freebsd-dev/sys/dev/vinum/vinuminterrupt.c
1999-08-24 02:23:21 +00:00

392 lines
16 KiB
C

/* vinuminterrupt.c: bottom half of the driver */
/*-
* Copyright (c) 1997, 1998, 1999
* Nan Yang Computer Services Limited. All rights reserved.
*
* Parts copyright (c) 1997, 1998 Cybernet Corporation, NetMAX project.
*
* Written by Greg Lehey
*
* This software is distributed under the so-called ``Berkeley
* License'':
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by Nan Yang Computer
* Services Limited.
* 4. Neither the name of the Company nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* This software is provided ``as is'', and any express or implied
* warranties, including, but not limited to, the implied warranties of
* merchantability and fitness for a particular purpose are disclaimed.
* In no event shall the company or contributors be liable for any
* direct, indirect, incidental, special, exemplary, or consequential
* damages (including, but not limited to, procurement of substitute
* goods or services; loss of use, data, or profits; or business
* interruption) however caused and on any theory of liability, whether
* in contract, strict liability, or tort (including negligence or
* otherwise) arising in any way out of the use of this software, even if
* advised of the possibility of such damage.
*
* $Id: vinuminterrupt.c,v 1.6 1999/06/18 00:50:53 grog Exp grog $
*/
#include <dev/vinum/vinumhdr.h>
#include <dev/vinum/request.h>
#include <sys/resourcevar.h>
void complete_raid5_write(struct rqelement *);
void complete_rqe(struct buf *bp);
void sdio_done(struct buf *bp);
/*
* Take a completed buffer, transfer the data back if
* it's a read, and complete the high-level request
* if this is the last subrequest.
*
* The bp parameter is in fact a struct rqelement, which
* includes a couple of extras at the end.
*/
void
complete_rqe(struct buf *bp)
{
struct rqelement *rqe;
struct request *rq;
struct rqgroup *rqg;
struct buf *ubp; /* user buffer */
rqe = (struct rqelement *) bp; /* point to the element element that completed */
rqg = rqe->rqg; /* and the request group */
rq = rqg->rq; /* and the complete request */
ubp = rq->bp; /* user buffer */
#ifdef VINUMDEBUG
if (debug & DEBUG_LASTREQS)
logrq(loginfo_iodone, (union rqinfou) rqe, ubp);
#endif
if ((bp->b_flags & B_ERROR) != 0) { /* transfer in error */
if (bp->b_error != 0) /* did it return a number? */
rq->error = bp->b_error; /* yes, put it in. */
else if (rq->error == 0) /* no: do we have one already? */
rq->error = EIO; /* no: catchall "I/O error" */
SD[rqe->sdno].lasterror = rq->error;
if (bp->b_flags & B_READ) {
log(LOG_ERR, "%s: fatal read I/O error\n", SD[rqe->sdno].name);
set_sd_state(rqe->sdno, sd_crashed, setstate_force); /* subdisk is crashed */
} else { /* write operation */
log(LOG_ERR, "%s: fatal write I/O error\n", SD[rqe->sdno].name);
set_sd_state(rqe->sdno, sd_stale, setstate_force); /* subdisk is stale */
}
if (rq->error == ENXIO) { /* the drive's down too */
log(LOG_ERR, "%s: fatal drive I/O error\n", DRIVE[rqe->driveno].label.name);
DRIVE[rqe->driveno].lasterror = rq->error;
set_drive_state(rqe->driveno, /* take the drive down */
drive_down,
setstate_force);
}
}
/* Now update the statistics */
if (bp->b_flags & B_READ) { /* read operation */
DRIVE[rqe->driveno].reads++;
DRIVE[rqe->driveno].bytes_read += bp->b_bcount;
SD[rqe->sdno].reads++;
SD[rqe->sdno].bytes_read += bp->b_bcount;
PLEX[rqe->rqg->plexno].reads++;
PLEX[rqe->rqg->plexno].bytes_read += bp->b_bcount;
} else { /* write operation */
DRIVE[rqe->driveno].writes++;
DRIVE[rqe->driveno].bytes_written += bp->b_bcount;
SD[rqe->sdno].writes++;
SD[rqe->sdno].bytes_written += bp->b_bcount;
PLEX[rqe->rqg->plexno].writes++;
PLEX[rqe->rqg->plexno].bytes_written += bp->b_bcount;
}
rqg->active--; /* one less request active */
if (rqg->flags & XFR_RECOVERY_READ) { /* recovery read, */
int *sdata; /* source */
int *data; /* and group data */
int length; /* and count involved */
int count; /* loop counter */
struct rqelement *urqe = &rqg->rqe[rqg->badsdno]; /* rqe of the bad subdisk */
/* XOR destination is the user data */
sdata = (int *) &rqe->b.b_data[rqe->groupoffset << DEV_BSHIFT]; /* old data contents */
data = (int *) &urqe->b.b_data[urqe->groupoffset << DEV_BSHIFT]; /* destination */
length = urqe->grouplen << (DEV_BSHIFT - 2); /* and count involved */
for (count = 0; count < length; count++)
data[count] ^= sdata[count];
/*
* In a normal read, we will normally read directly
* into the user buffer. This doesn't work if
* we're also doing a recovery, so we have to
* copy it
*/
if (rqe->flags & XFR_NORMAL_READ) { /* normal read as well, */
char *src = &rqe->b.b_data[rqe->dataoffset << DEV_BSHIFT]; /* read data is here */
char *dst;
dst = (char *) ubp->b_data + (rqe->useroffset << DEV_BSHIFT); /* where to put it in user buffer */
length = rqe->datalen << DEV_BSHIFT; /* and count involved */
bcopy(src, dst, length); /* move it */
}
} else if ((rqg->flags & (XFR_NORMAL_WRITE | XFR_DEGRADED_WRITE)) /* RAID 5 group write operation */
&&(rqg->active == 0)) /* and we've finished phase 1 */
complete_raid5_write(rqe);
if (rqg->active == 0) /* request group finished, */
rq->active--; /* one less */
if (rq->active == 0) { /* request finished, */
#if VINUMDEBUG
if (debug & DEBUG_RESID) {
if (ubp->b_resid != 0) /* still something to transfer? */
Debugger("resid");
}
#endif
if (rq->error) { /* did we have an error? */
if (rq->isplex) { /* plex operation, */
ubp->b_flags |= B_ERROR; /* yes, propagate to user */
ubp->b_error = rq->error;
} else /* try to recover */
queue_daemon_request(daemonrq_ioerror, (union daemoninfo) rq); /* let the daemon complete */
} else {
ubp->b_resid = 0; /* completed our transfer */
if (rq->isplex == 0) /* volume request, */
VOL[rq->volplex.volno].active--; /* another request finished */
biodone(ubp); /* top level buffer completed */
freerq(rq); /* return the request storage */
}
}
}
/* Free a request block and anything hanging off it */
void
freerq(struct request *rq)
{
struct rqgroup *rqg;
struct rqgroup *nrqg; /* next in chain */
int rqno;
for (rqg = rq->rqg; rqg != NULL; rqg = nrqg) { /* through the whole request chain */
if (rqg->lock) /* got a lock? */
unlockrange(rqg->plexno, rqg->lock); /* yes, free it */
for (rqno = 0; rqno < rqg->count; rqno++)
if ((rqg->rqe[rqno].flags & XFR_MALLOCED) /* data buffer was malloced, */
&&rqg->rqe[rqno].b.b_data) /* and the allocation succeeded */
Free(rqg->rqe[rqno].b.b_data); /* free it */
nrqg = rqg->next; /* note the next one */
Free(rqg); /* and free this one */
}
Free(rq); /* free the request itself */
}
/* I/O on subdisk completed */
void
sdio_done(struct buf *bp)
{
struct sdbuf *sbp;
sbp = (struct sdbuf *) bp;
if (sbp->b.b_flags & B_ERROR) { /* had an error */
bp->b_flags |= B_ERROR;
bp->b_error = sbp->b.b_error;
}
sbp->bp->b_resid = sbp->b.b_resid; /* copy the resid field */
biodone(sbp->bp); /* complete the caller's I/O */
/* Now update the statistics */
if (bp->b_flags & B_READ) { /* read operation */
DRIVE[sbp->driveno].reads++;
DRIVE[sbp->driveno].bytes_read += bp->b_bcount;
SD[sbp->sdno].reads++;
SD[sbp->sdno].bytes_read += bp->b_bcount;
} else { /* write operation */
DRIVE[sbp->driveno].writes++;
DRIVE[sbp->driveno].bytes_written += bp->b_bcount;
SD[sbp->sdno].writes++;
SD[sbp->sdno].bytes_written += bp->b_bcount;
}
Free(sbp);
}
/* Start the second phase of a RAID5 group write operation. */
void
complete_raid5_write(struct rqelement *rqe)
{
int *sdata; /* source */
int *pdata; /* and parity block data */
int length; /* and count involved */
int count; /* loop counter */
int rqno; /* request index */
int rqoffset; /* offset of request data from parity data */
struct buf *bp; /* user buffer header */
struct request *rq; /* pointer to our request */
struct rqgroup *rqg; /* and to the request group */
struct rqelement *prqe; /* point to the parity block */
struct drive *drive; /* drive to access */
rqg = rqe->rqg; /* and to our request group */
rq = rqg->rq; /* point to our request */
bp = rq->bp; /* user's buffer header */
prqe = &rqg->rqe[0]; /* point to the parity block */
/*
* If we get to this function, we have normal or
* degraded writes, or a combination of both. We do
* the same thing in each case: we perform an
* exclusive or to the parity block. The only
* difference is the origin of the data and the
* address range.
*/
if (rqe->flags & XFR_DEGRADED_WRITE) { /* do the degraded write stuff */
pdata = (int *) (&prqe->b.b_data[(prqe->groupoffset) << DEV_BSHIFT]); /* parity data pointer */
bzero(pdata, prqe->grouplen << DEV_BSHIFT); /* start with nothing in the parity block */
/* Now get what data we need from each block */
for (rqno = 1; rqno < rqg->count; rqno++) { /* for all the data blocks */
/*
* This can do with improvement. If we're doing
* both a degraded and a normal write, we don't
* need to xor (nor to read) the part of the block
* that we're going to overwrite. FIXME XXX
*/
rqe = &rqg->rqe[rqno]; /* this request */
sdata = (int *) (&rqe->b.b_data[rqe->groupoffset << DEV_BSHIFT]); /* old data */
length = rqe->grouplen << (DEV_BSHIFT - 2); /* and count involved */
/*
* add the data block to the parity block. Before
* we started the request, we zeroed the parity
* block, so the result of adding all the other
* blocks and the block we want to write will be
* the correct parity block.
*/
for (count = 0; count < length; count++)
pdata[count] ^= sdata[count];
if ((rqe->flags & XFR_MALLOCED) /* the buffer was malloced, */
&&((rqg->flags & XFR_NORMAL_WRITE) == 0)) { /* and we have no normal write, */
Free(rqe->b.b_data); /* free it now */
rqe->flags &= ~XFR_MALLOCED;
}
}
}
if (rqg->flags & XFR_NORMAL_WRITE) { /* do normal write stuff */
/* Get what data we need from each block */
for (rqno = 1; rqno < rqg->count; rqno++) { /* for all the data blocks */
rqe = &rqg->rqe[rqno]; /* this request */
if ((rqe->flags & (XFR_DATA_BLOCK | XFR_BAD_SUBDISK | XFR_NORMAL_WRITE))
== (XFR_DATA_BLOCK | XFR_NORMAL_WRITE)) { /* good data block to write */
sdata = (int *) &rqe->b.b_data[rqe->dataoffset << DEV_BSHIFT]; /* old data contents */
rqoffset = rqe->dataoffset + rqe->sdoffset - prqe->sdoffset; /* corresponding parity block offset */
pdata = (int *) (&prqe->b.b_data[rqoffset << DEV_BSHIFT]); /* parity data pointer */
length = rqe->datalen << (DEV_BSHIFT - 2); /* and count involved */
/*
* "remove" the old data block
* from the parity block
*/
if ((pdata < ((int *) prqe->b.b_data))
|| (&pdata[length] > ((int *) (prqe->b.b_data + prqe->b.b_bcount)))
|| (sdata < ((int *) rqe->b.b_data))
|| (&sdata[length] > ((int *) (rqe->b.b_data + rqe->b.b_bcount))))
panic("complete_raid5_write: bounds overflow");
for (count = 0; count < length; count++)
pdata[count] ^= sdata[count];
/* "add" the new data block */
sdata = (int *) (&bp->b_data[rqe->useroffset << DEV_BSHIFT]); /* new data */
if ((sdata < ((int *) bp->b_data))
|| (&sdata[length] > ((int *) (bp->b_data + bp->b_bcount))))
panic("complete_raid5_write: bounds overflow");
for (count = 0; count < length; count++)
pdata[count] ^= sdata[count];
/* Free the malloced buffer */
if (rqe->flags & XFR_MALLOCED) { /* the buffer was malloced, */
Free(rqe->b.b_data); /* free it */
rqe->flags &= ~XFR_MALLOCED;
} else
panic("complete_raid5_write: malloc conflict");
if ((rqe->b.b_flags & B_READ) /* this was a read */
&&((rqe->flags & XFR_BAD_SUBDISK) == 0)) { /* and we can write this block */
rqe->b.b_flags &= ~(B_READ | B_DONE); /* we're writing now */
rqe->b.b_flags |= B_CALL; /* call us when you're done */
rqe->flags &= ~XFR_PARITYOP; /* reset flags that brought use here */
rqe->b.b_data = &bp->b_data[rqe->useroffset << DEV_BSHIFT]; /* point to the user data */
rqe->b.b_bcount = rqe->datalen << DEV_BSHIFT; /* length to write */
rqe->b.b_bufsize = rqe->b.b_bcount; /* don't claim more */
rqe->b.b_resid = rqe->b.b_bcount; /* nothing transferred */
rqe->b.b_blkno += rqe->dataoffset; /* point to the correct block */
rqg->active++; /* another active request */
rqe->b.b_vp->v_numoutput++; /* one more output going */
drive = &DRIVE[rqe->driveno]; /* drive to access */
#if VINUMDEBUG
if (debug & DEBUG_ADDRESSES)
log(LOG_DEBUG,
" %s dev %d.%d, sd %d, offset 0x%x, devoffset 0x%x, length %ld\n",
rqe->b.b_flags & B_READ ? "Read" : "Write",
major(rqe->b.b_dev),
minor(rqe->b.b_dev),
rqe->sdno,
(u_int) (rqe->b.b_blkno - SD[rqe->sdno].driveoffset),
rqe->b.b_blkno,
rqe->b.b_bcount);
if (debug & DEBUG_NUMOUTPUT)
log(LOG_DEBUG,
" raid5.2 sd %d numoutput %ld\n",
rqe->sdno,
rqe->b.b_vp->v_numoutput);
if (debug & DEBUG_LASTREQS)
logrq(loginfo_raid5_data, (union rqinfou) rqe, bp);
#endif
BUF_STRATEGY(&rqe->b, 0);
}
}
}
}
/* Finally, write the parity block */
rqe = &rqg->rqe[0];
rqe->b.b_flags &= ~(B_READ | B_DONE); /* we're writing now */
rqe->b.b_flags |= B_CALL; /* call us when you're done */
rqe->flags &= ~XFR_PARITYOP; /* reset flags that brought use here */
rqg->flags &= ~XFR_PARITYOP; /* reset flags that brought use here */
rqe->b.b_bcount = rqe->buflen << DEV_BSHIFT; /* length to write */
rqe->b.b_bufsize = rqe->b.b_bcount; /* don't claim we have more */
rqe->b.b_resid = rqe->b.b_bcount; /* nothing transferred */
rqg->active++; /* another active request */
rqe->b.b_vp->v_numoutput++; /* one more output going */
drive = &DRIVE[rqe->driveno]; /* drive to access */
#if VINUMDEBUG
if (debug & DEBUG_ADDRESSES)
log(LOG_DEBUG,
" %s dev %d.%d, sd %d, offset 0x%x, devoffset 0x%x, length %ld\n",
rqe->b.b_flags & B_READ ? "Read" : "Write",
major(rqe->b.b_dev),
minor(rqe->b.b_dev),
rqe->sdno,
(u_int) (rqe->b.b_blkno - SD[rqe->sdno].driveoffset),
rqe->b.b_blkno,
rqe->b.b_bcount);
if (debug & DEBUG_NUMOUTPUT)
log(LOG_DEBUG,
" raid5.3 sd %d numoutput %ld\n",
rqe->sdno,
rqe->b.b_vp->v_numoutput);
if (debug & DEBUG_LASTREQS)
logrq(loginfo_raid5_parity, (union rqinfou) rqe, bp);
#endif
BUF_STRATEGY(&rqe->b, 0);
}