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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2015 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open Errors
open Util
open Pp
open Names
open Term
open Libnames
open Globnames
open Nametab
open Smartlocate
let coq = Nameops.coq_string (* "Coq" *)
(************************************************************************)
(* Generic functions to find Coq objects *)
type message = string
let make_dir l = DirPath.make (List.rev_map Id.of_string l)
let find_reference locstr dir s =
let sp = Libnames.make_path (make_dir dir) (Id.of_string s) in
try global_of_extended_global (Nametab.extended_global_of_path sp)
with Not_found ->
anomaly ~label:locstr (str "cannot find " ++ Libnames.pr_path sp)
let coq_reference locstr dir s = find_reference locstr (coq::dir) s
let coq_constant locstr dir s = Universes.constr_of_global (coq_reference locstr dir s)
let gen_reference = coq_reference
let gen_constant = coq_constant
let has_suffix_in_dirs dirs ref =
let dir = dirpath (path_of_global ref) in
List.exists (fun d -> is_dirpath_prefix_of d dir) dirs
let global_of_extended q =
try Some (global_of_extended_global q) with Not_found -> None
let gen_reference_in_modules locstr dirs s =
let dirs = List.map make_dir dirs in
let qualid = qualid_of_string s in
let all = Nametab.locate_extended_all qualid in
let all = List.map_filter global_of_extended all in
let all = List.sort_uniquize RefOrdered_env.compare all in
let these = List.filter (has_suffix_in_dirs dirs) all in
match these with
| [x] -> x
| [] ->
anomaly ~label:locstr (str "cannot find " ++ str s ++
str " in module" ++ str (if List.length dirs > 1 then "s " else " ") ++
prlist_with_sep pr_comma pr_dirpath dirs)
| l ->
anomaly ~label:locstr
(str "ambiguous name " ++ str s ++ str " can represent " ++
prlist_with_sep pr_comma
(fun x -> Libnames.pr_path (Nametab.path_of_global x)) l ++
str " in module" ++ str (if List.length dirs > 1 then "s " else " ") ++
prlist_with_sep pr_comma pr_dirpath dirs)
let gen_constant_in_modules locstr dirs s =
Universes.constr_of_global (gen_reference_in_modules locstr dirs s)
(* For tactics/commands requiring vernacular libraries *)
let check_required_library d =
let dir = make_dir d in
if Library.library_is_loaded dir then ()
else
let in_current_dir = match Lib.current_mp () with
| MPfile dp -> DirPath.equal dir dp
| _ -> false
in
if not in_current_dir then
(* Loading silently ...
let m, prefix = List.sep_last d' in
read_library
(Loc.ghost,make_qualid (DirPath.make (List.rev prefix)) m)
*)
(* or failing ...*)
errorlabstrm "Coqlib.check_required_library"
(str "Library " ++ str (DirPath.to_string dir) ++ str " has to be required first.")
(************************************************************************)
(* Specific Coq objects *)
let init_reference dir s =
let d = "Init"::dir in
check_required_library (coq::d); gen_reference "Coqlib" d s
let init_constant dir s =
let d = "Init"::dir in
check_required_library (coq::d); gen_constant "Coqlib" d s
let logic_reference dir s =
let d = "Logic"::dir in
check_required_library ("Coq"::d); gen_reference "Coqlib" d s
let arith_dir = [coq;"Arith"]
let arith_modules = [arith_dir]
let numbers_dir = [coq;"Numbers"]
let parith_dir = [coq;"PArith"]
let narith_dir = [coq;"NArith"]
let zarith_dir = [coq;"ZArith"]
let zarith_base_modules = [numbers_dir;parith_dir;narith_dir;zarith_dir]
let init_dir = [coq;"Init"]
let init_modules = [
init_dir@["Datatypes"];
init_dir@["Logic"];
init_dir@["Specif"];
init_dir@["Logic_Type"];
init_dir@["Nat"];
init_dir@["Peano"];
init_dir@["Wf"]
]
let prelude_module_name = init_dir@["Prelude"]
let prelude_module = make_dir prelude_module_name
let logic_module_name = init_dir@["Logic"]
let logic_module = make_dir logic_module_name
let logic_type_module_name = init_dir@["Logic_Type"]
let logic_type_module = make_dir logic_type_module_name
let datatypes_module_name = init_dir@["Datatypes"]
let datatypes_module = make_dir datatypes_module_name
let jmeq_module_name = [coq;"Logic";"JMeq"]
let jmeq_module = make_dir jmeq_module_name
(* TODO: temporary hack. Works only if the module isn't an alias *)
let make_ind dir id = Globnames.encode_mind dir (Id.of_string id)
let make_con dir id = Globnames.encode_con dir (Id.of_string id)
(** Identity *)
let id = make_con datatypes_module "idProp"
let type_of_id = make_con datatypes_module "IDProp"
let _ = Termops.set_impossible_default_clause
(fun () ->
let c, ctx = Universes.fresh_global_instance (Global.env()) (ConstRef id) in
let (_, u) = destConst c in
(c,mkConstU (type_of_id,u)), ctx)
(** Natural numbers *)
let nat_kn = make_ind datatypes_module "nat"
let nat_path = Libnames.make_path datatypes_module (Id.of_string "nat")
let glob_nat = IndRef (nat_kn,0)
let path_of_O = ((nat_kn,0),1)
let path_of_S = ((nat_kn,0),2)
let glob_O = ConstructRef path_of_O
let glob_S = ConstructRef path_of_S
(** Booleans *)
let bool_kn = make_ind datatypes_module "bool"
let glob_bool = IndRef (bool_kn,0)
let path_of_true = ((bool_kn,0),1)
let path_of_false = ((bool_kn,0),2)
let glob_true = ConstructRef path_of_true
let glob_false = ConstructRef path_of_false
(** Equality *)
let eq_kn = make_ind logic_module "eq"
let glob_eq = IndRef (eq_kn,0)
let identity_kn = make_ind datatypes_module "identity"
let glob_identity = IndRef (identity_kn,0)
let jmeq_kn = make_ind jmeq_module "JMeq"
let glob_jmeq = IndRef (jmeq_kn,0)
type coq_sigma_data = {
proj1 : global_reference;
proj2 : global_reference;
elim : global_reference;
intro : global_reference;
typ : global_reference }
type coq_bool_data = {
andb : constr;
andb_prop : constr;
andb_true_intro : constr}
let build_bool_type () =
{ andb = init_constant ["Datatypes"] "andb";
andb_prop = init_constant ["Datatypes"] "andb_prop";
andb_true_intro = init_constant ["Datatypes"] "andb_true_intro" }
let build_sigma_set () = anomaly (Pp.str "Use build_sigma_type")
let build_sigma_type () =
{ proj1 = init_reference ["Specif"] "projT1";
proj2 = init_reference ["Specif"] "projT2";
elim = init_reference ["Specif"] "sigT_rect";
intro = init_reference ["Specif"] "existT";
typ = init_reference ["Specif"] "sigT" }
let build_sigma () =
{ proj1 = init_reference ["Specif"] "proj1_sig";
proj2 = init_reference ["Specif"] "proj2_sig";
elim = init_reference ["Specif"] "sig_rect";
intro = init_reference ["Specif"] "exist";
typ = init_reference ["Specif"] "sig" }
let build_prod () =
{ proj1 = init_reference ["Datatypes"] "fst";
proj2 = init_reference ["Datatypes"] "snd";
elim = init_reference ["Datatypes"] "prod_rec";
intro = init_reference ["Datatypes"] "pair";
typ = init_reference ["Datatypes"] "prod" }
(* Equalities *)
type coq_eq_data = {
eq : global_reference;
ind : global_reference;
refl : global_reference;
sym : global_reference;
trans: global_reference;
congr: global_reference }
(* Data needed for discriminate and injection *)
type coq_inversion_data = {
inv_eq : global_reference; (* : forall params, t -> Prop *)
inv_ind : global_reference; (* : forall params P y, eq params y -> P y *)
inv_congr: global_reference (* : forall params B (f:t->B) y, eq params y -> f c=f y *)
}
let lazy_init_reference dir id = lazy (init_reference dir id)
let lazy_init_constant dir id = lazy (init_constant dir id)
let lazy_logic_reference dir id = lazy (logic_reference dir id)
(* Leibniz equality on Type *)
let coq_eq_eq = lazy_init_reference ["Logic"] "eq"
let coq_eq_refl = lazy_init_reference ["Logic"] "eq_refl"
let coq_eq_ind = lazy_init_reference ["Logic"] "eq_ind"
let coq_eq_congr = lazy_init_reference ["Logic"] "f_equal"
let coq_eq_sym = lazy_init_reference ["Logic"] "eq_sym"
let coq_eq_trans = lazy_init_reference ["Logic"] "eq_trans"
let coq_f_equal2 = lazy_init_reference ["Logic"] "f_equal2"
let coq_eq_congr_canonical =
lazy_init_reference ["Logic"] "f_equal_canonical_form"
let build_coq_eq_data () =
let _ = check_required_library logic_module_name in {
eq = Lazy.force coq_eq_eq;
ind = Lazy.force coq_eq_ind;
refl = Lazy.force coq_eq_refl;
sym = Lazy.force coq_eq_sym;
trans = Lazy.force coq_eq_trans;
congr = Lazy.force coq_eq_congr }
let build_coq_eq () = Lazy.force coq_eq_eq
let build_coq_eq_refl () = Lazy.force coq_eq_refl
let build_coq_eq_sym () = Lazy.force coq_eq_sym
let build_coq_f_equal2 () = Lazy.force coq_f_equal2
let build_coq_inversion_eq_data () =
let _ = check_required_library logic_module_name in {
inv_eq = Lazy.force coq_eq_eq;
inv_ind = Lazy.force coq_eq_ind;
inv_congr = Lazy.force coq_eq_congr_canonical }
(* Heterogenous equality on Type *)
let coq_jmeq_eq = lazy_logic_reference ["JMeq"] "JMeq"
let coq_jmeq_hom = lazy_logic_reference ["JMeq"] "JMeq_hom"
let coq_jmeq_refl = lazy_logic_reference ["JMeq"] "JMeq_refl"
let coq_jmeq_ind = lazy_logic_reference ["JMeq"] "JMeq_ind"
let coq_jmeq_sym = lazy_logic_reference ["JMeq"] "JMeq_sym"
let coq_jmeq_congr = lazy_logic_reference ["JMeq"] "JMeq_congr"
let coq_jmeq_trans = lazy_logic_reference ["JMeq"] "JMeq_trans"
let coq_jmeq_congr_canonical =
lazy_logic_reference ["JMeq"] "JMeq_congr_canonical_form"
let build_coq_jmeq_data () =
let _ = check_required_library jmeq_module_name in {
eq = Lazy.force coq_jmeq_eq;
ind = Lazy.force coq_jmeq_ind;
refl = Lazy.force coq_jmeq_refl;
sym = Lazy.force coq_jmeq_sym;
trans = Lazy.force coq_jmeq_trans;
congr = Lazy.force coq_jmeq_congr }
let build_coq_inversion_jmeq_data () =
let _ = check_required_library logic_module_name in {
inv_eq = Lazy.force coq_jmeq_hom;
inv_ind = Lazy.force coq_jmeq_ind;
inv_congr = Lazy.force coq_jmeq_congr_canonical }
(* Specif *)
let coq_sumbool = lazy_init_constant ["Specif"] "sumbool"
let build_coq_sumbool () = Lazy.force coq_sumbool
(* Equality on Type as a Type *)
let coq_identity_eq = lazy_init_reference ["Datatypes"] "identity"
let coq_identity_refl = lazy_init_reference ["Datatypes"] "identity_refl"
let coq_identity_ind = lazy_init_reference ["Datatypes"] "identity_ind"
let coq_identity_congr = lazy_init_reference ["Logic_Type"] "identity_congr"
let coq_identity_sym = lazy_init_reference ["Logic_Type"] "identity_sym"
let coq_identity_trans = lazy_init_reference ["Logic_Type"] "identity_trans"
let coq_identity_congr_canonical = lazy_init_reference ["Logic_Type"] "identity_congr_canonical_form"
let build_coq_identity_data () =
let _ = check_required_library datatypes_module_name in {
eq = Lazy.force coq_identity_eq;
ind = Lazy.force coq_identity_ind;
refl = Lazy.force coq_identity_refl;
sym = Lazy.force coq_identity_sym;
trans = Lazy.force coq_identity_trans;
congr = Lazy.force coq_identity_congr }
let build_coq_inversion_identity_data () =
let _ = check_required_library datatypes_module_name in
let _ = check_required_library logic_type_module_name in {
inv_eq = Lazy.force coq_identity_eq;
inv_ind = Lazy.force coq_identity_ind;
inv_congr = Lazy.force coq_identity_congr_canonical }
(* Equality to true *)
let coq_eq_true_eq = lazy_init_reference ["Datatypes"] "eq_true"
let coq_eq_true_ind = lazy_init_reference ["Datatypes"] "eq_true_ind"
let coq_eq_true_congr = lazy_init_reference ["Logic"] "eq_true_congr"
let build_coq_inversion_eq_true_data () =
let _ = check_required_library datatypes_module_name in
let _ = check_required_library logic_module_name in {
inv_eq = Lazy.force coq_eq_true_eq;
inv_ind = Lazy.force coq_eq_true_ind;
inv_congr = Lazy.force coq_eq_true_congr }
(* The False proposition *)
let coq_False = lazy_init_constant ["Logic"] "False"
(* The True proposition and its unique proof *)
let coq_True = lazy_init_constant ["Logic"] "True"
let coq_I = lazy_init_constant ["Logic"] "I"
(* Connectives *)
let coq_not = lazy_init_constant ["Logic"] "not"
let coq_and = lazy_init_constant ["Logic"] "and"
let coq_conj = lazy_init_constant ["Logic"] "conj"
let coq_or = lazy_init_constant ["Logic"] "or"
let coq_ex = lazy_init_constant ["Logic"] "ex"
let coq_iff = lazy_init_constant ["Logic"] "iff"
let coq_iff_left_proj = lazy_init_constant ["Logic"] "proj1"
let coq_iff_right_proj = lazy_init_constant ["Logic"] "proj2"
(* Runtime part *)
let build_coq_True () = Lazy.force coq_True
let build_coq_I () = Lazy.force coq_I
let build_coq_False () = Lazy.force coq_False
let build_coq_not () = Lazy.force coq_not
let build_coq_and () = Lazy.force coq_and
let build_coq_conj () = Lazy.force coq_conj
let build_coq_or () = Lazy.force coq_or
let build_coq_ex () = Lazy.force coq_ex
let build_coq_iff () = Lazy.force coq_iff
let build_coq_iff_left_proj () = Lazy.force coq_iff_left_proj
let build_coq_iff_right_proj () = Lazy.force coq_iff_right_proj
(* The following is less readable but does not depend on parsing *)
let coq_eq_ref = lazy (init_reference ["Logic"] "eq")
let coq_identity_ref = lazy (init_reference ["Datatypes"] "identity")
let coq_jmeq_ref = lazy (gen_reference "Coqlib" ["Logic";"JMeq"] "JMeq")
let coq_eq_true_ref = lazy (gen_reference "Coqlib" ["Init";"Datatypes"] "eq_true")
let coq_existS_ref = lazy (anomaly (Pp.str "use coq_existT_ref"))
let coq_existT_ref = lazy (init_reference ["Specif"] "existT")
let coq_exist_ref = lazy (init_reference ["Specif"] "exist")
let coq_not_ref = lazy (init_reference ["Logic"] "not")
let coq_False_ref = lazy (init_reference ["Logic"] "False")
let coq_sumbool_ref = lazy (init_reference ["Specif"] "sumbool")
let coq_sig_ref = lazy (init_reference ["Specif"] "sig")
let coq_or_ref = lazy (init_reference ["Logic"] "or")
let coq_iff_ref = lazy (init_reference ["Logic"] "iff")
|