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CONTRIBUTING.md

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Contributing to Fruit

This file contains various information and documentation for Fruit contributors. If you only want to use Fruit, see the wiki; you can find instructions for building Fruit manually here.

If you actually want to change Fruit itself, that's great! Read on.

Basics

Build systems

Fruit supports two build systems: CMake (configured in CMakeLists.txt files) and Bazel (configured in BUILD files).

This means that when you build/test Fruit code you have a choice of what build system you want to use, but also that for larger changes (typically, if you add new files) you might need changes in both CMakeLists.txt and BUILD files, to make sure that Fruit keeps building (and passing its tests) under both build systems. Both build systems are tested in Travis CI (see below).

Example commands to build a development version of Fruit using CMake (with all assertions enabled) and run the tests:

cd $PATH_TO_FRUIT
mkdir build-debug
cd build-debug
cmake .. -DCMAKE_BUILD_TYPE=Debug -DFRUIT_ENABLE_CLANG_TIDY=TRUE -DCMAKE_CXX_FLAGS="-Werror -DFRUIT_DEBUG=1 -DFRUIT_EXTRA_DEBUG=1 -D_GLIBCXX_DEBUG=1"
make -j 16
cd tests
py.test-3 -n auto

Continuous Integration (CI)

Fruit uses Github actions for continuous integration. You can see the latest CI runs in Github here. The CI configuration is defined in .github/workflows.

Fruit tests run as Github actions run in various configurations/environments, notably:

  • In Linux, OS X and Windows
  • In various OS versions
  • Using GCC, Clang, Apple-Clang or MSVC
  • Optionally running with ASan/UBSan
  • Using CMake or Bazel

These tests run after every commit in master and for every pull request (as soon as the pull request is sent).

Linux tests run in Docker, using a set of images built for this purpose (list of images).

If a test fails in CI in some configuration, look at the beginning of the CI Job log for a line such as:

export OS=linux; export COMPILER='clang-3.9'; export STL='libstdc++'; export UBUNTU='16.04'; extras/scripts/postsubmit.sh DebugValgrind

You can then run the same command locally (from your fruit directory) to reproduce the issue. Running this postsubmit.sh script will run the tests under Docker to ensure repeatability of the results.

For example, even if the failure only happens with an old Ubuntu/GCC version you don't have installed, it will download a Docker image containing that old Ubuntu/GCC and then run the tests inside a VM started from that image.

Once postsubmit.sh completes, if you want you can attach to the stopped VM used to run the tests by running:

docker attach fruit

This is often very useful to e.g. re-run a compilation manually with additional debug flags.

When running postsubmit.sh manually in this way, it will run using the latest changes in your fruit directory, even if they aren't staged/committed yet. This allows to do a quicker edit/test cycle.

To speed up the execution of postsubmit.sh you can also set the NJOBS variable, e.g.:

export NJOBS=16; export OS=linux; export COMPILER='clang-3.9'; export STL='libstdc++'; export UBUNTU='16.04'; extras/scripts/postsubmit.sh DebugValgrind

How to run Fruit tests on Windows

You can import Fruit in Visual Studio (2017 and later) as a CMake project. You need to set the relevant CMake flags in the CMakeSettings.json file that Visual Studio will create. For example, if you installed Boost in C:\boost\boost_1_62_0, you can put this configuration in your CMakeSettings.json:

{
    // See https://go.microsoft.com//fwlink//?linkid=834763 for more information about this file.
    "configurations": [
        {
          "name": "x64-Debug",
          "generator": "Visual Studio 16 2019 Win64",
          "configurationType": "Debug",
          "buildRoot": "${projectDir}\\out\\build\\${name}",
          "cmakeCommandArgs": "-DBoost_INCLUDE_DIR=C:\\boost\\boost_1_62_0  -DCMAKE_BUILD_TYPE=Debug -DFRUIT_ADDITIONAL_CXX_FLAGS=/Z7",
          "buildCommandArgs": "-m -v:minimal",
          "intelliSenseMode": "windows-msvc-x64"
        },
        {
          "name": "x64-Debug-noboost",
          "generator": "Visual Studio 16 2019 Win64",
          "configurationType": "Debug",
          "buildRoot": "${projectDir}\\out\\build\\${name}",
          "cmakeCommandArgs": "-DFRUIT_USES_BOOST=False -DCMAKE_BUILD_TYPE=Debug -DFRUIT_ADDITIONAL_CXX_FLAGS=/Z7",
          "buildCommandArgs": "-m -v:minimal",
          "intelliSenseMode": "windows-msvc-x64"
        }

    ]
}

The /Z7 flag instructs Visual Studio to use the C7 format for debugging information, which allows Fruit's tests to run in parallel without interfering with each other.

If you don't want to use Boost, you can replace the -DBoost_INCLUDE_DIR=... flags above with -DFRUIT_USES_BOOST=False.

You can now run CMake within Visual Studio (from the menu: CMake -> Cache -> Generate -> CMakeLists.txt) and build Fruit (from the menu: CMake -> Build All).

You can also run tests, but only from the command-line (after building Fruit from Visual Studio), running tests from Visual Studio doesn't work.

To do that, you'll need python3 installed (you can download it here).

You'll also some Python packages. You can install them with:

pip install absl-py
pip install pytest
pip install pytest-xdist

To do so:

  • Open the Start menu
  • From there, open the "Native Tools Command Prompt for VS 2017" shell for the chosen architecture. For example, "x64 Native Tools Command Prompt for VS 2017".
  • In Visual Studio, open the Output view (from the menu: View -> Output) and select "CMake" in the "Show output from:" dropdown menu.
  • Scroll to the beginning of that view. You should see two lines starting with "Command line" and "Working directory" respectively.
  • Cd to that working directory in the shell. For example, if the path in the "Working directory" line is C:\Users\Marco\AppData\Local\CMakeBuild\fa17dda0-4eec-6438-a358-e1253b7e86ff\build\x64-Debug, you can run cd "C:\Users\Marco\AppData\Local\CMakeBuild\fa17dda0-4eec-6438-a358-e1253b7e86ff\build\x64-Debug".
  • Cd to the "tests" subdirectory ("cd tests").
  • Then run pytest, e.g. py.test -n auto.

Sending pull requests

If you send a pull request, you should make sure that these CI tests are passing. They will run automatically on your pull request as soon as you send it.

As an exception, if the current master also failed the last CI run feel free to send the pull request anyway (you can go here to check if that's the case).

If a test fails, see the CI section above for informations on how to reproduce.

You should also make sure that your code:

  • Is formatted correctly (more details here)
  • Has appropriate tests (if your change is user-visible, or if you're introducing new branches that should be tested)

What to install in order to develop Fruit code

In addition to the compiler you need to install to build Fruit, when developing Fruit code you might need some of the following software. Note that depending on your change you may or may not need all of these; you might want to go ahead without these and then only install additional things if you get an error about a missing tool.

Useful command for fast edit/rebuild/retest cycles

This command uses Bazel to run the tests (so you need to have it installed in order to use this). Bazel has a much more fine-grained picture of what tests depend on what source files, so it will often avoid running tests that have passed before when it knows that they will pass (unlike py.test that runs the entire test suite every time). This is especially relevant for incremental builds when only test sources have changed (e.g. after adjusting an expectation in a test or fixing a bug in the test); there is little difference when changing src/ or include/ because all tests will be re-run anyway.

cd $PATH_TO_FRUIT/extras/bazel_root
bazel test --test_output=errors \ 
           --test_summary=terse \
           //third_party/fruit/...

Checking test coverage

Fruit's test suite supports collecting test coverage (only when building with GCC on Linux using CMake). Example commands:

cd $PATH_TO_FRUIT
mkdir build-coverage
cd build-coverage
CXX=g++-6 cmake .. -DCMAKE_BUILD_TYPE=RelWithDebInfo -DFRUIT_ENABLE_COVERAGE=ON
make -j 10
(cd tests; py.test-3 -n auto)
lcov --rc lcov_branch_coverage=1 --capture --directory . --output-file coverage.info
lcov --rc lcov_branch_coverage=1 --remove coverage.info '/usr/include/*' '/tmp/*' -o coverage-filtered.info
genhtml --no-function-coverage --rc lcov_branch_coverage=1 --rc genhtml_hi_limit=100 coverage-filtered.info --output-directory html
google-chrome html/index.html

The important figures for each file are:

  • Percentage of lines covered
  • Percentage of branches covered

Ideally, they should both be 100%. The LCOV_EXCL_LINE and LCOV_EXCL_BR_LINE markers can be used to mark lines and branches (respectively) that can't be covered and therefore should be excluded.

Note that the "percentage of functions covered" metric is not meaningful for Fruit, since it considers each instantiation of a template function/method as separate (even if they share the same source lines).

Code style

C++ code in Fruit should be indented using clang-format (a .clang-format file is provided in the Fruit root directory). You can re-indent all code using this command:

$ clang-format -i $(git ls-files | egrep '\.cpp|\.h' )

Reporting vulnerabilities

In case of a security vulnerability in Fruit, please contact poletti.marco@gmail.com directly instead of using the public issue tracker.