# Which one is faster and why?

``````(n >= 3 ) && (n <= 99)
``````

OR

`````` n `elem` [3..99]
``````

Which one is faster and why?

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The first one is faster

`````` (n >= 3) && (n <= 99)
``````

it is doing 3 operations

`````` n >= 3
n <= 99
and
``````

Where as the elem is looking up the item in the array, so is doing upto (99 - 3) * 2 operations.

``````index = 0
isFound = false
array[] = { 3, 4, 5, 6, ... 98, 99 }

while isFound == false
isFound = (n == array[index++])
``````
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Is this how `elem` is actually implemented? Is there really no black magic?? at all?? :) –  Pratik Deoghare Mar 11 '10 at 9:49
What "black magic" would you expect? Even if under the hood the compiler recognises [3..99] is a range and preformed a range check it would still only be the same as (n >= 3) && (n <= 99) –  Dead account Mar 11 '10 at 9:56
I'm guessing that you could get GHC to optimize this particular case by using a rewrite rule a la `"elem/enumFromTo" forall x lo hi. elem x (enumFromTo lo hi) = (x >= lo && x <= hi)`. I've never done anything with rewrite rules though (too much like black magic ;-), so take this with a big pinch of salt! –  yatima2975 Mar 11 '10 at 11:23
So I conclude that there is NO black magic! ;)) +1A I like answers with code. –  Pratik Deoghare Mar 11 '10 at 12:11
Well, `elem` has no way of knowing what list it's used on: in particular, the information that it comes from an expression like `[3..99]` is gone at runtime. Think about how to compute `elem n (3 : 4 : 50000 : [6..99]` and you'll see that elem has to go through all the elements. As for the question in your first comment: see the source of Data.List : haskell.org/ghc/docs/latest/html/libraries/base/src/… for the definition (it doesn't involve arrays) –  yatima2975 Mar 11 '10 at 14:54

(n >= 3) && (n <= 99) is faster as it involves only two trivial comparisons. If the compiler/interpreter does not do any kind of real black magic optimization it has to construct the list ([3..99]) because lazy evaluation cannot be used (normally "pulling" the next value until you're done, which would have a complexity of O(n/2) in this case).

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+1 Welcome to stackoverflow :) –  Dead account Mar 11 '10 at 9:44
+1 So there is no black magic though I was expecting some :) also welcome to SO! –  Pratik Deoghare Mar 11 '10 at 9:48

These two expressions don't mean the same thing. A subtle difference is that one relies on `Ord` and the other on `Enum`:

``````> :t \n -> (n >= 3) && (n <= 99)
\n -> (n >= 3) && (n <= 99) :: (Num a, Ord a) => a -> Bool

> :t \n -> n `elem` [3..99]
\n -> n `elem` [3..99] :: (Num a, Enum a) => a -> Bool
``````

So, for example, if n is 3.14159, then the first test will pass, but the second won't:

``````> (pi >= 3) && (pi <= 99)
True

> pi `elem` [3..99]
False
``````

Further, while the four Prelude `Num` instances (`Int`, `Integer`, `Float`, and `Double`) are all instances of both `Ord` and `Enum`, it is possible to imagine a numeric type that is an instance of `Ord` but not `Enum`. In such a case, then the second test wouldn't even be legal.

Hence, in general, the compiler can't optomize the second to be as fast as the first unless it knows for a given type, that it is `Ord` and that all ordered values in the range are also in the list enumeration created by `enumFromTo`. For `Float` and `Double` this isn't true, and for `Int` and `Integer` there is no way for the compiler to derive it, the compiler and library programmers would have to hand code it and ensure it held in all cases.

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