DeepWalk uses short random walks to learn representations for vertices in graphs.
- Example Usage
$deepwalk --input example_graphs/karate.adjlist --output karate.embeddings
--input: input_filename
--format adjlist
for an adjacency list, e.g:1 2 3 4 5 6 7 8 9 11 12 13 14 18 20 22 32 2 1 3 4 8 14 18 20 22 31 3 1 2 4 8 9 10 14 28 29 33 ...
--format edgelist
for an edge list, e.g:1 2 1 3 1 4 ...
--format mat
for a Matlab .mat file containing an adjacency matrix(note, you must also specify the variable name of the adjacency matrix
--matfile-variable-name
)
--output: output_filename
The output representations in skipgram format - first line is header, all other lines are node-id and d dimensional representation:
34 64 1 0.016579 -0.033659 0.342167 -0.046998 ... 2 -0.007003 0.265891 -0.351422 0.043923 ... ...
- Full Command List
- The full list of command line options is available with
$deepwalk --help
Here, we will show how to evaluate DeepWalk on the BlogCatalog dataset used in the DeepWalk paper. First, we run the following command to produce its DeepWalk embeddings:
deepwalk --format mat --input example_graphs/blogcatalog.mat --max-memory-data-size 0 --number-walks 80 --representation-size 128 --walk-length 40 --window-size 10 --workers 1 --output example_graphs/blogcatalog.embeddings
The parameters specified here are the same as in the paper.
If you are using a multi-core machine, try to set --workers
to a larger number for faster training.
On a single machine with 24 Xeon E5-2620 @ 2.00GHz CPUs, this command takes about 20 minutes to finish (--workers
is set to 20).
Then, we evaluate the learned embeddings on a multi-label node classification task with example_graphs/scoring.py
:
python example_graphs/scoring.py --emb example_graphs/blogcatalog.embeddings --network example_graphs/blogcatalog.mat --num-shuffle 10 --all
This command finishes in 8 minutes on the same machine. For faster evaluation, you can set --num-shuffle
to a smaller number, but expect more fluctuation in performance. The micro F1 and macro F1 scores we get with different ratio of labeled nodes are as follows:
% Labeled Nodes | 10% | 20% | 30% | 40% | 50% | 60% | 70% | 80% | 90% |
---|---|---|---|---|---|---|---|---|---|
Micro-F1 (%) | 35.86 | 38.51 | 39.96 | 40.76 | 41.51 | 41.85 | 42.27 | 42.35 | 42.40 |
Macro-F1 (%) | 21.08 | 23.98 | 25.71 | 26.73 | 27.68 | 28.28 | 28.88 | 28.70 | 28.21 |
Note that the current version of DeepWalk is based on a newer version of gensim, which may have a different implementation of the word2vec model. To completely reproduce the results in our paper, you will probably have to install an older version of gensim(version 0.10.2).
- numpy
- scipy
(may have to be independently installed) or pip install -r requirements.txt to install all dependencies
- cd deepwalk
- pip install -r requirements.txt
- python setup.py install
If you find DeepWalk useful in your research, we ask that you cite the following paper:
@inproceedings{Perozzi:2014:DOL:2623330.2623732, author = {Perozzi, Bryan and Al-Rfou, Rami and Skiena, Steven}, title = {DeepWalk: Online Learning of Social Representations}, booktitle = {Proceedings of the 20th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining}, series = {KDD '14}, year = {2014}, isbn = {978-1-4503-2956-9}, location = {New York, New York, USA}, pages = {701--710}, numpages = {10}, url = {http://doi.acm.org/10.1145/2623330.2623732}, doi = {10.1145/2623330.2623732}, acmid = {2623732}, publisher = {ACM}, address = {New York, NY, USA}, keywords = {deep learning, latent representations, learning with partial labels, network classification, online learning, social networks}, }
DeepWalk - Online learning of social representations.
- Free software: GPLv3 license