`filter`

has `n`

recursive calls, but you also do a copy operation on each iteration which takes `n`

, so you end up having Θ(n^2). If you implemented it 'properly' it should be Θ(n) though.

Same for `my_reverse`

.

Same for `revfilter_beta`

.

`revfilter_alpha`

just does a `filter`

and then a `reverse`

, so thats Θ(n^2 + n^2) = Θ(n^2).

EDIT: Let's look into `filter`

a bit more.

What you want to figure out is how many operations are performed relative to the size of the input. `O(n)`

means that at the very worst case, you will do on the order of `n`

operations. I say "on the order of" because you could, for example, do `O(n/2)`

operations, or `O(4n)`

, but the most important factor is `n`

. That is, as `n`

grows, the constant factor becomes less and less important, so we only look at the non-constant factor (`n`

in this case).

So, how many operations does `filter`

perform on a list of size `n`

?

Let's take it from the bottom up. What if `n`

is 0 - an empty list? Then it will just return an empty list. So let's say that's 1 operation.

What if `n`

is 1? It will check whether `lst[0]`

should be included - that check takes however long it takes to call `f`

- and then it will copy the rest of the list, and do a recursive call on that copy, which in this case is an empty list. so `filter(1)`

takes `f + copy(0) + filter(0)`

operations, where `copy(n)`

is how long it takes to copy a list, and `f`

is how long it takes to check whether an element should be included, assuming it takes the same amount of time for each element.

What about `filter(2)`

? It will do 1 check, then copy the rest of list and call `filter`

on the remainder: `f + copy(1) + filter(1)`

.

You can see the pattern already. `filter(n)`

takes `1 + copy(n-1) + filter(n-1)`

.

Now, `copy(n)`

is just `n`

- it takes `n`

operations to slice the list in that way. So we can simplify further: `filter(n) = f + n-1 + filter(n-1)`

.

Now you can try just expanding out `filter(n-1)`

a few times to see what happens:

```
filter(n) = f + n-1 + filter(n-1)
= 1 + n-1 + (f + n-2 + filter(n-2))
= f + n-1 + f + n-2 + filter(n-2)
= 2f + 2n-3 + filter(n-2)
= 2f + 2n-3 + (f + n-3 + filter(n-3))
= 3f + 3n-6 + filter(n-3)
= 3f + 3n-6 + (f + n-4 + filter(n-4))
= 4f + 4n-10 + filter(n-4)
= 5f + 5n-15 + filter(n-5)
...
```

Can we generalize for `x`

repetitions? That `1, 3, 6, 10, 15`

... sequence is the triangle numbers - that is, `1`

, `1+2`

, `1+2+3`

, `1+2+3+4`

, etc. The sum of all numbers from `1`

to `x`

is `x*(x-1)/2`

.

```
= x*f + x*n - x*(x-1)/2 + filter(n-x)
```

Now, what is `x`

? How many repetitions will we have? Well, you can see that when `x`

= `n`

, you have no more recursion - `filter(n-n)`

=`filter(0)`

=`1`

. So our formula is now:

```
filter(n) = n*f + n*n - n*(n-1)/2 + 1
```

Which we can simplify further:

```
filter(n) = n*f + n^2 - (n^2 - n)/2 + 1
= n*f + n^2 - n^2/2 + n/2 + 1
= n^2 - n^2/2 + f*n + n/2 + 1
= (1/2)n^2 + (f + 1/2)n + 1
```

So there ya have it - a rather detailed analysis. That would be `Θ((1/2)n^2 + (f + 1/2)n + 1)`

... assuming `f`

is insignificant (say `f`

=1) that gets to `Θ((1/2)n^2 + (3/2)n + 1)`

.

Now you'll notice, if `copy(n)`

took a constant amount of time instead of a linear amount of time (if `copy(n)`

was 1 instead of `n`

), then you wouldn't get that `n^2`

term in there.

I'll admit, when I said `Θ(n^2)`

initially, I didn't do this all in my head. Rather, I figured: ok, you have `n`

recursive steps, and each step will take `n`

amount of time because of the `copy`

. `n*n = n^2`

, thus `Θ(n^2)`

. To do that a bit more exactly, `n`

shrinks at each step, so you really have `n + (n-1) + (n-2) + (n-3) + ... + 1`

, which ends up being that same figure as above: `n*n - (1 + 2 + 3 + ... + n)`

= `n*n - n*(n-1)/2`

= `(1/2)n^2 + (1/2)n`

, which is the same if I had used `0`

instead of `f`

, above. Likewise, if you had `n`

steps but each step took `1`

instead of `n`

(if you didn't have to copy the list), then you'd have `1 + 1 + 1 + ... + 1`

, `n`

times, or simply `n`

.

But, that requires a bit more intuition so I figured I'd also show you the brute force method that you can apply to anything.

`filter`

? Is it really`n * n`

? – Ja͢ck Oct 11 '12 at 1:37`filter`

is just as much a built in as`reverse`

you might as well call it`my_filter`

as well – Claudiu Oct 11 '12 at 1:46`Θ(n)`

provides tighter bounds than`O(n)`

. – J.F. Sebastian Oct 11 '12 at 3:49