--- /dev/null
+(* $Id$ *)
+
+open Path_indexing
+
+(*
+let build_equality term =
+ let module C = Cic in
+ C.Implicit None, (C.Implicit None, term, C.Rel 1, Utils.Gt), [], []
+;;
+
+
+(*
+ f = Rel 1
+ g = Rel 2
+ a = Rel 3
+ b = Rel 4
+ c = Rel 5
+*)
+let path_indexing_test () =
+ let module C = Cic in
+ let terms = [
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Rel 3; C.Meta (1, [])]; C.Rel 5];
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Meta (1, []); C.Rel 4]; C.Meta (1, [])];
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Rel 3; C.Rel 4]; C.Rel 5];
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Meta (1, []); C.Rel 5]; C.Rel 4];
+ C.Appl [C.Rel 1; C.Meta (1, []); C.Meta (1, [])]
+ ] in
+ let path_strings = List.map (path_strings_of_term 0) terms in
+ let table =
+ List.fold_left index PSTrie.empty (List.map build_equality terms) in
+ let query =
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Meta (1, []); C.Rel 4]; C.Rel 5] in
+ let matches = retrieve_generalizations table query in
+ let unifications = retrieve_unifiables table query in
+ let eq1 = build_equality (C.Appl [C.Rel 1; C.Meta (1, []); C.Meta (1, [])])
+ and eq2 = build_equality (C.Appl [C.Rel 1; C.Meta (1, []); C.Meta (2, [])]) in
+ let res1 = in_index table eq1
+ and res2 = in_index table eq2 in
+ let print_results res =
+ String.concat "\n"
+ (PosEqSet.fold
+ (fun (p, e) l ->
+ let s =
+ "(" ^ (Utils.string_of_pos p) ^ ", " ^
+ (Inference.string_of_equality e) ^ ")"
+ in
+ s::l)
+ res [])
+ in
+ Printf.printf "path_strings:\n%s\n\n"
+ (String.concat "\n"
+ (List.map
+ (fun l ->
+ "{" ^ (String.concat "; " (List.map string_of_path_string l)) ^ "}"
+ ) path_strings));
+ Printf.printf "table:\n%s\n\n" (string_of_pstrie table);
+ Printf.printf "matches:\n%s\n\n" (print_results matches);
+ Printf.printf "unifications:\n%s\n\n" (print_results unifications);
+ Printf.printf "in_index %s: %s\n"
+ (Inference.string_of_equality eq1) (string_of_bool res1);
+ Printf.printf "in_index %s: %s\n"
+ (Inference.string_of_equality eq2) (string_of_bool res2);
+;;
+
+
+let differing () =
+ let module C = Cic in
+ let t1 =
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Rel 3; C.Meta (1, [])]; C.Rel 5]
+ and t2 =
+ C.Appl [C.Rel 1; C.Appl [C.Rel 5; C.Rel 4; C.Meta (1, [])]; C.Rel 5]
+ in
+ let res = Inference.extract_differing_subterms t1 t2 in
+ match res with
+ | None -> prerr_endline "NO DIFFERING SUBTERMS???"
+ | Some (t1, t2) ->
+ Printf.printf "OK: %s, %s\n" (CicPp.ppterm t1) (CicPp.ppterm t2);
+;;
+
+
+let next_after () =
+ let module C = Cic in
+ let t =
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Rel 3; C.Rel 4]; C.Rel 5]
+ in
+ let pos1 = Discrimination_tree.next_t [1] t in
+ let pos2 = Discrimination_tree.after_t [1] t in
+ Printf.printf "next_t 1: %s\nafter_t 1: %s\n"
+ (CicPp.ppterm (Discrimination_tree.subterm_at_pos pos1 t))
+ (CicPp.ppterm (Discrimination_tree.subterm_at_pos pos2 t));
+;;
+
+
+let discrimination_tree_test () =
+ let module C = Cic in
+ let terms = [
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Rel 3; C.Meta (1, [])]; C.Rel 5];
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Meta (1, []); C.Rel 4]; C.Meta (1, [])];
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Rel 3; C.Rel 4]; C.Rel 5];
+ C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Meta (1, []); C.Rel 5]; C.Rel 4];
+ C.Appl [C.Rel 10; C.Meta (5, []); C.Rel 11]
+ ] in
+ let path_strings =
+ List.map Discrimination_tree.path_string_of_term terms in
+ let table =
+ List.fold_left
+ Discrimination_tree.index
+ Discrimination_tree.DiscriminationTree.empty
+ (List.map build_equality terms)
+ in
+(* let query = *)
+(* C.Appl [C.Rel 1; C.Appl [C.Rel 2; C.Meta (1, []); C.Rel 4]; C.Rel 5] in *)
+ let query = C.Appl [C.Rel 10; C.Meta (14, []); C.Meta (13, [])] in
+ let matches = Discrimination_tree.retrieve_generalizations table query in
+ let unifications = Discrimination_tree.retrieve_unifiables table query in
+ let eq1 = build_equality (C.Appl [C.Rel 1; C.Meta (1, []); C.Meta (1, [])])
+ and eq2 = build_equality (C.Appl [C.Rel 1; C.Meta (1, []); C.Meta (2, [])]) in
+ let res1 = Discrimination_tree.in_index table eq1
+ and res2 = Discrimination_tree.in_index table eq2 in
+ let print_results res =
+ String.concat "\n"
+ (Discrimination_tree.PosEqSet.fold
+ (fun (p, e) l ->
+ let s =
+ "(" ^ (Utils.string_of_pos p) ^ ", " ^
+ (Inference.string_of_equality e) ^ ")"
+ in
+ s::l)
+ res [])
+ in
+ Printf.printf "path_strings:\n%s\n\n"
+ (String.concat "\n"
+ (List.map Discrimination_tree.string_of_path_string path_strings));
+ Printf.printf "table:\n%s\n\n"
+ (Discrimination_tree.string_of_discrimination_tree table);
+ Printf.printf "matches:\n%s\n\n" (print_results matches);
+ Printf.printf "unifications:\n%s\n\n" (print_results unifications);
+ Printf.printf "in_index %s: %s\n"
+ (Inference.string_of_equality eq1) (string_of_bool res1);
+ Printf.printf "in_index %s: %s\n"
+ (Inference.string_of_equality eq2) (string_of_bool res2);
+;;
+
+
+let test_subst () =
+ let module C = Cic in
+ let module M = CicMetaSubst in
+ let term = C.Appl [
+ C.Rel 1;
+ C.Appl [C.Rel 11;
+ C.Meta (43, []);
+ C.Appl [C.Rel 15; C.Rel 12; C.Meta (41, [])]];
+ C.Appl [C.Rel 11;
+ C.Appl [C.Rel 15; C.Meta (10, []); C.Meta (11, [])];
+ C.Appl [C.Rel 15; C.Meta (10, []); C.Meta (12, [])]]
+ ] in
+ let subst1 = [
+ (43, ([], C.Appl [C.Rel 15; C.Meta (10, []); C.Meta (11, [])], C.Rel 16));
+ (10, ([], C.Rel 12, C.Rel 16));
+ (12, ([], C.Meta (41, []), C.Rel 16))
+ ]
+ and subst2 = [
+ (43, ([], C.Appl [C.Rel 15; C.Rel 12; C.Meta (11, [])], C.Rel 16));
+ (10, ([], C.Rel 12, C.Rel 16));
+ (12, ([], C.Meta (41, []), C.Rel 16))
+ ] in
+ let t1 = M.apply_subst subst1 term
+ and t2 = M.apply_subst subst2 term in
+ Printf.printf "t1 = %s\nt2 = %s\n" (CicPp.ppterm t1) (CicPp.ppterm t2);
+;;
+*)
+
+
+let test_refl () =
+ let module C = Cic in
+ let context = [
+ Some (C.Name "H", C.Decl (
+ C.Prod (C.Name "z", C.Rel 3,
+ C.Appl [
+ C.MutInd (HelmLibraryObjects.Logic.eq_URI, 0, []);
+ C.Rel 4; C.Rel 3; C.Rel 1])));
+ Some (C.Name "x", C.Decl (C.Rel 2));
+ Some (C.Name "y", C.Decl (C.Rel 1));
+ Some (C.Name "A", C.Decl (C.Sort C.Set))
+ ]
+ in
+ let term = C.Appl [
+ C.Const (HelmLibraryObjects.Logic.eq_ind_URI, []); C.Rel 4;
+ C.Rel 2;
+ C.Lambda (C.Name "z", C.Rel 4,
+ C.Appl [
+ C.MutInd (HelmLibraryObjects.Logic.eq_URI, 0, []);
+ C.Rel 5; C.Rel 1; C.Rel 3
+ ]);
+ C.Appl [C.MutConstruct
+ (HelmLibraryObjects.Logic.eq_URI, 0, 1, []); (* reflexivity *)
+ C.Rel 4; C.Rel 2];
+ C.Rel 3;
+(* C.Appl [C.Const (HelmLibraryObjects.Logic.sym_eq_URI, []); (\* symmetry *\) *)
+(* C.Rel 4; C.Appl [C.Rel 1; C.Rel 2]] *)
+ C.Appl [
+ C.Const (HelmLibraryObjects.Logic.eq_ind_URI, []);
+ C.Rel 4; C.Rel 3;
+ C.Lambda (C.Name "z", C.Rel 4,
+ C.Appl [
+ C.MutInd (HelmLibraryObjects.Logic.eq_URI, 0, []);
+ C.Rel 5; C.Rel 1; C.Rel 4
+ ]);
+ C.Appl [C.MutConstruct (HelmLibraryObjects.Logic.eq_URI, 0, 1, []);
+ C.Rel 4; C.Rel 3];
+ C.Rel 2; C.Appl [C.Rel 1; C.Rel 2]
+ ]
+ ] in
+ let ens = [
+ (UriManager.uri_of_string "cic:/Coq/Init/Logic/Logic_lemmas/equality/A.var",
+ C.Rel 4);
+ (UriManager.uri_of_string "cic:/Coq/Init/Logic/Logic_lemmas/equality/x.var",
+ C.Rel 3);
+ (UriManager.uri_of_string "cic:/Coq/Init/Logic/Logic_lemmas/equality/y.var",
+ C.Rel 2);
+ ] in
+ let term2 = C.Appl [
+ C.Const (HelmLibraryObjects.Logic.sym_eq_URI, ens);
+ C.Appl [C.Rel 1; C.Rel 2]
+ ] in
+ let ty, ug =
+ CicTypeChecker.type_of_aux' [] context term CicUniv.empty_ugraph
+ in
+ Printf.printf "OK, %s ha tipo %s\n" (CicPp.ppterm term) (CicPp.ppterm ty);
+ let ty, ug =
+ CicTypeChecker.type_of_aux' [] context term2 CicUniv.empty_ugraph
+ in
+ Printf.printf "OK, %s ha tipo %s\n" (CicPp.ppterm term2) (CicPp.ppterm ty);
+;;
+
+
+let test_lib () =
+ let uri = Sys.argv.(1) in
+ let t = CicUtil.term_of_uri (UriManager.uri_of_string uri) in
+ let ty, _ = CicTypeChecker.type_of_aux' [] [] t CicUniv.empty_ugraph in
+ Printf.printf "Term of %s: %s\n" uri (CicPp.ppterm t);
+ Printf.printf "type: %s\n" (CicPp.ppterm ty);
+;;
+
+
+(* differing ();; *)
+(* next_after ();; *)
+(* discrimination_tree_test ();; *)
+(* path_indexing_test ();; *)
+(* test_subst ();; *)
+Helm_registry.load_from "../../matita/matita.conf.xml";
+(* test_refl ();; *)
+test_lib ();;