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|
(***********************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA-Rocquencourt & LRI-CNRS-Orsay *)
(* \VV/ *************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(***********************************************************************)
(*i $Id$ i*)
open Term
open Declarations
open Names
open Libnames
open Pp
open Util
open Miniml
open Table
open Extraction
open Mlutil
open Common
(*s Obtaining Coq environment. *)
let toplevel_env () =
let seg = Lib.contents_after None in
let get_reference = function
| (_,kn), Lib.Leaf o ->
let mp,_,l = repr_kn kn in
let seb = match Libobject.object_tag o with
| "CONSTANT" -> SEBconst (Global.lookup_constant kn)
| "INDUCTIVE" -> SEBmind (Global.lookup_mind kn)
| "MODULE" -> SEBmodule (Global.lookup_module (MPdot (mp,l)))
| "MODULE TYPE" -> SEBmodtype (Global.lookup_modtype kn)
| _ -> failwith "caught"
in l,seb
| _ -> failwith "caught"
in
match current_toplevel () with
| MPself msid -> MEBstruct (msid, List.rev (map_succeed get_reference seg))
| _ -> assert false
let environment_until dir_opt =
let rec parse = function
| [] when dir_opt = None -> [current_toplevel (), toplevel_env ()]
| [] -> []
| d :: l ->
match (Global.lookup_module (MPfile d)).mod_expr with
| Some meb ->
if dir_opt = Some d then [MPfile d, meb]
else (MPfile d, meb) :: (parse l)
| _ -> assert false
in parse (Library.loaded_libraries ())
(*s First, we parse everything in order to produce
a table of aliases between short and long [module_path]. *)
let rec init_aliases_seb loc abs = function
| l, SEBmodule mb ->
init_aliases_module loc (option_app (fun mp -> MPdot (mp,l)) abs) mb
| l, SEBmodtype mtb -> init_aliases_modtype loc mtb
| _ -> ()
and init_aliases_module loc abs mb =
option_iter (init_aliases_meb loc abs) mb.mod_expr
and init_aliases_meb loc abs = function
| MEBident mp -> ()
| MEBapply (meb, meb',_) ->
init_aliases_meb loc None meb; init_aliases_meb loc None meb'
| MEBfunctor (mbid, mtb, meb) ->
init_aliases_modtype loc mtb;
init_aliases_meb loc None meb
| MEBstruct (msid, msb) ->
let loc = MPself msid in
option_iter (add_aliases loc) abs;
List.iter (init_aliases_seb loc abs) msb
and init_aliases_modtype loc = function
| MTBident mp -> ()
| MTBfunsig (mbid, mtb, mtb') ->
init_aliases_modtype loc mtb;
init_aliases_modtype loc mtb'
| MTBsig (msid, sign) ->
let loc = MPself msid in
List.iter (init_aliases_spec loc) sign
and init_aliases_spec loc = function
| l, SPBmodule {msb_modtype=mtb} -> init_aliases_modtype loc mtb
| l, SPBmodtype mtb -> init_aliases_modtype loc mtb
| _ -> ()
let init_aliases l =
List.iter
(fun (mp,meb) -> init_aliases_meb (current_toplevel ()) (Some mp) meb) l
(*s The extraction pass. *)
type visit = { mutable kn : KNset.t; mutable mp : MPset.t }
let in_kn v kn = KNset.mem (long_kn kn) v.kn
let in_mp v mp = MPset.mem (long_mp mp) v.mp
let visit_ref v r =
let kn = long_kn (kn_of_r r) in
v.kn <- KNset.add kn v.kn;
v.mp <- MPset.union (prefixes_mp (modpath kn)) v.mp
exception Impossible
let check_arity env cb =
if Reduction.is_arity env cb.const_type then raise Impossible
let check_fix env cb i =
match cb.const_body with
| None -> raise Impossible
| Some lbody ->
match kind_of_term (Declarations.force lbody) with
| Fix ((_,j),recd) when i=j -> check_arity env cb; (true,recd)
| CoFix (j,recd) when i=j -> check_arity env cb; (false,recd)
| _ -> raise Impossible
let factor_fix env l cb msb =
let _,recd as check = check_fix env cb 0 in
let n = Array.length (let fi,_,_ = recd in fi) in
if n = 1 then [|l|], recd, msb
else begin
if List.length msb < n-1 then raise Impossible;
let msb', msb'' = list_chop (n-1) msb in
let labels = Array.make n l in
list_iter_i
(fun j ->
function
| (l,SEBconst cb') ->
if check <> check_fix env cb' (j+1) then raise Impossible;
labels.(j+1) <- l;
| _ -> raise Impossible) msb';
labels, recd, msb''
end
let logical_decl = function
| Dterm (_,MLdummy,Tdummy) -> true
| Dtype (_,[],Tdummy) -> true
| Dfix (_,av,tv) ->
(array_for_all ((=) MLdummy) av) && (array_for_all ((=) Tdummy) tv)
| Dind (_,i) -> array_for_all (fun ip -> ip.ip_logical) i.ind_packets
| _ -> false
let logical_spec = function
| Stype (_, [], Some Tdummy) -> true
| Sval (_,Tdummy) -> true
| Sind (_,i) -> array_for_all (fun ip -> ip.ip_logical) i.ind_packets
| _ -> false
let get_decl_references v d =
let f = visit_ref v in decl_iter_references f f f d
let get_spec_references v s =
let f = visit_ref v in spec_iter_references f f f s
let rec extract_msb env v all loc = function
| [] -> []
| (l,SEBconst cb) :: msb ->
(try
let vl,recd,msb = factor_fix env l cb msb in
let vkn = Array.map (make_kn loc empty_dirpath) vl in
let vkn = Array.map long_kn vkn in
let ms = extract_msb env v all loc msb in
let b = array_exists (in_kn v) vkn in
if all || b then
let d = extract_fixpoint env vkn recd in
if (not b) && (logical_decl d) then ms
else begin get_decl_references v d; (l,SEdecl d) :: ms end
else ms
with Impossible ->
let ms = extract_msb env v all loc msb in
let kn = make_kn loc empty_dirpath l in
let b = in_kn v kn in
if all || b then
let d = extract_constant env kn cb in
if (not b) && (logical_decl d) then ms
else begin get_decl_references v d; (l,SEdecl d) :: ms end
else ms)
| (l,SEBmind mib) :: msb ->
let ms = extract_msb env v all loc msb in
let kn = make_kn loc empty_dirpath l in
let b = in_kn v kn in
if all || b then
let d = Dind (kn, extract_inductive env kn) in
if (not b) && (logical_decl d) then ms
else begin get_decl_references v d; (l,SEdecl d) :: ms end
else ms
| (l,SEBmodule mb) :: msb ->
let ms = extract_msb env v all loc msb in
let loc = MPdot (loc,l) in
if all || in_mp v loc then
(l,SEmodule (extract_module env v true mb)) :: ms
else ms
| (l,SEBmodtype mtb) :: msb ->
let ms = extract_msb env v all loc msb in
let kn = make_kn loc empty_dirpath l in
if all || in_kn v kn then
(l,SEmodtype (extract_mtb env v mtb)) :: ms
else ms
and extract_meb env v all = function
| MEBident mp -> MEident mp
| MEBapply (meb, meb',_) ->
MEapply (extract_meb env v true meb, extract_meb env v true meb')
| MEBfunctor (mbid, mtb, meb) ->
let env' = add_functor mbid mtb env in
MEfunctor (mbid, extract_mtb env v mtb, extract_meb env' v true meb)
| MEBstruct (msid, msb) ->
let loc = MPself msid in
let env' = add_structure loc msb env in
MEstruct (msid, extract_msb env' v all loc msb)
and extract_module env v all mb =
{ ml_mod_expr = option_app (extract_meb env v all) mb.mod_expr;
ml_mod_type = (match mb.mod_user_type with
| None -> extract_mtb env v mb.mod_type
| Some mtb -> extract_mtb env v mtb);
ml_mod_equiv = mb.mod_equiv }
and extract_mtb env v = function
| MTBident kn -> MTident kn
| MTBfunsig (mbid, mtb, mtb') ->
let env' = add_functor mbid mtb env in
MTfunsig (mbid, extract_mtb env v mtb, extract_mtb env' v mtb')
| MTBsig (msid, msig) ->
let loc = MPself msid in
let env' = Modops.add_signature loc msig env in
MTsig (msid, extract_msig env' v loc msig)
and extract_msig env v loc = function
| [] -> []
| (l,SPBconst cb) :: msig ->
let kn = make_kn loc empty_dirpath l in
let s = extract_constant_spec env kn cb in
if logical_spec s then extract_msig env v loc msig
else begin
get_spec_references v s;
(l,Spec s) :: (extract_msig env v loc msig)
end
| (l,SPBmind cb) :: msig ->
let kn = make_kn loc empty_dirpath l in
let s = Sind (kn, extract_inductive env kn) in
if logical_spec s then extract_msig env v loc msig
else begin
get_spec_references v s;
(l,Spec s) :: (extract_msig env v loc msig)
end
| (l,SPBmodule {msb_modtype=mtb}) :: msig ->
(l,Smodule (extract_mtb env v mtb)) :: (extract_msig env v loc msig)
| (l,SPBmodtype mtb) :: msig ->
(l,Smodtype (extract_mtb env v mtb)) :: (extract_msig env v loc msig)
(* Searching one [ml_decl] in a [ml_structure] by its [kernel_name] *)
let get_decl_in_structure r struc =
try
let kn = kn_of_r r in
let base_mp,ll = labels_of_kn (long_kn kn) in
if not (at_toplevel base_mp) then error_not_visible r;
let sel = List.assoc base_mp struc in
let rec go ll sel = match ll with
| [] -> assert false
| l :: ll ->
match List.assoc l sel with
| SEdecl d -> d
| SEmodtype m -> assert false
| SEmodule m ->
match m.ml_mod_expr with
| Some (MEstruct (_,sel)) -> go ll sel
| _ -> error_not_visible r
in go ll sel
with Not_found -> assert false
(*s Extraction in the Coq toplevel. We display the extracted term in
Ocaml syntax and we use the Coq printers for globals. The
vernacular command is \verb!Extraction! [qualid]. *)
let unpack = function MEstruct (_,sel) -> sel | _ -> assert false
let mono_environment refs =
let l = environment_until None in
init_aliases l;
let v =
let kns = List.fold_right (fun r -> KNset.add (kn_of_r r)) refs KNset.empty
in let add_mp kn = MPset.union (prefixes_mp (modpath kn))
in { kn = kns; mp = KNset.fold add_mp kns MPset.empty }
in
let env = Global.env () in
List.rev_map (fun (mp,m) -> mp, unpack (extract_meb env v false m))
(List.rev l)
let extraction qid =
if is_something_opened () then error_section ();
let r = Nametab.global qid in
if is_custom r then
msgnl (str "User defined extraction:" ++ spc () ++
str (find_custom r) ++ fnl ())
else begin
let prm =
{ modular = false; mod_name = id_of_string "Main"; to_appear = [r]} in
let kn = kn_of_r r in
let struc = optimize_struct prm None (mono_environment [r]) in
let d = get_decl_in_structure r struc in
print_one_decl struc (long_mp (modpath kn)) d;
reset_tables ()
end
(*s Recursive extraction in the Coq toplevel. The vernacular command is
\verb!Recursive Extraction! [qualid1] ... [qualidn]. We use [extract_env]
to get the saturated environment to extract. *)
let mono_extraction (f,m) vl =
if is_something_opened () then error_section ();
let refs = List.map Nametab.global vl in
let prm = {modular=false; mod_name = m; to_appear= refs} in
let struc = optimize_struct prm None (mono_environment refs) in
print_structure_to_file f prm struc;
reset_tables ()
let extraction_rec = mono_extraction (None,id_of_string "Main")
(*s Extraction to a file (necessarily recursive).
The vernacular command is
\verb!Extraction "file"! [qualid1] ... [qualidn].*)
let lang_suffix () = match lang () with
| Ocaml -> ".ml",".mli"
| Haskell -> ".hs",".hi"
| Scheme -> ".scm",".scm"
| Toplevel -> assert false
let filename f =
let s,s' = lang_suffix () in
if Filename.check_suffix f s then
let f' = Filename.chop_suffix f s in
Some (f,f'^s'),id_of_string f'
else Some (f^s,f^s'),id_of_string f
let extraction_file f vl =
if lang () = Toplevel then error_toplevel ()
else mono_extraction (filename f) vl
(*s Extraction of a module. The vernacular command is
\verb!Extraction Module! [M]. *)
let module_file_name m = match lang () with
| Ocaml -> let f = String.uncapitalize (string_of_id m) in f^".ml", f^".mli"
| Haskell -> let f = String.capitalize (string_of_id m) in f^".hs", f^".hi"
| _ -> assert false
let dir_module_of_id m =
try Nametab.full_name_module (make_short_qualid m)
with Not_found -> error_unknown_module m
let extraction_module m =
if is_something_opened () then error_section ();
match lang () with
| Toplevel -> error_toplevel ()
| Scheme -> error_scheme ()
| _ ->
let dir_m = dir_module_of_id m in
let v = { kn = KNset.empty; mp = MPset.singleton (MPfile dir_m) } in
let l = environment_until (Some dir_m) in
init_aliases l;
(* TEMPORARY: make Extraction Module look like Recursive Extraction Module *)
let struc =
let env = Global.env () in
let select l (mp,meb) =
if in_mp v mp then (mp, unpack (extract_meb env v true meb)) :: l
else l
in List.fold_left select [] (List.rev l)
in
let dummy_prm = {modular=true; mod_name=m; to_appear=[]} in
let struc = optimize_struct dummy_prm None struc in
let rec print = function
| [] -> ()
| (MPfile dir, _) :: l when dir <> dir_m -> print l
| (MPfile dir, sel) as e :: l ->
let short_m = snd (split_dirpath dir) in
let f = module_file_name short_m in
let prm = {modular=true;mod_name=short_m;to_appear=[]} in
print_structure_to_file (Some f) prm [e];
print l
| _ -> assert false
in print struc;
reset_tables ()
(*s Recursive Extraction of all the modules [M] depends on.
The vernacular command is \verb!Recursive Extraction Module! [M]. *)
let recursive_extraction_module m =
if is_something_opened () then error_section ();
match lang () with
| Toplevel -> error_toplevel ()
| Scheme -> error_scheme ()
| _ ->
let dir_m = dir_module_of_id m in
let v = { kn = KNset.empty; mp = MPset.singleton (MPfile dir_m) } in
let l = environment_until (Some dir_m) in
init_aliases l;
let struc =
let env = Global.env () in
let select l (mp,meb) =
if in_mp v mp then (mp, unpack (extract_meb env v true meb)) :: l else l
in List.fold_left select [] (List.rev l)
in
let dummy_prm = {modular=true; mod_name=m; to_appear=[]} in
let struc = optimize_struct dummy_prm None struc in
let rec print = function
| [] -> ()
| (MPfile dir, sel) as e :: l ->
let short_m = snd (split_dirpath dir) in
let f = module_file_name short_m in
let prm = {modular=true;mod_name=short_m;to_appear=[]} in
print_structure_to_file (Some f) prm [e];
print l
| _ -> assert false
in print struc;
reset_tables ()
|
