CMake
is a tool that helps simplify the build process for development projects across different platforms.
CMake
automates the generation of buildsystems such as Makefiles and Visual Studio project files.
CMake
是第 3 方工具,具有自己的
文档编制
. The rest of this manual details the specifics of how to use Qt 5 with
CMake
. The minimum version required to use Qt5 is
CMake
2.8.3, but 3.1.0 is recommended.
The first requirement when using
CMake
is to use
find_package
to locate the libraries and header files shipped with Qt. These libraries and header files can then be used to build libraries and applications based on Qt.
The recommended way to use Qt libraries and headers with
CMake
2.8.11 is to use the
target_link_libraries
command. In
CMake
2.8.11 and later versions, this command automatically adds appropriate include directories, compile definitions, the position-independent-code flag, and links to the qtmain.lib library on Windows.
To build a helloworld GUI executable, typical usage would be:
cmake_minimum_required(VERSION 2.8.11) project(testproject) # Find includes in corresponding build directories set(CMAKE_INCLUDE_CURRENT_DIR ON) # Instruct CMake to run moc automatically when needed. set(CMAKE_AUTOMOC ON) # Find the QtWidgets library find_package(Qt5Widgets) # Tell CMake to create the helloworld executable add_executable(helloworld WIN32 main.cpp) # Use the Widgets module from Qt 5. target_link_libraries(helloworld Qt5::Widgets)
Note that setting the minimum required CMake version to 2.8.11 is required for automatic linking to the qtmain.lib library on Windows.
In order for
find_package
to be successful, Qt 5 must be found below the CMAKE_PREFIX_PATH, or the Qt5<Module>_DIR must be set in the
CMake
cache to the location of the Qt5WidgetsConfig.cmake file. The easiest way to use
CMake
is to set the CMAKE_PREFIX_PATH environment variable to the install prefix of Qt 5.
The CMAKE_AUTOMOC setting runs moc automatically when required. For more on this feature see the CMake AUTOMOC 文档编制
Imported targets are created for each Qt module. Imported target names should be preferred instead of using a variable like Qt5<Module>
_LIBRARIES
in CMake commands such as
target_link_libraries
. The actual path to the library can be obtained using the
LOCATION property
:
find_package(Qt5Core) get_target_property(QtCore_location Qt5::Core LOCATION)
Note however that it is rare to require the full location to the library in
CMake
code. Most
CMake
APIs are aware of imported targets and can automatically use them instead of the full path.
Each module in Qt 5 has a library target with the naming convention Qt5::<Module> which can be used for this purpose.
Imported targets are created with the configurations Qt was configured with. That is, if Qt was configured with the -debug switch, an imported target with the configuration DEBUG will be created. If Qt was configured with the -release switch an imported target with the configuration RELEASE will be created. If Qt was configured with the -debug-and-release switch (the default on windows), then imported targets will be created with both RELEASE and DEBUG configurations.
If your project has custom CMake build configurations, it may be necessary to set a mapping from your custom configuration to either the debug or release Qt configuration.
find_package(Qt5Core) set(CMAKE_CXX_FLAGS_COVERAGE "${CMAKE_CXX_FLAGS_RELEASE} -fprofile-arcs -ftest-coverage") # set up a mapping so that the Release configuration for the Qt imported target is # used in the COVERAGE CMake configuration. set_target_properties(Qt5::Core PROPERTIES MAP_IMPORTED_CONFIG_COVERAGE "RELEASE")
Plugins are also available as
IMPORTED
targets in CMake. The
Qt Network
,
Qt SQL
,
Qt GUI
,和
Qt Widgets
modules have plugins associated. They provide a list of plugins in the
Qt5
<Module>
_PLUGINS
变量。
foreach(plugin ${Qt5Network_PLUGINS}) get_target_property(_loc ${plugin} LOCATION) message("Plugin ${plugin} is at location ${_loc}") endforeach()
CMake
older than 3.1.0
Qt 5.7 requires C++11 support.
CMake
starting from version 3.1.0 implicitly adds the minimum required compiler flags (e.g.
-std=gnu++11
) to the Qt5 module targets. If you use
CMake
version older than 3.1.0, you need to add the needed
-std=...
to the targets linking against Qt5 modules yourself.
If you use Qt 5.7 and a
CMake
version above 3.1.0, plus require a more recent C++ standard version, use the CMake way of selecting the standard version, or specify features required and let CMake compute the flags. Example:
set(CMAKE_CXX_STANDARD 14)
Also see: CMake cmake-compile-features Documentation
CMake
older than 2.8.12
It is also necessary when using an older
CMake
to add Qt5<Module>_EXECUTABLE_COMPILE_FLAGS to the CMAKE_CXX_FLAGS so that the -fPIC flags are added to the compile flags if necessary (as is the default with Qt 5).
CMake
older than 2.8.11
The recommended way to use Qt libraries and headers with
CMake
prior to 2.8.11 is to use the
qt5_use_modules
宏。
Note that it is necessary to use
find_package
to find a Qt module before using the macro. See the documentation for the
CMake find_package Documentation
command for the full options it supports.
The
qt5_use_modules
macro encapsulates all of the variable usage required to use a Qt module. It automatically finds the modules given to it on the command line if they have not already been found.
find_package(Qt5Widgets) add_executable(helloworld WIN32 main.cpp) qt5_use_modules(helloworld Widgets)
CMake
older than 2.8.9
若使用
CMake
older than 2.8.9, the
qt5_use_modules
macro is not available. Attempting to use it will result in an error.
To use Qt 5 with versions of
CMake
older than 2.8.9, it is necessary to use the
target_link_libraries
,
include_directories
,和
add_definitions
commands, and to manually specify moc requirements with either
qt5_generate_moc
or
qt5_wrap_cpp
:
cmake_minimum_required(VERSION 2.8.3) project(testproject) # Find includes in corresponding build directories set(CMAKE_INCLUDE_CURRENT_DIR ON) # Find the QtWidgets library find_package(Qt5Widgets) # Add the include directories for the Qt 5 Widgets module to # the compile lines. include_directories(${Qt5Widgets_INCLUDE_DIRS}) # Use the compile definitions defined in the Qt 5 Widgets module add_definitions(${Qt5Widgets_DEFINITIONS}) # Add compiler flags for building executables (-fPIE) set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} ${Qt5Widgets_EXECUTABLE_COMPILE_FLAGS}") qt5_generate_moc(main.cpp main.moc) # Tell CMake to create the helloworld executable add_executable(helloworld main.cpp main.moc) #Link the helloworld executable to the Qt 5 widgets library. target_link_libraries(helloworld Qt5::Widgets)
The result of a
find_package
call is that imported targets will be created for use with
target_link_libraries
, some variables will be populated with information required to configure the build, and macros will be made available for use. The name of the imported target for each module matches the name of the module with a prefix of 'Qt5::', for example Qt5::Widgets. All of the package-specific variables have a consistent name with a prefix of the name of the package. For example,
find_package
(Qt5Widgets) will make the following variables available if successfully found:
Equivalents of those variables will be available for all packages found with a
find_package
call. Note that the variables are case-sensitive.
Additionally, several other variables are available which do not relate to a particular package, but to the Qt installation itself.
Macros available when Qt5Core is found.
Macro | 描述 |
---|---|
qt5_wrap_cpp(outfiles inputfile ... OPTIONS ...) | Create moc code from a list of files containing Qt class with the Q_OBJECT declaration. Per-directory preprocessor definitions are also added. Options may be given to moc, such as those found when executing "moc -help". |
qt5_add_resources(outfiles inputfile ... OPTIONS ...) | Create code from a list of Qt resource files. Options may be given to rcc, such as those found when executing "rcc -help". |
qt5_add_binary_resources(target inputfile ... OPTIONS ... DESTINATION ...) | Create an RCC file from a list of Qt resource files. Options may be given to rcc, such as those found when executing "rcc -help". A destination may be given to use a different filename or path for the RCC file. |
qt5_generate_moc(inputfile outputfile ) | Creates a rule to run moc on infile and create outfile. Use this if for some reason QT5_WRAP_CPP() isn't appropriate, e.g. because you need a custom filename for the moc file or something similar. |
qt5_use_modules(target [LINK_PUBLIC|LINK_PRIVATE] module ... ) |
Indicates that the target uses the named Qt 5 modules. The target will be linked to the specified modules, use the include directories installed by those modules, use the COMPILE_DEFINITIONS set by those modules, and use the COMPILE_FLAGS set by the modules. The LINK_PRIVATE or LINK_PUBLIC specifiers can optionally be specified. If LINK_PRIVATE is specified then the modules are not made part of the link interface of the target. See the documentation for
target_link_libraries
了解更多信息。
Note that this macro is only available if using
|
Macros available when Qt5Widgets is found.
Macro | 描述 |
---|---|
qt5_wrap_ui(outfiles inputfile ... OPTIONS ...) | Create code from a list of Qt designer ui files. Options may be given to uic, such as those found when executing "uic -help" |
Macros available when Qt5DBus is found.
Macro | 描述 |
---|---|
qt5_add_dbus_interface(outfiles interface basename) | Create the interface header and implementation files with the given basename from the given interface xml file and add it to the list of sources |
qt5_add_dbus_interfaces(outfiles inputfile ... ) | Create the interface header and implementation files for all listed interface xml files the name will be automatically determined from the name of the xml file |
qt5_add_dbus_adaptor(outfiles xmlfile parentheader parentclassname [basename] [classname]) | Create a dbus adaptor (header and implementation file) from the xml file describing the interface, and add it to the list of sources. The adaptor forwards the calls to a parent class, defined in parentheader and named parentclassname. The name of the generated files will be <basename>adaptor.{cpp,h} where basename defaults to the basename of the xml file. If <classname> is provided, then it will be used as the classname of the adaptor itself. |
qt5_generate_dbus_interface( header [interfacename] OPTIONS ...) | Generate the xml interface file from the given header. If the optional argument interfacename is omitted, the name of the interface file is constructed from the basename of the header with the suffix .xml appended. Options may be given to qdbuscpp2xml, such as those found when executing "qdbuscpp2xml --help" |
Macros available when Qt5LinguistTools is found.
Macro | 描述 |
---|---|
qt5_create_translation( qm_files directories ... sources ... ts_files ... OPTIONS ...) | Out: qm_files In: Directories sources ts_files Options: flags to pass to lupdate, such as -extensions to specify Extensions for a directory scan. Generates commands to create .ts (via lupdate) and .qm (via lrelease) - files from directories and/or sources. The ts files are created and/or updated in the source tree (unless given with full paths). The qm files are generated in the build tree. Updating the translations can be done by adding the qm_files to the source list of your library/executable, so they are always updated, or by adding a custom target to control when they get updated/generated. |
qt5_add_translation( qm_files ts_files ... ) | Out: qm_files In: ts_files Generates commands to create .qm from .ts - files. The generated filenames can be found in qm_files. The ts_files must exist and are not updated in any way. |