Alex
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This PR should be merged after the new website is deployed. - [x] Rename files - [x] Add front matter section to all `.md` files in the book (necessary for Zola) - [x] Change all internal links to use Zola's linking system that checks broken links - [x] Some updates to documentation contents and organization Co-authored-by: Alex Auvolat <alex@adnab.me> Reviewed-on: #213 Co-authored-by: Alex <alex@adnab.me> Co-committed-by: Alex <alex@adnab.me>
295 lines
10 KiB
Markdown
295 lines
10 KiB
Markdown
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title = "Deployment on a cluster"
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weight = 5
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+++
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To run Garage in cluster mode, we recommend having at least 3 nodes.
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This will allow you to setup Garage for three-way replication of your data,
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the safest and most available mode proposed by Garage.
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We recommend first following the [quick start guide](@/documentation/quick-start/_index.md) in order
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to get familiar with Garage's command line and usage patterns.
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## Prerequisites
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To run a real-world deployment, make sure the following conditions are met:
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- You have at least three machines with sufficient storage space available.
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- Each machine has a public IP address which is reachable by other machines.
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Running behind a NAT is likely to be possible but hasn't been tested for the latest version (TODO).
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- Ideally, each machine should have a SSD available in addition to the HDD you are dedicating
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to Garage. This will allow for faster access to metadata and has the potential
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to drastically reduce Garage's response times.
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- This guide will assume you are using Docker containers to deploy Garage on each node.
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Garage can also be run independently, for instance as a [Systemd service](@/documentation/cookbook/systemd.md).
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You can also use an orchestrator such as Nomad or Kubernetes to automatically manage
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Docker containers on a fleet of nodes.
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Before deploying Garage on your infrastructure, you must inventory your machines.
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For our example, we will suppose the following infrastructure with IPv6 connectivity:
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| Location | Name | IP Address | Disk Space |
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|----------|---------|------------|------------|
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| Paris | Mercury | fc00:1::1 | 1 To |
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| Paris | Venus | fc00:1::2 | 2 To |
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| London | Earth | fc00:B::1 | 2 To |
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| Brussels | Mars | fc00:F::1 | 1.5 To |
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## Get a Docker image
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Our docker image is currently named `dxflrs/amd64_garage` and is stored on the [Docker Hub](https://hub.docker.com/r/dxflrs/amd64_garage/tags?page=1&ordering=last_updated).
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We encourage you to use a fixed tag (eg. `v0.4.0`) and not the `latest` tag.
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For this example, we will use the latest published version at the time of the writing which is `v0.4.0` but it's up to you
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to check [the most recent versions on the Docker Hub](https://hub.docker.com/r/dxflrs/amd64_garage/tags?page=1&ordering=last_updated).
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For example:
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```
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sudo docker pull dxflrs/amd64_garage:v0.4.0
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```
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## Deploying and configuring Garage
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On each machine, we will have a similar setup,
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especially you must consider the following folders/files:
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- `/etc/garage.toml`: Garage daemon's configuration (see below)
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- `/var/lib/garage/meta/`: Folder containing Garage's metadata,
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put this folder on a SSD if possible
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- `/var/lib/garage/data/`: Folder containing Garage's data,
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this folder will be your main data storage and must be on a large storage (e.g. large HDD)
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A valid `/etc/garage/garage.toml` for our cluster would look as follows:
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```toml
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metadata_dir = "/var/lib/garage/meta"
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data_dir = "/var/lib/garage/data"
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replication_mode = "3"
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compression_level = 2
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rpc_bind_addr = "[::]:3901"
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rpc_public_addr = "<this node's public IP>:3901"
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rpc_secret = "<RPC secret>"
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bootstrap_peers = []
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[s3_api]
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s3_region = "garage"
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api_bind_addr = "[::]:3900"
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root_domain = ".s3.garage"
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[s3_web]
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bind_addr = "[::]:3902"
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root_domain = ".web.garage"
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index = "index.html"
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```
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Check the following for your configuration files:
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- Make sure `rpc_public_addr` contains the public IP address of the node you are configuring.
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This parameter is optional but recommended: if your nodes have trouble communicating with
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one another, consider adding it.
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- Make sure `rpc_secret` is the same value on all nodes. It should be a 32-bytes hex-encoded secret key.
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You can generate such a key with `openssl rand -hex 32`.
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## Starting Garage using Docker
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On each machine, you can run the daemon with:
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```bash
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docker run \
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-d \
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--name garaged \
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--restart always \
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--network host \
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-v /etc/garage.toml:/etc/garage.toml \
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-v /var/lib/garage/meta:/var/lib/garage/meta \
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-v /var/lib/garage/data:/var/lib/garage/data \
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lxpz/garage_amd64:v0.4.0
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```
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It should be restarted automatically at each reboot.
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Please note that we use host networking as otherwise Docker containers
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can not communicate with IPv6.
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Upgrading between Garage versions should be supported transparently,
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but please check the relase notes before doing so!
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To upgrade, simply stop and remove this container and
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start again the command with a new version of Garage.
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## Controling the daemon
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The `garage` binary has two purposes:
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- it acts as a daemon when launched with `garage server`
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- it acts as a control tool for the daemon when launched with any other command
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Ensure an appropriate `garage` binary (the same version as your Docker image) is available in your path.
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If your configuration file is at `/etc/garage.toml`, the `garage` binary should work with no further change.
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You can test your `garage` CLI utility by running a simple command such as:
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```bash
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garage status
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```
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At this point, nodes are not yet talking to one another.
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Your output should therefore look like follows:
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```
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Mercury$ garage status
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==== HEALTHY NODES ====
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ID Hostname Address Tag Zone Capacity
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563e1ac825ee3323… Mercury [fc00:1::1]:3901 NO ROLE ASSIGNED
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```
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## Connecting nodes together
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When your Garage nodes first start, they will generate a local node identifier
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(based on a public/private key pair).
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To obtain the node identifier of a node, once it is generated,
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run `garage node id`.
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This will print keys as follows:
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```bash
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Mercury$ garage node id
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563e1ac825ee3323aa441e72c26d1030d6d4414aeb3dd25287c531e7fc2bc95d@[fc00:1::1]:3901
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Venus$ garage node id
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86f0f26ae4afbd59aaf9cfb059eefac844951efd5b8caeec0d53f4ed6c85f332@[fc00:1::2]:3901
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etc.
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```
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You can then instruct nodes to connect to one another as follows:
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```bash
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# Instruct Venus to connect to Mercury (this will establish communication both ways)
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Venus$ garage node connect 563e1ac825ee3323aa441e72c26d1030d6d4414aeb3dd25287c531e7fc2bc95d@[fc00:1::1]:3901
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```
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You don't nead to instruct all node to connect to all other nodes:
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nodes will discover one another transitively.
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Now if your run `garage status` on any node, you should have an output that looks as follows:
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```
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==== HEALTHY NODES ====
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ID Hostname Address Tag Zone Capacity
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563e1ac825ee3323… Mercury [fc00:1::1]:3901 NO ROLE ASSIGNED
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86f0f26ae4afbd59… Venus [fc00:1::2]:3901 NO ROLE ASSIGNED
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68143d720f20c89d… Earth [fc00:B::1]:3901 NO ROLE ASSIGNED
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212f7572f0c89da9… Mars [fc00:F::1]:3901 NO ROLE ASSIGNED
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```
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## Creating a cluster layout
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We will now inform Garage of the disk space available on each node of the cluster
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as well as the zone (e.g. datacenter) in which each machine is located.
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This information is called the **cluster layout** and consists
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of a role that is assigned to each active cluster node.
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For our example, we will suppose we have the following infrastructure
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(Capacity, Identifier and Zone are specific values to Garage described in the following):
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| Location | Name | Disk Space | `Capacity` | `Identifier` | `Zone` |
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|----------|---------|------------|------------|--------------|--------------|
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| Paris | Mercury | 1 To | `10` | `563e` | `par1` |
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| Paris | Venus | 2 To | `20` | `86f0` | `par1` |
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| London | Earth | 2 To | `20` | `6814` | `lon1` |
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| Brussels | Mars | 1.5 To | `15` | `212f` | `bru1` |
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#### Node identifiers
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After its first launch, Garage generates a random and unique identifier for each nodes, such as:
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```
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563e1ac825ee3323aa441e72c26d1030d6d4414aeb3dd25287c531e7fc2bc95d
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```
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Often a shorter form can be used, containing only the beginning of the identifier, like `563e`,
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which identifies the server "Mercury" located in "Paris" according to our previous table.
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The most simple way to match an identifier to a node is to run:
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```
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garage status
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```
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It will display the IP address associated with each node;
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from the IP address you will be able to recognize the node.
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#### Zones
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Zones are simply a user-chosen identifier that identify a group of server that are grouped together logically.
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It is up to the system administrator deploying Garage to identify what does "grouped together" means.
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In most cases, a zone will correspond to a geographical location (i.e. a datacenter).
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Behind the scene, Garage will use zone definition to try to store the same data on different zones,
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in order to provide high availability despite failure of a zone.
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#### Capacity
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Garage reasons on an abstract metric about disk storage that is named the *capacity* of a node.
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The capacity configured in Garage must be proportional to the disk space dedicated to the node.
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Capacity values must be **integers** but can be given any signification.
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Here we chose that 1 unit of capacity = 100 GB.
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Note that the amount of data stored by Garage on each server may not be strictly proportional to
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its capacity value, as Garage will priorize having 3 copies of data in different zones,
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even if this means that capacities will not be strictly respected. For example in our above examples,
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nodes Earth and Mars will always store a copy of everything each, and the third copy will
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have 66% chance of being stored by Venus and 33% chance of being stored by Mercury.
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#### Injecting the topology
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Given the information above, we will configure our cluster as follow:
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```bash
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garage layout assign -z par1 -c 10 -t mercury 563e
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garage layout assign -z par1 -c 20 -t venus 86f0
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garage layout assign -z lon1 -c 20 -t earth 6814
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garage layout assign -z bru1 -c 15 -t mars 212f
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```
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At this point, the changes in the cluster layout have not yet been applied.
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To show the new layout that will be applied, call:
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```bash
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garage layout show
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```
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Once you are satisfied with your new layout, apply it with:
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```bash
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garage layout apply
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```
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**WARNING:** if you want to use the layout modification commands in a script,
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make sure to read [this page](@/documentation/reference-manual/layout.md) first.
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## Using your Garage cluster
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Creating buckets and managing keys is done using the `garage` CLI,
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and is covered in the [quick start guide](@/documentation/quick-start/_index.md).
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Remember also that the CLI is self-documented thanks to the `--help` flag and
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the `help` subcommand (e.g. `garage help`, `garage key --help`).
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Configuring S3-compatible applicatiosn to interact with Garage
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is covered in the [Integrations](@/documentation/connect/_index.md) section.
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