pvc/daemon-common/ceph.py

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#!/usr/bin/env python3
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# ceph.py - PVC client function library, Ceph cluster fuctions
# Part of the Parallel Virtual Cluster (PVC) system
#
# Copyright (C) 2018-2024 Joshua M. Boniface <joshua@boniface.me>
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#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, version 3.
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#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <https://www.gnu.org/licenses/>.
#
###############################################################################
import os
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import re
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import json
import time
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import math
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from concurrent.futures import ThreadPoolExecutor
from distutils.util import strtobool
from json import loads as jloads
from re import match, search
from uuid import uuid4
from os import path
import daemon_lib.vm as vm
import daemon_lib.common as common
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from daemon_lib.celery import start, log_info, log_warn, update, fail, finish
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#
# Supplemental functions
#
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# Verify OSD is valid in cluster
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def verifyOSD(zkhandler, osd_id):
return zkhandler.exists(("osd", osd_id))
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# Verify Pool is valid in cluster
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def verifyPool(zkhandler, name):
return zkhandler.exists(("pool", name))
# Verify Volume is valid in cluster
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def verifyVolume(zkhandler, pool, name):
return zkhandler.exists(("volume", f"{pool}/{name}"))
# Verify Snapshot is valid in cluster
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def verifySnapshot(zkhandler, pool, volume, name):
return zkhandler.exists(("snapshot", f"{pool}/{volume}/{name}"))
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# Verify OSD path is valid in cluster
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def verifyOSDBlock(zkhandler, node, device):
for osd in zkhandler.children("base.osd"):
osd_node = zkhandler.read(("osd.node", osd))
osd_device = zkhandler.read(("osd.device", osd))
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if node == osd_node and device == osd_device:
return osd
return None
# Matrix of human-to-byte values
byte_unit_matrix = {
"B": 1,
"K": 1024,
"M": 1024 * 1024,
"G": 1024 * 1024 * 1024,
"T": 1024 * 1024 * 1024 * 1024,
"P": 1024 * 1024 * 1024 * 1024 * 1024,
"E": 1024 * 1024 * 1024 * 1024 * 1024 * 1024,
"Z": 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024,
"Y": 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024,
"R": 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024,
"Q": 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024 * 1024,
}
# Matrix of human-to-metric values
ops_unit_matrix = {
"": 1,
"K": 1000,
"M": 1000 * 1000,
"G": 1000 * 1000 * 1000,
"T": 1000 * 1000 * 1000 * 1000,
"P": 1000 * 1000 * 1000 * 1000 * 1000,
"E": 1000 * 1000 * 1000 * 1000 * 1000 * 1000,
"Z": 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000,
"Y": 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000,
"R": 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000,
"Q": 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000 * 1000,
}
# Format byte sizes to/from human-readable units
def format_bytes_tohuman(databytes):
datahuman = ""
for unit in sorted(byte_unit_matrix, key=byte_unit_matrix.get, reverse=True):
new_bytes = int(math.ceil(databytes / byte_unit_matrix[unit]))
# Round up if 5 or more digits
if new_bytes > 9999:
# We can jump down another level
continue
else:
# We're at the end, display with this size
datahuman = "{}{}".format(new_bytes, unit)
return datahuman
def format_bytes_fromhuman(datahuman):
if not isinstance(datahuman, str):
datahuman = str(datahuman)
if not re.search(r"[A-Za-z]+", datahuman):
dataunit = "B"
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datasize = float(datahuman)
else:
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dataunit = str(re.match(r"[0-9\.]+([A-Za-z])[iBb]*", datahuman).group(1))
datasize = float(re.match(r"([0-9\.]+)[A-Za-z]+", datahuman).group(1))
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if byte_unit_matrix.get(dataunit.upper()):
databytes = int(datasize * byte_unit_matrix[dataunit.upper()])
return databytes
else:
return None
# Format ops sizes to/from human-readable units
def format_ops_tohuman(dataops):
datahuman = ""
for unit in sorted(ops_unit_matrix, key=ops_unit_matrix.get, reverse=True):
new_ops = int(math.ceil(dataops / ops_unit_matrix[unit]))
# Round up if 5 or more digits
if new_ops > 9999:
# We can jump down another level
continue
else:
# We're at the end, display with this size
datahuman = "{}{}".format(new_ops, unit)
return datahuman
def format_ops_fromhuman(datahuman):
# Trim off human-readable character
dataunit = datahuman[-1]
datasize = int(datahuman[:-1])
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dataops = datasize * ops_unit_matrix[dataunit.upper()]
return "{}".format(dataops)
def format_pct_tohuman(datapct):
datahuman = "{0:.1f}".format(float(datapct * 100.0))
return datahuman
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#
# Status functions
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#
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def get_status(zkhandler):
primary_node = zkhandler.read("base.config.primary_node")
ceph_status = zkhandler.read("base.storage").rstrip()
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# Create a data structure for the information
status_data = {
"type": "status",
"primary_node": primary_node,
"ceph_data": ceph_status,
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}
return True, status_data
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def get_health(zkhandler):
primary_node = zkhandler.read("base.config.primary_node")
ceph_health = zkhandler.read("base.storage.health").rstrip()
# Create a data structure for the information
status_data = {
"type": "health",
"primary_node": primary_node,
"ceph_data": ceph_health,
}
return True, status_data
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def get_util(zkhandler):
primary_node = zkhandler.read("base.config.primary_node")
ceph_df = zkhandler.read("base.storage.util").rstrip()
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# Create a data structure for the information
status_data = {
"type": "utilization",
"primary_node": primary_node,
"ceph_data": ceph_df,
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}
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return True, status_data
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#
# OSD functions
#
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def getClusterOSDList(zkhandler):
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# Get a list of VNIs by listing the children of /networks
return zkhandler.children("base.osd")
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def getOSDInformation(zkhandler, osd_id):
(
osd_fsid,
osd_node,
osd_device,
_osd_is_split,
osd_db_device,
osd_stats_raw,
) = zkhandler.read_many(
[
("osd.ofsid", osd_id),
("osd.node", osd_id),
("osd.device", osd_id),
("osd.is_split", osd_id),
("osd.db_device", osd_id),
("osd.stats", osd_id),
]
)
osd_is_split = bool(strtobool(_osd_is_split))
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# Parse the stats data
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osd_stats = dict(json.loads(osd_stats_raw))
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osd_information = {
"id": osd_id,
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"fsid": osd_fsid,
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"node": osd_node,
"device": osd_device,
"is_split": osd_is_split,
"db_device": osd_db_device,
"stats": osd_stats,
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}
return osd_information
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def in_osd(zkhandler, osd_id):
if not verifyOSD(zkhandler, osd_id):
return False, 'ERROR: No OSD with ID "{}" is present in the cluster.'.format(
osd_id
)
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retcode, stdout, stderr = common.run_os_command("ceph osd in {}".format(osd_id))
if retcode:
return False, "ERROR: Failed to enable OSD {}: {}".format(osd_id, stderr)
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return True, "Set OSD {} online.".format(osd_id)
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def out_osd(zkhandler, osd_id):
if not verifyOSD(zkhandler, osd_id):
return False, 'ERROR: No OSD with ID "{}" is present in the cluster.'.format(
osd_id
)
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retcode, stdout, stderr = common.run_os_command("ceph osd out {}".format(osd_id))
if retcode:
return False, "ERROR: Failed to disable OSD {}: {}".format(osd_id, stderr)
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return True, "Set OSD {} offline.".format(osd_id)
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def set_osd(zkhandler, option):
retcode, stdout, stderr = common.run_os_command("ceph osd set {}".format(option))
if retcode:
return False, 'ERROR: Failed to set property "{}": {}'.format(option, stderr)
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return True, 'Set OSD property "{}".'.format(option)
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def unset_osd(zkhandler, option):
retcode, stdout, stderr = common.run_os_command("ceph osd unset {}".format(option))
if retcode:
return False, 'ERROR: Failed to unset property "{}": {}'.format(option, stderr)
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return True, 'Unset OSD property "{}".'.format(option)
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def get_list_osd(zkhandler, limit=None, is_fuzzy=True):
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osd_list = []
full_osd_list = zkhandler.children("base.osd")
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if is_fuzzy and limit:
# Implicitly assume fuzzy limits
if not re.match(r"\^.*", limit):
limit = ".*" + limit
if not re.match(r".*\$", limit):
limit = limit + ".*"
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for osd in full_osd_list:
if limit:
try:
if re.fullmatch(limit, osd):
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osd_list.append(getOSDInformation(zkhandler, osd))
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except Exception as e:
return False, "Regex Error: {}".format(e)
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else:
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osd_list.append(getOSDInformation(zkhandler, osd))
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return True, sorted(osd_list, key=lambda x: int(x["id"]))
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#
# Pool functions
#
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def getPoolInformation(zkhandler, pool):
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# Parse the stats data
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(
pool_stats_raw,
tier,
pgs,
) = zkhandler.read_many(
[
("pool.stats", pool),
("pool.tier", pool),
("pool.pgs", pool),
]
)
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pool_stats = dict(json.loads(pool_stats_raw))
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volume_count = len(getCephVolumes(zkhandler, pool))
if tier is None:
tier = "default"
pool_information = {
"name": pool,
"volume_count": volume_count,
"tier": tier,
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"pgs": pgs,
"stats": pool_stats,
}
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return pool_information
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def add_pool(zkhandler, name, pgs, replcfg, tier=None):
# Prepare the copies/mincopies variables
try:
copies, mincopies = replcfg.split(",")
copies = int(copies.replace("copies=", ""))
mincopies = int(mincopies.replace("mincopies=", ""))
except Exception:
copies = None
mincopies = None
if not copies or not mincopies:
return False, f'ERROR: Replication configuration "{replcfg}" is not valid.'
# Prepare the tiers if applicable
if tier is not None and tier in ["hdd", "ssd", "nvme"]:
crush_rule = f"{tier}_tier"
# Create a CRUSH rule for the relevant tier
retcode, stdout, stderr = common.run_os_command(
f"ceph osd crush rule create-replicated {crush_rule} default host {tier}"
)
if retcode:
return (
False,
f"ERROR: Failed to create CRUSH rule {tier} for pool {name}: {stderr}",
)
else:
tier = "default"
crush_rule = "replicated"
# Create the pool
retcode, stdout, stderr = common.run_os_command(
f"ceph osd pool create {name} {pgs} {pgs} {crush_rule}"
)
if retcode:
return False, f'ERROR: Failed to create pool "{name}" with {pgs} PGs: {stderr}'
# Set the size and minsize
retcode, stdout, stderr = common.run_os_command(
f"ceph osd pool set {name} size {copies}"
)
if retcode:
return False, f'ERROR: Failed to set pool "{name}" size of {copies}: {stderr}'
retcode, stdout, stderr = common.run_os_command(
f"ceph osd pool set {name} min_size {mincopies}"
)
if retcode:
return (
False,
f'ERROR: Failed to set pool "{name}" minimum size of {mincopies}: {stderr}',
)
# Enable RBD application
retcode, stdout, stderr = common.run_os_command(
f"ceph osd pool application enable {name} rbd"
)
if retcode:
return (
False,
f'ERROR: Failed to enable RBD application on pool "{name}" : {stderr}',
)
# Add the new pool to Zookeeper
zkhandler.write(
[
(("pool", name), ""),
(("pool.pgs", name), pgs),
(("pool.tier", name), tier),
(("pool.stats", name), "{}"),
(("volume", name), ""),
(("snapshot", name), ""),
]
)
return True, f'Created RBD pool "{name}" with {pgs} PGs'
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def remove_pool(zkhandler, name):
if not verifyPool(zkhandler, name):
return False, 'ERROR: No pool with name "{}" is present in the cluster.'.format(
name
)
# 1. Remove pool volumes
for volume in zkhandler.children(("volume", name)):
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remove_volume(zkhandler, name, volume)
# 2. Remove the pool
retcode, stdout, stderr = common.run_os_command(
"ceph osd pool rm {pool} {pool} --yes-i-really-really-mean-it".format(pool=name)
)
if retcode:
return False, 'ERROR: Failed to remove pool "{}": {}'.format(name, stderr)
# 3. Delete pool from Zookeeper
zkhandler.delete(
[
("pool", name),
("volume", name),
("snapshot", name),
]
)
return True, 'Removed RBD pool "{}" and all volumes.'.format(name)
def set_pgs_pool(zkhandler, name, pgs):
if not verifyPool(zkhandler, name):
return False, f'ERROR: No pool with name "{name}" is present in the cluster.'
# Validate new PGs count
pgs = int(pgs)
if (pgs == 0) or (pgs & (pgs - 1) != 0):
return (
False,
f'ERROR: Invalid PGs number "{pgs}": must be a non-zero power of 2.',
)
# Set the new pgs number
retcode, stdout, stderr = common.run_os_command(
f"ceph osd pool set {name} pg_num {pgs}"
)
if retcode:
return False, f"ERROR: Failed to set pg_num on pool {name} to {pgs}: {stderr}"
# Set the new pgps number if increasing
current_pgs = int(zkhandler.read(("pool.pgs", name)))
if current_pgs >= pgs:
retcode, stdout, stderr = common.run_os_command(
f"ceph osd pool set {name} pgp_num {pgs}"
)
if retcode:
return (
False,
f"ERROR: Failed to set pg_num on pool {name} to {pgs}: {stderr}",
)
# Update Zookeeper count
zkhandler.write(
[
(("pool.pgs", name), pgs),
]
)
return True, f'Set PGs count to {pgs} for RBD pool "{name}".'
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def get_list_pool(zkhandler, limit=None, is_fuzzy=True):
full_pool_list = zkhandler.children("base.pool")
if is_fuzzy and limit:
# Implicitly assume fuzzy limits
if not re.match(r"\^.*", limit):
limit = ".*" + limit
if not re.match(r".*\$", limit):
limit = limit + ".*"
get_pool_info = dict()
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for pool in full_pool_list:
is_limit_match = False
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if limit:
try:
if re.fullmatch(limit, pool):
is_limit_match = True
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except Exception as e:
return False, "Regex Error: {}".format(e)
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else:
is_limit_match = True
get_pool_info[pool] = True if is_limit_match else False
pool_execute_list = [pool for pool in full_pool_list if get_pool_info[pool]]
pool_data_list = list()
with ThreadPoolExecutor(max_workers=32, thread_name_prefix="pool_list") as executor:
futures = []
for pool in pool_execute_list:
futures.append(executor.submit(getPoolInformation, zkhandler, pool))
for future in futures:
pool_data_list.append(future.result())
return True, sorted(pool_data_list, key=lambda x: int(x["stats"].get("id", 0)))
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#
# Volume functions
#
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def getCephVolumes(zkhandler, pool):
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volume_list = list()
if not pool:
pool_list = zkhandler.children("base.pool")
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else:
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pool_list = [pool]
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for pool_name in pool_list:
children = zkhandler.children(("volume", pool_name))
if children is None:
continue
for volume_name in children:
volume_list.append("{}/{}".format(pool_name, volume_name))
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return volume_list
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def getVolumeInformation(zkhandler, pool, volume):
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# Parse the stats data
volume_stats_raw = zkhandler.read(("volume.stats", f"{pool}/{volume}"))
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volume_stats = dict(json.loads(volume_stats_raw))
# Format the size to something nicer
volume_stats["size"] = format_bytes_tohuman(volume_stats["size"])
volume_information = {"name": volume, "pool": pool, "stats": volume_stats}
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return volume_information
def scan_volume(zkhandler, pool, name):
retcode, stdout, stderr = common.run_os_command(
"rbd info --format json {}/{}".format(pool, name)
)
volstats = stdout
# 3. Add the new volume to Zookeeper
zkhandler.write(
[
(("volume.stats", f"{pool}/{name}"), volstats),
]
)
def add_volume(zkhandler, pool, name, size, force_flag=False, zk_only=False):
# 1. Verify the size of the volume
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pool_information = getPoolInformation(zkhandler, pool)
size_bytes = format_bytes_fromhuman(size)
if size_bytes is None:
return (
False,
f"ERROR: Requested volume size '{size}' does not have a valid SI unit",
)
pool_total_free_bytes = int(pool_information["stats"]["free_bytes"])
if size_bytes >= pool_total_free_bytes:
return (
False,
f"ERROR: Requested volume size '{format_bytes_tohuman(size_bytes)}' is greater than the available free space in the pool ('{format_bytes_tohuman(pool_information['stats']['free_bytes'])}')",
)
# Check if we're greater than 80% utilization after the create; error if so unless we have the force flag
pool_total_bytes = (
int(pool_information["stats"]["stored_bytes"]) + pool_total_free_bytes
)
pool_safe_total_bytes = int(pool_total_bytes * 0.80)
pool_safe_free_bytes = pool_safe_total_bytes - int(
pool_information["stats"]["stored_bytes"]
)
if size_bytes >= pool_safe_free_bytes and not force_flag:
return (
False,
f"ERROR: Requested volume size '{format_bytes_tohuman(size_bytes)}' is greater than the safe free space in the pool ('{format_bytes_tohuman(pool_safe_free_bytes)}' for 80% full); retry with force to ignore this error",
)
# 2. Create the volume
# zk_only flag skips actually creating the volume - this would be done by some other mechanism
if not zk_only:
retcode, stdout, stderr = common.run_os_command(
"rbd create --size {}B {}/{}".format(size_bytes, pool, name)
)
if retcode:
return False, 'ERROR: Failed to create RBD volume "{}": {}'.format(
name, stderr
)
# 3. Add the new volume to Zookeeper
zkhandler.write(
[
(("volume", f"{pool}/{name}"), ""),
(("volume.stats", f"{pool}/{name}"), ""),
(("snapshot", f"{pool}/{name}"), ""),
]
)
# 4. Scan the volume stats
scan_volume(zkhandler, pool, name)
return True, 'Created RBD volume "{}" of size "{}" in pool "{}".'.format(
name, format_bytes_tohuman(size_bytes), pool
)
def clone_volume(zkhandler, pool, name_src, name_new, force_flag=False):
# 1. Verify the volume
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if not verifyVolume(zkhandler, pool, name_src):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
name_src, pool
)
volume_stats_raw = zkhandler.read(("volume.stats", f"{pool}/{name_src}"))
volume_stats = dict(json.loads(volume_stats_raw))
size_bytes = volume_stats["size"]
pool_information = getPoolInformation(zkhandler, pool)
pool_total_free_bytes = int(pool_information["stats"]["free_bytes"])
if size_bytes >= pool_total_free_bytes:
return (
False,
f"ERROR: Clone volume size '{format_bytes_tohuman(size_bytes)}' is greater than the available free space in the pool ('{format_bytes_tohuman(pool_information['stats']['free_bytes'])}')",
)
# Check if we're greater than 80% utilization after the create; error if so unless we have the force flag
pool_total_bytes = (
int(pool_information["stats"]["stored_bytes"]) + pool_total_free_bytes
)
pool_safe_total_bytes = int(pool_total_bytes * 0.80)
pool_safe_free_bytes = pool_safe_total_bytes - int(
pool_information["stats"]["stored_bytes"]
)
if size_bytes >= pool_safe_free_bytes and not force_flag:
return (
False,
f"ERROR: Clone volume size '{format_bytes_tohuman(size_bytes)}' is greater than the safe free space in the pool ('{format_bytes_tohuman(pool_safe_free_bytes)}' for 80% full); retry with force to ignore this error",
)
# 2. Clone the volume
retcode, stdout, stderr = common.run_os_command(
"rbd copy {}/{} {}/{}".format(pool, name_src, pool, name_new)
)
if retcode:
return (
False,
'ERROR: Failed to clone RBD volume "{}" to "{}" in pool "{}": {}'.format(
name_src, name_new, pool, stderr
),
)
# 3. Add the new volume to Zookeeper
zkhandler.write(
[
(("volume", f"{pool}/{name_new}"), ""),
(("volume.stats", f"{pool}/{name_new}"), ""),
(("snapshot", f"{pool}/{name_new}"), ""),
]
)
# 4. Scan the volume stats
scan_volume(zkhandler, pool, name_new)
return True, 'Cloned RBD volume "{}" to "{}" in pool "{}"'.format(
name_src, name_new, pool
)
def resize_volume(zkhandler, pool, name, size, force_flag=False):
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if not verifyVolume(zkhandler, pool, name):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
name, pool
)
# 1. Verify the size of the volume
pool_information = getPoolInformation(zkhandler, pool)
size_bytes = format_bytes_fromhuman(size)
if size_bytes is None:
return (
False,
f"ERROR: Requested volume size '{size}' does not have a valid SI unit",
)
pool_total_free_bytes = int(pool_information["stats"]["free_bytes"])
if size_bytes >= pool_total_free_bytes:
return (
False,
f"ERROR: Requested volume size '{format_bytes_tohuman(size_bytes)}' is greater than the available free space in the pool ('{format_bytes_tohuman(pool_information['stats']['free_bytes'])}')",
)
# Check if we're greater than 80% utilization after the create; error if so unless we have the force flag
pool_total_bytes = (
int(pool_information["stats"]["stored_bytes"]) + pool_total_free_bytes
)
pool_safe_total_bytes = int(pool_total_bytes * 0.80)
pool_safe_free_bytes = pool_safe_total_bytes - int(
pool_information["stats"]["stored_bytes"]
)
if size_bytes >= pool_safe_free_bytes and not force_flag:
return (
False,
f"ERROR: Requested volume size '{format_bytes_tohuman(size_bytes)}' is greater than the safe free space in the pool ('{format_bytes_tohuman(pool_safe_free_bytes)}' for 80% full); retry with force to ignore this error",
)
# 2. Resize the volume
retcode, stdout, stderr = common.run_os_command(
"rbd resize --size {} {}/{}".format(
format_bytes_tohuman(size_bytes), pool, name
)
)
if retcode:
return (
False,
'ERROR: Failed to resize RBD volume "{}" to size "{}" in pool "{}": {}'.format(
name, format_bytes_tohuman(size_bytes), pool, stderr
),
)
# 3a. Determine the node running this VM if applicable
active_node = None
volume_vm_name = name.split("_")[0]
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retcode, vm_info = vm.get_info(zkhandler, volume_vm_name)
if retcode:
for disk in vm_info["disks"]:
# This block device is present in this VM so we can continue
if disk["name"] == "{}/{}".format(pool, name):
active_node = vm_info["node"]
volume_id = disk["dev"]
# 3b. Perform a live resize in libvirt if the VM is running
if active_node is not None and vm_info.get("state", "") == "start":
import libvirt
# Run the libvirt command against the target host
try:
dest_lv = "qemu+tcp://{}/system".format(active_node)
target_lv_conn = libvirt.open(dest_lv)
target_vm_conn = target_lv_conn.lookupByName(vm_info["name"])
if target_vm_conn:
target_vm_conn.blockResize(
volume_id,
size_bytes,
libvirt.VIR_DOMAIN_BLOCK_RESIZE_BYTES,
)
target_lv_conn.close()
except Exception:
pass
# 4. Scan the volume stats
scan_volume(zkhandler, pool, name)
return True, 'Resized RBD volume "{}" to size "{}" in pool "{}".'.format(
name, format_bytes_tohuman(size_bytes), pool
)
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def rename_volume(zkhandler, pool, name, new_name):
if not verifyVolume(zkhandler, pool, name):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
name, pool
)
# 1. Rename the volume
retcode, stdout, stderr = common.run_os_command(
"rbd rename {}/{} {}".format(pool, name, new_name)
)
if retcode:
return (
False,
'ERROR: Failed to rename volume "{}" to "{}" in pool "{}": {}'.format(
name, new_name, pool, stderr
),
)
# 2. Rename the volume in Zookeeper
zkhandler.rename(
[
(("volume", f"{pool}/{name}"), ("volume", f"{pool}/{new_name}")),
(("snapshot", f"{pool}/{name}"), ("snapshot", f"{pool}/{new_name}")),
]
)
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# 3. Scan the volume stats
scan_volume(zkhandler, pool, new_name)
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return True, 'Renamed RBD volume "{}" to "{}" in pool "{}".'.format(
name, new_name, pool
)
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def remove_volume(zkhandler, pool, name):
if not verifyVolume(zkhandler, pool, name):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
name, pool
)
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# 1a. Remove PVC-managed volume snapshots
for snapshot in zkhandler.children(("snapshot", f"{pool}/{name}")):
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remove_snapshot(zkhandler, pool, name, snapshot)
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# 1b. Purge any remaining volume snapshots
retcode, stdout, stderr = common.run_os_command(
"rbd snap purge {}/{}".format(pool, name)
)
if retcode:
return (
False,
'ERROR: Failed to purge snapshots from RBD volume "{}" in pool "{}": {}'.format(
name, pool, stderr
),
)
# 2. Remove the volume
retcode, stdout, stderr = common.run_os_command("rbd rm {}/{}".format(pool, name))
if retcode:
return False, 'ERROR: Failed to remove RBD volume "{}" in pool "{}": {}'.format(
name, pool, stderr
)
# 3. Delete volume from Zookeeper
zkhandler.delete(
[
("volume", f"{pool}/{name}"),
("snapshot", f"{pool}/{name}"),
]
)
return True, 'Removed RBD volume "{}" in pool "{}".'.format(name, pool)
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def map_volume(zkhandler, pool, name):
if not verifyVolume(zkhandler, pool, name):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
name, pool
)
# 1. Map the volume onto the local system
retcode, stdout, stderr = common.run_os_command("rbd map {}/{}".format(pool, name))
if retcode:
return False, 'ERROR: Failed to map RBD volume "{}" in pool "{}": {}'.format(
name, pool, stderr
)
# 2. Calculate the absolute path to the mapped volume
mapped_volume = "/dev/rbd/{}/{}".format(pool, name)
# 3. Ensure the volume exists
if not os.path.exists(mapped_volume):
return (
False,
'ERROR: Mapped volume not found at expected location "{}".'.format(
mapped_volume
),
)
return True, mapped_volume
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def unmap_volume(zkhandler, pool, name):
if not verifyVolume(zkhandler, pool, name):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
name, pool
)
mapped_volume = "/dev/rbd/{}/{}".format(pool, name)
# 1. Ensure the volume exists
if not os.path.exists(mapped_volume):
return (
False,
'ERROR: Mapped volume not found at expected location "{}".'.format(
mapped_volume
),
)
# 2. Unap the volume
retcode, stdout, stderr = common.run_os_command(
"rbd unmap {}".format(mapped_volume)
)
if retcode:
return False, 'ERROR: Failed to unmap RBD volume at "{}": {}'.format(
mapped_volume, stderr
)
return True, 'Unmapped RBD volume at "{}".'.format(mapped_volume)
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def get_list_volume(zkhandler, pool, limit=None, is_fuzzy=True):
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if pool and not verifyPool(zkhandler, pool):
return False, 'ERROR: No pool with name "{}" is present in the cluster.'.format(
pool
)
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full_volume_list = getCephVolumes(zkhandler, pool)
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if is_fuzzy and limit:
# Implicitly assume fuzzy limits
if not re.match(r"\^.*", limit):
limit = ".*" + limit
if not re.match(r".*\$", limit):
limit = limit + ".*"
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get_volume_info = dict()
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for volume in full_volume_list:
pool_name, volume_name = volume.split("/")
is_limit_match = False
# Check on limit
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if limit:
# Try to match the limit against the volume name
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try:
if re.fullmatch(limit, volume_name):
is_limit_match = True
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except Exception as e:
return False, "Regex Error: {}".format(e)
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else:
is_limit_match = True
get_volume_info[volume] = True if is_limit_match else False
# Obtain our volume data in a thread pool
volume_execute_list = [
volume for volume in full_volume_list if get_volume_info[volume]
]
volume_data_list = list()
with ThreadPoolExecutor(
max_workers=32, thread_name_prefix="volume_list"
) as executor:
futures = []
for volume in volume_execute_list:
pool_name, volume_name = volume.split("/")
futures.append(
executor.submit(getVolumeInformation, zkhandler, pool_name, volume_name)
)
for future in futures:
volume_data_list.append(future.result())
return True, sorted(volume_data_list, key=lambda x: str(x["name"]))
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#
# Snapshot functions
#
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def getCephSnapshots(zkhandler, pool, volume):
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snapshot_list = list()
volume_list = list()
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volume_list = getCephVolumes(zkhandler, pool)
if volume:
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for volume_entry in volume_list:
volume_pool, volume_name = volume_entry.split("/")
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if volume_name == volume:
volume_list = ["{}/{}".format(volume_pool, volume_name)]
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for volume_entry in volume_list:
for snapshot_name in zkhandler.children(("snapshot", volume_entry)):
snapshot_list.append("{}@{}".format(volume_entry, snapshot_name))
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return snapshot_list
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def add_snapshot(zkhandler, pool, volume, name, zk_only=False):
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if not verifyVolume(zkhandler, pool, volume):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
volume, pool
)
# 1. Create the snapshot
if not zk_only:
retcode, stdout, stderr = common.run_os_command(
"rbd snap create {}/{}@{}".format(pool, volume, name)
)
if retcode:
return (
False,
'ERROR: Failed to create RBD snapshot "{}" of volume "{}" in pool "{}": {}'.format(
name, volume, pool, stderr
),
)
# 2. Get snapshot stats
retcode, stdout, stderr = common.run_os_command(
"rbd info --format json {}/{}@{}".format(pool, volume, name)
)
snapstats = stdout
# 3. Add the snapshot to Zookeeper
zkhandler.write(
[
(("snapshot", f"{pool}/{volume}/{name}"), ""),
(("snapshot.stats", f"{pool}/{volume}/{name}"), snapstats),
]
)
# 4. Update the count of snapshots on this volume
volume_stats_raw = zkhandler.read(("volume.stats", f"{pool}/{volume}"))
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volume_stats = dict(json.loads(volume_stats_raw))
volume_stats["snapshot_count"] = volume_stats["snapshot_count"] + 1
zkhandler.write(
[
(("volume.stats", f"{pool}/{volume}"), json.dumps(volume_stats)),
]
)
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return True, 'Created RBD snapshot "{}" of volume "{}" in pool "{}".'.format(
name, volume, pool
)
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def rename_snapshot(zkhandler, pool, volume, name, new_name):
if not verifyVolume(zkhandler, pool, volume):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
volume, pool
)
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if not verifySnapshot(zkhandler, pool, volume, name):
return (
False,
'ERROR: No snapshot with name "{}" is present for volume "{}" in pool "{}".'.format(
name, volume, pool
),
)
# 1. Rename the snapshot
retcode, stdout, stderr = common.run_os_command(
"rbd snap rename {pool}/{volume}@{name} {pool}/{volume}@{new_name}".format(
pool=pool, volume=volume, name=name, new_name=new_name
)
)
if retcode:
return (
False,
'ERROR: Failed to rename RBD snapshot "{}" to "{}" for volume "{}" in pool "{}": {}'.format(
name, new_name, volume, pool, stderr
),
)
# 2. Rename the snapshot in ZK
zkhandler.rename(
[
(
("snapshot", f"{pool}/{volume}/{name}"),
("snapshot", f"{pool}/{volume}/{new_name}"),
),
]
)
return (
True,
'Renamed RBD snapshot "{}" to "{}" for volume "{}" in pool "{}".'.format(
name, new_name, volume, pool
),
)
def rollback_snapshot(zkhandler, pool, volume, name):
if not verifyVolume(zkhandler, pool, volume):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
volume, pool
)
if not verifySnapshot(zkhandler, pool, volume, name):
return (
False,
'ERROR: No snapshot with name "{}" is present for volume "{}" in pool "{}".'.format(
name, volume, pool
),
)
# 1. Roll back the snapshot
retcode, stdout, stderr = common.run_os_command(
"rbd snap rollback {}/{}@{}".format(pool, volume, name)
)
if retcode:
return (
False,
'ERROR: Failed to roll back RBD volume "{}" in pool "{}" to snapshot "{}": {}'.format(
volume, pool, name, stderr
),
)
return True, 'Rolled back RBD volume "{}" in pool "{}" to snapshot "{}".'.format(
volume, pool, name
)
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def remove_snapshot(zkhandler, pool, volume, name):
if not verifyVolume(zkhandler, pool, volume):
return False, 'ERROR: No volume with name "{}" is present in pool "{}".'.format(
volume, pool
)
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if not verifySnapshot(zkhandler, pool, volume, name):
return (
False,
'ERROR: No snapshot with name "{}" is present of volume {} in pool {}.'.format(
name, volume, pool
),
)
# 1. Remove the snapshot
retcode, stdout, stderr = common.run_os_command(
"rbd snap rm {}/{}@{}".format(pool, volume, name)
)
if retcode:
return (
False,
'Failed to remove RBD snapshot "{}" of volume "{}" in pool "{}": {}'.format(
name, volume, pool, stderr
),
)
# 2. Delete snapshot from Zookeeper
zkhandler.delete([("snapshot", f"{pool}/{volume}/{name}")])
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# 3. Update the count of snapshots on this volume
volume_stats_raw = zkhandler.read(("volume.stats", f"{pool}/{volume}"))
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volume_stats = dict(json.loads(volume_stats_raw))
# Format the size to something nicer
volume_stats["snapshot_count"] = volume_stats["snapshot_count"] - 1
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volume_stats_raw = json.dumps(volume_stats)
zkhandler.write([(("volume.stats", f"{pool}/{volume}"), volume_stats_raw)])
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return True, 'Removed RBD snapshot "{}" of volume "{}" in pool "{}".'.format(
name, volume, pool
)
def get_list_snapshot(zkhandler, target_pool, target_volume, limit=None, is_fuzzy=True):
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snapshot_list = []
full_snapshot_list = getCephSnapshots(zkhandler, target_pool, target_volume)
if is_fuzzy and limit:
# Implicitly assume fuzzy limits
if not re.match(r"\^.*", limit):
limit = ".*" + limit
if not re.match(r".*\$", limit):
limit = limit + ".*"
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for snapshot in full_snapshot_list:
volume, snapshot_name = snapshot.split("@")
pool_name, volume_name = volume.split("/")
if target_pool and pool_name != target_pool:
continue
if target_volume and volume_name != target_volume:
continue
try:
snapshot_stats = json.loads(
zkhandler.read(
("snapshot.stats", f"{pool_name}/{volume_name}/{snapshot_name}")
)
)
except Exception:
snapshot_stats = []
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if limit:
try:
if re.fullmatch(limit, snapshot_name):
snapshot_list.append(
{
"pool": pool_name,
"volume": volume_name,
"snapshot": snapshot_name,
"stats": snapshot_stats,
}
)
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except Exception as e:
return False, "Regex Error: {}".format(e)
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else:
snapshot_list.append(
{
"pool": pool_name,
"volume": volume_name,
"snapshot": snapshot_name,
"stats": snapshot_stats,
}
)
return True, sorted(snapshot_list, key=lambda x: str(x["snapshot"]))
#
# Celery worker tasks (must be run on node, outputs log messages to worker)
#
def osd_worker_helper_find_osds_from_block(device):
# Try to query the passed block device directly
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm list --format json {device}"
)
if retcode:
found_osds = []
else:
found_osds = jloads(stdout)
return found_osds
def osd_worker_add_osd(
zkhandler,
celery,
node,
device,
weight,
ext_db_ratio=None,
ext_db_size=None,
split_count=None,
):
current_stage = 0
total_stages = 5
if split_count is None:
split_count = 1
else:
split_count = int(split_count)
total_stages = total_stages + 3 * int(split_count)
if ext_db_ratio is not None or ext_db_size is not None:
total_stages = total_stages + 3 * int(split_count) + 1
start(
celery,
f"Adding {split_count} new OSD(s) on device {device} with weight {weight}",
current=current_stage,
total=total_stages,
)
# Handle a detect device if that is passed
if match(r"detect:", device):
ddevice = common.get_detect_device(device)
if ddevice is None:
fail(
celery,
f"Failed to determine block device from detect string {device}",
)
return
else:
log_info(
celery, f"Determined block device {ddevice} from detect string {device}"
)
device = ddevice
if ext_db_size is not None and ext_db_ratio is not None:
fail(
celery,
"Invalid configuration: both an ext_db_size and ext_db_ratio were specified",
)
return
# Check if device has a partition table; it's not valid if it does
retcode, _, _ = common.run_os_command(f"sfdisk --dump {device}")
if retcode < 1:
fail(
celery,
f"Device {device} has a partition table and is unsuitable for an OSD",
)
return
if ext_db_size is not None or ext_db_ratio is not None:
ext_db_flag = True
else:
ext_db_flag = False
if split_count > 1:
split_flag = f"--osds-per-device {split_count}"
is_split = True
log_info(
celery, f"Creating {split_count} new OSD disks on block device {device}"
)
else:
split_flag = ""
is_split = False
log_info(celery, f"Creating 1 new OSD disk on block device {device}")
if "nvme" in device:
class_flag = "--crush-device-class nvme"
else:
class_flag = "--crush-device-class ssd"
# 1. Zap the block device
current_stage += 1
update(
celery,
f"Zapping block device {device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm zap --destroy {device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to perform ceph-volume lvm zap on {device}")
return
# 2. Prepare the OSD(s)
current_stage += 1
update(
celery,
f"Preparing OSD(s) on device {device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm batch --yes --prepare --bluestore {split_flag} {class_flag} {device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to perform ceph-volume lvm batch on {device}")
return
# 3. Get the list of created OSDs on the device (initial pass)
current_stage += 1
update(
celery,
f"Querying OSD(s) on device {device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm list --format json {device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to perform ceph-volume lvm list on {device}")
return
created_osds = jloads(stdout)
# 4. Prepare the WAL and DB devices
if ext_db_flag:
for created_osd in created_osds:
# 4a. Get the OSD FSID and ID from the details
osd_details = created_osds[created_osd][0]
osd_fsid = osd_details["tags"]["ceph.osd_fsid"]
osd_id = osd_details["tags"]["ceph.osd_id"]
osd_lv = osd_details["lv_path"]
current_stage += 1
update(
celery,
f"Preparing DB LV for OSD {osd_id}",
current=current_stage,
total=total_stages,
)
# 4b. Prepare the logical volume if ext_db_flag
if ext_db_ratio is not None:
_, osd_size_bytes, _ = common.run_os_command(
f"blockdev --getsize64 {osd_lv}"
)
osd_size_bytes = int(osd_size_bytes)
osd_db_size_bytes = int(osd_size_bytes * ext_db_ratio)
if ext_db_size is not None:
osd_db_size_bytes = format_bytes_fromhuman(ext_db_size)
osd_db_size_mb = int(osd_db_size_bytes / 1024 / 1024)
db_device = f"osd-db/osd-{osd_id}"
current_stage += 1
update(
celery,
f"Preparing Bluestore DB volume for OSD {osd_id} on {db_device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"lvcreate -L {osd_db_size_mb}M -n osd-{osd_id} --yes osd-db"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run lvcreate on {db_device}")
return
# 4c. Attach the new DB device to the OSD
current_stage += 1
update(
celery,
f"Attaching Bluestore DB volume to OSD {osd_id}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm new-db --osd-id {osd_id} --osd-fsid {osd_fsid} --target {db_device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(
celery, f"Failed to perform ceph-volume lvm new-db on OSD {osd_id}"
)
return
# 4d. Get the list of created OSDs on the device (final pass)
current_stage += 1
update(
celery,
f"Requerying OSD(s) on device {device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm list --format json {device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to perform ceph-volume lvm list on {device}")
return
created_osds = jloads(stdout)
# 5. Activate the OSDs
for created_osd in created_osds:
# 5a. Get the OSD FSID and ID from the details
osd_details = created_osds[created_osd][0]
osd_clusterfsid = osd_details["tags"]["ceph.cluster_fsid"]
osd_fsid = osd_details["tags"]["ceph.osd_fsid"]
osd_id = osd_details["tags"]["ceph.osd_id"]
db_device = osd_details["tags"].get("ceph.db_device", "")
osd_vg = osd_details["vg_name"]
osd_lv = osd_details["lv_name"]
# 5b. Add it to the crush map
current_stage += 1
update(
celery,
f"Adding OSD {osd_id} to CRUSH map",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph osd crush add osd.{osd_id} {weight} root=default host={node}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to perform ceph osd crush add for OSD {osd_id}")
return
# 5c. Activate the OSD
current_stage += 1
update(
celery,
f"Activating OSD {osd_id}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm activate --bluestore {osd_id} {osd_fsid}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to perform ceph osd crush add for OSD {osd_id}")
return
# 5d. Wait 1 second for it to activate
time.sleep(1)
# 5e. Verify it started
retcode, stdout, stderr = common.run_os_command(
f"systemctl status ceph-osd@{osd_id}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to start OSD {osd_id} process")
return
# 5f. Add the new OSD to PVC
current_stage += 1
update(
celery,
f"Adding OSD {osd_id} to PVC",
current=current_stage,
total=total_stages,
)
zkhandler.write(
[
(("osd", osd_id), ""),
(("osd.node", osd_id), node),
(("osd.device", osd_id), device),
(("osd.db_device", osd_id), db_device),
(("osd.fsid", osd_id), ""),
(("osd.ofsid", osd_id), osd_fsid),
(("osd.cfsid", osd_id), osd_clusterfsid),
(("osd.lvm", osd_id), ""),
(("osd.vg", osd_id), osd_vg),
(("osd.lv", osd_id), osd_lv),
(("osd.is_split", osd_id), is_split),
(
("osd.stats", osd_id),
'{"uuid": "|", "up": 0, "in": 0, "primary_affinity": "|", "utilization": "|", "var": "|", "pgs": "|", "kb": "|", "weight": "|", "reweight": "|", "node": "|", "used": "|", "avail": "|", "wr_ops": "|", "wr_data": "|", "rd_ops": "|", "rd_data": "|", "state": "|"}',
),
]
)
# 6. Wait for OSD to check in
current_stage += 1
update(
celery,
"Waiting for new OSD(s) to report stats",
current=current_stage,
total=total_stages,
)
last_osd = None
for osd in created_osds:
last_osd = osd
while (
jloads(
zkhandler.read(
("osd.stats", created_osds[last_osd][0]["tags"]["ceph.osd_id"])
)
)["weight"]
== "|"
):
time.sleep(1)
# 7. Log it
current_stage += 1
return finish(
celery,
f"Successfully created {len(created_osds.keys())} new OSD(s) {','.join(created_osds.keys())} on device {device}",
current=current_stage,
total=total_stages,
)
def osd_worker_replace_osd(
zkhandler,
celery,
node,
osd_id,
new_device,
old_device=None,
weight=None,
ext_db_ratio=None,
ext_db_size=None,
):
# Try to determine if any other OSDs shared a block device with this OSD
_, osd_list = get_list_osd(zkhandler, None)
osd_block = zkhandler.read(("osd.device", osd_id))
all_osds_on_block = [
o for o in osd_list if o["node"] == node and o["device"] == osd_block
]
all_osds_on_block_ids = [o["id"] for o in all_osds_on_block]
# Set up stages
current_stage = 0
total_stages = 3
_split_count = len(all_osds_on_block_ids)
total_stages = total_stages + 10 * int(_split_count)
if (
ext_db_ratio is not None
or ext_db_size is not None
or any([True for o in all_osds_on_block if o["db_device"]])
):
total_stages = total_stages + 2 * int(_split_count)
start(
celery,
f"Replacing OSD(s) {','.join(all_osds_on_block_ids)} with device {new_device}",
current=current_stage,
total=total_stages,
)
# Handle a detect device if that is passed
if match(r"detect:", new_device):
ddevice = common.get_detect_device(new_device)
if ddevice is None:
fail(
celery,
f"Failed to determine block device from detect string {new_device}",
)
return
else:
log_info(
celery,
f"Determined block device {ddevice} from detect string {new_device}",
)
new_device = ddevice
# Check if device has a partition table; it's not valid if it does
retcode, _, _ = common.run_os_command(f"sfdisk --dump {new_device}")
if retcode < 1:
fail(
celery,
f"Device {new_device} has a partition table and is unsuitable for an OSD",
)
return
# Phase 1: Try to determine what we can about the old device
real_old_device = None
# Determine information from a passed old_device
if old_device is not None:
found_osds = osd_worker_helper_find_osds_from_block(old_device)
if found_osds and osd_id in found_osds.keys():
real_old_device = old_device
else:
log_warn(
celery,
f"No OSD(s) found on device {old_device}; falling back to PVC detection",
)
# Try to get an old_device from our PVC information
if real_old_device is None:
found_osds = osd_worker_helper_find_osds_from_block(osd_block)
if osd_id in found_osds.keys():
real_old_device = osd_block
if real_old_device is None:
skip_zap = True
log_warn(
celery,
"No valid old block device found for OSD(s); skipping zap",
)
else:
skip_zap = False
# Determine the weight of the OSD(s)
if weight is None:
weight = all_osds_on_block[0]["stats"]["weight"]
# Take down the OSD(s), but keep it's CRUSH map details and IDs
for osd in all_osds_on_block:
osd_id = osd["id"]
# 1. Set the OSD down and out so it will flush
current_stage += 1
update(
celery,
f"Setting OSD {osd_id} down",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(f"ceph osd down {osd_id}")
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to set OSD {osd_id} down")
return
current_stage += 1
update(
celery,
f"Setting OSD {osd_id} out",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(f"ceph osd out {osd_id}")
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to set OSD {osd_id} out")
return
# 2. Wait for the OSD to be safe to remove (but don't wait for rebalancing to complete)
current_stage += 1
update(
celery,
f"Waiting for OSD {osd_id} to be safe to remove",
current=current_stage,
total=total_stages,
)
tcount = 0
while True:
retcode, stdout, stderr = common.run_os_command(
f"ceph osd safe-to-destroy osd.{osd_id}"
)
if int(retcode) in [0, 11]:
break
else:
common.run_os_command(f"ceph osd down {osd_id}")
common.run_os_command(f"ceph osd out {osd_id}")
time.sleep(1)
tcount += 1
if tcount > 60:
log_warn(
celery,
f"Timed out (60s) waiting for OSD {osd_id} to be safe to remove; proceeding anyways",
)
break
# 3. Stop the OSD process and wait for it to be terminated
current_stage += 1
update(
celery,
f"Stopping OSD {osd_id}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"systemctl stop ceph-osd@{osd_id}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to stop OSD {osd_id}")
return
time.sleep(5)
# 4. Destroy the OSD
current_stage += 1
update(
celery,
f"Destroying OSD {osd_id}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph osd destroy {osd_id} --yes-i-really-mean-it"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to destroy OSD {osd_id}")
return
current_stage += 1
update(
celery,
f"Zapping old disk {real_old_device} if possible",
current=current_stage,
total=total_stages,
)
if not skip_zap:
# 5. Zap the old disk
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm zap --destroy {real_old_device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
log_warn(
celery, f"Failed to zap old disk {real_old_device}; proceeding anyways"
)
# 6. Prepare the volume group on the new device
current_stage += 1
update(
celery,
f"Preparing LVM volume group on new disk {new_device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm zap --destroy {new_device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run ceph-volume lvm zap on new disk {new_device}")
return
retcode, stdout, stderr = common.run_os_command(f"pvcreate {new_device}")
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run pvcreate on new disk {new_device}")
return
vg_uuid = str(uuid4())
retcode, stdout, stderr = common.run_os_command(
f"vgcreate ceph-{vg_uuid} {new_device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run vgcreate on new disk {new_device}")
return
# Determine how many OSDs we want on the new device
osds_count = len(all_osds_on_block)
# Determine the size of the new device
_, new_device_size_bytes, _ = common.run_os_command(
f"blockdev --getsize64 {new_device}"
)
# Calculate the size of each OSD (in MB) based on the default 4M extent size
new_osd_size_mb = (
int(int(int(new_device_size_bytes) / osds_count) / 1024 / 1024 / 4) * 4
)
# Calculate the size, if applicable, of the OSD block if we were passed a ratio
if ext_db_ratio is not None:
osd_new_db_size_mb = int(int(int(new_osd_size_mb * ext_db_ratio) / 4) * 4)
elif ext_db_size is not None:
osd_new_db_size_mb = int(
int(int(format_bytes_fromhuman(ext_db_size)) / 1024 / 1024 / 4) * 4
)
else:
if all_osds_on_block[0]["db_device"]:
_, new_device_size_bytes, _ = common.run_os_command(
f"blockdev --getsize64 {all_osds_on_block[0]['db_device']}"
)
osd_new_db_size_mb = int(
int(int(new_device_size_bytes) / 1024 / 1024 / 4) * 4
)
else:
osd_new_db_size_mb = None
for osd in all_osds_on_block:
osd_id = osd["id"]
osd_fsid = osd["fsid"]
current_stage += 1
update(
celery,
f"Preparing LVM logical volume for OSD {osd_id} on new disk {new_device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"lvcreate -L {new_osd_size_mb}M -n osd-block-{osd_fsid} ceph-{vg_uuid}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run lvcreate for OSD {osd_id}")
return
current_stage += 1
update(
celery,
f"Preparing OSD {osd_id} on new disk {new_device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm prepare --bluestore --osd-id {osd_id} --osd-fsid {osd_fsid} --data /dev/ceph-{vg_uuid}/osd-block-{osd_fsid}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run ceph-volume lvm prepare for OSD {osd_id}")
return
for osd in all_osds_on_block:
osd_id = osd["id"]
osd_fsid = osd["fsid"]
if osd["db_device"]:
db_device = f"osd-db/osd-{osd_id}"
current_stage += 1
update(
celery,
f"Preparing Bluestore DB volume for OSD {osd_id} on {db_device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"lvremove --force {db_device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run lvremove on {db_device}")
return
retcode, stdout, stderr = common.run_os_command(
f"lvcreate -L {osd_new_db_size_mb}M -n osd-{osd_id} --yes osd-db"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run lvcreate on {db_device}")
return
current_stage += 1
update(
celery,
f"Attaching Bluestore DB volume to OSD {osd_id}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm new-db --osd-id {osd_id} --osd-fsid {osd_fsid} --target {db_device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run ceph-volume lvm new-db for OSD {osd_id}")
return
current_stage += 1
update(
celery,
f"Updating OSD {osd_id} in CRUSH map",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph osd crush add osd.{osd_id} {weight} root=default host={node}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run ceph osd crush add for OSD {osd_id}")
return
current_stage += 1
update(
celery,
f"Activating OSD {osd_id}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm activate --bluestore {osd_id} {osd_fsid}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run ceph-volume lvm activate for OSD {osd_id}")
return
# Wait 1 second for it to activate
time.sleep(1)
# Verify it started
retcode, stdout, stderr = common.run_os_command(
f"systemctl status ceph-osd@{osd_id}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to start OSD {osd_id} process")
return
current_stage += 1
update(
celery,
f"Updating OSD {osd_id} in PVC",
current=current_stage,
total=total_stages,
)
zkhandler.write(
[
(("osd.device", osd_id), new_device),
(("osd.vg", osd_id), f"ceph-{vg_uuid}"),
(("osd.lv", osd_id), f"osd-block-{osd_fsid}"),
]
)
# 6. Log it
current_stage += 1
return finish(
celery,
f"Successfully replaced OSD(s) {','.join(all_osds_on_block_ids)} on new disk {new_device}",
current=current_stage,
total=total_stages,
)
def osd_worker_refresh_osd(
zkhandler,
celery,
node,
osd_id,
device,
ext_db_flag,
):
# Try to determine if any other OSDs shared a block device with this OSD
_, osd_list = get_list_osd(zkhandler, None)
osd_block = zkhandler.read(("osd.device", osd_id))
all_osds_on_block = [
o for o in osd_list if o["node"] == node and o["device"] == osd_block
]
all_osds_on_block_ids = [o["id"] for o in all_osds_on_block]
# Set up stages
current_stage = 0
total_stages = 1
_split_count = len(all_osds_on_block_ids)
total_stages = total_stages + 3 * int(_split_count)
start(
celery,
f"Refreshing/reimporting OSD(s) {','.join(all_osds_on_block_ids)} on device {device}",
current=current_stage,
total=total_stages,
)
# Handle a detect device if that is passed
if match(r"detect:", device):
ddevice = common.get_detect_device(device)
if ddevice is None:
fail(
celery,
f"Failed to determine block device from detect string {device}",
)
return
else:
log_info(
celery,
f"Determined block device {ddevice} from detect string {device}",
)
device = ddevice
retcode, stdout, stderr = common.run_os_command("ceph osd ls")
osd_list = stdout.split("\n")
if osd_id not in osd_list:
fail(
celery,
f"Could not find OSD {osd_id} in the cluster",
)
return
found_osds = osd_worker_helper_find_osds_from_block(device)
if osd_id not in found_osds.keys():
fail(
celery,
f"Could not find OSD {osd_id} on device {device}",
)
return
for osd in found_osds:
found_osd = found_osds[osd][0]
lv_device = found_osd["lv_path"]
_, osd_pvc_information = get_list_osd(zkhandler, osd)
osd_information = osd_pvc_information[0]
current_stage += 1
update(
celery,
"Querying for OSD on device",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm list --format json {lv_device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run ceph-volume lvm list for OSD {osd}")
return
osd_detail = jloads(stdout)[osd][0]
osd_fsid = osd_detail["tags"]["ceph.osd_fsid"]
if osd_fsid != osd_information["fsid"]:
fail(
celery,
f"OSD {osd} FSID {osd_information['fsid']} does not match volume FSID {osd_fsid}; OSD cannot be imported",
)
return
dev_flags = f"--data {lv_device}"
if ext_db_flag:
db_device = "osd-db/osd-{osd}"
dev_flags += f" --block.db {db_device}"
if not path.exists(f"/dev/{db_device}"):
fail(
celery,
f"OSD Bluestore DB volume {db_device} does not exist; OSD cannot be imported",
)
return
else:
db_device = ""
current_stage += 1
update(
celery,
f"Activating OSD {osd}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm activate --bluestore {osd} {osd_fsid}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to run ceph-volume lvm activate for OSD {osd}")
return
# Wait 1 second for it to activate
time.sleep(1)
# Verify it started
retcode, stdout, stderr = common.run_os_command(
f"systemctl status ceph-osd@{osd}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(celery, f"Failed to start OSD {osd} process")
return
current_stage += 1
update(
celery,
f"Updating OSD {osd} in PVC",
current=current_stage,
total=total_stages,
)
zkhandler.write(
[
(("osd.device", osd), device),
(("osd.vg", osd), osd_detail["vg_name"]),
(("osd.lv", osd), osd_detail["lv_name"]),
]
)
# 6. Log it
current_stage += 1
return finish(
celery,
f"Successfully reimported OSD(s) {','.join(all_osds_on_block_ids)} on device {device}",
current=current_stage,
total=total_stages,
)
def osd_worker_remove_osd(
zkhandler, celery, node, osd_id, force_flag=False, skip_zap_flag=False
):
# Get initial data
data_device = zkhandler.read(("osd.device", osd_id))
if zkhandler.exists(("osd.db_device", osd_id)):
db_device = zkhandler.read(("osd.db_device", osd_id))
else:
db_device = None
# Set up stages
current_stage = 0
total_stages = 7
if not force_flag:
total_stages += 1
if not skip_zap_flag:
total_stages += 2
if db_device:
total_stages += 1
start(
celery,
f"Removing OSD {osd_id}",
current=current_stage,
total=total_stages,
)
# Verify the OSD is present
retcode, stdout, stderr = common.run_os_command("ceph osd ls")
osd_list = stdout.split("\n")
if osd_id not in osd_list:
if not force_flag:
fail(
celery,
f"OSD {osd_id} not found in Ceph",
)
return
else:
log_warn(
celery,
f"OSD {osd_id} not found in Ceph; ignoring error due to force flag",
)
# 1. Set the OSD down and out so it will flush
current_stage += 1
update(
celery,
f"Setting OSD {osd_id} down",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(f"ceph osd down {osd_id}")
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
if not force_flag:
fail(
celery,
f"Failed to set OSD {osd_id} down",
)
return
else:
log_warn(
celery,
f"Failed to set OSD {osd_id} down; ignoring error due to force flag",
)
current_stage += 1
update(
celery,
f"Setting OSD {osd_id} out",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(f"ceph osd out {osd_id}")
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
if not force_flag:
fail(
celery,
f"Failed to set OSD {osd_id} down",
)
return
else:
log_warn(
celery,
f"Failed to set OSD {osd_id} down; ignoring error due to force flag",
)
# 2. Wait for the OSD to be safe to remove (but don't wait for rebalancing to complete)
if not force_flag:
current_stage += 1
update(
celery,
f"Waiting for OSD {osd_id} to be safe to remove",
current=current_stage,
total=total_stages,
)
tcount = 0
while True:
retcode, stdout, stderr = common.run_os_command(
f"ceph osd safe-to-destroy osd.{osd_id}"
)
if int(retcode) in [0, 11]:
break
else:
common.run_os_command(f"ceph osd down {osd_id}")
common.run_os_command(f"ceph osd out {osd_id}")
time.sleep(1)
tcount += 1
if tcount > 60:
log_warn(
celery,
f"Timed out (60s) waiting for OSD {osd_id} to be safe to remove; proceeding anyways",
)
break
# 3. Stop the OSD process and wait for it to be terminated
current_stage += 1
update(
celery,
f"Stopping OSD {osd_id}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(f"systemctl stop ceph-osd@{osd_id}")
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
if not force_flag:
fail(
celery,
f"Failed to stop OSD {osd_id} process",
)
return
else:
log_warn(
celery,
f"Failed to stop OSD {osd_id} process; ignoring error due to force flag",
)
time.sleep(5)
# 4. Delete OSD from ZK
current_stage += 1
update(
celery,
f"Deleting OSD {osd_id} from PVC",
current=current_stage,
total=total_stages,
)
zkhandler.delete(("osd", osd_id), recursive=True)
# 5a. Destroy the OSD from Ceph
current_stage += 1
update(
celery,
f"Destroying OSD {osd_id}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"ceph osd destroy {osd_id} --yes-i-really-mean-it"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
if not force_flag:
fail(
celery,
f"Failed to destroy OSD {osd_id}",
)
return
else:
log_warn(
celery,
f"Failed to destroy OSD {osd_id}; ignoring error due to force flag",
)
time.sleep(2)
# 5b. Purge the OSD from Ceph
current_stage += 1
update(
celery,
f"Removing OSD {osd_id} from CRUSH map",
current=current_stage,
total=total_stages,
)
# Remove the OSD from the CRUSH map
retcode, stdout, stderr = common.run_os_command(f"ceph osd crush rm osd.{osd_id}")
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
if not force_flag:
fail(
celery,
f"Failed to remove OSD {osd_id} from CRUSH map",
)
return
else:
log_warn(
celery,
f"Failed to remove OSD {osd_id} from CRUSH map; ignoring error due to force flag",
)
# Purge the OSD
current_stage += 1
update(
celery,
f"Purging OSD {osd_id}",
current=current_stage,
total=total_stages,
)
if force_flag:
force_arg = "--force"
else:
force_arg = ""
retcode, stdout, stderr = common.run_os_command(
f"ceph osd purge {osd_id} {force_arg} --yes-i-really-mean-it"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
if not force_flag:
fail(
celery,
f"Failed to purge OSD {osd_id}",
)
return
else:
log_warn(
celery,
f"Failed to purge OSD {osd_id}; ignoring error due to force flag",
)
# 6. Remove the DB device
if db_device:
current_stage += 1
update(
celery,
f"Removing OSD DB logical volume {db_device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
f"lvremove --yes --force {db_device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
if not force_flag:
fail(
celery,
f"Failed to remove OSD DB logical volume {db_device}",
)
return
else:
log_warn(
celery,
f"Failed to remove OSD DB logical volume {db_device}; ignoring error due to force flag",
)
if not skip_zap_flag:
current_stage += 1
update(
celery,
f"Zapping old disk {data_device} if possible",
current=current_stage,
total=total_stages,
)
# 7. Determine the block devices
found_osds = osd_worker_helper_find_osds_from_block(data_device)
if osd_id in found_osds.keys():
# Try to determine if any other OSDs shared a block device with this OSD
_, osd_list = get_list_osd(zkhandler, None)
all_osds_on_block = [
o for o in osd_list if o["node"] == node and o["device"] == data_device
]
if len(all_osds_on_block) < 1:
log_info(
celery,
f"Found no peer split OSD(s) on {data_device}; zapping disk",
)
retcode, stdout, stderr = common.run_os_command(
f"ceph-volume lvm zap --destroy {data_device}"
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
if not force_flag:
fail(
celery,
f"Failed to run ceph-volume lvm zap on device {data_device}",
)
return
else:
log_warn(
celery,
f"Failed to run ceph-volume lvm zap on device {data_device}; ignoring error due to force flag",
)
else:
log_warn(
celery,
f"Found {len(all_osds_on_block)} OSD(s) still remaining on {data_device}; skipping zap",
)
else:
log_warn(
celery,
f"Could not find OSD {osd_id} on device {data_device}; skipping zap",
)
# 6. Log it
current_stage += 1
return finish(
celery,
f"Successfully removed OSD {osd_id}",
current=current_stage,
total=total_stages,
)
def osd_worker_add_db_vg(zkhandler, celery, device):
# Set up stages
current_stage = 0
total_stages = 4
start(
celery,
f"Creating new OSD database volume group on device {device}",
current=current_stage,
total=total_stages,
)
# Check if an existsing volume group exists
retcode, stdout, stderr = common.run_os_command("vgdisplay osd-db")
if retcode != 5:
fail(
celery,
"Ceph OSD database VG already exists",
)
return
# Handle a detect device if that is passed
if match(r"detect:", device):
ddevice = common.get_detect_device(device)
if ddevice is None:
fail(
celery,
f"Failed to determine block device from detect string {device}",
)
return
else:
log_info(
celery,
f"Determined block device {ddevice} from detect string {device}",
)
device = ddevice
# 1. Create an empty partition table
current_stage += 1
update(
celery,
f"Creating partitions on device {device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command("sgdisk --clear {}".format(device))
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(
celery,
f"Failed to create partition table on device {device}",
)
return
retcode, stdout, stderr = common.run_os_command(
"sgdisk --new 1:: --typecode 1:8e00 {}".format(device)
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(
celery,
f"Failed to set partition type to LVM PV on device {device}",
)
return
# Handle the partition ID portion
if search(r"by-path", device) or search(r"by-id", device):
# /dev/disk/by-path/pci-0000:03:00.0-scsi-0:1:0:0 -> pci-0000:03:00.0-scsi-0:1:0:0-part1
partition = "{}-part1".format(device)
elif search(r"nvme", device):
# /dev/nvme0n1 -> nvme0n1p1
partition = "{}p1".format(device)
else:
# /dev/sda -> sda1
# No other '/dev/disk/by-*' types are valid for raw block devices anyways
partition = "{}1".format(device)
# 2. Create the PV
current_stage += 1
update(
celery,
f"Creating LVM PV on device {device}",
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
"pvcreate --force {}".format(partition)
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(
celery,
f"Failed to create LVM PV on device {device}",
)
return
# 2. Create the VG (named 'osd-db')
current_stage += 1
update(
celery,
f'Creating LVM VG "osd-db" on device {device}',
current=current_stage,
total=total_stages,
)
retcode, stdout, stderr = common.run_os_command(
"vgcreate --force osd-db {}".format(partition)
)
log_info(celery, f"stdout: {stdout}")
log_info(celery, f"stderr: {stderr}")
if retcode:
fail(
celery,
f"Failed to create LVM VG on device {device}",
)
return
# Log it
current_stage += 1
return finish(
celery,
f"Successfully created new OSD DB volume group on device {device}",
current=current_stage,
total=total_stages,
)