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(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2015 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* Created by Jacek Chrzaszcz, Aug 2002 as part of the implementation of
the Coq module system *)
(* This module provides the main entry points for type-checking basic
declarations *)
open Errors
open Util
open Names
open Term
open Context
open Declarations
open Environ
open Entries
open Typeops
open Fast_typeops
let constrain_type env j poly subst = function
| `None ->
if not poly then (* Old-style polymorphism *)
make_polymorphic_if_constant_for_ind env j
else RegularArity (Vars.subst_univs_level_constr subst j.uj_type)
| `Some t ->
let tj = infer_type env t in
let _ = judge_of_cast env j DEFAULTcast tj in
assert (eq_constr t tj.utj_val);
RegularArity (Vars.subst_univs_level_constr subst t)
| `SomeWJ (t, tj) ->
let tj = infer_type env t in
let _ = judge_of_cast env j DEFAULTcast tj in
assert (eq_constr t tj.utj_val);
RegularArity (Vars.subst_univs_level_constr subst t)
let map_option_typ = function None -> `None | Some x -> `Some x
(* Insertion of constants and parameters in environment. *)
let mk_pure_proof c = (c, Univ.ContextSet.empty), Declareops.no_seff
let handle_side_effects env body side_eff =
let handle_sideff t se =
let cbl = match se with
| SEsubproof (c,cb,b) -> [c,cb,b]
| SEscheme (cl,_) -> List.map (fun (_,c,cb,b) -> c,cb,b) cl in
let not_exists (c,_,_) =
try ignore(Environ.lookup_constant c env); false
with Not_found -> true in
let cbl = List.filter not_exists cbl in
let cname c =
let name = string_of_con c in
for i = 0 to String.length name - 1 do
if name.[i] == '.' || name.[i] == '#' then name.[i] <- '_' done;
Name (id_of_string name) in
let rec sub c i x = match kind_of_term x with
| Const (c', _) when eq_constant c c' -> mkRel i
| _ -> map_constr_with_binders ((+) 1) (fun i x -> sub c i x) i x in
let rec sub_body c u b i x = match kind_of_term x with
| Const (c',u') when eq_constant c c' ->
Vars.subst_instance_constr u' b
| _ -> map_constr_with_binders ((+) 1) (fun i x -> sub_body c u b i x) i x in
let fix_body (c,cb,b) t =
match cb.const_body, b with
| Def b, _ ->
let b = Mod_subst.force_constr b in
let poly = cb.const_polymorphic in
if not poly then
let b_ty = Typeops.type_of_constant_type env cb.const_type in
let t = sub c 1 (Vars.lift 1 t) in
mkLetIn (cname c, b, b_ty, t)
else
let univs = cb.const_universes in
sub_body c (Univ.UContext.instance univs) b 1 (Vars.lift 1 t)
| OpaqueDef _, `Opaque (b,_) ->
let poly = cb.const_polymorphic in
if not poly then
let b_ty = Typeops.type_of_constant_type env cb.const_type in
let t = sub c 1 (Vars.lift 1 t) in
mkApp (mkLambda (cname c, b_ty, t), [|b|])
else
let univs = cb.const_universes in
sub_body c (Univ.UContext.instance univs) b 1 (Vars.lift 1 t)
| _ -> assert false
in
List.fold_right fix_body cbl t
in
(* CAVEAT: we assure a proper order *)
Declareops.fold_side_effects handle_sideff body
(Declareops.uniquize_side_effects side_eff)
let hcons_j j =
{ uj_val = hcons_constr j.uj_val; uj_type = hcons_constr j.uj_type}
let feedback_completion_typecheck =
Option.iter (fun state_id -> Pp.feedback ~state_id Feedback.Complete)
let infer_declaration env kn dcl =
match dcl with
| ParameterEntry (ctx,poly,(t,uctx),nl) ->
let env = push_context uctx env in
let j = infer env t in
let abstract = poly && not (Option.is_empty kn) in
let usubst, univs = Univ.abstract_universes abstract uctx in
let c = Typeops.assumption_of_judgment env j in
let t = hcons_constr (Vars.subst_univs_level_constr usubst c) in
Undef nl, RegularArity t, None, poly, univs, false, ctx
| DefinitionEntry ({ const_entry_type = Some typ;
const_entry_opaque = true;
const_entry_polymorphic = false} as c) ->
let env = push_context c.const_entry_universes env in
let { const_entry_body = body; const_entry_feedback = feedback_id } = c in
let tyj = infer_type env typ in
let proofterm =
Future.chain ~greedy:true ~pure:true body (fun ((body, ctx),side_eff) ->
let body = handle_side_effects env body side_eff in
let env' = push_context_set ctx env in
let j = infer env' body in
let j = hcons_j j in
let subst = Univ.LMap.empty in
let _typ = constrain_type env' j c.const_entry_polymorphic subst
(`SomeWJ (typ,tyj)) in
feedback_completion_typecheck feedback_id;
j.uj_val, ctx) in
let def = OpaqueDef (Opaqueproof.create proofterm) in
def, RegularArity typ, None, c.const_entry_polymorphic,
c.const_entry_universes,
c.const_entry_inline_code, c.const_entry_secctx
| DefinitionEntry c ->
let env = push_context c.const_entry_universes env in
let { const_entry_type = typ; const_entry_opaque = opaque } = c in
let { const_entry_body = body; const_entry_feedback = feedback_id } = c in
let (body, ctx), side_eff = Future.join body in
assert(Univ.ContextSet.is_empty ctx);
let body = handle_side_effects env body side_eff in
let abstract = c.const_entry_polymorphic && not (Option.is_empty kn) in
let usubst, univs = Univ.abstract_universes abstract c.const_entry_universes in
let j = infer env body in
let typ = constrain_type env j c.const_entry_polymorphic usubst (map_option_typ typ) in
let def = hcons_constr (Vars.subst_univs_level_constr usubst j.uj_val) in
let def =
if opaque then OpaqueDef (Opaqueproof.create (Future.from_val (def, Univ.ContextSet.empty)))
else Def (Mod_subst.from_val def)
in
feedback_completion_typecheck feedback_id;
def, typ, None, c.const_entry_polymorphic,
univs, c.const_entry_inline_code, c.const_entry_secctx
| ProjectionEntry {proj_entry_ind = ind; proj_entry_arg = i} ->
let mib, _ = Inductive.lookup_mind_specif env (ind,0) in
let kn, pb =
match mib.mind_record with
| Some (Some (id, kns, pbs)) ->
if i < Array.length pbs then
kns.(i), pbs.(i)
else assert false
| _ -> assert false
in
let term, typ = pb.proj_eta in
Def (Mod_subst.from_val (hcons_constr term)), RegularArity typ, Some pb,
mib.mind_polymorphic, mib.mind_universes, false, None
let global_vars_set_constant_type env = function
| RegularArity t -> global_vars_set env t
| TemplateArity (ctx,_) ->
Context.fold_rel_context
(fold_rel_declaration
(fun t c -> Id.Set.union (global_vars_set env t) c))
ctx ~init:Id.Set.empty
let record_aux env s1 s2 =
let v =
String.concat " "
(List.map (fun (id, _,_) -> Id.to_string id)
(keep_hyps env (Id.Set.union s1 s2))) in
Aux_file.record_in_aux "context_used" v
let suggest_proof_using = ref (fun _ _ _ _ _ -> ())
let set_suggest_proof_using f = suggest_proof_using := f
let build_constant_declaration kn env (def,typ,proj,poly,univs,inline_code,ctx) =
let check declared inferred =
let mk_set l = List.fold_right Id.Set.add (List.map pi1 l) Id.Set.empty in
let inferred_set, declared_set = mk_set inferred, mk_set declared in
if not (Id.Set.subset inferred_set declared_set) then
let l = Id.Set.elements (Idset.diff inferred_set declared_set) in
let n = List.length l in
errorlabstrm "" (Pp.(str "The following section " ++
str (String.plural n "variable") ++
str " " ++ str (String.conjugate_verb_to_be n) ++
str " used but not declared:" ++
fnl () ++ pr_sequence Id.print (List.rev l) ++ str ".")) in
(* We try to postpone the computation of used section variables *)
let hyps, def =
let context_ids = List.map pi1 (named_context env) in
match ctx with
| None when not (List.is_empty context_ids) ->
(* No declared section vars, and non-empty section context:
we must look at the body NOW, if any *)
let ids_typ = global_vars_set_constant_type env typ in
let ids_def = match def with
| Undef _ -> Idset.empty
| Def cs -> global_vars_set env (Mod_subst.force_constr cs)
| OpaqueDef lc ->
let vars =
global_vars_set env
(Opaqueproof.force_proof (opaque_tables env) lc) in
(* we force so that cst are added to the env immediately after *)
ignore(Opaqueproof.force_constraints (opaque_tables env) lc);
!suggest_proof_using kn env vars ids_typ context_ids;
if !Flags.compilation_mode = Flags.BuildVo then
record_aux env ids_typ vars;
vars
in
keep_hyps env (Idset.union ids_typ ids_def), def
| None ->
if !Flags.compilation_mode = Flags.BuildVo then
record_aux env Id.Set.empty Id.Set.empty;
[], def (* Empty section context: no need to check *)
| Some declared ->
(* We use the declared set and chain a check of correctness *)
declared,
match def with
| Undef _ as x -> x (* nothing to check *)
| Def cs as x ->
let ids_typ = global_vars_set_constant_type env typ in
let ids_def = global_vars_set env (Mod_subst.force_constr cs) in
let inferred = keep_hyps env (Idset.union ids_typ ids_def) in
check declared inferred;
x
| OpaqueDef lc -> (* In this case we can postpone the check *)
OpaqueDef (Opaqueproof.iter_direct_opaque (fun c ->
let ids_typ = global_vars_set_constant_type env typ in
let ids_def = global_vars_set env c in
let inferred = keep_hyps env (Idset.union ids_typ ids_def) in
check declared inferred) lc) in
let tps =
(* FIXME: incompleteness of the bytecode vm: we compile polymorphic
constants like opaque definitions. *)
if poly then Cemitcodes.from_val Cemitcodes.BCconstant
else
match proj with
| None -> Cemitcodes.from_val (compile_constant_body env def)
| Some pb ->
Cemitcodes.from_val (compile_constant_body env (Def (Mod_subst.from_val pb.proj_body)))
in
{ const_hyps = hyps;
const_body = def;
const_type = typ;
const_proj = proj;
const_body_code = tps;
const_polymorphic = poly;
const_universes = univs;
const_inline_code = inline_code }
(*s Global and local constant declaration. *)
let translate_constant env kn ce =
build_constant_declaration kn env (infer_declaration env (Some kn) ce)
let translate_local_assum env t =
let j = infer env t in
let t = Typeops.assumption_of_judgment env j in
t
let translate_recipe env kn r =
build_constant_declaration kn env (Cooking.cook_constant env r)
let translate_local_def env id centry =
let def,typ,proj,poly,univs,inline_code,ctx =
infer_declaration env None (DefinitionEntry centry) in
let typ = type_of_constant_type env typ in
def, typ, univs
(* Insertion of inductive types. *)
let translate_mind env kn mie = Indtypes.check_inductive env kn mie
let handle_entry_side_effects env ce = { ce with
const_entry_body = Future.chain ~greedy:true ~pure:true
ce.const_entry_body (fun ((body, ctx), side_eff) ->
(handle_side_effects env body side_eff, ctx), Declareops.no_seff);
}
|