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/*
* linux/fs/hfs/bfind.c
*
* Copyright (C) 1995, 1996 Paul H. Hargrove
* This file may be distributed under the terms of the GNU General Public License.
*
* This file contains the code to access records in a btree.
*
* "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"
/*================ Global functions ================*/
/*
* hfs_brec_relse()
*
* Description:
* This function releases some of the nodes associated with a brec.
* Input Variable(s):
* struct hfs_brec *brec: pointer to the brec to release some nodes from.
* struct hfs_belem *elem: the last node to release or NULL for all
* Output Variable(s):
* NONE
* Returns:
* void
* Preconditions:
* 'brec' points to a "valid" (struct hfs_brec)
* Postconditions:
* All nodes between the indicated node and the beginning of the path
* are released.
*/
void hfs_brec_relse(struct hfs_brec *brec, struct hfs_belem *elem)
{
if (!elem) {
elem = brec->bottom;
}
while (brec->top <= elem) {
hfs_bnode_relse(&brec->top->bnr);
++brec->top;
}
}
/*
* hfs_bfind()
*
* Description:
* This function has sole responsibility for locating existing
* records in a B-tree. Given a B-tree and a key it locates the
* "greatest" record "less than or equal to" the given key. The
* exact behavior is determined by the bits of the flags variable as
* follows:
* ('flags' & HFS_LOCK_MASK):
* The lock_type argument to be used when calling hfs_bnode_find().
* HFS_BFIND_EXACT: only accept an exact match, otherwise take the
* "largest" record less than 'target' as a "match"
* HFS_BFIND_LOCK: request HFS_LOCK_WRITE access to the node containing
* the "matching" record when it is located
* HFS_BPATH_FIRST: keep access to internal nodes when accessing their
* first child.
* HFS_BPATH_OVERFLOW: keep access to internal nodes when the accessed
* child is too full to insert another pointer record.
* HFS_BPATH_UNDERFLOW: keep access to internal nodes when the accessed
* child is would be less than half full upon removing a pointer record.
* Input Variable(s):
* struct hfs_brec *brec: pointer to the (struct hfs_brec) to hold
* the search results.
* struct hfs_bkey *target: pointer to the (struct hfs_bkey)
* to search for
* int flags: bitwise OR of flags which determine the function's behavior
* Output Variable(s):
* 'brec' contains the results of the search on success or is invalid
* on failure.
* Returns:
* int: 0 or 1 on success or an error code on failure:
* -EINVAL: one of the input variables was NULL.
* -ENOENT: tree is valid but empty or no "matching" record was located.
* If the HFS_BFIND_EXACT bit of 'flags' is not set then the case of no
* matching record will give a 'brec' with a 'record' field of zero
* rather than returning this error.
* -EIO: an I/O operation or an assertion about the structure of a
* valid B-tree failed indicating corruption of either the B-tree
* structure on the disk or one of the in-core structures representing
* the B-tree.
* (This could also be returned if a kmalloc() call failed in a
* subordinate routine that is intended to get the data from the
* disk or the buffer cache.)
* Preconditions:
* 'brec' is NULL or points to a (struct hfs_brec) with a 'tree' field
* which points to a valid (struct hfs_btree).
* 'target' is NULL or points to a "valid" (struct hfs_bkey)
* Postconditions:
* If 'brec', 'brec->tree' or 'target' is NULL then -EINVAL is returned.
* If 'brec', 'brec->tree' and 'target' are non-NULL but the tree
* is empty then -ENOENT is returned.
* If 'brec', 'brec->tree' and 'target' are non-NULL but the call to
* hfs_brec_init() fails then '*brec' is NULL and -EIO is returned.
* If 'brec', 'brec->tree' and 'target' are non-NULL and the tree is
* non-empty then the tree is searched as follows:
* If any call to hfs_brec_next() fails or returns a node that is
* neither an index node nor a leaf node then -EIO is returned to
* indicate that the B-tree or buffer-cache are corrupted.
* If every record in the tree is "greater than" the given key
* and the HFS_BFIND_EXACT bit of 'flags' is set then -ENOENT is returned.
* If every record in the tree is "greater than" the given key
* and the HFS_BFIND_EXACT bit of 'flags' is clear then 'brec' refers
* to the first leaf node in the tree and has a 'record' field of
* zero, and 1 is returned.
* If a "matching" record is located with key "equal to" 'target'
* then the return value is 0 and 'brec' indicates the record.
* If a "matching" record is located with key "greater than" 'target'
* then the behavior is determined as follows:
* If the HFS_BFIND_EXACT bit of 'flags' is not set then 1 is returned
* and 'brec' refers to the "matching" record.
* If the HFS_BFIND_EXACT bit of 'flags' is set then -ENOENT is returned.
* If the return value is non-negative and the HFS_BFIND_LOCK bit of
* 'flags' is set then hfs_brec_lock() is called on the bottom element
* of 'brec' before returning.
*/
int hfs_bfind(struct hfs_brec *brec, struct hfs_btree *tree,
const struct hfs_bkey *target, int flags)
{
struct hfs_belem *curr;
struct hfs_bkey *key;
struct hfs_bnode *bn;
int result, ntype;
/* check for invalid arguments */
if (!brec || (tree->magic != HFS_BTREE_MAGIC) || !target) {
return -EINVAL;
}
/* check for empty tree */
if (!tree->root || !tree->bthNRecs) {
return -ENOENT;
}
/* start search at root of tree */
if (!(curr = hfs_brec_init(brec, tree, flags))) {
return -EIO;
}
/* traverse the tree */
do {
bn = curr->bnr.bn;
if (!curr->record) {
hfs_warn("hfs_bfind: empty bnode\n");
hfs_brec_relse(brec, NULL);
return -EIO;
}
/* reverse linear search yielding largest key "less
than or equal to" 'target'.
It is questionable whether a binary search would be
significantly faster */
do {
key = belem_key(curr);
if (!key->KeyLen) {
hfs_warn("hfs_bfind: empty key\n");
hfs_brec_relse(brec, NULL);
return -EIO;
}
result = (tree->compare)(target, key);
} while ((result<0) && (--curr->record));
ntype = bn->ndType;
/* see if all keys > target */
if (!curr->record) {
if (bn->ndBLink) {
/* at a node other than the left-most at a
given level it means the parent had an
incorrect key for this child */
hfs_brec_relse(brec, NULL);
hfs_warn("hfs_bfind: corrupted b-tree %d.\n",
(int)ntohl(tree->entry.cnid));
return -EIO;
}
if (flags & HFS_BFIND_EXACT) {
/* we're not going to find it */
hfs_brec_relse(brec, NULL);
return -ENOENT;
}
if (ntype == ndIndxNode) {
/* since we are at the left-most node at
the current level and looking for the
predecessor of 'target' keep going down */
curr->record = 1;
} else {
/* we're at first leaf so fall through */
}
}
/* get next node if necessary */
if ((ntype == ndIndxNode) && !(curr = hfs_brec_next(brec))) {
return -EIO;
}
} while (ntype == ndIndxNode);
if (key->KeyLen > tree->bthKeyLen) {
hfs_warn("hfs_bfind: oversized key\n");
hfs_brec_relse(brec, NULL);
return -EIO;
}
if (ntype != ndLeafNode) {
hfs_warn("hfs_bfind: invalid node type %02x in node %d of "
"btree %d\n", bn->ndType, bn->node,
(int)ntohl(tree->entry.cnid));
hfs_brec_relse(brec, NULL);
return -EIO;
}
if ((flags & HFS_BFIND_EXACT) && result) {
hfs_brec_relse(brec, NULL);
return -ENOENT;
}
if (!(flags & HFS_BPATH_MASK)) {
hfs_brec_relse(brec, brec->bottom-1);
}
if (flags & HFS_BFIND_LOCK) {
hfs_brec_lock(brec, brec->bottom);
}
brec->key = brec_key(brec);
brec->data = bkey_record(brec->key);
return result ? 1 : 0;
}
/*
* hfs_bsucc()
*
* Description:
* This function overwrites '*brec' with its successor in the B-tree,
* obtaining the same type of access.
* Input Variable(s):
* struct hfs_brec *brec: address of the (struct hfs_brec) to overwrite
* with its successor
* Output Variable(s):
* struct hfs_brec *brec: address of the successor of the original
* '*brec' or to invalid data
* Returns:
* int: 0 on success, or one of -EINVAL, -EIO, or -EINVAL on failure
* Preconditions:
* 'brec' pointers to a "valid" (struct hfs_brec)
* Postconditions:
* If the given '*brec' is not "valid" -EINVAL is returned and
* '*brec' is unchanged.
* If the given 'brec' is "valid" but has no successor then -ENOENT
* is returned and '*brec' is invalid.
* If a call to hfs_bnode_find() is necessary to find the successor,
* but fails then -EIO is returned and '*brec' is invalid.
* If none of the three previous conditions prevents finding the
* successor of '*brec', then 0 is returned, and '*brec' is overwritten
* with the (struct hfs_brec) for its successor.
* In the cases when '*brec' is invalid, the old records is freed.
*/
int hfs_bsucc(struct hfs_brec *brec, int count)
{
struct hfs_belem *belem;
struct hfs_bnode *bn;
if (!brec || !(belem = brec->bottom) || (belem != brec->top) ||
!(bn = belem->bnr.bn) || (bn->magic != HFS_BNODE_MAGIC) ||
!bn->tree || (bn->tree->magic != HFS_BTREE_MAGIC) ||
!hfs_buffer_ok(bn->buf)) {
hfs_warn("hfs_bsucc: invalid/corrupt arguments.\n");
return -EINVAL;
}
while (count) {
int left = bn->ndNRecs - belem->record;
if (left < count) {
struct hfs_bnode_ref old;
hfs_u32 node;
/* Advance to next node */
if (!(node = bn->ndFLink)) {
hfs_brec_relse(brec, belem);
return -ENOENT;
}
if (node == bn->node) {
hfs_warn("hfs_bsucc: corrupt btree\n");
hfs_brec_relse(brec, belem);
return -EIO;
}
old = belem->bnr;
belem->bnr = hfs_bnode_find(brec->tree, node,
belem->bnr.lock_type);
hfs_bnode_relse(&old);
if (!(bn = belem->bnr.bn)) {
return -EIO;
}
belem->record = 1;
count -= (left + 1);
} else {
belem->record += count;
break;
}
}
brec->key = belem_key(belem);
brec->data = bkey_record(brec->key);
if (brec->key->KeyLen > brec->tree->bthKeyLen) {
hfs_warn("hfs_bsucc: oversized key\n");
hfs_brec_relse(brec, NULL);
return -EIO;
}
return 0;
}
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