URL
https://opencores.org/ocsvn/or1k/or1k/trunk
Subversion Repositories or1k
[/] [or1k/] [trunk/] [linux/] [linux-2.4/] [fs/] [hfs/] [btree.c] - Rev 1765
Compare with Previous | Blame | View Log
/* * linux/fs/hfs/btree.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 manipulate the B-tree structure. * The catalog and extents files are both B-trees. * * "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. * * The code in this file initializes some structures which contain * pointers by calling memset(&foo, 0, sizeof(foo)). * This produces the desired behavior only due to the non-ANSI * assumption that the machine representation of NULL is all zeros. */ #include "hfs_btree.h" /*================ File-local functions ================*/ /* * hfs_bnode_ditch() * * Description: * This function deletes an entire linked list of bnodes, so it * does not need to keep the linked list consistent as * hfs_bnode_delete() does. * Called by hfs_btree_init() for error cleanup and by hfs_btree_free(). * Input Variable(s): * struct hfs_bnode *bn: pointer to the first (struct hfs_bnode) in * the linked list to be deleted. * Output Variable(s): * NONE * Returns: * void * Preconditions: * 'bn' is NULL or points to a "valid" (struct hfs_bnode) with a 'prev' * field of NULL. * Postconditions: * 'bn' and all (struct hfs_bnode)s in the chain of 'next' pointers * are deleted, freeing the associated memory and hfs_buffer_put()ing * the associated buffer. */ static void hfs_bnode_ditch(struct hfs_bnode *bn) { struct hfs_bnode *tmp; #if defined(DEBUG_BNODES) || defined(DEBUG_ALL) extern int bnode_count; #endif while (bn != NULL) { tmp = bn->next; #if defined(DEBUG_BNODES) || defined(DEBUG_ALL) hfs_warn("deleting node %d from tree %d with count %d\n", bn->node, (int)ntohl(bn->tree->entry.cnid), bn->count); --bnode_count; #endif hfs_buffer_put(bn->buf); /* safe: checks for NULL argument */ /* free all but the header */ if (bn->node) { HFS_DELETE(bn); } bn = tmp; } } /*================ Global functions ================*/ /* * hfs_btree_free() * * Description: * This function frees a (struct hfs_btree) obtained from hfs_btree_init(). * Called by hfs_put_super(). * Input Variable(s): * struct hfs_btree *bt: pointer to the (struct hfs_btree) to free * Output Variable(s): * NONE * Returns: * void * Preconditions: * 'bt' is NULL or points to a "valid" (struct hfs_btree) * Postconditions: * If 'bt' points to a "valid" (struct hfs_btree) then all (struct * hfs_bnode)s associated with 'bt' are freed by calling * hfs_bnode_ditch() and the memory associated with the (struct * hfs_btree) is freed. * If 'bt' is NULL or not "valid" an error is printed and nothing * is changed. */ void hfs_btree_free(struct hfs_btree *bt) { int lcv; if (bt && (bt->magic == HFS_BTREE_MAGIC)) { hfs_extent_free(&bt->entry.u.file.data_fork); for (lcv=0; lcv<HFS_CACHELEN; ++lcv) { #if defined(DEBUG_BNODES) || defined(DEBUG_ALL) hfs_warn("deleting nodes from bucket %d:\n", lcv); #endif hfs_bnode_ditch(bt->cache[lcv]); } #if defined(DEBUG_BNODES) || defined(DEBUG_ALL) hfs_warn("deleting header and bitmap nodes\n"); #endif hfs_bnode_ditch(&bt->head); #if defined(DEBUG_BNODES) || defined(DEBUG_ALL) hfs_warn("deleting root node\n"); #endif hfs_bnode_ditch(bt->root); HFS_DELETE(bt); } else if (bt) { hfs_warn("hfs_btree_free: corrupted hfs_btree.\n"); } } /* * hfs_btree_init() * * Description: * Given some vital information from the MDB (HFS superblock), * initializes the fields of a (struct hfs_btree). * Input Variable(s): * struct hfs_mdb *mdb: pointer to the MDB * ino_t cnid: the CNID (HFS_CAT_CNID or HFS_EXT_CNID) of the B-tree * hfs_u32 tsize: the size, in bytes, of the B-tree * hfs_u32 csize: the size, in bytes, of the clump size for the B-tree * Output Variable(s): * NONE * Returns: * (struct hfs_btree *): pointer to the initialized hfs_btree on success, * or NULL on failure * Preconditions: * 'mdb' points to a "valid" (struct hfs_mdb) * Postconditions: * Assuming the inputs are what they claim to be, no errors occur * reading from disk, and no inconsistencies are noticed in the data * read from disk, the return value is a pointer to a "valid" * (struct hfs_btree). If there are errors reading from disk or * inconsistencies are noticed in the data read from disk, then and * all resources that were allocated are released and NULL is * returned. If the inputs are not what they claim to be or if they * are unnoticed inconsistencies in the data read from disk then the * returned hfs_btree is probably going to lead to errors when it is * used in a non-trivial way. */ struct hfs_btree * hfs_btree_init(struct hfs_mdb *mdb, ino_t cnid, hfs_byte_t ext[12], hfs_u32 tsize, hfs_u32 csize) { struct hfs_btree * bt; struct BTHdrRec * th; struct hfs_bnode * tmp; unsigned int next; #if defined(DEBUG_HEADER) || defined(DEBUG_ALL) unsigned char *p, *q; #endif if (!mdb || !ext || !HFS_NEW(bt)) { goto bail3; } bt->magic = HFS_BTREE_MAGIC; bt->sys_mdb = mdb->sys_mdb; bt->reserved = 0; bt->lock = 0; hfs_init_waitqueue(&bt->wait); bt->dirt = 0; memset(bt->cache, 0, sizeof(bt->cache)); #if 0 /* this is a fake entry. so we don't need to initialize it. */ memset(&bt->entry, 0, sizeof(bt->entry)); hfs_init_waitqueue(&bt->entry.wait); INIT_LIST_HEAD(&bt->entry.hash); INIT_LIST_HEAD(&bt->entry.list); #endif bt->entry.mdb = mdb; bt->entry.cnid = cnid; bt->entry.type = HFS_CDR_FIL; bt->entry.u.file.magic = HFS_FILE_MAGIC; bt->entry.u.file.clumpablks = (csize / mdb->alloc_blksz) >> HFS_SECTOR_SIZE_BITS; bt->entry.u.file.data_fork.entry = &bt->entry; bt->entry.u.file.data_fork.lsize = tsize; bt->entry.u.file.data_fork.psize = tsize >> HFS_SECTOR_SIZE_BITS; bt->entry.u.file.data_fork.fork = HFS_FK_DATA; hfs_extent_in(&bt->entry.u.file.data_fork, ext); hfs_bnode_read(&bt->head, bt, 0, HFS_STICKY); if (!hfs_buffer_ok(bt->head.buf)) { goto bail2; } th = (struct BTHdrRec *)((char *)hfs_buffer_data(bt->head.buf) + sizeof(struct NodeDescriptor)); /* read in the bitmap nodes (if any) */ tmp = &bt->head; while ((next = tmp->ndFLink)) { if (!HFS_NEW(tmp->next)) { goto bail2; } hfs_bnode_read(tmp->next, bt, next, HFS_STICKY); if (!hfs_buffer_ok(tmp->next->buf)) { goto bail2; } tmp->next->prev = tmp; tmp = tmp->next; } if (hfs_get_ns(th->bthNodeSize) != htons(HFS_SECTOR_SIZE)) { hfs_warn("hfs_btree_init: bthNodeSize!=512 not supported\n"); goto bail2; } if (cnid == htonl(HFS_CAT_CNID)) { bt->compare = (hfs_cmpfn)hfs_cat_compare; } else if (cnid == htonl(HFS_EXT_CNID)) { bt->compare = (hfs_cmpfn)hfs_ext_compare; } else { goto bail2; } bt->bthDepth = hfs_get_hs(th->bthDepth); bt->bthRoot = hfs_get_hl(th->bthRoot); bt->bthNRecs = hfs_get_hl(th->bthNRecs); bt->bthFNode = hfs_get_hl(th->bthFNode); bt->bthLNode = hfs_get_hl(th->bthLNode); bt->bthNNodes = hfs_get_hl(th->bthNNodes); bt->bthFree = hfs_get_hl(th->bthFree); bt->bthKeyLen = hfs_get_hs(th->bthKeyLen); #if defined(DEBUG_HEADER) || defined(DEBUG_ALL) hfs_warn("bthDepth %d\n", bt->bthDepth); hfs_warn("bthRoot %d\n", bt->bthRoot); hfs_warn("bthNRecs %d\n", bt->bthNRecs); hfs_warn("bthFNode %d\n", bt->bthFNode); hfs_warn("bthLNode %d\n", bt->bthLNode); hfs_warn("bthKeyLen %d\n", bt->bthKeyLen); hfs_warn("bthNNodes %d\n", bt->bthNNodes); hfs_warn("bthFree %d\n", bt->bthFree); p = (unsigned char *)hfs_buffer_data(bt->head.buf); q = p + HFS_SECTOR_SIZE; while (p < q) { hfs_warn("%02x %02x %02x %02x %02x %02x %02x %02x " "%02x %02x %02x %02x %02x %02x %02x %02x\n", *p++, *p++, *p++, *p++, *p++, *p++, *p++, *p++, *p++, *p++, *p++, *p++, *p++, *p++, *p++, *p++); } #endif /* Read in the root if it exists. The header always exists, but the root exists only if the tree is non-empty */ if (bt->bthDepth && bt->bthRoot) { if (!HFS_NEW(bt->root)) { goto bail2; } hfs_bnode_read(bt->root, bt, bt->bthRoot, HFS_STICKY); if (!hfs_buffer_ok(bt->root->buf)) { goto bail1; } } else { bt->root = NULL; } return bt; bail1: hfs_bnode_ditch(bt->root); bail2: hfs_bnode_ditch(&bt->head); HFS_DELETE(bt); bail3: return NULL; } /* * hfs_btree_commit() * * Called to write a possibly dirty btree back to disk. */ void hfs_btree_commit(struct hfs_btree *bt, hfs_byte_t ext[12], hfs_lword_t size) { if (bt->dirt) { struct BTHdrRec *th; th = (struct BTHdrRec *)((char *)hfs_buffer_data(bt->head.buf) + sizeof(struct NodeDescriptor)); hfs_put_hs(bt->bthDepth, th->bthDepth); hfs_put_hl(bt->bthRoot, th->bthRoot); hfs_put_hl(bt->bthNRecs, th->bthNRecs); hfs_put_hl(bt->bthFNode, th->bthFNode); hfs_put_hl(bt->bthLNode, th->bthLNode); hfs_put_hl(bt->bthNNodes, th->bthNNodes); hfs_put_hl(bt->bthFree, th->bthFree); hfs_buffer_dirty(bt->head.buf); /* * Commit the bnodes which are not cached. * The map nodes don't need to be committed here because * they are committed every time they are changed. */ hfs_bnode_commit(&bt->head); if (bt->root) { hfs_bnode_commit(bt->root); } hfs_put_hl(bt->bthNNodes << HFS_SECTOR_SIZE_BITS, size); hfs_extent_out(&bt->entry.u.file.data_fork, ext); /* hfs_buffer_dirty(mdb->buf); (Done by caller) */ bt->dirt = 0; } }