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Introduction

If you are reading this article, you probably wonder what callback functions are. This article explains what callback functions are, what are they good for, why you should use them, and so forth. However, before learning what callback functions are, you must be familiar with function pointers. If you aren't, consult a C/C++ book or consider reading the following:

What Is a Callback Function?

The simple answer to this first question is that a callback function is a function that is called through a function pointer. If you pass the pointer (address) of a function as an argument to another, when that pointer is used to call the function it points to it is said that a call back is made.

Why Should You Use Callback Functions?

Because they uncouple the caller from the callee. The caller doesn't care who the callee is; all it knows is that there is a callee with a certain prototype and probably some restriction (for instance, the returned value can be int, but certain values have certain meanings).

If you are wondering how is that useful in practice, imagine that you want to write a library that provides implementation for sorting algorithms (yes, that is pretty classic), such as bubble sort, shell short, shake sort, quick sort, and others. The catch is that you don't want to embed the sorting logic (which of two elements goes first in an array) into your functions, making your library more general to use. You want the client to be responsible to that kind of logic. Or, you want it to be used for various data types (ints, floats, strings, and so on). So, how do you do it? You use function pointers and make callbacks.

A callback can be used for notifications. For instance, you need to set a timer in your application. Each time the timer expires, your application must be notified. But, the implementer of the time'rs mechanism doesn't know anything about your application. It only wants a pointer to a function with a given prototype, and in using that pointer it makes a callback, notifying your application about the event that has occurred. Indeed, the SetTimer() WinAPI uses a callback function to notify that the timer has expired (and, in case there is no callback function provided, it posts a message to the application's queue).

Another example from WinAPI functions that use callback mechanism is EnumWindow(), which enumerates all the top-level windows on the screen. EnumWindow() iterates over the top-level windows, calling an application-provided function for each window, passing the handler of the window. If the callee returns a value, the iteration continues; otherwise, it stops. EnumWindows() just doesn't care where the callee is and what it does with the handler it passes over. It is only interested in the return value, because based on that it continues its execution or not.

However, callback functions are inherited from C. Thus, in C++, they should be only used for interfacing C code and existing callback interfaces. Except for these situations, you should use virtual methods or functors, not callback functions.

A Simple Implementation Example

Now, follow the example that can be found in the attached files. I have created a dynamic linked library called sort.dll. It exports a type called CompareFunction:

typedef int (__stdcall *CompareFunction)(const byte*, const byte*);

which will be the type of your callback functions. It also exports two methods, called Bubblesort() and Quicksort(), which have the same prototype but provide different behavior by implementing the sorting algorithms with the same name.

void DLLDIR __stdcall Bubblesort(byte* array,
                                 int size,
                                 int elem_size,
                                 CompareFunction cmpFunc);

void DLLDIR __stdcall Quicksort(byte* array,
                                int size,
                                int elem_size,
                                CompareFunction cmpFunc);

These two functions take the following parameters:

  • byte* array: a pointer to an array of elements (doesn't matter of which type)
  • int size: the number of elements in the array
  • int elem_size: the size, in bytes, of an element of the array
  • CompareFunction cmpFunc: a pointer to a callback function with the prototype listed above

The implementation of these two functions performs a sorting of the array. But, each time there is a need to decide which of two elements goes first, a callback is made to the function whose address was passed as an argument. For the library writer, it doesn't matter where that function is implemented, or how it is implemented. All that matters it is that it takes the address of two elements (that are the two be compared) and it returns one of the following values (this is a contract between the library developers and its clients):

  • -1: if the first element is lesser and/or should go before the second element (in a sorted array)
  • 0: if the two elements are equal and/or their relative position doesn't matter (each one can go before the other in a sorted array)
  • 1: if the first element is greater and/or should go after the second element (in a sorted array)

With this contract explicitly stated, the implementation of the Bubblesort() function is this (for Quicksort(), which a little bit more complicated, see the attached files).

void DLLDIR __stdcall Bubblesort(byte* array,
                                 int size,
                                 int elem_size,
                                 CompareFunction cmpFunc)
{
   for(int i=0; i < size; i++)
   {
      for(int j=0; j < size-1; j++)
      {
         // make the callback to the comparison function
         if(1 == (*cmpFunc)(array+j*elem_size,
                  array+(j+1)*elem_size))
         {
            // the two compared elements must be interchanged
            byte* temp = new byte[elem_size];
            memcpy(temp, array+j*elem_size, elem_size);
            memcpy(array+j*elem_size,
                   array+(j+1)*elem_size,
                   elem_size);
            memcpy(array+(j+1)*elem_size, temp, elem_size);
            delete [] temp;
         }
      }
   }
}
Note: Because the implementation uses memcpy(), these library functions should not be used for types other than POD (Plain-Old-Data).

On the client side, there must be a callback function whose address is to be passed to the Bubblesort() function. As a simple example, I have written a function that compares two integer values and one that compares two strings:

int __stdcall CompareInts(const byte* velem1, const byte* velem2)
{
   int elem1 = *(int*)velem1;
   int elem2 = *(int*)velem2;

   if(elem1 < elem2)
      return -1;
   if(elem1 > elem2)
      return 1;

   return 0;
}

int __stdcall CompareStrings(const byte* velem1, const byte* velem2)
{
   const char* elem1 = (char*)velem1;
   const char* elem2 = (char*)velem2;

   return strcmp(elem1, elem2);
}

To put all these to a test, I have written this short program. It passes an array with five elements to Bubblesort() or Quicksort() along with the pointer to the callback functions.

int main(int argc, char* argv[])
{
   int i;
   int array[] = {5432, 4321, 3210, 2109, 1098};

   cout << "Before sorting ints with Bubblesort\n";
   for(i=0; i < 5; i++)
      cout << array[i] << '\n';

   Bubblesort((byte*)array, 5, sizeof(array[0]), &CompareInts);

   cout << "After the sorting\n";
   for(i=0; i < 5; i++)
      cout << array[i] << '\n';

   const char str[5][10] = {"estella",
                            "danielle",
                            "crissy",
                            "bo",
                            "angie"};

   cout << "Before sorting strings with Quicksort\n";
   for(i=0; i < 5; i++)
      cout << str[i] << '\n';

   Quicksort((byte*)str, 5, 10, &CompareStrings);

   cout << "After the sorting\n";
   for(i=0; i < 5; i++)
      cout << str[i] << '\n';

   return 0;
}

If I decide that I want the sorting to be done descending (with the biggest element first), all I have to do is to change the callback function code, or provide another that implements the desired logic.

Calling Conventions

In the above code, you can see the word __stdcall in the function's prototype. Because it starts with a double underscore, it is, of course, a compiler-specific extension, more exactly a Microsoft-specific one. Any compiler that supports development of Win32-based applications must support this or an equivalent one. A function that is marked with __stdcall uses the standard calling convention so named because all Win32 API functions (except the few that take variable arguments) use it. Functions that follow the standard calling convention remove the parameters from the stack before they return to the caller. This is the standard convention for Pascal. But in C/C++, the calling convention is that the caller cleans up the stack instead of the called function. To enforce that a function uses the C/C++ calling convention, __cdeclmust be used. Variable argument functions use the C/C++ calling convention.

Windows adopted the standard calling convention (Pascal convention) because it reduces the size of the code. This was very important in the early days of Windows, when it ran on systems with 640 KB RAM.

If you don't like the word __stdcall, you can use the CALLBACK macro, defined in windef.h, as

#define CALLBACK    __stdcall

or

#define CALLBACK    PASCAL

where PASCAL is #defined as __stdcall.

You can read more about calling convention here: Calling Convetions in Microsoft Visual C++.

C++ Methods as Callback Functions

Because you probably write in C++, you want your callback function a method of a class. But, if you try this:

class CCallbackTester
{
public:
   int CALLBACK CompareInts(const byte* velem1, const byte* velem2);
};

Bubblesort((byte*)array, 5, sizeof(array[0]),
           &CCallbackTester::CompareInts);

with a MS compiler, you get this compilation error:

error C2664: 'Bubblesort' : cannot convert parameter 4 from 'int (__stdcall CCallbackTester::*)(const unsigned char *,const unsigned char *)' to 'int (__stdcall *)(const unsigned char *,const unsigned char *)' There is no context in which this conversion is possible

That happens because non-static member functions have an additional parameter, pointer this (see thisFAQ for more).

That obliges you to make the member function static. If that's not acceptable, you can use several techniques to overcome that. Check the following links to learn more.

Notices

The attached files contain two projects. SortingDLL is a Win32 DLL project. The sort.dll output library exports the two sorting functions, Bubblesort() and Quicksort(). The second project, SortDemo, is a Win32 Console Application that demonstrates how to use the sort.dll library. The output directory for both projects is Shared directory, where the following files can be found: sort.h, sort.dll, sort.lib, and SortDemo.exe.

Further References

About the Author

Marius Bancila is a Microsoft MVP for VC++. He works as a software developer for a Norwegian-based company. He is mainly focused on building desktop applications with MFC and VC#. He keeps a blog at www.mariusbancila.ro/blog, focused on Windows programming. He is the co-founder of codexpert.ro, a community for Romanian C++/VC++ programmers.

Downloads

  • callbacks.zip
  • posted on 2011-01-24 20:26 huangyi5209 阅读(781) 评论(0)  编辑 收藏 引用 所属分类: C/C++

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