canonize function does is what is described at the very end of this SA post, where we consider a situation like this:
The situation is this:
The active point is at
(red,'d',3), i.e. three characters into the
defg edge going out of the red node.
Now we follow a suffix link to the green node. In theory, our active node is now
Unfortunately that point does not exist, because the
de edge going out of the green node has got only 2 characters. Hence, we apply the
It works like this:
The starting character of the edge we are interested in is
d. This character is referred to as tk in Ukkonen's notation. So, "finding the tk-edge" means finding the
de edge at the green node.
That edge is only two characters in length. I.e.
(p' - k') == 2 in Ukkonen's notation. But the original edge had three characters:
(p - k) == 3. So
<= is true and we enter the loop.
We shorten the edge we are looking for from
f. This is what the
p := p + (k' - p') + 1 step does.
We advance to the state the
de edge points to, i.e. the blue state. That is what
s := s' does.
Since the remaining part
f of the edge is not empty (
k <= p), we identify the relevant outgoing edge (that is the
fg edge going out of the blue node). This step sets k' and p' to entirely new values, because they now refer to the string
fg, and its length (p' - k') will now be 2.
The length of the remaining edge
f, (p - k), is now 1, and the length of the candidate edge
fg for the new active point, (p' - k'), is 2. Hence the loop condition
while (p' - k') <= (p - k) do
is no longer true, so the loop ends, and indeed the new (and correct) active point is
[Actually, in Ukkonen's notation, the end pointer p of an edge points to the position of the final character of the edge, not the position that follows it. Hence, strictly speaking, (p - k) is 0, not 1, and (p' - k') is 1, not 2. But what matters is not the absolute value of the length, but the relative comparison of the two different lengths.]
A few final notes:
Pointers like p and k refer to positions in the original input text t. That can be quite confusing. For example, the pointers used in the
de edge at the green node will refer to some substring
de of t, and the pointers used in the
fg edge at the blue node will refer to some substring
fg of t. Although the string
defg must appear as one continuous string somewhere in t, the substring
fg might appear in other places, too. So, the pointer k of the
fg edge is not necessarily the end pointer p of the
de edge plus one.
What counts when we decide whether or not to end the loop is therefore not the absolute positions k or p, but the length (p - k) of the remaining edge compared to the length (p' - k') of the current candidate edge.
In your question, line 4 of the code snippet, there is a typo: It should be
k' instead of