# XNNPACK XNNPACK is a highly optimized library of floating-point neural network inference operators for ARM, WebAssembly, and x86 platforms. XNNPACK is not intended for direct use by deep learning practitioners and researchers; instead it provides low-level performance primitives for accelerating high-level machine learning frameworks, such as [TensorFlow Lite](https://www.tensorflow.org/lite), [TensorFlow.js](https://www.tensorflow.org/js), [PyTorch](https://pytorch.org/), and [MediaPipe](https://mediapipe.dev). ## Supported Architectures - ARM64 on Android, Linux, macOS, and iOS (including WatchOS and tvOS) - ARMv7 (with NEON) on Android, Linux, and iOS (including WatchOS) - x86 and x86-64 (up to AVX512) on Windows, Linux, macOS, Android, and iOS simulator - WebAssembly MVP - WebAssembly SIMD (experimental) ## Operator Coverage XNNPACK implements the following neural network operators: - 2D Convolution (including grouped and depthwise) - 2D Deconvolution (AKA Transposed Convolution) - 2D Average Pooling - 2D Max Pooling - 2D ArgMax Pooling (Max Pooling + indices) - 2D Unpooling - 2D Bilinear Resize - 2D Depth-to-Space (AKA Pixel Shuffle) - Add (including broadcasting, two inputs only) - Subtract (including broadcasting) - Divide (including broadcasting) - Maximum (including broadcasting) - Minimum (including broadcasting) - Multiply (including broadcasting) - Squared Difference (including broadcasting) - Global Average Pooling - Channel Shuffle - Fully Connected - Abs (absolute value) - Bankers' Rounding (rounding to nearest, ties to even) - Ceiling (rounding to integer above) - Clamp (includes ReLU and ReLU6) - Copy - ELU - Floor (rounding to integer below) - HardSwish - Leaky ReLU - Negate - Sigmoid - Softmax - Square - Truncation (rounding to integer towards zero) - PReLU All operators in XNNPACK support NHWC layout, but additionally allow custom stride along the **C**hannel dimension. Thus, operators can consume a subset of channels in the input tensor, and produce a subset of channels in the output tensor, providing a zero-cost Channel Split and Channel Concatenation operations. ## Performance ### Mobile phones The table below presents **single-threaded** performance of XNNPACK library on three generations of MobileNet models and three generations of Pixel phones. | Model | Pixel, ms | Pixel 2, ms | Pixel 3a, ms | | ------------------ | :-------: | :---------: | :----------: | | MobileNet v1 1.0X | 82 | 86 | 88 | | MobileNet v2 1.0X | 49 | 53 | 55 | | MobileNet v3 Large | 39 | 42 | 44 | | MobileNet v3 Small | 12 | 14 | 14 | The following table presents **multi-threaded** (using as many threads as there are big cores) performance of XNNPACK library on three generations of MobileNet models and three generations of Pixel phones. | Model | Pixel, ms | Pixel 2, ms | Pixel 3a, ms | | ------------------ | :-------: | :---------: | :----------: | | MobileNet v1 1.0X | 43 | 27 | 46 | | MobileNet v2 1.0X | 26 | 18 | 28 | | MobileNet v3 Large | 22 | 16 | 24 | | MobileNet v3 Small | 7 | 6 | 8 | Benchmarked on March 27, 2020 with `end2end_bench --benchmark_min_time=5` on an Android/ARM64 build with Android NDK r21 (`bazel build -c opt --config android_arm64 :end2end_bench`) and neural network models with randomized weights and inputs. ### Raspberry Pi The table below presents **multi-threaded** performance of XNNPACK library on three generations of MobileNet models and three generations of Raspberry Pi boards. | Model | RPi Zero W (BCM2835), ms | RPi 2 (BCM2836), ms | RPi 3+ (BCM2837B0), ms | RPi 4 (BCM2711), ms | | ------------------ | :----------------------: | :-----------------: | :--------------------: | :-----------------: | | MobileNet v1 1.0X | 4004 | 337 | 116 | 72 | | MobileNet v2 1.0X | 2011 | 195 | 83 | 41 | | MobileNet v3 Large | 1694 | 163 | 70 | 38 | | MobileNet v3 Small | 482 | 52 | 23 | 13 | Benchmarked on May 22, 2020 with `end2end-bench --benchmark_min_time=5` on a Raspbian Buster build with CMake (`./scripts/build-local.sh`) and neural network models with randomized weights and inputs. ## Publications - Marat Dukhan "The Indirect Convolution Algorithm". Presented on [Efficient Deep Learning for Compute Vision (ECV) 2019](https://sites.google.com/corp/view/ecv2019/) workshop ([slides](https://drive.google.com/file/d/1ZayB3By5ZxxQIRtN7UDq_JvPg1IYd3Ac/view), [paper on ArXiv](https://arxiv.org/abs/1907.02129)). - Erich Elsen, Marat Dukhan, Trevor Gale, Karen Simonyan "Fast Sparse ConvNets". [Paper on ArXiv](https://arxiv.org/abs/1911.09723), [pre-trained sparse models](https://github.com/google-research/google-research/tree/master/fastconvnets). - Marat Dukhan, Artsiom Ablavatski "The Two-Pass Softmax Algorithm". [Paper on ArXiv](https://arxiv.org/abs/2001.04438). - Yury Pisarchyk, Juhyun Lee "Efficient Memory Management for Deep Neural Net Inference". [Paper on ArXiv](https://arxiv.org/abs/2001.03288). ## Ecosystem ### Machine Learning Frameworks - [TensorFlow Lite](https://blog.tensorflow.org/2020/07/accelerating-tensorflow-lite-xnnpack-integration.html). - [TensorFlow.js WebAssembly backend](https://blog.tensorflow.org/2020/03/introducing-webassembly-backend-for-tensorflow-js.html). - [PyTorch Mobile](https://pytorch.org/mobile). - [MediaPipe for the Web](https://developers.googleblog.com/2020/01/mediapipe-on-web.html). - [Alibaba HALO (Heterogeneity-Aware Lowering and Optimization)](https://github.com/alibaba/heterogeneity-aware-lowering-and-optimization) - [Samsung ONE (On-device Neural Engine)](https://github.com/Samsung/ONE) ## Acknowledgements XNNPACK is a based on [QNNPACK](https://github.com/pytorch/QNNPACK) library. Over time its codebase diverged a lot, and XNNPACK API is no longer compatible with QNNPACK.