# Copyright 2013 Rackspace, Inc.
#
# 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 abc
import binascii
import functools
import os
import shlex
import time
from ironic_lib import disk_utils
from ironic_lib import utils as il_utils
from oslo_concurrency import processutils
from oslo_config import cfg
from oslo_log import log
import pint
import psutil
import pyudev
import six
import stevedore
from ironic_python_agent import encoding
from ironic_python_agent import errors
from ironic_python_agent import netutils
from ironic_python_agent import utils
_global_managers = None
LOG = log.getLogger()
CONF = cfg.CONF
UNIT_CONVERTER = pint.UnitRegistry(filename=None)
UNIT_CONVERTER.define('MB = []')
UNIT_CONVERTER.define('GB = 1024 MB')
NODE = None
def _get_device_info(dev, devclass, field):
"""Get the device info according to device class and field."""
try:
devname = os.path.basename(dev)
with open('/sys/class/%s/%s/device/%s' % (devclass, devname, field),
'r') as f:
return f.read().strip()
except IOError:
LOG.warning(
"Can't find field {} for device {} in device class {}".format(
field, dev, devclass))
def _udev_settle():
"""Wait for the udev event queue to settle.
Wait for the udev event queue to settle to make sure all devices
are detected once the machine boots up.
"""
try:
utils.execute('udevadm', 'settle')
except processutils.ProcessExecutionError as e:
LOG.warning('Something went wrong when waiting for udev '
'to settle. Error: %s', e)
return
def _check_for_iscsi():
"""Connect iSCSI shared connected via iBFT or OF.
iscsistart -f will print the iBFT or OF info.
In case such connection exists, we would like to issue
iscsistart -b to create a session to the target.
- If no connection is detected we simply return.
"""
try:
utils.execute('iscsistart', '-f')
except (processutils.ProcessExecutionError, EnvironmentError) as e:
LOG.debug("No iscsi connection detected. Skipping iscsi. "
"Error: %s", e)
return
try:
utils.execute('iscsistart', '-b')
except processutils.ProcessExecutionError as e:
LOG.warning("Something went wrong executing 'iscsistart -b' "
"Error: %s", e)
def list_all_block_devices(block_type='disk'):
"""List all physical block devices
The switches we use for lsblk: P for KEY="value" output, b for size output
in bytes, d to exclude dependent devices (like md or dm devices), i to
ensure ascii characters only, and o to specify the fields/columns we need.
Broken out as its own function to facilitate custom hardware managers that
don't need to subclass GenericHardwareManager.
:param block_type: Type of block device to find
:return: A list of BlockDevices
"""
_udev_settle()
columns = ['KNAME', 'MODEL', 'SIZE', 'ROTA', 'TYPE']
report = utils.execute('lsblk', '-Pbdi', '-o{}'.format(','.join(columns)),
check_exit_code=[0])[0]
lines = report.split('\n')
context = pyudev.Context()
devices = []
for line in lines:
device = {}
# Split into KEY=VAL pairs
vals = shlex.split(line)
for key, val in (v.split('=', 1) for v in vals):
device[key] = val.strip()
# Ignore block types not specified
if device.get('TYPE') != block_type:
LOG.debug(
"TYPE did not match. Wanted: {!r} but found: {!r}".format(
block_type, line))
continue
# Ensure all required columns are at least present, even if blank
missing = set(columns) - set(device)
if missing:
raise errors.BlockDeviceError(
'%s must be returned by lsblk.' % ', '.join(sorted(missing)))
name = '/dev/' + device['KNAME']
try:
udev = pyudev.Device.from_device_file(context, name)
# pyudev started raising another error in 0.18
except (ValueError, EnvironmentError, pyudev.DeviceNotFoundError) as e:
LOG.warning("Device %(dev)s is inaccessible, skipping... "
"Error: %(error)s", {'dev': name, 'error': e})
extra = {}
else:
# TODO(lucasagomes): Since lsblk only supports
# returning the short serial we are using
# ID_SERIAL_SHORT here to keep compatibility with the
# bash deploy ramdisk
extra = {key: udev.get('ID_%s' % udev_key) for key, udev_key in
[('wwn', 'WWN'), ('serial', 'SERIAL_SHORT'),
('wwn_with_extension', 'WWN_WITH_EXTENSION'),
('wwn_vendor_extension', 'WWN_VENDOR_EXTENSION')]}
# NOTE(lucasagomes): Newer versions of the lsblk tool supports
# HCTL as a parameter but let's get it from sysfs to avoid breaking
# old distros.
try:
extra['hctl'] = os.listdir(
'/sys/block/%s/device/scsi_device' % device['KNAME'])[0]
except (OSError, IndexError):
LOG.warning('Could not find the SCSI address (HCTL) for '
'device %s. Skipping', name)
devices.append(BlockDevice(name=name,
model=device['MODEL'],
size=int(device['SIZE']),
rotational=bool(int(device['ROTA'])),
vendor=_get_device_info(device['KNAME'],
'block', 'vendor'),
**extra))
return devices
[docs]class HardwareSupport(object):
"""Example priorities for hardware managers.
Priorities for HardwareManagers are integers, where largest means most
specific and smallest means most generic. These values are guidelines
that suggest values that might be returned by calls to
`evaluate_hardware_support()`. No HardwareManager in mainline IPA will
ever return a value greater than MAINLINE. Third party hardware managers
should feel free to return values of SERVICE_PROVIDER or greater to
distinguish between additional levels of hardware support.
"""
NONE = 0
GENERIC = 1
MAINLINE = 2
SERVICE_PROVIDER = 3
[docs]class HardwareType(object):
MAC_ADDRESS = 'mac_address'
[docs]class BlockDevice(encoding.SerializableComparable):
serializable_fields = ('name', 'model', 'size', 'rotational',
'wwn', 'serial', 'vendor', 'wwn_with_extension',
'wwn_vendor_extension', 'hctl')
def __init__(self, name, model, size, rotational, wwn=None, serial=None,
vendor=None, wwn_with_extension=None,
wwn_vendor_extension=None, hctl=None):
self.name = name
self.model = model
self.size = size
self.rotational = rotational
self.wwn = wwn
self.serial = serial
self.vendor = vendor
self.wwn_with_extension = wwn_with_extension
self.wwn_vendor_extension = wwn_vendor_extension
self.hctl = hctl
[docs]class NetworkInterface(encoding.SerializableComparable):
serializable_fields = ('name', 'mac_address', 'ipv4_address',
'has_carrier', 'lldp', 'vendor', 'product',
'client_id', 'biosdevname')
def __init__(self, name, mac_addr, ipv4_address=None, has_carrier=True,
lldp=None, vendor=None, product=None, client_id=None,
biosdevname=None):
self.name = name
self.mac_address = mac_addr
self.ipv4_address = ipv4_address
self.has_carrier = has_carrier
self.lldp = lldp
self.vendor = vendor
self.product = product
self.biosdevname = biosdevname
# client_id is used for InfiniBand only. we calculate the DHCP
# client identifier Option to allow DHCP to work over InfiniBand.
# see https://tools.ietf.org/html/rfc4390
self.client_id = client_id
[docs]class CPU(encoding.SerializableComparable):
serializable_fields = ('model_name', 'frequency', 'count', 'architecture',
'flags')
def __init__(self, model_name, frequency, count, architecture,
flags=None):
self.model_name = model_name
self.frequency = frequency
self.count = count
self.architecture = architecture
self.flags = flags or []
[docs]class Memory(encoding.SerializableComparable):
serializable_fields = ('total', 'physical_mb')
# physical = total + kernel binary + reserved space
def __init__(self, total, physical_mb=None):
self.total = total
self.physical_mb = physical_mb
[docs]class SystemVendorInfo(encoding.SerializableComparable):
serializable_fields = ('product_name', 'serial_number', 'manufacturer')
def __init__(self, product_name, serial_number, manufacturer):
self.product_name = product_name
self.serial_number = serial_number
self.manufacturer = manufacturer
[docs]class BootInfo(encoding.SerializableComparable):
serializable_fields = ('current_boot_mode', 'pxe_interface')
def __init__(self, current_boot_mode, pxe_interface=None):
self.current_boot_mode = current_boot_mode
self.pxe_interface = pxe_interface
@six.add_metaclass(abc.ABCMeta)
[docs]class HardwareManager(object):
@abc.abstractmethod
[docs] def evaluate_hardware_support(self):
pass
[docs] def list_network_interfaces(self):
raise errors.IncompatibleHardwareMethodError
[docs] def get_cpus(self):
raise errors.IncompatibleHardwareMethodError
[docs] def list_block_devices(self):
raise errors.IncompatibleHardwareMethodError
[docs] def get_memory(self):
raise errors.IncompatibleHardwareMethodError
[docs] def get_os_install_device(self):
raise errors.IncompatibleHardwareMethodError
[docs] def get_bmc_address(self):
raise errors.IncompatibleHardwareMethodError()
[docs] def get_boot_info(self):
raise errors.IncompatibleHardwareMethodError()
[docs] def get_interface_info(self, interface_name):
raise errors.IncompatibleHardwareMethodError()
[docs] def erase_block_device(self, node, block_device):
"""Attempt to erase a block device.
Implementations should detect the type of device and erase it in the
most appropriate way possible. Generic implementations should support
common erase mechanisms such as ATA secure erase, or multi-pass random
writes. Operators with more specific needs should override this method
in order to detect and handle "interesting" cases, or delegate to the
parent class to handle generic cases.
For example: operators running ACME MagicStore (TM) cards alongside
standard SSDs might check whether the device is a MagicStore and use a
proprietary tool to erase that, otherwise call this method on their
parent class. Upstream submissions of common functionality are
encouraged.
:param node: Ironic node object
:param block_device: a BlockDevice indicating a device to be erased.
:raises IncompatibleHardwareMethodError: when there is no known way to
erase the block device
:raises BlockDeviceEraseError: when there is an error erasing the
block device
"""
raise errors.IncompatibleHardwareMethodError
[docs] def erase_devices(self, node, ports):
"""Erase any device that holds user data.
By default this will attempt to erase block devices. This method can be
overridden in an implementation-specific hardware manager in order to
erase additional hardware, although backwards-compatible upstream
submissions are encouraged.
:param node: Ironic node object
:param ports: list of Ironic port objects
:return: a dictionary in the form {device.name: erasure output}
"""
erase_results = {}
block_devices = self.list_block_devices()
for block_device in block_devices:
result = dispatch_to_managers(
'erase_block_device', node=node, block_device=block_device)
erase_results[block_device.name] = result
return erase_results
[docs] def list_hardware_info(self):
"""Return full hardware inventory as a serializable dict.
This inventory is sent to Ironic on lookup and to Inspector on
inspection.
:return: a dictionary representing inventory
"""
# NOTE(dtantsur): don't forget to update docs when extending inventory
hardware_info = {}
hardware_info['interfaces'] = self.list_network_interfaces()
hardware_info['cpu'] = self.get_cpus()
hardware_info['disks'] = self.list_block_devices()
hardware_info['memory'] = self.get_memory()
hardware_info['bmc_address'] = self.get_bmc_address()
hardware_info['system_vendor'] = self.get_system_vendor_info()
hardware_info['boot'] = self.get_boot_info()
return hardware_info
[docs] def get_clean_steps(self, node, ports):
"""Get a list of clean steps with priority.
Returns a list of steps. Each step is represented by a dict::
{
'step': the HardwareManager function to call.
'priority': the order steps will be run in. Ironic will sort all
the clean steps from all the drivers, with the largest
priority step being run first. If priority is set to 0,
the step will not be run during cleaning, but may be
run during zapping.
'reboot_requested': Whether the agent should request Ironic reboots
the node via the power driver after the
operation completes.
'abortable': Boolean value. Whether the clean step can be
stopped by the operator or not. Some clean step may
cause non-reversible damage to a machine if interrupted
(i.e firmware update), for such steps this parameter
should be set to False. If no value is set for this
parameter, Ironic will consider False (non-abortable).
}
If multiple hardware managers return the same step name, the following
logic will be used to determine which manager's step "wins":
* Keep the step that belongs to HardwareManager with highest
HardwareSupport (larger int) value.
* If equal support level, keep the step with the higher defined
priority (larger int).
* If equal support level and priority, keep the step associated
with the HardwareManager whose name comes earlier in the
alphabet.
The steps will be called using `hardware.dispatch_to_managers` and
handled by the best suited hardware manager. If you need a step to be
executed by only your hardware manager, ensure it has a unique step
name.
`node` and `ports` can be used by other hardware managers to further
determine if a clean step is supported for the node.
:param node: Ironic node object
:param ports: list of Ironic port objects
:return: a list of cleaning steps, where each step is described as a
dict as defined above
"""
return []
[docs] def get_version(self):
"""Get a name and version for this hardware manager.
In order to avoid errors and make agent upgrades painless, cleaning
will check the version of all hardware managers during get_clean_steps
at the beginning of cleaning and before executing each step in the
agent.
The agent isn't aware of the steps being taken before or after via
out of band steps, so it can never know if a new step is safe to run.
Therefore, we default to restarting the whole process.
:returns: a dictionary with two keys: `name` and
`version`, where `name` is a string identifying the hardware
manager and `version` is an arbitrary version string. `name` will
be a class variable called HARDWARE_MANAGER_NAME, or default to
the class name and `version` will be a class variable called
HARDWARE_MANAGER_VERSION or default to '1.0'.
"""
return {
'name': getattr(self, 'HARDWARE_MANAGER_NAME',
type(self).__name__),
'version': getattr(self, 'HARDWARE_MANAGER_VERSION', '1.0')
}
[docs]class GenericHardwareManager(HardwareManager):
HARDWARE_MANAGER_NAME = 'generic_hardware_manager'
# 1.1 - Added new clean step called erase_devices_metadata
HARDWARE_MANAGER_VERSION = '1.1'
def __init__(self):
self.sys_path = '/sys'
self.lldp_data = {}
[docs] def evaluate_hardware_support(self):
# Do some initialization before we declare ourself ready
_check_for_iscsi()
self._wait_for_disks()
return HardwareSupport.GENERIC
def _wait_for_disks(self):
"""Wait for disk to appear
Wait for at least one suitable disk to show up, otherwise neither
inspection not deployment have any chances to succeed.
"""
for attempt in range(CONF.disk_wait_attempts):
try:
block_devices = self.list_block_devices()
utils.guess_root_disk(block_devices)
except errors.DeviceNotFound:
LOG.debug('Still waiting for at least one disk to appear, '
'attempt %d of %d', attempt + 1,
CONF.disk_wait_attempts)
time.sleep(CONF.disk_wait_delay)
else:
break
else:
LOG.warning('No disks detected in %d seconds',
CONF.disk_wait_delay * CONF.disk_wait_attempts)
[docs] def collect_lldp_data(self, interface_names):
"""Collect and convert LLDP info from the node.
In order to process the LLDP information later, the raw data needs to
be converted for serialization purposes.
:param interface_names: list of names of node's interfaces.
:return: a dict, containing the lldp data from every interface.
"""
interface_names = [name for name in interface_names if name != 'lo']
lldp_data = {}
try:
raw_lldp_data = netutils.get_lldp_info(interface_names)
except Exception:
# NOTE(sambetts) The get_lldp_info function will log this exception
# and we don't invalidate any existing data in the cache if we fail
# to get data to replace it so just return.
return lldp_data
for ifname, tlvs in raw_lldp_data.items():
# NOTE(sambetts) Convert each type-length-value (TLV) value to hex
# so that it can be serialised safely
processed_tlvs = []
for typ, data in tlvs:
try:
processed_tlvs.append((typ,
binascii.hexlify(data).decode()))
except (binascii.Error, binascii.Incomplete) as e:
LOG.warning('An error occurred while processing TLV type '
'%s for interface %s: %s', (typ, ifname, e))
lldp_data[ifname] = processed_tlvs
return lldp_data
def _get_lldp_data(self, interface_name):
if self.lldp_data:
return self.lldp_data.get(interface_name)
[docs] def get_interface_info(self, interface_name):
addr_path = '{}/class/net/{}/address'.format(self.sys_path,
interface_name)
with open(addr_path) as addr_file:
mac_addr = addr_file.read().strip()
return NetworkInterface(
interface_name, mac_addr,
ipv4_address=self.get_ipv4_addr(interface_name),
has_carrier=netutils.interface_has_carrier(interface_name),
vendor=_get_device_info(interface_name, 'net', 'vendor'),
product=_get_device_info(interface_name, 'net', 'device'),
biosdevname=self.get_bios_given_nic_name(interface_name))
[docs] def get_ipv4_addr(self, interface_id):
return netutils.get_ipv4_addr(interface_id)
[docs] def get_bios_given_nic_name(self, interface_name):
"""Collect the BIOS given NICs name.
This function uses the biosdevname utility to collect the BIOS given
name of network interfaces.
The collected data is added to the network interface inventory with an
extra field named ``biosdevname``.
:param interface_name: list of names of node's interfaces.
:return: the BIOS given NIC name of node's interfaces or default
as None.
"""
try:
stdout, _ = utils.execute('biosdevname', '-i',
interface_name)
return stdout.rstrip('\n')
except OSError:
LOG.warning("Executable 'biosdevname' not found")
return
except processutils.ProcessExecutionError as e:
# NOTE(alezil) biosdevname returns 4 if running in a
# virtual machine.
if e.exit_code == 4:
LOG.info('The system is a virtual machine, so biosdevname '
'utility does not provide names for virtual NICs.')
else:
LOG.warning('Biosdevname returned exit code %s', e.exit_code)
def _is_device(self, interface_name):
device_path = '{}/class/net/{}/device'.format(self.sys_path,
interface_name)
return os.path.exists(device_path)
[docs] def list_network_interfaces(self):
network_interfaces_list = []
iface_names = os.listdir('{}/class/net'.format(self.sys_path))
iface_names = [name for name in iface_names if self._is_device(name)]
if CONF.collect_lldp:
self.lldp_data = dispatch_to_managers('collect_lldp_data',
interface_names=iface_names)
for iface_name in iface_names:
result = dispatch_to_managers(
'get_interface_info', interface_name=iface_name)
result.lldp = self._get_lldp_data(iface_name)
network_interfaces_list.append(result)
return network_interfaces_list
[docs] def get_cpus(self):
lines = utils.execute('lscpu')[0]
cpu_info = {k.strip().lower(): v.strip() for k, v in
(line.split(':', 1)
for line in lines.split('\n')
if line.strip())}
# Current CPU frequency can be different from maximum one on modern
# processors
freq = cpu_info.get('cpu max mhz', cpu_info.get('cpu mhz'))
flags = []
out = utils.try_execute('grep', '-Em1', '^flags', '/proc/cpuinfo')
if out:
try:
# Example output (much longer for a real system):
# flags : fpu vme de pse
flags = out[0].strip().split(':', 1)[1].strip().split()
except (IndexError, ValueError):
LOG.warning('Malformed CPU flags information: %s', out)
else:
LOG.warning('Failed to get CPU flags')
return CPU(model_name=cpu_info.get('model name'),
frequency=freq,
# this includes hyperthreading cores
count=int(cpu_info.get('cpu(s)')),
architecture=cpu_info.get('architecture'),
flags=flags)
[docs] def get_memory(self):
# psutil returns a long, so we force it to an int
try:
total = int(psutil.virtual_memory().total)
except Exception:
# This is explicitly catching all exceptions. We want to catch any
# situation where a newly upgraded psutil would fail, and instead
# print an error instead of blowing up the stack on IPA.
total = None
LOG.exception(("Cannot fetch total memory size using psutil "
"version %s"), psutil.version_info[0])
try:
out, _e = utils.execute("dmidecode --type 17 | grep Size",
shell=True)
except (processutils.ProcessExecutionError, OSError) as e:
LOG.warning("Cannot get real physical memory size: %s", e)
physical = None
else:
physical = 0
for line in out.strip().split('\n'):
line = line.strip()
if not line:
continue
if 'Size:' not in line:
continue
value = None
try:
value = line.split('Size: ', 1)[1]
physical += int(UNIT_CONVERTER(value).to_base_units())
except Exception as exc:
if (value == "No Module Installed" or
value == "Not Installed"):
LOG.debug('One memory slot is empty')
else:
LOG.error('Cannot parse size expression %s: %s',
line, exc)
if not physical:
LOG.warning('failed to get real physical RAM, dmidecode '
'returned %s', out)
return Memory(total=total, physical_mb=physical)
[docs] def list_block_devices(self):
return list_all_block_devices()
[docs] def get_os_install_device(self):
cached_node = get_cached_node()
root_device_hints = None
if cached_node is not None:
root_device_hints = cached_node['properties'].get('root_device')
block_devices = self.list_block_devices()
if not root_device_hints:
return utils.guess_root_disk(block_devices).name
else:
serialized_devs = [dev.serialize() for dev in block_devices]
try:
device = il_utils.match_root_device_hints(serialized_devs,
root_device_hints)
except ValueError as e:
# NOTE(lucasagomes): Just playing on the safe side
# here, this exception should never be raised because
# Ironic should validate the root device hints before the
# deployment starts.
raise errors.DeviceNotFound(
'No devices could be found using the root device hints '
'%(hints)s because they failed to validate. Error: '
'%(error)s' % {'hints': root_device_hints, 'error': e})
if not device:
raise errors.DeviceNotFound(
"No suitable device was found for "
"deployment using these hints %s" % root_device_hints)
return device['name']
[docs] def get_system_vendor_info(self):
product_name = None
serial_number = None
manufacturer = None
try:
out, _e = utils.execute("dmidecode --type system",
shell=True)
except (processutils.ProcessExecutionError, OSError) as e:
LOG.warning("Cannot get system vendor information: %s", e)
else:
for line in out.split('\n'):
line_arr = line.split(':', 1)
if len(line_arr) != 2:
continue
if line_arr[0].strip() == 'Product Name':
product_name = line_arr[1].strip()
elif line_arr[0].strip() == 'Serial Number':
serial_number = line_arr[1].strip()
elif line_arr[0].strip() == 'Manufacturer':
manufacturer = line_arr[1].strip()
return SystemVendorInfo(product_name=product_name,
serial_number=serial_number,
manufacturer=manufacturer)
[docs] def get_boot_info(self):
boot_mode = 'uefi' if os.path.isdir('/sys/firmware/efi') else 'bios'
LOG.debug('The current boot mode is %s', boot_mode)
pxe_interface = utils.get_agent_params().get('BOOTIF')
return BootInfo(current_boot_mode=boot_mode,
pxe_interface=pxe_interface)
[docs] def erase_block_device(self, node, block_device):
# Check if the block device is virtual media and skip the device.
if self._is_virtual_media_device(block_device):
LOG.info("Skipping the erase of virtual media device %s",
block_device.name)
return
# Note(TheJulia) Use try/except to capture and log the failure
# and then revert to attempting to shred the volume if enabled.
try:
if self._ata_erase(block_device):
return
except errors.BlockDeviceEraseError as e:
info = node.get('driver_internal_info', {})
execute_shred = info.get(
'agent_continue_if_ata_erase_failed', False)
if execute_shred:
LOG.warning('Failed to invoke ata_erase, '
'falling back to shred: %(err)s',
{'err': e})
else:
msg = ('Failed to invoke ata_erase, '
'fallback to shred is not enabled: %(err)s'
% {'err': e})
LOG.error(msg)
raise errors.IncompatibleHardwareMethodError(msg)
if self._shred_block_device(node, block_device):
return
msg = ('Unable to erase block device {}: device is unsupported.'
).format(block_device.name)
LOG.error(msg)
raise errors.IncompatibleHardwareMethodError(msg)
def _shred_block_device(self, node, block_device):
"""Erase a block device using shred.
:param node: Ironic node info.
:param block_device: a BlockDevice object to be erased
:returns: True if the erase succeeds, False if it fails for any reason
"""
info = node.get('driver_internal_info', {})
npasses = info.get('agent_erase_devices_iterations', 1)
args = ('shred', '--force')
if info.get('agent_erase_devices_zeroize', True):
args += ('--zero', )
args += ('--verbose', '--iterations', str(npasses), block_device.name)
try:
utils.execute(*args)
except (processutils.ProcessExecutionError, OSError) as e:
msg = ("Erasing block device %(dev)s failed with error %(err)s ",
{'dev': block_device.name, 'err': e})
LOG.error(msg)
return False
return True
def _is_virtual_media_device(self, block_device):
"""Check if the block device corresponds to Virtual Media device.
:param block_device: a BlockDevice object
:returns: True if it's a virtual media device, else False
"""
vm_device_label = '/dev/disk/by-label/ir-vfd-dev'
if os.path.exists(vm_device_label):
link = os.readlink(vm_device_label)
device = os.path.normpath(os.path.join(os.path.dirname(
vm_device_label), link))
if block_device.name == device:
return True
return False
def _get_ata_security_lines(self, block_device):
output = utils.execute('hdparm', '-I', block_device.name)[0]
if '\nSecurity: ' not in output:
return []
# Get all lines after the 'Security: ' line
security_and_beyond = output.split('\nSecurity: \n')[1]
security_and_beyond_lines = security_and_beyond.split('\n')
security_lines = []
for line in security_and_beyond_lines:
if line.startswith('\t'):
security_lines.append(line.strip().replace('\t', ' '))
else:
break
return security_lines
def _ata_erase(self, block_device):
security_lines = self._get_ata_security_lines(block_device)
# If secure erase isn't supported return False so erase_block_device
# can try another mechanism. Below here, if secure erase is supported
# but fails in some way, error out (operators of hardware that supports
# secure erase presumably expect this to work).
if 'supported' not in security_lines:
return False
if 'enabled' in security_lines:
# Attempt to unlock the drive in the event it has already been
# locked by a previous failed attempt.
try:
utils.execute('hdparm', '--user-master', 'u',
'--security-unlock', 'NULL', block_device.name)
security_lines = self._get_ata_security_lines(block_device)
except processutils.ProcessExecutionError as e:
raise errors.BlockDeviceEraseError('Security password set '
'failed for device '
'%(name)s: %(err)s' %
{'name': block_device.name,
'err': e})
if 'enabled' in security_lines:
raise errors.BlockDeviceEraseError(
('Block device {} already has a security password set'
).format(block_device.name))
if 'not frozen' not in security_lines:
raise errors.BlockDeviceEraseError(
('Block device {} is frozen and cannot be erased'
).format(block_device.name))
try:
utils.execute('hdparm', '--user-master', 'u',
'--security-set-pass', 'NULL', block_device.name)
except processutils.ProcessExecutionError as e:
raise errors.BlockDeviceEraseError('Security password set '
'failed for device '
'%(name)s: %(err)s' %
{'name': block_device.name,
'err': e})
# Use the 'enhanced' security erase option if it's supported.
erase_option = '--security-erase'
if 'not supported: enhanced erase' not in security_lines:
erase_option += '-enhanced'
try:
utils.execute('hdparm', '--user-master', 'u', erase_option,
'NULL', block_device.name)
except processutils.ProcessExecutionError as e:
raise errors.BlockDeviceEraseError('Erase failed for device '
'%(name)s: %(err)s' %
{'name': block_device.name,
'err': e})
# Verify that security is now 'not enabled'
security_lines = self._get_ata_security_lines(block_device)
if 'not enabled' not in security_lines:
raise errors.BlockDeviceEraseError(
('An unknown error occurred erasing block device {}'
).format(block_device.name))
return True
[docs] def get_bmc_address(self):
# These modules are rarely loaded automatically
utils.try_execute('modprobe', 'ipmi_msghandler')
utils.try_execute('modprobe', 'ipmi_devintf')
utils.try_execute('modprobe', 'ipmi_si')
try:
out, _e = utils.execute(
"ipmitool lan print | grep -e 'IP Address [^S]' "
"| awk '{ print $4 }'", shell=True)
except (processutils.ProcessExecutionError, OSError) as e:
# Not error, because it's normal in virtual environment
LOG.warning("Cannot get BMC address: %s", e)
return
return out.strip()
[docs] def get_clean_steps(self, node, ports):
return [
{
'step': 'erase_devices',
'priority': 10,
'interface': 'deploy',
'reboot_requested': False,
'abortable': True
},
{
'step': 'erase_devices_metadata',
'priority': 99,
'interface': 'deploy',
'reboot_requested': False,
'abortable': True
}
]
def _compare_extensions(ext1, ext2):
mgr1 = ext1.obj
mgr2 = ext2.obj
return mgr2.evaluate_hardware_support() - mgr1.evaluate_hardware_support()
def _get_managers():
"""Get a list of hardware managers in priority order.
Use stevedore to find all eligible hardware managers, sort them based on
self-reported (via evaluate_hardware_support()) priorities, and return them
in a list. The resulting list is cached in _global_managers.
:returns: Priority-sorted list of hardware managers
:raises HardwareManagerNotFound: if no valid hardware managers found
"""
global _global_managers
if not _global_managers:
extension_manager = stevedore.ExtensionManager(
namespace='ironic_python_agent.hardware_managers',
invoke_on_load=True)
# There will always be at least one extension available (the
# GenericHardwareManager).
if six.PY2:
extensions = sorted(extension_manager, _compare_extensions)
else:
extensions = sorted(extension_manager,
key=functools.cmp_to_key(_compare_extensions))
preferred_managers = []
for extension in extensions:
if extension.obj.evaluate_hardware_support() > 0:
preferred_managers.append(extension.obj)
LOG.info('Hardware manager found: {}'.format(
extension.entry_point_target))
if not preferred_managers:
raise errors.HardwareManagerNotFound
_global_managers = preferred_managers
return _global_managers
def dispatch_to_all_managers(method, *args, **kwargs):
"""Dispatch a method to all hardware managers.
Dispatches the given method in priority order as sorted by
`_get_managers`. If the method doesn't exist or raises
IncompatibleHardwareMethodError, it continues to the next hardware manager.
All managers that have hardware support for this node will be called,
and their responses will be added to a dictionary of the form
{HardwareManagerClassName: response}.
:param method: hardware manager method to dispatch
:param *args: arguments to dispatched method
:param **kwargs: keyword arguments to dispatched method
:raises errors.HardwareManagerMethodNotFound: if all managers raise
IncompatibleHardwareMethodError.
:returns: a dictionary with keys for each hardware manager that returns
a response and the value as a list of results from that hardware
manager.
"""
responses = {}
managers = _get_managers()
for manager in managers:
if getattr(manager, method, None):
try:
response = getattr(manager, method)(*args, **kwargs)
except errors.IncompatibleHardwareMethodError:
LOG.debug('HardwareManager {} does not support {}'
.format(manager, method))
continue
except Exception as e:
LOG.exception('Unexpected error dispatching %(method)s to '
'manager %(manager)s: %(e)s',
{'method': method, 'manager': manager, 'e': e})
raise
responses[manager.__class__.__name__] = response
else:
LOG.debug('HardwareManager {} does not have method {}'
.format(manager, method))
if responses == {}:
raise errors.HardwareManagerMethodNotFound(method)
return responses
def dispatch_to_managers(method, *args, **kwargs):
"""Dispatch a method to best suited hardware manager.
Dispatches the given method in priority order as sorted by
`_get_managers`. If the method doesn't exist or raises
IncompatibleHardwareMethodError, it is attempted again with a more generic
hardware manager. This continues until a method executes that returns
any result without raising an IncompatibleHardwareMethodError.
:param method: hardware manager method to dispatch
:param *args: arguments to dispatched method
:param **kwargs: keyword arguments to dispatched method
:returns: result of successful dispatch of method
:raises HardwareManagerMethodNotFound: if all managers failed the method
:raises HardwareManagerNotFound: if no valid hardware managers found
"""
managers = _get_managers()
for manager in managers:
if getattr(manager, method, None):
try:
return getattr(manager, method)(*args, **kwargs)
except(errors.IncompatibleHardwareMethodError):
LOG.debug('HardwareManager {} does not support {}'
.format(manager, method))
except Exception as e:
LOG.exception('Unexpected error dispatching %(method)s to '
'manager %(manager)s: %(e)s',
{'method': method, 'manager': manager, 'e': e})
raise
else:
LOG.debug('HardwareManager {} does not have method {}'
.format(manager, method))
raise errors.HardwareManagerMethodNotFound(method)
def load_managers():
"""Preload hardware managers into the cache.
This method is to help warm up the cache for hardware managers when
called. Used to resolve bug 1490008, where agents can crash the first
time a hardware manager is needed.
:raises HardwareManagerNotFound: if no valid hardware managers found
"""
_get_managers()
def cache_node(node):
"""Store the node object in the hardware module.
Stores the node object in the hardware module to facilitate the
access of a node information in the hardware extensions.
:param node: Ironic node object
"""
global NODE
NODE = node
def get_cached_node():
"""Guard function around the module variable NODE."""
return NODE