Ceph in Kolla¶
The out-of-the-box Ceph deployment requires 3 hosts with at least one block device on each host that can be dedicated for sole use by Ceph. However, with tweaks to the Ceph cluster you can deploy a healthy cluster with a single host and a single block device.
Requirements¶
- A minimum of 3 hosts for a vanilla deploy
- A minimum of 1 block device per host
Preparation¶
To prepare a disk for use as a Ceph OSD you must add a special partition label to the disk. This partition label is how Kolla detects the disks to format and bootstrap. Any disk with a matching partition label will be reformatted so use caution.
To prepare a filestore OSD as a storage drive, execute the following operations:
Warning
ALL DATA ON $DISK will be LOST! Where $DISK is /dev/sdb or something similar.
parted $DISK -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_BOOTSTRAP 1 -1
The following shows an example of using parted to configure /dev/sdb for
usage with Kolla.
parted /dev/sdb -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_BOOTSTRAP 1 -1
parted /dev/sdb print
Model: VMware, VMware Virtual S (scsi)
Disk /dev/sdb: 10.7GB
Sector size (logical/physical): 512B/512B
Partition Table: gpt
Number Start End Size File system Name Flags
1 1049kB 10.7GB 10.7GB KOLLA_CEPH_OSD_BOOTSTRAP
To prepare a bluestore OSD partition, execute the following operations:
parted $DISK -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_BOOTSTRAP_BS 1 -1
If only one device is offered, Kolla Ceph will create the bluestore OSD on the device. Kolla Ceph will create two partitions for OSD and block separately.
If more than one devices are offered for one bluestore OSD, Kolla Ceph will create partitions for block, block.wal and block.db according to the partition labels.
To prepare a bluestore OSD block partition, execute the following operations:
parted $DISK -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_BOOTSTRAP_BS_FOO_B 1 -1
To prepare a bluestore OSD block.wal partition, execute the following operations:
parted $DISK -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_BOOTSTRAP_BS_FOO_W 1 -1
To prepare a bluestore OSD block.db partition, execute the following operations:
parted $DISK -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_BOOTSTRAP_BS_FOO_D 1 -1
Kolla Ceph will handle the bluestore OSD according to the above up to four partition labels. In Ceph bluestore OSD, the block.wal and block.db partitions are not mandatory.
Note
In the case there are more than one devices in one bluestore OSD and there
are more than one bluestore OSD in one node, it is required to use suffixes
(_42, _FOO, _FOO42, ..). Kolla Ceph will gather all the
partition labels and deploy bluestore OSD on top of the devices which have
the same suffix in the partition label.
Using an external journal drive¶
Note
The section is only meaningful for Ceph filestore OSD.
The steps documented above created a journal partition of 5 GByte and a data partition with the remaining storage capacity on the same tagged drive.
It is a common practice to place the journal of an OSD on a separate journal drive. This section documents how to use an external journal drive.
Prepare the storage drive in the same way as documented above:
Warning
ALL DATA ON $DISK will be LOST! Where $DISK is /dev/sdb or something similar.
parted $DISK -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_BOOTSTRAP_FOO 1 -1
To prepare the journal external drive execute the following command:
parted $DISK -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_BOOTSTRAP_FOO_J 1 -1
Note
Use different suffixes (_42, _FOO, _FOO42, ..) to use different external
journal drives for different storage drives. One external journal drive can only
be used for one storage drive.
Note
The partition labels KOLLA_CEPH_OSD_BOOTSTRAP and KOLLA_CEPH_OSD_BOOTSTRAP_J
are not working when using external journal drives. It is required to use
suffixes (_42, _FOO, _FOO42, ..). If you want to setup only one
storage drive with one external journal drive it is also necessary to use a suffix.
Configuration¶
Edit the [storage] group in the inventory which contains the hostname
of the hosts that have the block devices you have prepped as shown above.
[storage]
controller
compute1
Enable Ceph in /etc/kolla/globals.yml:
enable_ceph: "yes"
Ceph RADOS Gateway¶
RadosGW is optional, enable it in /etc/kolla/globals.yml:
enable_ceph_rgw: "yes"
Note
By default RadosGW supports both Swift and S3 API, and it is not
completely compatible with Swift API. The option ceph_rgw_compatibility
in /etc/kolla/globals.yml can enable/disable the RadosGW
compatibility with Swift API completely. After changing the value, run the
“reconfigure“ command to enable.
RGW requires a healthy cluster in order to be successfully deployed. On initial
start up, RGW will create several pools. The first pool should be in an
operational state to proceed with the second one, and so on. So, in the case of
an all-in-one deployment, it is necessary to change the default number of
copies for the pools before deployment. Modify the file
/etc/kolla/config/ceph.conf and add the contents:
[global]
osd pool default size = 1
osd pool default min size = 1
NFS¶
NFS is an optional feature, you can enable it in /etc/kolla/globals.yml:
enable_ceph_nfs: "yes"
Note
If you are using Ubuntu, please enable Ceph NFS before using
kolla-ansible bootstrap-servers command - it will install required rpcbind
package.
Store type¶
Configure the Ceph store type in /etc/kolla/globals.yml, the default
value is bluestore in Rocky:
ceph_osd_store_type: "bluestore"
Recommendations¶
Placement groups¶
Regarding number of placement groups (PGs)
Kolla sets very conservative values for the number of PGs per pool (ceph_pool_pg_num and ceph_pool_pgp_num). This is in order to ensure the majority of users will be able to deploy Ceph out of the box. It is highly recommended to consult the official Ceph documentation regarding these values before running Ceph in any kind of production scenario.
Cluster Network¶
To build a high performance and secure Ceph Storage Cluster, the Ceph community
recommend the use of two separate networks: public network and cluster network.
Edit the /etc/kolla/globals.yml and configure the cluster_interface:
cluster_interface: "eth2"
For more details, see NETWORK CONFIGURATION REFERENCE of Ceph Documentation.
Using a Cache Tiering¶
An optional cache tiering can be deployed by formatting at least one cache device and enabling cache. tiering in the globals.yml configuration file.
To prepare a filestore OSD as a cache device, execute the following operations:
parted $DISK -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_CACHE_BOOTSTRAP 1 -1
Note
To prepare a bluestore OSD as a cache device, change the partition name in the above command to “KOLLA_CEPH_OSD_CACHE_BOOTSTRAP_BS”. The deployment of bluestore cache OSD is the same as bluestore OSD.
Enable the Ceph cache tier in /etc/kolla/globals.yml:
enable_ceph: "yes"
ceph_enable_cache: "yes"
# Valid options are [ forward, none, writeback ]
ceph_cache_mode: "writeback"
After this run the playbooks as you normally would, for example:
kolla-ansible deploy -i path/to/inventory
Setting up an Erasure Coded Pool¶
Erasure code is the new big thing from Ceph. Kolla has the ability to setup your Ceph pools as erasure coded pools. Due to technical limitations with Ceph, using erasure coded pools as OpenStack uses them requires a cache tier. Additionally, you must make the choice to use an erasure coded pool or a replicated pool (the default) when you initially deploy. You cannot change this without completely removing the pool and recreating it.
To enable erasure coded pools add the following options to your
/etc/kolla/globals.yml configuration file:
# A requirement for using the erasure-coded pools is you must setup a cache tier
# Valid options are [ erasure, replicated ]
ceph_pool_type: "erasure"
# Optionally, you can change the profile
#ceph_erasure_profile: "k=4 m=2 ruleset-failure-domain=host"
Managing Ceph¶
Check the Ceph status for more diagnostic information. The sample output below indicates a healthy cluster:
docker exec ceph_mon ceph -s
cluster:
id: f2ed6c00-c043-4e1c-81b6-07c512db26b1
health: HEALTH_OK
services:
mon: 1 daemons, quorum 172.16.31.121
mgr: poc12-01(active)
osd: 4 osds: 4 up, 4 in; 5 remapped pgs
data:
pools: 4 pools, 512 pgs
objects: 0 objects, 0 bytes
usage: 432 MB used, 60963 MB / 61395 MB avail
pgs: 512 active+clean
If Ceph is run in an all-in-one deployment or with less than three storage nodes, further configuration is required. It is necessary to change the default number of copies for the pool. The following example demonstrates how to change the number of copies for the pool to 1:
docker exec ceph_mon ceph osd pool set rbd size 1
All the pools must be modified if Glance, Nova, and Cinder have been deployed. An example of modifying the pools to have 2 copies:
for p in images vms volumes backups; do docker exec ceph_mon ceph osd pool set ${p} size 2; done
If using a cache tier, these changes must be made as well:
for p in images vms volumes backups; do docker exec ceph_mon ceph osd pool set ${p}-cache size 2; done
The default pool Ceph creates is named rbd. It is safe to remove this pool:
docker exec ceph_mon ceph osd pool delete rbd rbd --yes-i-really-really-mean-it
Troubleshooting¶
Deploy fails with ‘Fetching Ceph keyrings … No JSON object could be decoded’¶
If an initial deploy of Ceph fails, perhaps due to improper configuration or similar, the cluster will be partially formed and will need to be reset for a successful deploy.
In order to do this the operator should remove the ceph_mon_config volume from each Ceph monitor node:
ansible -i ansible/inventory/multinode \
-a 'docker volume rm ceph_mon_config' \
ceph-mon
Simple 3 Node Example¶
This example will show how to deploy Ceph in a very simple setup using 3 storage nodes. 2 of those nodes (kolla1 and kolla2) will also provide other services like control, network, compute, and monitoring. The 3rd (kolla3) node will only act as a storage node.
This example will only focus on the Ceph aspect of the deployment and assumes that you can already deploy a fully functional environment using 2 nodes that does not employ Ceph yet. So we will be adding to the existing multinode inventory file you already have.
Each of the 3 nodes are assumed to have two disk, /dev/sda (40GB)
and /dev/sdb (10GB). Size is not all that important… but for now make
sure each sdb disk are of the same size and are at least 10GB. This example
will use a single disk (/dev/sdb) for both Ceph data and journal. It will not
implement caching.
Here is the top part of the multinode inventory file used in the example environment before adding the 3rd node for Ceph:
[control]
# These hostname must be resolvable from your deployment host
kolla1.ducourrier.com
kolla2.ducourrier.com
[network]
kolla1.ducourrier.com
kolla2.ducourrier.com
[compute]
kolla1.ducourrier.com
kolla2.ducourrier.com
[monitoring]
kolla1.ducourrier.com
kolla2.ducourrier.com
[storage]
kolla1.ducourrier.com
kolla2.ducourrier.com
Configuration¶
To prepare the 2nd disk (/dev/sdb) of each nodes for use by Ceph you will need to add a partition label to it as shown below:
parted /dev/sdb -s -- mklabel gpt mkpart KOLLA_CEPH_OSD_BOOTSTRAP 1 -1
Make sure to run this command on each of the 3 nodes or the deployment will fail.
Next, edit the multinode inventory file and make sure the 3 nodes are listed
under [storage]. In this example I will add kolla3.ducourrier.com to the
existing inventory file:
[control]
# These hostname must be resolvable from your deployment host
kolla1.ducourrier.com
kolla2.ducourrier.com
[network]
kolla1.ducourrier.com
kolla2.ducourrier.com
[compute]
kolla1.ducourrier.com
kolla2.ducourrier.com
[monitoring]
kolla1.ducourrier.com
kolla2.ducourrier.com
[storage]
kolla1.ducourrier.com
kolla2.ducourrier.com
kolla3.ducourrier.com
It is now time to enable Ceph in the environment by editing the
/etc/kolla/globals.yml file:
enable_ceph: "yes"
enable_ceph_rgw: "yes"
enable_cinder: "yes"
glance_backend_file: "no"
glance_backend_ceph: "yes"
Deployment¶
Finally deploy the Ceph-enabled configuration:
kolla-ansible deploy -i path/to/inventory-file
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