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|
--1 A Simple Norwegian Resource Morphology
--
-- Aarne Ranta 2002
--
-- This resource morphology contains definitions needed in the resource
-- syntax. It moreover contains copies of the most usual inflectional patterns
-- as defined in functional morphology (in the Haskell file $RulesSw.hs$).
--
-- We use the parameter types and word classes defined for morphology.
resource MorphoNor = CommonScand, ResNor ** open Prelude, Predef in {
-- genders
oper
masc = Utr Masc ;
fem = Utr Fem ;
neutr = Neutr ;
-- type synonyms
Subst : Type = {s : Number => Species => Case => Str} ;
Adj = Adjective ;
-- nouns
mkSubstantive : (_,_,_,_ : Str) -> Subst =
\dreng, drengen, drenger, drengene ->
{s = nounForms dreng drengen drenger drengene} ;
extNGen : Str -> Gender = \s -> case last s of {
"n" => Utr Masc ;
"a" => Utr Fem ;
_ => Neutr
} ;
nBil : Str -> Subst = \bil ->
mkSubstantive bil (bil + "en") (bil + "er") (bil + "erne") **
{h1 = masc} ;
nUke : Str -> Subst = \uke ->
mkSubstantive uke (init uke + "a") (uke + "r") (uke + "ne") **
{h1 = fem} ;
nHus : Str -> Subst = \hus ->
mkSubstantive hus (hus + "et") hus (hus + "ene") **
{h1 = neutr} ;
nHotell : Str -> Subst = \hotell ->
mkSubstantive hotell (hotell + "et") (hotell + "er") (hotell + "ene") **
{h1 = neutr} ;
-- adjectives
mkAdject : (_,_,_,_,_ : Str) -> Adj =
\stor,stort,store,storre,storst -> {s = table {
AF (APosit (Strong SgUtr )) c => mkCase c stor ;
AF (APosit (Strong SgNeutr)) c => mkCase c stort ;
AF (APosit _) c => mkCase c store ;
AF ACompar c => mkCase c storre ;
AF (ASuperl SupStrong) c => mkCase c storst ;
AF (ASuperl SupWeak) c => mkCase c (storst + "e")
}
} ;
aRod : Str -> Adj = \rod ->
mkAdject rod (rod + "t") (rod + "e") (rod + "ere") (rod + "est") ;
aAbstrakt : Str -> Adj = \abstrakt ->
mkAdject abstrakt abstrakt (abstrakt + "e") (abstrakt + "ere") (abstrakt + "est") ;
aRask : Str -> Adj = \rask ->
mkAdject rask rask (rask + "e") (rask + "ere") (rask + "est") ;
aBillig : Str -> Adj = \billig ->
mkAdject billig billig (billig + "e") (billig + "ere") (billig + "st") ;
-- verbs
Verbum : Type = {s : VForm => Str} ;
mkVerb6 : (_,_,_,_,_,_ : Str) -> Verbum =
\spise,spiser,spises,spiste,spist,spis -> {s = table {
VI (VInfin v) => mkVoice v spise ;
VF (VPres Act) => spiser ;
VF (VPres Pass) => spises ;
VF (VPret v) => mkVoice v spiste ; --# notpresent
VI (VSupin v) => mkVoice v spist ; --# notpresent
VI (VPtPret (Strong (SgUtr | SgNeutr)) c) => mkCase c spist ;
VI (VPtPret _ c) => case last spist of {
"a" => mkCase c spist ;
_ => mkCase c (spist + "e")
} ;
VF (VImper v) => mkVoice v spis
}
} ;
vHusk : Str -> Verbum = \husk ->
let huska : Str = husk + "a" ---- variants {husk + "a" ; husk + "et"}
in
mkVerb6 (husk + "e") (husk + "er") (husk + "es") huska huska husk ;
vSpis : Str -> Verbum = \spis ->
mkVerb6 (spis + "e") (spis + "er") (spis + "es") (spis + "te") (spis + "t") spis ;
vLev : Str -> Verbum = \lev ->
let lever = case last lev of {
"r" => lev ;
_ => lev + "er"
}
in
mkVerb6 (lev + "e") lever (lev + "es") (lev + "de") (lev + "d") lev ;
vBo : Str -> Verbum = \bo ->
mkVerb6 bo (bo + "r") (bo + "es") (bo + "dde") (bo + "dd") bo ;
regVerb : Str -> Str -> Verbum = \spise, spiste ->
let
spis = init spise ;
te = dp 2 spiste
in
case te of {
"te" => vSpis spis ;
"de" => case last spise of {
"e" => vLev spis ;
_ => vBo spise
} ;
_ => vHusk spis
} ;
-- For $Numeral$.
param DForm = ental | ton | tiotal ;
oper
LinDigit = {s : DForm => CardOrd => Str} ;
cardOrd : Str -> Str -> CardOrd => Str = \tre,tredje ->
table {
NCard _ => tre ;
NOrd a => tredje ---- a
} ;
cardReg : Str -> CardOrd => Str = \syv ->
cardOrd syv (syv + case last syv of {
"n" => "de" ;
"e" => "nde" ;
_ => "ende"
}) ;
mkTal : (x1,_,_,_,x5 : Str) -> LinDigit =
\två, tolv, tjugo, andra, tolfte ->
{s = table {
ental => cardOrd två andra ;
ton => cardOrd tolv tolfte ;
tiotal => cardReg tjugo
}
} ;
numPl : (CardOrd => Str) -> {s : CardOrd => Str ; n : Number} = \n ->
{s = n ; n = Pl} ;
invNum : CardOrd = NCard Neutr ;
}
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