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514 lines
13 KiB
C
514 lines
13 KiB
C
/*-
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* See the file LICENSE for redistribution information.
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*
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* Copyright (c) 1996, 1997, 1998
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* Sleepycat Software. All rights reserved.
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*/
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#include "config.h"
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#ifndef lint
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static const char sccsid[] = "@(#)mp_sync.c 10.25 (Sleepycat) 4/26/98";
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#endif /* not lint */
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#ifndef NO_SYSTEM_INCLUDES
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#include <sys/types.h>
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#include <errno.h>
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#include <stdlib.h>
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#endif
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#include "db_int.h"
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#include "shqueue.h"
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#include "db_shash.h"
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#include "mp.h"
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#include "common_ext.h"
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static int __bhcmp __P((const void *, const void *));
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static int __memp_fsync __P((DB_MPOOLFILE *));
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/*
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* memp_sync --
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* Mpool sync function.
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*/
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int
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memp_sync(dbmp, lsnp)
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DB_MPOOL *dbmp;
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DB_LSN *lsnp;
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{
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BH *bhp, **bharray;
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DB_ENV *dbenv;
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MPOOL *mp;
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MPOOLFILE *mfp;
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int ar_cnt, cnt, nalloc, next, ret, wrote;
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dbenv = dbmp->dbenv;
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if (dbenv->lg_info == NULL) {
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__db_err(dbenv, "memp_sync: requires logging");
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return (EINVAL);
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}
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/*
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* We try and write the buffers in page order so that the underlying
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* filesystem doesn't have to seek and can write contiguous blocks,
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* plus, we don't want to hold the region lock while we write the
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* buffers. Get memory to hold the buffer pointers. Get a good-size
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* block, too, because we realloc while holding the region lock if we
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* run out.
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*/
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if ((bharray =
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(BH **)__db_malloc((nalloc = 1024) * sizeof(BH *))) == NULL)
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return (ENOMEM);
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LOCKREGION(dbmp);
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/*
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* If the application is asking about a previous call to memp_sync(),
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* and we haven't found any buffers that the application holding the
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* pin couldn't write, return yes or no based on the current count.
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* Note, if the application is asking about a LSN *smaller* than one
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* we've already handled or are currently handling, then we return a
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* result based on the count for the larger LSN.
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*/
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mp = dbmp->mp;
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if (!F_ISSET(mp, MP_LSN_RETRY) && log_compare(lsnp, &mp->lsn) <= 0) {
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if (mp->lsn_cnt == 0) {
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*lsnp = mp->lsn;
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ret = 0;
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} else
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ret = DB_INCOMPLETE;
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goto done;
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}
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/* Else, it's a new checkpoint. */
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F_CLR(mp, MP_LSN_RETRY);
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/*
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* Save the LSN. We know that it's a new LSN or larger than the one
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* for which we were already doing a checkpoint. (BTW, I don't expect
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* to see multiple LSN's from the same or multiple processes, but You
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* Just Never Know. Responding as if they all called with the largest
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* of the LSNs specified makes everything work.)
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*
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* We don't currently use the LSN we save. We could potentially save
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* the last-written LSN in each buffer header and use it to determine
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* what buffers need to be written. The problem with this is that it's
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* sizeof(LSN) more bytes of buffer header. We currently write all the
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* dirty buffers instead.
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*
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* Walk the list of shared memory segments clearing the count of
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* buffers waiting to be written.
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*/
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mp->lsn = *lsnp;
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mp->lsn_cnt = 0;
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for (mfp = SH_TAILQ_FIRST(&dbmp->mp->mpfq, __mpoolfile);
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mfp != NULL; mfp = SH_TAILQ_NEXT(mfp, q, __mpoolfile))
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mfp->lsn_cnt = 0;
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/*
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* Walk the list of buffers and mark all dirty buffers to be written
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* and all pinned buffers to be potentially written (we can't know if
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* we'll need to write them until the holding process returns them to
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* the cache). We do this in one pass while holding the region locked
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* so that processes can't make new buffers dirty, causing us to never
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* finish. Since the application may have restarted the sync, clear
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* any BH_WRITE flags that appear to be left over from previous calls.
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*
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* Keep a count of the total number of buffers we need to write in
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* MPOOL->lsn_cnt, and for each file, in MPOOLFILE->lsn_count.
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*/
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ar_cnt = 0;
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for (bhp = SH_TAILQ_FIRST(&mp->bhq, __bh);
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bhp != NULL; bhp = SH_TAILQ_NEXT(bhp, q, __bh))
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if (F_ISSET(bhp, BH_DIRTY) || bhp->ref != 0) {
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F_SET(bhp, BH_WRITE);
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++mp->lsn_cnt;
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mfp = R_ADDR(dbmp, bhp->mf_offset);
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++mfp->lsn_cnt;
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/*
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* If the buffer isn't in use, we should be able to
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* write it immediately, so save a reference to it.
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*/
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if (bhp->ref == 0) {
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if (ar_cnt == nalloc) {
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nalloc *= 2;
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if ((bharray =
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(BH **)__db_realloc(bharray,
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nalloc * sizeof(BH *))) == NULL) {
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ret = ENOMEM;
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goto err;
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}
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}
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bharray[ar_cnt++] = bhp;
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}
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} else
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if (F_ISSET(bhp, BH_WRITE))
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F_CLR(bhp, BH_WRITE);
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/* If there no buffers we can write immediately, we're done. */
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if (ar_cnt == 0) {
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ret = mp->lsn_cnt ? DB_INCOMPLETE : 0;
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goto done;
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}
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/* Lock down the buffers and their contents. */
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for (cnt = 0; cnt < ar_cnt; ++cnt)
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++bharray[cnt]->ref;
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UNLOCKREGION(dbmp);
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/* Sort the buffers we're going to write. */
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qsort(bharray, ar_cnt, sizeof(BH *), __bhcmp);
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LOCKREGION(dbmp);
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/* Walk the array, writing buffers. */
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for (next = 0; next < ar_cnt; ++next) {
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/*
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* It's possible for a thread to have gotten the buffer since
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* we listed it for writing. If the reference count is still
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* 1, we're the only ones using the buffer, go ahead and write.
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* If it's >1, then skip the buffer and assume that it will be
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* written when it's returned to the cache.
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*/
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if (bharray[next]->ref > 1) {
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--bharray[next]->ref;
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continue;
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}
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/* Write the buffer. */
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mfp = R_ADDR(dbmp, bharray[next]->mf_offset);
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ret = __memp_bhwrite(dbmp, mfp, bharray[next], NULL, &wrote);
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/* Release the buffer. */
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--bharray[next]->ref;
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/* If there's an error, release the rest of the buffers. */
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if (ret != 0 || !wrote) {
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/*
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* Any process syncing the shared memory buffer pool
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* had better be able to write to any underlying file.
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* Be understanding, but firm, on this point.
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*/
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if (ret == 0) {
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__db_err(dbenv, "%s: unable to flush page: %lu",
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__memp_fns(dbmp, mfp),
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(u_long)bharray[next]->pgno);
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ret = EPERM;
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}
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while (++next < ar_cnt)
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--bharray[next]->ref;
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goto err;
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}
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}
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ret = mp->lsn_cnt ? DB_INCOMPLETE : 0;
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done:
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if (0) {
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err: /*
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* On error, clear:
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* MPOOL->lsn_cnt (the total sync count)
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* MPOOLFILE->lsn_cnt (the per-file sync count)
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* BH_WRITE flag (the scheduled for writing flag)
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*/
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mp->lsn_cnt = 0;
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for (mfp = SH_TAILQ_FIRST(&dbmp->mp->mpfq, __mpoolfile);
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mfp != NULL; mfp = SH_TAILQ_NEXT(mfp, q, __mpoolfile))
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mfp->lsn_cnt = 0;
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for (bhp = SH_TAILQ_FIRST(&mp->bhq, __bh);
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bhp != NULL; bhp = SH_TAILQ_NEXT(bhp, q, __bh))
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F_CLR(bhp, BH_WRITE);
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}
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UNLOCKREGION(dbmp);
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__db_free(bharray);
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return (ret);
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}
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/*
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* memp_fsync --
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* Mpool file sync function.
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*/
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int
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memp_fsync(dbmfp)
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DB_MPOOLFILE *dbmfp;
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{
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DB_MPOOL *dbmp;
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int is_tmp;
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dbmp = dbmfp->dbmp;
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/*
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* If this handle doesn't have a file descriptor that's open for
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* writing, or if the file is a temporary, there's no reason to
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* proceed further.
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*/
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if (F_ISSET(dbmfp, MP_READONLY))
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return (0);
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LOCKREGION(dbmp);
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is_tmp = F_ISSET(dbmfp->mfp, MP_TEMP);
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UNLOCKREGION(dbmp);
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if (is_tmp)
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return (0);
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return (__memp_fsync(dbmfp));
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}
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/*
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* __mp_xxx_fd --
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* Return a file descriptor for DB 1.85 compatibility locking.
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*
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* PUBLIC: int __mp_xxx_fd __P((DB_MPOOLFILE *, int *));
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*/
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int
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__mp_xxx_fd(dbmfp, fdp)
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DB_MPOOLFILE *dbmfp;
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int *fdp;
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{
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int ret;
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/*
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* This is a truly spectacular layering violation, intended ONLY to
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* support compatibility for the DB 1.85 DB->fd call.
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*
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* Sync the database file to disk, creating the file as necessary.
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*
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* We skip the MP_READONLY and MP_TEMP tests done by memp_fsync(3).
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* The MP_READONLY test isn't interesting because we will either
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* already have a file descriptor (we opened the database file for
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* reading) or we aren't readonly (we created the database which
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* requires write privileges). The MP_TEMP test isn't interesting
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* because we want to write to the backing file regardless so that
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* we get a file descriptor to return.
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*/
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ret = dbmfp->fd == -1 ? __memp_fsync(dbmfp) : 0;
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return ((*fdp = dbmfp->fd) == -1 ? ENOENT : ret);
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}
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/*
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* __memp_fsync --
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* Mpool file internal sync function.
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*/
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static int
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__memp_fsync(dbmfp)
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DB_MPOOLFILE *dbmfp;
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{
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BH *bhp, **bharray;
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DB_MPOOL *dbmp;
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size_t mf_offset;
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int ar_cnt, cnt, nalloc, next, pincnt, ret, wrote;
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ret = 0;
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dbmp = dbmfp->dbmp;
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mf_offset = R_OFFSET(dbmp, dbmfp->mfp);
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/*
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* We try and write the buffers in page order so that the underlying
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* filesystem doesn't have to seek and can write contiguous blocks,
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* plus, we don't want to hold the region lock while we write the
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* buffers. Get memory to hold the buffer pointers. Get a good-size
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* block, too, because we realloc while holding the region lock if we
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* run out.
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*/
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nalloc = 1024;
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if ((bharray =
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(BH **)__db_malloc((size_t)nalloc * sizeof(BH *))) == NULL)
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return (ENOMEM);
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LOCKREGION(dbmp);
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/*
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* Walk the LRU list of buffer headers, and get a list of buffers to
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* write for this MPOOLFILE.
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*/
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ar_cnt = pincnt = 0;
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for (bhp = SH_TAILQ_FIRST(&dbmp->mp->bhq, __bh);
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bhp != NULL; bhp = SH_TAILQ_NEXT(bhp, q, __bh)) {
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if (!F_ISSET(bhp, BH_DIRTY) || bhp->mf_offset != mf_offset)
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continue;
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if (bhp->ref != 0 || F_ISSET(bhp, BH_LOCKED)) {
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++pincnt;
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continue;
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}
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if (ar_cnt == nalloc) {
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nalloc *= 2;
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if ((bharray = (BH **)__db_realloc(bharray,
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nalloc * sizeof(BH *))) == NULL) {
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ret = ENOMEM;
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goto err;
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}
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}
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bharray[ar_cnt++] = bhp;
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}
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/* Lock down the buffers and their contents. */
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for (cnt = 0; cnt < ar_cnt; ++cnt)
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++bharray[cnt]->ref;
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UNLOCKREGION(dbmp);
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/* Sort the buffers we're going to write. */
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qsort(bharray, ar_cnt, sizeof(BH *), __bhcmp);
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LOCKREGION(dbmp);
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/* Walk the array, writing buffers. */
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for (next = 0; next < ar_cnt; ++next) {
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/*
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* It's possible for a thread to have gotten the buffer since
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* we listed it for writing. If the reference count is still
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* 1, we're the only ones using the buffer, go ahead and write.
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* If it's >1, then skip the buffer and assume that it will be
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* written when it's returned to the cache.
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*/
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if (bharray[next]->ref > 1) {
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++pincnt;
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--bharray[next]->ref;
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continue;
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}
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/* Write the buffer. */
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ret = __memp_pgwrite(dbmfp, bharray[next], NULL, &wrote);
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/* Release the buffer. */
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--bharray[next]->ref;
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/* If there's an error, release the rest of the buffers. */
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if (ret != 0) {
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while (++next < ar_cnt)
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--bharray[next]->ref;
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goto err;
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}
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if (!wrote)
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++pincnt;
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}
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err: UNLOCKREGION(dbmp);
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__db_free(bharray);
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/*
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* Sync the underlying file as the last thing we do, so that the OS
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* has maximal opportunity to flush buffers before we request it.
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*
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* XXX:
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* Don't lock the region around the sync, fsync(2) has no atomicity
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* issues.
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*/
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if (ret == 0)
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return (pincnt == 0 ? __db_fsync(dbmfp->fd) : DB_INCOMPLETE);
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return (ret);
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}
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/*
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* memp_trickle --
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* Keep a specified percentage of the buffers clean.
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*/
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int
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memp_trickle(dbmp, pct, nwrotep)
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DB_MPOOL *dbmp;
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int pct, *nwrotep;
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{
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BH *bhp;
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MPOOL *mp;
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MPOOLFILE *mfp;
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u_long total;
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int ret, wrote;
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mp = dbmp->mp;
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if (nwrotep != NULL)
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*nwrotep = 0;
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if (pct < 1 || pct > 100)
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return (EINVAL);
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LOCKREGION(dbmp);
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/*
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* If there are sufficient clean buffers, or no buffers or no dirty
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* buffers, we're done.
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*
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* XXX
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* Using st_page_clean and st_page_dirty is our only choice at the
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* moment, but it's not as correct as we might like in the presence
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* of pools with more than one buffer size, as a free 512-byte buffer
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* isn't the same as a free 8K buffer.
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*/
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loop: total = mp->stat.st_page_clean + mp->stat.st_page_dirty;
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if (total == 0 || mp->stat.st_page_dirty == 0 ||
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(mp->stat.st_page_clean * 100) / total >= (u_long)pct) {
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UNLOCKREGION(dbmp);
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return (0);
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}
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/* Loop until we write a buffer. */
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for (bhp = SH_TAILQ_FIRST(&mp->bhq, __bh);
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bhp != NULL; bhp = SH_TAILQ_NEXT(bhp, q, __bh)) {
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if (bhp->ref != 0 ||
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!F_ISSET(bhp, BH_DIRTY) || F_ISSET(bhp, BH_LOCKED))
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continue;
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mfp = R_ADDR(dbmp, bhp->mf_offset);
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/*
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* We can't write to temporary files -- see the comment in
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* mp_bh.c:__memp_bhwrite().
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*/
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if (F_ISSET(mfp, MP_TEMP))
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continue;
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if ((ret = __memp_bhwrite(dbmp, mfp, bhp, NULL, &wrote)) != 0)
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goto err;
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/*
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* Any process syncing the shared memory buffer pool had better
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* be able to write to any underlying file. Be understanding,
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* but firm, on this point.
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*/
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if (!wrote) {
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__db_err(dbmp->dbenv, "%s: unable to flush page: %lu",
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__memp_fns(dbmp, mfp), (u_long)bhp->pgno);
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ret = EPERM;
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goto err;
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}
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++mp->stat.st_page_trickle;
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if (nwrotep != NULL)
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++*nwrotep;
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goto loop;
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}
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/* No more buffers to write. */
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return (0);
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err: UNLOCKREGION(dbmp);
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return (ret);
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}
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static int
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__bhcmp(p1, p2)
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const void *p1, *p2;
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{
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BH *bhp1, *bhp2;
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bhp1 = *(BH * const *)p1;
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bhp2 = *(BH * const *)p2;
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/* Sort by file (shared memory pool offset). */
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if (bhp1->mf_offset < bhp2->mf_offset)
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return (-1);
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if (bhp1->mf_offset > bhp2->mf_offset)
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return (1);
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/* Sort by page in file. */
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return (bhp1->pgno < bhp2->pgno ? -1 : 1);
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}
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