clang/test/SemaCXX/constant-expression-cxx1z.cpp - llvm-project - Git at Google

 // RUN: %clang_cc1 -std=c++1z -verify %s -fcxx-exceptions -triple=x86_64-linux-gnu

 namespace BaseClassAggregateInit {
   struct A {
     int a, b, c;
     constexpr A(int n) : a(n), b(3 * n), c(b - 1) {} // expected-note {{outside the range of representable}}
     constexpr A() : A(10) {};
   };
   struct B : A {};
   struct C { int q; };
   struct D : B, C { int k; };

   constexpr D d1 = { 1, 2, 3 };
   static_assert(d1.a == 1 && d1.b == 3 && d1.c == 2 && d1.q == 2 && d1.k == 3);

   constexpr D d2 = { 14 };
   static_assert(d2.a == 14 && d2.b == 42 && d2.c == 41 && d2.q == 0 && d2.k == 0);

   constexpr D d3 = { A(5), C{2}, 1 };
   static_assert(d3.a == 5 && d3.b == 15 && d3.c == 14 && d3.q == 2 && d3.k == 1);

   constexpr D d4 = {};
   static_assert(d4.a == 10 && d4.b == 30 && d4.c == 29 && d4.q == 0 && d4.k == 0);

   constexpr D d5 = { __INT_MAX__ }; // expected-error {{must be initialized by a constant expression}}
   // expected-note-re@-1 {{in call to 'A({{.*}})'}}
 }

 namespace NoexceptFunctionTypes {
   template<typename T> constexpr bool f() noexcept(true) { return true; }
   constexpr bool (*fp)() = f<int>;
   static_assert(f<int>());
   static_assert(fp());

   template<typename T> struct A {
     constexpr bool f() noexcept(true) { return true; }
     constexpr bool g() { return f(); }
     constexpr bool operator()() const noexcept(true) { return true; }
   };
   static_assert(A<int>().f());
   static_assert(A<int>().g());
   static_assert(A<int>()());
 }

 namespace Cxx17CD_NB_GB19 {
   const int &r = 0;
   constexpr int n = r;
 }

 namespace PR37585 {
 template <class T> struct S { static constexpr bool value = true; };
 template <class T> constexpr bool f() { return true; }
 template <class T> constexpr bool v = true;

 void test() {
   if constexpr (true) {}
   else if constexpr (f<int>()) {}
   else if constexpr (S<int>::value) {}
   else if constexpr (v<int>) {}
 }
 }

 // Check that assignment operators evaluate their operands right-to-left.
 namespace EvalOrder {
   template<typename T> struct lvalue {
     T t;
     constexpr T &get() { return t; }
   };

   struct UserDefined {
     int n = 0;
     constexpr UserDefined &operator=(const UserDefined&) { return *this; }
     constexpr UserDefined &operator+=(const UserDefined&) { return *this; }
     constexpr void operator<<(const UserDefined&) const {}
     constexpr void operator>>(const UserDefined&) const {}
     constexpr void operator+(const UserDefined&) const {}
     constexpr void operator[](int) const {}
   };
   constexpr UserDefined ud;

   struct NonMember {};
   constexpr void operator+=(NonMember, NonMember) {}
   constexpr void operator<<(NonMember, NonMember) {}
   constexpr void operator>>(NonMember, NonMember) {}
   constexpr void operator+(NonMember, NonMember) {}
   constexpr NonMember nm;

   constexpr void f(...) {}

   // Helper to ensure that 'a' is evaluated before 'b'.
   struct seq_checker {
     bool done_a = false;
     bool done_b = false;

     template <typename T> constexpr T &&a(T &&v) {
       done_a = true;
       return (T &&)v;
     }
     template <typename T> constexpr T &&b(T &&v) {
       if (!done_a)
         throw "wrong";
       done_b = true;
       return (T &&)v;
     }

     constexpr bool ok() { return done_a && done_b; }
   };

   // SEQ(expr), where part of the expression is tagged A(...) and part is
   // tagged B(...), checks that A is evaluated before B.
   #define A sc.a
   #define B sc.b
   #define SEQ(...) static_assert([](seq_checker sc) { void(__VA_ARGS__); return sc.ok(); }({}))

   // Longstanding sequencing rules.
   SEQ((A(1), B(2)));
   SEQ((A(true) ? B(2) : throw "huh?"));
   SEQ((A(false) ? throw "huh?" : B(2)));
   SEQ(A(true) && B(true));
   SEQ(A(false) || B(true));

   // From P0145R3:

   // Rules 1 and 2 have no effect ('b' is not an expression).

   // Rule 3: a->*b
   SEQ(A(ud).*B(&UserDefined::n));
   SEQ(A(&ud)->*B(&UserDefined::n));

   // Rule 4: a(b1, b2, b3)
   SEQ(A(f)(B(1), B(2), B(3)));

   // Rule 5: b = a, b @= a
   SEQ(B(lvalue<int>().get()) = A(0));
   SEQ(B(lvalue<UserDefined>().get()) = A(ud));
   SEQ(B(lvalue<int>().get()) += A(0));
   SEQ(B(lvalue<UserDefined>().get()) += A(ud));
   SEQ(B(lvalue<NonMember>().get()) += A(nm));

   // Rule 6: a[b]
   constexpr int arr[3] = {};
   SEQ(A(arr)[B(0)]);
   SEQ(A(+arr)[B(0)]);
   SEQ(A(0)[B(arr)]);
   SEQ(A(0)[B(+arr)]);
   SEQ(A(ud)[B(0)]);

   // Rule 7: a << b
   SEQ(A(1) << B(2));
   SEQ(A(ud) << B(ud));
   SEQ(A(nm) << B(nm));

   // Rule 8: a >> b
   SEQ(A(1) >> B(2));
   SEQ(A(ud) >> B(ud));
   SEQ(A(nm) >> B(nm));

   // No particular order of evaluation is specified in other cases, but we in
   // practice evaluate left-to-right.
   // FIXME: Technically we're expected to check for undefined behavior due to
   // unsequenced read and modification and treat it as non-constant due to UB.
   SEQ(A(1) + B(2));
   SEQ(A(ud) + B(ud));
   SEQ(A(nm) + B(nm));
   SEQ(f(A(1), B(2)));

   #undef SEQ
   #undef A
   #undef B
 }

 namespace LambdaCallOp {
   constexpr void get_lambda(void (*&p)()) { p = []{}; }
   constexpr void call_lambda() {
     void (*p)() = nullptr;
     get_lambda(p);
     p();
   }
 }
	// RUN: %clang_cc1 -std=c++1z -verify %s -fcxx-exceptions -triple=x86_64-linux-gnu

	namespace BaseClassAggregateInit {
	struct A {
	int a, b, c;
	constexpr A(int n) : a(n), b(3 * n), c(b - 1) {} // expected-note {{outside the range of representable}}
	constexpr A() : A(10) {};
	};
	struct B : A {};
	struct C { int q; };
	struct D : B, C { int k; };

	constexpr D d1 = { 1, 2, 3 };
	static_assert(d1.a == 1 && d1.b == 3 && d1.c == 2 && d1.q == 2 && d1.k == 3);

	constexpr D d2 = { 14 };
	static_assert(d2.a == 14 && d2.b == 42 && d2.c == 41 && d2.q == 0 && d2.k == 0);

	constexpr D d3 = { A(5), C{2}, 1 };
	static_assert(d3.a == 5 && d3.b == 15 && d3.c == 14 && d3.q == 2 && d3.k == 1);

	constexpr D d4 = {};
	static_assert(d4.a == 10 && d4.b == 30 && d4.c == 29 && d4.q == 0 && d4.k == 0);

	constexpr D d5 = { __INT_MAX__ }; // expected-error {{must be initialized by a constant expression}}
	// expected-note-re@-1 {{in call to 'A({{.*}})'}}
	}

	namespace NoexceptFunctionTypes {
	template<typename T> constexpr bool f() noexcept(true) { return true; }
	constexpr bool (*fp)() = f<int>;
	static_assert(f<int>());
	static_assert(fp());

	template<typename T> struct A {
	constexpr bool f() noexcept(true) { return true; }
	constexpr bool g() { return f(); }
	constexpr bool operator()() const noexcept(true) { return true; }
	};
	static_assert(A<int>().f());
	static_assert(A<int>().g());
	static_assert(A<int>()());
	}

	namespace Cxx17CD_NB_GB19 {
	const int &r = 0;
	constexpr int n = r;
	}

	namespace PR37585 {
	template <class T> struct S { static constexpr bool value = true; };
	template <class T> constexpr bool f() { return true; }
	template <class T> constexpr bool v = true;

	void test() {
	if constexpr (true) {}
	else if constexpr (f<int>()) {}
	else if constexpr (S<int>::value) {}
	else if constexpr (v<int>) {}
	}
	}

	// Check that assignment operators evaluate their operands right-to-left.
	namespace EvalOrder {
	template<typename T> struct lvalue {
	T t;
	constexpr T &get() { return t; }
	};

	struct UserDefined {
	int n = 0;
	constexpr UserDefined &operator=(const UserDefined&) { return *this; }
	constexpr UserDefined &operator+=(const UserDefined&) { return *this; }
	constexpr void operator<<(const UserDefined&) const {}
	constexpr void operator>>(const UserDefined&) const {}
	constexpr void operator+(const UserDefined&) const {}
	constexpr void operator[](int) const {}
	};
	constexpr UserDefined ud;

	struct NonMember {};
	constexpr void operator+=(NonMember, NonMember) {}
	constexpr void operator<<(NonMember, NonMember) {}
	constexpr void operator>>(NonMember, NonMember) {}
	constexpr void operator+(NonMember, NonMember) {}
	constexpr NonMember nm;

	constexpr void f(...) {}

	// Helper to ensure that 'a' is evaluated before 'b'.
	struct seq_checker {
	bool done_a = false;
	bool done_b = false;

	template <typename T> constexpr T &&a(T &&v) {
	done_a = true;
	return (T &&)v;
	}
	template <typename T> constexpr T &&b(T &&v) {
	if (!done_a)
	throw "wrong";
	done_b = true;
	return (T &&)v;
	}

	constexpr bool ok() { return done_a && done_b; }
	};

	// SEQ(expr), where part of the expression is tagged A(...) and part is
	// tagged B(...), checks that A is evaluated before B.
	#define A sc.a
	#define B sc.b
	#define SEQ(...) static_assert([](seq_checker sc) { void(__VA_ARGS__); return sc.ok(); }({}))

	// Longstanding sequencing rules.
	SEQ((A(1), B(2)));
	SEQ((A(true) ? B(2) : throw "huh?"));
	SEQ((A(false) ? throw "huh?" : B(2)));
	SEQ(A(true) && B(true));
	SEQ(A(false) \|\| B(true));

	// From P0145R3:

	// Rules 1 and 2 have no effect ('b' is not an expression).

	// Rule 3: a->*b
	SEQ(A(ud).*B(&UserDefined::n));
	SEQ(A(&ud)->*B(&UserDefined::n));

	// Rule 4: a(b1, b2, b3)
	SEQ(A(f)(B(1), B(2), B(3)));

	// Rule 5: b = a, b @= a
	SEQ(B(lvalue<int>().get()) = A(0));
	SEQ(B(lvalue<UserDefined>().get()) = A(ud));
	SEQ(B(lvalue<int>().get()) += A(0));
	SEQ(B(lvalue<UserDefined>().get()) += A(ud));
	SEQ(B(lvalue<NonMember>().get()) += A(nm));

	// Rule 6: a[b]
	constexpr int arr[3] = {};
	SEQ(A(arr)[B(0)]);
	SEQ(A(+arr)[B(0)]);
	SEQ(A(0)[B(arr)]);
	SEQ(A(0)[B(+arr)]);
	SEQ(A(ud)[B(0)]);

	// Rule 7: a << b
	SEQ(A(1) << B(2));
	SEQ(A(ud) << B(ud));
	SEQ(A(nm) << B(nm));

	// Rule 8: a >> b
	SEQ(A(1) >> B(2));
	SEQ(A(ud) >> B(ud));
	SEQ(A(nm) >> B(nm));

	// No particular order of evaluation is specified in other cases, but we in
	// practice evaluate left-to-right.
	// FIXME: Technically we're expected to check for undefined behavior due to
	// unsequenced read and modification and treat it as non-constant due to UB.
	SEQ(A(1) + B(2));
	SEQ(A(ud) + B(ud));
	SEQ(A(nm) + B(nm));
	SEQ(f(A(1), B(2)));

	#undef SEQ
	#undef A
	#undef B
	}

	namespace LambdaCallOp {
	constexpr void get_lambda(void (*&p)()) { p = []{}; }
	constexpr void call_lambda() {
	void (*p)() = nullptr;
	get_lambda(p);
	p();
	}
	}