.ci | ||
csi | ||
deploy/charts/rawfile-csi | ||
orchestrator | ||
protos | ||
templates | ||
.dockerignore | ||
.drone.yml | ||
.gitignore | ||
.travis.yml | ||
bd2fs.py | ||
CODE_OF_CONDUCT.md | ||
consts.py | ||
declarative.py | ||
Dockerfile | ||
fs_util.py | ||
GOVERNANCE.md | ||
LICENSE | ||
MAINTAINERS | ||
metrics.py | ||
rawfile_servicer.py | ||
rawfile_util.py | ||
rawfile.py | ||
README.md | ||
remote.py | ||
requirements.in | ||
requirements.txt | ||
SECURITY.md | ||
util.py | ||
volume_schema.py |
RawFilePV
Kubernetes LocalPVs on Steroids
Prerequisite
- Kubernetes: 1.21+
Install
helm install -n kube-system rawfile-csi ./deploy/charts/rawfile-csi/
Usage
Create a StorageClass
with your desired options:
apiVersion: storage.k8s.io/v1
kind: StorageClass
metadata:
name: my-sc
provisioner: rawfile.csi.openebs.io
reclaimPolicy: Delete
volumeBindingMode: WaitForFirstConsumer
allowVolumeExpansion: true
Features
- Direct I/O: Near-zero disk performance overhead
- Dynamic provisioning
- Enforced volume size limit
- Access Modes
- ReadWriteOnce
ReadOnlyManyReadWriteMany
- Volume modes
Filesystem
modeBlock
mode
- Volume metrics
- Supports fsTypes:
ext4
,btrfs
,xfs
- Online expansion: If fs supports it (e.g. ext4, btrfs, xfs)
- Online shrinking: If fs supports it (e.g. btrfs)
- Offline expansion/shrinking
- Ephemeral inline volume
- Filesystem-level snapshots:
btrfs
supported
Motivation
One might have a couple of reasons to consider using node-based (rather than network-based) storage solutions:
- Performance: Almost no network-based storage solution can keep up with baremetal disk performance in terms of IOPS/latency/throughput combined. And you’d like to get the best out of the SSD you’ve got!
- On-premise Environment: You might not be able to afford the cost of upgrading all your networking infrastructure, to get the best out of your network-based storage solution.
- Complexity: Network-based solutions are distributed systems. And distributed systems are not easy! You might want to have a system that is easier to understand and to reason about. Also, with less complexity, you can fix unpredicted issues more easily.
Using node-based storage has come a long way since k8s was born. Right now, OpenEBS’s hostPath makes it pretty easy to automatically provision hostPath PVs and use them in your workloads. There are known limitations though:
- You can’t monitor volume usage: There are hacky workarounds to run “du” regularly, but that could prove to be a performance killer, since it could put a lot of burden on your CPU and cause your filesystem cache to fill up. Not really good for a production workload.
- You can’t enforce hard limits on your volume’s size: Again, you can hack your way around it, with the same caveats.
- You are stuck with whatever filesystem your kubelet node is offering
- You can’t customize your filesystem:
All these issues stem from the same root cause: hostPath/LocalPVs are simple bind-mounts from the host filesystem into the pod.
The idea here is to use a single file as the block device, using Linux’s loop, and create a volume based on it. That way:
- You can monitor volume usage by running df in
O(1)
since devices are mounted separately. - The size limit is enforced by the operating system, based on the backing file size.
- Since volumes are backed by different files, each file could be formatted using different filesystems, and/or customized with different filesystem options.