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--# -path=.:../scandinavian:../common:../abstract:../../prelude
--1 Swedish Lexical Paradigms
--
-- Aarne Ranta 2001 - 2006
--
-- This is an API for the user of the resource grammar
-- for adding lexical items. It gives functions for forming
-- expressions of open categories: nouns, adjectives, verbs.
--
-- Closed categories (determiners, pronouns, conjunctions) are
-- accessed through the resource syntax API, $Structural.gf$.
--
-- The main difference with $MorphoSwe.gf$ is that the types
-- referred to are compiled resource grammar types. We have moreover
-- had the design principle of always having existing forms, rather
-- than stems, as string arguments of the paradigms.
--
-- The structure of functions for each word class $C$ is the following:
-- first we give a handful of patterns that aim to cover all
-- regular cases. Then we give a worst-case function $mkC$, which serves as an
-- escape to construct the most irregular words of type $C$.
-- However, this function should only seldom be needed: we have a
-- separate module [``IrregSwe`` ../../swedish/IrregSwe],
-- which covers many irregular verbs.
resource ParadigmsSwe =
open
(Predef=Predef),
Prelude,
CommonScand,
ResSwe,
MorphoSwe,
CatSwe in {
--2 Parameters
--
-- To abstract over gender names, we define the following identifiers.
oper
Gender : Type ;
utrum : Gender ;
neutrum : Gender ;
-- To abstract over number names, we define the following.
Number : Type ;
singular : Number ;
plural : Number ;
-- To abstract over case names, we define the following.
Case : Type ;
nominative : Case ;
genitive : Case ;
-- Prepositions used in many-argument functions can be constructed from strings.
mkPrep : Str -> Prep ;
noPrep : Prep ; -- empty string
--2 Nouns
-- The following overloaded paradigm takes care of all noun formation.
mkN : overload {
-- The one-argument case takes the singular indefinite form and computes
-- the other forms and the gender by a simple heuristic. The heuristic is currently
-- to treat all words ending with "a" like "apa-apor", with "e" like "rike-riken",
-- and otherwise like "bil-bilar".
mkN : (apa : Str) -> N ;
-- The case with a string and gender makes it possible to treat
-- "lik" (neutrum) and "pojke" (utrum).
mkN : (lik : Str) -> Gender -> N ;
-- Giving two forms - the singular and plural indefinite - is sufficient for
-- most nouns. The paradigm deals correctly with the vowel contractions in
-- "nyckel - nycklar" such as "pojke - pojkar".
mkN : (nyckel,nycklar : Str) -> N ;
-- In the worst case, four forms are needed.
mkN : (museum,museet,museer,museerna : Str) -> N
} ;
-- All the functions above work quite as well to form *compound nouns*,
-- such as "fotboll".
--3 Relational nouns
--
-- Relational nouns ("kung av x") are nouns with a preposition.
-- As a special case, we provide regular nouns (formed with one-argument $mkN$)
-- with the preposition "av".
mkN2 : overload {
mkN2 : Str -> N2 ;
mkN2 : N -> Prep -> N2
} ;
-- Three-place relational nouns ("förbindelse från x till y")
-- need two prepositions.
mkN3 : N -> Prep -> Prep -> N3 ;
--3 Relational common noun phrases
--
-- In some cases, you may want to make a complex $CN$ into a
-- relational noun (e.g. "den före detta maken till"). However, $N2$ and
-- $N3$ are purely lexical categories. But you can use the $AdvCN$
-- and $PrepNP$ constructions to build phrases like this.
--
--3 Proper names and noun phrases
--
-- Proper names, with a regular genitive, are formed from strings and
-- have the default gender utrum.
mkPN : overload {
mkPN : Str -> PN ;
mkPN : Str -> Gender -> PN ;
-- In the worst case, the genitive form is irregular.
mkPN : (jesus,jesu : Str) -> Gender -> PN
} ;
--2 Adjectives
-- Adjectives need one to seven forms.
mkA : overload {
-- Most adjectives are formed simply by adding endings to a stem.
mkA : (billig : Str) -> A ;
-- Some adjectives have a deviant neuter form. The following pattern
-- also recognizes the neuter formation "galen-galet" and forms the
-- proper plural and comparison forms "galna-galnare-galnast".
mkA : (bred,brett : Str) -> A ;
-- Umlaut in comparison forms is
mkA : (tung,tyngre,tyngst : Str) -> A ;
-- A few adjectives need 5 forms.
mkA : (god,gott,goda,battre,bast : Str) -> A ;
-- Hardly any other adjective than "liten" needs the full 7 forms.
mkA : (liten,litet,lilla,sma,mindre,minst,minsta : Str) -> A
} ;
-- Comparison forms may be compound ("mera svensk" - "mest svensk");
-- this behaviour can be forced on any adjective.
compoundA : A -> A ;
--3 Two-place adjectives
--
-- Two-place adjectives need a preposition for their second argument.
mkA2 : A -> Prep -> A2 ;
--2 Adverbs
-- Adverbs are not inflected. Most lexical ones have position
-- after the verb. Some can be preverbal in subordinate position
-- (e.g. "alltid").
mkAdv : Str -> Adv ; -- här
mkAdV : Str -> AdV ; -- alltid
-- Adverbs modifying adjectives and sentences can also be formed.
mkAdA : Str -> AdA ;
--2 Verbs
--
-- All verbs can be defined by the overloaded paradigm $mkV$.
mkV : overload {
-- The 'regular verb' (= one-place) case is inspired by Lexin. It uses the
-- present tense indicative form. The value is the first conjugation if the
-- argument ends with "ar" ("tala" - "talar" - "talade" - "talat"),
-- the second with "er" ("leka" - "leker" - "lekte" - "lekt", with the
-- variations like in "gräva", "vända", "tyda", "hyra"), and
-- the third in other cases ("bo" - "bor" - "bodde" - "bott").
-- It is also possible to give the infinite form to it; they are treated
-- as if they were implicitly suffixed by "r". Moreover, deponent verbs
-- are recognized from the final "s" ("hoppas").
mkV : (stämmer : Str) -> V ;
-- Most irregular verbs need just the conventional three forms.
mkV : (dricka,drack,druckit : Str) -> V ;
-- In the worst case, six forms are given.
mkV : (gå,går,gå,gick,gått,gången : Str) -> V ;
-- Particle verbs, such as "passa på", are formed by adding a string to a verb.
mkV : V -> Str -> V
} ;
--3 Deponent verbs.
--
-- Some words are used in passive forms only, e.g. "hoppas", some as
-- reflexive e.g. "ångra sig". Regular deponent verbs are also
-- handled by $mkV$ and recognized from the ending "s".
depV : V -> V ;
reflV : V -> V ;
--3 Two-place verbs
--
-- Two-place verbs need a preposition, which default to the 'empty preposition'
-- i.e. direct object. (transitive verbs). The simplest case is a regular
-- verb (as in $mkV$) with a direct object.
-- Notice that, if a particle is needed, it comes from the $V$.
mkV2 : overload {
mkV2 : Str -> V2 ;
mkV2 : V -> V2 ;
mkV2 : V -> Prep -> V2
} ;
--3 Three-place verbs
--
-- Three-place (ditransitive) verbs need two prepositions, of which
-- the first one or both can be absent. The simplest case is a regular
-- verb (as in $mkV$) with no prepositions.
mkV3 : overload {
mkV3 : Str -> V3 ;
mkV3 : V -> V3 ;
mkV3 : V -> Prep -> V3 ;
mkV3 : V -> Prep -> Prep -> V3
} ;
--3 Other complement patterns
--
-- Verbs and adjectives can take complements such as sentences,
-- questions, verb phrases, and adjectives.
mkV0 : V -> V0 ;
mkVS : V -> VS ;
mkV2S : V -> Prep -> V2S ;
mkVV : V -> VV ;
mkV2V : V -> Prep -> Prep -> V2V ;
mkVA : V -> VA ;
mkV2A : V -> Prep -> V2A ;
mkVQ : V -> VQ ;
mkV2Q : V -> Prep -> V2Q ;
mkAS : A -> AS ;
mkA2S : A -> Prep -> A2S ;
mkAV : A -> AV ;
mkA2V : A -> Prep -> A2V ;
-- Notice: categories $AS, A2S, AV, A2V$ are just $A$.
-- $V0$ is just $V$.
V0 : Type ;
AS, A2S, AV, A2V : Type ;
--.
--2 Definitions of the paradigms
--
-- The definitions should not bother the user of the API. So they are
-- hidden from the document.
Gender = ResSwe.Gender ;
Number = CommonScand.Number ;
Case = CommonScand.Case ;
utrum = Utr ;
neutrum = Neutr ;
singular = Sg ;
plural = Pl ;
nominative = Nom ;
genitive = Gen ;
mkPrep p = {s = p ; lock_Prep = <>} ;
noPrep = mkPrep [] ;
mkN = overload {
mkN : (apa : Str) -> N = regN ;
mkN : Str -> Gender -> N = regGenN ;
mkN : (nyckel, nycklar : Str) -> N = mk2N ;
mkN : (museum,museet,museer,museerna : Str) -> N = mk4N ;
mkN : Str -> N -> N = compoundN ;
} ;
compoundN : Str -> N -> N = \s,no -> {
s = \\n,d,c => s ++ no.s ! n ! d ! c ;
g = no.g ;
lock_N = <>
} ;
mk4N : (museum,museet,museer,museerna : Str) -> N = \apa,apan,apor,aporna -> {
s = nounForms apa apan apor aporna ;
g = case last apan of {
"n" => Utr ;
_ => Neutr
}
} ** {lock_N = <>} ;
regN : Str -> N = \bil -> regGenN bil g where {
g = case <bil : Str> of {
_ + "e" => Neutr ;
_ => Utr
}
} ;
regGenN : Str -> Gender -> N = \bil, g -> case g of {
Utr => case last bil of {
"a" => decl1Noun bil ;
_ => decl2Noun bil
} ;
Neutr => case last bil of {
"e" => decl4Noun bil ;
_ => decl5Noun bil
}
} ** {lock_N = <>} ;
mk1N : Str -> N = \bilarna -> case bilarna of {
ap + "orna" => decl1Noun (ap + "a") ;
bil + "arna" => decl2Noun bil ;
rad + "erna" => decl3Noun rad ;
rik + "ena" => decl4Noun (rik + "e") ;
husen => decl5Noun (Predef.tk 2 husen)
} ;
mk2N : Str -> Str -> N = \bil,bilar ->
ifTok N bil bilar (decl5Noun bil) (
case Predef.dp 2 bilar of {
"or" => case bil of {
_ + "a" => decl1Noun bil ; -- apa, apor
_ + "o" => mk4N bil (bil + "n") bilar (bilar + "na") ; -- ko,kor
_ => mk4N bil (bil + "en") bilar (bilar + "na") -- ros,rosor
} ;
"ar" => decl2Noun bil ;
"er" => case bil of {
_ + "or" => mk4N bil (bil + "n") bilar (bilar + "na") ; -- motor,motorn
_ => decl3gNoun bil bilar -- fot, fötter
} ;
"en" => decl4Noun bil ; -- rike, riken
_ => mk4N bil (bil + "et") bilar (bilar + "n") -- centrum, centra
}) ;
-- School declensions.
decl1Noun : Str -> N = \apa ->
let ap = init apa in
mk4N apa (apa + "n") (ap + "or") (ap + "orna") ;
decl2Noun : Str -> N = \bil ->
let
bb : Str * Str = case bil of {
br + ("o" | "u" | "ö" | "å") => <bil + "ar", bil + "n"> ;
pojk + "e" => <pojk + "ar", bil + "n"> ;
hi + "mme" + l@("l" | "r") => <hi + "m" + l + "ar",hi + "m" + l + "en"> ;
nyck + "e" + l@("l" | "r") => <nyck + l + "ar",bil + "n"> ;
sock + "e" + "n" => <sock + "nar", sock + "nen"> ;
_ => <bil + "ar", bil + "en">
} ;
in mk4N bil bb.p2 bb.p1 (bb.p1 + "na") ;
decl3Noun : Str -> N = \sak ->
case last sak of {
"e" => mk4N sak (sak + "n") (sak +"r") (sak + "rna") ;
"y" | "å" | "é" | "y" => mk4N sak (sak + "n") (sak +"er") (sak + "erna") ;
_ => mk4N sak (sak + "en") (sak + "er") (sak + "erna")
} ;
decl3gNoun : Str -> Str -> N = \sak,saker ->
case last sak of {
"e" => mk4N sak (sak + "n") saker (saker + "na") ;
"y" | "å" | "é" | "y" => mk4N sak (sak + "n") saker (saker + "na") ;
_ => mk4N sak (sak + "en") saker (saker + "na")
} ;
decl4Noun : Str -> N = \rike ->
mk4N rike (rike + "t") (rike + "n") (rike + "na") ;
decl5Noun : Str -> N = \lik ->
case lik of {
nu + "mme" + l@("l" | "r") =>
mk4N lik (nu + "m" + l + "et") lik (nu + "m" + l + "en") ;
vad@(?+?+?+_) + "e" + l@("l" | "r") =>
mk4N lik (vad + l + "et") lik (vad + l + "en") ;
_ + "are" => mk4N lik (lik + "n") lik (init lik + "na") ; -- kikare
_ => mk4N lik (lik + "et") lik (lik + "en")
} ;
mkN2 = overload {
mkN2 : Str -> N2 = \s -> mmkN2 (regN s) (mkPrep "av") ;
mkN2 : N -> Prep -> N2 = mmkN2
} ;
mmkN2 : N -> Prep -> N2 ;
regN2 : Str -> Gender -> N2 ;
mmkN2 = \n,p -> n ** {lock_N2 = <> ; c2 = mkComplement p.s} ;
regN2 n g = mmkN2 (regGenN n g) (mkPrep "av") ;
mkN3 = \n,p,q -> n **
{lock_N3 = <> ; c2 = mkComplement p.s ; c3 = mkComplement q.s} ;
mkPN = overload {
mkPN : Str -> PN = regPN ;
mkPN : Str -> Gender -> PN = regGenPN ;
mkPN : (jesus,jesu : Str) -> Gender -> PN = \jesus,jesu,g ->
{s = table {Nom => jesus ; Gen => jesu} ; g = g ; lock_PN = <>} ;
} ;
regPN n = regGenPN n utrum ;
regGenPN n g = {s = \\c => mkCase c n ; g = g} ** {lock_PN = <>} ;
nounPN n = {s = n.s ! singular ! Indef ; g = n.g ; lock_PN = <>} ;
makeNP x y n g =
{s = table {NPPoss _ => y ; _ => x} ; a = agrP3 g n ; p = P3 ;
lock_NP = <>} ;
mkA = overload {
mkA : (billig : Str) -> A = regA ;
mkA : (bred,brett : Str) -> A = mk2A ;
mkA : (tung,tyngre,tyngst : Str) -> A = irregA ;
mkA : (god,gott,goda,battre,bast : Str) -> A =
\liten,litet,lilla,mindre,minst ->
mk7A liten litet lilla lilla mindre minst (minst + "a") ;
mkA : (liten,litet,lilla,sma,mindre,minst,minsta : Str) -> A = mk7A
} ;
regA : Str -> A ;
mk2A : (bred,brett : Str) -> A ;
irregA : (tung,tyngre,tyngst : Str) -> A ;
mk7A : (liten,litet,lilla,sma,mindre,minst,minsta : Str) -> A ;
mk7A a b c d e f g = mkAdjective a b c d e f g ** {isComp = False ; lock_A = <>} ;
regA fin =
let fint : Str = case fin of {
ru + "nd" => ru + "nt" ;
se + "dd" => se + "tt" ;
pla + "tt" => pla + "tt" ;
gla + "d" => gla + "tt" ;
_ => fin + "t"
}
in
mk3A fin fint (fin + "a") ;
irregA ung yngre yngst =
mk7A ung (ung + "t") (ung + "a") (ung + "a") yngre yngst (yngst+"a") ;
mk3A ljummen ljummet ljumma =
mk7A
ljummen ljummet ljumma ljumma
(ljumma + "re") (ljumma + "st") (ljumma + "ste") ;
mk2A vid vitt = case <vid,vitt> of {
<gal + "en", _ + "et"> => mk3A vid vitt (gal + "na") ;
_ => mk3A vid vitt (vid + "a")
} ;
compoundA adj = {s = adj.s ; isComp = True ; lock_A = <>} ;
mkA2 a p = a ** {c2 = mkComplement p.s ; lock_A2 = <>} ;
mkAdv x = ss x ** {lock_Adv = <>} ;
mkAdV x = ss x ** {lock_AdV = <>} ;
mkAdA x = ss x ** {lock_AdA = <>} ;
mkV = overload {
mkV : (stämmer : Str) -> V = regV ;
mkV : (dricka,drack,druckit : Str) -> V = irregV ;
mkV : (supa,super,sup,söp,supit,supen : Str) -> V = mk6V ;
mkV : V -> Str -> V = partV
} ;
mk6V = \finna,finner,finn,fann,funnit,funnen ->
let
funn = ptPretForms funnen ;
funnet = funn ! Strong SgNeutr ! Nom ;
funna = funn ! Strong Plg ! Nom
in
mkVerb finna finner finn fann funnit funnen funnet funna **
{part = [] ; vtype=VAct ; lock_V = <>} ;
regV leker = case leker of {
lek + "a" => conj1 leker ; --- bw compat
lek + "ar" => conj1 (lek + "a") ;
lek + "er" => conj2 (lek + "a") ;
bo + "r" => conj3 bo ;
ret + "as" => depV (conj1 (ret + "a")) ;
n + ("os" | "ys" | "ås" | "ös") => depV (conj3 (init leker)) ;
ret + "s" => depV (conj2 (ret + "a")) ;
_ => conj3 leker
} ;
mk2V leka lekte = case <leka,lekte> of {
<_, _ + "ade"> => conj1 leka ;
<_ + "a", _> => conj2 leka ;
_ => conj3 leka
} ;
-- school conjugations
conj1 : Str -> V = \tala ->
mk6V tala (tala + "r") tala (tala +"de") (tala +"t") (tala +"d") ;
conj2 : Str -> V = \leka ->
let lek = init leka in
case last lek of {
"l" | "m" | "n" | "v" | "g" =>
let gom = case <lek : Tok> of {
_ + "mm" => init lek ;
_ => lek
}
in mk6V leka (lek + "er") gom (gom +"de") (gom +"t") (gom +"d") ;
"r" =>
mk6V leka lek lek (lek +"de") (lek +"t") (lek +"d") ;
_ => case lek of {
_ + "nd" =>
mk6V leka (lek + "er") lek (lek +"e") (init lek +"t") lek ;
_ =>
mk6V leka (lek + "er") lek (lek +"te") (lek +"t") (lek +"t")
}
} ;
conj3 : Str -> V = \bo ->
mk6V bo (bo + "r") bo (bo +"dde") (bo +"tt") (bo +"dd") ;
irregV = \sälja, sålde, sålt ->
let
säljer = case last sälja of {
"a" => conj2 sälja ;
_ => conj3 sälja
} ;
såld = case Predef.dp 2 sålt of {
"it" => Predef.tk 2 sålt + "en" ;
"tt" => Predef.tk 2 sålt + "dd" ;
_ => init sålt + "d"
}
in
mk6V sälja (säljer.s ! VF (VPres Act)) (säljer.s ! (VF (VImper Act))) sålde sålt såld
** {s1 = [] ; lock_V = <>} ;
partV v p = {s = v.s ; part = p ; vtype = v.vtype ; lock_V = <>} ;
depV v = {s = v.s ; part = v.part ; vtype = VPass ; lock_V = <>} ;
reflV v = {s = v.s ; part = v.part ; vtype = VRefl ; lock_V = <>} ;
mkV2 = overload {
mkV2 : (läser : Str) -> V2 = \v -> dirV2 (regV v) ;
mkV2 : V -> V2 = dirV2 ;
mkV2 : V -> Prep -> V2 = mmkV2
} ;
mmkV2 v p = v ** {c2 = mkComplement p.s ; lock_V2 = <>} ;
dirV2 v = mmkV2 v noPrep ;
mkV3 = overload {
mkV3 : Str -> V3 = \v -> dirdirV3 (regV v) ;
mkV3 : V -> V3 = dirdirV3 ;
mkV3 : V -> Prep -> V3 = dirV3 ;
mkV3 : V -> Prep -> Prep -> V3 = mmkV3
} ;
mmkV3 : V -> Prep -> Prep -> V3 ; -- tala, med, om
dirV3 : V -> Prep -> V3 ; -- ge, (acc),till
dirdirV3 : V -> V3 ; -- ge, (dat), (acc)
mmkV3 v p q = v ** {c2 = mkComplement p.s ; c3 = mkComplement q.s ; lock_V3 = <>} ;
dirV3 v p = mmkV3 v noPrep p ;
dirdirV3 v = dirV3 v noPrep ;
mkV0 v = v ** {lock_V0 = <>} ;
mkVS v = v ** {lock_VS = <>} ;
mkVV v = v ** {c2 = mkComplement "att" ; lock_VV = <>} ;
mkVQ v = v ** {lock_VQ = <>} ;
mkVA v = v ** {lock_VA = <>} ;
mkV2A v p = mmkV2 v p ** {lock_V2A = <>} ;
V0 : Type = V ;
-- V2S, V2V, V2Q : Type = V2 ;
AS, A2S, AV : Type = A ;
A2V : Type = A2 ;
mkV2S v p = mmkV2 v p ** {lock_V2S = <>} ;
mkV2V v p t = mmkV2 v p ** {c3 = mkComplement "att" ; lock_V2V = <>} ;
mkV2Q v p = mmkV2 v p ** {lock_V2Q = <>} ;
mkAS v = v ** {lock_A = <>} ;
mkA2S v p = mkA2 v p ** {lock_A = <>} ;
mkAV v = v ** {lock_A = <>} ;
mkA2V v p = mkA2 v p ** {lock_A = <>} ;
----------Obsolete
-- To form a noun phrase that can also be plural and have an irregular
-- genitive, you can use the worst-case function.
makeNP : Str -> Str -> Number -> Gender -> NP ;
regGenPN : Str -> Gender -> PN ;
regPN : Str -> PN ; -- utrum
-- Sometimes you can reuse a common noun as a proper name, e.g. "Bank".
nounPN : N -> PN ;
-- Sometimes just the positive forms are irregular.
mk3A : (galen,galet,galna : Str) -> A ;
mk6V : (supa,super,sup,söp,supit,supen : Str) -> V ;
regV : (talar : Str) -> V ;
mk2V : (leka,lekte : Str) -> V ;
irregV : (dricka, drack, druckit : Str) -> V ;
partV : V -> Str -> V ;
mmkV2 : V -> Prep -> V2 ;
dirV2 : V -> V2 ;
} ;