fs/hfsplus/btree.c - third_party/linux - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /*
  *  linux/fs/hfsplus/btree.c
  *
  * Copyright (C) 2001
  * Brad Boyer (flar@allandria.com)
  * (C) 2003 Ardis Technologies <roman@ardistech.com>
  *
  * Handle opening/closing btree
  */

 #include <linux/slab.h>
 #include <linux/pagemap.h>
 #include <linux/log2.h>

 #include "hfsplus_fs.h"
 #include "hfsplus_raw.h"

 /*
  * Initial source code of clump size calculation is gotten
  * from http://opensource.apple.com/tarballs/diskdev_cmds/
  */
 #define CLUMP_ENTRIES	15

 static short clumptbl[CLUMP_ENTRIES * 3] = {
 /*
  *	    Volume	Attributes	 Catalog	 Extents
  *	     Size	Clump (MB)	Clump (MB)	Clump (MB)
  */
 	/*   1GB */	  4,		  4,		 4,
 	/*   2GB */	  6,		  6,		 4,
 	/*   4GB */	  8,		  8,		 4,
 	/*   8GB */	 11,		 11,		 5,
 	/*
 	 * For volumes 16GB and larger, we want to make sure that a full OS
 	 * install won't require fragmentation of the Catalog or Attributes
 	 * B-trees.  We do this by making the clump sizes sufficiently large,
 	 * and by leaving a gap after the B-trees for them to grow into.
 	 *
 	 * For SnowLeopard 10A298, a FullNetInstall with all packages selected
 	 * results in:
 	 * Catalog B-tree Header
 	 *	nodeSize:          8192
 	 *	totalNodes:       31616
 	 *	freeNodes:         1978
 	 * (used = 231.55 MB)
 	 * Attributes B-tree Header
 	 *	nodeSize:          8192
 	 *	totalNodes:       63232
 	 *	freeNodes:          958
 	 * (used = 486.52 MB)
 	 *
 	 * We also want Time Machine backup volumes to have a sufficiently
 	 * large clump size to reduce fragmentation.
 	 *
 	 * The series of numbers for Catalog and Attribute form a geometric
 	 * series. For Catalog (16GB to 512GB), each term is 8**(1/5) times
 	 * the previous term.  For Attributes (16GB to 512GB), each term is
 	 * 4**(1/5) times the previous term.  For 1TB to 16TB, each term is
 	 * 2**(1/5) times the previous term.
 	 */
 	/*  16GB */	 64,		 32,		 5,
 	/*  32GB */	 84,		 49,		 6,
 	/*  64GB */	111,		 74,		 7,
 	/* 128GB */	147,		111,		 8,
 	/* 256GB */	194,		169,		 9,
 	/* 512GB */	256,		256,		11,
 	/*   1TB */	294,		294,		14,
 	/*   2TB */	338,		338,		16,
 	/*   4TB */	388,		388,		20,
 	/*   8TB */	446,		446,		25,
 	/*  16TB */	512,		512,		32
 };

 u32 hfsplus_calc_btree_clump_size(u32 block_size, u32 node_size,
 					u64 sectors, int file_id)
 {
 	u32 mod = max(node_size, block_size);
 	u32 clump_size;
 	int column;
 	int i;

 	/* Figure out which column of the above table to use for this file. */
 	switch (file_id) {
 	case HFSPLUS_ATTR_CNID:
 		column = 0;
 		break;
 	case HFSPLUS_CAT_CNID:
 		column = 1;
 		break;
 	default:
 		column = 2;
 		break;
 	}

 	/*
 	 * The default clump size is 0.8% of the volume size. And
 	 * it must also be a multiple of the node and block size.
 	 */
 	if (sectors < 0x200000) {
 		clump_size = sectors << 2;	/*  0.8 %  */
 		if (clump_size < (8 * node_size))
 			clump_size = 8 * node_size;
 	} else {
 		/* turn exponent into table index... */
 		for (i = 0, sectors = sectors >> 22;
 		     sectors && (i < CLUMP_ENTRIES - 1);
 		     ++i, sectors = sectors >> 1) {
 			/* empty body */
 		}

 		clump_size = clumptbl[column + (i) * 3] * 1024 * 1024;
 	}

 	/*
 	 * Round the clump size to a multiple of node and block size.
 	 * NOTE: This rounds down.
 	 */
 	clump_size /= mod;
 	clump_size *= mod;

 	/*
 	 * Rounding down could have rounded down to 0 if the block size was
 	 * greater than the clump size.  If so, just use one block or node.
 	 */
 	if (clump_size == 0)
 		clump_size = mod;

 	return clump_size;
 }

 /* Get a reference to a B*Tree and do some initial checks */
 struct hfs_btree *hfs_btree_open(struct super_block *sb, u32 id)
 {
 	struct hfs_btree *tree;
 	struct hfs_btree_header_rec *head;
 	struct address_space *mapping;
 	struct inode *inode;
 	struct page *page;
 	unsigned int size;

 	tree = kzalloc(sizeof(*tree), GFP_KERNEL);
 	if (!tree)
 		return NULL;

 	mutex_init(&tree->tree_lock);
 	spin_lock_init(&tree->hash_lock);
 	tree->sb = sb;
 	tree->cnid = id;
 	inode = hfsplus_iget(sb, id);
 	if (IS_ERR(inode))
 		goto free_tree;
 	tree->inode = inode;

 	if (!HFSPLUS_I(tree->inode)->first_blocks) {
 		pr_err("invalid btree extent records (0 size)\n");
 		goto free_inode;
 	}

 	mapping = tree->inode->i_mapping;
 	page = read_mapping_page(mapping, 0, NULL);
 	if (IS_ERR(page))
 		goto free_inode;

 	/* Load the header */
 	head = (struct hfs_btree_header_rec *)(kmap(page) +
 		sizeof(struct hfs_bnode_desc));
 	tree->root = be32_to_cpu(head->root);
 	tree->leaf_count = be32_to_cpu(head->leaf_count);
 	tree->leaf_head = be32_to_cpu(head->leaf_head);
 	tree->leaf_tail = be32_to_cpu(head->leaf_tail);
 	tree->node_count = be32_to_cpu(head->node_count);
 	tree->free_nodes = be32_to_cpu(head->free_nodes);
 	tree->attributes = be32_to_cpu(head->attributes);
 	tree->node_size = be16_to_cpu(head->node_size);
 	tree->max_key_len = be16_to_cpu(head->max_key_len);
 	tree->depth = be16_to_cpu(head->depth);

 	/* Verify the tree and set the correct compare function */
 	switch (id) {
 	case HFSPLUS_EXT_CNID:
 		if (tree->max_key_len != HFSPLUS_EXT_KEYLEN - sizeof(u16)) {
 			pr_err("invalid extent max_key_len %d\n",
 				tree->max_key_len);
 			goto fail_page;
 		}
 		if (tree->attributes & HFS_TREE_VARIDXKEYS) {
 			pr_err("invalid extent btree flag\n");
 			goto fail_page;
 		}

 		tree->keycmp = hfsplus_ext_cmp_key;
 		break;
 	case HFSPLUS_CAT_CNID:
 		if (tree->max_key_len != HFSPLUS_CAT_KEYLEN - sizeof(u16)) {
 			pr_err("invalid catalog max_key_len %d\n",
 				tree->max_key_len);
 			goto fail_page;
 		}
 		if (!(tree->attributes & HFS_TREE_VARIDXKEYS)) {
 			pr_err("invalid catalog btree flag\n");
 			goto fail_page;
 		}

 		if (test_bit(HFSPLUS_SB_HFSX, &HFSPLUS_SB(sb)->flags) &&
 		    (head->key_type == HFSPLUS_KEY_BINARY))
 			tree->keycmp = hfsplus_cat_bin_cmp_key;
 		else {
 			tree->keycmp = hfsplus_cat_case_cmp_key;
 			set_bit(HFSPLUS_SB_CASEFOLD, &HFSPLUS_SB(sb)->flags);
 		}
 		break;
 	case HFSPLUS_ATTR_CNID:
 		if (tree->max_key_len != HFSPLUS_ATTR_KEYLEN - sizeof(u16)) {
 			pr_err("invalid attributes max_key_len %d\n",
 				tree->max_key_len);
 			goto fail_page;
 		}
 		tree->keycmp = hfsplus_attr_bin_cmp_key;
 		break;
 	default:
 		pr_err("unknown B*Tree requested\n");
 		goto fail_page;
 	}

 	if (!(tree->attributes & HFS_TREE_BIGKEYS)) {
 		pr_err("invalid btree flag\n");
 		goto fail_page;
 	}

 	size = tree->node_size;
 	if (!is_power_of_2(size))
 		goto fail_page;
 	if (!tree->node_count)
 		goto fail_page;

 	tree->node_size_shift = ffs(size) - 1;

 	tree->pages_per_bnode =
 		(tree->node_size + PAGE_SIZE - 1) >>
 		PAGE_SHIFT;

 	kunmap(page);
 	put_page(page);
 	return tree;

  fail_page:
 	put_page(page);
  free_inode:
 	tree->inode->i_mapping->a_ops = &hfsplus_aops;
 	iput(tree->inode);
  free_tree:
 	kfree(tree);
 	return NULL;
 }

 /* Release resources used by a btree */
 void hfs_btree_close(struct hfs_btree *tree)
 {
 	struct hfs_bnode *node;
 	int i;

 	if (!tree)
 		return;

 	for (i = 0; i < NODE_HASH_SIZE; i++) {
 		while ((node = tree->node_hash[i])) {
 			tree->node_hash[i] = node->next_hash;
 			if (atomic_read(&node->refcnt))
 				pr_crit("node %d:%d "
 						"still has %d user(s)!\n",
 					node->tree->cnid, node->this,
 					atomic_read(&node->refcnt));
 			hfs_bnode_free(node);
 			tree->node_hash_cnt--;
 		}
 	}
 	iput(tree->inode);
 	kfree(tree);
 }

 int hfs_btree_write(struct hfs_btree *tree)
 {
 	struct hfs_btree_header_rec *head;
 	struct hfs_bnode *node;
 	struct page *page;

 	node = hfs_bnode_find(tree, 0);
 	if (IS_ERR(node))
 		/* panic? */
 		return -EIO;
 	/* Load the header */
 	page = node->page[0];
 	head = (struct hfs_btree_header_rec *)(kmap(page) +
 		sizeof(struct hfs_bnode_desc));

 	head->root = cpu_to_be32(tree->root);
 	head->leaf_count = cpu_to_be32(tree->leaf_count);
 	head->leaf_head = cpu_to_be32(tree->leaf_head);
 	head->leaf_tail = cpu_to_be32(tree->leaf_tail);
 	head->node_count = cpu_to_be32(tree->node_count);
 	head->free_nodes = cpu_to_be32(tree->free_nodes);
 	head->attributes = cpu_to_be32(tree->attributes);
 	head->depth = cpu_to_be16(tree->depth);

 	kunmap(page);
 	set_page_dirty(page);
 	hfs_bnode_put(node);
 	return 0;
 }

 static struct hfs_bnode *hfs_bmap_new_bmap(struct hfs_bnode *prev, u32 idx)
 {
 	struct hfs_btree *tree = prev->tree;
 	struct hfs_bnode *node;
 	struct hfs_bnode_desc desc;
 	__be32 cnid;

 	node = hfs_bnode_create(tree, idx);
 	if (IS_ERR(node))
 		return node;

 	tree->free_nodes--;
 	prev->next = idx;
 	cnid = cpu_to_be32(idx);
 	hfs_bnode_write(prev, &cnid, offsetof(struct hfs_bnode_desc, next), 4);

 	node->type = HFS_NODE_MAP;
 	node->num_recs = 1;
 	hfs_bnode_clear(node, 0, tree->node_size);
 	desc.next = 0;
 	desc.prev = 0;
 	desc.type = HFS_NODE_MAP;
 	desc.height = 0;
 	desc.num_recs = cpu_to_be16(1);
 	desc.reserved = 0;
 	hfs_bnode_write(node, &desc, 0, sizeof(desc));
 	hfs_bnode_write_u16(node, 14, 0x8000);
 	hfs_bnode_write_u16(node, tree->node_size - 2, 14);
 	hfs_bnode_write_u16(node, tree->node_size - 4, tree->node_size - 6);

 	return node;
 }

 struct hfs_bnode *hfs_bmap_alloc(struct hfs_btree *tree)
 {
 	struct hfs_bnode *node, *next_node;
 	struct page **pagep;
 	u32 nidx, idx;
 	unsigned off;
 	u16 off16;
 	u16 len;
 	u8 *data, byte, m;
 	int i;

 	while (!tree->free_nodes) {
 		struct inode *inode = tree->inode;
 		struct hfsplus_inode_info *hip = HFSPLUS_I(inode);
 		u32 count;
 		int res;

 		res = hfsplus_file_extend(inode, hfs_bnode_need_zeroout(tree));
 		if (res)
 			return ERR_PTR(res);
 		hip->phys_size = inode->i_size =
 			(loff_t)hip->alloc_blocks <<
 				HFSPLUS_SB(tree->sb)->alloc_blksz_shift;
 		hip->fs_blocks =
 			hip->alloc_blocks << HFSPLUS_SB(tree->sb)->fs_shift;
 		inode_set_bytes(inode, inode->i_size);
 		count = inode->i_size >> tree->node_size_shift;
 		tree->free_nodes = count - tree->node_count;
 		tree->node_count = count;
 	}

 	nidx = 0;
 	node = hfs_bnode_find(tree, nidx);
 	if (IS_ERR(node))
 		return node;
 	len = hfs_brec_lenoff(node, 2, &off16);
 	off = off16;

 	off += node->page_offset;
 	pagep = node->page + (off >> PAGE_SHIFT);
 	data = kmap(*pagep);
 	off &= ~PAGE_MASK;
 	idx = 0;

 	for (;;) {
 		while (len) {
 			byte = data[off];
 			if (byte != 0xff) {
 				for (m = 0x80, i = 0; i < 8; m >>= 1, i++) {
 					if (!(byte & m)) {
 						idx += i;
 						data[off] |= m;
 						set_page_dirty(*pagep);
 						kunmap(*pagep);
 						tree->free_nodes--;
 						mark_inode_dirty(tree->inode);
 						hfs_bnode_put(node);
 						return hfs_bnode_create(tree,
 							idx);
 					}
 				}
 			}
 			if (++off >= PAGE_SIZE) {
 				kunmap(*pagep);
 				data = kmap(*++pagep);
 				off = 0;
 			}
 			idx += 8;
 			len--;
 		}
 		kunmap(*pagep);
 		nidx = node->next;
 		if (!nidx) {
 			hfs_dbg(BNODE_MOD, "create new bmap node\n");
 			next_node = hfs_bmap_new_bmap(node, idx);
 		} else
 			next_node = hfs_bnode_find(tree, nidx);
 		hfs_bnode_put(node);
 		if (IS_ERR(next_node))
 			return next_node;
 		node = next_node;

 		len = hfs_brec_lenoff(node, 0, &off16);
 		off = off16;
 		off += node->page_offset;
 		pagep = node->page + (off >> PAGE_SHIFT);
 		data = kmap(*pagep);
 		off &= ~PAGE_MASK;
 	}
 }

 void hfs_bmap_free(struct hfs_bnode *node)
 {
 	struct hfs_btree *tree;
 	struct page *page;
 	u16 off, len;
 	u32 nidx;
 	u8 *data, byte, m;

 	hfs_dbg(BNODE_MOD, "btree_free_node: %u\n", node->this);
 	BUG_ON(!node->this);
 	tree = node->tree;
 	nidx = node->this;
 	node = hfs_bnode_find(tree, 0);
 	if (IS_ERR(node))
 		return;
 	len = hfs_brec_lenoff(node, 2, &off);
 	while (nidx >= len * 8) {
 		u32 i;

 		nidx -= len * 8;
 		i = node->next;
 		hfs_bnode_put(node);
 		if (!i) {
 			/* panic */;
 			pr_crit("unable to free bnode %u. "
 					"bmap not found!\n",
 				node->this);
 			return;
 		}
 		node = hfs_bnode_find(tree, i);
 		if (IS_ERR(node))
 			return;
 		if (node->type != HFS_NODE_MAP) {
 			/* panic */;
 			pr_crit("invalid bmap found! "
 					"(%u,%d)\n",
 				node->this, node->type);
 			hfs_bnode_put(node);
 			return;
 		}
 		len = hfs_brec_lenoff(node, 0, &off);
 	}
 	off += node->page_offset + nidx / 8;
 	page = node->page[off >> PAGE_SHIFT];
 	data = kmap(page);
 	off &= ~PAGE_MASK;
 	m = 1 << (~nidx & 7);
 	byte = data[off];
 	if (!(byte & m)) {
 		pr_crit("trying to free free bnode "
 				"%u(%d)\n",
 			node->this, node->type);
 		kunmap(page);
 		hfs_bnode_put(node);
 		return;
 	}
 	data[off] = byte & ~m;
 	set_page_dirty(page);
 	kunmap(page);
 	hfs_bnode_put(node);
 	tree->free_nodes++;
 	mark_inode_dirty(tree->inode);
 }
	// SPDX-License-Identifier: GPL-2.0
	/*
	* linux/fs/hfsplus/btree.c
	*
	* Copyright (C) 2001
	* Brad Boyer (flar@allandria.com)
	* (C) 2003 Ardis Technologies <roman@ardistech.com>
	*
	* Handle opening/closing btree
	*/

	#include <linux/slab.h>
	#include <linux/pagemap.h>
	#include <linux/log2.h>

	#include "hfsplus_fs.h"
	#include "hfsplus_raw.h"

	/*
	* Initial source code of clump size calculation is gotten
	* from http://opensource.apple.com/tarballs/diskdev_cmds/
	*/
	#define CLUMP_ENTRIES 15

	static short clumptbl[CLUMP_ENTRIES * 3] = {
	/*
	* Volume Attributes Catalog Extents
	* Size Clump (MB) Clump (MB) Clump (MB)
	*/
	/* 1GB */ 4, 4, 4,
	/* 2GB */ 6, 6, 4,
	/* 4GB */ 8, 8, 4,
	/* 8GB */ 11, 11, 5,
	/*
	* For volumes 16GB and larger, we want to make sure that a full OS
	* install won't require fragmentation of the Catalog or Attributes
	* B-trees. We do this by making the clump sizes sufficiently large,
	* and by leaving a gap after the B-trees for them to grow into.
	*
	* For SnowLeopard 10A298, a FullNetInstall with all packages selected
	* results in:
	* Catalog B-tree Header
	* nodeSize: 8192
	* totalNodes: 31616
	* freeNodes: 1978
	* (used = 231.55 MB)
	* Attributes B-tree Header
	* nodeSize: 8192
	* totalNodes: 63232
	* freeNodes: 958
	* (used = 486.52 MB)
	*
	* We also want Time Machine backup volumes to have a sufficiently
	* large clump size to reduce fragmentation.
	*
	* The series of numbers for Catalog and Attribute form a geometric
	* series. For Catalog (16GB to 512GB), each term is 8**(1/5) times
	* the previous term. For Attributes (16GB to 512GB), each term is
	* 4**(1/5) times the previous term. For 1TB to 16TB, each term is
	* 2**(1/5) times the previous term.
	*/
	/* 16GB */ 64, 32, 5,
	/* 32GB */ 84, 49, 6,
	/* 64GB */ 111, 74, 7,
	/* 128GB */ 147, 111, 8,
	/* 256GB */ 194, 169, 9,
	/* 512GB */ 256, 256, 11,
	/* 1TB */ 294, 294, 14,
	/* 2TB */ 338, 338, 16,
	/* 4TB */ 388, 388, 20,
	/* 8TB */ 446, 446, 25,
	/* 16TB */ 512, 512, 32
	};

	u32 hfsplus_calc_btree_clump_size(u32 block_size, u32 node_size,
	u64 sectors, int file_id)
	{
	u32 mod = max(node_size, block_size);
	u32 clump_size;
	int column;
	int i;

	/* Figure out which column of the above table to use for this file. */
	switch (file_id) {
	case HFSPLUS_ATTR_CNID:
	column = 0;
	break;
	case HFSPLUS_CAT_CNID:
	column = 1;
	break;
	default:
	column = 2;
	break;
	}

	/*
	* The default clump size is 0.8% of the volume size. And
	* it must also be a multiple of the node and block size.
	*/
	if (sectors < 0x200000) {
	clump_size = sectors << 2; /* 0.8 % */
	if (clump_size < (8 * node_size))
	clump_size = 8 * node_size;
	} else {
	/* turn exponent into table index... */
	for (i = 0, sectors = sectors >> 22;
	sectors && (i < CLUMP_ENTRIES - 1);
	++i, sectors = sectors >> 1) {
	/* empty body */
	}

	clump_size = clumptbl[column + (i) * 3] * 1024 * 1024;
	}

	/*
	* Round the clump size to a multiple of node and block size.
	* NOTE: This rounds down.
	*/
	clump_size /= mod;
	clump_size *= mod;

	/*
	* Rounding down could have rounded down to 0 if the block size was
	* greater than the clump size. If so, just use one block or node.
	*/
	if (clump_size == 0)
	clump_size = mod;

	return clump_size;
	}

	/* Get a reference to a BTree and do some initial checks /
	struct hfs_btree hfs_btree_open(struct super_block sb, u32 id)
	{
	struct hfs_btree *tree;
	struct hfs_btree_header_rec *head;
	struct address_space *mapping;
	struct inode *inode;
	struct page *page;
	unsigned int size;

	tree = kzalloc(sizeof(*tree), GFP_KERNEL);
	if (!tree)
	return NULL;

	mutex_init(&tree->tree_lock);
	spin_lock_init(&tree->hash_lock);
	tree->sb = sb;
	tree->cnid = id;
	inode = hfsplus_iget(sb, id);
	if (IS_ERR(inode))
	goto free_tree;
	tree->inode = inode;

	if (!HFSPLUS_I(tree->inode)->first_blocks) {
	pr_err("invalid btree extent records (0 size)\n");
	goto free_inode;
	}

	mapping = tree->inode->i_mapping;
	page = read_mapping_page(mapping, 0, NULL);
	if (IS_ERR(page))
	goto free_inode;

	/* Load the header */
	head = (struct hfs_btree_header_rec *)(kmap(page) +
	sizeof(struct hfs_bnode_desc));
	tree->root = be32_to_cpu(head->root);
	tree->leaf_count = be32_to_cpu(head->leaf_count);
	tree->leaf_head = be32_to_cpu(head->leaf_head);
	tree->leaf_tail = be32_to_cpu(head->leaf_tail);
	tree->node_count = be32_to_cpu(head->node_count);
	tree->free_nodes = be32_to_cpu(head->free_nodes);
	tree->attributes = be32_to_cpu(head->attributes);
	tree->node_size = be16_to_cpu(head->node_size);
	tree->max_key_len = be16_to_cpu(head->max_key_len);
	tree->depth = be16_to_cpu(head->depth);

	/* Verify the tree and set the correct compare function */
	switch (id) {
	case HFSPLUS_EXT_CNID:
	if (tree->max_key_len != HFSPLUS_EXT_KEYLEN - sizeof(u16)) {
	pr_err("invalid extent max_key_len %d\n",
	tree->max_key_len);
	goto fail_page;
	}
	if (tree->attributes & HFS_TREE_VARIDXKEYS) {
	pr_err("invalid extent btree flag\n");
	goto fail_page;
	}

	tree->keycmp = hfsplus_ext_cmp_key;
	break;
	case HFSPLUS_CAT_CNID:
	if (tree->max_key_len != HFSPLUS_CAT_KEYLEN - sizeof(u16)) {
	pr_err("invalid catalog max_key_len %d\n",
	tree->max_key_len);
	goto fail_page;
	}
	if (!(tree->attributes & HFS_TREE_VARIDXKEYS)) {
	pr_err("invalid catalog btree flag\n");
	goto fail_page;
	}

	if (test_bit(HFSPLUS_SB_HFSX, &HFSPLUS_SB(sb)->flags) &&
	(head->key_type == HFSPLUS_KEY_BINARY))
	tree->keycmp = hfsplus_cat_bin_cmp_key;
	else {
	tree->keycmp = hfsplus_cat_case_cmp_key;
	set_bit(HFSPLUS_SB_CASEFOLD, &HFSPLUS_SB(sb)->flags);
	}
	break;
	case HFSPLUS_ATTR_CNID:
	if (tree->max_key_len != HFSPLUS_ATTR_KEYLEN - sizeof(u16)) {
	pr_err("invalid attributes max_key_len %d\n",
	tree->max_key_len);
	goto fail_page;
	}
	tree->keycmp = hfsplus_attr_bin_cmp_key;
	break;
	default:
	pr_err("unknown B*Tree requested\n");
	goto fail_page;
	}

	if (!(tree->attributes & HFS_TREE_BIGKEYS)) {
	pr_err("invalid btree flag\n");
	goto fail_page;
	}

	size = tree->node_size;
	if (!is_power_of_2(size))
	goto fail_page;
	if (!tree->node_count)
	goto fail_page;

	tree->node_size_shift = ffs(size) - 1;

	tree->pages_per_bnode =
	(tree->node_size + PAGE_SIZE - 1) >>
	PAGE_SHIFT;

	kunmap(page);
	put_page(page);
	return tree;

	fail_page:
	put_page(page);
	free_inode:
	tree->inode->i_mapping->a_ops = &hfsplus_aops;
	iput(tree->inode);
	free_tree:
	kfree(tree);
	return NULL;
	}

	/* Release resources used by a btree */
	void hfs_btree_close(struct hfs_btree *tree)
	{
	struct hfs_bnode *node;
	int i;

	if (!tree)
	return;

	for (i = 0; i < NODE_HASH_SIZE; i++) {
	while ((node = tree->node_hash[i])) {
	tree->node_hash[i] = node->next_hash;
	if (atomic_read(&node->refcnt))
	pr_crit("node %d:%d "
	"still has %d user(s)!\n",
	node->tree->cnid, node->this,
	atomic_read(&node->refcnt));
	hfs_bnode_free(node);
	tree->node_hash_cnt--;
	}
	}
	iput(tree->inode);
	kfree(tree);
	}

	int hfs_btree_write(struct hfs_btree *tree)
	{
	struct hfs_btree_header_rec *head;
	struct hfs_bnode *node;
	struct page *page;

	node = hfs_bnode_find(tree, 0);
	if (IS_ERR(node))
	/* panic? */
	return -EIO;
	/* Load the header */
	page = node->page[0];
	head = (struct hfs_btree_header_rec *)(kmap(page) +
	sizeof(struct hfs_bnode_desc));

	head->root = cpu_to_be32(tree->root);
	head->leaf_count = cpu_to_be32(tree->leaf_count);
	head->leaf_head = cpu_to_be32(tree->leaf_head);
	head->leaf_tail = cpu_to_be32(tree->leaf_tail);
	head->node_count = cpu_to_be32(tree->node_count);
	head->free_nodes = cpu_to_be32(tree->free_nodes);
	head->attributes = cpu_to_be32(tree->attributes);
	head->depth = cpu_to_be16(tree->depth);

	kunmap(page);
	set_page_dirty(page);
	hfs_bnode_put(node);
	return 0;
	}

	static struct hfs_bnode hfs_bmap_new_bmap(struct hfs_bnode prev, u32 idx)
	{
	struct hfs_btree *tree = prev->tree;
	struct hfs_bnode *node;
	struct hfs_bnode_desc desc;
	__be32 cnid;

	node = hfs_bnode_create(tree, idx);
	if (IS_ERR(node))
	return node;

	tree->free_nodes--;
	prev->next = idx;
	cnid = cpu_to_be32(idx);
	hfs_bnode_write(prev, &cnid, offsetof(struct hfs_bnode_desc, next), 4);

	node->type = HFS_NODE_MAP;
	node->num_recs = 1;
	hfs_bnode_clear(node, 0, tree->node_size);
	desc.next = 0;
	desc.prev = 0;
	desc.type = HFS_NODE_MAP;
	desc.height = 0;
	desc.num_recs = cpu_to_be16(1);
	desc.reserved = 0;
	hfs_bnode_write(node, &desc, 0, sizeof(desc));
	hfs_bnode_write_u16(node, 14, 0x8000);
	hfs_bnode_write_u16(node, tree->node_size - 2, 14);
	hfs_bnode_write_u16(node, tree->node_size - 4, tree->node_size - 6);

	return node;
	}

	struct hfs_bnode hfs_bmap_alloc(struct hfs_btree tree)
	{
	struct hfs_bnode node, next_node;
	struct page **pagep;
	u32 nidx, idx;
	unsigned off;
	u16 off16;
	u16 len;
	u8 *data, byte, m;
	int i;

	while (!tree->free_nodes) {
	struct inode *inode = tree->inode;
	struct hfsplus_inode_info *hip = HFSPLUS_I(inode);
	u32 count;
	int res;

	res = hfsplus_file_extend(inode, hfs_bnode_need_zeroout(tree));
	if (res)
	return ERR_PTR(res);
	hip->phys_size = inode->i_size =
	(loff_t)hip->alloc_blocks <<
	HFSPLUS_SB(tree->sb)->alloc_blksz_shift;
	hip->fs_blocks =
	hip->alloc_blocks << HFSPLUS_SB(tree->sb)->fs_shift;
	inode_set_bytes(inode, inode->i_size);
	count = inode->i_size >> tree->node_size_shift;
	tree->free_nodes = count - tree->node_count;
	tree->node_count = count;
	}

	nidx = 0;
	node = hfs_bnode_find(tree, nidx);
	if (IS_ERR(node))
	return node;
	len = hfs_brec_lenoff(node, 2, &off16);
	off = off16;

	off += node->page_offset;
	pagep = node->page + (off >> PAGE_SHIFT);
	data = kmap(*pagep);
	off &= ~PAGE_MASK;
	idx = 0;

	for (;;) {
	while (len) {
	byte = data[off];
	if (byte != 0xff) {
	for (m = 0x80, i = 0; i < 8; m >>= 1, i++) {
	if (!(byte & m)) {
	idx += i;
	data[off] \|= m;
	set_page_dirty(*pagep);
	kunmap(*pagep);
	tree->free_nodes--;
	mark_inode_dirty(tree->inode);
	hfs_bnode_put(node);
	return hfs_bnode_create(tree,
	idx);
	}
	}
	}
	if (++off >= PAGE_SIZE) {
	kunmap(*pagep);
	data = kmap(*++pagep);
	off = 0;
	}
	idx += 8;
	len--;
	}
	kunmap(*pagep);
	nidx = node->next;
	if (!nidx) {
	hfs_dbg(BNODE_MOD, "create new bmap node\n");
	next_node = hfs_bmap_new_bmap(node, idx);
	} else
	next_node = hfs_bnode_find(tree, nidx);
	hfs_bnode_put(node);
	if (IS_ERR(next_node))
	return next_node;
	node = next_node;

	len = hfs_brec_lenoff(node, 0, &off16);
	off = off16;
	off += node->page_offset;
	pagep = node->page + (off >> PAGE_SHIFT);
	data = kmap(*pagep);
	off &= ~PAGE_MASK;
	}
	}

	void hfs_bmap_free(struct hfs_bnode *node)
	{
	struct hfs_btree *tree;
	struct page *page;
	u16 off, len;
	u32 nidx;
	u8 *data, byte, m;

	hfs_dbg(BNODE_MOD, "btree_free_node: %u\n", node->this);
	BUG_ON(!node->this);
	tree = node->tree;
	nidx = node->this;
	node = hfs_bnode_find(tree, 0);
	if (IS_ERR(node))
	return;
	len = hfs_brec_lenoff(node, 2, &off);
	while (nidx >= len * 8) {
	u32 i;

	nidx -= len * 8;
	i = node->next;
	hfs_bnode_put(node);
	if (!i) {
	/* panic */;
	pr_crit("unable to free bnode %u. "
	"bmap not found!\n",
	node->this);
	return;
	}
	node = hfs_bnode_find(tree, i);
	if (IS_ERR(node))
	return;
	if (node->type != HFS_NODE_MAP) {
	/* panic */;
	pr_crit("invalid bmap found! "
	"(%u,%d)\n",
	node->this, node->type);
	hfs_bnode_put(node);
	return;
	}
	len = hfs_brec_lenoff(node, 0, &off);
	}
	off += node->page_offset + nidx / 8;
	page = node->page[off >> PAGE_SHIFT];
	data = kmap(page);
	off &= ~PAGE_MASK;
	m = 1 << (~nidx & 7);
	byte = data[off];
	if (!(byte & m)) {
	pr_crit("trying to free free bnode "
	"%u(%d)\n",
	node->this, node->type);
	kunmap(page);
	hfs_bnode_put(node);
	return;
	}
	data[off] = byte & ~m;
	set_page_dirty(page);
	kunmap(page);
	hfs_bnode_put(node);
	tree->free_nodes++;
	mark_inode_dirty(tree->inode);
	}