config/ax_cxx_compile_stdcxx.m4 - binutils-gdb - Git at Google

 # ===========================================================================
 #  https://www.gnu.org/software/autoconf-archive/ax_cxx_compile_stdcxx.html
 # ===========================================================================
 #
 # SYNOPSIS
 #
 #   AX_CXX_COMPILE_STDCXX(VERSION, [ext|noext], [mandatory|optional])
 #
 # DESCRIPTION
 #
 #   Check for baseline language coverage in the compiler for the specified
 #   version of the C++ standard.  If necessary, add switches to CXX and
 #   CXXCPP to enable support.  VERSION may be '11' (for the C++11 standard)
 #   or '14' (for the C++14 standard).
 #
 #   The second argument, if specified, indicates whether you insist on an
 #   extended mode (e.g. -std=gnu++11) or a strict conformance mode (e.g.
 #   -std=c++11).  If neither is specified, you get whatever works, with
 #   preference for no added switch, and then for an extended mode.
 #
 #   The third argument, if specified 'mandatory' or if left unspecified,
 #   indicates that baseline support for the specified C++ standard is
 #   required and that the macro should error out if no mode with that
 #   support is found.  If specified 'optional', then configuration proceeds
 #   regardless, after defining HAVE_CXX${VERSION} if and only if a
 #   supporting mode is found.
 #
 #   If the fourth argument is an optional CXX/CXXFLAG/CPPFLAG suffix, e.g.
 #   "_FOR_BUILD" or "_FOR_TARGET".
 #
 #
 # LICENSE
 #
 #   Copyright (c) 2008 Benjamin Kosnik <bkoz@redhat.com>
 #   Copyright (c) 2012 Zack Weinberg <zackw@panix.com>
 #   Copyright (c) 2013 Roy Stogner <roystgnr@ices.utexas.edu>
 #   Copyright (c) 2014, 2015 Google Inc.; contributed by Alexey Sokolov <sokolov@google.com>
 #   Copyright (c) 2015 Paul Norman <penorman@mac.com>
 #   Copyright (c) 2015 Moritz Klammler <moritz@klammler.eu>
 #   Copyright (c) 2016, 2018 Krzesimir Nowak <qdlacz@gmail.com>
 #   Copyright (c) 2019 Enji Cooper <yaneurabeya@gmail.com>
 #   Copyright (c) 2020 Jason Merrill <jason@redhat.com>
 #
 #   Copying and distribution of this file, with or without modification, are
 #   permitted in any medium without royalty provided the copyright notice
 #   and this notice are preserved.  This file is offered as-is, without any
 #   warranty.

 #serial 12

 dnl  This macro is based on the code from the AX_CXX_COMPILE_STDCXX_11 macro
 dnl  (serial version number 13).

 AC_DEFUN([AX_CXX_COMPILE_STDCXX], [dnl
   m4_if([$1], [11], [ax_cxx_compile_alternatives="11 0x"],
         [$1], [14], [ax_cxx_compile_alternatives="14 1y"],
         [$1], [17], [ax_cxx_compile_alternatives="17 1z"],
         [m4_fatal([invalid first argument `$1' to AX_CXX_COMPILE_STDCXX])])dnl
   m4_if([$2], [], [],
         [$2], [ext], [],
         [$2], [noext], [],
         [m4_fatal([invalid second argument `$2' to AX_CXX_COMPILE_STDCXX])])dnl
   m4_if([$3], [], [ax_cxx_compile_cxx$1_required=true],
         [$3], [mandatory], [ax_cxx_compile_cxx$1_required=true],
         [$3], [optional], [ax_cxx_compile_cxx$1_required=false],
         [m4_fatal([invalid third argument `$3' to AX_CXX_COMPILE_STDCXX])])
   AC_LANG_PUSH([C++])dnl
   ac_success=no
   m4_ifnblank([$4], [dnl
     ax_cv_cxx_compile_cxx$1_orig_cxx="$CXX"
     ax_cv_cxx_compile_cxx$1_orig_cxxflags="$CXXFLAGS"
     ax_cv_cxx_compile_cxx$1_orig_cppflags="$CPPFLAGS"
     CXX="$CXX$4"
     CXXFLAGS="$CXXFLAGS$4"
     CPPFLAGS="$CPPFLAGS$4"])
   m4_if([$2], [], [dnl
     AC_CACHE_CHECK(whether $CXX supports C++$1 features by default,
 		   ax_cv_cxx_compile_cxx$1$4,
       [AC_COMPILE_IFELSE([AC_LANG_SOURCE([_AX_CXX_COMPILE_STDCXX_testbody_$1])],
         [ax_cv_cxx_compile_cxx$1$4=yes],
         [ax_cv_cxx_compile_cxx$1$4=no])])
     if test x$ax_cv_cxx_compile_cxx$1$4 = xyes; then
       ac_success=yes
     fi])

   m4_if([$2], [noext], [], [dnl
   if test x$ac_success = xno; then
     for alternative in ${ax_cxx_compile_alternatives}; do
       switch="-std=gnu++${alternative}"
       cachevar=AS_TR_SH([ax_cv_cxx_compile_cxx$1$4_$switch])
       AC_CACHE_CHECK(whether $CXX supports C++$1 features with $switch,
                      $cachevar,
         [ac_save_CXX="$CXX"
          CXX="$CXX $switch"
          AC_COMPILE_IFELSE([AC_LANG_SOURCE([_AX_CXX_COMPILE_STDCXX_testbody_$1])],
           [eval $cachevar=yes],
           [eval $cachevar=no])
          CXX="$ac_save_CXX"])
       if eval test x\$$cachevar = xyes; then
         CXX="$CXX $switch"
         if test -n "$CXXCPP" ; then
           CXXCPP="$CXXCPP $switch"
         fi
         ac_success=yes
         break
       fi
     done
   fi])

   m4_if([$2], [ext], [], [dnl
   if test x$ac_success = xno; then
     dnl HP's aCC needs +std=c++11 according to:
     dnl http://h21007.www2.hp.com/portal/download/files/unprot/aCxx/PDF_Release_Notes/769149-001.pdf
     dnl Cray's crayCC needs "-h std=c++11"
     for alternative in ${ax_cxx_compile_alternatives}; do
       for switch in -std=c++${alternative} +std=c++${alternative} "-h std=c++${alternative}"; do
         cachevar=AS_TR_SH([ax_cv_cxx_compile_cxx$1$4_$switch])
         AC_CACHE_CHECK(whether $CXX supports C++$1 features with $switch,
                        $cachevar,
           [ac_save_CXX="$CXX"
            CXX="$CXX $switch"
            AC_COMPILE_IFELSE([AC_LANG_SOURCE([_AX_CXX_COMPILE_STDCXX_testbody_$1])],
             [eval $cachevar=yes],
             [eval $cachevar=no])
            CXX="$ac_save_CXX"])
         if eval test x\$$cachevar = xyes; then
           CXX="$CXX $switch"
           if test -n "$CXXCPP" ; then
             CXXCPP="$CXXCPP $switch"
           fi
           ac_success=yes
           break
         fi
       done
       if test x$ac_success = xyes; then
         break
       fi
     done
   fi])
   m4_ifnblank([$4], [dnl
     CXX$4="$CXX"
     CXXFLAGS$4="$CXXFLAGS"
     CPPFLAGS$4="$CPPFLAGS"
     CXX="$ax_cv_cxx_compile_cxx$1_orig_cxx"
     CXXFLAGS="$ax_cv_cxx_compile_cxx$1_orig_cxxflags"
     CPPFLAGS="$ax_cv_cxx_compile_cxx$1_orig_cppflags"])
   AC_LANG_POP([C++])
   if test x$ax_cxx_compile_cxx$1_required = xtrue; then
     if test x$ac_success = xno; then
       AC_MSG_ERROR([*** A compiler with support for C++$1 language features is required.])
     fi
   fi
   if test x$ac_success = xno; then
     HAVE_CXX$1$4=0
     AC_MSG_NOTICE([No compiler with C++$1 support was found])
   else
     HAVE_CXX$1$4=1
     AC_DEFINE(HAVE_CXX$1$4,1,
               [define if the compiler supports basic C++$1 syntax])
   fi
   AC_SUBST(HAVE_CXX$1$4)
 ])


 dnl  Test body for checking C++11 support

 m4_define([_AX_CXX_COMPILE_STDCXX_testbody_11],
   _AX_CXX_COMPILE_STDCXX_testbody_new_in_11
 )


 dnl  Test body for checking C++14 support

 m4_define([_AX_CXX_COMPILE_STDCXX_testbody_14],
   _AX_CXX_COMPILE_STDCXX_testbody_new_in_11
   _AX_CXX_COMPILE_STDCXX_testbody_new_in_14
 )

 m4_define([_AX_CXX_COMPILE_STDCXX_testbody_17],
   _AX_CXX_COMPILE_STDCXX_testbody_new_in_11
   _AX_CXX_COMPILE_STDCXX_testbody_new_in_14
   _AX_CXX_COMPILE_STDCXX_testbody_new_in_17
 )

 dnl  Tests for new features in C++11

 m4_define([_AX_CXX_COMPILE_STDCXX_testbody_new_in_11], [[

 // If the compiler admits that it is not ready for C++11, why torture it?
 // Hopefully, this will speed up the test.

 #ifndef __cplusplus

 #error "This is not a C++ compiler"

 #elif __cplusplus < 201103L

 #error "This is not a C++11 compiler"

 #else

 namespace cxx11
 {

   namespace test_static_assert
   {

     template <typename T>
     struct check
     {
       static_assert(sizeof(int) <= sizeof(T), "not big enough");
     };

   }

   namespace test_final_override
   {

     struct Base
     {
       virtual ~Base() {}
       virtual void f() {}
     };

     struct Derived : public Base
     {
       virtual ~Derived() override {}
       virtual void f() override {}
     };

   }

   namespace test_double_right_angle_brackets
   {

     template < typename T >
     struct check {};

     typedef check<void> single_type;
     typedef check<check<void>> double_type;
     typedef check<check<check<void>>> triple_type;
     typedef check<check<check<check<void>>>> quadruple_type;

   }

   namespace test_decltype
   {

     int
     f()
     {
       int a = 1;
       decltype(a) b = 2;
       return a + b;
     }

   }

   namespace test_type_deduction
   {

     template < typename T1, typename T2 >
     struct is_same
     {
       static const bool value = false;
     };

     template < typename T >
     struct is_same<T, T>
     {
       static const bool value = true;
     };

     template < typename T1, typename T2 >
     auto
     add(T1 a1, T2 a2) -> decltype(a1 + a2)
     {
       return a1 + a2;
     }

     int
     test(const int c, volatile int v)
     {
       static_assert(is_same<int, decltype(0)>::value == true, "");
       static_assert(is_same<int, decltype(c)>::value == false, "");
       static_assert(is_same<int, decltype(v)>::value == false, "");
       auto ac = c;
       auto av = v;
       auto sumi = ac + av + 'x';
       auto sumf = ac + av + 1.0;
       static_assert(is_same<int, decltype(ac)>::value == true, "");
       static_assert(is_same<int, decltype(av)>::value == true, "");
       static_assert(is_same<int, decltype(sumi)>::value == true, "");
       static_assert(is_same<int, decltype(sumf)>::value == false, "");
       static_assert(is_same<int, decltype(add(c, v))>::value == true, "");
       return (sumf > 0.0) ? sumi : add(c, v);
     }

   }

   namespace test_noexcept
   {

     int f() { return 0; }
     int g() noexcept { return 0; }

     static_assert(noexcept(f()) == false, "");
     static_assert(noexcept(g()) == true, "");

   }

   namespace test_constexpr
   {

     template < typename CharT >
     unsigned long constexpr
     strlen_c_r(const CharT *const s, const unsigned long acc) noexcept
     {
       return *s ? strlen_c_r(s + 1, acc + 1) : acc;
     }

     template < typename CharT >
     unsigned long constexpr
     strlen_c(const CharT *const s) noexcept
     {
       return strlen_c_r(s, 0UL);
     }

     static_assert(strlen_c("") == 0UL, "");
     static_assert(strlen_c("1") == 1UL, "");
     static_assert(strlen_c("example") == 7UL, "");
     static_assert(strlen_c("another\0example") == 7UL, "");

   }

   namespace test_rvalue_references
   {

     template < int N >
     struct answer
     {
       static constexpr int value = N;
     };

     answer<1> f(int&)       { return answer<1>(); }
     answer<2> f(const int&) { return answer<2>(); }
     answer<3> f(int&&)      { return answer<3>(); }

     void
     test()
     {
       int i = 0;
       const int c = 0;
       static_assert(decltype(f(i))::value == 1, "");
       static_assert(decltype(f(c))::value == 2, "");
       static_assert(decltype(f(0))::value == 3, "");
     }

   }

   namespace test_uniform_initialization
   {

     struct test
     {
       static const int zero {};
       static const int one {1};
     };

     static_assert(test::zero == 0, "");
     static_assert(test::one == 1, "");

   }

   namespace test_lambdas
   {

     void
     test1()
     {
       auto lambda1 = [](){};
       auto lambda2 = lambda1;
       lambda1();
       lambda2();
     }

     int
     test2()
     {
       auto a = [](int i, int j){ return i + j; }(1, 2);
       auto b = []() -> int { return '0'; }();
       auto c = [=](){ return a + b; }();
       auto d = [&](){ return c; }();
       auto e = [a, &b](int x) mutable {
         const auto identity = [](int y){ return y; };
         for (auto i = 0; i < a; ++i)
           a += b--;
         return x + identity(a + b);
       }(0);
       return a + b + c + d + e;
     }

     int
     test3()
     {
       const auto nullary = [](){ return 0; };
       const auto unary = [](int x){ return x; };
       using nullary_t = decltype(nullary);
       using unary_t = decltype(unary);
       const auto higher1st = [](nullary_t f){ return f(); };
       const auto higher2nd = [unary](nullary_t f1){
         return [unary, f1](unary_t f2){ return f2(unary(f1())); };
       };
       return higher1st(nullary) + higher2nd(nullary)(unary);
     }

   }

   namespace test_variadic_templates
   {

     template <int...>
     struct sum;

     template <int N0, int... N1toN>
     struct sum<N0, N1toN...>
     {
       static constexpr auto value = N0 + sum<N1toN...>::value;
     };

     template <>
     struct sum<>
     {
       static constexpr auto value = 0;
     };

     static_assert(sum<>::value == 0, "");
     static_assert(sum<1>::value == 1, "");
     static_assert(sum<23>::value == 23, "");
     static_assert(sum<1, 2>::value == 3, "");
     static_assert(sum<5, 5, 11>::value == 21, "");
     static_assert(sum<2, 3, 5, 7, 11, 13>::value == 41, "");

   }

   // http://stackoverflow.com/questions/13728184/template-aliases-and-sfinae
   // Clang 3.1 fails with headers of libstd++ 4.8.3 when using std::function
   // because of this.
   namespace test_template_alias_sfinae
   {

     struct foo {};

     template<typename T>
     using member = typename T::member_type;

     template<typename T>
     void func(...) {}

     template<typename T>
     void func(member<T>*) {}

     void test();

     void test() { func<foo>(0); }

   }

 }  // namespace cxx11

 #endif  // __cplusplus >= 201103L

 ]])


 dnl  Tests for new features in C++14

 m4_define([_AX_CXX_COMPILE_STDCXX_testbody_new_in_14], [[

 // If the compiler admits that it is not ready for C++14, why torture it?
 // Hopefully, this will speed up the test.

 #ifndef __cplusplus

 #error "This is not a C++ compiler"

 #elif __cplusplus < 201402L

 #error "This is not a C++14 compiler"

 #else

 namespace cxx14
 {

   namespace test_polymorphic_lambdas
   {

     int
     test()
     {
       const auto lambda = [](auto&&... args){
         const auto istiny = [](auto x){
           return (sizeof(x) == 1UL) ? 1 : 0;
         };
         const int aretiny[] = { istiny(args)... };
         return aretiny[0];
       };
       return lambda(1, 1L, 1.0f, '1');
     }

   }

   namespace test_binary_literals
   {

     constexpr auto ivii = 0b0000000000101010;
     static_assert(ivii == 42, "wrong value");

   }

   namespace test_generalized_constexpr
   {

     template < typename CharT >
     constexpr unsigned long
     strlen_c(const CharT *const s) noexcept
     {
       auto length = 0UL;
       for (auto p = s; *p; ++p)
         ++length;
       return length;
     }

     static_assert(strlen_c("") == 0UL, "");
     static_assert(strlen_c("x") == 1UL, "");
     static_assert(strlen_c("test") == 4UL, "");
     static_assert(strlen_c("another\0test") == 7UL, "");

   }

   namespace test_lambda_init_capture
   {

     int
     test()
     {
       auto x = 0;
       const auto lambda1 = [a = x](int b){ return a + b; };
       const auto lambda2 = [a = lambda1(x)](){ return a; };
       return lambda2();
     }

   }

   namespace test_digit_separators
   {

     constexpr auto ten_million = 100'000'000;
     static_assert(ten_million == 100000000, "");

   }

   namespace test_return_type_deduction
   {

     auto f(int& x) { return x; }
     decltype(auto) g(int& x) { return x; }

     template < typename T1, typename T2 >
     struct is_same
     {
       static constexpr auto value = false;
     };

     template < typename T >
     struct is_same<T, T>
     {
       static constexpr auto value = true;
     };

     int
     test()
     {
       auto x = 0;
       static_assert(is_same<int, decltype(f(x))>::value, "");
       static_assert(is_same<int&, decltype(g(x))>::value, "");
       return x;
     }

   }

 }  // namespace cxx14

 #endif  // __cplusplus >= 201402L

 ]])


 dnl  Tests for new features in C++17

 m4_define([_AX_CXX_COMPILE_STDCXX_testbody_new_in_17], [[

 // If the compiler admits that it is not ready for C++17, why torture it?
 // Hopefully, this will speed up the test.

 #ifndef __cplusplus

 #error "This is not a C++ compiler"

 #elif __cplusplus < 201703L

 #error "This is not a C++17 compiler"

 #else

 #include <initializer_list>
 #include <utility>
 #include <type_traits>

 namespace cxx17
 {

   namespace test_constexpr_lambdas
   {

     constexpr int foo = [](){return 42;}();

   }

   namespace test::nested_namespace::definitions
   {

   }

   namespace test_fold_expression
   {

     template<typename... Args>
     int multiply(Args... args)
     {
       return (args * ... * 1);
     }

     template<typename... Args>
     bool all(Args... args)
     {
       return (args && ...);
     }

   }

   namespace test_extended_static_assert
   {

     static_assert (true);

   }

   namespace test_auto_brace_init_list
   {

     auto foo = {5};
     auto bar {5};

     static_assert(std::is_same<std::initializer_list<int>, decltype(foo)>::value);
     static_assert(std::is_same<int, decltype(bar)>::value);
   }

   namespace test_typename_in_template_template_parameter
   {

     template<template<typename> typename X> struct D;

   }

   namespace test_fallthrough_nodiscard_maybe_unused_attributes
   {

     int f1()
     {
       return 42;
     }

     [[nodiscard]] int f2()
     {
       [[maybe_unused]] auto unused = f1();

       switch (f1())
       {
       case 17:
         f1();
         [[fallthrough]];
       case 42:
         f1();
       }
       return f1();
     }

   }

   namespace test_extended_aggregate_initialization
   {

     struct base1
     {
       int b1, b2 = 42;
     };

     struct base2
     {
       base2() {
         b3 = 42;
       }
       int b3;
     };

     struct derived : base1, base2
     {
         int d;
     };

     derived d1 {{1, 2}, {}, 4};  // full initialization
     derived d2 {{}, {}, 4};      // value-initialized bases

   }

   namespace test_general_range_based_for_loop
   {

     struct iter
     {
       int i;

       int& operator* ()
       {
         return i;
       }

       const int& operator* () const
       {
         return i;
       }

       iter& operator++()
       {
         ++i;
         return *this;
       }
     };

     struct sentinel
     {
       int i;
     };

     bool operator== (const iter& i, const sentinel& s)
     {
       return i.i == s.i;
     }

     bool operator!= (const iter& i, const sentinel& s)
     {
       return !(i == s);
     }

     struct range
     {
       iter begin() const
       {
         return {0};
       }

       sentinel end() const
       {
         return {5};
       }
     };

     void f()
     {
       range r {};

       for (auto i : r)
       {
         [[maybe_unused]] auto v = i;
       }
     }

   }

   namespace test_lambda_capture_asterisk_this_by_value
   {

     struct t
     {
       int i;
       int foo()
       {
         return [*this]()
         {
           return i;
         }();
       }
     };

   }

   namespace test_enum_class_construction
   {

     enum class byte : unsigned char
     {};

     byte foo {42};

   }

   namespace test_constexpr_if
   {

     template <bool cond>
     int f ()
     {
       if constexpr(cond)
       {
         return 13;
       }
       else
       {
         return 42;
       }
     }

   }

   namespace test_selection_statement_with_initializer
   {

     int f()
     {
       return 13;
     }

     int f2()
     {
       if (auto i = f(); i > 0)
       {
         return 3;
       }

       switch (auto i = f(); i + 4)
       {
       case 17:
         return 2;

       default:
         return 1;
       }
     }

   }

   namespace test_template_argument_deduction_for_class_templates
   {

     template <typename T1, typename T2>
     struct pair
     {
       pair (T1 p1, T2 p2)
         : m1 {p1},
           m2 {p2}
       {}

       T1 m1;
       T2 m2;
     };

     void f()
     {
       [[maybe_unused]] auto p = pair{13, 42u};
     }

   }

   namespace test_non_type_auto_template_parameters
   {

     template <auto n>
     struct B
     {};

     B<5> b1;
     B<'a'> b2;

   }

   namespace test_structured_bindings
   {

     int arr[2] = { 1, 2 };
     std::pair<int, int> pr = { 1, 2 };

     auto f1() -> int(&)[2]
     {
       return arr;
     }

     auto f2() -> std::pair<int, int>&
     {
       return pr;
     }

     struct S
     {
       int x1 : 2;
       volatile double y1;
     };

     S f3()
     {
       return {};
     }

     auto [ x1, y1 ] = f1();
     auto& [ xr1, yr1 ] = f1();
     auto [ x2, y2 ] = f2();
     auto& [ xr2, yr2 ] = f2();
     const auto [ x3, y3 ] = f3();

   }

   namespace test_exception_spec_type_system
   {

     struct Good {};
     struct Bad {};

     void g1() noexcept;
     void g2();

     template<typename T>
     Bad
     f(T*, T*);

     template<typename T1, typename T2>
     Good
     f(T1*, T2*);

     static_assert (std::is_same_v<Good, decltype(f(g1, g2))>);

   }

   namespace test_inline_variables
   {

     template<class T> void f(T)
     {}

     template<class T> inline T g(T)
     {
       return T{};
     }

     template<> inline void f<>(int)
     {}

     template<> int g<>(int)
     {
       return 5;
     }

   }

 }  // namespace cxx17

 #endif  // __cplusplus < 201703L

 ]])
	# ===========================================================================
	# https://www.gnu.org/software/autoconf-archive/ax_cxx_compile_stdcxx.html
	# ===========================================================================
	#
	# SYNOPSIS
	#
	# AX_CXX_COMPILE_STDCXX(VERSION, [ext\|noext], [mandatory\|optional])
	#
	# DESCRIPTION
	#
	# Check for baseline language coverage in the compiler for the specified
	# version of the C++ standard. If necessary, add switches to CXX and
	# CXXCPP to enable support. VERSION may be '11' (for the C++11 standard)
	# or '14' (for the C++14 standard).
	#
	# The second argument, if specified, indicates whether you insist on an
	# extended mode (e.g. -std=gnu++11) or a strict conformance mode (e.g.
	# -std=c++11). If neither is specified, you get whatever works, with
	# preference for no added switch, and then for an extended mode.
	#
	# The third argument, if specified 'mandatory' or if left unspecified,
	# indicates that baseline support for the specified C++ standard is
	# required and that the macro should error out if no mode with that
	# support is found. If specified 'optional', then configuration proceeds
	# regardless, after defining HAVE_CXX${VERSION} if and only if a
	# supporting mode is found.
	#
	# If the fourth argument is an optional CXX/CXXFLAG/CPPFLAG suffix, e.g.
	# "_FOR_BUILD" or "_FOR_TARGET".
	#
	#
	# LICENSE
	#
	# Copyright (c) 2008 Benjamin Kosnik <bkoz@redhat.com>
	# Copyright (c) 2012 Zack Weinberg <zackw@panix.com>
	# Copyright (c) 2013 Roy Stogner <roystgnr@ices.utexas.edu>
	# Copyright (c) 2014, 2015 Google Inc.; contributed by Alexey Sokolov <sokolov@google.com>
	# Copyright (c) 2015 Paul Norman <penorman@mac.com>
	# Copyright (c) 2015 Moritz Klammler <moritz@klammler.eu>
	# Copyright (c) 2016, 2018 Krzesimir Nowak <qdlacz@gmail.com>
	# Copyright (c) 2019 Enji Cooper <yaneurabeya@gmail.com>
	# Copyright (c) 2020 Jason Merrill <jason@redhat.com>
	#
	# Copying and distribution of this file, with or without modification, are
	# permitted in any medium without royalty provided the copyright notice
	# and this notice are preserved. This file is offered as-is, without any
	# warranty.

	#serial 12

	dnl This macro is based on the code from the AX_CXX_COMPILE_STDCXX_11 macro
	dnl (serial version number 13).

	AC_DEFUN([AX_CXX_COMPILE_STDCXX], [dnl
	m4_if([$1], [11], [ax_cxx_compile_alternatives="11 0x"],
	[$1], [14], [ax_cxx_compile_alternatives="14 1y"],
	[$1], [17], [ax_cxx_compile_alternatives="17 1z"],
	[m4_fatal([invalid first argument `$1' to AX_CXX_COMPILE_STDCXX])])dnl
	m4_if([$2], [], [],
	[$2], [ext], [],
	[$2], [noext], [],
	[m4_fatal([invalid second argument `$2' to AX_CXX_COMPILE_STDCXX])])dnl
	m4_if([$3], [], [ax_cxx_compile_cxx$1_required=true],
	[$3], [mandatory], [ax_cxx_compile_cxx$1_required=true],
	[$3], [optional], [ax_cxx_compile_cxx$1_required=false],
	[m4_fatal([invalid third argument `$3' to AX_CXX_COMPILE_STDCXX])])
	AC_LANG_PUSH([C++])dnl
	ac_success=no
	m4_ifnblank([$4], [dnl
	ax_cv_cxx_compile_cxx$1_orig_cxx="$CXX"
	ax_cv_cxx_compile_cxx$1_orig_cxxflags="$CXXFLAGS"
	ax_cv_cxx_compile_cxx$1_orig_cppflags="$CPPFLAGS"
	CXX="$CXX$4"
	CXXFLAGS="$CXXFLAGS$4"
	CPPFLAGS="$CPPFLAGS$4"])
	m4_if([$2], [], [dnl
	AC_CACHE_CHECK(whether $CXX supports C++$1 features by default,
	ax_cv_cxx_compile_cxx$1$4,
	[AC_COMPILE_IFELSE([AC_LANG_SOURCE([_AX_CXX_COMPILE_STDCXX_testbody_$1])],
	[ax_cv_cxx_compile_cxx$1$4=yes],
	[ax_cv_cxx_compile_cxx$1$4=no])])
	if test x$ax_cv_cxx_compile_cxx$1$4 = xyes; then
	ac_success=yes
	fi])

	m4_if([$2], [noext], [], [dnl
	if test x$ac_success = xno; then
	for alternative in ${ax_cxx_compile_alternatives}; do
	switch="-std=gnu++${alternative}"
	cachevar=AS_TR_SH([ax_cv_cxx_compile_cxx$1$4_$switch])
	AC_CACHE_CHECK(whether $CXX supports C++$1 features with $switch,
	$cachevar,
	[ac_save_CXX="$CXX"
	CXX="$CXX $switch"
	AC_COMPILE_IFELSE([AC_LANG_SOURCE([_AX_CXX_COMPILE_STDCXX_testbody_$1])],
	[eval $cachevar=yes],
	[eval $cachevar=no])
	CXX="$ac_save_CXX"])
	if eval test x\$$cachevar = xyes; then
	CXX="$CXX $switch"
	if test -n "$CXXCPP" ; then
	CXXCPP="$CXXCPP $switch"
	fi
	ac_success=yes
	break
	fi
	done
	fi])

	m4_if([$2], [ext], [], [dnl
	if test x$ac_success = xno; then
	dnl HP's aCC needs +std=c++11 according to:
	dnl http://h21007.www2.hp.com/portal/download/files/unprot/aCxx/PDF_Release_Notes/769149-001.pdf
	dnl Cray's crayCC needs "-h std=c++11"
	for alternative in ${ax_cxx_compile_alternatives}; do
	for switch in -std=c++${alternative} +std=c++${alternative} "-h std=c++${alternative}"; do
	cachevar=AS_TR_SH([ax_cv_cxx_compile_cxx$1$4_$switch])
	AC_CACHE_CHECK(whether $CXX supports C++$1 features with $switch,
	$cachevar,
	[ac_save_CXX="$CXX"
	CXX="$CXX $switch"
	AC_COMPILE_IFELSE([AC_LANG_SOURCE([_AX_CXX_COMPILE_STDCXX_testbody_$1])],
	[eval $cachevar=yes],
	[eval $cachevar=no])
	CXX="$ac_save_CXX"])
	if eval test x\$$cachevar = xyes; then
	CXX="$CXX $switch"
	if test -n "$CXXCPP" ; then
	CXXCPP="$CXXCPP $switch"
	fi
	ac_success=yes
	break
	fi
	done
	if test x$ac_success = xyes; then
	break
	fi
	done
	fi])
	m4_ifnblank([$4], [dnl
	CXX$4="$CXX"
	CXXFLAGS$4="$CXXFLAGS"
	CPPFLAGS$4="$CPPFLAGS"
	CXX="$ax_cv_cxx_compile_cxx$1_orig_cxx"
	CXXFLAGS="$ax_cv_cxx_compile_cxx$1_orig_cxxflags"
	CPPFLAGS="$ax_cv_cxx_compile_cxx$1_orig_cppflags"])
	AC_LANG_POP([C++])
	if test x$ax_cxx_compile_cxx$1_required = xtrue; then
	if test x$ac_success = xno; then
	AC_MSG_ERROR([*** A compiler with support for C++$1 language features is required.])
	fi
	fi
	if test x$ac_success = xno; then
	HAVE_CXX$1$4=0
	AC_MSG_NOTICE([No compiler with C++$1 support was found])
	else
	HAVE_CXX$1$4=1
	AC_DEFINE(HAVE_CXX$1$4,1,
	[define if the compiler supports basic C++$1 syntax])
	fi
	AC_SUBST(HAVE_CXX$1$4)
	])


	dnl Test body for checking C++11 support

	m4_define([_AX_CXX_COMPILE_STDCXX_testbody_11],
	_AX_CXX_COMPILE_STDCXX_testbody_new_in_11
	)


	dnl Test body for checking C++14 support

	m4_define([_AX_CXX_COMPILE_STDCXX_testbody_14],
	_AX_CXX_COMPILE_STDCXX_testbody_new_in_11
	_AX_CXX_COMPILE_STDCXX_testbody_new_in_14
	)

	m4_define([_AX_CXX_COMPILE_STDCXX_testbody_17],
	_AX_CXX_COMPILE_STDCXX_testbody_new_in_11
	_AX_CXX_COMPILE_STDCXX_testbody_new_in_14
	_AX_CXX_COMPILE_STDCXX_testbody_new_in_17
	)

	dnl Tests for new features in C++11

	m4_define([_AX_CXX_COMPILE_STDCXX_testbody_new_in_11], [[

	// If the compiler admits that it is not ready for C++11, why torture it?
	// Hopefully, this will speed up the test.

	#ifndef __cplusplus

	#error "This is not a C++ compiler"

	#elif __cplusplus < 201103L

	#error "This is not a C++11 compiler"

	#else

	namespace cxx11
	{

	namespace test_static_assert
	{

	template <typename T>
	struct check
	{
	static_assert(sizeof(int) <= sizeof(T), "not big enough");
	};

	}

	namespace test_final_override
	{

	struct Base
	{
	virtual ~Base() {}
	virtual void f() {}
	};

	struct Derived : public Base
	{
	virtual ~Derived() override {}
	virtual void f() override {}
	};

	}

	namespace test_double_right_angle_brackets
	{

	template < typename T >
	struct check {};

	typedef check<void> single_type;
	typedef check<check<void>> double_type;
	typedef check<check<check<void>>> triple_type;
	typedef check<check<check<check<void>>>> quadruple_type;

	}

	namespace test_decltype
	{

	int
	f()
	{
	int a = 1;
	decltype(a) b = 2;
	return a + b;
	}

	}

	namespace test_type_deduction
	{

	template < typename T1, typename T2 >
	struct is_same
	{
	static const bool value = false;
	};

	template < typename T >
	struct is_same<T, T>
	{
	static const bool value = true;
	};

	template < typename T1, typename T2 >
	auto
	add(T1 a1, T2 a2) -> decltype(a1 + a2)
	{
	return a1 + a2;
	}

	int
	test(const int c, volatile int v)
	{
	static_assert(is_same<int, decltype(0)>::value == true, "");
	static_assert(is_same<int, decltype(c)>::value == false, "");
	static_assert(is_same<int, decltype(v)>::value == false, "");
	auto ac = c;
	auto av = v;
	auto sumi = ac + av + 'x';
	auto sumf = ac + av + 1.0;
	static_assert(is_same<int, decltype(ac)>::value == true, "");
	static_assert(is_same<int, decltype(av)>::value == true, "");
	static_assert(is_same<int, decltype(sumi)>::value == true, "");
	static_assert(is_same<int, decltype(sumf)>::value == false, "");
	static_assert(is_same<int, decltype(add(c, v))>::value == true, "");
	return (sumf > 0.0) ? sumi : add(c, v);
	}

	}

	namespace test_noexcept
	{

	int f() { return 0; }
	int g() noexcept { return 0; }

	static_assert(noexcept(f()) == false, "");
	static_assert(noexcept(g()) == true, "");

	}

	namespace test_constexpr
	{

	template < typename CharT >
	unsigned long constexpr
	strlen_c_r(const CharT *const s, const unsigned long acc) noexcept
	{
	return *s ? strlen_c_r(s + 1, acc + 1) : acc;
	}

	template < typename CharT >
	unsigned long constexpr
	strlen_c(const CharT *const s) noexcept
	{
	return strlen_c_r(s, 0UL);
	}

	static_assert(strlen_c("") == 0UL, "");
	static_assert(strlen_c("1") == 1UL, "");
	static_assert(strlen_c("example") == 7UL, "");
	static_assert(strlen_c("another\0example") == 7UL, "");

	}

	namespace test_rvalue_references
	{

	template < int N >
	struct answer
	{
	static constexpr int value = N;
	};

	answer<1> f(int&) { return answer<1>(); }
	answer<2> f(const int&) { return answer<2>(); }
	answer<3> f(int&&) { return answer<3>(); }

	void
	test()
	{
	int i = 0;
	const int c = 0;
	static_assert(decltype(f(i))::value == 1, "");
	static_assert(decltype(f(c))::value == 2, "");
	static_assert(decltype(f(0))::value == 3, "");
	}

	}

	namespace test_uniform_initialization
	{

	struct test
	{
	static const int zero {};
	static const int one {1};
	};

	static_assert(test::zero == 0, "");
	static_assert(test::one == 1, "");

	}

	namespace test_lambdas
	{

	void
	test1()
	{
	auto lambda1 = [](){};
	auto lambda2 = lambda1;
	lambda1();
	lambda2();
	}

	int
	test2()
	{
	auto a = [](int i, int j){ return i + j; }(1, 2);
	auto b = []() -> int { return '0'; }();
	auto c = [=](){ return a + b; }();
	auto d = [&](){ return c; }();
	auto e = [a, &b](int x) mutable {
	const auto identity = [](int y){ return y; };
	for (auto i = 0; i < a; ++i)
	a += b--;
	return x + identity(a + b);
	}(0);
	return a + b + c + d + e;
	}

	int
	test3()
	{
	const auto nullary = [](){ return 0; };
	const auto unary = [](int x){ return x; };
	using nullary_t = decltype(nullary);
	using unary_t = decltype(unary);
	const auto higher1st = [](nullary_t f){ return f(); };
	const auto higher2nd = [unary](nullary_t f1){
	return [unary, f1](unary_t f2){ return f2(unary(f1())); };
	};
	return higher1st(nullary) + higher2nd(nullary)(unary);
	}

	}

	namespace test_variadic_templates
	{

	template <int...>
	struct sum;

	template <int N0, int... N1toN>
	struct sum<N0, N1toN...>
	{
	static constexpr auto value = N0 + sum<N1toN...>::value;
	};

	template <>
	struct sum<>
	{
	static constexpr auto value = 0;
	};

	static_assert(sum<>::value == 0, "");
	static_assert(sum<1>::value == 1, "");
	static_assert(sum<23>::value == 23, "");
	static_assert(sum<1, 2>::value == 3, "");
	static_assert(sum<5, 5, 11>::value == 21, "");
	static_assert(sum<2, 3, 5, 7, 11, 13>::value == 41, "");

	}

	// http://stackoverflow.com/questions/13728184/template-aliases-and-sfinae
	// Clang 3.1 fails with headers of libstd++ 4.8.3 when using std::function
	// because of this.
	namespace test_template_alias_sfinae
	{

	struct foo {};

	template<typename T>
	using member = typename T::member_type;

	template<typename T>
	void func(...) {}

	template<typename T>
	void func(member<T>*) {}

	void test();

	void test() { func<foo>(0); }

	}

	} // namespace cxx11

	#endif // __cplusplus >= 201103L

	]])


	dnl Tests for new features in C++14

	m4_define([_AX_CXX_COMPILE_STDCXX_testbody_new_in_14], [[

	// If the compiler admits that it is not ready for C++14, why torture it?
	// Hopefully, this will speed up the test.

	#ifndef __cplusplus

	#error "This is not a C++ compiler"

	#elif __cplusplus < 201402L

	#error "This is not a C++14 compiler"

	#else

	namespace cxx14
	{

	namespace test_polymorphic_lambdas
	{

	int
	test()
	{
	const auto lambda = [](auto&&... args){
	const auto istiny = [](auto x){
	return (sizeof(x) == 1UL) ? 1 : 0;
	};
	const int aretiny[] = { istiny(args)... };
	return aretiny[0];
	};
	return lambda(1, 1L, 1.0f, '1');
	}

	}

	namespace test_binary_literals
	{

	constexpr auto ivii = 0b0000000000101010;
	static_assert(ivii == 42, "wrong value");

	}

	namespace test_generalized_constexpr
	{

	template < typename CharT >
	constexpr unsigned long
	strlen_c(const CharT *const s) noexcept
	{
	auto length = 0UL;
	for (auto p = s; *p; ++p)
	++length;
	return length;
	}

	static_assert(strlen_c("") == 0UL, "");
	static_assert(strlen_c("x") == 1UL, "");
	static_assert(strlen_c("test") == 4UL, "");
	static_assert(strlen_c("another\0test") == 7UL, "");

	}

	namespace test_lambda_init_capture
	{

	int
	test()
	{
	auto x = 0;
	const auto lambda1 = [a = x](int b){ return a + b; };
	const auto lambda2 = [a = lambda1(x)](){ return a; };
	return lambda2();
	}

	}

	namespace test_digit_separators
	{

	constexpr auto ten_million = 100'000'000;
	static_assert(ten_million == 100000000, "");

	}

	namespace test_return_type_deduction
	{

	auto f(int& x) { return x; }
	decltype(auto) g(int& x) { return x; }

	template < typename T1, typename T2 >
	struct is_same
	{
	static constexpr auto value = false;
	};

	template < typename T >
	struct is_same<T, T>
	{
	static constexpr auto value = true;
	};

	int
	test()
	{
	auto x = 0;
	static_assert(is_same<int, decltype(f(x))>::value, "");
	static_assert(is_same<int&, decltype(g(x))>::value, "");
	return x;
	}

	}

	} // namespace cxx14

	#endif // __cplusplus >= 201402L

	]])


	dnl Tests for new features in C++17

	m4_define([_AX_CXX_COMPILE_STDCXX_testbody_new_in_17], [[

	// If the compiler admits that it is not ready for C++17, why torture it?
	// Hopefully, this will speed up the test.

	#ifndef __cplusplus

	#error "This is not a C++ compiler"

	#elif __cplusplus < 201703L

	#error "This is not a C++17 compiler"

	#else

	#include <initializer_list>
	#include <utility>
	#include <type_traits>

	namespace cxx17
	{

	namespace test_constexpr_lambdas
	{

	constexpr int foo = [](){return 42;}();

	}

	namespace test::nested_namespace::definitions
	{

	}

	namespace test_fold_expression
	{

	template<typename... Args>
	int multiply(Args... args)
	{
	return (args * ... * 1);
	}

	template<typename... Args>
	bool all(Args... args)
	{
	return (args && ...);
	}

	}

	namespace test_extended_static_assert
	{

	static_assert (true);

	}

	namespace test_auto_brace_init_list
	{

	auto foo = {5};
	auto bar {5};

	static_assert(std::is_same<std::initializer_list<int>, decltype(foo)>::value);
	static_assert(std::is_same<int, decltype(bar)>::value);
	}

	namespace test_typename_in_template_template_parameter
	{

	template<template<typename> typename X> struct D;

	}

	namespace test_fallthrough_nodiscard_maybe_unused_attributes
	{

	int f1()
	{
	return 42;
	}

	[[nodiscard]] int f2()
	{
	[[maybe_unused]] auto unused = f1();

	switch (f1())
	{
	case 17:
	f1();
	[[fallthrough]];
	case 42:
	f1();
	}
	return f1();
	}

	}

	namespace test_extended_aggregate_initialization
	{

	struct base1
	{
	int b1, b2 = 42;
	};

	struct base2
	{
	base2() {
	b3 = 42;
	}
	int b3;
	};

	struct derived : base1, base2
	{
	int d;
	};

	derived d1 {{1, 2}, {}, 4}; // full initialization
	derived d2 {{}, {}, 4}; // value-initialized bases

	}

	namespace test_general_range_based_for_loop
	{

	struct iter
	{
	int i;

	int& operator* ()
	{
	return i;
	}

	const int& operator* () const
	{
	return i;
	}

	iter& operator++()
	{
	++i;
	return *this;
	}
	};

	struct sentinel
	{
	int i;
	};

	bool operator== (const iter& i, const sentinel& s)
	{
	return i.i == s.i;
	}

	bool operator!= (const iter& i, const sentinel& s)
	{
	return !(i == s);
	}

	struct range
	{
	iter begin() const
	{
	return {0};
	}

	sentinel end() const
	{
	return {5};
	}
	};

	void f()
	{
	range r {};

	for (auto i : r)
	{
	[[maybe_unused]] auto v = i;
	}
	}

	}

	namespace test_lambda_capture_asterisk_this_by_value
	{

	struct t
	{
	int i;
	int foo()
	{
	return [*this]()
	{
	return i;
	}();
	}
	};

	}

	namespace test_enum_class_construction
	{

	enum class byte : unsigned char
	{};

	byte foo {42};

	}

	namespace test_constexpr_if
	{

	template <bool cond>
	int f ()
	{
	if constexpr(cond)
	{
	return 13;
	}
	else
	{
	return 42;
	}
	}

	}

	namespace test_selection_statement_with_initializer
	{

	int f()
	{
	return 13;
	}

	int f2()
	{
	if (auto i = f(); i > 0)
	{
	return 3;
	}

	switch (auto i = f(); i + 4)
	{
	case 17:
	return 2;

	default:
	return 1;
	}
	}

	}

	namespace test_template_argument_deduction_for_class_templates
	{

	template <typename T1, typename T2>
	struct pair
	{
	pair (T1 p1, T2 p2)
	: m1 {p1},
	m2 {p2}
	{}

	T1 m1;
	T2 m2;
	};

	void f()
	{
	[[maybe_unused]] auto p = pair{13, 42u};
	}

	}

	namespace test_non_type_auto_template_parameters
	{

	template <auto n>
	struct B
	{};

	B<5> b1;
	B<'a'> b2;

	}

	namespace test_structured_bindings
	{

	int arr[2] = { 1, 2 };
	std::pair<int, int> pr = { 1, 2 };

	auto f1() -> int(&)[2]
	{
	return arr;
	}

	auto f2() -> std::pair<int, int>&
	{
	return pr;
	}

	struct S
	{
	int x1 : 2;
	volatile double y1;
	};

	S f3()
	{
	return {};
	}

	auto [ x1, y1 ] = f1();
	auto& [ xr1, yr1 ] = f1();
	auto [ x2, y2 ] = f2();
	auto& [ xr2, yr2 ] = f2();
	const auto [ x3, y3 ] = f3();

	}

	namespace test_exception_spec_type_system
	{

	struct Good {};
	struct Bad {};

	void g1() noexcept;
	void g2();

	template<typename T>
	Bad
	f(T, T);

	template<typename T1, typename T2>
	Good
	f(T1, T2);

	static_assert (std::is_same_v<Good, decltype(f(g1, g2))>);

	}

	namespace test_inline_variables
	{

	template<class T> void f(T)
	{}

	template<class T> inline T g(T)
	{
	return T{};
	}

	template<> inline void f<>(int)
	{}

	template<> int g<>(int)
	{
	return 5;
	}

	}

	} // namespace cxx17

	#endif // __cplusplus < 201703L

	]])