+ self.out.warn("%s (ignored)" % msg)
+ self.out.success("done")
+
+ def umount(self):
+ """Umount all mounted filesystems."""
+ self.g.umount_all()
+
+ def _last_partition(self):
+ if self.meta['PARTITION_TABLE'] not in 'msdos' 'gpt':
+ msg = "Unsupported partition table: %s. Only msdos and gpt " \
+ "partition tables are supported" % self.meta['PARTITION_TABLE']
+ raise FatalError(msg)
+
+ is_extended = lambda p: \
+ self.g.part_get_mbr_id(self.guestfs_device, p['part_num']) == 5
+ is_logical = lambda p: \
+ self.meta['PARTITION_TABLE'] != 'msdos' and p['part_num'] > 4
+
+ partitions = self.g.part_list(self.guestfs_device)
+ last_partition = partitions[-1]
+
+ if is_logical(last_partition):
+ # The disk contains extended and logical partitions....
+ extended = [p for p in partitions if is_extended(p)][0]
+ last_primary = [p for p in partitions if p['part_num'] <= 4][-1]
+
+ # check if extended is the last primary partition
+ if last_primary['part_num'] > extended['part_num']:
+ last_partition = last_primary
+
+ return last_partition
+
+ def shrink(self):
+ """Shrink the disk.
+
+ This is accomplished by shrinking the last filesystem in the
+ disk and then updating the partition table. The new disk size
+ (in bytes) is returned.
+
+ ATTENTION: make sure unmount is called before shrink
+ """
+ get_fstype = lambda p: \
+ self.g.vfs_type("%s%d" % (self.guestfs_device, p['part_num']))
+ is_logical = lambda p: \
+ self.meta['PARTITION_TABLE'] == 'msdos' and p['part_num'] > 4
+ is_extended = lambda p: \
+ self.meta['PARTITION_TABLE'] == 'msdos' and \
+ self.g.part_get_mbr_id(self.guestfs_device, p['part_num']) == 5
+
+ part_add = lambda ptype, start, stop: \
+ self.g.part_add(self.guestfs_device, ptype, start, stop)
+ part_del = lambda p: self.g.part_del(self.guestfs_device, p)
+ part_get_id = lambda p: self.g.part_get_mbr_id(self.guestfs_device, p)
+ part_set_id = lambda p, id: \
+ self.g.part_set_mbr_id(self.guestfs_device, p, id)
+ part_get_bootable = lambda p: \
+ self.g.part_get_bootable(self.guestfs_device, p)
+ part_set_bootable = lambda p, bootable: \
+ self.g.part_set_bootable(self.guestfs_device, p, bootable)
+
+ MB = 2 ** 20
+
+ self.out.output("Shrinking image (this may take a while)...", False)
+
+ sector_size = self.g.blockdev_getss(self.guestfs_device)
+
+ last_part = None
+ fstype = None
+ while True:
+ last_part = self._last_partition()
+ fstype = get_fstype(last_part)
+
+ if fstype == 'swap':
+ self.meta['SWAP'] = "%d:%s" % \
+ (last_part['part_num'],
+ (last_part['part_size'] + MB - 1) // MB)
+ part_del(last_part['part_num'])
+ continue
+ elif is_extended(last_part):
+ part_del(last_part['part_num'])
+ continue
+
+ # Most disk manipulation programs leave 2048 sectors after the last
+ # partition
+ new_size = last_part['part_end'] + 1 + 2048 * sector_size
+ self.size = min(self.size, new_size)
+ break
+
+ if not re.match("ext[234]", fstype):
+ self.out.warn("Don't know how to resize %s partitions." % fstype)
+ return self.size
+
+ part_dev = "%s%d" % (self.guestfs_device, last_part['part_num'])
+ self.g.e2fsck_f(part_dev)
+ self.g.resize2fs_M(part_dev)
+
+ out = self.g.tune2fs_l(part_dev)
+ block_size = int(
+ filter(lambda x: x[0] == 'Block size', out)[0][1])
+ block_cnt = int(
+ filter(lambda x: x[0] == 'Block count', out)[0][1])
+
+ start = last_part['part_start'] / sector_size
+ end = start + (block_size * block_cnt) / sector_size - 1
+
+ if is_logical(last_part):
+ partitions = self.g.part_list(self.guestfs_device)
+
+ logical = [] # logical partitions
+ for partition in partitions:
+ if partition['part_num'] < 4:
+ continue
+ logical.append({
+ 'num': partition['part_num'],
+ 'start': partition['part_start'] / sector_size,
+ 'end': partition['part_end'] / sector_size,
+ 'id': part_get_(partition['part_num']),
+ 'bootable': part_get_bootable(partition['part_num'])
+ })
+
+ logical[-1]['end'] = end # new end after resize
+
+ # Recreate the extended partition
+ extended = [p for p in partitions if self._is_extended(p)][0]
+ part_del(extended['part_num'])
+ part_add('e', extended['part_start'], end)
+
+ # Create all the logical partitions back
+ for l in logical:
+ part_add('l', l['start'], l['end'])
+ part_set_id(l['num'], l['id'])
+ part_set_bootable(l['num'], l['bootable'])
+ else:
+ # Recreate the last partition
+ if self.meta['PARTITION_TABLE'] == 'msdos':
+ last_part['id'] = part_get_id(last_part['part_num'])
+
+ last_part['bootable'] = part_get_bootable(last_part['part_num'])
+ part_del(last_part['part_num'])
+ part_add('p', start, end)
+ part_set_bootable(last_part['part_num'], last_part['bootable'])
+
+ if self.meta['PARTITION_TABLE'] == 'msdos':
+ part_set_id(last_part['part_num'], last_part['id'])
+
+ new_size = (end + 1) * sector_size
+
+ assert (new_size <= self.size)
+
+ if self.meta['PARTITION_TABLE'] == 'gpt':
+ ptable = GPTPartitionTable(self.real_device)
+ self.size = ptable.shrink(new_size, self.size)
+ else:
+ self.size = min(new_size + 2048 * sector_size, self.size)
+
+ self.out.success("new size is %dMB" % ((self.size + MB - 1) // MB))
+
+ return self.size
+
+ def dump(self, outfile):
+ """Dumps the content of device into a file.
+
+ This method will only dump the actual payload, found by reading the
+ partition table. Empty space in the end of the device will be ignored.
+ """
+ MB = 2 ** 20
+ blocksize = 4 * MB # 4MB
+ size = self.size
+ progr_size = (size + MB - 1) // MB # in MB
+ progressbar = self.out.Progress(progr_size, "Dumping image file", 'mb')
+
+ with open(self.real_device, 'r') as src:
+ with open(outfile, "w") as dst:
+ left = size
+ offset = 0
+ progressbar.next()
+ while left > 0:
+ length = min(left, blocksize)
+ sent = sendfile(dst.fileno(), src.fileno(), offset, length)
+ offset += sent
+ left -= sent
+ progressbar.goto((size - left) // MB)
+ progressbar.success('image file %s was successfully created' % outfile)