# Break time, find any triple which matches pythagoras equation in O(n^2)

I think it's interesting to solve this in holiday:

Given `n` integers, all of them within `1..n^3`, find if there is a triple which matches pythagoras equation in O(n^2).

As you know pythagoras equation is `a^2 + b^2 = c^2`. for example `3^2 + 4^2 = 5^2`.

As you know O(n^2 log n) is easy (with a little thinking), but will help to solve O(n^2). (space is not important).

Edit: As yi_H offered there is lookup table which can solve this problem easily, but for making it harder, space limit is O(n^2).

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O(n2) time, O(n) space: square all array elements, sort, for each z in the array use the classic linear-time algorithm to determine whether there exist x, y in the array such that x + y = z.

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I like this idea. No need hashes or any memory allocations at all - you can just run it in-place in your input array. You might want to explain the "classic linear-time algorithm", though - I had not heard of that before, though it's easy to figure out if you think about it for a bit. –  Daniel Sep 17 '11 at 15:04
@Daniel Keep two array indices, one initially at the beginning and one initially at the end. If the sum of the elements at the current indices is too large, then the larger element cannot be involved in the solution – decrease the greater index. If the sum is too small, then the smaller element cannot be involved – increase the lesser index. Stop when the indices cross. –  the guy formerly known as d Sep 17 '11 at 15:29
+1 nice, but how you can find x+y=z in O(n^2)? –  Saeed Amiri Sep 17 '11 at 16:25
@Saeed Amiri Use the above O(n) algorithm n times (once for each z). –  the guy formerly known as d Sep 17 '11 at 16:31
Nice one. Simple and fast. –  ypercube Sep 17 '11 at 21:58

All pythagorean triplets `(a,b,c)` have the following relation:

``````a = d * (2 * m * n)
b = d * (m^2 - n^2)
c = d * (m^2 + n^2)
``````

where

``````d >= 1  and  (m,n) = 1
``````

(meaning: `m` and `n` have no comomn factor.

I guess one can find an algorithm to produce all triplets that are below `n^3` using this info.

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+1 nice equations but still you have 3 different variables, (m,n,d). –  Saeed Amiri Sep 17 '11 at 13:29
also, how many triplets are there? –  Karoly Horvath Sep 17 '11 at 13:36
@Saeed: I'm reading again your description. You have `n` integers that are in `1..n^3` range. The equations would be more helpful if you had ALL numbers in the `1..n^3` range. –  ypercube Sep 17 '11 at 13:41
@ypercube, I think you should develop with more detail your idea, I have a little complicated algorithmic way to solve this problem, but If you find a simple one with math it would be nice. –  Saeed Amiri Sep 17 '11 at 16:22
No, I think the @the guy formerly known as d has the best approach. Mine would work better if you had more numbers in the check-list, in the order of `O(n^3)`. –  ypercube Sep 17 '11 at 21:58

I guess O(n^2 log n) would be to sort the numbers, take any two pairs (O(n^2)) and see whether there is `c` in the number for which `c^2 = a^2 + b^2`. You can do the lookup for `c` with binary search, that's O(log(n)).

Now if space isn't an issue you can create a hash for all the values in O(n), then you can look up `c` in this hash with O(1), so it's going to be O(n^2). You can even create an lookup table for it since the numbers are between 1..n^2, so it's going to be a guaranteed O(1) lookup ;) You can also use a special lookup table which can do initialization, add and lookup in O(1).

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Hash is good idea but searching in hash is amortized O(1), not all the times for any input. –  Saeed Amiri Sep 17 '11 at 12:53
hehe, I just updated my answer to fix that small issue. –  Karoly Horvath Sep 17 '11 at 12:54
Also hash may be cause to collision, it's depend on input size and the hash size you should to take, also creation of big hash (which prevent collision) may be cause bigger than O(n^2) time, I don't know should show this mathmatically. –  Saeed Amiri Sep 17 '11 at 12:55
if you choose the hash function to be the identity function you end up with a lookup table. –  Karoly Horvath Sep 17 '11 at 12:57
there are lookup tables with O(1) initialization, insert, search and delete. MIT Introduction to algorithms, Exercises 11.1-4 is an example for it. It's not really difficult, now it's your turn to think about it;) –  Karoly Horvath Sep 17 '11 at 13:02