#!/usr/bin/env python3 # zkhandler.py - Secure versioned ZooKeeper updates # Part of the Parallel Virtual Cluster (PVC) system # # Copyright (C) 2018-2021 Joshua M. Boniface # # 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. # # 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 . # ############################################################################### import os import time import uuid import json import re from functools import wraps from kazoo.client import KazooClient, KazooState from kazoo.exceptions import NoNodeError # # Function decorators # class ZKConnection(object): """ Decorates a function with a Zookeeper connection before and after the main call. The decorated function must accept the `zkhandler` argument as its first argument, and then use this to access the connection. """ def __init__(self, config): self.config = config def __call__(self, function): if not callable(function): return @wraps(function) def connection(*args, **kwargs): zkhandler = ZKHandler(self.config) zkhandler.connect() schema_version = zkhandler.read('base.schema.version') if schema_version is None: schema_version = 0 zkhandler.schema.load(schema_version, quiet=True) ret = function(zkhandler, *args, **kwargs) zkhandler.disconnect() del zkhandler return ret return connection # # Exceptions # class ZKConnectionException(Exception): """ A exception when connecting to the cluster """ def __init__(self, zkhandler, error=None): if error is not None: self.message = "Failed to connect to Zookeeper at {}: {}".format(zkhandler.coordinators(), error) else: self.message = "Failed to connect to Zookeeper at {}".format(zkhandler.coordinators()) zkhandler.disconnect() def __str__(self): return str(self.message) # # Handler class # class ZKHandler(object): def __init__(self, config, logger=None): """ Initialize an instance of the ZKHandler class with config A zk_conn object will be created but not started A ZKSchema instance will be created """ self.encoding = 'utf8' self.coordinators = config['coordinators'] self.logger = logger self.zk_conn = KazooClient(hosts=self.coordinators) self._schema = ZKSchema() # # Class meta-functions # def coordinators(self): return str(self.coordinators) def log(self, message, state=''): if self.logger is not None: self.logger.out(message, state) else: print(message) # # Properties # @property def schema(self): return self._schema # # State/connection management # def listener(self, state): """ Listen for KazooState changes and log accordingly. This function does not do anything except for log the state, and Kazoo handles the rest. """ if state == KazooState.CONNECTED: self.log('Connection to Zookeeper resumed', state='o') else: self.log('Connection to Zookeeper lost with state {}'.format(state), state='w') def connect(self, persistent=False): """ Start the zk_conn object and connect to the cluster """ try: self.zk_conn.start() if persistent: self.log('Connection to Zookeeper started', state='o') self.zk_conn.add_listener(self.listener) except Exception as e: raise ZKConnectionException(self, e) def disconnect(self, persistent=False): """ Stop and close the zk_conn object and disconnect from the cluster The class instance may be reused later (avoids persistent connections) """ self.zk_conn.stop() self.zk_conn.close() if persistent: self.log('Connection to Zookeeper terminated', state='o') # # Schema helper actions # def get_schema_path(self, key): """ Get the Zookeeper path for {key} from the current schema based on its format. If {key} is a tuple of length 2, it's treated as a path plus an item instance of that path (e.g. a node, a VM, etc.). If {key} is a tuple of length 4, it is treated as a path plus an item instance, as well as another item instance of the subpath. If {key} is just a string, it's treated as a lone path (mostly used for the 'base' schema group. Otherwise, returns None since this is not a valid key. This function also handles the special case where a string that looks like an existing path (i.e. starts with '/') is passed; in that case it will silently return the same path back. This was mostly a migration functionality and is deprecated. """ if isinstance(key, tuple): # This is a key tuple with both an ipath and an item if len(key) == 2: # 2-length normal tuple ipath, item = key elif len(key) == 4: # 4-length sub-level tuple ipath, item, sub_ipath, sub_item = key return self.schema.path(ipath, item=item) + self.schema.path(sub_ipath, item=sub_item) else: # This is an invalid key return None elif isinstance(key, str): # This is a key string with just an ipath ipath = key item = None # This is a raw key path, used by backup/restore functionality if re.match(r'^/', ipath): return ipath else: # This is an invalid key return None return self.schema.path(ipath, item=item) # # Key Actions # def exists(self, key): """ Check if a key exists """ path = self.get_schema_path(key) if path is None: # This path is invalid, this is likely due to missing schema entries, so return False return False stat = self.zk_conn.exists(path) if stat: return True else: return False def read(self, key): """ Read data from a key """ try: path = self.get_schema_path(key) if path is None: # This path is invalid; this is likely due to missing schema entries, so return None return None return self.zk_conn.get(path)[0].decode(self.encoding) except NoNodeError: return None def write(self, kvpairs): """ Create or update one or more keys' data """ if type(kvpairs) is not list: self.log("ZKHandler error: Key-value sequence is not a list", state='e') return False transaction = self.zk_conn.transaction() for kvpair in (kvpairs): if type(kvpair) is not tuple: self.log("ZKHandler error: Key-value pair '{}' is not a tuple".format(kvpair), state='e') return False key = kvpair[0] value = kvpair[1] path = self.get_schema_path(key) if path is None: # This path is invalid; this is likely due to missing schema entries, so continue continue if not self.exists(key): # Creating a new key transaction.create(path, str(value).encode(self.encoding)) else: # Updating an existing key data = self.zk_conn.get(path) version = data[1].version # Validate the expected version after the execution new_version = version + 1 # Update the data transaction.set_data(path, str(value).encode(self.encoding)) # Check the data try: transaction.check(path, new_version) except TypeError: self.log("ZKHandler error: Key '{}' does not match expected version".format(path), state='e') return False try: transaction.commit() return True except Exception as e: self.log("ZKHandler error: Failed to commit transaction: {}".format(e), state='e') return False def delete(self, keys, recursive=True): """ Delete a key or list of keys (defaults to recursive) """ if type(keys) is not list: keys = [keys] for key in keys: if self.exists(key): try: path = self.get_schema_path(key) self.zk_conn.delete(path, recursive=recursive) except Exception as e: self.log("ZKHandler error: Failed to delete key {}: {}".format(path, e), state='e') return False return True def children(self, key): """ Lists all children of a key """ try: path = self.get_schema_path(key) if path is None: # This path is invalid; this is likely due to missing schema entries, so return None return None return self.zk_conn.get_children(path) except NoNodeError: return None def rename(self, kkpairs): """ Rename one or more keys to a new value """ if type(kkpairs) is not list: self.log("ZKHandler error: Key-key sequence is not a list", state='e') return False transaction = self.zk_conn.transaction() def rename_element(transaction, source_path, destination_path): data = self.zk_conn.get(source_path)[0] transaction.create(destination_path, data) if self.children(source_path): for child_path in self.children(source_path): child_source_path = "{}/{}".format(source_path, child_path) child_destination_path = "{}/{}".format(destination_path, child_path) rename_element(transaction, child_source_path, child_destination_path) transaction.delete(source_path) for kkpair in (kkpairs): if type(kkpair) is not tuple: self.log("ZKHandler error: Key-key pair '{}' is not a tuple".format(kkpair), state='e') return False source_key = kkpair[0] source_path = self.get_schema_path(source_key) if source_path is None: # This path is invalid; this is likely due to missing schema entries, so continue continue destination_key = kkpair[1] destination_path = self.get_schema_path(destination_key) if destination_path is None: # This path is invalid; this is likely due to missing schema entries, so continue continue if not self.exists(source_key): self.log("ZKHander error: Source key '{}' does not exist".format(source_path), state='e') return False if self.exists(destination_key): self.log("ZKHander error: Destination key '{}' already exists".format(destination_path), state='e') return False rename_element(transaction, source_path, destination_path) try: transaction.commit() return True except Exception as e: self.log("ZKHandler error: Failed to commit transaction: {}".format(e), state='e') return False # # Lock actions # def readlock(self, key): """ Acquires a read lock on a key """ count = 1 lock = None path = self.get_schema_path(key) while True: try: lock_id = str(uuid.uuid1()) lock = self.zk_conn.ReadLock(path, lock_id) break except NoNodeError: self.log("ZKHandler warning: Failed to acquire read lock on nonexistent path {}".format(path), state='e') return None except Exception as e: if count > 5: self.log("ZKHandler warning: Failed to acquire read lock after 5 tries: {}".format(e), state='e') break else: time.sleep(0.5) count += 1 continue return lock def writelock(self, key): """ Acquires a write lock on a key """ count = 1 lock = None path = self.get_schema_path(key) while True: try: lock_id = str(uuid.uuid1()) lock = self.zk_conn.WriteLock(path, lock_id) break except NoNodeError: self.log("ZKHandler warning: Failed to acquire write lock on nonexistent path {}".format(path), state='e') return None except Exception as e: if count > 5: self.log("ZKHandler warning: Failed to acquire write lock after 5 tries: {}".format(e), state='e') break else: time.sleep(0.5) count += 1 continue return lock def exclusivelock(self, key): """ Acquires an exclusive lock on a key """ count = 1 lock = None path = self.get_schema_path(key) while True: try: lock_id = str(uuid.uuid1()) lock = self.zk_conn.Lock(path, lock_id) break except NoNodeError: self.log("ZKHandler warning: Failed to acquire exclusive lock on nonexistent path {}".format(path), state='e') return None except Exception as e: if count > 5: self.log("ZKHandler warning: Failed to acquire exclusive lock after 5 tries: {}".format(e), state='e') break else: time.sleep(0.5) count += 1 continue return lock # # Schema classes # class ZKSchema(object): # Current version _version = 2 # Root for doing nested keys _schema_root = '' # Primary schema definition for the current version _schema = { 'version': f'{_version}', 'root': f'{_schema_root}', # Base schema defining core keys; this is all that is initialized on cluster init() 'base': { 'root': f'{_schema_root}', 'schema': f'{_schema_root}/schema', 'schema.version': f'{_schema_root}/schema/version', 'config': f'{_schema_root}/config', 'config.maintenance': f'{_schema_root}/config/maintenance', 'config.primary_node': f'{_schema_root}/config/primary_node', 'config.primary_node.sync_lock': f'{_schema_root}/config/primary_node/sync_lock', 'config.upstream_ip': f'{_schema_root}/config/upstream_ip', 'config.migration_target_selector': f'{_schema_root}/config/migration_target_selector', 'cmd': f'{_schema_root}/cmd', 'cmd.node': f'{_schema_root}/cmd/nodes', 'cmd.domain': f'{_schema_root}/cmd/domains', 'cmd.ceph': f'{_schema_root}/cmd/ceph', 'node': f'{_schema_root}/nodes', 'domain': f'{_schema_root}/domains', 'network': f'{_schema_root}/networks', 'storage': f'{_schema_root}/ceph', 'storage.util': f'{_schema_root}/ceph/util', 'osd': f'{_schema_root}/ceph/osds', 'pool': f'{_schema_root}/ceph/pools', 'volume': f'{_schema_root}/ceph/volumes', 'snapshot': f'{_schema_root}/ceph/snapshots', }, # The schema of an individual node entry (/nodes/{node_name}) 'node': { 'name': '', # The root key 'keepalive': '/keepalive', 'mode': '/daemonmode', 'data.active_schema': '/activeschema', 'data.latest_schema': '/latestschema', 'data.static': '/staticdata', 'data.pvc_version': '/pvcversion', 'running_domains': '/runningdomains', 'count.provisioned_domains': '/domainscount', 'count.networks': '/networkscount', 'state.daemon': '/daemonstate', 'state.router': '/routerstate', 'state.domain': '/domainstate', 'cpu.load': '/cpuload', 'vcpu.allocated': '/vcpualloc', 'memory.total': '/memtotal', 'memory.used': '/memused', 'memory.free': '/memfree', 'memory.allocated': '/memalloc', 'memory.provisioned': '/memprov', 'ipmi.hostname': '/ipmihostname', 'ipmi.username': '/ipmiusername', 'ipmi.password': '/ipmipassword', 'sriov': '/sriov', 'sriov.pf': '/sriov/pf', 'sriov.vf': '/sriov/vf', }, # The schema of an individual SR-IOV PF entry (/nodes/{node_name}/sriov/pf/{pf}) 'sriov_pf': { 'phy': '', # The root key 'mtu': '/mtu', 'vfcount': '/vfcount' }, # The schema of an individual SR-IOV VF entry (/nodes/{node_name}/sriov/vf/{vf}) 'sriov_vf': { 'phy': '', # The root key 'pf': '/pf', 'mtu': '/mtu', 'mac': '/mac', 'phy_mac': '/phy_mac', 'config': '/config', 'config.vlan_id': '/config/vlan_id', 'config.vlan_qos': '/config/vlan_qos', 'config.tx_rate_min': '/config/tx_rate_min', 'config.tx_rate_max': '/config/tx_rate_max', 'config.spoof_check': '/config/spoof_check', 'config.link_state': '/config/link_state', 'config.trust': '/config/trust', 'config.query_rss': '/config/query_rss', 'pci': '/pci', 'pci.domain': '/pci/domain', 'pci.bus': '/pci/bus', 'pci.slot': '/pci/slot', 'pci.function': '/pci/function', 'used': '/used', 'used_by': '/used_by' }, # The schema of an individual domain entry (/domains/{domain_uuid}) 'domain': { 'name': '', # The root key 'xml': '/xml', 'state': '/state', 'profile': '/profile', 'stats': '/stats', 'node': '/node', 'last_node': '/lastnode', 'failed_reason': '/failedreason', 'storage.volumes': '/rbdlist', 'console.log': '/consolelog', 'console.vnc': '/vnc', 'meta.autostart': '/node_autostart', 'meta.migrate_method': '/migration_method', 'meta.node_selector': '/node_selector', 'meta.node_limit': '/node_limit', 'migrate.sync_lock': '/migrate_sync_lock' }, # The schema of an individual network entry (/networks/{vni}) 'network': { 'vni': '', # The root key 'type': '/nettype', 'rule': '/firewall_rules', 'rule.in': '/firewall_rules/in', 'rule.out': '/firewall_rules/out', 'nameservers': '/name_servers', 'domain': '/domain', 'reservation': '/dhcp4_reservations', 'lease': '/dhcp4_leases', 'ip4.gateway': '/ip4_gateway', 'ip4.network': '/ip4_network', 'ip4.dhcp': '/dhcp4_flag', 'ip4.dhcp_start': '/dhcp4_start', 'ip4.dhcp_end': '/dhcp4_end', 'ip6.gateway': '/ip6_gateway', 'ip6.network': '/ip6_network', 'ip6.dhcp': '/dhcp6_flag' }, # The schema of an individual network DHCP(v4) reservation entry (/networks/{vni}/dhcp4_reservations/{mac}) 'reservation': { 'mac': '', # The root key 'ip': '/ipaddr', 'hostname': '/hostname' }, # The schema of an individual network DHCP(v4) lease entry (/networks/{vni}/dhcp4_leases/{mac}) 'lease': { 'mac': '', # The root key 'ip': '/ipaddr', 'hostname': '/hostname', 'expiry': '/expiry', 'client_id': '/clientid' }, # The schema for an individual network ACL entry (/networks/{vni}/firewall_rules/(in|out)/{acl} 'rule': { 'description': '', # The root key 'rule': '/rule', 'order': '/order' }, # The schema of an individual OSD entry (/ceph/osds/{osd_id}) 'osd': { 'id': '', # The root key 'node': '/node', 'device': '/device', 'stats': '/stats' }, # The schema of an individual pool entry (/ceph/pools/{pool_name}) 'pool': { 'name': '', # The root key 'pgs': '/pgs', 'stats': '/stats' }, # The schema of an individual volume entry (/ceph/volumes/{pool_name}/{volume_name}) 'volume': { 'name': '', # The root key 'stats': '/stats' }, # The schema of an individual snapshot entry (/ceph/volumes/{pool_name}/{volume_name}/{snapshot_name}) 'snapshot': { 'name': '', # The root key 'stats': '/stats' } } # Properties @property def schema_root(self): return self._schema_root @schema_root.setter def schema_root(self, schema_root): self._schema_root = schema_root @property def version(self): return int(self._version) @version.setter def version(self, version): self._version = int(version) @property def schema(self): return self._schema @schema.setter def schema(self, schema): self._schema = schema def __init__(self): pass def __repr__(self): return f'ZKSchema({self.version})' def __lt__(self, other): if self.version < other.version: return True else: return False def __le__(self, other): if self.version <= other.version: return True else: return False def __gt__(self, other): if self.version > other.version: return True else: return False def __ge__(self, other): if self.version >= other.version: return True else: return False def __eq__(self, other): if self.version == other.version: return True else: return False # Load the schema of a given version from a file def load(self, version, quiet=False): if not quiet: print(f'Loading schema version {version}') with open(f'daemon_lib/migrations/versions/{version}.json', 'r') as sfh: self.schema = json.load(sfh) self.version = self.schema.get('version') # Get key paths def path(self, ipath, item=None): itype, *ipath = ipath.split('.') if item is None: return self.schema.get(itype).get('.'.join(ipath)) else: base_path = self.schema.get('base').get(itype, None) if base_path is None: # This should only really happen for second-layer key types where the helper functions join them together base_path = '' if not ipath: # This is a root path return f'{base_path}/{item}' sub_path = self.schema.get(itype).get('.'.join(ipath)) if sub_path is None: # We didn't find the path we're looking for, so we don't want to do anything return None return f'{base_path}/{item}{sub_path}' # Get keys of a schema location def keys(self, itype=None): if itype is None: return list(self.schema.get('base').keys()) else: return list(self.schema.get(itype).keys()) # Get the active version of a cluster's schema def get_version(self, zkhandler): try: current_version = zkhandler.read(self.path('base.schema.version')) except NoNodeError: current_version = 0 return current_version # Validate an active schema against a Zookeeper cluster def validate(self, zkhandler, logger=None): result = True # Walk the entire tree checking our schema for elem in ['base']: for key in self.keys(elem): kpath = f'{elem}.{key}' if not zkhandler.zk_conn.exists(self.path(kpath)): if logger is not None: logger.out(f'Key not found: {self.path(kpath)}', state='w') result = False for elem in ['node', 'domain', 'network', 'osd', 'pool']: # First read all the subelements of the key class for child in zkhandler.zk_conn.get_children(self.path(f'base.{elem}')): # For each key in the schema for that particular elem for ikey in self.keys(elem): kpath = f'{elem}.{ikey}' # Validate that the key exists for that child if not zkhandler.zk_conn.exists(self.path(kpath, child)): if logger is not None: logger.out(f'Key not found: {self.path(kpath, child)}', state='w') result = False # Continue for child keys under network (reservation, acl) if elem in ['network'] and ikey in ['reservation', 'rule.in', 'rule.out']: if ikey in ['rule.in', 'rule.out']: sikey = 'rule' else: sikey = ikey npath = self.path(f'{elem}.{ikey}', child) for nchild in zkhandler.zk_conn.get_children(npath): nkpath = f'{npath}/{nchild}' for esikey in self.keys(sikey): nkipath = f'{nkpath}/{esikey}' if not zkhandler.zk_conn.exists(nkipath): result = False # One might expect child keys under node (specifically, sriov.pf and sriov.vf) to be # managed here as well, but those are created automatically every time pvcnoded starts # and thus never need to be validated or applied. # These two have several children layers that must be parsed through for elem in ['volume']: # First read all the subelements of the key class (pool layer) for pchild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}')): # Finally read all the subelements of the key class (volume layer) for vchild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}') + f'/{pchild}'): child = f'{pchild}/{vchild}' # For each key in the schema for that particular elem for ikey in self.keys(elem): kpath = f'{elem}.{ikey}' # Validate that the key exists for that child if not zkhandler.zk_conn.exists(self.path(kpath, child)): if logger is not None: logger.out(f'Key not found: {self.path(kpath, child)}', state='w') result = False for elem in ['snapshot']: # First read all the subelements of the key class (pool layer) for pchild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}')): # Next read all the subelements of the key class (volume layer) for vchild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}') + f'/{pchild}'): # Finally read all the subelements of the key class (volume layer) for schild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}') + f'/{pchild}/{vchild}'): child = f'{pchild}/{vchild}/{schild}' # For each key in the schema for that particular elem for ikey in self.keys(elem): kpath = f'{elem}.{ikey}' # Validate that the key exists for that child if not zkhandler.zk_conn.exists(self.path(kpath, child)): if logger is not None: logger.out(f'Key not found: {self.path(kpath, child)}', state='w') result = False return result # Apply the current schema to the cluster def apply(self, zkhandler): # Walk the entire tree checking our schema for elem in ['base']: for key in self.keys(elem): kpath = f'{elem}.{key}' if not zkhandler.zk_conn.exists(self.path(kpath)): # Ensure that we create base.schema.version with the current valid version value if kpath == 'base.schema.version': data = str(self.version) else: data = '' zkhandler.zk_conn.create(self.path(kpath), data.encode(zkhandler.encoding)) for elem in ['node', 'domain', 'network', 'osd', 'pool']: # First read all the subelements of the key class for child in zkhandler.zk_conn.get_children(self.path(f'base.{elem}')): # For each key in the schema for that particular elem for ikey in self.keys(elem): kpath = f'{elem}.{ikey}' # Validate that the key exists for that child if not zkhandler.zk_conn.exists(self.path(kpath, child)): zkhandler.zk_conn.create(self.path(kpath, child), ''.encode(zkhandler.encoding)) # Continue for child keys under network (reservation, acl) if elem in ['network'] and ikey in ['reservation', 'rule.in', 'rule.out']: if ikey in ['rule.in', 'rule.out']: sikey = 'rule' else: sikey = ikey npath = self.path(f'{elem}.{ikey}', child) for nchild in zkhandler.zk_conn.get_children(npath): nkpath = f'{npath}/{nchild}' for esikey in self.keys(sikey): nkipath = f'{nkpath}/{esikey}' if not zkhandler.zk_conn.exists(nkipath): zkhandler.zk_conn.create(nkipath, ''.encode(zkhandler.encoding)) # One might expect child keys under node (specifically, sriov.pf and sriov.vf) to be # managed here as well, but those are created automatically every time pvcnoded starts # and thus never need to be validated or applied. # These two have several children layers that must be parsed through for elem in ['volume']: # First read all the subelements of the key class (pool layer) for pchild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}')): # Finally read all the subelements of the key class (volume layer) for vchild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}') + f'/{pchild}'): child = f'{pchild}/{vchild}' # For each key in the schema for that particular elem for ikey in self.keys(elem): kpath = f'{elem}.{ikey}' # Validate that the key exists for that child if not zkhandler.zk_conn.exists(self.path(kpath, child)): zkhandler.zk_conn.create(self.path(kpath, child), ''.encode(zkhandler.encoding)) for elem in ['snapshot']: # First read all the subelements of the key class (pool layer) for pchild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}')): # Next read all the subelements of the key class (volume layer) for vchild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}') + f'/{pchild}'): # Finally read all the subelements of the key class (volume layer) for schild in zkhandler.zk_conn.get_children(self.path(f'base.{elem}') + f'/{pchild}/{vchild}'): child = f'{pchild}/{vchild}/{schild}' # For each key in the schema for that particular elem for ikey in self.keys(elem): kpath = f'{elem}.{ikey}' # Validate that the key exists for that child if not zkhandler.zk_conn.exists(self.path(kpath, child)): zkhandler.zk_conn.create(self.path(kpath, child), ''.encode(zkhandler.encoding)) # Migrate key diffs def run_migrate(self, zkhandler, changes): diff_add = changes['add'] diff_remove = changes['remove'] diff_rename = changes['rename'] add_tasks = list() for key in diff_add.keys(): add_tasks.append((diff_add[key], '')) remove_tasks = list() for key in diff_remove.keys(): remove_tasks.append(diff_remove[key]) rename_tasks = list() for key in diff_rename.keys(): rename_tasks.append((diff_rename[key]['from'], diff_rename[key]['to'])) zkhandler.write(add_tasks) zkhandler.delete(remove_tasks) zkhandler.rename(rename_tasks) # Migrate from older to newer schema def migrate(self, zkhandler, new_version): # Determine the versions in between versions = ZKSchema.find_all(start=self.version, end=new_version) if versions is None: return for version in versions: # Create a new schema at that version zkschema_new = ZKSchema() zkschema_new.load(version) # Get a list of changes changes = ZKSchema.key_diff(self, zkschema_new) # Apply those changes self.run_migrate(zkhandler, changes) # Rollback from newer to older schema def rollback(self, zkhandler, old_version): # Determine the versions in between versions = ZKSchema.find_all(start=old_version - 1, end=self.version - 1) if versions is None: return versions.reverse() for version in versions: # Create a new schema at that version zkschema_old = ZKSchema() zkschema_old.load(version) # Get a list of changes changes = ZKSchema.key_diff(self, zkschema_old) # Apply those changes self.run_migrate(zkhandler, changes) @classmethod def key_diff(cls, schema_a, schema_b): # schema_a = current # schema_b = new diff_add = dict() diff_remove = dict() diff_rename = dict() # Parse through each core element for elem in ['base', 'node', 'domain', 'network', 'osd', 'pool', 'volume', 'snapshot']: set_a = set(schema_a.keys(elem)) set_b = set(schema_b.keys(elem)) diff_keys = set_a ^ set_b for item in diff_keys: elem_item = f'{elem}.{item}' if item not in schema_a.keys(elem) and item in schema_b.keys(elem): diff_add[elem_item] = schema_b.path(elem_item) if item in schema_a.keys(elem) and item not in schema_b.keys(elem): diff_remove[elem_item] = schema_a.path(elem_item) for item in set_b: elem_item = f'{elem}.{item}' if schema_a.path(elem_item) is not None and \ schema_b.path(elem_item) is not None and \ schema_a.path(elem_item) != schema_b.path(elem_item): diff_rename[elem_item] = {'from': schema_a.path(elem_item), 'to': schema_b.path(elem_item)} return {'add': diff_add, 'remove': diff_remove, 'rename': diff_rename} # Load in the schemal of the current cluster @classmethod def load_current(cls, zkhandler): new_instance = cls() version = new_instance.get_version(zkhandler) new_instance.load(version) return new_instance # Write the latest schema to a file @classmethod def write(cls): schema_file = 'daemon_lib/migrations/versions/{}.json'.format(cls._version) with open(schema_file, 'w') as sfh: json.dump(cls._schema, sfh) # Static methods for reading information from the files @staticmethod def find_all(start=0, end=None): versions = list() for version in os.listdir('daemon_lib/migrations/versions'): sequence_id = int(version.split('.')[0]) if end is None: if sequence_id > start: versions.append(sequence_id) else: if sequence_id > start and sequence_id <= end: versions.append(sequence_id) if len(versions) > 0: return versions else: return None @staticmethod def find_latest(): latest_version = 0 for version in os.listdir('daemon_lib/migrations/versions'): sequence_id = int(version.split('.')[0]) if sequence_id > latest_version: latest_version = sequence_id return latest_version