pvc/client-cli/cli_lib/vm.py

649 lines
25 KiB
Python

#!/usr/bin/env python3
# vm.py - PVC CLI client function library, VM functions
# Part of the Parallel Virtual Cluster (PVC) system
#
# Copyright (C) 2018-2020 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 time
import re
import cli_lib.ansiprint as ansiprint
from cli_lib.common import call_api, format_bytes, format_metric
#
# Primary functions
#
def vm_info(config, vm):
"""
Get information about (single) VM
API endpoint: GET /api/v1/vm/{vm}
API arguments:
API schema: {json_data_object}
"""
response = call_api(config, 'get', '/vm/{vm}'.format(vm=vm))
if response.status_code == 200:
if isinstance(response.json(), list) and len(response.json()) > 1:
# No exact match; return not found
return False, "VM not found."
else:
if isinstance(response.json(), list):
response = response.json()[0]
else:
response = response.json()
return True, response
return True, response.json()
else:
return False, response.json().get('message', '')
def vm_list(config, limit, target_node, target_state):
"""
Get list information about VMs (limited by {limit}, {target_node}, or {target_state})
API endpoint: GET /api/v1/vm
API arguments: limit={limit}, node={target_node}, state={target_state}
API schema: [{json_data_object},{json_data_object},etc.]
"""
params = dict()
if limit:
params['limit'] = limit
if target_node:
params['node'] = target_node
if target_state:
params['state'] = target_state
response = call_api(config, 'get', '/vm', params=params)
if response.status_code == 200:
return True, response.json()
else:
return False, response.json().get('message', '')
def vm_define(config, xml, node, node_limit, node_selector, node_autostart, migration_method):
"""
Define a new VM on the cluster
API endpoint: POST /vm
API arguments: xml={xml}, node={node}, limit={node_limit}, selector={node_selector}, autostart={node_autostart}, migration_method={migration_method}
API schema: {"message":"{data}"}
"""
params = {
'node': node,
'limit': node_limit,
'selector': node_selector,
'autostart': node_autostart,
'migration_method': migration_method
}
data = {
'xml': xml
}
response = call_api(config, 'post', '/vm', params=params, data=data)
if response.status_code == 200:
retstatus = True
else:
retstatus = False
return retstatus, response.json().get('message', '')
def vm_modify(config, vm, xml, restart):
"""
Modify the configuration of VM
API endpoint: PUT /vm/{vm}
API arguments: xml={xml}, restart={restart}
API schema: {"message":"{data}"}
"""
params = {
'restart': restart
}
data = {
'xml': xml
}
response = call_api(config, 'put', '/vm/{vm}'.format(vm=vm), params=params, data=data)
if response.status_code == 200:
retstatus = True
else:
retstatus = False
return retstatus, response.json().get('message', '')
def vm_metadata(config, vm, node_limit, node_selector, node_autostart, migration_method, provisioner_profile):
"""
Modify PVC metadata of a VM
API endpoint: GET /vm/{vm}/meta, POST /vm/{vm}/meta
API arguments: limit={node_limit}, selector={node_selector}, autostart={node_autostart}, migration_method={migration_method} profile={provisioner_profile}
API schema: {"message":"{data}"}
"""
params = dict()
# Update any params that we've sent
if node_limit is not None:
params['limit'] = node_limit
if node_selector is not None:
params['selector'] = node_selector
if node_autostart is not None:
params['autostart'] = node_autostart
if migration_method is not None:
params['migration_method'] = migration_method
if provisioner_profile is not None:
params['profile'] = provisioner_profile
# Write the new metadata
response = call_api(config, 'post', '/vm/{vm}/meta'.format(vm=vm), params=params)
if response.status_code == 200:
retstatus = True
else:
retstatus = False
return retstatus, response.json().get('message', '')
def vm_remove(config, vm, delete_disks=False):
"""
Remove a VM
API endpoint: DELETE /vm/{vm}
API arguments: delete_disks={delete_disks}
API schema: {"message":"{data}"}
"""
params = {
'delete_disks': delete_disks
}
response = call_api(config, 'delete', '/vm/{vm}'.format(vm=vm), params=params)
if response.status_code == 200:
retstatus = True
else:
retstatus = False
return retstatus, response.json().get('message', '')
def vm_state(config, vm, target_state, wait=False):
"""
Modify the current state of VM
API endpoint: POST /vm/{vm}/state
API arguments: state={state}, wait={wait}
API schema: {"message":"{data}"}
"""
params = {
'state': target_state,
'wait': str(wait).lower()
}
response = call_api(config, 'post', '/vm/{vm}/state'.format(vm=vm), params=params)
if response.status_code == 200:
retstatus = True
else:
retstatus = False
return retstatus, response.json().get('message', '')
def vm_node(config, vm, target_node, action, force=False, wait=False, force_live=False):
"""
Modify the current node of VM via {action}
API endpoint: POST /vm/{vm}/node
API arguments: node={target_node}, action={action}, force={force}, wait={wait}, force_live={force_live}
API schema: {"message":"{data}"}
"""
params = {
'node': target_node,
'action': action,
'force': str(force).lower(),
'wait': str(wait).lower(),
'force_live': str(force_live).lower()
}
response = call_api(config, 'post', '/vm/{vm}/node'.format(vm=vm), params=params)
if response.status_code == 200:
retstatus = True
else:
retstatus = False
return retstatus, response.json().get('message', '')
def vm_locks(config, vm):
"""
Flush RBD locks of (stopped) VM
API endpoint: POST /vm/{vm}/locks
API arguments:
API schema: {"message":"{data}"}
"""
response = call_api(config, 'post', '/vm/{vm}/locks'.format(vm=vm))
if response.status_code == 200:
retstatus = True
else:
retstatus = False
return retstatus, response.json().get('message', '')
def view_console_log(config, vm, lines=100):
"""
Return console log lines from the API (and display them in a pager in the main CLI)
API endpoint: GET /vm/{vm}/console
API arguments: lines={lines}
API schema: {"name":"{vmname}","data":"{console_log}"}
"""
params = {
'lines': lines
}
response = call_api(config, 'get', '/vm/{vm}/console'.format(vm=vm), params=params)
if response.status_code != 200:
return False, response.json().get('message', '')
console_log = response.json()['data']
# Shrink the log buffer to length lines
shrunk_log = console_log.split('\n')[-lines:]
loglines = '\n'.join(shrunk_log)
return True, loglines
def follow_console_log(config, vm, lines=10):
"""
Return and follow console log lines from the API
API endpoint: GET /vm/{vm}/console
API arguments: lines={lines}
API schema: {"name":"{vmname}","data":"{console_log}"}
"""
params = {
'lines': lines
}
response = call_api(config, 'get', '/vm/{vm}/console'.format(vm=vm), params=params)
if response.status_code != 200:
return False, response.json().get('message', '')
# Shrink the log buffer to length lines
console_log = response.json()['data']
shrunk_log = console_log.split('\n')[-lines:]
loglines = '\n'.join(shrunk_log)
# Print the initial data and begin following
print(loglines, end='')
while True:
# Grab the next line set
try:
response = call_api(config, 'get', '/vm/{vm}/console'.format(vm=vm), params=params)
new_console_log = response.json()['data']
except Exception:
break
# Split the new and old log strings into constitutent lines
old_console_loglines = console_log.split('\n')
new_console_loglines = new_console_log.split('\n')
# Set the console log to the new log value for the next iteration
console_log = new_console_log
# Remove the lines from the old log until we hit the first line of the new log; this
# ensures that the old log is a string that we can remove from the new log entirely
for index, line in enumerate(old_console_loglines, start=0):
if line == new_console_loglines[0]:
del old_console_loglines[0:index]
break
# Rejoin the log lines into strings
old_console_log = '\n'.join(old_console_loglines)
new_console_log = '\n'.join(new_console_loglines)
# Remove the old lines from the new log
diff_console_log = new_console_log.replace(old_console_log, "")
# If there's a difference, print it out
if diff_console_log:
print(diff_console_log, end='')
# Wait a second
time.sleep(1)
return True, ''
#
# Output display functions
#
def format_info(config, domain_information, long_output):
# Format a nice output; do this line-by-line then concat the elements at the end
ainformation = []
ainformation.append('{}Virtual machine information:{}'.format(ansiprint.bold(), ansiprint.end()))
ainformation.append('')
# Basic information
ainformation.append('{}UUID:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['uuid']))
ainformation.append('{}Name:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['name']))
ainformation.append('{}Description:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['description']))
ainformation.append('{}Profile:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['profile']))
ainformation.append('{}Memory (M):{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['memory']))
ainformation.append('{}vCPUs:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['vcpu']))
ainformation.append('{}Topology (S/C/T):{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['vcpu_topology']))
if long_output is True:
# Virtualization information
ainformation.append('')
ainformation.append('{}Emulator:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['emulator']))
ainformation.append('{}Type:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['type']))
ainformation.append('{}Arch:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['arch']))
ainformation.append('{}Machine:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['machine']))
ainformation.append('{}Features:{} {}'.format(ansiprint.purple(), ansiprint.end(), ' '.join(domain_information['features'])))
ainformation.append('')
ainformation.append('{0}Memory stats:{1} {2}Swap In Swap Out Faults (maj/min) Available Usable Unused RSS{3}'.format(ansiprint.purple(), ansiprint.end(), ansiprint.bold(), ansiprint.end()))
ainformation.append(' {0: <7} {1: <8} {2: <16} {3: <10} {4: <7} {5: <7} {6: <10}'.format(
format_metric(domain_information['memory_stats'].get('swap_in')),
format_metric(domain_information['memory_stats'].get('swap_out')),
'/'.join([format_metric(domain_information['memory_stats'].get('major_fault')), format_metric(domain_information['memory_stats'].get('minor_fault'))]),
format_bytes(domain_information['memory_stats'].get('available')*1024),
format_bytes(domain_information['memory_stats'].get('usable')*1024),
format_bytes(domain_information['memory_stats'].get('unused')*1024),
format_bytes(domain_information['memory_stats'].get('rss')*1024)
))
ainformation.append('')
ainformation.append('{0}vCPU stats:{1} {2}CPU time (ns) User time (ns) System time (ns){3}'.format(ansiprint.purple(), ansiprint.end(), ansiprint.bold(), ansiprint.end()))
ainformation.append(' {0: <16} {1: <16} {2: <15}'.format(
str(domain_information['vcpu_stats'].get('cpu_time')),
str(domain_information['vcpu_stats'].get('user_time')),
str(domain_information['vcpu_stats'].get('system_time'))
))
# PVC cluster information
ainformation.append('')
dstate_colour = {
'start': ansiprint.green(),
'restart': ansiprint.yellow(),
'shutdown': ansiprint.yellow(),
'stop': ansiprint.red(),
'disable': ansiprint.blue(),
'fail': ansiprint.red(),
'migrate': ansiprint.blue(),
'unmigrate': ansiprint.blue(),
'provision': ansiprint.blue()
}
ainformation.append('{}State:{} {}{}{}'.format(ansiprint.purple(), ansiprint.end(), dstate_colour[domain_information['state']], domain_information['state'], ansiprint.end()))
ainformation.append('{}Current Node:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['node']))
if not domain_information['last_node']:
domain_information['last_node'] = "N/A"
ainformation.append('{}Previous Node:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['last_node']))
# Get a failure reason if applicable
if domain_information['failed_reason']:
ainformation.append('')
ainformation.append('{}Failure reason:{} {}'.format(ansiprint.purple(), ansiprint.end(), domain_information['failed_reason']))
if not domain_information.get('node_selector'):
formatted_node_selector = "False"
else:
formatted_node_selector = domain_information['node_selector']
if not domain_information.get('node_limit'):
formatted_node_limit = "False"
else:
formatted_node_limit = ', '.join(domain_information['node_limit'])
if not domain_information.get('node_autostart'):
formatted_node_autostart = "False"
else:
formatted_node_autostart = domain_information['node_autostart']
if not domain_information.get('migration_method'):
formatted_migration_method = "none"
else:
formatted_migration_method = domain_information['migration_method']
ainformation.append('{}Migration selector:{} {}'.format(ansiprint.purple(), ansiprint.end(), formatted_node_selector))
ainformation.append('{}Node limit:{} {}'.format(ansiprint.purple(), ansiprint.end(), formatted_node_limit))
ainformation.append('{}Autostart:{} {}'.format(ansiprint.purple(), ansiprint.end(), formatted_node_autostart))
ainformation.append('{}Migration Method:{} {}'.format(ansiprint.purple(), ansiprint.end(), formatted_migration_method))
# Network list
net_list = []
for net in domain_information['networks']:
# Split out just the numerical (VNI) part of the brXXXX name
net_vnis = re.findall(r'\d+', net['source'])
if net_vnis:
net_vni = net_vnis[0]
else:
net_vni = re.sub('br', '', net['source'])
response = call_api(config, 'get', '/network/{net}'.format(net=net_vni))
if response.status_code != 200 and net_vni not in ['cluster', 'storage', 'upstream']:
net_list.append(ansiprint.red() + net_vni + ansiprint.end() + ' [invalid]')
else:
net_list.append(net_vni)
ainformation.append('')
ainformation.append('{}Networks:{} {}'.format(ansiprint.purple(), ansiprint.end(), ', '.join(net_list)))
if long_output is True:
# Disk list
ainformation.append('')
name_length = 0
for disk in domain_information['disks']:
_name_length = len(disk['name']) + 1
if _name_length > name_length:
name_length = _name_length
ainformation.append('{0}Disks:{1} {2}ID Type {3: <{width}} Dev Bus Requests (r/w) Data (r/w){4}'.format(ansiprint.purple(), ansiprint.end(), ansiprint.bold(), 'Name', ansiprint.end(), width=name_length))
for disk in domain_information['disks']:
ainformation.append(' {0: <3} {1: <5} {2: <{width}} {3: <4} {4: <5} {5: <15} {6}'.format(
domain_information['disks'].index(disk),
disk['type'],
disk['name'],
disk['dev'],
disk['bus'],
'/'.join([str(format_metric(disk['rd_req'])), str(format_metric(disk['wr_req']))]),
'/'.join([str(format_bytes(disk['rd_bytes'])), str(format_bytes(disk['wr_bytes']))]),
width=name_length
))
ainformation.append('')
ainformation.append('{}Interfaces:{} {}ID Type Source Model MAC Data (r/w) Packets (r/w) Errors (r/w){}'.format(ansiprint.purple(), ansiprint.end(), ansiprint.bold(), ansiprint.end()))
for net in domain_information['networks']:
ainformation.append(' {0: <3} {1: <7} {2: <10} {3: <8} {4: <18} {5: <12} {6: <15} {7: <12}'.format(
domain_information['networks'].index(net),
net['type'],
net['source'],
net['model'],
net['mac'],
'/'.join([str(format_bytes(net['rd_bytes'])), str(format_bytes(net['wr_bytes']))]),
'/'.join([str(format_metric(net['rd_packets'])), str(format_metric(net['wr_packets']))]),
'/'.join([str(format_metric(net['rd_errors'])), str(format_metric(net['wr_errors']))]),
))
# Controller list
ainformation.append('')
ainformation.append('{}Controllers:{} {}ID Type Model{}'.format(ansiprint.purple(), ansiprint.end(), ansiprint.bold(), ansiprint.end()))
for controller in domain_information['controllers']:
ainformation.append(' {0: <3} {1: <14} {2: <8}'.format(domain_information['controllers'].index(controller), controller['type'], controller['model']))
# Join it all together
ainformation.append('')
return '\n'.join(ainformation)
def format_list(config, vm_list, raw):
# Handle single-element lists
if not isinstance(vm_list, list):
vm_list = [vm_list]
# Function to strip the "br" off of nets and return a nicer list
def getNiceNetID(domain_information):
# Network list
net_list = []
for net in domain_information['networks']:
# Split out just the numerical (VNI) part of the brXXXX name
net_vnis = re.findall(r'\d+', net['source'])
if net_vnis:
net_vni = net_vnis[0]
else:
net_vni = re.sub('br', '', net['source'])
net_list.append(net_vni)
return net_list
# Handle raw mode since it just lists the names
if raw:
ainformation = list()
for vm in sorted(item['name'] for item in vm_list):
ainformation.append(vm)
return '\n'.join(ainformation)
vm_list_output = []
# Determine optimal column widths
# Dynamic columns: node_name, node, migrated
vm_name_length = 5
vm_uuid_length = 37
vm_state_length = 6
vm_nets_length = 9
vm_ram_length = 8
vm_vcpu_length = 6
vm_node_length = 8
vm_migrated_length = 10
for domain_information in vm_list:
net_list = getNiceNetID(domain_information)
# vm_name column
_vm_name_length = len(domain_information['name']) + 1
if _vm_name_length > vm_name_length:
vm_name_length = _vm_name_length
# vm_state column
_vm_state_length = len(domain_information['state']) + 1
if _vm_state_length > vm_state_length:
vm_state_length = _vm_state_length
# vm_nets column
_vm_nets_length = len(','.join(net_list)) + 1
if _vm_nets_length > vm_nets_length:
vm_nets_length = _vm_nets_length
# vm_node column
_vm_node_length = len(domain_information['node']) + 1
if _vm_node_length > vm_node_length:
vm_node_length = _vm_node_length
# vm_migrated column
_vm_migrated_length = len(domain_information['migrated']) + 1
if _vm_migrated_length > vm_migrated_length:
vm_migrated_length = _vm_migrated_length
# Format the string (header)
vm_list_output.append(
'{bold}{vm_name: <{vm_name_length}} {vm_uuid: <{vm_uuid_length}} \
{vm_state_colour}{vm_state: <{vm_state_length}}{end_colour} \
{vm_networks: <{vm_nets_length}} \
{vm_memory: <{vm_ram_length}} {vm_vcpu: <{vm_vcpu_length}} \
{vm_node: <{vm_node_length}} \
{vm_migrated: <{vm_migrated_length}}{end_bold}'.format(
vm_name_length=vm_name_length,
vm_uuid_length=vm_uuid_length,
vm_state_length=vm_state_length,
vm_nets_length=vm_nets_length,
vm_ram_length=vm_ram_length,
vm_vcpu_length=vm_vcpu_length,
vm_node_length=vm_node_length,
vm_migrated_length=vm_migrated_length,
bold=ansiprint.bold(),
end_bold=ansiprint.end(),
vm_state_colour='',
end_colour='',
vm_name='Name',
vm_uuid='UUID',
vm_state='State',
vm_networks='Networks',
vm_memory='RAM (M)',
vm_vcpu='vCPUs',
vm_node='Node',
vm_migrated='Migrated'
)
)
# Keep track of nets we found to be valid to cut down on duplicate API hits
valid_net_list = []
# Format the string (elements)
for domain_information in vm_list:
if domain_information['state'] == 'start':
vm_state_colour = ansiprint.green()
elif domain_information['state'] == 'restart':
vm_state_colour = ansiprint.yellow()
elif domain_information['state'] == 'shutdown':
vm_state_colour = ansiprint.yellow()
elif domain_information['state'] == 'stop':
vm_state_colour = ansiprint.red()
elif domain_information['state'] == 'fail':
vm_state_colour = ansiprint.red()
else:
vm_state_colour = ansiprint.blue()
# Handle colouring for an invalid network config
raw_net_list = getNiceNetID(domain_information)
net_list = []
vm_net_colour = ''
for net_vni in raw_net_list:
if net_vni not in valid_net_list:
response = call_api(config, 'get', '/network/{net}'.format(net=net_vni))
if response.status_code != 200 and net_vni not in ['cluster', 'storage', 'upstream']:
vm_net_colour = ansiprint.red()
else:
valid_net_list.append(net_vni)
net_list.append(net_vni)
vm_list_output.append(
'{bold}{vm_name: <{vm_name_length}} {vm_uuid: <{vm_uuid_length}} \
{vm_state_colour}{vm_state: <{vm_state_length}}{end_colour} \
{vm_net_colour}{vm_networks: <{vm_nets_length}}{end_colour} \
{vm_memory: <{vm_ram_length}} {vm_vcpu: <{vm_vcpu_length}} \
{vm_node: <{vm_node_length}} \
{vm_migrated: <{vm_migrated_length}}{end_bold}'.format(
vm_name_length=vm_name_length,
vm_uuid_length=vm_uuid_length,
vm_state_length=vm_state_length,
vm_nets_length=vm_nets_length,
vm_ram_length=vm_ram_length,
vm_vcpu_length=vm_vcpu_length,
vm_node_length=vm_node_length,
vm_migrated_length=vm_migrated_length,
bold='',
end_bold='',
vm_state_colour=vm_state_colour,
end_colour=ansiprint.end(),
vm_name=domain_information['name'],
vm_uuid=domain_information['uuid'],
vm_state=domain_information['state'],
vm_net_colour=vm_net_colour,
vm_networks=','.join(net_list),
vm_memory=domain_information['memory'],
vm_vcpu=domain_information['vcpu'],
vm_node=domain_information['node'],
vm_migrated=domain_information['migrated']
)
)
return '\n'.join(sorted(vm_list_output))