mirror of https://github.com/python/cpython.git
432 lines
16 KiB
Plaintext
432 lines
16 KiB
Plaintext
This document explains Crochemore and Perrin's Two-Way string matching
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algorithm, in which a smaller string (the "pattern" or "needle")
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is searched for in a longer string (the "text" or "haystack"),
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determining whether the needle is a substring of the haystack, and if
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so, at what index(es). It is to be used by Python's string
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(and bytes-like) objects when calling `find`, `index`, `__contains__`,
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or implicitly in methods like `replace` or `partition`.
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This is essentially a re-telling of the paper
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Crochemore M., Perrin D., 1991, Two-way string-matching,
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Journal of the ACM 38(3):651-675.
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focused more on understanding and examples than on rigor. See also
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the code sample here:
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http://www-igm.univ-mlv.fr/~lecroq/string/node26.html#SECTION00260
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The algorithm runs in O(len(needle) + len(haystack)) time and with
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O(1) space. However, since there is a larger preprocessing cost than
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simpler algorithms, this Two-Way algorithm is to be used only when the
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needle and haystack lengths meet certain thresholds.
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These are the basic steps of the algorithm:
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* "Very carefully" cut the needle in two.
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* For each alignment attempted:
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1. match the right part
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* On failure, jump by the amount matched + 1
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2. then match the left part.
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* On failure jump by max(len(left), len(right)) + 1
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* If the needle is periodic, don't re-do comparisons; maintain
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a "memory" of how many characters you already know match.
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-------- Matching the right part --------
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We first scan the right part of the needle to check if it matches the
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the aligned characters in the haystack. We scan left-to-right,
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and if a mismatch occurs, we jump ahead by the amount matched plus 1.
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Example:
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text: ........EFGX...................
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pattern: ....abcdEFGH....
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cut: <<<<>>>>
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Matched 3, so jump ahead by 4:
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text: ........EFGX...................
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pattern: ....abcdEFGH....
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cut: <<<<>>>>
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Why are we allowed to do this? Because we cut the needle very
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carefully, in such a way that if the cut is ...abcd + EFGH... then
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we have
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d != E
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cd != EF
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bcd != EFG
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abcd != EFGH
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... and so on.
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If this is true for every pair of equal-length substrings around the
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cut, then the following alignments do not work, so we can skip them:
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text: ........EFG....................
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pattern: ....abcdEFGH....
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^ (Bad because d != E)
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text: ........EFG....................
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pattern: ....abcdEFGH....
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^^ (Bad because cd != EF)
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text: ........EFG....................
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pattern: ....abcdEFGH....
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^^^ (Bad because bcd != EFG)
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Skip 3 alignments => increment alignment by 4.
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-------- If len(left_part) < len(right_part) --------
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Above is the core idea, and it begins to suggest how the algorithm can
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be linear-time. There is one bit of subtlety involving what to do
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around the end of the needle: if the left half is shorter than the
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right, then we could run into something like this:
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text: .....EFG......
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pattern: cdEFGH
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The same argument holds that we can skip ahead by 4, so long as
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d != E
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cd != EF
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?cd != EFG
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??cd != EFGH
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etc.
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The question marks represent "wildcards" that always match; they're
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outside the limits of the needle, so there's no way for them to
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invalidate a match. To ensure that the inequalities above are always
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true, we need them to be true for all possible '?' values. We thus
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need cd != FG and cd != GH, etc.
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-------- Matching the left part --------
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Once we have ensured the right part matches, we scan the left part
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(order doesn't matter, but traditionally right-to-left), and if we
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find a mismatch, we jump ahead by
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max(len(left_part), len(right_part)) + 1. That we can jump by
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at least len(right_part) + 1 we have already seen:
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text: .....EFG.....
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pattern: abcdEFG
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Matched 3, so jump by 4,
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using the fact that d != E, cd != EF, and bcd != EFG.
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But we can also jump by at least len(left_part) + 1:
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text: ....cdEF.....
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pattern: abcdEF
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Jump by len('abcd') + 1 = 5.
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Skip the alignments:
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text: ....cdEF.....
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pattern: abcdEF
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text: ....cdEF.....
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pattern: abcdEF
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text: ....cdEF.....
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pattern: abcdEF
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text: ....cdEF.....
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pattern: abcdEF
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This requires the following facts:
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d != E
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cd != EF
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bcd != EF?
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abcd != EF??
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etc., for all values of ?s, as above.
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If we have both sets of inequalities, then we can indeed jump by
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max(len(left_part), len(right_part)) + 1. Under the assumption of such
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a nice splitting of the needle, we now have enough to prove linear
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time for the search: consider the forward-progress/comparisons ratio
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at each alignment position. If a mismatch occurs in the right part,
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the ratio is 1 position forward per comparison. On the other hand,
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if a mismatch occurs in the left half, we advance by more than
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len(needle)//2 positions for at most len(needle) comparisons,
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so this ratio is more than 1/2. This average "movement speed" is
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bounded below by the constant "1 position per 2 comparisons", so we
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have linear time.
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-------- The periodic case --------
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The sets of inequalities listed so far seem too good to be true in
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the general case. Indeed, they fail when a needle is periodic:
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there's no way to split 'AAbAAbAAbA' in two such that
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(the stuff n characters to the left of the split)
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cannot equal
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(the stuff n characters to the right of the split)
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for all n.
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This is because no matter how you cut it, you'll get
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s[cut-3:cut] == s[cut:cut+3]. So what do we do? We still cut the
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needle in two so that n can be as big as possible. If we were to
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split it as
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AAbA + AbAAbA
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then A == A at the split, so this is bad (we failed at length 1), but
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if we split it as
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AA + bAAbAAbA
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we at least have A != b and AA != bA, and we fail at length 3
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since ?AA == bAA. We already knew that a cut to make length-3
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mismatch was impossible due to the period, but we now see that the
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bound is sharp; we can get length-1 and length-2 to mismatch.
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This is exactly the content of the *critical factorization theorem*:
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that no matter the period of the original needle, you can cut it in
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such a way that (with the appropriate question marks),
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needle[cut-k:cut] mismatches needle[cut:cut+k] for all k < the period.
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Even "non-periodic" strings are periodic with a period equal to
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their length, so for such needles, the CFT already guarantees that
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the algorithm described so far will work, since we can cut the needle
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so that the length-k chunks on either side of the cut mismatch for all
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k < len(needle). Looking closer at the algorithm, we only actually
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require that k go up to max(len(left_part), len(right_part)).
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So long as the period exceeds that, we're good.
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The more general shorter-period case is a bit harder. The essentials
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are the same, except we use the periodicity to our advantage by
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"remembering" periods that we've already compared. In our running
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example, say we're computing
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"AAbAAbAAbA" in "bbbAbbAAbAAbAAbbbAAbAAbAAbAA".
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We cut as AA + bAAbAAbA, and then the algorithm runs as follows:
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First alignment:
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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^^X
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- Mismatch at third position, so jump by 3.
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- This requires that A!=b and AA != bA.
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Second alignment:
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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^^^^^^^^
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X
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- Matched entire right part
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- Mismatch at left part.
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- Jump forward a period, remembering the existing comparisons
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Third alignment:
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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mmmmmmm^^X
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- There's "memory": a bunch of characters were already matched.
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- Two more characters match beyond that.
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- The 8th character of the right part mismatched, so jump by 8
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- The above rule is more complicated than usual: we don't have
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the right inequalities for lengths 1 through 7, but we do have
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shifted copies of the length-1 and length-2 inequalities,
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along with knowledge of the mismatch. We can skip all of these
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alignments at once:
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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~ A != b at the cut
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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~~ AA != bA at the cut
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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^^^^X 7-3=4 match, and the 5th misses.
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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~ A != b at the cut
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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~~ AA != bA at the cut
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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^X 7-3-3=1 match and the 2nd misses.
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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~ A != b at the cut
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Fourth alignment:
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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^X
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- Second character mismatches, so jump by 2.
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Fifth alignment:
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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^^^^^^^^
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X
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- Right half matches, so use memory and skip ahead by period=3
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Sixth alignment:
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bbbAbbAAbAAbAAbbbAAbAAbAAbAA
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AAbAAbAAbA
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mmmmmmmm^^
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- Right part matches, left part is remembered, found a match!
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The one tricky skip by 8 here generalizes: if we have a period of p,
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then the CFT says we can ensure the cut has the inequality property
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for lengths 1 through p-1, and jumping by p would line up the
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matching characters and mismatched character one period earlier.
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Inductively, this proves that we can skip by the number of characters
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matched in the right half, plus 1, just as in the original algorithm.
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To make it explicit, the memory is set whenever the entire right part
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is matched and is then used as a starting point in the next alignment.
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In such a case, the alignment jumps forward one period, and the right
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half matches all except possibly the last period. Additionally,
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if we cut so that the left part has a length strictly less than the
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period (we always can!), then we can know that the left part already
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matches. The memory is reset to 0 whenever there is a mismatch in the
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right part.
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To prove linearity for the periodic case, note that if a right-part
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character mismatches, then we advance forward 1 unit per comparison.
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On the other hand, if the entire right part matches, then the skipping
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forward by one period "defers" some of the comparisons to the next
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alignment, where they will then be spent at the usual rate of
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one comparison per step forward. Even if left-half comparisons
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are always "wasted", they constitute less than half of all
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comparisons, so the average rate is certainly at least 1 move forward
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per 2 comparisons.
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-------- When to choose the periodic algorithm ---------
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The periodic algorithm is always valid but has an overhead of one
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more "memory" register and some memory computation steps, so the
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here-described-first non-periodic/long-period algorithm -- skipping by
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max(len(left_part), len(right_part)) + 1 rather than the period --
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should be preferred when possible.
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Interestingly, the long-period algorithm does not require an exact
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computation of the period; it works even with some long-period, but
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undeniably "periodic" needles:
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Cut: AbcdefAbc == Abcde + fAbc
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This cut gives these inequalities:
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e != f
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de != fA
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cde != fAb
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bcde != fAbc
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Abcde != fAbc?
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The first failure is a period long, per the CFT:
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?Abcde == fAbc??
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A sufficient condition for using the long-period algorithm is having
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the period of the needle be greater than
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max(len(left_part), len(right_part)). This way, after choosing a good
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split, we get all of the max(len(left_part), len(right_part))
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inequalities around the cut that were required in the long-period
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version of the algorithm.
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With all of this in mind, here's how we choose:
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(1) Choose a "critical factorization" of the needle -- a cut
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where we have period minus 1 inequalities in a row.
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More specifically, choose a cut so that the left_part
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is less than one period long.
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(2) Determine the period P_r of the right_part.
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(3) Check if the left part is just an extension of the pattern of
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the right part, so that the whole needle has period P_r.
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Explicitly, check if
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needle[0:cut] == needle[0+P_r:cut+P_r]
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If so, we use the periodic algorithm. If not equal, we use the
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long-period algorithm.
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Note that if equality holds in (3), then the period of the whole
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string is P_r. On the other hand, suppose equality does not hold.
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The period of the needle is then strictly greater than P_r. Here's
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a general fact:
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If p is a substring of s and p has period r, then the period
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of s is either equal to r or greater than len(p).
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We know that needle_period != P_r,
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and therefore needle_period > len(right_part).
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Additionally, we'll choose the cut (see below)
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so that len(left_part) < needle_period.
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Thus, in the case where equality does not hold, we have that
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needle_period >= max(len(left_part), len(right_part)) + 1,
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so the long-period algorithm works, but otherwise, we know the period
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of the needle.
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Note that this decision process doesn't always require an exact
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computation of the period -- we can get away with only computing P_r!
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-------- Computing the cut --------
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Our remaining tasks are now to compute a cut of the needle with as
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many inequalities as possible, ensuring that cut < needle_period.
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Meanwhile, we must also compute the period P_r of the right_part.
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The computation is relatively simple, essentially doing this:
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suffix1 = max(needle[i:] for i in range(len(needle)))
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suffix2 = ... # the same as above, but invert the alphabet
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cut1 = len(needle) - len(suffix1)
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cut2 = len(needle) - len(suffix2)
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cut = max(cut1, cut2) # the later cut
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For cut2, "invert the alphabet" is different than saying min(...),
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since in lexicographic order, we still put "py" < "python", even
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if the alphabet is inverted. Computing these, along with the method
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of computing the period of the right half, is easiest to read directly
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from the source code in fastsearch.h, in which these are computed
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in linear time.
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Crochemore & Perrin's Theorem 3.1 give that "cut" above is a
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critical factorization less than the period, but a very brief sketch
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of their proof goes something like this (this is far from complete):
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* If this cut splits the needle as some
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needle == (a + w) + (w + b), meaning there's a bad equality
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w == w, it's impossible for w + b to be bigger than both
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b and w + w + b, so this can't happen. We thus have all of
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the inequalities with no question marks.
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* By maximality, the right part is not a substring of the left
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part. Thus, we have all of the inequalities involving no
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left-side question marks.
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* If you have all of the inequalities without right-side question
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marks, we have a critical factorization.
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* If one such inequality fails, then there's a smaller period,
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but the factorization is nonetheless critical. Here's where
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you need the redundancy coming from computing both cuts and
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choosing the later one.
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-------- Some more Bells and Whistles --------
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Beyond Crochemore & Perrin's original algorithm, we can use a couple
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more tricks for speed in fastsearch.h:
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1. Even though C&P has a best-case O(n/m) time, this doesn't occur
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very often, so we add a Boyer-Moore bad character table to
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achieve sublinear time in more cases.
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2. The prework of computing the cut/period is expensive per
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needle character, so we shouldn't do it if it won't pay off.
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For this reason, if the needle and haystack are long enough,
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only automatically start with two-way if the needle's length
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is a small percentage of the length of the haystack.
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3. In cases where the needle and haystack are large but the needle
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makes up a significant percentage of the length of the
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haystack, don't pay the expensive two-way preprocessing cost
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if you don't need to. Instead, keep track of how many
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character comparisons are equal, and if that exceeds
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O(len(needle)), then pay that cost, since the simpler algorithm
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isn't doing very well.
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