# Algorithm to count the number of valid blocks in a permutation [duplicate]

Possible Duplicate:
Finding sorted sub-sequences in a permutation

Given an array A which holds a permutation of 1,2,...,n. A sub-block A[i..j]
of an array A is called a valid block if all the numbers appearing in A[i..j]
are consecutive numbers (may not be in order）.

Given an array A= [ 7 3 4 1 2 6 5 8] the valid blocks are [3 4], [1,2], [6,5],
[3 4 1 2], [3 4 1 2 6 5], [7 3 4 1 2 6 5], [7 3 4 1 2 6 5 8]

So the count for above permutation is 7.

Give an O( n log n) algorithm to count the number of valid blocks.

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## marked as duplicate by sdcvvc, Stephen, nlucaroni, wheaties, GravitonJul 28 '10 at 1:46

A quick google search reveals that it's been asked before on SO and another site, and no one figured it out. I haven't given it much thought, but if it's possible I'm guessing it involves some neat math trick. Congratulations to whoever figures it out... –  IVlad Jul 26 '10 at 23:09
Oh god, dynamic programming hurts my brain. –  sholsapp Jul 26 '10 at 23:45
You CANNOT do better than O(N^2) because in the trivial case of a sorted sequence you will have O(N^2) results. Interesting question. Dynamic programming or divide and conquer come to mind. –  Hamish Grubijan Jul 27 '10 at 0:25
@Nikita Rybak, ah ... they just want a total count. Must be a ridiculously clever algorithm. THIS IS LIKELY A TERRIBLE INTERVIEW QUESTION - most good developers will not solve it in the time given, and those who can might not work there anyway. –  Hamish Grubijan Jul 27 '10 at 0:43
Duplicate: stackoverflow.com/questions/1824388/…, with the same data and formulation –  sdcvvc Jul 27 '10 at 14:22

Ok, I am down to 1 rep because I put 200 bounty on a related question: http://stackoverflow.com/questions/1824388/finding-sorted-sub-sequences-in-a-permutation so I cannot leave comments for a while.

I have an idea: 1) Locate all permutation groups. They are: (78), (34), (12), (65). Unlike in group theory, their order and position, and whether they are adjacent matters. So, a group (78) can be represented as a structure (7, 8, false), while (34) would be (3,4,true). I am using Python's notation for tuples, but it is actually might be better to use a whole class for the group. Here true or false means contiguous or not. Two groups are "adjacent" if (max(gp1) == min(gp2) + 1 or max(gp2) == min(gp1) + 1) and contigous(gp1) and contiguos(gp2). This is not the only condition, for union(gp1, gp2) to be contiguous, because (14) and (23) combine into (14) nicely. This is a great question for algo class homework, but a terrible one for interview. I suspect this is homework.

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Just some thoughts:

At first sight, this sounds impossible: a fully sorted array would have O(n2) valid sub-blocks.

So, you would need to count more than one valid sub-block at a time. Checking the validity of a sub-block is O(n). Checking whether a sub-block is fully sorted is O(n) as well. A fully sorted sub-block contains n·(n - 1)/2 valid sub-blocks, which you can count without further breaking this sub-block up.

Now, the entire array is obviously always valid. For a divide-and-conquer approach, you would need to break this up. There are two conceivable breaking points: the location of the highest element, and that of the lowest element. If you break the array into two at one of these points, including the extremum in the part that contains the second-to-extreme element, there cannot be a valid sub-block crossing this break-point.

By always choosing the extremum that produces a more even split, this should work quite well (average O(n log n)) for "random" arrays. However, I can see problems when your input is something like (1 5 2 6 3 7 4 8), which seems to produce O(n2) behaviour. (1 4 7 2 5 8 3 6 9) would be similar (I hope you see the pattern). I currently see no trick to catch this kind of worse case, but it seems that it requires other splitting techniques.

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Every thing is possible, it is our mind that limit us. –  Damian Leszczyński - Vash Jul 27 '10 at 5:45

This question does involve a bit of a "math trick" but it's fairly straight forward once you get it. However, the rest of my solution won't fit the O(n log n) criteria.

The math portion:

For any two consecutive numbers their sum is 2k+1 where k is the smallest element. For three it is 3k+3, 4 : 4k+6 and for N such numbers it is Nk + sum(1,N-1). Hence, you need two steps which can be done simultaneously:

1. Create the sum of all the sub-arrays.
2. Determine the smallest element of a sub-array.

The dynamic programming portion

Build two tables using the results of the previous row's entries to build each successive row's entries. Unfortunately, I'm totally wrong as this would still necessitate n^2 sub-array checks. Ugh!

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My proposition

STEP = 2 // amount of examed number

B [0,0,0,0,0,0,0,0]

B [1,1,0,0,0,0,0,0]

VALID(A,B) - if not valid move one

B [0,1,1,0,0,0,0,0]

VALID(A,B) - if valid move one and step

B [0,0,0,1,1,0,0,0]

VALID (A,B)

B [0,0,0,0,0,1,1,0]

STEP = 3

B [1,1,1,0,0,0,0,0] not ok

B [0,1,1,1,0,0,0,0] ok

B [0,0,0,0,1,1,1,0] not ok

STEP = 4

B [1,1,1,1,0,0,0,0] not ok

B [0,1,1,1,1,0,0,0] ok

.....

CON <- 0
STEP <- 2
i <- 0
j <- 0
WHILE(STEP <= LEN(A)) DO
j <- STEP
WHILE(STEP <= LEN(A) - j) DO
IF(VALID(A,i,j)) DO
CON <- CON + 1
i <- j + 1
j <- j + STEP
ELSE
i <- i + 1
j <- j + 1
END
END
STEP <- STEP + 1
END


The valid method check that all elements are consecutive

Never tested but, might be ok

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Looks at least O(n^2) to me. Maybe even O(n^3) actually. –  IVlad Jul 26 '10 at 23:37
I think I could make VALID run in O(1) if one pre-populated some structure in O(N^2). For instance, it can be a hash table of a tuple(low, high) mapped to the value 1 << low | 1 << low + 1 | 1 << low + 2 ... | 1 << high -1 | 1 << high. This value could be computed on the fly, and so the amortized running time would be O(N^2) + O(NumResults), but numResults \in O(N^2), so it will be O(N^2). This is most useful for 64-bit integers only (which is a motherload of possibilities). If the size of N can grow arbitrarily, then one has to worry about the length of BigInt and then it'll take. –  Hamish Grubijan Jul 27 '10 at 0:31
@IVlad Yes, it is n^2... yesterday i was bit tired and i have forgot about this smal detail ;-), but it was some begining. Maby today i will came up with something new ;-). –  Damian Leszczyński - Vash Jul 27 '10 at 5:26
@Hamish Grubijan You have right but i think that You are complicating the job. THat we have assumption that we have to validate a table of permutation 1..n of consequntive number, so we need to check that value on the left or on the right is grater more than 2 if we found case like this whole part is not valid (ABS(A[i] - A[i+1]) == 1 || ABS(A[i] - A[i-1]) == 1) do not –  Damian Leszczyński - Vash Jul 27 '10 at 5:41

The original array doesn't contain duplicates so must itself be a consecutive block. Lets call this block (1 ~ n). We can test to see whether block (2 ~ n) is consecutive by checking if the first element is 1 or n which is O(1). Likewise we can test block (1 ~ n-1) by checking whether the last element is 1 or n.

I can't quite mould this into a solution that works but maybe it will help someone along...

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in the example You have 7 so it is not 1 or n. So nope. –  Damian Leszczyński - Vash Jul 27 '10 at 6:10
@Vash, yea I know it's not the right answer. I'm just trying to add to the discussion in the hope that someone will get it. –  Daniel Jul 27 '10 at 21:16

Like everybody else, I'm just throwing this out ... it works for the single example below, but YMMV!

The idea is to count the number of illegal sub-blocks, and subtract this from the total possible number. We count the illegal ones by examining each array element in turn and ruling out sub-blocks that include the element but not its predecessor or successor.

1. Foreach i in [1,N], compute B[A[i]] = i.

2. Let Count = the total number of sub-blocks with length>1, which is N-choose-2 (one for each possible combination of starting and ending index).

3. Foreach i, consider A[i]. Ignoring edge cases, let x=A[i]-1, and let y=A[i]+1. A[i] cannot participate in any sub-block that does not include x or y. Let iX=B[x] and iY=B[y]. There are several cases to be treated independently here. The general case is that iX<i<iY<i. In this case, we can eliminate the sub-block A[iX+1 .. iY-1] and all intervening blocks containing i. There are (i - iX + 1) * (iY - i + 1) such sub-blocks, so call this number Eliminated. (Other cases left as an exercise for the reader, as are those edge cases.) Set Count = Count - Eliminated.

4. Return Count.

The total cost appears to be N * (cost of step 2) = O(N).

WRINKLE: In step 2, we must be careful not to eliminate each sub-interval more than once. We can accomplish this by only eliminating sub-intervals that lie fully or partly to the right of position i.

Example:
A = [1, 3, 2, 4] B = [1, 3, 2, 4]

Initial count = (4*3)/2 = 6

i=1: A[i]=1, so need sub-blocks with 2 in them. We can eliminate [1,3] from consideration. Eliminated = 1, Count -> 5.

i=2: A[i]=3, so need sub-blocks with 2 or 4 in them. This rules out [1,3] but we already accounted for it when looking right from i=1. Eliminated = 0.

i=3: A[i] = 2, so need sub-blocks with [1] or [3] in them. We can eliminate [2,4] from consideration. Eliminated = 1, Count -> 4.

i=4: A[i] = 4, so we need sub-blocks with [3] in them. This rules out [2,4] but we already accounted for it when looking right from i=3. Eliminated = 0.

Final Count = 4, corresponding to the sub-blocks [1,3,2,4], [1,3,2], [3,2,4] and [3,2].

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(This is an attempt to do this N.log(N) worst case. Unfortunately it's wrong -- it sometimes undercounts. It incorrectly assumes you can find all the blocks by looking at only adjacent pairs of smaller valid blocks. In fact you have to look at triplets, quadruples, etc, to get all the larger blocks.)

You do it with a struct that represents a subblock and a queue for subblocks.

  struct
c_subblock
{
int           index   ;  /* index into original array, head of subblock */
int           width   ;  /* width of subblock > 0 */
int           lo_value;
c_subblock *  p_above ;  /* null or subblock above with same index */
};


Alloc an array of subblocks the same size as the original array, and init each subblock to have exactly one item in it. Add them to the queue as you go. If you start with array [ 7 3 4 1 2 6 5 8 ] you will end up with a queue like this:

queue: ( [7,7] [3,3] [4,4] [1,1] [2,2] [6,6] [5,5] [8,8] )

The { index, width, lo_value, p_above } values for subbblock [7,7] will be { 0, 1, 7, null }.

Now it's easy. Forgive the c-ish pseudo-code.

loop {
c_subblock * const p_left      = Pop subblock from queue.
int          const right_index = p_left.index + p_left.width;
if ( right_index < length original array ) {
// Find adjacent subblock on the right.
// To do this you'll need the original array of length-1 subblocks.
c_subblock const * p_right = array_basic_subblocks[ right_index ];
do {
Check the left/right subblocks to see if the two merged are also a subblock.
If they are add a new merged subblock to the end of the queue.
p_right = p_right.p_above;
}
while ( p_right );
}
}


This will find them all I think. It's usually O(N log(N)), but it'll be O(N^2) for a fully sorted or anti-sorted list. I think there's an answer to this though -- when you build the original array of subblocks you look for sorted and anti-sorted sequences and add them as the base-level subblocks. If you are keeping a count increment it by (width * (width + 1))/2 for the base-level. That'll give you the count INCLUDING all the 1-length subblocks.

After that just use the loop above, popping and pushing the queue. If you're counting you'll have to have a multiplier on both the left and right subblocks and multiply these together to calculate the increment. The multiplier is the width of the leftmost (for p_left) or rightmost (for p_right) base-level subblock.

Hope this is clear and not too buggy. I'm just banging it out, so it may even be wrong. [Later note. This doesn't work after all. See note below.]

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FTFY, Use the 1010 button, indent 4 spaces, or highlight and press ctrl-k to format code. For inline code, use backticks. –  Stephen Jul 27 '10 at 1:36
Thanks Stephen, I followed your advice. –  nealabq Jul 27 '10 at 1:53
How does this algorithm behave on an array {2, 4, 1, 3}? –  Maciej Hehl Jul 27 '10 at 14:34
Maciej, good point. The algorithm doesn't work after all, it gives you 4 for the above instead of 5. 0 instead of 1 if you don't count trivial subblocks. You'd be great to have at a design/code review. –  nealabq Jul 27 '10 at 17:37