HRoller tool

This is a design document detailing the cluster maintenance scheduler, HRoller.

Current state and shortcomings

To enable automating cluster-wide reboots a new htool, called HRoller, was added to Ganeti starting from version 2.7. This tool helps parallelizing cluster offline maintenances by calculating which nodes are not both primary and secondary for a DRBD instance, and thus can be rebooted at the same time, when all instances are down.

The way this is done is documented in the hroller(1) manpage.

We would now like to perform online maintenance on the cluster by rebooting nodes after evacuating their primary instances (rolling reboots).

Proposed changes

New options

  • HRoller should be able to operate on single nodegroups (-G flag) or select its target node through some other mean (eg. via a tag, or a regexp). (Note that individual node selection is already possible via the -O flag, that makes hroller ignore a node altogether).
  • HRoller should handle non redundant instances: currently these are ignored but there should be a way to select its behavior between “it’s ok to reboot a node when a non-redundant instance is on it” or “skip nodes with non-redundant instances”. This will only be selectable globally, and not per instance.
  • Hroller will make sure to keep any instance which is up in its current state, via live migrations, unless explicitly overridden. The algorithm that will be used calculate the rolling reboot with live migrations is described below, and any override on considering the instance status will only be possible on the whole run, and not per-instance.

Calculating rolling maintenances

In order to perform rolling maintenance we need to migrate instances off the nodes before a reboot. How this can be done depends on the instance’s disk template and status:

Down instances

If an instance was shutdown when the maintenance started it will be considered for avoiding contemporary reboot of its primary and secondary nodes, but will not be considered as a target for the node evacuation. This allows avoiding needlessly moving its primary around, since it won’t suffer a downtime anyway.

Note that a node with non-redundant instances will only ever be considered good for rolling-reboot if these are down (or the checking of status is overridden) and an explicit option to allow it is set.


Each node must migrate all instances off to their secondaries, and then can either be rebooted, or the secondaries can be evacuated as well.

Since currently doing a replace-disks on DRBD breaks redundancy, it’s not any safer than temporarily rebooting a node with secondaries on them (citation needed). As such we’ll implement for now just the “migrate+reboot” mode, and focus later on replace-disks as well.

In order to do that we can use the following algorithm:

  1. Compute node sets that don’t contain both the primary and the secondary for any instance. This can be done already by the current hroller graph coloring algorithm: nodes are in the same set (color) if and only if no edge (instance) exists between them (see the hroller(1) manpage for more details).
  2. Inside each node set calculate subsets that don’t have any secondary node in common (this can be done by creating a graph of nodes that are connected if and only if an instance on both has the same secondary node, and coloring that graph)
  3. It is then possible to migrate in parallel all nodes in a subset created at step 2, and then reboot/perform maintenance on them, and migrate back their original primaries, which allows the computation above to be reused for each following subset without N+1 failures being triggered, if none were present before. See below about the actual execution of the maintenance.


All non-DRBD disk templates that can be migrated have no “secondary” concept. As such instances can be migrated to any node (in the same nodegroup). In order to do the job we can either:

  • Perform migrations on one node at a time, perform the maintenance on that node, and proceed (the node will then be targeted again to host instances automatically, as hail chooses targets for the instances between all nodes in a group. Nodes in different nodegroups can be handled in parallel.
  • Perform migrations on one node at a time, but without waiting for the first node to come back before proceeding. This allows us to continue, restricting the cluster, until no more capacity in the nodegroup is available, and then having to wait for some nodes to come back so that capacity is available again for the last few nodes.
  • Pre-Calculate sets of nodes that can be migrated together (probably with a greedy algorithm) and parallelize between them, with the migrate-back approach discussed for DRBD to perform the calculation only once.

Note that for non-DRBD disks that still use local storage (eg. RBD and plain) redundancy might break anyway, and nothing except the first algorithm might be safe. This perhaps would be a good reason to consider managing better RBD pools, if those are implemented on top of nodes storage, rather than on dedicated storage machines.

Future work

Hroller should become able to execute rolling maintenances, rather than just calculate them. For this to succeed properly one of the following must happen:

  • HRoller handles rolling maintenances that happen at the same time as unrelated cluster jobs, and thus recalculates the maintenance at each step
  • HRoller can selectively drain the cluster so it’s sure that only the rolling maintenance can be going on

DRBD nodes’ replace-disks‘ functionality should be implemented. Note that when we will support a DRBD version that allows multi-secondary this can be done safely, without losing replication at any time, by adding a temporary secondary and only when the sync is finished dropping the previous one.

Non-redundant (plain or file) instances should have a way to be moved off as well via plain storage live migration or gnt-instance move (which requires downtime).

If/when RBD pools can be managed inside Ganeti, care can be taken so that the pool is evacuated as well from a node before it’s put into maintenance. This is equivalent to evacuating DRBD secondaries.

Master failovers during the maintenance should be performed by hroller. This requires RPC/RAPI support for master failover. Hroller should also be modified to better support running on the master itself and continuing on the new master.