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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2016 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open Pp
open CErrors
open Term
open Vars
open Environ
open Reduction
open Univ
open Declarations
open Names
open Inductive
open Util
open Nativecode
open Nativevalues
open Context.Rel.Declaration
module RelDecl = Context.Rel.Declaration
(** This module implements normalization by evaluation to OCaml code *)
exception Find_at of int
let invert_tag cst tag reloc_tbl =
try
for j = 0 to Array.length reloc_tbl - 1 do
let tagj,arity = reloc_tbl.(j) in
if Int.equal tag tagj && (cst && Int.equal arity 0 || not(cst || Int.equal arity 0)) then
raise (Find_at j)
else ()
done;raise Not_found
with Find_at j -> (j+1)
let decompose_prod env t =
let (name,dom,codom as res) = destProd (whd_all env t) in
match name with
| Anonymous -> (Name (id_of_string "x"),dom,codom)
| _ -> res
let app_type env c =
let t = whd_all env c in
try destApp t with DestKO -> (t,[||])
let find_rectype_a env c =
let (t, l) = app_type env c in
match kind_of_term t with
| Ind ind -> (ind, l)
| _ -> raise Not_found
(* Instantiate inductives and parameters in constructor type *)
let type_constructor mind mib u typ params =
let s = ind_subst mind mib u in
let ctyp = substl s typ in
let nparams = Array.length params in
if Int.equal nparams 0 then ctyp
else
let _,ctyp = decompose_prod_n nparams ctyp in
substl (List.rev (Array.to_list params)) ctyp
let construct_of_constr_notnative const env tag (mind, _ as ind) u allargs =
let mib,mip = lookup_mind_specif env ind in
let nparams = mib.mind_nparams in
let params = Array.sub allargs 0 nparams in
try
if const then
let ctyp = type_constructor mind mib u (mip.mind_nf_lc.(0)) params in
retroknowledge Retroknowledge.get_vm_decompile_constant_info env (mkInd ind) tag, ctyp
else
raise Not_found
with Not_found ->
let i = invert_tag const tag mip.mind_reloc_tbl in
let ctyp = type_constructor mind mib u (mip.mind_nf_lc.(i-1)) params in
(mkApp(mkConstructU((ind,i),u), params), ctyp)
let construct_of_constr const env tag typ =
let t, l = app_type env typ in
match kind_of_term t with
| Ind (ind,u) ->
construct_of_constr_notnative const env tag ind u l
| _ -> assert false
let construct_of_constr_const env tag typ =
fst (construct_of_constr true env tag typ)
let construct_of_constr_block = construct_of_constr false
let build_branches_type env (mind,_ as _ind) mib mip u params dep p =
let rtbl = mip.mind_reloc_tbl in
(* [build_one_branch i cty] construit le type de la ieme branche (commence
a 0) et les lambda correspondant aux realargs *)
let build_one_branch i cty =
let typi = type_constructor mind mib u cty params in
let decl,indapp = Reductionops.splay_prod env Evd.empty typi in
let decl_with_letin,_ = decompose_prod_assum typi in
let ind,cargs = find_rectype_a env indapp in
let nparams = Array.length params in
let carity = snd (rtbl.(i)) in
let crealargs = Array.sub cargs nparams (Array.length cargs - nparams) in
let codom =
let ndecl = List.length decl in
let papp = mkApp(lift ndecl p,crealargs) in
if dep then
let cstr = ith_constructor_of_inductive (fst ind) (i+1) in
let relargs = Array.init carity (fun i -> mkRel (carity-i)) in
let params = Array.map (lift ndecl) params in
let dep_cstr = mkApp(mkApp(mkConstructU (cstr,snd ind),params),relargs) in
mkApp(papp,[|dep_cstr|])
else papp
in
decl, decl_with_letin, codom
in Array.mapi build_one_branch mip.mind_nf_lc
let build_case_type dep p realargs c =
if dep then mkApp(mkApp(p, realargs), [|c|])
else mkApp(p, realargs)
(* TODO move this function *)
let type_of_rel env n =
env |> lookup_rel n |> RelDecl.get_type |> lift n
let type_of_prop = mkSort type1_sort
let type_of_sort s =
match s with
| Prop _ -> type_of_prop
| Type u -> mkType (Univ.super u)
let type_of_var env id =
let open Context.Named.Declaration in
try env |> lookup_named id |> get_type
with Not_found ->
anomaly ~label:"type_of_var" (str "variable " ++ Id.print id ++ str " unbound")
let sort_of_product env domsort rangsort =
match (domsort, rangsort) with
(* Product rule (s,Prop,Prop) *)
| (_, Prop Null) -> rangsort
(* Product rule (Prop/Set,Set,Set) *)
| (Prop _, Prop Pos) -> rangsort
(* Product rule (Type,Set,?) *)
| (Type u1, Prop Pos) ->
if is_impredicative_set env then
(* Rule is (Type,Set,Set) in the Set-impredicative calculus *)
rangsort
else
(* Rule is (Type_i,Set,Type_i) in the Set-predicative calculus *)
Type (sup u1 type0_univ)
(* Product rule (Prop,Type_i,Type_i) *)
| (Prop Pos, Type u2) -> Type (sup type0_univ u2)
(* Product rule (Prop,Type_i,Type_i) *)
| (Prop Null, Type _) -> rangsort
(* Product rule (Type_i,Type_i,Type_i) *)
| (Type u1, Type u2) -> Type (sup u1 u2)
(* normalisation of values *)
let branch_of_switch lvl ans bs =
let tbl = ans.asw_reloc in
let branch i =
let tag,arity = tbl.(i) in
let ci =
if Int.equal arity 0 then mk_const tag
else mk_block tag (mk_rels_accu lvl arity) in
bs ci in
Array.init (Array.length tbl) branch
let rec nf_val env v typ =
match kind_of_value v with
| Vaccu accu -> nf_accu env accu
| Vfun f ->
let lvl = nb_rel env in
let name,dom,codom =
try decompose_prod env typ
with DestKO ->
CErrors.anomaly
(Pp.strbrk "Returned a functional value in a type not recognized as a product type.")
in
let env = push_rel (LocalAssum (name,dom)) env in
let body = nf_val env (f (mk_rel_accu lvl)) codom in
mkLambda(name,dom,body)
| Vconst n -> construct_of_constr_const env n typ
| Vblock b ->
let capp,ctyp = construct_of_constr_block env (block_tag b) typ in
let args = nf_bargs env b ctyp in
mkApp(capp,args)
and nf_type env v =
match kind_of_value v with
| Vaccu accu -> nf_accu env accu
| _ -> assert false
and nf_type_sort env v =
match kind_of_value v with
| Vaccu accu ->
let t,s = nf_accu_type env accu in
let s = try destSort s with DestKO -> assert false in
t, s
| _ -> assert false
and nf_accu env accu =
let atom = atom_of_accu accu in
if Int.equal (accu_nargs accu) 0 then nf_atom env atom
else
let a,typ = nf_atom_type env atom in
let _, args = nf_args env accu typ in
mkApp(a,Array.of_list args)
and nf_accu_type env accu =
let atom = atom_of_accu accu in
if Int.equal (accu_nargs accu) 0 then nf_atom_type env atom
else
let a,typ = nf_atom_type env atom in
let t, args = nf_args env accu typ in
mkApp(a,Array.of_list args), t
and nf_args env accu t =
let aux arg (t,l) =
let _,dom,codom =
try decompose_prod env t with
DestKO ->
CErrors.anomaly
(Pp.strbrk "Returned a functional value in a type not recognized as a product type.")
in
let c = nf_val env arg dom in
(subst1 c codom, c::l)
in
let t,l = List.fold_right aux (args_of_accu accu) (t,[]) in
t, List.rev l
and nf_bargs env b t =
let t = ref t in
let len = block_size b in
Array.init len
(fun i ->
let _,dom,codom =
try decompose_prod env !t with
DestKO ->
CErrors.anomaly
(Pp.strbrk "Returned a functional value in a type not recognized as a product type.")
in
let c = nf_val env (block_field b i) dom in
t := subst1 c codom; c)
and nf_atom env atom =
match atom with
| Arel i -> mkRel (nb_rel env - i)
| Aconstant cst -> mkConstU cst
| Aind ind -> mkIndU ind
| Asort s -> mkSort s
| Avar id -> mkVar id
| Aprod(n,dom,codom) ->
let dom = nf_type env dom in
let vn = mk_rel_accu (nb_rel env) in
let env = push_rel (LocalAssum (n,dom)) env in
let codom = nf_type env (codom vn) in
mkProd(n,dom,codom)
| Ameta (mv,_) -> mkMeta mv
| Aevar (ev,_) -> mkEvar ev
| Aproj(p,c) ->
let c = nf_accu env c in
mkProj(Projection.make p true,c)
| _ -> fst (nf_atom_type env atom)
and nf_atom_type env atom =
match atom with
| Arel i ->
let n = (nb_rel env - i) in
mkRel n, type_of_rel env n
| Aconstant cst ->
mkConstU cst, Typeops.type_of_constant_in env cst
| Aind ind ->
mkIndU ind, Inductiveops.type_of_inductive env ind
| Asort s ->
mkSort s, type_of_sort s
| Avar id ->
mkVar id, type_of_var env id
| Acase(ans,accu,p,bs) ->
let a,ta = nf_accu_type env accu in
let ((mind,_),u as ind),allargs = find_rectype_a env ta in
let (mib,mip) = Inductive.lookup_mind_specif env (fst ind) in
let nparams = mib.mind_nparams in
let params,realargs = Array.chop nparams allargs in
let pT =
hnf_prod_applist env
(Inductiveops.type_of_inductive env ind) (Array.to_list params) in
let pT = whd_all env pT in
let dep, p = nf_predicate env ind mip params p pT in
(* Calcul du type des branches *)
let btypes = build_branches_type env (fst ind) mib mip u params dep p in
(* calcul des branches *)
let bsw = branch_of_switch (nb_rel env) ans bs in
let mkbranch i v =
let decl,decl_with_letin,codom = btypes.(i) in
let b = nf_val (Termops.push_rels_assum decl env) v codom in
Termops.it_mkLambda_or_LetIn_from_no_LetIn b decl_with_letin
in
let branchs = Array.mapi mkbranch bsw in
let tcase = build_case_type dep p realargs a in
let ci = ans.asw_ci in
mkCase(ci, p, a, branchs), tcase
| Afix(tt,ft,rp,s) ->
let tt = Array.map (fun t -> nf_type env t) tt in
let name = Array.map (fun _ -> (Name (id_of_string "Ffix"))) tt in
let lvl = nb_rel env in
let nbfix = Array.length ft in
let fargs = mk_rels_accu lvl (Array.length ft) in
(* Third argument of the tuple is ignored by push_rec_types *)
let env = push_rec_types (name,tt,[||]) env in
(* We lift here because the types of arguments (in tt) will be evaluated
in an environment where the fixpoints have been pushed *)
let norm_body i v = nf_val env (napply v fargs) (lift nbfix tt.(i)) in
let ft = Array.mapi norm_body ft in
mkFix((rp,s),(name,tt,ft)), tt.(s)
| Acofix(tt,ft,s,_) | Acofixe(tt,ft,s,_) ->
let tt = Array.map (nf_type env) tt in
let name = Array.map (fun _ -> (Name (id_of_string "Fcofix"))) tt in
let lvl = nb_rel env in
let fargs = mk_rels_accu lvl (Array.length ft) in
let env = push_rec_types (name,tt,[||]) env in
let ft = Array.mapi (fun i v -> nf_val env (napply v fargs) tt.(i)) ft in
mkCoFix(s,(name,tt,ft)), tt.(s)
| Aprod(n,dom,codom) ->
let dom,s1 = nf_type_sort env dom in
let vn = mk_rel_accu (nb_rel env) in
let env = push_rel (LocalAssum (n,dom)) env in
let codom,s2 = nf_type_sort env (codom vn) in
mkProd(n,dom,codom), mkSort (sort_of_product env s1 s2)
| Aevar(ev,ty) ->
let ty = nf_type env ty in
mkEvar ev, ty
| Ameta(mv,ty) ->
let ty = nf_type env ty in
mkMeta mv, ty
| Aproj(p,c) ->
let c,tc = nf_accu_type env c in
let cj = make_judge c tc in
let uj = Typeops.judge_of_projection env (Projection.make p true) cj in
uj.uj_val, uj.uj_type
and nf_predicate env ind mip params v pT =
match kind_of_value v, kind_of_term pT with
| Vfun f, Prod _ ->
let k = nb_rel env in
let vb = f (mk_rel_accu k) in
let name,dom,codom =
try decompose_prod env pT with
DestKO ->
CErrors.anomaly
(Pp.strbrk "Returned a functional value in a type not recognized as a product type.")
in
let dep,body =
nf_predicate (push_rel (LocalAssum (name,dom)) env) ind mip params vb codom in
dep, mkLambda(name,dom,body)
| Vfun f, _ ->
let k = nb_rel env in
let vb = f (mk_rel_accu k) in
let name = Name (id_of_string "c") in
let n = mip.mind_nrealargs in
let rargs = Array.init n (fun i -> mkRel (n-i)) in
let params = if Int.equal n 0 then params else Array.map (lift n) params in
let dom = mkApp(mkIndU ind,Array.append params rargs) in
let body = nf_type (push_rel (LocalAssum (name,dom)) env) vb in
true, mkLambda(name,dom,body)
| _, _ -> false, nf_type env v
let evars_of_evar_map sigma =
{ Nativelambda.evars_val = Evd.existential_opt_value sigma;
Nativelambda.evars_typ = Evd.existential_type sigma;
Nativelambda.evars_metas = Evd.meta_type sigma }
let native_norm env sigma c ty =
if Coq_config.no_native_compiler then
error "Native_compute reduction has been disabled at configure time."
else
let penv = Environ.pre_env env in
let sigma = evars_of_evar_map sigma in
(*
Format.eprintf "Numbers of free variables (named): %i\n" (List.length vl1);
Format.eprintf "Numbers of free variables (rel): %i\n" (List.length vl2);
*)
let ml_filename, prefix = Nativelib.get_ml_filename () in
let code, upd = mk_norm_code penv sigma prefix c in
match Nativelib.compile ml_filename code with
| true, fn ->
if !Flags.debug then Feedback.msg_debug (Pp.str "Running norm ...");
let t0 = Sys.time () in
Nativelib.call_linker ~fatal:true prefix fn (Some upd);
let t1 = Sys.time () in
let time_info = Format.sprintf "Evaluation done in %.5f@." (t1 -. t0) in
if !Flags.debug then Feedback.msg_debug (Pp.str time_info);
let res = nf_val env !Nativelib.rt1 ty in
let t2 = Sys.time () in
let time_info = Format.sprintf "Reification done in %.5f@." (t2 -. t1) in
if !Flags.debug then Feedback.msg_debug (Pp.str time_info);
res
| _ -> anomaly (Pp.str "Compilation failure")
let native_conv_generic pb sigma t =
Nativeconv.native_conv_gen pb (evars_of_evar_map sigma) t
let native_infer_conv ?(pb=Reduction.CUMUL) env sigma t1 t2 =
Reductionops.infer_conv_gen (fun pb ~l2r sigma ts -> native_conv_generic pb sigma)
~catch_incon:true ~pb env sigma t1 t2
|