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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 Util
open Names
open Globnames
open Nameops
open Term
open Vars
open Environ
open Declarations
open Entries
open Declare
open Constrintern
open Decl_kinds
open Type_errors
open Constrexpr
open Constrexpr_ops
open Goptions
open Sigma.Notations
open Context.Rel.Declaration
module RelDecl = Context.Rel.Declaration
(********** definition d'un record (structure) **************)
(** Flag governing use of primitive projections. Disabled by default. *)
let primitive_flag = ref false
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "use of primitive projections";
optkey = ["Primitive";"Projections"];
optread = (fun () -> !primitive_flag) ;
optwrite = (fun b -> primitive_flag := b) }
let typeclasses_strict = ref false
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "strict typeclass resolution";
optkey = ["Typeclasses";"Strict";"Resolution"];
optread = (fun () -> !typeclasses_strict);
optwrite = (fun b -> typeclasses_strict := b); }
let typeclasses_unique = ref false
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "unique typeclass instances";
optkey = ["Typeclasses";"Unique";"Instances"];
optread = (fun () -> !typeclasses_unique);
optwrite = (fun b -> typeclasses_unique := b); }
let interp_fields_evars env evars impls_env nots l =
List.fold_left2
(fun (env, uimpls, params, impls) no ((loc, i), b, t) ->
let t', impl = interp_type_evars_impls env evars ~impls t in
let b' = Option.map (fun x -> fst (interp_casted_constr_evars_impls env evars ~impls x t')) b in
let impls =
match i with
| Anonymous -> impls
| Name id -> Id.Map.add id (compute_internalization_data env Constrintern.Method t' impl) impls
in
let d = match b' with
| None -> LocalAssum (i,t')
| Some b' -> LocalDef (i,b',t')
in
List.iter (Metasyntax.set_notation_for_interpretation impls) no;
(push_rel d env, impl :: uimpls, d::params, impls))
(env, [], [], impls_env) nots l
let compute_constructor_level evars env l =
List.fold_right (fun d (env, univ) ->
let univ =
if is_local_assum d then
let s = Retyping.get_sort_of env evars (RelDecl.get_type d) in
Univ.sup (univ_of_sort s) univ
else univ
in (push_rel d env, univ))
l (env, Univ.type0m_univ)
let binder_of_decl = function
| Vernacexpr.AssumExpr(n,t) -> (n,None,t)
| Vernacexpr.DefExpr(n,c,t) -> (n,Some c, match t with Some c -> c | None -> CHole (fst n, None, Misctypes.IntroAnonymous, None))
let binders_of_decls = List.map binder_of_decl
let typecheck_params_and_fields def id pl t ps nots fs =
let env0 = Global.env () in
let ctx = Evd.make_evar_universe_context env0 pl in
let evars = ref (Evd.from_ctx ctx) in
let _ =
let error bk (loc, name) =
match bk, name with
| Default _, Anonymous ->
user_err ~loc ~hdr:"record" (str "Record parameters must be named")
| _ -> ()
in
List.iter
(function CLocalDef (b, _, _) -> error default_binder_kind b
| CLocalAssum (ls, bk, ce) -> List.iter (error bk) ls
| CLocalPattern (loc,_,_) ->
Loc.raise ~loc (Stream.Error "pattern with quote not allowed in record parameters.")) ps
in
let impls_env, ((env1,newps), imps) = interp_context_evars env0 evars ps in
let t', template = match t with
| Some t ->
let env = push_rel_context newps env0 in
let poly =
match t with
| CSort (_, Misctypes.GType []) -> true | _ -> false in
let s = interp_type_evars env evars ~impls:empty_internalization_env t in
let sred = Reductionops.whd_all env !evars s in
(match kind_of_term sred with
| Sort s' ->
(if poly then
match Evd.is_sort_variable !evars s' with
| Some l -> evars := Evd.make_flexible_variable !evars true l;
sred, true
| None -> s, false
else s, false)
| _ -> user_err ~loc:(constr_loc t) (str"Sort expected."))
| None ->
let uvarkind = Evd.univ_flexible_alg in
mkSort (Evarutil.evd_comb0 (Evd.new_sort_variable uvarkind) evars), true
in
let fullarity = it_mkProd_or_LetIn t' newps in
let env_ar = push_rel_context newps (push_rel (LocalAssum (Name id,fullarity)) env0) in
let env2,impls,newfs,data =
interp_fields_evars env_ar evars impls_env nots (binders_of_decls fs)
in
let sigma =
Pretyping.solve_remaining_evars Pretyping.all_and_fail_flags env_ar !evars (Evd.empty,!evars) in
let evars, nf = Evarutil.nf_evars_and_universes sigma in
let arity = nf t' in
let arity, evars =
let _, univ = compute_constructor_level evars env_ar newfs in
let ctx, aritysort = Reduction.dest_arity env0 arity in
assert(List.is_empty ctx); (* Ensured by above analysis *)
if not def && (Sorts.is_prop aritysort ||
(Sorts.is_set aritysort && is_impredicative_set env0)) then
arity, evars
else
let evars = Evd.set_leq_sort env_ar evars (Type univ) aritysort in
if Univ.is_small_univ univ &&
Option.cata (Evd.is_flexible_level evars) false (Evd.is_sort_variable evars aritysort) then
(* We can assume that the level in aritysort is not constrained
and clear it, if it is flexible *)
mkArity (ctx, Sorts.sort_of_univ univ),
Evd.set_eq_sort env_ar evars (Prop Pos) aritysort
else arity, evars
in
let evars, nf = Evarutil.nf_evars_and_universes evars in
let newps = Context.Rel.map nf newps in
let newfs = Context.Rel.map nf newfs in
let ce t = Pretyping.check_evars env0 Evd.empty evars t in
List.iter (iter_constr ce) (List.rev newps);
List.iter (iter_constr ce) (List.rev newfs);
Evd.universe_context ?names:pl evars, nf arity, template, imps, newps, impls, newfs
let degenerate_decl decl =
let id = match RelDecl.get_name decl with
| Name id -> id
| Anonymous -> anomaly (Pp.str "Unnamed record variable") in
match decl with
| LocalAssum (_,t) -> (id, LocalAssumEntry t)
| LocalDef (_,b,_) -> (id, LocalDefEntry b)
type record_error =
| MissingProj of Id.t * Id.t list
| BadTypedProj of Id.t * env * Type_errors.type_error
let warn_cannot_define_projection =
CWarnings.create ~name:"cannot-define-projection" ~category:"records"
(fun msg -> hov 0 msg)
(* If a projection is not definable, we throw an error if the user
asked it to be a coercion. Otherwise, we just print an info
message. The user might still want to name the field of the record. *)
let warning_or_error coe indsp err =
let st = match err with
| MissingProj (fi,projs) ->
let s,have = if List.length projs > 1 then "s","were" else "","was" in
(pr_id fi ++
strbrk" cannot be defined because the projection" ++ str s ++ spc () ++
prlist_with_sep pr_comma pr_id projs ++ spc () ++ str have ++
strbrk " not defined.")
| BadTypedProj (fi,ctx,te) ->
match te with
| ElimArity (_,_,_,_,Some (_,_,NonInformativeToInformative)) ->
(pr_id fi ++
strbrk" cannot be defined because it is informative and " ++
Printer.pr_inductive (Global.env()) indsp ++
strbrk " is not.")
| ElimArity (_,_,_,_,Some (_,_,StrongEliminationOnNonSmallType)) ->
(pr_id fi ++
strbrk" cannot be defined because it is large and " ++
Printer.pr_inductive (Global.env()) indsp ++
strbrk " is not.")
| _ ->
(pr_id fi ++ strbrk " cannot be defined because it is not typable.")
in
if coe then user_err ~hdr:"structure" st;
Flags.if_verbose Feedback.msg_info (hov 0 st)
type field_status =
| NoProjection of Name.t
| Projection of constr
exception NotDefinable of record_error
(* This replaces previous projection bodies in current projection *)
(* Undefined projs are collected and, at least one undefined proj occurs *)
(* in the body of current projection then the latter can not be defined *)
(* [c] is defined in ctxt [[params;fields]] and [l] is an instance of *)
(* [[fields]] defined in ctxt [[params;x:ind]] *)
let subst_projection fid l c =
let lv = List.length l in
let bad_projs = ref [] in
let rec substrec depth c = match kind_of_term c with
| Rel k ->
(* We are in context [[params;fields;x:ind;...depth...]] *)
if k <= depth+1 then
c
else if k-depth-1 <= lv then
match List.nth l (k-depth-2) with
| Projection t -> lift depth t
| NoProjection (Name id) -> bad_projs := id :: !bad_projs; mkRel k
| NoProjection Anonymous ->
user_err (str "Field " ++ pr_id fid ++
str " depends on the " ++ pr_nth (k-depth-1) ++ str
" field which has no name.")
else
mkRel (k-lv)
| _ -> map_constr_with_binders succ substrec depth c
in
let c' = lift 1 c in (* to get [c] defined in ctxt [[params;fields;x:ind]] *)
let c'' = substrec 0 c' in
if not (List.is_empty !bad_projs) then
raise (NotDefinable (MissingProj (fid,List.rev !bad_projs)));
c''
let instantiate_possibly_recursive_type indu paramdecls fields =
let subst = List.map_i (fun i _ -> mkRel i) 1 paramdecls in
Termops.substl_rel_context (subst@[mkIndU indu]) fields
let warn_non_primitive_record =
CWarnings.create ~name:"non-primitive-record" ~category:"record"
(fun (env,indsp) ->
(hov 0 (str "The record " ++ Printer.pr_inductive env indsp ++
strbrk" could not be defined as a primitive record")))
(* We build projections *)
let declare_projections indsp ?(kind=StructureComponent) binder_name coers fieldimpls fields =
let env = Global.env() in
let (mib,mip) = Global.lookup_inductive indsp in
let u = Declareops.inductive_instance mib in
let paramdecls = Inductive.inductive_paramdecls (mib, u) in
let poly = mib.mind_polymorphic in
let ctx = Univ.instantiate_univ_context mib.mind_universes in
let indu = indsp, u in
let r = mkIndU (indsp,u) in
let rp = applist (r, Context.Rel.to_extended_list 0 paramdecls) in
let paramargs = Context.Rel.to_extended_list 1 paramdecls in (*def in [[params;x:rp]]*)
let x = Name binder_name in
let fields = instantiate_possibly_recursive_type indu paramdecls fields in
let lifted_fields = Termops.lift_rel_context 1 fields in
let primitive =
if !primitive_flag then
let is_primitive =
match mib.mind_record with
| Some (Some _) -> true
| Some None | None -> false
in
if not is_primitive then
warn_non_primitive_record (env,indsp);
is_primitive
else false
in
let (_,_,kinds,sp_projs,_) =
List.fold_left3
(fun (nfi,i,kinds,sp_projs,subst) coe decl impls ->
let fi = RelDecl.get_name decl in
let ti = RelDecl.get_type decl in
let (sp_projs,i,subst) =
match fi with
| Anonymous ->
(None::sp_projs,i,NoProjection fi::subst)
| Name fid -> try
let kn, term =
if is_local_assum decl && primitive then
(** Already defined in the kernel silently *)
let kn = destConstRef (Nametab.locate (Libnames.qualid_of_ident fid)) in
Declare.definition_message fid;
kn, mkProj (Projection.make kn false,mkRel 1)
else
let ccl = subst_projection fid subst ti in
let body = match decl with
| LocalDef (_,ci,_) -> subst_projection fid subst ci
| LocalAssum _ ->
(* [ccl] is defined in context [params;x:rp] *)
(* [ccl'] is defined in context [params;x:rp;x:rp] *)
let ccl' = liftn 1 2 ccl in
let p = mkLambda (x, lift 1 rp, ccl') in
let branch = it_mkLambda_or_LetIn (mkRel nfi) lifted_fields in
let ci = Inductiveops.make_case_info env indsp LetStyle in
mkCase (ci, p, mkRel 1, [|branch|])
in
let proj =
it_mkLambda_or_LetIn (mkLambda (x,rp,body)) paramdecls in
let projtyp =
it_mkProd_or_LetIn (mkProd (x,rp,ccl)) paramdecls in
try
let entry = {
const_entry_body =
Future.from_val (Safe_typing.mk_pure_proof proj);
const_entry_secctx = None;
const_entry_type = Some projtyp;
const_entry_polymorphic = poly;
const_entry_universes =
if poly then ctx else Univ.UContext.empty;
const_entry_opaque = false;
const_entry_inline_code = false;
const_entry_feedback = None } in
let k = (DefinitionEntry entry,IsDefinition kind) in
let kn = declare_constant ~internal:InternalTacticRequest fid k in
let constr_fip =
let proj_args = (*Rel 1 refers to "x"*) paramargs@[mkRel 1] in
applist (mkConstU (kn,u),proj_args)
in
Declare.definition_message fid;
kn, constr_fip
with Type_errors.TypeError (ctx,te) ->
raise (NotDefinable (BadTypedProj (fid,ctx,te)))
in
let refi = ConstRef kn in
Impargs.maybe_declare_manual_implicits false refi impls;
if coe then begin
let cl = Class.class_of_global (IndRef indsp) in
Class.try_add_new_coercion_with_source refi ~local:false poly ~source:cl
end;
let i = if is_local_assum decl then i+1 else i in
(Some kn::sp_projs, i, Projection term::subst)
with NotDefinable why ->
warning_or_error coe indsp why;
(None::sp_projs,i,NoProjection fi::subst) in
(nfi-1,i,(fi, is_local_assum decl)::kinds,sp_projs,subst))
(List.length fields,0,[],[],[]) coers (List.rev fields) (List.rev fieldimpls)
in (kinds,sp_projs)
let structure_signature ctx =
let rec deps_to_evar evm l =
match l with [] -> Evd.empty
| [decl] ->
let env = Environ.empty_named_context_val in
let evm = Sigma.Unsafe.of_evar_map evm in
let Sigma (_, evm, _) = Evarutil.new_pure_evar env evm (RelDecl.get_type decl) in
let evm = Sigma.to_evar_map evm in
evm
| decl::tl ->
let env = Environ.empty_named_context_val in
let evm = Sigma.Unsafe.of_evar_map evm in
let Sigma (ev, evm, _) = Evarutil.new_pure_evar env evm (RelDecl.get_type decl) in
let evm = Sigma.to_evar_map evm in
let new_tl = Util.List.map_i
(fun pos decl ->
RelDecl.map_type (fun t -> Termops.replace_term (mkRel pos) (mkEvar(ev,[||])) t) decl) 1 tl in
deps_to_evar evm new_tl in
deps_to_evar Evd.empty (List.rev ctx)
open Typeclasses
let declare_structure finite poly ctx id idbuild paramimpls params arity template
fieldimpls fields ?(kind=StructureComponent) ?name is_coe coers sign =
let nparams = List.length params and nfields = List.length fields in
let args = Context.Rel.to_extended_list nfields params in
let ind = applist (mkRel (1+nparams+nfields), args) in
let type_constructor = it_mkProd_or_LetIn ind fields in
let binder_name =
match name with
| None -> Id.of_string (Unicode.lowercase_first_char (Id.to_string id))
| Some n -> n
in
let mie_ind =
{ mind_entry_typename = id;
mind_entry_arity = arity;
mind_entry_template = not poly && template;
mind_entry_consnames = [idbuild];
mind_entry_lc = [type_constructor] }
in
let mie =
{ mind_entry_params = List.map degenerate_decl params;
mind_entry_record = Some (if !primitive_flag then Some binder_name else None);
mind_entry_finite = finite;
mind_entry_inds = [mie_ind];
mind_entry_polymorphic = poly;
mind_entry_private = None;
mind_entry_universes = ctx;
}
in
let kn = Command.declare_mutual_inductive_with_eliminations mie [] [(paramimpls,[])] in
let rsp = (kn,0) in (* This is ind path of idstruc *)
let cstr = (rsp,1) in
let kinds,sp_projs = declare_projections rsp ~kind binder_name coers fieldimpls fields in
let build = ConstructRef cstr in
let () = if is_coe then Class.try_add_new_coercion build ~local:false poly in
Recordops.declare_structure(rsp,cstr,List.rev kinds,List.rev sp_projs);
rsp
let implicits_of_context ctx =
List.map_i (fun i name ->
let explname =
match name with
| Name n -> Some n
| Anonymous -> None
in ExplByPos (i, explname), (true, true, true))
1 (List.rev (Anonymous :: (List.map RelDecl.get_name ctx)))
let declare_class finite def poly ctx id idbuild paramimpls params arity
template fieldimpls fields ?(kind=StructureComponent) is_coe coers priorities sign =
let fieldimpls =
(* Make the class implicit in the projections, and the params if applicable. *)
let len = List.length params in
let impls = implicits_of_context params in
List.map (fun x -> impls @ Impargs.lift_implicits (succ len) x) fieldimpls
in
let binder_name = Namegen.next_ident_away (snd id) (Termops.ids_of_context (Global.env())) in
let impl, projs =
match fields with
| [LocalAssum (Name proj_name, field) | LocalDef (Name proj_name, _, field)] when def ->
let class_body = it_mkLambda_or_LetIn field params in
let class_type = it_mkProd_or_LetIn arity params in
let class_entry =
Declare.definition_entry ~types:class_type ~poly ~univs:ctx class_body in
let cst = Declare.declare_constant (snd id)
(DefinitionEntry class_entry, IsDefinition Definition)
in
let cstu = (cst, if poly then Univ.UContext.instance ctx else Univ.Instance.empty) in
let inst_type = appvectc (mkConstU cstu)
(Termops.rel_vect 0 (List.length params)) in
let proj_type =
it_mkProd_or_LetIn (mkProd(Name binder_name, inst_type, lift 1 field)) params in
let proj_body =
it_mkLambda_or_LetIn (mkLambda (Name binder_name, inst_type, mkRel 1)) params in
let proj_entry =
Declare.definition_entry ~types:proj_type ~poly
~univs:(if poly then ctx else Univ.UContext.empty) proj_body
in
let proj_cst = Declare.declare_constant proj_name
(DefinitionEntry proj_entry, IsDefinition Definition)
in
let cref = ConstRef cst in
Impargs.declare_manual_implicits false cref [paramimpls];
Impargs.declare_manual_implicits false (ConstRef proj_cst) [List.hd fieldimpls];
Classes.set_typeclass_transparency (EvalConstRef cst) false false;
let sub = match List.hd coers with
| Some b -> Some ((if b then Backward else Forward), List.hd priorities)
| None -> None
in
cref, [Name proj_name, sub, Some proj_cst]
| _ ->
let ind = declare_structure BiFinite poly ctx (snd id) idbuild paramimpls
params arity template fieldimpls fields
~kind:Method ~name:binder_name false (List.map (fun _ -> false) fields) sign
in
let coers = List.map2 (fun coe pri ->
Option.map (fun b ->
if b then Backward, pri else Forward, pri) coe)
coers priorities
in
let l = List.map3 (fun decl b y -> RelDecl.get_name decl, b, y)
(List.rev fields) coers (Recordops.lookup_projections ind)
in IndRef ind, l
in
let ctx_context =
List.map (fun decl ->
match Typeclasses.class_of_constr (RelDecl.get_type decl) with
| Some (_, ((cl,_), _)) -> Some (cl.cl_impl, true)
| None -> None)
params, params
in
let k =
{ cl_impl = impl;
cl_strict = !typeclasses_strict;
cl_unique = !typeclasses_unique;
cl_context = ctx_context;
cl_props = fields;
cl_projs = projs }
in
add_class k; impl
let add_constant_class cst =
let ty = Universes.unsafe_type_of_global (ConstRef cst) in
let ctx, arity = decompose_prod_assum ty in
let tc =
{ cl_impl = ConstRef cst;
cl_context = (List.map (const None) ctx, ctx);
cl_props = [LocalAssum (Anonymous, arity)];
cl_projs = [];
cl_strict = !typeclasses_strict;
cl_unique = !typeclasses_unique
}
in add_class tc;
set_typeclass_transparency (EvalConstRef cst) false false
let add_inductive_class ind =
let mind, oneind = Global.lookup_inductive ind in
let k =
let ctx = oneind.mind_arity_ctxt in
let inst = Univ.UContext.instance mind.mind_universes in
let ty = Inductive.type_of_inductive
(push_rel_context ctx (Global.env ()))
((mind,oneind),inst)
in
{ cl_impl = IndRef ind;
cl_context = List.map (const None) ctx, ctx;
cl_props = [LocalAssum (Anonymous, ty)];
cl_projs = [];
cl_strict = !typeclasses_strict;
cl_unique = !typeclasses_unique }
in add_class k
let declare_existing_class g =
match g with
| ConstRef x -> add_constant_class x
| IndRef x -> add_inductive_class x
| _ -> user_err ~hdr:"declare_existing_class"
(Pp.str"Unsupported class type, only constants and inductives are allowed")
open Vernacexpr
(* [fs] corresponds to fields and [ps] to parameters; [coers] is a
list telling if the corresponding fields must me declared as coercions
or subinstances. *)
let definition_structure (kind,poly,finite,(is_coe,((loc,idstruc),pl)),ps,cfs,idbuild,s) =
let cfs,notations = List.split cfs in
let cfs,priorities = List.split cfs in
let coers,fs = List.split cfs in
let extract_name acc = function
Vernacexpr.AssumExpr((_,Name id),_) -> id::acc
| Vernacexpr.DefExpr ((_,Name id),_,_) -> id::acc
| _ -> acc in
let allnames = idstruc::(List.fold_left extract_name [] fs) in
let () = match List.duplicates Id.equal allnames with
| [] -> ()
| id :: _ -> user_err (str "Two objects have the same name" ++ spc () ++ quote (Id.print id))
in
let isnot_class = match kind with Class false -> false | _ -> true in
if isnot_class && List.exists (fun opt -> not (Option.is_empty opt)) priorities then
error "Priorities only allowed for type class substructures";
(* Now, younger decl in params and fields is on top *)
let (pl, ctx), arity, template, implpars, params, implfs, fields =
States.with_state_protection (fun () ->
typecheck_params_and_fields (kind = Class true) idstruc pl s ps notations fs) () in
let sign = structure_signature (fields@params) in
let gr = match kind with
| Class def ->
let priorities = List.map (fun id -> {hint_priority = id; hint_pattern = None}) priorities in
let gr = declare_class finite def poly ctx (loc,idstruc) idbuild
implpars params arity template implfs fields is_coe coers priorities sign in
gr
| _ ->
let implfs = List.map
(fun impls -> implpars @ Impargs.lift_implicits
(succ (List.length params)) impls) implfs in
let ind = declare_structure finite poly ctx idstruc
idbuild implpars params arity template implfs
fields is_coe (List.map (fun coe -> not (Option.is_empty coe)) coers) sign in
IndRef ind
in
Universes.register_universe_binders gr pl;
gr
|