/* * linux/fs/hfs/balloc.c * * Copyright (C) 1995-1997 Paul H. Hargrove * This file may be distributed under the terms of the GNU General Public License. * * hfs_bnode_alloc() and hfs_bnode_bitop() are based on GPLed code * Copyright (C) 1995 Michael Dreher * * This file contains the code to create and destroy nodes * in the B-tree structure. * * "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 ================*/ /* * get_new_node() * * Get a buffer for a new node with out reading it from disk. */ static hfs_buffer get_new_node(struct hfs_btree *tree, hfs_u32 node) { int tmp; hfs_buffer retval = HFS_BAD_BUFFER; tmp = hfs_extent_map(&tree->entry.u.file.data_fork, node, 0); if (tmp) { retval = hfs_buffer_get(tree->sys_mdb, tmp, 0); } return retval; } /* * hfs_bnode_init() * * Description: * Initialize a newly allocated bnode. * Input Variable(s): * struct hfs_btree *tree: Pointer to a B-tree * hfs_u32 node: the node number to allocate * Output Variable(s): * NONE * Returns: * struct hfs_bnode_ref for the new node * Preconditions: * 'tree' points to a "valid" (struct hfs_btree) * 'node' exists and has been allocated in the bitmap of bnodes. * Postconditions: * On success: * The node is not read from disk, nor added to the bnode cache. * The 'sticky' and locking-related fields are all zero/NULL. * The bnode's nd{[FB]Link, Type, NHeight} fields are uninitialized. * The bnode's ndNRecs field and offsets table indicate an empty bnode. * On failure: * The node is deallocated. */ static struct hfs_bnode_ref hfs_bnode_init(struct hfs_btree * tree, hfs_u32 node) { #if defined(DEBUG_BNODES) || defined(DEBUG_ALL) extern int bnode_count; #endif struct hfs_bnode_ref retval; retval.lock_type = HFS_LOCK_NONE; if (!HFS_NEW(retval.bn)) { hfs_warn("hfs_bnode_init: out of memory.\n"); goto bail2; } /* Partially initialize the in-core structure */ memset(retval.bn, 0, sizeof(*retval.bn)); retval.bn->magic = HFS_BNODE_MAGIC; retval.bn->tree = tree; retval.bn->node = node; hfs_init_waitqueue(&retval.bn->wqueue); hfs_init_waitqueue(&retval.bn->rqueue); hfs_bnode_lock(&retval, HFS_LOCK_WRITE); retval.bn->buf = get_new_node(tree, node); if (!hfs_buffer_ok(retval.bn->buf)) { goto bail1; } #if defined(DEBUG_BNODES) || defined(DEBUG_ALL) ++bnode_count; #endif /* Partially initialize the on-disk structure */ memset(hfs_buffer_data(retval.bn->buf), 0, HFS_SECTOR_SIZE); hfs_put_hs(sizeof(struct NodeDescriptor), RECTBL(retval.bn, 1)); return retval; bail1: HFS_DELETE(retval.bn); bail2: /* clear the bit in the bitmap */ hfs_bnode_bitop(tree, node, 0); return retval; } /* * init_mapnode() * * Description: * Initializes a given node as a mapnode in the given tree. * Input Variable(s): * struct hfs_bnode *bn: the node to add the mapnode after. * hfs_u32: the node to use as a mapnode. * Output Variable(s): * NONE * Returns: * struct hfs_bnode *: the new mapnode or NULL * Preconditions: * 'tree' is a valid (struct hfs_btree). * 'node' is the number of the first node in 'tree' that is not * represented by a bit in the existing mapnodes. * Postconditions: * On failure 'tree' is unchanged and NULL is returned. * On success the node given by 'node' has been added to the linked * list of mapnodes attached to 'tree', and has been initialized as * a valid mapnode with its first bit set to indicate itself as * allocated. */ static struct hfs_bnode *init_mapnode(struct hfs_bnode *bn, hfs_u32 node) { #if defined(DEBUG_BNODES) || defined(DEBUG_ALL) extern int bnode_count; #endif struct hfs_bnode *retval; if (!HFS_NEW(retval)) { hfs_warn("hfs_bnode_add: out of memory.\n"); return NULL; } memset(retval, 0, sizeof(*retval)); retval->magic = HFS_BNODE_MAGIC; retval->tree = bn->tree; retval->node = node; retval->sticky = HFS_STICKY; retval->buf = get_new_node(bn->tree, node); if (!hfs_buffer_ok(retval->buf)) { HFS_DELETE(retval); return NULL; } #if defined(DEBUG_BNODES) || defined(DEBUG_ALL) ++bnode_count; #endif /* Initialize the bnode data structure */ memset(hfs_buffer_data(retval->buf), 0, HFS_SECTOR_SIZE); retval->ndFLink = 0; retval->ndBLink = bn->node; retval->ndType = ndMapNode; retval->ndNHeight = 0; retval->ndNRecs = 1; hfs_put_hs(sizeof(struct NodeDescriptor), RECTBL(retval, 1)); hfs_put_hs(0x1fa, RECTBL(retval, 2)); *((hfs_u8 *)bnode_key(retval, 1)) = 0x80; /* set first bit of bitmap */ retval->prev = bn; hfs_bnode_commit(retval); bn->ndFLink = node; bn->next = retval; hfs_bnode_commit(bn); return retval; } /*================ Global functions ================*/ /* * hfs_bnode_bitop() * * Description: * Allocate/free the requested node of a B-tree of the hfs filesystem * by setting/clearing the corresponding bit in the B-tree bitmap. * The size of the B-tree will not be changed. * Input Variable(s): * struct hfs_btree *tree: Pointer to a B-tree * hfs_u32 bitnr: The node number to free * int set: 0 to clear the bit, non-zero to set it. * Output Variable(s): * None * Returns: * 0: no error * -1: The node was already allocated/free, nothing has been done. * -2: The node is out of range of the B-tree. * -4: not enough map nodes to hold all the bits * Preconditions: * 'tree' points to a "valid" (struct hfs_btree) * 'bitnr' is a node number within the range of the btree, which is * currently free/allocated. * Postconditions: * The bit number 'bitnr' of the node bitmap is set/cleared and the * number of free nodes in the btree is decremented/incremented by one. */ int hfs_bnode_bitop(struct hfs_btree *tree, hfs_u32 bitnr, int set) { struct hfs_bnode *bn; /* the current bnode */ hfs_u16 start; /* the start (in bits) of the bitmap in node */ hfs_u16 len; /* the len (in bits) of the bitmap in node */ hfs_u32 *u32; /* address of the u32 containing the bit */ if (bitnr >= tree->bthNNodes) { hfs_warn("hfs_bnode_bitop: node number out of range.\n"); return -2; } bn = &tree->head; for (;;) { start = bnode_offset(bn, bn->ndNRecs) << 3; len = (bnode_offset(bn, bn->ndNRecs + 1) << 3) - start; if (bitnr < len) { break; } /* continue on to next map node if available */ if (!(bn = bn->next)) { hfs_warn("hfs_bnode_bitop: too few map nodes.\n"); return -4; } bitnr -= len; } /* Change the correct bit */ bitnr += start; u32 = (hfs_u32 *)hfs_buffer_data(bn->buf) + (bitnr >> 5); bitnr %= 32; if ((set && hfs_set_bit(bitnr, u32)) || (!set && !hfs_clear_bit(bitnr, u32))) { hfs_warn("hfs_bnode_bitop: bitmap corruption.\n"); return -1; } hfs_buffer_dirty(bn->buf); /* adjust the free count */ tree->bthFree += (set ? -1 : 1); tree->dirt = 1; return 0; } /* * hfs_bnode_alloc() * * Description: * Find a cleared bit in the B-tree node bitmap of the hfs filesystem, * set it and return the corresponding bnode, with its contents zeroed. * When there is no free bnode in the tree, an error is returned, no * new nodes will be added by this function! * Input Variable(s): * struct hfs_btree *tree: Pointer to a B-tree * Output Variable(s): * NONE * Returns: * struct hfs_bnode_ref for the new bnode * Preconditions: * 'tree' points to a "valid" (struct hfs_btree) * There is at least one free bnode. * Postconditions: * On success: * The corresponding bit in the btree bitmap is set. * The number of free nodes in the btree is decremented by one. * The node is not read from disk, nor added to the bnode cache. * The 'sticky' field is uninitialized. */ struct hfs_bnode_ref hfs_bnode_alloc(struct hfs_btree *tree) { struct hfs_bnode *bn; /* the current bnode */ hfs_u32 bitnr = 0; /* which bit are we examining */ hfs_u16 first; /* the first clear bit in this bnode */ hfs_u16 start; /* the start (in bits) of the bitmap in node */ hfs_u16 end; /* the end (in bits) of the bitmap in node */ hfs_u32 *data; /* address of the data in this bnode */ bn = &tree->head; for (;;) { start = bnode_offset(bn, bn->ndNRecs) << 3; end = bnode_offset(bn, bn->ndNRecs + 1) << 3; data = (hfs_u32 *)hfs_buffer_data(bn->buf); /* search the current node */ first = hfs_find_zero_bit(data, end, start); if (first < end) { break; } /* continue search in next map node */ bn = bn->next; if (!bn) { hfs_warn("hfs_bnode_alloc: too few map nodes.\n"); goto bail; } bitnr += (end - start); } if ((bitnr += (first - start)) >= tree->bthNNodes) { hfs_warn("hfs_bnode_alloc: no free nodes found, " "count wrong?\n"); goto bail; } if (hfs_set_bit(first % 32, data + (first>>5))) { hfs_warn("hfs_bnode_alloc: bitmap corruption.\n"); goto bail; } hfs_buffer_dirty(bn->buf); /* decrement the free count */ --tree->bthFree; tree->dirt = 1; return hfs_bnode_init(tree, bitnr); bail: return (struct hfs_bnode_ref){NULL, HFS_LOCK_NONE}; } /* * hfs_btree_extend() * * Description: * Adds nodes to a B*-tree if possible. * Input Variable(s): * struct hfs_btree *tree: the btree to add nodes to. * Output Variable(s): * NONE * Returns: * void * Preconditions: * 'tree' is a valid (struct hfs_btree *). * Postconditions: * If possible the number of nodes indicated by the tree's clumpsize * have been added to the tree, updating all in-core and on-disk * allocation information. * If insufficient disk-space was available then fewer nodes may have * been added than would be expected based on the clumpsize. * In the case of the extents B*-tree this function will add fewer * nodes than expected if adding more would result in an extent * record for the extents tree being added to the extents tree. * The situation could be dealt with, but doing so confuses Macs. */ void hfs_btree_extend(struct hfs_btree *tree) { struct hfs_bnode_ref head; struct hfs_bnode *bn, *tmp; struct hfs_cat_entry *entry = &tree->entry; struct hfs_mdb *mdb = entry->mdb; hfs_u32 old_nodes, new_nodes, total_nodes, new_mapnodes, seen; old_nodes = entry->u.file.data_fork.psize; entry->u.file.data_fork.lsize += 1; /* rounded up to clumpsize */ hfs_extent_adj(&entry->u.file.data_fork); total_nodes = entry->u.file.data_fork.psize; entry->u.file.data_fork.lsize = total_nodes << HFS_SECTOR_SIZE_BITS; new_nodes = total_nodes - old_nodes; if (!new_nodes) { return; } head = hfs_bnode_find(tree, 0, HFS_LOCK_WRITE); if (!(bn = head.bn)) { hfs_warn("hfs_btree_extend: header node not found.\n"); return; } seen = 0; new_mapnodes = 0; for (;;) { seen += bnode_rsize(bn, bn->ndNRecs) << 3; if (seen >= total_nodes) { break; } if (!bn->next) { tmp = init_mapnode(bn, seen); if (!tmp) { hfs_warn("hfs_btree_extend: " "can't build mapnode.\n"); hfs_bnode_relse(&head); return; } ++new_mapnodes; } bn = bn->next; } hfs_bnode_relse(&head); tree->bthNNodes = total_nodes; tree->bthFree += (new_nodes - new_mapnodes); tree->dirt = 1; /* write the backup MDB, not returning until it is written */ hfs_mdb_commit(mdb, 1); return; } /* * hfs_bnode_free() * * Remove a node from the cache and mark it free in the bitmap. */ int hfs_bnode_free(struct hfs_bnode_ref *bnr) { hfs_u32 node = bnr->bn->node; struct hfs_btree *tree = bnr->bn->tree; if (bnr->bn->count != 1) { hfs_warn("hfs_bnode_free: count != 1.\n"); return -EIO; } hfs_bnode_relse(bnr); hfs_bnode_bitop(tree, node, 0); return 0; }