VMware vSphere

Introduction

OpenStack Compute supports the VMware vSphere product family and enables access to advanced features such as vMotion, High Availability, and Dynamic Resource Scheduling (DRS).

This section describes how to configure VMware-based virtual machine images for launch. The VMware driver supports vCenter version 5.5.0 and later.

The VMware vCenter driver enables the nova-compute service to communicate with a VMware vCenter server that manages one or more ESX host clusters. The driver aggregates the ESX hosts in each cluster to present one large hypervisor entity for each cluster to the Compute scheduler. Because individual ESX hosts are not exposed to the scheduler, Compute schedules to the granularity of clusters and vCenter uses DRS to select the actual ESX host within the cluster. When a virtual machine makes its way into a vCenter cluster, it can use all vSphere features.

The following sections describe how to configure the VMware vCenter driver.

High-level architecture

The following diagram shows a high-level view of the VMware driver architecture:

VMware driver architecture

../../_images/vmware-nova-driver-architecture.jpg

As the figure shows, the OpenStack Compute Scheduler sees three hypervisors that each correspond to a cluster in vCenter. nova-compute contains the VMware driver. You can run with multiple nova-compute services. It is recommended to run with one nova-compute service per ESX cluster thus ensuring that while Compute schedules at the granularity of the nova-compute service it is also in effect able to schedule at the cluster level. In turn the VMware driver inside nova-compute interacts with the vCenter APIs to select an appropriate ESX host within the cluster. Internally, vCenter uses DRS for placement.

The VMware vCenter driver also interacts with the Image service to copy VMDK images from the Image service back-end store. The dotted line in the figure represents VMDK images being copied from the OpenStack Image service to the vSphere data store. VMDK images are cached in the data store so the copy operation is only required the first time that the VMDK image is used.

After OpenStack boots a VM into a vSphere cluster, the VM becomes visible in vCenter and can access vSphere advanced features. At the same time, the VM is visible in the OpenStack dashboard and you can manage it as you would any other OpenStack VM. You can perform advanced vSphere operations in vCenter while you configure OpenStack resources such as VMs through the OpenStack dashboard.

The figure does not show how networking fits into the architecture. For details, see Networking with VMware vSphere.

Configuration overview

To get started with the VMware vCenter driver, complete the following high-level steps:

  1. Configure vCenter. See Prerequisites and limitations.

  2. Configure the VMware vCenter driver in the nova.conf file. See VMware vCenter driver.

  3. Load desired VMDK images into the Image service. See Images with VMware vSphere.

  4. Configure the Networking service (neutron). See Networking with VMware vSphere.

Prerequisites and limitations

Use the following list to prepare a vSphere environment that runs with the VMware vCenter driver:

Copying VMDK files

In vSphere 5.1, copying large image files (for example, 12 GB and greater) from the Image service can take a long time. To improve performance, VMware recommends that you upgrade to VMware vCenter Server 5.1 Update 1 or later. For more information, see the Release Notes.

DRS

For any cluster that contains multiple ESX hosts, enable DRS and enable fully automated placement.

Shared storage

Only shared storage is supported and data stores must be shared among all hosts in a cluster. It is recommended to remove data stores not intended for OpenStack from clusters being configured for OpenStack.

Clusters and data stores

Do not use OpenStack clusters and data stores for other purposes. If you do, OpenStack displays incorrect usage information.

Networking

The networking configuration depends on the desired networking model. See Networking with VMware vSphere.

Security groups

If you use the VMware driver with OpenStack Networking and the NSX plug-in, security groups are supported.

Note

The NSX plug-in is the only plug-in that is validated for vSphere.

VNC

The port range 5900 - 6105 (inclusive) is automatically enabled for VNC connections on every ESX host in all clusters under OpenStack control.

Note

In addition to the default VNC port numbers (5900 to 6000) specified in the above document, the following ports are also used: 6101, 6102, and 6105.

You must modify the ESXi firewall configuration to allow the VNC ports. Additionally, for the firewall modifications to persist after a reboot, you must create a custom vSphere Installation Bundle (VIB) which is then installed onto the running ESXi host or added to a custom image profile used to install ESXi hosts. For details about how to create a VIB for persisting the firewall configuration modifications, see Knowledge Base.

Note

The VIB can be downloaded from openstack-vmwareapi-team/Tools.

To use multiple vCenter installations with OpenStack, each vCenter must be assigned to a separate availability zone. This is required as the OpenStack Block Storage VMDK driver does not currently work across multiple vCenter installations.

VMware vCenter service account

OpenStack integration requires a vCenter service account with the following minimum permissions. Apply the permissions to the Datacenter root object, and select the Propagate to Child Objects option.

vCenter permissions tree

All Privileges

Datastore

Allocate space

Browse datastore

Low level file operation

Remove file

Extension

Register extension

Folder

Create folder

Host

Configuration

Maintenance

Network configuration

Storage partition configuration

Network

Assign network

Resource

Assign virtual machine to resource pool

Migrate powered off virtual machine

Migrate powered on virtual machine

Virtual Machine

Configuration

Add existing disk

Add new disk

Add or remove device

Advanced

CPU count

Change resource

Disk change tracking

Host USB device

Memory

Modify device settings

Raw device

Remove disk

Rename

Set annotation

Swapfile placement

Interaction

Configure CD media

Power Off

Power On

Reset

Suspend

Inventory

Create from existing

Create new

Move

Remove

Unregister

Provisioning

Clone virtual machine

Customize

Create template from virtual machine

Snapshot management

Create snapshot

Remove snapshot

Profile-driven storage

Profile-driven storage view

Sessions

Validate session

View and stop sessions

vApp

Export

Import

VMware vCenter driver

Use the VMware vCenter driver (VMwareVCDriver) to connect OpenStack Compute with vCenter. This recommended configuration enables access through vCenter to advanced vSphere features like vMotion, High Availability, and Dynamic Resource Scheduling (DRS).

VMwareVCDriver configuration options

Add the following VMware-specific configuration options to the nova.conf file:

[DEFAULT]
compute_driver = vmwareapi.VMwareVCDriver

[vmware]
host_ip = <vCenter hostname or IP address>
host_username = <vCenter username>
host_password = <vCenter password>
cluster_name = <vCenter cluster name>
datastore_regex = <optional datastore regex>

Note

  • Clusters: The vCenter driver can support only a single cluster. Clusters and data stores used by the vCenter driver should not contain any VMs other than those created by the driver.

  • Data stores: The datastore_regex setting specifies the data stores to use with Compute. For example, datastore_regex="nas.*" selects all the data stores that have a name starting with “nas”. If this line is omitted, Compute uses the first data store returned by the vSphere API. It is recommended not to use this field and instead remove data stores that are not intended for OpenStack.

  • Reserved host memory: The reserved_host_memory_mb option value is 512 MB by default. However, VMware recommends that you set this option to 0 MB because the vCenter driver reports the effective memory available to the virtual machines.

  • The vCenter driver generates instance name by instance ID. Instance name template is ignored.

  • The minimum supported vCenter version is 5.5.0. Starting in the OpenStack Ocata release any version lower than 5.5.0 will be logged as a warning. In the OpenStack Pike release this will be enforced.

A nova-compute service can control one or more clusters containing multiple ESXi hosts, making nova-compute a critical service from a high availability perspective. Because the host that runs nova-compute can fail while the vCenter and ESX still run, you must protect the nova-compute service against host failures.

Note

Many nova.conf options are relevant to libvirt but do not apply to this driver.

Images with VMware vSphere

The vCenter driver supports images in the VMDK format. Disks in this format can be obtained from VMware Fusion or from an ESX environment. It is also possible to convert other formats, such as qcow2, to the VMDK format using the qemu-img utility. After a VMDK disk is available, load it into the Image service. Then, you can use it with the VMware vCenter driver. The following sections provide additional details on the supported disks and the commands used for conversion and upload.

Supported image types

Upload images to the OpenStack Image service in VMDK format. The following VMDK disk types are supported:

  • VMFS Flat Disks (includes thin, thick, zeroedthick, and eagerzeroedthick). Note that once a VMFS thin disk is exported from VMFS to a non-VMFS location, like the OpenStack Image service, it becomes a preallocated flat disk. This impacts the transfer time from the Image service to the data store when the full preallocated flat disk, rather than the thin disk, must be transferred.

  • Monolithic Sparse disks. Sparse disks get imported from the Image service into ESXi as thin provisioned disks. Monolithic Sparse disks can be obtained from VMware Fusion or can be created by converting from other virtual disk formats using the qemu-img utility.

  • Stream-optimized disks. Stream-optimized disks are compressed sparse disks. They can be obtained from VMware vCenter/ESXi when exporting vm to ovf/ova template.

The following table shows the vmware_disktype property that applies to each of the supported VMDK disk types:

OpenStack Image service disk type settings

vmware_disktype property

VMDK disk type

sparse

Monolithic Sparse

thin

VMFS flat, thin provisioned

preallocated (default)

VMFS flat, thick/zeroedthick/eagerzeroedthick

streamOptimized

Compressed Sparse

The vmware_disktype property is set when an image is loaded into the Image service. For example, the following command creates a Monolithic Sparse image by setting vmware_disktype to sparse:

$ openstack image create \
  --disk-format vmdk \
  --container-format bare \
  --property vmware_disktype="sparse" \
  --property vmware_ostype="ubuntu64Guest" \
  ubuntu-sparse < ubuntuLTS-sparse.vmdk

Note

Specifying thin does not provide any advantage over preallocated with the current version of the driver. Future versions might restore the thin properties of the disk after it is downloaded to a vSphere data store.

The following table shows the vmware_ostype property that applies to each of the supported guest OS:

Note

If a glance image has a vmware_ostype property which does not correspond to a valid VMware guestId, VM creation will fail, and a warning will be logged.

OpenStack Image service OS type settings

vmware_ostype property

Retail Name

asianux3_64Guest

Asianux Server 3 (64 bit)

asianux3Guest

Asianux Server 3

asianux4_64Guest

Asianux Server 4 (64 bit)

asianux4Guest

Asianux Server 4

darwin64Guest

Darwin 64 bit

darwinGuest

Darwin

debian4_64Guest

Debian GNU/Linux 4 (64 bit)

debian4Guest

Debian GNU/Linux 4

debian5_64Guest

Debian GNU/Linux 5 (64 bit)

debian5Guest

Debian GNU/Linux 5

dosGuest

MS-DOS

freebsd64Guest

FreeBSD x64

freebsdGuest

FreeBSD

mandrivaGuest

Mandriva Linux

netware4Guest

Novell NetWare 4

netware5Guest

Novell NetWare 5.1

netware6Guest

Novell NetWare 6.x

nld9Guest

Novell Linux Desktop 9

oesGuest

Open Enterprise Server

openServer5Guest

SCO OpenServer 5

openServer6Guest

SCO OpenServer 6

opensuse64Guest

openSUSE (64 bit)

opensuseGuest

openSUSE

os2Guest

OS/2

other24xLinux64Guest

Linux 2.4x Kernel (64 bit) (experimental)

other24xLinuxGuest

Linux 2.4x Kernel

other26xLinux64Guest

Linux 2.6x Kernel (64 bit) (experimental)

other26xLinuxGuest

Linux 2.6x Kernel (experimental)

otherGuest

Other Operating System

otherGuest64

Other Operating System (64 bit) (experimental)

otherLinux64Guest

Linux (64 bit) (experimental)

otherLinuxGuest

Other Linux

redhatGuest

Red Hat Linux 2.1

rhel2Guest

Red Hat Enterprise Linux 2

rhel3_64Guest

Red Hat Enterprise Linux 3 (64 bit)

rhel3Guest

Red Hat Enterprise Linux 3

rhel4_64Guest

Red Hat Enterprise Linux 4 (64 bit)

rhel4Guest

Red Hat Enterprise Linux 4

rhel5_64Guest

Red Hat Enterprise Linux 5 (64 bit) (experimental)

rhel5Guest

Red Hat Enterprise Linux 5

rhel6_64Guest

Red Hat Enterprise Linux 6 (64 bit)

rhel6Guest

Red Hat Enterprise Linux 6

sjdsGuest

Sun Java Desktop System

sles10_64Guest

SUSE Linux Enterprise Server 10 (64 bit) (experimental)

sles10Guest

SUSE Linux Enterprise Server 10

sles11_64Guest

SUSE Linux Enterprise Server 11 (64 bit)

sles11Guest

SUSE Linux Enterprise Server 11

sles64Guest

SUSE Linux Enterprise Server 9 (64 bit)

slesGuest

SUSE Linux Enterprise Server 9

solaris10_64Guest

Solaris 10 (64 bit) (experimental)

solaris10Guest

Solaris 10 (32 bit) (experimental)

solaris6Guest

Solaris 6

solaris7Guest

Solaris 7

solaris8Guest

Solaris 8

solaris9Guest

Solaris 9

suse64Guest

SUSE Linux (64 bit)

suseGuest

SUSE Linux

turboLinux64Guest

Turbolinux (64 bit)

turboLinuxGuest

Turbolinux

ubuntu64Guest

Ubuntu Linux (64 bit)

ubuntuGuest

Ubuntu Linux

unixWare7Guest

SCO UnixWare 7

win2000AdvServGuest

Windows 2000 Advanced Server

win2000ProGuest

Windows 2000 Professional

win2000ServGuest

Windows 2000 Server

win31Guest

Windows 3.1

win95Guest

Windows 95

win98Guest

Windows 98

windows7_64Guest

Windows 7 (64 bit)

windows7Guest

Windows 7

windows7Server64Guest

Windows Server 2008 R2 (64 bit)

winLonghorn64Guest

Windows Longhorn (64 bit) (experimental)

winLonghornGuest

Windows Longhorn (experimental)

winMeGuest

Windows Millennium Edition

winNetBusinessGuest

Windows Small Business Server 2003

winNetDatacenter64Guest

Windows Server 2003, Datacenter Edition (64 bit) (experimental)

winNetDatacenterGuest

Windows Server 2003, Datacenter Edition

winNetEnterprise64Guest

Windows Server 2003, Enterprise Edition (64 bit)

winNetEnterpriseGuest

Windows Server 2003, Enterprise Edition

winNetStandard64Guest

Windows Server 2003, Standard Edition (64 bit)

winNetEnterpriseGuest

Windows Server 2003, Enterprise Edition

winNetStandard64Guest

Windows Server 2003, Standard Edition (64 bit)

winNetStandardGuest

Windows Server 2003, Standard Edition

winNetWebGuest

Windows Server 2003, Web Edition

winNTGuest

Windows NT 4

winVista64Guest

Windows Vista (64 bit)

winVistaGuest

Windows Vista

winXPHomeGuest

Windows XP Home Edition

winXPPro64Guest

Windows XP Professional Edition (64 bit)

winXPProGuest

Windows XP Professional

Convert and load images

Using the qemu-img utility, disk images in several formats (such as, qcow2) can be converted to the VMDK format.

For example, the following command can be used to convert a qcow2 Ubuntu Trusty cloud image:

$ qemu-img convert -f qcow2 ~/Downloads/trusty-server-cloudimg-amd64-disk1.img \
  -O vmdk trusty-server-cloudimg-amd64-disk1.vmdk

VMDK disks converted through qemu-img are always monolithic sparse VMDK disks with an IDE adapter type. Using the previous example of the Ubuntu Trusty image after the qemu-img conversion, the command to upload the VMDK disk should be something like:

$ openstack image create \
  --container-format bare --disk-format vmdk \
  --property vmware_disktype="sparse" \
  --property vmware_adaptertype="ide" \
  trusty-cloud < trusty-server-cloudimg-amd64-disk1.vmdk

Note that the vmware_disktype is set to sparse and the vmware_adaptertype is set to ide in the previous command.

If the image did not come from the qemu-img utility, the vmware_disktype and vmware_adaptertype might be different. To determine the image adapter type from an image file, use the following command and look for the ddb.adapterType= line:

$ head -20 <vmdk file name>

Assuming a preallocated disk type and an iSCSI lsiLogic adapter type, the following command uploads the VMDK disk:

$ openstack image create \
  --disk-format vmdk \
  --container-format bare \
  --property vmware_adaptertype="lsiLogic" \
  --property vmware_disktype="preallocated" \
  --property vmware_ostype="ubuntu64Guest" \
  ubuntu-thick-scsi < ubuntuLTS-flat.vmdk

Currently, OS boot VMDK disks with an IDE adapter type cannot be attached to a virtual SCSI controller and likewise disks with one of the SCSI adapter types (such as, busLogic, lsiLogic, lsiLogicsas, paraVirtual) cannot be attached to the IDE controller. Therefore, as the previous examples show, it is important to set the vmware_adaptertype property correctly. The default adapter type is lsiLogic, which is SCSI, so you can omit the vmware_adaptertype property if you are certain that the image adapter type is lsiLogic.

Tag VMware images

In a mixed hypervisor environment, OpenStack Compute uses the hypervisor_type tag to match images to the correct hypervisor type. For VMware images, set the hypervisor type to vmware. Other valid hypervisor types include: hyperv, ironic, lxc, qemu, uml, and xen. Note that qemu is used for both QEMU and KVM hypervisor types.

$ openstack image create \
  --disk-format vmdk \
  --container-format bare \
  --property vmware_adaptertype="lsiLogic" \
  --property vmware_disktype="preallocated" \
  --property hypervisor_type="vmware" \
  --property vmware_ostype="ubuntu64Guest" \
  ubuntu-thick-scsi < ubuntuLTS-flat.vmdk

Optimize images

Monolithic Sparse disks are considerably faster to download but have the overhead of an additional conversion step. When imported into ESX, sparse disks get converted to VMFS flat thin provisioned disks. The download and conversion steps only affect the first launched instance that uses the sparse disk image. The converted disk image is cached, so subsequent instances that use this disk image can simply use the cached version.

To avoid the conversion step (at the cost of longer download times) consider converting sparse disks to thin provisioned or preallocated disks before loading them into the Image service.

Use one of the following tools to pre-convert sparse disks.

vSphere CLI tools

Sometimes called the remote CLI or rCLI.

Assuming that the sparse disk is made available on a data store accessible by an ESX host, the following command converts it to preallocated format:

vmkfstools --server=ip_of_some_ESX_host -i \
  /vmfs/volumes/datastore1/sparse.vmdk \
  /vmfs/volumes/datastore1/converted.vmdk

Note that the vifs tool from the same CLI package can be used to upload the disk to be converted. The vifs tool can also be used to download the converted disk if necessary.

vmkfstools directly on the ESX host

If the SSH service is enabled on an ESX host, the sparse disk can be uploaded to the ESX data store through scp and the vmkfstools local to the ESX host can use used to perform the conversion. After you log in to the host through ssh, run this command:

vmkfstools -i /vmfs/volumes/datastore1/sparse.vmdk /vmfs/volumes/datastore1/converted.vmdk
vmware-vdiskmanager

vmware-vdiskmanager is a utility that comes bundled with VMware Fusion and VMware Workstation. The following example converts a sparse disk to preallocated format:

'/Applications/VMware Fusion.app/Contents/Library/vmware-vdiskmanager' -r sparse.vmdk -t 4 converted.vmdk

In the previous cases, the converted vmdk is actually a pair of files:

  • The descriptor file converted.vmdk.

  • The actual virtual disk data file converted-flat.vmdk.

The file to be uploaded to the Image service is converted-flat.vmdk.

Image handling

The ESX hypervisor requires a copy of the VMDK file in order to boot up a virtual machine. As a result, the vCenter OpenStack Compute driver must download the VMDK via HTTP from the Image service to a data store that is visible to the hypervisor. To optimize this process, the first time a VMDK file is used, it gets cached in the data store. A cached image is stored in a folder named after the image ID. Subsequent virtual machines that need the VMDK use the cached version and don’t have to copy the file again from the Image service.

Even with a cached VMDK, there is still a copy operation from the cache location to the hypervisor file directory in the shared data store. To avoid this copy, boot the image in linked_clone mode. To learn how to enable this mode, see Configuration reference.

Note

You can also use the img_linked_clone property (or legacy property vmware_linked_clone) in the Image service to override the linked_clone mode on a per-image basis.

If spawning a virtual machine image from ISO with a VMDK disk, the image is created and attached to the virtual machine as a blank disk. In that case img_linked_clone property for the image is just ignored.

If multiple compute nodes are running on the same host, or have a shared file system, you can enable them to use the same cache folder on the back-end data store. To configure this action, set the cache_prefix option in the nova.conf file. Its value stands for the name prefix of the folder where cached images are stored.

Note

This can take effect only if compute nodes are running on the same host, or have a shared file system.

You can automatically purge unused images after a specified period of time. To configure this action, set these options in the :oslo.config:group`image_cache` section in the nova.conf file:

Networking with VMware vSphere

The VMware driver supports networking with the Networking Service (neutron). Depending on your installation, complete these configuration steps before you provision VMs:

  1. Before provisioning VMs, create a port group with the same name as the vmware.integration_bridge value in nova.conf (default is br-int). All VM NICs are attached to this port group for management by the OpenStack Networking plug-in.

Volumes with VMware vSphere

The VMware driver supports attaching volumes from the Block Storage service. The VMware VMDK driver for OpenStack Block Storage is recommended and should be used for managing volumes based on vSphere data stores. For more information about the VMware VMDK driver, see Cinder’s manual on the VMDK Driver (TODO: this has not yet been imported and published). Also an iSCSI volume driver provides limited support and can be used only for attachments.

Configuration reference

To customize the VMware driver, use the configuration option settings below.

Description of VMware configuration options

Configuration option = Default value

Description

[vmware]

api_retry_count = 10

(Integer) Number of times VMware vCenter server API must be retried on connection failures, e.g. socket error, etc.

ca_file = None

(String) Specifies the CA bundle file to be used in verifying the vCenter server certificate.

cache_prefix = None

(String) This option adds a prefix to the folder where cached images are stored

This is not the full path - just a folder prefix. This should only be used when a datastore cache is shared between compute nodes.

Note

This should only be used when the compute nodes are running on same host or they have a shared file system.

Possible values:

  • Any string representing the cache prefix to the folder

cluster_name = None

(String) Name of a VMware Cluster ComputeResource.

console_delay_seconds = None

(Integer) Set this value if affected by an increased network latency causing repeated characters when typing in a remote console.

datastore_regex = None

(String) Regular expression pattern to match the name of datastore.

The datastore_regex setting specifies the datastores to use with Compute. For example, datastore_regex=”nas.*” selects all the data stores that have a name starting with “nas”.

Note

If no regex is given, it just picks the datastore with the most freespace.

Possible values:

  • Any matching regular expression to a datastore must be given

host_ip = None

(String) Hostname or IP address for connection to VMware vCenter host.

host_password = None

(String) Password for connection to VMware vCenter host.

host_port = 443

(Port number) Port for connection to VMware vCenter host.

host_username = None

(String) Username for connection to VMware vCenter host.

insecure = False

(Boolean) If true, the vCenter server certificate is not verified. If false, then the default CA truststore is used for verification.

Related options:

  • ca_file: This option is ignored if “ca_file” is set.

integration_bridge = None

(String) This option should be configured only when using the NSX-MH Neutron plugin. This is the name of the integration bridge on the ESXi server or host. This should not be set for any other Neutron plugin. Hence the default value is not set.

Possible values:

  • Any valid string representing the name of the integration bridge

maximum_objects = 100

(Integer) This option specifies the limit on the maximum number of objects to return in a single result.

A positive value will cause the operation to suspend the retrieval when the count of objects reaches the specified limit. The server may still limit the count to something less than the configured value. Any remaining objects may be retrieved with additional requests.

pbm_default_policy = None

(String) This option specifies the default policy to be used.

If pbm_enabled is set and there is no defined storage policy for the specific request, then this policy will be used.

Possible values:

  • Any valid storage policy such as VSAN default storage policy

Related options:

  • pbm_enabled

pbm_enabled = False

(Boolean) This option enables or disables storage policy based placement of instances.

Related options:

  • pbm_default_policy

pbm_wsdl_location = None

(String) This option specifies the PBM service WSDL file location URL.

Setting this will disable storage policy based placement of instances.

Possible values:

serial_port_proxy_uri = None

(String) Identifies a proxy service that provides network access to the serial_port_service_uri.

Possible values:

  • Any valid URI

Related options: This option is ignored if serial_port_service_uri is not specified.

  • serial_port_service_uri

serial_port_service_uri = None

(String) Identifies the remote system where the serial port traffic will be sent.

This option adds a virtual serial port which sends console output to a configurable service URI. At the service URI address there will be virtual serial port concentrator that will collect console logs. If this is not set, no serial ports will be added to the created VMs.

Possible values:

  • Any valid URI

task_poll_interval = 0.5

(Floating point) Time interval in seconds to poll remote tasks invoked on VMware VC server.

use_linked_clone = True

(Boolean) This option enables/disables the use of linked clone.

The ESX hypervisor requires a copy of the VMDK file in order to boot up a virtual machine. The compute driver must download the VMDK via HTTP from the OpenStack Image service to a datastore that is visible to the hypervisor and cache it. Subsequent virtual machines that need the VMDK use the cached version and don’t have to copy the file again from the OpenStack Image service.

If set to false, even with a cached VMDK, there is still a copy operation from the cache location to the hypervisor file directory in the shared datastore. If set to true, the above copy operation is avoided as it creates copy of the virtual machine that shares virtual disks with its parent VM.

wsdl_location = None

(String) This option specifies VIM Service WSDL Location

If vSphere API versions 5.1 and later is being used, this section can be ignored. If version is less than 5.1, WSDL files must be hosted locally and their location must be specified in the above section.

Optional over-ride to default location for bug work-arounds.

Possible values:

Troubleshooting

Operators can troubleshoot VMware specific failures by correlating OpenStack logs to vCenter logs. Every RPC call which is made by an OpenStack driver has an opID which can be traced in the vCenter logs. For example consider the following excerpt from a nova-compute log:

Aug 15 07:31:09 localhost nova-compute[16683]: DEBUG oslo_vmware.service [-] Invoking Folder.CreateVM_Task with opID=oslo.vmware-debb6064-690e-45ac-b0ae-1b94a9638d1f {{(pid=16683) request_handler /opt/stack/oslo.vmware/oslo_vmware/service.py:355}}

In this case the opID is oslo.vmware-debb6064-690e-45ac-b0ae-1b94a9638d1f and we can grep the vCenter log (usually /var/log/vmware/vpxd/vpxd.log) for it to find if anything went wrong with the CreateVM operation.