For practical deep neural network design on mobile devices, it is essential to consider the constraints incurred by the computational resources and the inference latency in various applications. Among deep network acceleration related approaches, pruning is a widely adopted practice to balance the computational resource consumption and the accuracy, where unimportant connections can be removed either channel-wisely or randomly with a minimal impact on model accuracy. The channel pruning instantly results in a significant latency reduction, while the random weight pruning is more flexible to balance the latency and accuracy. In this paper, we present a unified framework with Joint Channel pruning and Weight pruning (JCW), and achieves a better Pareto-frontier between the latency and accuracy than previous model compression approaches. To fully optimize the trade-off between the latency and accuracy, we develop a tailored multi-objective evolutionary algorithm in the JCW framework, which enables one single search to obtain the optimal candidate architectures for various deployment requirements. Extensive experiments demonstrate that the JCW achieves a better trade-off between the latency and accuracy against various state-of-the-art pruning methods on the ImageNet classification dataset.
| Method | Latency/ms | Accuracy |
|---|---|---|
| Uniform 1x | 537 | 69.8 |
| DMCP | 341 | 69.7 |
| APS | 363 | 70.3 |
| JCW | 160 | 69.2 |
| 194 | 69.7 | |
| 196 | 69.9 | |
| 224 | 70.2 |
| Method | Latency/ms | Accuracy |
|---|---|---|
| Uniform 1x | 167 | 70.9 |
| Uniform 0.75x | 102 | 68.4 |
| Uniform 0.5x | 53 | 64.4 |
| AMC | 94 | 70.7 |
| Fast | 61 | 68.4 |
| AutoSlim | 99 | 71.5 |
| AutoSlim | 55 | 67.9 |
| USNet | 102 | 69.5 |
| USNet | 53 | 64.2 |
| JCW | 31 | 69.1 |
| 39 | 69.9 | |
| 43 | 69.8 | |
| 54 | 70.3 | |
| 69 | 71.4 |
| Method | Latency/ms | Accuracy |
|---|---|---|
| Uniform 1x | 114 | 71.8 |
| Uniform 0.75x | 71 | 69.8 |
| Uniform 0.5x | 41 | 65.4 |
| APS | 110 | 72.8 |
| APS | 64 | 69.0 |
| DMCP | 83 | 72.4 |
| DMCP | 45 | 67.0 |
| DMCP | 43 | 66.1 |
| Fast | 89 | 72.0 |
| Fast | 62 | 70.2 |
| JCW | 30 | 69.1 |
| 40 | 69.9 | |
| 44 | 70.8 | |
| 59 | 72.2 |
- torch
- torchvision
- numpy
- scipy
The JCW works in a two-step fashion. i.e. the search step and the training step. The search step seaches for the layer-wise channel numbers and weight sparsity for Pareto-optimal models. The training steps trains the searched models with ADMM. We give a simple example for resnet18.
-
Modify the configuration file
First, open the file
experiments/res18-search.yaml:vim experiments/res18-search.yaml
Go to the 44th line and find the following codes:
DATASET: data: ImageNet root: /path/to/imagenet ...and modify the
rootproperty ofDATASETto the path of ImageNet dataset on your machine. -
Apply the search
After modifying the configuration file, you can simply start the search by:
python emo_search.py --config experiments/res18-search.yaml | tee experiments/res18-search.logAfter searching, the search results will be saved in
experiments/search.pth
After searching, we can train the searched models by:
-
Modify the base configuration file
Open the file
experiments/res18-train.yaml:vim experiments/res18-train.yaml
Go to the 5th line, find the following codes:
root: &root /path/to/imagenetand modify the root property to the path of ImageNet dataset on your machine.
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Generate configuration files for training
After modifying the base configuration file, we are ready to generate the configuration files for training. To do that, simply run the following command:
python scripts/generate_training_configs.py --base-config experiments/res18-train.yaml --search-result experiments/search.pth --output ./train-configs
After running the above command, the training configuration files will be written into ./train-configs/model-{id}/train.yaml.
-
Apply the training
After generating the configuration files, simply run the following command to train one certain model:
python train.py --config xxxx/xxx/train.yaml | tee xxx/xxx/train.log