test/SemaTemplate/constexpr-instantiate.cpp - third_party/swift-clang - Git at Google

 // RUN: %clang_cc1 -std=c++11 -verify %s

 namespace UseBeforeDefinition {
   struct A {
     template<typename T> static constexpr T get() { return T(); }
     // ok, not a constant expression.
     int n = get<int>();
   };

   // ok, constant expression.
   constexpr int j = A::get<int>();

   template<typename T> constexpr int consume(T);
   // ok, not a constant expression.
   const int k = consume(0); // expected-note {{here}}

   template<typename T> constexpr int consume(T) { return 0; }
   // ok, constant expression.
   constexpr int l = consume(0);

   constexpr int m = k; // expected-error {{constant expression}} expected-note {{initializer of 'k'}}
 }

 namespace IntegralConst {
   template<typename T> constexpr T f(T n) { return n; }
   enum E {
     v = f(0), w = f(1) // ok
   };
   static_assert(w == 1, "");

   char arr[f('x')]; // ok
   static_assert(sizeof(arr) == 'x', "");
 }

 namespace ConvertedConst {
   template<typename T> constexpr T f(T n) { return n; }
   int f() {
     switch (f()) {
       case f(4): return 0;
     }
     return 1;
   }
 }

 namespace OverloadResolution {
   template<typename T> constexpr T f(T t) { return t; }

   template<int n> struct S { };

   template<typename T> auto g(T t) -> S<f(sizeof(T))> &;
   char &f(...);

   template<typename T> auto h(T t[f(sizeof(T))]) -> decltype(&*t) {
     return t;
   }

   S<4> &k = g(0);
   int *p, *q = h(p);
 }

 namespace DataMember {
   template<typename T> struct S { static const int k; };
   const int n = S<int>::k; // expected-note {{here}}
   template<typename T> const int S<T>::k = 0;
   constexpr int m = S<int>::k; // ok
   constexpr int o = n; // expected-error {{constant expression}} expected-note {{initializer of 'n'}}
 }

 namespace Reference {
   const int k = 5;
   template<typename T> struct S {
     static volatile int &r;
   };
   template<typename T> volatile int &S<T>::r = const_cast<volatile int&>(k);
   constexpr int n = const_cast<int&>(S<int>::r);
   static_assert(n == 5, "");
 }

 namespace Unevaluated {
   // We follow the current proposed resolution of core issue 1581: a constexpr
   // function template specialization requires a definition if:
   //  * it is odr-used, or would be odr-used except that it appears within the
   //    definition of a template, or
   //  * it is used within a braced-init-list, where it may be necessary for
   //    detecting narrowing conversions.
   //
   // We apply this both for instantiating constexpr function template
   // specializations and for implicitly defining defaulted constexpr special
   // member functions.
   //
   // FIXME: None of this is required by the C++ standard yet. The rules in this
   //        area are subject to change.
   namespace NotConstexpr {
     template<typename T> struct S {
       S() : n(0) {}
       S(const S&) : n(T::error) {}
       int n;
     };
     struct U : S<int> {};
     decltype(U(U())) u;
   }
   namespace Constexpr {
     template<typename T> struct S {
       constexpr S() : n(0) {}
       constexpr S(const S&) : n(T::error) {}
       int n;
     };
     struct U : S<int> {};
     decltype(U(U())) u;
   }
   namespace ConstexprList {
     template<int N> struct S {
       constexpr S() : n(0) {
         static_assert(N >= 0, "");
       }
       constexpr operator int() const { return 0; }
       int n;
     };
     struct U : S<0> {};
     // ok, trigger instantiation within a list
     decltype(char{U()}) t0;
     decltype(new char{S<1>()}) t1; // expected-warning {{side effects}}
     decltype((char){S<2>()}) t2;
     decltype(+(char[1]){{S<3>()}}) t3;
     // do not trigger instantiation outside a list
     decltype(char(S<-1>())) u1;
     decltype(new char(S<-2>())) u2; // expected-warning {{side effects}}
     decltype((char)(S<-3>())) u3;
   }

   namespace PR11851_Comment0 {
     template<int x> constexpr int f() { return x; }
     template<int i> void ovf(int (&x)[f<i>()]);
     void f() { int x[10]; ovf<10>(x); }
   }

   namespace PR11851_Comment1 {
     template<typename T>
     constexpr bool Integral() {
       return true;
     }
     template<typename T, bool Int = Integral<T>()>
     struct safe_make_unsigned {
       typedef T type;
     };
     template<typename T>
     using Make_unsigned = typename safe_make_unsigned<T>::type;
     template <typename T>
     struct get_distance_type {
       using type = int;
     };
     template<typename R>
     auto size(R) -> Make_unsigned<typename get_distance_type<R>::type>;
     auto check() -> decltype(size(0));
   }

   namespace PR11851_Comment6 {
     template<int> struct foo {};
     template<class> constexpr int bar() { return 0; }
     template<class T> foo<bar<T>()> foobar();
     auto foobar_ = foobar<int>();
   }

   namespace PR11851_Comment9 {
     struct S1 {
       constexpr S1() {}
       constexpr operator int() const { return 0; }
     };
     int k1 = sizeof(short{S1(S1())});

     struct S2 {
       constexpr S2() {}
       constexpr operator int() const { return 123456; }
     };
     int k2 = sizeof(short{S2(S2())}); // expected-error {{cannot be narrowed}} expected-note {{insert an explicit cast to silence this issue}}
   }

   namespace PR12288 {
     template <typename> constexpr bool foo() { return true; }
     template <bool> struct bar {};
     template <typename T> bar<foo<T>()> baz() { return bar<foo<T>()>(); }
     int main() { baz<int>(); }
   }

   namespace PR13423 {
     template<bool, typename> struct enable_if {};
     template<typename T> struct enable_if<true, T> { using type = T; };

     template<typename T> struct F {
       template<typename U>
       static constexpr bool f() { return sizeof(T) < U::size; }

       template<typename U>
       static typename enable_if<f<U>(), void>::type g() {} // expected-note {{requirement 'f<Unevaluated::PR13423::U>()' was not satisfied}}
     };

     struct U { static constexpr int size = 2; };

     void h() { F<char>::g<U>(); }
     void i() { F<int>::g<U>(); } // expected-error {{no matching function}}
   }

   namespace PR14203 {
     struct duration { constexpr duration() {} };

     template <typename>
     void sleep_for() {
       constexpr duration max = duration();
     }
   }

   // For variables, we instantiate when they are used in a context in which
   // evaluation could be required (odr-used, used in a template whose
   // instantiations would odr-use, or used in list initialization), if they
   // can be used as a constant (const integral or constexpr).
   namespace Variables {
     template<int N> struct A {
       static const int k;
       static int n;
     };
     template<const int *N> struct B {};
     template<int N> constexpr int A<N>::k = *(int[N]){N}; // expected-error 1+{{negative}}
     template<int N> int A<N>::n = *(int[N]){0};

     template <typename> void f() {
       (void)A<-1>::n; // ok
       (void)A<-1>::k; // expected-note {{instantiation of }}
       B<&A<-2>::n> b1; // ok
       B<&A<-2>::k> b2; // expected-note {{instantiation of }}
     };

     decltype(A<-3>::k) d1 = 0; // ok
     decltype(char{A<-4>::k}) d2 = 0; // expected-note {{instantiation of }} expected-error {{narrow}} expected-note {{cast}}
     decltype(char{A<1>::k}) d3 = 0; // ok
     decltype(char{A<1 + (unsigned char)-1>::k}) d4 = 0; // expected-error {{narrow}} expected-note {{cast}}
   }
 }

 namespace NoInstantiationWhenSelectingOverload {
   // Check that we don't instantiate conversion functions when we're checking
   // for the existence of an implicit conversion sequence, only when a function
   // is actually chosen by overload resolution.
   struct S {
     template<typename T> constexpr S(T) : n(T::error) {} // expected-error {{no members}}
     int n;
   };

   constexpr int f(S) { return 0; }
   constexpr int f(int) { return 0; }

   void g() { f(0); }
   void h() { (void)sizeof(char{f(0)}); }
   void i() { (void)sizeof(char{f("oops")}); } // expected-note {{instantiation of}}
 }

 namespace PR20090 {
   template <typename T> constexpr T fact(T n) {
     return n == 0 ? 1 : [=] { return n * fact(n - 1); }();
   }
   static_assert(fact(0) == 1, "");
 }
	// RUN: %clang_cc1 -std=c++11 -verify %s

	namespace UseBeforeDefinition {
	struct A {
	template<typename T> static constexpr T get() { return T(); }
	// ok, not a constant expression.
	int n = get<int>();
	};

	// ok, constant expression.
	constexpr int j = A::get<int>();

	template<typename T> constexpr int consume(T);
	// ok, not a constant expression.
	const int k = consume(0); // expected-note {{here}}

	template<typename T> constexpr int consume(T) { return 0; }
	// ok, constant expression.
	constexpr int l = consume(0);

	constexpr int m = k; // expected-error {{constant expression}} expected-note {{initializer of 'k'}}
	}

	namespace IntegralConst {
	template<typename T> constexpr T f(T n) { return n; }
	enum E {
	v = f(0), w = f(1) // ok
	};
	static_assert(w == 1, "");

	char arr[f('x')]; // ok
	static_assert(sizeof(arr) == 'x', "");
	}

	namespace ConvertedConst {
	template<typename T> constexpr T f(T n) { return n; }
	int f() {
	switch (f()) {
	case f(4): return 0;
	}
	return 1;
	}
	}

	namespace OverloadResolution {
	template<typename T> constexpr T f(T t) { return t; }

	template<int n> struct S { };

	template<typename T> auto g(T t) -> S<f(sizeof(T))> &;
	char &f(...);

	template<typename T> auto h(T t[f(sizeof(T))]) -> decltype(&*t) {
	return t;
	}

	S<4> &k = g(0);
	int p, q = h(p);
	}

	namespace DataMember {
	template<typename T> struct S { static const int k; };
	const int n = S<int>::k; // expected-note {{here}}
	template<typename T> const int S<T>::k = 0;
	constexpr int m = S<int>::k; // ok
	constexpr int o = n; // expected-error {{constant expression}} expected-note {{initializer of 'n'}}
	}

	namespace Reference {
	const int k = 5;
	template<typename T> struct S {
	static volatile int &r;
	};
	template<typename T> volatile int &S<T>::r = const_cast<volatile int&>(k);
	constexpr int n = const_cast<int&>(S<int>::r);
	static_assert(n == 5, "");
	}

	namespace Unevaluated {
	// We follow the current proposed resolution of core issue 1581: a constexpr
	// function template specialization requires a definition if:
	// * it is odr-used, or would be odr-used except that it appears within the
	// definition of a template, or
	// * it is used within a braced-init-list, where it may be necessary for
	// detecting narrowing conversions.
	//
	// We apply this both for instantiating constexpr function template
	// specializations and for implicitly defining defaulted constexpr special
	// member functions.
	//
	// FIXME: None of this is required by the C++ standard yet. The rules in this
	// area are subject to change.
	namespace NotConstexpr {
	template<typename T> struct S {
	S() : n(0) {}
	S(const S&) : n(T::error) {}
	int n;
	};
	struct U : S<int> {};
	decltype(U(U())) u;
	}
	namespace Constexpr {
	template<typename T> struct S {
	constexpr S() : n(0) {}
	constexpr S(const S&) : n(T::error) {}
	int n;
	};
	struct U : S<int> {};
	decltype(U(U())) u;
	}
	namespace ConstexprList {
	template<int N> struct S {
	constexpr S() : n(0) {
	static_assert(N >= 0, "");
	}
	constexpr operator int() const { return 0; }
	int n;
	};
	struct U : S<0> {};
	// ok, trigger instantiation within a list
	decltype(char{U()}) t0;
	decltype(new char{S<1>()}) t1; // expected-warning {{side effects}}
	decltype((char){S<2>()}) t2;
	decltype(+(char[1]){{S<3>()}}) t3;
	// do not trigger instantiation outside a list
	decltype(char(S<-1>())) u1;
	decltype(new char(S<-2>())) u2; // expected-warning {{side effects}}
	decltype((char)(S<-3>())) u3;
	}

	namespace PR11851_Comment0 {
	template<int x> constexpr int f() { return x; }
	template<int i> void ovf(int (&x)[f<i>()]);
	void f() { int x[10]; ovf<10>(x); }
	}

	namespace PR11851_Comment1 {
	template<typename T>
	constexpr bool Integral() {
	return true;
	}
	template<typename T, bool Int = Integral<T>()>
	struct safe_make_unsigned {
	typedef T type;
	};
	template<typename T>
	using Make_unsigned = typename safe_make_unsigned<T>::type;
	template <typename T>
	struct get_distance_type {
	using type = int;
	};
	template<typename R>
	auto size(R) -> Make_unsigned<typename get_distance_type<R>::type>;
	auto check() -> decltype(size(0));
	}

	namespace PR11851_Comment6 {
	template<int> struct foo {};
	template<class> constexpr int bar() { return 0; }
	template<class T> foo<bar<T>()> foobar();
	auto foobar_ = foobar<int>();
	}

	namespace PR11851_Comment9 {
	struct S1 {
	constexpr S1() {}
	constexpr operator int() const { return 0; }
	};
	int k1 = sizeof(short{S1(S1())});

	struct S2 {
	constexpr S2() {}
	constexpr operator int() const { return 123456; }
	};
	int k2 = sizeof(short{S2(S2())}); // expected-error {{cannot be narrowed}} expected-note {{insert an explicit cast to silence this issue}}
	}

	namespace PR12288 {
	template <typename> constexpr bool foo() { return true; }
	template <bool> struct bar {};
	template <typename T> bar<foo<T>()> baz() { return bar<foo<T>()>(); }
	int main() { baz<int>(); }
	}

	namespace PR13423 {
	template<bool, typename> struct enable_if {};
	template<typename T> struct enable_if<true, T> { using type = T; };

	template<typename T> struct F {
	template<typename U>
	static constexpr bool f() { return sizeof(T) < U::size; }

	template<typename U>
	static typename enable_if<f<U>(), void>::type g() {} // expected-note {{requirement 'f<Unevaluated::PR13423::U>()' was not satisfied}}
	};

	struct U { static constexpr int size = 2; };

	void h() { F<char>::g<U>(); }
	void i() { F<int>::g<U>(); } // expected-error {{no matching function}}
	}

	namespace PR14203 {
	struct duration { constexpr duration() {} };

	template <typename>
	void sleep_for() {
	constexpr duration max = duration();
	}
	}

	// For variables, we instantiate when they are used in a context in which
	// evaluation could be required (odr-used, used in a template whose
	// instantiations would odr-use, or used in list initialization), if they
	// can be used as a constant (const integral or constexpr).
	namespace Variables {
	template<int N> struct A {
	static const int k;
	static int n;
	};
	template<const int *N> struct B {};
	template<int N> constexpr int A<N>::k = *(int[N]){N}; // expected-error 1+{{negative}}
	template<int N> int A<N>::n = *(int[N]){0};

	template <typename> void f() {
	(void)A<-1>::n; // ok
	(void)A<-1>::k; // expected-note {{instantiation of }}
	B<&A<-2>::n> b1; // ok
	B<&A<-2>::k> b2; // expected-note {{instantiation of }}
	};

	decltype(A<-3>::k) d1 = 0; // ok
	decltype(char{A<-4>::k}) d2 = 0; // expected-note {{instantiation of }} expected-error {{narrow}} expected-note {{cast}}
	decltype(char{A<1>::k}) d3 = 0; // ok
	decltype(char{A<1 + (unsigned char)-1>::k}) d4 = 0; // expected-error {{narrow}} expected-note {{cast}}
	}
	}

	namespace NoInstantiationWhenSelectingOverload {
	// Check that we don't instantiate conversion functions when we're checking
	// for the existence of an implicit conversion sequence, only when a function
	// is actually chosen by overload resolution.
	struct S {
	template<typename T> constexpr S(T) : n(T::error) {} // expected-error {{no members}}
	int n;
	};

	constexpr int f(S) { return 0; }
	constexpr int f(int) { return 0; }

	void g() { f(0); }
	void h() { (void)sizeof(char{f(0)}); }
	void i() { (void)sizeof(char{f("oops")}); } // expected-note {{instantiation of}}
	}

	namespace PR20090 {
	template <typename T> constexpr T fact(T n) {
	return n == 0 ? 1 : [=] { return n * fact(n - 1); }();
	}
	static_assert(fact(0) == 1, "");
	}