For substrings and fuzzy matches, the Levenshtein distance algorithm has worked fairly well for me. Though I will admit it does not seem to be as perfect as industry implementations of autocomplete/suggest. Both Google and Microsoft's Intellisense do a better job, I think because they've refined this basic algorithm to weigh the kind of edit operations it takes to match the dissimilar strings. E.g. transposing two characters should probably only count as 1 operation, not 2 (an insert & delete).
But even so I find this is close enough. Here is it's implementation in C#...
// This is the traditional Levenshtein Distance algorithem, though I've tweaked it to make
// it more like Google's autocomplete/suggest. It returns the number of operations
// (insert/delete/substitute) required to change one string into another, with the
// expectation that userTyped is only a partial version of fullEntry.
// Gives us a measurement of how similar the two strings are.
public static int EditDistance(string userTyped, string fullEntry)
if (userTyped.Length == 0) // all entries are assumed to be fully legit possibilities
return 0; // at this point, because the user hasn't typed anything.
var inx = fullEntry.IndexOf(userTyped);
if (inx < 0) // If the 1st character doesn't exist anywhere in the entry, it's not
return Int32.MaxValue; // a possible match.
var lastInx = inx;
var lastMatchCount = 0;
// Is there a better starting point?
var len = fullEntry.Length - inx;
var matchCount = 1;
var k = 1;
for (; k < len; k++)
if (k == userTyped.Length || userTyped[k] != fullEntry[k + inx])
if (matchCount > lastMatchCount)
lastMatchCount = matchCount;
lastInx = inx;
inx = fullEntry.IndexOf(userTyped, inx + 1);
matchCount = 0;
if (inx > 0)
if (k == len && matchCount > lastMatchCount)
lastInx = inx;
if (lastInx > 0)
fullEntry = fullEntry.Substring(lastInx); // Jump to 1st character match, ignoring previous values
// The start of the Levenshtein Distance algorithem.
var m = userTyped.Length;
var n = Math.Min(m, fullEntry.Length);
int[,] d = new int[m + 1, n + 1]; // "distance" - meaning number of operations.
for (var i = 0; i <= m; i++)
d[i, 0] = i; // the distance of any first string to an empty second string
for (var j = 0; j <= n; j++)
d[0, j] = j; // the distance of any second string to an empty first string
for (var j = 1; j <= n; j++)
for (var i = 1; i <= m; i++)
if (userTyped[i - 1] == fullEntry[j - 1])
d[i, j] = d[i - 1, j - 1]; // no operation required
d[i, j] = Math.Min
d[i - 1, j] + 1, // a deletion
d[i, j - 1] + 1, // an insertion
d[i - 1, j - 1] + 1 // a substitution
return d[m, n];