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TectoMT Tutorial
Welcome at TectoMT Tutorial. This tutorial should take about 2 hours.
What is TectoMT
TectoMT is a highly modular NLP (Natural Language Processing) software system implemented in Perl programming language under Linux. It is primarily aimed at Machine Translation, making use of the ideas and technology created during the Prague Dependency Treebank project. At the same time, it is also hoped to significantly facilitate and accelerate development of software solutions of many other NLP tasks, especially due to re-usability of the numerous integrated processing modules (called blocks), which are equipped with uniform object-oriented interfaces.
Prerequisities
In this tutorial, we assume that TectoMT has been successfully installed on your machine. For installation details, see Getting started in TectoMT Developer's Guide.
Before running any experiments with TectoMT, you must set up your environment by running
source devel/config/init_shell_environ.sh
Theoretical background
TrEd
TectoMT Architecture
In TectoMT, there is the following hierarchy of processing units (software components that process data):
- The basic units are blocks. They serve for some very limited, well defined, and often linguistically interpretable tasks (e.g., tokenization, tagging, parsing). Blocks are not parametrizable. Technically, blocks are Perl classes inherited from
TectoMT::Block
. Blocks can be found indevel/libs/blocks/
- To solve a more complex task, selected blocks can be chained into a block sequence, called also a scenario. Technically, scenarios are instances of
TectoMT::Scenario
class, but in some situations (e.g. on the command line) it is sufficient to specify the scenario simply by listing block names separated with spaces. - The highest unit is called application. Applications correspond to end-to-end tasks, be they real end-user applications (such as machine translation), or 'only' NLP-related experiments. Technically, applications are often implemented as
Makefiles
, which only glue the components existing in TectoMT. Some demo applications, including this tutorial, can be found indevel/applications/
Layers of Linguistic Structures
TectoMT blocks repository is saved in devel/libs/blocks/
. In correspondence with …, the blocks are located in directories describing their purpose.
Thus, the set of TectoMT layers is Cartesian product {S,T} x {English,Czech} x {W,M,P,A,T}, in which:
- {S,T} distinguishes whether the data was created by analysis or transfer/synthesis (mnemonics: S and T correspond to (S)ource and (T)arget in MT perspective).
- {English,Czech…} represents the language in question
- {W,M,P,A,T…} represents the layer of description in terms of PDT 2.0 (W - word layer, M - morphological layer, A - analytical layer, T - tectogrammatical layer) or extensions (P - phrase-structure layer).
Example: Block adding Czech morphological tags (pos, case, gender, etc.) can be found in devel/libs/blocks/SCzechW_toSCzechM/Simple_tagger.pm
.
There are also other directories for other purpose blocks, for example blocks which only print out some information go to devel/libs/Print
.
First application
Once you have TectoMT installed on your machine, you can find this tutorial in devel/applications/tutorial/
. After you cd in to this directory, you can see our plain text sample data in sample.txt
.
Most applications are defined in Makefiles, which describe sequence of blocks to be applied on our data. In our particular Makefile
, four blocks are going to be applied on our sample text: sentence segmentation, tokenization, tagging and lemmatization. Since we have our input text in plain text format, the file is going to be converted into tmt
format beforehand (the in
section).
We can run the application:
make all
Our plain text data sample.txt
have been transformed into tmt
, internal TectoMT format, and saved into sample.tmt
. Then, all four blocks have been loaded and our data has been processed. We can now examine sample.tmt
using a regular text editor. We'll now stop and describe data structure in TectoMT.
- One physical file corresponds to one document.
- A document consists of a sequence of bundles (
<bundle>
), mirroring a sequence of natural language sentences originating from the text. So, for one sentence we have one<bundle>
. - Each bundle contains tree shaped sentence representations on various linguistic layers. In our example
sample.tmt
we have morphological tree (SEnglishM
) in each bundle. Later on, also an analytical layer (SEnglishA
) will appear in each bundle as we proceed with our analysis. - Trees are formed by nodes and edges. Attributes can be attached only to nodes. Edge's attributes must be equivalently stored as the lower node's attributes. Tree's attributes must be stored as attributes of the root node.
Changing the scenario
We'll now add syntax analysis to our scenario by adding four more blocks. Instead of
analyze: eval ${BRUNBLOCKS} -S -o \ SEnglishW_to_SEnglishM::Sentence_segmentation_simple \ SEnglishW_to_SEnglishM::Penn_style_tokenization \ SEnglishW_to_SEnglishM::TagTnT \ SEnglishW_to_SEnglishM::Lemmatize_mtree -- sample.tmt
we'll have:
analyze: eval ${BRUNBLOCKS} -S -o \ SEnglishW_to_SEnglishM::Sentence_segmentation_simple \ SEnglishW_to_SEnglishM::Penn_style_tokenization \ SEnglishW_to_SEnglishM::TagTnT \ SEnglishW_to_SEnglishM::Lemmatize_mtree \ SEnglishM_to_SEnglishA::McD_parser_local \ SEnglishM_to_SEnglishA::Fix_McD_Tree \ SEnglishM_to_SEnglishA::Fill_afun_after_McD -- sample.tmt
Note: Makefiles use tabulators to mark command lines. Make sure your lines start with tabulator (or two tabulators) and not, for example, with 4 spaces.
After running
make all
we can examine our sample.tmt
again. Really, an analytical layer SEnglishA
describing a dependency tree with analytical functions (<afun>
) has been added to each bundle.
Adding a new block
The linguistic structures in TectoMT are represented using the following object-oriented interface/types:
- document -
TectoMT::Document
- bundle -
TectoMT::Bundle
- node -
TectoMT::Node
We'll now examine an example of a new block in file devel/applications/tutorial/Tutorial.pm
This block illustrates the most common methods for accessing objects:
my @bundles = $document→get_bundles
- an array of bundles contained in the documentmy $root_node = $bundle→get_tree($layer_name);
- the root node of the tree of the given type in the given bundlemy @children = $node→get_children;
- array of the node's childrenmy @descendants = $node→get_descendants;
- array of the node's children and their children and children of their children …my $parent = $node→get_parent;
- parent node of the given node, or undef for rootmy $root_node = $node→get_root;
- the root node of the tree into which the node belongs
Attributes of documents, bundles or nodes can be accessed by attribute getters and setters, for example:
$node→get_attr($attr_name);
$node→set_attr($attr_name, $attr_value);
Our tutorial block Tutorial.pm
is ready to use and we only have to copy it to the blocks repository devel/libs/blocks/Print
.
cp devel/applications/Tutorial.pm devel/libs/blocks/Print/Tutorial.pm
We also have to add this block to our scenario which can be done by adding new Makefile
target:
printafun: eval ${BRUNBLOCKS} -S -o \ Print::Tutorial -- sample.tmt
And we'll observe our new block's behaviour:
make printfun
More advanced block
In this application, we'll split the text into finite clauses.