Expand a Distributed MinIO Deployment

Networking and Firewalls

Each node should have full bidirectional network access to every other node in the deployment. For containerized or orchestrated infrastructures, this may require specific configuration of networking and routing components such as ingress or load balancers. Certain operating systems may also require setting firewall rules. For example, the following command explicitly opens the default MinIO server API port 9000 on servers using firewalld:

firewall-cmd --permanent --zone=public --add-port=9000/tcp
firewall-cmd --reload

All MinIO servers in the deployment must use the same listen port.

If you set a static MinIO Console port (e.g. :9001) you must also grant access to that port to ensure connectivity from external clients.

MinIO strongly recomends using a load balancer to manage connectivity to the cluster. The Load Balancer should use a “Least Connections” algorithm for routing requests to the MinIO deployment, since any MinIO node in the deployment can receive, route, or process client requests.

The following load balancers are known to work well with MinIO:

• NGINX

• HAProxy

Configuring firewalls or load balancers to support MinIO is out of scope for this procedure. The Configure NGINX Proxy for MinIO Server reference provides a baseline configuration for using NGINX as a reverse proxy with basic load balancing configured.

Sequential Hostnames

MinIO requires using expansion notation {x...y} to denote a sequential series of MinIO hosts when creating a server pool. MinIO therefore requires using sequentially-numbered hostnames to represent each minio server process in the pool.

Create the necessary DNS hostname mappings prior to starting this procedure. For example, the following hostnames would support a 4-node distributed server pool:

• minio5.example.com

• minio6.example.com

• minio7.example.com

• minio8.example.com

You can specify the entire range of hostnames using the expansion notation minio{5...8}.example.com.

Configuring DNS to support MinIO is out of scope for this procedure.

Storage Requirements

The following requirements summarize the Storage section of MinIO’s hardware recommendations:

Use Local Storage

Direct-Attached Storage (DAS) has significant performance and consistency advantages over networked storage (NAS, SAN, NFS). MinIO strongly recommends flash storage (NVMe, SSD) for primary or “hot” data.

Use XFS-Formatting for Drives

MinIO strongly recommends provisioning XFS formatted drives for storage. MinIO uses XFS as part of internal testing and validation suites, providing additional confidence in performance and behavior at all scales.

MinIO does not test nor recommend any other filesystem, such as EXT4, BTRFS, or ZFS.

Use Consistent Type of Drive

MinIO does not distinguish drive types and does not benefit from mixed storage types. Each pool must use the same type (NVMe, SSD)

For example, deploy a pool consisting of only NVMe drives. If you deploy some drives as SSD or HDD, MinIO treats those drives identically to the NVMe drives. This can result in performance issues, as some drives have differing or worse read/write characteristics and cannot respond at the same rate as the NVMe drives.

Use Consistent Size of Drive

MinIO limits the size used per drive to the smallest drive in the deployment.

For example, deploy a pool consisting of the same number of NVMe drives with identical capacity of 7.68TiB. If you deploy one drive with 3.84TiB, MinIO treats all drives in the pool as having that smaller capacity.

Configure Sequential Drive Mounting

MinIO uses Go expansion notation {x...y} to denote a sequential series of drives when creating the new server pool, where all nodes in the server pool have an identical set of mounted drives. Configure drive mounting paths as a sequential series to best support this notation. For example, mount your drives using a pattern of /mnt/drive-n, where n starts at 1 and increments by 1 per drive.

Persist Drive Mounting and Mapping Across Reboots

Use /etc/fstab to ensure consistent drive-to-mount mapping across node reboots.

Non-Linux Operating Systems should use the equivalent drive mount management tool.

Minimum Drives for Erasure Code Parity

MinIO requires each pool satisfy the deployment erasure code settings. Specifically the new pool topology must support a minimum of 2 x EC:N drives per erasure set, where EC:N is the Standard parity storage class of the deployment. This requirement ensures the new server pool can satisfy the expected SLA of the deployment.

You can use the MinIO Erasure Code Calculator to check the Erasure Code Stripe Size (K+M) of your new pool. If the highest listed value is at least 2 x EC:N, the pool supports the deployment’s erasure parity settings.

Time Synchronization

Multi-node systems must maintain synchronized time and date to maintain stable internode operations and interactions. Make sure all nodes sync to the same time server regularly. Operating systems vary for methods used to synchronize time and date, such as with ntp, timedatectl, or timesyncd.

Check the documentation for your operating system for how to set up and maintain accurate and identical system clock times across nodes.

Back Up Cluster Settings First

Use the mc admin cluster bucket export and mc admin cluster iam export commands to take a snapshot of the bucket metadata and IAM configurations respectively prior to starting decommissioning. You can use these snapshots to restore bucket and IAM settings to recover from user or process errors as necessary.

Writing Files

MinIO does not automatically rebalance objects across the new server pools. Instead, MinIO performs new write operations to the pool with the most free storage weighted by the amount of free space on the pool divided by the free space across all available pools.

The formula to determine the probability of a write operation on a particular pool is

\(FreeSpaceOnPoolA / FreeSpaceOnAllPools\)

Consider a situation where a group of two pools has a total of 10 TiB of free space distributed as:

• Pool A has 3 TiB of free space

• Pool B has 2 TiB of free space

• Pool C has 5 TiB of free space

MinIO calculates the probability of a write operation to each of the pools as:

• Pool A: 30% chance (\(3TiB / 10TiB\))

• Pool B: 20% chance (\(2TiB / 10TiB\))

• Pool C: 50% chance (\(5TiB / 10TiB\))

In addition to the free space calculation, if a write option (with parity) would bring a drive usage above 99% or a known free inode count below 1000, MinIO does not write to the pool.

If desired, you can manually initiate a rebalance procedure with mc admin rebalance. For more about how rebalancing works, see managing objects across a deployment.

Likewise, MinIO does not write to pools in a decommissioning process.

Expansion is Non-Disruptive

Adding a new server pool requires restarting all MinIO server processes in the deployment at around same time.

MinIO strongly recommends restarting all MinIO Server processes in a deployment simultaneously. MinIO operations are atomic and strictly consistent. As such the restart procedure is non-disruptive to applications and ongoing operations.

Do not perform “rolling” (e.g. one node at a time) restarts.

Capacity-Based Planning

MinIO recommends planning storage capacity sufficient to store at least 2 years of data before reaching 70% usage. Performing server pool expansion more frequently or on a “just-in-time” basis generally indicates an architecture or planning issue.

For example, consider an application suite expected to produce at least 100 TiB of data per year and a 3 year target before expansion. The deployment has ~500TiB of usable storage in the initial server pool, such that the cluster safely met the 70% threshold with some buffer for data growth. The new server pool should ideally meet at minimum 500TiB of additional storage to allow for a similar lifespan before further expansion.

Since MinIO erasure coding requires some storage for parity, the total raw storage must exceed the planned usable capacity. Consider using the MinIO Erasure Code Calculator for guidance in planning capacity around specific erasure code settings.

Recommended Operating Systems

This tutorial assumes all hosts running MinIO use a recommended Linux operating system.

All hosts in the deployment should run with matching software configurations.

1) Install the MinIO Binary on Each Node in the New Server Pool

The following tabs provide examples of installing MinIO onto 64-bit Linux operating systems using RPM, DEB, or binary. The RPM and DEB packages automatically install MinIO to the necessary system paths and create a minio service for systemctl. MinIO strongly recommends using the RPM or DEB installation routes. To update deployments managed using systemctl, see Update systemctl-Managed MinIO Deployments.

wget https://dl.min.io/server/minio/release/linux-amd64/archive/minio-20240406052602.0.0-1.x86_64.rpm -O minio.rpm
sudo dnf install minio.rpm

wget https://dl.min.io/server/minio/release/linux-amd64/archive/minio_20240406052602.0.0_amd64.deb -O minio.deb
sudo dpkg -i minio.deb

wget https://dl.min.io/server/minio/release/linux-amd64/minio
chmod +x minio
sudo mv minio /usr/local/bin/

wget https://dl.min.io/server/minio/release/linux-arm64/archive/minio-20240406052602.0.0-1.aarch64.rpm -O minio.rpm
sudo dnf install minio.rpm

wget https://dl.min.io/server/minio/release/linux-arm64/archive/minio_20240406052602.0.0_arm64.deb -O minio.deb
sudo dpkg -i minio.deb

wget https://dl.min.io/server/minio/release/linux-arm64/minio
chmod +x minio
MINIO_ROOT_USER=admin MINIO_ROOT_PASSWORD=password ./minio server /mnt/data --console-address ":9001"

2) Add TLS/SSL Certificates

MinIO enables Transport Layer Security (TLS) 1.2+ automatically upon detecting a valid x.509 certificate (.crt) and private key (.key) in the MinIO ${HOME}/.minio/certs directory.

For systemd-managed deployments, use the $HOME directory for the user which runs the MinIO server process. The provided minio.service file runs the process as minio-user. The previous step includes instructions for creating this user with a home directory /home/minio-user.

• Place TLS certificates into /home/minio-user/.minio/certs on each host.

• If any MinIO server or client uses certificates signed by an unknown Certificate Authority (self-signed or internal CA), you must place the CA certs in the /home/minio-user/.minio/certs/CAs on all MinIO hosts in the deployment. MinIO rejects invalid certificates (untrusted, expired, or malformed).

If the minio.service file specifies a different user account, use the $HOME directory for that account. Alternatively, specify a custom certificate directory using the minio server --certs-dir commandline argument. Modify the MINIO_OPTS variable in /etc/defaults/minio to set this option. The systemd user which runs the MinIO server process must have read and listing permissions for the specified directory.

For more specific guidance on configuring MinIO for TLS, including multi-domain support via Server Name Indication (SNI), see Network Encryption (TLS). You can optionally skip this step to deploy without TLS enabled. MinIO strongly recommends against non-TLS deployments outside of early development.

3) Create the systemd Service File

The .deb or .rpm packages install the following systemd service file to /usr/lib/systemd/system/minio.service. For binary installations, create this file manually on all MinIO hosts.

[Unit]
Description=MinIO
Documentation=https://min.io/docs/minio/linux/index.html
Wants=network-online.target
After=network-online.target
AssertFileIsExecutable=/usr/local/bin/minio

[Service]
WorkingDirectory=/usr/local

User=minio-user
Group=minio-user
ProtectProc=invisible

EnvironmentFile=-/etc/default/minio
ExecStartPre=/bin/bash -c "if [ -z \"${MINIO_VOLUMES}\" ]; then echo \"Variable MINIO_VOLUMES not set in /etc/default/minio\"; exit 1; fi"
ExecStart=/usr/local/bin/minio server $MINIO_OPTS $MINIO_VOLUMES

# MinIO RELEASE.2023-05-04T21-44-30Z adds support for Type=notify (https://www.freedesktop.org/software/systemd/man/systemd.service.html#Type=)
# This may improve systemctl setups where other services use `After=minio.server`
# Uncomment the line to enable the functionality
# Type=notify

# Let systemd restart this service always
Restart=always

# Specifies the maximum file descriptor number that can be opened by this process
LimitNOFILE=65536

# Specifies the maximum number of threads this process can create
TasksMax=infinity

# Disable timeout logic and wait until process is stopped
TimeoutStopSec=infinity
SendSIGKILL=no

[Install]
WantedBy=multi-user.target

# Built for ${project.name}-${project.version} (${project.name})

The minio.service file runs as the minio-user User and Group by default. You can create the user and group using the groupadd and useradd commands. The following example creates the user, group, and sets permissions to access the folder paths intended for use by MinIO. These commands typically require root (sudo) permissions.

groupadd -r minio-user
useradd -M -r -g minio-user minio-user
chown minio-user:minio-user /mnt/disk1 /mnt/disk2 /mnt/disk3 /mnt/disk4

The specified drive paths are provided as an example. Change them to match the path to those drives intended for use by MinIO.

Alternatively, change the User and Group values to another user and group on the system host with the necessary access and permissions.

MinIO publishes additional startup script examples on github.com/minio/minio-service.

To update deployments managed using systemctl, see Update systemctl-Managed MinIO Deployments.

4) Create the Service Environment File

Create an environment file at /etc/default/minio. The MinIO service uses this file as the source of all environment variables used by MinIO and the minio.service file.

The following examples assumes that:

• The deployment has a single server pool consisting of four MinIO server hosts with sequential hostnames.

  minio1.example.com   minio3.example.com
  minio2.example.com   minio4.example.com
  

  Each host has 4 locally attached drives with sequential mount points:

  /mnt/disk1/minio   /mnt/disk3/minio
  /mnt/disk2/minio   /mnt/disk4/minio
  

• The new server pool consists of eight new MinIO hosts with sequential hostnames:

  minio5.example.com   minio9.example.com
  minio6.example.com   minio10.example.com
  minio7.example.com   minio11.example.com
  minio8.example.com   minio12.example.com
  

• All hosts have eight locally-attached drives with sequential mount-points:

  /mnt/disk1/minio  /mnt/disk5/minio
  /mnt/disk2/minio  /mnt/disk6/minio
  /mnt/disk3/minio  /mnt/disk7/minio
  /mnt/disk4/minio  /mnt/disk8/minio
  

• The deployment has a load balancer running at https://minio.example.net that manages connections across all MinIO hosts. The load balancer should not be routing requests to the new hosts at this step, but should have the necessary configuration updates planned.

Modify the example to reflect your deployment topology:

# Set the hosts and volumes MinIO uses at startup
# The command uses MinIO expansion notation {x...y} to denote a
# sequential series.
#
# The following example starts the MinIO server with two server pools.
#
# The space delimiter indicates a seperate server pool
#
# The second set of hostnames and volumes is the newly added pool.
# The pool has sufficient stripe size to meet the existing erasure code
# parity of the deployment (2 x EC:4)
#
# The command includes the port on which the MinIO servers listen for each
# server pool.

MINIO_VOLUMES="https://minio{1...4}.example.net:9000/mnt/disk{1...4}/minio https://minio{5...12}.example.net:9000/mnt/disk{1...8}/minio"

# Set all MinIO server options
#
# The following explicitly sets the MinIO Console listen address to
# port 9001 on all network interfaces. The default behavior is dynamic
# port selection.

MINIO_OPTS="--console-address :9001"

# Set the root username. This user has unrestricted permissions to
# perform S3 and administrative API operations on any resource in the
# deployment.
#
# Defer to your organizations requirements for superadmin user name.

MINIO_ROOT_USER=minioadmin

# Set the root password
#
# Use a long, random, unique string that meets your organizations
# requirements for passwords.

MINIO_ROOT_PASSWORD=minio-secret-key-CHANGE-ME

# Set to the URL of the load balancer for the MinIO deployment
# This value *must* match across all MinIO servers. If you do
# not have a load balancer, set this value to to any *one* of the
# MinIO hosts in the deployment as a temporary measure.
MINIO_SERVER_URL="https://minio.example.net:9000"

You may specify other environment variables or server commandline options as required by your deployment. All MinIO nodes in the deployment should include the same environment variables with the matching values.

5) Restart the MinIO Deployment with Expanded Configuration

Issue the following commands on each node simultaneously in the deployment to restart the MinIO service:

sudo systemctl restart minio.service

Use the following commands to confirm the service is online and functional:

sudo systemctl status minio.service
journalctl -f -u minio.service

MinIO may log an increased number of non-critical warnings while the server processes connect and synchronize. These warnings are typically transient and should resolve as the deployment comes online.

MinIO strongly recommends restarting all MinIO Server processes in a deployment simultaneously. MinIO operations are atomic and strictly consistent. As such the restart procedure is non-disruptive to applications and ongoing operations.

Do not perform “rolling” (e.g. one node at a time) restarts.

6) Next Steps

• Update any load balancers, reverse proxies, or other network control planes to route client requests to the new hosts in the MinIO distributed deployment. While MinIO automatically manages routing internally, having the control planes handle initial connection management may reduce network hops and improve efficiency.

• Review the MinIO Console to confirm the updated cluster topology and monitor performance.