So I've got the following expression:
int (*f1(int(*a)(int, int))) (int, int);
and I'm trying to make sense out of it, but it's confusing. I figured out that "a" is a pointer to a function which takes 2 arguments(int, int). Then f1 seems to be a pointer to another function that takes 2 int arguments. But what's confusing me is how f1 relates to a.
Can someone give me some hints or properly explain what the above expression is doing?
It declares f1 as a function with a single parameter called a. Both type of the parameter and return type are "pointer to function with two int parameters returning int".
Here's how you parse it:
// f1 is...
f1
// ...a function...
f1( )
// ...with a single parameter called `a`, which is...
f1( a )
// ...a pointer to...
f1( *a )
// (skip parentheses)
f1( (*a) )
// ...a function...
f1( (*a)( ))
// ...with two `int` parameters...
f1( (*a)(int, int))
// ...returning an `int`. The `f1` itself returns...
f1(int(*a)(int, int))
// ...a pointer to...
*f1(int(*a)(int, int))
// (skip parentheses)
(*f1(int(*a)(int, int)))
// ...a function...
(*f1(int(*a)(int, int))) ( )
// ...with two int parameters...
(*f1(int(*a)(int, int))) (int, int)
// ...returning an `int`.
int (*f1(int(*a)(int, int))) (int, int)
This is a declaration of the function f1 which takes a parameter a- a pointer to function which takes 2 ints as argument and returns an int - and returns a pointer to function of the same type.
Breaking it down with a typedef:
typedef int(*t)(int, int);
t f1(t a); //this is your declaration
The tip in C is to read a declaration as it were an expression. This is this famous symmetrie that make C elegant.
How to read it? following the operators precedence rules:
*a: if I dereference variable a;(*a)(int,int): and then call it with two integers;int (*a)(int,int): then I get an integer;So a is a pointer to a function taking two ints as parameter and returning an int.
Then:
f( int(*a)(int,int) ) if I call f with the argument a;*f( int(*a)(int,int) ) and then I dereference the result;(*f( int(*a)(int,int) )(int,int) and then call this result with 2 int as argumentint (*f( int(*a)(int,int) )(int,int) I get an intSo f is a function taking an a as argument and returning a pointer to a function that take two ints as argument and returning an int. So f return type is the same as its argument return type. It could have been simpler:
using ftype = int(*)(int,int);
ftype f( ftype a);
int &x; declares x as a reference to int, but it doesn't mean that &x has type int (it actually has type int*). So this is all true only if your declaration doesn't have references in it.
a is the name of f1's only parameter; when you remove it, then you can use https://cdecl.org/ to decipher the entire declaration:
declare f1 as function (pointer to function (int, int) returning int) returning pointer to function (int, int) returning int
So f1 is a function. It takes a function pointer (called a) and it returns a function pointer.
Both of those function pointers are for functions which take two ints and return an int.
Here is an example to see it all in action:
#include <iostream>
int passed(int x, int y) { std::cout << "passed\n"; return x * y; }
int returned(int x, int y) { std::cout << "returned\n"; return x + y; }
// a is redundant here, where we just declare f1:
int (*f1(int(*a)(int, int))) (int, int);
// but not here, where we define f1:
int (*f1(int(*a)(int, int))) (int, int)
{
std::cout << "f1\n";
int result_of_passed = a(10, 10);
std::cout << result_of_passed << '\n';
return returned;
}
int main()
{
int x = f1(passed)(10, 10);
std::cout << x << '\n';
}
Output:
f1
passed
100
returned
20
