qt_add_qml_module
This command was introduced in Qt 6.2.
Synopsis
qt_add_qml_module( target URI uri [VERSION version] [PAST_MAJOR_VERSIONS ...] [STATIC | SHARED] [PLUGIN_TARGET plugin_target] [OUTPUT_DIRECTORY output_dir] [RESOURCE_PREFIX resource_prefix] [CLASS_NAME class_name] [TYPEINFO typeinfo] [IMPORTS ...] [OPTIONAL_IMPORTS ...] [DEFAULT_IMPORTS ...] [DEPENDENCIES ...] [IMPORT_PATH ...] [SOURCES ...] [QML_FILES ...] [RESOURCES ...] [OUTPUT_TARGETS out_targets_var] [DESIGNER_SUPPORTED] [FOLLOW_FOREIGN_VERSIONING] [NAMESPACE namespace] [NO_PLUGIN] [NO_PLUGIN_OPTIONAL] [NO_CREATE_PLUGIN_TARGET] [NO_GENERATE_PLUGIN_SOURCE] [NO_GENERATE_QMLTYPES] [NO_GENERATE_QMLDIR] [NO_LINT] [NO_CACHEGEN] [NO_RESOURCE_TARGET_PATH] [NO_IMPORT_SCAN] [ENABLE_TYPE_COMPILER] [TYPE_COMPILER_NAMESPACE namespace] )
If versionless commands are disabled, use qt6_add_qml_module()
instead. It supports the same set of arguments as this command.
See Building a QML application and Building a reusable QML module for examples that define QML modules.
Description
This command defines a QML module that can consist of C++ sources, .qml
files, or both. It ensures that essential module details are provided and that they are consistent. It also sets up and coordinates things like cached compilation of .qml
sources, resource embedding, linting checks, and auto-generation of some key module files.
Target Structure
A QML module can be structured in a few different ways. The following scenarios are the typical arrangements:
Separate backing and plugin targets
This is the recommended arrangement for most QML modules. All of the module's functionality is implemented in the backing target, which is given as the first command argument. C++ sources, .qml
files, and resources should all be added to the backing target. The backing target is a library that should be installed in the same location as any other library defined by the project.
The source directory structure under which the backing target is created should match the target path of the QML module (the target path is the module's URI with dots replaced by forward slashes). If the source directory structure doesn't match the target path, qt_add_qml_module()
will issue a warning.
The following example shows a suitable source directory structure for a QML module with a URI of MyThings.Panels
. The call to qt_add_qml_module()
would be in the CMakeLists.txt
file shown.
src +-- MyThings +-- Panels +-- CMakeLists.txt
A separate plugin target is associated with the QML module. It is used at runtime to load the module dynamically when the application doesn't already link to the backing target. The plugin target will also be a library and is normally installed to the same directory as the module's qmldir file.
The plugin target should ideally contain nothing more than a trivial implementation of the plugin class. This allows the plugin to be designated as optional in the qmldir
file. Other targets can then link directly to the backing target and the plugin will not be needed at runtime, which can improve load-time performance. By default, a C++ source file that defines a minimal plugin class will be automatically generated and added to the plugin target. For cases where the QML module needs a custom plugin class implementation, the NO_GENERATE_PLUGIN_SOURCE and usually the NO_PLUGIN_OPTIONAL options will be needed.
The STATIC
QML modules also generate the static QML plugins if NO_PLUGIN
is not specified. Targets that import such STATIC
QML modules also need to explicitly link to corresponding QML plugins.
Note: When using static linking, it might be necessary to use Q_IMPORT_QML_PLUGIN to ensure that the QML plugin is correctly linked.
Plugin target with no backing target
A QML module can be defined with the plugin target serving as its own backing target. In this case, the module must be loaded dynamically at runtime and cannot be linked to directly by other targets. To create this arrangement, the PLUGIN_TARGET
keyword must be used, with the target
repeated as the plugin target name. For example:
qt_add_qml_module(someTarget PLUGIN_TARGET someTarget ... )
While this arrangement may seem marginally simpler to deploy, a separate backing target should be preferred where possible due to the potentially better load-time performance.
Executable as a QML module
An executable target can act as a backing target for a QML module. In this case, there will be no plugin library, since the QML module will always be loaded directly as part of the application. The qt_add_qml_module()
command will detect when an executable is used as the backing target and will automatically disable the creation of a separate plugin. Do not use any of the options with PLUGIN
in their name when using this arrangement.
When an executable is used as the backing target, the source directory structure is not expected to match the QML module's target path. See Caching compiled QML sources for additional target path differences for compiled-in resources.
Auto-generating qmldir
and typeinfo files
By default, a qmldir file and a typeinfo file will be auto-generated for the QML module being defined. The contents of those files are determined by the various arguments given to this command, as well as the sources and .qml
files added to the backing target. The OUTPUT_DIRECTORY argument determines where the qmldir
and typeinfo files will be written to. If the QML module has a plugin, that plugin will also be created in the same directory as the qmldir
file.
If using a statically built Qt, the backing target's .qml
files will be scanned during the CMake configure run to determine the imports used by the module and to set up linking relationships (the NO_IMPORT_SCAN
keyword can be given to disable this). When a .qml
file is added to or removed from the module, CMake will normally re-run automatically and the relevant files will be re-scanned, since a CMakeLists.txt
file will have been modified. During the course of development, an existing .qml
file may add or remove an import or a type. On its own, this would not cause CMake to re-run automatically, so you should explicitly re-run CMake to force the qmldir
file to be regenerated and any linking relationships to be updated.
The backing target's C++ sources are scanned at build time to generate a typeinfo file and a C++ file to register the associated types. The generated C++ file is automatically added to the backing target as a source. This requires AUTOMOC
to be enabled on the target. The project is responsible for ensuring this, usually by setting the CMAKE_AUTOMOC
variable to TRUE
before calling qt_add_qml_module()
, or by passing in an existing target with the AUTOMOC
target property already set to TRUE
. It isn't an error to have AUTOMOC
disabled on the target, but the project is then responsible for handling the consequences. This may include having to manually generate the typeinfo file instead of allowing it to be auto-generated with missing details, and adding C++ code to register the types.
Projects should prefer to use the auto-generated typeinfo and qmldir
files where possible. They are easier to maintain and they don't suffer from the same susceptibility to errors that hand-written files do. Nevertheless, for situations where the project needs to provide these files itself, the auto-generation can be disabled. The NO_GENERATE_QMLDIR
option disables the qmldir
auto-generation and the NO_GENERATE_QMLTYPES
option disables the typeinfo and C++ type registration auto-generation. If the auto-generated typeinfo file is acceptable, but the project wants to use a different name for that file, it can override the default name with the TYPEINFO
option (but this should not typically be needed).
Caching compiled QML sources
All .qml
, .js
, and .mjs
files added to the module via the QML_FILES
argument will be compiled to bytecode and cached directly in the backing target. This improves load-time performance of the module. The original uncompiled files are also stored in the backing target's resources, as these may still be needed in certain situations by the QML engine.
The resource path of each file is determined by its path relative to the current source directory (CMAKE_CURRENT_SOURCE_DIR
). This resource path is appended to a prefix formed by concatenating the RESOURCE_PREFIX and the target path (but see NO_RESOURCE_TARGET_PATH for an exception to this).
If QTP0001 policy is set to NEW
, the RESOURCE_PREFIX defaults to /qt/qml/
which is the default import path of the QML engine. This ensures that modules are put into the QML Import Path and can be found without further setup.
Ordinarily, the project should aim to place .qml
files in the same relative location as they would have in the resources. If the .qml
file is in a different relative directory to its desired resource path, its location in the resources needs to be explicitly specified. This is done by setting the QT_RESOURCE_ALIAS
source file property, which must be set before the .qml
file is added. For example:
set_source_files_properties(path/to/somewhere/MyFrame.qml PROPERTIES QT_RESOURCE_ALIAS MyFrame.qml ) qt_add_qml_module(someTarget URI MyCo.Frames RESOURCE_PREFIX /my.company.com/imports QML_FILES path/to/somewhere/MyFrame.qml AnotherFrame.qml )
In the above example, the target path will be MyCo/Frames
. After taking into account the source file properties, the two .qml
files will be found at the following resource paths:
/my.company.com/imports/MyCo/Frames/MyFrame.qml
/my.company.com/imports/MyCo/Frames/AnotherFrame.qml
In the rare case that you want to override the automatic selection of the qmlcachegen program to be used, you may set the QT_QMLCACHEGEN_EXECUTABLE
target property on the module target. For example:
set_target_properties(someTarget PROPERTIES QT_QMLCACHEGEN_EXECUTABLE qmlcachegen )
This explicitly selects qmlcachegen as the program to be used, even if better alternatives are available.
Furthermore, you can pass extra arguments to qmlcachegen, by setting the QT_QMLCACHEGEN_ARGUMENTS
option. In particular, the --only-bytecode
option will turn off compilation of QML script code to C++. For example:
set_target_properties(someTarget PROPERTIES QT_QMLCACHEGEN_ARGUMENTS "--only-bytecode" )
Another important argument is --direct-calls
. You can use it to enable the direct mode of The QML script compiler in case the Qt Quick Compiler Extensions are installed. If the extensions are not installed, the argument is ignored. There is a shorthand called QT_QMLCACHEGEN_DIRECT_CALLS
for it.
set_target_properties(someTarget PROPERTIES QT_QMLCACHEGEN_DIRECT_CALLS ON )
Linting QML sources
A separate linting target will be automatically created if any .qml
files are added to the module via the QML_FILES
keyword, or by a later call to qt_target_qml_sources(). The name of the linting target will be the target
followed by _qmllint
. An all_qmllint
target which depends on all the individual *_qmllint
targets is also provided as a convenience.
Naming conventions for .js
files
JavaScript file names that are intended to be addressed as components should start with an uppercase letter.
Alternatively, you may use lowercase file names and set the source file property QT_QML_SOURCE_TYPENAME to the desired type name.
Singletons
If a QML module has .qml
files which provide singleton types, these files need to have their QT_QML_SINGLETON_TYPE
source property set to TRUE
, to ensure that the singleton
command is written into the qmldir file. This must be done in addition to the QML file containing the pragma Singleton
statement.
See qt_target_qml_sources() for an example on how to set the QT_QML_SINGLETON_TYPE
property.
Compiling QML to C++ with QML type compiler
Note: The QML type compiler qmltc
does not guarantee that the generated C++ stays API-, source- or binary-compatible between past or future versions, even patch versions. Furthermore, qmltc-compiled apps using Qt's QML modules will require linking against private Qt API, see also Compiling QML code with qmltc.
If a QML module has .qml
files, you can compile them to C++ using qmltc. Unlike bytecode compilation, you have to explicitly enable qmltc via ENABLE_TYPE_COMPILER argument. In which case, .qml
files specified under QML_FILES
would be compiled. Files ending with .js
and .mjs
are ignored as qmltc does not compile JavaScript code. Additionally, files marked with QT_QML_SKIP_TYPE_COMPILER source file property are also skipped.
By default, qmltc creates lower-case .h
and .cpp
files for a given .qml
file. For example, Foo.qml
ends up being compiled into foo.h
and foo.cpp
.
The created C++ files are placed into a dedicated .qmltc/<target>/
sub-directory of the BINARY_DIR
of the target
. These files are then automatically added to the target sources and compiled as Qt C++ code along with other source files.
While processing QML_FILES, the following source file properties are respected:
QT_QMLTC_FILE_BASENAME
: use this source file property to specify a non-default .h and .cpp file name, which might be useful to e.g. resolve conflicting file names (imagine you have main.qml that is being compiled, but main.h already exists, so #include "main.h" might not do what you expect it to do). QT_QMLTC_FILE_BASENAME is expected to be a file name (without extension), so any preceding directory is ignored. Unlike in the case of default behavior, the QT_QMLTC_FILE_BASENAME is not lower-cased.QT_QML_SKIP_TYPE_COMPILER
: use this source file property to specify that a QML file must be ignored by qmltc.
Arguments
Required arguments
The target
specifies the name of the backing target for the QML module. By default, it is created as a shared library if Qt was built as shared libraries, or as a static library otherwise. This choice can be explicitly overridden with the STATIC
or SHARED
options.
Every QML module must define a URI
. It should be specified in dotted URI notation, such as QtQuick.Layouts
. Each segment must be a well-formed ECMAScript Identifier Name. This means, for example, the segments must not start with a number and they must not contain - (minus) characters. As the URI
will be translated into directory names, you should restrict it to alphanumeric characters of the latin alphabet, underscores, and dots. Other QML modules may use this name in import statements to import the module. The URI
will be used in the module
line of the generated qmldir file. The URI
is also used to form the target path by replacing dots with forward slashes.
See Identified Modules for further in-depth discussion of the module URI.
Versions
A QML module can also define a VERSION
in the form Major.Minor
, where both Major
and Minor
must be integers. An additional .Patch
component may be appended, but will be ignored. A list of earlier major versions the module provides types for can also optionally be given after the PAST_MAJOR_VERSIONS
keyword (see below). See Identified Modules for further in-depth discussion of the module URI and version numbering, Registering past major versions for registering past major versions, and Keeping module versions in sync for keeping module versions in sync.
If you don't need versions you should omit the VERSION
argument. It defaults to the highest possible version. Internal versioning of QML modules has some fundamental flaws. You should use an external package management mechanism to manage different versions of your QML modules.
Adding sources and resources to the module
SOURCES
specifies a list of non-QML sources to be added to the backing target. It is provided as a convenience and is equivalent to adding the sources to the backing target with the built-in target_sources()
CMake command.
QML_FILES
lists the .qml
, .js
and .mjs
files for the module. These will be automatically compiled into bytecode and embedded in the backing target unless the NO_CACHEGEN
option is given. The uncompiled file is always stored in the embedded resources of the backing target, even if NO_CACHEGEN
is specified. Unless the NO_LINT
option is given, the uncompiled files will also be processed by qmllint
via a separate custom build target. The files will also be used to populate type information in the generated qmldir file by default. NO_GENERATE_QMLDIR
can be given to disable the automatic generation of the qmldir
file. This should normally be avoided, but for cases where the project needs to provide its own qmldir
file, this option can be used.
Note: See qt_target_qml_sources() for further details on how to add qmlfiles after qt_add_qml_module()
was called. For example, you may wish to add files conditionally based on an if statement expression, or from subdirectories that will only be added if certain criteria are met. Furthermore, files added with qt_target_qml_sources() also can specify if they should be skipped for the linting, bytecode compilation or qmldir
file generation.
RESOURCES
lists any other files needed by the module, such as images referenced from the QML code. These files will be added as compiled-in resources (see RESOURCE_PREFIX for an explanation of the base point they will be located under). If needed, their relative location can be controlled by setting the QT_RESOURCE_ALIAS
source property, just as for .qml
files (see Caching compiled QML sources).
RESOURCE_PREFIX
is intended to encapsulate a namespace for the project and will often be the same for all QML modules that the project defines. It should be chosen to avoid clashing with the resource prefix of anything else used by the project or likely to be used by any other project that might consume it. A good choice is to incorporate the domain name of the organization the project belongs to. A common convention is to append /imports
to the domain name to form the resource prefix. For example:
qt_add_qml_module(someTarget RESOURCE_PREFIX /my.company.com/imports ... )
When various files are added to the compiled-in resources, they are placed under a path formed by concatenating the RESOURCE_PREFIX
and the target path. For the special case where the backing target is an executable, it may be desirable to place the module's .qml
files and other resources directly under the RESOURCE_PREFIX
instead. This can be achieved by specifying the NO_RESOURCE_TARGET_PATH
option, which may only be used if the backing target is an executable.
Registering past major versions
PAST_MAJOR_VERSIONS
contains a list of additional major version that the module provides. For each of those versions and each QML file without a QT_QML_SOURCE_VERSIONS
setting an additional entry in the qmldir file will be generated to specify the extra version. Furthermore, the generated module registration code will register the past major versions using qmlRegisterModule() on the C++ side. The module registration code is automatically generated for your QML module, unless you specify NO_GENERATE_QMLTYPES
(but use of this option is strongly discouraged). Usage of PAST_MAJOR_VERSIONS
adds some overhead when your module is imported. You should increment the major version of your module as rarely as possible. Once you can rely on all QML files importing this module to omit the version in their imports, you can safely omit PAST_MAJOR_VERSIONS
. All the QML files will then import the latest version of your module. If you have to support versioned imports, consider supporting only a limited number of past major versions.
Declaring module dependencies
IMPORTS
provides a list of other QML modules that this module imports. Each module listed here will be added as an import
entry in the generated qmldir file. If a QML file imports this module, it also imports all the modules listed under IMPORTS
. Optionally, a version can be specified by appending it after a slash, such as QtQuick/2.0
. Omitting the version will cause the greatest version available to be imported. You may only specify the major version, as in QtQuick/2
. In that case the greatest minor version available with the given major version will be imported. Finally, auto
may be given as version (QtQuick/auto
). If auto
is given, the version that the current module is being imported with is propagated to the module to be imported. Given an entry QtQuick/auto
in a module YourModule
, if a QML file specifies import YourModule 3.14
, this results in importing version 3.14
of QtQuick
. For related modules that follow a common versioning scheme, you should use auto
.
OPTIONAL_IMPORTS
provides a list of other QML modules that this module may import at run-time. These are not automatically imported by the QML engine when importing the current module, but rather serve as hints to tools like qmllint
. Versions can be specified in the same way as for IMPORTS
. Each module listed here will be added as an optional import
entry in the generated qmldir file.
DEFAULT_IMPORTS
specifies which of the optional imports are the default entries that should be loaded by tooling. One entry should be specified for every group of OPTIONAL_IMPORTS
in the module. As optional imports are only resolved at runtime, tooling like qmllint cannot in general know which of the optional imports should be resolved. To remedy this, you can specify one of the optional imports as the default import; tooling will then pick it. If you have one optional import that gets used at runtime without any further configuration, that is an ideal candidate for the default import.
DEPENDENCIES
provides a list of other QML modules that this module depends on, but doesn't necessarily import. It would typically be used for dependencies that only exist at the C++ level, such as a module registering a class to QML which is a subclass of one defined in another module.
For example, if one would like to subclass QQuickItem
as following:
class MyItem: public QQuickItem { ... };
then one has to make sure that the module containing QQuickItem
, called QtQuick
, is declared as a dependency via the DEPENDENCIES
option. Not doing so might result in errors during type compilation with qmltc or during binding and function compilation to C++ with qmlcachegen.
Note: Adding the module to DEPENDENCIES
is not necessary if the module is already imported via the IMPORTS
option. The recommended way is to use the lighter alternative DEPENDENCIES
over IMPORTS
.
The module version of the dependencies must be specified along with the module name, in the same form as used for IMPORTS
and OPTIONAL_IMPORTS
. Each module listed here will be added as a depends
entry in the generated qmldir file.
IMPORT_PATH
can be used to add to the search paths where other QML modules that this one depends on can be found. The other modules must have their qmldir
file under their own target path below one of the search paths.
If the backing target is a static library and that static library will be installed, OUTPUT_TARGETS
should be given to provide a variable in which to store a list of additional targets that will also need to be installed. These additional targets are generated internally by qt_add_qml_module()
and are referenced by the backing target's linking requirements as part of ensuring that resources are set up and loaded correctly.
Targets and plugin targets
PLUGIN_TARGET
specifies the plugin target associated with the QML module. The PLUGIN_TARGET
can be the same as the backing target
, in which case there will be no separate backing target. If PLUGIN_TARGET
is not given, it defaults to target
with plugin
appended. For example, a backing target called mymodule
would have a default plugin name of mymoduleplugin
. The plugin target's name will be used to populate a plugin
line in the generated qmldir file. Therefore, you must not try to change the plugin's output name by setting target properties like OUTPUT_NAME
or any of its related properties.
The backing target
and the plugin target (if different) will be created by the command, unless they already exist. Projects should generally let them be created by the command so that they are created as the appropriate target type. If the backing target
is a static library, the plugin will also be created as a static library. If the backing target
is a shared library, the plugin will be created as a module library. If an existing target
is passed in and it is an executable target, there will be no plugin. If you intend to always link directly to the backing target and do not need a plugin, it can be disabled by adding the NO_PLUGIN
option. Specifying both NO_PLUGIN
and PLUGIN_TARGET
is an error.
In certain situations, the project may want to delay creating the plugin target until after the call. The NO_CREATE_PLUGIN_TARGET
option can be given in that situation. The project is then expected to call qt_add_qml_plugin() on the plugin target once it has been created. When NO_CREATE_PLUGIN_TARGET
is given, PLUGIN_TARGET
must also be provided to explicitly name the plugin target.
By default, qt_add_qml_module()
will auto-generate a .cpp
file that implements the plugin class named by the CLASS_NAME
argument. The generated .cpp
file will be automatically added to the plugin target as a source file to be compiled. If the project wants to provide its own implementation of the plugin class, the NO_GENERATE_PLUGIN_SOURCE
option should be given. Where no CLASS_NAME
is provided, it defaults to the URI
with dots replaced by underscores, then Plugin
appended. Unless the QML module has no plugin, the class name will be recorded as a classname
line in the generated qmldir file. You need to add any C++ files with custom plugin code to the plugin target. Since the plugin then likely contains functionality that goes beyond simply loading the backing library, you will probably want to add NO_PLUGIN_OPTIONAL, too. Otherwise the QML engine may skip loading the plugin if it detects that the backing library is already linked.
If the NO_PLUGIN
keyword is given, then no plugin will be built. This keyword is thus incompatible with all the options that customize the plugin target, in particular NO_GENERATE_PLUGIN_SOURCE, NO_PLUGIN_OPTIONAL, PLUGIN_TARGET, NO_CREATE_PLUGIN_TARGET, and CLASS_NAME. If you do not provide a plugin for your module, it will only be fully usable if its backing library has been linked into the executable. It is generally hard to guarantee that a linker preserves the linkage to a library it considers unused.
If the NO_PLUGIN_OPTIONAL
keyword is given, then the plugin is recorded in the generated qmldir
file as non-optional. If all of a QML module's functionality is implemented in its backing target and the plugin target is separate, then the plugin can be optional, which is the default and recommended arrangement. The auto-generated plugin source file satisfies this requirement. Where a project provides its own .cpp
implementation for the plugin, that would normally mean the NO_PLUGIN_OPTIONAL
keyword is also needed because the plugin will almost certainly contain functionality that the QML module requires.
Automatic type registration
Type registration is automatically performed for the backing target's C++ sources that are processed by AUTOMOC. This will generate a typeinfo file in the output directory, the file name being the target
name with .qmltypes
appended. This file name can be changed using the TYPEINFO
option if desired, but this should not normally be necessary. The file name is also recorded as a typeinfo
entry in the generated qmldir file. Automatic type registration can be disabled using the NO_GENERATE_QMLTYPES
option, in which case no typeinfo file will be generated, but the project will still be expected to generate a typeinfo file and place it in the same directory as the generated qmldir
file.
OUTPUT_DIRECTORY
specifies where the plugin library, qmldir
and typeinfo files are generated. When this keyword is not given, the default value will be the target path (formed from the URI
) appended to the value of the QT_QML_OUTPUT_DIRECTORY variable. If that variable is not defined, the default depends on the type of backing target. For executables, the value will be the target path appended to ${CMAKE_CURRENT_BINARY_DIR}
, whereas for other targets it will be just ${CMAKE_CURRENT_BINARY_DIR}
. When the structure of the source tree matches the structure of QML module target paths (which is highly recommended), QT_QML_OUTPUT_DIRECTORY often isn't needed. In order to match the structure of the target paths, you have to call your directories exactly like the segments of your module URI. For example, if your module URI is MyUpperCaseThing.mylowercasething
, you need to put this in a directory called MyUpperCaseThing/mylowercasething/
.
The need for specifying the OUTPUT_DIRECTORY
keyword should be rare, but if it is used, it is likely that the caller will also need to add to the IMPORT_PATH to ensure that linting, cached compilation of qml sources, automatic importing of plugins in static builds, and deploying imported QML modules for non-static builds all work correctly.
Qt Quick Designer compatibility
DESIGNER_SUPPORTED
should be given if the QML module supports Qt Quick Designer. When present, the generated qmldir
file will contain a designersupported
line. See Module Definition qmldir Files for how this affects the way Qt Quick Designer handles the plugin.
Keeping module versions in sync
The FOLLOW_FOREIGN_VERSIONING
keyword relates to base types of your own C++-defined QML types that live in different QML modules. Typically, the versioning scheme of your module does not match that of the module providing the base types. Therefore, by default all revisions of the base types are made available in any import of your module. If FOLLOW_FOREIGN_VERSIONING
is given, the version information attached to the base types and their properties is respected. So, an import MyModule 2.8
will then only make available versioned properties up to version 2.8
of any base types outside MyModule
. This is mostly useful if you want to keep your module version in sync with other modules you're basing types on. In that case you might want your custom types to not expose properties from a module's base type version greater than the one being imported.
C++ namespaces of generated code
If a namespace is given with the NAMESPACE
keyword, the plugin and registration code will be generated into a C++ namespace of this name.
qmlimportscanner and NO_IMPORT_SCAN
For static Qt builds, qmlimportscanner
is run at configure time to scan the .qml
files of a QML module and identify the QML imports it uses (see qt_import_qml_plugins()). For non-static Qt builds, if the target is an executable, a similar scan is performed at build time to provide the information needed by deployment scripts (see qt_deploy_qml_imports()). Both scans can be disabled by providing the NO_IMPORT_SCAN
option. Doing so means the project takes on the responsibility of ensuring all required plugins are instantiated and linked for static builds. For non-static builds the project must manually work out and deploy all QML modules used by an executable target.
Arguments for qmltc
ENABLE_TYPE_COMPILER
can be used to compile .qml
files to C++ source code with qmltc. Files with the source property QT_QML_SKIP_TYPE_COMPILER
are not compiled to C++.
TYPE_COMPILER_NAMESPACE
argument allows to override the namespace in which qmltc generates code. By default, the namespace of the generated code follows the module hierarchy as depicted in the URI, e.g., MyModule
for a module with URI MyModule
or com::example::Module
for URI com.example.MyModule
. By specifying the TYPE_COMPILER_NAMESPACE
option, the generated code can be put instead in a custom namespace, where different subnamespaces are to be separated by a "::", e.g. "MyNamespace::MySubnamespace" for the namespace MySubnamespace that is inside the MyNamespace. Apart from the "::", C++ namespace naming rules apply.
QMLTC_QMLTC_EXPORT_DIRECTIVE
should be used with QMLTC_EXPORT_FILE_NAME
when the classes generated by qmltc should be exported from the qml library. By default, classes generated by qmltc are not exported from their library. The header defining the export macro for the current library can be specified as an optional argument to QMLTC_EXPORT_FILE_NAME
while the exporting macro name should be specified as an argument to QMLTC_QMLTC_EXPORT_DIRECTIVE
. If no additional include is required or wanted, e.g. when the header of the export macro is already indirectly included by a base class, then the QMLTC_EXPORT_FILE_NAME
option can be left out.
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