Help/manual/cmake-cxxmodules.7.rst - third_party/cmake - Git at Google

 .. cmake-manual-description: CMake C++ Modules Support Reference

 cmake-cxxmodules(7)
 *******************

 .. versionadded:: 3.28

 C++ 20 introduced the concept of "modules" to the language.  The design
 requires build systems to order compilations among each other to satisfy
 ``import`` statements reliably.  CMake's implementation asks the compiler
 to scan source files for module dependencies during the build, collates
 scanning results to infer ordering constraints, and tells the build tool
 how to dynamically update the build graph.

 Compilation Strategy
 ====================

 With C++ modules, compiling a set of C++ sources is no longer embarrassingly
 parallel. That is, any given source may first require the compilation of
 another source file first in order to provide a "CMI" (compiled module
 interface) or "BMI" (binary module interface) that C++ compilers use to
 satisfy ``import`` statements in other sources. With headers, sources could
 share their declarations so that any consumers could compile independently.
 With modules, declarations are now generated into these BMI files by the
 compiler during compilation based on the contents of the source file and its
 ``export`` statements.

 The order necessary for compilation requires build-time resolution of the
 ordering because the order is controlled by the contents of the sources. This
 means that the ordering needs extracted from the source during the build to
 avoid regenerating the build graph via a configure and generate phase for
 every source change to get a correct build.

 The general strategy is to use a "scanner" to extract the ordering dependency
 information and update the build graph with new edges between existing edges
 by taking the per-source scan results (represented by `P1689R5`_ files) and
 "collating" the dependencies within a target and to modules produced by
 targets visible to the target. The primary task is to generate "module map"
 files to pass to each compile rule with the paths to the BMIs needed to
 satisfy ``import`` statements. The collator also has tasks to use the
 build-time information to fill out information including ``install`` rules for
 the module interface units, their BMIs, and properties for any exported
 targets with C++ modules.

 .. _`P1689R5`: https://www.open-std.org/jtc1/sc22/wg21/docs/papers/2022/p1689r5.html

 .. note:

    CMake is focusing on correct builds before looking at performance
    improvements. There are known tactics within the chosen strategy which may
    offer build performance improvements. However, they are being deferred
    until we have a working model against which to compare them. It is also
    important to note that a tactic useful in one situation (e.g., clean
    builds) may not be performant in a different situation (e.g., incremental
    builds). Finding a balance and offering controls to select the tactics is
    future work.

 Scanning Control
 ================

 Whether or not sources get scanned for C++ module usage is dependent on the
 following queries. The first query that provides a yes/no answer is used.

 - If the source file belongs to a file set of type ``CXX_MODULES``, it will
   be scanned.
 - If the target does not use at least C++ 20, it will not be scanned.
 - If the source file is not the language ``CXX``, it will not be scanned.
 - If the :prop_sf:`CXX_SCAN_FOR_MODULES` source file property is set, its
   value will be used.
 - If the :prop_tgt:`CXX_SCAN_FOR_MODULES` target property is set, its value
   will be used.  Set the :variable:`CMAKE_CXX_SCAN_FOR_MODULES` variable
   to initialize this property on all targets as they are created.
 - Otherwise, the source file will be scanned if the compiler and generator
   support scanning.  See policy :policy:`CMP0155`.

 Note that any scanned source will be excluded from any unity build (see
 :prop_tgt:`UNITY_BUILD`) because module-related statements can only happen at
 one place within a C++ translation unit.

 Compiler Support
 ================

 Compilers which CMake natively supports module dependency scanning include:

 * MSVC toolset 14.34 and newer (provided with Visual Studio 17.4 and newer)
 * LLVM/Clang 16.0 and newer
 * GCC 14 (for the in-development branch, after 2023-09-20) and newer

 ``import std`` Support
 ======================

 Support for ``import std`` is limited to the following toolchain and standard
 library combinations:

 * Clang 18.1.2 and newer with ``-stdlib=libc++``
 * MSVC toolset 14.36 and newer (provided with Visual Studio 17.6 Preview 2 and
   newer)

 The :variable:`CMAKE_CXX_COMPILER_IMPORT_STD` variable may be used to detect
 support for a standard level with the active C++ toolchain.

 .. note ::

    This support is provided only when experimental support for
    ``import std;`` has been enabled by the
    ``CMAKE_EXPERIMENTAL_CXX_IMPORT_STD`` gate.

 Generator Support
 =================

 The list of generators which support scanning sources for C++ modules include:

 - :generator:`Ninja`
 - :generator:`Ninja Multi-Config`
 - :generator:`Visual Studio 17 2022`

 Limitations
 -----------

 There are a number of known limitations of the current C++ module support in
 CMake.  This does not document known limitations or bugs in compilers as these
 can change over time.

 For all generators:

 - Header units are not supported.
 - No builtin support for ``import std;`` or other compiler-provided modules.

 For the Ninja Generators:

 - ``ninja`` 1.11 or newer is required.

 For the :ref:`Visual Studio Generators`:

 - Only Visual Studio 2022 and MSVC toolsets 14.34 (Visual Studio
   17.4) and newer.
 - No support for exporting or installing BMI or module information.
 - No support for compiling BMIs from ``IMPORTED`` targets with C++ modules
   (including ``import std``).
 - No diagnosis of using modules provided by ``PRIVATE`` sources from
   ``PUBLIC`` module sources.
	.. cmake-manual-description: CMake C++ Modules Support Reference

	cmake-cxxmodules(7)
	*******************

	.. versionadded:: 3.28

	C++ 20 introduced the concept of "modules" to the language. The design
	requires build systems to order compilations among each other to satisfy
	``import`` statements reliably. CMake's implementation asks the compiler
	to scan source files for module dependencies during the build, collates
	scanning results to infer ordering constraints, and tells the build tool
	how to dynamically update the build graph.

	Compilation Strategy
	====================

	With C++ modules, compiling a set of C++ sources is no longer embarrassingly
	parallel. That is, any given source may first require the compilation of
	another source file first in order to provide a "CMI" (compiled module
	interface) or "BMI" (binary module interface) that C++ compilers use to
	satisfy ``import`` statements in other sources. With headers, sources could
	share their declarations so that any consumers could compile independently.
	With modules, declarations are now generated into these BMI files by the
	compiler during compilation based on the contents of the source file and its
	``export`` statements.

	The order necessary for compilation requires build-time resolution of the
	ordering because the order is controlled by the contents of the sources. This
	means that the ordering needs extracted from the source during the build to
	avoid regenerating the build graph via a configure and generate phase for
	every source change to get a correct build.

	The general strategy is to use a "scanner" to extract the ordering dependency
	information and update the build graph with new edges between existing edges
	by taking the per-source scan results (represented by `P1689R5`_ files) and
	"collating" the dependencies within a target and to modules produced by
	targets visible to the target. The primary task is to generate "module map"
	files to pass to each compile rule with the paths to the BMIs needed to
	satisfy ``import`` statements. The collator also has tasks to use the
	build-time information to fill out information including ``install`` rules for
	the module interface units, their BMIs, and properties for any exported
	targets with C++ modules.

	.. _`P1689R5`: https://www.open-std.org/jtc1/sc22/wg21/docs/papers/2022/p1689r5.html

	.. note:

	CMake is focusing on correct builds before looking at performance
	improvements. There are known tactics within the chosen strategy which may
	offer build performance improvements. However, they are being deferred
	until we have a working model against which to compare them. It is also
	important to note that a tactic useful in one situation (e.g., clean
	builds) may not be performant in a different situation (e.g., incremental
	builds). Finding a balance and offering controls to select the tactics is
	future work.

	Scanning Control
	================

	Whether or not sources get scanned for C++ module usage is dependent on the
	following queries. The first query that provides a yes/no answer is used.

	- If the source file belongs to a file set of type ``CXX_MODULES``, it will
	be scanned.
	- If the target does not use at least C++ 20, it will not be scanned.
	- If the source file is not the language ``CXX``, it will not be scanned.
	- If the :prop_sf:`CXX_SCAN_FOR_MODULES` source file property is set, its
	value will be used.
	- If the :prop_tgt:`CXX_SCAN_FOR_MODULES` target property is set, its value
	will be used. Set the :variable:`CMAKE_CXX_SCAN_FOR_MODULES` variable
	to initialize this property on all targets as they are created.
	- Otherwise, the source file will be scanned if the compiler and generator
	support scanning. See policy :policy:`CMP0155`.

	Note that any scanned source will be excluded from any unity build (see
	:prop_tgt:`UNITY_BUILD`) because module-related statements can only happen at
	one place within a C++ translation unit.

	Compiler Support
	================

	Compilers which CMake natively supports module dependency scanning include:

	* MSVC toolset 14.34 and newer (provided with Visual Studio 17.4 and newer)
	* LLVM/Clang 16.0 and newer
	* GCC 14 (for the in-development branch, after 2023-09-20) and newer

	``import std`` Support
	======================

	Support for ``import std`` is limited to the following toolchain and standard
	library combinations:

	* Clang 18.1.2 and newer with ``-stdlib=libc++``
	* MSVC toolset 14.36 and newer (provided with Visual Studio 17.6 Preview 2 and
	newer)

	The :variable:`CMAKE_CXX_COMPILER_IMPORT_STD` variable may be used to detect
	support for a standard level with the active C++ toolchain.

	.. note ::

	This support is provided only when experimental support for
	``import std;`` has been enabled by the
	``CMAKE_EXPERIMENTAL_CXX_IMPORT_STD`` gate.

	Generator Support
	=================

	The list of generators which support scanning sources for C++ modules include:

	- :generator:`Ninja`
	- :generator:`Ninja Multi-Config`
	- :generator:`Visual Studio 17 2022`

	Limitations
	-----------

	There are a number of known limitations of the current C++ module support in
	CMake. This does not document known limitations or bugs in compilers as these
	can change over time.

	For all generators:

	- Header units are not supported.
	- No builtin support for ``import std;`` or other compiler-provided modules.

	For the Ninja Generators:

	- ``ninja`` 1.11 or newer is required.

	For the :ref:`Visual Studio Generators`:

	- Only Visual Studio 2022 and MSVC toolsets 14.34 (Visual Studio
	17.4) and newer.
	- No support for exporting or installing BMI or module information.
	- No support for compiling BMIs from ``IMPORTED`` targets with C++ modules
	(including ``import std``).
	- No diagnosis of using modules provided by ``PRIVATE`` sources from
	``PUBLIC`` module sources.