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I was recently asked this question in a technical interview. Here is my solution. Did I make a mistake or is there a better solution?

Find the length of the longest non-decreasing sequence through adjacent, non-repeating cells (including diagonals) in a rectangular grid of numbers in a language of your choice. The solution should handle grids of arbitrary width and height.
For example, in the following grid, one legal path (though not the longest) that could be traced is 0->3->7->9 and its length would be 4.
8 2 4
0 7 1
3 7 9
The path can only connect adjacent locations (you could not connect 8 -> 9). The longest possible sequence for this example would be of length 6 by tracing the path 0->2->4->7->7->9 or 1->2->4->7->7->8.
Write a method, in a language of your choice, that takes a rectangular grid of numbers as input, and returns the length of the longest such sequence as output.

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closed as not a real question by David Nehme, luser droog, Blachshma, Stefan Steinegger, Graviton Apr 4 '13 at 6:31

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

Is there a restricion on what adjacent cells you can move to? For example, can you only move to the right and/or down? – abeln Mar 21 '13 at 16:47
Also, you have a v matrix in your code that is not being updated. – abeln Mar 21 '13 at 16:47
the v matrix(visited) is to keep track of the current path through the matrix and updated as a cell is visited. – user2196041 Mar 21 '13 at 16:52
The movement restrictions are just that the adjacent cell must be >= to the current cell and you can't visit a cell you've been to already. – user2196041 Mar 21 '13 at 16:58
You link is broken. (Which is exactly why) code should be pasted directly into the question, not linked to. And if it was code, I'd suggest changing it to a few lines of pseudo-code or a high-level description instead. – Dukeling May 24 '13 at 7:33

You can model your problem with directed graph:

Each cell is vertex in your graph and there is an edge from Ci,j→Ck,m if two cells Ci,j,Ck,m are adjacent and Ci,j < Ck,m.

Now your problem is finding longest path in this graph, but this graph is Directed acyclic graph, because as problem says there isn't repeated number in matrix also "<" relation is anti symmetric. So your problem reduced to find longest path in directed acyclic graph, which is easy by first doing topological sort then finding longest path . e.g see this.

Update: At first glance I thought is impossible to have equal neighbors but now I see is possible, In the above graph construction we should replace < with <= then sure graph is not acyclic but still problem is equal to find the longest path in this graph.

P.S1: If I have any polynomial answer for this longest path problem I'll bring it here, but may be by this classification of problem is easier to search around it.

P.S2: as mbeckish mentioned in comments, the longest path problem is NP-Hard in general graph, but I think in this special case can be solved in P, but I don't have exact algorithm right now.

P.S3: I do a little research on it, I saw, Hamiltonian path in grid graph is NP-Complete, So seems your problem is also NP-Complete (I don't have reduction right now but they are very close to each other).

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I thought about using a directed graph, but in this case there can be repeated adjacent numbers potentially creating a cycle. So a simple topological sort through a DAG doesn't help much. – user2196041 Mar 21 '13 at 17:24
Your criteria "Ci,j < Ck,m" is strictly increasing, not strictly non-decreasing. If you change it to "Ci,j <= Ck,m", then you have to also check for cycles every time you add an edge where Ci,j = Ck,m. – mbeckish Mar 21 '13 at 17:24
@mbeckish, See problem statement: "non-repeating cells" means two neighbor are not equal at all, I used this fact to say it's anti-symmetric. Also user2196041 I think I answered to you by this comment. – Saeed Amiri Mar 21 '13 at 17:26
@SaeedAmiri - You are correct. The question is just worded poorly. – mbeckish Mar 21 '13 at 17:28
Using @user2196041's interpretation, your graph will have cycles, which would turn this into the Longest Path Problem, which is NP-Hard. – mbeckish Mar 21 '13 at 17:52

Your solution takes exponential time (in the size of the matrix) in the worst case.

To speed it up, use memoization, or bottom-up dynamic programming.

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I doubt that OP can change his algorithm to bottom up one, because visited and unvisited case in his algorithm is not easy to change, would you show that how he can improve mentioned algorithm to run it in P? – Saeed Amiri Mar 21 '13 at 17:09

Also using n dijkstra calls (reverse it to find max path) you can solve it in O(n^3). Using a max heap can lower it to 0(n^2 log n). When building the graph, only create edges to neighbors that are >= to the current vertex.

I tried the topological sorting but I found cycles in the graph. Need to check my code.

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If by reversing Dijkstra we can find longest path then we can show that P=NP. – Saeed Amiri Mar 21 '13 at 18:34
Good point Saeed, longest path is an NP problem. Do you have a counterexample for an unweighted graph like the one described in this problem? – richard Mar 21 '13 at 20:34
If you define your graph as my way and define edge weight as 1, then there are tones of counterexample furthermore when you claim something you should prove it not looking for counterexample and if you see there is no counter example saying it's correct, I'd offer you to read about russel's teepot – Saeed Amiri Mar 21 '13 at 22:31
Don't get me wrong, I'm not claiming my solution is correct. In fact, I did say you had a good point about N=NP. Just wanted to see if you had a counterexample handy. – richard Mar 21 '13 at 23:17
I know you didn't claim this (because of this I just left a comment for you), and I know you just looking for handy counterexample, but as I said your graph definition is not clear to me, Also if I suggest you to check Russel's teepot is just for your information in general and for your future not this answer, because is simple to fall in this trap. – Saeed Amiri Mar 22 '13 at 0:48

It seems to me that the starting indexes not to test are those that are included in longer paths, which include all the lists of allowed 'next indexes' for all indexes.

So I first mapped the allowed next indexes for each index and removed all of them from the group of starting indexes to test:

*Main> indexesIncludedInLongerPaths
[2,0,4,6,1,7,8] (numbers 4,8,7,3,2,7,9)

which left two indexes to test:

*Main> indexesToTest
[3,5] (numbers 0,1)

After that, I searched all paths from those starting indexes and returned the longest.

*Main> nonDesc matrix

Haskell code:

import Data.List (nub, delete, sortBy, groupBy)

matrix = [8,2,4
m = 3
n = 3

neighbors index
  | index == 0           = [1,m]
  | index == m - 1       = [m-2, 2*m-1, 2*m-2]
  | index == m*n - 1     = [m*n-2, m*(n-1)-1, m*(n-1)-2]
  | index == m*(n-1)     = [m*(n-1)+1, m*(n-2), m*(n-2)+1]
  | index < m            = [index+1, index-1, index+m, index+m-1, index+m+1]
  | index > m*(n-1)      = [index+1, index-1, index-m, index-m-1, index-m+1]
  | mod index m == 0     = [index+1, index-m, index+m, index-m+1, index+m+1]
  | mod (index+1) m == 0 = [index-1, index-m, index+m, index-m-1, index+m-1]
  | otherwise            = [index+1, index-1, index-m, index+m
                           ,index-m+1, index-m-1, index+m+1, index+m-1]

indexesIncludedInLongerPaths = 
  nub $ concatMap (\x -> [a | a <- neighbors x
                              ,matrix!!x <= matrix!!a]) [0..length matrix-1]

indexesToTest = 
  foldr (\a b -> delete a b) [0..length matrix-1] indexesIncludedInLongerPaths

nonDesc matrix = solve indexesToTest [[]] where
  solve []     result = last $ groupBy (\a b -> length a == length b)
                        $ sortBy (\a b -> compare (length a) (length b)) 
                        $ map (\x -> map (\y -> matrix!!y) x) (concat result)
  solve (x:xs) result = 
    let paths = solve' [x] 
    in solve xs (paths:result)         
      where solve' y = 
              let b = [a | a <- neighbors (last y)
                                ,notElem a y
                                ,matrix!!(last y) <= matrix!!a]
              in if null b
                    then return y
                    else do a <- b
                            solve' (y ++ [a])
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