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Cayley

Cayley is an open-source graph inspired by the graph database behind [Freebase](http://freebase.com) and Google's [Knowledge Graph](https://en.wikipedia.org/wiki/Knowledge_Graph).

Its goal is to be a part of the developer's toolbox where Linked Data and graph-shaped data (semantic webs, social networks, etc) in general are concerned.

Build Status Trello Board

Features

  • Written in Go
  • Easy to get running (3 or 4 commands, below)
  • RESTful API
    • or a REPL if you prefer
  • Built-in query editor and visualizer
  • Multiple query languages:
    • JavaScript, with a Gremlin-inspired* graph object.
    • (simplified) MQL, for Freebase fans
  • Plays well with multiple backend stores:
  • Modular design; easy to extend with new languages and backends
  • Good test coverage
  • Speed, where possible.

Rough performance testing shows that, on consumer hardware and an average disk, 134m quads in LevelDB is no problem and a multi-hop intersection query -- films starring X and Y -- takes ~150ms.

* Note that while it's not exactly Gremlin, it certainly takes inspiration from that API. For this flavor, see the documentation.

Getting Started

Grab the latest release binary and extract it wherever you like.

If you prefer to build from source, see the documentation on the wiki at How to start hacking on Cayley or type

mkdir -p ~/cayley && cd ~/cayley
export GOPATH=`pwd`
export PATH=$PATH:~/cayley/bin
mkdir -p bin pkg src/github.com/google
cd src/github.com/google
git clone https://github.com/google/cayley
cd cayley
go get github.com/tools/godep
godep restore
go build ./cmd/cayley

Then cd to the directory and give it a quick test with:

./cayley repl --dbpath=data/testdata.nq

To run the web frontend, replace the "repl" command with "http"

./cayley http --dbpath=data/testdata.nq

You should see a cayley> REPL prompt. Go ahead and give it a try:

// Simple math
cayley> 2 + 2

// JavaScript syntax
cayley> x = 2 * 8
cayley> x

// See all the entities in this small follow graph.
cayley> graph.Vertex().All()

// See only dani.
cayley> graph.Vertex("dani").All()

// See who dani follows.
cayley> graph.Vertex("dani").Out("follows").All()

Running the visualizer on the web frontend

To run the visualizer: click on visualize and enter:

// Visualize who dani follows.
g.V("dani").Tag("source").Out("follows").Tag("target").All()

The visualizer expects to tag nodes as either "source" or "target." Your source is represented as a blue node. While your target is represented as an orange node. The idea being that our node relationship goes from blue to orange (source to target).

Sample Data

For somewhat more interesting data, a sample of 30k movies from Freebase comes in the checkout.

./cayley repl --dbpath=data/30kmoviedata.nq.gz

To run the web frontend, replace the "repl" command with "http"

./cayley http --dbpath=data/30kmoviedata.nq.gz

And visit port 64210 on your machine, commonly http://localhost:64210

Running queries

The default environment is based on Gremlin and is simply a JavaScript environment. If you can write jQuery, you can query a graph.

You'll notice we have a special object, graph or g, which is how you can interact with the graph.

The simplest query is merely to return a single vertex. Using the 30kmoviedata.nq dataset from above, let's walk through some simple queries:

// Query all vertices in the graph, limit to the first 5 vertices found.
graph.Vertex().GetLimit(5)

// Start with only one vertex, the literal name "Humphrey Bogart", and retrieve all of them.
graph.Vertex("Humphrey Bogart").All()

// `g` and `V` are synonyms for `graph` and `Vertex` respectively, as they are quite common.
g.V("Humphrey Bogart").All()

// "Humphrey Bogart" is a name, but not an entity. Let's find the entities with this name in our dataset.
// Follow links that are pointing In to our "Humphrey Bogart" node with the predicate "name".
g.V("Humphrey Bogart").In("name").All()

// Notice that "name" is a generic predicate in our dataset.
// Starting with a movie gives a similar effect.
g.V("Casablanca").In("name").All()

// Relatedly, we can ask the reverse; all ids with the name "Casablanca"
g.V().Has("name", "Casablanca").All()

You may start to notice a pattern here: with Gremlin, the query lines tend to:

Start somewhere in the graph | Follow a path | Run the query with "All" or "GetLimit"

g.V("Casablanca") | .In("name") | .All()

And these pipelines continue...

// Let's get the list of actors in the film
g.V().Has("name","Casablanca")
  .Out("/film/film/starring").Out("/film/performance/actor")
  .Out("name").All()

// But this is starting to get long. Let's use a morphism -- a pre-defined path stored in a variable -- as our linkage

var filmToActor = g.Morphism().Out("/film/film/starring").Out("/film/performance/actor")

g.V().Has("name", "Casablanca").Follow(filmToActor).Out("name").All()

There's more in the JavaScript API Documentation, but that should give you a feel for how to walk around the graph.

Disclaimer

Not a Google project, but created and maintained by a Googler, with permission from and assignment to Google, under the Apache License, version 2.0.

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