gparted/src/GParted_Core.cc

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/* Copyright (C) 2004 Bart 'plors' Hakvoort
*
* 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 Library 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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
#include "../include/Win_GParted.h"
#include "../include/GParted_Core.h"
#include "../include/OperationCopy.h"
#include "../include/OperationCreate.h"
#include "../include/OperationDelete.h"
#include "../include/OperationFormat.h"
#include "../include/OperationResizeMove.h"
#include <cerrno>
#include <sys/statvfs.h>
Glib::ustring ped_error ; //see e.g. ped_exception_handler()
namespace GParted
{
GParted_Core::GParted_Core()
{
lp_device = NULL ;
lp_disk = NULL ;
lp_partition = NULL ;
p_filesystem = NULL ;
ped_exception_set_handler( ped_exception_handler ) ;
//get valid flags ...
for ( PedPartitionFlag flag = ped_partition_flag_next( static_cast<PedPartitionFlag>( NULL ) ) ;
flag ;
flag = ped_partition_flag_next( flag ) )
flags .push_back( flag ) ;
//throw libpartedversion to the stdout to see which version is actually used.
std::cout << "======================" << std::endl ;
std::cout << "libparted : " << ped_get_version() << std::endl ;
std::cout << "======================" << std::endl ;
//initialize filesystemlist
find_supported_filesystems() ;
}
void GParted_Core::find_supported_filesystems()
{
FILESYSTEMS .clear() ;
ext2 fs_ext2;
FILESYSTEMS .push_back( fs_ext2 .get_filesystem_support() ) ;
ext3 fs_ext3;
FILESYSTEMS .push_back( fs_ext3 .get_filesystem_support() ) ;
fat16 fs_fat16;
FILESYSTEMS .push_back( fs_fat16 .get_filesystem_support() ) ;
fat32 fs_fat32;
FILESYSTEMS .push_back( fs_fat32 .get_filesystem_support() ) ;
hfs fs_hfs;
FILESYSTEMS .push_back( fs_hfs .get_filesystem_support() ) ;
hfsplus fs_hfsplus;
FILESYSTEMS .push_back( fs_hfsplus .get_filesystem_support() ) ;
jfs fs_jfs;
FILESYSTEMS .push_back( fs_jfs .get_filesystem_support() ) ;
linux_swap fs_linux_swap;
FILESYSTEMS .push_back( fs_linux_swap .get_filesystem_support() ) ;
ntfs fs_ntfs;
FILESYSTEMS .push_back( fs_ntfs .get_filesystem_support() ) ;
reiser4 fs_reiser4;
FILESYSTEMS .push_back( fs_reiser4 .get_filesystem_support() ) ;
reiserfs fs_reiserfs;
FILESYSTEMS .push_back( fs_reiserfs .get_filesystem_support() ) ;
xfs fs_xfs;
FILESYSTEMS .push_back( fs_xfs .get_filesystem_support() ) ;
//unknown filesystem (default when no match is found)
FS fs ; fs .filesystem = GParted::FS_UNKNOWN ;
FILESYSTEMS .push_back( fs ) ;
}
void GParted_Core::set_user_devices( const std::vector<Glib::ustring> & user_devices )
{
this ->device_paths = user_devices ;
this ->probe_devices = ! user_devices .size() ;
}
bool GParted_Core::check_device_path( const Glib::ustring & device_path )
{
return ( device_path .length() > 6 && device_path .is_ascii() ) ;
}
void GParted_Core::get_devices( std::vector<Device> & devices )
{
devices .clear() ;
Device temp_device ;
init_maps() ;
//only probe if no devices were specified as arguments..
if ( probe_devices )
{
device_paths .clear() ;
//try to find all available devices
ped_device_probe_all();
lp_device = ped_device_get_next( NULL );
while ( lp_device )
{
device_paths .push_back( lp_device ->path ) ;
lp_device = ped_device_get_next( lp_device ) ;
}
close_device_and_disk() ;
std::sort( device_paths .begin(), device_paths .end() ) ;
}
for ( unsigned int t = 0 ; t < device_paths .size() ; t++ )
{
if ( check_device_path( device_paths[ t ] ) &&
open_device_and_disk( device_paths[ t ], false ) &&
lp_device )
{
temp_device .Reset() ;
//device info..
temp_device .add_path( device_paths[ t ] ) ;
temp_device .add_paths( get_alternate_paths( temp_device .get_path() ) ) ;
temp_device .model = lp_device ->model ;
temp_device .heads = lp_device ->bios_geom .heads ;
temp_device .sectors = lp_device ->bios_geom .sectors ;
temp_device .cylinders = lp_device ->bios_geom .cylinders ;
temp_device .length = temp_device .heads * temp_device .sectors * temp_device .cylinders ;
temp_device .cylsize = temp_device .heads * temp_device .sectors ;
//make sure cylsize is at least 1 MiB
if ( temp_device .cylsize < MEBIBYTE )
temp_device .cylsize = MEBIBYTE ;
//normal harddisk
if ( lp_disk )
{
temp_device .disktype = lp_disk ->type ->name ;
temp_device .max_prims = ped_disk_get_max_primary_partition_count( lp_disk ) ;
set_device_partitions( temp_device ) ;
set_mountpoints( temp_device .partitions ) ;
set_used_sectors( temp_device .partitions ) ;
if ( temp_device .highest_busy )
temp_device .readonly = ! ped_disk_commit_to_os( lp_disk ) ;
}
//harddisk without disklabel
else
{
temp_device .disktype = _("unrecognized") ;
temp_device .max_prims = -1 ;
Partition partition_temp ;
partition_temp .Set_Unallocated( temp_device .get_path(),
0,
temp_device .length,
false );
temp_device .partitions .push_back( partition_temp );
}
devices .push_back( temp_device ) ;
close_device_and_disk() ;
}
}
//clear leftover information...
//NOTE that we cannot clear mountinfo since it might be needed in get_all_mountpoints()
alternate_paths .clear() ;
fstab_info .clear() ;
}
void GParted_Core::read_mountpoints_from_file( const Glib::ustring & filename,
std::map< Glib::ustring, std::vector<Glib::ustring> > & map )
{
std::string line ;
char node[255], mountpoint[255] ;
unsigned int index ;
std::ifstream file( filename .c_str() ) ;
if ( file )
{
while ( getline( file, line ) )
if ( Glib::str_has_prefix( line, "/" ) &&
sscanf( line .c_str(), "%255s %255s", node, mountpoint ) == 2 &&
static_cast<Glib::ustring>( node ) != "/dev/root" )
{
line = mountpoint ;
//see if mountpoint contains spaces and deal with it
index = line .find( "\\040" ) ;
if ( index < line .length() )
line .replace( index, 4, " " ) ;
map[ node ] .push_back( line ) ;
}
file .close() ;
}
}
void GParted_Core::init_maps()
{
alternate_paths .clear() ;
mount_info .clear() ;
fstab_info .clear() ;
read_mountpoints_from_file( "/proc/mounts", mount_info ) ;
read_mountpoints_from_file( "/etc/mtab", mount_info ) ;
read_mountpoints_from_file( "/etc/fstab", fstab_info ) ;
//sort the mountpoints and remove duplicates.. (no need to do this for fstab_info)
for ( iter_mp = mount_info .begin() ; iter_mp != mount_info .end() ; ++iter_mp )
{
std::sort( iter_mp ->second .begin(), iter_mp ->second .end() ) ;
iter_mp ->second .erase(
std::unique( iter_mp ->second .begin(), iter_mp ->second .end() ),
iter_mp ->second .end() ) ;
}
//initialize alternate_paths...
std::string line ;
std::ifstream proc_partitions( "/proc/partitions" ) ;
if ( proc_partitions )
{
char c_str[255] ;
while ( getline( proc_partitions, line ) )
if ( sscanf( line .c_str(), "%*d %*d %*d %255s", c_str ) == 1 )
{
line = "/dev/" ;
line += c_str ;
if ( realpath( line .c_str(), c_str ) && line != c_str )
{
//because we can make no assumption about which path libparted will detect
//we add all combinations.
alternate_paths[ c_str ] = line ;
alternate_paths[ line ] = c_str ;
}
}
proc_partitions .close() ;
}
}
GParted::FILESYSTEM GParted_Core::get_filesystem()
{
//standard libparted filesystems..
if ( lp_partition && lp_partition ->fs_type )
{
if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "extended" )
return GParted::FS_EXTENDED ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "ext2" )
return GParted::FS_EXT2 ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "ext3" )
return GParted::FS_EXT3 ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "linux-swap" )
return GParted::FS_LINUX_SWAP ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "fat16" )
return GParted::FS_FAT16 ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "fat32" )
return GParted::FS_FAT32 ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "ntfs" )
return GParted::FS_NTFS ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "reiserfs" )
return GParted::FS_REISERFS ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "xfs" )
return GParted::FS_XFS ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "jfs" )
return GParted::FS_JFS ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "hfs" )
return GParted::FS_HFS ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "hfs+" )
return GParted::FS_HFSPLUS ;
else if ( static_cast<Glib::ustring>( lp_partition ->fs_type ->name ) == "ufs" )
return GParted::FS_UFS ;
}
//other filesystems libparted couldn't detect (i've send patches for these filesystems to the parted guys)
char buf[512] ;
ped_device_open( lp_device );
//reiser4
ped_geometry_read( & lp_partition ->geom, buf, 128, 1 ) ;
ped_device_close( lp_device );
if ( static_cast<Glib::ustring>( buf ) == "ReIsEr4" )
return GParted::FS_REISER4 ;
//no filesystem found....
partition_temp .error = _( "Unable to detect filesystem! Possible reasons are:" ) ;
partition_temp .error += "\n-";
partition_temp .error += _( "The filesystem is damaged" ) ;
partition_temp .error += "\n-" ;
partition_temp .error += _( "The filesystem is unknown to libparted" ) ;
partition_temp .error += "\n-";
partition_temp .error += _( "There is no filesystem available (unformatted)" ) ;
return GParted::FS_UNKNOWN ;
}
void GParted_Core::set_device_partitions( Device & device )
{
int EXT_INDEX = -1 ;
char * lp_path ;//we have to free the result of ped_partition_get_path()..
//clear partitions
device .partitions .clear() ;
lp_partition = ped_disk_next_partition( lp_disk, NULL ) ;
while ( lp_partition )
{
partition_temp .Reset() ;
switch ( lp_partition ->type )
{
case PED_PARTITION_NORMAL:
case PED_PARTITION_LOGICAL:
lp_path = ped_partition_get_path( lp_partition ) ;
partition_temp .Set( device .get_path(),
lp_path,
lp_partition ->num,
lp_partition ->type == 0 ?
GParted::TYPE_PRIMARY : GParted::TYPE_LOGICAL,
get_filesystem(),
lp_partition ->geom .start,
lp_partition ->geom .end,
lp_partition ->type,
ped_partition_is_busy( lp_partition ) ) ;
free( lp_path ) ;
partition_temp .add_paths( get_alternate_paths( partition_temp .get_path() ) ) ;
set_flags( partition_temp ) ;
if ( partition_temp .busy && partition_temp .partition_number > device .highest_busy )
device .highest_busy = partition_temp .partition_number ;
break ;
case PED_PARTITION_EXTENDED:
lp_path = ped_partition_get_path( lp_partition ) ;
partition_temp .Set( device .get_path(),
lp_path,
lp_partition ->num,
GParted::TYPE_EXTENDED,
GParted::FS_EXTENDED,
lp_partition ->geom .start,
lp_partition ->geom .end,
false,
ped_partition_is_busy( lp_partition ) ) ;
free( lp_path ) ;
partition_temp .add_paths( get_alternate_paths( partition_temp .get_path() ) ) ;
set_flags( partition_temp ) ;
EXT_INDEX = device .partitions .size() ;
break ;
default:
break;
}
//if there's an end, there's a partition ;)
if ( partition_temp .sector_end > -1 )
{
if ( ! partition_temp .inside_extended )
device .partitions .push_back( partition_temp );
else
device .partitions[ EXT_INDEX ] .logicals .push_back( partition_temp ) ;
}
//next partition (if any)
lp_partition = ped_disk_next_partition( lp_disk, lp_partition ) ;
}
if ( EXT_INDEX > -1 )
insert_unallocated( device .get_path(),
device .partitions[ EXT_INDEX ] .logicals,
device .partitions[ EXT_INDEX ] .sector_start,
device .partitions[ EXT_INDEX ] .sector_end,
true ) ;
insert_unallocated( device .get_path(), device .partitions, 0, device .length -1, false ) ;
}
void GParted_Core::set_mountpoints( std::vector<Partition> & partitions )
{
for ( unsigned int t = 0 ; t < partitions .size() ; t++ )
{
if ( ( partitions[ t ] .type == GParted::TYPE_PRIMARY ||
partitions[ t ] .type == GParted::TYPE_LOGICAL ) &&
partitions[ t ] .filesystem != GParted::FS_LINUX_SWAP )
{
if ( partitions[ t ] .busy )
{
for ( unsigned int i = 0 ; i < partitions[ t ] .get_paths() .size() ; i++ )
{
iter_mp = mount_info .find( partitions[ t ] .get_paths()[ i ] ) ;
if ( iter_mp != mount_info .end() )
{
partitions[ t ] .add_mountpoints( iter_mp ->second ) ;
break ;
}
}
if ( partitions[ t ] .get_mountpoints() .empty() )
partitions[ t ] .error = _("Unable to find mountpoint") ;
}
else
{
iter_mp = fstab_info .find( partitions[ t ] .get_path() );
if ( iter_mp != fstab_info .end() )
partitions[ t ] .add_mountpoints( iter_mp ->second ) ;
}
}
else if ( partitions[ t ] .type == GParted::TYPE_EXTENDED )
set_mountpoints( partitions[ t ] .logicals ) ;
}
}
std::vector<Glib::ustring> GParted_Core::get_alternate_paths( const Glib::ustring & path )
{
std::vector<Glib::ustring> paths ;
iter = alternate_paths .find( path ) ;
if ( iter != alternate_paths .end() )
paths .push_back( iter ->second ) ;
return paths ;
}
void GParted_Core::set_used_sectors( std::vector<Partition> & partitions )
{
struct statvfs sfs ;
temp = _("Unable to read the contents of this filesystem!") ;
temp += "\n" ;
temp += _("Because of this some operations may be unavailable.") ;
temp += "\n\n" ;
temp += _("Did you install the correct plugin for this filesystem?") ;
for ( unsigned int t = 0 ; t < partitions .size() ; t++ )
{
if ( partitions[ t ] .filesystem != GParted::FS_LINUX_SWAP &&
partitions[ t ] .filesystem != GParted::FS_UNKNOWN )
{
if ( partitions[ t ] .type == GParted::TYPE_PRIMARY ||
partitions[ t ] .type == GParted::TYPE_LOGICAL )
{
if ( partitions[ t ] .busy )
{
if ( partitions[ t ] .get_mountpoints() .size() > 0 )
{
if ( statvfs( partitions[ t ] .get_mountpoint() .c_str(), &sfs ) == 0 )
partitions[ t ] .Set_Unused( sfs .f_bfree * (sfs .f_bsize / 512) ) ;
else
partitions[ t ] .error =
"statvfs (" + partitions[ t ] .get_mountpoint() + "): " + Glib::strerror( errno );
}
}
else
{
switch( get_fs( partitions[ t ] .filesystem ) .read )
{
case GParted::FS::EXTERNAL :
set_proper_filesystem( partitions[ t ] .filesystem ) ;
p_filesystem ->Set_Used_Sectors( partitions[ t ] ) ;
break ;
case GParted::FS::LIBPARTED :
LP_Set_Used_Sectors( partitions[ t ] ) ;
break ;
default:
break ;
}
}
if ( partitions[ t ] .sectors_used == -1 && partitions[ t ] .error .empty() )
partitions[ t ] .error = temp ;
}
else if ( partitions[ t ] .type == GParted::TYPE_EXTENDED )
set_used_sectors( partitions[ t ] .logicals ) ;
}
}
}
void GParted_Core::insert_unallocated( const Glib::ustring & device_path,
std::vector<Partition> & partitions,
Sector start,
Sector end,
bool inside_extended )
{
partition_temp .Reset() ;
partition_temp .Set_Unallocated( device_path, 0, 0, inside_extended ) ;
//if there are no partitions at all..
if ( partitions .empty() )
{
partition_temp .sector_start = start ;
partition_temp .sector_end = end ;
partitions .push_back( partition_temp );
return ;
}
//start <---> first partition start
if ( (partitions .front() .sector_start - start) >= MEBIBYTE )
{
partition_temp .sector_start = start ;
partition_temp .sector_end = partitions .front() .sector_start -1 ;
partitions .insert( partitions .begin(), partition_temp );
}
//look for gaps in between
for ( unsigned int t =0 ; t < partitions .size() -1 ; t++ )
if ( ( partitions[ t +1 ] .sector_start - partitions[ t ] .sector_end ) >= MEBIBYTE )
{
partition_temp .sector_start = partitions[ t ] .sector_end +1 ;
partition_temp .sector_end = partitions[ t +1 ] .sector_start -1 ;
partitions .insert( partitions .begin() + ++t, partition_temp );
}
//last partition end <---> end
if ( (end - partitions .back() .sector_end ) >= MEBIBYTE )
{
partition_temp .sector_start = partitions .back() .sector_end +1 ;
partition_temp .sector_end = end ;
partitions .push_back( partition_temp );
}
}
bool GParted_Core::apply_operation_to_disk( Operation * operation )
{
switch ( operation ->type )
{
case DELETE:
return Delete( operation ->partition_original, operation ->operation_details .sub_details ) ;
case CREATE:
return create( operation ->device,
operation ->partition_new,
operation ->operation_details .sub_details ) ;
case RESIZE_MOVE:
return resize( operation ->device,
operation ->partition_original,
operation ->partition_new,
operation ->operation_details .sub_details ) ;
case FORMAT:
return format( operation ->partition_new, operation ->operation_details .sub_details ) ;
case COPY:
operation ->partition_new .add_path( operation ->partition_original .get_path(), true ) ;
return copy( static_cast<OperationCopy*>( operation ) ->partition_copied .get_path(),
operation ->partition_new,
static_cast<OperationCopy*>( operation ) ->partition_copied .get_length(),
operation ->operation_details .sub_details ) ;
}
return false ;
}
bool GParted_Core::create( const Device & device,
Partition & new_partition,
std::vector<OperationDetails> & operation_details )
{
if ( new_partition .type == GParted::TYPE_EXTENDED )
{
return create_empty_partition( new_partition, operation_details ) ;
}
else if ( create_empty_partition( new_partition, operation_details, get_fs( new_partition .filesystem ) .MIN ) )
{
set_proper_filesystem( new_partition .filesystem ) ;
//most likely this means the user created an unformatted partition,
//however in theory, it could also screw some errorhandling.
if ( ! p_filesystem )
return true ;
return set_partition_type( new_partition, operation_details ) &&
p_filesystem ->Create( new_partition, operation_details ) ;
}
return false ;
}
bool GParted_Core::format( const Partition & partition, std::vector<OperationDetails> & operation_details )
{
//remove all filesystem signatures...
erase_filesystem_signatures( partition ) ;
set_proper_filesystem( partition .filesystem ) ;
return set_partition_type( partition, operation_details ) &&
p_filesystem ->Create( partition, operation_details ) ;
}
bool GParted_Core::Delete( const Partition & partition, std::vector<OperationDetails> & operation_details )
{
bool return_value = false ;
if ( open_device_and_disk( partition .device_path ) )
{
if ( partition .type == GParted::TYPE_EXTENDED )
lp_partition = ped_disk_extended_partition( lp_disk ) ;
else
lp_partition = ped_disk_get_partition_by_sector(
lp_disk,
(partition .sector_end + partition .sector_start) / 2 ) ;
return_value = ped_disk_delete_partition( lp_disk, lp_partition ) && commit() ;
sleep( 1 ) ; //give the kernel some time to reread the partitiontable
close_device_and_disk() ;
}
return return_value ;
}
bool GParted_Core::resize( const Device & device,
const Partition & partition_old,
const Partition & partition_new,
std::vector<OperationDetails> & operation_details )
{
//extended partition
if ( partition_old .type == GParted::TYPE_EXTENDED )
return resize_container_partition( partition_old, partition_new, false, operation_details ) ;
bool succes = false ;
set_proper_filesystem( partition_new .filesystem ) ;
//resize using libparted..
if ( get_fs( partition_old .filesystem ) .grow == GParted::FS::LIBPARTED )
{
if ( p_filesystem && p_filesystem ->Check_Repair( partition_new, operation_details ) )
{
succes = resize_normal_using_libparted( partition_old, partition_new, operation_details ) ;
//always check after a resize, but if it failes the whole operation failes
if ( ! p_filesystem ->Check_Repair( partition_new, operation_details ) )
succes = false ;
}
return succes ;
}
//use custom resize tools..
if ( p_filesystem && p_filesystem ->Check_Repair( partition_new, operation_details ) )
{
succes = true ;
if ( partition_new .get_length() < partition_old .get_length() )
{
p_filesystem ->cylinder_size = device .cylsize ;
succes = p_filesystem ->Resize( partition_new, operation_details ) ;
}
if ( succes )
succes = resize_container_partition(
partition_old,
partition_new,
! get_fs( partition_new .filesystem ) .move,
operation_details ) ;
//these 3 are always executed, however, if 1 of them fails the whole operation fails
if ( ! p_filesystem ->Check_Repair( partition_new, operation_details ) )
succes = false ;
//expand filesystem to fit exactly in partition
if ( ! p_filesystem ->Resize( partition_new, operation_details, true ) )
succes = false ;
if ( ! p_filesystem ->Check_Repair( partition_new, operation_details ) )
succes = false ;
return succes ;
}
return false ;
}
bool GParted_Core::copy( const Glib::ustring & src_part_path,
Partition & partition_dest,
Sector min_size,
std::vector<OperationDetails> & operation_details )
{
//FIXME: some filesystems (e.g. fat*) can be copied using libparted..
set_proper_filesystem( partition_dest .filesystem ) ;
if ( p_filesystem && p_filesystem ->Check_Repair( Partition( src_part_path ), operation_details ) )
{
bool succes = true ;
if ( partition_dest .status == GParted::STAT_NEW )
succes = create_empty_partition( partition_dest, operation_details, min_size ) ;
return ( succes &&
set_partition_type( partition_dest, operation_details ) &&
p_filesystem ->Copy( src_part_path, partition_dest .get_path(), operation_details ) &&
p_filesystem ->Check_Repair( partition_dest, operation_details ) &&
p_filesystem ->Resize( partition_dest, operation_details, true ) &&
p_filesystem ->Check_Repair( partition_dest, operation_details ) ) ;
}
return false ;
}
bool GParted_Core::Set_Disklabel( const Glib::ustring & device_path, const Glib::ustring & disklabel )
{
bool return_value = false ;
if ( open_device_and_disk( device_path, false ) )
{
PedDiskType *type = NULL ;
type = ped_disk_type_get( disklabel .c_str() ) ;
if ( type )
{
lp_disk = ped_disk_new_fresh( lp_device, type );
return_value = commit() ;
}
close_device_and_disk() ;
}
return return_value ;
}
const std::vector<FS> & GParted_Core::get_filesystems() const
{
return FILESYSTEMS ;
}
const FS & GParted_Core::get_fs( GParted::FILESYSTEM filesystem ) const
{
for ( unsigned int t = 0 ; t < FILESYSTEMS .size() ; t++ )
if ( FILESYSTEMS[ t ] .filesystem == filesystem )
return FILESYSTEMS[ t ] ;
return FILESYSTEMS .back() ;
}
std::vector<Glib::ustring> GParted_Core::get_disklabeltypes()
{
std::vector<Glib::ustring> disklabeltypes ;
//msdos should be first in the list
disklabeltypes .push_back( "msdos" ) ;
PedDiskType *disk_type ;
for ( disk_type = ped_disk_type_get_next( NULL ) ; disk_type ; disk_type = ped_disk_type_get_next( disk_type ) )
if ( static_cast<Glib::ustring>( disk_type->name ) != "msdos" )
disklabeltypes .push_back( disk_type->name ) ;
return disklabeltypes ;
}
std::vector<Glib::ustring> GParted_Core::get_all_mountpoints()
{
std::vector<Glib::ustring> mountpoints ;
for ( iter_mp = mount_info .begin() ; iter_mp != mount_info .end() ; ++iter_mp )
mountpoints .insert( mountpoints .end(), iter_mp ->second .begin(), iter_mp ->second .end() ) ;
return mountpoints ;
}
std::map<Glib::ustring, bool> GParted_Core::get_available_flags( const Partition & partition )
{
std::map<Glib::ustring, bool> flag_info ;
if ( open_device_and_disk( partition .device_path ) )
{
lp_partition = NULL ;
if ( partition .type == GParted::TYPE_EXTENDED )
lp_partition = ped_disk_extended_partition( lp_disk ) ;
else
lp_partition = ped_disk_get_partition_by_sector(
lp_disk,
(partition .sector_end + partition .sector_start) / 2 ) ;
if ( lp_partition )
{
for ( unsigned int t = 0 ; t < flags .size() ; t++ )
if ( ped_partition_is_flag_available( lp_partition, flags[ t ] ) )
flag_info[ ped_partition_flag_get_name( flags[ t ] ) ] =
ped_partition_get_flag( lp_partition, flags[ t ] ) ;
}
close_device_and_disk() ;
}
return flag_info ;
}
bool GParted_Core::toggle_flag( const Partition & partition, const Glib::ustring & flag, bool state )
{
bool succes = false ;
if ( open_device_and_disk( partition .device_path ) )
{
lp_partition = NULL ;
if ( partition .type == GParted::TYPE_EXTENDED )
lp_partition = ped_disk_extended_partition( lp_disk ) ;
else
lp_partition = ped_disk_get_partition_by_sector(
lp_disk,
(partition .sector_end + partition .sector_start) / 2 ) ;
if ( lp_partition )
{
PedPartitionFlag lp_flag = ped_partition_flag_get_by_name( flag .c_str() ) ;
if ( lp_flag > 0 && ped_partition_set_flag( lp_partition, lp_flag, state ) )
succes = commit() ;
}
close_device_and_disk() ;
}
return succes ;
}
void GParted_Core::LP_Set_Used_Sectors( Partition & partition )
{
PedFileSystem *fs = NULL;
PedConstraint *constraint = NULL;
if ( lp_disk )
{
lp_partition = ped_disk_get_partition_by_sector(
lp_disk,
(partition .sector_end + partition .sector_start) / 2 ) ;
if ( lp_partition )
{
fs = ped_file_system_open( & lp_partition ->geom );
if ( fs )
{
constraint = ped_file_system_get_resize_constraint( fs ) ;
if ( constraint )
{
partition .Set_Unused( partition .get_length() - constraint ->min_size ) ;
ped_constraint_destroy( constraint );
}
ped_file_system_close( fs ) ;
}
}
}
}
bool GParted_Core::create_empty_partition( Partition & new_partition,
std::vector<OperationDetails> & operation_details,
Sector min_size )
{
operation_details .push_back( OperationDetails( _("create empty partition") ) ) ;
new_partition .partition_number = 0 ;
ped_error .clear() ;
if ( open_device_and_disk( new_partition .device_path ) )
{
PedPartitionType type;
lp_partition = NULL ;
PedConstraint *constraint = NULL ;
//create new partition
switch ( new_partition .type )
{
case GParted::TYPE_PRIMARY:
type = PED_PARTITION_NORMAL ;
break ;
case GParted::TYPE_LOGICAL:
type = PED_PARTITION_LOGICAL ;
break ;
case GParted::TYPE_EXTENDED:
type = PED_PARTITION_EXTENDED ;
break ;
default :
type = PED_PARTITION_FREESPACE;
}
lp_partition = ped_partition_new( lp_disk,
type,
NULL,
new_partition .sector_start,
new_partition .sector_end ) ;
if ( lp_partition )
{
if ( new_partition .strict )
{
PedGeometry *geom = ped_geometry_new( lp_device,
new_partition .sector_start,
new_partition .get_length() ) ;
if ( geom )
constraint = ped_constraint_exact( geom ) ;
}
else
constraint = ped_constraint_any( lp_device );
if ( constraint )
{
if ( min_size > 0 )
constraint ->min_size = min_size ;
if ( ped_disk_add_partition( lp_disk, lp_partition, constraint ) && commit() )
{
//we have to free the result of ped_partition_get_path()..
char * lp_path = ped_partition_get_path( lp_partition ) ;
new_partition .add_path( lp_path, true ) ;
free( lp_path ) ;
new_partition .partition_number = lp_partition ->num ;
Sector start = lp_partition ->geom .start ;
Sector end = lp_partition ->geom .end ;
operation_details .back() .sub_details .push_back(
OperationDetails(
"<i>" +
String::ucompose( _("path: %1"), new_partition .get_path() ) + "\n" +
String::ucompose( _("start: %1"), start ) + "\n" +
String::ucompose( _("end: %1"), end ) + "\n" +
String::ucompose( _("size: %1"), Utils::format_size( end - start + 1 ) ) +
"</i>",
OperationDetails::NONE ) ) ;
}
ped_constraint_destroy( constraint );
}
}
close_device_and_disk() ;
}
if ( new_partition .partition_number > 0 &&
(
new_partition .type == GParted::TYPE_EXTENDED ||
(
wait_for_node( new_partition .get_path() ) &&
erase_filesystem_signatures( new_partition )
)
)
)
{
operation_details .back() .status = OperationDetails::SUCCES ;
return new_partition .partition_number > 0 ;
}
else
{
if ( ! ped_error .empty() )
operation_details .back() .sub_details .push_back(
OperationDetails( "<i>" + ped_error + "</i>", OperationDetails::NONE ) ) ;
operation_details .back() .status = OperationDetails::ERROR ;
return false ;
}
}
bool GParted_Core::resize_container_partition( const Partition & partition_old,
const Partition & partition_new,
bool fixed_start,
std::vector<OperationDetails> & operation_details )
{
operation_details .push_back( OperationDetails( _("resize partition") ) ) ;
operation_details .back() .sub_details .push_back(
OperationDetails(
"<i>" +
String::ucompose( _("old start: %1"), partition_old .sector_start ) + "\n" +
String::ucompose( _("old end: %1"), partition_old .sector_end ) + "\n" +
String::ucompose( _("old size: %1"), Utils::format_size( partition_old .get_length() ) ) +
"</i>",
OperationDetails::NONE ) ) ;
bool return_value = false ;
PedConstraint *constraint = NULL ;
lp_partition = NULL ;
ped_error .clear() ;
if ( open_device_and_disk( partition_old .device_path ) )
{
if ( partition_old .type == GParted::TYPE_EXTENDED )
lp_partition = ped_disk_extended_partition( lp_disk ) ;
else
lp_partition = ped_disk_get_partition_by_sector(
lp_disk,
(partition_old .sector_end + partition_old .sector_start) / 2 ) ;
if ( lp_partition )
{
constraint = ped_constraint_any( lp_device );
if ( fixed_start && constraint )
{
//create a constraint which keeps de startpoint intact and rounds the end to a cylinder
ped_disk_set_partition_geom( lp_disk,
lp_partition,
constraint,
partition_new .sector_start,
partition_new .sector_end ) ;
ped_constraint_destroy( constraint );
constraint = NULL ;
ped_geometry_set_start( & lp_partition ->geom, partition_new .sector_start ) ;
constraint = ped_constraint_exact( & lp_partition ->geom ) ;
}
if ( constraint )
{
if ( ped_disk_set_partition_geom( lp_disk,
lp_partition,
constraint,
partition_new .sector_start,
partition_new .sector_end ) )
return_value = commit() ;
ped_constraint_destroy( constraint );
}
}
close_device_and_disk() ;
}
if ( return_value )
{
//use start/end vars since lp_partition ->geom loses his values after a functioncall :/
//this is actually quite weird, but i don't have time to investigate it more thorough.
Sector start = lp_partition ->geom .start ;
Sector end = lp_partition ->geom .end ;
operation_details .back() .sub_details .push_back(
OperationDetails(
"<i>" +
String::ucompose( _("new start: %1"), start ) + "\n" +
String::ucompose( _("new end: %1"), end ) + "\n" +
String::ucompose( _("new size: %1"), Utils::format_size( end - start + 1 ) ) +
"</i>",
OperationDetails::NONE ) ) ;
}
else if ( ! ped_error .empty() )
operation_details .back() .sub_details .push_back(
OperationDetails( "<i>" + ped_error + "</i>", OperationDetails::NONE ) ) ;
if ( partition_old .type == GParted::TYPE_EXTENDED )
{
operation_details .back() .status = return_value ? OperationDetails::SUCCES : OperationDetails::ERROR ;
return return_value ;
}
else
{
return_value &= wait_for_node( partition_new .get_path() ) ;
operation_details .back() .status = return_value ? OperationDetails::SUCCES : OperationDetails::ERROR ;
return return_value ;
}
}
bool GParted_Core::resize_normal_using_libparted( const Partition & partition_old,
const Partition & partition_new,
std::vector<OperationDetails> & operation_details )
{
operation_details .push_back( OperationDetails( _("resize partition and filesystem using libparted") ) ) ;
bool return_value = false ;
PedFileSystem *fs = NULL ;
PedConstraint *constraint = NULL ;
lp_partition = NULL ;
ped_error .clear() ;
if ( open_device_and_disk( partition_old .device_path ) )
{
lp_partition = ped_disk_get_partition_by_sector(
lp_disk,
(partition_old .sector_end + partition_old .sector_start) / 2 ) ;
if ( lp_partition )
{
fs = ped_file_system_open( & lp_partition ->geom );
if ( fs )
{
constraint = ped_file_system_get_resize_constraint( fs );
if ( constraint )
{
if ( ped_disk_set_partition_geom( lp_disk,
lp_partition,
constraint,
partition_new .sector_start,
partition_new .sector_end )
&&
ped_file_system_resize( fs, & lp_partition ->geom, NULL )
)
return_value = commit() ;
ped_constraint_destroy( constraint );
}
ped_file_system_close( fs );
}
}
close_device_and_disk() ;
}
operation_details .back() .status = return_value ? OperationDetails::SUCCES : OperationDetails::ERROR ;
if ( ! return_value && ! ped_error .empty() )
operation_details .back() .sub_details .push_back(
OperationDetails( "<i>" + ped_error + "</i>", OperationDetails::NONE ) ) ;
return return_value ;
}
void GParted_Core::set_flags( Partition & partition )
{
for ( unsigned int t = 0 ; t < flags .size() ; t++ )
if ( ped_partition_is_flag_available( lp_partition, flags[ t ] ) &&
ped_partition_get_flag( lp_partition, flags[ t ] ) )
partition .flags .push_back( ped_partition_flag_get_name( flags[ t ] ) ) ;
}
void GParted_Core::set_proper_filesystem( const FILESYSTEM & filesystem )
{
if ( p_filesystem )
delete p_filesystem ;
switch( filesystem )
{
case FS_EXT2 : p_filesystem = new ext2() ; break ;
case FS_EXT3 : p_filesystem = new ext3() ; break ;
case FS_LINUX_SWAP : p_filesystem = new linux_swap() ; break ;
case FS_FAT16 : p_filesystem = new fat16() ; break ;
case FS_FAT32 : p_filesystem = new fat32() ; break ;
case FS_NTFS : p_filesystem = new ntfs() ; break ;
case FS_REISERFS : p_filesystem = new reiserfs() ; break ;
case FS_REISER4 : p_filesystem = new reiser4() ; break ;
case FS_XFS : p_filesystem = new xfs() ; break ;
case FS_JFS : p_filesystem = new jfs() ; break ;
case FS_HFS : p_filesystem = new hfs() ; break ;
case FS_HFSPLUS : p_filesystem = new hfsplus() ; break ;
default : p_filesystem = NULL ;
}
}
bool GParted_Core::set_partition_type( const Partition & partition,
std::vector<OperationDetails> & operation_details )
{
operation_details .push_back( OperationDetails( _("set partitiontype") ) ) ;
bool return_value = false ;
if ( open_device_and_disk( partition .device_path ) )
{
PedFileSystemType * fs_type =
2006-03-28 05:40:29 -07:00
ped_file_system_type_get( Utils::get_filesystem_string( partition .filesystem ) .c_str() ) ;
//default is Linux (83)
if ( ! fs_type )
fs_type = ped_file_system_type_get( "ext2" ) ;
if ( fs_type )
{
lp_partition = ped_disk_get_partition_by_sector(
lp_disk,
(partition .sector_end + partition .sector_start) / 2 ) ;
if ( lp_partition && ped_partition_set_system( lp_partition, fs_type ) && commit() )
return_value = wait_for_node( partition .get_path() ) ;
}
close_device_and_disk() ;
}
operation_details .back() .status = return_value ? OperationDetails::SUCCES : OperationDetails::ERROR ;
return return_value ;
}
bool GParted_Core::wait_for_node( const Glib::ustring & node )
{
//we'll loop for 10 seconds or till 'node' appeares...
for( short t = 0 ; t < 50 ; t++ )
{
//FIXME: find a better way to check if a file exists
//the current way is suboptimal (at best)
if ( Glib::file_test( node, Glib::FILE_TEST_EXISTS ) )
{
sleep( 2 ) ; //apperantly the node isn't available immediatly after file_test returns succesfully :/
return true ;
}
else
usleep( 200000 ) ; //200 milliseconds
}
return false ;
}
bool GParted_Core::erase_filesystem_signatures( const Partition & partition )
{
bool return_value = false ;
if ( open_device_and_disk( partition .device_path ) )
{
lp_partition = ped_disk_get_partition_by_sector(
lp_disk,
(partition .sector_end + partition .sector_start) / 2 ) ;
if ( lp_partition && ped_file_system_clobber( & lp_partition ->geom ) )
{
//filesystems not yet supported by libparted
if ( ped_device_open( lp_device ) )
{
//reiser4 stores "ReIsEr4" at sector 128
return_value = ped_geometry_write( & lp_partition ->geom, "0000000", 128, 1 ) ;
ped_device_close( lp_device ) ;
}
}
close_device_and_disk() ;
}
return return_value ;
}
bool GParted_Core::open_device( const Glib::ustring & device_path )
{
lp_device = ped_device_get( device_path .c_str() );
return lp_device ;
}
bool GParted_Core::open_device_and_disk( const Glib::ustring & device_path, bool strict )
{
lp_device = NULL ;
lp_disk = NULL ;
if ( open_device( device_path ) )
{
lp_disk = ped_disk_new( lp_device );
//if ! disk and writeable it's probably a HD without disklabel.
//We return true here and deal with them in GParted_Core::get_devices
if ( lp_disk || ( ! strict && ! lp_device ->read_only ) )
return true ;
close_device_and_disk() ;
}
return false ;
}
void GParted_Core::close_device_and_disk()
{
if ( lp_device )
ped_device_destroy( lp_device ) ;
if ( lp_disk )
ped_disk_destroy( lp_disk ) ;
lp_device = NULL ;
lp_disk = NULL ;
}
bool GParted_Core::commit()
{
bool return_value = ped_disk_commit_to_dev( lp_disk ) ;
ped_disk_commit_to_os( lp_disk ) ;
return return_value ;
}
PedExceptionOption GParted_Core::ped_exception_handler( PedException * e )
{
std::cout << e ->message << std::endl ;
ped_error = e ->message ;
return PED_EXCEPTION_UNHANDLED ;
}
GParted_Core::~GParted_Core()
{
if ( p_filesystem )
delete p_filesystem ;
}
} //GParted