rules.ml
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open Xstd
open Types
open Printf
type tags =
T of string * string
| A of string
let parse_name s =
if s = "" then failwith "parse_name: empty name" else
if String.get s 0 = '@' then String.sub s 1 (String.length s - 1)
else failwith ("parse_name: invalid name " ^ s)
let parse_tags s =
Xlist.map (Xstring.split " " s) (fun t ->
match Xstring.split "=" t with
[k] -> A k
| [k;v] -> T(k,v)
| _ -> failwith "parse_tags")
let parse_star = function
"" -> Productive
| "*" -> Star
| "ndm" -> Ndm
| "D" -> Dial
| "C" -> Acro
| "B" -> Aux2
| "A" -> Aux
| s -> failwith ("parse_star: " ^ s)
exception MergeStars of star * star
let merge_stars = function
Productive,Productive -> Productive
| Star,Star -> Star
| Dial,Dial -> Dial
| Acro,Acro -> Acro
| Aux,Aux -> Aux
| Aux2,Aux2 -> Aux2
| Star,Productive -> Star
| Productive,Star -> Star
| Dial,Productive -> Dial
| Productive,Dial -> Dial
| Acro,Productive -> Acro
| Productive,Acro -> Acro
| Aux,Productive -> Aux
| Productive,Aux -> Aux
| Aux2,Productive -> Aux2
| Productive,Aux2 -> Aux2
| Aux2,Aux -> Aux2
| Aux,Aux2 -> Aux2
| a,b -> raise (MergeStars(a,b))
let string_of_star = function
Productive -> ""
| Star -> "*"
| Ndm -> "ndm"
| Dial -> "D"
| Acro -> "C"
| Aux2 -> "B"
| Aux -> "A"
let print_rule file rule =
Printf.fprintf file "%s\t%d\t%s\t%s\t%s\t%s\t%s\n" rule.id rule.freq (string_of_star rule.star)
rule.pref rule.find rule.set rule.interp
(**********************************************************************************************)
type alternation = {astar: star; aphone: string; aphone2: string; afind: string; aset: string}
let load_alternations filename =
let alternations,name,alts = File.fold_tab filename ([],"",[]) (fun (found,name,alts) -> function
[alt_name] ->
let alt_name = parse_name alt_name in
if name = "" then found,alt_name,[] else (name,List.rev alts) :: found,alt_name,[]
| [star;d;a;b;c] -> found,name,{astar=parse_star star; aphone=a; aphone2=d; afind=b; aset=c} :: alts
| line -> failwith ("load_alternations:" ^ String.concat "\t" line)) in
(name,List.rev alts) :: alternations
let alternations () = load_alternations "../morphology/data/alternations.dic"
let revert_alternations l =
Xlist.map l (fun a -> {a with afind=a.aset; aset=a.afind})
let alternation_map alternations = Xlist.fold alternations StringMap.empty (fun map (k,v) ->
StringMap.add map k v)
let rev_alternation_map alternations = Xlist.fold alternations StringMap.empty (fun map (k,v) ->
StringMap.add map k (revert_alternations v))
type suf_rule = {sstar: star; salt_name: string; ssufix: string; stags: tags list}
type pref_rule = {pstar: star; pprefix: string; ptags: tags list}
let load_suf_rules filename =
let suf_rules,name,rules = File.fold_tab filename ([],"",[]) (fun (found,name,rules) -> function
[rules_name] ->
let rules_name = parse_name rules_name in
if name = "" then found,rules_name,[] else (name,List.rev rules) :: found,rules_name,[]
| [star;alt_name;sufix;tags] -> found,name,{sstar=parse_star star; salt_name=alt_name; ssufix=sufix; stags=parse_tags tags} :: rules
| line -> failwith ("load_suf_rules: " ^ String.concat "\t" line)) in
(name,List.rev rules) :: suf_rules
let load_pref_rules filename =
let pref_rules,name,rules = File.fold_tab filename ([],"",[]) (fun (found,name,rules) -> function
[rules_name] ->
let rules_name = parse_name rules_name in
if name = "" then found,rules_name,[] else (name,List.rev rules) :: found,rules_name,[]
| [star;prefix;tags] -> found,name,{pstar=parse_star star; pprefix=prefix; ptags=parse_tags tags} :: rules
| _ -> failwith "load_pref_rules") in
(name,List.rev rules) :: pref_rules
let rules () = load_suf_rules "../morphology/data/rules.dic"
let rev_rules () = load_suf_rules "../morphology/data/rev_rules.dic"
let pref_rules () = load_pref_rules "../morphology/data/pref_rules.dic"
let expand_tags x y l =
List.flatten (Xlist.map l (function
T(k,v) -> [k,v]
| A k ->
(if x = "" then [] else [k,x]) @
(if y = "" then [] else [k ^ "2",y])))
let expand_tags_simple l =
Xlist.map l (function
T(k,v) -> k,v
| A k -> failwith ("expand_tags_simple: " ^ k))
let load_freq_rules filename =
File.fold_tab filename [] (fun rules -> function
[id; freq; star; pref; find; set; interp; tags] ->
{id=id; freq=int_of_string freq; star=parse_star star; pref=pref; find=find; set=set;
tags=expand_tags_simple (parse_tags tags); interp=interp} :: rules
| _ -> failwith "load_freq_rules")
let prepare_rules alternation_map suf_rules =
Xlist.fold suf_rules [] (fun rules s ->
let alternation = try StringMap.find alternation_map s.salt_name with Not_found -> failwith ("prepare_rules: " ^ s.salt_name) in
Xlist.fold alternation rules (fun rules a ->
try
{star=merge_stars (s.sstar,a.astar); pref=""; find=a.afind ^ s.ssufix; set=a.aset;
tags=expand_tags a.aphone a.aphone2 s.stags; interp=""; id=""; freq=0} :: rules
with MergeStars _ -> rules))
let prepare_rev_rules rev_alternation_map suf_rules =
Xlist.fold suf_rules [] (fun rules s ->
let alternation = try StringMap.find rev_alternation_map s.salt_name with Not_found -> failwith ("prepare_rev_rules: " ^ s.salt_name) in
Xlist.fold alternation rules (fun rules a ->
try
{star=merge_stars (s.sstar,a.astar); pref=""; find=a.afind; set=a.aset ^ s.ssufix;
tags=expand_tags a.aphone a.aphone2 s.stags; interp=""; id=""; freq=0} :: rules
with MergeStars _ -> rules))
let prepare_pref_rules pref_rules =
Xlist.fold pref_rules [] (fun rules p ->
{star=p.pstar; pref=p.pprefix; find=""; set=""; tags=expand_tags "" "" p.ptags; interp=""; id=""; freq=0} :: rules)
let rule_map alternation_map rev_alternation_map rules rev_rules pref_rules =
let map = Xlist.fold rules StringMap.empty (fun map (k,v) -> StringMap.add map k (prepare_rules alternation_map v)) in
let map = Xlist.fold rev_rules map (fun map (k,v) -> StringMap.add map k (prepare_rev_rules rev_alternation_map v)) in
Xlist.fold pref_rules map (fun map (k,v) -> StringMap.add map k (prepare_pref_rules v))
let schemata () = File.load_tab "../morphology/data/schemata.dic" (fun l -> l)
(**********************************************************************************************)
let rec extract_tag s rev = function
[] -> "", List.rev rev
| (k,v) :: l -> if s = k then v, List.rev rev @ l else extract_tag s ((k,v) :: rev) l
let get_tag l tag =
try Xlist.assoc l tag with Not_found -> ""
let create_compound_rules schemata rule_map =
let found = Xlist.fold schemata [] (fun found schema ->
let compounds = Xlist.fold schema [{star=Productive;pref="";find="";set="";tags=[];interp=""; id=""; freq=0}] (fun compounds rule_set_name ->
let rules = try StringMap.find rule_map rule_set_name with Not_found -> failwith ("create_compound_rules: " ^ rule_set_name) in
Xlist.fold compounds [] (fun compounds compound ->
Xlist.fold rules compounds (fun compounds rule ->
(* printf "compound.find=%s; compound.set=%s\n" compound.find compound.set;
printf "rule.find=%s; rule.set=%s\n" rule.find rule.set; *)
try
if rule.find = "" && rule.set = "" then
{compound with star=merge_stars (compound.star, rule.star);
pref=compound.pref ^ rule.pref; tags=rule.tags@compound.tags} :: compounds
else if Xstring.check_sufix compound.set rule.find then
{compound with star=merge_stars (compound.star, rule.star);
find=Xstring.cut_sufix compound.set rule.find ^ compound.find; set=rule.set; tags=rule.tags@compound.tags} :: compounds
else if Xstring.check_sufix rule.find compound.set then
{compound with star=merge_stars (compound.star, rule.star);
find=compound.find; set=Xstring.cut_sufix rule.find compound.set ^ rule.set; tags=rule.tags@compound.tags} :: compounds
else compounds
with MergeStars _ -> compounds))) in
compounds @ found) in
let found = Xlist.rev_map found (fun rule ->
let suf, tags = extract_tag "suf" [] rule.tags in
{rule with set=rule.set ^ suf; tags=tags}) in
found
let make_compound_rules () =
let schemata = schemata () in
let alternations = alternations () in
let alternation_map = alternation_map alternations in
let rev_alternation_map = rev_alternation_map alternations in
let rule_map = rule_map alternation_map rev_alternation_map (rules ()) (rev_rules ()) (pref_rules ()) in
create_compound_rules schemata rule_map
(**********************************************************************************************)
let tag_value = function
"cat" -> 1
| "pref" -> 2
| "con" -> 3
| "con2" -> 4
| "grad" -> 5
| "group" -> 6
| "flex2" -> 7
| "flex" -> 8
| "lemma" -> 9
| "lcon" -> 10
| "lcon2" -> 11
| "palat" -> 12
| "velar" -> 13
| "agl" -> 14
| "agl2" -> 15
| "orth" -> 16
| s -> failwith ("tag_value: " ^ s)
let tag_value2 = function
"cat" -> 1
| "flex" -> 2
| "flex2" -> 3
| "grad" -> 4
| "pref" -> 5
| "lemma" -> 6
| "con" -> 7
| "con2" -> 8
| "lcon" -> 9
| "lcon2" -> 10
| "group" -> 11
| "palat" -> 12
| "velar" -> 13
| "agl" -> 14
| "agl2" -> 15
| "orth" -> 16
| s -> failwith ("tag_value2: " ^ s)
let compare_tag (a,_) (b,_) =
compare (tag_value a) (tag_value b)
let compare_tag2 (a,_) (b,_) =
compare (tag_value2 a) (tag_value2 b)
let load_interp_rules filename =
File.load_tab filename (function
star :: tags :: interp :: comment :: [] ->
{star=parse_star star;
pref=""; find=""; set="";
tags=expand_tags_simple (parse_tags tags); interp=interp; (*comment=comment;*) id=""; freq=0}
| line -> failwith ("load_tab: " ^ (String.concat "\t" line)))
module InterpTree = struct
type t =
N of string * t StringMap.t * rule list
| L of rule list
let empty = L []
let rec create_rec rule = function
[],N(key,map,rules) -> N(key,map,rule :: rules)
| [],L rules -> L(rule :: rules)
| (k,v) :: tags,N(key,map,rules) ->
if k <> key then failwith ("create_rec: " ^ k ^ " " ^ key) else
let tree = try StringMap.find map v with Not_found -> empty in
let tree = create_rec rule (tags,tree) in
N(key,StringMap.add map v tree,rules)
| (k,v) :: tags,L rules ->
let tree = create_rec rule (tags,empty) in
N(k,StringMap.add StringMap.empty v tree,rules)
let create interp_rules =
Xlist.fold interp_rules empty (fun interp_tree rule ->
let tags = Xlist.sort rule.tags compare_tag2 in
create_rec rule (tags,interp_tree))
let rec find_rec = function
[],N(_,_,rules) -> rules
| _,L rules -> rules
| (k,v) :: tags,N(key,map,rules) ->
if k <> key then find_rec (tags,N(key,map,rules)) else
try rules @ (find_rec (tags,StringMap.find map v))
with Not_found -> rules
let find interp_tree tags =
find_rec (Xlist.sort tags compare_tag2,interp_tree)
end
let interp_tree () = InterpTree.create (load_interp_rules "../morphology/data/interp_rules.dic")
(**********************************************************************************************)
let create_interp_compound_rules interp_tree compound_rules =
Xlist.fold compound_rules [] (fun interp_compound_rules rule ->
let interp_rules = InterpTree.find interp_tree rule.tags in
Xlist.fold interp_rules interp_compound_rules (fun interp_compound_rules interp_rule ->
try {rule with interp=interp_rule.interp; star=merge_stars (rule.star, interp_rule.star)} :: interp_compound_rules
with MergeStars _ -> interp_compound_rules))
let assign_ids rules =
fst (Xlist.fold rules ([],1) (fun (rules,id) rule ->
{rule with id=string_of_int id} :: rules, id+1))
let interp_compound_rules compound_rules = assign_ids (create_interp_compound_rules (interp_tree ()) compound_rules)
(**********************************************************************************************)
module CharTrees = struct
type t = M of t CharMap.t * rule list
let empty = M(CharMap.empty,[])
let rec add_path_rules rule orth_suf i (M(map,rules)) =
if i = -1 then M(map,rule :: rules) else
let tree = try CharMap.find map (String.get orth_suf i) with Not_found -> empty in
let tree = add_path_rules rule orth_suf (i-1) tree in
M(CharMap.add map (String.get orth_suf i) tree,rules)
let create_char_tree rules =
let tree = Xlist.fold rules empty (fun tree rule ->
add_path_rules rule rule.find (String.length rule.find - 1) tree) in
tree
let create rules =
let prefix_map = Xlist.fold rules StringMap.empty (fun prefix_map rule ->
StringMap.add_inc prefix_map rule.pref [rule] (fun l -> rule :: l)) in
StringMap.fold prefix_map [] (fun trees prefix rules -> (prefix, create_char_tree rules) :: trees)
let rec find_rec l i orth (M(map,rules)) =
if i = 0 then Xlist.fold rules l (fun l rule -> ("", rule) :: l) else
let l = try find_rec l (i-1) orth (CharMap.find map (String.get orth (i-1))) with Not_found -> l in
Xlist.fold rules l (fun l rule -> (String.sub orth 0 i, rule) :: l)
let find trees orth =
Xlist.fold trees [] (fun found (pref,tree) ->
(* print_endline pref; *)
if Xstring.check_prefix pref orth then (
let orth = Xstring.cut_prefix pref orth in
(* printf "%s %d " orth (Xlist.size found); *)
let found = find_rec found (String.length orth) orth tree in
(* printf "%d\n%!" (Xlist.size found); *)
(* Xlist.iter found (fun (stem,rule) -> printf "F %s\t%s\n" stem (string_of_rule rule)); *)
found)
else found)
let add_char c rule =
let s = String.make 1 c in
{rule with find=s ^ rule.find; set=s ^ rule.set}
let rec disjoint_rec super (M(map,rules)) =
let rules = rules @ super in
if CharMap.is_empty map then M(map,rules) else
M(CharMap.mapi map (fun c tree ->
disjoint_rec (Xlist.rev_map rules (add_char c)) tree),[])
let disjoint trees =
Xlist.rev_map trees (fun (pref,tree) ->
pref, disjoint_rec [] tree)
let rec print_rules_rec file (M(map,rules)) =
Xlist.iter rules (print_rule file);
CharMap.iter map (fun _ tree -> print_rules_rec file tree)
let print_rules filename trees =
File.file_out filename (fun file ->
Xlist.iter trees (fun (_,tree) ->
print_rules_rec file tree))
end
let compound_rule_trees compound_rules = CharTrees.create compound_rules
let interp_compound_rule_trees interp_compound_rules = CharTrees.create interp_compound_rules
let make_compound_rule_trees = compound_rule_trees
let make_interp_compound_rule_trees compound_rules =
interp_compound_rule_trees (interp_compound_rules compound_rules)
(**********************************************************************************************)
module OrderedRule = struct
type t = rule
let compare = compare
end
module RuleQMap = Xmap.MakeQ(OrderedRule)
let string_of_freq_rule rule =
sprintf "%s\t%d\t%s\t%s\t%s\t%s\t%s\t%s" rule.id rule.freq (string_of_star rule.star) rule.pref rule.find rule.set rule.interp (string_of_tags rule.tags)
(**********************************************************************************************)
let latex_escape_char = function
"′" -> "$'$"
| "ʲ" -> "\\textipa{\\super{j}}"
| "ʒ" -> "\\textipa{Z}"
| "ǯ" -> "\\textipa{\\v{Z}}"
| "ε" -> "$\\varepsilon$"
| c -> c
let latex_escape_string s =
String.concat "" (Xlist.map (Xunicode.utf8_chars_of_utf8_string s) latex_escape_char)
let latex_of_alternation a =
(if a.astar = Star then "$\\star$" else "") ^
latex_escape_string a.afind ^ " $\\rightarrow$ " ^ latex_escape_string a.aset
let make_alternation_line phons alternation =
let l,map = Xlist.fold phons ([],StringMap.empty) (fun (l,map) phon ->
if not (StringMap.mem alternation phon) then "" :: l,map else
let alts = StringMap.find alternation phon in
latex_of_alternation (List.hd alts) :: l,
if List.tl alts = [] then map else (StringMap.add map phon (List.tl alts))) in
String.concat " & " (List.rev l), map
let rec print_alternation name phons map =
if StringMap.is_empty map then print_endline "\\hline\\\\" else (
let s,map = make_alternation_line phons map in
print_endline (latex_escape_string name ^ " & " ^ s ^ "\\\\");
print_alternation "" phons map)
let make_alternation_line2 alts =
let l,alts = Xlist.fold alts ([],[]) (fun (l,alts) -> function
[] -> "" :: l,[] :: alts
| alt :: a -> latex_of_alternation alt :: l, a :: alts) in
String.concat " & " (List.rev l), List.rev alts
let rec print_alternation2 name alts =
if Xlist.fold alts true (fun b -> function [] -> b | _ -> false) then print_endline "\\hline" else (
let s,alts = make_alternation_line2 alts in
print_endline (latex_escape_string name ^ " & " ^ s ^ "\\\\");
print_alternation2 "" alts)
let alt_names = [
"funkcjonalnie_miekkie_iy","\\boldmath$\\alpha'${\\bf y}";
"funkcjonalnie_miekkie_ae","\\boldmath$\\alpha'$";
"funkcjonalnie_miekkie_wyglos","\\boldmath$\\alpha'\\varepsilon$";
"funkcjonalnie_twarde_y","\\boldmath$\\alpha${\\bf y}";
"funkcjonalnie_twarde_e","\\boldmath$\\alpha${\\bf e}";
"funkcjonalnie_twarde_a","\\boldmath$\\alpha$";
"funkcjonalnie_twarde_i","\\boldmath$\\alpha${\\bf i}";
"funkcjonalnie_twarde_ie","\\boldmath$\\alpha${\\bf ie}";
"funkcjonalnie_twarde_wyglos","\\boldmath$\\alpha\\varepsilon$";
"funkcjonalnie_twarde_u1","\\boldmath$\\alpha_1$";
"funkcjonalnie_twarde_u2","\\boldmath$\\alpha_2$";
"dowolne","";
"funkcjonalnie_twarde_ie1","\\boldmath$\\alpha${\\bf ie}$_1$";
"funkcjonalnie_twarde_ie2","\\boldmath$\\alpha${\\bf ie}$_2$";
"adj_grad_miekkie_sz","\\boldmath$\\kappa'$";
"adj_grad_miekkie_iejsz","\\boldmath$\\lambda'$";
"adj_grad_twarde_sz","\\boldmath$\\kappa$";
"adj_grad_twarde_iejsz","\\boldmath$\\lambda$";
"adv_grad_miekkie","\\boldmath$\\xi'$";
"adv_grad_twarde","\\boldmath$\\xi$";
"sz","{\\bf š}";
"sz_i","{\\bf ši}";
"c_cz","{\\bf č}";
"aiy","\\boldmath$\\iota$";
(* "ger_t","{\\bf t\\boldmath$'$}";
"ger_n","{\\bf n\\boldmath$'$}";
"pact","{\\bf c}";
"ppas_t","{\\bf t}";
"ppas_n","{\\bf n}";
"ppas_ti","{\\bf t\\boldmath$'$i}";
"ppas_ni","{\\bf n\\boldmath$'$i}";
"praet","{\\bf ł}";*)
"praet_i","\\boldmath$\\beta${\\bf li}";
"ae","{\\bf a}";
"verb_n","\\boldmath$\\eta$";
"verb_impt","\\boldmath$\\gamma\\varepsilon$";
"verb_fin","\\boldmath$\\gamma$";
"verb_łszy","\\boldmath$\\beta${\\bf ł}";
"verb_inf_ć","\\boldmath$\\beta${\\bf t}$'$";
"ppas_e","\\boldmath$\\nu$";
"verb_owa","";
"verb_ywa","y";
"verb_awa","";
"verb_a","";
"verb_u","";
"verb_y","";
"verb_palat","";
"verb_palat_e","";
"prefix_e","{\\bf }";
"verb_ą2","{\\bf }";
"verb_ą1","{\\bf }";
"verb_ą3","{\\bf }";
"funkcjonalnie_miekkie_ae2","\\boldmath$\\alpha'$";
"funkcjonalnie_miekkie_iy2","\\boldmath$\\beta'${\\bf y}";
"palat_j","\\boldmath$\\zeta$";
"kapitaliki_y","{\\bf }";
"kapitaliki_e","{\\bf }";
"kapitaliki_a","{\\bf }";
"kapitaliki_ie","{\\bf }";
"kapitaliki_wyglos","{\\bf }";
"obce_ais","{\\bf }";
"obce_apostrof","{\\bf }";
"obce_funkcjonalnie_miekkie_ae","{\\bf }";
"obce_funkcjonalnie_twarde_iy","{\\bf }";
"obce_funkcjonalnie_twarde_ie","{\\bf }";
"obce_funkcjonalnie_twarde_e","{\\bf }";
"obce_funkcjonalnie_twarde_a","{\\bf }";
"obce_funkcjonalnie_twarde_i","{\\bf }";
"obce_funkcjonalnie_twarde_wyglos","{\\bf }";
"obce_funkcjonalnie_miekkie_iy","{\\bf }";
"obce_funkcjonalnie_miekkie_wyglos","{\\bf }";
"obce_eu","{\\bf }";
"obce_ech","{\\bf }";
]
let rec print_alternations names phons alternations =
print_endline ("\\begin{center}\n\\begin{tabular}{r" ^ String.concat "" (Xlist.map phons (fun _ -> "r")) ^ "}");
print_endline (" & " ^ String.concat " & " (Xlist.map phons latex_escape_string) ^ "\\\\");
print_endline "\\hline\\\\";
Xlist.iter names (fun name ->
let name2 = Xlist.assoc alt_names name in
let alternation = StringMap.find alternations name in
let alternation = Xlist.fold alternation StringMap.empty (fun alternation a ->
StringMap.add_inc alternation a.aphone [a] (fun l -> a :: l)) in
let alternation = StringMap.map alternation List.rev in
print_alternation name2 phons alternation);
print_endline "\\end{tabular}\n\\end{center}\n"
let rec print_alternations2 names phons alternations =
print_endline ("\\begin{longtable}{r|" ^ String.concat "" (Xlist.map names (fun _ -> "r")) ^ "}");
print_endline (" & " ^ String.concat " & " (Xlist.map names (fun name ->
try Xlist.assoc alt_names name with Not_found -> failwith ("print_alternations2: " ^ name))) ^ "\\\\");
print_endline "\\hline";
(* print_endline "\\endhead\n\\hline\\\\"; *)
let alternations = Xlist.map names (fun name ->
try StringMap.find alternations name with Not_found -> failwith ("print_alternations2: " ^ name)) in
let alternations = Xlist.map alternations (fun alternation ->
Xlist.fold alternation StringMap.empty (fun alternation a ->
StringMap.add_inc alternation a.aphone [a] (fun l -> a :: l))) in
Xlist.iter phons (fun phon ->
print_alternation2 phon (Xlist.map alternations (fun a -> try List.rev (StringMap.find a phon) with Not_found -> [])));
print_endline "\\end{longtable}\n"
let palat_alts = [
"funkcjonalnie_miekkie_iy";
"funkcjonalnie_miekkie_ae";
"funkcjonalnie_miekkie_wyglos";]
let npalat_alts = [
"funkcjonalnie_twarde_y";
"funkcjonalnie_twarde_e";
"funkcjonalnie_twarde_a";
"funkcjonalnie_twarde_i";
"funkcjonalnie_twarde_ie";
"funkcjonalnie_twarde_wyglos";]
let palat_grad = [
"adj_grad_miekkie_sz";
"adj_grad_miekkie_iejsz";
"adv_grad_miekkie";
]
let npalat_grad = [
"adj_grad_twarde_sz";
"adj_grad_twarde_iejsz";
"adv_grad_twarde";
]
let other = [
"sz";
"sz_i";
"c_cz";
"aiy";
"ppas_e";
"ae"
]
let verb_flex = [
"verb_łszy";
"praet_i";
"verb_inf_ć";
"verb_impt";
"verb_fin";
"verb_n";
"palat_j";
]
let palat_phons = ["b′";"d′";"f′";"m′";"n′";"p′";"s′";"t′";"v′";"z′";"l";"c";"č";"ʒ";"ǯ";"ř";"š";"ž";"ʲ";"j";"g′";"k′";"a";"e"]
let palat_phons1 = ["b′";"d′";"f′";"m′";"n′"]
let palat_phons2 = ["p′";"s′";"t′";"v′";"z′";"l"]
let palat_phons3 = ["c";"č";"ʒ";"ǯ";"ř";"š";"ž"]
let palat_phons4 = ["ʲ";"j";"g′";"k′";"a";"e"]
let npalat_phons = ["b";"x";"d";"f";"h";"ł";"m";"n";"p";"r";"s";"t";"v";"z";"g";"k";"o";"u"]
let npalat_phons1 = ["b";"x";"d";"f";"h";"ł"]
let npalat_phons2 = ["m";"n";"p";"r";"s"]
let npalat_phons3 = ["t";"v";"z";"g";"k";"o";"u"]
let palat_grad_phons = ["m′";"n′";"p′";"c";"č";"ž"]
let npalat_grad_phons = ["b";"x";"d";"h";"ł";"m";"n";"p";"r";"t";"v";"g";"k"]
let other_phons = ["c";"š";"a";"e";"i";"o";"y"]
let all_phons = ["b′";"d′";"f′";"m′";"n′";"p′";"s′";"t′";"v′";"z′";"l";"c";"č";"ʒ";"ǯ";"ř";"š";"ž";"ʲ";"j";"g′";"k′";"a";"e";
"b";"x";"d";"f";"h";"ł";"m";"n";"p";"r";"s";"t";"v";"z";"g";"k";"o";"u";"i";"y";"ą";"ę"]
let verb_flex_phons = ["";"l";"c";"č";"ř";"ž";"j";"a";
"b";"x";"d";"f";"h";"ł";"m";"n";"p";"r";"s";"t";"v";"z";"g";"k"]
let merge_ie alternations =
let ie1 = StringMap.find alternations "funkcjonalnie_twarde_ie1" in
let ie2 = StringMap.find alternations "funkcjonalnie_twarde_ie2" in
let ie = ie1 @ ie2 in
StringMap.add alternations "funkcjonalnie_twarde_ie" ie
let latex_of_alternations filename =
let alternations = alternation_map (load_alternations filename) in
let alternations = merge_ie alternations in
(* print_alternations palat_alts palat_phons1 alternations;
print_alternations palat_alts palat_phons2 alternations;
print_alternations palat_alts palat_phons3 alternations;
print_alternations palat_alts palat_phons4 alternations;
print_alternations npalat_alts npalat_phons1 alternations;
print_alternations npalat_alts npalat_phons2 alternations;
print_alternations npalat_alts npalat_phons3 alternations; *)
print_alternations2 palat_alts palat_phons alternations;
print_alternations2 npalat_alts npalat_phons alternations;
print_alternations2 palat_grad palat_grad_phons alternations;
print_alternations2 npalat_grad npalat_grad_phons alternations;
print_alternations2 other other_phons alternations;
print_alternations2 verb_flex verb_flex_phons alternations;
()
let latex_math_text s =
if s = "" then "\\varepsilon" else
"\\text{" ^ latex_escape_string s ^ "}"
let latex_prepare_tags tags =
String.concat ", " (List.rev (Xlist.fold tags [] (fun l -> function
T("cat",v) -> (latex_math_text v) :: l
| T("palat","t") -> "\\uparrow" :: l
| T("palat","n") -> "\\downarrow" :: l
| T("palat","ę") -> l
| T("palat","anin") -> l
| T("palat","mię") -> l
| T("palat","o") -> l
| T("palat","stwo") -> l
| T("palat","ni") -> l
| T("velar","t") -> "\\rightarrow" :: l
| T("velar","n") -> "\\leftarrow" :: l
| T(k,v) -> (latex_math_text k ^ ":=" ^ latex_math_text v) :: l
| A _ -> l)))
let latex_prepare_tags2 tags =
String.concat ", " (List.rev (Xlist.fold tags [] (fun l -> function
("cat",v) -> (latex_escape_string v) :: l
| ("palat","t") -> "$\\uparrow$" :: l
| ("palat","n") -> "$\\downarrow$" :: l
| ("palat","ę") -> l
| ("palat","anin") -> l
| ("palat","mię") -> l
| ("palat","o") -> l
| ("palat","stwo") -> l
| ("palat","ni") -> l
| ("velar","t") -> "$\\rightarrow$" :: l
| ("velar","n") -> "$\\leftarrow$" :: l
| (k,v) -> (k ^ ":=" ^ latex_escape_string v) :: l)))
let latex_prepare_rule r =
(if r.sstar = Star then "\\star" else if r.sstar = Dial then "D" else "") ^
"-" ^ latex_math_text ((try Xlist.assoc alt_names r.salt_name with Not_found -> print_endline r.salt_name; "???") ^ r.ssufix) ^
" & " ^ (latex_prepare_tags r.stags)
let latex_prepare_rev_rule r =
(if r.sstar = Star then "\\star" else if r.sstar = Dial then "D" else "") ^
"+" ^ latex_math_text ((try Xlist.assoc alt_names r.salt_name with Not_found -> print_endline r.salt_name; "???") ^ r.ssufix) ^
" & " ^ (latex_prepare_tags r.stags)
let latex_prepare_pref_rule r =
(if r.pstar = Star then "\\star" else if r.pstar = Dial then "D" else "") ^
latex_math_text r.pprefix ^ "- & " ^ (latex_prepare_tags r.ptags)
let latex_prepare_rules prepare_fun rule_map (name,rules) =
let rules = Xlist.map rules prepare_fun in
let rules = "\\left[\\begin{array}{ll}\n" ^ String.concat "\\\\\n" rules ^ "\n\\end{array}\\right]" in
StringMap.add rule_map name rules
let latex_of_schemata () =
let rule_map = Xlist.fold (rules ()) StringMap.empty (latex_prepare_rules latex_prepare_rule) in
let rule_map = Xlist.fold (rev_rules ()) rule_map (latex_prepare_rules latex_prepare_rev_rule) in
let rule_map = Xlist.fold (pref_rules ()) rule_map (latex_prepare_rules latex_prepare_pref_rule) in
Xlist.iter (schemata ()) (fun schema ->
print_endline "\\begin{scriptsize}\\[";
let schema = Xlist.map schema (fun rule_set_name ->
try StringMap.find rule_map rule_set_name with Not_found -> failwith ("create_compound_rules: " ^ rule_set_name)) in
print_endline (String.concat " \\otimes " schema);
print_endline "\\]\\end{scriptsize}\n")
let make_rule_key r =
let cat = get_tag r.tags "cat" in
let lemma = get_tag r.tags "lemma" in
let group = get_tag r.tags "group" in
let gender =
match Xstring.split ":" (List.hd (Xstring.split "|" r.interp)) with
"subst" :: n :: c :: g -> (String.concat ":" g)
| "depr" :: _ -> "m1"
| _ -> "" in
if cat = "adj" || cat = "adv" || cat = "adj:grad" || cat = "ndm" then cat, cat else
if cat = "verb" then
if lemma = "" then cat, "verb:general" else
cat ^ " " ^ lemma, cat else
cat ^ " " ^ lemma ^ " " ^ group ^ " " ^ gender, cat
let case_number c =
match List.hd (Xstring.split "\\." c) with
"nom" -> 1
| "gen" -> 2
| "dat" -> 3
| "acc" -> 4
| "inst" -> 5
| "loc" -> 6
| "voc" -> 7
| _ -> failwith "case_number"
let key_of_noun_nc s =
match Xstring.split ":" s with
["sg";c] -> case_number c
| ["pl";c] -> 7 + case_number c
| ["depr"] -> 15
| _ -> failwith "key_of_noun_nc"
let rec get_gender = function
s :: l ->
let ll = Xstring.split "|" s in
(match Xstring.split ":" (List.hd ll) with
"subst" :: _ :: _ :: g -> String.concat ":" g
| _ -> get_gender (List.tl ll @ l))
| [] -> failwith "get_gender"
let latex_of_noun_interp_rules l =
let cat = get_tag (List.hd l).tags "cat" in
let lemma = get_tag (List.hd l).tags "lemma" in
let gender = get_gender (Xlist.map l (fun r -> r.interp)) in
let l = Xlist.map l (fun r -> {r with tags = snd (extract_tag "cat" [] r.tags)}) in
let l = Xlist.map l (fun r -> {r with tags = snd (extract_tag "lemma" [] r.tags)}) in
print_endline ("cat=" ^ cat ^ " lemma=" ^ latex_escape_string lemma ^ " gender:=" ^ gender ^ "\\\\");
let map = Xlist.fold l StringMap.empty (fun map r ->
StringMap.add_inc map r.interp [r] (fun l -> r :: l)) in
let l = List.sort compare (StringMap.fold map [] (fun l interp rules ->
let interp = String.concat "|" (Xlist.map (Xstring.split "|" interp) (fun interp ->
match Xstring.split ":" interp with
"subst" :: n :: c :: _ -> n ^ ":" ^ c
| "depr" :: _ -> "depr"
| _ -> failwith "latex_of_noun_interp_rules: interp")) in
let key = key_of_noun_nc (List.hd (Xstring.split "|" interp)) in
(key, interp, Xlist.map rules (fun r ->
let flex,tags = extract_tag "flex" [] r.tags in
let palat,tags = extract_tag "palat" [] tags in
let velar,tags = extract_tag "velar" [] tags in
let palat_velar =
(match palat with
"t" -> "\\uparrow"
| "n" -> "\\downarrow"
| "" -> ""
| _ -> failwith "latex_of_noun_interp_rules: palat") ^
(match velar with
"t" -> "\\rightarrow"
| "n" -> "\\leftarrow"
| "" -> ""
| _ -> failwith "latex_of_noun_interp_rules: velar") in
if tags <> [] then failwith "latex_of_noun_interp_rules: tags" else
(if r.star = Star then "$\\star$" else "") ^
latex_escape_char flex ^
(if palat_velar = "" then "" else "$" ^ palat_velar ^ "$"))) :: l)) in
print_endline "\\begin{tabular}{l|l}";
Xlist.iter l (fun (_,interp,l) ->
print_endline (interp ^ " & " ^ (String.concat " " l) ^ "\\\\"));
print_endline "\\end{tabular}\\\\"
let latex_of_interp_rules_table l tags =
print_endline ("\\begin{longtable}{p{7cm}|" ^ String.concat "|" (Xlist.map tags (fun _ -> "l")) ^ "}");
print_endline ("interpretation & " ^ String.concat " & " tags ^ "\\\\\n\\hline");
Xlist.iter (List.rev l) (fun (r: rule) ->
let interp = String.concat "" (Xstring.split ":imperf\\.perf" r.interp) in
let interp = String.concat " " (Xstring.split "|" interp) in
print_endline ((if r.star = Star then "$\\star$" else "") ^ interp ^ " & " ^
String.concat " & " (Xlist.map tags (fun tag ->
latex_escape_string (get_tag r.tags tag))) ^ "\\\\"));
print_endline "\\end{longtable}"
let latex_of_interp_rules () =
let map = Xlist.fold (load_interp_rules "../morphology/data/interp_rules.dic") StringMap.empty (fun map r ->
let key, cat = make_rule_key r in
StringMap.add_inc map key (cat,[r]) (fun (_,l) -> cat, r :: l)) in
StringMap.iter map (fun _ (cat,l) ->
if cat = "noun" then latex_of_noun_interp_rules l else
if cat = "adj" then latex_of_interp_rules_table l ["cat";"flex";"lemma"] else
if cat = "adj:grad" then latex_of_interp_rules_table l ["cat";"pref";"flex";"lemma"] else
if cat = "ndm" then latex_of_interp_rules_table l ["cat"] else
if cat = "adv" then latex_of_interp_rules_table l ["cat";"flex";"lemma"] else
if cat = "verb" then latex_of_interp_rules_table l ["cat";"pref";"group";"flex";"flex2";"lemma"] else
if cat = "verb:general" then latex_of_interp_rules_table l ["cat";"pref";"flex";"flex2"] else
Xlist.iter l (fun r ->
print_endline ((if r.star = Star then "$\\star$" else "") ^ r.interp ^ " $\\leftarrow$ " ^ (latex_prepare_tags2 r.tags) ^ "\\\\")))