(DL)² - A Deep Learning Data Loading Analysis Sandbox

This repository contains the source code, experiment logs, and result analyses for our ICDE 2023 paper "The Art of Losing to Win: Using Lossy Image Compression to Improve Data Loading in Deep Learning Pipelines". A preprint of the paper is available at [1].

(DL)² is an experiment sandbox that we built for our research.

Requirements

(DL)² is developed on Ubuntu using NVIDIA GPUs and the following software:

• Python 3.8
• CUDA 10.2 and CUDA 11.1, depending on the GPU
• PyTorch 1.9

PyTorch 1.9 is necessary due to suboptimal performance on NVIDIA Ampere GPUs of previous releases (see [2]). For other libraries used in this project, please see the respective requirements files for CUDA 10 and CUDA 11.

Note: The requirements files only cover requirements to execute experiments and gather log data. To run the analysis notebooks, a common Jupyter setup with numpy, pandas, and matplotlib is required. To generate plots in the same format as they appear in the paper, a LaTeX installation is necessary as well. To analyze image quality with the analyze_image_dataset script, magick must be installed and accessible on your $PATH.

Setup

Clone the repository to your machine and export its location as an environment variable.

git clone https://github.com/lbhm/dl2.git
export DL2_HOME=$(pwd)/dl2

We recommend that you either directly copy or symlink your benchmark datasets in a data/ directory at the top-level of this repo.

ln -s <path_to_your_data> $DL2_HOME/data

As we compare different storage types in the paper, we created multiple data-x/ directories with x referring to the storage type.

Installation

You can run the experiments in a Docker container or directly on your system.

Docker Installation

Switch to the docker/ directory and build the docker image.

cd docker
make build

The docker container uses CUDA 11.1.

Native Installation

We recommend creating a virtual environment and installing the required packages into that environment.

virtualenv venv
source venv/bin/activate
pip install -r requirements_cuda11.txt

Execution

The main user interface of (DL)² is the dl2/main.py script. To get an overview of possible parameters and their usage, run

python dl2/main.py -h

Other scripts and helper tools all have a CLI documentation available via -h.

Docker Execution

We provide a convenience script called run_docker.sh that starts a docker container with some sensible runtime parameters set. Start the container by running

run_docker.sh

This will start a bash shell in which you can run experiments such as

python dl2/main.py -d <path_to_data> -a resnet50 -l dali-cpu -w 8 -b 256 -e 50 \
    -p 100 --label-smoothing 0.1 --lr 0.256 --lr-policy cosine --mom 0.875 \
    --wd 3.0517578125e-05 --amp --static-loss-scale 128 --memory-format nhwc \
    -n docker-test

Alternatively, you can directly pass your command to the run_docker.sh script:

run_docker.sh python <command>

Native Execution

To execute code directly on your system, run the dl2/main.py script. For example:

python dl2/main.py -d <path_to_data> -a resnet50 -l dali-cpu -w 8 -b 256 -e 50 \
    -p 100 --label-smoothing 0.1 --lr 0.256 --lr-policy cosine --mom 0.875 \
    --wd 3.0517578125e-05 --amp --static-loss-scale 128 --memory-format nhwc \
    -n native-test

To run an experiment with multple GPUs or in a distributed setup, prepend your command with the torch.distributed.run module. For example:

python -m torch.distributed.run --nproc_per_node 4 dl2/main.py <args>

Logs, Notebooks, and Plots

Experiment logs for all results that we report in the paper are in logs/. The logs are organized by the correponding hypothesis that we invetigate in the paper. The experiment names, such as inet-alex-ssd-raw-pytorch, encode important parameters of the respective experiment. The full list of parameters is always logged in the first line of each experiment_report.json file. In addition to the experiment logs, logs/misc/ contains some additional summary plots about the datasets we used.

Note: Some of the experiment folders in h5/ (learned compression) are empty since the experiments did not finish within their time limit as we describe in the paper.

The notebooks/ directory contains the Jupyter notebooks that we used for analyzing the experiment results and creating the plots in our paper. All files in plots/ can be recreated by running the respective notebooks.

Note: A matplotlib-compatible TeX installation is required to recreate the plots as they appear in our paper. Alternatively, with the DEBUG flag set to True, the plots can be recreated without TeX though with a different layout.

Reproducibility

To reproduce the results from our paper, execute the instructions provided in scripts/command_list.sh. The commands assume a server infrastructure as we describe in our paper and refer to three data folders (data-ssd, data-hdd, and data-sas) that link to disks of the respective type.

Note: The command list was not designed to be executed in a fully automatic way so please read the comments. For example, we cannot provide a copy of the datasets that we use. To acquire a copy of ImageNet and Places365, please see the download instrcutions at [3] and [4].

Warning: Executing all the commands will take a very long time.

Citation

@inproceedings{behme_art_2023,
  title        = {
    The Art of Losing to Win: Using Lossy Image Compression to Improve Data Loading in
    Deep Learning Pipelines
  },
  author       = {
    Behme, Lennart and Thirumuruganathan, Saravanan and Mahdiraji, Alireza Rezaei and
    Quian\'{e}-Ruiz, Jorge-Arnulfo and Markl, Volker
  },
  year         = 2023,
  booktitle    = {{IEEE} 39th International Conference on Data Engineering ({ICDE})},
  address      = {Anaheim, CA, USA},
  pages        = {936--949},
  doi          = {10.1109/ICDE55515.2023.00077},
  eventtitle   = {{ICDE} '23}
}

References

• [1] https://lbeh.me/pdf/The_Art_of_Losing_to_Win.pdf
• [2] pytorch/pytorch#60434
• [3] https://image-net.org/download.php
• [4] http://places2.csail.mit.edu/download.html