src/third_party/llvm-project/clang/test/SemaCXX/lambda-expressions.cpp - cobalt - Git at Google

 // RUN: %clang_cc1 -std=c++14 -Wno-unused-value -fsyntax-only -verify -fblocks %s

 namespace std { class type_info; };

 namespace ExplicitCapture {
   class C {
     int Member;

     static void Overload(int);
     void Overload();
     virtual C& Overload(float);

     void ImplicitThisCapture() {
       [](){(void)Member;}; // expected-error {{'this' cannot be implicitly captured in this context}}
       [&](){(void)Member;};

       [this](){(void)Member;};
       [this]{[this]{};};
       []{[this]{};};// expected-error {{'this' cannot be implicitly captured in this context}}
       []{Overload(3);};
       []{Overload();}; // expected-error {{'this' cannot be implicitly captured in this context}}
       []{(void)typeid(Overload());};
       []{(void)typeid(Overload(.5f));};// expected-error {{'this' cannot be implicitly captured in this context}}
     }
   };

   void f() {
     [this] () {}; // expected-error {{'this' cannot be captured in this context}}
   }
 }

 namespace ReturnDeduction {
   void test() {
     [](){ return 1; };
     [](){ return 1; };
     [](){ return ({return 1; 1;}); };
     [](){ return ({return 'c'; 1;}); }; // expected-error {{must match previous return type}}
     []()->int{ return 'c'; return 1; };
     [](){ return 'c'; return 1; };  // expected-error {{must match previous return type}}
     []() { return; return (void)0; };
     [](){ return 1; return 1; };
   }
 }

 namespace ImplicitCapture {
   void test() {
     int a = 0; // expected-note 5 {{declared}}
     []() { return a; }; // expected-error {{variable 'a' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{begins here}}
     [&]() { return a; };
     [=]() { return a; };
     [=]() { int* b = &a; }; // expected-error {{cannot initialize a variable of type 'int *' with an rvalue of type 'const int *'}}
     [=]() { return [&]() { return a; }; };
     []() { return [&]() { return a; }; }; // expected-error {{variable 'a' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{lambda expression begins here}}
     []() { return ^{ return a; }; };// expected-error {{variable 'a' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{lambda expression begins here}}
     []() { return [&a] { return a; }; }; // expected-error 2 {{variable 'a' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note 2 {{lambda expression begins here}}
     [=]() { return [&a] { return a; }; }; //

     const int b = 2;
     []() { return b; };

     union { // expected-note {{declared}}
       int c;
       float d;
     };
     d = 3;
     [=]() { return c; }; // expected-error {{unnamed variable cannot be implicitly captured in a lambda expression}}

     __block int e; // expected-note 3 {{declared}}
     [&]() { return e; }; // expected-error {{__block variable 'e' cannot be captured in a lambda expression}}
     [&e]() { return e; }; // expected-error 2 {{__block variable 'e' cannot be captured in a lambda expression}}

     int f[10]; // expected-note {{declared}}
     [&]() { return f[2]; };
     (void) ^{ return []() { return f[2]; }; }; // expected-error {{variable 'f' cannot be implicitly captured in a lambda with no capture-default specified}} \
     // expected-note{{lambda expression begins here}}

     struct G { G(); G(G&); int a; }; // expected-note 6 {{not viable}}
     G g;
     [=]() { const G* gg = &g; return gg->a; };
     [=]() { return [=]{ const G* gg = &g; return gg->a; }(); }; // expected-error {{no matching constructor for initialization of 'G'}}
     (void)^{ return [=]{ const G* gg = &g; return gg->a; }(); }; // expected-error 2 {{no matching constructor for initialization of 'const G'}}

     const int h = a; // expected-note {{declared}}
     []() { return h; }; // expected-error {{variable 'h' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{lambda expression begins here}}

     // References can appear in constant expressions if they are initialized by
     // reference constant expressions.
     int i;
     int &ref_i = i; // expected-note {{declared}}
     [] { return ref_i; }; // expected-error {{variable 'ref_i' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{lambda expression begins here}}

     static int j;
     int &ref_j = j;
     [] { return ref_j; }; // ok
   }
 }

 namespace SpecialMembers {
   void f() {
     auto a = []{}; // expected-note 2{{here}} expected-note 2{{candidate}}
     decltype(a) b; // expected-error {{no matching constructor}}
     decltype(a) c = a;
     decltype(a) d = static_cast<decltype(a)&&>(a);
     a = a; // expected-error {{copy assignment operator is implicitly deleted}}
     a = static_cast<decltype(a)&&>(a); // expected-error {{copy assignment operator is implicitly deleted}}
   }
   struct P {
     P(const P&) = delete; // expected-note {{deleted here}}
   };
   struct Q {
     ~Q() = delete; // expected-note {{deleted here}}
   };
   struct R {
     R(const R&) = default;
     R(R&&) = delete;
     R &operator=(const R&) = delete;
     R &operator=(R&&) = delete;
   };
   void g(P &p, Q &q, R &r) {
     auto pp = [p]{}; // expected-error {{deleted constructor}}
     auto qq = [q]{}; // expected-error {{deleted function}} expected-note {{because}}

     auto a = [r]{}; // expected-note 2{{here}}
     decltype(a) b = a;
     decltype(a) c = static_cast<decltype(a)&&>(a); // ok, copies R
     a = a; // expected-error {{copy assignment operator is implicitly deleted}}
     a = static_cast<decltype(a)&&>(a); // expected-error {{copy assignment operator is implicitly deleted}}
   }
 }

 namespace PR12031 {
   struct X {
     template<typename T>
     X(const T&);
     ~X();
   };

   void f(int i, X x);
   void g() {
     const int v = 10;
     f(v, [](){});
   }
 }

 namespace Array {
   int &f(int *p);
   char &f(...);
   void g() {
     int n = -1;
     [=] {
       int arr[n]; // VLA
     } ();

     const int m = -1;
     [] {
       int arr[m]; // expected-error{{negative size}}
     } ();

     [&] {
       int arr[m]; // expected-error{{negative size}}
     } ();

     [=] {
       int arr[m]; // expected-error{{negative size}}
     } ();

     [m] {
       int arr[m]; // expected-error{{negative size}}
     } ();
   }
 }

 void PR12248()
 {
   unsigned int result = 0;
   auto l = [&]() { ++result; };
 }

 namespace ModifyingCapture {
   void test() {
     int n = 0;
     [=] {
       n = 1; // expected-error {{cannot assign to a variable captured by copy in a non-mutable lambda}}
     };
   }
 }

 namespace VariadicPackExpansion {
   template<typename T, typename U> using Fst = T;
   template<typename...Ts> bool g(Fst<bool, Ts> ...bools);
   template<typename...Ts> bool f(Ts &&...ts) {
     return g<Ts...>([&ts] {
       if (!ts)
         return false;
       --ts;
       return true;
     } () ...);
   }
   void h() {
     int a = 5, b = 2, c = 3;
     while (f(a, b, c)) {
     }
   }

   struct sink {
     template<typename...Ts> sink(Ts &&...) {}
   };

   template<typename...Ts> void local_class() {
     sink {
       [] (Ts t) {
         struct S : Ts {
           void f(Ts t) {
             Ts &that = *this;
             that = t;
           }
           Ts g() { return *this; };
         };
         S s;
         s.f(t);
         return s;
       } (Ts()).g() ...
     };
   };
   struct X {}; struct Y {};
   template void local_class<X, Y>();

   template<typename...Ts> void nested(Ts ...ts) {
     f(
       // Each expansion of this lambda implicitly captures all of 'ts', because
       // the inner lambda also expands 'ts'.
       [&] {
         return ts + [&] { return f(ts...); } ();
       } () ...
     );
   }
   template void nested(int, int, int);

   template<typename...Ts> void nested2(Ts ...ts) { // expected-note 2{{here}}
     // Capture all 'ts', use only one.
     f([&ts...] { return ts; } ()...);
     // Capture each 'ts', use it.
     f([&ts] { return ts; } ()...);
     // Capture all 'ts', use all of them.
     f([&ts...] { return (int)f(ts...); } ());
     // Capture each 'ts', use all of them. Ill-formed. In more detail:
     //
     // We instantiate two lambdas here; the first captures ts$0, the second
     // captures ts$1. Both of them reference both ts parameters, so both are
     // ill-formed because ts can't be implicitly captured.
     //
     // FIXME: This diagnostic does not explain what's happening. We should
     // specify which 'ts' we're referring to in its diagnostic name. We should
     // also say which slice of the pack expansion is being performed in the
     // instantiation backtrace.
     f([&ts] { return (int)f(ts...); } ()...); // \
     // expected-error 2{{'ts' cannot be implicitly captured}} \
     // expected-note 2{{lambda expression begins here}}
   }
   template void nested2(int); // ok
   template void nested2(int, int); // expected-note {{in instantiation of}}
 }

 namespace PR13860 {
   void foo() {
     auto x = PR13860UndeclaredIdentifier(); // expected-error {{use of undeclared identifier 'PR13860UndeclaredIdentifier'}}
     auto y = [x]() { };
     static_assert(sizeof(y), "");
   }
 }

 namespace PR13854 {
   auto l = [](void){};
 }

 namespace PR14518 {
   auto f = [](void) { return __func__; }; // no-warning
 }

 namespace PR16708 {
   auto L = []() {
     auto ret = 0;
     return ret;
     return 0;
   };
 }

 namespace TypeDeduction {
   struct S {};
   void f() {
     const S s {};
     S &&t = [&] { return s; } ();
 #if __cplusplus > 201103L
     S &&u = [&] () -> auto { return s; } ();
 #endif
   }
 }


 namespace lambdas_in_NSDMIs {
   template<class T>
   struct L {
       T t{};
       T t2 = ([](int a) { return [](int b) { return b; };})(t)(t);
   };
   L<int> l;

   namespace non_template {
     struct L {
       int t = 0;
       int t2 = ([](int a) { return [](int b) { return b; };})(t)(t);
     };
     L l;
   }
 }

 // PR18477: don't try to capture 'this' from an NSDMI encountered while parsing
 // a lambda.
 namespace NSDMIs_in_lambdas {
   template<typename T> struct S { int a = 0; int b = a; };
   void f() { []() { S<int> s; }; }

   auto x = []{ struct S { int n, m = n; }; };
   auto y = [&]{ struct S { int n, m = n; }; }; // expected-error {{non-local lambda expression cannot have a capture-default}}
   void g() { auto z = [&]{ struct S { int n, m = n; }; }; }
 }

 namespace CaptureIncomplete {
   struct Incomplete; // expected-note 2{{forward decl}}
   void g(const Incomplete &a);
   void f(Incomplete &a) {
     (void) [a] {}; // expected-error {{incomplete}}
     (void) [&a] {};

     (void) [=] { g(a); }; // expected-error {{incomplete}}
     (void) [&] { f(a); };
   }
 }

 namespace CaptureAbstract {
   struct S {
     virtual void f() = 0; // expected-note {{unimplemented}}
     int n = 0;
   };
   struct T : S {
     constexpr T() {}
     void f();
   };
   void f() {
     constexpr T t = T();
     S &s = const_cast<T&>(t);
     // FIXME: Once we properly compute odr-use per DR712, this should be
     // accepted (and should not capture 's').
     [=] { return s.n; }; // expected-error {{abstract}}
   }
 }

 namespace PR18128 {
   auto l = [=]{}; // expected-error {{non-local lambda expression cannot have a capture-default}}

   struct S {
     int n;
     int (*f())[true ? 1 : ([=]{ return n; }(), 0)];
     // expected-error@-1 {{non-local lambda expression cannot have a capture-default}}
     // expected-error@-2 {{invalid use of non-static data member 'n'}}
     // expected-error@-3 {{a lambda expression may not appear inside of a constant expression}}
     int g(int k = ([=]{ return n; }(), 0));
     // expected-error@-1 {{non-local lambda expression cannot have a capture-default}}
     // expected-error@-2 {{invalid use of non-static data member 'n'}}

     int a = [=]{ return n; }(); // ok
     int b = [=]{ return [=]{ return n; }(); }(); // ok
     int c = []{ int k = 0; return [=]{ return k; }(); }(); // ok
     int d = []{ return [=]{ return n; }(); }(); // expected-error {{'this' cannot be implicitly captured in this context}}
   };
 }

 namespace PR18473 {
   template<typename T> void f() {
     T t(0);
     (void) [=]{ int n = t; }; // expected-error {{deleted}}
   }

   template void f<int>();
   struct NoCopy {
     NoCopy(int);
     NoCopy(const NoCopy &) = delete; // expected-note {{deleted}}
     operator int() const;
   };
   template void f<NoCopy>(); // expected-note {{instantiation}}
 }

 void PR19249() {
   auto x = [&x]{}; // expected-error {{cannot appear in its own init}}
 }

 namespace PR20731 {
 template <class L, int X = sizeof(L)>
 void Job(L l);

 template <typename... Args>
 void Logger(Args &&... args) {
   auto len = Invalid_Function((args)...);
   // expected-error@-1 {{use of undeclared identifier 'Invalid_Function'}}
   Job([len]() {});
 }

 void GetMethod() {
   Logger();
   // expected-note@-1 {{in instantiation of function template specialization 'PR20731::Logger<>' requested here}}
 }

 template <typename T>
 struct A {
   T t;
   // expected-error@-1 {{field has incomplete type 'void'}}
 };

 template <typename F>
 void g(F f) {
   auto a = A<decltype(f())>{};
   // expected-note@-1 {{in instantiation of template class 'PR20731::A<void>' requested here}}
   auto xf = [a, f]() {};
   int x = sizeof(xf);
 };
 void f() {
   g([] {});
   // expected-note-re@-1 {{in instantiation of function template specialization 'PR20731::g<(lambda at {{.*}}>' requested here}}
 }

 template <class _Rp> struct function {
   template <class _Fp>
   function(_Fp) {
     static_assert(sizeof(_Fp) > 0, "Type must be complete.");
   }
 };

 template <typename T> void p(T t) {
   auto l = some_undefined_function(t);
   // expected-error@-1 {{use of undeclared identifier 'some_undefined_function'}}
   function<void()>(([l]() {}));
 }
 void q() { p(0); }
 // expected-note@-1 {{in instantiation of function template specialization 'PR20731::p<int>' requested here}}
 }

 namespace lambda_in_default_mem_init {
   template<typename T> void f() {
     struct S { int n = []{ return 0; }(); };
   }
   template void f<int>();

   template<typename T> void g() {
     struct S { int n = [](int n){ return n; }(0); };
   }
   template void g<int>();
 }

 namespace error_in_transform_prototype {
   template<class T>
   void f(T t) {
     // expected-error@+2 {{type 'int' cannot be used prior to '::' because it has no members}}
     // expected-error@+1 {{no member named 'ns' in 'error_in_transform_prototype::S'}}
     auto x = [](typename T::ns::type &k) {};
   }
   class S {};
   void foo() {
     f(5); // expected-note {{requested here}}
     f(S()); // expected-note {{requested here}}
   }
 }

 namespace PR21857 {
   template<typename Fn> struct fun : Fn {
     fun() = default;
     using Fn::operator();
   };
   template<typename Fn> fun<Fn> wrap(Fn fn);
   auto x = wrap([](){});
 }

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

 namespace PR23860 {
 template <class> struct A {
   void f(int x = []() {
     struct B {
       void g() {}
     };
     return 0;
   }());
 };

 int main() {
 }

 A<int> a;
 }

 // rdar://22032373
 namespace rdar22032373 {
 void foo() {
   auto blk = [](bool b) {
     if (b)
       return undeclared_error; // expected-error {{use of undeclared identifier}}
     return 0;
   };
 }
 }

 namespace nested_lambda {
 template <int N>
 class S {};

 void foo() {
   const int num = 18;
   auto outer = []() {
     auto inner = [](S<num> &X) {};
   };
 }
 }

 namespace PR27994 {
 struct A { template <class T> A(T); };

 template <class T>
 struct B {
   int x;
   A a = [&] { int y = x; };
   A b = [&] { [&] { [&] { int y = x; }; }; };
   A d = [&](auto param) { int y = x; };
   A e = [&](auto param) { [&] { [&](auto param2) { int y = x; }; }; };
 };

 B<int> b;

 template <class T> struct C {
   struct D {
     int x;
     A f = [&] { int y = x; };
   };
 };

 int func() {
   C<int> a;
   decltype(a)::D b;
 }
 }

 namespace PR30566 {
 int name1; // expected-note {{'name1' declared here}}

 struct S1 {
   template<class T>
   S1(T t) { s = sizeof(t); }
   int s;
 };

 void foo1() {
   auto s0 = S1{[name=]() {}}; // expected-error 2 {{expected expression}}
   auto s1 = S1{[name=name]() {}}; // expected-error {{use of undeclared identifier 'name'; did you mean 'name1'?}}
 }
 }

 namespace PR25627_dont_odr_use_local_consts {

   template<int> struct X {};

   void foo() {
     const int N = 10;
     (void) [] { X<N> x; };
   }
 }

 namespace ConversionOperatorDoesNotHaveDeducedReturnType {
   auto x = [](int){};
   auto y = [](auto) -> void {};
   using T = decltype(x);
   using U = decltype(y);
   using ExpectedTypeT = void (*)(int);
   template<typename T>
     using ExpectedTypeU = void (*)(T);

   struct X {
     friend T::operator ExpectedTypeT() const;

     // Formally, this is invalid, because the return type of the conversion
     // function for a generic lambda expression is an unspecified decltype
     // type, which this should not match. However, this declaration is
     // functionally equivalent to that one, so we're permitted to choose to
     // accept this.
     template<typename T>
       friend U::operator ExpectedTypeU<T>() const;
   };

   // This used to crash in return type deduction for the conversion opreator.
   struct A { int n; void f() { +[](decltype(n)) {}; } };
 }

 namespace TypoCorrection {
 template <typename T> struct X {};
 // expected-note@-1 {{template parameter is declared here}}

 template <typename T>
 void Run(const int& points) {
 // expected-note@-1 {{'points' declared here}}
   auto outer_lambda = []() {
     auto inner_lambda = [](const X<Points>&) {};
     // expected-error@-1 {{use of undeclared identifier 'Points'; did you mean 'points'?}}
     // expected-error@-2 {{template argument for template type parameter must be a type}}
   };
 }
 }
	// RUN: %clang_cc1 -std=c++14 -Wno-unused-value -fsyntax-only -verify -fblocks %s

	namespace std { class type_info; };

	namespace ExplicitCapture {
	class C {
	int Member;

	static void Overload(int);
	void Overload();
	virtual C& Overload(float);

	void ImplicitThisCapture() {
	[](){(void)Member;}; // expected-error {{'this' cannot be implicitly captured in this context}}
	[&](){(void)Member;};

	[this](){(void)Member;};
	[this]{[this]{};};
	[]{[this]{};};// expected-error {{'this' cannot be implicitly captured in this context}}
	[]{Overload(3);};
	[]{Overload();}; // expected-error {{'this' cannot be implicitly captured in this context}}
	[]{(void)typeid(Overload());};
	[]{(void)typeid(Overload(.5f));};// expected-error {{'this' cannot be implicitly captured in this context}}
	}
	};

	void f() {
	[this] () {}; // expected-error {{'this' cannot be captured in this context}}
	}
	}

	namespace ReturnDeduction {
	void test() {
	[](){ return 1; };
	[](){ return 1; };
	[](){ return ({return 1; 1;}); };
	[](){ return ({return 'c'; 1;}); }; // expected-error {{must match previous return type}}
	[]()->int{ return 'c'; return 1; };
	[](){ return 'c'; return 1; }; // expected-error {{must match previous return type}}
	[]() { return; return (void)0; };
	[](){ return 1; return 1; };
	}
	}

	namespace ImplicitCapture {
	void test() {
	int a = 0; // expected-note 5 {{declared}}
	[]() { return a; }; // expected-error {{variable 'a' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{begins here}}
	[&]() { return a; };
	[=]() { return a; };
	[=]() { int* b = &a; }; // expected-error {{cannot initialize a variable of type 'int ' with an rvalue of type 'const int '}}
	[=]() { return [&]() { return a; }; };
	[]() { return [&]() { return a; }; }; // expected-error {{variable 'a' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{lambda expression begins here}}
	[]() { return ^{ return a; }; };// expected-error {{variable 'a' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{lambda expression begins here}}
	[]() { return [&a] { return a; }; }; // expected-error 2 {{variable 'a' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note 2 {{lambda expression begins here}}
	[=]() { return [&a] { return a; }; }; //

	const int b = 2;
	[]() { return b; };

	union { // expected-note {{declared}}
	int c;
	float d;
	};
	d = 3;
	[=]() { return c; }; // expected-error {{unnamed variable cannot be implicitly captured in a lambda expression}}

	__block int e; // expected-note 3 {{declared}}
	[&]() { return e; }; // expected-error {{__block variable 'e' cannot be captured in a lambda expression}}
	[&e]() { return e; }; // expected-error 2 {{__block variable 'e' cannot be captured in a lambda expression}}

	int f[10]; // expected-note {{declared}}
	[&]() { return f[2]; };
	(void) ^{ return []() { return f[2]; }; }; // expected-error {{variable 'f' cannot be implicitly captured in a lambda with no capture-default specified}} \
	// expected-note{{lambda expression begins here}}

	struct G { G(); G(G&); int a; }; // expected-note 6 {{not viable}}
	G g;
	[=]() { const G* gg = &g; return gg->a; };
	[=]() { return [=]{ const G* gg = &g; return gg->a; }(); }; // expected-error {{no matching constructor for initialization of 'G'}}
	(void)^{ return [=]{ const G* gg = &g; return gg->a; }(); }; // expected-error 2 {{no matching constructor for initialization of 'const G'}}

	const int h = a; // expected-note {{declared}}
	[]() { return h; }; // expected-error {{variable 'h' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{lambda expression begins here}}

	// References can appear in constant expressions if they are initialized by
	// reference constant expressions.
	int i;
	int &ref_i = i; // expected-note {{declared}}
	[] { return ref_i; }; // expected-error {{variable 'ref_i' cannot be implicitly captured in a lambda with no capture-default specified}} expected-note {{lambda expression begins here}}

	static int j;
	int &ref_j = j;
	[] { return ref_j; }; // ok
	}
	}

	namespace SpecialMembers {
	void f() {
	auto a = []{}; // expected-note 2{{here}} expected-note 2{{candidate}}
	decltype(a) b; // expected-error {{no matching constructor}}
	decltype(a) c = a;
	decltype(a) d = static_cast<decltype(a)&&>(a);
	a = a; // expected-error {{copy assignment operator is implicitly deleted}}
	a = static_cast<decltype(a)&&>(a); // expected-error {{copy assignment operator is implicitly deleted}}
	}
	struct P {
	P(const P&) = delete; // expected-note {{deleted here}}
	};
	struct Q {
	~Q() = delete; // expected-note {{deleted here}}
	};
	struct R {
	R(const R&) = default;
	R(R&&) = delete;
	R &operator=(const R&) = delete;
	R &operator=(R&&) = delete;
	};
	void g(P &p, Q &q, R &r) {
	auto pp = [p]{}; // expected-error {{deleted constructor}}
	auto qq = [q]{}; // expected-error {{deleted function}} expected-note {{because}}

	auto a = [r]{}; // expected-note 2{{here}}
	decltype(a) b = a;
	decltype(a) c = static_cast<decltype(a)&&>(a); // ok, copies R
	a = a; // expected-error {{copy assignment operator is implicitly deleted}}
	a = static_cast<decltype(a)&&>(a); // expected-error {{copy assignment operator is implicitly deleted}}
	}
	}

	namespace PR12031 {
	struct X {
	template<typename T>
	X(const T&);
	~X();
	};

	void f(int i, X x);
	void g() {
	const int v = 10;
	f(v, [](){});
	}
	}

	namespace Array {
	int &f(int *p);
	char &f(...);
	void g() {
	int n = -1;
	[=] {
	int arr[n]; // VLA
	} ();

	const int m = -1;
	[] {
	int arr[m]; // expected-error{{negative size}}
	} ();

	[&] {
	int arr[m]; // expected-error{{negative size}}
	} ();

	[=] {
	int arr[m]; // expected-error{{negative size}}
	} ();

	[m] {
	int arr[m]; // expected-error{{negative size}}
	} ();
	}
	}

	void PR12248()
	{
	unsigned int result = 0;
	auto l = [&]() { ++result; };
	}

	namespace ModifyingCapture {
	void test() {
	int n = 0;
	[=] {
	n = 1; // expected-error {{cannot assign to a variable captured by copy in a non-mutable lambda}}
	};
	}
	}

	namespace VariadicPackExpansion {
	template<typename T, typename U> using Fst = T;
	template<typename...Ts> bool g(Fst<bool, Ts> ...bools);
	template<typename...Ts> bool f(Ts &&...ts) {
	return g<Ts...>([&ts] {
	if (!ts)
	return false;
	--ts;
	return true;
	} () ...);
	}
	void h() {
	int a = 5, b = 2, c = 3;
	while (f(a, b, c)) {
	}
	}

	struct sink {
	template<typename...Ts> sink(Ts &&...) {}
	};

	template<typename...Ts> void local_class() {
	sink {
	[] (Ts t) {
	struct S : Ts {
	void f(Ts t) {
	Ts &that = *this;
	that = t;
	}
	Ts g() { return *this; };
	};
	S s;
	s.f(t);
	return s;
	} (Ts()).g() ...
	};
	};
	struct X {}; struct Y {};
	template void local_class<X, Y>();

	template<typename...Ts> void nested(Ts ...ts) {
	f(
	// Each expansion of this lambda implicitly captures all of 'ts', because
	// the inner lambda also expands 'ts'.
	[&] {
	return ts + [&] { return f(ts...); } ();
	} () ...
	);
	}
	template void nested(int, int, int);

	template<typename...Ts> void nested2(Ts ...ts) { // expected-note 2{{here}}
	// Capture all 'ts', use only one.
	f([&ts...] { return ts; } ()...);
	// Capture each 'ts', use it.
	f([&ts] { return ts; } ()...);
	// Capture all 'ts', use all of them.
	f([&ts...] { return (int)f(ts...); } ());
	// Capture each 'ts', use all of them. Ill-formed. In more detail:
	//
	// We instantiate two lambdas here; the first captures ts$0, the second
	// captures ts$1. Both of them reference both ts parameters, so both are
	// ill-formed because ts can't be implicitly captured.
	//
	// FIXME: This diagnostic does not explain what's happening. We should
	// specify which 'ts' we're referring to in its diagnostic name. We should
	// also say which slice of the pack expansion is being performed in the
	// instantiation backtrace.
	f([&ts] { return (int)f(ts...); } ()...); // \
	// expected-error 2{{'ts' cannot be implicitly captured}} \
	// expected-note 2{{lambda expression begins here}}
	}
	template void nested2(int); // ok
	template void nested2(int, int); // expected-note {{in instantiation of}}
	}

	namespace PR13860 {
	void foo() {
	auto x = PR13860UndeclaredIdentifier(); // expected-error {{use of undeclared identifier 'PR13860UndeclaredIdentifier'}}
	auto y = [x]() { };
	static_assert(sizeof(y), "");
	}
	}

	namespace PR13854 {
	auto l = [](void){};
	}

	namespace PR14518 {
	auto f = [](void) { return __func__; }; // no-warning
	}

	namespace PR16708 {
	auto L = []() {
	auto ret = 0;
	return ret;
	return 0;
	};
	}

	namespace TypeDeduction {
	struct S {};
	void f() {
	const S s {};
	S &&t = [&] { return s; } ();
	#if __cplusplus > 201103L
	S &&u = [&] () -> auto { return s; } ();
	#endif
	}
	}


	namespace lambdas_in_NSDMIs {
	template<class T>
	struct L {
	T t{};
	T t2 = ([](int a) { return [](int b) { return b; };})(t)(t);
	};
	L<int> l;

	namespace non_template {
	struct L {
	int t = 0;
	int t2 = ([](int a) { return [](int b) { return b; };})(t)(t);
	};
	L l;
	}
	}

	// PR18477: don't try to capture 'this' from an NSDMI encountered while parsing
	// a lambda.
	namespace NSDMIs_in_lambdas {
	template<typename T> struct S { int a = 0; int b = a; };
	void f() { []() { S<int> s; }; }

	auto x = []{ struct S { int n, m = n; }; };
	auto y = [&]{ struct S { int n, m = n; }; }; // expected-error {{non-local lambda expression cannot have a capture-default}}
	void g() { auto z = [&]{ struct S { int n, m = n; }; }; }
	}

	namespace CaptureIncomplete {
	struct Incomplete; // expected-note 2{{forward decl}}
	void g(const Incomplete &a);
	void f(Incomplete &a) {
	(void) [a] {}; // expected-error {{incomplete}}
	(void) [&a] {};

	(void) [=] { g(a); }; // expected-error {{incomplete}}
	(void) [&] { f(a); };
	}
	}

	namespace CaptureAbstract {
	struct S {
	virtual void f() = 0; // expected-note {{unimplemented}}
	int n = 0;
	};
	struct T : S {
	constexpr T() {}
	void f();
	};
	void f() {
	constexpr T t = T();
	S &s = const_cast<T&>(t);
	// FIXME: Once we properly compute odr-use per DR712, this should be
	// accepted (and should not capture 's').
	[=] { return s.n; }; // expected-error {{abstract}}
	}
	}

	namespace PR18128 {
	auto l = [=]{}; // expected-error {{non-local lambda expression cannot have a capture-default}}

	struct S {
	int n;
	int (*f())[true ? 1 : ([=]{ return n; }(), 0)];
	// expected-error@-1 {{non-local lambda expression cannot have a capture-default}}
	// expected-error@-2 {{invalid use of non-static data member 'n'}}
	// expected-error@-3 {{a lambda expression may not appear inside of a constant expression}}
	int g(int k = ([=]{ return n; }(), 0));
	// expected-error@-1 {{non-local lambda expression cannot have a capture-default}}
	// expected-error@-2 {{invalid use of non-static data member 'n'}}

	int a = [=]{ return n; }(); // ok
	int b = [=]{ return [=]{ return n; }(); }(); // ok
	int c = []{ int k = 0; return [=]{ return k; }(); }(); // ok
	int d = []{ return [=]{ return n; }(); }(); // expected-error {{'this' cannot be implicitly captured in this context}}
	};
	}

	namespace PR18473 {
	template<typename T> void f() {
	T t(0);
	(void) [=]{ int n = t; }; // expected-error {{deleted}}
	}

	template void f<int>();
	struct NoCopy {
	NoCopy(int);
	NoCopy(const NoCopy &) = delete; // expected-note {{deleted}}
	operator int() const;
	};
	template void f<NoCopy>(); // expected-note {{instantiation}}
	}

	void PR19249() {
	auto x = [&x]{}; // expected-error {{cannot appear in its own init}}
	}

	namespace PR20731 {
	template <class L, int X = sizeof(L)>
	void Job(L l);

	template <typename... Args>
	void Logger(Args &&... args) {
	auto len = Invalid_Function((args)...);
	// expected-error@-1 {{use of undeclared identifier 'Invalid_Function'}}
	Job([len]() {});
	}

	void GetMethod() {
	Logger();
	// expected-note@-1 {{in instantiation of function template specialization 'PR20731::Logger<>' requested here}}
	}

	template <typename T>
	struct A {
	T t;
	// expected-error@-1 {{field has incomplete type 'void'}}
	};

	template <typename F>
	void g(F f) {
	auto a = A<decltype(f())>{};
	// expected-note@-1 {{in instantiation of template class 'PR20731::A<void>' requested here}}
	auto xf = [a, f]() {};
	int x = sizeof(xf);
	};
	void f() {
	g([] {});
	// expected-note-re@-1 {{in instantiation of function template specialization 'PR20731::g<(lambda at {{.*}}>' requested here}}
	}

	template <class _Rp> struct function {
	template <class _Fp>
	function(_Fp) {
	static_assert(sizeof(_Fp) > 0, "Type must be complete.");
	}
	};

	template <typename T> void p(T t) {
	auto l = some_undefined_function(t);
	// expected-error@-1 {{use of undeclared identifier 'some_undefined_function'}}
	function<void()>(([l]() {}));
	}
	void q() { p(0); }
	// expected-note@-1 {{in instantiation of function template specialization 'PR20731::p<int>' requested here}}
	}

	namespace lambda_in_default_mem_init {
	template<typename T> void f() {
	struct S { int n = []{ return 0; }(); };
	}
	template void f<int>();

	template<typename T> void g() {
	struct S { int n = [](int n){ return n; }(0); };
	}
	template void g<int>();
	}

	namespace error_in_transform_prototype {
	template<class T>
	void f(T t) {
	// expected-error@+2 {{type 'int' cannot be used prior to '::' because it has no members}}
	// expected-error@+1 {{no member named 'ns' in 'error_in_transform_prototype::S'}}
	auto x = [](typename T::ns::type &k) {};
	}
	class S {};
	void foo() {
	f(5); // expected-note {{requested here}}
	f(S()); // expected-note {{requested here}}
	}
	}

	namespace PR21857 {
	template<typename Fn> struct fun : Fn {
	fun() = default;
	using Fn::operator();
	};
	template<typename Fn> fun<Fn> wrap(Fn fn);
	auto x = wrap([](){});
	}

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

	namespace PR23860 {
	template <class> struct A {
	void f(int x = []() {
	struct B {
	void g() {}
	};
	return 0;
	}());
	};

	int main() {
	}

	A<int> a;
	}

	// rdar://22032373
	namespace rdar22032373 {
	void foo() {
	auto blk = [](bool b) {
	if (b)
	return undeclared_error; // expected-error {{use of undeclared identifier}}
	return 0;
	};
	}
	}

	namespace nested_lambda {
	template <int N>
	class S {};

	void foo() {
	const int num = 18;
	auto outer = []() {
	auto inner = [](S<num> &X) {};
	};
	}
	}

	namespace PR27994 {
	struct A { template <class T> A(T); };

	template <class T>
	struct B {
	int x;
	A a = [&] { int y = x; };
	A b = [&] { [&] { [&] { int y = x; }; }; };
	A d = [&](auto param) { int y = x; };
	A e = [&](auto param) { [&] { [&](auto param2) { int y = x; }; }; };
	};

	B<int> b;

	template <class T> struct C {
	struct D {
	int x;
	A f = [&] { int y = x; };
	};
	};

	int func() {
	C<int> a;
	decltype(a)::D b;
	}
	}

	namespace PR30566 {
	int name1; // expected-note {{'name1' declared here}}

	struct S1 {
	template<class T>
	S1(T t) { s = sizeof(t); }
	int s;
	};

	void foo1() {
	auto s0 = S1{[name=]() {}}; // expected-error 2 {{expected expression}}
	auto s1 = S1{[name=name]() {}}; // expected-error {{use of undeclared identifier 'name'; did you mean 'name1'?}}
	}
	}

	namespace PR25627_dont_odr_use_local_consts {

	template<int> struct X {};

	void foo() {
	const int N = 10;
	(void) [] { X<N> x; };
	}
	}

	namespace ConversionOperatorDoesNotHaveDeducedReturnType {
	auto x = [](int){};
	auto y = [](auto) -> void {};
	using T = decltype(x);
	using U = decltype(y);
	using ExpectedTypeT = void (*)(int);
	template<typename T>
	using ExpectedTypeU = void (*)(T);

	struct X {
	friend T::operator ExpectedTypeT() const;

	// Formally, this is invalid, because the return type of the conversion
	// function for a generic lambda expression is an unspecified decltype
	// type, which this should not match. However, this declaration is
	// functionally equivalent to that one, so we're permitted to choose to
	// accept this.
	template<typename T>
	friend U::operator ExpectedTypeU<T>() const;
	};

	// This used to crash in return type deduction for the conversion opreator.
	struct A { int n; void f() { +[](decltype(n)) {}; } };
	}

	namespace TypoCorrection {
	template <typename T> struct X {};
	// expected-note@-1 {{template parameter is declared here}}

	template <typename T>
	void Run(const int& points) {
	// expected-note@-1 {{'points' declared here}}
	auto outer_lambda = []() {
	auto inner_lambda = [](const X<Points>&) {};
	// expected-error@-1 {{use of undeclared identifier 'Points'; did you mean 'points'?}}
	// expected-error@-2 {{template argument for template type parameter must be a type}}
	};
	}
	}