Android VTS 9.0 Release 4 (5007851)
Snap for 4801384 from cfcdf332ca22f71c9e68331b2777ad58a8bb5b5f to pi-release

Change-Id: I437662886cb9bb0e4e4f5aab557cb4949728f2fb
tree: 2751ccba1a25a91386c9d90439d1be2f28a51c80
  1. assets/
  2. experiments/
  3. ipynb/
  4. libs/
  5. results/
  6. src/
  7. tests/
  8. tools/
  9. .gitignore
  10. .gitmodules
  11. .travis.yml
  12. init_env
  13. install_base_ubuntu.sh
  14. LICENSE.txt
  15. LisaShell.txt
  16. logging.conf
  17. MODULE_LICENSE_APACHE2
  18. NOTICE
  19. README.md
  20. target.config
  21. Vagrantfile
  22. youtube_EAS12_schedutil_iowaitboost_off_bigsoff.ipynb
README.md

NOTE: This is still a work in progress project, suitable for: developers, contributors and testers. None of the provided tests have been extensively evaluated as of January 2017.

Introduction

The LISA project provides a toolkit that supports regression testing and interactive analysis of Linux kernel behavior. LISA stands for Linux Integrated/Interactive System Analysis. LISA's goal is to help Linux kernel developers to measure the impact of modifications in core parts of the kernel. The focus is on the scheduler (e.g. EAS), power management and thermal frameworks. However LISA is generic and can be used for other purposes too.

LISA has a “host”/“target” model. LISA itself runs on a host machine, and uses the devlib toolkit to interact with the target via SSH, ADB or telnet. LISA is flexible with regard to the target OS; its only expectation is a Linux kernel-based system. Android, GNU/Linux and busybox style systems have all been used.

LISA provides features to describe workloads (notably using rt-app) and run them on targets. It can collect trace files from the target OS (e.g. systrace and ftrace traces), parse them via the TRAPpy framework. These traces can then be parsed and analysed in order to examine detailed target behaviour during the workload's execution.

Some LISA features may require modifying the target OS. For example, in order to collect ftrace files the target kernel must have CONFIG_DYNAMIC_FTRACE enabled.

There are two “entry points” for running LISA:

  • Via the Jupyter/IPython notebook framework. This allows LISA to be used interactively and supports visualisation of trace data. Some notebooks are provided with example and ready-made LISA use-cases.

  • Via the automated test framework. This framework allows the development of automated pass/fail regression tests for kernel behaviour. The BART toolkit provides additional domain-specific test assertions for this use-case. LISA provides some ready-made automated tests under the tests/ directory.

Motivations

The main goals of LISA are:

  • Support study of existing behaviours (i.e. “how does PELT work?”)
  • Support analysis of new code being developed (i.e. “what is the impact on existing code?”)
  • Get insights on what's not working and possibly chase down why
  • Share reproducible experiments by means of a common language that:
    • is flexible enough to reproduce the same experiment on different targets
    • simplifies generation and execution of well defined workloads
    • defines a set of metrics to evaluate kernel behaviours
    • enables kernel developers to easily post process data to produce statistics and plots

Documentation

More formal API documentation for LISA is a work in progress, however much of the API is currently described in the provided tutorial Jupyter notebooks.

External Links

  • Linux Integrated System Analysis (LISA) & Friends Slides and Video

License

This project is licensed under Apache-2.0.

This project includes some third-party code under other open source licenses. For more information, see lisa/tools/LICENSE.*

Contributions / Pull Requests

Contributions are accepted under Apache-2.0. Only submit contributions where you have authored all of the code. If you do this on work time make sure your employer is cool with this.