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Edit Distance for Strings

String Algorithms
O(m×n) time, O(m×n) space
Intermediate

Minimum operations (insert/delete/substitute) to transform one string to another. DP solution optimized for string comparison.

Visualization

Interactive visualization for Edit Distance for Strings

Edit Distance (Levenshtein)

• Time: O(m × n)

• Space: O(m × n)

• Used in spell checkers, DNA analysis

Interactive visualization with step-by-step execution

Implementation

Language:
1function editDistance(s1: string, s2: string): number {
2  const m = s1.length, n = s2.length;
3  const dp = Array(m+1).fill(0).map(() => Array(n+1).fill(0));
4  
5  for (let i = 0; i <= m; i++) dp[i][0] = i;
6  for (let j = 0; j <= n; j++) dp[0][j] = j;
7  
8  for (let i = 1; i <= m; i++) {
9    for (let j = 1; j <= n; j++) {
10      if (s1[i-1] === s2[j-1]) {
11        dp[i][j] = dp[i-1][j-1];
12      } else {
13        dp[i][j] = 1 + Math.min(
14          dp[i-1][j],    // delete
15          dp[i][j-1],    // insert
16          dp[i-1][j-1]   // replace
17        );
18      }
19    }
20  }
21  return dp[m][n];
22}

Deep Dive

Theoretical Foundation

dp[i][j] = min edits to transform s1[0..i] to s2[0..j]. If chars match: dp[i-1][j-1]. Else: 1 + min(insert, delete, replace).

Complexity

Time

Best

O(m×n)

Average

O(m×n)

Worst

O(m×n)

Space

Required

O(m×n)

Applications

Use Cases

Spell checking
DNA comparison
Fuzzy search
Diff tools

Related Algorithms

Knuth-Morris-Pratt (KMP) Algorithm

An efficient string pattern matching algorithm that searches for occurrences of a 'word' within a 'text' by employing the observation that when a mismatch occurs, the word itself embodies sufficient information to determine where the next match could begin. Developed by Donald Knuth, Vaughan Pratt, and James H. Morris in 1977, it's one of the most important string algorithms with O(n+m) time complexity.

String Algorithms

Rabin-Karp Algorithm

A string-searching algorithm that uses hashing to find pattern(s) in a text. Developed by Michael O. Rabin and Richard M. Karp in 1987, it's particularly useful for multiple pattern search and plagiarism detection. Uses rolling hash for efficiency.

String Algorithms

Boyer-Moore Algorithm

One of the most efficient string searching algorithms in practice, using two heuristics: bad character rule and good suffix rule. Developed by Robert S. Boyer and J Strother Moore in 1977, it's the standard benchmark for practical string search, often outperforming other algorithms by skipping sections of text.

String Algorithms

Aho-Corasick Algorithm

A string-searching algorithm for locating elements of a finite set of strings (dictionary) within an input text. Invented by Alfred V. Aho and Margaret J. Corasick in 1975, it's a kind of dictionary-matching algorithm that simultaneously searches for all patterns in linear time, making it extremely efficient for multiple pattern matching.

String Algorithms
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