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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 Namegen
open Nameops
open Libnames
open Globnames
open Table
open Miniml
open Mlutil
let ascii_of_id id =
let s = Id.to_string id in
for i = 0 to String.length s - 2 do
if s.[i] == '_' && s.[i+1] == '_' then warning_id s
done;
Unicode.ascii_of_ident s
let is_mp_bound = function MPbound _ -> true | _ -> false
(*s Some pretty-print utility functions. *)
let pp_par par st = if par then str "(" ++ st ++ str ")" else st
(** [pp_apply] : a head part applied to arguments, possibly with parenthesis *)
let pp_apply st par args = match args with
| [] -> st
| _ -> hov 2 (pp_par par (st ++ spc () ++ prlist_with_sep spc identity args))
(** Same as [pp_apply], but with also protection of the head by parenthesis *)
let pp_apply2 st par args =
let par' = not (List.is_empty args) || par in
pp_apply (pp_par par' st) par args
let pr_binding = function
| [] -> mt ()
| l -> str " " ++ prlist_with_sep (fun () -> str " ") pr_id l
let pp_tuple_light f = function
| [] -> mt ()
| [x] -> f true x
| l ->
pp_par true (prlist_with_sep (fun () -> str "," ++ spc ()) (f false) l)
let pp_tuple f = function
| [] -> mt ()
| [x] -> f x
| l -> pp_par true (prlist_with_sep (fun () -> str "," ++ spc ()) f l)
let pp_boxed_tuple f = function
| [] -> mt ()
| [x] -> f x
| l -> pp_par true (hov 0 (prlist_with_sep (fun () -> str "," ++ spc ()) f l))
(** By default, in module Format, you can do horizontal placing of blocks
even if they include newlines, as long as the number of chars in the
blocks is less that a line length. To avoid this awkward situation,
we attach a big virtual size to [fnl] newlines. *)
(* EG: This looks quite suspicious... but beware of bugs *)
(* let fnl () = stras (1000000,"") ++ fnl () *)
let fnl () = fnl ()
let fnl2 () = fnl () ++ fnl ()
let space_if = function true -> str " " | false -> mt ()
let begins_with s prefix =
let len = String.length prefix in
String.length s >= len && String.equal (String.sub s 0 len) prefix
let begins_with_CoqXX s =
let n = String.length s in
n >= 4 && s.[0] == 'C' && s.[1] == 'o' && s.[2] == 'q' &&
let i = ref 3 in
try while !i < n do
match s.[!i] with
| '_' -> i:=n (*Stop*)
| '0'..'9' -> incr i
| _ -> raise Not_found
done; true
with Not_found -> false
let unquote s =
if lang () != Scheme then s
else String.map (fun c -> if c == '\'' then '~' else c) s
let rec qualify delim = function
| [] -> assert false
| [s] -> s
| ""::l -> qualify delim l
| s::l -> s^delim^(qualify delim l)
let dottify = qualify "."
let pseudo_qualify = qualify "__"
(*s Uppercase/lowercase renamings. *)
let is_upper s = match s.[0] with 'A' .. 'Z' -> true | _ -> false
let is_lower s = match s.[0] with 'a' .. 'z' | '_' -> true | _ -> false
let lowercase_id id = Id.of_string (String.uncapitalize (ascii_of_id id))
let uppercase_id id =
let s = ascii_of_id id in
assert (not (String.is_empty s));
if s.[0] == '_' then Id.of_string ("Coq_"^s)
else Id.of_string (String.capitalize s)
type kind = Term | Type | Cons | Mod
module KOrd =
struct
type t = kind * string
let compare (k1, s1) (k2, s2) =
let c = Pervasives.compare k1 k2 (** OK *) in
if c = 0 then String.compare s1 s2
else c
end
module KMap = Map.Make(KOrd)
let upperkind = function
| Type -> lang () == Haskell
| Term -> false
| Cons | Mod -> true
let kindcase_id k id =
if upperkind k then uppercase_id id else lowercase_id id
(*s de Bruijn environments for programs *)
type env = Id.t list * Id.Set.t
(*s Generic renaming issues for local variable names. *)
let rec rename_id id avoid =
if Id.Set.mem id avoid then rename_id (increment_subscript id) avoid else id
let rec rename_vars avoid = function
| [] ->
[], avoid
| id :: idl when id == dummy_name ->
(* we don't rename dummy binders *)
let (idl', avoid') = rename_vars avoid idl in
(id :: idl', avoid')
| id :: idl ->
let (idl, avoid) = rename_vars avoid idl in
let id = rename_id (lowercase_id id) avoid in
(id :: idl, Id.Set.add id avoid)
let rename_tvars avoid l =
let rec rename avoid = function
| [] -> [],avoid
| id :: idl ->
let id = rename_id (lowercase_id id) avoid in
let idl, avoid = rename (Id.Set.add id avoid) idl in
(id :: idl, avoid) in
fst (rename avoid l)
let push_vars ids (db,avoid) =
let ids',avoid' = rename_vars avoid ids in
ids', (ids' @ db, avoid')
let get_db_name n (db,_) = List.nth db (pred n)
(*S Renamings of global objects. *)
(*s Tables of global renamings *)
let register_cleanup, do_cleanup =
let funs = ref [] in
(fun f -> funs:=f::!funs), (fun () -> List.iter (fun f -> f ()) !funs)
type phase = Pre | Impl | Intf
let set_phase, get_phase =
let ph = ref Impl in ((:=) ph), (fun () -> !ph)
let set_keywords, get_keywords =
let k = ref Id.Set.empty in
((:=) k), (fun () -> !k)
let add_global_ids, get_global_ids =
let ids = ref Id.Set.empty in
register_cleanup (fun () -> ids := get_keywords ());
let add s = ids := Id.Set.add s !ids
and get () = !ids
in (add,get)
let empty_env () = [], get_global_ids ()
(* We might have built [global_reference] whose canonical part is
inaccurate. We must hence compare only the user part,
hence using a Hashtbl might be incorrect *)
let mktable_id autoclean =
let m = ref Id.Map.empty in
let clear () = m := Id.Map.empty in
if autoclean then register_cleanup clear;
(fun r v -> m := Id.Map.add r v !m), (fun r -> Id.Map.find r !m), clear
let mktable_ref autoclean =
let m = ref Refmap'.empty in
let clear () = m := Refmap'.empty in
if autoclean then register_cleanup clear;
(fun r v -> m := Refmap'.add r v !m), (fun r -> Refmap'.find r !m), clear
let mktable_modpath autoclean =
let m = ref MPmap.empty in
let clear () = m := MPmap.empty in
if autoclean then register_cleanup clear;
(fun r v -> m := MPmap.add r v !m), (fun r -> MPmap.find r !m), clear
(* A table recording objects in the first level of all MPfile *)
let add_mpfiles_content,get_mpfiles_content,clear_mpfiles_content =
mktable_modpath false
let get_mpfiles_content mp =
try get_mpfiles_content mp
with Not_found -> failwith "get_mpfiles_content"
(*s The list of external modules that will be opened initially *)
let mpfiles_add, mpfiles_mem, mpfiles_list, mpfiles_clear =
let m = ref MPset.empty in
let add mp = m:=MPset.add mp !m
and mem mp = MPset.mem mp !m
and list () = MPset.elements !m
and clear () = m:=MPset.empty
in
register_cleanup clear;
(add,mem,list,clear)
(*s List of module parameters that we should alpha-rename *)
let params_ren_add, params_ren_mem =
let m = ref MPset.empty in
let add mp = m:=MPset.add mp !m
and mem mp = MPset.mem mp !m
and clear () = m:=MPset.empty
in
register_cleanup clear;
(add,mem)
(*s table indicating the visible horizon at a precise moment,
i.e. the stack of structures we are inside.
- The sequence of [mp] parts should have the following form:
a [MPfile] at the beginning, and then more and more [MPdot]
over this [MPfile], or [MPbound] when inside the type of a
module parameter.
- the [params] are the [MPbound] when [mp] is a functor,
the innermost [MPbound] coming first in the list.
- The [content] part is used to record all the names already
seen at this level.
*)
type visible_layer = { mp : module_path;
params : module_path list;
mutable content : Label.t KMap.t; }
let pop_visible, push_visible, get_visible =
let vis = ref [] in
register_cleanup (fun () -> vis := []);
let pop () =
match !vis with
| [] -> assert false
| v :: vl ->
vis := vl;
(* we save the 1st-level-content of MPfile for later use *)
if get_phase () == Impl && modular () && is_modfile v.mp
then add_mpfiles_content v.mp v.content
and push mp mps =
vis := { mp = mp; params = mps; content = KMap.empty } :: !vis
and get () = !vis
in (pop,push,get)
let get_visible_mps () = List.map (function v -> v.mp) (get_visible ())
let top_visible () = match get_visible () with [] -> assert false | v::_ -> v
let top_visible_mp () = (top_visible ()).mp
let add_visible ks l =
let visible = top_visible () in
visible.content <- KMap.add ks l visible.content
(* table of local module wrappers used to provide non-ambiguous names *)
module DupOrd =
struct
type t = ModPath.t * Label.t
let compare (mp1, l1) (mp2, l2) =
let c = Label.compare l1 l2 in
if Int.equal c 0 then ModPath.compare mp1 mp2 else c
end
module DupMap = Map.Make(DupOrd)
let add_duplicate, get_duplicate =
let index = ref 0 and dups = ref DupMap.empty in
register_cleanup (fun () -> index := 0; dups := DupMap.empty);
let add mp l =
incr index;
let ren = "Coq__" ^ string_of_int !index in
dups := DupMap.add (mp,l) ren !dups
and get mp l =
try Some (DupMap.find (mp, l) !dups) with Not_found -> None
in (add,get)
type reset_kind = AllButExternal | Everything
let reset_renaming_tables flag =
do_cleanup ();
if flag == Everything then clear_mpfiles_content ()
(*S Renaming functions *)
(* This function creates from [id] a correct uppercase/lowercase identifier.
This is done by adding a [Coq_] or [coq_] prefix. To avoid potential clashes
with previous [Coq_id] variable, these prefixes are duplicated if already
existing. *)
let modular_rename k id =
let s = ascii_of_id id in
let prefix,is_ok = if upperkind k then "Coq_",is_upper else "coq_",is_lower
in
if not (is_ok s) || Id.Set.mem id (get_keywords ()) || begins_with s prefix
then prefix ^ s
else s
(*s For monolithic extraction, first-level modules might have to be renamed
with unique numbers *)
let modfstlev_rename =
let add_index,get_index,_ = mktable_id true in
fun l ->
let id = Label.to_id l in
try
let n = get_index id in
add_index id (n+1);
let s = if n == 0 then "" else string_of_int (n-1) in
"Coq"^s^"_"^(ascii_of_id id)
with Not_found ->
let s = ascii_of_id id in
if is_lower s || begins_with_CoqXX s then
(add_index id 1; "Coq_"^s)
else
(add_index id 0; s)
(*s Creating renaming for a [module_path] : first, the real function ... *)
let rec mp_renaming_fun mp = match mp with
| _ when not (modular ()) && at_toplevel mp -> [""]
| MPdot (mp,l) ->
let lmp = mp_renaming mp in
let mp = match lmp with
| [""] -> modfstlev_rename l
| _ -> modular_rename Mod (Label.to_id l)
in
mp ::lmp
| MPbound mbid ->
let s = modular_rename Mod (MBId.to_id mbid) in
if not (params_ren_mem mp) then [s]
else let i,_,_ = MBId.repr mbid in [s^"__"^string_of_int i]
| MPfile _ ->
assert (modular ()); (* see [at_toplevel] above *)
assert (get_phase () == Pre);
let current_mpfile = (List.last (get_visible ())).mp in
if not (ModPath.equal mp current_mpfile) then mpfiles_add mp;
[string_of_modfile mp]
(* ... and its version using a cache *)
and mp_renaming =
let add,get,_ = mktable_modpath true in
fun x ->
try if is_mp_bound (base_mp x) then raise Not_found; get x
with Not_found -> let y = mp_renaming_fun x in add x y; y
(*s Renamings creation for a [global_reference]: we build its fully-qualified
name in a [string list] form (head is the short name). *)
let ref_renaming_fun (k,r) =
let mp = modpath_of_r r in
let l = mp_renaming mp in
let l = if lang () != Ocaml && not (modular ()) then [""] else l in
let s =
let idg = safe_basename_of_global r in
match l with
| [""] -> (* this happens only at toplevel of the monolithic case *)
let globs = Id.Set.elements (get_global_ids ()) in
let id = next_ident_away (kindcase_id k idg) globs in
Id.to_string id
| _ -> modular_rename k idg
in
add_global_ids (Id.of_string s);
s::l
(* Cached version of the last function *)
let ref_renaming =
let add,get,_ = mktable_ref true in
fun ((k,r) as x) ->
try if is_mp_bound (base_mp (modpath_of_r r)) then raise Not_found; get r
with Not_found -> let y = ref_renaming_fun x in add r y; y
(* [visible_clash mp0 (k,s)] checks if [mp0-s] of kind [k]
can be printed as [s] in the current context of visible
modules. More precisely, we check if there exists a
visible [mp] that contains [s].
The verification stops if we encounter [mp=mp0]. *)
let rec clash mem mp0 ks = function
| [] -> false
| mp :: _ when ModPath.equal mp mp0 -> false
| mp :: _ when mem mp ks -> true
| _ :: mpl -> clash mem mp0 ks mpl
let mpfiles_clash mp0 ks =
clash (fun mp k -> KMap.mem k (get_mpfiles_content mp)) mp0 ks
(List.rev (mpfiles_list ()))
let rec params_lookup mp0 ks = function
| [] -> false
| param :: _ when ModPath.equal mp0 param -> true
| param :: params ->
let () = match ks with
| (Mod, mp) when String.equal (List.hd (mp_renaming param)) mp -> params_ren_add param
| _ -> ()
in
params_lookup mp0 ks params
let visible_clash mp0 ks =
let rec clash = function
| [] -> false
| v :: _ when ModPath.equal v.mp mp0 -> false
| v :: vis ->
let b = KMap.mem ks v.content in
if b && not (is_mp_bound mp0) then true
else begin
if b then params_ren_add mp0;
if params_lookup mp0 ks v.params then false
else clash vis
end
in clash (get_visible ())
(* Same, but with verbose output (and mp0 shouldn't be a MPbound) *)
let visible_clash_dbg mp0 ks =
let rec clash = function
| [] -> None
| v :: _ when ModPath.equal v.mp mp0 -> None
| v :: vis ->
try Some (v.mp,KMap.find ks v.content)
with Not_found ->
if params_lookup mp0 ks v.params then None
else clash vis
in clash (get_visible ())
(* After the 1st pass, we can decide which modules will be opened initially *)
let opened_libraries () =
if not (modular ()) then []
else
let used_files = mpfiles_list () in
let used_ks = List.map (fun mp -> Mod,string_of_modfile mp) used_files in
(* By default, we open all used files. Ambiguities will be resolved later
by using qualified names. Nonetheless, we don't open any file A that
contains an immediate submodule A.B hiding another file B : otherwise,
after such an open, there's no unambiguous way to refer to objects of B. *)
let to_open =
List.filter
(fun mp ->
not (List.exists (fun k -> KMap.mem k (get_mpfiles_content mp)) used_ks))
used_files
in
mpfiles_clear ();
List.iter mpfiles_add to_open;
mpfiles_list ()
(*s On-the-fly qualification issues for both monolithic or modular extraction. *)
(* [pp_ocaml_gen] below is a function that factorize the printing of both
[global_reference] and module names for ocaml. When [k=Mod] then [olab=None],
otherwise it contains the label of the reference to print.
[rls] is the string list giving the qualified name, short name at the end. *)
(* In Coq, we can qualify [M.t] even if we are inside [M], but in Ocaml we
cannot do that. So, if [t] gets hidden and we need a long name for it,
we duplicate the _definition_ of t in a Coq__XXX module, and similarly
for a sub-module [M.N] *)
let pp_duplicate k' prefix mp rls olab =
let rls', lbl =
if k' != Mod then
(* Here rls=[s], the ref to print is <prefix>.<s>, and olab<>None *)
rls, Option.get olab
else
(* Here rls=s::rls', we search the label for s inside mp *)
List.tl rls, get_nth_label_mp (mp_length mp - mp_length prefix) mp
in
match get_duplicate prefix lbl with
| Some ren -> dottify (ren :: rls')
| None ->
assert (get_phase () == Pre); (* otherwise it's too late *)
add_duplicate prefix lbl; dottify rls
let fstlev_ks k = function
| [] -> assert false
| [s] -> k,s
| s::_ -> Mod,s
(* [pp_ocaml_local] : [mp] has something in common with [top_visible ()]
but isn't equal to it *)
let pp_ocaml_local k prefix mp rls olab =
(* what is the largest prefix of [mp] that belongs to [visible]? *)
assert (k != Mod || not (ModPath.equal mp prefix)); (* mp as whole module isn't in itself *)
let rls' = List.skipn (mp_length prefix) rls in
let k's = fstlev_ks k rls' in
(* Reference r / module path mp is of the form [<prefix>.s.<...>]. *)
if not (visible_clash prefix k's) then dottify rls'
else pp_duplicate (fst k's) prefix mp rls' olab
(* [pp_ocaml_bound] : [mp] starts with a [MPbound], and we are not inside
(i.e. we are not printing the type of the module parameter) *)
let pp_ocaml_bound base rls =
(* clash with a MPbound will be detected and fixed by renaming this MPbound *)
if get_phase () == Pre then ignore (visible_clash base (Mod,List.hd rls));
dottify rls
(* [pp_ocaml_extern] : [mp] isn't local, it is defined in another [MPfile]. *)
let pp_ocaml_extern k base rls = match rls with
| [] -> assert false
| base_s :: rls' ->
if (not (modular ())) (* Pseudo qualification with "" *)
|| (List.is_empty rls') (* Case of a file A.v used as a module later *)
|| (not (mpfiles_mem base)) (* Module not opened *)
|| (mpfiles_clash base (fstlev_ks k rls')) (* Conflict in opened files *)
|| (visible_clash base (fstlev_ks k rls')) (* Local conflict *)
then
(* We need to fully qualify. Last clash situation is unsupported *)
match visible_clash_dbg base (Mod,base_s) with
| None -> dottify rls
| Some (mp,l) -> error_module_clash base (MPdot (mp,l))
else
(* Standard situation : object in an opened file *)
dottify rls'
(* [pp_ocaml_gen] : choosing between [pp_ocaml_local] or [pp_ocaml_extern] *)
let pp_ocaml_gen k mp rls olab =
match common_prefix_from_list mp (get_visible_mps ()) with
| Some prefix -> pp_ocaml_local k prefix mp rls olab
| None ->
let base = base_mp mp in
if is_mp_bound base then pp_ocaml_bound base rls
else pp_ocaml_extern k base rls
(* For Haskell, things are simplier: we have removed (almost) all structures *)
let pp_haskell_gen k mp rls = match rls with
| [] -> assert false
| s::rls' ->
let str = pseudo_qualify rls' in
let str = if is_upper str && not (upperkind k) then ("_"^str) else str in
if ModPath.equal (base_mp mp) (top_visible_mp ()) then str else s^"."^str
(* Main name printing function for a reference *)
let pp_global k r =
let ls = ref_renaming (k,r) in
assert (List.length ls > 1);
let s = List.hd ls in
let mp,_,l = repr_of_r r in
if ModPath.equal mp (top_visible_mp ()) then
(* simpliest situation: definition of r (or use in the same context) *)
(* we update the visible environment *)
(add_visible (k,s) l; unquote s)
else
let rls = List.rev ls in (* for what come next it's easier this way *)
match lang () with
| Scheme -> unquote s (* no modular Scheme extraction... *)
| JSON -> dottify (List.map unquote rls)
| Haskell -> if modular () then pp_haskell_gen k mp rls else s
| Ocaml -> pp_ocaml_gen k mp rls (Some l)
(* The next function is used only in Ocaml extraction...*)
let pp_module mp =
let ls = mp_renaming mp in
match mp with
| MPdot (mp0,l) when ModPath.equal mp0 (top_visible_mp ()) ->
(* simpliest situation: definition of mp (or use in the same context) *)
(* we update the visible environment *)
let s = List.hd ls in
add_visible (Mod,s) l; s
| _ -> pp_ocaml_gen Mod mp (List.rev ls) None
(** Special hack for constants of type Ascii.ascii : if an
[Extract Inductive ascii => char] has been declared, then
the constants are directly turned into chars *)
let mk_ind path s =
MutInd.make2 (MPfile (dirpath_of_string path)) (Label.make s)
let ind_ascii = mk_ind "Coq.Strings.Ascii" "ascii"
let check_extract_ascii () =
try
let char_type = match lang () with
| Ocaml -> "char"
| Haskell -> "Prelude.Char"
| _ -> raise Not_found
in
String.equal (find_custom (IndRef (ind_ascii, 0))) (char_type)
with Not_found -> false
let is_list_cons l =
List.for_all (function MLcons (_,ConstructRef(_,_),[]) -> true | _ -> false) l
let is_native_char = function
| MLcons(_,ConstructRef ((kn,0),1),l) ->
MutInd.equal kn ind_ascii && check_extract_ascii () && is_list_cons l
| _ -> false
let get_native_char c =
let rec cumul = function
| [] -> 0
| MLcons(_,ConstructRef(_,j),[])::l -> (2-j) + 2 * (cumul l)
| _ -> assert false
in
let l = match c with MLcons(_,_,l) -> l | _ -> assert false in
Char.chr (cumul l)
let pp_native_char c = str ("'"^Char.escaped (get_native_char c)^"'")
|