// RUN: %clang_cc1 -fsyntax-only -std=c++1y %s -verify int a; int &b = [] (int &r) -> decltype(auto) { return r; } (a); int &c = [] (int &r) -> decltype(auto) { return (r); } (a); int &d = [] (int &r) -> auto & { return r; } (a); int &e = [] (int &r) -> auto { return r; } (a); // expected-error {{cannot bind to a temporary}} int &f = [] (int r) -> decltype(auto) { return r; } (a); // expected-error {{cannot bind to a temporary}} int &g = [] (int r) -> decltype(auto) { return (r); } (a); // expected-warning {{reference to stack}} int test_explicit_auto_return() { struct X {}; auto L = [](auto F, auto a) { return F(a); }; auto M = [](auto a) -> auto { return a; }; // OK auto MRef = [](auto b) -> auto& { return b; }; //expected-warning{{reference to stack}} auto MPtr = [](auto c) -> auto* { return &c; }; //expected-warning{{address of stack}} auto MDeclType = [](auto&& d) -> decltype(auto) { return static_cast<decltype(d)>(d); }; //OK M(3); auto &&x = MDeclType(X{}); auto &&x1 = M(X{}); auto &&x2 = MRef(X{});//expected-note{{in instantiation of}} auto &&x3 = MPtr(X{}); //expected-note{{in instantiation of}} return 0; } int test_implicit_auto_return() { { auto M = [](auto a) { return a; }; struct X {}; X x = M(X{}); } } int test_multiple_returns() { auto M = [](auto a) { bool k; if (k) return a; else return 5; //expected-error{{deduced as 'int' here}} }; M(3); // OK M('a'); //expected-note{{in instantiation of}} return 0; } int test_no_parameter_list() { static int si = 0; auto M = [] { return 5; }; // OK auto M2 = [] -> auto&& { return si; }; // expected-error{{lambda requires '()'}} M(); } int test_conditional_in_return() { auto Fac = [](auto f, auto n) { return n <= 0 ? n : f(f, n - 1) * n; }; // FIXME: this test causes a recursive limit - need to error more gracefully. //Fac(Fac, 3); }