ocaml 3.09 transition

[helm.git] / helm / ocaml / tactics / ring.ml

diff --git a/helm/ocaml/tactics/ring.ml b/helm/ocaml/tactics/ring.ml
index ab7bde56f8dfa4049ca0989ccb55e64d3ac7eada..1d7cc10e6bfad0a0a16fe9b7ad2b74bc0dc6d078 100644 (file)
--- a/helm/ocaml/tactics/ring.ml
+++ b/helm/ocaml/tactics/ring.ml
@@ -28,8 +28,6 @@ open PrimitiveTactics
 open ProofEngineTypes
 open UriManager
 
-open HelmLibraryObjects
-
 (** DEBUGGING *)
 
   (** perform debugging output? *)
@@ -37,9 +35,7 @@ let debug = false
 let debug_print = fun _ -> ()
 
   (** debugging print *)
-let warn s =
-  if debug then
-    debug_print ("RING WARNING: " ^ s)
+let warn s = debug_print (lazy ("RING WARNING: " ^ (Lazy.force s)))
 
 (** CIC URIS *)
 
@@ -192,19 +188,19 @@ exception GoalUnringable
   *)
 let ringable =
   let is_equality = function
-    | Cic.MutInd (uri, 0, []) when (eq uri Logic.eq_URI) -> true
+    | Cic.MutInd (uri, 0, []) when (eq uri HelmLibraryObjects.Logic.eq_URI) -> true
     | _ -> false
   in
   let is_real = function
-    | Cic.Const (uri, _) when (eq uri Reals.r_URI) -> true
+    | Cic.Const (uri, _) when (eq uri HelmLibraryObjects.Reals.r_URI) -> true
     | _ -> false
   in
   function
     | Cic.Appl (app::set::_::_::[]) when (is_equality app && is_real set) ->
-        warn "Goal Ringable!";
+        warn (lazy "Goal Ringable!");
         true
     | _ ->
-        warn "Goal Not Ringable :-((";
+        warn (lazy "Goal Not Ringable :-((");
         false
 
   (**
@@ -216,8 +212,8 @@ let ringable =
   *)
 let split_eq = function
   | (Cic.Appl (_::_::t1::t2::[])) as term when ringable term ->
-        warn ("<term1>" ^ (CicPp.ppterm t1) ^ "</term1>");
-        warn ("<term2>" ^ (CicPp.ppterm t2) ^ "</term2>");
+        warn (lazy ("<term1>" ^ (CicPp.ppterm t1) ^ "</term1>"));
+        warn (lazy ("<term2>" ^ (CicPp.ppterm t2) ^ "</term2>"));
         (t1, t2)
   | _ -> raise GoalUnringable
 
@@ -254,7 +250,7 @@ let path_of_int n =
     @return a cic term representing the variable map containing vars variables
   *)
 let btree_of_array ~vars =
-  let r = Reals.r in
+  let r = HelmLibraryObjects.Reals.r in
   let empty_vm_r = mkCtor empty_vm_uri [quote_varmap_A_uri,r] in
   let node_vm_r = mkCtor node_vm_uri [quote_varmap_A_uri,r] in
   let size = Array.length vars in
@@ -287,17 +283,17 @@ let abstract_poly ~terms =
   let rec aux = function  (* TODO not tail recursive *)
     (* "bop" -> binary operator | "uop" -> unary operator *)
     | Cic.Appl (bop::t1::t2::[])
-      when (cic_is_const ~uri:(Some Reals.rplus_URI) bop) -> (* +. *)
+      when (cic_is_const ~uri:(Some HelmLibraryObjects.Reals.rplus_URI) bop) -> (* +. *)
         Cic.Appl [mkCtor applus_uri []; aux t1; aux t2]
     | Cic.Appl (bop::t1::t2::[])
-      when (cic_is_const ~uri:(Some Reals.rmult_URI) bop) -> (* *. *)
+      when (cic_is_const ~uri:(Some HelmLibraryObjects.Reals.rmult_URI) bop) -> (* *. *)
         Cic.Appl [mkCtor apmult_uri []; aux t1; aux t2]
     | Cic.Appl (uop::t::[])
-      when (cic_is_const ~uri:(Some Reals.ropp_URI) uop) -> (* ~-. *)
+      when (cic_is_const ~uri:(Some HelmLibraryObjects.Reals.ropp_URI) uop) -> (* ~-. *)
         Cic.Appl [mkCtor apopp_uri []; aux t]
-    | t when (cic_is_const ~uri:(Some Reals.r0_URI) t) -> (* 0. *)
+    | t when (cic_is_const ~uri:(Some HelmLibraryObjects.Reals.r0_URI) t) -> (* 0. *)
         mkCtor ap0_uri []
-    | t when (cic_is_const ~uri:(Some Reals.r1_URI) t) -> (* 1. *)
+    | t when (cic_is_const ~uri:(Some HelmLibraryObjects.Reals.r1_URI) t) -> (* 1. *)
         mkCtor ap1_uri []
     | t ->  (* variable *)
       try
@@ -328,20 +324,20 @@ let abstract_poly ~terms =
   *)
 let build_segments ~terms =
   let theory_args_subst varmap =
-   [abstract_rings_A_uri, Reals.r ;
-    abstract_rings_Aplus_uri, Reals.rplus ;
-    abstract_rings_Amult_uri, Reals.rmult ;
-    abstract_rings_Aone_uri, Reals.r1 ;
-    abstract_rings_Azero_uri, Reals.r0 ;
-    abstract_rings_Aopp_uri, Reals.ropp ;
+   [abstract_rings_A_uri, HelmLibraryObjects.Reals.r ;
+    abstract_rings_Aplus_uri, HelmLibraryObjects.Reals.rplus ;
+    abstract_rings_Amult_uri, HelmLibraryObjects.Reals.rmult ;
+    abstract_rings_Aone_uri, HelmLibraryObjects.Reals.r1 ;
+    abstract_rings_Azero_uri, HelmLibraryObjects.Reals.r0 ;
+    abstract_rings_Aopp_uri, HelmLibraryObjects.Reals.ropp ;
     abstract_rings_vm_uri, varmap] in
   let theory_args_subst' eq varmap t =
-   [abstract_rings_A_uri, Reals.r ;
-    abstract_rings_Aplus_uri, Reals.rplus ;
-    abstract_rings_Amult_uri, Reals.rmult ;
-    abstract_rings_Aone_uri, Reals.r1 ;
-    abstract_rings_Azero_uri, Reals.r0 ;
-    abstract_rings_Aopp_uri, Reals.ropp ;
+   [abstract_rings_A_uri, HelmLibraryObjects.Reals.r ;
+    abstract_rings_Aplus_uri, HelmLibraryObjects.Reals.rplus ;
+    abstract_rings_Amult_uri, HelmLibraryObjects.Reals.rmult ;
+    abstract_rings_Aone_uri, HelmLibraryObjects.Reals.r1 ;
+    abstract_rings_Azero_uri, HelmLibraryObjects.Reals.r0 ;
+    abstract_rings_Aopp_uri, HelmLibraryObjects.Reals.ropp ;
     abstract_rings_Aeq_uri, eq ;
     abstract_rings_vm_uri, varmap ;
     abstract_rings_T_uri, t] in
@@ -353,8 +349,8 @@ let build_segments ~terms =
   let apolynomial_normalize_ok eq varmap t =
    mkConst apolynomial_normalize_ok_uri (theory_args_subst' eq varmap t) in
   let lxy_false =   (** Cic funcion "fun (x,y):R -> false" *)
-    Cic.Lambda (Cic.Anonymous, Reals.r,
-      Cic.Lambda (Cic.Anonymous, Reals.r, Datatypes.falseb))
+    Cic.Lambda (Cic.Anonymous, HelmLibraryObjects.Reals.r,
+      Cic.Lambda (Cic.Anonymous, HelmLibraryObjects.Reals.r, HelmLibraryObjects.Datatypes.falseb))
   in
   let (aterms, varmap) = abstract_poly ~terms in  (* abstract polys *)
   List.map    (* build ring segments *)
@@ -362,7 +358,7 @@ let build_segments ~terms =
      Cic.Appl [interp_ap varmap ; t],
      Cic.Appl (
        [interp_sacs varmap ; Cic.Appl [apolynomial_normalize; t]]),
-     Cic.Appl [apolynomial_normalize_ok lxy_false varmap Reals.rtheory ; t]
+     Cic.Appl [apolynomial_normalize_ok lxy_false varmap HelmLibraryObjects.Reals.rtheory ; t]
    ) aterms
 
 
@@ -370,7 +366,7 @@ let status_of_single_goal_tactic_result =
  function
     proof,[goal] -> proof,goal
   | _ ->
-    raise (Fail "status_of_single_goal_tactic_result: the tactic did not produce exactly a new goal")
+    raise (Fail (lazy "status_of_single_goal_tactic_result: the tactic did not produce exactly a new goal"))
 
 (* Galla: spostata in variousTactics.ml 
   (**
@@ -379,7 +375,7 @@ let status_of_single_goal_tactic_result =
     @param term term to cut
   *)
 let elim_type_tac ~term status =
-  warn "in Ring.elim_type_tac";
+  warn (lazy "in Ring.elim_type_tac");
   Tacticals.thens ~start:(cut_tac ~term)
    ~continuations:[elim_simpl_intros_tac ~term:(Cic.Rel 1) ; Tacticals.id_tac] status
 *)
@@ -390,12 +386,13 @@ let elim_type_tac ~term status =
     @param term term to cut
     @param proof term used to prove second subgoal generated by elim_type
   *)
+(* FG: METTERE I NOMI ANCHE QUI? *)  
 let elim_type2_tac ~term ~proof =
  let elim_type2_tac ~term ~proof status =
   let module E = EliminationTactics in
-  warn "in Ring.elim_type2";
+  warn (lazy "in Ring.elim_type2");
   ProofEngineTypes.apply_tactic 
-   (Tacticals.thens ~start:(E.elim_type_tac ~term)
+   (Tacticals.thens ~start:(E.elim_type_tac term)
     ~continuations:[Tacticals.id_tac ; exact_tac ~term:proof]) status
  in
   ProofEngineTypes.mk_tactic (elim_type2_tac ~term ~proof)
@@ -408,7 +405,7 @@ let elim_type2_tac ~term ~proof =
     @param status current proof engine status
   *)
 let reflexivity_tac (proof, goal) =
-  warn "in Ring.reflexivity_tac";
+  warn (lazy "in Ring.reflexivity_tac");
   let refl_eqt = mkCtor ~uri:refl_eqt_uri ~exp_named_subst:[] in
   try
     apply_tac (proof, goal) ~term:refl_eqt
@@ -465,17 +462,18 @@ let purge_hyps_tac ~count =
  
 let ring_tac status =
   let (proof, goal) = status in
-  warn "in Ring tactic";
-  let eqt = mkMutInd (Logic.eq_URI, 0) [] in
-  let r = Reals.r in
+  warn (lazy "in Ring tactic");
+  let eqt = mkMutInd (HelmLibraryObjects.Logic.eq_URI, 0) [] in
+  let r = HelmLibraryObjects.Reals.r in
   let metasenv = metasenv_of_status status in
   let (metano, context, ty) = CicUtil.lookup_meta goal metasenv in
   let (t1, t2) = split_eq ty in (* goal like t1 = t2 *)
   match (build_segments ~terms:[t1; t2]) with
   | (t1', t1'', t1'_eq_t1'')::(t2', t2'', t2'_eq_t2'')::[] -> begin
+     if debug then
       List.iter  (* debugging, feel free to remove *)
         (fun (descr, term) ->
-          warn (descr ^ " " ^ (CicPp.ppterm term)))
+          warn (lazy (descr ^ " " ^ (CicPp.ppterm term))))
         (List.combine
           ["t1"; "t1'"; "t1''"; "t1'_eq_t1''";
            "t2"; "t2'"; "t2''"; "t2'_eq_t2''"]
@@ -484,7 +482,7 @@ let ring_tac status =
       try
         let new_hyps = ref 0 in  (* number of new hypotheses created *)
        ProofEngineTypes.apply_tactic 
-         (Tacticals.try_tactics
+         (Tacticals.first
           ~tactics:[
             "reflexivity", EqualityTactics.reflexivity_tac ;
             "exact t1'_eq_t1''", exact_tac ~term:t1'_eq_t1'' ;
@@ -492,8 +490,8 @@ let ring_tac status =
             "exact sym_eqt su t1 ...", exact_tac
             ~term:(
               Cic.Appl
-               [mkConst Logic.sym_eq_URI
-                 [equality_is_a_congruence_A, Reals.r;
+               [mkConst HelmLibraryObjects.Logic.sym_eq_URI
+                 [equality_is_a_congruence_A, HelmLibraryObjects.Reals.r;
                   equality_is_a_congruence_x, t1'' ;
                   equality_is_a_congruence_y, t1
                  ] ;
@@ -505,7 +503,7 @@ let ring_tac status =
                let b,_ = (*TASSI : FIXME*)
                  are_convertible context t1'' t1 CicUniv.empty_ugraph in 
                 if not b then begin
-                  warn "t1'' and t1 are NOT CONVERTIBLE";
+                  warn (lazy "t1'' and t1 are NOT CONVERTIBLE");
                   let newstatus =
                    ProofEngineTypes.apply_tactic 
                     (elim_type2_tac  (* 1st elim_type use *)
@@ -518,7 +516,7 @@ let ring_tac status =
                       (proof,[goal]) -> proof,goal
                     | _ -> assert false
                 end else begin
-                  warn "t1'' and t1 are CONVERTIBLE";
+                  warn (lazy "t1'' and t1 are CONVERTIBLE");
                   status
                 end
               in
@@ -527,15 +525,15 @@ let ring_tac status =
               in
               let status'' =
               ProofEngineTypes.apply_tactic
-                (Tacticals.try_tactics (* try to solve 1st subgoal *)
+                (Tacticals.first (* try to solve 1st subgoal *)
                   ~tactics:[
                     "exact t2'_eq_t2''", exact_tac ~term:t2'_eq_t2'';
                     "exact sym_eqt su t2 ...",
                       exact_tac
                        ~term:(
                          Cic.Appl
-                          [mkConst Logic.sym_eq_URI
-                            [equality_is_a_congruence_A, Reals.r;
+                          [mkConst HelmLibraryObjects.Logic.sym_eq_URI
+                            [equality_is_a_congruence_A, HelmLibraryObjects.Reals.r;
                              equality_is_a_congruence_x, t2'' ;
                              equality_is_a_congruence_y, t2
                             ] ;
@@ -549,7 +547,7 @@ let ring_tac status =
                          are_convertible context t2'' t2 CicUniv.empty_ugraph 
                        in
                          if not b then begin 
-                          warn "t2'' and t2 are NOT CONVERTIBLE";
+                          warn (lazy "t2'' and t2 are NOT CONVERTIBLE");
                           let newstatus =
                            ProofEngineTypes.apply_tactic 
                              (elim_type2_tac  (* 2nd elim_type use *)
@@ -562,16 +560,16 @@ let ring_tac status =
                              (proof,[goal]) -> proof,goal
                            | _ -> assert false
                         end else begin
-                          warn "t2'' and t2 are CONVERTIBLE";
+                          warn (lazy "t2'' and t2 are CONVERTIBLE");
                           status
                         end
                       in
                       try (* try to solve main goal *)
-                        warn "trying reflexivity ....";
+                        warn (lazy "trying reflexivity ....");
                         ProofEngineTypes.apply_tactic 
                         EqualityTactics.reflexivity_tac status'
                       with (Fail _) ->  (* leave conclusion to the user *)
-                        warn "reflexivity failed, solution's left as an ex :-)";
+                        warn (lazy "reflexivity failed, solution's left as an ex :-)");
                         ProofEngineTypes.apply_tactic 
                         (purge_hyps_tac ~count:!new_hyps) status')])
                  status'       
@@ -579,7 +577,7 @@ let ring_tac status =
               status'')])
         status      
       with (Fail s) ->
-        raise (Fail ("Ring failure: " ^ s))
+        raise (Fail (lazy ("Ring failure: " ^ Lazy.force s)))
     end
   | _ -> (* impossible: we are applying ring exacty to 2 terms *)
     assert false
@@ -590,7 +588,7 @@ let ring_tac status =
   try
     ring_tac status
   with GoalUnringable ->
-    raise (Fail "goal unringable")
+    raise (Fail (lazy "goal unringable"))
 
 let ring_tac = ProofEngineTypes.mk_tactic ring_tac