diff options
author | Stavros Aronis <aronisstav@gmail.com> | 2012-02-03 19:23:44 +0100 |
---|---|---|
committer | Henrik Nord <henrik@erlang.org> | 2012-05-21 15:31:21 +0200 |
commit | 9b0cf90622c3f84f2e3f463c2685d0257d249846 (patch) | |
tree | c77fe96a33e92c6c9e97400d804a6670c3d95b22 /lib/dialyzer/src | |
parent | 1630eaa34f2cb8d6fceefbb752cfe94ac8e44b6a (diff) | |
download | otp-9b0cf90622c3f84f2e3f463c2685d0257d249846.tar.gz otp-9b0cf90622c3f84f2e3f463c2685d0257d249846.tar.bz2 otp-9b0cf90622c3f84f2e3f463c2685d0257d249846.zip |
Solve big SCC constraints in parallel
Diffstat (limited to 'lib/dialyzer/src')
-rw-r--r-- | lib/dialyzer/src/dialyzer_typesig.erl | 214 |
1 files changed, 173 insertions, 41 deletions
diff --git a/lib/dialyzer/src/dialyzer_typesig.erl b/lib/dialyzer/src/dialyzer_typesig.erl index d0d27740f3..3f73afb971 100644 --- a/lib/dialyzer/src/dialyzer_typesig.erl +++ b/lib/dialyzer/src/dialyzer_typesig.erl @@ -91,23 +91,25 @@ -type typesig_scc() :: [{mfa(), {cerl:c_var(), cerl:c_fun()}, dict()}]. -type typesig_funmap() :: [{type_var(), type_var()}]. %% Orddict --record(state, {callgraph :: dialyzer_callgraph:callgraph(), - cs = [] :: [constr()], - cmap = dict:new() :: dict(), - fun_map = [] :: typesig_funmap(), - fun_arities = dict:new() :: dict(), - in_match = false :: boolean(), - in_guard = false :: boolean(), - module :: module(), - name_map = dict:new() :: dict(), - next_label :: label(), - self_recs :: [label()], - plt :: dialyzer_plt:plt(), - prop_types = dict:new() :: dict(), - records = dict:new() :: dict(), - opaques = [] :: [erl_types:erl_type()], - scc = [] :: [type_var()], - mfas = [] :: [dialyzer_callgraph:mfa_or_funlbl()] +-type dict_or_ets() :: {'d', dict()} | {'e', ets:tid()}. + +-record(state, {callgraph :: dialyzer_callgraph:callgraph(), + cs = [] :: [constr()], + cmap = {'d', dict:new()} :: dict_or_ets(), + fun_map = [] :: typesig_funmap(), + fun_arities = dict:new() :: dict(), + in_match = false :: boolean(), + in_guard = false :: boolean(), + module :: module(), + name_map = dict:new() :: dict(), + next_label = 0 :: label(), + self_rec :: erl_types:erl_type(), + plt :: dialyzer_plt:plt(), + prop_types = {'d', dict:new()} :: dict_or_ets(), + records = dict:new() :: dict(), + opaques = [] :: [erl_types:erl_type()], + scc = [] :: [type_var()], + mfas :: [tuple()] }). %%----------------------------------------------------------------------------- @@ -1665,7 +1667,12 @@ solve([Fun], State) -> solve([_|_] = SCC, State) -> ?debug("============ Analyzing SCC: ~w ===========\n", [[debug_lookup_name(F) || F <- SCC]]), - solve_scc(SCC, dict:new(), State, false). + {Parallel, NewState} = + case parallel_split(SCC) of + false -> {false, State}; + SplitSCC -> {SplitSCC, minimize_state(State)} + end, + solve_scc(SCC, Parallel, dict:new(), NewState, false). solve_fun(Fun, FunMap, State) -> Cs = state__get_cs(Fun, State), @@ -1680,8 +1687,7 @@ solve_fun(Fun, FunMap, State) -> end, enter_type(Fun, NewType, NewFunMap1). -solve_scc(SCC, Map, State, TryingUnit) -> - State1 = state__mark_as_non_self_rec(SCC, State), +solve_scc(SCC, Parallel, Map, State, TryingUnit) -> Vars0 = [{Fun, state__get_rec_var(Fun, State)} || Fun <- SCC], Vars = [Var || {_, {ok, Var}} <- Vars0], Funs = [Fun || {Fun, {ok, _}} <- Vars0], @@ -1692,9 +1698,12 @@ solve_scc(SCC, Map, State, TryingUnit) -> end, Map, SCC), Map1 = enter_type_lists(Vars, RecTypes, CleanMap), ?debug("Checking SCC: ~w\n", [[debug_lookup_name(F) || F <- SCC]]), - SolveFun = fun(X, Y) -> scc_fold_fun(X, Y, State1) end, - Map2 = lists:foldl(SolveFun, Map1, SCC), FunSet = ordsets:from_list([t_var_name(F) || F <- SCC]), + Map2 = + case Parallel of + false -> solve_whole_scc(SCC, Map1, State); + SplitSCC -> solve_whole_scc_parallel(SplitSCC, Map1, State) + end, case maps_are_equal(Map2, Map, FunSet) of true -> ?debug("SCC ~w reached fixpoint\n", [SCC]), @@ -1708,15 +1717,127 @@ solve_scc(SCC, Map, State, TryingUnit) -> true -> t_fun(t_fun_args(T), t_unit()) end || T <- NewTypes], Map3 = enter_type_lists(Funs, UnitTypes, Map2), - solve_scc(SCC, Map3, State, true); + solve_scc(SCC, Parallel, Map3, State, true); false -> + case Parallel of + false -> true; + _ -> dispose_state(State) + end, Map2 end; false -> ?debug("SCC ~w did not reach fixpoint\n", [SCC]), - solve_scc(SCC, Map2, State, TryingUnit) + solve_scc(SCC, Parallel, Map2, State, TryingUnit) + end. + +solve_whole_scc(SCC, Map, State) -> + SolveFun = fun(X, Y) -> scc_fold_fun(X, Y, State) end, + lists:foldl(SolveFun, Map, SCC). + +%%------------------------------------------------------------------------------ + +-define(worth_it, 42). + +parallel_split(SCC) -> + Length = length(SCC), + case Length > 2*?worth_it of + false -> false; + true -> + case min(erlang:system_info(logical_processors_available), 8) of + 1 -> false; + CPUs -> + FullShare = Length div CPUs + 1, + Unit = max(FullShare, ?worth_it), + split(SCC, Unit, []) + end end. +minimize_state(#state{ + cmap = {d, CMap}, + fun_map = FunMap, + fun_arities = FunArities, + self_rec = SelfRec, + prop_types = {d, PropTypes}, + opaques = Opaques + }) -> + ETSCMap = ets:new(cmap,[{read_concurrency, true}]), + ETSPropTypes = ets:new(prop_types,[{read_concurrency, true}]), + true = ets:insert(ETSCMap, dict:to_list(CMap)), + true = ets:insert(ETSPropTypes, dict:to_list(PropTypes)), + #state + {cmap = {e, ETSCMap}, + fun_map = FunMap, + fun_arities = FunArities, + self_rec = SelfRec, + prop_types = {e, ETSPropTypes}, + opaques = Opaques + }. + +dispose_state(#state{cmap = {e, ETSCMap}, + prop_types = {e, ETSPropTypes}}) -> + true = ets:delete(ETSCMap), + true = ets:delete(ETSPropTypes). + +solve_whole_scc_parallel(SplitSCC, Map, State) -> + Workers = spawn_workers(SplitSCC, Map, State), + wait_results(Workers, Map, fold_res_fun(State)). + +spawn_workers(SplitSCC, Map, State) -> + Spawner = solve_scc_spawner(self(), Map, State), + lists:foreach(Spawner, SplitSCC), + length(SplitSCC). + +wait_results(0, Map, _FoldResFun) -> + Map; +wait_results(Pending, Map, FoldResFun) -> + Res = receive_scc_result(), + NewMap = lists:foldl(FoldResFun, Map, Res), + wait_results(Pending-1, NewMap, FoldResFun). + +solve_scc_spawner(Parent, Map, State) -> + fun(SCCPart) -> + spawn_link(fun() -> solve_scc_worker(Parent, SCCPart, Map, State) end) + end. + +split([], _Unit, Acc) -> + Acc; +split(List, Unit, Acc) -> + {Taken, Rest} = + try + lists:split(Unit, List) + catch + _:_ -> {List, []} + end, + split(Rest, Unit, [Taken|Acc]). + +solve_scc_worker(Parent, SCCPart, Map, State) -> + SolveFun = fun(X, Y) -> scc_fold_fun(X, Y, State) end, + FinalMap = lists:foldl(SolveFun, Map, SCCPart), + Res = + [{F, t_limit(unsafe_lookup_type(F, FinalMap), ?TYPE_LIMIT)} || + F <- SCCPart], + send_scc_result(Parent, Res). + +fold_res_fun(State) -> + fun({F, Type}, Map) -> + case state__get_rec_var(F, State) of + {ok, R} -> + enter_type(R, Type, enter_type(F, Type, Map)); + error -> + enter_type(F, Type, Map) + end + end. + +receive_scc_result() -> + receive + {scc_fun, Res} -> Res + end. + +send_scc_result(Parent, Res) -> + Parent ! {scc_fun, Res}. + +%%------------------------------------------------------------------------------ + scc_fold_fun(F, FunMap, State) -> Deps = get_deps(state__get_cs(F, State)), Cs = mk_constraint_ref(F, Deps), @@ -2090,11 +2211,19 @@ new_state(SCC0, NextLabel, CallGraph, Plt, PropTypes) -> NameMap = dict:from_list(List), MFAs = [MFA || {MFA, _Var} <- List], SCC = [mk_var(Fun) || {_MFA, {_Var, Fun}, _Rec} <- SCC0], - SelfRecs = [F || F <- SCC, - dialyzer_callgraph:is_self_rec(t_var_name(F), CallGraph)], + SelfRec = + case SCC of + [OneF] -> + Label = t_var_name(OneF), + case dialyzer_callgraph:is_self_rec(Label, CallGraph) of + true -> OneF; + false -> false + end; + _Many -> false + end, #state{callgraph = CallGraph, name_map = NameMap, next_label = NextLabel, - prop_types = PropTypes, plt = Plt, scc = ordsets:from_list(SCC), - mfas = MFAs, self_recs = ordsets:from_list(SelfRecs)}. + prop_types = {d, PropTypes}, plt = Plt, scc = ordsets:from_list(SCC), + mfas = MFAs, self_rec = SelfRec}. state__set_rec_dict(State, RecDict) -> State#state{records = RecDict}. @@ -2193,14 +2322,21 @@ state__plt(#state{plt = PLT}) -> state__new_constraint_context(State) -> State#state{cs = []}. -state__prop_domain(FunLabel, #state{prop_types = PropTypes}) -> +state__prop_domain(FunLabel, #state{prop_types = {e, ETSPropTypes}}) -> + try ets:lookup_element(ETSPropTypes, FunLabel, 2) of + {_Range_Fun, Dom} -> {ok, Dom}; + FunType -> {ok, t_fun_args(FunType)} + catch + _:_ -> error + end; +state__prop_domain(FunLabel, #state{prop_types = {d, PropTypes}}) -> case dict:find(FunLabel, PropTypes) of error -> error; {ok, {_Range_Fun, Dom}} -> {ok, Dom}; {ok, FunType} -> {ok, t_fun_args(FunType)} end. -state__add_prop_constrs(Tree, #state{prop_types = PropTypes} = State) -> +state__add_prop_constrs(Tree, #state{prop_types = {d, PropTypes}} = State) -> Label = cerl_trees:get_label(Tree), case dict:find(Label, PropTypes) of error -> State; @@ -2263,21 +2399,17 @@ state__mk_vars(N, #state{next_label = NL} = State) -> Vars = [t_var(X) || X <- lists:seq(NL, NewLabel-1)], {State#state{next_label = NewLabel}, Vars}. -state__store_constrs(Id, Cs, #state{cmap = Dict} = State) -> +state__store_constrs(Id, Cs, #state{cmap = {d, Dict}} = State) -> NewDict = dict:store(Id, Cs, Dict), - State#state{cmap = NewDict}. + State#state{cmap = {d, NewDict}}. -state__get_cs(Var, #state{cmap = Dict}) -> +state__get_cs(Var, #state{cmap = {e, ETSDict}}) -> + ets:lookup_element(ETSDict, Var, 2); +state__get_cs(Var, #state{cmap = {d, Dict}}) -> dict:fetch(Var, Dict). -%% The functions here will not be treated as self recursive. -%% These functions will need to be handled as such manually. -state__mark_as_non_self_rec(SCC, #state{self_recs = SelfRecs} = State) -> - %% TODO: Check if the result is always empty and just set it to [] if so. - State#state{self_recs = ordsets:subtract(SelfRecs, ordsets:from_list(SCC))}. - -state__is_self_rec(Fun, #state{self_recs = SelfRecs}) -> - ordsets:is_element(Fun, SelfRecs). +state__is_self_rec(Fun, #state{self_rec = SelfRec}) -> + Fun =:= SelfRec. state__store_funs(Vars0, Funs0, #state{fun_map = Map} = State) -> debug_make_name_map(Vars0, Funs0), |