Take the following:
int i = 10;
A corresponding pointer can be defined like this:
int* p = &i;
Variable "p" is very similar to "i", in that they are both numbers. However, the value of 'p' is the memory address of variable 'i', in other words, it is the exact memory address where value 10 is stored. Furthermore, 'p' knows the type of the value at that memory address. It knows it is an "int", since it was defined as "int" + "star".
Similarly, consider a function:
int m(char* arg1, double arg2)
/* do something */
C provides the ability to access the memory address of where this function is stored. A function is not like a value, e.g. it cannot be changed, so when one says the memory address of a function, this actually means the memory address where the code of the function is located, e.g. whatever is written between the curly braces.
However, there is a similarity between a function and a variable. They both have a type. A function's type is comprised of:
- Return Type
- Parameter Type List, namely:
- Type of parameter #1
- Type of parameter #2
- Type of parameter #N
C treats all functions that have the same return type and parameter type lists as "the same type of function". Similar to how two variables declared as "int i,j" are considered to be the same type, so are two functions with the same signature considered the same type.
The syntax for describing the type of a function includes the bare minimum: the return type and the types of each parameter (in the right order):
return-type (* <variable-name>)(Type-of-Param-1, Type-of-Param-2, ..., Type-of-Param-N)
In effect, in order to declare a pointer to function 'm' above:
int (*p)(char*, double) = &m;
"int" is the return type of method 'm', the fir pair of round brackets and the star are part of the syntax, 'p' is the variable name, "char*" is the type of the first parameter, and "double" is the tyep of the second parameter. There is no reference to the parameter names -- as the names of the parameters are not relevant to the type/signature of a function.
Note that similar to a variable, the address of a method is obtained exactly the same as for a variable, i.e. by prepending it with an ampersand.
Pointers to functions can be passed around simlar to pointers to variables, and more importantly, the code of the function at that particular memory address can be invoked. For example, in order to invoke function 'm' by means of pointer 'p', it would take something like this:
int result = p(NULL, 10.0);
int result = (*p) (NULL, 10.0); // alternative syntax