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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2017 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open CErrors
open Util
open Names
open Cic
open Term
open Inductive
open Reduction
open Typeops
open Pp
open Declarations
open Environ
let rec debug_string_of_mp = function
| MPfile sl -> DirPath.to_string sl
| MPbound uid -> "bound("^MBId.to_string uid^")"
| MPdot (mp,l) -> debug_string_of_mp mp ^ "." ^ Label.to_string l
let rec string_of_mp = function
| MPfile sl -> DirPath.to_string sl
| MPbound uid -> MBId.to_string uid
| MPdot (mp,l) -> string_of_mp mp ^ "." ^ Label.to_string l
let string_of_mp mp =
if !Flags.debug then debug_string_of_mp mp else string_of_mp mp
let prkn kn =
let (mp,_,l) = KerName.repr kn in
str(string_of_mp mp ^ "." ^ Label.to_string l)
let prcon c =
let ck = Constant.canonical c in
let uk = Constant.user c in
if KerName.equal ck uk then prkn uk else (prkn uk ++str"(="++prkn ck++str")")
(* Same as noccur_between but may perform reductions.
Could be refined more... *)
let weaker_noccur_between env x nvars t =
if noccur_between x nvars t then Some t
else
let t' = whd_all env t in
if noccur_between x nvars t' then Some t'
else None
let is_constructor_head t =
match fst(decompose_app t) with
| Rel _ -> true
| _ -> false
let conv_ctxt_prefix env (ctx1:rel_context) ctx2 =
let rec chk env rctx1 rctx2 =
match rctx1, rctx2 with
(LocalAssum (_,ty1) as d1)::rctx1', LocalAssum (_,ty2)::rctx2' ->
conv env ty1 ty2;
chk (push_rel d1 env) rctx1' rctx2'
| (LocalDef (_,bd1,ty1) as d1)::rctx1', LocalDef (_,bd2,ty2)::rctx2' ->
conv env ty1 ty2;
conv env bd1 bd2;
chk (push_rel d1 env) rctx1' rctx2'
| [],_ -> ()
| _ -> failwith "non convertible contexts" in
chk env (List.rev ctx1) (List.rev ctx2)
(************************************************************************)
(* Various well-formedness check for inductive declarations *)
(* Errors related to inductive constructions *)
type inductive_error =
| NonPos of env * constr * constr
| NotEnoughArgs of env * constr * constr
| NotConstructor of env * constr * constr
| NonPar of env * constr * int * constr * constr
| SameNamesTypes of Id.t
| SameNamesConstructors of Id.t
| SameNamesOverlap of Id.t list
| NotAnArity of Id.t
| BadEntry
exception InductiveError of inductive_error
(************************************************************************)
(************************************************************************)
(* Typing the arities and constructor types *)
let rec sorts_of_constr_args env t =
let t = whd_allnolet env t in
match t with
| Prod (name,c1,c2) ->
let varj = infer_type env c1 in
let env1 = push_rel (LocalAssum (name,c1)) env in
varj :: sorts_of_constr_args env1 c2
| LetIn (name,def,ty,c) ->
let env1 = push_rel (LocalDef (name,def,ty)) env in
sorts_of_constr_args env1 c
| _ when is_constructor_head t -> []
| _ -> anomaly ~label:"infos_and_sort" (Pp.str "not a positive constructor.")
(* Prop and Set are small *)
let is_small_sort = function
| Prop _ -> true
| _ -> false
let is_logic_sort = function
| Prop Null -> true
| _ -> false
(* [infos] is a sequence of pair [islogic,issmall] for each type in
the product of a constructor or arity *)
let is_small_constr infos = List.for_all (fun s -> is_small_sort s) infos
let is_logic_constr infos = List.for_all (fun s -> is_logic_sort s) infos
(* An inductive definition is a "unit" if it has only one constructor
and that all arguments expected by this constructor are
logical, this is the case for equality, conjunction of logical properties
*)
let is_unit constrsinfos =
match constrsinfos with (* One info = One constructor *)
| [|constrinfos|] -> is_logic_constr constrinfos
| [||] -> (* type without constructors *) true
| _ -> false
let small_unit constrsinfos =
let issmall = Array.for_all is_small_constr constrsinfos
and isunit = is_unit constrsinfos in
issmall, isunit
(* check information related to inductive arity *)
let typecheck_arity env params inds =
let nparamargs = rel_context_nhyps params in
let nparamdecls = rel_context_length params in
let check_arity arctxt = function
| RegularArity mar ->
let ar = mar.mind_user_arity in
let _ = infer_type env ar in
conv env (it_mkProd_or_LetIn (Sort mar.mind_sort) arctxt) ar;
ar
| TemplateArity par ->
check_polymorphic_arity env params par;
it_mkProd_or_LetIn (Sort(Type par.template_level)) arctxt
in
let env_arities =
Array.fold_left
(fun env_ar ind ->
let ar_ctxt = ind.mind_arity_ctxt in
let _ = check_ctxt env ar_ctxt in
conv_ctxt_prefix env params ar_ctxt;
(* Arities (with params) are typed-checked here *)
let arity = check_arity ar_ctxt ind.mind_arity in
(* mind_nrealargs *)
let nrealargs = rel_context_nhyps ar_ctxt - nparamargs in
if ind.mind_nrealargs <> nrealargs then
failwith "bad number of real inductive arguments";
let nrealargs_ctxt = rel_context_length ar_ctxt - nparamdecls in
if ind.mind_nrealdecls <> nrealargs_ctxt then
failwith "bad length of real inductive arguments signature";
(* We do not need to generate the universe of full_arity; if
later, after the validation of the inductive definition,
full_arity is used as argument or subject to cast, an
upper universe will be generated *)
let id = ind.mind_typename in
let env_ar' = push_rel (LocalAssum (Name id, arity)) env_ar in
env_ar')
env
inds in
env_arities
(* Allowed eliminations *)
let check_predicativity env s small level =
match s, engagement env with
Type u, _ ->
(* let u' = fresh_local_univ () in *)
(* let cst = *)
(* merge_constraints (enforce_leq u u' empty_constraint) *)
(* (universes env) in *)
if not (Univ.check_leq (universes env) level u) then
failwith "impredicative Type inductive type"
| Prop Pos, ImpredicativeSet -> ()
| Prop Pos, _ ->
if not small then failwith "impredicative Set inductive type"
| Prop Null,_ -> ()
let sort_of_ind = function
| RegularArity mar -> mar.mind_sort
| TemplateArity par -> Type par.template_level
let all_sorts = [InProp;InSet;InType]
let small_sorts = [InProp;InSet]
let logical_sorts = [InProp]
let allowed_sorts issmall isunit s =
match family_of_sort s with
(* Type: all elimination allowed *)
| InType -> all_sorts
(* Small Set is predicative: all elimination allowed *)
| InSet when issmall -> all_sorts
(* Large Set is necessarily impredicative: forbids large elimination *)
| InSet -> small_sorts
(* Unitary/empty Prop: elimination to all sorts are realizable *)
(* unless the type is large. If it is large, forbids large elimination *)
(* which otherwise allows simulating the inconsistent system Type:Type *)
| InProp when isunit -> if issmall then all_sorts else small_sorts
(* Other propositions: elimination only to Prop *)
| InProp -> logical_sorts
let compute_elim_sorts env_ar params mib arity lc =
let inst = extended_rel_list 0 params in
let env_params = push_rel_context params env_ar in
let lc = Array.map
(fun c ->
hnf_prod_applist env_params (lift (rel_context_length params) c) inst)
lc in
let s = sort_of_ind arity in
let infos = Array.map (sorts_of_constr_args env_params) lc in
let (small,unit) = small_unit infos in
(* We accept recursive unit types... *)
(* compute the max of the sorts of the products of the constructor type *)
let level = max_inductive_sort
(Array.concat (Array.to_list (Array.map Array.of_list infos))) in
check_predicativity env_ar s small level;
allowed_sorts small unit s
let typecheck_one_inductive env params mib mip =
(* mind_typename and mind_consnames not checked *)
(* mind_reloc_tbl, mind_nb_constant, mind_nb_args not checked (VM) *)
(* mind_arity_ctxt, mind_arity, mind_nrealargs DONE (typecheck_arity) *)
(* mind_user_lc *)
let _ = Array.map (infer_type env) mip.mind_user_lc in
(* mind_nf_lc *)
let _ = Array.map (infer_type env) mip.mind_nf_lc in
Array.iter2 (conv env) mip.mind_nf_lc mip.mind_user_lc;
(* mind_consnrealdecls *)
let check_cons_args c n =
let ctx,_ = decompose_prod_assum c in
if n <> rel_context_length ctx - rel_context_length params then
failwith "bad number of real constructor arguments" in
Array.iter2 check_cons_args mip.mind_nf_lc mip.mind_consnrealdecls;
(* mind_kelim: checked by positivity criterion ? *)
let sorts =
compute_elim_sorts env params mib mip.mind_arity mip.mind_nf_lc in
let reject_sort s = not (List.mem_f family_equal s sorts) in
if List.exists reject_sort mip.mind_kelim then
failwith "elimination not allowed";
(* mind_recargs: checked by positivity criterion *)
()
(************************************************************************)
(************************************************************************)
(* Positivity *)
type ill_formed_ind =
| LocalNonPos of int
| LocalNotEnoughArgs of int
| LocalNotConstructor
| LocalNonPar of int * int * int
exception IllFormedInd of ill_formed_ind
(* [mind_extract_params mie] extracts the params from an inductive types
declaration, and checks that they are all present (and all the same)
for all the given types. *)
let mind_extract_params = decompose_prod_n_assum
let explain_ind_err ntyp env0 nbpar c err =
let (lpar,c') = mind_extract_params nbpar c in
let env = push_rel_context lpar env0 in
match err with
| LocalNonPos kt ->
raise (InductiveError (NonPos (env,c',Rel (kt+nbpar))))
| LocalNotEnoughArgs kt ->
raise (InductiveError
(NotEnoughArgs (env,c',Rel (kt+nbpar))))
| LocalNotConstructor ->
raise (InductiveError
(NotConstructor (env,c',Rel (ntyp+nbpar))))
| LocalNonPar (n,i,l) ->
raise (InductiveError
(NonPar (env,c',n,Rel i,Rel (l+nbpar))))
let failwith_non_pos n ntypes c =
for k = n to n + ntypes - 1 do
if not (noccurn k c) then raise (IllFormedInd (LocalNonPos (k-n+1)))
done
let failwith_non_pos_vect n ntypes v =
Array.iter (failwith_non_pos n ntypes) v;
anomaly ~label:"failwith_non_pos_vect" (Pp.str "some k in [n;n+ntypes-1] should occur.")
let failwith_non_pos_list n ntypes l =
List.iter (failwith_non_pos n ntypes) l;
anomaly ~label:"failwith_non_pos_list" (Pp.str "some k in [n;n+ntypes-1] should occur.")
(* Conclusion of constructors: check the inductive type is called with
the expected parameters *)
let check_correct_par (env,n,ntypes,_) hyps l largs =
let nparams = rel_context_nhyps hyps in
let largs = Array.of_list largs in
if Array.length largs < nparams then
raise (IllFormedInd (LocalNotEnoughArgs l));
let (lpar,largs') = Array.chop nparams largs in
let nhyps = List.length hyps in
let rec check k index = function
| [] -> ()
| LocalDef _ :: hyps -> check k (index+1) hyps
| _::hyps ->
match whd_all env lpar.(k) with
| Rel w when w = index -> check (k-1) (index+1) hyps
| _ -> raise (IllFormedInd (LocalNonPar (k+1,index,l)))
in check (nparams-1) (n-nhyps) hyps;
if not (Array.for_all (noccur_between n ntypes) largs') then
failwith_non_pos_vect n ntypes largs'
(* Arguments of constructor: check the number of recursive parameters nrecp.
the first parameters which are constant in recursive arguments
n is the current depth, nmr is the maximum number of possible
recursive parameters *)
let check_rec_par (env,n,_,_) hyps nrecp largs =
let (lpar,_) = List.chop nrecp largs in
let rec find index =
function
| ([],_) -> ()
| (_,[]) ->
failwith "number of recursive parameters cannot be greater than the number of parameters."
| (lp,LocalDef _ :: hyps) -> find (index-1) (lp,hyps)
| (p::lp,_::hyps) ->
(match whd_all env p with
| Rel w when w = index -> find (index-1) (lp,hyps)
| _ -> failwith "bad number of recursive parameters")
in find (n-1) (lpar,List.rev hyps)
let lambda_implicit_lift n a =
let lambda_implicit a = Lambda(Anonymous,Evar(0,[||]),a) in
iterate lambda_implicit n (lift n a)
(* This removes global parameters of the inductive types in lc (for
nested inductive types only ) *)
let abstract_mind_lc env ntyps npars lc =
if npars = 0 then
lc
else
let make_abs =
List.init ntyps
(function i -> lambda_implicit_lift npars (Rel (i+1)))
in
Array.map (substl make_abs) lc
(* [env] is the typing environment
[n] is the dB of the last inductive type
[ntypes] is the number of inductive types in the definition
(i.e. range of inductives is [n; n+ntypes-1])
[lra] is the list of recursive tree of each variable
*)
let ienv_push_var (env, n, ntypes, lra) (x,a,ra) =
(push_rel (LocalAssum (x,a)) env, n+1, ntypes, (Norec,ra)::lra)
let ienv_push_inductive (env, n, ntypes, ra_env) ((mi,u),lpar) =
let auxntyp = 1 in
let specif = lookup_mind_specif env mi in
let env' =
let decl = LocalAssum (Anonymous,
hnf_prod_applist env (type_of_inductive env (specif,u)) lpar) in
push_rel decl env in
let ra_env' =
(Imbr mi,(Rtree.mk_rec_calls 1).(0)) ::
List.map (fun (r,t) -> (r,Rtree.lift 1 t)) ra_env in
(* New index of the inductive types *)
let newidx = n + auxntyp in
(env', newidx, ntypes, ra_env')
let rec ienv_decompose_prod (env,_,_,_ as ienv) n c =
if n=0 then (ienv,c) else
let c' = whd_all env c in
match c' with
Prod(na,a,b) ->
let ienv' = ienv_push_var ienv (na,a,mk_norec) in
ienv_decompose_prod ienv' (n-1) b
| _ -> assert false
(* The recursive function that checks positivity and builds the list
of recursive arguments *)
let check_positivity_one (env, _,ntypes,_ as ienv) hyps nrecp (_,i as ind) indlc =
let lparams = rel_context_length hyps in
(* check the inductive types occur positively in [c] *)
let rec check_pos (env, n, ntypes, ra_env as ienv) c =
let x,largs = decompose_app (whd_all env c) in
match x with
| Prod (na,b,d) ->
assert (List.is_empty largs);
(match weaker_noccur_between env n ntypes b with
None -> failwith_non_pos_list n ntypes [b]
| Some b ->
check_pos (ienv_push_var ienv (na, b, mk_norec)) d)
| Rel k ->
(try
let (ra,rarg) = List.nth ra_env (k-1) in
(match ra with
Mrec _ -> check_rec_par ienv hyps nrecp largs
| _ -> ());
if not (List.for_all (noccur_between n ntypes) largs)
then failwith_non_pos_list n ntypes largs
else rarg
with Failure _ | Invalid_argument _ -> mk_norec)
| Ind ind_kn ->
(* If the inductive type being defined appears in a
parameter, then we have an imbricated type *)
if List.for_all (noccur_between n ntypes) largs then mk_norec
else check_positive_imbr ienv (ind_kn, largs)
| err ->
if noccur_between n ntypes x &&
List.for_all (noccur_between n ntypes) largs
then mk_norec
else failwith_non_pos_list n ntypes (x::largs)
(* accesses to the environment are not factorised, but is it worth it? *)
and check_positive_imbr (env,n,ntypes,ra_env as ienv) ((mi,u), largs) =
let (mib,mip) = lookup_mind_specif env mi in
let auxnpar = mib.mind_nparams_rec in
let nonrecpar = mib.mind_nparams - auxnpar in
let (lpar,auxlargs) =
try List.chop auxnpar largs
with Failure _ -> raise (IllFormedInd (LocalNonPos n)) in
(* If the inductive appears in the args (non params) then the
definition is not positive. *)
if not (List.for_all (noccur_between n ntypes) auxlargs) then
raise (IllFormedInd (LocalNonPos n));
(* We do not deal with imbricated mutual inductive types *)
let auxntyp = mib.mind_ntypes in
if auxntyp <> 1 then raise (IllFormedInd (LocalNonPos n));
(* The nested inductive type with parameters removed *)
let auxlcvect = abstract_mind_lc env auxntyp auxnpar mip.mind_nf_lc in
(* Extends the environment with a variable corresponding to
the inductive def *)
let (env',_,_,_ as ienv') = ienv_push_inductive ienv ((mi,u),lpar) in
(* Parameters expressed in env' *)
let lpar' = List.map (lift auxntyp) lpar in
let irecargs =
(* fails if the inductive type occurs non positively *)
(* with recursive parameters substituted *)
Array.map
(function c ->
let c' = hnf_prod_applist env' c lpar' in
(* skip non-recursive parameters *)
let (ienv',c') = ienv_decompose_prod ienv' nonrecpar c' in
check_constructors ienv' false c')
auxlcvect in
(Rtree.mk_rec [|mk_paths (Imbr mi) irecargs|]).(0)
(* check the inductive types occur positively in the products of C, if
check_head=true, also check the head corresponds to a constructor of
the ith type *)
and check_constructors ienv check_head c =
let rec check_constr_rec (env,n,ntypes,ra_env as ienv) lrec c =
let x,largs = decompose_app (whd_all env c) in
match x with
| Prod (na,b,d) ->
assert (List.is_empty largs);
let recarg = check_pos ienv b in
let ienv' = ienv_push_var ienv (na,b,mk_norec) in
check_constr_rec ienv' (recarg::lrec) d
| hd ->
if check_head then
match hd with
| Rel j when j = (n + ntypes - i - 1) ->
check_correct_par ienv hyps (ntypes-i) largs
| _ ->
raise (IllFormedInd LocalNotConstructor)
else
if not (List.for_all (noccur_between n ntypes) largs)
then raise (IllFormedInd (LocalNonPos n));
List.rev lrec
in check_constr_rec ienv [] c
in
let irecargs =
Array.map
(fun c ->
let _,rawc = mind_extract_params lparams c in
try
check_constructors ienv true rawc
with IllFormedInd err ->
explain_ind_err (ntypes-i) env lparams c err)
indlc
in mk_paths (Mrec ind) irecargs
let check_subtree t1 t2 =
let cmp_labels l1 l2 = l1 == Norec || eq_recarg l1 l2 in
if not (Rtree.equiv eq_recarg cmp_labels t1 t2)
then failwith "bad recursive trees"
(* if t1=t2 then () else msg_warning (str"TODO: check recursive positions")*)
let check_positivity env_ar mind params nrecp inds =
let ntypes = Array.length inds in
let rc =
Array.mapi (fun j t -> (Mrec(mind,j),t)) (Rtree.mk_rec_calls ntypes) in
let lra_ind = List.rev (Array.to_list rc) in
let lparams = rel_context_length params in
let check_one i mip =
let ra_env =
List.init lparams (fun _ -> (Norec,mk_norec)) @ lra_ind in
let ienv = (env_ar, 1+lparams, ntypes, ra_env) in
check_positivity_one ienv params nrecp (mind,i) mip.mind_nf_lc
in
let irecargs = Array.mapi check_one inds in
let wfp = Rtree.mk_rec irecargs in
Array.iter2 (fun ind wfpi -> check_subtree ind.mind_recargs wfpi) inds wfp
(* Check arities and constructors *)
let check_subtyping_arity_constructor env (subst : Univ.Instance.t) (arcn : constr) numparams is_arity =
let numchecked = ref 0 in
let basic_check ev tp =
if !numchecked < numparams then () else conv_leq ev tp (Term.subst_instance_constr subst tp);
numchecked := !numchecked + 1
in
let check_typ typ typ_env =
match typ with
| LocalAssum (_, typ') ->
begin
try
basic_check typ_env typ'; Environ.push_rel typ typ_env
with NotConvertible ->
anomaly ~label:"bad inductive subtyping relation" (Pp.str "Invalid subtyping relation")
end
| _ -> anomaly (Pp.str "")
in
let typs, codom = dest_prod env arcn in
let last_env = fold_rel_context_outside check_typ typs ~init:env in
if not is_arity then basic_check last_env codom else ()
(* Check that the subtyping information inferred for inductive types in the block is correct. *)
(* This check produces a value of the unit type if successful or raises an anomaly if check fails. *)
let check_subtyping cumi paramsctxt env inds =
let open Univ in
let numparams = rel_context_nhyps paramsctxt in
(** In [env] we already have [ Var(0) ... Var(n-1) |- cst ] available.
We must produce the substitution σ : [ Var(i) -> Var (i + n) | 0 <= i < n]
and push the constraints [ Var(n) ... Var(2n - 1) |- cst{σ} ], together
with the cumulativity constraints [ cumul_cst ]. *)
let len = AUContext.size (ACumulativityInfo.univ_context cumi) in
let inst = Instance.of_array (Array.init len (fun i -> Level.var (i + len))) in
let other_context = ACumulativityInfo.univ_context cumi in
let uctx_other = UContext.make (inst, AUContext.instantiate inst other_context) in
let cumul_context = AUContext.repr (ACumulativityInfo.subtyp_context cumi) in
let cumul_cst = UContext.constraints cumul_context in
let env = Environ.push_context uctx_other env in
let env = Environ.add_constraints cumul_cst env in
(* process individual inductive types: *)
Array.iter (fun { mind_user_lc = lc; mind_arity = arity } ->
match arity with
| RegularArity { mind_user_arity = full_arity} ->
check_subtyping_arity_constructor env inst full_arity numparams true;
Array.iter (fun cnt -> check_subtyping_arity_constructor env inst cnt numparams false) lc
| TemplateArity _ -> ()
) inds
(************************************************************************)
(************************************************************************)
let check_inductive env kn mib =
Flags.if_verbose Feedback.msg_notice (str " checking ind: " ++ MutInd.print kn);
(* check mind_constraints: should be consistent with env *)
let ind_ctx =
match mib.mind_universes with
| Monomorphic_ind _ -> Univ.UContext.empty (** Already in the global environment *)
| Polymorphic_ind auctx -> Univ.AUContext.repr auctx
| Cumulative_ind cumi ->
Univ.AUContext.repr (Univ.ACumulativityInfo.univ_context cumi)
in
let env = Environ.push_context ind_ctx env in
(* check mind_record : TODO ? check #constructor = 1 ? *)
(* check mind_finite : always OK *)
(* check mind_ntypes *)
if Array.length mib.mind_packets <> mib.mind_ntypes then
user_err Pp.(str "not the right number of packets");
(* check mind_params_ctxt *)
let params = mib.mind_params_ctxt in
let _ = check_ctxt env params in
(* check mind_nparams *)
if rel_context_nhyps params <> mib.mind_nparams then
user_err Pp.(str "number the right number of parameters");
(* mind_packets *)
(* - check arities *)
let env_ar = typecheck_arity env params mib.mind_packets in
(* - check constructor types *)
Array.iter (typecheck_one_inductive env_ar params mib) mib.mind_packets;
(* check the inferred subtyping relation *)
let () =
match mib.mind_universes with
| Monomorphic_ind _ | Polymorphic_ind _ -> ()
| Cumulative_ind acumi ->
check_subtyping acumi params env_ar mib.mind_packets
in
(* check mind_nparams_rec: positivity condition *)
check_positivity env_ar kn params mib.mind_nparams_rec mib.mind_packets;
(* check mind_equiv... *)
(* Now we can add the inductive *)
add_mind kn mib env
|