Towards Knowledge-Based Personalized Product Description Generation in E-commerce @ KDD 2019
New: We release KOBE v2, a refactored version of the original code with the latest deep learning tools in 2021 and greatly improved installation, reproducibility, performance, and visualization, in memory of Kobe Bryant.
This repo contains code and pre-trained models for KOBE, a sequence-to-sequence based approach for automatically generating product descriptions by leveraging conditional inputs, e.g., user category, and incorporating knowledge with retrieval augmented product titles.
Paper accepted at KDD 2019 (Applied Data Science Track). Latest version at arXiv.
Clone and install KOBE.
git clone https://github.com/THUDM/KOBE
cd KOBE
pip install -e .
Verify that KOBE is correctly installed by import kobe
.
We use the TaoDescribe dataset, which contains 2,129,187 product titles and descriptions in Chinese.
Run the following command to automatically download the dataset:
python -m kobe.data.download
The downloaded files will be placed at saved/raw/
:
1.6G KOBE/saved
1.6G ├──raw
42K │ ├──test.cond
1.4M │ ├──test.desc
2.0M │ ├──test.fact
450K │ ├──test.title
17M │ ├──train.cond
553M │ ├──train.desc
794M │ ├──train.fact
183M │ ├──train.title
80K │ ├──valid.cond
2.6M │ ├──valid.desc
3.7M │ ├──valid.fact
853K │ └──valid.title
...
Preprocessing is a commonly neglected part in code release. However, we now provide the preprocessing scripts to rebuild the vocabulary and tokenize the texts, just in case that you wish to preprocess the KOBE data yourself or need to run on your own data.
We use BPE to build a vocabulary on the conditions (including attributes and user categories). For texts, we will use existing BertTokenizer from the huggingface transformers library.
python -m kobe.data.vocab \
--input saved/raw/train.cond \
--vocab-file saved/vocab.cond \
--vocab-size 31 --algo word
Then, we will tokenize the raw inputs and save the preprocessed samples to .tar
files. Note: this process can take a while (about 20 minutes with a 8-core processor).
python -m kobe.data.preprocess \
--raw-path saved/raw/ \
--processed-path saved/processed/ \
--split train valid test \
--vocab-file bert-base-chinese \
--cond-vocab-file saved/vocab.cond.model
You can peek into the saved/
directories to see what these preprocessing scripts did:
8.2G KOBE/saved
16G ├──processed
20M │ ├──test.tar
1.0G │ ├──train-0.tar
1.0G │ ├──train-1.tar
1.0G │ ├──train-2.tar
1.0G │ ├──train-3.tar
1.0G │ ├──train-4.tar
1.0G │ ├──train-5.tar
1.0G │ ├──train-6.tar
1.0G │ ├──train-7.tar
38M │ └──valid.tar
1.6G ├──raw
│ ├──...
238K └──vocab.cond.model
First, set up WandB, which is an 🌟 incredible tool for visualize deep learning experiments. In case you haven’t use it before, please login and follow the instructions.
wandb login
We provide four training modes: baseline
, kobe-attr
, kobe-know
, kobe-full
, corresponding to the models explored in the paper. They can be trained with the following commands:
python -m kobe.train --mode baseline --name baseline
python -m kobe.train --mode kobe-attr --name kobe-attr
python -m kobe.train --mode kobe-know --name kobe-know
python -m kobe.train --mode kobe-full --name kobe-full
After launching any of the experiment above, please go to the WandB link printed out in the terminal to view the training progress and evaluation results (updated at every epoch end about once per 2 hours).
If you would like to change other hyperparameters, please look at kobe/utils/options.py
. For example, the default setting train the models for 30 epochs with batch size 64, which is around 1 millison steps. You could add options like --epochs 100
to train for more epochs and obtain better results. You can also increase --num-encoder-layers
and --num-decoder-layers
if better GPUs available.
Expected Training Progress
We provide a reference for the training progress (training takes about 150 hours on a 2080 Ti). The full KOBE model achieves the best BERTScore and diversity, with a slightly lower BLEU score than KOBE-Attr (as shown in the paper).
The resulting training/validation/test curves and examples are shown below:
Evaluation is now super convenient and reproducible with the help of pytorch-lightning and WandB. The checkpoint with best bleu score will be saved at kobe-v2/<wandb-run-id>/checkpoints/<best_epoch-best_step>.ckpt
. To evaluate this model, run the following command:
python -m kobe.train --mode baseline --name test-baseline --test --load-file kobe-v2/<wandb-run-id>/checkpoints/<best_epoch-best_step>.ckpt
The results will be displayed on the WandB dashboard with the link printed out in the terminal. The evaluation metrics we provide include BLEU score (sacreBLEU), diversity score and BERTScore. You can also manually view some generated examples and their references under the examples/
section on WandB.
We provide Nucleus sampling (https://arxiv.org/abs/1904.09751) to replace the beam search in the original KOBE paper. To test this great decoding strategy, run:
python -m kobe.train --mode baseline --name test-baseline --test --load-file kobe-v2/<wandb-run-id>/checkpoints/<best_epoch-best_step>.ckpt --decoding-strategy nucleus
Pre-trained model checkpoints are available at https://bit.ly/3FiI7Ed (requires network access to Google Drive). In addition, download the vocabulary file and place under saved/
Please cite our paper if you use this code in your own work:
@inproceedings{chen2019towards,
title={Towards knowledge-based personalized product description generation in e-commerce},
author={Chen, Qibin and Lin, Junyang and Zhang, Yichang and Yang, Hongxia and Zhou, Jingren and Tang, Jie},
booktitle={Proceedings of the 25th ACM SIGKDD International Conference on Knowledge Discovery \& Data Mining},
pages={3040--3050},
year={2019}
}