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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* $Id$ *)
(*i*)
open Util
open Names
open Sign
open Term
open Libnames
open Nametab
open Evd
(*i*)
(* Untyped intermediate terms, after ASTs and before constr. *)
(* locs here refers to the ident's location, not whole pat *)
(* the last argument of PatCstr is a possible alias ident for the pattern *)
type cases_pattern =
| PatVar of loc * name
| PatCstr of loc * constructor * cases_pattern list * name
let cases_pattern_loc = function
PatVar(loc,_) -> loc
| PatCstr(loc,_,_,_) -> loc
type patvar = identifier
type rawsort = RProp of Term.contents | RType of Univ.universe option
type binder_kind = BProd | BLambda | BLetIn
type binding_kind = Explicit | Implicit
type quantified_hypothesis = AnonHyp of int | NamedHyp of identifier
type 'a explicit_bindings = (loc * quantified_hypothesis * 'a) list
type 'a bindings =
| ImplicitBindings of 'a list
| ExplicitBindings of 'a explicit_bindings
| NoBindings
type 'a with_bindings = 'a * 'a bindings
type 'a cast_type =
| CastConv of cast_kind * 'a
| CastCoerce (* Cast to a base type (eg, an underlying inductive type) *)
type rawconstr =
| RRef of (loc * global_reference)
| RVar of (loc * identifier)
| REvar of loc * existential_key * rawconstr list option
| RPatVar of loc * (bool * patvar) (* Used for patterns only *)
| RApp of loc * rawconstr * rawconstr list
| RLambda of loc * name * binding_kind * rawconstr * rawconstr
| RProd of loc * name * binding_kind * rawconstr * rawconstr
| RLetIn of loc * name * rawconstr * rawconstr
| RCases of loc * rawconstr option * tomatch_tuples * cases_clauses
| RLetTuple of loc * name list * (name * rawconstr option) *
rawconstr * rawconstr
| RLetPattern of loc * tomatch_tuple * cases_clause
| RIf of loc * rawconstr * (name * rawconstr option) * rawconstr * rawconstr
| RRec of loc * fix_kind * identifier array * rawdecl list array *
rawconstr array * rawconstr array
| RSort of loc * rawsort
| RHole of (loc * hole_kind)
| RCast of loc * rawconstr * rawconstr cast_type
| RDynamic of loc * Dyn.t
and rawdecl = name * binding_kind * rawconstr option * rawconstr
and fix_recursion_order = RStructRec | RWfRec of rawconstr | RMeasureRec of rawconstr
and fix_kind =
| RFix of ((int option * fix_recursion_order) array * int)
| RCoFix of int
and predicate_pattern =
name * (loc * inductive * int * name list) option
and tomatch_tuple = (rawconstr * predicate_pattern)
and tomatch_tuples = tomatch_tuple list
and cases_clause = (loc * identifier list * cases_pattern list * rawconstr)
and cases_clauses = cases_clause list
let cases_predicate_names tml =
List.flatten (List.map (function
| (tm,(na,None)) -> [na]
| (tm,(na,Some (_,_,_,nal))) -> na::nal) tml)
(*i - if PRec (_, names, arities, bodies) is in env then arities are
typed in env too and bodies are typed in env enriched by the
arities incrementally lifted
[On pourrait plutot mettre les arités aves le type qu'elles auront
dans le contexte servant à typer les body ???]
- boolean in POldCase means it is recursive
i*)
let map_rawdecl f (na,k,obd,ty) = (na,k,Option.map f obd,f ty)
let map_rawconstr f = function
| RVar (loc,id) -> RVar (loc,id)
| RApp (loc,g,args) -> RApp (loc,f g, List.map f args)
| RLambda (loc,na,bk,ty,c) -> RLambda (loc,na,bk,f ty,f c)
| RProd (loc,na,bk,ty,c) -> RProd (loc,na,bk,f ty,f c)
| RLetIn (loc,na,b,c) -> RLetIn (loc,na,f b,f c)
| RCases (loc,rtntypopt,tml,pl) ->
RCases (loc,Option.map f rtntypopt,
List.map (fun (tm,x) -> (f tm,x)) tml,
List.map (fun (loc,idl,p,c) -> (loc,idl,p,f c)) pl)
| RLetTuple (loc,nal,(na,po),b,c) ->
RLetTuple (loc,nal,(na,Option.map f po),f b,f c)
| RLetPattern (loc,(b,x),(loc',idl,p,c)) ->
RLetPattern (loc,(f b,x),(loc',idl,p,f c))
| RIf (loc,c,(na,po),b1,b2) ->
RIf (loc,f c,(na,Option.map f po),f b1,f b2)
| RRec (loc,fk,idl,bl,tyl,bv) ->
RRec (loc,fk,idl,Array.map (List.map (map_rawdecl f)) bl,
Array.map f tyl,Array.map f bv)
| RCast (loc,c,k) -> RCast (loc,f c, match k with CastConv (k,t) -> CastConv (k, f t) | x -> x)
| (RSort _ | RHole _ | RRef _ | REvar _ | RPatVar _ | RDynamic _) as x -> x
(*
let name_app f e = function
| Name id -> let (id, e) = f id e in (Name id, e)
| Anonymous -> Anonymous, e
let fold_ident g idl e =
let (idl,e) =
Array.fold_right
(fun id (idl,e) -> let id,e = g id e in (id::idl,e)) idl ([],e)
in (Array.of_list idl,e)
let map_rawconstr_with_binders_loc loc g f e = function
| RVar (_,id) -> RVar (loc,id)
| RApp (_,a,args) -> RApp (loc,f e a, List.map (f e) args)
| RLambda (_,na,ty,c) ->
let na,e = name_app g e na in RLambda (loc,na,f e ty,f e c)
| RProd (_,na,ty,c) ->
let na,e = name_app g e na in RProd (loc,na,f e ty,f e c)
| RLetIn (_,na,b,c) ->
let na,e = name_app g e na in RLetIn (loc,na,f e b,f e c)
| RCases (_,tyopt,tml,pl) ->
(* We don't modify pattern variable since we don't traverse patterns *)
let g' id e = snd (g id e) in
let h (_,idl,p,c) = (loc,idl,p,f (List.fold_right g' idl e) c) in
RCases
(loc,Option.map (f e) tyopt,List.map (f e) tml, List.map h pl)
| RRec (_,fk,idl,tyl,bv) ->
let idl',e' = fold_ident g idl e in
RRec (loc,fk,idl',Array.map (f e) tyl,Array.map (f e') bv)
| RCast (_,c,t) -> RCast (loc,f e c,f e t)
| RSort (_,x) -> RSort (loc,x)
| RHole (_,x) -> RHole (loc,x)
| RRef (_,x) -> RRef (loc,x)
| REvar (_,x,l) -> REvar (loc,x,l)
| RPatVar (_,x) -> RPatVar (loc,x)
| RDynamic (_,x) -> RDynamic (loc,x)
*)
let occur_rawconstr id =
let rec occur = function
| RVar (loc,id') -> id = id'
| RApp (loc,f,args) -> (occur f) or (List.exists occur args)
| RLambda (loc,na,bk,ty,c) -> (occur ty) or ((na <> Name id) & (occur c))
| RProd (loc,na,bk,ty,c) -> (occur ty) or ((na <> Name id) & (occur c))
| RLetIn (loc,na,b,c) -> (occur b) or ((na <> Name id) & (occur c))
| RCases (loc,rtntypopt,tml,pl) ->
(occur_option rtntypopt)
or (List.exists (fun (tm,_) -> occur tm) tml)
or (List.exists occur_pattern pl)
| RLetTuple (loc,nal,rtntyp,b,c) ->
occur_return_type rtntyp id
or (occur b) or (not (List.mem (Name id) nal) & (occur c))
| RLetPattern (loc, (b, _), p) -> (occur b) or (occur_pattern p)
| RIf (loc,c,rtntyp,b1,b2) ->
occur_return_type rtntyp id or (occur c) or (occur b1) or (occur b2)
| RRec (loc,fk,idl,bl,tyl,bv) ->
not (array_for_all4 (fun fid bl ty bd ->
let rec occur_fix = function
[] -> not (occur ty) && (fid=id or not(occur bd))
| (na,k,bbd,bty)::bl ->
not (occur bty) &&
(match bbd with
Some bd -> not (occur bd)
| _ -> true) &&
(na=Name id or not(occur_fix bl)) in
occur_fix bl)
idl bl tyl bv)
| RCast (loc,c,k) -> (occur c) or (match k with CastConv (_, t) -> occur t | CastCoerce -> false)
| (RSort _ | RHole _ | RRef _ | REvar _ | RPatVar _ | RDynamic _) -> false
and occur_pattern (loc,idl,p,c) = not (List.mem id idl) & (occur c)
and occur_option = function None -> false | Some p -> occur p
and occur_return_type (na,tyopt) id = na <> Name id & occur_option tyopt
in occur
let add_name_to_ids set na =
match na with
| Anonymous -> set
| Name id -> Idset.add id set
let free_rawvars =
let rec vars bounded vs = function
| RVar (loc,id') -> if Idset.mem id' bounded then vs else Idset.add id' vs
| RApp (loc,f,args) -> List.fold_left (vars bounded) vs (f::args)
| RLambda (loc,na,_,ty,c) | RProd (loc,na,_,ty,c) | RLetIn (loc,na,ty,c) ->
let vs' = vars bounded vs ty in
let bounded' = add_name_to_ids bounded na in
vars bounded' vs' c
| RCases (loc,rtntypopt,tml,pl) ->
let vs1 = vars_option bounded vs rtntypopt in
let vs2 = List.fold_left (fun vs (tm,_) -> vars bounded vs tm) vs1 tml in
List.fold_left (vars_pattern bounded) vs2 pl
| RLetTuple (loc,nal,rtntyp,b,c) ->
let vs1 = vars_return_type bounded vs rtntyp in
let vs2 = vars bounded vs1 b in
let bounded' = List.fold_left add_name_to_ids bounded nal in
vars bounded' vs2 c
| RLetPattern (loc, (c, _), p) -> vars_pattern bounded (vars bounded vs c) p
| RIf (loc,c,rtntyp,b1,b2) ->
let vs1 = vars_return_type bounded vs rtntyp in
let vs2 = vars bounded vs1 c in
let vs3 = vars bounded vs2 b1 in
vars bounded vs3 b2
| RRec (loc,fk,idl,bl,tyl,bv) ->
let bounded' = Array.fold_right Idset.add idl bounded in
let vars_fix i vs fid =
let vs1,bounded1 =
List.fold_left
(fun (vs,bounded) (na,k,bbd,bty) ->
let vs' = vars_option bounded vs bbd in
let vs'' = vars bounded vs' bty in
let bounded' = add_name_to_ids bounded na in
(vs'',bounded')
)
(vs,bounded')
bl.(i)
in
let vs2 = vars bounded1 vs1 tyl.(i) in
vars bounded1 vs2 bv.(i)
in
array_fold_left_i vars_fix vs idl
| RCast (loc,c,k) -> let v = vars bounded vs c in
(match k with CastConv (_,t) -> vars bounded v t | _ -> v)
| (RSort _ | RHole _ | RRef _ | REvar _ | RPatVar _ | RDynamic _) -> vs
and vars_pattern bounded vs (loc,idl,p,c) =
let bounded' = List.fold_right Idset.add idl bounded in
vars bounded' vs c
and vars_option bounded vs = function None -> vs | Some p -> vars bounded vs p
and vars_return_type bounded vs (na,tyopt) =
let bounded' = add_name_to_ids bounded na in
vars_option bounded' vs tyopt
in
fun rt ->
let vs = vars Idset.empty Idset.empty rt in
Idset.elements vs
let loc_of_rawconstr = function
| RRef (loc,_) -> loc
| RVar (loc,_) -> loc
| REvar (loc,_,_) -> loc
| RPatVar (loc,_) -> loc
| RApp (loc,_,_) -> loc
| RLambda (loc,_,_,_,_) -> loc
| RProd (loc,_,_,_,_) -> loc
| RLetIn (loc,_,_,_) -> loc
| RLetPattern (loc,_,_) -> loc
| RCases (loc,_,_,_) -> loc
| RLetTuple (loc,_,_,_,_) -> loc
| RIf (loc,_,_,_,_) -> loc
| RRec (loc,_,_,_,_,_) -> loc
| RSort (loc,_) -> loc
| RHole (loc,_) -> loc
| RCast (loc,_,_) -> loc
| RDynamic (loc,_) -> loc
(**********************************************************************)
(* Conversion from rawconstr to cases pattern, if possible *)
let rec cases_pattern_of_rawconstr na = function
| RVar (loc,id) when na<>Anonymous ->
(* Unable to manage the presence of both an alias and a variable *)
raise Not_found
| RVar (loc,id) -> PatVar (loc,Name id)
| RHole (loc,_) -> PatVar (loc,na)
| RRef (loc,ConstructRef cstr) ->
PatCstr (loc,cstr,[],na)
| RApp (loc,RRef (_,ConstructRef cstr),l) ->
PatCstr (loc,cstr,List.map (cases_pattern_of_rawconstr Anonymous) l,na)
| _ -> raise Not_found
(* Turn a closed cases pattern into a rawconstr *)
let rec rawconstr_of_closed_cases_pattern_aux = function
| PatCstr (loc,cstr,[],Anonymous) ->
RRef (loc,ConstructRef cstr)
| PatCstr (loc,cstr,l,Anonymous) ->
let ref = RRef (loc,ConstructRef cstr) in
RApp (loc,ref, List.map rawconstr_of_closed_cases_pattern_aux l)
| _ -> raise Not_found
let rawconstr_of_closed_cases_pattern = function
| PatCstr (loc,cstr,l,na) ->
na,rawconstr_of_closed_cases_pattern_aux (PatCstr (loc,cstr,l,Anonymous))
| _ ->
raise Not_found
(**********************************************************************)
(* Reduction expressions *)
type 'a raw_red_flag = {
rBeta : bool;
rIota : bool;
rZeta : bool;
rDelta : bool; (* true = delta all but rConst; false = delta only on rConst*)
rConst : 'a list
}
let all_flags =
{rBeta = true; rIota = true; rZeta = true; rDelta = true; rConst = []}
type 'a or_var = ArgArg of 'a | ArgVar of identifier located
type 'a with_occurrences = int or_var list * 'a
type ('a,'b) red_expr_gen =
| Red of bool
| Hnf
| Simpl of 'a with_occurrences option
| Cbv of 'b raw_red_flag
| Lazy of 'b raw_red_flag
| Unfold of 'b with_occurrences list
| Fold of 'a list
| Pattern of 'a with_occurrences list
| ExtraRedExpr of string
| CbvVm
type ('a,'b) may_eval =
| ConstrTerm of 'a
| ConstrEval of ('a,'b) red_expr_gen * 'a
| ConstrContext of (loc * identifier) * 'a
| ConstrTypeOf of 'a
|