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Implementing a simple Trie for efficient Levenshtein Distance calculation - Java

UPDATE 3

Done. Below is the code that finally passed all of my tests. Again, this is modeled after Murilo Vasconcelo's modified version of Steve Hanov's algorithm. Thanks to all that helped!

/**
 * Computes the minimum Levenshtein Distance between the given word (represented as an array of Characters) and the
 * words stored in theTrie. This algorithm is modeled after Steve Hanov's blog article "Fast and Easy Levenshtein
 * distance using a Trie" and Murilo Vasconcelo's revised version in C++.
 * 
 * http://stevehanov.ca/blog/index.php?id=114
 * http://murilo.wordpress.com/2011/02/01/fast-and-easy-levenshtein-distance-using-a-trie-in-c/
 * 
 * @param ArrayList<Character> word - the characters of an input word as an array representation
 * @return int - the minimum Levenshtein Distance
 */
private int computeMinimumLevenshteinDistance(ArrayList<Character> word) {

    theTrie.minLevDist = Integer.MAX_VALUE;

    int iWordLength = word.size();
    int[] currentRow = new int[iWordLength + 1];

    for (int i = 0; i <= iWordLength; i++) {
        currentRow[i] = i;
    }

    for (int i = 0; i < iWordLength; i++) {
        traverseTrie(theTrie.root, word.get(i), word, currentRow);
    }
    return theTrie.minLevDist;
}

/**
 * Recursive helper function. Traverses theTrie in search of the minimum Levenshtein Distance.
 * 
 * @param TrieNode node - the current TrieNode
 * @param char letter - the current character of the current word we're working with
 * @param ArrayList<Character> word - an array representation of the current word
 * @param int[] previousRow - a row in the Levenshtein Distance matrix
 */
private void traverseTrie(TrieNode node, char letter, ArrayList<Character> word, int[] previousRow) {

    int size = previousRow.length;
    int[] currentRow = new int[size];
    currentRow[0] = previousRow[0] + 1;

    int minimumElement = currentRow[0];
    int insertCost, deleteCost, replaceCost;

    for (int i = 1; i < size; i++) {

        insertCost = currentRow[i - 1] + 1;
        deleteCost = previousRow[i] + 1;

        if (word.get(i - 1) == letter) {
            replaceCost = previousRow[i - 1];
        } else {
            replaceCost = previousRow[i - 1] + 1;
        }

        currentRow[i] = minimum(insertCost, deleteCost, replaceCost);

        if (currentRow[i] < minimumElement) {
            minimumElement = currentRow[i];
        }
    }

    if (currentRow[size - 1] < theTrie.minLevDist && node.isWord) {
        theTrie.minLevDist = currentRow[size - 1];
    }

    if (minimumElement < theTrie.minLevDist) {

        for (Character c : node.children.keySet()) {
            traverseTrie(node.children.get(c), c, word, currentRow);
        }
    }
}

UPDATE 2

Finally, I've managed to get this to work for most of my test cases. My implementation is practically a direct translation from Murilo's C++ version of Steve Hanov's algorithm. So how should I refactor this algorithm and/or make optimizations? Below is the code...

public int search(String word) {

    theTrie.minLevDist = Integer.MAX_VALUE;

    int size = word.length();
    int[] currentRow = new int[size + 1];

    for (int i = 0; i <= size; i++) {
        currentRow[i] = i;
    }
    for (int i = 0; i < size; i++) {
        char c = word.charAt(i);
        if (theTrie.root.children.containsKey(c)) {
            searchRec(theTrie.root.children.get(c), c, word, currentRow);
        }
    }
    return theTrie.minLevDist;
}
private void searchRec(TrieNode node, char letter, String word, int[] previousRow) {

    int size = previousRow.length;
    int[] currentRow = new int[size];
    currentRow[0] = previousRow[0] + 1;

    int insertCost, deleteCost, replaceCost;

    for (int i = 1; i < size; i++) {

        insertCost = currentRow[i - 1] + 1;
        deleteCost = previousRow[i] + 1;

        if (word.charAt(i - 1) == letter) {
            replaceCost = previousRow[i - 1];
        } else {
            replaceCost = previousRow[i - 1] + 1;
        }
        currentRow[i] = minimum(insertCost, deleteCost, replaceCost);
    }

    if (currentRow[size - 1] < theTrie.minLevDist && node.isWord) {
        theTrie.minLevDist = currentRow[size - 1];
    }

    if (minElement(currentRow) < theTrie.minLevDist) {

        for (Character c : node.children.keySet()) {
            searchRec(node.children.get(c), c, word, currentRow);

        }
    }
}

Thank you everyone who contributed to this question. I tried getting the Levenshtein Automata to work, but I couldn't make it happen.

So I'm looking for suggestions on refactoring and/or optimizations regarding the above code. Please let me know if there's any confusion. As always, I can provide the rest of the source code as needed.


UPDATE 1

So I've implemented a simple Trie data structure and I've been trying to follow Steve Hanov's python tutorial to compute the Levenshtein Distance. Actually, I'm interested in computing the minimum Levenshtein Distance between a given word and the words in the Trie, thus I've been following Murilo Vasconcelos's version of Steve Hanov's algorithm. It's not working very well, but here's my Trie class:

public class Trie {

    public TrieNode root;
    public int minLevDist;

    public Trie() {
        this.root = new TrieNode(' ');
    }

    public void insert(String word) {

        int length = word.length();
        TrieNode current = this.root;

        if (length == 0) {
            current.isWord = true;
        }
        for (int index = 0; index < length; index++) {

            char letter = word.charAt(index);
            TrieNode child = current.getChild(letter);

            if (child != null) {
                current = child;
            } else {
                current.children.put(letter, new TrieNode(letter));
                current = current.getChild(letter);
            }
            if (index == length - 1) {
                current.i开发者_开发技巧sWord = true;
            }
        }
    }
}

... and the TrieNode class:

public class TrieNode {

    public final int ALPHABET = 26;

    public char letter;
    public boolean isWord;
    public Map<Character, TrieNode> children;

    public TrieNode(char letter) {
        this.isWord = false;
        this.letter = letter;
        children = new HashMap<Character, TrieNode>(ALPHABET);
    }

    public TrieNode getChild(char letter) {

        if (children != null) {
            if (children.containsKey(letter)) {
                return children.get(letter); 
            }
        }
        return null;
    }
}

Now, I've tried to implement the search as Murilo Vasconcelos has it, but something is off and I need some help debugging this. Please give suggestions on how to refactor this and/or point out where the bugs are. The very first thing I'd like to refactor is the "minCost" global variable, but that's the smallest of things. Anyway, here's the code...

public void search(String word) {

    int size = word.length();
    int[] currentRow = new int[size + 1];

    for (int i = 0; i <= size; i++) {
        currentRow[i] = i;
    }
    for (int i = 0; i < size; i++) {
        char c = word.charAt(i);
        if (theTrie.root.children.containsKey(c)) {
            searchRec(theTrie.root.children.get(c), c, word, currentRow);
        }
    }
}

private void searchRec(TrieNode node, char letter, String word, int[] previousRow) {

    int size = previousRow.length;
    int[] currentRow = new int[size];
    currentRow[0] = previousRow[0] + 1;

    int replace, insertCost, deleteCost;

    for (int i = 1; i < size; i++) {

        char c = word.charAt(i - 1);

        insertCost = currentRow[i - 1] + 1;
        deleteCost = previousRow[i] + 1;
        replace = (c == letter) ? previousRow[i - 1] : (previousRow[i - 1] + 1);

        currentRow[i] = minimum(insertCost, deleteCost, replace);
    }

    if (currentRow[size - 1] < minCost && !node.isWord) {
        minCost = currentRow[size - 1];
    }
    Integer minElement = minElement(currentRow);
    if (minElement < minCost) {

        for (Map.Entry<Character, TrieNode> entry : node.children.entrySet()) {
            searchRec(node, entry.getKey(), word, currentRow);
        }
    }
}

I apologize for the lack of comments. So what am I doing wrong?

INITIAL POST

I've been reading an article, Fast and Easy Levenshtein distance using a Trie, in hopes of figuring out an efficient way to compute the Levenshtein Distance between two Strings. My main goal with this is, given a large set of words, to be able to find the minimal Levenshtein Distance between an input word(s) and this set of words.

In my trivial implementation, I compute the Levenshtein Distance between an input word and the set of words, for each input word, and return the minimum. It works, but it is not efficient...

I've been looking for implementations of a Trie, in Java, and I've come across two seemingly good sources:

  • Koders.com version
  • code.google.com version (EDIT: This seems to have moved to github.com/rkapsi)

However, these implementations seem too complicated for what I'm trying to do. As I've been reading through them to understand how they work and how Trie data structures work in general, I've only become more confused.

So how would I implement a simple Trie data structure in Java? My intuition tells me that each TrieNode should store the String it represents and also references to letters of the alphabet, not necessarily all letters. Is my intuition correct?

Once that is implemented, the next task is to compute the Levenshtein Distance. I read through the Python code example in the article above, but I don't speak Python, and my Java implementation runs out of Heap memory once I hit the recursive searching. So how would I compute the Levenshtein Distance using the Trie data structure? I have a trivial implementation, modeled after this source code, but it doesn't use a Trie... it is inefficient.

It would be really nice to see some code in addition to your comments and suggestions. After all, this is a learning process for me... I've never implemented a Trie... so I have plenty to learn from this experience.

Thanks.

p.s. I can provide any source code if need be. Also, I've already read through and tried using a BK-Tree as suggested in Nick Johnson's blog, but its not as efficient as I think it can be... or maybe my implementation is wrong.


From what I can tell you don't need to improve the efficiency of Levenshtein Distance, you need to store your strings in a structure that stops you needing to run distance computations so many times i.e by pruning the search space.

Since Levenshtein distance is a metric, you can use any of the metric spaces indices which take advantage of triangle inequality - you mentioned BK-Trees, but there are others eg. Vantage Point Trees, Fixed-Queries Trees, Bisector Trees, Spatial Approximation Trees. Here are their descriptions:

Burkhard-Keller Tree

Nodes are inserted into the tree as follows: For the root node pick an arbitary element from the space; add unique edge-labeled children such that the value of each edge is the distance from the pivot to that element; apply recursively, selecting the child as the pivot when an edge already exists.

Fixed-Queries Tree

As with BKTs except: Elements are stored at leaves; Each leaf has multiple elements; For each level of the tree the same pivot is used.

Bisector Tree

Each node contains two pivot elements with their covering radius (maximum distance between the centre element and any of its subtree elements); Filter into two sets those elements which are closest to the first pivot and those closest to the second, and recursively build two subtrees from these sets.

Spatial Approximation Tree

Initially all elements are in a bag; Choose an arbitrary element to be the pivot; Build a collection of nearest neighbours within range of the pivot; Put each remaining element into the bag of the nearest element to it from collection just built; Recursively form a subtree from each element of this collection.

Vantage Point Tree

Choose a pivot from the set abitrarily; Calculate the median distance between this pivot and each element of the remaining set; Filter elements from the set into left and right recursive subtrees such that those with distances less than or equal to the median form the left and those greater form the right.


I've implemented the algo described on "Fast and Easy Levenshtein distance using a Trie" article in C++ and it is really fast. If you want (understand C++ better than Python), I can past the code in somewhere.

Edit: I posted it on my blog.


Here is an example of Levenshtein Automata in Java (EDIT: moved to github).These will probably also be helpful:

http://svn.apache.org/repos/asf/lucene/dev/trunk/lucene/src/java/org/apache/lucene/util/automaton/ http://svn.apache.org/repos/asf/lucene/dev/trunk/lucene/src/test/org/apache/lucene/util/automaton/

EDIT: The above links seem to have moved to github:

https://github.com/apache/lucene-solr/tree/master/lucene/core/src/java/org/apache/lucene/util/automaton https://github.com/apache/lucene-solr/tree/master/lucene/core/src/test/org/apache/lucene/util/automaton

It looks like the experimental Lucene code is based off of the dk.brics.automaton package.

Usage appears to be something similar to below:

LevenshteinAutomata builder = new LevenshteinAutomata(s);
Automaton automata = builder.toAutomaton(n);
boolean result1 = BasicOperations.run(automata, "foo");
boolean result2 = BasicOperations.run(automata, "bar");


In many ways, Steve Hanov's algorithm (presented in the first article linked in the question, Fast and Easy Levenshtein distance using a Trie), the ports of the algorithm made by Murilo and you (OP), and quite possibly every pertinent algorithm involving a Trie or similar structure, function much like a Levenshtein Automaton (which has been mentioned several times here) does:

Given:
       dict is a dictionary represented as a DFA (ex. trie or dawg)
       dictState is a state in dict
       dictStartState is the start state in dict
       dictAcceptState is a dictState arrived at after following the transitions defined by a word in dict
       editDistance is an edit distance
       laWord is a word
       la is a Levenshtein Automaton defined for laWord and editDistance
       laState is a state in la
       laStartState is the start state in la
       laAcceptState is a laState arrived at after following the transitions defined by a word that is within editDistance of laWord
       charSequence is a sequence of chars
       traversalDataStack is a stack of (dictState, laState, charSequence) tuples

Define dictState as dictStartState
Define laState as laStartState
Push (dictState, laState, "") on to traversalDataStack
While traversalDataStack is not empty
    Define currentTraversalDataTuple as the the product of a pop of traversalDataStack
    Define currentDictState as the dictState in currentTraversalDataTuple
    Define currentLAState as the laState in currentTraversalDataTuple
    Define currentCharSequence as the charSequence in currentTraversalDataTuple
    For each char in alphabet
        Check if currentDictState has outgoing transition labeled by char
        Check if currentLAState has outgoing transition labeled by char
        If both currentDictState and currentLAState have outgoing transitions labeled by char
            Define newDictState as the state arrived at after following the outgoing transition of dictState labeled by char
            Define newLAState as the state arrived at after following the outgoing transition of laState labeled by char
            Define newCharSequence as concatenation of currentCharSequence and char
            Push (newDictState, newLAState, newCharSequence) on to currentTraversalDataTuple
            If newDictState is a dictAcceptState, and if newLAState is a laAcceptState
                Add newCharSequence to resultSet
            endIf
        endIf
    endFor
endWhile

Steve Hanov's algorithm and its aforementioned derivatives obviously use a Levenshtein distance computation matrix in place of a formal Levenshtein Automaton. Pretty fast, but a formal Levenshtein Automaton can have its parametric states (abstract states which describe the concrete states of the automaton) generated and used for traversal, bypassing any edit-distance-related runtime computation whatsoever. So, it should be run even faster than the aforementioned algorithms.

If you (or anybody else) is interested in a formal Levenshtein Automaton solution, have a look at LevenshteinAutomaton. It implements the aforementioned parametric-state-based algorithm, as well as a pure concrete-state-traversal-based algorithm (outlined above) and dynamic-programming-based algorithms (for both edit distance and neighbor determination). It's maintained by yours truly :) .


My intuition tells me that each TrieNode should store the String it represents and also references to letters of the alphabet, not necessarily all letters. Is my intuition correct?

No, a trie doesn't represent a String, it represents a set of strings (and all their prefixes). A trie node maps an input character to another trie node. So it should hold something like an array of characters and a corresponding array of TrieNode references. (Maybe not that exact representation, depending on efficiency in your particular use of it.)


As I see it right, you want to loop over all branches of the trie. That's not that difficult using a recursive function. I'm using a trie as well in my k-nearest neighbor algorithm, using the same kind of function. I don't know Java, however but here's some pseudocode:

function walk (testitem trie)
   make an empty array results
   function compare (testitem children distance)
     if testitem = None
        place the distance and children into results
     else compare(testitem from second position, 
                  the sub-children of the first child in children,
                  if the first item of testitem is equal to that 
                  of the node of the first child of children 
                  add one to the distance (! non-destructive)
                  else just the distance)
        when there are any children left
             compare (testitem, the children without the first item,
                      distance)
    compare(testitem, children of root-node in trie, distance set to 0)
    return the results

Hope it helps.


The function walk takes a testitem (for example a indexable string, or an array of characters) and a trie. A trie can be an object with two slots. One specifying the node of the trie, the other the children of that node. The children are tries as well. In python it would be something like:

class Trie(object):
    def __init__(self, node=None, children=[]):
        self.node = node
        self.children = children

Or in Lisp...

(defstruct trie (node nil) (children nil))

Now a trie looks something like this:

(trie #node None
      #children ((trie #node f
                       #children ((trie #node o
                                        #children ((trie #node o
                                                         #children None)))
                                  (trie #node u
                                        #children ((trie #node n
                                                         #children None)))))))

Now the internal function (which you also can write separately) takes the testitem, the children of the root node of the tree (of which the node value is None or whatever), and an initial distance set to 0.

Then we just recursively traverse both branches of the tree, starting left and then right.


I'll just leave this here in case anyone is looking for yet another treatment of this problem:

http://code.google.com/p/oracleofwoodyallen/wiki/ApproximateStringMatching


I was looking at your latest update 3, the algorithm seem not work well for me.

Let s see you have below test cases:

    Trie dict = new Trie();
    dict.insert("arb");
    dict.insert("area");

    ArrayList<Character> word = new ArrayList<Character>();
    word.add('a');
    word.add('r');
    word.add('c');

In this case, the minimum edit distance between "arc" and the dict should be 1, which is the edit distance between "arc" and "arb", but you algorithms will return 2 instead.

I went through the below code piece:

        if (word.get(i - 1) == letter) {
            replaceCost = previousRow[i - 1];
        } else {
            replaceCost = previousRow[i - 1] + 1;
        }

At least for the first loop, the letter is one of the characters in the word, but instead, you should be compare the nodes in the trie, so there will be one line duplicate with the first character in the word, is that right? each DP matrix has the first line as a duplicate. I executed the exact same code you put on the solution.


Well, here's how I did it a long time ago. I stored the dictionary as a trie, which is simply a finite-state-machine restricted to the form of a tree. You can enhance it by not making that restriction. For example, common suffixes can simply be a shared subtree. You could even have loops, to capture stuff like "nation", "national", "nationalize", "nationalization", ...

Keep the trie as absolutely simple as possible. Don't go stuffing strings in it.

Remember, you don't do this to find the distance between two given strings. You use it to find the strings in the dictionary that are closest to one given string. The time it takes depends on how much levenshtein distance you can tolerate. For distance zero, it is simply O(n) where n is the word length. For arbitrary distance, it is O(N) where N is the number of words in the dictionary.


Correct me if I am wrong but I believe your update3 has an extra loop which is unnecesary and makes the program much slower:

for (int i = 0; i < iWordLength; i++) {
    traverseTrie(theTrie.root, word.get(i), word, currentRow);
}

You ought to call traverseTrie only once because within traverseTrie you are already looping over the whole word. The code should be only as follows:

traverseTrie(theTrie.root, ' ', word, currentRow);
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