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Crochemore’s algorithm for repetitions and its fast and space-efficient implementation

Crochemore’s algorithm for repetitions and its fast and space-efficient implementation. F. Franek Algorithms Research Group Computing and Software McMaster University November 2001. slide 1/9.

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Crochemore’s algorithm for repetitions and its fast and space-efficient implementation

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  1. Crochemore’s algorithm for repetitions and its fast and space-efficient implementation F. Franek Algorithms Research GroupComputing and Software McMaster University November 2001 slide 1/9

  2. for(i = 0; i < N-2; i++) {for(k = 1; k <= (N-i)/2; k++) { s = 1;for(j = 0; j < k; j++) if (x[i+j] != x[i+k+j]) {s=0; break; } if (s) printf(“square of length %d at position %d\n”,k,i);}} Trivial, brute force O(n3) algorithm for repetitions. slide 2/9

  3. a b a a b a b a a b a a b a b0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 level 1 {0,2,3,5,7,8,10,11,13}a {1,4,6,9,12,14}b 2 {2,7,10}aa {0,3,5,8,11,13}ab {1,4,6,9,12}ba {14}b$ 3 {2,7,10}aab {0,3,5,8,11}aba {13}ab$ {1,6,9}baa {4,12}bab 4 {2,7,10}aaba {0,5,8}abaa {3,11}abab {1,6,9}baab {4}baba {12}bab$ 5 {7}aabaa {2,10}aabab {0,5,8}abaab {3}ababa {11}abab$ {1,6,9}baaba 6 {2}aababa {10}aabab$ {0,5,8}abaaba {6}baabaa {1,9}baabab 7 {5,8}abaabaa {0}abaabab {1}baababa {9}baabab$ 8 {5}abaabaab {8}abaabaa$ slide 3/9

  4. O O 0 1 2 3 4 5 6 N indexes 4 5 CNext[ ] c1={2,4,5} 2 4 CPrev[ ] 5 CEnd[ ] 2 CStart[ ] 3 CSize[ ] 1 1 1 CMember[] Total this slide 6*Nsubtotal 6*N slide 4/9

  5. 0 1 2 3 4 5 6 N indexes …. 0 1 3 CEmptyStack SelQueue ScQueue RefStack Refine[] Total this slide 5*Nsubtotal 11*N slide 5/9

  6. O O 0 1 2 3 4 5 6 N indexes 5 FNext[ ] f2={3,5} 3 FPrev[ ] 3 FStart[ ] 2 2 FMember[] Total this slide 4*Noverall total 15*N slide 6/9

  7. 0 1 2 3 4 5 6 N indexes 4 5 3 CNext[ ] c1={2,4,5} 5 2 CPrev[ ] Memoryvirtualization CEnd[ ] 2 CStart[ ] CSize[ ] 1 1 1 CMember[] Total this slide 4*Nsubtotal 4*N slide 7/9

  8. 0 1 2 3 4 5 6 N indexes ScQueue CEmptyStack …. 0 1 3 Memorymultiplexing RefStack SelQueue Refine[] Refine[] is virtualized over FNext[], FPrev[], and FStart[] Total this slide 2*Nsubtotal 6*N slide 8/9

  9. 0 1 2 3 4 5 6 N indexes 5 FNext[ ] f2={3,5} 3 FPrev[ ] Memoryvirtualization 3 FStart[ ] 2 2 FMember[] Refine[] is virtualized over Total this slide 4*Noverall total 10*N slide 9/9

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