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In C++ you can declare lambdas for example like this:

int x = 5;
auto a = [=]() mutable { ++x; std::cout << x << '\n'; };
auto b = [&]()         { ++x; std::cout << x << '\n'; };

Both let me modify x, so what is the difference?

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1 Answer 1

up vote 61 down vote accepted

What is happening

The first will only modify its own copy of x and leave the outside x unchanged. The second will modify the outside x.

Add a print statement after trying each:

a();
std::cout << x << "----\n";
b();
std::cout << x << '\n';

This is expected to print:

6
5
----
6
6

Why

It may help to consider that lambda [...] expressions provide a concise way to create simple function objects (see [expr.prim.lambda] of the Standard).

They have [...] a public inline function call operator [...] which is declared as a const member function, but only [...] if and only if the lambdaexpression’s parameter-declaration-clause is not followed by mutable (italicized text = quotes from the standard).

You can think of as if

    int x = 5;
    auto a = [=]() mutable { ++x; std::cout << x << '\n'; };

==>

    int x = 5;

    class __lambda_a {
        int x;
    public:
        __lambda_a () : x($lookup-one-outer$::x) {}
        inline void operator() { ++x; std::cout << x << '\n'; }     
    } a;

and

    auto b = [&]()         { ++x; std::cout << x << '\n'; };

==>

    int x = 5;

    class __lambda_b {
        int &x;
    public:
        __lambda_b() : x($lookup-one-outer$::x) {}
        inline void operator() const { ++x; std::cout << x << '\n'; }         
        //                     ^^^^^
    } b;

Q: But if it is a const function, why can I still change x?

A: You are only changing the outside x. The lambda's own x is a reference, and the operation ++x does not modify the reference, but the refered value.

This works because in C++, the constness of a pointer/reference does not change the constness of the pointee/referencee seen through it.

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Nice and thorough. But I think you have a some places you meant b. And your objects of anonymous class type don't have initializers. Might want to explain we're pretending lambda_a() is a constructor although the class has no name. –  aschepler Jun 5 '13 at 18:52
    
@aschepler: Thanks for the suggestions :) I changed to reserved names. –  phresnel Jun 6 '13 at 9:33
    
Could you explain a bit more about the constness? I didn't get a clear picture there. I think explaining what would happen if the 'const' was not present there would make it easy. –  Anoop K. Prabhu Jul 30 '13 at 6:39
2  
@AnoopK.Prabhu: In the last example, the const actually makes no difference. You always mutate the referencee through a reference. But to give another example: int main () { int x; auto a = [=]() { ++x; }; }. g++ will give an error message for that because the [=] means that the generated function object gets its own member variable x, but the lack of mutable means that a const member function call operator is generated, therefore the x is not assignable. –  phresnel Jul 30 '13 at 8:27
    
Excellent! +1 particularly for the above comment and the constness of a pointer/reference does not change the constness of the pointee/referencee seen through it. Adding this case auto c = [=]() { ++x; }; above would give more clarity on why mutable, and there by const, makes a difference. –  legends2k Jun 12 '14 at 13:15

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