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A template CMake project to get you started with C++ and tooling

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cpp_starter_project

Build status CMake codecov Language grade: C++

Getting Started

Use the Github template

First, click the green Use this template button near the top of this page. This will take you to Github's 'Generate Repository' page. Fill in a repository name and short description, and click 'Create repository from template'. This will allow you to create a new repository in your Github account, prepopulated with the contents of this project. Now you can clone the project locally and get to work!

git clone https://github.com/<user>/<your_new_repo>.git

Remove frameworks you're not going to use

If you know you're not going to use one or more of the optional gui/graphics frameworks (fltk, gtkmm, imgui, etc.), you can remove them with git rm:

git rm -r src/<unnecessary_framework>

Dependencies

Note about install commands:

  • for Windows, we use choco.
  • for MacOS, we use brew.
  • In case of an error in cmake, make sure that the dependencies are on the PATH.

Too Long, Didn't Install

This is a really long list of dependencies, and it's easy to mess up. That's why we have a Docker image that's already set up for you. See the Docker instructions below.

Necessary Dependencies

  1. A C++ compiler that supports C++17. See cppreference.com to see which features are supported by each compiler. The following compilers should work:
  • gcc 7+

    Install command
    • Debian/Ubuntu:

        sudo apt install build-essential
      
    • Windows:

        choco install mingw -y
      
    • MacOS:

        brew install gcc
      
  • clang 6+

    Install command
    • Debian/Ubuntu:

        bash -c "$(wget -O - https://apt.llvm.org/llvm.sh)"
      
    • Windows:

      Visual Studio 2019 ships with LLVM (see the Visual Studio section). However, to install LLVM separately:

        choco install llvm -y
      

      llvm-utils for using external LLVM with Visual Studio generator:

        git clone https://github.com/zufuliu/llvm-utils.git
        cd llvm-utils/VS2017
        .\install.bat
      
    • MacOS:

        brew install llvm
      
  • Visual Studio 2019 or higher

    Install command + Environment setup

    On Windows, you need to install Visual Studio 2019 because of the SDK and libraries that ship with it.

    Visual Studio IDE - 2019 Community (installs Clang too):

    choco install -y visualstudio2019community --package-parameters "add Microsoft.VisualStudio.Workload.NativeDesktop --includeRecommended --includeOptional --passive --locale en-US"
    

    Put MSVC compiler, Clang compiler, and vcvarsall.bat on the path:

    	choco install vswhere -y
    	refreshenv
    
    	# change to x86 for 32bit
    	$clpath = vswhere -products * -latest -prerelease -find **/Hostx64/x64/*
    	$clangpath = vswhere -products * -latest -prerelease -find **/Llvm/bin/*
    	$vcvarsallpath =  vswhere -products * -latest -prerelease -find **/Auxiliary/Build/*
    
    	$path = [System.Environment]::GetEnvironmentVariable("PATH", "User")
    	[Environment]::SetEnvironmentVariable("Path", $path + ";$clpath" + ";$clangpath" + ";$vcvarsallpath", "User")
    	refreshenv
    
  1. Conan

    Install Command
  2. CMake 3.15+

    Install Command
    • Debian/Ubuntu:

        sudo apt-get install cmake
      
    • Windows:

        choco install cmake -y
      
    • MacOS:

        brew install cmake
      

Optional Dependencies

C++ Tools

  • Doxygen

    Install Command
    • Debian/Ubuntu:

        sudo apt-get install doxygen
        sudo apt-get install graphviz
      
    • Windows:

        choco install doxygen.install -y
        choco install graphviz -y
      
    • MacOS:

        brew install doxygen
        brew install graphviz
      
  • ccache

    Install Command
    • Debian/Ubuntu:

        sudo apt-get install ccache
      
    • Windows:

        choco install ccache -y
      
    • MacOS:

        brew install ccache
      
  • Cppcheck

    Install Command
    • Debian/Ubuntu:

        sudo apt-get install cppcheck
      
    • Windows:

        choco install cppcheck -y
      
    • MacOS:

        brew install cppcheck
      
  • include-what-you-use

    Install Command

    Follow instructions here: https://github.com/include-what-you-use/include-what-you-use#how-to-install

GUI libraries

This project can be made to work with several optional GUI frameworks.

If desired, you should install the following optional dependencies as directed by their documentation, linked here:

The following dependencies can be downloaded automatically by CMake and Conan. All you need to do to install them is to turn on a CMake flag during configuration. If you run into difficulty using them, please refer to their documentation, linked here:

  • NANA
  • SDL
  • IMGUI: This framework depends on SFML, and if you are using Linux, you may need to install several of SFML's dependencies using your package manager. See the SFML build tutorial for specifics.

Build Instructions

A full build has different steps:

  1. Specifying the compiler using environment variables
  2. Configuring the project
  3. Building the project

For the subsequent builds, in case you change the source code, you only need to repeat the last step.

(1) Specify the compiler using environment variables

By default (if you don't set environment variables CC and CXX), the system default compiler will be used.

Conan and CMake use the environment variables CC and CXX to decide which compiler to use. So to avoid the conflict issues only specify the compilers using these variables.

CMake will detect which compiler was used to build each of the Conan targets. If you build all of your Conan targets with one compiler, and then build your CMake targets with a different compiler, the project may fail to build.

Commands for setting the compilers
  • Debian/Ubuntu/MacOS:

    Set your desired compiler (clang, gcc, etc):

    • Temporarily (only for the current shell)

      Run one of the followings in the terminal:

      • clang

          CC=clang CXX=clang++
        
      • gcc

          CC=gcc CXX=g++
        
    • Permanent:

      Open ~/.bashrc using your text editor:

        gedit ~/.bashrc
      

      Add CC and CXX to point to the compilers:

        export CC=clang
        export CXX=clang++
      

      Save and close the file.

  • Windows:

    • Permanent:

      Run one of the followings in PowerShell:

      • Visual Studio generator and compiler (cl)

          [Environment]::SetEnvironmentVariable("CC", "cl.exe", "User")
          [Environment]::SetEnvironmentVariable("CXX", "cl.exe", "User")
          refreshenv
        

        Set the architecture using vcvarsall:

          vcvarsall.bat x64
        
      • clang

          [Environment]::SetEnvironmentVariable("CC", "clang.exe", "User")
          [Environment]::SetEnvironmentVariable("CXX", "clang++.exe", "User")
          refreshenv
        
      • gcc

          [Environment]::SetEnvironmentVariable("CC", "gcc.exe", "User")
          [Environment]::SetEnvironmentVariable("CXX", "g++.exe", "User")
          refreshenv
        
    • Temporarily (only for the current shell):

      	$Env:CC="clang.exe"
      	$Env:CXX="clang++.exe"
      

(2) Configure your build

To configure the project, you could use cmake, or ccmake or cmake-gui. Each of them are explained in the following:

(2.a) Configuring via cmake:

With Cmake directly:

cmake -S . -B ./build

Cmake will automatically create the ./build folder if it does not exist, and it wil configure the project.

(2.b) Configuring via ccmake:

With the Cmake Curses Dialog Command Line tool:

ccmake -S . -B ./build

Once ccmake has finished setting up, press 'c' to configure the project, press 'g' to generate, and 'q' to quit.

(2.c) Configuring via cmake-gui:

To use the GUI of the cmake:

2.c.1) Open cmake-gui from the project directory:

cmake-gui .

2.c.2) Set the build directory:

build_dir

2.c.3) Configure the generator:

In cmake-gui, from the upper menu select Tools/Configure.

Warning: if you have set CC and CXX always choose the use default native compilers option. This picks CC and CXX. Don't change the compiler at this stage!

Windows - MinGW Makefiles

Choose MinGW Makefiles as the generator:

mingw
Windows - Visual Studio generator and compiler

You should have already set C and CXX to cl.exe.

Choose "Visual Studio 16 2019" as the generator:

default_vs
Windows - Visual Studio generator and Clang Compiler

You should have already set C and CXX to clang.exe and clang++.exe.

Choose "Visual Studio 16 2019" as the generator. To tell Visual studio to use clang-cl.exe:

  • If you use the LLVM that is shipped with Visual Studio: write ClangCl under "optional toolset to use".
visual_studio
  • If you use an external LLVM: write LLVM_v142 under "optional toolset to use".
visual_studio

2.c.4) Choose the Cmake options and then generate:

generate

(3) Build the project

Once you have selected all the options you would like to use, you can build the project (all targets):

cmake --build ./build

For Visual Studio, give the build configuration (Release, RelWithDeb, Debug, etc) like the following:

cmake --build ./build -- /p:configuration=Release

Running the tests

You can use the ctest command run the tests.

cd ./build
ctest -C Debug
cd ../

Troubleshooting

Update Conan

Many problems that users have can be resolved by updating Conan, so if you are having any trouble with this project, you should start by doing that.

To update conan:

pip install --user --upgrade conan

You may need to use pip3 instead of pip in this command, depending on your platform.

Clear Conan cache

If you continue to have trouble with your Conan dependencies, you can try clearing your Conan cache:

conan remove -f '*'

The next time you run cmake or cmake --build, your Conan dependencies will be rebuilt. If you aren't using your system's default compiler, don't forget to set the CC, CXX, CMAKE_C_COMPILER, and CMAKE_CXX_COMPILER variables, as described in the 'Build using an alternate compiler' section above.

Identifying misconfiguration of Conan dependencies

If you have a dependency 'A' that requires a specific version of another dependency 'B', and your project is trying to use the wrong version of dependency 'B', Conan will produce warnings about this configuration error when you run CMake. These warnings can easily get lost between a couple hundred or thousand lines of output, depending on the size of your project.

If your project has a Conan configuration error, you can use conan info to find it. conan info displays information about the dependency graph of your project, with colorized output in some terminals.

cd build
conan info .

In my terminal, the first couple lines of conan info's output show all of the project's configuration warnings in a bright yellow font.

For example, the package spdlog/1.5.0 depends on the package fmt/6.1.2. If you were to modify the file conanfile.py so that it requires an earlier version of fmt, such as fmt/6.0.0, and then run:

conan remove -f '*'       # clear Conan cache
rm -rf build              # clear previous CMake build
cmake -S . -B ./build     # rebuild Conan dependencies
conan info ./build

...the first line of output would be a warning that spdlog needs a more recent version of fmt.

Testing

See Catch2 tutorial

Fuzz testing

See libFuzzer Tutorial

Docker Instructions

If you have Docker installed, you can run this in your terminal, when the Dockerfile is in your working directory:

docker build --tag=my_project:latest .
docker run -it my_project:latest

This command will put you in a bash session in a Ubuntu 18.04 Docker container, with all of the tools listed in the Dependencies section already installed. Additionally, you will have g++-10 and clang++-11 installed as the default versions of g++ and clang++.

If you want to build this container using some other versions of gcc and clang, you may do so with the GCC_VER and LLVM_VER arguments:

docker build --tag=myproject:latest --build-arg GCC_VER=9 --build-arg LLVM_VER=10 .

The CC and CXX environment variables are set to GCC version 10 by default. If you wish to use clang as your default CC and CXX environment variables, you may do so like this:

docker build --tag=my_project:latest --build-arg USE_CLANG=1 .

You will be logged in as root, so you will see the # symbol as your prompt. You will be in a directory that contains a copy of the cpp_starter_project; any changes you make to your local copy will not be updated in the Docker image until you rebuild it. If you need to mount your local copy directly in the Docker image, see Docker volumes docs. TLDR:

docker run -it \
	-v absolute_path_on_host_machine:absolute_path_in_guest_container \
	my_project:latest

You can configure and build as directed above using these commands:

/starter_project# mkdir build
/starter_project# cmake -S . -B ./build
/starter_project# cmake --build ./build

You can configure and build using clang-11, without rebuilding the container, with these commands:

/starter_project# mkdir build
/starter_project# CC=clang CXX=clang++ cmake -S . -B ./build
/starter_project# cmake --build ./build

The ccmake tool is also installed; you can substitute ccmake for cmake to configure the project interactively. All of the tools this project supports are installed in the Docker image; enabling them is as simple as flipping a switch using the ccmake interface. Be aware that some of the sanitizers conflict with each other, so be sure to run them separately.

A script called build_examples.sh is provided to help you to build the example GUI projects in this container.

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