#!/usr/bin/env python3 # 2-ova.py - PVC Provisioner example script for OVA profile install # Part of the Parallel Virtual Cluster (PVC) system # # Copyright (C) 2018-2022 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 . # ############################################################################### # This script provides an example of a PVC provisioner script. It will create a # standard VM config suitable for the OVA profile, and prepare the disks, but do # no additional install tasks (noop). # This script can thus be used as an example or reference implementation of a # PVC provisioner script and expanded upon as required. # *** READ THIS SCRIPT THOROUGHLY BEFORE USING TO UNDERSTAND HOW IT WORKS. *** # A script must implement the class "VMBuilderScript" which extends "VMBuilder", # providing the 5 functions indicated. Detailed explanation of the role of each # function is provided in context of the example; see the other examples for # more potential uses. # Within the VMBuilderScript class, several common variables are exposed through # the parent VMBuilder class: # self.vm_name: The name of the VM from PVC's perspective # self.vm_id: The VM ID (numerical component of the vm_name) from PVC's perspective # self.vm_uuid: An automatically-generated UUID for the VM # self.vm_profile: The PVC provisioner profile name used for the VM # self.vm_data: A dictionary of VM data collected by the provisioner; as an example: # { # "ceph_monitor_list": [ # "hv1.pvcstorage.tld", # "hv2.pvcstorage.tld", # "hv3.pvcstorage.tld" # ], # "ceph_monitor_port": "6789", # "ceph_monitor_secret": "96721723-8650-4a72-b8f6-a93cd1a20f0c", # "mac_template": null, # "networks": [ # { # "eth_bridge": "vmbr1001", # "id": 72, # "network_template": 69, # "vni": "1001" # }, # { # "eth_bridge": "vmbr101", # "id": 73, # "network_template": 69, # "vni": "101" # } # ], # "script": [contents of this file] # "script_arguments": { # "deb_mirror": "http://ftp.debian.org/debian", # "deb_release": "bullseye" # }, # "system_architecture": "x86_64", # "system_details": { # "id": 78, # "migration_method": "live", # "name": "small", # "node_autostart": false, # "node_limit": null, # "node_selector": null, # "ova": null, # "serial": true, # "vcpu_count": 2, # "vnc": false, # "vnc_bind": null, # "vram_mb": 2048 # }, # "volumes": [ # { # "disk_id": "sda", # "disk_size_gb": 4, # "filesystem": "ext4", # "filesystem_args": "-L=root", # "id": 9, # "mountpoint": "/", # "pool": "vms", # "source_volume": null, # "storage_template": 67 # }, # { # "disk_id": "sdb", # "disk_size_gb": 4, # "filesystem": "ext4", # "filesystem_args": "-L=var", # "id": 10, # "mountpoint": "/var", # "pool": "vms", # "source_volume": null, # "storage_template": 67 # }, # { # "disk_id": "sdc", # "disk_size_gb": 4, # "filesystem": "ext4", # "filesystem_args": "-L=log", # "id": 11, # "mountpoint": "/var/log", # "pool": "vms", # "source_volume": null, # "storage_template": 67 # } # ] # } # # Any other information you may require must be obtained manually. # WARNING: # # For safety reasons, the script runs in a modified chroot. It will have full access to # the entire / (root partition) of the hypervisor, but read-only. In addition it has # access to /dev, /sys, /run, and a fresh /tmp to write to; use /tmp/target (as # convention) as the destination for any mounting of volumes and installation. # Of course, in addition to this safety, it is VERY IMPORTANT to be aware that this # script runs AS ROOT ON THE HYPERVISOR SYSTEM. You should never allow arbitrary, # untrusted users the ability to add provisioning scripts even with this safeguard, # since they could still do destructive things to /dev and the like! # This import is always required here, as VMBuilder is used by the VMBuilderScript class # and ProvisioningError is the primary exception that should be raised within the class. from pvcapid.vmbuilder import VMBuilder, ProvisioningError # The VMBuilderScript class must be named as such, and extend VMBuilder. class VMBuilderScript(VMBuilder): def setup(self): """ setup(): Perform special setup steps or validation before proceeding Validate that we're actually an OVA profile. """ if self.vm_data.get("ova_details") is None: raise ProvisioningError( "Attempting to provision non-OVA profile with OVA script." ) def create(self): """ create(): Create the VM libvirt schema definition This step *must* return a fully-formed Libvirt XML document as a string or the provisioning task will fail. This example leverages the built-in libvirt_schema objects provided by PVC; these can be used as-is, or replaced with your own schema(s) on a per-script basis. """ # Run any imports first import pvcapid.libvirt_schema as libvirt_schema import datetime import random # Create the empty schema document that we will append to and return at the end schema = "" # Prepare a description based on the VM profile description = f"PVC provisioner @ {datetime.datetime.now()}, profile '{self.vm_profile}', OVA '{self.vm_data['ova_details']['name']}'" # Format the header schema += libvirt_schema.libvirt_header.format( vm_name=self.vm_name, vm_uuid=self.vm_uuid, vm_description=description, vm_memory=self.vm_data["system_details"]["vram_mb"], vm_vcpus=self.vm_data["system_details"]["vcpu_count"], vm_architecture=self.vm_data["system_architecture"], ) # Add the disk devices monitor_list = self.vm_data["ceph_monitor_list"] monitor_port = self.vm_data["ceph_monitor_port"] monitor_secret = self.vm_data["ceph_monitor_secret"] for volume in self.vm_data["volumes"]: schema += libvirt_schema.devices_disk_header.format( ceph_storage_secret=monitor_secret, disk_pool=volume["pool"], vm_name=self.vm_name, disk_id=volume["disk_id"], ) for monitor in monitor_list: schema += libvirt_schema.devices_disk_coordinator.format( coordinator_name=monitor, coordinator_ceph_mon_port=monitor_port, ) schema += libvirt_schema.devices_disk_footer # Add the special vhostmd device for hypervisor information inside the VM schema += libvirt_schema.devices_vhostmd # Add the network devices network_id = 0 for network in self.vm_data["networks"]: vm_id_hex = "{:x}".format(int(self.vm_id % 16)) net_id_hex = "{:x}".format(int(network_id % 16)) if self.vm_data.get("mac_template") is not None: mac_prefix = "52:54:01" macgen_template = self.vm_data["mac_template"] eth_macaddr = macgen_template.format( prefix=mac_prefix, vmid=vm_id_hex, netid=net_id_hex ) else: mac_prefix = "52:54:00" random_octet_A = "{:x}".format(random.randint(16, 238)) random_octet_B = "{:x}".format(random.randint(16, 238)) random_octet_C = "{:x}".format(random.randint(16, 238)) macgen_template = "{prefix}:{octetA}:{octetB}:{octetC}" eth_macaddr = macgen_template.format( prefix=mac_prefix, octetA=random_octet_A, octetB=random_octet_B, octetC=random_octet_C, ) schema += libvirt_schema.devices_net_interface.format( eth_macaddr=eth_macaddr, eth_bridge=network["eth_bridge"], ) network_id += 1 # Add default devices schema += libvirt_schema.devices_default # Add serial device if self.vm_data["system_details"]["serial"]: schema += libvirt_schema.devices_serial.format(vm_name=self.vm_name) # Add VNC device if self.vm_data["system_details"]["vnc"]: if self.vm_data["system_details"]["vnc_bind"]: vm_vnc_bind = self.vm_data["system_details"]["vnc_bind"] else: vm_vnc_bind = "127.0.0.1" vm_vncport = 5900 vm_vnc_autoport = "yes" schema += libvirt_schema.devices_vnc.format( vm_vncport=vm_vncport, vm_vnc_autoport=vm_vnc_autoport, vm_vnc_bind=vm_vnc_bind, ) # Add SCSI controller schema += libvirt_schema.devices_scsi_controller # Add footer schema += libvirt_schema.libvirt_footer return schema def prepare(self): """ prepare(): Prepare any disks/volumes for the install() step """ # Run any imports first from pvcapid.vmbuilder import open_zk from pvcapid.Daemon import config import daemon_lib.common as pvc_common import daemon_lib.ceph as pvc_ceph import os # First loop: Create the destination disks print("Creating destination disk volumes") for volume in self.vm_data["volumes"]: print(f"Processing volume {volume['volume_name']}") with open_zk(config) as zkhandler: success, message = pvc_ceph.add_volume( zkhandler, volume["pool"], f"{self.vm_name}_{volume['disk_id']}", f"{volume['disk_size_gb']}G", ) print(message) if not success: raise ProvisioningError( f"Failed to create volume '{volume['disk_id']}'." ) # Second loop: Map the destination disks print("Mapping destination disk volumes") for volume in self.vm_data["volumes"]: print(f"Processing volume {volume['volume_name']}") dst_volume_name = f"{self.vm_name}_{volume['disk_id']}" dst_volume = f"{volume['pool']}/{dst_volume_name}" with open_zk(config) as zkhandler: success, message = pvc_ceph.map_volume( zkhandler, volume["pool"], dst_volume_name, ) print(message) if not success: raise ProvisioningError(f"Failed to map volume '{dst_volume}'.") # Third loop: Map the source disks print("Mapping source disk volumes") for volume in self.vm_data["volumes"]: print(f"Processing volume {volume['volume_name']}") src_volume_name = volume["volume_name"] src_volume = f"{volume['pool']}/{src_volume_name}" with open_zk(config) as zkhandler: success, message = pvc_ceph.map_volume( zkhandler, volume["pool"], src_volume_name, ) print(message) if not success: raise ProvisioningError(f"Failed to map volume '{src_volume}'.") def install(self): """ install(): Perform the installation Convert the mapped source volumes to the mapped destination volumes """ # Run any imports first import daemon_lib.common as pvc_common for volume in self.vm_data["volumes"]: src_volume_name = volume["volume_name"] src_volume = f"{volume['pool']}/{src_volume_name}" src_devpath = f"/dev/rbd/{src_volume}" dst_volume_name = f"{self.vm_name}_{volume['disk_id']}" dst_volume = f"{volume['pool']}/{dst_volume_name}" dst_devpath = f"/dev/rbd/{dst_volume}" print( f"Converting {volume['volume_format']} {src_volume} at {src_devpath} to {dst_volume} at {dst_devpath}" ) retcode, stdout, stderr = pvc_common.run_os_command( f"qemu-img convert -C -f {volume['volume_format']} -O raw {src_devpath} {dst_devpath}" ) if retcode: raise ProvisioningError( f"Failed to convert {volume['volume_format']} volume '{src_volume}' to raw volume '{dst_volume}' with qemu-img: {stderr}" ) def cleanup(self): """ cleanup(): Perform any cleanup required due to prepare()/install() This function is also called if there is ANY exception raised in the prepare() or install() steps. While this doesn't mean you shouldn't or can't raise exceptions here, be warned that doing so might cause loops. Do this only if you really need to. """ # Run any imports first from pvcapid.vmbuilder import open_zk from pvcapid.Daemon import config import daemon_lib.ceph as pvc_ceph for volume in list(reversed(self.vm_data["volumes"])): src_volume_name = volume["volume_name"] src_volume = f"{volume['pool']}/{src_volume_name}" src_devpath = f"/dev/rbd/{src_volume}" with open_zk(config) as zkhandler: success, message = pvc_ceph.unmap_volume( zkhandler, volume["pool"], src_volume_name, ) if not success: raise ProvisioningError( f"Failed to unmap source volume '{src_volume_name}': {message}" ) for volume in list(reversed(self.vm_data["volumes"])): dst_volume_name = f"{self.vm_name}_{volume['disk_id']}" dst_volume = f"{volume['pool']}/{dst_volume_name}" dst_devpath = f"/dev/rbd/{dst_volume}" with open_zk(config) as zkhandler: success, message = pvc_ceph.unmap_volume( zkhandler, volume["pool"], dst_volume_name, ) if not success: raise ProvisioningError( f"Failed to unmap destination volume '{dst_volume_name}': {message}" )