What the `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 `(green,'d',3)`

.

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 **`canonize`

function.

**It works like this:**

The starting character of the edge we are interested in is `d`

. This character is referred to as t_{k} in Ukkonen's notation. So, "finding the t_{k}-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 `def`

to `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 `(blue,'f',1)`

.

*[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 `k;`

.

Algorithmica? In that case, the reference would be DOI 10.1007/BF01206331. – jogojapan Apr 11 '12 at 2:04