* http://cs.unibo.it/helm/.
*)
-exception CicReductionInternalError;;
+(* $Id$ *)
+
+(* 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
+ CicPp.ppobj (C.Variable ("DEBUG", None, t, [], [])) ^ "\n" ^ i
in
if !fdebug = 0 then
- begin
- print_endline (s ^ "\n" ^ List.fold_right debug_aux (t::env) "") ;
- flush stdout
- end
+ debug_print (lazy (s ^ "\n" ^ List.fold_right debug_aux (t::env) ""))
;;
-exception Impossible of int;;
-exception ReferenceToDefinition;;
-exception ReferenceToAxiom;;
-exception ReferenceToVariable;;
-exception ReferenceToCurrentProof;;
-exception ReferenceToInductiveDefinition;;
+module type Strategy =
+ sig
+ type stack_term
+ type env_term
+ type ens_term
+ type config = int * env_term list * ens_term Cic.explicit_named_substitution * Cic.term * stack_term list
+ val to_env : config -> env_term
+ val to_ens : config -> ens_term
+ val from_stack : stack_term -> config
+ val from_stack_list_for_unwind :
+ unwind: (config -> Cic.term) ->
+ stack_term list -> Cic.term list
+ val from_env : env_term -> config
+ val from_env_for_unwind :
+ unwind: (config -> Cic.term) ->
+ env_term -> Cic.term
+ val from_ens : ens_term -> config
+ val from_ens_for_unwind :
+ unwind: (config -> Cic.term) ->
+ ens_term -> Cic.term
+ val stack_to_env :
+ reduce: (config -> config) ->
+ unwind: (config -> Cic.term) ->
+ stack_term -> env_term
+ val compute_to_env :
+ reduce: (config -> config) ->
+ unwind: (config -> Cic.term) ->
+ int -> env_term list -> ens_term Cic.explicit_named_substitution ->
+ Cic.term -> env_term
+ val compute_to_stack :
+ reduce: (config -> config) ->
+ unwind: (config -> Cic.term) ->
+ config -> stack_term
+ end
+;;
-(* takes a well-typed term *)
-let whd =
- let rec whdaux l =
- let module C = Cic in
- let module S = CicSubstitution in
+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
+;;
+
+
+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 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
- C.Rel _ as t -> if l = [] then t else C.Appl (t::l)
- | C.Var uri as t ->
- (match CicEnvironment.get_cooked_obj uri 0 with
- C.Definition _ -> raise ReferenceToDefinition
- | C.Axiom _ -> raise ReferenceToAxiom
- | C.CurrentProof _ -> raise ReferenceToCurrentProof
- | C.InductiveDefinition _ -> raise ReferenceToInductiveDefinition
- | C.Variable (_,None,_) -> if l = [] then t else C.Appl (t::l)
- | C.Variable (_,Some body,_) -> whdaux l body
- )
- | C.Meta _ as t -> if l = [] then t else C.Appl (t::l)
- | C.Sort _ as t -> t (* l should be empty *)
- | C.Implicit as t -> t
- | C.Cast (te,ty) -> whdaux l te (*CSC E' GIUSTO BUTTARE IL CAST? *)
- | C.Prod _ as t -> t (* l should be empty *)
- | C.Lambda (name,s,t) as t' ->
- (match l with
- [] -> t'
- | he::tl -> whdaux tl (S.subst he t)
- (* when name is Anonimous the substitution should be superfluous *)
- )
- | C.LetIn (n,s,t) -> whdaux l (S.subst (whdaux [] s) t)
- | C.Appl (he::tl) -> whdaux (tl@l) he
- | C.Appl [] -> raise (Impossible 1)
- | C.Const (uri,cookingsno) as t ->
- (match CicEnvironment.get_cooked_obj uri cookingsno with
- C.Definition (_,body,_,_) -> whdaux l body
- | C.Axiom _ -> if l = [] then t else C.Appl (t::l)
- | C.Variable _ -> raise ReferenceToVariable
- | C.CurrentProof (_,_,body,_) -> whdaux l body
- | C.InductiveDefinition _ -> raise ReferenceToInductiveDefinition
- )
- | C.Abst _ as t -> t (*CSC l should be empty ????? *)
- | C.MutInd (uri,_,_) as t -> if l = [] then t else C.Appl (t::l)
- | C.MutConstruct (uri,_,_,_) as t -> if l = [] then t else C.Appl (t::l)
- | C.MutCase (mutind,cookingsno,i,_,term,pl) as t ->
- let decofix =
- function
- C.CoFix (i,fl) as t ->
- let (_,_,body) = List.nth fl i in
- let body' =
- let counter = ref (List.length fl) in
- List.fold_right
- (fun _ -> decr counter ; S.subst (C.CoFix (!counter,fl)))
- fl
- body
- in
- whdaux [] body'
- | C.Appl (C.CoFix (i,fl) :: tl) ->
- let (_,_,body) = List.nth fl i in
- let body' =
- let counter = ref (List.length fl) in
- List.fold_right
- (fun _ -> decr counter ; S.subst (C.CoFix (!counter,fl)))
- fl
- body
- in
- whdaux tl body'
- | t -> t
- in
- (match decofix (whdaux [] term) with
- C.MutConstruct (_,_,_,j) -> whdaux l (List.nth pl (j-1))
- | C.Appl (C.MutConstruct (_,_,_,j) :: tl) ->
- let (arity, r, num_ingredients) =
- match CicEnvironment.get_obj mutind with
- C.InductiveDefinition (tl,ingredients,r) ->
- let (_,_,arity,_) = List.nth tl i
- and num_ingredients =
- List.fold_right
- (fun (k,l) i ->
- if k < cookingsno then i + List.length l else i
- ) ingredients 0
- in
- (arity,r,num_ingredients)
- | _ -> raise WrongUriToInductiveDefinition
- in
- let ts =
- let num_to_eat = r + num_ingredients in
- let rec eat_first =
- function
- (0,l) -> l
- | (n,he::tl) when n > 0 -> eat_first (n - 1, tl)
- | _ -> raise (Impossible 5)
- in
- eat_first (num_to_eat,tl)
- in
- whdaux (ts@l) (List.nth pl (j-1))
- | C.Abst _| C.Cast _ | C.Implicit ->
- raise (Impossible 2) (* we don't trust our whd ;-) *)
- | _ -> t
- )
- | C.Fix (i,fl) as t ->
- let (_,recindex,_,body) = List.nth fl i in
- let recparam =
+ 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
+ type env = RS.env_term list
+ type ens = RS.ens_term Cic.explicit_named_substitution
+ type stack = RS.stack_term list
+ type config = int * env * ens * Cic.term * stack
+
+ (* k is the length of the environment e *)
+ (* m is the current depth inside the term *)
+ let rec unwind' m k e ens t =
+ let module C = Cic in
+ let module S = CicSubstitution in
+ if k = 0 && ens = [] then
+ t
+ else
+ let rec unwind_aux m =
+ function
+ C.Rel n as t ->
+ if n <= m then t else
+ let d =
+ try
+ Some (RS.from_env_for_unwind ~unwind (List.nth e (n-m-1)))
+ with _ -> None
+ in
+ (match d with
+ Some t' ->
+ if m = 0 then t' else S.lift m t'
+ | None -> C.Rel (n-k)
+ )
+ | C.Var (uri,exp_named_subst) ->
+(*
+debug_print (lazy ("%%%%%UWVAR " ^ String.concat " ; " (List.map (function (uri,t) -> UriManager.string_of_uri uri ^ " := " ^ CicPp.ppterm t) ens))) ;
+*)
+ if List.exists (function (uri',_) -> UriManager.eq uri' uri) ens then
+ CicSubstitution.lift m (RS.from_ens_for_unwind ~unwind (List.assq uri ens))
+ else
+ let params =
+ let o,_ =
+ CicEnvironment.get_cooked_obj CicUniv.empty_ugraph uri
+ in
+ (match o with
+ C.Constant _ -> raise ReferenceToConstant
+ | C.Variable (_,_,_,params,_) -> params
+ | C.CurrentProof _ -> raise ReferenceToCurrentProof
+ | C.InductiveDefinition _ -> raise ReferenceToInductiveDefinition
+ )
+ in
+ let exp_named_subst' =
+ substaux_in_exp_named_subst params exp_named_subst m
+ in
+ C.Var (uri,exp_named_subst')
+ | C.Meta (i,l) ->
+ let l' =
+ List.map
+ (function
+ None -> None
+ | Some t -> Some (unwind_aux m t)
+ ) l
+ in
+ C.Meta (i, l')
+ | C.Sort _ as t -> t
+ | C.Implicit _ as t -> t
+ | C.Cast (te,ty) -> C.Cast (unwind_aux m te, unwind_aux m ty) (*CSC ???*)
+ | C.Prod (n,s,t) -> C.Prod (n, unwind_aux m s, unwind_aux (m + 1) t)
+ | C.Lambda (n,s,t) -> C.Lambda (n, unwind_aux m s, unwind_aux (m + 1) t)
+ | C.LetIn (n,s,t) -> C.LetIn (n, unwind_aux m s, unwind_aux (m + 1) t)
+ | C.Appl l -> C.Appl (List.map (unwind_aux m) l)
+ | C.Const (uri,exp_named_subst) ->
+ let params =
+ let o,_ =
+ CicEnvironment.get_cooked_obj CicUniv.empty_ugraph uri
+ in
+ (match o with
+ C.Constant (_,_,_,params,_) -> params
+ | C.Variable _ -> raise ReferenceToVariable
+ | C.CurrentProof (_,_,_,_,params,_) -> params
+ | C.InductiveDefinition _ -> raise ReferenceToInductiveDefinition
+ )
+ in
+ let exp_named_subst' =
+ substaux_in_exp_named_subst params exp_named_subst m
+ in
+ C.Const (uri,exp_named_subst')
+ | C.MutInd (uri,i,exp_named_subst) ->
+ let params =
+ let o,_ =
+ CicEnvironment.get_cooked_obj CicUniv.empty_ugraph uri
+ in
+ (match o with
+ C.Constant _ -> raise ReferenceToConstant
+ | C.Variable _ -> raise ReferenceToVariable
+ | C.CurrentProof _ -> raise ReferenceToCurrentProof
+ | C.InductiveDefinition (_,params,_,_) -> params
+ )
+ in
+ let exp_named_subst' =
+ substaux_in_exp_named_subst params exp_named_subst m
+ in
+ C.MutInd (uri,i,exp_named_subst')
+ | C.MutConstruct (uri,i,j,exp_named_subst) ->
+ let params =
+ let o,_ =
+ CicEnvironment.get_cooked_obj CicUniv.empty_ugraph uri
+ in
+ (match o with
+ C.Constant _ -> raise ReferenceToConstant
+ | C.Variable _ -> raise ReferenceToVariable
+ | C.CurrentProof _ -> raise ReferenceToCurrentProof
+ | C.InductiveDefinition (_,params,_,_) -> params
+ )
+ in
+ let exp_named_subst' =
+ substaux_in_exp_named_subst params exp_named_subst m
+ in
+ C.MutConstruct (uri,i,j,exp_named_subst')
+ | C.MutCase (sp,i,outt,t,pl) ->
+ C.MutCase (sp,i,unwind_aux m outt, unwind_aux m t,
+ List.map (unwind_aux m) pl)
+ | C.Fix (i,fl) ->
+ let len = List.length fl in
+ let substitutedfl =
+ List.map
+ (fun (name,i,ty,bo) ->
+ (name, i, unwind_aux m ty, unwind_aux (m+len) bo))
+ fl
+ in
+ C.Fix (i, substitutedfl)
+ | C.CoFix (i,fl) ->
+ let len = List.length fl in
+ let substitutedfl =
+ List.map
+ (fun (name,ty,bo) -> (name, unwind_aux m ty, unwind_aux (m+len) bo))
+ fl
+ in
+ C.CoFix (i, substitutedfl)
+ and substaux_in_exp_named_subst params exp_named_subst' m =
+ (*CSC: Idea di Andrea di ordinare compatibilmente con l'ordine dei params
+ let ens' =
+ List.map (function (uri,t) -> uri, unwind_aux m t) exp_named_subst' @
+ (*CSC: qui liftiamo tutti gli ens anche se magari me ne servono la meta'!!! *)
+ List.map (function (uri,t) -> uri, CicSubstitution.lift m t) ens
+ in
+ let rec filter_and_lift =
+ function
+ [] -> []
+ | uri::tl ->
+ let r = filter_and_lift tl in
+ (try
+ (uri,(List.assq uri ens'))::r
+ with
+ Not_found -> r
+ )
+ in
+ filter_and_lift params
+ *)
+
+ (*CSC: invece di concatenare sarebbe meglio rispettare l'ordine dei params *)
+ (*CSC: e' vero???? una veloce prova non sembra confermare la teoria *)
+
+ (*CSC: codice copiato e modificato dalla cicSubstitution.subst_vars *)
+ (*CSC: codice altamente inefficiente *)
+ let rec filter_and_lift already_instantiated =
+ function
+ [] -> []
+ | (uri,t)::tl when
+ List.for_all
+ (function (uri',_)-> not (UriManager.eq uri uri')) exp_named_subst'
+ &&
+ not (List.mem uri already_instantiated)
+ &&
+ List.mem uri params
+ ->
+ (uri,CicSubstitution.lift m (RS.from_ens_for_unwind ~unwind t)) ::
+ (filter_and_lift (uri::already_instantiated) tl)
+ | _::tl -> filter_and_lift already_instantiated tl
+(*
+ | (uri,_)::tl ->
+debug_print (lazy ("---- SKIPPO " ^ UriManager.string_of_uri uri)) ;
+if List.for_all (function (uri',_) -> not (UriManager.eq uri uri'))
+exp_named_subst' then debug_print (lazy "---- OK1") ;
+debug_print (lazy ("++++ uri " ^ UriManager.string_of_uri uri ^ " not in " ^ String.concat " ; " (List.map UriManager.string_of_uri params))) ;
+if List.mem uri params then debug_print (lazy "---- OK2") ;
+ filter_and_lift tl
+*)
+ in
+ List.map (function (uri,t) -> uri, unwind_aux m t) exp_named_subst' @
+ (filter_and_lift [] (List.rev ens))
+ in
+ unwind_aux m t
+
+ and unwind (k,e,ens,t,s) =
+ let t' = unwind' 0 k e ens t in
+ if s = [] then t' else Cic.Appl (t'::(RS.from_stack_list_for_unwind ~unwind s))
+ ;;
+
+(*
+ let unwind =
+ let profiler_unwind = HExtlib.profile ~enable:profile "are_convertible.unwind" in
+ fun k e ens t ->
+ profiler_unwind.HExtlib.profile (unwind k e ens) t
+ ;;
+*)
+
+ let reduce ~delta ?(subst = []) context : config -> config =
+ let module C = Cic in
+ let module S = CicSubstitution in
+ let rec reduce =
+ function
+ (k, e, _, C.Rel n, s) as config ->
+ let config' =
try
- Some (List.nth l recindex)
+ Some (RS.from_env (List.nth e (n-1)))
with
- _ -> None
+ Failure _ ->
+ try
+ begin
+ match List.nth context (n - 1 - k) with
+ None -> assert false
+ | Some (_,C.Decl _) -> None
+ | Some (_,C.Def (x,_)) -> Some (0,[],[],S.lift (n - k) x,[])
+ end
+ with
+ Failure _ -> None
in
- (match recparam with
- Some recparam ->
- (match whdaux [] recparam with
- C.MutConstruct _
- | C.Appl ((C.MutConstruct _)::_) ->
- let body' =
- let counter = ref (List.length fl) in
- List.fold_right
- (fun _ -> decr counter ; S.subst (C.Fix (!counter,fl)))
- fl
- body
- in
- (* Possible optimization: substituting whd recparam in l *)
- whdaux l body'
- | _ -> if l = [] then t else C.Appl (t::l)
- )
- | None -> if l = [] then t else C.Appl (t::l)
- )
- | C.CoFix (i,fl) as t ->
- (*CSC vecchio codice
- let (_,_,body) = List.nth fl i in
- let body' =
- let counter = ref (List.length fl) in
- List.fold_right
- (fun _ -> decr counter ; S.subst (C.CoFix (!counter,fl)))
- fl
- body
+ (match config' with
+ Some (k',e',ens',t',s') -> reduce (k',e',ens',t',s'@s)
+ | None -> config)
+ | (k, e, ens, C.Var (uri,exp_named_subst), s) as config ->
+ if List.exists (function (uri',_) -> UriManager.eq uri' uri) ens then
+ let (k',e',ens',t',s') = RS.from_ens (List.assq uri ens) in
+ reduce (k',e',ens',t',s'@s)
+ else
+ ( let o,_ =
+ CicEnvironment.get_cooked_obj CicUniv.empty_ugraph uri
+ in
+ match o with
+ C.Constant _ -> raise ReferenceToConstant
+ | C.CurrentProof _ -> raise ReferenceToCurrentProof
+ | C.InductiveDefinition _ -> raise ReferenceToInductiveDefinition
+ | C.Variable (_,None,_,_,_) -> config
+ | C.Variable (_,Some body,_,_,_) ->
+ let ens' = push_exp_named_subst k e ens exp_named_subst in
+ reduce (0, [], ens', body, s)
+ )
+ | (k, e, ens, C.Meta (n,l), s) as config ->
+ (try
+ let (_, term,_) = CicUtil.lookup_subst n subst in
+ reduce (k, e, ens,CicSubstitution.subst_meta l term,s)
+ with CicUtil.Subst_not_found _ -> config)
+ | (_, _, _, C.Sort _, _)
+ | (_, _, _, C.Implicit _, _) as config -> config
+ | (k, e, ens, C.Cast (te,ty), s) ->
+ reduce (k, e, ens, te, s)
+ | (_, _, _, C.Prod _, _) as config -> config
+ | (_, _, _, C.Lambda _, []) as config -> config
+ | (k, e, ens, C.Lambda (_,_,t), p::s) ->
+ reduce (k+1, (RS.stack_to_env ~reduce ~unwind p)::e, ens, t,s)
+ | (k, e, ens, C.LetIn (_,m,t), s) ->
+ let m' = RS.compute_to_env ~reduce ~unwind k e ens m in
+ reduce (k+1, m'::e, ens, t, s)
+ | (_, _, _, C.Appl [], _) -> assert false
+ | (k, e, ens, C.Appl (he::tl), s) ->
+ let tl' =
+ List.map
+ (function t -> RS.compute_to_stack ~reduce ~unwind (k,e,ens,t,[])) tl
in
- whdaux l body'
- *)
- if l = [] then t else C.Appl (t::l)
- in
- whdaux []
+ reduce (k, e, ens, he, (List.append tl') s)
+ | (_, _, _, C.Const _, _) as config when delta=false-> config
+ | (k, e, ens, C.Const (uri,exp_named_subst), s) as config ->
+ (let o,_ =
+ CicEnvironment.get_cooked_obj CicUniv.empty_ugraph uri
+ in
+ match o with
+ C.Constant (_,Some body,_,_,_) ->
+ let ens' = push_exp_named_subst k e ens exp_named_subst in
+ (* constants are closed *)
+ reduce (0, [], ens', body, s)
+ | C.Constant (_,None,_,_,_) -> config
+ | C.Variable _ -> raise ReferenceToVariable
+ | C.CurrentProof (_,_,body,_,_,_) ->
+ let ens' = push_exp_named_subst k e ens exp_named_subst in
+ (* constants are closed *)
+ reduce (0, [], ens', body, s)
+ | C.InductiveDefinition _ -> raise ReferenceToInductiveDefinition
+ )
+ | (_, _, _, C.MutInd _, _)
+ | (_, _, _, C.MutConstruct _, _) as config -> config
+ | (k, e, ens, C.MutCase (mutind,i,outty,term,pl),s) as config ->
+ let decofix =
+ function
+ (k, e, ens, C.CoFix (i,fl), s) ->
+ let (_,_,body) = List.nth fl i in
+ let body' =
+ let counter = ref (List.length fl) in
+ List.fold_right
+ (fun _ -> decr counter ; S.subst (C.CoFix (!counter,fl)))
+ fl
+ body
+ in
+ reduce (k,e,ens,body',s)
+ | config -> config
+ in
+ (match decofix (reduce (k,e,ens,term,[])) with
+ (k', e', ens', C.MutConstruct (_,_,j,_), []) ->
+ reduce (k, e, ens, (List.nth pl (j-1)), [])
+ | (k', e', ens', C.MutConstruct (_,_,j,_), s') ->
+ let (arity, r) =
+ let o,_ =
+ CicEnvironment.get_cooked_obj CicUniv.empty_ugraph mutind
+ in
+ match o with
+ C.InductiveDefinition (s,ingredients,r,_) ->
+ let (_,_,arity,_) = List.nth s i in
+ (arity,r)
+ | _ -> raise WrongUriToInductiveDefinition
+ in
+ let ts =
+ let num_to_eat = r in
+ let rec eat_first =
+ function
+ (0,l) -> l
+ | (n,he::s) when n > 0 -> eat_first (n - 1, s)
+ | _ -> raise (Impossible 5)
+ in
+ eat_first (num_to_eat,s')
+ in
+ reduce (k, e, ens, (List.nth pl (j-1)), ts@s)
+ | (_, _, _, C.Cast _, _)
+ | (_, _, _, C.Implicit _, _) ->
+ raise (Impossible 2) (* we don't trust our whd ;-) *)
+ | config' ->
+ (*CSC: here I am unwinding the configuration and for sure I
+ will do it twice; to avoid this unwinding I should push the
+ "match [] with _" continuation on the stack;
+ another possibility is to just return the original configuration,
+ partially undoing the weak-head computation *)
+ (*this code is uncorrect since term' lives in e' <> e
+ let term' = unwind config' in
+ (k, e, ens, C.MutCase (mutind,i,outty,term',pl),s)
+ *)
+ config)
+ | (k, e, ens, C.Fix (i,fl), s) as config ->
+ let (_,recindex,_,body) = List.nth fl i in
+ let recparam =
+ try
+ Some (RS.from_stack (List.nth s recindex))
+ with
+ _ -> None
+ in
+ (match recparam with
+ Some recparam ->
+ (match reduce recparam with
+ (_,_,_,C.MutConstruct _,_) as config ->
+ let leng = List.length fl in
+ let new_env =
+ let counter = ref 0 in
+ let rec build_env e =
+ if !counter = leng then e
+ else
+ (incr counter ;
+ build_env
+ ((RS.to_env (k,e,ens,C.Fix (!counter -1, fl),[]))::e))
+ in
+ build_env e
+ in
+ let rec replace i s t =
+ match i,s with
+ 0,_::tl -> t::tl
+ | n,he::tl -> he::(replace (n - 1) tl t)
+ | _,_ -> assert false in
+ let new_s =
+ replace recindex s (RS.compute_to_stack ~reduce ~unwind config)
+ in
+ reduce (k+leng, new_env, ens, body, new_s)
+ | _ -> config)
+ | None -> config
+ )
+ | (_,_,_,C.CoFix _,_) as config -> config
+ and push_exp_named_subst k e ens =
+ function
+ [] -> ens
+ | (uri,t)::tl ->
+ push_exp_named_subst k e ((uri,RS.to_ens (k,e,ens,t,[]))::ens) tl
+ in
+ reduce
+ ;;
+
+ let whd ?(delta=true) ?(subst=[]) context t =
+ unwind (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(ClosuresOnStackByValueFromEnvOrEnsStrategy);;*)
+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
+
(* t1, t2 must be well-typed *)
-let are_convertible t1 t2 =
- let module U = UriManager in
- let rec aux t1 t2 =
- debug t1 [t2] "PREWHD";
- (* this trivial euristic cuts down the total time of about five times ;-) *)
- (* this because most of the time t1 and t2 are "sintactically" the same *)
- if t1 = t2 then
- true
- else
+let are_convertible whd ?(subst=[]) ?(metasenv=[]) =
+ let rec aux test_equality_only context t1 t2 ugraph =
+ let aux2 test_equality_only t1 t2 ugraph =
+
+ (* this trivial euristic cuts down the total time of about five times ;-) *)
+ (* this because most of the time t1 and t2 are "sintactically" the same *)
+ if t1 === t2 then
+ true,ugraph
+ else
+ begin
+ let module C = Cic in
+ match (t1,t2) with
+ (C.Rel n1, C.Rel n2) -> (n1 = n2),ugraph
+ | (C.Var (uri1,exp_named_subst1), C.Var (uri2,exp_named_subst2)) ->
+ if U.eq uri1 uri2 then
+ (try
+ List.fold_right2
+ (fun (uri1,x) (uri2,y) (b,ugraph) ->
+ let b',ugraph' = aux test_equality_only context x y ugraph in
+ (U.eq uri1 uri2 && b' && b),ugraph'
+ ) exp_named_subst1 exp_named_subst2 (true,ugraph)
+ with
+ Invalid_argument _ -> false,ugraph
+ )
+ else
+ false,ugraph
+ | (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
+ (* TASSI: CONSTRAINTS *)
+ | (C.Sort (C.Type t1), C.Sort (C.Type t2)) when test_equality_only ->
+ true,(CicUniv.add_eq t2 t1 ugraph)
+ (* TASSI: CONSTRAINTS *)
+ | (C.Sort (C.Type t1), C.Sort (C.Type t2)) ->
+ true,(CicUniv.add_ge t2 t1 ugraph)
+ (* TASSI: CONSTRAINTS *)
+ | (C.Sort s1, C.Sort (C.Type _)) -> (not test_equality_only),ugraph
+ (* TASSI: CONSTRAINTS *)
+ | (C.Sort s1, C.Sort s2) -> (s1 = s2),ugraph
+ | (C.Prod (name1,s1,t1), C.Prod(_,s2,t2)) ->
+ let b',ugraph' = aux true context s1 s2 ugraph in
+ if b' then
+ aux test_equality_only ((Some (name1, (C.Decl s1)))::context)
+ t1 t2 ugraph'
+ else
+ false,ugraph
+ | (C.Lambda (name1,s1,t1), C.Lambda(_,s2,t2)) ->
+ let b',ugraph' = aux test_equality_only context s1 s2 ugraph in
+ if b' then
+ aux test_equality_only ((Some (name1, (C.Decl s1)))::context)
+ t1 t2 ugraph'
+ else
+ 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.map (function (n,_,ty,_) -> Some (C.Name n,(C.Decl ty))) 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.map (function (n,ty,_) -> Some (C.Name n,(C.Decl ty))) 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 _, _) | (_, C.Cast _)
+ | (C.Implicit _, _) | (_, C.Implicit _) -> assert false
+ | (_,_) -> false,ugraph
+ end
+ in
+ debug t1 [t2] "PREWHD";
+ 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";
+ aux2 test_equality_only t1' t2' ugraph
+ in
+ aux false (*c t1 t2 ugraph *)
+;;
+
+(* 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
- let module C = Cic in
- let t1' = whd t1
- and t2' = whd t2 in
- debug t1' [t2'] "POSTWHD";
- match (t1',t2') with
- (C.Rel n1, C.Rel n2) -> n1 = n2
- | (C.Var uri1, C.Var uri2) -> U.eq uri1 uri2
- | (C.Meta n1, C.Meta n2) -> n1 = n2
- | (C.Sort s1, C.Sort s2) -> true (*CSC da finire con gli universi *)
- | (C.Prod (_,s1,t1), C.Prod(_,s2,t2)) ->
- aux s1 s2 && aux t1 t2
- | (C.Lambda (_,s1,t1), C.Lambda(_,s2,t2)) ->
- aux s1 s2 && aux t1 t2
- | (C.Appl l1, C.Appl l2) ->
- (try
- List.fold_right2 (fun x y b -> aux x y && b) l1 l2 true
- with
- Invalid_argument _ -> false
- )
- | (C.Const (uri1,_), C.Const (uri2,_)) ->
- (*CSC: questo commento e' chiaro o delirante? Io lo sto scrivendo *)
- (*CSC: mentre sono delirante, quindi ... *)
- (* WARNING: it is really important that the two cookingsno are not *)
- (* checked for equality. This allows not to cook an object with no *)
- (* ingredients only to update the cookingsno. E.g: if a term t has *)
- (* a reference to a term t1 which does not depend on any variable *)
- (* and t1 depends on a term t2 (that can't depend on any variable *)
- (* because of t1), then t1 cooked at every level could be the same *)
- (* as t1 cooked at level 0. Doing so, t2 will be extended in t *)
- (* with cookingsno 0 and not 2. But this will not cause any trouble*)
- (* if here we don't check that the two cookingsno are equal. *)
- U.eq uri1 uri2
- | (C.MutInd (uri1,k1,i1), C.MutInd (uri2,k2,i2)) ->
- (* WARNIG: see the previous warning *)
- U.eq uri1 uri2 && i1 = i2
- | (C.MutConstruct (uri1,_,i1,j1), C.MutConstruct (uri2,_,i2,j2)) ->
- (* WARNIG: see the previous warning *)
- U.eq uri1 uri2 && i1 = i2 && j1 = j2
- | (C.MutCase (uri1,_,i1,outtype1,term1,pl1),
- C.MutCase (uri2,_,i2,outtype2,term2,pl2)) ->
- (* WARNIG: see the previous warning *)
- (* aux outtype1 outtype2 should be true if aux pl1 pl2 *)
- U.eq uri1 uri2 && i1 = i2 && aux outtype1 outtype2 &&
- aux term1 term2 &&
- List.fold_right2 (fun x y b -> b && aux x y) pl1 pl2 true
- | (C.Fix (i1,fl1), C.Fix (i2,fl2)) ->
- i1 = i2 &&
- List.fold_right2
- (fun (_,recindex1,ty1,bo1) (_,recindex2,ty2,bo2) b ->
- b && recindex1 = recindex2 && aux ty1 ty2 && aux bo1 bo2)
- fl1 fl2 true
- | (C.CoFix (i1,fl1), C.CoFix (i2,fl2)) ->
- i1 = i2 &&
- List.fold_right2
- (fun (_,ty1,bo1) (_,ty2,bo2) b ->
- b && aux ty1 ty2 && aux bo1 bo2)
- fl1 fl2 true
- | (C.Abst _, _) | (_, C.Abst _) | (C.Cast _, _) | (_, C.Cast _)
- | (C.Implicit, _) | (_, C.Implicit) ->
- raise (Impossible 3) (* we don't trust our whd ;-) *)
- | (_,_) -> false
+ 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
- in
- aux t1 t2
+ else
+ res
;;
+*)
+
+let are_convertible = are_convertible whd
+
+let whd = R.whd
+
+(*
+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 ()
+*)
+
+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 =
+ function
+ (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 he'''
+ | Cic.Cast (te,_) -> head_beta_reduce te
+ | t -> t