Proxmox Cluster file system (pmxcfs): Difference between revisions
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Proxmox Cluster file system (pmxcfs) is a database-driven file system for storing configuration files, replicated in real time on all nodes using corosync. We use this to store all PVE related configuration files. Although the file system stores all data inside a persistent database on disk, a copy of the data resides in RAM. That imposes restriction on the maximal size, which is currently 30MB. This is still enough to store the configuration of several thousand virtual machines. | Proxmox Cluster file system (pmxcfs) is a database-driven file system for storing configuration files, replicated in real time on all nodes using corosync. We use this to store all PVE related configuration files. Although the file system stores all data inside a persistent database on disk, a copy of the data resides in RAM. That imposes restriction on the maximal size, which is currently 30MB. This is still enough to store the configuration of several thousand virtual machines. | ||
Note that this restriction is also imposed from the real time replication through a totem ring protocol. | |||
=== Advantages === | === Advantages === |
Revision as of 07:29, 19 July 2016
Introduction
Proxmox Cluster file system (pmxcfs) is a database-driven file system for storing configuration files, replicated in real time on all nodes using corosync. We use this to store all PVE related configuration files. Although the file system stores all data inside a persistent database on disk, a copy of the data resides in RAM. That imposes restriction on the maximal size, which is currently 30MB. This is still enough to store the configuration of several thousand virtual machines. Note that this restriction is also imposed from the real time replication through a totem ring protocol.
Advantages
- seamless replication of all configuration to all nodes in real time
- provides strong consistency checks to avoid duplicate VM IDs
- read-only when a node looses quorum
- automatic updates of the corosync cluster configuration to all nodes.
POSIX Compatibility
The file system is based on fuse, so the behavior is POSIX like. But many feature are simply not implemented, because we do not need them:
- you can just generate normal files and directories, but no symbolic links, ...
- you can't rename non-empty directories (because this makes it easier to guarantee that VMIDs are unique).
- you can't change file permissions (permissions are based on path)
- O_EXCL creates were not atomic (like old NFS)
- O_TRUNC creates are not atomic (fuse restriction)
- ...
File access rights
All files/dirs are owned by user 'root' and have group 'www-data'. Only root has write permissions, but group 'www-data' can read most files. Files below the following paths:
/etc/pve/priv/ /etc/pve/nodes/${NAME}/priv/
are only accessible by root.
Technology
We use the Corosync Cluster Engine for cluster communication, and SQlite for the database file. The filesystem is implemented in user space using FUSE.
File system layout
The file system is mounted at:
/etc/pve
Files
corosync.conf => corosync/cman cluster configuration file (previous to PVE 4.x this file was called cluster.conf) storage.cfg => PVE storage configuration user.cfg => PVE access control configuration (users/groups/...) domains.cfg => PVE Authentication domains authkey.pub => public key used by ticket system
priv/shadow.cfg => shadow password file priv/authkey.key => private key used by ticket system
nodes/${NAME}/pve-ssl.pem => public ssl key for web server nodes/${NAME}/priv/pve-ssl.key => private ssl key nodes/${NAME}/qemu-server/${VMID}.conf => VM configuration data for KVM VMs nodes/${NAME}/openvz/${VMID}.conf => VM configuratin data for OpenVZ containers
Symbolic links
local => nodes/${LOCALNAME} qemu-server => nodes/${LOCALNAME}/qemu-server/ openvz => nodes/${LOCALNAME}/openvz/
Special status files for debugging (JSON)
.version => file versions (to detect file modifications) .members => Info about cluster members .vmlist => List of all VMs .clusterlog => Cluster log (last 50 entries) .rrd => RRD data (most recent entries)
Enable/Disable debugging =
# enable verbose syslog messages echo "1" >/etc/pve/.debug
# disable verbose syslog messages echo "0" >/etc/pve/.debug
Recovery
If you have major problems with your Proxmox VE host, e.g. hardware issues, it could be helpful to just copy the pmxcfs database file /var/lib/pve-cluster/config.db and move it to a new Proxmox VE host. On the new host (with nothing running), you need to stop the pve-cluster service and replace the config.db file (needed permissions : 600). Second, adapt /etc/hostname and /etc/hosts according to the lost Proxmox VE host, then reboot and check. (And don´t forget your VM/CT data)
Remove Cluster configuration
The recommended way is to reinstall the node after you removed it from your cluster. This makes sure that all secret cluster/ssh keys and any shared configuration data is destroyed.
I some cases, you might prefer to put a node back to local mode without reinstall, which is described here:
- stop the cluster file system in /etc/pve/
# service pve-cluster stop
or if you use PVE 4.0 and newer
# systemctl stop pve-cluster
- start it again but forcing local mode
# pmxcfs -l
- remove the cluster config
# rm -f /etc/pve/cluster.conf /etc/pve/corosync.conf # rm -f /etc/cluster/cluster.conf /etc/corosync/corosync.conf # rm /var/lib/pve-cluster/corosync.authkey
- stop the cluster file system again
# # on PVE 3.4 and earlier # service pve-cluster stop # # on PVE 4.0 and newer # systemctl stop pve-cluster
- you may have to delete the lockfile of the cluster filesystem:
# rm /var/lib/pve-cluster/.pmxcfs.lockfile
- restart pve services (or reboot)
on PVE 3.4 and older:
# service pve-cluster start # service pvedaemon restart # service pveproxy restart # service pvestatd restart
on pve 4.0 and newer
# systemctl start pve-cluster # systemctl restart pvedaemon # systemctl restart pveproxy # systemctl restart pvestatd
Source code
The source code is available here.