/* * Copyright (c) 2000-2005 Silicon Graphics, Inc. * All Rights Reserved. * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation. * * This program is distributed in the hope that it would be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include "xfs.h" #include "xfs_fs.h" #include "xfs_types.h" #include "xfs_bit.h" #include "xfs_log.h" #include "xfs_inum.h" #include "xfs_trans.h" #include "xfs_sb.h" #include "xfs_ag.h" #include "xfs_mount.h" #include "xfs_bmap_btree.h" #include "xfs_inode.h" #include "xfs_dinode.h" #include "xfs_error.h" #include "xfs_filestream.h" #include "xfs_vnodeops.h" #include "xfs_inode_item.h" #include "xfs_quota.h" #include "xfs_trace.h" #include #include STATIC xfs_inode_t * xfs_inode_ag_lookup( struct xfs_mount *mp, struct xfs_perag *pag, uint32_t *first_index, int tag) { int nr_found; struct xfs_inode *ip; /* * use a gang lookup to find the next inode in the tree * as the tree is sparse and a gang lookup walks to find * the number of objects requested. */ if (tag == XFS_ICI_NO_TAG) { nr_found = radix_tree_gang_lookup(&pag->pag_ici_root, (void **)&ip, *first_index, 1); } else { nr_found = radix_tree_gang_lookup_tag(&pag->pag_ici_root, (void **)&ip, *first_index, 1, tag); } if (!nr_found) return NULL; /* * Update the index for the next lookup. Catch overflows * into the next AG range which can occur if we have inodes * in the last block of the AG and we are currently * pointing to the last inode. */ *first_index = XFS_INO_TO_AGINO(mp, ip->i_ino + 1); if (*first_index < XFS_INO_TO_AGINO(mp, ip->i_ino)) return NULL; return ip; } STATIC int xfs_inode_ag_walk( struct xfs_mount *mp, struct xfs_perag *pag, int (*execute)(struct xfs_inode *ip, struct xfs_perag *pag, int flags), int flags, int tag, int exclusive, int *nr_to_scan) { uint32_t first_index; int last_error = 0; int skipped; restart: skipped = 0; first_index = 0; do { int error = 0; xfs_inode_t *ip; if (exclusive) write_lock(&pag->pag_ici_lock); else read_lock(&pag->pag_ici_lock); ip = xfs_inode_ag_lookup(mp, pag, &first_index, tag); if (!ip) { if (exclusive) write_unlock(&pag->pag_ici_lock); else read_unlock(&pag->pag_ici_lock); break; } /* execute releases pag->pag_ici_lock */ error = execute(ip, pag, flags); if (error == EAGAIN) { skipped++; continue; } if (error) last_error = error; /* bail out if the filesystem is corrupted. */ if (error == EFSCORRUPTED) break; } while ((*nr_to_scan)--); if (skipped) { delay(1); goto restart; } return last_error; } /* * Select the next per-ag structure to iterate during the walk. The reclaim * walk is optimised only to walk AGs with reclaimable inodes in them. */ static struct xfs_perag * xfs_inode_ag_iter_next_pag( struct xfs_mount *mp, xfs_agnumber_t *first, int tag) { struct xfs_perag *pag = NULL; if (tag == XFS_ICI_RECLAIM_TAG) { int found; int ref; spin_lock(&mp->m_perag_lock); found = radix_tree_gang_lookup_tag(&mp->m_perag_tree, (void **)&pag, *first, 1, tag); if (found <= 0) { spin_unlock(&mp->m_perag_lock); return NULL; } *first = pag->pag_agno + 1; /* open coded pag reference increment */ ref = atomic_inc_return(&pag->pag_ref); spin_unlock(&mp->m_perag_lock); trace_xfs_perag_get_reclaim(mp, pag->pag_agno, ref, _RET_IP_); } else { pag = xfs_perag_get(mp, *first); (*first)++; } return pag; } int xfs_inode_ag_iterator( struct xfs_mount *mp, int (*execute)(struct xfs_inode *ip, struct xfs_perag *pag, int flags), int flags, int tag, int exclusive, int *nr_to_scan) { struct xfs_perag *pag; int error = 0; int last_error = 0; xfs_agnumber_t ag; int nr; nr = nr_to_scan ? *nr_to_scan : INT_MAX; ag = 0; while ((pag = xfs_inode_ag_iter_next_pag(mp, &ag, tag))) { error = xfs_inode_ag_walk(mp, pag, execute, flags, tag, exclusive, &nr); xfs_perag_put(pag); if (error) { last_error = error; if (error == EFSCORRUPTED) break; } if (nr <= 0) break; } if (nr_to_scan) *nr_to_scan = nr; return XFS_ERROR(last_error); } /* must be called with pag_ici_lock held and releases it */ int xfs_sync_inode_valid( struct xfs_inode *ip, struct xfs_perag *pag) { struct inode *inode = VFS_I(ip); int error = EFSCORRUPTED; /* nothing to sync during shutdown */ if (XFS_FORCED_SHUTDOWN(ip->i_mount)) goto out_unlock; /* avoid new or reclaimable inodes. Leave for reclaim code to flush */ error = ENOENT; if (xfs_iflags_test(ip, XFS_INEW | XFS_IRECLAIMABLE | XFS_IRECLAIM)) goto out_unlock; /* If we can't grab the inode, it must on it's way to reclaim. */ if (!igrab(inode)) goto out_unlock; if (is_bad_inode(inode)) { IRELE(ip); goto out_unlock; } /* inode is valid */ error = 0; out_unlock: read_unlock(&pag->pag_ici_lock); return error; } STATIC int xfs_sync_inode_data( struct xfs_inode *ip, struct xfs_perag *pag, int flags) { struct inode *inode = VFS_I(ip); struct address_space *mapping = inode->i_mapping; int error = 0; error = xfs_sync_inode_valid(ip, pag); if (error) return error; if (!mapping_tagged(mapping, PAGECACHE_TAG_DIRTY)) goto out_wait; if (!xfs_ilock_nowait(ip, XFS_IOLOCK_SHARED)) { if (flags & SYNC_TRYLOCK) goto out_wait; xfs_ilock(ip, XFS_IOLOCK_SHARED); } error = xfs_flush_pages(ip, 0, -1, (flags & SYNC_WAIT) ? 0 : XBF_ASYNC, FI_NONE); xfs_iunlock(ip, XFS_IOLOCK_SHARED); out_wait: if (flags & SYNC_WAIT) xfs_ioend_wait(ip); IRELE(ip); return error; } STATIC int xfs_sync_inode_attr( struct xfs_inode *ip, struct xfs_perag *pag, int flags) { int error = 0; error = xfs_sync_inode_valid(ip, pag); if (error) return error; xfs_ilock(ip, XFS_ILOCK_SHARED); if (xfs_inode_clean(ip)) goto out_unlock; if (!xfs_iflock_nowait(ip)) { if (!(flags & SYNC_WAIT)) goto out_unlock; xfs_iflock(ip); } if (xfs_inode_clean(ip)) { xfs_ifunlock(ip); goto out_unlock; } error = xfs_iflush(ip, flags); out_unlock: xfs_iunlock(ip, XFS_ILOCK_SHARED); IRELE(ip); return error; } /* * Write out pagecache data for the whole filesystem. */ int xfs_sync_data( struct xfs_mount *mp, int flags) { int error; ASSERT((flags & ~(SYNC_TRYLOCK|SYNC_WAIT)) == 0); error = xfs_inode_ag_iterator(mp, xfs_sync_inode_data, flags, XFS_ICI_NO_TAG, 0, NULL); if (error) return XFS_ERROR(error); xfs_log_force(mp, (flags & SYNC_WAIT) ? XFS_LOG_SYNC : 0); return 0; } /* * Write out inode metadata (attributes) for the whole filesystem. */ int xfs_sync_attr( struct xfs_mount *mp, int flags) { ASSERT((flags & ~SYNC_WAIT) == 0); return xfs_inode_ag_iterator(mp, xfs_sync_inode_attr, flags, XFS_ICI_NO_TAG, 0, NULL); } STATIC int xfs_commit_dummy_trans( struct xfs_mount *mp, uint flags) { struct xfs_inode *ip = mp->m_rootip; struct xfs_trans *tp; int error; /* * Put a dummy transaction in the log to tell recovery * that all others are OK. */ tp = xfs_trans_alloc(mp, XFS_TRANS_DUMMY1); error = xfs_trans_reserve(tp, 0, XFS_ICHANGE_LOG_RES(mp), 0, 0, 0); if (error) { xfs_trans_cancel(tp, 0); return error; } xfs_ilock(ip, XFS_ILOCK_EXCL); xfs_trans_ijoin(tp, ip); xfs_trans_log_inode(tp, ip, XFS_ILOG_CORE); error = xfs_trans_commit(tp, 0); xfs_iunlock(ip, XFS_ILOCK_EXCL); /* the log force ensures this transaction is pushed to disk */ xfs_log_force(mp, (flags & SYNC_WAIT) ? XFS_LOG_SYNC : 0); return error; } STATIC int xfs_sync_fsdata( struct xfs_mount *mp) { struct xfs_buf *bp; /* * If the buffer is pinned then push on the log so we won't get stuck * waiting in the write for someone, maybe ourselves, to flush the log. * * Even though we just pushed the log above, we did not have the * superblock buffer locked at that point so it can become pinned in * between there and here. */ bp = xfs_getsb(mp, 0); if (XFS_BUF_ISPINNED(bp)) xfs_log_force(mp, 0); return xfs_bwrite(mp, bp); } /* * When remounting a filesystem read-only or freezing the filesystem, we have * two phases to execute. This first phase is syncing the data before we * quiesce the filesystem, and the second is flushing all the inodes out after * we've waited for all the transactions created by the first phase to * complete. The second phase ensures that the inodes are written to their * location on disk rather than just existing in transactions in the log. This * means after a quiesce there is no log replay required to write the inodes to * disk (this is the main difference between a sync and a quiesce). */ /* * First stage of freeze - no writers will make progress now we are here, * so we flush delwri and delalloc buffers here, then wait for all I/O to * complete. Data is frozen at that point. Metadata is not frozen, * transactions can still occur here so don't bother flushing the buftarg * because it'll just get dirty again. */ int xfs_quiesce_data( struct xfs_mount *mp) { int error, error2 = 0; /* push non-blocking */ xfs_sync_data(mp, 0); xfs_qm_sync(mp, SYNC_TRYLOCK); /* push and block till complete */ xfs_sync_data(mp, SYNC_WAIT); xfs_qm_sync(mp, SYNC_WAIT); /* write superblock and hoover up shutdown errors */ error = xfs_sync_fsdata(mp); /* make sure all delwri buffers are written out */ xfs_flush_buftarg(mp->m_ddev_targp, 1); /* mark the log as covered if needed */ if (xfs_log_need_covered(mp)) error2 = xfs_commit_dummy_trans(mp, SYNC_WAIT); /* flush data-only devices */ if (mp->m_rtdev_targp) XFS_bflush(mp->m_rtdev_targp); return error ? error : error2; } STATIC void xfs_quiesce_fs( struct xfs_mount *mp) { int count = 0, pincount; xfs_reclaim_inodes(mp, 0); xfs_flush_buftarg(mp->m_ddev_targp, 0); /* * This loop must run at least twice. The first instance of the loop * will flush most meta data but that will generate more meta data * (typically directory updates). Which then must be flushed and * logged before we can write the unmount record. We also so sync * reclaim of inodes to catch any that the above delwri flush skipped. */ do { xfs_reclaim_inodes(mp, SYNC_WAIT); xfs_sync_attr(mp, SYNC_WAIT); pincount = xfs_flush_buftarg(mp->m_ddev_targp, 1); if (!pincount) { delay(50); count++; } } while (count < 2); } /* * Second stage of a quiesce. The data is already synced, now we have to take * care of the metadata. New transactions are already blocked, so we need to * wait for any remaining transactions to drain out before proceding. */ void xfs_quiesce_attr( struct xfs_mount *mp) { int error = 0; /* wait for all modifications to complete */ while (atomic_read(&mp->m_active_trans) > 0) delay(100); /* flush inodes and push all remaining buffers out to disk */ xfs_quiesce_fs(mp); /* * Just warn here till VFS can correctly support * read-only remount without racing. */ WARN_ON(atomic_read(&mp->m_active_trans) != 0); /* Push the superblock and write an unmount record */ error = xfs_log_sbcount(mp, 1); if (error) xfs_fs_cmn_err(CE_WARN, mp, "xfs_attr_quiesce: failed to log sb changes. " "Frozen image may not be consistent."); xfs_log_unmount_write(mp); xfs_unmountfs_writesb(mp); } /* * Enqueue a work item to be picked up by the vfs xfssyncd thread. * Doing this has two advantages: * - It saves on stack space, which is tight in certain situations * - It can be used (with care) as a mechanism to avoid deadlocks. * Flushing while allocating in a full filesystem requires both. */ STATIC void xfs_syncd_queue_work( struct xfs_mount *mp, void *data, void (*syncer)(struct xfs_mount *, void *), struct completion *completion) { struct xfs_sync_work *work; work = kmem_alloc(sizeof(struct xfs_sync_work), KM_SLEEP); INIT_LIST_HEAD(&work->w_list); work->w_syncer = syncer; work->w_data = data; work->w_mount = mp; work->w_completion = completion; spin_lock(&mp->m_sync_lock); list_add_tail(&work->w_list, &mp->m_sync_list); spin_unlock(&mp->m_sync_lock); wake_up_process(mp->m_sync_task); } /* * Flush delayed allocate data, attempting to free up reserved space * from existing allocations. At this point a new allocation attempt * has failed with ENOSPC and we are in the process of scratching our * heads, looking about for more room... */ STATIC void xfs_flush_inodes_work( struct xfs_mount *mp, void *arg) { struct inode *inode = arg; xfs_sync_data(mp, SYNC_TRYLOCK); xfs_sync_data(mp, SYNC_TRYLOCK | SYNC_WAIT); iput(inode); } void xfs_flush_inodes( xfs_inode_t *ip) { struct inode *inode = VFS_I(ip); DECLARE_COMPLETION_ONSTACK(completion); igrab(inode); xfs_syncd_queue_work(ip->i_mount, inode, xfs_flush_inodes_work, &completion); wait_for_completion(&completion); xfs_log_force(ip->i_mount, XFS_LOG_SYNC); } /* * Every sync period we need to unpin all items, reclaim inodes and sync * disk quotas. We might need to cover the log to indicate that the * filesystem is idle. */ STATIC void xfs_sync_worker( struct xfs_mount *mp, void *unused) { int error; if (!(mp->m_flags & XFS_MOUNT_RDONLY)) { xfs_log_force(mp, 0); xfs_reclaim_inodes(mp, 0); /* dgc: errors ignored here */ error = xfs_qm_sync(mp, SYNC_TRYLOCK); if (xfs_log_need_covered(mp)) error = xfs_commit_dummy_trans(mp, 0); } mp->m_sync_seq++; wake_up(&mp->m_wait_single_sync_task); } STATIC int xfssyncd( void *arg) { struct xfs_mount *mp = arg; long timeleft; xfs_sync_work_t *work, *n; LIST_HEAD (tmp); set_freezable(); timeleft = xfs_syncd_centisecs * msecs_to_jiffies(10); for (;;) { if (list_empty(&mp->m_sync_list)) timeleft = schedule_timeout_interruptible(timeleft); /* swsusp */ try_to_freeze(); if (kthread_should_stop() && list_empty(&mp->m_sync_list)) break; spin_lock(&mp->m_sync_lock); /* * We can get woken by laptop mode, to do a sync - * that's the (only!) case where the list would be * empty with time remaining. */ if (!timeleft || list_empty(&mp->m_sync_list)) { if (!timeleft) timeleft = xfs_syncd_centisecs * msecs_to_jiffies(10); INIT_LIST_HEAD(&mp->m_sync_work.w_list); list_add_tail(&mp->m_sync_work.w_list, &mp->m_sync_list); } list_splice_init(&mp->m_sync_list, &tmp); spin_unlock(&mp->m_sync_lock); list_for_each_entry_safe(work, n, &tmp, w_list) { (*work->w_syncer)(mp, work->w_data); list_del(&work->w_list); if (work == &mp->m_sync_work) continue; if (work->w_completion) complete(work->w_completion); kmem_free(work); } } return 0; } int xfs_syncd_init( struct xfs_mount *mp) { mp->m_sync_work.w_syncer = xfs_sync_worker; mp->m_sync_work.w_mount = mp; mp->m_sync_work.w_completion = NULL; mp->m_sync_task = kthread_run(xfssyncd, mp, "xfssyncd/%s", mp->m_fsname); if (IS_ERR(mp->m_sync_task)) return -PTR_ERR(mp->m_sync_task); return 0; } void xfs_syncd_stop( struct xfs_mount *mp) { kthread_stop(mp->m_sync_task); } void __xfs_inode_set_reclaim_tag( struct xfs_perag *pag, struct xfs_inode *ip) { radix_tree_tag_set(&pag->pag_ici_root, XFS_INO_TO_AGINO(ip->i_mount, ip->i_ino), XFS_ICI_RECLAIM_TAG); if (!pag->pag_ici_reclaimable) { /* propagate the reclaim tag up into the perag radix tree */ spin_lock(&ip->i_mount->m_perag_lock); radix_tree_tag_set(&ip->i_mount->m_perag_tree, XFS_INO_TO_AGNO(ip->i_mount, ip->i_ino), XFS_ICI_RECLAIM_TAG); spin_unlock(&ip->i_mount->m_perag_lock); trace_xfs_perag_set_reclaim(ip->i_mount, pag->pag_agno, -1, _RET_IP_); } pag->pag_ici_reclaimable++; } /* * We set the inode flag atomically with the radix tree tag. * Once we get tag lookups on the radix tree, this inode flag * can go away. */ void xfs_inode_set_reclaim_tag( xfs_inode_t *ip) { struct xfs_mount *mp = ip->i_mount; struct xfs_perag *pag; pag = xfs_perag_get(mp, XFS_INO_TO_AGNO(mp, ip->i_ino)); write_lock(&pag->pag_ici_lock); spin_lock(&ip->i_flags_lock); __xfs_inode_set_reclaim_tag(pag, ip); __xfs_iflags_set(ip, XFS_IRECLAIMABLE); spin_unlock(&ip->i_flags_lock); write_unlock(&pag->pag_ici_lock); xfs_perag_put(pag); } void __xfs_inode_clear_reclaim_tag( xfs_mount_t *mp, xfs_perag_t *pag, xfs_inode_t *ip) { radix_tree_tag_clear(&pag->pag_ici_root, XFS_INO_TO_AGINO(mp, ip->i_ino), XFS_ICI_RECLAIM_TAG); pag->pag_ici_reclaimable--; if (!pag->pag_ici_reclaimable) { /* clear the reclaim tag from the perag radix tree */ spin_lock(&ip->i_mount->m_perag_lock); radix_tree_tag_clear(&ip->i_mount->m_perag_tree, XFS_INO_TO_AGNO(ip->i_mount, ip->i_ino), XFS_ICI_RECLAIM_TAG); spin_unlock(&ip->i_mount->m_perag_lock); trace_xfs_perag_clear_reclaim(ip->i_mount, pag->pag_agno, -1, _RET_IP_); } } /* * Inodes in different states need to be treated differently, and the return * value of xfs_iflush is not sufficient to get this right. The following table * lists the inode states and the reclaim actions necessary for non-blocking * reclaim: * * * inode state iflush ret required action * --------------- ---------- --------------- * bad - reclaim * shutdown EIO unpin and reclaim * clean, unpinned 0 reclaim * stale, unpinned 0 reclaim * clean, pinned(*) 0 requeue * stale, pinned EAGAIN requeue * dirty, delwri ok 0 requeue * dirty, delwri blocked EAGAIN requeue * dirty, sync flush 0 reclaim * * (*) dgc: I don't think the clean, pinned state is possible but it gets * handled anyway given the order of checks implemented. * * As can be seen from the table, the return value of xfs_iflush() is not * sufficient to correctly decide the reclaim action here. The checks in * xfs_iflush() might look like duplicates, but they are not. * * Also, because we get the flush lock first, we know that any inode that has * been flushed delwri has had the flush completed by the time we check that * the inode is clean. The clean inode check needs to be done before flushing * the inode delwri otherwise we would loop forever requeuing clean inodes as * we cannot tell apart a successful delwri flush and a clean inode from the * return value of xfs_iflush(). * * Note that because the inode is flushed delayed write by background * writeback, the flush lock may already be held here and waiting on it can * result in very long latencies. Hence for sync reclaims, where we wait on the * flush lock, the caller should push out delayed write inodes first before * trying to reclaim them to minimise the amount of time spent waiting. For * background relaim, we just requeue the inode for the next pass. * * Hence the order of actions after gaining the locks should be: * bad => reclaim * shutdown => unpin and reclaim * pinned, delwri => requeue * pinned, sync => unpin * stale => reclaim * clean => reclaim * dirty, delwri => flush and requeue * dirty, sync => flush, wait and reclaim */ STATIC int xfs_reclaim_inode( struct xfs_inode *ip, struct xfs_perag *pag, int sync_mode) { int error = 0; /* * The radix tree lock here protects a thread in xfs_iget from racing * with us starting reclaim on the inode. Once we have the * XFS_IRECLAIM flag set it will not touch us. */ spin_lock(&ip->i_flags_lock); ASSERT_ALWAYS(__xfs_iflags_test(ip, XFS_IRECLAIMABLE)); if (__xfs_iflags_test(ip, XFS_IRECLAIM)) { /* ignore as it is already under reclaim */ spin_unlock(&ip->i_flags_lock); write_unlock(&pag->pag_ici_lock); return 0; } __xfs_iflags_set(ip, XFS_IRECLAIM); spin_unlock(&ip->i_flags_lock); write_unlock(&pag->pag_ici_lock); xfs_ilock(ip, XFS_ILOCK_EXCL); if (!xfs_iflock_nowait(ip)) { if (!(sync_mode & SYNC_WAIT)) goto out; xfs_iflock(ip); } if (is_bad_inode(VFS_I(ip))) goto reclaim; if (XFS_FORCED_SHUTDOWN(ip->i_mount)) { xfs_iunpin_wait(ip); goto reclaim; } if (xfs_ipincount(ip)) { if (!(sync_mode & SYNC_WAIT)) { xfs_ifunlock(ip); goto out; } xfs_iunpin_wait(ip); } if (xfs_iflags_test(ip, XFS_ISTALE)) goto reclaim; if (xfs_inode_clean(ip)) goto reclaim; /* Now we have an inode that needs flushing */ error = xfs_iflush(ip, sync_mode); if (sync_mode & SYNC_WAIT) { xfs_iflock(ip); goto reclaim; } /* * When we have to flush an inode but don't have SYNC_WAIT set, we * flush the inode out using a delwri buffer and wait for the next * call into reclaim to find it in a clean state instead of waiting for * it now. We also don't return errors here - if the error is transient * then the next reclaim pass will flush the inode, and if the error * is permanent then the next sync reclaim will reclaim the inode and * pass on the error. */ if (error && error != EAGAIN && !XFS_FORCED_SHUTDOWN(ip->i_mount)) { xfs_fs_cmn_err(CE_WARN, ip->i_mount, "inode 0x%llx background reclaim flush failed with %d", (long long)ip->i_ino, error); } out: xfs_iflags_clear(ip, XFS_IRECLAIM); xfs_iunlock(ip, XFS_ILOCK_EXCL); /* * We could return EAGAIN here to make reclaim rescan the inode tree in * a short while. However, this just burns CPU time scanning the tree * waiting for IO to complete and xfssyncd never goes back to the idle * state. Instead, return 0 to let the next scheduled background reclaim * attempt to reclaim the inode again. */ return 0; reclaim: xfs_ifunlock(ip); xfs_iunlock(ip, XFS_ILOCK_EXCL); xfs_ireclaim(ip); return error; } int xfs_reclaim_inodes( xfs_mount_t *mp, int mode) { return xfs_inode_ag_iterator(mp, xfs_reclaim_inode, mode, XFS_ICI_RECLAIM_TAG, 1, NULL); } /* * Shrinker infrastructure. */ static int xfs_reclaim_inode_shrink( struct shrinker *shrink, int nr_to_scan, gfp_t gfp_mask) { struct xfs_mount *mp; struct xfs_perag *pag; xfs_agnumber_t ag; int reclaimable; mp = container_of(shrink, struct xfs_mount, m_inode_shrink); if (nr_to_scan) { if (!(gfp_mask & __GFP_FS)) return -1; xfs_inode_ag_iterator(mp, xfs_reclaim_inode, 0, XFS_ICI_RECLAIM_TAG, 1, &nr_to_scan); /* if we don't exhaust the scan, don't bother coming back */ if (nr_to_scan > 0) return -1; } reclaimable = 0; ag = 0; while ((pag = xfs_inode_ag_iter_next_pag(mp, &ag, XFS_ICI_RECLAIM_TAG))) { reclaimable += pag->pag_ici_reclaimable; xfs_perag_put(pag); } return reclaimable; } void xfs_inode_shrinker_register( struct xfs_mount *mp) { mp->m_inode_shrink.shrink = xfs_reclaim_inode_shrink; mp->m_inode_shrink.seeks = DEFAULT_SEEKS; register_shrinker(&mp->m_inode_shrink); } void xfs_inode_shrinker_unregister( struct xfs_mount *mp) { unregister_shrinker(&mp->m_inode_shrink); }