let fail_exc metasenv subst context t1 t2 =
UnificationFailure (lazy (
"Can't unify " ^ NCicPp.ppterm ~metasenv ~subst ~context t1 ^
- " with " ^ NCicPp.ppterm ~metasenv ~subst ~context t2))
+ " with " ^ NCicPp.ppterm ~metasenv ~subst ~context t2));
;;
let mk_appl hd tl =
else
NCic.Sort (NCic.Type (
match NCicEnvironment.sup NCicEnvironment.type0 with
- | Some x -> x
+ | Some x -> x
| _ -> assert false))
| NCic.Meta _ as orig -> orig
| t -> NCicUtils.map (fun _ _ -> ()) () aux t
with
| NCicTypeChecker.AssertFailure msg ->
(pp (lazy "fine typeof (fallimento)");
- let ft =
- fix_sorts swap metasenv subst context (NCic.Meta (n,lc)) t
- in
+ let ft=fix_sorts swap metasenv subst context (NCic.Meta (n,lc)) t in
if ft == t then
(prerr_endline ( ("ILLTYPED: " ^
NCicPp.ppterm ~metasenv ~subst ~context t
with NCicTypeChecker.AssertFailure _ ->
assert false)
| NCicTypeChecker.TypeCheckerFailure msg ->
+ prerr_endline (Lazy.force msg);
pp msg; assert false
in
let lty = NCicSubstitution.subst_meta lc ty in
- pp (lazy("On the types: " ^
+ pp (lazy ("On the types: " ^
NCicPp.ppterm ~metasenv ~subst ~context:ctx ty ^ " ~~~ " ^
NCicPp.ppterm ~metasenv ~subst ~context lty ^ " === "
^ NCicPp.ppterm ~metasenv ~subst ~context ty_t));
unify false;;
-
-(*
-
-open Printf
-
-exception UnificationFailure of string Lazy.t;;
-exception Uncertain of string Lazy.t;;
-exception AssertFailure of string Lazy.t;;
-
-let verbose = false;;
-let debug_print = fun _ -> ()
-
-let profiler_toa = HExtlib.profile "fo_unif_subst.type_of_aux'"
-let profiler_beta_expand = HExtlib.profile "fo_unif_subst.beta_expand"
-let profiler_deref = HExtlib.profile "fo_unif_subst.deref'"
-let profiler_are_convertible = HExtlib.profile "fo_unif_subst.are_convertible"
-
-let profile = HExtlib.profile "U/CicTypeChecker.type_of_aux'"
-
-let type_of_aux' metasenv subst context term ugraph =
-let foo () =
- try
- profile.HExtlib.profile
- (CicTypeChecker.type_of_aux' ~subst metasenv context term) ugraph
- with
- CicTypeChecker.TypeCheckerFailure msg ->
- let msg =
- lazy
- (sprintf
- "Kernel Type checking error:
-%s\n%s\ncontext=\n%s\nmetasenv=\n%s\nsubstitution=\n%s\nException:\n%s.\nToo bad."
- (CicMetaSubst.ppterm ~metasenv subst term)
- (CicMetaSubst.ppterm ~metasenv [] term)
- (CicMetaSubst.ppcontext ~metasenv subst context)
- (CicMetaSubst.ppmetasenv subst metasenv)
- (CicMetaSubst.ppsubst ~metasenv subst) (Lazy.force msg)) in
- raise (AssertFailure msg)
- | CicTypeChecker.AssertFailure msg ->
- let msg = lazy
- (sprintf
- "Kernel Type checking assertion failure:
-%s\n%s\ncontext=\n%s\nmetasenv=\n%s\nsubstitution=\n%s\nException:\n%s.\nToo bad."
- (CicMetaSubst.ppterm ~metasenv subst term)
- (CicMetaSubst.ppterm ~metasenv [] term)
- (CicMetaSubst.ppcontext ~metasenv subst context)
- (CicMetaSubst.ppmetasenv subst metasenv)
- (CicMetaSubst.ppsubst ~metasenv subst) (Lazy.force msg)) in
- raise (AssertFailure msg)
-in profiler_toa.HExtlib.profile foo ()
-;;
-
-let exists_a_meta l =
- List.exists
- (function
- | Cic.Meta _
- | Cic.Appl (Cic.Meta _::_) -> true
- | _ -> false) l
-
-let rec deref subst t =
- let snd (_,a,_) = a in
- match t with
- Cic.Meta(n,l) ->
- (try
- deref subst
- (CicSubstitution.subst_meta
- l (snd (CicUtil.lookup_subst n subst)))
- with
- CicUtil.Subst_not_found _ -> t)
- | Cic.Appl(Cic.Meta(n,l)::args) ->
- (match deref subst (Cic.Meta(n,l)) with
- | Cic.Lambda _ as t ->
- deref subst (CicReduction.head_beta_reduce (Cic.Appl(t::args)))
- | r -> Cic.Appl(r::args))
- | Cic.Appl(((Cic.Lambda _) as t)::args) ->
- deref subst (CicReduction.head_beta_reduce (Cic.Appl(t::args)))
- | t -> t
-;;
-
-let deref subst t =
- let foo () = deref subst t
- in profiler_deref.HExtlib.profile foo ()
-
-exception WrongShape;;
-let eta_reduce after_beta_expansion after_beta_expansion_body
- before_beta_expansion
- =
- try
- match before_beta_expansion,after_beta_expansion_body with
- Cic.Appl l, Cic.Appl l' ->
- let rec all_but_last check_last =
- function
- [] -> assert false
- | [Cic.Rel 1] -> []
- | [_] -> if check_last then raise WrongShape else []
- | he::tl -> he::(all_but_last check_last tl)
- in
- let all_but_last check_last l =
- match all_but_last check_last l with
- [] -> assert false
- | [he] -> he
- | l -> Cic.Appl l
- in
- let t = CicSubstitution.subst (Cic.Rel (-1)) (all_but_last true l') in
- let all_but_last = all_but_last false l in
- (* here we should test alpha-equivalence; however we know by
- construction that here alpha_equivalence is equivalent to = *)
- if t = all_but_last then
- all_but_last
- else
- after_beta_expansion
- | _,_ -> after_beta_expansion
- with
- WrongShape -> after_beta_expansion
-
-let rec beta_expand num test_equality_only metasenv subst context t arg ugraph =
- let module S = CicSubstitution in
- let module C = Cic in
-let foo () =
- let rec aux metasenv subst n context t' ugraph =
- try
-
- let subst,metasenv,ugraph1 =
- fo_unif_subst test_equality_only subst context metasenv
- (CicSubstitution.lift n arg) t' ugraph
-
- in
- subst,metasenv,C.Rel (1 + n),ugraph1
- with
- Uncertain _
- | UnificationFailure _ ->
- match t' with
- | C.Rel m -> subst,metasenv,
- (if m <= n then C.Rel m else C.Rel (m+1)),ugraph
- | C.Var (uri,exp_named_subst) ->
- let subst,metasenv,exp_named_subst',ugraph1 =
- aux_exp_named_subst metasenv subst n context exp_named_subst ugraph
- in
- subst,metasenv,C.Var (uri,exp_named_subst'),ugraph1
- | C.Meta (i,l) ->
- (* andrea: in general, beta_expand can create badly typed
- terms. This happens quite seldom in practice, UNLESS we
- iterate on the local context. For this reason, we renounce
- to iterate and just lift *)
- let l =
- List.map
- (function
- Some t -> Some (CicSubstitution.lift 1 t)
- | None -> None) l in
- subst, metasenv, C.Meta (i,l), ugraph
- | C.Sort _
- | C.Implicit _ as t -> subst,metasenv,t,ugraph
- | C.Cast (te,ty) ->
- let subst,metasenv,te',ugraph1 =
- aux metasenv subst n context te ugraph in
- let subst,metasenv,ty',ugraph2 =
- aux metasenv subst n context ty ugraph1 in
- (* TASSI: sure this is in serial? *)
- subst,metasenv,(C.Cast (te', ty')),ugraph2
- | C.Prod (nn,s,t) ->
- let subst,metasenv,s',ugraph1 =
- aux metasenv subst n context s ugraph in
- let subst,metasenv,t',ugraph2 =
- aux metasenv subst (n+1) ((Some (nn, C.Decl s))::context) t
- ugraph1
- in
- (* TASSI: sure this is in serial? *)
- subst,metasenv,(C.Prod (nn, s', t')),ugraph2
- | C.Lambda (nn,s,t) ->
- let subst,metasenv,s',ugraph1 =
- aux metasenv subst n context s ugraph in
- let subst,metasenv,t',ugraph2 =
- aux metasenv subst (n+1) ((Some (nn, C.Decl s))::context) t ugraph1
- in
- (* TASSI: sure this is in serial? *)
- subst,metasenv,(C.Lambda (nn, s', t')),ugraph2
- | C.LetIn (nn,s,ty,t) ->
- let subst,metasenv,s',ugraph1 =
- aux metasenv subst n context s ugraph in
- let subst,metasenv,ty',ugraph1 =
- aux metasenv subst n context ty ugraph in
- let subst,metasenv,t',ugraph2 =
- aux metasenv subst (n+1) ((Some (nn, C.Def (s,ty)))::context) t
- ugraph1
- in
- (* TASSI: sure this is in serial? *)
- subst,metasenv,(C.LetIn (nn, s', ty', t')),ugraph2
- | C.Appl l ->
- let subst,metasenv,revl',ugraph1 =
- List.fold_left
- (fun (subst,metasenv,appl,ugraph) t ->
- let subst,metasenv,t',ugraph1 =
- aux metasenv subst n context t ugraph in
- subst,metasenv,(t'::appl),ugraph1
- ) (subst,metasenv,[],ugraph) l
- in
- subst,metasenv,(C.Appl (List.rev revl')),ugraph1
- | C.Const (uri,exp_named_subst) ->
- let subst,metasenv,exp_named_subst',ugraph1 =
- aux_exp_named_subst metasenv subst n context exp_named_subst ugraph
- in
- subst,metasenv,(C.Const (uri,exp_named_subst')),ugraph1
- | C.MutInd (uri,i,exp_named_subst) ->
- let subst,metasenv,exp_named_subst',ugraph1 =
- aux_exp_named_subst metasenv subst n context exp_named_subst ugraph
- in
- subst,metasenv,(C.MutInd (uri,i,exp_named_subst')),ugraph1
- | C.MutConstruct (uri,i,j,exp_named_subst) ->
- let subst,metasenv,exp_named_subst',ugraph1 =
- aux_exp_named_subst metasenv subst n context exp_named_subst ugraph
- in
- subst,metasenv,(C.MutConstruct (uri,i,j,exp_named_subst')),ugraph1
- | C.MutCase (sp,i,outt,t,pl) ->
- let subst,metasenv,outt',ugraph1 =
- aux metasenv subst n context outt ugraph in
- let subst,metasenv,t',ugraph2 =
- aux metasenv subst n context t ugraph1 in
- let subst,metasenv,revpl',ugraph3 =
- List.fold_left
- (fun (subst,metasenv,pl,ugraph) t ->
- let subst,metasenv,t',ugraph1 =
- aux metasenv subst n context t ugraph in
- subst,metasenv,(t'::pl),ugraph1
- ) (subst,metasenv,[],ugraph2) pl
- in
- subst,metasenv,(C.MutCase (sp,i,outt', t', List.rev revpl')),ugraph3
- (* TASSI: not sure this is serial *)
- | C.Fix (i,fl) ->
-(*CSC: not implemented
- let tylen = List.length fl in
- let substitutedfl =
- List.map
- (fun (name,i,ty,bo) -> (name, i, aux n ty, aux (n+tylen) bo))
- fl
- in
- C.Fix (i, substitutedfl)
-*)
- subst,metasenv,(CicSubstitution.lift 1 t' ),ugraph
- | C.CoFix (i,fl) ->
-(*CSC: not implemented
- let tylen = List.length fl in
- let substitutedfl =
- List.map
- (fun (name,ty,bo) -> (name, aux n ty, aux (n+tylen) bo))
- fl
- in
- C.CoFix (i, substitutedfl)
-
-*)
- subst,metasenv,(CicSubstitution.lift 1 t'), ugraph
-
- and aux_exp_named_subst metasenv subst n context ens ugraph =
- List.fold_right
- (fun (uri,t) (subst,metasenv,l,ugraph) ->
- let subst,metasenv,t',ugraph1 = aux metasenv subst n context t ugraph in
- subst,metasenv,((uri,t')::l),ugraph1) ens (subst,metasenv,[],ugraph)
- in
- let argty,ugraph1 = type_of_aux' metasenv subst context arg ugraph in
- let fresh_name =
- FreshNamesGenerator.mk_fresh_name ~subst
- metasenv context (Cic.Name ("Hbeta" ^ string_of_int num)) ~typ:argty
- in
- let subst,metasenv,t',ugraph2 = aux metasenv subst 0 context t ugraph1 in
- let t'' = eta_reduce (C.Lambda (fresh_name,argty,t')) t' t in
- subst, metasenv, t'', ugraph2
-in profiler_beta_expand.HExtlib.profile foo ()
-
-
-and beta_expand_many test_equality_only metasenv subst context t args ugraph =
- let _,subst,metasenv,hd,ugraph =
- List.fold_right
- (fun arg (num,subst,metasenv,t,ugraph) ->
- let subst,metasenv,t,ugraph1 =
- beta_expand num test_equality_only
- metasenv subst context t arg ugraph
- in
- num+1,subst,metasenv,t,ugraph1
- ) args (1,subst,metasenv,t,ugraph)
- in
- subst,metasenv,hd,ugraph
-
-and warn_if_not_unique xxx to1 to2 carr car1 car2 =
- match xxx with
- | [] -> ()
- | (m2,_,c2,c2')::_ ->
- let m1,c1,c1' = carr,to1,to2 in
- let unopt =
- function Some (_,t) -> CicPp.ppterm t
- | None -> "id"
- in
- HLog.warn
- ("There are two minimal joins of "^ CoercDb.string_of_carr car1^" and "^
- CoercDb.string_of_carr car2^": " ^
- CoercDb.string_of_carr m1^" via "^unopt c1^" + "^
- unopt c1'^" and "^ CoercDb.string_of_carr m2^" via "^
- unopt c2^" + "^unopt c2')
-
-(* NUOVA UNIFICAZIONE *)
-(* A substitution is a (int * Cic.term) list that associates a
- metavariable i with its body.
- A metaenv is a (int * Cic.term) list that associate a metavariable
- i with is type.
- fo_unif_new takes a metasenv, a context, two terms t1 and t2 and gives back
- a new substitution which is _NOT_ unwinded. It must be unwinded before
- applying it. *)
-
-and fo_unif_subst test_equality_only subst context metasenv t1 t2 ugraph =
- let module C = Cic in
- let module R = CicReduction in
- let module S = CicSubstitution in
- let t1 = deref subst t1 in
- let t2 = deref subst t2 in
- let (&&&) a b = (a && b) || ((not a) && (not b)) in
-(* let bef = Sys.time () in *)
- let b,ugraph =
- if not (CicUtil.is_meta_closed (CicMetaSubst.apply_subst subst t1) &&& CicUtil.is_meta_closed (CicMetaSubst.apply_subst subst t2)) then
- false,ugraph
- else
-let foo () =
- R.are_convertible ~subst ~metasenv context t1 t2 ugraph
-in profiler_are_convertible.HExtlib.profile foo ()
- in
-(* let aft = Sys.time () in
-if (aft -. bef > 2.0) then prerr_endline ("LEEEENTO: " ^
-CicMetaSubst.ppterm_in_context subst ~metasenv t1 context ^ " <===> " ^
-CicMetaSubst.ppterm_in_context subst ~metasenv t2 context); *)
- if b then
- subst, metasenv, ugraph
- else
- match (t1, t2) with
- | (C.Meta (n,ln), C.Meta (m,lm)) when n=m ->
- let _,subst,metasenv,ugraph1 =
- (try
- List.fold_left2
- (fun (j,subst,metasenv,ugraph) t1 t2 ->
- match t1,t2 with
- None,_
- | _,None -> j+1,subst,metasenv,ugraph
- | Some t1', Some t2' ->
- (* First possibility: restriction *)
- (* Second possibility: unification *)
- (* Third possibility: convertibility *)
- let b, ugraph1 =
- R.are_convertible
- ~subst ~metasenv context t1' t2' ugraph
- in
- if b then
- j+1,subst,metasenv, ugraph1
- else
- (try
- let subst,metasenv,ugraph2 =
- fo_unif_subst
- test_equality_only
- subst context metasenv t1' t2' ugraph
- in
- j+1,subst,metasenv,ugraph2
- with
- Uncertain _
- | UnificationFailure _ ->
-debug_print (lazy ("restringo Meta n." ^ (string_of_int n) ^ "on variable n." ^ (string_of_int j)));
- let metasenv, subst =
- CicMetaSubst.restrict
- subst [(n,j)] metasenv in
- j+1,subst,metasenv,ugraph1)
- ) (1,subst,metasenv,ugraph) ln lm
- with
- Exit ->
- raise
- (UnificationFailure (lazy "1"))
- (*
- (sprintf
- "Error trying to unify %s with %s: the algorithm tried to check whether the two substitutions are convertible; if they are not, it tried to unify the two substitutions. No restriction was attempted."
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (CicMetaSubst.ppterm ~metasenv subst t2))) *)
- | Invalid_argument _ ->
- raise
- (UnificationFailure (lazy "2")))
- (*
- (sprintf
- "Error trying to unify %s with %s: the lengths of the two local contexts do not match."
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (CicMetaSubst.ppterm ~metasenv subst t2)))) *)
- in subst,metasenv,ugraph1
- | (C.Meta (n,_), C.Meta (m,_)) when n>m ->
- fo_unif_subst test_equality_only subst context metasenv t2 t1 ugraph
- | (C.Meta (n,l), t)
- | (t, C.Meta (n,l)) ->
- let swap =
- match t1,t2 with
- C.Meta (n,_), C.Meta (m,_) when n < m -> false
- | _, C.Meta _ -> false
- | _,_ -> true
- in
- let lower = fun x y -> if swap then y else x in
- let upper = fun x y -> if swap then x else y in
- let fo_unif_subst_ordered
- test_equality_only subst context metasenv m1 m2 ugraph =
- fo_unif_subst test_equality_only subst context metasenv
- (lower m1 m2) (upper m1 m2) ugraph
- in
- begin
- let subst,metasenv,ugraph1 =
- let (_,_,meta_type) = CicUtil.lookup_meta n metasenv in
- (try
- let tyt,ugraph1 =
- type_of_aux' metasenv subst context t ugraph
- in
- fo_unif_subst
- test_equality_only
- subst context metasenv tyt (S.subst_meta l meta_type) ugraph1
- with
- UnificationFailure _ as e -> raise e
- | Uncertain msg -> raise (UnificationFailure msg)
- | AssertFailure _ ->
- debug_print (lazy "siamo allo huge hack");
- (* TODO huge hack!!!!
- * we keep on unifying/refining in the hope that
- * the problem will be eventually solved.
- * In the meantime we're breaking a big invariant:
- * the terms that we are unifying are no longer well
- * typed in the current context (in the worst case
- * we could even diverge) *)
- (subst, metasenv,ugraph)) in
- let t',metasenv,subst =
- try
- CicMetaSubst.delift n subst context metasenv l t
- with
- (CicMetaSubst.MetaSubstFailure msg)->
- raise (UnificationFailure msg)
- | (CicMetaSubst.Uncertain msg) -> raise (Uncertain msg)
- in
- let t'',ugraph2 =
- match t' with
- C.Sort (C.Type u) when not test_equality_only ->
- let u' = CicUniv.fresh () in
- let s = C.Sort (C.Type u') in
- (try
- let ugraph2 =
- CicUniv.add_ge (upper u u') (lower u u') ugraph1
- in
- s,ugraph2
- with
- CicUniv.UniverseInconsistency msg ->
- raise (UnificationFailure msg))
- | _ -> t',ugraph1
- in
- (* Unifying the types may have already instantiated n. Let's check *)
- try
- let (_, oldt,_) = CicUtil.lookup_subst n subst in
- let lifted_oldt = S.subst_meta l oldt in
- fo_unif_subst_ordered
- test_equality_only subst context metasenv t lifted_oldt ugraph2
- with
- CicUtil.Subst_not_found _ ->
- let (_, context, ty) = CicUtil.lookup_meta n metasenv in
- let subst = (n, (context, t'',ty)) :: subst in
- let metasenv =
- List.filter (fun (m,_,_) -> not (n = m)) metasenv in
- subst, metasenv, ugraph2
- end
- | (C.Var (uri1,exp_named_subst1),C.Var (uri2,exp_named_subst2))
- | (C.Const (uri1,exp_named_subst1),C.Const (uri2,exp_named_subst2)) ->
- if UriManager.eq uri1 uri2 then
- fo_unif_subst_exp_named_subst test_equality_only subst context metasenv
- exp_named_subst1 exp_named_subst2 ugraph
- else
- raise (UnificationFailure (lazy
- (sprintf
- "Can't unify %s with %s due to different constants"
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (CicMetaSubst.ppterm ~metasenv subst t2))))
- | C.MutInd (uri1,i1,exp_named_subst1),C.MutInd (uri2,i2,exp_named_subst2) ->
- if UriManager.eq uri1 uri2 && i1 = i2 then
- fo_unif_subst_exp_named_subst
- test_equality_only
- subst context metasenv exp_named_subst1 exp_named_subst2 ugraph
- else
- raise (UnificationFailure
- (lazy
- (sprintf
- "Can't unify %s with %s due to different inductive principles"
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (CicMetaSubst.ppterm ~metasenv subst t2))))
- | C.MutConstruct (uri1,i1,j1,exp_named_subst1),
- C.MutConstruct (uri2,i2,j2,exp_named_subst2) ->
- if UriManager.eq uri1 uri2 && i1 = i2 && j1 = j2 then
- fo_unif_subst_exp_named_subst
- test_equality_only
- subst context metasenv exp_named_subst1 exp_named_subst2 ugraph
- else
- raise (UnificationFailure
- (lazy
- (sprintf
- "Can't unify %s with %s due to different inductive constructors"
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (CicMetaSubst.ppterm ~metasenv subst t2))))
- | (C.Implicit _, _) | (_, C.Implicit _) -> assert false
- | (C.Cast (te,ty), t2) -> fo_unif_subst test_equality_only
- subst context metasenv te t2 ugraph
- | (t1, C.Cast (te,ty)) -> fo_unif_subst test_equality_only
- subst context metasenv t1 te ugraph
- | (C.Lambda (n1,s1,t1), C.Lambda (_,s2,t2)) ->
- let subst',metasenv',ugraph1 =
- fo_unif_subst test_equality_only subst context metasenv s1 s2 ugraph
- in
- fo_unif_subst test_equality_only
- subst' ((Some (n1,(C.Decl s1)))::context) metasenv' t1 t2 ugraph1
- | (C.LetIn (_,s1,ty1,t1), t2)
- | (t2, C.LetIn (_,s1,ty1,t1)) ->
- fo_unif_subst
- test_equality_only subst context metasenv t2 (S.subst s1 t1) ugraph
- | (C.Appl l1, C.Appl l2) ->
- (* andrea: this case should be probably rewritten in the
- spirit of deref *)
- (match l1,l2 with
- | C.Meta (i,_)::args1, C.Meta (j,_)::args2 when i = j ->
- (try
- List.fold_left2
- (fun (subst,metasenv,ugraph) t1 t2 ->
- fo_unif_subst
- test_equality_only subst context metasenv t1 t2 ugraph)
- (subst,metasenv,ugraph) l1 l2
- with (Invalid_argument msg) ->
- raise (UnificationFailure (lazy msg)))
- | C.Meta (i,l)::args, _ when not(exists_a_meta args) ->
- (* we verify that none of the args is a Meta,
- since beta expanding with respoect to a metavariable
- makes no sense *)
- (*
- (try
- let (_,t,_) = CicUtil.lookup_subst i subst in
- let lifted = S.subst_meta l t in
- let reduced = CicReduction.head_beta_reduce (Cic.Appl (lifted::args)) in
- fo_unif_subst
- test_equality_only
- subst context metasenv reduced t2 ugraph
- with CicUtil.Subst_not_found _ -> *)
- let subst,metasenv,beta_expanded,ugraph1 =
- beta_expand_many
- test_equality_only metasenv subst context t2 args ugraph
- in
- fo_unif_subst test_equality_only subst context metasenv
- (C.Meta (i,l)) beta_expanded ugraph1
- | _, C.Meta (i,l)::args when not(exists_a_meta args) ->
- (* (try
- let (_,t,_) = CicUtil.lookup_subst i subst in
- let lifted = S.subst_meta l t in
- let reduced = CicReduction.head_beta_reduce (Cic.Appl (lifted::args)) in
- fo_unif_subst
- test_equality_only
- subst context metasenv t1 reduced ugraph
- with CicUtil.Subst_not_found _ -> *)
- let subst,metasenv,beta_expanded,ugraph1 =
- beta_expand_many
- test_equality_only
- metasenv subst context t1 args ugraph
- in
- fo_unif_subst test_equality_only subst context metasenv
- (C.Meta (i,l)) beta_expanded ugraph1
- | _,_ ->
- let lr1 = List.rev l1 in
- let lr2 = List.rev l2 in
- let rec
- fo_unif_l test_equality_only subst metasenv (l1,l2) ugraph =
- match (l1,l2) with
- [],_
- | _,[] -> assert false
- | ([h1],[h2]) ->
- fo_unif_subst
- test_equality_only subst context metasenv h1 h2 ugraph
- | ([h],l)
- | (l,[h]) ->
- fo_unif_subst test_equality_only subst context metasenv
- h (C.Appl (List.rev l)) ugraph
- | ((h1::l1),(h2::l2)) ->
- let subst', metasenv',ugraph1 =
- fo_unif_subst
- test_equality_only
- subst context metasenv h1 h2 ugraph
- in
- fo_unif_l
- test_equality_only subst' metasenv' (l1,l2) ugraph1
- in
- (try
- fo_unif_l
- test_equality_only subst metasenv (lr1, lr2) ugraph
- with
- | UnificationFailure s
- | Uncertain s as exn ->
- (match l1, l2 with
- (* {{{ pullback *)
- | (((Cic.Const (uri1, ens1)) as cc1) :: tl1),
- (((Cic.Const (uri2, ens2)) as cc2) :: tl2) when
- CoercDb.is_a_coercion cc1 <> None &&
- CoercDb.is_a_coercion cc2 <> None &&
- not (UriManager.eq uri1 uri2) ->
-(*DEBUGGING ONLY:
-prerr_endline ("<<<< " ^ CicMetaSubst.ppterm_in_context ~metasenv subst (C.Appl l1) context ^ " <==> " ^ CicMetaSubst.ppterm_in_context ~metasenv subst (C.Appl l2) context);
-*)
- let inner_coerced t =
- let t = CicMetaSubst.apply_subst subst t in
- let rec aux c x t =
- match t with
- | Cic.Appl l ->
- (match CoercGraph.coerced_arg l with
- | None -> c, x
- | Some (t,_) -> aux (List.hd l) t t)
- | _ -> c, x
- in
- aux (Cic.Implicit None) (Cic.Implicit None) t
- in
- let c1,last_tl1 = inner_coerced (Cic.Appl l1) in
- let c2,last_tl2 = inner_coerced (Cic.Appl l2) in
- let car1, car2 =
- match
- CoercDb.is_a_coercion c1, CoercDb.is_a_coercion c2
- with
- | Some (s1,_,_,_,_), Some (s2,_,_,_,_) -> s1, s2
- | _ -> assert false
- in
- let head1_c, head2_c =
- match
- CoercDb.is_a_coercion cc1, CoercDb.is_a_coercion cc2
- with
- | Some (_,t1,_,_,_), Some (_,t2,_,_,_) -> t1, t2
- | _ -> assert false
- in
- let unfold uri ens args =
- let o, _ =
- CicEnvironment.get_obj CicUniv.oblivion_ugraph uri
- in
- assert (ens = []);
- match o with
- | Cic.Constant (_,Some bo,_,_,_) ->
- CicReduction.head_beta_reduce ~delta:false
- (Cic.Appl (bo::args))
- | _ -> assert false
- in
- let conclude subst metasenv ugraph last_tl1' last_tl2' =
- let subst',metasenv,ugraph =
-(*DEBUGGING ONLY:
-prerr_endline
- ("OK " ^ CicMetaSubst.ppterm_in_context ~metasenv subst last_tl1' context ^
- " <==> " ^ CicMetaSubst.ppterm_in_context ~metasenv subst last_tl2' context);
-*)
- fo_unif_subst test_equality_only subst context
- metasenv last_tl1' last_tl2' ugraph
- in
- if subst = subst' then raise exn
- else
-(*DEBUGGING ONLY:
-let subst,metasenv,ugrph as res =
-*)
- fo_unif_subst test_equality_only subst' context
- metasenv (C.Appl l1) (C.Appl l2) ugraph
-(*DEBUGGING ONLY:
-in
-(prerr_endline
- (">>>> "^CicMetaSubst.ppterm_in_context ~metasenv subst (C.Appl l1) context ^
- " <==> "^CicMetaSubst.ppterm_in_context ~metasenv subst (C.Appl l2) context);
-res)
-*)
- in
- if CoercDb.eq_carr car1 car2 then
- match last_tl1,last_tl2 with
- | C.Meta (i1,_),C.Meta(i2,_) when i1 = i2 -> raise exn
- | _, C.Meta _
- | C.Meta _, _ ->
- let subst,metasenv,ugraph =
- fo_unif_subst test_equality_only subst context
- metasenv last_tl1 last_tl2 ugraph
- in
- fo_unif_subst test_equality_only subst context
- metasenv (Cic.Appl l1) (Cic.Appl l2) ugraph
- | _ when CoercDb.eq_carr head1_c head2_c ->
- (* composite VS composition + metas avoiding
- * coercions not only in coerced position *)
- if c1 <> cc1 && c2 <> cc2 then
- conclude subst metasenv ugraph
- last_tl1 last_tl2
- else
- let l1, l2 =
- if c1 = cc1 then
- unfold uri1 ens1 tl1, Cic.Appl (cc2::tl2)
- else
- Cic.Appl (cc1::tl1), unfold uri2 ens2 tl2
- in
- fo_unif_subst test_equality_only subst context
- metasenv l1 l2 ugraph
- | _ -> raise exn
- else
- let grow1 =
- match last_tl1 with Cic.Meta _ -> true | _ -> false in
- let grow2 =
- match last_tl2 with Cic.Meta _ -> true | _ -> false in
- if not (grow1 || grow2) then
- (* no flexible terminals -> no pullback, but
- * we still unify them, in some cases it helps *)
- conclude subst metasenv ugraph last_tl1 last_tl2
- else
- let meets =
- CoercGraph.meets
- metasenv subst context (grow1,car1) (grow2,car2)
- in
- (match meets with
- | [] -> raise exn
- | (carr,metasenv,to1,to2)::xxx ->
- warn_if_not_unique xxx to1 to2 carr car1 car2;
- let last_tl1',(subst,metasenv,ugraph) =
- match grow1,to1 with
- | true,Some (last,coerced) ->
- last,
- fo_unif_subst test_equality_only subst context
- metasenv coerced last_tl1 ugraph
- | _ -> last_tl1,(subst,metasenv,ugraph)
- in
- let last_tl2',(subst,metasenv,ugraph) =
- match grow2,to2 with
- | true,Some (last,coerced) ->
- last,
- fo_unif_subst test_equality_only subst context
- metasenv coerced last_tl2 ugraph
- | _ -> last_tl2,(subst,metasenv,ugraph)
- in
- conclude subst metasenv ugraph last_tl1' last_tl2')
- (* }}} pullback *)
- (* {{{ CSC: This is necessary because of the "elim H" tactic
- where the type of H is only reducible to an
- inductive type. This could be extended from inductive
- types to any rigid term. However, the code is
- duplicated in two places: inside applications and
- outside them. Probably it would be better to
- work with lambda-bar terms instead. *)
- | (Cic.MutInd _::_, Cic.MutInd _::_) -> raise exn
- | (_, Cic.MutInd _::_) ->
- let t1' = R.whd ~subst context t1 in
- (match t1' with
- C.Appl (C.MutInd _::_) ->
- fo_unif_subst test_equality_only
- subst context metasenv t1' t2 ugraph
- | _ -> raise (UnificationFailure (lazy "88")))
- | (Cic.MutInd _::_,_) ->
- let t2' = R.whd ~subst context t2 in
- (match t2' with
- C.Appl (C.MutInd _::_) ->
- fo_unif_subst test_equality_only
- subst context metasenv t1 t2' ugraph
- | _ -> raise
- (UnificationFailure
- (lazy ("not a mutind :"^
- CicMetaSubst.ppterm ~metasenv subst t2 ))))
- (* }}} elim H *)
- | _ -> raise exn)))
- | (C.MutCase (_,_,outt1,t1',pl1), C.MutCase (_,_,outt2,t2',pl2))->
- let subst', metasenv',ugraph1 =
- fo_unif_subst test_equality_only subst context metasenv outt1 outt2
- ugraph in
- let subst'',metasenv'',ugraph2 =
- fo_unif_subst test_equality_only subst' context metasenv' t1' t2'
- ugraph1 in
- (try
- List.fold_left2
- (fun (subst,metasenv,ugraph) t1 t2 ->
- fo_unif_subst
- test_equality_only subst context metasenv t1 t2 ugraph
- ) (subst'',metasenv'',ugraph2) pl1 pl2
- with
- Invalid_argument _ ->
- raise (UnificationFailure (lazy "6.1")))
- (* (sprintf
- "Error trying to unify %s with %s: the number of branches is not the same."
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (CicMetaSubst.ppterm ~metasenv subst t2)))) *)
- | (C.Rel _, _) | (_, C.Rel _) ->
- if t1 = t2 then
- subst, metasenv,ugraph
- else
- raise (UnificationFailure (lazy
- (sprintf
- "Can't unify %s with %s because they are not convertible"
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (CicMetaSubst.ppterm ~metasenv subst t2))))
- | (C.Appl (C.Meta(i,l)::args),t2) when not(exists_a_meta args) ->
- let subst,metasenv,beta_expanded,ugraph1 =
- beta_expand_many
- test_equality_only metasenv subst context t2 args ugraph
- in
- fo_unif_subst test_equality_only subst context metasenv
- (C.Meta (i,l)) beta_expanded ugraph1
- | (t1,C.Appl (C.Meta(i,l)::args)) when not(exists_a_meta args) ->
- let subst,metasenv,beta_expanded,ugraph1 =
- beta_expand_many
- test_equality_only metasenv subst context t1 args ugraph
- in
- fo_unif_subst test_equality_only subst context metasenv
- beta_expanded (C.Meta (i,l)) ugraph1
-(* Works iff there are no arguments applied to it; similar to the
- case below
- | (_, C.MutInd _) ->
- let t1' = R.whd ~subst context t1 in
- (match t1' with
- C.MutInd _ ->
- fo_unif_subst test_equality_only
- subst context metasenv t1' t2 ugraph
- | _ -> raise (UnificationFailure (lazy "8")))
-*)
- | (C.Prod (n1,s1,t1), C.Prod (_,s2,t2)) ->
- let subst',metasenv',ugraph1 =
- fo_unif_subst true subst context metasenv s1 s2 ugraph
- in
- fo_unif_subst test_equality_only
- subst' ((Some (n1,(C.Decl s1)))::context) metasenv' t1 t2 ugraph1
- | (C.Prod _, _) ->
- (match CicReduction.whd ~subst context t2 with
- | C.Prod _ as t2 ->
- fo_unif_subst test_equality_only subst context metasenv t1 t2 ugraph
- | _ -> raise (UnificationFailure (lazy (CicMetaSubst.ppterm ~metasenv subst t2^"Not a product"))))
- | (_, C.Prod _) ->
- (match CicReduction.whd ~subst context t1 with
- | C.Prod _ as t1 ->
- fo_unif_subst test_equality_only subst context metasenv t1 t2 ugraph
- | _ -> raise (UnificationFailure (lazy (CicMetaSubst.ppterm ~metasenv subst t1^"Not a product"))))
- | (_,_) ->
- (* delta-beta reduction should almost never be a problem for
- unification since:
- 1. long computations require iota reduction
- 2. it is extremely rare that a close term t1 (that could be unified
- to t2) beta-delta reduces to t1' while t2 does not beta-delta
- reduces in the same way. This happens only if one meta of t2
- occurs in head position during beta reduction. In this unluky
- case too much reduction will be performed on t1 and unification
- will surely fail. *)
- let t1' = CicReduction.head_beta_reduce ~delta:true t1 in
- let t2' = CicReduction.head_beta_reduce ~delta:true t2 in
- if t1 = t1' && t2 = t2' then
- raise (UnificationFailure
- (lazy
- (sprintf
- "Can't unify %s with %s because they are not convertible"
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (CicMetaSubst.ppterm ~metasenv subst t2))))
- else
- try
- fo_unif_subst test_equality_only subst context metasenv t1' t2' ugraph
- with
- UnificationFailure _
- | Uncertain _ ->
- raise (UnificationFailure
- (lazy
- (sprintf
- "Can't unify %s with %s because they are not convertible"
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (CicMetaSubst.ppterm ~metasenv subst t2))))
-
-and fo_unif_subst_exp_named_subst test_equality_only subst context metasenv
- exp_named_subst1 exp_named_subst2 ugraph
-=
- try
- List.fold_left2
- (fun (subst,metasenv,ugraph) (uri1,t1) (uri2,t2) ->
- assert (uri1=uri2) ;
- fo_unif_subst test_equality_only subst context metasenv t1 t2 ugraph
- ) (subst,metasenv,ugraph) exp_named_subst1 exp_named_subst2
- with
- Invalid_argument _ ->
- let print_ens ens =
- String.concat " ; "
- (List.map
- (fun (uri,t) ->
- UriManager.string_of_uri uri ^ " := " ^ (CicMetaSubst.ppterm ~metasenv subst t)
- ) ens)
- in
- raise (UnificationFailure (lazy (sprintf
- "Error trying to unify the two explicit named substitutions (local contexts) %s and %s: their lengths is different." (print_ens exp_named_subst1) (print_ens exp_named_subst2))))
-
-(* A substitution is a (int * Cic.term) list that associates a *)
-(* metavariable i with its body. *)
-(* metasenv is of type Cic.metasenv *)
-(* fo_unif takes a metasenv, a context, two terms t1 and t2 and gives back *)
-(* a new substitution which is already unwinded and ready to be applied and *)
-(* a new metasenv in which some hypothesis in the contexts of the *)
-(* metavariables may have been restricted. *)
-let fo_unif metasenv context t1 t2 ugraph =
- fo_unif_subst false [] context metasenv t1 t2 ugraph ;;
-
-let enrich_msg msg subst context metasenv t1 t2 ugraph =
- lazy (
- if verbose then
- sprintf "[Verbose] Unification error unifying %s of type %s with %s of type %s in context\n%s\nand metasenv\n%s\nand substitution\n%s\nbecause %s"
- (CicMetaSubst.ppterm ~metasenv subst t1)
- (try
- let ty_t1,_ = type_of_aux' metasenv subst context t1 ugraph in
- CicPp.ppterm ty_t1
- with
- | UnificationFailure s
- | Uncertain s
- | AssertFailure s -> sprintf "MALFORMED(t1): \n<BEGIN>%s\n<END>" (Lazy.force s))
- (CicMetaSubst.ppterm ~metasenv subst t2)
- (try
- let ty_t2,_ = type_of_aux' metasenv subst context t2 ugraph in
- CicPp.ppterm ty_t2
- with
- | UnificationFailure s
- | Uncertain s
- | AssertFailure s -> sprintf "MALFORMED(t2): \n<BEGIN>%s\n<END>" (Lazy.force s))
- (CicMetaSubst.ppcontext ~metasenv subst context)
- (CicMetaSubst.ppmetasenv subst metasenv)
- (CicMetaSubst.ppsubst ~metasenv subst) (Lazy.force msg)
- else
- sprintf "Unification error unifying %s of type %s with %s of type %s in context\n%s\nand metasenv\n%s\nbecause %s"
- (CicMetaSubst.ppterm_in_context ~metasenv subst t1 context)
- (try
- let ty_t1,_ = type_of_aux' metasenv subst context t1 ugraph in
- CicMetaSubst.ppterm_in_context ~metasenv subst ty_t1 context
- with
- | UnificationFailure s
- | Uncertain s
- | AssertFailure s -> sprintf "MALFORMED(t1): \n<BEGIN>%s\n<END>" (Lazy.force s))
- (CicMetaSubst.ppterm_in_context ~metasenv subst t2 context)
- (try
- let ty_t2,_ = type_of_aux' metasenv subst context t2 ugraph in
- CicMetaSubst.ppterm_in_context ~metasenv subst ty_t2 context
- with
- | UnificationFailure s
- | Uncertain s
- | AssertFailure s -> sprintf "MALFORMED(t2): \n<BEGIN>%s\n<END>" (Lazy.force s))
- (CicMetaSubst.ppcontext ~metasenv subst context)
- (CicMetaSubst.ppmetasenv subst metasenv)
- (Lazy.force msg)
- )
-
-let fo_unif_subst subst context metasenv t1 t2 ugraph =
- try
- fo_unif_subst false subst context metasenv t1 t2 ugraph
- with
- | AssertFailure msg ->
- raise (AssertFailure (enrich_msg msg subst context metasenv t1 t2 ugraph))
- | UnificationFailure msg ->
- raise (UnificationFailure (enrich_msg msg subst context metasenv t1 t2 ugraph))
-;;
-*)