Provided by: cmake-data_3.30.3-1_all bug

NAME

       cmake-compile-features - CMake Compile Features Reference

INTRODUCTION

       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

       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.

   Requiring Language Standards
       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).

       NOTE:
          If the compiler's default standard level is at least that  of  the  requested  feature,
          CMake  may  omit the -std= flag.  The flag may still be added if the compiler's default
          extensions mode does not  match  the  <LANG>_EXTENSIONS  target  property,  or  if  the
          <LANG>_STANDARD target property is set.

   Availability of Compiler Extensions
       The   <LANG>_EXTENSIONS   target   property   defaults  to  the  compiler's  default  (see
       CMAKE_<LANG>_EXTENSIONS_DEFAULT). Note that because most compilers  enable  extensions  by
       default,  this  may  expose portability bugs in user code or in the headers of third-party
       dependencies.

       <LANG>_EXTENSIONS used to default to ON. See CMP0128.

OPTIONAL COMPILE FEATURES

       Compile features may be preferred if  available,  without  creating  a  hard  requirement.
       This can be achieved by not specifying features with target_compile_features() and instead
       checking the compiler capabilities with preprocessor conditions in project code.

       In this use-case, the project may wish to establish  a  particular  language  standard  if
       available  from  the  compiler,  and  use  preprocessor  conditions to detect the features
       actually available.   A  language  standard  may  be  established  by  Requiring  Language
       Standards  using  target_compile_features()  with  meta-features  like  cxx_std_11,  or by
       setting the CXX_STANDARD target property or CMAKE_CXX_STANDARD variable.

       See also policy CMP0120 and legacy  documentation  on  Example  Usage  of  the  deprecated
       WriteCompilerDetectionHeader module.

CONDITIONAL COMPILATION OPTIONS

       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 may be possible to write an abstraction interface.h header containing something like:

          #ifdef HAVE_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)

SUPPORTED COMPILERS

       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:

       • all compilers and versions listed above for C++.

       • 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+.

       • Fujitsu: Fujitsu HPC compiler 4.0+.

       • PGI: PGI version 12.10+.

       • NVHPC: NVIDIA HPC compilers version 11.0+.

       • TI: Texas Instruments compiler.

       • TIClang: Texas Instruments Clang-based compilers.

       • 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:

       • all compilers and versions listed above with only meta-features for C++.

       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:

       • Clang: Clang compiler 5.0+.

       • NVIDIA: NVIDIA nvcc compiler 7.5+.

LANGUAGE STANDARD FLAGS

       In order to satisfy requirements specified by the target_compile_features() command or the
       CMAKE_<LANG>_STANDARD variable, CMake may pass a language standard flag to  the  compiler,
       such as -std=c++11.

       For Visual Studio Generators, CMake cannot precisely control the placement of the language
       standard flag on the compiler command line.  For Ninja  Generators,  Makefile  Generators,
       and Xcode, CMake places the language standard flag just after the language-wide flags from
       CMAKE_<LANG>_FLAGS and CMAKE_<LANG>_FLAGS_<CONFIG>.

       Changed in version 3.26: The language standard flag is placed before  flags  specified  by
       other abstractions such as the target_compile_options() command.  Prior to CMake 3.26, the
       language standard flag was placed after them.

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