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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 Pp
open Util
open Names
open Term
open Declarations
open Libobject
open Environ
open Pattern
open Printer
open Libnames
open Globnames
open Nametab
open Goptions
type filter_function = global_reference -> env -> constr -> bool
type display_function = global_reference -> env -> constr -> unit
(* This option restricts the output of [SearchPattern ...],
[SearchAbout ...], etc. to the names of the symbols matching the
query, separated by a newline. This type of output is useful for
editors (like emacs), to generate a list of completion candidates
without having to parse thorugh the types of all symbols. *)
let search_output_name_only = ref false
let _ =
declare_bool_option
{ optsync = true;
optdepr = false;
optname = "output-name-only search";
optkey = ["Search";"Output";"Name";"Only"];
optread = (fun () -> !search_output_name_only);
optwrite = (:=) search_output_name_only }
type glob_search_about_item =
| GlobSearchSubPattern of constr_pattern
| GlobSearchString of string
module SearchBlacklist =
Goptions.MakeStringTable
(struct
let key = ["Search";"Blacklist"]
let title = "Current search blacklist : "
let member_message s b =
str "Search blacklist does " ++ (if b then mt () else str "not ") ++ str "include " ++ str s
let synchronous = true
end)
(* The functions iter_constructors and iter_declarations implement the behavior
needed for the Coq searching commands.
These functions take as first argument the procedure
that will be called to treat each entry. This procedure receives the name
of the object, the assumptions that will make it possible to print its type,
and the constr term that represent its type. *)
let iter_constructors indsp u fn env nconstr =
for i = 1 to nconstr do
let typ = Inductiveops.type_of_constructor env ((indsp, i), u) in
fn (ConstructRef (indsp, i)) env typ
done
let iter_named_context_name_type f =
let open Context.Named.Declaration in
List.iter (fun decl -> f (get_id decl) (get_type decl))
(* General search over hypothesis of a goal *)
let iter_hypothesis glnum (fn : global_reference -> env -> constr -> unit) =
let env = Global.env () in
let iter_hyp idh typ = fn (VarRef idh) env typ in
let evmap,e = Pfedit.get_goal_context glnum in
let pfctxt = named_context e in
iter_named_context_name_type iter_hyp pfctxt
(* General search over declarations *)
let iter_declarations (fn : global_reference -> env -> constr -> unit) =
let open Context.Named.Declaration in
let env = Global.env () in
let iter_obj (sp, kn) lobj = match object_tag lobj with
| "VARIABLE" ->
begin try
let decl = Global.lookup_named (basename sp) in
fn (VarRef (get_id decl)) env (get_type decl)
with Not_found -> (* we are in a section *) () end
| "CONSTANT" ->
let cst = Global.constant_of_delta_kn kn in
let gr = ConstRef cst in
let typ = Global.type_of_global_unsafe gr in
fn gr env typ
| "INDUCTIVE" ->
let mind = Global.mind_of_delta_kn kn in
let mib = Global.lookup_mind mind in
let iter_packet i mip =
let ind = (mind, i) in
let u = Declareops.inductive_instance mib in
let i = (ind, u) in
let typ = Inductiveops.type_of_inductive env i in
let () = fn (IndRef ind) env typ in
let len = Array.length mip.mind_user_lc in
iter_constructors ind u fn env len
in
Array.iteri iter_packet mib.mind_packets
| _ -> ()
in
try Declaremods.iter_all_segments iter_obj
with Not_found -> ()
let generic_search glnumopt fn =
(match glnumopt with
| None -> ()
| Some glnum -> iter_hypothesis glnum fn);
iter_declarations fn
(** Standard display *)
let plain_display accu ref env c =
let pr = pr_global ref in
if !search_output_name_only then
accu := pr :: !accu
else begin
let pc = pr_lconstr_env env Evd.empty c in
accu := hov 2 (pr ++ str":" ++ spc () ++ pc) :: !accu
end
let format_display l = prlist_with_sep fnl (fun x -> x) (List.rev l)
(** Filters *)
(** This function tries to see whether the conclusion matches a pattern. *)
(** FIXME: this is quite dummy, we may find a more efficient algorithm. *)
let rec pattern_filter pat ref env typ =
let typ = strip_outer_cast typ in
if Constr_matching.is_matching env Evd.empty pat typ then true
else match kind_of_term typ with
| Prod (_, _, typ)
| LetIn (_, _, _, typ) -> pattern_filter pat ref env typ
| _ -> false
let rec head_filter pat ref env typ =
let typ = strip_outer_cast typ in
if Constr_matching.is_matching_head env Evd.empty pat typ then true
else match kind_of_term typ with
| Prod (_, _, typ)
| LetIn (_, _, _, typ) -> head_filter pat ref env typ
| _ -> false
let full_name_of_reference ref =
let (dir,id) = repr_path (path_of_global ref) in
DirPath.to_string dir ^ "." ^ Id.to_string id
(** Whether a reference is blacklisted *)
let blacklist_filter ref env typ =
let l = SearchBlacklist.elements () in
let name = full_name_of_reference ref in
let is_not_bl str = not (String.string_contains ~where:name ~what:str) in
List.for_all is_not_bl l
let module_filter (mods, outside) ref env typ =
let sp = path_of_global ref in
let sl = dirpath sp in
let is_outside md = not (is_dirpath_prefix_of md sl) in
let is_inside md = is_dirpath_prefix_of md sl in
if outside then List.for_all is_outside mods
else List.is_empty mods || List.exists is_inside mods
let name_of_reference ref = Id.to_string (basename_of_global ref)
let search_about_filter query gr env typ = match query with
| GlobSearchSubPattern pat ->
Constr_matching.is_matching_appsubterm ~closed:false env Evd.empty pat typ
| GlobSearchString s ->
String.string_contains ~where:(name_of_reference gr) ~what:s
(** SearchPattern *)
let search_pattern gopt pat mods =
let ans = ref [] in
let filter ref env typ =
let f_module = module_filter mods ref env typ in
let f_blacklist = blacklist_filter ref env typ in
let f_pattern () = pattern_filter pat ref env typ in
f_module && f_pattern () && f_blacklist
in
let iter ref env typ =
if filter ref env typ then plain_display ans ref env typ
in
let () = generic_search gopt iter in
format_display !ans
(** SearchRewrite *)
let eq = Coqlib.glob_eq
let rewrite_pat1 pat =
PApp (PRef eq, [| PMeta None; pat; PMeta None |])
let rewrite_pat2 pat =
PApp (PRef eq, [| PMeta None; PMeta None; pat |])
let search_rewrite gopt pat mods =
let pat1 = rewrite_pat1 pat in
let pat2 = rewrite_pat2 pat in
let ans = ref [] in
let filter ref env typ =
let f_module = module_filter mods ref env typ in
let f_blacklist = blacklist_filter ref env typ in
let f_pattern () =
pattern_filter pat1 ref env typ ||
pattern_filter pat2 ref env typ
in
f_module && f_pattern () && f_blacklist
in
let iter ref env typ =
if filter ref env typ then plain_display ans ref env typ
in
let () = generic_search gopt iter in
format_display !ans
(** Search *)
let search_by_head gopt pat mods =
let ans = ref [] in
let filter ref env typ =
let f_module = module_filter mods ref env typ in
let f_blacklist = blacklist_filter ref env typ in
let f_pattern () = head_filter pat ref env typ in
f_module && f_pattern () && f_blacklist
in
let iter ref env typ =
if filter ref env typ then plain_display ans ref env typ
in
let () = generic_search gopt iter in
format_display !ans
(** SearchAbout *)
let search_about gopt items mods =
let ans = ref [] in
let filter ref env typ =
let eqb b1 b2 = if b1 then b2 else not b2 in
let f_module = module_filter mods ref env typ in
let f_about (b, i) = eqb b (search_about_filter i ref env typ) in
let f_blacklist = blacklist_filter ref env typ in
f_module && List.for_all f_about items && f_blacklist
in
let iter ref env typ =
if filter ref env typ then plain_display ans ref env typ
in
let () = generic_search gopt iter in
format_display !ans
type search_constraint =
| Name_Pattern of Str.regexp
| Type_Pattern of Pattern.constr_pattern
| SubType_Pattern of Pattern.constr_pattern
| In_Module of Names.DirPath.t
| Include_Blacklist
type 'a coq_object = {
coq_object_prefix : string list;
coq_object_qualid : string list;
coq_object_object : 'a;
}
let interface_search =
let rec extract_flags name tpe subtpe mods blacklist = function
| [] -> (name, tpe, subtpe, mods, blacklist)
| (Name_Pattern regexp, b) :: l ->
extract_flags ((regexp, b) :: name) tpe subtpe mods blacklist l
| (Type_Pattern pat, b) :: l ->
extract_flags name ((pat, b) :: tpe) subtpe mods blacklist l
| (SubType_Pattern pat, b) :: l ->
extract_flags name tpe ((pat, b) :: subtpe) mods blacklist l
| (In_Module id, b) :: l ->
extract_flags name tpe subtpe ((id, b) :: mods) blacklist l
| (Include_Blacklist, b) :: l ->
extract_flags name tpe subtpe mods b l
in
fun ?glnum flags ->
let (name, tpe, subtpe, mods, blacklist) =
extract_flags [] [] [] [] false flags
in
let filter_function ref env constr =
let id = Names.Id.to_string (Nametab.basename_of_global ref) in
let path = Libnames.dirpath (Nametab.path_of_global ref) in
let toggle x b = if x then b else not b in
let match_name (regexp, flag) =
toggle (Str.string_match regexp id 0) flag
in
let match_type (pat, flag) =
toggle (Constr_matching.is_matching env Evd.empty pat constr) flag
in
let match_subtype (pat, flag) =
toggle
(Constr_matching.is_matching_appsubterm ~closed:false
env Evd.empty pat constr) flag
in
let match_module (mdl, flag) =
toggle (Libnames.is_dirpath_prefix_of mdl path) flag
in
let in_blacklist =
blacklist || (blacklist_filter ref env constr)
in
List.for_all match_name name &&
List.for_all match_type tpe &&
List.for_all match_subtype subtpe &&
List.for_all match_module mods && in_blacklist
in
let ans = ref [] in
let print_function ref env constr =
let fullpath = DirPath.repr (Nametab.dirpath_of_global ref) in
let qualid = Nametab.shortest_qualid_of_global Id.Set.empty ref in
let (shortpath, basename) = Libnames.repr_qualid qualid in
let shortpath = DirPath.repr shortpath in
(* [shortpath] is a suffix of [fullpath] and we're looking for the missing
prefix *)
let rec prefix full short accu = match full, short with
| _, [] ->
let full = List.rev_map Id.to_string full in
(full, accu)
| _ :: full, m :: short ->
prefix full short (Id.to_string m :: accu)
| _ -> assert false
in
let (prefix, qualid) = prefix fullpath shortpath [Id.to_string basename] in
let answer = {
coq_object_prefix = prefix;
coq_object_qualid = qualid;
coq_object_object = string_of_ppcmds (pr_lconstr_env env Evd.empty constr);
} in
ans := answer :: !ans;
in
let iter ref env typ =
if filter_function ref env typ then print_function ref env typ
in
let () = generic_search glnum iter in
!ans
|