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I found this piece of code doesn't work:

typedef int (*fp)(int a, int b);

constexpr fp addition()
    return [](int a, int b){ return a+b; };

#include <iostream>

int main()
    fp fun = addition();
    std::cout << fun(2,2);

It gives me error

cexpr.cpp: In function 'constexpr int (* addition())(int, int)':
cexpr.cpp:5:43: error: call to non-constexpr function 'addition()::<lambda(int,
int)>::operator int (*)(int, int)() const'

Why is that? I'm not calling it here.

Direct approach works:

typedef int (*fp)(int a, int b);

#include <iostream>

int main()
    fp fun = [](int a, int b){ return a+b; };
    std::cout << fun(2,2);

I'm using MinGW with g++ version 4.7.2.

share|improve this question
The implicit conversion to function pointers isn't constexpr apparently. – Pubby Dec 29 '12 at 21:12
@Pubby changing it to return static_cast<fp>([](int a, int b){ return a+b; });, and it still doesn't work. – milleniumbug Dec 29 '12 at 21:14
@Pubby: That is not a problem. constexpr int f(int a) { return a; } is absolutely fine! – Nawaz Dec 29 '12 at 21:19
The conversion function? Yes, you are calling it. – Lightness Races in Orbit Dec 29 '12 at 21:31
up vote 9 down vote accepted

Your function fp() does not return a literal type, therefore it cannot be a constexpr function:

From 7.1.5: "The definition of a constexpr function shall satisfy the following constraints:

  • it shall not be virtual (10.3);
  • its return type shall be a literal type;
  • each of its parameter types shall be a literal type;
  • its function-body shall be = delete, = default, or a compound-statement that contains only
    • null statements,
    • static_assert-declarations
    • typedef declarations and alias-declarations that do not define classes or enumerations,
    • using-declarations,
    • using-directives,
    • and exactly one return statement;"

I do not think there is any bug here, and especially nothing related to lambdas as mentioned in an earlier answer: variables simply cannot be declared inside of a constexpr function.

share|improve this answer
But according to this site (i don't have a copy of the C++11 standard) pointer type is a literal type. – milleniumbug Dec 29 '12 at 22:11
@milleniumbug: (sorry, I am editing this comment because the previous version was badly formatted): from what I understand, the standard defines nullptr as the only pointer-literal (2.14.7) "The pointer literal is the keyword nullptr. [...]" – Andy Prowl Dec 29 '12 at 22:16
btw you can download the working draft of the standard from this link: – Andy Prowl Dec 29 '12 at 22:19
Oh well - A literal constant expression is a prvalue core constant expression of literal type, but not pointer type (after conversions as required by the context). (5.19.4) – milleniumbug Dec 29 '12 at 22:24
BTW thanks for the link - this is even newer than what I found several months ago. I thought after the C++11 has been released, there won't be any updates. Silly me ;) – milleniumbug Dec 29 '12 at 22:27

According to N3376 working draft of the standard section 5.19 [expr.const]:

Certain contexts require expressions that satisfy additional requirements as detailed in this sub-clause; other contexts have different semantics depending on whether or not an expression satisfies these requirements. Expressions that satisfy these requirements are called constant expressions. [ Note: Constant expressions can be evaluated during translation.— end note ]

It goes on to say:

A conditional-expression is a core constant expression unless it involves one of the following as a potentially evaluated subexpression (3.2), but subexpressions of logical AND (5.14), logical OR (5.15), and conditional (5.16) operations that are not evaluated are not considered [ Note: An overloaded operator invokes a function.— end note ]:

Which lists under it:

— a lambda-expression (5.1.2);

So while I don't know enough standardese, I believe this says that a constexpr shouldn't have a lambda expression inside.

share|improve this answer
I believe "constant expression" and "constexpr functions" are two different things. The requirements for a "constexpr function" in the standard are listed under 7.1.5 (point 3), and this doesn't mention that the body of a "constexpr function" must be a "constant expression". The latter probably allows for more than the former (but I admit I do not speak standardese either). – Andy Prowl Dec 29 '12 at 22:12
@AndyProwl I am unsure because all the example code from the section uses constexpr as a measure of "okay" or "not". I did end up looking further into it though and it lists the requirements for a constexpr function at around section 7.1.5 point 3 like you say so. – Rapptz Dec 29 '12 at 22:16
I believe it does so to show that a "constexpr variable" can be initialized by invoking a "constexpr function" and that makes it a valid "constant expression", but that does not specify what can and cannot be part of the body of a "constexpr function" – Andy Prowl Dec 29 '12 at 22:22

The error message gcc gave you was precise and correct:

error: call to non-constexpr function 'addition()::
             operator int (*)(int, int)() const'

I've reformatted it a bit and added emphasis. By coercing the lambda to a function pointer, you're implicitly calling the automatically-created conversion function from lambda to pointer to function of type "auto (int, int)->int", which is not a constexpr function because the automatically-created conversion function is not declared constexpr (and the standard doesn't require it to be).

share|improve this answer
"It's too late" - doesn't matter. The more answers, the better for me ;) Have an upvote. – milleniumbug Dec 29 '12 at 22:58
Now that I see it, this is completely obvious, but wasn't when I was asking. Probably I saw here operator int (int, int)() const instead and was confused. What You See Is Not Always What You Want To See indeed. – milleniumbug Jan 3 '13 at 22:29

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