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|
CMake Tutorial
**************
.. only:: html
.. contents::
The CMake tutorial provides a step-by-step guide that covers common build
system issues that CMake helps address. Seeing how various topics all
work together in an example project can be very helpful. The tutorial
documentation and source code for examples can be found in the
``Help/guide/tutorial`` directory of the CMake source code tree. Each step has
its own subdirectory containing code that may be used as a starting point. The
tutorial examples are progressive so that each step provides the complete
solution for the previous step.
A Basic Starting Point (Step 1)
===============================
The most basic project is an executable built from source code files.
For simple projects, a three line CMakeLists file is all that is required.
This will be the starting point for our tutorial. Create a ``CMakeLists.txt``
file in the ``Step1`` directory that looks like:
.. code-block:: cmake
cmake_minimum_required(VERSION 3.10)
# set the project name
project(Tutorial)
# add the executable
add_executable(Tutorial tutorial.cxx)
Note that this example uses lower case commands in the CMakeLists file.
Upper, lower, and mixed case commands are supported by CMake. The source
code for ``tutorial.cxx`` is provided in the ``Step1`` directory and can be
used to compute the square root of a number.
Adding a Version Number and Configured Header File
--------------------------------------------------
The first feature we will add is to provide our executable and project with a
version number. While we could do this exclusively in the source code, using
CMakeLists provides more flexibility.
First, modify the CMakeLists file to set the version number.
.. literalinclude:: Step2/CMakeLists.txt
:language: cmake
:end-before: # specify the C++ standard
Then, configure a header file to pass the version number to the source
code:
.. literalinclude:: Step2/CMakeLists.txt
:language: cmake
:start-after: # to the source code
:end-before: # add the executable
Since the configured file will be written into the binary tree, we
must add that directory to the list of paths to search for include
files. Add the following lines to the end of the CMakeLists file:
.. literalinclude:: Step2/CMakeLists.txt
:language: cmake
:start-after: # so that we will find TutorialConfig.h
Using your favorite editor, create ``TutorialConfig.h.in`` in the source
directory with the following contents:
.. literalinclude:: Step2/TutorialConfig.h.in
:language: cmake
When CMake configures this header file the values for
``@Tutorial_VERSION_MAJOR@`` and ``@Tutorial_VERSION_MINOR@`` will be
replaced.
Next modify ``tutorial.cxx`` to include the configured header file,
``TutorialConfig.h``.
Finally, let's print out the version number by updating ``tutorial.cxx`` as
follows:
.. literalinclude:: Step2/tutorial.cxx
:language: c++
:start-after: {
:end-before: // convert input to double
Specify the C++ Standard
-------------------------
Next let's add some C++11 features to our project by replacing ``atof`` with
``std::stod`` in ``tutorial.cxx``. At the same time, remove
``#include <cstdlib>``.
.. literalinclude:: Step2/tutorial.cxx
:language: c++
:start-after: // convert input to double
:end-before: // calculate square root
We will need to explicitly state in the CMake code that it should use the
correct flags. The easiest way to enable support for a specific C++ standard
in CMake is by using the ``CMAKE_CXX_STANDARD`` variable. For this tutorial,
set the ``CMAKE_CXX_STANDARD`` variable in the CMakeLists file to 11 and
``CMAKE_CXX_STANDARD_REQUIRED`` to True:
.. literalinclude:: Step2/CMakeLists.txt
:language: cmake
:end-before: # configure a header file to pass some of the CMake settings
Build and Test
--------------
Run **cmake** or **cmake-gui** to configure the project and then build it
with your chosen build tool.
For example, from the command line we could navigate to the
``Help/guide/tutorial`` directory of the CMake source code tree and run the
following commands:
.. code-block:: console
mkdir Step1_build
cd Step1_build
cmake ../Step1
cmake --build .
Navigate to the directory where Tutorial was built (likely the make directory
or a Debug or Release build configuration subdirectory) and run these commands:
.. code-block:: console
Tutorial 4294967296
Tutorial 10
Tutorial
Adding a Library (Step 2)
=========================
Now we will add a library to our project. This library will contain our own
implementation for computing the square root of a number. The executable can
then use this library instead of the standard square root function provided by
the compiler.
For this tutorial we will put the library into a subdirectory
called MathFunctions. This directory already contains a header file,
``MathFunctions.h``, and a source file ``mysqrt.cxx``. The source file has one
function called ``mysqrt`` that provides similar functionality to the
compiler's ``sqrt`` function.
Add the following one line ``CMakeLists.txt`` file to the MathFunctions
directory:
.. literalinclude:: Step3/MathFunctions/CMakeLists.txt
:language: cmake
To make use of the new library we will add an ``add_subdirectory`` call in the
top-level CMakeLists file so that the library will get built. We add the new
library to the executable, and add MathFunctions as an include directory so
that the ``mqsqrt.h`` header file can be found. The last few lines of the
top-level CMakeLists file should now look like:
.. code-block:: cmake
# add the MathFunctions library
add_subdirectory(MathFunctions)
# add the executable
add_executable(Tutorial tutorial.cxx)
target_link_libraries(Tutorial PUBLIC MathFunctions)
# add the binary tree to the search path for include files
# so that we will find TutorialConfig.h
target_include_directories(Tutorial PUBLIC
"${PROJECT_BINARY_DIR}"
"${PROJECT_SOURCE_DIR}/MathFunctions"
)
Now let us make the MathFunctions library optional. While for the tutorial
there really isn’t any need to do so, for larger projects this is a common
occurrence. The first step is to add an option to the top-level CMakeLists
file.
.. literalinclude:: Step3/CMakeLists.txt
:language: cmake
:start-after: # should we use our own math functions
:end-before: # add the MathFunctions library
This option will be displayed in the CMake GUI and ccmake with a default
value of ON that can be changed by the user. This setting will be stored in
the cache so that the user does not need to set the value each time they run
CMake on a build directory.
The next change is to make building and linking the MathFunctions library
conditional. To do this we change the end of the top-level CMakeLists file to
look like the following:
.. literalinclude:: Step3/CMakeLists.txt
:language: cmake
:start-after: # add the MathFunctions library
Note the use of the variable ``EXTRA_LIBS`` to collect up any optional
libraries to later be linked into the executable. The variable
``EXTRA_INCLUDES`` is used similarly for optional header files. This is a
classic approach when dealing with many optional components, we will cover
the modern approach in the next step.
The corresponding changes to the source code are fairly straightforward. First,
in ``tutorial.cxx``, include the MathFunctions header if we need it:
.. literalinclude:: Step3/tutorial.cxx
:language: c++
:start-after: // should we include the MathFunctions header
:end-before: int main
Then, in the same file, make which square root function is used dependent on
``USE_MYMATH``:
.. literalinclude:: Step3/tutorial.cxx
:language: c++
:start-after: // which square root function should we use?
:end-before: std::cout << "The square root of
Since the source code now requires ``USE_MYMATH`` we can add it to
``TutorialConfig.h.in`` with the following line:
.. literalinclude:: Step3/TutorialConfig.h.in
:language: c
:lines: 4
**Exercise**: Why is it important that we configure ``TutorialConfig.h.in``
after the option for ``USE_MYMATH``? What would happen if we inverted the two?
Run **cmake** or **cmake-gui** to configure the project and then build it
with your chosen build tool. Then run the built Tutorial executable.
Use ccmake or the CMake GUI to update the value of ``USE_MYMATH``. Rebuild and
run the tutorial again. Which function gives better results, sqrt or mysqrt?
Adding Usage Requirements for Library (Step 3)
==============================================
Usage requirements allow for far better control over a library or executable's
link and include line while also giving more control over the transitive
property of targets inside CMake. The primary commands that leverage usage
requirements are:
- ``target_compile_definitions``
- ``target_compile_options``
- ``target_include_directories``
- ``target_link_libraries``
Let's refactor our code from `Adding a Library (Step 2)`_ to use the modern
CMake approach of usage requirements. We first state that anybody linking to
MathFunctions needs to include the current source directory, while
MathFunctions itself doesn't. So this can become an ``INTERFACE`` usage
requirement.
Remember ``INTERFACE`` means things that consumers require but the producer
doesn't. Add the following lines to the end of ``MathFunctions/CMakeLists.txt``:
.. literalinclude:: Step4/MathFunctions/CMakeLists.txt
:language: cmake
:start-after: # to find MathFunctions.h
Now that we've specified usage requirements for MathFunctions we can safely
remove our uses of the ``EXTRA_INCLUDES`` variable from the top-level
CMakeLists, here:
.. literalinclude:: Step4/CMakeLists.txt
:language: cmake
:start-after: # add the MathFunctions library
:end-before: # add the executable
And here:
.. literalinclude:: Step4/CMakeLists.txt
:language: cmake
:start-after: # so that we will find TutorialConfig.h
Once this is done, run **cmake** or **cmake-gui** to configure the project
and then build it with your chosen build tool or by using ``cmake --build .``
from the build directory.
Installing and Testing (Step 4)
===============================
Now we can start adding install rules and testing support to our project.
Install Rules
-------------
The install rules are fairly simple: for MathFunctions we want to install the
library and header file and for the application we want to install the
executable and configured header.
So to the end of ``MathFunctions/CMakeLists.txt`` we add:
.. literalinclude:: Step5/MathFunctions/CMakeLists.txt
:language: cmake
:start-after: # install rules
And to the end of the top-level ``CMakeLists.txt`` we add:
.. literalinclude:: Step5/CMakeLists.txt
:language: cmake
:start-after: # add the install targets
:end-before: # enable testing
That is all that is needed to create a basic local install of the tutorial.
Run **cmake** or **cmake-gui** to configure the project and then build it
with your chosen build tool. Run the install step by typing
``cmake --install .`` (introduced in 3.15, older versions of CMake must use
``make install``) from the command line, or build the ``INSTALL`` target from
an IDE. This will install the appropriate header files, libraries, and
executables.
The CMake variable ``CMAKE_INSTALL_PREFIX`` is used to determine the root of
where the files will be installed. If using ``cmake --install`` a custom
installation directory can be given via ``--prefix`` argument. For
multi-configuration tools, use the ``--config`` argument to specify the
configuration.
Verify that the installed Tutorial runs.
Testing Support
---------------
Next let's test our application. At the end of the top-level CMakeLists file we
can enable testing and then add a number of basic tests to verify that the
application is working correctly.
.. literalinclude:: Step5/CMakeLists.txt
:language: cmake
:start-after: # enable testing
The first test simply verifies that the application runs, does not segfault or
otherwise crash, and has a zero return value. This is the basic form of a CTest
test.
The next test makes use of the ``PASS_REGULAR_EXPRESSION`` test property to
verify that the output of the test contains certain strings. In this case,
verifying that the the usage message is printed when an incorrect number of
arguments are provided.
Lastly, we have a function called ``do_test`` that runs the application and
verifies that the computed square root is correct for given input. For each
invocation of ``do_test``, another test is added to the project with a name,
input, and expected results based on the passed arguments.
Rebuild the application and then cd to the binary directory and run
``ctest -N`` and ``ctest -VV``. For multi-config generators (e.g. Visual
Studio), the configuration type must be specified. To run tests in Debug mode,
for example, use ``ctest -C Debug -VV`` from the build directory (not the
Debug subdirectory!). Alternatively, build the ``RUN_TESTS`` target from the
IDE.
Adding System Introspection (Step 5)
====================================
Let us consider adding some code to our project that depends on features the
target platform may not have. For this example, we will add some code that
depends on whether or not the target platform has the ``log`` and ``exp``
functions. Of course almost every platform has these functions but for this
tutorial assume that they are not common.
If the platform has ``log`` and ``exp`` then we will use them to compute the
square root in the ``mysqrt`` function. We first test for the availability of
these functions using the ``CheckSymbolExists.cmake`` macro in the top-level
CMakeLists. We're going to use the new defines in ``TutorialConfig.h.in``,
so be sure to set them before that file is configured.
.. literalinclude:: Step6/MathFunctions/CMakeLists.txt
:language: cmake
:start-after: # does this system provide the log and exp functions?
:end-before: if(HAVE_LOG AND HAVE_EXP)
Now let's add these defines to ``TutorialConfig.h.in`` so that we can use them
from ``mysqrt.cxx``:
.. code-block:: console
// does the platform provide exp and log functions?
#cmakedefine HAVE_LOG
#cmakedefine HAVE_EXP
Modify ``mysqrt.cxx`` to include cmath. Next, in that same file in the
``mysqrt`` function we can provide an alternate implementation based on
``log`` and ``exp`` if they are available on the system using the following
code (don't forget the ``#endif`` before returning the result!):
.. literalinclude:: Step6/MathFunctions/mysqrt.cxx
:language: c++
:start-after: // if we have both log and exp then use them
:end-before: // do ten iterations
Run **cmake** or **cmake-gui** to configure the project and then build it
with your chosen build tool and run the Tutorial executable.
You will notice that we're not using ``log`` and ``exp``, even if we think they
should be available. We should realize quickly that we have forgotten to include
``TutorialConfig.h`` in ``mysqrt.cxx``.
We will also need to update MathFunctions/CMakeLists so ``mysqrt.cxx`` knows
where this file is located:
.. code-block:: cmake
target_include_directories(MathFunctions
INTERFACE ${CMAKE_CURRENT_SOURCE_DIR}
PRIVATE ${CMAKE_BINARY_DIR}
)
After making this update, go ahead and build the project again and run the built
Tutorial executable. If ``log`` and ``exp`` are still not being used, open the
generated ``TutorialConfig.h`` file from the build directory. Maybe they aren't
available on the current system?
Which function gives better results now, sqrt or mysqrt?
Specify Compile Definition
--------------------------
Is there a better place for us to save the ``HAVE_LOG`` and ``HAVE_EXP`` values
other than in ``TutorialConfig.h``? Let's try to use
``target_compile_definitions``.
First, remove the defines from ``TutorialConfig.h.in``. We no longer need to
include ``TutorialConfig.h`` from ``mysqrt.cxx`` or the extra include in
MathFunctions/CMakeLists.
Next, we can move the check for ``HAVE_LOG`` and ``HAVE_EXP`` to
MathFunctions/CMakeLists and then add specify those values as ``PRIVATE``
compile definitions.
.. literalinclude:: Step6/MathFunctions/CMakeLists.txt
:language: cmake
:start-after: # does this system provide the log and exp functions?
:end-before: # install rules
After making these updates, go ahead and build the project again. Run the
built Tutorial executable and verify that the results are same as earlier in
this step.
Adding a Custom Command and Generated File (Step 6)
===================================================
Suppose, for the purpose of this tutorial, we decide that we never want to use
the platform ``log`` and ``exp`` functions and instead would like to
generate a table of precomputed values to use in the ``mysqrt`` function.
In this section, we will create the table as part of the build process,
and then compile that table into our application.
First, let's remove the check for the ``log`` and ``exp`` functions in
MathFunctions/CMakeLists. Then remove the check for ``HAVE_LOG`` and
``HAVE_EXP`` from ``mysqrt.cxx``. At the same time, we can remove
:code:`#include <cmath>`.
In the MathFunctions subdirectory, a new source file named ``MakeTable.cxx``
has been provided to generate the table.
After reviewing the file, we can see that the table is produced as valid C++
code and that the output filename is passed in as an argument.
The next step is to add the appropriate commands to MathFunctions CMakeLists
file to build the MakeTable executable and then run it as part of the build
process. A few commands are needed to accomplish this.
First, at the top of MathFunctions/CMakeLists, the executable for ``MakeTable``
is added as any other executable would be added.
.. literalinclude:: Step7/MathFunctions/CMakeLists.txt
:language: cmake
:start-after: # first we add the executable that generates the table
:end-before: # add the command to generate the source code
Then we add a custom command that specifies how to produce ``Table.h``
by running MakeTable.
.. literalinclude:: Step7/MathFunctions/CMakeLists.txt
:language: cmake
:start-after: # add the command to generate the source code
:end-before: # add the main library
Next we have to let CMake know that ``mysqrt.cxx`` depends on the generated
file ``Table.h``. This is done by adding the generated ``Table.h`` to the list
of sources for the library MathFunctions.
.. literalinclude:: Step7/MathFunctions/CMakeLists.txt
:language: cmake
:start-after: # add the main library
:end-before: # state that anybody linking
We also have to add the current binary directory to the list of include
directories so that ``Table.h`` can be found and included by ``mysqrt.cxx``.
.. literalinclude:: Step7/MathFunctions/CMakeLists.txt
:start-after: # state that we depend on our bin
:end-before: # install rules
Now let's use the generated table. First, modify ``mysqrt.cxx`` to include
``Table.h``. Next, we can rewrite the mysqrt function to use the table:
.. literalinclude:: Step7/MathFunctions/mysqrt.cxx
:language: c++
:start-after: // a hack square root calculation using simple operations
Run **cmake** or **cmake-gui** to configure the project and then build it
with your chosen build tool.
When this project is built it will first build the ``MakeTable`` executable.
It will then run ``MakeTable`` to produce ``Table.h``. Finally, it will
compile ``mysqrt.cxx`` which includes ``Table.h`` to produce the MathFunctions
library.
Run the Tutorial executable and verify that it is using the table.
Building an Installer (Step 7)
==============================
Next suppose that we want to distribute our project to other people so that
they can use it. We want to provide both binary and source distributions on a
variety of platforms. This is a little different from the install we did
previously in `Installing and Testing (Step 4)`_ , where we were
installing the binaries that we had built from the source code. In this
example we will be building installation packages that support binary
installations and package management features. To accomplish this we will use
CPack to create platform specific installers. Specifically we need to add
a few lines to the bottom of our top-level ``CMakeLists.txt`` file.
.. literalinclude:: Step8/CMakeLists.txt
:language: cmake
:start-after: # setup installer
That is all there is to it. We start by including
``InstallRequiredSystemLibraries``. This module will include any runtime
libraries that are needed by the project for the current platform. Next we
set some CPack variables to where we have stored the license and version
information for this project. The version information was set earlier in this
tutorial and the ``license.txt`` has been included in the top-level source
directory for this step.
Finally we include the CPack module which will use these variables and some
other properties of the current system to setup an installer.
The next step is to build the project in the usual manner and then run
CPack on it. To build a binary distribution, from the binary directory run:
.. code-block:: console
cpack
To specify the generator, use the ``-G`` option. For multi-config builds, use
``-C`` to specify the configuration. For example:
.. code-block:: console
cpack -G ZIP -C Debug
To create a source distribution you would type:
.. code-block:: console
cpack --config CPackSourceConfig.cmake
Alternatively, run ``make package`` or right click the ``Package`` target and
``Build Project`` from an IDE.
Run the installer found in the binary directory. Then run the
installed executable and verify that it works.
Adding Support for a Dashboard (Step 8)
=======================================
Adding support for submitting our test results to a dashboard is very easy. We
already defined a number of tests for our project in `Testing Support`_. Now we
just have to run those tests and submit them to a dashboard. To include support
for dashboards we include the CTest module in our top-level ``CMakeLists.txt``.
Replace:
.. code-block:: cmake
# enable testing
enable_testing()
With:
.. code-block:: cmake
# enable dashboard scripting
include(CTest)
The CTest module will automatically call ``enable_testing()``, so
we can remove it from our CMake files.
We will also need to create a ``CTestConfig.cmake`` file in the top-level
directory where we can specify the name of the project and where to submit the
dashboard.
.. literalinclude:: Step9/CTestConfig.cmake
:language: cmake
CTest will read in this file when it runs. To create a simple dashboard you can
run **cmake** or **cmake-gui** to configure the project, but do not build it
yet. Instead, change directory to the binary tree, and then run::
ctest [-VV] –D Experimental
Remember, for multi-config generators (e.g. Visual Studio), the configuration
type must be specified::
ctest [-VV] -C Debug –D Experimental
Or, from an IDE, build the ``Experimental`` target.
Ctest will build and test the project and submit the results to the Kitware
public dashboard. The results of your dashboard will be uploaded to Kitware's
public dashboard here: https://my.cdash.org/index.php?project=CMakeTutorial.
Mixing Static and Shared (Step 9)
=================================
In this section we will show how by using the ``BUILD_SHARED_LIBS`` variable
we can control the default behavior of ``add_library``, and allow control
over how libraries without an explicit type (STATIC/SHARED/MODULE/OBJECT) are
built.
To accomplish this we need to add ``BUILD_SHARED_LIBS`` to the top-level
``CMakeLists.txt``. We use the ``option`` command as it allows users to
optionally select if the value should be On or Off.
Next we are going to refactor MathFunctions to become a real library that
encapsulates using ``mysqrt`` or ``sqrt``, instead of requiring the calling
code to do this logic. This will also mean that ``USE_MYMATH`` will not control
building MathFuctions, but instead will control the behavior of this library.
The first step is to update the starting section of the top-level
``CMakeLists.txt`` to look like:
.. literalinclude:: Step10/CMakeLists.txt
:language: cmake
:end-before: # add the binary tree
Now that we have made MathFunctions always be used, we will need to update
the logic of that library. So, in ``MathFunctions/CMakeLists.txt`` we need to
create a SqrtLibrary that will conditionally be built when ``USE_MYMATH`` is
enabled. Now, since this is a tutorial, we are going to explicitly require
that SqrtLibrary is built statically.
The end result is that ``MathFunctions/CMakeLists.txt`` should look like:
.. literalinclude:: Step10/MathFunctions/CMakeLists.txt
:language: cmake
:lines: 1-36,42-
Next, update ``MathFunctions/mysqrt.cxx`` to use the ``mathfunctions`` and
``detail`` namespaces:
.. literalinclude:: Step10/MathFunctions/mysqrt.cxx
:language: c++
We also need to make some changes in ``tutorial.cxx``, so that it no longer
uses ``USE_MYMATH``:
#. Always include ``MathFunctions.h``
#. Always use ``mathfunctions::sqrt``
#. Don't include cmath
Finally, update ``MathFunctions/MathFunctions.h`` to use dll export defines:
.. literalinclude:: Step10/MathFunctions/MathFunctions.h
:language: c++
At this point, if you build everything, you will notice that linking fails
as we are combining a static library without position enabled code with a
library that has position enabled code. The solution to this is to explicitly
set the ``POSITION_INDEPENDENT_CODE`` target property of SqrtLibrary to be
True no matter the build type.
.. literalinclude:: Step10/MathFunctions/CMakeLists.txt
:language: cmake
:lines: 37-42
**Exercise**: We modified ``MathFunctions.h`` to use dll export defines.
Using CMake documentation can you find a helper module to simplify this?
Adding Generator Expressions (Step 10)
======================================
Generator expressions are evaluated during build system generation to produce
information specific to each build configuration.
Generator expressions are allowed in the context of many target properties,
such as ``LINK_LIBRARIES``, ``INCLUDE_DIRECTORIES``, ``COMPILE_DEFINITIONS``
and others. They may also be used when using commands to populate those
properties, such as ``target_link_libraries()``,
``target_include_directories()``,
``target_compile_definitions()`` and others.
Generator expressions may be used to enable conditional linking, conditional
definitions used when compiling, conditional include directories and more.
The conditions may be based on the build configuration, target properties,
platform information or any other queryable information.
There are different types of generator expressions including Logical,
Informational, and Output expressions.
Logical expressions are used to create conditional output. The basic
expressions are the 0 and 1 expressions. A ``$<0:...>`` results in the empty
string, and ``<1:...>`` results in the content of "...". They can also be
nested.
A common usage of generator expressions is to conditionally add compiler
flags, such as those as language levels or warnings. A nice pattern is
to associate this information to an ``INTERFACE`` target allowing this
information to propagate. Lets start by constructing an ``INTERFACE``
target and specifying the required C++ standard level of ``11`` instead
of using ``CMAKE_CXX_STANDARD``.
So the following code:
.. literalinclude:: Step10/CMakeLists.txt
:language: cmake
:start-after: project(Tutorial VERSION 1.0)
:end-before: # control where the static and shared libraries are built so that on windows
Would be replaced with:
.. literalinclude:: Step11/CMakeLists.txt
:language: cmake
:start-after: project(Tutorial VERSION 1.0)
:end-before: # add compiler warning flags just when building this project via
Next we add the desired compiler warning flags that we want for our
project. As warning flags vary based on the compiler we use
the ``COMPILE_LANG_AND_ID`` generator expression to control which
flags to apply given a language and a set of compiler ids as seen
below:
.. literalinclude:: Step11/CMakeLists.txt
:language: cmake
:start-after: # the BUILD_INTERFACE genex
:end-before: # control where the static and shared libraries are built so that on windows
Looking at this we see that the warning flags are encapsulated inside a
``BUILD_INTERFACE`` condition. This is done so that consumers of our installed
project will not inherit our warning flags.
**Exercise**: Modify ``MathFunctions/CMakeLists.txt`` so that
all targets have a ``target_link_libraries()`` call to ``tutorial_compiler_flags``.
Adding Export Configuration (Step 11)
=====================================
During `Installing and Testing (Step 4)`_ of the tutorial we added the ability
for CMake to install the library and headers of the project. During
`Building an Installer (Step 7)`_ we added the ability to package up this
information so it could be distributed to other people.
The next step is to add the necessary information so that other CMake projects
can use our project, be it from a build directory, a local install or when
packaged.
The first step is to update our ``install(TARGETS)`` commands to not only
specify a ``DESTINATION`` but also an ``EXPORT``. The ``EXPORT`` keyword
generates and installs a CMake file containing code to import all targets
listed in the install command from the installation tree. So let's go ahead
and explicitly ``EXPORT`` the MathFunctions library by updating the
``install`` command in ``MathFunctions/CMakeLists.txt`` to look like:
.. literalinclude:: Complete/MathFunctions/CMakeLists.txt
:language: cmake
:start-after: # install rules
Now that we have MathFunctions being exported, we also need to explicitly
install the generated ``MathFunctionsTargets.cmake`` file. This is done by
adding the following to the bottom of the top-level ``CMakeLists.txt``:
.. literalinclude:: Complete/CMakeLists.txt
:language: cmake
:start-after: # install the configuration targets
:end-before: include(CMakePackageConfigHelpers)
At this point you should try and run CMake. If everything is setup properly
you will see that CMake will generate an error that looks like:
.. code-block:: console
Target "MathFunctions" INTERFACE_INCLUDE_DIRECTORIES property contains
path:
"/Users/robert/Documents/CMakeClass/Tutorial/Step11/MathFunctions"
which is prefixed in the source directory.
What CMake is trying to say is that during generating the export information
it will export a path that is intrinsically tied to the current machine and
will not be valid on other machines. The solution to this is to update the
MathFunctions ``target_include_directories`` to understand that it needs
different ``INTERFACE`` locations when being used from within the build
directory and from an install / package. This means converting the
``target_include_directories`` call for MathFunctions to look like:
.. literalinclude:: Complete/MathFunctions/CMakeLists.txt
:language: cmake
:start-after: # to find MathFunctions.h, while we don't.
:end-before: # should we use our own math functions
Once this has been updated, we can re-run CMake and see verify that it doesn't
warn anymore.
At this point, we have CMake properly packaging the target information that is
required but we will still need to generate a ``MathFunctionsConfig.cmake`` so
that the CMake ``find_package command`` can find our project. So let's go
ahead and add a new file to the top-level of the project called
``Config.cmake.in`` with the following contents:
.. literalinclude:: Complete/Config.cmake.in
Then, to properly configure and install that file, add the following to the
bottom of the top-level CMakeLists:
.. literalinclude:: Complete/CMakeLists.txt
:language: cmake
:start-after: # install the configuration targets
:end-before: # generate the export
At this point, we have generated a relocatable CMake Configuration for our
project that can be used after the project has been installed or packaged. If
we want our project to also be used from a build directory we only have to add
the following to the bottom of the top level CMakeLists:
.. literalinclude:: Complete/CMakeLists.txt
:language: cmake
:start-after: # needs to be after the install(TARGETS ) command
With this export call we now generate a ``Targets.cmake``, allowing the
configured ``MathFunctionsConfig.cmake`` in the build directory to be used by
other projects, without needing it to be installed.
Import a CMake Project (Consumer)
=================================
This examples shows how a project can find other CMake packages that
generate ``Config.cmake`` files.
It also shows how to state a project's external dependencies when generating
a ``Config.cmake``.
Packaging Debug and Release (MultiPackage)
==========================================
By default CMake is model is that a build directory only contains a single
configuration, be it Debug, Release, MinSizeRel, or RelWithDebInfo.
But it is possible to setup CPack to bundle multiple build directories at the
same time to build a package that contains multiple configurations of the
same project.
First we need to ahead and construct a directory called ``multi_config`` this
will contain all the builds that we want to package together.
Second create a ``debug`` and ``release`` directory underneath
``multi_config``. At the end you should have a layout that looks like:
─ multi_config
├── debug
└── release
Now we need to setup debug and release builds, which would roughly entail
the following:
.. code-block:: console
cd debug
cmake -DCMAKE_BUILD_TYPE=Debug ../../MultiPackage/
cmake --build .
cd ../release
cmake -DCMAKE_BUILD_TYPE=Release ../../MultiPackage/
cmake --build .
cd ..
Now that both the debug and release builds are complete we can now use
the custom MultiCPackConfig to package both builds into a single release.
.. code-block:: console
cpack --config ../../MultiPackage/MultiCPackConfig.cmake
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