSY;
	369	bp->b_back->b_forw = bp->b_forw;
	370	bp->b_forw->b_back = bp->b_back;
	371	bp->b_forw = dp->b_forw;
	372	bp->b_back = dp;
	373	dp->b_forw->b_back = bp;
	374	dp->b_forw = bp;
	375	bp->b_dev = dev;
	376	bp->b_blkno = dblkno;
5603d07d BJ	377	i = BUFHASH(blkno);
	378	bp->b_hlink = bufhash[i];
	379	bufhash[i] = bp - buf;
663dbc72 BJ	380	return(bp);
	381	}
	382
	383	/*
	384	* get an empty block,
	385	* not assigned to any particular device
	386	*/
	387	struct buf *
	388	geteblk()
	389	{
5603d07d BJ	390	register struct buf bp, dp, *ep;
5603d07d BJ	391	register int i, x;
663dbc72 BJ	392
663dbc72 BJ	393	loop:
81263dba	394	(void) spl6();
663dbc72 BJ	395	while (bfreelist.av_forw == &bfreelist) {
	396	bfreelist.b_flags \|= B_WANTED;
	397	sleep((caddr_t)&bfreelist, PRIBIO+1);
	398	}
81263dba	399	(void) spl0();
663dbc72 BJ	400	dp = &bfreelist;
	401	bp = bfreelist.av_forw;
	402	notavail(bp);
	403	if (bp->b_flags & B_DELWRI) {
	404	bp->b_flags \|= B_ASYNC;
	405	bwrite(bp);
	406	goto loop;
	407	}
5603d07d BJ	408	if (bp->b_dev != NODEV)
5603d07d BJ	409	bunhash(bp);
663dbc72 BJ	410	bp->b_flags = B_BUSY;
	411	bp->b_back->b_forw = bp->b_forw;
	412	bp->b_forw->b_back = bp->b_back;
	413	bp->b_forw = dp->b_forw;
	414	bp->b_back = dp;
	415	dp->b_forw->b_back = bp;
	416	dp->b_forw = bp;
	417	bp->b_dev = (dev_t)NODEV;
5603d07d	418	bp->b_hlink = -1;
663dbc72 BJ	419	return(bp);
	420	}
	421
5603d07d BJ	422	bunhash(bp)
	423	register struct buf *bp;
	424	{
	425	register struct buf *ep;
	426	register int i, x;
	427
	428	if (bp->b_dev == NODEV)
	429	return;
	430	i = BUFHASH(dbtofsb(bp->b_blkno));
	431	x = bp - buf;
	432	if (bufhash[i] == x) {
	433	bufhash[i] = bp->b_hlink;
	434	return;
	435	}
	436	for (ep = &buf[bufhash[i]]; ep != &buf[-1];
	437	ep = &buf[ep->b_hlink])
	438	if (ep->b_hlink == x) {
	439	ep->b_hlink = bp->b_hlink;
	440	return;
	441	}
	442	panic("bunhash");
	443	}
	444
663dbc72 BJ	445	/*
	446	* Wait for I/O completion on the buffer; return errors
	447	* to the user.
	448	*/
	449	iowait(bp)
	450	register struct buf *bp;
	451	{
	452
81263dba	453	(void) spl6();
663dbc72 BJ	454	while ((bp->b_flags&B_DONE)==0)
663dbc72 BJ	455	sleep((caddr_t)bp, PRIBIO);
81263dba	456	(void) spl0();
663dbc72 BJ	457	geterror(bp);
	458	}
	459
	460	#ifndef FASTVAX
	461	/*
	462	* Unlink a buffer from the available list and mark it busy.
	463	* (internal interface)
	464	*/
	465	notavail(bp)
	466	register struct buf *bp;
	467	{
	468	register s;
	469
	470	s = spl6();
	471	bp->av_back->av_forw = bp->av_forw;
	472	bp->av_forw->av_back = bp->av_back;
	473	bp->b_flags \|= B_BUSY;
	474	splx(s);
	475	}
	476	#endif
	477
	478	/*
	479	* Mark I/O complete on a buffer. If the header
	480	* indicates a dirty page push completion, the
	481	* header is inserted into the ``cleaned'' list
	482	* to be processed by the pageout daemon. Otherwise
	483	* release it if I/O is asynchronous, and wake
	484	* up anyone waiting for it.
	485	*/
	486	iodone(bp)
	487	register struct buf *bp;
	488	{
	489	register int s;
	490
	491	bp->b_flags \|= B_DONE;
	492	if (bp->b_flags & B_DIRTY) {
	493	if (bp->b_flags & B_ERROR)
	494	panic("IO err in push");
	495	s = spl6();
	496	cnt.v_pgout++;
	497	bp->av_forw = bclnlist;
	498	bp->b_bcount = swsize[bp - swbuf];
	499	bp->b_pfcent = swpf[bp - swbuf];
	500	bclnlist = bp;
	501	if (bswlist.b_flags & B_WANTED)
	502	wakeup((caddr_t)&proc[2]);
	503	splx(s);
	504	}
	505	if (bp->b_flags&B_ASYNC)
	506	brelse(bp);
	507	else {
	508	bp->b_flags &= ~B_WANTED;
	509	wakeup((caddr_t)bp);
	510	}
	511	}
	512
	513	/*
	514	* Zero the core associated with a buffer.
	515	*/
	516	clrbuf(bp)
	517	struct buf *bp;
	518	{
	519	register *p;
	520	register c;
521
522	p = bp->b_un.b_words;
523	c = BSIZE/sizeof(int);
524	do
525	*p++ = 0;
526	while (--c);
527	bp->b_resid = 0;
528	}
529
530	/*
531	* swap I/O -
532	*
533	* If the flag indicates a dirty page push initiated
534	* by the pageout daemon, we map the page into the i th
535	* virtual page of process 2 (the daemon itself) where i is
536	* the index of the swap header that has been allocated.
537	* We simply initialize the header and queue the I/O but
538	* do not wait for completion. When the I/O completes,
539	* iodone() will link the header to a list of cleaned
540	* pages to be processed by the pageout daemon.
541	*/
542	swap(p, dblkno, addr, nbytes, rdflg, flag, dev, pfcent)
543	struct proc *p;
544	swblk_t dblkno;
545	caddr_t addr;
546	int flag, nbytes;
547	dev_t dev;
548	unsigned pfcent;
549	{
550	register struct buf *bp;
551	register int c;
552	int p2dp;
553	register struct pte dpte, vpte;
554
81263dba	555	(void) spl6();
663dbc72 BJ	556	while (bswlist.av_forw == NULL) {
	557	bswlist.b_flags \|= B_WANTED;
	558	sleep((caddr_t)&bswlist, PSWP+1);
	559	}
	560	bp = bswlist.av_forw;
	561	bswlist.av_forw = bp->av_forw;
81263dba	562	(void) spl0();
663dbc72 BJ	563
	564	bp->b_flags = B_BUSY \| B_PHYS \| rdflg \| flag;
	565	if ((bp->b_flags & (B_DIRTY\|B_PGIN)) == 0)
	566	if (rdflg == B_READ)
	567	sum.v_pswpin += btoc(nbytes);
	568	else
	569	sum.v_pswpout += btoc(nbytes);
	570	bp->b_proc = p;
	571	if (flag & B_DIRTY) {
	572	p2dp = ((bp - swbuf) * CLSIZE) * KLMAX;
	573	dpte = dptopte(&proc[2], p2dp);
	574	vpte = vtopte(p, btop(addr));
	575	for (c = 0; c < nbytes; c += NBPG) {
	576	if (vpte->pg_pfnum == 0 \|\| vpte->pg_fod)
	577	panic("swap bad pte");
	578	dpte++ = vpte++;
	579	}
	580	bp->b_un.b_addr = (caddr_t)ctob(p2dp);
	581	} else
	582	bp->b_un.b_addr = addr;
	583	while (nbytes > 0) {
	584	c = imin(ctob(120), nbytes);
	585	bp->b_bcount = c;
	586	bp->b_blkno = dblkno;
	587	bp->b_dev = dev;
	588	if (dev == swapdev)
	589	bp->b_blkno += swplo;
	590	(*bdevsw[major(dev)].d_strategy)(bp);
	591	if (flag & B_DIRTY) {
	592	if (c < nbytes)
	593	panic("big push");
	594	swsize[bp - swbuf] = nbytes;
	595	swpf[bp - swbuf] = pfcent;
	596	return;
	597	}
81263dba	598	(void) spl6();
663dbc72 BJ	599	while((bp->b_flags&B_DONE)==0)
663dbc72 BJ	600	sleep((caddr_t)bp, PSWP);
81263dba	601	(void) spl0();
663dbc72 BJ	602	bp->b_un.b_addr += c;
	603	bp->b_flags &= ~B_DONE;
	604	if (bp->b_flags & B_ERROR) {
	605	if ((flag & (B_UAREA\|B_PAGET)) \|\| rdflg == B_WRITE)
	606	panic("hard IO err in swap");
	607	swkill(p, (char *)0);
	608	}
	609	nbytes -= c;
	610	dblkno += btoc(c);
	611	}
81263dba	612	(void) spl6();
663dbc72 BJ	613	bp->b_flags &= ~(B_BUSY\|B_WANTED\|B_PHYS\|B_PAGET\|B_UAREA\|B_DIRTY);
	614	bp->av_forw = bswlist.av_forw;
	615	bswlist.av_forw = bp;
	616	if (bswlist.b_flags & B_WANTED) {
	617	bswlist.b_flags &= ~B_WANTED;
	618	wakeup((caddr_t)&bswlist);
	619	wakeup((caddr_t)&proc[2]);
	620	}
81263dba	621	(void) spl0();
663dbc72 BJ	622	}
	623
	624	/*
	625	* If rout == 0 then killed on swap error, else
	626	* rout is the name of the routine where we ran out of
	627	* swap space.
	628	*/
	629	swkill(p, rout)
	630	struct proc *p;
	631	char *rout;
	632	{
	633
	634	printf("%d: ", p->p_pid);
	635	if (rout)
	636	printf("out of swap space in %s\n", rout);
	637	else
	638	printf("killed on swap error\n");
	639	/*
	640	* To be sure no looping (e.g. in vmsched trying to
	641	* swap out) mark process locked in core (as though
	642	* done by user) after killing it so noone will try
	643	* to swap it out.
	644	*/
	645	psignal(p, SIGKIL);
	646	p->p_flag \|= SULOCK;
	647	}
	648
	649	/*
	650	* make sure all write-behind blocks
	651	* on dev (or NODEV for all)
	652	* are flushed out.
	653	* (from umount and update)
	654	*/
	655	bflush(dev)
	656	dev_t dev;
	657	{
	658	register struct buf *bp;
	659
	660	loop:
81263dba	661	(void) spl6();
663dbc72 BJ	662	for (bp = bfreelist.av_forw; bp != &bfreelist; bp = bp->av_forw) {
	663	if (bp->b_flags&B_DELWRI && (dev == NODEV\|\|dev==bp->b_dev)) {
	664	bp->b_flags \|= B_ASYNC;
	665	notavail(bp);
	666	bwrite(bp);
	667	goto loop;
	668	}
	669	}
81263dba	670	(void) spl0();
663dbc72 BJ	671	}
	672
	673	/*
	674	* Raw I/O. The arguments are
	675	* The strategy routine for the device
	676	* A buffer, which will always be a special buffer
	677	* header owned exclusively by the device for this purpose
	678	* The device number
	679	* Read/write flag
	680	* Essentially all the work is computing physical addresses and
	681	* validating them.
	682	* If the user has the proper access privilidges, the process is
	683	* marked 'delayed unlock' and the pages involved in the I/O are
	684	* faulted and locked. After the completion of the I/O, the above pages
	685	* are unlocked.
	686	*/
	687	physio(strat, bp, dev, rw, mincnt)
	688	int (*strat)();
	689	register struct buf *bp;
	690	unsigned (*mincnt)();
	691	{
	692	register int c;
	693	char *a;
	694
	695	if (useracc(u.u_base,u.u_count,rw==B_READ?B_WRITE:B_READ) == NULL) {
	696	u.u_error = EFAULT;
	697	return;
	698	}
81263dba	699	(void) spl6();
663dbc72 BJ	700	while (bp->b_flags&B_BUSY) {
	701	bp->b_flags \|= B_WANTED;
	702	sleep((caddr_t)bp, PRIBIO+1);
	703	}
	704	bp->b_error = 0;
	705	bp->b_proc = u.u_procp;
	706	bp->b_un.b_addr = u.u_base;
	707	while (u.u_count != 0 && bp->b_error==0) {
	708	bp->b_flags = B_BUSY \| B_PHYS \| rw;
	709	bp->b_dev = dev;
	710	bp->b_blkno = u.u_offset >> PGSHIFT;
	711	bp->b_bcount = u.u_count;
	712	(*mincnt)(bp);
	713	c = bp->b_bcount;
	714	u.u_procp->p_flag \|= SPHYSIO;
	715	vslock(a = bp->b_un.b_addr, c);
	716	(*strat)(bp);
81263dba	717	(void) spl6();
663dbc72 BJ	718	while ((bp->b_flags&B_DONE) == 0)
	719	sleep((caddr_t)bp, PRIBIO);
	720	vsunlock(a, c, rw);
	721	u.u_procp->p_flag &= ~SPHYSIO;
	722	if (bp->b_flags&B_WANTED)
	723	wakeup((caddr_t)bp);
81263dba	724	(void) spl0();
663dbc72 BJ	725	bp->b_un.b_addr += c;
	726	u.u_count -= c;
	727	u.u_offset += c;
	728	}
	729	bp->b_flags &= ~(B_BUSY\|B_WANTED\|B_PHYS);
	730	u.u_count = bp->b_resid;
	731	geterror(bp);
	732	}
	733
	734	/ARGSUSED/
	735	unsigned
	736	minphys(bp)
	737	struct buf *bp;
	738	{
	739
	740	if (bp->b_bcount > 60 * 1024)
	741	bp->b_bcount = 60 * 1024;
	742	}
	743
	744	/*
	745	* Pick up the device's error number and pass it to the user;
	746	* if there is an error but the number is 0 set a generalized
	747	* code. Actually the latter is always true because devices
	748	* don't yet return specific errors.
	749	*/
	750	geterror(bp)
	751	register struct buf *bp;
	752	{
	753
	754	if (bp->b_flags&B_ERROR)
	755	if ((u.u_error = bp->b_error)==0)
	756	u.u_error = EIO;
	757	}