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you get a number x and you have to set the all the from 1 to x twic in an array of size 2x. the rule is the numbers have to be placed in a cell that is the difference from their value. for example if you set the number 2 like this: |2| | | | | the bex one has to be like this: |2| |2| | |

let's say x=4, then we have an array of 8 cells and we can set the numbers like this: 1 2 3 4 5 6 7 8 |4|2|3|2|4|3|1|1|

you can place the number in various ways.

can you do the same for the number 10 (array size 20), 12(array size 24)? if yes, show how, if not explain why for each number.

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closed as too localized by Andy Hayden, Blachshma, Uwe Keim, Jens Björnhager, InfantPro'Aravind' Dec 8 '12 at 15:12

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Is it homework? If so - please tag it as such. What exactly are you looking for? A general case algorithm? What complexity are you expecting? Last but not least: What did you try? –  amit Aug 19 '12 at 8:49
I saw that it only works on 1, 4 and 5. It doesn't work on 10 or 12 (and for that matter on 2, 3, 6, 7 and 8 as well). Each time I try to place a number I start from the top and skips on a cell until the middle. My theory is that it only works on this numbers: 1, 4 and 5 . –  moria am Aug 19 '12 at 9:03
@MoriaAM: Judging from the pattern I can see in my answer, I think it works for any x equivalent to 0 or 1 mod 4. –  Mark Byers Aug 19 '12 at 9:09

2 Answers 2

up vote 0 down vote accepted

This problem is NP-Complete you must try all possibilities to determine feasibility and to get a result set of possible solutions.

If you want a yes/no answer to whether it can be done that is defined by the function 1/2(4n + (-1)^n - 1), plugging values of n starting at 1...infinity will give you the sequence of numbers that are yes answers. Proof not included :)

To clarify, the solution set finding is NP-Complete and the yes/no answer for a given N can be done using the above formula. (I hope I haven't fudged the math on that one, its a generating function)

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This problem is NP-Complete: proof/source? Also - if the above formula is correct - the problem is not NP-Complete, because using this function - you can easily evaluate if there is a solution in polynomial time. –  amit Aug 19 '12 at 9:39
@amit Generating all solutions of the problem is NP-Complete, generating a yes or no on whether for a given N it works is not. It can be shown using combinatorics based on the initial placement of any number. Initial placement in the worst case cannot reduce the problem size significantly in some cases. –  Jesus Ramos Aug 20 '12 at 5:23
NP-Hardness of problems deals with Languages. For example, the TSP is L={(G,k) | The graph G has a cyclic shortest path with weight k }. As I see it, in here the language is L={n | | There is a solution to n} , which is easily solved according to you. This concept is similar to the Euler Path Problem (Given a graph - does it have an eularian path?) - which is NOT NP-Hard –  amit Aug 20 '12 at 5:44
@amit Giving a yes/no is simple. Giving a solution which is a 2x sized array with the numbers in any correct sequence (the if yes show how part of the question) is NP-Complete. –  Jesus Ramos Aug 20 '12 at 6:19
What is the language to the NP-Complete problem? Remember that NP-Complete is a class of languages, so - what is the language? can you define it formally? –  amit Aug 20 '12 at 6:27

It is not possible with 10. It is possible with 12. I tried for all integers up to 13, and there is a clear pattern which I'm sure can be proven (but I can't see how at the moment):

1  yes
2  no
3  no
4  yes
5  yes
6  no
7  no
8  yes
9  yes
10 no
11 no
12 yes
13 yes

It can be solved with a recursive function that tries every possibility, using backtracking if a match cannot be found.

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