Midori is a plugin-based orchestrator that allows researchers to run software engineering experiments on remote clusters. It is a byproduct of my thesis. It is designed to be automated for time-consuming experiments that require a large number of runs.
- Why Midori? Because there are so many things to consider when it comes to running software engineering experiments, such as:
- Cooling down before each trial.
- SSH Connection.
- Randomizing the order of the trials.
- Switching between different treatments.
- ...
- What is an orchestrator? Midori is meant to be a local tool that manipulates the remote cluster to run the experiments using SSH. In this way, the overhead of the experiment on the remote cluster is minimized.
Plugins and experiment subject are essential to conducting experiments with Midori. Plugins are used to interact with experiment subject or the remote cluster as a whole.
Midori is only compatible with Python 3.12. Install it via pip or other package managers:
pip install midori
Initialize the orchestrator with the following parameters and run:
from midori.core import Orchestrator
orchestrator = Orchestrator(
hostname: str,
username: str,
password: str,
repetitions: int,
before_trial_cooling_time: int,
trial_timespan: int,
after_trial_cooling_time: int,
variables: Dict[str, List[str]],
subject_path: str,
before_experiment_plugins: List[Type[PluginHelper]] = [],
setup_plugins: List[Type[PluginHelper]] = [],
end_trial_plugins: List[Type[PluginHelper]] = [],
end_experiment_plugins: List[Type[PluginHelper]] = [],
)
orchestrator.run()- The
subject_pathis a directory on the remote node. It is a valid experiment subject if- It is a git repository.
- It contains branches named after the combinations of the
variables. Each branch represents a treatment.
For example, if variable is
variables = {'drink': ['orange', 'apple', 'watermelon'], 'size': [300, 600, 100], 'temperature': [20, 30]}The subject_path should be a git repository that contains branches named orange-300-20, orange-300-30, orange-600-20, orange-600-30, etc. You do not have to include all the combinations, Midori will skip the missing branches.
hostname,username,password: Midori needs these parameters to connect to the remote node via SSH.repetitions: The number of repetitions for the experiment.before_trial_cooling_time: The cooling time before each trial, in seconds.trial_timespan: The time span of each trial, in seconds.after_trial_cooling_time: The cooling time after each trial, in seconds.variables: The variables to be manipulated in the experiment. For example, if you have two variables,xandy, and you want to run the experiment with the values ofxas[1, 2, 3]and the values ofyas[4, 5, 6], you can define the variables as{'x': [1, 2, 3], 'y': [4, 5, 6]}.subject_path: The path of the subject to be run on the remote cluster. For example, if you want to run the subject in the~/subjectdirectory, you can define the path as~/subject.before_experiment_plugins: The plugins to be run before the experiment, such as setting environment variables, installing dependencies, close unnecessary services, etc.setup_plugins: The plugins to be run before each trial, such as setting up treatment-dependent environment variables, cleaning up the environment, etc.end_trial_plugins: The plugins to be run after each trial, such as collecting logs, cleaning up the environment, etc.end_experiment_plugins: The plugins to be run after the experiment.
To help you better understand this, the green boxes in the collapsed illustration represent the parameters.
Clearly there are 4 parameters that invoke the plugins to be run at different stages of the experiment. The 4 parameters are lists of class definitions (not instances).
Plugins defined in before_experiment_plugins, setup_plugins, end_trial_plugins, end_experiment_plugins are run in the order. [A, B, C] means A is run first, then B, and finally C, with the output of A passed to B and the output of B passed to C.
The way we define these plugins is by inheriting from the PluginHelper class and overriding the action method. Here is an example:
from midori.plugins.helpers import PluginHelper
class SkaffoldSetup(PluginHelper):
def action(self) -> str:
return f"cd {self.subject_path} && skaffold delete && skaffold run"
class CheckRam(PluginHelper):
def action(self) -> str:
return "cat /proc/meminfo | grep MemTotal"action() method should return either an str or None. If it returns an str, it will be executed on the remote cluster. If it returns None, it will be skipped. You may want to implement side effects in the action() method based on 3 accessible attributes:
self.subject_path: The path of the subject to be run on the remote cluster, which is the same as thesubject_pathparameter ofOrchestrator.self.previous_output: The output of the previous plugin. For example, ifend_trial_plugins = [CheckRam, NewPlugin], whereCheckRamis the plugin shown above, theNewPluginwill have access to the output ofCheckRaminself.previous_outputasMemTotal: 900000000 kB.self.treatment: The treatment of the current trial.
- If you really want access to the SSH client in the plugin
action()method, you can access it viaself._ssh(it'sparamiko.SSHClient). Most of the time it's not necessary to use it. The only reason I kept it is to make my old plugins work with the new version of Midori.
- Install poetry.
- Navigate to the root of the project and run
poetry install. - Enter the virtual environment by running
poetry shell. - Run
pre-commit installto install pre-commit hooks. - Develop on
devbranch and create a pull request todevbranch.
@misc{midori,
author = {Xingwen Xiao},
title = {Midori},
year = {2024},
publisher = {GitHub},
journal = {GitHub repository},
howpublished = {\url{https://github.com/imchell/midori}},
}