Deploy CockroachDB on Microsoft Azure (Insecure)

This page shows you how to manually deploy an insecure multi-node CockroachDB cluster on Microsoft Azure, using Azure's managed load balancing service to distribute client traffic.

{{site.data.alerts.callout_danger}}If you plan to use CockroachDB in production, we strongly recommend using a secure cluster instead. Select Secure above for instructions.{{site.data.alerts.end}}

Requirements

You must have SSH access to each machine. This is necessary for distributing and starting CockroachDB binaries.
Your network configuration must allow TCP communication on the following ports:
- 26257 for intra-cluster and client-cluster communication
- 8080 to expose your Admin UI

Recommendations

If you plan to use CockroachDB in production, carefully review the Production Checklist.
Consider using a secure cluster instead. Using an insecure cluster comes with risks:
- Your cluster is open to any client that can access any node's IP addresses.
- Any user, even root, can log in without providing a password.
- Any user, connecting as root, can read or write any data in your cluster.
- There is no network encryption or authentication, and thus no confidentiality.

Decide how you want to access your Admin UI:

Access Level	Description
Partially open	Set a firewall rule to allow only specific IP addresses to communicate on port `8080`.
Completely open	Set a firewall rule to allow all IP addresses to communicate on port `8080`.
Completely closed	Set a firewall rule to disallow all communication on port `8080`. In this case, a machine with SSH access to a node could use an SSH tunnel to access the Admin UI.

Step 1. Configure your network

CockroachDB requires TCP communication on two ports:

26257 (tcp:26257) for inter-node communication (i.e., working as a cluster), for applications to connect to the load balancer, and for routing from the load balancer to nodes
8080 (tcp:8080) for exposing your Admin UI

To enable this in Azure, you must create a Resource Group, Virtual Network, and Network Security Group.

Create a Resource Group.
Create a Virtual Network that uses your Resource Group.

Create a Network Security Group that uses your Resource Group, and then add the following inbound rules to it:

Admin UI support:

Field	Recommended Value
Name	cockroachadmin
Source	IP Addresses
Source IP addresses/CIDR ranges	Your local network’s IP ranges
Source port ranges	*
Destination	Any
Destination port range	8080
Protocol	TCP
Action	Allow
Priority	Any value > 1000

Application support:

{{site.data.alerts.callout_success}}If your application is also hosted on the same Azure Virtual Network, you will not need to create a firewall rule for your application to communicate with your load balancer.{{site.data.alerts.end}}

Field	Recommended Value
Name	cockroachapp
Source	IP Addresses
Source IP addresses/CIDR ranges	Your local network’s IP ranges
Source port ranges	*
Destination	Any
Destination port range	26257
Protocol	TCP
Action	Allow
Priority	Any value > 1000

Step 2. Create VMs

Create Linux VMs for each node you plan to have in your cluster. If you plan to run a sample workload against the cluster, create a separate VM for that workload.

Run at least 3 nodes to ensure survivability.
Use storage-optimized Ls-series VMs with Premium Storage or local SSD storage with a Linux filesystem such as ext4 (not the Windows ntfs filesystem). For example, Cockroach Labs has used Standard_L4s VMs (4 vCPUs and 32 GiB of RAM per VM) for internal testing.
- If you choose local SSD storage, on reboot, the VM can come back with the ntfs filesystem. Be sure your automation monitors for this and reformats the disk to the Linux filesystem you chose initially.
Do not use "burstable" B-series VMs, which limit the load on a single core. Also, Cockroach Labs has experienced data corruption issues on A-series VMs and irregular disk performance on D-series VMs, so we recommend avoiding those as well.
When creating the VMs, make sure to select the Resource Group, Virtual Network, and Network Security Group you created.

For more details, see Hardware Recommendations and Cluster Topology.

Step 3. Synchronize clocks

CockroachDB requires moderate levels of clock synchronization to preserve data consistency. For this reason, when a node detects that its clock is out of sync with at least half of the other nodes in the cluster by 80% of the maximum offset allowed (500ms by default), it spontaneously shuts down. This avoids the risk of consistency anomalies, but it's best to prevent clocks from drifting too far in the first place by running clock synchronization software on each node.

ntpd should keep offsets in the single-digit milliseconds, so that software is featured here, but other methods of clock synchronization are suitable as well.

SSH to the first machine.
Disable timesyncd, which tends to be active by default on some Linux distributions:
```
$ sudo timedatectl set-ntp no
```
Verify that timesyncd is off:
```
$ timedatectl
```
Look for Network time on: no or NTP enabled: no in the output.
Install the ntp package:
```
$ sudo apt-get install ntp
```
Stop the NTP daemon:
```
$ sudo service ntp stop
```
Sync the machine's clock with Google's NTP service:
```
$ sudo ntpd -b time.google.com
```
To make this change permanent, in the /etc/ntp.conf file, remove or comment out any lines starting with server or pool and add the following lines:
```
server time1.google.com iburst
server time2.google.com iburst
server time3.google.com iburst
server time4.google.com iburst
```
Restart the NTP daemon:
```
$ sudo service ntp start
```
{{site.data.alerts.callout_info}}We recommend Google's external NTP service because they handle "smearing" the leap second. If you use a different NTP service that doesn't smear the leap second, you must configure client-side smearing manually and do so in the same way on each machine.{{site.data.alerts.end}}
Verify that the machine is using a Google NTP server:
```
$ sudo ntpq -p
```
The active NTP server will be marked with an asterisk.
Repeat these steps for each machine where a CockroachDB node will run.

Compute Engine instances are preconfigured to use NTP, which should keep offsets in the single-digit milliseconds. However, Google can’t predict how external NTP services, such as pool.ntp.org, will handle the leap second. Therefore, you should:

Configure each GCE instances to use Google's internal NTP service.
If you plan to run a hybrid cluster across GCE and other cloud providers or environments, configure the non-GCE machines to use Google's external NTP service.

Amazon provides the Amazon Time Sync Service, which uses a fleet of satellite-connected and atomic reference clocks in each AWS Region to deliver accurate current time readings. The service also smears the leap second.

If you plan to run your entire cluster on AWS, configure each AWS instance to use the internal Amazon Time Sync Service.
However, if you plan to run a hybrid cluster across AWS and other cloud providers or environments, configure all machines to use Google's external NTP service, which is comparably accurate and also handles "smearing" the leap second.

ntpd should keep offsets in the single-digit milliseconds, so that software is featured here. However, to run ntpd properly on Azure VMs, it's necessary to first unbind the Time Synchronization device used by the Hyper-V technology running Azure VMs; this device aims to synchronize time between the VM and its host operating system but has been known to cause problems.

SSH to the first machine.

Find the ID of the Hyper-V Time Synchronization device:

$ curl -O https://raw.githubusercontent.com/torvalds/linux/master/tools/hv/lsvmbus

$ python lsvmbus -vv | grep -w "Time Synchronization" -A 3

VMBUS ID 12: Class_ID = {9527e630-d0ae-497b-adce-e80ab0175caf} - [Time Synchronization]
    Device_ID = {2dd1ce17-079e-403c-b352-a1921ee207ee}
    Sysfs path: /sys/bus/vmbus/devices/2dd1ce17-079e-403c-b352-a1921ee207ee
    Rel_ID=12, target_cpu=0

Unbind the device, using the Device_ID from the previous command's output:
```
$ echo <DEVICE_ID> | sudo tee /sys/bus/vmbus/drivers/hv_util/unbind
```
Install the ntp package:
```
$ sudo apt-get install ntp
```
Stop the NTP daemon:
```
$ sudo service ntp stop
```
Sync the machine's clock with Google's NTP service:
```
$ sudo ntpd -b time.google.com
```
To make this change permanent, in the /etc/ntp.conf file, remove or comment out any lines starting with server or pool and add the following lines:
```
server time1.google.com iburst
server time2.google.com iburst
server time3.google.com iburst
server time4.google.com iburst
```
Restart the NTP daemon:
```
$ sudo service ntp start
```
{{site.data.alerts.callout_info}}We recommend Google's NTP service because they handle "smearing" the leap second. If you use a different NTP service that doesn't smear the leap second, be sure to configure client-side smearing in the same way on each machine.{{site.data.alerts.end}}
Verify that the machine is using a Google NTP server:
```
$ sudo ntpq -p
```
The active NTP server will be marked with an asterisk.
Repeat these steps for each machine where a CockroachDB node will run.

Step 4. Set up load balancing

Each CockroachDB node is an equally suitable SQL gateway to your cluster, but to ensure client performance and reliability, it's important to use load balancing:

Performance: Load balancers spread client traffic across nodes. This prevents any one node from being overwhelmed by requests and improves overall cluster performance (queries per second).
Reliability: Load balancers decouple client health from the health of a single CockroachDB node. In cases where a node fails, the load balancer redirects client traffic to available nodes.

Microsoft Azure offers fully-managed load balancing to distribute traffic between instances.

Add Azure load balancing. Be sure to:
- Set forwarding rules to route TCP traffic from the load balancer's port 26257 to port 26257 on the nodes.
- Configure health checks to use HTTP port 8080 and path /health?ready=1. This health endpoint ensures that load balancers do not direct traffic to nodes that are live but not ready to receive requests.
Note the provisioned IP Address for the load balancer. You'll use this later to test load balancing and to connect your application to the cluster.

{{site.data.alerts.callout_info}}If you would prefer to use HAProxy instead of Azure's managed load balancing, see the On-Premises tutorial for guidance.{{site.data.alerts.end}}

Step 5. Start nodes

You can start the nodes manually or automate the process using systemd.

For each initial node of your cluster, complete the following steps: {{site.data.alerts.callout_info}} After completing these steps, nodes will not yet be live. They will complete the startup process and join together to form a cluster as soon as the cluster is initialized in the next step. {{site.data.alerts.end}} 1. SSH to the machine where you want the node to run. 2. Download the [CockroachDB archive](https://binaries.cockroachdb.com/cockroach-{{ page.release_info.version }}.linux-amd64.tgz) for Linux, and extract the binary: {% include copy-clipboard.html %} ~~~ shell $ wget -qO- https://binaries.cockroachdb.com/cockroach-{{ page.release_info.version }}.linux-amd64.tgz \ | tar xvz ~~~ 3. Copy the binary into the `PATH`: {% include copy-clipboard.html %} ~~~ shell $ cp -i cockroach-{{ page.release_info.version }}.linux-amd64/cockroach /usr/local/bin/ ~~~ If you get a permissions error, prefix the command with `sudo`. 4. Run the [`cockroach start`](start-a-node.html) command: {% include copy-clipboard.html %} ~~~ shell $ cockroach start \ --insecure \ --advertise-addr= \ --join= , , \ --cache=.25 \ --max-sql-memory=.25 \ --background ~~~ This command primes the node to start, using the following flags: Flag | Description -----|------------ `--insecure` | Indicates that the cluster is insecure, with no network encryption or authentication. `--advertise-addr` | Specifies the IP address/hostname and port to tell other nodes to use. The port number can be omitted, in which case it defaults to `26257`.

This value must route to an IP address the node is listening on (with `--listen-addr` unspecified, the node listens on all IP addresses).

In some networking scenarios, you may need to use `--advertise-addr` and/or `--listen-addr` differently. For more details, see [Networking](recommended-production-settings.html#networking). `--join` | Identifies the address of 3-5 of the initial nodes of the cluster. These addresses should match the addresses that the target nodes are advertising. `--cache`
`--max-sql-memory` | Increases the node's cache and temporary SQL memory size to 25% of available system memory to improve read performance and increase capacity for in-memory SQL processing. For more details, see [Cache and SQL Memory Size](recommended-production-settings.html#cache-and-sql-memory-size). `--background` | Starts the node in the background so you gain control of the terminal to issue more commands. When deploying across multiple datacenters, or when there is otherwise high latency between nodes, it is recommended to set `--locality` as well. It is also required to use certain enterprise features. For more details, see [Locality](start-a-node.html#locality). For other flags not explicitly set, the command uses default values. For example, the node stores data in `--store=cockroach-data` and binds Admin UI HTTP requests to `--http-addr=localhost:8080`. To set these options manually, see [Start a Node](start-a-node.html). 5. Repeat these steps for each additional node that you want in your cluster.

For each initial node of your cluster, complete the following steps: {{site.data.alerts.callout_info}}After completing these steps, nodes will not yet be live. They will complete the startup process and join together to form a cluster as soon as the cluster is initialized in the next step.{{site.data.alerts.end}} 1. SSH to the machine where you want the node to run. Ensure you are logged in as the `root` user. 2. Download the [CockroachDB archive](https://binaries.cockroachdb.com/cockroach-{{ page.release_info.version }}.linux-amd64.tgz) for Linux, and extract the binary: {% include copy-clipboard.html %} ~~~ shell $ wget -qO- https://binaries.cockroachdb.com/cockroach-{{ page.release_info.version }}.linux-amd64.tgz \ | tar xvz ~~~ 3. Copy the binary into the `PATH`: {% include copy-clipboard.html %} ~~~ shell $ cp -i cockroach-{{ page.release_info.version }}.linux-amd64/cockroach /usr/local/bin/ ~~~ If you get a permissions error, prefix the command with `sudo`. 4. Create the Cockroach directory: {% include copy-clipboard.html %} ~~~ shell $ mkdir /var/lib/cockroach ~~~ 5. Create a Unix user named `cockroach`: {% include copy-clipboard.html %} ~~~ shell $ useradd cockroach ~~~ 6. Change the ownership of `Cockroach` directory to the user `cockroach`: {% include copy-clipboard.html %} ~~~ shell $ chown cockroach /var/lib/cockroach ~~~ 7. Download the [sample configuration template](https://raw.githubusercontent.com/cockroachdb/docs/master/_includes/{{ page.version.version }}/prod-deployment/insecurecockroachdb.service) and save the file in the `/etc/systemd/system/` directory: {% include copy-clipboard.html %} ~~~ shell $ wget -qO- https://raw.githubusercontent.com/cockroachdb/docs/master/_includes/{{ page.version.version }}/prod-deployment/insecurecockroachdb.service ~~~ Alternatively, you can create the file yourself and copy the script into it: {% include copy-clipboard.html %} ~~~ shell {% include {{ page.version.version }}/prod-deployment/insecurecockroachdb.service %} ~~~ 8. In the sample configuration template, specify values for the following flags: {% include {{ page.version.version }}/prod-deployment/advertise-addr-join.md %} When deploying across multiple datacenters, or when there is otherwise high latency between nodes, it is recommended to set `--locality` as well. It is also required to use certain enterprise features. For more details, see [Locality](start-a-node.html#locality). For other flags not explicitly set, the command uses default values. For example, the node stores data in `--store=cockroach-data` and binds Admin UI HTTP requests to `--http-port=8080`. To set these options manually, see [Start a Node](start-a-node.html). 9. Start the CockroachDB cluster: {% include copy-clipboard.html %} ~~~ shell $ systemctl start insecurecockroachdb ~~~ 10. Repeat these steps for each additional node that you want in your cluster. {{site.data.alerts.callout_info}} `systemd` handles node restarts in case of node failure. To stop a node without `systemd` restarting it, run `systemctl stop insecurecockroachdb` {{site.data.alerts.end}}

Step 6. Initialize the cluster

On your local machine, complete the node startup process and have them join together as a cluster:

Install CockroachDB on your local machine, if you haven't already.
Run the cockroach init command, with the --host flag set to the address of any node:
```
$ cockroach init --insecure --host=<address of any node>
```
Each node then prints helpful details to the standard output, such as the CockroachDB version, the URL for the admin UI, and the SQL URL for clients.

Step 7. Test the cluster

CockroachDB replicates and distributes data for you behind-the-scenes and uses a Gossip protocol to enable each node to locate data across the cluster.

To test this, use the built-in SQL client locally as follows:

On your local machine, launch the built-in SQL client, with the --host flag set to the address of any node:
```
	$ cockroach sql --insecure --host=<address of any node>
```
Create an insecurenodetest database:
```
	> CREATE DATABASE insecurenodetest;
```
Use \q or ctrl-d to exit the SQL shell.
Launch the built-in SQL client, with the --host flag set to the address of a different node:
```
	$ cockroach sql --insecure --host=<address of different node>
```

View the cluster's databases, which will include insecurenodetest:

	> SHOW DATABASES;

	+--------------------+
	|      Database      |
	+--------------------+
	| crdb_internal      |
	| information_schema |
	| insecurenodetest   |
	| pg_catalog         |
	| system             |
	+--------------------+
	(5 rows)

Use \q to exit the SQL shell.

Step 8. Run a sample workload

CockroachDB offers a pre-built workload binary for Linux that includes several load generators for simulating client traffic against your cluster. This step features CockroachDB's version of the TPC-C workload.

{{site.data.alerts.callout_success}}For comprehensive guidance on benchmarking CockroachDB with TPC-C, see our Performance Benchmarking white paper.{{site.data.alerts.end}}

SSH to the machine where you want the run the sample TPC-C workload.

This should be a machine that is not running a CockroachDB node.

Download workload and make it executable:

$ wget https://edge-binaries.cockroachdb.com/cockroach/workload.LATEST ; chmod 755 workload.LATEST

Rename and copy workload into the PATH:

$ cp -i workload.LATEST /usr/local/bin/workload

Start the TPC-C workload, pointing it at the IP address of the load balancer:
```
$ workload run tpcc \
--drop \
--init \
--duration=20m \
--tolerate-errors \
"postgresql://root@<IP ADDRESS OF LOAD BALANCER:26257/tpcc?sslmode=disable"
```
This command runs the TPC-C workload against the cluster for 20 minutes, loading 1 "warehouse" of data initially and then issuing about 12 queries per minute via 10 "worker" threads. These workers share SQL connections since individual workers are idle for long periods of time between queries.

{{site.data.alerts.callout_success}}For more tpcc options, use workload run tpcc --help. For details about other load generators included in workload, use workload run --help.
To monitor the load generator's progress, open the Admin UI by pointing a browser to the address in the admin field in the standard output of any node on startup.

Since the load generator is pointed at the load balancer, the connections will be evenly distributed across nodes. To verify this, click Metrics on the left, select the SQL dashboard, and then check the SQL Connections graph. You can use the Graph menu to filter the graph for specific nodes.

Step 9. Set up monitoring and alerting

Despite CockroachDB's various built-in safeguards against failure, it is critical to actively monitor the overall health and performance of a cluster running in production and to create alerting rules that promptly send notifications when there are events that require investigation or intervention.

For details about available monitoring options and the most important events and metrics to alert on, see Monitoring and Alerting.

Step 10. Scale the cluster

You can start the nodes manually or automate the process using systemd.

For each additional node you want to add to the cluster, complete the following steps: 1. SSH to the machine where you want the node to run. 2. Download the [CockroachDB archive](https://binaries.cockroachdb.com/cockroach-{{ page.release_info.version }}.linux-amd64.tgz) for Linux, and extract the binary: {% include copy-clipboard.html %} ~~~ shell $ wget -qO- https://binaries.cockroachdb.com/cockroach-{{ page.release_info.version }}.linux-amd64.tgz \ | tar xvz ~~~ 3. Copy the binary into the `PATH`: {% include copy-clipboard.html %} ~~~ shell $ cp -i cockroach-{{ page.release_info.version }}.linux-amd64/cockroach /usr/local/bin/ ~~~ If you get a permissions error, prefix the command with `sudo`. 4. Run the [`cockroach start`](start-a-node.html) command just like you did for the initial nodes: {% include copy-clipboard.html %} ~~~ shell $ cockroach start --insecure \ --advertise-addr= \ --locality= \ --cache=.25 \ --max-sql-memory=.25 \ --join= , , \ --background ~~~ 5. Update your load balancer to recognize the new node.

For each additional node you want to add to the cluster, complete the following steps: 1. SSH to the machine where you want the node to run. Ensure you are logged in as the `root` user. 2. Download the [CockroachDB archive](https://binaries.cockroachdb.com/cockroach-{{ page.release_info.version }}.linux-amd64.tgz) for Linux, and extract the binary: {% include copy-clipboard.html %} ~~~ shell $ wget -qO- https://binaries.cockroachdb.com/cockroach-{{ page.release_info.version }}.linux-amd64.tgz \ | tar xvz ~~~ 3. Copy the binary into the `PATH`: {% include copy-clipboard.html %} ~~~ shell $ cp -i cockroach-{{ page.release_info.version }}.linux-amd64/cockroach /usr/local/bin/ ~~~ If you get a permissions error, prefix the command with `sudo`. 4. Create the Cockroach directory: {% include copy-clipboard.html %} ~~~ shell $ mkdir /var/lib/cockroach ~~~ 5. Create a Unix user named `cockroach`: {% include copy-clipboard.html %} ~~~ shell $ useradd cockroach ~~~ 6. Change the ownership of `Cockroach` directory to the user `cockroach`: {% include copy-clipboard.html %} ~~~ shell $ chown cockroach /var/lib/cockroach ~~~ 7. Download the [sample configuration template](https://raw.githubusercontent.com/cockroachdb/docs/master/_includes/{{ page.version.version }}/prod-deployment/insecurecockroachdb.service): {% include copy-clipboard.html %} ~~~ shell $ wget -qO- https://raw.githubusercontent.com/cockroachdb/docs/master/_includes/{{ page.version.version }}/prod-deployment/insecurecockroachdb.service ~~~ Alternatively, you can create the file yourself and copy the script into it: {% include copy-clipboard.html %} ~~~ shell {% include {{ page.version.version }}/prod-deployment/insecurecockroachdb.service %} ~~~ Save the file in the `/etc/systemd/system/` directory 8. Customize the sample configuration template for your deployment: Specify values for the following flags in the sample configuration template: {% include {{ page.version.version }}/prod-deployment/advertise-addr-join.md %} 9. Repeat these steps for each additional node that you want in your cluster.

Step 11. Use the cluster

Now that your deployment is working, you can:

Implement your data model.
Create users and grant them privileges.
Connect your application. Be sure to connect your application to the Azure load balancer, not to a CockroachDB node.

Requirements

Recommendations

Step 1. Configure your network

Step 2. Create VMs

Step 3. Synchronize clocks

Step 4. Set up load balancing

Step 5. Start nodes

Step 6. Initialize the cluster

Step 7. Test the cluster

Step 8. Run a sample workload

Step 9. Set up monitoring and alerting

Step 10. Scale the cluster

Step 11. Use the cluster

See also