Main classes implementing the WebGraph algorithms.
Classes implementing useful algorithms on graphs.
Example classes that do nice things using the WebGraph framework.
Main classes implementing labelling for immutable graphs.
WebGraph is a framework to study the web graph. It provides simple ways to manage very large graphs, exploiting modern compression techniques. More precisely, it is currently made of:
HyperBall, which has been used to show that Facebook has just four degrees of separation.
In the end, with WebGraph you can access and analyse very large web graphs. Using WebGraph is as easy as installing a few jar files and downloading a data set.
You are welcome to use and improve WebGraph! If you find our software useful for your research, please quote our paper “The WebGraph Framework I: Compression Techniques”, by Paolo Boldi and Sebastiano Vigna, in Proc. of the Thirteenth World–Wide Web Conference, pages 595−601, 2004, ACM Press.
For in-depth information on the Webgraph framework, you should have a look at its home page, where you can find some papers about the compression techniques it uses. Datasets are available at the LAW web site.
The classes of interest for the casual Webgraph user are
ImmutableGraph, which specifies the access
methods for an immutable graph,
which allow to retrieve or recompress a graph stored in the format
described in The WebGraph
Framework I: Compression Techniques, and
provides several ways to transform an
it.unimi.dsi.webgraph.examples contains useful
examples that show how to access sequentially and randomly an immutable
java -server it.unimi.dsi.webgraph.ASCIIGraph sourcebasename destor
java -server it.unimi.dsi.webgraph.ArcListASCIIGraph sourcebasename dest
Please consult the documentation and the command-line help of these two classes to get more information.
If you want to import your own data into WebGraph, you must write
an implementation of
exposes your data. A simple example is given in
a stub class exposing a simple, noncompressed binary format as an
Once your data is exposed in that way, you can get a compressed version
store() method of your class of interest. Often, there
is a main method (see, e.g.,
will load your class and invoke
store() for you.
As an alternative, the class
can be used to read graphs specified in a very simple ASCII format. The class
that the file can be just piped into a class offering a main method that supports
You can also generate a graph in ASCII format and read it using
graph will not be loaded into main memory.
ASCIIGraph requires listing the successors of each
node on a separate line. If your graph is specified arc by arc (one arc per line) you
ShiftedByOneArcListASCIIGraph can be used if your input
data numbers (rather insensibly) nodes starting from one.
Another possibility is to specify your graph incrementally. which just involves enumerating arrays of successors for each node.
Arc-labelled graphs are represented using implementations of
Most arc-labelled graphs are based on an underlying
ArcLabelledImmutableGraph implementation just provides
label handling. The example
shows how to expose your data as an instance of
so you can save your data using your preferred combination of implementations.