ArangoDB v3.13 is under development and not released yet. This documentation is not final and potentially incomplete.

The scalability of ArangoDB and its data models

ArangoDB supports scaling horizontally and vertically, and each supported data model has different properties when scaling to large datasets

Horizontal and vertical scalability

ArangoDB is a distributed database system supporting multiple data models, and can thus be scaled horizontally, that is, by using many servers, typically based on commodity hardware. This approach not only delivers performance as well as capacity improvements, but also achieves resilience by means of replication and automatic fail-over. Furthermore, you can build systems that scale their capacity dynamically up and down automatically according to demand.

You can also scale ArangoDB vertically, that is, by using ever larger and more powerful servers. There is no built-in limitation in ArangoDB, for example, the server will automatically use more threads if more CPUs are present. However, scaling vertically has the disadvantage that the costs grow faster than linear with the size of the server, and none of the resilience and dynamical capabilities can be achieved in this way.

Key/value pairs

The key/value store data model is the easiest to scale. In ArangoDB, this is implemented in the sense that a document collection always has a primary key _key attribute and in the absence of further secondary indexes the document collection behaves like a simple key/value store.

The only operations that are possible in this context are single key lookups and key/value pair insertions and updates. If _key is the only sharding attribute then the sharding is done with respect to the primary key and all these operations scale linearly. If the sharding is done using different shard keys, then a lookup of a single key involves asking all shards and thus does not scale linearly.

Document store

For the document store case even in the presence of secondary indexes essentially the same arguments apply, since an index for a sharded collection is simply the same as a local index for each shard. Therefore, single document operations still scale linearly with the size of the cluster, unless a special sharding configuration makes lookups or write operations more expensive.

Complex queries and joins

The AQL query language allows complex queries, using multiple collections, secondary indexes as well as joins. In particular with the latter, scaling can be a challenge, since if the data to be joined resides on different machines, a lot of communication has to happen. The AQL query execution engine organizes a data pipeline across the cluster to put together the results in the most efficient way. The query optimizer is aware of the cluster structure and knows what data is where and how it is indexed. Therefore, it can arrive at an informed decision about what parts of the query ought to run where in the cluster.

Nevertheless, for certain complicated joins, there are limits as to what can be achieved.

Graph database

Graph databases are particularly good at queries on graphs that involve paths in the graph of an a priori unknown length. For example, finding the shortest path between two vertices in a graph, or finding all paths that match a certain pattern starting at a given vertex are such examples.

However, if the vertices and edges along the occurring paths are distributed across the cluster, then a lot of communication is necessary between nodes, and performance suffers. To achieve good performance at scale, it is therefore necessary to get the distribution of the graph data across the shards in the cluster right. Most of the time, the application developers and users of ArangoDB know best, how their graphs are structured. Therefore, ArangoDB allows users to specify, according to which attributes the graph data is sharded. A useful first step is usually to make sure that the edges originating at a vertex reside on the same cluster node as the vertex.