# devices.py # Device classes for anaconda's storage configuration module. # # Copyright (C) 2009 Red Hat, Inc. # # This copyrighted material is made available to anyone wishing to use, # modify, copy, or redistribute it subject to the terms and conditions of # the GNU General Public License v.2, or (at your option) any later version. # This program is distributed in the hope that it will be useful, but WITHOUT # ANY WARRANTY expressed or implied, including the implied warranties 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 Street, Fifth Floor, Boston, MA # 02110-1301, USA. Any Red Hat trademarks that are incorporated in the # source code or documentation are not subject to the GNU General Public # License and may only be used or replicated with the express permission of # Red Hat, Inc. # # Red Hat Author(s): Dave Lehman # """ Device classes for use by anaconda. This is the hierarchy of device objects that anaconda will use for managing storage devices in the system. These classes will individually make use of external support modules as needed to perform operations specific to the type of device they represent. TODO: - see how to do network devices (NetworkManager may help) - perhaps just a wrapper here - document return values of all methods/functions - find out what other kinds of wild and crazy devices we need to represent here (iseries? xen? more mainframe? mac? ps?) - PReP - this is a prime candidate for a PseudoDevice - DASD - ZFCP - XEN What specifications do we allow? new existing partitions usage + + filesystem, partition type are implicit mountpoint + + size exact + - range + - resize - + format - + encryption + + disk exact + - set + - how will we specify this? partition w/ multiple parents cannot otherwise occur primary + - mdraid sets filesystem (*) + + mountpoint + + size? format - + encryption + + level + ? device minor + ? member devices + ? spares + ? name? bitmap? (boolean) + - volume groups name + - member pvs + + pesize + ? logical volumes filesystem + + mountpoint + + size exact + ? format - + encryption + + name + ? vgname + ? """ import os import math import copy # device backend modules from devicelibs import mdraid from devicelibs import lvm from devicelibs import dm import parted import _ped import platform import block from errors import * from iutil import log_method_call, notify_kernel, numeric_type from udev import * from formats import get_device_format_class, getFormat, DeviceFormat import gettext _ = lambda x: gettext.ldgettext("anaconda", x) import logging log = logging.getLogger("storage") def get_device_majors(): majors = {} for line in open("/proc/devices").readlines(): try: (major, device) = line.split() except ValueError: continue try: majors[int(major)] = device except ValueError: continue return majors device_majors = get_device_majors() def devicePathToName(devicePath): if devicePath.startswith("/dev/"): name = devicePath[5:] else: name = devicePath if name.startswith("mapper/"): name = name[7:] return name def deviceNameToDiskByPath(deviceName=None): bypath = '/dev/disk/by-path' if not deviceName: return "" if not os.path.isdir(bypath): return "" for path in os.listdir(bypath): target = os.path.basename(os.readlink(bypath + '/' + path)) if target == deviceName: return path return "" class Device(object): """ A generic device. Device instances know which devices they depend upon (parents attribute). They do not know which devices depend upon them, but they do know whether or not they have any dependent devices (isleaf attribute). A Device's setup method should set up all parent devices as well as the device itself. It should not run the resident format's setup method. Which Device types rely on their parents' formats being active? DMCryptDevice A Device's teardown method should accept the keyword argument recursive, which takes a boolean value and indicates whether or not to recursively close parent devices. A Device's create method should create all parent devices as well as the device itself. It should also run the Device's setup method after creating the device. The create method should not create a device's resident format. Which device type rely on their parents' formats to be created before they can be created/assembled? VolumeGroup DMCryptDevice A Device's destroy method should destroy any resident format before destroying the device itself. """ # This is a counter for generating unique ids for Devices. _id = 0 _type = "generic device" _packages = [] def __init__(self, name, parents=None): """ Create a Device instance. Arguments: name -- the device name (generally a device node's basename) Keyword Arguments: parents -- a list of required Device instances """ self._name = name if parents is None: parents = [] elif not isinstance(parents, list): raise ValueError("parents must be a list of Device instances") self.parents = parents self.kids = 0 # Set this instance's id and increment the counter. self.id = Device._id Device._id += 1 for parent in self.parents: parent.addChild() def __deepcopy__(self, memo): """ Create a deep copy of a Device instance. We can't do copy.deepcopy on parted objects, which is okay. For these parted objects, we just do a shallow copy. """ new = self.__class__.__new__(self.__class__) memo[id(self)] = new shallow_copy_attrs = ('_partedDisk', '_partedDevice', '_partedPartition', '_origPartedDisk', '_raidSet') for (attr, value) in self.__dict__.items(): if attr in shallow_copy_attrs: setattr(new, attr, copy.copy(value)) else: setattr(new, attr, copy.deepcopy(value, memo)) return new def __str__(self): s = ("%(type)s instance (%(id)s) --\n" " name = %(name)s status = %(status)s" " parents = %(parents)s\n" " kids = %(kids)s\n" " id = %(dev_id)s\n" % {"type": self.__class__.__name__, "id": "%#x" % id(self), "name": self.name, "parents": self.parents, "kids": self.kids, "status": self.status, "dev_id": self.id}) return s def writeKS(self, f, preexisting=False, noformat=False, s=None): return def removeChild(self): log_method_call(self, name=self.name, kids=self.kids) self.kids -= 1 def addChild(self): log_method_call(self, name=self.name, kids=self.kids) self.kids += 1 def setup(self, intf=None): """ Open, or set up, a device. """ raise NotImplementedError("setup method not defined for Device") def teardown(self, recursive=None): """ Close, or tear down, a device. """ raise NotImplementedError("teardown method not defined for Device") def create(self, intf=None): """ Create the device. """ raise NotImplementedError("create method not defined for Device") def destroy(self): """ Destroy the device. """ raise NotImplementedError("destroy method not defined for Device") def setupParents(self): """ Run setup method of all parent devices. """ for parent in self.parents: parent.setup() def teardownParents(self, recursive=None): """ Run teardown method of all parent devices. """ for parent in self.parents: parent.teardown(recursive=recursive) def createParents(self): """ Run create method of all parent devices. """ log.info("NOTE: recursive device creation disabled") for parent in self.parents: if not parent.exists: raise DeviceError("parent device does not exist", self.path) #parent.create() def dependsOn(self, dep): """ Return True if this device depends on dep. """ # XXX does a device depend on itself? if dep in self.parents: return True for parent in self.parents: if parent.dependsOn(dep): return True return False def dracutSetupString(self): return "" @property def status(self): """ This device's status. For now, this should return a boolean: True the device is open and ready for use False the device is not open """ return False @property def name(self): """ This device's name. """ return self._name @property def isleaf(self): """ True if this device has no children. """ return self.kids == 0 @property def typeDescription(self): """ String describing the device type. """ return self._type @property def type(self): """ Device type. """ return self._type @property def packages(self): """ List of packages required to manage devices of this type. This list includes the packages required by this device's format type as well those required by all of its parent devices. """ packages = self._packages packages.extend(self.format.packages) for parent in self.parents: for package in parent.packages: if package not in packages: packages.append(package) for package in parent.format.packages: if package not in packages: packages.append(package) return packages @property def mediaPresent(self): return True class NetworkStorageDevice(object): """ Virtual base class for network backed storage devices """ def __init__(self, host_address=None, nic=None): """ Create a NetworkStorage Device instance. Note this class is only to be used as a baseclass and then only with multiple inheritance. The only correct use is: class MyStorageDevice(StorageDevice, NetworkStorageDevice): The sole purpose of this class is to: 1) Be able to check if a StorageDevice is network backed (using isinstance). 2) To be able to get the host address of the host (server) backing the storage *or* the NIC through which the storage is connected Arguments: host_address -- host address of the backing server nic -- nic to which the storage is bound """ self.host_address = host_address self.nic = nic class StorageDevice(Device): """ A generic storage device. A fully qualified path to the device node can be obtained via the path attribute, although it is not guaranteed to be useful, or even present, unless the StorageDevice's setup method has been run. StorageDevice instances can optionally contain a filesystem, represented by an FS instance. A StorageDevice's create method should create a filesystem if one has been specified. """ _type = "storage device" _devDir = "/dev" sysfsBlockDir = "class/block" _resizable = False def __init__(self, device, format=None, size=None, major=None, minor=None, sysfsPath='', parents=None, exists=None, serial=None): """ Create a StorageDevice instance. Arguments: device -- the device name (generally a device node's basename) Keyword Arguments: size -- the device's size (units/format TBD) major -- the device major minor -- the device minor sysfsPath -- sysfs device path format -- a DeviceFormat instance parents -- a list of required Device instances """ # allow specification of individual parents if isinstance(parents, Device): parents = [parents] Device.__init__(self, device, parents=parents) self.uuid = None self._format = None self._size = numeric_type(size) self.major = numeric_type(major) self.minor = numeric_type(minor) self.sysfsPath = sysfsPath self.exists = exists self.serial = serial self.protected = False # this may be handy for disk, dmraid, mpath, mdraid self.diskLabel = None self.format = format self.fstabComment = "" self._targetSize = self._size self._partedDevice = None @property def partedDevice(self): if self.exists and self.status and not self._partedDevice: log.debug("looking up parted Device: %s" % self.path) # We aren't guaranteed to be able to get a device. In # particular, built-in USB flash readers show up as devices but # do not always have any media present, so parted won't be able # to find a device. try: self._partedDevice = parted.Device(path=self.path) except _ped.DeviceException: pass return self._partedDevice def _getTargetSize(self): return self._targetSize def _setTargetSize(self, newsize): self._targetSize = newsize targetSize = property(lambda s: s._getTargetSize(), lambda s, v: s._setTargetSize(v), doc="Target size of this device") def __str__(self): s = Device.__str__(self) s += (" uuid = %(uuid)s format = %(format)r size = %(size)s\n" " major = %(major)s minor = %(minor)r exists = %(exists)s\n" " sysfs path = %(sysfs)s label = %(diskLabel)s\n" " target size = %(targetSize)s path = %(path)s\n" " format args = %(formatArgs)s" % {"uuid": self.uuid, "format": self.format, "size": self.size, "major": self.major, "minor": self.minor, "exists": self.exists, "sysfs": self.sysfsPath, "diskLabel": self.diskLabel, "targetSize": self.targetSize, "path": self.path, "formatArgs": self.formatArgs}) return s @property def path(self): """ Device node representing this device. """ return "%s/%s" % (self._devDir, self.name) def updateSysfsPath(self): """ Update this device's sysfs path. """ log_method_call(self, self.name, status=self.status) sysfsName = self.name.replace("/", "!") path = os.path.join("/sys", self.sysfsBlockDir, sysfsName) self.sysfsPath = os.path.realpath(path)[4:] log.debug("%s sysfsPath set to %s" % (self.name, self.sysfsPath)) @property def formatArgs(self): """ Device-specific arguments to format creation program. """ return [] @property def resizable(self): """ Can this type of device be resized? """ return self._resizable and self.exists def notifyKernel(self): """ Send a 'change' uevent to the kernel for this device. """ log_method_call(self, self.name, status=self.status) if not self.exists: log.debug("not sending change uevent for non-existent device") return if not self.status: log.debug("not sending change uevent for inactive device") return path = os.path.normpath("/sys/%s" % self.sysfsPath) try: notify_kernel(path, action="change") except Exception, e: log.warning("failed to notify kernel of change: %s" % e) @property def fstabSpec(self): spec = self.path if self.format and self.format.uuid: spec = "UUID=%s" % self.format.uuid return spec def resize(self, intf=None): """ Resize the device. New size should already be set. """ raise NotImplementedError("resize method not defined for StorageDevice") def setup(self, intf=None): """ Open, or set up, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) self.setupParents() for parent in self.parents: parent.format.setup() def teardown(self, recursive=None): """ Close, or tear down, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists and not recursive: raise DeviceError("device has not been created", self.path) if self.status and self.format.exists: self.format.teardown() udev_settle(timeout=10) if recursive: self.teardownParents(recursive=recursive) def _getSize(self): """ Get the device's size in MB, accounting for pending changes. """ if self.exists and not self.mediaPresent: return 0 if self.exists and self.partedDevice: self._size = self.currentSize size = self._size if self.exists and self.resizable and self.targetSize != size: size = self.targetSize return size def _setSize(self, newsize): """ Set the device's size to a new value. """ if newsize > self.maxSize: raise DeviceError("device cannot be larger than %s MB" % (self.maxSize(),), self.path) self._size = newsize size = property(lambda x: x._getSize(), lambda x, y: x._setSize(y), doc="The device's size in MB, accounting for pending changes") @property def currentSize(self): """ The device's actual size. """ size = 0 if self.exists and self.partedDevice: size = self.partedDevice.getSize() elif self.exists: size = self._size return size @property def minSize(self): """ The minimum size this device can be. """ if self.format.minSize: return self.format.minSize else: return self.size @property def maxSize(self): """ The maximum size this device can be. """ if self.format.maxSize > self.currentSize: return self.currentSize else: return self.format.maxSize @property def status(self): """ This device's status. For now, this should return a boolean: True the device is open and ready for use False the device is not open """ if not self.exists: return False return os.access(self.path, os.W_OK) def _setFormat(self, format): """ Set the Device's format. """ if not format: format = getFormat(None, device=self.path, exists=self.exists) log_method_call(self, self.name, type=format.type, current=getattr(self._format, "type", None)) if self._format and self._format.status: # FIXME: self.format.status doesn't mean much raise DeviceError("cannot replace active format", self.path) self._format = format def _getFormat(self): return self._format format = property(lambda d: d._getFormat(), lambda d,f: d._setFormat(f), doc="The device's formatting.") def create(self, intf=None): """ Create the device. """ log_method_call(self, self.name, status=self.status) if self.exists: raise DeviceError("device has already been created", self.path) self.createParents() self.setupParents() self.exists = True self.setup() def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if not self.isleaf: raise DeviceError("Cannot destroy non-leaf device", self.path) self.exists = False # we already did this in DeviceTree._removeDevice #for parent in self.parents: # parent.removeChild() @property def removable(self): devpath = os.path.normpath("/sys/%s" % self.sysfsPath) remfile = os.path.normpath("%s/removable" % devpath) return (self.sysfsPath and os.path.exists(devpath) and os.access(remfile, os.R_OK) and open(remfile).readline().strip() == "1") class DiskDevice(StorageDevice): """ A disk """ _type = "disk" def __init__(self, device, format=None, size=None, major=None, minor=None, sysfsPath='', \ parents=None, initcb=None, initlabel=None): """ Create a DiskDevice instance. Arguments: device -- the device name (generally a device node's basename) Keyword Arguments: size -- the device's size (units/format TBD) major -- the device major minor -- the device minor sysfsPath -- sysfs device path format -- a DeviceFormat instance parents -- a list of required Device instances removable -- whether or not this is a removable device initcb -- the call back to be used when initiating disk. initlabel -- whether to start with a fresh disklabel DiskDevices always exist. """ StorageDevice.__init__(self, device, format=format, size=size, major=major, minor=minor, exists=True, sysfsPath=sysfsPath, parents=parents) self._partedDisk = None self._initlabel = initlabel self._initcb = initcb # We save the actual state of the disk here. Before the first # modification (addPartition or removePartition) to the partition # table we reset self.partedPartition to this state so we can # perform the modifications one at a time. if self.partedDisk: self._origPartedDisk = self.partedDisk.duplicate() else: self._origPartedDisk = None @property def partedDisk(self): if self._partedDisk: return self._partedDisk log.debug("looking up parted Device: %s" % self.path) if self.partedDevice: log.debug("creating parted Disk: %s" % self.path) if self._initlabel: self._partedDisk = self.freshPartedDisk() else: try: self._partedDisk = parted.Disk(device=self.partedDevice) except _ped.DiskLabelException: # if we have a cb function use it. else an error. if self._initcb is not None and self._initcb(): self._partedDisk = parted.freshDisk( \ device=self.partedDevice, \ ty = platform.getPlatform(None).diskType) else: raise DeviceUserDeniedFormatError("User prefered to not format.") # When the device has no partition table but it has a FS, it # will be created with label type loop. Treat the same as if # the device had no label (cause it really doesn't). if self._partedDisk.type == "loop": if self._initcb is not None and self._initcb(): self._partedDisk = parted.freshDisk( \ device=self.partedDevice, \ ty = platform.getPlatform(None).diskType) else: raise DeviceUserDeniedFormatError("User prefered to not format.") return self._partedDisk def __str__(self): s = StorageDevice.__str__(self) s += (" removable = %(removable)s partedDevice = %(partedDevice)r\n" " partedDisk = %(partedDisk)r" % {"removable": self.removable, "partedDisk": self.partedDisk, "partedDevice": self.partedDevice}) return s def freshPartedDisk(self): log_method_call(self, self.name) labelType = platform.getPlatform(None).diskType return parted.freshDisk(device=self.partedDevice, ty=labelType) @property def mediaPresent(self): return self.partedDevice is not None @property def model(self): return getattr(self.partedDevice, "model", None) @property def description(self): return self.model @property def size(self): """ The disk's size in MB """ return super(DiskDevice, self).size #size = property(StorageDevice._getSize) def resetPartedDisk(self): """ Reset parted.Disk to reflect the actual layout of the disk. """ log_method_call(self, self.name) self._partedDisk = self._origPartedDisk def removePartition(self, device): log_method_call(self, self.name, part=device.name) if not self.mediaPresent: raise DeviceError("cannot remove partition from disk %s which has no media" % self.name, self.path) partition = self.partedDisk.getPartitionByPath(device.path) if partition: self.partedDisk.removePartition(partition) def addPartition(self, device): log_method_call(self, self.name, part=device.name) if not self.mediaPresent: raise DeviceError("cannot add partition to disk with no media", self.path) for part in self.partedDisk.partitions: log.debug("disk %s: partition %s has geom %s" % (self.name, part.getDeviceNodeName(), part.geometry)) geometry = device.partedPartition.geometry constraint = parted.Constraint(exactGeom=geometry) partition = parted.Partition(disk=self.partedDisk, type=device.partedPartition.type, geometry=geometry) self.partedDisk.addPartition(partition, constraint=constraint) def probe(self): """ Probe for any missing information about this device. pyparted should be able to tell us anything we want to know. size, disklabel type, maybe even partition layout """ log_method_call(self, self.name, size=self.size, partedDevice=self.partedDevice) if not self.diskLabel: log.debug("setting %s diskLabel to %s" % (self.name, self.partedDisk.type)) self.diskLabel = self.partedDisk.type def commit(self, intf=None): """ Commit changes to the device. """ log_method_call(self, self.name, status=self.status) if not self.mediaPresent: raise DeviceError("cannot commit to disk with no media", self.path) self.setupParents() self.setup() # give committing 5 tries, failing that, raise an exception attempt = 1 maxTries = 5 keepTrying = True while keepTrying and (attempt <= maxTries): try: self.partedDisk.commit() keepTrying = False except parted.DiskException as msg: log.warning(msg) attempt += 1 if keepTrying: raise DeviceError("cannot commit to disk after %d attempts" % (maxTries,), self.path) # commit makes the kernel re-scan the partition table udev_settle() def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status) if not self.mediaPresent: raise DeviceError("cannot destroy disk with no media", self.path) self.partedDisk.deleteAllPartitions() # this is perhaps a separate operation (wiping the disklabel) self.partedDisk.clobber() self.partedDisk.commit() self.teardown() def setup(self, intf=None): """ Open, or set up, a device. """ log_method_call(self, self.name, status=self.status) if not os.path.exists(self.path): raise DeviceError("device does not exist", self.path) class PartitionDevice(StorageDevice): """ A disk partition. On types and flags... We don't need to deal with numerical partition types at all. The only type we are concerned with is primary/logical/extended. Usage specification is accomplished through the use of flags, which we will set according to the partition's format. """ _type = "partition" _resizable = True def __init__(self, name, format=None, size=None, grow=False, maxsize=None, major=None, minor=None, bootable=None, sysfsPath='', parents=None, exists=None, partType=None, primary=False, weight=0): """ Create a PartitionDevice instance. Arguments: name -- the device name (generally a device node's basename) Keyword Arguments: exists -- indicates whether this is an existing device format -- the device's format (DeviceFormat instance) For existing partitions: parents -- the disk that contains this partition major -- the device major minor -- the device minor sysfsPath -- sysfs device path For new partitions: partType -- primary,extended,&c (as parted constant) grow -- whether or not to grow the partition maxsize -- max size for growable partitions (in MB) size -- the device's size (in MB) bootable -- whether the partition is bootable parents -- a list of potential containing disks weight -- an initial sorting weight to assign """ self.req_disks = [] self.req_partType = None self.req_primary = None self.req_grow = None self.req_bootable = None self.req_size = 0 self.req_base_size = 0 self.req_max_size = 0 self.req_base_weight = 0 self._bootable = False StorageDevice.__init__(self, name, format=format, size=size, major=major, minor=minor, exists=exists, sysfsPath=sysfsPath, parents=parents) if not exists: # this is a request, not a partition -- it has no parents self.req_disks = self.parents[:] for dev in self.parents: dev.removeChild() self.parents = [] # FIXME: Validate partType, but only if this is a new partition # Otherwise, overwrite it with the partition's type. self._partType = None self.partedFlags = {} self._partedPartition = None # FIXME: Validate size, but only if this is a new partition. # For existing partitions we will get the size from # parted. if self.exists: log.debug("looking up parted Partition: %s" % self.path) #self.partedPartition = parted.getPartitionByName(self.path) self._partedPartition = self.disk.partedDisk.getPartitionByPath(self.path) if not self._partedPartition: raise DeviceError("cannot find parted partition instance", self.path) # collect information about the partition from parted self.probe() if self.getFlag(parted.PARTITION_PREP): # the only way to identify a PPC PReP Boot partition is to # check the partition type/flags, so do it here. self.format = getFormat("prepboot", device=self.path, exists=True) else: # XXX It might be worthwhile to create a shit-simple # PartitionRequest class and pass one to this constructor # for new partitions. self.req_name = name self.req_partType = partType self.req_primary = primary self.req_max_size = numeric_type(maxsize) self.req_grow = grow self.req_bootable = bootable # req_size may be manipulated in the course of partitioning self.req_size = self._size # req_base_size will always remain constant self.req_base_size = self._size self.req_base_weight = weight def __str__(self): s = StorageDevice.__str__(self) s += (" grow = %(grow)s max size = %(maxsize)s bootable = %(bootable)s\n" " part type = %(partType)s primary = %(primary)s\n" " partedPartition = %(partedPart)r disk = %(disk)r" % {"grow": self.req_grow, "maxsize": self.req_max_size, "bootable": self.bootable, "partType": self.partType, "primary": self.req_primary, "partedPart": self.partedPartition, "disk": self.disk}) return s def writeKS(self, f, preexisting=False, noformat=False, s=None): args = [] if self.isExtended: return if self.req_grow: args.append("--grow") if self.req_max_size: args.append("--maxsize=%s" % self.req_max_size) if self.req_primary: args.append("--asprimary") if self.req_size: args.append("--size=%s" % (self.req_size or 1)) if preexisting: if len(self.req_disks) == 1: args.append("--ondisk=%s" % self.req_disks[0].name) else: args.append("--onpart=%s" % self.name) if noformat: args.append("--noformat") f.write("#part ") self.format.writeKS(f) f.write(" %s" % " ".join(args)) if s: f.write(" %s" % s) def _setTargetSize(self, newsize): if newsize != self.currentSize: # change this partition's geometry in-memory so that other # partitioning operations can complete (e.g., autopart) self._targetSize = newsize disk = self.disk.partedDisk # resize the partition's geometry in memory (constraint, geometry) = self._computeResize(self.partedPartition) disk.setPartitionGeometry(partition=self.partedPartition, constraint=constraint, start=geometry.start, end=geometry.end) @property def path(self): """ Device node representing this device. """ if not self.parents: # Bogus, but code in various places compares devices by path # So we must return something unique return self.name return "%s/%s" % (self.parents[0]._devDir, self.name) @property def partType(self): """ Get the partition's type (as parted constant). """ try: ptype = self.partedPartition.type except AttributeError: ptype = self._partType if not self.exists and ptype is None: ptype = self.req_partType return ptype @property def isExtended(self): return (self.partType is not None and self.partType & parted.PARTITION_EXTENDED) @property def isLogical(self): return (self.partType is not None and self.partType & parted.PARTITION_LOGICAL) @property def isPrimary(self): return (self.partType is not None and self.partType == parted.PARTITION_NORMAL) @property def isProtected(self): return (self.partType is not None and self.partType & parted.PARTITION_PROTECTED) def _getPartedPartition(self): return self._partedPartition def _setPartedPartition(self, partition): """ Set this PartitionDevice's parted Partition instance. """ log_method_call(self, self.name) if partition is None: path = None elif isinstance(partition, parted.Partition): path = partition.path else: raise ValueError("partition must be a parted.Partition instance") log.debug("device %s new partedPartition %s has path %s" % (self.name, partition, path)) self._partedPartition = partition self.updateName() partedPartition = property(lambda d: d._getPartedPartition(), lambda d,p: d._setPartedPartition(p)) def _getWeight(self): return self.req_base_weight def _setWeight(self, weight): self.req_base_weight = weight weight = property(lambda d: d._getWeight(), lambda d,w: d._setWeight(w)) def updateSysfsPath(self): """ Update this device's sysfs path. """ log_method_call(self, self.name, status=self.status) if not self.parents: self.sysfsPath = '' elif self.parents[0]._devDir == "/dev/mapper": dm_node = dm.dm_node_from_name(self.name) path = os.path.join("/sys", self.sysfsBlockDir, dm_node) self.sysfsPath = os.path.realpath(path)[4:] else: StorageDevice.updateSysfsPath(self) def updateName(self): if self.partedPartition is None: self._name = self.req_name else: self._name = \ devicePathToName(self.partedPartition.getDeviceNodeName()) def dependsOn(self, dep): """ Return True if this device depends on dep. """ if isinstance(dep, PartitionDevice) and dep.isExtended and \ self.isLogical and self.disk == dep.disk: return True return Device.dependsOn(self, dep) def _setFormat(self, format): """ Set the Device's format. """ log_method_call(self, self.name) StorageDevice._setFormat(self, format) def _setBootable(self, bootable): """ Set the bootable flag for this partition. """ if self.partedPartition: if iutil.isS390(): return if self.flagAvailable(parted.PARTITION_BOOT): if bootable: self.setFlag(parted.PARTITION_BOOT) else: self.unsetFlag(parted.PARTITION_BOOT) else: raise DeviceError("boot flag not available for this partition", self.path) self._bootable = bootable else: self.req_bootable = bootable def _getBootable(self): return self._bootable or self.req_bootable bootable = property(_getBootable, _setBootable) def flagAvailable(self, flag): log_method_call(self, path=self.path, flag=flag, part=self.partedPartition) if not self.partedPartition: return return self.partedPartition.isFlagAvailable(flag) def getFlag(self, flag): log_method_call(self, path=self.path, flag=flag, part=self.partedPartition) if not self.partedPartition or not self.flagAvailable(flag): return return self.partedPartition.getFlag(flag) def setFlag(self, flag): log_method_call(self, path=self.path, flag=flag, part=self.partedPartition) if not self.partedPartition or not self.flagAvailable(flag): return self.partedPartition.setFlag(flag) def unsetFlag(self, flag): log_method_call(self, path=self.path, flag=flag, part=self.partedPartition) if not self.partedPartition or not self.flagAvailable(flag): return self.partedPartition.unsetFlag(flag) def probe(self): """ Probe for any missing information about this device. size, partition type, flags """ log_method_call(self, self.name, exists=self.exists) if not self.exists: return # this is in MB self._size = self.partedPartition.getSize() self.targetSize = self._size self._partType = self.partedPartition.type self._bootable = self.getFlag(parted.PARTITION_BOOT) def create(self, intf=None): """ Create the device. """ log_method_call(self, self.name, status=self.status) if self.exists: raise DeviceError("device already exists", self.path) self.createParents() self.setupParents() self.disk.addPartition(self) self.disk.commit() # Ensure old metadata which lived in freespace so did not get # explictly destroyed by a destroyformat action gets wiped DeviceFormat(device=self.path, exists=True).destroy() self.partedPartition = self.disk.partedDisk.getPartitionByPath(self.path) self.exists = True self.setup() def _computeResize(self, partition): log_method_call(self, self.name, status=self.status) # compute new size for partition currentGeom = partition.geometry currentDev = currentGeom.device newLen = long(self.targetSize * 1024 * 1024) / currentDev.sectorSize newGeometry = parted.Geometry(device=currentDev, start=currentGeom.start, length=newLen) constraint = parted.Constraint(exactGeom=newGeometry) return (constraint, newGeometry) def resize(self, intf=None): """ Resize the device. self.targetSize must be set to the new size. """ log_method_call(self, self.name, status=self.status) if self.targetSize != self.currentSize: # partedDisk has been restored to _origPartedDisk, so # recalculate resize geometry because we may have new # partitions on the disk, which could change constraints partition = self.disk.partedDisk.getPartitionByPath(self.path) (constraint, geometry) = self._computeResize(partition) self.disk.partedDisk.setPartitionGeometry(partition=partition, constraint=constraint, start=geometry.start, end=geometry.end) self.disk.commit() self.notifyKernel() def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if not self.sysfsPath: return if not self.isleaf: raise DeviceError("Cannot destroy non-leaf device", self.path) self.setupParents() self.disk.removePartition(self) self.disk.commit() self.exists = False def _getSize(self): """ Get the device's size. """ size = self._size if self.partedPartition: # this defaults to MB size = self.partedPartition.getSize() return size def _setSize(self, newsize): """ Set the device's size (for resize, not creation). Arguments: newsize -- the new size (in MB) """ log_method_call(self, self.name, status=self.status, size=self._size, newsize=newsize) if not self.exists: raise DeviceError("device does not exist", self.path) if newsize > self.disk.size: raise ValueError("partition size would exceed disk size") # this defaults to MB maxAvailableSize = self.partedPartition.getMaxAvailableSize() if newsize > maxAvailableSize: raise ValueError("new size is greater than available space") # now convert the size to sectors and update the geometry geometry = self.partedPartition.geometry physicalSectorSize = geometry.device.physicalSectorSize new_length = (newsize * (1024 * 1024)) / physicalSectorSize geometry.length = new_length def _getDisk(self): """ The disk that contains this partition.""" try: disk = self.parents[0] except IndexError: disk = None return disk def _setDisk(self, disk): """Change the parent. Setting up a disk is not trivial. It has the potential to change the underlying object. If necessary we must also change this object. """ log_method_call(self, self.name, old=self.disk, new=disk) if self.disk: self.disk.removeChild() if disk: self.parents = [disk] disk.addChild() else: self.parents = [] disk = property(lambda p: p._getDisk(), lambda p,d: p._setDisk(d)) @property def maxSize(self): """ The maximum size this partition can be. """ # XXX: this is MB by default maxPartSize = self.partedPartition.getMaxAvailableSize() if self.format.maxSize > maxPartSize: return maxPartSize else: return self.format.maxSize class DMDevice(StorageDevice): """ A device-mapper device """ _type = "dm" _devDir = "/dev/mapper" def __init__(self, name, format=None, size=None, dmUuid=None, target=None, exists=None, parents=None, sysfsPath=''): """ Create a DMDevice instance. Arguments: name -- the device name (generally a device node's basename) Keyword Arguments: target -- the device-mapper target type (string) size -- the device's size (units/format TBD) dmUuid -- the device's device-mapper UUID sysfsPath -- sysfs device path format -- a DeviceFormat instance parents -- a list of required Device instances exists -- indicates whether this is an existing device """ StorageDevice.__init__(self, name, format=format, size=size, exists=exists, parents=parents, sysfsPath=sysfsPath) self.target = target self.dmUuid = dmUuid def __str__(self): s = StorageDevice.__str__(self) s += (" target = %(target)s dmUuid = %(dmUuid)s" % {"target": self.target, "dmUuid": self.dmUuid}) return s @property def fstabSpec(self): """ Return the device specifier for use in /etc/fstab. """ return self.path def updateSysfsPath(self): """ Update this device's sysfs path. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if self.status: dm_node = self.getDMNode() path = os.path.join("/sys", self.sysfsBlockDir, dm_node) self.sysfsPath = os.path.realpath(path)[4:] else: self.sysfsPath = '' #def getTargetType(self): # return dm.getDmTarget(name=self.name) def getDMNode(self): """ Return the dm-X (eg: dm-0) device node for this device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) return dm.dm_node_from_name(self.name) def _setName(self, name): """ Set the device's map name. """ log_method_call(self, self.name, status=self.status) if self.status: raise DeviceError("cannot rename active device", self.path) self._name = name #self.sysfsPath = "/dev/disk/by-id/dm-name-%s" % self.name name = property(lambda d: d._name, lambda d,n: d._setName(n)) class DMCryptDevice(DMDevice): """ A dm-crypt device """ _type = "dm-crypt" def __init__(self, name, format=None, size=None, uuid=None, exists=None, sysfsPath='', parents=None): """ Create a DMCryptDevice instance. Arguments: name -- the device name (generally a device node's basename) Keyword Arguments: size -- the device's size (units/format TBD) sysfsPath -- sysfs device path format -- a DeviceFormat instance parents -- a list of required Device instances exists -- indicates whether this is an existing device """ DMDevice.__init__(self, name, format=format, size=size, parents=parents, sysfsPath=sysfsPath, exists=exists, target="crypt") class LUKSDevice(DMCryptDevice): """ A mapped LUKS device. """ _type = "luks/dm-crypt" def __init__(self, name, format=None, size=None, uuid=None, exists=None, sysfsPath='', parents=None): """ Create a LUKSDevice instance. Arguments: name -- the device name Keyword Arguments: size -- the device's size in MB uuid -- the device's UUID sysfsPath -- sysfs device path format -- a DeviceFormat instance parents -- a list of required Device instances exists -- indicates whether this is an existing device """ DMCryptDevice.__init__(self, name, format=format, size=size, parents=parents, sysfsPath=sysfsPath, uuid=None, exists=exists) def writeKS(self, f, preexisting=False, noformat=False, s=None): self.slave.writeKS(f, preexisting=preexisting, noformat=noformat, s=s) self.format.writeKS(f) if s: f.write(" %s" % s) @property def size(self): if not self.exists or not self.partedDevice: # the LUKS header takes up 4040 512-byte sectors w/ a 512-bit key size = float(self.slave.size) - ((4040 * 2.0) / 1024) else: size = self.partedDevice.getSize() return size def create(self, intf=None): """ Create the device. """ log_method_call(self, self.name, status=self.status) if self.exists: raise DeviceError("device already exists", self.path) self.createParents() self.setupParents() #if not self.slave.format.exists: # self.slave.format.create() self._name = self.slave.format.mapName self.exists = True self.setup() def setup(self, intf=None): """ Open, or set up, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) self.slave.setup() self.slave.format.setup() # we always probe since the device may not be set up when we want # information about it self._size = self.currentSize def teardown(self, recursive=False): """ Close, or tear down, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists and not recursive: raise DeviceError("device has not been created", self.path) if self.status and self.format.exists: self.format.teardown() udev_settle(timeout=10) if self.slave.format.exists: self.slave.format.teardown() udev_settle(timeout=10) if recursive: self.teardownParents(recursive=recursive) def destroy(self): log_method_call(self, self.name, status=self.status) self.format.teardown() udev_settle(timeout=10) self.teardown() @property def slave(self): """ This device's backing device. """ return self.parents[0] class LVMVolumeGroupDevice(DMDevice): """ An LVM Volume Group XXX Maybe this should inherit from StorageDevice instead of DMDevice since there's no actual device. """ _type = "lvmvg" def __init__(self, name, parents, size=None, free=None, peSize=None, peCount=None, peFree=None, pvCount=None, lvNames=[], uuid=None, exists=None, sysfsPath=''): """ Create a LVMVolumeGroupDevice instance. Arguments: name -- the device name (generally a device node's basename) parents -- a list of physical volumes (StorageDevice) Keyword Arguments: peSize -- physical extent size (in MB) exists -- indicates whether this is an existing device sysfsPath -- sysfs device path For existing VG's only: size -- the VG's size (in MB) free -- amount of free space in the VG peFree -- number of free extents peCount -- total number of extents pvCount -- number of PVs in this VG lvNames -- the names of this VG's LVs uuid -- the VG's UUID """ self.pvClass = get_device_format_class("lvmpv") if not self.pvClass: raise StorageError("cannot find 'lvmpv' class") if isinstance(parents, list): for dev in parents: if not isinstance(dev.format, self.pvClass): raise ValueError("constructor requires a list of PVs") elif not isinstance(parents.format, self.pvClass): raise ValueError("constructor requires a list of PVs") DMDevice.__init__(self, name, parents=parents, exists=exists, sysfsPath=sysfsPath) self.uuid = uuid self.free = numeric_type(free) self.peSize = numeric_type(peSize) self.peCount = numeric_type(peCount) self.peFree = numeric_type(peFree) self.pvCount = numeric_type(pvCount) self.lvNames = lvNames # circular references, here I come self._lvs = [] # TODO: validate peSize if given if not self.peSize: self.peSize = 4.0 # MB #self.probe() def __str__(self): s = DMDevice.__str__(self) s += (" free = %(free)s PE Size = %(peSize)s PE Count = %(peCount)s\n" " PE Free = %(peFree)s PV Count = %(pvCount)s\n" " LV Names = %(lvNames)s modified = %(modified)s\n" " extents = %(extents)s free space = %(freeSpace)s\n" " free extents = %(freeExtents)s\n" " PVs = %(pvs)s\n" " LVs = %(lvs)s" % {"free": self.free, "peSize": self.peSize, "peCount": self.peCount, "peFree": self.peFree, "pvCount": self.pvCount, "lvNames": self.lvNames, "modified": self.isModified, "extents": self.extents, "freeSpace": self.freeSpace, "freeExtents": self.freeExtents, "pvs": self.pvs, "lvs": self.lvs}) return s def writeKS(self, f, preexisting=False, noformat=False, s=None): args = ["--pesize=%s" % int(self.peSize * 1024)] pvs = [] for pv in self.pvs: pvs.append("pv.%s" % pv.format.uuid) if preexisting: args.append("--useexisting") if noformat: args.append("--noformat") f.write("#volgroup %s %s %s" % (self.name, " ".join(args), " ".join(pvs))) if s: f.write(" %s" % s) def probe(self): """ Probe for any information about this device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) @property def path(self): """ Device node representing this device. """ # Thank you lvm for this lovely hack. return "%s/%s" % (self._devDir, self.name.replace("-","--")) def getDMNode(self): """ Return the dm-X (eg: dm-0) device node for this device. """ # Thank you lvm for this lovely hack. log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) return dm.dm_node_from_name(self.name.replace("-","--")) @property def status(self): """ The device's status (True means active). """ if not self.exists: return False # certainly if any of this VG's LVs are active then so are we for lv in self.lvs: if lv.status: return True # if any of our PVs are not active then we cannot be for pv in self.pvs: if not pv.status: return False # if we are missing some of our PVs we cannot be active if len(self.pvs) != self.pvCount: return False return True def _addDevice(self, device): """ Add a new physical volume device to the volume group. XXX This is for use by device probing routines and is not intended for modification of the VG. """ log_method_call(self, self.name, device=device.name, status=self.status) if not self.exists: raise DeviceError("device does not exist", self.path) if not isinstance(device.format, self.pvClass): raise ValueError("addDevice requires a PV arg") if self.uuid and device.format.vgUuid != self.uuid: raise ValueError("UUID mismatch") if device in self.pvs: raise ValueError("device is already a member of this VG") self.parents.append(device) device.addChild() # now see if the VG can be activated if len(self.parents) == self.pvCount: self.setup() def _removeDevice(self, device): """ Remove a physical volume from the volume group. This is for cases like clearing of preexisting partitions. """ log_method_call(self, self.name, device=device.name, status=self.status) try: self.parents.remove(device) except ValueError, e: raise ValueError("cannot remove non-member PV device from VG") device.removeChild() def setup(self, intf=None): """ Open, or set up, a device. XXX we don't do anything like "vgchange -ay" because we don't want all of the LVs activated, just the VG itself. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if self.status: return if len(self.parents) < self.pvCount: raise DeviceError("cannot activate VG with missing PV(s)", self.path) self.setupParents() def teardown(self, recursive=None): """ Close, or tear down, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists and not recursive: raise DeviceError("device has not been created", self.path) if self.status: lvm.vgdeactivate(self.name) if recursive: self.teardownParents(recursive=recursive) def create(self, intf=None): """ Create the device. """ log_method_call(self, self.name, status=self.status) if self.exists: raise DeviceError("device already exists", self.path) pv_list = [] #for pv in self.parents: # This is a little bit different from other devices in that # for VG we need the PVs to be formatted before we can create # the VG. # pv.create() # pv.format.create() # pv_list.append(pv.path) pv_list = [pv.path for pv in self.parents] self.createParents() self.setupParents() lvm.vgcreate(self.name, pv_list, self.peSize) # FIXME set / update self.uuid here self.exists = True self.setup() def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) # set up the pvs since lvm needs access to them to do the vgremove self.setupParents() # this sometimes fails for some reason. try: lvm.vgreduce(self.name, [], rm=True) lvm.vgremove(self.name) except lvm.LVMError: raise DeviceError("Could not completely remove VG", self.path) finally: self.notifyKernel() self.exists = False def reduce(self, pv_list): """ Remove the listed PVs from the VG. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) lvm.vgreduce(self.name, pv_list) # XXX do we need to notify the kernel? def _addLogVol(self, lv): """ Add an LV to this VG. """ if lv in self._lvs: raise ValueError("lv is already part of this vg") # verify we have the space, then add it # do not verify for growing vg (because of ks) if not lv.exists and \ not [pv for pv in self.pvs if getattr(pv, "req_grow", None)] and \ lv.size > self.freeSpace: raise DeviceError("new lv is too large to fit in free space", self.path) self._lvs.append(lv) def _removeLogVol(self, lv): """ Remove an LV from this VG. """ if lv not in self.lvs: raise ValueError("specified lv is not part of this vg") self._lvs.remove(lv) def _addPV(self, pv): """ Add a PV to this VG. """ if pv in self.pvs: raise ValueError("pv is already part of this vg") # for the time being we will not allow vgextend if self.exists: raise DeviceError("cannot add pv to existing vg", self.path) self.parents.append(pv) pv.addChild() def _removePV(self, pv): """ Remove an PV from this VG. """ if not pv in self.pvs: raise ValueError("specified pv is not part of this vg") # for the time being we will not allow vgreduce if self.exists: raise DeviceError("cannot remove pv from existing vg", self.path) self.parents.remove(pv) pv.removeChild() # We can't rely on lvm to tell us about our size, free space, &c # since we could have modifications queued, unless the VG and all of # its PVs already exist. # # -- liblvm may contain support for in-memory devices @property def isModified(self): """ Return True if the VG has changes queued that LVM is unaware of. """ modified = True if self.exists and not filter(lambda d: not d.exists, self.pvs): modified = False return modified @property def size(self): """ The size of this VG """ # TODO: just ask lvm if isModified returns False # sum up the sizes of the PVs and align to pesize size = 0 for pv in self.pvs: size += max(0, self.align(pv.size - pv.format.peStart)) return size @property def extents(self): """ Number of extents in this VG """ # TODO: just ask lvm if isModified returns False return self.size / self.peSize @property def freeSpace(self): """ The amount of free space in this VG (in MB). """ # TODO: just ask lvm if isModified returns False # total the sizes of any LVs used = 0 size = self.size log.debug("%s size is %dMB" % (self.name, size)) for lv in self.lvs: log.debug("lv %s (%s) uses %dMB" % (lv.name, lv, lv.size)) used += self.align(lv.size, roundup=True) free = self.size - used log.debug("vg %s has %dMB free" % (self.name, free)) return free @property def freeExtents(self): """ The number of free extents in this VG. """ # TODO: just ask lvm if isModified returns False return self.freeSpace / self.peSize def align(self, size, roundup=None): """ Align a size to a multiple of physical extent size. """ size = numeric_type(size) if roundup: round = math.ceil else: round = math.floor # we want Kbytes as a float for our math size *= 1024.0 pesize = self.peSize * 1024.0 return long((round(size / pesize) * pesize) / 1024) @property def pvs(self): """ A list of this VG's PVs """ return self.parents[:] # we don't want folks changing our list @property def lvs(self): """ A list of this VG's LVs """ return self._lvs[:] # we don't want folks changing our list @property def complete(self): """Check if the vg has all its pvs in the system Return True if complete. """ return len(self.pvs) == self.pvCount or not self.exists class LVMLogicalVolumeDevice(DMDevice): """ An LVM Logical Volume """ _type = "lvmlv" _resizable = True def __init__(self, name, vgdev, size=None, uuid=None, format=None, exists=None, sysfsPath='', grow=None, maxsize=None, percent=None): """ Create a LVMLogicalVolumeDevice instance. Arguments: name -- the device name (generally a device node's basename) vgdev -- volume group (LVMVolumeGroupDevice instance) Keyword Arguments: size -- the device's size (in MB) uuid -- the device's UUID sysfsPath -- sysfs device path format -- a DeviceFormat instance exists -- indicates whether this is an existing device For new (non-existent) LVs only: grow -- whether to grow this LV maxsize -- maximum size for growable LV (in MB) percent -- percent of VG space to take """ if isinstance(vgdev, list): if len(vgdev) != 1: raise ValueError("constructor requires a single LVMVolumeGroupDevice instance") elif not isinstance(vgdev[0], LVMVolumeGroupDevice): raise ValueError("constructor requires a LVMVolumeGroupDevice instance") elif not isinstance(vgdev, LVMVolumeGroupDevice): raise ValueError("constructor requires a LVMVolumeGroupDevice instance") DMDevice.__init__(self, name, size=size, format=format, sysfsPath=sysfsPath, parents=vgdev, exists=exists) self.uuid = uuid self.req_grow = None self.req_max_size = 0 self.req_size = 0 self.req_percent = 0 if not self.exists: self.req_grow = grow self.req_max_size = numeric_type(maxsize) # XXX should we enforce that req_size be pe-aligned? self.req_size = self._size self.req_percent = numeric_type(percent) # here we go with the circular references self.vg._addLogVol(self) def __str__(self): s = DMDevice.__str__(self) s += (" VG device = %(vgdev)r percent = %(percent)s" % {"vgdev": self.vg, "percent": self.req_percent}) return s def writeKS(self, f, preexisting=False, noformat=False, s=None): args = ["--name=%s" % self.lvname, "--vgname=%s" % self.vg.name] if self.req_grow: args.extend(["--grow", "--size=%s" % (self.req_size or 1)]) if self.req_max_size > 0: args.append("--maxsize=%s" % self.req_max_size) else: if self.req_percent > 0: args.append("--percent=%s" % self.req_percent) elif self.req_size > 0: args.append("--size=%s" % self.req_size) if preexisting: args.append("--useexisting") if noformat: args.append("--noformat") f.write("#logvol ") self.format.writeKS(f) f.write(" %s" % " ".join(args)) if s: f.write(" %s" % s) def _setSize(self, size): size = self.vg.align(numeric_type(size)) log.debug("trying to set lv %s size to %dMB" % (self.name, size)) if size <= (self.vg.freeSpace + self._size): self._size = size self.targetSize = size else: log.debug("failed to set size: %dMB short" % (size - (self.vg.freeSpace + self._size),)) raise ValueError("not enough free space in volume group") size = property(StorageDevice._getSize, _setSize) @property def vg(self): """ This Logical Volume's Volume Group. """ return self.parents[0] @property def path(self): """ Device node representing this device. """ # Thank you lvm for this lovely hack. return "%s/%s-%s" % (self._devDir, self.vg.name.replace("-","--"), self._name.replace("-","--")) def getDMNode(self): """ Return the dm-X (eg: dm-0) device node for this device. """ # Thank you lvm for this lovely hack. log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) return dm.dm_node_from_name("%s-%s" % (self.vg.name.replace("-","--"), \ self._name.replace("-","--"))) @property def name(self): """ This device's name. """ return "%s-%s" % (self.vg.name, self._name) @property def lvname(self): """ The LV's name (not including VG name). """ return self._name @property def complete(self): """ Test if vg exits and if it has all pvs. """ return self.vg.complete @property def status(self): """ True if the LV is active, False otherwise. """ try: lvstatus = lvm.lvs(self.vg.name) except lvm.LVMError: return False try: if lvstatus[self._name]['attr'].find('a') == -1: return False else: return True except KeyError: return False def setup(self, intf=None): """ Open, or set up, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if self.status: return self.vg.setup() lvm.lvactivate(self.vg.name, self._name) # we always probe since the device may not be set up when we want # information about it self._size = self.currentSize def teardown(self, recursive=None): """ Close, or tear down, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists and not recursive: raise DeviceError("device has not been created", self.path) if self.status and self.format.exists: self.format.teardown() udev_settle(timeout=10) if self.status: lvm.lvdeactivate(self.vg.name, self._name) if recursive: # It's likely that teardown of a VG will fail due to other # LVs being active (filesystems mounted, &c), so don't let # it bring everything down. try: self.vg.teardown(recursive=recursive) except Exception as e: log.debug("vg %s teardown failed; continuing" % self.vg.name) def create(self, intf=None): """ Create the device. """ log_method_call(self, self.name, status=self.status) if self.exists: raise DeviceError("device already exists", self.path) self.createParents() self.setupParents() # should we use --zero for safety's sake? lvm.lvcreate(self.vg.name, self._name, self.size) # FIXME set / update self.uuid here self.exists = True self.setup() def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) self.teardown() # set up the vg's pvs so lvm can remove the lv self.vg.setupParents() lvm.lvremove(self.vg.name, self._name) self.exists = False def resize(self, intf=None): # XXX resize format probably, right? log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) # Setup VG parents (in case they are dmraid partitions for example) self.vg.setupParents() if self.format.exists: self.format.teardown() udev_settle(timeout=10) lvm.lvresize(self.vg.name, self._name, self.size) class MDRaidArrayDevice(StorageDevice): """ An mdraid (Linux RAID) device. Since this is derived from StorageDevice, not PartitionDevice, it can be used to represent a partitionable device. """ _type = "mdarray" def __init__(self, name, level=None, minor=None, size=None, memberDevices=None, totalDevices=None, bitmap=False, uuid=None, format=None, exists=None, parents=None, sysfsPath=''): """ Create a MDRaidArrayDevice instance. Arguments: name -- the device name (generally a device node's basename) Keyword Arguments: level -- the device's RAID level (a string, eg: '1' or 'raid1') parents -- list of member devices (StorageDevice instances) size -- the device's size (units/format TBD) uuid -- the device's UUID minor -- the device minor bitmap -- whether to use a bitmap (boolean) sysfsPath -- sysfs device path format -- a DeviceFormat instance exists -- indicates whether this is an existing device """ StorageDevice.__init__(self, name, format=format, exists=exists, minor=minor, size=size, parents=parents, sysfsPath=sysfsPath) self.level = level if level == "container": self._type = "mdcontainer" elif level is not None: self.level = mdraid.raidLevel(level) self.uuid = uuid self._totalDevices = numeric_type(totalDevices) self._memberDevices = numeric_type(memberDevices) self.sysfsPath = "/devices/virtual/block/%s" % name self.chunkSize = 64.0 / 1024.0 # chunk size in MB self.superBlockSize = 128.0 / 1024.0 # superblock size in MB # FIXME: Bitmap is more complicated than this. # It can be internal or external. External requires a filename. self.bitmap = bitmap self.formatClass = get_device_format_class("mdmember") if not self.formatClass: raise DeviceError("cannot find class for 'mdmember'", self.path) if self.exists and self.uuid: # this is a hack to work around mdadm's insistence on giving # really high minors to arrays it has no config entry for open("/etc/mdadm.conf", "a").write("ARRAY %s UUID=%s\n" % (self.path, self.uuid)) @property def smallestMember(self): try: smallest = sorted(self.devices, key=lambda d: d.size)[0] except IndexError: smallest = None return smallest @property def size(self): if not self.devices: return 0 size = 0 smallestMemberSize = self.smallestMember.size - self.superBlockSize if not self.exists or not self.partedDevice: if self.level == mdraid.RAID0: size = self.memberDevices * smallestMemberSize size -= size % self.chunkSize elif self.level == mdraid.RAID1: size = smallestMemberSize elif self.level == mdraid.RAID5: size = (self.memberDevices - 1) * smallestMemberSize size -= size % self.chunkSize elif self.level == mdraid.RAID6: size = (self.memberDevices - 2) * smallestMemberSize size -= size % self.chunkSize elif self.level == mdraid.RAID10: size = (self.memberDevices / 2.0) * smallestMemberSize size -= size % self.chunkSize else: size = self.partedDevice.getSize() return size def __str__(self): s = StorageDevice.__str__(self) s += (" level = %(level)s bitmap = %(bitmap)s spares = %(spares)s\n" " members = %(memberDevices)s\n" " total devices = %(totalDevices)s" % {"level": self.level, "bitmap": self.bitmap, "spares": self.spares, "memberDevices": self.memberDevices, "totalDevices": self.totalDevices}) return s def writeKS(self, f, preexisting=False, noformat=False, s=None): args = ["--level=%s" % self.level, "--device=%s" % self.name] mems = [] if self.spares > 0: args.append("--spares=%s" % self.spares) if preexisting: args.append("--useexisting") if noformat: args.append("--noformat") for mem in self.parents: mems.append("raid.%s" % mem.format.uuid) f.write("#raid ") self.format.writeKS(f) f.write(" %s" % " ".join(args)) f.write(" %s" % " ".join(mems)) if s: f.write(" %s" % s) @property def mdadmConfEntry(self): """ This array's mdadm.conf entry. """ if self.level is None or self.memberDevices is None or not self.uuid: raise DeviceError("array is not fully defined", self.path) fmt = "ARRAY %s level=raid%d num-devices=%d UUID=%s\n" return fmt % (self.path, self.level, self.memberDevices, self.uuid) @property def totalDevices(self): """ Total number of devices in the array, including spares. """ count = len(self.parents) if not self.exists: count = self._totalDevices return count def _getMemberDevices(self): return self._memberDevices def _setMemberDevices(self, number): if not isinstance(number, int): raise ValueError("memberDevices is an integer") if number > self.totalDevices: raise ValueError("memberDevices cannot be greater than totalDevices") self._memberDevices = number memberDevices = property(_getMemberDevices, _setMemberDevices, doc="number of member devices") def _getSpares(self): spares = 0 if self.memberDevices is not None: if self.totalDevices is not None: spares = self.totalDevices - self.memberDevices else: spares = self.memberDevices self.totalDevices = self.memberDevices return spares def _setSpares(self, spares): # FIXME: this is too simple to be right if self.totalDevices > spares: self.memberDevices = self.totalDevices - spares spares = property(_getSpares, _setSpares) def probe(self): """ Probe for any missing information about this device. I'd like to avoid paying any attention to "Preferred Minor" as it seems problematic. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) try: self.devices[0].setup() except Exception: return info = mdraid.mdexamine(self.devices[0].path) if self.level is None: self.level = mdraid.raidLevel(info['level']) @property def fstabSpec(self): return self.path def updateSysfsPath(self): """ Update this device's sysfs path. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if self.status: self.sysfsPath = "/devices/virtual/block/%s" % self.name else: self.sysfsPath = '' def _addDevice(self, device): """ Add a new member device to the array. XXX This is for use when probing devices, not for modification of arrays. """ log_method_call(self, self.name, device=device.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if not isinstance(device.format, self.formatClass): raise ValueError("invalid device format for mdraid member") if self.uuid and device.format.mdUuid != self.uuid: raise ValueError("cannot add member with non-matching UUID") if device in self.devices: raise ValueError("device is already a member of this array") # we added it, so now set up the relations self.devices.append(device) device.addChild() device.setup() udev_settle(timeout=10) try: mdraid.mdadd(device.path, len(self.devices) < self.memberDevices) except MDRaidError as e: log.warning("failed to add member %s to md array %s: %s" % (device.path, self.path, e)) if self.status: # we always probe since the device may not be set up when we want # information about it self._size = self.currentSize def _removeDevice(self, device): """ Remove a component device from the array. XXX This is for use by clearpart, not for reconfiguration. """ log_method_call(self, self.name, device=device.name, status=self.status) if device not in self.devices: raise ValueError("cannot remove non-member device from array") self.devices.remove(device) device.removeChild() @property def status(self): """ This device's status. For now, this should return a boolean: True the device is open and ready for use False the device is not open """ # check the status in sysfs status = False if not self.exists: return status state_file = "/sys/%s/md/array_state" % self.sysfsPath if os.access(state_file, os.R_OK): state = open(state_file).read().strip() log.debug("%s state is %s" % (self.name, state)) if state in ("clean", "active", "active-idle"): status = True return status @property def degraded(self): """ Return True if the array is running in degraded mode. """ rc = False degraded_file = "/sys/%s/md/degraded" % self.sysfsPath if os.access(degraded_file, os.R_OK): val = open(degraded_file).read().strip() log.debug("%s degraded is %s" % (self.name, val)) if val == "1": rc = True return rc @property def devices(self): """ Return a list of this array's member device instances. """ return self.parents def setup(self, intf=None): """ Open, or set up, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if self.status: return disks = [] for member in self.devices: member.setup() disks.append(member.path) mdraid.mdactivate(self.path, members=disks, super_minor=self.minor, uuid=self.uuid) udev_settle() # we always probe since the device may not be set up when we want # information about it self._size = self.currentSize def teardown(self, recursive=None): """ Close, or tear down, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists and not recursive: raise DeviceError("device has not been created", self.path) if self.status and self.format.exists: self.format.teardown() udev_settle(timeout=10) # We don't really care what the array's state is. If the device # file exists, we want to deactivate it. mdraid has too many # states. if self.exists and os.path.exists(self.path): mdraid.mddeactivate(self.path) if recursive: self.teardownParents(recursive=recursive) def create(self, intf=None): """ Create the device. """ log_method_call(self, self.name, status=self.status) if self.exists: raise DeviceError("device already exists", self.path) disks = [disk.path for disk in self.devices] self.createParents() self.setupParents() spares = len(self.devices) - self.memberDevices mdraid.mdcreate(self.path, self.level, disks, spares) self.exists = True # the array is automatically activated upon creation, but... self.setup() udev_settle() self.updateSysfsPath() info = udev_get_block_device(self.sysfsPath) self.uuid = udev_device_get_md_uuid(info) for member in self.devices: member.mdUuid = self.uuid @property def formatArgs(self): formatArgs = [] if self.format.type == "ext2": if self.level == mdraid.RAID5: formatArgs = ['-R', 'stride=%d' % ((self.memberDevices - 1) * 16)] elif self.level == mdraid.RAID0: formatArgs = ['-R', 'stride=%d' % (self.memberDevices * 16)] def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) self.teardown() # The destruction of the formatting on the member devices does the # real work, but it isn't our place to do it from here. self.exists = False class DMRaidArrayDevice(DiskDevice): """ A dmraid (device-mapper RAID) device """ _type = "dm-raid array" _packages = ["dmraid"] _devDir = "/dev/mapper" def __init__(self, name, raidSet=None, format=None, size=None, major=None, minor=None, parents=None, sysfsPath='', initcb=None, initlabel=None): """ Create a DMRaidArrayDevice instance. Arguments: name -- the dmraid name also the device node's basename Keyword Arguments: raidSet -- the RaidSet object from block parents -- a list of the member devices sysfsPath -- sysfs device path size -- the device's size format -- a DeviceFormat instance initcb -- the call back to be used when initiating disk. initlabel -- whether to start with a fresh disklabel """ if isinstance(parents, list): for parent in parents: if not parent.format or parent.format.type != "dmraidmember": raise ValueError("parent devices must contain dmraidmember format") DiskDevice.__init__(self, name, format=format, size=size, major=major, minor=minor, parents=parents, sysfsPath=sysfsPath, initcb=initcb, initlabel=initlabel) self.formatClass = get_device_format_class("dmraidmember") if not self.formatClass: raise StorageError("cannot find class for 'dmraidmember'") self._raidSet = raidSet @property def raidSet(self): return self._raidSet def _addDevice(self, device): """ Add a new member device to the array. XXX This is for use when probing devices, not for modification of arrays. """ log_method_call(self, self.name, device=device.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if not isinstance(device.format, self.formatClass): raise ValueError("invalid device format for dmraid member") if device in self.members: raise ValueError("device is already a member of this array") # we added it, so now set up the relations self.devices.append(device) device.addChild() @property def members(self): return self.parents @property def devices(self): """ Return a list of this array's member device instances. """ return self.parents def updateSysfsPath(self): """ Update this device's sysfs path. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if self.status: dm_node = dm.dm_node_from_name(self.name) path = os.path.join("/sys", self.sysfsBlockDir, dm_node) self.sysfsPath = os.path.realpath(path)[4:] else: self.sysfsPath = '' def teardown(self, recursive=None): """ Close, or tear down, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) if self.format.exists: self.format.teardown() udev_settle(timeout=10) # This call already checks if the set is not active. self._raidSet.deactivate() def setup(self, intf=None): """ Open, or set up, a device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) # This call already checks if the set is active. self._raidSet.activate(mknod=True) udev_settle() # we always probe since the device may not be set up when we want # information about it self._size = self.currentSize class _MultipathDeviceNameGenerator: def __init__(self): self.number = 0 def get(self): ret = self.number self.number += 1 return ret _multipathDeviceNameGenerator = _MultipathDeviceNameGenerator() def generateMultipathDeviceName(): number = _multipathDeviceNameGenerator.get() return "mpath%s" % (number, ) class MultipathDevice(DiskDevice): """ A multipath device """ _type = "dm-multipath" _packages = ["device-mapper-multipath"] _devDir = "/dev/mapper" def __init__(self, name, info, format=None, size=None, parents=None, sysfsPath='', initcb=None, initlabel=None): """ Create a MultipathDevice instance. Arguments: name -- the device name (generally a device node's basename) info -- the udev info for this device Keyword Arguments: sysfsPath -- sysfs device path size -- the device's size format -- a DeviceFormat instance parents -- a list of the backing devices (Device instances) initcb -- the call back to be used when initiating disk. initlabel -- whether to start with a fresh disklabel """ self._info = info self._isUp = False self._pyBlockMultiPath = None self.setupIdentity() DiskDevice.__init__(self, name, format=format, size=size, parents=parents, sysfsPath=sysfsPath, initcb=initcb, initlabel=initlabel) def setupIdentity(self): """ Adds identifying remarks to MultipathDevice object. May be overridden by a sub-class for e.g. RDAC handling. """ self._serial = self._info['ID_SERIAL_SHORT'] @property def identity(self): """ Get identity set with setupIdentityFromInfo() May be overridden by a sub-class for e.g. RDAC handling. """ if not hasattr(self, "_serial"): raise RuntimeError, "setupIdentityFromInfo() has not been called." return self._serial @property def status(self): return self._isUp @property def wwid(self): serial = self.identity ret = [] while serial: ret.append(serial[:2]) serial = serial[2:] return ":".join(ret) @property def description(self): return "WWID %s" % (self.wwid,) def addParent(self, parent): if self.status: self.teardown() self.parents.append(parent) self.setup() else: self.parents.append(parent) def setup(self, intf=None): if self.status: self.teardown() self._isUp = True parents = [] for p in self.parents: parents.append(p.path) self._pyBlockMultiPath = block.device.MultiPath(*parents) def teardown(self, recursive=None): if not self.status: return self._isUp = False self._pyBlockMultiPath = None class NoDevice(StorageDevice): """ A nodev device for nodev filesystems like tmpfs. """ _type = "nodev" def __init__(self, format=None): """ Create a NoDevice instance. Arguments: Keyword Arguments: format -- a DeviceFormat instance """ if format: name = format.type else: name = "none" StorageDevice.__init__(self, name, format=format) @property def path(self): """ Device node representing this device. """ return self.name def probe(self): """ Probe for any missing information about this device. """ log_method_call(self, self.name, status=self.status) def setup(self, intf=None): """ Open, or set up, a device. """ log_method_call(self, self.name, status=self.status) def teardown(self, recursive=False): """ Close, or tear down, a device. """ log_method_call(self, self.name, status=self.status) def create(self, intf=None): """ Create the device. """ log_method_call(self, self.name, status=self.status) self.setupParents() def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status) class FileDevice(StorageDevice): """ A file on a filesystem. This exists because of swap files. """ _type = "file" _devDir = "" def __init__(self, path, format=None, size=None, exists=None, parents=None): """ Create a FileDevice instance. Arguments: path -- full path to the file Keyword Arguments: format -- a DeviceFormat instance size -- the file size (units TBD) parents -- a list of required devices (Device instances) exists -- indicates whether this is an existing device """ StorageDevice.__init__(self, path, format=format, size=size, exists=exists, parents=parents) def probe(self): """ Probe for any missing information about this device. """ pass @property def fstabSpec(self): return self.name @property def path(self): path = self.name root = "" try: status = self.parents[0].format.status except (AttributeError, IndexError): status = False if status: # this is the actual active mountpoint root = self.parents[0].format._mountpoint # trim the mountpoint down to the chroot since we already have # the otherwise fully-qualified path root = root[:-len(self.parents[0].format.mountpoint)] return os.path.normpath("%s/%s" % (root, path)) def setup(self): StorageDevice.setup(self) if self.format and self.format.exists and not self.format.status: self.format.device = self.path for parent in self.parents: parent.format.setup() def teardown(self, recursive=None): StorageDevice.teardown(self) if self.format and self.format.exists and not self.format.status: self.format.device = self.path def create(self, intf=None): """ Create the device. """ log_method_call(self, self.name, status=self.status) if self.exists: raise DeviceError("device already exists", self.path) # this only checks that parents exist self.createParents() self.setupParents() try: fd = os.open(self.path, os.O_RDWR) except OSError as e: raise DeviceError(e, self.path) try: buf = '\0' * 1024 * 1024 * self.size os.write(fd, buf) except (OSError, TypeError) as e: log.error("error writing out %s: %s" % (self.path, e)) finally: os.close(fd) self.exists = True def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) os.unlink(self.path) self.exists = False class DirectoryDevice(FileDevice): """ A directory on a filesystem. This exists because of bind mounts. """ _type = "directory" def create(self): """ Create the device. """ log_method_call(self, self.name, status=self.status) if self.exists: raise DeviceError("device already exists", self.path) self.createParents() self.setupParents() try: iutil.mkdirChain(self.path) except Exception, e: raise DeviceError(e, self.path) self.exists = True def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) os.unlink(self.path) self.exists = False class iScsiDiskDevice(DiskDevice, NetworkStorageDevice): """ An iSCSI disk. """ _type = "iscsi" _packages = ["iscsi-initiator-utils"] def __init__(self, device, **kwargs): self.node = kwargs.pop("node") self.ibft = kwargs.pop("ibft") DiskDevice.__init__(self, device, **kwargs) NetworkStorageDevice.__init__(self, host_address=self.node.address) log.debug("created new iscsi disk %s %s:%d" % (self.node.name, self.node.address, self.node.port)) def dracutSetupString(self): if self.ibft: return "iscsi_firmware" netroot="netroot=iscsi:" auth = self.node.getAuth() if auth: netroot += "%s:%s" % (auth.username, auth.password) if len(auth.reverse_username) or len(auth.reverse_password): netroot += ":%s:%s" % (auth.reverse_username, auth.reverse_password) netroot += "@%s::%d::%s" % (self.node.address, self.node.port, self.node.name) return netroot class FcoeDiskDevice(DiskDevice, NetworkStorageDevice): """ An FCoE disk. """ _type = "fcoe" _packages = ["fcoe-utils"] def __init__(self, device, **kwargs): self.nic = kwargs.pop("nic") self.identifier = kwargs.pop("identifier") DiskDevice.__init__(self, device, **kwargs) NetworkStorageDevice.__init__(self, nic=self.nic) log.debug("created new fcoe disk %s @ %s" % (device, self.nic)) class OpticalDevice(StorageDevice): """ An optical drive, eg: cdrom, dvd+r, &c. XXX Is this useful? """ _type = "cdrom" def __init__(self, name, major=None, minor=None, exists=None, format=None, parents=None, sysfsPath=''): StorageDevice.__init__(self, name, format=format, major=major, minor=minor, exists=True, parents=parents, sysfsPath=sysfsPath) @property def mediaPresent(self): """ Return a boolean indicating whether or not the device contains media. """ log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) try: fd = os.open(self.path, os.O_RDONLY) except OSError as e: # errno 123 = No medium found if e.errno == 123: return False else: return True else: os.close(fd) return True def eject(self): """ Eject the drawer. """ import _isys log_method_call(self, self.name, status=self.status) if not self.exists: raise DeviceError("device has not been created", self.path) #try to umount and close device before ejecting self.teardown() # Make a best effort attempt to do the eject. If it fails, it's not # critical. fd = os.open(self.path, os.O_RDONLY | os.O_NONBLOCK) try: _isys.ejectcdrom(fd) except SystemError as e: log.warning("error ejecting cdrom %s: %s" % (self.name, e)) os.close(fd) class ZFCPDiskDevice(DiskDevice): """ A mainframe ZFCP disk. """ _type = "zfcp" def __init__(self, name, size=None, major=None, minor=None, devnum=None, wwpn=None, fcplun=None, parents=None, sysfsPath=''): self.devnum = devnum self.wwpn = wwpn self.fcplun = fcplun name = "zfcp://%s/%s/%s" % (self.devnum, self.wwpn, self.fcplun) DiskDevice.__init__(self, name, size=size, major=major, minor=minor, parents=parents, sysfsPath=sysfsPath) def __str__(self): s = DiskDevice.__str__(self) s += (" devnum = %(devnum)s wwpn = %(wwpn)s fcplun = %(fcplun)s" % {"devnum": self.devnum, "wwpn": self.wwpn, "fcplun": self.fcplun}) return s class DASDDevice(DiskDevice): """ A mainframe DASD. """ _type = "dasd" def __init__(self, device, size=None, major=None, minor=None, parents=None, sysfsPath=''): DiskDevice.__init__(self, device, size=size, major=major, minor=minor, parents=parents, sysfsPath=sysfsPath) class NFSDevice(StorageDevice, NetworkStorageDevice): """ An NFS device """ _type = "nfs" def __init__(self, device, format=None, parents=None): # we could make host/ip, path, &c but will anything use it? StorageDevice.__init__(self, device, format=format, parents=parents) NetworkStorageDevice.__init__(self, device.split(":")[0]) @property def path(self): """ Device node representing this device. """ return self.name def setup(self, intf=None): """ Open, or set up, a device. """ log_method_call(self, self.name, status=self.status) def teardown(self, recursive=None): """ Close, or tear down, a device. """ log_method_call(self, self.name, status=self.status) def create(self, intf=None): """ Create the device. """ log_method_call(self, self.name, status=self.status) self.createParents() self.setupParents() def destroy(self): """ Destroy the device. """ log_method_call(self, self.name, status=self.status)