// RUN: %clang_cc1 -std=c++1y -verify -fsyntax-only -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 -fsyntax-only -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 struct first_impl { typedef F type; }; template using first = typename first_impl::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()(3.14); //expected-warning{{implicit conversion}} return 0; } } //end ns namespace test_conversion_to_fptr_2 { template struct X { T (*fp)(T) = [](auto a) { return a; }; }; X xi; template 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 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{{no viable conversion}}\ //expected-note{{candidate}} using F = int(int); using G = int(void*); L.operator F*(); L.operator G*(); // expected-note-re {{instantiation of function template specialization '{{.*}}::operator()'}} // 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 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}} 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{{no viable conversion}}\ //expected-note{{candidate template ignored}} 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 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 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 void print(Ts ... ts) { } template 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{}); }; 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 void print(Ts ... ts) { } template F& FirstArg(F& f, Rest...) { return f; } template 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{}); }; 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 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{}); }; 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{}); 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 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 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 F& FirstArg(F& f, Rest& ... r) { return f; }; template 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{}); 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 void finalizeDefaultAtomValues() { auto startEnd = [](const char * sym) -> void { string start("__"); start += sym; }; startEnd("preinit_array"); } void f() { finalizeDefaultAtomValues(); } } namespace PR17476_variant { struct string { string(const char *__s) { } string &operator+=(const string &__str) { return *this; } }; template void finalizeDefaultAtomValues() { auto startEnd = [](const T *sym) -> void { string start("__"); start += sym; }; startEnd("preinit_array"); } void f() { finalizeDefaultAtomValues(); } } namespace PR17877_lambda_declcontext_and_get_cur_lambda_disconnect { template struct U { int t = 0; }; template struct V { U size() const { return U{}; } }; template void Do() { V 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}} 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}} int (*fpG)(int) = [](auto i) { return i; }; void fooptrG(int (*fp)(char) = [](auto c) { return 0; }) { } }; }; } //end ns namespace ns2 { struct X1 { template 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}} 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}} int (*fpG)(T) = [](auto i) { return i; }; void fooptrG(T (*fp)(char) = [](auto c) { return 0; }) { } template int fooG2(T (*fp)(U) = [](auto a) { return 0; }) { return 0; } template int fooG3(T (*fp)(U) = [](auto a) { return 0; }); }; }; template template int X1::X2::fooG3(T (*fp)(U)) { return 0; } X1::X2 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 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'}} }