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1822 1823 1824 1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837 1838 1839 1840 1841 1842 1843 1844 1845 1846 1847 1848 1849 1850 1851 1852 1853 1854 1855 1856 1857 1858 1859 1860 1861 1862 1863 1864 1865 1866 1867 1868 1869 1870 1871 1872 1873 1874 1875 1876 1877 1878 1879 1880 | /* * linux/fs/journal.c * * Written by Stephen C. Tweedie <sct@redhat.com>, 1998 * * Copyright 1998 Red Hat corp --- All Rights Reserved * * This file is part of the Linux kernel and is made available under * the terms of the GNU General Public License, version 2, or at your * option, any later version, incorporated herein by reference. * * Generic filesystem journal-writing code; part of the ext2fs * journaling system. * * This file manages journals: areas of disk reserved for logging * transactional updates. This includes the kernel journaling thread * which is responsible for scheduling updates to the log. * * We do not actually manage the physical storage of the journal in this * file: that is left to a per-journal policy function, which allows us * to store the journal within a filesystem-specified area for ext2 * journaling (ext2 can use a reserved inode for storing the log). */ #include <linux/module.h> #include <linux/time.h> #include <linux/fs.h> #include <linux/jbd.h> #include <linux/errno.h> #include <linux/slab.h> #include <linux/smp_lock.h> #include <linux/init.h> #include <linux/mm.h> #include <linux/slab.h> #include <linux/suspend.h> #include <linux/pagemap.h> #include <asm/uaccess.h> #include <linux/proc_fs.h> EXPORT_SYMBOL(journal_start); EXPORT_SYMBOL(journal_try_start); EXPORT_SYMBOL(journal_restart); EXPORT_SYMBOL(journal_extend); EXPORT_SYMBOL(journal_stop); EXPORT_SYMBOL(journal_lock_updates); EXPORT_SYMBOL(journal_unlock_updates); EXPORT_SYMBOL(journal_get_write_access); EXPORT_SYMBOL(journal_get_create_access); EXPORT_SYMBOL(journal_get_undo_access); EXPORT_SYMBOL(journal_dirty_data); EXPORT_SYMBOL(journal_dirty_metadata); #if 0 EXPORT_SYMBOL(journal_release_buffer); #endif EXPORT_SYMBOL(journal_forget); #if 0 EXPORT_SYMBOL(journal_sync_buffer); #endif EXPORT_SYMBOL(journal_flush); EXPORT_SYMBOL(journal_revoke); EXPORT_SYMBOL(journal_callback_set); EXPORT_SYMBOL(journal_init_dev); EXPORT_SYMBOL(journal_init_inode); EXPORT_SYMBOL(journal_update_format); EXPORT_SYMBOL(journal_check_used_features); EXPORT_SYMBOL(journal_check_available_features); EXPORT_SYMBOL(journal_set_features); EXPORT_SYMBOL(journal_create); EXPORT_SYMBOL(journal_load); EXPORT_SYMBOL(journal_destroy); EXPORT_SYMBOL(journal_recover); EXPORT_SYMBOL(journal_update_superblock); EXPORT_SYMBOL(journal_abort); EXPORT_SYMBOL(journal_errno); EXPORT_SYMBOL(journal_ack_err); EXPORT_SYMBOL(journal_clear_err); EXPORT_SYMBOL(log_wait_commit); EXPORT_SYMBOL(log_start_commit); EXPORT_SYMBOL(journal_wipe); EXPORT_SYMBOL(journal_blocks_per_page); EXPORT_SYMBOL(journal_invalidatepage); EXPORT_SYMBOL(journal_try_to_free_buffers); EXPORT_SYMBOL(journal_bmap); EXPORT_SYMBOL(journal_force_commit); static int journal_convert_superblock_v1(journal_t *, journal_superblock_t *); /* * journal_datalist_lock is used to protect data buffers: * * bh->b_transaction * bh->b_tprev * bh->b_tnext * * journal_free_buffer() is called from journal_try_to_free_buffer(), and is * async wrt everything else. * * It is also used for checkpoint data, also to protect against * journal_try_to_free_buffer(): * * bh->b_cp_transaction * bh->b_cpnext * bh->b_cpprev * transaction->t_checkpoint_list * transaction->t_cpnext * transaction->t_cpprev * journal->j_checkpoint_transactions * * It is global at this time rather than per-journal because it's * impossible for __journal_free_buffer to go from a buffer_head * back to a journal_t unracily (well, not true. Fix later) * * * The `datalist' and `checkpoint list' functions are quite * separate and we could use two spinlocks here. * * lru_list_lock nests inside journal_datalist_lock. */ spinlock_t journal_datalist_lock = SPIN_LOCK_UNLOCKED; /* * jh_splice_lock needs explantion. * * In a number of places we want to do things like: * * if (buffer_jbd(bh) && bh2jh(bh)->foo) * * This is racy on SMP, because another CPU could remove the journal_head * in the middle of this expression. We need locking. * * But we can greatly optimise the locking cost by testing BH_JBD * outside the lock. So, effectively: * * ret = 0; * if (buffer_jbd(bh)) { * spin_lock(&jh_splice_lock); * if (buffer_jbd(bh)) { (* Still there? *) * ret = bh2jh(bh)->foo; * } * spin_unlock(&jh_splice_lock); * } * return ret; * * Now, that protects us from races where another CPU can remove the * journal_head. But it doesn't defend us from the situation where another * CPU can *add* a journal_head. This is a correctness issue. But it's not * a problem because a) the calling code was *already* racy and b) it often * can't happen at the call site and c) the places where we add journal_heads * tend to be under external locking. */ spinlock_t jh_splice_lock = SPIN_LOCK_UNLOCKED; /* * List of all journals in the system. Protected by the BKL. */ static LIST_HEAD(all_journals); /* * Helper function used to manage commit timeouts */ static void commit_timeout(unsigned long __data) { struct task_struct * p = (struct task_struct *) __data; wake_up_process(p); } /* Static check for data structure consistency. There's no code * invoked --- we'll just get a linker failure if things aren't right. */ void __journal_internal_check(void) { extern void journal_bad_superblock_size(void); if (sizeof(struct journal_superblock_s) != 1024) journal_bad_superblock_size(); } /* * kjournald: The main thread function used to manage a logging device * journal. * * This kernel thread is responsible for two things: * * 1) COMMIT: Every so often we need to commit the current state of the * filesystem to disk. The journal thread is responsible for writing * all of the metadata buffers to disk. * * 2) CHECKPOINT: We cannot reuse a used section of the log file until all * of the data in that part of the log has been rewritten elsewhere on * the disk. Flushing these old buffers to reclaim space in the log is * known as checkpointing, and this thread is responsible for that job. */ journal_t *current_journal; // AKPM: debug int kjournald(void *arg) { journal_t *journal = (journal_t *) arg; transaction_t *transaction; struct timer_list timer; current_journal = journal; lock_kernel(); daemonize(); spin_lock_irq(¤t->sig->siglock); sigfillset(¤t->blocked); recalc_sigpending(); spin_unlock_irq(¤t->sig->siglock); sprintf(current->comm, "kjournald"); /* Set up an interval timer which can be used to trigger a commit wakeup after the commit interval expires */ init_timer(&timer); timer.data = (unsigned long) current; timer.function = commit_timeout; journal->j_commit_timer = &timer; /* Record that the journal thread is running */ journal->j_task = current; wake_up(&journal->j_wait_done_commit); printk(KERN_INFO "kjournald starting. Commit interval %ld seconds\n", journal->j_commit_interval / HZ); list_add(&journal->j_all_journals, &all_journals); /* And now, wait forever for commit wakeup events. */ while (1) { if (journal->j_flags & JFS_UNMOUNT) break; jbd_debug(1, "commit_sequence=%d, commit_request=%d\n", journal->j_commit_sequence, journal->j_commit_request); if (journal->j_commit_sequence != journal->j_commit_request) { jbd_debug(1, "OK, requests differ\n"); if (journal->j_commit_timer_active) { journal->j_commit_timer_active = 0; del_timer(journal->j_commit_timer); } journal_commit_transaction(journal); continue; } wake_up(&journal->j_wait_done_commit); if (current->flags & PF_FREEZE) { /* The simpler the better. Flushing journal isn't a good idea, because that depends on threads that may be already stopped. */ jbd_debug(1, "Now suspending kjournald\n"); refrigerator(PF_IOTHREAD); jbd_debug(1, "Resuming kjournald\n"); } else /* we assume on resume that commits are already there, so we don't sleep */ interruptible_sleep_on(&journal->j_wait_commit); jbd_debug(1, "kjournald wakes\n"); /* Were we woken up by a commit wakeup event? */ if ((transaction = journal->j_running_transaction) != NULL && time_after_eq(jiffies, transaction->t_expires)) { journal->j_commit_request = transaction->t_tid; jbd_debug(1, "woke because of timeout\n"); } } if (journal->j_commit_timer_active) { journal->j_commit_timer_active = 0; del_timer_sync(journal->j_commit_timer); } list_del(&journal->j_all_journals); journal->j_task = NULL; wake_up(&journal->j_wait_done_commit); jbd_debug(1, "Journal thread exiting.\n"); unlock_kernel(); return 0; } static void journal_start_thread(journal_t *journal) { kernel_thread(kjournald, (void *) journal, CLONE_VM | CLONE_FS | CLONE_FILES); while (!journal->j_task) sleep_on(&journal->j_wait_done_commit); } static void journal_kill_thread(journal_t *journal) { journal->j_flags |= JFS_UNMOUNT; while (journal->j_task) { wake_up(&journal->j_wait_commit); sleep_on(&journal->j_wait_done_commit); } } #if 0 This is no longer needed - we do it in commit quite efficiently. Note that if this function is resurrected, the loop needs to be reorganised into the next_jh/last_jh algorithm. /* * journal_clean_data_list: cleanup after data IO. * * Once the IO system has finished writing the buffers on the transaction's * data list, we can remove those buffers from the list. This function * scans the list for such buffers and removes them cleanly. * * We assume that the journal is already locked. * We are called with journal_datalist_lock held. * * AKPM: This function looks inefficient. Approximately O(n^2) * for potentially thousands of buffers. It no longer shows on profiles * because these buffers are mainly dropped in journal_commit_transaction(). */ void __journal_clean_data_list(transaction_t *transaction) { struct journal_head *jh, *next; assert_spin_locked(&journal_datalist_lock); restart: jh = transaction->t_sync_datalist; if (!jh) goto out; do { next = jh->b_tnext; if (!buffer_locked(jh2bh(jh)) && !buffer_dirty(jh2bh(jh))) { struct buffer_head *bh = jh2bh(jh); BUFFER_TRACE(bh, "data writeout complete: unfile"); __journal_unfile_buffer(jh); jh->b_transaction = NULL; __journal_remove_journal_head(bh); __brelse(bh); goto restart; } jh = next; } while (transaction->t_sync_datalist && jh != transaction->t_sync_datalist); out: return; } #endif /* * journal_write_metadata_buffer: write a metadata buffer to the journal. * * Writes a metadata buffer to a given disk block. The actual IO is not * performed but a new buffer_head is constructed which labels the data * to be written with the correct destination disk block. * * Any magic-number escaping which needs to be done will cause a * copy-out here. If the buffer happens to start with the * JFS_MAGIC_NUMBER, then we can't write it to the log directly: the * magic number is only written to the log for descripter blocks. In * this case, we copy the data and replace the first word with 0, and we * return a result code which indicates that this buffer needs to be * marked as an escaped buffer in the corresponding log descriptor * block. The missing word can then be restored when the block is read * during recovery. * * If the source buffer has already been modified by a new transaction * since we took the last commit snapshot, we use the frozen copy of * that data for IO. If we end up using the existing buffer_head's data * for the write, then we *have* to lock the buffer to prevent anyone * else from using and possibly modifying it while the IO is in * progress. * * The function returns a pointer to the buffer_heads to be used for IO. * * We assume that the journal has already been locked in this function. * * Return value: * <0: Error * >=0: Finished OK * * On success: * Bit 0 set == escape performed on the data * Bit 1 set == buffer copy-out performed (kfree the data after IO) */ static inline unsigned long virt_to_offset(void *p) {return ((unsigned long) p) & ~PAGE_MASK;} int journal_write_metadata_buffer(transaction_t *transaction, struct journal_head *jh_in, struct journal_head **jh_out, int blocknr) { int need_copy_out = 0; int done_copy_out = 0; int do_escape = 0; char *mapped_data; struct buffer_head *new_bh; struct journal_head * new_jh; struct page *new_page; unsigned int new_offset; /* * The buffer really shouldn't be locked: only the current committing * transaction is allowed to write it, so nobody else is allowed * to do any IO. * * akpm: except if we're journalling data, and write() output is * also part of a shared mapping, and another thread has * decided to launch a writepage() against this buffer. */ J_ASSERT_JH(jh_in, buffer_jdirty(jh2bh(jh_in))); /* * If a new transaction has already done a buffer copy-out, then * we use that version of the data for the commit. */ if (jh_in->b_frozen_data) { done_copy_out = 1; new_page = virt_to_page(jh_in->b_frozen_data); new_offset = virt_to_offset(jh_in->b_frozen_data); } else { new_page = jh2bh(jh_in)->b_page; new_offset = virt_to_offset(jh2bh(jh_in)->b_data); } mapped_data = ((char *) kmap(new_page)) + new_offset; /* * Check for escaping */ if (* ((unsigned int *) mapped_data) == htonl(JFS_MAGIC_NUMBER)) { need_copy_out = 1; do_escape = 1; } /* * Do we need to do a data copy? */ if (need_copy_out && !done_copy_out) { char *tmp; tmp = jbd_rep_kmalloc(jh2bh(jh_in)->b_size, GFP_NOFS); jh_in->b_frozen_data = tmp; memcpy (tmp, mapped_data, jh2bh(jh_in)->b_size); /* If we get to this path, we'll always need the new address kmapped so that we can clear the escaped magic number below. */ kunmap(new_page); new_page = virt_to_page(tmp); new_offset = virt_to_offset(tmp); mapped_data = ((char *) kmap(new_page)) + new_offset; done_copy_out = 1; } /* * Right, time to make up the new buffer_head. */ do { new_bh = alloc_buffer_head(); if (!new_bh) { printk (KERN_NOTICE "%s: ENOMEM at alloc_buffer_head, " "trying again.\n", __FUNCTION__); yield(); } } while (!new_bh); /* keep subsequent assertions sane */ new_bh->b_state = 0; init_buffer(new_bh, NULL, NULL); atomic_set(&new_bh->b_count, 1); new_jh = journal_add_journal_head(new_bh); set_bh_page(new_bh, new_page, new_offset); new_jh->b_transaction = NULL; new_bh->b_size = jh2bh(jh_in)->b_size; new_bh->b_bdev = transaction->t_journal->j_dev; new_bh->b_blocknr = blocknr; set_buffer_mapped(new_bh); set_buffer_dirty(new_bh); *jh_out = new_jh; /* * Did we need to do an escaping? Now we've done all the * copying, we can finally do so. */ if (do_escape) * ((unsigned int *) mapped_data) = 0; kunmap(new_page); /* * The to-be-written buffer needs to get moved to the io queue, * and the original buffer whose contents we are shadowing or * copying is moved to the transaction's shadow queue. */ JBUFFER_TRACE(jh_in, "file as BJ_Shadow"); journal_file_buffer(jh_in, transaction, BJ_Shadow); JBUFFER_TRACE(new_jh, "file as BJ_IO"); journal_file_buffer(new_jh, transaction, BJ_IO); return do_escape | (done_copy_out << 1); } /* * Allocation code for the journal file. Manage the space left in the * journal, so that we can begin checkpointing when appropriate. */ /* * log_space_left: Return the number of free blocks left in the journal. * * Called with the journal already locked. */ int log_space_left (journal_t *journal) { int left = journal->j_free; /* Be pessimistic here about the number of those free blocks * which might be required for log descriptor control blocks. */ #define MIN_LOG_RESERVED_BLOCKS 32 /* Allow for rounding errors */ left -= MIN_LOG_RESERVED_BLOCKS; if (left <= 0) return 0; left -= (left >> 3); return left; } /* * This function must be non-allocating for PF_MEMALLOC tasks */ tid_t log_start_commit (journal_t *journal, transaction_t *transaction) { tid_t target = journal->j_commit_request; lock_kernel(); /* Protect journal->j_running_transaction */ /* * A NULL transaction asks us to commit the currently running * transaction, if there is one. */ if (transaction) target = transaction->t_tid; else { transaction = journal->j_running_transaction; if (!transaction) goto out; target = transaction->t_tid; } /* * Are we already doing a recent enough commit? */ if (tid_geq(journal->j_commit_request, target)) goto out; /* * We want a new commit: OK, mark the request and wakup the * commit thread. We do _not_ do the commit ourselves. */ journal->j_commit_request = target; jbd_debug(1, "JBD: requesting commit %d/%d\n", journal->j_commit_request, journal->j_commit_sequence); wake_up(&journal->j_wait_commit); out: unlock_kernel(); return target; } /* * Wait for a specified commit to complete. * The caller may not hold the journal lock. */ void log_wait_commit (journal_t *journal, tid_t tid) { lock_kernel(); #ifdef CONFIG_JBD_DEBUG lock_journal(journal); if (!tid_geq(journal->j_commit_request, tid)) { printk(KERN_EMERG "%s: error: j_commit_request=%d, tid=%d\n", __FUNCTION__, journal->j_commit_request, tid); } unlock_journal(journal); #endif while (tid_gt(tid, journal->j_commit_sequence)) { jbd_debug(1, "JBD: want %d, j_commit_sequence=%d\n", tid, journal->j_commit_sequence); wake_up(&journal->j_wait_commit); sleep_on(&journal->j_wait_done_commit); } unlock_kernel(); } /* * Log buffer allocation routines: */ int journal_next_log_block(journal_t *journal, unsigned long *retp) { unsigned long blocknr; J_ASSERT(journal->j_free > 1); blocknr = journal->j_head; journal->j_head++; journal->j_free--; if (journal->j_head == journal->j_last) journal->j_head = journal->j_first; return journal_bmap(journal, blocknr, retp); } /* * Conversion of logical to physical block numbers for the journal * * On external journals the journal blocks are identity-mapped, so * this is a no-op. If needed, we can use j_blk_offset - everything is * ready. */ int journal_bmap(journal_t *journal, unsigned long blocknr, unsigned long *retp) { int err = 0; unsigned long ret; if (journal->j_inode) { ret = bmap(journal->j_inode, blocknr); if (ret) *retp = ret; else { printk(KERN_ALERT "%s: journal block not found " "at offset %lu on %s\n", __FUNCTION__, blocknr, bdevname(journal->j_dev)); err = -EIO; __journal_abort_soft(journal, err); } } else { *retp = blocknr; /* +journal->j_blk_offset */ } return err; } /* * We play buffer_head aliasing tricks to write data/metadata blocks to * the journal without copying their contents, but for journal * descriptor blocks we do need to generate bona fide buffers. */ struct journal_head * journal_get_descriptor_buffer(journal_t *journal) { struct buffer_head *bh; unsigned long blocknr; int err; err = journal_next_log_block(journal, &blocknr); if (err) return NULL; bh = __getblk(journal->j_dev, blocknr, journal->j_blocksize); bh->b_state |= (1 << BH_Dirty); BUFFER_TRACE(bh, "return this buffer"); return journal_add_journal_head(bh); } /* * Management for journal control blocks: functions to create and * destroy journal_t structures, and to initialise and read existing * journal blocks from disk. */ /* First: create and setup a journal_t object in memory. We initialise * very few fields yet: that has to wait until we have created the * journal structures from from scratch, or loaded them from disk. */ static journal_t * journal_init_common (void) { journal_t *journal; int err; MOD_INC_USE_COUNT; journal = jbd_kmalloc(sizeof(*journal), GFP_KERNEL); if (!journal) goto fail; memset(journal, 0, sizeof(*journal)); init_waitqueue_head(&journal->j_wait_transaction_locked); init_waitqueue_head(&journal->j_wait_logspace); init_waitqueue_head(&journal->j_wait_done_commit); init_waitqueue_head(&journal->j_wait_checkpoint); init_waitqueue_head(&journal->j_wait_commit); init_waitqueue_head(&journal->j_wait_updates); init_MUTEX(&journal->j_barrier); init_MUTEX(&journal->j_checkpoint_sem); init_MUTEX(&journal->j_sem); journal->j_commit_interval = (HZ * 5); /* The journal is marked for error until we succeed with recovery! */ journal->j_flags = JFS_ABORT; /* Set up a default-sized revoke table for the new mount. */ err = journal_init_revoke(journal, JOURNAL_REVOKE_DEFAULT_HASH); if (err) { kfree(journal); goto fail; } return journal; fail: MOD_DEC_USE_COUNT; return NULL; } /* journal_init_dev and journal_init_inode: * * Create a journal structure assigned some fixed set of disk blocks to * the journal. We don't actually touch those disk blocks yet, but we * need to set up all of the mapping information to tell the journaling * system where the journal blocks are. * * journal_init_dev creates a journal which maps a fixed contiguous * range of blocks on an arbitrary block device. * * journal_init_inode creates a journal which maps an on-disk inode as * the journal. The inode must exist already, must support bmap() and * must have all data blocks preallocated. */ journal_t * journal_init_dev(struct block_device *bdev, struct block_device *fs_dev, int start, int len, int blocksize) { journal_t *journal = journal_init_common(); struct buffer_head *bh; if (!journal) return NULL; journal->j_dev = bdev; journal->j_fs_dev = fs_dev; journal->j_blk_offset = start; journal->j_maxlen = len; journal->j_blocksize = blocksize; bh = __getblk(journal->j_dev, start, journal->j_blocksize); J_ASSERT(bh != NULL); journal->j_sb_buffer = bh; journal->j_superblock = (journal_superblock_t *)bh->b_data; return journal; } journal_t * journal_init_inode (struct inode *inode) { struct buffer_head *bh; journal_t *journal = journal_init_common(); int err; unsigned long blocknr; if (!journal) return NULL; journal->j_dev = journal->j_fs_dev = inode->i_sb->s_bdev; journal->j_inode = inode; jbd_debug(1, "journal %p: inode %s/%ld, size %Ld, bits %d, blksize %ld\n", journal, inode->i_sb->s_id, inode->i_ino, (long long) inode->i_size, inode->i_sb->s_blocksize_bits, inode->i_sb->s_blocksize); journal->j_maxlen = inode->i_size >> inode->i_sb->s_blocksize_bits; journal->j_blocksize = inode->i_sb->s_blocksize; err = journal_bmap(journal, 0, &blocknr); /* If that failed, give up */ if (err) { printk(KERN_ERR "%s: Cannnot locate journal superblock\n", __FUNCTION__); kfree(journal); return NULL; } bh = __getblk(journal->j_dev, blocknr, journal->j_blocksize); J_ASSERT(bh != NULL); journal->j_sb_buffer = bh; journal->j_superblock = (journal_superblock_t *)bh->b_data; return journal; } /* * If the journal init or create aborts, we need to mark the journal * superblock as being NULL to prevent the journal destroy from writing * back a bogus superblock. */ static void journal_fail_superblock (journal_t *journal) { struct buffer_head *bh = journal->j_sb_buffer; brelse(bh); journal->j_sb_buffer = NULL; } /* * Given a journal_t structure, initialise the various fields for * startup of a new journaling session. We use this both when creating * a journal, and after recovering an old journal to reset it for * subsequent use. */ static int journal_reset (journal_t *journal) { journal_superblock_t *sb = journal->j_superblock; unsigned int first, last; first = ntohl(sb->s_first); last = ntohl(sb->s_maxlen); journal->j_first = first; journal->j_last = last; journal->j_head = first; journal->j_tail = first; journal->j_free = last - first; journal->j_tail_sequence = journal->j_transaction_sequence; journal->j_commit_sequence = journal->j_transaction_sequence - 1; journal->j_commit_request = journal->j_commit_sequence; journal->j_max_transaction_buffers = journal->j_maxlen / 4; /* Add the dynamic fields and write it to disk. */ journal_update_superblock(journal, 1); lock_journal(journal); journal_start_thread(journal); unlock_journal(journal); return 0; } /* * Given a journal_t structure which tells us which disk blocks we can * use, create a new journal superblock and initialise all of the * journal fields from scratch. */ int journal_create (journal_t *journal) { unsigned long blocknr; struct buffer_head *bh; journal_superblock_t *sb; int i, err; if (journal->j_maxlen < JFS_MIN_JOURNAL_BLOCKS) { printk (KERN_ERR "Journal length (%d blocks) too short.\n", journal->j_maxlen); journal_fail_superblock(journal); return -EINVAL; } if (journal->j_inode == NULL) { /* * We don't know what block to start at! */ printk(KERN_EMERG "%s: creation of journal on external device!\n", __FUNCTION__); BUG(); } /* Zero out the entire journal on disk. We cannot afford to have any blocks on disk beginning with JFS_MAGIC_NUMBER. */ jbd_debug(1, "JBD: Zeroing out journal blocks...\n"); for (i = 0; i < journal->j_maxlen; i++) { err = journal_bmap(journal, i, &blocknr); if (err) return err; bh = __getblk(journal->j_dev, blocknr, journal->j_blocksize); lock_buffer(bh); memset (bh->b_data, 0, journal->j_blocksize); BUFFER_TRACE(bh, "marking dirty"); mark_buffer_dirty(bh); BUFFER_TRACE(bh, "marking uptodate"); set_buffer_uptodate(bh); unlock_buffer(bh); __brelse(bh); } fsync_bdev(journal->j_dev); jbd_debug(1, "JBD: journal cleared.\n"); /* OK, fill in the initial static fields in the new superblock */ sb = journal->j_superblock; sb->s_header.h_magic = htonl(JFS_MAGIC_NUMBER); sb->s_header.h_blocktype = htonl(JFS_SUPERBLOCK_V2); sb->s_blocksize = htonl(journal->j_blocksize); sb->s_maxlen = htonl(journal->j_maxlen); sb->s_first = htonl(1); journal->j_transaction_sequence = 1; journal->j_flags &= ~JFS_ABORT; journal->j_format_version = 2; return journal_reset(journal); } /* * Update a journal's dynamic superblock fields and write it to disk, * optionally waiting for the IO to complete. */ void journal_update_superblock(journal_t *journal, int wait) { journal_superblock_t *sb = journal->j_superblock; struct buffer_head *bh = journal->j_sb_buffer; jbd_debug(1,"JBD: updating superblock (start %ld, seq %d, errno %d)\n", journal->j_tail, journal->j_tail_sequence, journal->j_errno); sb->s_sequence = htonl(journal->j_tail_sequence); sb->s_start = htonl(journal->j_tail); sb->s_errno = htonl(journal->j_errno); BUFFER_TRACE(bh, "marking dirty"); mark_buffer_dirty(bh); ll_rw_block(WRITE, 1, &bh); if (wait) wait_on_buffer(bh); /* If we have just flushed the log (by marking s_start==0), then * any future commit will have to be careful to update the * superblock again to re-record the true start of the log. */ if (sb->s_start) journal->j_flags &= ~JFS_FLUSHED; else journal->j_flags |= JFS_FLUSHED; } /* * Read the superblock for a given journal, performing initial * validation of the format. */ static int journal_get_superblock(journal_t *journal) { struct buffer_head *bh; journal_superblock_t *sb; int err = -EIO; bh = journal->j_sb_buffer; J_ASSERT(bh != NULL); if (!buffer_uptodate(bh)) { ll_rw_block(READ, 1, &bh); wait_on_buffer(bh); if (!buffer_uptodate(bh)) { printk (KERN_ERR "JBD: IO error reading journal superblock\n"); goto out; } } sb = journal->j_superblock; err = -EINVAL; if (sb->s_header.h_magic != htonl(JFS_MAGIC_NUMBER) || sb->s_blocksize != htonl(journal->j_blocksize)) { printk(KERN_WARNING "JBD: no valid journal superblock found\n"); goto out; } switch(ntohl(sb->s_header.h_blocktype)) { case JFS_SUPERBLOCK_V1: journal->j_format_version = 1; break; case JFS_SUPERBLOCK_V2: journal->j_format_version = 2; break; default: printk(KERN_WARNING "JBD: unrecognised superblock format ID\n"); goto out; } if (ntohl(sb->s_maxlen) < journal->j_maxlen) journal->j_maxlen = ntohl(sb->s_maxlen); else if (ntohl(sb->s_maxlen) > journal->j_maxlen) { printk (KERN_WARNING "JBD: journal file too short\n"); goto out; } return 0; out: journal_fail_superblock(journal); return err; } /* * Load the on-disk journal superblock and read the key fields into the * journal_t. */ static int load_superblock(journal_t *journal) { int err; journal_superblock_t *sb; err = journal_get_superblock(journal); if (err) return err; sb = journal->j_superblock; journal->j_tail_sequence = ntohl(sb->s_sequence); journal->j_tail = ntohl(sb->s_start); journal->j_first = ntohl(sb->s_first); journal->j_last = ntohl(sb->s_maxlen); journal->j_errno = ntohl(sb->s_errno); return 0; } /* * Given a journal_t structure which tells us which disk blocks contain * a journal, read the journal from disk to initialise the in-memory * structures. */ int journal_load(journal_t *journal) { int err; err = load_superblock(journal); if (err) return err; /* If this is a V2 superblock, then we have to check the * features flags on it. */ if (journal->j_format_version >= 2) { journal_superblock_t *sb = journal->j_superblock; if ((sb->s_feature_ro_compat & ~cpu_to_be32(JFS_KNOWN_ROCOMPAT_FEATURES)) || (sb->s_feature_incompat & ~cpu_to_be32(JFS_KNOWN_INCOMPAT_FEATURES))) { printk (KERN_WARNING "JBD: Unrecognised features on journal\n"); return -EINVAL; } } /* Let the recovery code check whether it needs to recover any * data from the journal. */ if (journal_recover(journal)) goto recovery_error; /* OK, we've finished with the dynamic journal bits: * reinitialise the dynamic contents of the superblock in memory * and reset them on disk. */ if (journal_reset(journal)) goto recovery_error; journal->j_flags &= ~JFS_ABORT; journal->j_flags |= JFS_LOADED; return 0; recovery_error: printk (KERN_WARNING "JBD: recovery failed\n"); return -EIO; } /* * Release a journal_t structure once it is no longer in use by the * journaled object. */ void journal_destroy (journal_t *journal) { /* Wait for the commit thread to wake up and die. */ journal_kill_thread(journal); /* Force a final log commit */ if (journal->j_running_transaction) journal_commit_transaction(journal); /* Force any old transactions to disk */ lock_journal(journal); while (journal->j_checkpoint_transactions != NULL) log_do_checkpoint(journal, 1); J_ASSERT(journal->j_running_transaction == NULL); J_ASSERT(journal->j_committing_transaction == NULL); J_ASSERT(journal->j_checkpoint_transactions == NULL); /* We can now mark the journal as empty. */ journal->j_tail = 0; journal->j_tail_sequence = ++journal->j_transaction_sequence; if (journal->j_sb_buffer) { journal_update_superblock(journal, 1); brelse(journal->j_sb_buffer); } if (journal->j_inode) iput(journal->j_inode); if (journal->j_revoke) journal_destroy_revoke(journal); unlock_journal(journal); kfree(journal); MOD_DEC_USE_COUNT; } /* Published API: Check whether the journal uses all of a given set of * features. Return true (non-zero) if it does. */ int journal_check_used_features (journal_t *journal, unsigned long compat, unsigned long ro, unsigned long incompat) { journal_superblock_t *sb; if (!compat && !ro && !incompat) return 1; if (journal->j_format_version == 1) return 0; sb = journal->j_superblock; if (((be32_to_cpu(sb->s_feature_compat) & compat) == compat) && ((be32_to_cpu(sb->s_feature_ro_compat) & ro) == ro) && ((be32_to_cpu(sb->s_feature_incompat) & incompat) == incompat)) return 1; return 0; } /* Published API: Check whether the journaling code supports the use of * all of a given set of features on this journal. Return true * (non-zero) if it can. */ int journal_check_available_features (journal_t *journal, unsigned long compat, unsigned long ro, unsigned long incompat) { journal_superblock_t *sb; if (!compat && !ro && !incompat) return 1; sb = journal->j_superblock; /* We can support any known requested features iff the * superblock is in version 2. Otherwise we fail to support any * extended sb features. */ if (journal->j_format_version != 2) return 0; if ((compat & JFS_KNOWN_COMPAT_FEATURES) == compat && (ro & JFS_KNOWN_ROCOMPAT_FEATURES) == ro && (incompat & JFS_KNOWN_INCOMPAT_FEATURES) == incompat) return 1; return 0; } /* Published API: Mark a given journal feature as present on the * superblock. Returns true if the requested features could be set. */ int journal_set_features (journal_t *journal, unsigned long compat, unsigned long ro, unsigned long incompat) { journal_superblock_t *sb; if (journal_check_used_features(journal, compat, ro, incompat)) return 1; if (!journal_check_available_features(journal, compat, ro, incompat)) return 0; jbd_debug(1, "Setting new features 0x%lx/0x%lx/0x%lx\n", compat, ro, incompat); sb = journal->j_superblock; sb->s_feature_compat |= cpu_to_be32(compat); sb->s_feature_ro_compat |= cpu_to_be32(ro); sb->s_feature_incompat |= cpu_to_be32(incompat); return 1; } /* * Published API: * Given an initialised but unloaded journal struct, poke about in the * on-disk structure to update it to the most recent supported version. */ int journal_update_format (journal_t *journal) { journal_superblock_t *sb; int err; err = journal_get_superblock(journal); if (err) return err; sb = journal->j_superblock; switch (ntohl(sb->s_header.h_blocktype)) { case JFS_SUPERBLOCK_V2: return 0; case JFS_SUPERBLOCK_V1: return journal_convert_superblock_v1(journal, sb); default: break; } return -EINVAL; } static int journal_convert_superblock_v1(journal_t *journal, journal_superblock_t *sb) { int offset, blocksize; struct buffer_head *bh; printk(KERN_WARNING "JBD: Converting superblock from version 1 to 2.\n"); /* Pre-initialise new fields to zero */ offset = ((char *) &(sb->s_feature_compat)) - ((char *) sb); blocksize = ntohl(sb->s_blocksize); memset(&sb->s_feature_compat, 0, blocksize-offset); sb->s_nr_users = cpu_to_be32(1); sb->s_header.h_blocktype = cpu_to_be32(JFS_SUPERBLOCK_V2); journal->j_format_version = 2; bh = journal->j_sb_buffer; BUFFER_TRACE(bh, "marking dirty"); mark_buffer_dirty(bh); ll_rw_block(WRITE, 1, &bh); wait_on_buffer(bh); return 0; } /* * Flush all data for a given journal to disk and empty the journal. * Filesystems can use this when remounting readonly to ensure that * recovery does not need to happen on remount. */ int journal_flush (journal_t *journal) { int err = 0; transaction_t *transaction = NULL; unsigned long old_tail; lock_kernel(); /* Force everything buffered to the log... */ if (journal->j_running_transaction) { transaction = journal->j_running_transaction; log_start_commit(journal, transaction); } else if (journal->j_committing_transaction) transaction = journal->j_committing_transaction; /* Wait for the log commit to complete... */ if (transaction) log_wait_commit(journal, transaction->t_tid); /* ...and flush everything in the log out to disk. */ lock_journal(journal); while (!err && journal->j_checkpoint_transactions != NULL) err = log_do_checkpoint(journal, journal->j_maxlen); cleanup_journal_tail(journal); /* Finally, mark the journal as really needing no recovery. * This sets s_start==0 in the underlying superblock, which is * the magic code for a fully-recovered superblock. Any future * commits of data to the journal will restore the current * s_start value. */ old_tail = journal->j_tail; journal->j_tail = 0; journal_update_superblock(journal, 1); journal->j_tail = old_tail; unlock_journal(journal); J_ASSERT(!journal->j_running_transaction); J_ASSERT(!journal->j_committing_transaction); J_ASSERT(!journal->j_checkpoint_transactions); J_ASSERT(journal->j_head == journal->j_tail); J_ASSERT(journal->j_tail_sequence == journal->j_transaction_sequence); unlock_kernel(); return err; } /* * Wipe out all of the contents of a journal, safely. This will produce * a warning if the journal contains any valid recovery information. * Must be called between journal_init_*() and journal_load(). * * If (write) is non-zero, then we wipe out the journal on disk; otherwise * we merely suppress recovery. */ int journal_wipe (journal_t *journal, int write) { journal_superblock_t *sb; int err = 0; J_ASSERT (!(journal->j_flags & JFS_LOADED)); err = load_superblock(journal); if (err) return err; sb = journal->j_superblock; if (!journal->j_tail) goto no_recovery; printk (KERN_WARNING "JBD: %s recovery information on journal\n", write ? "Clearing" : "Ignoring"); err = journal_skip_recovery(journal); if (write) journal_update_superblock(journal, 1); no_recovery: return err; } /* * journal_dev_name: format a character string to describe on what * device this journal is present. */ const char * journal_dev_name(journal_t *journal) { struct block_device *bdev; if (journal->j_inode) bdev = journal->j_inode->i_sb->s_bdev; else bdev = journal->j_dev; return bdevname(bdev); } /* * journal_abort: perform a complete, immediate shutdown of the ENTIRE * journal (not of a single transaction). This operation cannot be * undone without closing and reopening the journal. * * The journal_abort function is intended to support higher level error * recovery mechanisms such as the ext2/ext3 remount-readonly error * mode. * * Journal abort has very specific semantics. Any existing dirty, * unjournaled buffers in the main filesystem will still be written to * disk by bdflush, but the journaling mechanism will be suspended * immediately and no further transaction commits will be honoured. * * Any dirty, journaled buffers will be written back to disk without * hitting the journal. Atomicity cannot be guaranteed on an aborted * filesystem, but we _do_ attempt to leave as much data as possible * behind for fsck to use for cleanup. * * Any attempt to get a new transaction handle on a journal which is in * ABORT state will just result in an -EROFS error return. A * journal_stop on an existing handle will return -EIO if we have * entered abort state during the update. * * Recursive transactions are not disturbed by journal abort until the * final journal_stop, which will receive the -EIO error. * * Finally, the journal_abort call allows the caller to supply an errno * which will be recored (if possible) in the journal superblock. This * allows a client to record failure conditions in the middle of a * transaction without having to complete the transaction to record the * failure to disk. ext3_error, for example, now uses this * functionality. * * Errors which originate from within the journaling layer will NOT * supply an errno; a null errno implies that absolutely no further * writes are done to the journal (unless there are any already in * progress). */ /* Quick version for internal journal use (doesn't lock the journal). * Aborts hard --- we mark the abort as occurred, but do _nothing_ else, * and don't attempt to make any other journal updates. */ void __journal_abort_hard (journal_t *journal) { transaction_t *transaction; if (journal->j_flags & JFS_ABORT) return; printk (KERN_ERR "Aborting journal on device %s.\n", journal_dev_name(journal)); journal->j_flags |= JFS_ABORT; transaction = journal->j_running_transaction; if (transaction) log_start_commit(journal, transaction); } /* Soft abort: record the abort error status in the journal superblock, * but don't do any other IO. */ void __journal_abort_soft (journal_t *journal, int errno) { if (journal->j_flags & JFS_ABORT) return; if (!journal->j_errno) journal->j_errno = errno; __journal_abort_hard(journal); if (errno) journal_update_superblock(journal, 1); } /* Full version for external use */ void journal_abort (journal_t *journal, int errno) { lock_journal(journal); __journal_abort_soft(journal, errno); unlock_journal(journal); } int journal_errno (journal_t *journal) { int err; lock_journal(journal); if (journal->j_flags & JFS_ABORT) err = -EROFS; else err = journal->j_errno; unlock_journal(journal); return err; } int journal_clear_err (journal_t *journal) { int err = 0; lock_journal(journal); if (journal->j_flags & JFS_ABORT) err = -EROFS; else journal->j_errno = 0; unlock_journal(journal); return err; } void journal_ack_err (journal_t *journal) { lock_journal(journal); if (journal->j_errno) journal->j_flags |= JFS_ACK_ERR; unlock_journal(journal); } int journal_blocks_per_page(struct inode *inode) { return 1 << (PAGE_CACHE_SHIFT - inode->i_sb->s_blocksize_bits); } /* * shrink_journal_memory(). * Called when we're under memory pressure. Free up all the written-back * checkpointed metadata buffers. */ void shrink_journal_memory(void) { struct list_head *list; lock_kernel(); list_for_each(list, &all_journals) { journal_t *journal = list_entry(list, journal_t, j_all_journals); spin_lock(&journal_datalist_lock); __journal_clean_checkpoint_list(journal); spin_unlock(&journal_datalist_lock); } unlock_kernel(); } /* * Simple support for retying memory allocations. Introduced to help to * debug different VM deadlock avoidance strategies. */ /* * Simple support for retying memory allocations. Introduced to help to * debug different VM deadlock avoidance strategies. */ void * __jbd_kmalloc (const char *where, size_t size, int flags, int retry) { void *p; static unsigned long last_warning; while (1) { p = kmalloc(size, flags); if (p) return p; if (!retry) return NULL; /* Log every retry for debugging. Also log them to the * syslog, but do rate-limiting on the non-debugging * messages. */ jbd_debug(1, "ENOMEM in %s, retrying.\n", where); if (time_after(jiffies, last_warning + 5*HZ)) { printk(KERN_NOTICE "ENOMEM in %s, retrying.\n", where); last_warning = jiffies; } yield(); } } /* * Journal_head storage management */ static kmem_cache_t *journal_head_cache; #ifdef CONFIG_JBD_DEBUG static atomic_t nr_journal_heads = ATOMIC_INIT(0); #endif static int journal_init_journal_head_cache(void) { int retval; J_ASSERT(journal_head_cache == 0); journal_head_cache = kmem_cache_create("journal_head", sizeof(struct journal_head), 0, /* offset */ 0, /* flags */ NULL, /* ctor */ NULL); /* dtor */ retval = 0; if (journal_head_cache == 0) { retval = -ENOMEM; printk(KERN_EMERG "JBD: no memory for journal_head cache\n"); } return retval; } static void journal_destroy_journal_head_cache(void) { J_ASSERT(journal_head_cache != NULL); kmem_cache_destroy(journal_head_cache); journal_head_cache = 0; } /* * journal_head splicing and dicing */ static struct journal_head *journal_alloc_journal_head(void) { struct journal_head *ret; static unsigned long last_warning; #ifdef CONFIG_JBD_DEBUG atomic_inc(&nr_journal_heads); #endif ret = kmem_cache_alloc(journal_head_cache, GFP_NOFS); if (ret == 0) { jbd_debug(1, "out of memory for journal_head\n"); if (time_after(jiffies, last_warning + 5*HZ)) { printk(KERN_NOTICE "ENOMEM in %s, retrying.\n", __FUNCTION__); last_warning = jiffies; } while (ret == 0) { yield(); ret = kmem_cache_alloc(journal_head_cache, GFP_NOFS); } } return ret; } static void journal_free_journal_head(struct journal_head *jh) { #ifdef CONFIG_JBD_DEBUG atomic_dec(&nr_journal_heads); memset(jh, 0x5b, sizeof(*jh)); #endif kmem_cache_free(journal_head_cache, jh); } /* * A journal_head is attached to a buffer_head whenever JBD has an * interest in the buffer. * * Whenever a buffer has an attached journal_head, its ->b_state:BH_JBD bit * is set. This bit is tested in core kernel code where we need to take * JBD-specific actions. Testing the zeroness of ->b_private is not reliable * there. * * When a buffer has its BH_JBD bit set, its ->b_count is elevated by one. * * When a buffer has its BH_JBD bit set it is immune from being released by * core kernel code, mainly via ->b_count. * * A journal_head may be detached from its buffer_head when the journal_head's * b_transaction, b_cp_transaction and b_next_transaction pointers are NULL. * Various places in JBD call journal_remove_journal_head() to indicate that the * journal_head can be dropped if needed. * * Various places in the kernel want to attach a journal_head to a buffer_head * _before_ attaching the journal_head to a transaction. To protect the * journal_head in this situation, journal_add_journal_head elevates the * journal_head's b_jcount refcount by one. The caller must call * journal_unlock_journal_head() to undo this. * * So the typical usage would be: * * (Attach a journal_head if needed. Increments b_jcount) * struct journal_head *jh = journal_add_journal_head(bh); * ... * jh->b_transaction = xxx; * journal_unlock_journal_head(jh); * * Now, the journal_head's b_jcount is zero, but it is safe from being released * because it has a non-zero b_transaction. */ /* * Give a buffer_head a journal_head. * * Doesn't need the journal lock. * May sleep. * Cannot be called with journal_datalist_lock held. */ struct journal_head *journal_add_journal_head(struct buffer_head *bh) { struct journal_head *jh; spin_lock(&journal_datalist_lock); if (buffer_jbd(bh)) { jh = bh2jh(bh); } else { J_ASSERT_BH(bh, (atomic_read(&bh->b_count) > 0) || (bh->b_page && bh->b_page->mapping)); spin_unlock(&journal_datalist_lock); jh = journal_alloc_journal_head(); memset(jh, 0, sizeof(*jh)); spin_lock(&journal_datalist_lock); if (buffer_jbd(bh)) { /* Someone did it for us! */ J_ASSERT_BH(bh, bh->b_private != NULL); journal_free_journal_head(jh); jh = bh->b_private; } else { /* * We actually don't need jh_splice_lock when * adding a journal_head - only on removal. */ spin_lock(&jh_splice_lock); set_bit(BH_JBD, &bh->b_state); bh->b_private = jh; jh->b_bh = bh; atomic_inc(&bh->b_count); spin_unlock(&jh_splice_lock); BUFFER_TRACE(bh, "added journal_head"); } } jh->b_jcount++; spin_unlock(&journal_datalist_lock); return bh->b_private; } /* * journal_remove_journal_head(): if the buffer isn't attached to a transaction * and has a zero b_jcount then remove and release its journal_head. If we did * see that the buffer is not used by any transaction we also "logically" * decrement ->b_count. * * We in fact take an additional increment on ->b_count as a convenience, * because the caller usually wants to do additional things with the bh * after calling here. * The caller of journal_remove_journal_head() *must* run __brelse(bh) at some * time. Once the caller has run __brelse(), the buffer is eligible for * reaping by try_to_free_buffers(). * * Requires journal_datalist_lock. */ void __journal_remove_journal_head(struct buffer_head *bh) { struct journal_head *jh = bh2jh(bh); assert_spin_locked(&journal_datalist_lock); J_ASSERT_JH(jh, jh->b_jcount >= 0); atomic_inc(&bh->b_count); if (jh->b_jcount == 0) { if (jh->b_transaction == NULL && jh->b_next_transaction == NULL && jh->b_cp_transaction == NULL) { J_ASSERT_BH(bh, buffer_jbd(bh)); J_ASSERT_BH(bh, jh2bh(jh) == bh); BUFFER_TRACE(bh, "remove journal_head"); spin_lock(&jh_splice_lock); bh->b_private = NULL; jh->b_bh = NULL; /* debug, really */ clear_bit(BH_JBD, &bh->b_state); __brelse(bh); spin_unlock(&jh_splice_lock); journal_free_journal_head(jh); } else { BUFFER_TRACE(bh, "journal_head was locked"); } } } void journal_unlock_journal_head(struct journal_head *jh) { spin_lock(&journal_datalist_lock); J_ASSERT_JH(jh, jh->b_jcount > 0); --jh->b_jcount; if (!jh->b_jcount && !jh->b_transaction) { struct buffer_head *bh; bh = jh2bh(jh); __journal_remove_journal_head(bh); __brelse(bh); } spin_unlock(&journal_datalist_lock); } void journal_remove_journal_head(struct buffer_head *bh) { spin_lock(&journal_datalist_lock); __journal_remove_journal_head(bh); spin_unlock(&journal_datalist_lock); } /* * /proc tunables */ #if defined(CONFIG_JBD_DEBUG) int journal_enable_debug; EXPORT_SYMBOL(journal_enable_debug); #endif #if defined(CONFIG_JBD_DEBUG) && defined(CONFIG_PROC_FS) static struct proc_dir_entry *proc_jbd_debug; int read_jbd_debug(char *page, char **start, off_t off, int count, int *eof, void *data) { int ret; ret = sprintf(page + off, "%d\n", journal_enable_debug); *eof = 1; return ret; } int write_jbd_debug(struct file *file, const char *buffer, unsigned long count, void *data) { char buf[32]; if (count > ARRAY_SIZE(buf) - 1) count = ARRAY_SIZE(buf) - 1; if (copy_from_user(buf, buffer, count)) return -EFAULT; buf[ARRAY_SIZE(buf) - 1] = '\0'; journal_enable_debug = simple_strtoul(buf, NULL, 10); return count; } #define JBD_PROC_NAME "sys/fs/jbd-debug" static void __init create_jbd_proc_entry(void) { proc_jbd_debug = create_proc_entry(JBD_PROC_NAME, 0644, NULL); if (proc_jbd_debug) { /* Why is this so hard? */ proc_jbd_debug->read_proc = read_jbd_debug; proc_jbd_debug->write_proc = write_jbd_debug; } } static void __exit remove_jbd_proc_entry(void) { if (proc_jbd_debug) remove_proc_entry(JBD_PROC_NAME, NULL); } #else #define create_jbd_proc_entry() do {} while (0) #define remove_jbd_proc_entry() do {} while (0) #endif /* * Module startup and shutdown */ static int __init journal_init_caches(void) { int ret; ret = journal_init_revoke_caches(); if (ret == 0) ret = journal_init_journal_head_cache(); return ret; } static void journal_destroy_caches(void) { journal_destroy_revoke_caches(); journal_destroy_journal_head_cache(); } static int __init journal_init(void) { int ret; printk(KERN_INFO "Journalled Block Device driver loaded\n"); ret = journal_init_caches(); if (ret != 0) journal_destroy_caches(); create_jbd_proc_entry(); return ret; } static void __exit journal_exit(void) { #ifdef CONFIG_JBD_DEBUG int n = atomic_read(&nr_journal_heads); if (n) printk(KERN_EMERG "JBD: leaked %d journal_heads!\n", n); #endif remove_jbd_proc_entry(); journal_destroy_caches(); } MODULE_LICENSE("GPL"); module_init(journal_init); module_exit(journal_exit); |