%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 1998-2010. All Rights Reserved.
%%
%% The contents of this file are subject to the Erlang Public License,
%% Version 1.1, (the "License"); you may not use this file except in
%% compliance with the License. You should have received a copy of the
%% Erlang Public License along with this software. If not, it can be
%% retrieved online at http://www.erlang.org/.
%%
%% Software distributed under the License is distributed on an "AS IS"
%% basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
%% the License for the specific language governing rights and limitations
%% under the License.
%%
%% %CopyrightEnd%
%%
-module(dbg_iload).
-export([load_mod/4]).
%%====================================================================
%% External exports
%%====================================================================
%%--------------------------------------------------------------------
%% load_mod(Mod, File, Binary, Db) -> {ok, Mod}
%% Mod = module()
%% File = string() Source file (including path)
%% Binary = binary()
%% Db = ETS identifier
%% Load a new module into the database.
%%
%% We want the loading of a module to be synchronous so that no other
%% process tries to interpret code in a module not being completely
%% loaded. This is achieved as this function is called from
%% dbg_iserver. We are suspended until the module has been loaded.
%%--------------------------------------------------------------------
-spec load_mod(Mod, file:filename(), binary(), ets:tid()) ->
{'ok', Mod} when is_subtype(Mod, atom()).
load_mod(Mod, File, Binary, Db) ->
Flag = process_flag(trap_exit, true),
Pid = spawn_link(fun () -> load_mod1(Mod, File, Binary, Db) end),
receive
{'EXIT', Pid, What} ->
process_flag(trap_exit, Flag),
What
end.
-spec load_mod1(atom(), file:filename(), binary(), ets:tid()) -> no_return().
load_mod1(Mod, File, Binary, Db) ->
store_module(Mod, File, Binary, Db),
exit({ok, Mod}).
%%====================================================================
%% Internal functions
%%====================================================================
store_module(Mod, File, Binary, Db) ->
{interpreter_module, Exp, Abst, Src, MD5} = binary_to_term(Binary),
Forms = case abstr(Abst) of
{abstract_v1,Forms0} -> Forms0;
{abstract_v2,Forms0} -> Forms0;
{raw_abstract_v1,Code0} ->
Code = interpret_file_attribute(Code0),
{_,_,Forms0,_} = sys_pre_expand:module(Code, []),
Forms0
end,
dbg_idb:insert(Db, mod_file, File),
dbg_idb:insert(Db, exports, Exp),
dbg_idb:insert(Db, defs, []),
put(vcount, 0),
put(fun_count, 0),
put(funs, []),
put(mod_md5, MD5),
Attr = store_forms(Forms, Mod, Db, Exp, []),
erase(mod_md5),
erase(current_function),
%% store_funs(Db, Mod),
erase(vcount),
erase(funs),
erase(fun_count),
dbg_idb:insert(Db, attributes, Attr),
NewBinary = store_mod_line_no(Mod, Db, binary_to_list(Src)),
dbg_idb:insert(Db, mod_bin, NewBinary),
dbg_idb:insert(Db, mod_raw, <<Src/binary,0:8>>), %% Add eos
dbg_idb:insert(Db, module, Mod).
%% Adjust line numbers using the file/2 attribute.
%% Also take the absolute value of line numbers.
%% This simple fix will make the marker point at the correct line
%% (assuming the file attributes are correct) in the source; it will
%% not point at code in included files.
interpret_file_attribute(Code) ->
epp:interpret_file_attribute(Code).
abstr(Bin) when is_binary(Bin) -> binary_to_term(Bin);
abstr(Term) -> Term.
% store_funs(Db, Mod) ->
% store_funs_1(get(funs), Db, Mod).
% store_funs_1([{Name,Index,Uniq,_,_,Arity,Cs}|Fs], Db, Mod) ->
% dbg_idb:insert(Db, {Mod,Name,Arity,false}, Cs),
% dbg_idb:insert(Db, {'fun',Mod,Index,Uniq}, {Name,Arity,Cs}),
% store_funs_1(Fs, Db, Mod);
% store_funs_1([], _, _) -> ok.
store_forms([{function,_,module_info,0,_}|Fs], Mod, Db, Exp, Attr) ->
Cs = [{clause,0,[],[], [{module_info_0,0,Mod}]}],
dbg_idb:insert(Db, {Mod,module_info,0,true}, Cs),
store_forms(Fs, Mod, Db, Exp, Attr);
store_forms([{function,_,module_info,1,_}|Fs], Mod, Db, Exp, Attr) ->
Cs = [{clause,0,[{var,0,'What'}],[], [{module_info_1,0,Mod,[{var,0,'What'}]}]}],
dbg_idb:insert(Db, {Mod,module_info,1,true}, Cs),
store_forms(Fs, Mod, Db, Exp, Attr);
store_forms([{function,_,Name,Arity,Cs0}|Fs], Mod, Db, Exp, Attr) ->
FA = {Name,Arity},
put(current_function, FA),
Cs = clauses(Cs0),
Exported = lists:member(FA, Exp),
dbg_idb:insert(Db, {Mod,Name,Arity,Exported}, Cs),
store_forms(Fs, Mod, Db, Exp, Attr);
store_forms([{attribute,_,Name,Val}|Fs], Mod, Db, Exp, Attr) ->
store_forms(Fs, Mod, Db, Exp, [{Name,Val}|Attr]);
store_forms([F|_], _Mod, _Db, _Exp, _Attr) ->
exit({unknown_form,F});
store_forms([], _, _, _, Attr) ->
lists:reverse(Attr).
store_mod_line_no(Mod, Db, Contents) ->
store_mod_line_no(Mod, Db, Contents, 1, 0, []).
store_mod_line_no(_, _, [], _, _, NewCont) ->
list_to_binary(lists:reverse(NewCont));
store_mod_line_no(Mod, Db, Contents, LineNo, Pos, NewCont) when is_integer(LineNo) ->
{ContTail,Pos1,NewCont1} = store_line(Mod, Db, Contents, LineNo, Pos, NewCont),
store_mod_line_no(Mod, Db, ContTail, LineNo+1, Pos1, NewCont1).
store_line(_, Db, Contents, LineNo, Pos, NewCont) ->
{ContHead,ContTail,PosNL} = get_nl(Contents,Pos+8,[]),
dbg_idb:insert(Db,LineNo,{Pos+8,PosNL}),
{ContTail,PosNL+1,[make_lineno(LineNo, 8, ContHead)|NewCont]}.
make_lineno(N, P, Acc) ->
S = integer_to_list(N),
S ++ [$:|spaces(P-length(S)-1, Acc)].
spaces(P, Acc) when P > 0 ->
spaces(P-1, [$\s|Acc]);
spaces(_, Acc) -> Acc.
get_nl([10|T],Pos,Head) -> {lists:reverse([10|Head]),T,Pos};
get_nl([H|T],Pos,Head) ->
get_nl(T,Pos+1,[H|Head]);
get_nl([],Pos,Head) -> {lists:reverse(Head),[],Pos}.
%%% Rewrite the abstract syntax tree to that it will be easier (== faster)
%%% to interpret.
clauses([C0|Cs]) ->
C1 = clause(C0),
[C1|clauses(Cs)];
clauses([]) -> [].
clause({clause,Line,H0,G0,B0}) ->
H1 = head(H0),
G1 = guard(G0),
B1 = exprs(B0),
{clause,Line,H1,G1,B1}.
head(Ps) -> patterns(Ps).
%% These patterns are processed "sequentially" for purposes of variable
%% definition etc.
patterns([P0|Ps]) ->
P1 = pattern(P0),
[P1|patterns(Ps)];
patterns([]) -> [].
%% N.B. Only valid patterns are included here.
pattern({var,Line,V}) -> {var,Line,V};
pattern({char,Line,I}) -> {value,Line,I};
pattern({integer,Line,I}) -> {value,Line,I};
pattern({match,Line,Pat1,Pat2}) ->
{match,Line,pattern(Pat1),pattern(Pat2)};
pattern({float,Line,F}) -> {value,Line,F};
pattern({atom,Line,A}) -> {value,Line,A};
pattern({string,Line,S}) -> {value,Line,S};
pattern({nil,Line}) -> {value,Line,[]};
pattern({cons,Line,H0,T0}) ->
H1 = pattern(H0),
T1 = pattern(T0),
{cons,Line,H1,T1};
pattern({tuple,Line,Ps0}) ->
Ps1 = pattern_list(Ps0),
{tuple,Line,Ps1};
pattern({op,_,'-',{integer,Line,I}}) ->
{value,Line,-I};
pattern({op,_,'+',{integer,Line,I}}) ->
{value,Line,I};
pattern({op,_,'-',{char,Line,I}}) ->
{value,Line,-I};
pattern({op,_,'+',{char,Line,I}}) ->
{value,Line,I};
pattern({op,_,'-',{float,Line,I}}) ->
{value,Line,-I};
pattern({op,_,'+',{float,Line,I}}) ->
{value,Line,I};
pattern({bin,Line,Grp}) ->
Grp1 = pattern_list(Grp),
{bin,Line,Grp1};
pattern({bin_element,Line,Expr,Size,Type}) ->
Expr1 = pattern(Expr),
Size1 = expr(Size),
{bin_element,Line,Expr1,Size1,Type}.
%% These patterns are processed "in parallel" for purposes of variable
%% definition etc.
pattern_list([P0|Ps]) ->
P1 = pattern(P0),
[P1|pattern_list(Ps)];
pattern_list([]) -> [].
guard([G0|Gs]) ->
G1 = and_guard(G0),
[G1|guard(Gs)];
guard([]) -> [].
and_guard([{atom,_,true}|Gs]) ->
and_guard(Gs);
and_guard([G0|Gs]) ->
G1 = guard_test(G0),
[G1|and_guard(Gs)];
and_guard([]) -> [].
guard_test({call,Line,{remote,_,{atom,_,erlang},{atom,_,F}},As0}) ->
As = gexpr_list(As0),
case map_guard_bif(F, length(As0)) of
{ok,Name} ->
{safe_bif,Line,erlang,Name,As};
error ->
{safe_bif,Line,erlang,F,As}
end;
guard_test({op,Line,Op,L0}) ->
true = erl_internal:arith_op(Op, 1) orelse %Assertion.
erl_internal:bool_op(Op, 1),
L1 = gexpr(L0),
{safe_bif,Line,erlang,Op,[L1]};
guard_test({op,Line,Op,L0,R0}) when Op =:= 'andalso'; Op =:= 'orelse' ->
L1 = gexpr(L0),
R1 = gexpr(R0), %They see the same variables
{Op,Line,L1,R1};
guard_test({op,Line,Op,L0,R0}) ->
true = erl_internal:comp_op(Op, 2) orelse %Assertion.
erl_internal:bool_op(Op, 2) orelse
erl_internal:arith_op(Op, 2),
L1 = gexpr(L0),
R1 = gexpr(R0), %They see the same variables
{safe_bif,Line,erlang,Op,[L1,R1]};
guard_test({integer,_,_}=I) -> I;
guard_test({char,_,_}=C) -> C;
guard_test({float,_,_}=F) -> F;
guard_test({atom,_,_}=A) -> A;
guard_test({nil,_}=N) -> N;
guard_test({var,_,_}=V) ->V. % Boolean var
map_guard_bif(integer, 1) -> {ok,is_integer};
map_guard_bif(float, 1) -> {ok,is_float};
map_guard_bif(number, 1) -> {ok,is_number};
map_guard_bif(atom, 1) -> {ok,is_atom};
map_guard_bif(list, 1) -> {ok,is_list};
map_guard_bif(tuple, 1) -> {ok,is_tuple};
map_guard_bif(pid, 1) -> {ok,is_pid};
map_guard_bif(reference, 1) -> {ok,is_reference};
map_guard_bif(port, 1) -> {ok,is_port};
map_guard_bif(binary, 1) -> {ok,is_binary};
map_guard_bif(function, 1) -> {ok,is_function};
map_guard_bif(_, _) -> error.
gexpr({var,Line,V}) -> {var,Line,V};
gexpr({integer,Line,I}) -> {value,Line,I};
gexpr({char,Line,I}) -> {value,Line,I};
gexpr({float,Line,F}) -> {value,Line,F};
gexpr({atom,Line,A}) -> {value,Line,A};
gexpr({string,Line,S}) -> {value,Line,S};
gexpr({nil,Line}) -> {value,Line,[]};
gexpr({cons,Line,H0,T0}) ->
case {gexpr(H0),gexpr(T0)} of
{{value,Line,H1},{value,Line,T1}} -> {value,Line,[H1|T1]};
{H1,T1} -> {cons,Line,H1,T1}
end;
gexpr({tuple,Line,Es0}) ->
Es1 = gexpr_list(Es0),
{tuple,Line,Es1};
gexpr({bin,Line,Flds0}) ->
Flds = gexpr_list(Flds0),
{bin,Line,Flds};
gexpr({bin_element,Line,Expr0,Size0,Type}) ->
Expr = gexpr(Expr0),
Size = gexpr(Size0),
{bin_element,Line,Expr,Size,Type};
%%% The previous passes have added the module name 'erlang' to
%%% all BIF calls, even in guards.
gexpr({call,Line,{remote,_,{atom,_,erlang},{atom,_,self}},[]}) ->
{dbg, Line, self, []};
gexpr({call,Line,{remote,_,{atom,_,erlang},{atom,_,F}},As0}) ->
As = gexpr_list(As0),
{safe_bif,Line,erlang,F,As};
gexpr({op,Line,Op,A0}) ->
erl_internal:arith_op(Op, 1),
A1 = gexpr(A0),
{safe_bif,Line,erlang,Op,[A1]};
gexpr({op,Line,Op,L0,R0}) when Op =:= 'andalso'; Op =:= 'orelse' ->
L1 = gexpr(L0),
R1 = gexpr(R0), %They see the same variables
{Op,Line,L1,R1};
gexpr({op,Line,Op,L0,R0}) ->
true = erl_internal:arith_op(Op, 2) orelse erl_internal:comp_op(Op, 2)
orelse erl_internal:bool_op(Op, 2),
L1 = gexpr(L0),
R1 = gexpr(R0), %They see the same variables
{safe_bif,Line,erlang,Op,[L1,R1]}.
%% These expressions are processed "in parallel" for purposes of variable
%% definition etc.
gexpr_list([E0|Es]) ->
E1 = gexpr(E0),
[E1|gexpr_list(Es)];
gexpr_list([]) -> [].
%% These expressions are processed "sequentially" for purposes of variable
%% definition etc.
exprs([E0|Es]) ->
E1 = expr(E0),
[E1|exprs(Es)];
exprs([]) -> [].
expr({var,Line,V}) -> {var,Line,V};
expr({integer,Line,I}) -> {value,Line,I};
expr({char,Line,I}) -> {value,Line,I};
expr({float,Line,F}) -> {value,Line,F};
expr({atom,Line,A}) -> {value,Line,A};
expr({string,Line,S}) -> {value,Line,S};
expr({nil,Line}) -> {value,Line,[]};
expr({cons,Line,H0,T0}) ->
case {expr(H0),expr(T0)} of
{{value,Line,H1},{value,Line,T1}} -> {value,Line,[H1|T1]};
{H1,T1} -> {cons,Line,H1,T1}
end;
expr({tuple,Line,Es0}) ->
Es1 = expr_list(Es0),
{tuple,Line,Es1};
expr({block,Line,Es0}) ->
%% Unfold block into a sequence.
Es1 = exprs(Es0),
{block,Line,Es1};
expr({'if',Line,Cs0}) ->
Cs1 = icr_clauses(Cs0),
{'if',Line,Cs1};
expr({'case',Line,E0,Cs0}) ->
E1 = expr(E0),
Cs1 = icr_clauses(Cs0),
{'case',Line,E1,Cs1};
expr({'receive',Line,Cs0}) ->
Cs1 = icr_clauses(Cs0),
{'receive',Line,Cs1};
expr({'receive',Line,Cs0,To0,ToEs0}) ->
To1 = expr(To0),
ToEs1 = exprs(ToEs0),
Cs1 = icr_clauses(Cs0),
{'receive',Line,Cs1,To1,ToEs1};
expr({'fun',Line,{clauses,Cs0},{_,_,Name}}) when is_atom(Name) ->
%% New R10B-2 format (abstract_v2).
Cs = fun_clauses(Cs0),
{make_fun,Line,Name,Cs};
expr({'fun',Line,{clauses,Cs0},{_,_,_,_,Name}}) when is_atom(Name) ->
%% New R8 format (abstract_v2).
Cs = fun_clauses(Cs0),
{make_fun,Line,Name,Cs};
expr({'fun',Line,{function,F,A},{_Index,_OldUniq,Name}}) ->
%% New R8 format (abstract_v2).
As = new_vars(A, Line),
Cs = [{clause,Line,As,[],[{local_call,Line,F,As}]}],
{make_fun,Line,Name,Cs};
expr({'fun',_,{clauses,_},{_OldUniq,_Hvss,_Free}}) ->
%% Old format (abstract_v1).
exit({?MODULE,old_funs});
expr({call,Line,{remote,_,{atom,_,erlang},{atom,_,self}},[]}) ->
{dbg,Line,self,[]};
expr({call,Line,{remote,_,{atom,_,erlang},{atom,_,get_stacktrace}},[]}) ->
{dbg,Line,get_stacktrace,[]};
expr({call,Line,{remote,_,{atom,_,erlang},{atom,_,throw}},[_]=As}) ->
{dbg,Line,throw,expr_list(As)};
expr({call,Line,{remote,_,{atom,_,erlang},{atom,_,error}},[_]=As}) ->
{dbg,Line,error,expr_list(As)};
expr({call,Line,{remote,_,{atom,_,erlang},{atom,_,exit}},[_]=As}) ->
{dbg,Line,exit,expr_list(As)};
expr({call,Line,{remote,_,{atom,_,erlang},{atom,_,apply}},[_,_,_]=As0}) ->
As = expr_list(As0),
{apply,Line,As};
expr({call,Line,{remote,_,{atom,_,Mod},{atom,_,Func}},As0}) ->
As = expr_list(As0),
case erlang:is_builtin(Mod, Func, length(As)) of
false ->
{call_remote,Line,Mod,Func,As};
true ->
case bif_type(Mod, Func, length(As0)) of
safe -> {safe_bif,Line,Mod,Func,As};
spawn -> {spawn_bif,Line,Mod,Func,As};
unsafe ->{bif,Line,Mod,Func,As}
end
end;
expr({call,Line,{remote,_,Mod0,Func0},As0}) ->
%% New R8 format (abstract_v2).
Mod = expr(Mod0),
Func = expr(Func0),
As = consify(expr_list(As0)),
{apply,Line,[Mod,Func,As]};
expr({call,Line,{atom,_,Func},As0}) ->
As = expr_list(As0),
{local_call,Line,Func,As};
expr({call,Line,Fun0,As0}) ->
Fun = expr(Fun0),
As = expr_list(As0),
{apply_fun,Line,Fun,As};
expr({'catch',Line,E0}) ->
%% No new variables added.
E1 = expr(E0),
{'catch',Line,E1};
expr({'try',Line,Es0,CaseCs0,CatchCs0,As0}) ->
%% No new variables added.
Es = expr_list(Es0),
CaseCs = icr_clauses(CaseCs0),
CatchCs = icr_clauses(CatchCs0),
As = expr_list(As0),
{'try',Line,Es,CaseCs,CatchCs,As};
expr({'query', Line, E0}) ->
E = expr(E0),
{'query', Line, E};
expr({lc,Line,E0,Gs0}) -> %R8.
Gs = lists:map(fun ({generate,L,P0,Qs}) ->
{generate,L,expr(P0),expr(Qs)};
({b_generate,L,P0,Qs}) -> %R12.
{b_generate,L,expr(P0),expr(Qs)};
(Expr) ->
case is_guard_test(Expr) of
true -> {guard,[[guard_test(Expr)]]};
false -> expr(Expr)
end
end, Gs0),
{lc,Line,expr(E0),Gs};
expr({bc,Line,E0,Gs0}) -> %R12.
Gs = lists:map(fun ({generate,L,P0,Qs}) ->
{generate,L,expr(P0),expr(Qs)};
({b_generate,L,P0,Qs}) -> %R12.
{b_generate,L,expr(P0),expr(Qs)};
(Expr) ->
case is_guard_test(Expr) of
true -> {guard,[[guard_test(Expr)]]};
false -> expr(Expr)
end
end, Gs0),
{bc,Line,expr(E0),Gs};
expr({match,Line,P0,E0}) ->
E1 = expr(E0),
P1 = pattern(P0),
{match,Line,P1,E1};
expr({op,Line,Op,A0}) ->
A1 = expr(A0),
{op,Line,Op,[A1]};
expr({op,Line,'++',L0,R0}) ->
L1 = expr(L0),
R1 = expr(R0), %They see the same variables
{op,Line,append,[L1,R1]};
expr({op,Line,'--',L0,R0}) ->
L1 = expr(L0),
R1 = expr(R0), %They see the same variables
{op,Line,subtract,[L1,R1]};
expr({op,Line,'!',L0,R0}) ->
L1 = expr(L0),
R1 = expr(R0), %They see the same variables
{send,Line,L1,R1};
expr({op,Line,Op,L0,R0}) when Op =:= 'andalso'; Op =:= 'orelse' ->
L1 = expr(L0),
R1 = expr(R0), %They see the same variables
{Op,Line,L1,R1};
expr({op,Line,Op,L0,R0}) ->
L1 = expr(L0),
R1 = expr(R0), %They see the same variables
{op,Line,Op,[L1,R1]};
expr({bin,Line,Grp}) ->
Grp1 = expr_list(Grp),
{bin,Line,Grp1};
expr({bin_element,Line,Expr,Size,Type}) ->
Expr1 = expr(Expr),
Size1 = expr(Size),
{bin_element,Line,Expr1,Size1,Type};
expr(Other) ->
exit({?MODULE,{unknown_expr,Other}}).
%% is_guard_test(Expression) -> true | false.
%% Test if a general expression is a guard test. Cannot use erl_lint
%% here as sys_pre_expand has transformed source.
is_guard_test({op,_,Op,L,R}) ->
erl_internal:comp_op(Op, 2) andalso is_gexpr_list([L,R]);
is_guard_test({call,_,{remote,_,{atom,_,erlang},{atom,_,Test}},As}) ->
erl_internal:type_test(Test, length(As)) andalso is_gexpr_list(As);
is_guard_test({atom,_,true}) -> true;
is_guard_test(_) -> false.
is_gexpr({var,_,_}) -> true;
is_gexpr({atom,_,_}) -> true;
is_gexpr({integer,_,_}) -> true;
is_gexpr({char,_,_}) -> true;
is_gexpr({float,_,_}) -> true;
is_gexpr({string,_,_}) -> true;
is_gexpr({nil,_}) -> true;
is_gexpr({cons,_,H,T}) -> is_gexpr_list([H,T]);
is_gexpr({tuple,_,Es}) -> is_gexpr_list(Es);
is_gexpr({call,_,{remote,_,{atom,_,erlang},{atom,_,F}},As}) ->
Ar = length(As),
case erl_internal:guard_bif(F, Ar) of
true -> is_gexpr_list(As);
false -> erl_internal:arith_op(F, Ar) andalso is_gexpr_list(As)
end;
is_gexpr({op,_,Op,A}) ->
erl_internal:arith_op(Op, 1) andalso is_gexpr(A);
is_gexpr({op,_,Op,A1,A2}) ->
erl_internal:arith_op(Op, 2) andalso is_gexpr_list([A1,A2]);
is_gexpr(_) -> false.
is_gexpr_list(Es) -> lists:all(fun (E) -> is_gexpr(E) end, Es).
consify([A|As]) ->
{cons,0,A,consify(As)};
consify([]) -> {value,0,[]}.
%% -type expr_list([Expression]) -> [Expression].
%% These expressions are processed "in parallel" for purposes of variable
%% definition etc.
expr_list([E0|Es]) ->
E1 = expr(E0),
[E1|expr_list(Es)];
expr_list([]) -> [].
icr_clauses([C0|Cs]) ->
C1 = clause(C0),
[C1|icr_clauses(Cs)];
icr_clauses([]) -> [].
fun_clauses([{clause,L,H,G,B}|Cs]) ->
[{clause,L,head(H),guard(G),exprs(B)}|fun_clauses(Cs)];
fun_clauses([]) -> [].
%% new_var_name() -> VarName.
new_var_name() ->
C = get(vcount),
put(vcount, C+1),
list_to_atom("%" ++ integer_to_list(C)).
%% new_vars(Count, Line) -> [Var].
%% Make Count new variables.
new_vars(N, L) -> new_vars(N, L, []).
new_vars(N, L, Vs) when N > 0 ->
V = {var,L,new_var_name()},
new_vars(N-1, L, [V|Vs]);
new_vars(0, _, Vs) -> Vs.
bif_type(erlang, Name, Arity) ->
case erl_internal:guard_bif(Name, Arity) of
true ->
%% Guard BIFs are safe (except for self/0, but it is
%% handled with a special instruction anyway).
safe;
false ->
bif_type(Name)
end;
bif_type(_, _, _) -> unsafe.
bif_type(register) -> safe;
bif_type(unregister) -> safe;
bif_type(whereis) -> safe;
bif_type(registered) -> safe;
bif_type(math) -> safe;
bif_type(setelement) -> safe;
bif_type(atom_to_list) -> safe;
bif_type(list_to_atom) -> safe;
bif_type(integer_to_list) -> safe;
bif_type(list_to_integer) -> safe;
bif_type(float_to_list) -> safe;
bif_type(list_to_float) -> safe;
bif_type(tuple_to_list) -> safe;
bif_type(list_to_tuple) -> safe;
bif_type(make_ref) -> safe;
bif_type(time) -> safe;
bif_type(date) -> safe;
bif_type(processes) -> safe;
bif_type(process_info) -> safe;
bif_type(load_module) -> safe;
bif_type(delete_module) -> safe;
bif_type(halt) -> safe;
bif_type(check_process_code) -> safe;
bif_type(purge_module) -> safe;
bif_type(pid_to_list) -> safe;
bif_type(list_to_pid) -> safe;
bif_type(module_loaded) -> safe;
bif_type(binary_to_term) -> safe;
bif_type(term_to_binary) -> safe;
bif_type(alive) -> safe;
bif_type(notalive) -> safe;
bif_type(nodes) -> safe;
bif_type(is_alive) -> safe;
bif_type(disconnect_node) -> safe;
bif_type(binary_to_list) -> safe;
bif_type(list_to_binary) -> safe;
bif_type(split_binary) -> safe;
bif_type(term_to_atom) -> safe;
bif_type(hash) -> safe;
bif_type(pre_loaded) -> safe;
bif_type(info) -> safe;
bif_type(set_cookie) -> safe;
bif_type(get_cookie) -> safe;
bif_type(spawn) -> spawn;
bif_type(spawn_link) -> spawn;
bif_type(spawn_opt) -> spawn;
bif_type(_) -> unsafe.