The NVIDIA Data Loading Library (DALI) is a library for data loading and pre-processing to accelerate deep learning applications. It provides a collection of highly optimized building blocks for loading and processing image, video and audio data. It can be used as a portable drop-in replacement for built in data loaders and data iterators in popular deep learning frameworks.
Deep learning applications require complex, multi-stage data processing pipelines that include loading, decoding, cropping, resizing, and many other augmentations. These data processing pipelines, which are currently executed on the CPU, have become a bottleneck, limiting the performance and scalability of training and inference.
DALI addresses the problem of the CPU bottleneck by offloading data preprocessing to the GPU. Additionally, DALI relies on its own execution engine, built to maximize the throughput of the input pipeline. Features such as prefetching, parallel execution, and batch processing are handled transparently for the user.
In addition, the deep learning frameworks have multiple data pre-processing implementations, resulting in challenges such as portability of training and inference workflows, and code maintainability. Data processing pipelines implemented using DALI are portable because they can easily be retargeted to TensorFlow, PyTorch, MXNet and PaddlePaddle.
DALI in action:
from nvidia.dali.pipeline import pipeline_def import nvidia.dali.types as types import nvidia.dali.fn as fn from nvidia.dali.plugin.pytorch import DALIGenericIterator import os # To run with different data, see documentation of nvidia.dali.fn.readers.file # points to https://github.com/NVIDIA/DALI_extra data_root_dir = os.environ['DALI_EXTRA_PATH'] images_dir = os.path.join(data_root_dir, 'db', 'single', 'jpeg') def loss_func(pred, y): pass def model(x): pass def backward(loss, model): pass @pipeline_def(num_threads=4, device_id=0) def get_dali_pipeline(): images, labels = fn.readers.file( file_root=images_dir, random_shuffle=True, name="Reader") # decode data on the GPU images = fn.decoders.image_random_crop( images, device="mixed", output_type=types.RGB) # the rest of processing happens on the GPU as well images = fn.resize(images, resize_x=256, resize_y=256) images = fn.crop_mirror_normalize( images, crop_h=224, crop_w=224, mean=[0.485 * 255, 0.456 * 255, 0.406 * 255], std=[0.229 * 255, 0.224 * 255, 0.225 * 255], mirror=fn.random.coin_flip()) return images, labels train_data = DALIGenericIterator( [get_dali_pipeline(batch_size=16)], ['data', 'label'], reader_name='Reader' ) for i, data in enumerate(train_data): x, y = data[0]['data'], data[0]['label'] pred = model(x) loss = loss_func(pred, y) backward(loss, model)
- Easy-to-use functional style Python API.
- Multiple data formats support - LMDB, RecordIO, TFRecord, COCO, JPEG, JPEG 2000, WAV, FLAC, OGG, H.264, VP9 and HEVC.
- Portable across popular deep learning frameworks: TensorFlow, PyTorch, MXNet, PaddlePaddle.
- Supports CPU and GPU execution.
- Scalable across multiple GPUs.
- Flexible graphs let developers create custom pipelines.
- Extensible for user-specific needs with custom operators.
- Accelerates image classification (ResNet-50), object detection (SSD) workloads as well as ASR models (Jasper, RNN-T).
- Allows direct data path between storage and GPU memory with GPUDirect Storage.
- Easy integration with NVIDIA Triton Inference Server with DALI TRITON Backend.
- Open source.
The following issue represents a high-level overview of our 2022 plan. You should be aware that this roadmap may change at any time and the order below does not reflect any type of priority.
We strongly encourage you to comment on our roadmap and provide us feedback on the mentioned GitHub issue.
To install the latest DALI release for the latest CUDA version (11.x):
pip install --extra-index-url https://developer.download.nvidia.com/compute/redist --upgrade nvidia-dali-cuda110
DALI comes preinstalled in the TensorFlow, PyTorch, and MXNet containers on NVIDIA GPU Cloud (versions 18.07 and later).
For other installation paths (TensorFlow plugin, older CUDA version, nightly and weekly builds, etc), please refer to the Installation Guide.
To build DALI from source, please refer to the Compilation Guide.
An introduction to DALI can be found in the Getting Started page.
More advanced examples can be found in the Examples and Tutorials page.
For an interactive version (Jupyter notebook) of the examples, go to the docs/examples directory.
Note: Select the Latest Release Documentation or the Nightly Release Documentation, which stays in sync with the main branch, depending on your version.
- GPU Technology Conference 2022; Effective NVIDIA DALI: Accelerating Real-life Deep-learning Applications; Rafał Banaś: event.
- GPU Technology Conference 2022; Introduction to NVIDIA DALI: GPU-accelerated Data Preprocessing; Joaquin Anton Guirao: event.
- GPU Technology Conference 2021; NVIDIA DALI: GPU-Powered Data Preprocessing by Krzysztof Łęcki and Michał Szołucha: event.
- GPU Technology Conference 2020; Fast Data Pre-Processing with NVIDIA Data Loading Library (DALI); Albert Wolant, Joaquin Anton Guirao recording.
- GPU Technology Conference 2019; Fast AI data pre-preprocessing with DALI; Janusz Lisiecki, Michał Zientkiewicz: slides, recording.
- GPU Technology Conference 2019; Integration of DALI with TensorRT on Xavier; Josh Park and Anurag Dixit: slides, recording.
- GPU Technology Conference 2018; Fast data pipeline for deep learning training, T. Gale, S. Layton and P. Trędak: slides, recording.
- Developer Page.
- Blog Posts.
We welcome contributions to DALI. To contribute to DALI and make pull requests, follow the guidelines outlined in the Contributing document.
If you are looking for a task good for the start please check one from external contribution welcome label.
We appreciate feedback, questions or bug reports. When you need help with the code, follow the process outlined in the Stack Overflow https://stackoverflow.com/help/mcve document. Ensure that the posted examples are:
- minimal: Use as little code as possible that still produces the same problem.
- complete: Provide all parts needed to reproduce the problem. Check if you can strip external dependency and still show the problem. The less time we spend on reproducing the problems, the more time we can dedicate to the fixes.
- verifiable: Test the code you are about to provide, to make sure that it reproduces the problem. Remove all other problems that are not related to your request.
DALI was originally built with major contributions from Trevor Gale, Przemek Tredak, Simon Layton, Andrei Ivanov and Serge Panev.