-(* ||M|| This file is part of HELM, an Hypertextual, Electronic
+(*
+ ||M|| This file is part of HELM, an Hypertextual, Electronic
||A|| Library of Mathematics, developed at the Computer Science
||T|| Department, University of Bologna, Italy.
||I||
(* $Id$ *)
-(* TODO unify exceptions *)
-
-exception WrongUriToInductiveDefinition;;
-exception Impossible of int;;
-exception ReferenceToConstant;;
-exception ReferenceToVariable;;
-exception ReferenceToCurrentProof;;
-exception ReferenceToInductiveDefinition;;
-
-let debug = false
-let profile = false
-let debug_print s = if debug then prerr_endline (Lazy.force s)
-
-let fdebug = ref 1;;
-let debug t env s =
- let rec debug_aux t i =
- let module C = Cic in
- let module U = UriManager in
- CicPp.ppobj (C.Variable ("DEBUG", None, t, [], [])) ^ "\n" ^ i
- in
- if !fdebug = 0 then
- debug_print (lazy (s ^ "\n" ^ List.fold_right debug_aux (t::env) ""))
-;;
+module C = NCic
+module Ref = NReference
+module E = NCicEnvironment
-module type Strategy =
- sig
+module type Strategy = sig
type stack_term
type env_term
- type config = int * env_term list * NCic.term * stack_term list
+ type config = int * env_term list * C.term * stack_term list
val to_env :
- reduce: (config -> config) ->
- unwind: (config -> NCic.term) ->
- config -> env_term
+ reduce: (config -> config * bool) -> unwind: (config -> C.term) ->
+ config -> env_term
val from_stack : stack_term -> config
val from_stack_list_for_unwind :
- unwind: (config -> NCic.term) ->
- stack_term list -> NCic.term list
+ unwind: (config -> C.term) -> stack_term list -> C.term list
val from_env : env_term -> config
val from_env_for_unwind :
- unwind: (config -> NCic.term) ->
- env_term -> NCic.term
+ unwind: (config -> C.term) -> env_term -> C.term
val stack_to_env :
- reduce: (config -> config) ->
- unwind: (config -> NCic.term) ->
- stack_term -> env_term
+ reduce: (config -> config * bool) -> unwind: (config -> C.term) ->
+ stack_term -> env_term
val compute_to_env :
- reduce: (config -> config) ->
- unwind: (config -> NCic.term) ->
- int -> env_term list ->
- NCic.term -> env_term
+ reduce: (config -> config * bool) -> unwind: (config -> C.term) ->
+ int -> env_term list -> C.term -> env_term
val compute_to_stack :
- reduce: (config -> config) ->
- unwind: (config -> NCic.term) ->
- config -> stack_term
+ reduce: (config -> config * bool) -> unwind: (config -> C.term) ->
+ config -> stack_term
end
;;
-module CallByValueByNameForUnwind' =
- struct
- type config = int * env_term list * NCic.term * stack_term list
- and stack_term = config lazy_t * NCic.term lazy_t (* cbv, cbn *)
- and env_term = config lazy_t * NCic.term lazy_t (* cbv, cbn *)
- let to_env ~reduce ~unwind c = lazy (reduce c),lazy (unwind c)
+module CallByValueByNameForUnwind' = struct
+ type config = int * env_term list * C.term * stack_term list
+ and stack_term = config lazy_t * C.term lazy_t (* cbv, cbn *)
+ and env_term = config lazy_t * C.term lazy_t (* cbv, cbn *)
+ let to_env ~reduce ~unwind c = lazy (fst (reduce c)),lazy (unwind c)
let from_stack (c,_) = Lazy.force c
let from_stack_list_for_unwind ~unwind:_ l =
List.map (function (_,c) -> Lazy.force c) l
let from_env_for_unwind ~unwind:_ (_,c) = Lazy.force c
let stack_to_env ~reduce:_ ~unwind:_ config = config
let compute_to_env ~reduce ~unwind k e t =
- lazy (reduce (k,e,t,[])), lazy (unwind (k,e,t,[]))
+ lazy (fst (reduce (k,e,t,[]))), lazy (unwind (k,e,t,[]))
let compute_to_stack ~reduce ~unwind config =
- lazy (reduce config), lazy (unwind config)
+ lazy (fst (reduce config)), lazy (unwind config)
end
;;
-
-(* {{{ module CallByValueByNameForUnwind =
- struct
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- and stack_term = config
- and env_term = config * config (* cbv, cbn *)
- and ens_term = config * config (* cbv, cbn *)
-
- let to_env c = c,c
- let to_ens c = c,c
- let from_stack config = config
- let from_stack_list_for_unwind ~unwind l = List.map unwind l
- let from_env (c,_) = c
- let from_ens (c,_) = c
- let from_env_for_unwind ~unwind (_,c) = unwind c
- let from_ens_for_unwind ~unwind (_,c) = unwind c
- let stack_to_env ~reduce ~unwind config = reduce config, (0,[],[],unwind config,[])
- let compute_to_env ~reduce ~unwind k e ens t = (k,e,ens,t,[]), (k,e,ens,t,[])
- let compute_to_stack ~reduce ~unwind config = config
- end
-;;
-
-
-(* Old Machine *)
-module CallByNameStrategy =
- struct
- type stack_term = Cic.term
- type env_term = Cic.term
- type ens_term = Cic.term
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- let to_env v = v
- let to_ens v = v
- let from_stack ~unwind v = v
- let from_stack_list ~unwind l = l
- let from_env v = v
- let from_ens v = v
- let from_env_for_unwind ~unwind v = v
- let from_ens_for_unwind ~unwind v = v
- let stack_to_env ~reduce ~unwind v = v
- let compute_to_stack ~reduce ~unwind k e ens t = unwind k e ens t
- let compute_to_env ~reduce ~unwind k e ens t = unwind k e ens t
- end
-;;
-
-module CallByNameStrategy =
- struct
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- and stack_term = config
- and env_term = config
- and ens_term = config
-
- let to_env c = c
- let to_ens c = c
- let from_stack config = config
- let from_stack_list_for_unwind ~unwind l = List.map unwind l
- let from_env c = c
- let from_ens c = c
- let from_env_for_unwind ~unwind c = unwind c
- let from_ens_for_unwind ~unwind c = unwind c
- let stack_to_env ~reduce ~unwind config = 0,[],[],unwind config,[]
- let compute_to_env ~reduce ~unwind k e ens t = k,e,ens,t,[]
- let compute_to_stack ~reduce ~unwind config = config
- end
-;;
-
-module CallByValueStrategy =
- struct
- type stack_term = Cic.term
- type env_term = Cic.term
- type ens_term = Cic.term
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- let to_env v = v
- let to_ens v = v
- let from_stack ~unwind v = v
- let from_stack_list ~unwind l = l
- let from_env v = v
- let from_ens v = v
- let from_env_for_unwind ~unwind v = v
- let from_ens_for_unwind ~unwind v = v
- let stack_to_env ~reduce ~unwind v = v
- let compute_to_stack ~reduce ~unwind k e ens t = reduce (k,e,ens,t,[])
- let compute_to_env ~reduce ~unwind k e ens t = reduce (k,e,ens,t,[])
- end
-;;
-
-module CallByValueStrategyByNameOnConstants =
- struct
- type stack_term = Cic.term
- type env_term = Cic.term
- type ens_term = Cic.term
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- let to_env v = v
- let to_ens v = v
- let from_stack ~unwind v = v
- let from_stack_list ~unwind l = l
- let from_env v = v
- let from_ens v = v
- let from_env_for_unwind ~unwind v = v
- let from_ens_for_unwind ~unwind v = v
- let stack_to_env ~reduce ~unwind v = v
- let compute_to_stack ~reduce ~unwind k e ens =
- function
- Cic.Const _ as t -> unwind k e ens t
- | t -> reduce (k,e,ens,t,[])
- let compute_to_env ~reduce ~unwind k e ens =
- function
- Cic.Const _ as t -> unwind k e ens t
- | t -> reduce (k,e,ens,t,[])
- end
-;;
-
-module LazyCallByValueStrategy =
- struct
- type stack_term = Cic.term lazy_t
- type env_term = Cic.term lazy_t
- type ens_term = Cic.term lazy_t
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- let to_env v = lazy v
- let to_ens v = lazy v
- let from_stack ~unwind v = Lazy.force v
- let from_stack_list ~unwind l = List.map (from_stack ~unwind) l
- let from_env v = Lazy.force v
- let from_ens v = Lazy.force v
- let from_env_for_unwind ~unwind v = Lazy.force v
- let from_ens_for_unwind ~unwind v = Lazy.force v
- let stack_to_env ~reduce ~unwind v = v
- let compute_to_stack ~reduce ~unwind k e ens t = lazy (reduce (k,e,ens,t,[]))
- let compute_to_env ~reduce ~unwind k e ens t = lazy (reduce (k,e,ens,t,[]))
- end
-;;
-
-module LazyCallByValueStrategyByNameOnConstants =
- struct
- type stack_term = Cic.term lazy_t
- type env_term = Cic.term lazy_t
- type ens_term = Cic.term lazy_t
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- let to_env v = lazy v
- let to_ens v = lazy v
- let from_stack ~unwind v = Lazy.force v
- let from_stack_list ~unwind l = List.map (from_stack ~unwind) l
- let from_env v = Lazy.force v
- let from_ens v = Lazy.force v
- let from_env_for_unwind ~unwind v = Lazy.force v
- let from_ens_for_unwind ~unwind v = Lazy.force v
- let stack_to_env ~reduce ~unwind v = v
- let compute_to_stack ~reduce ~unwind k e ens t =
- lazy (
- match t with
- Cic.Const _ as t -> unwind k e ens t
- | t -> reduce (k,e,ens,t,[]))
- let compute_to_env ~reduce ~unwind k e ens t =
- lazy (
- match t with
- Cic.Const _ as t -> unwind k e ens t
- | t -> reduce (k,e,ens,t,[]))
- end
-;;
-
-module LazyCallByNameStrategy =
- struct
- type stack_term = Cic.term lazy_t
- type env_term = Cic.term lazy_t
- type ens_term = Cic.term lazy_t
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- let to_env v = lazy v
- let to_ens v = lazy v
- let from_stack ~unwind v = Lazy.force v
- let from_stack_list ~unwind l = List.map (from_stack ~unwind) l
- let from_env v = Lazy.force v
- let from_ens v = Lazy.force v
- let from_env_for_unwind ~unwind v = Lazy.force v
- let from_ens_for_unwind ~unwind v = Lazy.force v
- let stack_to_env ~reduce ~unwind v = v
- let compute_to_stack ~reduce ~unwind k e ens t = lazy (unwind k e ens t)
- let compute_to_env ~reduce ~unwind k e ens t = lazy (unwind k e ens t)
- end
-;;
-
-module
- LazyCallByValueByNameOnConstantsWhenFromStack_ByNameStrategyWhenFromEnvOrEns
-=
- struct
- type stack_term = reduce:bool -> Cic.term
- type env_term = reduce:bool -> Cic.term
- type ens_term = reduce:bool -> Cic.term
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- let to_env v =
- let value = lazy v in
- fun ~reduce -> Lazy.force value
- let to_ens v =
- let value = lazy v in
- fun ~reduce -> Lazy.force value
- let from_stack ~unwind v = (v ~reduce:false)
- let from_stack_list ~unwind l = List.map (from_stack ~unwind) l
- let from_env v = (v ~reduce:true)
- let from_ens v = (v ~reduce:true)
- let from_env_for_unwind ~unwind v = (v ~reduce:true)
- let from_ens_for_unwind ~unwind v = (v ~reduce:true)
- let stack_to_env ~reduce ~unwind v = v
- let compute_to_stack ~reduce ~unwind k e ens t =
- let svalue =
- lazy (
- match t with
- Cic.Const _ as t -> unwind k e ens t
- | t -> reduce (k,e,ens,t,[])
- ) in
- let lvalue =
- lazy (unwind k e ens t)
- in
- fun ~reduce ->
- if reduce then Lazy.force svalue else Lazy.force lvalue
- let compute_to_env ~reduce ~unwind k e ens t =
- let svalue =
- lazy (
- match t with
- Cic.Const _ as t -> unwind k e ens t
- | t -> reduce (k,e,ens,t,[])
- ) in
- let lvalue =
- lazy (unwind k e ens t)
- in
- fun ~reduce ->
- if reduce then Lazy.force svalue else Lazy.force lvalue
- end
-;;
-
-module ClosuresOnStackByValueFromEnvOrEnsStrategy =
- struct
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- and stack_term = config
- and env_term = config
- and ens_term = config
-
- let to_env config = config
- let to_ens config = config
- let from_stack config = config
- let from_stack_list_for_unwind ~unwind l = List.map unwind l
- let from_env v = v
- let from_ens v = v
- let from_env_for_unwind ~unwind config = unwind config
- let from_ens_for_unwind ~unwind config = unwind config
- let stack_to_env ~reduce ~unwind config = reduce config
- let compute_to_env ~reduce ~unwind k e ens t = (k,e,ens,t,[])
- let compute_to_stack ~reduce ~unwind config = config
- end
-;;
-
-module ClosuresOnStackByValueFromEnvOrEnsByNameOnConstantsStrategy =
- struct
- type stack_term =
- int * Cic.term list * Cic.term Cic.explicit_named_substitution * Cic.term
- type env_term = Cic.term
- type ens_term = Cic.term
- type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
- let to_env v = v
- let to_ens v = v
- let from_stack ~unwind (k,e,ens,t) = unwind k e ens t
- let from_stack_list ~unwind l = List.map (from_stack ~unwind) l
- let from_env v = v
- let from_ens v = v
- let from_env_for_unwind ~unwind v = v
- let from_ens_for_unwind ~unwind v = v
- let stack_to_env ~reduce ~unwind (k,e,ens,t) =
- match t with
- Cic.Const _ as t -> unwind k e ens t
- | t -> reduce (k,e,ens,t,[])
- let compute_to_env ~reduce ~unwind k e ens t =
- unwind k e ens t
- let compute_to_stack ~reduce ~unwind k e ens t = (k,e,ens,t)
- end
-;;
-
-}}} *)
-
-module Reduction(RS : Strategy) =
- struct
+module Reduction(RS : Strategy) = struct
type env = RS.env_term list
type stack = RS.stack_term list
- type config = int * env * NCic.term * stack
+ type config = int * env * C.term * stack
let rec unwind (k,e,t,s) =
let t =
if k = 0 then t
else
NCicSubstitution.psubst ~avoid_beta_redexes:true
- true 0 (RS.from_env_for_unwind ~unwind) e t
+ (RS.from_env_for_unwind ~unwind) e t
in
if s = [] then t
- else NCic.Appl(t::(RS.from_stack_list_for_unwind ~unwind s))
+ else C.Appl(t::(RS.from_stack_list_for_unwind ~unwind s))
;;
let list_nth l n = try List.nth l n with Failure _ -> assert false;;
| _,_ -> assert false
;;
- let rec reduce ~delta ?(subst = []) context : config -> config =
+ let rec reduce ~delta ?(subst = []) context : config -> config * bool =
let rec aux = function
- | k, e, NCic.Rel n, s when n <= k ->
+ | k, e, C.Rel n, s when n <= k ->
let k',e',t',s' = RS.from_env (list_nth e (n-1)) in
aux (k',e',t',s'@s)
- | k, _, NCic.Rel n, s as config (* when n > k *) ->
- (match List.nth context (n - 1 - k) with
- | (_,NCic.Decl _) -> config
- | (_,NCic.Def (x,_)) -> aux (0,[],NCicSubstitution.lift (n - k) x,s))
- | (k, e, NCic.Meta (n,l), s) as config ->
+ | k, _, C.Rel n, s as config (* when n > k *) ->
+ let x= try Some (List.nth context (n - 1 - k)) with Failure _ -> None in
+ (match x with
+ | Some(_,C.Def(x,_)) -> aux (0,[],NCicSubstitution.lift (n - k) x,s)
+ | _ -> config, true)
+ | (k, e, C.Meta (n,l), s) as config ->
(try
let _,_, term,_ = NCicUtils.lookup_subst n subst in
aux (k, e, NCicSubstitution.subst_meta l term,s)
- with NCicUtils.Subst_not_found _ -> config)
- | (_, _, NCic.Sort _, _) as config -> config
- | (_, _, NCic.Implicit _, _) -> assert false
- | (_, _, NCic.Prod _, _) as config -> config
- | (_, _, NCic.Lambda _, []) as config -> config
- | (k, e, NCic.Lambda (_,_,t), p::s) ->
+ with NCicUtils.Subst_not_found _ -> config, true)
+ | (_, _, C.Implicit _, _) -> assert false
+ | (_, _, C.Sort _, _)
+ | (_, _, C.Prod _, _)
+ | (_, _, C.Lambda _, []) as config -> config, true
+ | (k, e, C.Lambda (_,_,t), p::s) ->
aux (k+1, (RS.stack_to_env ~reduce:aux ~unwind p)::e, t,s)
- | (k, e, NCic.LetIn (_,_,m,t), s) ->
+ | (k, e, C.LetIn (_,_,m,t), s) ->
let m' = RS.compute_to_env ~reduce:aux ~unwind k e m in
aux (k+1, m'::e, t, s)
- | (_, _, NCic.Appl [], _) -> assert false
- | (k, e, NCic.Appl (he::tl), s) ->
+ | (_, _, C.Appl ([]|[_]), _) -> assert false
+ | (k, e, C.Appl (he::tl), s) ->
let tl' =
List.map (fun t->RS.compute_to_stack ~reduce:aux ~unwind (k,e,t,[])) tl
in
aux (k, e, he, tl' @ s)
- | (_, _, NCic.Const
- (NReference.Ref (_,_,NReference.Def) as refer), s) as config ->
- let _,_,body,_,_,height = NCicEnvironment.get_checked_def refer in
- if delta >= height then config else aux (0, [], body, s)
- | (_, _, NCic.Const (NReference.Ref
- (_,_,NReference.Fix (_,recindex)) as refer),s) as config ->
- let _,_,body,_, _, height = NCicEnvironment.get_checked_fix refer in
- if delta >= height then config else
+ | (_, _, C.Const
+ (Ref.Ref (_,Ref.Def height) as refer), s) as config ->
+ if delta >= height then
+ config, false
+ else
+ let _,_,body,_,_,_ = NCicEnvironment.get_checked_def refer in
+ aux (0, [], body, s)
+ | (_, _, C.Const (Ref.Ref (_,
+ (Ref.Decl|Ref.Ind _|Ref.Con _|Ref.CoFix _))), _) as config ->
+ config, true
+ | (_, _, (C.Const (Ref.Ref
+ (_,Ref.Fix (fixno,recindex,height)) as refer) as head),s) as config ->
+(* if delta >= height then config else *)
(match
try Some (RS.from_stack (List.nth s recindex))
with Failure _ -> None
with
- | None -> config
+ | None -> config, true
| Some recparam ->
+ let fixes,_,_ = NCicEnvironment.get_checked_fixes_or_cofixes refer in
match reduce ~delta:0 ~subst context recparam with
- | (_,_,NCic.Const (NReference.Ref (_,_,NReference.Con _)), _) as c ->
+ | (_,_,C.Const (Ref.Ref (_,Ref.Con _)), _) as c, _
+ when delta >= height ->
+ let new_s =
+ replace recindex s (RS.compute_to_stack ~reduce:aux ~unwind c)
+ in
+ (0, [], head, new_s), false
+ | (_,_,C.Const (Ref.Ref (_,Ref.Con _)), _) as c, _ ->
let new_s =
replace recindex s (RS.compute_to_stack ~reduce:aux ~unwind c)
in
+ let _,_,_,_,body = List.nth fixes fixno in
aux (0, [], body, new_s)
- | _ -> config)
- | (_, _, NCic.Const _, _) as config -> config
- | (k, e, NCic.Match (_,_,term,pl),s) as config ->
+ | _ -> config, true)
+ | (k, e, C.Match (_,_,term,pl),s) as config ->
let decofix = function
- | (_,_,NCic.Const(NReference.Ref(_,_,NReference.CoFix _)as refer),s)->
- let _,_,body,_,_,_ = NCicEnvironment.get_checked_cofix refer in
- reduce ~delta:0 ~subst context (0,[],body,s)
+ | (_,_,C.Const(Ref.Ref(_,Ref.CoFix c)as refer),s)->
+ let cofixes,_,_ =
+ NCicEnvironment.get_checked_fixes_or_cofixes refer in
+ let _,_,_,_,body = List.nth cofixes c in
+ let c,_ = reduce ~delta:0 ~subst context (0,[],body,s) in
+ c
| config -> config
in
- (match decofix (reduce ~delta:0 ~subst context (k,e,term,[])) with
- | (_, _, NCic.Const (NReference.Ref (_,_,NReference.Con (_,j))),[]) ->
+ let match_head = k,e,term,[] in
+ let reduced,_ = reduce ~delta:0 ~subst context match_head in
+ (match decofix reduced with
+ | (_, _, C.Const (Ref.Ref (_,Ref.Con (_,j,_))),[]) ->
aux (k, e, List.nth pl (j-1), s)
- | (_, _, NCic.Const
- (NReference.Ref (_,_,NReference.Con (_,j)) as refer), s') ->
- let leftno = NCicEnvironment.get_indty_leftno refer in
- let _,params = HExtlib.split_nth leftno s' in
+ | (_, _, C.Const (Ref.Ref (_,Ref.Con (_,j,lno))), s')->
+ let _,params = HExtlib.split_nth lno s' in
aux (k, e, List.nth pl (j-1), params@s)
- | _ -> config)
+ | _ -> config, true)
in
aux
;;
- let whd ?(delta=0) ?(subst=[]) context t =
- unwind (reduce ~delta ~subst context (0, [], t, []))
+ let whd ?(delta=0) ~subst context t =
+ unwind (fst (reduce ~delta ~subst context (0, [], t, [])))
;;
end
;;
-(* {{{ ROTTO = rompe l'unificazione poiche' riduce gli argomenti di un'applicazione
- senza ridurre la testa
-module R = Reduction CallByNameStrategy;; OK 56.368s
-module R = Reduction CallByValueStrategy;; ROTTO
-module R = Reduction CallByValueStrategyByNameOnConstants;; ROTTO
-module R = Reduction LazyCallByValueStrategy;; ROTTO
-module R = Reduction LazyCallByValueStrategyByNameOnConstants;; ROTTO
-module R = Reduction LazyCallByNameStrategy;; OK 0m56.398s
-module R = Reduction
- LazyCallByValueByNameOnConstantsWhenFromStack_ByNameStrategyWhenFromEnvOrEns;;
- OK 59.058s
-module R = Reduction ClosuresOnStackByValueFromEnvOrEnsStrategy;; OK 58.583s
-module R = Reduction
- ClosuresOnStackByValueFromEnvOrEnsByNameOnConstantsStrategy;; OK 58.094s
-module R = Reduction(ClosuresOnStackByValueFromEnvOrEnsStrategy);; OK 58.127s
-module R = Reduction(CallByValueByNameForUnwind);;
-module R = Reduction(CallByNameStrategy);;
-module R = Reduction(ClosuresOnStackByValueFromEnvOrEnsStrategy);;}}} *)
module RS = CallByValueByNameForUnwind';;
-
module R = Reduction(RS);;
-module U = UriManager;;
let whd = R.whd
-(*
-let whd =
- let profiler_whd = HExtlib.profile ~enable:profile "are_convertible.whd" in
- fun ?(delta=true) ?(subst=[]) context t ->
- profiler_whd.HExtlib.profile (whd ~delta ~subst context) t
-*)
-
-(*
-
- (* mimic ocaml (<< 3.08) "=" behaviour. Tests physical equality first then
- * fallbacks to structural equality *)
let (===) x y = Pervasives.compare x y = 0 ;;
-module C = NCic
+let get_relevance = ref (fun ~metasenv:_ ~subst:_ _ _ -> assert false);;
+
+let set_get_relevance f = get_relevance := f;;
(* t1, t2 must be well-typed *)
-let are_convertible whd ?(subst=[]) ?(metasenv=[]) =
- let heuristic = ref true in
- let rec aux test_equality_only context t1 t2 =
- let rec aux2 test_equality_only t1 t2 =
+let are_convertible ~metasenv ~subst =
+ let rec aux test_eq_only context t1 t2 =
+ let alpha_eq test_eq_only t1 t2 =
if t1 === t2 then
true
else
match (t1,t2) with
- | (C.Rel n1, C.Rel n2) -> n1 = n2
-
- | (C.Sort (C.Type a), C.Sort (C.Type b)) -> a <= b
- | (C.Sort (C.Type a), C.Sort (C.Type b)) when test_equality_only -> a=b
- | (C.Sort s1,C.Sort (C.Type _)) -> (not test_equality_only)
- | (C.Sort s1, C.Sort s2) -> s1 = s2
+ | (C.Sort (C.Type a), C.Sort (C.Type b)) when not test_eq_only ->
+ NCicEnvironment.universe_leq a b
+ | (C.Sort (C.Type a), C.Sort (C.Type b)) ->
+ NCicEnvironment.universe_eq a b
+ | (C.Sort C.Prop,C.Sort (C.Type _)) -> (not test_eq_only)
+ | (C.Sort C.Prop, C.Sort C.Prop) -> true
| (C.Prod (name1,s1,t1), C.Prod(_,s2,t2)) ->
aux true context s1 s2 &&
- aux test_equality_only ((name1, C.Decl s1)::context) t1 t2
- | (C.Lambda (name1,s1,t1), C.Lambda(_,s2,t2)) ->
- aux test_equality_only context s1 s2 && (* sure?! *)
- aux test_equality_only ((name1, C.Decl s1)::context) t1 t2
-
- | (C.Meta (n1,l1), C.Meta (n2,l2)) ->
- if n1 = n2 then
- let b2, ugraph1 =
- let l1 = CicUtil.clean_up_local_context subst metasenv n1 l1 in
- let l2 = CicUtil.clean_up_local_context subst metasenv n2 l2 in
- List.fold_left2
- (fun (b,ugraph) t1 t2 ->
- if b then
- match t1,t2 with
- None,_
- | _,None -> true,ugraph
- | Some t1',Some t2' ->
- aux test_equality_only context t1' t2' ugraph
- else
- false,ugraph
- ) (true,ugraph) l1 l2
- in
- if b2 then true,ugraph1 else false,ugraph
- else
- false,ugraph
- | C.Meta (n1,l1), _ ->
- (try
- let _,term,_ = NCicUtils.lookup_subst n1 subst in
- let term' = CicSubstitution.subst_meta l1 term in
- aux test_equality_only context term' t2 ugraph
- with CicUtil.Subst_not_found _ -> false,ugraph)
- | _, C.Meta (n2,l2) ->
- (try
- let _,term,_ = CicUtil.lookup_subst n2 subst in
- let term' = CicSubstitution.subst_meta l2 term in
- aux test_equality_only context t1 term' ugraph
- with CicUtil.Subst_not_found _ -> false,ugraph)
- | (C.LetIn (name1,s1,t1), C.LetIn(_,s2,t2)) ->
- let b',ugraph' = aux test_equality_only context s1 s2 ugraph in
- if b' then
- aux test_equality_only
- ((Some (name1, (C.Def (s1,None))))::context) t1 t2 ugraph'
- else
- false,ugraph
- | (C.Appl l1, C.Appl l2) ->
- (try
- List.fold_right2
- (fun x y (b,ugraph) ->
- if b then
- aux test_equality_only context x y ugraph
- else
- false,ugraph) l1 l2 (true,ugraph)
- with
- Invalid_argument _ -> false,ugraph
- )
- | (C.Const (uri1,exp_named_subst1), C.Const (uri2,exp_named_subst2)) ->
- let b' = U.eq uri1 uri2 in
- if b' then
- (try
- List.fold_right2
- (fun (uri1,x) (uri2,y) (b,ugraph) ->
- if b && U.eq uri1 uri2 then
- aux test_equality_only context x y ugraph
- else
- false,ugraph
- ) exp_named_subst1 exp_named_subst2 (true,ugraph)
- with
- Invalid_argument _ -> false,ugraph
- )
- else
- false,ugraph
- | (C.MutInd (uri1,i1,exp_named_subst1),
- C.MutInd (uri2,i2,exp_named_subst2)
- ) ->
- let b' = U.eq uri1 uri2 && i1 = i2 in
- if b' then
- (try
- List.fold_right2
- (fun (uri1,x) (uri2,y) (b,ugraph) ->
- if b && U.eq uri1 uri2 then
- aux test_equality_only context x y ugraph
- else
- false,ugraph
- ) exp_named_subst1 exp_named_subst2 (true,ugraph)
- with
- Invalid_argument _ -> false,ugraph
- )
- else
- false,ugraph
- | (C.MutConstruct (uri1,i1,j1,exp_named_subst1),
- C.MutConstruct (uri2,i2,j2,exp_named_subst2)
- ) ->
- let b' = U.eq uri1 uri2 && i1 = i2 && j1 = j2 in
- if b' then
- (try
- List.fold_right2
- (fun (uri1,x) (uri2,y) (b,ugraph) ->
- if b && U.eq uri1 uri2 then
- aux test_equality_only context x y ugraph
- else
- false,ugraph
- ) exp_named_subst1 exp_named_subst2 (true,ugraph)
- with
- Invalid_argument _ -> false,ugraph
- )
- else
- false,ugraph
- | (C.MutCase (uri1,i1,outtype1,term1,pl1),
- C.MutCase (uri2,i2,outtype2,term2,pl2)) ->
- let b' = U.eq uri1 uri2 && i1 = i2 in
- if b' then
- let b'',ugraph''=aux test_equality_only context
- outtype1 outtype2 ugraph in
- if b'' then
- let b''',ugraph'''= aux test_equality_only context
- term1 term2 ugraph'' in
- List.fold_right2
- (fun x y (b,ugraph) ->
- if b then
- aux test_equality_only context x y ugraph
- else
- false,ugraph)
- pl1 pl2 (b''',ugraph''')
- else
- false,ugraph
- else
- false,ugraph
- | (C.Fix (i1,fl1), C.Fix (i2,fl2)) ->
- let tys,_ =
- List.fold_left
- (fun (types,len) (n,_,ty,_) ->
- (Some (C.Name n,(C.Decl (CicSubstitution.lift len ty)))::types,
- len+1)
- ) ([],0) fl1
- in
- if i1 = i2 then
- List.fold_right2
- (fun (_,recindex1,ty1,bo1) (_,recindex2,ty2,bo2) (b,ugraph) ->
- if b && recindex1 = recindex2 then
- let b',ugraph' = aux test_equality_only context ty1 ty2
- ugraph in
- if b' then
- aux test_equality_only (tys@context) bo1 bo2 ugraph'
- else
- false,ugraph
- else
- false,ugraph)
- fl1 fl2 (true,ugraph)
- else
- false,ugraph
- | (C.CoFix (i1,fl1), C.CoFix (i2,fl2)) ->
- let tys,_ =
- List.fold_left
- (fun (types,len) (n,ty,_) ->
- (Some (C.Name n,(C.Decl (CicSubstitution.lift len ty)))::types,
- len+1)
- ) ([],0) fl1
- in
- if i1 = i2 then
- List.fold_right2
- (fun (_,ty1,bo1) (_,ty2,bo2) (b,ugraph) ->
- if b then
- let b',ugraph' = aux test_equality_only context ty1 ty2
- ugraph in
- if b' then
- aux test_equality_only (tys@context) bo1 bo2 ugraph'
- else
- false,ugraph
- else
- false,ugraph)
- fl1 fl2 (true,ugraph)
- else
- false,ugraph
- | C.Cast (bo,_),t -> aux2 test_equality_only bo t ugraph
- | t,C.Cast (bo,_) -> aux2 test_equality_only t bo ugraph
- | (C.Implicit _, _) | (_, C.Implicit _) -> assert false
- | (_,_) -> false,ugraph
+ aux test_eq_only ((name1, C.Decl s1)::context) t1 t2
+ | (C.Lambda (name1,s1,t1), C.Lambda(_,_,t2)) ->
+ (* thanks to inversion of well typedness, the source
+ * of these lambdas must be already convertible *)
+ aux test_eq_only ((name1, C.Decl s1)::context) t1 t2
+ | (C.LetIn (name1,ty1,s1,t1), C.LetIn(_,ty2,s2,t2)) ->
+ aux test_eq_only context ty1 ty2 &&
+ aux test_eq_only context s1 s2 &&
+ aux test_eq_only ((name1, C.Def (s1,ty1))::context) t1 t2
+
+ | (C.Meta (n1,(s1, C.Irl _)), C.Meta (n2,(s2, C.Irl _)))
+ when n1 = n2 && s1 = s2 -> true
+ | (C.Meta (n1,(s1, l1)), C.Meta (n2,(s2, l2))) when n1 = n2 &&
+ let l1 = NCicUtils.expand_local_context l1 in
+ let l2 = NCicUtils.expand_local_context l2 in
+ (try List.for_all2
+ (fun t1 t2 -> aux test_eq_only context
+ (NCicSubstitution.lift s1 t1)
+ (NCicSubstitution.lift s2 t2))
+ l1 l2
+ with Invalid_argument "List.for_all2" ->
+ prerr_endline ("Meta " ^ string_of_int n1 ^
+ " occurrs with local contexts of different lenght\n"^
+ NCicPp.ppterm ~metasenv ~subst ~context t1 ^ " === " ^
+ NCicPp.ppterm ~metasenv ~subst ~context t2);
+ assert false) -> true
+
+ | C.Meta (n1,l1), _ ->
+ (try
+ let _,_,term,_ = NCicUtils.lookup_subst n1 subst in
+ let term = NCicSubstitution.subst_meta l1 term in
+ aux test_eq_only context term t2
+ with NCicUtils.Subst_not_found _ -> false)
+ | _, C.Meta (n2,l2) ->
+ (try
+ let _,_,term,_ = NCicUtils.lookup_subst n2 subst in
+ let term = NCicSubstitution.subst_meta l2 term in
+ aux test_eq_only context t1 term
+ with NCicUtils.Subst_not_found _ -> false)
+
+ | (C.Appl ((C.Const r1) as hd1::tl1), C.Appl (C.Const r2::tl2))
+ when (Ref.eq r1 r2 &&
+ List.length (E.get_relevance r1) >= List.length tl1) ->
+ let relevance = E.get_relevance r1 in
+ let relevance = match r1 with
+ | Ref.Ref (_,Ref.Con (_,_,lno)) ->
+ let _,relevance = HExtlib.split_nth lno relevance in
+ HExtlib.mk_list false lno @ relevance
+ | _ -> relevance
+ in
+ (try
+ HExtlib.list_forall_default3_var
+ (fun t1 t2 b -> not b || aux true context t1 t2 )
+ tl1 tl2 true relevance
+ with Invalid_argument _ -> false
+ | HExtlib.FailureAt fail ->
+ let relevance =
+ !get_relevance ~metasenv ~subst context hd1 tl1 in
+ let _,relevance = HExtlib.split_nth fail relevance in
+ let b,relevance = (match relevance with
+ | [] -> assert false
+ | b::tl -> b,tl) in
+ if (not b) then
+ let _,tl1 = HExtlib.split_nth (fail+1) tl1 in
+ let _,tl2 = HExtlib.split_nth (fail+1) tl2 in
+ try
+ HExtlib.list_forall_default3
+ (fun t1 t2 b -> not b || aux true context t1 t2)
+ tl1 tl2 true relevance
+ with Invalid_argument _ -> false
+ else false)
+
+ | (C.Appl (hd1::tl1), C.Appl (hd2::tl2)) ->
+ aux test_eq_only context hd1 hd2 &&
+ let relevance = !get_relevance ~metasenv ~subst context hd1 tl1 in
+ (try
+ HExtlib.list_forall_default3
+ (fun t1 t2 b -> not b || aux true context t1 t2)
+ tl1 tl2 true relevance
+ with Invalid_argument _ -> false)
+
+ | (C.Match (Ref.Ref (_,Ref.Ind (_,tyno,_)) as ref1,outtype1,term1,pl1),
+ C.Match (ref2,outtype2,term2,pl2)) ->
+ let _,_,itl,_,_ = E.get_checked_indtys ref1 in
+ let _,_,ty,_ = List.nth itl tyno in
+ let rec remove_prods ~subst context ty =
+ let ty = whd ~subst context ty in
+ match ty with
+ | C.Sort _ -> ty
+ | C.Prod (name,so,ta) -> remove_prods ~subst ((name,(C.Decl so))::context) ta
+ | _ -> assert false
+ in
+ let is_prop =
+ match remove_prods ~subst [] ty with
+ | C.Sort C.Prop -> true
+ | _ -> false
+ in
+ Ref.eq ref1 ref2 &&
+ aux test_eq_only context outtype1 outtype2 &&
+ (is_prop || aux test_eq_only context term1 term2) &&
+ (try List.for_all2 (aux test_eq_only context) pl1 pl2
+ with Invalid_argument _ -> false)
+ | (C.Implicit _, _) | (_, C.Implicit _) -> assert false
+ | (_,_) -> false
in
- let res =
- if !heuristic then
- aux2 test_equality_only t1 t2 ugraph
- else
- false,ugraph
- in
- if fst res = true then
- res
- else
-begin
-(*if !heuristic then prerr_endline ("NON FACILE: " ^ CicPp.ppterm t1 ^ " <===> " ^ CicPp.ppterm t2);*)
- (* heuristic := false; *)
- debug t1 [t2] "PREWHD";
-(*prerr_endline ("PREWHD: " ^ CicPp.ppterm t1 ^ " <===> " ^ CicPp.ppterm t2);*)
-(*
-prerr_endline ("PREWHD: " ^ CicPp.ppterm t1 ^ " <===> " ^ CicPp.ppterm t2);
- let t1' = whd ?delta:(Some true) ?subst:(Some subst) context t1 in
- let t2' = whd ?delta:(Some true) ?subst:(Some subst) context t2 in
- debug t1' [t2'] "POSTWHD";
-*)
-let rec convert_machines ugraph =
- function
- [] -> true,ugraph
- | ((k1,env1,ens1,h1,s1),(k2,env2,ens2,h2,s2))::tl ->
- let (b,ugraph) as res =
- aux2 test_equality_only
- (R.unwind (k1,env1,ens1,h1,[])) (R.unwind (k2,env2,ens2,h2,[])) ugraph
+ if alpha_eq test_eq_only t1 t2 then
+ true
+ else
+ let height_of = function
+ | C.Const (Ref.Ref (_,Ref.Def h))
+ | C.Const (Ref.Ref (_,Ref.Fix (_,_,h)))
+ | C.Appl(C.Const(Ref.Ref(_,Ref.Def h))::_)
+ | C.Appl(C.Const(Ref.Ref(_,Ref.Fix (_,_,h)))::_) -> h
+ | _ -> 0
in
- if b then
- let problems =
+ let put_in_whd m1 m2 =
+ R.reduce ~delta:max_int ~subst context m1,
+ R.reduce ~delta:max_int ~subst context m2
+ in
+ let small_delta_step
+ ((_,_,t1,_ as m1), norm1 as x1) ((_,_,t2,_ as m2), norm2 as x2)
+ =
+ assert(not (norm1 && norm2));
+ if norm1 then
+ x1, R.reduce ~delta:(height_of t2 -1) ~subst context m2
+ else if norm2 then
+ R.reduce ~delta:(height_of t1 -1) ~subst context m1, x2
+ else
+ let h1 = height_of t1 in
+ let h2 = height_of t2 in
+ let delta = if h1 = h2 then max 0 (h1 -1) else min h1 h2 in
+ R.reduce ~delta ~subst context m1,
+ R.reduce ~delta ~subst context m2
+ in
+ let rec convert_machines test_eq_only
+ ((k1,e1,t1,s1),norm1 as m1),((k2,e2,t2,s2), norm2 as m2)
+ =
+ (alpha_eq test_eq_only
+ (R.unwind (k1,e1,t1,[])) (R.unwind (k2,e2,t2,[])) &&
+ let relevance =
+ match t1 with
+ C.Const r -> NCicEnvironment.get_relevance r
+ | _ -> [] in
try
- Some
- (List.combine
- (List.map
- (fun si-> R.reduce ~delta:false ~subst context(RS.from_stack si))
- s1)
- (List.map
- (fun si-> R.reduce ~delta:false ~subst context(RS.from_stack si))
- s2)
- @ tl)
- with
- Invalid_argument _ -> None
- in
- match problems with
- None -> false,ugraph
- | Some problems -> convert_machines ugraph problems
- else
- res
-in
- convert_machines ugraph
- [R.reduce ~delta:true ~subst context (0,[],[],t1,[]),
- R.reduce ~delta:true ~subst context (0,[],[],t2,[])]
-(*prerr_endline ("POSTWH: " ^ CicPp.ppterm t1' ^ " <===> " ^ CicPp.ppterm t2');*)
-(*
- aux2 test_equality_only t1' t2' ugraph
-*)
-end
+ HExtlib.list_forall_default3
+ (fun t1 t2 b ->
+ not b ||
+ let t1 = RS.from_stack t1 in
+ let t2 = RS.from_stack t2 in
+ convert_machines true (put_in_whd t1 t2)) s1 s2 true relevance
+ with Invalid_argument _ -> false) ||
+ (not (norm1 && norm2) && convert_machines test_eq_only (small_delta_step m1 m2))
+ in
+ convert_machines test_eq_only (put_in_whd (0,[],t1,[]) (0,[],t2,[]))
in
- aux false (*c t1 t2 ugraph *)
+ aux false
;;
-*)
-(* {{{ DEBUGGING ONLY
-let whd ?(delta=true) ?(subst=[]) context t =
- let res = whd ~delta ~subst context t in
- let rescsc = CicReductionNaif.whd ~delta ~subst context t in
- if not (fst (are_convertible CicReductionNaif.whd ~subst context res rescsc CicUniv.empty_ugraph)) then
- begin
- debug_print (lazy ("PRIMA: " ^ CicPp.ppterm t)) ;
- flush stderr ;
- debug_print (lazy ("DOPO: " ^ CicPp.ppterm res)) ;
- flush stderr ;
- debug_print (lazy ("CSC: " ^ CicPp.ppterm rescsc)) ;
- flush stderr ;
-fdebug := 0 ;
-let _ = are_convertible CicReductionNaif.whd ~subst context res rescsc CicUniv.empty_ugraph in
- assert false ;
- end
- else
- res
+let rec head_beta_reduce ?(delta=max_int) ?(upto=(-1)) t l =
+ match upto, t, l with
+ | 0, C.Appl l1, _ -> C.Appl (l1 @ l)
+ | 0, t, [] -> t
+ | 0, t, _ -> C.Appl (t::l)
+ | _, C.Appl (hd::tl), _ -> head_beta_reduce ~delta ~upto hd (tl @ l)
+ | _, C.Lambda(_,_,bo), arg::tl ->
+ let bo = NCicSubstitution.subst arg bo in
+ head_beta_reduce ~delta ~upto:(upto - 1) bo tl
+ | _, C.Const (Ref.Ref (_, Ref.Def height) as re), _
+ when delta <= height ->
+ let _, _, bo, _, _, _ = NCicEnvironment.get_checked_def re in
+ head_beta_reduce ~upto ~delta bo l
+ | _, t, [] -> t
+ | _, t, _ -> C.Appl (t::l)
;;
- }}} *)
-(*let are_convertible = are_convertible whd*)
+let head_beta_reduce ?delta ?upto t = head_beta_reduce ?delta ?upto t [];;
-(* {{{ let profiler_other_whd = HExtlib.profile ~enable:profile "~are_convertible.whd"
-let whd ?(delta=true) ?(subst=[]) context t =
- let foo () =
- whd ~delta ~subst context t
- in
- profiler_other_whd.HExtlib.profile foo ()
- }}} *)
+type stack_item = RS.stack_term
+type environment_item = RS.env_term
-(* {{{ let rec normalize ?(delta=true) ?(subst=[]) ctx term =
- let module C = Cic in
- let t = whd ~delta ~subst ctx term in
- let aux = normalize ~delta ~subst in
- let decl name t = Some (name, C.Decl t) in
- match t with
- | C.Rel n -> t
- | C.Var (uri,exp_named_subst) ->
- C.Var (uri, List.map (fun (n,t) -> n,aux ctx t) exp_named_subst)
- | C.Meta (i,l) ->
- C.Meta (i,List.map (function Some t -> Some (aux ctx t) | None -> None) l)
- | C.Sort _ -> t
- | C.Implicit _ -> t
- | C.Cast (te,ty) -> C.Cast (aux ctx te, aux ctx ty)
- | C.Prod (n,s,t) ->
- let s' = aux ctx s in
- C.Prod (n, s', aux ((decl n s')::ctx) t)
- | C.Lambda (n,s,t) ->
- let s' = aux ctx s in
- C.Lambda (n, s', aux ((decl n s')::ctx) t)
- | C.LetIn (n,s,t) ->
- (* the term is already in weak head normal form *)
- assert false
- | C.Appl (h::l) -> C.Appl (h::(List.map (aux ctx) l))
- | C.Appl [] -> assert false
- | C.Const (uri,exp_named_subst) ->
- C.Const (uri, List.map (fun (n,t) -> n,aux ctx t) exp_named_subst)
- | C.MutInd (uri,typeno,exp_named_subst) ->
- C.MutInd (uri,typeno, List.map (fun (n,t) -> n,aux ctx t) exp_named_subst)
- | C.MutConstruct (uri,typeno,consno,exp_named_subst) ->
- C.MutConstruct (uri, typeno, consno,
- List.map (fun (n,t) -> n,aux ctx t) exp_named_subst)
- | C.MutCase (sp,i,outt,t,pl) ->
- C.MutCase (sp,i, aux ctx outt, aux ctx t, List.map (aux ctx) pl)
-(*CSC: to be completed, I suppose *)
- | C.Fix _ -> t
- | C.CoFix _ -> t
-
-let normalize ?delta ?subst ctx term =
-(* prerr_endline ("NORMALIZE:" ^ CicPp.ppterm term); *)
- let t = normalize ?delta ?subst ctx term in
-(* prerr_endline ("NORMALIZED:" ^ CicPp.ppterm t); *)
- t
- }}} *)
-
-(* {{{ performs an head beta/cast reduction
-let rec head_beta_reduce ?(delta=false) ?(upto=(-1)) t =
- match upto with
- 0 -> t
- | n ->
- match t with
- (Cic.Appl (Cic.Lambda (_,_,t)::he'::tl')) ->
- let he'' = CicSubstitution.subst he' t in
- if tl' = [] then
- he''
- else
- let he''' =
- match he'' with
- Cic.Appl l -> Cic.Appl (l@tl')
- | _ -> Cic.Appl (he''::tl')
- in
- head_beta_reduce ~delta ~upto:(upto - 1) he'''
- | Cic.Cast (te,_) -> head_beta_reduce ~delta ~upto te
- | Cic.Appl (Cic.Const (uri,ens)::tl) as t when delta=true ->
- let bo =
- match fst (CicEnvironment.get_cooked_obj CicUniv.empty_ugraph uri) with
- Cic.Constant (_,bo,_,_,_) -> bo
- | Cic.Variable _ -> raise ReferenceToVariable
- | Cic.CurrentProof (_,_,bo,_,_,_) -> Some bo
- | Cic.InductiveDefinition _ -> raise ReferenceToInductiveDefinition
- in
- (match bo with
- None -> t
- | Some bo ->
- head_beta_reduce ~upto
- ~delta (Cic.Appl ((CicSubstitution.subst_vars ens bo)::tl)))
- | Cic.Const (uri,ens) as t when delta=true ->
- let bo =
- match fst (CicEnvironment.get_cooked_obj CicUniv.empty_ugraph uri) with
- Cic.Constant (_,bo,_,_,_) -> bo
- | Cic.Variable _ -> raise ReferenceToVariable
- | Cic.CurrentProof (_,_,bo,_,_,_) -> Some bo
- | Cic.InductiveDefinition _ -> raise ReferenceToInductiveDefinition
- in
- (match bo with
- None -> t
- | Some bo ->
- head_beta_reduce ~delta ~upto (CicSubstitution.subst_vars ens bo))
- | t -> t
- }}} *)
+type machine = int * environment_item list * NCic.term * stack_item list
-(* {{{
-let are_convertible ?subst ?metasenv context t1 t2 ugraph =
- let before = Unix.gettimeofday () in
- let res = are_convertible ?subst ?metasenv context t1 t2 ugraph in
- let after = Unix.gettimeofday () in
- let diff = after -. before in
- if diff > 0.1 then
- begin
- let nc = List.map (function None -> None | Some (n,_) -> Some n) context in
- prerr_endline
- ("\n#(" ^ string_of_float diff ^ "):\n" ^ CicPp.pp t1 nc ^ "\n<=>\n" ^ CicPp.pp t2 nc);
- end;
- res
- }}} *)
+let reduce_machine = R.reduce
+let from_stack = RS.from_stack
+let unwind = R.unwind
(* vim:set foldmethod=marker: *)