Neural network inference engine that delivers GPU-class performance for sparsified models on CPUs
Project description
DeepSparse
Neural network inference engine that delivers GPU-class performance for sparsified models on CPUs
Overview
The DeepSparse Engine is a CPU runtime that delivers GPU-class performance by taking advantage of sparsity (read more about sparsification here) within neural networks to reduce compute required as well as accelerate memory bound workloads. It is focused on model deployment and scaling machine learning pipelines, fitting seamlessly into your existing deployments as an inference backend.
The GitHub repository includes package APIs along with examples to quickly get started benchmarking and inferencing sparse models.
Highlights
Tutorials
Installation
This repository is tested on Python 3.6+, and ONNX 1.5.0+. It is recommended to install in a virtual environment to keep your system in order.
Install with pip using:
pip install deepsparse
Hardware Support
The DeepSparse Engine is validated to work on x86 Intel and AMD CPUs running Linux operating systems. Mac and Windows require running Linux in a Docker or virtual machine.
It is highly recommended to run on a CPU with AVX-512 instructions available for optimal algorithms to be enabled.
Here is a table detailing specific support for some algorithms over different microarchitectures:
x86 Extension | Microarchitectures | Activation Sparsity | Kernel Sparsity | Sparse Quantization |
---|---|---|---|---|
AMD AVX2 | Zen 2, Zen 3 | not supported | optimized | not supported |
Intel AVX2 | Haswell, Broadwell, and newer | not supported | optimized | not supported |
Intel AVX-512 | Skylake, Cannon Lake, and newer | optimized | optimized | emulated |
Intel AVX-512 VNNI (DL Boost) | Cascade Lake, Ice Lake, Cooper Lake, Tiger Lake | optimized | optimized | optimized |
Compatibility
The DeepSparse Engine ingests models in the ONNX format, allowing for compatibility with PyTorch, TensorFlow, Keras, and many other frameworks that support it. This reduces the extra work of preparing your trained model for inference to just one step of exporting.
Quick Tour
To expedite inference and benchmarking on real models, we include the sparsezoo
package.
SparseZoo hosts inference-optimized models, trained on repeatable sparsification recipes using state-of-the-art techniques from SparseML.
Quickstart with SparseZoo ONNX Models
ResNet-50 Dense
Here is how to quickly perform inference with DeepSparse Engine on a pre-trained dense ResNet-50 from SparseZoo.
from deepsparse import compile_model
from sparsezoo.models import classification
batch_size = 64
# Download model and compile as optimized executable for your machine
model = classification.resnet_50()
engine = compile_model(model, batch_size=batch_size)
# Fetch sample input and predict output using engine
inputs = model.data_inputs.sample_batch(batch_size=batch_size)
outputs, inference_time = engine.timed_run(inputs)
ResNet-50 Sparsified
When exploring available optimized models, you can use the Zoo.search_optimized_models
utility to find models that share a base.
Try this on the dense ResNet-50 to see what is available:
from sparsezoo import Zoo
from sparsezoo.models import classification
model = classification.resnet_50()
print(Zoo.search_sparse_models(model))
Output:
[
Model(stub=cv/classification/resnet_v1-50/pytorch/sparseml/imagenet/pruned-conservative),
Model(stub=cv/classification/resnet_v1-50/pytorch/sparseml/imagenet/pruned-moderate),
Model(stub=cv/classification/resnet_v1-50/pytorch/sparseml/imagenet/pruned_quant-moderate),
Model(stub=cv/classification/resnet_v1-50/pytorch/sparseml/imagenet-augmented/pruned_quant-aggressive)
]
We can see there are two pruned versions targeting FP32 and two pruned, quantized versions targeting INT8.
The conservative
, moderate
, and aggressive
tags recover to 100%, >=99%, and <99% of baseline accuracy respectively.
For a version of ResNet-50 that recovers close to the baseline and is very performant, choose the pruned_quant-moderate model. This model will run nearly 7x faster than the baseline model on a compatible CPU (with the VNNI instruction set enabled). For hardware compatibility, see the Hardware Support section.
from deepsparse import compile_model
import numpy
batch_size = 64
sample_inputs = [numpy.random.randn(batch_size, 3, 224, 224).astype(numpy.float32)]
# run baseline benchmarking
engine_base = compile_model(
model="zoo:cv/classification/resnet_v1-50/pytorch/sparseml/imagenet/base-none",
batch_size=batch_size,
)
benchmarks_base = engine_base.benchmark(sample_inputs)
print(benchmarks_base)
# run sparse benchmarking
engine_sparse = compile_model(
model="zoo:cv/classification/resnet_v1-50/pytorch/sparseml/imagenet/pruned_quant-moderate",
batch_size=batch_size,
)
if not engine_sparse.cpu_vnni:
print("WARNING: VNNI instructions not detected, quantization speedup not well supported")
benchmarks_sparse = engine_sparse.benchmark(sample_inputs)
print(benchmarks_sparse)
print(f"Speedup: {benchmarks_sparse.items_per_second / benchmarks_base.items_per_second:.2f}x")
Quickstart with Custom ONNX Models
We accept ONNX files for custom models, too. Simply plug in your model to compare performance with other solutions.
> wget https://github.com/onnx/models/raw/master/vision/classification/mobilenet/model/mobilenetv2-7.onnx
Saving to: ‘mobilenetv2-7.onnx’
from deepsparse import compile_model
from deepsparse.utils import generate_random_inputs
onnx_filepath = "mobilenetv2-7.onnx"
batch_size = 16
# Generate random sample input
inputs = generate_random_inputs(onnx_filepath, batch_size)
# Compile and run
engine = compile_model(onnx_filepath, batch_size)
outputs = engine.run(inputs)
Compatibility/Support Notes
- ONNX version 1.5-1.7
- ONNX opset version 11+
- ONNX IR version has not been tested at this time
For a more in-depth read on available APIs and workflows, check out the examples and DeepSparse Engine documentation.
Resources
Learning More
Release History
Official builds are hosted on PyPI
- stable: deepsparse
- nightly (dev): deepsparse-nightly
Additionally, more information can be found via GitHub Releases.
License
The project's binary containing the DeepSparse Engine is licensed under the Neural Magic Engine License.
Example files and scripts included in this repository are licensed under the Apache License Version 2.0 as noted.
Community
Contribute
We appreciate contributions to the code, examples, integrations, and documentation as well as bug reports and feature requests! Learn how here.
Join
For user help or questions about the DeepSparse Engine, sign up or log in: Deep Sparse Community Discourse Forum and/or Slack. We are growing the community member by member and happy to see you there.
You can get the latest news, webinar and event invites, research papers, and other ML Performance tidbits by subscribing to the Neural Magic community.
For more general questions about Neural Magic, please fill out this form.
Cite
Find this project useful in your research or other communications? Please consider citing:
@InProceedings{
pmlr-v119-kurtz20a,
title = {Inducing and Exploiting Activation Sparsity for Fast Inference on Deep Neural Networks},
author = {Kurtz, Mark and Kopinsky, Justin and Gelashvili, Rati and Matveev, Alexander and Carr, John and Goin, Michael and Leiserson, William and Moore, Sage and Nell, Bill and Shavit, Nir and Alistarh, Dan},
booktitle = {Proceedings of the 37th International Conference on Machine Learning},
pages = {5533--5543},
year = {2020},
editor = {Hal Daumé III and Aarti Singh},
volume = {119},
series = {Proceedings of Machine Learning Research},
address = {Virtual},
month = {13--18 Jul},
publisher = {PMLR},
pdf = {http://proceedings.mlr.press/v119/kurtz20a/kurtz20a.pdf},
url = {http://proceedings.mlr.press/v119/kurtz20a.html},
abstract = {Optimizing convolutional neural networks for fast inference has recently become an extremely active area of research. One of the go-to solutions in this context is weight pruning, which aims to reduce computational and memory footprint by removing large subsets of the connections in a neural network. Surprisingly, much less attention has been given to exploiting sparsity in the activation maps, which tend to be naturally sparse in many settings thanks to the structure of rectified linear (ReLU) activation functions. In this paper, we present an in-depth analysis of methods for maximizing the sparsity of the activations in a trained neural network, and show that, when coupled with an efficient sparse-input convolution algorithm, we can leverage this sparsity for significant performance gains. To induce highly sparse activation maps without accuracy loss, we introduce a new regularization technique, coupled with a new threshold-based sparsification method based on a parameterized activation function called Forced-Activation-Threshold Rectified Linear Unit (FATReLU). We examine the impact of our methods on popular image classification models, showing that most architectures can adapt to significantly sparser activation maps without any accuracy loss. Our second contribution is showing that these these compression gains can be translated into inference speedups: we provide a new algorithm to enable fast convolution operations over networks with sparse activations, and show that it can enable significant speedups for end-to-end inference on a range of popular models on the large-scale ImageNet image classification task on modern Intel CPUs, with little or no retraining cost.}
}
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