# Natural problems to solve using closures

I have read quite a few articles on closures, and, embarassingly enough, I still don't understand this concept! Articles explain how to create a closure with a few examples, but I don't see any point in paying much attention to them, as they largely look contrived examples. I am not saying all of them are contrived, just that the ones I found looked contrived, and I dint see how even after understanding them, I will be able to use them. So in order to understand closures, I am looking at a few real problems, that can be solved very naturally using closures.

For instance, a natural way to explain recursion to a person could be to explain the computation of n!. It is very natural to understand a problem like computing the factorial of a number using recursion. Similarly, it is almost a no-brainer to find an element in an unsorted array by reading each element, and comparing with the number in question. Also, at a different level, doing Object-oriented programming also makes sense.

So I am trying to find a number of problems that could be solved with or without closures, but using closures makes thinking about them and solving them easier. Also, there are two types to closures, where each call to a closure can create a copy of the environment variables, or reference the same variables. So what sort of problems can be solved more naturally in which of the closure implementations?

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Alright, say you're generating a menu in, say, javascript.

``````var menuItems = [
{ id: 1, text: 'Home' },
{ id: 2, text: 'About' },
{ id: 3, text: 'Contact' }
];
``````

And your creating them in a loop, like this:

``````for(var i = 0; i < menuItems.length; i++) {

var a = document.createElement('a');
a.href = '#';

// assign onclick listener

}
``````

Now, for the onclick listener, you might attempt something like this:

``````a.addEventListener('click', function() {
}, false);
``````

But you'll find that this will have every link alert '3'. Because at the time of the click, your onclick code is executed, and the value of `menuItem` is evaluated to the last item, since that was the value it was last assigned, upon the last iteration of the for loop.

Instead, what you can do is to create a new closure for each link, using the value of `menuItem` as it is at that point in execution

``````a.addEventListener('click', (function(item) {
return function() {
}
``````

So what's going on here? We're actually creating a function that accepts `item` and then immediately call that function, passing `menuItem`. So that 'wrapper' function is not what will be executed when you click the link. We're executing it immediately, and assigning the returned function as the click handler.

What happens here is that, for each iteration, the function is called with a new value of `menuItem`, and a function is returned which has access to that value, which is effectively creating a new closure.

Hope that cleared things up =)

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quite a bit actually! –  umar May 19 '10 at 16:26

Callbacks are a great example. Let's take JavaScript.

Imagine you have a news site, with headlines and short blurbs and "Read More..." buttons next to each one. When the user clicks the button, you want to asynchronously load the content corresponding to the clicked button, and present the user with an indicator next to the requested headline so that the user can "see the page working at it".

``````function handleClickOnReadMore(element) {
// the user clicked on one of our 17 "request more info" buttons.
// we'll put a whirly gif next to the clicked one so the user knows
// what he's waiting for...
spinner = makeSpinnerNextTo(element);

// now get the data from the server
performAJAXRequest('http://example.com/',
function(response) {
handleResponse(response);

// this is where the closure comes in
// the identity of the spinner did not
// go through the response, but the handler
// still knows it, even seconds later,
// because the closure remembers it.
stopSpinner(spinner);
}
);
}
``````
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Personally I hated to write sort routines when I had a list of objects.
Usually you had the sort function and a separate function to compare the two objects.
Now you can do it in one statement

``````List<Person> fList = new List<Person>();
fList.Sort((a, b) => a.Age.CompareTo(b.Age));
``````
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This is a good example. Trying to "naturalize" it, I see that the sort routine doesnt know how to compare list elements beforehand, and passing it a comparator function is a good and natural use of closures –  umar May 19 '10 at 16:10
this is sorting, but you can as well add other collection operations like select, filter, map (collect), reduce (fold) and each (foreach). –  Gabriel Ščerbák May 20 '10 at 20:20
I disagree about this being a good example, because it does not really demonstrate the power of the closure concept. The reason is, it does not show how closure captures the local environment, since the comparator here does not use any variables aside from its parameters, which is the defining characteristic of a closure. What this does demonstrate is an anonymous function - which, incidentally, is a closure in most languages, but is not necessarily so (anonymous functions that are not closures are possible, just decidedly less useful). –  Amadan May 23 '10 at 15:50

Well, after some time, spent with Scala, I can not imagine a code, operating on some list without closures. Example:

``````val multiplier = (i:Int) => i * 2
val list1 = List(1, 2, 3, 4, 5) map multiplier

val divider = (i:Int) => i / 2
val list2 = List(1, 2, 3, 4, 5) map divider

val map = list1 zip list2

println(map)
``````

The output would be

``````List((2,0), (4,1), (6,1), (8,2), (10,2))
``````

I'm not sure, if it is the example, you are looking for, but I personally think, that best examples of closures's real power can be seen on lists-examples: all kinds of sortings, searchings, iterating, etc.

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Sorry, but that's just an example of anonymous functions/HOF, since there's no reference to out-of-scope variables. –  Hugo S Ferreira Feb 20 '13 at 0:48

In C#, a function can implement the concept of filtering by proximity to a point:

``````IEnumerable<Point> WithinRadius(this IEnumerable<Point> points, Point c, double r)
{
return points.Where(p => (p - c).Length <= r);
}
``````

The lambda (closure) captures the supplied parameters and binds them up into a computation that will performed at some later time.

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My point is, why should i try to use closure to do that? and why would i want to not perform the computation there and then? any advantages i will get by deferring the computation? –  umar May 19 '10 at 13:45
What if `IEnumerable<Point>` is an infinite sequence? –  Marcelo Cantos May 19 '10 at 13:56
@m.u.sheikh: I don't know about you, but I would use a closure to do that because it leads to significantly less code (and more importantly less code duplication) than the alternative. –  sepp2k May 19 '10 at 14:15

Well, I use Closures on a daily basis in the form of a function composition operator and a curry operator, both are implemented in Scheme by closures:

Quicksort in Scheme for instance:

``````(define (qsort lst cmp)
(if (null? lst) lst
(let* ((pivot (car lst))
(stacks (split-by (cdr lst) (curry cmp pivot))))
(cons pivot
(qsort (car stacks) cmp))))))
``````

Where I cmp is a binary function usually applied as (cmp one two), I curried it in this case to split my stack in two by creating a unitary predicate if you like, my curry operators:

``````(define (curry f . args)
(lambda lst (apply f (append args lst))))

(define (curryl f . args)
(lambda lst (apply f (append lst args))))
``````

Which respectively curry righthanded and lefthanded.

So currying is a good example of closures, another example is functional composition. Or for instance a function which takes list and makes from that a predicate that tests if its argument is a member of that list or not, that's a closure too.

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