Your reasoning might be a bit flawed.
Consider the following example:
2 3 4 2 5 6 7 8 9 10
Here, the answer is 4 (one needs to change the first 4 inputs), but according to original poster's logic, if we strip out:
A[i] less than or equals i
we'll get a residual list of numbers:
2 3 4 5 6 7 8 9 10
which obviously gives an answer of 1 if LIS is directly applied to it (the entire sequence is strictly increasing, and you are discarding only A in the original array)
My approach would be as follows:
Try to build LIS. That is, keep an array A[i], such that A[i] = lowest i-th item in an increasing subsequence found so far that ALSO obeys the law that its index in the input array of the value of A[i] has a difference with index of A[i-1] such that:
The difference between their respective values is >= this difference of their indices in the original array. If that is not the case, then unfortunately one can't squeeze in integral values in between them.
As a special case, if i is 0, that is it is first item in the LIS array, then it is mandatory that its value be > its index in the input array (your logic does apply here)
For each item, binary search for greatest item which is less than the current input item AND that satisfies point#1 above. One can always binary search like this because if the premise holds for a certain value, then it recursively holds for ALL value less than the current binary search value under consideration.
I pass test cases with this approach.
[Edit]: Adding more explanation since comment section won't allow verbose comments.
Let LIS be the LIS that we maintain. Then after ALL Dosas have been processed, the final answer = N - size(LIS)
Now, the challenge boils down to find how to create and maintain this array -> LIS, that too efficiently. It can be done in O(N^2), but that will timeout for a large N, possibly with value upto 10^6. We'll try to solve it in O(N*log(N))
I propose the following invariant:
Let LIS[i] = 2-tuple (pair) containing price of Dosa that is just (minimally possible value) higher than value of Dosa at LIS[i-1] and whose "index difference" with Dosa at LIS[i-1] is less than or equal to "price difference" with Dosa at LIS[i-1]
That is, if:
LIS[i-1] = pair(a,b), where a = value of Dosa and b = its index in original input array
Then the following must hold:
If LIS[i] = pair(u,v), where u = value of Dosa and v = its index in original input array
Then the following should always hold true:
u > a (i.e., price of Dosa in LIS[i] must be strictly greater than value of Dosa at LIS[i-1]. Why? Well, that's what we want in the first place, don't we? A strictly increasing sub sequence)
u - a ≥ v - b (Now, you might need to ponder a little bit why this MUST hold)
Consider a contradiction. Let's say, u - a < v - b.
Then there is no way you can uniquely fit in Dosas between indices b and a in the original array. Since it would require at least one duplicate Dosa by Pigeon Hole Principle.
Now, the above properties lend themselves beautifully to binary search. Why?
While trying to fit the current Dosa under consideration into the LIS at a certain position with its (Dosa value, original array index) pair value as, say, (u,v), we must have:
Current Dosa value > u (because we want strictly increasing sub sequence)
Difference between their indices should be less than or equal to difference between their Dosa values (as explained in #2 above)
If this doesn't hold, then we are sure that either of the following is true:
Either the current Dosa value ≤ u or,
The Index diff between current Dosa and the Dosa at binary search position (value v) < their respective Dosa value difference
If it is #1, then we obviously need to search on the left partition in binary search (since we've gone too far to the right)
If it is #2, then even if current Dosa value > u, then even by going right, let's say binary search item's Dosa value is u + Delta, then it's height must be at least v + Delta, hence there is no way it can have the index difference <= height difference by continuing proceeding towards right. So, we must stop and search in the left partition.
[Pause. Read again if it's still unclear]
[EDIT]: SPOILER - Adding working code (scroll to uncover)
[Sorry, I was unable to add code here without getting "Your post appears to contain code that is not properly formatted" errors. So, putting ideone.com link]
Sample code here: http://ideone.com/tPkUWk
[Edit]: I don't want to spoil for others, so I'm making the code private.