1 (* Copyright (C) 2004, HELM Team.
3 * This file is part of HELM, an Hypertextual, Electronic
4 * Library of Mathematics, developed at the Computer Science
5 * Department, University of Bologna, Italy.
7 * HELM is free software; you can redistribute it and/or
8 * modify it under the terms of the GNU General Public License
9 * as published by the Free Software Foundation; either version 2
10 * of the License, or (at your option) any later version.
12 * HELM is distributed in the hope that it will be useful,
13 * but WITHOUT ANY WARRANTY; without even the implied warranty of
14 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 * GNU General Public License for more details.
17 * You should have received a copy of the GNU General Public License
18 * along with HELM; if not, write to the Free Software
19 * Foundation, Inc., 59 Temple Place - Suite 330, Boston,
22 * For details, see the HELM World-Wide-Web page,
23 * http://helm.cs.unibo.it/
28 exception Meta_not_found of int
29 exception Subst_not_found of int
31 let lookup_meta index metasenv =
33 List.find (fun (index', _, _) -> index = index') metasenv
34 with Not_found -> raise (Meta_not_found index)
36 let lookup_subst n subst =
39 with Not_found -> raise (Subst_not_found n)
41 let exists_meta index = List.exists (fun (index', _, _) -> (index = index'))
43 (* clean_up_meta take a substitution, a metasenv a meta_inex and a local
44 context l and clean up l with respect to the hidden hipothesis in the
47 let clean_up_local_context subst metasenv n l =
50 let (cc,_,_) = lookup_subst n subst in cc
51 with Subst_not_found _ ->
53 let (_,cc,_) = lookup_meta n metasenv in cc
54 with Meta_not_found _ -> assert false) in
62 Invalid_argument _ -> assert false)
68 C.Rel m when m > k -> false
72 (fun i t -> i && (match t with None -> true | Some t -> is_closed k t)
75 | C.Implicit _ -> assert false
76 | C.Cast (te,ty) -> is_closed k te && is_closed k ty
77 | C.Prod (name,so,dest) -> is_closed k so && is_closed (k+1) dest
78 | C.Lambda (_,so,dest) -> is_closed k so && is_closed (k+1) dest
79 | C.LetIn (_,so,dest) -> is_closed k so && is_closed (k+1) dest
81 List.fold_right (fun x i -> i && is_closed k x) l true
82 | C.Var (_,exp_named_subst)
83 | C.Const (_,exp_named_subst)
84 | C.MutInd (_,_,exp_named_subst)
85 | C.MutConstruct (_,_,_,exp_named_subst) ->
86 List.fold_right (fun (_,x) i -> i && is_closed k x)
88 | C.MutCase (_,_,out,te,pl) ->
89 is_closed k out && is_closed k te &&
90 List.fold_right (fun x i -> i && is_closed k x) pl true
92 let len = List.length fl in
93 let k_plus_len = k + len in
95 (fun (_,_,ty,bo) i -> i && is_closed k ty && is_closed k_plus_len bo
98 let len = List.length fl in
99 let k_plus_len = k + len in
101 (fun (_,ty,bo) i -> i && is_closed k ty && is_closed k_plus_len bo
107 let rec is_meta_closed =
110 | Cic.Meta _ -> false
112 | Cic.Implicit _ -> assert false
113 | Cic.Cast (te,ty) -> is_meta_closed te && is_meta_closed ty
114 | Cic.Prod (name,so,dest) -> is_meta_closed so && is_meta_closed dest
115 | Cic.Lambda (_,so,dest) -> is_meta_closed so && is_meta_closed dest
116 | Cic.LetIn (_,so,dest) -> is_meta_closed so && is_meta_closed dest
118 List.fold_right (fun x i -> i && is_meta_closed x) l true
119 | Cic.Var (_,exp_named_subst)
120 | Cic.Const (_,exp_named_subst)
121 | Cic.MutInd (_,_,exp_named_subst)
122 | Cic.MutConstruct (_,_,_,exp_named_subst) ->
123 List.fold_right (fun (_,x) i -> i && is_meta_closed x)
125 | Cic.MutCase (_,_,out,te,pl) ->
126 is_meta_closed out && is_meta_closed te &&
127 List.fold_right (fun x i -> i && is_meta_closed x) pl true
130 (fun (_,_,ty,bo) i -> i && is_meta_closed ty && is_meta_closed bo
132 | Cic.CoFix (_,fl) ->
134 (fun (_,ty,bo) i -> i && is_meta_closed ty && is_meta_closed bo
138 let xpointer_RE = Str.regexp "\\([^#]+\\)#xpointer(\\(.*\\))"
139 let slash_RE = Str.regexp "/"
142 let uri = UriManager.uri_of_string s in
144 (if String.sub s (String.length s - 4) 4 = ".con" then
146 else if String.sub s (String.length s - 4) 4 = ".var" then
148 else if not (Str.string_match xpointer_RE s 0) then
149 raise (UriManager.IllFormedUri s)
151 let (baseuri,xpointer) = (Str.matched_group 1 s, Str.matched_group 2 s) in
152 let baseuri = UriManager.uri_of_string baseuri in
153 (match Str.split slash_RE xpointer with
154 | [_; tyno] -> Cic.MutInd (baseuri, int_of_string tyno - 1, [])
155 | [_; tyno; consno] ->
157 (baseuri, int_of_string tyno - 1, int_of_string consno, [])
162 | Not_found -> raise (UriManager.IllFormedUri s)
164 let uri_of_term = function
165 | Cic.Const (uri, [])
166 | Cic.Var (uri, []) -> UriManager.string_of_uri uri
167 | Cic.MutInd (baseuri, tyno, []) ->
168 sprintf "%s#xpointer(1/%d)" (UriManager.string_of_uri baseuri) (tyno + 1)
169 | Cic.MutConstruct (baseuri, tyno, consno, []) ->
170 sprintf "%s#xpointer(1/%d/%d)" (UriManager.string_of_uri baseuri)
172 | _ -> raise (Invalid_argument "uri_of_term")
174 let select ~term ~context =
175 let rec aux context term =
176 match (context, term) with
177 | Cic.Implicit (Some `Hole), t -> [t]
178 | Cic.Implicit None,_ -> []
179 | Cic.Meta (_, ctxt1), Cic.Meta (_, ctxt2) ->
183 (match (t1, t2) with Some t1, Some t2 -> aux t1 t2 | _ -> []))
185 | Cic.Cast (te1, ty1), Cic.Cast (te2, ty2) -> aux te1 te2 @ aux ty1 ty2
186 | Cic.Prod (_, s1, t1), Cic.Prod (_, s2, t2)
187 | Cic.Lambda (_, s1, t1), Cic.Lambda (_, s2, t2)
188 | Cic.LetIn (_, s1, t1), Cic.LetIn (_, s2, t2) -> aux s1 s2 @ aux t1 t2
189 | Cic.Appl terms1, Cic.Appl terms2 -> auxs terms1 terms2
190 | Cic.Var (_, subst1), Cic.Var (_, subst2)
191 | Cic.Const (_, subst1), Cic.Const (_, subst2)
192 | Cic.MutInd (_, _, subst1), Cic.MutInd (_, _, subst2)
193 | Cic.MutConstruct (_, _, _, subst1), Cic.MutConstruct (_, _, _, subst2) ->
194 auxs (List.map snd subst1) (List.map snd subst2)
195 | Cic.MutCase (_, _, out1, t1, pat1), Cic.MutCase (_ , _, out2, t2, pat2) ->
196 aux out1 out2 @ aux t1 t2 @ auxs pat1 pat2
197 | Cic.Fix (_, funs1), Cic.Fix (_, funs2) ->
200 (fun (_, _, ty1, bo1) (_, _, ty2, bo2) -> aux ty1 ty2 @ aux bo1 bo2)
202 | Cic.CoFix (_, funs1), Cic.CoFix (_, funs2) ->
205 (fun (_, ty1, bo1) (_, ty2, bo2) -> aux ty1 ty2 @ aux bo1 bo2)
208 and auxs terms1 terms2 = (* as aux for list of terms *)
209 List.concat (List.map2 aux terms1 terms2)
213 let context_of ?(equality=(==)) ~term terms =
214 let (===) x y = equality x y in
217 | t when List.exists (fun t' -> t === t') terms -> Cic.Implicit (Some `Hole)
218 | Cic.Var (uri, subst) -> Cic.Var (uri, aux_subst subst)
219 | Cic.Meta (i, ctxt) ->
221 List.map (function None -> None | Some t -> Some (aux t)) ctxt
224 | Cic.Cast (t, ty) -> Cic.Cast (aux t, aux ty)
225 | Cic.Prod (name, s, t) -> Cic.Prod (name, aux s, aux t)
226 | Cic.Lambda (name, s, t) -> Cic.Lambda (name, aux s, aux t)
227 | Cic.LetIn (name, s, t) -> Cic.LetIn (name, aux s, aux t)
228 | Cic.Appl terms -> Cic.Appl (List.map aux terms)
229 | Cic.Const (uri, subst) -> Cic.Const (uri, aux_subst subst)
230 | Cic.MutInd (uri, tyno, subst) -> Cic.MutInd (uri, tyno, aux_subst subst)
231 | Cic.MutConstruct (uri, tyno, consno, subst) ->
232 Cic.MutConstruct (uri, tyno, consno, aux_subst subst)
233 | Cic.MutCase (uri, tyno, outty, t, pat) ->
234 Cic.MutCase (uri, tyno, aux outty, aux t, List.map aux pat)
235 | Cic.Fix (funno, funs) ->
237 List.map (fun (name, i, ty, bo) -> (name, i, aux ty, aux bo)) funs
239 Cic.Fix (funno, funs)
240 | Cic.CoFix (funno, funs) ->
242 List.map (fun (name, ty, bo) -> (name, aux ty, aux bo)) funs
244 Cic.CoFix (funno, funs)
247 | Cic.Implicit _ -> t
248 and aux_subst subst =
249 List.map (fun (uri, t) -> (uri, aux t)) subst
255 (fun term acc -> Cic.Prod (Cic.Anonymous, term, acc))
256 terms (Cic.Sort (Cic.Type (CicUniv.fresh ())))
258 let rec unpack = function
259 | Cic.Prod (Cic.Anonymous, term, Cic.Sort (Cic.Type _)) -> [term]
260 | Cic.Prod (Cic.Anonymous, term, tgt) -> term :: unpack tgt
263 let rec strip_prods n = function
265 | Cic.Prod (_, _, tgt) when n > 0 -> strip_prods (n-1) tgt
266 | _ -> failwith "not enough prods"
268 let params_of_obj = function
269 | Cic.Constant (_, _, _, params, _)
270 | Cic.Variable (_, _, _, params, _)
271 | Cic.CurrentProof (_, _, _, _, params, _)
272 | Cic.InductiveDefinition (_, params, _, _) ->
275 let attributes_of_obj = function
276 | Cic.Constant (_, _, _, _, attributes)
277 | Cic.Variable (_, _, _, _, attributes)
278 | Cic.CurrentProof (_, _, _, _, _, attributes)
279 | Cic.InductiveDefinition (_, _, _, attributes) ->