When implementing a callback function in C++, should I still use the C-style function pointer:

void (*callbackFunc)(int);

Or should I make use of std::function:

std::function< void(int) > callbackFunc;
  • 12
    If the callback function is known at compile time, consider a template instead.
    – Baum mit Augen
    Sep 15, 2014 at 13:05
  • 5
    When implementing a callback function you should do whatever the caller requires. If your question is really about designing a callback interface, there's nowhere near enough information here to answer it. What do you want the recipient of your callback to do? What information do you need to pass to the recipient? What information should the recipient pass back to you as a result of the call? Sep 15, 2014 at 19:41

7 Answers 7


In short, use std::function unless you have a reason not to.

Function pointers have the disadvantage of not being able to capture some context. You won't be able to for example pass a lambda function as a callback which captures some context variables (but it will work if it doesn't capture any). Calling a data member of an object (i.e. non-static) is thus also not possible, since the object (this-pointer) needs to be captured.(1)

std::function (since C++11) is primarily to store a function (passing it around doesn't require it to be stored). Hence if you want to store the callback for example in a data member, it's probably your best choice. But also if you don't store it, it's a good "first choice" although it has the disadvantage of introducing some (very small) overhead when being called (so in a very performance-critical situation it might be a problem but in most it should not). It is very "universal": if you care a lot about consistent and readable code as well as don't want to think about every choice you make (i.e. want to keep it simple), use std::function for every function you pass around.

Think about a third option: If you're about to implement a small function which then reports something via the provided callback function, consider a template parameter, which can then be any callable object, i.e. a function pointer, a functor, a lambda, a std::function, ... Drawback here is that your (outer) function becomes a template and hence needs to be implemented in the header. On the other hand you get the advantage that the call to the callback can be inlined, as the client code of your (outer) function "sees" the call to the callback will the exact type information being available.

Example for the version with the template parameter (write & instead of && for pre-C++11):

template <typename CallbackFunction>
void myFunction(..., CallbackFunction && callback) {

As you can see in the following table, all of them have their advantages and disadvantages:

function ptr std::function template param
can capture context variables no1 yes yes
no call overhead (see comments) yes no yes
can be inlined (see comments) no no yes
can be stored in a class member yes yes no2
can be implemented outside of header yes yes no
supported without C++11 standard yes no3 yes
nicely readable (my opinion) no yes (yes)

(1) Workarounds exist to overcome this limitation, for example passing the additional data as further parameters to your (outer) function: myFunction(..., callback, data) will call callback(data). That's the C-style "callback with arguments", which is possible in C++ (and by the way heavily used in the WIN32 API) but should be avoided because we have better options in C++.

(2) Unless we're talking about a class template, i.e. the class in which you store the function is a template. But that would mean that on the client side the type of the function decides the type of the object which stores the callback, which is almost never an option for actual use cases.

(3) For pre-C++11, use boost::function

  • 10
    function pointers have call overhead compared to template parameters. template parameters make inlining easy, even if you are passed down upteen levels, because the code being executed is described by the type of the parameter not the value. And template function objects being stored in template return types is a common and useful pattern (with a good copy constructor, you can create the efficient template function invokable that can be converted to the std::function type-erased one if you need to store it outside the immediately called context). Sep 15, 2014 at 18:05
  • 1
    @tohecz I now mention if it requires C++11 or not.
    – leemes
    Sep 15, 2014 at 20:32
  • 1
    @Yakk Oh of course, forgot about that! Added it, thanks.
    – leemes
    Sep 15, 2014 at 21:38
  • 1
    @MooingDuck Of course it depends on the implementation. But if I remember correctly, due to how type erasure works there is one more indirection taking place? But now that I think about it again, I guess this is not the case if you assign function pointers or capture-less lambdas to it... (as a typical optimization)
    – leemes
    Sep 15, 2014 at 22:59
  • 1
    @leemes: Right, for function pointers or captureless lambdas, it ought to have the same overhead as a c-func-ptr. Which is is still a pipeline stall + not trivially inlined. Sep 15, 2014 at 23:06

void (*callbackFunc)(int); may be a C style callback function, but it is a horribly unusable one of poor design.

A well designed C style callback looks like void (*callbackFunc)(void*, int); -- it has a void* to allow the code that does the callback to maintain state beyond the function. Not doing this forces the caller to store state globally, which is impolite.

std::function< int(int) > ends up being slightly more expensive than int(*)(void*, int) invocation in most implementations. It is however harder for some compilers to inline. There are std::function clone implementations that rival function pointer invocation overheads (see 'fastest possible delegates' etc) that may make their way into libraries.

Now, clients of a callback system often need to set up resources and dispose of them when the callback is created and removed, and to be aware of the lifetime of the callback. void(*callback)(void*, int) does not provide this.

Sometimes this is available via code structure (the callback has limited lifetime) or through other mechanisms (unregister callbacks and the like).

std::function provides a means for limited lifetime management (the last copy of the object goes away when it is forgotten).

In general, I'd use a std::function unless performance concerns manifest. If they did, I'd first look for structural changes (instead of a per-pixel callback, how about generating a scanline processor based off of the lambda you pass me? which should be enough to reduce function-call overhead to trivial levels.). Then, if it persists, I'd write a delegate based off fastest possible delegates, and see if the performance problem goes away.

I would mostly only use function pointers for legacy APIs, or for creating C interfaces for communicating between different compilers generated code. I have also used them as internal implementation details when I am implementing jump tables, type erasure, etc: when I am both producing and consuming it, and am not exposing it externally for any client code to use, and function pointers do all I need.

Note that you can write wrappers that turn a std::function<int(int)> into a int(void*,int) style callback, assuming there are proper callback lifetime management infrastructure. So as a smoke test for any C-style callback lifetime management system, I'd make sure that wrapping a std::function works reasonably well.

  • 2
    Where did this void* come from? Why would you want to maintain state beyond the function? A function should contain all code it needs, all functionality, you just pass it the desired arguments and modify and return something. If you need some external state then why would a functionPtr or callback carry that luggage? I think that callback is unnecessarily complex.
    – KeyC0de
    Sep 26, 2018 at 9:16
  • @nik-lz I'm uncertain how I would teach you the use and history of callbacks in C in a comment. Or the philosophy of procedural as opposed to functional programming. So, you'll leave unfullfilled. Sep 26, 2018 at 9:56
  • I forgot this. Is it because one has to account the case of a member function being called, so we need the this pointer to point to the address of the object? If I'm wrong could you give me a link to where I can find more info on this, because I can't find much about it. Thanks in advance.
    – KeyC0de
    Sep 27, 2018 at 15:16
  • @Nik-Lz member functions aren't functions. Functions have no (runtime) state. Callbacks take a void* to permit transmission of runtime state. A function pointer with a void* and a void* argument can emulate a member function call to an object. Sorry, I don't know of a resource that walks through "designing C callback mechanisms 101". Sep 27, 2018 at 15:22
  • Yeah, that's what I was talking about. Runtime state is basically the address of the object being called (because it changes between runs). It's still about this. That's what I meant. Ok, thanks anyway.
    – KeyC0de
    Sep 27, 2018 at 15:27

Use std::function to store arbitrary callable objects. It allows the user to provide whatever context is needed for the callback; a plain function pointer does not.

If you do need to use plain function pointers for some reason (perhaps because you want a C-compatible API), then you should add a void * user_context argument so it's at least possible (albeit inconvenient) for it to access state that's not directly passed to the function.

  • Whats the type of p here? will it be a std::function type? void f(){}; auto p = f; p();
    – uss
    May 12, 2020 at 3:51

The only reason to avoid std::function is support of legacy compilers that lack support for this template, which has been introduced in C++11.

If supporting pre-C++11 language is not a requirement, using std::function gives your callers more choice in implementing the callback, making it a better option compared to "plain" function pointers. It offers the users of your API more choice, while abstracting out the specifics of their implementation for your code that performs the callback.


std::function may bring VMT to the code in some cases, which has some impact on performance.

  • 3
    Can you explain hat this VMT is?
    – TonySalimi
    Mar 20, 2019 at 10:28
  • 1
    Virtual method table?
    – mic
    Jan 6, 2021 at 18:49

The other answers answer based on technical merits. I'll give you an answer based on experience.

As a very heavy X-Windows developer who always worked with function pointer callbacks with void* pvUserData arguments, I started using std::function with some trepidation.

But I find out that combined with the power of lambdas and the like, it has freed up my work considerably to be able to, at a whim, throw multiple arguments in, re-order them, ignore parameters the caller wants to supply but I don't need, etc. It really makes development feel looser and more responsive, saves me time, and adds clarity.

On this basis I'd recommend anyone to try using std::function any time they'd normally have a callback. Try it everywhere, for like six months, and you may find you hate the idea of going back.

Yes there's some slight performance penalty, but I write high-performance code and I'm willing to pay the price. As an exercise, time it yourself and try to figure out whether the performance difference would ever matter, with your computers, compilers and application space.


There is 1 use case where plain C function pointers are the right answer: Comparison.

std::function has no proper concept of (in)equality. The only supported comparison is to nullptr, AKA the 'empty' state. Whereas function pointers are just pointers, so "==" works and does what you usually want: Return true for callbacks pointing to the exact same code (or both null), otherwise compare false. So if you really need to support comparing your callbacks, you need plain old function pointers or a custom functor type (a struct with an "operator ()") instead of std::function.

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