do-like-javac (or dljc for short) is a tool for monitoring the build process of
a Java project and recording information about what parameters were passed to javac
for the purpose of later analysis. It can also automate the running of various
analysis tools, including:
do-like-javac supports projects built with:
- Apache Ant
- Apache Maven
- Gradle
- Manual invocation of
javac
If you have a project that builds through Eclipse that you want to analyze,
Eclipse can generate an Ant-compatible build.xml file by right-clicking the
project, selecting "Export" and choosing the "Ant Buildfiles" option.
- Python 3
- The analysis tool(s) you want to run.
- Any build dependencies of the project you're analyzing.
do-like-javac was built and tested on Mac OS X and GNU/Linux. It may also
work on Microsoft Windows, but we provide no support.
git clone https://github.com/SRI-CSL/do-like-javac.git
Then symlink the dljc executable to somewhere in your $PATH, e.g.
ln -s /path/to/dljc $HOME/bin/dljc
First, make sure your project is in a clean state (e.g. via ant clean,
mvn clean, etc.). Since do-like-javac monitors the build process and build
tools skip already-built files, if you run dljc on an already-built project,
you won't get any results.
Next, invoke dljc from the directory of the project you want to analyze:
dljc -o logs -- ant build
Where "ant build" is replaced by whatever command builds your project. Output will be emitted to logs/toplevel.log
You may also run one or more checking tools on the discovered java files, by invoking with the -t option and a comma separated list of tools to use (e.g. "-t print", "-t randoop" or "-t print,randoop").
If you're running checking tools, there are a couple more flags that may be
helpful. --quiet suppresses output from tools, and --timeout <seconds>
kills any tool subcommand that runs longer than <seconds>.
Instructions for adding support for new tools or build systems to DLJC can be found in Extending.md.
do-like-javac can only extract data from a full compile of a project. That means
if you want to re-run it with new arguments or different analysis tools, you will
have to clean and fully re-compile the project. To save time and shortcut this
process, we save a cache of the results in the output directory. If you want dljc
to use this cache, simply add the --cache flag and the cache (if available) will
be used instead of recompiling the project.
IMPORTANT NOTE: We don't do any sort of cache invalidation or freshness checking.
If you add new files to your project and want dljc to pick up on them, you will have
to do a full clean and run dljc without the --cache flag.
The print tool (dljc -t print) will pretty-print the detected javac commands, as well as any generated JAR files, and their entry points if applicable.
The Bixie tool will run your project through Bixie. You will need to provide a library directory containing bixie.jar using the --lib option.
dljc --lib path/to/libs/ -t bixie -- mvn compile
The Dyntrace tool will run your project through Randoop to generate tests, then run those tests with Daikon/Chicory to generate likely invariants. You will need to provide a library directory with the following jars using the --lib option:
- randoop.jar
- junit-4.12.jar
- hamcrest-core-1.3.jar
You will also need Daikon built and installed somewhere, with the environment variable DAIKONDIR pointing to your installation.
dljc --lib path/to/libs/ -t dyntrace -- mvn compile
The Checker Framework's whole-program inference tool will iteratively type-check your
program using the specified Checker Framework checker until the set of annotations reaches
a fix-point (note that this process may not terminate). You will need the Checker Framework's
checker.jar file. An example of invoking this tool might look like this:
dljc --lib path/to/checker.jar -t wpi --checker org.checkerframework.checker.nullness.NullnessChecker -- ./gradlew compileJava
The --checker option is usually required. Its argument is the name(s) of the checker you want to run, separated by commas
(identically to the standard syntax used by the -processor argument to javac). If no --checker argument is supplied,
then the classpath will be searched for annotation processors using javac's standard annotation processor discovery
mechanism; from the javac documentation:
The search path can be specified with the -processorpath option. If no path is specified, then the user class path is used. Processors are located by means of service provider-configuration files named
META-INF/services/javax.annotation.processing.Processoron the search path. Such files should contain the names of any annotation processors to be used, listed one per line.
This tool also supports some other tool-specific optional arguments:
--stubs /path/to/stubstells the checker to run with the specified stub files.--ajava /path/to/ajavatells the checker to run with the specified ajava files.--jdkVersion 8/11/17tells the Checker Framework to run using JDK8, JDK11, or JDK17..--quals /path/to/qual.jartells the Checker Framework where to find qualifiers (annotations) to put on the classpath.--extraJavacArgs='-AcustomArg1 -AcustomArg2'passes the given arguments to invocations ofjavacthat run a Checker Framework checker as an annotation processor (i.e., the arguments are NOT passed to thejavacused while building the target project without running the analysis). This option is intended for Checker Framework options, such as-AassumeSideEffectFreeor others documented in the Checker Framework manual, but you can also use it to pass standardjavacoptions (e.g. those documented by Oracle).
Parts of the code in this project were taken from the Facebook Infer project. Files containing such code have Facebook copyright notices at the top and are licensed under the terms laid out in LICENSE_Facebook.
The rest of the project is licensed under the BSD license under the terms laid out in LICENSE.