Skip to content

teeramisu/LovaszSoftmax

 
 

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

28 Commits
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

The Lovász-Softmax loss: A tractable surrogate for the optimization of the intersection-over-union measure in neural networks

Maxim Berman, Amal Rannen Triki, Matthew B. Blaschko

ESAT-PSI, KU Leuven, Belgium.

Published in CVPR 2018. See project page, arxiv paper, paper on CVF open access.

PyTorch implementation of the loss layer (pytorch folder)

Files included:

  • lovasz_losses.py: Standalone PyTorch implementation of the Lovász hinge and Lovász-Softmax for the Jaccard index
  • demo_binary.ipynb: Jupyter notebook showcasing binary training of a linear model, with the Lovász Hinge and with the Lovász-Sigmoid.
  • demo_multiclass.ipynb: Jupyter notebook showcasing multiclass training of a linear model with the Lovász-Softmax

The binary lovasz_hinge expects real-valued scores (positive scores correspond to foreground pixels).

The multiclass lovasz_softmax expect class probabilities (the maximum scoring category is predicted). First use a Softmax layer on the unnormalized scores.

TensorFlow implementation of the loss layer (tensorflow folder)

Files included:

  • lovasz_losses_tf.py: Standalone TensorFlow implementation of the Lovász hinge and Lovász-Softmax for the Jaccard index
  • demo_binary_tf.ipynb: Jupyter notebook showcasing binary training of a linear model, with the Lovász Hinge and with the Lovász-Sigmoid.
  • demo_multiclass_tf.ipynb: Jupyter notebook showcasing the application of the multiclass loss with the Lovász-Softmax

Warning: the losses values and gradients have been tested to be the same as in PyTorch (see notebooks), however we have not used the TF implementation in a training setting.

Usage

See the demos for simple proofs of principle.

FAQ

  • How should I use the Lovász-Softmax loss?

The loss can be optimized on its own, but the optimal optimization hyperparameters (learning rates, momentum) might be different from the best ones for cross-entropy. As discussed in the paper, optimizing the dataset-mIoU (Pascal VOC measure) is dependent on the batch size and number of classes. Therefore you might have best results by optimizing with cross-entropy first and finetuning with our loss, or by combining the two losses.

See for example how the work Land Cover Classification From Satellite Imagery With U-Net and Lovasz-Softmax Loss by Alexander Rakhlin et al. used our loss in the CVPR 18 DeepGlobe challenge.

  • Inference in Tensorflow is very slow...

Compiling from Tensorflow master (or using a future distribution that includes commit tensorflow/tensorflow@73e3215) should solve this problem; see issue #6.

Citation

Please cite

@inproceedings{berman2018lovasz,
  title={The Lov{\'a}sz-Softmax loss: A tractable surrogate for the optimization of the intersection-over-union measure in neural networks},
  author={Berman, Maxim and Rannen Triki, Amal and Blaschko, Matthew B},
  booktitle={Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition},
  pages={4413--4421},
  year={2018}
}

About

Code for the Lovász-Softmax loss (CVPR 2018)

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages

  • Jupyter Notebook 97.6%
  • Python 2.4%