A Python agent for provisioning and deprovisioning Bare Metal servers.
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# 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 collections
import functools
import ipaddress
import json
from multiprocessing.pool import ThreadPool
import os
import re
import shlex
import string
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 stevedore
import yaml
from ironic_python_agent import encoding
from ironic_python_agent import errors
from ironic_python_agent.extensions import base as ext_base
from ironic_python_agent import netutils
from ironic_python_agent import raid_utils
from ironic_python_agent import tls_utils
from ironic_python_agent import utils
_global_managers = None
LOG = log.getLogger()
CONF = cfg.CONF
WARN_BIOSDEVNAME_NOT_FOUND = False
UNIT_CONVERTER = pint.UnitRegistry(filename=None)
UNIT_CONVERTER.define('bytes = []')
UNIT_CONVERTER.define('MB = 1048576 bytes')
_MEMORY_ID_RE = re.compile(r'^memory(:\d+)?$')
NODE = None
API_CLIENT = None
API_LOOKUP_TIMEOUT = None
API_LOOKUP_INTERVAL = None
SUPPORTED_SOFTWARE_RAID_LEVELS = frozenset(['0', '1', '1+0', '5', '6'])
RAID_APPLY_CONFIGURATION_ARGSINFO = {
"raid_config": {
"description": "The RAID configuration to apply.",
"required": True,
},
"delete_existing": {
"description": (
"Setting this to 'True' indicates to delete existing RAID "
"configuration prior to creating the new configuration. "
"Default value is 'True'."
),
"required": False,
}
}
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 _get_system_lshw_dict():
"""Get a dict representation of the system from lshw
Retrieves a json representation of the system from lshw and converts
it to a python dict
:return: A python dict from the lshw json output
"""
out, _e = utils.execute('lshw', '-quiet', '-json', log_stdout=False)
out = json.loads(out)
# Depending on lshw version, output might be a list, starting with
# https://github.com/lyonel/lshw/commit/135a853c60582b14c5b67e5cd988a8062d9896f4 # noqa
if isinstance(out, list):
return out[0]
return out
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 _get_md_uuid(raid_device):
"""Get the md UUID of a Software RAID device.
:param raid_device: A Software RAID block device name.
:returns: A string containing the UUID of an md device.
"""
try:
out, _ = utils.execute('mdadm', '--detail', raid_device,
use_standard_locale=True)
except processutils.ProcessExecutionError as e:
msg = ('Could not get the details of %(dev)s: %(err)s' %
{'dev': raid_device, 'err': e})
LOG.warning(msg)
return
lines = out.splitlines()
# the first line contains the md device itself
for line in lines[1:]:
match = re.search(r'UUID : ([a-f0-9:]+)', line)
if match:
return match.group(1)
def _get_component_devices(raid_device):
"""Get the component devices of a Software RAID device.
Get the UUID of the md device and scan all other devices
for the same md UUID.
:param raid_device: A Software RAID block device name.
:returns: A list of the component devices.
"""
if not raid_device:
return []
md_uuid = _get_md_uuid(raid_device)
if not md_uuid:
return []
LOG.debug('%s has UUID %s', raid_device, md_uuid)
component_devices = []
block_devices = list_all_block_devices()
block_devices.extend(list_all_block_devices(block_type='part',
ignore_raid=True))
for bdev in block_devices:
try:
out, _ = utils.execute('mdadm', '--examine', bdev.name,
use_standard_locale=True)
except processutils.ProcessExecutionError as e:
if "No md superblock detected" in str(e):
# actually not a component device
LOG.debug('Not a component device %s', bdev.name)
continue
else:
LOG.warning("Failed to examine device %s: %s",
bdev.name, e)
continue
lines = out.splitlines()
for line in lines:
if md_uuid in line:
component_devices.append(bdev.name)
LOG.info('Found component devices for %s: %s',
raid_device, component_devices)
return component_devices
def _calc_memory(sys_dict):
physical = 0
for sys_child in sys_dict['children']:
if sys_child['id'] != 'core':
continue
for core_child in sys_child['children']:
if not _MEMORY_ID_RE.match(core_child['id']):
continue
if (not core_child.get("children")
and core_child.get('size')):
value = ("%(size)s %(units)s" % core_child)
physical += int(UNIT_CONVERTER(value).to
('MB').magnitude)
for bank in core_child.get('children', ()):
if bank.get('size'):
value = ("%(size)s %(units)s" % bank)
physical += int(UNIT_CONVERTER(value).to
('MB').magnitude)
return physical
def get_holder_disks(raid_device):
"""Get the holder disks of a Software RAID device.
Examine an md device and return its underlying disks.
:param raid_device: A Software RAID block device name.
:returns: A list of the holder disks.
"""
if not raid_device:
return []
try:
out, _ = utils.execute('mdadm', '--detail', raid_device,
use_standard_locale=True)
except processutils.ProcessExecutionError as e:
msg = ('Could not get holder disks of %(dev)s: %(err)s' %
{'dev': raid_device, 'err': e})
LOG.warning(msg)
return []
holder_disks = []
lines = out.splitlines()
# the first line contains the md device itself
holder_parts = []
for line in lines[1:]:
device = re.findall(r'/dev/\w+', line)
holder_parts += device
for part in holder_parts:
device = utils.extract_device(part)
if not device:
msg = ('Could not get holder disks of %s: unexpected pattern '
'for partition %s') % (raid_device, part)
raise errors.SoftwareRAIDError(msg)
holder_disks.append(device)
return holder_disks
def is_md_device(raid_device):
"""Check if a device is an md device
Check if a device is a Software RAID (md) device.
:param raid_device: A Software RAID block device name.
:returns: True if the device is an md device, False otherwise.
"""
try:
utils.execute('mdadm', '--detail', raid_device)
LOG.debug("%s is an md device", raid_device)
return True
except FileNotFoundError:
LOG.debug('mdadm has not been found, assuming %s is not an md device',
raid_device)
return False
except processutils.ProcessExecutionError:
LOG.debug("%s is not an md device", raid_device)
return False
def md_restart(raid_device):
"""Restart an md device
Stop and re-assemble a Software RAID (md) device.
:param raid_device: A Software RAID block device name.
:raises: CommandExecutionError in case the restart fails.
"""
try:
LOG.debug('Restarting software RAID device %s', raid_device)
component_devices = _get_component_devices(raid_device)
utils.execute('mdadm', '--stop', raid_device)
utils.execute('mdadm', '--assemble', raid_device,
*component_devices)
except processutils.ProcessExecutionError as e:
error_msg = ('Could not restart md device %(dev)s: %(err)s' %
{'dev': raid_device, 'err': e})
LOG.error(error_msg)
raise errors.CommandExecutionError(error_msg)
def md_get_raid_devices():
"""Get all discovered Software RAID (md) devices
:return: A python dict containing details about the discovered RAID
devices
"""
report = utils.execute('mdadm', '--examine', '--scan')[0]
lines = report.splitlines()
result = {}
for line in lines:
vals = shlex.split(line)
device = vals[1]
result[device] = {}
for key, val in (v.split('=', 1) for v in vals[2:]):
result[device][key] = val.strip()
return result
def _md_scan_and_assemble():
"""Scan all md devices and assemble RAID arrays from them.
This call does not fail if no md devices are present.
"""
try:
utils.execute('mdadm', '--assemble', '--scan', '--verbose')
except FileNotFoundError:
LOG.warning('mdadm has not been found, RAID devices will not be '
'supported')
except processutils.ProcessExecutionError:
LOG.info('No new RAID devices assembled during start-up')
def list_all_block_devices(block_type='disk',
ignore_raid=False,
ignore_floppy=True,
ignore_empty=True):
"""List all physical block devices
The switches we use for lsblk: P for KEY="value" output, b for size output
in bytes, 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
:param ignore_raid: Ignore auto-identified raid devices, example: md0
Defaults to false as these are generally disk
devices and should be treated as such if encountered.
:param ignore_floppy: Ignore floppy disk devices in the block device
list. By default, these devices are filtered out.
:param ignore_empty: Whether to ignore disks with size equal 0.
:return: A list of BlockDevices
"""
def _is_known_device(existing, new_device_name):
"""Return true if device name is already known."""
for known_dev in existing:
if os.path.join('/dev', new_device_name) == known_dev.name:
return True
return False
_udev_settle()
# map device names to /dev/disk/by-path symbolic links that points to it
by_path_mapping = {}
disk_by_path_dir = '/dev/disk/by-path'
try:
paths = os.listdir(disk_by_path_dir)
for path in paths:
path = os.path.join(disk_by_path_dir, path)
# Turn possibly relative symbolic link into absolute
devname = os.path.join(disk_by_path_dir, os.readlink(path))
devname = os.path.abspath(devname)
by_path_mapping[devname] = path
except OSError as e:
# NOTE(TheJulia): This is for multipath detection, and will raise
# some warning logs with unrelated tests.
LOG.warning("Path %(path)s is inaccessible, /dev/disk/by-path/* "
"version of block device name is unavailable "
"Cause: %(error)s", {'path': disk_by_path_dir, 'error': e})
# NOTE(dtantsur): keep in sync with utils.LSBLK_COLUMNS
columns = ['KNAME', 'MODEL', 'SIZE', 'ROTA', 'TYPE']
report = utils.execute('lsblk', '-Pbia', '-o{}'.format(','.join(columns)),
check_exit_code=[0])[0]
lines = report.splitlines()
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
devtype = device.get('TYPE')
# We already have devices, we should ensure we don't store duplicates.
if _is_known_device(devices, device.get('KNAME')):
continue
# If we collected the RM column, we could consult it for removable
# media, however USB devices are also flagged as removable media.
# we have to explicitly do this as floppy disks are type disk.
if ignore_floppy and str(device.get('KNAME')).startswith('fd'):
LOG.debug('Ignoring floppy disk device %s', device)
continue
# Search for raid in the reply type, as RAID is a
# disk device, and we should honor it if is present.
# Other possible type values, which we skip recording:
# lvm, part, rom, loop
if devtype != block_type:
if (devtype is None or ignore_raid):
LOG.debug("Skipping: {!r}".format(line))
continue
elif ('raid' in devtype
and block_type in ['raid', 'disk']):
LOG.debug(
"TYPE detected to contain 'raid', signifying a "
"RAID volume. Found: {!r}".format(line))
elif (devtype == 'md'
and (block_type == 'part'
or block_type == 'md')):
# NOTE(dszumski): Partitions on software RAID devices have type
# 'md'. This may also contain RAID devices in a broken state in
# rare occasions. See https://review.opendev.org/#/c/670807 for
# more detail.
LOG.debug(
"TYPE detected to contain 'md', signifying a "
"RAID partition. Found: {!r}".format(line))
else:
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)))
# NOTE(dtantsur): RAM disks and zRAM devices appear in the output of
# lsblk as disks, but we cannot do anything useful with them.
if (device['KNAME'].startswith('ram')
or device['KNAME'].startswith('zram')):
LOG.debug('Skipping RAM device %s', device)
continue
# NOTE(dtantsur): some hardware represents virtual floppy devices as
# normal block devices with size 0. Filter them out.
if ignore_empty and not int(device['SIZE'] or 0):
LOG.debug('Skipping device %s with zero size', device)
continue
name = os.path.join('/dev', device['KNAME'])
try:
udev = pyudev.Devices.from_device_file(context, name)
except pyudev.DeviceNotFoundByFileError as e:
LOG.warning("Device %(dev)s is inaccessible, skipping... "
"Error: %(error)s", {'dev': name, 'error': e})
extra = {}
except pyudev.DeviceNotFoundByNumberError as e:
LOG.warning("Device %(dev)s is not supported by pyudev, "
"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)
# Not all /dev entries are pointed to from /dev/disk/by-path
by_path_name = by_path_mapping.get(name)
devices.append(BlockDevice(name=name,
model=device['MODEL'],
size=int(device['SIZE'] or 0),
rotational=bool(int(device['ROTA'])),
vendor=_get_device_info(device['KNAME'],
'block', 'vendor'),
by_path=by_path_name,
**extra))
return devices
def save_api_client(client=None, timeout=None, interval=None):
"""Preserves access to the API client for potential later re-use."""
global API_CLIENT, API_LOOKUP_TIMEOUT, API_LOOKUP_INTERVAL
if client and timeout and interval and not API_CLIENT:
API_CLIENT = client
API_LOOKUP_TIMEOUT = timeout
API_LOOKUP_INTERVAL = interval
def update_cached_node():
"""Attmepts to update the node cache via the API"""
cached_node = get_cached_node()
if API_CLIENT:
LOG.info('Agent is requesting to perform an explicit node cache '
'update. This is to pickup any chanages in the cache '
'before deployment.')
try:
if cached_node is None:
uuid = None
else:
uuid = cached_node['uuid']
content = API_CLIENT.lookup_node(
hardware_info=list_hardware_info(use_cache=True),
timeout=API_LOOKUP_TIMEOUT,
starting_interval=API_LOOKUP_INTERVAL,
node_uuid=uuid)
cache_node(content['node'])
return content['node']
except Exception as exc:
LOG.warning('Failed to update node cache. Error %s', exc)
return cached_node
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
class HardwareType(object):
MAC_ADDRESS = 'mac_address'
class BlockDevice(encoding.SerializableComparable):
serializable_fields = ('name', 'model', 'size', 'rotational',
'wwn', 'serial', 'vendor', 'wwn_with_extension',
'wwn_vendor_extension', 'hctl', 'by_path')
def __init__(self, name, model, size, rotational, wwn=None, serial=None,
vendor=None, wwn_with_extension=None,
wwn_vendor_extension=None, hctl=None, by_path=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
self.by_path = by_path
class NetworkInterface(encoding.SerializableComparable):
serializable_fields = ('name', 'mac_address', 'ipv4_address',
'ipv6_address', 'has_carrier', 'lldp',
'vendor', 'product', 'client_id',
'biosdevname')
def __init__(self, name, mac_addr, ipv4_address=None, ipv6_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.ipv6_address = ipv6_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
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 []
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
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
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
class HardwareManager(object, metaclass=abc.ABCMeta):
@abc.abstractmethod
def evaluate_hardware_support(self):
pass
def list_network_interfaces(self):
raise errors.IncompatibleHardwareMethodError
def get_cpus(self):
raise errors.IncompatibleHardwareMethodError
def list_block_devices(self, include_partitions=False):
"""List physical block devices
:param include_partitions: If to include partitions
:return: A list of BlockDevices
"""
raise errors.IncompatibleHardwareMethodError
def get_memory(self):
raise errors.IncompatibleHardwareMethodError
def get_os_install_device(self, permit_refresh=False):
raise errors.IncompatibleHardwareMethodError
def get_bmc_address(self):
raise errors.IncompatibleHardwareMethodError()
def get_bmc_v6address(self):
raise errors.IncompatibleHardwareMethodError()
def get_boot_info(self):
raise errors.IncompatibleHardwareMethodError()
def get_interface_info(self, interface_name):
raise errors.IncompatibleHardwareMethodError()
def generate_tls_certificate(self, ip_address):
raise errors.IncompatibleHardwareMethodError()
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.
This interface could be called concurrently to speed up erasure, as
such, it should be implemented in a thread-safe way.
: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
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()
if not len(block_devices):
return {}
info = node.get('driver_internal_info', {})
max_pool_size = info.get('disk_erasure_concurrency', 1)
thread_pool = ThreadPool(min(max_pool_size, len(block_devices)))
for block_device in block_devices:
params = {'node': node, 'block_device': block_device}
erase_results[block_device.name] = thread_pool.apply_async(
dispatch_to_managers, ('erase_block_device',), params)
thread_pool.close()
thread_pool.join()
for device_name, result in erase_results.items():
erase_results[device_name] = result.get()
return erase_results
def wait_for_disks(self):
"""Wait for the root disk to appear.
Wait for at least one suitable disk to show up or a specific disk
if any device hint is specified. Otherwise neither inspection
not deployment have any chances to succeed.
"""
if not CONF.disk_wait_attempts:
return
max_waits = CONF.disk_wait_attempts - 1
for attempt in range(CONF.disk_wait_attempts):
try:
self.get_os_install_device()
except errors.DeviceNotFound:
LOG.debug('Still waiting for the root device to appear, '
'attempt %d of %d', attempt + 1,
CONF.disk_wait_attempts)
if attempt < max_waits:
time.sleep(CONF.disk_wait_delay)
else:
break
else:
if max_waits:
LOG.warning('The root device was not detected in %d seconds',
CONF.disk_wait_delay * max_waits)
else:
LOG.warning('The root device was not detected')
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
"""
start = time.time()
LOG.info('Collecting full 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['bmc_v6address'] = self.get_bmc_v6address()
hardware_info['system_vendor'] = self.get_system_vendor_info()
hardware_info['boot'] = self.get_boot_info()
hardware_info['hostname'] = netutils.get_hostname()
LOG.info('Inventory collected in %.2f second(s)', time.time() - start)
return hardware_info
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::
{
'interface': the name of the driver interface that should execute
the step.
'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 []
def get_deploy_steps(self, node, ports):
"""Get a list of deploy steps with priority.
Returns a list of steps. Each step is represented by a dict::
{
'interface': the name of the driver interface that should execute
the step.
'step': the HardwareManager function to call.
'priority': the order steps will be run in. Ironic will sort all
the deploy 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 deployment
automatically, but may be requested via deploy
templates.
'reboot_requested': Whether the agent should request Ironic reboots
the node via the power driver after the
operation completes.
'argsinfo': arguments specification.
}
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 deploy step is supported for the node.
:param node: Ironic node object
:param ports: list of Ironic port objects
:return: a list of deploying steps, where each step is described as a
dict as defined above
"""
return []
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')
}
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 = {}
def evaluate_hardware_support(self):
# Do some initialization before we declare ourself ready
_check_for_iscsi()
_md_scan_and_assemble()
self.wait_for_disks()
return HardwareSupport.GENERIC
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)
def get_interface_info(self, interface_name):
mac_addr = netutils.get_mac_addr(interface_name)
if mac_addr is None:
raise errors.IncompatibleHardwareMethodError()
return NetworkInterface(
interface_name, mac_addr,
ipv4_address=self.get_ipv4_addr(interface_name),
ipv6_address=self.get_ipv6_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))
def get_ipv4_addr(self, interface_id):
return netutils.get_ipv4_addr(interface_id)
def get_ipv6_addr(self, interface_id):
"""Get the default IPv6 address assigned to the interface.
With different networking environment, the address could be a
link-local address, ULA or something else.
"""
return netutils.get_ipv6_addr(interface_id)
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.
"""
global WARN_BIOSDEVNAME_NOT_FOUND
if self._is_vlan(interface_name):
LOG.debug('Interface %s is a VLAN, biosdevname not called',
interface_name)
return
try:
stdout, _ = utils.execute('biosdevname', '-i',
interface_name)
return stdout.rstrip('\n')
except OSError:
if not WARN_BIOSDEVNAME_NOT_FOUND:
LOG.warning("Executable 'biosdevname' not found")
WARN_BIOSDEVNAME_NOT_FOUND = True
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)
def _is_vlan(self, interface_name):
# A VLAN interface does not have /device, check naming convention
# used when adding VLAN interface
interface, sep, vlan = interface_name.partition('.')
return vlan.isdigit()
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_vlan(name) or 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:
try:
result = dispatch_to_managers(
'get_interface_info', interface_name=iface_name)
except errors.HardwareManagerMethodNotFound:
LOG.warning('No hardware manager was able to handle '
'interface %s', iface_name)
continue
result.lldp = self._get_lldp_data(iface_name)
network_interfaces_list.append(result)
# If configured, bring up vlan interfaces. If the actual vlans aren't
# defined they are derived from LLDP data
if CONF.enable_vlan_interfaces:
vlan_iface_names = netutils.bring_up_vlan_interfaces(
network_interfaces_list)
for vlan_iface_name in vlan_iface_names:
result = dispatch_to_managers(
'get_interface_info', interface_name=vlan_iface_name)
network_interfaces_list.append(result)
return network_interfaces_list
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)
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:
sys_dict = _get_system_lshw_dict()
except (processutils.ProcessExecutionError, OSError, ValueError) as e:
LOG.warning('Could not get real physical RAM from lshw: %s', e)
physical = None
else:
physical = _calc_memory(sys_dict)
if not physical:
LOG.warning('Did not find any physical RAM')
return Memory(total=total, physical_mb=physical)
def list_block_devices(self, include_partitions=False):
block_devices = list_all_block_devices()
if include_partitions:
block_devices.extend(
list_all_block_devices(block_type='part',
ignore_raid=True)
)
return block_devices
def get_os_install_device(self, permit_refresh=False):
cached_node = get_cached_node()
root_device_hints = None
if cached_node is not None:
root_device_hints = (
cached_node['instance_info'].get('root_device')
or cached_node['properties'].get('root_device'))
if permit_refresh and not root_device_hints:
cached_node = update_cached_node()
root_device_hints = (
cached_node['instance_info'].get('root_device')
or cached_node['properties'].get('root_device'))
LOG.debug('Looking for a device matching root hints %s',
root_device_hints)
block_devices = self.list_block_devices()
if not root_device_hints:
dev_name = 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)
dev_name = device['name']
LOG.info('Picked root device %(dev)s for node %(node)s based on '
'root device hints %(hints)s',
{'dev': dev_name, 'hints': root_device_hints,
'node': cached_node['uuid'] if cached_node else None})
return dev_name
def get_system_vendor_info(self):
try:
sys_dict = _get_system_lshw_dict()
except (processutils.ProcessExecutionError, OSError, ValueError) as e:
LOG.warning('Could not retrieve vendor info from lshw: %s', e)
sys_dict = {}
return SystemVendorInfo(product_name=sys_dict.get('product', ''),
serial_number=sys_dict.get('serial', ''),
manufacturer=sys_dict.get('vendor', ''))
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)
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 erase of virtual media device %s",
block_device.name)
return
if self._is_linux_raid_member(block_device):
LOG.info("Skipping erase of RAID member device %s",
block_device.name)
return
info = node.get('driver_internal_info', {})
if self._is_read_only_device(block_device):
if info.get('agent_erase_skip_read_only', False):
LOG.info("Skipping erase of read-only device %s",
block_device.name)
return
else:
msg = ('Failed to invoke erase of device %(device)s '
'as the device is flagged read-only, and the '
'conductor has not signaled this is a permitted '
'case.' % {'device': block_device.name})
LOG.error(msg)
raise errors.BlockDeviceEraseError(msg)
# Note(TheJulia) Use try/except to capture and log the failure
# and then revert to attempting to shred the volume if enabled.
try:
execute_secure_erase = info.get(
'agent_enable_ata_secure_erase', True)
if execute_secure_erase and self._ata_erase(block_device):
return
except errors.BlockDeviceEraseError as e:
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 erase_devices_metadata(self, node, ports):
"""Attempt to erase the disk devices metadata.
:param node: Ironic node object
:param ports: list of Ironic port objects
:raises BlockDeviceEraseError: when there's an error erasing the
block device
"""
block_devices = self.list_block_devices(include_partitions=True)
# NOTE(coreywright): Reverse sort by device name so a partition (eg
# sda1) is processed before it disappears when its associated disk (eg
# sda) has its partition table erased and the kernel notified.
block_devices.sort(key=lambda dev: dev.name, reverse=True)
erase_errors = {}
for dev in block_devices:
if self._is_virtual_media_device(dev):
LOG.info("Skipping metadata erase of virtual media device %s",
dev.name)
continue
if self._is_linux_raid_member(dev):
LOG.info("Skipping metadata erase of RAID member device %s",
dev.name)
continue
if self._is_read_only_device(dev):
LOG.info("Skipping metadata erase of read-only device %s",
dev.name)
continue
try:
disk_utils.destroy_disk_metadata(dev.name, node['uuid'])
except processutils.ProcessExecutionError as e:
LOG.error('Failed to erase the metadata on device "%(dev)s". '
'Error: %(error)s', {'dev': dev.name, 'error': e})
erase_errors[dev.name] = e
if erase_errors:
excpt_msg = ('Failed to erase the metadata on the device(s): %s' %
'; '.join(['"%s": %s' % (k, v)
for k, v in erase_errors.items()]))
raise errors.BlockDeviceEraseError(excpt_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"
LOG.error(msg, {'dev': block_device.name, 'err': e})
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 _is_linux_raid_member(self, block_device):
"""Check if a block device is a Linux RAID member.
:param block_device: a BlockDevice object
:returns: True if it's Linux RAID member (or if we do not
manage to verify), False otherwise.
"""
try:
# Don't use the '--nodeps' of lsblk to also catch the
# parent device of partitions which are RAID members.
out, _ = utils.execute('lsblk', '--fs', '--noheadings',
block_device.name)
except processutils.ProcessExecutionError as e:
LOG.warning("Could not determine if %s is a RAID member: %s",
block_device.name, e)
return True
return 'linux_raid_member' in out
def _is_read_only_device(self, block_device, partition=False):
"""Check if a block device is read-only.
Checks the device read-only flag in order to identify virtual
and firmware driven devices that block write device access.
:param block_device: a BlockDevice object
:param partition: if True, this device is a partition
:returns: True if the device is read-only.
"""
try:
dev_name = os.path.basename(block_device.name)
if partition:
# Check the base device
dev_name = dev_name.rstrip(string.digits)
with open('/sys/block/%s/ro' % dev_name, 'r') as f:
flag = f.read().strip()
if flag == '1':
return True
except IOError as e:
# Check underlying device as the file may exist there
if (not partition and dev_name[-1].isdigit()
and 'nvme' not in dev_name):
return self._is_read_only_device(block_device, partition=True)
LOG.warning("Could not determine if %(name)s is a"
"read-only device. Error: %(err)s",
{'name': block_device.name, 'err': e})
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 _smartctl_security_check(self, block_device):
"""Checks if we can query security via smartctl.
:param block_device: A block_device object
:returns: True if we can query the block device via ATA
or the smartctl binary is not present.
False if we cannot query the device.
"""
try:
# NOTE(TheJulia): smartctl has a concept of drivers being how
# to query or interpret data from the device. We want to use `ata`
# instead of `scsi` or `sat` as smartctl will not be able to read
# a bridged device that it doesn't understand, and accordingly
# return an error code.
output = utils.execute('smartctl', '-d', 'ata', block_device.name,
'-g', 'security',
check_exit_code=[0, 127])[0]
if 'Unavailable' in output:
# Smartctl is reporting it is unavailable, lets return false.
LOG.debug('Smartctl has reported that security is '
'unavailable on device %s.', block_device.name)
return False
return True
except processutils.ProcessExecutionError:
# Things don't look so good....
LOG.warning('Refusing to permit ATA Secure Erase as direct '
'ATA commands via the `smartctl` utility with device '
'%s do not succeed.', block_device.name)
return False
except OSError:
# Processutils can raise OSError if a path is not found,
# and it is okay that we tollerate that since it was the
# prior behavior.
return True
def _ata_erase(self, block_device):
def __attempt_unlock_drive(block_device, security_lines=None):
# Attempt to unlock the drive in the event it has already been
# locked by a previous failed attempt. We try the empty string as
# versions of hdparm < 9.51, interpreted NULL as the literal
# string, "NULL", as opposed to the empty string.
if not security_lines:
security_lines = self._get_ata_security_lines(block_device)
unlock_passwords = ['NULL', '']
for password in unlock_passwords:
if 'not locked' in security_lines:
break
try:
utils.execute('hdparm', '--user-master', 'u',
'--security-unlock', password,
block_device.name)
except processutils.ProcessExecutionError as e:
LOG.info('Security unlock failed for device '
'%(name)s using password "%(password)s": %(err)s',
{'name': block_device.name,
'password': password,
'err': e})
security_lines = self._get_ata_security_lines(block_device)
return security_lines
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 (not self._smartctl_security_check(block_device)
or 'supported' not in security_lines):
return False
# At this point, we could be SEC1,2,4,5,6
if 'not frozen' not in security_lines:
# In SEC2 or 6
raise errors.BlockDeviceEraseError(
('Block device {} is frozen and cannot be erased'
).format(block_device.name))
# At this point, we could be in SEC1,4,5
# Attempt to unlock the drive if it has failed in a prior attempt.
security_lines = __attempt_unlock_drive(block_device, security_lines)
# If the unlock failed we will still be in SEC4, otherwise, we will be
# in SEC1 or SEC5
if 'not locked' not in security_lines:
# In SEC4
raise errors.BlockDeviceEraseError(
('Block device {} already has a security password set'
).format(block_device.name))
# At this point, we could be in SEC1 or 5
if 'not enabled' in security_lines:
# SEC1. Try to transition to SEC5 by setting empty user
# password.
try:
utils.execute('hdparm', '--user-master', 'u',
'--security-set-pass', 'NULL', block_device.name)
except processutils.ProcessExecutionError as e:
error_msg = ('Security password set failed for device '
'{name}: {err}'
).format(name=block_device.name, err=e)
raise errors.BlockDeviceEraseError(error_msg)
# 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:
# NOTE(TheJulia): Attempt unlock to allow fallback to shred
# to occur, otherwise shred will fail as well, as the security
# mode will prevent IO operations to the disk.
__attempt_unlock_drive(block_device)
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:
# Not SEC1 - fail
raise errors.BlockDeviceEraseError(
('An unknown error occurred erasing block device {}'
).format(block_device.name))
# In SEC1 security state
return True
def get_bmc_address(self):
"""Attempt to detect BMC IP address
:return: IP address of lan channel or 0.0.0.0 in case none of them is
configured properly
"""
# 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:
# From all the channels 0-15, only 1-11 can be assigned to
# different types of communication media and protocols and
# effectively used
for channel in range(1, 12):
out, e = utils.execute(
"ipmitool lan print {} | awk '/IP Address[ \\t]*:/"
" {{print $4}}'".format(channel), shell=True)
if e.startswith("Invalid channel"):
continue
out = out.strip()
try:
ipaddress.ip_address(out)
except ValueError as exc:
LOG.warning('Invalid IP address %s: %s', out, exc)
continue
# In case we get 0.0.0.0 on a valid channel, we need to keep
# querying
if out != '0.0.0.0':
return out
except (processutils.ProcessExecutionError, OSError) as e:
# Not error, because it's normal in virtual environment
LOG.warning("Cannot get BMC address: %s", e)
return
return '0.0.0.0'
def get_bmc_v6address(self):
"""Attempt to detect BMC v6 address
:return: IPv6 address of lan channel or ::/0 in case none of them is
configured properly. May return None value if it cannot
interract with system tools or critical error occurs.
"""
# These modules are rarely loaded automatically
utils.try_execute('modprobe', 'ipmi_msghandler')
utils.try_execute('modprobe', 'ipmi_devintf')
utils.try_execute('modprobe', 'ipmi_si')
null_address_re = re.compile(r'^::(/\d{1,3})*$')
def get_addr(channel, dynamic=False):
cmd = "ipmitool lan6 print {} {}_addr".format(
channel, 'dynamic' if dynamic else 'static')
try:
out, exc = utils.execute(cmd, shell=True)
except processutils.ProcessExecutionError:
return
# NOTE: More likely ipmitool was not intended to return
# stdout in yaml format. Fortunately, output of
# dynamic_addr and static_addr commands is a valid yaml.
try:
out = yaml.safe_load(out.strip())
except yaml.YAMLError as excpt:
LOG.warning('Cannot process output of "%(cmd)s" '
'command: %(e)s', {'cmd': cmd, 'e': excpt})
return
for addr_dict in out.values():
address = addr_dict['Address']
if dynamic:
enabled = addr_dict['Source/Type'] in ['DHCPv6', 'SLAAC']
else:
enabled = addr_dict['Enabled']
if addr_dict['Status'] == 'active' and enabled \
and not null_address_re.match(address):
return address
try:
# From all the channels 0-15, only 1-11 can be assigned to
# different types of communication media and protocols and
# effectively used
for channel in range(1, 12):
addr_mode, e = utils.execute(
r"ipmitool lan6 print {} enables | "
r"awk '/IPv6\/IPv4 Addressing Enables[ \t]*:/"
r"{{print $NF}}'".format(channel), shell=True)
if addr_mode.strip() not in ['ipv6', 'both']:
continue
address = get_addr(channel, dynamic=True) or get_addr(channel)
if not address:
continue
try:
return str(ipaddress.ip_interface(address).ip)
except ValueError as exc:
LOG.warning('Invalid IP address %s: %s', address, exc)
continue
except (processutils.ProcessExecutionError, OSError) as exc:
# Not error, because it's normal in virtual environment
LOG.warning("Cannot get BMC v6 address: %s", exc)
return
return '::/0'
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
},
{
'step': 'delete_configuration',
'priority': 0,
'interface': 'raid',
'reboot_requested': False,
'abortable': True
},
{
'step': 'create_configuration',
'priority': 0,
'interface': 'raid',
'reboot_requested': False,
'abortable': True
}
]
def get_deploy_steps(self, node, ports):
return [
{
'step': 'erase_devices_metadata',
'priority': 0,
'interface': 'deploy',
'reboot_requested': False,
},
{
'step': 'apply_configuration',
'priority': 0,
'interface': 'raid',
'reboot_requested': False,
'argsinfo': RAID_APPLY_CONFIGURATION_ARGSINFO,
},
{
'step': 'write_image',
# NOTE(dtantsur): this step has to be proxied via an
# out-of-band step with the same name, hence the priority here
# doesn't really matter.
'priority': 0,
'interface': 'deploy',
'reboot_requested': False,
},
]
def apply_configuration(self, node, ports, raid_config,
delete_existing=True):
"""Apply RAID configuration.
:param node: A dictionary of the node object.
:param ports: A list of dictionaries containing information
of ports for the node.
:param raid_config: The configuration to apply.
:param delete_existing: Whether to delete the existing configuration.
"""
self.validate_configuration(raid_config, node)
if delete_existing:
self.delete_configuration(node, ports)
return self._do_create_configuration(node, ports, raid_config)
def create_configuration(self, node, ports):
"""Create a RAID configuration.
Unless overwritten by a local hardware manager, this method
will create a software RAID configuration as read from the
node's 'target_raid_config'.
:param node: A dictionary of the node object.
:param ports: A list of dictionaries containing information
of ports for the node.
:returns: The current RAID configuration in the usual format.
:raises: SoftwareRAIDError if the desired configuration is not
valid or if there was an error when creating the RAID
devices.
"""
raid_config = node.get('target_raid_config', {})
if not raid_config:
LOG.debug("No target_raid_config found")
return {}
return self._do_create_configuration(node, ports, raid_config)
def _do_create_configuration(self, node, ports, raid_config):
# incr starts to 1
# It means md0 is on the partition 1, md1 on 2...
# incr could be incremented if we ever decide, for example to create
# some additional partitions here (boot partitions)
incr = 1
# No 'software' controller: do nothing. If 'controller' is
# set to 'software' on only one of the drives, the validation
# code will catch it.
software_raid = False
logical_disks = raid_config.get('logical_disks')
for logical_disk in logical_disks:
if logical_disk.get('controller') == 'software':
software_raid = True
break
if not software_raid:
LOG.debug("No Software RAID config found")
return {}
LOG.info("Creating Software RAID")
# Check if the config is compliant with current limitations.
self.validate_configuration(raid_config, node)
# Log the validated target_raid_configuration.
LOG.debug("Target Software RAID configuration: %s", raid_config)
block_devices, logical_disks = raid_utils.get_block_devices_for_raid(
self.list_block_devices(), logical_disks)
# Make sure there are no partitions yet (or left behind).
with_parts = []
for dev_name in block_devices:
try:
if disk_utils.list_partitions(dev_name):
with_parts.append(dev_name)
except processutils.ProcessExecutionError:
# Presumably no partitions (or no partition table)
continue
if with_parts:
msg = ("Partitions detected on devices %s during RAID config"
% ', '.join(with_parts))
raise errors.SoftwareRAIDError(msg)
partition_table_type = utils.get_partition_table_type_from_specs(node)
target_boot_mode = utils.get_node_boot_mode(node)
parted_start_dict = raid_utils.create_raid_partition_tables(
block_devices, partition_table_type, target_boot_mode)
LOG.debug("First available sectors per devices %s", parted_start_dict)
# Reorder logical disks so that MAX comes last if any:
reordered_logical_disks = []
max_disk = None
for logical_disk in logical_disks:
psize = logical_disk['size_gb']
if psize == 'MAX':
max_disk = logical_disk
else:
reordered_logical_disks.append(logical_disk)
if max_disk:
reordered_logical_disks.append(max_disk)
logical_disks = reordered_logical_disks
# With the partitioning below, the first partition is not
# exactly the size_gb provided, but rather the size minus a small
# amount (often 2048*512B=1MiB, depending on the disk geometry).
# Easier to ignore. Another way could be to use sgdisk, which is really
# user-friendly to compute part boundaries automatically, instead of
# parted, then convert back to mbr table if needed and possible.
for logical_disk in logical_disks:
# Note: from the doc,
# https://docs.openstack.org/ironic/latest/admin/raid.html#target-raid-configuration
# size_gb unit is GiB
psize = logical_disk['size_gb']
if psize == 'MAX':
psize = -1
else:
psize = int(psize)
# NOTE(dtantsur): populated in get_block_devices_for_raid
disk_names = logical_disk['block_devices']
for device in disk_names:
start = parted_start_dict[device]
start_str, end_str, end = (
raid_utils.calc_raid_partition_sectors(psize, start)
)
try:
LOG.debug("Creating partition on {}: {} {}".format(
device, start_str, end_str))
utils.execute('parted', device, '-s', '-a',
'optimal', '--', 'mkpart', 'primary',
start_str, end_str)
# Necessary, if we want to avoid hitting
# an error when creating the mdadm array below
# 'mdadm: cannot open /dev/nvme1n1p1: No such file
# or directory'.
# The real difference between partx and partprobe is
# unclear, but note that partprobe does not seem to
# work synchronously for nvme drives...
utils.execute("partx", "-u", device,
check_exit_code=False)
except processutils.ProcessExecutionError as e:
msg = "Failed to create partitions on {}: {}".format(
device, e)
raise errors.SoftwareRAIDError(msg)
parted_start_dict[device] = end
# Create the RAID devices.
for index, logical_disk in enumerate(logical_disks):
md_device = '/dev/md%d' % index
component_devices = []
for device in logical_disk['block_devices']:
# The partition delimiter for all common harddrives (sd[a-z]+)
part_delimiter = ''
if 'nvme' in device:
part_delimiter = 'p'
component_devices.append(
device + part_delimiter + str(index + incr))
raid_level = logical_disk['raid_level']
# The schema check allows '1+0', but mdadm knows it as '10'.
if raid_level == '1+0':
raid_level = '10'
try:
LOG.debug("Creating md device {} on {}".format(
md_device, component_devices))
utils.execute('mdadm', '--create', md_device, '--force',
'--run', '--metadata=1', '--level', raid_level,
'--raid-devices', len(component_devices),
*component_devices)
except processutils.ProcessExecutionError as e:
msg = "Failed to create md device {} on {}: {}".format(
md_device, ' '.join(component_devices), e)
raise errors.SoftwareRAIDError(msg)
LOG.info("Successfully created Software RAID")
return raid_config
def delete_configuration(self, node, ports):
"""Delete a RAID configuration.
Unless overwritten by a local hardware manager, this method
will delete all software RAID devices on the node.
NOTE(arne_wiebalck): It may be worth considering to only
delete RAID devices in the node's 'target_raid_config'. If
that config has been lost, though, the cleanup may become
difficult. So, for now, we delete everything we detect.
:param node: A dictionary of the node object
:param ports: A list of dictionaries containing information
of ports for the node
"""
def _scan_raids():
utils.execute('mdadm', '--assemble', '--scan',
check_exit_code=False)
raid_devices = list_all_block_devices(block_type='raid',
ignore_raid=False,
ignore_empty=False)
# NOTE(dszumski): Fetch all devices of type 'md'. This
# will generally contain partitions on a software RAID
# device, but crucially may also contain devices in a
# broken state. See https://review.opendev.org/#/c/670807/
# for more detail.
raid_devices.extend(
list_all_block_devices(block_type='md',
ignore_raid=False,
ignore_empty=False)
)
return raid_devices
raid_devices = _scan_raids()
attempts = 0
while attempts < 2:
attempts += 1
self._delete_config_pass(raid_devices)
raid_devices = _scan_raids()
if not raid_devices:
break
else:
msg = "Unable to clean all softraid correctly. Remaining {}".\
format([dev.name for dev in raid_devices])
LOG.error(msg)
raise errors.SoftwareRAIDError(msg)
def _delete_config_pass(self, raid_devices):
all_holder_disks = []
for raid_device in raid_devices:
component_devices = _get_component_devices(raid_device.name)
if not component_devices:
# A "Software RAID device" without components is usually
# a partition on an md device (as, for instance, created
# by the conductor for the config drive). This will be
# cleaned with the hosting md device.
msg = ("Software RAID cleaning is skipping "
"partition %s" % raid_device.name)
LOG.info(msg)
continue
holder_disks = get_holder_disks(raid_device.name)
LOG.info("Deleting Software RAID device {}".format(
raid_device.name))
LOG.debug('Found component devices %s', component_devices)
LOG.debug('Found holder disks %s', holder_disks)
# Remove md devices.
try:
utils.execute('wipefs', '-af', raid_device.name)
except processutils.ProcessExecutionError as e:
LOG.warning('Failed to wipefs %s: %s',
raid_device.name, e)
try:
utils.execute('mdadm', '--stop', raid_device.name)
except processutils.ProcessExecutionError as e:
LOG.warning('Failed to stop %s: %s',
raid_device.name, e)
# Remove md metadata from component devices.
for component_device in component_devices:
try:
utils.execute('mdadm', '--examine', component_device,
use_standard_locale=True)
except processutils.ProcessExecutionError as e:
if "No md superblock detected" in str(e):
# actually not a component device
continue
else:
msg = "Failed to examine device {}: {}".format(
component_device, e)
raise errors.SoftwareRAIDError(msg)
LOG.debug('Deleting md superblock on %s', component_device)
try:
utils.execute('mdadm', '--zero-superblock',
component_device)
except processutils.ProcessExecutionError as e:
LOG.warning('Failed to remove superblock from %s: %s',
raid_device.name, e)
# NOTE(arne_wiebalck): We cannot delete the partitions right
# away since there may be other partitions on the same disks
# which are members of other RAID devices. So we remember them
# for later.
all_holder_disks.extend(holder_disks)
LOG.info('Deleted Software RAID device %s', raid_device.name)
# Remove all remaining raid traces from any drives, in case some
# drives or partitions have been member of some raid once
# TBD: should we consider all block devices by default, but still
# provide some 'control' through the node information
# (for example target_raid_config at the time of calling this). This
# may make sense if you do not want the delete_config to touch some
# drives, like cinder volumes locally attached, for example, or any
# kind of 'non-ephemeral' drive that you do not want to consider during
# deployment (= specify which drives to consider just like create
# configuration might consider the physical_disks parameter in a near
# future)
# Consider partitions first, before underlying disks, never hurts and
# can even avoid some failures. Example to reproduce:
# mdadm --stop /dev/md0
# mdadm --zero-superblock /dev/block
# mdadm: Unrecognised md component device - /dev/block
# (mdadm -E /dev/block still returns 0 so won't be skipped for zeroing)
# mdadm --zero-superblock /dev/block1
# mdadm: Couldn't open /dev/block for write - not zeroing
# mdadm -E /dev/block1: still shows superblocks
all_blks = reversed(self.list_block_devices(include_partitions=True))
for blk in all_blks:
try:
utils.execute('mdadm', '--examine', blk.name,
use_standard_locale=True)
except processutils.ProcessExecutionError as e:
if "No md superblock detected" in str(e):
# actually not a component device
continue
else:
msg = "Failed to examine device {}: {}".format(
blk.name, e)
LOG.warning(msg)
continue
try:
utils.execute('mdadm', '--zero-superblock', blk.name)
except processutils.ProcessExecutionError as e:
LOG.warning('Failed to remove superblock from %s: %s',
raid_device.name, e)
# Erase all partition tables we created
all_holder_disks_uniq = list(
collections.OrderedDict.fromkeys(all_holder_disks))
for holder_disk in all_holder_disks_uniq:
LOG.info('Removing partitions on holder disk %s', holder_disk)
try:
utils.execute('wipefs', '-af', holder_disk)
except processutils.ProcessExecutionError as e:
LOG.warning('Failed to remove partitions on %s: %s',
holder_disk, e)
LOG.debug("Finished deleting Software RAID(s)")
def validate_configuration(self, raid_config, node):
"""Validate a (software) RAID configuration
Validate a given raid_config, in particular with respect to
the limitations of the current implementation of software
RAID support.
:param raid_config: The current RAID configuration in the usual format.
"""
LOG.debug("Validating Software RAID config: {}".format(raid_config))
if not raid_config:
LOG.error("No RAID config passed")
return False
logical_disks = raid_config.get('logical_disks')
if not logical_disks:
msg = "RAID config contains no logical disks"
raise errors.SoftwareRAIDError(msg)
raid_errors = []
# Only one or two RAID devices are supported for now.
if len(logical_disks) not in [1, 2]:
msg = ("Software RAID configuration requires one or "
"two logical disks")
raid_errors.append(msg)
# All disks need to be flagged for Software RAID
for logical_disk in logical_disks:
if logical_disk.get('controller') != 'software':
msg = ("Software RAID configuration requires all logical "
"disks to have 'controller'='software'")
raid_errors.append(msg)
physical_disks = logical_disk.get('physical_disks')
if physical_disks is not None:
if (not isinstance(physical_disks, list)
or len(physical_disks) < 2):
msg = ("The physical_disks parameter for software RAID "
"must be a list with at least 2 items, each "
"specifying a disk in the device hints format")
raid_errors.append(msg)
if any(not isinstance(item, dict) for item in physical_disks):
msg = ("The physical_disks parameter for software RAID "
"must be a list of device hints (dictionaries)")
raid_errors.append(msg)
# The first RAID device needs to be RAID-1.
if logical_disks[0]['raid_level'] != '1':
msg = ("Software RAID Configuration requires RAID-1 for the "
"first logical disk")
raid_errors.append(msg)
# Additional checks when we have two RAID devices.
if len(logical_disks) == 2:
size1 = logical_disks[0]['size_gb']
size2 = logical_disks[1]['size_gb']
# Only one logical disk is allowed to span the whole device.
if size1 == 'MAX' and size2 == 'MAX':
msg = ("Software RAID can have only one RAID device with "
"size 'MAX'")
raid_errors.append(msg)
# Check the accepted RAID levels.
current_level = logical_disks[1]['raid_level']
if current_level not in SUPPORTED_SOFTWARE_RAID_LEVELS:
msg = ("Software RAID configuration does not support "
"RAID level %s" % current_level)
raid_errors.append(msg)
physical_device_count = len(self.list_block_devices())
if current_level == '5' and physical_device_count < 3:
msg = ("Software RAID configuration is not possible for "
"RAID level 5 with only %s block devices found."
% physical_device_count)
raid_errors.append(msg)
if current_level == '6' and physical_device_count < 4:
msg = ("Software RAID configuration is not possible for "
"RAID level 6 with only %s block devices found."
% physical_device_count)
raid_errors.append(msg)
if raid_errors:
error = ('Could not validate Software RAID config for %(node)s: '
'%(errors)s') % {'node': node['uuid'],
'errors': '; '.join(raid_errors)}
raise errors.SoftwareRAIDError(error)
def write_image(self, node, ports, image_info, configdrive=None):
"""A deploy step to write an image.
Downloads and writes an image to disk if necessary. Also writes a
configdrive to disk if the configdrive parameter is specified.
:param node: A dictionary of the node object
:param ports: A list of dictionaries containing information
of ports for the node
:param image_info: Image information dictionary.
:param configdrive: A string containing the location of the config
drive as a URL OR the contents (as gzip/base64)
of the configdrive. Optional, defaults to None.
"""
ext = ext_base.get_extension('standby')
cmd = ext.prepare_image(image_info=image_info, configdrive=configdrive)
# The result is asynchronous, wait here.
return cmd.wait()
def generate_tls_certificate(self, ip_address):
"""Generate a TLS certificate for the IP address."""
return tls_utils.generate_tls_certificate(ip_address)
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).
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)
_CACHED_HW_INFO = None
def list_hardware_info(use_cache=True):
"""List hardware information with caching."""
global _CACHED_HW_INFO
if _CACHED_HW_INFO is None:
_CACHED_HW_INFO = dispatch_to_managers('list_hardware_info')
return _CACHED_HW_INFO
if use_cache:
return _CACHED_HW_INFO
else:
return dispatch_to_managers('list_hardware_info')
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.
If the new node does not match the previously cached one, wait for the
expected root device to appear.
:param node: Ironic node object
:param wait_for_disks: Default True switch to wait for disk setup to be
completed so the node information can be aligned
with the physical storage devices of the host.
This is likely to be used in unit testing.
"""
global NODE
new_node = NODE is None or NODE['uuid'] != node['uuid']
NODE = node
if new_node:
LOG.info('Cached node %s, waiting for its root device to appear',
node['uuid'])
# Root device hints, stored in the new node, can change the expected
# root device. So let us wait for it to appear again.
dispatch_to_managers('wait_for_disks')
def get_cached_node():
"""Guard function around the module variable NODE."""
return NODE
def get_current_versions():
"""Fetches versions from all hardware managers.
:returns: Dict in the format {name: version} containing one entry for
every hardware manager.
"""
return {version.get('name'): version.get('version')
for version in dispatch_to_all_managers('get_version').values()}
def check_versions(provided_version=None):
"""Ensure the version of hardware managers hasn't changed.
:param provided_version: Hardware manager versions used by ironic.
:raises: errors.VersionMismatch if any hardware manager version on
the currently running agent doesn't match the one stored in
provided_version.
:returns: None
"""
# If the version is None, assume this is the first run
if provided_version is None:
return
agent_version = get_current_versions()
if provided_version != agent_version:
LOG.warning('Mismatched hardware managers versions. Agent version: '
'%(agent)s, node version: %(node)s',
{'agent': agent_version, 'node': provided_version})
raise errors.VersionMismatch(agent_version=agent_version,
node_version=provided_version)
def _step_sort_key(step):
return (-step['hwm']['support'], -step['priority'], step['hwm']['name'])
def deduplicate_steps(candidate_steps):
"""Remove duplicated clean or deploy steps
Deduplicates steps returned from HardwareManagers to prevent running
a given step more than once. Other than individual step priority,
it doesn't actually impact the deployment which specific steps are kept
and what HardwareManager they are associated with.
However, in order to make testing easier, this method returns
deterministic results.
Uses the following filtering logic to decide which 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.
:param candidate_steps: A dict containing all possible steps from
all managers, key=manager, value=list of steps
:returns: A deduplicated dictionary of {hardware_manager: [steps]}
"""
support = dispatch_to_all_managers(
'evaluate_hardware_support')
steps = collections.defaultdict(list)
deduped_steps = collections.defaultdict(list)
for manager, manager_steps in candidate_steps.items():
# We cannot deduplicate steps with unknown hardware support
if manager not in support:
LOG.warning('Unknown hardware support for %(manager)s, '
'dropping steps: %(steps)s',
{'manager': manager, 'steps': manager_steps})
continue
for step in manager_steps:
# build a new dict of steps that's easier to filter
step['hwm'] = {'name': manager,
'support': support[manager]}
steps[step['step']].append(step)
for step_name, step_list in steps.items():
winning_step = sorted(step_list, key=_step_sort_key)[0]
# Remove extra metadata we added to the step for filtering
manager = winning_step.pop('hwm')['name']
# Add winning step to deduped_steps
deduped_steps[manager].append(winning_step)
return deduped_steps