-let rec count_prods context ty =
- match CicReduction.whd context ty with
- Cic.Prod (n,s,t) -> 1 + count_prods (Some (n,Cic.Decl s)::context) t
+let rec count_prods subst context ty =
+ match CicReduction.whd ~subst context ty with
+ Cic.Prod (n,s,t) -> 1 + count_prods subst (Some (n,Cic.Decl s)::context) t
(* Assumption: The term "term" must be closed in the current context *)
let module T = CicTypeChecker in
let module R = CicReduction in
let module C = Cic in
(* Assumption: The term "term" must be closed in the current context *)
let module T = CicTypeChecker in
let module R = CicReduction in
let module C = Cic in
- let (_,metasenv,_subst,_,_, _) = proof in
+ let (_,metasenv,subst,_,_, _) = proof in
let metano,context,ty = CicUtil.lookup_meta goal metasenv in
let newmeta = max (CicMkImplicit.new_meta metasenv subst) maxmeta in
let exp_named_subst_diff,newmeta',newmetasenvfragment,term' =
let metano,context,ty = CicUtil.lookup_meta goal metasenv in
let newmeta = max (CicMkImplicit.new_meta metasenv subst) maxmeta in
let exp_named_subst_diff,newmeta',newmetasenvfragment,term' =
let subst,newmetasenv',t =
let rec add_one_argument n =
try
let subst,newmetasenv',t =
let rec add_one_argument n =
try
newmetasenv''
in
let subst = ((metano,(context,bo',ty))::subst) in
newmetasenv''
in
let subst = ((metano,(context,bo',ty))::subst) in
subst,
(newproof, List.map (function (i,_,_) -> i) new_uninstantiatedmetas),
max maxmeta (CicMkImplicit.new_meta newmetasenv''' subst)
subst,
(newproof, List.map (function (i,_,_) -> i) new_uninstantiatedmetas),
max maxmeta (CicMkImplicit.new_meta newmetasenv''' subst)
-(* apply_tac_verbose ~term status *)
- apply_with_subst ~term ~subst ~maxmeta status
- (* TODO cacciare anche altre eccezioni? *)
+ let status =
+ if subst <> [] then
+ let (u,m,_,p,t,l), g = status in (u,m,subst,p,t,l), g
+ else status
+ in
+ apply_with_subst ~term ~maxmeta status
with
| CicUnification.UnificationFailure msg
| CicTypeChecker.TypeCheckerFailure msg -> raise (PET.Fail msg)
with
| CicUnification.UnificationFailure msg
| CicTypeChecker.TypeCheckerFailure msg -> raise (PET.Fail msg)
let instantiated_eliminator =
let f n = if n = 1 then arg else C.Implicit None in
C.Appl (using :: args_init args_no f)
let instantiated_eliminator =
let f n = if n = 1 then arg else C.Implicit None in
C.Appl (using :: args_init args_no f)
- let rec mk_pred metasenv context' pred arg' cpattern' = function
- | [] -> metasenv, pred, arg'
+ let rec mk_pred metasenv subst context' pred arg' cpattern' = function
+ | [] -> metasenv, subst, pred, arg'
- let argty, _ugraph = TC.type_of_aux' metasenv context arg ugraph in
- let argty = CicReduction.whd context argty in
+ let argty, _ = TC.type_of_aux' metasenv ~subst context arg ugraph in
+ let argty = CicReduction.whd ~subst context argty in
let hyp = Some (fresh_name, C.Decl argty) in
let lazy_term c m u =
let distance = List.length c - List.length context in
S.lift distance arg, m, u in
let pattern = Some lazy_term, [], Some cpattern' in
let subst, metasenv, _ugraph, _conjecture, selected_terms =
let hyp = Some (fresh_name, C.Decl argty) in
let lazy_term c m u =
let distance = List.length c - List.length context in
S.lift distance arg, m, u in
let pattern = Some lazy_term, [], Some cpattern' in
let subst, metasenv, _ugraph, _conjecture, selected_terms =
~conjecture:(0, context, pred) ~pattern in
let metasenv = MS.apply_subst_metasenv subst metasenv in
let map (_context_of_t, t) l = t :: l in
let what = List.fold_right map selected_terms [] in
let arg' = MS.apply_subst subst arg' in
~conjecture:(0, context, pred) ~pattern in
let metasenv = MS.apply_subst_metasenv subst metasenv in
let map (_context_of_t, t) l = t :: l in
let what = List.fold_right map selected_terms [] in
let arg' = MS.apply_subst subst arg' in
let pred = PER.replace_with_rel_1_from ~equality:(==) ~what 1 pred in
let pred = MS.apply_subst subst pred in
let pred = PER.replace_with_rel_1_from ~equality:(==) ~what 1 pred in
let pred = MS.apply_subst subst pred in
- let metasenv, pred, arg =
- mk_pred metasenv context goal arg cpattern (List.rev actual_args)
+ let metasenv, subst, pred, arg =
+ mk_pred metasenv subst context goal arg cpattern (List.rev actual_args)
- metasenv, pred, arg, actual_args
+ metasenv, subst, pred, arg, actual_args
let (proof, goal) = status in
let module C = Cic in
let module T = Tacticals in
let (proof, goal) = status in
let module C = Cic in
let module T = Tacticals in
- let uri,metasenv,_subst,pbo,pty, attrs = proof in
+ let uri,metasenv,subst,pbo,pty, attrs = proof in
let (_,context,ty) as conjecture = CicUtil.lookup_meta goal metasenv in
let subst,metasenv,u,selected_hyps,terms_with_context =
let (_,context,ty) as conjecture = CicUtil.lookup_meta goal metasenv in
let subst,metasenv,u,selected_hyps,terms_with_context =
~conjecture ~pattern in
let context = CicMetaSubst.apply_subst_context subst context in
let metasenv = CicMetaSubst.apply_subst_metasenv subst metasenv in
~conjecture ~pattern in
let context = CicMetaSubst.apply_subst_context subst context in
let metasenv = CicMetaSubst.apply_subst_metasenv subst metasenv in
context_of_t, t context_of_t metasenv u
| (context_of_t, t)::_, None -> context_of_t, (t, metasenv, u)
in
context_of_t, t context_of_t metasenv u
| (context_of_t, t)::_, None -> context_of_t, (t, metasenv, u)
in
in
(*CSC: I am not sure about the following two assertions;
maybe I need to propagate the new subst and metasenv *)
in
(*CSC: I am not sure about the following two assertions;
maybe I need to propagate the new subst and metasenv *)
assert (metasenv' = metasenv);
let typ,u = CicTypeChecker.type_of_aux' ~subst metasenv context t u in
u,typ,t,metasenv
assert (metasenv' = metasenv);
let typ,u = CicTypeChecker.type_of_aux' ~subst metasenv context t u in
u,typ,t,metasenv
- let status = (uri,metasenv',_subst,pbo,pty, attrs),goal in
+ let status = (uri,metasenv',subst,pbo,pty, attrs),goal in
- let _,metasenv'',_subst,_,_, _ = proof in
+ let _,metasenv'',_,_,_, _ = proof in
let elim_tac ?using ?(pattern = PET.conclusion_pattern None) term =
let elim_tac pattern (proof, goal) =
let ugraph = CicUniv.oblivion_ugraph in
let elim_tac ?using ?(pattern = PET.conclusion_pattern None) term =
let elim_tac pattern (proof, goal) =
let ugraph = CicUniv.oblivion_ugraph in
- let curi, metasenv, _subst, proofbo, proofty, attrs = proof in
+ let curi, metasenv, subst, proofbo, proofty, attrs = proof in
let conjecture = CicUtil.lookup_meta goal metasenv in
let metano, context, ty = conjecture in
let pattern = pattern_after_generalize_pattern_tac pattern in
let conjecture = CicUtil.lookup_meta goal metasenv in
let metano, context, ty = conjecture in
let pattern = pattern_after_generalize_pattern_tac pattern in
match pattern with
| None, [], Some cpattern -> cpattern
| _ -> raise (PET.Fail (lazy "not implemented")) in
match pattern with
| None, [], Some cpattern -> cpattern
| _ -> raise (PET.Fail (lazy "not implemented")) in
- let termty,_ugraph = TC.type_of_aux' metasenv context term ugraph in
- let termty = CicReduction.whd context termty in
+ let termty,_ugraph = TC.type_of_aux' metasenv ~subst context term ugraph in
+ let termty = CicReduction.whd ~subst context termty in
let termty, metasenv', arguments, _fresh_meta =
TermUtil.saturate_term
(ProofEngineHelpers.new_meta_of_proof proof) metasenv context termty 0 in
let termty, metasenv', arguments, _fresh_meta =
TermUtil.saturate_term
(ProofEngineHelpers.new_meta_of_proof proof) metasenv context termty 0 in
(* FG: ADDED PART ***********************************************************)
(* FG: we can not assume eliminator is the default eliminator ***************)
let splits, args_no = PEH.split_with_whd (context, ety) in
(* FG: ADDED PART ***********************************************************)
(* FG: we can not assume eliminator is the default eliminator ***************)
let splits, args_no = PEH.split_with_whd (context, ety) in
| _, C.Appl (C.Rel i :: _) when i > 1 && i <= args_no -> i
| _ -> raise NotAnEliminator
in
| _, C.Appl (C.Rel i :: _) when i > 1 && i <= args_no -> i
| _ -> raise NotAnEliminator
in
- let metasenv', pred, term, actual_args = match pattern with
+ let metasenv', subst, pred, term, actual_args = match pattern with
- metasenv', C.Implicit None, term, []
+ metasenv', subst, C.Implicit None, term, []
- let refined_term,_refined_termty,metasenv'',_ugraph =
- CicRefine.type_of_aux' metasenv' context term_to_refine ugraph
+ let refined_term,_refined_termty,metasenv'',subst,_ugraph =
+ CicRefine.type_of metasenv' subst context term_to_refine ugraph
+ in
+ let ipred = match refined_term with
+ | C.Appl ts -> List.nth ts (List.length ts - pred_pos)
+ | _ -> assert false
- let proof' = curi,metasenv'',_subst,proofbo,proofty, attrs in
+ let proof' = curi,metasenv'',subst,proofbo,proofty, attrs in
let proof'', new_goals' =
PET.apply_tactic (apply_tac ~term:refined_term) (proof',goal)
in
(* The apply_tactic can have closed some of the new_goals *)
let patched_new_goals =
let proof'', new_goals' =
PET.apply_tactic (apply_tac ~term:refined_term) (proof',goal)
in
(* The apply_tactic can have closed some of the new_goals *)
let patched_new_goals =
- let (_,metasenv''',_subst,_,_, _) = proof'' in
+ let (_,metasenv''',_,_,_, _) = proof'' in
List.filter
(function i -> List.exists (function (j,_,_) -> j=i) metasenv''')
new_goals @ new_goals'
in
let res = proof'', patched_new_goals in
let upto = List.length actual_args in
List.filter
(function i -> List.exists (function (j,_,_) -> j=i) metasenv''')
new_goals @ new_goals'
in
let res = proof'', patched_new_goals in
let upto = List.length actual_args in
- if upto = 0 then res else
- let continuation = beta_after_elim_tac upto pred in
+ if upto = 0 then res else
+(* FG: we use ipred (instantiated pred) instead of pred (not instantiated) *)
+ let continuation = beta_after_elim_tac upto ipred in
let dummy_status = proof,goal in
PET.apply_tactic
(T.then_ ~start:(PET.mk_tactic (fun _ -> res)) ~continuation)
let dummy_status = proof,goal in
PET.apply_tactic
(T.then_ ~start:(PET.mk_tactic (fun _ -> res)) ~continuation)