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WPILib Project

CI C++ Documentation Java Documentation

Welcome to the WPILib project. This repository contains the HAL, WPILibJ, and WPILibC projects. These are the core libraries for creating robot programs for the roboRIO.

WPILib Mission

The WPILib Mission is to enable FIRST Robotics teams to focus on writing game-specific software rather than focusing on hardware details - "raise the floor, don't lower the ceiling". We work to enable teams with limited programming knowledge and/or mentor experience to be as successful as possible, while not hampering the abilities of teams with more advanced programming capabilities. We support Kit of Parts control system components directly in the library. We also strive to keep parity between major features of each language (Java, C++, and NI's LabVIEW), so that teams aren't at a disadvantage for choosing a specific programming language. WPILib is an open source project, licensed under the BSD 3-clause license. You can find a copy of the license here.

Quick Start

Below is a list of instructions that guide you through cloning, building, publishing and using local allwpilib binaries in a robot project. This quick start is not intended as a replacement for the information further listed in this document.

  1. Clone the repository with git clone https://github.com/wpilibsuite/allwpilib.git
  2. Build the repository with ./gradlew build or ./gradlew build --build-cache if you have an internet connection
  3. Publish the artifacts locally by running ./gradlew publish
  4. Update your build.gradle to use the artifacts

Building WPILib

Using Gradle makes building WPILib very straightforward. It only has a few dependencies on outside tools, such as the ARM cross compiler for creating roboRIO binaries.

Requirements

  • JDK 11
    • Note that the JRE is insufficient; the full JDK is required
    • On Ubuntu, run sudo apt install openjdk-11-jdk
    • On Windows, install the JDK 11 .msi from the link above
    • On macOS, install the JDK 11 .pkg from the link above
  • C++ compiler
    • On Linux, install GCC 11 or greater
    • On Windows, install Visual Studio Community 2022 and select the C++ programming language during installation (Gradle can't use the build tools for Visual Studio)
    • On macOS, install the Xcode command-line build tools via xcode-select --install
  • ARM compiler toolchain
    • Run ./gradlew installRoboRioToolchain after cloning this repository
    • If the WPILib installer was used, this toolchain is already installed
  • Raspberry Pi toolchain (optional)
    • Run ./gradlew installArm32Toolchain after cloning this repository

On macOS ARM, run softwareupdate --install-rosetta. This is necessary to be able to use the macOS x86 roboRIO toolchain on ARM.

Setup

Clone the WPILib repository and follow the instructions above for installing any required tooling.

See the styleguide README for wpiformat setup instructions. We use clang-format 14.

Building

All build steps are executed using the Gradle wrapper, gradlew. Each target that Gradle can build is referred to as a task. The most common Gradle task to use is build. This will build all the outputs created by WPILib. To run, open a console and cd into the cloned WPILib directory. Then:

./gradlew build

To build a specific subproject, such as WPILibC, you must access the subproject and run the build task only on that project. Accessing a subproject in Gradle is quite easy. Simply use :subproject_name:task_name with the Gradle wrapper. For example, building just WPILibC:

./gradlew :wpilibc:build

The gradlew wrapper only exists in the root of the main project, so be sure to run all commands from there. All of the subprojects have build tasks that can be run. Gradle automatically determines and rebuilds dependencies, so if you make a change in the HAL and then run ./gradlew :wpilibc:build, the HAL will be rebuilt, then WPILibC.

There are a few tasks other than build available. To see them, run the meta-task tasks. This will print a list of all available tasks, with a description of each task.

If opening from a fresh clone, generated java dependencies will not exist. Most IDEs will not run the generation tasks, which will cause lots of IDE errors. Manually run ./gradlew compileJava from a terminal to run all the compile tasks, and then refresh your IDE's configuration (In VS Code open settings.gradle and save).

Faster builds

./gradlew build builds everything, which includes debug and release builds for desktop and all installed cross compilers. Many developers don't need or want to build all of this. Therefore, common tasks have shortcuts to only build necessary components for common development and testing tasks.

./gradlew testDesktopCpp and ./gradlew testDesktopJava will build and run the tests for wpilibc and wpilibj respectively. They will only build the minimum components required to run the tests.

testDesktopCpp and testDesktopJava tasks also exist for the projects wpiutil, ntcore, cscore, hal wpilibNewCommands and cameraserver. These can be ran with ./gradlew :projectName:task.

./gradlew buildDesktopCpp and ./gradlew buildDesktopJava will compile wpilibcExamples and wpilibjExamples respectively. The results can't be ran, but they can compile.

Build Cache

Run with --build-cache on the command-line to use the shared build cache artifacts generated by the continuous integration server. Example:

./gradlew build --build-cache

Using Development Builds

Please read the documentation available here

Custom toolchain location

If you have installed the FRC Toolchain to a directory other than the default, or if the Toolchain location is not on your System PATH, you can pass the toolChainPath property to specify where it is located. Example:

./gradlew build -PtoolChainPath=some/path/to/frc/toolchain/bin

Gazebo simulation

If you also want to force building Gazebo simulation support, add -PforceGazebo. This requires gazebo_transport. We have tested on 14.04 and 15.05, but any correct install of Gazebo should work, even on Windows if you build Gazebo from source. Correct means CMake needs to be able to find gazebo-config.cmake. See The Gazebo website for installation instructions.

./gradlew build -PforceGazebo

If you prefer to use CMake directly, the you can still do so. The common CMake tasks are wpilibcSim, frc_gazebo_plugins, and gz_msgs

mkdir build #run this in the root of allwpilib
cd build
cmake ..
make

Formatting/linting

wpiformat

wpiformat can be executed anywhere in the repository via py -3 -m wpiformat -clang 14 on Windows or python3 -m wpiformat -clang 14 on other platforms.

Once a PR has been submitted, formatting can be run in CI by commenting /wpiformat on the PR. A new commit will be pushed with the formatting changes.

Java Code Quality Tools

The Java code quality tools Checkstyle, PMD, and Spotless can be run via ./gradlew javaFormat. SpotBugs can be run via the spotbugsMain, spotbugsTest, and spotbugsDev tasks. These tools will all be run automatically by the build task. To disable this behavior, pass the -PskipJavaFormat flag.

If you only want to run the Java autoformatter, run ./gradlew spotlessApply.

CMake

CMake is also supported for building. See README-CMAKE.md.

Publishing

If you are building to test with other dependencies or just want to export the build as a Maven-style dependency, simply run the publish task. This task will publish all available packages to ~/releases/maven/development. If you need to publish the project to a different repo, you can specify it with -Prepo=repo_name. Valid options are:

  • development - The default repo.
  • beta - Publishes to ~/releases/maven/beta.
  • stable - Publishes to ~/releases/maven/stable.
  • release - Publishes to ~/releases/maven/release.

The maven artifacts are described in MavenArtifacts.md

Structure and Organization

The main WPILib code you're probably looking for is in WPILibJ and WPILibC. Those directories are split into shared, sim, and athena. Athena contains the WPILib code meant to run on your roboRIO. Sim is WPILib code meant to run on your computer with Gazebo, and shared is code shared between the two. Shared code must be platform-independent, since it will be compiled with both the ARM cross-compiler and whatever desktop compiler you are using (g++, msvc, etc...).

The Simulation directory contains extra simulation tools and libraries, such as gz_msgs and JavaGazebo. See sub-directories for more information.

The integration test directories for C++ and Java contain test code that runs on our test-system. When you submit code for review, it is tested by those programs. If you add new functionality you should make sure to write tests for it so we don't break it in the future.

The hal directory contains more C++ code meant to run on the roboRIO. HAL is an acronym for "Hardware Abstraction Layer", and it interfaces with the NI Libraries. The NI Libraries contain the low-level code for controlling devices on your robot. The NI Libraries are found in the ni-libraries project.

The upstream_utils directory contains scripts for updating copies of thirdparty code in the repository.

The styleguide repository contains our style guides for C++ and Java code. Anything submitted to the WPILib project needs to follow the code style guides outlined in there. For details about the style, please see the contributors document here.

Contributing to WPILib

See CONTRIBUTING.md.