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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 Names
open Term
open Declarations
open Nameops
open Namegen
open Libobject
open Goptions
open Libnames
open Globnames
open CErrors
open Util
open Pp
open Miniml
(** Sets and maps for [global_reference] that use the "user" [kernel_name]
instead of the canonical one *)
module Refmap' = Refmap_env
module Refset' = Refset_env
(*S Utilities about [module_path] and [kernel_names] and [global_reference] *)
let occur_kn_in_ref kn = function
| IndRef (kn',_)
| ConstructRef ((kn',_),_) -> Names.eq_mind kn kn'
| ConstRef _ -> false
| VarRef _ -> assert false
let repr_of_r = function
| ConstRef kn -> repr_con kn
| IndRef (kn,_)
| ConstructRef ((kn,_),_) -> repr_mind kn
| VarRef _ -> assert false
let modpath_of_r r =
let mp,_,_ = repr_of_r r in mp
let label_of_r r =
let _,_,l = repr_of_r r in l
let rec base_mp = function
| MPdot (mp,l) -> base_mp mp
| mp -> mp
let is_modfile = function
| MPfile _ -> true
| _ -> false
let raw_string_of_modfile = function
| MPfile f -> String.capitalize (Id.to_string (List.hd (DirPath.repr f)))
| _ -> assert false
let is_toplevel mp =
ModPath.equal mp initial_path || ModPath.equal mp (Lib.current_mp ())
let at_toplevel mp =
is_modfile mp || is_toplevel mp
let mp_length mp =
let mp0 = Lib.current_mp () in
let rec len = function
| mp when ModPath.equal mp mp0 -> 1
| MPdot (mp,_) -> 1 + len mp
| _ -> 1
in len mp
let rec prefixes_mp mp = match mp with
| MPdot (mp',_) -> MPset.add mp (prefixes_mp mp')
| _ -> MPset.singleton mp
let rec get_nth_label_mp n = function
| MPdot (mp,l) -> if Int.equal n 1 then l else get_nth_label_mp (n-1) mp
| _ -> failwith "get_nth_label: not enough MPdot"
let common_prefix_from_list mp0 mpl =
let prefixes = prefixes_mp mp0 in
let rec f = function
| [] -> None
| mp :: l -> if MPset.mem mp prefixes then Some mp else f l
in f mpl
let rec parse_labels2 ll mp1 = function
| mp when ModPath.equal mp1 mp -> mp,ll
| MPdot (mp,l) -> parse_labels2 (l::ll) mp1 mp
| mp -> mp,ll
let labels_of_ref r =
let mp_top = Lib.current_mp () in
let mp,_,l = repr_of_r r in
parse_labels2 [l] mp_top mp
(*S The main tables: constants, inductives, records, ... *)
(* Theses tables are not registered within coq save/undo mechanism
since we reset their contents at each run of Extraction *)
(* We use [constant_body] (resp. [mutual_inductive_body]) as checksum
to ensure that the table contents aren't outdated. *)
(*s Constants tables. *)
let typedefs = ref (Cmap_env.empty : (constant_body * ml_type) Cmap_env.t)
let init_typedefs () = typedefs := Cmap_env.empty
let add_typedef kn cb t =
typedefs := Cmap_env.add kn (cb,t) !typedefs
let lookup_typedef kn cb =
try
let (cb0,t) = Cmap_env.find kn !typedefs in
if cb0 == cb then Some t else None
with Not_found -> None
let cst_types =
ref (Cmap_env.empty : (constant_body * ml_schema) Cmap_env.t)
let init_cst_types () = cst_types := Cmap_env.empty
let add_cst_type kn cb s = cst_types := Cmap_env.add kn (cb,s) !cst_types
let lookup_cst_type kn cb =
try
let (cb0,s) = Cmap_env.find kn !cst_types in
if cb0 == cb then Some s else None
with Not_found -> None
(*s Inductives table. *)
let inductives =
ref (Mindmap_env.empty : (mutual_inductive_body * ml_ind) Mindmap_env.t)
let init_inductives () = inductives := Mindmap_env.empty
let add_ind kn mib ml_ind =
inductives := Mindmap_env.add kn (mib,ml_ind) !inductives
let lookup_ind kn mib =
try
let (mib0,ml_ind) = Mindmap_env.find kn !inductives in
if mib == mib0 then Some ml_ind
else None
with Not_found -> None
let unsafe_lookup_ind kn = snd (Mindmap_env.find kn !inductives)
let inductive_kinds =
ref (Mindmap_env.empty : inductive_kind Mindmap_env.t)
let init_inductive_kinds () = inductive_kinds := Mindmap_env.empty
let add_inductive_kind kn k =
inductive_kinds := Mindmap_env.add kn k !inductive_kinds
let is_coinductive r =
let kn = match r with
| ConstructRef ((kn,_),_) -> kn
| IndRef (kn,_) -> kn
| _ -> assert false
in
try Mindmap_env.find kn !inductive_kinds == Coinductive
with Not_found -> false
let is_coinductive_type = function
| Tglob (r,_) -> is_coinductive r
| _ -> false
let get_record_fields r =
let kn = match r with
| ConstructRef ((kn,_),_) -> kn
| IndRef (kn,_) -> kn
| _ -> assert false
in
try match Mindmap_env.find kn !inductive_kinds with
| Record f -> f
| _ -> []
with Not_found -> []
let record_fields_of_type = function
| Tglob (r,_) -> get_record_fields r
| _ -> []
(*s Recursors table. *)
(* NB: here we can use the equivalence between canonical
and user constant names. *)
let recursors = ref KNset.empty
let init_recursors () = recursors := KNset.empty
let add_recursors env ind =
let kn = MutInd.canonical ind in
let mk_kn id =
KerName.make (KerName.modpath kn) DirPath.empty (Label.of_id id)
in
let mib = Environ.lookup_mind ind env in
Array.iter
(fun mip ->
let id = mip.mind_typename in
let kn_rec = mk_kn (Nameops.add_suffix id "_rec")
and kn_rect = mk_kn (Nameops.add_suffix id "_rect") in
recursors := KNset.add kn_rec (KNset.add kn_rect !recursors))
mib.mind_packets
let is_recursor = function
| ConstRef c -> KNset.mem (Constant.canonical c) !recursors
| _ -> false
(*s Record tables. *)
(* NB: here, working modulo name equivalence is ok *)
let projs = ref (Refmap.empty : (inductive*int) Refmap.t)
let init_projs () = projs := Refmap.empty
let add_projection n kn ip = projs := Refmap.add (ConstRef kn) (ip,n) !projs
let is_projection r = Refmap.mem r !projs
let projection_arity r = snd (Refmap.find r !projs)
let projection_info r = Refmap.find r !projs
(*s Table of used axioms *)
let info_axioms = ref Refset'.empty
let log_axioms = ref Refset'.empty
let init_axioms () = info_axioms := Refset'.empty; log_axioms := Refset'.empty
let add_info_axiom r = info_axioms := Refset'.add r !info_axioms
let remove_info_axiom r = info_axioms := Refset'.remove r !info_axioms
let add_log_axiom r = log_axioms := Refset'.add r !log_axioms
let opaques = ref Refset'.empty
let init_opaques () = opaques := Refset'.empty
let add_opaque r = opaques := Refset'.add r !opaques
let remove_opaque r = opaques := Refset'.remove r !opaques
(*s Extraction modes: modular or monolithic, library or minimal ?
Nota:
- Recursive Extraction : monolithic, minimal
- Separate Extraction : modular, minimal
- Extraction Library : modular, library
*)
let modular_ref = ref false
let library_ref = ref false
let set_modular b = modular_ref := b
let modular () = !modular_ref
let set_library b = library_ref := b
let library () = !library_ref
(*s Printing. *)
(* The following functions work even on objects not in [Global.env ()].
Warning: for inductive objects, this only works if an [extract_inductive]
have been done earlier, otherwise we can only ask the Nametab about
currently visible objects. *)
let safe_basename_of_global r =
let last_chance r =
try Nametab.basename_of_global r
with Not_found ->
anomaly (Pp.str "Inductive object unknown to extraction and not globally visible")
in
match r with
| ConstRef kn -> Label.to_id (con_label kn)
| IndRef (kn,0) -> Label.to_id (mind_label kn)
| IndRef (kn,i) ->
(try (unsafe_lookup_ind kn).ind_packets.(i).ip_typename
with Not_found -> last_chance r)
| ConstructRef ((kn,i),j) ->
(try (unsafe_lookup_ind kn).ind_packets.(i).ip_consnames.(j-1)
with Not_found -> last_chance r)
| VarRef _ -> assert false
let string_of_global r =
try string_of_qualid (Nametab.shortest_qualid_of_global Id.Set.empty r)
with Not_found -> Id.to_string (safe_basename_of_global r)
let safe_pr_global r = str (string_of_global r)
(* idem, but with qualification, and only for constants. *)
let safe_pr_long_global r =
try Printer.pr_global r
with Not_found -> match r with
| ConstRef kn ->
let mp,_,l = repr_con kn in
str ((string_of_mp mp)^"."^(Label.to_string l))
| _ -> assert false
let pr_long_mp mp =
let lid = DirPath.repr (Nametab.dirpath_of_module mp) in
str (String.concat "." (List.rev_map Id.to_string lid))
let pr_long_global ref = pr_path (Nametab.path_of_global ref)
(*S Warning and Error messages. *)
let err s = errorlabstrm "Extraction" s
let warn_extraction_axiom_to_realize =
CWarnings.create ~name:"extraction-axiom-to-realize" ~category:"extraction"
(fun axioms ->
let s = if Int.equal (List.length axioms) 1 then "axiom" else "axioms" in
strbrk ("The following "^s^" must be realized in the extracted code:")
++ hov 1 (spc () ++ prlist_with_sep spc safe_pr_global axioms)
++ str "." ++ fnl ())
let warn_extraction_logical_axiom =
CWarnings.create ~name:"extraction-logical-axiom" ~category:"extraction"
(fun axioms ->
let s =
if Int.equal (List.length axioms) 1 then "axiom was" else "axioms were"
in
(strbrk ("The following logical "^s^" encountered:") ++
hov 1 (spc () ++ prlist_with_sep spc safe_pr_global axioms ++ str ".\n")
++ strbrk "Having invalid logical axiom in the environment when extracting"
++ spc () ++ strbrk "may lead to incorrect or non-terminating ML terms." ++
fnl ()))
let warning_axioms () =
let info_axioms = Refset'.elements !info_axioms in
if not (List.is_empty info_axioms) then
warn_extraction_axiom_to_realize info_axioms;
let log_axioms = Refset'.elements !log_axioms in
if not (List.is_empty log_axioms) then
warn_extraction_logical_axiom log_axioms
let warn_extraction_opaque_accessed =
CWarnings.create ~name:"extraction-opaque-accessed" ~category:"extraction"
(fun lst -> strbrk "The extraction is currently set to bypass opacity, " ++
strbrk "the following opaque constant bodies have been accessed :" ++
lst ++ str "." ++ fnl ())
let warn_extraction_opaque_as_axiom =
CWarnings.create ~name:"extraction-opaque-as-axiom" ~category:"extraction"
(fun lst -> strbrk "The extraction now honors the opacity constraints by default, " ++
strbrk "the following opaque constants have been extracted as axioms :" ++
lst ++ str "." ++ fnl () ++
strbrk "If necessary, use \"Set Extraction AccessOpaque\" to change this."
++ fnl ())
let warning_opaques accessed =
let opaques = Refset'.elements !opaques in
if not (List.is_empty opaques) then
let lst = hov 1 (spc () ++ prlist_with_sep spc safe_pr_global opaques) in
if accessed then warn_extraction_opaque_accessed lst
else warn_extraction_opaque_as_axiom lst
let warning_ambiguous_name =
CWarnings.create ~name:"extraction-ambiguous-name" ~category:"extraction"
(fun (q,mp,r) -> strbrk "The name " ++ pr_qualid q ++ strbrk " is ambiguous, " ++
strbrk "do you mean module " ++
pr_long_mp mp ++
strbrk " or object " ++
pr_long_global r ++ str " ?" ++ fnl () ++
strbrk "First choice is assumed, for the second one please use " ++
strbrk "fully qualified name." ++ fnl ())
let error_axiom_scheme r i =
err (str "The type scheme axiom " ++ spc () ++
safe_pr_global r ++ spc () ++ str "needs " ++ int i ++
str " type variable(s).")
let warn_extraction_inside_module =
CWarnings.create ~name:"extraction-inside-module" ~category:"extraction"
(fun () -> strbrk "Extraction inside an opened module is experimental." ++
strbrk "In case of problem, close it first.")
let check_inside_module () =
if Lib.is_modtype () then
err (str "You can't do that within a Module Type." ++ fnl () ++
str "Close it and try again.")
else if Lib.is_module () then
warn_extraction_inside_module ()
let check_inside_section () =
if Lib.sections_are_opened () then
err (str "You can't do that within a section." ++ fnl () ++
str "Close it and try again.")
let warn_extraction_reserved_identifier =
CWarnings.create ~name:"extraction-reserved-identifier" ~category:"extraction"
(fun s -> strbrk ("The identifier "^s^
" contains __ which is reserved for the extraction"))
let warning_id s = warn_extraction_reserved_identifier s
let error_constant r =
err (safe_pr_global r ++ str " is not a constant.")
let error_inductive r =
err (safe_pr_global r ++ spc () ++ str "is not an inductive type.")
let error_nb_cons () =
err (str "Not the right number of constructors.")
let error_module_clash mp1 mp2 =
err (str "The Coq modules " ++ pr_long_mp mp1 ++ str " and " ++
pr_long_mp mp2 ++ str " have the same ML name.\n" ++
str "This is not supported yet. Please do some renaming first.")
let error_no_module_expr mp =
err (str "The module " ++ pr_long_mp mp
++ str " has no body, it probably comes from\n"
++ str "some Declare Module outside any Module Type.\n"
++ str "This situation is currently unsupported by the extraction.")
let error_singleton_become_prop id og =
let loc =
match og with
| Some g -> fnl () ++ str "in " ++ safe_pr_global g ++
str " (or in its mutual block)"
| None -> mt ()
in
err (str "The informative inductive type " ++ pr_id id ++
str " has a Prop instance" ++ loc ++ str "." ++ fnl () ++
str "This happens when a sort-polymorphic singleton inductive type\n" ++
str "has logical parameters, such as (I,I) : (True * True) : Prop.\n" ++
str "The Ocaml extraction cannot handle this situation yet.\n" ++
str "Instead, use a sort-monomorphic type such as (True /\\ True)\n" ++
str "or extract to Haskell.")
let error_unknown_module m =
err (str "Module" ++ spc () ++ pr_qualid m ++ spc () ++ str "not found.")
let error_scheme () =
err (str "No Scheme modular extraction available yet.")
let error_not_visible r =
err (safe_pr_global r ++ str " is not directly visible.\n" ++
str "For example, it may be inside an applied functor.\n" ++
str "Use Recursive Extraction to get the whole environment.")
let error_MPfile_as_mod mp b =
let s1 = if b then "asked" else "required" in
let s2 = if b then "extract some objects of this module or\n" else "" in
err (str ("Extraction of file "^(raw_string_of_modfile mp)^
".v as a module is "^s1^".\n"^
"Monolithic Extraction cannot deal with this situation.\n"^
"Please "^s2^"use (Recursive) Extraction Library instead.\n"))
let argnames_of_global r =
let typ = Global.type_of_global_unsafe r in
let rels,_ =
decompose_prod (Reduction.whd_all (Global.env ()) typ) in
List.rev_map fst rels
let msg_of_implicit = function
| Kimplicit (r,i) ->
let name = match List.nth (argnames_of_global r) (i-1) with
| Anonymous -> ""
| Name id -> "(" ^ Id.to_string id ^ ") "
in
(String.ordinal i)^" argument "^name^"of "^(string_of_global r)
| Ktype | Kprop -> ""
let error_remaining_implicit k =
let s = msg_of_implicit k in
err (str ("An implicit occurs after extraction : "^s^".") ++ fnl () ++
str "Please check your Extraction Implicit declarations." ++ fnl() ++
str "You might also try Unset Extraction SafeImplicits to force" ++
fnl() ++ str "the extraction of unsafe code and review it manually.")
let warn_extraction_remaining_implicit =
CWarnings.create ~name:"extraction-remaining-implicit" ~category:"extraction"
(fun s -> strbrk ("At least an implicit occurs after extraction : "^s^".") ++ fnl () ++
strbrk "Extraction SafeImplicits is unset, extracting nonetheless,"
++ strbrk "but this code is potentially unsafe, please review it manually.")
let warning_remaining_implicit k =
let s = msg_of_implicit k in
warn_extraction_remaining_implicit s
let check_loaded_modfile mp = match base_mp mp with
| MPfile dp ->
if not (Library.library_is_loaded dp) then begin
match base_mp (Lib.current_mp ()) with
| MPfile dp' when not (DirPath.equal dp dp') ->
err (str "Please load library " ++ pr_dirpath dp ++ str " first.")
| _ -> ()
end
| _ -> ()
let info_file f =
Flags.if_verbose Feedback.msg_info
(str ("The file "^f^" has been created by extraction."))
(*S The Extraction auxiliary commands *)
(* The objects defined below should survive an arbitrary time,
so we register them to coq save/undo mechanism. *)
let my_bool_option name initval =
let flag = ref initval in
let access = fun () -> !flag in
let _ = declare_bool_option
{optsync = true;
optdepr = false;
optname = "Extraction "^name;
optkey = ["Extraction"; name];
optread = access;
optwrite = (:=) flag }
in
access
(*s Extraction AccessOpaque *)
let access_opaque = my_bool_option "AccessOpaque" true
(*s Extraction AutoInline *)
let auto_inline = my_bool_option "AutoInline" false
(*s Extraction TypeExpand *)
let type_expand = my_bool_option "TypeExpand" true
(*s Extraction KeepSingleton *)
let keep_singleton = my_bool_option "KeepSingleton" false
(*s Extraction Optimize *)
type opt_flag =
{ opt_kill_dum : bool; (* 1 *)
opt_fix_fun : bool; (* 2 *)
opt_case_iot : bool; (* 4 *)
opt_case_idr : bool; (* 8 *)
opt_case_idg : bool; (* 16 *)
opt_case_cst : bool; (* 32 *)
opt_case_fun : bool; (* 64 *)
opt_case_app : bool; (* 128 *)
opt_let_app : bool; (* 256 *)
opt_lin_let : bool; (* 512 *)
opt_lin_beta : bool } (* 1024 *)
let kth_digit n k = not (Int.equal (n land (1 lsl k)) 0)
let flag_of_int n =
{ opt_kill_dum = kth_digit n 0;
opt_fix_fun = kth_digit n 1;
opt_case_iot = kth_digit n 2;
opt_case_idr = kth_digit n 3;
opt_case_idg = kth_digit n 4;
opt_case_cst = kth_digit n 5;
opt_case_fun = kth_digit n 6;
opt_case_app = kth_digit n 7;
opt_let_app = kth_digit n 8;
opt_lin_let = kth_digit n 9;
opt_lin_beta = kth_digit n 10 }
(* For the moment, we allow by default everything except :
- the type-unsafe optimization [opt_case_idg], which anyway
cannot be activated currently (cf [Mlutil.branch_as_fun])
- the linear let and beta reduction [opt_lin_let] and [opt_lin_beta]
(may lead to complexity blow-up, subsumed by finer reductions
when inlining recursors).
*)
let int_flag_init = 1 + 2 + 4 + 8 (*+ 16*) + 32 + 64 + 128 + 256 (*+ 512 + 1024*)
let int_flag_ref = ref int_flag_init
let opt_flag_ref = ref (flag_of_int int_flag_init)
let chg_flag n = int_flag_ref := n; opt_flag_ref := flag_of_int n
let optims () = !opt_flag_ref
let _ = declare_bool_option
{optsync = true;
optdepr = false;
optname = "Extraction Optimize";
optkey = ["Extraction"; "Optimize"];
optread = (fun () -> not (Int.equal !int_flag_ref 0));
optwrite = (fun b -> chg_flag (if b then int_flag_init else 0))}
let _ = declare_int_option
{ optsync = true;
optdepr = false;
optname = "Extraction Flag";
optkey = ["Extraction";"Flag"];
optread = (fun _ -> Some !int_flag_ref);
optwrite = (function
| None -> chg_flag 0
| Some i -> chg_flag (max i 0))}
(* This option controls whether "dummy lambda" are removed when a
toplevel constant is defined. *)
let conservative_types_ref = ref false
let conservative_types () = !conservative_types_ref
let _ = declare_bool_option
{optsync = true;
optdepr = false;
optname = "Extraction Conservative Types";
optkey = ["Extraction"; "Conservative"; "Types"];
optread = (fun () -> !conservative_types_ref);
optwrite = (fun b -> conservative_types_ref := b) }
(* Allows to print a comment at the beginning of the output files *)
let file_comment_ref = ref ""
let file_comment () = !file_comment_ref
let _ = declare_string_option
{optsync = true;
optdepr = false;
optname = "Extraction File Comment";
optkey = ["Extraction"; "File"; "Comment"];
optread = (fun () -> !file_comment_ref);
optwrite = (fun s -> file_comment_ref := s) }
(*s Extraction Lang *)
type lang = Ocaml | Haskell | Scheme | JSON
let lang_ref = Summary.ref Ocaml ~name:"ExtrLang"
let lang () = !lang_ref
let extr_lang : lang -> obj =
declare_object
{(default_object "Extraction Lang") with
cache_function = (fun (_,l) -> lang_ref := l);
load_function = (fun _ (_,l) -> lang_ref := l)}
let extraction_language x = Lib.add_anonymous_leaf (extr_lang x)
(*s Extraction Inline/NoInline *)
let empty_inline_table = (Refset'.empty,Refset'.empty)
let inline_table = Summary.ref empty_inline_table ~name:"ExtrInline"
let to_inline r = Refset'.mem r (fst !inline_table)
let to_keep r = Refset'.mem r (snd !inline_table)
let add_inline_entries b l =
let f b = if b then Refset'.add else Refset'.remove in
let i,k = !inline_table in
inline_table :=
(List.fold_right (f b) l i),
(List.fold_right (f (not b)) l k)
(* Registration of operations for rollback. *)
let inline_extraction : bool * global_reference list -> obj =
declare_object
{(default_object "Extraction Inline") with
cache_function = (fun (_,(b,l)) -> add_inline_entries b l);
load_function = (fun _ (_,(b,l)) -> add_inline_entries b l);
classify_function = (fun o -> Substitute o);
discharge_function =
(fun (_,(b,l)) -> Some (b, List.map pop_global_reference l));
subst_function =
(fun (s,(b,l)) -> (b,(List.map (fun x -> fst (subst_global s x)) l)))
}
(* Grammar entries. *)
let extraction_inline b l =
let refs = List.map Smartlocate.global_with_alias l in
List.iter
(fun r -> match r with
| ConstRef _ -> ()
| _ -> error_constant r) refs;
Lib.add_anonymous_leaf (inline_extraction (b,refs))
(* Printing part *)
let print_extraction_inline () =
let (i,n)= !inline_table in
let i'= Refset'.filter (function ConstRef _ -> true | _ -> false) i in
(str "Extraction Inline:" ++ fnl () ++
Refset'.fold
(fun r p ->
(p ++ str " " ++ safe_pr_long_global r ++ fnl ())) i' (mt ()) ++
str "Extraction NoInline:" ++ fnl () ++
Refset'.fold
(fun r p ->
(p ++ str " " ++ safe_pr_long_global r ++ fnl ())) n (mt ()))
(* Reset part *)
let reset_inline : unit -> obj =
declare_object
{(default_object "Reset Extraction Inline") with
cache_function = (fun (_,_)-> inline_table := empty_inline_table);
load_function = (fun _ (_,_)-> inline_table := empty_inline_table)}
let reset_extraction_inline () = Lib.add_anonymous_leaf (reset_inline ())
(*s Extraction Implicit *)
let safe_implicit = my_bool_option "SafeImplicits" true
let err_or_warn_remaining_implicit k =
if safe_implicit () then
error_remaining_implicit k
else
warning_remaining_implicit k
type int_or_id = ArgInt of int | ArgId of Id.t
let implicits_table = Summary.ref Refmap'.empty ~name:"ExtrImplicit"
let implicits_of_global r =
try Refmap'.find r !implicits_table with Not_found -> Int.Set.empty
let add_implicits r l =
let names = argnames_of_global r in
let n = List.length names in
let add_arg s = function
| ArgInt i ->
if 1 <= i && i <= n then Int.Set.add i s
else err (int i ++ str " is not a valid argument number for " ++
safe_pr_global r)
| ArgId id ->
try
let i = List.index Name.equal (Name id) names in
Int.Set.add i s
with Not_found ->
err (str "No argument " ++ pr_id id ++ str " for " ++
safe_pr_global r)
in
let ints = List.fold_left add_arg Int.Set.empty l in
implicits_table := Refmap'.add r ints !implicits_table
(* Registration of operations for rollback. *)
let implicit_extraction : global_reference * int_or_id list -> obj =
declare_object
{(default_object "Extraction Implicit") with
cache_function = (fun (_,(r,l)) -> add_implicits r l);
load_function = (fun _ (_,(r,l)) -> add_implicits r l);
classify_function = (fun o -> Substitute o);
subst_function = (fun (s,(r,l)) -> (fst (subst_global s r), l))
}
(* Grammar entries. *)
let extraction_implicit r l =
check_inside_section ();
Lib.add_anonymous_leaf (implicit_extraction (Smartlocate.global_with_alias r,l))
(*s Extraction Blacklist of filenames not to use while extracting *)
let blacklist_table = Summary.ref Id.Set.empty ~name:"ExtrBlacklist"
let modfile_ids = ref []
let modfile_mps = ref MPmap.empty
let reset_modfile () =
modfile_ids := Id.Set.elements !blacklist_table;
modfile_mps := MPmap.empty
let string_of_modfile mp =
try MPmap.find mp !modfile_mps
with Not_found ->
let id = Id.of_string (raw_string_of_modfile mp) in
let id' = next_ident_away id !modfile_ids in
let s' = Id.to_string id' in
modfile_ids := id' :: !modfile_ids;
modfile_mps := MPmap.add mp s' !modfile_mps;
s'
(* same as [string_of_modfile], but preserves the capital/uncapital 1st char *)
let file_of_modfile mp =
let s0 = match mp with
| MPfile f -> Id.to_string (List.hd (DirPath.repr f))
| _ -> assert false
in
let s = String.copy (string_of_modfile mp) in
if s.[0] != s0.[0] then s.[0] <- s0.[0];
s
let add_blacklist_entries l =
blacklist_table :=
List.fold_right (fun s -> Id.Set.add (Id.of_string (String.capitalize s)))
l !blacklist_table
(* Registration of operations for rollback. *)
let blacklist_extraction : string list -> obj =
declare_object
{(default_object "Extraction Blacklist") with
cache_function = (fun (_,l) -> add_blacklist_entries l);
load_function = (fun _ (_,l) -> add_blacklist_entries l);
subst_function = (fun (_,x) -> x)
}
(* Grammar entries. *)
let extraction_blacklist l =
let l = List.rev_map Id.to_string l in
Lib.add_anonymous_leaf (blacklist_extraction l)
(* Printing part *)
let print_extraction_blacklist () =
prlist_with_sep fnl pr_id (Id.Set.elements !blacklist_table)
(* Reset part *)
let reset_blacklist : unit -> obj =
declare_object
{(default_object "Reset Extraction Blacklist") with
cache_function = (fun (_,_)-> blacklist_table := Id.Set.empty);
load_function = (fun _ (_,_)-> blacklist_table := Id.Set.empty)}
let reset_extraction_blacklist () = Lib.add_anonymous_leaf (reset_blacklist ())
(*s Extract Constant/Inductive. *)
(* UGLY HACK: to be defined in [extraction.ml] *)
let (use_type_scheme_nb_args, type_scheme_nb_args_hook) = Hook.make ()
let customs = Summary.ref Refmap'.empty ~name:"ExtrCustom"
let add_custom r ids s = customs := Refmap'.add r (ids,s) !customs
let is_custom r = Refmap'.mem r !customs
let is_inline_custom r = (is_custom r) && (to_inline r)
let find_custom r = snd (Refmap'.find r !customs)
let find_type_custom r = Refmap'.find r !customs
let custom_matchs = Summary.ref Refmap'.empty ~name:"ExtrCustomMatchs"
let add_custom_match r s =
custom_matchs := Refmap'.add r s !custom_matchs
let indref_of_match pv =
if Array.is_empty pv then raise Not_found;
let (_,pat,_) = pv.(0) in
match pat with
| Pusual (ConstructRef (ip,_)) -> IndRef ip
| Pcons (ConstructRef (ip,_),_) -> IndRef ip
| _ -> raise Not_found
let is_custom_match pv =
try Refmap'.mem (indref_of_match pv) !custom_matchs
with Not_found -> false
let find_custom_match pv =
Refmap'.find (indref_of_match pv) !custom_matchs
(* Registration of operations for rollback. *)
let in_customs : global_reference * string list * string -> obj =
declare_object
{(default_object "ML extractions") with
cache_function = (fun (_,(r,ids,s)) -> add_custom r ids s);
load_function = (fun _ (_,(r,ids,s)) -> add_custom r ids s);
classify_function = (fun o -> Substitute o);
subst_function =
(fun (s,(r,ids,str)) -> (fst (subst_global s r), ids, str))
}
let in_custom_matchs : global_reference * string -> obj =
declare_object
{(default_object "ML extractions custom matchs") with
cache_function = (fun (_,(r,s)) -> add_custom_match r s);
load_function = (fun _ (_,(r,s)) -> add_custom_match r s);
classify_function = (fun o -> Substitute o);
subst_function = (fun (subs,(r,s)) -> (fst (subst_global subs r), s))
}
(* Grammar entries. *)
let extract_constant_inline inline r ids s =
check_inside_section ();
let g = Smartlocate.global_with_alias r in
match g with
| ConstRef kn ->
let env = Global.env () in
let typ = Global.type_of_global_unsafe (ConstRef kn) in
let typ = Reduction.whd_all env typ in
if Reduction.is_arity env typ
then begin
let nargs = Hook.get use_type_scheme_nb_args env typ in
if not (Int.equal (List.length ids) nargs) then error_axiom_scheme g nargs
end;
Lib.add_anonymous_leaf (inline_extraction (inline,[g]));
Lib.add_anonymous_leaf (in_customs (g,ids,s))
| _ -> error_constant g
let extract_inductive r s l optstr =
check_inside_section ();
let g = Smartlocate.global_with_alias r in
Dumpglob.add_glob (loc_of_reference r) g;
match g with
| IndRef ((kn,i) as ip) ->
let mib = Global.lookup_mind kn in
let n = Array.length mib.mind_packets.(i).mind_consnames in
if not (Int.equal n (List.length l)) then error_nb_cons ();
Lib.add_anonymous_leaf (inline_extraction (true,[g]));
Lib.add_anonymous_leaf (in_customs (g,[],s));
Option.iter (fun s -> Lib.add_anonymous_leaf (in_custom_matchs (g,s)))
optstr;
List.iteri
(fun j s ->
let g = ConstructRef (ip,succ j) in
Lib.add_anonymous_leaf (inline_extraction (true,[g]));
Lib.add_anonymous_leaf (in_customs (g,[],s))) l
| _ -> error_inductive g
(*s Tables synchronization. *)
let reset_tables () =
init_typedefs (); init_cst_types (); init_inductives ();
init_inductive_kinds (); init_recursors ();
init_projs (); init_axioms (); init_opaques (); reset_modfile ()
|