Source file mod_typing.ml
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open Util
open Names
open Declarations
open Entries
open Environ
open Modops
open Mod_subst
type 'alg translation =
module_signature * 'alg * delta_resolver * Univ.Constraints.t
let rec mp_from_mexpr = function
| MEident mp -> mp
| MEapply (expr,_) -> mp_from_mexpr expr
| MEwith (expr,_) -> mp_from_mexpr expr
let is_modular = function
| SFBmodule _ | SFBmodtype _ -> true
| SFBconst _ | SFBmind _ -> false
(** Split a [structure_body] at some label corresponding to
a modular definition or not. *)
let split_struc k m struc =
let rec split rev_before = function
| [] -> raise Not_found
| (k',b)::after when Label.equal k k' && (is_modular b) == (m : bool) ->
List.rev rev_before,b,after
| h::tail -> split (h::rev_before) tail
in split [] struc
let discr_resolver mtb = match mtb.mod_type with
| NoFunctor _ -> mtb.mod_delta
| MoreFunctor _ -> empty_delta_resolver
let rec rebuild_mp mp l =
match l with
| []-> mp
| i::r -> rebuild_mp (MPdot(mp,Label.of_id i)) r
let infer_gen_conv state env c1 c2 =
Reduction.generic_conv Reduction.CONV ~l2r:false (fun _ -> None) TransparentState.full env state c1 c2
let infer_gen_conv_leq state env c1 c2 =
Reduction.generic_conv Reduction.CUMUL ~l2r:false (fun _ -> None) TransparentState.full env state c1 c2
let rec check_with_def (cst, ustate) env struc (idl,(c,ctx)) mp reso =
let lab,idl = match idl with
| [] -> assert false
| id::idl -> Label.of_id id, idl
in
try
let modular = not (List.is_empty idl) in
let before,spec,after = split_struc lab modular struc in
let env' = Modops.add_structure mp before reso env in
if List.is_empty idl then
let cb = match spec with
| SFBconst cb -> cb
| _ -> error_not_a_constant lab
in
let univs, ctx' =
match cb.const_universes, ctx with
| Monomorphic, None ->
let cst = match cb.const_body with
| Undef _ | OpaqueDef _ ->
let j = Typeops.infer env' c in
assert (j.uj_val == c);
let typ = cb.const_type in
let cst = infer_gen_conv_leq (cst, ustate) env' j.uj_type typ in
cst
| Def c' ->
infer_gen_conv (cst, ustate) env' c c'
| Primitive _ ->
error_incorrect_with_constraint lab
in
Monomorphic, cst
| Polymorphic uctx, Some ctx ->
let () =
if not (UGraph.check_subtype (Environ.universes env) uctx ctx) then
error_incorrect_with_constraint lab
in
(** Terms are compared in a context with De Bruijn universe indices *)
let env' = Environ.push_context ~strict:false (Univ.AbstractContext.repr uctx) env in
let () = match cb.const_body with
| Undef _ | OpaqueDef _ ->
let j = Typeops.infer env' c in
assert (j.uj_val == c);
let typ = cb.const_type in
begin
try Reduction.conv_leq env' j.uj_type typ
with Reduction.NotConvertible -> error_incorrect_with_constraint lab
end
| Def c' ->
begin
try Reduction.conv env' c c'
with Reduction.NotConvertible -> error_incorrect_with_constraint lab
end
| Primitive _ ->
error_incorrect_with_constraint lab
in
Polymorphic ctx, cst
| _ -> error_incorrect_with_constraint lab
in
let def = Def c in
let cb' =
{ cb with
const_body = def;
const_universes = univs ;
const_body_code =
(Vmbytegen.compile_constant_body ~fail_on_error:false env' cb.const_universes def) }
in
before@(lab,SFBconst(cb'))::after, ctx'
else
let mb = match spec with
| SFBmodule mb -> mb
| _ -> error_not_a_module_label lab
in
begin match mb.mod_expr with
| Abstract ->
let struc = Modops.destr_nofunctor (MPdot (mp,lab)) mb.mod_type in
let struc', cst =
check_with_def (cst, ustate) env' struc (idl,(c,ctx)) (MPdot(mp,lab)) mb.mod_delta
in
let mb' = { mb with
mod_type = NoFunctor struc';
mod_type_alg = None }
in
before@(lab,SFBmodule mb')::after, cst
| _ -> error_generative_module_expected lab
end
with
| Not_found -> error_no_such_label lab mp
| Reduction.NotConvertible -> error_incorrect_with_constraint lab
let rec check_with_mod (cst, ustate) env struc (idl,new_mp) mp reso =
let lab,idl = match idl with
| [] -> assert false
| id::idl -> Label.of_id id, idl
in
try
let before,spec,after = split_struc lab true struc in
let env' = Modops.add_structure mp before reso env in
let old = match spec with
| SFBmodule mb -> mb
| _ -> error_not_a_module_label lab
in
if List.is_empty idl then
let new_mb = lookup_module new_mp env in
let new_mtb = module_type_of_module new_mb in
let cst = match old.mod_expr with
| Abstract ->
let mtb_old = module_type_of_module old in
let cst = Subtyping.check_subtypes (cst, ustate) env' new_mtb mtb_old in
cst
| Algebraic (NoFunctor (MEident(mp'))) ->
check_modpath_equiv env' new_mp mp';
cst
| _ -> error_generative_module_expected lab
in
let mp' = MPdot (mp,lab) in
let new_mb = strengthen_and_subst_module_body new_mb mp' false in
let new_mb' =
{ new_mb with
mod_mp = mp';
mod_expr = Algebraic (NoFunctor (MEident new_mp));
}
in
let new_reso = add_delta_resolver reso new_mb.mod_delta in
let id_subst = map_mp mp' mp' new_mb.mod_delta in
let new_after = subst_structure id_subst after in
before@(lab,SFBmodule new_mb')::new_after, new_reso, cst
else
let mp' = MPdot (mp,lab) in
let old = match spec with
| SFBmodule msb -> msb
| _ -> error_not_a_module_label lab
in
begin match old.mod_expr with
| Abstract ->
let struc = destr_nofunctor mp' old.mod_type in
let struc',reso',cst =
check_with_mod (cst, ustate) env' struc (idl,new_mp) mp' old.mod_delta
in
let new_mb =
{ old with
mod_type = NoFunctor struc';
mod_type_alg = None;
mod_delta = reso' }
in
let new_reso = add_delta_resolver reso reso' in
let id_subst = map_mp mp' mp' reso' in
let new_after = subst_structure id_subst after in
before@(lab,SFBmodule new_mb)::new_after, new_reso, cst
| Algebraic (NoFunctor (MEident mp0)) ->
let mpnew = rebuild_mp mp0 idl in
check_modpath_equiv env' mpnew mp;
before@(lab,spec)::after, reso, cst
| _ -> error_generative_module_expected lab
end
with
| Not_found -> error_no_such_label lab mp
| Reduction.NotConvertible -> error_incorrect_with_constraint lab
let check_with ustate env mp (sign,reso,cst) = function
| WithDef(idl, (c, ctx)) ->
let struc = destr_nofunctor mp sign in
let struc', cst = check_with_def (cst, ustate) env struc (idl, (c, ctx)) mp reso in
NoFunctor struc', reso, cst
| WithMod(idl,new_mp) ->
let struc = destr_nofunctor mp sign in
let struc',reso',cst = check_with_mod (cst, ustate) env struc (idl,new_mp) mp reso in
NoFunctor struc', reso', cst
let check_with_alg ustate env mp (sign,alg,reso,cst) wd =
let struc, reso, cst = check_with ustate env mp (sign, reso, cst) wd in
struc, MEwith (alg, wd), reso, cst
let translate_apply ustate env inl (sign,alg,reso,cst) mp1 mkalg =
let farg_id, farg_b, fbody_b = destr_functor sign in
let mtb = module_type_of_module (lookup_module mp1 env) in
let cst = Subtyping.check_subtypes (cst, ustate) env mtb farg_b in
let mp_delta = discr_resolver mtb in
let mp_delta = inline_delta_resolver env inl mp1 farg_id farg_b mp_delta in
let subst = map_mbid farg_id mp1 mp_delta in
let body = subst_signature subst fbody_b in
let alg' = mkalg alg mp1 in
let reso' = subst_codom_delta_resolver subst reso in
body, alg', reso', cst
(** Translation of a module struct entry :
- We translate to a module when a [module_path] is given,
otherwise to a module type.
- The first output is the expanded signature
- The second output is the algebraic expression, kept for the extraction.
*)
let mk_alg_app alg arg = MEapply (alg,arg)
let rec translate_mse (cst, ustate) env mpo inl = function
| MEident mp1 as me ->
let mb = match mpo with
| Some mp -> strengthen_and_subst_module_body (lookup_module mp1 env) mp false
| None ->
let mt = lookup_modtype mp1 env in
module_body_of_type mt.mod_mp mt
in
mb.mod_type, me, mb.mod_delta, cst
| MEapply (fe,mp1) ->
translate_apply ustate env inl (translate_mse (cst, ustate) env mpo inl fe) mp1 mk_alg_app
|MEwith(me, with_decl) ->
assert (Option.is_empty mpo);
let mp = mp_from_mexpr me in
check_with_alg ustate env mp (translate_mse (cst, ustate) env None inl me) with_decl
let mk_mod mp e ty reso =
{ mod_mp = mp;
mod_expr = e;
mod_type = ty;
mod_type_alg = None;
mod_delta = reso;
mod_retroknowledge = ModBodyRK []; }
let mk_modtype mp ty reso =
let mb = mk_mod mp Abstract ty reso in
{ mb with mod_expr = (); mod_retroknowledge = ModTypeRK }
let rec translate_mse_funct (cst, ustate) env ~is_mod mp inl mse = function
|[] ->
let sign,alg,reso,cst = translate_mse (cst, ustate) env (if is_mod then Some mp else None) inl mse in
let sign,reso =
if is_mod then sign,reso
else subst_modtype_signature_and_resolver (mp_from_mexpr mse) mp sign reso in
sign, NoFunctor alg, reso, cst
|(mbid, ty, ty_inl) :: params ->
let mp_id = MPbound mbid in
let mtb, cst = translate_modtype (cst, ustate) env mp_id ty_inl ([],ty) in
let env' = add_module_type mp_id mtb env in
let sign,alg,reso,cst = translate_mse_funct (cst, ustate) env' ~is_mod mp inl mse params in
let alg' = MoreFunctor (mbid,mtb,alg) in
MoreFunctor (mbid, mtb, sign), alg',reso, cst
and translate_modtype state env mp inl (params,mte) =
let sign,alg,reso,cst = translate_mse_funct state env ~is_mod:false mp inl mte params in
let mtb = mk_modtype mp sign reso in
{ mtb with mod_type_alg = Some alg }, cst
(** [finalize_module] :
from an already-translated (or interactive) implementation and
an (optional) signature entry, produces a final [module_body] *)
let finalize_module (cst, ustate) env mp (sign,alg,reso) restype = match restype with
| None ->
let impl = match alg with Some e -> Algebraic e | None -> FullStruct in
mk_mod mp impl sign reso, cst
| Some (params_mte,inl) ->
let res_mtb, cst = translate_modtype (cst, ustate) env mp inl params_mte in
let auto_mtb = mk_modtype mp sign reso in
let cst = Subtyping.check_subtypes (cst, ustate) env auto_mtb res_mtb in
let impl = match alg with Some e -> Algebraic e | None -> Struct sign in
{ res_mtb with
mod_mp = mp;
mod_expr = impl;
mod_retroknowledge = ModBodyRK [];
},
(** constraints from module body typing + subtyping + module type. *)
cst
let translate_module (cst, ustate) env mp inl = function
| MType (params,ty) ->
let mtb, cst = translate_modtype (cst, ustate) env mp inl (params,ty) in
module_body_of_type mp mtb, cst
|MExpr (params,mse,oty) ->
let (sg,alg,reso,cst) = translate_mse_funct (cst, ustate) env ~is_mod:true mp inl mse params in
let restype = Option.map (fun ty -> ((params,ty),inl)) oty in
finalize_module (cst, ustate) env mp (sg,Some alg,reso) restype
(** We now forbid any Include of functors with restricted signatures.
Otherwise, we could end with the creation of undesired axioms
(see #3746). Note that restricted non-functorized modules are ok,
thanks to strengthening. *)
let rec unfunct = function
| NoFunctor me -> me
| MoreFunctor(_,_,me) -> unfunct me
let rec forbid_incl_signed_functor env = function
| MEapply(fe,_) -> forbid_incl_signed_functor env fe
| MEwith _ -> assert false
| MEident mp1 ->
let mb = lookup_module mp1 env in
match mb.mod_type, mb.mod_type_alg, mb.mod_expr with
| MoreFunctor _, Some _, _ ->
error_include_restricted_functor mp1
| MoreFunctor _, None, Algebraic me ->
forbid_incl_signed_functor env (unfunct me)
|_ -> ()
let rec translate_mse_include_module (cst, ustate) env mp inl = function
| MEident mp1 ->
let mb = strengthen_and_subst_module_body (lookup_module mp1 env) mp true in
let sign = clean_bounded_mod_expr mb.mod_type in
sign,(),mb.mod_delta,cst
| MEapply (fe,arg) ->
let ftrans = translate_mse_include_module (cst, ustate) env mp inl fe in
translate_apply ustate env inl ftrans arg (fun _ _ -> ())
| MEwith _ -> assert false
let translate_mse_include is_mod (cst, ustate) env mp inl me =
if is_mod then
let () = forbid_incl_signed_functor env me in
translate_mse_include_module (cst, ustate) env mp inl me
else
let mtb, cst = translate_modtype (cst, ustate) env mp inl ([],me) in
let sign = clean_bounded_mod_expr mtb.mod_type in
sign, (), mtb.mod_delta, cst