parted-1.8.7/libparted/fs/fat/table.c - nest-learning-thermostat/5.1.6/parted - Git at Google

 /*
     libparted
     Copyright (C) 1998, 1999, 2000, 2007 Free Software Foundation, Inc.

     This program is free software; you can redistribute it and/or modify
     it under the terms of the GNU General Public License as published by
     the Free Software Foundation; either version 2 of the License, or
     (at your option) any later version.

     This program is distributed in the hope that it will be useful,
     but WITHOUT ANY WARRANTY; without even the implied warranty of
     MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
     GNU General Public License for more details.

     You should have received a copy of the GNU General Public License
     along with this program; if not, write to the Free Software
     Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
 */

 #include <config.h>
 #include <parted/endian.h>
 #include "fat.h"

 #ifndef DISCOVER_ONLY

 FatTable*
 fat_table_new (FatType fat_type, FatCluster size)
 {
 	FatTable*	ft;
 	int		entry_size = fat_table_entry_size (fat_type);

 	ft = (FatTable*) ped_malloc (sizeof (FatTable));
 	if (!ft) return NULL;

 	ft->cluster_count = ft->free_cluster_count = size - 2;

 /* ensure there's some free room on the end, to finish off the sector */
 	ft->size = ped_div_round_up (size * entry_size, 512) * 512 / entry_size;
 	ft->fat_type = fat_type;
 	ft->raw_size = ft->size * entry_size;

 	ft->table = ped_malloc (ft->raw_size);
 	if (!ft->table) {
 		ped_free (ft);
 		return NULL;
 	}

 	fat_table_clear (ft);
 	return ft;
 }

 void
 fat_table_destroy (FatTable* ft)
 {
 	ped_free (ft->table);
 	ped_free (ft);
 }

 FatTable*
 fat_table_duplicate (const FatTable* ft)
 {
 	FatTable*	dup;

 	dup = fat_table_new (ft->fat_type, ft->size);
 	if (!dup) return NULL;

 	dup->cluster_count	= ft->cluster_count;
 	dup->free_cluster_count	= ft->free_cluster_count;
 	dup->bad_cluster_count	= ft->bad_cluster_count;
 	dup->last_alloc		= ft->last_alloc;

 	memcpy (dup->table, ft->table, ft->raw_size);

 	return dup;
 }

 void
 fat_table_clear (FatTable* ft)
 {
 	memset (ft->table, 0, ft->raw_size);

 	fat_table_set (ft, 0, 0x0ffffff8);
 	fat_table_set (ft, 1, 0x0fffffff);

 	ft->free_cluster_count = ft->cluster_count;
 	ft->bad_cluster_count = 0;
 	ft->last_alloc = 1;
 }

 int
 fat_table_set_cluster_count (FatTable* ft, FatCluster new_cluster_count)
 {
 	PED_ASSERT (new_cluster_count + 2 <= ft->size, return 0);

 	ft->cluster_count = new_cluster_count;
 	return fat_table_count_stats (ft);
 }

 int
 fat_table_count_stats (FatTable* ft)
 {
 	FatCluster	i;

 	PED_ASSERT (ft->cluster_count + 2 <= ft->size, return 0);

 	ft->free_cluster_count = 0;
 	ft->bad_cluster_count = 0;

 	for (i=2; i < ft->cluster_count + 2; i++) {
 		if (fat_table_is_available (ft, i))
 			ft->free_cluster_count++;
 		if (fat_table_is_bad (ft, i))
 			ft->bad_cluster_count++;
 	}
 	return 1;
 }

 int
 fat_table_read (FatTable* ft, const PedFileSystem* fs, int table_num)
 {
 	FatSpecific*	fs_info = FAT_SPECIFIC (fs);

 	PED_ASSERT (ft->raw_size >= fs_info->fat_sectors * 512, return 0);

 	memset (ft->table, 0, ft->raw_size);

         if (!ped_geometry_read (fs->geom, (void *) ft->table,
 				fs_info->fat_offset
 					+ table_num * fs_info->fat_sectors,
 				fs_info->fat_sectors))
 		return 0;

         if ( *((unsigned char*) ft->table) != fs_info->boot_sector.media) {
 		if (ped_exception_throw (
 			PED_EXCEPTION_ERROR,
 			PED_EXCEPTION_IGNORE_CANCEL,
 			_("FAT %d media %x doesn't match the boot sector's "
 			  "media %x.  You should probably run scandisk."),
 			(int) table_num + 1,
 			(int) *((unsigned char*) ft->table),
 			(int) fs_info->boot_sector.media)
 				!= PED_EXCEPTION_IGNORE)
 			return 0;
         }

 	ft->cluster_count = fs_info->cluster_count;

 	fat_table_count_stats (ft);

 	return 1;
 }

 int
 fat_table_write (const FatTable* ft, PedFileSystem* fs, int table_num)
 {
 	FatSpecific*	fs_info = FAT_SPECIFIC (fs);

 	PED_ASSERT (ft->raw_size >= fs_info->fat_sectors * 512, return 0);

         if (!ped_geometry_write (fs->geom, (void *) ft->table,
 				 fs_info->fat_offset
 					+ table_num * fs_info->fat_sectors,
 				 fs_info->fat_sectors))
 		return 0;
 	if (!ped_geometry_sync (fs->geom))
 		return 0;

 	return 1;
 }

 int
 fat_table_write_all (const FatTable* ft, PedFileSystem* fs)
 {
 	FatSpecific*	fs_info = FAT_SPECIFIC (fs);
 	int		i;

 	for (i = 0; i < fs_info->fat_table_count; i++) {
 		if (!fat_table_write (ft, fs, i))
 			return 0;
 	}

 	return 1;
 }

 int
 fat_table_compare (const FatTable* a, const FatTable* b)
 {
 	FatCluster	i;

 	if (a->cluster_count != b->cluster_count)
 		return 0;

 	for (i = 0; i < a->cluster_count + 2; i++) {
 		if (fat_table_get (a, i) != fat_table_get (b, i))
 			return 0;
 	}

 	return 1;
 }

 static int
 _test_code_available (const FatTable* ft, FatCluster code)
 {
 	return code == 0;
 }

 static int
 _test_code_bad (const FatTable* ft, FatCluster code)
 {
 	switch (ft->fat_type) {
                 case FAT_TYPE_FAT12:
                 if (code == 0xff7) return 1;
                 break;

 		case FAT_TYPE_FAT16:
 		if (code == 0xfff7) return 1;
 		break;

 		case FAT_TYPE_FAT32:
 		if (code == 0x0ffffff7) return 1;
 		break;
 	}
 	return 0;
 }

 static int
 _test_code_eof (const FatTable* ft, FatCluster code)
 {
 	switch (ft->fat_type) {
                 case FAT_TYPE_FAT12:
                 if (code >= 0xff7) return 1;
                 break;

 		case FAT_TYPE_FAT16:
 		if (code >= 0xfff7) return 1;
 		break;

 		case FAT_TYPE_FAT32:
 		if (code >= 0x0ffffff7) return 1;
 		break;
 	}
 	return 0;
 }

 void
 _update_stats (FatTable* ft, FatCluster cluster, FatCluster value)
 {
 	if (_test_code_available (ft, value)
 	    && !fat_table_is_available (ft, cluster)) {
 		ft->free_cluster_count++;
 		if (fat_table_is_bad (ft, cluster))
 			ft->bad_cluster_count--;
 	}

 	if (!_test_code_available (ft, value)
 	    && fat_table_is_available (ft, cluster)) {
 		ft->free_cluster_count--;
 		if (_test_code_bad (ft, cluster))
 			ft->bad_cluster_count--;
 	}
 }

 int
 fat_table_set (FatTable* ft, FatCluster cluster, FatCluster value)
 {
 	if (cluster >= ft->cluster_count + 2) {
 		ped_exception_throw (PED_EXCEPTION_BUG,
 				     PED_EXCEPTION_CANCEL,
 				     _("fat_table_set: cluster %ld outside "
 				       "file system"),
 				     (long) cluster);
 		return 0;
 	}

 	_update_stats (ft, cluster, value);

 	switch (ft->fat_type) {
                 case FAT_TYPE_FAT12:
                 PED_ASSERT (0, (void) 0);
                 break;

 		case FAT_TYPE_FAT16:
 		((unsigned short *) ft->table) [cluster]
 			= PED_CPU_TO_LE16 (value);
 		break;

 		case FAT_TYPE_FAT32:
 		((unsigned int *) ft->table) [cluster]
 			= PED_CPU_TO_LE32 (value);
 		break;
 	}
 	return 1;
 }

 FatCluster
 fat_table_get (const FatTable* ft, FatCluster cluster)
 {
 	if (cluster >= ft->cluster_count + 2) {
 		ped_exception_throw (PED_EXCEPTION_BUG,
 				     PED_EXCEPTION_CANCEL,
 				     _("fat_table_get: cluster %ld outside "
 				       "file system"),
 				     (long) cluster);
 		exit (1);	/* FIXME */
 	}

 	switch (ft->fat_type) {
                 case FAT_TYPE_FAT12:
                 PED_ASSERT (0, (void) 0);
                 break;

 		case FAT_TYPE_FAT16:
 		return PED_LE16_TO_CPU
 			(((unsigned short *) ft->table) [cluster]);

 		case FAT_TYPE_FAT32:
 		return PED_LE32_TO_CPU
 			(((unsigned int *) ft->table) [cluster]);
 	}

 	return 0;
 }

 FatCluster
 fat_table_alloc_cluster (FatTable* ft)
 {
 	FatCluster	i;
 	FatCluster	cluster;

 /* hack: assumes the first two FAT entries are marked as used (which they
  * always should be)
  */
 	for (i=1; i < ft->cluster_count + 1; i++) {
 		cluster = (i + ft->last_alloc) % ft->cluster_count;
 		if (fat_table_is_available (ft, cluster)) {
 			ft->last_alloc = cluster;
 			return cluster;
 		}
 	}

 	ped_exception_throw (PED_EXCEPTION_ERROR,
 			     PED_EXCEPTION_CANCEL,
 			     _("fat_table_alloc_cluster: no free clusters"));
 	return 0;
 }

 FatCluster
 fat_table_alloc_check_cluster (FatTable* ft, PedFileSystem* fs)
 {
 	FatSpecific*	fs_info = FAT_SPECIFIC (fs);
 	FatCluster	result;

 	while (1) {
 		result = fat_table_alloc_cluster (ft);
 		if (!result)
 			return 0;
 		if (fat_read_cluster (fs, fs_info->buffer, result))
 			return result;
 		fat_table_set_bad (ft, result);
 	}
 }

 /*
     returns true if <cluster> is marked as bad
 */
 int
 fat_table_is_bad (const FatTable* ft, FatCluster cluster)
 {
 	return _test_code_bad (ft, fat_table_get (ft, cluster));
 }

 /*
     returns true if <cluster> represents an EOF marker
 */
 int
 fat_table_is_eof (const FatTable* ft, FatCluster cluster)
 {
 	return _test_code_eof (ft, cluster);
 }

 /*
     returns true if <cluster> is available.
 */
 int
 fat_table_is_available (const FatTable* ft, FatCluster cluster)
 {
 	return _test_code_available (ft, fat_table_get (ft, cluster));
 }

 /*
     returns true if <cluster> is empty.  Note that this includes bad clusters.
 */
 int
 fat_table_is_empty (const FatTable* ft, FatCluster cluster)
 {
 	return fat_table_is_available (ft, cluster)
 		|| fat_table_is_bad (ft, cluster);
 }

 /*
     returns true if <cluster> is being used for something constructive.
 */
 int
 fat_table_is_active (const FatTable* ft, FatCluster cluster)
 {
 	return !fat_table_is_bad (ft, cluster)
 		&& !fat_table_is_available (ft, cluster);
 }

 /*
     marks <cluster> as the last cluster in the chain
 */
 int
 fat_table_set_eof (FatTable* ft, FatCluster cluster)
 {

 	switch (ft->fat_type) {
                 case FAT_TYPE_FAT12:
                 PED_ASSERT (0, (void) 0);
                 break;

 		case FAT_TYPE_FAT16:
 		return fat_table_set (ft, cluster, 0xfff8);

 		case FAT_TYPE_FAT32:
 		return fat_table_set (ft, cluster, 0x0fffffff);
 	}

 	return 0;
 }

 /*
 	Marks a clusters as unusable, due to physical disk damage.
 */
 int
 fat_table_set_bad (FatTable* ft, FatCluster cluster)
 {
 	if (!fat_table_is_bad (ft, cluster))
 		ft->bad_cluster_count++;

 	switch (ft->fat_type) {
                 case FAT_TYPE_FAT12:
 		return fat_table_set (ft, cluster, 0xff7);

 		case FAT_TYPE_FAT16:
 		return fat_table_set (ft, cluster, 0xfff7);

 		case FAT_TYPE_FAT32:
 		return fat_table_set (ft, cluster, 0x0ffffff7);
 	}

 	return 0;
 }

 /*
     marks <cluster> as unused/free/available
 */
 int
 fat_table_set_avail (FatTable* ft, FatCluster cluster)
 {
 	return fat_table_set (ft, cluster, 0);
 }

 #endif /* !DISCOVER_ONLY */

 int
 fat_table_entry_size (FatType fat_type)
 {
 	switch (fat_type) {
 		case FAT_TYPE_FAT12:
 		return 2;		/* FIXME: how? */

 		case FAT_TYPE_FAT16:
 		return 2;

 		case FAT_TYPE_FAT32:
 		return 4;
 	}

 	return 0;
 }
	/*
	libparted
	Copyright (C) 1998, 1999, 2000, 2007 Free Software Foundation, Inc.

	This program is free software; you can redistribute it and/or modify
	it under the terms of the GNU General Public License as published by
	the Free Software Foundation; either version 2 of the License, or
	(at your option) any later version.

	This program is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	GNU General Public License for more details.

	You should have received a copy of the GNU General Public License
	along with this program; if not, write to the Free Software
	Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
	*/

	#include <config.h>
	#include <parted/endian.h>
	#include "fat.h"

	#ifndef DISCOVER_ONLY

	FatTable*
	fat_table_new (FatType fat_type, FatCluster size)
	{
	FatTable* ft;
	int entry_size = fat_table_entry_size (fat_type);

	ft = (FatTable*) ped_malloc (sizeof (FatTable));
	if (!ft) return NULL;

	ft->cluster_count = ft->free_cluster_count = size - 2;

	/* ensure there's some free room on the end, to finish off the sector */
	ft->size = ped_div_round_up (size * entry_size, 512) * 512 / entry_size;
	ft->fat_type = fat_type;
	ft->raw_size = ft->size * entry_size;

	ft->table = ped_malloc (ft->raw_size);
	if (!ft->table) {
	ped_free (ft);
	return NULL;
	}

	fat_table_clear (ft);
	return ft;
	}

	void
	fat_table_destroy (FatTable* ft)
	{
	ped_free (ft->table);
	ped_free (ft);
	}

	FatTable*
	fat_table_duplicate (const FatTable* ft)
	{
	FatTable* dup;

	dup = fat_table_new (ft->fat_type, ft->size);
	if (!dup) return NULL;

	dup->cluster_count = ft->cluster_count;
	dup->free_cluster_count = ft->free_cluster_count;
	dup->bad_cluster_count = ft->bad_cluster_count;
	dup->last_alloc = ft->last_alloc;

	memcpy (dup->table, ft->table, ft->raw_size);

	return dup;
	}

	void
	fat_table_clear (FatTable* ft)
	{
	memset (ft->table, 0, ft->raw_size);

	fat_table_set (ft, 0, 0x0ffffff8);
	fat_table_set (ft, 1, 0x0fffffff);

	ft->free_cluster_count = ft->cluster_count;
	ft->bad_cluster_count = 0;
	ft->last_alloc = 1;
	}

	int
	fat_table_set_cluster_count (FatTable* ft, FatCluster new_cluster_count)
	{
	PED_ASSERT (new_cluster_count + 2 <= ft->size, return 0);

	ft->cluster_count = new_cluster_count;
	return fat_table_count_stats (ft);
	}

	int
	fat_table_count_stats (FatTable* ft)
	{
	FatCluster i;

	PED_ASSERT (ft->cluster_count + 2 <= ft->size, return 0);

	ft->free_cluster_count = 0;
	ft->bad_cluster_count = 0;

	for (i=2; i < ft->cluster_count + 2; i++) {
	if (fat_table_is_available (ft, i))
	ft->free_cluster_count++;
	if (fat_table_is_bad (ft, i))
	ft->bad_cluster_count++;
	}
	return 1;
	}

	int
	fat_table_read (FatTable* ft, const PedFileSystem* fs, int table_num)
	{
	FatSpecific* fs_info = FAT_SPECIFIC (fs);

	PED_ASSERT (ft->raw_size >= fs_info->fat_sectors * 512, return 0);

	memset (ft->table, 0, ft->raw_size);

	if (!ped_geometry_read (fs->geom, (void *) ft->table,
	fs_info->fat_offset
	+ table_num * fs_info->fat_sectors,
	fs_info->fat_sectors))
	return 0;

	if ( ((unsigned char) ft->table) != fs_info->boot_sector.media) {
	if (ped_exception_throw (
	PED_EXCEPTION_ERROR,
	PED_EXCEPTION_IGNORE_CANCEL,
	_("FAT %d media %x doesn't match the boot sector's "
	"media %x. You should probably run scandisk."),
	(int) table_num + 1,
	(int) ((unsigned char) ft->table),
	(int) fs_info->boot_sector.media)
	!= PED_EXCEPTION_IGNORE)
	return 0;
	}

	ft->cluster_count = fs_info->cluster_count;

	fat_table_count_stats (ft);

	return 1;
	}

	int
	fat_table_write (const FatTable* ft, PedFileSystem* fs, int table_num)
	{
	FatSpecific* fs_info = FAT_SPECIFIC (fs);

	PED_ASSERT (ft->raw_size >= fs_info->fat_sectors * 512, return 0);

	if (!ped_geometry_write (fs->geom, (void *) ft->table,
	fs_info->fat_offset
	+ table_num * fs_info->fat_sectors,
	fs_info->fat_sectors))
	return 0;
	if (!ped_geometry_sync (fs->geom))
	return 0;

	return 1;
	}

	int
	fat_table_write_all (const FatTable* ft, PedFileSystem* fs)
	{
	FatSpecific* fs_info = FAT_SPECIFIC (fs);
	int i;

	for (i = 0; i < fs_info->fat_table_count; i++) {
	if (!fat_table_write (ft, fs, i))
	return 0;
	}

	return 1;
	}

	int
	fat_table_compare (const FatTable* a, const FatTable* b)
	{
	FatCluster i;

	if (a->cluster_count != b->cluster_count)
	return 0;

	for (i = 0; i < a->cluster_count + 2; i++) {
	if (fat_table_get (a, i) != fat_table_get (b, i))
	return 0;
	}

	return 1;
	}

	static int
	_test_code_available (const FatTable* ft, FatCluster code)
	{
	return code == 0;
	}

	static int
	_test_code_bad (const FatTable* ft, FatCluster code)
	{
	switch (ft->fat_type) {
	case FAT_TYPE_FAT12:
	if (code == 0xff7) return 1;
	break;

	case FAT_TYPE_FAT16:
	if (code == 0xfff7) return 1;
	break;

	case FAT_TYPE_FAT32:
	if (code == 0x0ffffff7) return 1;
	break;
	}
	return 0;
	}

	static int
	_test_code_eof (const FatTable* ft, FatCluster code)
	{
	switch (ft->fat_type) {
	case FAT_TYPE_FAT12:
	if (code >= 0xff7) return 1;
	break;

	case FAT_TYPE_FAT16:
	if (code >= 0xfff7) return 1;
	break;

	case FAT_TYPE_FAT32:
	if (code >= 0x0ffffff7) return 1;
	break;
	}
	return 0;
	}

	void
	_update_stats (FatTable* ft, FatCluster cluster, FatCluster value)
	{
	if (_test_code_available (ft, value)
	&& !fat_table_is_available (ft, cluster)) {
	ft->free_cluster_count++;
	if (fat_table_is_bad (ft, cluster))
	ft->bad_cluster_count--;
	}

	if (!_test_code_available (ft, value)
	&& fat_table_is_available (ft, cluster)) {
	ft->free_cluster_count--;
	if (_test_code_bad (ft, cluster))
	ft->bad_cluster_count--;
	}
	}

	int
	fat_table_set (FatTable* ft, FatCluster cluster, FatCluster value)
	{
	if (cluster >= ft->cluster_count + 2) {
	ped_exception_throw (PED_EXCEPTION_BUG,
	PED_EXCEPTION_CANCEL,
	_("fat_table_set: cluster %ld outside "
	"file system"),
	(long) cluster);
	return 0;
	}

	_update_stats (ft, cluster, value);

	switch (ft->fat_type) {
	case FAT_TYPE_FAT12:
	PED_ASSERT (0, (void) 0);
	break;

	case FAT_TYPE_FAT16:
	((unsigned short *) ft->table) [cluster]
	= PED_CPU_TO_LE16 (value);
	break;

	case FAT_TYPE_FAT32:
	((unsigned int *) ft->table) [cluster]
	= PED_CPU_TO_LE32 (value);
	break;
	}
	return 1;
	}

	FatCluster
	fat_table_get (const FatTable* ft, FatCluster cluster)
	{
	if (cluster >= ft->cluster_count + 2) {
	ped_exception_throw (PED_EXCEPTION_BUG,
	PED_EXCEPTION_CANCEL,
	_("fat_table_get: cluster %ld outside "
	"file system"),
	(long) cluster);
	exit (1); /* FIXME */
	}

	switch (ft->fat_type) {
	case FAT_TYPE_FAT12:
	PED_ASSERT (0, (void) 0);
	break;

	case FAT_TYPE_FAT16:
	return PED_LE16_TO_CPU
	(((unsigned short *) ft->table) [cluster]);

	case FAT_TYPE_FAT32:
	return PED_LE32_TO_CPU
	(((unsigned int *) ft->table) [cluster]);
	}

	return 0;
	}

	FatCluster
	fat_table_alloc_cluster (FatTable* ft)
	{
	FatCluster i;
	FatCluster cluster;

	/* hack: assumes the first two FAT entries are marked as used (which they
	* always should be)
	*/
	for (i=1; i < ft->cluster_count + 1; i++) {
	cluster = (i + ft->last_alloc) % ft->cluster_count;
	if (fat_table_is_available (ft, cluster)) {
	ft->last_alloc = cluster;
	return cluster;
	}
	}

	ped_exception_throw (PED_EXCEPTION_ERROR,
	PED_EXCEPTION_CANCEL,
	_("fat_table_alloc_cluster: no free clusters"));
	return 0;
	}

	FatCluster
	fat_table_alloc_check_cluster (FatTable* ft, PedFileSystem* fs)
	{
	FatSpecific* fs_info = FAT_SPECIFIC (fs);
	FatCluster result;

	while (1) {
	result = fat_table_alloc_cluster (ft);
	if (!result)
	return 0;
	if (fat_read_cluster (fs, fs_info->buffer, result))
	return result;
	fat_table_set_bad (ft, result);
	}
	}

	/*
	returns true if <cluster> is marked as bad
	*/
	int
	fat_table_is_bad (const FatTable* ft, FatCluster cluster)
	{
	return _test_code_bad (ft, fat_table_get (ft, cluster));
	}

	/*
	returns true if <cluster> represents an EOF marker
	*/
	int
	fat_table_is_eof (const FatTable* ft, FatCluster cluster)
	{
	return _test_code_eof (ft, cluster);
	}

	/*
	returns true if <cluster> is available.
	*/
	int
	fat_table_is_available (const FatTable* ft, FatCluster cluster)
	{
	return _test_code_available (ft, fat_table_get (ft, cluster));
	}

	/*
	returns true if <cluster> is empty. Note that this includes bad clusters.
	*/
	int
	fat_table_is_empty (const FatTable* ft, FatCluster cluster)
	{
	return fat_table_is_available (ft, cluster)
	\|\| fat_table_is_bad (ft, cluster);
	}

	/*
	returns true if <cluster> is being used for something constructive.
	*/
	int
	fat_table_is_active (const FatTable* ft, FatCluster cluster)
	{
	return !fat_table_is_bad (ft, cluster)
	&& !fat_table_is_available (ft, cluster);
	}

	/*
	marks <cluster> as the last cluster in the chain
	*/
	int
	fat_table_set_eof (FatTable* ft, FatCluster cluster)
	{

	switch (ft->fat_type) {
	case FAT_TYPE_FAT12:
	PED_ASSERT (0, (void) 0);
	break;

	case FAT_TYPE_FAT16:
	return fat_table_set (ft, cluster, 0xfff8);

	case FAT_TYPE_FAT32:
	return fat_table_set (ft, cluster, 0x0fffffff);
	}

	return 0;
	}

	/*
	Marks a clusters as unusable, due to physical disk damage.
	*/
	int
	fat_table_set_bad (FatTable* ft, FatCluster cluster)
	{
	if (!fat_table_is_bad (ft, cluster))
	ft->bad_cluster_count++;

	switch (ft->fat_type) {
	case FAT_TYPE_FAT12:
	return fat_table_set (ft, cluster, 0xff7);

	case FAT_TYPE_FAT16:
	return fat_table_set (ft, cluster, 0xfff7);

	case FAT_TYPE_FAT32:
	return fat_table_set (ft, cluster, 0x0ffffff7);
	}

	return 0;
	}

	/*
	marks <cluster> as unused/free/available
	*/
	int
	fat_table_set_avail (FatTable* ft, FatCluster cluster)
	{
	return fat_table_set (ft, cluster, 0);
	}

	#endif /* !DISCOVER_ONLY */

	int
	fat_table_entry_size (FatType fat_type)
	{
	switch (fat_type) {
	case FAT_TYPE_FAT12:
	return 2; /* FIXME: how? */

	case FAT_TYPE_FAT16:
	return 2;

	case FAT_TYPE_FAT32:
	return 4;
	}

	return 0;
	}