garage/doc/book/cookbook/real-world.md
Florian Klink a0f6bc5b7f add rpc_public_addr_subnet config option
In case `rpc_public_addr` is not set, but autodiscovery is used, this
allows filtering the list of automatically discovered IPs to a specific
subnet.

For example, if nodes should pick *their* IP inside a specific subnet,
but you don't want to explicitly write the IP down (as it's dynamic, or
you want to share configs across nodes), you can use this option.
2024-06-05 08:41:36 +02:00

14 KiB

+++ title = "Deployment on a cluster" weight = 5 +++

To run Garage in cluster mode, we recommend having at least 3 nodes. This will allow you to setup Garage for three-way replication of your data, the safest and most available mode proposed by Garage.

We recommend first following the quick start guide in order to get familiar with Garage's command line and usage patterns.

Preparing your environment

Prerequisites

To run a real-world deployment, make sure the following conditions are met:

  • You have at least three machines with sufficient storage space available.

  • Each machine has an IP address which makes it directly reachable by all other machines. In many cases, nodes will be behind a NAT and will not each have a public IPv4 addresses. In this case, is recommended that you use IPv6 for this end-to-end connectivity if it is available. Otherwise, using a mesh VPN such as Nebula or Yggdrasil are approaches to consider in addition to building out your own VPN tunneling.

  • This guide will assume you are using Docker containers to deploy Garage on each node. Garage can also be run independently, for instance as a Systemd service. You can also use an orchestrator such as Nomad or Kubernetes to automatically manage Docker containers on a fleet of nodes.

Before deploying Garage on your infrastructure, you must inventory your machines. For our example, we will suppose the following infrastructure with IPv6 connectivity:

Location Name IP Address Disk Space
Paris Mercury fc00:1::1 1 TB
Paris Venus fc00:1::2 2 TB
London Earth fc00:B::1 2 TB
Brussels Mars fc00:F::1 1.5 TB

Note that Garage will always store the three copies of your data on nodes at different locations. This means that in the case of this small example, the usable capacity of the cluster is in fact only 1.5 TB, because nodes in Brussels can't store more than that. This also means that nodes in Paris and London will be under-utilized. To make better use of the available hardware, you should ensure that the capacity available in the different locations of your cluster is roughly the same. For instance, here, the Mercury node could be moved to Brussels; this would allow the cluster to store 2 TB of data in total.

Best practices

  • If you have reasonably fast networking between all your nodes, and are planing to store mostly large files, bump the block_size configuration parameter to 10 MB (block_size = "10M").

  • Garage stores its files in two locations: it uses a metadata directory to store frequently-accessed small metadata items, and a data directory to store data blocks of uploaded objects. Ideally, the metadata directory would be stored on an SSD (smaller but faster), and the data directory would be stored on an HDD (larger but slower).

  • For the data directory, Garage already does checksumming and integrity verification, so there is no need to use a filesystem such as BTRFS or ZFS that does it. We recommend using XFS for the data partition, as it has the best performance. EXT4 is not recommended as it has more strict limitations on the number of inodes, which might cause issues with Garage when large numbers of objects are stored.

  • Servers with multiple HDDs are supported natively by Garage without resorting to RAID, see our dedicated documentation page.

  • For the metadata storage, Garage does not do checksumming and integrity verification on its own, so it is better to use a robust filesystem such as BTRFS or ZFS. Users have reported that when using the LMDB database engine (the default), database files have a tendency of becoming corrupted after an unclean shutdown (e.g. a power outage), so you should take regular snapshots to be able to recover from such a situation. This can be done using Garage's built-in automatic snapshotting (since v0.9.4), or by using filesystem level snapshots. If you cannot do so, you might want to switch to Sqlite which is more robust.

  • LMDB is the fastest and most tested database engine, but it has the following weaknesses: 1/ data files are not architecture-independent, you cannot simply move a Garage metadata directory between nodes running different architectures, and 2/ LMDB is not suited for 32-bit platforms. Sqlite is a viable alternative if any of these are of concern.

  • If you only have an HDD and no SSD, it's fine to put your metadata alongside the data on the same drive, but then consider your filesystem choice wisely (see above). Having lots of RAM for your kernel to cache the metadata will help a lot with performance. The default LMDB database engine is the most tested and has good performance.

Get a Docker image

Our docker image is currently named dxflrs/garage and is stored on the Docker Hub. We encourage you to use a fixed tag (eg. v1.0.0) and not the latest tag. For this example, we will use the latest published version at the time of the writing which is v1.0.0 but it's up to you to check the most recent versions on the Docker Hub.

For example:

sudo docker pull dxflrs/garage:v1.0.0

Deploying and configuring Garage

On each machine, we will have a similar setup, especially you must consider the following folders/files:

  • /etc/garage.toml: Garage daemon's configuration (see below)

  • /var/lib/garage/meta/: Folder containing Garage's metadata, put this folder on a SSD if possible

  • /var/lib/garage/data/: Folder containing Garage's data, this folder will be your main data storage and must be on a large storage (e.g. large HDD)

A valid /etc/garage.toml for our cluster would look as follows:

metadata_dir = "/var/lib/garage/meta"
data_dir = "/var/lib/garage/data"
db_engine = "lmdb"
metadata_auto_snapshot_interval = "6h"

replication_factor = 3

compression_level = 2

rpc_bind_addr = "[::]:3901"
rpc_public_addr = "<this node's public IP>:3901"
rpc_secret = "<RPC secret>"

[s3_api]
s3_region = "garage"
api_bind_addr = "[::]:3900"
root_domain = ".s3.garage"

[s3_web]
bind_addr = "[::]:3902"
root_domain = ".web.garage"
index = "index.html"

Check the following for your configuration files:

  • Make sure rpc_public_addr contains the public IP address of the node you are configuring. This parameter is optional but recommended: if your nodes have trouble communicating with one another, consider adding it. Alternatively, you can also set rpc_public_addr_subnet, which can filter the addresses announced to other peers to a specific subnet.

  • Make sure rpc_secret is the same value on all nodes. It should be a 32-bytes hex-encoded secret key. You can generate such a key with openssl rand -hex 32.

Starting Garage using Docker

On each machine, you can run the daemon with:

docker run \
  -d \
  --name garaged \
  --restart always \
  --network host \
  -v /etc/garage.toml:/etc/garage.toml \
  -v /var/lib/garage/meta:/var/lib/garage/meta \
  -v /var/lib/garage/data:/var/lib/garage/data \
  dxflrs/garage:v1.0.0

With this command line, Garage should be started automatically at each boot. Please note that we use host networking as otherwise the network indirection added by Docker would prevent Garage nodes from communicating with one another (especially if using IPv6).

If you want to use docker-compose, you may use the following docker-compose.yml file as a reference:

version: "3"
services:
  garage:
    image: dxflrs/garage:v1.0.0
    network_mode: "host"
    restart: unless-stopped
    volumes:
      - /etc/garage.toml:/etc/garage.toml
      - /var/lib/garage/meta:/var/lib/garage/meta
      - /var/lib/garage/data:/var/lib/garage/data

If you wish to upgrade your cluster, make sure to read the corresponding documentation page first, as well as the documentation relevant to your version of Garage in the case of major upgrades. With the containerized setup proposed here, the upgrade process will require stopping and removing the existing container, and re-creating it with the upgraded version.

Controlling the daemon

The garage binary has two purposes:

  • it acts as a daemon when launched with garage server
  • it acts as a control tool for the daemon when launched with any other command

Ensure an appropriate garage binary (the same version as your Docker image) is available in your path. If your configuration file is at /etc/garage.toml, the garage binary should work with no further change.

You can also use an alias as follows to use the Garage binary inside your docker container:

alias garage="docker exec -ti <container name> /garage"

You can test your garage CLI utility by running a simple command such as:

garage status

At this point, nodes are not yet talking to one another. Your output should therefore look like follows:

Mercury$ garage status
==== HEALTHY NODES ====
ID                  Hostname  Address           Tag                   Zone  Capacity
563e1ac825ee3323…   Mercury   [fc00:1::1]:3901  NO ROLE ASSIGNED

Connecting nodes together

When your Garage nodes first start, they will generate a local node identifier (based on a public/private key pair).

To obtain the node identifier of a node, once it is generated, run garage node id. This will print keys as follows:

Mercury$ garage node id
563e1ac825ee3323aa441e72c26d1030d6d4414aeb3dd25287c531e7fc2bc95d@[fc00:1::1]:3901

Venus$ garage node id
86f0f26ae4afbd59aaf9cfb059eefac844951efd5b8caeec0d53f4ed6c85f332@[fc00:1::2]:3901

etc.

You can then instruct nodes to connect to one another as follows:

# Instruct Venus to connect to Mercury (this will establish communication both ways)
Venus$ garage node connect 563e1ac825ee3323aa441e72c26d1030d6d4414aeb3dd25287c531e7fc2bc95d@[fc00:1::1]:3901

You don't need to instruct all node to connect to all other nodes: nodes will discover one another transitively.

Now if your run garage status on any node, you should have an output that looks as follows:

==== HEALTHY NODES ====
ID                  Hostname  Address           Tag                   Zone  Capacity
563e1ac825ee3323…   Mercury   [fc00:1::1]:3901  NO ROLE ASSIGNED
86f0f26ae4afbd59…   Venus     [fc00:1::2]:3901  NO ROLE ASSIGNED
68143d720f20c89d…   Earth     [fc00:B::1]:3901  NO ROLE ASSIGNED
212f7572f0c89da9…   Mars      [fc00:F::1]:3901  NO ROLE ASSIGNED

Creating a cluster layout

We will now inform Garage of the disk space available on each node of the cluster as well as the zone (e.g. datacenter) in which each machine is located. This information is called the cluster layout and consists of a role that is assigned to each active cluster node.

For our example, we will suppose we have the following infrastructure (Capacity, Identifier and Zone are specific values to Garage described in the following):

Location Name Disk Space Identifier Zone (-z) Capacity (-c)
Paris Mercury 1 TB 563e par1 1T
Paris Venus 2 TB 86f0 par1 2T
London Earth 2 TB 6814 lon1 2T
Brussels Mars 1.5 TB 212f bru1 1.5T

Node identifiers

After its first launch, Garage generates a random and unique identifier for each nodes, such as:

563e1ac825ee3323aa441e72c26d1030d6d4414aeb3dd25287c531e7fc2bc95d

Often a shorter form can be used, containing only the beginning of the identifier, like 563e, which identifies the server "Mercury" located in "Paris" according to our previous table.

The most simple way to match an identifier to a node is to run:

garage status

It will display the IP address associated with each node; from the IP address you will be able to recognize the node.

We will now use the garage layout assign command to configure the correct parameters for each node.

Zones

Zones are simply a user-chosen identifier that identify a group of server that are grouped together logically. It is up to the system administrator deploying Garage to identify what does "grouped together" means.

In most cases, a zone will correspond to a geographical location (i.e. a datacenter). Behind the scene, Garage will use zone definition to try to store the same data on different zones, in order to provide high availability despite failure of a zone.

Zones are passed to Garage using the -z flag of garage layout assign (see below).

Capacity

Garage needs to know the storage capacity (disk space) it can/should use on each node, to be able to correctly balance data.

Capacity values are expressed in bytes and are passed to Garage using the -c flag of garage layout assign (see below).

Tags

You can add additional tags to nodes using the -t flag of garage layout assign (see below). Tags have no specific meaning for Garage and can be used at your convenience.

Injecting the topology

Given the information above, we will configure our cluster as follow:

garage layout assign 563e -z par1 -c 1T -t mercury
garage layout assign 86f0 -z par1 -c 2T -t venus
garage layout assign 6814 -z lon1 -c 2T -t earth
garage layout assign 212f -z bru1 -c 1.5T -t mars

At this point, the changes in the cluster layout have not yet been applied. To show the new layout that will be applied, call:

garage layout show

Make sure to read carefully the output of garage layout show. Once you are satisfied with your new layout, apply it with:

garage layout apply

WARNING: if you want to use the layout modification commands in a script, make sure to read this page first.

Using your Garage cluster

Creating buckets and managing keys is done using the garage CLI, and is covered in the quick start guide. Remember also that the CLI is self-documented thanks to the --help flag and the help subcommand (e.g. garage help, garage key --help).

Configuring S3-compatible applications to interact with Garage is covered in the Integrations section.