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Pytorch implementation of Generative Adversarial Text-to-Image Synthesis paper

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Text-to-Image-Synthesis

Intoduction

This is a pytorch implementation of Generative Adversarial Text-to-Image Synthesis paper, we train a conditional generative adversarial network, conditioned on text descriptions, to generate images that correspond to the description. The network architecture is shown below (Image from [1]). This architecture is based on DCGAN.

Image credits [1]

Requirements

  • pytorch
  • visdom
  • h5py
  • PIL
  • numpy

This implementation currently only support running with GPUs.

Implementation details

This implementation follows the Generative Adversarial Text-to-Image Synthesis paper [1], however it works more on training stablization and preventing mode collapses by implementing:

  • Feature matching [2]
  • One sided label smoothing [2]
  • minibatch discrimination [2] (implemented but not used)
  • WGAN [3]
  • WGAN-GP [4] (implemented but not used)

Datasets

We used Caltech-UCSD Birds 200 and Flowers datasets, we converted each dataset (images, text embeddings) to hd5 format.

We used the text embeddings provided by the paper authors

To use this code you can either:

Hd5 file taxonomy `

  • split (train | valid | test )
    • example_name
      • 'name'
      • 'img'
      • 'embeddings'
      • 'class'
      • 'txt'

Usage

Training

`python runtime.py

Arguments:

  • type : GAN archiecture to use (gan | wgan | vanilla_gan | vanilla_wgan). default = gan. Vanilla mean not conditional
  • dataset: Dataset to use (birds | flowers). default = flowers
  • split : An integer indicating which split to use (0 : train | 1: valid | 2: test). default = 0
  • lr : The learning rate. default = 0.0002
  • diter : Only for WGAN, number of iteration for discriminator for each iteration of the generator. default = 5
  • vis_screen : The visdom env name for visualization. default = gan
  • save_path : Path for saving the models.
  • l1_coef : L1 loss coefficient in the generator loss fucntion for gan and vanilla_gan. default=50
  • l2_coef : Feature matching coefficient in the generator loss fucntion for gan and vanilla_gan. default=100
  • pre_trained_disc : Discriminator pre-tranined model path used for intializing training.
  • pre_trained_gen Generator pre-tranined model path used for intializing training.
  • batch_size: Batch size. default= 64
  • num_workers: Number of dataloader workers used for fetching data. default = 8
  • epochs : Number of training epochs. default=200
  • cls: Boolean flag to whether train with cls algorithms or not. default=False

Results

Generated Images

Text to image synthesis

Text Generated Images
A blood colored pistil collects together with a group of long yellow stamens around the outside
The petals of the flower are narrow and extremely pointy, and consist of shades of yellow, blue
This pale peach flower has a double row of long thin petals with a large brown center and coarse loo
The flower is pink with petals that are soft, and separately arranged around the stamens that has pi
A one petal flower that is white with a cluster of yellow anther filaments in the center

References

[1] Generative Adversarial Text-to-Image Synthesis https://arxiv.org/abs/1605.05396

[2] Improved Techniques for Training GANs https://arxiv.org/abs/1606.03498

[3] Wasserstein GAN https://arxiv.org/abs/1701.07875

[4] Improved Training of Wasserstein GANs https://arxiv.org/pdf/1704.00028.pdf

Other Implementations

  1. https://github.com/reedscot/icml2016 (the authors version)
  2. https://github.com/paarthneekhara/text-to-image (tensorflow)

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Pytorch implementation of Generative Adversarial Text-to-Image Synthesis paper

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