I am passing my local-variables by reference to two lambda. I call these lambdas outside of the function scope. Is this undefined ?

std::pair<std::function<int()>, std::function<int()>> addSome() {
    int a = 0, b = 0;
    return std::make_pair([&a,&b] {
        ++a; ++b;
        return a+b;
        }, [&a, &b] {
            return a;

int main() {
    auto f = addSome();
    std::cout << f.first() << " " << f.second();
    return 0;

If it is not, however, changes in one lambda are not reflected in other lambda.

Am i misunderstanding pass-by-reference in context of lambdas ?

I am writing to the variables and it seems to be working fine with no runtime-errors with output

2 0. If it works then i would expect output 2 1.

3 Answers 3


Yes, this causes undefined behavior. The lambdas will reference stack-allocated objects that have gone out of scope. (Technically, as I understand it, the behavior is defined until the lambdas access a and/or b. If you never invoke the returned lambdas then there is no UB.)

This is undefined behavior the same way that it's undefined behavior to return a reference to a stack-allocated local and then use that reference after the local goes out of scope, except that in this case it's being obfuscated a bit by the lambda.

Further, note that the order in which the lambdas are invoked is unspecified -- the compiler is free to invoke f.second() before f.first() because both are part of the same full-expression. Therefore, even if we fix the undefined behavior caused by using references to destroyed objects, both 2 0 and 2 1 are still valid outputs from this program, and which you get depends on the order in which your compiler decides to execute the lambdas. Note that this is not undefined behavior, because the compiler can't do anything at all, rather it simply has some freedom in deciding the order in which to do some things.

(Keep in mind that << in your main() function is invoking a custom operator<< function, and the order in which function arguments are evaluated is unspecified. Compilers are free to emit code that evaluates all of the function arguments within the same full-expression in any order, with the constraint that all arguments to a function must be evaluated before that function is invoked.)

To fix the first problem, use std::shared_ptr to create a reference-counted object. Capture this shared pointer by value, and the lambdas will keep the pointed-to object alive as long as they (and any copies thereof) exist. This heap-allocated object is where we will store the shared state of a and b.

To fix the second problem, evaluate each lambda in a separate statement.

Here is your code rewritten with the undefined behavior fixed, and with f.first() guaranteed to be invoked before f.second():

std::pair<std::function<int()>, std::function<int()>> addSome() {
    // We store the "a" and "b" ints instead in a shared_ptr containing a pair.
    auto numbers = std::make_shared<std::pair<int, int>>(0, 0);

    // a becomes numbers->first
    // b becomes numbers->second

    // And we capture the shared_ptr by value.
    return std::make_pair(
        [numbers] {
            return numbers->first + numbers->second;
        [numbers] {
            return numbers->first;

int main() {
    auto f = addSome();
    // We break apart the output into two statements to guarantee that f.first()
    // is evaluated prior to f.second().
    std::cout << f.first();
    std::cout << " " << f.second();
    return 0;

(See it run.)

  • This is a slightly old answer, but I ran across it while wondering about the same thing (capturing by reference of an out-of-scope local variable). But! Now I wonder if it's true that cout << f.first() << " " << f.second() could execute first() and second() in either order. I am skeptical -- if the iostream operators were syntactic sugar for big_print( f.first()," ",f.second() ) then I'd agree -- compiler can compute args for one function in any order. But cout << a << b << c is actually 3 calls of operator<<(s&,val), so by operator precedence, I think it has to go left->right.
    – Dave M.
    Sep 27, 2020 at 23:27
  • NVM, @cdhowie is right. cout << a << b << c is operator<<( operator<<( operator<<( cout, a ), b ), c ), and either of the dyads could be done first. So evaluation could be a before cout, b before operator<<(cout,a), or c before operator<<(operator<<(cout,a),b). Weird.
    – Dave M.
    Sep 27, 2020 at 23:38
  • Technically, the order of executing the lambdas in this specific scenario is termed as unspecified behavior as the compiler is free to reorder the evaluation of arguments in any way it wants.
    – ghd
    Mar 7, 2022 at 10:39

Unfortunately C++ lambdas can capture by reference but don't solve the "upwards funarg problem".

Doing so would require allocating captured locals in "cells" and garbage collection or reference counting for deallocation. C++ is not doing it and unfortunately this make C++ lambdas a lot less useful and more dangerous than in other languages like Lisp, Python or Javascript.

More specifically in my experience you should avoid at all costs implicit capture by reference (i.e. using the [&](…){…} form) for lambda objects that survive the local scope because that's a recipe for random segfaults later during maintenance.

Always plan carefully about what to capture and how and about the lifetime of captured references.

Of course it's safe to capture everything by reference with [&] if all you are doing is simply using the lambda in the same scope to pass code for example to algorithms like std::sort without having to define a named comparator function outside of the function or as locally used utility functions (I find this use very readable and nice because you can get a lot of context implicitly and there is no need to 1. make up a global name for something that will never be reused anywhere else, 2. pass a lot of context or creating extra classes just for that context).

An approach that can work sometimes is capturing by value a shared_ptr to a heap-allocated state. This is basically implementing by hand what Python does automatically (but pay attention to reference cycles to avoid memory leaks: Python has a garbage collector, C++ doesn't).

  • 3
    [&] is fine if the lifetime of the closure and its copies is limited to the enclosing {}, otherwise it is unsafe or dangerous. As such limited lifetime closures are common, avoiding it as a general rule seems overkill? Jan 5, 2015 at 8:34
  • 1
    @Yakk: I was thinking to lambdas for their use as closures, not as a poor man way to embed code in algorithms. I'll edit to explain that.
    – 6502
    Jan 5, 2015 at 8:38
  • Best answer for pointing to the funarg problem and for the comparison with other languages.
    – Maggyero
    Jan 30, 2017 at 7:09
  • I don't think it's good advice to say that folks should avoid capturing by reference at all costs. You should do it when it's a good idea, which is pretty often, in my experience. Obviously the value must remain in scope over the lifetime of the lambda's execution. Jul 16, 2018 at 21:36
  • @DanNissenbaum: I said that you should avoid default capture by reference if the lambda is going to survive the scope because that is a recipe for a disaster. Capturing by reference by default with [&] is perfectly OK only for lambdas that are used immediately.
    – 6502
    Jul 16, 2018 at 22:01

When you are going out of scope, make a copy of the locals you use with capture by value ([=]):

MyType func(void)
    int x = 5;
    //When called, local x will no longer be in scope; so, use capture by value.
    return ([=] {
         x += 2;

When you are in the same scope, better to use capture by reference ([&]):

void func(void)
    int x = 5;
    //When called, local x will still be in scope; safe to use capture by reference.
    ([&] {
        x += 2;
    })(); //Lambda is immediately invoked here, in the same scope as x, with ().
  • 3
    Your examples are backwards. In the first case, & is safe, while in the second it should be =.
    – cdhowie
    Aug 30, 2018 at 2:37
  • @cdhowie Fixed with an edit.
    – Andrew
    Jan 13 at 10:03

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