/* * Copyright (c) 2017 Christoph Hellwig. * * This program is free software; you can redistribute it and/or modify it * under the terms and conditions of the GNU General Public License, * version 2, as published by the Free Software Foundation. * * This program is distributed in the hope 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. */ #include #include #include #include "xfs.h" #include "xfs_format.h" #include "xfs_bit.h" #include "xfs_log_format.h" #include "xfs_inode.h" #include "xfs_inode_fork.h" #include "xfs_trans_resv.h" #include "xfs_mount.h" #include "xfs_trace.h" /* * In-core extent record layout: * * +-------+----------------------------+ * | 00:53 | all 54 bits of startoff | * | 54:63 | low 10 bits of startblock | * +-------+----------------------------+ * | 00:20 | all 21 bits of length | * | 21 | unwritten extent bit | * | 22:63 | high 42 bits of startblock | * +-------+----------------------------+ */ #define XFS_IEXT_STARTOFF_MASK xfs_mask64lo(BMBT_STARTOFF_BITLEN) #define XFS_IEXT_LENGTH_MASK xfs_mask64lo(BMBT_BLOCKCOUNT_BITLEN) #define XFS_IEXT_STARTBLOCK_MASK xfs_mask64lo(BMBT_STARTBLOCK_BITLEN) struct xfs_iext_rec { uint64_t lo; uint64_t hi; }; /* * Given that the length can't be a zero, only an empty hi value indicates an * unused record. */ static bool xfs_iext_rec_is_empty(struct xfs_iext_rec *rec) { return rec->hi == 0; } static inline void xfs_iext_rec_clear(struct xfs_iext_rec *rec) { rec->lo = 0; rec->hi = 0; } static void xfs_iext_set( struct xfs_iext_rec *rec, struct xfs_bmbt_irec *irec) { ASSERT((irec->br_startoff & ~XFS_IEXT_STARTOFF_MASK) == 0); ASSERT((irec->br_blockcount & ~XFS_IEXT_LENGTH_MASK) == 0); ASSERT((irec->br_startblock & ~XFS_IEXT_STARTBLOCK_MASK) == 0); rec->lo = irec->br_startoff & XFS_IEXT_STARTOFF_MASK; rec->hi = irec->br_blockcount & XFS_IEXT_LENGTH_MASK; rec->lo |= (irec->br_startblock << 54); rec->hi |= ((irec->br_startblock & ~xfs_mask64lo(10)) << (22 - 10)); if (irec->br_state == XFS_EXT_UNWRITTEN) rec->hi |= (1 << 21); } static void xfs_iext_get( struct xfs_bmbt_irec *irec, struct xfs_iext_rec *rec) { irec->br_startoff = rec->lo & XFS_IEXT_STARTOFF_MASK; irec->br_blockcount = rec->hi & XFS_IEXT_LENGTH_MASK; irec->br_startblock = rec->lo >> 54; irec->br_startblock |= (rec->hi & xfs_mask64hi(42)) >> (22 - 10); if (rec->hi & (1 << 21)) irec->br_state = XFS_EXT_UNWRITTEN; else irec->br_state = XFS_EXT_NORM; } enum { NODE_SIZE = 256, KEYS_PER_NODE = NODE_SIZE / (sizeof(uint64_t) + sizeof(void *)), RECS_PER_LEAF = (NODE_SIZE - (2 * sizeof(struct xfs_iext_leaf *))) / sizeof(struct xfs_iext_rec), }; /* * In-core extent btree block layout: * * There are two types of blocks in the btree: leaf and inner (non-leaf) blocks. * * The leaf blocks are made up by %KEYS_PER_NODE extent records, which each * contain the startoffset, blockcount, startblock and unwritten extent flag. * See above for the exact format, followed by pointers to the previous and next * leaf blocks (if there are any). * * The inner (non-leaf) blocks first contain KEYS_PER_NODE lookup keys, followed * by an equal number of pointers to the btree blocks at the next lower level. * * +-------+-------+-------+-------+-------+----------+----------+ * Leaf: | rec 1 | rec 2 | rec 3 | rec 4 | rec N | prev-ptr | next-ptr | * +-------+-------+-------+-------+-------+----------+----------+ * * +-------+-------+-------+-------+-------+-------+------+-------+ * Inner: | key 1 | key 2 | key 3 | key N | ptr 1 | ptr 2 | ptr3 | ptr N | * +-------+-------+-------+-------+-------+-------+------+-------+ */ struct xfs_iext_node { uint64_t keys[KEYS_PER_NODE]; #define XFS_IEXT_KEY_INVALID (1ULL << 63) void *ptrs[KEYS_PER_NODE]; }; struct xfs_iext_leaf { struct xfs_iext_rec recs[RECS_PER_LEAF]; struct xfs_iext_leaf *prev; struct xfs_iext_leaf *next; }; inline xfs_extnum_t xfs_iext_count(struct xfs_ifork *ifp) { return ifp->if_bytes / sizeof(struct xfs_iext_rec); } static inline int xfs_iext_max_recs(struct xfs_ifork *ifp) { if (ifp->if_height == 1) return xfs_iext_count(ifp); return RECS_PER_LEAF; } static inline struct xfs_iext_rec *cur_rec(struct xfs_iext_cursor *cur) { return &cur->leaf->recs[cur->pos]; } static inline bool xfs_iext_valid(struct xfs_ifork *ifp, struct xfs_iext_cursor *cur) { if (!cur->leaf) return false; if (cur->pos < 0 || cur->pos >= xfs_iext_max_recs(ifp)) return false; if (xfs_iext_rec_is_empty(cur_rec(cur))) return false; return true; } static void * xfs_iext_find_first_leaf( struct xfs_ifork *ifp) { struct xfs_iext_node *node = ifp->if_u1.if_root; int height; if (!ifp->if_height) return NULL; for (height = ifp->if_height; height > 1; height--) { node = node->ptrs[0]; ASSERT(node); } return node; } static void * xfs_iext_find_last_leaf( struct xfs_ifork *ifp) { struct xfs_iext_node *node = ifp->if_u1.if_root; int height, i; if (!ifp->if_height) return NULL; for (height = ifp->if_height; height > 1; height--) { for (i = 1; i < KEYS_PER_NODE; i++) if (!node->ptrs[i]) break; node = node->ptrs[i - 1]; ASSERT(node); } return node; } void xfs_iext_first( struct xfs_ifork *ifp, struct xfs_iext_cursor *cur) { cur->pos = 0; cur->leaf = xfs_iext_find_first_leaf(ifp); } void xfs_iext_last( struct xfs_ifork *ifp, struct xfs_iext_cursor *cur) { int i; cur->leaf = xfs_iext_find_last_leaf(ifp); if (!cur->leaf) { cur->pos = 0; return; } for (i = 1; i < xfs_iext_max_recs(ifp); i++) { if (xfs_iext_rec_is_empty(&cur->leaf->recs[i])) break; } cur->pos = i - 1; } void xfs_iext_next( struct xfs_ifork *ifp, struct xfs_iext_cursor *cur) { if (!cur->leaf) { ASSERT(cur->pos <= 0 || cur->pos >= RECS_PER_LEAF); xfs_iext_first(ifp, cur); return; } ASSERT(cur->pos >= 0); ASSERT(cur->pos < xfs_iext_max_recs(ifp)); cur->pos++; if (ifp->if_height > 1 && !xfs_iext_valid(ifp, cur) && cur->leaf->next) { cur->leaf = cur->leaf->next; cur->pos = 0; } } void xfs_iext_prev( struct xfs_ifork *ifp, struct xfs_iext_cursor *cur) { if (!cur->leaf) { ASSERT(cur->pos <= 0 || cur->pos >= RECS_PER_LEAF); xfs_iext_last(ifp, cur); return; } ASSERT(cur->pos >= 0); ASSERT(cur->pos <= RECS_PER_LEAF); recurse: do { cur->pos--; if (xfs_iext_valid(ifp, cur)) return; } while (cur->pos > 0); if (ifp->if_height > 1 && cur->leaf->prev) { cur->leaf = cur->leaf->prev; cur->pos = RECS_PER_LEAF; goto recurse; } } static inline int xfs_iext_key_cmp( struct xfs_iext_node *node, int n, xfs_fileoff_t offset) { if (node->keys[n] > offset) return 1; if (node->keys[n] < offset) return -1; return 0; } static inline int xfs_iext_rec_cmp( struct xfs_iext_rec *rec, xfs_fileoff_t offset) { uint64_t rec_offset = rec->lo & XFS_IEXT_STARTOFF_MASK; uint32_t rec_len = rec->hi & XFS_IEXT_LENGTH_MASK; if (rec_offset > offset) return 1; if (rec_offset + rec_len <= offset) return -1; return 0; } static void * xfs_iext_find_level( struct xfs_ifork *ifp, xfs_fileoff_t offset, int level) { struct xfs_iext_node *node = ifp->if_u1.if_root; int height, i; if (!ifp->if_height) return NULL; for (height = ifp->if_height; height > level; height--) { for (i = 1; i < KEYS_PER_NODE; i++) if (xfs_iext_key_cmp(node, i, offset) > 0) break; node = node->ptrs[i - 1]; if (!node) break; } return node; } static int xfs_iext_node_pos( struct xfs_iext_node *node, xfs_fileoff_t offset) { int i; for (i = 1; i < KEYS_PER_NODE; i++) { if (xfs_iext_key_cmp(node, i, offset) > 0) break; } return i - 1; } static int xfs_iext_node_insert_pos( struct xfs_iext_node *node, xfs_fileoff_t offset) { int i; for (i = 0; i < KEYS_PER_NODE; i++) { if (xfs_iext_key_cmp(node, i, offset) > 0) return i; } return KEYS_PER_NODE; } static int xfs_iext_node_nr_entries( struct xfs_iext_node *node, int start) { int i; for (i = start; i < KEYS_PER_NODE; i++) { if (node->keys[i] == XFS_IEXT_KEY_INVALID) break; } return i; } static int xfs_iext_leaf_nr_entries( struct xfs_ifork *ifp, struct xfs_iext_leaf *leaf, int start) { int i; for (i = start; i < xfs_iext_max_recs(ifp); i++) { if (xfs_iext_rec_is_empty(&leaf->recs[i])) break; } return i; } static inline uint64_t xfs_iext_leaf_key( struct xfs_iext_leaf *leaf, int n) { return leaf->recs[n].lo & XFS_IEXT_STARTOFF_MASK; } static void xfs_iext_grow( struct xfs_ifork *ifp) { struct xfs_iext_node *node = kmem_zalloc(NODE_SIZE, KM_NOFS); int i; if (ifp->if_height == 1) { struct xfs_iext_leaf *prev = ifp->if_u1.if_root; node->keys[0] = xfs_iext_leaf_key(prev, 0); node->ptrs[0] = prev; } else { struct xfs_iext_node *prev = ifp->if_u1.if_root; ASSERT(ifp->if_height > 1); node->keys[0] = prev->keys[0]; node->ptrs[0] = prev; } for (i = 1; i < KEYS_PER_NODE; i++) node->keys[i] = XFS_IEXT_KEY_INVALID; ifp->if_u1.if_root = node; ifp->if_height++; } static void xfs_iext_update_node( struct xfs_ifork *ifp, xfs_fileoff_t old_offset, xfs_fileoff_t new_offset, int level, void *ptr) { struct xfs_iext_node *node = ifp->if_u1.if_root; int height, i; for (height = ifp->if_height; height > level; height--) { for (i = 0; i < KEYS_PER_NODE; i++) { if (i > 0 && xfs_iext_key_cmp(node, i, old_offset) > 0) break; if (node->keys[i] == old_offset) node->keys[i] = new_offset; } node = node->ptrs[i - 1]; ASSERT(node); } ASSERT(node == ptr); } static struct xfs_iext_node * xfs_iext_split_node( struct xfs_iext_node **nodep, int *pos, int *nr_entries) { struct xfs_iext_node *node = *nodep; struct xfs_iext_node *new = kmem_zalloc(NODE_SIZE, KM_NOFS); const int nr_move = KEYS_PER_NODE / 2; int nr_keep = nr_move + (KEYS_PER_NODE & 1); int i = 0; /* for sequential append operations just spill over into the new node */ if (*pos == KEYS_PER_NODE) { *nodep = new; *pos = 0; *nr_entries = 0; goto done; } for (i = 0; i < nr_move; i++) { new->keys[i] = node->keys[nr_keep + i]; new->ptrs[i] = node->ptrs[nr_keep + i]; node->keys[nr_keep + i] = XFS_IEXT_KEY_INVALID; node->ptrs[nr_keep + i] = NULL; } if (*pos >= nr_keep) { *nodep = new; *pos -= nr_keep; *nr_entries = nr_move; } else { *nr_entries = nr_keep; } done: for (; i < KEYS_PER_NODE; i++) new->keys[i] = XFS_IEXT_KEY_INVALID; return new; } static void xfs_iext_insert_node( struct xfs_ifork *ifp, uint64_t offset, void *ptr, int level) { struct xfs_iext_node *node, *new; int i, pos, nr_entries; again: if (ifp->if_height < level) xfs_iext_grow(ifp); new = NULL; node = xfs_iext_find_level(ifp, offset, level); pos = xfs_iext_node_insert_pos(node, offset); nr_entries = xfs_iext_node_nr_entries(node, pos); ASSERT(pos >= nr_entries || xfs_iext_key_cmp(node, pos, offset) != 0); ASSERT(nr_entries <= KEYS_PER_NODE); if (nr_entries == KEYS_PER_NODE) new = xfs_iext_split_node(&node, &pos, &nr_entries); /* * Update the pointers in higher levels if the first entry changes * in an existing node. */ if (node != new && pos == 0 && nr_entries > 0) xfs_iext_update_node(ifp, node->keys[0], offset, level, node); for (i = nr_entries; i > pos; i--) { node->keys[i] = node->keys[i - 1]; node->ptrs[i] = node->ptrs[i - 1]; } node->keys[pos] = offset; node->ptrs[pos] = ptr; if (new) { offset = new->keys[0]; ptr = new; level++; goto again; } } static struct xfs_iext_leaf * xfs_iext_split_leaf( struct xfs_iext_cursor *cur, int *nr_entries) { struct xfs_iext_leaf *leaf = cur->leaf; struct xfs_iext_leaf *new = kmem_zalloc(NODE_SIZE, KM_NOFS); const int nr_move = RECS_PER_LEAF / 2; int nr_keep = nr_move + (RECS_PER_LEAF & 1); int i; /* for sequential append operations just spill over into the new node */ if (cur->pos == RECS_PER_LEAF) { cur->leaf = new; cur->pos = 0; *nr_entries = 0; goto done; } for (i = 0; i < nr_move; i++) { new->recs[i] = leaf->recs[nr_keep + i]; xfs_iext_rec_clear(&leaf->recs[nr_keep + i]); } if (cur->pos >= nr_keep) { cur->leaf = new; cur->pos -= nr_keep; *nr_entries = nr_move; } else { *nr_entries = nr_keep; } done: if (leaf->next) leaf->next->prev = new; new->next = leaf->next; new->prev = leaf; leaf->next = new; return new; } static void xfs_iext_alloc_root( struct xfs_ifork *ifp, struct xfs_iext_cursor *cur) { ASSERT(ifp->if_bytes == 0); ifp->if_u1.if_root = kmem_zalloc(sizeof(struct xfs_iext_rec), KM_NOFS); ifp->if_height = 1; /* now that we have a node step into it */ cur->leaf = ifp->if_u1.if_root; cur->pos = 0; } static void xfs_iext_realloc_root( struct xfs_ifork *ifp, struct xfs_iext_cursor *cur) { size_t new_size = ifp->if_bytes + sizeof(struct xfs_iext_rec); void *new; /* account for the prev/next pointers */ if (new_size / sizeof(struct xfs_iext_rec) == RECS_PER_LEAF) new_size = NODE_SIZE; new = kmem_realloc(ifp->if_u1.if_root, new_size, KM_NOFS); memset(new + ifp->if_bytes, 0, new_size - ifp->if_bytes); ifp->if_u1.if_root = new; cur->leaf = new; } void xfs_iext_insert( struct xfs_inode *ip, struct xfs_iext_cursor *cur, struct xfs_bmbt_irec *irec, int state) { struct xfs_ifork *ifp = xfs_iext_state_to_fork(ip, state); xfs_fileoff_t offset = irec->br_startoff; struct xfs_iext_leaf *new = NULL; int nr_entries, i; trace_xfs_iext_insert(ip, cur, state, _RET_IP_); if (ifp->if_height == 0) xfs_iext_alloc_root(ifp, cur); else if (ifp->if_height == 1) xfs_iext_realloc_root(ifp, cur); nr_entries = xfs_iext_leaf_nr_entries(ifp, cur->leaf, cur->pos); ASSERT(nr_entries <= RECS_PER_LEAF); ASSERT(cur->pos >= nr_entries || xfs_iext_rec_cmp(cur_rec(cur), irec->br_startoff) != 0); if (nr_entries == RECS_PER_LEAF) new = xfs_iext_split_leaf(cur, &nr_entries); /* * Update the pointers in higher levels if the first entry changes * in an existing node. */ if (cur->leaf != new && cur->pos == 0 && nr_entries > 0) { xfs_iext_update_node(ifp, xfs_iext_leaf_key(cur->leaf, 0), offset, 1, cur->leaf); } for (i = nr_entries; i > cur->pos; i--) cur->leaf->recs[i] = cur->leaf->recs[i - 1]; xfs_iext_set(cur_rec(cur), irec); ifp->if_bytes += sizeof(struct xfs_iext_rec); if (new) xfs_iext_insert_node(ifp, xfs_iext_leaf_key(new, 0), new, 2); } static struct xfs_iext_node * xfs_iext_rebalance_node( struct xfs_iext_node *parent, int *pos, struct xfs_iext_node *node, int nr_entries) { /* * If the neighbouring nodes are completely full, or have different * parents, we might never be able to merge our node, and will only * delete it once the number of entries hits zero. */ if (nr_entries == 0) return node; if (*pos > 0) { struct xfs_iext_node *prev = parent->ptrs[*pos - 1]; int nr_prev = xfs_iext_node_nr_entries(prev, 0), i; if (nr_prev + nr_entries <= KEYS_PER_NODE) { for (i = 0; i < nr_entries; i++) { prev->keys[nr_prev + i] = node->keys[i]; prev->ptrs[nr_prev + i] = node->ptrs[i]; } return node; } } if (*pos + 1 < xfs_iext_node_nr_entries(parent, *pos)) { struct xfs_iext_node *next = parent->ptrs[*pos + 1]; int nr_next = xfs_iext_node_nr_entries(next, 0), i; if (nr_entries + nr_next <= KEYS_PER_NODE) { /* * Merge the next node into this node so that we don't * have to do an additional update of the keys in the * higher levels. */ for (i = 0; i < nr_next; i++) { node->keys[nr_entries + i] = next->keys[i]; node->ptrs[nr_entries + i] = next->ptrs[i]; } ++*pos; return next; } } return NULL; } static void xfs_iext_remove_node( struct xfs_ifork *ifp, xfs_fileoff_t offset, void *victim) { struct xfs_iext_node *node, *parent; int level = 2, pos, nr_entries, i; ASSERT(level <= ifp->if_height); node = xfs_iext_find_level(ifp, offset, level); pos = xfs_iext_node_pos(node, offset); again: ASSERT(node->ptrs[pos]); ASSERT(node->ptrs[pos] == victim); kmem_free(victim); nr_entries = xfs_iext_node_nr_entries(node, pos) - 1; offset = node->keys[0]; for (i = pos; i < nr_entries; i++) { node->keys[i] = node->keys[i + 1]; node->ptrs[i] = node->ptrs[i + 1]; } node->keys[nr_entries] = XFS_IEXT_KEY_INVALID; node->ptrs[nr_entries] = NULL; if (pos == 0 && nr_entries > 0) { xfs_iext_update_node(ifp, offset, node->keys[0], level, node); offset = node->keys[0]; } if (nr_entries >= KEYS_PER_NODE / 2) return; if (level < ifp->if_height) { /* * If we aren't at the root yet try to find a neighbour node to * merge with (or delete the node if it is empty), and then * recurse up to the next level. */ level++; parent = xfs_iext_find_level(ifp, offset, level); pos = xfs_iext_node_pos(parent, offset); ASSERT(pos != KEYS_PER_NODE); ASSERT(parent->ptrs[pos] == node); node = xfs_iext_rebalance_node(parent, &pos, node, nr_entries); if (node) { victim = node; node = parent; goto again; } } else if (nr_entries == 1) { /* * If we are at the root and only one entry is left we can just * free this node and update the root pointer. */ ASSERT(node == ifp->if_u1.if_root); ifp->if_u1.if_root = node->ptrs[0]; ifp->if_height--; kmem_free(node); } } static void xfs_iext_rebalance_leaf( struct xfs_ifork *ifp, struct xfs_iext_cursor *cur, struct xfs_iext_leaf *leaf, xfs_fileoff_t offset, int nr_entries) { /* * If the neighbouring nodes are completely full we might never be able * to merge our node, and will only delete it once the number of * entries hits zero. */ if (nr_entries == 0) goto remove_node; if (leaf->prev) { int nr_prev = xfs_iext_leaf_nr_entries(ifp, leaf->prev, 0), i; if (nr_prev + nr_entries <= RECS_PER_LEAF) { for (i = 0; i < nr_entries; i++) leaf->prev->recs[nr_prev + i] = leaf->recs[i]; if (cur->leaf == leaf) { cur->leaf = leaf->prev; cur->pos += nr_prev; } goto remove_node; } } if (leaf->next) { int nr_next = xfs_iext_leaf_nr_entries(ifp, leaf->next, 0), i; if (nr_entries + nr_next <= RECS_PER_LEAF) { /* * Merge the next node into this node so that we don't * have to do an additional update of the keys in the * higher levels. */ for (i = 0; i < nr_next; i++) { leaf->recs[nr_entries + i] = leaf->next->recs[i]; } if (cur->leaf == leaf->next) { cur->leaf = leaf; cur->pos += nr_entries; } offset = xfs_iext_leaf_key(leaf->next, 0); leaf = leaf->next; goto remove_node; } } return; remove_node: if (leaf->prev) leaf->prev->next = leaf->next; if (leaf->next) leaf->next->prev = leaf->prev; xfs_iext_remove_node(ifp, offset, leaf); } static void xfs_iext_free_last_leaf( struct xfs_ifork *ifp) { ifp->if_u1.if_root = NULL; ifp->if_height--; kmem_free(ifp->if_u1.if_root); } void xfs_iext_remove( struct xfs_inode *ip, struct xfs_iext_cursor *cur, int state) { struct xfs_ifork *ifp = xfs_iext_state_to_fork(ip, state); struct xfs_iext_leaf *leaf = cur->leaf; xfs_fileoff_t offset = xfs_iext_leaf_key(leaf, 0); int i, nr_entries; trace_xfs_iext_remove(ip, cur, state, _RET_IP_); ASSERT(ifp->if_height > 0); ASSERT(ifp->if_u1.if_root != NULL); ASSERT(xfs_iext_valid(ifp, cur)); nr_entries = xfs_iext_leaf_nr_entries(ifp, leaf, cur->pos) - 1; for (i = cur->pos; i < nr_entries; i++) leaf->recs[i] = leaf->recs[i + 1]; xfs_iext_rec_clear(&leaf->recs[nr_entries]); ifp->if_bytes -= sizeof(struct xfs_iext_rec); if (cur->pos == 0 && nr_entries > 0) { xfs_iext_update_node(ifp, offset, xfs_iext_leaf_key(leaf, 0), 1, leaf); offset = xfs_iext_leaf_key(leaf, 0); } else if (cur->pos == nr_entries) { if (ifp->if_height > 1 && leaf->next) cur->leaf = leaf->next; else cur->leaf = NULL; cur->pos = 0; } if (nr_entries >= RECS_PER_LEAF / 2) return; if (ifp->if_height > 1) xfs_iext_rebalance_leaf(ifp, cur, leaf, offset, nr_entries); else if (nr_entries == 0) xfs_iext_free_last_leaf(ifp); } /* * Lookup the extent covering bno. * * If there is an extent covering bno return the extent index, and store the * expanded extent structure in *gotp, and the extent cursor in *cur. * If there is no extent covering bno, but there is an extent after it (e.g. * it lies in a hole) return that extent in *gotp and its cursor in *cur * instead. * If bno is beyond the last extent return false, and return an invalid * cursor value. */ bool xfs_iext_lookup_extent( struct xfs_inode *ip, struct xfs_ifork *ifp, xfs_fileoff_t offset, struct xfs_iext_cursor *cur, struct xfs_bmbt_irec *gotp) { XFS_STATS_INC(ip->i_mount, xs_look_exlist); cur->leaf = xfs_iext_find_level(ifp, offset, 1); if (!cur->leaf) { cur->pos = 0; return false; } for (cur->pos = 0; cur->pos < xfs_iext_max_recs(ifp); cur->pos++) { struct xfs_iext_rec *rec = cur_rec(cur); if (xfs_iext_rec_is_empty(rec)) break; if (xfs_iext_rec_cmp(rec, offset) >= 0) goto found; } /* Try looking in the next node for an entry > offset */ if (ifp->if_height == 1 || !cur->leaf->next) return false; cur->leaf = cur->leaf->next; cur->pos = 0; if (!xfs_iext_valid(ifp, cur)) return false; found: xfs_iext_get(gotp, cur_rec(cur)); return true; } /* * Returns the last extent before end, and if this extent doesn't cover * end, update end to the end of the extent. */ bool xfs_iext_lookup_extent_before( struct xfs_inode *ip, struct xfs_ifork *ifp, xfs_fileoff_t *end, struct xfs_iext_cursor *cur, struct xfs_bmbt_irec *gotp) { /* could be optimized to not even look up the next on a match.. */ if (xfs_iext_lookup_extent(ip, ifp, *end - 1, cur, gotp) && gotp->br_startoff <= *end - 1) return true; if (!xfs_iext_prev_extent(ifp, cur, gotp)) return false; *end = gotp->br_startoff + gotp->br_blockcount; return true; } void xfs_iext_update_extent( struct xfs_inode *ip, int state, struct xfs_iext_cursor *cur, struct xfs_bmbt_irec *new) { struct xfs_ifork *ifp = xfs_iext_state_to_fork(ip, state); if (cur->pos == 0) { struct xfs_bmbt_irec old; xfs_iext_get(&old, cur_rec(cur)); if (new->br_startoff != old.br_startoff) { xfs_iext_update_node(ifp, old.br_startoff, new->br_startoff, 1, cur->leaf); } } trace_xfs_bmap_pre_update(ip, cur, state, _RET_IP_); xfs_iext_set(cur_rec(cur), new); trace_xfs_bmap_post_update(ip, cur, state, _RET_IP_); } /* * Return true if the cursor points at an extent and return the extent structure * in gotp. Else return false. */ bool xfs_iext_get_extent( struct xfs_ifork *ifp, struct xfs_iext_cursor *cur, struct xfs_bmbt_irec *gotp) { if (!xfs_iext_valid(ifp, cur)) return false; xfs_iext_get(gotp, cur_rec(cur)); return true; } /* * This is a recursive function, because of that we need to be extremely * careful with stack usage. */ static void xfs_iext_destroy_node( struct xfs_iext_node *node, int level) { int i; if (level > 1) { for (i = 0; i < KEYS_PER_NODE; i++) { if (node->keys[i] == XFS_IEXT_KEY_INVALID) break; xfs_iext_destroy_node(node->ptrs[i], level - 1); } } kmem_free(node); } void xfs_iext_destroy( struct xfs_ifork *ifp) { xfs_iext_destroy_node(ifp->if_u1.if_root, ifp->if_height); ifp->if_bytes = 0; ifp->if_height = 0; ifp->if_u1.if_root = NULL; }