Consider this:

#include <functional>
#include <iostream>

std::function<void()> make_function(int& x) {
    return [&]{ std::cout << x << std::endl; };

int main() {
    int i = 3;
    auto f = make_function(i);
    i = 5;

Is this program guaranteed to output 5 without invoking undefined behavior?

I understand how it works if I capture x by value ([=]), but I am not sure if I am invoking undefined behavior by capturing it by reference. Could it be that I will end up with a dangling reference after make_function returns, or is the captured reference guaranteed to work as long as the originally referenced object is still there?

Looking for definitive standards-based answers here :) It works well enough in practice so far ;)

  • 1
    Note that another safe solution to capturing the location of x is: std::function<void()> make_function(int& x) { auto px = &x; return [=](){ std::cout << *px << std::endl; }; } – Ben Voigt Jan 29 '14 at 21:32
  • Yes, that's worth mentioning. Thanks. – Magnus Hoff Jan 29 '14 at 21:33
  • Just updated above comment to show that the parameter can stay a reference. Important thing is to close on a pointer, by value. – Ben Voigt Jan 29 '14 at 21:33
up vote 21 down vote accepted

The code is guaranteed to work.

Before we delve into the standards wording: it's the C++ committee's intent that this code works. However, the wording as it stands was believed to be insufficiently clear on this (and indeed, bugfixes made to the standard post-C++14 broke the delicate arrangement that made it work), so CWG issue 2011 was raised to clarify matters, and is making its way through the committee now. As far as I know, no implementation gets this wrong.

I'd like to clarify a couple of things, because Ben Voigt's answer contains some factual errors that are creating some confusion:

  1. "Scope" is a static, lexical notion in C++, that describes a region of the program source code in which unqualified name lookup associates a particular name with a declaration. It has nothing to do with lifetime. See [basic.scope.declarative]/1.
  2. The "reaching scope" rules for lambdas are, likewise, a syntactic property that determine when capture is permitted. For example:

    void f(int n) {
      struct A {
        void g() { // reaching scope of lambda starts here
          [&] { int k = n; };
          // ...

    n is in scope here, but the reaching scope of the lambda does not include it, so it cannot be captured. Put another way, the reaching scope of the lambda is how far "up" it can reach and capture variables -- it can reach up to the enclosing (non-lambda) function and its parameters, but it can't reach outside that and capture declarations that appear outside.

So the notion of "reaching scope" is irrelevant to this question. The entity being captured is make_function's parameter x, which is within the reaching scope of the lambda.

OK, so let's look at the standard's wording on this issue. Per [expr.prim.lambda]/17, only id-expressions referring to entities captured by copy are transformed into a member access on the lambda closure type; id-expressions referring to entities captured by reference are left alone, and still denote the same entity they would have denoted in the enclosing scope.

This immediately seems bad: the reference x's lifetime has ended, so how can we refer to it? Well, it turns out that there is almost (see below) no way to refer to a reference outside its lifetime (you can either see a declaration of it, in which case it's in scope and thus presumably OK to use, or it's a class member, in which case the class itself must be within its lifetime for the member access expression to be valid). As a result, the standard did not have any prohibitions on using a reference outside its lifetime until very recently.

The lambda wording took advantage of the fact that there is no penalty for using a reference outside its lifetime, and so didn't need to give any explicit rules for what access to an entity captured by reference means -- it just means you use that entity; if it's a reference, the name denotes its initializer. And that's how this was guaranteed to work up until very recently (including in C++11 and C++14).

However, it's not quite true that you can't mention a reference outside its lifetime; in particular, you can reference it from within its own initializer, from the initializer of a class member earlier than the reference, or if it is a namespace-scope variable and you access it from another global that is initialized before it is. CWG issue 2012 was introduced to fix that oversight, but it inadvertantly broke the specification for lambda capture by reference of references. We should get this regression fixed before C++17 ships; I've filed a National Body comment to make sure it's suitably prioritized.

  • 1
    There are no factual errors in my answer, my mention of reaching scope is a proof that the captured entity is x not i, which you state without proof. We appear to agree on all points, including that "the arrangement that [would have] made it work" was broken in C++14. Glad to see a fix in C++17, you'll note that my answer said exactly "Definitely something I would like to see the Standard clarify." – Ben Voigt Dec 1 '17 at 15:24
  • has the CWG2011 issue been vetted in c++17 ? – Jean-Michaël Celerier Dec 7 '17 at 14:46
  • 1
    In the last C++17 draft, the relevant part is now, p. 106. – Carsten S Jan 9 at 9:26

TL;DR: The code in the question is not guaranteed by the Standard, and there are reasonable implementations of lambdas which cause it to break. Assume it is non-portable and instead use

std::function<void()> make_function(int& x)
    const auto px = &x;
    return [/* = */ px]{ std::cout << *px << std::endl; };

Beginning in C++14, you can do away with explicit use of a pointer using an initialized capture, which forces a new reference variable to be created for the lambda, instead of reusing the one in the enclosing scope:

std::function<void()> make_function(int& x)
    return [&x = x]{ std::cout << x << std::endl; };

On first glance, it seems that should be safe, but the wording of the Standard causes a bit of a problem:

A lambda-expression whose smallest enclosing scope is a block scope (3.3.3) is a local lambda expression; any other lambda-expression shall not have a capture-default or simple-capture in its lambda-introducer. The reaching scope of a local lambda expression is the set of enclosing scopes up to and including the innermost enclosing function and its parameters.


All such implicitly captured entities shall be declared within the reaching scope of the lambda expression.


[ Note: If an entity is implicitly or explicitly captured by reference, invoking the function call operator of the corresponding lambda-expression after the lifetime of the entity has ended is likely to result in undefined behavior. — end note ]

What we expect to happen is that x, as used inside make_function, refers to i in main() (since that is what references do), and the entity i is captured by reference. Since that entity still lives at the time of the lambda call, everything is good.

But! "implicitly captured entities" must be "within the reaching scope of the lambda expression", and i in main() is not in the reaching scope. :( Unless the parameter x counts as "declared within the reaching scope" even though the entity i itself is outside the reaching scope.

What this sounds like is that, unlike any other place in C++, a reference-to-reference is created, and the lifetime of a reference has meaning.

Definitely something I would like to see the Standard clarify.

In the meantime, the variant shown in the TL;DR section is definitely safe because the pointer is captured by value (stored inside the lambda object itself), and it is a valid pointer to an object which lasts through the call of the lambda. I would also expect that capturing by reference actually ends up storing a pointer anyway, so there should be no runtime penalty for doing this.

On closer inspection, we also imagine that it could break. Remember that on x86, in the final machine code, both local variables and function parameters are accessed using EBP-relative addressing. Parameters have a positive offset, while locals are negative. (Other architectures have different register names but many work in the same way.) Anyway, this means that capture-by-reference can be implemented by capturing only the value of EBP. Then locals and parameters alike can again be found via relative addressing. And in fact I believe I've heard of lambda implementations (in languages which had lambdas long before C++) doing exactly this: capturing the "stack frame" where the lambda was defined.

What this implies is that when make_function returns and its stack frame goes away, so does all ability to access locals AND parameters, even those which are references.

And the Standard contains the following rule, likely specifically to enable this approach:

It is unspecified whether additional unnamed non-static data members are declared in the closure type for entities captured by reference.

Conclusion: The code in the question is not guaranteed by the Standard, and there are reasonable implementations of lambdas which cause it to break. Assume it is non-portable.

  • 3
    "is likely to result in undefined behavior". Is this normal standard-speak? :) That sounds unexpectedly vague :P – Magnus Hoff Jan 29 '14 at 21:45
  • 3
    @dyp: Look at /18 (or /17) again. "Every id-expression that is an odr-use (3.2) of an entity captured by copy is transformed into an access to the corresponding unnamed data member of the closure type." It is transformed to an access to a member of the closure type. Before this transformation, it was an access to the original entity. And the transformation isn't done for capture-by-reference. Those remain as access to the original entity in the reaching scope. – Ben Voigt Jan 29 '14 at 22:02
  • 1
    @dyp: So what we know is that inside the lambda, variable accesses which haven't been transformed are accesses to the original entity in the reaching scope. How the compiler accomplishes this "capture by reference" is left unrestricted. (/17 or /18 states this explicitly for accesses which are not odr-use, and also do not get transformed) – Ben Voigt Jan 29 '14 at 22:05
  • 1
    @BenVoigt Certainly the variable with a reference type is 'captured by reference' but that term isn't defined such that we can reason about what happens when a variable which is captured by reference goes out of scope. C++11 5.1.2/22 is non-normative and I think somewhat confused, referring to the 'lifetime' of a variable, rather than a scope. My conclusion is that the result is undefined behavior simply because the standard fails to define the behavior. – bames53 Jan 31 '14 at 15:24
  • 1
    @kriss: I'm sorry you disagree with the specification. It is very explicit that (1) the captured entity is the reference, not the referent and (2) use of the lambda after the lifetime of the captured entities has ended is not defined. How is "entity captured by reference, and the entity is itself a reference" not a reference to reference? If what you want is a copy of the pointer, there's a syntax for that, which has been part of my answer for the last six months. – Ben Voigt Sep 3 '14 at 16:43

Your Answer


By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.