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I need to calculate the edit distance between trees for a personal project of mine. This paper describes an algorithm, but I can't make heads or tails out of it. Are you aware of any resources that describe an applicable algorithm in a more approachable way? Pseudocode or code would be helpful, too.

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7 Answers

up vote 2 down vote accepted

Here's some java source code (gzipped tarball at the bottom) for a Tree Edit Distance algorithm that might be useful to you.

The page includes references and some slides that go through the "Zhang and Shasha" algorithm step-by-step and other useful links to get you up to speed.

Edit: While this answer was accepted because it pointed to the Zhang-Shasha algorithm, the code in the link has bugs. Steve Johnson and tim.tadh have provided working Python code. See Steve Johnson's comment for more details.

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The implementation linked here is incorrect. (See my answer.) I started my implementation by porting it, but when I finally found the paper it was referencing, I found a few departures from the original paper which caused it to fail basic tests of symmetry, triangle inequality, etc. –  Steve Johnson Nov 24 '10 at 17:32
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(Edited this answer to link to current version of the implementation given by tim.tadh)

This Python library implements the Zhang-Shasha algorithm correctly: https://github.com/timtadh/zhang-shasha

It began as a direct port of the Java source listed in the currently accepted answer (the one with the tarball link), but that implementation is not correct and is nearly impossible to run at all.

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Thanks for contributing that back -- glad you were able to implement the Zhang-Shasha algorithm correctly. Sorry the code I linked to wasn't working. –  Naaff Nov 24 '10 at 18:27
2  
Steve's fork is no longer the canonical fork of the algorithm see: github.com/timtadh/zhang-shasha –  tim.tadh Dec 8 '10 at 9:42
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I wrote an implementation (https://github.com/hoonto/jqgram.git) based on the existing PyGram Python code (https://github.com/Sycondaman/PyGram) for those of you who wish to use tree edit distance approximation using PQ-Gram algorithm in the browser and/or in Node.js.

The jqgram tree edit distance approximation module implements the PQ-Gram algorithm for both server-side and browser-side applications; O(n log n) time and O(n) space performant where n is the number of nodes. See the academic paper from which the algorithm comes: (http://www.vldb2005.org/program/paper/wed/p301-augsten.pdf)

The PQ-Gram approximation is much faster than obtaining the true edit distance via Zhang & Shasha, Klein, or Guha et. al, whom provide true edit distance algorithms that all perform minimum O(n^2) time and are therefore often unsuitable.

Often in real-world applications it is not necessary to know the true edit distance if a relative approximation of multiple trees to a known standard can be obtained. Javascript, in the browser and now on the server with the advent of Node.js deal frequently with tree structures and end-user performance is usually critical in algorithm implementation and design; thus jqgram.

Example:

var jq = require("jqgram").jqgram;
var root1 = {
    "thelabel": "a",
    "thekids": [
        { "thelabel": "b",
        "thekids": [
            { "thelabel": "c" },
            { "thelabel": "d" }
        ]},
        { "thelabel": "e" },
        { "thelabel": "f" }
    ]
}

var root2 = {
    "name": "a",
    "kiddos": [
        { "name": "b",
        "kiddos": [
            { "name": "c" },
            { "name": "d" },
            { "name": "y" }
        ]},
        { "name": "e" },
        { "name": "x" }
    ]
}

jq.distance({
    root: root1,
    lfn: function(node){ return node.thelabel; },
    cfn: function(node){ return node.thekids; }
},{
    root: root2,
    lfn: function(node){ return node.name; },
    cfn: function(node){ return node.kiddos; }
},{ p:2, q:3, depth:10 },
function(result) {
    console.log(result.distance);
});

Note that the lfn and cfn parameters specify how each tree should determine the node label names and the children array for each tree root independently so that you can do funky things like comparing an object to a browser DOM for example. All you need to do is provide those functions along with each root and jqgram will do the rest, calling your lfn and cfn provided functions to build out the trees. So in that sense it is (in my opinion anyway) much easier to use than PyGram. Plus, its Javascript, so use it client or server-side!

Now one approach you can use is to use jqgram or PyGram to get a few trees that are close and then go on to use a true edit distance algorithm against a smaller set of trees, why spend all the computation on trees you can already easily determine are very distant, or vice versa. So you can use jqgram to narrow down choices too.

Hope the code helps some folks out.

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See also this answer. –  Jonathan Leffler Jun 16 '13 at 5:20
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There is a journal version of the ICALP2007 paper you refer to at http://www.wisdom.weizmann.ac.il/~oweimann/Publications/TEDinTALG.pdf This version also has a pseudocode.

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There are many variations of tree edit distance. If you can go with top-down tree edit distance, which limits insertions and deletes to the leaves, I suggest trying the following paper: http://portal.acm.org/citation.cfm?id=671669&dl=GUIDE&coll=GUIDE&CFID=68408627&CFTOKEN=54202965. The implementation is a straightforward dynamic programming matrix with O(n2) cost.

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Here you find Java implementations of tree edit distance algorithms:

http://www.inf.unibz.it/dis/projects/tree-edit-distance

In addition to Zhang&Shasha's algorithm of 1989, there are also tree edit distance implementations of more recent algorithms including Klein 1998, Demaine et al. 2009, and the Robust Tree Edit Distance (RTED) algorithm by Pawlik&Augsten, 2011.

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I think you're just looking for the shortest path between two verticies. If so, you can use Dijkstra's algorithm. (The wikipedia page has pseudocode on it for you to refer to.)

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Tree Edit Distance is the cost associated with the "edit script" (series of edit operations) that turns one tree into another. I don't think you can directly use Dijkstra's algorithm for that. –  Naaff Jun 30 '09 at 19:21
1  
@Naaff: In fact you can use Dijkstra's algorithm for that (I wouldn't recommend it though). The nodes of the graph will be the OP's problem's trees, and they will have edges to trees with edit distance 1. This graph is infinite and therefore you won't store it in memory, but rather will compute it as you go. For trees that are not very near this algorithm will have an utterly horrible performance and memory consumption. –  yairchu Jul 1 '09 at 10:11
    
@yairchu: Thanks for the insight. Interesting to see how one could use Dijkstra's algorithm, even if one shouldn't. :) –  Naaff Jul 1 '09 at 20:38
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