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|
%% -*- erlang-indent-level: 2 -*-
%%-----------------------------------------------------------------------
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2006-2017. All Rights Reserved.
%%
%% Licensed under the Apache License, Version 2.0 (the "License");
%% you may not use this file except in compliance with the License.
%% You may obtain a copy of the License at
%%
%% http://www.apache.org/licenses/LICENSE-2.0
%%
%% Unless required by applicable law or agreed to in writing, software
%% distributed under the License is distributed on an "AS IS" BASIS,
%% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
%% See the License for the specific language governing permissions and
%% limitations under the License.
%%
%% %CopyrightEnd%
%%
%%%-------------------------------------------------------------------
%%% File : dialyzer_callgraph.erl
%%% Author : Tobias Lindahl <[email protected]>
%%% Description :
%%%
%%% Created : 30 Mar 2005 by Tobias Lindahl <[email protected]>
%%%-------------------------------------------------------------------
-module(dialyzer_callgraph).
-export([add_edges/2,
add_edges/3,
all_nodes/1,
delete/1,
finalize/1,
is_escaping/2,
is_self_rec/2,
non_local_calls/1,
lookup_letrec/2,
lookup_rec_var/2,
lookup_call_site/2,
lookup_label/2,
lookup_name/2,
modules/1,
module_deps/1,
%% module_postorder/1,
module_postorder_from_funs/2,
new/0,
get_depends_on/2,
get_required_by/2,
in_neighbours/2,
renew_race_info/4,
renew_race_code/2,
renew_race_public_tables/2,
reset_from_funs/2,
scan_core_tree/2,
strip_module_deps/2,
remove_external/1,
to_dot/2,
to_ps/3]).
-export([cleanup/1, get_digraph/1, get_named_tables/1, get_public_tables/1,
get_race_code/1, get_race_detection/1, race_code_new/1,
put_digraph/2, put_race_code/2, put_race_detection/2,
put_named_tables/2, put_public_tables/2, put_behaviour_api_calls/2,
get_behaviour_api_calls/1, dispose_race_server/1, duplicate/1]).
-export_type([callgraph/0, mfa_or_funlbl/0, callgraph_edge/0, mod_deps/0]).
-include("dialyzer.hrl").
%%----------------------------------------------------------------------
-type scc() :: [mfa_or_funlbl()].
-type mfa_call() :: {mfa_or_funlbl(), mfa_or_funlbl()}.
-type mfa_calls() :: [mfa_call()].
-type mod_deps() :: dict:dict(module(), [module()]).
%%-----------------------------------------------------------------------------
%% A callgraph is a directed graph where the nodes are functions and a
%% call between two functions is an edge from the caller to the callee.
%%
%% calls - A mapping from call site (and apply site) labels
%% to the possible functions that can be called.
%% digraph - A digraph representing the callgraph.
%% Nodes are represented as MFAs or labels.
%% esc - A set of all escaping functions as reported by dialyzer_dep.
%% letrec_map - A dict mapping from letrec bound labels to function labels.
%% Includes all functions.
%% name_map - A mapping from label to MFA.
%% rev_name_map - A reverse mapping of the name_map.
%% rec_var_map - A dict mapping from letrec bound labels to function names.
%% Only for top level functions (from module defs).
%% self_rec - A set containing all self recursive functions.
%% Note that this contains MFAs for named functions and labels
%% whenever applicable.
%%-----------------------------------------------------------------------------
%% Types with comment 'race' are due to dialyzer_races.erl.
-record(callgraph, {digraph = digraph:new() :: digraph:graph(),
active_digraph :: active_digraph()
| 'undefined', % race
esc :: ets:tid()
| 'undefined', % race
letrec_map :: ets:tid()
| 'undefined', % race
name_map :: ets:tid(),
rev_name_map :: ets:tid(),
rec_var_map :: ets:tid()
| 'undefined', % race
self_rec :: ets:tid()
| 'undefined', % race
calls :: ets:tid()
| 'undefined', % race
race_detection = false :: boolean(),
race_data_server = dialyzer_race_data_server:new() :: pid()}).
%% Exported Types
-opaque callgraph() :: #callgraph{}.
-type active_digraph() :: {'d', digraph:graph()}
| {'e',
Out :: ets:tid(),
In :: ets:tid(),
Map :: ets:tid()}.
%%----------------------------------------------------------------------
-spec new() -> callgraph().
new() ->
[ETSEsc, ETSNameMap, ETSRevNameMap, ETSRecVarMap, ETSLetrecMap, ETSSelfRec, ETSCalls] =
[ets:new(N,[public, {read_concurrency, true}]) ||
N <- [callgraph_esc, callgraph_name_map, callgraph_rev_name_map,
callgraph_rec_var_map, callgraph_letrec_map, callgraph_self_rec, callgraph_calls]],
#callgraph{esc = ETSEsc,
letrec_map = ETSLetrecMap,
name_map = ETSNameMap,
rev_name_map = ETSRevNameMap,
rec_var_map = ETSRecVarMap,
self_rec = ETSSelfRec,
calls = ETSCalls}.
-spec delete(callgraph()) -> 'true'.
delete(#callgraph{digraph = Digraph}) ->
digraph_delete(Digraph).
-spec all_nodes(callgraph()) -> [mfa()].
all_nodes(#callgraph{digraph = DG}) ->
digraph_vertices(DG).
-spec lookup_rec_var(label(), callgraph()) -> 'error' | {'ok', mfa()}.
lookup_rec_var(Label, #callgraph{rec_var_map = RecVarMap})
when is_integer(Label) ->
ets_lookup_dict(Label, RecVarMap).
-spec lookup_letrec(label(), callgraph()) -> 'error' | {'ok', label()}.
lookup_letrec(Label, #callgraph{letrec_map = LetrecMap})
when is_integer(Label) ->
ets_lookup_dict(Label, LetrecMap).
-spec lookup_call_site(label(), callgraph()) -> 'error' | {'ok', [_]}. % XXX: refine
lookup_call_site(Label, #callgraph{calls = Calls})
when is_integer(Label) ->
ets_lookup_dict(Label, Calls).
-spec lookup_name(label(), callgraph()) -> 'error' | {'ok', mfa()}.
lookup_name(Label, #callgraph{name_map = NameMap})
when is_integer(Label) ->
ets_lookup_dict(Label, NameMap).
-spec lookup_label(mfa_or_funlbl(), callgraph()) -> 'error' | {'ok', integer()}.
lookup_label({_,_,_} = MFA, #callgraph{rev_name_map = RevNameMap}) ->
ets_lookup_dict(MFA, RevNameMap);
lookup_label(Label, #callgraph{}) when is_integer(Label) ->
{ok, Label}.
-spec in_neighbours(mfa_or_funlbl(), callgraph()) -> 'none' | [mfa_or_funlbl(),...].
in_neighbours(Label, #callgraph{digraph = Digraph} = CG)
when is_integer(Label) ->
Name = case lookup_name(Label, CG) of
{ok, Val} -> Val;
error -> Label
end,
digraph_in_neighbours(Name, Digraph);
in_neighbours({_, _, _} = MFA, #callgraph{digraph = Digraph}) ->
digraph_in_neighbours(MFA, Digraph).
-spec is_self_rec(mfa_or_funlbl(), callgraph()) -> boolean().
is_self_rec(MfaOrLabel, #callgraph{self_rec = SelfRecs}) ->
ets_lookup_set(MfaOrLabel, SelfRecs).
-spec is_escaping(label(), callgraph()) -> boolean().
is_escaping(Label, #callgraph{esc = Esc}) when is_integer(Label) ->
ets_lookup_set(Label, Esc).
-type callgraph_edge() :: {mfa_or_funlbl(),mfa_or_funlbl()}.
-spec add_edges([callgraph_edge()], callgraph()) -> ok.
add_edges([], _CG) ->
ok;
add_edges(Edges, #callgraph{digraph = Digraph}) ->
digraph_add_edges(Edges, Digraph).
-spec add_edges([callgraph_edge()], [mfa_or_funlbl()], callgraph()) -> ok.
add_edges(Edges, MFAs, #callgraph{digraph = DG} = CG) ->
digraph_confirm_vertices(MFAs, DG),
add_edges(Edges, CG).
-spec remove_external(callgraph()) -> {callgraph(), [tuple()]}.
remove_external(#callgraph{digraph = DG} = CG) ->
{DG, External} = digraph_remove_external(DG),
{CG, External}.
-spec non_local_calls(callgraph()) -> mfa_calls().
non_local_calls(#callgraph{digraph = DG}) ->
Edges = digraph_edges(DG),
find_non_local_calls(Edges, sets:new()).
-type call_tab() :: sets:set(mfa_call()).
-spec find_non_local_calls([{mfa_or_funlbl(), mfa_or_funlbl()}], call_tab()) ->
mfa_calls().
find_non_local_calls([{{M,_,_}, {M,_,_}}|Left], Set) ->
find_non_local_calls(Left, Set);
find_non_local_calls([{{M1,_,_}, {M2,_,_}} = Edge|Left], Set) when M1 =/= M2 ->
find_non_local_calls(Left, sets:add_element(Edge, Set));
find_non_local_calls([{{_,_,_}, Label}|Left], Set) when is_integer(Label) ->
find_non_local_calls(Left, Set);
find_non_local_calls([{Label, {_,_,_}}|Left], Set) when is_integer(Label) ->
find_non_local_calls(Left, Set);
find_non_local_calls([{Label1, Label2}|Left], Set) when is_integer(Label1),
is_integer(Label2) ->
find_non_local_calls(Left, Set);
find_non_local_calls([], Set) ->
sets:to_list(Set).
-spec get_depends_on(scc() | module(), callgraph()) -> [scc()].
get_depends_on(SCC, #callgraph{active_digraph = {'e', Out, _In, Maps}}) ->
lookup_scc(SCC, Out, Maps);
get_depends_on(SCC, #callgraph{active_digraph = {'d', DG}}) ->
digraph:out_neighbours(DG, SCC).
-spec get_required_by(scc() | module(), callgraph()) -> [scc()].
get_required_by(SCC, #callgraph{active_digraph = {'e', _Out, In, Maps}}) ->
lookup_scc(SCC, In, Maps);
get_required_by(SCC, #callgraph{active_digraph = {'d', DG}}) ->
digraph:in_neighbours(DG, SCC).
lookup_scc(SCC, Table, Maps) ->
case ets_lookup_dict({'scc', SCC}, Maps) of
{ok, SCCInt} ->
case ets_lookup_dict(SCCInt, Table) of
{ok, Ints} ->
[ets:lookup_element(Maps, Int, 2) || Int <- Ints];
error ->
[]
end;
error -> []
end.
%%----------------------------------------------------------------------
%% Handling of modules & SCCs
%%----------------------------------------------------------------------
-spec modules(callgraph()) -> [module()].
modules(#callgraph{digraph = DG}) ->
ordsets:from_list([M || {M,_F,_A} <- digraph_vertices(DG)]).
-spec module_postorder(callgraph()) -> {[module()], {'d', digraph:graph()}}.
module_postorder(#callgraph{digraph = DG}) ->
Edges = lists:foldl(fun edge_fold/2, sets:new(), digraph_edges(DG)),
Nodes = sets:from_list([M || {M,_F,_A} <- digraph_vertices(DG)]),
MDG = digraph:new([acyclic]),
digraph_confirm_vertices(sets:to_list(Nodes), MDG),
Foreach = fun({M1,M2}) -> digraph:add_edge(MDG, M1, M2) end,
lists:foreach(Foreach, sets:to_list(Edges)),
{digraph_utils:topsort(MDG), {'d', MDG}}.
edge_fold({{M1,_,_},{M2,_,_}}, Set) ->
case M1 =/= M2 of
true -> sets:add_element({M1,M2},Set);
false -> Set
end;
edge_fold(_, Set) -> Set.
%% The module deps of a module are modules that depend on the module
-spec module_deps(callgraph()) -> mod_deps().
module_deps(#callgraph{digraph = DG}) ->
Edges = lists:foldl(fun edge_fold/2, sets:new(), digraph_edges(DG)),
Nodes = sets:from_list([M || {M,_F,_A} <- digraph_vertices(DG)]),
MDG = digraph:new(),
digraph_confirm_vertices(sets:to_list(Nodes), MDG),
Foreach = fun({M1,M2}) -> digraph:add_edge(MDG, M1, M2) end,
lists:foreach(Foreach, sets:to_list(Edges)),
Deps = [{N, ordsets:from_list(digraph:in_neighbours(MDG, N))}
|| N <- sets:to_list(Nodes)],
digraph_delete(MDG),
dict:from_list(Deps).
-spec strip_module_deps(mod_deps(), sets:set(module())) -> mod_deps().
strip_module_deps(ModDeps, StripSet) ->
FilterFun1 = fun(Val) -> not sets:is_element(Val, StripSet) end,
MapFun = fun(_Key, ValSet) -> ordsets:filter(FilterFun1, ValSet) end,
ModDeps1 = dict:map(MapFun, ModDeps),
FilterFun2 = fun(_Key, ValSet) -> ValSet =/= [] end,
dict:filter(FilterFun2, ModDeps1).
-spec finalize(callgraph()) -> {[scc()], callgraph()}.
finalize(#callgraph{digraph = DG} = CG) ->
{ActiveDG, Postorder} = condensation(DG),
{Postorder, CG#callgraph{active_digraph = ActiveDG}}.
-spec reset_from_funs([mfa_or_funlbl()], callgraph()) -> {[scc()], callgraph()}.
reset_from_funs(Funs, #callgraph{digraph = DG, active_digraph = ADG} = CG) ->
active_digraph_delete(ADG),
SubGraph = digraph_reaching_subgraph(Funs, DG),
{NewActiveDG, Postorder} = condensation(SubGraph),
digraph_delete(SubGraph),
{Postorder, CG#callgraph{active_digraph = NewActiveDG}}.
-spec module_postorder_from_funs([mfa_or_funlbl()], callgraph()) ->
{[module()], callgraph()}.
module_postorder_from_funs(Funs, #callgraph{digraph = DG,
active_digraph = ADG} = CG) ->
active_digraph_delete(ADG),
SubGraph = digraph_reaching_subgraph(Funs, DG),
{PO, Active} = module_postorder(CG#callgraph{digraph = SubGraph}),
digraph_delete(SubGraph),
{PO, CG#callgraph{active_digraph = Active}}.
ets_lookup_dict(Key, Table) ->
try ets:lookup_element(Table, Key, 2) of
Val -> {ok, Val}
catch
_:_ -> error
end.
ets_lookup_set(Key, Table) ->
ets:lookup(Table, Key) =/= [].
%%----------------------------------------------------------------------
%% Core code
%%----------------------------------------------------------------------
%% The core tree must be labeled as by cerl_trees:label/1 (or /2).
%% The set of labels in the tree must be disjoint from the set of
%% labels already occuring in the callgraph.
-spec scan_core_tree(cerl:c_module(), callgraph()) ->
{[mfa_or_funlbl()], [callgraph_edge()]}.
scan_core_tree(Tree, #callgraph{calls = ETSCalls,
esc = ETSEsc,
letrec_map = ETSLetrecMap,
name_map = ETSNameMap,
rec_var_map = ETSRecVarMap,
rev_name_map = ETSRevNameMap,
self_rec = ETSSelfRec}) ->
%% Build name map and recursion variable maps.
build_maps(Tree, ETSRecVarMap, ETSNameMap, ETSRevNameMap, ETSLetrecMap),
%% First find the module-local dependencies.
{Deps0, EscapingFuns, Calls, Letrecs} = dialyzer_dep:analyze(Tree),
true = ets:insert(ETSCalls, dict:to_list(Calls)),
true = ets:insert(ETSLetrecMap, dict:to_list(Letrecs)),
true = ets:insert(ETSEsc, [{E} || E <- EscapingFuns]),
LabelEdges = get_edges_from_deps(Deps0),
%% Find the self recursive functions. Named functions get both the
%% key and their name for convenience.
SelfRecs0 = lists:foldl(fun({Key, Key}, Acc) ->
case ets_lookup_dict(Key, ETSNameMap) of
error -> [Key|Acc];
{ok, Name} -> [Key, Name|Acc]
end;
(_, Acc) -> Acc
end, [], LabelEdges),
true = ets:insert(ETSSelfRec, [{S} || S <- SelfRecs0]),
NamedEdges1 = name_edges(LabelEdges, ETSNameMap),
%% We need to scan for inter-module calls since these are not tracked
%% by dialyzer_dep. Note that the caller is always recorded as the
%% top level function. This is OK since the included functions are
%% stored as scc with the parent.
NamedEdges2 = scan_core_funs(Tree),
%% Confirm all nodes in the tree.
Names1 = lists:append([[X, Y] || {X, Y} <- NamedEdges1]),
Names2 = ordsets:from_list(Names1),
%% Get rid of the 'top' function from nodes and edges.
Names3 = ordsets:del_element(top, Names2),
NewNamedEdges2 =
[E || {From, To} = E <- NamedEdges2, From =/= top, To =/= top],
NewNamedEdges1 =
[E || {From, To} = E <- NamedEdges1, From =/= top, To =/= top],
NamedEdges3 = NewNamedEdges1 ++ NewNamedEdges2,
{Names3, NamedEdges3}.
build_maps(Tree, ETSRecVarMap, ETSNameMap, ETSRevNameMap, ETSLetrecMap) ->
%% We only care about the named (top level) functions. The anonymous
%% functions will be analysed together with their parents.
Defs = cerl:module_defs(Tree),
Mod = cerl:atom_val(cerl:module_name(Tree)),
Fun =
fun({Var, Function}) ->
FunName = cerl:fname_id(Var),
Arity = cerl:fname_arity(Var),
MFA = {Mod, FunName, Arity},
FunLabel = get_label(Function),
VarLabel = get_label(Var),
true = ets:insert(ETSLetrecMap, {VarLabel, FunLabel}),
true = ets:insert(ETSNameMap, {FunLabel, MFA}),
true = ets:insert(ETSRevNameMap, {MFA, FunLabel}),
true = ets:insert(ETSRecVarMap, {VarLabel, MFA})
end,
lists:foreach(Fun, Defs).
get_edges_from_deps(Deps) ->
%% Convert the dependencies as produced by dialyzer_dep to a list of
%% edges. Also, remove 'external' since we are not interested in
%% this information.
Edges = dict:fold(fun(external, _Set, Acc) -> Acc;
(Caller, Set, Acc) ->
[[{Caller, Callee} || Callee <- Set,
Callee =/= external]|Acc]
end, [], Deps),
lists:flatten(Edges).
name_edges(Edges, ETSNameMap) ->
%% If a label is present in the name map it is renamed. Otherwise
%% keep the label as the identity.
MapFun = fun(X) ->
case ets_lookup_dict(X, ETSNameMap) of
error -> X;
{ok, MFA} -> MFA
end
end,
name_edges(Edges, MapFun, []).
name_edges([{From, To}|Left], MapFun, Acc) ->
NewFrom = MapFun(From),
NewTo = MapFun(To),
name_edges(Left, MapFun, [{NewFrom, NewTo}|Acc]);
name_edges([], _MapFun, Acc) ->
Acc.
scan_core_funs(Tree) ->
Defs = cerl:module_defs(Tree),
Mod = cerl:atom_val(cerl:module_name(Tree)),
DeepEdges = lists:foldl(fun({Var, Function}, Edges) ->
FunName = cerl:fname_id(Var),
Arity = cerl:fname_arity(Var),
MFA = {Mod, FunName, Arity},
[scan_one_core_fun(Function, MFA)|Edges]
end, [], Defs),
lists:flatten(DeepEdges).
scan_one_core_fun(TopTree, FunName) ->
FoldFun = fun(Tree, Acc) ->
case cerl:type(Tree) of
call ->
CalleeM = cerl:call_module(Tree),
CalleeF = cerl:call_name(Tree),
CalleeArgs = cerl:call_args(Tree),
A = length(CalleeArgs),
case (cerl:is_c_atom(CalleeM) andalso
cerl:is_c_atom(CalleeF)) of
true ->
M = cerl:atom_val(CalleeM),
F = cerl:atom_val(CalleeF),
case erl_bif_types:is_known(M, F, A) of
true ->
case {M, F, A} of
{erlang, make_fun, 3} ->
[CA1, CA2, CA3] = CalleeArgs,
case
cerl:is_c_atom(CA1) andalso
cerl:is_c_atom(CA2) andalso
cerl:is_c_int(CA3)
of
true ->
MM = cerl:atom_val(CA1),
FF = cerl:atom_val(CA2),
AA = cerl:int_val(CA3),
case erl_bif_types:is_known(MM, FF, AA) of
true -> Acc;
false -> [{FunName, {MM, FF, AA}}|Acc]
end;
false ->
Acc
end;
_ ->
Acc
end;
false -> [{FunName, {M, F, A}}|Acc]
end;
false ->
%% We cannot handle run-time bindings
Acc
end;
_ ->
%% Nothing that can introduce new edges in the callgraph.
Acc
end
end,
cerl_trees:fold(FoldFun, [], TopTree).
get_label(T) ->
case cerl:get_ann(T) of
[{label, L} | _] when is_integer(L) -> L;
_ -> erlang:error({missing_label, T})
end.
%%----------------------------------------------------------------------
%% Digraph
%%----------------------------------------------------------------------
digraph_add_edges([{From, To}|Left], DG) ->
digraph_add_edge(From, To, DG),
digraph_add_edges(Left, DG);
digraph_add_edges([], _DG) ->
ok.
digraph_add_edge(From, To, DG) ->
case digraph:vertex(DG, From) of
false -> digraph:add_vertex(DG, From);
{From, _} -> ok
end,
case digraph:vertex(DG, To) of
false -> digraph:add_vertex(DG, To);
{To, _} -> ok
end,
digraph:add_edge(DG, {From, To}, From, To, []),
ok.
digraph_confirm_vertices([MFA|Left], DG) ->
digraph:add_vertex(DG, MFA, confirmed),
digraph_confirm_vertices(Left, DG);
digraph_confirm_vertices([], _DG) ->
ok.
digraph_remove_external(DG) ->
Vertices = digraph:vertices(DG),
Unconfirmed = remove_unconfirmed(Vertices, DG),
{DG, Unconfirmed}.
remove_unconfirmed(Vertexes, DG) ->
remove_unconfirmed(Vertexes, DG, []).
remove_unconfirmed([V|Left], DG, Unconfirmed) ->
case digraph:vertex(DG, V) of
{V, confirmed} -> remove_unconfirmed(Left, DG, Unconfirmed);
{V, []} -> remove_unconfirmed(Left, DG, [V|Unconfirmed])
end;
remove_unconfirmed([], DG, Unconfirmed) ->
BadCalls = lists:append([digraph:in_edges(DG, V) || V <- Unconfirmed]),
BadCallsSorted = lists:keysort(1, BadCalls),
digraph:del_vertices(DG, Unconfirmed),
BadCallsSorted.
digraph_delete(DG) ->
digraph:delete(DG).
active_digraph_delete({'d', DG}) ->
digraph:delete(DG);
active_digraph_delete({'e', Out, In, Maps}) ->
ets:delete(Out),
ets:delete(In),
ets:delete(Maps).
digraph_edges(DG) ->
digraph:edges(DG).
digraph_vertices(DG) ->
digraph:vertices(DG).
digraph_in_neighbours(V, DG) ->
case digraph:in_neighbours(DG, V) of
[] -> none;
List -> List
end.
digraph_reaching_subgraph(Funs, DG) ->
Vertices = digraph_utils:reaching(Funs, DG),
digraph_utils:subgraph(DG, Vertices).
%%----------------------------------------------------------------------
%% Races
%%----------------------------------------------------------------------
-spec renew_race_info(callgraph(), dict:dict(), [label()], [string()]) ->
callgraph().
renew_race_info(#callgraph{race_data_server = RaceDataServer} = CG,
RaceCode, PublicTables, NamedTables) ->
ok = dialyzer_race_data_server:cast(
{renew_race_info, {RaceCode, PublicTables, NamedTables}},
RaceDataServer),
CG.
-spec renew_race_code(dialyzer_races:races(), callgraph()) -> callgraph().
renew_race_code(Races, #callgraph{race_data_server = RaceDataServer} = CG) ->
Fun = dialyzer_races:get_curr_fun(Races),
FunArgs = dialyzer_races:get_curr_fun_args(Races),
Code = lists:reverse(dialyzer_races:get_race_list(Races)),
ok = dialyzer_race_data_server:cast(
{renew_race_code, {Fun, FunArgs, Code}},
RaceDataServer),
CG.
-spec renew_race_public_tables(label(), callgraph()) -> callgraph().
renew_race_public_tables(VarLabel,
#callgraph{race_data_server = RaceDataServer} = CG) ->
ok =
dialyzer_race_data_server:cast({renew_race_public_tables, VarLabel}, RaceDataServer),
CG.
-spec cleanup(callgraph()) -> callgraph().
cleanup(#callgraph{digraph = Digraph,
name_map = NameMap,
rev_name_map = RevNameMap,
race_data_server = RaceDataServer}) ->
#callgraph{digraph = Digraph,
name_map = NameMap,
rev_name_map = RevNameMap,
race_data_server = dialyzer_race_data_server:duplicate(RaceDataServer)}.
-spec duplicate(callgraph()) -> callgraph().
duplicate(#callgraph{race_data_server = RaceDataServer} = Callgraph) ->
Callgraph#callgraph{
race_data_server = dialyzer_race_data_server:duplicate(RaceDataServer)}.
-spec dispose_race_server(callgraph()) -> ok.
dispose_race_server(#callgraph{race_data_server = RaceDataServer}) ->
dialyzer_race_data_server:stop(RaceDataServer).
-spec get_digraph(callgraph()) -> digraph:graph().
get_digraph(#callgraph{digraph = Digraph}) ->
Digraph.
-spec get_named_tables(callgraph()) -> [string()].
get_named_tables(#callgraph{race_data_server = RaceDataServer}) ->
dialyzer_race_data_server:call(get_named_tables, RaceDataServer).
-spec get_public_tables(callgraph()) -> [label()].
get_public_tables(#callgraph{race_data_server = RaceDataServer}) ->
dialyzer_race_data_server:call(get_public_tables, RaceDataServer).
-spec get_race_code(callgraph()) -> dict:dict().
get_race_code(#callgraph{race_data_server = RaceDataServer}) ->
dialyzer_race_data_server:call(get_race_code, RaceDataServer).
-spec get_race_detection(callgraph()) -> boolean().
get_race_detection(#callgraph{race_detection = RD}) ->
RD.
-spec get_behaviour_api_calls(callgraph()) -> [{mfa(), mfa()}].
get_behaviour_api_calls(#callgraph{race_data_server = RaceDataServer}) ->
dialyzer_race_data_server:call(get_behaviour_api_calls, RaceDataServer).
-spec race_code_new(callgraph()) -> callgraph().
race_code_new(#callgraph{race_data_server = RaceDataServer} = CG) ->
ok = dialyzer_race_data_server:cast(race_code_new, RaceDataServer),
CG.
-spec put_digraph(digraph:graph(), callgraph()) -> callgraph().
put_digraph(Digraph, Callgraph) ->
Callgraph#callgraph{digraph = Digraph}.
-spec put_race_code(dict:dict(), callgraph()) -> callgraph().
put_race_code(RaceCode, #callgraph{race_data_server = RaceDataServer} = CG) ->
ok = dialyzer_race_data_server:cast({put_race_code, RaceCode}, RaceDataServer),
CG.
-spec put_race_detection(boolean(), callgraph()) -> callgraph().
put_race_detection(RaceDetection, Callgraph) ->
Callgraph#callgraph{race_detection = RaceDetection}.
-spec put_named_tables([string()], callgraph()) -> callgraph().
put_named_tables(NamedTables,
#callgraph{race_data_server = RaceDataServer} = CG) ->
ok = dialyzer_race_data_server:cast({put_named_tables, NamedTables}, RaceDataServer),
CG.
-spec put_public_tables([label()], callgraph()) -> callgraph().
put_public_tables(PublicTables,
#callgraph{race_data_server = RaceDataServer} = CG) ->
ok = dialyzer_race_data_server:cast({put_public_tables, PublicTables}, RaceDataServer),
CG.
-spec put_behaviour_api_calls([{mfa(), mfa()}], callgraph()) -> callgraph().
put_behaviour_api_calls(Calls,
#callgraph{race_data_server = RaceDataServer} = CG) ->
ok = dialyzer_race_data_server:cast({put_behaviour_api_calls, Calls}, RaceDataServer),
CG.
%%=============================================================================
%% Utilities for 'dot'
%%=============================================================================
-spec to_dot(callgraph(), file:filename()) -> 'ok'.
to_dot(#callgraph{digraph = DG, esc = Esc} = CG, File) ->
Fun = fun(L) ->
case lookup_name(L, CG) of
error -> L;
{ok, Name} -> Name
end
end,
Escaping = [{Fun(L), {color, red}}
|| L <- [E || {E} <- ets:tab2list(Esc)], L =/= external],
Vertices = digraph_edges(DG),
hipe_dot:translate_list(Vertices, File, "CG", Escaping).
-spec to_ps(callgraph(), file:filename(), string()) -> 'ok'.
to_ps(#callgraph{} = CG, File, Args) ->
Dot_File = filename:rootname(File) ++ ".dot",
to_dot(CG, Dot_File),
Command = io_lib:format("dot -Tps ~s -o ~s ~s", [Args, File, Dot_File]),
_ = os:cmd(Command),
ok.
condensation(G) ->
SCCs = digraph_utils:strong_components(G),
%% Assign unique numbers to SCCs:
Ints = lists:seq(1, length(SCCs)),
IntToSCC = lists:zip(Ints, SCCs),
IntScc = sofs:relation(IntToSCC, [{int, scc}]),
%% Subsitute strong components for vertices in edges using the
%% unique numbers:
C2V = sofs:relation([{SC, V} || SC <- SCCs, V <- SC], [{scc, v}]),
I2V = sofs:relative_product(IntScc, C2V), % [{v, int}]
Es = sofs:relation(digraph:edges(G), [{v, v}]),
R1 = sofs:relative_product(I2V, Es),
R2 = sofs:relative_product(I2V, sofs:converse(R1)),
%% Create in- and out-neighbours:
In = sofs:relation_to_family(sofs:strict_relation(R2)),
R3 = sofs:converse(R2),
Out = sofs:relation_to_family(sofs:strict_relation(R3)),
[OutETS, InETS, MapsETS] =
[ets:new(Name,[{read_concurrency, true}]) ||
Name <- [callgraph_deps_out, callgraph_deps_in, callgraph_scc_map]],
ets:insert(OutETS, sofs:to_external(Out)),
ets:insert(InETS, sofs:to_external(In)),
%% Create mappings from SCCs to unique integers, and the inverse:
ets:insert(MapsETS, lists:zip([{'scc', SCC} || SCC<- SCCs], Ints)),
ets:insert(MapsETS, IntToSCC),
{{'e', OutETS, InETS, MapsETS}, SCCs}.
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