1#include "cache.h"
 2#include "levenshtein.h"
 
 
 
 3
 4/*
 5 * This function implements the Damerau-Levenshtein algorithm to
 6 * calculate a distance between strings.
 7 *
 8 * Basically, it says how many letters need to be swapped, substituted,
 9 * deleted from, or added to string1, at least, to get string2.
10 *
11 * The idea is to build a distance matrix for the substrings of both
12 * strings.  To avoid a large space complexity, only the last three rows
13 * are kept in memory (if swaps had the same or higher cost as one deletion
14 * plus one insertion, only two rows would be needed).
15 *
16 * At any stage, "i + 1" denotes the length of the current substring of
17 * string1 that the distance is calculated for.
18 *
19 * row2 holds the current row, row1 the previous row (i.e. for the substring
20 * of string1 of length "i"), and row0 the row before that.
21 *
22 * In other words, at the start of the big loop, row2[j + 1] contains the
23 * Damerau-Levenshtein distance between the substring of string1 of length
24 * "i" and the substring of string2 of length "j + 1".
25 *
26 * All the big loop does is determine the partial minimum-cost paths.
27 *
28 * It does so by calculating the costs of the path ending in characters
29 * i (in string1) and j (in string2), respectively, given that the last
30 * operation is a substition, a swap, a deletion, or an insertion.
31 *
32 * This implementation allows the costs to be weighted:
33 *
34 * - w (as in "sWap")
35 * - s (as in "Substitution")
36 * - a (for insertion, AKA "Add")
37 * - d (as in "Deletion")
38 *
39 * Note that this algorithm calculates a distance _iff_ d == a.
40 */
41int levenshtein(const char *string1, const char *string2,
42		int w, int s, int a, int d)
43{
44	int len1 = strlen(string1), len2 = strlen(string2);
45	int *row0 = malloc(sizeof(int) * (len2 + 1));
46	int *row1 = malloc(sizeof(int) * (len2 + 1));
47	int *row2 = malloc(sizeof(int) * (len2 + 1));
48	int i, j;
49
50	for (j = 0; j <= len2; j++)
51		row1[j] = j * a;
52	for (i = 0; i < len1; i++) {
53		int *dummy;
54
55		row2[0] = (i + 1) * d;
56		for (j = 0; j < len2; j++) {
57			/* substitution */
58			row2[j + 1] = row1[j] + s * (string1[i] != string2[j]);
59			/* swap */
60			if (i > 0 && j > 0 && string1[i - 1] == string2[j] &&
61					string1[i] == string2[j - 1] &&
62					row2[j + 1] > row0[j - 1] + w)
63				row2[j + 1] = row0[j - 1] + w;
64			/* deletion */
65			if (row2[j + 1] > row1[j + 1] + d)
66				row2[j + 1] = row1[j + 1] + d;
67			/* insertion */
68			if (row2[j + 1] > row2[j] + a)
69				row2[j + 1] = row2[j] + a;
70		}
71
72		dummy = row0;
73		row0 = row1;
74		row1 = row2;
75		row2 = dummy;
76	}
77
78	i = row1[len2];
79	free(row0);
80	free(row1);
81	free(row2);
82
83	return i;
84}

 1// SPDX-License-Identifier: GPL-2.0
 2#include "levenshtein.h"
 3#include <errno.h>
 4#include <stdlib.h>
 5#include <string.h>
 6
 7/*
 8 * This function implements the Damerau-Levenshtein algorithm to
 9 * calculate a distance between strings.
10 *
11 * Basically, it says how many letters need to be swapped, substituted,
12 * deleted from, or added to string1, at least, to get string2.
13 *
14 * The idea is to build a distance matrix for the substrings of both
15 * strings.  To avoid a large space complexity, only the last three rows
16 * are kept in memory (if swaps had the same or higher cost as one deletion
17 * plus one insertion, only two rows would be needed).
18 *
19 * At any stage, "i + 1" denotes the length of the current substring of
20 * string1 that the distance is calculated for.
21 *
22 * row2 holds the current row, row1 the previous row (i.e. for the substring
23 * of string1 of length "i"), and row0 the row before that.
24 *
25 * In other words, at the start of the big loop, row2[j + 1] contains the
26 * Damerau-Levenshtein distance between the substring of string1 of length
27 * "i" and the substring of string2 of length "j + 1".
28 *
29 * All the big loop does is determine the partial minimum-cost paths.
30 *
31 * It does so by calculating the costs of the path ending in characters
32 * i (in string1) and j (in string2), respectively, given that the last
33 * operation is a substitution, a swap, a deletion, or an insertion.
34 *
35 * This implementation allows the costs to be weighted:
36 *
37 * - w (as in "sWap")
38 * - s (as in "Substitution")
39 * - a (for insertion, AKA "Add")
40 * - d (as in "Deletion")
41 *
42 * Note that this algorithm calculates a distance _iff_ d == a.
43 */
44int levenshtein(const char *string1, const char *string2,
45		int w, int s, int a, int d)
46{
47	int len1 = strlen(string1), len2 = strlen(string2);
48	int *row0 = malloc(sizeof(int) * (len2 + 1));
49	int *row1 = malloc(sizeof(int) * (len2 + 1));
50	int *row2 = malloc(sizeof(int) * (len2 + 1));
51	int i, j;
52
53	for (j = 0; j <= len2; j++)
54		row1[j] = j * a;
55	for (i = 0; i < len1; i++) {
56		int *dummy;
57
58		row2[0] = (i + 1) * d;
59		for (j = 0; j < len2; j++) {
60			/* substitution */
61			row2[j + 1] = row1[j] + s * (string1[i] != string2[j]);
62			/* swap */
63			if (i > 0 && j > 0 && string1[i - 1] == string2[j] &&
64					string1[i] == string2[j - 1] &&
65					row2[j + 1] > row0[j - 1] + w)
66				row2[j + 1] = row0[j - 1] + w;
67			/* deletion */
68			if (row2[j + 1] > row1[j + 1] + d)
69				row2[j + 1] = row1[j + 1] + d;
70			/* insertion */
71			if (row2[j + 1] > row2[j] + a)
72				row2[j + 1] = row2[j] + a;
73		}
74
75		dummy = row0;
76		row0 = row1;
77		row1 = row2;
78		row2 = dummy;
79	}
80
81	i = row1[len2];
82	free(row0);
83	free(row1);
84	free(row2);
85
86	return i;
87}