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In c++, when and how do you use a callback function?

EDIT:
I would like to see a simple example to write a callback function.

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7 Answers 7

up vote 33 down vote accepted

A Callback function is a method that is passed into a routine, and called at some point by the routine to which it is passed.

This is very useful for making reusable software. For example, many operating system APIs (such as the Windows API) use callbacks heavily.

For example, if you wanted to work with files in a folder - you can call an API function, with your own routine, and your routine gets run once per file in the specified folder. This allows the API to be very flexible.

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23  
This answer really doesn't average programmer tell anything he didn't know. I'm learning C++ while being familiar with many other languages. What callback is in general doesn't concern me. –  Tomáš Zato Dec 28 '14 at 1:32

There is also the C way of doing callbacks: function pointers

//Define a type for the callback signature,
//it is not necessary, but makes life easier

//Function pointer called CallbackType that takes a float
//and returns an int
typedef int (*CallbackType)(float);  


void DoWork(CallbackType callback)
{
  float variable = 0.0f;

  //Do calculations

  //Call the callback with the variable, and retrieve the
  //result
  int result = callback(variable);

  //Do something with the result
}

int SomeCallback(float variable)
{
  int result;

  //Interpret variable

  return result;
}

int main(int argc, char ** argv)
{
  //Pass in SomeCallback to the DoWork
  DoWork(&SomeCallback);
}

Now if you want to pass in class methods as callbacks, the declarations to those function pointers have more complex declarations, example:

//Declaration:
typedef int (ClassName::*CallbackType)(float);

//This method performs work using an object instance
void DoWorkObject(CallbackType callback)
{
  //Class instance to invoke it through
  ClassName objectInstance;

  //Invocation
  int result = (objectInstance.*callback)(1.0f);
}

//This method performs work using an object pointer
void DoWorkPointer(CallbackType callback)
{
  //Class pointer to invoke it through
  ClassName * pointerInstance;

  //Invocation
  int result = (pointerInstance->*callback)(1.0f);
}

int main(int argc, char ** argv)
{
  //Pass in SomeCallback to the DoWork
  DoWorkObject(&ClassName::Method);
  DoWorkPointer(&ClassName::Method);
}
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1  
that's neat...! –  user677656 Feb 2 '12 at 1:57
1  
There is an error in the class method example. The Invocation should be: (instance.*callback)(1.0f) –  CarlJohnson Sep 24 '12 at 22:15
    
Thank you for pointing that out. I'll add both to illustrate invoking through an object, and through an object pointer. –  Ramon Zarazua Sep 24 '12 at 22:16
3  
This has the disadvantage from std::tr1:function in that the callback is typed per-class; this makes it impractical to use C-style callbacks when the object performing the call doesn't know the class of the object to be called. –  bleater Feb 22 '13 at 3:00
1  
Yes you can. typedef is just syntactic sugar to make it more readable. Without typedef, the definition of DoWorkObject for function pointers would be: void DoWorkObject(int (*callback)(float)). For member pointers would be: void DoWorkObject(int (ClassName::*callback)(float)) –  Ramon Zarazua Jan 16 at 4:15

Scott Meyers gives a nice example:

class GameCharacter;
int defaultHealthCalc(const GameCharacter& gc);

class GameCharacter
{
public:
  typedef std::tr1::function<int (const GameCharacter&)> HealthCalcFunc;

  explicit GameCharacter(HealthCalcFunc hcf = defaultHealthCalc)
  : healthFunc(hcf)
  { }

  int healthValue() const { return healthFunc(*this); }

private:
  HealthCalcFunc healthFunc;
};

I think the example says it all.

tr1::function<> is the "modern" way of writing C++ callbacks.

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1  
Out of interest, which book does SM give this example in? Cheers :) –  sjwarner Nov 16 '11 at 8:45
1  
@sjwarner "Effective C++" –  Karl von Moor Dec 11 '11 at 19:12
4  
I know this is old, but because I almost started doing this and it ended up not working on my setup (mingw), if you're using GCC version < 4.x, this method is not supported. Some of the dependencies I'm using won't compile without a lot of work in gcc version >= 4.0.1, so I'm stuck with using good old fashioned C-style callbacks, which work just fine. –  OzBarry Aug 25 '12 at 0:52
    
@KarlvonMoor Which edition? –  Kimbluey Jun 12 at 14:32

Callback functions are part of the C standard, an therefore also part of C++. But if you are working with C++, I would suggest you use the observer pattern instead: http://en.wikipedia.org/wiki/Observer_pattern

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Callback functions are not necessarily synonymous with executing a function via a function pointer that was passed as an argument. By some definitions, the term callback function carries the additional semantics of notifying some other code of something that just happened, or that is time that something should happen. From that perspective, a callback function is not part of the C standard, but can be easily implemented using function pointers, which are part of the standard. –  Darryl Apr 7 '14 at 16:18
    
"part of the C standard, an therefore also part of C++." This is a typical misunderstandang, but a misunderstanding nonetheless :-) –  Limited Atonement Feb 10 at 18:47
    
I have to agree. I will leave it as it is, since it will only cause more confusion if I change it now. I meant to say that function pointer (!) are part of the standard. Saying anything different from that - I agree - is misleading. –  AudioDroid Feb 26 at 13:01

What are callables in C++?

Most of the answers cover function pointers which is one possibility to achieve "callback" logic in C++, but as of today not the most favourable one I think.

Callback functionality can be realized in several ways in C++ since several different things turn out to be callable*:

  • Function pointers (including pointers to member functions)
  • std::function objects
  • Lambda expressions
  • Bind expressions
  • Function objects (classes with overloaded function call operator operator())

* Note: Pointer to data members are callable as well but no function is called at all.

Why to use callbacks?

The reason to use callbacks is to write generic code which is independant from the logic in the called function and can be reused with different callbacks.

Benefit of different callable types

Basic callbacks can be realized using function pointers in C and C++.

Function objects

So what is the point in having callable function objects? The answer is: They have a state and enable the callback logic itself to be more complex than a simple function call. (See the d_printer class in example 1 and sum_square in example 2.) Note: The same logic can possibly be implemented with function pointers as well but this is likely to make the code more complicated.

Lambda functions

Lambda functions are unnamed, temporary "closures"; callable function objects which can capture variables from the local scope.

They enable you to simply write customized in-line function objects.

struct X { int s; };
// ...
std::vector<X> a = { /*...*/ }; // Vector of X sorted via X::s
int limit = 5;
auto it = std::lower_bound(a.begin(), a.end(), limit, [](X const &v, int const i){ 
  return v.s < i; 
});

Generic callable parameters

Since template parameters can match any of these callable types, it is quite powerful (and popular) to write generic code using a templated callback.

A lot of examples for the usage of such "general purpose callables" can be found in the C++ standard itself. for_each, find_if, lower_bound ... and many more.

Example 1: Print vector using std::for_each with different callables

The signature is:

template<class InputIt, class UnaryFunction>
UnaryFunction for_each(InputIt first, InputIt last, UnaryFunction f);

"Writing a callback function" for this function is quite easy since a callback function is nothing but a function taking a single argument the type of which has to match with the type of the dereferenced iterator.

Simple function pointer callback ...

void print_d(double const v) { std::cout << v; }
// ...
std::vector<double> const a{ 1.0, 2.0, 3.0 };
std::for_each(a.begin(), a.end(), &print_d);

Once for_each is called, the type UnaryFunction of f is deduced from the passed argument and f gets called for each element in the range first to last.

... and other callback types

The following example should give you an idea how callbacks can work. (See it on ideone)

I replaced std::for_each with my own implementation for_every to print the demangled, deduced type of the callback type.

#include <vector>
#include <algorithm>
#include <functional>
#include <iostream>
#include <typeinfo>
#include <string>
#include <memory>
#include <cxxabi.h>

template <class T>
std::string type_name()
{
  typedef typename std::remove_reference<T>::type TR;
  std::unique_ptr<char, void(*)(void*)> own
    (abi::__cxa_demangle(typeid(TR).name(), nullptr,
    nullptr, nullptr), std::free);
  std::string r = own != nullptr?own.get():typeid(TR).name();
  if (std::is_const<TR>::value)
    r += " const";
  if (std::is_volatile<TR>::value)
    r += " volatile";
  if (std::is_lvalue_reference<T>::value)
    r += " &";
  else if (std::is_rvalue_reference<T>::value)
    r += " &&";
  return r;
}

template<class InputIt, class UnaryFunction>
UnaryFunction for_every(InputIt first, InputIt last, UnaryFunction f)
{
  std::cout << "Calling callable object of type ";
  std::cout << type_name<UnaryFunction>() << ".\n";
  for (; first != last; ++first) 
  { 
    f(*first); // f is called here
  }
  std::cout << "\n";
  return f;
}

void d_to_cout(double const v) { std::cout << v; }
void d_to_cout_sep(double const v, char const sep) 
{ std::cout << v << sep; }

struct d_printer
{
  bool first = true;
  void operator () (double const v)
  {
    if (!first) std::cout << ", ";
    std::cout << v;
    first = false;
  }
};


int main()
{
  std::vector<double> const a{ 1.0, 2.0, 3.0 };
  for_every(a.begin(), a.end(), &d_to_cout);
  for_every(a.begin(), a.end(), std::function<void(double const)>(d_to_cout));
  for_every(a.begin(), a.end(), d_printer());
  for_every(a.begin(), a.end(), &d_to_cout);
  for_every(a.begin(), a.end(), [](double const v) {
    std::cout << v;
  });
  for_every(a.begin(), a.end(), std::bind(
    d_to_cout_sep, std::placeholders::_1, '/'
  ));
  return 0;
}

Output:

Calling callable object of type void(*)(double).
123
Calling callable object of type std::function<void(double)>.
123
Calling callable object of type d_printer.
1, 2, 3
Calling callable object of type void(*)(double).
123
Calling callable object of type main::{lambda(double)#1}.
123
Calling callable object of type std::_Bind<void(*(std::_Placeholder<1>, char))(double, char)>.
1 / 2 / 3 /

Example: Sum squares of vector values using std::for_each

#include <vector>
#include <algorithm>
#include <iostream>

struct sum_square
{
  double sum = double();
  void operator() (double const v) { sum += v*v; }
};

int main()
{
  std::vector<double> const a{ 1.0, 2.0, 3.0 };
  double sum = std::for_each(a.begin(), a.end(), sum_square()).sum;
  std::cout << sum << "\n";
  return 0;
}

The output is

14

As you see the implementation of for_each is quite generic and you can use it for a lot of things because a callback is used.

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There isn't an explicit concept of a callback function in C++. Callback mechanisms are often implemented via function pointers, functor objects, or callback objects. The programmers have to explicitly design and implement callback functionality.

Edit based on feedback:

In spite of the negative feedback this answer has received, it is not wrong. I'll try to do a better job of explaining where I'm coming from.

C and C++ have everything you need to implement callback functions. The most common and trivial way to implement a callback function is to pass a function pointer as a function argument.

However, callback functions and function pointers are not synonymous. A function pointer is a language mechanism, while a callback function is a semantic concept. Function pointers are not the only way to implement a callback function - you can also use functors and even garden variety virtual functions. What makes a function call a callback is not the mechanism used to identify and call the function, but the context and semantics of the call. Saying something is a callback function implies a greater than normal separation between the calling function and the specific function being called, a looser conceptual coupling between the caller and the callee, with the caller having explicit control over what gets called. It is that fuzzy notion of looser conceptual coupling and caller-driven function selection that makes something a callback function, not the use of a function pointer.

For example, the .NET documentation for IFormatProvider says that "GetFormat is a callback method", even though it is just a run-of-the-mill interface method. I don't think anyone would argue that all virtual method calls are callback functions. What makes GetFormat a callback method is not the mechanics of how it is passed or invoked, but the semantics of the caller picking which object's GetFormat method will be called.

Some languages include features with explicit callback semantics, typically related to events and event handling. For example, C# has the event type with syntax and semantics explicitly designed around the concept of callbacks. Visual Basic has its Handles clause, which explicitly declares a method to be a callback function while abstracting away the concept of delegates or function pointers. In these cases, the semantic concept of a callback is integrated into the language itself.

C and C++, on the other hand, does not embed the semantic concept of callback functions nearly as explicitly. The mechanisms are there, the integrated semantics are not. You can implement callback functions just fine, but to get something more sophisticated which includes explicit callback semantics you have to build it on top of what C++ provides, such as what Qt did with their Signals and Slots.

In a nutshell, C++ has what you need to implement callbacks, often quite easily and trivially using function pointers. What it does not have is keywords and features whose semantics are specific to callbacks, such as raise, emit, Handles, event +=, etc. If you're coming from a language with those types of elements, the native callback support in C++ will feel neutered.

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fortunately this was not the first answer I read when I visited this page, otherwise I would have made ​​an immediate bounce! –  ubugnu Apr 5 '14 at 19:33

See the above definition where it states that a callback function is passed off to some other function and at some point it is called.

In C++ it is desirable to have callback functions call a classes method. When you do this you have access to the member data. If you use the C way of defining a callback you will have to point it to a static member function. This is not very desirable.

Here is how you can use callbacks in C++. Assume 4 files. A pair of .CPP/.H files for each class. Class C1 is the class with a method we want to callback. C2 calls back to C1's method. In this example the callback function takes 1 parameter which I added for the readers sake. The example doesn't show any objects being instantiated and used. One use case for this implementation is when you have one class that reads and stores data into temporary space and another that post processes the data. With a callback function, for every row of data read the callback can then process it. This technique cuts outs the overhead of the temporary space required. It is particularly useful for SQL queries that return a large amount of data which then has to be post-processed.

/////////////////////////////////////////////////////////////////////
// C1 H file

class C1
{
    public:
    C1() {};
    ~C1() {};
    void CALLBACK F1(int i);
};

/////////////////////////////////////////////////////////////////////
// C1 CPP file

void CALLBACK C1::F1(int i)
{
// Do stuff with C1, its methods and data, and even do stuff with the passed in parameter
}

/////////////////////////////////////////////////////////////////////
// C2 H File

class C1; // Forward declaration

class C2
{
    typedef void (CALLBACK C1::* pfnCallBack)(int i);
public:
    C2() {};
    ~C2() {};

    void Fn(C1 * pThat,pfnCallBack pFn);
};

/////////////////////////////////////////////////////////////////////
// C2 CPP File

void C2::Fn(C1 * pThat,pfnCallBack pFn)
{
    // Call a non-static method in C1
    int i = 1;
    (pThat->*pFn)(i);
}
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