Difference between revisions of "Multiwords"

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(Explain the action of 'g' tags in more detail)
m (Grammar change)
 
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#* <pre>analysis: ^coffees with milk/coffee<n><pl># with milk$</pre>
#* <pre>analysis: ^coffees with milk/coffee<n><pl># with milk$</pre>
#* <pre>after disambiguation and pre-transfer: ^coffee# with milk<n><pl>$</pre>
#* <pre>after disambiguation and pre-transfer: ^coffee# with milk<n><pl>$</pre>
#* So the tags are "in the ''middle''", right after the inflection, in the analyser, but appears ''after'' the whole lemma (including <code><g/></code> group) in the bidix
# '''<code><j/></code>''' is used when you want the multiword to be split into two lexical units, each with its own analysis (set of tags), where both parts may vary independently
# '''<code><j/></code>''' is used when you want the multiword to be split into two lexical units, each with its own analysis (set of tags), where both parts may vary independently
#* <pre>entry: <e>wr</i><par n="wr/ite__vblex"/><p><l><b/>about</l><r><j/>about<s n="pr"/></r></p></e></pre>
#* <pre>entry: <e>wr</i><par n="wr/ite__vblex"/><p><l><b/>about</l><r><j/>about<s n="pr"/></r></p></e></pre>
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The following multiwords are not very well supported [[User:Skh/Application_GSoC_2010|quite yet]]:
The following multiwords are in the process of being supported:
* ''Agreement multiwords'': complex multiwords where two (or more) parts show some sort of agreement/dependence of tags (or, where certain tag combinations are illegal)
* [[User:Skh/Application_GSoC_2010|''Agreement multiwords'':]] complex multiwords where two or more parts show some sort of agreement/dependence of tags (or, where certain tag combinations are illegal)
** lt-mwpp takes a file which specifies which lemma combinations are multiwords, and what tags need to agree, and generates all the legal combinations in the lttoolbox dix format
** lt-mwpp takes a file which specifies which lemma combinations are multiwords, and what tags need to agree, and generates all the legal combinations in the lttoolbox dix format
* ''Discontiguous multiwords'': multiwords with an arbitrary number of unrelated words in between, eg. the separable verbs in Germanic languages
* [[User:Irene/proposal|''Discontiguous multiwords'':]] multiwords with an arbitrary number of unrelated words in between, eg. the separable verbs in Germanic languages
(but see hacks below)
(but see hacks below)

== Why make a multiword entry? ==
== Why make a multiword entry? ==
The first thing to say about multiword translations is that they can sometimes be handled by knowing only the [[Monodix basics]] and [[Bilingual dictionary]] basics (and also the superblank '<b/>').
The first thing to say about multiword translations is that they can sometimes be handled by knowing only the [[Monodix basics]] and [[Bilingual dictionary]] basics (and also the superblank '<b/>').
Line 45: Line 47:
The English verb 'roll' is often supplemented with a word for orientation/direction e.g. 'to roll over' or 'to roll down'. Within the Apertium system, we would like to treat these as 'many (two) words that make a single verb'. You might find this many-word verb in a sentence like 'the car rolled down the hill'. Perhaps a linguist may wish to study word-constructions like this further, but recognising 'roll down' as one word is a good step forward in machine translation.
The English verb 'roll' is often supplemented with a word for orientation/direction e.g. 'to roll over' or 'to roll down'. Within the Apertium system, we would like to treat these as 'many (two) words that make a single verb'. You might find this many-word verb in a sentence like 'the car rolled down the hill'. Perhaps a linguist may wish to study word-constructions like this further, but recognising 'roll down' as one word is a good step forward in machine translation.


We can do this by creating an English monodix paradigm. Please note that his example is a little contrived, as the same effect can be made with no more than a section entry (however, if we show a paradigm the example will work even if the multiword verb was more difficult),
We can do this by creating an English monodix paradigm. Please note that this example is a little contrived, as the same effect can be made with no more than a section entry (however, if we show a paradigm the example will work even if the multiword verb was more difficult),


<pre>
<pre>
Line 64: Line 66:
Note how the superblank '<b/>' is used to mark the limits of the words in the multiword verb.
Note how the superblank '<b/>' is used to mark the limits of the words in the multiword verb.
We can use/trigger the multiword aradigm from an English monodix 'section' entry,
We can use/trigger the multiword paradigm from an English monodix 'section' entry,


<pre>
<pre>
Line 78: Line 80:
Note the use of the superblank '<b/>' again, this time to construct the lemma.
Note the use of the superblank '<b/>' again, this time to construct the lemma.


This is a surprisingly easy and clear way to construct multiword recognition. at the time of writing, you can find examples of this method in dictionaries on Apertium. This is possibly due to the ease and clarity, or because the dictionary entries are old.
This is a surprisingly easy and clear way to construct multiword recognition. At the time of writing, you can find examples of this method in dictionaries on Apertium. This is possibly due to the ease and clarity, or because the dictionary entries are old.



So you may ask, 'why not let Apertium treat these two words as separate words?'. Apertium is a flexible system :) If you need to get the effect, various bidix/monodix entries, or a rule in the first stage of the chunker module will work.
So you may ask, 'why not let Apertium treat these two words as separate words?'. Apertium is a flexible system :) If you need to get the effect, various bidix/monodix entries, or a rule in the first stage of the chunker module will work.
Line 98: Line 99:


By all means patch to make some progress, but this is not a good end solution.
By all means patch to make some progress, but this is not a good end solution.



== Simple usage ==
== Simple usage ==


=== Simple usage of &lt;g/&gt; and &lt;b/&gt; ===
=== Simple usage of &lt;g/&gt; and &lt;b/&gt; ===
The first thing to say about this solution is that it may need a transfer rule. Without the rule, translation text may be lost. If you start adding any multiword rules, it is a good idea to have the transfer rule in place. The rule is very general and can be added to most language pairs.


There is an example from English to Esperanto with '''inner inflection''' followed by an invariant part with spaces.
There is an example from English to Esperanto with '''inner inflection''' followed by an invariant part with spaces.
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</pre>
</pre>


Compare this to the simple example in "Why make a multiword entry?". The verb mark is next to the word it is changing/inflecting, and so can use the generic paradigm for 'roll' (which is 'accept__vblex'), not a dedicated paradigm. This is a step forward.
Compare this to the simple example in [[#Why make a multiword entry?]]. The verb mark is next to the word it is changing/inflecting, and so can use the generic paradigm for 'roll' (which is 'accept__vblex'), not a dedicated paradigm. This is a step forward.


However, this produces results we do not want. It recognises the output, but truncates like this,
However, this produces results we do not want. It recognises the output, but truncates like this,
Line 199: Line 200:
</pre>
</pre>


For a monodix, this is a long and complex line. But, you will remember, this method avoids creating ac massive and non-reusable paradigm.
For a monodix, this is a long and complex line. But, you will remember, this method avoids creating a massive and non-reusable paradigm.


==== The translation rule ====
Before we have a translation, there is a last step. The 'g' tags may solve the problem of the unrecognised lemma, but they do nothing with the tags attached to the invariant words. The post-translation stream for 'roll down' may be,

<pre>
^roll# down<vblex><imp>$
</pre>

But the new monodix entry uses the 'g' tag to signal an invariant addition (there may be shortcuts for some situations? R.C.). We asked the bidex to have the tags at the end so Apertium would recognise and trigger the lemma we intended. Now Apertium needs the invariant part, ''after'' the morphological tags:

<pre>
^roll<vblex><imp># down$
</pre>

From the manual the transfer rule (in a .t1x file) is this,


Also note that you need at least one verbal transfer rule to ensure that the invariant part, the '''lemq''' (this is the <g> in dix), is put ''after'' the morphological tags (a_verb, temps):
<pre>
<pre>
<rule comment="VBLEX">
<rule comment="VBLEX">
Line 219: Line 235:
</rule>
</rule>
</pre>
</pre>

The 'clip' entries are grabbing the 'pos=1' pattern match (here there is only one, anyway) from the translated side, then stripping the various 'parts' before reassembling them in order, ensuring the lemma tail/queue is at the end.
'lemh' and 'lemq' are (unusual) predefined part-definitions, which refer to the head e.g. 'roll' and tail e.g. 'over ...' of the lemma. 'a_verb' and 'temps' are the usual def-attrs for capturing a verb and tags, and the end-form of a verb such as 'imperative', 'past particle' etc.

A verbose version of the above may be,

<pre>
<section-def-cats>
<def-cat n="vblex">
<cat-item tags="vblex.*"/>
</def-cat>
...

</section-def-cats>

<section-def-attrs>
<def-attr n="a_lexical_verb">
<attr-item tags="vblex">
</def-attr>

<def-attr n="a_verb_form">
<attr-item tags="inf">
<attr-item tags="imp">
<attr-item tags="pp">
<attr-item tags="pprs">
<attr-item tags="ger">
<attr-item tags="subs">
<attr-item tags="pres">
<attr-item tags="past">
</def-attr>
<def-attr n="a_persona">
<attr-item tags="p1">
<attr-item tags="p2">
<attr-item tags="mp3">
</def-attr>

<def-attr n="a_gender">
<attr-item tags="f">
<attr-item tags="m">
<attr-item tags="mf">
</def-attr>

<def-attr n="a_number">
<attr-item tags="sg">
<attr-item tags="pl">
<attr-item tags="sp">
<attr-item tags="ND">
</def-attr>
...

</section-def-attrs>


<pre>
<rule comment="VBLEX">
<pattern>
<pattern-item n="vblex"/>
</pattern>
<action>
<out>
<lu>
<clip pos="1" side="tl" part="lemh"/>
<clip pos="1" side="tl" part="a_lexical_verb"/>
<clip pos="1" side="tl" part="a_verb_form"/>
<clip pos="1" side="tl" part="a_persona"/>
<clip pos="1" side="tl" part="a_gender"/>
<clip pos="1" side="tl" part="a_number"/>
<clip pos="1" side="tl" part="lemq"/>
</lu>
</out>
</action>
</rule>
</pre>


But your language dictionary/translation may have different needs. You may not be handling multiword verbs. You may need other categories of tagging.


=== Simple usage of &lt;j/&gt; ===
=== Simple usage of &lt;j/&gt; ===
Line 243: Line 337:


(This also happens with compounds.)
(This also happens with compounds.)



== Can I translate simple entries to and from multiword entries? ==
From the [https://wiki.apertium.org/w/images/d/d0/Apertium2-documentation.pdf Manual],

<blockquote>
It can be the case that a lemma is a multiword of this kind in one language and a single word in the other language. In that case, in the bilingual dictionary, the multiword will contain the <g> element and the single word will not.
</blockquote>

Yes you can. The bidex only cares about lemmas.




==The complicated cases==
==The complicated cases==

Latest revision as of 05:17, 10 December 2017

The term multiword includes simple words that have spaces in them, words with separable parts, contractions and compounds of several lemmas. Apertium supports these to varying degrees.

En français

Overview[edit]

lttoolbox currently has four mechanisms for creating multiwords, of varying complexity:

  1. simply inserts a blank; use it if you want a word that has a space in it, but only inflection at the end
    • entry: <e><i>record<b/>player</i><par n="house__n"/></e>
    • analysis: ^record player/record player<n><sg>$
    • analysis: ^record players/record player<n><pl>$
  2. <g/> is used (in combination with ) when you have inflection in the middle of the word, and an invariant part at the end
    • entry: <e><i>coffee</i><par n="house__n"/><p><l><b/>with<b/>milk</l><r><g><b/>with<b/>milk</g></r></p></e>
    • analysis: ^coffee with milk/coffee<n><sg># with milk$
    • after disambiguation and pre-transfer: ^coffee# with milk<n><sg>$
    • analysis: ^coffees with milk/coffee<n><pl># with milk$
    • after disambiguation and pre-transfer: ^coffee# with milk<n><pl>$
    • So the tags are "in the middle", right after the inflection, in the analyser, but appears after the whole lemma (including <g/> group) in the bidix
  3. <j/> is used when you want the multiword to be split into two lexical units, each with its own analysis (set of tags), where both parts may vary independently
    • entry: <e>wr</i><par n="wr/ite__vblex"/><p><l><b/>about</l><r><j/>about<s n="pr"/></r></p></e>
    • analysis: ^write about/write<vblex><inf>+about<pr>/write<vblex><pres>+about<pr>$
    • after disambiguation and pre-transfer: ^write<vblex><inf>$ ^about<pr>$
    • analysis: ^writes about/write<vblex><pri><p3><sg>+about<pr>$
    • after disambiguation and pre-transfer: ^write<vblex><pri><p3><sg>$ ^about<pr>$
  4. <s n="compound-only-L"/> and <s n="compound-R"/> – an analysis with the compound-only-L tag in it can be the left part of a compound (many of these can chain), but can never stand alone as an analysis, while an analysis with the compound-R tag in it can be either a word on its own, or the final part of a compound.
    • entry: <e><p><l>kaffe</l><r>kaffe<s n="n"/><s n="m"/><s n="sg"/><s n="ind"/><s n="cmp"/><s n="compound-only-L"/></r></p>
    • entry: <e><p><l>bilet</l><r>bilete<s n="n"/><s n="nt"/><s n="sg"/><s n="ind"/><s n="cmp"/><s n="compound-only-L"/></r></p> 
    • entry: <e><p><l>kostnaden</l><r>kostnad<s n="n"/><s n="m"/><s n="sg"/><s n="def"/><s n="compound-R"/></r></p> 
    • analysis: ^kaffekostnaden/kaffe<n><m><sg><ind><cmp>+kostnad<n><m><sg><def>$
    • analysis: ^kaffebiletkostnaden/kaffe<n><m><sg><ind><cmp>+bilet<n><nt><sg><ind><cmp>+kostnad<n><m><sg><def>$
    • no analysis: ^bilet/*bilet$


More information on these below under Simple usage, Compounds and the documentation (esp. sec.3.1.2.6).


The following multiwords are in the process of being supported:

  • Agreement multiwords: complex multiwords where two or more parts show some sort of agreement/dependence of tags (or, where certain tag combinations are illegal)
    • lt-mwpp takes a file which specifies which lemma combinations are multiwords, and what tags need to agree, and generates all the legal combinations in the lttoolbox dix format
  • Discontiguous multiwords: multiwords with an arbitrary number of unrelated words in between, eg. the separable verbs in Germanic languages

(but see hacks below)

Why make a multiword entry?[edit]

The first thing to say about multiword translations is that they can sometimes be handled by knowing only the Monodix basics and Bilingual dictionary basics (and also the superblank '').

The English verb 'roll' is often supplemented with a word for orientation/direction e.g. 'to roll over' or 'to roll down'. Within the Apertium system, we would like to treat these as 'many (two) words that make a single verb'. You might find this many-word verb in a sentence like 'the car rolled down the hill'. Perhaps a linguist may wish to study word-constructions like this further, but recognising 'roll down' as one word is a good step forward in machine translation.

We can do this by creating an English monodix paradigm. Please note that this example is a little contrived, as the same effect can be made with no more than a section entry (however, if we show a paradigm the example will work even if the multiword verb was more difficult),

<pardef n="roll_down__vblex">
  <e>
    <p><l><b/>down</l><r><b/>down<s n="vblex"><s n="inf"></r></p>
  </e>
  <e>
    <p><l><b/>down</l><r><b/>down<s n="vblex"><s n="imp"></r></p>
  </e>
  <e>
    <p><l><b/>down</l><r><b/>down<s n="vblex"><s n="pp"></r></p>
  </e>
...
</pardef>

Note how the superblank '' is used to mark the limits of the words in the multiword verb.

We can use/trigger the multiword paradigm from an English monodix 'section' entry,

<e lm="roll down"><i>roll</i><par n="roll_down__vblex"></e>

Now, if another language needs to identify 'roll down' as a special verb, the above definition can be triggered from a bidex,

<e><p><l>???lemma from another language???</l><r>roll</b>down<s n="vblex"></r></p></e>

Note the use of the superblank '' again, this time to construct the lemma.

This is a surprisingly easy and clear way to construct multiword recognition. At the time of writing, you can find examples of this method in dictionaries on Apertium. This is possibly due to the ease and clarity, or because the dictionary entries are old.

So you may ask, 'why not let Apertium treat these two words as separate words?'. Apertium is a flexible system :) If you need to get the effect, various bidix/monodix entries, or a rule in the first stage of the chunker module will work.

But the stream you will generate will be something like (simplified, 'chunker' stage),

{roll<vblex><imp>}{down<at_pr>}

and does not reflect the connection of the two words. We would prefer a stream that looked like,

{roll down<vblex><imp>}

The lack of connection between the words may limit us later. We will not be able to identify the two words as one unit when translating back from English. We may be using the chunker for simple connection rules, which is not what the chunker is for and makes our translation pairs confusing to read. If we want to do further manipulations on the text stream, in either direction, tracing the effects will become harder and harder. If we have used the chunker we may find it difficult to use the chunker for other purposes.

By all means patch to make some progress, but this is not a good end solution.

Simple usage[edit]

Simple usage of <g/> and <b/>[edit]

The first thing to say about this solution is that it may need a transfer rule. Without the rule, translation text may be lost. If you start adding any multiword rules, it is a good idea to have the transfer rule in place. The rule is very general and can be added to most language pairs.

There is an example from English to Esperanto with inner inflection followed by an invariant part with spaces.

In en.dix is

<e lm="become"><i>bec</i><par n="bec/ome__vblex"/></e>
<e lm="become acquainted">
  <i>bec</i>
  <par n="bec/ome__vblex"/>
  <p>
    <l><b/>acquainted</l>  
    <r><g><b/>acquainted</g></r>    
  </p>
</e>
<e lm="become acquainted with">
  <i>bec</i>
  <par n="bec/ome__vblex"/>
  <p>
    <l><b/>acquainted<b/>with</l>
    <r><g><b/>acquainted<b/>with</g></r>
  </p>
</e>

So become is conjugated as a normal verb and the rest is fixed (invariant). Note that <b/> is a space (blank) and that the fixed words are inside <g> </g>.

When "become acquainted" is read from the analyser, the output is

^become acquainted/become<vblex><inf># acquainted$

Before lexical transfer, the "lemma queue" (# acquainted) is put onto the lemma:

^become# acquainted<vblex><inf>$

In Esperanto, "become" is "iĝi" (or "fariĝi"), "become acquainted" is "konatiĝi" and "become acquainted with" is "konatiĝi kun". The iĝi/konatiĝi should be conjugated according to become. Thus the bidix entries are

<e><p><l>iĝi<s n="vblex"/></l><r>become<s n="vblex"/></r></p></e>
<e><p><l>konatiĝi<s n="vblex"/></l><r>become<g><b/>acquainted</g><s n="vblex"/></r></p></e>
<e><p><l>konatiĝi<g><b/>kun</g><s n="vblex"/></l><r>become<g><b/>acquainted<b/>with</g><s n="vblex"/></r></p></e>

And the eo monodix

<e lm="iĝi"><i>iĝ</i><par n="verb__vblex"/></e>
<e lm="konatiĝi"><i>konatiĝ</i><par n="verb__vblex"/></e>
<e lm="konatiĝi kun">
  <i>konatiĝ</i>
  <par n="verb__vblex"/>
  <p>
    <l><b/>kun</l>
    <r><g><b/>kun</g></r>
  </p>
</e>	

Note how the English fixed words <g><b/>acquaintedwith</g> become <g><b/>kun</g>


The action of <g></g> tags[edit]

The action of <g></g> in the bidex is important. It enables us to keep the verb (or other word) in an inflection position.

You may think you do it like this, putting the tags next to the relevant word,

<e><p><l>???lemma from another language???</l><r>roll<s n="vblex"></b>down</r></p></e>

Compare this to the simple example in #Why make a multiword entry?. The verb mark is next to the word it is changing/inflecting, and so can use the generic paradigm for 'roll' (which is 'accept__vblex'), not a dedicated paradigm. This is a step forward.

However, this produces results we do not want. It recognises the output, but truncates like this,

rolls

The manual has no explanation for why the bidex parser fails on a lemma containing interfering tags. The parser can process superbanks? Does it process up to the <vblex> tag then abandon work? If so, it would produce the results we see, seeking a 'roll<vblex>' lemma, failing to detect a 'roll down' lemma, and failing to write 'over'.

What the manual makes clear is that extra words need shifting backwards in the stream to precede the final tags. And that this happens in the 'pretransfer' stage. And that the 'g' tag provides the hint. So the following code will produce our intended lemma. It places the informative tags at the end of the bidex entry. It signals the word 'down' is invariant, so the trailing <vblex> must refer to the text 'roll',

e><p><l>???lemma from another language???</l><r>roll<g></b>down</g><s n="vblex"></r></p></e>

We need to do the same in a mono-dictionary. If we do not, the result will again go unrecognised. So, to enable multiword verb translation,

<e lm="roll down">
  <i>roll</i><par n="accept__vblex">
  <p>
    <l><b/>down</l>
    <r><g><b/>down</g></r>
  </p>
</e>

For a monodix, this is a long and complex line. But, you will remember, this method avoids creating a massive and non-reusable paradigm.


The translation rule[edit]

Before we have a translation, there is a last step. The 'g' tags may solve the problem of the unrecognised lemma, but they do nothing with the tags attached to the invariant words. The post-translation stream for 'roll down' may be,

^roll# down<vblex><imp>$

But the new monodix entry uses the 'g' tag to signal an invariant addition (there may be shortcuts for some situations? R.C.). We asked the bidex to have the tags at the end so Apertium would recognise and trigger the lemma we intended. Now Apertium needs the invariant part, after the morphological tags:

^roll<vblex><imp># down$

From the manual the transfer rule (in a .t1x file) is this,

    <rule comment="VBLEX">
      <pattern>
	<pattern-item n="vblex"/>
      </pattern>
      <action>
        <out>
          <lu>	    
            <clip pos="1" side="tl" part="lemh"/>
            <clip pos="1" side="tl" part="a_verb"/>
            <clip pos="1" side="tl" part="temps"/>
            <clip pos="1" side="tl" part="lemq"/>
          </lu>
        </out>
      </action>
    </rule>

The 'clip' entries are grabbing the 'pos=1' pattern match (here there is only one, anyway) from the translated side, then stripping the various 'parts' before reassembling them in order, ensuring the lemma tail/queue is at the end.

'lemh' and 'lemq' are (unusual) predefined part-definitions, which refer to the head e.g. 'roll' and tail e.g. 'over ...' of the lemma. 'a_verb' and 'temps' are the usual def-attrs for capturing a verb and tags, and the end-form of a verb such as 'imperative', 'past particle' etc.

A verbose version of the above may be,

<section-def-cats>
  <def-cat n="vblex">
    <cat-item tags="vblex.*"/>
  </def-cat>
  ...

</section-def-cats>

<section-def-attrs>
  <def-attr n="a_lexical_verb">
    <attr-item tags="vblex">
  </def-attr>

  <def-attr n="a_verb_form">
    <attr-item tags="inf">
    <attr-item tags="imp">
    <attr-item tags="pp">
    <attr-item tags="pprs">
    <attr-item tags="ger">
    <attr-item tags="subs">
    <attr-item tags="pres">
    <attr-item tags="past">
  </def-attr>
 
  <def-attr n="a_persona">
    <attr-item tags="p1">
    <attr-item tags="p2">
    <attr-item tags="mp3">
  </def-attr>

  <def-attr n="a_gender">
    <attr-item tags="f">
    <attr-item tags="m">
    <attr-item tags="mf">
  </def-attr>

  <def-attr n="a_number">
    <attr-item tags="sg">
    <attr-item tags="pl">
    <attr-item tags="sp">
    <attr-item tags="ND">
  </def-attr>
  ...

</section-def-attrs>


<pre>
    <rule comment="VBLEX">
      <pattern>
	<pattern-item n="vblex"/>
      </pattern>
      <action>
        <out>
          <lu>	    
            <clip pos="1" side="tl" part="lemh"/>
            <clip pos="1" side="tl" part="a_lexical_verb"/>
            <clip pos="1" side="tl" part="a_verb_form"/>
            <clip pos="1" side="tl" part="a_persona"/>
            <clip pos="1" side="tl" part="a_gender"/>
	    <clip pos="1" side="tl" part="a_number"/>
            <clip pos="1" side="tl" part="lemq"/>
          </lu>
        </out>
      </action>
    </rule>


But your language dictionary/translation may have different needs. You may not be handling multiword verbs. You may need other categories of tagging.

Simple usage of <j/>[edit]

The documentation gives the following example from monodix:

<e lm="del" r="LR"> 
  <p> 
    <l>del</l> 
    <r>de<s n="pr"/><j/>el<s n="det"/><s n="def"/><s n="m"/><s n="sg"/></r> 
  </p> 
</e> 

(This is marked r="LR" and so will only be used in analysis.) When "del" is read, the output from the analyser is

^del/de<pr>+el<det><def><m><sg>$

This is passed as-is through the tagger, but apertium-pretransfer turns it into

^de<pr>$ ^el<det><def><m><sg>$^

before bidix lookup.

(This also happens with compounds.)


Can I translate simple entries to and from multiword entries?[edit]

From the Manual,

It can be the case that a lemma is a multiword of this kind in one language and a single word in the other language. In that case, in the bilingual dictionary, the multiword will contain the <g> element and the single word will not.

Yes you can. The bidex only cares about lemmas.


The complicated cases[edit]

Its possible to have pretty complex multiword combinations.

    <e lm="zračna luka">
      <i>zračn</i>
      <par n="zračn/a__adj"/>
      <p>
        <l><b/>luk</l>
        <r><g><b/>luk</g></r>
      </p>
      <par n="stolic/a__n"/>
    </e>
$ echo "zračna luka" |  lt-proc sh-mk.automorf.bin 
^zračna luka/zračna<adj><f><sg><nom># luka<n><f><gen><pl>/zračna<adj><f><sg><nom># luka<n><f><nom><sg>$

$ echo "zračna luka" |  lt-proc sh-mk.automorf.bin  | apertium-tagger -g sh-mk.prob 
^zračna<adj><f><sg><nom># luka<n><f><gen><pl>$

$ echo "zračna luka" |  lt-proc sh-mk.automorf.bin  | apertium-tagger -g sh-mk.prob  | apertium-pretransfer
^zračna# luka<adj><f><sg><nom><n><f><gen><pl>$
Need to consider
  • Analysis
  • Transfer (e.g. in the bidix)
  • Generation
  • Head initial, and head final multiwords (e.g. adj+noun and phrasal verbs)
Problems
  • How to resolve ^zračna# luka<adj><f><sg><nom><n><f><gen><pl>$ in the bidix?
Solutions
  • Have two paradigms for each adjective, one with tags, one without. (bad)
This would leave us with: ^zračna luka<n><f><gen><pl>$ (basically an orthographic paradigm).
  • Have more than one entry per multi-word — this is done in apertium-es-ca, see "dirección general", "direcciones generales". (bad)
  • Have a parameterised paradigm, that when called one way outputs a paradigm with symbols, and another way outputs a paradigm without symbols.
This would only be one way, the problem would come when we try and generate. How do we get the adjective to agree with the noun?

The Spanish hack[edit]

This is how it is taken care of in the current apertium-es-ca pair, which is tenable just about for Spanish, but for Slavic languages no chance.

    <e lm="dirección general">
      <p>
        <l>dirección<b/>general</l>
        <r>dirección<b/>general<s n="n"/><s n="f"/><s n="sg"/></r>
      </p>
    </e>
    <e lm="dirección general">
      <p>
        <l>direcciones<b/>generales</l>
        <r>dirección<b/>general<s n="n"/><s n="f"/><s n="pl"/></r>
      </p>
    </e>

The Polish hack[edit]

The Polish analyser uses Metadix to solve the multiword problem, though this is less than desirable:

<pardef n="kamie/ń [nazębn]y__n">
  <e>
    <p>
      <l>ń<b/></l>
      <r>ń<b/></r>
    </p>
    <i><prm/></i>
    <p>
      <l>y</l>
      <r>y<s n="n"/><s n="mi"/><s n="sg"/><s n="nom"/></r>
    </p>
  </e>
  <e>
    <p>
      <l>nia<b/></l>
      <r>ń<b/></r>
    </p>
    <i><prm/></i>
    <p>
      <l>ego</l>
      <r>y<s n="n"/><s n="mi"/><s n="sg"/><s n="gen"/></r>
    </p>
  </e>
  [etc.]
</pardef>

with the following entries:

<e lm="kamień nazębny"><i>kamie</i><par n="kamie/ń [nazębn]y__n" prm="nazębn"/></e>
<e lm="kamień szlachetny"><i>kamie</i><par n="kamie/ń [nazębn]y__n" prm="szlachetn"/></e>

The Nynorsk hack[edit]

(See this mailing list discussion for alternative versions.)

What we want:

anbefale<vblex> => rå til
anbefale<vblex> ikke<adv> => rå ikkje til
publisere<vblex> => gje ut
publisere<vblex> helst<adv> daglig<adv> => gje helst dagleg ut

ie. we want a simple Bokmål verb translated into a particle verb, and any following string of adverbs should be placed between the (inflected) verb and the (uninflected/invariant) particle.

The hack:

For generation we don't actually need the multiwords in monodix (but it doesn't hurt). We have the regular multiword entry in bidix:

 <e>       <p><l>rå<g><b/>til</g></l><r>anbefale</r></p><par n="vblex"/></e>

and the transfer rule that matches "vblex adv" writes

      <out>
        <lu>
          <clip pos="1" side="tl" part="lemh"/>
          <clip pos="1" side="tl" part="a_verb"/>
          <clip pos="1" side="tl" part="temps"/>
        </lu>
        
        <lu><clip pos="2" side="tl" part="whole"/></lu>
        
        <lu><clip pos="1" side="tl" part="lemq"/></lu>
      </out>

So now transfer will give us the following result:

 echo ^anbefale<vblex><pret>$ ^ikke<adv>$ | apertium-transfer apertium-nn-nb.nb-nn.t1x nb-nn.t1x.bin nb-nn.autobil.bin
 ^rå<vblex><pret>$ ^ikkje<adv>$ ^# til$

Thus we have three "lemma" which need dictionary entries in generation, the first to ("rå" and "ikkje") are in there already as regular simple entries, the last one is "# til", which we add in this manner:

   <e lm="# til" r="RL"><p><l>til</l><r># til</r></p></e>

Ugly, but it works. And since there are not very many such particles, the Nynorsk monodix doesn't need that many ugly entries.


Of course, the Nynorsk monodix could also have "regular" entries for multiwords with inner inflection for catching "rå til" when there are no adverbs between the two, but we won't be able to analyse "rå ikkje/helst/dagleg til" with the above method.

See also[edit]