(* Copyright (C) 2005, HELM Team. * * This file is part of HELM, an Hypertextual, Electronic * Library of Mathematics, developed at the Computer Science * Department, University of Bologna, Italy. * * HELM is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * HELM 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with HELM; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, * MA 02111-1307, USA. * * For details, see the HELM World-Wide-Web page, * http://helm.cs.unibo.it/ *) (* $Id: termAcicContent.ml 9304 2008-12-05 23:12:39Z sacerdot $ *) open Printf module Ast = CicNotationPt let debug = false let debug_print s = if debug then prerr_endline (Lazy.force s) else () type id = string (* type interpretation_id = int type term_info = { sort: (Cic.id, Ast.sort_kind) Hashtbl.t; uri: (Cic.id, UriManager.uri) Hashtbl.t; } let get_types uri = let o,_ = CicEnvironment.get_obj CicUniv.oblivion_ugraph uri in match o with | Cic.InductiveDefinition (l,_,leftno,_) -> l, leftno | _ -> assert false *) let freshid register_ref register_father_id = let id = ref 0 in fun ?reference father_id -> incr id; let id = "i" ^ string_of_int !id in (match reference with None -> () | Some r -> register_ref id r); register_father_id id father_id; Some id, fun t -> Ast.AttributedTerm (`IdRef id, t) ;; (* CODICE c&p da NCicPp *) let nast_of_cic0 ~(freshid: ?reference:NReference.reference -> id option -> id option * (CicNotationPt.term -> CicNotationPt.term)) ~output_type ~subst k ~context father_id = function | NCic.Rel n -> let id, idref = freshid father_id in (try let name,_ = List.nth context (n-1) in let name = if name = "_" then "__"^string_of_int n else name in idref (Ast.Ident (name,None)) with Failure "nth" | Invalid_argument "List.nth" -> idref (Ast.Ident ("-"^ string_of_int (n - List.length context),None))) | NCic.Const r -> let id, idref = freshid ~reference:r father_id in idref (Ast.Ident (NCicPp.r2s true r, None)) | NCic.Meta (n,lc) when List.mem_assoc n subst -> let _,_,t,_ = List.assoc n subst in k ~context father_id (NCicSubstitution.subst_meta lc t) | NCic.Meta (n,(s,l)) -> let id, idref = freshid father_id in (* CSC: qua non dovremmo espandere *) let l = NCicUtils.expand_local_context l in idref (Ast.Meta (n, List.map (fun x->Some(k ~context id (NCicSubstitution.lift s x))) l)) | NCic.Sort NCic.Prop -> let id, idref = freshid father_id in idref (Ast.Sort `Prop) | NCic.Sort NCic.Type _ -> let id, idref = freshid father_id in idref (Ast.Sort `Set) (* CSC: | C.Sort (C.Type []) -> F.fprintf f "Type0" | C.Sort (C.Type [false, u]) -> F.fprintf f "%s" (NUri.name_of_uri u) | C.Sort (C.Type [true, u]) -> F.fprintf f "S(%s)" (NUri.name_of_uri u) | C.Sort (C.Type l) -> F.fprintf f "Max("; aux ctx (C.Sort (C.Type [List.hd l])); List.iter (fun x -> F.fprintf f ",";aux ctx (C.Sort (C.Type [x]))) (List.tl l); F.fprintf f ")"*) (* CSC: qua siamo grezzi *) | NCic.Implicit `Hole -> let id, idref = freshid father_id in idref (Ast.UserInput) | NCic.Implicit _ -> let id, idref = freshid father_id in idref (Ast.Implicit) | NCic.Prod (n,s,t) -> let id, idref = freshid father_id in let n = if n.[0] = '_' then "_" else n in let binder_kind = `Forall in idref (Ast.Binder (binder_kind, (Ast.Ident (n,None), Some (k ~context id s)), k ~context:((n,NCic.Decl s)::context) id t)) | NCic.Lambda (n,s,t) -> let id, idref = freshid father_id in idref (Ast.Binder (`Lambda,(Ast.Ident (n,None), Some (k ~context id s)), k ~context:((n,NCic.Decl s)::context) id t)) | NCic.LetIn (n,s,ty,t) -> let id, idref = freshid father_id in idref (Ast.LetIn ((Ast.Ident (n,None), Some (k ~context id ty)), k ~context id s, k ~context:((n,NCic.Decl s)::context) id t)) | NCic.Appl (NCic.Meta (n,lc) :: args) when List.mem_assoc n subst -> let _,_,t,_ = List.assoc n subst in let hd = NCicSubstitution.subst_meta lc t in k ~context father_id (NCicReduction.head_beta_reduce ~upto:(List.length args) (match hd with | NCic.Appl l -> NCic.Appl (l@args) | _ -> NCic.Appl (hd :: args))) | NCic.Appl args -> let id, idref = freshid father_id in idref (Ast.Appl (List.map (k ~context id) args)) | NCic.Match (NReference.Ref (uri,_) as r,outty,te,patterns) -> let id, idref = freshid father_id in let name = NUri.name_of_uri uri in (* CSC let uri_str = UriManager.string_of_uri uri in let puri_str = sprintf "%s#xpointer(1/%d)" uri_str (typeno+1) in let ctor_puri j = UriManager.uri_of_string (sprintf "%s#xpointer(1/%d/%d)" uri_str (typeno+1) j) in *) let case_indty = name, None(*CSC Some (UriManager.uri_of_string puri_str)*) in let constructors, leftno = let _,leftno,tys,_,n = NCicEnvironment.get_checked_indtys r in let _,_,_,cl = List.nth tys n in cl,leftno in let rec eat_branch n ctx ty pat = match (ty, pat) with | NCic.Prod (name, s, t), _ when n > 0 -> eat_branch (pred n) ((name,NCic.Decl s)::ctx) t pat | NCic.Prod (_, _, t), NCic.Lambda (name, s, t') -> let cv, rhs = eat_branch 0 ((name,NCic.Decl s)::ctx) t t' in (Ast.Ident (name,None), Some (k ~context id s)) :: cv, rhs | _, _ -> [], k ~context id pat in let j = ref 0 in let patterns = try List.map2 (fun (_, name, ty) pat -> incr j; let name,(capture_variables,rhs) = match output_type with `Term -> name, eat_branch leftno context ty pat | `Pattern -> "_", ([], k ~context id pat) in Ast.Pattern (name, None(*CSC Some (ctor_puri !j)*), capture_variables),rhs ) constructors patterns with Invalid_argument _ -> assert false in let indty = match output_type with `Pattern -> None | `Term -> Some case_indty in idref (Ast.Case (k ~context id te, indty, Some (k ~context id outty), patterns)) ;; (* persistent state *) (* let initial_level2_patterns32 () = Hashtbl.create 211 let initial_interpretations () = Hashtbl.create 211 let level2_patterns32 = ref (initial_level2_patterns32 ()) (* symb -> id list ref *) let interpretations = ref (initial_interpretations ()) *) let compiled32 = ref None (* let pattern32_matrix = ref [] let counter = ref ~-1 let stack = ref [] let push () = stack := (!counter,!level2_patterns32,!interpretations,!compiled32,!pattern32_matrix)::!stack; counter := ~-1; level2_patterns32 := initial_level2_patterns32 (); interpretations := initial_interpretations (); compiled32 := None; pattern32_matrix := [] ;; let pop () = match !stack with [] -> assert false | (ocounter,olevel2_patterns32,ointerpretations,ocompiled32,opattern32_matrix)::old -> stack := old; counter := ocounter; level2_patterns32 := olevel2_patterns32; interpretations := ointerpretations; compiled32 := ocompiled32; pattern32_matrix := opattern32_matrix ;; *) let get_compiled32 () = match !compiled32 with | None -> assert false | Some f -> Lazy.force f let set_compiled32 f = compiled32 := Some f let add_idrefs = List.fold_right (fun idref t -> Ast.AttributedTerm (`IdRef idref, t)) let instantiate32 idrefs env symbol args = let rec instantiate_arg = function | Ast.IdentArg (n, name) -> let t = try List.assoc name env with Not_found -> prerr_endline ("name not found in env: "^name); assert false in let rec count_lambda = function | Ast.AttributedTerm (_, t) -> count_lambda t | Ast.Binder (`Lambda, _, body) -> 1 + count_lambda body | _ -> 0 in let rec add_lambda t n = if n > 0 then let name = CicNotationUtil.fresh_name () in Ast.Binder (`Lambda, (Ast.Ident (name, None), None), Ast.Appl [add_lambda t (n - 1); Ast.Ident (name, None)]) else t in add_lambda t (n - count_lambda t) in let head = let symbol = Ast.Symbol (symbol, 0) in add_idrefs idrefs symbol in if args = [] then head else Ast.Appl (head :: List.map instantiate_arg args) let rec nast_of_cic1 ~freshid ~output_type ~subst ~context father_id term = match (get_compiled32 ()) term with | None -> nast_of_cic0 ~freshid ~output_type ~subst (nast_of_cic1 ~freshid ~output_type ~subst) ~context father_id term | Some (env, ctors, pid) -> let id, idref = freshid father_id in let idrefs = List.map (fun term -> let id, _ = freshid ~reference: (match term with NCic.Const nref -> nref | _ -> assert false) father_id in match id with Some id -> id | None -> assert false ) ctors in let env = List.map (fun (name, term) -> name,nast_of_cic1 ~freshid ~output_type ~subst ~context id term ) env in let _, symbol, args, _ = try TermAcicContent.find_level2_patterns32 pid with Not_found -> assert false in let ast = instantiate32 idrefs env symbol args in idref ast (*Ast.AttributedTerm (`IdRef (idref term), ast)*) ;; let load_patterns32 t = let t = HExtlib.filter_map (function (true, ap, id) -> Some (ap, id) | _ -> None) t in set_compiled32 (lazy (Ncic2astMatcher.Matcher32.compiler t)) in TermAcicContent.add_load_patterns32 load_patterns32; TermAcicContent.init () ;; (* let ast_of_acic ~output_type id_to_sort annterm = debug_print (lazy ("ast_of_acic <- " ^ CicPp.ppterm (Deannotate.deannotate_term annterm))); let term_info = { sort = id_to_sort; uri = Hashtbl.create 211 } in let ast = ast_of_acic1 ~output_type term_info annterm in debug_print (lazy ("ast_of_acic -> " ^ CicNotationPp.pp_term ast)); ast, term_info.uri let fresh_id = fun () -> incr counter; !counter let add_interpretation dsc (symbol, args) appl_pattern = let id = fresh_id () in Hashtbl.add !level2_patterns32 id (dsc, symbol, args, appl_pattern); pattern32_matrix := (true, appl_pattern, id) :: !pattern32_matrix; load_patterns32 !pattern32_matrix; (try let ids = Hashtbl.find !interpretations symbol in ids := id :: !ids with Not_found -> Hashtbl.add !interpretations symbol (ref [id])); id let get_all_interpretations () = List.map (function (_, _, id) -> let (dsc, _, _, _) = try Hashtbl.find !level2_patterns32 id with Not_found -> assert false in (id, dsc)) !pattern32_matrix let get_active_interpretations () = HExtlib.filter_map (function (true, _, id) -> Some id | _ -> None) !pattern32_matrix let set_active_interpretations ids = let pattern32_matrix' = List.map (function | (_, ap, id) when List.mem id ids -> (true, ap, id) | (_, ap, id) -> (false, ap, id)) !pattern32_matrix in pattern32_matrix := pattern32_matrix'; load_patterns32 !pattern32_matrix exception Interpretation_not_found let lookup_interpretations symbol = try HExtlib.list_uniq (List.sort Pervasives.compare (List.map (fun id -> let (dsc, _, args, appl_pattern) = try Hashtbl.find !level2_patterns32 id with Not_found -> assert false in dsc, args, appl_pattern) !(Hashtbl.find !interpretations symbol))) with Not_found -> raise Interpretation_not_found let remove_interpretation id = (try let dsc, symbol, _, _ = Hashtbl.find !level2_patterns32 id in let ids = Hashtbl.find !interpretations symbol in ids := List.filter ((<>) id) !ids; Hashtbl.remove !level2_patterns32 id; with Not_found -> raise Interpretation_not_found); pattern32_matrix := List.filter (fun (_, _, id') -> id <> id') !pattern32_matrix; load_patterns32 !pattern32_matrix let _ = load_patterns32 [] let instantiate_appl_pattern ~mk_appl ~mk_implicit ~term_of_uri env appl_pattern = let lookup name = try List.assoc name env with Not_found -> prerr_endline (sprintf "Name %s not found" name); assert false in let rec aux = function | Ast.UriPattern uri -> term_of_uri uri | Ast.ImplicitPattern -> mk_implicit false | Ast.VarPattern name -> lookup name | Ast.ApplPattern terms -> mk_appl (List.map aux terms) in aux appl_pattern *) let nmap_sequent0 ~freshid ~subst (i,(n,context,ty):int * NCic.conjecture) = let module K = Content in let nast_of_cic ~context = nast_of_cic1 ~freshid ~output_type:`Term ~subst ~context None in let context',_ = List.fold_right (fun item (res,context) -> match item with | name,NCic.Decl t -> Some (* We should call build_decl_item, but we have not computed *) (* the inner-types ==> we always produce a declaration *) (`Declaration { K.dec_name = (Some name); K.dec_id = "-1"; K.dec_inductive = false; K.dec_aref = "-1"; K.dec_type = nast_of_cic ~context t })::res,item::context | name,NCic.Def (t,ty) -> Some (* We should call build_def_item, but we have not computed *) (* the inner-types ==> we always produce a declaration *) (`Definition { K.def_name = (Some name); K.def_id = "-1"; K.def_aref = "-1"; K.def_term = nast_of_cic ~context t; K.def_type = nast_of_cic ~context ty })::res,item::context ) context ([],[]) in ("-1",i,context',nast_of_cic ~context ty) ;; let nmap_sequent ~subst metasenv = let module K = Content in let ids_to_refs = Hashtbl.create 503 in let ids_to_father_ids = Hashtbl.create 503 in let register_ref = Hashtbl.add ids_to_refs in let register_father_id = Hashtbl.add ids_to_father_ids in nmap_sequent0 ~freshid:(freshid register_ref register_father_id) ~subst metasenv,ids_to_refs,ids_to_father_ids ;; let object_prefix = "obj:";; let declaration_prefix = "decl:";; let definition_prefix = "def:";; let get_id = function Ast.AttributedTerm (`IdRef id, _) -> id | _ -> assert false ;; let gen_id prefix seed = let res = prefix ^ string_of_int !seed in incr seed ; res ;; let build_def_item seed context metasenv id n t ty = let module K = Content in (* try let sort = Hashtbl.find ids_to_inner_sorts id in if sort = `Prop then (let p = (acic2content seed context metasenv ?name:(name_of n) ~ids_to_inner_sorts ~ids_to_inner_types t) in `Proof p;) else *) `Definition { K.def_name = Some n; K.def_id = gen_id definition_prefix seed; K.def_aref = id; K.def_term = t; K.def_type = ty } (* with Not_found -> assert false *) let build_decl_item seed id n s = let module K = Content in (* let sort = try Some (Hashtbl.find ids_to_inner_sorts (Cic2acic.source_id_of_id id)) with Not_found -> None in match sort with | Some `Prop -> `Hypothesis { K.dec_name = name_of n; K.dec_id = gen_id declaration_prefix seed; K.dec_inductive = false; K.dec_aref = id; K.dec_type = s } | _ -> *) `Declaration { K.dec_name = Some n; K.dec_id = gen_id declaration_prefix seed; K.dec_inductive = false; K.dec_aref = id; K.dec_type = s } ;; let nmap_obj (uri,_,metasenv,subst,kind) = let module K = Content in let ids_to_refs = Hashtbl.create 503 in let register_ref = Hashtbl.add ids_to_refs in let ids_to_father_ids = Hashtbl.create 503 in let register_father_id = Hashtbl.add ids_to_father_ids in let freshid = freshid register_ref register_father_id in let nast_of_cic ~context = nast_of_cic1 ~freshid ~output_type:`Term ~subst ~context None in let seed = ref 0 in let conjectures = match metasenv with [] -> None | _ -> (*Some (List.map (map_conjectures seed) metasenv)*) (*CSC: used to be the previous line, that uses seed *) Some (List.map (nmap_sequent0 ~freshid ~subst) metasenv) in let res = match kind with NCic.Constant (_,_,Some bo,ty,_) -> let ty = nast_of_cic ~context:[] ty in let bo = nast_of_cic ~context:[] bo in (gen_id object_prefix seed, [], conjectures, `Def (K.Const,ty, build_def_item seed [] [] (get_id bo) (NUri.name_of_uri uri) bo ty)) | NCic.Constant (_,_,None,ty,_) -> let ty = nast_of_cic ~context:[] ty in (gen_id object_prefix seed, [], conjectures, `Decl (K.Const, (*CSC: ??? get_id ty here used to be the id of the axiom! *) build_decl_item seed (get_id ty) (NUri.name_of_uri uri) ty)) (* | C.AInductiveDefinition (id,l,params,nparams,_) -> (gen_id object_prefix seed, params, conjectures, `Joint { K.joint_id = gen_id joint_prefix seed; K.joint_kind = `Inductive nparams; K.joint_defs = List.map (build_inductive seed) l }) and build_inductive seed = let module K = Content in fun (_,n,b,ty,l) -> `Inductive { K.inductive_id = gen_id inductive_prefix seed; K.inductive_name = n; K.inductive_kind = b; K.inductive_type = ty; K.inductive_constructors = build_constructors seed l } and build_constructors seed l = let module K = Content in List.map (fun (n,t) -> { K.dec_name = Some n; K.dec_id = gen_id declaration_prefix seed; K.dec_inductive = false; K.dec_aref = ""; K.dec_type = t }) l *) in res,ids_to_refs,ids_to_father_ids ;;