46

How can I compare two C++11 std::functions with operator==, and return true if both of said functions refer to the same function pointer?

4
  • 1
    Then what does std::function::target do? – JesseTG Dec 30 '13 at 4:50
  • 1
    Funnily enough, boost::function allows more equality checking than std::function AFAIK. – chris Dec 30 '13 at 5:01
  • Appears to be a duplicate of: stackoverflow.com/questions/3629835/… – MW_dev Sep 17 '14 at 4:04
  • std::function doesn't have to refer to a function pointer. What does it mean for two functions to be equal anyway? It's a dubious operation to begin with, even before you get to std::function. – n. 1.8e9-where's-my-share m. Aug 18 '20 at 6:48
22

operator== for std::function compares a std::function with a null pointer, as far as I can tell the standard does not provide any details as to why.

Although, this boost FAQ entry, Why can't I compare boost::function objects with operator== or operator!=? provides a rationale and as far as I can tell should be applicable to std::function as well. Quoting the FAQ:

Comparison between boost::function objects cannot be implemented "well", and therefore will not be implemented. [...]

it then outlines requested solutions similar to Preet's and goes on to say:

The problem occurs when the type of the function objects stored by both f and g doesn't have an operator==[...]

and explains why this has to has to be dealt with in either the assignment operator or constructor and then goes on to say:

All of these problems translate into failures in the boost::function constructors or assignment operator, even if the user never invokes operator==. We can't do that to users.

Update

Found a standards rationale in Accessing the target of a tr1::function object, which is pretty old but is consistent with the boost FAQ and says:

operator== is unimplementable for tr1::function within the C++ language, because we do not have a reliable way to detect if a given type T is Equality Comparable without user assistance.

0
13

You can actually get it to work with .target:

template<typename T, typename... U>
size_t getAddress(std::function<T(U...)> f) {
    typedef T(fnType)(U...);
    fnType ** fnPointer = f.template target<fnType*>();
    return (size_t) *fnPointer;
}

if (getAddress(f) == getAddress(g)) {...}

(Ref: C++ trying to get function address from a std::function)

4
  • Magic, thanks. For some reason my attempts at this without templating returned different function pointers for two std::function wrappers of the same function. Curious! – andybuckley Apr 19 '16 at 9:37
  • 2
    Converting function pointer to size_t is conditionally-supported with implementation-defined semantics. So this solution may not be portable. – M.M Dec 13 '17 at 3:45
  • 3
    This only works if the wrapped object is a function pointer, not if it is a callable class or one of several other things that can be wrapped by a std::function – Baruch Jan 14 '18 at 10:04
  • If you know the type of the target, then perhaps you don't need std::function to begin with. – n. 1.8e9-where's-my-share m. Aug 18 '20 at 6:48
4

You could try comparing a and b first by comparing their .target_type() and if these target type ids are the same, then you can compare their .target() pointers. You can use a mismatching target type as an early out false.

2
  • 4
    target<T>() requires knowing the type stored, not just knowing that it is the same. – Yakk - Adam Nevraumont Dec 30 '13 at 5:09
  • You mean the type of function? Because I think I can actually do that. – JesseTG Dec 30 '13 at 22:15
2

If the std::function<T(U...)> f is a member function,the fnPointer will be null.

2

Be aware that equality of functions (deciding if two functions have always the same observable behavior) is an undecidable problem in lambda calculus (and that is why many programming languages forbid comparing functions).

So even if the == test compiles, it would at most just test that the code is identical (has the same address), not that the compared functions have the same behaviour.

1

Well, if you are not afraid of hacks, you can do something like this:

// Simple function means no std::bind was used
bool IsSimpleFunction(std::function<void(Args...)> function)
{
    typedef void(functionType)(Args...);
    functionType** functionPointer = function.template target<functionType*>();
    return functionPointer != NULL;
}

bool AreEqual(std::function<void(Args...)> left, std::function<void(Args...)> right)
{
    const int size = sizeof(std::function<void(Args...)>);
    std::byte leftArray[size] = { {(std::byte)0} };
    std::byte rightArray[size] = { {(std::byte)0} };
    std::byte* leftByte = (std::byte*) new (&leftArray) std::function<void(Args...)>(left);
    std::byte* rightByte = (std::byte*) new (&rightArray) std::function<void(Args...)>(right);

    // PrintFunctionsBytes(leftByte, rightByte, size);

    // Here the HACK starts
    // By resetting certain values we are able to compare functions correctly
    // When values are reset it has the same effect as when these values are ignored
    bool isSimpleFunction = IsSimpleFunction(left);
    if (!isSimpleFunction)
    {
        ResetAt(leftArray, rightArray, 16);
    }
    ResetAt(leftArray, rightArray, 56);
    ResetAt(leftArray, rightArray, 57);
    // Here the HACK ends

    for (int i = 0; i < size; i++, leftByte++, rightByte++)
    {
        if (*leftByte != *rightByte)
        {
            return false;
        }
    }
    return true;
}

void ResetAt(std::byte* leftArray, std::byte* rightArray, int i)
{
    leftArray[i] = (std::byte)0;
    rightArray[i] = (std::byte)0;
}

// Only for debug
void PrintFunctionsBytes(std::byte* leftFirstByte, std::byte* rightFirstByte, unsigned long long size)
{
    std::vector<std::byte> leftVector(leftFirstByte, leftFirstByte + size);
    std::vector<std::byte> rightVector(rightFirstByte, rightFirstByte + size);
    std::cout << "Left: ";
    for (int i = 0; i < size; i++)
    {
        std::cout << i << ':' << (int)leftVector[i] << std::endl;
    }
    std::cout << "Right: ";
    for (int i = 0; i < size; i++)
    {
        std::cout << i << ':' << (int)rightVector[i] << std::endl;
    }
}

This was tested in MSVC and on 64 bit release configuration. And it was working for simple functions and for std::bind converted to std::function.

If you have different compiler or build configuration, you'll have to adjust ignored bytes for your environment.

Complete example here: https://github.com/linksplatform/Delegates

0

What about comparing two shared_ptr?

using MessageFilter = std::function<void(const int msgID)>;

static void onMessageReceived(const int msgID)
{
    std::cout << "msg id => " << msgID << std::endl;
}

static void someFunc()
{
    auto filter = std::make_shared<MessageFilter>(&onMessageReceived);

    if (filter && *filter)
    {
        (*filter)(1234);
    }
}

As you can see, 'filter' is a shared_ptr, so it is easy to compare with another.

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