This repository contains an implementation of TriScale, a framework supporting reproducible performance evaluations in networking.
TriScale is described in details in the following paper
Designing Replicable Networking Experiments with TriScale
Romain Jacob, Marco Zimmerling, Carlo Alberto Boano, Laurent Vanbever, Lothar Thiele
(under submission), 2021.
doi.org/10.5281/zenodo.3464273
Check out the project webpage for more info:
http://triscale.ethz.ch/
TriScale source code is split in the following files
triscale.py
Implements the main functions of TriScale (the public API).helpers.py
Additional support functions for running the TriScale analysis.triplots.py
Plotting functions used in TriScale. All plots are created using Plotly.
This repository contains all the necessary code and information to reproduce the results analysis and plots presented in the TriScale paper. Jupyter notebooks are used as wrappers for all our data analysis.
Note. If you are not familiar with Jupyter notebooks, you can find some basic information on TriScale's tutorial page.
We provide three options to reproduce the paper results:
Keep in mind that running the plotting and case study notebooks require to download the experiment raw data (available in a separate Zenodo repository); in particular, the congestion-control data zip file is about 2.7 GB large. The required download commands are included in the respective notebooks.
Recommended alternative | |
---|---|
To quickly try out the API | Binder |
If not familiar with Python environments | Binder or nbviewer |
For a quick look | nbviewer |
With limited Internet connection | nbviewer |
For a more in-depth trial | locally |
You can run the TriScale's notebooks directly in your web-browser, thanks to the amazing service provided by MyBinder.org!
- Click this
launch binder
button (it may take a few minutes to load);
- Open any notebook in the repository (see the notebooks' description below);
- Explore the different functions, run the example code snippets, modify them, run them again...
Note. You cannot save the state of the notebooks open using Binder; once your session expires, you will not be able to retrieve changes you made, or outputs you computed.
If you want to do that, you should run the notebooks locally.
MyBinder.org in a nutshell
MyBinder.org is a service that fetches a public repository, builds a Docker image with all required dependencies, then runs and serves an image in a cloud platform, making it accessible to anyone with on the web, without requiring any install!
Best of all, MyBinder.org is a free and open-source service, managed for scientists by scientists. Check it out, it's really cool!
You can simply visualize the notebooks using nbviewer
.
Note. The code cannot be run, but you can read all descriptions, comments, and see the outputs. Links for visualizing notebooks in
nbviewer
are provided in the descriptions below.
You can run the notebooks locally by cloning this repository. The list of dependencies is included in the environment.yml
file.
If you are using conda
, simply execute the following commands to get started:
git clone [email protected]:romain-jacob/triscale.git
cd triscale
conda env create -f environment.yml
conda activate myenv
jupyter notebooks
If you prefer
pip
overconda
, you will also find arequirements.txt
file, but this one is not guaranteed to be complete.
The TriScale paper includes a set of case studies that illustrate the use and benefits of TriScale for concrete networking performance evaluations.
This repository contains the notebooks that allows to reproduce the analysis of these case studies. The raw data are available in a separate Zenodo repository, each notebook contains the required wget
commands.
This case study presents a comparison between 17 congestion-control schemes. It reproduces some of the analysis performed in the Pantheon paper, illustrates its limitations, and shows how the approach in TriScale helps to overcome them.
This case study compares the performance of Glossy, a low-power wireless communication protocol, for different parameter values, using the FlockLab testbed as experiment environment. In particular, this case study illustrates the importance of network profiling: this example shows how one may reach wrong conclusions (even with high confidence!) when the environmental conditions are not properly assessed.
This case study revisits the analysis of Blink, an algorithm that detects failures and reroutes traffic directly in the data plane. We only perform the data analysis and show how using TriScale allows to generalize the results.
This case study revisits the analysis of Pensieve, a system that generates adaptive bitrate algorithms for video streaming using reinforcement learning. We show how TriScale can be used to provide confidence intervals not only on single KPIs, but on entire cumulative distribution functions (CDFs).
The scalability evaluation of TriScale can be reproduced by running the triscale_scalability.ipynb
notebook.
Keep in mind that, for this evaluation, the results depend on the computing power and load of the machine, therefore you may obtain results slightly different from those reported in the paper. However, the trends and orders of magnitude should remain similar.
Running this notebook on Binder is technically possible but not recommended: it includes time measurement of rather heavy computations, which is unlikely to be meaningful (the current load of the servers hosting MyBinder.org is unknown and unpredictable.)
All plots presented in the TriScale paper have been produced using the triscale_plots.ipynb
notebook. This same notebook produces larger versions of these plots if you want to have a closer look.
In order to run this notebook (either in Binder or locally), you will need to download the data from all the case studies. The required download commands are included in the notebook.