/neural-style

Neural style in TensorFlow! 🎨

Primary LanguagePythonGNU General Public License v3.0GPL-3.0

neural-style

An implementation of neural style in TensorFlow.

This implementation is a lot simpler than a lot of the other ones out there, thanks to TensorFlow's really nice API and automatic differentiation.

TensorFlow doesn't support L-BFGS (which is what the original authors used), so we use Adam. This may require a little bit more hyperparameter tuning to get nice results.

Related Projects

See here for an implementation of fast (feed-forward) neural style in TensorFlow.

Try neural style client-side in your web browser without installing any software (using TensorFire).

Running

python neural_style.py --content <content file> --styles <style file> --output <output file>

Run python neural_style.py --help to see a list of all options.

If you are running this project on Floydhub you can use the following syntax (this pulls in the pre-trained VGG network automatically):

floyd run --gpu --env tensorflow-1.3 --data floydhub/datasets/imagenet-vgg-verydeep-19/3:vgg "python neural_style.py --network /vgg/imagenet-vgg-verydeep-19.mat --content <content file> --styles <style file> --output <output file>"

Use --checkpoint-output and --checkpoint-iterations to save checkpoint images.

Use --iterations to change the number of iterations (default 1000). For a 512×512 pixel content file, 1000 iterations take 60 seconds on a GTX 1080 Ti, 90 seconds on a Maxwell Titan X, or 60 minutes on an Intel Core i7-5930K. Using a GPU is highly recommended due to the huge speedup.

Example 1

Running it for 500-2000 iterations seems to produce nice results. With certain images or output sizes, you might need some hyperparameter tuning (especially --content-weight, --style-weight, and --learning-rate).

The following example was run for 1000 iterations to produce the result (with default parameters):

output

These were the input images used (me sleeping at a hackathon and Starry Night):

input-content

input-style

Example 2

The following example demonstrates style blending, and was run for 1000 iterations to produce the result (with style blend weight parameters 0.8 and 0.2):

output

The content input image was a picture of the Stata Center at MIT:

input-content

The style input images were Picasso's "Dora Maar" and Starry Night, with the Picasso image having a style blend weight of 0.8 and Starry Night having a style blend weight of 0.2:

input-style input-style

Tweaking

--style-layer-weight-exp command line argument could be used to tweak how "abstract" the style transfer should be. Lower values mean that style transfer of a finer features will be favored over style transfer of a more coarse features, and vice versa. Default value is 1.0 - all layers treated equally. Somewhat extreme examples of what you can achieve:

--style-layer-weight-exp 0.2 --style-layer-weight-exp 2.0

(left: 0.2 - finer features style transfer; right: 2.0 - coarser features style transfer)

--content-weight-blend specifies the coefficient of content transfer layers. Default value - 1.0, style transfer tries to preserve finer grain content details. The value should be in range [0.0; 1.0].

--content-weight-blend 1.0 --content-weight-blend 0.1

(left: 1.0 - default value; right: 0.1 - more abstract picture)

--pooling allows to select which pooling layers to use (specify either max or avg). Original VGG topology uses max pooling, but the style transfer paper suggests replacing it with average pooling. The outputs are perceptually different, max pool in general tends to have finer detail style transfer, but could have troubles at lower-freqency detail level:

--pooling max --pooling avg

(left: max pooling; right: average pooling)

--preserve-colors boolean command line argument adds post-processing step, which combines colors from the original image and luma from the stylized image (YCbCr color space), thus producing color-preserving style transfer:

--pooling max --pooling max

(left: original stylized image; right: color-preserving style transfer)

Requirements

Data Files

  • Pre-trained VGG network (MD5 106118b7cf60435e6d8e04f6a6dc3657) - put it in the top level of this repository, or specify its location using the --network option.

Dependencies

You can install Python dependencies using pip install -r requirements.txt, and it should just work. If you want to install the packages manually, here's a list:

Citation

If you use this implementation in your work, please cite the following:

@misc{athalye2015neuralstyle,
  author = {Anish Athalye},
  title = {Neural Style},
  year = {2015},
  howpublished = {\url{https://github.com/anishathalye/neural-style}},
  note = {commit xxxxxxx}
}

License

Copyright (c) 2015-2019 Anish Athalye. Released under GPLv3. See LICENSE.txt for details.