In the previous post, we discussed Finite Automata based pattern searching algorithm. The FA (Finite Automata) construction method discussed in previous post takes O((m^3)*NO_OF_CHARS) time. FA can be constructed in O(m*NO_OF_CHARS) time. In this post, we will discuss the O(m*NO_OF_CHARS) algorithm for FA construction. The idea is similar to lps (longest prefix suffix) array construction discussed in the KMP algorithm. We use previously filled rows to fill a new row.C++ programming for Pattern Searching Set 6 Efficient Construction of Finite Automata

C++ programming for Pattern Searching Set 6 Efficient Construction of Finite Automata

The abvoe diagrams represent graphical and tabular representations of pattern ACACAGA.

Algorithm:
1) Fill the first row. All entries in first row are always 0 except the entry for pat[0] character. For pat[0] character, we always need to go to state 1.
2) Initialize lps as 0. lps for the first index is always 0.
3) Do following for rows at index i = 1 to M. (M is the length of the pattern)
…..a) Copy the entries from the row at index equal to lps.
…..b) Update the entry for pat[i] character to i+1.
…..c) Update lps “lps = TF[lps][pat[i]]” where TF is the 2D array which is being constructed.

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Implementation
Following is C implementation for the above algorithm.

C++
#include<stdio.h>
#include<string.h>
#define NO_OF_CHARS 256

/* This function builds the TF table which represents Finite Automata for a
given pattern */
void computeTransFun(char *pat, int M, int TF[][NO_OF_CHARS])
{
int i, lps = 0, x;

// Fill entries in first row
for (x =0; x < NO_OF_CHARS; x++)
TF[0][x] = 0;
TF[0][pat[0]] = 1;

// Fill entries in other rows
for (i = 1; i<= M; i++)
{
// Copy values from row at index lps
for (x = 0; x < NO_OF_CHARS; x++)
TF[i][x] = TF[lps][x];

// Update the entry corresponding to this character
TF[i][pat[i]] = i + 1;

// Update lps for next row to be filled
if (i < M)
lps = TF[lps][pat[i]];
}
}

/* Prints all occurrences of pat in txt */
void search(char *pat, char *txt)
{
int M = strlen(pat);
int N = strlen(txt);

int TF[M+1][NO_OF_CHARS];

computeTransFun(pat, M, TF);

// process text over FA.
int i, j=0;
for (i = 0; i < N; i++)
{
j = TF[j][txt[i]];
if (j == M)
{
printf ("\n pattern found at index %d", i-M+1);
}
}
}

/* Driver program to test above function */
int main()
{
char *txt = "GEEKS FOR GEEKS";
char *pat = "GEEKS";
search(pat, txt);
getchar();
return 0;
}

Output:

 pattern found at index 0
 pattern found at index 10

Time Complexity for FA construction is O(M*NO_OF_CHARS). The code for search is same as the previous post and time complexity for it is O(n).

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