/* * Copyright 2000, International Business Machines Corporation and others. * All Rights Reserved. * * This software has been released under the terms of the IBM Public * License. For details, see the LICENSE file in the top-level source * directory or online at http://www.openafs.org/dl/license10.html */ #include #include "afs/param.h" #include "afs/sysincludes.h" #include "afsincludes.h" #if !defined(UKERNEL) #if !defined(AFS_LINUX26_ENV) # include "h/param.h" #endif #include "h/types.h" #include "h/time.h" #if defined(AFS_AIX31_ENV) #include "h/limits.h" #endif #if !defined(AFS_AIX_ENV) && !defined(AFS_SUN5_ENV) && !defined(AFS_SGI_ENV) && !defined(AFS_LINUX20_ENV) #include "h/kernel.h" /* Doesn't needed, so it should go */ #endif #endif /* !defined(UKERNEL) */ #include "afs/afs_osi.h" #include "afsint.h" #include "afs/lock.h" #if !defined(UKERNEL) && !defined(AFS_LINUX20_ENV) #include "h/buf.h" #endif /* !defined(UKERNEL) */ #include "afs/stds.h" #include "afs/volerrors.h" #include "afs/exporter.h" #include "afs/prs_fs.h" #include "afs/afs_chunkops.h" #include "afs/dir.h" #include "afs/afs_stats.h" #include "afs/afs.h" #ifndef BUF_TIME_MAX #define BUF_TIME_MAX 0x7fffffff #endif #define NPB 8 /* must be a pwer of 2 */ static int afs_max_buffers; /* should be an integral multiple of NPB */ /* page size */ #define AFS_BUFFER_PAGESIZE 2048 /* log page size */ #define LOGPS 11 /* If you change any of this PH stuff, make sure you don't break DZap() */ /* use last two bits for page */ #define PHPAGEMASK 3 /* use next five bits for fid */ #define PHFIDMASK 124 /* page hash table size - this is pretty intertwined with pHash */ #define PHSIZE (PHPAGEMASK + PHFIDMASK + 1) /* the pHash macro */ #define pHash(fid,page) ((((afs_int32)(fid)) & PHFIDMASK) \ | (page & PHPAGEMASK)) #ifdef dirty #undef dirty /* XXX */ #endif static struct buffer *Buffers = 0; static char *BufferData; #ifdef AFS_AIX_ENV extern struct buf *geteblk(); #endif #ifdef AFS_FBSD_ENV #define timecounter afs_timecounter #endif /* A note on locking in 'struct buffer' * * afs_bufferLock protects the hash chain, and the 'lockers' field where that * has a zero value. It must be held whenever lockers is incremented from zero. * * The individual buffer lock protects the contents of the structure, including * the lockers field. * * For safety: afs_bufferLock and the individual buffer lock must be held * when obtaining a reference on a structure. Only the individual buffer lock * need be held when releasing a reference. * * The locking hierarchy is afs_bufferLock-> buffer.lock * */ static afs_lock_t afs_bufferLock; static struct buffer *phTable[PHSIZE]; /* page hash table */ static int nbuffers; static afs_int32 timecounter; /* Prototypes for static routines */ static struct buffer *afs_newslot(struct dcache *adc, afs_int32 apage, struct buffer *lp); static int dinit_flag = 0; void DInit(int abuffers) { /* Initialize the venus buffer system. */ int i; struct buffer *tb; AFS_STATCNT(DInit); if (dinit_flag) return; dinit_flag = 1; /* round up to next multiple of NPB, since we allocate multiple pages per chunk */ abuffers = ((abuffers - 1) | (NPB - 1)) + 1; afs_max_buffers = abuffers << 2; /* possibly grow up to 4 times as big */ LOCK_INIT(&afs_bufferLock, "afs_bufferLock"); Buffers = afs_osi_Alloc(afs_max_buffers * sizeof(struct buffer)); osi_Assert(Buffers != NULL); timecounter = 1; afs_stats_cmperf.bufAlloced = nbuffers = abuffers; for (i = 0; i < PHSIZE; i++) phTable[i] = 0; for (i = 0; i < abuffers; i++) { if ((i & (NPB - 1)) == 0) { /* time to allocate a fresh buffer */ BufferData = afs_osi_Alloc(AFS_BUFFER_PAGESIZE * NPB); osi_Assert(BufferData != NULL); } /* Fill in each buffer with an empty indication. */ tb = &Buffers[i]; tb->fid = NULLIDX; afs_reset_inode(&tb->inode); tb->accesstime = 0; tb->lockers = 0; tb->data = &BufferData[AFS_BUFFER_PAGESIZE * (i & (NPB - 1))]; tb->hashIndex = 0; tb->dirty = 0; AFS_RWLOCK_INIT(&tb->lock, "buffer lock"); } return; } /*! * Read and return the requested directory page. * * \param[in] adc pointer to directory dcache * \param[in] page number of the desired directory page * \param[out] entry buffer to return requested page * \param[out] physerr (optional) pointer to return errno, if any * * \retval 0 success * \retval non-zero invalid directory or internal IO error; * if physerr is supplied by caller, it will be set: * 0 logical error * errno physical error */ int DReadWithErrno(struct dcache *adc, int page, struct DirBuffer *entry, int *physerr) { /* Read a page from the disk. */ struct buffer *tb, *tb2; struct osi_file *tfile; int code; AFS_STATCNT(DRead); if (physerr != NULL) *physerr = 0; memset(entry, 0, sizeof(struct DirBuffer)); if (adc->f.chunk == 0 && adc->f.chunkBytes == 0) { /* The directory blob is empty, apparently. This is not a valid dir * blob, so throw an error. */ return EIO; } if (page * AFS_BUFFER_PAGESIZE >= adc->f.chunkBytes) { return ENOENT; /* past the end */ } ObtainWriteLock(&afs_bufferLock, 256); #define bufmatch(tb) (tb->page == page && tb->fid == adc->index) #define buf_Front(head,parent,p) {(parent)->hashNext = (p)->hashNext; (p)->hashNext= *(head);*(head)=(p);} /* this apparently-complicated-looking code is simply an example of * a little bit of loop unrolling, and is a standard linked-list * traversal trick. It saves a few assignments at the the expense * of larger code size. This could be simplified by better use of * macros. */ if ((tb = phTable[pHash(adc->index, page)])) { if (bufmatch(tb)) { ObtainWriteLock(&tb->lock, 257); tb->lockers++; ReleaseWriteLock(&afs_bufferLock); tb->accesstime = timecounter++; AFS_STATS(afs_stats_cmperf.bufHits++); ReleaseWriteLock(&tb->lock); entry->buffer = tb; entry->data = tb->data; return 0; } else { struct buffer **bufhead; bufhead = &(phTable[pHash(adc->index, page)]); while ((tb2 = tb->hashNext)) { if (bufmatch(tb2)) { buf_Front(bufhead, tb, tb2); ObtainWriteLock(&tb2->lock, 258); tb2->lockers++; ReleaseWriteLock(&afs_bufferLock); tb2->accesstime = timecounter++; AFS_STATS(afs_stats_cmperf.bufHits++); ReleaseWriteLock(&tb2->lock); entry->buffer = tb2; entry->data = tb2->data; return 0; } if ((tb = tb2->hashNext)) { if (bufmatch(tb)) { buf_Front(bufhead, tb2, tb); ObtainWriteLock(&tb->lock, 259); tb->lockers++; ReleaseWriteLock(&afs_bufferLock); tb->accesstime = timecounter++; AFS_STATS(afs_stats_cmperf.bufHits++); ReleaseWriteLock(&tb->lock); entry->buffer = tb; entry->data = tb->data; return 0; } } else break; } } } else tb2 = NULL; AFS_STATS(afs_stats_cmperf.bufMisses++); /* can't find it */ /* The last thing we looked at was either tb or tb2 (or nothing). That * is at least the oldest buffer on one particular hash chain, so it's * a pretty good place to start looking for the truly oldest buffer. */ tb = afs_newslot(adc, page, (tb ? tb : tb2)); if (!tb) { ReleaseWriteLock(&afs_bufferLock); return EIO; } ObtainWriteLock(&tb->lock, 260); tb->lockers++; ReleaseWriteLock(&afs_bufferLock); tfile = afs_CFileOpen(&adc->f.inode); if (!tfile) { code = EIO; goto error; } code = afs_CFileRead(tfile, tb->page * AFS_BUFFER_PAGESIZE, tb->data, AFS_BUFFER_PAGESIZE); afs_CFileClose(tfile); if (code < AFS_BUFFER_PAGESIZE) { if (code < 0 && physerr != NULL) *physerr = -code; code = EIO; goto error; } /* Note that findslot sets the page field in the buffer equal to * what it is searching for. */ ReleaseWriteLock(&tb->lock); entry->buffer = tb; entry->data = tb->data; return 0; error: tb->fid = NULLIDX; afs_reset_inode(&tb->inode); tb->lockers--; ReleaseWriteLock(&tb->lock); return code; } /*! * Read and return the requested directory page. * * \param[in] adc pointer to directory dcache * \param[in] page number of the desired directory page * \param[out] entry buffer to return requested page * * \retval 0 success * \retval non-zero invalid directory or internal IO error; */ int DRead(struct dcache *adc, int page, struct DirBuffer *entry) { return DReadWithErrno(adc, page, entry, NULL); } static void FixupBucket(struct buffer *ap) { struct buffer **lp, *tp; int i; /* first try to get it out of its current hash bucket, in which it * might not be */ AFS_STATCNT(FixupBucket); i = ap->hashIndex; lp = &phTable[i]; for (tp = *lp; tp; tp = tp->hashNext) { if (tp == ap) { *lp = tp->hashNext; break; } lp = &tp->hashNext; } /* now figure the new hash bucket */ i = pHash(ap->fid, ap->page); ap->hashIndex = i; /* remember where we are for deletion */ ap->hashNext = phTable[i]; /* add us to the list */ phTable[i] = ap; /* at the front, since it's LRU */ } /* lp is pointer to a fairly-old buffer */ static struct buffer * afs_newslot(struct dcache *adc, afs_int32 apage, struct buffer *lp) { /* Find a usable buffer slot */ afs_int32 i; afs_int32 lt = 0; struct buffer *tp; struct osi_file *tfile; AFS_STATCNT(afs_newslot); /* we take a pointer here to a buffer which was at the end of an * LRU hash chain. Odds are, it's one of the older buffers, not * one of the newer. Having an older buffer to start with may * permit us to avoid a few of the assignments in the "typical * case" for loop below. */ if (lp && (lp->lockers == 0)) { lt = lp->accesstime; } else { lp = NULL; } /* timecounter might have wrapped, if machine is very very busy * and stays up for a long time. Timecounter mustn't wrap twice * (positive->negative->positive) before calling newslot, but that * would require 2 billion consecutive cache hits... Anyway, the * penalty is only that the cache replacement policy will be * almost MRU for the next ~2 billion DReads... newslot doesn't * get called nearly as often as DRead, so in order to avoid the * performance penalty of using the hypers, it's worth doing the * extra check here every time. It's probably cheaper than doing * hcmp, anyway. There is a little performance hit resulting from * resetting all the access times to 0, but it only happens once * every month or so, and the access times will rapidly sort * themselves back out after just a few more DReads. */ if (timecounter < 0) { timecounter = 1; tp = Buffers; for (i = 0; i < nbuffers; i++, tp++) { tp->accesstime = 0; if (!lp && !tp->lockers) /* one is as good as the rest, I guess */ lp = tp; } } else { /* this is the typical case */ tp = Buffers; for (i = 0; i < nbuffers; i++, tp++) { if (tp->lockers == 0) { if (!lp || tp->accesstime < lt) { lp = tp; lt = tp->accesstime; } } } } if (lp == 0) { /* No unlocked buffers. If still possible, allocate a new increment */ if (nbuffers + NPB > afs_max_buffers) { /* There are no unlocked buffers -- this used to panic, but that * seems extreme. To the best of my knowledge, all the callers * of DRead are prepared to handle a zero return. Some of them * just panic directly, but not all of them. */ afs_warn("afs: all buffers locked\n"); return 0; } BufferData = afs_osi_Alloc(AFS_BUFFER_PAGESIZE * NPB); osi_Assert(BufferData != NULL); for (i = 0; i< NPB; i++) { /* Fill in each buffer with an empty indication. */ tp = &Buffers[i + nbuffers]; tp->fid = NULLIDX; afs_reset_inode(&tp->inode); tp->accesstime = 0; tp->lockers = 0; tp->data = &BufferData[AFS_BUFFER_PAGESIZE * i]; tp->hashIndex = 0; tp->dirty = 0; AFS_RWLOCK_INIT(&tp->lock, "buffer lock"); } lp = &Buffers[nbuffers]; nbuffers += NPB; } if (lp->dirty) { /* see DFlush for rationale for not getting and locking the dcache */ tfile = afs_CFileOpen(&lp->inode); if (!tfile) return NULL; /* Callers will flag as EIO */ afs_CFileWrite(tfile, lp->page * AFS_BUFFER_PAGESIZE, lp->data, AFS_BUFFER_PAGESIZE); lp->dirty = 0; afs_CFileClose(tfile); AFS_STATS(afs_stats_cmperf.bufFlushDirty++); } /* Zero out the data so we don't leak something we shouldn't. */ memset(lp->data, 0, AFS_BUFFER_PAGESIZE); /* Now fill in the header. */ lp->fid = adc->index; afs_copy_inode(&lp->inode, &adc->f.inode); lp->page = apage; lp->accesstime = timecounter++; FixupBucket(lp); /* move to the right hash bucket */ return lp; } void DRelease(struct DirBuffer *entry, int flag) { struct buffer *tp; AFS_STATCNT(DRelease); tp = entry->buffer; if (tp == NULL) return; ObtainWriteLock(&tp->lock, 261); tp->lockers--; if (flag) tp->dirty = 1; ReleaseWriteLock(&tp->lock); } int DVOffset(struct DirBuffer *entry) { struct buffer *bp; AFS_STATCNT(DVOffset); bp = entry->buffer; return AFS_BUFFER_PAGESIZE * bp->page + (char *)entry->data - (char *)bp->data; } /*! * Zap one dcache entry: destroy one FID's buffers. * * 1/1/91 - I've modified the hash function to take the page as well * as the *fid, so that lookup will be a bit faster. That presents some * difficulties for Zap, which now has to have some knowledge of the nature * of the hash function. Oh well. This should use the list traversal * method of DRead... * * \param adc The dcache entry to be zapped. */ void DZap(struct dcache *adc) { int i; /* Destroy all buffers pertaining to a particular fid. */ struct buffer *tb; AFS_STATCNT(DZap); ObtainReadLock(&afs_bufferLock); for (i = 0; i <= PHPAGEMASK; i++) for (tb = phTable[pHash(adc->index, i)]; tb; tb = tb->hashNext) if (tb->fid == adc->index) { ObtainWriteLock(&tb->lock, 262); tb->fid = NULLIDX; afs_reset_inode(&tb->inode); tb->dirty = 0; ReleaseWriteLock(&tb->lock); } ReleaseReadLock(&afs_bufferLock); } static void DFlushBuffer(struct buffer *ab) { struct osi_file *tfile; tfile = afs_CFileOpen(&ab->inode); osi_Assert(tfile); afs_CFileWrite(tfile, ab->page * AFS_BUFFER_PAGESIZE, ab->data, AFS_BUFFER_PAGESIZE); ab->dirty = 0; /* Clear the dirty flag */ afs_CFileClose(tfile); } void DFlushDCache(struct dcache *adc) { int i; struct buffer *tb; ObtainReadLock(&afs_bufferLock); for (i = 0; i <= PHPAGEMASK; i++) for (tb = phTable[pHash(adc->index, i)]; tb; tb = tb->hashNext) if (tb->fid == adc->index) { ObtainWriteLock(&tb->lock, 701); tb->lockers++; ReleaseReadLock(&afs_bufferLock); if (tb->dirty) { DFlushBuffer(tb); } tb->lockers--; ReleaseWriteLock(&tb->lock); ObtainReadLock(&afs_bufferLock); } ReleaseReadLock(&afs_bufferLock); } int DFlush(void) { /* Flush all the modified buffers. */ int i; struct buffer *tb; AFS_STATCNT(DFlush); tb = Buffers; ObtainReadLock(&afs_bufferLock); for (i = 0; i < nbuffers; i++, tb++) { if (tb->dirty) { ObtainWriteLock(&tb->lock, 263); tb->lockers++; ReleaseReadLock(&afs_bufferLock); if (tb->dirty) { /* it seems safe to do this I/O without having the dcache * locked, since the only things that will update the data in * a directory are the buffer package, which holds the relevant * tb->lock while doing the write, or afs_GetDCache, which * DZap's the directory while holding the dcache lock. * It is not possible to lock the dcache or even call * afs_GetDSlot to map the index to the dcache since the dir * package's caller has some dcache object locked already (so * we cannot lock afs_xdcache). In addition, we cannot obtain * a dcache lock while holding the tb->lock of the same file * since that can deadlock with DRead/DNew */ DFlushBuffer(tb); } tb->lockers--; ReleaseWriteLock(&tb->lock); ObtainReadLock(&afs_bufferLock); } } ReleaseReadLock(&afs_bufferLock); return 0; } /*! * Prepare a new directory page buffer * * \param adc pointer to the directory object dcache * \param nblobs page we want * \param entry buffer to return requested page * * \retval 0 success; entry is updated * \retval non-zero internal error or IO error writing to disk */ int DNew(struct dcache *adc, int page, struct DirBuffer *entry) { /* Same as read, only do *not* even try to read the page, since it * probably doesn't exist. */ struct buffer *tb; int code; AFS_STATCNT(DNew); ObtainWriteLock(&afs_bufferLock, 264); if ((tb = afs_newslot(adc, page, NULL)) == 0) { ReleaseWriteLock(&afs_bufferLock); return EIO; } /* extend the chunk, if needed */ /* Do it now, not in DFlush or afs_newslot when the data is written out, * since now our caller has adc->lock writelocked, and we can't acquire * that lock (or even map from a fid to a dcache) in afs_newslot or * DFlush due to lock hierarchy issues */ if ((page + 1) * AFS_BUFFER_PAGESIZE > adc->f.chunkBytes) { afs_AdjustSize(adc, (page + 1) * AFS_BUFFER_PAGESIZE); code = afs_WriteDCache(adc, 1); if (code) { ReleaseWriteLock(&afs_bufferLock); return code; } } ObtainWriteLock(&tb->lock, 265); tb->lockers++; ReleaseWriteLock(&afs_bufferLock); ReleaseWriteLock(&tb->lock); entry->buffer = tb; entry->data = tb->data; return 0; } void shutdown_bufferpackage(void) { struct buffer *tp; int i; AFS_STATCNT(shutdown_bufferpackage); /* Free all allocated Buffers and associated buffer pages */ DFlush(); dinit_flag = 0; tp = Buffers; for (i = 0; i < nbuffers; i += NPB, tp += NPB) { afs_osi_Free(tp->data, NPB * AFS_BUFFER_PAGESIZE); } afs_osi_Free(Buffers, nbuffers * sizeof(struct buffer)); Buffers = NULL; nbuffers = 0; timecounter = 1; for (i = 0; i < PHSIZE; i++) phTable[i] = NULL; if (afs_cold_shutdown) { memset(&afs_bufferLock, 0, sizeof(afs_lock_t)); } }