# Copyright (c) 2013 The Johns Hopkins University/Applied Physics Laboratory # All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); you may # not use this file except in compliance with the License. You may obtain # a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, WITHOUT # WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the # License for the specific language governing permissions and limitations # under the License. import binascii import os from oslo_concurrency import processutils from oslo_log import log as logging from os_brick.encryptors import base from os_brick import exception from os_brick.privileged import rootwrap as priv_rootwrap from os_brick import utils LOG = logging.getLogger(__name__) def is_luks(root_helper, device, execute=None): """Checks if the specified device uses LUKS for encryption. :param device: the device to check :returns: true if the specified device uses LUKS; false otherwise """ try: # check to see if the device uses LUKS: exit status is 0 # if the device is a LUKS partition and non-zero if not if execute is None: execute = priv_rootwrap.execute execute('cryptsetup', 'isLuks', '--verbose', device, run_as_root=True, root_helper=root_helper, check_exit_code=True) return True except processutils.ProcessExecutionError as e: LOG.warning("isLuks exited abnormally (status %(exit_code)s): " "%(stderr)s", {"exit_code": e.exit_code, "stderr": e.stderr}) return False class LuksEncryptor(base.VolumeEncryptor): """A VolumeEncryptor based on LUKS. This VolumeEncryptor uses dm-crypt to encrypt the specified volume. """ def __init__(self, root_helper, connection_info, keymgr, execute=None, *args, **kwargs): super(LuksEncryptor, self).__init__( root_helper=root_helper, connection_info=connection_info, keymgr=keymgr, execute=execute, *args, **kwargs) # Fail if no device_path was set when connecting the volume, e.g. in # the case of libvirt network volume drivers. data = connection_info['data'] if not data.get('device_path'): volume_id = data.get('volume_id') or connection_info.get('serial') raise exception.VolumeEncryptionNotSupported( volume_id=volume_id, volume_type=connection_info['driver_volume_type']) # the device's path as given to libvirt -- e.g., /dev/disk/by-path/... self.symlink_path = connection_info['data']['device_path'] # a unique name for the volume -- e.g., the iSCSI participant name self.dev_name = 'crypt-%s' % os.path.basename(self.symlink_path) # NOTE(lixiaoy1): This is to import fix for 1439869 from Nova. # NOTE(tsekiyama): In older version of nova, dev_name was the same # as the symlink name. Now it has 'crypt-' prefix to avoid conflict # with multipath device symlink. To enable rolling update, we use the # old name when the encrypted volume already exists. old_dev_name = os.path.basename(self.symlink_path) wwn = data.get('multipath_id') if self._is_crypt_device_available(old_dev_name): self.dev_name = old_dev_name LOG.debug("Using old encrypted volume name: %s", self.dev_name) elif wwn and wwn != old_dev_name: # FibreChannel device could be named '/dev/mapper/'. if self._is_crypt_device_available(wwn): self.dev_name = wwn LOG.debug( "Using encrypted volume name from wwn: %s", self.dev_name) # the device's actual path on the compute host -- e.g., /dev/sd_ self.dev_path = os.path.realpath(self.symlink_path) def _is_crypt_device_available(self, dev_name): if not os.path.exists('/dev/mapper/%s' % dev_name): return False try: self._execute('cryptsetup', 'status', dev_name, run_as_root=True) except processutils.ProcessExecutionError as e: # If /dev/mapper/ is a non-crypt block device (such as a # normal disk or multipath device), exit_code will be 1. In the # case, we will omit the warning message. if e.exit_code != 1: LOG.warning('cryptsetup status %(dev_name)s exited ' 'abnormally (status %(exit_code)s): %(err)s', {"dev_name": dev_name, "exit_code": e.exit_code, "err": e.stderr}) return False return True def _format_volume(self, passphrase, **kwargs): """Creates a LUKS v1 header on the volume. :param passphrase: the passphrase used to access the volume """ self._format_luks_volume(passphrase, 'luks1', **kwargs) def _format_luks_volume(self, passphrase, version, **kwargs): """Creates a LUKS header of a given version or type on the volume. :param passphrase: the passphrase used to access the volume :param version: the LUKS version or type to use: one of `luks`, `luks1`, or `luks2`. Be aware that `luks` gives you the default LUKS format preferred by the particular cryptsetup being used (depends on version and compile time parameters), which could be either LUKS1 or LUKS2, so it's better to be specific about what you want here """ LOG.debug("formatting encrypted volume %s", self.dev_path) # NOTE(joel-coffman): cryptsetup will strip trailing newlines from # input specified on stdin unless --key-file=- is specified. cmd = ["cryptsetup", "--batch-mode", "luksFormat", "--type", version, "--key-file=-"] cipher = kwargs.get("cipher", None) if cipher is not None: cmd.extend(["--cipher", cipher]) key_size = kwargs.get("key_size", None) if key_size is not None: cmd.extend(["--key-size", key_size]) cmd.extend([self.dev_path]) self._execute(*cmd, process_input=passphrase, check_exit_code=True, run_as_root=True, root_helper=self._root_helper, attempts=3) def _get_passphrase(self, key): """Convert raw key to string.""" return binascii.hexlify(key).decode('utf-8') def _open_volume(self, passphrase, **kwargs): """Opens the LUKS partition on the volume using passphrase. :param passphrase: the passphrase used to access the volume """ LOG.debug("opening encrypted volume %s", self.dev_path) self._execute('cryptsetup', 'luksOpen', '--key-file=-', self.dev_path, self.dev_name, process_input=passphrase, run_as_root=True, check_exit_code=True, root_helper=self._root_helper) def attach_volume(self, context, **kwargs): """Shadow the device and pass an unencrypted version to the instance. Transparent disk encryption is achieved by mounting the volume via dm-crypt and passing the resulting device to the instance. The instance is unaware of the underlying encryption due to modifying the original symbolic link to refer to the device mounted by dm-crypt. """ key = self._get_key(context).get_encoded() passphrase = self._get_passphrase(key) try: self._open_volume(passphrase, **kwargs) except processutils.ProcessExecutionError as e: if e.exit_code == 1 and not is_luks(self._root_helper, self.dev_path, execute=self._execute): # the device has never been formatted; format it and try again LOG.info("%s is not a valid LUKS device;" " formatting device for first use", self.dev_path) self._format_volume(passphrase, **kwargs) self._open_volume(passphrase, **kwargs) else: raise # modify the original symbolic link to refer to the decrypted device self._execute('ln', '--symbolic', '--force', '/dev/mapper/%s' % self.dev_name, self.symlink_path, root_helper=self._root_helper, run_as_root=True, check_exit_code=True) def _close_volume(self, **kwargs): """Closes the device (effectively removes the dm-crypt mapping).""" LOG.debug("closing encrypted volume %s", self.dev_path) # NOTE(mdbooth): luksClose will return 4 (wrong device specified) if # the device doesn't exist. We assume here that the caller hasn't # specified the wrong device, and that it doesn't exist because it # isn't open. We don't fail in this case in order to make this # operation idempotent. self._execute('cryptsetup', 'luksClose', self.dev_name, run_as_root=True, check_exit_code=[0, 4], root_helper=self._root_helper, attempts=3) def detach_volume(self, **kwargs): """Removes the dm-crypt mapping for the device.""" self._close_volume(**kwargs) def extend_volume(self, context, **kwargs): """Extend an encrypted volume and return the decrypted volume size.""" symlink = self.symlink_path LOG.debug('Resizing mapping %s to match underlying device', symlink) key = self._get_key(context).get_encoded() passphrase = self._get_passphrase(key) self._execute('cryptsetup', 'resize', symlink, process_input=passphrase, run_as_root=True, check_exit_code=True, root_helper=self._root_helper) res = utils.get_device_size(self, symlink) LOG.debug('New size of mapping is %s', res) return res class Luks2Encryptor(LuksEncryptor): """A VolumeEncryptor based on LUKS v2. This VolumeEncryptor uses dm-crypt to encrypt the specified volume. """ def __init__(self, root_helper, connection_info, keymgr, execute=None, *args, **kwargs): super(Luks2Encryptor, self).__init__( root_helper=root_helper, connection_info=connection_info, keymgr=keymgr, execute=execute, *args, **kwargs) # type: ignore def _format_volume(self, passphrase, **kwargs): """Creates a LUKS v2 header on the volume. :param passphrase: the passphrase used to access the volume """ self._format_luks_volume(passphrase, 'luks2', **kwargs)