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Mining Framework

Java CI

This is a framework for mining and analyzing git projects.

We focus on analyzing merge commits, although this could be easily changed to analyze any kind of commit.

We basically have variability points (hot spots) for

  • preprocessing the set of projects to be analyzed (like forking projects)
  • filtering the set of merge commits in such projects (like for focusing only on merge commits with parents that involve changes to the same method)
  • collecting experimental data from each merge commit (like revisions of the files declaring the method that was changed in both parents, commit hashes, line numbers of the changes in each parent, overall statistics about the merge commit, result of replaying the merge operation with different tools, etc.)
  • postprocessing the collected experimental data (like aggregating and summarizing data, or any kind of operation that is more expensive to perform in a per merge commit basis, such as downloading generated ".jar" files for each merge revision, merging spreadsheets created by different data collectors, etc.), after all projects have been analyzed

We also have a number of implementations for such variability points, so that one can reuse or adapt them as needed for instantiating the framework. The examples illustrated above correspond to some of the implementations we provide here.

Getting Started

  • Fork and clone the project. If you want to run the project tests, you must clone the repository with the recursive option: git clone --recursive https://github.com/spgroup/miningframework

  • This project uses Apache Groovy. You have to install version 3.0.x or newer to use the framework and start mining projects.

  • For one of the implementation of the postprocessing variability point (OutputProcessorImpl), you also have to install Python version 3.7.x or newer. This is needed for a script that fetches build files from Github, and another script that converts collected data to a format that is used by the SOOT static analyses invoked by this instantiation. You may need to install dependencies for Python scripts. Once you have Python 3 installed, run pip3 install -r requirements.txt at the root of the project. If you don't wish to use this specific implementation of the postprocessing variability point, there is no need to install Python.

  • For one of the implementation of the postprocessing variability point (OutputProcessorImpl), you also need conflict static analysis, which implements the SOOT static analyses mentioned above. The class OutputProcessorImpl basically invokes the CLI provided by the conflict static analysis to execute a number of conflict static analysis algorithms.

  • If you are using Windows, you will need to install DiffUtils manually. That done, add the installation directory to PATH in your environment variables.

Instantiating or extending the framework

You need to implement the following interfaces (see interfaces/) or choose their existing implementations (see services/):

  • ProjectProcessor
  • CommitFilter
  • DataCollector
  • OutputProcessor

They correspond to the four variability points described at the beginning of the page. The following Interfaces can have multiple implementations injected:

  • ProjectProcessor
  • DataCollector
  • OutputProcessor

For those, the order which the they are injected will be followed by the framework, running the implementations in order

The framework uses Google Guice to implement dependency injection, and inject the interface implementations. So, to select the interface implementations you want to use in your desired instantiation of the framework, you also need to write a class such as StaticAnalysisConflictsDetectionModule in the injectors package, which acts as the dependency injector. This one, in particular, is used as a default injector if no other is specified when invoking the framework.

Running Mining Framework with Docker

If you have Docker available on your machine, you might find it easier to start playing with Mining Framework by using our pre-built Docker image.

The image is built upon Amazon Corretto with Java 8, and provides an already compiled distribution of Mining Framework. To start running it with Docker, simply run:

docker run -v $PWD/output:/usr/src/miningframework/output/ -v $PWD/projects.csv:/usr/src/miningframework/projects.csv --rm ghcr.io/spgroup/miningframework:master projects.csv 

Running a specific framework instantiation

You can run the framework by including the src directory in the classpath and executing src/main/app/Main.groovy. This project uses Gradle as its build system, so we will be using Gradle tasks to execute all framework's operations.

This can be done by configuring an IDE or executing the following command in a terminal:

  • Linux/Mac: ./gradlew run --args="[options] [input] [output]"
  • Windows: .\gradlew run --args="[options] [input] [output]"

[input] is the path to a CSV file containing the list of projects to be analyzed (like projects.csv), one project per line. The list can contain external projects to be downloaded by the framework (the path field should be an URL to a git project hosted in the cloud), or local projects (the path field should refer to a local directory).

[output] is the path to a directory that the framework should create containing the results (collected experimental data, statistics, etc.) of the mining process.

[options] a combination of our command line configuration options. It's useful to type --help in the [options] field to see the supported options and associated information.

The options are available to all variability points implementations, but some of the implementations might not make use of all options. So check the documentation of the variability points implementations you need to confirm that they really make use of the options of interest.

If you intend to use the framework multithreading option, be aware of the need to synchronize the access to output files or state manipulated by the implementations of the framework variability points.

For example, for running the study we use as an example to illustrate the variability points at the beginning of the page, we invoke the following command at the project top folder:

  • Linux/Mac: ./gradlew run --args="--access-key github-personal-access-token --threads 2 ./projects.csv SOOTAnalysisOutput"
  • Windows: .\gradlew run --args="--access-key github-personal-access-token --threads 2 ./projects.csv SOOTAnalysisOutput"

The CLI has the following help page:

usage: miningframework [options] [input] [output]
the Mining Framework take an input csv file and a name for the output dir
(default: output)
 Options:
 -a,--access-key <access key>               Specify the access key of the git account
                                            for when the analysis needs user access to
                                            GitHub
 -e, --extension <extension>                Specify the file extension that should be 
                                            used in the analysis (e.g. .rb, .ts, .java,
                                            .cpp. Default: .java)
 -h,--help                                  Show help for executing commands
 -i,--injector <class>                      Specify the class of the dependency
                                            injector (Must provide full name, default
                                            injectors.StaticAnalysisConflictsDetection
                                            Module)
 -k,--keep-projects                         Specify that cloned projects must be kept
                                            after the analysis (those are kept in
                                            clonedRepositories/ )
 -l,--language-separators <'separators'>    Specify the language separators that should
                                            be used in the analysis. Required for (and 
                                            only considered when) running studies with 
                                            the CSDiff tool. Default: '{ } ( ) ; ,'
 -log,--log-level <log level                Specify the minimum log level: (OFF, FATAL,
                                            ERROR, WARN, INFO, DEBUG, TRACE, ALL).
                                            Default: "INFO"
 -p,--push <link>                           Specify a git repository to upload the
                                            output in the end of the analysis (format
                                            https://github.com/<owner>/<name>
 -s,--since <date>                          Use commits more recent than a specific
                                            date (format DD/MM/YYY)
 -t,--threads <threads>                     Number of cores used in analysis (default:
                                            1)
 -u,--until <date>                          Use commits older than a specific
                                            date(format DD/MM/YYYY)

Testing

One can run the framework tests by running the check task:

./gradlew check

  • To create new tests, you have to create a git repository with a merge scenario simulating a specific situation you want to test, add it to the test_repositories directory, add a corresponding entry to src/test/input.csv, and then create the Test class.

Building

.\gradlew build -x test