Update dataset

b23ae36 verified 2 months ago

No virus

8.39 kB

	---
	license: mit
	datasets:
	- imagenet-1k-blurred
	pipeline_tag: image-classification
	tags:
	- sparsity
	- vision-transformer
	- pytorch
	library_name: torchvision
	metrics:
	- accuracy
	---
	# SuperBlock

	SuperBlock combines two techniques for efficient neural network training and inference: Supermask and Block Compressed Sparse Row (BSR)

	### Supermask
	[Supermask](https://arxiv.org/abs/2207.00670) is a technique for applying structured sparsity to neural networks using a learned mask. It works by learning a continuous mask (scores) that is applied element-wise to the weights of a neural network layer. The mask scores are learned separately from the weights and are thresholded based on a target sparsity level to obtain a binary mask. The mask determines which weigths are kept and which are pruned, and is learned during training.

	During inference, the binary mask is applied element-wise to the weights, pruning the weights that correspond to a 0 in the mask, resulting in a sparse network that can be efficiently computed.

	### Block compressed Sparse Row Format (BSR)
	[The BSR format](https://pytorch.org/docs/main/sparse.html#sparse-bsr-tensor) is a sparse matrix representation that stores dense sub-blocks of non-zero elements instead of individual non-zero elements. The matrix is divided into equal-sized blocks, and only the non-zero blocks are stored.

	The BSR format is efficient for sparse matrices with a block structure, where non-zero elements tend to cluster in dense sub-blocks. It reduces storage requirements and enables efficient matrix operations on the non-zero blocks.

	Currently, the BSR format is optimized for Nvidia A100 GPU(s) only.

	## Setup
	To use SuperBlock, you will need
	* [PyTorch](https://pytorch.org/get-started/locally/)

	To train the model or evaluate accuracy, you will need:
	* ImageNet2012-blurred dataset

	At least one GPU:
	* A100 or H100

	## Installation
	* Clone this repo
	```
	git clone https://github.com/pytorch-labs/superblock.git
	cd superblock
	```
	* Create a new conda environment
	```
	conda create -n superblock
	conda activate superblock
	```
	* Install PyTorch. For best performance, we recommend `2.3.0.dev20240305+cu121` nightly
	```
	pip install --pre torch==2.3.0.dev20240305+cu121 --index-url https://download.pytorch.org/whl/nightly/cu121
	pip install --pre torchvision==0.18.0 --no-deps
	```


	## Benchmarking
	Baseline:
	```
	python benchmark.py \
	--model vit_b_16 \
	--batch-size 256 \
	> /dev/null
	```
	Result:
	```
	532.1160546875 ms
	```


	80% sparsity, block size 64 (random weights):
	```
	python benchmark.py --model vit_b_16 \
	--batch-size 256 \
	--sparsity-linear 0.8 \
	--sp-linear-tile-size 64 \
	--sparsify-weights \
	--bsr 64 \
	> /dev/null
	```
	Result:
	```
	393.864453125 ms
	```


	## Training
	Please refer to [TRAINING.md](TRAINING.md) for training from scratch. We use [Torchvision](https://github.com/pytorch/vision/tree/main/references/classification) as our framework for training. Supermask can be applied during training.

	To apply supermask, we have the following arguments at our disposal,

	* Apply Supermask to linear layers:
	```
	--sparsity-linear
	--sp-linear-tile-size
	```
	* Apply Supermask to conv1x1 layers:
	```
	--sparsity-conv1x1
	--sp-conv1x1-tile-size
	```
	* Apply Supermask to all other convolutional layers:
	```
	--sparsity-conv
	--sp-conv-tile-size
	```
	* Skip the first transformer layer and/or last linear layer (ViT only):
	```
	--skip-last-layer-sparsity
	--skip-first-transformer-sparsity
	```

	For example, if you would like to train a `vit_b_16` from scratch using Supermask, you can use the respective torchvision command found in [TRAINING.md](TRAINING.md) and append the supermask arguments:
	```
	torchrun --nproc_per_node=8 train.py\
	--model vit_b_16 --epochs 300 --batch-size 512 --opt adamw --lr 0.003 --wd 0.3\
	--lr-scheduler cosineannealinglr --lr-warmup-method linear --lr-warmup-epochs 30\
	--lr-warmup-decay 0.033 --amp --label-smoothing 0.11 --mixup-alpha 0.2 --auto-augment ra\
	--clip-grad-norm 1 --ra-sampler --cutmix-alpha 1.0 --model-ema\
	--sparsity-linear 0.9 --sp-linear-tile-size 32
	```
	Through this command, we are training a `vit_b_16` with 90% sparsity to linear layers using 32x32 tiles.

	Please run `python train.py --help` for a full list of available arguments.

	## Evaluation

	To run an evaluation of a Supermask-trained model, you can use [evaluate.py](evaluate.py). Our current version has signficant speedup with float32 only and not float16, hence, to illustrate speedup, we don't pass `--amp` in the example commands below.

	```
	MODEL_PATH=<put the path of the trained checkpoint here>
	IMAGENET_PATH=<put the path of ImageNet dataset here>
	NGPUS=1 # put number of available GPUS here
	```

	* Offline sparsification with BSR:
	```
	torchrun --nproc_per_node=${NGPUS} evaluate.py --model vit_b_16 --batch-size 256 --sparsity-linear 0.9 --sp-linear-tile-size 32 --weights-path ${MODEL_PATH} --data-path ${IMAGENET_PATH} --sparsify-weights --bsr 32
	```
	This command applies 90% sparsity to linear layers using 32x32 tiles, loads the model weights from ${MODEL_PATH}, loads the ImageNet validation set located at the specified path, applies offline sparsification to the weights, and converts the sparse weights to BSR format with a block size of 32. It is recommended to set `--bsr` the same as tile size.

	* Online sparsification without BSR:
	```
	torchrun --nproc_per_node=${NGPUS} evaluate.py --model vit_b_16 --batch-size 256 --sparsity-linear 0.9 --sp-linear-tile-size 32 --weights-path ${MODEL_PATH} --data-path ${IMAGENET_PATH}
	```
	This is similar to the previous command, but it does not apply offline sparsification or BSR conversion. Instead, the sparsity is applied on-the-fly during evaluation.

	Please run `python evaluate.py --help` for a full list of available arguments.

	Results (1x A100):
	* Baseline
	```
	Test: Total time: 0:02:11
	Test: Acc@1 78.392 Acc@5 93.592
	```

	* Sparsity= 0.9, Tile Size = 32, Online Sparsification, BSR = None
	```
	Test: Total time: 0:01:52
	Test: Acc@1 76.092 Acc@5 92.656
	```

	* Sparsity= 0.9, Tile Size = 32, Offline Sparsification, BSR = None
	```
	Test: Total time: 0:01:54
	Test: Acc@1 76.092 Acc@5 92.656
	```

	* Sparsity= 0.9, Tile Size = 32, Offline Sparsification, BSR = 32
	```
	Test: Total time: 0:01:25
	Test: Acc@1 76.092 Acc@5 92.656
	```

	## Pretrained Weights

	### Download:
	Instead of training from scratch, if you'd like to use the Supermask weights of `vit_b_16` trained on privacy mitigated Imagenet-blurred, you can download them here:
	```
	SPARSITY=0.80 # Checkpoints available for: 0.70, 0.80, 0.82, 0.84, 0.86, 0.88, 0.90
	BLOCK_SIZE=32 # Checkpoints available for: 16, 32, 64
	```

	```
	mkdir checkpoints
	# For baseline,
	wget https://huggingface.co/facebook/superblock-vit-b-16/resolve/main/checkpoints/baseline.pth -P checkpoints/
	# For sparsified checkpoints,
	wget https://huggingface.co/facebook/superblock-vit-b-16/resolve/main/checkpoints/sp${SPARSITY}-ts${BLOCK_SIZE}.pth -P checkpoints/
	```

	### Benchmark:
	```
	python benchmark.py --model vit_b_16 \
	--batch-size 256 \
	--sparsity-linear ${SPARSITY} \
	--sp-linear-tile-size ${BLOCK_SIZE} \
	--sparsify-weights \
	--bsr ${BLOCK_SIZE} \
	--weights-path ./checkpoints/superblock-vit-b-16-sp${SPARSITY}-ts${BLOCK_SIZE}.pth \
	> /dev/null
	```
	Result:
	```
	530.342578125 ms
	```

	### Evaluate:
	8 x A100 GPUs:
	```
	torchrun --nproc_per_node=8 evaluate.py --model vit_b_16 --batch-size 256 --sparsity-linear ${SPARSITY} --sp-linear-tile-size ${BLOCK_SIZE} --bsr ${BLOCK_SIZE} --sparsify-weights --weights-path checkpoints/superblock-vit-b-16-sp${SPARSITY}-ts${BLOCK_SIZE}.pth --data-path ${IMAGENET_PATH}
	```
	Result:
	```
	Test: Total time: 0:01:01
	Test: Acc@1 77.644 Acc@5 93.554
	```

	1 x A100 GPUs:
	```
	torchrun --nproc_per_node=1 evaluate.py --model vit_b_16 --batch-size 256 --sparsity-linear ${SPARSITY} --sp-linear-tile-size ${BLOCK_SIZE} --bsr ${BLOCK_SIZE} --sparsify-weights --weights-path checkpoints/superblock-vit-b-16-sp${SPARSITY}-ts${BLOCK_SIZE}.pth --data-path ${IMAGENET_PATH}
	```
	Result:
	```
	Test: Total time: 0:01:51
	Test: Acc@1 77.644 Acc@5 93.554
	```

	## License
	SuperBlock is released under the [MIT license](https://github.com/pytorch-labs/superblock?tab=MIT-1-ov-file#readme).