Based on your comment, I'll assume we have access to the suffix array
SA as well as the standard
LCP array, i.e. a data structure that tells us, at index i>0, what the length of the longest common prefix of suffix
SA[i] and its lexicographic predecessor
I'll use the letter L to refer to the special LCP array we want to construct, as described in the question. I'll use the letter N to refer to the length of the input string
Then what we can do is this:
Determine the position of
str within the suffix array. We can do this by screening
SA linearly to find the entry
str is the suffix of
str starting at position 0. Therefore,
0 must appear as an entry of the suffix array.)
Suppose the entry we find is at index k. Then we can set
L[k]:=N, we because
SA[k] is the string itself and has a prefix of N characters in common with itself.
Then we can set
L[k+1]:=LCP[k+1] because that is how the standard LCP is defined.
Then we go backwards from i:=k-2 down to 0 and set
L[i] := min(LCP[i+1],L[i+1])
This works because, at each iteration i,
LCP[i+1] tells us the longest common prefix of the adjacent suffixes
L[i+1] tells us the longest common prefix of the previously processed suffix
SA[i+1] and the input string
L[i] must be the minimum of those two, because
L[i] indicates how long a prefix
SA[i] has in common with
str, and that cannot be longer than the prefix it has in common with
SA[i+1], otherwise its position in the suffix array would be closer to k.
We also count forward from i:=k+2 to N and set
L[i] := min(LCP[i],L[i-1])
based on the same reasoning.
Then all N values of
L have been set, and it took no more than O(N) time, assuming that random access to the arrays and integer comparison are O(1), respectively.
Since the array we compute is N entries in length, a complexity of O(N) is optimal.
(Note. You can start the loops in steps 4 and 5 at k-1 and k+1, respectively, and get rid of step 3. The extra step only serves to make the explanation -- hopefully -- a little easier to follow.)