#subgraph #graph #graph-algorithms #enumeration #isomorphism #graph-traversal #esu

app memoesu

fast subgraph enumeration on graphs using a memoized parallel ESU algorithm

5 releases

0.2.7 Jul 5, 2023
0.2.6 Jun 27, 2023
0.2.5 Jun 27, 2023
0.2.4 Jun 26, 2023
0.2.3 Jun 26, 2023

#3 in #isomorphism

31 downloads per month

MIT license

92KB
2K SLoC

MEMO-ESU

Enumeration of subgraphs using a memoized parallel ESU algorithm.

Background

Subgraph enumeration is the process of counting how many times a specific subgraph appears in a larger graph.

This requires traversing the graph, avoiding double counting sets of nodes, and calculating isomorphism for each subgraph to increments its abundance.

The ESU algorithm was described by Wernicke in 20051 which describes a graph traversal method similar to DFS but only following child nodes with larger node labels.

This is a very fast subgraph identification method, but at the end of every subgraph identification a call is made to NAUTY2 to calculate that subgraphs canonical labeling, which is the rate limiting step of the algorithm.

This program is a rust implementation of the ESU algorithm, but with an additional memoization step to avoid making multiple calls to NAUTY by hashing the bitvector representing the adjacency matrix of the subgraph. It also allows the user to run the ESU algorithm in parallel across multiple threads to speed up the enumeration.

Installation

Using Cargo

This can be installed using cargo the rust package manager:

cargo install memoesu

Installing Cargo

You can install the rust package manager cargo with the following command:

curl https://sh.rustup.rs -sSf | sh

Usage

Enumeration

The basic usage of this tool is to run the enumerate subcommand, which accepts at minimum the path to a plaintext graph and the size of the subgraphs to enumerate.

In the following command we enumerate all size 4 subgraphs in the ecoli graph.

memoesu enumerate -i example/ecoli.txt -s 4

By default, the graph is assumed to be directed, but you can also force the graph to be undirected and count all undirected subgraphs.

memoesu enumerate -i example/ecoli.txt -s 4 -u

You can also specify multiple threads, in this case 8.

memoesu enumerate -i example/ecoli.txt -s 4 -t 8

Format

memoesu will only accept networks with integer label graphs.

However, you can reformat a string labeled graph into an integer graph using the format subcommand

memoesu format -i example/unformatted.txt -o formatted

Which will generate two new files with the formatted prefix:

formatted.network.tsv and formatted.dictionary.tsv

which give the integer labeled network and a dictionary relating every label to their respective integer.

Switch

To calculate network motifs we need to first create a background set of random graphs that are comparable to the original network.

The method we employ here is the random switching method, originally used in the mfinder tool, and described by Milo3, which describes an algorithm to generate random graphs with equivalent degree sequences to the original graph.

To perform the switching algorithm to generate a random graph we can use the switch subcommand:

memoesu switch -i example/example.txt

This creates a new random graph with an identical degree sequence to the original graph.

Groups

The NAUTY canonical graph calculation also calculates orbit information for every node in the subgraph. To gather both subgraph membership, as well as subgraph node label and orbit, for every node in the original graph we can use the groups subcommand.

Currently this is only supported as a single-threaded command.

memoesu groups -i example/example.txt -s 3 -o groups.txt

This will output a table whose columns are:

  1. node_index
  2. subgraph graph6 string
  3. node_label (i.e. position in subgraph)
  4. orbit

References

  1. S. Wernicke, “Efficient Detection of Network Motifs,” IEEE/ACM Trans. Comput. Biol. and Bioinf., vol. 3, no. 4, pp. 347–359, Oct. 2006, doi: 10.1109/TCBB.2006.51.
  2. B. D. McKay and A. Piperno, “Practical graph isomorphism, II,” Journal of Symbolic Computation, vol. 60, pp. 94–112, Jan. 2014, doi: 10.1016/j.jsc.2013.09.003.
  3. R. Milo, N. Kashtan, S. Itzkovitz, M. E. J. Newman, and U. Alon, “On the uniform generation of random graphs with prescribed degree sequences.” arXiv, May 30, 2004. Accessed: Jun. 26, 2023. [Online]. Available: http://arxiv.org/abs/cond-mat/0312028

Dependencies

~10–18MB
~243K SLoC