%% -*- erlang-indent-level: 2 -*-
%%-----------------------------------------------------------------------
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2006-2014. 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%
%%
%%%-------------------------------------------------------------------
%%% File : dialyzer_dep.erl
%%% Author : Tobias Lindahl <[email protected]>
%%%
%%% Description: A pretty limited but efficient escape/dependency
%%% analysis of Core Erlang.
%%%
%%% Created : 28 Oct 2005 by Tobias Lindahl <[email protected]>
%%%-------------------------------------------------------------------
-module(dialyzer_dep).
-export([analyze/1]).
-define(NO_UNUSED, true).
-ifndef(NO_UNUSED).
-export([test/1]).
-endif.
-include("dialyzer.hrl").
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%
%% analyze(CoreTree) -> {Deps, Esc, Calls, Letrecs}.
%%
%% Deps = a dict mapping labels of functions to an ordset of functions
%% it calls.
%%
%% Esc = an ordset of the labels of escaping functions. A function
%% is considered to escape if the control escapes a function,
%% i.e., this analysis is not module-local but rather
%% function-local.
%%
%% Calls = a dict mapping apply:s to an ordset of function labels to
%% which the operation can refer to. If 'external' is part of
%% the set the operation can be externally defined.
%%
%% Letrecs = a dict mapping var labels to their recursive definition.
%% top-level letrecs are not included as they are handled
%% separately.
%%
-spec analyze(cerl:c_module()) ->
{dict:dict(), ordsets:ordset('external' | label()), dict:dict(), dict:dict()}.
analyze(Tree) ->
%% io:format("Handling ~w\n", [cerl:atom_val(cerl:module_name(Tree))]),
{_, State} = traverse(Tree, map__new(), state__new(Tree), top),
Esc = state__esc(State),
%% Add dependency from 'external' to all escaping functions
State1 = state__add_deps(external, output(Esc), State),
Deps = state__deps(State1),
Calls = state__calls(State1),
Letrecs = state__letrecs(State1),
{map__finalize(Deps), set__to_ordsets(Esc), map__finalize(Calls), Letrecs}.
traverse(Tree, Out, State, CurrentFun) ->
%% io:format("Type: ~w\n", [cerl:type(Tree)]),
case cerl:type(Tree) of
apply ->
Op = cerl:apply_op(Tree),
Args = cerl:apply_args(Tree),
%% Op is always a variable and should not be marked as escaping
%% based on its use.
case var =:= cerl:type(Op) of
false -> erlang:error({apply_op_not_a_variable, cerl:type(Op)});
true -> ok
end,
OpFuns = case map__lookup(cerl_trees:get_label(Op), Out) of
none -> output(none);
{value, OF} -> OF
end,
{ArgFuns, State2} = traverse_list(Args, Out, State, CurrentFun),
State3 = state__add_esc(merge_outs(ArgFuns), State2),
State4 = state__add_deps(CurrentFun, OpFuns, State3),
State5 = state__store_callsite(cerl_trees:get_label(Tree),
OpFuns, length(Args), State4),
{output(set__singleton(external)), State5};
binary ->
{output(none), State};
'case' ->
Arg = cerl:case_arg(Tree),
{Funs, NewState} = traverse(Arg, Out, State, CurrentFun),
Clauses = cerl:case_clauses(Tree),
traverse_clauses(Clauses, Funs, Out, NewState, CurrentFun);
call ->
Args = cerl:call_args(Tree),
{ArgFuns, State1} = traverse_list(Args, Out, State, CurrentFun),
remote_call(Tree, merge_outs(ArgFuns), State1);
'catch' ->
traverse(cerl:catch_body(Tree), Out, State, CurrentFun);
cons ->
{HdFuns, State1} = traverse(cerl:cons_hd(Tree), Out, State, CurrentFun),
{TlFuns, State2} = traverse(cerl:cons_tl(Tree), Out, State1, CurrentFun),
{merge_outs([HdFuns, TlFuns]), State2};
'fun' ->
%% io:format("Entering fun: ~w\n", [cerl_trees:get_label(Tree)]),
Body = cerl:fun_body(Tree),
Label = cerl_trees:get_label(Tree),
State1 =
if CurrentFun =:= top ->
state__add_deps(top, output(set__singleton(Label)), State);
true ->
O1 = output(set__singleton(CurrentFun)),
O2 = output(set__singleton(Label)),
TmpState = state__add_deps(Label, O1, State),
state__add_deps(CurrentFun, O2,TmpState)
end,
{BodyFuns, State2} = traverse(Body, Out, State1,
cerl_trees:get_label(Tree)),
{output(set__singleton(Label)), state__add_esc(BodyFuns, State2)};
'let' ->
Vars = cerl:let_vars(Tree),
Arg = cerl:let_arg(Tree),
Body = cerl:let_body(Tree),
{ArgFuns, State1} = traverse(Arg, Out, State, CurrentFun),
Out1 = bind_list(Vars, ArgFuns, Out),
traverse(Body, Out1, State1, CurrentFun);
letrec ->
Defs = cerl:letrec_defs(Tree),
Body = cerl:letrec_body(Tree),
State1 = lists:foldl(fun({ Var, Fun }, Acc) ->
state__add_letrecs(cerl_trees:get_label(Var), cerl_trees:get_label(Fun), Acc)
end, State, Defs),
Out1 = bind_defs(Defs, Out),
State2 = traverse_defs(Defs, Out1, State1, CurrentFun),
traverse(Body, Out1, State2, CurrentFun);
literal ->
{output(none), State};
module ->
Defs = cerl:module_defs(Tree),
Out1 = bind_defs(Defs, Out),
State1 = traverse_defs(Defs, Out1, State, CurrentFun),
{output(none), State1};
primop ->
Args = cerl:primop_args(Tree),
{ArgFuns, State1} = traverse_list(Args, Out, State, CurrentFun),
primop(Tree, merge_outs(ArgFuns), State1);
'receive' ->
Clauses = cerl:receive_clauses(Tree),
TimeOut = cerl:receive_timeout(Tree),
Action = cerl:receive_action(Tree),
{ClauseFuns, State1} =
traverse_clauses(Clauses, output(none), Out, State, CurrentFun),
{_, State2} = traverse(TimeOut, Out, State1, CurrentFun),
{ActionFuns, State3} = traverse(Action, Out, State2, CurrentFun),
{merge_outs([ClauseFuns, ActionFuns]), State3};
seq ->
{_, State1} = traverse(cerl:seq_arg(Tree), Out, State, CurrentFun),
traverse(cerl:seq_body(Tree), Out, State1, CurrentFun);
'try' ->
Arg = cerl:try_arg(Tree),
Body = cerl:try_body(Tree),
Vars = cerl:try_vars(Tree),
EVars = cerl:try_evars(Tree),
Handler = cerl:try_handler(Tree),
{ArgFuns, State1} = traverse(Arg, Out, State, CurrentFun),
Out1 = bind_list(Vars, ArgFuns, Out),
{BodyFuns, State2} = traverse(Body, Out1, State1, CurrentFun),
Out2 = bind_single(EVars, output(set__singleton(external)), Out),
{HandlerFuns, State3} = traverse(Handler, Out2, State2, CurrentFun),
{merge_outs([BodyFuns, HandlerFuns]), State3};
tuple ->
Args = cerl:tuple_es(Tree),
{List, State1} = traverse_list(Args, Out, State, CurrentFun),
{merge_outs(List), State1};
map ->
Args = cerl:map_es(Tree),
{List, State1} = traverse_list(Args, Out, State, CurrentFun),
{merge_outs(List), State1};
map_pair ->
Key = cerl:map_pair_key(Tree),
Val = cerl:map_pair_val(Tree),
{List, State1} = traverse_list([Key,Val], Out, State, CurrentFun),
{merge_outs(List), State1};
values ->
traverse_list(cerl:values_es(Tree), Out, State, CurrentFun);
var ->
case map__lookup(cerl_trees:get_label(Tree), Out) of
none -> {output(none), State};
{value, Val} ->
case is_only_external(Val) of
true ->
%% Do nothing
{Val, State};
false ->
%% If this is used in a function this means a dependency.
{Val, state__add_deps(CurrentFun, Val, State)}
end
end
end.
traverse_list(Trees, Out, State, CurrentFun) ->
traverse_list(Trees, Out, State, CurrentFun, []).
traverse_list([Tree|Left], Out, State, CurrentFun, Acc) ->
{X, State1} = traverse(Tree, Out, State, CurrentFun),
traverse_list(Left, Out, State1, CurrentFun, [X|Acc]);
traverse_list([], _Out, State, _CurrentFun, Acc) ->
{output(lists:reverse(Acc)), State}.
traverse_defs([{_, Fun}|Left], Out, State, CurrentFun) ->
{_, State1} = traverse(Fun, Out, State, CurrentFun),
traverse_defs(Left, Out, State1, CurrentFun);
traverse_defs([], _Out, State, _CurrentFun) ->
State.
traverse_clauses(Clauses, ArgFuns, Out, State, CurrentFun) ->
case filter_match_fail(Clauses) of
[] ->
%% Can happen for example with receives used as timouts.
{output(none), State};
Clauses1 ->
traverse_clauses(Clauses1, ArgFuns, Out, State, CurrentFun, [])
end.
traverse_clauses([Clause|Left], ArgFuns, Out, State, CurrentFun, Acc) ->
Pats = cerl:clause_pats(Clause),
Guard = cerl:clause_guard(Clause),
Body = cerl:clause_body(Clause),
Out1 = bind_pats_list(Pats, ArgFuns, Out),
{_, State2} = traverse(Guard, Out1, State, CurrentFun),
{BodyFuns, State3} = traverse(Body, Out1, State2, CurrentFun),
traverse_clauses(Left, ArgFuns, Out, State3, CurrentFun, [BodyFuns|Acc]);
traverse_clauses([], _ArgFuns, _Out, State, _CurrentFun, Acc) ->
{merge_outs(Acc), State}.
filter_match_fail([Clause]) ->
Body = cerl:clause_body(Clause),
case cerl:type(Body) of
primop ->
case cerl:atom_val(cerl:primop_name(Body)) of
match_fail -> [];
raise -> [];
_ -> [Clause]
end;
_ -> [Clause]
end;
filter_match_fail([H|T]) ->
[H|filter_match_fail(T)];
filter_match_fail([]) ->
%% This can actually happen, for example in
%% receive after 1 -> ok end
[].
remote_call(Tree, ArgFuns, State) ->
M = cerl:call_module(Tree),
F = cerl:call_name(Tree),
A = length(cerl:call_args(Tree)),
case cerl:is_c_atom(M) andalso cerl:is_c_atom(F) of
false ->
%% Unknown function.
{output(set__singleton(external)), state__add_esc(ArgFuns, State)};
true ->
M1 = cerl:atom_val(M),
F1 = cerl:atom_val(F),
Literal = cerl_closurean:is_literal_op(M1, F1, A),
case erl_bifs:is_pure(M1, F1, A) of
true ->
case Literal of
true ->
{output(none), State};
false ->
{output(set__singleton(external)), state__add_esc(ArgFuns, State)}
end;
false ->
State1 = case cerl_closurean:is_escape_op(M1, F1, A) of
true -> state__add_esc(ArgFuns, State);
false -> State
end,
case Literal of
true -> {output(none), State1};
false -> {add_external(ArgFuns), State1}
end
end
end.
primop(Tree, ArgFuns, State) ->
F = cerl:atom_val(cerl:primop_name(Tree)),
A = length(cerl:primop_args(Tree)),
State1 = case cerl_closurean:is_escape_op(F, A) of
true -> state__add_esc(ArgFuns, State);
false -> State
end,
case cerl_closurean:is_literal_op(F, A) of
true -> {output(none), State1};
false -> {ArgFuns, State1}
end.
%%------------------------------------------------------------
%% Set
%%
-record(set, {set :: sets:set()}).
set__singleton(Val) ->
#set{set = sets:add_element(Val, sets:new())}.
set__from_list(List) ->
#set{set = sets:from_list(List)}.
set__is_element(_El, none) ->
false;
set__is_element(El, #set{set = Set}) ->
sets:is_element(El, Set).
set__union(none, Set) -> Set;
set__union(Set, none) -> Set;
set__union(#set{set = S1}, #set{set = S2}) -> #set{set = sets:union(S1, S2)}.
set__to_ordsets(none) -> [];
set__to_ordsets(#set{set = Set}) -> ordsets:from_list(sets:to_list(Set)).
set__size(none) -> 0;
set__size(#set{set = Set}) -> sets:size(Set).
set__filter(#set{set = Set}, Fun) ->
NewSet = sets:filter(Fun, Set),
case sets:size(NewSet) =:= 0 of
true -> none;
false -> #set{set = NewSet}
end.
%%------------------------------------------------------------
%% Outputs
%%
-record(output, {type :: 'single' | 'list',
content :: 'none' | #set{} | [#output{}]}).
output(none) -> #output{type = single, content = none};
output(S = #set{}) -> #output{type = single, content = S};
output(List) when is_list(List) -> #output{type = list, content = List}.
merge_outs([H|T]) ->
merge_outs(T, H);
merge_outs(#output{type = list, content = [H|T]}) ->
merge_outs(T, H);
merge_outs(#output{type = list, content = []}) ->
output(none).
merge_outs([#output{content = none}|Left], O) ->
merge_outs(Left, O);
merge_outs([O|Left], #output{content = none}) ->
merge_outs(Left, O);
merge_outs([#output{type = single, content = S1}|Left],
#output{type = single, content = S2}) ->
merge_outs(Left, output(set__union(S1, S2)));
merge_outs([#output{type = list, content = L1}|Left],
#output{type = list, content = L2}) ->
NewList = [merge_outs([X, Y]) || {X, Y} <- lists:zip(L1, L2)],
merge_outs(Left, output(NewList));
merge_outs([], Res) ->
Res.
filter_outs(#output{type = single, content = S}, Fun) ->
output(set__filter(S, Fun)).
add_external(#output{type = single, content = Set}) ->
output(set__union(Set, set__singleton(external)));
add_external(#output{type = list, content = List}) ->
output([add_external(O) || O <- List]).
is_only_external(#output{type = single, content = Set}) ->
set__is_element(external, Set) andalso (set__size(Set) =:= 1).
%%------------------------------------------------------------
%% Map
%%
map__new() ->
dict:new().
map__add(_Label, none, Map) ->
Map;
map__add(Label, Set, Map) ->
case map__lookup(Label, Map) of
{value, OldSet} ->
NewSet = set__union(OldSet, Set),
map__store(Label, NewSet, Map);
none ->
map__store(Label, Set, Map)
end.
map__store(Label, Val, Map) ->
dict:store(Label, Val, Map).
map__lookup(Label, Map) ->
case dict:find(Label, Map) of
{ok, Val} -> {value, Val};
error -> none
end.
map__finalize(Map) ->
dict:map(fun (_Key, #set{} = Set) -> set__to_ordsets(Set);
(_Key, #output{type = single, content = Set}) ->
set__to_ordsets(Set)
end, Map).
%%------------------------------------------------------------
%% Binding outs in the map
%%
bind_pats_list(_Pats, #output{content = none}, Map) ->
Map;
bind_pats_list([Pat], #output{type = single} = O, Map) ->
bind_single(all_vars(Pat), O, Map);
bind_pats_list(Pats, #output{type = list, content = List}, Map) ->
bind_pats_list(Pats, List, Map);
bind_pats_list([Pat|PatLeft],
[#output{type = single} = O|SetLeft], Map)->
Map1 = bind_single(all_vars(Pat), O, Map),
bind_pats_list(PatLeft, SetLeft, Map1);
bind_pats_list([Pat|PatLeft],
[#output{type = list, content = List}|SetLeft], Map) ->
Map1 = case cerl:is_c_values(Pat) of
true -> bind_pats_list(cerl:values_es(Pat), List, Map);
false -> bind_single(all_vars(Pat), merge_outs(List), Map)
end,
bind_pats_list(PatLeft, SetLeft, Map1);
bind_pats_list([], [], Map) ->
Map.
bind_single([Var|Left], O, Map) ->
bind_single(Left, O, map__store(cerl_trees:get_label(Var), O, Map));
bind_single([], _O, Map) ->
Map.
bind_list(List, #output{type = single} = O, Map) ->
bind_single(List, O, Map);
bind_list(List1, #output{type = list, content = List2}, Map) ->
bind_list1(List1, List2, Map).
bind_list1([Var|VarLeft], [O|OLeft], Map) ->
bind_list1(VarLeft, OLeft, map__store(cerl_trees:get_label(Var), O, Map));
bind_list1([], [], Map) ->
Map.
bind_defs([{Var, Fun}|Left], Map) ->
O = output(set__singleton(cerl_trees:get_label(Fun))),
Map1 = map__store(cerl_trees:get_label(Var), O, Map),
bind_defs(Left, Map1);
bind_defs([], Map) ->
Map.
all_vars(Tree) ->
all_vars(Tree, []).
all_vars(Tree, AccIn) ->
cerl_trees:fold(fun(SubTree, Acc) ->
case cerl:is_c_var(SubTree) of
true -> [SubTree|Acc];
false -> Acc
end
end, AccIn, Tree).
%%------------------------------------------------------------
%% The state
%%
-type local_set() :: 'none' | #set{}.
-record(state, {deps :: dict:dict(),
esc :: local_set(),
call :: dict:dict(),
arities :: dict:dict(),
letrecs :: dict:dict()}).
state__new(Tree) ->
Exports = set__from_list([X || X <- cerl:module_exports(Tree)]),
%% get the labels of all exported functions
ExpLs = [cerl_trees:get_label(Fun) || {Var, Fun} <- cerl:module_defs(Tree),
set__is_element(Var, Exports)],
%% make sure to also initiate an analysis from all functions called
%% from on_load attributes; in Core these exist as a list of {F,A} pairs
OnLoadFAs = lists:flatten([cerl:atom_val(Args)
|| {Attr, Args} <- cerl:module_attrs(Tree),
cerl:atom_val(Attr) =:= on_load]),
OnLoadLs = [cerl_trees:get_label(Fun)
|| {Var, Fun} <- cerl:module_defs(Tree),
lists:member(cerl:var_name(Var), OnLoadFAs)],
%% init the escaping function labels to exported + called from on_load
InitEsc = set__from_list(OnLoadLs ++ ExpLs),
Arities = cerl_trees:fold(fun find_arities/2, dict:new(), Tree),
#state{deps = map__new(), esc = InitEsc, call = map__new(),
arities = Arities, letrecs = map__new()}.
find_arities(Tree, AccMap) ->
case cerl:is_c_fun(Tree) of
true ->
Label = cerl_trees:get_label(Tree),
Arity = cerl:fun_arity(Tree),
dict:store(Label, Arity, AccMap);
false ->
AccMap
end.
state__add_deps(_From, #output{content = none}, State) ->
State;
state__add_deps(From, #output{type = single, content=To},
#state{deps = Map} = State) ->
%% io:format("Adding deps from ~w to ~w\n", [From, set__to_ordsets(To)]),
State#state{deps = map__add(From, To, Map)}.
state__add_letrecs(Var, Fun, #state{letrecs = Map} = State) ->
State#state{letrecs = map__store(Var, Fun, Map)}.
state__deps(#state{deps = Deps}) ->
Deps.
state__letrecs(#state{letrecs = Letrecs}) ->
Letrecs.
state__add_esc(#output{content = none}, State) ->
State;
state__add_esc(#output{type = single, content = Set},
#state{esc = Esc} = State) ->
State#state{esc = set__union(Set, Esc)}.
state__esc(#state{esc = Esc}) ->
Esc.
state__store_callsite(_From, #output{content = none}, _CallArity, State) ->
State;
state__store_callsite(From, To, CallArity,
#state{call = Calls, arities = Arities} = State) ->
Filter = fun(external) -> true;
(Fun) -> CallArity =:= dict:fetch(Fun, Arities)
end,
case filter_outs(To, Filter) of
#output{content = none} -> State;
To1 -> State#state{call = map__store(From, To1, Calls)}
end.
state__calls(#state{call = Calls}) ->
Calls.
%%------------------------------------------------------------
%% A test function. Not part of the intended interface.
%%
-ifndef(NO_UNUSED).
test(Mod) ->
{ok, _, Code} = compile:file(Mod, [to_core, binary]),
Tree = cerl:from_records(Code),
{LabeledTree, _} = cerl_trees:label(Tree),
{Deps, Esc, Calls} = analyze(LabeledTree),
Edges0 = dict:fold(fun(Caller, Set, Acc) ->
[[{Caller, Callee} || Callee <- Set]|Acc]
end, [], Deps),
Edges1 = lists:flatten(Edges0),
Edges = [Edge || {X,_Y} = Edge <- Edges1, X =/= top],
Fun = fun(SubTree, Acc) ->
case cerl:type(SubTree) of
'fun' ->
case lists:keyfind(id, 1, cerl:get_ann(SubTree)) of
false -> Acc;
{id, ID} ->
dict:store(cerl_trees:get_label(SubTree), ID, Acc)
end;
module ->
Defs = cerl:module_defs(SubTree),
lists:foldl(fun({Var, Fun}, Acc1) ->
dict:store(cerl_trees:get_label(Fun),
{cerl:fname_id(Var),
cerl:fname_arity(Var)},
Acc1)
end, Acc, Defs);
letrec ->
Defs = cerl:letrec_defs(SubTree),
lists:foldl(fun({Var, Fun}, Acc1) ->
dict:store(cerl_trees:get_label(Fun),
{cerl:fname_id(Var),
cerl:fname_arity(Var)},
Acc1)
end, Acc, Defs);
_ -> Acc
end
end,
NameMap1 = cerl_trees:fold(Fun, dict:new(), LabeledTree),
NameMap = dict:store(external, external, NameMap1),
NamedEdges = [{dict:fetch(X, NameMap), dict:fetch(Y, NameMap)}
|| {X, Y} <- Edges],
NamedEsc = [dict:fetch(X, NameMap) || X <- Esc],
%% Color the edges
ColorEsc = [{X, {color, red}} || X <- NamedEsc],
CallEdges0 = dict:fold(fun(Caller, Set, Acc) ->
[[{Caller, Callee} || Callee <- Set]|Acc]
end, [], Calls),
CallEdges = lists:flatten(CallEdges0),
NamedCallEdges = [{X, dict:fetch(Y, NameMap)} || {X, Y} <- CallEdges],
AllNamedEdges = NamedEdges ++ NamedCallEdges,
hipe_dot:translate_list(AllNamedEdges, "/tmp/cg.dot", "CG", ColorEsc),
os:cmd("dot -T ps -o /tmp/cg.ps /tmp/cg.dot"),
ok.
-endif.