# Why do function pointer definitions work with any number of ampersands '&' or asterisks '*'?

Why do the following work?

``````void foo() {
cout << "Foo to you too!\n";
};

int main() {
void (*p1_foo)() = foo;
void (*p2_foo)() = *foo;
void (*p3_foo)() = &foo;
void (*p4_foo)() = *&foo;
void (*p5_foo)() = &*foo;
void (*p6_foo)() = **foo;
void (*p7_foo)() = **********************foo;

(*p1_foo)();
(*p2_foo)();
(*p3_foo)();
(*p4_foo)();
(*p5_foo)();
(*p6_foo)();
(*p7_foo)();
}
``````

There are a few pieces to this that allow all of these combinations of operators to work the same way.

The fundamental reason why all of these work is that a function (like `foo`) is implicitly convertible to a pointer to the function. This is why `void (*p1_foo)() = foo;` works: `foo` is implicitly converted into a pointer to itself and that pointer is assigned to `p1_foo`.

The unary `&`, when applied to a function, yields a pointer to the function, just like it yields the address of an object when it is applied to an object. For pointers to ordinary functions, it is always redundant because of the implicit function-to-function-pointer conversion. In any case, this is why `void (*p3_foo)() = &foo;` works.

The unary `*`, when applied to a function pointer, yields the pointed-to function, just like it yields the pointed-to object when it is applied to an ordinary pointer to an object.

These rules can be combined. Consider your second to last example, `**foo`:

• First, `foo` is implicitly converted to a pointer to itself and the first `*` is applied to that function pointer, yielding the function `foo` again.
• Then, the result is again implicitly converted to a pointer to itself and the second `*` is applied, again yielding the function `foo`.
• It is then implicitly converted to a function pointer again and assigned to the variable.

You can add as many `*`s as you like, the result is always the same. The more `*`s, the merrier.

We can also consider your fifth example, `&*foo`:

• First, `foo` is implicitly converted to a pointer to itself; the unary `*` is applied, yielding `foo` again.
• Then, the `&` is applied to `foo`, yielding a pointer to `foo`, which is assigned to the variable.

The `&` can only be applied to a function though, not to a function that has been converted to a function pointer (unless, of course, the function pointer is a variable, in which case the result is a pointer-to-a-pointer-to-a-function; for example, you could add to your list `void (**pp_foo)() = &p7_foo;`).

This is why `&&foo` doesn't work: `&foo` is not a function; it is a function pointer that is an rvalue. However, `&*&*&*&*&*&*foo` would work, as would `&******&foo`, because in both of those expressions the `&` is always applied to a function and not to an rvalue function pointer.

Note also that you do not need to use the unary `*` to make the call via the function pointer; both `(*p1_foo)();` and `(p1_foo)();` have the same result, again because of the function-to-function-pointer conversion.

• @Jimmy: Those aren't references to function pointers, they are just function pointers. `&foo` takes the address of `foo`, which results in a function pointer pointing at `foo`, as one would expect. Aug 1, 2011 at 0:59
• You can't chain `&` operators for objects either: given `int p;`, `&p` yields a pointer to `p` and is an rvalue expression; the `&` operator requires an lvalue expression. Aug 1, 2011 at 1:15
• I disagree. The more `*`'s, the less merry. Aug 1, 2011 at 1:28
• Please do not edit the syntax of my examples. I have picked the examples very specifically to demonstrate features of the language. Mar 4, 2012 at 5:58
• As a side note, the C standard explicitly states that a combination of `&*` cancel out each other (6.5.3.2): `"The unary & operator yields the address of its operand."` /--/ `"If the operand is the result of a unary * operator, neither that operator nor the & operator is evaluated and the result is as if both were omitted, except that the constraints on the operators still apply and the result is not an lvalue."`. Nov 30, 2015 at 15:21

I think it's also helpful to remember that C is just an abstraction for the underlying machine and this is one of the places where that abstraction is leaking.

From the perspective of the computer, a function is just a memory address which, if executed, performs other instructions. So a function in C is itself modelled as an address, which probably leads to the design that a function is "the same" as the address it points to.

`&` and `*` are idempotent operations on a symbol declared as a function in C which means `func == *func == &func == *&func` and therefore `*func == **func`, but they have different types, so you'll get a warning.

The parameter type of a passed function address to a function can be `int ()` or `int (*)()`, and it can be passed as `*func`, `func` or `&func`. Calling `(&func)()` is the same as `func()` or `(*func)()`. Godbolt link.

`*` and `&` have no meaning on a function symbol, and instead of producing an error, the compiler chooses to interpret it as the address of func in both cases. The function does not exist as a separate pointer, like an array symbol, therefore `&arr` is the same as `arr`, because it is not a physical pointer with an address at runtime, it's a logical pointer at compiler level. Furthermore `*func` would read the first byte of the function code, which is an a code section, and rather than produce a compiler error or allow it to be a runtime error segmentation fault, it's just interpreted by the compiler as the address of the function.

`&` on a symbol declared as a function pointer however will get the address of the pointer (because it is now an actual pointer variable that manifests on the stack or data section), whereas `funcp` and `*funcp` will still be interpreted to be the address of the function.

If you are still not very convinced with @JamesMcNellis's answer, here is a prove. This is the AST(abstract syntax tree) from Clang compiler. Abstract syntax tree is the internal representation of the program structure inside the compiler.

``````void func1() {};
void test() {
func1();
(*func1)();
(&func1)();

void(*func1ptr)(void) = func1;
func1ptr();
(*func1ptr)();
//(&func1ptr)();//error since func1ptr is a variable, &func1ptr is its address which is not callable.
}
``````

AST:

``````//func1();
|-CallExpr //call the pointer
| `-ImplicitCastExpr //implicitly convert func1 to pointer
|   `-DeclRefExpr //reference func1

//(*func1)();
|-CallExpr //call the pointer
| `-ImplicitCastExpr //implicitly convert the funtion to pointer
|   `-ParenExpr //parentheses
|     `-UnaryOperator //* operator get function from the pointer
|       `-ImplicitCastExpr //implicitly convert func1 to pointer
|         `-DeclRefExpr //reference func1

//(&func1)();
|-CallExpr //call the pointer
| `-ParenExpr //parentheses
|   `-UnaryOperator //& get pointer from func1
|     `-DeclRefExpr //reference func1

//void(*func1ptr)(void) = func1;
|-DeclStmt //define variable func1ptr
| `-VarDecl //define variable func1ptr
|   `-ImplicitCastExpr //implicitly convert func1 to pointer
|     `-DeclRefExpr  //reference func1

//func1ptr();
|-CallExpr  //call the pointer
| `-ImplicitCastExpr //implicitly convert func1ptr to pointer
|   `-DeclRefExpr //reference the variable func1ptr

//(*func1ptr)();
`-CallExpr //call the pointer
`-ImplicitCastExpr //implicitly convert the function to pointer
`-ParenExpr //parentheses
`-UnaryOperator //* get the function from the pointer
`-ImplicitCastExpr //implicitly convert func1ptr to pointer
`-DeclRefExpr //reference the variable func1ptr
``````

When calling `foo` from a pointer, even the parentheses and the asterisk can be omitted, just as directly calling the function with its original name, i.e. `(*p1_foo)()` is equivalent to `p1_foo()`.