I'm not sure if this is the correct answer, but anyway:

**While constructing** the hash value, we can check for a match in the set of string hashes. Aka, the *current* hash value. The hash function/code is usually implemented as a loop and inside that loop we can insert our quick look up.

Of course, we must pick `m`

to have the maximum string length from the set of strings.

**Update:** From Wikipedia,

```
[...]
for i from 1 to n-m+1
if hs ∈ hsubs
if s[i..i+m-1] = a substring with hash hs
return i
hs := hash(s[i+1..i+m]) // <---- calculating current hash
[...]
```

We calculate *current* hash in `m`

steps. On each step there is a *temporary* hash value that we can look up ( O(1) complexity ) in the set of hashes. All hashes will have the same size, ie 32 bit.

**Update 2:** an amortized (average) O(n) time complexity ?

Above I said that `m`

must have the maximum string length. It turns out that we can exploit the opposite.

With hashing for shifting substring search and a fixed `m`

size we can achieve O(n) complexity.

If we have variable length strings we can set `m`

to the minimum string length. Additionally, in the set of hashes we don't associate a hash with the whole string but with the first m-characters of it.

Now, while searching the text we check if the current hash is in the hash set and we examine the associated strings for a match.

This technique will increase the false alarms but on average it has O(n) time complexity.