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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2012 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* Created under Benjamin Werner account by Bruno Barras to implement
a call-by-value conversion algorithm and a lazy reduction machine
with sharing, Nov 1996 *)
(* Addition of zeta-reduction (let-in contraction) by Hugo Herbelin, Oct 2000 *)
(* Irreversibility of opacity by Bruno Barras *)
(* Cleaning and lightening of the kernel by Bruno Barras, Nov 2001 *)
(* Equal inductive types by Jacek Chrzaszcz as part of the module
system, Aug 2002 *)
open Util
open Names
open Term
open Univ
open Declarations
open Environ
open Closure
open Esubst
let unfold_reference ((ids, csts), infos) k =
match k with
| VarKey id when not (Idpred.mem id ids) -> None
| ConstKey cst when not (Cpred.mem cst csts) -> None
| _ -> unfold_reference infos k
let rec is_empty_stack = function
[] -> true
| Zupdate _::s -> is_empty_stack s
| Zshift _::s -> is_empty_stack s
| _ -> false
(* Compute the lift to be performed on a term placed in a given stack *)
let el_stack el stk =
let n =
List.fold_left
(fun i z ->
match z with
Zshift n -> i+n
| _ -> i)
0
stk in
el_shft n el
let compare_stack_shape stk1 stk2 =
let rec compare_rec bal stk1 stk2 =
match (stk1,stk2) with
([],[]) -> bal=0
| ((Zupdate _|Zshift _)::s1, _) -> compare_rec bal s1 stk2
| (_, (Zupdate _|Zshift _)::s2) -> compare_rec bal stk1 s2
| (Zapp l1::s1, _) -> compare_rec (bal+Array.length l1) s1 stk2
| (_, Zapp l2::s2) -> compare_rec (bal-Array.length l2) stk1 s2
| (Zcase(c1,_,_)::s1, Zcase(c2,_,_)::s2) ->
bal=0 (* && c1.ci_ind = c2.ci_ind *) && compare_rec 0 s1 s2
| (Zfix(_,a1)::s1, Zfix(_,a2)::s2) ->
bal=0 && compare_rec 0 a1 a2 && compare_rec 0 s1 s2
| (_,_) -> false in
compare_rec 0 stk1 stk2
type lft_constr_stack_elt =
Zlapp of (lift * fconstr) array
| Zlfix of (lift * fconstr) * lft_constr_stack
| Zlcase of case_info * lift * fconstr * fconstr array
and lft_constr_stack = lft_constr_stack_elt list
let rec zlapp v = function
Zlapp v2 :: s -> zlapp (Array.append v v2) s
| s -> Zlapp v :: s
let pure_stack lfts stk =
let rec pure_rec lfts stk =
match stk with
[] -> (lfts,[])
| zi::s ->
(match (zi,pure_rec lfts s) with
(Zupdate _,lpstk) -> lpstk
| (Zshift n,(l,pstk)) -> (el_shft n l, pstk)
| (Zapp a, (l,pstk)) ->
(l,zlapp (Array.map (fun t -> (l,t)) a) pstk)
| (Zfix(fx,a),(l,pstk)) ->
let (lfx,pa) = pure_rec l a in
(l, Zlfix((lfx,fx),pa)::pstk)
| (Zcase(ci,p,br),(l,pstk)) ->
(l,Zlcase(ci,l,p,br)::pstk)) in
snd (pure_rec lfts stk)
(****************************************************************************)
(* Reduction Functions *)
(****************************************************************************)
let whd_betaiota t =
whd_val (create_clos_infos betaiota empty_env) (inject t)
let nf_betaiota t =
norm_val (create_clos_infos betaiota empty_env) (inject t)
let whd_betaiotazeta x =
match kind_of_term x with
| (Sort _|Var _|Meta _|Evar _|Const _|Ind _|Construct _|
Prod _|Lambda _|Fix _|CoFix _) -> x
| _ -> whd_val (create_clos_infos betaiotazeta empty_env) (inject x)
let whd_betadeltaiota env t =
match kind_of_term t with
| (Sort _|Meta _|Evar _|Ind _|Construct _|
Prod _|Lambda _|Fix _|CoFix _) -> t
| _ -> whd_val (create_clos_infos betadeltaiota env) (inject t)
let whd_betadeltaiota_nolet env t =
match kind_of_term t with
| (Sort _|Meta _|Evar _|Ind _|Construct _|
Prod _|Lambda _|Fix _|CoFix _|LetIn _) -> t
| _ -> whd_val (create_clos_infos betadeltaiotanolet env) (inject t)
(* Beta *)
let beta_appvect c v =
let rec stacklam env t stack =
match kind_of_term t, stack with
Lambda(_,_,c), arg::stacktl -> stacklam (arg::env) c stacktl
| _ -> applist (substl env t, stack) in
stacklam [] c (Array.to_list v)
let betazeta_appvect n c v =
let rec stacklam n env t stack =
if n = 0 then applist (substl env t, stack) else
match kind_of_term t, stack with
Lambda(_,_,c), arg::stacktl -> stacklam (n-1) (arg::env) c stacktl
| LetIn(_,b,_,c), _ -> stacklam (n-1) (b::env) c stack
| _ -> anomaly "Not enough lambda/let's" in
stacklam n [] c (Array.to_list v)
(********************************************************************)
(* Conversion *)
(********************************************************************)
(* Conversion utility functions *)
type 'a conversion_function = env -> 'a -> 'a -> Univ.constraints
type 'a trans_conversion_function = transparent_state -> env -> 'a -> 'a -> Univ.constraints
exception NotConvertible
exception NotConvertibleVect of int
let compare_stacks f fmind lft1 stk1 lft2 stk2 cuniv =
let rec cmp_rec pstk1 pstk2 cuniv =
match (pstk1,pstk2) with
| (z1::s1, z2::s2) ->
let cu1 = cmp_rec s1 s2 cuniv in
(match (z1,z2) with
| (Zlapp a1,Zlapp a2) -> array_fold_right2 f a1 a2 cu1
| (Zlfix(fx1,a1),Zlfix(fx2,a2)) ->
let cu2 = f fx1 fx2 cu1 in
cmp_rec a1 a2 cu2
| (Zlcase(ci1,l1,p1,br1),Zlcase(ci2,l2,p2,br2)) ->
if not (fmind ci1.ci_ind ci2.ci_ind) then
raise NotConvertible;
let cu2 = f (l1,p1) (l2,p2) cu1 in
array_fold_right2 (fun c1 c2 -> f (l1,c1) (l2,c2)) br1 br2 cu2
| _ -> assert false)
| _ -> cuniv in
if compare_stack_shape stk1 stk2 then
cmp_rec (pure_stack lft1 stk1) (pure_stack lft2 stk2) cuniv
else raise NotConvertible
(* Convertibility of sorts *)
(* The sort cumulativity is
Prop <= Set <= Type 1 <= ... <= Type i <= ...
and this holds whatever Set is predicative or impredicative
*)
type conv_pb =
| CONV
| CUMUL
let sort_cmp pb s0 s1 cuniv =
match (s0,s1) with
| (Prop c1, Prop c2) when pb = CUMUL ->
if c1 = Null or c2 = Pos then cuniv (* Prop <= Set *)
else raise NotConvertible
| (Prop c1, Prop c2) ->
if c1 = c2 then cuniv else raise NotConvertible
| (Prop c1, Type u) when pb = CUMUL -> assert (is_univ_variable u); cuniv
| (Type u1, Type u2) ->
assert (is_univ_variable u2);
(match pb with
| CONV -> enforce_eq u1 u2 cuniv
| CUMUL -> enforce_geq u2 u1 cuniv)
| (_, _) -> raise NotConvertible
let conv_sort env s0 s1 = sort_cmp CONV s0 s1 empty_constraint
let conv_sort_leq env s0 s1 = sort_cmp CUMUL s0 s1 empty_constraint
let rec no_arg_available = function
| [] -> true
| Zupdate _ :: stk -> no_arg_available stk
| Zshift _ :: stk -> no_arg_available stk
| Zapp v :: stk -> Array.length v = 0 && no_arg_available stk
| Zcase _ :: _ -> true
| Zfix _ :: _ -> true
let rec no_nth_arg_available n = function
| [] -> true
| Zupdate _ :: stk -> no_nth_arg_available n stk
| Zshift _ :: stk -> no_nth_arg_available n stk
| Zapp v :: stk ->
let k = Array.length v in
if n >= k then no_nth_arg_available (n-k) stk
else false
| Zcase _ :: _ -> true
| Zfix _ :: _ -> true
let rec no_case_available = function
| [] -> true
| Zupdate _ :: stk -> no_case_available stk
| Zshift _ :: stk -> no_case_available stk
| Zapp _ :: stk -> no_case_available stk
| Zcase _ :: _ -> false
| Zfix _ :: _ -> true
let in_whnf (t,stk) =
match fterm_of t with
| (FLetIn _ | FCases _ | FApp _ | FCLOS _ | FLIFT _ | FCast _) -> false
| FLambda _ -> no_arg_available stk
| FConstruct _ -> no_case_available stk
| FCoFix _ -> no_case_available stk
| FFix(((ri,n),(_,_,_)),_) -> no_nth_arg_available ri.(n) stk
| (FFlex _ | FProd _ | FEvar _ | FInd _ | FAtom _ | FRel _) -> true
| FLOCKED -> assert false
(* Conversion between [lft1]term1 and [lft2]term2 *)
let rec ccnv cv_pb l2r infos lft1 lft2 term1 term2 cuniv =
eqappr cv_pb l2r infos (lft1, (term1,[])) (lft2, (term2,[])) cuniv
(* Conversion between [lft1](hd1 v1) and [lft2](hd2 v2) *)
and eqappr cv_pb l2r infos (lft1,st1) (lft2,st2) cuniv =
Util.check_for_interrupt ();
(* First head reduce both terms *)
let rec whd_both (t1,stk1) (t2,stk2) =
let st1' = whd_stack (snd infos) t1 stk1 in
let st2' = whd_stack (snd infos) t2 stk2 in
(* Now, whd_stack on term2 might have modified st1 (due to sharing),
and st1 might not be in whnf anymore. If so, we iterate ccnv. *)
if in_whnf st1' then (st1',st2') else whd_both st1' st2' in
let ((hd1,v1),(hd2,v2)) = whd_both st1 st2 in
let appr1 = (lft1,(hd1,v1)) and appr2 = (lft2,(hd2,v2)) in
(* compute the lifts that apply to the head of the term (hd1 and hd2) *)
let el1 = el_stack lft1 v1 in
let el2 = el_stack lft2 v2 in
match (fterm_of hd1, fterm_of hd2) with
(* case of leaves *)
| (FAtom a1, FAtom a2) ->
(match kind_of_term a1, kind_of_term a2 with
| (Sort s1, Sort s2) ->
if not (is_empty_stack v1 && is_empty_stack v2) then
anomaly "conversion was given ill-typed terms (Sort)";
sort_cmp cv_pb s1 s2 cuniv
| (Meta n, Meta m) ->
if n=m
then convert_stacks l2r infos lft1 lft2 v1 v2 cuniv
else raise NotConvertible
| _ -> raise NotConvertible)
| (FEvar ((ev1,args1),env1), FEvar ((ev2,args2),env2)) ->
if ev1=ev2 then
let u1 = convert_stacks l2r infos lft1 lft2 v1 v2 cuniv in
convert_vect l2r infos el1 el2
(Array.map (mk_clos env1) args1)
(Array.map (mk_clos env2) args2) u1
else raise NotConvertible
(* 2 index known to be bound to no constant *)
| (FRel n, FRel m) ->
if reloc_rel n el1 = reloc_rel m el2
then convert_stacks l2r infos lft1 lft2 v1 v2 cuniv
else raise NotConvertible
(* 2 constants, 2 local defined vars or 2 defined rels *)
| (FFlex fl1, FFlex fl2) ->
(try (* try first intensional equality *)
if eq_table_key fl1 fl2
then convert_stacks l2r infos lft1 lft2 v1 v2 cuniv
else raise NotConvertible
with NotConvertible ->
(* else the oracle tells which constant is to be expanded *)
let (app1,app2) =
if Conv_oracle.oracle_order l2r fl1 fl2 then
match unfold_reference infos fl1 with
| Some def1 -> ((lft1, whd_stack (snd infos) def1 v1), appr2)
| None ->
(match unfold_reference infos fl2 with
| Some def2 -> (appr1, (lft2, whd_stack (snd infos) def2 v2))
| None -> raise NotConvertible)
else
match unfold_reference infos fl2 with
| Some def2 -> (appr1, (lft2, whd_stack (snd infos) def2 v2))
| None ->
(match unfold_reference infos fl1 with
| Some def1 -> ((lft1, whd_stack (snd infos) def1 v1), appr2)
| None -> raise NotConvertible) in
eqappr cv_pb l2r infos app1 app2 cuniv)
(* other constructors *)
| (FLambda _, FLambda _) ->
(* Inconsistency: we tolerate that v1, v2 contain shift and update but
we throw them away *)
if not (is_empty_stack v1 && is_empty_stack v2) then
anomaly "conversion was given ill-typed terms (FLambda)";
let (_,ty1,bd1) = destFLambda mk_clos hd1 in
let (_,ty2,bd2) = destFLambda mk_clos hd2 in
let u1 = ccnv CONV l2r infos el1 el2 ty1 ty2 cuniv in
ccnv CONV l2r infos (el_lift el1) (el_lift el2) bd1 bd2 u1
| (FProd (_,c1,c2), FProd (_,c'1,c'2)) ->
if not (is_empty_stack v1 && is_empty_stack v2) then
anomaly "conversion was given ill-typed terms (FProd)";
(* Luo's system *)
let u1 = ccnv CONV l2r infos el1 el2 c1 c'1 cuniv in
ccnv cv_pb l2r infos (el_lift el1) (el_lift el2) c2 c'2 u1
(* Eta-expansion on the fly *)
| (FLambda _, _) ->
if v1 <> [] then
anomaly "conversion was given unreduced term (FLambda)";
let (_,_ty1,bd1) = destFLambda mk_clos hd1 in
eqappr CONV l2r infos
(el_lift lft1, (bd1, [])) (el_lift lft2, (hd2, eta_expand_stack v2)) cuniv
| (_, FLambda _) ->
if v2 <> [] then
anomaly "conversion was given unreduced term (FLambda)";
let (_,_ty2,bd2) = destFLambda mk_clos hd2 in
eqappr CONV l2r infos
(el_lift lft1, (hd1, eta_expand_stack v1)) (el_lift lft2, (bd2, [])) cuniv
(* only one constant, defined var or defined rel *)
| (FFlex fl1, _) ->
(match unfold_reference infos fl1 with
| Some def1 ->
eqappr cv_pb l2r infos (lft1, whd_stack (snd infos) def1 v1) appr2 cuniv
| None -> raise NotConvertible)
| (_, FFlex fl2) ->
(match unfold_reference infos fl2 with
| Some def2 ->
eqappr cv_pb l2r infos appr1 (lft2, whd_stack (snd infos) def2 v2) cuniv
| None -> raise NotConvertible)
(* Inductive types: MutInd MutConstruct Fix Cofix *)
| (FInd ind1, FInd ind2) ->
if eq_ind ind1 ind2
then
convert_stacks l2r infos lft1 lft2 v1 v2 cuniv
else raise NotConvertible
| (FConstruct (ind1,j1), FConstruct (ind2,j2)) ->
if j1 = j2 && eq_ind ind1 ind2
then
convert_stacks l2r infos lft1 lft2 v1 v2 cuniv
else raise NotConvertible
| (FFix ((op1,(_,tys1,cl1)),e1), FFix((op2,(_,tys2,cl2)),e2)) ->
if op1 = op2
then
let n = Array.length cl1 in
let fty1 = Array.map (mk_clos e1) tys1 in
let fty2 = Array.map (mk_clos e2) tys2 in
let fcl1 = Array.map (mk_clos (subs_liftn n e1)) cl1 in
let fcl2 = Array.map (mk_clos (subs_liftn n e2)) cl2 in
let u1 = convert_vect l2r infos el1 el2 fty1 fty2 cuniv in
let u2 =
convert_vect l2r infos
(el_liftn n el1) (el_liftn n el2) fcl1 fcl2 u1 in
convert_stacks l2r infos lft1 lft2 v1 v2 u2
else raise NotConvertible
| (FCoFix ((op1,(_,tys1,cl1)),e1), FCoFix((op2,(_,tys2,cl2)),e2)) ->
if op1 = op2
then
let n = Array.length cl1 in
let fty1 = Array.map (mk_clos e1) tys1 in
let fty2 = Array.map (mk_clos e2) tys2 in
let fcl1 = Array.map (mk_clos (subs_liftn n e1)) cl1 in
let fcl2 = Array.map (mk_clos (subs_liftn n e2)) cl2 in
let u1 = convert_vect l2r infos el1 el2 fty1 fty2 cuniv in
let u2 =
convert_vect l2r infos
(el_liftn n el1) (el_liftn n el2) fcl1 fcl2 u1 in
convert_stacks l2r infos lft1 lft2 v1 v2 u2
else raise NotConvertible
(* Should not happen because both (hd1,v1) and (hd2,v2) are in whnf *)
| ( (FLetIn _, _) | (FCases _,_) | (FApp _,_) | (FCLOS _,_) | (FLIFT _,_)
| (_, FLetIn _) | (_,FCases _) | (_,FApp _) | (_,FCLOS _) | (_,FLIFT _)
| (FLOCKED,_) | (_,FLOCKED) ) -> assert false
(* In all other cases, terms are not convertible *)
| _ -> raise NotConvertible
and convert_stacks l2r infos lft1 lft2 stk1 stk2 cuniv =
compare_stacks
(fun (l1,t1) (l2,t2) c -> ccnv CONV l2r infos l1 l2 t1 t2 c)
(eq_ind)
lft1 stk1 lft2 stk2 cuniv
and convert_vect l2r infos lft1 lft2 v1 v2 cuniv =
let lv1 = Array.length v1 in
let lv2 = Array.length v2 in
if lv1 = lv2
then
let rec fold n univ =
if n >= lv1 then univ
else
let u1 = ccnv CONV l2r infos lft1 lft2 v1.(n) v2.(n) univ in
fold (n+1) u1 in
fold 0 cuniv
else raise NotConvertible
let clos_fconv trans cv_pb l2r evars env t1 t2 =
let infos = trans, create_clos_infos ~evars betaiotazeta env in
ccnv cv_pb l2r infos el_id el_id (inject t1) (inject t2) empty_constraint
let trans_fconv reds cv_pb l2r evars env t1 t2 =
if eq_constr t1 t2 then empty_constraint
else clos_fconv reds cv_pb l2r evars env t1 t2
let trans_conv_cmp ?(l2r=false) conv reds = trans_fconv reds conv l2r (fun _->None)
let trans_conv ?(l2r=false) ?(evars=fun _->None) reds = trans_fconv reds CONV l2r evars
let trans_conv_leq ?(l2r=false) ?(evars=fun _->None) reds = trans_fconv reds CUMUL l2r evars
let fconv = trans_fconv (Idpred.full, Cpred.full)
let conv_cmp ?(l2r=false) cv_pb = fconv cv_pb l2r (fun _->None)
let conv ?(l2r=false) ?(evars=fun _->None) = fconv CONV l2r evars
let conv_leq ?(l2r=false) ?(evars=fun _->None) = fconv CUMUL l2r evars
let conv_leq_vecti ?(l2r=false) ?(evars=fun _->None) env v1 v2 =
array_fold_left2_i
(fun i c t1 t2 ->
let c' =
try conv_leq ~l2r ~evars env t1 t2
with NotConvertible -> raise (NotConvertibleVect i) in
union_constraints c c')
empty_constraint
v1
v2
(* option for conversion *)
let vm_conv = ref (fun cv_pb -> fconv cv_pb false (fun _->None))
let set_vm_conv f = vm_conv := f
let vm_conv cv_pb env t1 t2 =
try
!vm_conv cv_pb env t1 t2
with Not_found | Invalid_argument _ ->
(* If compilation fails, fall-back to closure conversion *)
fconv cv_pb false (fun _->None) env t1 t2
let default_conv = ref (fun cv_pb ?(l2r=false) -> fconv cv_pb l2r (fun _->None))
let set_default_conv f = default_conv := f
let default_conv cv_pb ?(l2r=false) env t1 t2 =
try
!default_conv ~l2r cv_pb env t1 t2
with Not_found | Invalid_argument _ ->
(* If compilation fails, fall-back to closure conversion *)
fconv cv_pb false (fun _->None) env t1 t2
let default_conv_leq = default_conv CUMUL
(*
let convleqkey = Profile.declare_profile "Kernel_reduction.conv_leq";;
let conv_leq env t1 t2 =
Profile.profile4 convleqkey conv_leq env t1 t2;;
let convkey = Profile.declare_profile "Kernel_reduction.conv";;
let conv env t1 t2 =
Profile.profile4 convleqkey conv env t1 t2;;
*)
(********************************************************************)
(* Special-Purpose Reduction *)
(********************************************************************)
(* pseudo-reduction rule:
* [hnf_prod_app env s (Prod(_,B)) N --> B[N]
* with an HNF on the first argument to produce a product.
* if this does not work, then we use the string S as part of our
* error message. *)
let hnf_prod_app env t n =
match kind_of_term (whd_betadeltaiota env t) with
| Prod (_,_,b) -> subst1 n b
| _ -> anomaly "hnf_prod_app: Need a product"
let hnf_prod_applist env t nl =
List.fold_left (hnf_prod_app env) t nl
(* Dealing with arities *)
let dest_prod env =
let rec decrec env m c =
let t = whd_betadeltaiota env c in
match kind_of_term t with
| Prod (n,a,c0) ->
let d = (n,None,a) in
decrec (push_rel d env) (add_rel_decl d m) c0
| _ -> m,t
in
decrec env empty_rel_context
(* The same but preserving lets *)
let dest_prod_assum env =
let rec prodec_rec env l ty =
let rty = whd_betadeltaiota_nolet env ty in
match kind_of_term rty with
| Prod (x,t,c) ->
let d = (x,None,t) in
prodec_rec (push_rel d env) (add_rel_decl d l) c
| LetIn (x,b,t,c) ->
let d = (x,Some b,t) in
prodec_rec (push_rel d env) (add_rel_decl d l) c
| Cast (c,_,_) -> prodec_rec env l c
| _ -> l,rty
in
prodec_rec env empty_rel_context
exception NotArity
let dest_arity env c =
let l, c = dest_prod_assum env c in
match kind_of_term c with
| Sort s -> l,s
| _ -> raise NotArity
let is_arity env c =
try
let _ = dest_arity env c in
true
with NotArity -> false
|