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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 *)
(************************************************************************)
module CVars = Vars
open Pp
open CErrors
open Util
open Term
open Environ
open EConstr
open Vars
open Reductionops
open Inductive
open Inductiveops
open Typeops
open Arguments_renaming
open Pretype_errors
open Context.Rel.Declaration
let push_rec_types pfix env =
let (i, c, t) = pfix in
let inj c = EConstr.Unsafe.to_constr c in
push_rec_types (i, Array.map inj c, Array.map inj t) env
let meta_type evd mv =
let ty =
try Evd.meta_ftype evd mv
with Not_found -> anomaly (str "unknown meta ?" ++ str (Nameops.string_of_meta mv) ++ str ".") in
let ty = Evd.map_fl EConstr.of_constr ty in
meta_instance evd ty
let constant_type_knowing_parameters env sigma (cst, u) jl =
let u = Unsafe.to_instance u in
let paramstyp = Array.map (fun j -> lazy (EConstr.to_constr sigma j.uj_type)) jl in
EConstr.of_constr (type_of_constant_knowing_parameters_in env (cst, u) paramstyp)
let inductive_type_knowing_parameters env sigma (ind,u) jl =
let u = Unsafe.to_instance u in
let mspec = lookup_mind_specif env ind in
let paramstyp = Array.map (fun j -> lazy (EConstr.to_constr sigma j.uj_type)) jl in
EConstr.of_constr (Inductive.type_of_inductive_knowing_parameters env (mspec,u) paramstyp)
let e_type_judgment env evdref j =
match EConstr.kind !evdref (whd_all env !evdref j.uj_type) with
| Sort s -> {utj_val = j.uj_val; utj_type = ESorts.kind !evdref s }
| Evar ev ->
let (evd,s) = Evardefine.define_evar_as_sort env !evdref ev in
evdref := evd; { utj_val = j.uj_val; utj_type = s }
| _ -> error_not_a_type env !evdref j
let e_assumption_of_judgment env evdref j =
try (e_type_judgment env evdref j).utj_val
with Type_errors.TypeError _ | PretypeError _ ->
error_assumption env !evdref j
let e_judge_of_apply env evdref funj argjv =
let rec apply_rec n typ = function
| [] ->
{ uj_val = mkApp (j_val funj, Array.map j_val argjv);
uj_type = typ }
| hj::restjl ->
match EConstr.kind !evdref (whd_all env !evdref typ) with
| Prod (_,c1,c2) ->
if Evarconv.e_cumul env evdref hj.uj_type c1 then
apply_rec (n+1) (subst1 hj.uj_val c2) restjl
else
error_cant_apply_bad_type env !evdref (n, c1, hj.uj_type) funj argjv
| Evar ev ->
let (evd',t) = Evardefine.define_evar_as_product !evdref ev in
evdref := evd';
let (_,_,c2) = destProd evd' t in
apply_rec (n+1) (subst1 hj.uj_val c2) restjl
| _ ->
error_cant_apply_not_functional env !evdref funj argjv
in
apply_rec 1 funj.uj_type (Array.to_list argjv)
let e_check_branch_types env evdref (ind,u) cj (lfj,explft) =
if not (Int.equal (Array.length lfj) (Array.length explft)) then
error_number_branches env !evdref cj (Array.length explft);
for i = 0 to Array.length explft - 1 do
if not (Evarconv.e_cumul env evdref lfj.(i).uj_type explft.(i)) then
error_ill_formed_branch env !evdref cj.uj_val ((ind,i+1),u) lfj.(i).uj_type explft.(i)
done
let max_sort l =
if Sorts.List.mem InType l then InType else
if Sorts.List.mem InSet l then InSet else InProp
let e_is_correct_arity env evdref c pj ind specif params =
let arsign = make_arity_signature env !evdref true (make_ind_family (ind,params)) in
let allowed_sorts = elim_sorts specif in
let error () = Pretype_errors.error_elim_arity env !evdref ind allowed_sorts c pj None in
let rec srec env pt ar =
let pt' = whd_all env !evdref pt in
match EConstr.kind !evdref pt', ar with
| Prod (na1,a1,t), (LocalAssum (_,a1'))::ar' ->
if not (Evarconv.e_cumul env evdref a1 a1') then error ();
srec (push_rel (LocalAssum (na1,a1)) env) t ar'
| Sort s, [] ->
let s = ESorts.kind !evdref s in
if not (Sorts.List.mem (Sorts.family s) allowed_sorts)
then error ()
| Evar (ev,_), [] ->
let evd, s = Evd.fresh_sort_in_family env !evdref (max_sort allowed_sorts) in
evdref := Evd.define ev (Constr.mkSort s) evd
| _, (LocalDef _ as d)::ar' ->
srec (push_rel d env) (lift 1 pt') ar'
| _ ->
error ()
in
srec env pj.uj_type (List.rev arsign)
let lambda_applist_assum sigma n c l =
let rec app n subst t l =
if Int.equal n 0 then
if l == [] then substl subst t
else anomaly (Pp.str "Not enough arguments.")
else match EConstr.kind sigma t, l with
| Lambda(_,_,c), arg::l -> app (n-1) (arg::subst) c l
| LetIn(_,b,_,c), _ -> app (n-1) (substl subst b::subst) c l
| _ -> anomaly (Pp.str "Not enough lambda/let's.") in
app n [] c l
let e_type_case_branches env evdref (ind,largs) pj c =
let specif = lookup_mind_specif env (fst ind) in
let nparams = inductive_params specif in
let (params,realargs) = List.chop nparams largs in
let p = pj.uj_val in
let params = List.map EConstr.Unsafe.to_constr params in
let () = e_is_correct_arity env evdref c pj ind specif params in
let lc = build_branches_type ind specif params (EConstr.to_constr !evdref p) in
let lc = Array.map EConstr.of_constr lc in
let n = (snd specif).Declarations.mind_nrealdecls in
let ty = whd_betaiota !evdref (lambda_applist_assum !evdref (n+1) p (realargs@[c])) in
(lc, ty)
let e_judge_of_case env evdref ci pj cj lfj =
let ((ind, u), spec) =
try find_mrectype env !evdref cj.uj_type
with Not_found -> error_case_not_inductive env !evdref cj in
let indspec = ((ind, EInstance.kind !evdref u), spec) in
let _ = check_case_info env (fst indspec) ci in
let (bty,rslty) = e_type_case_branches env evdref indspec pj cj.uj_val in
e_check_branch_types env evdref (fst indspec) cj (lfj,bty);
{ uj_val = mkCase (ci, pj.uj_val, cj.uj_val, Array.map j_val lfj);
uj_type = rslty }
let check_type_fixpoint ?loc env evdref lna lar vdefj =
let lt = Array.length vdefj in
if Int.equal (Array.length lar) lt then
for i = 0 to lt-1 do
if not (Evarconv.e_cumul env evdref (vdefj.(i)).uj_type
(lift lt lar.(i))) then
error_ill_typed_rec_body ?loc env !evdref
i lna vdefj lar
done
(* FIXME: might depend on the level of actual parameters!*)
let check_allowed_sort env sigma ind c p =
let pj = Retyping.get_judgment_of env sigma p in
let ksort = family_of_sort (ESorts.kind sigma (sort_of_arity env sigma pj.uj_type)) in
let specif = Global.lookup_inductive (fst ind) in
let sorts = elim_sorts specif in
if not (List.exists ((==) ksort) sorts) then
let s = inductive_sort_family (snd specif) in
error_elim_arity env sigma ind sorts c pj
(Some(ksort,s,Type_errors.error_elim_explain ksort s))
let e_judge_of_cast env evdref cj k tj =
let expected_type = tj.utj_val in
if not (Evarconv.e_cumul env evdref cj.uj_type expected_type) then
error_actual_type_core env !evdref cj expected_type;
{ uj_val = mkCast (cj.uj_val, k, expected_type);
uj_type = expected_type }
let enrich_env env evdref =
let penv = Environ.pre_env env in
let penv' = Pre_env.({ penv with env_stratification =
{ penv.env_stratification with env_universes = Evd.universes !evdref } }) in
Environ.env_of_pre_env penv'
let check_fix env sigma pfix =
let inj c = EConstr.to_constr sigma c in
let (idx, (ids, cs, ts)) = pfix in
check_fix env (idx, (ids, Array.map inj cs, Array.map inj ts))
let check_cofix env sigma pcofix =
let inj c = EConstr.to_constr sigma c in
let (idx, (ids, cs, ts)) = pcofix in
check_cofix env (idx, (ids, Array.map inj cs, Array.map inj ts))
(* The typing machine with universes and existential variables. *)
let judge_of_prop =
{ uj_val = EConstr.mkProp;
uj_type = EConstr.mkSort type1_sort }
let judge_of_set =
{ uj_val = EConstr.mkSet;
uj_type = EConstr.mkSort type1_sort }
let judge_of_prop_contents = function
| Null -> judge_of_prop
| Pos -> judge_of_set
let judge_of_type u =
let uu = Univ.Universe.super u in
{ uj_val = EConstr.mkType u;
uj_type = EConstr.mkType uu }
let judge_of_relative env v =
Termops.on_judgment EConstr.of_constr (judge_of_relative env v)
let judge_of_variable env id =
Termops.on_judgment EConstr.of_constr (judge_of_variable env id)
let judge_of_projection env sigma p cj =
let pb = lookup_projection p env in
let (ind,u), args =
try find_mrectype env sigma cj.uj_type
with Not_found -> error_case_not_inductive env sigma cj
in
let u = EInstance.kind sigma u in
let ty = EConstr.of_constr (CVars.subst_instance_constr u pb.Declarations.proj_type) in
let ty = substl (cj.uj_val :: List.rev args) ty in
{uj_val = EConstr.mkProj (p,cj.uj_val);
uj_type = ty}
let judge_of_abstraction env name var j =
{ uj_val = mkLambda (name, var.utj_val, j.uj_val);
uj_type = mkProd (name, var.utj_val, j.uj_type) }
let judge_of_product env name t1 t2 =
let s = sort_of_product env t1.utj_type t2.utj_type in
{ uj_val = mkProd (name, t1.utj_val, t2.utj_val);
uj_type = mkSort s }
let judge_of_letin env name defj typj j =
{ uj_val = mkLetIn (name, defj.uj_val, typj.utj_val, j.uj_val) ;
uj_type = subst1 defj.uj_val j.uj_type }
(* cstr must be in n.f. w.r.t. evars and execute returns a judgement
where both the term and type are in n.f. *)
let rec execute env evdref cstr =
let cstr = whd_evar !evdref cstr in
match EConstr.kind !evdref cstr with
| Meta n ->
{ uj_val = cstr; uj_type = meta_type !evdref n }
| Evar ev ->
let ty = EConstr.existential_type !evdref ev in
let jty = execute env evdref ty in
let jty = e_assumption_of_judgment env evdref jty in
{ uj_val = cstr; uj_type = jty }
| Rel n ->
judge_of_relative env n
| Var id ->
judge_of_variable env id
| Const (c, u) ->
let u = EInstance.kind !evdref u in
make_judge cstr (EConstr.of_constr (rename_type_of_constant env (c, u)))
| Ind (ind, u) ->
let u = EInstance.kind !evdref u in
make_judge cstr (EConstr.of_constr (rename_type_of_inductive env (ind, u)))
| Construct (cstruct, u) ->
let u = EInstance.kind !evdref u in
make_judge cstr (EConstr.of_constr (rename_type_of_constructor env (cstruct, u)))
| Case (ci,p,c,lf) ->
let cj = execute env evdref c in
let pj = execute env evdref p in
let lfj = execute_array env evdref lf in
e_judge_of_case env evdref ci pj cj lfj
| Fix ((vn,i as vni),recdef) ->
let (_,tys,_ as recdef') = execute_recdef env evdref recdef in
let fix = (vni,recdef') in
check_fix env !evdref fix;
make_judge (mkFix fix) tys.(i)
| CoFix (i,recdef) ->
let (_,tys,_ as recdef') = execute_recdef env evdref recdef in
let cofix = (i,recdef') in
check_cofix env !evdref cofix;
make_judge (mkCoFix cofix) tys.(i)
| Sort s ->
begin match ESorts.kind !evdref s with
| Prop c ->
judge_of_prop_contents c
| Type u ->
judge_of_type u
end
| Proj (p, c) ->
let cj = execute env evdref c in
judge_of_projection env !evdref p cj
| App (f,args) ->
let jl = execute_array env evdref args in
let j =
match EConstr.kind !evdref f with
| Ind (ind, u) when EInstance.is_empty u && Environ.template_polymorphic_ind ind env ->
make_judge f
(inductive_type_knowing_parameters env !evdref (ind, u) jl)
| Const (cst, u) when EInstance.is_empty u && Environ.template_polymorphic_constant cst env ->
make_judge f
(constant_type_knowing_parameters env !evdref (cst, u) jl)
| _ ->
(* No template polymorphism *)
execute env evdref f
in
e_judge_of_apply env evdref j jl
| Lambda (name,c1,c2) ->
let j = execute env evdref c1 in
let var = e_type_judgment env evdref j in
let env1 = push_rel (LocalAssum (name, var.utj_val)) env in
let j' = execute env1 evdref c2 in
judge_of_abstraction env1 name var j'
| Prod (name,c1,c2) ->
let j = execute env evdref c1 in
let varj = e_type_judgment env evdref j in
let env1 = push_rel (LocalAssum (name, varj.utj_val)) env in
let j' = execute env1 evdref c2 in
let varj' = e_type_judgment env1 evdref j' in
judge_of_product env name varj varj'
| LetIn (name,c1,c2,c3) ->
let j1 = execute env evdref c1 in
let j2 = execute env evdref c2 in
let j2 = e_type_judgment env evdref j2 in
let _ = e_judge_of_cast env evdref j1 DEFAULTcast j2 in
let env1 = push_rel (LocalDef (name, j1.uj_val, j2.utj_val)) env in
let j3 = execute env1 evdref c3 in
judge_of_letin env name j1 j2 j3
| Cast (c,k,t) ->
let cj = execute env evdref c in
let tj = execute env evdref t in
let tj = e_type_judgment env evdref tj in
e_judge_of_cast env evdref cj k tj
and execute_recdef env evdref (names,lar,vdef) =
let larj = execute_array env evdref lar in
let lara = Array.map (e_assumption_of_judgment env evdref) larj in
let env1 = push_rec_types (names,lara,vdef) env in
let vdefj = execute_array env1 evdref vdef in
let vdefv = Array.map j_val vdefj in
let _ = check_type_fixpoint env1 evdref names lara vdefj in
(names,lara,vdefv)
and execute_array env evdref = Array.map (execute env evdref)
let e_check env evdref c t =
let env = enrich_env env evdref in
let j = execute env evdref c in
if not (Evarconv.e_cumul env evdref j.uj_type t) then
error_actual_type_core env !evdref j t
(* Type of a constr *)
let unsafe_type_of env evd c =
let evdref = ref evd in
let env = enrich_env env evdref in
let j = execute env evdref c in
j.uj_type
(* Sort of a type *)
let e_sort_of env evdref c =
let env = enrich_env env evdref in
let j = execute env evdref c in
let a = e_type_judgment env evdref j in
a.utj_type
(* Try to solve the existential variables by typing *)
let type_of ?(refresh=false) env evd c =
let evdref = ref evd in
let env = enrich_env env evdref in
let j = execute env evdref c in
(* side-effect on evdref *)
if refresh then
Evarsolve.refresh_universes ~onlyalg:true (Some false) env !evdref j.uj_type
else !evdref, j.uj_type
let e_type_of ?(refresh=false) env evdref c =
let env = enrich_env env evdref in
let j = execute env evdref c in
(* side-effect on evdref *)
if refresh then
let evd, c = Evarsolve.refresh_universes ~onlyalg:true (Some false) env !evdref j.uj_type in
let () = evdref := evd in
c
else j.uj_type
let e_solve_evars env evdref c =
let env = enrich_env env evdref in
let c = (execute env evdref c).uj_val in
(* side-effect on evdref *)
nf_evar !evdref c
let _ = Evarconv.set_solve_evars (fun env evdref c -> e_solve_evars env evdref c)
|