/* * This file is part of UBIFS. * * Copyright (C) 2006-2008 Nokia Corporation. * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 as published by * the Free Software Foundation. * * This program is distributed in the hope that it will 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 to the Free Software Foundation, Inc., 51 * Franklin St, Fifth Floor, Boston, MA 02110-1301 USA * * Author: Adrian Hunter */ #include "ubifs.h" /* * An orphan is an inode number whose inode node has been committed to the index * with a link count of zero. That happens when an open file is deleted * (unlinked) and then a commit is run. In the normal course of events the inode * would be deleted when the file is closed. However in the case of an unclean * unmount, orphans need to be accounted for. After an unclean unmount, the * orphans' inodes must be deleted which means either scanning the entire index * looking for them, or keeping a list on flash somewhere. This unit implements * the latter approach. * * The orphan area is a fixed number of LEBs situated between the LPT area and * the main area. The number of orphan area LEBs is specified when the file * system is created. The minimum number is 1. The size of the orphan area * should be so that it can hold the maximum number of orphans that are expected * to ever exist at one time. * * The number of orphans that can fit in a LEB is: * * (c->leb_size - UBIFS_ORPH_NODE_SZ) / sizeof(__le64) * * For example: a 15872 byte LEB can fit 1980 orphans so 1 LEB may be enough. * * Orphans are accumulated in a rb-tree. When an inode's link count drops to * zero, the inode number is added to the rb-tree. It is removed from the tree * when the inode is deleted. Any new orphans that are in the orphan tree when * the commit is run, are written to the orphan area in 1 or more orphan nodes. * If the orphan area is full, it is consolidated to make space. There is * always enough space because validation prevents the user from creating more * than the maximum number of orphans allowed. */ #ifdef CONFIG_UBIFS_FS_DEBUG static int dbg_check_orphans(struct ubifs_info *c); #else #define dbg_check_orphans(c) 0 #endif /** * ubifs_add_orphan - add an orphan. * @c: UBIFS file-system description object * @inum: orphan inode number * * Add an orphan. This function is called when an inodes link count drops to * zero. */ int ubifs_add_orphan(struct ubifs_info *c, ino_t inum) { struct ubifs_orphan *orphan, *o; struct rb_node **p, *parent = NULL; orphan = kzalloc(sizeof(struct ubifs_orphan), GFP_NOFS); if (!orphan) return -ENOMEM; orphan->inum = inum; orphan->new = 1; spin_lock(&c->orphan_lock); if (c->tot_orphans >= c->max_orphans) { spin_unlock(&c->orphan_lock); kfree(orphan); return -ENFILE; } p = &c->orph_tree.rb_node; while (*p) { parent = *p; o = rb_entry(parent, struct ubifs_orphan, rb); if (inum < o->inum) p = &(*p)->rb_left; else if (inum > o->inum) p = &(*p)->rb_right; else { dbg_err("orphaned twice"); spin_unlock(&c->orphan_lock); kfree(orphan); return 0; } } c->tot_orphans += 1; c->new_orphans += 1; rb_link_node(&orphan->rb, parent, p); rb_insert_color(&orphan->rb, &c->orph_tree); list_add_tail(&orphan->list, &c->orph_list); list_add_tail(&orphan->new_list, &c->orph_new); spin_unlock(&c->orphan_lock); dbg_gen("ino %lu", (unsigned long)inum); return 0; } /** * ubifs_delete_orphan - delete an orphan. * @c: UBIFS file-system description object * @inum: orphan inode number * * Delete an orphan. This function is called when an inode is deleted. */ void ubifs_delete_orphan(struct ubifs_info *c, ino_t inum) { struct ubifs_orphan *o; struct rb_node *p; spin_lock(&c->orphan_lock); p = c->orph_tree.rb_node; while (p) { o = rb_entry(p, struct ubifs_orphan, rb); if (inum < o->inum) p = p->rb_left; else if (inum > o->inum) p = p->rb_right; else { if (o->dnext) { spin_unlock(&c->orphan_lock); dbg_gen("deleted twice ino %lu", (unsigned long)inum); return; } if (o->cnext) { o->dnext = c->orph_dnext; c->orph_dnext = o; spin_unlock(&c->orphan_lock); dbg_gen("delete later ino %lu", (unsigned long)inum); return; } rb_erase(p, &c->orph_tree); list_del(&o->list); c->tot_orphans -= 1; if (o->new) { list_del(&o->new_list); c->new_orphans -= 1; } spin_unlock(&c->orphan_lock); kfree(o); dbg_gen("inum %lu", (unsigned long)inum); return; } } spin_unlock(&c->orphan_lock); dbg_err("missing orphan ino %lu", (unsigned long)inum); dump_stack(); } /** * ubifs_orphan_start_commit - start commit of orphans. * @c: UBIFS file-system description object * * Start commit of orphans. */ int ubifs_orphan_start_commit(struct ubifs_info *c) { struct ubifs_orphan *orphan, **last; spin_lock(&c->orphan_lock); last = &c->orph_cnext; list_for_each_entry(orphan, &c->orph_new, new_list) { ubifs_assert(orphan->new); orphan->new = 0; *last = orphan; last = &orphan->cnext; } *last = orphan->cnext; c->cmt_orphans = c->new_orphans; c->new_orphans = 0; dbg_cmt("%d orphans to commit", c->cmt_orphans); INIT_LIST_HEAD(&c->orph_new); if (c->tot_orphans == 0) c->no_orphs = 1; else c->no_orphs = 0; spin_unlock(&c->orphan_lock); return 0; } /** * avail_orphs - calculate available space. * @c: UBIFS file-system description object * * This function returns the number of orphans that can be written in the * available space. */ static int avail_orphs(struct ubifs_info *c) { int avail_lebs, avail, gap; avail_lebs = c->orph_lebs - (c->ohead_lnum - c->orph_first) - 1; avail = avail_lebs * ((c->leb_size - UBIFS_ORPH_NODE_SZ) / sizeof(__le64)); gap = c->leb_size - c->ohead_offs; if (gap >= UBIFS_ORPH_NODE_SZ + sizeof(__le64)) avail += (gap - UBIFS_ORPH_NODE_SZ) / sizeof(__le64); return avail; } /** * tot_avail_orphs - calculate total space. * @c: UBIFS file-system description object * * This function returns the number of orphans that can be written in half * the total space. That leaves half the space for adding new orphans. */ static int tot_avail_orphs(struct ubifs_info *c) { int avail_lebs, avail; avail_lebs = c->orph_lebs; avail = avail_lebs * ((c->leb_size - UBIFS_ORPH_NODE_SZ) / sizeof(__le64)); return avail / 2; } /** * do_write_orph_node - write a node to the orphan head. * @c: UBIFS file-system description object * @len: length of node * @atomic: write atomically * * This function writes a node to the orphan head from the orphan buffer. If * %atomic is not zero, then the write is done atomically. On success, %0 is * returned, otherwise a negative error code is returned. */ static int do_write_orph_node(struct ubifs_info *c, int len, int atomic) { int err = 0; if (atomic) { ubifs_assert(c->ohead_offs == 0); ubifs_prepare_node(c, c->orph_buf, len, 1); len = ALIGN(len, c->min_io_size); err = ubifs_leb_change(c, c->ohead_lnum, c->orph_buf, len, UBI_SHORTTERM); } else { if (c->ohead_offs == 0) { /* Ensure LEB has been unmapped */ err = ubifs_leb_unmap(c, c->ohead_lnum); if (err) return err; } err = ubifs_write_node(c, c->orph_buf, len, c->ohead_lnum, c->ohead_offs, UBI_SHORTTERM); } return err; } /** * write_orph_node - write an orphan node. * @c: UBIFS file-system description object * @atomic: write atomically * * This function builds an orphan node from the cnext list and writes it to the * orphan head. On success, %0 is returned, otherwise a negative error code * is returned. */ static int write_orph_node(struct ubifs_info *c, int atomic) { struct ubifs_orphan *orphan, *cnext; struct ubifs_orph_node *orph; int gap, err, len, cnt, i; ubifs_assert(c->cmt_orphans > 0); gap = c->leb_size - c->ohead_offs; if (gap < UBIFS_ORPH_NODE_SZ + sizeof(__le64)) { c->ohead_lnum += 1; c->ohead_offs = 0; gap = c->leb_size; if (c->ohead_lnum > c->orph_last) { /* * We limit the number of orphans so that this should * never happen. */ ubifs_err("out of space in orphan area"); return -EINVAL; } } cnt = (gap - UBIFS_ORPH_NODE_SZ) / sizeof(__le64); if (cnt > c->cmt_orphans) cnt = c->cmt_orphans; len = UBIFS_ORPH_NODE_SZ + cnt * sizeof(__le64); ubifs_assert(c->orph_buf); orph = c->orph_buf; orph->ch.node_type = UBIFS_ORPH_NODE; spin_lock(&c->orphan_lock); cnext = c->orph_cnext; for (i = 0; i < cnt; i++) { orphan = cnext; orph->inos[i] = cpu_to_le64(orphan->inum); cnext = orphan->cnext; orphan->cnext = NULL; } c->orph_cnext = cnext; c->cmt_orphans -= cnt; spin_unlock(&c->orphan_lock); if (c->cmt_orphans) orph->cmt_no = cpu_to_le64(c->cmt_no); else /* Mark the last node of the commit */ orph->cmt_no = cpu_to_le64((c->cmt_no) | (1ULL << 63)); ubifs_assert(c->ohead_offs + len <= c->leb_size); ubifs_assert(c->ohead_lnum >= c->orph_first); ubifs_assert(c->ohead_lnum <= c->orph_last); err = do_write_orph_node(c, len, atomic); c->ohead_offs += ALIGN(len, c->min_io_size); c->ohead_offs = ALIGN(c->ohead_offs, 8); return err; } /** * write_orph_nodes - write orphan nodes until there are no more to commit. * @c: UBIFS file-system description object * @atomic: write atomically * * This function writes orphan nodes for all the orphans to commit. On success, * %0 is returned, otherwise a negative error code is returned. */ static int write_orph_nodes(struct ubifs_info *c, int atomic) { int err; while (c->cmt_orphans > 0) { err = write_orph_node(c, atomic); if (err) return err; } if (atomic) { int lnum; /* Unmap any unused LEBs after consolidation */ lnum = c->ohead_lnum + 1; for (lnum = c->ohead_lnum + 1; lnum <= c->orph_last; lnum++) { err = ubifs_leb_unmap(c, lnum); if (err) return err; } } return 0; } /** * consolidate - consolidate the orphan area. * @c: UBIFS file-system description object * * This function enables consolidation by putting all the orphans into the list * to commit. The list is in the order that the orphans were added, and the * LEBs are written atomically in order, so at no time can orphans be lost by * an unclean unmount. * * This function returns %0 on success and a negative error code on failure. */ static int consolidate(struct ubifs_info *c) { int tot_avail = tot_avail_orphs(c), err = 0; spin_lock(&c->orphan_lock); dbg_cmt("there is space for %d orphans and there are %d", tot_avail, c->tot_orphans); if (c->tot_orphans - c->new_orphans <= tot_avail) { struct ubifs_orphan *orphan, **last; int cnt = 0; /* Change the cnext list to include all non-new orphans */ last = &c->orph_cnext; list_for_each_entry(orphan, &c->orph_list, list) { if (orphan->new) continue; *last = orphan; last = &orphan->cnext; cnt += 1; } *last = orphan->cnext; ubifs_assert(cnt == c->tot_orphans - c->new_orphans); c->cmt_orphans = cnt; c->ohead_lnum = c->orph_first; c->ohead_offs = 0; } else { /* * We limit the number of orphans so that this should * never happen. */ ubifs_err("out of space in orphan area"); err = -EINVAL; } spin_unlock(&c->orphan_lock); return err; } /** * commit_orphans - commit orphans. * @c: UBIFS file-system description object * * This function commits orphans to flash. On success, %0 is returned, * otherwise a negative error code is returned. */ static int commit_orphans(struct ubifs_info *c) { int avail, atomic = 0, err; ubifs_assert(c->cmt_orphans > 0); avail = avail_orphs(c); if (avail < c->cmt_orphans) { /* Not enough space to write new orphans, so consolidate */ err = consolidate(c); if (err) return err; atomic = 1; } err = write_orph_nodes(c, atomic); return err; } /** * erase_deleted - erase the orphans marked for deletion. * @c: UBIFS file-system description object * * During commit, the orphans being committed cannot be deleted, so they are * marked for deletion and deleted by this function. Also, the recovery * adds killed orphans to the deletion list, and therefore they are deleted * here too. */ static void erase_deleted(struct ubifs_info *c) { struct ubifs_orphan *orphan, *dnext; spin_lock(&c->orphan_lock); dnext = c->orph_dnext; while (dnext) { orphan = dnext; dnext = orphan->dnext; ubifs_assert(!orphan->new); rb_erase(&orphan->rb, &c->orph_tree); list_del(&orphan->list); c->tot_orphans -= 1; dbg_gen("deleting orphan ino %lu", (unsigned long)orphan->inum); kfree(orphan); } c->orph_dnext = NULL; spin_unlock(&c->orphan_lock); } /** * ubifs_orphan_end_commit - end commit of orphans. * @c: UBIFS file-system description object * * End commit of orphans. */ int ubifs_orphan_end_commit(struct ubifs_info *c) { int err; if (c->cmt_orphans != 0) { err = commit_orphans(c); if (err) return err; } erase_deleted(c); err = dbg_check_orphans(c); return err; } /** * ubifs_clear_orphans - erase all LEBs used for orphans. * @c: UBIFS file-system description object * * If recovery is not required, then the orphans from the previous session * are not needed. This function locates the LEBs used to record * orphans, and un-maps them. */ int ubifs_clear_orphans(struct ubifs_info *c) { int lnum, err; for (lnum = c->orph_first; lnum <= c->orph_last; lnum++) { err = ubifs_leb_unmap(c, lnum); if (err) return err; } c->ohead_lnum = c->orph_first; c->ohead_offs = 0; return 0; } /** * insert_dead_orphan - insert an orphan. * @c: UBIFS file-system description object * @inum: orphan inode number * * This function is a helper to the 'do_kill_orphans()' function. The orphan * must be kept until the next commit, so it is added to the rb-tree and the * deletion list. */ static int insert_dead_orphan(struct ubifs_info *c, ino_t inum) { struct ubifs_orphan *orphan, *o; struct rb_node **p, *parent = NULL; orphan = kzalloc(sizeof(struct ubifs_orphan), GFP_KERNEL); if (!orphan) return -ENOMEM; orphan->inum = inum; p = &c->orph_tree.rb_node; while (*p) { parent = *p; o = rb_entry(parent, struct ubifs_orphan, rb); if (inum < o->inum) p = &(*p)->rb_left; else if (inum > o->inum) p = &(*p)->rb_right; else { /* Already added - no problem */ kfree(orphan); return 0; } } c->tot_orphans += 1; rb_link_node(&orphan->rb, parent, p); rb_insert_color(&orphan->rb, &c->orph_tree); list_add_tail(&orphan->list, &c->orph_list); orphan->dnext = c->orph_dnext; c->orph_dnext = orphan; dbg_mnt("ino %lu, new %d, tot %d", (unsigned long)inum, c->new_orphans, c->tot_orphans); return 0; } /** * do_kill_orphans - remove orphan inodes from the index. * @c: UBIFS file-system description object * @sleb: scanned LEB * @last_cmt_no: cmt_no of last orphan node read is passed and returned here * @outofdate: whether the LEB is out of date is returned here * @last_flagged: whether the end orphan node is encountered * * This function is a helper to the 'kill_orphans()' function. It goes through * every orphan node in a LEB and for every inode number recorded, removes * all keys for that inode from the TNC. */ static int do_kill_orphans(struct ubifs_info *c, struct ubifs_scan_leb *sleb, unsigned long long *last_cmt_no, int *outofdate, int *last_flagged) { struct ubifs_scan_node *snod; struct ubifs_orph_node *orph; unsigned long long cmt_no; ino_t inum; int i, n, err, first = 1; list_for_each_entry(snod, &sleb->nodes, list) { if (snod->type != UBIFS_ORPH_NODE) { ubifs_err("invalid node type %d in orphan area at " "%d:%d", snod->type, sleb->lnum, snod->offs); ubifs_dump_node(c, snod->node); return -EINVAL; } orph = snod->node; /* Check commit number */ cmt_no = le64_to_cpu(orph->cmt_no) & LLONG_MAX; /* * The commit number on the master node may be less, because * of a failed commit. If there are several failed commits in a * row, the commit number written on orphan nodes will continue * to increase (because the commit number is adjusted here) even * though the commit number on the master node stays the same * because the master node has not been re-written. */ if (cmt_no > c->cmt_no) c->cmt_no = cmt_no; if (cmt_no < *last_cmt_no && *last_flagged) { /* * The last orphan node had a higher commit number and * was flagged as the last written for that commit * number. That makes this orphan node, out of date. */ if (!first) { ubifs_err("out of order commit number %llu in " "orphan node at %d:%d", cmt_no, sleb->lnum, snod->offs); ubifs_dump_node(c, snod->node); return -EINVAL; } dbg_rcvry("out of date LEB %d", sleb->lnum); *outofdate = 1; return 0; } if (first) first = 0; n = (le32_to_cpu(orph->ch.len) - UBIFS_ORPH_NODE_SZ) >> 3; for (i = 0; i < n; i++) { inum = le64_to_cpu(orph->inos[i]); dbg_rcvry("deleting orphaned inode %lu", (unsigned long)inum); err = ubifs_tnc_remove_ino(c, inum); if (err) return err; err = insert_dead_orphan(c, inum); if (err) return err; } *last_cmt_no = cmt_no; if (le64_to_cpu(orph->cmt_no) & (1ULL << 63)) { dbg_rcvry("last orph node for commit %llu at %d:%d", cmt_no, sleb->lnum, snod->offs); *last_flagged = 1; } else *last_flagged = 0; } return 0; } /** * kill_orphans - remove all orphan inodes from the index. * @c: UBIFS file-system description object * * If recovery is required, then orphan inodes recorded during the previous * session (which ended with an unclean unmount) must be deleted from the index. * This is done by updating the TNC, but since the index is not updated until * the next commit, the LEBs where the orphan information is recorded are not * erased until the next commit. */ static int kill_orphans(struct ubifs_info *c) { unsigned long long last_cmt_no = 0; int lnum, err = 0, outofdate = 0, last_flagged = 0; c->ohead_lnum = c->orph_first; c->ohead_offs = 0; /* Check no-orphans flag and skip this if no orphans */ if (c->no_orphs) { dbg_rcvry("no orphans"); return 0; } /* * Orph nodes always start at c->orph_first and are written to each * successive LEB in turn. Generally unused LEBs will have been unmapped * but may contain out of date orphan nodes if the unmap didn't go * through. In addition, the last orphan node written for each commit is * marked (top bit of orph->cmt_no is set to 1). It is possible that * there are orphan nodes from the next commit (i.e. the commit did not * complete successfully). In that case, no orphans will have been lost * due to the way that orphans are written, and any orphans added will * be valid orphans anyway and so can be deleted. */ for (lnum = c->orph_first; lnum <= c->orph_last; lnum++) { struct ubifs_scan_leb *sleb; dbg_rcvry("LEB %d", lnum); sleb = ubifs_scan(c, lnum, 0, c->sbuf, 1); if (IS_ERR(sleb)) { if (PTR_ERR(sleb) == -EUCLEAN) sleb = ubifs_recover_leb(c, lnum, 0, c->sbuf, -1); if (IS_ERR(sleb)) { err = PTR_ERR(sleb); break; } } err = do_kill_orphans(c, sleb, &last_cmt_no, &outofdate, &last_flagged); if (err || outofdate) { ubifs_scan_destroy(sleb); break; } if (sleb->endpt) { c->ohead_lnum = lnum; c->ohead_offs = sleb->endpt; } ubifs_scan_destroy(sleb); } return err; } /** * ubifs_mount_orphans - delete orphan inodes and erase LEBs that recorded them. * @c: UBIFS file-system description object * @unclean: indicates recovery from unclean unmount * @read_only: indicates read only mount * * This function is called when mounting to erase orphans from the previous * session. If UBIFS was not unmounted cleanly, then the inodes recorded as * orphans are deleted. */ int ubifs_mount_orphans(struct ubifs_info *c, int unclean, int read_only) { int err = 0; c->max_orphans = tot_avail_orphs(c); if (!read_only) { c->orph_buf = vmalloc(c->leb_size); if (!c->orph_buf) return -ENOMEM; } if (unclean) err = kill_orphans(c); else if (!read_only) err = ubifs_clear_orphans(c); return err; } #ifdef CONFIG_UBIFS_FS_DEBUG struct check_orphan { struct rb_node rb; ino_t inum; }; struct check_info { unsigned long last_ino; unsigned long tot_inos; unsigned long missing; unsigned long long leaf_cnt; struct ubifs_ino_node *node; struct rb_root root; }; static int dbg_find_orphan(struct ubifs_info *c, ino_t inum) { struct ubifs_orphan *o; struct rb_node *p; spin_lock(&c->orphan_lock); p = c->orph_tree.rb_node; while (p) { o = rb_entry(p, struct ubifs_orphan, rb); if (inum < o->inum) p = p->rb_left; else if (inum > o->inum) p = p->rb_right; else { spin_unlock(&c->orphan_lock); return 1; } } spin_unlock(&c->orphan_lock); return 0; } static int dbg_ins_check_orphan(struct rb_root *root, ino_t inum) { struct check_orphan *orphan, *o; struct rb_node **p, *parent = NULL; orphan = kzalloc(sizeof(struct check_orphan), GFP_NOFS); if (!orphan) return -ENOMEM; orphan->inum = inum; p = &root->rb_node; while (*p) { parent = *p; o = rb_entry(parent, struct check_orphan, rb); if (inum < o->inum) p = &(*p)->rb_left; else if (inum > o->inum) p = &(*p)->rb_right; else { kfree(orphan); return 0; } } rb_link_node(&orphan->rb, parent, p); rb_insert_color(&orphan->rb, root); return 0; } static int dbg_find_check_orphan(struct rb_root *root, ino_t inum) { struct check_orphan *o; struct rb_node *p; p = root->rb_node; while (p) { o = rb_entry(p, struct check_orphan, rb); if (inum < o->inum) p = p->rb_left; else if (inum > o->inum) p = p->rb_right; else return 1; } return 0; } static void dbg_free_check_tree(struct rb_root *root) { struct rb_node *this = root->rb_node; struct check_orphan *o; while (this) { if (this->rb_left) { this = this->rb_left; continue; } else if (this->rb_right) { this = this->rb_right; continue; } o = rb_entry(this, struct check_orphan, rb); this = rb_parent(this); if (this) { if (this->rb_left == &o->rb) this->rb_left = NULL; else this->rb_right = NULL; } kfree(o); } } static int dbg_orphan_check(struct ubifs_info *c, struct ubifs_zbranch *zbr, void *priv) { struct check_info *ci = priv; ino_t inum; int err; inum = key_inum(c, &zbr->key); if (inum != ci->last_ino) { /* Lowest node type is the inode node, so it comes first */ if (key_type(c, &zbr->key) != UBIFS_INO_KEY) ubifs_err("found orphan node ino %lu, type %d", (unsigned long)inum, key_type(c, &zbr->key)); ci->last_ino = inum; ci->tot_inos += 1; err = ubifs_tnc_read_node(c, zbr, ci->node); if (err) { ubifs_err("node read failed, error %d", err); return err; } if (ci->node->nlink == 0) /* Must be recorded as an orphan */ if (!dbg_find_check_orphan(&ci->root, inum) && !dbg_find_orphan(c, inum)) { ubifs_err("missing orphan, ino %lu", (unsigned long)inum); ci->missing += 1; } } ci->leaf_cnt += 1; return 0; } static int dbg_read_orphans(struct check_info *ci, struct ubifs_scan_leb *sleb) { struct ubifs_scan_node *snod; struct ubifs_orph_node *orph; ino_t inum; int i, n, err; list_for_each_entry(snod, &sleb->nodes, list) { cond_resched(); if (snod->type != UBIFS_ORPH_NODE) continue; orph = snod->node; n = (le32_to_cpu(orph->ch.len) - UBIFS_ORPH_NODE_SZ) >> 3; for (i = 0; i < n; i++) { inum = le64_to_cpu(orph->inos[i]); err = dbg_ins_check_orphan(&ci->root, inum); if (err) return err; } } return 0; } static int dbg_scan_orphans(struct ubifs_info *c, struct check_info *ci) { int lnum, err = 0; void *buf; /* Check no-orphans flag and skip this if no orphans */ if (c->no_orphs) return 0; buf = __vmalloc(c->leb_size, GFP_NOFS, PAGE_KERNEL); if (!buf) { ubifs_err("cannot allocate memory to check orphans"); return 0; } for (lnum = c->orph_first; lnum <= c->orph_last; lnum++) { struct ubifs_scan_leb *sleb; sleb = ubifs_scan(c, lnum, 0, buf, 0); if (IS_ERR(sleb)) { err = PTR_ERR(sleb); break; } err = dbg_read_orphans(ci, sleb); ubifs_scan_destroy(sleb); if (err) break; } vfree(buf); return err; } static int dbg_check_orphans(struct ubifs_info *c) { struct check_info ci; int err; if (!dbg_is_chk_orph(c)) return 0; ci.last_ino = 0; ci.tot_inos = 0; ci.missing = 0; ci.leaf_cnt = 0; ci.root = RB_ROOT; ci.node = kmalloc(UBIFS_MAX_INO_NODE_SZ, GFP_NOFS); if (!ci.node) { ubifs_err("out of memory"); return -ENOMEM; } err = dbg_scan_orphans(c, &ci); if (err) goto out; err = dbg_walk_index(c, &dbg_orphan_check, NULL, &ci); if (err) { ubifs_err("cannot scan TNC, error %d", err); goto out; } if (ci.missing) { ubifs_err("%lu missing orphan(s)", ci.missing); err = -EINVAL; goto out; } dbg_cmt("last inode number is %lu", ci.last_ino); dbg_cmt("total number of inodes is %lu", ci.tot_inos); dbg_cmt("total number of leaf nodes is %llu", ci.leaf_cnt); out: dbg_free_check_tree(&ci.root); kfree(ci.node); return err; } #endif /* CONFIG_UBIFS_FS_DEBUG */