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[/] [or1k/] [trunk/] [linux/] [linux-2.4/] [fs/] [hfs/] [binsert.c] - Rev 1774
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/* * linux/fs/hfs/binsert.c * * Copyright (C) 1995-1997 Paul H. Hargrove * This file may be distributed under the terms of the GNU General Public License. * * This file contains the code to insert records in a B-tree. * * "XXX" in a comment is a note to myself to consider changing something. * * In function preconditions the term "valid" applied to a pointer to * a structure means that the pointer is non-NULL and the structure it * points to has all fields initialized to consistent values. */ #include "hfs_btree.h" /*================ File-local functions ================*/ /* btree locking functions */ static inline void hfs_btree_lock(struct hfs_btree *tree) { while (tree->lock) hfs_sleep_on(&tree->wait); tree->lock = 1; } static inline void hfs_btree_unlock(struct hfs_btree *tree) { tree->lock = 0; hfs_wake_up(&tree->wait); } /* * binsert_nonfull() * * Description: * Inserts a record in a given bnode known to have sufficient space. * Input Variable(s): * struct hfs_brec* brec: pointer to the brec for the insertion * struct hfs_belem* belem: the element in the search path to insert in * struct hfs_bkey* key: pointer to the key for the record to insert * void* data: pointer to the record to insert * hfs_u16 keysize: size of the key to insert * hfs_u16 datasize: size of the record to insert * Output Variable(s): * NONE * Returns: * NONE * Preconditions: * 'brec' points to a valid (struct hfs_brec). * 'belem' points to a valid (struct hfs_belem) in 'brec', the node * of which has enough free space to insert 'key' and 'data'. * 'key' is a pointer to a valid (struct hfs_bkey) of length 'keysize' * which, in sorted order, belongs at the location indicated by 'brec'. * 'data' is non-NULL an points to appropriate data of length 'datasize' * Postconditions: * The record has been inserted in the position indicated by 'brec'. */ static void binsert_nonfull(struct hfs_brec *brec, struct hfs_belem *belem, const struct hfs_bkey *key, const void *data, hfs_u8 keysize, hfs_u16 datasize) { int i, rec, nrecs, size, tomove; hfs_u8 *start; struct hfs_bnode *bnode = belem->bnr.bn; rec = ++(belem->record); size = ROUND(keysize+1) + datasize; nrecs = bnode->ndNRecs + 1; tomove = bnode_offset(bnode, nrecs) - bnode_offset(bnode, rec); /* adjust the record table */ for (i = nrecs; i >= rec; --i) { hfs_put_hs(bnode_offset(bnode,i) + size, RECTBL(bnode,i+1)); } /* make room */ start = bnode_key(bnode, rec); memmove(start + size, start, tomove); /* copy in the key and the data*/ *start = keysize; keysize = ROUND(keysize+1); memcpy(start + 1, (hfs_u8 *)key + 1, keysize-1); memcpy(start + keysize, data, datasize); /* update record count */ ++bnode->ndNRecs; } /* * add_root() * * Description: * Adds a new root to a B*-tree, increasing its height. * Input Variable(s): * struct hfs_btree *tree: the tree to add a new root to * struct hfs_bnode *left: the new root's first child or NULL * struct hfs_bnode *right: the new root's second child or NULL * Output Variable(s): * NONE * Returns: * void * Preconditions: * 'tree' points to a valid (struct hfs_btree). * 'left' and 'right' point to valid (struct hfs_bnode)s, which * resulted from splitting the old root node, or are both NULL * if there was no root node before. * Postconditions: * Upon success a new root node is added to 'tree' with either * two children ('left' and 'right') or none. */ static void add_root(struct hfs_btree *tree, struct hfs_bnode *left, struct hfs_bnode *right) { struct hfs_bnode_ref bnr; struct hfs_bnode *root; struct hfs_bkey *key; int keylen = tree->bthKeyLen; if (left && !right) { hfs_warn("add_root: LEFT but no RIGHT\n"); return; } bnr = hfs_bnode_alloc(tree); if (!(root = bnr.bn)) { return; } root->sticky = HFS_STICKY; tree->root = root; tree->bthRoot = root->node; ++tree->bthDepth; root->ndNHeight = tree->bthDepth; root->ndFLink = 0; root->ndBLink = 0; if (!left) { /* tree was empty */ root->ndType = ndLeafNode; root->ndNRecs = 0; tree->bthFNode = root->node; tree->bthLNode = root->node; } else { root->ndType = ndIndxNode; root->ndNRecs = 2; hfs_put_hs(sizeof(struct NodeDescriptor) + ROUND(1+keylen) + sizeof(hfs_u32), RECTBL(root, 2)); key = bnode_key(root, 1); key->KeyLen = keylen; memcpy(key->value, ((struct hfs_bkey *)bnode_key(left, 1))->value, keylen); hfs_put_hl(left->node, bkey_record(key)); hfs_put_hs(sizeof(struct NodeDescriptor) + 2*ROUND(1+keylen) + 2*sizeof(hfs_u32), RECTBL(root, 3)); key = bnode_key(root, 2); key->KeyLen = keylen; memcpy(key->value, ((struct hfs_bkey *)bnode_key(right, 1))->value, keylen); hfs_put_hl(right->node, bkey_record(key)); /* the former root (left) is now just a normal node */ left->sticky = HFS_NOT_STICKY; if ((left->next = bhash(tree, left->node))) { left->next->prev = left; } bhash(tree, left->node) = left; } hfs_bnode_relse(&bnr); tree->dirt = 1; } /* * insert_empty_bnode() * * Description: * Adds an empty node to the right of 'left'. * Input Variable(s): * struct hfs_btree *tree: the tree to add a node to * struct hfs_bnode *left: the node to add a node after * Output Variable(s): * NONE * Returns: * struct hfs_bnode_ref *: reference to the new bnode. * Preconditions: * 'tree' points to a valid (struct hfs_btree) with at least 1 free node. * 'left' points to a valid (struct hfs_bnode) belonging to 'tree'. * Postconditions: * If NULL is returned then 'tree' and 'left' are unchanged. * Otherwise a node with 0 records is inserted in the tree to the right * of the node 'left'. The 'ndFLink' of 'left' and the 'ndBLink' of * the former right-neighbor of 'left' (if one existed) point to the * new node. If 'left' had no right neighbor and is a leaf node the * the 'bthLNode' of 'tree' points to the new node. The free-count and * bitmap for 'tree' are kept current by hfs_bnode_alloc() which supplies * the required node. */ static struct hfs_bnode_ref insert_empty_bnode(struct hfs_btree *tree, struct hfs_bnode *left) { struct hfs_bnode_ref retval; struct hfs_bnode_ref right; retval = hfs_bnode_alloc(tree); if (!retval.bn) { hfs_warn("hfs_binsert: out of bnodes?.\n"); goto done; } retval.bn->sticky = HFS_NOT_STICKY; if ((retval.bn->next = bhash(tree, retval.bn->node))) { retval.bn->next->prev = retval.bn; } bhash(tree, retval.bn->node) = retval.bn; if (left->ndFLink) { right = hfs_bnode_find(tree, left->ndFLink, HFS_LOCK_WRITE); if (!right.bn) { hfs_warn("hfs_binsert: corrupt btree.\n"); hfs_bnode_bitop(tree, retval.bn->node, 0); hfs_bnode_relse(&retval); goto done; } right.bn->ndBLink = retval.bn->node; hfs_bnode_relse(&right); } else if (left->ndType == ndLeafNode) { tree->bthLNode = retval.bn->node; tree->dirt = 1; } retval.bn->ndFLink = left->ndFLink; retval.bn->ndBLink = left->node; retval.bn->ndType = left->ndType; retval.bn->ndNHeight = left->ndNHeight; retval.bn->ndNRecs = 0; left->ndFLink = retval.bn->node; done: return retval; } /* * split() * * Description: * Splits an over full node during insertion. * Picks the split point that results in the most-nearly equal * space usage in the new and old nodes. * Input Variable(s): * struct hfs_belem *elem: the over full node. * int size: the number of bytes to be used by the new record and its key. * Output Variable(s): * struct hfs_belem *elem: changed to indicate where the new record * should be inserted. * Returns: * struct hfs_bnode_ref: reference to the new bnode. * Preconditions: * 'elem' points to a valid path element corresponding to the over full node. * 'size' is positive. * Postconditions: * The records in the node corresponding to 'elem' are redistributed across * the old and new nodes so that after inserting the new record, the space * usage in these two nodes is as equal as possible. * 'elem' is updated so that a call to binsert_nonfull() will insert the * new record in the correct location. */ static inline struct hfs_bnode_ref split(struct hfs_belem *elem, int size) { struct hfs_bnode *bnode = elem->bnr.bn; int nrecs, cutoff, index, tmp, used, in_right; struct hfs_bnode_ref right; right = insert_empty_bnode(bnode->tree, bnode); if (right.bn) { nrecs = bnode->ndNRecs; cutoff = (size + bnode_end(bnode) - sizeof(struct NodeDescriptor) + (nrecs+1)*sizeof(hfs_u16))/2; used = 0; in_right = 1; /* note that this only works because records sizes are even */ for (index=1; index <= elem->record; ++index) { tmp = (sizeof(hfs_u16) + bnode_rsize(bnode, index))/2; used += tmp; if (used > cutoff) { goto found; } used += tmp; } tmp = (size + sizeof(hfs_u16))/2; used += tmp; if (used > cutoff) { goto found; } in_right = 0; used += tmp; for (; index <= nrecs; ++index) { tmp = (sizeof(hfs_u16) + bnode_rsize(bnode, index))/2; used += tmp; if (used > cutoff) { goto found; } used += tmp; } /* couldn't find the split point! */ hfs_bnode_relse(&right); } return right; found: if (in_right) { elem->bnr = right; elem->record -= index-1; } hfs_bnode_shift_right(bnode, right.bn, index); return right; } /* * binsert() * * Description: * Inserts a record in a tree known to have enough room, even if the * insertion requires the splitting of nodes. * Input Variable(s): * struct hfs_brec *brec: partial path to the node to insert in * const struct hfs_bkey *key: key for the new record * const void *data: data for the new record * hfs_u8 keysize: size of the key * hfs_u16 datasize: size of the data * int reserve: number of nodes reserved in case of splits * Output Variable(s): * *brec = NULL * Returns: * int: 0 on success, error code on failure * Preconditions: * 'brec' points to a valid (struct hfs_brec) corresponding to a * record in a leaf node, after which a record is to be inserted, * or to "record 0" of the leaf node if the record is to be inserted * before all existing records in the node. The (struct hfs_brec) * includes all ancestors of the leaf node that are needed to * complete the insertion including the parents of any nodes that * will be split. * 'key' points to a valid (struct hfs_bkey) which is appropriate * to this tree, and which belongs at the insertion point. * 'data' points data appropriate for the indicated node. * 'keysize' gives the size in bytes of the key. * 'datasize' gives the size in bytes of the data. * 'reserve' gives the number of nodes that have been reserved in the * tree to allow for splitting of nodes. * Postconditions: * All 'reserve'd nodes have been either used or released. * *brec = NULL * On success the key and data have been inserted at the indicated * location in the tree, all appropriate fields of the in-core data * structures have been changed and updated versions of the on-disk * data structures have been scheduled for write-back to disk. * On failure the B*-tree is probably invalid both on disk and in-core. * * XXX: Some attempt at repair might be made in the event of failure, * or the fs should be remounted read-only so things don't get worse. */ static int binsert(struct hfs_brec *brec, const struct hfs_bkey *key, const void *data, hfs_u8 keysize, hfs_u16 datasize, int reserve) { struct hfs_bnode_ref left, right, other; struct hfs_btree *tree = brec->tree; struct hfs_belem *belem = brec->bottom; int tmpsize = 1 + tree->bthKeyLen; struct hfs_bkey *tmpkey = hfs_malloc(tmpsize); hfs_u32 node; while ((belem >= brec->top) && (belem->flags & HFS_BPATH_OVERFLOW)) { left = belem->bnr; if (left.bn->ndFLink && hfs_bnode_in_brec(left.bn->ndFLink, brec)) { hfs_warn("hfs_binsert: corrupt btree\n"); tree->reserved -= reserve; hfs_free(tmpkey, tmpsize); return -EIO; } right = split(belem, ROUND(keysize+1) + ROUND(datasize)); --reserve; --tree->reserved; if (!right.bn) { hfs_warn("hfs_binsert: unable to split node!\n"); tree->reserved -= reserve; hfs_free(tmpkey, tmpsize); return -ENOSPC; } binsert_nonfull(brec, belem, key, data, keysize, datasize); if (belem->bnr.bn == left.bn) { other = right; if (belem->record == 1) { hfs_bnode_update_key(brec, belem, left.bn, 0); } } else { other = left; } if (left.bn->node == tree->root->node) { add_root(tree, left.bn, right.bn); hfs_bnode_relse(&other); goto done; } data = &node; datasize = sizeof(node); node = htonl(right.bn->node); key = tmpkey; keysize = tree->bthKeyLen; memcpy(tmpkey, bnode_key(right.bn, 1), keysize+1); hfs_bnode_relse(&other); --belem; } if (belem < brec->top) { hfs_warn("hfs_binsert: Missing parent.\n"); tree->reserved -= reserve; hfs_free(tmpkey, tmpsize); return -EIO; } binsert_nonfull(brec, belem, key, data, keysize, datasize); done: tree->reserved -= reserve; hfs_free(tmpkey, tmpsize); return 0; } /*================ Global functions ================*/ /* * hfs_binsert() * * Description: * This function inserts a new record into a b-tree. * Input Variable(s): * struct hfs_btree *tree: pointer to the (struct hfs_btree) to insert in * struct hfs_bkey *key: pointer to the (struct hfs_bkey) to insert * void *data: pointer to the data to associate with 'key' in the b-tree * unsigned int datasize: the size of the data * Output Variable(s): * NONE * Returns: * int: 0 on success, error code on failure * Preconditions: * 'tree' points to a valid (struct hfs_btree) * 'key' points to a valid (struct hfs_bkey) * 'data' points to valid memory of length 'datasize' * Postconditions: * If zero is returned then the record has been inserted in the * indicated location updating all in-core data structures and * scheduling all on-disk data structures for write-back. */ int hfs_binsert(struct hfs_btree *tree, const struct hfs_bkey *key, const void *data, hfs_u16 datasize) { struct hfs_brec brec; struct hfs_belem *belem; int err, reserve, retval; hfs_u8 keysize; if (!tree || (tree->magic != HFS_BTREE_MAGIC) || !key || !data) { hfs_warn("hfs_binsert: invalid arguments.\n"); return -EINVAL; } if (key->KeyLen > tree->bthKeyLen) { hfs_warn("hfs_binsert: oversized key\n"); return -EINVAL; } restart: if (!tree->bthNRecs) { /* create the root bnode */ add_root(tree, NULL, NULL); if (!hfs_brec_init(&brec, tree, HFS_BFIND_INSERT)) { hfs_warn("hfs_binsert: failed to create root.\n"); return -ENOSPC; } } else { err = hfs_bfind(&brec, tree, key, HFS_BFIND_INSERT); if (err < 0) { hfs_warn("hfs_binsert: hfs_brec_find failed.\n"); return err; } else if (err == 0) { hfs_brec_relse(&brec, NULL); return -EEXIST; } } keysize = key->KeyLen; datasize = ROUND(datasize); belem = brec.bottom; belem->flags = 0; if (bnode_freespace(belem->bnr.bn) < (sizeof(hfs_u16) + ROUND(keysize+1) + datasize)) { belem->flags |= HFS_BPATH_OVERFLOW; } if (belem->record == 0) { belem->flags |= HFS_BPATH_FIRST; } if (!belem->flags) { hfs_brec_lock(&brec, brec.bottom); reserve = 0; } else { reserve = brec.bottom - brec.top; if (brec.top == 0) { ++reserve; } /* make certain we have enough nodes to proceed */ if ((tree->bthFree - tree->reserved) < reserve) { hfs_brec_relse(&brec, NULL); hfs_btree_lock(tree); if ((tree->bthFree - tree->reserved) < reserve) { hfs_btree_extend(tree); } hfs_btree_unlock(tree); if ((tree->bthFree - tree->reserved) < reserve) { return -ENOSPC; } else { goto restart; } } tree->reserved += reserve; hfs_brec_lock(&brec, NULL); } retval = binsert(&brec, key, data, keysize, datasize, reserve); hfs_brec_relse(&brec, NULL); if (!retval) { ++tree->bthNRecs; tree->dirt = 1; } return retval; }
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