Ceph
PLEASE NOTE: This document applies to v0.9 version and not to the latest stable release v1.8
Documentation for other releases can be found by using the version selector in the top right of any doc page.Advanced Cluster Configuration
These examples show how to perform advanced configuration tasks on your Rook storage cluster.
- Use custom Ceph user and secret for mounting
- Log Collection
- OSD Information
- Separate Storage Groups
- Configuring Pools
- Custom ceph.conf Settings
- OSD CRUSH Settings
- OSD Dedicated Network
- Phantom OSD Removal
Prerequisites
Most of the examples make use of the ceph
client command. A quick way to use
the Ceph client suite is from a Rook Toolbox container.
The Kubernetes based examples assume Rook OSD pods are in the rook-ceph
namespace.
If you run them in a different namespace, modify kubectl -n rook-ceph [...]
to fit
your situation.
Use custom Ceph user and secret for mounting
NOTE For extensive info about creating Ceph users, consult the Ceph documentation: http://docs.ceph.com/docs/mimic/rados/operations/user-management/#add-a-user. Using a custom Ceph user and secret can be done for filesystem and block storage.
Create a custom user in Ceph with read-write access in the /bar
directory on CephFS (For Ceph Mimic or newer, use data=POOL_NAME
instead of pool=POOL_NAME
):
ceph auth get-or-create-key client.user1 mon 'allow r' osd 'allow rw tag cephfs pool=YOUR_FS_DATA_POOL' mds 'allow r, allow rw path=/bar'
The command will return a Ceph secret key, this key should be added as a secret in Kubernetes like this:
kubectl create secret generic ceph-user1-secret --from-literal=key=YOUR_CEPH_KEY
NOTE This secret with the same name must be created in each namespace where the StorageClass will be used. In addition to this Secret you must create a RoleBinding to allow the Rook Ceph agent to get the secret from each namespace. The RoleBinding is optional if you are using a ClusterRoleBinding for the Rook Ceph agent secret access. A ClusterRole which contains the permissions which are needed and used for the Bindings are shown as an example after the next step.
On a StorageClass parameters
and/or flexvolume Volume entry options
set the following options:
mountUser: user1
mountSecret: ceph-user1-secret
If you want the Rook Ceph agent to require a mountUser
and mountSecret
to be set in StorageClasses using Rook, you must set the environment variable AGENT_MOUNT_SECURITY_MODE
to Restricted
on the Rook Ceph operator Deployment.
For more information on using the Ceph feature to limit access to CephFS paths, see Ceph Documentation - Path Restriction.
ClusterRole
NOTE: When you are using the Helm chart to install the Rook Ceph operator and have set mountSecurityMode
to e.g., Restricted
, then the below ClusterRole has already been created for you.
This ClusterRole is needed no matter if you want to use a RoleBinding per namespace or a ClusterRoleBinding.
apiVersion: rbac.authorization.k8s.io/v1beta1
kind: ClusterRole
metadata:
name: rook-ceph-agent-mount
labels:
operator: rook
storage-backend: ceph
rules:
- apiGroups:
- ""
resources:
- secrets
verbs:
- get
RoleBinding
NOTE: You either need a RoleBinding in each namespace in which a mount secret resides in or create a ClusterRoleBinding with which the Rook Ceph agent has access to Kubernetes secrets in all namespaces.
Create the RoleBinding shown here in each namespace the Rook Ceph agent should read secrets for mounting.
The RoleBinding subjects
’ namespace
must be the one the Rook Ceph agent runs in (default rook-ceph-system
).
Replace namespace: name-of-namespace-with-mountsecret
according to the name of all namespaces a mountSecret
can be in.
kind: RoleBinding
apiVersion: rbac.authorization.k8s.io/v1beta1
metadata:
name: rook-ceph-agent-mount
namespace: name-of-namespace-with-mountsecret
labels:
operator: rook
storage-backend: ceph
roleRef:
apiGroup: rbac.authorization.k8s.io
kind: ClusterRole
name: rook-ceph-agent-mount
subjects:
- kind: ServiceAccount
name: rook-ceph-system
namespace: rook-ceph-system
ClusterRoleBinding
This ClusterRoleBinding only needs to be created once, as it covers the whole cluster.
kind: ClusterRoleBinding
apiVersion: rbac.authorization.k8s.io/v1beta1
metadata:
name: rook-ceph-agent-mount
labels:
operator: rook
storage-backend: ceph
roleRef:
apiGroup: rbac.authorization.k8s.io
kind: ClusterRole
name: rook-ceph-agent-mount
subjects:
- kind: ServiceAccount
name: rook-ceph-system
namespace: rook-ceph-system
Log Collection
All Rook logs can be collected in a Kubernetes environment with the following command:
(for p in $(kubectl -n rook-ceph get pods -o jsonpath='{.items[*].metadata.name}')
do
for c in $(kubectl -n rook-ceph get pod ${p} -o jsonpath='{.spec.containers[*].name}')
do
echo "BEGIN logs from pod: ${p} ${c}"
kubectl -n rook-ceph logs -c ${c} ${p}
echo "END logs from pod: ${p} ${c}"
done
done
for i in $(kubectl -n rook-ceph-system get pods -o jsonpath='{.items[*].metadata.name}')
do
echo "BEGIN logs from pod: ${i}"
kubectl -n rook-ceph-system logs ${i}
echo "END logs from pod: ${i}"
done) | gzip > /tmp/rook-logs.gz
This gets the logs for every container in every Rook pod and then compresses them into a .gz
archive
for easy sharing. Note that instead of gzip
, you could instead pipe to less
or to a single text file.
OSD Information
Keeping track of OSDs and their underlying storage devices/directories can be difficult. The following scripts will clear things up quickly.
Kubernetes
# Get OSD Pods
# This uses the example/default cluster name "rook"
OSD_PODS=$(kubectl get pods --all-namespaces -l \
app=rook-ceph-osd,rook_cluster=rook-ceph -o jsonpath='{.items[*].metadata.name}')
# Find node and drive associations from OSD pods
for pod in $(echo ${OSD_PODS})
do
echo "Pod: ${pod}"
echo "Node: $(kubectl -n rook-ceph get pod ${pod} -o jsonpath='{.spec.nodeName}')"
kubectl -n rook-ceph exec ${pod} -- sh -c '\
for i in /var/lib/rook/osd*; do
[ -f ${i}/ready ] || continue
echo -ne "-$(basename ${i}) "
echo $(lsblk -n -o NAME,SIZE ${i}/block 2> /dev/null || \
findmnt -n -v -o SOURCE,SIZE -T ${i}) $(cat ${i}/type)
done|sort -V
echo'
done
The output should look something like this. Note that OSDs on the same node will show duplicate information.
Pod: osd-m2fz2
Node: node1.zbrbdl
-osd0 sda3 557.3G bluestore
-osd1 sdf3 110.2G bluestore
-osd2 sdd3 277.8G bluestore
-osd3 sdb3 557.3G bluestore
-osd4 sde3 464.2G bluestore
-osd5 sdc3 557.3G bluestore
Pod: osd-nxxnq
Node: node3.zbrbdl
-osd6 sda3 110.7G bluestore
-osd17 sdd3 1.8T bluestore
-osd18 sdb3 231.8G bluestore
-osd19 sdc3 231.8G bluestore
Pod: osd-tww1h
Node: node2.zbrbdl
-osd7 sdc3 464.2G bluestore
-osd8 sdj3 557.3G bluestore
-osd9 sdf3 66.7G bluestore
-osd10 sdd3 464.2G bluestore
-osd11 sdb3 147.4G bluestore
-osd12 sdi3 557.3G bluestore
-osd13 sdk3 557.3G bluestore
-osd14 sde3 66.7G bluestore
-osd15 sda3 110.2G bluestore
-osd16 sdh3 135.1G bluestore
Separate Storage Groups
By default Rook/Ceph puts all storage under one replication rule in the CRUSH Map which provides the maximum amount of storage capacity for a cluster. If you would like to use different storage endpoints for different purposes, you’ll have to create separate storage groups.
In the following example we will separate SSD drives from spindle-based drives, a common practice for those looking to target certain workloads onto faster (database) or slower (file archive) storage.
CRUSH Hierarchy
To see the CRUSH hierarchy of all your hosts and OSDs run:
ceph osd tree
Before we separate our disks into groups, our example cluster looks like this:
ID WEIGHT TYPE NAME UP/DOWN REWEIGHT PRIMARY-AFFINITY
-1 7.21828 root default
-2 0.94529 host node1
0 0.55730 osd.0 up 1.00000 1.00000
1 0.11020 osd.1 up 1.00000 1.00000
2 0.27779 osd.2 up 1.00000 1.00000
-3 1.22480 host node2
3 0.55730 osd.3 up 1.00000 1.00000
4 0.11020 osd.4 up 1.00000 1.00000
5 0.55730 osd.5 up 1.00000 1.00000
-4 1.22480 host node3
6 0.55730 osd.6 up 1.00000 1.00000
7 0.11020 osd.7 up 1.00000 1.00000
8 0.06670 osd.8 up 1.00000 1.00000
We have one root bucket default
that every host and OSD is under, so all of
these storage locations get pooled together for reads/writes/replication.
Let’s say that osd.1
, osd.3
, and osd.7
are our small SSD drives that we
want to use separately.
First we will create a new root
bucket called ssd
in our CRUSH map. Under
this new bucket we will add new host
buckets for each node that contains an
SSD drive so data can be replicated and used separately from the default HDD
group.
# Create a new tree in the CRUSH Map for SSD hosts and OSDs
ceph osd crush add-bucket ssd root
ceph osd crush add-bucket node1-ssd host
ceph osd crush add-bucket node2-ssd host
ceph osd crush add-bucket node3-ssd host
ceph osd crush move node1-ssd root=ssd
ceph osd crush move node2-ssd root=ssd
ceph osd crush move node3-ssd root=ssd
# Create a new rule for replication using the new tree
ceph osd crush rule create-simple ssd ssd host firstn
Secondly we will move the SSD OSDs into the new ssd
tree, under their
respective host
buckets:
ceph osd crush set osd.1 .1102 root=ssd host=node1-ssd
ceph osd crush set osd.3 .1102 root=ssd host=node2-ssd
ceph osd crush set osd.7 .1102 root=ssd host=node3-ssd
It’s important to note that the ceph osd crush set
command requires a weight
to be specified (our example uses .1102
). If you’d like to change their
weight you can do that here, otherwise be sure to specify their original weight
seen in the ceph osd tree
output.
So let’s look at our CRUSH tree again with these changes:
ID WEIGHT TYPE NAME UP/DOWN REWEIGHT PRIMARY-AFFINITY
-8 0.22040 root ssd
-5 0.11020 host node1-ssd
1 0.11020 osd.1 up 1.00000 1.00000
-6 0.11020 host node2-ssd
4 0.11020 osd.4 up 1.00000 1.00000
-7 0.11020 host node3-ssd
7 0.11020 osd.7 up 1.00000 1.00000
-1 7.21828 root default
-2 0.83509 host node1
0 0.55730 osd.0 up 1.00000 1.00000
2 0.27779 osd.2 up 1.00000 1.00000
-3 1.11460 host node2
3 0.55730 osd.3 up 1.00000 1.00000
5 0.55730 osd.5 up 1.00000 1.00000
-4 1.11460 host node3
6 0.55730 osd.6 up 1.00000 1.00000
8 0.55730 osd.8 up 1.00000 1.00000
Using Disk Groups With Pools
Now we have a separate storage group for our SSDs, but we can’t use that storage
until we associate a pool with it. The default group already has a pool called
rbd
in many cases. If you created a pool via CustomResourceDefinition,
it will use the default storage group as well.
Here’s how to create new pools:
# SSD backed pool with 128 (total) PGs
ceph osd pool create ssd 128 128 replicated ssd
Now all you need to do is create RBD images or Kubernetes StorageClass
es that
specify the ssd
pool to put it to use.
Configuring Pools
Placement Group Sizing
The general rules for deciding how many PGs your pool(s) should contain is:
- Less than 5 OSDs set pg_num to 128
- Between 5 and 10 OSDs set pg_num to 512
- Between 10 and 50 OSDs set pg_num to 1024
If you have more than 50 OSDs, you need to understand the tradeoffs and how to calculate the pg_num value by yourself. For calculating pg_num yourself please make use of the pgcalc tool
If you’re already using a pool it is generally safe to increase its PG count on-the-fly. Decreasing the PG count is not recommended on a pool that is in use. The safest way to decrease the PG count is to back-up the data, delete the pool, and recreate it. With backups you can try a few potentially unsafe tricks for live pools, documented here.
Deleting A Pool
Be warned that this deletes all data from the pool, so Ceph by default makes it somewhat difficult to do.
First you must inject arguments to the Mon daemons to tell them to allow the deletion of pools. In Rook Tools you can do this:
ceph tell mon.\* injectargs '--mon-allow-pool-delete=true'
Then to delete a pool, rbd
in this example, run:
ceph osd pool rm rbd rbd --yes-i-really-really-mean-it
Creating A Pool
# Create a pool called rbd with 1024 total PGs, using the default
# replication ruleset
ceph osd pool create rbd 1024 1024 replicated replicated_ruleset
replicated_ruleset
is the default CRUSH rule that replicates between the hosts
and OSDs in the default
root hierarchy.
Setting The Number Of Replicas
The size
setting of a pool tells the cluster how many copies of the data
should be kept for redundancy. By default the cluster will distribute these
copies between host
buckets in the CRUSH Map This can be set when creating a
pool via CustomResourceDefinition or after creation with ceph
.
So for example let’s change the size
of the rbd
pool to three:
ceph osd pool set rbd size 3
Now if you run ceph -s
you may see “recovery” operations and
PGs in “undersized” and other “unclean” states. The cluster is essentially
fixing itself since the number of replicas has been increased, and should go
back to “active/clean” state shortly, after data has been replicated between
hosts. When that’s done you will be able to lose two of your storage nodes and
still have access to all your data in that pool, since the CRUSH algorithm will
guarantee that at least one replica will still be available on another storage node.
Of course you will only have 1/3 the capacity as a tradeoff.
Setting PG Count
Be sure to read the placement group sizing section before changing the number of PGs.
# Set the number of PGs in the rbd pool to 512
ceph osd pool set rbd pg_num 512
Custom ceph.conf Settings
With Rook the full swath of Ceph settings are available to use on your storage cluster. When we supply Rook with a ceph.conf file those settings will be propagated to all Mon, OSD, MDS, and RGW daemons to use.
In this example we will set the default pool size
to two, and tell OSD
daemons not to change the weight of OSDs on startup.
WARNING: Modify Ceph settings carefully. You are leaving the sandbox tested by Rook. Changing the settings could result in unhealthy daemons or even data loss if used incorrectly.
Kubernetes
When the Rook Operator creates a cluster, a placeholder ConfigMap is created that will allow you to override Ceph configuration settings. When the daemon pods are started, the settings specified in this ConfigMap will be merged with the default settings generated by Rook.
The default override settings are blank. Cutting out the extraneous properties, we would see the following defaults after creating a cluster:
$ kubectl -n rook-ceph get ConfigMap rook-config-override -o yaml
kind: ConfigMap
apiVersion: v1
metadata:
name: rook-config-override
namespace: rook-ceph
data:
config: ""
To apply your desired configuration, you will need to update this ConfigMap. The next time the daemon pod(s) start, the settings will be merged with the default settings created by Rook.
kubectl -n rook-ceph edit configmap rook-config-override
Modify the settings and save. Each line you add should be indented from the config
property as such:
apiVersion: v1
kind: ConfigMap
metadata:
name: rook-config-override
namespace: rook-ceph
data:
config: |
[global]
osd crush update on start = false
osd pool default size = 2
Each daemon will need to be restarted where you want the settings applied:
- Mons: ensure all three mons are online and healthy before restarting each mon pod, one at a time
- OSDs: restart your the pods by deleting them, one at a time, and running
ceph -s
between each restart to ensure the cluster goes back to “active/clean” state. - RGW: the pods are stateless and can be restarted as needed
- MDS: the pods are stateless and can be restarted as needed
After the pod restart, your new settings should be in effect. Note that if you create
the ConfigMap in the rook
namespace before the cluster is even created
the daemons will pick up the settings at first launch.
The only validation of the settings done by Rook is whether the settings can be merged using the ini file format with the default settings created by Rook. Beyond that, the validity of the settings is your responsibility.
OSD CRUSH Settings
A useful view of the CRUSH Map is generated with the following command:
ceph osd tree
In this section we will be tweaking some of the values seen in the output.
OSD Weight
The CRUSH weight controls the ratio of data that should be distributed to each OSD. This also means a higher or lower amount of disk I/O operations for an OSD with higher/lower weight, respectively.
By default OSDs get a weight relative to their storage capacity, which maximizes overall cluster capacity by filling all drives at the same rate, even if drive sizes vary. This should work for most use-cases, but the following situations could warrant weight changes:
- Your cluster has some relatively slow OSDs or nodes. Lowering their weight can reduce the impact of this bottleneck.
- You’re using bluestore drives provisioned with Rook v0.3.1 or older. In this case you may notice OSD weights did not get set relative to their storage capacity. Changing the weight can fix this and maximize cluster capacity.
This example sets the weight of osd.0 which is 600GiB
ceph osd crush reweight osd.0 .600
OSD Primary Affinity
When pools are set with a size setting greater than one, data is replicated between nodes and OSDs. For every chunk of data a Primary OSD is selected to be used for reading that data to be sent to clients. You can control how likely it is for an OSD to become a Primary using the Primary Affinity setting. This is similar to the OSD weight setting, except it only affects reads on the storage device, not capacity or writes.
In this example we will make sure osd.0
is only selected as Primary if all
other OSDs holding replica data are unavailable:
ceph osd primary-affinity osd.0 0
OSD Dedicated Network
It is possible to configure ceph to leverage a dedicated network for the OSDs to communicate across. A useful overview is the CEPH Networks section of the Ceph documentation. If you declare a cluster network, OSDs will route heartbeat, object replication and recovery traffic over the cluster network. This may improve performance compared to using a single network.
Two changes are necessary to the configuration to enable this capability:
Use hostNetwork in the rook ceph cluster configuration
Enable the hostNetwork
setting in the Ceph Cluster CRD configuration.
For example,
network:
hostNetwork: true
Define the subnets to use for public and private OSD networks
Edit the rook-config-override
configmap to define the custom network
configuration:
kubectl -n rook-ceph edit configmap rook-config-override
In the editor, add a custom configuration to instruct ceph which subnet is the public network and which subnet is the private network. For example:
apiVersion: v1
data:
config: |
[global]
public network = 10.0.7.0/24
cluster network = 10.0.10.0/24
public addr = ""
cluster addr = ""
After applying the updated rook-config-override configmap, it will be necessary to restart the OSDs by deleting the OSD pods in order to apply the change. Restart the OSD pods by deleting them, one at a time, and running ceph -s between each restart to ensure the cluster goes back to “active/clean” state.
Phantom OSD Removal
If you have OSDs in which are not showing any disks, you can remove those “Phantom OSDs” by following the instructions below. To check for “Phantom OSDs”, you can run:
ceph osd tree
An example output looks like this:
ID CLASS WEIGHT TYPE NAME STATUS REWEIGHT PRI-AFF
-1 57.38062 root default
-13 7.17258 host node1.example.com
2 hdd 3.61859 osd.2 up 1.00000 1.00000
-7 0 host node2.example.com down 0 1.00000
The host node2.example.com
in the output has no disks, so it is most likely a “Phantom OSD”.
Now to remove it, use the ID in the first column of the output and replace <ID>
with it. In the example output above the ID would be -7
.
The commands are:
ceph osd out <ID>
ceph osd crush remove osd.<ID>
ceph auth del osd.<ID>
ceph osd rm <ID>
To recheck that the Phantom OSD got removed, re-run the following command and check if the OSD with the ID doesn’t show up anymore:
ceph osd tree