// SPDX-License-Identifier: GPL-2.0+ /* * NILFS segment constructor. * * Copyright (C) 2005-2008 Nippon Telegraph and Telephone Corporation. * * Written by Ryusuke Konishi. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "nilfs.h" #include "btnode.h" #include "page.h" #include "segment.h" #include "sufile.h" #include "cpfile.h" #include "ifile.h" #include "segbuf.h" /* * Segment constructor */ #define SC_N_INODEVEC 16 /* Size of locally allocated inode vector */ #define SC_MAX_SEGDELTA 64 /* * Upper limit of the number of segments * appended in collection retry loop */ /* Construction mode */ enum { SC_LSEG_SR = 1, /* Make a logical segment having a super root */ SC_LSEG_DSYNC, /* * Flush data blocks of a given file and make * a logical segment without a super root. */ SC_FLUSH_FILE, /* * Flush data files, leads to segment writes without * creating a checkpoint. */ SC_FLUSH_DAT, /* * Flush DAT file. This also creates segments * without a checkpoint. */ }; /* Stage numbers of dirty block collection */ enum { NILFS_ST_INIT = 0, NILFS_ST_GC, /* Collecting dirty blocks for GC */ NILFS_ST_FILE, NILFS_ST_IFILE, NILFS_ST_CPFILE, NILFS_ST_SUFILE, NILFS_ST_DAT, NILFS_ST_SR, /* Super root */ NILFS_ST_DSYNC, /* Data sync blocks */ NILFS_ST_DONE, }; #define CREATE_TRACE_POINTS #include /* * nilfs_sc_cstage_inc(), nilfs_sc_cstage_set(), nilfs_sc_cstage_get() are * wrapper functions of stage count (nilfs_sc_info->sc_stage.scnt). Users of * the variable must use them because transition of stage count must involve * trace events (trace_nilfs2_collection_stage_transition). * * nilfs_sc_cstage_get() isn't required for the above purpose because it doesn't * produce tracepoint events. It is provided just for making the intention * clear. */ static inline void nilfs_sc_cstage_inc(struct nilfs_sc_info *sci) { sci->sc_stage.scnt++; trace_nilfs2_collection_stage_transition(sci); } static inline void nilfs_sc_cstage_set(struct nilfs_sc_info *sci, int next_scnt) { sci->sc_stage.scnt = next_scnt; trace_nilfs2_collection_stage_transition(sci); } static inline int nilfs_sc_cstage_get(struct nilfs_sc_info *sci) { return sci->sc_stage.scnt; } /* State flags of collection */ #define NILFS_CF_NODE 0x0001 /* Collecting node blocks */ #define NILFS_CF_IFILE_STARTED 0x0002 /* IFILE stage has started */ #define NILFS_CF_SUFREED 0x0004 /* segment usages has been freed */ #define NILFS_CF_HISTORY_MASK (NILFS_CF_IFILE_STARTED | NILFS_CF_SUFREED) /* Operations depending on the construction mode and file type */ struct nilfs_sc_operations { int (*collect_data)(struct nilfs_sc_info *, struct buffer_head *, struct inode *); int (*collect_node)(struct nilfs_sc_info *, struct buffer_head *, struct inode *); int (*collect_bmap)(struct nilfs_sc_info *, struct buffer_head *, struct inode *); void (*write_data_binfo)(struct nilfs_sc_info *, struct nilfs_segsum_pointer *, union nilfs_binfo *); void (*write_node_binfo)(struct nilfs_sc_info *, struct nilfs_segsum_pointer *, union nilfs_binfo *); }; /* * Other definitions */ static void nilfs_segctor_start_timer(struct nilfs_sc_info *); static void nilfs_segctor_do_flush(struct nilfs_sc_info *, int); static void nilfs_segctor_do_immediate_flush(struct nilfs_sc_info *); static void nilfs_dispose_list(struct the_nilfs *, struct list_head *, int); #define nilfs_cnt32_ge(a, b) \ (typecheck(__u32, a) && typecheck(__u32, b) && \ ((__s32)((a) - (b)) >= 0)) static int nilfs_prepare_segment_lock(struct super_block *sb, struct nilfs_transaction_info *ti) { struct nilfs_transaction_info *cur_ti = current->journal_info; void *save = NULL; if (cur_ti) { if (cur_ti->ti_magic == NILFS_TI_MAGIC) return ++cur_ti->ti_count; /* * If journal_info field is occupied by other FS, * it is saved and will be restored on * nilfs_transaction_commit(). */ nilfs_warn(sb, "journal info from a different FS"); save = current->journal_info; } if (!ti) { ti = kmem_cache_alloc(nilfs_transaction_cachep, GFP_NOFS); if (!ti) return -ENOMEM; ti->ti_flags = NILFS_TI_DYNAMIC_ALLOC; } else { ti->ti_flags = 0; } ti->ti_count = 0; ti->ti_save = save; ti->ti_magic = NILFS_TI_MAGIC; current->journal_info = ti; return 0; } /** * nilfs_transaction_begin - start indivisible file operations. * @sb: super block * @ti: nilfs_transaction_info * @vacancy_check: flags for vacancy rate checks * * nilfs_transaction_begin() acquires a reader/writer semaphore, called * the segment semaphore, to make a segment construction and write tasks * exclusive. The function is used with nilfs_transaction_commit() in pairs. * The region enclosed by these two functions can be nested. To avoid a * deadlock, the semaphore is only acquired or released in the outermost call. * * This function allocates a nilfs_transaction_info struct to keep context * information on it. It is initialized and hooked onto the current task in * the outermost call. If a pre-allocated struct is given to @ti, it is used * instead; otherwise a new struct is assigned from a slab. * * When @vacancy_check flag is set, this function will check the amount of * free space, and will wait for the GC to reclaim disk space if low capacity. * * Return Value: On success, 0 is returned. On error, one of the following * negative error code is returned. * * %-ENOMEM - Insufficient memory available. * * %-ENOSPC - No space left on device */ int nilfs_transaction_begin(struct super_block *sb, struct nilfs_transaction_info *ti, int vacancy_check) { struct the_nilfs *nilfs; int ret = nilfs_prepare_segment_lock(sb, ti); struct nilfs_transaction_info *trace_ti; if (unlikely(ret < 0)) return ret; if (ret > 0) { trace_ti = current->journal_info; trace_nilfs2_transaction_transition(sb, trace_ti, trace_ti->ti_count, trace_ti->ti_flags, TRACE_NILFS2_TRANSACTION_BEGIN); return 0; } sb_start_intwrite(sb); nilfs = sb->s_fs_info; down_read(&nilfs->ns_segctor_sem); if (vacancy_check && nilfs_near_disk_full(nilfs)) { up_read(&nilfs->ns_segctor_sem); ret = -ENOSPC; goto failed; } trace_ti = current->journal_info; trace_nilfs2_transaction_transition(sb, trace_ti, trace_ti->ti_count, trace_ti->ti_flags, TRACE_NILFS2_TRANSACTION_BEGIN); return 0; failed: ti = current->journal_info; current->journal_info = ti->ti_save; if (ti->ti_flags & NILFS_TI_DYNAMIC_ALLOC) kmem_cache_free(nilfs_transaction_cachep, ti); sb_end_intwrite(sb); return ret; } /** * nilfs_transaction_commit - commit indivisible file operations. * @sb: super block * * nilfs_transaction_commit() releases the read semaphore which is * acquired by nilfs_transaction_begin(). This is only performed * in outermost call of this function. If a commit flag is set, * nilfs_transaction_commit() sets a timer to start the segment * constructor. If a sync flag is set, it starts construction * directly. */ int nilfs_transaction_commit(struct super_block *sb) { struct nilfs_transaction_info *ti = current->journal_info; struct the_nilfs *nilfs = sb->s_fs_info; int err = 0; BUG_ON(ti == NULL || ti->ti_magic != NILFS_TI_MAGIC); ti->ti_flags |= NILFS_TI_COMMIT; if (ti->ti_count > 0) { ti->ti_count--; trace_nilfs2_transaction_transition(sb, ti, ti->ti_count, ti->ti_flags, TRACE_NILFS2_TRANSACTION_COMMIT); return 0; } if (nilfs->ns_writer) { struct nilfs_sc_info *sci = nilfs->ns_writer; if (ti->ti_flags & NILFS_TI_COMMIT) nilfs_segctor_start_timer(sci); if (atomic_read(&nilfs->ns_ndirtyblks) > sci->sc_watermark) nilfs_segctor_do_flush(sci, 0); } up_read(&nilfs->ns_segctor_sem); trace_nilfs2_transaction_transition(sb, ti, ti->ti_count, ti->ti_flags, TRACE_NILFS2_TRANSACTION_COMMIT); current->journal_info = ti->ti_save; if (ti->ti_flags & NILFS_TI_SYNC) err = nilfs_construct_segment(sb); if (ti->ti_flags & NILFS_TI_DYNAMIC_ALLOC) kmem_cache_free(nilfs_transaction_cachep, ti); sb_end_intwrite(sb); return err; } void nilfs_transaction_abort(struct super_block *sb) { struct nilfs_transaction_info *ti = current->journal_info; struct the_nilfs *nilfs = sb->s_fs_info; BUG_ON(ti == NULL || ti->ti_magic != NILFS_TI_MAGIC); if (ti->ti_count > 0) { ti->ti_count--; trace_nilfs2_transaction_transition(sb, ti, ti->ti_count, ti->ti_flags, TRACE_NILFS2_TRANSACTION_ABORT); return; } up_read(&nilfs->ns_segctor_sem); trace_nilfs2_transaction_transition(sb, ti, ti->ti_count, ti->ti_flags, TRACE_NILFS2_TRANSACTION_ABORT); current->journal_info = ti->ti_save; if (ti->ti_flags & NILFS_TI_DYNAMIC_ALLOC) kmem_cache_free(nilfs_transaction_cachep, ti); sb_end_intwrite(sb); } void nilfs_relax_pressure_in_lock(struct super_block *sb) { struct the_nilfs *nilfs = sb->s_fs_info; struct nilfs_sc_info *sci = nilfs->ns_writer; if (sb_rdonly(sb) || unlikely(!sci) || !sci->sc_flush_request) return; set_bit(NILFS_SC_PRIOR_FLUSH, &sci->sc_flags); up_read(&nilfs->ns_segctor_sem); down_write(&nilfs->ns_segctor_sem); if (sci->sc_flush_request && test_bit(NILFS_SC_PRIOR_FLUSH, &sci->sc_flags)) { struct nilfs_transaction_info *ti = current->journal_info; ti->ti_flags |= NILFS_TI_WRITER; nilfs_segctor_do_immediate_flush(sci); ti->ti_flags &= ~NILFS_TI_WRITER; } downgrade_write(&nilfs->ns_segctor_sem); } static void nilfs_transaction_lock(struct super_block *sb, struct nilfs_transaction_info *ti, int gcflag) { struct nilfs_transaction_info *cur_ti = current->journal_info; struct the_nilfs *nilfs = sb->s_fs_info; struct nilfs_sc_info *sci = nilfs->ns_writer; WARN_ON(cur_ti); ti->ti_flags = NILFS_TI_WRITER; ti->ti_count = 0; ti->ti_save = cur_ti; ti->ti_magic = NILFS_TI_MAGIC; current->journal_info = ti; for (;;) { trace_nilfs2_transaction_transition(sb, ti, ti->ti_count, ti->ti_flags, TRACE_NILFS2_TRANSACTION_TRYLOCK); down_write(&nilfs->ns_segctor_sem); if (!test_bit(NILFS_SC_PRIOR_FLUSH, &sci->sc_flags)) break; nilfs_segctor_do_immediate_flush(sci); up_write(&nilfs->ns_segctor_sem); cond_resched(); } if (gcflag) ti->ti_flags |= NILFS_TI_GC; trace_nilfs2_transaction_transition(sb, ti, ti->ti_count, ti->ti_flags, TRACE_NILFS2_TRANSACTION_LOCK); } static void nilfs_transaction_unlock(struct super_block *sb) { struct nilfs_transaction_info *ti = current->journal_info; struct the_nilfs *nilfs = sb->s_fs_info; BUG_ON(ti == NULL || ti->ti_magic != NILFS_TI_MAGIC); BUG_ON(ti->ti_count > 0); up_write(&nilfs->ns_segctor_sem); current->journal_info = ti->ti_save; trace_nilfs2_transaction_transition(sb, ti, ti->ti_count, ti->ti_flags, TRACE_NILFS2_TRANSACTION_UNLOCK); } static void *nilfs_segctor_map_segsum_entry(struct nilfs_sc_info *sci, struct nilfs_segsum_pointer *ssp, unsigned int bytes) { struct nilfs_segment_buffer *segbuf = sci->sc_curseg; unsigned int blocksize = sci->sc_super->s_blocksize; void *p; if (unlikely(ssp->offset + bytes > blocksize)) { ssp->offset = 0; BUG_ON(NILFS_SEGBUF_BH_IS_LAST(ssp->bh, &segbuf->sb_segsum_buffers)); ssp->bh = NILFS_SEGBUF_NEXT_BH(ssp->bh); } p = ssp->bh->b_data + ssp->offset; ssp->offset += bytes; return p; } /** * nilfs_segctor_reset_segment_buffer - reset the current segment buffer * @sci: nilfs_sc_info */ static int nilfs_segctor_reset_segment_buffer(struct nilfs_sc_info *sci) { struct nilfs_segment_buffer *segbuf = sci->sc_curseg; struct buffer_head *sumbh; unsigned int sumbytes; unsigned int flags = 0; int err; if (nilfs_doing_gc()) flags = NILFS_SS_GC; err = nilfs_segbuf_reset(segbuf, flags, sci->sc_seg_ctime, sci->sc_cno); if (unlikely(err)) return err; sumbh = NILFS_SEGBUF_FIRST_BH(&segbuf->sb_segsum_buffers); sumbytes = segbuf->sb_sum.sumbytes; sci->sc_finfo_ptr.bh = sumbh; sci->sc_finfo_ptr.offset = sumbytes; sci->sc_binfo_ptr.bh = sumbh; sci->sc_binfo_ptr.offset = sumbytes; sci->sc_blk_cnt = sci->sc_datablk_cnt = 0; return 0; } /** * nilfs_segctor_zeropad_segsum - zero pad the rest of the segment summary area * @sci: segment constructor object * * nilfs_segctor_zeropad_segsum() zero-fills unallocated space at the end of * the current segment summary block. */ static void nilfs_segctor_zeropad_segsum(struct nilfs_sc_info *sci) { struct nilfs_segsum_pointer *ssp; ssp = sci->sc_blk_cnt > 0 ? &sci->sc_binfo_ptr : &sci->sc_finfo_ptr; if (ssp->offset < ssp->bh->b_size) memset(ssp->bh->b_data + ssp->offset, 0, ssp->bh->b_size - ssp->offset); } static int nilfs_segctor_feed_segment(struct nilfs_sc_info *sci) { sci->sc_nblk_this_inc += sci->sc_curseg->sb_sum.nblocks; if (NILFS_SEGBUF_IS_LAST(sci->sc_curseg, &sci->sc_segbufs)) return -E2BIG; /* * The current segment is filled up * (internal code) */ nilfs_segctor_zeropad_segsum(sci); sci->sc_curseg = NILFS_NEXT_SEGBUF(sci->sc_curseg); return nilfs_segctor_reset_segment_buffer(sci); } static int nilfs_segctor_add_super_root(struct nilfs_sc_info *sci) { struct nilfs_segment_buffer *segbuf = sci->sc_curseg; int err; if (segbuf->sb_sum.nblocks >= segbuf->sb_rest_blocks) { err = nilfs_segctor_feed_segment(sci); if (err) return err; segbuf = sci->sc_curseg; } err = nilfs_segbuf_extend_payload(segbuf, &segbuf->sb_super_root); if (likely(!err)) segbuf->sb_sum.flags |= NILFS_SS_SR; return err; } /* * Functions for making segment summary and payloads */ static int nilfs_segctor_segsum_block_required( struct nilfs_sc_info *sci, const struct nilfs_segsum_pointer *ssp, unsigned int binfo_size) { unsigned int blocksize = sci->sc_super->s_blocksize; /* Size of finfo and binfo is enough small against blocksize */ return ssp->offset + binfo_size + (!sci->sc_blk_cnt ? sizeof(struct nilfs_finfo) : 0) > blocksize; } static void nilfs_segctor_begin_finfo(struct nilfs_sc_info *sci, struct inode *inode) { sci->sc_curseg->sb_sum.nfinfo++; sci->sc_binfo_ptr = sci->sc_finfo_ptr; nilfs_segctor_map_segsum_entry( sci, &sci->sc_binfo_ptr, sizeof(struct nilfs_finfo)); if (NILFS_I(inode)->i_root && !test_bit(NILFS_SC_HAVE_DELTA, &sci->sc_flags)) set_bit(NILFS_SC_HAVE_DELTA, &sci->sc_flags); /* skip finfo */ } static void nilfs_segctor_end_finfo(struct nilfs_sc_info *sci, struct inode *inode) { struct nilfs_finfo *finfo; struct nilfs_inode_info *ii; struct nilfs_segment_buffer *segbuf; __u64 cno; if (sci->sc_blk_cnt == 0) return; ii = NILFS_I(inode); if (ii->i_type & NILFS_I_TYPE_GC) cno = ii->i_cno; else if (NILFS_ROOT_METADATA_FILE(inode->i_ino)) cno = 0; else cno = sci->sc_cno; finfo = nilfs_segctor_map_segsum_entry(sci, &sci->sc_finfo_ptr, sizeof(*finfo)); finfo->fi_ino = cpu_to_le64(inode->i_ino); finfo->fi_nblocks = cpu_to_le32(sci->sc_blk_cnt); finfo->fi_ndatablk = cpu_to_le32(sci->sc_datablk_cnt); finfo->fi_cno = cpu_to_le64(cno); segbuf = sci->sc_curseg; segbuf->sb_sum.sumbytes = sci->sc_binfo_ptr.offset + sci->sc_super->s_blocksize * (segbuf->sb_sum.nsumblk - 1); sci->sc_finfo_ptr = sci->sc_binfo_ptr; sci->sc_blk_cnt = sci->sc_datablk_cnt = 0; } static int nilfs_segctor_add_file_block(struct nilfs_sc_info *sci, struct buffer_head *bh, struct inode *inode, unsigned int binfo_size) { struct nilfs_segment_buffer *segbuf; int required, err = 0; retry: segbuf = sci->sc_curseg; required = nilfs_segctor_segsum_block_required( sci, &sci->sc_binfo_ptr, binfo_size); if (segbuf->sb_sum.nblocks + required + 1 > segbuf->sb_rest_blocks) { nilfs_segctor_end_finfo(sci, inode); err = nilfs_segctor_feed_segment(sci); if (err) return err; goto retry; } if (unlikely(required)) { nilfs_segctor_zeropad_segsum(sci); err = nilfs_segbuf_extend_segsum(segbuf); if (unlikely(err)) goto failed; } if (sci->sc_blk_cnt == 0) nilfs_segctor_begin_finfo(sci, inode); nilfs_segctor_map_segsum_entry(sci, &sci->sc_binfo_ptr, binfo_size); /* Substitution to vblocknr is delayed until update_blocknr() */ nilfs_segbuf_add_file_buffer(segbuf, bh); sci->sc_blk_cnt++; failed: return err; } /* * Callback functions that enumerate, mark, and collect dirty blocks */ static int nilfs_collect_file_data(struct nilfs_sc_info *sci, struct buffer_head *bh, struct inode *inode) { int err; err = nilfs_bmap_propagate(NILFS_I(inode)->i_bmap, bh); if (err < 0) return err; err = nilfs_segctor_add_file_block(sci, bh, inode, sizeof(struct nilfs_binfo_v)); if (!err) sci->sc_datablk_cnt++; return err; } static int nilfs_collect_file_node(struct nilfs_sc_info *sci, struct buffer_head *bh, struct inode *inode) { return nilfs_bmap_propagate(NILFS_I(inode)->i_bmap, bh); } static int nilfs_collect_file_bmap(struct nilfs_sc_info *sci, struct buffer_head *bh, struct inode *inode) { WARN_ON(!buffer_dirty(bh)); return nilfs_segctor_add_file_block(sci, bh, inode, sizeof(__le64)); } static void nilfs_write_file_data_binfo(struct nilfs_sc_info *sci, struct nilfs_segsum_pointer *ssp, union nilfs_binfo *binfo) { struct nilfs_binfo_v *binfo_v = nilfs_segctor_map_segsum_entry( sci, ssp, sizeof(*binfo_v)); *binfo_v = binfo->bi_v; } static void nilfs_write_file_node_binfo(struct nilfs_sc_info *sci, struct nilfs_segsum_pointer *ssp, union nilfs_binfo *binfo) { __le64 *vblocknr = nilfs_segctor_map_segsum_entry( sci, ssp, sizeof(*vblocknr)); *vblocknr = binfo->bi_v.bi_vblocknr; } static const struct nilfs_sc_operations nilfs_sc_file_ops = { .collect_data = nilfs_collect_file_data, .collect_node = nilfs_collect_file_node, .collect_bmap = nilfs_collect_file_bmap, .write_data_binfo = nilfs_write_file_data_binfo, .write_node_binfo = nilfs_write_file_node_binfo, }; static int nilfs_collect_dat_data(struct nilfs_sc_info *sci, struct buffer_head *bh, struct inode *inode) { int err; err = nilfs_bmap_propagate(NILFS_I(inode)->i_bmap, bh); if (err < 0) return err; err = nilfs_segctor_add_file_block(sci, bh, inode, sizeof(__le64)); if (!err) sci->sc_datablk_cnt++; return err; } static int nilfs_collect_dat_bmap(struct nilfs_sc_info *sci, struct buffer_head *bh, struct inode *inode) { WARN_ON(!buffer_dirty(bh)); return nilfs_segctor_add_file_block(sci, bh, inode, sizeof(struct nilfs_binfo_dat)); } static void nilfs_write_dat_data_binfo(struct nilfs_sc_info *sci, struct nilfs_segsum_pointer *ssp, union nilfs_binfo *binfo) { __le64 *blkoff = nilfs_segctor_map_segsum_entry(sci, ssp, sizeof(*blkoff)); *blkoff = binfo->bi_dat.bi_blkoff; } static void nilfs_write_dat_node_binfo(struct nilfs_sc_info *sci, struct nilfs_segsum_pointer *ssp, union nilfs_binfo *binfo) { struct nilfs_binfo_dat *binfo_dat = nilfs_segctor_map_segsum_entry(sci, ssp, sizeof(*binfo_dat)); *binfo_dat = binfo->bi_dat; } static const struct nilfs_sc_operations nilfs_sc_dat_ops = { .collect_data = nilfs_collect_dat_data, .collect_node = nilfs_collect_file_node, .collect_bmap = nilfs_collect_dat_bmap, .write_data_binfo = nilfs_write_dat_data_binfo, .write_node_binfo = nilfs_write_dat_node_binfo, }; static const struct nilfs_sc_operations nilfs_sc_dsync_ops = { .collect_data = nilfs_collect_file_data, .collect_node = NULL, .collect_bmap = NULL, .write_data_binfo = nilfs_write_file_data_binfo, .write_node_binfo = NULL, }; static size_t nilfs_lookup_dirty_data_buffers(struct inode *inode, struct list_head *listp, size_t nlimit, loff_t start, loff_t end) { struct address_space *mapping = inode->i_mapping; struct folio_batch fbatch; pgoff_t index = 0, last = ULONG_MAX; size_t ndirties = 0; int i; if (unlikely(start != 0 || end != LLONG_MAX)) { /* * A valid range is given for sync-ing data pages. The * range is rounded to per-page; extra dirty buffers * may be included if blocksize < pagesize. */ index = start >> PAGE_SHIFT; last = end >> PAGE_SHIFT; } folio_batch_init(&fbatch); repeat: if (unlikely(index > last) || !filemap_get_folios_tag(mapping, &index, last, PAGECACHE_TAG_DIRTY, &fbatch)) return ndirties; for (i = 0; i < folio_batch_count(&fbatch); i++) { struct buffer_head *bh, *head; struct folio *folio = fbatch.folios[i]; folio_lock(folio); if (unlikely(folio->mapping != mapping)) { /* Exclude folios removed from the address space */ folio_unlock(folio); continue; } head = folio_buffers(folio); if (!head) head = create_empty_buffers(folio, i_blocksize(inode), 0); folio_unlock(folio); bh = head; do { if (!buffer_dirty(bh) || buffer_async_write(bh)) continue; get_bh(bh); list_add_tail(&bh->b_assoc_buffers, listp); ndirties++; if (unlikely(ndirties >= nlimit)) { folio_batch_release(&fbatch); cond_resched(); return ndirties; } } while (bh = bh->b_this_page, bh != head); } folio_batch_release(&fbatch); cond_resched(); goto repeat; } static void nilfs_lookup_dirty_node_buffers(struct inode *inode, struct list_head *listp) { struct nilfs_inode_info *ii = NILFS_I(inode); struct inode *btnc_inode = ii->i_assoc_inode; struct folio_batch fbatch; struct buffer_head *bh, *head; unsigned int i; pgoff_t index = 0; if (!btnc_inode) return; folio_batch_init(&fbatch); while (filemap_get_folios_tag(btnc_inode->i_mapping, &index, (pgoff_t)-1, PAGECACHE_TAG_DIRTY, &fbatch)) { for (i = 0; i < folio_batch_count(&fbatch); i++) { bh = head = folio_buffers(fbatch.folios[i]); do { if (buffer_dirty(bh) && !buffer_async_write(bh)) { get_bh(bh); list_add_tail(&bh->b_assoc_buffers, listp); } bh = bh->b_this_page; } while (bh != head); } folio_batch_release(&fbatch); cond_resched(); } } static void nilfs_dispose_list(struct the_nilfs *nilfs, struct list_head *head, int force) { struct nilfs_inode_info *ii, *n; struct nilfs_inode_info *ivec[SC_N_INODEVEC], **pii; unsigned int nv = 0; while (!list_empty(head)) { spin_lock(&nilfs->ns_inode_lock); list_for_each_entry_safe(ii, n, head, i_dirty) { list_del_init(&ii->i_dirty); if (force) { if (unlikely(ii->i_bh)) { brelse(ii->i_bh); ii->i_bh = NULL; } } else if (test_bit(NILFS_I_DIRTY, &ii->i_state)) { set_bit(NILFS_I_QUEUED, &ii->i_state); list_add_tail(&ii->i_dirty, &nilfs->ns_dirty_files); continue; } ivec[nv++] = ii; if (nv == SC_N_INODEVEC) break; } spin_unlock(&nilfs->ns_inode_lock); for (pii = ivec; nv > 0; pii++, nv--) iput(&(*pii)->vfs_inode); } } static void nilfs_iput_work_func(struct work_struct *work) { struct nilfs_sc_info *sci = container_of(work, struct nilfs_sc_info, sc_iput_work); struct the_nilfs *nilfs = sci->sc_super->s_fs_info; nilfs_dispose_list(nilfs, &sci->sc_iput_queue, 0); } static int nilfs_test_metadata_dirty(struct the_nilfs *nilfs, struct nilfs_root *root) { int ret = 0; if (nilfs_mdt_fetch_dirty(root->ifile)) ret++; if (nilfs_mdt_fetch_dirty(nilfs->ns_cpfile)) ret++; if (nilfs_mdt_fetch_dirty(nilfs->ns_sufile)) ret++; if ((ret || nilfs_doing_gc()) && nilfs_mdt_fetch_dirty(nilfs->ns_dat)) ret++; return ret; } static int nilfs_segctor_clean(struct nilfs_sc_info *sci) { return list_empty(&sci->sc_dirty_files) && !test_bit(NILFS_SC_DIRTY, &sci->sc_flags) && sci->sc_nfreesegs == 0 && (!nilfs_doing_gc() || list_empty(&sci->sc_gc_inodes)); } static int nilfs_segctor_confirm(struct nilfs_sc_info *sci) { struct the_nilfs *nilfs = sci->sc_super->s_fs_info; int ret = 0; if (nilfs_test_metadata_dirty(nilfs, sci->sc_root)) set_bit(NILFS_SC_DIRTY, &sci->sc_flags); spin_lock(&nilfs->ns_inode_lock); if (list_empty(&nilfs->ns_dirty_files) && nilfs_segctor_clean(sci)) ret++; spin_unlock(&nilfs->ns_inode_lock); return ret; } static void nilfs_segctor_clear_metadata_dirty(struct nilfs_sc_info *sci) { struct the_nilfs *nilfs = sci->sc_super->s_fs_info; nilfs_mdt_clear_dirty(sci->sc_root->ifile); nilfs_mdt_clear_dirty(nilfs->ns_cpfile); nilfs_mdt_clear_dirty(nilfs->ns_sufile); nilfs_mdt_clear_dirty(nilfs->ns_dat); } static void nilfs_fill_in_file_bmap(struct inode *ifile, struct nilfs_inode_info *ii) { struct buffer_head *ibh; struct nilfs_inode *raw_inode; if (test_bit(NILFS_I_BMAP, &ii->i_state)) { ibh = ii->i_bh; BUG_ON(!ibh); raw_inode = nilfs_ifile_map_inode(ifile, ii->vfs_inode.i_ino, ibh); nilfs_bmap_write(ii->i_bmap, raw_inode); nilfs_ifile_unmap_inode(raw_inode); } } static void nilfs_segctor_fill_in_file_bmap(struct nilfs_sc_info *sci) { struct nilfs_inode_info *ii; list_for_each_entry(ii, &sci->sc_dirty_files, i_dirty) { nilfs_fill_in_file_bmap(sci->sc_root->ifile, ii); set_bit(NILFS_I_COLLECTED, &ii->i_state); } } /** * nilfs_write_root_mdt_inode - export root metadata inode information to * the on-disk inode * @inode: inode object of the root metadata file * @raw_inode: on-disk inode * * nilfs_write_root_mdt_inode() writes inode information and bmap data of * @inode to the inode area of the metadata file allocated on the super root * block created to finalize the log. Since super root blocks are configured * each time, this function zero-fills the unused area of @raw_inode. */ static void nilfs_write_root_mdt_inode(struct inode *inode, struct nilfs_inode *raw_inode) { struct the_nilfs *nilfs = inode->i_sb->s_fs_info; nilfs_write_inode_common(inode, raw_inode); /* zero-fill unused portion of raw_inode */ raw_inode->i_xattr = 0; raw_inode->i_pad = 0; memset((void *)raw_inode + sizeof(*raw_inode), 0, nilfs->ns_inode_size - sizeof(*raw_inode)); nilfs_bmap_write(NILFS_I(inode)->i_bmap, raw_inode); } static void nilfs_segctor_fill_in_super_root(struct nilfs_sc_info *sci, struct the_nilfs *nilfs) { struct buffer_head *bh_sr; struct nilfs_super_root *raw_sr; unsigned int isz, srsz; bh_sr = NILFS_LAST_SEGBUF(&sci->sc_segbufs)->sb_super_root; lock_buffer(bh_sr); raw_sr = (struct nilfs_super_root *)bh_sr->b_data; isz = nilfs->ns_inode_size; srsz = NILFS_SR_BYTES(isz); raw_sr->sr_sum = 0; /* Ensure initialization within this update */ raw_sr->sr_bytes = cpu_to_le16(srsz); raw_sr->sr_nongc_ctime = cpu_to_le64(nilfs_doing_gc() ? nilfs->ns_nongc_ctime : sci->sc_seg_ctime); raw_sr->sr_flags = 0; nilfs_write_root_mdt_inode(nilfs->ns_dat, (void *)raw_sr + NILFS_SR_DAT_OFFSET(isz)); nilfs_write_root_mdt_inode(nilfs->ns_cpfile, (void *)raw_sr + NILFS_SR_CPFILE_OFFSET(isz)); nilfs_write_root_mdt_inode(nilfs->ns_sufile, (void *)raw_sr + NILFS_SR_SUFILE_OFFSET(isz)); memset((void *)raw_sr + srsz, 0, nilfs->ns_blocksize - srsz); set_buffer_uptodate(bh_sr); unlock_buffer(bh_sr); } static void nilfs_redirty_inodes(struct list_head *head) { struct nilfs_inode_info *ii; list_for_each_entry(ii, head, i_dirty) { if (test_bit(NILFS_I_COLLECTED, &ii->i_state)) clear_bit(NILFS_I_COLLECTED, &ii->i_state); } } static void nilfs_drop_collected_inodes(struct list_head *head) { struct nilfs_inode_info *ii; list_for_each_entry(ii, head, i_dirty) { if (!test_and_clear_bit(NILFS_I_COLLECTED, &ii->i_state)) continue; clear_bit(NILFS_I_INODE_SYNC, &ii->i_state); set_bit(NILFS_I_UPDATED, &ii->i_state); } } static int nilfs_segctor_apply_buffers(struct nilfs_sc_info *sci, struct inode *inode, struct list_head *listp, int (*collect)(struct nilfs_sc_info *, struct buffer_head *, struct inode *)) { struct buffer_head *bh, *n; int err = 0; if (collect) { list_for_each_entry_safe(bh, n, listp, b_assoc_buffers) { list_del_init(&bh->b_assoc_buffers); err = collect(sci, bh, inode); brelse(bh); if (unlikely(err)) goto dispose_buffers; } return 0; } dispose_buffers: while (!list_empty(listp)) { bh = list_first_entry(listp, struct buffer_head, b_assoc_buffers); list_del_init(&bh->b_assoc_buffers); brelse(bh); } return err; } static size_t nilfs_segctor_buffer_rest(struct nilfs_sc_info *sci) { /* Remaining number of blocks within segment buffer */ return sci->sc_segbuf_nblocks - (sci->sc_nblk_this_inc + sci->sc_curseg->sb_sum.nblocks); } static int nilfs_segctor_scan_file(struct nilfs_sc_info *sci, struct inode *inode, const struct nilfs_sc_operations *sc_ops) { LIST_HEAD(data_buffers); LIST_HEAD(node_buffers); int err; if (!(sci->sc_stage.flags & NILFS_CF_NODE)) { size_t n, rest = nilfs_segctor_buffer_rest(sci); n = nilfs_lookup_dirty_data_buffers( inode, &data_buffers, rest + 1, 0, LLONG_MAX); if (n > rest) { err = nilfs_segctor_apply_buffers( sci, inode, &data_buffers, sc_ops->collect_data); BUG_ON(!err); /* always receive -E2BIG or true error */ goto break_or_fail; } } nilfs_lookup_dirty_node_buffers(inode, &node_buffers); if (!(sci->sc_stage.flags & NILFS_CF_NODE)) { err = nilfs_segctor_apply_buffers( sci, inode, &data_buffers, sc_ops->collect_data); if (unlikely(err)) { /* dispose node list */ nilfs_segctor_apply_buffers( sci, inode, &node_buffers, NULL); goto break_or_fail; } sci->sc_stage.flags |= NILFS_CF_NODE; } /* Collect node */ err = nilfs_segctor_apply_buffers( sci, inode, &node_buffers, sc_ops->collect_node); if (unlikely(err)) goto break_or_fail; nilfs_bmap_lookup_dirty_buffers(NILFS_I(inode)->i_bmap, &node_buffers); err = nilfs_segctor_apply_buffers( sci, inode, &node_buffers, sc_ops->collect_bmap); if (unlikely(err)) goto break_or_fail; nilfs_segctor_end_finfo(sci, inode); sci->sc_stage.flags &= ~NILFS_CF_NODE; break_or_fail: return err; } static int nilfs_segctor_scan_file_dsync(struct nilfs_sc_info *sci, struct inode *inode) { LIST_HEAD(data_buffers); size_t n, rest = nilfs_segctor_buffer_rest(sci); int err; n = nilfs_lookup_dirty_data_buffers(inode, &data_buffers, rest + 1, sci->sc_dsync_start, sci->sc_dsync_end); err = nilfs_segctor_apply_buffers(sci, inode, &data_buffers, nilfs_collect_file_data); if (!err) { nilfs_segctor_end_finfo(sci, inode); BUG_ON(n > rest); /* always receive -E2BIG or true error if n > rest */ } return err; } /** * nilfs_free_segments - free the segments given by an array of segment numbers * @nilfs: nilfs object * @segnumv: array of segment numbers to be freed * @nsegs: number of segments to be freed in @segnumv * * nilfs_free_segments() wraps nilfs_sufile_freev() and * nilfs_sufile_cancel_freev(), and edits the segment usage metadata file * (sufile) to free all segments given by @segnumv and @nsegs at once. If * it fails midway, it cancels the changes so that none of the segments are * freed. If @nsegs is 0, this function does nothing. * * The freeing of segments is not finalized until the writing of a log with * a super root block containing this sufile change is complete, and it can * be canceled with nilfs_sufile_cancel_freev() until then. * * Return: 0 on success, or the following negative error code on failure. * * %-EINVAL - Invalid segment number. * * %-EIO - I/O error (including metadata corruption). * * %-ENOMEM - Insufficient memory available. */ static int nilfs_free_segments(struct the_nilfs *nilfs, __u64 *segnumv, size_t nsegs) { size_t ndone; int ret; if (!nsegs) return 0; ret = nilfs_sufile_freev(nilfs->ns_sufile, segnumv, nsegs, &ndone); if (unlikely(ret)) { nilfs_sufile_cancel_freev(nilfs->ns_sufile, segnumv, ndone, NULL); /* * If a segment usage of the segments to be freed is in a * hole block, nilfs_sufile_freev() will return -ENOENT. * In this case, -EINVAL should be returned to the caller * since there is something wrong with the given segment * number array. This error can only occur during GC, so * there is no need to worry about it propagating to other * callers (such as fsync). */ if (ret == -ENOENT) { nilfs_err(nilfs->ns_sb, "The segment usage entry %llu to be freed is invalid (in a hole)", (unsigned long long)segnumv[ndone]); ret = -EINVAL; } } return ret; } static int nilfs_segctor_collect_blocks(struct nilfs_sc_info *sci, int mode) { struct the_nilfs *nilfs = sci->sc_super->s_fs_info; struct list_head *head; struct nilfs_inode_info *ii; int err = 0; switch (nilfs_sc_cstage_get(sci)) { case NILFS_ST_INIT: /* Pre-processes */ sci->sc_stage.flags = 0; if (!test_bit(NILFS_SC_UNCLOSED, &sci->sc_flags)) { sci->sc_nblk_inc = 0; sci->sc_curseg->sb_sum.flags = NILFS_SS_LOGBGN; if (mode == SC_LSEG_DSYNC) { nilfs_sc_cstage_set(sci, NILFS_ST_DSYNC); goto dsync_mode; } } sci->sc_stage.dirty_file_ptr = NULL; sci->sc_stage.gc_inode_ptr = NULL; if (mode == SC_FLUSH_DAT) { nilfs_sc_cstage_set(sci, NILFS_ST_DAT); goto dat_stage; } nilfs_sc_cstage_inc(sci); fallthrough; case NILFS_ST_GC: if (nilfs_doing_gc()) { head = &sci->sc_gc_inodes; ii = list_prepare_entry(sci->sc_stage.gc_inode_ptr, head, i_dirty); list_for_each_entry_continue(ii, head, i_dirty) { err = nilfs_segctor_scan_file( sci, &ii->vfs_inode, &nilfs_sc_file_ops); if (unlikely(err)) { sci->sc_stage.gc_inode_ptr = list_entry( ii->i_dirty.prev, struct nilfs_inode_info, i_dirty); goto break_or_fail; } set_bit(NILFS_I_COLLECTED, &ii->i_state); } sci->sc_stage.gc_inode_ptr = NULL; } nilfs_sc_cstage_inc(sci); fallthrough; case NILFS_ST_FILE: head = &sci->sc_dirty_files; ii = list_prepare_entry(sci->sc_stage.dirty_file_ptr, head, i_dirty); list_for_each_entry_continue(ii, head, i_dirty) { clear_bit(NILFS_I_DIRTY, &ii->i_state); err = nilfs_segctor_scan_file(sci, &ii->vfs_inode, &nilfs_sc_file_ops); if (unlikely(err)) { sci->sc_stage.dirty_file_ptr = list_entry(ii->i_dirty.prev, struct nilfs_inode_info, i_dirty); goto break_or_fail; } /* sci->sc_stage.dirty_file_ptr = NILFS_I(inode); */ /* XXX: required ? */ } sci->sc_stage.dirty_file_ptr = NULL; if (mode == SC_FLUSH_FILE) { nilfs_sc_cstage_set(sci, NILFS_ST_DONE); return 0; } nilfs_sc_cstage_inc(sci); sci->sc_stage.flags |= NILFS_CF_IFILE_STARTED; fallthrough; case NILFS_ST_IFILE: err = nilfs_segctor_scan_file(sci, sci->sc_root->ifile, &nilfs_sc_file_ops); if (unlikely(err)) break; nilfs_sc_cstage_inc(sci); /* Creating a checkpoint */ err = nilfs_cpfile_create_checkpoint(nilfs->ns_cpfile, nilfs->ns_cno); if (unlikely(err)) break; fallthrough; case NILFS_ST_CPFILE: err = nilfs_segctor_scan_file(sci, nilfs->ns_cpfile, &nilfs_sc_file_ops); if (unlikely(err)) break; nilfs_sc_cstage_inc(sci); fallthrough; case NILFS_ST_SUFILE: err = nilfs_free_segments(nilfs, sci->sc_freesegs, sci->sc_nfreesegs); if (unlikely(err)) break; sci->sc_stage.flags |= NILFS_CF_SUFREED; err = nilfs_segctor_scan_file(sci, nilfs->ns_sufile, &nilfs_sc_file_ops); if (unlikely(err)) break; nilfs_sc_cstage_inc(sci); fallthrough; case NILFS_ST_DAT: dat_stage: err = nilfs_segctor_scan_file(sci, nilfs->ns_dat, &nilfs_sc_dat_ops); if (unlikely(err)) break; if (mode == SC_FLUSH_DAT) { nilfs_sc_cstage_set(sci, NILFS_ST_DONE); return 0; } nilfs_sc_cstage_inc(sci); fallthrough; case NILFS_ST_SR: if (mode == SC_LSEG_SR) { /* Appending a super root */ err = nilfs_segctor_add_super_root(sci); if (unlikely(err)) break; } /* End of a logical segment */ sci->sc_curseg->sb_sum.flags |= NILFS_SS_LOGEND; nilfs_sc_cstage_set(sci, NILFS_ST_DONE); return 0; case NILFS_ST_DSYNC: dsync_mode: sci->sc_curseg->sb_sum.flags |= NILFS_SS_SYNDT; ii = sci->sc_dsync_inode; if (!test_bit(NILFS_I_BUSY, &ii->i_state)) break; err = nilfs_segctor_scan_file_dsync(sci, &ii->vfs_inode); if (unlikely(err)) break; sci->sc_curseg->sb_sum.flags |= NILFS_SS_LOGEND; nilfs_sc_cstage_set(sci, NILFS_ST_DONE); return 0; case NILFS_ST_DONE: return 0; default: BUG(); } break_or_fail: return err; } /** * nilfs_segctor_begin_construction - setup segment buffer to make a new log * @sci: nilfs_sc_info * @nilfs: nilfs object */ static int nilfs_segctor_begin_construction(struct nilfs_sc_info *sci, struct the_nilfs *nilfs) { struct nilfs_segment_buffer *segbuf, *prev; __u64 nextnum; int err, alloc = 0; segbuf = nilfs_segbuf_new(sci->sc_super); if (unlikely(!segbuf)) return -ENOMEM; if (list_empty(&sci->sc_write_logs)) { nilfs_segbuf_map(segbuf, nilfs->ns_segnum, nilfs->ns_pseg_offset, nilfs); if (segbuf->sb_rest_blocks < NILFS_PSEG_MIN_BLOCKS) { nilfs_shift_to_next_segment(nilfs); nilfs_segbuf_map(segbuf, nilfs->ns_segnum, 0, nilfs); } segbuf->sb_sum.seg_seq = nilfs->ns_seg_seq; nextnum = nilfs->ns_nextnum; if (nilfs->ns_segnum == nilfs->ns_nextnum) /* Start from the head of a new full segment */ alloc++; } else { /* Continue logs */ prev = NILFS_LAST_SEGBUF(&sci->sc_write_logs); nilfs_segbuf_map_cont(segbuf, prev); segbuf->sb_sum.seg_seq = prev->sb_sum.seg_seq; nextnum = prev->sb_nextnum; if (segbuf->sb_rest_blocks < NILFS_PSEG_MIN_BLOCKS) { nilfs_segbuf_map(segbuf, prev->sb_nextnum, 0, nilfs); segbuf->sb_sum.seg_seq++; alloc++; } } err = nilfs_sufile_mark_dirty(nilfs->ns_sufile, segbuf->sb_segnum); if (err) goto failed; if (alloc) { err = nilfs_sufile_alloc(nilfs->ns_sufile, &nextnum); if (err) goto failed; } nilfs_segbuf_set_next_segnum(segbuf, nextnum, nilfs); BUG_ON(!list_empty(&sci->sc_segbufs)); list_add_tail(&segbuf->sb_list, &sci->sc_segbufs); sci->sc_segbuf_nblocks = segbuf->sb_rest_blocks; return 0; failed: nilfs_segbuf_free(segbuf); return err; } static int nilfs_segctor_extend_segments(struct nilfs_sc_info *sci, struct the_nilfs *nilfs, int nadd) { struct nilfs_segment_buffer *segbuf, *prev; struct inode *sufile = nilfs->ns_sufile; __u64 nextnextnum; LIST_HEAD(list); int err, ret, i; prev = NILFS_LAST_SEGBUF(&sci->sc_segbufs); /* * Since the segment specified with nextnum might be allocated during * the previous construction, the buffer including its segusage may * not be dirty. The following call ensures that the buffer is dirty * and will pin the buffer on memory until the sufile is written. */ err = nilfs_sufile_mark_dirty(sufile, prev->sb_nextnum); if (unlikely(err)) return err; for (i = 0; i < nadd; i++) { /* extend segment info */ err = -ENOMEM; segbuf = nilfs_segbuf_new(sci->sc_super); if (unlikely(!segbuf)) goto failed; /* map this buffer to region of segment on-disk */ nilfs_segbuf_map(segbuf, prev->sb_nextnum, 0, nilfs); sci->sc_segbuf_nblocks += segbuf->sb_rest_blocks; /* allocate the next next full segment */ err = nilfs_sufile_alloc(sufile, &nextnextnum); if (unlikely(err)) goto failed_segbuf; segbuf->sb_sum.seg_seq = prev->sb_sum.seg_seq + 1; nilfs_segbuf_set_next_segnum(segbuf, nextnextnum, nilfs); list_add_tail(&segbuf->sb_list, &list); prev = segbuf; } list_splice_tail(&list, &sci->sc_segbufs); return 0; failed_segbuf: nilfs_segbuf_free(segbuf); failed: list_for_each_entry(segbuf, &list, sb_list) { ret = nilfs_sufile_free(sufile, segbuf->sb_nextnum); WARN_ON(ret); /* never fails */ } nilfs_destroy_logs(&list); return err; } static void nilfs_free_incomplete_logs(struct list_head *logs, struct the_nilfs *nilfs) { struct nilfs_segment_buffer *segbuf, *prev; struct inode *sufile = nilfs->ns_sufile; int ret; segbuf = NILFS_FIRST_SEGBUF(logs); if (nilfs->ns_nextnum != segbuf->sb_nextnum) { ret = nilfs_sufile_free(sufile, segbuf->sb_nextnum); WARN_ON(ret); /* never fails */ } if (atomic_read(&segbuf->sb_err)) { /* Case 1: The first segment failed */ if (segbuf->sb_pseg_start != segbuf->sb_fseg_start) /* * Case 1a: Partial segment appended into an existing * segment */ nilfs_terminate_segment(nilfs, segbuf->sb_fseg_start, segbuf->sb_fseg_end); else /* Case 1b: New full segment */ set_nilfs_discontinued(nilfs); } prev = segbuf; list_for_each_entry_continue(segbuf, logs, sb_list) { if (prev->sb_nextnum != segbuf->sb_nextnum) { ret = nilfs_sufile_free(sufile, segbuf->sb_nextnum); WARN_ON(ret); /* never fails */ } if (atomic_read(&segbuf->sb_err) && segbuf->sb_segnum != nilfs->ns_nextnum) /* Case 2: extended segment (!= next) failed */ nilfs_sufile_set_error(sufile, segbuf->sb_segnum); prev = segbuf; } } static void nilfs_segctor_update_segusage(struct nilfs_sc_info *sci, struct inode *sufile) { struct nilfs_segment_buffer *segbuf; unsigned long live_blocks; int ret; list_for_each_entry(segbuf, &sci->sc_segbufs, sb_list) { live_blocks = segbuf->sb_sum.nblocks + (segbuf->sb_pseg_start - segbuf->sb_fseg_start); ret = nilfs_sufile_set_segment_usage(sufile, segbuf->sb_segnum, live_blocks, sci->sc_seg_ctime); WARN_ON(ret); /* always succeed because the segusage is dirty */ } } static void nilfs_cancel_segusage(struct list_head *logs, struct inode *sufile) { struct nilfs_segment_buffer *segbuf; int ret; segbuf = NILFS_FIRST_SEGBUF(logs); ret = nilfs_sufile_set_segment_usage(sufile, segbuf->sb_segnum, segbuf->sb_pseg_start - segbuf->sb_fseg_start, 0); WARN_ON(ret); /* always succeed because the segusage is dirty */ list_for_each_entry_continue(segbuf, logs, sb_list) { ret = nilfs_sufile_set_segment_usage(sufile, segbuf->sb_segnum, 0, 0); WARN_ON(ret); /* always succeed */ } } static void nilfs_segctor_truncate_segments(struct nilfs_sc_info *sci, struct nilfs_segment_buffer *last, struct inode *sufile) { struct nilfs_segment_buffer *segbuf = last; int ret; list_for_each_entry_continue(segbuf, &sci->sc_segbufs, sb_list) { sci->sc_segbuf_nblocks -= segbuf->sb_rest_blocks; ret = nilfs_sufile_free(sufile, segbuf->sb_nextnum); WARN_ON(ret); } nilfs_truncate_logs(&sci->sc_segbufs, last); } static int nilfs_segctor_collect(struct nilfs_sc_info *sci, struct the_nilfs *nilfs, int mode) { struct nilfs_cstage prev_stage = sci->sc_stage; int err, nadd = 1; /* Collection retry loop */ for (;;) { sci->sc_nblk_this_inc = 0; sci->sc_curseg = NILFS_FIRST_SEGBUF(&sci->sc_segbufs); err = nilfs_segctor_reset_segment_buffer(sci); if (unlikely(err)) goto failed; err = nilfs_segctor_collect_blocks(sci, mode); sci->sc_nblk_this_inc += sci->sc_curseg->sb_sum.nblocks; if (!err) break; if (unlikely(err != -E2BIG)) goto failed; /* The current segment is filled up */ if (mode != SC_LSEG_SR || nilfs_sc_cstage_get(sci) < NILFS_ST_CPFILE) break; nilfs_clear_logs(&sci->sc_segbufs); if (sci->sc_stage.flags & NILFS_CF_SUFREED) { err = nilfs_sufile_cancel_freev(nilfs->ns_sufile, sci->sc_freesegs, sci->sc_nfreesegs, NULL); WARN_ON(err); /* do not happen */ sci->sc_stage.flags &= ~NILFS_CF_SUFREED; } err = nilfs_segctor_extend_segments(sci, nilfs, nadd); if (unlikely(err)) return err; nadd = min_t(int, nadd << 1, SC_MAX_SEGDELTA); sci->sc_stage = prev_stage; } nilfs_segctor_zeropad_segsum(sci); nilfs_segctor_truncate_segments(sci, sci->sc_curseg, nilfs->ns_sufile); return 0; failed: return err; } static void nilfs_list_replace_buffer(struct buffer_head *old_bh, struct buffer_head *new_bh) { BUG_ON(!list_empty(&new_bh->b_assoc_buffers)); list_replace_init(&old_bh->b_assoc_buffers, &new_bh->b_assoc_buffers); /* The caller must release old_bh */ } static int nilfs_segctor_update_payload_blocknr(struct nilfs_sc_info *sci, struct nilfs_segment_buffer *segbuf, int mode) { struct inode *inode = NULL; sector_t blocknr; unsigned long nfinfo = segbuf->sb_sum.nfinfo; unsigned long nblocks = 0, ndatablk = 0; const struct nilfs_sc_operations *sc_op = NULL; struct nilfs_segsum_pointer ssp; struct nilfs_finfo *finfo = NULL; union nilfs_binfo binfo; struct buffer_head *bh, *bh_org; ino_t ino = 0; int err = 0; if (!nfinfo) goto out; blocknr = segbuf->sb_pseg_start + segbuf->sb_sum.nsumblk; ssp.bh = NILFS_SEGBUF_FIRST_BH(&segbuf->sb_segsum_buffers); ssp.offset = sizeof(struct nilfs_segment_summary); list_for_each_entry(bh, &segbuf->sb_payload_buffers, b_assoc_buffers) { if (bh == segbuf->sb_super_root) break; if (!finfo) { finfo = nilfs_segctor_map_segsum_entry( sci, &ssp, sizeof(*finfo)); ino = le64_to_cpu(finfo->fi_ino); nblocks = le32_to_cpu(finfo->fi_nblocks); ndatablk = le32_to_cpu(finfo->fi_ndatablk); inode = bh->b_folio->mapping->host; if (mode == SC_LSEG_DSYNC) sc_op = &nilfs_sc_dsync_ops; else if (ino == NILFS_DAT_INO) sc_op = &nilfs_sc_dat_ops; else /* file blocks */ sc_op = &nilfs_sc_file_ops; } bh_org = bh; get_bh(bh_org); err = nilfs_bmap_assign(NILFS_I(inode)->i_bmap, &bh, blocknr, &binfo); if (bh != bh_org) nilfs_list_replace_buffer(bh_org, bh); brelse(bh_org); if (unlikely(err)) goto failed_bmap; if (ndatablk > 0) sc_op->write_data_binfo(sci, &ssp, &binfo); else sc_op->write_node_binfo(sci, &ssp, &binfo); blocknr++; if (--nblocks == 0) { finfo = NULL; if (--nfinfo == 0) break; } else if (ndatablk > 0) ndatablk--; } out: return 0; failed_bmap: return err; } static int nilfs_segctor_assign(struct nilfs_sc_info *sci, int mode) { struct nilfs_segment_buffer *segbuf; int err; list_for_each_entry(segbuf, &sci->sc_segbufs, sb_list) { err = nilfs_segctor_update_payload_blocknr(sci, segbuf, mode); if (unlikely(err)) return err; nilfs_segbuf_fill_in_segsum(segbuf); } return 0; } static void nilfs_begin_folio_io(struct folio *folio) { if (!folio || folio_test_writeback(folio)) /* * For split b-tree node pages, this function may be called * twice. We ignore the 2nd or later calls by this check. */ return; folio_lock(folio); folio_clear_dirty_for_io(folio); folio_start_writeback(folio); folio_unlock(folio); } /** * nilfs_prepare_write_logs - prepare to write logs * @logs: logs to prepare for writing * @seed: checksum seed value * * nilfs_prepare_write_logs() adds checksums and prepares the block * buffers/folios for writing logs. In order to stabilize folios of * memory-mapped file blocks by putting them in writeback state before * calculating the checksums, first prepare to write payload blocks other * than segment summary and super root blocks in which the checksums will * be embedded. */ static void nilfs_prepare_write_logs(struct list_head *logs, u32 seed) { struct nilfs_segment_buffer *segbuf; struct folio *bd_folio = NULL, *fs_folio = NULL; struct buffer_head *bh; /* Prepare to write payload blocks */ list_for_each_entry(segbuf, logs, sb_list) { list_for_each_entry(bh, &segbuf->sb_payload_buffers, b_assoc_buffers) { if (bh == segbuf->sb_super_root) break; set_buffer_async_write(bh); if (bh->b_folio != fs_folio) { nilfs_begin_folio_io(fs_folio); fs_folio = bh->b_folio; } } } nilfs_begin_folio_io(fs_folio); nilfs_add_checksums_on_logs(logs, seed); /* Prepare to write segment summary blocks */ list_for_each_entry(segbuf, logs, sb_list) { list_for_each_entry(bh, &segbuf->sb_segsum_buffers, b_assoc_buffers) { mark_buffer_dirty(bh); if (bh->b_folio == bd_folio) continue; if (bd_folio) { folio_lock(bd_folio); folio_wait_writeback(bd_folio); folio_clear_dirty_for_io(bd_folio); folio_start_writeback(bd_folio); folio_unlock(bd_folio); } bd_folio = bh->b_folio; } } /* Prepare to write super root block */ bh = NILFS_LAST_SEGBUF(logs)->sb_super_root; if (bh) { mark_buffer_dirty(bh); if (bh->b_folio != bd_folio) { folio_lock(bd_folio); folio_wait_writeback(bd_folio); folio_clear_dirty_for_io(bd_folio); folio_start_writeback(bd_folio); folio_unlock(bd_folio); bd_folio = bh->b_folio; } } if (bd_folio) { folio_lock(bd_folio); folio_wait_writeback(bd_folio); folio_clear_dirty_for_io(bd_folio); folio_start_writeback(bd_folio); folio_unlock(bd_folio); } } static int nilfs_segctor_write(struct nilfs_sc_info *sci, struct the_nilfs *nilfs) { int ret; ret = nilfs_write_logs(&sci->sc_segbufs, nilfs); list_splice_tail_init(&sci->sc_segbufs, &sci->sc_write_logs); return ret; } static void nilfs_end_folio_io(struct folio *folio, int err) { if (!folio) return; if (buffer_nilfs_node(folio_buffers(folio)) && !folio_test_writeback(folio)) { /* * For b-tree node pages, this function may be called twice * or more because they might be split in a segment. */ if (folio_test_dirty(folio)) { /* * For pages holding split b-tree node buffers, dirty * flag on the buffers may be cleared discretely. * In that case, the page is once redirtied for * remaining buffers, and it must be cancelled if * all the buffers get cleaned later. */ folio_lock(folio); if (nilfs_folio_buffers_clean(folio)) __nilfs_clear_folio_dirty(folio); folio_unlock(folio); } return; } if (err || !nilfs_folio_buffers_clean(folio)) filemap_dirty_folio(folio->mapping, folio); folio_end_writeback(folio); } static void nilfs_abort_logs(struct list_head *logs, int err) { struct nilfs_segment_buffer *segbuf; struct folio *bd_folio = NULL, *fs_folio = NULL; struct buffer_head *bh; if (list_empty(logs)) return; list_for_each_entry(segbuf, logs, sb_list) { list_for_each_entry(bh, &segbuf->sb_segsum_buffers, b_assoc_buffers) { clear_buffer_uptodate(bh); if (bh->b_folio != bd_folio) { if (bd_folio) folio_end_writeback(bd_folio); bd_folio = bh->b_folio; } } list_for_each_entry(bh, &segbuf->sb_payload_buffers, b_assoc_buffers) { if (bh == segbuf->sb_super_root) { clear_buffer_uptodate(bh); if (bh->b_folio != bd_folio) { folio_end_writeback(bd_folio); bd_folio = bh->b_folio; } break; } clear_buffer_async_write(bh); if (bh->b_folio != fs_folio) { nilfs_end_folio_io(fs_folio, err); fs_folio = bh->b_folio; } } } if (bd_folio) folio_end_writeback(bd_folio); nilfs_end_folio_io(fs_folio, err); } static void nilfs_segctor_abort_construction(struct nilfs_sc_info *sci, struct the_nilfs *nilfs, int err) { LIST_HEAD(logs); int ret; list_splice_tail_init(&sci->sc_write_logs, &logs); ret = nilfs_wait_on_logs(&logs); nilfs_abort_logs(&logs, ret ? : err); list_splice_tail_init(&sci->sc_segbufs, &logs); if (list_empty(&logs)) return; /* if the first segment buffer preparation failed */ nilfs_cancel_segusage(&logs, nilfs->ns_sufile); nilfs_free_incomplete_logs(&logs, nilfs); if (sci->sc_stage.flags & NILFS_CF_SUFREED) { ret = nilfs_sufile_cancel_freev(nilfs->ns_sufile, sci->sc_freesegs, sci->sc_nfreesegs, NULL); WARN_ON(ret); /* do not happen */ } nilfs_destroy_logs(&logs); } static void nilfs_set_next_segment(struct the_nilfs *nilfs, struct nilfs_segment_buffer *segbuf) { nilfs->ns_segnum = segbuf->sb_segnum; nilfs->ns_nextnum = segbuf->sb_nextnum; nilfs->ns_pseg_offset = segbuf->sb_pseg_start - segbuf->sb_fseg_start + segbuf->sb_sum.nblocks; nilfs->ns_seg_seq = segbuf->sb_sum.seg_seq; nilfs->ns_ctime = segbuf->sb_sum.ctime; } static void nilfs_segctor_complete_write(struct nilfs_sc_info *sci) { struct nilfs_segment_buffer *segbuf; struct folio *bd_folio = NULL, *fs_folio = NULL; struct the_nilfs *nilfs = sci->sc_super->s_fs_info; int update_sr = false; list_for_each_entry(segbuf, &sci->sc_write_logs, sb_list) { struct buffer_head *bh; list_for_each_entry(bh, &segbuf->sb_segsum_buffers, b_assoc_buffers) { set_buffer_uptodate(bh); clear_buffer_dirty(bh); if (bh->b_folio != bd_folio) { if (bd_folio) folio_end_writeback(bd_folio); bd_folio = bh->b_folio; } } /* * We assume that the buffers which belong to the same folio * continue over the buffer list. * Under this assumption, the last BHs of folios is * identifiable by the discontinuity of bh->b_folio * (folio != fs_folio). * * For B-tree node blocks, however, this assumption is not * guaranteed. The cleanup code of B-tree node folios needs * special care. */ list_for_each_entry(bh, &segbuf->sb_payload_buffers, b_assoc_buffers) { const unsigned long set_bits = BIT(BH_Uptodate); const unsigned long clear_bits = (BIT(BH_Dirty) | BIT(BH_Async_Write) | BIT(BH_Delay) | BIT(BH_NILFS_Volatile) | BIT(BH_NILFS_Redirected)); if (bh == segbuf->sb_super_root) { set_buffer_uptodate(bh); clear_buffer_dirty(bh); if (bh->b_folio != bd_folio) { folio_end_writeback(bd_folio); bd_folio = bh->b_folio; } update_sr = true; break; } set_mask_bits(&bh->b_state, clear_bits, set_bits); if (bh->b_folio != fs_folio) { nilfs_end_folio_io(fs_folio, 0); fs_folio = bh->b_folio; } } if (!nilfs_segbuf_simplex(segbuf)) { if (segbuf->sb_sum.flags & NILFS_SS_LOGBGN) { set_bit(NILFS_SC_UNCLOSED, &sci->sc_flags); sci->sc_lseg_stime = jiffies; } if (segbuf->sb_sum.flags & NILFS_SS_LOGEND) clear_bit(NILFS_SC_UNCLOSED, &sci->sc_flags); } } /* * Since folios may continue over multiple segment buffers, * end of the last folio must be checked outside of the loop. */ if (bd_folio) folio_end_writeback(bd_folio); nilfs_end_folio_io(fs_folio, 0); nilfs_drop_collected_inodes(&sci->sc_dirty_files); if (nilfs_doing_gc()) nilfs_drop_collected_inodes(&sci->sc_gc_inodes); else nilfs->ns_nongc_ctime = sci->sc_seg_ctime; sci->sc_nblk_inc += sci->sc_nblk_this_inc; segbuf = NILFS_LAST_SEGBUF(&sci->sc_write_logs); nilfs_set_next_segment(nilfs, segbuf); if (update_sr) { nilfs->ns_flushed_device = 0; nilfs_set_last_segment(nilfs, segbuf->sb_pseg_start, segbuf->sb_sum.seg_seq, nilfs->ns_cno++); clear_bit(NILFS_SC_HAVE_DELTA, &sci->sc_flags); clear_bit(NILFS_SC_DIRTY, &sci->sc_flags); set_bit(NILFS_SC_SUPER_ROOT, &sci->sc_flags); nilfs_segctor_clear_metadata_dirty(sci); } else clear_bit(NILFS_SC_SUPER_ROOT, &sci->sc_flags); } static int nilfs_segctor_wait(struct nilfs_sc_info *sci) { int ret; ret = nilfs_wait_on_logs(&sci->sc_write_logs); if (!ret) { nilfs_segctor_complete_write(sci); nilfs_destroy_logs(&sci->sc_write_logs); } return ret; } static int nilfs_segctor_collect_dirty_files(struct nilfs_sc_info *sci, struct the_nilfs *nilfs) { struct nilfs_inode_info *ii, *n; struct inode *ifile = sci->sc_root->ifile; spin_lock(&nilfs->ns_inode_lock); retry: list_for_each_entry_safe(ii, n, &nilfs->ns_dirty_files, i_dirty) { if (!ii->i_bh) { struct buffer_head *ibh; int err; spin_unlock(&nilfs->ns_inode_lock); err = nilfs_ifile_get_inode_block( ifile, ii->vfs_inode.i_ino, &ibh); if (unlikely(err)) { nilfs_warn(sci->sc_super, "log writer: error %d getting inode block (ino=%lu)", err, ii->vfs_inode.i_ino); return err; } spin_lock(&nilfs->ns_inode_lock); if (likely(!ii->i_bh)) ii->i_bh = ibh; else brelse(ibh); goto retry; } // Always redirty the buffer to avoid race condition mark_buffer_dirty(ii->i_bh); nilfs_mdt_mark_dirty(ifile); clear_bit(NILFS_I_QUEUED, &ii->i_state); set_bit(NILFS_I_BUSY, &ii->i_state); list_move_tail(&ii->i_dirty, &sci->sc_dirty_files); } spin_unlock(&nilfs->ns_inode_lock); return 0; } static void nilfs_segctor_drop_written_files(struct nilfs_sc_info *sci, struct the_nilfs *nilfs) { struct nilfs_inode_info *ii, *n; int during_mount = !(sci->sc_super->s_flags & SB_ACTIVE); int defer_iput = false; spin_lock(&nilfs->ns_inode_lock); list_for_each_entry_safe(ii, n, &sci->sc_dirty_files, i_dirty) { if (!test_and_clear_bit(NILFS_I_UPDATED, &ii->i_state) || test_bit(NILFS_I_DIRTY, &ii->i_state)) continue; clear_bit(NILFS_I_BUSY, &ii->i_state); brelse(ii->i_bh); ii->i_bh = NULL; list_del_init(&ii->i_dirty); if (!ii->vfs_inode.i_nlink || during_mount) { /* * Defer calling iput() to avoid deadlocks if * i_nlink == 0 or mount is not yet finished. */ list_add_tail(&ii->i_dirty, &sci->sc_iput_queue); defer_iput = true; } else { spin_unlock(&nilfs->ns_inode_lock); iput(&ii->vfs_inode); spin_lock(&nilfs->ns_inode_lock); } } spin_unlock(&nilfs->ns_inode_lock); if (defer_iput) schedule_work(&sci->sc_iput_work); } /* * Main procedure of segment constructor */ static int nilfs_segctor_do_construct(struct nilfs_sc_info *sci, int mode) { struct the_nilfs *nilfs = sci->sc_super->s_fs_info; int err; if (sb_rdonly(sci->sc_super)) return -EROFS; nilfs_sc_cstage_set(sci, NILFS_ST_INIT); sci->sc_cno = nilfs->ns_cno; err = nilfs_segctor_collect_dirty_files(sci, nilfs); if (unlikely(err)) goto out; if (nilfs_test_metadata_dirty(nilfs, sci->sc_root)) set_bit(NILFS_SC_DIRTY, &sci->sc_flags); if (nilfs_segctor_clean(sci)) goto out; do { sci->sc_stage.flags &= ~NILFS_CF_HISTORY_MASK; err = nilfs_segctor_begin_construction(sci, nilfs); if (unlikely(err)) goto failed; /* Update time stamp */ sci->sc_seg_ctime = ktime_get_real_seconds(); err = nilfs_segctor_collect(sci, nilfs, mode); if (unlikely(err)) goto failed; /* Avoid empty segment */ if (nilfs_sc_cstage_get(sci) == NILFS_ST_DONE && nilfs_segbuf_empty(sci->sc_curseg)) { nilfs_segctor_abort_construction(sci, nilfs, 1); goto out; } err = nilfs_segctor_assign(sci, mode); if (unlikely(err)) goto failed; if (sci->sc_stage.flags & NILFS_CF_IFILE_STARTED) nilfs_segctor_fill_in_file_bmap(sci); if (mode == SC_LSEG_SR && nilfs_sc_cstage_get(sci) >= NILFS_ST_CPFILE) { err = nilfs_cpfile_finalize_checkpoint( nilfs->ns_cpfile, nilfs->ns_cno, sci->sc_root, sci->sc_nblk_inc + sci->sc_nblk_this_inc, sci->sc_seg_ctime, !test_bit(NILFS_SC_HAVE_DELTA, &sci->sc_flags)); if (unlikely(err)) goto failed_to_write; nilfs_segctor_fill_in_super_root(sci, nilfs); } nilfs_segctor_update_segusage(sci, nilfs->ns_sufile); /* Write partial segments */ nilfs_prepare_write_logs(&sci->sc_segbufs, nilfs->ns_crc_seed); err = nilfs_segctor_write(sci, nilfs); if (unlikely(err)) goto failed_to_write; if (nilfs_sc_cstage_get(sci) == NILFS_ST_DONE || nilfs->ns_blocksize_bits != PAGE_SHIFT) { /* * At this point, we avoid double buffering * for blocksize < pagesize because page dirty * flag is turned off during write and dirty * buffers are not properly collected for * pages crossing over segments. */ err = nilfs_segctor_wait(sci); if (err) goto failed_to_write; } } while (nilfs_sc_cstage_get(sci) != NILFS_ST_DONE); out: nilfs_segctor_drop_written_files(sci, nilfs); return err; failed_to_write: failed: if (mode == SC_LSEG_SR && nilfs_sc_cstage_get(sci) >= NILFS_ST_IFILE) nilfs_redirty_inodes(&sci->sc_dirty_files); if (nilfs_doing_gc()) nilfs_redirty_inodes(&sci->sc_gc_inodes); nilfs_segctor_abort_construction(sci, nilfs, err); goto out; } /** * nilfs_segctor_start_timer - set timer of background write * @sci: nilfs_sc_info * * If the timer has already been set, it ignores the new request. * This function MUST be called within a section locking the segment * semaphore. */ static void nilfs_segctor_start_timer(struct nilfs_sc_info *sci) { spin_lock(&sci->sc_state_lock); if (!(sci->sc_state & NILFS_SEGCTOR_COMMIT)) { if (sci->sc_task) { sci->sc_timer.expires = jiffies + sci->sc_interval; add_timer(&sci->sc_timer); } sci->sc_state |= NILFS_SEGCTOR_COMMIT; } spin_unlock(&sci->sc_state_lock); } static void nilfs_segctor_do_flush(struct nilfs_sc_info *sci, int bn) { spin_lock(&sci->sc_state_lock); if (!(sci->sc_flush_request & BIT(bn))) { unsigned long prev_req = sci->sc_flush_request; sci->sc_flush_request |= BIT(bn); if (!prev_req) wake_up(&sci->sc_wait_daemon); } spin_unlock(&sci->sc_state_lock); } /** * nilfs_flush_segment - trigger a segment construction for resource control * @sb: super block * @ino: inode number of the file to be flushed out. */ void nilfs_flush_segment(struct super_block *sb, ino_t ino) { struct the_nilfs *nilfs = sb->s_fs_info; struct nilfs_sc_info *sci = nilfs->ns_writer; if (!sci || nilfs_doing_construction()) return; nilfs_segctor_do_flush(sci, NILFS_MDT_INODE(sb, ino) ? ino : 0); /* assign bit 0 to data files */ } struct nilfs_segctor_wait_request { wait_queue_entry_t wq; __u32 seq; int err; atomic_t done; }; static int nilfs_segctor_sync(struct nilfs_sc_info *sci) { struct nilfs_segctor_wait_request wait_req; int err = 0; init_wait(&wait_req.wq); wait_req.err = 0; atomic_set(&wait_req.done, 0); init_waitqueue_entry(&wait_req.wq, current); /* * To prevent a race issue where completion notifications from the * log writer thread are missed, increment the request sequence count * "sc_seq_request" and insert a wait queue entry using the current * sequence number into the "sc_wait_request" queue at the same time * within the lock section of "sc_state_lock". */ spin_lock(&sci->sc_state_lock); wait_req.seq = ++sci->sc_seq_request; add_wait_queue(&sci->sc_wait_request, &wait_req.wq); spin_unlock(&sci->sc_state_lock); wake_up(&sci->sc_wait_daemon); for (;;) { set_current_state(TASK_INTERRUPTIBLE); /* * Synchronize only while the log writer thread is alive. * Leave flushing out after the log writer thread exits to * the cleanup work in nilfs_segctor_destroy(). */ if (!sci->sc_task) break; if (atomic_read(&wait_req.done)) { err = wait_req.err; break; } if (!signal_pending(current)) { schedule(); continue; } err = -ERESTARTSYS; break; } finish_wait(&sci->sc_wait_request, &wait_req.wq); return err; } static void nilfs_segctor_wakeup(struct nilfs_sc_info *sci, int err, bool force) { struct nilfs_segctor_wait_request *wrq, *n; unsigned long flags; spin_lock_irqsave(&sci->sc_wait_request.lock, flags); list_for_each_entry_safe(wrq, n, &sci->sc_wait_request.head, wq.entry) { if (!atomic_read(&wrq->done) && (force || nilfs_cnt32_ge(sci->sc_seq_done, wrq->seq))) { wrq->err = err; atomic_set(&wrq->done, 1); } if (atomic_read(&wrq->done)) { wrq->wq.func(&wrq->wq, TASK_UNINTERRUPTIBLE | TASK_INTERRUPTIBLE, 0, NULL); } } spin_unlock_irqrestore(&sci->sc_wait_request.lock, flags); } /** * nilfs_construct_segment - construct a logical segment * @sb: super block * * Return Value: On success, 0 is returned. On errors, one of the following * negative error code is returned. * * %-EROFS - Read only filesystem. * * %-EIO - I/O error * * %-ENOSPC - No space left on device (only in a panic state). * * %-ERESTARTSYS - Interrupted. * * %-ENOMEM - Insufficient memory available. */ int nilfs_construct_segment(struct super_block *sb) { struct the_nilfs *nilfs = sb->s_fs_info; struct nilfs_sc_info *sci = nilfs->ns_writer; struct nilfs_transaction_info *ti; if (sb_rdonly(sb) || unlikely(!sci)) return -EROFS; /* A call inside transactions causes a deadlock. */ BUG_ON((ti = current->journal_info) && ti->ti_magic == NILFS_TI_MAGIC); return nilfs_segctor_sync(sci); } /** * nilfs_construct_dsync_segment - construct a data-only logical segment * @sb: super block * @inode: inode whose data blocks should be written out * @start: start byte offset * @end: end byte offset (inclusive) * * Return Value: On success, 0 is returned. On errors, one of the following * negative error code is returned. * * %-EROFS - Read only filesystem. * * %-EIO - I/O error * * %-ENOSPC - No space left on device (only in a panic state). * * %-ERESTARTSYS - Interrupted. * * %-ENOMEM - Insufficient memory available. */ int nilfs_construct_dsync_segment(struct super_block *sb, struct inode *inode, loff_t start, loff_t end) { struct the_nilfs *nilfs = sb->s_fs_info; struct nilfs_sc_info *sci = nilfs->ns_writer; struct nilfs_inode_info *ii; struct nilfs_transaction_info ti; int err = 0; if (sb_rdonly(sb) || unlikely(!sci)) return -EROFS; nilfs_transaction_lock(sb, &ti, 0); ii = NILFS_I(inode); if (test_bit(NILFS_I_INODE_SYNC, &ii->i_state) || nilfs_test_opt(nilfs, STRICT_ORDER) || test_bit(NILFS_SC_UNCLOSED, &sci->sc_flags) || nilfs_discontinued(nilfs)) { nilfs_transaction_unlock(sb); err = nilfs_segctor_sync(sci); return err; } spin_lock(&nilfs->ns_inode_lock); if (!test_bit(NILFS_I_QUEUED, &ii->i_state) && !test_bit(NILFS_I_BUSY, &ii->i_state)) { spin_unlock(&nilfs->ns_inode_lock); nilfs_transaction_unlock(sb); return 0; } spin_unlock(&nilfs->ns_inode_lock); sci->sc_dsync_inode = ii; sci->sc_dsync_start = start; sci->sc_dsync_end = end; err = nilfs_segctor_do_construct(sci, SC_LSEG_DSYNC); if (!err) nilfs->ns_flushed_device = 0; nilfs_transaction_unlock(sb); return err; } #define FLUSH_FILE_BIT (0x1) /* data file only */ #define FLUSH_DAT_BIT BIT(NILFS_DAT_INO) /* DAT only */ /** * nilfs_segctor_accept - record accepted sequence count of log-write requests * @sci: segment constructor object */ static void nilfs_segctor_accept(struct nilfs_sc_info *sci) { bool thread_is_alive; spin_lock(&sci->sc_state_lock); sci->sc_seq_accepted = sci->sc_seq_request; thread_is_alive = (bool)sci->sc_task; spin_unlock(&sci->sc_state_lock); /* * This function does not race with the log writer thread's * termination. Therefore, deleting sc_timer, which should not be * done after the log writer thread exits, can be done safely outside * the area protected by sc_state_lock. */ if (thread_is_alive) del_timer_sync(&sci->sc_timer); } /** * nilfs_segctor_notify - notify the result of request to caller threads * @sci: segment constructor object * @mode: mode of log forming * @err: error code to be notified */ static void nilfs_segctor_notify(struct nilfs_sc_info *sci, int mode, int err) { /* Clear requests (even when the construction failed) */ spin_lock(&sci->sc_state_lock); if (mode == SC_LSEG_SR) { sci->sc_state &= ~NILFS_SEGCTOR_COMMIT; sci->sc_seq_done = sci->sc_seq_accepted; nilfs_segctor_wakeup(sci, err, false); sci->sc_flush_request = 0; } else { if (mode == SC_FLUSH_FILE) sci->sc_flush_request &= ~FLUSH_FILE_BIT; else if (mode == SC_FLUSH_DAT) sci->sc_flush_request &= ~FLUSH_DAT_BIT; /* re-enable timer if checkpoint creation was not done */ if ((sci->sc_state & NILFS_SEGCTOR_COMMIT) && sci->sc_task && time_before(jiffies, sci->sc_timer.expires)) add_timer(&sci->sc_timer); } spin_unlock(&sci->sc_state_lock); } /** * nilfs_segctor_construct - form logs and write them to disk * @sci: segment constructor object * @mode: mode of log forming */ static int nilfs_segctor_construct(struct nilfs_sc_info *sci, int mode) { struct the_nilfs *nilfs = sci->sc_super->s_fs_info; struct nilfs_super_block **sbp; int err = 0; nilfs_segctor_accept(sci); if (nilfs_discontinued(nilfs)) mode = SC_LSEG_SR; if (!nilfs_segctor_confirm(sci)) err = nilfs_segctor_do_construct(sci, mode); if (likely(!err)) { if (mode != SC_FLUSH_DAT) atomic_set(&nilfs->ns_ndirtyblks, 0); if (test_bit(NILFS_SC_SUPER_ROOT, &sci->sc_flags) && nilfs_discontinued(nilfs)) { down_write(&nilfs->ns_sem); err = -EIO; sbp = nilfs_prepare_super(sci->sc_super, nilfs_sb_will_flip(nilfs)); if (likely(sbp)) { nilfs_set_log_cursor(sbp[0], nilfs); err = nilfs_commit_super(sci->sc_super, NILFS_SB_COMMIT); } up_write(&nilfs->ns_sem); } } nilfs_segctor_notify(sci, mode, err); return err; } static void nilfs_construction_timeout(struct timer_list *t) { struct nilfs_sc_info *sci = from_timer(sci, t, sc_timer); wake_up_process(sci->sc_task); } static void nilfs_remove_written_gcinodes(struct the_nilfs *nilfs, struct list_head *head) { struct nilfs_inode_info *ii, *n; list_for_each_entry_safe(ii, n, head, i_dirty) { if (!test_bit(NILFS_I_UPDATED, &ii->i_state)) continue; list_del_init(&ii->i_dirty); truncate_inode_pages(&ii->vfs_inode.i_data, 0); nilfs_btnode_cache_clear(ii->i_assoc_inode->i_mapping); iput(&ii->vfs_inode); } } int nilfs_clean_segments(struct super_block *sb, struct nilfs_argv *argv, void **kbufs) { struct the_nilfs *nilfs = sb->s_fs_info; struct nilfs_sc_info *sci = nilfs->ns_writer; struct nilfs_transaction_info ti; int err; if (unlikely(!sci)) return -EROFS; nilfs_transaction_lock(sb, &ti, 1); err = nilfs_mdt_save_to_shadow_map(nilfs->ns_dat); if (unlikely(err)) goto out_unlock; err = nilfs_ioctl_prepare_clean_segments(nilfs, argv, kbufs); if (unlikely(err)) { nilfs_mdt_restore_from_shadow_map(nilfs->ns_dat); goto out_unlock; } sci->sc_freesegs = kbufs[4]; sci->sc_nfreesegs = argv[4].v_nmembs; list_splice_tail_init(&nilfs->ns_gc_inodes, &sci->sc_gc_inodes); for (;;) { err = nilfs_segctor_construct(sci, SC_LSEG_SR); nilfs_remove_written_gcinodes(nilfs, &sci->sc_gc_inodes); if (likely(!err)) break; nilfs_warn(sb, "error %d cleaning segments", err); set_current_state(TASK_INTERRUPTIBLE); schedule_timeout(sci->sc_interval); } if (nilfs_test_opt(nilfs, DISCARD)) { int ret = nilfs_discard_segments(nilfs, sci->sc_freesegs, sci->sc_nfreesegs); if (ret) { nilfs_warn(sb, "error %d on discard request, turning discards off for the device", ret); nilfs_clear_opt(nilfs, DISCARD); } } out_unlock: sci->sc_freesegs = NULL; sci->sc_nfreesegs = 0; nilfs_mdt_clear_shadow_map(nilfs->ns_dat); nilfs_transaction_unlock(sb); return err; } static void nilfs_segctor_thread_construct(struct nilfs_sc_info *sci, int mode) { struct nilfs_transaction_info ti; nilfs_transaction_lock(sci->sc_super, &ti, 0); nilfs_segctor_construct(sci, mode); /* * Unclosed segment should be retried. We do this using sc_timer. * Timeout of sc_timer will invoke complete construction which leads * to close the current logical segment. */ if (test_bit(NILFS_SC_UNCLOSED, &sci->sc_flags)) nilfs_segctor_start_timer(sci); nilfs_transaction_unlock(sci->sc_super); } static void nilfs_segctor_do_immediate_flush(struct nilfs_sc_info *sci) { int mode = 0; spin_lock(&sci->sc_state_lock); mode = (sci->sc_flush_request & FLUSH_DAT_BIT) ? SC_FLUSH_DAT : SC_FLUSH_FILE; spin_unlock(&sci->sc_state_lock); if (mode) { nilfs_segctor_do_construct(sci, mode); spin_lock(&sci->sc_state_lock); sci->sc_flush_request &= (mode == SC_FLUSH_FILE) ? ~FLUSH_FILE_BIT : ~FLUSH_DAT_BIT; spin_unlock(&sci->sc_state_lock); } clear_bit(NILFS_SC_PRIOR_FLUSH, &sci->sc_flags); } static int nilfs_segctor_flush_mode(struct nilfs_sc_info *sci) { if (!test_bit(NILFS_SC_UNCLOSED, &sci->sc_flags) || time_before(jiffies, sci->sc_lseg_stime + sci->sc_mjcp_freq)) { if (!(sci->sc_flush_request & ~FLUSH_FILE_BIT)) return SC_FLUSH_FILE; else if (!(sci->sc_flush_request & ~FLUSH_DAT_BIT)) return SC_FLUSH_DAT; } return SC_LSEG_SR; } /** * nilfs_log_write_required - determine whether log writing is required * @sci: nilfs_sc_info struct * @modep: location for storing log writing mode * * Return: true if log writing is required, false otherwise. If log writing * is required, the mode is stored in the location pointed to by @modep. */ static bool nilfs_log_write_required(struct nilfs_sc_info *sci, int *modep) { bool timedout, ret = true; spin_lock(&sci->sc_state_lock); timedout = ((sci->sc_state & NILFS_SEGCTOR_COMMIT) && time_after_eq(jiffies, sci->sc_timer.expires)); if (timedout || sci->sc_seq_request != sci->sc_seq_done) *modep = SC_LSEG_SR; else if (sci->sc_flush_request) *modep = nilfs_segctor_flush_mode(sci); else ret = false; spin_unlock(&sci->sc_state_lock); return ret; } /** * nilfs_segctor_thread - main loop of the log writer thread * @arg: pointer to a struct nilfs_sc_info. * * nilfs_segctor_thread() is the main loop function of the log writer kernel * thread, which determines whether log writing is necessary, and if so, * performs the log write in the background, or waits if not. It is also * used to decide the background writeback of the superblock. * * Return: Always 0. */ static int nilfs_segctor_thread(void *arg) { struct nilfs_sc_info *sci = (struct nilfs_sc_info *)arg; struct the_nilfs *nilfs = sci->sc_super->s_fs_info; nilfs_info(sci->sc_super, "segctord starting. Construction interval = %lu seconds, CP frequency < %lu seconds", sci->sc_interval / HZ, sci->sc_mjcp_freq / HZ); set_freezable(); while (!kthread_should_stop()) { DEFINE_WAIT(wait); bool should_write; int mode; if (freezing(current)) { try_to_freeze(); continue; } prepare_to_wait(&sci->sc_wait_daemon, &wait, TASK_INTERRUPTIBLE); should_write = nilfs_log_write_required(sci, &mode); if (!should_write) schedule(); finish_wait(&sci->sc_wait_daemon, &wait); if (nilfs_sb_dirty(nilfs) && nilfs_sb_need_update(nilfs)) set_nilfs_discontinued(nilfs); if (should_write) nilfs_segctor_thread_construct(sci, mode); } /* end sync. */ spin_lock(&sci->sc_state_lock); sci->sc_task = NULL; timer_shutdown_sync(&sci->sc_timer); spin_unlock(&sci->sc_state_lock); return 0; } /* * Setup & clean-up functions */ static struct nilfs_sc_info *nilfs_segctor_new(struct super_block *sb, struct nilfs_root *root) { struct the_nilfs *nilfs = sb->s_fs_info; struct nilfs_sc_info *sci; sci = kzalloc(sizeof(*sci), GFP_KERNEL); if (!sci) return NULL; sci->sc_super = sb; nilfs_get_root(root); sci->sc_root = root; init_waitqueue_head(&sci->sc_wait_request); init_waitqueue_head(&sci->sc_wait_daemon); spin_lock_init(&sci->sc_state_lock); INIT_LIST_HEAD(&sci->sc_dirty_files); INIT_LIST_HEAD(&sci->sc_segbufs); INIT_LIST_HEAD(&sci->sc_write_logs); INIT_LIST_HEAD(&sci->sc_gc_inodes); INIT_LIST_HEAD(&sci->sc_iput_queue); INIT_WORK(&sci->sc_iput_work, nilfs_iput_work_func); sci->sc_interval = HZ * NILFS_SC_DEFAULT_TIMEOUT; sci->sc_mjcp_freq = HZ * NILFS_SC_DEFAULT_SR_FREQ; sci->sc_watermark = NILFS_SC_DEFAULT_WATERMARK; if (nilfs->ns_interval) sci->sc_interval = HZ * nilfs->ns_interval; if (nilfs->ns_watermark) sci->sc_watermark = nilfs->ns_watermark; return sci; } static void nilfs_segctor_write_out(struct nilfs_sc_info *sci) { int ret, retrycount = NILFS_SC_CLEANUP_RETRY; /* * The segctord thread was stopped and its timer was removed. * But some tasks remain. */ do { struct nilfs_transaction_info ti; nilfs_transaction_lock(sci->sc_super, &ti, 0); ret = nilfs_segctor_construct(sci, SC_LSEG_SR); nilfs_transaction_unlock(sci->sc_super); flush_work(&sci->sc_iput_work); } while (ret && ret != -EROFS && retrycount-- > 0); } /** * nilfs_segctor_destroy - destroy the segment constructor. * @sci: nilfs_sc_info * * nilfs_segctor_destroy() kills the segctord thread and frees * the nilfs_sc_info struct. * Caller must hold the segment semaphore. */ static void nilfs_segctor_destroy(struct nilfs_sc_info *sci) { struct the_nilfs *nilfs = sci->sc_super->s_fs_info; int flag; up_write(&nilfs->ns_segctor_sem); if (sci->sc_task) { wake_up(&sci->sc_wait_daemon); kthread_stop(sci->sc_task); } spin_lock(&sci->sc_state_lock); flag = ((sci->sc_state & NILFS_SEGCTOR_COMMIT) || sci->sc_flush_request || sci->sc_seq_request != sci->sc_seq_done); spin_unlock(&sci->sc_state_lock); /* * Forcibly wake up tasks waiting in nilfs_segctor_sync(), which can * be called from delayed iput() via nilfs_evict_inode() and can race * with the above log writer thread termination. */ nilfs_segctor_wakeup(sci, 0, true); if (flush_work(&sci->sc_iput_work)) flag = true; if (flag || !nilfs_segctor_confirm(sci)) nilfs_segctor_write_out(sci); if (!list_empty(&sci->sc_dirty_files)) { nilfs_warn(sci->sc_super, "disposed unprocessed dirty file(s) when stopping log writer"); nilfs_dispose_list(nilfs, &sci->sc_dirty_files, 1); } if (!list_empty(&sci->sc_iput_queue)) { nilfs_warn(sci->sc_super, "disposed unprocessed inode(s) in iput queue when stopping log writer"); nilfs_dispose_list(nilfs, &sci->sc_iput_queue, 1); } WARN_ON(!list_empty(&sci->sc_segbufs)); WARN_ON(!list_empty(&sci->sc_write_logs)); nilfs_put_root(sci->sc_root); down_write(&nilfs->ns_segctor_sem); kfree(sci); } /** * nilfs_attach_log_writer - attach log writer * @sb: super block instance * @root: root object of the current filesystem tree * * This allocates a log writer object, initializes it, and starts the * log writer. * * Return: 0 on success, or the following negative error code on failure. * * %-EINTR - Log writer thread creation failed due to interruption. * * %-ENOMEM - Insufficient memory available. */ int nilfs_attach_log_writer(struct super_block *sb, struct nilfs_root *root) { struct the_nilfs *nilfs = sb->s_fs_info; struct nilfs_sc_info *sci; struct task_struct *t; int err; if (nilfs->ns_writer) { /* * This happens if the filesystem is made read-only by * __nilfs_error or nilfs_remount and then remounted * read/write. In these cases, reuse the existing * writer. */ return 0; } sci = nilfs_segctor_new(sb, root); if (unlikely(!sci)) return -ENOMEM; nilfs->ns_writer = sci; t = kthread_create(nilfs_segctor_thread, sci, "segctord"); if (IS_ERR(t)) { err = PTR_ERR(t); nilfs_err(sb, "error %d creating segctord thread", err); nilfs_detach_log_writer(sb); return err; } sci->sc_task = t; timer_setup(&sci->sc_timer, nilfs_construction_timeout, 0); wake_up_process(sci->sc_task); return 0; } /** * nilfs_detach_log_writer - destroy log writer * @sb: super block instance * * This kills log writer daemon, frees the log writer object, and * destroys list of dirty files. */ void nilfs_detach_log_writer(struct super_block *sb) { struct the_nilfs *nilfs = sb->s_fs_info; LIST_HEAD(garbage_list); down_write(&nilfs->ns_segctor_sem); if (nilfs->ns_writer) { nilfs_segctor_destroy(nilfs->ns_writer); nilfs->ns_writer = NULL; } set_nilfs_purging(nilfs); /* Force to free the list of dirty files */ spin_lock(&nilfs->ns_inode_lock); if (!list_empty(&nilfs->ns_dirty_files)) { list_splice_init(&nilfs->ns_dirty_files, &garbage_list); nilfs_warn(sb, "disposed unprocessed dirty file(s) when detaching log writer"); } spin_unlock(&nilfs->ns_inode_lock); up_write(&nilfs->ns_segctor_sem); nilfs_dispose_list(nilfs, &garbage_list, 1); clear_nilfs_purging(nilfs); }