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Clang Static Analyzer Test Bench

The CSA test bench is a collection of tools that aim to ease Clang Static Analyzer development by finding projects on which certain checks or analyzer engine changes can be tested and by making the evaluation of the results easier.

Generate Project List utility

The generate_project_list.py utility can help discover relevant projects on which a check or a change can be tested. It generates a list of projects that use a certain API or language construct extensively, based on SearchCode query results.

Example usage:

python generate_project_list.py 'pthread_mutex_t' 'C C++' 5 --output pthread.json

The above command will generate a list of 5 projects written in either C or C++ that use pthread_mutex_t.

Generate Project List from Debian packages

It is also possible to create a project list file from Debian source packages. The resulting file will contain lots of unsupported projects, so we advise filtering the list afterward.

python project_list_from_debian.py -u ftp://ftp.se.debian.org/debian/ --output debian.json

We do plan to include additional facilities to help with filtering the list and building the packages in the future.

Running Experiments

The run_experiments.py script runs the Clang Static Analyzer on a set of projects and generates a detailed report from the results. It downloads the projects specified in a JSON config file from a git repository or a tarball, infers the build system, generates a build log, runs the Static Analyzer, collects the output, and generates an HTML report that holds all information needed to reproduce the same experiment.

Example usage:

python run_experiments.py --config projects.json --jobs 8

Note that the CodeChecker server at the URL specified in the config file needs to be started separately before running an experiment.

Example configuration:

{
  "projects": [
    {
      "name": "tmux",
      "url": "https://github.com/tmux/tmux.git",
      "tag": "2.6"
    },
    {
      "name": "curl",
      "url": "https://github.com/curl/curl.git"
    }
  ],
  "configurations": [
    {
      "name": "baseline",
      "clang_sa_args": "-Xclang -analyzer-stats"
    },
    {
      "name": "unroll",
      "clang_sa_args": "-Xclang -analyzer-stats -Xclang -analyzer-config -Xclang unroll-loops=true,cfg-loopexit=true"
    }
  ],
  "CodeChecker": {
    "url": "http://localhost:15010/Default"
  }
}

Example report:

Example report

Dependencies

In order for this set of scripts to work, CodeChecker needs to be installed and available in the PATH. Packages from the python_requirements file should also be installed after CodeChecker's virtual environment was activated. Example setup below:

cd path/to/CodeChecker
make venv
source venv/bin/activate
make package
export PATH="$PWD/build/CodeChecker/bin:$PATH"
cd path/to/csa-testbench
pip install -r python_requirements

If the cloc utility is in the path, the script will also count the lines of code of the analyzed projects and include them in the final report.

If clang is compiled with statistics enabled, the scripts will collect and include them in the final report.

If line based code coverage support is present, the script can collect coverage data and include it in the final report. Note that this requires a patched version of clang, this feature is not upstreamed yet. For the code coverage collection support to work, you need to have the MergeCoverage.py script and gcovr utility in the PATH.

Add the "coverage": true line to the configuration in which you want to record the coverage:

{
  "projects": [ ... ],
  "configurations": [
    {
      "name": "your_configuration",
      "coverage": true
    },
    ...
  ],
  "CodeChecker": { ... }
}

Example coverage report:

Coverage report

Configuration

A minimal configuration should contain a list of projects and a CodeChecker URL. Each project should at least contain a git or tarball URL and a name. Other configuration values are optional.

{
  "projects": [
    {
      "name": "tmux",
      "url": "https://github.com/tmux/tmux.git",
      "tag": "2.6",
      "skip": [ "-*/cmd-break-pane.c*", "-*/cmd-bind-key.c*"],
      "configure_command": "sh autogen.sh && ./configure",
      "configurations": [
        {
          "name": "original"
        },
        {
          "name": "with_stats",
          "clang_sa_args": "-Xclang -analyzer-stats"
        }
      ]
    },
    {
      "name": "SQLite",
      "url": "https://www.sqlite.org/2018/sqlite-autoconf-3230000.tar.gz"
    },
    {
      "name": "bitcoin",
      "url": "https://github.com/bitcoin/bitcoin.git",
      "tag": "v0.15.1",
      "clang_sa_args": "-Xclang -analyzer-stats"
    },
    {
      "name": "redis",
      "url": "https://github.com/antirez/redis.git",
      "tag": "727dd43614ec45e23e2dedbba08b393323feaa4f",
      "make_command": "make -j $JOBS",
      "binary_dir": "build"
    },
    {
      "name": "xerces-c",
      "url": "https://github.com/apache/xerces-c.git",
      "prepared": true
    },
    {
      "name": "icu",
      "url": "http://download.icu-project.org/files/icu4c/61.1/icu4c-61_1-src.tgz",
      "source_dir": "source"
    },
    {
      "name": "llvm",
      "url": "https://github.com/llvm-mirror/llvm.git",
      "binary_dir": "build",
      "subprojects": [
        {
          "name": "clang",
          "subdir": "tools/clang",
          "url": "https://github.com/llvm-mirror/clang.git"
        }
      ]
    },
    {
      "name": "zlibconan",
      "package": "zlib/1.2.11@conan/stable",
      "package_type": "conan"
    },
    {
      "name": "zlibvcpkg",
      "package": "zlib",
      "package_type": "vcpkg"
    }
  ],
  "configurations": [
    {
      "name": "original",
      "clang_sa_args": "",
      "analyze_args": "",
      "store_args": "",
      "clang_path": ""
    },
    {
      "name": "with_stats",
      "clang_sa_args": "-Xclang -analyzer-stats",
      "coverage": true
    }
  ],
  "charts": ["Coverage", "Duration", "Result count"],
  "CodeChecker": {
    "url": "http://localhost:8001/Default",
    "analyze_args": "",
    "store_args": "",
    "analyzers": "clangsa clang-tidy"
  }
}

Optional configuration values

  • configurations: It is possible to specify multiple clang configurations, in which case each project will be analyzed using each of the clang configurations. The global configuration entry applies to each project. A configuration entry local to a project will overwrite the global settings. Each configuration should have at least a name.
  • clang_sa_args: Arguments passed to clang (not cc1). The entry under CodeChecker applies to all projects and is appended to the final list of arguments. Entries under the projects apply to each configuration.
  • analyze_args: Arguments passed to the CodeChecker analyze command. It works the same way as clang_sa_args.
  • analyzers: Which analyzers to run. Defaults to Clang Static Analyzer only.
  • store_args: Arguments passed to the CodeChecker store command. It works the same way as clang_sa_args.
  • coverage: If set to true, precise coverage information will be recorded.
  • clang_path: The directory containing the clang binaries. This can be useful for testing clang before and after a patch is applied.
  • tag: A commit hash or tag name of a project that will be checked out. It can be useful to make the experiments reproducible, i.e., always test with the same code.
  • configure_command: If this configuration value is set, the script will issue this command before building the project. It will not appear in the build log. The working directory will be the root of the project. The string $JOBS will be replaced with the number of jobs specified in the command line.
  • make_command: If this configuration value is set, the script will not try to infer the build system, but will invoke the make command specified in this value. The working directory will be the root of the project. The string $JOBS will be replaced with the number of jobs specified in the command line.
  • binary_dir: The binary dir can be specified for out-of-tree builds. It can be relative to the project root. Currently, this is only supported for cmake projects.
  • source_dir: If the source code and the related build files of the project are not in the project root, this directory can specify the location.
  • prepared: If this configuration value is set to true, the script will not attempt to check out the project and will not attempt to create a build log. It will assume that a folder with the name of the project exists and contains a compile_commands.json file. It will use that file for the analysis of the project.
  • submodules: If this configuration value is set to true, the script will also initialize submodules after checking the repository out.
  • charts: The list of statistics that should be charted.
  • subprojects: List of other repositories to check out before building into the subdir directory.
  • package_type: package manager to build a C++ package. Conan and vcpkg are supported.
  • skip: specify the skiplist for a project. Each element in the list corresponds to a line in the generated skiplist file.

Limitations

These scripts will not figure out the dependencies of a project. It is the user's responsibility to make sure that the projects in the configuration file can be compiled on the machine on which the experiments are run.

Measuring bug path length statistics

The bug_stats.py file can be used to calculate descriptive statistics from the results of the analysis. It takes the "product URL" argument of a running CodeChecker server (--url http://localhost:8001/Default) and some project names (--name Project1 Project2, or --all) and generates statistics and histograms for each project given.

bug_stats.py --url http://example.org:8080/MyProduct --name my_run

Example bug statistics

This script also supports generating statistics from the difference of two runs, based on the bug reports presented by CodeChecker cmd diff:

bug_stats.py --url http://example.org:8080/MyProduct --diff \
  --basename baseline --newname csa_patched --new

Other Tips and Tricks

CReduce diffs

CReduce is a useful tool to get minimal reproducers for compiler bugs. It is also great for getting minimal reproducers for assertion fails or crashes of static analysis tools. Moreover, we can use this tool to get minimal regressions or improvements between two versions of an analysis engine.

This section is a small example of how to do it for the Clang Static Analyzer.

  1. Create the file to reduce

Create a preprocessed file for which the two versions of the analyzer give different results

  1. Create the reduce script

Create a script that executes both versions of the analyzer on the preprocessed file and compares the output. Note that this script should return 0 if a transformation of creduce preserved the property we want, and non-zero otherwise. In case one of the implementations is crashed, we should return non-zero since our goal is not to get minimal crash reproducers.

# reduce.sh
set -e
/path/to/basline/clang --analyze preprocessed.c 2> out1.txt
/path/to/modified/clang --analyze preprocessed.c 2> out2.txt

! cmp --silent out1.txt out2.txt
  1. Execute creduce and wait for the results
creduce reduce.sh preprocessed.c --n 8

Note that the final result might contain a warning that differs from the initials.