I've been playing around with some of the new features in C++11, and I tried to write the following program, expecting it not to work. Much to my surprise, it does (on GCC 4.6.1 on Linux x86 with the 'std=c++0x' flag):

#include <functional>
#include <iostream>
#include <memory>

std::function<int()> count_up_in_2s(const int from) {
    std::shared_ptr<int> from_ref(new int(from));
    return [from_ref]() { return *from_ref += 2; };

int main() {
    auto iter_1 = count_up_in_2s(5);
    auto iter_2 = count_up_in_2s(10);

    for (size_t i = 1; i <= 10; i++)
        std::cout << iter_1() << '\t' << iter_2() << '\n'

I was expecting 'from_ref' to be deleted when each execution of the returned lambda runs. Here's my reasoning: once count_up_in_2s is run, from_ref is popped off the stack, yet because the returned lambda isn't neccessarily ran straight away, since it's returned, there isn't another reference in existence for a brief period until the same reference is pushed back on when the lambda is actually run, so shouldn't shared_ptr's reference count hit zero and then delete the data?

Unless C++11's lambda capturing is a great deal more clever than I'm giving it credit for, which if it is, I'll be pleased. If this is the case, can I assume that C++11's variable capturing will allow all the lexical scoping/closure trickery a la Lisp as long as /something/ is taking care of dynamically allocated memory? Can I assume that all captured references will stay alive until the lambda itself is deleted, allowing me to use smart_ptrs in the above fashion?

If this is as I think it is, doesn't this mean that C++11 allows expressive higher-order programming? If so, I think the C++11 committee did an excellent job =)


The lambda captures from_ref by value, so it makes a copy. Because of this copy, the ref count is not 0 when from_ref gets destroyed, it is 1 because of the copy that still exists in the lambda.

  • 1
    So am I right in understanding that the std::function object itself stores the captures values throughout the duration of the instance? And that by storing this reference, the shared_ptr reference count never hits 0? Ah, I see. How elegant. – Louis Dec 19 '11 at 4:19
  • 3
    @Louis no, not the function object, but the lambda. std::function doesn't know about the captures of lambdas. – Seth Carnegie Dec 19 '11 at 4:23
  • So the capturing and storing of the reference is handled as a special case rather than stored as a member in the std::function instance, say. Thanks. – Louis Dec 19 '11 at 4:24
  • @Louis yes, that's right – Seth Carnegie Dec 19 '11 at 4:28
  • 3
    @Louis - The captured variable is stored as a member variable of the compiler-generated lambda object. Each lambda expression causes the generation of a custom class that stores captures as members (either by reference or by value, depending on the capture mode) and has an operator() equivalent to the lambda body. This class is then instantiated to create the result value of the lambda expression. – JohannesD Dec 19 '11 at 11:09

The following:

std::shared_ptr<int> from_ref(new int(from));
return [from_ref]() { return *from_ref += 2; };

is mostly equivalent to this:

std::shared_ptr<int> from_ref(new int(from));
class __uniqueLambdaType1432 {
  std::shared_ptr<int> capture1;
  __uniqueLambdaType1432(std::shared_ptr<int> capture1) :
    capture1(capture1) { 
  decltype(*capture1 += 2) operator ()() const {
    return *capture1 += 2;
return __uniqueLambdaType1432(from_ref);

where __uniqueLambdaType1432 is a program-globally unique type distinct from any other, even other lambda types generated by a lexically identical lambda expression. Its actual name is not available to the programmer, and besides the object resulting from the original lambda expression, no other instances of it can be created because the constructor is actually hidden with compiler magic.


from_ref is captured by value.

Your reasoning works if you substitute

return [from_ref]() { return *from_ref += 2; };


return [&from_ref]() { return *from_ref += 2; };

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