/doc/admin.rst - ganeti-local - Greek Research and Technology Network's projects

| Branch: | Tag: | Revision:

root / doc / admin.rst @ ebbdde89

History | View | Annotate | Download (73 kB)

       Ganeti administrator's guide
       ============================
       Documents Ganeti version |version|
       .. contents::
       .. highlight:: shell-example
       Introduction
       ------------
       Ganeti is a virtualization cluster management software. You are expected
       to be a system administrator familiar with your Linux distribution and
       the Xen or KVM virtualization environments before using it.
       The various components of Ganeti all have man pages and interactive
       help. This manual though will help you getting familiar with the system
       by explaining the most common operations, grouped by related use.
       After a terminology glossary and a section on the prerequisites needed
       to use this manual, the rest of this document is divided in sections
       for the different targets that a command affects: instance, nodes, etc.
       .. _terminology-label:
       Ganeti terminology
       ++++++++++++++++++
       This section provides a small introduction to Ganeti terminology, which
       might be useful when reading the rest of the document.
       Cluster
       ~~~~~~~
       A set of machines (nodes) that cooperate to offer a coherent, highly
       available virtualization service under a single administration domain.
       Node
       ~~~~
       A physical machine which is member of a cluster.  Nodes are the basic
       cluster infrastructure, and they don't need to be fault tolerant in
       order to achieve high availability for instances.
       Node can be added and removed (if they host no instances) at will from
       the cluster. In a HA cluster and only with HA instances, the loss of any
       single node will not cause disk data loss for any instance; of course,
       a node crash will cause the crash of its primary instances.
       A node belonging to a cluster can be in one of the following roles at a
       given time:
       - *master* node, which is the node from which the cluster is controlled
       - *master candidate* node, only nodes in this role have the full cluster
         configuration and knowledge, and only master candidates can become the
         master node
       - *regular* node, which is the state in which most nodes will be on
         bigger clusters (>20 nodes)
       - *drained* node, nodes in this state are functioning normally but the
         cannot receive new instances; the intention is that nodes in this role
         have some issue and they are being evacuated for hardware repairs
       - *offline* node, in which there is a record in the cluster
         configuration about the node, but the daemons on the master node will
         not talk to this node; any instances declared as having an offline
         node as either primary or secondary will be flagged as an error in the
         cluster verify operation
       Depending on the role, each node will run a set of daemons:
       - the :command:`ganeti-noded` daemon, which controls the manipulation of
         this node's hardware resources; it runs on all nodes which are in a
         cluster
       - the :command:`ganeti-confd` daemon (Ganeti 2.1+) which runs on all
         nodes, but is only functional on master candidate nodes; this daemon
         can be disabled at configuration time if you don't need its
         functionality
       - the :command:`ganeti-rapi` daemon which runs on the master node and
         offers an HTTP-based API for the cluster
       - the :command:`ganeti-masterd` daemon which runs on the master node and
         allows control of the cluster
       Beside the node role, there are other node flags that influence its
       behaviour:
       - the *master_capable* flag denotes whether the node can ever become a
         master candidate; setting this to 'no' means that auto-promotion will
         never make this node a master candidate; this flag can be useful for a
         remote node that only runs local instances, and having it become a
         master is impractical due to networking or other constraints
       - the *vm_capable* flag denotes whether the node can host instances or
         not; for example, one might use a non-vm_capable node just as a master
         candidate, for configuration backups; setting this flag to no
         disallows placement of instances of this node, deactivates hypervisor
         and related checks on it (e.g. bridge checks, LVM check, etc.), and
         removes it from cluster capacity computations
       Instance
       ~~~~~~~~
       A virtual machine which runs on a cluster. It can be a fault tolerant,
       highly available entity.
       An instance has various parameters, which are classified in three
       categories: hypervisor related-parameters (called ``hvparams``), general
       parameters (called ``beparams``) and per network-card parameters (called
       ``nicparams``). All these parameters can be modified either at instance
       level or via defaults at cluster level.
       Disk template
       ~~~~~~~~~~~~~
       The are multiple options for the storage provided to an instance; while
       the instance sees the same virtual drive in all cases, the node-level
       configuration varies between them.
       There are five disk templates you can choose from:
       diskless
         The instance has no disks. Only used for special purpose operating
         systems or for testing.
       file
         The instance will use plain files as backend for its disks. No
         redundancy is provided, and this is somewhat more difficult to
         configure for high performance. Note that for security reasons the
         file storage directory must be listed under
         ``/etc/ganeti/file-storage-paths``, and that file is not copied
         automatically to all nodes by Ganeti. The format of that file is a
         newline-separated list of directories.
       sharedfile
         The instance will use plain files as backend, but Ganeti assumes that
         those files will be available and in sync automatically on all nodes.
         This allows live migration and failover of instances using this
         method. As for ``file`` the file storage directory must be listed under
         ``/etc/ganeti/file-storage-paths`` or ganeti will refuse to create
         instances under it.
       plain
         The instance will use LVM devices as backend for its disks. No
         redundancy is provided.
       drbd
         .. note:: This is only valid for multi-node clusters using DRBD 8.0+
         A mirror is set between the local node and a remote one, which must be
         specified with the second value of the --node option. Use this option
         to obtain a highly available instance that can be failed over to a
         remote node should the primary one fail.
         .. note:: Ganeti does not support DRBD stacked devices:
            DRBD stacked setup is not fully symmetric and as such it is
            not working with live migration.
       rbd
         The instance will use Volumes inside a RADOS cluster as backend for its
         disks. It will access them using the RADOS block device (RBD).
       ext
         The instance will use an external storage provider. See
         :manpage:`ganeti-extstorage-interface(7)` for how to implement one.
       IAllocator
       ~~~~~~~~~~
       A framework for using external (user-provided) scripts to compute the
       placement of instances on the cluster nodes. This eliminates the need to
       manually specify nodes in instance add, instance moves, node evacuate,
       etc.
       In order for Ganeti to be able to use these scripts, they must be place
       in the iallocator directory (usually ``lib/ganeti/iallocators`` under
       the installation prefix, e.g. ``/usr/local``).
       “Primary” and “secondary” concepts
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       An instance has a primary and depending on the disk configuration, might
       also have a secondary node. The instance always runs on the primary node
       and only uses its secondary node for disk replication.
       Similarly, the term of primary and secondary instances when talking
       about a node refers to the set of instances having the given node as
       primary, respectively secondary.
       Tags
       ~~~~
       Tags are short strings that can be attached to either to cluster itself,
       or to nodes or instances. They are useful as a very simplistic
       information store for helping with cluster administration, for example
       by attaching owner information to each instance after it's created::
         $ gnt-instance add … %instance1%
         $ gnt-instance add-tags %instance1% %owner:user2%
       And then by listing each instance and its tags, this information could
       be used for contacting the users of each instance.
       Jobs and OpCodes
       ~~~~~~~~~~~~~~~~
       While not directly visible by an end-user, it's useful to know that a
       basic cluster operation (e.g. starting an instance) is represented
       internally by Ganeti as an *OpCode* (abbreviation from operation
       code). These OpCodes are executed as part of a *Job*. The OpCodes in a
       single Job are processed serially by Ganeti, but different Jobs will be
       processed (depending on resource availability) in parallel. They will
       not be executed in the submission order, but depending on resource
       availability, locks and (starting with Ganeti 2.3) priority. An earlier
       job may have to wait for a lock while a newer job doesn't need any locks
       and can be executed right away. Operations requiring a certain order
       need to be submitted as a single job, or the client must submit one job
       at a time and wait for it to finish before continuing.
       For example, shutting down the entire cluster can be done by running the
       command ``gnt-instance shutdown --all``, which will submit for each
       instance a separate job containing the “shutdown instance” OpCode.
       Prerequisites
       +++++++++++++
       You need to have your Ganeti cluster installed and configured before you
       try any of the commands in this document. Please follow the
       :doc:`install` for instructions on how to do that.
       Instance management
       -------------------
       Adding an instance
       ++++++++++++++++++
       The add operation might seem complex due to the many parameters it
       accepts, but once you have understood the (few) required parameters and
       the customisation capabilities you will see it is an easy operation.
       The add operation requires at minimum five parameters:
       - the OS for the instance
       - the disk template
       - the disk count and size
       - the node specification or alternatively the iallocator to use
       - and finally the instance name
       The OS for the instance must be visible in the output of the command
       ``gnt-os list`` and specifies which guest OS to install on the instance.
       The disk template specifies what kind of storage to use as backend for
       the (virtual) disks presented to the instance; note that for instances
       with multiple virtual disks, they all must be of the same type.
       The node(s) on which the instance will run can be given either manually,
       via the ``-n`` option, or computed automatically by Ganeti, if you have
       installed any iallocator script.
       With the above parameters in mind, the command is::
         $ gnt-instance add \
           -n %TARGET_NODE%:%SECONDARY_NODE% \
           -o %OS_TYPE% \
           -t %DISK_TEMPLATE% -s %DISK_SIZE% \
           %INSTANCE_NAME%
       The instance name must be resolvable (e.g. exist in DNS) and usually
       points to an address in the same subnet as the cluster itself.
       The above command has the minimum required options; other options you
       can give include, among others:
       - The maximum/minimum memory size (``-B maxmem``, ``-B minmem``)
         (``-B memory`` can be used to specify only one size)
       - The number of virtual CPUs (``-B vcpus``)
       - Arguments for the NICs of the instance; by default, a single-NIC
         instance is created. The IP and/or bridge of the NIC can be changed
         via ``--net 0:ip=IP,link=BRIDGE``
       See :manpage:`ganeti-instance(8)` for the detailed option list.
       For example if you want to create an highly available instance, with a
       single disk of 50GB and the default memory size, having primary node
       ``node1`` and secondary node ``node3``, use the following command::
         $ gnt-instance add -n node1:node3 -o debootstrap -t drbd -s 50G \
           instance1
       There is a also a command for batch instance creation from a
       specification file, see the ``batch-create`` operation in the
       gnt-instance manual page.
       Regular instance operations
       +++++++++++++++++++++++++++
       Removal
       ~~~~~~~
       Removing an instance is even easier than creating one. This operation is
       irreversible and destroys all the contents of your instance. Use with
       care::
         $ gnt-instance remove %INSTANCE_NAME%
       .. _instance-startup-label:
       Startup/shutdown
       ~~~~~~~~~~~~~~~~
       Instances are automatically started at instance creation time. To
       manually start one which is currently stopped you can run::
         $ gnt-instance startup %INSTANCE_NAME%
       Ganeti will start an instance with up to its maximum instance memory. If
       not enough memory is available Ganeti will use all the available memory
       down to the instance minimum memory. If not even that amount of memory
       is free Ganeti will refuse to start the instance.
       Note, that this will not work when an instance is in a permanently
       stopped state ``offline``. In this case, you will first have to
       put it back to online mode by running::
         $ gnt-instance modify --online %INSTANCE_NAME%
       The command to stop the running instance is::
         $ gnt-instance shutdown %INSTANCE_NAME%
       If you want to shut the instance down more permanently, so that it
       does not require dynamically allocated resources (memory and vcpus),
       after shutting down an instance, execute the following::
         $ gnt-instance modify --offline %INSTANCE_NAME%
       .. warning:: Do not use the Xen or KVM commands directly to stop
          instances. If you run for example ``xm shutdown`` or ``xm destroy``
          on an instance Ganeti will automatically restart it (via
          the :command:`ganeti-watcher(8)` command which is launched via cron).
       Querying instances
       ~~~~~~~~~~~~~~~~~~
       There are two ways to get information about instances: listing
       instances, which does a tabular output containing a given set of fields
       about each instance, and querying detailed information about a set of
       instances.
       The command to see all the instances configured and their status is::
         $ gnt-instance list
       The command can return a custom set of information when using the ``-o``
       option (as always, check the manpage for a detailed specification). Each
       instance will be represented on a line, thus making it easy to parse
       this output via the usual shell utilities (grep, sed, etc.).
       To get more detailed information about an instance, you can run::
         $ gnt-instance info %INSTANCE%
       which will give a multi-line block of information about the instance,
       it's hardware resources (especially its disks and their redundancy
       status), etc. This is harder to parse and is more expensive than the
       list operation, but returns much more detailed information.
       Changing an instance's runtime memory
       +++++++++++++++++++++++++++++++++++++
       Ganeti will always make sure an instance has a value between its maximum
       and its minimum memory available as runtime memory. As of version 2.6
       Ganeti will only choose a size different than the maximum size when
       starting up, failing over, or migrating an instance on a node with less
       than the maximum memory available. It won't resize other instances in
       order to free up space for an instance.
       If you find that you need more memory on a node any instance can be
       manually resized without downtime, with the command::
         $ gnt-instance modify -m %SIZE% %INSTANCE_NAME%
       The same command can also be used to increase the memory available on an
       instance, provided that enough free memory is available on its node, and
       the specified size is not larger than the maximum memory size the
       instance had when it was first booted (an instance will be unable to see
       new memory above the maximum that was specified to the hypervisor at its
       boot time, if it needs to grow further a reboot becomes necessary).
       Export/Import
       +++++++++++++
       You can create a snapshot of an instance disk and its Ganeti
       configuration, which then you can backup, or import into another
       cluster. The way to export an instance is::
         $ gnt-backup export -n %TARGET_NODE% %INSTANCE_NAME%
       The target node can be any node in the cluster with enough space under
       ``/srv/ganeti`` to hold the instance image. Use the ``--noshutdown``
       option to snapshot an instance without rebooting it. Note that Ganeti
       only keeps one snapshot for an instance - any previous snapshot of the
       same instance existing cluster-wide under ``/srv/ganeti`` will be
       removed by this operation: if you want to keep them, you need to move
       them out of the Ganeti exports directory.
       Importing an instance is similar to creating a new one, but additionally
       one must specify the location of the snapshot. The command is::
         $ gnt-backup import -n %TARGET_NODE% \
           --src-node=%NODE% --src-dir=%DIR% %INSTANCE_NAME%
       By default, parameters will be read from the export information, but you
       can of course pass them in via the command line - most of the options
       available for the command :command:`gnt-instance add` are supported here
       too.
       Import of foreign instances
       +++++++++++++++++++++++++++
       There is a possibility to import a foreign instance whose disk data is
       already stored as LVM volumes without going through copying it: the disk
       adoption mode.
       For this, ensure that the original, non-managed instance is stopped,
       then create a Ganeti instance in the usual way, except that instead of
       passing the disk information you specify the current volumes::
         $ gnt-instance add -t plain -n %HOME_NODE% ... \
           --disk 0:adopt=%lv_name%[,vg=%vg_name%] %INSTANCE_NAME%
       This will take over the given logical volumes, rename them to the Ganeti
       standard (UUID-based), and without installing the OS on them start
       directly the instance. If you configure the hypervisor similar to the
       non-managed configuration that the instance had, the transition should
       be seamless for the instance. For more than one disk, just pass another
       disk parameter (e.g. ``--disk 1:adopt=...``).
       Instance kernel selection
       +++++++++++++++++++++++++
       The kernel that instances uses to bootup can come either from the node,
       or from instances themselves, depending on the setup.
       Xen-PVM
       ~~~~~~~
       With Xen PVM, there are three options.
       First, you can use a kernel from the node, by setting the hypervisor
       parameters as such:
       - ``kernel_path`` to a valid file on the node (and appropriately
         ``initrd_path``)
       - ``kernel_args`` optionally set to a valid Linux setting (e.g. ``ro``)
       - ``root_path`` to a valid setting (e.g. ``/dev/xvda1``)
       - ``bootloader_path`` and ``bootloader_args`` to empty
       Alternatively, you can delegate the kernel management to instances, and
       use either ``pvgrub`` or the deprecated ``pygrub``. For this, you must
       install the kernels and initrds in the instance and create a valid GRUB
       v1 configuration file.
       For ``pvgrub`` (new in version 2.4.2), you need to set:
       - ``kernel_path`` to point to the ``pvgrub`` loader present on the node
         (e.g. ``/usr/lib/xen/boot/pv-grub-x86_32.gz``)
       - ``kernel_args`` to the path to the GRUB config file, relative to the
         instance (e.g. ``(hd0,0)/grub/menu.lst``)
       - ``root_path`` **must** be empty
       - ``bootloader_path`` and ``bootloader_args`` to empty
       While ``pygrub`` is deprecated, here is how you can configure it:
       - ``bootloader_path`` to the pygrub binary (e.g. ``/usr/bin/pygrub``)
       - the other settings are not important
       More information can be found in the Xen wiki pages for `pvgrub
       <http://wiki.xensource.com/xenwiki/PvGrub>`_ and `pygrub
       <http://wiki.xensource.com/xenwiki/PyGrub>`_.
       KVM
       ~~~
       For KVM also the kernel can be loaded either way.
       For loading the kernels from the node, you need to set:
       - ``kernel_path`` to a valid value
       - ``initrd_path`` optionally set if you use an initrd
       - ``kernel_args`` optionally set to a valid value (e.g. ``ro``)
       If you want instead to have the instance boot from its disk (and execute
       its bootloader), simply set the ``kernel_path`` parameter to an empty
       string, and all the others will be ignored.
       Instance HA features
       --------------------
       .. note:: This section only applies to multi-node clusters
       .. _instance-change-primary-label:
       Changing the primary node
       +++++++++++++++++++++++++
       There are three ways to exchange an instance's primary and secondary
       nodes; the right one to choose depends on how the instance has been
       created and the status of its current primary node. See
       :ref:`rest-redundancy-label` for information on changing the secondary
       node. Note that it's only possible to change the primary node to the
       secondary and vice-versa; a direct change of the primary node with a
       third node, while keeping the current secondary is not possible in a
       single step, only via multiple operations as detailed in
       :ref:`instance-relocation-label`.
       Failing over an instance
       ~~~~~~~~~~~~~~~~~~~~~~~~
       If an instance is built in highly available mode you can at any time
       fail it over to its secondary node, even if the primary has somehow
       failed and it's not up anymore. Doing it is really easy, on the master
       node you can just run::
         $ gnt-instance failover %INSTANCE_NAME%
       That's it. After the command completes the secondary node is now the
       primary, and vice-versa.
       The instance will be started with an amount of memory between its
       ``maxmem`` and its ``minmem`` value, depending on the free memory on its
       target node, or the operation will fail if that's not possible. See
       :ref:`instance-startup-label` for details.
       If the instance's disk template is of type rbd, then you can specify
       the target node (which can be any node) explicitly, or specify an
       iallocator plugin. If you omit both, the default iallocator will be
       used to determine the target node::
         $ gnt-instance failover -n %TARGET_NODE% %INSTANCE_NAME%
       Live migrating an instance
       ~~~~~~~~~~~~~~~~~~~~~~~~~~
       If an instance is built in highly available mode, it currently runs and
       both its nodes are running fine, you can migrate it over to its
       secondary node, without downtime. On the master node you need to run::
         $ gnt-instance migrate %INSTANCE_NAME%
       The current load on the instance and its memory size will influence how
       long the migration will take. In any case, for both KVM and Xen
       hypervisors, the migration will be transparent to the instance.
       If the destination node has less memory than the instance's current
       runtime memory, but at least the instance's minimum memory available
       Ganeti will automatically reduce the instance runtime memory before
       migrating it, unless the ``--no-runtime-changes`` option is passed, in
       which case the target node should have at least the instance's current
       runtime memory free.
       If the instance's disk template is of type rbd, then you can specify
       the target node (which can be any node) explicitly, or specify an
       iallocator plugin. If you omit both, the default iallocator will be
       used to determine the target node::
          $ gnt-instance migrate -n %TARGET_NODE% %INSTANCE_NAME%
       Moving an instance (offline)
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       If an instance has not been create as mirrored, then the only way to
       change its primary node is to execute the move command::
         $ gnt-instance move -n %NEW_NODE% %INSTANCE%
       This has a few prerequisites:
       - the instance must be stopped
       - its current primary node must be on-line and healthy
       - the disks of the instance must not have any errors
       Since this operation actually copies the data from the old node to the
       new node, expect it to take proportional to the size of the instance's
       disks and the speed of both the nodes' I/O system and their networking.
       Disk operations
       +++++++++++++++
       Disk failures are a common cause of errors in any server
       deployment. Ganeti offers protection from single-node failure if your
       instances were created in HA mode, and it also offers ways to restore
       redundancy after a failure.
       Preparing for disk operations
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       It is important to note that for Ganeti to be able to do any disk
       operation, the Linux machines on top of which Ganeti runs must be
       consistent; for LVM, this means that the LVM commands must not return
       failures; it is common that after a complete disk failure, any LVM
       command aborts with an error similar to::
         $ vgs
         /dev/sdb1: read failed after 0 of 4096 at 0: Input/output error
         /dev/sdb1: read failed after 0 of 4096 at 750153695232: Input/output error
         /dev/sdb1: read failed after 0 of 4096 at 0: Input/output error
         Couldn't find device with uuid 't30jmN-4Rcf-Fr5e-CURS-pawt-z0jU-m1TgeJ'.
         Couldn't find all physical volumes for volume group xenvg.
       Before restoring an instance's disks to healthy status, it's needed to
       fix the volume group used by Ganeti so that we can actually create and
       manage the logical volumes. This is usually done in a multi-step
       process:
       #. first, if the disk is completely gone and LVM commands exit with
          “Couldn't find device with uuid…” then you need to run the command::
           $ vgreduce --removemissing %VOLUME_GROUP%
       #. after the above command, the LVM commands should be executing
          normally (warnings are normal, but the commands will not fail
          completely).
       #. if the failed disk is still visible in the output of the ``pvs``
          command, you need to deactivate it from allocations by running::
           $ pvs -x n /dev/%DISK%
       At this point, the volume group should be consistent and any bad
       physical volumes should not longer be available for allocation.
       Note that since version 2.1 Ganeti provides some commands to automate
       these two operations, see :ref:`storage-units-label`.
       .. _rest-redundancy-label:
       Restoring redundancy for DRBD-based instances
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       A DRBD instance has two nodes, and the storage on one of them has
       failed. Depending on which node (primary or secondary) has failed, you
       have three options at hand:
       - if the storage on the primary node has failed, you need to re-create
         the disks on it
       - if the storage on the secondary node has failed, you can either
         re-create the disks on it or change the secondary and recreate
         redundancy on the new secondary node
       Of course, at any point it's possible to force re-creation of disks even
       though everything is already fine.
       For all three cases, the ``replace-disks`` operation can be used::
         # re-create disks on the primary node
         $ gnt-instance replace-disks -p %INSTANCE_NAME%
         # re-create disks on the current secondary
         $ gnt-instance replace-disks -s %INSTANCE_NAME%
         # change the secondary node, via manual specification
         $ gnt-instance replace-disks -n %NODE% %INSTANCE_NAME%
         # change the secondary node, via an iallocator script
         $ gnt-instance replace-disks -I %SCRIPT% %INSTANCE_NAME%
         # since Ganeti 2.1: automatically fix the primary or secondary node
         $ gnt-instance replace-disks -a %INSTANCE_NAME%
       Since the process involves copying all data from the working node to the
       target node, it will take a while, depending on the instance's disk
       size, node I/O system and network speed. But it is (barring any network
       interruption) completely transparent for the instance.
       Re-creating disks for non-redundant instances
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       .. versionadded:: 2.1
       For non-redundant instances, there isn't a copy (except backups) to
       re-create the disks. But it's possible to at-least re-create empty
       disks, after which a reinstall can be run, via the ``recreate-disks``
       command::
         $ gnt-instance recreate-disks %INSTANCE%
       Note that this will fail if the disks already exists. The instance can
       be assigned to new nodes automatically by specifying an iallocator
       through the ``--iallocator`` option.
       Conversion of an instance's disk type
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       It is possible to convert between a non-redundant instance of type
       ``plain`` (LVM storage) and redundant ``drbd`` via the ``gnt-instance
       modify`` command::
         # start with a non-redundant instance
         $ gnt-instance add -t plain ... %INSTANCE%
         # later convert it to redundant
         $ gnt-instance stop %INSTANCE%
         $ gnt-instance modify -t drbd -n %NEW_SECONDARY% %INSTANCE%
         $ gnt-instance start %INSTANCE%
         # and convert it back
         $ gnt-instance stop %INSTANCE%
         $ gnt-instance modify -t plain %INSTANCE%
         $ gnt-instance start %INSTANCE%
       The conversion must be done while the instance is stopped, and
       converting from plain to drbd template presents a small risk, especially
       if the instance has multiple disks and/or if one node fails during the
       conversion procedure). As such, it's recommended (as always) to make
       sure that downtime for manual recovery is acceptable and that the
       instance has up-to-date backups.
       Debugging instances
       +++++++++++++++++++
       Accessing an instance's disks
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       From an instance's primary node you can have access to its disks. Never
       ever mount the underlying logical volume manually on a fault tolerant
       instance, or will break replication and your data will be
       inconsistent. The correct way to access an instance's disks is to run
       (on the master node, as usual) the command::
         $ gnt-instance activate-disks %INSTANCE%
       And then, *on the primary node of the instance*, access the device that
       gets created. For example, you could mount the given disks, then edit
       files on the filesystem, etc.
       Note that with partitioned disks (as opposed to whole-disk filesystems),
       you will need to use a tool like :manpage:`kpartx(8)`::
         # on node1
         $ gnt-instance activate-disks %instance1%
         node3:disk/0:…
         $ ssh node3
         # on node 3
         $ kpartx -l /dev/…
         $ kpartx -a /dev/…
         $ mount /dev/mapper/… /mnt/
         # edit files under mnt as desired
         $ umount /mnt/
         $ kpartx -d /dev/…
         $ exit
         # back to node 1
       After you've finished you can deactivate them with the deactivate-disks
       command, which works in the same way::
         $ gnt-instance deactivate-disks %INSTANCE%
       Note that if any process started by you is still using the disks, the
       above command will error out, and you **must** cleanup and ensure that
       the above command runs successfully before you start the instance,
       otherwise the instance will suffer corruption.
       Accessing an instance's console
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       The command to access a running instance's console is::
         $ gnt-instance console %INSTANCE_NAME%
       Use the console normally and then type ``^]`` when done, to exit.
       Other instance operations
       +++++++++++++++++++++++++
       Reboot
       ~~~~~~
       There is a wrapper command for rebooting instances::
         $ gnt-instance reboot %instance2%
       By default, this does the equivalent of shutting down and then starting
       the instance, but it accepts parameters to perform a soft-reboot (via
       the hypervisor), a hard reboot (hypervisor shutdown and then startup) or
       a full one (the default, which also de-configures and then configures
       again the disks of the instance).
       Instance OS definitions debugging
       +++++++++++++++++++++++++++++++++
       Should you have any problems with instance operating systems the command
       to see a complete status for all your nodes is::
          $ gnt-os diagnose
       .. _instance-relocation-label:
       Instance relocation
       ~~~~~~~~~~~~~~~~~~~
       While it is not possible to move an instance from nodes ``(A, B)`` to
       nodes ``(C, D)`` in a single move, it is possible to do so in a few
       steps::
         # instance is located on A, B
         $ gnt-instance replace-disks -n %nodeC% %instance1%
         # instance has moved from (A, B) to (A, C)
         # we now flip the primary/secondary nodes
         $ gnt-instance migrate %instance1%
         # instance lives on (C, A)
         # we can then change A to D via:
         $ gnt-instance replace-disks -n %nodeD% %instance1%
       Which brings it into the final configuration of ``(C, D)``. Note that we
       needed to do two replace-disks operation (two copies of the instance
       disks), because we needed to get rid of both the original nodes (A and
       B).
       Network Management
       ------------------
       Ganeti used to describe NICs of an Instance with an IP, a MAC, a connectivity
       link and mode. This had three major shortcomings:
         * there was no easy way to assign a unique IP to an instance
         * network info (subnet, gateway, domain, etc.) was not available on target
           node (kvm-ifup, hooks, etc)
         * one should explicitly pass L2 info (mode, and link) to every NIC
       Plus there was no easy way to get the current networking overview (which
       instances are on the same L2 or L3 network, which IPs are reserved, etc).
       All the above required an external management tool that has an overall view
       and provides the corresponding info to Ganeti.
       gnt-network aims to support a big part of this functionality inside Ganeti and
       abstract the network as a separate entity. Currently, a Ganeti network
       provides the following:
         * A single IPv4 pool, subnet and gateway
         * Connectivity info per nodegroup (mode, link)
         * MAC prefix for each NIC inside the network
         * IPv6 prefix/Gateway related to this network
         * Tags
       IP pool management ensures IP uniqueness inside this network. The user can
       pass `ip=pool,network=test` and will:
 . Get the first available IP in the pool
 . Inherit the connectivity mode and link of the network's netparams
 . NIC will obtain the MAC prefix of the network
 . All network related info will be available as environment variables in
          kvm-ifup scripts and hooks, so that they can dynamically manage all
          networking-related setup on the host.
       Hands on with gnt-network
       +++++++++++++++++++++++++
       To create a network do::
         # gnt-network add --network=192.0.2.0/24 --gateway=192.0.2.1 test
       Please see all other available options (--add-reserved-ips, --mac-prefix,
       --network6, --gateway6, --tags).
       Currently, IPv6 info is not used by Ganeti itself. It only gets exported
       to NIC configuration scripts and hooks via environment variables.
       To make this network available on a nodegroup you should specify the
       connectivity mode and link during connection::
         # gnt-network connect test bridged br100 default nodegroup1
       To add a NIC inside this network::
         # gnt-instance modify --net -1:add,ip=pool,network=test inst1
       This will let a NIC obtain a unique IP inside this network, and inherit the
       nodegroup's netparams (bridged, br100). IP here is optional. If missing the
       NIC will just get the L2 info.
       To move an existing NIC from a network to another and remove its IP::
         # gnt-instance modify --net -1:ip=none,network=test1 inst1
       This will release the old IP from the old IP pool and the NIC will inherit the
       new nicparams.
       On the above actions there is a extra option `--no-conflicts-ckeck`. This
       does not check for conflicting setups. Specifically:
 . When a network is added, IPs of nodes and master are not being checked.
 . When connecting a network on a nodegroup, IPs of instances inside this
          nodegroup are not checked whether they reside inside the subnet or not.
 . When specifying explicitly a IP without passing a network, Ganeti will not
          check if this IP is included inside any available network on the nodegroup.
       External components
       +++++++++++++++++++
       All the aforementioned steps assure NIC configuration from the Ganeti
       perspective. Of course this has nothing to do, how the instance eventually will
       get the desired connectivity (IPv4, IPv6, default routes, DNS info, etc) and
       where will the IP resolve.  This functionality is managed by the external
       components.
       Let's assume that the VM will need to obtain a dynamic IP via DHCP, get a SLAAC
       address, and use DHCPv6 for other configuration information (in case RFC-6106
       is not supported by the client, e.g.  Windows).  This means that the following
       external services are needed:
 . A DHCP server
 . An IPv6 router sending Router Advertisements
 . A DHCPv6 server exporting DNS info
 . A dynamic DNS server
       These components must be configured dynamically and on a per NIC basis.
       The way to do this is by using custom kvm-ifup scripts and hooks.
       snf-network
       ~~~~~~~~~~~
       The snf-network package [1,3] includes custom scripts that will provide the
       aforementioned functionality. `kvm-vif-bridge` and `vif-custom` is an
       alternative to `kvm-ifup` and `vif-ganeti` that take into account all network
       info being exported. Their actions depend on network tags. Specifically:
       `dns`: will update an external DDNS server (nsupdate on a bind server)
       `ip-less-routed`: will setup routes, rules and proxy ARP
       This setup assumes a pre-existing routing table along with some local
       configuration and provides connectivity to instances via an external
       gateway/router without requiring nodes to have an IP inside this network.
       `private-filtered`: will setup ebtables rules to ensure L2 isolation on a
       common bridge. Only packets with the same MAC prefix will be forwarded to the
       corresponding virtual interface.
       `nfdhcpd`: will update an external DHCP server
       nfdhcpd
       ~~~~~~~
       snf-network works with nfdhcpd [2,3]: a custom user space DHCP
       server based on NFQUEUE. Currently, nfdhcpd replies on BOOTP/DHCP requests
       originating from a tap or a bridge. Additionally in case of a routed setup it
       provides a ra-stateless configuration by responding to router and neighbour
       solicitations along with DHCPv6 requests for DNS options.  Its db is
       dynamically updated using text files inside a local dir with inotify
       (snf-network just adds a per NIC binding file with all relevant info if the
       corresponding network tag is found). Still we need to mangle all these
       packets and send them to the corresponding NFQUEUE.
       Known shortcomings
       ++++++++++++++++++
       Currently the following things are some know weak points of the gnt-network
       design and implementation:
        * Cannot define a network without an IP pool
        * The pool defines the size of the network
        * Reserved IPs must be defined explicitly (inconvenient for a big range)
        * Cannot define an IPv6 only network
       Future work
       +++++++++++
       Any upcoming patches should target:
        * Separate L2, L3, IPv6, IP pool info
        * Support a set of IP pools per network
        * Make IP/network in NIC object take a list of entries
        * Introduce external scripts for node configuration
          (dynamically create/destroy bridges/routes upon network connect/disconnect)
       [1] https://code.grnet.gr/git/snf-network
       [2] https://code.grnet.gr/git/snf-nfdhcpd
       [3] deb http:/apt.dev.grnet.gr/ wheezy/
       Node operations
       ---------------
       There are much fewer node operations available than for instances, but
       they are equivalently important for maintaining a healthy cluster.
       Add/readd
       +++++++++
       It is at any time possible to extend the cluster with one more node, by
       using the node add operation::
         $ gnt-node add %NEW_NODE%
       If the cluster has a replication network defined, then you need to pass
       the ``-s REPLICATION_IP`` parameter to this option.
       A variation of this command can be used to re-configure a node if its
       Ganeti configuration is broken, for example if it has been reinstalled
       by mistake::
         $ gnt-node add --readd %EXISTING_NODE%
       This will reinitialise the node as if it's been newly added, but while
       keeping its existing configuration in the cluster (primary/secondary IP,
       etc.), in other words you won't need to use ``-s`` here.
       Changing the node role
       ++++++++++++++++++++++
       A node can be in different roles, as explained in the
       :ref:`terminology-label` section. Promoting a node to the master role is
       special, while the other roles are handled all via a single command.
       Failing over the master node
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       If you want to promote a different node to the master role (for whatever
       reason), run on any other master-candidate node the command::
         $ gnt-cluster master-failover
       and the node you ran it on is now the new master. In case you try to run
       this on a non master-candidate node, you will get an error telling you
       which nodes are valid.
       Changing between the other roles
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       The ``gnt-node modify`` command can be used to select a new role::
         # change to master candidate
         $ gnt-node modify -C yes %NODE%
         # change to drained status
         $ gnt-node modify -D yes %NODE%
         # change to offline status
         $ gnt-node modify -O yes %NODE%
         # change to regular mode (reset all flags)
         $ gnt-node modify -O no -D no -C no %NODE%
       Note that the cluster requires that at any point in time, a certain
       number of nodes are master candidates, so changing from master candidate
       to other roles might fail. It is recommended to either force the
       operation (via the ``--force`` option) or first change the number of
       master candidates in the cluster - see :ref:`cluster-config-label`.
       Evacuating nodes
       ++++++++++++++++
       There are two steps of moving instances off a node:
       - moving the primary instances (actually converting them into secondary
         instances)
       - moving the secondary instances (including any instances converted in
         the step above)
       Primary instance conversion
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~
       For this step, you can use either individual instance move
       commands (as seen in :ref:`instance-change-primary-label`) or the bulk
       per-node versions; these are::
         $ gnt-node migrate %NODE%
         $ gnt-node evacuate -s %NODE%
       Note that the instance “move” command doesn't currently have a node
       equivalent.
       Both these commands, or the equivalent per-instance command, will make
       this node the secondary node for the respective instances, whereas their
       current secondary node will become primary. Note that it is not possible
       to change in one step the primary node to another node as primary, while
       keeping the same secondary node.
       Secondary instance evacuation
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       For the evacuation of secondary instances, a command called
       :command:`gnt-node evacuate` is provided and its syntax is::
         $ gnt-node evacuate -I %IALLOCATOR_SCRIPT% %NODE%
         $ gnt-node evacuate -n %DESTINATION_NODE% %NODE%
       The first version will compute the new secondary for each instance in
       turn using the given iallocator script, whereas the second one will
       simply move all instances to DESTINATION_NODE.
       Removal
       +++++++
       Once a node no longer has any instances (neither primary nor secondary),
       it's easy to remove it from the cluster::
         $ gnt-node remove %NODE_NAME%
       This will deconfigure the node, stop the ganeti daemons on it and leave
       it hopefully like before it joined to the cluster.
       Replication network changes
       +++++++++++++++++++++++++++
       The :command:`gnt-node modify -s` command can be used to change the
       secondary IP of a node. This operation can only be performed if:
       - No instance is active on the target node
       - The new target IP is reachable from the master's secondary IP
       Also this operation will not allow to change a node from single-homed
       (same primary and secondary ip) to multi-homed (separate replication
       network) or vice versa, unless:
       - The target node is the master node and `--force` is passed.
       - The target cluster is single-homed and the new primary ip is a change
         to single homed for a particular node.
       - The target cluster is multi-homed and the new primary ip is a change
         to multi homed for a particular node.
       For example to do a single-homed to multi-homed conversion::
         $ gnt-node modify --force -s %SECONDARY_IP% %MASTER_NAME%
         $ gnt-node modify -s %SECONDARY_IP% %NODE1_NAME%
         $ gnt-node modify -s %SECONDARY_IP% %NODE2_NAME%
         $ gnt-node modify -s %SECONDARY_IP% %NODE3_NAME%
         ...
       The same commands can be used for multi-homed to single-homed except the
       secondary IPs should be the same as the primaries for each node, for
       that case.
       Storage handling
       ++++++++++++++++
       When using LVM (either standalone or with DRBD), it can become tedious
       to debug and fix it in case of errors. Furthermore, even file-based
       storage can become complicated to handle manually on many hosts. Ganeti
       provides a couple of commands to help with automation.
       Logical volumes
       ~~~~~~~~~~~~~~~
       This is a command specific to LVM handling. It allows listing the
       logical volumes on a given node or on all nodes and their association to
       instances via the ``volumes`` command::
         $ gnt-node volumes
         Node  PhysDev   VG    Name             Size Instance
         node1 /dev/sdb1 xenvg e61fbc97-….disk0 512M instance17
         node1 /dev/sdb1 xenvg ebd1a7d1-….disk0 512M instance19
         node2 /dev/sdb1 xenvg 0af08a3d-….disk0 512M instance20
         node2 /dev/sdb1 xenvg cc012285-….disk0 512M instance16
         node2 /dev/sdb1 xenvg f0fac192-….disk0 512M instance18
       The above command maps each logical volume to a volume group and
       underlying physical volume and (possibly) to an instance.
       .. _storage-units-label:
       Generalized storage handling
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~~
       .. versionadded:: 2.1
       Starting with Ganeti 2.1, a new storage framework has been implemented
       that tries to abstract the handling of the storage type the cluster
       uses.
       First is listing the backend storage and their space situation::
         $ gnt-node list-storage
         Node  Name        Size Used   Free
         node1 /dev/sda7 673.8G   0M 673.8G
         node1 /dev/sdb1 698.6G 1.5G 697.1G
         node2 /dev/sda7 673.8G   0M 673.8G
         node2 /dev/sdb1 698.6G 1.0G 697.6G
       The default is to list LVM physical volumes. It's also possible to list
       the LVM volume groups::
         $ gnt-node list-storage -t lvm-vg
         Node  Name  Size
         node1 xenvg 1.3T
         node2 xenvg 1.3T
       Next is repairing storage units, which is currently only implemented for
       volume groups and does the equivalent of ``vgreduce --removemissing``::
         $ gnt-node repair-storage %node2% lvm-vg xenvg
         Sun Oct 25 22:21:45 2009 Repairing storage unit 'xenvg' on node2 ...
       Last is the modification of volume properties, which is (again) only
       implemented for LVM physical volumes and allows toggling the
       ``allocatable`` value::
         $ gnt-node modify-storage --allocatable=no %node2% lvm-pv /dev/%sdb1%
       Use of the storage commands
       ~~~~~~~~~~~~~~~~~~~~~~~~~~~
       All these commands are needed when recovering a node from a disk
       failure:
       - first, we need to recover from complete LVM failure (due to missing
         disk), by running the ``repair-storage`` command
       - second, we need to change allocation on any partially-broken disk
         (i.e. LVM still sees it, but it has bad blocks) by running
         ``modify-storage``
       - then we can evacuate the instances as needed
       Cluster operations
       ------------------
       Beside the cluster initialisation command (which is detailed in the
       :doc:`install` document) and the master failover command which is
       explained under node handling, there are a couple of other cluster
       operations available.
       .. _cluster-config-label:
       Standard operations
       +++++++++++++++++++
       One of the few commands that can be run on any node (not only the
       master) is the ``getmaster`` command::
         # on node2
         $ gnt-cluster getmaster
         node1.example.com
       It is possible to query and change global cluster parameters via the
       ``info`` and ``modify`` commands::
         $ gnt-cluster info
         Cluster name: cluster.example.com
         Cluster UUID: 07805e6f-f0af-4310-95f1-572862ee939c
         Creation time: 2009-09-25 05:04:15
         Modification time: 2009-10-18 22:11:47
         Master node: node1.example.com
         Architecture (this node): 64bit (x86_64)
         …
         Tags: foo
         Default hypervisor: xen-pvm
         Enabled hypervisors: xen-pvm
         Hypervisor parameters:
           - xen-pvm:
               root_path: /dev/sda1
               …
         Cluster parameters:
           - candidate pool size: 10
             …
         Default instance parameters:
           - default:
               memory: 128
               …
         Default nic parameters:
           - default:
               link: xen-br0
               …
       There various parameters above can be changed via the ``modify``
       commands as follows:
       - the hypervisor parameters can be changed via ``modify -H
         xen-pvm:root_path=…``, and so on for other hypervisors/key/values
       - the "default instance parameters" are changeable via ``modify -B
         parameter=value…`` syntax
       - the cluster parameters are changeable via separate options to the
         modify command (e.g. ``--candidate-pool-size``, etc.)
       For detailed option list see the :manpage:`gnt-cluster(8)` man page.
       The cluster version can be obtained via the ``version`` command::
         $ gnt-cluster version
         Software version: 2.1.0
         Internode protocol: 20
         Configuration format: 2010000
         OS api version: 15
         Export interface: 0
       This is not very useful except when debugging Ganeti.
       Global node commands
       ++++++++++++++++++++
       There are two commands provided for replicating files to all nodes of a
       cluster and for running commands on all the nodes::
         $ gnt-cluster copyfile %/path/to/file%
         $ gnt-cluster command %ls -l /path/to/file%
       These are simple wrappers over scp/ssh and more advanced usage can be
       obtained using :manpage:`dsh(1)` and similar commands. But they are
       useful to update an OS script from the master node, for example.
       Cluster verification
       ++++++++++++++++++++
       There are three commands that relate to global cluster checks. The first
       one is ``verify`` which gives an overview on the cluster state,
       highlighting any issues. In normal operation, this command should return
       no ``ERROR`` messages::
         $ gnt-cluster verify
         Sun Oct 25 23:08:58 2009 * Verifying global settings
         Sun Oct 25 23:08:58 2009 * Gathering data (2 nodes)
         Sun Oct 25 23:09:00 2009 * Verifying node status
         Sun Oct 25 23:09:00 2009 * Verifying instance status
         Sun Oct 25 23:09:00 2009 * Verifying orphan volumes
         Sun Oct 25 23:09:00 2009 * Verifying remaining instances
         Sun Oct 25 23:09:00 2009 * Verifying N+1 Memory redundancy
         Sun Oct 25 23:09:00 2009 * Other Notes
         Sun Oct 25 23:09:00 2009   - NOTICE: 5 non-redundant instance(s) found.
         Sun Oct 25 23:09:00 2009 * Hooks Results
       The second command is ``verify-disks``, which checks that the instance's
       disks have the correct status based on the desired instance state
       (up/down)::
         $ gnt-cluster verify-disks
       Note that this command will show no output when disks are healthy.
       The last command is used to repair any discrepancies in Ganeti's
       recorded disk size and the actual disk size (disk size information is
       needed for proper activation and growth of DRBD-based disks)::
         $ gnt-cluster repair-disk-sizes
         Sun Oct 25 23:13:16 2009  - INFO: Disk 0 of instance instance1 has mismatched size, correcting: recorded 512, actual 2048
         Sun Oct 25 23:13:17 2009  - WARNING: Invalid result from node node4, ignoring node results
       The above shows one instance having wrong disk size, and a node which
       returned invalid data, and thus we ignored all primary instances of that
       node.
       Configuration redistribution
       ++++++++++++++++++++++++++++
       If the verify command complains about file mismatches between the master
       and other nodes, due to some node problems or if you manually modified
       configuration files, you can force an push of the master configuration
       to all other nodes via the ``redist-conf`` command::
         $ gnt-cluster redist-conf
       This command will be silent unless there are problems sending updates to
       the other nodes.
       Cluster renaming
       ++++++++++++++++
       It is possible to rename a cluster, or to change its IP address, via the
       ``rename`` command. If only the IP has changed, you need to pass the
       current name and Ganeti will realise its IP has changed::
         $ gnt-cluster rename %cluster.example.com%
         This will rename the cluster to 'cluster.example.com'. If
         you are connected over the network to the cluster name, the operation
         is very dangerous as the IP address will be removed from the node and
         the change may not go through. Continue?
         y/[n]/?: %y%
         Failure: prerequisites not met for this operation:
         Neither the name nor the IP address of the cluster has changed
       In the above output, neither value has changed since the cluster
       initialisation so the operation is not completed.
       Queue operations
       ++++++++++++++++
       The job queue execution in Ganeti 2.0 and higher can be inspected,
       suspended and resumed via the ``queue`` command::
         $ gnt-cluster queue info
         The drain flag is unset
         $ gnt-cluster queue drain
         $ gnt-instance stop %instance1%
         Failed to submit job for instance1: Job queue is drained, refusing job
         $ gnt-cluster queue info
         The drain flag is set
         $ gnt-cluster queue undrain
       This is most useful if you have an active cluster and you need to
       upgrade the Ganeti software, or simply restart the software on any node:
       #. suspend the queue via ``queue drain``
       #. wait until there are no more running jobs via ``gnt-job list``
       #. restart the master or another node, or upgrade the software
       #. resume the queue via ``queue undrain``
       .. note:: this command only stores a local flag file, and if you
          failover the master, it will not have effect on the new master.
       Watcher control
       +++++++++++++++
       The :manpage:`ganeti-watcher(8)` is a program, usually scheduled via
       ``cron``, that takes care of cluster maintenance operations (restarting
       downed instances, activating down DRBD disks, etc.). However, during
       maintenance and troubleshooting, this can get in your way; disabling it
       via commenting out the cron job is not so good as this can be
       forgotten. Thus there are some commands for automated control of the
       watcher: ``pause``, ``info`` and ``continue``::
         $ gnt-cluster watcher info
         The watcher is not paused.
         $ gnt-cluster watcher pause %1h%
         The watcher is paused until Mon Oct 26 00:30:37 2009.
         $ gnt-cluster watcher info
         The watcher is paused until Mon Oct 26 00:30:37 2009.
         $ ganeti-watcher -d
 -10-25 23:30:47,984:  pid=28867 ganeti-watcher:486 DEBUG Pause has been set, exiting
         $ gnt-cluster watcher continue
         The watcher is no longer paused.
         $ ganeti-watcher -d
 -10-25 23:31:04,789:  pid=28976 ganeti-watcher:345 DEBUG Archived 0 jobs, left 0
 -10-25 23:31:05,884:  pid=28976 ganeti-watcher:280 DEBUG Got data from cluster, writing instance status file
 -10-25 23:31:06,061:  pid=28976 ganeti-watcher:150 DEBUG Data didn't change, just touching status file
         $ gnt-cluster watcher info
         The watcher is not paused.
       The exact details of the argument to the ``pause`` command are available
       in the manpage.
       .. note:: this command only stores a local flag file, and if you
          failover the master, it will not have effect on the new master.
       Node auto-maintenance
       +++++++++++++++++++++
       If the cluster parameter ``maintain_node_health`` is enabled (see the
       manpage for :command:`gnt-cluster`, the init and modify subcommands),
       then the following will happen automatically:
       - the watcher will shutdown any instances running on offline nodes
       - the watcher will deactivate any DRBD devices on offline nodes
       In the future, more actions are planned, so only enable this parameter
       if the nodes are completely dedicated to Ganeti; otherwise it might be
       possible to lose data due to auto-maintenance actions.
       Removing a cluster entirely
       +++++++++++++++++++++++++++
       The usual method to cleanup a cluster is to run ``gnt-cluster destroy``
       however if the Ganeti installation is broken in any way then this will
       not run.
       It is possible in such a case to cleanup manually most if not all traces
       of a cluster installation by following these steps on all of the nodes:
 . Shutdown all instances. This depends on the virtualisation method
          used (Xen, KVM, etc.):
         - Xen: run ``xm list`` and ``xm destroy`` on all the non-Domain-0
           instances
         - KVM: kill all the KVM processes
         - chroot: kill all processes under the chroot mountpoints
 . If using DRBD, shutdown all DRBD minors (which should by at this time
          no-longer in use by instances); on each node, run ``drbdsetup
          /dev/drbdN down`` for each active DRBD minor.
 . If using LVM, cleanup the Ganeti volume group; if only Ganeti created
          logical volumes (and you are not sharing the volume group with the
          OS, for example), then simply running ``lvremove -f xenvg`` (replace
          'xenvg' with your volume group name) should do the required cleanup.
 . If using file-based storage, remove recursively all files and
          directories under your file-storage directory: ``rm -rf
          /srv/ganeti/file-storage/*`` replacing the path with the correct path
          for your cluster.
 . Stop the ganeti daemons (``/etc/init.d/ganeti stop``) and kill any
          that remain alive (``pgrep ganeti`` and ``pkill ganeti``).
 . Remove the ganeti state directory (``rm -rf /var/lib/ganeti/*``),
          replacing the path with the correct path for your installation.
 . If using RBD, run ``rbd unmap /dev/rbdN`` to unmap the RBD disks.
          Then remove the RBD disk images used by Ganeti, identified by their
          UUIDs (``rbd rm uuid.rbd.diskN``).
       On the master node, remove the cluster from the master-netdev (usually
       ``xen-br0`` for bridged mode, otherwise ``eth0`` or similar), by running
       ``ip a del $clusterip/32 dev xen-br0`` (use the correct cluster ip and
       network device name).
       At this point, the machines are ready for a cluster creation; in case
       you want to remove Ganeti completely, you need to also undo some of the
       SSH changes and log directories:
       - ``rm -rf /var/log/ganeti /srv/ganeti`` (replace with the correct
         paths)
       - remove from ``/root/.ssh`` the keys that Ganeti added (check the
         ``authorized_keys`` and ``id_dsa`` files)
       - regenerate the host's SSH keys (check the OpenSSH startup scripts)
       - uninstall Ganeti
       Otherwise, if you plan to re-create the cluster, you can just go ahead
       and rerun ``gnt-cluster init``.
       Replacing the SSH and SSL keys
       ++++++++++++++++++++++++++++++
       Ganeti uses both SSL and SSH keys, and actively modifies the SSH keys on
       the nodes.  As result, in order to replace these keys, a few extra steps
       need to be followed: :doc:`cluster-keys-replacement`
       Monitoring the cluster
       ----------------------
       Starting with Ganeti 2.8, a monitoring daemon is available, providing
       information about the status and the performance of the system.
       The monitoring daemon runs on every node, listening on TCP port 1815. Each
       instance of the daemon provides information related to the node it is running
       on.
       .. include:: monitoring-query-format.rst
       Tags handling
       -------------
       The tags handling (addition, removal, listing) is similar for all the
       objects that support it (instances, nodes, and the cluster).
       Limitations
       +++++++++++
       Note that the set of characters present in a tag and the maximum tag
       length are restricted. Currently the maximum length is 128 characters,
       there can be at most 4096 tags per object, and the set of characters is
       comprised by alphanumeric characters and additionally ``.+*/:@-``.
       Operations
       ++++++++++
       Tags can be added via ``add-tags``::
         $ gnt-instance add-tags %INSTANCE% %a% %b% %c%
         $ gnt-node add-tags %INSTANCE% %a% %b% %c%
         $ gnt-cluster add-tags %a% %b% %c%
       The above commands add three tags to an instance, to a node and to the
       cluster. Note that the cluster command only takes tags as arguments,
       whereas the node and instance commands first required the node and
       instance name.
       Tags can also be added from a file, via the ``--from=FILENAME``
       argument. The file is expected to contain one tag per line.
       Tags can also be remove via a syntax very similar to the add one::
         $ gnt-instance remove-tags %INSTANCE% %a% %b% %c%
       And listed via::
         $ gnt-instance list-tags
         $ gnt-node list-tags
         $ gnt-cluster list-tags
       Global tag search
       +++++++++++++++++
       It is also possible to execute a global search on the all tags defined
       in the cluster configuration, via a cluster command::
         $ gnt-cluster search-tags %REGEXP%
       The parameter expected is a regular expression (see
       :manpage:`regex(7)`). This will return all tags that match the search,
       together with the object they are defined in (the names being show in a
       hierarchical kind of way)::
         $ gnt-cluster search-tags %o%
         /cluster foo
         /instances/instance1 owner:bar
       Autorepair
       ----------
       The tool ``harep`` can be used to automatically fix some problems that are
       present in the cluster.
       It is mainly meant to be regularly and automatically executed
       as a cron job. This is quite evident by considering that, when executed, it does
       not immediately fix all the issues of the instances of the cluster, but it
       cycles the instances through a series of states, one at every ``harep``
       execution. Every state performs a step towards the resolution of the problem.
       This process goes on until the instance is brought back to the healthy state,
       or the tool realizes that it is not able to fix the instance, and
       therefore marks it as in failure state.
       Allowing harep to act on the cluster
       ++++++++++++++++++++++++++++++++++++
       By default, ``harep`` checks the status of the cluster but it is not allowed to
       perform any modification. Modification must be explicitly allowed by an
       appropriate use of tags. Tagging can be applied at various levels, and can
       enable different kinds of autorepair, as hereafter described.
       All the tags that authorize ``harep`` to perform modifications follow this
       syntax::
         ganeti:watcher:autorepair:<type>
       where ``<type>`` indicates the kind of intervention that can be performed. Every
       possible value of ``<type>`` includes at least all the authorization of the
       previous one, plus its own. The possible values, in increasing order of
       severity, are:
       - ``fix-storage`` allows a disk replacement or another operation that
         fixes the instance backend storage without affecting the instance
         itself. This can for example recover from a broken drbd secondary, but
         risks data loss if something is wrong on the primary but the secondary
         was somehow recoverable.
       - ``migrate`` allows an instance migration. This can recover from a
         drained primary, but can cause an instance crash in some cases (bugs).
       - ``failover`` allows instance reboot on the secondary. This can recover
         from an offline primary, but the instance will lose its running state.
       - ``reinstall`` allows disks to be recreated and an instance to be
         reinstalled. This can recover from primary&secondary both being
         offline, or from an offline primary in the case of non-redundant
         instances. It causes data loss.
       These autorepair tags can be applied to a cluster, a nodegroup or an instance,
       and will act where they are applied and to everything in the entities sub-tree
       (e.g. a tag applied to a nodegroup will apply to all the instances contained in
       that nodegroup, but not to the rest of the cluster).
       If there are multiple ``ganeti:watcher:autorepair:<type>`` tags in an
       object (cluster, node group or instance), the least destructive tag
       takes precedence. When multiplicity happens across objects, the nearest
       tag wins. For example, if in a cluster with two instances, *I1* and
       *I2*, *I1* has ``failover``, and the cluster itself has both
       ``fix-storage`` and ``reinstall``, *I1* will end up with ``failover``
       and *I2* with ``fix-storage``.
       Limiting harep
       ++++++++++++++
       Sometimes it is useful to stop harep from performing its task temporarily,
       and it is useful to be able to do so without distrupting its configuration, that
       is, without removing the authorization tags. In order to do this, suspend tags
       are provided.
       Suspend tags can be added to cluster, nodegroup or instances, and act on the
       entire entities sub-tree. No operation will be performed by ``harep`` on the
       instances protected by a suspend tag. Their syntax is as follows::
         ganeti:watcher:autorepair:suspend[:<timestamp>]
       If there are multiple suspend tags in an object, the form without timestamp
       takes precedence (permanent suspension); or, if all object tags have a
       timestamp, the one with the highest timestamp.
       Tags with a timestamp will be automatically removed when the time indicated by
       the timestamp is passed. Indefinite suspension tags have to be removed manually.
       Result reporting
       ++++++++++++++++
       Harep will report about the result of its actions both through its CLI, and by
       adding tags to the instances it operated on. Such tags will follow the syntax
       hereby described::
         ganeti:watcher:autorepair:result:<type>:<id>:<timestamp>:<result>:<jobs>
       If this tag is present a repair of type ``type`` has been performed on
       the instance and has been completed by ``timestamp``. The result is
       either ``success``, ``failure`` or ``enoperm``, and jobs is a
       *+*-separated list of jobs that were executed for this repair.
       An ``enoperm`` result is an error state due to permission problems. It
       is returned when the repair cannot proceed because it would require to perform
       an operation that is not allowed by the ``ganeti:watcher:autorepair:<type>`` tag
       that is defining the instance autorepair permissions.
       NB: if an instance repair ends up in a failure state, it will not be touched
       again by ``harep`` until it has been manually fixed by the system administrator
       and the ``ganeti:watcher:autorepair:result:failure:*`` tag has been manually
       removed.
       Job operations
       --------------
       The various jobs submitted by the instance/node/cluster commands can be
       examined, canceled and archived by various invocations of the
       ``gnt-job`` command.
       First is the job list command::
         $ gnt-job list
 success INSTANCE_QUERY_DATA
 success CLUSTER_VERIFY_DISKS
 success CLUSTER_REPAIR_DISK_SIZES
 error   CLUSTER_RENAME(cluster.example.com)
 success CLUSTER_REDIST_CONF
 success INSTANCE_REBOOT(instance1.example.com)
       More detailed information about a job can be found via the ``info``
       command::
         $ gnt-job info %17776%
         Job ID: 17776
           Status: error
           Received:         2009-10-25 23:18:02.180569
           Processing start: 2009-10-25 23:18:02.200335 (delta 0.019766s)
           Processing end:   2009-10-25 23:18:02.279743 (delta 0.079408s)
           Total processing time: 0.099174 seconds
           Opcodes:
             OP_CLUSTER_RENAME
               Status: error
               Processing start: 2009-10-25 23:18:02.200335
               Processing end:   2009-10-25 23:18:02.252282
               Input fields:
                 name: cluster.example.com
               Result:
                 OpPrereqError
                 [Neither the name nor the IP address of the cluster has changed]
               Execution log:
       During the execution of a job, it's possible to follow the output of a
       job, similar to the log that one get from the ``gnt-`` commands, via the
       watch command::
         $ gnt-instance add --submit … %instance1%
         JobID: 17818
         $ gnt-job watch %17818%
         Output from job 17818 follows
         -----------------------------
         Mon Oct 26 00:22:48 2009  - INFO: Selected nodes for instance instance1 via iallocator dumb: node1, node2
         Mon Oct 26 00:22:49 2009 * creating instance disks...
         Mon Oct 26 00:22:52 2009 adding instance instance1 to cluster config
         Mon Oct 26 00:22:52 2009  - INFO: Waiting for instance instance1 to sync disks.
         …
         Mon Oct 26 00:23:03 2009 creating os for instance instance1 on node node1
         Mon Oct 26 00:23:03 2009 * running the instance OS create scripts...
         Mon Oct 26 00:23:13 2009 * starting instance...
+        $
       This is useful if you need to follow a job's progress from multiple
       terminals.
       A job that has not yet started to run can be canceled::
         $ gnt-job cancel %17810%
       But not one that has already started execution::
         $ gnt-job cancel %17805%
         Job 17805 is no longer waiting in the queue
       There are two queues for jobs: the *current* and the *archive*
       queue. Jobs are initially submitted to the current queue, and they stay
       in that queue until they have finished execution (either successfully or
       not). At that point, they can be moved into the archive queue using e.g.
       ``gnt-job autoarchive all``. The ``ganeti-watcher`` script will do this
       automatically 6 hours after a job is finished. The ``ganeti-cleaner``
       script will then remove archived the jobs from the archive directory
       after three weeks.
       Note that ``gnt-job list`` only shows jobs in the current queue.
       Archived jobs can be viewed using ``gnt-job info <id>``.
       Special Ganeti deployments
       --------------------------
       Since Ganeti 2.4, it is possible to extend the Ganeti deployment with
       two custom scenarios: Ganeti inside Ganeti and multi-site model.
       Running Ganeti under Ganeti
       +++++++++++++++++++++++++++
       It is sometimes useful to be able to use a Ganeti instance as a Ganeti
       node (part of another cluster, usually). One example scenario is two
       small clusters, where we want to have an additional master candidate
       that holds the cluster configuration and can be used for helping with
       the master voting process.
       However, these Ganeti instance should not host instances themselves, and
       should not be considered in the normal capacity planning, evacuation
       strategies, etc. In order to accomplish this, mark these nodes as
       non-``vm_capable``::
         $ gnt-node modify --vm-capable=no %node3%
       The vm_capable status can be listed as usual via ``gnt-node list``::
         $ gnt-node list -oname,vm_capable
         Node  VMCapable
         node1 Y
         node2 Y
         node3 N
       When this flag is set, the cluster will not do any operations that
       relate to instances on such nodes, e.g. hypervisor operations,
       disk-related operations, etc. Basically they will just keep the ssconf
       files, and if master candidates the full configuration.
       Multi-site model
       ++++++++++++++++
       If Ganeti is deployed in multi-site model, with each site being a node
       group (so that instances are not relocated across the WAN by mistake),
       it is conceivable that either the WAN latency is high or that some sites
       have a lower reliability than others. In this case, it doesn't make
       sense to replicate the job information across all sites (or even outside
       of a “central” node group), so it should be possible to restrict which
       nodes can become master candidates via the auto-promotion algorithm.
       Ganeti 2.4 introduces for this purpose a new ``master_capable`` flag,
       which (when unset) prevents nodes from being marked as master
       candidates, either manually or automatically.
       As usual, the node modify operation can change this flag::
         $ gnt-node modify --auto-promote --master-capable=no %node3%
         Fri Jan  7 06:23:07 2011  - INFO: Demoting from master candidate
         Fri Jan  7 06:23:08 2011  - INFO: Promoted nodes to master candidate role: node4
         Modified node node3
          - master_capable -> False
          - master_candidate -> False
       And the node list operation will list this flag::
         $ gnt-node list -oname,master_capable %node1% %node2% %node3%
         Node  MasterCapable
         node1 Y
         node2 Y
         node3 N
       Note that marking a node both not ``vm_capable`` and not
       ``master_capable`` makes the node practically unusable from Ganeti's
       point of view. Hence these two flags should be used probably in
       contrast: some nodes will be only master candidates (master_capable but
       not vm_capable), and other nodes will only hold instances (vm_capable
       but not master_capable).
       Ganeti tools
       ------------
       Beside the usual ``gnt-`` and ``ganeti-`` commands which are provided
       and installed in ``$prefix/sbin`` at install time, there are a couple of
       other tools installed which are used seldom but can be helpful in some
       cases.
       lvmstrap
       ++++++++
       The ``lvmstrap`` tool, introduced in :ref:`configure-lvm-label` section,
       has two modes of operation:
       - ``diskinfo`` shows the discovered disks on the system and their status
       - ``create`` takes all not-in-use disks and creates a volume group out
         of them
       .. warning:: The ``create`` argument to this command causes data-loss!
       cfgupgrade
       ++++++++++
       The ``cfgupgrade`` tools is used to upgrade between major (and minor)
       Ganeti versions, and to roll back. Point-releases are usually
       transparent for the admin.
       More information about the upgrade procedure is listed on the wiki at
       http://code.google.com/p/ganeti/wiki/UpgradeNotes.
       There is also a script designed to upgrade from Ganeti 1.2 to 2.0,
       called ``cfgupgrade12``.
       cfgshell
       ++++++++
       .. note:: This command is not actively maintained; make sure you backup
          your configuration before using it
       This can be used as an alternative to direct editing of the
       main configuration file if Ganeti has a bug and prevents you, for
       example, from removing an instance or a node from the configuration
       file.
       .. _burnin-label:
       burnin
       ++++++
       .. warning:: This command will erase existing instances if given as
          arguments!
       This tool is used to exercise either the hardware of machines or
       alternatively the Ganeti software. It is safe to run on an existing
       cluster **as long as you don't pass it existing instance names**.
       The command will, by default, execute a comprehensive set of operations
       against a list of instances, these being:
       - creation
       - disk replacement (for redundant instances)
       - failover and migration (for redundant instances)
       - move (for non-redundant instances)
       - disk growth
       - add disks, remove disk
       - add NICs, remove NICs
       - export and then import
       - rename
       - reboot
       - shutdown/startup
       - and finally removal of the test instances
       Executing all these operations will test that the hardware performs
       well: the creation, disk replace, disk add and disk growth will exercise
       the storage and network; the migrate command will test the memory of the
       systems. Depending on the passed options, it can also test that the
       instance OS definitions are executing properly the rename, import and
       export operations.
       sanitize-config
       +++++++++++++++
       This tool takes the Ganeti configuration and outputs a "sanitized"
       version, by randomizing or clearing:
       - DRBD secrets and cluster public key (always)
       - host names (optional)
       - IPs (optional)
       - OS names (optional)
       - LV names (optional, only useful for very old clusters which still have
         instances whose LVs are based on the instance name)
       By default, all optional items are activated except the LV name
       randomization. When passing ``--no-randomization``, which disables the
       optional items (i.e. just the DRBD secrets and cluster public keys are
       randomized), the resulting file can be used as a safety copy of the
       cluster config - while not trivial, the layout of the cluster can be
       recreated from it and if the instance disks have not been lost it
       permits recovery from the loss of all master candidates.
       move-instance
       +++++++++++++
       See :doc:`separate documentation for move-instance <move-instance>`.
       users-setup
       +++++++++++
       Ganeti can either be run entirely as root, or with every daemon running as
       its own specific user (if the parameters ``--with-user-prefix`` and/or
       ``--with-group-prefix`` have been specified at ``./configure``-time).
       In case split users are activated, they are required to exist on the system,
       and they need to belong to the proper groups in order for the access
       permissions to files and programs to be correct.
       The ``users-setup`` tool, when run, takes care of setting up the proper
       users and groups.
       When invoked without parameters, the tool runs in interactive mode, showing the
       list of actions it will perform and asking for confirmation before proceeding.
       Providing the ``--yes-do-it`` parameter to the tool prevents the confirmation
       from being asked, and the users and groups will be created immediately.
       .. TODO: document cluster-merge tool
       Other Ganeti projects
       ---------------------
       Below is a list (which might not be up-to-date) of additional projects
       that can be useful in a Ganeti deployment. They can be downloaded from
       the project site (http://code.google.com/p/ganeti/) and the repositories
       are also on the project git site (http://git.ganeti.org).
       NBMA tools
       ++++++++++
       The ``ganeti-nbma`` software is designed to allow instances to live on a
       separate, virtual network from the nodes, and in an environment where
       nodes are not guaranteed to be able to reach each other via multicasting
       or broadcasting. For more information see the README in the source
       archive.
       ganeti-htools
       +++++++++++++
       Before Ganeti version 2.5, this was a standalone project; since that
       version it is integrated into the Ganeti codebase (see
       :doc:`install-quick` for instructions on how to enable it). If you run
       an older Ganeti version, you will have to download and build it
       separately.
       For more information and installation instructions, see the README file
       in the source archive.
       .. vim: set textwidth=72 :
       .. Local Variables:
       .. mode: rst
       .. fill-column: 72
       .. End:

Synnefo » snf-ganeti » ganeti-local

root / doc / admin.rst @ ebbdde89