forked from Deuxfleurs/garage
274 lines
12 KiB
Markdown
274 lines
12 KiB
Markdown
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title = "Cluster layout management"
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weight = 20
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The cluster layout in Garage is a table that assigns to each node a role in
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the cluster. The role of a node in Garage can either be a storage node with
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a certain capacity, or a gateway node that does not store data and is only
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used as an API entry point for faster cluster access.
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An introduction to building cluster layouts can be found in the [production deployment](@/documentation/cookbook/real-world.md) page.
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In Garage, all of the data that can be stored in a given cluster is divided
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into slices which we call *partitions*. Each partition is stored by
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one or several nodes in the cluster
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(see [`replication_mode`](@/documentation/reference-manual/configuration.md#replication-mode)).
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The layout determines the correspondence between these partition,
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which exist on a logical level, and actual storage nodes.
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## How cluster layouts work in Garage
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A cluster layout is composed of the following components:
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- a table of roles assigned to nodes, defined by the user
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- an optimal assignation of partitions to nodes, computed by an algorithm that is ran once when calling `garage layout apply` or the ApplyClusterLayout API endpoint
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- a version number
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Garage nodes will always use the cluster layout with the highest version number.
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Garage nodes also maintain and synchronize between them a set of proposed role
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changes that haven't yet been applied. These changes will be applied (or
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canceled) in the next version of the layout.
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All operations on the layout can be realized using the `garage` CLI or using the
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[administration API endpoint](@/documentation/reference-manual/admin-api.md).
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We give here a description of CLI commands, the admin API semantics are very similar.
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The following commands insert modifications to the set of proposed role changes
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for the next layout version (but they do not create the new layout immediately):
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```bash
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garage layout assign [...]
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garage layout remove [...]
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```
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The following command can be used to inspect the layout that is currently set in the cluster
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and the changes proposed for the next layout version, if any:
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```bash
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garage layout show
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```
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The following commands create a new layout with the specified version number,
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that either takes into account the proposed changes or cancels them:
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```bash
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garage layout apply --version <new_version_number>
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garage layout revert --version <new_version_number>
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```
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The version number of the new layout to create must be 1 + the version number
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of the previous layout that existed in the cluster. The `apply` and `revert`
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commands will fail otherwise.
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## Warnings about Garage cluster layout management
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**⚠️ Never make several calls to `garage layout apply` or `garage layout
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revert` with the same value of the `--version` flag. Doing so can lead to the
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creation of several different layouts with the same version number, in which
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case your Garage cluster will become inconsistent until fixed.** If a call to
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`garage layout apply` or `garage layout revert` has failed and `garage layout
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show` indicates that a new layout with the given version number has not been
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set in the cluster, then it is fine to call the command again with the same
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version number.
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If you are using the `garage` CLI by typing individual commands in your
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shell, you shouldn't have much issues as long as you run commands one after
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the other and take care of checking the output of `garage layout show`
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before applying any changes.
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If you are using the `garage` CLI or the admin API to script layout changes,
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follow the following recommendations:
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- If using the CLI, make all of your `garage` CLI calls to the same RPC host.
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If using the admin API, make all of your API calls to the same Garage node. Do
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not connect to individual nodes to send them each a piece of the layout changes
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you are making, as the changes propagate asynchronously between nodes and might
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not all be taken into account at the time when the new layout is applied.
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- **Only call `garage layout apply`/ApplyClusterLayout once**, and call it
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**strictly after** all of the `layout assign` and `layout remove`
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commands/UpdateClusterLayout API calls have returned.
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## Understanding unexpected layout calculations
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When adding, removing or modifying nodes in a cluster layout, sometimes
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unexpected assigntations of partitions to node can occur. These assignations
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are in fact normal and logical, given the objectives of the algorihtm. Indeed,
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**the layout algorithm prioritizes moving less data between nodes over the fact
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of achieving equal distribution of load. It also tries to use all links between
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pairs of nodes in equal proportions when moving data.** This section presents
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two examples and illustrates how one can control Garage's behavior to obtain
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the desired results.
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### Example 1
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In this example, a cluster is originally composed of 3 nodes in 3 different
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zones (data centers). The three nodes are of equal capacity, therefore they
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are all fully exploited and all store a copy of all of the data in the cluster.
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Then, a fourth node of the same size is added in the datacenter `dc1`.
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As illustrated by the following, **Garage will by default not store any data on the new node**:
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```
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$ garage layout show
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==== CURRENT CLUSTER LAYOUT ====
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ID Tags Zone Capacity Usable capacity
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b10c110e4e854e5a node1 dc1 1000.0 MB 1000.0 MB (100.0%)
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a235ac7695e0c54d node2 dc2 1000.0 MB 1000.0 MB (100.0%)
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62b218d848e86a64 node3 dc3 1000.0 MB 1000.0 MB (100.0%)
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Zone redundancy: maximum
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Current cluster layout version: 6
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==== STAGED ROLE CHANGES ====
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ID Tags Zone Capacity
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a11c7cf18af29737 node4 dc1 1000.0 MB
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==== NEW CLUSTER LAYOUT AFTER APPLYING CHANGES ====
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ID Tags Zone Capacity Usable capacity
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b10c110e4e854e5a node1 dc1 1000.0 MB 1000.0 MB (100.0%)
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a11c7cf18af29737 node4 dc1 1000.0 MB 0 B (0.0%)
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a235ac7695e0c54d node2 dc2 1000.0 MB 1000.0 MB (100.0%)
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62b218d848e86a64 node3 dc3 1000.0 MB 1000.0 MB (100.0%)
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Zone redundancy: maximum
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==== COMPUTATION OF A NEW PARTITION ASSIGNATION ====
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Partitions are replicated 3 times on at least 3 distinct zones.
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Optimal partition size: 3.9 MB (3.9 MB in previous layout)
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Usable capacity / total cluster capacity: 3.0 GB / 4.0 GB (75.0 %)
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Effective capacity (replication factor 3): 1000.0 MB
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A total of 0 new copies of partitions need to be transferred.
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dc1 Tags Partitions Capacity Usable capacity
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b10c110e4e854e5a node1 256 (0 new) 1000.0 MB 1000.0 MB (100.0%)
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a11c7cf18af29737 node4 0 (0 new) 1000.0 MB 0 B (0.0%)
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TOTAL 256 (256 unique) 2.0 GB 1000.0 MB (50.0%)
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dc2 Tags Partitions Capacity Usable capacity
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a235ac7695e0c54d node2 256 (0 new) 1000.0 MB 1000.0 MB (100.0%)
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TOTAL 256 (256 unique) 1000.0 MB 1000.0 MB (100.0%)
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dc3 Tags Partitions Capacity Usable capacity
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62b218d848e86a64 node3 256 (0 new) 1000.0 MB 1000.0 MB (100.0%)
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TOTAL 256 (256 unique) 1000.0 MB 1000.0 MB (100.0%)
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```
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While unexpected, this is logical because of the following facts:
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- storing some data on the new node does not help increase the total quantity
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of data that can be stored on the cluster, as the two other zones (`dc2` and
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`dc3`) still need to store a full copy of everything, and their capacity is
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still the same;
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- there is therefore no need to move any data on the new node as this would be pointless;
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- moving data to the new node has a cost which the algorithm decides to not pay if not necessary.
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This distribution of data can however not be what the administrator wanted: if
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they added a new node to `dc1`, it might be because the existing node is too
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slow, and they wish to divide its load by half. In that case, what they need to
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do to force Garage to distribute the data between the two nodes is to attribute
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only half of the capacity to each node in `dc1` (in our example, 500M instead of 1G).
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In that case, Garage would determine that to be able to store 1G in total, it
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would need to store 500M on the old node and 500M on the added one.
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### Example 2
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The following example is a slightly different scenario, where `dc1` had two
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nodes that were used at 50%, and `dc2` and `dc3` each have one node that is
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100% used. All node capacities are the same.
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Then, a node from `dc1` is moved into `dc3`. One could expect that the roles of
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`dc1` and `dc3` would simply be swapped: the remaining node in `dc1` would be
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used at 100%, and the two nodes now in `dc3` would be used at 50%. Instead,
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this happens:
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```
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==== CURRENT CLUSTER LAYOUT ====
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ID Tags Zone Capacity Usable capacity
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b10c110e4e854e5a node1 dc1 1000.0 MB 500.0 MB (50.0%)
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a11c7cf18af29737 node4 dc1 1000.0 MB 500.0 MB (50.0%)
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a235ac7695e0c54d node2 dc2 1000.0 MB 1000.0 MB (100.0%)
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62b218d848e86a64 node3 dc3 1000.0 MB 1000.0 MB (100.0%)
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Zone redundancy: maximum
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Current cluster layout version: 8
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==== STAGED ROLE CHANGES ====
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ID Tags Zone Capacity
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a11c7cf18af29737 node4 dc3 1000.0 MB
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==== NEW CLUSTER LAYOUT AFTER APPLYING CHANGES ====
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ID Tags Zone Capacity Usable capacity
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b10c110e4e854e5a node1 dc1 1000.0 MB 1000.0 MB (100.0%)
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a235ac7695e0c54d node2 dc2 1000.0 MB 1000.0 MB (100.0%)
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62b218d848e86a64 node3 dc3 1000.0 MB 753.9 MB (75.4%)
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a11c7cf18af29737 node4 dc3 1000.0 MB 246.1 MB (24.6%)
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Zone redundancy: maximum
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==== COMPUTATION OF A NEW PARTITION ASSIGNATION ====
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Partitions are replicated 3 times on at least 3 distinct zones.
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Optimal partition size: 3.9 MB (3.9 MB in previous layout)
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Usable capacity / total cluster capacity: 3.0 GB / 4.0 GB (75.0 %)
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Effective capacity (replication factor 3): 1000.0 MB
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A total of 128 new copies of partitions need to be transferred.
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dc1 Tags Partitions Capacity Usable capacity
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b10c110e4e854e5a node1 256 (128 new) 1000.0 MB 1000.0 MB (100.0%)
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TOTAL 256 (256 unique) 1000.0 MB 1000.0 MB (100.0%)
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dc2 Tags Partitions Capacity Usable capacity
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a235ac7695e0c54d node2 256 (0 new) 1000.0 MB 1000.0 MB (100.0%)
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TOTAL 256 (256 unique) 1000.0 MB 1000.0 MB (100.0%)
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dc3 Tags Partitions Capacity Usable capacity
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62b218d848e86a64 node3 193 (0 new) 1000.0 MB 753.9 MB (75.4%)
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a11c7cf18af29737 node4 63 (0 new) 1000.0 MB 246.1 MB (24.6%)
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TOTAL 256 (256 unique) 2.0 GB 1000.0 MB (50.0%)
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```
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As we can see, the node that was moved to `dc3` (node4) is only used at 25% (approximatively),
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whereas the node that was already in `dc3` (node3) is used at 75%.
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This can be explained by the following:
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- node1 will now be the only node remaining in `dc1`, thus it has to store all
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of the data in the cluster. Since it was storing only half of it before, it has
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to retrieve the other half from other nodes in the cluster.
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- The data which it does not have is entirely stored by the other node that was
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in `dc1` and that is now in `dc3` (node4). There is also a copy of it on node2
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and node3 since both these nodes have a copy of everything.
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- node3 and node4 are the two nodes that will now be in a datacenter that is
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under-utilized (`dc3`), this means that those are the two candidates from which
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data can be removed to be moved to node1.
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- Garage will move data in equal proportions from all possible sources, in this
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case it means that it will tranfer 25% of the entire data set from node3 to
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node1 and another 25% from node4 to node1.
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This explains why node3 ends with 75% utilization (100% from before minus 25%
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that is moved to node1), and node4 ends with 25% (50% from before minus 25%
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that is moved to node1).
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This illustrates the second principle of the layout computation: **if there is
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a choice in moving data out of some nodes, then all links between pairs of
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nodes are used in equal proportions** (this is approximately true, there is
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randomness in the algorihtm to achieve this so there might be some small
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fluctuations, as we see above).
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