Gaudi CMake Documentation¶
This documentation is the updated version of https://twiki.cern.ch/twiki/bin/view/LHCb/GaudiCMakeConfiguration and is based on CMake 3.15. It was written after the modernization of the configuration of Gaudi.
Introduction¶
CMake is an Open Source, cross-platform configuration and build tool used in several projects around the world.
Among its advantages we can count the support that comes from a large user base and the CMake configuration language that doubles as a portable and powerful scripting language.
The main drawbacks of CMake are the syntax of its language (not very nice looking) and the lack of support for runtime environment definition, but, thanks to the power of the language, we can overcome the drawbacks.
Here I’ll describe how to write the CMake configuration for projects and packages. See also the CMake Documentation.
Understanding and Writing CMake Code¶
A minimal introduction on the CMake syntax and conventions is mandatory for people who never used it. info The syntax highlighting in the code blocks is not correct because TWiki.SyntaxHighlightingPlugin does not understand the CMake language.
In CMake every statement is a function call, written as an identifier
followed by optional spaces and the arguments to the function as a
space-separated list enclosed in parentheses. The arguments to a
function can span over several lines, and double quotes (") can be
used to pass arguments containing spaces and new-lines. Examples of
functions:
message("hello world")
if(1 GREATER 0)
message("this is true")
else()
message("this is false")
endif()
One can add comments to the code using # at the beginning of the
comment text (spaces preceding # are ignored), like, e.g., in Unix
shells and Python:
# I'm a comment
if(TRUE)
# this is always printed
message("it's true")
else() # this is never printed
message("it's false")
endif()
The CMake language supports variables, which are set with the function
set and dereferenced with ${...}, e.g.:
set(MyMessage "hello world")
message(${MyMessage})
Dereferencing of variables can be nested and works also in between double quotes:
set(name MyName)
set(${name}_msg "This is${name}")
message(${${name}_msg})
There is something special in the way CMake functions are invoked. CMake functions and macros (similar to functions) accept variable number of arguments and the only separators between arguments are spaces (tabs and new-lines too), so it might not be obvious how to pass optional arguments (like it’s done in Python with named arguments). The solution found by CMake developers is to use keyword-separated lists of arguments. For example, we can imagine a function that requires a mandatory argument name and two optional lists of files, C sources and C++ sources. In CMake you could find it invoked like this:
make_a_library(MyLibrary C_SOURCES file1.c file2.c file3.c)
make_a_library(MyLibrary CXX_SOURCES file1.cpp file2.cpp file3.cpp)
make_a_library(MyLibrary C_SOURCES file1.c file2.c file3.c CXX_SOURCES file1.cpp file2.cpp file3.cpp)
Warning: Function names are case-insensitive, but variable names are case sensitive as well as string comparison.
CMake Configuration of a Gaudi-based Project¶
Several steps must be performed to build a Gaudi based project:
Set up the build environment (if not already set up)
Configure the project with CMake (generate Makefile or build.ninja)
Compile the source files and link the binaries
Test the previously build binaries (optional but recommended)
Set up the build environment¶
To set up the build environment, some environment variables need to be set.
BINARY_TAG: the variable that describe the platform
CMAKE_PREFIX_PATH: is a path-like variable that must contain the list the list of path to:
the compiler e.g. g++, clang++ (the compiler may be a wrapper)
the build system e.g. make, ninja
all third-party dependencies e.g. Boost, ROOT
PATH (optional): may contain the paths to the compiler and the build system
There are several ways to set these variables: * use export several time (or run a shell script that will do so) * source a view (a shell script that sets the aforementioned variables to a directory of symlinks) * specify a toolchain to the configuration
With export¶
export BINARY_TAG="x86_64-centos7-gcc8-opt"
export CMAKE_PREFIX_PATH="/path/to/g++:/path/to/boost:/path/to/ROOT:..."
It is also possible to list the call to export in a shell script to be able to source it later on.
With a view¶
source/cvmfs/sft.cern.ch/lcg/views/LCG_96/x86_64-centos7-gcc8-opt/setup.sh
# the views may lack some stuff
export CMAKE_PREFIX_PATH="$CMAKE_PREFIX_PATH:/cvmfs/sft.cern.ch/lcg/releases/LCG_95/vectorclass/1.30/x86_64-centos7-gcc8-opt:/cvmfs/projects.cern.ch/intelsw/psxe/linux/x86_64/2019/vtune_amplifier"
Warning: Sourcing a view is not the same as sourcing a shell script that uses export. A view is a directory of symbolic links and a setup.sh script.
With a toolchain¶
# Either use
-D CMAKE_TOOLCHAIN_FILE=/path/to/a/toolchain
# at configure time when calling cmake
# or
ln -s /path/to/a/toolchain
toolchain.cmake
# right away
Configuration of the project¶
The configuration requires at least CMake 3.15. CMake 3.15.0 was released on 2019-07-17.
# Check CMake version
cmake --version
# if version < 3.15
export PATH="/cvmfs/lhcb.cern.ch/lib/contrib/CMake/3.15.2/Linux-x86_64/bin:$PATH"
The configuration is the step when CMake is called and produces the files for the build system (e.g. make, ninja).
Two directories must be specified: * the source tree: contains the sources * the build tree: will contain the outputs of the build
cmake -S . -B build.$BINARY_TAG
# options can be passed at configure time
cmake -S . -B build.$BINARY_TAG -G Ninja
# set the build system
cmake -S . -B build.$BINARY_TAG -D GAUDI_USE_AIDA=OFF
# enable/disable a third party dependency
cmake -S . -B build.$BINARY_TAG -D CMAKE_BUILD_TYPE=Developer
# select a build type (a set of compile and link options)
cmake -S . -B build.$BINARY_TAG -DCMAKE_TOOLCHAIN_FILE=toolchain.cmake
# specify a toolchain
# several options may be specified with: -D ... -D ... -D ...
# ccmake and cmake-gui can be used
cmake -LH build.$BINARY_TAG
# to see all the options and their help messages
Compilation of the project¶
Once the project is configured, several files are already in the build tree. They will be used to compile the project.
cd build.$BINARY_TAG
make # or ninja or an IDE
# or directly with CMake
cmake --build build.$BINARY_TAG
Test the binaries¶
Good developers test their code. To run the tests:
cd build.$BINARY_TAG
ctest -j <nproc> --output-on-failure --schedule-random
The wrapper¶
Doing all these steps each time may be tedious so there is a Makefile file at the top level of Gaudi-based projects to wrap the call to these commands.
# configure + compile
make
# run the tests
make test
The wrapper uses a toolchain if a file called toolchain.cmake exists in the current directory. It might be useful to have a shell function to easily switch from one toolchain to another.
function switch_platform {
export BINARY_TAG=$1
rm -f toolchain.cmake
ln -s /cvmfs/.../toolchains/$1.cmake toolchain.cmake # !! Use the right path on CVMFS
}
Use the software¶
In order to use the previously built software, it is mandatory to use the runtime environment (it may differ from the build environment). The runtime environment is generated by the configuration at configure time in the build tree in a script called run.
cd build.$BINARY_TAG
# ./run <program> <args...>
./run listcomponents -h
./run gaudirun.py
Modify the configuration¶
At the top level directory of a project and in every sub-project
(package) there must be one file: CMakeLists.txt
The file at the top level directory describes the build of the whole project: * may contain a licence block * contains documentation (how to configure it, available options) * describes the project (name, version) * fetches the dependencies * sets options for the build (C++ standard) * list all the sub-projects (packages in sub-directories) * handles the installation The files in the sub-projects directories: * describes the binaries that will be compiled (libraries, modules, executable, ROOT dictionaries) * register tests for these binaries * handles the installation of their python packages and scripts
Configuration of sub-projects¶
Look and feel of typical sub-project CMakeLists.txt:
# {licence block if needed}
# {SubdirName} subdirectory
# Build the library
gaudi_add_library(SubdirNameLib SOURCES src/Lib/Counter.cpp src/Lib/Event.cpp LINK PUBLIC GaudiKernel)
# Build the plugin gaudi_add_module(SubdirName
SOURCES src/AbortEvent/AbortEventAlg.cpp src/AlgSequencer/HelloWorld.cpp
LINK GaudiKernel GaudiExamplesLib ROOT::Tree Rangev3::rangev3)
if(GAUDI_USE_AIDA) # optional dependency
target_sources(SubdirName
PRIVATE src/EvtColsEx/EvtColAlg.cpp src/Histograms/Aida2Root.cpp)
target_link_libraries(SubdirName PRIVATE AIDA::aida)
endif()
# Build the executable
gaudi_add_executable(Allocator
SOURCES src/Allocator/Allocator.cpp src/Allocator/MyClass1.cpp
LINK SubdirNameLib GaudiKernel)
# Generate GaudiExamples_user.confdb
gaudi_generate_confuserdb()
# Tests
gaudi_add_tests(QMTest)
gaudi_add_pytest(tests/pytest)
# Compiled python module
gaudi_add_python_module(PyExample
SOURCES src/PythonModule/Functions.cpp src/PythonModule/PyExample.cpp
LINK Python::Python Boost::python)
# ROOT dictionaries
gaudi_add_dictionary(SubdirNameDict
HEADERFILES src/IO/dict.h
SELECTION src/IO/dict.xml
LINK SubdirNameLib)
# Install python modules
gaudi_install(PYTHON)
# Install other scripts
gaudi_install(SCRIPTS)
Why is the explicit list of sources mandatory?
Even tough CMake is
able to use glob patterns with file(GLOB...), those glob patterns
are expanded at configure time and their results hardcoded in
makefile or build.ninja or whichever file used by IDEs. This
means that if a new file that matches the pattern is added, there is no
way for the build system (make, ninja…) to notice it. The first
solution is to reconfigure the project each time a new file is added to
update the hardcoded list of sources. (This can be done either by
rerunning the configuration command or by touching a
CMakeLists.txt.) The other solution would be to forward the glob
pattern to the build system. CMake offers a way to do so:
file(GLOB ... CONFIGURE_DEPENDS) but for the time being, only
Makefiles generators and Ninja are supported, meaning that people using
IDEs would still have to reconfigure the project themselves.
Adding a new sub-project to the project¶
If a new sub-project is added to a project, its directory must be added
to the list of sub-projects in the top-level CMakeLists.txt
alongside with the other sub-projects with:
add_subdirectory(SubdirName)
The directory of the sub-project must also contain a CMakeLists.txt
that looks like the one above.
Adding a new third-party dependency¶
First, look in the documentation of the dependency. If it uses CMake, it
may provide a config file (a file named
{DependencyName}Config.cmake). Otherwise, it is necessary to write a
find module file (a file named Find{DependencyName}.cmake) that
will do the look up of this dependency (find the include directory, find
all the libraries, find any other useful files provided by the
dependency and create some IMPORTED targets). (Have a look at the other
find module files in the project to get an idea of what it should look
like. They should be in cmake/modules.)
Then, add the look up of the dependency in the file
cmake/{ProjectName}Dependencies.cmake (replace <DependencyName> with
the name of the dependency and <minVersion> with the minimal required
version).
# For mandatory dependencies
find_package(<DependencyName> <minVersion> ${__quiet})
set_package_properties(<DependencyName> PROPERTIES TYPE REQUIRED)
# For optional dependencies
if(GAUDI_USE_<DEPENDENCY_NAME>)
find_package(<DependencyName> <minVersion> ${__quiet})
if(CMAKE_FIND_PACKAGE_NAME)
# if the lookup is perform from ProjectConfig.cmake
# then, all optional dependencies become required
set_package_properties(<DependencyName> PROPERTIES TYPE REQUIRED)
else()
set_package_properties(<DependencyName> PROPERTIES TYPE RECOMMENDED)
endif()
endif()
# and add the option GAUDI_USE_<DEPENDENCY_NAME> in the top level CMakeLists.txt
#Finally, it is usable.
gaudi_add_<type>(... LINK ... Dependency::Target ...)
Removing an old third-party dependency¶
If a dependency is no longer used (nothing defined by it is used
anywhere), it is no use keeping to look for it. In this case, remove the
chunk of code that looks for it in
cmake/{ProjectName}Dependencies.cmake (see Adding a new third-party
dependency).
Then remove the find module file Find{DependencyName}.cmake in
cmake/modules if it exists.
Gaudi CMake functions to help the configuration¶
All the gaudi_*() functions are defined by Gaudi. Their content and
documentation can be found
here
in GaudiToolbox.cmake.
List of defined functions:
gaudi_add_library()gaudi_add_header_only_library()gaudi_add_module()gaudi_add_python_module()gaudi_add_executable()gaudi_add_tests()gaudi_add_dictionary()gaudi_install()gaudi_generate_confuserdb()gaudi_check_python_module()gaudi_generate_version_header_file()
Building a stack of project at once¶
With the configuration it is possible to build a stack of project at once. CMake may configure all the projects of the stack in one go, enabling the compilation to be done in parallel for all the projects.
Example of a stack: Gaudi, LHCb, Lbcom, Rec, Brunel
mkdir workspace
cd workspace
git clone project_url
# of all the projects of the desired stack
cat <<EOF > CMakeLists.txt
cmake_minimum_required(VERSION 3.15)
project(LHCbFullStack LANGUAGES CXX DESCRIPTION "LHCb full stack")
enable_testing()
add_subdirectory(Gaudi)
add_subdirectory(LHCb)
# add_subdirectory() ... all the other projects of the stack
EOF
Using GaudiObjDesc (LHCb-specific)¶
Warning: GaudiObjDesc has not been modernized because it should be removed soon. Do not use GaudiObjDesc in future project. However, if you need to maintain a package that uses GaudiObjDesc have a look at the old documentation here
Pro tip: do not document too much GaudiObjDesc so that people begrudge to use GaudiObjDesc.
Update old Gaudi Projects to the new CMake Configuration in v35¶
When updating an existing Gaudi Project to use v35, the following changes need to be made:
Add a
project(PROJECTNAME)line in the top level CMakeLists.txtchange
find_package(GaudiProject)tofind_package(Gaudi)in the top level CMakeLists.txtremove any calls to
gaudi_project(...)explicitly add all subdirectories that contain a CMakeLists.txt with
add_subdirectory(...)update any calls to
`gaudi_add_library`to use the new signatureupdate any calls to
`gaudi_add_module`to use the new signaturechange
gaudi_install_*()togaudi_install(*)Export all libraries and modules as targets with
install(TARGETS ... EXPORT ...)add a call to
gaudi_install(CMAKE)int the top level CMakeLists.txtadd a CMake config file
cmake/PROJECTNAMEConfig.cmakewhich should include the targets file
For a concrete example, see the changes needed to update key4hep framework core library: https://github.com/key4hep/k4FWCore/pull/19/files