未验证 提交 883471f5 编写于 作者: W Weiyue Su 提交者: GitHub

Merge pull request #61 from PaddlePaddle/develop

pgl v1.1
<img src="./docs/source/_static/logo.png" alt="The logo of Paddle Graph Learning (PGL)" width="320"> <img src="./docs/source/_static/logo.png" alt="The logo of Paddle Graph Learning (PGL)" width="320">
[![PyPi Latest Release](https://img.shields.io/pypi/v/pgl.svg)](https://pypi.org/project/pgl/)
[![License](https://img.shields.io/badge/License-Apache%202.0-blue.svg)](./LICENSE)
[DOC](https://pgl.readthedocs.io/en/latest/) | [Quick Start](https://pgl.readthedocs.io/en/latest/quick_start/instruction.html) | [中文](./README.zh.md) [DOC](https://pgl.readthedocs.io/en/latest/) | [Quick Start](https://pgl.readthedocs.io/en/latest/quick_start/instruction.html) | [中文](./README.zh.md)
## Breaking News !!
PGL v1.1 2020.4.29
- You can find **ERNIESage**, a novel model for modeling text and graph structures, and its introduction [here](./examples/erniesage/).
- PGL for [Open Graph Benchmark](https://github.com/snap-stanford/ogb) examples can be find [here](./ogb_examples/).
- We add newly graph level operators like **GraphPooling** and [**GraphNormalization**](https://arxiv.org/abs/2003.00982) for graph level predictions.
- We relase a PGL-KE toolkit [here](./examples/pgl-ke) including classical knowledge graph embedding t algorithms like TransE, TransR, RotatE.
------
Paddle Graph Learning (PGL) is an efficient and flexible graph learning framework based on [PaddlePaddle](https://github.com/PaddlePaddle/Paddle). Paddle Graph Learning (PGL) is an efficient and flexible graph learning framework based on [PaddlePaddle](https://github.com/PaddlePaddle/Paddle).
<img src="./docs/source/_static/framework_of_pgl.png" alt="The Framework of Paddle Graph Learning (PGL)" width="800"> <img src="./docs/source/_static/framework_of_pgl_en.png" alt="The Framework of Paddle Graph Learning (PGL)" width="800">
The newly released PGL supports heterogeneous graph learning on both walk based paradigm and message-passing based paradigm by providing MetaPath sampling and Message Passing mechanism on heterogeneous graph. Furthermor, The newly released PGL also support distributed graph storage and some distributed training algorithms, such as distributed deep walk and distributed graphsage. Combined with the PaddlePaddle deep learning framework, we are able to support both graph representation learning models and graph neural networks, and thus our framework has a wide range of graph-based applications. The newly released PGL supports heterogeneous graph learning on both walk based paradigm and message-passing based paradigm by providing MetaPath sampling and Message Passing mechanism on heterogeneous graph. Furthermor, The newly released PGL also support distributed graph storage and some distributed training algorithms, such as distributed deep walk and distributed graphsage. Combined with the PaddlePaddle deep learning framework, we are able to support both graph representation learning models and graph neural networks, and thus our framework has a wide range of graph-based applications.
...@@ -82,10 +99,11 @@ In most cases of large-scale graph learning, we need distributed graph storage a ...@@ -82,10 +99,11 @@ In most cases of large-scale graph learning, we need distributed graph storage a
## Model Zoo ## Model Zoo
The following are 13 graph learning models that have been implemented in the framework. See the details [here](https://pgl.readthedocs.io/en/latest/introduction.html#highlight-tons-of-models) The following graph learning models have been implemented in the framework. You can find more [examples](./examples) and the [details](https://pgl.readthedocs.io/en/latest/introduction.html#highlight-tons-of-models)
|Model | feature | |Model | feature |
|---|---| |---|---|
| [**ERNIESage**](./examples/erniesage/) | ERNIE SAmple aggreGatE for Text and Graph |
| GCN | Graph Convolutional Neural Networks | | GCN | Graph Convolutional Neural Networks |
| GAT | Graph Attention Network | | GAT | Graph Attention Network |
| GraphSage |Large-scale graph convolution network based on neighborhood sampling| | GraphSage |Large-scale graph convolution network based on neighborhood sampling|
......
<img src="./docs/source/_static/logo.png" alt="The logo of Paddle Graph Learning (PGL)" width="320"> <img src="./docs/source/_static/logo.png" alt="The logo of Paddle Graph Learning (PGL)" width="320">
[![PyPi Latest Release](https://img.shields.io/pypi/v/pgl.svg)](https://pypi.org/project/pgl/)
[![License](https://img.shields.io/badge/License-Apache%202.0-blue.svg)](./LICENSE)
[文档](https://pgl.readthedocs.io/en/latest/) | [快速开始](https://pgl.readthedocs.io/en/latest/quick_start/instruction.html) | [English](./README.md) [文档](https://pgl.readthedocs.io/en/latest/) | [快速开始](https://pgl.readthedocs.io/en/latest/quick_start/instruction.html) | [English](./README.md)
## 最新消息
PGL v1.1 2020.4.29
- **ERNIESage**是PGL团队最新提出的模型,可以用于建模文本以及图结构信息。你可以在[这里](./examples/erniesage)看到详细的介绍。
- PGL现在提供[Open Graph Benchmark](https://github.com/snap-stanford/ogb)的一些例子,你可以在[这里](./ogb_examples)找到。
- 新增了图级别的算子包括**GraphPooling**以及[**GraphNormalization**](https://arxiv.org/abs/2003.00982),这样你就能实现更多复杂的图级别分类模型。
- 新增PGL-KE工具包,里面包含许多经典知识图谱图嵌入算法,包括TransE, TransR, RotatE,详情可见[这里](./examples/pgl-ke)
------
Paddle Graph Learning (PGL)是一个基于[PaddlePaddle](https://github.com/PaddlePaddle/Paddle)的高效易用的图学习框架 Paddle Graph Learning (PGL)是一个基于[PaddlePaddle](https://github.com/PaddlePaddle/Paddle)的高效易用的图学习框架
<img src="./docs/source/_static/framework_of_pgl.png" alt="The Framework of Paddle Graph Learning (PGL)" width="800"> <img src="./docs/source/_static/framework_of_pgl.png" alt="The Framework of Paddle Graph Learning (PGL)" width="800">
...@@ -77,10 +94,11 @@ Paddle Graph Learning (PGL)是一个基于[PaddlePaddle](https://github.com/Padd ...@@ -77,10 +94,11 @@ Paddle Graph Learning (PGL)是一个基于[PaddlePaddle](https://github.com/Padd
## 丰富性——覆盖业界大部分图学习网络 ## 丰富性——覆盖业界大部分图学习网络
下列是框架中已经自带实现的十三种图网络学习模型。详情请参考[这里](https://pgl.readthedocs.io/en/latest/introduction.html#highlight-tons-of-models) 下列是框架中部分已经实现的图网络模型,更多的模型在[这里](./examples)可以找到。详情请参考[这里](https://pgl.readthedocs.io/en/latest/introduction.html#highlight-tons-of-models)
| 模型 | 特点 | | 模型 | 特点 |
|---|---| |---|---|
| [**ERNIESage**](./examples/erniesage/) | 能同时建模文本以及图结构的ERNIE SAmple aggreGatE |
| GCN | 图卷积网络 | | GCN | 图卷积网络 |
| GAT | 基于Attention的图卷积网络 | | GAT | 基于Attention的图卷积网络 |
| GraphSage | 基于邻居采样的大规模图卷积网络 | | GraphSage | 基于邻居采样的大规模图卷积网络 |
......
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...@@ -53,7 +53,6 @@ place = fluid.CUDAPlace(0) if use_cuda else fluid.CPUPlace() ...@@ -53,7 +53,6 @@ place = fluid.CUDAPlace(0) if use_cuda else fluid.CPUPlace()
# use GraphWrapper as a container for graph data to construct a graph neural network # use GraphWrapper as a container for graph data to construct a graph neural network
gw = pgl.graph_wrapper.GraphWrapper(name='graph', gw = pgl.graph_wrapper.GraphWrapper(name='graph',
place = place,
node_feat=g.node_feat_info()) node_feat=g.node_feat_info())
``` ```
......
...@@ -77,7 +77,6 @@ place = fluid.CPUPlace() ...@@ -77,7 +77,6 @@ place = fluid.CPUPlace()
# create a GraphWrapper as a container for graph data # create a GraphWrapper as a container for graph data
gw = heter_graph_wrapper.HeterGraphWrapper(name='heter_graph', gw = heter_graph_wrapper.HeterGraphWrapper(name='heter_graph',
place = place,
edge_types = g.edge_types_info(), edge_types = g.edge_types_info(),
node_feat=g.node_feat_info(), node_feat=g.node_feat_info(),
edge_feat=g.edge_feat_info()) edge_feat=g.edge_feat_info())
......
...@@ -53,7 +53,6 @@ class GATNE(object): ...@@ -53,7 +53,6 @@ class GATNE(object):
self.gw = heter_graph_wrapper.HeterGraphWrapper( self.gw = heter_graph_wrapper.HeterGraphWrapper(
name="heter_graph", name="heter_graph",
place=place,
edge_types=self.graph.edge_types_info(), edge_types=self.graph.edge_types_info(),
node_feat=self.graph.node_feat_info(), node_feat=self.graph.node_feat_info(),
edge_feat=self.graph.edge_feat_info()) edge_feat=self.graph.edge_feat_info())
......
...@@ -65,7 +65,6 @@ def main(args): ...@@ -65,7 +65,6 @@ def main(args):
with fluid.program_guard(train_program, startup_program): with fluid.program_guard(train_program, startup_program):
gw = pgl.graph_wrapper.GraphWrapper( gw = pgl.graph_wrapper.GraphWrapper(
name="graph", name="graph",
place=place,
node_feat=dataset.graph.node_feat_info()) node_feat=dataset.graph.node_feat_info())
output = pgl.layers.gcn(gw, output = pgl.layers.gcn(gw,
......
...@@ -170,7 +170,7 @@ def main(args): ...@@ -170,7 +170,7 @@ def main(args):
with fluid.program_guard(train_program, startup_program): with fluid.program_guard(train_program, startup_program):
graph_wrapper = pgl.graph_wrapper.GraphWrapper( graph_wrapper = pgl.graph_wrapper.GraphWrapper(
"sub_graph", fluid.CPUPlace(), node_feat=[('feats', [None, 602], np.dtype('float32'))]) "sub_graph", node_feat=[('feats', [None, 602], np.dtype('float32'))])
model_loss, model_acc = build_graph_model( model_loss, model_acc = build_graph_model(
graph_wrapper, graph_wrapper,
num_class=data["num_class"], num_class=data["num_class"],
......
# ERNIESage in PGL
[中文版 README](./README.md)
## Introduction
In many industrial applications, there is often a special graph shown below: Text Graph. As the name implies, the node attributes of such graph consist of text, and the edges provide structural information. Take the search scenario for example, nodes can be expressed by search query, web page titles, and web page content, while the edges are constructed by user feedback or hyperlink information.
<img src="./docs/source/_static/text_graph.png" alt="Text Graph" width="800">
**ERNIESage** (abbreviation of ERNIE SAmple aggreGatE), a model proposed by the PGL team, effectively improves the performance on text graph by simultaneously modeling text semantics and graph structure information. It's worth mentioning that [**ERNIE**](https://github.com/PaddlePaddle/ERNIE) in **ERNIESage** is a continual pre-training framework for language understanding launched by Baidu.
**ERNIESage** is an aggregation of ERNIE and GraphSAGE. Its structure is shown in the figure below. The main idea is to use ERNIE as an aggregation function (Aggregators) to model the semantic and structural relationship between its own nodes and neighbor nodes. In addition, for the position-independent characteristics of neighbor nodes, attention mask and independent position embedding mechanism for neighbor blindness are designed.
<img src="./docs/source/_static/ernie_aggregator.png" alt="ERNIESage" width="800">
GraphSAGE with ID feature can only model the graph structure information, while ERNIE can only deal with the text. With the help of PGL, the proposed **ERNIESage** model can combine the advantages of both models. Take the following recommendation example of text graph, we can see that **ERNIESage** achieves the best performance when compared to single ERNIE model or GraphSAGE model.
<img src="./docs/source/_static/ERNIESage_result.png" alt="ERNIESage_result" width="800">
Thanks to the flexibility and usability of PGL, **ERNIESage** can be quickly implemented under PGL's Message Passing paradigm. Acutally, there are four PGL version of ERNIESage:
- **ERNIESage v1**: ERNIE is applied to the NODE of the text graph;
- **ERNIESage v2**: ERNIE is applied to the EDGE of the text graph;
- **ERNIESage v3**: ERNIE is applied to the first order neighbors and center node;
- **ERNIESage v4**: ERNIE is applied to the N-order neighbors and center node.
<img src="./docs/source/_static/ERNIESage_v1_4.png" alt="ERNIESage_v1_4" width="800">
## Dependencies
- paddlepaddle>=1.7
- pgl>=1.1
## Dataformat
## How to run
We adopt [PaddlePaddle Fleet](https://github.com/PaddlePaddle/Fleet) as our distributed training frameworks ```config/*.yaml``` are some example config files for hyperparameters.
```sh
# train ERNIESage in distributed gpu mode.
sh local_run.sh config/enriesage_v1_gpu.yaml
# train ERNIESage in distributed cpu mode.
sh local_run.sh config/enriesage_v1_cpu.yaml
```
## Hyperparamters
- learner_type: `gpu` or `cpu`; gpu use fleet Collective mode, cpu use fleet Transpiler mode.
## Citation
```
@misc{ERNIESage,
author = {PGL Team},
title = {ERNIESage: ERNIE SAmple aggreGatE},
year = {2020},
publisher = {GitHub},
journal = {GitHub repository},
howpublished = {\url{https://github.com/PaddlePaddle/PGL/tree/master/examples/erniesage},
}
```
# 使用PGL实现ERNIESage
[ENG Readme](./README.en.md)
## 背景介绍
在很多工业应用中,往往出现如下图所示的一种特殊的图:Text Graph。顾名思义,图的节点属性由文本构成,而边的构建提供了结构信息。如搜索场景下的Text Graph,节点可由搜索词、网页标题、网页正文来表达,用户反馈和超链信息则可构成边关系。
<img src="./docs/source/_static/text_graph.png" alt="Text Graph" width="800">
**ERNIESage** 由PGL团队提出,是ERNIE SAmple aggreGatE的简称,该模型可以同时建模文本语义与图结构信息,有效提升 Text Graph 的应用效果。其中 [**ERNIE**](https://github.com/PaddlePaddle/ERNIE) 是百度推出的基于知识增强的持续学习语义理解框架,
**ERNIESage** 是 ERNIE 与 GraphSAGE 碰撞的结果,是 ERNIE SAmple aggreGatE 的简称,它的结构如下图所示,主要思想是通过 ERNIE 作为聚合函数(Aggregators),建模自身节点和邻居节点的语义与结构关系。ERNIESage 对于文本的建模是构建在邻居聚合的阶段,中心节点文本会与所有邻居节点文本进行拼接;然后通过预训练的 ERNIE 模型进行消息汇聚,捕捉中心节点以及邻居节点之间的相互关系;最后使用 ERNIESage 搭配独特的邻居互相看不见的 Attention Mask 和独立的 Position Embedding 体系,就可以轻松构建 TextGraph 中句子之间以及词之间的关系。
<img src="./docs/source/_static/ernie_aggregator.png" alt="ERNIESage" width="800">
使用ID特征的GraphSAGE只能够建模图的结构信息,而单独的ERNIE只能处理文本信息。通过PGL搭建的图与文本的桥梁,**ERNIESage**能够很简单的把GraphSAGE以及ERNIE的优点结合一起。以下面TextGraph的场景,**ERNIESage**的效果能够比单独的ERNIE以及GraphSAGE模型都要好。
<img src="./docs/source/_static/ERNIESage_result.png" alt="ERNIESage_result" width="800">
**ERNIESage**可以很轻松地在PGL中的消息传递范式中进行实现,目前PGL提供了4个版本的ERNIESage模型:
- **ERNIESage v1**: ERNIE 作用于text graph节点上;
- **ERNIESage v2**: ERNIE 作用在text graph的边上;
- **ERNIESage v3**: ERNIE 作用于一阶邻居及起边上;
- **ERNIESage v4**: ERNIE 作用于N阶邻居及边上;
<img src="./docs/source/_static/ERNIESage_v1_4.png" alt="ERNIESage_v1_4" width="800">
## 环境依赖
- paddlepaddle>=1.7
- pgl>=1.1
## Dataformat
## How to run
我们采用了[PaddlePaddle Fleet](https://github.com/PaddlePaddle/Fleet)作为我们的分布式训练框架,在```config/*.yaml```中,由部分用于训练ERNIESage的配置。
```sh
# 分布式GPU模式或单机模式ERNIESage
sh local_run.sh config/enriesage_v1_gpu.yaml
# 分布式CPU模式训练ERNIESage
sh local_run.sh config/enriesage_v1_cpu.yaml
```
## Hyperparamters
- learner_type: `gpu` or `cpu`; gpu 使用fleet Collective 模式, cpu 使用fleet Transpiler 模式.
## Citation
```
@misc{ERNIESage,
author = {PGL Team},
title = {ERNIESage: ERNIE SAmple aggreGatE},
year = {2020},
publisher = {GitHub},
journal = {GitHub repository},
howpublished = {\url{https://github.com/PaddlePaddle/PGL/tree/master/examples/erniesage},
}
```
# Global Enviroment Settings
#
# trainer config ------
learner_type: "cpu"
optimizer_type: "adam"
lr: 0.00005
batch_size: 2
CPU_NUM: 10
epoch: 20
log_per_step: 1
save_per_step: 100
output_path: "./output"
ckpt_path: "./ernie_base_ckpt"
# data config ------
input_data: "./data.txt"
graph_path: "./workdir"
sample_workers: 1
use_pyreader: true
input_type: "text"
# model config ------
samples: [10]
model_type: "ErnieSageModelV1"
layer_type: "graphsage_sum"
max_seqlen: 40
num_layers: 1
hidden_size: 128
final_fc: true
final_l2_norm: true
loss_type: "hinge"
margin: 0.3
# infer config ------
infer_model: "./output/last"
infer_batch_size: 128
# ernie config ------
encoding: "utf8"
ernie_vocab_file: "./vocab.txt"
ernie_config:
attention_probs_dropout_prob: 0.1
hidden_act: "relu"
hidden_dropout_prob: 0.1
hidden_size: 768
initializer_range: 0.02
max_position_embeddings: 513
num_attention_heads: 12
num_hidden_layers: 12
sent_type_vocab_size: 4
task_type_vocab_size: 3
vocab_size: 18000
use_task_id: false
use_fp16: false
# Global Enviroment Settings
#
# trainer config ------
learner_type: "gpu"
optimizer_type: "adam"
lr: 0.00005
batch_size: 32
CPU_NUM: 10
epoch: 20
log_per_step: 1
save_per_step: 100
output_path: "./output"
ckpt_path: "./ernie_base_ckpt"
# data config ------
input_data: "./data.txt"
graph_path: "./workdir"
sample_workers: 1
use_pyreader: true
input_type: "text"
# model config ------
samples: [10]
model_type: "ErnieSageModelV1"
layer_type: "graphsage_sum"
max_seqlen: 40
num_layers: 1
hidden_size: 128
final_fc: true
final_l2_norm: true
loss_type: "hinge"
margin: 0.3
# infer config ------
infer_model: "./output/last"
infer_batch_size: 128
# ernie config ------
encoding: "utf8"
ernie_vocab_file: "./vocab.txt"
ernie_config:
attention_probs_dropout_prob: 0.1
hidden_act: "relu"
hidden_dropout_prob: 0.1
hidden_size: 768
initializer_range: 0.02
max_position_embeddings: 513
num_attention_heads: 12
num_hidden_layers: 12
sent_type_vocab_size: 4
task_type_vocab_size: 3
vocab_size: 18000
use_task_id: false
use_fp16: false
# Global Enviroment Settings
#
# trainer config ------
learner_type: "cpu"
optimizer_type: "adam"
lr: 0.00005
batch_size: 2
CPU_NUM: 10
epoch: 20
log_per_step: 1
save_per_step: 100
output_path: "./output"
ckpt_path: "./ernie_base_ckpt"
# data config ------
input_data: "./data.txt"
graph_path: "./workdir"
sample_workers: 1
use_pyreader: true
input_type: "text"
# model config ------
samples: [10]
model_type: "ErnieSageModelV2"
max_seqlen: 40
num_layers: 1
hidden_size: 128
final_fc: true
final_l2_norm: true
loss_type: "hinge"
margin: 0.3
# infer config ------
infer_model: "./output/last"
infer_batch_size: 128
# ernie config ------
encoding: "utf8"
ernie_vocab_file: "./vocab.txt"
ernie_config:
attention_probs_dropout_prob: 0.1
hidden_act: "relu"
hidden_dropout_prob: 0.1
hidden_size: 768
initializer_range: 0.02
max_position_embeddings: 513
num_attention_heads: 12
num_hidden_layers: 12
sent_type_vocab_size: 4
task_type_vocab_size: 3
vocab_size: 18000
use_task_id: false
use_fp16: false
# Global Enviroment Settings
#
# trainer config ------
learner_type: "gpu"
optimizer_type: "adam"
lr: 0.00005
batch_size: 32
CPU_NUM: 10
epoch: 20
log_per_step: 1
save_per_step: 100
output_path: "./output"
ckpt_path: "./ernie_base_ckpt"
# data config ------
input_data: "./data.txt"
graph_path: "./workdir"
sample_workers: 1
use_pyreader: true
input_type: "text"
# model config ------
samples: [10]
model_type: "ErnieSageModelV2"
max_seqlen: 40
num_layers: 1
hidden_size: 128
final_fc: true
final_l2_norm: true
loss_type: "hinge"
margin: 0.3
# infer config ------
infer_model: "./output/last"
infer_batch_size: 128
# ernie config ------
encoding: "utf8"
ernie_vocab_file: "./vocab.txt"
ernie_config:
attention_probs_dropout_prob: 0.1
hidden_act: "relu"
hidden_dropout_prob: 0.1
hidden_size: 768
initializer_range: 0.02
max_position_embeddings: 513
num_attention_heads: 12
num_hidden_layers: 12
sent_type_vocab_size: 4
task_type_vocab_size: 3
vocab_size: 18000
use_task_id: false
use_fp16: false
# Global Enviroment Settings
#
# trainer config ------
learner_type: "cpu"
optimizer_type: "adam"
lr: 0.00005
batch_size: 2
CPU_NUM: 10
epoch: 20
log_per_step: 1
save_per_step: 100
output_path: "./output"
ckpt_path: "./ernie_base_ckpt"
# data config ------
input_data: "./data.txt"
graph_path: "./workdir"
sample_workers: 1
use_pyreader: true
input_type: "text"
# model config ------
samples: [10]
model_type: "ErnieSageModelV3"
max_seqlen: 40
num_layers: 1
hidden_size: 128
final_fc: true
final_l2_norm: true
loss_type: "hinge"
margin: 0.3
# infer config ------
infer_model: "./output/last"
infer_batch_size: 128
# ernie config ------
encoding: "utf8"
ernie_vocab_file: "./vocab.txt"
ernie_config:
attention_probs_dropout_prob: 0.1
hidden_act: "relu"
hidden_dropout_prob: 0.1
hidden_size: 768
initializer_range: 0.02
max_position_embeddings: 513
num_attention_heads: 12
num_hidden_layers: 12
sent_type_vocab_size: 4
task_type_vocab_size: 3
vocab_size: 18000
use_task_id: false
use_fp16: false
# Global Enviroment Settings
#
# trainer config ------
learner_type: "gpu"
optimizer_type: "adam"
lr: 0.00005
batch_size: 32
CPU_NUM: 10
epoch: 20
log_per_step: 1
save_per_step: 100
output_path: "./output"
ckpt_path: "./ernie_base_ckpt"
# data config ------
input_data: "./data.txt"
graph_path: "./workdir"
sample_workers: 1
use_pyreader: true
input_type: "text"
# model config ------
samples: [10]
model_type: "ErnieSageModelV3"
max_seqlen: 40
num_layers: 1
hidden_size: 128
final_fc: true
final_l2_norm: true
loss_type: "hinge"
margin: 0.3
# infer config ------
infer_model: "./output/last"
infer_batch_size: 128
# ernie config ------
encoding: "utf8"
ernie_vocab_file: "./vocab.txt"
ernie_config:
attention_probs_dropout_prob: 0.1
hidden_act: "relu"
hidden_dropout_prob: 0.1
hidden_size: 768
initializer_range: 0.02
max_position_embeddings: 513
num_attention_heads: 12
num_hidden_layers: 12
sent_type_vocab_size: 4
task_type_vocab_size: 3
vocab_size: 18000
use_task_id: false
use_fp16: false
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""Base DataLoader
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
from __future__ import unicode_literals
from __future__ import absolute_import
import os
import sys
import six
from io import open
from collections import namedtuple
import numpy as np
import tqdm
import paddle
from pgl.utils import mp_reader
import collections
import time
from pgl.utils.logger import log
import traceback
if six.PY3:
import io
sys.stdout = io.TextIOWrapper(sys.stdout.buffer, encoding='utf-8')
sys.stderr = io.TextIOWrapper(sys.stderr.buffer, encoding='utf-8')
def batch_iter(data, perm, batch_size, fid, num_workers):
"""node_batch_iter
"""
size = len(data)
start = 0
cc = 0
while start < size:
index = perm[start:start + batch_size]
start += batch_size
cc += 1
if cc % num_workers != fid:
continue
yield data[index]
def scan_batch_iter(data, batch_size, fid, num_workers):
"""node_batch_iter
"""
batch = []
cc = 0
for line_example in data.scan():
cc += 1
if cc % num_workers != fid:
continue
batch.append(line_example)
if len(batch) == batch_size:
yield batch
batch = []
if len(batch) > 0:
yield batch
class BaseDataGenerator(object):
"""Base Data Geneartor"""
def __init__(self, buf_size, batch_size, num_workers, shuffle=True):
self.num_workers = num_workers
self.batch_size = batch_size
self.line_examples = []
self.buf_size = buf_size
self.shuffle = shuffle
def batch_fn(self, batch_examples):
""" batch_fn batch producer"""
raise NotImplementedError("No defined Batch Fn")
def batch_iter(self, fid, perm):
""" batch iterator"""
if self.shuffle:
for batch in batch_iter(self, perm, self.batch_size, fid, self.num_workers):
yield batch
else:
for batch in scan_batch_iter(self, self.batch_size, fid, self.num_workers):
yield batch
def __len__(self):
return len(self.line_examples)
def __getitem__(self, idx):
if isinstance(idx, collections.Iterable):
return [self[bidx] for bidx in idx]
else:
return self.line_examples[idx]
def generator(self):
"""batch dict generator"""
def worker(filter_id, perm):
""" multiprocess worker"""
def func_run():
""" func_run """
pid = os.getpid()
np.random.seed(pid + int(time.time()))
for batch_examples in self.batch_iter(filter_id, perm):
try:
batch_dict = self.batch_fn(batch_examples)
except Exception as e:
traceback.print_exc()
log.info(traceback.format_exc())
log.info(str(e))
continue
if batch_dict is None:
continue
yield batch_dict
return func_run
# consume a seed
np.random.rand()
if self.shuffle:
perm = np.arange(0, len(self))
np.random.shuffle(perm)
else:
perm = None
if self.num_workers == 1:
r = paddle.reader.buffered(worker(0, perm), self.buf_size)
else:
worker_pool = [worker(wid, perm) for wid in range(self.num_workers)]
worker = mp_reader.multiprocess_reader(
worker_pool, use_pipe=True, queue_size=1000)
r = paddle.reader.buffered(worker, self.buf_size)
for batch in r():
yield batch
def scan(self):
for line_example in self.line_examples:
yield line_example
"""Graph Dataset
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
from __future__ import unicode_literals
from __future__ import absolute_import
import os
import pgl
import sys
import numpy as np
from pgl.utils.logger import log
from dataset.base_dataset import BaseDataGenerator
from pgl.sample import alias_sample
from pgl.sample import pinsage_sample
from pgl.sample import graphsage_sample
from pgl.sample import edge_hash
class GraphGenerator(BaseDataGenerator):
def __init__(self, graph_wrappers, data, batch_size, samples,
num_workers, feed_name_list, use_pyreader,
phase, graph_data_path, shuffle=True, buf_size=1000):
super(GraphGenerator, self).__init__(
buf_size=buf_size,
num_workers=num_workers,
batch_size=batch_size, shuffle=shuffle)
# For iteration
self.line_examples = data
self.graph_wrappers = graph_wrappers
self.samples = samples
self.feed_name_list = feed_name_list
self.use_pyreader = use_pyreader
self.phase = phase
self.load_graph(graph_data_path)
self.num_layers = len(graph_wrappers)
def load_graph(self, graph_data_path):
self.graph = pgl.graph.MemmapGraph(graph_data_path)
self.alias = np.load(os.path.join(graph_data_path, "alias.npy"), mmap_mode="r")
self.events = np.load(os.path.join(graph_data_path, "events.npy"), mmap_mode="r")
self.term_ids = np.load(os.path.join(graph_data_path, "term_ids.npy"), mmap_mode="r")
def batch_fn(self, batch_ex):
# batch_ex = [
# (src, dst, neg),
# (src, dst, neg),
# (src, dst, neg),
# ]
#
batch_src = []
batch_dst = []
batch_neg = []
for batch in batch_ex:
batch_src.append(batch[0])
batch_dst.append(batch[1])
if len(batch) == 3: # default neg samples
batch_neg.append(batch[2])
if len(batch_src) != self.batch_size:
if self.phase == "train":
return None #Skip
if len(batch_neg) > 0:
batch_neg = np.unique(np.concatenate(batch_neg))
batch_src = np.array(batch_src, dtype="int64")
batch_dst = np.array(batch_dst, dtype="int64")
sampled_batch_neg = alias_sample(batch_dst.shape, self.alias, self.events)
if len(batch_neg) > 0:
batch_neg = np.concatenate([batch_neg, sampled_batch_neg], 0)
else:
batch_neg = sampled_batch_neg
if self.phase == "train":
ignore_edges = set()
else:
ignore_edges = set()
nodes = np.unique(np.concatenate([batch_src, batch_dst, batch_neg], 0))
subgraphs = graphsage_sample(self.graph, nodes, self.samples, ignore_edges=ignore_edges)
feed_dict = {}
for i in range(self.num_layers):
feed_dict.update(self.graph_wrappers[i].to_feed(subgraphs[i]))
# only reindex from first subgraph
sub_src_idx = subgraphs[0].reindex_from_parrent_nodes(batch_src)
sub_dst_idx = subgraphs[0].reindex_from_parrent_nodes(batch_dst)
sub_neg_idx = subgraphs[0].reindex_from_parrent_nodes(batch_neg)
feed_dict["user_index"] = np.array(sub_src_idx, dtype="int64")
feed_dict["item_index"] = np.array(sub_dst_idx, dtype="int64")
#feed_dict["neg_item_index"] = np.array(sub_neg_idx, dtype="int64")
feed_dict["term_ids"] = self.term_ids[subgraphs[0].node_feat["index"]]
return feed_dict
def __call__(self):
return self.generator()
def generator(self):
try:
for feed_dict in super(GraphGenerator, self).generator():
if self.use_pyreader:
yield [feed_dict[name] for name in self.feed_name_list]
else:
yield feed_dict
except Exception as e:
log.exception(e)
# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from __future__ import division
from __future__ import absolute_import
from __future__ import print_function
from __future__ import unicode_literals
import argparse
import pickle
import time
import glob
import os
import io
import traceback
import pickle as pkl
role = os.getenv("TRAINING_ROLE", "TRAINER")
import numpy as np
import yaml
from easydict import EasyDict as edict
import pgl
from pgl.utils.logger import log
from pgl.utils import paddle_helper
import paddle
import paddle.fluid as F
from models.model_factory import Model
from dataset.graph_reader import GraphGenerator
class PredictData(object):
def __init__(self, num_nodes):
trainer_id = int(os.getenv("PADDLE_TRAINER_ID", "0"))
trainer_count = int(os.getenv("PADDLE_TRAINERS_NUM", "1"))
train_usr = np.arange(trainer_id, num_nodes, trainer_count)
#self.data = (train_usr, train_usr)
self.data = train_usr
def __getitem__(self, index):
return [self.data[index], self.data[index]]
def tostr(data_array):
return " ".join(["%.5lf" % d for d in data_array])
def run_predict(py_reader,
exe,
program,
model_dict,
log_per_step=1,
args=None):
if args.input_type == "text":
id2str = np.load(os.path.join(args.graph_path, "id2str.npy"), mmap_mode="r")
trainer_id = int(os.getenv("PADDLE_TRAINER_ID", "0"))
trainer_count = int(os.getenv("PADDLE_TRAINERS_NUM", "1"))
if not os.path.exists(args.output_path):
os.mkdir(args.output_path)
fout = io.open("%s/part-%s" % (args.output_path, trainer_id), "w", encoding="utf8")
batch = 0
for batch_feed_dict in py_reader():
batch += 1
batch_usr_feat, batch_ad_feat, batch_src_real_index = exe.run(
program,
feed=batch_feed_dict,
fetch_list=model_dict.outputs)
if batch % log_per_step == 0:
log.info("Predict %s finished" % batch)
for ufs, _, sri in zip(batch_usr_feat, batch_ad_feat, batch_src_real_index):
if args.input_type == "text":
sri = id2str[int(sri)]
line = "{}\t{}\n".format(sri, tostr(ufs))
fout.write(line)
fout.close()
def _warmstart(exe, program, path='params'):
def _existed_persitables(var):
#if not isinstance(var, fluid.framework.Parameter):
# return False
if not F.io.is_persistable(var):
return False
param_path = os.path.join(path, var.name)
log.info("Loading parameter: {} persistable: {} exists: {}".format(
param_path,
F.io.is_persistable(var),
os.path.exists(param_path),
))
return os.path.exists(param_path)
F.io.load_vars(
exe,
path,
main_program=program,
predicate=_existed_persitables
)
def main(config):
model = Model.factory(config)
if config.learner_type == "cpu":
place = F.CPUPlace()
elif config.learner_type == "gpu":
gpu_id = int(os.getenv("FLAGS_selected_gpus", "0"))
place = F.CUDAPlace(gpu_id)
else:
raise ValueError
exe = F.Executor(place)
val_program = F.default_main_program().clone(for_test=True)
exe.run(F.default_startup_program())
_warmstart(exe, F.default_startup_program(), path=config.infer_model)
num_threads = int(os.getenv("CPU_NUM", 1))
trainer_id = int(os.getenv("PADDLE_TRAINER_ID", 0))
exec_strategy = F.ExecutionStrategy()
exec_strategy.num_threads = num_threads
build_strategy = F.BuildStrategy()
build_strategy.enable_inplace = True
build_strategy.memory_optimize = True
build_strategy.remove_unnecessary_lock = False
build_strategy.memory_optimize = False
if num_threads > 1:
build_strategy.reduce_strategy = F.BuildStrategy.ReduceStrategy.Reduce
val_compiled_prog = F.compiler.CompiledProgram(
val_program).with_data_parallel(
build_strategy=build_strategy,
exec_strategy=exec_strategy)
num_nodes = int(np.load(os.path.join(config.graph_path, "num_nodes.npy")))
predict_data = PredictData(num_nodes)
predict_iter = GraphGenerator(
graph_wrappers=model.graph_wrappers,
batch_size=config.infer_batch_size,
data=predict_data,
samples=config.samples,
num_workers=config.sample_workers,
feed_name_list=[var.name for var in model.feed_list],
use_pyreader=config.use_pyreader,
phase="predict",
graph_data_path=config.graph_path,
shuffle=False)
if config.learner_type == "cpu":
model.data_loader.decorate_batch_generator(
predict_iter, places=F.cpu_places())
elif config.learner_type == "gpu":
gpu_id = int(os.getenv("FLAGS_selected_gpus", "0"))
place = F.CUDAPlace(gpu_id)
model.data_loader.decorate_batch_generator(
predict_iter, places=place)
else:
raise ValueError
run_predict(model.data_loader,
program=val_compiled_prog,
exe=exe,
model_dict=model,
args=config)
if __name__ == "__main__":
parser = argparse.ArgumentParser(description='main')
parser.add_argument("--conf", type=str, default="./config.yaml")
args = parser.parse_args()
config = edict(yaml.load(open(args.conf), Loader=yaml.FullLoader))
print(config)
main(config)
unset http_proxy https_proxy
set -x
mode=${1:-local}
config=${2:-"./config.yaml"}
function parse_yaml {
local prefix=$2
local s='[[:space:]]*' w='[a-zA-Z0-9_]*' fs=$(echo @|tr @ '\034')
sed -ne "s|^\($s\):|\1|" \
-e "s|^\($s\)\($w\)$s:$s[\"']\(.*\)[\"']$s\$|\1$fs\2$fs\3|p" \
-e "s|^\($s\)\($w\)$s:$s\(.*\)$s\$|\1$fs\2$fs\3|p" $1 |
awk -F$fs '{
indent = length($1)/2;
vname[indent] = $2;
for (i in vname) {if (i > indent) {delete vname[i]}}
if (length($3) > 0) {
vn=""; for (i=0; i<indent; i++) {vn=(vn)(vname[i])("_")}
printf("%s%s%s=\"%s\"\n", "'$prefix'",vn, $2, $3);
}
}'
}
eval $(parse_yaml $config)
export CPU_NUM=$CPU_NUM
export FLAGS_rpc_deadline=3000000
export FLAGS_rpc_retry_times=1000
if [[ $async_mode == "True" ]];then
echo "async_mode is True"
else
export FLAGS_communicator_send_queue_size=1
export FLAGS_communicator_min_send_grad_num_before_recv=0
export FLAGS_communicator_max_merge_var_num=1 # important!
export FLAGS_communicator_merge_sparse_grad=0
fi
export FLAGS_communicator_recv_wait_times=5000000
mkdir -p output
python ./train.py --conf $config
if [[ $TRAINING_ROLE == "TRAINER" ]];then
python ./infer.py --conf $config
fi
# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import time
import os
role = os.getenv("TRAINING_ROLE", "TRAINER")
import numpy as np
from pgl.utils.logger import log
import paddle.fluid as F
import paddle.fluid.layers as L
from paddle.fluid.incubate.fleet.parameter_server.distribute_transpiler import StrategyFactory
from paddle.fluid.incubate.fleet.collective import DistributedStrategy
from paddle.fluid.transpiler.distribute_transpiler import DistributeTranspilerConfig
from paddle.fluid.incubate.fleet.collective import fleet as cfleet
from paddle.fluid.incubate.fleet.parameter_server.distribute_transpiler import fleet as tfleet
import paddle.fluid.incubate.fleet.base.role_maker as role_maker
from tensorboardX import SummaryWriter
class Learner(object):
@classmethod
def factory(cls, name):
if name == "cpu":
return TranspilerLearner()
elif name == "gpu":
return CollectiveLearner()
else:
raise ValueError
def build(self, model, data_gen, config):
raise NotImplementedError
def warmstart(self, program, path='./checkpoints'):
def _existed_persitables(var):
#if not isinstance(var, fluid.framework.Parameter):
# return False
if not F.io.is_persistable(var):
return False
param_path = os.path.join(path, var.name)
log.info("Loading parameter: {} persistable: {} exists: {}".format(
param_path,
F.io.is_persistable(var),
os.path.exists(param_path),
))
return os.path.exists(param_path)
F.io.load_vars(
self.exe,
path,
main_program=program,
predicate=_existed_persitables
)
def start(self):
batch = 0
start = time.time()
trainer_id = int(os.getenv("PADDLE_TRAINER_ID", "0"))
if trainer_id == 0:
writer = SummaryWriter(os.path.join(self.config.output_path, "train_history"))
for epoch_idx in range(self.config.epoch):
for idx, batch_feed_dict in enumerate(self.model.data_loader()):
try:
cpu_time = time.time()
batch += 1
batch_loss = self.exe.run(
self.program,
feed=batch_feed_dict,
fetch_list=[self.model.loss])
end = time.time()
if trainer_id == 0:
writer.add_scalar("loss", np.mean(batch_loss), batch)
if batch % self.config.log_per_step == 0:
log.info(
"Epoch %s Batch %s %s-Loss %s \t Speed(per batch) %.5lf/%.5lf sec"
% (epoch_idx, batch, "train", np.mean(batch_loss), (end - start) /batch, (end - cpu_time)))
writer.flush()
if batch % self.config.save_per_step == 0:
self.fleet.save_persistables(self.exe, os.path.join(self.config.output_path, str(batch)))
except Exception as e:
log.info("Pyreader train error")
log.exception(e)
log.info("epcoh %s done." % epoch_idx)
def stop(self):
self.fleet.save_persistables(self.exe, os.path.join(self.config.output_path, "last"))
class TranspilerLearner(Learner):
def __init__(self):
training_role = os.getenv("TRAINING_ROLE", "TRAINER")
paddle_role = role_maker.Role.WORKER
place = F.CPUPlace()
if training_role == "PSERVER":
paddle_role = role_maker.Role.SERVER
# set the fleet runtime environment according to configure
port = os.getenv("PADDLE_PORT", "6174")
pserver_ips = os.getenv("PADDLE_PSERVERS") # ip,ip...
eplist = []
for ip in pserver_ips.split(","):
eplist.append(':'.join([ip, port]))
pserver_endpoints = eplist # ip:port,ip:port...
worker_num = int(os.getenv("PADDLE_TRAINERS_NUM", "0"))
trainer_id = int(os.getenv("PADDLE_TRAINER_ID", "0"))
role = role_maker.UserDefinedRoleMaker(
current_id=trainer_id,
role=paddle_role,
worker_num=worker_num,
server_endpoints=pserver_endpoints)
tfleet.init(role)
tfleet.save_on_pserver = True
def build(self, model, data_gen, config):
self.optimize(model.loss, config.optimizer_type, config.lr)
self.init_and_run_ps_worker(config.ckpt_path)
self.program = self.complie_program(model.loss)
self.fleet = tfleet
model.data_loader.decorate_batch_generator(
data_gen, places=F.cpu_places())
self.config = config
self.model = model
def optimize(self, loss, optimizer_type, lr):
strategy = DistributeTranspilerConfig()
strategy.sync_mode = False
log.info('learning rate:%f' % lr)
if optimizer_type == "sgd":
optimizer = F.optimizer.SGD(learning_rate=lr)
elif optimizer_type == "adam":
# Don't slice tensor ensure convergence
optimizer = F.optimizer.Adam(learning_rate=lr, lazy_mode=True)
else:
raise ValueError("Unknown Optimizer %s" % optimizer_type)
#create the DistributeTranspiler configure
optimizer = tfleet.distributed_optimizer(optimizer, strategy)
optimizer.minimize(loss)
def init_and_run_ps_worker(self, ckpt_path):
# init and run server or worker
self.exe = F.Executor(F.CPUPlace())
if tfleet.is_server():
tfleet.init_server()
self.warmstart(tfleet.startup_program, path=ckpt_path)
tfleet.run_server()
exit()
if tfleet.is_worker():
log.info("start init worker done")
tfleet.init_worker()
self.exe.run(tfleet.startup_program)
def complie_program(self, loss):
num_threads = int(os.getenv("CPU_NUM", 1))
exec_strategy = F.ExecutionStrategy()
exec_strategy.num_threads = num_threads
exec_strategy.use_thread_barrier = False
build_strategy = F.BuildStrategy()
build_strategy.enable_inplace = True
build_strategy.memory_optimize = True
build_strategy.remove_unnecessary_lock = False
build_strategy.memory_optimize = False
build_strategy.async_mode = False
if num_threads > 1:
build_strategy.reduce_strategy = F.BuildStrategy.ReduceStrategy.Reduce
log.info("start build compile program...")
compiled_prog = F.compiler.CompiledProgram(tfleet.main_program
).with_data_parallel(
loss_name=loss.name,
build_strategy=build_strategy,
exec_strategy=exec_strategy)
return compiled_prog
class CollectiveLearner(Learner):
def __init__(self):
role = role_maker.PaddleCloudRoleMaker(is_collective=True)
cfleet.init(role)
def optimize(self, loss, optimizer_type, lr):
optimizer = F.optimizer.Adam(learning_rate=lr)
dist_strategy = DistributedStrategy()
optimizer = cfleet.distributed_optimizer(optimizer, strategy=dist_strategy)
_, param_grads = optimizer.minimize(loss, F.default_startup_program())
def build(self, model, data_gen, config):
self.optimize(model.loss, config.optimizer_type, config.lr)
self.program = cfleet.main_program
gpu_id = int(os.getenv("FLAGS_selected_gpus", "0"))
place = F.CUDAPlace(gpu_id)
self.exe = F.Executor(place)
self.exe.run(F.default_startup_program())
self.warmstart(F.default_startup_program(), config.ckpt_path)
self.fleet = cfleet
model.data_loader.decorate_batch_generator(
data_gen, places=place)
self.config = config
self.model = model
#!/bin/bash
set -x
config=${1:-"./config.yaml"}
unset http_proxy https_proxy
function parse_yaml {
local prefix=$2
local s='[[:space:]]*' w='[a-zA-Z0-9_]*' fs=$(echo @|tr @ '\034')
sed -ne "s|^\($s\):|\1|" \
-e "s|^\($s\)\($w\)$s:$s[\"']\(.*\)[\"']$s\$|\1$fs\2$fs\3|p" \
-e "s|^\($s\)\($w\)$s:$s\(.*\)$s\$|\1$fs\2$fs\3|p" $1 |
awk -F$fs '{
indent = length($1)/2;
vname[indent] = $2;
for (i in vname) {if (i > indent) {delete vname[i]}}
if (length($3) > 0) {
vn=""; for (i=0; i<indent; i++) {vn=(vn)(vname[i])("_")}
printf("%s%s%s=\"%s\"\n", "'$prefix'",vn, $2, $3);
}
}'
}
transpiler_local_train(){
export PADDLE_TRAINERS_NUM=1
export PADDLE_PSERVERS_NUM=1
export PADDLE_PORT=6206
export PADDLE_PSERVERS="127.0.0.1"
export BASE="./local_dir"
echo `which python`
if [ -d ${BASE} ]; then
rm -rf ${BASE}
fi
mkdir ${BASE}
rm job_id
for((i=0;i<${PADDLE_PSERVERS_NUM};i++))
do
echo "start ps server: ${i}"
TRAINING_ROLE="PSERVER" PADDLE_TRAINER_ID=${i} sh job.sh local $config \
&> $BASE/pserver.$i.log &
echo $! >> job_id
done
sleep 3s
for((j=0;j<${PADDLE_TRAINERS_NUM};j++))
do
echo "start ps work: ${j}"
TRAINING_ROLE="TRAINER" PADDLE_TRAINER_ID=${j} sh job.sh local $config \
echo $! >> job_id
done
}
collective_local_train(){
export PATH=./python27-gcc482-gpu/bin/:$PATH
echo `which python`
python -m paddle.distributed.launch train.py --conf $config
python -m paddle.distributed.launch infer.py --conf $config
}
eval $(parse_yaml $config)
unalias python
python3 ./preprocessing/dump_graph.py -i $input_data -o $graph_path --encoding $encoding \
-l $max_seqlen --vocab_file $ernie_vocab_file
if [[ $learner_type == "cpu" ]];then
transpiler_local_train
fi
if [[ $learner_type == "gpu" ]];then
collective_local_train
fi
# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import time
import glob
import os
import numpy as np
import pgl
import paddle.fluid as F
import paddle.fluid.layers as L
from models import message_passing
def get_layer(layer_type, gw, feature, hidden_size, act, initializer, learning_rate, name, is_test=False):
return getattr(message_passing, layer_type)(gw, feature, hidden_size, act, initializer, learning_rate, name)
class BaseGraphWrapperBuilder(object):
def __init__(self, config):
self.config = config
self.node_feature_info = []
self.edge_feature_info = []
def __call__(self):
place = F.CPUPlace()
graph_wrappers = []
for i in range(self.config.num_layers):
# all graph have same node_feat_info
graph_wrappers.append(
pgl.graph_wrapper.GraphWrapper(
"layer_%s" % i, place, node_feat=self.node_feature_info, edge_feat=self.edge_feature_info))
return graph_wrappers
class GraphsageGraphWrapperBuilder(BaseGraphWrapperBuilder):
def __init__(self, config):
super(GraphsageGraphWrapperBuilder, self).__init__(config)
self.node_feature_info.append(('index', [None], np.dtype('int64')))
class BaseGNNModel(object):
def __init__(self, config):
self.config = config
self.graph_wrapper_builder = self.gen_graph_wrapper_builder(config)
self.net_fn = self.gen_net_fn(config)
self.feed_list_builder = self.gen_feed_list_builder(config)
self.data_loader_builder = self.gen_data_loader_builder(config)
self.loss_fn = self.gen_loss_fn(config)
self.build()
def gen_graph_wrapper_builder(self, config):
return GraphsageGraphWrapperBuilder(config)
def gen_net_fn(self, config):
return BaseNet(config)
def gen_feed_list_builder(self, config):
return BaseFeedListBuilder(config)
def gen_data_loader_builder(self, config):
return BaseDataLoaderBuilder(config)
def gen_loss_fn(self, config):
return BaseLoss(config)
def build(self):
self.graph_wrappers = self.graph_wrapper_builder()
self.inputs, self.outputs = self.net_fn(self.graph_wrappers)
self.feed_list = self.feed_list_builder(self.inputs, self.graph_wrappers)
self.data_loader = self.data_loader_builder(self.feed_list)
self.loss = self.loss_fn(self.outputs)
class BaseFeedListBuilder(object):
def __init__(self, config):
self.config = config
def __call__(self, inputs, graph_wrappers):
feed_list = []
for i in range(len(graph_wrappers)):
feed_list.extend(graph_wrappers[i].holder_list)
feed_list.extend(inputs)
return feed_list
class BaseDataLoaderBuilder(object):
def __init__(self, config):
self.config = config
def __call__(self, feed_list):
data_loader = F.io.PyReader(
feed_list=feed_list, capacity=20, use_double_buffer=True, iterable=True)
return data_loader
class BaseNet(object):
def __init__(self, config):
self.config = config
def take_final_feature(self, feature, index, name):
"""take final feature"""
feat = L.gather(feature, index, overwrite=False)
if self.config.final_fc:
feat = L.fc(feat,
self.config.hidden_size,
param_attr=F.ParamAttr(name=name + '_w'),
bias_attr=F.ParamAttr(name=name + '_b'))
if self.config.final_l2_norm:
feat = L.l2_normalize(feat, axis=1)
return feat
def build_inputs(self):
user_index = L.data(
"user_index", shape=[None], dtype="int64", append_batch_size=False)
item_index = L.data(
"item_index", shape=[None], dtype="int64", append_batch_size=False)
return [user_index, item_index]
def build_embedding(self, graph_wrappers, inputs=None):
num_embed = int(np.load(os.path.join(self.config.graph_path, "num_nodes.npy")))
is_sparse = self.config.trainer_type == "Transpiler"
embed = L.embedding(
input=L.reshape(graph_wrappers[0].node_feat['index'], [-1, 1]),
size=[num_embed, self.config.hidden_size],
is_sparse=is_sparse,
param_attr=F.ParamAttr(name="node_embedding", initializer=F.initializer.Uniform(
low=-1. / self.config.hidden_size,
high=1. / self.config.hidden_size)))
return embed
def gnn_layers(self, graph_wrappers, feature):
features = [feature]
initializer = None
fc_lr = self.config.lr / 0.001
for i in range(self.config.num_layers):
if i == self.config.num_layers - 1:
act = None
else:
act = "leaky_relu"
feature = get_layer(
self.config.layer_type,
graph_wrappers[i],
feature,
self.config.hidden_size,
act,
initializer,
learning_rate=fc_lr,
name="%s_%s" % (self.config.layer_type, i))
features.append(feature)
return features
def __call__(self, graph_wrappers):
inputs = self.build_inputs()
feature = self.build_embedding(graph_wrappers, inputs)
features = self.gnn_layers(graph_wrappers, feature)
outputs = [self.take_final_feature(features[-1], i, "final_fc") for i in inputs]
src_real_index = L.gather(graph_wrappers[0].node_feat['index'], inputs[0])
outputs.append(src_real_index)
return inputs, outputs
class BaseLoss(object):
def __init__(self, config):
self.config = config
def __call__(self, outputs):
user_feat, item_feat = outputs[0], outputs[1]
loss_type = self.config.loss_type
# Calc Loss
if self.config.loss_type == "hinge":
pos = L.reduce_sum(user_feat * item_feat, -1, keep_dim=True) # [B, 1]
neg = L.matmul(user_feat, item_feat, transpose_y=True) # [B, B]
loss = L.reduce_mean(L.relu(neg - pos + self.config.margin))
elif self.config.loss_type == "softmax":
pass
# TODO
# pos = L.reduce_sum(user_feat * item_feat, -1, keep_dim=True) # [B, 1]
# neg = L.matmul(user_feat, neg_feat, transpose_y=True) # [B, B]
# logits = L.concat([pos, neg], -1) # [B, 1+B]
# labels = L.fill_constant_batch_size_like(logits, [-1, 1], "int64", 0)
# loss = L.reduce_mean(L.softmax_with_cross_entropy(logits, labels))
else:
raise ValueError
return loss
"""Ernie
"""
from models.base import BaseNet, BaseGNNModel
class Ernie(BaseNet):
def build_inputs(self):
inputs = super(Ernie, self).build_inputs()
term_ids = L.data(
"term_ids", shape=[None, self.config.max_seqlen], dtype="int64", append_batch_size=False)
return inputs + [term_ids]
def build_embedding(self, graph_wrappers, term_ids):
term_ids = L.unsqueeze(term_ids, [-1])
ernie_config = self.config.ernie_config
ernie = ErnieModel(
src_ids=term_ids,
sentence_ids=L.zeros_like(term_ids),
task_ids=None,
config=ernie_config,
use_fp16=False,
name="student_")
feature = ernie.get_pooled_output()
return feature
def __call__(self, graph_wrappers):
inputs = self.build_inputs()
feature = self.build_embedding(graph_wrappers, inputs[-1])
features = [feature]
outputs = [self.take_final_feature(features[-1], i, "final_fc") for i in inputs[:-1]]
src_real_index = L.gather(graph_wrappers[0].node_feat['index'], inputs[0])
outputs.append(src_real_index)
return inputs, outputs
class ErnieModel(BaseGNNModel):
def gen_net_fn(self, config):
return Ernie(config)
# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""Ernie model."""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
from __future__ import unicode_literals
import json
import six
import logging
import paddle.fluid as fluid
import paddle.fluid.layers as L
from io import open
from models.ernie_model.transformer_encoder import encoder, pre_process_layer
from models.ernie_model.transformer_encoder import graph_encoder
log = logging.getLogger(__name__)
class ErnieConfig(object):
def __init__(self, config_path):
self._config_dict = self._parse(config_path)
def _parse(self, config_path):
try:
with open(config_path, 'r', encoding='utf8') as json_file:
config_dict = json.load(json_file)
except Exception:
raise IOError("Error in parsing Ernie model config file '%s'" %
config_path)
else:
return config_dict
def __getitem__(self, key):
return self._config_dict.get(key, None)
def print_config(self):
for arg, value in sorted(six.iteritems(self._config_dict)):
log.info('%s: %s' % (arg, value))
log.info('------------------------------------------------')
class ErnieModel(object):
def __init__(self,
src_ids,
sentence_ids,
task_ids=None,
config=None,
weight_sharing=True,
use_fp16=False,
name=""):
self._set_config(config, name, weight_sharing)
input_mask = self._build_input_mask(src_ids)
position_ids = self._build_position_ids(src_ids)
self._build_model(src_ids, position_ids, sentence_ids, task_ids,
input_mask)
self._debug_summary(input_mask)
def _debug_summary(self, input_mask):
#histogram
seqlen_before_pad = L.cast(
L.reduce_sum(
input_mask, dim=1), dtype='float32')
seqlen_after_pad = L.reduce_sum(
L.cast(
L.zeros_like(input_mask), dtype='float32') + 1.0, dim=1)
pad_num = seqlen_after_pad - seqlen_before_pad
pad_rate = pad_num / seqlen_after_pad
def _build_position_ids(self, src_ids):
d_shape = L.shape(src_ids)
d_seqlen = d_shape[1]
d_batch = d_shape[0]
position_ids = L.reshape(
L.range(
0, d_seqlen, 1, dtype='int32'), [1, d_seqlen, 1],
inplace=True)
position_ids = L.expand(position_ids, [d_batch, 1, 1])
position_ids = L.cast(position_ids, 'int64')
position_ids.stop_gradient = True
return position_ids
def _build_input_mask(self, src_ids):
zero = L.fill_constant([1], dtype='int64', value=0)
input_mask = L.logical_not(L.equal(src_ids,
zero)) # assume pad id == 0
input_mask = L.cast(input_mask, 'float')
input_mask.stop_gradient = True
return input_mask
def _set_config(self, config, name, weight_sharing):
self._emb_size = config['hidden_size']
self._n_layer = config['num_hidden_layers']
self._n_head = config['num_attention_heads']
self._voc_size = config['vocab_size']
self._max_position_seq_len = config['max_position_embeddings']
if config.get('sent_type_vocab_size'):
self._sent_types = config['sent_type_vocab_size']
else:
self._sent_types = config['type_vocab_size']
self._use_task_id = config['use_task_id']
if self._use_task_id:
self._task_types = config['task_type_vocab_size']
self._hidden_act = config['hidden_act']
self._postprocess_cmd = config.get('postprocess_cmd', 'dan')
self._preprocess_cmd = config.get('preprocess_cmd', '')
self._prepostprocess_dropout = config['hidden_dropout_prob']
self._attention_dropout = config['attention_probs_dropout_prob']
self._weight_sharing = weight_sharing
self.name = name
self._word_emb_name = self.name + "word_embedding"
self._pos_emb_name = self.name + "pos_embedding"
self._sent_emb_name = self.name + "sent_embedding"
self._task_emb_name = self.name + "task_embedding"
self._dtype = "float16" if config['use_fp16'] else "float32"
self._emb_dtype = "float32"
# Initialize all weigths by truncated normal initializer, and all biases
# will be initialized by constant zero by default.
self._param_initializer = fluid.initializer.TruncatedNormal(
scale=config['initializer_range'])
def _build_model(self, src_ids, position_ids, sentence_ids, task_ids,
input_mask):
emb_out = self._build_embedding(src_ids, position_ids, sentence_ids,
task_ids)
self.input_mask = input_mask
self._enc_out, self.all_hidden, self.all_attn, self.all_ffn = encoder(
enc_input=emb_out,
input_mask=input_mask,
n_layer=self._n_layer,
n_head=self._n_head,
d_key=self._emb_size // self._n_head,
d_value=self._emb_size // self._n_head,
d_model=self._emb_size,
d_inner_hid=self._emb_size * 4,
prepostprocess_dropout=self._prepostprocess_dropout,
attention_dropout=self._attention_dropout,
relu_dropout=0,
hidden_act=self._hidden_act,
preprocess_cmd=self._preprocess_cmd,
postprocess_cmd=self._postprocess_cmd,
param_initializer=self._param_initializer,
name=self.name + 'encoder')
if self._dtype == "float16":
self._enc_out = fluid.layers.cast(
x=self._enc_out, dtype=self._emb_dtype)
def _build_embedding(self, src_ids, position_ids, sentence_ids, task_ids):
# padding id in vocabulary must be set to 0
emb_out = fluid.layers.embedding(
input=src_ids,
size=[self._voc_size, self._emb_size],
dtype=self._emb_dtype,
param_attr=fluid.ParamAttr(
name=self._word_emb_name, initializer=self._param_initializer),
is_sparse=False)
position_emb_out = fluid.layers.embedding(
input=position_ids,
size=[self._max_position_seq_len, self._emb_size],
dtype=self._emb_dtype,
param_attr=fluid.ParamAttr(
name=self._pos_emb_name, initializer=self._param_initializer))
sent_emb_out = fluid.layers.embedding(
sentence_ids,
size=[self._sent_types, self._emb_size],
dtype=self._emb_dtype,
param_attr=fluid.ParamAttr(
name=self._sent_emb_name, initializer=self._param_initializer))
self.all_emb = [emb_out, position_emb_out, sent_emb_out]
emb_out = emb_out + position_emb_out
emb_out = emb_out + sent_emb_out
if self._use_task_id:
task_emb_out = fluid.layers.embedding(
task_ids,
size=[self._task_types, self._emb_size],
dtype=self._emb_dtype,
param_attr=fluid.ParamAttr(
name=self._task_emb_name,
initializer=self._param_initializer))
emb_out = emb_out + task_emb_out
emb_out = pre_process_layer(
emb_out,
'nd',
self._prepostprocess_dropout,
name=self.name + 'pre_encoder')
if self._dtype == "float16":
emb_out = fluid.layers.cast(x=emb_out, dtype=self._dtype)
return emb_out
def get_sequence_output(self):
return self._enc_out
def get_pooled_output(self):
"""Get the first feature of each sequence for classification"""
next_sent_feat = self._enc_out[:, 0, :]
#next_sent_feat = fluid.layers.slice(input=self._enc_out, axes=[1], starts=[0], ends=[1])
next_sent_feat = fluid.layers.fc(
input=next_sent_feat,
size=self._emb_size,
act="tanh",
param_attr=fluid.ParamAttr(
name=self.name + "pooled_fc.w_0",
initializer=self._param_initializer),
bias_attr=self.name + "pooled_fc.b_0")
return next_sent_feat
def get_lm_output(self, mask_label, mask_pos):
"""Get the loss & accuracy for pretraining"""
mask_pos = fluid.layers.cast(x=mask_pos, dtype='int32')
# extract the first token feature in each sentence
self.next_sent_feat = self.get_pooled_output()
reshaped_emb_out = fluid.layers.reshape(
x=self._enc_out, shape=[-1, self._emb_size])
# extract masked tokens' feature
mask_feat = fluid.layers.gather(input=reshaped_emb_out, index=mask_pos)
# transform: fc
mask_trans_feat = fluid.layers.fc(
input=mask_feat,
size=self._emb_size,
act=self._hidden_act,
param_attr=fluid.ParamAttr(
name=self.name + 'mask_lm_trans_fc.w_0',
initializer=self._param_initializer),
bias_attr=fluid.ParamAttr(name=self.name + 'mask_lm_trans_fc.b_0'))
# transform: layer norm
mask_trans_feat = fluid.layers.layer_norm(
mask_trans_feat,
begin_norm_axis=len(mask_trans_feat.shape) - 1,
param_attr=fluid.ParamAttr(
name=self.name + 'mask_lm_trans_layer_norm_scale',
initializer=fluid.initializer.Constant(1.)),
bias_attr=fluid.ParamAttr(
name=self.name + 'mask_lm_trans_layer_norm_bias',
initializer=fluid.initializer.Constant(0.)))
# transform: layer norm
#mask_trans_feat = pre_process_layer(
# mask_trans_feat, 'n', name=self.name + 'mask_lm_trans')
mask_lm_out_bias_attr = fluid.ParamAttr(
name=self.name + "mask_lm_out_fc.b_0",
initializer=fluid.initializer.Constant(value=0.0))
if self._weight_sharing:
fc_out = fluid.layers.matmul(
x=mask_trans_feat,
y=fluid.default_main_program().global_block().var(
self._word_emb_name),
transpose_y=True)
fc_out += fluid.layers.create_parameter(
shape=[self._voc_size],
dtype=self._emb_dtype,
attr=mask_lm_out_bias_attr,
is_bias=True)
else:
fc_out = fluid.layers.fc(input=mask_trans_feat,
size=self._voc_size,
param_attr=fluid.ParamAttr(
name=self.name + "mask_lm_out_fc.w_0",
initializer=self._param_initializer),
bias_attr=mask_lm_out_bias_attr)
mask_lm_loss = fluid.layers.softmax_with_cross_entropy(
logits=fc_out, label=mask_label)
return mask_lm_loss
def get_task_output(self, task, task_labels):
task_fc_out = fluid.layers.fc(
input=self.next_sent_feat,
size=task["num_labels"],
param_attr=fluid.ParamAttr(
name=self.name + task["task_name"] + "_fc.w_0",
initializer=self._param_initializer),
bias_attr=self.name + task["task_name"] + "_fc.b_0")
task_loss, task_softmax = fluid.layers.softmax_with_cross_entropy(
logits=task_fc_out, label=task_labels, return_softmax=True)
task_acc = fluid.layers.accuracy(input=task_softmax, label=task_labels)
return task_loss, task_acc
class ErnieGraphModel(ErnieModel):
def __init__(self,
src_ids,
task_ids=None,
config=None,
weight_sharing=True,
use_fp16=False,
slot_seqlen=40,
name=""):
self.slot_seqlen = slot_seqlen
self._set_config(config, name, weight_sharing)
input_mask = self._build_input_mask(src_ids)
position_ids = self._build_position_ids(src_ids)
sentence_ids = self._build_sentence_ids(src_ids)
self._build_model(src_ids, position_ids, sentence_ids, task_ids,
input_mask)
self._debug_summary(input_mask)
def _build_position_ids(self, src_ids):
src_shape = L.shape(src_ids)
src_seqlen = src_shape[1]
src_batch = src_shape[0]
slot_seqlen = self.slot_seqlen
num_b = (src_seqlen / slot_seqlen) - 1
a_position_ids = L.reshape(
L.range(
0, slot_seqlen, 1, dtype='int32'), [1, slot_seqlen, 1],
inplace=True) # [1, slot_seqlen, 1]
a_position_ids = L.expand(a_position_ids, [src_batch, 1, 1]) # [B, slot_seqlen * num_b, 1]
zero = L.fill_constant([1], dtype='int64', value=0)
input_mask = L.cast(L.equal(src_ids[:, :slot_seqlen], zero), "int32") # assume pad id == 0 [B, slot_seqlen, 1]
a_pad_len = L.reduce_sum(input_mask, 1) # [B, 1, 1]
b_position_ids = L.reshape(
L.range(
slot_seqlen, 2*slot_seqlen, 1, dtype='int32'), [1, slot_seqlen, 1],
inplace=True) # [1, slot_seqlen, 1]
b_position_ids = L.expand(b_position_ids, [src_batch, num_b, 1]) # [B, slot_seqlen * num_b, 1]
b_position_ids = b_position_ids - a_pad_len # [B, slot_seqlen * num_b, 1]
position_ids = L.concat([a_position_ids, b_position_ids], 1)
position_ids = L.cast(position_ids, 'int64')
position_ids.stop_gradient = True
return position_ids
def _build_sentence_ids(self, src_ids):
src_shape = L.shape(src_ids)
src_seqlen = src_shape[1]
src_batch = src_shape[0]
slot_seqlen = self.slot_seqlen
zeros = L.zeros([src_batch, slot_seqlen, 1], "int64")
ones = L.ones([src_batch, src_seqlen-slot_seqlen, 1], "int64")
sentence_ids = L.concat([zeros, ones], 1)
sentence_ids.stop_gradient = True
return sentence_ids
def _build_model(self, src_ids, position_ids, sentence_ids, task_ids,
input_mask):
emb_out = self._build_embedding(src_ids, position_ids, sentence_ids,
task_ids)
self.input_mask = input_mask
self._enc_out, self.all_hidden, self.all_attn, self.all_ffn = graph_encoder(
enc_input=emb_out,
input_mask=input_mask,
n_layer=self._n_layer,
n_head=self._n_head,
d_key=self._emb_size // self._n_head,
d_value=self._emb_size // self._n_head,
d_model=self._emb_size,
d_inner_hid=self._emb_size * 4,
prepostprocess_dropout=self._prepostprocess_dropout,
attention_dropout=self._attention_dropout,
relu_dropout=0,
hidden_act=self._hidden_act,
preprocess_cmd=self._preprocess_cmd,
postprocess_cmd=self._postprocess_cmd,
param_initializer=self._param_initializer,
slot_seqlen=self.slot_seqlen,
name=self.name + 'encoder')
if self._dtype == "float16":
self._enc_out = fluid.layers.cast(
x=self._enc_out, dtype=self._emb_dtype)
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from functools import partial
import numpy as np
from contextlib import contextmanager
import paddle.fluid as fluid
import paddle.fluid.layers as L
import paddle.fluid.layers as layers
#import propeller.paddle as propeller
#from propeller import log
#determin this at the begining
to_3d = lambda a: a # will change later
to_2d = lambda a: a
def multi_head_attention(queries,
keys,
values,
attn_bias,
d_key,
d_value,
d_model,
n_head=1,
dropout_rate=0.,
cache=None,
param_initializer=None,
name='multi_head_att'):
"""
Multi-Head Attention. Note that attn_bias is added to the logit before
computing softmax activiation to mask certain selected positions so that
they will not considered in attention weights.
"""
keys = queries if keys is None else keys
values = keys if values is None else values
def __compute_qkv(queries, keys, values, n_head, d_key, d_value):
"""
Add linear projection to queries, keys, and values.
"""
q = layers.fc(input=queries,
size=d_key * n_head,
num_flatten_dims=len(queries.shape) - 1,
param_attr=fluid.ParamAttr(
name=name + '_query_fc.w_0',
initializer=param_initializer),
bias_attr=name + '_query_fc.b_0')
k = layers.fc(input=keys,
size=d_key * n_head,
num_flatten_dims=len(keys.shape) - 1,
param_attr=fluid.ParamAttr(
name=name + '_key_fc.w_0',
initializer=param_initializer),
bias_attr=name + '_key_fc.b_0')
v = layers.fc(input=values,
size=d_value * n_head,
num_flatten_dims=len(values.shape) - 1,
param_attr=fluid.ParamAttr(
name=name + '_value_fc.w_0',
initializer=param_initializer),
bias_attr=name + '_value_fc.b_0')
return q, k, v
def __split_heads(x, n_head):
"""
Reshape the last dimension of inpunt tensor x so that it becomes two
dimensions and then transpose. Specifically, input a tensor with shape
[bs, max_sequence_length, n_head * hidden_dim] then output a tensor
with shape [bs, n_head, max_sequence_length, hidden_dim].
"""
hidden_size = x.shape[-1]
# The value 0 in shape attr means copying the corresponding dimension
# size of the input as the output dimension size.
reshaped = layers.reshape(
x=x, shape=[0, 0, n_head, hidden_size // n_head], inplace=True)
# permuate the dimensions into:
# [batch_size, n_head, max_sequence_len, hidden_size_per_head]
return layers.transpose(x=reshaped, perm=[0, 2, 1, 3])
def __combine_heads(x):
"""
Transpose and then reshape the last two dimensions of inpunt tensor x
so that it becomes one dimension, which is reverse to __split_heads.
"""
if len(x.shape) == 3: return x
if len(x.shape) != 4:
raise ValueError("Input(x) should be a 4-D Tensor.")
trans_x = layers.transpose(x, perm=[0, 2, 1, 3])
# The value 0 in shape attr means copying the corresponding dimension
# size of the input as the output dimension size.
#trans_x.desc.set_shape((-1, 1, n_head, d_value))
return layers.reshape(x=trans_x, shape=[0, 0, d_model], inplace=True)
def scaled_dot_product_attention(q, k, v, attn_bias, d_key, dropout_rate):
"""
Scaled Dot-Product Attention
"""
scaled_q = layers.scale(x=q, scale=d_key**-0.5)
product = layers.matmul(x=scaled_q, y=k, transpose_y=True)
if attn_bias:
product += attn_bias
weights = layers.softmax(product)
if dropout_rate:
weights = layers.dropout(
weights,
dropout_prob=dropout_rate,
dropout_implementation="upscale_in_train",
is_test=False)
out = layers.matmul(weights, v)
#return out, product
return out, weights
q, k, v = __compute_qkv(queries, keys, values, n_head, d_key, d_value)
q = to_3d(q)
k = to_3d(k)
v = to_3d(v)
if cache is not None: # use cache and concat time steps
# Since the inplace reshape in __split_heads changes the shape of k and
# v, which is the cache input for next time step, reshape the cache
# input from the previous time step first.
k = cache["k"] = layers.concat(
[layers.reshape(
cache["k"], shape=[0, 0, d_model]), k], axis=1)
v = cache["v"] = layers.concat(
[layers.reshape(
cache["v"], shape=[0, 0, d_model]), v], axis=1)
q = __split_heads(q, n_head)
k = __split_heads(k, n_head)
v = __split_heads(v, n_head)
ctx_multiheads, ctx_multiheads_attn = scaled_dot_product_attention(
q, k, v, attn_bias, d_key, dropout_rate)
out = __combine_heads(ctx_multiheads)
out = to_2d(out)
# Project back to the model size.
proj_out = layers.fc(input=out,
size=d_model,
num_flatten_dims=len(out.shape) - 1,
param_attr=fluid.ParamAttr(
name=name + '_output_fc.w_0',
initializer=param_initializer),
bias_attr=name + '_output_fc.b_0')
return proj_out, ctx_multiheads_attn
def positionwise_feed_forward(x,
d_inner_hid,
d_hid,
dropout_rate,
hidden_act,
param_initializer=None,
name='ffn'):
"""
Position-wise Feed-Forward Networks.
This module consists of two linear transformations with a ReLU activation
in between, which is applied to each position separately and identically.
"""
hidden = layers.fc(input=x,
size=d_inner_hid,
num_flatten_dims=len(x.shape) - 1,
act=hidden_act,
param_attr=fluid.ParamAttr(
name=name + '_fc_0.w_0',
initializer=param_initializer),
bias_attr=name + '_fc_0.b_0')
if dropout_rate:
hidden = layers.dropout(
hidden,
dropout_prob=dropout_rate,
dropout_implementation="upscale_in_train",
is_test=False)
out = layers.fc(input=hidden,
size=d_hid,
num_flatten_dims=len(hidden.shape) - 1,
param_attr=fluid.ParamAttr(
name=name + '_fc_1.w_0',
initializer=param_initializer),
bias_attr=name + '_fc_1.b_0')
return out
def pre_post_process_layer(prev_out,
out,
process_cmd,
dropout_rate=0.,
name=''):
"""
Add residual connection, layer normalization and droput to the out tensor
optionally according to the value of process_cmd.
This will be used before or after multi-head attention and position-wise
feed-forward networks.
"""
for cmd in process_cmd:
if cmd == "a": # add residual connection
out = out + prev_out if prev_out else out
elif cmd == "n": # add layer normalization
out_dtype = out.dtype
if out_dtype == fluid.core.VarDesc.VarType.FP16:
out = layers.cast(x=out, dtype="float32")
out = layers.layer_norm(
out,
begin_norm_axis=len(out.shape) - 1,
param_attr=fluid.ParamAttr(
name=name + '_layer_norm_scale',
initializer=fluid.initializer.Constant(1.)),
bias_attr=fluid.ParamAttr(
name=name + '_layer_norm_bias',
initializer=fluid.initializer.Constant(0.)))
if out_dtype == fluid.core.VarDesc.VarType.FP16:
out = layers.cast(x=out, dtype="float16")
elif cmd == "d": # add dropout
if dropout_rate:
out = layers.dropout(
out,
dropout_prob=dropout_rate,
dropout_implementation="upscale_in_train",
is_test=False)
return out
pre_process_layer = partial(pre_post_process_layer, None)
post_process_layer = pre_post_process_layer
def encoder_layer(enc_input,
attn_bias,
n_head,
d_key,
d_value,
d_model,
d_inner_hid,
prepostprocess_dropout,
attention_dropout,
relu_dropout,
hidden_act,
preprocess_cmd="n",
postprocess_cmd="da",
param_initializer=None,
name=''):
"""The encoder layers that can be stacked to form a deep encoder.
This module consits of a multi-head (self) attention followed by
position-wise feed-forward networks and both the two components companied
with the post_process_layer to add residual connection, layer normalization
and droput.
"""
#L.Print(L.reduce_mean(enc_input), message='1')
attn_output, ctx_multiheads_attn = multi_head_attention(
pre_process_layer(
enc_input,
preprocess_cmd,
prepostprocess_dropout,
name=name + '_pre_att'),
None,
None,
attn_bias,
d_key,
d_value,
d_model,
n_head,
attention_dropout,
param_initializer=param_initializer,
name=name + '_multi_head_att')
#L.Print(L.reduce_mean(attn_output), message='1')
attn_output = post_process_layer(
enc_input,
attn_output,
postprocess_cmd,
prepostprocess_dropout,
name=name + '_post_att')
#L.Print(L.reduce_mean(attn_output), message='2')
ffd_output = positionwise_feed_forward(
pre_process_layer(
attn_output,
preprocess_cmd,
prepostprocess_dropout,
name=name + '_pre_ffn'),
d_inner_hid,
d_model,
relu_dropout,
hidden_act,
param_initializer=param_initializer,
name=name + '_ffn')
#L.Print(L.reduce_mean(ffd_output), message='3')
ret = post_process_layer(
attn_output,
ffd_output,
postprocess_cmd,
prepostprocess_dropout,
name=name + '_post_ffn')
#L.Print(L.reduce_mean(ret), message='4')
return ret, ctx_multiheads_attn, ffd_output
def build_pad_idx(input_mask):
pad_idx = L.where(L.cast(L.squeeze(input_mask, [2]), 'bool'))
return pad_idx
def build_attn_bias(input_mask, n_head, dtype):
attn_bias = L.matmul(
input_mask, input_mask, transpose_y=True) # [batch, seq, seq]
attn_bias = (1. - attn_bias) * -10000.
attn_bias = L.stack([attn_bias] * n_head, 1) # [batch, n_head, seq, seq]
if attn_bias.dtype != dtype:
attn_bias = L.cast(attn_bias, dtype)
return attn_bias
def build_graph_attn_bias(input_mask, n_head, dtype, slot_seqlen):
input_shape = L.shape(input_mask)
input_batch = input_shape[0]
input_seqlen = input_shape[1]
num_slot = input_seqlen / slot_seqlen
num_b = num_slot - 1
ones = L.ones([num_b], dtype="float32") # [num_b]
diag_ones = L.diag(ones) # [num_b, num_b]
diag_ones = L.unsqueeze(diag_ones, [1, -1]) # [num_b, 1, num_b, 1]
diag_ones = L.expand(diag_ones, [1, slot_seqlen, 1, slot_seqlen]) # [num_b, seqlen, num_b, seqlen]
diag_ones = L.reshape(diag_ones, [1, num_b*slot_seqlen, num_b*slot_seqlen]) # [1, num_b*seqlen, num_b*seqlen]
graph_attn_bias = L.concat([L.ones([1, num_b*slot_seqlen, slot_seqlen], dtype="float32"), diag_ones], 2)
graph_attn_bias = L.concat([L.ones([1, slot_seqlen, num_slot*slot_seqlen], dtype="float32"), graph_attn_bias], 1) # [1, seq, seq]
pad_attn_bias = L.matmul(
input_mask, input_mask, transpose_y=True) # [batch, seq, seq]
attn_bias = graph_attn_bias * pad_attn_bias
attn_bias = (1. - attn_bias) * -10000.
attn_bias = L.stack([attn_bias] * n_head, 1) # [batch, n_head, seq, seq]
if attn_bias.dtype != dtype:
attn_bias = L.cast(attn_bias, dtype)
return attn_bias
def encoder(enc_input,
input_mask,
n_layer,
n_head,
d_key,
d_value,
d_model,
d_inner_hid,
prepostprocess_dropout,
attention_dropout,
relu_dropout,
hidden_act,
preprocess_cmd="n",
postprocess_cmd="da",
param_initializer=None,
name=''):
"""
The encoder is composed of a stack of identical layers returned by calling
encoder_layer.
"""
#global to_2d, to_3d #, batch, seqlen, dynamic_dim
d_shape = L.shape(input_mask)
pad_idx = build_pad_idx(input_mask)
attn_bias = build_attn_bias(input_mask, n_head, enc_input.dtype)
# d_batch = d_shape[0]
# d_seqlen = d_shape[1]
# pad_idx = L.where(
# L.cast(L.reshape(input_mask, [d_batch, d_seqlen]), 'bool'))
# attn_bias = L.matmul(
# input_mask, input_mask, transpose_y=True) # [batch, seq, seq]
# attn_bias = (1. - attn_bias) * -10000.
# attn_bias = L.stack([attn_bias] * n_head, 1)
# if attn_bias.dtype != enc_input.dtype:
# attn_bias = L.cast(attn_bias, enc_input.dtype)
# def to_2d(t_3d):
# t_2d = L.gather_nd(t_3d, pad_idx)
# return t_2d
# def to_3d(t_2d):
# t_3d = L.scatter_nd(
# pad_idx, t_2d, shape=[d_shape[0], d_shape[1], d_model])
# return t_3d
enc_input = to_2d(enc_input)
all_hidden = []
all_attn = []
all_ffn = []
for i in range(n_layer):
enc_output, ctx_multiheads_attn, ffn_output = encoder_layer(
enc_input,
attn_bias,
n_head,
d_key,
d_value,
d_model,
d_inner_hid,
prepostprocess_dropout,
attention_dropout,
relu_dropout,
hidden_act,
preprocess_cmd,
postprocess_cmd,
param_initializer=param_initializer,
name=name + '_layer_' + str(i))
all_hidden.append(enc_output)
all_attn.append(ctx_multiheads_attn)
all_ffn.append(ffn_output)
enc_input = enc_output
enc_output = pre_process_layer(
enc_output,
preprocess_cmd,
prepostprocess_dropout,
name="post_encoder")
enc_output = to_3d(enc_output)
#enc_output.desc.set_shape((-1, 1, final_dim))
return enc_output, all_hidden, all_attn, all_ffn
def graph_encoder(enc_input,
input_mask,
n_layer,
n_head,
d_key,
d_value,
d_model,
d_inner_hid,
prepostprocess_dropout,
attention_dropout,
relu_dropout,
hidden_act,
preprocess_cmd="n",
postprocess_cmd="da",
param_initializer=None,
slot_seqlen=40,
name=''):
"""
The encoder is composed of a stack of identical layers returned by calling
encoder_layer.
"""
#global to_2d, to_3d #, batch, seqlen, dynamic_dim
d_shape = L.shape(input_mask)
pad_idx = build_pad_idx(input_mask)
attn_bias = build_graph_attn_bias(input_mask, n_head, enc_input.dtype, slot_seqlen)
#attn_bias = build_attn_bias(input_mask, n_head, enc_input.dtype)
# d_batch = d_shape[0]
# d_seqlen = d_shape[1]
# pad_idx = L.where(
# L.cast(L.reshape(input_mask, [d_batch, d_seqlen]), 'bool'))
# attn_bias = L.matmul(
# input_mask, input_mask, transpose_y=True) # [batch, seq, seq]
# attn_bias = (1. - attn_bias) * -10000.
# attn_bias = L.stack([attn_bias] * n_head, 1)
# if attn_bias.dtype != enc_input.dtype:
# attn_bias = L.cast(attn_bias, enc_input.dtype)
# def to_2d(t_3d):
# t_2d = L.gather_nd(t_3d, pad_idx)
# return t_2d
# def to_3d(t_2d):
# t_3d = L.scatter_nd(
# pad_idx, t_2d, shape=[d_shape[0], d_shape[1], d_model])
# return t_3d
enc_input = to_2d(enc_input)
all_hidden = []
all_attn = []
all_ffn = []
for i in range(n_layer):
enc_output, ctx_multiheads_attn, ffn_output = encoder_layer(
enc_input,
attn_bias,
n_head,
d_key,
d_value,
d_model,
d_inner_hid,
prepostprocess_dropout,
attention_dropout,
relu_dropout,
hidden_act,
preprocess_cmd,
postprocess_cmd,
param_initializer=param_initializer,
name=name + '_layer_' + str(i))
all_hidden.append(enc_output)
all_attn.append(ctx_multiheads_attn)
all_ffn.append(ffn_output)
enc_input = enc_output
enc_output = pre_process_layer(
enc_output,
preprocess_cmd,
prepostprocess_dropout,
name="post_encoder")
enc_output = to_3d(enc_output)
#enc_output.desc.set_shape((-1, 1, final_dim))
return enc_output, all_hidden, all_attn, all_ffn
import pgl
import paddle.fluid as F
import paddle.fluid.layers as L
from models.base import BaseNet, BaseGNNModel
from models.ernie_model.ernie import ErnieModel
from models.ernie_model.ernie import ErnieGraphModel
from models.ernie_model.ernie import ErnieConfig
class ErnieSageV1(BaseNet):
def build_inputs(self):
inputs = super(ErnieSageV1, self).build_inputs()
term_ids = L.data(
"term_ids", shape=[None, self.config.max_seqlen], dtype="int64", append_batch_size=False)
return inputs + [term_ids]
def build_embedding(self, graph_wrappers, term_ids):
term_ids = L.unsqueeze(term_ids, [-1])
ernie_config = self.config.ernie_config
ernie = ErnieModel(
src_ids=term_ids,
sentence_ids=L.zeros_like(term_ids),
task_ids=None,
config=ernie_config,
use_fp16=False,
name="student_")
feature = ernie.get_pooled_output()
return feature
def __call__(self, graph_wrappers):
inputs = self.build_inputs()
feature = self.build_embedding(graph_wrappers, inputs[-1])
features = self.gnn_layers(graph_wrappers, feature)
outputs = [self.take_final_feature(features[-1], i, "final_fc") for i in inputs[:-1]]
src_real_index = L.gather(graph_wrappers[0].node_feat['index'], inputs[0])
outputs.append(src_real_index)
return inputs, outputs
class ErnieSageModelV1(BaseGNNModel):
def gen_net_fn(self, config):
return ErnieSageV1(config)
import pgl
import paddle.fluid as F
import paddle.fluid.layers as L
from models.base import BaseNet, BaseGNNModel
from models.ernie_model.ernie import ErnieModel
from models.ernie_model.ernie import ErnieGraphModel
from models.ernie_model.ernie import ErnieConfig
class ErnieSageV2(BaseNet):
def build_inputs(self):
inputs = super(ErnieSageV2, self).build_inputs()
term_ids = L.data(
"term_ids", shape=[None, self.config.max_seqlen], dtype="int64", append_batch_size=False)
return inputs + [term_ids]
def gnn_layer(self, gw, feature, hidden_size, act, initializer, learning_rate, name):
def ernie_send(src_feat, dst_feat, edge_feat):
"""doc"""
cls = L.fill_constant_batch_size_like(src_feat["term_ids"], [-1, 1, 1], "int64", 1)
src_ids = L.concat([cls, src_feat["term_ids"]], 1)
dst_ids = dst_feat["term_ids"]
sent_ids = L.concat([L.zeros_like(src_ids), L.ones_like(dst_ids)], 1)
term_ids = L.concat([src_ids, dst_ids], 1)
term_ids.stop_gradient = True
sent_ids.stop_gradient = True
ernie = ErnieModel(
term_ids, sent_ids,
config=self.config.ernie_config)
feature = ernie.get_pooled_output()
return feature
def erniesage_v2_aggregator(gw, feature, hidden_size, act, initializer, learning_rate, name):
feature = L.unsqueeze(feature, [-1])
msg = gw.send(ernie_send, nfeat_list=[("term_ids", feature)])
neigh_feature = gw.recv(msg, lambda feat: F.layers.sequence_pool(feat, pool_type="sum"))
term_ids = feature
cls = L.fill_constant_batch_size_like(term_ids, [-1, 1, 1], "int64", 1)
term_ids = L.concat([cls, term_ids], 1)
term_ids.stop_gradient = True
ernie = ErnieModel(
term_ids, L.zeros_like(term_ids),
config=self.config.ernie_config)
self_feature = ernie.get_pooled_output()
self_feature = L.fc(self_feature,
hidden_size,
act=act,
param_attr=F.ParamAttr(name=name + "_l",
learning_rate=learning_rate),
)
neigh_feature = L.fc(neigh_feature,
hidden_size,
act=act,
param_attr=F.ParamAttr(name=name + "_r",
learning_rate=learning_rate),
)
output = L.concat([self_feature, neigh_feature], axis=1)
output = L.l2_normalize(output, axis=1)
return output
return erniesage_v2_aggregator(gw, feature, hidden_size, act, initializer, learning_rate, name)
def gnn_layers(self, graph_wrappers, feature):
features = [feature]
initializer = None
fc_lr = self.config.lr / 0.001
for i in range(self.config.num_layers):
if i == self.config.num_layers - 1:
act = None
else:
act = "leaky_relu"
feature = self.gnn_layer(
graph_wrappers[i],
feature,
self.config.hidden_size,
act,
initializer,
learning_rate=fc_lr,
name="%s_%s" % ("erniesage_v2", i))
features.append(feature)
return features
def __call__(self, graph_wrappers):
inputs = self.build_inputs()
feature = inputs[-1]
features = self.gnn_layers(graph_wrappers, feature)
outputs = [self.take_final_feature(features[-1], i, "final_fc") for i in inputs[:-1]]
src_real_index = L.gather(graph_wrappers[0].node_feat['index'], inputs[0])
outputs.append(src_real_index)
return inputs, outputs
class ErnieSageModelV2(BaseGNNModel):
def gen_net_fn(self, config):
return ErnieSageV2(config)
# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import pgl
import paddle.fluid as F
import paddle.fluid.layers as L
from models.base import BaseNet, BaseGNNModel
from models.ernie_model.ernie import ErnieModel
from models.ernie_model.ernie import ErnieGraphModel
from models.ernie_model.ernie import ErnieConfig
from models.message_passing import copy_send
class ErnieSageV3(BaseNet):
def __init__(self, config):
super(ErnieSageV3, self).__init__(config)
self.config.layer_type = "ernie_recv_sum"
def build_inputs(self):
inputs = super(ErnieSageV3, self).build_inputs()
term_ids = L.data(
"term_ids", shape=[None, self.config.max_seqlen], dtype="int64", append_batch_size=False)
return inputs + [term_ids]
def gnn_layer(self, gw, feature, hidden_size, act, initializer, learning_rate, name):
def ernie_recv(feat):
"""doc"""
# TODO maxlen 400
#pad_value = L.cast(L.assign(input=np.array([0], dtype=np.int32)), "int64")
pad_value = L.zeros([1], "int64")
out, _ = L.sequence_pad(feat, pad_value=pad_value, maxlen=10)
out = L.reshape(out, [0, 400])
return out
def erniesage_v3_aggregator(gw, feature, hidden_size, act, initializer, learning_rate, name):
msg = gw.send(copy_send, nfeat_list=[("h", feature)])
neigh_feature = gw.recv(msg, ernie_recv)
neigh_feature = L.cast(L.unsqueeze(neigh_feature, [-1]), "int64")
feature = L.unsqueeze(feature, [-1])
cls = L.fill_constant_batch_size_like(feature, [-1, 1, 1], "int64", 1)
term_ids = L.concat([cls, feature[:, :-1], neigh_feature], 1)
term_ids.stop_gradient = True
return term_ids
return erniesage_v3_aggregator(gw, feature, hidden_size, act, initializer, learning_rate, name)
def gnn_layers(self, graph_wrappers, feature):
features = [feature]
initializer = None
fc_lr = self.config.lr / 0.001
for i in range(self.config.num_layers):
if i == self.config.num_layers - 1:
act = None
else:
act = "leaky_relu"
feature = self.gnn_layer(
graph_wrappers[i],
feature,
self.config.hidden_size,
act,
initializer,
learning_rate=fc_lr,
name="%s_%s" % (self.config.layer_type, i))
features.append(feature)
return features
def take_final_feature(self, feature, index, name):
"""take final feature"""
feat = L.gather(feature, index, overwrite=False)
ernie_config = self.config.ernie_config
ernie = ErnieGraphModel(
src_ids=feat,
config=ernie_config,
slot_seqlen=self.config.max_seqlen,
name="student_")
feat = ernie.get_pooled_output()
fc_lr = self.config.lr / 0.001
feat= L.fc(feat,
self.config.hidden_size,
act="relu",
param_attr=F.ParamAttr(name=name + "_l",
learning_rate=fc_lr),
)
feat = L.l2_normalize(feat, axis=1)
if self.config.final_fc:
feat = L.fc(feat,
self.config.hidden_size,
param_attr=F.ParamAttr(name=name + '_w'),
bias_attr=F.ParamAttr(name=name + '_b'))
if self.config.final_l2_norm:
feat = L.l2_normalize(feat, axis=1)
return feat
def __call__(self, graph_wrappers):
inputs = self.build_inputs()
feature = inputs[-1]
features = self.gnn_layers(graph_wrappers, feature)
outputs = [self.take_final_feature(features[-1], i, "final_fc") for i in inputs[:-1]]
src_real_index = L.gather(graph_wrappers[0].node_feat['index'], inputs[0])
outputs.append(src_real_index)
return inputs, outputs
class ErnieSageModelV3(BaseGNNModel):
def gen_net_fn(self, config):
return ErnieSageV3(config)
# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import numpy as np
import paddle
import paddle.fluid as fluid
import paddle.fluid.layers as L
def copy_send(src_feat, dst_feat, edge_feat):
"""doc"""
return src_feat["h"]
def weighted_copy_send(src_feat, dst_feat, edge_feat):
"""doc"""
return src_feat["h"] * edge_feat["weight"]
def mean_recv(feat):
"""doc"""
return fluid.layers.sequence_pool(feat, pool_type="average")
def sum_recv(feat):
"""doc"""
return fluid.layers.sequence_pool(feat, pool_type="sum")
def max_recv(feat):
"""doc"""
return fluid.layers.sequence_pool(feat, pool_type="max")
def lstm_recv(feat):
"""doc"""
hidden_dim = 128
forward, _ = fluid.layers.dynamic_lstm(
input=feat, size=hidden_dim * 4, use_peepholes=False)
output = fluid.layers.sequence_last_step(forward)
return output
def graphsage_sum(gw, feature, hidden_size, act, initializer, learning_rate, name):
"""doc"""
msg = gw.send(copy_send, nfeat_list=[("h", feature)])
neigh_feature = gw.recv(msg, sum_recv)
self_feature = feature
self_feature = fluid.layers.fc(self_feature,
hidden_size,
act=act,
param_attr=fluid.ParamAttr(name=name + "_l", initializer=initializer,
learning_rate=learning_rate),
)
neigh_feature = fluid.layers.fc(neigh_feature,
hidden_size,
act=act,
param_attr=fluid.ParamAttr(name=name + "_r", initializer=initializer,
learning_rate=learning_rate),
)
output = fluid.layers.concat([self_feature, neigh_feature], axis=1)
output = fluid.layers.l2_normalize(output, axis=1)
return output
def graphsage_mean(gw, feature, hidden_size, act, initializer, learning_rate, name):
"""doc"""
msg = gw.send(copy_send, nfeat_list=[("h", feature)])
neigh_feature = gw.recv(msg, mean_recv)
self_feature = feature
self_feature = fluid.layers.fc(self_feature,
hidden_size,
act=act,
param_attr=fluid.ParamAttr(name=name + "_l", initializer=initializer,
learning_rate=learning_rate),
)
neigh_feature = fluid.layers.fc(neigh_feature,
hidden_size,
act=act,
param_attr=fluid.ParamAttr(name=name + "_r", initializer=initializer,
learning_rate=learning_rate),
)
output = fluid.layers.concat([self_feature, neigh_feature], axis=1)
output = fluid.layers.l2_normalize(output, axis=1)
return output
def pinsage_mean(gw, feature, hidden_size, act, initializer, learning_rate, name):
"""doc"""
msg = gw.send(weighted_copy_send, nfeat_list=[("h", feature)], efeat_list=["weight"])
neigh_feature = gw.recv(msg, mean_recv)
self_feature = feature
self_feature = fluid.layers.fc(self_feature,
hidden_size,
act=act,
param_attr=fluid.ParamAttr(name=name + "_l", initializer=initializer,
learning_rate=learning_rate),
)
neigh_feature = fluid.layers.fc(neigh_feature,
hidden_size,
act=act,
param_attr=fluid.ParamAttr(name=name + "_r", initializer=initializer,
learning_rate=learning_rate),
)
output = fluid.layers.concat([self_feature, neigh_feature], axis=1)
output = fluid.layers.l2_normalize(output, axis=1)
return output
def pinsage_sum(gw, feature, hidden_size, act, initializer, learning_rate, name):
"""doc"""
msg = gw.send(weighted_copy_send, nfeat_list=[("h", feature)], efeat_list=["weight"])
neigh_feature = gw.recv(msg, sum_recv)
self_feature = feature
self_feature = fluid.layers.fc(self_feature,
hidden_size,
act=act,
param_attr=fluid.ParamAttr(name=name + "_l", initializer=initializer,
learning_rate=learning_rate),
)
neigh_feature = fluid.layers.fc(neigh_feature,
hidden_size,
act=act,
param_attr=fluid.ParamAttr(name=name + "_r", initializer=initializer,
learning_rate=learning_rate),
)
output = fluid.layers.concat([self_feature, neigh_feature], axis=1)
output = fluid.layers.l2_normalize(output, axis=1)
return output
from models.base import BaseGNNModel
from models.ernie import ErnieModel
from models.erniesage_v1 import ErnieSageModelV1
from models.erniesage_v2 import ErnieSageModelV2
from models.erniesage_v3 import ErnieSageModelV3
class Model(object):
@classmethod
def factory(cls, config):
name = config.model_type
if name == "BaseGNNModel":
return BaseGNNModel(config)
if name == "ErnieModel":
return ErnieModel(config)
if name == "ErnieSageModelV1":
return ErnieSageModelV1(config)
if name == "ErnieSageModelV2":
return ErnieSageModelV2(config)
if name == "ErnieSageModelV3":
return ErnieSageModelV3(config)
else:
raise ValueError
#!/usr/bin/env python
# -*- coding: utf-8 -*-
########################################################################
#
# Copyright (c) 2020 Baidu.com, Inc. All Rights Reserved
#
# File: dump_graph.py
# Author: suweiyue(suweiyue@baidu.com)
# Date: 2020/03/01 22:17:13
#
########################################################################
"""
Comment.
"""
from __future__ import division
from __future__ import absolute_import
from __future__ import print_function
#from __future__ import unicode_literals
import io
import os
import sys
import argparse
import logging
import multiprocessing
from functools import partial
from io import open
import numpy as np
import tqdm
import pgl
from pgl.graph_kernel import alias_sample_build_table
from pgl.utils.logger import log
from tokenization import FullTokenizer
def term2id(string, tokenizer, max_seqlen):
string = string.split("\t")[1]
tokens = tokenizer.tokenize(string)
ids = tokenizer.convert_tokens_to_ids(tokens)
ids = ids[:max_seqlen-1]
ids = ids + [2] # ids + [sep]
ids = ids + [0] * (max_seqlen - len(ids))
return ids
def dump_graph(args):
if not os.path.exists(args.outpath):
os.makedirs(args.outpath)
neg_samples = []
str2id = dict()
term_file = io.open(os.path.join(args.outpath, "terms.txt"), "w", encoding=args.encoding)
terms = []
count = 0
with io.open(args.inpath, encoding=args.encoding) as f:
edges = []
for idx, line in enumerate(f):
if idx % 100000 == 0:
log.info("%s readed %s lines" % (args.inpath, idx))
slots = []
for col_idx, col in enumerate(line.strip("\n").split("\t")):
s = col[:args.max_seqlen]
if s not in str2id:
str2id[s] = count
count += 1
term_file.write(str(col_idx) + "\t" + col + "\n")
slots.append(str2id[s])
src = slots[0]
dst = slots[1]
neg_samples.append(slots[2:])
edges.append((src, dst))
edges.append((dst, src))
term_file.close()
edges = np.array(edges, dtype="int64")
num_nodes = len(str2id)
str2id.clear()
log.info("building graph...")
graph = pgl.graph.Graph(num_nodes=num_nodes, edges=edges)
indegree = graph.indegree()
graph.outdegree()
graph.dump(args.outpath)
# dump alias sample table
sqrt_indegree = np.sqrt(indegree)
distribution = 1. * sqrt_indegree / sqrt_indegree.sum()
alias, events = alias_sample_build_table(distribution)
np.save(os.path.join(args.outpath, "alias.npy"), alias)
np.save(os.path.join(args.outpath, "events.npy"), events)
np.save(os.path.join(args.outpath, "neg_samples.npy"), np.array(neg_samples))
log.info("End Build Graph")
def dump_id2str_map(args):
log.info("Dump id2str map starting...")
id2str = np.array([line.strip("\n") for line in open(os.path.join(args.outpath, "terms.txt"), "r", encoding=args.encoding)])
np.save(os.path.join(args.outpath, "id2str.npy"), id2str)
log.info("Dump id2str map done.")
def dump_node_feat(args):
log.info("Dump node feat starting...")
id2str = np.load(os.path.join(args.outpath, "id2str.npy"), mmap_mode="r")
pool = multiprocessing.Pool()
tokenizer = FullTokenizer(args.vocab_file)
term_ids = pool.map(partial(term2id, tokenizer=tokenizer, max_seqlen=args.max_seqlen), id2str)
np.save(os.path.join(args.outpath, "term_ids.npy"), np.array(term_ids))
log.info("Dump node feat done.")
pool.terminate()
if __name__ == "__main__":
parser = argparse.ArgumentParser(description='main')
parser.add_argument("-i", "--inpath", type=str, default=None)
parser.add_argument("-l", "--max_seqlen", type=int, default=30)
parser.add_argument("--vocab_file", type=str, default="./vocab.txt")
parser.add_argument("--encoding", type=str, default="utf8")
parser.add_argument("-o", "--outpath", type=str, default=None)
args = parser.parse_args()
dump_graph(args)
dump_id2str_map(args)
dump_node_feat(args)
# coding=utf-8
# Copyright 2018 The Google AI Language Team Authors.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""Tokenization classes."""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import collections
import unicodedata
import six
import sentencepiece as sp
def convert_to_unicode(text):
"""Converts `text` to Unicode (if it's not already), assuming utf-8 input."""
if six.PY3:
if isinstance(text, str):
return text
elif isinstance(text, bytes):
return text.decode("utf-8", "ignore")
else:
raise ValueError("Unsupported string type: %s" % (type(text)))
elif six.PY2:
if isinstance(text, str):
return text.decode("utf-8", "ignore")
elif isinstance(text, unicode):
return text
else:
raise ValueError("Unsupported string type: %s" % (type(text)))
else:
raise ValueError("Not running on Python2 or Python 3?")
def printable_text(text):
"""Returns text encoded in a way suitable for print or `tf.logging`."""
# These functions want `str` for both Python2 and Python3, but in one case
# it's a Unicode string and in the other it's a byte string.
if six.PY3:
if isinstance(text, str):
return text
elif isinstance(text, bytes):
return text.decode("utf-8", "ignore")
else:
raise ValueError("Unsupported string type: %s" % (type(text)))
elif six.PY2:
if isinstance(text, str):
return text
elif isinstance(text, unicode):
return text.encode("utf-8")
else:
raise ValueError("Unsupported string type: %s" % (type(text)))
else:
raise ValueError("Not running on Python2 or Python 3?")
def load_vocab(vocab_file):
"""Loads a vocabulary file into a dictionary."""
vocab = collections.OrderedDict()
fin = open(vocab_file, 'rb')
for num, line in enumerate(fin):
items = convert_to_unicode(line.strip()).split("\t")
if len(items) > 2:
break
token = items[0]
index = items[1] if len(items) == 2 else num
token = token.strip()
vocab[token] = int(index)
return vocab
def convert_by_vocab(vocab, items):
"""Converts a sequence of [tokens|ids] using the vocab."""
output = []
for item in items:
output.append(vocab[item])
return output
def convert_tokens_to_ids_include_unk(vocab, tokens, unk_token="[UNK]"):
output = []
for token in tokens:
if token in vocab:
output.append(vocab[token])
else:
output.append(vocab[unk_token])
return output
def convert_tokens_to_ids(vocab, tokens):
return convert_by_vocab(vocab, tokens)
def convert_ids_to_tokens(inv_vocab, ids):
return convert_by_vocab(inv_vocab, ids)
def whitespace_tokenize(text):
"""Runs basic whitespace cleaning and splitting on a peice of text."""
text = text.strip()
if not text:
return []
tokens = text.split()
return tokens
class FullTokenizer(object):
"""Runs end-to-end tokenziation."""
def __init__(self, vocab_file, do_lower_case=True):
self.vocab = load_vocab(vocab_file)
self.inv_vocab = {v: k for k, v in self.vocab.items()}
self.basic_tokenizer = BasicTokenizer(do_lower_case=do_lower_case)
self.wordpiece_tokenizer = WordpieceTokenizer(vocab=self.vocab)
def tokenize(self, text):
split_tokens = []
for token in self.basic_tokenizer.tokenize(text):
for sub_token in self.wordpiece_tokenizer.tokenize(token):
split_tokens.append(sub_token)
return split_tokens
def convert_tokens_to_ids(self, tokens):
return convert_by_vocab(self.vocab, tokens)
def convert_ids_to_tokens(self, ids):
return convert_by_vocab(self.inv_vocab, ids)
class CharTokenizer(object):
"""Runs end-to-end tokenziation."""
def __init__(self, vocab_file, do_lower_case=True):
self.vocab = load_vocab(vocab_file)
self.inv_vocab = {v: k for k, v in self.vocab.items()}
self.tokenizer = WordpieceTokenizer(vocab=self.vocab)
def tokenize(self, text):
split_tokens = []
for token in text.lower().split(" "):
for sub_token in self.tokenizer.tokenize(token):
split_tokens.append(sub_token)
return split_tokens
def convert_tokens_to_ids(self, tokens):
return convert_by_vocab(self.vocab, tokens)
def convert_ids_to_tokens(self, ids):
return convert_by_vocab(self.inv_vocab, ids)
class BasicTokenizer(object):
"""Runs basic tokenization (punctuation splitting, lower casing, etc.)."""
def __init__(self, do_lower_case=True):
"""Constructs a BasicTokenizer.
Args:
do_lower_case: Whether to lower case the input.
"""
self.do_lower_case = do_lower_case
def tokenize(self, text):
"""Tokenizes a piece of text."""
text = convert_to_unicode(text)
text = self._clean_text(text)
# This was added on November 1st, 2018 for the multilingual and Chinese
# models. This is also applied to the English models now, but it doesn't
# matter since the English models were not trained on any Chinese data
# and generally don't have any Chinese data in them (there are Chinese
# characters in the vocabulary because Wikipedia does have some Chinese
# words in the English Wikipedia.).
text = self._tokenize_chinese_chars(text)
orig_tokens = whitespace_tokenize(text)
split_tokens = []
for token in orig_tokens:
if self.do_lower_case:
token = token.lower()
token = self._run_strip_accents(token)
split_tokens.extend(self._run_split_on_punc(token))
output_tokens = whitespace_tokenize(" ".join(split_tokens))
return output_tokens
def _run_strip_accents(self, text):
"""Strips accents from a piece of text."""
text = unicodedata.normalize("NFD", text)
output = []
for char in text:
cat = unicodedata.category(char)
if cat == "Mn":
continue
output.append(char)
return "".join(output)
def _run_split_on_punc(self, text):
"""Splits punctuation on a piece of text."""
chars = list(text)
i = 0
start_new_word = True
output = []
while i < len(chars):
char = chars[i]
if _is_punctuation(char):
output.append([char])
start_new_word = True
else:
if start_new_word:
output.append([])
start_new_word = False
output[-1].append(char)
i += 1
return ["".join(x) for x in output]
def _tokenize_chinese_chars(self, text):
"""Adds whitespace around any CJK character."""
output = []
for char in text:
cp = ord(char)
if self._is_chinese_char(cp):
output.append(" ")
output.append(char)
output.append(" ")
else:
output.append(char)
return "".join(output)
def _is_chinese_char(self, cp):
"""Checks whether CP is the codepoint of a CJK character."""
# This defines a "chinese character" as anything in the CJK Unicode block:
# https://en.wikipedia.org/wiki/CJK_Unified_Ideographs_(Unicode_block)
#
# Note that the CJK Unicode block is NOT all Japanese and Korean characters,
# despite its name. The modern Korean Hangul alphabet is a different block,
# as is Japanese Hiragana and Katakana. Those alphabets are used to write
# space-separated words, so they are not treated specially and handled
# like the all of the other languages.
if ((cp >= 0x4E00 and cp <= 0x9FFF) or #
(cp >= 0x3400 and cp <= 0x4DBF) or #
(cp >= 0x20000 and cp <= 0x2A6DF) or #
(cp >= 0x2A700 and cp <= 0x2B73F) or #
(cp >= 0x2B740 and cp <= 0x2B81F) or #
(cp >= 0x2B820 and cp <= 0x2CEAF) or
(cp >= 0xF900 and cp <= 0xFAFF) or #
(cp >= 0x2F800 and cp <= 0x2FA1F)): #
return True
return False
def _clean_text(self, text):
"""Performs invalid character removal and whitespace cleanup on text."""
output = []
for char in text:
cp = ord(char)
if cp == 0 or cp == 0xfffd or _is_control(char):
continue
if _is_whitespace(char):
output.append(" ")
else:
output.append(char)
return "".join(output)
class SentencepieceTokenizer(object):
"""Runs SentencePiece tokenziation."""
def __init__(self, vocab_file, do_lower_case=True, unk_token="[UNK]"):
self.vocab = load_vocab(vocab_file)
self.inv_vocab = {v: k for k, v in self.vocab.items()}
self.do_lower_case = do_lower_case
self.tokenizer = sp.SentencePieceProcessor()
self.tokenizer.Load(vocab_file + ".model")
self.sp_unk_token = "<unk>"
self.unk_token = unk_token
def tokenize(self, text):
"""Tokenizes a piece of text into its word pieces.
Returns:
A list of wordpiece tokens.
"""
text = text.lower() if self.do_lower_case else text
text = convert_to_unicode(text.replace("\1", " "))
tokens = self.tokenizer.EncodeAsPieces(text)
output_tokens = []
for token in tokens:
if token == self.sp_unk_token:
token = self.unk_token
if token in self.vocab:
output_tokens.append(token)
else:
output_tokens.append(self.unk_token)
return output_tokens
def convert_tokens_to_ids(self, tokens):
return convert_by_vocab(self.vocab, tokens)
def convert_ids_to_tokens(self, ids):
return convert_by_vocab(self.inv_vocab, ids)
class WordsegTokenizer(object):
"""Runs Wordseg tokenziation."""
def __init__(self, vocab_file, do_lower_case=True, unk_token="[UNK]",
split_token="\1"):
self.vocab = load_vocab(vocab_file)
self.inv_vocab = {v: k for k, v in self.vocab.items()}
self.tokenizer = sp.SentencePieceProcessor()
self.tokenizer.Load(vocab_file + ".model")
self.do_lower_case = do_lower_case
self.unk_token = unk_token
self.split_token = split_token
def tokenize(self, text):
"""Tokenizes a piece of text into its word pieces.
Returns:
A list of wordpiece tokens.
"""
text = text.lower() if self.do_lower_case else text
text = convert_to_unicode(text)
output_tokens = []
for token in text.split(self.split_token):
if token in self.vocab:
output_tokens.append(token)
else:
sp_tokens = self.tokenizer.EncodeAsPieces(token)
for sp_token in sp_tokens:
if sp_token in self.vocab:
output_tokens.append(sp_token)
return output_tokens
def convert_tokens_to_ids(self, tokens):
return convert_by_vocab(self.vocab, tokens)
def convert_ids_to_tokens(self, ids):
return convert_by_vocab(self.inv_vocab, ids)
class WordpieceTokenizer(object):
"""Runs WordPiece tokenziation."""
def __init__(self, vocab, unk_token="[UNK]", max_input_chars_per_word=100):
self.vocab = vocab
self.unk_token = unk_token
self.max_input_chars_per_word = max_input_chars_per_word
def tokenize(self, text):
"""Tokenizes a piece of text into its word pieces.
This uses a greedy longest-match-first algorithm to perform tokenization
using the given vocabulary.
For example:
input = "unaffable"
output = ["un", "##aff", "##able"]
Args:
text: A single token or whitespace separated tokens. This should have
already been passed through `BasicTokenizer.
Returns:
A list of wordpiece tokens.
"""
text = convert_to_unicode(text)
output_tokens = []
for token in whitespace_tokenize(text):
chars = list(token)
if len(chars) > self.max_input_chars_per_word:
output_tokens.append(self.unk_token)
continue
is_bad = False
start = 0
sub_tokens = []
while start < len(chars):
end = len(chars)
cur_substr = None
while start < end:
substr = "".join(chars[start:end])
if start > 0:
substr = "##" + substr
if substr in self.vocab:
cur_substr = substr
break
end -= 1
if cur_substr is None:
is_bad = True
break
sub_tokens.append(cur_substr)
start = end
if is_bad:
output_tokens.append(self.unk_token)
else:
output_tokens.extend(sub_tokens)
return output_tokens
def _is_whitespace(char):
"""Checks whether `chars` is a whitespace character."""
# \t, \n, and \r are technically contorl characters but we treat them
# as whitespace since they are generally considered as such.
if char == " " or char == "\t" or char == "\n" or char == "\r":
return True
cat = unicodedata.category(char)
if cat == "Zs":
return True
return False
def _is_control(char):
"""Checks whether `chars` is a control character."""
# These are technically control characters but we count them as whitespace
# characters.
if char == "\t" or char == "\n" or char == "\r":
return False
cat = unicodedata.category(char)
if cat.startswith("C"):
return True
return False
def _is_punctuation(char):
"""Checks whether `chars` is a punctuation character."""
cp = ord(char)
# We treat all non-letter/number ASCII as punctuation.
# Characters such as "^", "$", and "`" are not in the Unicode
# Punctuation class but we treat them as punctuation anyways, for
# consistency.
if ((cp >= 33 and cp <= 47) or (cp >= 58 and cp <= 64) or
(cp >= 91 and cp <= 96) or (cp >= 123 and cp <= 126)):
return True
cat = unicodedata.category(char)
if cat.startswith("P"):
return True
return False
# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import os
import argparse
import traceback
import yaml
import numpy as np
from easydict import EasyDict as edict
from pgl.utils.logger import log
from pgl.utils import paddle_helper
from learner import Learner
from models.model_factory import Model
from dataset.graph_reader import GraphGenerator
class TrainData(object):
def __init__(self, graph_path):
trainer_id = int(os.getenv("PADDLE_TRAINER_ID", "0"))
trainer_count = int(os.getenv("PADDLE_TRAINERS_NUM", "1"))
log.info("trainer_id: %s, trainer_count: %s." % (trainer_id, trainer_count))
edges = np.load(os.path.join(graph_path, "edges.npy"), allow_pickle=True)
# edges is bidirectional.
train_usr = edges[trainer_id::trainer_count, 0]
train_ad = edges[trainer_id::trainer_count, 1]
returns = {
"train_data": [train_usr, train_ad]
}
if os.path.exists(os.path.join(graph_path, "neg_samples.npy")):
neg_samples = np.load(os.path.join(graph_path, "neg_samples.npy"), allow_pickle=True)
if neg_samples.size != 0:
train_negs = neg_samples[trainer_id::trainer_count]
returns["train_data"].append(train_negs)
log.info("Load train_data done.")
self.data = returns
def __getitem__(self, index):
return [ data[index] for data in self.data["train_data"]]
def __len__(self):
return len(self.data["train_data"][0])
def main(config):
# Select Model
model = Model.factory(config)
# Build Train Edges
data = TrainData(config.graph_path)
# Build Train Data
train_iter = GraphGenerator(
graph_wrappers=model.graph_wrappers,
batch_size=config.batch_size,
data=data,
samples=config.samples,
num_workers=config.sample_workers,
feed_name_list=[var.name for var in model.feed_list],
use_pyreader=config.use_pyreader,
phase="train",
graph_data_path=config.graph_path,
shuffle=True)
log.info("build graph reader done.")
learner = Learner.factory(config.learner_type)
learner.build(model, train_iter, config)
learner.start()
learner.stop()
if __name__ == "__main__":
parser = argparse.ArgumentParser(description='main')
parser.add_argument("--conf", type=str, default="./config.yaml")
args = parser.parse_args()
config = edict(yaml.load(open(args.conf), Loader=yaml.FullLoader))
print(config)
main(config)
...@@ -44,7 +44,6 @@ def main(args): ...@@ -44,7 +44,6 @@ def main(args):
with fluid.program_guard(train_program, startup_program): with fluid.program_guard(train_program, startup_program):
gw = pgl.graph_wrapper.GraphWrapper( gw = pgl.graph_wrapper.GraphWrapper(
name="graph", name="graph",
place=place,
node_feat=dataset.graph.node_feat_info()) node_feat=dataset.graph.node_feat_info())
output = pgl.layers.gat(gw, output = pgl.layers.gat(gw,
......
...@@ -4,18 +4,19 @@ ...@@ -4,18 +4,19 @@
### Datasets ### Datasets
The dataset can be downloaded from [here](https://github.com/weihua916/powerful-gnns/blob/master/dataset.zip) The dataset can be downloaded from [here](https://github.com/weihua916/powerful-gnns/blob/master/dataset.zip).
After downloading the data,uncompress them, then a directory named `./dataset/` can be found in current directory. Note that the current directory is the root directory of GIN model.
### Dependencies ### Dependencies
- paddlepaddle 1.6 - paddlepaddle >= 1.6
- pgl 1.0.2 - pgl 1.0.2
### How to run ### How to run
For examples, use GPU to train GIN model on MUTAG dataset. For examples, use GPU to train GIN model on MUTAG dataset.
``` ```
python main.py --use_cuda --dataset_name MUTAG python main.py --use_cuda --dataset_name MUTAG --data_path ./dataset
``` ```
### Hyperparameters ### Hyperparameters
......
...@@ -50,7 +50,16 @@ class GINModel(object): ...@@ -50,7 +50,16 @@ class GINModel(object):
init_eps=0.0, init_eps=0.0,
train_eps=self.train_eps) train_eps=self.train_eps)
h = fl.batch_norm(h) h = fl.layer_norm(
h,
begin_norm_axis=1,
param_attr=fluid.ParamAttr(
name="norm_scale_%s" % (i),
initializer=fluid.initializer.Constant(1.0)),
bias_attr=fluid.ParamAttr(
name="norm_bias_%s" % (i),
initializer=fluid.initializer.Constant(0.0)), )
h = fl.relu(h) h = fl.relu(h)
features_list.append(h) features_list.append(h)
......
...@@ -204,8 +204,8 @@ def main(args): ...@@ -204,8 +204,8 @@ def main(args):
graph_wrapper = pgl.graph_wrapper.GraphWrapper( graph_wrapper = pgl.graph_wrapper.GraphWrapper(
"sub_graph", "sub_graph",
fluid.CPUPlace(),
node_feat=data['graph'].node_feat_info()) node_feat=data['graph'].node_feat_info())
model_loss, model_acc = build_graph_model( model_loss, model_acc = build_graph_model(
graph_wrapper, graph_wrapper,
num_class=data["num_class"], num_class=data["num_class"],
......
...@@ -231,7 +231,6 @@ def main(args): ...@@ -231,7 +231,6 @@ def main(args):
with fluid.program_guard(train_program, startup_program): with fluid.program_guard(train_program, startup_program):
graph_wrapper = pgl.graph_wrapper.GraphWrapper( graph_wrapper = pgl.graph_wrapper.GraphWrapper(
"sub_graph", "sub_graph",
fluid.CPUPlace(),
node_feat=data['graph'].node_feat_info()) node_feat=data['graph'].node_feat_info())
model_loss, model_acc = build_graph_model( model_loss, model_acc = build_graph_model(
......
...@@ -227,7 +227,6 @@ def main(args): ...@@ -227,7 +227,6 @@ def main(args):
with fluid.program_guard(train_program, startup_program): with fluid.program_guard(train_program, startup_program):
graph_wrapper = pgl.graph_wrapper.GraphWrapper( graph_wrapper = pgl.graph_wrapper.GraphWrapper(
"sub_graph", "sub_graph",
fluid.CPUPlace(),
node_feat=data['graph'].node_feat_info()) node_feat=data['graph'].node_feat_info())
model_loss, model_acc = build_graph_model( model_loss, model_acc = build_graph_model(
......
...@@ -49,7 +49,6 @@ def main(args): ...@@ -49,7 +49,6 @@ def main(args):
with fluid.program_guard(train_program, startup_program): with fluid.program_guard(train_program, startup_program):
gw = pgl.graph_wrapper.GraphWrapper( gw = pgl.graph_wrapper.GraphWrapper(
"gw", "gw",
place,
node_feat=[('norm', [None, 1], "float32")], node_feat=[('norm', [None, 1], "float32")],
edge_feat=[('weights', [None, 1], "float32")]) edge_feat=[('weights', [None, 1], "float32")])
......
...@@ -88,7 +88,7 @@ def build_graph_model(args): ...@@ -88,7 +88,7 @@ def build_graph_model(args):
graph_wrappers.append( graph_wrappers.append(
pgl.graph_wrapper.GraphWrapper( pgl.graph_wrapper.GraphWrapper(
"layer_0", fluid.CPUPlace(), node_feat=node_feature_info)) "layer_0", node_feat=node_feature_info))
#edge_feat=[("f", [None, 1], "float32")])) #edge_feat=[("f", [None, 1], "float32")]))
num_embed = args.num_nodes num_embed = args.num_nodes
......
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""test ogb
"""
import argparse
import pgl
import numpy as np
import paddle.fluid as fluid
from pgl.contrib.ogb.graphproppred.dataset_pgl import PglGraphPropPredDataset
from pgl.utils import paddle_helper
from ogb.graphproppred import Evaluator
from pgl.contrib.ogb.graphproppred.mol_encoder import AtomEncoder, BondEncoder
def train(exe, batch_size, graph_wrapper, train_program, splitted_idx, dataset,
evaluator, fetch_loss, fetch_pred):
"""Train"""
graphs, labels = dataset[splitted_idx["train"]]
perm = np.arange(0, len(graphs))
np.random.shuffle(perm)
start_batch = 0
batch_no = 0
pred_output = np.zeros_like(labels, dtype="float32")
while start_batch < len(perm):
batch_index = perm[start_batch:start_batch + batch_size]
start_batch += batch_size
batch_graph = pgl.graph.MultiGraph(graphs[batch_index])
batch_label = labels[batch_index]
batch_valid = (batch_label == batch_label).astype("float32")
batch_label = np.nan_to_num(batch_label).astype("float32")
feed_dict = graph_wrapper.to_feed(batch_graph)
feed_dict["label"] = batch_label
feed_dict["weight"] = batch_valid
loss, pred = exe.run(train_program,
feed=feed_dict,
fetch_list=[fetch_loss, fetch_pred])
pred_output[batch_index] = pred
batch_no += 1
print("train", evaluator.eval({"y_true": labels, "y_pred": pred_output}))
def evaluate(exe, batch_size, graph_wrapper, val_program, splitted_idx,
dataset, mode, evaluator, fetch_pred):
"""Eval"""
graphs, labels = dataset[splitted_idx[mode]]
perm = np.arange(0, len(graphs))
start_batch = 0
batch_no = 0
pred_output = np.zeros_like(labels, dtype="float32")
while start_batch < len(perm):
batch_index = perm[start_batch:start_batch + batch_size]
start_batch += batch_size
batch_graph = pgl.graph.MultiGraph(graphs[batch_index])
feed_dict = graph_wrapper.to_feed(batch_graph)
pred = exe.run(val_program, feed=feed_dict, fetch_list=[fetch_pred])
pred_output[batch_index] = pred[0]
batch_no += 1
print(mode, evaluator.eval({"y_true": labels, "y_pred": pred_output}))
def send_func(src_feat, dst_feat, edge_feat):
"""Send"""
return src_feat["h"] + edge_feat["h"]
class GNNModel(object):
"""GNNModel"""
def __init__(self, name, emb_dim, num_task, num_layers):
self.num_task = num_task
self.emb_dim = emb_dim
self.num_layers = num_layers
self.name = name
self.atom_encoder = AtomEncoder(name=name, emb_dim=emb_dim)
self.bond_encoder = BondEncoder(name=name, emb_dim=emb_dim)
def forward(self, graph):
"""foward"""
h_node = self.atom_encoder(graph.node_feat['feat'])
h_edge = self.bond_encoder(graph.edge_feat['feat'])
for layer in range(self.num_layers):
msg = graph.send(
send_func,
nfeat_list=[("h", h_node)],
efeat_list=[("h", h_edge)])
h_node = graph.recv(msg, 'sum') + h_node
h_node = fluid.layers.fc(h_node,
size=self.emb_dim,
name=self.name + '_%s' % layer,
act="relu")
graph_nodes = pgl.layers.graph_pooling(graph, h_node, "average")
graph_pred = fluid.layers.fc(graph_nodes, self.num_task, name="final")
return graph_pred
def main():
"""main
"""
# Training settings
parser = argparse.ArgumentParser(description='Graph Dataset')
parser.add_argument(
'--epochs',
type=int,
default=100,
help='number of epochs to train (default: 100)')
parser.add_argument(
'--dataset',
type=str,
default="ogbg-mol-tox21",
help='dataset name (default: proteinfunc)')
args = parser.parse_args()
place = fluid.CPUPlace() # Dataset too big to use GPU
### automatic dataloading and splitting
dataset = PglGraphPropPredDataset(name=args.dataset)
splitted_idx = dataset.get_idx_split()
### automatic evaluator. takes dataset name as input
evaluator = Evaluator(args.dataset)
graph_data, label = dataset[:2]
batch_graph = pgl.graph.MultiGraph(graph_data)
graph_data = batch_graph
train_program = fluid.Program()
startup_program = fluid.Program()
test_program = fluid.Program()
# degree normalize
graph_data.edge_feat["feat"] = graph_data.edge_feat["feat"].astype("int64")
graph_data.node_feat["feat"] = graph_data.node_feat["feat"].astype("int64")
model = GNNModel(
name="gnn", num_task=dataset.num_tasks, emb_dim=64, num_layers=2)
with fluid.program_guard(train_program, startup_program):
gw = pgl.graph_wrapper.GraphWrapper(
"graph",
place=place,
node_feat=graph_data.node_feat_info(),
edge_feat=graph_data.edge_feat_info())
pred = model.forward(gw)
sigmoid_pred = fluid.layers.sigmoid(pred)
val_program = train_program.clone(for_test=True)
initializer = []
with fluid.program_guard(train_program, startup_program):
train_label = fluid.layers.data(
name="label", dtype="float32", shape=[None, dataset.num_tasks])
train_weight = fluid.layers.data(
name="weight", dtype="float32", shape=[None, dataset.num_tasks])
train_loss_t = fluid.layers.sigmoid_cross_entropy_with_logits(
x=pred, label=train_label) * train_weight
train_loss_t = fluid.layers.reduce_sum(train_loss_t)
adam = fluid.optimizer.Adam(
learning_rate=1e-2,
regularization=fluid.regularizer.L2DecayRegularizer(
regularization_coeff=0.0005))
adam.minimize(train_loss_t)
exe = fluid.Executor(place)
exe.run(startup_program)
for epoch in range(1, args.epochs + 1):
print("Epoch", epoch)
train(exe, 128, gw, train_program, splitted_idx, dataset, evaluator,
train_loss_t, sigmoid_pred)
evaluate(exe, 128, gw, val_program, splitted_idx, dataset, "valid",
evaluator, sigmoid_pred)
evaluate(exe, 128, gw, val_program, splitted_idx, dataset, "test",
evaluator, sigmoid_pred)
if __name__ == "__main__":
main()
# Graph Property Prediction for Open Graph Benchmark (OGB)
[The Open Graph Benchmark (OGB)](https://ogb.stanford.edu/) is a collection of benchmark datasets, data loaders, and evaluators for graph machine learning. Here we complete the Graph Property Prediction task based on PGL.
### Requirements
- paddlpaddle >= 1.7.1
- pgl 1.0.2
- ogb
NOTE: To install ogb that is fited for this project, run below command to install ogb
```
git clone https://github.com/snap-stanford/ogb.git
git checkout 482c40bc9f31fe25f9df5aa11c8fb657bd2b1621
python setup.py install
```
### How to run
For example, use GPU to train model on ogbg-molhiv dataset and ogb-molpcba dataset.
```
CUDA_VISIBLE_DEVICES=1 python -u main.py --config hiv_config.yaml --use_cuda
CUDA_VISIBLE_DEVICES=2 python -u main.py --config pcba_config.yaml --use_cuda
```
If you want to use CPU to train model, environment variables `CPU_NUM` should be specified and should be in the range of 1 to N, where N is the total CPU number on your machine.
```
CPU_NUM=1 python -u main.py --config hiv_config.yaml
CPU_NUM=1 python -u main.py --config pcba_config.yaml
```
### Experiment results
| model | hiv (rocauc)| pcba (prcauc)|
|-------|-------------|--------------|
| GIN |0.7719 (0.0079) | 0.2232 (0.0018) |
# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
from __future__ import unicode_literals
from __future__ import absolute_import
import os
import time
import argparse
from utils.args import ArgumentGroup
# yapf: disable
parser = argparse.ArgumentParser(__doc__)
parser.add_argument('--use_cuda', action='store_true')
model_g = ArgumentGroup(parser, "model", "model configuration and paths.")
model_g.add_arg("init_checkpoint", str, None, "Init checkpoint to resume training from.")
model_g.add_arg("init_pretraining_params", str, None,
"Init pre-training params which preforms fine-tuning from. If the "
"arg 'init_checkpoint' has been set, this argument wouldn't be valid.")
model_g.add_arg("./save_dir", str, "./checkpoints", "Path to save checkpoints.")
model_g.add_arg("hidden_size", int, 128, "hidden size.")
train_g = ArgumentGroup(parser, "training", "training options.")
train_g.add_arg("epoch", int, 3, "Number of epoches for fine-tuning.")
train_g.add_arg("learning_rate", float, 5e-5, "Learning rate used to train with warmup.")
train_g.add_arg("lr_scheduler", str, "linear_warmup_decay",
"scheduler of learning rate.", choices=['linear_warmup_decay', 'noam_decay'])
train_g.add_arg("weight_decay", float, 0.01, "Weight decay rate for L2 regularizer.")
train_g.add_arg("warmup_proportion", float, 0.1,
"Proportion of training steps to perform linear learning rate warmup for.")
train_g.add_arg("save_steps", int, 10000, "The steps interval to save checkpoints.")
train_g.add_arg("validation_steps", int, 1000, "The steps interval to evaluate model performance.")
train_g.add_arg("use_dynamic_loss_scaling", bool, True, "Whether to use dynamic loss scaling.")
train_g.add_arg("init_loss_scaling", float, 102400,
"Loss scaling factor for mixed precision training, only valid when use_fp16 is enabled.")
train_g.add_arg("test_save", str, "./checkpoints/test_result", "test_save")
train_g.add_arg("metric", str, "simple_accuracy", "metric")
train_g.add_arg("incr_every_n_steps", int, 100, "Increases loss scaling every n consecutive.")
train_g.add_arg("decr_every_n_nan_or_inf", int, 2,
"Decreases loss scaling every n accumulated steps with nan or inf gradients.")
train_g.add_arg("incr_ratio", float, 2.0,
"The multiplier to use when increasing the loss scaling.")
train_g.add_arg("decr_ratio", float, 0.8,
"The less-than-one-multiplier to use when decreasing.")
log_g = ArgumentGroup(parser, "logging", "logging related.")
log_g.add_arg("skip_steps", int, 10, "The steps interval to print loss.")
log_g.add_arg("verbose", bool, False, "Whether to output verbose log.")
log_g.add_arg("log_dir", str, './logs/', "Whether to output verbose log.")
data_g = ArgumentGroup(parser, "data", "Data paths, vocab paths and data processing options")
data_g.add_arg("tokenizer", str, "FullTokenizer",
"ATTENTION: the INPUT must be splited by Word with blank while using SentencepieceTokenizer or WordsegTokenizer")
data_g.add_arg("train_set", str, None, "Path to training data.")
data_g.add_arg("test_set", str, None, "Path to test data.")
data_g.add_arg("dev_set", str, None, "Path to validation data.")
data_g.add_arg("aug1_type", str, "scheme1", "augment type")
data_g.add_arg("aug2_type", str, "scheme1", "augment type")
data_g.add_arg("batch_size", int, 32, "Total examples' number in batch for training. see also --in_tokens.")
data_g.add_arg("predict_batch_size", int, None, "Total examples' number in batch for predict. see also --in_tokens.")
data_g.add_arg("random_seed", int, None, "Random seed.")
data_g.add_arg("buf_size", int, 1000, "Random seed.")
run_type_g = ArgumentGroup(parser, "run_type", "running type options.")
run_type_g.add_arg("num_iteration_per_drop_scope", int, 10, "Iteration intervals to drop scope.")
run_type_g.add_arg("do_train", bool, True, "Whether to perform training.")
run_type_g.add_arg("do_val", bool, True, "Whether to perform evaluation on dev data set.")
run_type_g.add_arg("do_test", bool, True, "Whether to perform evaluation on test data set.")
run_type_g.add_arg("metrics", bool, True, "Whether to perform evaluation on test data set.")
run_type_g.add_arg("shuffle", bool, True, "")
run_type_g.add_arg("for_cn", bool, True, "model train for cn or for other langs.")
run_type_g.add_arg("num_workers", int, 1, "use multiprocess to generate graph")
run_type_g.add_arg("output_dir", str, None, "path to save model")
run_type_g.add_arg("config", str, None, "configure yaml file")
run_type_g.add_arg("n", str, None, "task name")
run_type_g.add_arg("task_name", str, None, "task name")
run_type_g.add_arg("pretrain", bool, False, "Whether do pretrian")
run_type_g.add_arg("pretrain_name", str, None, "pretrain task name")
run_type_g.add_arg("pretrain_config", str, None, "pretrain config.yaml file")
run_type_g.add_arg("pretrain_model_step", str, None, "pretrain model step")
run_type_g.add_arg("model_type", str, "BaseLineModel", "pretrain model step")
run_type_g.add_arg("num_class", int, 1, "number class")
run_type_g.add_arg("dataset_name", str, None, "finetune dataset name")
run_type_g.add_arg("eval_metrics", str, None, "evaluate metrics")
run_type_g.add_arg("task_type", str, None, "regression or classification")
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import sys
import os
from ogb.graphproppred import GraphPropPredDataset
import pgl
from pgl.utils.logger import log
class BaseDataset(object):
def __init__(self):
pass
def __getitem__(self, idx):
raise NotImplementedError
def __len__(self):
raise NotImplementedError
class Subset(BaseDataset):
r"""
Subset of a dataset at specified indices.
Arguments:
dataset (Dataset): The whole Dataset
indices (sequence): Indices in the whole set selected for subset
"""
def __init__(self, dataset, indices):
self.dataset = dataset
self.indices = indices
def __getitem__(self, idx):
return self.dataset[self.indices[idx]]
def __len__(self):
return len(self.indices)
class Dataset(BaseDataset):
def __init__(self, args):
self.args = args
self.raw_dataset = GraphPropPredDataset(name=args.dataset_name)
self.num_tasks = self.raw_dataset.num_tasks
self.eval_metrics = self.raw_dataset.eval_metric
self.task_type = self.raw_dataset.task_type
self.pgl_graph_list = []
self.graph_label_list = []
for i in range(len(self.raw_dataset)):
graph, label = self.raw_dataset[i]
edges = list(zip(graph["edge_index"][0], graph["edge_index"][1]))
g = pgl.graph.Graph(num_nodes=graph["num_nodes"], edges=edges)
if graph["edge_feat"] is not None:
g.edge_feat["feat"] = graph["edge_feat"]
if graph["node_feat"] is not None:
g.node_feat["feat"] = graph["node_feat"]
self.pgl_graph_list.append(g)
self.graph_label_list.append(label)
def __getitem__(self, idx):
return self.pgl_graph_list[idx], self.graph_label_list[idx]
def __len__(self):
return len(slef.pgl_graph_list)
def get_idx_split(self):
return self.raw_dataset.get_idx_split()
# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
This file implement the graph dataloader.
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
from __future__ import unicode_literals
from __future__ import absolute_import
import ssl
ssl._create_default_https_context = ssl._create_unverified_context
# SSL
import torch
import sys
import six
from io import open
import collections
from collections import namedtuple
import numpy as np
import tqdm
import time
import paddle
import paddle.fluid as fluid
import paddle.fluid.layers as fl
import pgl
from pgl.utils import mp_reader
from pgl.utils.logger import log
from ogb.graphproppred import GraphPropPredDataset
def batch_iter(data, batch_size, fid, num_workers):
"""node_batch_iter
"""
size = len(data)
perm = np.arange(size)
np.random.shuffle(perm)
start = 0
cc = 0
while start < size:
index = perm[start:start + batch_size]
start += batch_size
cc += 1
if cc % num_workers != fid:
continue
yield data[index]
def scan_batch_iter(data, batch_size, fid, num_workers):
"""scan_batch_iter
"""
batch = []
cc = 0
for line_example in data.scan():
cc += 1
if cc % num_workers != fid:
continue
batch.append(line_example)
if len(batch) == batch_size:
yield batch
batch = []
if len(batch) > 0:
yield batch
class GraphDataloader(object):
"""Graph Dataloader
"""
def __init__(self,
dataset,
graph_wrapper,
batch_size,
seed=0,
num_workers=1,
buf_size=1000,
shuffle=True):
self.shuffle = shuffle
self.seed = seed
self.num_workers = num_workers
self.buf_size = buf_size
self.batch_size = batch_size
self.dataset = dataset
self.graph_wrapper = graph_wrapper
def batch_fn(self, batch_examples):
""" batch_fn batch producer"""
graphs = [b[0] for b in batch_examples]
labels = [b[1] for b in batch_examples]
join_graph = pgl.graph.MultiGraph(graphs)
labels = np.array(labels)
feed_dict = self.graph_wrapper.to_feed(join_graph)
batch_valid = (labels == labels).astype("float32")
labels = np.nan_to_num(labels).astype("float32")
feed_dict['labels'] = labels
feed_dict['unmask'] = batch_valid
return feed_dict
def batch_iter(self, fid):
"""batch_iter"""
if self.shuffle:
for batch in batch_iter(self, self.batch_size, fid,
self.num_workers):
yield batch
else:
for batch in scan_batch_iter(self, self.batch_size, fid,
self.num_workers):
yield batch
def __len__(self):
"""__len__"""
return len(self.dataset)
def __getitem__(self, idx):
"""__getitem__"""
if isinstance(idx, collections.Iterable):
return [self[bidx] for bidx in idx]
else:
return self.dataset[idx]
def __iter__(self):
"""__iter__"""
def worker(filter_id):
def func_run():
for batch_examples in self.batch_iter(filter_id):
batch_dict = self.batch_fn(batch_examples)
yield batch_dict
return func_run
if self.num_workers == 1:
r = paddle.reader.buffered(worker(0), self.buf_size)
else:
worker_pool = [worker(wid) for wid in range(self.num_workers)]
worker = mp_reader.multiprocess_reader(
worker_pool, use_pipe=True, queue_size=1000)
r = paddle.reader.buffered(worker, self.buf_size)
for batch in r():
yield batch
def scan(self):
"""scan"""
for example in self.dataset:
yield example
if __name__ == "__main__":
from base_dataset import BaseDataset, Subset
dataset = GraphPropPredDataset(name="ogbg-molhiv")
splitted_index = dataset.get_idx_split()
train_dataset = Subset(dataset, splitted_index['train'])
valid_dataset = Subset(dataset, splitted_index['valid'])
test_dataset = Subset(dataset, splitted_index['test'])
log.info("Train Examples: %s" % len(train_dataset))
log.info("Val Examples: %s" % len(valid_dataset))
log.info("Test Examples: %s" % len(test_dataset))
# train_loader = GraphDataloader(train_dataset, batch_size=3)
# for batch_data in train_loader:
# graphs, labels = batch_data
# print(labels.shape)
# time.sleep(4)
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import sys
import os
import logging
from random import random
import pandas as pd
import numpy as np
from itertools import compress
import scipy.sparse as sp
from sklearn.model_selection import StratifiedKFold
from sklearn.preprocessing import StandardScaler
from rdkit.Chem.Scaffolds import MurckoScaffold
import pgl
from pgl.utils import paddle_helper
try:
from dataset.Dataset import Subset
from dataset.Dataset import ChemDataset
except:
from Dataset import Subset
from Dataset import ChemDataset
log = logging.getLogger("logger")
def random_split(dataset, args):
total_precent = args.frac_train + args.frac_valid + args.frac_test
np.testing.assert_almost_equal(total_precent, 1.0)
length = len(dataset)
perm = list(range(length))
np.random.shuffle(perm)
num_train = int(args.frac_train * length)
num_valid = int(args.frac_valid * length)
num_test = int(args.frac_test * length)
train_indices = perm[0:num_train]
valid_indices = perm[num_train:(num_train + num_valid)]
test_indices = perm[(num_train + num_valid):]
assert (len(train_indices) + len(valid_indices) + len(test_indices)
) == length
train_dataset = Subset(dataset, train_indices)
valid_dataset = Subset(dataset, valid_indices)
test_dataset = Subset(dataset, test_indices)
return train_dataset, valid_dataset, test_dataset
def scaffold_split(dataset, args, return_smiles=False):
total_precent = args.frac_train + args.frac_valid + args.frac_test
np.testing.assert_almost_equal(total_precent, 1.0)
smiles_list_file = os.path.join(args.data_dir, "smiles.csv")
smiles_list = pd.read_csv(smiles_list_file, header=None)[0].tolist()
non_null = np.ones(len(dataset)) == 1
smiles_list = list(compress(enumerate(smiles_list), non_null))
# create dict of the form {scaffold_i: [idx1, idx....]}
all_scaffolds = {}
for i, smiles in smiles_list:
scaffold = MurckoScaffold.MurckoScaffoldSmiles(
smiles=smiles, includeChirality=True)
# scaffold = generate_scaffold(smiles, include_chirality=True)
if scaffold not in all_scaffolds:
all_scaffolds[scaffold] = [i]
else:
all_scaffolds[scaffold].append(i)
# sort from largest to smallest sets
all_scaffolds = {
key: sorted(value)
for key, value in all_scaffolds.items()
}
all_scaffold_sets = [
scaffold_set
for (scaffold, scaffold_set) in sorted(
all_scaffolds.items(),
key=lambda x: (len(x[1]), x[1][0]),
reverse=True)
]
# get train, valid test indices
train_cutoff = args.frac_train * len(smiles_list)
valid_cutoff = (args.frac_train + args.frac_valid) * len(smiles_list)
train_idx, valid_idx, test_idx = [], [], []
for scaffold_set in all_scaffold_sets:
if len(train_idx) + len(scaffold_set) > train_cutoff:
if len(train_idx) + len(valid_idx) + len(
scaffold_set) > valid_cutoff:
test_idx.extend(scaffold_set)
else:
valid_idx.extend(scaffold_set)
else:
train_idx.extend(scaffold_set)
assert len(set(train_idx).intersection(set(valid_idx))) == 0
assert len(set(test_idx).intersection(set(valid_idx))) == 0
# log.info(len(scaffold_set))
# log.info(["train_idx", train_idx])
# log.info(["valid_idx", valid_idx])
# log.info(["test_idx", test_idx])
train_dataset = Subset(dataset, train_idx)
valid_dataset = Subset(dataset, valid_idx)
test_dataset = Subset(dataset, test_idx)
if return_smiles:
train_smiles = [smiles_list[i][1] for i in train_idx]
valid_smiles = [smiles_list[i][1] for i in valid_idx]
test_smiles = [smiles_list[i][1] for i in test_idx]
return train_dataset, valid_dataset, test_dataset, (
train_smiles, valid_smiles, test_smiles)
return train_dataset, valid_dataset, test_dataset
if __name__ == "__main__":
file_path = os.path.dirname(os.path.realpath(__file__))
proj_path = os.path.join(file_path, '../')
sys.path.append(proj_path)
from utils.config import Config
from dataset.Dataset import Subset
from dataset.Dataset import ChemDataset
config_file = "./finetune_config.yaml"
args = Config(config_file)
log.info("loading dataset")
dataset = ChemDataset(args)
train_dataset, valid_dataset, test_dataset = scaffold_split(dataset, args)
log.info("Train Examples: %s" % len(train_dataset))
log.info("Val Examples: %s" % len(valid_dataset))
log.info("Test Examples: %s" % len(test_dataset))
import ipdb
ipdb.set_trace()
log.info("preprocess finish")
task_name: hiv
seed: 15391
dataset_name: ogbg-molhiv
eval_metrics: null
task_type: null
num_class: null
pool_type: average
train_eps: True
norm_type: layer_norm
model_type: GNNModel
embed_dim: 128
num_layers: 5
hidden_size: 256
save_dir: ./checkpoints
# finetune model config
init_checkpoint: null
init_pretraining_params: null
# data config
data_dir: ./dataset/
symmetry: True
batch_size: 32
buf_size: 1000
metrics: True
shuffle: True
num_workers: 12
output_dir: ./outputs/
# trainging config
epoch: 50
learning_rate: 0.0001
lr_scheduler: linear_warmup_decay
weight_decay: 0.01
warmup_proportion: 0.1
save_steps: 10000
validation_steps: 1000
use_dynamic_loss_scaling: True
init_loss_scaling: 102400
metric: simple_accuracy
incr_every_n_steps: 100
decr_every_n_nan_or_inf: 2
incr_ratio: 2.0
decr_ratio: 0.8
log_dir: ./logs
eval_step: 400
train_log_step: 20
# log config
skip_steps: 10
verbose: False
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import ssl
ssl._create_default_https_context = ssl._create_unverified_context
# SSL
import torch
import os
import re
import time
from random import random
from functools import reduce, partial
import numpy as np
import multiprocessing
from ogb.graphproppred import Evaluator
import paddle
import paddle.fluid as F
import paddle.fluid.layers as L
import pgl
from pgl.utils import paddle_helper
from pgl.utils.logger import log
from utils.args import print_arguments, check_cuda, prepare_logger
from utils.init import init_checkpoint, init_pretraining_params
from utils.config import Config
from optimization import optimization
from monitor.train_monitor import train_and_evaluate
from args import parser
import model as Model
from data.base_dataset import Subset, Dataset
from data.dataloader import GraphDataloader
def main(args):
log.info('loading data')
dataset = Dataset(args)
args.num_class = dataset.num_tasks
args.eval_metrics = dataset.eval_metrics
args.task_type = dataset.task_type
splitted_index = dataset.get_idx_split()
train_dataset = Subset(dataset, splitted_index['train'])
valid_dataset = Subset(dataset, splitted_index['valid'])
test_dataset = Subset(dataset, splitted_index['test'])
log.info("preprocess finish")
log.info("Train Examples: %s" % len(train_dataset))
log.info("Val Examples: %s" % len(valid_dataset))
log.info("Test Examples: %s" % len(test_dataset))
train_prog = F.Program()
startup_prog = F.Program()
if args.use_cuda:
dev_list = F.cuda_places()
place = dev_list[0]
dev_count = len(dev_list)
else:
place = F.CPUPlace()
dev_count = int(os.environ.get('CPU_NUM', multiprocessing.cpu_count()))
# dev_count = args.cpu_num
log.info("building model")
with F.program_guard(train_prog, startup_prog):
with F.unique_name.guard():
graph_model = getattr(Model, args.model_type)(args, dataset)
train_ds = GraphDataloader(
train_dataset,
graph_model.graph_wrapper,
batch_size=args.batch_size)
num_train_examples = len(train_dataset)
max_train_steps = args.epoch * num_train_examples // args.batch_size // dev_count
warmup_steps = int(max_train_steps * args.warmup_proportion)
scheduled_lr, loss_scaling = optimization(
loss=graph_model.loss,
warmup_steps=warmup_steps,
num_train_steps=max_train_steps,
learning_rate=args.learning_rate,
train_program=train_prog,
startup_prog=startup_prog,
weight_decay=args.weight_decay,
scheduler=args.lr_scheduler,
use_fp16=False,
use_dynamic_loss_scaling=args.use_dynamic_loss_scaling,
init_loss_scaling=args.init_loss_scaling,
incr_every_n_steps=args.incr_every_n_steps,
decr_every_n_nan_or_inf=args.decr_every_n_nan_or_inf,
incr_ratio=args.incr_ratio,
decr_ratio=args.decr_ratio)
test_prog = F.Program()
with F.program_guard(test_prog, startup_prog):
with F.unique_name.guard():
_graph_model = getattr(Model, args.model_type)(args, dataset)
test_prog = test_prog.clone(for_test=True)
valid_ds = GraphDataloader(
valid_dataset,
graph_model.graph_wrapper,
batch_size=args.batch_size,
shuffle=False)
test_ds = GraphDataloader(
test_dataset,
graph_model.graph_wrapper,
batch_size=args.batch_size,
shuffle=False)
exe = F.Executor(place)
exe.run(startup_prog)
for init in graph_model.init_vars:
init(place)
for init in _graph_model.init_vars:
init(place)
if args.init_pretraining_params is not None:
init_pretraining_params(
exe, args.init_pretraining_params, main_program=startup_prog)
nccl2_num_trainers = 1
nccl2_trainer_id = 0
if dev_count > 1:
exec_strategy = F.ExecutionStrategy()
exec_strategy.num_threads = dev_count
train_exe = F.ParallelExecutor(
use_cuda=args.use_cuda,
loss_name=graph_model.loss.name,
exec_strategy=exec_strategy,
main_program=train_prog,
num_trainers=nccl2_num_trainers,
trainer_id=nccl2_trainer_id)
test_exe = exe
else:
train_exe, test_exe = exe, exe
evaluator = Evaluator(args.dataset_name)
train_and_evaluate(
exe=exe,
train_exe=train_exe,
valid_exe=test_exe,
train_ds=train_ds,
valid_ds=valid_ds,
test_ds=test_ds,
train_prog=train_prog,
valid_prog=test_prog,
args=args,
dev_count=dev_count,
evaluator=evaluator,
model=graph_model)
if __name__ == "__main__":
args = parser.parse_args()
if args.config is not None:
config = Config(args.config, isCreate=True, isSave=True)
config['use_cuda'] = args.use_cuda
log.info(config)
main(config)
#-*- coding: utf-8 -*-
import os
import re
import time
import logging
from random import random
from functools import reduce, partial
import numpy as np
import multiprocessing
import paddle
import paddle.fluid as F
import paddle.fluid.layers as L
import pgl
from pgl.graph_wrapper import GraphWrapper
from pgl.layers.conv import gcn, gat
from pgl.utils import paddle_helper
from pgl.utils.logger import log
from utils.args import print_arguments, check_cuda, prepare_logger
from utils.init import init_checkpoint, init_pretraining_params
from mol_encoder import AtomEncoder, BondEncoder
def copy_send(src_feat, dst_feat, edge_feat):
return src_feat["h"]
def mean_recv(feat):
return L.sequence_pool(feat, pool_type="average")
def sum_recv(feat):
return L.sequence_pool(feat, pool_type="sum")
def max_recv(feat):
return L.sequence_pool(feat, pool_type="max")
def unsqueeze(tensor):
tensor = L.unsqueeze(tensor, axes=-1)
tensor.stop_gradient = True
return tensor
class Metric:
def __init__(self, **args):
self.args = args
@property
def vars(self):
values = [self.args[k] for k in self.args.keys()]
return values
def parse(self, fetch_list):
tup = list(zip(self.args.keys(), [float(v[0]) for v in fetch_list]))
return dict(tup)
def gin_layer(gw, node_features, edge_features, train_eps, name):
def send_func(src_feat, dst_feat, edge_feat):
"""Send"""
return src_feat["h"] + edge_feat["h"]
epsilon = L.create_parameter(
shape=[1, 1],
dtype="float32",
attr=F.ParamAttr(name="%s_eps" % name),
default_initializer=F.initializer.ConstantInitializer(value=0.0))
if not train_eps:
epsilon.stop_gradient = True
msg = gw.send(
send_func,
nfeat_list=[("h", node_features)],
efeat_list=[("h", edge_features)])
node_feat = gw.recv(msg, "sum") + node_features * (epsilon + 1.0)
# if apply_func is not None:
# node_feat = apply_func(node_feat, name)
return node_feat
class GNNModel(object):
def __init__(self, args, dataset):
self.args = args
self.dataset = dataset
self.hidden_size = self.args.hidden_size
self.embed_dim = self.args.embed_dim
self.dropout_prob = self.args.dropout_rate
self.pool_type = self.args.pool_type
self._init_vars = []
graph_data = []
g, label = self.dataset[0]
graph_data.append(g)
g, label = self.dataset[1]
graph_data.append(g)
batch_graph = pgl.graph.MultiGraph(graph_data)
graph_data = batch_graph
graph_data.edge_feat["feat"] = graph_data.edge_feat["feat"].astype(
"int64")
graph_data.node_feat["feat"] = graph_data.node_feat["feat"].astype(
"int64")
self.graph_wrapper = GraphWrapper(
name="graph",
place=F.CPUPlace(),
node_feat=graph_data.node_feat_info(),
edge_feat=graph_data.edge_feat_info())
self.atom_encoder = AtomEncoder(name="atom", emb_dim=self.embed_dim)
self.bond_encoder = BondEncoder(name="bond", emb_dim=self.embed_dim)
self.labels = L.data(
"labels",
shape=[None, self.args.num_class],
dtype="float32",
append_batch_size=False)
self.unmask = L.data(
"unmask",
shape=[None, self.args.num_class],
dtype="float32",
append_batch_size=False)
self.build_model()
def build_model(self):
node_features = self.atom_encoder(self.graph_wrapper.node_feat['feat'])
edge_features = self.bond_encoder(self.graph_wrapper.edge_feat['feat'])
self._enc_out = self.node_repr_encode(node_features, edge_features)
logits = L.fc(self._enc_out,
self.args.num_class,
act=None,
param_attr=F.ParamAttr(name="final_fc"))
# L.Print(self.labels, message="labels")
# L.Print(self.unmask, message="unmask")
loss = L.sigmoid_cross_entropy_with_logits(x=logits, label=self.labels)
loss = loss * self.unmask
self.loss = L.reduce_sum(loss) / L.reduce_sum(self.unmask)
self.pred = L.sigmoid(logits)
self._metrics = Metric(loss=self.loss)
def node_repr_encode(self, node_features, edge_features):
features_list = [node_features]
for layer in range(self.args.num_layers):
feat = gin_layer(
self.graph_wrapper,
features_list[layer],
edge_features,
train_eps=self.args.train_eps,
name="gin_%s" % layer, )
feat = self.mlp(feat, name="mlp_%s" % layer)
feat = feat + features_list[layer] # residual
features_list.append(feat)
output = pgl.layers.graph_pooling(
self.graph_wrapper, features_list[-1], self.args.pool_type)
return output
def mlp(self, features, name):
h = features
dim = features.shape[-1]
dim_list = [dim * 2, dim]
for i in range(2):
h = L.fc(h,
size=dim_list[i],
name="%s_fc_%s" % (name, i),
act=None)
if self.args.norm_type == "layer_norm":
log.info("norm_type is %s" % self.args.norm_type)
h = L.layer_norm(
h,
begin_norm_axis=1,
param_attr=F.ParamAttr(
name="norm_scale_%s_%s" % (name, i),
initializer=F.initializer.Constant(1.0)),
bias_attr=F.ParamAttr(
name="norm_bias_%s_%s" % (name, i),
initializer=F.initializer.Constant(0.0)), )
else:
log.info("using batch_norm")
h = L.batch_norm(h)
h = pgl.layers.graph_norm(self.graph_wrapper, h)
h = L.relu(h)
return h
def get_enc_output(self):
return self._enc_out
@property
def init_vars(self):
return self._init_vars
@property
def metrics(self):
return self._metrics
# Copyright (c) 2020 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""MolEncoder for ogb
"""
import paddle.fluid as fluid
from ogb.utils.features import get_atom_feature_dims, get_bond_feature_dims
class AtomEncoder(object):
"""AtomEncoder for encoding node features"""
def __init__(self, name, emb_dim):
self.emb_dim = emb_dim
self.name = name
def __call__(self, x):
atom_feature = get_atom_feature_dims()
atom_input = fluid.layers.split(
x, num_or_sections=len(atom_feature), dim=-1)
outputs = None
count = 0
for _x, _atom_input_dim in zip(atom_input, atom_feature):
count += 1
emb = fluid.layers.embedding(
_x,
size=(_atom_input_dim, self.emb_dim),
param_attr=fluid.ParamAttr(
name=self.name + '_atom_feat_%s' % count))
if outputs is None:
outputs = emb
else:
outputs = outputs + emb
return outputs
class BondEncoder(object):
"""Bond for encoding edge features"""
def __init__(self, name, emb_dim):
self.emb_dim = emb_dim
self.name = name
def __call__(self, x):
bond_feature = get_bond_feature_dims()
bond_input = fluid.layers.split(
x, num_or_sections=len(bond_feature), dim=-1)
outputs = None
count = 0
for _x, _bond_input_dim in zip(bond_input, bond_feature):
count += 1
emb = fluid.layers.embedding(
_x,
size=(_bond_input_dim, self.emb_dim),
param_attr=fluid.ParamAttr(
name=self.name + '_bond_feat_%s' % count))
if outputs is None:
outputs = emb
else:
outputs = outputs + emb
return outputs
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...@@ -13,7 +13,7 @@ ...@@ -13,7 +13,7 @@
# limitations under the License. # limitations under the License.
"""Generate pgl apis """Generate pgl apis
""" """
__version__ = "1.0.2" __version__ = "1.1.0"
from pgl import layers from pgl import layers
from pgl import graph_wrapper from pgl import graph_wrapper
from pgl import graph from pgl import graph
......
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