Project source code may depend on, or be conditional on, the availability of certain features of the compiler. There are three use-cases which arise: Compile Feature Requirements, Optional Compile Features and Conditional Compilation Options.
While features are typically specified in programming language standards, CMake provides a primary user interface based on granular handling of the features, not the language standard that introduced the feature.
The CMAKE_C_KNOWN_FEATURES
, CMAKE_CUDA_KNOWN_FEATURES
, and CMAKE_CXX_KNOWN_FEATURES
global properties contain all the features known to CMake, regardless of compiler support for the feature. The CMAKE_C_COMPILE_FEATURES
, CMAKE_CUDA_COMPILE_FEATURES
, and CMAKE_CXX_COMPILE_FEATURES
variables contain all features CMake knows are known to the compiler, regardless of language standard or compile flags needed to use them.
Features known to CMake are named mostly following the same convention as the Clang feature test macros. There are some exceptions, such as CMake using cxx_final
and cxx_override
instead of the single cxx_override_control
used by Clang.
Note that there are no separate compile features properties or variables for the OBJC
or OBJCXX
languages. These are based off C
or C++
respectively, so the properties and variables for their corresponding base language should be used instead.
Compile feature requirements may be specified with the target_compile_features()
command. For example, if a target must be compiled with compiler support for the cxx_constexpr
feature:
add_library(mylib requires_constexpr.cpp) target_compile_features(mylib PRIVATE cxx_constexpr)
In processing the requirement for the cxx_constexpr
feature, cmake(1)
will ensure that the in-use C++ compiler is capable of the feature, and will add any necessary flags such as -std=gnu++11
to the compile lines of C++ files in the mylib
target. A FATAL_ERROR
is issued if the compiler is not capable of the feature.
The exact compile flags and language standard are deliberately not part of the user interface for this use-case. CMake will compute the appropriate compile flags to use by considering the features specified for each target.
Such compile flags are added even if the compiler supports the particular feature without the flag. For example, the GNU compiler supports variadic templates (with a warning) even if -std=gnu++98
is used. CMake adds the -std=gnu++11
flag if cxx_variadic_templates
is specified as a requirement.
In the above example, mylib
requires cxx_constexpr
when it is built itself, but consumers of mylib
are not required to use a compiler which supports cxx_constexpr
. If the interface of mylib
does require the cxx_constexpr
feature (or any other known feature), that may be specified with the PUBLIC
or INTERFACE
signatures of target_compile_features()
:
add_library(mylib requires_constexpr.cpp) # cxx_constexpr is a usage-requirement target_compile_features(mylib PUBLIC cxx_constexpr) # main.cpp will be compiled with -std=gnu++11 on GNU for cxx_constexpr. add_executable(myexe main.cpp) target_link_libraries(myexe mylib)
Feature requirements are evaluated transitively by consuming the link implementation. See cmake-buildsystem(7)
for more on transitive behavior of build properties and usage requirements.
In projects that use a large number of commonly available features from a particular language standard (e.g. C++ 11) one may specify a meta-feature (e.g. cxx_std_11
) that requires use of a compiler mode that is at minimum aware of that standard, but could be greater. This is simpler than specifying all the features individually, but does not guarantee the existence of any particular feature. Diagnosis of use of unsupported features will be delayed until compile time.
For example, if C++ 11 features are used extensively in a project’s header files, then clients must use a compiler mode that is no less than C++ 11. This can be requested with the code:
target_compile_features(mylib PUBLIC cxx_std_11)
In this example, CMake will ensure the compiler is invoked in a mode of at-least C++ 11 (or C++ 14, C++ 17, …), adding flags such as -std=gnu++11
if necessary. This applies to sources within mylib
as well as any dependents (that may include headers from mylib
).
Because the CXX_EXTENSIONS
target property is ON
by default, CMake uses extended variants of language dialects by default, such as -std=gnu++11
instead of -std=c++11
. That target property may be set to OFF
to use the non-extended variant of the dialect flag. Note that because most compilers enable extensions by default, this could expose cross-platform bugs in user code or in the headers of third-party dependencies.
Compile features may be preferred if available, without creating a hard requirement. For example, a library may provides alternative implementations depending on whether the cxx_variadic_templates
feature is available:
#if Foo_COMPILER_CXX_VARIADIC_TEMPLATES template<int I, int... Is> struct Interface; template<int I> struct Interface<I> { static int accumulate() { return I; } }; template<int I, int... Is> struct Interface { static int accumulate() { return I + Interface<Is...>::accumulate(); } }; #else template<int I1, int I2 = 0, int I3 = 0, int I4 = 0> struct Interface { static int accumulate() { return I1 + I2 + I3 + I4; } }; #endif
Such an interface depends on using the correct preprocessor defines for the compiler features. CMake can generate a header file containing such defines using the WriteCompilerDetectionHeader
module. The module contains the write_compiler_detection_header
function which accepts parameters to control the content of the generated header file:
write_compiler_detection_header( FILE "${CMAKE_CURRENT_BINARY_DIR}/foo_compiler_detection.h" PREFIX Foo COMPILERS GNU FEATURES cxx_variadic_templates )
Such a header file may be used internally in the source code of a project, and it may be installed and used in the interface of library code.
For each feature listed in FEATURES
, a preprocessor definition is created in the header file, and defined to either 1
or 0
.
Additionally, some features call for additional defines, such as the cxx_final
and cxx_override
features. Rather than being used in #ifdef
code, the final
keyword is abstracted by a symbol which is defined to either final
, a compiler-specific equivalent, or to empty. That way, C++ code can be written to unconditionally use the symbol, and compiler support determines what it is expanded to:
struct Interface { virtual void Execute() = 0; }; struct Concrete Foo_FINAL { void Execute() Foo_OVERRIDE; };
In this case, Foo_FINAL
will expand to final
if the compiler supports the keyword, or to empty otherwise.
In this use-case, the CMake code will wish to enable a particular language standard if available from the compiler. The CXX_STANDARD
target property variable may be set to the desired language standard for a particular target, and the CMAKE_CXX_STANDARD
may be set to influence all following targets:
write_compiler_detection_header( FILE "${CMAKE_CURRENT_BINARY_DIR}/foo_compiler_detection.h" PREFIX Foo COMPILERS GNU FEATURES cxx_final cxx_override ) # Includes foo_compiler_detection.h and uses the Foo_FINAL symbol # which will expand to 'final' if the compiler supports the requested # CXX_STANDARD. add_library(foo foo.cpp) set_property(TARGET foo PROPERTY CXX_STANDARD 11) # Includes foo_compiler_detection.h and uses the Foo_FINAL symbol # which will expand to 'final' if the compiler supports the feature, # even though CXX_STANDARD is not set explicitly. The requirement of # cxx_constexpr causes CMake to set CXX_STANDARD internally, which # affects the compile flags. add_library(foo_impl foo_impl.cpp) target_compile_features(foo_impl PRIVATE cxx_constexpr)
The write_compiler_detection_header
function also creates compatibility code for other features which have standard equivalents. For example, the cxx_static_assert
feature is emulated with a template and abstracted via the <PREFIX>_STATIC_ASSERT
and <PREFIX>_STATIC_ASSERT_MSG
function-macros.
Libraries may provide entirely different header files depending on requested compiler features.
For example, a header at with_variadics/interface.h
may contain:
template<int I, int... Is> struct Interface; template<int I> struct Interface<I> { static int accumulate() { return I; } }; template<int I, int... Is> struct Interface { static int accumulate() { return I + Interface<Is...>::accumulate(); } };
while a header at no_variadics/interface.h
may contain:
template<int I1, int I2 = 0, int I3 = 0, int I4 = 0> struct Interface { static int accumulate() { return I1 + I2 + I3 + I4; } };
It would be possible to write a abstraction interface.h
header containing something like:
#include "foo_compiler_detection.h" #if Foo_COMPILER_CXX_VARIADIC_TEMPLATES #include "with_variadics/interface.h" #else #include "no_variadics/interface.h" #endif
However this could be unmaintainable if there are many files to abstract. What is needed is to use alternative include directories depending on the compiler capabilities.
CMake provides a COMPILE_FEATURES
generator expression
to implement such conditions. This may be used with the build-property commands such as target_include_directories()
and target_link_libraries()
to set the appropriate buildsystem
properties:
add_library(foo INTERFACE) set(with_variadics ${CMAKE_CURRENT_SOURCE_DIR}/with_variadics) set(no_variadics ${CMAKE_CURRENT_SOURCE_DIR}/no_variadics) target_include_directories(foo INTERFACE "$<$<COMPILE_FEATURES:cxx_variadic_templates>:${with_variadics}>" "$<$<NOT:$<COMPILE_FEATURES:cxx_variadic_templates>>:${no_variadics}>" )
Consuming code then simply links to the foo
target as usual and uses the feature-appropriate include directory
add_executable(consumer_with consumer_with.cpp) target_link_libraries(consumer_with foo) set_property(TARGET consumer_with CXX_STANDARD 11) add_executable(consumer_no consumer_no.cpp) target_link_libraries(consumer_no foo)
CMake is currently aware of the C++ standards
and compile features
available from the following compiler ids
as of the versions specified for each:
AppleClang
: Apple Clang for Xcode versions 4.4+.Clang
: Clang compiler versions 2.9+.GNU
: GNU compiler versions 4.4+.MSVC
: Microsoft Visual Studio versions 2010+.SunPro
: Oracle SolarisStudio versions 12.4+.Intel
: Intel compiler versions 12.1+.CMake is currently aware of the C standards
and compile features
available from the following compiler ids
as of the versions specified for each:
GNU
: GNU compiler versions 3.4+CMake is currently aware of the C++ standards
and their associated meta-features (e.g. cxx_std_11
) available from the following compiler ids
as of the versions specified for each:
Cray
: Cray Compiler Environment version 8.1+.PGI
: PGI version 12.10+.TI
: Texas Instruments compiler.XL
: IBM XL version 10.1+.CMake is currently aware of the C standards
and their associated meta-features (e.g. c_std_99
) available from the following compiler ids
as of the versions specified for each:
CMake is currently aware of the CUDA standards
and their associated meta-features (e.g. cuda_std_11
) available from the following compiler ids
as of the versions specified for each:
NVIDIA
: NVIDIA nvcc compiler 7.5+.
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Licensed under the BSD 3-clause License.
https://cmake.org/cmake/help/v3.19/manual/cmake-compile-features.7.html