llvm/clang/test/SemaCXX/cxx1y-generic-lambdas.cpp

// RUN: %clang_cc1 -std=c++1y -verify -fblocks -emit-llvm-only %s
// RUN: %clang_cc1 -std=c++1y -verify -fsyntax-only -fblocks -fdelayed-template-parsing %s -DDELAYED_TEMPLATE_PARSING
// RUN: %clang_cc1 -std=c++1y -verify -fsyntax-only -fblocks -fms-extensions %s -DMS_EXTENSIONS
// RUN: %clang_cc1 -std=c++1y -verify -fsyntax-only -fblocks -fdelayed-template-parsing -fms-extensions %s -DMS_EXTENSIONS -DDELAYED_TEMPLATE_PARSING
// RUN: %clang_cc1 -std=c++1y -verify -fblocks -triple i386-windows-pc -emit-llvm-only %s
// RUN: %clang_cc1 -std=c++1y -verify -fsyntax-only -fblocks -triple i386-windows-pc -fdelayed-template-parsing %s -DDELAYED_TEMPLATE_PARSING
// RUN: %clang_cc1 -std=c++1y -verify -fsyntax-only -fblocks -triple i386-windows-pc -fms-extensions %s -DMS_EXTENSIONS
// RUN: %clang_cc1 -std=c++1y -verify -fsyntax-only -fblocks -triple i386-windows-pc -fdelayed-template-parsing -fms-extensions %s -DMS_EXTENSIONS -DDELAYED_TEMPLATE_PARSING

template<class F, class ...Rest> struct first_impl { typedef F type; };
template<class ...Args> using first = typename first_impl<Args...>::type;

namespace simple_explicit_capture {
  void test() {
    int i;
    auto L = [i](auto a) { return i + a; };
    L(3.14);
  }
}

namespace explicit_call {
int test() {
  auto L = [](auto a) { return a; };
  L.operator()(3);
  L.operator()<char>(3.14); //expected-warning{{implicit conversion}}
  return 0;
}
} //end ns

namespace test_conversion_to_fptr_2 {

template<class T> struct X {

  T (*fp)(T) = [](auto a) { return a; };

};

X<int> xi;

template<class T>
void fooT(T t, T (*fp)(T) = [](auto a) { return a; }) {
  fp(t);
}

int test() {
{
  auto L = [](auto a) { return a; };
  int (*fp)(int) = L;
  fp(5);
  L(3);
  char (*fc)(char) = L;
  fc('b');
  L('c');
  double (*fd)(double) = L;
  fd(3.14);
  fd(6.26);
  L(4.25);
}
{
  auto L = [](auto a) ->int { return a; }; //expected-note 2{{candidate template ignored}}
  int (*fp)(int) = L;
  char (*fc)(char) = L; //expected-error{{no viable conversion}}
  double (*fd)(double) = L; //expected-error{{no viable conversion}}
}
{
  int x = 5;
  auto L = [=](auto b, char c = 'x') {
    int i = x;
    return [](auto a) ->decltype(a) { return a; };
  };
  int (*fp)(int) = L(8);
  fp(5);
  L(3);
  char (*fc)(char) = L('a');
  fc('b');
  L('c');
  double (*fd)(double) = L(3.14);
  fd(3.14);
  fd(6.26);

}
{
 auto L = [=](auto b) {
    return [](auto a) ->decltype(b)* { return (decltype(b)*)0; };
  };
  int* (*fp)(int) = L(8);
  fp(5);
  L(3);
  char* (*fc)(char) = L('a');
  fc('b');
  L('c');
  double* (*fd)(double) = L(3.14);
  fd(3.14);
  fd(6.26);
}
{
 auto L = [=](auto b) {
    return [](auto a) ->decltype(b)* { return (decltype(b)*)0; }; //expected-note{{candidate template ignored}}
  };
  char* (*fp)(int) = L('8');
  fp(5);
  char* (*fc)(char) = L('a');
  fc('b');
  double* (*fi)(int) = L(3.14);
  fi(5);
  int* (*fi2)(int) = L(3.14); //expected-error{{no viable conversion}}
}

{
 auto L = [=](auto b) {
    return [](auto a) {
      return [=](auto c) {
        return [](auto d) ->decltype(a + b + c + d) { return d; };
      };
    };
  };
  int (*fp)(int) = L('8')(3)(short{});
  double (*fs)(char) = L(3.14)(short{})('4');
}

  fooT(3);
  fooT('a');
  fooT(3.14);
  fooT("abcdefg");
  return 0;
}
int run2 = test();

}


namespace test_conversion_to_fptr {

void f1(int (*)(int)) { }
void f2(char (*)(int)) { } // expected-note{{candidate}}
void g(int (*)(int)) { } // #1 expected-note{{candidate}}
void g(char (*)(char)) { } // #2 expected-note{{candidate}}
void h(int (*)(int)) { } // #3
void h(char (*)(int)) { } // #4

int test() {
{
  auto glambda = [](auto a) { return a; };
  glambda(1);
  f1(glambda); // OK
  f2(glambda); // expected-error{{no matching function}}
  g(glambda); // expected-error{{call to 'g' is ambiguous}}
  h(glambda); // OK: calls #3 since it is convertible from ID

  int& (*fpi)(int*) = [](auto* a) -> auto& { return *a; }; // OK

}
{

  auto L = [](auto a) { return a; };
  int (*fp)(int) = L;
  fp(5);
  L(3);
  char (*fc)(char) = L;
  fc('b');
  L('c');
  double (*fd)(double) = L;
  fd(3.14);
  fd(6.26);
  L(4.25);
}
{
  auto L = [](auto a) ->int { return a; }; //expected-note 2{{candidate template ignored}}
  int (*fp)(int) = L;
  char (*fc)(char) = L; //expected-error{{no viable conversion}}
  double (*fd)(double) = L; //expected-error{{no viable conversion}}
}
{
  int* (*fp)(int*) = [](auto *a) -> auto* { return a; };
  fp(0);
}
}

namespace more_converion_to_ptr_to_function_tests {


int test() {
  {
    int& (*fpi)(int*) = [](auto* a) -> auto& { return *a; }; // OK
    int (*fp2)(int) = [](auto b) -> int {  return b; };
    int (*fp3)(char) = [](auto c) -> int { return c; };
    char (*fp4)(int) = [](auto d) { return d; }; //expected-error{{no viable conversion}}\
                                                 //expected-note{{candidate function [with d:auto = int]}}
    char (*fp5)(char) = [](auto e) -> int { return e; }; //expected-error{{no viable conversion}}\
                                                 //expected-note{{candidate template ignored}}

    fp2(3);
    fp3('\n');
    fp3('a');
    return 0;
  }
} // end test()

template<class ... Ts> void vfun(Ts ... ) { }

int variadic_test() {

 int (*fp)(int, char, double) = [](auto ... a) -> int { vfun(a...); return 4; };
 fp(3, '4', 3.14);

 int (*fp2)(int, char, double) = [](auto ... a) { vfun(a...); return 4; };
 fp(3, '4', 3.14);
 return 2;
}

} // end ns

namespace conversion_operator {
  void test() {
    auto L = [](auto a) -> int { return a; }; // expected-error {{cannot initialize}}
    int (*fp)(int) = L;
    int (&fp2)(int) = [](auto a) { return a; };  // expected-error{{non-const lvalue}}
    int (&&fp3)(int) = [](auto a) { return a; };
    // expected-error@-1   {{no viable conversion}}
    // expected-note-re@-2 {{candidate template ignored: could not match 'auto (*)(auto){{.*}}' against 'int (int)'}}

    using F = int(int);
    using G = int(void*);
    L.operator F*();
    L.operator G*(); // expected-note-re {{instantiation of function template specialization '{{.*}}::operator()<void *>'}}

    // Here, the conversion function is named 'operator auto (*)(int)', and
    // there is no way to write that name in valid C++.
    auto M = [](auto a) -> auto { return a; };
    M.operator F*(); // expected-error {{no member named 'operator int (*)(int)'}}
  }
}
}

namespace return_type_deduction_ok {
 auto l = [](auto a) ->auto { return a; }(2);
 auto l2 = [](auto a) ->decltype(auto) { return a; }(2);
 auto l3 = [](auto a) { return a; }(2);

}

namespace generic_lambda_as_default_argument_ok {
  void test(int i = [](auto a)->int { return a; }(3)) {
  }
}

namespace nested_non_capturing_lambda_tests {
template<class ... Ts> void print(Ts ...) { }
int test() {
{
  auto L = [](auto a) {
    return [](auto b) {
      return b;
    };
  };
  auto M = L(3);
  M(4.15);
 }
{
  int i = 10; //expected-note 3{{declared here}}
  auto L = [](auto a) {
    return [](auto b) { //expected-note 3{{begins here}} expected-note 6 {{capture 'i' by}} expected-note 6 {{default capture by}} expected-note {{while substituting into a lambda}}
      i = b;  //expected-error 3{{cannot be implicitly captured}}
      return b;
    };
  };
  auto M = L(3); //expected-note{{instantiation}}
  M(4.15); //expected-note{{instantiation}}
 }
 {
  int i = 10;
  auto L = [](auto a) {
    return [](auto b) {
      b = sizeof(i);  //ok
      return b;
    };
  };
 }
 {
  auto L = [](auto a) {
    print("a = ", a, "\n");
    return [](auto b) ->decltype(a) {
      print("b = ", b, "\n");
      return b;
    };
  };
  auto M = L(3);
  M(4.15);
 }

{
  auto L = [](auto a) ->decltype(a) {
    print("a = ", a, "\n");
    return [](auto b) ->decltype(a) {
      // expected-error@-1   {{no viable conversion}}
      // expected-note-re@-2 {{candidate template ignored: could not match 'auto (*)(auto){{.*}}' ({{.*}}) against 'decltype(a)' (aka 'int')}}
      print("b = ", b, "\n");
      return b;
    };
  };
  auto M = L(3); //expected-note{{in instantiation of}}
 }
{
  auto L = [](auto a) {
    print("a = ", a, "\n");
    return [](auto ... b) ->decltype(a) {
      print("b = ", b ..., "\n");
      return 4;
    };
  };
  auto M = L(3);
  M(4.15, 3, "fv");
}

{
  auto L = [](auto a) {
    print("a = ", a, "\n");
    return [](auto ... b) ->decltype(a) {
      print("b = ", b ..., "\n");
      return 4;
    };
  };
  auto M = L(3);
  int (*fp)(double, int, const char*) = M;
  fp(4.15, 3, "fv");
}

{
  auto L = [](auto a) {
    print("a = ", a, "\n");
    return [](char b) {
      return [](auto ... c) ->decltype(b) {
        print("c = ", c ..., "\n");
        return 42;
      };
    };
  };
  L(4);
  auto M = L(3);
  M('a');
  auto N = M('x');
  N("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
  char (*np)(const char*, int, const char*, double, const char*, int) = N;
  np("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
}


{
  auto L = [](auto a) {
    print("a = ", a, "\n");
    return [](decltype(a) b) {
      return [](auto ... c) ->decltype(b) {
        print("c = ", c ..., "\n");
        return 42;
      };
    };
  };
  L('4');
  auto M = L('3');
  M('a');
  auto N = M('x');
  N("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
  char (*np)(const char*, int, const char*, double, const char*, int) = N;
  np("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
}


{
 struct X {
  static void foo(double d) { }
  void test() {
    auto L = [](auto a) {
      print("a = ", a, "\n");
      foo(a);
      return [](decltype(a) b) {
        foo(b);
        foo(sizeof(a) + sizeof(b));
        return [](auto ... c) ->decltype(b) {
          print("c = ", c ..., "\n");
          foo(decltype(b){});
          foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
          return 42;
        };
      };
    };
    L('4');
    auto M = L('3');
    M('a');
    auto N = M('x');
    N("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
    char (*np)(const char*, int, const char*, double, const char*, int) = N;
    np("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
  }
};
X x;
x.test();
}
// Make sure we can escape the function
{
 struct X {
  static void foo(double d) { }
  auto test() {
    auto L = [](auto a) {
      print("a = ", a, "\n");
      foo(a);
      return [](decltype(a) b) {
        foo(b);
        foo(sizeof(a) + sizeof(b));
        return [](auto ... c) ->decltype(b) {
          print("c = ", c ..., "\n");
          foo(decltype(b){});
          foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
          return 42;
        };
      };
    };
    return L;
  }
};
  X x;
  auto L = x.test();
  L('4');
  auto M = L('3');
  M('a');
  auto N = M('x');
  N("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
  char (*np)(const char*, int, const char*, double, const char*, int) = N;
  np("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
}

{
 struct X {
  static void foo(double d) { }
  auto test() {
    auto L = [](auto a) {
      print("a = ", a, "\n");
      foo(a);
      return [](decltype(a) b) {
        foo(b);
        foo(sizeof(a) + sizeof(b));
        return [](auto ... c) {
          print("c = ", c ..., "\n");
          foo(decltype(b){});
          foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
          return [](decltype(c) ... d) ->decltype(a) { //expected-note{{candidate}}
            print("d = ", d ..., "\n");
            foo(decltype(b){});
            foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
            return decltype(a){};
          };
        };
      };
    };
    return L;
  }
};
  X x;
  auto L = x.test();
  L('4');
  auto M = L('3');
  M('a');
  auto N = M('x');
  auto O = N("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
  char (*np)(const char*, int, const char*, double, const char*, int) = O;
  np("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
  int (*np2)(const char*, int, const char*, double, const char*, int) = O; // expected-error{{no viable conversion}}

}
} // end test()

namespace wrapped_within_templates {

namespace explicit_return {
template<class T> int fooT(T t) {
  auto L = [](auto a) -> void {
    auto M = [](char b) -> void {
      auto N = [](auto c) -> void {
        int x = 0;
        x = sizeof(a);
        x = sizeof(b);
        x = sizeof(c);
      };
      N('a');
      N(decltype(a){});
    };
  };
  L(t);
  L(3.14);
  return 0;
}

int run = fooT('a') + fooT(3.14);

} // end explicit_return

namespace implicit_return_deduction {
template<class T> auto fooT(T t) {
  auto L = [](auto a)  {
    auto M = [](char b)  {
      auto N = [](auto c)  {
        int x = 0;
        x = sizeof(a);
        x = sizeof(b);
        x = sizeof(c);
      };
      N('a');
      N(decltype(a){});
    };
  };
  L(t);
  L(3.14);
  return 0;
}

int run = fooT('a') + fooT(3.14);

template<class ... Ts> void print(Ts ... ts) { }

template<class ... Ts> auto fooV(Ts ... ts) {
  auto L = [](auto ... a) {
    auto M = [](decltype(a) ... b) {
      auto N = [](auto c) {
        int x = 0;
        x = sizeof...(a);
        x = sizeof...(b);
        x = sizeof(c);
      };
      N('a');
      N(N);
      N(first<Ts...>{});
    };
    M(a...);
    print("a = ", a..., "\n");
  };
  L(L, ts...);
  print("ts = ", ts..., "\n");
  return 0;
}

int run2 = fooV(3.14, " ", '4', 5) + fooV("BC", 3, 2.77, 'A', float{}, short{}, unsigned{});

} //implicit_return_deduction


} //wrapped_within_templates

namespace at_ns_scope {
  void foo(double d) { }
  auto test() {
    auto L = [](auto a) {
      print("a = ", a, "\n");
      foo(a);
      return [](decltype(a) b) {
        foo(b);
        foo(sizeof(a) + sizeof(b));
        return [](auto ... c) {
          print("c = ", c ..., "\n");
          foo(decltype(b){});
          foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
          return [](decltype(c) ... d) ->decltype(a) { //expected-note{{candidate}}
            print("d = ", d ..., "\n");
            foo(decltype(b){});
            foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
            return decltype(a){};
          };
        };
      };
    };
    return L;
  }
auto L = test();
auto L_test = L('4');
auto M = L('3');
auto M_test = M('a');
auto N = M('x');
auto O = N("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
char (*np)(const char*, int, const char*, double, const char*, int) = O;
auto NP_result = np("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
int (*np2)(const char*, int, const char*, double, const char*, int) = O; // expected-error{{no viable conversion}}



}

namespace variadic_tests_1 {
template<class ... Ts> void print(Ts ... ts) { }

template<class F, class ... Rest> F& FirstArg(F& f, Rest...) { return f; }

template<class ... Ts> int fooV(Ts ... ts) {
  auto L = [](auto ... a) -> void {
    auto M = [](decltype(a) ... b) -> void {
      auto N = [](auto c) -> void {
        int x = 0;
        x = sizeof...(a);
        x = sizeof...(b);
        x = sizeof(c);
      };
      N('a');
      N(N);
      N(first<Ts...>{});
    };
    M(a...);
    print("a = ", a..., "\n");
  };
  L(L, ts...);
  print("ts = ", ts..., "\n");
  return 0;
}

int run2 = fooV(3.14, " ", '4', 5) + fooV("BC", 3, 2.77, 'A', float{}, short{}, unsigned{});

namespace more_variadic_1 {

template<class ... Ts> int fooV(Ts ... ts) {
  auto L = [](auto ... a) {
    auto M = [](decltype(a) ... b) -> void {
      auto N = [](auto c) -> void {
        int x = 0;
        x = sizeof...(a);
        x = sizeof...(b);
        x = sizeof(c);
      };
      N('a');
      N(N);
      N(first<Ts...>{});
    };
    M(a...);
    return M;
  };
  auto M = L(L, ts...);
  decltype(L(L, ts...)) (*fp)(decltype(L), decltype(ts) ...) = L;
  void (*fp2)(decltype(L), decltype(ts) ...) = L(L, ts...);

  {
    auto L = [](auto ... a) {
      auto M = [](decltype(a) ... b) {
        auto N = [](auto c) -> void {
          int x = 0;
          x = sizeof...(a);
          x = sizeof...(b);
          x = sizeof(c);
        };
        N('a');
        N(N);
        N(first<Ts...>{});
        return N;
      };
      M(a...);
      return M;
    };
    auto M = L(L, ts...);
    decltype(L(L, ts...)) (*fp)(decltype(L), decltype(ts) ...) = L;
    fp(L, ts...);
    decltype(L(L, ts...)(L, ts...)) (*fp2)(decltype(L), decltype(ts) ...) = L(L, ts...);
    fp2 = fp(L, ts...);
    void (*fp3)(char) = fp2(L, ts...);
    fp3('a');
  }
  return 0;
}

int run2 = fooV(3.14, " ", '4', 5) + fooV("BC", 3, 2.77, 'A', float{}, short{}, unsigned{});


} //end ns more_variadic_1

} // end ns variadic_tests_1

namespace at_ns_scope_within_class_member {
 struct X {
  static void foo(double d) { }
  auto test() {
    auto L = [](auto a) {
      print("a = ", a, "\n");
      foo(a);
      return [](decltype(a) b) {
        foo(b);
        foo(sizeof(a) + sizeof(b));
        return [](auto ... c) {
          print("c = ", c ..., "\n");
          foo(decltype(b){});
          foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
          return [](decltype(c) ... d) ->decltype(a) { //expected-note{{candidate}}
            print("d = ", d ..., "\n");
            foo(decltype(b){});
            foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
            return decltype(a){};
          };
        };
      };
    };
    return L;
  }
};
X x;
auto L = x.test();
auto L_test = L('4');
auto M = L('3');
auto M_test = M('a');
auto N = M('x');
auto O = N("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
char (*np)(const char*, int, const char*, double, const char*, int) = O;
auto NP_result = np("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
int (*np2)(const char*, int, const char*, double, const char*, int) = O; // expected-error{{no viable conversion}}

} //end at_ns_scope_within_class_member


namespace at_ns_scope_within_class_template_member {
 struct X {
  static void foo(double d) { }
  template<class T = int>
  auto test(T = T{}) {
    auto L = [](auto a) {
      print("a = ", a, "\n");
      foo(a);
      return [](decltype(a) b) {
        foo(b);
        foo(sizeof(a) + sizeof(b));
        return [](auto ... c) {
          print("c = ", c ..., "\n");
          foo(decltype(b){});
          foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
          return [](decltype(c) ... d) ->decltype(a) { //expected-note{{candidate}}
            print("d = ", d ..., "\n");
            foo(decltype(b){});
            foo(sizeof(decltype(a)*) + sizeof(decltype(b)*));
            return decltype(a){};
          };
        };
      };
    };
    return L;
  }

};
X x;
auto L = x.test();
auto L_test = L('4');
auto M = L('3');
auto M_test = M('a');
auto N = M('x');
auto O = N("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
char (*np)(const char*, int, const char*, double, const char*, int) = O;
auto NP_result = np("\n3 = ", 3, "\n6.14 = ", 6.14, "\n4'123'456 = ", 4'123'456);
int (*np2)(const char*, int, const char*, double, const char*, int) = O; // expected-error{{no viable conversion}}

} //end at_ns_scope_within_class_member


namespace nested_generic_lambdas_123 {
void test() {
  auto L = [](auto a) -> int {
    auto M = [](auto b, decltype(a) b2) -> int {
      return 1;
    };
    M(a, a);
  };
  L(3);
}
template<class T> void foo(T) {
 auto L = [](auto a) { return a; };
}
template void foo(int);
} // end ns nested_generic_lambdas_123

namespace nested_fptr_235 {
int test()
{
  auto L = [](auto b) {
    return [](auto a) ->decltype(a) { return a; };
  };
  int (*fp)(int) = L(8);
  fp(5);
  L(3);
  char (*fc)(char) = L('a');
  fc('b');
  L('c');
  double (*fd)(double) = L(3.14);
  fd(3.14);
  fd(6.26);
  return 0;
}
int run = test();
}


namespace fptr_with_decltype_return_type {
template<class F, class ... Rest> F& FirstArg(F& f, Rest& ... r) { return f; };
template<class ... Ts> auto vfun(Ts&& ... ts) {
  print(ts...);
  return FirstArg(ts...);
}
int test()
{
 {
   auto L = [](auto ... As) {
    return [](auto b) ->decltype(b) {
      vfun([](decltype(As) a) -> decltype(a) { return a; } ...)(first<decltype(As)...>{});
      return decltype(b){};
    };
   };
   auto LL = L(1, 'a', 3.14, "abc");
   LL("dim");
 }
  return 0;
}
int run = test();
}

} // end ns nested_non_capturing_lambda_tests

namespace PR17476 {
struct string {
  string(const char *__s) { }
  string &operator+=(const string &__str) { return *this; }
};

template <class T>
void finalizeDefaultAtomValues() {
  auto startEnd = [](const char * sym) -> void {
    string start("__");
    start += sym;
  };
  startEnd("preinit_array");
}

void f() { finalizeDefaultAtomValues<char>(); }

}

namespace PR17476_variant {
struct string {
  string(const char *__s) { }
  string &operator+=(const string &__str) { return *this; }
};

template <class T>
void finalizeDefaultAtomValues() {
  auto startEnd = [](const T *sym) -> void {
    string start("__");
    start += sym;
  };
  startEnd("preinit_array");
}

void f() { finalizeDefaultAtomValues<char>(); }

}

namespace PR17877_lambda_declcontext_and_get_cur_lambda_disconnect {


template<class T> struct U {
  int t = 0;
};

template<class T>
struct V {
  U<T> size() const { return U<T>{}; }
};

template<typename T>
void Do() {
  V<int> v{};
  [=] { v.size(); };
}

}

namespace inclass_lambdas_within_nested_classes {
namespace ns1 {

struct X1 {
  struct X2 {
    enum { E = [](auto i) { return i; }(3) }; //expected-error{{inside of a constant expression}}\
                                          //expected-error{{constant}}\
                                          //expected-note{{non-literal type}}
    int L = ([] (int i) { return i; })(2);
    void foo(int i = ([] (int i) { return i; })(2)) { }
    int B : ([](int i) { return i; })(3); //expected-error{{inside of a constant expression}}\
                                          //expected-error{{not an integral constant}}\
                                          //expected-note{{non-literal type}}
    int arr[([](int i) { return i; })(3)]; //expected-error{{inside of a constant expression}}\
                                           //expected-error{{must have a constant size}}\
                                           //expected-warning{{variable length arrays in C++ are a Clang extension}}\
                                           //expected-note-re{{non-literal type '{{.*}}' cannot be used in a constant expression}}
    int (*fp)(int) = [](int i) { return i; };
    void fooptr(int (*fp)(char) = [](char c) { return 0; }) { }
    int L2 = ([](auto i) { return i; })(2);
    void fooG(int i = ([] (auto i) { return i; })(2)) { }
    int BG : ([](auto i) { return i; })(3); //expected-error{{inside of a constant expression}}  \
                                            //expected-error{{not an integral constant}}\
                                            //expected-note{{non-literal type}}
    int arrG[([](auto i) { return i; })(3)]; //expected-error{{inside of a constant expression}}\
                                             //expected-error{{must have a constant size}}\
                                             //expected-warning{{variable length arrays in C++ are a Clang extension}}\
                                             //expected-note-re{{non-literal type '{{.*}}' cannot be used in a constant expression}}

    int (*fpG)(int) = [](auto i) { return i; };
    void fooptrG(int (*fp)(char) = [](auto c) { return 0; }) { }
  };
};
} //end ns

namespace ns2 {
struct X1 {
  template<class T>
  struct X2 {
    int L = ([] (T i) { return i; })(2);
    void foo(int i = ([] (int i) { return i; })(2)) { }
    int B : ([](T i) { return i; })(3); //expected-error{{inside of a constant expression}}\
                                        //expected-error{{not an integral constant}}\
                                        //expected-note{{non-literal type}}
    int arr[([](T i) { return i; })(3)]; //expected-error{{inside of a constant expression}}\
                                         //expected-error{{must have a constant size}}\
                                         //expected-warning{{variable length arrays in C++ are a Clang extension}}\
                                         //expected-note-re{{non-literal type '{{.*}}' cannot be used in a constant expression}}

    int (*fp)(T) = [](T i) { return i; };
    void fooptr(T (*fp)(char) = [](char c) { return 0; }) { }
    int L2 = ([](auto i) { return i; })(2);
    void fooG(T i = ([] (auto i) { return i; })(2)) { }
    int BG : ([](auto i) { return i; })(3); //expected-error{{not an integral constant}}\
                                            //expected-note{{non-literal type}}\
                                            //expected-error{{inside of a constant expression}}
    int arrG[([](auto i) { return i; })(3)]; //expected-error{{must have a constant size}} \
                                             //expected-error{{inside of a constant expression}}\
                                             //expected-warning{{variable length arrays in C++ are a Clang extension}}\
                                             //expected-note-re{{non-literal type '{{.*}}' cannot be used in a constant expression}}

    int (*fpG)(T) = [](auto i) { return i; };
    void fooptrG(T (*fp)(char) = [](auto c) { return 0; }) { }
    template<class U = char> int fooG2(T (*fp)(U) = [](auto a) { return 0; }) { return 0; }
    template<class U = char> int fooG3(T (*fp)(U) = [](auto a) { return 0; });
  };
};
template<class T>
template<class U>
int X1::X2<T>::fooG3(T (*fp)(U)) { return 0; }
X1::X2<int> x2; //expected-note {{in instantiation of}}
int run1 = x2.fooG2();
int run2 = x2.fooG3();
} // end ns



} //end ns inclass_lambdas_within_nested_classes

namespace pr21684_disambiguate_auto_followed_by_ellipsis_no_id {
int a = [](auto ...) { return 0; }();
}

namespace PR22117 {
  int x = [](auto) {
    return [](auto... run_args) {
      using T = int(decltype(run_args)...);
      return 0;
    };
  }(0)(0);
}

namespace PR41139 {
  int y = [](auto outer) {
    return [](auto inner) {
      using T = int(decltype(outer), decltype(inner));
      return 0;
    };
  }(0)(0);
}

namespace PR23716 {
template<typename T>
auto f(T x) {
  auto g = [](auto&&... args) {
    auto h = [args...]() -> int {
      return 0;
    };
    return h;
  };
  return g;
}

auto x = f(0)();
}

namespace PR13987 {
class Enclosing {
  void Method(char c = []()->char {
    int d = [](auto x)->int {
        struct LocalClass {
          int Method() { return 0; }
        };
      return 0;
    }(0);
    return d; }()
  );
};

class Enclosing2 {
  void Method(char c = [](auto x)->char {
    int d = []()->int {
        struct LocalClass {
          int Method() { return 0; }
        };
      return 0;
    }();
    return d; }(0)
  );
};

class Enclosing3 {
  void Method(char c = [](auto x)->char {
    int d = [](auto y)->int {
        struct LocalClass {
          int Method() { return 0; }
        };
      return 0;
    }(0);
    return d; }(0)
  );
};
}

namespace PR32638 {
 //https://bugs.llvm.org/show_bug.cgi?id=32638
 void test() {
    [](auto x) noexcept(noexcept(x)) { } (0);
 }
}

namespace PR46637 {
  auto x = [](auto (*p)()) { return p(); };
  auto y = [](auto (*p)() -> auto) { return p(); };
  int f();
  void *v = x(f); // expected-error {{cannot initialize a variable of type 'void *' with an rvalue of type 'int'}}
  void *w = y(f); // expected-error {{cannot initialize a variable of type 'void *' with an rvalue of type 'int'}}
}

namespace GH37792 {
struct A { int x; };

void f() {
  [](auto t) -> decltype(decltype(t)::x) { return 0; }(A());
}
}