Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Dave Kleikamp | 8212 | 97.03% | 51 | 57.95% |
Christoph Hellwig | 38 | 0.45% | 8 | 9.09% |
Ingo Molnar | 32 | 0.38% | 2 | 2.27% |
Kent Overstreet | 30 | 0.35% | 2 | 2.27% |
Jan Kara | 24 | 0.28% | 1 | 1.14% |
Andy Shevchenko | 23 | 0.27% | 1 | 1.14% |
Lizhi Xu | 21 | 0.25% | 1 | 1.14% |
Al Viro | 16 | 0.19% | 2 | 2.27% |
Alexey Dobriyan | 13 | 0.15% | 1 | 1.14% |
Thomas Gleixner | 10 | 0.12% | 2 | 2.27% |
Gu Zheng | 7 | 0.08% | 1 | 1.14% |
Jiapeng Chong | 5 | 0.06% | 1 | 1.14% |
Christoph Lameter | 4 | 0.05% | 1 | 1.14% |
Tejun Heo | 4 | 0.05% | 2 | 2.27% |
Linus Torvalds | 4 | 0.05% | 2 | 2.27% |
Joe Perches | 4 | 0.05% | 2 | 2.27% |
Paul Gortmaker | 3 | 0.04% | 1 | 1.14% |
Dave Jones | 3 | 0.04% | 1 | 1.14% |
Eric Sesterhenn / Snakebyte | 3 | 0.04% | 1 | 1.14% |
Johannes Thumshirn | 2 | 0.02% | 1 | 1.14% |
Linus Torvalds (pre-git) | 2 | 0.02% | 1 | 1.14% |
Nikanth Karthikesan | 1 | 0.01% | 1 | 1.14% |
Neil Brown | 1 | 0.01% | 1 | 1.14% |
Nigel Cunningham | 1 | 0.01% | 1 | 1.14% |
Total | 8463 | 88 |
// SPDX-License-Identifier: GPL-2.0-or-later /* * Copyright (C) International Business Machines Corp., 2000-2004 * Portions Copyright (C) Christoph Hellwig, 2001-2002 */ /* * jfs_logmgr.c: log manager * * for related information, see transaction manager (jfs_txnmgr.c), and * recovery manager (jfs_logredo.c). * * note: for detail, RTFS. * * log buffer manager: * special purpose buffer manager supporting log i/o requirements. * per log serial pageout of logpage * queuing i/o requests and redrive i/o at iodone * maintain current logpage buffer * no caching since append only * appropriate jfs buffer cache buffers as needed * * group commit: * transactions which wrote COMMIT records in the same in-memory * log page during the pageout of previous/current log page(s) are * committed together by the pageout of the page. * * TBD lazy commit: * transactions are committed asynchronously when the log page * containing it COMMIT is paged out when it becomes full; * * serialization: * . a per log lock serialize log write. * . a per log lock serialize group commit. * . a per log lock serialize log open/close; * * TBD log integrity: * careful-write (ping-pong) of last logpage to recover from crash * in overwrite. * detection of split (out-of-order) write of physical sectors * of last logpage via timestamp at end of each sector * with its mirror data array at trailer). * * alternatives: * lsn - 64-bit monotonically increasing integer vs * 32-bit lspn and page eor. */ #include <linux/fs.h> #include <linux/blkdev.h> #include <linux/interrupt.h> #include <linux/completion.h> #include <linux/kthread.h> #include <linux/buffer_head.h> /* for sync_blockdev() */ #include <linux/bio.h> #include <linux/freezer.h> #include <linux/export.h> #include <linux/delay.h> #include <linux/mutex.h> #include <linux/seq_file.h> #include <linux/slab.h> #include "jfs_incore.h" #include "jfs_filsys.h" #include "jfs_metapage.h" #include "jfs_superblock.h" #include "jfs_txnmgr.h" #include "jfs_debug.h" /* * lbuf's ready to be redriven. Protected by log_redrive_lock (jfsIO thread) */ static struct lbuf *log_redrive_list; static DEFINE_SPINLOCK(log_redrive_lock); /* * log read/write serialization (per log) */ #define LOG_LOCK_INIT(log) mutex_init(&(log)->loglock) #define LOG_LOCK(log) mutex_lock(&((log)->loglock)) #define LOG_UNLOCK(log) mutex_unlock(&((log)->loglock)) /* * log group commit serialization (per log) */ #define LOGGC_LOCK_INIT(log) spin_lock_init(&(log)->gclock) #define LOGGC_LOCK(log) spin_lock_irq(&(log)->gclock) #define LOGGC_UNLOCK(log) spin_unlock_irq(&(log)->gclock) #define LOGGC_WAKEUP(tblk) wake_up_all(&(tblk)->gcwait) /* * log sync serialization (per log) */ #define LOGSYNC_DELTA(logsize) min((logsize)/8, 128*LOGPSIZE) #define LOGSYNC_BARRIER(logsize) ((logsize)/4) /* #define LOGSYNC_DELTA(logsize) min((logsize)/4, 256*LOGPSIZE) #define LOGSYNC_BARRIER(logsize) ((logsize)/2) */ /* * log buffer cache synchronization */ static DEFINE_SPINLOCK(jfsLCacheLock); #define LCACHE_LOCK(flags) spin_lock_irqsave(&jfsLCacheLock, flags) #define LCACHE_UNLOCK(flags) spin_unlock_irqrestore(&jfsLCacheLock, flags) /* * See __SLEEP_COND in jfs_locks.h */ #define LCACHE_SLEEP_COND(wq, cond, flags) \ do { \ if (cond) \ break; \ __SLEEP_COND(wq, cond, LCACHE_LOCK(flags), LCACHE_UNLOCK(flags)); \ } while (0) #define LCACHE_WAKEUP(event) wake_up(event) /* * lbuf buffer cache (lCache) control */ /* log buffer manager pageout control (cumulative, inclusive) */ #define lbmREAD 0x0001 #define lbmWRITE 0x0002 /* enqueue at tail of write queue; * init pageout if at head of queue; */ #define lbmRELEASE 0x0004 /* remove from write queue * at completion of pageout; * do not free/recycle it yet: * caller will free it; */ #define lbmSYNC 0x0008 /* do not return to freelist * when removed from write queue; */ #define lbmFREE 0x0010 /* return to freelist * at completion of pageout; * the buffer may be recycled; */ #define lbmDONE 0x0020 #define lbmERROR 0x0040 #define lbmGC 0x0080 /* lbmIODone to perform post-GC processing * of log page */ #define lbmDIRECT 0x0100 /* * Global list of active external journals */ static LIST_HEAD(jfs_external_logs); static struct jfs_log *dummy_log; static DEFINE_MUTEX(jfs_log_mutex); /* * forward references */ static int lmWriteRecord(struct jfs_log * log, struct tblock * tblk, struct lrd * lrd, struct tlock * tlck); static int lmNextPage(struct jfs_log * log); static int lmLogFileSystem(struct jfs_log * log, struct jfs_sb_info *sbi, int activate); static int open_inline_log(struct super_block *sb); static int open_dummy_log(struct super_block *sb); static int lbmLogInit(struct jfs_log * log); static void lbmLogShutdown(struct jfs_log * log); static struct lbuf *lbmAllocate(struct jfs_log * log, int); static void lbmFree(struct lbuf * bp); static void lbmfree(struct lbuf * bp); static int lbmRead(struct jfs_log * log, int pn, struct lbuf ** bpp); static void lbmWrite(struct jfs_log * log, struct lbuf * bp, int flag, int cant_block); static void lbmDirectWrite(struct jfs_log * log, struct lbuf * bp, int flag); static int lbmIOWait(struct lbuf * bp, int flag); static bio_end_io_t lbmIODone; static void lbmStartIO(struct lbuf * bp); static void lmGCwrite(struct jfs_log * log, int cant_block); static int lmLogSync(struct jfs_log * log, int hard_sync); /* * statistics */ #ifdef CONFIG_JFS_STATISTICS static struct lmStat { uint commit; /* # of commit */ uint pagedone; /* # of page written */ uint submitted; /* # of pages submitted */ uint full_page; /* # of full pages submitted */ uint partial_page; /* # of partial pages submitted */ } lmStat; #endif static void write_special_inodes(struct jfs_log *log, int (*writer)(struct address_space *)) { struct jfs_sb_info *sbi; list_for_each_entry(sbi, &log->sb_list, log_list) { writer(sbi->ipbmap->i_mapping); writer(sbi->ipimap->i_mapping); writer(sbi->direct_inode->i_mapping); } } /* * NAME: lmLog() * * FUNCTION: write a log record; * * PARAMETER: * * RETURN: lsn - offset to the next log record to write (end-of-log); * -1 - error; * * note: todo: log error handler */ int lmLog(struct jfs_log * log, struct tblock * tblk, struct lrd * lrd, struct tlock * tlck) { int lsn; int diffp, difft; struct metapage *mp = NULL; unsigned long flags; jfs_info("lmLog: log:0x%p tblk:0x%p, lrd:0x%p tlck:0x%p", log, tblk, lrd, tlck); LOG_LOCK(log); /* log by (out-of-transaction) JFS ? */ if (tblk == NULL) goto writeRecord; /* log from page ? */ if (tlck == NULL || tlck->type & tlckBTROOT || (mp = tlck->mp) == NULL) goto writeRecord; /* * initialize/update page/transaction recovery lsn */ lsn = log->lsn; LOGSYNC_LOCK(log, flags); /* * initialize page lsn if first log write of the page */ if (mp->lsn == 0) { mp->log = log; mp->lsn = lsn; log->count++; /* insert page at tail of logsynclist */ list_add_tail(&mp->synclist, &log->synclist); } /* * initialize/update lsn of tblock of the page * * transaction inherits oldest lsn of pages associated * with allocation/deallocation of resources (their * log records are used to reconstruct allocation map * at recovery time: inode for inode allocation map, * B+-tree index of extent descriptors for block * allocation map); * allocation map pages inherit transaction lsn at * commit time to allow forwarding log syncpt past log * records associated with allocation/deallocation of * resources only after persistent map of these map pages * have been updated and propagated to home. */ /* * initialize transaction lsn: */ if (tblk->lsn == 0) { /* inherit lsn of its first page logged */ tblk->lsn = mp->lsn; log->count++; /* insert tblock after the page on logsynclist */ list_add(&tblk->synclist, &mp->synclist); } /* * update transaction lsn: */ else { /* inherit oldest/smallest lsn of page */ logdiff(diffp, mp->lsn, log); logdiff(difft, tblk->lsn, log); if (diffp < difft) { /* update tblock lsn with page lsn */ tblk->lsn = mp->lsn; /* move tblock after page on logsynclist */ list_move(&tblk->synclist, &mp->synclist); } } LOGSYNC_UNLOCK(log, flags); /* * write the log record */ writeRecord: lsn = lmWriteRecord(log, tblk, lrd, tlck); /* * forward log syncpt if log reached next syncpt trigger */ logdiff(diffp, lsn, log); if (diffp >= log->nextsync) lsn = lmLogSync(log, 0); /* update end-of-log lsn */ log->lsn = lsn; LOG_UNLOCK(log); /* return end-of-log address */ return lsn; } /* * NAME: lmWriteRecord() * * FUNCTION: move the log record to current log page * * PARAMETER: cd - commit descriptor * * RETURN: end-of-log address * * serialization: LOG_LOCK() held on entry/exit */ static int lmWriteRecord(struct jfs_log * log, struct tblock * tblk, struct lrd * lrd, struct tlock * tlck) { int lsn = 0; /* end-of-log address */ struct lbuf *bp; /* dst log page buffer */ struct logpage *lp; /* dst log page */ caddr_t dst; /* destination address in log page */ int dstoffset; /* end-of-log offset in log page */ int freespace; /* free space in log page */ caddr_t p; /* src meta-data page */ caddr_t src; int srclen; int nbytes; /* number of bytes to move */ int i; int len; struct linelock *linelock; struct lv *lv; struct lvd *lvd; int l2linesize; len = 0; /* retrieve destination log page to write */ bp = (struct lbuf *) log->bp; lp = (struct logpage *) bp->l_ldata; dstoffset = log->eor; /* any log data to write ? */ if (tlck == NULL) goto moveLrd; /* * move log record data */ /* retrieve source meta-data page to log */ if (tlck->flag & tlckPAGELOCK) { p = (caddr_t) (tlck->mp->data); linelock = (struct linelock *) & tlck->lock; } /* retrieve source in-memory inode to log */ else if (tlck->flag & tlckINODELOCK) { if (tlck->type & tlckDTREE) p = (caddr_t) &JFS_IP(tlck->ip)->i_dtroot; else p = (caddr_t) &JFS_IP(tlck->ip)->i_xtroot; linelock = (struct linelock *) & tlck->lock; } else { jfs_err("lmWriteRecord: UFO tlck:0x%p", tlck); return 0; /* Probably should trap */ } l2linesize = linelock->l2linesize; moveData: ASSERT(linelock->index <= linelock->maxcnt); lv = linelock->lv; for (i = 0; i < linelock->index; i++, lv++) { if (lv->length == 0) continue; /* is page full ? */ if (dstoffset >= LOGPSIZE - LOGPTLRSIZE) { /* page become full: move on to next page */ lmNextPage(log); bp = log->bp; lp = (struct logpage *) bp->l_ldata; dstoffset = LOGPHDRSIZE; } /* * move log vector data */ src = (u8 *) p + (lv->offset << l2linesize); srclen = lv->length << l2linesize; len += srclen; while (srclen > 0) { freespace = (LOGPSIZE - LOGPTLRSIZE) - dstoffset; nbytes = min(freespace, srclen); dst = (caddr_t) lp + dstoffset; memcpy(dst, src, nbytes); dstoffset += nbytes; /* is page not full ? */ if (dstoffset < LOGPSIZE - LOGPTLRSIZE) break; /* page become full: move on to next page */ lmNextPage(log); bp = (struct lbuf *) log->bp; lp = (struct logpage *) bp->l_ldata; dstoffset = LOGPHDRSIZE; srclen -= nbytes; src += nbytes; } /* * move log vector descriptor */ len += 4; lvd = (struct lvd *) ((caddr_t) lp + dstoffset); lvd->offset = cpu_to_le16(lv->offset); lvd->length = cpu_to_le16(lv->length); dstoffset += 4; jfs_info("lmWriteRecord: lv offset:%d length:%d", lv->offset, lv->length); } if ((i = linelock->next)) { linelock = (struct linelock *) lid_to_tlock(i); goto moveData; } /* * move log record descriptor */ moveLrd: lrd->length = cpu_to_le16(len); src = (caddr_t) lrd; srclen = LOGRDSIZE; while (srclen > 0) { freespace = (LOGPSIZE - LOGPTLRSIZE) - dstoffset; nbytes = min(freespace, srclen); dst = (caddr_t) lp + dstoffset; memcpy(dst, src, nbytes); dstoffset += nbytes; srclen -= nbytes; /* are there more to move than freespace of page ? */ if (srclen) goto pageFull; /* * end of log record descriptor */ /* update last log record eor */ log->eor = dstoffset; bp->l_eor = dstoffset; lsn = (log->page << L2LOGPSIZE) + dstoffset; if (lrd->type & cpu_to_le16(LOG_COMMIT)) { tblk->clsn = lsn; jfs_info("wr: tclsn:0x%x, beor:0x%x", tblk->clsn, bp->l_eor); INCREMENT(lmStat.commit); /* # of commit */ /* * enqueue tblock for group commit: * * enqueue tblock of non-trivial/synchronous COMMIT * at tail of group commit queue * (trivial/asynchronous COMMITs are ignored by * group commit.) */ LOGGC_LOCK(log); /* init tblock gc state */ tblk->flag = tblkGC_QUEUE; tblk->bp = log->bp; tblk->pn = log->page; tblk->eor = log->eor; /* enqueue transaction to commit queue */ list_add_tail(&tblk->cqueue, &log->cqueue); LOGGC_UNLOCK(log); } jfs_info("lmWriteRecord: lrd:0x%04x bp:0x%p pn:%d eor:0x%x", le16_to_cpu(lrd->type), log->bp, log->page, dstoffset); /* page not full ? */ if (dstoffset < LOGPSIZE - LOGPTLRSIZE) return lsn; pageFull: /* page become full: move on to next page */ lmNextPage(log); bp = (struct lbuf *) log->bp; lp = (struct logpage *) bp->l_ldata; dstoffset = LOGPHDRSIZE; src += nbytes; } return lsn; } /* * NAME: lmNextPage() * * FUNCTION: write current page and allocate next page. * * PARAMETER: log * * RETURN: 0 * * serialization: LOG_LOCK() held on entry/exit */ static int lmNextPage(struct jfs_log * log) { struct logpage *lp; int lspn; /* log sequence page number */ int pn; /* current page number */ struct lbuf *bp; struct lbuf *nextbp; struct tblock *tblk; /* get current log page number and log sequence page number */ pn = log->page; bp = log->bp; lp = (struct logpage *) bp->l_ldata; lspn = le32_to_cpu(lp->h.page); LOGGC_LOCK(log); /* * write or queue the full page at the tail of write queue */ /* get the tail tblk on commit queue */ if (list_empty(&log->cqueue)) tblk = NULL; else tblk = list_entry(log->cqueue.prev, struct tblock, cqueue); /* every tblk who has COMMIT record on the current page, * and has not been committed, must be on commit queue * since tblk is queued at commit queueu at the time * of writing its COMMIT record on the page before * page becomes full (even though the tblk thread * who wrote COMMIT record may have been suspended * currently); */ /* is page bound with outstanding tail tblk ? */ if (tblk && tblk->pn == pn) { /* mark tblk for end-of-page */ tblk->flag |= tblkGC_EOP; if (log->cflag & logGC_PAGEOUT) { /* if page is not already on write queue, * just enqueue (no lbmWRITE to prevent redrive) * buffer to wqueue to ensure correct serial order * of the pages since log pages will be added * continuously */ if (bp->l_wqnext == NULL) lbmWrite(log, bp, 0, 0); } else { /* * No current GC leader, initiate group commit */ log->cflag |= logGC_PAGEOUT; lmGCwrite(log, 0); } } /* page is not bound with outstanding tblk: * init write or mark it to be redriven (lbmWRITE) */ else { /* finalize the page */ bp->l_ceor = bp->l_eor; lp->h.eor = lp->t.eor = cpu_to_le16(bp->l_ceor); lbmWrite(log, bp, lbmWRITE | lbmRELEASE | lbmFREE, 0); } LOGGC_UNLOCK(log); /* * allocate/initialize next page */ /* if log wraps, the first data page of log is 2 * (0 never used, 1 is superblock). */ log->page = (pn == log->size - 1) ? 2 : pn + 1; log->eor = LOGPHDRSIZE; /* ? valid page empty/full at logRedo() */ /* allocate/initialize next log page buffer */ nextbp = lbmAllocate(log, log->page); nextbp->l_eor = log->eor; log->bp = nextbp; /* initialize next log page */ lp = (struct logpage *) nextbp->l_ldata; lp->h.page = lp->t.page = cpu_to_le32(lspn + 1); lp->h.eor = lp->t.eor = cpu_to_le16(LOGPHDRSIZE); return 0; } /* * NAME: lmGroupCommit() * * FUNCTION: group commit * initiate pageout of the pages with COMMIT in the order of * page number - redrive pageout of the page at the head of * pageout queue until full page has been written. * * RETURN: * * NOTE: * LOGGC_LOCK serializes log group commit queue, and * transaction blocks on the commit queue. * N.B. LOG_LOCK is NOT held during lmGroupCommit(). */ int lmGroupCommit(struct jfs_log * log, struct tblock * tblk) { int rc = 0; LOGGC_LOCK(log); /* group committed already ? */ if (tblk->flag & tblkGC_COMMITTED) { if (tblk->flag & tblkGC_ERROR) rc = -EIO; LOGGC_UNLOCK(log); return rc; } jfs_info("lmGroup Commit: tblk = 0x%p, gcrtc = %d", tblk, log->gcrtc); if (tblk->xflag & COMMIT_LAZY) tblk->flag |= tblkGC_LAZY; if ((!(log->cflag & logGC_PAGEOUT)) && (!list_empty(&log->cqueue)) && (!(tblk->xflag & COMMIT_LAZY) || test_bit(log_FLUSH, &log->flag) || jfs_tlocks_low)) { /* * No pageout in progress * * start group commit as its group leader. */ log->cflag |= logGC_PAGEOUT; lmGCwrite(log, 0); } if (tblk->xflag & COMMIT_LAZY) { /* * Lazy transactions can leave now */ LOGGC_UNLOCK(log); return 0; } /* lmGCwrite gives up LOGGC_LOCK, check again */ if (tblk->flag & tblkGC_COMMITTED) { if (tblk->flag & tblkGC_ERROR) rc = -EIO; LOGGC_UNLOCK(log); return rc; } /* upcount transaction waiting for completion */ log->gcrtc++; tblk->flag |= tblkGC_READY; __SLEEP_COND(tblk->gcwait, (tblk->flag & tblkGC_COMMITTED), LOGGC_LOCK(log), LOGGC_UNLOCK(log)); /* removed from commit queue */ if (tblk->flag & tblkGC_ERROR) rc = -EIO; LOGGC_UNLOCK(log); return rc; } /* * NAME: lmGCwrite() * * FUNCTION: group commit write * initiate write of log page, building a group of all transactions * with commit records on that page. * * RETURN: None * * NOTE: * LOGGC_LOCK must be held by caller. * N.B. LOG_LOCK is NOT held during lmGroupCommit(). */ static void lmGCwrite(struct jfs_log * log, int cant_write) { struct lbuf *bp; struct logpage *lp; int gcpn; /* group commit page number */ struct tblock *tblk; struct tblock *xtblk = NULL; /* * build the commit group of a log page * * scan commit queue and make a commit group of all * transactions with COMMIT records on the same log page. */ /* get the head tblk on the commit queue */ gcpn = list_entry(log->cqueue.next, struct tblock, cqueue)->pn; list_for_each_entry(tblk, &log->cqueue, cqueue) { if (tblk->pn != gcpn) break; xtblk = tblk; /* state transition: (QUEUE, READY) -> COMMIT */ tblk->flag |= tblkGC_COMMIT; } tblk = xtblk; /* last tblk of the page */ /* * pageout to commit transactions on the log page. */ bp = (struct lbuf *) tblk->bp; lp = (struct logpage *) bp->l_ldata; /* is page already full ? */ if (tblk->flag & tblkGC_EOP) { /* mark page to free at end of group commit of the page */ tblk->flag &= ~tblkGC_EOP; tblk->flag |= tblkGC_FREE; bp->l_ceor = bp->l_eor; lp->h.eor = lp->t.eor = cpu_to_le16(bp->l_ceor); lbmWrite(log, bp, lbmWRITE | lbmRELEASE | lbmGC, cant_write); INCREMENT(lmStat.full_page); } /* page is not yet full */ else { bp->l_ceor = tblk->eor; /* ? bp->l_ceor = bp->l_eor; */ lp->h.eor = lp->t.eor = cpu_to_le16(bp->l_ceor); lbmWrite(log, bp, lbmWRITE | lbmGC, cant_write); INCREMENT(lmStat.partial_page); } } /* * NAME: lmPostGC() * * FUNCTION: group commit post-processing * Processes transactions after their commit records have been written * to disk, redriving log I/O if necessary. * * RETURN: None * * NOTE: * This routine is called a interrupt time by lbmIODone */ static void lmPostGC(struct lbuf * bp) { unsigned long flags; struct jfs_log *log = bp->l_log; struct logpage *lp; struct tblock *tblk, *temp; //LOGGC_LOCK(log); spin_lock_irqsave(&log->gclock, flags); /* * current pageout of group commit completed. * * remove/wakeup transactions from commit queue who were * group committed with the current log page */ list_for_each_entry_safe(tblk, temp, &log->cqueue, cqueue) { if (!(tblk->flag & tblkGC_COMMIT)) break; /* if transaction was marked GC_COMMIT then * it has been shipped in the current pageout * and made it to disk - it is committed. */ if (bp->l_flag & lbmERROR) tblk->flag |= tblkGC_ERROR; /* remove it from the commit queue */ list_del(&tblk->cqueue); tblk->flag &= ~tblkGC_QUEUE; if (tblk == log->flush_tblk) { /* we can stop flushing the log now */ clear_bit(log_FLUSH, &log->flag); log->flush_tblk = NULL; } jfs_info("lmPostGC: tblk = 0x%p, flag = 0x%x", tblk, tblk->flag); if (!(tblk->xflag & COMMIT_FORCE)) /* * Hand tblk over to lazy commit thread */ txLazyUnlock(tblk); else { /* state transition: COMMIT -> COMMITTED */ tblk->flag |= tblkGC_COMMITTED; if (tblk->flag & tblkGC_READY) log->gcrtc--; LOGGC_WAKEUP(tblk); } /* was page full before pageout ? * (and this is the last tblk bound with the page) */ if (tblk->flag & tblkGC_FREE) lbmFree(bp); /* did page become full after pageout ? * (and this is the last tblk bound with the page) */ else if (tblk->flag & tblkGC_EOP) { /* finalize the page */ lp = (struct logpage *) bp->l_ldata; bp->l_ceor = bp->l_eor; lp->h.eor = lp->t.eor = cpu_to_le16(bp->l_eor); jfs_info("lmPostGC: calling lbmWrite"); lbmWrite(log, bp, lbmWRITE | lbmRELEASE | lbmFREE, 1); } } /* are there any transactions who have entered lnGroupCommit() * (whose COMMITs are after that of the last log page written. * They are waiting for new group commit (above at (SLEEP 1)) * or lazy transactions are on a full (queued) log page, * select the latest ready transaction as new group leader and * wake her up to lead her group. */ if ((!list_empty(&log->cqueue)) && ((log->gcrtc > 0) || (tblk->bp->l_wqnext != NULL) || test_bit(log_FLUSH, &log->flag) || jfs_tlocks_low)) /* * Call lmGCwrite with new group leader */ lmGCwrite(log, 1); /* no transaction are ready yet (transactions are only just * queued (GC_QUEUE) and not entered for group commit yet). * the first transaction entering group commit * will elect herself as new group leader. */ else log->cflag &= ~logGC_PAGEOUT; //LOGGC_UNLOCK(log); spin_unlock_irqrestore(&log->gclock, flags); return; } /* * NAME: lmLogSync() * * FUNCTION: write log SYNCPT record for specified log * if new sync address is available * (normally the case if sync() is executed by back-ground * process). * calculate new value of i_nextsync which determines when * this code is called again. * * PARAMETERS: log - log structure * hard_sync - 1 to force all metadata to be written * * RETURN: 0 * * serialization: LOG_LOCK() held on entry/exit */ static int lmLogSync(struct jfs_log * log, int hard_sync) { int logsize; int written; /* written since last syncpt */ int free; /* free space left available */ int delta; /* additional delta to write normally */ int more; /* additional write granted */ struct lrd lrd; int lsn; struct logsyncblk *lp; unsigned long flags; /* push dirty metapages out to disk */ if (hard_sync) write_special_inodes(log, filemap_fdatawrite); else write_special_inodes(log, filemap_flush); /* * forward syncpt */ /* if last sync is same as last syncpt, * invoke sync point forward processing to update sync. */ if (log->sync == log->syncpt) { LOGSYNC_LOCK(log, flags); if (list_empty(&log->synclist)) log->sync = log->lsn; else { lp = list_entry(log->synclist.next, struct logsyncblk, synclist); log->sync = lp->lsn; } LOGSYNC_UNLOCK(log, flags); } /* if sync is different from last syncpt, * write a SYNCPT record with syncpt = sync. * reset syncpt = sync */ if (log->sync != log->syncpt) { lrd.logtid = 0; lrd.backchain = 0; lrd.type = cpu_to_le16(LOG_SYNCPT); lrd.length = 0; lrd.log.syncpt.sync = cpu_to_le32(log->sync); lsn = lmWriteRecord(log, NULL, &lrd, NULL); log->syncpt = log->sync; } else lsn = log->lsn; /* * setup next syncpt trigger (SWAG) */ logsize = log->logsize; logdiff(written, lsn, log); free = logsize - written; delta = LOGSYNC_DELTA(logsize); more = min(free / 2, delta); if (more < 2 * LOGPSIZE) { jfs_warn("\n ... Log Wrap ... Log Wrap ... Log Wrap ...\n"); /* * log wrapping * * option 1 - panic ? No.! * option 2 - shutdown file systems * associated with log ? * option 3 - extend log ? * option 4 - second chance * * mark log wrapped, and continue. * when all active transactions are completed, * mark log valid for recovery. * if crashed during invalid state, log state * implies invalid log, forcing fsck(). */ /* mark log state log wrap in log superblock */ /* log->state = LOGWRAP; */ /* reset sync point computation */ log->syncpt = log->sync = lsn; log->nextsync = delta; } else /* next syncpt trigger = written + more */ log->nextsync = written + more; /* if number of bytes written from last sync point is more * than 1/4 of the log size, stop new transactions from * starting until all current transactions are completed * by setting syncbarrier flag. */ if (!test_bit(log_SYNCBARRIER, &log->flag) && (written > LOGSYNC_BARRIER(logsize)) && log->active) { set_bit(log_SYNCBARRIER, &log->flag); jfs_info("log barrier on: lsn=0x%x syncpt=0x%x", lsn, log->syncpt); /* * We may have to initiate group commit */ jfs_flush_journal(log, 0); } return lsn; } /* * NAME: jfs_syncpt * * FUNCTION: write log SYNCPT record for specified log * * PARAMETERS: log - log structure * hard_sync - set to 1 to force metadata to be written */ void jfs_syncpt(struct jfs_log *log, int hard_sync) { LOG_LOCK(log); if (!test_bit(log_QUIESCE, &log->flag)) lmLogSync(log, hard_sync); LOG_UNLOCK(log); } /* * NAME: lmLogOpen() * * FUNCTION: open the log on first open; * insert filesystem in the active list of the log. * * PARAMETER: ipmnt - file system mount inode * iplog - log inode (out) * * RETURN: * * serialization: */ int lmLogOpen(struct super_block *sb) { int rc; struct bdev_handle *bdev_handle; struct jfs_log *log; struct jfs_sb_info *sbi = JFS_SBI(sb); if (sbi->flag & JFS_NOINTEGRITY) return open_dummy_log(sb); if (sbi->mntflag & JFS_INLINELOG) return open_inline_log(sb); mutex_lock(&jfs_log_mutex); list_for_each_entry(log, &jfs_external_logs, journal_list) { if (log->bdev_handle->bdev->bd_dev == sbi->logdev) { if (!uuid_equal(&log->uuid, &sbi->loguuid)) { jfs_warn("wrong uuid on JFS journal"); mutex_unlock(&jfs_log_mutex); return -EINVAL; } /* * add file system to log active file system list */ if ((rc = lmLogFileSystem(log, sbi, 1))) { mutex_unlock(&jfs_log_mutex); return rc; } goto journal_found; } } if (!(log = kzalloc(sizeof(struct jfs_log), GFP_KERNEL))) { mutex_unlock(&jfs_log_mutex); return -ENOMEM; } INIT_LIST_HEAD(&log->sb_list); init_waitqueue_head(&log->syncwait); /* * external log as separate logical volume * * file systems to log may have n-to-1 relationship; */ bdev_handle = bdev_open_by_dev(sbi->logdev, BLK_OPEN_READ | BLK_OPEN_WRITE, log, NULL); if (IS_ERR(bdev_handle)) { rc = PTR_ERR(bdev_handle); goto free; } log->bdev_handle = bdev_handle; uuid_copy(&log->uuid, &sbi->loguuid); /* * initialize log: */ if ((rc = lmLogInit(log))) goto close; list_add(&log->journal_list, &jfs_external_logs); /* * add file system to log active file system list */ if ((rc = lmLogFileSystem(log, sbi, 1))) goto shutdown; journal_found: LOG_LOCK(log); list_add(&sbi->log_list, &log->sb_list); sbi->log = log; LOG_UNLOCK(log); mutex_unlock(&jfs_log_mutex); return 0; /* * unwind on error */ shutdown: /* unwind lbmLogInit() */ list_del(&log->journal_list); lbmLogShutdown(log); close: /* close external log device */ bdev_release(bdev_handle); free: /* free log descriptor */ mutex_unlock(&jfs_log_mutex); kfree(log); jfs_warn("lmLogOpen: exit(%d)", rc); return rc; } static int open_inline_log(struct super_block *sb) { struct jfs_log *log; int rc; if (!(log = kzalloc(sizeof(struct jfs_log), GFP_KERNEL))) return -ENOMEM; INIT_LIST_HEAD(&log->sb_list); init_waitqueue_head(&log->syncwait); set_bit(log_INLINELOG, &log->flag); log->bdev_handle = sb->s_bdev_handle; log->base = addressPXD(&JFS_SBI(sb)->logpxd); log->size = lengthPXD(&JFS_SBI(sb)->logpxd) >> (L2LOGPSIZE - sb->s_blocksize_bits); log->l2bsize = sb->s_blocksize_bits; ASSERT(L2LOGPSIZE >= sb->s_blocksize_bits); /* * initialize log. */ if ((rc = lmLogInit(log))) { kfree(log); jfs_warn("lmLogOpen: exit(%d)", rc); return rc; } list_add(&JFS_SBI(sb)->log_list, &log->sb_list); JFS_SBI(sb)->log = log; return rc; } static int open_dummy_log(struct super_block *sb) { int rc; mutex_lock(&jfs_log_mutex); if (!dummy_log) { dummy_log = kzalloc(sizeof(struct jfs_log), GFP_KERNEL); if (!dummy_log) { mutex_unlock(&jfs_log_mutex); return -ENOMEM; } INIT_LIST_HEAD(&dummy_log->sb_list); init_waitqueue_head(&dummy_log->syncwait); dummy_log->no_integrity = 1; /* Make up some stuff */ dummy_log->base = 0; dummy_log->size = 1024; rc = lmLogInit(dummy_log); if (rc) { kfree(dummy_log); dummy_log = NULL; mutex_unlock(&jfs_log_mutex); return rc; } } LOG_LOCK(dummy_log); list_add(&JFS_SBI(sb)->log_list, &dummy_log->sb_list); JFS_SBI(sb)->log = dummy_log; LOG_UNLOCK(dummy_log); mutex_unlock(&jfs_log_mutex); return 0; } /* * NAME: lmLogInit() * * FUNCTION: log initialization at first log open. * * logredo() (or logformat()) should have been run previously. * initialize the log from log superblock. * set the log state in the superblock to LOGMOUNT and * write SYNCPT log record. * * PARAMETER: log - log structure * * RETURN: 0 - if ok * -EINVAL - bad log magic number or superblock dirty * error returned from logwait() * * serialization: single first open thread */ int lmLogInit(struct jfs_log * log) { int rc = 0; struct lrd lrd; struct logsuper *logsuper; struct lbuf *bpsuper; struct lbuf *bp; struct logpage *lp; int lsn = 0; jfs_info("lmLogInit: log:0x%p", log); /* initialize the group commit serialization lock */ LOGGC_LOCK_INIT(log); /* allocate/initialize the log write serialization lock */ LOG_LOCK_INIT(log); LOGSYNC_LOCK_INIT(log); INIT_LIST_HEAD(&log->synclist); INIT_LIST_HEAD(&log->cqueue); log->flush_tblk = NULL; log->count = 0; /* * initialize log i/o */ if ((rc = lbmLogInit(log))) return rc; if (!test_bit(log_INLINELOG, &log->flag)) log->l2bsize = L2LOGPSIZE; /* check for disabled journaling to disk */ if (log->no_integrity) { /* * Journal pages will still be filled. When the time comes * to actually do the I/O, the write is not done, and the * endio routine is called directly. */ bp = lbmAllocate(log , 0); log->bp = bp; bp->l_pn = bp->l_eor = 0; } else { /* * validate log superblock */ if ((rc = lbmRead(log, 1, &bpsuper))) goto errout10; logsuper = (struct logsuper *) bpsuper->l_ldata; if (logsuper->magic != cpu_to_le32(LOGMAGIC)) { jfs_warn("*** Log Format Error ! ***"); rc = -EINVAL; goto errout20; } /* logredo() should have been run successfully. */ if (logsuper->state != cpu_to_le32(LOGREDONE)) { jfs_warn("*** Log Is Dirty ! ***"); rc = -EINVAL; goto errout20; } /* initialize log from log superblock */ if (test_bit(log_INLINELOG,&log->flag)) { if (log->size != le32_to_cpu(logsuper->size)) { rc = -EINVAL; goto errout20; } jfs_info("lmLogInit: inline log:0x%p base:0x%Lx size:0x%x", log, (unsigned long long)log->base, log->size); } else { if (!uuid_equal(&logsuper->uuid, &log->uuid)) { jfs_warn("wrong uuid on JFS log device"); rc = -EINVAL; goto errout20; } log->size = le32_to_cpu(logsuper->size); log->l2bsize = le32_to_cpu(logsuper->l2bsize); jfs_info("lmLogInit: external log:0x%p base:0x%Lx size:0x%x", log, (unsigned long long)log->base, log->size); } log->page = le32_to_cpu(logsuper->end) / LOGPSIZE; log->eor = le32_to_cpu(logsuper->end) - (LOGPSIZE * log->page); /* * initialize for log append write mode */ /* establish current/end-of-log page/buffer */ if ((rc = lbmRead(log, log->page, &bp))) goto errout20; lp = (struct logpage *) bp->l_ldata; jfs_info("lmLogInit: lsn:0x%x page:%d eor:%d:%d", le32_to_cpu(logsuper->end), log->page, log->eor, le16_to_cpu(lp->h.eor)); log->bp = bp; bp->l_pn = log->page; bp->l_eor = log->eor; /* if current page is full, move on to next page */ if (log->eor >= LOGPSIZE - LOGPTLRSIZE) lmNextPage(log); /* * initialize log syncpoint */ /* * write the first SYNCPT record with syncpoint = 0 * (i.e., log redo up to HERE !); * remove current page from lbm write queue at end of pageout * (to write log superblock update), but do not release to * freelist; */ lrd.logtid = 0; lrd.backchain = 0; lrd.type = cpu_to_le16(LOG_SYNCPT); lrd.length = 0; lrd.log.syncpt.sync = 0; lsn = lmWriteRecord(log, NULL, &lrd, NULL); bp = log->bp; bp->l_ceor = bp->l_eor; lp = (struct logpage *) bp->l_ldata; lp->h.eor = lp->t.eor = cpu_to_le16(bp->l_eor); lbmWrite(log, bp, lbmWRITE | lbmSYNC, 0); if ((rc = lbmIOWait(bp, 0))) goto errout30; /* * update/write superblock */ logsuper->state = cpu_to_le32(LOGMOUNT); log->serial = le32_to_cpu(logsuper->serial) + 1; logsuper->serial = cpu_to_le32(log->serial); lbmDirectWrite(log, bpsuper, lbmWRITE | lbmRELEASE | lbmSYNC); if ((rc = lbmIOWait(bpsuper, lbmFREE))) goto errout30; } /* initialize logsync parameters */ log->logsize = (log->size - 2) << L2LOGPSIZE; log->lsn = lsn; log->syncpt = lsn; log->sync = log->syncpt; log->nextsync = LOGSYNC_DELTA(log->logsize); jfs_info("lmLogInit: lsn:0x%x syncpt:0x%x sync:0x%x", log->lsn, log->syncpt, log->sync); /* * initialize for lazy/group commit */ log->clsn = lsn; return 0; /* * unwind on error */ errout30: /* release log page */ log->wqueue = NULL; bp->l_wqnext = NULL; lbmFree(bp); errout20: /* release log superblock */ lbmFree(bpsuper); errout10: /* unwind lbmLogInit() */ lbmLogShutdown(log); jfs_warn("lmLogInit: exit(%d)", rc); return rc; } /* * NAME: lmLogClose() * * FUNCTION: remove file system <ipmnt> from active list of log <iplog> * and close it on last close. * * PARAMETER: sb - superblock * * RETURN: errors from subroutines * * serialization: */ int lmLogClose(struct super_block *sb) { struct jfs_sb_info *sbi = JFS_SBI(sb); struct jfs_log *log = sbi->log; struct bdev_handle *bdev_handle; int rc = 0; jfs_info("lmLogClose: log:0x%p", log); mutex_lock(&jfs_log_mutex); LOG_LOCK(log); list_del(&sbi->log_list); LOG_UNLOCK(log); sbi->log = NULL; /* * We need to make sure all of the "written" metapages * actually make it to disk */ sync_blockdev(sb->s_bdev); if (test_bit(log_INLINELOG, &log->flag)) { /* * in-line log in host file system */ rc = lmLogShutdown(log); kfree(log); goto out; } if (!log->no_integrity) lmLogFileSystem(log, sbi, 0); if (!list_empty(&log->sb_list)) goto out; /* * TODO: ensure that the dummy_log is in a state to allow * lbmLogShutdown to deallocate all the buffers and call * kfree against dummy_log. For now, leave dummy_log & its * buffers in memory, and resuse if another no-integrity mount * is requested. */ if (log->no_integrity) goto out; /* * external log as separate logical volume */ list_del(&log->journal_list); bdev_handle = log->bdev_handle; rc = lmLogShutdown(log); bdev_release(bdev_handle); kfree(log); out: mutex_unlock(&jfs_log_mutex); jfs_info("lmLogClose: exit(%d)", rc); return rc; } /* * NAME: jfs_flush_journal() * * FUNCTION: initiate write of any outstanding transactions to the journal * and optionally wait until they are all written to disk * * wait == 0 flush until latest txn is committed, don't wait * wait == 1 flush until latest txn is committed, wait * wait > 1 flush until all txn's are complete, wait */ void jfs_flush_journal(struct jfs_log *log, int wait) { int i; struct tblock *target = NULL; /* jfs_write_inode may call us during read-only mount */ if (!log) return; jfs_info("jfs_flush_journal: log:0x%p wait=%d", log, wait); LOGGC_LOCK(log); if (!list_empty(&log->cqueue)) { /* * This ensures that we will keep writing to the journal as long * as there are unwritten commit records */ target = list_entry(log->cqueue.prev, struct tblock, cqueue); if (test_bit(log_FLUSH, &log->flag)) { /* * We're already flushing. * if flush_tblk is NULL, we are flushing everything, * so leave it that way. Otherwise, update it to the * latest transaction */ if (log->flush_tblk) log->flush_tblk = target; } else { /* Only flush until latest transaction is committed */ log->flush_tblk = target; set_bit(log_FLUSH, &log->flag); /* * Initiate I/O on outstanding transactions */ if (!(log->cflag & logGC_PAGEOUT)) { log->cflag |= logGC_PAGEOUT; lmGCwrite(log, 0); } } } if ((wait > 1) || test_bit(log_SYNCBARRIER, &log->flag)) { /* Flush until all activity complete */ set_bit(log_FLUSH, &log->flag); log->flush_tblk = NULL; } if (wait && target && !(target->flag & tblkGC_COMMITTED)) { DECLARE_WAITQUEUE(__wait, current); add_wait_queue(&target->gcwait, &__wait); set_current_state(TASK_UNINTERRUPTIBLE); LOGGC_UNLOCK(log); schedule(); LOGGC_LOCK(log); remove_wait_queue(&target->gcwait, &__wait); } LOGGC_UNLOCK(log); if (wait < 2) return; write_special_inodes(log, filemap_fdatawrite); /* * If there was recent activity, we may need to wait * for the lazycommit thread to catch up */ if ((!list_empty(&log->cqueue)) || !list_empty(&log->synclist)) { for (i = 0; i < 200; i++) { /* Too much? */ msleep(250); write_special_inodes(log, filemap_fdatawrite); if (list_empty(&log->cqueue) && list_empty(&log->synclist)) break; } } assert(list_empty(&log->cqueue)); #ifdef CONFIG_JFS_DEBUG if (!list_empty(&log->synclist)) { struct logsyncblk *lp; printk(KERN_ERR "jfs_flush_journal: synclist not empty\n"); list_for_each_entry(lp, &log->synclist, synclist) { if (lp->xflag & COMMIT_PAGE) { struct metapage *mp = (struct metapage *)lp; print_hex_dump(KERN_ERR, "metapage: ", DUMP_PREFIX_ADDRESS, 16, 4, mp, sizeof(struct metapage), 0); print_hex_dump(KERN_ERR, "page: ", DUMP_PREFIX_ADDRESS, 16, sizeof(long), mp->page, sizeof(struct page), 0); } else print_hex_dump(KERN_ERR, "tblock:", DUMP_PREFIX_ADDRESS, 16, 4, lp, sizeof(struct tblock), 0); } } #else WARN_ON(!list_empty(&log->synclist)); #endif clear_bit(log_FLUSH, &log->flag); } /* * NAME: lmLogShutdown() * * FUNCTION: log shutdown at last LogClose(). * * write log syncpt record. * update super block to set redone flag to 0. * * PARAMETER: log - log inode * * RETURN: 0 - success * * serialization: single last close thread */ int lmLogShutdown(struct jfs_log * log) { int rc; struct lrd lrd; int lsn; struct logsuper *logsuper; struct lbuf *bpsuper; struct lbuf *bp; struct logpage *lp; jfs_info("lmLogShutdown: log:0x%p", log); jfs_flush_journal(log, 2); /* * write the last SYNCPT record with syncpoint = 0 * (i.e., log redo up to HERE !) */ lrd.logtid = 0; lrd.backchain = 0; lrd.type = cpu_to_le16(LOG_SYNCPT); lrd.length = 0; lrd.log.syncpt.sync = 0; lsn = lmWriteRecord(log, NULL, &lrd, NULL); bp = log->bp; lp = (struct logpage *) bp->l_ldata; lp->h.eor = lp->t.eor = cpu_to_le16(bp->l_eor); lbmWrite(log, log->bp, lbmWRITE | lbmRELEASE | lbmSYNC, 0); lbmIOWait(log->bp, lbmFREE); log->bp = NULL; /* * synchronous update log superblock * mark log state as shutdown cleanly * (i.e., Log does not need to be replayed). */ if ((rc = lbmRead(log, 1, &bpsuper))) goto out; logsuper = (struct logsuper *) bpsuper->l_ldata; logsuper->state = cpu_to_le32(LOGREDONE); logsuper->end = cpu_to_le32(lsn); lbmDirectWrite(log, bpsuper, lbmWRITE | lbmRELEASE | lbmSYNC); rc = lbmIOWait(bpsuper, lbmFREE); jfs_info("lmLogShutdown: lsn:0x%x page:%d eor:%d", lsn, log->page, log->eor); out: /* * shutdown per log i/o */ lbmLogShutdown(log); if (rc) { jfs_warn("lmLogShutdown: exit(%d)", rc); } return rc; } /* * NAME: lmLogFileSystem() * * FUNCTION: insert (<activate> = true)/remove (<activate> = false) * file system into/from log active file system list. * * PARAMETE: log - pointer to logs inode. * fsdev - kdev_t of filesystem. * serial - pointer to returned log serial number * activate - insert/remove device from active list. * * RETURN: 0 - success * errors returned by vms_iowait(). */ static int lmLogFileSystem(struct jfs_log * log, struct jfs_sb_info *sbi, int activate) { int rc = 0; int i; struct logsuper *logsuper; struct lbuf *bpsuper; uuid_t *uuid = &sbi->uuid; /* * insert/remove file system device to log active file system list. */ if ((rc = lbmRead(log, 1, &bpsuper))) return rc; logsuper = (struct logsuper *) bpsuper->l_ldata; if (activate) { for (i = 0; i < MAX_ACTIVE; i++) if (uuid_is_null(&logsuper->active[i].uuid)) { uuid_copy(&logsuper->active[i].uuid, uuid); sbi->aggregate = i; break; } if (i == MAX_ACTIVE) { jfs_warn("Too many file systems sharing journal!"); lbmFree(bpsuper); return -EMFILE; /* Is there a better rc? */ } } else { for (i = 0; i < MAX_ACTIVE; i++) if (uuid_equal(&logsuper->active[i].uuid, uuid)) { uuid_copy(&logsuper->active[i].uuid, &uuid_null); break; } if (i == MAX_ACTIVE) { jfs_warn("Somebody stomped on the journal!"); lbmFree(bpsuper); return -EIO; } } /* * synchronous write log superblock: * * write sidestream bypassing write queue: * at file system mount, log super block is updated for * activation of the file system before any log record * (MOUNT record) of the file system, and at file system * unmount, all meta data for the file system has been * flushed before log super block is updated for deactivation * of the file system. */ lbmDirectWrite(log, bpsuper, lbmWRITE | lbmRELEASE | lbmSYNC); rc = lbmIOWait(bpsuper, lbmFREE); return rc; } /* * log buffer manager (lbm) * ------------------------ * * special purpose buffer manager supporting log i/o requirements. * * per log write queue: * log pageout occurs in serial order by fifo write queue and * restricting to a single i/o in pregress at any one time. * a circular singly-linked list * (log->wrqueue points to the tail, and buffers are linked via * bp->wrqueue field), and * maintains log page in pageout ot waiting for pageout in serial pageout. */ /* * lbmLogInit() * * initialize per log I/O setup at lmLogInit() */ static int lbmLogInit(struct jfs_log * log) { /* log inode */ int i; struct lbuf *lbuf; jfs_info("lbmLogInit: log:0x%p", log); /* initialize current buffer cursor */ log->bp = NULL; /* initialize log device write queue */ log->wqueue = NULL; /* * Each log has its own buffer pages allocated to it. These are * not managed by the page cache. This ensures that a transaction * writing to the log does not block trying to allocate a page from * the page cache (for the log). This would be bad, since page * allocation waits on the kswapd thread that may be committing inodes * which would cause log activity. Was that clear? I'm trying to * avoid deadlock here. */ init_waitqueue_head(&log->free_wait); log->lbuf_free = NULL; for (i = 0; i < LOGPAGES;) { char *buffer; uint offset; struct page *page = alloc_page(GFP_KERNEL | __GFP_ZERO); if (!page) goto error; buffer = page_address(page); for (offset = 0; offset < PAGE_SIZE; offset += LOGPSIZE) { lbuf = kmalloc(sizeof(struct lbuf), GFP_KERNEL); if (lbuf == NULL) { if (offset == 0) __free_page(page); goto error; } if (offset) /* we already have one reference */ get_page(page); lbuf->l_offset = offset; lbuf->l_ldata = buffer + offset; lbuf->l_page = page; lbuf->l_log = log; init_waitqueue_head(&lbuf->l_ioevent); lbuf->l_freelist = log->lbuf_free; log->lbuf_free = lbuf; i++; } } return (0); error: lbmLogShutdown(log); return -ENOMEM; } /* * lbmLogShutdown() * * finalize per log I/O setup at lmLogShutdown() */ static void lbmLogShutdown(struct jfs_log * log) { struct lbuf *lbuf; jfs_info("lbmLogShutdown: log:0x%p", log); lbuf = log->lbuf_free; while (lbuf) { struct lbuf *next = lbuf->l_freelist; __free_page(lbuf->l_page); kfree(lbuf); lbuf = next; } } /* * lbmAllocate() * * allocate an empty log buffer */ static struct lbuf *lbmAllocate(struct jfs_log * log, int pn) { struct lbuf *bp; unsigned long flags; /* * recycle from log buffer freelist if any */ LCACHE_LOCK(flags); LCACHE_SLEEP_COND(log->free_wait, (bp = log->lbuf_free), flags); log->lbuf_free = bp->l_freelist; LCACHE_UNLOCK(flags); bp->l_flag = 0; bp->l_wqnext = NULL; bp->l_freelist = NULL; bp->l_pn = pn; bp->l_blkno = log->base + (pn << (L2LOGPSIZE - log->l2bsize)); bp->l_ceor = 0; return bp; } /* * lbmFree() * * release a log buffer to freelist */ static void lbmFree(struct lbuf * bp) { unsigned long flags; LCACHE_LOCK(flags); lbmfree(bp); LCACHE_UNLOCK(flags); } static void lbmfree(struct lbuf * bp) { struct jfs_log *log = bp->l_log; assert(bp->l_wqnext == NULL); /* * return the buffer to head of freelist */ bp->l_freelist = log->lbuf_free; log->lbuf_free = bp; wake_up(&log->free_wait); return; } /* * NAME: lbmRedrive * * FUNCTION: add a log buffer to the log redrive list * * PARAMETER: * bp - log buffer * * NOTES: * Takes log_redrive_lock. */ static inline void lbmRedrive(struct lbuf *bp) { unsigned long flags; spin_lock_irqsave(&log_redrive_lock, flags); bp->l_redrive_next = log_redrive_list; log_redrive_list = bp; spin_unlock_irqrestore(&log_redrive_lock, flags); wake_up_process(jfsIOthread); } /* * lbmRead() */ static int lbmRead(struct jfs_log * log, int pn, struct lbuf ** bpp) { struct bio *bio; struct lbuf *bp; /* * allocate a log buffer */ *bpp = bp = lbmAllocate(log, pn); jfs_info("lbmRead: bp:0x%p pn:0x%x", bp, pn); bp->l_flag |= lbmREAD; bio = bio_alloc(log->bdev_handle->bdev, 1, REQ_OP_READ, GFP_NOFS); bio->bi_iter.bi_sector = bp->l_blkno << (log->l2bsize - 9); __bio_add_page(bio, bp->l_page, LOGPSIZE, bp->l_offset); BUG_ON(bio->bi_iter.bi_size != LOGPSIZE); bio->bi_end_io = lbmIODone; bio->bi_private = bp; /*check if journaling to disk has been disabled*/ if (log->no_integrity) { bio->bi_iter.bi_size = 0; lbmIODone(bio); } else { submit_bio(bio); } wait_event(bp->l_ioevent, (bp->l_flag != lbmREAD)); return 0; } /* * lbmWrite() * * buffer at head of pageout queue stays after completion of * partial-page pageout and redriven by explicit initiation of * pageout by caller until full-page pageout is completed and * released. * * device driver i/o done redrives pageout of new buffer at * head of pageout queue when current buffer at head of pageout * queue is released at the completion of its full-page pageout. * * LOGGC_LOCK() serializes lbmWrite() by lmNextPage() and lmGroupCommit(). * LCACHE_LOCK() serializes xflag between lbmWrite() and lbmIODone() */ static void lbmWrite(struct jfs_log * log, struct lbuf * bp, int flag, int cant_block) { struct lbuf *tail; unsigned long flags; jfs_info("lbmWrite: bp:0x%p flag:0x%x pn:0x%x", bp, flag, bp->l_pn); /* map the logical block address to physical block address */ bp->l_blkno = log->base + (bp->l_pn << (L2LOGPSIZE - log->l2bsize)); LCACHE_LOCK(flags); /* disable+lock */ /* * initialize buffer for device driver */ bp->l_flag = flag; /* * insert bp at tail of write queue associated with log * * (request is either for bp already/currently at head of queue * or new bp to be inserted at tail) */ tail = log->wqueue; /* is buffer not already on write queue ? */ if (bp->l_wqnext == NULL) { /* insert at tail of wqueue */ if (tail == NULL) { log->wqueue = bp; bp->l_wqnext = bp; } else { log->wqueue = bp; bp->l_wqnext = tail->l_wqnext; tail->l_wqnext = bp; } tail = bp; } /* is buffer at head of wqueue and for write ? */ if ((bp != tail->l_wqnext) || !(flag & lbmWRITE)) { LCACHE_UNLOCK(flags); /* unlock+enable */ return; } LCACHE_UNLOCK(flags); /* unlock+enable */ if (cant_block) lbmRedrive(bp); else if (flag & lbmSYNC) lbmStartIO(bp); else { LOGGC_UNLOCK(log); lbmStartIO(bp); LOGGC_LOCK(log); } } /* * lbmDirectWrite() * * initiate pageout bypassing write queue for sidestream * (e.g., log superblock) write; */ static void lbmDirectWrite(struct jfs_log * log, struct lbuf * bp, int flag) { jfs_info("lbmDirectWrite: bp:0x%p flag:0x%x pn:0x%x", bp, flag, bp->l_pn); /* * initialize buffer for device driver */ bp->l_flag = flag | lbmDIRECT; /* map the logical block address to physical block address */ bp->l_blkno = log->base + (bp->l_pn << (L2LOGPSIZE - log->l2bsize)); /* * initiate pageout of the page */ lbmStartIO(bp); } /* * NAME: lbmStartIO() * * FUNCTION: Interface to DD strategy routine * * RETURN: none * * serialization: LCACHE_LOCK() is NOT held during log i/o; */ static void lbmStartIO(struct lbuf * bp) { struct bio *bio; struct jfs_log *log = bp->l_log; struct block_device *bdev = NULL; jfs_info("lbmStartIO"); if (!log->no_integrity) bdev = log->bdev_handle->bdev; bio = bio_alloc(bdev, 1, REQ_OP_WRITE | REQ_SYNC, GFP_NOFS); bio->bi_iter.bi_sector = bp->l_blkno << (log->l2bsize - 9); __bio_add_page(bio, bp->l_page, LOGPSIZE, bp->l_offset); BUG_ON(bio->bi_iter.bi_size != LOGPSIZE); bio->bi_end_io = lbmIODone; bio->bi_private = bp; /* check if journaling to disk has been disabled */ if (log->no_integrity) { bio->bi_iter.bi_size = 0; lbmIODone(bio); } else { submit_bio(bio); INCREMENT(lmStat.submitted); } } /* * lbmIOWait() */ static int lbmIOWait(struct lbuf * bp, int flag) { unsigned long flags; int rc = 0; jfs_info("lbmIOWait1: bp:0x%p flag:0x%x:0x%x", bp, bp->l_flag, flag); LCACHE_LOCK(flags); /* disable+lock */ LCACHE_SLEEP_COND(bp->l_ioevent, (bp->l_flag & lbmDONE), flags); rc = (bp->l_flag & lbmERROR) ? -EIO : 0; if (flag & lbmFREE) lbmfree(bp); LCACHE_UNLOCK(flags); /* unlock+enable */ jfs_info("lbmIOWait2: bp:0x%p flag:0x%x:0x%x", bp, bp->l_flag, flag); return rc; } /* * lbmIODone() * * executed at INTIODONE level */ static void lbmIODone(struct bio *bio) { struct lbuf *bp = bio->bi_private; struct lbuf *nextbp, *tail; struct jfs_log *log; unsigned long flags; /* * get back jfs buffer bound to the i/o buffer */ jfs_info("lbmIODone: bp:0x%p flag:0x%x", bp, bp->l_flag); LCACHE_LOCK(flags); /* disable+lock */ bp->l_flag |= lbmDONE; if (bio->bi_status) { bp->l_flag |= lbmERROR; jfs_err("lbmIODone: I/O error in JFS log"); } bio_put(bio); /* * pagein completion */ if (bp->l_flag & lbmREAD) { bp->l_flag &= ~lbmREAD; LCACHE_UNLOCK(flags); /* unlock+enable */ /* wakeup I/O initiator */ LCACHE_WAKEUP(&bp->l_ioevent); return; } /* * pageout completion * * the bp at the head of write queue has completed pageout. * * if single-commit/full-page pageout, remove the current buffer * from head of pageout queue, and redrive pageout with * the new buffer at head of pageout queue; * otherwise, the partial-page pageout buffer stays at * the head of pageout queue to be redriven for pageout * by lmGroupCommit() until full-page pageout is completed. */ bp->l_flag &= ~lbmWRITE; INCREMENT(lmStat.pagedone); /* update committed lsn */ log = bp->l_log; log->clsn = (bp->l_pn << L2LOGPSIZE) + bp->l_ceor; if (bp->l_flag & lbmDIRECT) { LCACHE_WAKEUP(&bp->l_ioevent); LCACHE_UNLOCK(flags); return; } tail = log->wqueue; /* single element queue */ if (bp == tail) { /* remove head buffer of full-page pageout * from log device write queue */ if (bp->l_flag & lbmRELEASE) { log->wqueue = NULL; bp->l_wqnext = NULL; } } /* multi element queue */ else { /* remove head buffer of full-page pageout * from log device write queue */ if (bp->l_flag & lbmRELEASE) { nextbp = tail->l_wqnext = bp->l_wqnext; bp->l_wqnext = NULL; /* * redrive pageout of next page at head of write queue: * redrive next page without any bound tblk * (i.e., page w/o any COMMIT records), or * first page of new group commit which has been * queued after current page (subsequent pageout * is performed synchronously, except page without * any COMMITs) by lmGroupCommit() as indicated * by lbmWRITE flag; */ if (nextbp->l_flag & lbmWRITE) { /* * We can't do the I/O at interrupt time. * The jfsIO thread can do it */ lbmRedrive(nextbp); } } } /* * synchronous pageout: * * buffer has not necessarily been removed from write queue * (e.g., synchronous write of partial-page with COMMIT): * leave buffer for i/o initiator to dispose */ if (bp->l_flag & lbmSYNC) { LCACHE_UNLOCK(flags); /* unlock+enable */ /* wakeup I/O initiator */ LCACHE_WAKEUP(&bp->l_ioevent); } /* * Group Commit pageout: */ else if (bp->l_flag & lbmGC) { LCACHE_UNLOCK(flags); lmPostGC(bp); } /* * asynchronous pageout: * * buffer must have been removed from write queue: * insert buffer at head of freelist where it can be recycled */ else { assert(bp->l_flag & lbmRELEASE); assert(bp->l_flag & lbmFREE); lbmfree(bp); LCACHE_UNLOCK(flags); /* unlock+enable */ } } int jfsIOWait(void *arg) { struct lbuf *bp; do { spin_lock_irq(&log_redrive_lock); while ((bp = log_redrive_list)) { log_redrive_list = bp->l_redrive_next; bp->l_redrive_next = NULL; spin_unlock_irq(&log_redrive_lock); lbmStartIO(bp); spin_lock_irq(&log_redrive_lock); } if (freezing(current)) { spin_unlock_irq(&log_redrive_lock); try_to_freeze(); } else { set_current_state(TASK_INTERRUPTIBLE); spin_unlock_irq(&log_redrive_lock); schedule(); } } while (!kthread_should_stop()); jfs_info("jfsIOWait being killed!"); return 0; } /* * NAME: lmLogFormat()/jfs_logform() * * FUNCTION: format file system log * * PARAMETERS: * log - volume log * logAddress - start address of log space in FS block * logSize - length of log space in FS block; * * RETURN: 0 - success * -EIO - i/o error * * XXX: We're synchronously writing one page at a time. This needs to * be improved by writing multiple pages at once. */ int lmLogFormat(struct jfs_log *log, s64 logAddress, int logSize) { int rc = -EIO; struct jfs_sb_info *sbi; struct logsuper *logsuper; struct logpage *lp; int lspn; /* log sequence page number */ struct lrd *lrd_ptr; int npages = 0; struct lbuf *bp; jfs_info("lmLogFormat: logAddress:%Ld logSize:%d", (long long)logAddress, logSize); sbi = list_entry(log->sb_list.next, struct jfs_sb_info, log_list); /* allocate a log buffer */ bp = lbmAllocate(log, 1); npages = logSize >> sbi->l2nbperpage; /* * log space: * * page 0 - reserved; * page 1 - log superblock; * page 2 - log data page: A SYNC log record is written * into this page at logform time; * pages 3-N - log data page: set to empty log data pages; */ /* * init log superblock: log page 1 */ logsuper = (struct logsuper *) bp->l_ldata; logsuper->magic = cpu_to_le32(LOGMAGIC); logsuper->version = cpu_to_le32(LOGVERSION); logsuper->state = cpu_to_le32(LOGREDONE); logsuper->flag = cpu_to_le32(sbi->mntflag); /* ? */ logsuper->size = cpu_to_le32(npages); logsuper->bsize = cpu_to_le32(sbi->bsize); logsuper->l2bsize = cpu_to_le32(sbi->l2bsize); logsuper->end = cpu_to_le32(2 * LOGPSIZE + LOGPHDRSIZE + LOGRDSIZE); bp->l_flag = lbmWRITE | lbmSYNC | lbmDIRECT; bp->l_blkno = logAddress + sbi->nbperpage; lbmStartIO(bp); if ((rc = lbmIOWait(bp, 0))) goto exit; /* * init pages 2 to npages-1 as log data pages: * * log page sequence number (lpsn) initialization: * * pn: 0 1 2 3 n-1 * +-----+-----+=====+=====+===.....===+=====+ * lspn: N-1 0 1 N-2 * <--- N page circular file ----> * * the N (= npages-2) data pages of the log is maintained as * a circular file for the log records; * lpsn grows by 1 monotonically as each log page is written * to the circular file of the log; * and setLogpage() will not reset the page number even if * the eor is equal to LOGPHDRSIZE. In order for binary search * still work in find log end process, we have to simulate the * log wrap situation at the log format time. * The 1st log page written will have the highest lpsn. Then * the succeeding log pages will have ascending order of * the lspn starting from 0, ... (N-2) */ lp = (struct logpage *) bp->l_ldata; /* * initialize 1st log page to be written: lpsn = N - 1, * write a SYNCPT log record is written to this page */ lp->h.page = lp->t.page = cpu_to_le32(npages - 3); lp->h.eor = lp->t.eor = cpu_to_le16(LOGPHDRSIZE + LOGRDSIZE); lrd_ptr = (struct lrd *) &lp->data; lrd_ptr->logtid = 0; lrd_ptr->backchain = 0; lrd_ptr->type = cpu_to_le16(LOG_SYNCPT); lrd_ptr->length = 0; lrd_ptr->log.syncpt.sync = 0; bp->l_blkno += sbi->nbperpage; bp->l_flag = lbmWRITE | lbmSYNC | lbmDIRECT; lbmStartIO(bp); if ((rc = lbmIOWait(bp, 0))) goto exit; /* * initialize succeeding log pages: lpsn = 0, 1, ..., (N-2) */ for (lspn = 0; lspn < npages - 3; lspn++) { lp->h.page = lp->t.page = cpu_to_le32(lspn); lp->h.eor = lp->t.eor = cpu_to_le16(LOGPHDRSIZE); bp->l_blkno += sbi->nbperpage; bp->l_flag = lbmWRITE | lbmSYNC | lbmDIRECT; lbmStartIO(bp); if ((rc = lbmIOWait(bp, 0))) goto exit; } rc = 0; exit: /* * finalize log */ /* release the buffer */ lbmFree(bp); return rc; } #ifdef CONFIG_JFS_STATISTICS int jfs_lmstats_proc_show(struct seq_file *m, void *v) { seq_printf(m, "JFS Logmgr stats\n" "================\n" "commits = %d\n" "writes submitted = %d\n" "writes completed = %d\n" "full pages submitted = %d\n" "partial pages submitted = %d\n", lmStat.commit, lmStat.submitted, lmStat.pagedone, lmStat.full_page, lmStat.partial_page); return 0; } #endif /* CONFIG_JFS_STATISTICS */
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