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.

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

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).

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.

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].

`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