This is a PyToch implementation of "Real-time Scene Text Detection with Differentiable Binarization". This paper presents a real-time arbitrary-shape scene text detector, achieving the state-of-the-art performance on standard benchmarks.
Part of the code is inherited from MegReader.
- Release code
- Document for Installation
- Trained models
- Document for testing and training
- Evaluation
- Demo script
- re-organize and clean the parameters
- Python3
- PyTorch >= 1.2
- GCC >= 4.9 (This is important for PyTorch)
- CUDA >= 9.0 (10.1 is recommended)
# first, make sure that your conda is setup properly with the right environment
# for that, check that `which conda`, `which pip` and `which python` points to the
# right path. From a clean conda env, this is what you need to do
conda create --name DB -y
conda activate DB
# this installs the right pip and dependencies for the fresh python
conda install ipython pip
# python dependencies
pip install -r requirement.txt
# install PyTorch with cuda-10.1
conda install pytorch torchvision cudatoolkit=10.1 -c pytorch
# clone repo
git clone https://github.com/MhLiao/DB.git
cd DB/
# build deformable convolution opertor
# make sure your cuda path of $CUDA_HOME is the same version as your cuda in PyTorch
# make sure GCC >= 4.9
# you need to delete the build directory before you re-build it.
echo $CUDA_HOME
cd assets/ops/dcn/
python setup.py build_ext --inplace
Download Trained models Baidu Drive (download code: p6u3), Google Drive.
pre-trained-model-synthtext -- used to finetune models, not for evaluation
td500_resnet18
td500_resnet50
totaltext_resnet18
totaltext_resnet50
The root of the dataset directory can be DB/datasets/
.
Download the converted ground-truth and data list Baidu Drive (download code: mz0a), Google Drive. The images of each dataset can be obtained from their official website.
An example of the path of test images:
datasets/total_text/train_images
datasets/total_text/train_gts
datasets/total_text/train_list.txt
datasets/total_text/test_images
datasets/total_text/test_gts
datasets/total_text/test_list.txt
The data root directory and the data list file can be defined in base_totaltext.yaml
The YAML files with the name of base*.yaml
should not be used as the training or testing config file directly.
Run the model inference with a single image. Here is an example:
CUDA_VISIBLE_DEVICES=0 python demo.py experiments/seg_detector/totaltext_resnet18_deform_thre.yaml --image_path datasets/total_text/test_images/img10.jpg --resume path-to-model-directory/totaltext_resnet18 --polygon --box_thresh 0.7 --visualize
The results can be find in demo_results
.
Note that we do not provide all the protocols for all benchmarks for simplification. The embedded evaluation protocol in the code is modified from the protocol of ICDAR 2015 dataset while support arbitrary-shape polygons. It almost produces the same results as the pascal evaluation protocol in Total-Text dataset.
The img651.jpg
in the test set of Total-Text contains exif info for a 90° rotation thus the gt does not match the image. You should read and re-write this image to get normal results. The converted image is also provided in the dataset links.
The following command can re-implement the results in the paper:
CUDA_VISIBLE_DEVICES=0 python eval.py experiments/seg_detector/totaltext_resnet18_deform_thre.yaml --resume path-to-model-directory/totaltext_resnet18 --polygon --box_thresh 0.7
CUDA_VISIBLE_DEVICES=0 python eval.py experiments/seg_detector/totaltext_resnet50_deform_thre.yaml --resume path-to-model-directory/totaltext_resnet50 --polygon --box_thresh 0.6
CUDA_VISIBLE_DEVICES=0 python eval.py experiments/seg_detector/td500_resnet18_deform_thre.yaml --resume path-to-model-directory/td500_resnet18 --box_thresh 0.5
CUDA_VISIBLE_DEVICES=0 python eval.py experiments/seg_detector/td500_resnet50_deform_thre.yaml --resume path-to-model-directory/td500_resnet50 --box_thresh 0.5
# short side 736, which can be changed in base_ic15.yaml
CUDA_VISIBLE_DEVICES=0 python eval.py experiments/seg_detector/ic15_resnet18_deform_thre.yaml --resume path-to-model-directory/ic15_resnet18 --box_thresh 0.55
# short side 736, which can be changed in base_ic15.yaml
CUDA_VISIBLE_DEVICES=0 python eval.py experiments/seg_detector/ic15_resnet50_deform_thre.yaml --resume path-to-model-directory/ic15_resnet50 --box_thresh 0.6
# short side 1152, which can be changed in base_ic15.yaml
CUDA_VISIBLE_DEVICES=0 python eval.py experiments/seg_detector/ic15_resnet50_deform_thre.yaml --resume path-to-model-directory/ic15_resnet50 --box_thresh 0.6
The results should be as follows:
Model | precision | recall | F-measure | precision (paper) | recall (paper) | F-measure (paper) |
---|---|---|---|---|---|---|
totaltext-resnet18 | 88.9 | 77.6 | 82.9 | 88.3 | 77.9 | 82.8 |
totaltext-resnet50 | 88.0 | 81.5 | 84.6 | 87.1 | 82.5 | 84.7 |
td500-resnet18 | 86.5 | 79.4 | 82.8 | 90.4 | 76.3 | 82.8 |
td500-resnet50 | 91.1 | 80.8 | 85.6 | 91.5 | 79.2 | 84.9 |
ic15-resnet18 (736) | 87.7 | 77.5 | 82.3 | 86.8 | 78.4 | 82.3 |
ic15-resnet50 (736) | 91.3 | 80.3 | 85.4 | 88.2 | 82.7 | 85.4 |
ic15-resnet50 (1152) | 90.7 | 84.0 | 87.2 | 91.8 | 83.2 | 87.3 |
box_thresh
can be used to balance the precision and recall, which may be different for different datasets to get a good F-measure. polygon
is only used for arbitrary-shape text dataset. The size of the input images are defined in validate_data->processes->AugmentDetectionData
in base_*.yaml
.
Set adaptive
to False
in the yaml file to speedup the inference without decreasing the performance. The speed is evaluated by performing a testing image for 50 times to exclude extra IO time.
CUDA_VISIBLE_DEVICES=0 python eval.py experiments/seg_detector/totaltext_resnet18_deform_thre.yaml --resume path-to-model-directory/totaltext_resnet18 --polygon --box_thresh 0.7 --speed
Note that the speed is related to both to the GPU and the CPU since the model runs with the GPU and the post-processing algorithm runs with the CPU.
Check the paths of data_dir and data_list in the base_*.yaml file. For better performance, you can first per-train the model with SynthText and then fine-tune it with the specific real-world dataset.
CUDA_VISIBLE_DEVICES=0,1,2,3 python train.py path-to-yaml-file --num_gpus 4
You can also try distributed training (Note that the distributed mode is not fully tested. I am not sure whether it can achieves the same performance as non-distributed training.)
CUDA_VISIBLE_DEVICES=0,1,2,3 python -m torch.distributed.launch --nproc_per_node=4 train.py path-to-yaml-file --num_gpus 4
Note that the current implementation is written by pure Python code except for the deformable convolution operator. Thus, the code can be further optimized by some optimization skills, such as TensorRT for the model forward and efficient C++ code for the post-processing function.
Another option to increase speed is to run the model forward and the post-processing algorithm in parallel through a producer-consumer strategy.
Contributions or pull requests are welcome.
- Keras implementation: xuannianz/DifferentiableBinarization
Please cite the related works in your publications if it helps your research:
@inproceedings{liao2020real,
author={Liao, Minghui and Wan, Zhaoyi and Yao, Cong and Chen, Kai and Bai, Xiang},
title={Real-time Scene Text Detection with Differentiable Binarization},
booktitle={Proc. AAAI},
year={2020}
}