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--- |
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datasets: |
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- danjacobellis/LSDIR_540 |
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--- |
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# Wavelet Learned Lossy Compression (WaLLoC) |
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WaLLoC sandwiches a convolutional autoencoder between time-frequency analysis and synthesis transforms using |
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CDF 9/7 wavelet filters. The time-frequency transform increases the number of signal channels, but reduces the temporal or spatial resolution, resulting in lower GPU memory consumption and higher throughput. WaLLoC's training procedure is highly simplified compared to other $\beta$-VAEs, VQ-VAEs, and neural codecs, but still offers significant dimensionality reduction and compression. This makes it suitable for dataset storage and compressed-domain learning. It currently supports 2D signals (e.g. grayscale, RGB, or hyperspectral images). Support for 1D and 3D signals is in progress. |
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## Installation |
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1. Follow the installation instructions for [torch](https://pytorch.org/get-started/locally/) |
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2. Install WaLLoC and other dependencies via pip |
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```pip install walloc PyWavelets pytorch-wavelets``` |
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## Pre-trained checkpoints |
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Pre-trained checkpoints are available on [Hugging Face](https://huggingface.co/danjacobellis/walloc). |
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## Training |
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Access to training code is provided by request via [email.](mailto:[email protected]) |
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## Usage example |
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```python |
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import os |
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import torch |
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import matplotlib.pyplot as plt |
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import numpy as np |
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from PIL import Image |
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from IPython.display import display |
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from torchvision.transforms import ToPILImage, PILToTensor |
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from walloc import walloc |
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from walloc.walloc import latent_to_pil, pil_to_latent |
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class Args: pass |
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``` |
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### Load the model from a pre-trained checkpoint |
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```wget https://hf.co/danjacobellis/walloc/resolve/main/v0.6.3_ext.pth``` |
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```python |
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device = "cpu" |
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checkpoint = torch.load("v0.6.3_ext.pth",map_location="cpu") |
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args = checkpoint['args'] |
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codec = walloc.Walloc( |
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channels = args.channels, |
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J = args.J, |
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N = args.N, |
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latent_dim = args.latent_dim, |
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latent_bits = 5 |
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) |
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codec.load_state_dict(checkpoint['model_state_dict']) |
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codec = codec.to(device) |
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``` |
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### Load an example image |
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```wget "https://r0k.us/graphics/kodak/kodak/kodim05.png"``` |
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```python |
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img = Image.open("kodim05.png") |
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img |
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``` |
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### Full encoding and decoding pipeline with .forward() |
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* If `codec.eval()` is called, the latent is rounded to nearest integer. |
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* If `codec.train()` is called, uniform noise is added instead of rounding. |
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```python |
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with torch.no_grad(): |
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codec.eval() |
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x = PILToTensor()(img).to(torch.float) |
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x = (x/255 - 0.5).unsqueeze(0).to(device) |
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x_hat, _, _ = codec(x) |
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ToPILImage()(x_hat[0]+0.5) |
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``` |
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### Accessing latents |
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```python |
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with torch.no_grad(): |
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codec.eval() |
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X = codec.wavelet_analysis(x,J=codec.J) |
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Y = codec.encoder(X) |
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X_hat = codec.decoder(Y) |
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x_hat = codec.wavelet_synthesis(X_hat,J=codec.J) |
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print(f"dimensionality reduction: {x.numel()/Y.numel()}×") |
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``` |
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dimensionality reduction: 12.0× |
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```python |
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Y.unique() |
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``` |
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tensor([-15., -14., -13., -12., -11., -10., -9., -8., -7., -6., -5., -4., |
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-3., -2., -1., -0., 1., 2., 3., 4., 5., 6., 7., 8., |
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9., 10., 11., 12., 13., 14., 15.]) |
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```python |
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plt.figure(figsize=(5,3),dpi=150) |
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plt.hist( |
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Y.flatten().numpy(), |
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range=(-17.5,17.5), |
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bins=35, |
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density=True, |
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width=0.8); |
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plt.title("Histogram of latents") |
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plt.xticks(range(-15,16,5)); |
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``` |
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# Lossless compression of latents |
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### Single channel PNG (L) |
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```python |
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Y_pil = latent_to_pil(Y,5,1) |
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display(Y_pil[0]) |
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Y_pil[0].save('latent.png') |
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png = [Image.open("latent.png")] |
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Y_rec = pil_to_latent(png,16,5,1) |
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assert(Y_rec.equal(Y)) |
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print("compression_ratio: ", x.numel()/os.path.getsize("latent.png")) |
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``` |
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compression_ratio: 20.307596963280485 |
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### Three channel WebP (RGB) |
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```python |
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Y_pil = latent_to_pil(Y[:,:12],5,3) |
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display(Y_pil[0]) |
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Y_pil[0].save('latent.webp',lossless=True) |
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webp = [Image.open("latent.webp")] |
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Y_rec = pil_to_latent(webp,16,5,3) |
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assert(Y_rec.equal(Y[:,:12])) |
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print("compression_ratio: ", (12/16)*x.numel()/os.path.getsize("latent.webp")) |
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``` |
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compression_ratio: 21.436712541190154 |
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### Four channel TIF (CMYK) |
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```python |
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Y_pil = latent_to_pil(Y,5,4) |
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display(Y_pil[0]) |
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Y_pil[0].save('latent.tif',compression="tiff_adobe_deflate") |
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tif = [Image.open("latent.tif")] |
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Y_rec = pil_to_latent(tif,16,5,4) |
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assert(Y_rec.equal(Y)) |
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print("compression_ratio: ", x.numel()/os.path.getsize("latent.png")) |
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``` |
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compression_ratio: 20.307596963280485 |
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```python |
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!jupyter nbconvert --to markdown README.ipynb |
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``` |
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[NbConvertApp] Converting notebook README.ipynb to markdown |
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[NbConvertApp] Support files will be in README_files/ |
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[NbConvertApp] Making directory README_files |
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[NbConvertApp] Writing 5002 bytes to README.md |
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```python |
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!sed -i 's|!\[png](README_files/\(README_[0-9]*_[0-9]*\.png\))||g' README.md |
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``` |
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