(***********************************************************************) (* *) (* Objective Caml *) (* *) (* Xavier Leroy and Jerome Vouillon, projet Cristal, INRIA Rocquencourt*) (* *) (* Copyright 1996 Institut National de Recherche en Informatique et *) (* Automatique. Distributed only by permission. *) (* *) (***********************************************************************) (* $Id$ *) (* Printing functions *) open Misc open Ctype open Format open Longident open Path open Asttypes open Types (* Print a long identifier *) let rec longident = function Lident s -> print_string s | Ldot(p, s) -> longident p; print_string "."; print_string s | Lapply(p1, p2) -> longident p1; print_string "("; longident p2; print_string ")" (* Print an identifier *) let ident id = print_string(Ident.name id) (* Print a path *) let ident_pervasive = Ident.create_persistent "Pervasives" let rec path = function Pident id -> ident id | Pdot(Pident id, s, pos) when Ident.same id ident_pervasive -> print_string s | Pdot(p, s, pos) -> path p; print_string "."; print_string s | Papply(p1, p2) -> path p1; print_string "("; path p2; print_string ")" (* Print a type expression *) let names = ref ([] : (type_expr * string) list) let name_counter = ref 0 let reset_names () = names := []; name_counter := 0 let new_name () = let name = if !name_counter < 26 then String.make 1 (Char.chr(97 + !name_counter)) else String.make 1 (Char.chr(97 + !name_counter mod 26)) ^ string_of_int(!name_counter / 26) in incr name_counter; name let name_of_type t = try List.assq t !names with Not_found -> let name = new_name () in names := (t, name) :: !names; name let rec list_removeq a = function [] -> [] | (b, _) as e::l -> if a == b then l else e::list_removeq a l let remove_name_of_type t = names := list_removeq t !names let visited_objects = ref ([] : type_expr list) let aliased = ref ([] : type_expr list) let rec mark_loops_rec visited ty = let ty = repr ty in match ty.desc with Tvar -> () | Tarrow(ty1, ty2) -> mark_loops_rec visited ty1; mark_loops_rec visited ty2 | Ttuple tyl -> List.iter (mark_loops_rec visited) tyl | Tconstr(_, tyl, _) -> if List.memq ty visited then begin if not (List.memq ty !aliased) then aliased := ty :: !aliased end else List.iter (mark_loops_rec (ty::visited)) tyl | Tobject (fi, nm) -> if List.memq ty !visited_objects or List.memq ty visited then begin if not (List.memq ty !aliased) then aliased := ty :: !aliased end else begin if opened_object ty then visited_objects := ty :: !visited_objects; let name = match !nm with None -> None | Some (n, v::l) -> let v' = repr v in begin match v'.desc with Tvar -> Some (n, v'::l) | _ -> None end | _ -> fatal_error "Printtyp.mark_loops_rec" in nm := name; begin match !nm with None -> mark_loops_rec (ty::visited) fi | Some (_, l) -> List.iter (mark_loops_rec (ty::visited)) l end end | Tfield(_, ty1, ty2) -> mark_loops_rec visited ty1; mark_loops_rec visited ty2 | Tnil -> () | Tlink _ -> fatal_error "Printtyp.mark_loops_rec (2)" let mark_loops ty = mark_loops_rec [] ty let reset_loop_marks () = visited_objects := []; aliased := [] let reset () = reset_names (); reset_loop_marks () let rec typexp sch prio ty = let ty = repr ty in match ty.desc with Tvar -> if (not sch) or ty.level = generic_level then print_string "'" else print_string "'_"; print_string(name_of_type ty) | Tarrow(ty1, ty2) -> if prio >= 1 then begin open_hovbox 1; print_string "(" end else open_hovbox 0; typexp sch 1 ty1; print_string " ->"; print_space(); typexp sch 0 ty2; if prio >= 1 then print_string ")"; close_box() | Ttuple tyl -> if prio >= 2 then begin open_hovbox 1; print_string "(" end else open_hovbox 0; typlist sch 2 " *" tyl; if prio >= 2 then print_string ")"; close_box() | Tconstr(p, tyl, _) -> open_hovbox 0; begin try List.assq ty !names; print_string "'"; print_string (name_of_type ty) with Not_found -> if List.memq ty !aliased then begin name_of_type ty; if prio >= 1 then begin open_hovbox 1; print_string "(" end end; open_hovbox 0; begin match tyl with [] -> () | [ty1] -> typexp sch 2 ty1; print_space() | tyl -> open_hovbox 1; print_string "("; typlist sch 0 "," tyl; print_string ")"; close_box(); print_space() end; path p; close_box(); if List.memq ty !aliased then begin print_string " as "; print_string "'"; print_string (name_of_type ty); remove_name_of_type ty; if prio >= 1 then begin print_string ")"; close_box () end end end; close_box() | Tobject (fi, nm) -> typobject sch prio ty fi nm | _ -> fatal_error "Printtyp.typexp" and typlist sch prio sep = function [] -> () | [ty] -> typexp sch prio ty | ty::tyl -> typexp sch prio ty; print_string sep; print_space(); typlist sch prio sep tyl and typobject sch prio ty fi nm = try List.assq ty !names; print_string "'"; print_string (name_of_type ty) with Not_found -> if List.memq ty !aliased then begin name_of_type ty; if prio >= 1 then begin open_hovbox 1; print_string "(" end end; begin match !nm with None -> open_hovbox 2; print_string "< "; (let (fields, rest) = flatten_fields fi in typfields sch rest fields); print_string " >"; close_box () | Some (p, {desc = Tvar}::tyl) -> open_hovbox 0; begin match tyl with [] -> () | [ty1] -> typexp sch 2 ty1; print_space() | tyl -> open_hovbox 1; print_string "("; typlist sch 0 "," tyl; print_string ")"; close_box(); print_space() end; if sch & ty.level <> generic_level then print_string "_"; print_string "#"; path p; close_box() | _ -> fatal_error "Printtyp.typobject" end; if List.memq ty !aliased then begin print_string " as "; print_string "'"; print_string (name_of_type ty); if not (opened_object ty) then remove_name_of_type ty; if prio >= 1 then begin print_string ")"; close_box () end end and typfields sch rest = function [] -> begin match rest.desc with Tvar -> if sch & rest.level <> generic_level then print_string "_"; print_string ".." | Tnil -> () | _ -> fatal_error "typfields (1)" end | [(s, t)] -> print_string s; print_string " : "; typexp sch 0 t; begin match rest.desc with Tvar -> print_string ";"; print_space () | Tnil -> () | _ -> fatal_error "typfields (2)" end; typfields sch rest [] | (s, t)::l -> print_string s; print_string " : "; typexp sch 0 t; print_string ";"; print_space (); typfields sch rest l let type_expr ty = typexp false 0 ty and type_sch ty = typexp true 0 ty and type_scheme ty = reset(); mark_loops ty; typexp true 0 ty (* Print one type declaration *) let rec type_declaration id decl = reset(); open_hvbox 2; print_string "type "; type_expr {desc = Tconstr(Pident id, decl.type_params, ref []); level = generic_level}; begin match decl.type_manifest with None -> () | Some ty -> print_string " ="; print_space(); mark_loops ty; type_expr ty end; begin match decl.type_kind with Type_abstract -> () | Type_variant [] -> () (* A fatal error actually, except when printing type exn... *) | Type_variant (cstr1 :: cstrs as cstrs0) -> List.iter (fun (_, args) -> List.iter mark_loops args) cstrs0; print_string " ="; print_break 1 2; constructor cstr1; List.iter (fun cstr -> print_space(); print_string "| "; constructor cstr) cstrs | Type_record (lbl1 :: lbls as l) -> List.iter (fun (_, _, ty) -> mark_loops ty) l; print_string " ="; print_space(); print_string "{ "; label lbl1; List.iter (fun lbl -> print_string ";"; print_break 1 2; label lbl) lbls; print_string " }" end; close_box() and constructor (name, args) = print_string name; match args with [] -> () | _ -> print_string " of "; open_hovbox 2; typlist false 2 " *" args; close_box() and label (name, mut, arg) = begin match mut with Immutable -> () | Mutable -> print_string "mutable " end; print_string name; print_string ": "; type_expr arg (* Print an exception declaration *) let exception_declaration id decl = print_string "exception "; constructor (Ident.name id, decl) (* Print a value declaration *) let value_description id decl = open_hovbox 2; print_string "val "; ident id; print_string " :"; print_space(); type_scheme decl.val_type; begin match decl.val_kind with Val_prim p -> print_space(); print_string "= "; Primitive.print_description p | _ -> () end; close_box() (* Print a class type *) let class_arg arg = print_space (); open_hovbox 1; print_string "("; type_sch arg; print_string ")"; close_box () let constrain (v, ty) = print_space (); open_hovbox 2; print_string "constraint "; type_sch v; print_string " ="; print_space(); type_sch ty; close_box() let class_var l (m, t) = print_space (); open_hovbox 2; print_string "val "; begin match m with Immutable -> () | Mutable -> print_string "mutable " end; print_string l; print_string " :"; print_space(); type_sch t; close_box() let metho kind (l, t) = print_space (); open_hovbox 2; print_string kind; print_string l; print_string " :"; print_space(); type_sch t; close_box() let methods_of_type ty = match (repr ty).desc with Tobject (m, _) -> m | _ -> fatal_error "Printtyp.methods_of_type" let rec list_meths ty = match (repr ty).desc with Tfield(lab, ty, ty') -> (lab, ty) :: (list_meths ty') | _ -> [] let class_type id cl_ty = begin_def (); let (cstr, args, vars, self) = Ctype.prune_class_type cl_ty in end_def (); List.iter (fun (v, c) -> generalize v; generalize c) cstr; List.iter generalize args; Vars.iter (fun l (m, t) -> generalize t) vars; generalize self; let self = repr self in let params = List.map fst cstr in let cstr = List.fold_right (fun ((v, ty) as c) l -> if v == ty then l else c::l) cstr [] in reset (); (* Self may have a name *) visited_objects := self :: !visited_objects; begin match self.desc with Tobject (fi, _) -> mark_loops fi | _ -> fatal_error "Printtyp.class_type" end; List.iter mark_loops args; List.iter (fun (_, ty) -> mark_loops ty) cstr; Vars.iter (fun _ (_, ty) -> mark_loops ty) vars; open_hvbox 2; open_hovbox 0; print_string "class "; if cl_ty.cty_new = None then print_string "virtual "; if not (opened_object self) then print_string "closed "; type_sch {desc = Tconstr(Pident id, params, ref []); level = 0}; if List.memq self !aliased then (name_of_type self; ()); List.iter class_arg args; if List.memq self !aliased then begin print_string " : "; print_string "'"; print_string (name_of_type self) end; print_string " ="; close_box (); List.iter constrain cstr; Vars.iter class_var vars; let meths = list_meths (methods_of_type self) in let (meths, virt) = List.fold_right (fun ((lab, ty) as m) (ml, vl) -> if Concr.mem lab cl_ty.cty_concr then (m::ml, vl) else (ml, m::vl)) meths ([], []) in List.iter (metho "method ") meths; List.iter (metho "virtual ") virt; print_break 1 (-2); print_string "end"; close_box() (* Print a module type *) let rec modtype = function Tmty_ident p -> path p | Tmty_signature sg -> open_hvbox 2; print_string "sig"; signature_body true sg; print_break 1 (-2); print_string "end"; close_box() | Tmty_functor(param, ty_arg, ty_res) -> open_hovbox 2; print_string "functor"; print_cut(); print_string "("; ident param; print_string " : "; modtype ty_arg; print_string ") ->"; print_space(); modtype ty_res; close_box() and signature_body spc = function [] -> () | item :: rem -> if spc then print_space(); let cont = match item with Tsig_value(id, decl) -> value_description id decl; rem | Tsig_type(id, decl) -> type_declaration id decl; rem | Tsig_exception(id, decl) -> exception_declaration id decl; rem | Tsig_module(id, mty) -> open_hovbox 2; print_string "module "; ident id; print_string " :"; print_space(); modtype mty; close_box(); rem | Tsig_modtype(id, decl) -> modtype_declaration id decl; rem | Tsig_class(id, decl) -> class_type id decl; match rem with tydecl1 :: tydecl2 :: rem -> rem | _ -> [] in signature_body true cont and modtype_declaration id decl = open_hovbox 2; print_string "module type "; ident id; begin match decl with Tmodtype_abstract -> () | Tmodtype_manifest mty -> print_string " ="; print_space(); modtype mty end; close_box() (* Print a signature body (used when compiling a .mli and printing results in interactive use). *) let signature sg = open_vbox 0; signature_body false sg; close_box() (* Print an unification error *) let type_expansion t t' = if t == t' then type_expr t else begin open_hovbox 2; type_expr t; print_space (); print_string "="; print_space (); type_expr t'; close_box () end let rec trace fst txt = function (t1, t1')::(t2, t2')::rem -> if not fst then print_cut (); open_box 0; print_string "Type"; print_break 1 2; type_expansion t1 t1'; print_space (); txt (); print_break 1 2; type_expansion t2 t2'; close_box (); trace false txt rem | _ -> () let unification_error tr txt1 txt2 = reset (); List.iter (function (t, t') -> mark_loops t; if t != t' then mark_loops t') tr; open_box 0; let (t1, t1') = List.hd tr in let (t2, t2') = List.hd (List.tl tr) in txt1 (); print_break 1 2; type_expansion t1 t1'; print_space(); txt2 (); print_break 1 2; type_expansion t2 t2'; close_box(); trace false (fun _ -> print_string "is not compatible with type") (List.tl (List.tl tr))