fs/hfs/libhfs.c

1.3  dillo /*	$NetBSD: libhfs.c,v 1.3 2007/03/09 22:14:09 dillo Exp $	*/
1.1  dillo
1.1  dillo /*-
1.1  dillo  * Copyright (c) 2005, 2007 The NetBSD Foundation, Inc.
1.1  dillo  * All rights reserved.
1.1  dillo  *
1.1  dillo  * This code is derived from software contributed to The NetBSD Foundation
1.1  dillo  * by Yevgeny Binder and Dieter Baron.
1.1  dillo  *
1.1  dillo  * Redistribution and use in source and binary forms, with or without
1.1  dillo  * modification, are permitted provided that the following conditions
1.1  dillo  * are met:
1.1  dillo  * 1. Redistributions of source code must retain the above copyright
1.1  dillo  *    notice, this list of conditions and the following disclaimer.
1.1  dillo  * 2. Redistributions in binary form must reproduce the above copyright
1.1  dillo  *    notice, this list of conditions and the following disclaimer in the
1.1  dillo  *    documentation and/or other materials provided with the distribution.
1.1  dillo  *
1.1  dillo  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.1  dillo  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  dillo  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  dillo  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.1  dillo  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  dillo  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  dillo  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  dillo  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  dillo  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  dillo  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  dillo  * POSSIBILITY OF SUCH DAMAGE.
1.1  dillo  */
1.1  dillo
1.1  dillo /*
1.2  dillo  *  All functions and variable types have the prefix "hfs_". All constants
1.2  dillo  *  have the prefix "HFS_".
1.1  dillo  *
1.1  dillo  *  Naming convention for functions which read/write raw, linear data
1.1  dillo  *	into/from a structured form:
1.1  dillo  *
1.2  dillo  *  hfs_read/write[d][a]_foo_bar
1.1  dillo  *      [d] - read/write from/to [d]isk instead of a memory buffer
1.1  dillo  *      [a] - [a]llocate output buffer instead of using an existing one
1.1  dillo  *            (not applicable for writing functions)
1.1  dillo  *
1.1  dillo  *  Most functions do not have either of these options, so they will read from
1.1  dillo  *	or write to a memory buffer, which has been previously allocated by the
1.1  dillo  *	caller.
1.1  dillo  */
1.1  dillo
1.2  dillo #include "libhfs.h"
1.1  dillo
1.1  dillo /* global private file/folder keys */
1.2  dillo hfs_catalog_key_t hfs_gMetadataDirectoryKey; /* contains HFS+ inodes */
1.2  dillo hfs_catalog_key_t hfs_gJournalInfoBlockFileKey;
1.2  dillo hfs_catalog_key_t hfs_gJournalBufferFileKey;
1.2  dillo hfs_catalog_key_t* hfs_gPrivateObjectKeys[4] = {
1.2  dillo 	&hfs_gMetadataDirectoryKey,
1.2  dillo 	&hfs_gJournalInfoBlockFileKey,
1.2  dillo 	&hfs_gJournalBufferFileKey,
1.1  dillo 	NULL};
1.1  dillo
1.1  dillo
1.1  dillo extern uint16_t be16tohp(void** inout_ptr);
1.1  dillo extern uint32_t be32tohp(void** inout_ptr);
1.1  dillo extern uint64_t be64tohp(void** inout_ptr);
1.1  dillo
1.2  dillo int hfslib_create_casefolding_table(void);
1.1  dillo
1.1  dillo #ifdef DLO_DEBUG
1.1  dillo #include <stdio.h>
1.1  dillo void
1.2  dillo dlo_print_key(hfs_catalog_key_t *key)
1.1  dillo {
1.1  dillo 	int i;
1.1  dillo
1.1  dillo 	printf("%ld:[", (long)key->parent_cnid);
1.1  dillo 	for (i=0; i<key->name.length; i++) {
1.1  dillo 		if (key->name.unicode[i] < 256
1.1  dillo 		    && isprint(key->name.unicode[i]))
1.1  dillo 			putchar(key->name.unicode[i]);
1.1  dillo 		else
1.1  dillo 			printf("<%04x>", key->name.unicode[i]);
1.1  dillo 	}
1.1  dillo 	printf("]");
1.1  dillo }
1.1  dillo #endif
1.1  dillo
1.1  dillo void
1.2  dillo hfslib_init(hfs_callbacks* in_callbacks)
1.1  dillo {
1.1  dillo 	unichar_t	temp[256];
1.1  dillo
1.1  dillo 	if(in_callbacks!=NULL)
1.2  dillo 		memcpy(&hfs_gcb, in_callbacks, sizeof(hfs_callbacks));
1.1  dillo
1.2  dillo 	hfs_gcft = NULL;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * Create keys for the HFS+ "private" files so we can reuse them whenever
1.1  dillo 	 * we perform a user-visible operation, such as listing directory contents.
1.1  dillo 	 */
1.1  dillo
1.1  dillo #define ATOU(str, len) /* quick & dirty ascii-to-unicode conversion */ \
1.1  dillo 	do{ int i; for(i=0; i<len; i++) temp[i]=str[i]; } \
1.1  dillo 	while( /*CONSTCOND*/ 0)
1.1  dillo
1.1  dillo 	ATOU("\0\0\0\0HFS+ Private Data", 21);
1.2  dillo 	hfslib_make_catalog_key(HFS_CNID_ROOT_FOLDER, 21, temp,
1.2  dillo 		&hfs_gMetadataDirectoryKey);
1.1  dillo
1.1  dillo 	ATOU(".journal_info_block", 19);
1.2  dillo 	hfslib_make_catalog_key(HFS_CNID_ROOT_FOLDER, 19, temp,
1.2  dillo 		&hfs_gJournalInfoBlockFileKey);
1.1  dillo
1.1  dillo 	ATOU(".journal", 8);
1.2  dillo 	hfslib_make_catalog_key(HFS_CNID_ROOT_FOLDER, 8, temp,
1.2  dillo 		&hfs_gJournalBufferFileKey);
1.1  dillo
1.1  dillo #undef ATOU
1.1  dillo }
1.1  dillo
1.1  dillo void
1.2  dillo hfslib_done(void)
1.1  dillo {
1.2  dillo 	hfs_callback_args	cbargs;
1.1  dillo
1.2  dillo 	if(hfs_gcft!=NULL) {
1.2  dillo 		hfslib_init_cbargs(&cbargs);
1.2  dillo 		hfslib_free(hfs_gcft, &cbargs);
1.2  dillo 		hfs_gcft = NULL;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	return;
1.1  dillo }
1.1  dillo
1.1  dillo void
1.2  dillo hfslib_init_cbargs(hfs_callback_args* ptr)
1.1  dillo {
1.2  dillo 	memset(ptr, 0, sizeof(hfs_callback_args));
1.1  dillo }
1.1  dillo
1.1  dillo #if 0
1.1  dillo #pragma mark -
1.1  dillo #pragma mark High-Level Routines
1.1  dillo #endif
1.1  dillo
1.1  dillo int
1.2  dillo hfslib_open_volume(
1.1  dillo 	const char* in_device,
1.1  dillo 	uint64_t in_offset, /* given in BYTES, not BLOCKS */
1.1  dillo 	int in_readonly,
1.2  dillo 	hfs_volume* out_vol,
1.2  dillo 	hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	hfs_catalog_key_t		rootkey;
1.2  dillo 	hfs_thread_record_t	rootthread;
1.3  dillo 	uint16_t	node_rec_sizes[1];
1.3  dillo 	void*		node_recs[1];
1.1  dillo 	void*		buffer;
1.1  dillo 	void*		buffer2;	/* used as temporary pointer for realloc() */
1.1  dillo 	int			result;
1.1  dillo
1.1  dillo 	result = 1;
1.1  dillo 	buffer = NULL;
1.1  dillo
1.1  dillo 	if(in_device==NULL || out_vol==NULL)
1.1  dillo 		return 1;
1.1  dillo
1.1  dillo 	out_vol->readonly = in_readonly;
1.1  dillo
1.2  dillo 	if(hfslib_openvoldevice(out_vol, in_device, in_offset, cbargs) != 0)
1.2  dillo 		HFS_LIBERR("could not open device");
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 *	Read the volume header.
1.1  dillo 	 */
1.2  dillo 	buffer = hfslib_malloc(sizeof(hfs_volume_header_t), cbargs);
1.1  dillo 	if(buffer==NULL)
1.2  dillo 		HFS_LIBERR("could not allocate volume header");
1.1  dillo
1.2  dillo 	if(hfslib_readd(out_vol, buffer, sizeof(hfs_volume_header_t),
1.2  dillo 		HFS_VOLUME_HEAD_RESERVE_SIZE, cbargs)!=0)
1.2  dillo 		HFS_LIBERR("could not read volume header");
1.2  dillo 	if(hfslib_read_volume_header(buffer, &(out_vol->vh))==0)
1.2  dillo 		HFS_LIBERR("could not parse volume header");
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * Check the volume signature to see if this is a legitimate HFS+ or HFSX
1.1  dillo 	 * volume. If so, set the key comparison function pointers appropriately.
1.1  dillo 	 */
1.1  dillo 	switch(out_vol->vh.signature)
1.1  dillo 	{
1.2  dillo 		case HFS_SIG_HFSP:
1.2  dillo 			out_vol->keycmp = hfslib_compare_catalog_keys_cf;
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		case HFS_SIG_HFSX:
1.1  dillo 			out_vol->keycmp = NULL; /* will be set below */
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		case HFS_SIG_HFS:
1.2  dillo 			HFS_LIBERR("HFS volumes and HFS+ volumes with HFS wrappers are"
1.1  dillo 						"not currently supported");
1.1  dillo 			break;
1.1  dillo
1.1  dillo 		default:
1.2  dillo 			HFS_LIBERR("unrecognized volume format");
1.1  dillo 	}
1.1  dillo
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 *	Read the catalog header.
1.1  dillo 	 */
1.3  dillo 	buffer2 = hfslib_realloc(buffer, 512, cbargs);
1.1  dillo 	if(buffer2==NULL)
1.2  dillo 		HFS_LIBERR("could not allocate catalog header node");
1.1  dillo 	buffer = buffer2;
1.1  dillo
1.3  dillo 	/*
1.3  dillo 	  We are only interested in the node header, so read the first
1.3  dillo 	  512 bytes and construct the node descriptor by hand.
1.3  dillo 	*/
1.3  dillo 	if(hfslib_readd(out_vol, buffer, 512,
1.3  dillo 	       out_vol->vh.catalog_file.extents[0].start_block
1.3  dillo 	       *(uint64_t)out_vol->vh.block_size,
1.1  dillo 		cbargs) != 0)
1.2  dillo 		HFS_LIBERR("could not read catalog header node");
1.3  dillo 	node_recs[0] = (char *)buffer+14;
1.3  dillo 	node_rec_sizes[0] = 120;
1.3  dillo 	if(hfslib_read_header_node(node_recs, node_rec_sizes, 1,
1.1  dillo 		&out_vol->chr, NULL, NULL)==0)
1.2  dillo 		HFS_LIBERR("could not parse catalog header node");
1.1  dillo
1.1  dillo 	/* If this is an HFSX volume, the catalog header specifies the type of
1.1  dillo 	 * key comparison method (case-folding or binary compare) we should use. */
1.1  dillo 	if(out_vol->keycmp == NULL)
1.1  dillo 	{
1.2  dillo 		if(out_vol->chr.keycomp_type == HFS_KEY_CASEFOLD)
1.2  dillo 			out_vol->keycmp = hfslib_compare_catalog_keys_cf;
1.2  dillo 		else if(out_vol->chr.keycomp_type == HFS_KEY_BINARY)
1.2  dillo 			out_vol->keycmp = hfslib_compare_catalog_keys_bc;
1.1  dillo 		else
1.2  dillo 			HFS_LIBERR("undefined key compare method");
1.1  dillo 	}
1.3  dillo
1.3  dillo 	out_vol->catkeysizefieldsize
1.3  dillo 	    = (out_vol->chr.attributes & HFS_BIG_KEYS_MASK) ?
1.3  dillo 	    sizeof(uint16_t) : sizeof(uint8_t);
1.3  dillo
1.1  dillo 	/*
1.1  dillo 	 *	Read the extent overflow header.
1.1  dillo 	 */
1.3  dillo 	/*
1.3  dillo 	  We are only interested in the node header, so read the first
1.3  dillo 	  512 bytes and construct the node descriptor by hand.
1.3  dillo 	  buffer is already 512 bytes long.
1.3  dillo 	*/
1.3  dillo 	if(hfslib_readd(out_vol, buffer, 512,
1.3  dillo 	       out_vol->vh.extents_file.extents[0].start_block
1.3  dillo 	       *(uint64_t)out_vol->vh.block_size,
1.1  dillo 		cbargs) != 0)
1.2  dillo 		HFS_LIBERR("could not read extent header node");
1.1  dillo
1.3  dillo 	node_recs[0] = (char *)buffer+14;
1.3  dillo 	node_rec_sizes[0] = 120;
1.3  dillo 	if(hfslib_read_header_node(node_recs, node_rec_sizes, 1,
1.1  dillo 		&out_vol->ehr, NULL, NULL)==0)
1.2  dillo 		HFS_LIBERR("could not parse extent header node");
1.3  dillo 	out_vol->extkeysizefieldsize
1.3  dillo 	    = (out_vol->ehr.attributes & HFS_BIG_KEYS_MASK) ?
1.3  dillo 	    sizeof(uint16_t):sizeof(uint8_t);
1.1  dillo 	/*
1.1  dillo 	 * Read the journal info block and journal header (if volume journaled).
1.1  dillo 	 */
1.2  dillo 	if(out_vol->vh.attributes & (1<<HFS_VOL_JOURNALED))
1.1  dillo 	{
1.1  dillo 		/* journal info block */
1.2  dillo 		buffer2 = hfslib_realloc(buffer, sizeof(hfs_journal_info_t), cbargs);
1.1  dillo 		if(buffer2==NULL)
1.2  dillo 			HFS_LIBERR("could not allocate journal info block");
1.1  dillo 		buffer = buffer2;
1.1  dillo
1.2  dillo 		if(hfslib_readd(out_vol, buffer, sizeof(hfs_journal_info_t),
1.1  dillo 			out_vol->vh.journal_info_block * out_vol->vh.block_size,
1.1  dillo 			cbargs) != 0)
1.2  dillo 			HFS_LIBERR("could not read journal info block");
1.1  dillo
1.2  dillo 		if(hfslib_read_journal_info(buffer, &out_vol->jib)==0)
1.2  dillo 			HFS_LIBERR("could not parse journal info block");
1.1  dillo
1.1  dillo 		/* journal header */
1.2  dillo 		buffer2 = hfslib_realloc(buffer, sizeof(hfs_journal_header_t),cbargs);
1.1  dillo 		if(buffer2==NULL)
1.2  dillo 			HFS_LIBERR("could not allocate journal header");
1.1  dillo 		buffer = buffer2;
1.1  dillo
1.2  dillo 		if(hfslib_readd(out_vol, buffer, sizeof(hfs_journal_header_t),
1.1  dillo 			out_vol->jib.offset, cbargs) != 0)
1.2  dillo 			HFS_LIBERR("could not read journal header");
1.1  dillo
1.2  dillo 		if(hfslib_read_journal_header(buffer, &out_vol->jh)==0)
1.2  dillo 			HFS_LIBERR("could not parse journal header");
1.1  dillo
1.1  dillo 		out_vol->journaled = 1;
1.1  dillo 	}
1.1  dillo 	else
1.1  dillo 	{
1.1  dillo 		out_vol->journaled = 0;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * If this volume uses case-folding comparison and the folding table hasn't
1.2  dillo 	 * been created yet, do that here. (We don't do this in hfslib_init()
1.1  dillo 	 * because the table is large and we might never even need to use it.)
1.1  dillo 	 */
1.2  dillo 	if(out_vol->keycmp==hfslib_compare_catalog_keys_cf && hfs_gcft==NULL)
1.2  dillo 		result = hfslib_create_casefolding_table();
1.1  dillo 	else
1.1  dillo 		result = 0;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * Find and store the volume name.
1.1  dillo 	 */
1.2  dillo 	if(hfslib_make_catalog_key(HFS_CNID_ROOT_FOLDER, 0, NULL, &rootkey)==0)
1.2  dillo 		HFS_LIBERR("could not make root search key");
1.1  dillo
1.2  dillo 	if(hfslib_find_catalog_record_with_key(out_vol, &rootkey,
1.2  dillo 		(hfs_catalog_keyed_record_t*)&rootthread, cbargs)!=0)
1.2  dillo 		HFS_LIBERR("could not find root parent");
1.1  dillo
1.2  dillo 	memcpy(&out_vol->name, &rootthread.name, sizeof(hfs_unistr255_t));
1.1  dillo
1.1  dillo
1.1  dillo 	/* FALLTHROUGH */
1.1  dillo error:
1.1  dillo 	if(buffer!=NULL)
1.2  dillo 		hfslib_free(buffer, cbargs);
1.1  dillo
1.1  dillo 	return result;
1.1  dillo }
1.1  dillo
1.1  dillo void
1.2  dillo hfslib_close_volume(hfs_volume* in_vol, hfs_callback_args* cbargs)
1.1  dillo {
1.1  dillo 	if(in_vol==NULL)
1.1  dillo 		return;
1.1  dillo
1.2  dillo 	hfslib_closevoldevice(in_vol, cbargs);
1.1  dillo }
1.1  dillo
1.1  dillo int
1.2  dillo hfslib_path_to_cnid(hfs_volume* in_vol,
1.2  dillo 	hfs_cnid_t in_cnid,
1.1  dillo 	char** out_unicode,
1.1  dillo 	uint16_t* out_length,
1.2  dillo 	hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	hfs_thread_record_t	parent_thread;
1.2  dillo 	hfs_cnid_t	parent_cnid, child_cnid;
1.1  dillo 	char*		newpath;
1.1  dillo 	char*		path;
1.1  dillo 	int			path_offset = 0;
1.1  dillo 	int			result;
1.1  dillo 	uint16_t*	ptr;	/* dummy var */
1.1  dillo 	uint16_t	uchar;	/* dummy var */
1.1  dillo 	uint16_t	total_path_length;
1.1  dillo
1.1  dillo 	if(in_vol==NULL || in_cnid==0 || out_unicode==NULL || out_length==NULL)
1.1  dillo 		return 1;
1.1  dillo
1.1  dillo 	result = 1;
1.1  dillo 	*out_unicode = NULL;
1.1  dillo 	*out_length = 0;
1.1  dillo 	path = NULL;
1.1  dillo 	total_path_length = 0;
1.1  dillo
1.2  dillo 	path = hfslib_malloc(514, cbargs); /* 256 unichars plus a forward slash */
1.1  dillo 	if(path==NULL)
1.1  dillo 		return 1;
1.1  dillo
1.1  dillo 	child_cnid = in_cnid;
1.1  dillo 	parent_cnid = child_cnid; /* skips loop in case in_cnid is root id */
1.2  dillo 	while(parent_cnid != HFS_CNID_ROOT_FOLDER
1.2  dillo 		&& parent_cnid != HFS_CNID_ROOT_PARENT)
1.1  dillo 	{
1.1  dillo 		if(child_cnid!=in_cnid)
1.1  dillo 		{
1.2  dillo 			newpath = hfslib_realloc(path, 514 + total_path_length*2, cbargs);
1.1  dillo
1.1  dillo 			if(newpath==NULL)
1.1  dillo 				goto exit;
1.1  dillo 			path = newpath;
1.1  dillo
1.1  dillo 			memmove(path + 514, path + path_offset, total_path_length*2);
1.1  dillo 		}
1.1  dillo
1.2  dillo 		parent_cnid = hfslib_find_parent_thread(in_vol, child_cnid,
1.1  dillo 			&parent_thread, cbargs);
1.1  dillo 		if(parent_cnid==0)
1.1  dillo 			goto exit;
1.1  dillo
1.1  dillo 		path_offset = 512 - parent_thread.name.length*2;
1.1  dillo
1.1  dillo 		memcpy(path + path_offset, parent_thread.name.unicode,
1.1  dillo 			parent_thread.name.length*2);
1.1  dillo
1.1  dillo 		/*	Add a forward slash. The unicode string was specified in big endian
1.1  dillo 		 *	format, so convert to core format if necessary. */
1.1  dillo 		path[512]=0x00;
1.1  dillo 		path[513]=0x2F;
1.1  dillo
1.1  dillo 		ptr = (uint16_t*)path + 256;
1.1  dillo 		uchar = be16tohp((void*)&ptr);
1.1  dillo 		*(ptr-1) = uchar;
1.1  dillo
1.1  dillo 		total_path_length += parent_thread.name.length + 1;
1.1  dillo
1.1  dillo 		child_cnid = parent_cnid;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 *	At this point, 'path' holds a sequence of unicode characters which
1.1  dillo 	 *	represent the absolute path to the given cnid. This string is missing
1.1  dillo 	 *	a terminating null char and an initial forward slash that represents
1.1  dillo 	 *	the root of the filesystem. It most likely also has extra space in
1.1  dillo 	 *	the beginning, due to the fact that we reserve 512 bytes for each path
1.1  dillo 	 *	component and won't usually use all that space. So, we allocate the
1.1  dillo 	 *	final string based on the actual length of the absolute path, plus four
1.1  dillo 	 *	additional bytes (two unichars) for the forward slash and the null char.
1.1  dillo 	 */
1.1  dillo
1.2  dillo 	*out_unicode = hfslib_malloc((total_path_length+2)*2, cbargs);
1.1  dillo 	if(*out_unicode == NULL)
1.1  dillo 		goto exit;
1.1  dillo
1.1  dillo 	/* copy only the bytes that are actually used */
1.1  dillo 	memcpy(*out_unicode+2, path + path_offset, total_path_length*2);
1.1  dillo
1.1  dillo 	/* insert forward slash at start */
1.1  dillo 	(*out_unicode)[0] = 0x00;
1.1  dillo 	(*out_unicode)[1] = 0x2F;
1.1  dillo 	ptr = (uint16_t*)*out_unicode;
1.1  dillo 	uchar = be16tohp((void*)&ptr);
1.1  dillo 	*(ptr-1) = uchar;
1.1  dillo
1.1  dillo 	/* insert null char at end */
1.1  dillo 	(*out_unicode)[total_path_length*2+2] = 0x00;
1.1  dillo 	(*out_unicode)[total_path_length*2+3] = 0x00;
1.1  dillo
1.1  dillo 	*out_length = total_path_length + 1 /* extra for forward slash */ ;
1.1  dillo
1.1  dillo 	result = 0;
1.1  dillo
1.1  dillo exit:
1.1  dillo 	if(path!=NULL)
1.2  dillo 		hfslib_free(path, cbargs);
1.1  dillo
1.1  dillo 	return result;
1.1  dillo }
1.1  dillo
1.2  dillo hfs_cnid_t
1.2  dillo hfslib_find_parent_thread(
1.2  dillo 	hfs_volume* in_vol,
1.2  dillo 	hfs_cnid_t in_child,
1.2  dillo 	hfs_thread_record_t* out_thread,
1.2  dillo 	hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	hfs_catalog_key_t	childkey;
1.1  dillo
1.1  dillo 	if(in_vol==NULL || in_child==0 || out_thread==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.2  dillo 	if(hfslib_make_catalog_key(in_child, 0, NULL, &childkey)==0)
1.1  dillo 		return 0;
1.1  dillo
1.2  dillo 	if(hfslib_find_catalog_record_with_key(in_vol, &childkey,
1.2  dillo 		(hfs_catalog_keyed_record_t*)out_thread, cbargs)!=0)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	return out_thread->parent_cnid;
1.1  dillo }
1.1  dillo
1.1  dillo /*
1.2  dillo  * hfslib_find_catalog_record_with_cnid()
1.1  dillo  *
1.2  dillo  * Looks up a catalog record by calling hfslib_find_parent_thread() and
1.2  dillo  * hfslib_find_catalog_record_with_key(). out_key may be NULL; if not, the key
1.1  dillo  * corresponding to this cnid is stuffed in it. Returns 0 on success.
1.1  dillo  */
1.1  dillo int
1.2  dillo hfslib_find_catalog_record_with_cnid(
1.2  dillo 	hfs_volume* in_vol,
1.2  dillo 	hfs_cnid_t in_cnid,
1.2  dillo 	hfs_catalog_keyed_record_t* out_rec,
1.2  dillo 	hfs_catalog_key_t* out_key,
1.2  dillo 	hfs_callback_args* cbargs)
1.2  dillo {
1.2  dillo 	hfs_cnid_t					parentcnid;
1.2  dillo 	hfs_thread_record_t		parentthread;
1.2  dillo 	hfs_catalog_key_t			key;
1.1  dillo
1.1  dillo 	if(in_vol==NULL || in_cnid==0 || out_rec==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	parentcnid =
1.2  dillo 		hfslib_find_parent_thread(in_vol, in_cnid, &parentthread, cbargs);
1.1  dillo 	if(parentcnid == 0)
1.2  dillo 		HFS_LIBERR("could not find parent thread for cnid %i", in_cnid);
1.1  dillo
1.2  dillo 	if(hfslib_make_catalog_key(parentthread.parent_cnid,
1.1  dillo 		parentthread.name.length, parentthread.name.unicode, &key) == 0)
1.2  dillo 		HFS_LIBERR("could not make catalog search key");
1.1  dillo
1.1  dillo 	if(out_key!=NULL)
1.1  dillo 		memcpy(out_key, &key, sizeof(key));
1.1  dillo
1.2  dillo 	return hfslib_find_catalog_record_with_key(in_vol, &key, out_rec, cbargs);
1.1  dillo
1.1  dillo error:
1.1  dillo 	return 1;
1.1  dillo }
1.1  dillo
1.1  dillo /* Returns 0 on success, 1 on error, and -1 if record was not found. */
1.1  dillo int
1.2  dillo hfslib_find_catalog_record_with_key(
1.2  dillo 	hfs_volume* in_vol,
1.2  dillo 	hfs_catalog_key_t* in_key,
1.2  dillo 	hfs_catalog_keyed_record_t* out_rec,
1.2  dillo 	hfs_callback_args* cbargs)
1.2  dillo {
1.2  dillo 	hfs_node_descriptor_t			nd;
1.2  dillo 	hfs_extent_descriptor_t*		extents;
1.2  dillo 	hfs_catalog_keyed_record_t		lastrec;
1.2  dillo 	hfs_catalog_key_t*	curkey;
1.1  dillo 	void**				recs;
1.1  dillo 	void*				buffer;
1.1  dillo 	uint64_t			bytesread;
1.1  dillo 	uint32_t			curnode;
1.1  dillo 	uint16_t*			recsizes;
1.1  dillo 	uint16_t			numextents;
1.1  dillo 	uint16_t			recnum;
1.1  dillo 	int16_t				leaftype;
1.1  dillo 	int					keycompare;
1.1  dillo 	int					result;
1.1  dillo
1.1  dillo 	if(in_key==NULL || out_rec==NULL || in_vol==NULL)
1.1  dillo 		return 1;
1.1  dillo
1.1  dillo 	result = 1;
1.1  dillo 	buffer = NULL;
1.1  dillo 	curkey = NULL;
1.1  dillo 	extents = NULL;
1.1  dillo 	recs = NULL;
1.1  dillo 	recsizes = NULL;
1.1  dillo
1.1  dillo 	/* The key takes up over half a kb of ram, which is a lot for the BSD
1.1  dillo 	 * kernel stack. So allocate it in the heap instead to play it safe. */
1.2  dillo 	curkey = hfslib_malloc(sizeof(hfs_catalog_key_t), cbargs);
1.1  dillo 	if(curkey==NULL)
1.2  dillo 		HFS_LIBERR("could not allocate catalog search key");
1.1  dillo
1.2  dillo 	buffer = hfslib_malloc(in_vol->chr.node_size, cbargs);
1.1  dillo 	if(buffer==NULL)
1.2  dillo 		HFS_LIBERR("could not allocate node buffer");
1.1  dillo
1.2  dillo 	numextents = hfslib_get_file_extents(in_vol, HFS_CNID_CATALOG,
1.2  dillo 		HFS_DATAFORK, &extents, cbargs);
1.1  dillo 	if(numextents==0)
1.2  dillo 		HFS_LIBERR("could not locate fork extents");
1.1  dillo
1.1  dillo 	nd.num_recs = 0;
1.1  dillo 	curnode = in_vol->chr.root_node;
1.1  dillo
1.1  dillo #ifdef DLO_DEBUG
1.1  dillo 	printf("-> key ");
1.1  dillo 	dlo_print_key(in_key);
1.1  dillo 	printf("\n");
1.1  dillo #endif
1.1  dillo
1.1  dillo 	do
1.1  dillo 	{
1.1  dillo #ifdef DLO_DEBUG
1.1  dillo 		printf("--> node %d\n", curnode);
1.1  dillo #endif
1.1  dillo
1.2  dillo 		if(hfslib_readd_with_extents(in_vol, buffer,
1.1  dillo 			&bytesread,in_vol->chr.node_size, curnode * in_vol->chr.node_size,
1.1  dillo 			extents, numextents, cbargs)!=0)
1.2  dillo 			HFS_LIBERR("could not read catalog node #%i", curnode);
1.1  dillo
1.2  dillo 		if(hfslib_reada_node(buffer, &nd, &recs, &recsizes, HFS_CATALOG_FILE,
1.1  dillo 			in_vol, cbargs)==0)
1.2  dillo 			HFS_LIBERR("could not parse catalog node #%i", curnode);
1.1  dillo
1.1  dillo 		for(recnum=0; recnum<nd.num_recs; recnum++)
1.1  dillo 		{
1.1  dillo 			leaftype = nd.kind;
1.2  dillo 			if(hfslib_read_catalog_keyed_record(recs[recnum], out_rec,
1.1  dillo 				&leaftype, curkey, in_vol)==0)
1.2  dillo 				HFS_LIBERR("could not read catalog record #%i",recnum);
1.1  dillo
1.1  dillo #ifdef DLO_DEBUG
1.1  dillo 			printf("---> record %d: ", recnum);
1.1  dillo 			dlo_print_key(curkey);
1.1  dillo 			fflush(stdout);
1.1  dillo #endif
1.1  dillo 			keycompare = in_vol->keycmp(in_key, curkey);
1.1  dillo #ifdef DLO_DEBUG
1.1  dillo 			printf(" %c\n",
1.1  dillo 			       keycompare < 0 ? '<'
1.1  dillo 			       : keycompare == 0 ? '=' : '>');
1.1  dillo #endif
1.1  dillo
1.1  dillo 			if(keycompare < 0)
1.1  dillo 			{
1.1  dillo 				/* Check if key is less than *every* record, which should never
1.1  dillo 				 * happen if the volume is consistent and the key legit. */
1.1  dillo 				if(recnum==0)
1.2  dillo 					HFS_LIBERR("all records greater than key");
1.1  dillo
1.1  dillo 				/* Otherwise, we've found the first record that exceeds our key,
1.1  dillo 				 * so retrieve the previous record, which is still less... */
1.1  dillo 				memcpy(out_rec, &lastrec,
1.2  dillo 					sizeof(hfs_catalog_keyed_record_t));
1.1  dillo
1.1  dillo 				/* ...unless this is a leaf node, which means we've gone from
1.1  dillo 				 * a key which is smaller than the search key, in the previous
1.1  dillo 				 * loop, to a key which is larger, in this loop, and that
1.1  dillo 				 * implies that our search key does not exist on the volume. */
1.2  dillo 				if(nd.kind==HFS_LEAFNODE)
1.1  dillo 					result = -1;
1.1  dillo
1.1  dillo 				break;
1.1  dillo 			}
1.1  dillo 			else if(keycompare == 0)
1.1  dillo 			{
1.1  dillo 				/* If leaf node, found an exact match. */
1.1  dillo 				result = 0;
1.1  dillo 				break;
1.1  dillo 			}
1.1  dillo 			else if(recnum==nd.num_recs-1 && keycompare > 0)
1.1  dillo 			{
1.1  dillo 				/* If leaf node, we've reached the last record with no match,
1.1  dillo 				 * which means this key is not present on the volume. */
1.1  dillo 				result = -1;
1.1  dillo 				break;
1.1  dillo 			}
1.1  dillo
1.2  dillo 			memcpy(&lastrec, out_rec, sizeof(hfs_catalog_keyed_record_t));
1.1  dillo 		}
1.1  dillo
1.2  dillo 		if(nd.kind==HFS_INDEXNODE)
1.1  dillo 			curnode = out_rec->child;
1.2  dillo 		else if(nd.kind==HFS_LEAFNODE)
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs);
1.1  dillo 	}
1.2  dillo 	while(nd.kind!=HFS_LEAFNODE);
1.1  dillo
1.1  dillo 	/* FALLTHROUGH */
1.1  dillo error:
1.1  dillo 	if(extents!=NULL)
1.2  dillo 		hfslib_free(extents, cbargs);
1.2  dillo 	hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs);
1.1  dillo 	if(curkey!=NULL)
1.2  dillo 		hfslib_free(curkey, cbargs);
1.1  dillo 	if(buffer!=NULL)
1.2  dillo 		hfslib_free(buffer, cbargs);
1.1  dillo
1.1  dillo 	return result;
1.1  dillo }
1.1  dillo
1.1  dillo /* returns 0 on success */
1.1  dillo /* XXX Need to look this over and make sure it gracefully handles cases where
1.1  dillo  * XXX the key is not found. */
1.1  dillo int
1.2  dillo hfslib_find_extent_record_with_key(hfs_volume* in_vol,
1.2  dillo 	hfs_extent_key_t* in_key,
1.2  dillo 	hfs_extent_record_t* out_rec,
1.2  dillo 	hfs_callback_args* cbargs)
1.2  dillo {
1.2  dillo 	hfs_node_descriptor_t		nd;
1.2  dillo 	hfs_extent_descriptor_t*	extents;
1.2  dillo 	hfs_extent_record_t		lastrec;
1.2  dillo 	hfs_extent_key_t	curkey;
1.1  dillo 	void**				recs;
1.1  dillo 	void*				buffer;
1.1  dillo 	uint64_t			bytesread;
1.1  dillo 	uint32_t			curnode;
1.1  dillo 	uint16_t*			recsizes;
1.1  dillo 	uint16_t			numextents;
1.1  dillo 	uint16_t			recnum;
1.1  dillo 	int					keycompare;
1.1  dillo 	int					result;
1.1  dillo
1.1  dillo 	if(in_vol==NULL || in_key==NULL || out_rec==NULL)
1.1  dillo 		return 1;
1.1  dillo
1.1  dillo 	result = 1;
1.1  dillo 	buffer = NULL;
1.1  dillo 	extents = NULL;
1.1  dillo 	recs = NULL;
1.1  dillo 	recsizes = NULL;
1.1  dillo
1.2  dillo 	buffer = hfslib_malloc(in_vol->ehr.node_size, cbargs);
1.1  dillo 	if(buffer==NULL)
1.2  dillo 		HFS_LIBERR("could not allocate node buffer");
1.1  dillo
1.2  dillo 	numextents = hfslib_get_file_extents(in_vol, HFS_CNID_EXTENTS,
1.2  dillo 		HFS_DATAFORK, &extents, cbargs);
1.1  dillo 	if(numextents==0)
1.2  dillo 		HFS_LIBERR("could not locate fork extents");
1.1  dillo
1.1  dillo 	nd.num_recs = 0;
1.1  dillo 	curnode = in_vol->ehr.root_node;
1.1  dillo
1.1  dillo 	do
1.1  dillo 	{
1.2  dillo 		hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs);
1.1  dillo 		recnum = 0;
1.1  dillo
1.2  dillo 		if(hfslib_readd_with_extents(in_vol, buffer, &bytesread,
1.1  dillo 			in_vol->ehr.node_size, curnode * in_vol->ehr.node_size, extents,
1.1  dillo 			numextents, cbargs)!=0)
1.2  dillo 			HFS_LIBERR("could not read extents overflow node #%i", curnode);
1.1  dillo
1.2  dillo 		if(hfslib_reada_node(buffer, &nd, &recs, &recsizes, HFS_EXTENTS_FILE,
1.1  dillo 			in_vol, cbargs)==0)
1.2  dillo 			HFS_LIBERR("could not parse extents overflow node #%i",curnode);
1.1  dillo
1.1  dillo 		for(recnum=0; recnum<nd.num_recs; recnum++)
1.1  dillo 		{
1.2  dillo 			memcpy(&lastrec, out_rec, sizeof(hfs_extent_record_t));
1.1  dillo
1.2  dillo 			if(hfslib_read_extent_record(recs[recnum], out_rec, nd.kind,
1.1  dillo 				&curkey, in_vol)==0)
1.2  dillo 				HFS_LIBERR("could not read extents record #%i",recnum);
1.1  dillo
1.2  dillo 			keycompare = hfslib_compare_extent_keys(in_key, &curkey);
1.1  dillo 			if(keycompare < 0)
1.1  dillo 			{
1.1  dillo 				/* this should never happen for any legitimate key */
1.1  dillo 				if(recnum==0)
1.1  dillo 					return 1;
1.1  dillo
1.2  dillo 				memcpy(out_rec, &lastrec, sizeof(hfs_extent_record_t));
1.1  dillo
1.1  dillo 				break;
1.1  dillo 			}
1.1  dillo 			else if(keycompare == 0 ||
1.1  dillo 				(recnum==nd.num_recs-1 && keycompare > 0))
1.1  dillo 				break;
1.1  dillo 		}
1.1  dillo
1.2  dillo 		if(nd.kind==HFS_INDEXNODE)
1.1  dillo 			curnode = *((uint32_t *)out_rec); /* out_rec is a node ptr in this case */
1.2  dillo 		else if(nd.kind==HFS_LEAFNODE)
1.1  dillo 			break;
1.1  dillo 		else
1.2  dillo 		    HFS_LIBERR("unknwon node type for extents overflow node #%i",curnode);
1.1  dillo 	}
1.2  dillo 	while(nd.kind!=HFS_LEAFNODE);
1.1  dillo
1.1  dillo 	result = 0;
1.1  dillo
1.1  dillo 	/* FALLTHROUGH */
1.1  dillo
1.1  dillo error:
1.1  dillo 	if(buffer!=NULL)
1.2  dillo 		hfslib_free(buffer, cbargs);
1.1  dillo 	if(extents!=NULL)
1.2  dillo 		hfslib_free(extents, cbargs);
1.2  dillo 	hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs);
1.1  dillo
1.1  dillo 	return result;
1.1  dillo }
1.1  dillo
1.1  dillo /* out_extents may be NULL. */
1.1  dillo uint16_t
1.2  dillo hfslib_get_file_extents(hfs_volume* in_vol,
1.2  dillo 	hfs_cnid_t in_cnid,
1.1  dillo 	uint8_t in_forktype,
1.2  dillo 	hfs_extent_descriptor_t** out_extents,
1.2  dillo 	hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	hfs_extent_descriptor_t*	dummy;
1.2  dillo 	hfs_extent_key_t		extentkey;
1.2  dillo 	hfs_file_record_t		file;
1.2  dillo 	hfs_catalog_key_t		filekey;
1.2  dillo 	hfs_thread_record_t	fileparent;
1.2  dillo 	hfs_fork_t				fork;
1.2  dillo 	hfs_extent_record_t	nextextentrec;
1.1  dillo 	uint32_t	numblocks;
1.1  dillo 	uint16_t	numextents, n;
1.1  dillo
1.1  dillo 	if(in_vol==NULL || in_cnid==0)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	if(out_extents!=NULL)
1.1  dillo 	{
1.2  dillo 		*out_extents = hfslib_malloc(sizeof(hfs_extent_descriptor_t), cbargs);
1.1  dillo 		if(*out_extents==NULL)
1.1  dillo 			return 0;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	switch(in_cnid)
1.1  dillo 	{
1.2  dillo 		case HFS_CNID_CATALOG:
1.1  dillo 			fork = in_vol->vh.catalog_file;
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		case HFS_CNID_EXTENTS:
1.1  dillo 			fork = in_vol->vh.extents_file;
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		case HFS_CNID_ALLOCATION:
1.1  dillo 			fork = in_vol->vh.allocation_file;
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		case HFS_CNID_ATTRIBUTES:
1.1  dillo 			fork = in_vol->vh.attributes_file;
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		case HFS_CNID_STARTUP:
1.1  dillo 			fork = in_vol->vh.startup_file;
1.1  dillo 			break;
1.1  dillo
1.1  dillo 		default:
1.2  dillo 			if(hfslib_find_parent_thread(in_vol, in_cnid, &fileparent,
1.1  dillo 				cbargs)==0)
1.1  dillo 				goto error;
1.1  dillo
1.2  dillo 			if(hfslib_make_catalog_key(fileparent.parent_cnid,
1.1  dillo 				fileparent.name.length, fileparent.name.unicode, &filekey)==0)
1.1  dillo 				goto error;
1.1  dillo
1.2  dillo 			if(hfslib_find_catalog_record_with_key(in_vol, &filekey,
1.2  dillo 				(hfs_catalog_keyed_record_t*)&file, cbargs)!=0)
1.1  dillo 				goto error;
1.1  dillo
1.1  dillo 			/* only files have extents, not folders or threads */
1.2  dillo 			if(file.rec_type!=HFS_REC_FILE)
1.1  dillo 				goto error;
1.1  dillo
1.2  dillo 			if(in_forktype==HFS_DATAFORK)
1.1  dillo 				fork = file.data_fork;
1.2  dillo 			else if(in_forktype==HFS_RSRCFORK)
1.1  dillo 				fork = file.rsrc_fork;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	numextents = 0;
1.1  dillo 	numblocks = 0;
1.2  dillo 	memcpy(&nextextentrec, &fork.extents, sizeof(hfs_extent_record_t));
1.1  dillo
1.1  dillo 	while(1)
1.1  dillo 	{
1.1  dillo 		for(n=0; n<8; n++)
1.1  dillo 		{
1.1  dillo 			if(nextextentrec[n].block_count==0)
1.1  dillo 				break;
1.1  dillo
1.1  dillo 			numblocks += nextextentrec[n].block_count;
1.1  dillo 		}
1.1  dillo
1.1  dillo 		if(out_extents!=NULL)
1.1  dillo 		{
1.2  dillo 			dummy = hfslib_realloc(*out_extents,
1.2  dillo 			    (numextents+n) * sizeof(hfs_extent_descriptor_t),
1.1  dillo 			    cbargs);
1.1  dillo 			if(dummy==NULL)
1.1  dillo 				goto error;
1.1  dillo 			*out_extents = dummy;
1.1  dillo
1.1  dillo 			memcpy(*out_extents + numextents,
1.2  dillo 			    &nextextentrec, n*sizeof(hfs_extent_descriptor_t));
1.1  dillo 		}
1.1  dillo 		numextents += n;
1.1  dillo
1.1  dillo 		if(numblocks >= fork.total_blocks)
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		if(hfslib_make_extent_key(in_cnid, in_forktype, numblocks,
1.1  dillo 			&extentkey)==0)
1.1  dillo 			goto error;
1.1  dillo
1.2  dillo 		if(hfslib_find_extent_record_with_key(in_vol, &extentkey,
1.1  dillo 			&nextextentrec, cbargs)!=0)
1.1  dillo 			goto error;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	goto exit;
1.1  dillo
1.1  dillo error:
1.1  dillo 	if(out_extents!=NULL && *out_extents!=NULL)
1.1  dillo 	{
1.2  dillo 		hfslib_free(*out_extents, cbargs);
1.1  dillo 		*out_extents = NULL;
1.1  dillo 	}
1.1  dillo 	return 0;
1.1  dillo
1.1  dillo exit:
1.1  dillo 	return numextents;
1.1  dillo }
1.1  dillo
1.1  dillo /*
1.2  dillo  * hfslib_get_directory_contents()
1.1  dillo  *
1.1  dillo  * Finds the immediate children of a given directory CNID and places their
1.1  dillo  * CNIDs in an array allocated here. The first child is found by doing a
1.1  dillo  * catalog search that only compares parent CNIDs (ignoring file/folder names)
1.1  dillo  * and skips over thread records. Then the remaining children are listed in
1.1  dillo  * ascending order by name, according to the HFS+ spec, so just read off each
1.1  dillo  * successive leaf node until a different parent CNID is found.
1.1  dillo  *
1.1  dillo  * If out_childnames is not NULL, it will be allocated and set to an array of
1.2  dillo  * hfs_unistr255_t's which correspond to the name of the child with that same
1.1  dillo  * index.
1.1  dillo  *
1.1  dillo  * out_children may be NULL.
1.1  dillo  *
1.1  dillo  * Returns 0 on success.
1.1  dillo  */
1.1  dillo int
1.2  dillo hfslib_get_directory_contents(
1.2  dillo 	hfs_volume* in_vol,
1.2  dillo 	hfs_cnid_t in_dir,
1.2  dillo 	hfs_catalog_keyed_record_t** out_children,
1.2  dillo 	hfs_unistr255_t** out_childnames,
1.1  dillo 	uint32_t* out_numchildren,
1.2  dillo 	hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	hfs_node_descriptor_t			nd;
1.2  dillo 	hfs_extent_descriptor_t*		extents;
1.2  dillo 	hfs_catalog_keyed_record_t		currec;
1.2  dillo 	hfs_catalog_key_t	curkey;
1.1  dillo 	void**				recs;
1.1  dillo 	void*				buffer;
1.1  dillo 	void*				ptr; /* temporary pointer for realloc() */
1.1  dillo 	uint64_t			bytesread;
1.1  dillo 	uint32_t			curnode;
1.1  dillo 	uint32_t			lastnode;
1.1  dillo 	uint16_t*			recsizes;
1.1  dillo 	uint16_t			numextents;
1.1  dillo 	uint16_t			recnum;
1.1  dillo 	int16_t				leaftype;
1.1  dillo 	int					keycompare;
1.1  dillo 	int					result;
1.1  dillo
1.1  dillo 	if(in_vol==NULL || in_dir==0 || out_numchildren==NULL)
1.1  dillo 		return 1;
1.1  dillo
1.1  dillo 	result = 1;
1.1  dillo 	buffer = NULL;
1.1  dillo 	extents = NULL;
1.1  dillo 	lastnode = 0;
1.1  dillo 	recs = NULL;
1.1  dillo 	recsizes = NULL;
1.1  dillo 	*out_numchildren = 0;
1.1  dillo 	if(out_children!=NULL)
1.1  dillo 		*out_children = NULL;
1.1  dillo 	if(out_childnames!=NULL)
1.1  dillo 		*out_childnames = NULL;
1.1  dillo
1.2  dillo 	buffer = hfslib_malloc(in_vol->chr.node_size, cbargs);
1.1  dillo 	if(buffer==NULL)
1.2  dillo 		HFS_LIBERR("could not allocate node buffer");
1.1  dillo
1.2  dillo 	numextents = hfslib_get_file_extents(in_vol, HFS_CNID_CATALOG,
1.2  dillo 		HFS_DATAFORK, &extents, cbargs);
1.1  dillo 	if(numextents==0)
1.2  dillo 		HFS_LIBERR("could not locate fork extents");
1.1  dillo
1.1  dillo 	nd.num_recs = 0;
1.1  dillo 	curnode = in_vol->chr.root_node;
1.1  dillo
1.1  dillo 	while(1)
1.1  dillo 	{
1.2  dillo 		hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs);
1.1  dillo 		recnum = 0;
1.1  dillo
1.2  dillo 		if(hfslib_readd_with_extents(in_vol, buffer, &bytesread,
1.1  dillo 			in_vol->chr.node_size, curnode * in_vol->chr.node_size, extents,
1.1  dillo 			numextents, cbargs)!=0)
1.2  dillo 			HFS_LIBERR("could not read catalog node #%i", curnode);
1.1  dillo
1.2  dillo 		if(hfslib_reada_node(buffer, &nd, &recs, &recsizes, HFS_CATALOG_FILE,
1.1  dillo 			in_vol, cbargs)==0)
1.2  dillo 			HFS_LIBERR("could not parse catalog node #%i", curnode);
1.1  dillo
1.1  dillo 		for(recnum=0; recnum<nd.num_recs; recnum++)
1.1  dillo 		{
1.1  dillo 			leaftype = nd.kind; /* needed b/c leaftype might be modified now */
1.2  dillo 			if(hfslib_read_catalog_keyed_record(recs[recnum], &currec,
1.1  dillo 				&leaftype, &curkey, in_vol)==0)
1.2  dillo 				HFS_LIBERR("could not read cat record %i:%i", curnode, recnum);
1.1  dillo
1.2  dillo 			if(nd.kind==HFS_INDEXNODE)
1.1  dillo 			{
1.1  dillo 				keycompare = in_dir - curkey.parent_cnid;
1.1  dillo 				if(keycompare < 0)
1.1  dillo 				{
1.1  dillo 					/* Check if key is less than *every* record, which should
1.1  dillo 					 * never happen if the volume and key are good. */
1.1  dillo 					if(recnum==0)
1.2  dillo 						HFS_LIBERR("all records greater than key");
1.1  dillo
1.1  dillo 					/* Otherwise, we've found the first record that exceeds our
1.1  dillo 					 * key, so retrieve the previous, lesser record. */
1.1  dillo 					curnode = lastnode;
1.1  dillo 					break;
1.1  dillo 				}
1.1  dillo 				else if(keycompare == 0)
1.1  dillo 				{
1.1  dillo 					/*
1.1  dillo 					 * Normally, if we were doing a typical catalog lookup with
1.1  dillo 					 * both a parent cnid AND a name, keycompare==0 would be an
1.1  dillo 					 * exact match. However, since we are ignoring object names
1.1  dillo 					 * in this case and only comparing parent cnids, a direct
1.1  dillo 					 * match on only a parent cnid could mean that we've found
1.1  dillo 					 * an object with that parent cnid BUT which is NOT the
1.1  dillo 					 * first object (according to the HFS+ spec) with that
1.1  dillo 					 * parent cnid. Thus, when we find a parent cnid match, we
1.1  dillo 					 * still go back to the previously found leaf node and start
1.1  dillo 					 * checking it for a possible prior instance of an object
1.1  dillo 					 * with our desired parent cnid.
1.1  dillo 					 */
1.1  dillo 					curnode = lastnode;
1.1  dillo 					break;
1.1  dillo 				}
1.1  dillo 				else if (recnum==nd.num_recs-1 && keycompare > 0)
1.1  dillo 				{
1.1  dillo 					/* Descend to child node if we found an exact match, or if
1.1  dillo 					 * this is the last pointer record. */
1.1  dillo 					curnode = currec.child;
1.1  dillo 					break;
1.1  dillo 				}
1.1  dillo
1.1  dillo 				lastnode = currec.child;
1.1  dillo 			}
1.1  dillo 			else
1.1  dillo 			{
1.1  dillo 				/*
1.1  dillo 				 * We have now descended down the hierarchy of index nodes into
1.1  dillo 				 * the leaf node that contains the first catalog record with a
1.1  dillo 				 * matching parent CNID. Since all leaf nodes are chained
1.1  dillo 				 * through their flink/blink, we can simply walk forward through
1.1  dillo 				 * this chain, copying every matching non-thread record, until
1.1  dillo 				 * we hit a record with a different parent CNID. At that point,
1.1  dillo 				 * we've retrieved all of our directory's items, if any.
1.1  dillo 				 */
1.1  dillo 				curnode = nd.flink;
1.1  dillo
1.1  dillo 				if(curkey.parent_cnid<in_dir)
1.1  dillo 					continue;
1.1  dillo 				else if(curkey.parent_cnid==in_dir)
1.1  dillo 				{
1.1  dillo 					/* Hide files/folders which are supposed to be invisible
1.1  dillo 					 * to users, according to the hfs+ spec. */
1.2  dillo 					if(hfslib_is_private_file(&curkey))
1.1  dillo 						continue;
1.1  dillo
1.1  dillo 					/* leaftype has now been set to the catalog record type */
1.2  dillo 					if(leaftype==HFS_REC_FLDR || leaftype==HFS_REC_FILE)
1.1  dillo 					{
1.1  dillo 						(*out_numchildren)++;
1.1  dillo
1.1  dillo 						if(out_children!=NULL)
1.1  dillo 						{
1.2  dillo 							ptr = hfslib_realloc(*out_children,
1.1  dillo 								*out_numchildren *
1.2  dillo 								sizeof(hfs_catalog_keyed_record_t), cbargs);
1.1  dillo 							if(ptr==NULL)
1.2  dillo 								HFS_LIBERR("could not allocate child record");
1.1  dillo 							*out_children = ptr;
1.1  dillo
1.1  dillo 							memcpy(&((*out_children)[*out_numchildren-1]),
1.2  dillo 								&currec, sizeof(hfs_catalog_keyed_record_t));
1.1  dillo 						}
1.1  dillo
1.1  dillo 						if(out_childnames!=NULL)
1.1  dillo 						{
1.2  dillo 							ptr = hfslib_realloc(*out_childnames,
1.2  dillo 								*out_numchildren * sizeof(hfs_unistr255_t),
1.1  dillo 								cbargs);
1.1  dillo 							if(ptr==NULL)
1.2  dillo 								HFS_LIBERR("could not allocate child name");
1.1  dillo 							*out_childnames = ptr;
1.1  dillo
1.1  dillo 							memcpy(&((*out_childnames)[*out_numchildren-1]),
1.2  dillo 								&curkey.name, sizeof(hfs_unistr255_t));
1.1  dillo 						}
1.1  dillo 					}
1.1  dillo 				} else {
1.1  dillo 					result = 0;
1.1  dillo 					/* We have just now passed the last item in the desired
1.1  dillo 					 * folder (or the folder was empty), so exit. */
1.1  dillo 					goto exit;
1.1  dillo 				}
1.1  dillo 			}
1.1  dillo 		}
1.1  dillo 	}
1.1  dillo
1.1  dillo 	result = 0;
1.1  dillo
1.1  dillo 	goto exit;
1.1  dillo
1.1  dillo error:
1.1  dillo 	if(out_children!=NULL && *out_children!=NULL)
1.2  dillo 		hfslib_free(*out_children, cbargs);
1.1  dillo 	if(out_childnames!=NULL && *out_childnames!=NULL)
1.2  dillo 		hfslib_free(*out_childnames, cbargs);
1.1  dillo
1.1  dillo 	/* FALLTHROUGH */
1.1  dillo
1.1  dillo exit:
1.1  dillo 	if(extents!=NULL)
1.2  dillo 		hfslib_free(extents, cbargs);
1.2  dillo 	hfslib_free_recs(&recs, &recsizes, &nd.num_recs, cbargs);
1.1  dillo 	if(buffer!=NULL)
1.2  dillo 		hfslib_free(buffer, cbargs);
1.1  dillo
1.1  dillo 	return result;
1.1  dillo }
1.1  dillo
1.1  dillo int
1.2  dillo hfslib_is_journal_clean(hfs_volume* in_vol)
1.1  dillo {
1.1  dillo 	if(in_vol==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	/* return true if no journal */
1.2  dillo 	if(!(in_vol->vh.attributes & (1<<HFS_VOL_JOURNALED)))
1.1  dillo 		return 1;
1.1  dillo
1.1  dillo 	return (in_vol->jh.start == in_vol->jh.end);
1.1  dillo }
1.1  dillo
1.1  dillo /*
1.2  dillo  * hfslib_is_private_file()
1.1  dillo  *
1.1  dillo  * Given a file/folder's key and parent CNID, determines if it should be hidden
1.1  dillo  * from the user (e.g., the journal header file or the HFS+ Private Data folder)
1.1  dillo  */
1.1  dillo int
1.2  dillo hfslib_is_private_file(hfs_catalog_key_t *filekey)
1.1  dillo {
1.2  dillo 	hfs_catalog_key_t* curkey = NULL;
1.1  dillo 	int i = 0;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * According to the HFS+ spec to date, all special objects are located in
1.1  dillo 	 * the root directory of the volume, so don't bother going further if the
1.1  dillo 	 * requested object is not.
1.1  dillo 	 */
1.2  dillo 	if(filekey->parent_cnid != HFS_CNID_ROOT_FOLDER)
1.1  dillo 		return 0;
1.1  dillo
1.2  dillo 	while((curkey = hfs_gPrivateObjectKeys[i]) != NULL)
1.1  dillo 	{
1.1  dillo 		/* XXX Always use binary compare here, or use volume's specific key
1.1  dillo 		 * XXX comparison routine? */
1.1  dillo 		if(filekey->name.length == curkey->name.length
1.1  dillo 			&& memcmp(filekey->name.unicode, curkey->name.unicode,
1.1  dillo 				2 * curkey->name.length)==0)
1.1  dillo 			return 1;
1.1  dillo
1.1  dillo 		i++;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	return 0;
1.1  dillo }
1.1  dillo
1.1  dillo
1.1  dillo /* bool
1.2  dillo hfslib_is_journal_valid(hfs_volume* in_vol)
1.1  dillo {
1.1  dillo 	- check magic numbers
1.1  dillo 	- check Other Things
1.1  dillo }*/
1.1  dillo
1.1  dillo #if 0
1.1  dillo #pragma mark -
1.1  dillo #pragma mark Major Structures
1.1  dillo #endif
1.1  dillo
1.1  dillo /*
1.2  dillo  *	hfslib_read_volume_header()
1.1  dillo  *
1.1  dillo  *	Reads in_bytes, formats the data appropriately, and places the result
1.1  dillo  *	in out_header, which is assumed to be previously allocated. Returns number
1.1  dillo  *	of bytes read, 0 if failed.
1.1  dillo  */
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_volume_header(void* in_bytes, hfs_volume_header_t* out_header)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo 	size_t	last_bytes_read;
1.1  dillo 	int		i;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_header==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	out_header->signature = be16tohp(&ptr);
1.1  dillo 	out_header->version = be16tohp(&ptr);
1.1  dillo 	out_header->attributes = be32tohp(&ptr);
1.1  dillo 	out_header->last_mounting_version = be32tohp(&ptr);
1.1  dillo 	out_header->journal_info_block = be32tohp(&ptr);
1.1  dillo
1.1  dillo 	out_header->date_created = be32tohp(&ptr);
1.1  dillo 	out_header->date_modified = be32tohp(&ptr);
1.1  dillo 	out_header->date_backedup = be32tohp(&ptr);
1.1  dillo 	out_header->date_checked = be32tohp(&ptr);
1.1  dillo
1.1  dillo 	out_header->file_count = be32tohp(&ptr);
1.1  dillo 	out_header->folder_count = be32tohp(&ptr);
1.1  dillo
1.1  dillo 	out_header->block_size = be32tohp(&ptr);
1.1  dillo 	out_header->total_blocks = be32tohp(&ptr);
1.1  dillo 	out_header->free_blocks = be32tohp(&ptr);
1.1  dillo 	out_header->next_alloc_block = be32tohp(&ptr);
1.1  dillo 	out_header->rsrc_clump_size = be32tohp(&ptr);
1.1  dillo 	out_header->data_clump_size = be32tohp(&ptr);
1.1  dillo 	out_header->next_cnid = be32tohp(&ptr);
1.1  dillo
1.1  dillo 	out_header->write_count = be32tohp(&ptr);
1.1  dillo 	out_header->encodings = be64tohp(&ptr);
1.1  dillo
1.1  dillo 	for(i=0;i<8;i++)
1.1  dillo 		out_header->finder_info[i] = be32tohp(&ptr);
1.1  dillo
1.2  dillo 	if((last_bytes_read = hfslib_read_fork_descriptor(ptr,
1.1  dillo 		&out_header->allocation_file))==0)
1.1  dillo 		return 0;
1.1  dillo 	ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.2  dillo 	if((last_bytes_read = hfslib_read_fork_descriptor(ptr,
1.1  dillo 		&out_header->extents_file))==0)
1.1  dillo 		return 0;
1.1  dillo 	ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.2  dillo 	if((last_bytes_read = hfslib_read_fork_descriptor(ptr,
1.1  dillo 		&out_header->catalog_file))==0)
1.1  dillo 		return 0;
1.1  dillo 	ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.2  dillo 	if((last_bytes_read = hfslib_read_fork_descriptor(ptr,
1.1  dillo 		&out_header->attributes_file))==0)
1.1  dillo 		return 0;
1.1  dillo 	ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.2  dillo 	if((last_bytes_read = hfslib_read_fork_descriptor(ptr,
1.1  dillo 		&out_header->startup_file))==0)
1.1  dillo 		return 0;
1.1  dillo 	ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo /*
1.2  dillo  *	hfslib_reada_node()
1.1  dillo  *
1.1  dillo  *	Given the pointer to and size of a buffer containing the entire, raw
1.1  dillo  *	contents of any b-tree node from the disk, this function will:
1.1  dillo  *
1.1  dillo  *		1.	determine the type of node and read its contents
1.1  dillo  *		2.	allocate memory for each record and fill it appropriately
1.1  dillo  *		3.	set out_record_ptrs_array to point to an array (which it allocates)
1.1  dillo  *			which has out_node_descriptor->num_recs many pointers to the
1.1  dillo  *			records themselves
1.1  dillo  *		4.	allocate out_record_ptr_sizes_array and fill it with the sizes of
1.1  dillo  *			each record
1.1  dillo  *		5.	return the number of bytes read (i.e., the size of the node)
1.1  dillo  *			or 0 on failure
1.1  dillo  *
1.1  dillo  *	out_node_descriptor must be allocated by the caller and may not be NULL.
1.1  dillo  *
1.1  dillo  *	out_record_ptrs_array and out_record_ptr_sizes_array must both be specified,
1.1  dillo  *	or both be NULL if the caller is not interested in reading the records.
1.1  dillo  *
1.1  dillo  *	out_record_ptr_sizes_array may be NULL if the caller is not interested in
1.1  dillo  *	reading the records, but must not be NULL if out_record_ptrs_array is not.
1.1  dillo  *
1.2  dillo  *	in_parent_file is HFS_CATALOG_FILE, HFS_EXTENTS_FILE, or
1.2  dillo  *	HFS_ATTRIBUTES_FILE, depending on the special file in which this node
1.1  dillo  *	resides.
1.1  dillo  *
1.1  dillo  *	inout_volume must have its catnodesize or extnodesize field (depending on
1.1  dillo  *	the parent file) set to the correct value if this is an index, leaf, or map
1.1  dillo  *	node. If this is a header node, the field will be set to its correct value.
1.1  dillo  */
1.1  dillo size_t
1.2  dillo hfslib_reada_node(void* in_bytes,
1.2  dillo 	hfs_node_descriptor_t* out_node_descriptor,
1.1  dillo 	void** out_record_ptrs_array[],
1.1  dillo 	uint16_t* out_record_ptr_sizes_array[],
1.2  dillo 	hfs_btree_file_type in_parent_file,
1.2  dillo 	hfs_volume* inout_volume,
1.2  dillo 	hfs_callback_args* cbargs)
1.1  dillo {
1.1  dillo 	void*		ptr;
1.1  dillo 	uint16_t*	rec_offsets;
1.1  dillo 	size_t		last_bytes_read;
1.1  dillo 	uint16_t	nodesize;
1.1  dillo 	uint16_t	numrecords;
1.1  dillo 	uint16_t	free_space_offset;	/* offset to free space in node */
1.1  dillo 	int			keysizefieldsize;
1.1  dillo 	int			i;
1.1  dillo
1.1  dillo 	numrecords = 0;
1.1  dillo 	rec_offsets = NULL;
1.1  dillo 	if(out_record_ptrs_array!=NULL)
1.1  dillo 		*out_record_ptrs_array = NULL;
1.1  dillo 	if(out_record_ptr_sizes_array!=NULL)
1.1  dillo 		*out_record_ptr_sizes_array = NULL;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || inout_volume==NULL || out_node_descriptor==NULL
1.1  dillo 		|| (out_record_ptrs_array==NULL && out_record_ptr_sizes_array!=NULL)
1.1  dillo 		|| (out_record_ptrs_array!=NULL && out_record_ptr_sizes_array==NULL) )
1.1  dillo 		goto error;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	out_node_descriptor->flink = be32tohp(&ptr);
1.1  dillo 	out_node_descriptor->blink = be32tohp(&ptr);
1.1  dillo 	out_node_descriptor->kind = *(((int8_t*)ptr));
1.1  dillo 	ptr = (uint8_t*)ptr + 1;
1.1  dillo 	out_node_descriptor->height = *(((uint8_t*)ptr));
1.1  dillo 	ptr = (uint8_t*)ptr + 1;
1.1  dillo 	out_node_descriptor->num_recs = be16tohp(&ptr);
1.1  dillo 	out_node_descriptor->reserved = be16tohp(&ptr);
1.1  dillo
1.1  dillo 	numrecords = out_node_descriptor->num_recs;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 *	To go any further, we will need to know the size of this node, as well
1.1  dillo 	 *	as the width of keyed records' key_len parameters for this btree. If
1.1  dillo 	 *	this is an index, leaf, or map node, inout_volume already has the node
1.1  dillo 	 *	size set in its catnodesize or extnodesize field and the key length set
1.1  dillo 	 *	in the catkeysizefieldsize or extkeysizefieldsize for catalog files and
1.1  dillo 	 *	extent files, respectively. However, if this is a header node, this
1.1  dillo 	 *	information has not yet been determined, so this is the place to do it.
1.1  dillo 	 */
1.2  dillo 	if(out_node_descriptor->kind == HFS_HEADERNODE)
1.1  dillo 	{
1.2  dillo 		hfs_header_record_t	hr;
1.1  dillo 		void*		header_rec_offset[1];
1.1  dillo 		uint16_t	header_rec_size[1];
1.1  dillo
1.1  dillo 		/* sanity check to ensure this is a good header node */
1.1  dillo 		if(numrecords!=3)
1.2  dillo 			HFS_LIBERR("header node does not have exactly 3 records");
1.1  dillo
1.1  dillo 		header_rec_offset[0] = ptr;
1.2  dillo 		header_rec_size[0] = sizeof(hfs_header_record_t);
1.1  dillo
1.2  dillo 		last_bytes_read = hfslib_read_header_node(header_rec_offset,
1.1  dillo 			header_rec_size, 1, &hr, NULL, NULL);
1.1  dillo 		if(last_bytes_read==0)
1.2  dillo 			HFS_LIBERR("could not read header node");
1.1  dillo
1.1  dillo 		switch(in_parent_file)
1.1  dillo 		{
1.2  dillo 			case HFS_CATALOG_FILE:
1.1  dillo 				inout_volume->chr.node_size = hr.node_size;
1.1  dillo 				inout_volume->catkeysizefieldsize =
1.2  dillo 					(hr.attributes & HFS_BIG_KEYS_MASK) ?
1.1  dillo 						sizeof(uint16_t):sizeof(uint8_t);
1.1  dillo 				break;
1.1  dillo
1.2  dillo 			case HFS_EXTENTS_FILE:
1.1  dillo 				inout_volume->ehr.node_size = hr.node_size;
1.1  dillo 				inout_volume->extkeysizefieldsize =
1.2  dillo 					(hr.attributes & HFS_BIG_KEYS_MASK) ?
1.1  dillo 						sizeof(uint16_t):sizeof(uint8_t);
1.1  dillo 				break;
1.1  dillo
1.2  dillo 			case HFS_ATTRIBUTES_FILE:
1.1  dillo 			default:
1.2  dillo 				HFS_LIBERR("invalid parent file type specified");
1.1  dillo 				/* NOTREACHED */
1.1  dillo 		}
1.1  dillo 	}
1.1  dillo
1.1  dillo 	switch(in_parent_file)
1.1  dillo 	{
1.2  dillo 		case HFS_CATALOG_FILE:
1.1  dillo 			nodesize = inout_volume->chr.node_size;
1.1  dillo 			keysizefieldsize = inout_volume->catkeysizefieldsize;
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		case HFS_EXTENTS_FILE:
1.1  dillo 			nodesize = inout_volume->ehr.node_size;
1.1  dillo 			keysizefieldsize = inout_volume->extkeysizefieldsize;
1.1  dillo 			break;
1.1  dillo
1.2  dillo 		case HFS_ATTRIBUTES_FILE:
1.1  dillo 		default:
1.2  dillo 			HFS_LIBERR("invalid parent file type specified");
1.1  dillo 			/* NOTREACHED */
1.1  dillo 	}
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 *	Don't care about records so just exit after getting the node descriptor.
1.1  dillo 	 *	Note: This happens after the header node code, and not before it, in
1.1  dillo 	 *	case the caller calls this function and ignores the record data just to
1.1  dillo 	 *	get at the node descriptor, but then tries to call it again on a non-
1.1  dillo 	 *	header node without first setting inout_volume->cat/extnodesize.
1.1  dillo 	 */
1.1  dillo 	if(out_record_ptrs_array==NULL)
1.1  dillo 		return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo
1.2  dillo 	rec_offsets = hfslib_malloc(numrecords * sizeof(uint16_t), cbargs);
1.1  dillo 	*out_record_ptr_sizes_array =
1.2  dillo 		hfslib_malloc(numrecords * sizeof(uint16_t), cbargs);
1.1  dillo 	if(rec_offsets==NULL || *out_record_ptr_sizes_array==NULL)
1.2  dillo 		HFS_LIBERR("could not allocate node record offsets");
1.1  dillo
1.2  dillo 	*out_record_ptrs_array = hfslib_malloc(numrecords * sizeof(void*), cbargs);
1.1  dillo 	if(*out_record_ptrs_array==NULL)
1.2  dillo 		HFS_LIBERR("could not allocate node records");
1.1  dillo
1.2  dillo 	last_bytes_read = hfslib_reada_node_offsets((uint8_t*)in_bytes + nodesize -
1.1  dillo 			numrecords * sizeof(uint16_t), rec_offsets);
1.1  dillo 	if(last_bytes_read==0)
1.2  dillo 		HFS_LIBERR("could not read node record offsets");
1.1  dillo
1.1  dillo 	/*	The size of the last record (i.e. the first one listed in the offsets)
1.1  dillo 	 *	must be determined using the offset to the node's free space. */
1.1  dillo 	free_space_offset = be16toh(*(uint16_t*)((uint8_t*)in_bytes + nodesize -
1.1  dillo 			(numrecords+1) * sizeof(uint16_t)));
1.1  dillo
1.1  dillo 	(*out_record_ptr_sizes_array)[numrecords-1] =
1.1  dillo 		free_space_offset - rec_offsets[0];
1.1  dillo 	for(i=1;i<numrecords;i++)
1.1  dillo 	{
1.1  dillo 		(*out_record_ptr_sizes_array)[numrecords-i-1] =
1.1  dillo 			rec_offsets[i-1] - rec_offsets[i];
1.1  dillo 	}
1.1  dillo
1.1  dillo 	for(i=0;i<numrecords;i++)
1.1  dillo 	{
1.1  dillo 		(*out_record_ptrs_array)[i] =
1.2  dillo 			hfslib_malloc((*out_record_ptr_sizes_array)[i], cbargs);
1.1  dillo
1.1  dillo 		if((*out_record_ptrs_array)[i]==NULL)
1.2  dillo 			HFS_LIBERR("could not allocate node record #%i",i);
1.1  dillo
1.1  dillo 		/*
1.1  dillo 		 *	If this is a keyed node (i.e., a leaf or index node), there are two
1.1  dillo 		 *	boundary rules that each record must obey:
1.1  dillo 		 *
1.1  dillo 		 *		1.	A pad byte must be placed between the key and data if the
1.1  dillo 		 *			size of the key plus the size of the key_len field is odd.
1.1  dillo 		 *
1.1  dillo 		 *		2.	A pad byte must be placed after the data if the data size
1.1  dillo 		 *			is odd.
1.1  dillo 		 *
1.1  dillo 		 *	So in the first case we increment the starting point of the data
1.1  dillo 		 *	and correspondingly decrement the record size. In the second case
1.1  dillo 		 *	we decrement the record size.
1.1  dillo 		 */
1.2  dillo 		if(out_node_descriptor->kind == HFS_LEAFNODE ||
1.2  dillo 		   out_node_descriptor->kind == HFS_INDEXNODE)
1.1  dillo 		{
1.2  dillo 			hfs_catalog_key_t	reckey;
1.1  dillo 			uint16_t			rectype;
1.1  dillo
1.1  dillo 			rectype = out_node_descriptor->kind;
1.2  dillo 			last_bytes_read = hfslib_read_catalog_keyed_record(ptr, NULL,
1.1  dillo 				&rectype, &reckey, inout_volume);
1.1  dillo 			if(last_bytes_read==0)
1.2  dillo 				HFS_LIBERR("could not read node record");
1.1  dillo
1.1  dillo 			if((reckey.key_len + keysizefieldsize) % 2 == 1)
1.1  dillo 			{
1.1  dillo 				ptr = (uint8_t*)ptr + 1;
1.1  dillo 				(*out_record_ptr_sizes_array)[i]--;
1.1  dillo 			}
1.1  dillo
1.1  dillo 			if((*out_record_ptr_sizes_array)[i] % 2 == 1)
1.1  dillo 				(*out_record_ptr_sizes_array)[i]--;
1.1  dillo 		}
1.1  dillo
1.1  dillo 		memcpy((*out_record_ptrs_array)[i], ptr,
1.1  dillo 				(*out_record_ptr_sizes_array)[i]);
1.1  dillo 		ptr = (uint8_t*)ptr + (*out_record_ptr_sizes_array)[i];
1.1  dillo 	}
1.1  dillo
1.1  dillo 	goto exit;
1.1  dillo
1.1  dillo error:
1.2  dillo 	hfslib_free_recs(out_record_ptrs_array, out_record_ptr_sizes_array,
1.1  dillo 		&numrecords, cbargs);
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.2  dillo 	/* warn("error occurred in hfslib_reada_node()"); */
1.1  dillo
1.1  dillo 	/* FALLTHROUGH */
1.1  dillo
1.1  dillo exit:
1.1  dillo 	if(rec_offsets!=NULL)
1.2  dillo 		hfslib_free(rec_offsets, cbargs);
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo /*
1.2  dillo  *	hfslib_reada_node_offsets()
1.1  dillo  *
1.1  dillo  *	Sets out_offset_array to contain the offsets to each record in the node,
1.1  dillo  *	in reverse order. Does not read the free space offset.
1.1  dillo  */
1.1  dillo size_t
1.2  dillo hfslib_reada_node_offsets(void* in_bytes, uint16_t* out_offset_array)
1.1  dillo {
1.1  dillo 	void*		ptr;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_offset_array==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 *	The offset for record 0 (which is the very last offset in the node) is
1.1  dillo 	 *	always equal to 14, the size of the node descriptor. So, once we hit
1.1  dillo 	 *	offset=14, we know this is the last offset. In this way, we don't need
1.1  dillo 	 *	to know the number of records beforehand.
1.1  dillo 	*/
1.1  dillo 	out_offset_array--;
1.1  dillo 	do
1.1  dillo 	{
1.1  dillo 		out_offset_array++;
1.1  dillo 		*out_offset_array = be16tohp(&ptr);
1.1  dillo 	}
1.1  dillo 	while(*out_offset_array != (uint16_t)14);
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.2  dillo /*	hfslib_read_header_node()
1.1  dillo  *
1.1  dillo  *	out_header_record and/or out_map_record may be NULL if the caller doesn't
1.1  dillo  *	care about their contents.
1.1  dillo  */
1.1  dillo size_t
1.2  dillo hfslib_read_header_node(void** in_recs,
1.1  dillo 	uint16_t* in_rec_sizes,
1.1  dillo 	uint16_t in_num_recs,
1.2  dillo 	hfs_header_record_t* out_hr,
1.1  dillo 	void* out_userdata,
1.1  dillo 	void* out_map)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo 	int		i;
1.1  dillo
1.1  dillo 	if(in_recs==NULL || in_rec_sizes==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	if(out_hr!=NULL)
1.1  dillo 	{
1.1  dillo 		ptr = in_recs[0];
1.1  dillo
1.1  dillo 		out_hr->tree_depth = be16tohp(&ptr);
1.1  dillo 		out_hr->root_node = be32tohp(&ptr);
1.1  dillo 		out_hr->leaf_recs = be32tohp(&ptr);
1.1  dillo 		out_hr->first_leaf = be32tohp(&ptr);
1.1  dillo 		out_hr->last_leaf = be32tohp(&ptr);
1.1  dillo 		out_hr->node_size = be16tohp(&ptr);
1.1  dillo 		out_hr->max_key_len = be16tohp(&ptr);
1.1  dillo 		out_hr->total_nodes = be32tohp(&ptr);
1.1  dillo 		out_hr->free_nodes = be32tohp(&ptr);
1.1  dillo 		out_hr->reserved = be16tohp(&ptr);
1.1  dillo 		out_hr->clump_size = be32tohp(&ptr);
1.1  dillo 		out_hr->btree_type = *(((uint8_t*)ptr));
1.1  dillo 		ptr = (uint8_t*)ptr + 1;
1.1  dillo 		out_hr->keycomp_type = *(((uint8_t*)ptr));
1.1  dillo 		ptr = (uint8_t*)ptr + 1;
1.1  dillo 		out_hr->attributes = be32tohp(&ptr);
1.1  dillo 		for(i=0;i<16;i++)
1.1  dillo 			out_hr->reserved2[i] = be32tohp(&ptr);
1.1  dillo 	}
1.1  dillo
1.1  dillo 	if(out_userdata!=NULL)
1.1  dillo 	{
1.1  dillo 		memcpy(out_userdata, in_recs[1], in_rec_sizes[1]);
1.1  dillo 	}
1.1  dillo 	ptr = (uint8_t*)ptr + in_rec_sizes[1];	/* size of user data record */
1.1  dillo
1.1  dillo 	if(out_map!=NULL)
1.1  dillo 	{
1.1  dillo 		memcpy(out_map, in_recs[2], in_rec_sizes[2]);
1.1  dillo 	}
1.1  dillo 	ptr = (uint8_t*)ptr + in_rec_sizes[2];	/* size of map record */
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_recs[0]);
1.1  dillo }
1.1  dillo
1.1  dillo /*
1.2  dillo  *	hfslib_read_catalog_keyed_record()
1.1  dillo  *
1.2  dillo  *	out_recdata can be NULL. inout_rectype must be set to either HFS_LEAFNODE
1.2  dillo  *	or HFS_INDEXNODE upon calling this function, and will be set by the
1.2  dillo  *	function to one of HFS_REC_FLDR, HFS_REC_FILE, HFS_REC_FLDR_THREAD, or
1.2  dillo  *	HFS_REC_FLDR_THREAD upon return if the node is a leaf node. If it is an
1.1  dillo  *	index node, inout_rectype will not be changed.
1.1  dillo  */
1.1  dillo size_t
1.2  dillo hfslib_read_catalog_keyed_record(
1.1  dillo 	void* in_bytes,
1.2  dillo 	hfs_catalog_keyed_record_t* out_recdata,
1.1  dillo 	int16_t* inout_rectype,
1.2  dillo 	hfs_catalog_key_t* out_key,
1.2  dillo 	hfs_volume* in_volume)
1.1  dillo {
1.1  dillo 	void*		ptr;
1.1  dillo 	size_t		last_bytes_read;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_key==NULL || inout_rectype==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	/*	For HFS+, the key length is always a 2-byte number. This is indicated
1.2  dillo 	 *	by the HFS_BIG_KEYS_MASK bit in the attributes field of the catalog
1.1  dillo 	 *	header record. However, we just assume this bit is set, since all HFS+
1.1  dillo 	 *	volumes should have it set anyway. */
1.1  dillo 	if(in_volume->catkeysizefieldsize == sizeof(uint16_t))
1.1  dillo 		out_key->key_len = be16tohp(&ptr);
1.1  dillo 	else if (in_volume->catkeysizefieldsize == sizeof(uint8_t)) {
1.1  dillo 		out_key->key_len = *(((uint8_t*)ptr));
1.1  dillo 		ptr = (uint8_t*)ptr + 1;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	out_key->parent_cnid = be32tohp(&ptr);
1.1  dillo
1.2  dillo 	last_bytes_read = hfslib_read_unistr255(ptr, &out_key->name);
1.1  dillo 	if(last_bytes_read==0)
1.1  dillo 		return 0;
1.1  dillo 	ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.1  dillo 	/* don't waste time if the user just wanted the key and/or record type */
1.1  dillo 	if(out_recdata==NULL)
1.1  dillo 	{
1.2  dillo 		if(*inout_rectype == HFS_LEAFNODE)
1.1  dillo 			*inout_rectype = be16tohp(&ptr);
1.2  dillo 		else if(*inout_rectype != HFS_INDEXNODE)
1.1  dillo 			return 0;	/* should not happen if we were given valid arguments */
1.1  dillo
1.1  dillo 		return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo 	}
1.1  dillo
1.2  dillo 	if(*inout_rectype == HFS_INDEXNODE)
1.1  dillo 	{
1.1  dillo 		out_recdata->child = be32tohp(&ptr);
1.1  dillo 	}
1.1  dillo 	else
1.1  dillo 	{
1.1  dillo 		/* first need to determine what kind of record this is */
1.1  dillo 		*inout_rectype = be16tohp(&ptr);
1.1  dillo 		out_recdata->type = *inout_rectype;
1.1  dillo
1.1  dillo 		switch(out_recdata->type)
1.1  dillo 		{
1.2  dillo 			case HFS_REC_FLDR:
1.1  dillo 			{
1.1  dillo 				out_recdata->folder.flags = be16tohp(&ptr);
1.1  dillo 				out_recdata->folder.valence = be32tohp(&ptr);
1.1  dillo 				out_recdata->folder.cnid = be32tohp(&ptr);
1.1  dillo 				out_recdata->folder.date_created = be32tohp(&ptr);
1.1  dillo 				out_recdata->folder.date_content_mod = be32tohp(&ptr);
1.1  dillo 				out_recdata->folder.date_attrib_mod = be32tohp(&ptr);
1.1  dillo 				out_recdata->folder.date_accessed = be32tohp(&ptr);
1.1  dillo 				out_recdata->folder.date_backedup = be32tohp(&ptr);
1.1  dillo
1.2  dillo 				last_bytes_read = hfslib_read_bsd_data(ptr,
1.1  dillo 					&out_recdata->folder.bsd);
1.1  dillo 				if(last_bytes_read==0)
1.1  dillo 					return 0;
1.1  dillo 				ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.2  dillo 				last_bytes_read = hfslib_read_folder_userinfo(ptr,
1.1  dillo 					&out_recdata->folder.user_info);
1.1  dillo 				if(last_bytes_read==0)
1.1  dillo 					return 0;
1.1  dillo 				ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.2  dillo 				last_bytes_read = hfslib_read_folder_finderinfo(ptr,
1.1  dillo 					&out_recdata->folder.finder_info);
1.1  dillo 				if(last_bytes_read==0)
1.1  dillo 					return 0;
1.1  dillo 				ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.1  dillo 				out_recdata->folder.text_encoding = be32tohp(&ptr);
1.1  dillo 				out_recdata->folder.reserved = be32tohp(&ptr);
1.1  dillo 			}
1.1  dillo 			break;
1.1  dillo
1.2  dillo 			case HFS_REC_FILE:
1.1  dillo 			{
1.1  dillo 				out_recdata->file.flags = be16tohp(&ptr);
1.1  dillo 				out_recdata->file.reserved = be32tohp(&ptr);
1.1  dillo 				out_recdata->file.cnid = be32tohp(&ptr);
1.1  dillo 				out_recdata->file.date_created = be32tohp(&ptr);
1.1  dillo 				out_recdata->file.date_content_mod = be32tohp(&ptr);
1.1  dillo 				out_recdata->file.date_attrib_mod = be32tohp(&ptr);
1.1  dillo 				out_recdata->file.date_accessed = be32tohp(&ptr);
1.1  dillo 				out_recdata->file.date_backedup = be32tohp(&ptr);
1.1  dillo
1.2  dillo 				last_bytes_read = hfslib_read_bsd_data(ptr,
1.1  dillo 					&out_recdata->file.bsd);
1.1  dillo 				if(last_bytes_read==0)
1.1  dillo 					return 0;
1.1  dillo 				ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.2  dillo 				last_bytes_read = hfslib_read_file_userinfo(ptr,
1.1  dillo 					&out_recdata->file.user_info);
1.1  dillo 				if(last_bytes_read==0)
1.1  dillo 					return 0;
1.1  dillo 				ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.2  dillo 				last_bytes_read = hfslib_read_file_finderinfo(ptr,
1.1  dillo 					&out_recdata->file.finder_info);
1.1  dillo 				if(last_bytes_read==0)
1.1  dillo 					return 0;
1.1  dillo 				ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.1  dillo 				out_recdata->file.text_encoding = be32tohp(&ptr);
1.1  dillo 				out_recdata->file.reserved2 = be32tohp(&ptr);
1.1  dillo
1.2  dillo 				last_bytes_read = hfslib_read_fork_descriptor(ptr,
1.1  dillo 					&out_recdata->file.data_fork);
1.1  dillo 				if(last_bytes_read==0)
1.1  dillo 					return 0;
1.1  dillo 				ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.2  dillo 				last_bytes_read = hfslib_read_fork_descriptor(ptr,
1.1  dillo 					&out_recdata->file.rsrc_fork);
1.1  dillo 				if(last_bytes_read==0)
1.1  dillo 					return 0;
1.1  dillo 				ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo 			}
1.1  dillo 			break;
1.1  dillo
1.2  dillo 			case HFS_REC_FLDR_THREAD:
1.2  dillo 			case HFS_REC_FILE_THREAD:
1.1  dillo 			{
1.1  dillo 				out_recdata->thread.reserved = be16tohp(&ptr);
1.1  dillo 				out_recdata->thread.parent_cnid = be32tohp(&ptr);
1.1  dillo
1.2  dillo 				last_bytes_read = hfslib_read_unistr255(ptr,
1.1  dillo 					&out_recdata->thread.name);
1.1  dillo 				if(last_bytes_read==0)
1.1  dillo 					return 0;
1.1  dillo 				ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo 			}
1.1  dillo 			break;
1.1  dillo
1.1  dillo 			default:
1.1  dillo 				return 1;
1.1  dillo 				/* NOTREACHED */
1.1  dillo 		}
1.1  dillo 	}
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo /* out_rec may be NULL */
1.1  dillo size_t
1.2  dillo hfslib_read_extent_record(
1.1  dillo 	void* in_bytes,
1.2  dillo 	hfs_extent_record_t* out_rec,
1.2  dillo 	hfs_node_kind in_nodekind,
1.2  dillo 	hfs_extent_key_t* out_key,
1.2  dillo 	hfs_volume* in_volume)
1.1  dillo {
1.1  dillo 	void*		ptr;
1.1  dillo 	size_t		last_bytes_read;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_key==NULL
1.2  dillo 		|| (in_nodekind!=HFS_LEAFNODE && in_nodekind!=HFS_INDEXNODE))
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	/*	For HFS+, the key length is always a 2-byte number. This is indicated
1.2  dillo 	 *	by the HFS_BIG_KEYS_MASK bit in the attributes field of the extent
1.1  dillo 	 *	overflow header record. However, we just assume this bit is set, since
1.1  dillo 	 *	all HFS+ volumes should have it set anyway. */
1.1  dillo 	if(in_volume->extkeysizefieldsize == sizeof(uint16_t))
1.1  dillo 		out_key->key_length = be16tohp(&ptr);
1.1  dillo 	else if (in_volume->extkeysizefieldsize == sizeof(uint8_t)) {
1.1  dillo 		out_key->key_length = *(((uint8_t*)ptr));
1.1  dillo 		ptr = (uint8_t*)ptr + 1;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	out_key->fork_type = *(((uint8_t*)ptr));
1.1  dillo 	ptr = (uint8_t*)ptr + 1;
1.1  dillo 	out_key->padding = *(((uint8_t*)ptr));
1.1  dillo 	ptr = (uint8_t*)ptr + 1;
1.1  dillo 	out_key->file_cnid = be32tohp(&ptr);
1.1  dillo 	out_key->start_block = be32tohp(&ptr);
1.1  dillo
1.1  dillo 	/* don't waste time if the user just wanted the key */
1.1  dillo 	if(out_rec==NULL)
1.1  dillo 		return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo
1.2  dillo 	if(in_nodekind==HFS_LEAFNODE)
1.1  dillo 	{
1.2  dillo 		last_bytes_read = hfslib_read_extent_descriptors(ptr, out_rec);
1.1  dillo 		if(last_bytes_read==0)
1.1  dillo 			return 0;
1.1  dillo 		ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo 	}
1.1  dillo 	else
1.1  dillo 	{
1.1  dillo 		/* XXX: this is completely bogus */
1.1  dillo                 /*      (uint32_t*)*out_rec = be32tohp(&ptr); */
1.1  dillo 	    uint32_t *ptr_32 = (uint32_t *)out_rec;
1.1  dillo 		*ptr_32 = be32tohp(&ptr);
1.1  dillo 	        /* (*out_rec)[0].start_block = be32tohp(&ptr); */
1.1  dillo 	}
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo void
1.2  dillo hfslib_free_recs(
1.1  dillo 	void*** inout_node_recs,
1.1  dillo 	uint16_t** inout_rec_sizes,
1.1  dillo 	uint16_t* inout_num_recs,
1.2  dillo 	hfs_callback_args* cbargs)
1.1  dillo {
1.1  dillo 	uint16_t	i;
1.1  dillo
1.1  dillo 	if(inout_num_recs==NULL || *inout_num_recs==0)
1.1  dillo 		return;
1.1  dillo
1.1  dillo 	if(inout_node_recs!=NULL && *inout_node_recs!=NULL)
1.1  dillo 	{
1.1  dillo 		for(i=0;i<*inout_num_recs;i++)
1.1  dillo 		{
1.1  dillo 			if((*inout_node_recs)[i]!=NULL)
1.1  dillo 			{
1.2  dillo 				hfslib_free((*inout_node_recs)[i], cbargs);
1.1  dillo 				(*inout_node_recs)[i] = NULL;
1.1  dillo 			}
1.1  dillo 		}
1.1  dillo
1.2  dillo 		hfslib_free(*inout_node_recs, cbargs);
1.1  dillo 		*inout_node_recs = NULL;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	if(inout_rec_sizes!=NULL && *inout_rec_sizes!=NULL)
1.1  dillo 	{
1.2  dillo 		hfslib_free(*inout_rec_sizes, cbargs);
1.1  dillo 		*inout_rec_sizes = NULL;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	*inout_num_recs = 0;
1.1  dillo }
1.1  dillo
1.1  dillo #if 0
1.1  dillo #pragma mark -
1.1  dillo #pragma mark Individual Fields
1.1  dillo #endif
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_fork_descriptor(void* in_bytes, hfs_fork_t* out_forkdata)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo 	size_t	last_bytes_read;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_forkdata==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	out_forkdata->logical_size = be64tohp(&ptr);
1.1  dillo 	out_forkdata->clump_size = be32tohp(&ptr);
1.1  dillo 	out_forkdata->total_blocks = be32tohp(&ptr);
1.1  dillo
1.2  dillo 	if((last_bytes_read = hfslib_read_extent_descriptors(ptr,
1.1  dillo 		&out_forkdata->extents))==0)
1.1  dillo 		return 0;
1.1  dillo 	ptr = (uint8_t*)ptr + last_bytes_read;
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_extent_descriptors(
1.1  dillo 	void* in_bytes,
1.2  dillo 	hfs_extent_record_t* out_extentrecord)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo 	int		i;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_extentrecord==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	for(i=0;i<8;i++)
1.1  dillo 	{
1.2  dillo 		(((hfs_extent_descriptor_t*)*out_extentrecord)[i]).start_block =
1.1  dillo 			be32tohp(&ptr);
1.2  dillo 		(((hfs_extent_descriptor_t*)*out_extentrecord)[i]).block_count =
1.1  dillo 			be32tohp(&ptr);
1.1  dillo 	}
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_unistr255(void* in_bytes, hfs_unistr255_t* out_string)
1.1  dillo {
1.1  dillo 	void*		ptr;
1.1  dillo 	uint16_t	i, length;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_string==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	length = be16tohp(&ptr);
1.1  dillo 	if(length>255)
1.1  dillo 		length = 255; /* hfs+ folder/file names have a limit of 255 chars */
1.1  dillo 	out_string->length = length;
1.1  dillo
1.1  dillo 	for(i=0; i<length; i++)
1.1  dillo 	{
1.1  dillo 		out_string->unicode[i] = be16tohp(&ptr);
1.1  dillo 	}
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_bsd_data(void* in_bytes, hfs_bsd_data_t* out_perms)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_perms==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	out_perms->owner_id = be32tohp(&ptr);
1.1  dillo 	out_perms->group_id = be32tohp(&ptr);
1.1  dillo 	out_perms->admin_flags = *(((uint8_t*)ptr));
1.1  dillo 	ptr = (uint8_t*)ptr + 1;
1.1  dillo 	out_perms->owner_flags = *(((uint8_t*)ptr));
1.1  dillo 	ptr = (uint8_t*)ptr + 1;
1.1  dillo 	out_perms->file_mode = be16tohp(&ptr);
1.1  dillo 	out_perms->special.inode_num = be32tohp(&ptr); /* this field is a union */
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_file_userinfo(void* in_bytes, hfs_macos_file_info_t* out_info)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_info==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	out_info->file_type = be32tohp(&ptr);
1.1  dillo 	out_info->file_creator = be32tohp(&ptr);
1.1  dillo 	out_info->finder_flags = be16tohp(&ptr);
1.1  dillo 	out_info->location.v = be16tohp(&ptr);
1.1  dillo 	out_info->location.h = be16tohp(&ptr);
1.1  dillo 	out_info->reserved = be16tohp(&ptr);
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_file_finderinfo(
1.1  dillo 	void* in_bytes,
1.2  dillo 	hfs_macos_extended_file_info_t* out_info)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_info==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo #if 0
1.1  dillo 	#pragma warn Fill in with real code!
1.1  dillo #endif
1.1  dillo 	/* FIXME: Fill in with real code! */
1.1  dillo 	memset(out_info, 0, sizeof(*out_info));
1.2  dillo 	ptr = (uint8_t*)ptr + sizeof(hfs_macos_extended_file_info_t);
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_folder_userinfo(void* in_bytes, hfs_macos_folder_info_t* out_info)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_info==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo #if 0
1.1  dillo 	#pragma warn Fill in with real code!
1.1  dillo #endif
1.1  dillo 	/* FIXME: Fill in with real code! */
1.1  dillo 	memset(out_info, 0, sizeof(*out_info));
1.2  dillo 	ptr = (uint8_t*)ptr + sizeof(hfs_macos_folder_info_t);
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_folder_finderinfo(
1.1  dillo 	void* in_bytes,
1.2  dillo 	hfs_macos_extended_folder_info_t* out_info)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_info==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo #if 0
1.1  dillo 	#pragma warn Fill in with real code!
1.1  dillo #endif
1.1  dillo 	/* FIXME: Fill in with real code! */
1.1  dillo 	memset(out_info, 0, sizeof(*out_info));
1.2  dillo 	ptr = (uint8_t*)ptr + sizeof(hfs_macos_extended_folder_info_t);
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_journal_info(void* in_bytes, hfs_journal_info_t* out_info)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo 	int		i;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_info==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	out_info->flags = be32tohp(&ptr);
1.1  dillo 	for(i=0; i<8; i++)
1.1  dillo 	{
1.1  dillo 		out_info->device_signature[i] = be32tohp(&ptr);
1.1  dillo 	}
1.1  dillo 	out_info->offset = be64tohp(&ptr);
1.1  dillo 	out_info->size = be64tohp(&ptr);
1.1  dillo 	for(i=0; i<32; i++)
1.1  dillo 	{
1.1  dillo 		out_info->reserved[i] = be64tohp(&ptr);
1.1  dillo 	}
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo size_t
1.2  dillo hfslib_read_journal_header(void* in_bytes, hfs_journal_header_t* out_header)
1.1  dillo {
1.1  dillo 	void*	ptr;
1.1  dillo
1.1  dillo 	if(in_bytes==NULL || out_header==NULL)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	ptr = in_bytes;
1.1  dillo
1.1  dillo 	out_header->magic = be32tohp(&ptr);
1.1  dillo 	out_header->endian = be32tohp(&ptr);
1.1  dillo 	out_header->start = be64tohp(&ptr);
1.1  dillo 	out_header->end = be64tohp(&ptr);
1.1  dillo 	out_header->size = be64tohp(&ptr);
1.1  dillo 	out_header->blocklist_header_size = be32tohp(&ptr);
1.1  dillo 	out_header->checksum = be32tohp(&ptr);
1.1  dillo 	out_header->journal_header_size = be32tohp(&ptr);
1.1  dillo
1.1  dillo 	return ((uint8_t*)ptr - (uint8_t*)in_bytes);
1.1  dillo }
1.1  dillo
1.1  dillo #if 0
1.1  dillo #pragma mark -
1.1  dillo #pragma mark Disk Access
1.1  dillo #endif
1.1  dillo
1.1  dillo /*
1.2  dillo  *	hfslib_readd_with_extents()
1.1  dillo  *
1.1  dillo  *	This function reads the contents of a file from the volume, given an array
1.1  dillo  *	of extent descriptors which specify where every extent of the file is
1.1  dillo  *	located (in addition to the usual pread() arguments). out_bytes is presumed
1.1  dillo  *  to exist and be large enough to hold in_length number of bytes. Returns 0
1.1  dillo  *	on success.
1.1  dillo  */
1.1  dillo int
1.2  dillo hfslib_readd_with_extents(
1.2  dillo 	hfs_volume*	in_vol,
1.1  dillo 	void*		out_bytes,
1.1  dillo 	uint64_t*	out_bytesread,
1.1  dillo 	uint64_t	in_length,
1.1  dillo 	uint64_t	in_offset,
1.2  dillo 	hfs_extent_descriptor_t in_extents[],
1.1  dillo 	uint16_t	in_numextents,
1.2  dillo 	hfs_callback_args*	cbargs)
1.1  dillo {
1.1  dillo 	uint64_t	ext_length, last_offset;
1.1  dillo 	uint16_t	i;
1.1  dillo 	int			error;
1.1  dillo
1.1  dillo 	if(in_vol==NULL || out_bytes==NULL || in_extents==NULL || in_numextents==0
1.1  dillo 		|| out_bytesread==NULL)
1.1  dillo 		return -1;
1.1  dillo
1.1  dillo 	*out_bytesread = 0;
1.1  dillo 	last_offset = 0;
1.1  dillo
1.1  dillo 	for(i=0; i<in_numextents; i++)
1.1  dillo 	{
1.1  dillo 		if(in_extents[i].block_count==0)
1.1  dillo 			continue;
1.1  dillo
1.1  dillo 		ext_length = in_extents[i].block_count * in_vol->vh.block_size;
1.1  dillo
1.1  dillo 		if(in_offset < last_offset+ext_length
1.1  dillo 			&& in_offset+in_length >= last_offset)
1.1  dillo 		{
1.1  dillo 			uint64_t	isect_start, isect_end;
1.1  dillo
1.1  dillo 			isect_start = max(in_offset, last_offset);
1.1  dillo 			isect_end = min(in_offset+in_length, last_offset+ext_length);
1.2  dillo 			error = hfslib_readd(in_vol, out_bytes, isect_end-isect_start,
1.1  dillo 				isect_start - last_offset + (uint64_t)in_extents[i].start_block
1.1  dillo 					* in_vol->vh.block_size, cbargs);
1.1  dillo
1.1  dillo 			if(error!=0)
1.1  dillo 				return error;
1.1  dillo
1.1  dillo 			*out_bytesread += isect_end-isect_start;
1.1  dillo 			out_bytes = (uint8_t*)out_bytes + isect_end-isect_start;
1.1  dillo 		}
1.1  dillo
1.1  dillo 		last_offset += ext_length;
1.1  dillo 	}
1.1  dillo
1.1  dillo
1.1  dillo 	return 0;
1.1  dillo }
1.1  dillo
1.1  dillo #if 0
1.1  dillo #pragma mark -
1.1  dillo #pragma mark Callback Wrappers
1.1  dillo #endif
1.1  dillo
1.1  dillo void
1.2  dillo hfslib_error(const char* in_format, const char* in_file, int in_line, ...)
1.1  dillo {
1.1  dillo 	va_list		ap;
1.1  dillo
1.1  dillo 	if(in_format==NULL)
1.1  dillo 		return;
1.1  dillo
1.2  dillo 	if(hfs_gcb.error!=NULL)
1.1  dillo 	{
1.1  dillo 		va_start(ap, in_line);
1.1  dillo
1.2  dillo 		hfs_gcb.error(in_format, in_file, in_line, ap);
1.1  dillo
1.1  dillo 		va_end(ap);
1.1  dillo 	}
1.1  dillo }
1.1  dillo
1.1  dillo void*
1.2  dillo hfslib_malloc(size_t size, hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	if(hfs_gcb.allocmem!=NULL)
1.2  dillo 		return hfs_gcb.allocmem(size, cbargs);
1.1  dillo
1.1  dillo 	return NULL;
1.1  dillo }
1.1  dillo
1.1  dillo void*
1.2  dillo hfslib_realloc(void* ptr, size_t size, hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	if(hfs_gcb.reallocmem!=NULL)
1.2  dillo 		return hfs_gcb.reallocmem(ptr, size, cbargs);
1.1  dillo
1.1  dillo 	return NULL;
1.1  dillo }
1.1  dillo
1.1  dillo void
1.2  dillo hfslib_free(void* ptr, hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	if(hfs_gcb.freemem!=NULL && ptr!=NULL)
1.2  dillo 		hfs_gcb.freemem(ptr, cbargs);
1.1  dillo }
1.1  dillo
1.1  dillo int
1.2  dillo hfslib_openvoldevice(
1.2  dillo 	hfs_volume* in_vol,
1.1  dillo 	const char* in_device,
1.1  dillo 	uint64_t in_offset,
1.2  dillo 	hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	if(hfs_gcb.openvol!=NULL && in_device!=NULL)
1.2  dillo 		return hfs_gcb.openvol(in_vol, in_device, in_offset, cbargs);
1.1  dillo
1.1  dillo 	return 1;
1.1  dillo }
1.1  dillo
1.1  dillo void
1.2  dillo hfslib_closevoldevice(hfs_volume* in_vol, hfs_callback_args* cbargs)
1.1  dillo {
1.2  dillo 	if(hfs_gcb.closevol!=NULL)
1.2  dillo 		hfs_gcb.closevol(in_vol, cbargs);
1.1  dillo }
1.1  dillo
1.1  dillo int
1.2  dillo hfslib_readd(
1.2  dillo 	hfs_volume* in_vol,
1.1  dillo 	void* out_bytes,
1.1  dillo 	uint64_t in_length,
1.1  dillo 	uint64_t in_offset,
1.2  dillo 	hfs_callback_args* cbargs)
1.1  dillo {
1.1  dillo 	if(in_vol==NULL || out_bytes==NULL)
1.1  dillo 		return -1;
1.1  dillo
1.2  dillo 	if(hfs_gcb.read!=NULL)
1.2  dillo 		return hfs_gcb.read(in_vol, out_bytes, in_length, in_offset, cbargs);
1.1  dillo
1.1  dillo 	return -1;
1.1  dillo }
1.1  dillo
1.1  dillo #if 0
1.1  dillo #pragma mark -
1.1  dillo #pragma mark Other
1.1  dillo #endif
1.1  dillo
1.1  dillo /* returns key length */
1.1  dillo uint16_t
1.2  dillo hfslib_make_catalog_key(
1.2  dillo 	hfs_cnid_t in_parent_cnid,
1.1  dillo 	uint16_t in_name_len,
1.1  dillo 	unichar_t* in_unicode,
1.2  dillo 	hfs_catalog_key_t* out_key)
1.1  dillo {
1.1  dillo 	if(in_parent_cnid==0 || (in_name_len>0 && in_unicode==NULL) || out_key==0)
1.1  dillo 		return 0;
1.1  dillo
1.1  dillo 	if(in_name_len>255)
1.1  dillo 		in_name_len = 255;
1.1  dillo
1.1  dillo 	out_key->key_len = 6 + 2 * in_name_len;
1.1  dillo 	out_key->parent_cnid = in_parent_cnid;
1.1  dillo 	out_key->name.length = in_name_len;
1.1  dillo 	if(in_name_len>0)
1.1  dillo 		memcpy(&out_key->name.unicode, in_unicode, in_name_len*2);
1.1  dillo
1.1  dillo 	return out_key->key_len;
1.1  dillo }
1.1  dillo
1.1  dillo /* returns key length */
1.1  dillo uint16_t
1.2  dillo hfslib_make_extent_key(
1.2  dillo 	hfs_cnid_t in_cnid,
1.1  dillo 	uint8_t in_forktype,
1.1  dillo 	uint32_t in_startblock,
1.2  dillo 	hfs_extent_key_t* out_key)
1.1  dillo {
1.1  dillo 	if(in_cnid==0 || out_key==0)
1.1  dillo 		return 0;
1.1  dillo
1.2  dillo 	out_key->key_length = HFS_MAX_EXT_KEY_LEN;
1.1  dillo 	out_key->fork_type = in_forktype;
1.1  dillo 	out_key->padding = 0;
1.1  dillo 	out_key->file_cnid = in_cnid;
1.1  dillo 	out_key->start_block = in_startblock;
1.1  dillo
1.1  dillo 	return out_key->key_length;
1.1  dillo }
1.1  dillo
1.1  dillo /* case-folding */
1.1  dillo int
1.2  dillo hfslib_compare_catalog_keys_cf (
1.1  dillo 	const void *ap,
1.1  dillo 	const void *bp)
1.1  dillo {
1.2  dillo 	const hfs_catalog_key_t	*a, *b;
1.1  dillo 	unichar_t	ac, bc; /* current character from a, b */
1.1  dillo 	unichar_t	lc; /* lowercase version of current character */
1.1  dillo 	uint8_t		apos, bpos; /* current character indices */
1.1  dillo
1.2  dillo 	a = (const hfs_catalog_key_t*)ap;
1.2  dillo 	b = (const hfs_catalog_key_t*)bp;
1.1  dillo
1.1  dillo 	if(a->parent_cnid != b->parent_cnid)
1.1  dillo 	{
1.1  dillo 		return (a->parent_cnid - b->parent_cnid);
1.1  dillo 	}
1.1  dillo 	else
1.1  dillo 	{
1.1  dillo 		/*
1.1  dillo 		 * The following code implements the pseudocode suggested by
1.1  dillo 		 * the HFS+ technote.
1.1  dillo 		 */
1.1  dillo
1.1  dillo /*
1.1  dillo  * XXX These need to be revised to be endian-independent!
1.1  dillo  */
1.1  dillo #define hbyte(x) ((x) >> 8)
1.1  dillo #define lbyte(x) ((x) & 0x00FF)
1.1  dillo
1.1  dillo 		apos = bpos = 0;
1.1  dillo 		while(1)
1.1  dillo 		{
1.1  dillo 			/* get next valid character from a */
1.1  dillo 			for (lc=0; lc == 0 && apos < a->name.length; apos++) {
1.1  dillo 				ac = a->name.unicode[apos];
1.2  dillo 				lc = hfs_gcft[hbyte(ac)];
1.1  dillo 				if(lc==0)
1.1  dillo 					lc = ac;
1.1  dillo 				else
1.2  dillo 					lc = hfs_gcft[lc + lbyte(ac)];
1.1  dillo 			};
1.1  dillo 			ac=lc;
1.1  dillo
1.1  dillo 			/* get next valid character from b */
1.1  dillo 			for (lc=0; lc == 0 && bpos < b->name.length; bpos++) {
1.1  dillo 				bc = b->name.unicode[bpos];
1.2  dillo 				lc = hfs_gcft[hbyte(bc)];
1.1  dillo 				if(lc==0)
1.1  dillo 					lc = bc;
1.1  dillo 				else
1.2  dillo 					lc = hfs_gcft[lc + lbyte(bc)];
1.1  dillo 			};
1.1  dillo 			bc=lc;
1.1  dillo
1.1  dillo 			/* on end of string ac/bc are 0, otherwise > 0 */
1.1  dillo 			if (ac != bc || (ac == 0  && bc == 0))
1.1  dillo 				return ac - bc;
1.1  dillo 		}
1.1  dillo #undef hbyte
1.1  dillo #undef lbyte
1.1  dillo 	}
1.1  dillo }
1.1  dillo
1.1  dillo /* binary compare (i.e., not case folding) */
1.1  dillo int
1.2  dillo hfslib_compare_catalog_keys_bc (
1.1  dillo 	const void *a,
1.1  dillo 	const void *b)
1.1  dillo {
1.2  dillo 	if(((const hfs_catalog_key_t*)a)->parent_cnid
1.2  dillo 		== ((const hfs_catalog_key_t*)b)->parent_cnid)
1.1  dillo 	{
1.2  dillo 		if(((const hfs_catalog_key_t*)a)->name.length == 0 &&
1.2  dillo 			((const hfs_catalog_key_t*)b)->name.length == 0)
1.1  dillo 			return 0;
1.1  dillo
1.2  dillo 		if(((const hfs_catalog_key_t*)a)->name.length == 0)
1.1  dillo 			return -1;
1.2  dillo 		if(((const hfs_catalog_key_t*)b)->name.length == 0)
1.1  dillo 			return 1;
1.1  dillo
1.1  dillo 		/* FIXME: This does a byte-per-byte comparison, whereas the HFS spec
1.1  dillo 		 * mandates a uint16_t chunk comparison. */
1.2  dillo 		return memcmp(((const hfs_catalog_key_t*)a)->name.unicode,
1.2  dillo 			((const hfs_catalog_key_t*)b)->name.unicode,
1.2  dillo 			min(((const hfs_catalog_key_t*)a)->name.length,
1.2  dillo 				((const hfs_catalog_key_t*)b)->name.length));
1.1  dillo 	}
1.1  dillo 	else
1.1  dillo 	{
1.2  dillo 		return (((const hfs_catalog_key_t*)a)->parent_cnid -
1.2  dillo 				((const hfs_catalog_key_t*)b)->parent_cnid);
1.1  dillo 	}
1.1  dillo }
1.1  dillo
1.1  dillo int
1.2  dillo hfslib_compare_extent_keys (
1.1  dillo 	const void *a,
1.1  dillo 	const void *b)
1.1  dillo {
1.1  dillo 	/*
1.1  dillo 	 *	Comparison order, in descending importance:
1.1  dillo 	 *
1.1  dillo 	 *		CNID -> fork type -> start block
1.1  dillo 	 */
1.1  dillo
1.2  dillo 	if(((const hfs_extent_key_t*)a)->file_cnid
1.2  dillo 		== ((const hfs_extent_key_t*)b)->file_cnid)
1.1  dillo 	{
1.2  dillo 		if(((const hfs_extent_key_t*)a)->fork_type
1.2  dillo 			== ((const hfs_extent_key_t*)b)->fork_type)
1.1  dillo 		{
1.2  dillo 			if(((const hfs_extent_key_t*)a)->start_block
1.2  dillo 				== ((const hfs_extent_key_t*)b)->start_block)
1.1  dillo 			{
1.1  dillo 				return 0;
1.1  dillo 			}
1.1  dillo 			else
1.1  dillo 			{
1.2  dillo 				return (((const hfs_extent_key_t*)a)->start_block -
1.2  dillo 						((const hfs_extent_key_t*)b)->start_block);
1.1  dillo 			}
1.1  dillo 		}
1.1  dillo 		else
1.1  dillo 		{
1.2  dillo 			return (((const hfs_extent_key_t*)a)->fork_type -
1.2  dillo 					((const hfs_extent_key_t*)b)->fork_type);
1.1  dillo 		}
1.1  dillo 	}
1.1  dillo 	else
1.1  dillo 	{
1.2  dillo 		return (((const hfs_extent_key_t*)a)->file_cnid -
1.2  dillo 				((const hfs_extent_key_t*)b)->file_cnid);
1.1  dillo 	}
1.1  dillo }
1.1  dillo
1.1  dillo /* 1+10 tables of 16 rows and 16 columns, each 2 bytes wide = 5632 bytes */
1.1  dillo int
1.2  dillo hfslib_create_casefolding_table(void)
1.1  dillo {
1.2  dillo 	hfs_callback_args	cbargs;
1.1  dillo 	unichar_t*	t; /* convenience */
1.1  dillo 	uint16_t	s; /* current subtable * 256 */
1.1  dillo 	uint16_t	i; /* current subtable index (0 to 255) */
1.1  dillo
1.2  dillo 	if(hfs_gcft!=NULL)
1.1  dillo 		return 0; /* no sweat, table already exists */
1.1  dillo
1.2  dillo 	hfslib_init_cbargs(&cbargs);
1.2  dillo 	hfs_gcft = hfslib_malloc(5632, &cbargs);
1.2  dillo 	if(hfs_gcft==NULL)
1.2  dillo 		HFS_LIBERR("could not allocate case folding table");
1.1  dillo
1.2  dillo 	t = hfs_gcft;	 /* easier to type :) */
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * high byte indices
1.1  dillo 	 */
1.1  dillo 	s = 0 * 256;
1.1  dillo 	memset(t, 0x00, 512);
1.1  dillo 	t[s+  0] = 0x0100;
1.1  dillo 	t[s+  1] = 0x0200;
1.1  dillo 	t[s+  3] = 0x0300;
1.1  dillo 	t[s+  4] = 0x0400;
1.1  dillo 	t[s+  5] = 0x0500;
1.1  dillo 	t[s+ 16] = 0x0600;
1.1  dillo 	t[s+ 32] = 0x0700;
1.1  dillo 	t[s+ 33] = 0x0800;
1.1  dillo 	t[s+254] = 0x0900;
1.1  dillo 	t[s+255] = 0x0a00;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 1 (high byte 0x00)
1.1  dillo 	 */
1.1  dillo 	s = 1 * 256;
1.1  dillo 	for(i=0; i<65; i++)
1.1  dillo 		t[s+i] = i;
1.1  dillo 	t[s+  0] = 0xffff;
1.1  dillo 	for(i=65; i<91; i++)
1.1  dillo 		t[s+i] = i + 0x20;
1.1  dillo 	for(i=91; i<256; i++)
1.1  dillo 		t[s+i] = i;
1.1  dillo 	t[s+198] = 0x00e6;
1.1  dillo 	t[s+208] = 0x00f0;
1.1  dillo 	t[s+216] = 0x00f8;
1.1  dillo 	t[s+222] = 0x00fe;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 2 (high byte 0x01)
1.1  dillo 	 */
1.1  dillo 	s = 2 * 256;
1.1  dillo 	for(i=0; i<256; i++)
1.1  dillo 		t[s+i] = i + 0x0100;
1.1  dillo 	t[s+ 16] = 0x0111;
1.1  dillo 	t[s+ 38] = 0x0127;
1.1  dillo 	t[s+ 50] = 0x0133;
1.1  dillo 	t[s+ 63] = 0x0140;
1.1  dillo 	t[s+ 65] = 0x0142;
1.1  dillo 	t[s+ 74] = 0x014b;
1.1  dillo 	t[s+ 82] = 0x0153;
1.1  dillo 	t[s+102] = 0x0167;
1.1  dillo 	t[s+129] = 0x0253;
1.1  dillo 	t[s+130] = 0x0183;
1.1  dillo 	t[s+132] = 0x0185;
1.1  dillo 	t[s+134] = 0x0254;
1.1  dillo 	t[s+135] = 0x0188;
1.1  dillo 	t[s+137] = 0x0256;
1.1  dillo 	t[s+138] = 0x0257;
1.1  dillo 	t[s+139] = 0x018c;
1.1  dillo 	t[s+142] = 0x01dd;
1.1  dillo 	t[s+143] = 0x0259;
1.1  dillo 	t[s+144] = 0x025b;
1.1  dillo 	t[s+145] = 0x0192;
1.1  dillo 	t[s+147] = 0x0260;
1.1  dillo 	t[s+148] = 0x0263;
1.1  dillo 	t[s+150] = 0x0269;
1.1  dillo 	t[s+151] = 0x0268;
1.1  dillo 	t[s+152] = 0x0199;
1.1  dillo 	t[s+156] = 0x026f;
1.1  dillo 	t[s+157] = 0x0272;
1.1  dillo 	t[s+159] = 0x0275;
1.1  dillo 	t[s+162] = 0x01a3;
1.1  dillo 	t[s+164] = 0x01a5;
1.1  dillo 	t[s+167] = 0x01a8;
1.1  dillo 	t[s+169] = 0x0283;
1.1  dillo 	t[s+172] = 0x01ad;
1.1  dillo 	t[s+174] = 0x0288;
1.1  dillo 	t[s+177] = 0x028a;
1.1  dillo 	t[s+178] = 0x028b;
1.1  dillo 	t[s+179] = 0x01b4;
1.1  dillo 	t[s+181] = 0x01b6;
1.1  dillo 	t[s+183] = 0x0292;
1.1  dillo 	t[s+184] = 0x01b9;
1.1  dillo 	t[s+188] = 0x01bd;
1.1  dillo 	t[s+196] = 0x01c6;
1.1  dillo 	t[s+197] = 0x01c6;
1.1  dillo 	t[s+199] = 0x01c9;
1.1  dillo 	t[s+200] = 0x01c9;
1.1  dillo 	t[s+202] = 0x01cc;
1.1  dillo 	t[s+203] = 0x01cc;
1.1  dillo 	t[s+228] = 0x01e5;
1.1  dillo 	t[s+241] = 0x01f3;
1.1  dillo 	t[s+242] = 0x01f3;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 3 (high byte 0x03)
1.1  dillo 	 */
1.1  dillo 	s = 3 * 256;
1.1  dillo 	for(i=0; i<145; i++)
1.1  dillo 		t[s+i] = i + 0x0300;
1.1  dillo 	for(i=145; i<170; i++)
1.1  dillo 		t[s+i] = i + 0x0320;
1.1  dillo 	t[s+162] = 0x03a2;
1.1  dillo 	for(i=170; i<256; i++)
1.1  dillo 		t[s+i] = i + 0x0300;
1.1  dillo
1.1  dillo 	for(i=226; i<239; i+=2)
1.1  dillo 		t[s+i] = i + 0x0301;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 4 (high byte 0x04)
1.1  dillo 	 */
1.1  dillo 	s = 4 * 256;
1.1  dillo 	for(i=0; i<16; i++)
1.1  dillo 		t[s+i] = i + 0x0400;
1.1  dillo 	t[s+  2] = 0x0452;
1.1  dillo 	t[s+  4] = 0x0454;
1.1  dillo 	t[s+  5] = 0x0455;
1.1  dillo 	t[s+  6] = 0x0456;
1.1  dillo 	t[s+  8] = 0x0458;
1.1  dillo 	t[s+  9] = 0x0459;
1.1  dillo 	t[s+ 10] = 0x045a;
1.1  dillo 	t[s+ 11] = 0x045b;
1.1  dillo 	t[s+ 15] = 0x045f;
1.1  dillo
1.1  dillo 	for(i=16; i<48; i++)
1.1  dillo 		t[s+i] = i + 0x0420;
1.1  dillo 	t[s+ 25] = 0x0419;
1.1  dillo 	for(i=48; i<256; i++)
1.1  dillo 		t[s+i] = i + 0x0400;
1.1  dillo 	t[s+195] = 0x04c4;
1.1  dillo 	t[s+199] = 0x04c8;
1.1  dillo 	t[s+203] = 0x04cc;
1.1  dillo
1.1  dillo 	for(i=96; i<129; i+=2)
1.1  dillo 		t[s+i] = i + 0x0401;
1.1  dillo 	t[s+118] = 0x0476;
1.1  dillo 	for(i=144; i<191; i+=2)
1.1  dillo 		t[s+i] = i + 0x0401;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 5 (high byte 0x05)
1.1  dillo 	 */
1.1  dillo 	s = 5 * 256;
1.1  dillo 	for(i=0; i<49; i++)
1.1  dillo 		t[s+i] = i + 0x0500;
1.1  dillo 	for(i=49; i<87; i++)
1.1  dillo 		t[s+i] = i + 0x0530;
1.1  dillo 	for(i=87; i<256; i++)
1.1  dillo 		t[s+i] = i + 0x0500;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 6 (high byte 0x10)
1.1  dillo 	 */
1.1  dillo 	s = 6 * 256;
1.1  dillo 	for(i=0; i<160; i++)
1.1  dillo 		t[s+i] = i + 0x1000;
1.1  dillo 	for(i=160; i<198; i++)
1.1  dillo 		t[s+i] = i + 0x1030;
1.1  dillo 	for(i=198; i<256; i++)
1.1  dillo 		t[s+i] = i + 0x1000;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 7 (high byte 0x20)
1.1  dillo 	 */
1.1  dillo 	s = 7 * 256;
1.1  dillo 	for(i=0; i<256; i++)
1.1  dillo 		t[s+i] = i + 0x2000;
1.1  dillo 	{
1.1  dillo 		uint8_t zi[15] = { 12,  13,  14,  15,
1.1  dillo 						   42,  43,  44,  45,  46,
1.1  dillo 						  106, 107, 108, 109, 110, 111};
1.1  dillo
1.1  dillo 		for(i=0; i<15; i++)
1.1  dillo 			t[s+zi[i]] = 0x0000;
1.1  dillo 	}
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 8 (high byte 0x21)
1.1  dillo 	 */
1.1  dillo 	s = 8 * 256;
1.1  dillo 	for(i=0; i<96; i++)
1.1  dillo 		t[s+i] = i + 0x2100;
1.1  dillo 	for(i=96; i<112; i++)
1.1  dillo 		t[s+i] = i + 0x2110;
1.1  dillo 	for(i=112; i<256; i++)
1.1  dillo 		t[s+i] = i + 0x2100;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 9 (high byte 0xFE)
1.1  dillo 	 */
1.1  dillo 	s = 9 * 256;
1.1  dillo 	for(i=0; i<256; i++)
1.1  dillo 		t[s+i] = i + 0xFE00;
1.1  dillo 	t[s+255] = 0x0000;
1.1  dillo
1.1  dillo 	/*
1.1  dillo 	 * table 10 (high byte 0xFF)
1.1  dillo 	 */
1.1  dillo 	s = 10 * 256;
1.1  dillo 	for(i=0; i<33; i++)
1.1  dillo 		t[s+i] = i + 0xFF00;
1.1  dillo 	for(i=33; i<59; i++)
1.1  dillo 		t[s+i] = i + 0xFF20;
1.1  dillo 	for(i=59; i<256; i++)
1.1  dillo 		t[s+i] = i + 0xFF00;
1.1  dillo
1.1  dillo 	return 0;
1.1  dillo
1.1  dillo error:
1.1  dillo 	return 1;
1.1  dillo }
1.1  dillo
1.1  dillo int
1.2  dillo hfslib_get_hardlink(hfs_volume *vol, uint32_t inode_num,
1.2  dillo 		     hfs_catalog_keyed_record_t *rec,
1.2  dillo 		     hfs_callback_args *cbargs)
1.1  dillo {
1.2  dillo 	hfs_catalog_keyed_record_t metadata;
1.2  dillo 	hfs_catalog_key_t key;
1.1  dillo 	char name[16];
1.1  dillo 	unichar_t name_uni[16];
1.1  dillo 	int i, len;
1.1  dillo
1.1  dillo 	/* XXX: cache this */
1.2  dillo 	if (hfslib_find_catalog_record_with_key(vol,
1.2  dillo 						 &hfs_gMetadataDirectoryKey,
1.1  dillo 						 &metadata, cbargs) != 0
1.2  dillo 		|| metadata.type != HFS_REC_FLDR)
1.1  dillo 		return -1;
1.1  dillo
1.1  dillo 	len = snprintf(name, sizeof(name), "iNode%d", inode_num);
1.1  dillo 	for (i=0; i<len; i++)
1.1  dillo 		name_uni[i] = name[i];
1.1  dillo
1.2  dillo 	if (hfslib_make_catalog_key(metadata.folder.cnid, len, name_uni,
1.1  dillo 				     &key) == 0)
1.1  dillo 		return -1;
1.1  dillo
1.2  dillo 	return hfslib_find_catalog_record_with_key(vol, &key, rec, cbargs);
1.1  dillo }