[ECCV'20] Fair DARTS: Eliminating Unfair Advantages in Differentiable Architecture Search

August 10, 2020 · View on GitHub

*: This is the official implementation of the FairDARTS paper.

Differentiable Architecture Search (DARTS) is now a widely disseminated weight-sharing neural architecture search method. However, there are two fundamental weaknesses remain untackled. First, we observe that the well-known aggregation of skip connections during optimization is caused by an unfair advantage in an exclusive competition. Second, there is a non-negligible incongruence when discretizing continuous architectural weights to a one-hot representation. Because of these two reasons, DARTS delivers a biased solution that might not even be suboptimal. In this paper, we present a novel approach to curing both frailties. Specifically, as unfair advantages in a pure exclusive competition easily induce a monopoly, we relax the choice of operations to be collaborative, where we let each operation have an equal opportunity to develop its strength. We thus call our method Fair DARTS. Moreover, we propose a zero-one loss to directly reduce the discretization gap. Experiments are performed on two mainstream search spaces, in which we achieve new state-of-the-art networks on ImageNet.

User Guide

Prerequisites

Python 3

pip install -r requirements.txt

The fairdarts folder includes our search, train and evaluation code. The darts folder consists of random and noise experiments on the original DARTS.

python train_search.py --aux_loss_weight 10 --learning_rate 0.005 --batch_size 128 --parse_method threshold_sparse --save 'EXP-lr_0005_alw_10'

Default batch-size is 128

Single Model Training

python train.py --auxiliary --cutout --arch FairDARTS_a --parse_method threshold --batch_size 128 --epoch 600

Single Model Evaluation

python evaluate_model.py  --arch FairDARTS_b --model_path ../best_model/FairDARTS-b.tar --parse_method threshold

Searched Architectures by FairDARTS

Note that we select architecture by barring with threshold σ, and |edge| <= 2 per node.

FairDARTS_a:

DCO_SPARSE_normal DCO_SPARSE_reduce

FairDARTS_b

DCO_SPARSE_3_normal DCO_SPARSE_3_reduce

FairDARTS_c

DCO_SPARSE_1_normal DCO_SPARSE_1_reduce

FairDARTS_d

DCO_SPARSE_2_normal DCO_SPARSE_2_reduce

FairDARTS_e

DCO_SPARSE_4_normal DCO_SPARSE_4_reduce

FairDARTS_f

DCO_SPARSE_5_normal DCO_SPARSE_5_reduce

FairDARTS_g

DCO_SPARSE_6_normal DCO_SPARSE_6_reduce

The isolated nodes (in gray) are ignored after parsing the genotypes.

Evaluation Results on CIFAR-10

Performance Stability

We run FairDARTS 7 times, all searched architectures have close performance.

ModelFlopsParamsPerformance
FairDARTS_a373M2.83M97.46
FairDARTS_b536M3.88M97.49
FairDARTS_c400M2.59M97.50
FairDARTS_d532M3.84M97.51
FairDARTS_e414M3.12M97.47
FairDARTS_f497M3.62M97.35
FairDARTS_g453M3.38M97.46
mean,var~457.85M~3.32M97.46±0.049

Note: We remove batch normalization for FLOPs' calculation in thop package. This is to follow status quo treamtment.

Comparison with Other State-of-the-art Results (CIFAR-10)

ModelFLOPsParamsBatch sizelrDPOptimizerPerformance
FairDARTS-a373M2.83960.0250.2SGD+CosineAnnealingLR97.46
FairDARTS-b536M3.88960.0250.2SGD+CosineAnnealingLR97.49
DARTS_V2522M3.36960.0250.2SGD+CosineAnnealingLR96.94*
PC-DARTS558M3.63960.0250.2SGD+CosineAnnealingLR97.31*
PDARTS532M3.43960.0250.2SGD+CosineAnnealingLR97.53*

*: Results obtained by training their published code.

Citation

@inproceedings{chu2019fairdarts,
    title={{Fair DARTS: Eliminating Unfair Advantages in Differentiable Architecture Search}},
    author={Chu, Xiangxiang and Zhou, Tianbao and Zhang, Bo and Li, Jixiang},
    booktitle={16th Europoean Conference On Computer Vision},
    url={https://arxiv.org/abs/1911.12126.pdf},
    year={2020}
}

Acknowledgement

This code is based on the implementation of DARTS.