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Checking the divisibility of neural networks, and investigating the nature of the pieces networks can be divided into.

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nn-clustering-pytorch

Checking the divisibility of neural networks, and investigating the nature of the pieces networks can be divided into.

NOTE: this code is still under active development. Use at your own peril.

Things this codebase can do:

  • Train a neural network using gradient descent and pruning. The neural network can have convolutions, fully-connected layers, batch norm, dropout, and max pooling, as long as it uses only ReLU activations. This is done in src/train_model.py.
  • Turn such a neural network into a graph and apply graph clustering to it. This is done in src/spectral_cluster_model.py.
  • Compare the clusterability of a model to that of random shuffles of the model's weights. This is done in src/shuffle_and_cluster.py.
  • Regularize graph-clusterability during training, while normalizing weights. This is done in src/clusterability_gradient.py and src/train_model.py. Note: high values of the regularization weight might cause networks to lose connection between their inputs and outputs. I advise using values between 1e-4 and 1e-1.

After cloning, enter the pipenv by running pipenv shell. To install dependencies:

  • if you don't want to contribute to development, just run pipenv install.
  • if you do want to contribute to development, install dependencies by running pipenv install -d, then install pre-commit hooks for yapf, isort, and flake8 by running pre-commit install.

You should also probably create directories where results will be saved: datasets, models, training_runs, clustering_runs, and shuffle_clust_runs.

This codebase uses sacred extensively, which you can read about here.

NB: the codebase assumes that networks are defined in a very specific way. The operations must be grouped either into ModuleDicts (see this pytorch doc page) or nn.Sequential modules.

For ModuleDicts:

  • One ModuleDict should be used per layer.
  • Batch norm modules must be in the ModuleDict of the linear transform they come after.
  • Within a ModuleDict, fully connected modules should be have the key 'fc', convolutional modules should have the key 'conv', and batch norm modules should have the key 'bn'. Nothing else should have those keys.
  • ModuleDicts can't contain both a convolutional and a fully connected module.

For Sequential modules:

  • Sequential modules should be formed by taking in an ordered dict, where keys are names of operations and values are modules.
  • The keys of the ordered dict should be formatted <name of layer>_<name of module>, e.g. 0_fc, 5_conv, layer6_relu. Rules for names of modules are as for ModuleDicts.
  • One layer should contain at most one fully-connected or convolutional module.

In both cases, there can only be one batch norm module between two linear transformations. For examples of networks that meet these specifications, see src/networks.py.

TODOs:

  • Refactor code so that ablation_accuracy and compare_masks_clusters share functions
  • Docstrings in compare_masks_clusters
  • Move dataset stuff to its own separate file

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Checking the divisibility of neural networks, and investigating the nature of the pieces networks can be divided into.

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