open Utils;;
+let string_of_equality ?env =
+ match env with
+ | None -> (
+ function
+ | _, (ty, left, right), _, _ ->
+ Printf.sprintf "{%s}: %s = %s" (CicPp.ppterm ty)
+ (CicPp.ppterm left) (CicPp.ppterm right)
+ )
+ | Some (_, context, _) -> (
+ let names = names_of_context context in
+ function
+ | _, (ty, left, right), _, _ ->
+ Printf.sprintf "{%s}: %s = %s" (CicPp.pp ty names)
+ (CicPp.pp left names) (CicPp.pp right names)
+ )
+;;
+
+
+let rec metas_of_term = function
+ | Cic.Meta (i, c) -> [i]
+ | Cic.Var (_, ens)
+ | Cic.Const (_, ens)
+ | Cic.MutInd (_, _, ens)
+ | Cic.MutConstruct (_, _, _, ens) ->
+ List.flatten (List.map (fun (u, t) -> metas_of_term t) ens)
+ | Cic.Cast (s, t)
+ | Cic.Prod (_, s, t)
+ | Cic.Lambda (_, s, t)
+ | Cic.LetIn (_, s, t) -> (metas_of_term s) @ (metas_of_term t)
+ | Cic.Appl l -> List.flatten (List.map metas_of_term l)
+ | Cic.MutCase (uri, i, s, t, l) ->
+ (metas_of_term s) @ (metas_of_term t) @
+ (List.flatten (List.map metas_of_term l))
+ | Cic.Fix (i, il) ->
+ List.flatten
+ (List.map (fun (s, i, t1, t2) ->
+ (metas_of_term t1) @ (metas_of_term t2)) il)
+ | Cic.CoFix (i, il) ->
+ List.flatten
+ (List.map (fun (s, t1, t2) ->
+ (metas_of_term t1) @ (metas_of_term t2)) il)
+ | _ -> []
+;;
+
+
exception NotMetaConvertible;;
let meta_convertibility_aux table t1 t2 =
let module C = Cic in
- let rec aux table t1 t2 =
+ let print_table t =
+ String.concat ", "
+ (List.map
+ (fun (k, v) -> Printf.sprintf "(%d, %d)" k v) t)
+ in
+ let rec aux ((table_l, table_r) as table) t1 t2 =
+(* Printf.printf "aux %s, %s\ntable_l: %s, table_r: %s\n" *)
+(* (CicPp.ppterm t1) (CicPp.ppterm t2) *)
+(* (print_table table_l) (print_table table_r); *)
match t1, t2 with
- | t1, t2 when t1 = t2 -> table
| C.Meta (m1, tl1), C.Meta (m2, tl2) ->
- let m1_binding, table =
- try List.assoc m1 table, table
- with Not_found -> m2, (m1, m2)::table
+ let m1_binding, table_l =
+ try List.assoc m1 table_l, table_l
+ with Not_found -> m2, (m1, m2)::table_l
+ and m2_binding, table_r =
+ try List.assoc m2 table_r, table_r
+ with Not_found -> m1, (m2, m1)::table_r
in
- if m1_binding <> m2 then
+(* let m1_binding, m2_binding, table = *)
+(* let m1b, table = *)
+(* try List.assoc m1 table, table *)
+(* with Not_found -> m2, (m1, m2)::table *)
+(* in *)
+(* let m2b, table = *)
+(* try List.assoc m2 table, table *)
+(* with Not_found -> m1, (m2, m1)::table *)
+(* in *)
+(* m1b, m2b, table *)
+(* in *)
+(* Printf.printf "table_l: %s\ntable_r: %s\n\n" *)
+(* (print_table table_l) (print_table table_r); *)
+ if (m1_binding <> m2) || (m2_binding <> m1) then
raise NotMetaConvertible
else (
try
| None, Some _ | Some _, None -> raise NotMetaConvertible
| None, None -> res
| Some t1, Some t2 -> (aux res t1 t2))
- table tl1 tl2
+ (table_l, table_r) tl1 tl2
with Invalid_argument _ ->
raise NotMetaConvertible
)
table il1 il2
with Invalid_argument _ -> raise NotMetaConvertible
)
+ | t1, t2 when t1 = t2 -> table
| _, _ -> raise NotMetaConvertible
and aux_ens table ens1 ens2 =
and _, (ty', left', right'), _, _ = eq2 in
if ty <> ty' then
false
+ else if (left = left') && (right = right') then
+ true
+ else if (left = right') && (right = left') then
+ true
else
- let print_table t w =
- Printf.printf "table %s is:\n" w;
- List.iter
- (fun (k, v) -> Printf.printf "?%d: ?%d\n" k v)
- t;
- print_newline ();
- in
try
- let table = meta_convertibility_aux [] left left' in
-(* print_table table "before"; *)
- let table = meta_convertibility_aux table right right' in
-(* print_table table "after"; *)
+ let table = meta_convertibility_aux ([], []) left left' in
+ let _ = meta_convertibility_aux table right right' in
true
with NotMetaConvertible ->
-(* Printf.printf "NotMetaConvertible:\n%s = %s\n%s = %s\n\n" *)
-(* (CicPp.ppterm left) (CicPp.ppterm right) *)
-(* (CicPp.ppterm left') (CicPp.ppterm right'); *)
- false
+ try
+ let table = meta_convertibility_aux ([], []) left right' in
+ let _ = meta_convertibility_aux table right left' in
+ true
+ with NotMetaConvertible ->
+ false
;;
let meta_convertibility t1 t2 =
- try
- let _ = meta_convertibility_aux [] t1 t2 in
+ let f t =
+ String.concat ", "
+ (List.map
+ (fun (k, v) -> Printf.sprintf "(%d, %d)" k v) t)
+ in
+ if t1 = t2 then
true
- with NotMetaConvertible ->
- false
+ else
+ try
+ let l, r = meta_convertibility_aux ([], []) t1 t2 in
+ (* Printf.printf "meta_convertibility:\n%s\n%s\n\n" (f l) (f r); *)
+ true
+ with NotMetaConvertible ->
+ false
+;;
+
+
+let replace_metas (* context *) term =
+ let module C = Cic in
+ let rec aux = function
+ | C.Meta (i, c) ->
+(* let irl = *)
+(* CicMkImplicit.identity_relocation_list_for_metavariable context *)
+(* in *)
+(* if c = irl then *)
+(* C.Implicit (Some (`MetaIndex i)) *)
+(* else ( *)
+(* Printf.printf "WARNING: c non e` un identity_relocation_list!\n%s\n" *)
+(* (String.concat "\n" *)
+(* (List.map *)
+(* (function None -> "" | Some t -> CicPp.ppterm t) c)); *)
+(* C.Meta (i, c) *)
+(* ) *)
+ C.Implicit (Some (`MetaInfo (i, c)))
+ | C.Var (u, ens) -> C.Var (u, aux_ens ens)
+ | C.Const (u, ens) -> C.Const (u, aux_ens ens)
+ | C.Cast (s, t) -> C.Cast (aux s, aux t)
+ | C.Prod (name, s, t) -> C.Prod (name, aux s, aux t)
+ | C.Lambda (name, s, t) -> C.Lambda (name, aux s, aux t)
+ | C.LetIn (name, s, t) -> C.LetIn (name, aux s, aux t)
+ | C.Appl l -> C.Appl (List.map aux l)
+ | C.MutInd (uri, i, ens) -> C.MutInd (uri, i, aux_ens ens)
+ | C.MutConstruct (uri, i, j, ens) -> C.MutConstruct (uri, i, j, aux_ens ens)
+ | C.MutCase (uri, i, s, t, l) ->
+ C.MutCase (uri, i, aux s, aux t, List.map aux l)
+ | C.Fix (i, il) ->
+ let il' =
+ List.map (fun (s, i, t1, t2) -> (s, i, aux t1, aux t2)) il in
+ C.Fix (i, il')
+ | C.CoFix (i, il) ->
+ let il' =
+ List.map (fun (s, t1, t2) -> (s, aux t1, aux t2)) il in
+ C.CoFix (i, il')
+ | t -> t
+ and aux_ens ens =
+ List.map (fun (u, t) -> (u, aux t)) ens
+ in
+ aux term
+;;
+
+
+let restore_metas (* context *) term =
+ let module C = Cic in
+ let rec aux = function
+ | C.Implicit (Some (`MetaInfo (i, c))) ->
+(* let c = *)
+(* CicMkImplicit.identity_relocation_list_for_metavariable context *)
+(* in *)
+(* C.Meta (i, c) *)
+(* let local_context:(C.term option) list = *)
+(* Marshal.from_string mc 0 *)
+(* in *)
+(* C.Meta (i, local_context) *)
+ C.Meta (i, c)
+ | C.Var (u, ens) -> C.Var (u, aux_ens ens)
+ | C.Const (u, ens) -> C.Const (u, aux_ens ens)
+ | C.Cast (s, t) -> C.Cast (aux s, aux t)
+ | C.Prod (name, s, t) -> C.Prod (name, aux s, aux t)
+ | C.Lambda (name, s, t) -> C.Lambda (name, aux s, aux t)
+ | C.LetIn (name, s, t) -> C.LetIn (name, aux s, aux t)
+ | C.Appl l -> C.Appl (List.map aux l)
+ | C.MutInd (uri, i, ens) -> C.MutInd (uri, i, aux_ens ens)
+ | C.MutConstruct (uri, i, j, ens) -> C.MutConstruct (uri, i, j, aux_ens ens)
+ | C.MutCase (uri, i, s, t, l) ->
+ C.MutCase (uri, i, aux s, aux t, List.map aux l)
+ | C.Fix (i, il) ->
+ let il' =
+ List.map (fun (s, i, t1, t2) -> (s, i, aux t1, aux t2)) il in
+ C.Fix (i, il')
+ | C.CoFix (i, il) ->
+ let il' =
+ List.map (fun (s, t1, t2) -> (s, aux t1, aux t2)) il in
+ C.CoFix (i, il')
+ | t -> t
+ and aux_ens ens =
+ List.map (fun (u, t) -> (u, aux t)) ens
+ in
+ aux term
+;;
+
+
+let rec restore_subst (* context *) subst =
+ List.map
+ (fun (i, (c, t, ty)) ->
+ i, (c, restore_metas (* context *) t, ty))
+ subst
+;;
+
+
+exception MatchingFailure;;
+
+let matching metasenv context t1 t2 ugraph =
+ try
+ let subst, metasenv, ugraph =
+ CicUnification.fo_unif metasenv context t1 t2 ugraph
+ in
+ let t' = CicMetaSubst.apply_subst subst t1 in
+ if not (meta_convertibility t1 t') then
+ raise MatchingFailure
+ else
+ let metas = metas_of_term t1 in
+ let fix_subst = function
+ | (i, (c, Cic.Meta (j, lc), ty)) when List.mem i metas ->
+ (j, (c, Cic.Meta (i, lc), ty))
+ | s -> s
+ in
+ let subst = List.map fix_subst subst in
+ subst, metasenv, ugraph
+ with e ->
+ raise MatchingFailure
;;
what type_of_what where context metasenv ugraph =
let module S = CicSubstitution in
let module C = Cic in
+
+ let print_info = false in
+
+(* let _ = *)
+(* let names = names_of_context context in *)
+(* Printf.printf "beta_expand:\nwhat: %s, %s\nwhere: %s, %s\n" *)
+(* (CicPp.pp what names) (CicPp.ppterm what) *)
+(* (CicPp.pp where names) (CicPp.ppterm where); *)
+(* print_newline (); *)
+(* in *)
(*
return value:
((list of all possible beta expansions, subst, metasenv, ugraph),
| C.Meta _ when (not metas_ok) ->
res, lifted_term
| _ ->
+(* let term' = *)
+(* if match_only then replace_metas context term *)
+(* else term *)
+(* in *)
try
let subst', metasenv', ugraph' =
- CicUnification.fo_unif metasenv context
- (S.lift lift_amount what) term ugraph
+(* Printf.printf "provo a unificare %s e %s\n" *)
+(* (CicPp.ppterm (S.lift lift_amount what)) (CicPp.ppterm term); *)
+ if match_only then
+ matching metasenv context term (S.lift lift_amount what)ugraph
+ else
+ CicUnification.fo_unif metasenv context
+ (S.lift lift_amount what) term ugraph
in
- (* Printf.printf "Ok, trovato: %s\n\nwhat: %s" (CicPp.ppterm term) *)
- (* (CicPp.ppterm (S.lift lift_amount what)); *)
- (* Printf.printf "substitution:\n%s\n\n" (print_subst subst'); *)
- (* Printf.printf "metasenv': %s\n" (print_metasenv metasenv'); *)
+(* Printf.printf "Ok, trovato: %s\n\nwhat: %s" (CicPp.ppterm term) *)
+(* (CicPp.ppterm (S.lift lift_amount what)); *)
+(* Printf.printf "substitution:\n%s\n\n" (print_subst subst'); *)
+(* Printf.printf "metasenv': %s\n" (print_metasenv metasenv'); *)
(* Printf.printf "metasenv: %s\n\n" (print_metasenv metasenv); *)
- let term' = CicMetaSubst.apply_subst subst' term in (
- if match_only && not (meta_convertibility term term') then (
-(* Printf.printf "term e term' sono diversi!:\n%s\n%s\n\n" *)
-(* (CicPp.ppterm term) (CicPp.ppterm term'); *)
- res, lifted_term
- )
- else
-(* let _ = *)
-(* if match_only then *)
-(* Printf.printf "OK, trovato match con %s\n" *)
-(* (CicPp.ppterm term) *)
+(* if match_only then *)
+(* let t' = CicMetaSubst.apply_subst subst' term in *)
+(* if not (meta_convertibility term t') then ( *)
+(* res, lifted_term *)
+(* ) else ( *)
+(* let metas = metas_of_term term in *)
+(* let fix_subst = function *)
+(* | (i, (c, C.Meta (j, lc), ty)) when List.mem i metas -> *)
+(* (j, (c, C.Meta (i, lc), ty)) *)
+(* | s -> s *)
(* in *)
- ((C.Rel (1 + lift_amount), subst', metasenv', ugraph')::res,
- lifted_term)
- )
- with _ ->
+(* let subst' = List.map fix_subst subst' in *)
+(* ((C.Rel (1 + lift_amount), subst', metasenv', ugraph')::res, *)
+(* lifted_term) *)
+(* ) *)
+(* else *)
+ ((C.Rel (1 + lift_amount), subst', metasenv', ugraph')::res,
+ lifted_term)
+ with e ->
+ if print_info then (
+ print_endline ("beta_expand ERROR!: " ^ (Printexc.to_string e));
+ );
res, lifted_term
in
(* Printf.printf "exit aux\n"; *)
) exp_named_subst ([], [])
in
- let expansions, _ = aux 0 where context metasenv [] ugraph in
- List.map
- (fun (term, subst, metasenv, ugraph) ->
- let term' = C.Lambda (C.Anonymous, type_of_what, term) in
-(* Printf.printf "term is: %s\nsubst is:\n%s\n\n" *)
-(* (CicPp.ppterm term') (print_subst subst); *)
- (term', subst, metasenv, ugraph))
- expansions
+ let expansions, _ =
+(* let where = *)
+(* if match_only then replace_metas (\* context *\) where *)
+(* else where *)
+(* in *)
+ if print_info then (
+ Printf.printf "searching %s inside %s\n"
+ (CicPp.ppterm what) (CicPp.ppterm where);
+ );
+ aux 0 where context metasenv [] ugraph
+ in
+ let mapfun =
+(* if match_only then *)
+(* (fun (term, subst, metasenv, ugraph) -> *)
+(* let term' = *)
+(* C.Lambda (C.Anonymous, type_of_what, restore_metas term) *)
+(* and subst = restore_subst subst in *)
+(* (term', subst, metasenv, ugraph)) *)
+(* else *)
+ (fun (term, subst, metasenv, ugraph) ->
+ let term' = C.Lambda (C.Anonymous, type_of_what, term) in
+ (term', subst, metasenv, ugraph))
+ in
+ List.map mapfun expansions
;;
let fix_metas newmeta ((proof, (ty, left, right), menv, args) as equality) =
+ let table = Hashtbl.create (List.length args) in
let newargs, _ =
List.fold_right
(fun t (newargs, index) ->
match t with
- | Cic.Meta (i, l) -> ((Cic.Meta (index, l))::newargs, index+1)
+ | Cic.Meta (i, l) ->
+ Hashtbl.add table i index;
+ ((Cic.Meta (index, l))::newargs, index+1)
| _ -> assert false)
args ([], newmeta)
in
ProofEngineReduction.replace ~equality:(=) ~what:args ~with_what:newargs
~where
in
- let menv', _ =
+ let menv' =
List.fold_right
- (fun (i, context, term) (menv, index) ->
- ((index, context, term)::menv, index+1))
- menv ([], newmeta)
+ (fun (i, context, term) menv ->
+ try
+ let index = Hashtbl.find table i in
+ (index, context, term)::menv
+ with Not_found ->
+ (i, context, term)::menv)
+ menv []
+ in
+ let ty = repl ty
+ and left = repl left
+ and right = repl right in
+ let metas = (metas_of_term left) @ (metas_of_term right) in
+ let menv' = List.filter (fun (i, _, _) -> List.mem i metas) menv'
+ and newargs =
+ List.filter
+ (function Cic.Meta (i, _) -> List.mem i metas | _ -> assert false) newargs
in
(newmeta + (List.length newargs) + 1,
- (repl proof, (repl ty, repl left, repl right), menv', newargs))
+ (repl proof, (ty, left, right), menv', newargs))
;;
let proof, (eq_ty, left, right), _, _ = target in
let eqproof, (ty, t1, t2), newmetas, args = source in
- (* ALB: TODO check that ty and eq_ty are indeed equal... *)
- assert (eq_ty = ty);
-
- let where, is_left =
- match nonrec_kbo left right with
- | Lt -> right, false
- | Gt -> left, true
- | _ -> (
- Printf.printf "????????? %s = %s" (CicPp.ppterm left)
- (CicPp.ppterm right);
- print_newline ();
- assert false (* again, for ground terms this shouldn't happen... *)
- )
- in
- let metasenv' = newmetas @ metasenv in
- let res1 =
- List.filter
- (fun (t, s, m, ug) ->
- nonrec_kbo (M.apply_subst s t1) (M.apply_subst s t2) = Gt)
- (beta_expand t1 ty where context metasenv' ugraph)
- and res2 =
- List.filter
- (fun (t, s, m, ug) ->
- nonrec_kbo (M.apply_subst s t2) (M.apply_subst s t1) = Gt)
- (beta_expand t2 ty where context metasenv' ugraph)
- in
-(* let what, other = *)
-(* if is_left then left, right *)
-(* else right, left *)
-(* in *)
- let build_new what other eq_URI (t, s, m, ug) =
- let newgoal, newgoalproof =
- match t with
- | C.Lambda (nn, ty, bo) ->
- let bo' = S.subst (M.apply_subst s other) bo in
- let bo'' =
- C.Appl (
- [C.MutInd (HL.Logic.eq_URI, 0, []);
- S.lift 1 eq_ty] @
- if is_left then [bo'; S.lift 1 right] else [S.lift 1 left; bo'])
+ let compare_terms = !Utils.compare_terms in
+
+ if eq_ty <> ty then
+ []
+ else
+ let where, is_left =
+ match compare_terms left right with
+ | Lt -> right, false
+ | Gt -> left, true
+ | _ -> (
+ Printf.printf "????????? %s = %s" (CicPp.ppterm left)
+ (CicPp.ppterm right);
+ print_newline ();
+ assert false (* again, for ground terms this shouldn't happen... *)
+ )
+ in
+ let metasenv' = newmetas @ metasenv in
+ let result = compare_terms t1 t2 in
+ let res1, res2 =
+ match result with
+ | Gt -> (beta_expand t1 ty where context metasenv' ugraph), []
+ | Lt -> [], (beta_expand t2 ty where context metasenv' ugraph)
+ | _ ->
+ let res1 =
+ List.filter
+ (fun (t, s, m, ug) ->
+ compare_terms (M.apply_subst s t1) (M.apply_subst s t2) = Gt)
+ (beta_expand t1 ty where context metasenv' ugraph)
+ and res2 =
+ List.filter
+ (fun (t, s, m, ug) ->
+ compare_terms (M.apply_subst s t2) (M.apply_subst s t1) = Gt)
+ (beta_expand t2 ty where context metasenv' ugraph)
in
- let t' = C.Lambda (nn, ty, bo'') in
- S.subst (M.apply_subst s other) bo,
- M.apply_subst s
- (C.Appl [C.Const (eq_URI, []); ty; what; t';
- proof; other; eqproof])
- | _ -> assert false
+ res1, res2
in
- let equation =
- if is_left then (eq_ty, newgoal, right)
- else (eq_ty, left, newgoal)
+ (* let what, other = *)
+ (* if is_left then left, right *)
+ (* else right, left *)
+ (* in *)
+ let build_new what other eq_URI (t, s, m, ug) =
+ let newgoal, newgoalproof =
+ match t with
+ | C.Lambda (nn, ty, bo) ->
+ let bo' = S.subst (M.apply_subst s other) bo in
+ let bo'' =
+ C.Appl (
+ [C.MutInd (HL.Logic.eq_URI, 0, []);
+ S.lift 1 eq_ty] @
+ if is_left then [bo'; S.lift 1 right]
+ else [S.lift 1 left; bo'])
+ in
+ let t' = C.Lambda (nn, ty, bo'') in
+ S.subst (M.apply_subst s other) bo,
+ M.apply_subst s
+ (C.Appl [C.Const (eq_URI, []); ty; what; t';
+ proof; other; eqproof])
+ | _ -> assert false
+ in
+ let equation =
+ if is_left then (eq_ty, newgoal, right)
+ else (eq_ty, left, newgoal)
+ in
+ (eqproof, equation, [], [])
in
- (eqproof, equation, [], [])
- in
- let new1 = List.map (build_new t1 t2 HL.Logic.eq_ind_URI) res1
- and new2 = List.map (build_new t2 t1 HL.Logic.eq_ind_r_URI) res2 in
- new1 @ new2
+ let new1 = List.map (build_new t1 t2 HL.Logic.eq_ind_URI) res1
+ and new2 = List.map (build_new t2 t1 HL.Logic.eq_ind_r_URI) res2 in
+ new1 @ new2
;;
let eqp', (ty', t1, t2), newm', args' = source in
let maxmeta = ref newmeta in
- (* TODO check if ty and ty' are equal... *)
- assert (eq_ty = ty');
-
-(* let ok term subst other other_eq_side ugraph = *)
-(* match term with *)
-(* | C.Lambda (nn, ty, bo) -> *)
-(* let bo' = S.subst (M.apply_subst subst other) bo in *)
-(* let res, _ = CR.are_convertible context bo' other_eq_side ugraph in *)
-(* not res *)
-(* | _ -> assert false *)
-(* in *)
- let condition left right what other (t, s, m, ug) =
- let subst = M.apply_subst s in
- let cmp1 = nonrec_kbo (subst what) (subst other) in
- let cmp2 = nonrec_kbo (subst left) (subst right) in
-(* cmp1 = Gt && cmp2 = Gt *)
- cmp1 <> Lt && cmp1 <> Le && cmp2 <> Lt && cmp2 <> Le
-(* && (ok t s other right ug) *)
- in
- let metasenv' = metasenv @ newmetas @ newm' in
- let beta_expand = beta_expand ~metas_ok:false in
- let res1 =
- List.filter
- (condition left right t1 t2)
- (beta_expand t1 eq_ty left context metasenv' ugraph)
- and res2 =
- List.filter
- (condition left right t2 t1)
- (beta_expand t2 eq_ty left context metasenv' ugraph)
- and res3 =
- List.filter
- (condition right left t1 t2)
- (beta_expand t1 eq_ty right context metasenv' ugraph)
- and res4 =
- List.filter
- (condition right left t2 t1)
- (beta_expand t2 eq_ty right context metasenv' ugraph)
- in
- let newmetas = newmetas @ newm' in
- let newargs = args @ args' in
- let build_new what other is_left eq_URI (t, s, m, ug) =
-(* let what, other = *)
-(* if is_left then left, right *)
-(* else right, left *)
-(* in *)
- let newterm, neweqproof =
- match t with
- | C.Lambda (nn, ty, bo) ->
- let bo' = M.apply_subst s (S.subst other bo) in
- let bo'' =
- C.Appl (
- [C.MutInd (HL.Logic.eq_URI, 0, []); S.lift 1 eq_ty] @
- if is_left then [bo'; S.lift 1 right] else [S.lift 1 left; bo'])
- in
- let t' = C.Lambda (nn, ty, bo'') in
- bo',
- M.apply_subst s
- (C.Appl [C.Const (eq_URI, []); ty; what; t'; eqproof; other; eqp'])
- | _ -> assert false
+ let compare_terms = !Utils.compare_terms in
+
+ if eq_ty <> ty' then
+ newmeta, []
+ else
+ (* let ok term subst other other_eq_side ugraph = *)
+ (* match term with *)
+ (* | C.Lambda (nn, ty, bo) -> *)
+ (* let bo' = S.subst (M.apply_subst subst other) bo in *)
+ (* let res, _ = CR.are_convertible context bo' other_eq_side ugraph in *)
+ (* not res *)
+ (* | _ -> assert false *)
+ (* in *)
+ let condition left right what other (t, s, m, ug) =
+ let subst = M.apply_subst s in
+ let cmp1 = compare_terms (subst what) (subst other) in
+ let cmp2 = compare_terms (subst left) (subst right) in
+ (* cmp1 = Gt && cmp2 = Gt *)
+ cmp1 <> Lt && cmp1 <> Le && cmp2 <> Lt && cmp2 <> Le
+ (* && (ok t s other right ug) *)
in
- let newmeta, newequality =
- let left, right =
- if is_left then (newterm, M.apply_subst s right)
- else (M.apply_subst s left, newterm) in
- fix_metas !maxmeta
- (neweqproof, (eq_ty, left, right), newmetas, newargs)
+ let metasenv' = metasenv @ newmetas @ newm' in
+ let beta_expand = beta_expand ~metas_ok:false in
+ let cmp1 = compare_terms left right
+ and cmp2 = compare_terms t1 t2 in
+ let res1, res2, res3, res4 =
+ let res l r s t =
+ List.filter
+ (condition l r s t)
+ (beta_expand s eq_ty l context metasenv' ugraph)
+ in
+ match cmp1, cmp2 with
+ | Gt, Gt ->
+ (beta_expand t1 eq_ty left context metasenv' ugraph), [], [], []
+ | Gt, Lt ->
+ [], (beta_expand t2 eq_ty left context metasenv' ugraph), [], []
+ | Lt, Gt ->
+ [], [], (beta_expand t1 eq_ty right context metasenv' ugraph), []
+ | Lt, Lt ->
+ [], [], [], (beta_expand t2 eq_ty right context metasenv' ugraph)
+ | Gt, _ ->
+ let res1 = res left right t1 t2
+ and res2 = res left right t2 t1 in
+ res1, res2, [], []
+ | Lt, _ ->
+ let res3 = res right left t1 t2
+ and res4 = res right left t2 t1 in
+ [], [], res3, res4
+ | _, Gt ->
+ let res1 = res left right t1 t2
+ and res3 = res right left t1 t2 in
+ res1, [], res3, []
+ | _, Lt ->
+ let res2 = res left right t2 t1
+ and res4 = res right left t2 t1 in
+ [], res2, [], res4
+ | _, _ ->
+ let res1 = res left right t1 t2
+ and res2 = res left right t2 t1
+ and res3 = res right left t1 t2
+ and res4 = res right left t2 t1 in
+ res1, res2, res3, res4
in
- maxmeta := newmeta;
- newequality
- in
- let new1 = List.map (build_new t1 t2 true HL.Logic.eq_ind_URI) res1
- and new2 = List.map (build_new t2 t1 true HL.Logic.eq_ind_r_URI) res2
- and new3 = List.map (build_new t1 t2 false HL.Logic.eq_ind_URI) res3
- and new4 = List.map (build_new t2 t1 false HL.Logic.eq_ind_r_URI) res4 in
- let ok = function
- | _, (_, left, right), _, _ ->
- not (fst (CR.are_convertible context left right ugraph))
- in
- !maxmeta, (List.filter ok (new1 @ new2 @ new3 @ new4))
+ let newmetas = newmetas @ newm' in
+ let newargs = args @ args' in
+ let build_new what other is_left eq_URI (t, s, m, ug) =
+ (* let what, other = *)
+ (* if is_left then left, right *)
+ (* else right, left *)
+ (* in *)
+ let newterm, neweqproof =
+ match t with
+ | C.Lambda (nn, ty, bo) ->
+ let bo' = M.apply_subst s (S.subst other bo) in
+ let bo'' =
+ C.Appl (
+ [C.MutInd (HL.Logic.eq_URI, 0, []); S.lift 1 eq_ty] @
+ if is_left then [bo'; S.lift 1 right]
+ else [S.lift 1 left; bo'])
+ in
+ let t' = C.Lambda (nn, ty, bo'') in
+ bo',
+ M.apply_subst s
+ (C.Appl [C.Const (eq_URI, []); ty; what; t';
+ eqproof; other; eqp'])
+ | _ -> assert false
+ in
+ let newmeta, newequality =
+ let left, right =
+ if is_left then (newterm, M.apply_subst s right)
+ else (M.apply_subst s left, newterm) in
+ fix_metas !maxmeta
+ (neweqproof, (eq_ty, left, right), newmetas, newargs)
+ in
+ maxmeta := newmeta;
+ newequality
+ in
+ let new1 = List.map (build_new t1 t2 true HL.Logic.eq_ind_URI) res1
+ and new2 = List.map (build_new t2 t1 true HL.Logic.eq_ind_r_URI) res2
+ and new3 = List.map (build_new t1 t2 false HL.Logic.eq_ind_URI) res3
+ and new4 = List.map (build_new t2 t1 false HL.Logic.eq_ind_r_URI) res4 in
+ let ok = function
+ | _, (_, left, right), _, _ ->
+ not (fst (CR.are_convertible context left right ugraph))
+ in
+ !maxmeta, (List.filter ok (new1 @ new2 @ new3 @ new4))
+;;
+
+
+let is_identity ((_, context, ugraph) as env) = function
+ | ((_, (ty, left, right), _, _) as equality) ->
+ let res =
+ (left = right ||
+ (fst (CicReduction.are_convertible context left right ugraph)))
+ in
+(* if res then ( *)
+(* Printf.printf "is_identity: %s" (string_of_equality ~env equality); *)
+(* print_newline (); *)
+(* ); *)
+ res
;;
let proof, (eq_ty, left, right), metas, args = target
and proof', (ty, t1, t2), metas', args' = source in
+
+ let compare_terms = !Utils.compare_terms in
+
if eq_ty <> ty then
newmeta, target
else
- let get_params step =
- match step with
- | 3 -> true, t1, t2, HL.Logic.eq_ind_URI
- | 2 -> false, t1, t2, HL.Logic.eq_ind_URI
- | 1 -> true, t2, t1, HL.Logic.eq_ind_r_URI
- | 0 -> false, t2, t1, HL.Logic.eq_ind_r_URI
- | _ -> assert false
+ let first_step, get_params =
+ match compare_terms t1 t2 with
+ | Gt -> 1, (function
+ | 1 -> true, t1, t2, HL.Logic.eq_ind_URI
+ | 0 -> false, t1, t2, HL.Logic.eq_ind_URI
+ | _ -> assert false)
+ | Lt -> 1, (function
+ | 1 -> true, t2, t1, HL.Logic.eq_ind_r_URI
+ | 0 -> false, t2, t1, HL.Logic.eq_ind_r_URI
+ | _ -> assert false)
+ | _ ->
+ let first_step = 3 in
+ let get_params step =
+ match step with
+ | 3 -> true, t1, t2, HL.Logic.eq_ind_URI
+ | 2 -> false, t1, t2, HL.Logic.eq_ind_URI
+ | 1 -> true, t2, t1, HL.Logic.eq_ind_r_URI
+ | 0 -> false, t2, t1, HL.Logic.eq_ind_r_URI
+ | _ -> assert false
+ in
+ first_step, get_params
in
let rec demodulate newmeta step metasenv target =
let proof, (eq_ty, left, right), metas, args = target in
let is_left, what, other, eq_URI = get_params step in
+
+ let env = metasenv, context, ugraph in
+ let names = names_of_context context in
(* Printf.printf *)
-(* "demodulate\ntarget: %s = %s\nwhat: %s\nother: %s\nis_left: %s\n" *)
-(* (CicPp.ppterm left) (CicPp.ppterm right) (CicPp.ppterm what) *)
-(* (CicPp.ppterm other) (string_of_bool is_left); *)
-(* Printf.printf "step: %d\n" step; *)
+(* "demodulate\ntarget: %s\nwhat: %s\nother: %s\nis_left: %s\n" *)
+(* (string_of_equality ~env target) (CicPp.pp what names) *)
+(* (CicPp.pp other names) (string_of_bool is_left); *)
+(* Printf.printf "step: %d" step; *)
(* print_newline (); *)
+
let ok (t, s, m, ug) =
- nonrec_kbo (M.apply_subst s what) (M.apply_subst s other) = Gt
+ compare_terms (M.apply_subst s what) (M.apply_subst s other) = Gt
in
let res =
- List.filter ok
- (beta_expand ~metas_ok:false ~match_only:true
- what ty left context (metasenv @ metas) ugraph)
+ let r = (beta_expand ~metas_ok:false ~match_only:true
+ what ty (if is_left then left else right)
+ context (metasenv @ metas) ugraph)
+ in
+(* let m' = metas_of_term what *)
+(* and m'' = metas_of_term (if is_left then left else right) in *)
+(* if (List.mem 527 m'') && (List.mem 6 m') then ( *)
+(* Printf.printf *)
+(* "demodulate\ntarget: %s\nwhat: %s\nother: %s\nis_left: %s\n" *)
+(* (string_of_equality ~env target) (CicPp.pp what names) *)
+(* (CicPp.pp other names) (string_of_bool is_left); *)
+(* Printf.printf "step: %d" step; *)
+(* print_newline (); *)
+(* print_endline "res:"; *)
+(* List.iter (fun (t, s, m, ug) -> print_endline (CicPp.pp t names)) r; *)
+(* print_newline (); *)
+(* Printf.printf "metasenv:\n%s\n" (print_metasenv (metasenv @ metas)); *)
+(* print_newline (); *)
+(* ); *)
+ List.filter ok r
in
match res with
| [] ->
let newterm, newproof =
match t with
| C.Lambda (nn, ty, bo) ->
- let bo' = M.apply_subst s (S.subst other bo) in
+(* let bo' = M.apply_subst s (S.subst other bo) in *)
+ let bo' = S.subst (M.apply_subst s other) bo in
let bo'' =
C.Appl (
[C.MutInd (HL.Logic.eq_URI, 0, []);
else [S.lift 1 left; bo'])
in
let t' = C.Lambda (nn, ty, bo'') in
- M.apply_subst s (S.subst other bo),
+(* M.apply_subst s (S.subst other bo), *)
+ bo',
M.apply_subst s
(C.Appl [C.Const (eq_URI, []); ty; what; t';
proof; other; proof'])
in
let newmeta, newtarget =
let left, right =
- if is_left then (newterm, M.apply_subst s right)
- else (M.apply_subst s left, newterm) in
- let newmetasenv = metasenv @ metas in
- let newargs = args @ args' in
- fix_metas newmeta
- (newproof, (eq_ty, left, right), newmetasenv, newargs)
+(* if is_left then (newterm, M.apply_subst s right) *)
+(* else (M.apply_subst s left, newterm) in *)
+ if is_left then newterm, right
+ else left, newterm
+ in
+(* let newmetasenv = metasenv @ metas in *)
+(* let newargs = args @ args' in *)
+(* fix_metas newmeta *)
+(* (newproof, (eq_ty, left, right), newmetasenv, newargs) *)
+ let m = (metas_of_term left) @ (metas_of_term right) in
+ let newmetasenv = List.filter (fun (i, _, _) -> List.mem i m) metas
+ and newargs =
+ List.filter
+ (function C.Meta (i, _) -> List.mem i m | _ -> assert false)
+ args
+ in
+ newmeta, (newproof, (eq_ty, left, right), newmetasenv, newargs)
in
- let _, (_, left, right), _, _ = newtarget
- and _, (_, oldleft, oldright), _, _ = target in
(* Printf.printf *)
-(* "demodulate, newtarget: %s = %s\ntarget was: %s = %s\n" *)
-(* (CicPp.ppterm left) (CicPp.ppterm right) *)
-(* (CicPp.ppterm oldleft) (CicPp.ppterm oldright); *)
+(* "demodulate, newtarget: %s\ntarget was: %s\n" *)
+(* (string_of_equality ~env newtarget) *)
+(* (string_of_equality ~env target); *)
+(* (\* let _, _, newm, newa = newtarget in *\) *)
+(* (\* Printf.printf "newmetasenv:\n%s\nnewargs:\n%s\n" *\) *)
+(* (\* (print_metasenv newm) *\) *)
+(* (\* (String.concat "\n" (List.map CicPp.ppterm newa)); *\) *)
(* print_newline (); *)
- demodulate newmeta step metasenv newtarget
+ if is_identity env newtarget then
+ newmeta, newtarget
+ else
+ demodulate newmeta first_step metasenv newtarget
in
- demodulate newmeta 3 (metasenv @ metas') target
+ demodulate newmeta first_step (metasenv @ metas') target
;;
*)
+let subsumption env target source =
+ let _, (ty, tl, tr), tmetas, _ = target
+ and _, (ty', sl, sr), smetas, _ = source in
+ if ty <> ty' then
+ false
+ else
+ let metasenv, context, ugraph = env in
+ let metasenv = metasenv @ tmetas @ smetas in
+ let names = names_of_context context in
+ let samesubst subst subst' =
+(* Printf.printf "samesubst:\nsubst: %s\nsubst': %s\n" *)
+(* (print_subst subst) (print_subst subst'); *)
+(* print_newline (); *)
+ let tbl = Hashtbl.create (List.length subst) in
+ List.iter (fun (m, (c, t1, t2)) -> Hashtbl.add tbl m (c, t1, t2)) subst;
+ List.for_all
+ (fun (m, (c, t1, t2)) ->
+ try
+ let c', t1', t2' = Hashtbl.find tbl m in
+ if (c = c') && (t1 = t1') && (t2 = t2') then true
+ else false
+ with Not_found ->
+ true)
+ subst'
+ in
+ let subsaux left right left' right' =
+ try
+ let subst, menv, ug = matching metasenv context left left' ugraph
+ and subst', menv', ug' = matching metasenv context right right' ugraph
+ in
+(* Printf.printf "left = right: %s = %s\n" *)
+(* (CicPp.pp left names) (CicPp.pp right names); *)
+(* Printf.printf "left' = right': %s = %s\n" *)
+(* (CicPp.pp left' names) (CicPp.pp right' names); *)
+ samesubst subst subst'
+ with e ->
+(* print_endline (Printexc.to_string e); *)
+ false
+ in
+ let res =
+ if subsaux tl tr sl sr then true
+ else subsaux tl tr sr sl
+ in
+ if res then (
+ Printf.printf "subsumption!:\ntarget: %s\nsource: %s\n"
+ (string_of_equality ~env target) (string_of_equality ~env source);
+ print_newline ();
+ );
+ res
+;;