Skip to content

snitch3s/grimoirelab-graal

 
 

Repository files navigation

Graal: a Generic Repository AnALyzer Build Status Coverage Status PyPI version

Graal leverages on the Git backend of Perceval and enhances it to set up ad-hoc source code analysis. Thus, it fetches the commits from a Git repository and provides a mechanism to plug third party tools/libraries focused on source code analysis.

How it works

The Perceval Git backend creates a local mirror of a Git repository (local or remote), fetches the metadata of commits in chronological order and returns them as a list of JSON documents (one per commit). Graal leverages on the incremental functionalities provided by the Git backend and enhances the logic to handle Git repositories by creating a working tree to perform checkout operations (which are not possible on a Git mirror). Graal intercepts each JSON document and enables the user to perform the following steps:

  • Filter. The filtering is used to select or discard commits based on the information available in the JSON document and/or via the Graal parameters. For any selected commit, Graal executes a checkout on the working tree using the commit hash, thus setting the state of the working tree at that given revision.
  • Analyze. The analysis takes the JSON document and the current working tree and enables the user to set up ad-hoc source code analysis by plugging existing tools through system calls or their Python interfaces, when possible. The results of the analysis are parsed and manipulated by the user and then automatically embedded in the JSON document. It is worth noting that in this step the user can rely on some predefined functionalities of Graal to deal with the repository snapshot (e.g., listing files, creating archives).
  • Post-process. In the final step, the inflated JSON document can be optionally processed to alter (e.g., renaming, removing) its attributes, thus granting the user complete control over the output of Graal executions.

Several parameters (inherited from the Git backend) are available to control the execution; for instance, from_date and to_date allow to select commits authored since and before a given date, branches allows to fetch commits only from specific branches, and latest_items returns only those commits which are new since the last fetch operation. Graal includes additional parameters to drive the analysis to filter in/out files and directories in the repository (in_paths and out_paths), set the entrypoint and define the details level of the analysis (useful when analyzing large software projects).

Requirements

You will also need some other Python libraries for running the tool, you can find the whole list of dependencies in pyproject.toml file.

How to install and create the executables:

  • github-linguist

    Library is used to detect blob languages, ignore binary or vendored files, suppress generated files in diffs, and generate language breakdown graphs.

    $ gem install github-linguist -v 7.15
    
  • FOSSology

    Open source license compliance software system and toolkit. You can run license, copyright, and export control scans from the command line.

    $ wget https://github.com/fossology/fossology/releases/download/3.11.0/FOSSology-3.11.0-ubuntu-focal.tar.gz
    $ tar -xzf FOSSology-3.11.0-ubuntu-focal.tar.gz
    $ sudo apt-get -y install ./packages/fossology-common_3.11.0-1_amd64.deb \
                              ./packages/fossology-nomos_3.11.0-1_amd64.deb
    
  • Cloc

    Count blank lines, comment lines, and physical lines of source code in many programming languages.

    $ sudo apt-get install cloc
    
  • SCC

    A tool similar to cloc - for counting physical the lines of code, blank lines, comment lines, and physical lines of source code in many programming languages and COCOMO estimates written in pure Go.

    $ go install github.com/boyter/scc@latest
    
  • ScanCode Toolkit

    ScanCode detects licenses, copyrights, package manifests & dependencies and more by scanning code.

    $ mkdir exec
    $ cd exec
    $ git clone https://github.com/nexB/scancode-toolkit.git
    $ cd scancode-toolkit
    $ git checkout -b test_scancli 96069fd84066c97549d54f66bd2fe8c7813c6b52
    $ ./scancode --help
    

    Note: We're now using a clone of scancode-toolkit instead of a release, as the latest release is of 15th February 2019 and the scancli.py script (required for execution of scancode_cli) was incorporated later i.e 5th March 2019 and there hasn't been a release since.

  • crossJadolint

    This is a Dockerfile linter tool, implemented in Java and essentialy is a port of Hadolint (Haskell Dockerfile Linter)

    $ cd exec
    $ wget https://github.com/crossminer/crossJadolint/releases/download/Pre-releasev2/jadolint.jar
    

Installation

There are several ways to install Graal on your system: packages or source code using Poetry or pip.

PyPI

Graal can be installed using pip, a tool for installing Python packages. To do it, run the next command:

$ pip install graal

Source code

To install from the source code you will need to clone the repository first:

$ git clone https://github.com/chaoss/grimoirelab-graal
$ cd grimoirelab-graal

Then use pip or Poetry to install the package along with its dependencies.

Pip

To install the package from local directory run the following command:

$ pip install .

In case you are a developer, you should install graal in editable mode:

$ pip install -e .

Poetry

We use poetry for dependency management and packaging. You can install it following its documentation. Once you have installed it, you can install graal and the dependencies in a project isolated environment using:

$ poetry install

To spaw a new shell within the virtual environment use:

$ poetry shell

Backends

Several backends have been developed to assess the genericity of Graal. Those backends leverage on source code analysis tools, where executions are triggered via system calls or their Python interfaces. In the current status, the backends mostly target Python code, however other backends can be easily developed to cover other programming languages. The currently available backends are:

  • CoCom gathers data about code complexity (e.g., cyclomatic complexity, LOC) from projects written in popular programming languages such as: C/C++, Java, Scala, JavaScript, Ruby, Python, Lua and Golang. It leverages on Cloc, Lizard and scc. The tool can be exectued at file and repository levels activated with the help of category: code_complexity_lizard_file or code_complexity_lizard_repository.
  • CoDep extracts package and class dependencies of a Python module and serialized them as JSON structures, composed of edges and nodes, thus easing the bridging with front-end technologies for graph visualizations. It combines PyReverse and NetworkX.
  • CoQua retrieves code quality insights, such as checks about line-code’s length, well-formed variable names, unused imported modules and code clones. It uses PyLint and Flake8. The tools can be activated by passing the corresponding category: code_quality_pylint or code_quality_flake8.
  • CoVuln scans the code to identify security vulnerabilities such as potential SQL and Shell injections, hard-coded passwords and weak cryptographic key size. It relies on Bandit.
  • CoLic scans the code to extract license & copyright information. It currently supports Nomos and ScanCode. They can be activated by passing the corresponding category: code_license_nomos, code_license_scancode, or code_license_scancode_cli.
  • CoLang gathers insights about code language distribution of a git repository. It relies on Linguist and Cloc tools. They can be activated by passing the corresponding category: code_language_linguist or code_language_cloc.

How to develop a backend

Creating your own backend is pretty easy, you only need to redefine the following methods of Graal:

  • _filter_commit. This method is used to select or discard commits based on the information available in the JSON document and/or via the Graal parameters (e.g., the commits authored by a given user or targeting a given software component). For any selected commit, Graal executes a checkout on the working tree using the commit hash, thus setting the state of the working tree at that given revision.
  • _analyze. This method takes the document and the current working tree and allows to connect existing tools through system calls or their Python interfaces, when possible. The results of the analysis, parsed and manipulated by the user, are automatically embedded in the JSON document.
  • _post. This method allows to alter (e.g., renaming, removing) the attributes of the inflated JSON documents.

How to use

From command line

Launching Graal from command line does not require much effort, but only some basic knowledge of GNU/Linux shell commands.

The example below shows how easy it is to fetch code complexity information from a Git repository. The CoCom backend requires the URL where the repository is located (https://github.com/chaoss/grimoirelab-perceval) and the local path where to mirror the repository (/tmp/graal-cocom). Then, the JSON documents produced are redirected to the file graal-cocom.test.

  • CoCom Backend
$ graal cocom https://github.com/chaoss/grimoirelab-perceval --git-path /tmp/graal-cocom > /graal-cocom.test
Starting the quest for the Graal.
Git worktree /tmp/... created!
Fetching commits: ...
Git worktree /tmp/... deleted!
Fetch process completed: .. commits inspected
Quest completed.
  • CoLic Backend
graal colic https://github.com/chaoss/grimoirelab-toolkit --git-path /tmp/scancode_cli --exec-path /home/scancode-toolkit/etc/scripts/scancli.py --category code_license_scancode_cli
Starting the quest for the Graal.
Git worktree /tmp/... created!
Fetching commits: ...
Git worktree /tmp/... deleted!
Fetch process completed: .. commits inspected
Quest completed.

In the above example, we're using scancode_cli analyzer. Similarly, we can use the scancode analyzer by providing the category as code_license_scancode and it's corresponding executable path.

From Python

Graal’s functionalities can be embedded in Python scripts. Again, the effort of using Graal is minimum. In this case the user only needs some knowledge of Python scripting. The example below shows how to use Graal in a script.

The graal.backends.core.cocom module is imported at the beginning of the file, then the repo_uri and repo_dir variables are set to the URI of the Git repository and the local path where to mirror it. These variables are used to initialize a CoCom class object. In the last line of the script, the commits inflated with the result of the analysis are retrieved using the fetch method. The fetch method inherits its argument from Perceval, thus it optionally accept two Datetime objects to gather only those commits after and before a given date, a list of branches to focus on specific development activities, and a flag to collect the commits available after the last execution.

#! /usr/bin/env python3
from graal.backends.core.cocom import CoCom

# URL for the git repo to analyze
repo_uri = ’http://github.com/chaoss/grimoirelab-perceval’

# directory where to mirror the repo
repo_dir = ’/tmp/graal-cocom’

# Cocom object initialization
cc = CoCom(uri=repo_uri, git_path=repo_dir)

# fetch all commits
commits = [commit for commit in cc.fetch()]

How to integrate it with Arthur

Arthur is another tool of the Grimoirelab ecosystem. It was originally designed to allow to schedule and run Perceval executions at scale through distributed Redis queues, and store the obtained results in an ElasticSearch database.

Arthur has been extended to allow handling Graal tasks, which inherit from Perceval Git tasks. The code to make this extension possible is available at: chaoss/grimoirelab-kingarthur#33.

Information about Arthur is available at https://github.com/chaoss/grimoirelab-kingarthur.

Releases

No releases published

Packages

No packages published

Languages

  • Python 99.4%
  • Dockerfile 0.6%