// RUN: %clang_cc1 -std=c++11 -Wno-unused-value -fsyntax-only -verify -fblocks %s // RUN: %clang_cc1 -std=c++1y -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 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 // expected-error@-2 {{drops qualifiers}} #else 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}} }