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About the Differentiable Architecture Search

The algorithm follows the idea proposed in DARTS: Differentiable Architecture Search by Hanxiao Liu, Karen Simonyan, Yiming Yang (https://arxiv.org/abs/1806.09055).

The implementation is based on official github implementation and popular repository.

The algorithm addresses the scalability challenge of architecture search by formulating the task in a differentiable manner. It is based on continuous relaxation and gradient descent in the search space. It is able to efficiently design high-performance convolutional architectures for image classification (on CIFAR-10 and ImageNet) and recurrent architectures for language modeling (on Penn Treebank and WikiText-2).

Katib implementation

To support DARTS in current Katib functionality the implementation follows this way:

  1. DARTS Suggestion service creates set of primitive operations from the Experiment search space. For example: ['separable_convolution_3x3', 'dilated_convolution_3x3', 'dilated_convolution_5x5', 'avg_pooling_3x3', 'max_pooling_3x3', 'skip_connection'].

  2. Suggestion returns algorithm settings, number of layers and set of primitives to Katib Controller

  3. Katib controller starts DARTS training container with appropriate settings and all possible operations.

  4. Training container runs DARTS algorithm.

  5. Metrics collector saves Best Genotype from the training container log.

DARTS Experiment example you can find here.

Best Genotype representation

Best Genotype is the best cell for each neural network layer. Cells are generated by DARTS algorithm. Here is an example of the Best Genotype:

Genotype(
  normal=[
      [('max_pooling_3x3',0),('max_pooling_3x3',1)],
      [('max_pooling_3x3',0),('max_pooling_3x3',1)],
      [('max_pooling_3x3',0),('dilated_convolution_3x3',3)],
      [('max_pooling_3x3',0),('max_pooling_3x3',1)]
    ],
    normal_concat=range(2,6),
  reduce=[
      [('dilated_convolution_5x5',1),('separable_convolution_3x3',0)],
      [('max_pooling_3x3',2),('dilated_convolution_5x5',1)],
      [('dilated_convolution_5x5',3),('dilated_convolution_5x5',2)],
      [('dilated_convolution_5x5',3),('dilated_convolution_5x5',4)]
    ],
    reduce_concat=range(2,6)
)

In this example you can see 4 DARTS nodes with indexes: 2,3,4,5.

reduce parameter is the cells which located at the 1/3 and 2/3 of the total neural network layers. They represent reduction cells in which all the operations adjacent to the input nodes are of stride two.

normal parameter is the cells which is located at the rest neural network layers. They represent normal cell.

In CNN all reduce and normal intermediate nodes are concatenated and each node has 2 edges.

Each element in normal array is the node which has 2 edges. First element is the operation on the edge and second element is the node index connection. Note that index 0 is the C_{k-2} node and index 1 is the C_{k-1} node.

For example [('max_pooling_3x3',0),('max_pooling_3x3',1)] means that C_{k-2} node connects to the first node with max_pooling_3x3 operation (Max Pooling with filter size 3) and C_{k-1} node connects to the first node with max_pooling_3x3 operation.

reduce array follows the same way as normal array.

normal_concat and reduce_concat means concatenation between intermediate nodes.

Currently, it supports running only on single GPU and second-order approximation, which produced better results than first-order.

TODO list

  • Integrate E2E test in CI. Create simple example, which can run on CPU.

  • Support multi GPU training. Add functionality to select GPU for training.

  • Support DARTS in Katib UI.

  • Think about better representation of Best Genotype.

  • Add more dataset for CNN. Currently, it supports only CIFAR-10.

  • Support RNN in addition to CNN.

  • Support micro mode, which means searching for a particular neural network cell.