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The Porter Stemming Algorithm



This page was completely revised Jan 2006. The earlier edition is here.

This is the ‘official’ home page for distribution of the Porter Stemming Algorithm, written and maintained by its author, Martin Porter.

The Porter stemming algorithm (or ‘Porter stemmer’) is a process for removing the commoner morphological and inflexional endings from words in English. Its main use is as part of a term normalisation process that is usually done when setting up Information Retrieval systems.


History

The original stemming algorithm paper was written in 1979 in the Computer Laboratory, Cambridge (England), as part of a larger IR project, and appeared as Chapter 6 of the final project report,
C.J. van Rijsbergen, S.E. Robertson and M.F. Porter, 1980. New models in probabilistic information retrieval. London: British Library. (British Library Research and Development Report, no. 5587).
With van Rijsbergen’s encouragement, it was also published in,
M.F. Porter, 1980, An algorithm for suffix stripping, Program, 14(3) pp 130−137.
And since then it has been reprinted in
Karen Sparck Jones and Peter Willet, 1997, Readings in Information Retrieval, San Francisco: Morgan Kaufmann, ISBN 1-55860-454-4.
The original stemmer was written in BCPL, a language once popular, but now defunct. For the first few years after 1980 it was distributed in its BCPL form, via the medium of punched paper tape. Versions in other languages soon began to appear, and by 1999 it was being widely used, quoted and adapted. Unfortunately there were numerous variations in functionality among these versions, and this web page was set up primarily to ‘put the record straight’ and establish a definitive version for distribution.


Encodings

The ANSI C version that heads the table below is exactly equivalent to the original BCPL version. The BCPL version did, however, differ in three minor points from the published algorithm and these are clearly marked in the downloadable ANSI C version. They are discussed further below.

This ANSI C version may be regarded as definitive, in that it now acts as a better definition of the algorithm than the original published paper.

Over the years, I have received many encoding from other workers, and they are also presented below. I have a reasonable confidence that all these versions are correctly encoded.



language     author     affiliation     received     notes
ANSI C     me
ANSI C thread safe     me
java     me
Perl     me
Perl     Daniel van Balen         Oct 1999     slightly faster?
python     Vivake Gupta         Jan 2001    
Csharp     André Hazelwood     The Official Web Guide     Sep 2001    
Csharp .NET compliant     Leif Azzopardi     Univerity of Paisley, Scotland     Nov 2002    
Csharp again!     Brad Patton     ratborg.blogspot.com     Dec 2015     "more like standard
C# code" (Brad)
Csharp and again!     Frank Kolnick         Jan 2021     "compacted and
simplified" (Frank)
Common Lisp     Steven M. Haflich     Franz Inc     Mar 2002    
Ruby     Ray Pereda     www.raypereda.com     Jan 2003     github link
Visual Basic VB6     Navonil Mustafee     Brunel University     Apr 2003    
Delphi     Jo Rabin         Apr 2004    
Javascript     ‘Andargor’     www.andargor.com     Jul 2004     substantial revisions by
Christopher McKenzie
Visual Basic
VB7; .NET compliant    
Christos Attikos     University of Piraeus, Greece     Jan 2005    
php     Richard Heyes     www.phpguru.org     Feb 2005    
Prolog     Philip Brooks     University of Georgia     Oct 2005    
Haskell     Dmitry Antonyuk         Nov 2005    
T-SQL     Keith Lubell     www.atelierdevitraux.com     May 2006    
matlab     Juan Carlos Lopez     California Pacific Medical Center
Research Institute
   
Sep 2006    
Tcl     Aris Theodorakos     NCSR Demokritos     Nov 2006    
D     Daniel Truemper     Humboldt-Universitaet zu Berlin     May 2007    
erlang (1) erlang (2)     Alden Dima     National Institute of Standards and
Technology, Gaithersburg, MD USA    
Sep 2007    
REBOL     Dale K Brearcliffe         Apr 2009    
Scala     Ken Faulkner         May 2009    
sas     Antoine St-Pierre     Business Researchers, Inc     Apr 2010    
plugin vim script     Mitchell Bowden         May 2010     github link
node.js     Jed Parsons     jedparsons.com     May 2011     github link
Google Go     Alex Gonopolskiy         Oct 2011     github link
awk     Gregory Grefenstette     3ds.com/exalead     Jul 2012    
clojure     Yushi Wang         Mar 2013     bitbucket link
Rust     Do Nhat Minh     Nanyang Technological University     Aug 2013     github link
vala     Serge Hulne         Sep 2013    
MySQL     John Carty     Enlighten Jobs     Jan 2015     github link
Julia     Matías Guzmán Naranjo         May 2015     github link
flex     Zalán Bodó     Babes-Bolyai University     Oct 2015     (Zalan’s notes)
R     Mohit Makkar     Indian Institute of Technology, Delhi     Nov 2015    
Groovy     Dhaval Dave         Jun 2016     github link
ooRexx     P.O. Jonsson         Jul 2016     sourceforge link
XSLT     Joey Takeda         Feb 2019     github link
LPA Win-Prolog     Brian D Steel     solanum.org     Apr 2020    
GNU PSPP     Frans Houweling         Feb 2023    
TypeScript     Max Patiiuk         May 2023     github link


All these encodings of the algorithm can be used free of charge for any purpose. Questions about the algorithms should be directed to their authors, and not to Martin Porter (except when he is the author).

To test the programs out, here is a sample vocabulary (0.19 megabytes), and the corresponding output.

Email any comments, suggestions, queries


Points of difference from the published algorithm

There is an extra rule in Step 2,
(m>0) logi  →  log
So archaeology is equated with archaeological etc.

The Step 2 rule
(m>0) abli  →  able
is replaced by
(m>0) bli  →  ble
So possibly is equated with possible etc.

The algorithm leaves alone strings of length 1 or 2. In any case a string of length 1 will be unchanged if passed through the algorithm, but strings of length 2 might lose a final s, so as goes to a and is to i.

These differences may have been present in the program from which the published algorithm derived. But at such a great distance from the original publication it is now difficult to say.

It must be emphasised that these differences are very small indeed compared to the variations that have been observed in other encodings of the algorithm.


Status

The Porter stemmer should be regarded as ‘frozen’, that is, strictly defined, and not amenable to further modification. As a stemmer, it is slightly inferior to the Snowball English or Porter2 stemmer, which derives from it, and which is subjected to occasional improvements. For practical work, therefore, the new Snowball stemmer is recommended. The Porter stemmer is appropriate to IR research work involving stemming where the experiments need to be exactly repeatable.

Common errors

Historically, the following shortcomings have been found in other encodings of the stemming algorithm.

The algorithm clearly explains that when a set of rules of the type
(condition)S1  →  S2
are presented together, only one rule is applied, the one with the longest matching suffix S1 for the given word. This is true whether the rule succeeds or fails (i.e. whether or not S2 replaces S1). Despite this, the rules are sometimes simply applied in turn until either one of them succeeds or the list runs out.

This leads to small errors in various places, for example in the Step 4 rules
(m>1)ement  → 
(m>1)ment  → 
(m>1)ent  → 
to remove final ement, ment and ent.

Properly, argument stems to argument. The longest matching suffix is -ment. Then stem argu- has measure m equal to 1 and so -ment will not be removed. End of Step 4. But if the three rules are applied in turn, then for suffix -ent the stem argum- has measure m equal to 2, and -ent gets removed.

The more delicate rules are liable to misinterpretation. (Perhaps greater care was required in explaining them.) So
((m>1) and (*s or *t))ion
is taken to mean
(m>1)(s or t)ion
The former means that taking off -ion leaves a stem with measure greater than 1 ending -s or -t; the latter means that taking off -sion or -tion leaves a stem of measure greater than 1. A similar confusion tends to arise in interpreting rule 5b, to reduce final double L to single L.

Occasionally cruder errors have been seen. For example the test for Y being consonant or vowel set up the wrong way round.

It is interesting that although the published paper explains how to do the tests on the strings S1 by a program switch on the last or last but one letter, many encodings fail to use this technique, making them much slower than they need be.


FAQs (frequently asked questions)


#1. What is the licensing arrangement for this software?

This question has become very popular recently (the period 2008−2009), despite the clear statment above that ‘‘all these encodings of the algorithm can be used free of charge for any purpose.’’ The problem I think is that intellectual property has become such a major issue that some more formal statement is expected. So to restate it:

The software is completely free for any purpose, unless notes at the head of the program text indicates otherwise (which is rare). In any case, the notes about licensing are never more restrictive than the BSD License.

In every case where the software is not written by me (Martin Porter), this licensing arrangement has been endorsed by the contributor, and it is therefore unnecessary to ask the contributor again to confirm it.

I have not asked any contributors (or their employers, if they have them) for proofs that they have the right to distribute their software in this way.

(For anyone taking software from the Snowball website, the position is similar but simpler. There, all the software is issued under the BSD License, and for contributions not written by Martin Porter and Richard Boulton, we have again not asked the authors, or the authors’ employers, for proofs that they have such distribution rights.)


#2. Why is the stemmer not producing proper words?

It is often taken to be a crude error that a stemming algorithm does not leave a real word after removing the stem. But the purpose of stemming is to bring variant forms of a word together, not to map a word onto its ‘paradigm’ form.

And connected with this,


#3. Why are there errors?

The question normally comes in the form, why should word X be stemmed to x1, when one would have expected it to be stemmed to x2? It is important to remember that the stemming algorithm cannot achieve perfection. On balance it will (or may) improve IR performance, but in individual cases it may sometimes make what are, or what seem to be, errors. Of course, this is a different matter from suggesting an additional rule that might be included in the stemmer to improve its performance.