pvc/client-common/common.py

302 lines
8.3 KiB
Python

#!/usr/bin/env python3
# common.py - PVC client function library, common fuctions
# Part of the Parallel Virtual Cluster (PVC) system
#
# Copyright (C) 2018 Joshua M. Boniface <joshua@boniface.me>
#
# 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, either version 3 of the License, or
# (at your option) any later version.
#
# 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 uuid
import lxml
import math
import kazoo.client
import client_lib.zkhandler as zkhandler
###############################################################################
# Supplemental functions
###############################################################################
#
# Validate a UUID
#
def validateUUID(dom_uuid):
try:
uuid.UUID(dom_uuid)
return True
except:
return False
#
# Connect and disconnect from Zookeeper
#
def startZKConnection(zk_host):
zk_conn = kazoo.client.KazooClient(hosts=zk_host)
zk_conn.start()
return zk_conn
def stopZKConnection(zk_conn):
zk_conn.stop()
zk_conn.close()
return 0
#
# Parse a Domain XML object
#
def getDomainXML(zk_conn, dom_uuid):
try:
xml = zkhandler.readdata(zk_conn, '/domains/{}/xml'.format(dom_uuid))
except:
return None
# Parse XML using lxml.objectify
parsed_xml = lxml.objectify.fromstring(xml)
return parsed_xml
#
# Get the main details for a VM object from XML
#
def getDomainMainDetails(parsed_xml):
# Get the information we want from it
duuid = str(parsed_xml.uuid)
try:
ddescription = str(parsed_xml.description)
except AttributeError:
ddescription = "N/A"
dname = str(parsed_xml.name)
dmemory = str(parsed_xml.memory)
dmemory_unit = str(parsed_xml.memory.attrib['unit'])
if dmemory_unit == 'KiB':
dmemory = int(int(dmemory) / 1024)
elif dmemory_unit == 'GiB':
dmemory = int(int(dmemory) * 1024)
dvcpu = str(parsed_xml.vcpu)
try:
dvcputopo = '{}/{}/{}'.format(parsed_xml.cpu.topology.attrib['sockets'], parsed_xml.cpu.topology.attrib['cores'], parsed_xml.cpu.topology.attrib['threads'])
except:
dvcputopo = 'N/A'
return duuid, dname, ddescription, dmemory, dvcpu, dvcputopo
#
# Get long-format details
#
def getDomainExtraDetails(parsed_xml):
dtype = parsed_xml.os.type
darch = parsed_xml.os.type.attrib['arch']
dmachine = parsed_xml.os.type.attrib['machine']
dconsole = parsed_xml.devices.console.attrib['type']
demulator = parsed_xml.devices.emulator
return dtype, darch, dmachine, dconsole, demulator
#
# Get CPU features
#
def getDomainCPUFeatures(parsed_xml):
dfeatures = []
for feature in parsed_xml.features.getchildren():
dfeatures.append(feature.tag)
return dfeatures
#
# Get disk devices
#
def getDomainDisks(parsed_xml):
ddisks = []
for device in parsed_xml.devices.getchildren():
if device.tag == 'disk':
disk_attrib = device.source.attrib
disk_target = device.target.attrib
disk_type = device.attrib['type']
if disk_type == 'network':
disk_obj = { 'type': disk_attrib.get('protocol'), 'name': disk_attrib.get('name'), 'dev': disk_target.get('dev'), 'bus': disk_target.get('bus') }
elif disk_type == 'file':
disk_obj = { 'type': 'file', 'name': disk_attrib.get('file'), 'dev': disk_target.get('dev'), 'bus': disk_target.get('bus') }
else:
disk_obj = {}
ddisks.append(disk_obj)
return ddisks
#
# Get network devices
#
def getDomainNetworks(parsed_xml):
dnets = []
for device in parsed_xml.devices.getchildren():
if device.tag == 'interface':
net_type = device.attrib['type']
net_mac = device.mac.attrib['address']
net_bridge = device.source.attrib[net_type]
net_model = device.model.attrib['type']
net_obj = { 'type': net_type, 'mac': net_mac, 'source': net_bridge, 'model': net_model }
dnets.append(net_obj)
return dnets
#
# Get controller devices
#
def getDomainControllers(parsed_xml):
dcontrollers = []
for device in parsed_xml.devices.getchildren():
if device.tag == 'controller':
controller_type = device.attrib['type']
try:
controller_model = device.attrib['model']
except KeyError:
controller_model = 'none'
controller_obj = { 'type': controller_type, 'model': controller_model }
dcontrollers.append(controller_obj)
return dcontrollers
#
# Verify node is valid in cluster
#
def verifyNode(zk_conn, node):
if zkhandler.exists(zk_conn, '/nodes/{}'.format(node)):
return True
else:
return False
#
# Get the primary coordinator node
#
def getPrimaryNode(zk_conn):
failcount = 0
while True:
try:
primary_node = zkhandler.readdata(zk_conn, '/primary_node')
except:
primary_node == 'none'
if primary_node == 'none':
raise
time.sleep(1)
failcount += 1
continue
else:
break
if failcount > 2:
return None
return primary_node
#
# Get the list of valid target nodes
#
def getNodes(zk_conn, dom_uuid):
valid_node_list = []
full_node_list = zkhandler.listchildren(zk_conn, '/nodes')
try:
current_node = zkhandler.readdata(zk_conn, '/domains/{}/node'.format(dom_uuid))
except:
current_node = None
for node in full_node_list:
daemon_state = zkhandler.readdata(zk_conn, '/nodes/{}/daemonstate'.format(node))
domain_state = zkhandler.readdata(zk_conn, '/nodes/{}/domainstate'.format(node))
if node == current_node:
continue
if daemon_state != 'run' or domain_state != 'ready':
continue
valid_node_list.append(node)
return valid_node_list
#
# Find a migration target
#
def findTargetNode(zk_conn, search_field, dom_uuid):
if search_field == 'mem':
return findTargetNodeMem(zk_conn, dom_uuid)
if search_field == 'load':
return findTargetNodeLoad(zk_conn, dom_uuid)
if search_field == 'vcpus':
return findTargetNodeVCPUs(zk_conn, dom_uuid)
if search_field == 'vms':
return findTargetNodeVMs(zk_conn, dom_uuid)
return None
# via allocated memory
def findTargetNodeMem(zk_conn, dom_uuid):
least_alloc = math.inf
target_node = None
node_list = getNodes(zk_conn, dom_uuid)
for node in node_list:
alloc = float(zkhandler.readdata(zk_conn, '/nodes/{}/memalloc'.format(node)))
if alloc < least_alloc:
least_alloc = alloc
target_node = node
return target_node
# via load average
def findTargetNodeLoad(zk_conn, dom_uuid):
least_load = math.inf
target_node = None
node_list = getNodes(zk_conn, dom_uuid)
for node in node_list:
load = float(zkhandler.readdata(zk_conn, '/nodes/{}/cpuload'.format(node)))
if load < least_load:
least_load = load
target_node = node
return target_node
# via total vCPUs
def findTargetNodeVCPUs(zk_conn, dom_uuid):
least_vcpus = math.inf
target_node = None
node_list = getNodes(zk_conn, dom_uuid)
for node in node_list:
vcpus = float(zkhandler.readdata(zk_conn, '/nodes/{}/vcpualloc'.format(node)))
if vcpus < least_vcpus:
least_vcpus = vcpus
target_node = node
return target_node
# via total VMs
def findTargetNodeVMs(zk_conn, dom_uuid):
least_vms = math.inf
target_node = None
node_list = getNodes(zk_conn, dom_uuid)
for node in node_list:
vms = float(zkhandler.readdata(zk_conn, '/nodes/{}/domainscount'.format(node)))
if vms < least_vms:
least_vms = vms
target_node = node
return target_node