Samba CTDB GlusterFS Cluster HowTo

From SambaWiki

Introduction

CTDB is a clustered database component in clustered Samba that provides a high-availability load-sharing CIFS server cluster.

The main functions of CTDB are:

  • Provide a clustered version of the TDB database with automatic rebuild/recovery of the databases upon node failures.
  • Monitor nodes in the cluster and services running on each node.
  • Manage a pool of public IP addresses that are used to provide services to clients. Alternatively, CTDB can be used with LVS.

Combined with a cluster filesystem CTDB provides a full high-availability (HA) environment for services such as clustered Samba, NFS and other services.

Setting up CTDB

After setting up the cluster filesystem you can set up a CTDB-cluster. To user CTDB you have to install the ctdb-package for your distribution. After installing the package with all it's dependencies you will find a directory /etc/ctdb. Inside tis directory you need some configuration files for CTDB.

Let's take a look at the files needed for configuring CTDB.

File Content
/etc/ctdb/ctdb.conf Basic configuration
/etc/ctdb/script.options Setting options for event-scripts
/etc/ctdb/nodes All IP-addresses of all nodes
/etc/ctdb/public_addresses Dynamic IP-addresses for all nodes

The ctdb.conf file

The ctdb.conf file has changed a lot from the old configuration style (< Samba 4.9). This file will no longer be used to configure the different services managed by CTDB. At the moment the only setting you have to do inside the file is setting up the recovery lock file. This file is used by all nodes to check if it's possible to lock files inside the cluster for exclusive use. If you don't use a recovery lock file your cluster can run into a split brain situation. By default the 'recovery lock' is NOT set. You should not use CTDB without a recovery lock unless you know what you are doing. The variable must point to a file inside your mounted gluster-volume. To use the recovery lock enter the following line into /etc/ctdb/ctdb.conf on both nodes:

recovery lock = /glusterfs/ctdb.lock

The file script.options

All the service CTDB will provide will be started via special scripts. In this file you can set options to the script. An example is shown in the script. There is as section for the service-script 50.samba.options named CTDB_SAMBA_SKIP_SHARE_CHECK this option by default is set to yes. This means, every time you create a new share CTDB will check if the path exists, if not CTDB will stop. But if you use the vfs-module glusterfs you will have no local path in the share-configuration. The share points to a directory on your gluster-volume, so CTDB can`t check the path. So if you going to use glusterfs you must set this option for Samba to no.

Because you can set all options to all service-scripts in this file, you don't have to change any of the service-scripts. You will find more information on all options in the manpage man ctdb-script.options.

The file nodes

CTDB must know all hosts belonging to it's cluster, in this file you have to put all IPs from the heartbeat network of all nodes. This file must have the same content on all nodes. Just put the two IPs from the two nodes into the file. Here you see the content of the file.

192.168.57.42
192.168.57.43

In most distributions the file does'n exists, you have to create it.

The file public_addresses

Every time CTDB starts it will provide an IP-address to all nodes in the CTDB-Cluster, this must be an IP-address from the production network.

After starting the cluster, CTDB will take care of those IP-addresses and will give an IP-address of this list to every CTDB-node. If a CTDB-node crashes CTDB will assign the IP-address, from the crashed node, to another CTDB-node. So every IP-address from this file is always assigned to on of the nodes.

CTDB is doing the failover for the services. If one node fails the IP-address will switch to one of the remaining nodes. All clients will then reconnect to this node. That`s possible because all nodes have all session-information of all clients.

For each node you need a public_addresses-file. The files can be different on the nodes, depending to which subnet you would like to assign the node. The example uses just one subnet, so both nodes have identical public_addresses-files. Here you see the content of the file:

192.168.56.101/24 enp0s8
192.168.56.102/24 enp0s8

Starting CTDB the first time

Now you have configured the CTDB-service on both nodes, then you will be ready for the first start. To see what will happened during the start you can open another terminal and start tail -f /var/log/ctdb/ctdb.log to see the messages. First start one node with systemctl restart ctdb, look at the log-messages and then start the second node and still keep an eye on the log.

2020/02/11 17:32:53.778637 ctdbd[1926]: monitor event OK - node re-enabled
2020/02/11 17:32:53.778831 ctdbd[1926]: Node became HEALTHY. Ask recovery master to reallocate IPs 
2020/02/11 17:32:53.779152 ctdb-recoverd[1966]: Node 0 has changed flags - now 0x0  was 0x2
2020/02/11 17:32:54.575970 ctdb-recoverd[1966]: Unassigned IP 192.168.56.102 can be served by this node
2020/02/11 17:32:54.576047 ctdb-recoverd[1966]: Unassigned IP 192.168.56.101 can be served by this node
2020/02/11 17:32:54.576254 ctdb-recoverd[1966]: Trigger takeoverrun
2020/02/11 17:32:54.576780 ctdb-recoverd[1966]: Takeover run starting
2020/02/11 17:32:54.594527 ctdbd[1926]: Takeover of IP 192.168.56.102/24 on interface enp0s8
2020/02/11 17:32:54.595551 ctdbd[1926]: Takeover of IP 192.168.56.101/24 on interface enp0s8
2020/02/11 17:32:54.843175 ctdb-recoverd[1966]: Takeover run completed successfully

Here you can see, that the node has taken both dynamic IP-addresses, you can check this with ip a l enp0s8.

Before you start the second node, take a look at the CTDB-status with ctdb status. You will see that the first node you have just started has the status OK, the other node has the status DISCONNECTED|UNHEALTHY|INACTIVE.

root@cluster-01:~# ctdb status
Number of nodes:2
pnn:0 192.168.57.42    OK (THIS NODE)
pnn:1 192.168.57.43    DISCONNECTED|UNHEALTHY|INACTIVE
Generation:1636031659
Size:1
hash:0 lmaster:0
Recovery mode:NORMAL (0)
Recovery master:0

Now you can start CTDB on the second node with systemctl restart ctdb. Inside the log on the first node you will see the message that the takeover was successfully. Next you will see the last lines from the log:

2020/02/11 17:51:49.964668 ctdb-recoverd[6598]: Takeover run starting
2020/02/11 17:51:50.004374 ctdb-recoverd[6598]: Takeover run completed successfully
2020/02/11 17:51:59.061780 ctdb-recoverd[6598]: Reenabling recoveries after timeout
2020/02/11 17:52:04.632267 ctdb-recoverd[6598]: Node 1 has changed flags - now 0x0  was 0x2
2020/02/11 17:52:04.989395 ctdb-recoverd[6598]: Takeover run starting
2020/02/11 17:52:05.008763 ctdbd[6554]: Release of IP 192.168.56.102/24 on interface enp0s8  node:1
2020/02/11 17:52:05.154588 ctdb-recoverd[6598]: Takeover run completed successfully

If you see a lot of messages as in the next listing, check if the gluster-volume is mounted correctly and if the recovery lock-option in /etc/ctdb/ctdb.conf is set correctly:

2020/02/11 17:51:00.883523 ctdbd[6554]: CTDB_WAIT_UNTIL_RECOVERED
2020/02/11 17:51:00.883630 ctdbd[6554]: ../../ctdb/server/ctdb_monitor.c:324 wait for pending recoveries to end. Wait one more second.


A look at the status will show both nodes OK, as you can see in ctsdb status

root@cluster-01:~# ctdb status
Number of nodes:2
pnn:0 192.168.57.42    OK (THIS NODE)
pnn:1 192.168.57.43    OK
Generation:101877096
Size:2
hash:0 lmaster:0
hash:1 lmaster:1
Recovery mode:NORMAL (0)
Recovery master:0

Whenever you stop a node, the other node will takeover the IP-address assigned by CTDB. Now CTDB is running, but you still have no service configured. You should only continue configuring the services if both nodes are healthy.

As a test you can stop CTDB on one node and you will see, that the other node will get the IP from the stopped node. As soon as you restart the node, one of the IP-addresses will be assigned to the node and both nodes will have the status OK again.

The next step will be setting up samba.

Configuring Samba

In this part you see how to set up a Samba-cluster to provide fileservices to Windows- and Linux-clients. The cluster will br joined into a Samba Active Directory-domain and create shares. There will be three different techniques described to serve the shares to the clients:

  • Using the local mounted gluster-volume to create the share.
  • Using the vfs-module glusterfs to directly point to the volume on the gluster-cluster without mounting the volume on the local system.
  • Using the new vfs-module glusterfs_fuse.

Joining the domain

To join the cluster to the domain you have to do the following steps:

  • Creating the DNS-records
  • Configure Samba via registry
  • Join the cluster

Creating the DNS-records

To join the domain, the first step should be creating the DNS-entries for the cluster. If you already have a reverse zone configured you can skip the command to create the reverse zone.

root@addc-01:~# kinit administrator
administrator@EXAMPLE.NET's Password:********

root@addc-01:~# samba-tool dns zonecreate addc-01 56.168.192.in-addr.arpa -k yes
Zone 56.168.192.in-addr.arpa created successfully

root@addc-01:~# systemctl restart samba-ad-dc

You only have to restart the DC if you are using the internal DNS-server from Samba

root@addc-01:~# samba-tool dns add addc-01 example.net cluster A 192.168.56.101 
Record added successfully

root@addc-01:~# samba-tool dns add addc-01 example.net cluster A 192.168.56.102
Record added successfully

root@addc-01:~# samba-tool dns add addc-01 56.168.192.in-addr.arpa 101 PTR cluster.example.net
Record added successfully

root@addc-01:~# samba-tool dns add addc-01 56.168.192.in-addr.arpa 102 PTR cluster.example.net
Record added successfully

Test the namesesulution.

root@addc-01:~# host cluster
cluster.example.net has address 192.168.56.101
cluster.example.net has address 192.168.56.102

root@addc-01:~# host 192.168.56.101
101.56.168.192.in-addr.arpa domain name pointer cluster.example.net.
root@addc-01:~# host 192.168.56.102
102.56.168.192.in-addr.arpa domain name pointer cluster.example.net.


In the listing you see that both dynamic IP-addresses getting the same DNS-name. Resolving the hostname will give you both IP-addresses. So a client can connect to either of the addresses and will always reach one of the cluster nodes.

Configuring Samba

If you use Samba together with CTDB you have to use the registry to configure Samba. The reason is, that you configure the cluster and not every single host. All configurations of the cluster can be done on either one of the Samba-hosts. The CTDB-Samba-hosts will share all TDB-files. The files will be stored locally but will be committed between all nodes.

The easiest way to write the settings into the registry is to write a file in smb.conf-style and the import the file into the registry.

If you start Samba, the first place where Samba looks for any configuration is the smb.conf file. This is the reason why you always have a minimum smb.conf. In the following listing you will see the settings for the configuration.

[global]
       workgroup = EXAMPLE
       realm = EXAMPLE.NET
       netbios name = CLUSTER
       security = ADS
       template shell = /bin/bash
       winbind use default domain = Yes
       winbind refresh tickets = Yes
       idmap config *:range = 10000-19999
       idmap config samba-ad:range = 1000000-1999999
       idmap config samba-ad:backend = rid


The next step is to create the smb.conf to tell Samba that clustering should be used and all the configuration comes out of the registry.

[global]
       clustering = yes
       include = registry

Now import the configuration file into the registry with the command net conf import /daten/smb.conf.first. You can test the import with net conf list on both nodes. Test all settings with testparm on both nodes. If you got no error message you can join the cluster into the domain:

root@cluster-01:/etc/ctdb# net ads join -U administrator
Enter administrator's password: *******

Using short domain name -- EXAMPLE
Joined 'CLUSTER' to dns domain 'example.net'
Not doing automatic DNS update in a clustered setup.
root@cluster-01:~# net ads testjoin
Join is OK

A DNS-update, during the join, for a cluster is not possible, that's why the DND-records were created before joining the cluster, but as you can see with net ads testjoin the join is valid. Another test is to see if the account for the cluster was created in AD to do the test do a samba-tool computer list on your domain controller.

Now you have joined the cluster to the domain. Up to this point you haven't started any of the Samba-services. Starting and stopping the services smbd, nmbd and winbind} should be done by CTDB and not via systemd}. So before you you configure CTDB to take care of the services you have to stop and disable the services in systemd:

root@cluster-01:~# systemctl stop smbd nmbd winbind
root@cluster-01:~# systemctl disable smbd nmbd winbind
root@cluster-02:~# systemctl stop smbd nmbd winbind
root@cluster-02:~# systemctl disable smbd nmbd winbind

As you can see, you have to do it on both nodes.

Configure CTDB to take care of Samba-services

After you have done the configuration of Samba and you joined the cluster into your domain, you can start configuring of CTDB to take care of the Samba-services. Since Samba 4.9 the way to configure CTDB has changed a lot, up to this point you had only noticed this while you where configuring the recovery lock. The old way to configure the services was activating the services in the ctdb.conf. Starting with Samba 4.9 that has changed, now you have a command to activated the services.

Every service will be enabled via an event script. To enable the scripts you use the command ctdb. We need the Samba-script and the winbind-script. In the next listing you see the commands to enable the scripts:

root@cluster-01:~# ctdb event script enable legacy 50.samba
root@cluster-01:~# ctdb event script enable legacy 49.winbind
root@cluster-02:~# ctdb event script enable legacy 50.samba
root@cluster-02:~# ctdb event script enable legacy 49.winbind

After enabling both -- 50.samba and 49.winbind -- restart CTDB with systemctl restart ctdb on both nodes.

After a while both CTDB-nodes becoming Ok again. Checking with ps | egrep 'mbd|winbind' and ss -tlpn you will see, that the Samba-services are running. Now you have configured CTDB to take care of starting and stopping all Samba-services.

What will happen when you execute the command? All event scripts are located in /usr/share/ctdb/events/legacy if you activate a script, the script will be linked to /etc/ctdb/events/legacy/. If you take a look at the script, you will see, it looks like a init-script of a service -- that's all it is.

Checking the CTDB-cluster

After your CTDB-cluster is running and the Samba-services are active let's take a look at some CTDB-tests.

ctdb status

Shows the actual status of the whole cluster. All nodes are listed and you can see the status of all nodes.

root@cluster-02:~# ctdb status
Number of nodes:2
pnn:0 192.168.57.42    OK
pnn:1 192.168.57.43    OK (THIS NODE)
Generation:1823539022
Size:2
hash:0 lmaster:0
hash:1 lmaster:1
Recovery mode:NORMAL (0)
Recovery master:1

What do you see here:

  • The number of nodes in the cluster.
  • A list of all nodes \textit{pnn}-number the IP-address and the status.
  • Generation is just a number which changes if a reconfiguration is taking place. There is no special meaning.
  • The size of the cluster -- here 2 nodes.
  • The line hash:<n> lmaster:<n> is used to calculate the lmaster}, it's calculated via a hash value.
  • The Recovery mode shows if everything in the cluster is good NORMAL, or a recovery is taking place RECOVERY.
  • The Recovery master is the node which is responsible for a recovery.

If you just want to see the status of all nodes or just one node, or some hosts, you can use ctdb nodestatus. With nodestatus you can see the status of the actual node or a list of hosts:

root@cluster-01:~# ctdb nodestatus
pnn:0 192.168.57.42    OK (THIS NODE)
root@cluster-01:~# ctdb nodestatus 1
pnn:1 192.168.57.43    OK
root@cluster-01:~# ctdb nodestatus 0,1
pnn:0 192.168.57.42    OK (THIS NODE)
pnn:1 192.168.57.43    OK
root@cluster-01:~# ctdb nodestatus all
Number of nodes:2
pnn:0 192.168.57.42    OK (THIS NODE)
pnn:1 192.168.57.43    OK


There are some more possibilities to check the cluster:

root@cluster-01:~# ctdb uptime
Current time of node 0        :                Wed Feb 12 18:56:14 2020
Ctdbd start time              : (000 04:53:49) Wed Feb 12 14:02:25 2020
Time of last recovery/failover: (000 04:53:43) Wed Feb 12 14:02:31 2020
Duration of last recovery/failover: 0.573115 seconds
root@cluster-01:~# ctdb listnodes
192.168.57.42
192.168.57.43
root@cluster-01:~# ctdb ping
response from 0 time=0.000124 sec  (20 clients)
root@cluster-01:~# ctdb ip
Public IPs on node 0
192.168.56.101 1
192.168.56.102 0

For more information about testing a CTDB-cluster see the manpage of ctdb.

Check all services

The next important check is to see which services can CTDB provide and which services are actually configured. You could use the command ctdb scriptstatus to list all the running services, but this command is deprecated. Since Samba 4.9 you should check the event scripts with event status legacy monitor. Then you will see all the running (monitored) services. To see the list of all services do a ctdb event script list legacy.

root@cluster-01:~# ctdb event status legacy monitor
00.ctdb              OK         0.005 Thu Feb 13 18:28:35 2020
01.reclock           OK         0.023 Thu Feb 13 18:28:35 2020
05.system            OK         0.017 Thu Feb 13 18:28:35 2020
10.interface         OK         0.019 Thu Feb 13 18:28:35 2020
49.winbind           OK         0.011 Thu Feb 13 18:28:35 2020
50.samba             OK         0.101 Thu Feb 13 18:28:35 2020
root@cluster-01:~#  ctdb event script list legacy  
* 00.ctdb
* 01.reclock
* 05.system
  06.nfs
* 10.interface
  11.natgw
  11.routing
  13.per_ip_routing
  20.multipathd
  31.clamd
  40.vsftpd
  41.httpd
* 49.winbind
* 50.samba
  60.nfs
  70.iscsi
  91.lvs

The first command is showing all running services. The second command is showing all services CTDB can provide, all running services are marked with a *.

The command onnode

The command onnode can be used to execute a command on all, or some, nodes of the cluster. To get onnode running without being ask for a password, on each host create a ssh-key without passphrase. Use the command ssh-keygen for the user \textsl{root} and spread it to all nodes. To copy the key to all nodes, including the own host use the command ssh.copy-id. You need the key on the localhost too, because all commands will be executed via ssh even on the localhost. To copy an ID from node \c-01 to root@c-02 execute root@cluster-01 ssh-copy-id -i .ssh/id_rsa.pub root@c-02. After you copied all keys, try if you can login without password.

After you managed to login without password do the test from the next listing:

root@cluster-02:~# onnode all ctdb nodestatus

>> NODE: 192.168.57.42 <<
pnn:0 192.168.57.42    OK (THIS NODE)

>> NODE: 192.168.57.43 <<
pnn:1 192.168.57.43    OK (THIS NODE)

You see here, that the command ctdb nodestatus will be executed on all nodes in the cluster. Instead of all you can give a node-number or a comma separated list of node-numbers, then the command will be executed only on this nodes.

You can also restart services on all nodes so the command onnode all systemctl restart ctdb would restart the CTDB on all nodes. You can execute any command via onnode.

One more useful thing you can do with onnode is -- you can copy files out of the storage into a directory of all nodes. A good example:

You want to add a new node to your CTDB-cluster so you have to add a new line to the files nodes and public_addresses, so the easiest way to do so is creating the needed file in /glusterfs on one node where the gluster-volume is mounted. Then copy the file with onnode:

root@cluster-01:~# vi /glusterfs/nodes
...
root@cluster-01:~# onnode all cp /glusterfs/node /etc/ctdb

>> NODE: 192.168.57.42 <<

>> NODE: 192.168.57.43 <<

If you would do the same with public_addresses you would have added another node to your CTDB-cluster.

Creating shares

To make a CTDB-cluster a fileserver you have to create shares, so that your users can store their files in the cluster. Together with Gluster you have three ways to create shares:

  • The classic way (the gluster-volume is mounted via the glusterfs-client)
  • Using the VFS-module glusterfs
  • Using the VFS-module glusterfs_fuse

The classic way

You can mount the gluster-volume via the glusterfs-client to all CTDB-nodes. Then create the share via a local path. It doesn't matters if you have the Gluster-volume on the same host or on different hosts, you can mount the via the gluster-client (see https://wiki.samba.org/index.php/GlusterFS#Mounting_the_gluster-volume)

But remember, because we use the clustermode on the Samba-server you must configure the share (like all other shares) over the registry.

A simple way to change the registry is exporting the registry with net conf list > registry.conf. This command exports the registry in a smb.conf-style file. You can append the new share to the exported smb.conf and the you can import the share with net conf import registry.conf.

root@cluster-01:~# net conf list > registry.conf
root@cluster-01:~# mkdir /glusterfs/localshare
root@cluster-01:~# vi registry.conf

--- start append to file ----

[localshare]
       inherit acls = Yes
       path = /glusterfs/localshare
       read only = No
       vfs objects = axl_xattr

--- end append to file ----

root@cluster-01:~# net conf import registry.conf

You don't have to restart the cluster after you have created the new share. smbclient -L cluster can be used to list all shares of the cluster.

root@cluster-01:~# smbclient -L cluster
Enter EXAMPLE\root's password: 
Anonymous login successful

       Sharename       Type      Comment
       ---------       ----      -------
       IPC$            IPC       IPC Service (Samba 4.11.6-Debian)
       localshare      Disk      
SMB1 disabled -- no workgroup available

Using the glusterfs VFS-module

You can access the gluster-volume without mounting the gluster-volume to a local mountpoint on the CTDB-nodes. Using the glusterfs VFS-module the first step has to be deactivating the foldercheck in CTDB. Edit the file /etc/ctdb/script.options on all nodes.

# 50.samba.options
CTDB_SAMBA_SKIP_SHARE_CHECK=yes

After changing the settings on all nodes, restart CTDB.

Now create a new folder on the gluster-volume. Then, again export the registry into a file and add the changes to the end of the file.

root@cluster-01:~# mkdir /glusterfs/cfs-share
root@cluster-01:~# vi registry.conf

--- start append to file ----

[vfs-share]
       read only = no
       vfs objects = acl_xattr glusterfs
       glusterfs:volume = gv0
       glusterfs:logfile = /var/log/samba/glusterfs-gv1.log
       glusterfs:loglevel = 7
       glusterfs:volfile_server = cluster.example.net
       kernel share modes = no
       path = /vfs-share

--- end append to file ----

root@cluster-01:~# net conf import registry.conf

There is no local path-variable set, just a path on the gluster-volume. You must give the path relative to the volume-mountpoint on any of the gluster-nodes. After importing the changes you can list the new share with smbclient -L cluster.


After you have imported the changes to the registry, smbclient will show the shares.

root@cluster-01:~# smbclient -L cluster
Enter EXAMPLE\root's password: 
Anonymous login successful

       Sharename       Type      Comment
       ---------       ----      -------
       IPC$            IPC       IPC Service (Samba 4.11.6-Debian)
       localshare      Disk      
       vfs-share       Disk
SMB1 disabled -- no workgroup available

Using the glusterfs fuse module

The third way to create a share together with gluster is using the new glusterfs_fuse-module. The glusterfs\_fuse needs a via glusterfs-client mounted gluster-volume. So the share will point to a local path, but the module provides support for the get_real_filename-VFS call which enhances file access performance by avoiding multiple expensive case folding lookup calls to detect the appropriate case of an existing filename.

Again, the new share must be added via net conf import

[fuse-share]
       path = /glusterfs/fuse-share
       read only = no
       vfs objects = acl_xattr glusterfs_fuse
       inherit acls = yes

You can combine the glusterfs_fuse-module with any other vfs-module, but the glusterfs_fuse must be the last in the list.

After you created the directory for the share and add the changes to the registry, smbclient will list the share.

root@cluster-01:~# smbclient -L cluster
Enter EXAMPLE\root's password: 
Anonymous login successful

       Sharename       Type      Comment
       ---------       ----      -------
       IPC$            IPC       IPC Service (Samba 4.11.6-Debian)
       localshare      Disk      
       vfs-share       Disk      
       fuse-share      Disk      
SMB1 disabled -- no workgroup available