INTRODUCTION
============
Morfette website: https://code.google.com/p/morfette/
Morfette is a tool for supervised learning of inflectional
morphology. Given a corpus of sentences annotated with lemmas
and morphological labels, and optionally a lexicon, morfette
learns how to morphologically analyze new sentences.
In the learning stage Morfette fits two separate logistic regression
models: one for morphological tagging and one for lemmatization. The
predictions of the models are combined dynamically and produce a
globally plausible sequence of morphological-tag - lemma pairs for
a sentence.
In Morfette lemmatization is cast as a classification task where a
a lemmatization class corresponds to the specification of the edit
operations which are needed to transform the inflected word form into
the corresponding lemma.
The basic approach is described in (Chrupała et al 2008 and Chrupała 2008).
The current version of Morfette uses an averaged perceptron to
fit the models, rather than Maximum Entropy training. The lemmatization
classes are Edit-Tree-based as described in (Chrupała 2008).
LICENSE
=======
The source code in the src directory is licensed under
the BSD license.
INSTALLATION
============
The easiest way to install Morfette is to first install the Haskell
Platform <http://www.haskell.org/platform/> then execute the following
commands from within the morfette directory:
> cabal update
> cabal install --bindir=$HOME/bin
This will compile Morfette and install the executable in $HOME/bin.
Cabal can also download Morfette from the source code repository
Hackage:
> cabal install morfette --bindir=$HOME/bin --datadir=$HOME/share
This will download Morfette, compile it, install the executable in
$HOME/bin, and install the data files in a $HOME/share.
There are also pre-built binaries available from the project website.
USAGE
=====
Usage: morfette command [OPTION...] [ARG...]
train: train models
train [OPTION...] TRAIN-FILE MODEL-DIR
--dict-file=PATH path to optional dictionary
--language-configuration=es|pl|tr|.. language configuration
--iter-pos=NUM iterations for POS model
--iter-lemma=NUM iterations for Lemma model
extract-features:
extract features
extract-features [OPTION...] MODEL-DIR
--dict-file=PATH path to optional dictionary
--model-id=pos|lemma model id (`pos' or `lemma')
predict: predict postags and lemmas using saved model data
predict [OPTION...] MODEL-DIR
--beam=+INT beam size to use
--tokenize tokenize input
--multi=+INT n-best output
eval: evaluate morpho-tagging and lemmatization results
eval [OPTION...] TRAIN-FILE GOLD-FILE TEST-FILE
--ignore-case ignore case for evaluation
--baseline-file=PATH path to baseline results
--dict-file=PATH path to optional dictionary
--ignore-punctuation ignore punctuation for evaluation
--ignore-pos=POS-prefix ignore POS starting with POS-prefix for evaluation
version: show version
version [OPTION...]
EXAMPLE USAGE
=============
To train a new model:
> morfette train --dict-file=DICT TRAINING-FILE MODEL-DIR
To use the model in MODEL-DIR to analyze new data:
> morfette predict MODEL-DIR < TEST-DATA > ANALYZED-TEST-DATA
PRETRAINED MODELS
=================
Pretrained models for Spanish and French are available in the data
directory: data/es/model and data/fr/model. For example you can use
the Spanish model like this:
> morfette predict data/es/model < TEST-DATA > ANALYZER-TEST-DATA
DATA FORMAT
===========
Morfette expects both training and testing data to be tokenized and
split into sentences. The format of training data look like this:
Gómez Gómez np0000p
sostiene sostener vmip3s0
que que cs
la el da0fs0
propuesta propuesta ncfs000
no no rn
cambiará cambiar vmif3s0
. . Fp
La el da0fs0
propuesta propuesta ncfs000
será ser vsif3s0
la el da0fs0
misma mismo pi0fs000
There is one token per line, with three columns separated by spaces or
tabs. The columns contain word form, lemma and morphological tag
respectively. Sentences are separated by an empty line. Text should be
encoded in UTF-8.
Test data format is similar, except only the first column is needed:
Gómez
sostiene
que
la
propuesta
no
cambiará
.
La
propuesta
será
la
misma
Optionally, Morfette can also use vector representations of words for
training and prediction, in addition to character strings, as
described in [3]. In this case, the second column of is used for the
vectors. Inside this field vector components are separated by commas:
Gómez 0.1,0.0,0.9 Gómez np0000p
sostiene 0.0,0.0,0.2 sostener vmip3s0
For prediction the format is similar, but only the first two columns
are used:
Gómez 0.1,0.0,0.9
sostiene 0.0,0.0,0.2
Each vector should have the same number of components.
References
==========
[1] Grzegorz Chrupała, Georgiana Dinu and Josef van Genabith. 2008.
Learning Morphology with Morfette. In Proceedings of LREC 2008.
http://www.lrec-conf.org/proceedings/lrec2008/pdf/594_paper.pdf
[2] Grzegorz Chrupała. 2008. Towards a Machine-Learning Architecture
for Lexical Functional Grammar Parsing. Chapter 6. PhD
dissertation, Dublin City
University.
http://grzegorz.chrupala.me/papers/phd.pdf
[3] Grzegorz Chrupała. 2010. Efficient induction of probabilistic word
classes with LDA. IJCNLP.
http://grzegorz.chrupala.me/papers/ijcnlp-2011.pdf