Awesome
PipeDream: Pipeline Parallelism for DNN Training
This repository contains the source code implementation of the following papers:
- "PipeDream: Generalized Pipeline Parallelism for DNN Training",
which appeared at SOSP 2019 (
pipedream
branch). - "Memory-Efficient Pipeline-Parallel DNN Training",
which appeared at ICML 2021 (
pipedream_2bw
branch).
This work was one as part of Microsoft Research's Project Fiddle. This source code is available under the MIT License.
Directory Structure
graph
This contains a Python implementation of a graph, used by the PipeDream profiler
and optimizer. Profiling scripts in profiler
generate graph profiles, that can
then be ingested by the optimizer located in optimizer
to generate a partitioned
model, that can then be fed to the PipeDream runtime.
profiler
Instrumented PyTorch applications which return profiles that can be ingested by the optimizer.
optimizer
A Python implementation of PipeDream's optimizer.
runtime
PipeDream's runtime, which implements model parallelism, as well as input pipelining in PyTorch. This can be fused with data parallelism to give hybrid model and data parallelism, and input pipelining.
Setup
Software Dependencies
To run PipeDream, you will need a NVIDIA GPU with CUDA 10.0, GPU driver version 418.56, nvidia-docker2, and Python 3. On a Linux server with NVIDIA GPU(s) and Ubuntu 16.04, these dependencies can be installed using,
bash setup.sh
All dependencies are in the nvcr.io/nvidia/pytorch:19.05-py3 container, which can be downloaded using,
nvidia-docker pull nvcr.io/nvidia/pytorch:19.05-py3
To run the PipeDream profiler, you will need to build a new Docker image, which can be done using the
Dockerfile in this directory. Note that the Dockerfile has a dependency on the pre_hook.patch
and
requirements.txt
files in this directory. This container can be built using,
docker build --tag <CONTAINER_NAME> .
The PyTorch Docker Container can then be run using,
nvidia-docker run -it -v /mnt:/mnt --ipc=host --net=host <CONTAINER_NAME> /bin/bash
Data
Image Classification
All image classification experiments are run using the ImageNet ILSVC 2012 dataset. This can be downloaded using the following command (within the docker container above),
cd scripts; python download_imagenet.py --data_dir <DATASET_DIR>
Note that the ImageNet dataset is about 145GB, so this download script can take some time.
Translation
All translation experiments are run using the WMT En-De dataset, also used for the MLPerf translation (RNN) task. This can be downloaded using the instructions in the MLPerf repository.
End-to-end Workflow
To run a demo, run the following commands (the optimizer and runtime have been verified to work unchanged in nvcr.io/nvidia/pytorch:19.05-py3
).
More detailed instructions for each of the individual components are in the corresponding directory READMEs,
and more detailed instructions on how to run the main experiments in the SOSP paper are in EXPERIMENTS.md
.
[from pipedream/profiler/image_classification
; you will need to have the changes to PyTorch listed above]
Note that the profiling step must be run with only a single GPU (hence the CUDA_VISIBLE_DEVICES=0
before the command).
CUDA_VISIBLE_DEVICES=0 python main.py -a vgg16 -b 64 --data_dir <path to ImageNet directory>
[from pipedream/optimizer
]
python optimizer_graph_hierarchical.py -f ../profiler/image_classification/profiles/vgg16/graph.txt -n 4 --activation_compression_ratio 1 -o vgg16_partitioned
[from pipedream/optimizer
]
python convert_graph_to_model.py -f vgg16_partitioned/gpus=4.txt -n VGG16Partitioned -a vgg16 -o ../runtime/image_classification/models/vgg16/gpus=4 --stage_to_num_ranks 0:3,1:1
[from pipedream/runtime/image_classification
; run on 4 GPUs (including a single server with 4 GPUs)]
python main_with_runtime.py --module models.vgg16.gpus=4 -b 64 --data_dir <path to ImageNet> --rank 0 --local_rank 0 --master_addr <master IP address> --config_path models/vgg16/gpus=4/hybrid_conf.json --distributed_backend gloo
python main_with_runtime.py --module models.vgg16.gpus=4 -b 64 --data_dir <path to ImageNet> --rank 1 --local_rank 1 --master_addr <master IP address> --config_path models/vgg16/gpus=4/hybrid_conf.json --distributed_backend gloo
python main_with_runtime.py --module models.vgg16.gpus=4 -b 64 --data_dir <path to ImageNet> --rank 2 --local_rank 2 --master_addr <master IP address> --config_path models/vgg16/gpus=4/hybrid_conf.json --distributed_backend gloo
python main_with_runtime.py --module models.vgg16.gpus=4 -b 64 --data_dir <path to ImageNet> --rank 3 --local_rank 3 --master_addr <master IP address> --config_path models/vgg16/gpus=4/hybrid_conf.json --distributed_backend gloo
master IP address
here is the IP address of the rank 0 process. On a server with 4 GPUs, localhost
can be specified.
When running DP setups, please use the nccl
backend for optimal performance. When running hybrid setups, please use
the gloo
backend.
Code of Conduct
This project has adopted the Microsoft Open Source Code of Conduct. For more information see the Code of Conduct FAQ or contact opencode@microsoft.com with any additional questions or comments.
License
Copyright (c) Microsoft Corporation. All rights reserved.
Licensed under the MIT license.