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I'm really confused at the documentation of isSomeFunction, as well as at the following code:

static assert(!isFunctionPointer!(typeof(Object.toString)));  // makes sense
static assert(!isDelegate!(typeof(Object.toString)));         // what??
static assert( isSomeFunction!(typeof(Object.toString)));     // what??

Could someone please explain the difference between a "function" and a "function pointer" to me?

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1 Answer

up vote 6 down vote accepted

Short Answer:

  • is(T == function)      Whether T is a function
  • isFunctionPointer!T  Whether T is a function pointer (and not a delegate)
  • isDelegate!T                Whether T is a delegate
  • isSomeFunction!T        Whether T is a function, a function pointer, or a delegate

Long Answer:

A function is, well, a function.

auto func(int val) {...}

It's a chunk of code with a name that you can call using that name. You give it arguments, it does whatever it does, and it returns a result. You can call it, but you can't pass it around. You need a function pointer for that.

A function pointer is a pointer to a function. So just like int is an int and int* is a pointer to an int, and int is not a pointer to int, a function isn't a function pointer. If you want a function pointer, you need a pointer to a function. The syntax is different from how it is with int, but it's the same concept.

A delegate is a function pointer with state. So for instance, in

int foo(int value)
{
    int bar()
    {
        return value + 5;
    }

    auto barDel = &bar;

    return barDel();
}

void main()
{
    auto fooFunc = &foo;
}

foo is a function, bar is a nested function which has access to its outer scope, and barDel is a delegate, because it's a function pointer with state (the outer state that bar has access to). If you pass barDel to another function (or return it), you'll get a closure (unless the function it's passed to takes the delegate by scope, in which case that function guarantees that the delegate will not escape its scope), because that state needs to be put on the heap so that it continues to exist even if the function call that its state comes from has completed when it's called. funcFoo, on the other hand, is a function pointer, because foo doesn't have any outer state. If bar were static, then barDel would also be a function pointer rather than a delegate, because bar would no longer have access to the function that it's in (though its body would then have to be changed, since it would no longer have access to value).

Now, as to your example. Object.toString is a member function of Object. So, it's a function. It has no state associated with it. Functions never do. Its current signature is

string toString();

But because it's a member function of Object, its signature is really something like

string toString(Object this);

this is passed to toString as an argument. It's not state associated with toString. So, &Object.toString is not a delegate. It's just a function pointer. And Object.toString isn't a function pointer, so even if &Object.toString were a delegate, static assert(isDelegate!(typeof(Object.toString))) would still fail, because in order to be a delegate, it must be a function pointer, which it's not. It's a function.

Now, unfortunately, typeof(&Object.toString) is considered to be string function() rather than string function(Object), so using it to call toString with an actual Object takes a bit of work. It can be done, but I don't remember how at the moment (and it's a bit ugly IIRC). But it wouldn't be a delegate regardless, because there's no state associated with it.

If you want a function that you can pass an Object to and have it call a member function, then you could do something like

auto obj = getObjectFromSomewhere();
auto func = function(Object obj){return obj.toString();};
auto result = func(obj);

If you want to associate an object with a member function and be able to call that member function on that object without having to pass the object around, then you just wrap it in a delegate:

auto obj = getObjectFromSomewhere();
auto del = delegate(){return obj.toString();};
auto result = del();

This bit of code should sum things up and illustrate things fairly well:

int foo(int value)
{
    int bar()
    {
        return value + 5;
    }

    static assert( is(typeof(bar) == function));
    static assert(!isFunctionPointer!(typeof(bar)));
    static assert(!isDelegate!(typeof(bar)));
    static assert( isSomeFunction!(typeof(bar)));

    auto barDel = &bar;
    static assert(!is(typeof(barDel) == function));
    static assert(!isFunctionPointer!(typeof(barDel)));
    static assert( isDelegate!(typeof(barDel)));
    static assert( isSomeFunction!(typeof(barDel)));

    static int boz(int i)
    {
        return i + 2;
    }

    static assert( is(typeof(boz) == function));
    static assert(!isFunctionPointer!(typeof(boz)));
    static assert(!isDelegate!(typeof(boz)));
    static assert(isSomeFunction!(typeof(boz)));

    auto bozFunc = &boz;
    static assert(!is(typeof(bozFunc) == function));
    static assert( isFunctionPointer!(typeof(bozFunc)));
    static assert(!isDelegate!(typeof(bozFunc)));
    static assert( isSomeFunction!(typeof(bozFunc)));

    return boz(bar());
}

static assert( is(typeof(foo) == function));
static assert(!isFunctionPointer!(typeof(foo)));
static assert(!isDelegate!(typeof(foo)));
static assert( isSomeFunction!(typeof(foo)));

void main()
{
    auto fooFunc = &foo;
    static assert(!is(typeof(fooFunc) == function));
    static assert( isFunctionPointer!(typeof(fooFunc)));
    static assert(!isDelegate!(typeof(fooFunc)));
    static assert( isSomeFunction!(typeof(fooFunc)));
}

static assert( is(typeof(Object.toString) == function));
static assert(!isFunctionPointer!(typeof(Object.toString)));
static assert(!isDelegate!(typeof(Object.toString)));
static assert( isSomeFunction!(typeof(Object.toString)));

static assert(!is(typeof(&Object.toString) == function));
static assert( isFunctionPointer!(typeof(&Object.toString)));
static assert(!isDelegate!(typeof(&Object.toString)));
static assert( isSomeFunction!(typeof(&Object.toString)));

isSomeFunction is true for all of them, because they're all either functions, function pointers without state, or delegates.

foo, bar, boz, and Object.toString are all functions, so they're true for is(T == function) but not for the others.

fooFunc, bozFunc, and &Object.toString are function pointers without state, so they're true for isFunctionPointer!T but not for the others.

barDel is a delegate, so it's true for isDelegate!T but not for the others.

Hopefully, that clears things up for you.

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Did you intend and int is not a pointer to int, to be and int is not a pointer to int*, ? –  jcolebrand Jun 17 '12 at 2:21
1  
@jcolebrand No. I meant what I said. int is not a pointer to int. int* is. It's the same with a function. A function is not a function pointer. And if isFunctionPointer!(Object.toString) were true, that would mean that a function was a function pointer, which would be like saying that int was a pointer to int. –  Jonathan M Davis Jun 17 '12 at 2:24
    
Ooooh, my bad, I misread that at first. Good that I asked then, in case someone else makes the same braindead thought leap I did. That was dumb of me. –  jcolebrand Jun 17 '12 at 2:26
1  
@jcolebrand Actually, in D, they're often not the same size, because int is always defined to be 32 bits, whereas int* is size_t whose size varies according to the architecture. It is 32 bits on a 32-bit system and so would be the same size as int in that case, but on a 64-bit system, it would be 64 bits, so it wouldn't be the same size. But I can see how you might make that leap, given that int and int* are often the same size in C/C++. –  Jonathan M Davis Jun 17 '12 at 2:32
1  
@jcolebrand Windows developers programming in D pretty much have to use 32-bit right now, because dmd does not yet support 64-bit code generation on Windows, but many developers on POSIX systems compile for 64-bit rather than 32-bit. So, assuming that int.sizeof == size_t.sizeof is definitely a bad idea. I certainly wouldn't say that int.sizeof == size_t.sizeof in the general case, but I could see why a Windows developer would think that way. –  Jonathan M Davis Jun 17 '12 at 2:49
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