Graph4Rec is a universal and large-scale toolkit with graph neural networks for recommender systems. It contains a large-scale graph engine to store graph data and a parameter server to support distributed GNN training. We also unify the paradigm to train GNN models into the following parts: graph inputs, random walk generation, ego graphs generation, pairs generation and GNNs selection. From this training pipeline, one can easily establish his own GNN model with a few configurations.
Highlighted features:
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Richness: Pre-built rich graph models, including walk-based and GNN-based models.
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Flexibility: With a few configurations, one can easily launch single or distributed training.
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Large-scale: With the help of graph engine and parameter server, Graph4Rec supports industrial graph representation training.
Please install paddlepaddle and pgl before using Graph4Rec.
python -m pip install paddlepaddle-gpu==2.2.2
python -m pip install pgl==2.1.5
Suppose there are three different types of nodes, namely "u", "t" and "f". They can form three kinds of edges, namely "u2t (u-t)", "u2f (u-f)" and "t2f (t-f)". Then the format of edges file is as follows:
src_node_id \t dst_node_id
for example:
12345 \t 23345
12345 \t 23346
12346 \t 23345
If there are edge weights, one can directly add the weight behind each edge, the format is as follows:
src_node_id \t dst_node_id \t edge_weight
for example:
12345 \t 23345 \t 0.4
12345 \t 23346 \t 0.2
12346 \t 23345 \t 0.8
The format of the node types file is as follows:
node_type \t node_id
for example:
u \t 12345
u \t 12346
t \t 23345
f \t 23346
You can also find out the specific data format in ./toy_data.
Now we support distributed loading graph data using PGL Graph Engine. We also develop a simple tutorial to show how to launch a graph engine, please refer to here.
To launch a distributed graph service, please follow the steps below.
The first step is to set the IP list for each graph server. Each IP address with port represents a server. In ./toy_data/ip_list.txt file, we set up 4 graph server as follow for demo:
127.0.0.1:8813
127.0.0.1:8814
127.0.0.1:8815
127.0.0.1:8816
Before launching the graph engine, you should set up the below hyper-parameters in configuration file in ./user_configs/metapath2vec.yaml:
etype2files: "u2buy2t:./toy_data/u2buy2i.txt,u2click2i:./toy_data/u2click2i.txt"
ntype2files: "u:./toy_data/node_types.txt,i:./toy_data/node_types.txt"
symmetry: True
shard_num: 1000
Then, we can launch the graph engine with the help of OpenMPI.
mpirun -np 4 python -m pgl.distributed.launch --ip_config ./toy_data/ip_list.txt --conf ./user_configs/metapath2vec.yaml --mode mpi --shard_num 1000
If you didn't install OpenMPI, you can launch the graph engine manually.
Fox example, if we want to use 4 servers, we should run the following command separately on 4 terminals.
# terminal 3
python -m pgl.distributed.launch --ip_config ./toy_data/ip_list.txt --conf ./user_configs/metapath2vec.yaml --shard_num 1000 --server_id 3
# terminal 2
python -m pgl.distributed.launch --ip_config ./toy_data/ip_list.txt --conf ./user_configs/metapath2vec.yaml --shard_num 1000 --server_id 2
# terminal 1
python -m pgl.distributed.launch --ip_config ./toy_data/ip_list.txt --conf ./user_configs/metapath2vec.yaml --shard_num 1000 --server_id 1
# terminal 0
python -m pgl.distributed.launch --ip_config ./toy_data/ip_list.txt --conf ./user_configs/metapath2vec.yaml --shard_num 1000 --server_id 0
Note that the shard_num should be the same as in configuration file.
After successfully launching the graph engine, you can run the below command to train the model in different modes.
# Training
cd ./env_run/src
export CUDA_VISIBLE_DEVICES=0
python train.py --config ../../user_configs/metapath2vec.yaml --ip ../../toy_data/ip_list.txt
# Inference
python infer.py --config ../../user_configs/metapath2vec.yaml \
--ip ../../toy_data/ip_list.txt \
--save_dir ./save_embed/ \
--infer_from ../../ckpt_custom/metapath2vec.0712/ckpt.pdparams
# The node embeddings will be saved in ./save_embed/embedding.txt
# Training
cd ./env_run/src
CPU_NUM=12 fleetrun --log_dir ../../fleet_logs \
--worker_num 4 \
--server_num 4 \
dist_cpu_train.py --config ../../user_configs/metapath2vec.yaml \
--ip ../../toy_data/ip_list.txt
# Inference
CPU_NUM=12 fleetrun --log_dir ../../fleet_logs_infer \
--worker_num 4 \
--server_num 4 \
dist_cpu_infer.py --config ../../user_configs/metapath2vec.yaml \
--ip ../../toy_data/ip_list.txt \
--save_dir ./save_dist_embed/ \
--infer_from ../../ckpt_custom/metapath2vec.0712/
# The node embeddings will be saved in ./save_dist_embed/
Note that the worker_num and server_num in inference stage should be the same as in training stage.
The training log will be saved in ../../fleet_logs.
Suppose we perform distributed training on two machines, and deploy a server node and a trainer node on each machine. You only need to specify the ip and port list of the service node --servers and the ip and port list of the training node --workers, to perform multi-machine training.
In the following example, xx.xx.xx.xx represents machine 1, yy.yy.yy.yy represents machine 2. Then, runing the following commands in each machine.
# Training
cd ./env_run/src
export PADDLE_WITH_GLOO=1
export FLAGS_START_PORT=30510 # http port for multi-machine communication
CPU_NUM=12 fleetrun --log_dir ../../fleet_logs \
--workers "xx.xx.xx.xx:8170,yy.yy.yy.yy:8171" \
--servers "xx.xx.xx.xx:8270,yy.yy.yy.yy:8271" \
dist_cpu_train.py --config ../../user_configs/metapath2vec.yaml \
--ip ../../toy_data/ip_list.txt
If you use Graph4Rec in a scientific publication, we would appreciate citations to the following paper:
@article{Graph4Rec,
title={Graph4Rec: A Universal Toolkit with Graph Neural Networks for Recommender Systems},
author={Li, Weibin and He, Mingkai and Huang, Zhengjie and Wang, Xianming and Feng, Shikun and Wu, Zhihua and Su, Weiyue and Sun, Yu},
journal={arXiv preprint arXiv:2112.01035},
year={2021}
}