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Tuned Boyer Moore Algorithm
Fast string searching , HUME A. and SUNDAY D.M., Software - Practice &
Experience 21(11), 1991, pp. 1221-1248.
Adviser: R. C. T. Lee
Speaker: C. W. Cheng
National Chi Nan University
Problem Definition
Input: a text string T with length n and a pattern string P with length m.
Output: all occurrences of P in T.
Definition• Ts : the first character of a string T aligns to a pattern P.
• Pl : the first character of a pattern P aligns to a string T.
• Tj : the character of the jth position of a string T.
• Pi : the character of the ith position of a pattern P.
• Pf : the last character of a pattern P.
• n : The length of T.
• m : The length of P.
Rule 2-2: 1-Suffix Rule (A Special Version of Rule 2)
• Consider the 1-suffix x. We may apply Rule 2-2 now.
T
P
x
x
Introduction
• simplification of the Boyer-Moore algorithm.
• uses only the bad-character shift.
• easy to implement.
• very fast in practice
• uses Rule 2-2: 1-Suffix Rule
Tuned Boyer Moore Algorithm
• In this algorithm, We always focus on the last character of the window of T and try to slide the pattern to match the last character of T.
Tuned Boyer Moore Algorithm Rule
T x z y
Since Ts+m-1 ≠ Pf , we move the pattern P to right such that the largest position i in the right of Pi is equal to Ts+m. We can shift the pattern at least (m-i) positions right until Ts+m-1 = Pf.
Shift
s s+m-1
P z x yi1 f
P z x yi1 f
P z x yi1 f
Shift
Tuned Boyer Moore Preprocessing Table
• In this algorithm, we construct a table as follow. Let x be a character in the alphabet. We record the position of the last x, if it exists in P, we record the position of x from the second last position of P. If x does not exist in P1 to Pm-1, we record it as m.
Tuned Boyer Moore Preprocessing Table
• Example: 6 5 4 3 2 1
P=AGCAGAC
A C G T
bmBC 1 4 2 7
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
tbmBC[A]=1, shift=1
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
→
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
tbmBC[G]=2, shift=2
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
→
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
match
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
exact match
tbmBC[C]=4, shift=4
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
→
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
match
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
mismatch
tbmBC[C]=4, shift=4
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
→
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
tbmBC[T]=7, shift=7
Example
• Text string T=GCGAGCAGACGTGCGAGTACG
• Pattern string
P=AGCAGAC
G C G A G C A G A C G T G C G A G T A C G
A G C A G A C
A C G T
tbmBC 1 4 2 7
→
Time complexity
• preprocessing phase in O(m+ σ) time and O(σ) space complexity, σ is the number of alphabets in pattern.
• searching phase in O(mn) time complexity.
Reference[KMP77] Fast pattern matching in strings, D. E. Knuth, J. H. Morris, Jr and V. B. Pratt, SIAM J. Computing, 6, 1977, pp. 323–350.[BM77] A fast string search algorithm, R. S. Boyer and J. S. Moore, Comm. ACM, 20, 1977, pp. 762–772.[S90] A very fast substring search algorithm, D. M. Sunday, Comm. ACM, 33, 1990, pp. 132–142.[RR89] The Rand MH Message Handling system: User’s Manual (UCIVersion), M. T. Rose and J. L. Romine, University of California, Irvine, 1989.[S82] A comparison of three string matching algorithms, G. De V. Smith, Software—Practice and Experience,12, 1982, pp. 57–66.[HS91] Fast string searching, HUME A. and SUNDAY D.M. , Software - Practice & Experience 21(11), 1991, pp.
1221-1248. [S94] String Searching Algorithms , Stephen, G.A., World Scientific, 1994. [ZT87] On improving the average case of the Boyer-Moore string matching algorithm, ZHU, R.F. and TAKAOKA, T., Journal of Information Processing 10(3) , 1987, pp. 173-177 .[R92] Tuning the Boyer-Moore-Horspool string searching algorithm, RAITA T., Software - Practice & Experienc
e, 22(10) , 1992, pp. 879-884. [S94] On tuning the Boyer-Moore-Horspool string searching algorithms, SMITH, P.D., Software - Practice & Experience, 24(4) , 1994, pp. 435-436. [BR92] Average running time of the Boyer-Moore-Horspool algorithm, BAEZA-YATES, R.A., RÉGNIER, M., Theoretical Computer Science 92(1) , 1992, pp. 19-31. [H80] Practical fast searching in strings, HORSPOOL R.N., Software - Practice & Experience, 10(6) , 1980, pp. 501-506. [L95] Experimental results on string matching algorithms, LECROQ, T., Software - Practice & Experience 25(7) , 1995, pp. 727-765.
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