ENIAMsemGraph.ml
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(*
* ENIAMsemantics implements semantic processing for ENIAM
* Copyright (C) 2016-2017 Wojciech Jaworski <wjaworski atSPAMfree mimuw dot edu dot pl>
* Copyright (C) 2016-2017 Institute of Computer Science Polish Academy of Sciences
*
* This library is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*)
open ENIAMsemTypes
open Xstd
open Printf
(**let empty_concept =
{c_sense=Dot;c_gsense=Dot;c_orth=Dot;c_name=Dot;(* c_variable: string; c_visible_var: bool;*) c_quant=Dot; c_local_quant=true; (*c_modalities: (string * type_term) list;
c_left_input_pos: int; c_right_input_pos: int;*) c_relations=Dot; c_variable="",""; c_pos=(-1); c_cat=Dot; c_label=""; c_def_label=""}
let empty_context = {cx_sense=Dot; cx_contents=Dot; cx_relations=Dot; cx_variable="",""; cx_pos=(-1); cx_cat=Dot; cx_label=""; cx_def_label=""}*)
let make_tuple = function
[] -> Dot
| [t] -> t
| l -> Tuple l
(*let rec make_args_list = function
Tuple l -> List.flatten (Xlist.map l make_args_list)
| t -> [t]
let symbols = StringSet.of_list [
"symbol"; "date"; "date-interval"; "hour-minute"; "hour"; "hour-minute-interval"; "hour-interval";
"year"; "year-interval"; "day"; "day-interval"; "day-month"; "day-month-interval"; "month-interval"; "roman"; "roman-interval";
"match-result"; "url"; "email"; "phone-number"; "obj-id"; "building-number";
"month-lex"; "day-lex"]
let rec get_person = function
("PERS", Val s) :: _ -> s
| ("PERS", _) :: _-> failwith "get_person"
| _ :: l -> get_person l
| [] -> ""
let make_relation t c =
match t.gf with
"subj" | "obj" | "arg" ->
Relation(t.role,t.role_attr,c)
| "adjunct" ->
if t.arev then RevRelation(t.arole,t.arole_attr,c) else
Relation(t.arole,t.arole_attr,c)
| "core" -> Relation("CORE","",c)
| s -> failwith ("make_relation: " ^ s)
(*let make_make_triple_relation t c =
match t.gf with
"subj" | "obj" | "arg" ->
MakeTripleRelation(t.role,t.role_attr,c)
| "adjunct" -> MakeTripleRelation(t.arole,t.arole_attr,c)
| s -> failwith ("make_make_triple_relation: " ^ s)*)
(* let add_coerced coerced c =
if coerced = Dot then Concept c else
Concept{empty_concept with c_cat=coerced; c_relations=Tuple[Relation("Has","",Concept{c with c_relations=Dot});c.c_relations]} *)
let add_coerced coerced c =
if coerced = Dot then Concept c else
Concept{empty_concept with c_cat=coerced; c_relations=Relation("Has","",Concept c)} (* FIXME: trzeba dodać concept do tokenów *)
(* let add_coerced coerced c =
if coerced = Dot then Concept c else
let coerced_rels,c_rels = split_relations c.c_relations in
Concept{empty_concept with c_cat=coerced; c_relations=Tuple[Relation("Has","",Concept{c with c_relations=c_rels});coerced_rels]} *)
let add_coerced2 coerced c =
if coerced = Dot then c else
Concept{empty_concept with c_cat=coerced; c_relations=Relation("Has","",c)} (* FIXME: trzeba dodać concept do tokenów *)
let create_normal_concept tokens lex_sems t cat coerced =
(*if t.agf = ENIAMwalTypes.NOSEM then t.args else*)
let cat,coerced = if !user_ontology_flag then cat,coerced else Dot,Dot in
let coerced = if coerced = cat then Dot else coerced in
let c = {empty_concept with
c_sense = (*if !user_ontology_flag then Val t.lemma else*) (*if t.lemma = "<root>" then Dot else*) t.sense;
c_relations=t.args;
c_quant=if t.label = "" then t.sem_args else Dot; (* FIXME: zakładam że t.label <> "" występuje tylko dla pro *)
c_variable=string_of_int t.id,"";
c_pos=(ExtArray.get tokens t.id).ENIAMtokenizerTypes.beg;
c_local_quant=true;
c_cat=cat;
c_label=t.label;
c_def_label=t.def_label} in
if t.pos = "subst" || t.pos = "depr" || t.pos = "ger" || t.pos = "unk" || StringSet.mem symbols t.pos then (* FIXME: wykrywanie plurale tantum *)
let c = {c with c_local_quant=false} in
let c,measure,cx_flag = Xlist.fold t.attrs (c,false,false) (fun (c,measure,cx_flag) -> function
"NSYN",Val "common" -> c,measure,cx_flag
| "NSYN",Val "proper" -> {c with c_name=Val t.lemma; c_sense=Dot(*t.sense*)(*c_sense=if Val t.pred=c.c_sense then Dot else c.c_sense*)},measure,cx_flag; (* FIXME: zaślepka na potrzeby gramatyk semantycznych *) (* Rozpoznawanie propoer names nieznanego typu - ryzykowne ale proste *)
| "NSYN",Val "pronoun" -> c(*{c with c_quant=Tuple[c.c_quant;Val "indexical"]}*),measure,cx_flag
| "NSEM",Val "count" -> c(*{c with c_quant=Tuple[c.c_quant;Val "count"]}*),measure,cx_flag
| "NSEM",Val "mass" -> {c with c_quant=Tuple[c.c_quant;Val "mass"]},measure,cx_flag
| "NSEM",Variant(e,[a,Val "mass";b,Val "count"]) -> {c with c_quant=Tuple[c.c_quant;Variant(e,[a,Val "mass";b,Val "count"])]},measure,cx_flag (* FIXME: tu by należało podzielić to na dwa pudełka *)
| "NSEM",Variant(e,[a,Val "count";b,Val "mass"]) -> {c with c_quant=Tuple[c.c_quant;Variant(e,[a,Val "count";b,Val "mass"])]},measure,cx_flag
| "NSEM",Val "measure" -> c,true,cx_flag
| "NSEM",Val "time" -> c,measure,cx_flag(*failwith "create_normal_concept: time"*)
| "NUM",t -> {c with c_quant=Tuple[c.c_quant;t]},measure,cx_flag
| "CASE",_ -> c,measure,cx_flag
| "GEND",_ -> c,measure,cx_flag
| "PERS",Val "ter" -> c,measure,cx_flag
| "PERS",Val "sec" -> {c with c_relations=Tuple[c.c_relations;SingleRelation(Val "impt")]},measure,true
| "ASPECT",_ -> c,measure,cx_flag
| "NEGATION",Val "aff" -> c,measure,cx_flag
| "NEGATION",Val "neg" -> {c with c_quant=Tuple[c.c_quant;Val "nie"]},measure,cx_flag
| "controller",_ -> c,measure,cx_flag
(* | "INCLUSION",_ -> c,measure ,cx_flag
| "QUOT",Val "+" -> {c with c_relations=Tuple[c.c_relations;SingleRelation(Val "quot")]},measure,cx_flag
| "LEX",_ -> c,measure,cx_flag (* FIXME *) *)
(* | "TYPE",Val "int" -> {c with c_quant=Tuple[c.c_quant;Val "interrogative"]},measure *)
(* | "TYPE",_ -> c,measure,cx_flag (* FIXME *) *)
| e,t -> failwith ("create_normal_concept noun: " ^ e ^ ": " ^ ENIAMsemStringOf.linear_term 0 t)) in
(* let c = if t.pos = "depr" then {c with c_relations=Tuple[c.c_relations;SingleRelation(Val "depr")]} else c in *)
if cx_flag then
let id = ExtArray.add tokens ENIAMtokenizerTypes.empty_token_env in
let _ = ExtArray.add lex_sems ENIAMlexSemanticsTypes.empty_lex_sem in
make_relation t (Context{empty_context with cx_contents=add_coerced coerced c; cx_variable=string_of_int id,""; cx_pos=c.c_pos})
else
make_relation t (add_coerced coerced c) else
if t.pos = "fin" || t.pos = "bedzie" || t.pos = "praet" || t.pos = "winien" || t.pos = "impt" || t.pos = "imps" || t.pos = "pred" || t.lemma = "pro-komunikować" then
let c = {c with c_local_quant=false} in
let c = Xlist.fold t.attrs c (fun c -> function
(* "SENSE",t -> {c with c_sense=Tuple[c.c_sense;t]} *)
| "NUM",t -> c
| "GEND",_ -> c
| "PERS",_ -> c
| "ASPECT",_ -> c
(* | "CTYPE",_ -> c (* FIXME *) *)
| "TENSE",t -> {c with c_relations=Tuple[c.c_relations;SingleRelation t]}
| "MOOD",Val "indicative" -> c
| "MOOD",Val "conditional" -> {c with c_relations=Tuple[c.c_relations;SingleRelation(Val "cond")]} (* FIXME *)
| "MOOD",Val "imperative" -> {c with c_relations=Tuple[c.c_relations;SingleRelation(Val "impt")]} (* FIXME *)
| "NEGATION",Val "aff" -> c
| "NEGATION",Val "neg" -> {c with c_quant=Tuple[c.c_quant;Val "nie"]}
| e,t -> failwith ("create_normal_concept verb: " ^ e)) in
let c = if t.lemma = "pro-komunikować" then {c with c_relations=Relation("Theme","",c.c_relations)} else c in (* FIXME: to by trzeba przesunąć na wcześniej *)
let id = ExtArray.add tokens ENIAMtokenizerTypes.empty_token_env in
let _ = ExtArray.add lex_sems ENIAMlexSemanticsTypes.empty_lex_sem in
let cx = {empty_context with cx_contents=add_coerced coerced c; cx_variable=string_of_int id,""; cx_pos=c.c_pos; cx_cat=Val "Situation"} in
(* if t.role <> "" || t.role_attr <> "" then failwith "create_normal_concept: verb" else *)
make_relation t (Context cx) else
if t.pos = "inf" then
let c = {c with c_local_quant=false} in
let c = Xlist.fold t.attrs c (fun c -> function
| "ASPECT",_ -> c
| "TENSE",t -> {c with c_relations=Tuple[c.c_relations;SingleRelation t]}
| "NEGATION",Val "aff" -> c
| "NEGATION",Val "neg" -> {c with c_quant=Tuple[c.c_quant;Val "nie"]}
| e,t -> failwith ("create_normal_concept verb: " ^ e)) in
let id = ExtArray.add tokens ENIAMtokenizerTypes.empty_token_env in
let _ = ExtArray.add lex_sems ENIAMlexSemanticsTypes.empty_lex_sem in
let cx = {empty_context with cx_contents=add_coerced coerced c; cx_variable=string_of_int id,""; cx_pos=c.c_pos; cx_cat=Val "Situation"} in
make_relation t (Context cx) else
if t.pos = "adj" || t.pos = "adjc" || t.pos = "adjp" || t.pos = "adja" || t.pos = "pact" || t.pos = "ppas" || t.pos = "apron" || t.pos = "ordnum" || t.pos = "roman-adj" then
let c = if t.pos = "pact" || t.pos = "ppas" then {c with c_local_quant=false} else c in
let c = Xlist.fold t.attrs c (fun c -> function
(* "SENSE",t -> {c with c_sense=Tuple[c.c_sense;t]} *)
| "SYN",Val "common" -> c
| "SYN",Val "pronoun" -> c(*{c with c_quant=Tuple[c.c_quant;Val "indexical"]}*)
| "SYN",Val "proper" -> if t.pos = "roman-adj" then c else failwith "create_normal_concept adj: SYN=proper"
| "NSEM",Val "count" -> if t.pos = "roman-adj" then c else failwith "create_normal_concept adj: NSEM=count"
| "NUM",_ -> c
| "CASE",_ -> c
| "GEND",_ -> c
| "GRAD",Val "pos" -> c
| "GRAD",Val "com" -> {c with c_relations=Tuple[c.c_relations;SingleRelation (Val "com")]}
| "GRAD",Val "sup" -> {c with c_relations=Tuple[c.c_relations;SingleRelation (Val "sup")]}
| "ASPECT",_ -> c
| "CTYPE",_ -> c (* FIXME1: trzeba zaznaczyć pytajność w grafie, CTYPE pojawia się w dwu węzłach *)
(* | "TYPE",Val "int" -> {c with c_quant=Tuple[c.c_quant;Val "interrogative"]} *)
| "TYPE",_ -> c (* FIXME *)
| "PERS",_ -> c
| "NEGATION",Val "aff" -> c
| "NEGATION",Val "neg" -> {c with c_quant=Tuple[c.c_quant;Val "nie"]}
| "LEX",_ -> c (* FIXME *)
| e,t -> failwith ("create_normal_concept adj: " ^ e)) in
make_relation t (Concept c) else
if t.pos = "adv" || t.pos = "pcon" || t.pos = "pant" then
let c = if t.pos = "pcon" || t.pos = "pant" then {c with c_local_quant=false} else c in
let c = Xlist.fold t.attrs c (fun c -> function
(* "SENSE",t -> {c with c_sense=Tuple[c.c_sense;t]} *)
| "GRAD",Val "pos" -> c
| "GRAD",Val "com" -> {c with c_relations=Tuple[c.c_relations;SingleRelation (Val "com")]}
| "GRAD",Val "sup" -> {c with c_relations=Tuple[c.c_relations;SingleRelation (Val "sup")]}
| "ASPECT",_ -> c
(* | "TYPE",Val "int" -> {c with c_quant=Tuple[c.c_quant;Val "interrogative"]} *)
| "TYPE",_ -> c
| "MODE",_ -> c
| "NEGATION",Val "aff" -> c
| "NEGATION",Val "neg" -> {c with c_quant=Tuple[c.c_quant;Val "nie"]}
| e,t -> failwith ("create_normal_concept adv: " ^ e)) in
make_relation t (add_coerced coerced c) else
if t.pos = "prep" then
(* if t.arole = "NOSEM" then make_relation t (t.args) else *)
let c,is_sem = Xlist.fold t.attrs (c,false) (fun (c,is_sem) -> function
| "CASE",_ -> c,is_sem
| "PSEM",Val "sem" -> c,true
| "PSEM",Val "nosem" -> c,false
| e,t -> failwith ("create_normal_concept prep: " ^ e)) in
(* make_make_triple_relation t (Concept c) else *)
if is_sem then make_relation t (add_coerced2 coerced (CreateContext({empty_context with cx_sense=c.c_sense; cx_variable=c.c_variable; cx_pos=c.c_pos; cx_cat=c.c_cat},c.c_relations)))
else make_relation t (RemoveRelation("CORE","",c.c_relations)) else
if coerced <> Dot then failwith ("create_normal_concept coerced: " ^ t.lemma ^ ":" ^ t.pos) else
if t.pos = "pro" || t.pos = "ppron12" || t.pos = "ppron3" || t.pos = "siebie" then (* FIXME: indexicalność *)
let c = {c with c_local_quant=false} in
let c = Xlist.fold t.attrs c (fun c -> function
(* "NUM",t -> {c with c_relations=Tuple[c.c_relations;SingleRelation t]}
| "GEND",t -> {c with c_relations=Tuple[c.c_relations;SingleRelation t]}
| "PERS",t2 -> if t.pos = "siebie" then c else {c with c_relations=Tuple[c.c_relations;SingleRelation t2]} *)
"NUM",t -> {c with c_quant=Tuple[c.c_quant;t]}
| "GEND",t -> {c with c_quant=Tuple[c.c_quant;t]}
| "PERS",t2 -> if t.pos = "siebie" then c else {c with c_quant=Tuple[c.c_quant;t2]}
| "CASE",_ -> c
| "SYN",_ -> c
| "NSEM",_ -> c
| "controller",_ -> c
| "controllee",_ -> c
(* | "coref",t -> {c with c_relations=Tuple[c.c_relations;SingleRelation (Val "coref")]} (* FIXME: zaślepka do poprawienia przy implementacji kontroli *) *)
| e,t -> failwith ("create_normal_concept pron: " ^ e)) in
make_relation t (Concept c) else
if t.pos = "num" || t.pos = "intnum" || t.pos = "realnum" || t.pos = "intnum-interval" || t.pos = "realnum-interval" then
let c = Xlist.fold t.attrs c (fun c -> function
(* "SENSE",t -> {c with c_sense=Tuple[c.c_sense;t]} *)
| "ACM",_ -> c
| "NUM",_ -> c
| "CASE",_ -> c
| "GEND",_ -> c
| "PERS",_ -> c
| "NSYN",_ -> c
| "NSEM",_ -> c
| e,t -> failwith ("create_normal_concept num: " ^ e)) in
make_relation t ((*Quantifier*)(Concept c)) else
if t.pos = "part" && t.lemma="się" then
(*let c = {c with c_quant=Tuple[c.c_quant;Val "coreferential"]} in*)
make_relation t ((*Quantifier*)(Concept c)) else
if t.pos = "part" && (t.lemma="czy" || t.lemma="gdyby") then
make_relation t (SetContextName(c.c_sense,RemoveRelation("CORE","",c.c_relations))) else
if t.pos = "qub" then
let c = Xlist.fold t.attrs c (fun c -> function
(* | "TYPE",Val "int" -> {c with c_quant=Tuple[c.c_quant;Val "interrogative"]}
| "TYPE",_ -> c*)
| e,t -> failwith ("create_normal_concept qub: " ^ e)) in
make_relation t (Concept c) else
if t.pos = "comp" then
make_relation t (SetContextName(c.c_sense,RemoveRelation("CORE","",c.c_relations))) else
if t.pos = "conj" then
let c = {empty_context with cx_sense=t.sense; cx_contents=t.args; cx_variable=c.c_variable; cx_pos=c.c_pos; cx_cat=c.c_cat; cx_def_label=c.c_def_label; cx_label=c.c_label} in
let c = Xlist.fold t.attrs c (fun c -> function
| "NUM",_ -> c
| "CASE",_ -> c
| "GEND",_ -> c
| "PERS",_ -> c
| "ASPECT",_ -> c
| "controller",_ -> c
| "controllee",_ -> c
| e,t -> failwith ("create_normal_concept conj: " ^ e)) in
ManageCoordination({t with attrs=[]; args=Dot},Context c) else
(* if t.pos = "interj" then
let c = Xlist.fold t.attrs c (fun c -> function
| e,t -> failwith ("create_normal_concept interj: " ^ e)) in
make_relation t (Concept c) else *)
if t.pos = "sinterj" || t.pos = "interj" then
let c = Xlist.fold t.attrs c (fun c -> function
| e,t -> failwith ("create_normal_concept sinterj: " ^ e)) in
let id = ExtArray.add tokens ENIAMtokenizerTypes.empty_token_env in
let _ = ExtArray.add lex_sems ENIAMlexSemanticsTypes.empty_lex_sem in
let cx = {empty_context with cx_contents=add_coerced coerced c; cx_variable=string_of_int id,""; cx_pos=c.c_pos; cx_cat=Val "Situation"} in
make_relation t (Context cx) else
if t.lemma = "<root>" then t.args else
if t.lemma = "<merge>" then RemoveRelation("null","",t.args) else
(* if t.pos = "interp" && t.lemma = "?" && t.args = Dot then SingleRelation(Val "int") else *)
if t.pos = "interp" && t.lemma = "?" then
make_relation t (AddSingleRelation(Val "int",RemoveRelation("CORE","",t.args))) else (* FIXME1: to powinno tworzyć kontekst i zaznaczać ze jest interrogative *)
if t.pos = "interp" && t.lemma = ":" then
make_relation t (RemoveRelation("CORE","",t.args)) else
if t.pos = "interp" && t.lemma = "</sentence>" then
let l = (*List.rev*) (make_args_list t.args) in
Xlist.fold (List.tl l) (RemoveRelation("null","",List.hd l)) (fun t s -> AddRelation(t,"Next","Clause",RemoveRelation("null","",s))) else
if t.pos = "interp" && t.lemma = "<sentence>" then t.args else
if t.pos = "interp" && t.lemma = "</query>" then
let l = (*List.rev*) (make_args_list t.args) in
Xlist.fold (List.tl l) (List.hd l) (fun t s -> AddRelation(t,"Next","Sentence",s)) else
if t.pos = "interp" && t.lemma = "<query>" then t.args else
(* if t.pos = "interp" && t.lemma = "”s" then
let l = List.rev (make_args_list t.args) in
let x = Xlist.fold (List.tl l) (List.hd l) (fun t s -> AddRelation(RemoveRelation t,"Next","Sentence",RemoveRelation s)) in
Relation(t.arole,t.arole_attr,x) else (* FIXME: czy na pewno tu i w następnych arole a nie position.role? *)
if t.pos = "interp" && t.lemma = "<or>" then
Relation(t.arole,t.arole_attr,t.args) else
if t.pos = "interp" && t.lemma = "<speaker>" then
Relation(t.arole,t.arole_attr,RemoveRelation t.args) else
if t.pos = "interp" && t.lemma = "</query>" then
let l = List.rev (make_args_list t.args) in
let x = Xlist.fold (List.tl l) (List.hd l) (fun t s -> AddRelation(RemoveRelation t,"Next","Sentence",RemoveRelation s)) in
if t.gf = "obj" then Relation(t.arole,t.arole_attr,x) else x else
if t.pos = "interp" && t.lemma = "<query1>" then t.args else
if t.pos = "interp" && t.lemma = "<query2>" then t.args else
if t.pos = "interp" && t.lemma = "<query4>" then t.args else
if t.pos = "interp" && t.lemma = "<query5>" then
let l = List.rev (make_args_list t.args) in
Xlist.fold (List.tl l) (List.hd l) (fun t s -> AddRelation(RemoveRelation t,"Next","Sentence",RemoveRelation s)) else
if t.pos = "interp" && t.lemma = "<query6>" then
let l = List.rev (make_args_list t.args) in
Xlist.fold (List.tl l) (List.hd l) (fun t s -> AddRelation(RemoveRelation t,"Next","Sentence",RemoveRelation s)) else
if t.pos = "interp" && t.lemma = "?" then SingleRelation(Val "int") else
if t.pos = "interp" && t.lemma = "„" then
make_relation t (RemoveRelation t.args) else
if t.pos = "interp" || t.lemma = "</or-sentence>" then make_relation t (t.args) else*) (
if t.pos = "interp" then Node t else
(*if t.pos = "" then make_relation t (t.args) else*)
(* print_endline t.lemma; *)
Node t)
let rec translate_node tokens lex_sems t =
let attrs = Xlist.map t.ENIAM_LCGtypes.attrs (fun (k,t) -> k, create_concepts tokens lex_sems t) in
let t = {
orth=t.ENIAM_LCGtypes.orth; lemma=t.ENIAM_LCGtypes.lemma; pos=t.ENIAM_LCGtypes.pos; weight=t.ENIAM_LCGtypes.weight;
id=t.ENIAM_LCGtypes.id; symbol=create_concepts tokens lex_sems t.ENIAM_LCGtypes.symbol; arg_symbol=create_concepts tokens lex_sems t.ENIAM_LCGtypes.arg_symbol;
arg_dir=t.ENIAM_LCGtypes.arg_dir;
attrs=[]; label=""; def_label=""; snode="";
args=create_concepts tokens lex_sems t.ENIAM_LCGtypes.args;
gf=""; role=""; role_attr=""; coord_arg=""; selprefs=Dot; sense=Dot; arole=""; arole_attr=""; arev=false; sem_args=Dot;
(*cat=Dot;coerced=Dot*)} in
let t,attrs,cat,coerced = Xlist.fold attrs (t,[],Dot,Dot) (fun (t,attrs,cat,coerced) -> function
"gf",Val s -> {t with gf=s},attrs,cat,coerced
| "role",Val s -> {t with role=s},attrs,cat,coerced
| "role-attr",Val s -> {t with role_attr=s},attrs,cat,coerced
| "selprefs",s -> {t with selprefs=s},attrs,cat,coerced
| "sense",s -> {t with sense=s},attrs,cat,coerced
| "hipero",_ -> t,attrs,cat,coerced
| "arole",Val s -> {t with arole=s},attrs,cat,coerced
| "arole-attr",Val s -> {t with arole_attr=s},attrs,cat,coerced
| "arev",Val "-" -> {t with arev=false},attrs,cat,coerced
| "arev",Val "+" -> {t with arev=true},attrs,cat,coerced
| "agf",Val s -> t,attrs,cat,coerced
| "sem-args",s -> {t with sem_args=s},attrs,cat,coerced
| "rev-hipero",_ -> t,attrs,cat,coerced
| "fopinion",_ -> t,attrs,cat,coerced
| "sopinion",_ -> t,attrs,cat,coerced
| "ACM",s -> t,("ACM",s) :: attrs,cat,coerced
| "ASPECT",s -> t,("ASPECT",s) :: attrs,cat,coerced
| "NEGATION",s -> t,("NEGATION",s) :: attrs,cat,coerced
| "MOOD",s -> t,("MOOD",s) :: attrs,cat,coerced
| "TENSE",s -> t,("TENSE",s) :: attrs,cat,coerced
| "CTYPE",s -> t,("CTYPE",s) :: attrs,cat,coerced
| "controller",s -> t,("controller",s) :: attrs,cat,coerced
| "controllee",s -> t,("controllee",s) :: attrs,cat,coerced
| "coref",s -> t,attrs,cat,coerced
| "label",Val s -> {t with label=s},attrs,cat,coerced
| "def-label",Val s -> {t with def_label=s},attrs,cat,coerced
| "CAT",s -> t,attrs,s,coerced
| "COERCED",s -> t,attrs,cat,s
| "NUM",s -> t,("NUM",s) :: attrs,cat,coerced
| "CASE",s -> t,("CASE",s) :: attrs,cat,coerced
| "GEND",s -> t,("GEND",s) :: attrs,cat,coerced
| "PERS",s -> t,("PERS",s) :: attrs,cat,coerced
| "NSYN",s -> t,("NSYN",s) :: attrs,cat,coerced
| "NSEM",s -> t,("NSEM",s) :: attrs,cat,coerced
| "MODE",s -> t,("MODE",s) :: attrs,cat,coerced
| "GRAD",s -> t,("GRAD",s) :: attrs,cat,coerced
| "PSEM",s -> t,("PSEM",s) :: attrs,cat,coerced
(* | k,v -> printf "translate_node: %s %s\n%!" k (ENIAMsemStringOf.linear_term 0 v); t, (k,v) :: attrs,cat,coerced) in *)
| k,v -> failwith (sprintf "translate_node: %s %s\n%!" k (ENIAMsemStringOf.linear_term 0 v))) in
{t with attrs=attrs},cat,coerced
and create_concepts tokens lex_sems = function
ENIAM_LCGtypes.Node t ->
let t,cat,coerced = translate_node tokens lex_sems t in
create_normal_concept tokens lex_sems t cat coerced
| ENIAM_LCGtypes.Tuple l -> Tuple(Xlist.map l (create_concepts tokens lex_sems))
| ENIAM_LCGtypes.Variant(e,l) -> Variant(e,Xlist.map l (fun (i,t) -> i, create_concepts tokens lex_sems t))
| ENIAM_LCGtypes.Dot -> Dot
| ENIAM_LCGtypes.Val s -> Val s
| ENIAM_LCGtypes.Ref i -> Ref i
(* | Choice choices -> Choice(StringMap.map choices (create_concepts tokens lex_sems)) *)
| t -> failwith ("create_concepts: " ^ ENIAM_LCGstringOf.linear_term 0 t)
let translate tokens lex_sems term =
let sem = Array.make (Array.length term) Dot in
Int.iter 0 (Array.length sem - 1) (fun i ->
sem.(i) <- create_concepts tokens lex_sems term.(i));
sem**)
let translate tokens lex_sems term = failwith "translate: ni"
let rec make_tree_rec references = function
Node t -> Node{t with args=make_tree_rec references t.args}
| Concept c -> Concept{c with relations=make_tree_rec references c.relations; contents=List.rev (Xlist.rev_map c.contents (make_tree_rec references))}
(* | Context c -> Context{c with cx_contents=make_tree_rec references c.cx_contents; cx_relations=make_tree_rec references c.cx_relations} *)
| Relation(r,a,t) -> Relation(r,a,make_tree_rec references t)
| RevRelation(r,a,t) -> RevRelation(r,a,make_tree_rec references t)
| SingleRelation r -> SingleRelation r
(* | TripleRelation(r,a,s,t) -> TripleRelation(r,a,make_tree_rec references s,make_tree_rec references t) *)
| AddRelation(t,r,a,s) -> AddRelation(make_tree_rec references t,r,a,make_tree_rec references s)
| AddParentRelation(t,s) -> AddParentRelation(make_tree_rec references t,make_tree_rec references s)
| AddSingleRelation(r,s) -> AddSingleRelation(r,make_tree_rec references s)
| RemoveRelation(r,a,t) -> RemoveRelation(r,a,make_tree_rec references t)
| SetContextName(s,t) -> SetContextName(s,make_tree_rec references t)
| CreateContext(s,t) -> CreateContext(s,make_tree_rec references t)
(* | MakeTripleRelation(r,a,t) -> MakeTripleRelation(r,a,make_tree_rec references t) *)
| ManageCoordination(n,t) -> ManageCoordination(n,make_tree_rec references t)
| Tuple l -> Tuple(Xlist.map l (make_tree_rec references))
| Variant(e,l) -> Variant(e,Xlist.map l (fun (i,t) -> i, make_tree_rec references t))
| Dot -> Dot
| Val s -> Val s
| Ref i -> make_tree_rec references references.(i)
(* | t -> failwith ("make_tree_rec: " ^ LCGstringOf.linear_term 0 t) *)
let make_tree references =
(*RemoveRelation*)(make_tree_rec references references.(0))
let rec validate_translation r = function
Node t ->
r := ("validate_translation: " ^ ENIAMsemStringOf.linear_term 0 (Node{t with args=Dot})) :: !r;
validate_translation r t.args
| Concept c -> validate_translation r c.relations; Xlist.iter c.contents (validate_translation r)
(* | Context c -> validate_translation r c.cx_contents; validate_translation r c.cx_relations *)
| Relation(_,_,t) -> validate_translation r t
| RevRelation(_,_,t) -> validate_translation r t
| SingleRelation _ -> ()
(* | TripleRelation(_,_,s,t) -> validate_translation r s; validate_translation r t *)
| AddRelation(t,_,_,s) -> validate_translation r t; validate_translation r s
| AddParentRelation(t,s) -> validate_translation r t; validate_translation r s
| AddSingleRelation(_,s) -> validate_translation r s
| RemoveRelation(_,_,t) -> validate_translation r t
| SetContextName(s,t) -> validate_translation r t
| CreateContext(s,t) -> validate_translation r t
(* | MakeTripleRelation(_,_,t) -> validate_translation r t *)
| ManageCoordination(_,t) -> validate_translation r t
| Tuple l -> Xlist.iter l (validate_translation r)
| Variant(e,l) ->
if e = "" then r := "validate_translation: empty variant label" :: !r;
Xlist.iter l (fun (i,t) -> validate_translation r t)
| Dot -> ()
| t -> failwith ("validate_translation: " ^ ENIAMsemStringOf.linear_term 0 t)
(***************************************************************************************)
let rec simplify_tree_add_relation r a s = function
Concept c -> Concept{c with relations=Tuple[Relation(r,a,s);c.relations]}
(* | Context c -> Context{c with cx_relations=Tuple[Relation(r,a,s);c.cx_relations]} *)
| Variant(e,l) -> Variant(e,Xlist.map l (fun (i,t) -> i, simplify_tree_add_relation r a s t))
| t -> AddRelation(t,r,a,s)
let rec transpose_tuple_variant e ll =
match List.hd ll with
_,[] -> []
| _ ->
let hd,tl = Xlist.fold ll ([],[]) (fun (hd,tl) (i,l) ->
(i,List.hd l) :: hd, (i,List.tl l) :: tl) in
(Variant (e,List.rev hd)) :: (transpose_tuple_variant e (List.rev tl))
(* FIXME TODO:
Bryka chmara wieczorów: problem z wyborem relacji
uzgadnianie preferencji i role tematyczne przy num, measure i prep:nosem
Witold bryka.: dezambiguacja
Niearanżowany szpak bryka.: lematyzacja 'Niearanżowany'
dobre:
Bryka na chmarze strusi.
Pięć strusi bryka.
*)
let rec is_core_variant = function
Variant(e,l) -> Xlist.fold l true (fun b (_,t) -> is_core_variant t && b)
| Relation("CORE","",_) -> true
| Relation _ -> false
| RevRelation _ -> false
| SingleRelation _ -> false
(* | TripleRelation("CORE","",_,_) -> true *)
| Dot -> false
| t -> failwith ("is_core_variant: " ^ ENIAMsemStringOf.linear_term 0 t)
let get_core_tuple = function
Tuple l ->
let core,nocore = Xlist.fold l ([],[]) (fun (core,nocore) t ->
if is_core_variant t then t :: core,nocore else core,t :: nocore) in
(match core with
[t] -> t
| _ -> failwith "get_core_tuple"),
(match nocore with
[] -> Dot
| [t] -> t
| l -> Tuple l)
| t -> if is_core_variant t then t,Dot else failwith ("get_core_tuple: " ^ ENIAMsemStringOf.linear_term 0 t)
(* let get_core c =
let core,l = get_core_tuple c.c_relations in
core,{c with c_relations=l} *)
let set_aroles t r a b =
if t.arole="" then {t with arole=r; arole_attr=a; arev=b} else
if t.arole=r && t.arole_attr=a && t.arev=b then t else
failwith "set_aroles"
let rec extract_aroles t = function
Relation(r,a,s) -> set_aroles t r a false, s
| RevRelation(r,a,s) -> set_aroles t r a true, s
| Tuple l ->
let t,l = Xlist.fold l (t,[]) (fun (t,l) s ->
let t,s = extract_aroles t s in t, s :: l) in
t,Tuple(List.rev l)
| Variant(e,l) ->
let t,l = Xlist.fold l (t,[]) (fun (t,l) (i,s) ->
let t,s = extract_aroles t s in t, (i,s) :: l) in
t,Variant(e,List.rev l)
| Dot -> t,Dot
| s -> failwith ("extract_aroles: " ^ ENIAMsemStringOf.linear_term 0 s)
let rec reduce_tree = function
Concept c -> Concept{c with relations=reduce_tree c.relations; contents=List.rev (Xlist.rev_map c.contents reduce_tree)}
(* | Context c -> Context{c with cx_contents=reduce_tree c.cx_contents; cx_relations=reduce_tree c.cx_relations} *)
| Relation(r,a,t) ->
(match reduce_tree t with
AddParentRelation(x,Dot) -> x
| AddParentRelation(x,y) -> Tuple[Relation(r,a,y);x]
| t -> Relation(r,a,reduce_tree t))
| RevRelation(r,a,t) -> RevRelation(r,a,reduce_tree t)
| SingleRelation r -> SingleRelation r
(* | TripleRelation(r,a,s,t) -> TripleRelation(r,a,reduce_tree s,reduce_tree t) *)
(* | AddRelation(Concept c,r,a,s) -> reduce_tree (Concept{c with c_relations=Tuple[Relation(Val r,Val a,s);c.c_relations]})
| AddRelation(Context c,r,a,s) -> reduce_tree (Context{c with cx_relations=Tuple[Relation(Val r,Val a,s);c.cx_relations]})*)
| AddSingleRelation(r,t) ->
(match reduce_tree t with
Concept t -> Concept{t with relations=Tuple[t.relations;SingleRelation r]}
(* | Context({cx_sense=Val "czy"} as t) -> Context t
| Context({cx_sense=Val "jaki"} as t) -> Context t
| Context({cx_sense=Dot} as t) -> Context{t with cx_sense=Val "czy"}*)
| Variant(e,l) -> Variant(e,Xlist.map l (fun (i,t) -> i, reduce_tree (AddSingleRelation(r,t))))
| t -> AddSingleRelation(r,t))
| AddRelation(t,r,a,s) -> simplify_tree_add_relation r a (reduce_tree s) (reduce_tree t)
(* let t = reduce_tree t in
let s = reduce_tree s in
(match t with
Concept c -> Concept{c with c_relations=Tuple[Relation(Val r,Val a,s);c.c_relations]}
| Context c -> Context{c with cx_relations=Tuple[Relation(Val r,Val a,s);c.cx_relations]}
| _ -> AddRelation(t,r,a,s))*)
| AddParentRelation(t,s) -> AddParentRelation(reduce_tree t,reduce_tree s)
| RemoveRelation(r0,a0,t) ->
(match reduce_tree t with
Relation(r,a,t) ->
if (r = r0 && a = a0) || r0 = "" then t else
Concept{empty_concept with cat="Situation"; contents=
[Concept{empty_concept with relations=Relation(r,a,t)}]; (*cx_variable=string_of_int id,""; cx_pos=c.c_pos*)}
(* | TripleRelation(r,a,s,t) ->
Context{empty_context with cx_contents=
Concept{empty_concept with c_relations=TripleRelation(r,a,s,t)}; (*cx_variable=string_of_int id,""; cx_pos=c.c_pos*)} *)
| Dot -> Dot
| Variant(e,l) -> reduce_tree (Variant(e,Xlist.map l (fun (i,t) -> i,RemoveRelation(r0,a0,t))))
| Tuple l -> reduce_tree (Tuple(Xlist.map l (fun t -> RemoveRelation(r0,a0,t))))
(* | Context t -> Context t
| Concept t -> Concept t *)
| t -> RemoveRelation(r0,a0,t))
| SetContextName(s,t) ->
(match reduce_tree t with
Concept({sense=""} as t) -> Concept{t with sense=s}
| Variant(e,l) -> reduce_tree (Variant(e,Xlist.map l (fun (i,t) -> i,SetContextName(s,t))))
| t -> SetContextName(s,t))
| CreateContext(c,t) ->
(match reduce_tree t with
| Variant(e,l) -> reduce_tree (Variant(e,Xlist.map l (fun (i,t) -> i, CreateContext(c,t))))
| t ->
let core,t = get_core_tuple t in
Concept{c with relations=t; contents=[reduce_tree (RemoveRelation("CORE","",core))]})
(* | MakeTripleRelation(r,a,t) ->
(match reduce_tree t with
Concept t ->
let core,t = get_core t in
TripleRelation(r,a,Concept t,reduce_tree (RemoveRelation("CORE","",core)))
| Variant(e,l) -> reduce_tree (Variant(e,Xlist.map l (fun (i,t) -> i, MakeTripleRelation(r,a,t))))
| t -> MakeTripleRelation(r,a,t))*)
| ManageCoordination(t,c) ->
(match reduce_tree c with
Concept c ->
let t,args = extract_aroles {t with arole=""} (Tuple c.contents) in
(*make_relation t (Context {c with cx_contents=args})*) (* FIXME: to trzeba poprawić tak by działało w obu wersjach parserów *)
Relation(t.role,"",Concept {c with contents=[args]})
| Variant(e,l) -> reduce_tree (Variant(e,Xlist.map l (fun (i,c) -> i,ManageCoordination(t,c))))
| c -> ManageCoordination(t,c))
| Tuple l -> Tuple(List.rev (Xlist.rev_map l reduce_tree))
| Variant(e,l) -> Variant(e,Xlist.map l (fun (i,t) -> i, reduce_tree t))
| Dot -> Dot
| Val s -> Val s
| t -> failwith ("reduce_tree: " ^ ENIAMsemStringOf.linear_term 0 t)
let rec validate_reduction r = function
Concept c -> validate_reduction r c.relations; Xlist.iter c.contents (validate_reduction r)
(* | Context c -> validate_reduction r c.cx_contents; validate_reduction r c.cx_relations *)
| Relation(_,_,t) -> validate_reduction r t
| RevRelation(_,_,t) -> validate_reduction r t
| SingleRelation _ -> ()
(* | TripleRelation(_,_,s,t) -> validate_reduction r s; validate_reduction r t *)
| Tuple l -> Xlist.iter l (validate_reduction r)
| Variant(e,l) ->
if e = "" then r := "validate_reduction: empty variant label" :: !r;
Xlist.iter l (fun (i,t) -> validate_reduction r t)
| Dot -> ()
| t -> r := ("validate_reduction: " ^ ENIAMsemStringOf.linear_term 0 t) :: !r
(***************************************************************************************)
let rec count_variant_labels map = function
Concept c -> Xlist.fold (c.relations :: c.contents) map count_variant_labels
(* Concept c -> Xlist.fold [c.c_sense; c.c_name; c.c_quant; c.c_cat; c.c_relations] map count_variant_labels
| Context c -> Xlist.fold [c.cx_sense; c.cx_contents; c.cx_cat; c.cx_relations] map count_variant_labels*)
| Relation(_,_,t) -> count_variant_labels map t
| RevRelation(_,_,t) -> count_variant_labels map t
| SingleRelation t -> count_variant_labels map t
| Tuple l -> Xlist.fold l map count_variant_labels
| Variant(e,l) ->
let map = StringQMap.add map e in
Xlist.fold l map (fun map (i,t) -> count_variant_labels map t)
| Dot -> map
| Val s -> map
| t -> failwith ("count_variant_labels: " ^ ENIAMsemStringOf.linear_term 0 t)
let rec remove_variant_labels map = function
Concept c -> Concept{c with
(* c_sense=remove_variant_labels map c.c_sense;
c_name=remove_variant_labels map c.c_name;
c_quant=remove_variant_labels map c.c_quant;
c_cat=remove_variant_labels map c.c_cat;*)
contents=List.rev (Xlist.rev_map c.contents (remove_variant_labels map));
relations=remove_variant_labels map c.relations}
(* | Context c -> Context{c with
cx_sense=remove_variant_labels map c.cx_sense;
cx_contents=remove_variant_labels map c.cx_contents;
cx_cat=remove_variant_labels map c.cx_cat;
cx_relations=remove_variant_labels map c.cx_relations}*)
| Relation(r,a,t) -> Relation(r,a,remove_variant_labels map t)
| RevRelation(r,a,t) -> RevRelation(r,a,remove_variant_labels map t)
| SingleRelation r -> SingleRelation r
| Tuple l -> Tuple(List.rev (Xlist.rev_map l (remove_variant_labels map)))
| Variant(e,l) ->
let e = if StringQMap.find map e = 1 then "" else e in
let l = Xlist.rev_map l (fun (i,t) -> i, remove_variant_labels map t) in
Variant(e,Xlist.sort l (fun x y -> compare (fst x) (fst y)))
| Dot -> Dot
| Val s -> Val s
| t -> failwith ("remove_variant_labels: " ^ ENIAMsemStringOf.linear_term 0 t)
let rec set_variant_labels map = function
Concept c -> Concept{c with
(* c_sense=set_variant_labels map c.c_sense;
c_name=set_variant_labels map c.c_name;
c_quant=set_variant_labels map c.c_quant;
c_cat=set_variant_labels map c.c_cat;*)
contents=List.rev (Xlist.rev_map c.contents (set_variant_labels map));
relations=set_variant_labels map c.relations}
(* | Context c -> Context{c with
cx_sense=set_variant_labels map c.cx_sense;
cx_contents=set_variant_labels map c.cx_contents;
cx_cat=set_variant_labels map c.cx_cat;
cx_relations=set_variant_labels map c.cx_relations}*)
| Relation(r,a,t) -> Relation(r,a,set_variant_labels map t)
| RevRelation(r,a,t) -> RevRelation(r,a,set_variant_labels map t)
| SingleRelation r -> SingleRelation r
| Tuple l -> Tuple(List.rev (Xlist.rev_map l (set_variant_labels map)))
| Variant(e,l) ->
let e = try StringMap.find map e with Not_found -> ENIAM_LCGreductions.get_variant_label () in
let l = Xlist.rev_map l (fun (i,t) -> i, set_variant_labels map t) in
Variant(e,List.rev l)
| Dot -> Dot
| Val s -> Val s
| t -> failwith ("set_variant_labels: " ^ ENIAMsemStringOf.linear_term 0 t)
let manage_variant_labels t =
ENIAM_LCGreductions.reset_variant_label ();
let qmap = count_variant_labels StringQMap.empty t in
let map = StringQMap.fold qmap StringMap.empty (fun map k _ ->
if k = "" then map else
StringMap.add map k (ENIAM_LCGreductions.get_variant_label ())) in
set_variant_labels map t
let rec simplify_tree = function
Concept c -> Concept{c with
(* c_sense=simplify_tree c.c_sense;
c_name=simplify_tree c.c_name;
c_quant=simplify_tree c.c_quant;
c_cat=simplify_tree c.c_cat;*)
contents=List.rev (Xlist.rev_map c.contents simplify_tree);
relations=simplify_tree c.relations}
(* | Context c -> Context{c with
cx_sense=simplify_tree c.cx_sense;
cx_contents=simplify_tree c.cx_contents;
cx_cat=simplify_tree c.cx_cat;
cx_relations=simplify_tree c.cx_relations}*)
| Relation(r,a,t) -> Relation(r,a,simplify_tree t)
| RevRelation(r,a,t) -> RevRelation(r,a,simplify_tree t)
| SingleRelation r -> SingleRelation r
(* | TripleRelation(r,a,s,t) -> TripleRelation(r,a,simplify_tree s,simplify_tree t) *)
| Tuple l ->
let l = Xlist.fold l [] (fun l t ->
match simplify_tree t with
Dot -> l
| Tuple l2 -> l2 @ l
| t -> t :: l) in
make_tuple (List.rev l)
| Variant(_,[_,t]) -> simplify_tree t
| Variant(e,l) ->
let l = Xlist.map l (fun (i,t) -> i, simplify_tree t) in
let set = Xlist.fold l TermSet.empty (fun set (_,t) -> TermSet.add set t) in
if TermSet.size set = 1 then TermSet.max_elt set else
let l = List.rev (fst (TermSet.fold set ([],1) (fun (l,i) t -> (string_of_int i,t) :: l, i+1))) in
let _,t = List.hd l in
let b = Xlist.fold (List.tl l) true (fun b (_,s) -> if s = t then b else false) in
if b then t else
(try
(match t with
Concept c ->
let lt = Xlist.fold l [] (fun lt -> function
i,Concept c2 ->
if c.sense = c2.sense && c.cat = c2.cat && c.label = c2.label &&
c.def_label = c2.def_label && c2.contents = [] then (i,c2.relations) :: lt else raise Not_found
| _ -> raise Not_found) in
let e = if e = "" then ENIAM_LCGreductions.get_variant_label () else e in
Concept{c with
relations = simplify_tree (Variant(e,lt))}
(* Concept c ->
let lt1,lt2,lt3 = Xlist.fold l ([],[],[]) (fun (lt1,lt2,lt3) -> function
i,Concept c2 ->
if c.c_sense = c2.c_sense && c.c_name = c2.c_name &&
c.c_local_quant = c2.c_local_quant && c.c_label = c2.c_label &&
c.c_def_label = c2.c_def_label then (i,c2.c_quant) :: lt1, (i,c2.c_relations) :: lt2, (i,c2.c_cat) :: lt3 else raise Not_found
| _ -> raise Not_found) in
let e = if e = "" then ENIAM_LCGreductions.get_variant_label () else e in
Concept{c with
c_quant = simplify_tree (Variant(e,lt1));
c_relations = simplify_tree (Variant(e,lt2));
c_cat = simplify_tree (Variant(e,lt3))}
| Context c ->
let lt1,lt2,lt3 = Xlist.fold l ([],[],[]) (fun (lt1,lt2,lt3) -> function
i,Context c2 -> if c.cx_sense = c2.cx_sense && c.cx_label = c2.cx_label &&
c.cx_def_label = c2.cx_def_label then (i,c2.cx_contents) :: lt1, (i,c2.cx_relations) :: lt2, (i,c2.cx_cat) :: lt3 else raise Not_found
| _ -> raise Not_found) in
let e = if e = "" then ENIAM_LCGreductions.get_variant_label () else e in
Context{c with
cx_contents= simplify_tree (Variant(e,lt1));
cx_relations = simplify_tree (Variant(e,lt2));
cx_cat = simplify_tree (Variant(e,lt3))}*)
| Relation(r,a,t) ->
let lt = Xlist.fold l [] (fun lt -> function
i,Relation(r2,a2,t2) -> if r = r2 && a = a2 then (i,t2) :: lt else raise Not_found
| _ -> raise Not_found) in
simplify_tree (Relation(r,a,Variant(e,lt)))
(* | TripleRelation(r,a,s,t) ->
let ls,lt = Xlist.fold l ([],[]) (fun (ls,lt) -> function
i,TripleRelation(r2,a2,s2,t2) -> if r = r2 && a = a2 then (i,s2) :: ls, (i,t2) :: lt else raise Not_found
| _ -> raise Not_found) in
simplify_tree (TripleRelation(r,a,Variant(e,ls),Variant(e,lt))) *)
| Tuple tl ->
(* print_endline ("V3: " ^ LCGstringOf.linear_term 0 (Variant l)); *)
let n = Xlist.size tl in
let lt = Xlist.fold l [] (fun lt -> function
i,Tuple tl -> if n = Xlist.size tl then (i,tl) :: lt else raise Not_found
| _ -> raise Not_found) in
let e = if e = "" then ENIAM_LCGreductions.get_variant_label () else e in
let t = Tuple(transpose_tuple_variant e lt) in
(* print_endline ("V4: " ^ LCGstringOf.linear_term 0 t); *)
simplify_tree t
| Dot -> if Xlist.fold l true (fun b -> function
_,Dot -> b
| _ -> false) then Dot else raise Not_found
| _ -> raise Not_found)
with Not_found -> Variant(e,l))
(* Variant(e,Xlist.map l (fun (i,t) -> i, simplify_tree t)) *)
| Dot -> Dot
| Val s -> Val s
| t -> failwith ("simplify_tree: " ^ ENIAMsemStringOf.linear_term 0 t)
let greater_simplify tree =
let map = count_variant_labels StringQMap.empty tree in
let tree = remove_variant_labels map tree in
let tree = simplify_tree tree in
let map = count_variant_labels StringQMap.empty tree in
let tree = remove_variant_labels map tree in
tree
(*let rec manage_quantification2 (quants,quant) = function
Tuple l -> Xlist.fold l (quants,quant) manage_quantification2
| Dot -> quants,quant
| Val s -> quants,Tuple[Val s;quant]
| t -> (Relation("Quantifier","",t)) :: quants,quant
let rec manage_quantification = function
Node t -> Node{t with args=manage_quantification t.args}
| Concept c ->
let quants,quant = manage_quantification2 ([],Dot) c.c_quant in
Concept{c with c_quant=quant; c_relations=manage_quantification (Tuple(c.c_relations :: quants))}
| Context c -> Context{c with cx_contents=manage_quantification c.cx_contents; cx_relations=manage_quantification c.cx_relations}
| Relation(r,a,t) -> Relation(r,a,manage_quantification t)
| RevRelation(r,a,t) -> RevRelation(r,a,manage_quantification t)
| SingleRelation r -> SingleRelation r
| AddRelation(t,r,a,s) -> AddRelation(manage_quantification t,r,a,manage_quantification s)
(* | RemoveRelation t -> RemoveRelation(manage_quantification t) *)
| Tuple l -> Tuple(Xlist.map l manage_quantification)
| Variant(e,l) -> Variant(e,Xlist.map l (fun (i,t) -> i, manage_quantification t))
| Dot -> Dot
| Val s -> Val s
| t -> failwith ("manage_quantification: " ^ ENIAMsemStringOf.linear_term 0 t)*)
let simplify_gender2 = function
Variant("",l) ->
let l2 = List.sort compare (Xlist.rev_map l (function (_,Val s) -> s | _ -> raise Not_found)) in
(match l2 with
["f"; "m1"; "m2"; "m3"; "n"] -> Dot
| ["m1"; "m2"; "m3"] -> Val "m"
| ["f"; "m2"; "m3"; "n"] -> Val "nmo"
| ["pl"; "sg"] -> Dot
| _ -> raise Not_found)
| _ -> raise Not_found
let rec simplify_gender = function
Concept c -> Concept{c with relations=simplify_gender c.relations; contents=List.rev (Xlist.rev_map c.contents simplify_gender)(*c_quant=simplify_gender c.c_quant*)}
(* | Context c -> Context{c with cx_contents=simplify_gender c.cx_contents; cx_relations=simplify_gender c.cx_relations} *)
| Relation(r,a,t) -> Relation(r,a,simplify_gender t)
| RevRelation(r,a,t) -> RevRelation(r,a,simplify_gender t)
| SingleRelation r -> SingleRelation(simplify_gender r)
| Tuple l -> Tuple(Xlist.map l simplify_gender)
| Variant(e,l) ->
(try simplify_gender2 (Variant(e,l)) with Not_found ->
Variant(e,Xlist.map l (fun (i,t) -> i, simplify_gender t)))
| Dot -> Dot
| Val s -> Val s
| t -> failwith ("simplify_gender: " ^ ENIAMsemStringOf.linear_term 0 t)
(***************************************************************************************)
(*
let rec validate_semantics_quant = function
Val _ -> true
| Variant(e,l) -> Xlist.fold l true (fun b (_,t) -> b && validate_semantics_quant t)
| Tuple l -> Xlist.fold l true (fun b t -> b && validate_semantics_quant t)
| Dot -> true
| t -> (*print_endline ("validate_semantics_quant: " ^ ENIAMsemStringOf.linear_term 0 t);*) false
let rec validate_semantics_sense = function
Val _ -> true
| Dot -> true
| t -> (*print_endline ("validate_semantics_sense: " ^ ENIAMsemStringOf.linear_term 0 t);*) false
let rec validate_semantics_rel_name = function
Val _ -> true
| t -> (*print_endline ("validate_semantics_rel_name: " ^ ENIAMsemStringOf.linear_term 0 t);*) false
let rec validate_semantics = function
Context c -> validate_semantics_sense c.cx_sense && validate_semantics_contents c.cx_contents && validate_semantics_relations c.cx_relations
| Variant(e,l) -> Xlist.fold l true (fun b (_,t) -> b && validate_semantics t)
| t -> (*print_endline ("validate_semantics: " ^ ENIAMsemStringOf.linear_term 0 t);*) false
and validate_semantics_relations = function
SingleRelation r -> validate_semantics_rel_name r
| Relation(r,a,t) -> validate_semantics_rel_name r && validate_semantics_rel_name a && validate_semantics_concept t
| RevRelation(r,a,t) -> validate_semantics_rel_name r && validate_semantics_rel_name a && validate_semantics_concept t
| Variant(e,l) -> Xlist.fold l true (fun b (_,t) -> b && validate_semantics_relations t)
| Tuple l -> Xlist.fold l true (fun b t -> b && validate_semantics_relations t)
| Dot -> true
| t -> (*print_endline ("validate_semantics_relations: " ^ ENIAMsemStringOf.linear_term 0 t);*) false
and validate_semantics_concept = function
Concept c -> validate_semantics_sense c.c_sense && validate_semantics_sense c.c_name && validate_semantics_quant c.c_quant && validate_semantics_relations c.c_relations
| Context c -> validate_semantics_sense c.cx_sense && validate_semantics_contents c.cx_contents && validate_semantics_relations c.cx_relations
| Variant(e,l) -> Xlist.fold l true (fun b (_,t) -> b && validate_semantics_concept t)
| t -> (*print_endline ("validate_semantics_concept: " ^ ENIAMsemStringOf.linear_term 0 t);*) false
and validate_semantics_contents = function
Concept c -> validate_semantics_concept (Concept c)
| Context c -> validate_semantics_concept (Context c)
| Variant(e,l) -> Xlist.fold l true (fun b (_,t) -> b && validate_semantics_contents t)
| Tuple l -> Xlist.fold l true (fun b t -> b && validate_semantics_contents t)
| t -> (*print_endline ("validate_semantics_contents: " ^ ENIAMsemStringOf.linear_term 0 t);*) false
(***************************************************************************************)
let rec find_multiple_variants v m = function
Concept c ->
let v,m = find_multiple_variants v m c.c_quant in
let v,m = find_multiple_variants v m c.c_relations in
v,m
| Context c ->
let v,m = find_multiple_variants v m c.cx_contents in
let v,m = find_multiple_variants v m c.cx_relations in
v,m
| Relation(r,a,t) -> find_multiple_variants v m t
| RevRelation(r,a,t) -> find_multiple_variants v m t
| SingleRelation r -> v,m
| Tuple l ->
Xlist.fold l (v,m) (fun (v,m) t ->
find_multiple_variants v m t)
| Variant(e,l) ->
let m = if StringSet.mem v e then StringMap.add m e (Xlist.map l fst) else m in
let v = StringSet.add v e in
let vl,m = Xlist.fold l ([],m) (fun (vl,m) (i,t) ->
let v2,m = find_multiple_variants v m t in
v2 :: vl,m) in
Xlist.fold vl v StringSet.union, m
| Dot -> v,m
| Val s -> v,m
| t -> failwith ("find_multiple_variants: " ^ ENIAMsemStringOf.linear_term 0 t)
type variant_structure =
C of variant_structure * variant_structure
| E
| T of variant_structure list
| V of string * int * (string * int * variant_structure) list
let rec string_of_variant_structure = function
C(s,t) -> sprintf "C(%s,%s)" (string_of_variant_structure s) (string_of_variant_structure t)
| E -> "E"
| T l -> sprintf "T[%s]" (String.concat ";" (Xlist.map l string_of_variant_structure))
| V(e,n,l) ->
sprintf "V(%s,%d,[%s])" e n (String.concat ";" (Xlist.map l (fun (i,n,t) ->
sprintf "%s,%d,%s" i n (string_of_variant_structure t))))
let rec create_variant_structure = function
Concept c -> (*create_variant_structure c.c_relations*)
let n,s = create_variant_structure c.c_quant in
let m,t = create_variant_structure c.c_relations in
m*n,C(s,t)
| Context c ->
let n,s = create_variant_structure c.cx_contents in
let m,t = create_variant_structure c.cx_relations in
m*n,C(s,t)
| Relation(r,a,t) -> create_variant_structure t
| RevRelation(r,a,t) -> create_variant_structure t
| SingleRelation r -> 1,E
| Tuple l ->
let n,l = Xlist.fold l (1,[]) (fun (n,l) t ->
let m,v = create_variant_structure t in
n*m,v :: l) in
n,T(List.rev l)
| Variant(e,l) ->
let n,l = Xlist.fold l (0,[]) (fun (n,l) (i,t) ->
let m,v = create_variant_structure t in
n+m,(i,m,v) :: l) in
n,V(e,n,List.rev l)
| Dot -> 1,E
| Val s -> 1,E
| t -> failwith ("create_variant_structure: " ^ ENIAMsemStringOf.linear_term 0 t)
let rec get_all_variants = function
Concept c ->
(* let l = get_all_variants c.c_relations in
Xlist.map l (fun t -> Concept{c with c_relations=t})*)
let lq = get_all_variants c.c_quant in
let lr = get_all_variants c.c_relations in
List.flatten (Xlist.map lq (fun q ->
Xlist.map lr (fun r ->
Concept{c with c_relations=r; c_quant=q})))
| Context cx ->
let lc = get_all_variants cx.cx_contents in
let lr = get_all_variants cx.cx_relations in
List.flatten (Xlist.map lc (fun c ->
Xlist.map lr (fun r ->
Context{cx with cx_contents=c; cx_relations=r})))
| Relation(r,a,t) ->
let l = get_all_variants t in
Xlist.map l (fun t -> Relation(r,a,t))
| RevRelation(r,a,t) ->
let l = get_all_variants t in
Xlist.map l (fun t -> RevRelation(r,a,t))
| SingleRelation r -> [SingleRelation r]
| Tuple l ->
let ll = Xlist.multiply_list (Xlist.map l get_all_variants) in
Xlist.map ll (fun l -> Tuple l)
| Variant(e,l) ->
List.rev (Xlist.fold l [] (fun l (_,t) -> get_all_variants t @ l))
| Dot -> [Dot]
| Val s -> [Val s]
| t -> failwith ("get_all_variants: " ^ ENIAMsemStringOf.linear_term 0 t)
let _ = Random.self_init ()
let rec draw_variant2 k = function
(i2,m,v) :: lv, (i,t) :: l ->
if i2 <> i then failwith "draw_variant2" else
if k < m then v,t else
draw_variant2 (k - m) (lv,l)
| _ -> failwith "draw_variant2"
let rec draw_variant = function
(* s,Concept c -> Concept{c with c_relations=draw_variant (s,c.c_relations)} *)
C(s,t),Concept c -> Concept{c with c_quant=draw_variant (s,c.c_quant); c_relations=draw_variant (t,c.c_relations)}
| C(s,t),Context c -> Context{c with cx_contents=draw_variant (s,c.cx_contents); cx_relations=draw_variant (t,c.cx_relations)}
| s,Relation(r,a,t) -> Relation(r,a,draw_variant (s,t))
| s,RevRelation(r,a,t) -> RevRelation(r,a,draw_variant (s,t))
| E,SingleRelation r -> SingleRelation r
| T lv,Tuple l -> Tuple(List.rev (Xlist.fold2 lv l [] (fun l s t -> (draw_variant (s,t)) :: l)))
| V(e2,n,lv),Variant(e,l) ->
if e <> e2 then failwith "draw_variant" else
let k = Random.int n in
let s,t = draw_variant2 k (lv,l) in
draw_variant (s,t)
| E,Dot -> Dot
| E,Val s -> Val s
| s,t -> (*print_endline ("draw_variant: " ^ ENIAMsemStringOf.linear_term 0 t);*) failwith ("draw_variant: " ^ string_of_variant_structure s)
let rec get_some_variants chosen = function
Concept c -> (* FIXME: czy pozostałe atrybuty można pominąć? *)
let q = get_some_variants chosen c.c_quant in
let r = get_some_variants chosen c.c_relations in
Concept{c with c_relations=r; c_quant=q}
| Context cx ->
let c = get_some_variants chosen cx.cx_contents in
let r = get_some_variants chosen cx.cx_relations in
Context{cx with cx_contents=c; cx_relations=r}
| Relation(r,a,t) -> Relation(r,a,get_some_variants chosen t)
| RevRelation(r,a,t) -> RevRelation(r,a,get_some_variants chosen t)
| SingleRelation r -> SingleRelation r
| Tuple l -> Tuple(Xlist.map l (get_some_variants chosen))
| Variant(e,l) ->
if StringMap.mem chosen e then
let t = try Xlist.assoc l (StringMap.find chosen e) with Not_found -> failwith "get_some_variants" in
get_some_variants chosen t
else Variant(e,Xlist.map l (fun (i,t) -> i,get_some_variants chosen t))
| Dot -> Dot
| Val s -> Val s
| t -> failwith ("get_some_variants: " ^ ENIAMsemStringOf.linear_term 0 t)
let get_all_multiple_variants t mv =
let ll = StringMap.fold mv [] (fun ll e l ->
(Xlist.map l (fun i -> e,i)) :: ll) in
if ll = [] then [t] else
Xlist.fold (Xlist.multiply_list ll) [] (fun variants l ->
let chosen = Xlist.fold l StringMap.empty (fun chosen (e,i) -> StringMap.add chosen e i) in
get_some_variants chosen t :: variants)
(*let rec merge_multiple_variant l = function
[] -> l
| x :: rev -> merge_multiple_variant (x :: l) rev
let rec select_multiple_variant rev k = function
[] -> failwith "select_multiple_variant"
| x :: l -> if k=0 then x, merge_multiple_variant rev l else select_multiple_variant (x :: rev) (k-1) l*)
let rec select_multiple_variant k = function
[] -> failwith "select_multiple_variant"
| x :: l -> if k=0 then x else select_multiple_variant (k-1) l
let draw_multiple_variant k t mv =
let ll = StringMap.fold mv [] (fun ll e l ->
(Xlist.map l (fun i -> e,i)) :: ll) in
let mv = Int.fold 1 k [] (fun mv _ ->
let variants = Xlist.fold ll [] (fun variants l ->
let k = Random.int (Xlist.size l) in
select_multiple_variant k l :: variants) in
variants :: mv) in
Xlist.fold mv [] (fun variants l ->
let chosen = Xlist.fold l StringMap.empty (fun chosen (e,i) -> StringMap.add chosen e i) in
get_some_variants chosen t :: variants)
let rec draw_multiple_variant2_rec k = function
[] -> failwith "draw_multiple_variant2_rec"
| (n,s,t) :: l -> if k < n then s,t else draw_multiple_variant2_rec (k-n) l
let draw_multiple_variant2 sum_n mv =
let k = Random.int sum_n in
draw_multiple_variant2_rec k mv
let draw_trees max_n t =
let _,multiple_variants = find_multiple_variants StringSet.empty StringMap.empty t in
let mo = StringMap.fold multiple_variants 1 (fun mo _ l -> mo * Xlist.size l) in
(* printf "|multiple_variants|=%d |mo|=%d\n%!" (StringMap.size multiple_variants) mo; *)
let multiple_variants =
if mo <= 100 then get_all_multiple_variants t multiple_variants else
draw_multiple_variant 100 t multiple_variants in
(* printf "|multiple_variants|=%d |mo|=%d\n%!" (Xlist.size multiple_variants) mo; *)
let multiple_variants = Xlist.map multiple_variants (fun t ->
let n,s = create_variant_structure t in
n,s,t) in
let sum_n = Xlist.fold multiple_variants 0 (fun sum_n (n,_,_) -> sum_n + n) in
(* print_endline (ENIAMsemStringOf.linear_term 0 t);
print_endline (string_of_variant_structure s);*)
if sum_n <= max_n then
List.flatten (Xlist.rev_map multiple_variants (fun (n,s,t) ->
get_all_variants t)) else
Int.fold 1 max_n [] (fun l _ ->
let s,t = draw_multiple_variant2 sum_n multiple_variants in
(draw_variant (s,t)) :: l)
(* FIXME!: założenie o jednokrotnym występowaniu wagi nie jest prawdziwe np. dla zdania: "Łódź wyprzedza statek." *)
*)