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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 *)
(************************************************************************)
(* Created by Hugo Herbelin from contents related to inductive schemes
initially developed by Christine Paulin (induction schemes), Vincent
Siles (decidable equality and boolean equality) and Matthieu Sozeau
(combined scheme) in file command.ml, Sep 2009 *)
(* This file provides entry points for manually or automatically
declaring new schemes *)
open Pp
open CErrors
open Util
open Names
open Declarations
open Entries
open Term
open Inductive
open Decl_kinds
open Indrec
open Declare
open Libnames
open Globnames
open Goptions
open Nameops
open Termops
open Pretyping
open Nametab
open Smartlocate
open Vernacexpr
open Ind_tables
open Auto_ind_decl
open Eqschemes
open Elimschemes
open Context.Rel.Declaration
(* Flags governing automatic synthesis of schemes *)
let elim_flag = ref true
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "automatic declaration of induction schemes";
optkey = ["Elimination";"Schemes"];
optread = (fun () -> !elim_flag) ;
optwrite = (fun b -> elim_flag := b) }
let bifinite_elim_flag = ref false
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "automatic declaration of induction schemes for non-recursive types";
optkey = ["Nonrecursive";"Elimination";"Schemes"];
optread = (fun () -> !bifinite_elim_flag) ;
optwrite = (fun b -> bifinite_elim_flag := b) }
let _ =
declare_bool_option
{ optsync = true;
optdepr = true; (* compatibility 2014-09-03*)
optname = "automatic declaration of induction schemes for non-recursive types";
optkey = ["Record";"Elimination";"Schemes"];
optread = (fun () -> !bifinite_elim_flag) ;
optwrite = (fun b -> bifinite_elim_flag := b) }
let case_flag = ref false
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "automatic declaration of case analysis schemes";
optkey = ["Case";"Analysis";"Schemes"];
optread = (fun () -> !case_flag) ;
optwrite = (fun b -> case_flag := b) }
let eq_flag = ref false
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "automatic declaration of boolean equality";
optkey = ["Boolean";"Equality";"Schemes"];
optread = (fun () -> !eq_flag) ;
optwrite = (fun b -> eq_flag := b) }
let _ = (* compatibility *)
declare_bool_option
{ optsync = true;
optdepr = true;
optname = "automatic declaration of boolean equality";
optkey = ["Equality";"Scheme"];
optread = (fun () -> !eq_flag) ;
optwrite = (fun b -> eq_flag := b) }
let is_eq_flag () = !eq_flag && Flags.version_strictly_greater Flags.V8_2
let eq_dec_flag = ref false
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "automatic declaration of decidable equality";
optkey = ["Decidable";"Equality";"Schemes"];
optread = (fun () -> !eq_dec_flag) ;
optwrite = (fun b -> eq_dec_flag := b) }
let rewriting_flag = ref false
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname ="automatic declaration of rewriting schemes for equality types";
optkey = ["Rewriting";"Schemes"];
optread = (fun () -> !rewriting_flag) ;
optwrite = (fun b -> rewriting_flag := b) }
(* Util *)
let define id internal ctx c t =
let f = declare_constant ~internal in
let kn = f id
(DefinitionEntry
{ const_entry_body = c;
const_entry_secctx = None;
const_entry_type = t;
const_entry_polymorphic = Flags.is_universe_polymorphism ();
const_entry_universes = snd (Evd.universe_context ctx);
const_entry_opaque = false;
const_entry_inline_code = false;
const_entry_feedback = None;
},
Decl_kinds.IsDefinition Scheme) in
definition_message id;
kn
(* Boolean equality *)
let declare_beq_scheme_gen internal names kn =
ignore (define_mutual_scheme beq_scheme_kind internal names kn)
let alarm what internal msg =
let debug = false in
match internal with
| UserAutomaticRequest
| InternalTacticRequest ->
(if debug then
Feedback.msg_debug
(hov 0 msg ++ fnl () ++ what ++ str " not defined.")); None
| _ -> Some msg
let try_declare_scheme what f internal names kn =
try f internal names kn
with e ->
let e = CErrors.push e in
let msg = match fst e with
| ParameterWithoutEquality cst ->
alarm what internal
(str "Boolean equality not found for parameter " ++ Printer.pr_global cst ++
str".")
| InductiveWithProduct ->
alarm what internal
(str "Unable to decide equality of functional arguments.")
| InductiveWithSort ->
alarm what internal
(str "Unable to decide equality of type arguments.")
| NonSingletonProp ind ->
alarm what internal
(str "Cannot extract computational content from proposition " ++
quote (Printer.pr_inductive (Global.env()) ind) ++ str ".")
| EqNotFound (ind',ind) ->
alarm what internal
(str "Boolean equality on " ++
quote (Printer.pr_inductive (Global.env()) ind') ++
strbrk " is missing.")
| UndefinedCst s ->
alarm what internal
(strbrk "Required constant " ++ str s ++ str " undefined.")
| AlreadyDeclared msg ->
alarm what internal (msg ++ str ".")
| DecidabilityMutualNotSupported ->
alarm what internal
(str "Decidability lemma for mutual inductive types not supported.")
| e when CErrors.noncritical e ->
alarm what internal
(str "Unexpected error during scheme creation: " ++ CErrors.print e)
| _ -> iraise e
in
match msg with
| None -> ()
| Some msg -> iraise (UserError (None, msg), snd e)
let beq_scheme_msg mind =
let mib = Global.lookup_mind mind in
(* TODO: mutual inductive case *)
str "Boolean equality on " ++
pr_enum (fun ind -> quote (Printer.pr_inductive (Global.env()) ind))
(List.init (Array.length mib.mind_packets) (fun i -> (mind,i)))
let declare_beq_scheme_with l kn =
try_declare_scheme (beq_scheme_msg kn) declare_beq_scheme_gen UserIndividualRequest l kn
let try_declare_beq_scheme kn =
(* TODO: handle Fix, eventually handle
proof-irrelevance; improve decidability by depending on decidability
for the parameters rather than on the bl and lb properties *)
try_declare_scheme (beq_scheme_msg kn) declare_beq_scheme_gen UserAutomaticRequest [] kn
let declare_beq_scheme = declare_beq_scheme_with []
(* Case analysis schemes *)
let declare_one_case_analysis_scheme ind =
let (mib,mip) = Global.lookup_inductive ind in
let kind = inductive_sort_family mip in
let dep =
if kind == InProp then case_scheme_kind_from_prop
else if not (Inductiveops.has_dependent_elim mib) then
case_scheme_kind_from_type
else case_dep_scheme_kind_from_type in
let kelim = elim_sorts (mib,mip) in
(* in case the inductive has a type elimination, generates only one
induction scheme, the other ones share the same code with the
apropriate type *)
if Sorts.List.mem InType kelim then
ignore (define_individual_scheme dep UserAutomaticRequest None ind)
(* Induction/recursion schemes *)
let kinds_from_prop =
[InType,rect_scheme_kind_from_prop;
InProp,ind_scheme_kind_from_prop;
InSet,rec_scheme_kind_from_prop]
let kinds_from_type =
[InType,rect_dep_scheme_kind_from_type;
InProp,ind_dep_scheme_kind_from_type;
InSet,rec_dep_scheme_kind_from_type]
let nondep_kinds_from_type =
[InType,rect_scheme_kind_from_type;
InProp,ind_scheme_kind_from_type;
InSet,rec_scheme_kind_from_type]
let declare_one_induction_scheme ind =
let (mib,mip) = Global.lookup_inductive ind in
let kind = inductive_sort_family mip in
let from_prop = kind == InProp in
let depelim = Inductiveops.has_dependent_elim mib in
let kelim = elim_sorts (mib,mip) in
let elims =
List.map_filter (fun (sort,kind) ->
if Sorts.List.mem sort kelim then Some kind else None)
(if from_prop then kinds_from_prop
else if depelim then kinds_from_type
else nondep_kinds_from_type) in
List.iter (fun kind -> ignore (define_individual_scheme kind UserAutomaticRequest None ind))
elims
let declare_induction_schemes kn =
let mib = Global.lookup_mind kn in
if mib.mind_finite <> Decl_kinds.CoFinite then begin
for i = 0 to Array.length mib.mind_packets - 1 do
declare_one_induction_scheme (kn,i);
done;
end
(* Decidable equality *)
let declare_eq_decidability_gen internal names kn =
let mib = Global.lookup_mind kn in
if mib.mind_finite <> Decl_kinds.CoFinite then
ignore (define_mutual_scheme eq_dec_scheme_kind internal names kn)
let eq_dec_scheme_msg ind = (* TODO: mutual inductive case *)
str "Decidable equality on " ++ quote (Printer.pr_inductive (Global.env()) ind)
let declare_eq_decidability_scheme_with l kn =
try_declare_scheme (eq_dec_scheme_msg (kn,0))
declare_eq_decidability_gen UserIndividualRequest l kn
let try_declare_eq_decidability kn =
try_declare_scheme (eq_dec_scheme_msg (kn,0))
declare_eq_decidability_gen UserAutomaticRequest [] kn
let declare_eq_decidability = declare_eq_decidability_scheme_with []
let ignore_error f x =
try ignore (f x) with e when CErrors.noncritical e -> ()
let declare_rewriting_schemes ind =
if Hipattern.is_inductive_equality ind then begin
ignore (define_individual_scheme rew_r2l_scheme_kind UserAutomaticRequest None ind);
ignore (define_individual_scheme rew_r2l_dep_scheme_kind UserAutomaticRequest None ind);
ignore (define_individual_scheme rew_r2l_forward_dep_scheme_kind
UserAutomaticRequest None ind);
(* These ones expect the equality to be symmetric; the first one also *)
(* needs eq *)
ignore_error (define_individual_scheme rew_l2r_scheme_kind UserAutomaticRequest None) ind;
ignore_error
(define_individual_scheme rew_l2r_dep_scheme_kind UserAutomaticRequest None) ind;
ignore_error
(define_individual_scheme rew_l2r_forward_dep_scheme_kind UserAutomaticRequest None) ind
end
let warn_cannot_build_congruence =
CWarnings.create ~name:"cannot-build-congruence" ~category:"schemes"
(fun () ->
strbrk "Cannot build congruence scheme because eq is not found")
let declare_congr_scheme ind =
if Hipattern.is_equality_type (mkInd ind) then begin
if
try Coqlib.check_required_library Coqlib.logic_module_name; true
with e when CErrors.noncritical e -> false
then
ignore (define_individual_scheme congr_scheme_kind UserAutomaticRequest None ind)
else
warn_cannot_build_congruence ()
end
let declare_sym_scheme ind =
if Hipattern.is_inductive_equality ind then
(* Expect the equality to be symmetric *)
ignore_error (define_individual_scheme sym_scheme_kind UserAutomaticRequest None) ind
(* Scheme command *)
let smart_global_inductive y = smart_global_inductive y
let rec split_scheme l =
let env = Global.env() in
match l with
| [] -> [],[]
| (Some id,t)::q -> let l1,l2 = split_scheme q in
( match t with
| InductionScheme (x,y,z) -> ((id,x,smart_global_inductive y,z)::l1),l2
| CaseScheme (x,y,z) -> ((id,x,smart_global_inductive y,z)::l1),l2
| EqualityScheme x -> l1,((Some id,smart_global_inductive x)::l2)
)
(*
if no name has been provided, we build one from the types of the ind
requested
*)
| (None,t)::q ->
let l1,l2 = split_scheme q in
let names inds recs isdep y z =
let ind = smart_global_inductive y in
let sort_of_ind = inductive_sort_family (snd (lookup_mind_specif env ind)) in
let z' = interp_elimination_sort z in
let suffix = (
match sort_of_ind with
| InProp ->
if isdep then (match z' with
| InProp -> inds ^ "_dep"
| InSet -> recs ^ "_dep"
| InType -> recs ^ "t_dep")
else ( match z' with
| InProp -> inds
| InSet -> recs
| InType -> recs ^ "t" )
| _ ->
if isdep then (match z' with
| InProp -> inds
| InSet -> recs
| InType -> recs ^ "t" )
else (match z' with
| InProp -> inds ^ "_nodep"
| InSet -> recs ^ "_nodep"
| InType -> recs ^ "t_nodep")
) in
let newid = add_suffix (basename_of_global (IndRef ind)) suffix in
let newref = (Loc.ghost,newid) in
((newref,isdep,ind,z)::l1),l2
in
match t with
| CaseScheme (x,y,z) -> names "_case" "_case" x y z
| InductionScheme (x,y,z) -> names "_ind" "_rec" x y z
| EqualityScheme x -> l1,((None,smart_global_inductive x)::l2)
let do_mutual_induction_scheme lnamedepindsort =
let lrecnames = List.map (fun ((_,f),_,_,_) -> f) lnamedepindsort
and env0 = Global.env() in
let sigma, lrecspec, _ =
List.fold_right
(fun (_,dep,ind,sort) (evd, l, inst) ->
let evd, indu, inst =
match inst with
| None ->
let _, ctx = Global.type_of_global_in_context env0 (IndRef ind) in
let ctxs = Univ.ContextSet.of_context ctx in
let evd = Evd.from_ctx (Evd.evar_universe_context_of ctxs) in
let u = Univ.UContext.instance ctx in
evd, (ind,u), Some u
| Some ui -> evd, (ind, ui), inst
in
(evd, (indu,dep,interp_elimination_sort sort) :: l, inst))
lnamedepindsort (Evd.from_env env0,[],None)
in
let sigma, listdecl = Indrec.build_mutual_induction_scheme env0 sigma lrecspec in
let declare decl fi lrecref =
let decltype = Retyping.get_type_of env0 sigma decl in
let proof_output = Future.from_val ((decl,Univ.ContextSet.empty),Safe_typing.empty_private_constants) in
let cst = define fi UserIndividualRequest sigma proof_output (Some decltype) in
ConstRef cst :: lrecref
in
let _ = List.fold_right2 declare listdecl lrecnames [] in
fixpoint_message None lrecnames
let get_common_underlying_mutual_inductive = function
| [] -> assert false
| (id,(mind,i as ind))::l as all ->
match List.filter (fun (_,(mind',_)) -> not (eq_mind mind mind')) l with
| (_,ind')::_ ->
raise (RecursionSchemeError (NotMutualInScheme (ind,ind')))
| [] ->
if not (List.distinct_f Int.compare (List.map snd (List.map snd all)))
then error "A type occurs twice";
mind,
List.map_filter
(function (Some id,(_,i)) -> Some (i,snd id) | (None,_) -> None) all
let do_scheme l =
let ischeme,escheme = split_scheme l in
(* we want 1 kind of scheme at a time so we check if the user
tried to declare different schemes at once *)
if not (List.is_empty ischeme) && not (List.is_empty escheme)
then
error "Do not declare equality and induction scheme at the same time."
else (
if not (List.is_empty ischeme) then do_mutual_induction_scheme ischeme
else
let mind,l = get_common_underlying_mutual_inductive escheme in
declare_beq_scheme_with l mind;
declare_eq_decidability_scheme_with l mind
)
(**********************************************************************)
(* Combined scheme *)
(* Matthieu Sozeau, Dec 2006 *)
let list_split_rev_at index l =
let rec aux i acc = function
hd :: tl when Int.equal i index -> acc, tl
| hd :: tl -> aux (succ i) (hd :: acc) tl
| [] -> failwith "List.split_when: Invalid argument"
in aux 0 [] l
let fold_left' f = function
[] -> invalid_arg "fold_left'"
| hd :: tl -> List.fold_left f hd tl
let build_combined_scheme env schemes =
let defs = List.map (fun cst -> (* FIXME *)
let evd, c = Evd.fresh_constant_instance env (Evd.from_env env) cst in
(c, Typeops.type_of_constant_in env c)) schemes in
(* let nschemes = List.length schemes in *)
let find_inductive ty =
let (ctx, arity) = decompose_prod ty in
let (_, last) = List.hd ctx in
match kind_of_term last with
| App (ind, args) ->
let ind = destInd ind in
let (_,spec) = Inductive.lookup_mind_specif env (fst ind) in
ctx, ind, spec.mind_nrealargs
| _ -> ctx, destInd last, 0
in
let (c, t) = List.hd defs in
let ctx, ind, nargs = find_inductive t in
(* Number of clauses, including the predicates quantification *)
let prods = nb_prod t - (nargs + 1) in
let coqand = Coqlib.build_coq_and () and coqconj = Coqlib.build_coq_conj () in
let relargs = rel_vect 0 prods in
let concls = List.rev_map
(fun (cst, t) -> (* FIXME *)
mkApp(mkConstU cst, relargs),
snd (decompose_prod_n prods t)) defs in
let concl_bod, concl_typ =
fold_left'
(fun (accb, acct) (cst, x) ->
mkApp (coqconj, [| x; acct; cst; accb |]),
mkApp (coqand, [| x; acct |])) concls
in
let ctx, _ =
list_split_rev_at prods
(List.rev_map (fun (x, y) -> LocalAssum (x, y)) ctx) in
let typ = it_mkProd_wo_LetIn concl_typ ctx in
let body = it_mkLambda_or_LetIn concl_bod ctx in
(body, typ)
let do_combined_scheme name schemes =
let csts =
List.map (fun x ->
let refe = Ident x in
let qualid = qualid_of_reference refe in
try Nametab.locate_constant (snd qualid)
with Not_found -> error ((string_of_qualid (snd qualid))^" is not declared."))
schemes
in
let body,typ = build_combined_scheme (Global.env ()) csts in
let proof_output = Future.from_val ((body,Univ.ContextSet.empty),Safe_typing.empty_private_constants) in
ignore (define (snd name) UserIndividualRequest Evd.empty proof_output (Some typ));
fixpoint_message None [snd name]
(**********************************************************************)
let map_inductive_block f kn n = for i=0 to n-1 do f (kn,i) done
let declare_default_schemes kn =
let mib = Global.lookup_mind kn in
let n = Array.length mib.mind_packets in
if !elim_flag && (mib.mind_finite <> BiFinite || !bifinite_elim_flag)
&& mib.mind_typing_flags.check_guarded then
declare_induction_schemes kn;
if !case_flag then map_inductive_block declare_one_case_analysis_scheme kn n;
if is_eq_flag() then try_declare_beq_scheme kn;
if !eq_dec_flag then try_declare_eq_decidability kn;
if !rewriting_flag then map_inductive_block declare_congr_scheme kn n;
if !rewriting_flag then map_inductive_block declare_sym_scheme kn n;
if !rewriting_flag then map_inductive_block declare_rewriting_schemes kn n
|