Lambda expressions (since C++11)

From cppreference.com
< cpp‎ | language
 
 
C++ language
General topics
Flow control
Conditional execution statements
if
Iteration statements (loops)
for
range-for (C++11)
Jump statements
Functions
Function declaration
Lambda function expression
inline specifier
Dynamic exception specifications (until C++17*)
noexcept specifier (C++11)
Exceptions
Namespaces
Types
Specifiers
decltype (C++11)
auto (C++11)
alignas (C++11)
Storage duration specifiers
Initialization
Expressions
Alternative representations
Literals
Boolean - Integer - Floating-point
Character - String - nullptr (C++11)
User-defined (C++11)
Utilities
Attributes (C++11)
Types
typedef declaration
Type alias declaration (C++11)
Casts
Implicit conversions - Explicit conversions
static_cast - dynamic_cast
const_cast - reinterpret_cast
Memory allocation
Classes
Class-specific function properties
explicit (C++11)
static
Special member functions
Templates
Miscellaneous
 
Expressions
General
Value categories (lvalue, rvalue, xvalue)
Order of evaluation (sequence points)
Constant expressions
Potentially-evaluated expressions
Primary expressions
Lambda expressions(C++11)
Literals
Integer literals
Floating-point literals
Boolean literals
Character literals including escape sequences
String literals
Null pointer literal(C++11)
User-defined literal(C++11)
Operators
a=b, a+=b, a-=b, a*=b, a/=b, a%=b, a&=b, a|=b, a^=b, a<<=b, a>>=b
++a, --a, a++, a--
+a, -a, a+b, a-b, a*b, a/b, a%b, ~a, a&b, a|b, a^b, a<<b, a>>b
a||b, a&&b, !a
a==b, a!=b, a<b, a>b, a<=b, a>=b, a<=>b (since C++20)
a[b], *a, &a, a->b, a.b, a->*b, a.*b
a(...), a,b, a?b:c
new-expression
delete-expression
throw-expression
alignof
sizeof
sizeof...(C++11)
typeid
noexcept(C++11)
Fold expressions(C++17)
Alternative representations of operators
Precedence and associativity
Operator overloading
Default comparisons(C++20)
Conversions
Implicit conversions
Usual arithmetic conversions
const_cast
static_cast
reinterpret_cast
dynamic_cast
Explicit conversions: (T)a, T(a), auto(a), auto{a} (since C++23)
User-defined conversion
 
 

Constructs a closure: an unnamed function object capable of capturing variables in scope.

Syntax

[ captures ] ( params ) specs requires (optional) { body } (1)
[ captures ] attr ( params ) specs requires (optional) { body } (1) (since C++23)
[ captures ] { body } (2)
[ captures ] attr specs { body } (2) (since C++23)
[ captures ] < tparams > requires (optional) ( params ) specs requires (optional) { body } (3) (since C++20)
[ captures ] < tparams > requires (optional) attr ( params ) specs requires (optional) { body } (3) (since C++23)
[ captures ] < tparams > requires (optional) { body } (4) (since C++20)
[ captures ] < tparams > requires (optional) attr specs { body } (4) (since C++23)
1) Full form.
2) Omitted parameter list: function takes no arguments, as if the parameter list were ().
3) Same as (1), but specifies a generic lambda and explicitly provides a list of template parameters.
4) Same as (2), but specifies a generic lambda and explicitly provides a list of template parameters.

Explanation

captures - a comma-separated list of zero or more captures, optionally beginning with a capture-default.

See below for the detailed description of captures.

A lambda expression can use a variable without capturing it if the variable

  • is a non-local variable or has static or thread local storage duration (in which case the variable cannot be captured), or
  • is a reference that has been initialized with a constant expression.

A lambda expression can read the value of a variable without capturing it if the variable

  • has const non-volatile integral or enumeration type and has been initialized with a constant expression, or
  • is constexpr and has no mutable members.
tparams - a non-empty comma-separated list of template parameters, used to provide names to the template parameters of a generic lambda (see ClosureType::operator() below).
params - The list of parameters, as in named functions.
specs - consists of specifiers, exception, attr and trailing-return-type in that order; each of these components is optional
specifiers - Optional sequence of specifiers. If not provided, the objects captured by copy are const in the lambda body. The following specifiers are allowed at most once in each sequence:
  • mutable: allows body to modify the objects captured by copy, and to call their non-const member functions
  • constexpr: explicitly specifies that the function call operator or any given operator template specialization is a constexpr function. When this specifier is not present, the function call operator or any given operator template specialization will be constexpr anyway, if it happens to satisfy all constexpr function requirements
(since C++17)
  • consteval: specifies that the function call operator or any given operator template specialization is an immediate function. consteval and constexpr cannot be used at the same time.
(since C++20)
  • static: specifies that the function call operator or any given operator template specialization is a static member function. mutable and static cannot be used at the same time, and captures must be empty if static is present.
(since C++23)
exception - provides the dynamic exception specification or (until C++20) the noexcept specifier for operator() of the closure type
attr - optional attribute specifier sequence.

An attribute specifier sequence applies to the type of the function call operator or operator template of the closure type. Any attribute so specified does not appertain to the function call operator or operator template itself, but its type. (For example, the [[noreturn]] attribute cannot be used.)

(until C++23)

If an attribute specifier sequence appears before the parameter list, lambda specifiers, or noexcept specifier, it applies to the function call operator or operator template of the closure type (and thus the [[noreturn]] attribute can be used). Otherwise, it applies to the type of the function call operator or operator template.

(since C++23)
trailing-return-type - -> ret, where ret specifies the return type. If trailing-return-type is not present, the return type of the closure's operator() is deduced from return statements as if for a function whose return type is declared auto.
requires - (since C++20) adds constraints to operator() of the closure type
body - Function body


If auto is used as a type of a parameter or an explicit template parameter list is provided (since C++20), the lambda is a generic lambda.

(since C++14)

A variable __func__ is implicitly defined at the beginning of body, with semantics as described here.

The lambda expression is a prvalue expression of unique unnamed non-union non-aggregate class type, known as closure type, which is declared (for the purposes of ADL) in the smallest block scope, class scope, or namespace scope that contains the lambda expression. The closure type has the following members, they cannot be explicitly instantiated, explicitly specialized, or (since C++14) named in a friend declaration:

ClosureType::operator()(params)

ret operator()(params) { body }
(static and const may be present, see below)
template<template-params>
ret operator()(params) { body }
(since C++14)
(generic lambda, static and const may be present, see below)

Executes the body of the lambda-expression, when invoked. When accessing a variable, accesses its captured copy (for the entities captured by copy), or the original object (for the entities captured by reference).

Unless the keyword mutable was used in the lambda specifiers, the cv-qualifier of the function-call operator or operator template is const and the objects that were captured by copy are non-modifiable from inside this operator(). Explicit const qualifier is not allowed. The function-call operator or operator template is never virtual and cannot have the volatile qualifier.

The function-call operator or any given operator template specialization is always constexpr if it satisfies the requirements of a constexpr function. It is also constexpr if the keyword constexpr was used in the lambda specifiers.

(since C++17)

The function-call operator or any given operator template specialization is an immediate function if the keyword consteval was used in the lambda specifiers.

(since C++20)

The function-call operator or any given operator template specialization is a static member function if the keyword static was used in the lambda specifiers.

(since C++23)


For each parameter in params whose type is specified as auto, an invented template parameter is added to template-params, in order of appearance. The invented template parameter may be a parameter pack if the corresponding function member of params is a function parameter pack.

// generic lambda, operator() is a template with two parameters
auto glambda = [](auto a, auto&& b) { return a < b; };
bool b = glambda(3, 3.14); // OK
 
// generic lambda, operator() is a template with one parameter
auto vglambda = [](auto printer)
{
    return [=](auto&&... ts) // generic lambda, ts is a parameter pack
    { 
        printer(std::forward<decltype(ts)>(ts)...);
        // nullary lambda (takes no parameters):
        return [=] { printer(ts...); };
    };
};
 
auto p = vglambda([](auto v1, auto v2, auto v3)
{
    std::cout << v1 << v2 << v3;
});
 
auto q = p(1, 'a', 3.14); // outputs 1a3.14
q();                      // outputs 1a3.14
(since C++14)


If the lambda definition uses an explicit template parameter list, that template parameter list is used with operator(). For each parameter in params whose type is specified as auto, an additional invented template parameter is appended to the end of that template parameter list:

// generic lambda, operator() is a template with two parameters
auto glambda = []<class T>(T a, auto&& b) { return a < b; };
 
// generic lambda, operator() is a template with one parameter pack
auto f = []<typename... Ts>(Ts&&... ts)
{
    return foo(std::forward<Ts>(ts)...);
};
(since C++20)

The exception specification exception on the lambda-expression applies to the function-call operator or operator template.

For the purpose of name lookup, determining the type and value of the this pointer and for accessing non-static class members, the body of the closure type's function call operator or operator template is considered in the context of the lambda-expression.

struct X
{
    int x, y;
    int operator()(int);
    void f()
    {
        // the context of the following lambda is the member function X::f
        [=]() -> int
        {
            return operator()(this->x + y); // X::operator()(this->x + (*this).y)
                                            // this has type X*
        };
    }
};

Dangling references

If a non-reference entity is captured by reference, implicitly or explicitly, and the function call operator or a specialization of the function call operator template of the closure object is invoked after the entity's lifetime has ended, undefined behavior occurs. The C++ closures do not extend the lifetimes of objects captured by reference.

Same applies to the lifetime of the current *this object captured via this.

ClosureType::operator ret(*)(params)()

capture-less non-generic lambda
using F = ret(*)(params);
operator F() const noexcept;
(until C++17)
using F = ret(*)(params);
constexpr operator F() const noexcept;
(since C++17)
capture-less generic lambda
template<template-params> using fptr_t = /*see below*/;

template<template-params>

operator fptr_t<template-params>() const noexcept;
(since C++14)
(until C++17)
template<template-params> using fptr_t = /*see below*/;

template<template-params>

constexpr operator fptr_t<template-params>() const noexcept;
(since C++17)

This user-defined conversion function is only defined if the capture list of the lambda-expression is empty. It is a public, constexpr, (since C++17) non-virtual, non-explicit, const noexcept member function of the closure object.

This function is an immediate function if the function call operator (or specialization, for generic lambdas) is an immediate function.

(since C++20)


A generic captureless lambda has a user-defined conversion function template with the same invented template parameter list as the function-call operator template. If the return type is empty or auto, it is obtained by return type deduction on the function template specialization, which, in turn, is obtained by template argument deduction for conversion function templates.

void f1(int (*)(int)) {}
void f2(char (*)(int)) {}
void h(int (*)(int)) {}  // #1
void h(char (*)(int)) {} // #2
 
auto glambda = [](auto a) { return a; };
f1(glambda); // OK
f2(glambda); // error: not convertible
h(glambda);  // OK: calls #1 since #2 is not convertible
 
int& (*fpi)(int*) = [](auto* a) -> auto& { return *a; }; // OK
(since C++14)


The value returned by the conversion function is a pointer to a function with C++ language linkage that, when invoked, has the same effect as invoking the closure type's function call operator on a default-constructed instance of the closure type.

(until C++14)

The value returned by the conversion function (template) is a pointer to a function with C++ language linkage that, when invoked, has the same effect as:

  • for non-generic lambdas, invoking the closure type's function call operator on a default-constructed instance of the closure type.
  • for generic lambdas, invoking the generic lambda's corresponding function call operator template specialization on a default-constructed instance of the closure type.
(since C++14)
(until C++23)

The value returned by the conversion function (template) is

  • if operator() is static, a pointer to that operator() (specialization) with C++ language linkage,
  • otherwise, a pointer to a function with C++ language linkage that, when invoked, has the same effect as:
    • for non-generic lambdas, invoking the closure type's function call operator on a default-constructed instance of the closure type.
    • for generic lambdas, invoking the generic lambda's corresponding function call operator template specialization on a default-constructed instance of the closure type.
(since C++23)


This function is constexpr if the function call operator (or specialization, for generic lambdas) is constexpr.

auto Fwd = [](int(*fp)(int), auto a) { return fp(a); };
auto C = [](auto a) { return a; };
static_assert(Fwd(C, 3) == 3);  // OK
 
auto NC = [](auto a) { static int s; return a; };
static_assert(Fwd(NC, 3) == 3); // error: no specialization can be
                                // constexpr because of static s

If the closure object's operator() has a non-throwing exception specification, then the pointer returned by this function has the type pointer to noexcept function.

(since C++17)

ClosureType::ClosureType()

ClosureType() = default;
(since C++20)
(only if no captures are specified)
ClosureType(const ClosureType&) = default;
ClosureType(ClosureType&&) = default;

Closure types are not DefaultConstructible. Closure types have no default constructor.

(until C++20)

If no captures are specified, the closure type has a defaulted default constructor. Otherwise, it has no default constructor (this includes the case when there is a capture-default, even if it does not actually capture anything).

(since C++20)

The copy constructor and the move constructor are declared as defaulted and may be implicitly-defined according to the usual rules for copy constructors and move constructors.

ClosureType::operator=(const ClosureType&)

ClosureType& operator=(const ClosureType&) = delete;
(until C++20)
ClosureType& operator=(const ClosureType&) = default;
ClosureType& operator=(ClosureType&&) = default;
(since C++20)
(only if no captures are specified)
ClosureType& operator=(const ClosureType&) = delete;
(since C++20)
(otherwise)

The copy assignment operator is defined as deleted (and the move assignment operator is not declared). Closure types are not CopyAssignable.

(until C++20)

If no captures are specified, the closure type has a defaulted copy assignment operator and a defaulted move assignment operator. Otherwise, it has a deleted copy assignment operator (this includes the case when there is a capture-default, even if it does not actually capture anything).

(since C++20)

ClosureType::~ClosureType()

~ClosureType() = default;

The destructor is implicitly-declared.

ClosureType::Captures

T1 a;

T2 b;

...

If the lambda-expression captures anything by copy (either implicitly with capture clause [=] or explicitly with a capture that does not include the character &, e.g. [a, b, c]), the closure type includes unnamed non-static data members, declared in unspecified order, that hold copies of all entities that were so captured.

Those data members that correspond to captures without initializers are direct-initialized when the lambda-expression is evaluated. Those that correspond to captures with initializers are initialized as the initializer requires (could be copy- or direct-initialization). If an array is captured, array elements are direct-initialized in increasing index order. The order in which the data members are initialized is the order in which they are declared (which is unspecified).

The type of each data member is the type of the corresponding captured entity, except if the entity has reference type (in that case, references to functions are captured as lvalue references to the referenced functions, and references to objects are captured as copies of the referenced objects).

For the entities that are captured by reference (with the capture-default [&] or when using the character &, e.g. [&a, &b, &c]), it is unspecified if additional data members are declared in the closure type, but any such additional members must satisfy LiteralType (since C++17).


Lambda-expressions are not allowed in unevaluated expressions, template arguments, alias declarations, typedef declarations, and anywhere in a function (or function template) declaration except the function body and the function's default arguments.

(until C++20)

Lambda capture

The captures is a comma-separated list of zero or more captures, optionally beginning with the capture-default. The capture list defines the outside variables that are accessible from within the lambda function body. The only capture defaults are

  • & (implicitly capture the used automatic variables by reference) and
  • = (implicitly capture the used automatic variables by copy).

The current object (*this) can be implicitly captured if either capture default is present. If implicitly captured, it is always captured by reference, even if the capture default is =. The implicit capture of *this when the capture default is = is deprecated. (since C++20)

The syntax of an individual capture in captures is

identifier (1)
identifier ... (2)
identifier initializer (3) (since C++14)
& identifier (4)
& identifier ... (5)
& identifier initializer (6) (since C++14)
this (7)
* this (8) (since C++17)
... identifier initializer (9) (since C++20)
& ... identifier initializer (10) (since C++20)
1) simple by-copy capture
2) simple by-copy capture that is a pack expansion
3) by-copy capture with an initializer
4) simple by-reference capture
5) simple by-reference capture that is a pack expansion
6) by-reference capture with an initializer
7) simple by-reference capture of the current object
8) simple by-copy capture of the current object
9) by-copy capture with an initializer that is a pack expansion
10) by-reference capture with an initializer that is a pack expansion

If the capture-default is &, subsequent simple captures must not begin with &.

struct S2 { void f(int i); };
void S2::f(int i)
{
    [&] {};          // OK: by-reference capture default
    [&, i] {};       // OK: by-reference capture, except i is captured by copy
    [&, &i] {};      // Error: by-reference capture when by-reference is the default
    [&, this] {};    // OK, equivalent to [&]
    [&, this, i] {}; // OK, equivalent to [&, i]
}

If the capture-default is =, subsequent simple captures must begin with & or be *this (since C++17) or this (since C++20).

struct S2 { void f(int i); };
void S2::f(int i)
{
    [=] {};        // OK: by-copy capture default
    [=, &i] {};    // OK: by-copy capture, except i is captured by reference
    [=, *this] {}; // until C++17: Error: invalid syntax
                   // since C++17: OK: captures the enclosing S2 by copy
    [=, this] {};  // until C++20: Error: this when = is the default
                   // since C++20: OK, same as [=]
}

Any capture may appear only once, and its name must be different from any parameter name:

struct S2 { void f(int i); };
void S2::f(int i)
{
    [i, i] {};        // Error: i repeated
    [this, *this] {}; // Error: "this" repeated (C++17)
 
    [i] (int i) {};   // Error: parameter and capture have the same name
}

Only lambda-expressions defined at block scope or in a default member initializer may have a capture-default or captures without initializers. For such lambda-expression, the reaching scope is defined as the set of enclosing scopes up to and including the innermost enclosing function (and its parameters). This includes nested block scopes and the scopes of enclosing lambdas if this lambda is nested.

The identifier in any capture without an initializer (other than the this-capture) is looked up using usual unqualified name lookup in the reaching scope of the lambda. The result of the lookup must be a variable with automatic storage duration declared in the reaching scope, or a structured binding whose corresponding variable satisfies such requirements (since C++20). The entity is explicitly captured.

A capture with an initializer acts as if it declares and explicitly captures a variable declared with type auto, whose declarative region is the body of the lambda expression (that is, it is not in scope within its initializer), except that:

  • if the capture is by-copy, the non-static data member of the closure object is another way to refer to that auto variable.
  • if the capture is by-reference, the reference variable's lifetime ends when the lifetime of the closure object ends.

This is used to capture move-only types with a capture such as x = std::move(x).

This also makes it possible to capture by const reference, with &cr = std::as_const(x) or similar.

int x = 4;
 
auto y = [&r = x, x = x + 1]() -> int
{
    r += 2;
    return x * x;
}(); // updates ::x to 6 and initializes y to 25.
(since C++14)

If a capture list has a capture-default and does not explicitly capture the enclosing object (as this or *this), or an automatic variable that is odr-usable in the lambda body, or a structured binding whose corresponding variable has atomic storage duration (since C++20), it captures it implicitly if

  • the body of the lambda odr-uses the entity
  • or the entity is named in a potentially-evaluated expression within an expression that depends on a generic lambda parameter (until C++17) (including when the implicit this-> is added before a use of non-static class member). For this purpose, the operand of typeid is always considered potentially-evaluated. Entities might be implicitly captured even if they are only named within a discarded statement. (since C++17)
void f(int, const int (&)[2] = {}) {}   // #1
void f(const int&, const int (&)[1]) {} // #2
 
void test()
{
    const int x = 17;
 
    auto g0 = [](auto a) { f(x); };  // OK: calls #1, does not capture x
 
    auto g1 = [=](auto a) { f(x); }; // does not capture x in C++14, captures x in C++17
                                     // the capture can be optimized away
    auto g2 = [=](auto a)
    {
        int selector[sizeof(a) == 1 ? 1 : 2] = {};
        f(x, selector); // OK: is a dependent expression, so captures x
    };
 
    auto g3 = [=](auto a)
    {
        typeid(a + x);  // captures x regardless of
                        // whether a + x is an unevaluated operand
    };
}
(since C++14)

If the body of a lambda odr-uses an entity captured by copy, the member of the closure type is accessed. If it is not odr-using the entity, the access is to the original object:

void f(const int*);
void g()
{
    const int N = 10;
    [=]
    { 
        int arr[N]; // not an odr-use: refers to g's const int N
        f(&N); // odr-use: causes N to be captured (by copy)
               // &N is the address of the closure object's member N, not g's N
    }();
}

If a lambda odr-uses a reference that is captured by reference, it is using the object referred-to by the original reference, not the captured reference itself:

#include <iostream>
 
auto make_function(int& x)
{
    return [&] { std::cout << x << '\n'; };
}
 
int main()
{
    int i = 3;
    auto f = make_function(i); // the use of x in f binds directly to i
    i = 5;
    f(); // OK: prints 5
}

Within the body of a lambda with capture default =, the type of any capturable entity is as if it were captured (and thus const-qualification is often added if the lambda is not mutable), even though the entity is in an unevaluated operand and not captured (e.g. in decltype):

void f3()
{
    float x, &r = x;
    [=]
    { // x and r are not captured (appearance in a decltype operand is not an odr-use)
        decltype(x) y1;        // y1 has type float
        decltype((x)) y2 = y1; // y2 has type float const& because this lambda
                               // is not mutable and x is an lvalue
        decltype(r) r1 = y1;   // r1 has type float& (transformation not considered)
        decltype((r)) r2 = y2; // r2 has type float const&
    };
}

Any entity captured by a lambda (implicitly or explicitly) is odr-used by the lambda-expression (therefore, implicit capture by a nested lambda triggers implicit capture in the enclosing lambda).

All implicitly-captured variables must be declared within the reaching scope of the lambda.

If a lambda captures the enclosing object (as this or *this), either the nearest enclosing function must be a non-static member function or the lambda must be in a default member initializer:

struct s2
{
    double ohseven = .007;
    auto f() // nearest enclosing function for the following two lambdas
    {
        return [this]      // capture the enclosing s2 by reference
        {
            return [*this] // capture the enclosing s2 by copy (C++17)
            {
                return ohseven;// OK
            }
        }();
    }
 
    auto g()
    {
        return [] // capture nothing
        { 
            return [*this] {};// error: *this not captured by outer lambda-expression
        }();
    }
};

If a lambda expression (or an instantiation of a generic lambda's function call operator) (since C++14) ODR-uses *this or any variable with automatic storage duration, it must be captured by the lambda expression.

void f1(int i)
{
    int const N = 20;
    auto m1 = [=]
    {
        int const M = 30;
        auto m2 = [i]
        {
            int x[N][M]; // N and M are not odr-used 
                         // (ok that they are not captured)
            x[0][0] = i; // i is explicitly captured by m2
                         // and implicitly captured by m1
        };
    };
 
    struct s1 // local class within f1()
    {
        int f;
        void work(int n) // non-static member function
        {
            int m = n * n;
            int j = 40;
            auto m3 = [this, m]
            {
                auto m4 = [&, j] // error: j is not captured by m3
                {
                    int x = n; // error: n is implicitly captured by m4
                               // but not captured by m3
                    x += m;    // OK: m is implicitly captured by m4
                               // and explicitly captured by m3
                    x += i;    // error: i is outside of the reaching scope
                               // (which ends at work())
                    x += f;    // OK: this is captured implicitly by m4
                               // and explicitly captured by m3
                };
            };
        }
    };
}

Class members cannot be captured explicitly by a capture without initializer (as mentioned above, only variables are permitted in the capture list):

class S
{
    int x = 0;
 
    void f()
    {
        int i = 0;
    //  auto l1 = [i, x] { use(i, x); };      // error: x is not a variable
        auto l2 = [i, x = x] { use(i, x); };  // OK, copy capture
        i = 1; x = 1; l2(); // calls use(0,0)
        auto l3 = [i, &x = x] { use(i, x); }; // OK, reference capture
        i = 2; x = 2; l3(); // calls use(1,2)
    }
};

When a lambda captures a member using implicit by-copy capture, it does not make a copy of that member variable: the use of a member variable m is treated as an expression (*this).m, and *this is always implicitly captured by reference:

class S
{
    int x = 0;
 
    void f()
    {
        int i = 0;
 
        auto l1 = [=] { use(i, x); }; // captures a copy of i and
                                      // a copy of the this pointer
        i = 1; x = 1; l1();           // calls use(0, 1), as if
                                      // i by copy and x by reference
 
        auto l2 = [i, this] { use(i, x); }; // same as above, made explicit
        i = 2; x = 2; l2();           // calls use(1, 2), as if
                                      // i by copy and x by reference
 
        auto l3 = [&] { use(i, x); }; // captures i by reference and
                                      // a copy of the this pointer
        i = 3; x = 2; l3();           // calls use(3, 2), as if
                                      // i and x are both by reference
 
        auto l4 = [i, *this] { use(i, x); }; // makes a copy of *this,
                                             // including a copy of x
        i = 4; x = 4; l4();           // calls use(3, 2), as if
                                      // i and x are both by copy
    }
};

If a lambda expression appears in a default argument, it cannot explicitly or implicitly capture anything, unless all captures have initializers which satisfy the constraints of an expression appearing in a default argument (since C++14):

void f2()
{
    int i = 1;
 
    void g1(int = ([i] { return i; })()); // error: captures something
    void g2(int = ([i] { return 0; })()); // error: captures something
    void g3(int = ([=] { return i; })()); // error: captures something
 
    void g4(int = ([=] { return 0; })());       // OK: capture-less
    void g5(int = ([] { return sizeof i; })()); // OK: capture-less
 
    // C++14
    void g6(int = ([x = 1] { return x; }))(); // OK: 1 can appear
                                              //     in a default argument
    void g7(int = ([x = i] { return x; }))(); // error: i cannot appear
                                              //        in a default argument
}
(since C++11)

Members of anonymous unions members cannot be captured. Bit-fields can only be captured by copy.

If a nested lambda m2 captures something that is also captured by the immediately enclosing lambda m1, then m2's capture is transformed as follows:

  • if the enclosing lambda m1 captures by copy, m2 is capturing the non-static member of m1's closure type, not the original variable or *this; if m1 is not mutable, the non-static data member is considered to be const-qualified.
  • if the enclosing lambda m1 captures by reference, m2 is capturing the original variable or *this.
#include <iostream>
 
int main()
{
    int a = 1, b = 1, c = 1;
 
    auto m1 = [a, &b, &c]() mutable
    {
        auto m2 = [a, b, &c]() mutable
        {
            std::cout << a << b << c << '\n';
            a = 4; b = 4; c = 4;
        };
        a = 3; b = 3; c = 3;
        m2();
    };
 
    a = 2; b = 2; c = 2;
 
    m1();                             // calls m2() and prints 123
    std::cout << a << b << c << '\n'; // prints 234
}

Notes

Feature-test macro Value Std Comment
__cpp_lambdas 200907L (C++11) Lambda expressions
__cpp_generic_lambdas 201304L (C++14) Generic lambda expressions
201707L (C++20) Explicit template parameter list for generic lambdas
__cpp_init_captures 201304L (C++14) Lambda init-capture
201803L (C++20) Allow pack expansion in lambda init-capture
__cpp_capture_star_this 201603L (C++17) Lambda capture of *this by value as [=, *this]
__cpp_constexpr 201603L (C++17) constexpr lambda
__cpp_static_call_operator 202207L (C++23) static operator() for captureless lambdas

Example

This example shows how to pass a lambda to a generic algorithm and how objects resulting from a lambda expression can be stored in std::function objects.

#include <algorithm>
#include <functional>
#include <iostream>
#include <vector>
 
int main()
{
    std::vector<int> c{1, 2, 3, 4, 5, 6, 7};
    int x = 5;
    c.erase(std::remove_if(c.begin(), c.end(), [x](int n) { return n < x; }), c.end());
 
    std::cout << "c: ";
    std::for_each(c.begin(), c.end(), [](int i) { std::cout << i << ' '; });
    std::cout << '\n';
 
    // the type of a closure cannot be named, but can be inferred with auto
    // since C++14, lambda could own default arguments
    auto func1 = [](int i = 6) { return i + 4; };
    std::cout << "func1: " << func1() << '\n';
 
    // like all callable objects, closures can be captured in std::function
    // (this may incur unnecessary overhead)
    std::function<int(int)> func2 = [](int i) { return i + 4; };
    std::cout << "func2: " << func2(6) << '\n';
 
    constexpr int fib_max {8};
    std::cout << "Emulate `recursive lambda` calls:\nFibonacci numbers: ";
    auto nth_fibonacci = [](int n)
    {
        std::function<int(int, int, int)> fib = [&](int n, int a, int b)
        {
            return n ? fib(n - 1, a + b, a) : b;
        };
        return fib(n, 0, 1);
    };
 
    for (int i{1}; i <= fib_max; ++i)
        std::cout << nth_fibonacci(i) << (i < fib_max ? ", " : "\n");
 
    std::cout << "Alternative approach to lambda recursion:\nFibonacci numbers: ";
    auto nth_fibonacci2 = [](auto self, int n, int a = 0, int b = 1) -> int
    {
        return n ? self(self, n - 1, a + b, a) : b;
    };
 
    for (int i{1}; i <= fib_max; ++i)
        std::cout << nth_fibonacci2(nth_fibonacci2, i) << (i < fib_max ? ", " : "\n");
 
#ifdef __cpp_explicit_this_parameter
    std::cout << "C++23 approach to lambda recursion:\n";
    auto nth_fibonacci3 = [](this auto self, int n, int a = 0, int b = 1) -> int
    {
         return n ? self(n - 1, a + b, a) : b;
    };
 
    for (int i{1}; i <= fib_max; ++i)
        std::cout << nth_fibonacci3(i) << (i < fib_max ? ", " : "\n");
#endif
}

Possible output:

c: 5 6 7
func1: 10
func2: 10
Emulate `recursive lambda` calls:
Fibonacci numbers: 0, 1, 1, 2, 3, 5, 8, 13
Alternative approach to lambda recursion:
Fibonacci numbers: 0, 1, 1, 2, 3, 5, 8, 13

Defect reports

The following behavior-changing defect reports were applied retroactively to previously published C++ standards.

DR Applied to Behavior as published Correct behavior
CWG 974 C++11 default argument was not allowed in the
parameter list of a lambda expression
allowed
CWG 975 C++11 the return type of closure's operator() was only
deduced if lambda body contains a single return
deduced as if for C++14
auto-returning function
CWG 1249 C++11 it is not clear that whether the captured member of the
enclosing non-mutable lambda is considered const or not
considered const
CWG 1557 C++11 the language linkage of the returned function type of
the closure type's conversion function was not specified
it has C++
language linkage
CWG 1607 C++11 lambda expressions could appear in
function and function template signatures
not allowed
CWG 1612 C++11 members of anonymous unions could be captured not allowed
CWG 1722 C++11 the conversion function for captureless lambdas
had unspecified exception specification
conversion function
is noexcept
CWG 1772 C++11 the semantic of __func__ in lambda body was not clear it refers to the closure
class's operator()
CWG 1780 C++14 it was unclear whether the members of the closure types of generic
lambdas can be explicitly instantiated or explicitly specialized
neither is allowed
CWG 1891 C++11 closure had a deleted default constructor
and implicit copy/move constructors
no default and defaulted
copy/move constructors
CWG 1937 C++11 as for the effect of invoking the result of the conversion function, it was
unspecified on which object calling its operator() has the same effect
on a default-constructed
instance of the closure type
CWG 2011 C++11 for a reference captured by reference, it was unspecified
which entity the identifier of the capture refers to
it refers to the originally
referenced entity
CWG 2095 C++11 the behavior of capturing rvalue references
to functions by copy was not clear
made clear
CWG 2211 C++11 the behavior was unspecified if a capture
has the same name as a parameter
the program is ill-
formed in this case
CWG 2358 C++14 lambda expressions appearing in default arguments had
to be capture-less even if all captures are initialized with
expressions which can appear in default arguments
allow such lambda
expressions with captures
CWG 2509 C++17 each specifier could have multiple
occurrences in the specifier sequence
each specifier can only
appear at most once in
the specifier sequence

See also

auto specifier (C++11) specifies a type deduced from an expression
(C++11)
wraps callable object of any copy constructible type with specified function call signature
(class template)
wraps callable object of any type with specified function call signature
(class template)

External links

Nested function - a function which is defined within another (enclosing) function.