openstack-manuals/doc/training-guide/module001-ch011-block-storage.xml
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xml:id="module001-ch011-block-storage">
<title>OpenStack Block Storage</title>
<para><emphasis role="bold">Block Storage and OpenStack
Compute</emphasis></para>
<para>OpenStack provides two classes of block storage, "ephemeral"
storage and persistent "volumes". Ephemeral storage exists only
for the life of an instance, it will persist across reboots of the
guest operating system but when the instance is deleted so is the
associated storage. All instances have some ephemeral storage.
Volumes are persistent virtualized block devices independent of
any particular instance. Volumes may be attached to a single
instance at a time, but may be detached or reattached to a
different instance while retaining all data, much like a USB
drive.</para>
<para><guilabel>Ephemeral Storage</guilabel></para>
<para>Ephemeral storage is associated with a single unique instance.
Its size is defined by the flavor of the instance.</para>
<para>Data on ephemeral storage ceases to exist when the instance it
is associated with is terminated. Rebooting the VM or restarting
the host server, however, will not destroy ephemeral data. In the
typical use case an instance's root filesystem is stored on
ephemeral storage. This is often an unpleasant surprise for people
unfamiliar with the cloud model of computing.</para>
<para>In addition to the ephemeral root volume all flavors except
the smallest, m1.tiny, provide an additional ephemeral block
device varying from 20G for the m1.small through 160G for the
m1.xlarge by default - these sizes are configurable. This is
presented as a raw block device with no partition table or
filesystem. Cloud aware operating system images may discover,
format, and mount this device. For example the cloud-init package
included in Ubuntu's stock cloud images will format this space as
an ext3 filesystem and mount it on /mnt. It is important to note
this a feature of the guest operating system. OpenStack only
provisions the raw storage.</para>
<para><guilabel>Volume Storage</guilabel></para>
<para>Volume storage is independent of any particular instance and
is persistent. Volumes are user created and within quota and
availability limits may be of any arbitrary size.</para>
<para>When first created volumes are raw block devices with no
partition table and no filesystem. They must be attached to an
instance to be partitioned and/or formatted. Once this is done
they may be used much like an external disk drive. Volumes may
attached to only one instance at a time, but may be detached and
reattached to either the same or different instances.</para>
<para>It is possible to configure a volume so that it is bootable
and provides a persistent virtual instance similar to traditional
non-cloud based virtualization systems. In this use case the
resulting instance may still have ephemeral storage depending on
the flavor selected, but the root filesystem (and possibly others)
will be on the persistent volume and thus state will be maintained
even if the instance it shutdown. Details of this configuration
are discussed in the<link
xlink:href="http://docs.openstack.org/user-guide/content/"
>OpenStack End User Guide</link>.</para>
<para>Volumes do not provide concurrent access from multiple
instances. For that you need either a traditional network
filesystem like NFS or CIFS or a cluster filesystem such as
GlusterFS. These may be built within an OpenStack cluster or
provisioned outside of it, but are not features provided by the
OpenStack software.</para>
<para>The OpenStack Block Storage service works via the interaction
of a series of daemon processes named cinder-* that reside
persistently on the host machine or machines. The binaries can all
be run from a single node, or spread across multiple nodes. They
can also be run on the same node as other OpenStack
services.</para>
<para><guilabel>The current services available in OpenStack Block
Storage are:</guilabel></para>
<itemizedlist>
<listitem>
<para><emphasis role="bold">cinder-api</emphasis> - The
cinder-api service is a WSGI app that authenticates and routes
requests throughout the Block Storage system. It supports the
OpenStack API's only, although there is a translation that can
be done via Nova's EC2 interface which calls in to the
cinderclient.</para>
</listitem>
</itemizedlist>
<itemizedlist>
<listitem>
<para><emphasis role="bold">cinder-scheduler</emphasis> - The
cinder-scheduler is responsible for scheduling/routing
requests to the appropriate volume service. As of Grizzly;
depending upon your configuration this may be simple
round-robin scheduling to the running volume services, or it
can be more sophisticated through the use of the Filter
Scheduler. The Filter Scheduler is the default in Grizzly and
enables filter on things like Capacity, Availability Zone,
Volume Types and Capabilities as well as custom
filters.</para>
</listitem>
</itemizedlist>
<itemizedlist>
<listitem>
<para><emphasis role="bold">cinder-volume</emphasis> - The
cinder-volume service is responsible for managing Block
Storage devices, specifically the back-end devices
themselves.</para>
</listitem>
</itemizedlist>
<itemizedlist>
<listitem>
<para><emphasis role="bold">cinder-backup</emphasis> - The
cinder-backup service provides a means to back up a Cinder
Volume to OpenStack Object Store (SWIFT).</para>
</listitem>
</itemizedlist>
<para><guilabel>Introduction to OpenStack Block
Storage</guilabel></para>
<para>OpenStack Block Storage provides persistent High Performance
Block Storage resources that can be consumed by OpenStack Compute
instances. This includes secondary attached storage similar to
Amazon's Elastic Block Storage (EBS). In addition images can be
written to a Block Storage device and specified for OpenStack
Compute to use a bootable persistent instance.</para>
<para>There are some differences from Amazon's EBS that one should
be aware of. OpenStack Block Storage is not a shared storage
solution like NFS, but currently is designed so that the device is
attached and in use by a single instance at a time.</para>
<para><guilabel>Backend Storage Devices</guilabel></para>
<para>OpenStack Block Storage requires some form of back-end storage
that the service is built on. The default implementation is to use
LVM on a local Volume Group named "cinder-volumes". In addition to
the base driver implementation, OpenStack Block Storage also
provides the means to add support for other storage devices to be
utilized such as external Raid Arrays or other Storage
appliances.</para>
<para><guilabel>Users and Tenants (Projects)</guilabel></para>
<para>The OpenStack Block Storage system is designed to be used by
many different cloud computing consumers or customers, basically
tenants on a shared system, using role-based access assignments.
Roles control the actions that a user is allowed to perform. In
the default configuration, most actions do not require a
particular role, but this is configurable by the system
administrator editing the appropriate policy.json file that
maintains the rules. A user's access to particular volumes is
limited by tenant, but the username and password are assigned per
user. Key pairs granting access to a volume are enabled per user,
but quotas to control resource consumption across available
hardware resources are per tenant.</para>
<para><guilabel>For tenants, quota controls are available to limit
the:</guilabel></para>
<itemizedlist>
<listitem>
<para>Number of volumes which may be created</para>
</listitem>
<listitem>
<para>Number of snapshots which may be created</para>
</listitem>
<listitem>
<para>Total number of Giga Bytes allowed per tenant (shared
between snapshots and volumes)</para>
</listitem>
</itemizedlist>
<para><guilabel>Volumes Snapshots and Backups</guilabel></para>
<para>This introduction provides a high level overview of the two
basic resources offered by the OpenStack Block Storage service.
The first is Volumes and the second is Snapshots which are derived
from Volumes.</para>
<para><guilabel>Volumes</guilabel></para>
<para>Volumes are allocated block storage resources that can be
attached to instances as secondary storage or they can be used as
the root store to boot instances. Volumes are persistent R/W Block
Storage devices most commonly attached to the Compute node via
iSCSI.</para>
<para><guilabel>Snapshots</guilabel></para>
<para>A Snapshot in OpenStack Block Storage is a read-only point in
time copy of a Volume. The Snapshot can be created from a Volume
that is currently in use (via the use of '--force True') or in an
available state. The Snapshot can then be used to create a new
volume via create from snapshot.</para>
<para><guilabel>Backups</guilabel></para>
<para>A Backup is an archived copy of a Volume currently stored in
Object Storage (Swift).</para>
<para><guilabel>Managing Volumes</guilabel></para>
<para>Cinder is the OpenStack service that allows you to give extra
block level storage to your OpenStack Compute instances. You may
recognize this as a similar offering from Amazon EC2 known as
Elastic Block Storage (EBS). The default Cinder implementation is
an iSCSI solution that employs the use of Logical Volume Manager
(LVM) for Linux. Note that a volume may only be attached to one
instance at a time. This is not a shared storage solution like a
SAN of NFS on which multiple servers can attach to. It's also
important to note that Cinder also includes a number of drivers to
allow you to use a number of other vendor's back-end storage
devices in addition to or instead of the base LVM
implementation.</para>
<para>Here is brief walk-through of a simple create/attach sequence,
keep in mind this requires proper configuration of both OpenStack
Compute via cinder.conf and OpenStack Block Storage via
cinder.conf.</para>
<orderedlist>
<listitem>
<para>The volume is created via cinder create; which creates
an LV into the volume group (VG) "cinder-volumes"</para>
</listitem>
<listitem>
<para>The volume is attached to an instance via nova
volume-attach; which creates a unique iSCSI IQN that will be
exposed to the compute node</para>
</listitem>
<listitem>
<para>The compute node which run the concerned instance has
now an active ISCSI session; and a new local storage
(usually a /dev/sdX disk)</para>
</listitem>
<listitem>
<para>libvirt uses that local storage as a storage for the
instance; the instance get a new disk (usually a /dev/vdX
disk)</para>
</listitem>
</orderedlist>
<para><guilabel>Block Storage Capabilities</guilabel></para>
<itemizedlist>
<listitem>
<para>OpenStack provides persistent block level storage
devices for use with OpenStack compute instances.</para>
</listitem>
<listitem>
<para>The block storage system manages the creation, attaching
and detaching of the block devices to servers. Block storage
volumes are fully integrated into OpenStack Compute and the
Dashboard allowing for cloud users to manage their own
storage needs.</para>
</listitem>
<listitem>
<para>In addition to using simple Linux server storage, it has
unified storage support for numerous storage platforms
including Ceph, NetApp, Nexenta, SolidFire, and
Zadara.</para>
</listitem>
<listitem>
<para>Block storage is appropriate for performance sensitive
scenarios such as database storage, expandable file systems,
or providing a server with access to raw block level
storage.</para>
</listitem>
<listitem>
<para>Snapshot management provides powerful functionality for
backing up data stored on block storage volumes. Snapshots
can be restored or used to create a new block storage
volume.</para>
</listitem>
</itemizedlist>
</chapter>