Class | Description |
---|---|
Analyzer |
An Analyzer builds TokenStreams, which analyze text.
|
Analyzer.ReuseStrategy |
Strategy defining how TokenStreamComponents are reused per call to
Analyzer.tokenStream(String, java.io.Reader) . |
Analyzer.TokenStreamComponents |
This class encapsulates the outer components of a token stream.
|
AnalyzerWrapper |
Extension to
Analyzer suitable for Analyzers which wrap
other Analyzers. |
CachingTokenFilter |
This class can be used if the token attributes of a TokenStream
are intended to be consumed more than once.
|
CharacterUtils |
Utility class to write tokenizers or token filters.
|
CharacterUtils.CharacterBuffer |
A simple IO buffer to use with
CharacterUtils.fill(CharacterBuffer, Reader) . |
CharArrayMap<V> |
A simple class that stores key Strings as char[]'s in a
hash table.
|
CharArraySet |
A simple class that stores Strings as char[]'s in a
hash table.
|
CharFilter |
Subclasses of CharFilter can be chained to filter a Reader
They can be used as
Reader with additional offset
correction. |
DelegatingAnalyzerWrapper |
An analyzer wrapper, that doesn't allow to wrap components or readers.
|
FilteringTokenFilter |
Abstract base class for TokenFilters that may remove tokens.
|
GraphTokenFilter |
An abstract TokenFilter that exposes its input stream as a graph
Call
GraphTokenFilter.incrementBaseToken() to move the root of the graph to the next
position in the TokenStream, GraphTokenFilter.incrementGraphToken() to move along
the current graph, and GraphTokenFilter.incrementGraph() to reset to the next graph
based at the current root. |
LowerCaseFilter |
Normalizes token text to lower case.
|
StopFilter |
Removes stop words from a token stream.
|
StopwordAnalyzerBase |
Base class for Analyzers that need to make use of stopword sets.
|
TokenFilter |
A TokenFilter is a TokenStream whose input is another TokenStream.
|
Tokenizer |
A Tokenizer is a TokenStream whose input is a Reader.
|
TokenStream | |
TokenStreamToAutomaton |
Consumes a TokenStream and creates an
Automaton
where the transition labels are UTF8 bytes (or Unicode
code points if unicodeArcs is true) from the TermToBytesRefAttribute . |
WordlistLoader |
Loader for text files that represent a list of stopwords.
|
API and code to convert text into indexable/searchable tokens. Covers Analyzer
and related classes.
Lucene, an indexing and search library, accepts only plain text input.
Applications that build their search capabilities upon Lucene may support documents in various formats – HTML, XML, PDF, Word – just to name a few. Lucene does not care about the Parsing of these and other document formats, and it is the responsibility of the application using Lucene to use an appropriate Parser to convert the original format into plain text before passing that plain text to Lucene.
Plain text passed to Lucene for indexing goes through a process generally called tokenization. Tokenization is the process of breaking input text into small indexing elements – tokens. The way input text is broken into tokens heavily influences how people will then be able to search for that text. For instance, sentences beginnings and endings can be identified to provide for more accurate phrase and proximity searches (though sentence identification is not provided by Lucene).
In some cases simply breaking the input text into tokens is not enough – a deeper Analysis may be needed. Lucene includes both pre- and post-tokenization analysis facilities.
Pre-tokenization analysis can include (but is not limited to) stripping HTML markup, and transforming or removing text matching arbitrary patterns or sets of fixed strings.
There are many post-tokenization steps that can be done, including (but not limited to):
The analysis package provides the mechanism to convert Strings and Readers into tokens that can be indexed by Lucene. There are four main classes in the package from which all analysis processes are derived. These are:
Analyzer
– An Analyzer
is
responsible for supplying a
TokenStream
which can be consumed
by the indexing and searching processes. See below for more information
on implementing your own Analyzer
. Most of the time, you can use
an anonymous subclass of Analyzer
.
CharFilter
– CharFilter
extends
Reader
to transform the text before it is
tokenized, while providing
corrected character offsets to account for these modifications. This
capability allows highlighting to function over the original text when
indexed tokens are created from CharFilter
-modified text with offsets
that are not the same as those in the original text. Tokenizer.setReader(java.io.Reader)
accept CharFilter
s. CharFilter
s may
be chained to perform multiple pre-tokenization modifications.
Tokenizer
– A Tokenizer
is a
TokenStream
and is responsible for
breaking up incoming text into tokens. In many cases, an Analyzer
will
use a Tokenizer
as the first step in the analysis process. However,
to modify text prior to tokenization, use a CharFilter
subclass (see
above).
TokenFilter
– A TokenFilter
is
a TokenStream
and is responsible
for modifying tokens that have been created by the Tokenizer
. Common
modifications performed by a TokenFilter
are: deletion, stemming, synonym
injection, and case folding. Not all Analyzer
s require TokenFilter
s.
The relationship between Analyzer
and
CharFilter
s,
Tokenizer
s,
and TokenFilter
s is sometimes confusing. To ease
this confusion, here is some clarifications:
Analyzer
is a
factory for analysis chains. Analyzer
s don't
process text, Analyzer
s construct CharFilter
s, Tokenizer
s, and/or
TokenFilter
s that process text. An Analyzer
has two tasks:
to produce TokenStream
s that accept a
reader and produces tokens, and to wrap or otherwise
pre-process Reader
objects.
CharFilter
is a subclass of
Reader
that supports offset tracking.
Tokenizer
is only responsible for breaking the input text into tokens.
TokenFilter
modifies a
stream of tokens and their contents.
Tokenizer
is a TokenStream
,
but Analyzer
is not.
Analyzer
is "field aware", but
Tokenizer
is not. Analyzer
s may
take a field name into account when constructing the TokenStream
.
If you want to use a particular combination of CharFilter
s, a
Tokenizer
, and some TokenFilter
s, the simplest thing is often an
create an anonymous subclass of Analyzer
, provide Analyzer.createComponents(String)
and perhaps also
Analyzer.initReader(String,
java.io.Reader)
. However, if you need the same set of components
over and over in many places, you can make a subclass of
Analyzer
. In fact, Apache Lucene
supplies a large family of Analyzer
classes that deliver useful
analysis chains. The most common of these is the StandardAnalyzer.
Many applications will have a long and industrious life with nothing more
than the StandardAnalyzer
. The analyzers-common
library provides many pre-existing analyzers for various languages.
The analysis-common library also allows to configure a custom Analyzer without subclassing using the
CustomAnalyzer
class.
Aside from the StandardAnalyzer
,
Lucene includes several components containing analysis components,
all under the 'analysis' directory of the distribution. Some of
these support particular languages, others integrate external
components. The 'common' subdirectory has some noteworthy
general-purpose analyzers, including the PerFieldAnalyzerWrapper. Most Analyzer
s perform the same operation on all
Field
s. The PerFieldAnalyzerWrapper can be used to associate a different Analyzer
with different
Field
s. There is a great deal of
functionality in the analysis area, you should study it carefully to
find the pieces you need.
Analysis is one of the main causes of slow indexing. Simply put, the more you analyze the slower the indexing (in most cases). Perhaps your application would be just fine using the simple WhitespaceTokenizer combined with a StopFilter. The benchmark/ library can be useful for testing out the speed of the analysis process.
Applications usually do not invoke analysis – Lucene does it
for them. Applications construct Analyzer
s and pass then into Lucene,
as follows:
addDocument(doc)
,
the Analyzer
in effect for indexing is invoked for each indexed field of the added document.
QueryParser
may invoke the Analyzer during parsing. Note that for some queries, analysis does not
take place, e.g. wildcard queries.
However an application might invoke Analysis of any text for testing or for any other purpose, something like:
Version matchVersion = Version.LUCENE_XY; // Substitute desired Lucene version for XY
Analyzer analyzer = new StandardAnalyzer(matchVersion); // or any other analyzer
TokenStream ts = analyzer.tokenStream("myfield", new StringReader("some text goes here"));
// The Analyzer class will construct the Tokenizer, TokenFilter(s), and CharFilter(s),
// and pass the resulting Reader to the Tokenizer.
OffsetAttribute offsetAtt = ts.addAttribute(OffsetAttribute.class);
try {
ts.reset(); // Resets this stream to the beginning. (Required)
while (ts.incrementToken()) {
// Use AttributeSource.reflectAsString(boolean)
// for token stream debugging.
System.out.println("token: " + ts.reflectAsString(true));
System.out.println("token start offset: " + offsetAtt.startOffset());
System.out.println(" token end offset: " + offsetAtt.endOffset());
}
ts.end(); // Perform end-of-stream operations, e.g. set the final offset.
} finally {
ts.close(); // Release resources associated with this stream.
}
Selecting the "correct" analyzer is crucial for search quality, and can also affect indexing and search performance. The "correct" analyzer for your application will depend on what your input text looks like and what problem you are trying to solve. Lucene java's wiki page AnalysisParalysis provides some data on "analyzing your analyzer". Here are some rules of thumb:
Creating your own Analyzer is straightforward. Your Analyzer should subclass Analyzer
. It can use
existing analysis components — CharFilter(s) (optional), a
Tokenizer, and TokenFilter(s) (optional) — or components you
create, or a combination of existing and newly created components. Before
pursuing this approach, you may find it worthwhile to explore the
analyzers-common library and/or ask on the
java-user@lucene.apache.org mailing list first to see if what you
need already exists. If you are still committed to creating your own
Analyzer, have a look at the source code of any one of the many samples
located in this package.
The following sections discuss some aspects of implementing your own analyzer.
When document.add(field)
is called multiple times for the same field name, we could say that each such call creates a new
section for that field in that document.
In fact, a separate call to
tokenStream(field,reader)
would take place for each of these so called "sections".
However, the default Analyzer behavior is to treat all these sections as one large section.
This allows phrase search and proximity search to seamlessly cross
boundaries between these "sections".
In other words, if a certain field "f" is added like this:
document.add(new Field("f","first ends",...); document.add(new Field("f","starts two",...); indexWriter.addDocument(document);
Then, a phrase search for "ends starts" would find that document.
Where desired, this behavior can be modified by introducing a "position gap" between consecutive field "sections",
simply by overriding
Analyzer.getPositionIncrementGap(fieldName)
:
Version matchVersion = Version.LUCENE_XY; // Substitute desired Lucene version for XY Analyzer myAnalyzer = new StandardAnalyzer(matchVersion) { public int getPositionIncrementGap(String fieldName) { return 10; } };
At the ends of each field, Lucene will call the TokenStream.end()
.
The components of the token stream (the tokenizer and the token filters) must
put accurate values into the token attributes to reflect the situation at the end of the field.
The Offset attribute must contain the final offset (the total number of characters processed)
in both start and end. Attributes like PositionLength must be correct.
The base methodTokenStream.end()
sets PositionIncrement to 0, which is required.
Other components must override this method to fix up the other attributes.
By default, TokenStream arranges for the
position increment
of all tokens to be one.
This means that the position stored for that token in the index would be one more than
that of the previous token.
Recall that phrase and proximity searches rely on position info.
If the selected analyzer filters the stop words "is" and "the", then for a document containing the string "blue is the sky", only the tokens "blue", "sky" are indexed, with position("sky") = 3 + position("blue"). Now, a phrase query "blue is the sky" would find that document, because the same analyzer filters the same stop words from that query. But the phrase query "blue sky" would not find that document because the position increment between "blue" and "sky" is only 1.
If this behavior does not fit the application needs, the query parser needs to be configured to not take position increments into account when generating phrase queries.
Note that a filter that filters out tokens must increment the position increment in order not to generate corrupt tokenstream graphs. Here is the logic used by StopFilter to increment positions when filtering out tokens:
public TokenStream tokenStream(final String fieldName, Reader reader) { final TokenStream ts = someAnalyzer.tokenStream(fieldName, reader); TokenStream res = new TokenStream() { CharTermAttribute termAtt = addAttribute(CharTermAttribute.class); PositionIncrementAttribute posIncrAtt = addAttribute(PositionIncrementAttribute.class); public boolean incrementToken() throws IOException { int extraIncrement = 0; while (true) { boolean hasNext = ts.incrementToken(); if (hasNext) { if (stopWords.contains(termAtt.toString())) { extraIncrement += posIncrAtt.getPositionIncrement(); // filter this word continue; } if (extraIncrement > 0) { posIncrAtt.setPositionIncrement(posIncrAtt.getPositionIncrement()+extraIncrement); } } return hasNext; } } }; return res; }
A few more use cases for modifying position increments are:
SynoymGraphFilter
at search time only.
By default, all tokens created by Analyzers and Tokenizers have a
position length
of one.
This means that the token occupies a single position. This attribute is not indexed
and thus not taken into account for positional queries, but is used by eg. suggesters.
The main use case for positions lengths is multi-word synonyms. With single-word synonyms, setting the position increment to 0 is enough to denote the fact that two words are synonyms, for example:
Term | red | magenta |
Position increment | 1 | 0 |
Given that position(magenta) = 0 + position(red), they are at the same position, so anything working with analyzers will return the exact same result if you replace "magenta" with "red" in the input. However, multi-word synonyms are more tricky. Let's say that you want to build a TokenStream where "IBM" is a synonym of "Internal Business Machines". Position increments are not enough anymore:
Term | IBM | International | Business | Machines |
Position increment | 1 | 0 | 1 | 1 |
The problem with this token stream is that "IBM" is at the same position as "International" although it is a synonym with "International Business Machines" as a whole. Setting the position increment of "Business" and "Machines" to 0 wouldn't help as it would mean than "International" is a synonym of "Business". The only way to solve this issue is to make "IBM" span across 3 positions, this is where position lengths come to rescue.
Term | IBM | International | Business | Machines |
Position increment | 1 | 0 | 1 | 1 |
Position length | 3 | 1 | 1 | 1 |
This new attribute makes clear that "IBM" and "International Business Machines" start and end at the same positions.
There are a few rules to observe when writing custom Tokenizers and TokenFilters:
AttributeSource.clearAttributes()
in
incrementToken().TokenStream.end()
, and pass the final
offset (the total number of input characters processed) to both
parameters of OffsetAttribute.setOffset(int, int)
.Although these rules might seem easy to follow, problems can quickly happen when chaining badly implemented filters that play with positions and offsets, such as synonym or n-grams filters. Here are good practices for writing correct filters:
AttributeSource.clearAttributes()
first."Flexible Indexing" summarizes the effort of making the Lucene indexer pluggable and extensible for custom index formats. A fully customizable indexer means that users will be able to store custom data structures on disk. Therefore the analysis API must transport custom types of data from the documents to the indexer. (It also supports communications amongst the analysis components.)
Classes Attribute
and
AttributeSource
serve as the basis upon which
the analysis elements of "Flexible Indexing" are implemented. An Attribute
holds a particular piece of information about a text token. For example,
CharTermAttribute
contains the term text of a token, and
OffsetAttribute
contains
the start and end character offsets of a token. An AttributeSource is a
collection of Attributes with a restriction: there may be only one instance
of each attribute type. TokenStream now extends AttributeSource, which means
that one can add Attributes to a TokenStream. Since TokenFilter extends
TokenStream, all filters are also AttributeSources.
Lucene provides seven Attributes out of the box:
CharTermAttribute |
The term text of a token. Implements CharSequence
(providing methods length() and charAt(), and allowing e.g. for direct
use with regular expression Matcher s) and
Appendable (allowing the term text to be appended to.)
|
OffsetAttribute |
The start and end offset of a token in characters. |
PositionIncrementAttribute |
See above for detailed information about position increment. |
PositionLengthAttribute |
The number of positions occupied by a token. |
PayloadAttribute |
The payload that a Token can optionally have. |
TypeAttribute |
The type of the token. Default is 'word'. |
FlagsAttribute |
Optional flags a token can have. |
KeywordAttribute |
Keyword-aware TokenStreams/-Filters skip modification of tokens that return true from this attribute's isKeyword() method. |
Analyzer
applies a reuse
strategy to the tokenizer and the token filters. It will reuse
them. For each new input, it calls Tokenizer.setReader(java.io.Reader)
to set the input. Your components must be prepared for this scenario,
as described below.
Tokenizer
.
TokenStream.end()
.
Your implementation must call
super.end()
. It must set a correct final offset into
the offset attribute, and finish up and other attributes to reflect
the end of the stream.
TokenStream.reset()
or TokenStream.close()
, it
must call the corresponding superclass method.
TokenFilter
.
If your token filter overrides TokenStream.reset()
,
TokenStream.end()
or TokenStream.close()
, it
must call the corresponding superclass method.
Tokenizer
but delegate
selected logic to another tokenizer) must also set the reader to the delegate in the overridden
Tokenizer.reset()
method, e.g.:
public class ForwardingTokenizer extends Tokenizer { private Tokenizer delegate; ... @Override public void reset() { super.reset(); delegate.setReader(this.input); delegate.reset(); } }
The lucene-test-framework component defines BaseTokenStreamTestCase. By extending this class, you can create JUnit tests that validate that your Analyzer and/or analysis components correctly implement the protocol. The checkRandomData methods of that class are particularly effective in flushing out errors.
Class
)
of an Attribute as an argument and returns an instance. If an Attribute of the same type was previously added, then
the already existing instance is returned, otherwise a new instance is created and returned. Therefore TokenStreams/-Filters
can safely call addAttribute() with the same Attribute type multiple times. Even consumers of TokenStreams should
normally call addAttribute() instead of getAttribute(), because it would not fail if the TokenStream does not have this
Attribute (getAttribute() would throw an IllegalArgumentException, if the Attribute is missing). More advanced code
could simply check with hasAttribute(), if a TokenStream has it, and may conditionally leave out processing for
extra performance.
In this example we will create a WhiteSpaceTokenizer and use a LengthFilter to suppress all words that have only two or fewer characters. The LengthFilter is part of the Lucene core and its implementation will be explained here to illustrate the usage of the TokenStream API.
Then we will develop a custom Attribute, a PartOfSpeechAttribute, and add another filter to the chain which utilizes the new custom attribute, and call it PartOfSpeechTaggingFilter.
public class MyAnalyzer extends Analyzer { private Version matchVersion; public MyAnalyzer(Version matchVersion) { this.matchVersion = matchVersion; } @Override protected TokenStreamComponents createComponents(String fieldName) { return new TokenStreamComponents(new WhitespaceTokenizer(matchVersion)); } public static void main(String[] args) throws IOException { // text to tokenize final String text = "This is a demo of the TokenStream API"; Version matchVersion = Version.LUCENE_XY; // Substitute desired Lucene version for XY MyAnalyzer analyzer = new MyAnalyzer(matchVersion); TokenStream stream = analyzer.tokenStream("field", new StringReader(text)); // get the CharTermAttribute from the TokenStream CharTermAttribute termAtt = stream.addAttribute(CharTermAttribute.class); try { stream.reset(); // print all tokens until stream is exhausted while (stream.incrementToken()) { System.out.println(termAtt.toString()); } stream.end(); } finally { stream.close(); } } }In this easy example a simple white space tokenization is performed. In main() a loop consumes the stream and prints the term text of the tokens by accessing the CharTermAttribute that the WhitespaceTokenizer provides. Here is the output:
This is a demo of the new TokenStream API
createComponents()
method in our analyzer needs to be changed:
@Override protected TokenStreamComponents createComponents(String fieldName) { final Tokenizer source = new WhitespaceTokenizer(matchVersion); TokenStream result = new LengthFilter(true, source, 3, Integer.MAX_VALUE); return new TokenStreamComponents(source, result); }Note how now only words with 3 or more characters are contained in the output:
This demo the new TokenStream APINow let's take a look how the LengthFilter is implemented:
public final class LengthFilter extends FilteringTokenFilter { private final int min; private final int max; private final CharTermAttribute termAtt = addAttribute(CharTermAttribute.class); /** * Create a new LengthFilter. This will filter out tokens whose * CharTermAttribute is either too short * (< min) or too long (> max). * @param version the Lucene match version * @param in the TokenStream to consume * @param min the minimum length * @param max the maximum length */ public LengthFilter(Version version, TokenStream in, int min, int max) { super(version, in); this.min = min; this.max = max; } @Override public boolean accept() { final int len = termAtt.length(); return (len >= min && len <= max); } }
In LengthFilter, the CharTermAttribute is added and stored in the instance
variable termAtt
. Remember that there can only be a single
instance of CharTermAttribute in the chain, so in our example the
addAttribute()
call in LengthFilter returns the
CharTermAttribute that the WhitespaceTokenizer already added.
The tokens are retrieved from the input stream in FilteringTokenFilter's
incrementToken()
method (see below), which calls LengthFilter's
accept()
method. By looking at the term text in the
CharTermAttribute, the length of the term can be determined and tokens that
are either too short or too long are skipped. Note how
accept()
can efficiently access the instance variable; no
attribute lookup is necessary. The same is true for the consumer, which can
simply use local references to the Attributes.
LengthFilter extends FilteringTokenFilter:
public abstract class FilteringTokenFilter extends TokenFilter { private final PositionIncrementAttribute posIncrAtt = addAttribute(PositionIncrementAttribute.class); /** * Create a new FilteringTokenFilter. * @param in the TokenStream to consume */ public FilteringTokenFilter(Version version, TokenStream in) { super(in); } /** Override this method and return if the current input token should be returned by incrementToken. */ protected abstract boolean accept() throws IOException; @Override public final boolean incrementToken() throws IOException { int skippedPositions = 0; while (input.incrementToken()) { if (accept()) { if (skippedPositions != 0) { posIncrAtt.setPositionIncrement(posIncrAtt.getPositionIncrement() + skippedPositions); } return true; } skippedPositions += posIncrAtt.getPositionIncrement(); } // reached EOS -- return false return false; } @Override public void reset() throws IOException { super.reset(); } }
PartOfSpeechAttribute
. First we need to define the interface of the new Attribute:
public interface PartOfSpeechAttribute extends Attribute { public static enum PartOfSpeech { Noun, Verb, Adjective, Adverb, Pronoun, Preposition, Conjunction, Article, Unknown } public void setPartOfSpeech(PartOfSpeech pos); public PartOfSpeech getPartOfSpeech(); }
Now we also need to write the implementing class. The name of that class is important here: By default, Lucene
checks if there is a class with the name of the Attribute with the suffix 'Impl'. In this example, we would
consequently call the implementing class PartOfSpeechAttributeImpl
.
This should be the usual behavior. However, there is also an expert-API that allows changing these naming conventions:
AttributeFactory
. The factory accepts an Attribute interface as argument
and returns an actual instance. You can implement your own factory if you need to change the default behavior.
Now here is the actual class that implements our new Attribute. Notice that the class has to extend
AttributeImpl
:
public final class PartOfSpeechAttributeImpl extends AttributeImpl implements PartOfSpeechAttribute { private PartOfSpeech pos = PartOfSpeech.Unknown; public void setPartOfSpeech(PartOfSpeech pos) { this.pos = pos; } public PartOfSpeech getPartOfSpeech() { return pos; } @Override public void clear() { pos = PartOfSpeech.Unknown; } @Override public void copyTo(AttributeImpl target) { ((PartOfSpeechAttribute) target).setPartOfSpeech(pos); } }
This is a simple Attribute implementation has only a single variable that
stores the part-of-speech of a token. It extends the
AttributeImpl
class and therefore implements its abstract methods
clear()
and copyTo()
. Now we need a TokenFilter that
can set this new PartOfSpeechAttribute for each token. In this example we
show a very naive filter that tags every word with a leading upper-case letter
as a 'Noun' and all other words as 'Unknown'.
public static class PartOfSpeechTaggingFilter extends TokenFilter { PartOfSpeechAttribute posAtt = addAttribute(PartOfSpeechAttribute.class); CharTermAttribute termAtt = addAttribute(CharTermAttribute.class); protected PartOfSpeechTaggingFilter(TokenStream input) { super(input); } public boolean incrementToken() throws IOException { if (!input.incrementToken()) {return false;} posAtt.setPartOfSpeech(determinePOS(termAtt.buffer(), 0, termAtt.length())); return true; } // determine the part of speech for the given term protected PartOfSpeech determinePOS(char[] term, int offset, int length) { // naive implementation that tags every uppercased word as noun if (length > 0 && Character.isUpperCase(term[0])) { return PartOfSpeech.Noun; } return PartOfSpeech.Unknown; } }
Just like the LengthFilter, this new filter stores references to the attributes it needs in instance variables. Notice how you only need to pass in the interface of the new Attribute and instantiating the correct class is automatically taken care of.
Now we need to add the filter to the chain in MyAnalyzer:
@Override protected TokenStreamComponents createComponents(String fieldName) { final Tokenizer source = new WhitespaceTokenizer(matchVersion); TokenStream result = new LengthFilter(true, source, 3, Integer.MAX_VALUE); result = new PartOfSpeechTaggingFilter(result); return new TokenStreamComponents(source, result); }Now let's look at the output:
This demo the new TokenStream APIApparently it hasn't changed, which shows that adding a custom attribute to a TokenStream/Filter chain does not affect any existing consumers, simply because they don't know the new Attribute. Now let's change the consumer to make use of the new PartOfSpeechAttribute and print it out:
public static void main(String[] args) throws IOException { // text to tokenize final String text = "This is a demo of the TokenStream API"; MyAnalyzer analyzer = new MyAnalyzer(); TokenStream stream = analyzer.tokenStream("field", new StringReader(text)); // get the CharTermAttribute from the TokenStream CharTermAttribute termAtt = stream.addAttribute(CharTermAttribute.class); // get the PartOfSpeechAttribute from the TokenStream PartOfSpeechAttribute posAtt = stream.addAttribute(PartOfSpeechAttribute.class); try { stream.reset(); // print all tokens until stream is exhausted while (stream.incrementToken()) { System.out.println(termAtt.toString() + ": " + posAtt.getPartOfSpeech()); } stream.end(); } finally { stream.close(); } }The change that was made is to get the PartOfSpeechAttribute from the TokenStream and print out its contents in the while loop that consumes the stream. Here is the new output:
This: Noun demo: Unknown the: Unknown new: Unknown TokenStream: Noun API: NounEach word is now followed by its assigned PartOfSpeech tag. Of course this is a naive part-of-speech tagging. The word 'This' should not even be tagged as noun; it is only spelled capitalized because it is the first word of a sentence. Actually this is a good opportunity for an exercise. To practice the usage of the new API the reader could now write an Attribute and TokenFilter that can specify for each word if it was the first token of a sentence or not. Then the PartOfSpeechTaggingFilter can make use of this knowledge and only tag capitalized words as nouns if not the first word of a sentence (we know, this is still not a correct behavior, but hey, it's a good exercise). As a small hint, this is how the new Attribute class could begin:
public class FirstTokenOfSentenceAttributeImpl extends AttributeImpl implements FirstTokenOfSentenceAttribute { private boolean firstToken; public void setFirstToken(boolean firstToken) { this.firstToken = firstToken; } public boolean getFirstToken() { return firstToken; } @Override public void clear() { firstToken = false; } ...
Reader
s as input. Of course you can wrap your Readers with FilterReader
s
to manipulate content, but this would have the big disadvantage that character offsets might be inconsistent with your original
text.
CharFilter
is designed to allow you to pre-process input like a FilterReader would, but also
preserve the original offsets associated with those characters. This way mechanisms like highlighting still work correctly.
CharFilters can be chained.
Example:
public class MyAnalyzer extends Analyzer { @Override protected TokenStreamComponents createComponents(String fieldName) { return new TokenStreamComponents(new MyTokenizer()); } @Override protected Reader initReader(String fieldName, Reader reader) { // wrap the Reader in a CharFilter chain. return new SecondCharFilter(new FirstCharFilter(reader)); } }
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