%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2010-2016. 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%
%%
-module(lcnt).
-behaviour(gen_server).
-author("Björn-Egil Dahlberg").
%% gen_server callbacks
-export([init/1,
handle_call/3,
handle_cast/2,
handle_info/2,
terminate/2,
code_change/3]).
%% start/stop
-export([start/0,
stop/0]).
%% erts_debug:lock_counters api
-export([rt_collect/0,
rt_collect/1,
rt_clear/0,
rt_clear/1,
rt_opt/1,
rt_opt/2]).
%% gen_server call api
-export([raw/0,
collect/0,
collect/1,
clear/0,
clear/1,
conflicts/0,
conflicts/1,
locations/0,
locations/1,
inspect/1,
inspect/2,
histogram/1,
histogram/2,
information/0,
swap_pid_keys/0,
% set options
set/1,
set/2,
load/1,
save/1]).
%% convenience
-export([apply/3,
apply/2,
apply/1,
all_conflicts/0,
all_conflicts/1,
pid/2, pid/3,
port/1, port/2]).
-define(version, "1.0").
-record(state, {
locks = [],
duration = 0
}).
-record(stats, {
file :: atom(),
line :: non_neg_integer() | 'undefined',
tries :: non_neg_integer(),
colls :: non_neg_integer(),
time :: non_neg_integer(), % us
nt :: non_neg_integer(), % #timings collected
hist :: tuple() | 'undefined' % histogram
}).
-record(lock, {
name,
id,
type,
stats = []
}).
-record(print, {
name,
id,
type,
entry,
tries,
colls,
cr, % collision ratio
time,
dtr, % time duration ratio
%% new
hist % log2 histogram of lock wait_time
}).
%% -------------------------------------------------------------------- %%
%%
%% start/stop/init
%%
%% -------------------------------------------------------------------- %%
start() -> gen_server:start({local, ?MODULE}, ?MODULE, [], []).
stop() -> gen_server:call(?MODULE, stop, infinity).
init([]) -> {ok, #state{ locks = [], duration = 0 } }.
start_internal() ->
case start() of
{ok,_} -> ok;
{error, {already_started,_}} -> ok;
Error -> Error
end.
%% -------------------------------------------------------------------- %%
%%
%% API erts_debug:lock_counters
%%
%% -------------------------------------------------------------------- %%
rt_collect() ->
erts_debug:lock_counters(info).
rt_collect(Node) ->
rpc:call(Node, erts_debug, lock_counters, [info]).
rt_clear() ->
erts_debug:lock_counters(clear).
rt_clear(Node) ->
rpc:call(Node, erts_debug, lock_counters, [clear]).
rt_opt({Type, Opt}) ->
erts_debug:lock_counters({Type, Opt}).
rt_opt(Node, {Type, Opt}) ->
rpc:call(Node, erts_debug, lock_counters, [{Type, Opt}]).
%% -------------------------------------------------------------------- %%
%%
%% API implementation
%%
%% -------------------------------------------------------------------- %%
clear() -> rt_clear().
clear(Node) -> rt_clear(Node).
collect() -> call({collect, rt_collect()}).
collect(Node) -> call({collect, rt_collect(Node)}).
locations() -> call({locations,[]}).
locations(Opts) -> call({locations, Opts}).
conflicts() -> call({conflicts, []}).
conflicts(Opts) -> call({conflicts, Opts}).
inspect(Lock) -> call({inspect, Lock, []}).
inspect(Lock, Opts) -> call({inspect, Lock, Opts}).
histogram(Lock) -> call({histogram, Lock, []}).
histogram(Lock, Opts)-> call({histogram, Lock, Opts}).
information() -> call(information).
swap_pid_keys() -> call(swap_pid_keys).
raw() -> call(raw).
set(Option, Value) -> call({set, Option, Value}).
set({Option, Value}) -> call({set, Option, Value}).
save(Filename) -> call({save, Filename}).
load(Filename) -> ok = start_internal(), call({load, Filename}).
call(Msg) -> gen_server:call(?MODULE, Msg, infinity).
%% -------------------------------------------------------------------- %%
%%
%% convenience implementation
%%
%% -------------------------------------------------------------------- %%
apply(M,F,As) when is_atom(M), is_atom(F), is_list(As) ->
ok = start_internal(),
Opt = lcnt:rt_opt({copy_save, true}),
lcnt:clear(),
Res = erlang:apply(M,F,As),
lcnt:collect(),
lcnt:rt_opt({copy_save, Opt}),
Res.
apply(Fun) when is_function(Fun) ->
lcnt:apply(Fun, []).
apply(Fun, As) when is_function(Fun) ->
ok = start_internal(),
Opt = lcnt:rt_opt({copy_save, true}),
lcnt:clear(),
Res = erlang:apply(Fun, As),
lcnt:collect(),
lcnt:rt_opt({copy_save, Opt}),
Res.
all_conflicts() -> all_conflicts(time).
all_conflicts(Sort) ->
conflicts([{max_locks, none}, {thresholds, []},{combine,false}, {sort, Sort}, {reverse, true}]).
pid(Id, Serial) -> pid(node(), Id, Serial).
pid(Node, Id, Serial) when is_atom(Node) ->
Header = <<131,103,100>>,
String = atom_to_list(Node),
L = length(String),
binary_to_term(list_to_binary([Header, bytes16(L), String, bytes32(Id), bytes32(Serial),0])).
port(Id) -> port(node(), Id).
port(Node, Id ) when is_atom(Node) ->
Header = <<131,102,100>>,
String = atom_to_list(Node),
L = length(String),
binary_to_term(list_to_binary([Header, bytes16(L), String, bytes32(Id), 0])).
%% -------------------------------------------------------------------- %%
%%
%% handle_call
%%
%% -------------------------------------------------------------------- %%
% printing
handle_call({conflicts, InOpts}, _From, #state{ locks = Locks } = State) when is_list(InOpts) ->
Default = [
{sort, time},
{reverse, false},
{print, [name,id,tries,colls,ratio,time,duration]},
{max_locks, 20},
{combine, true},
{thresholds, [{tries, 0}, {colls, 0}, {time, 0}] },
{locations, false}],
Opts = options(InOpts, Default),
Flocks = filter_locks_type(Locks, proplists:get_value(type, Opts)),
Combos = combine_classes(Flocks, proplists:get_value(combine, Opts)),
Printables = locks2print(Combos, State#state.duration),
Filtered = filter_print(Printables, Opts),
print_lock_information(Filtered, proplists:get_value(print, Opts)),
{reply, ok, State};
handle_call(information, _From, State) ->
print_state_information(State),
{reply, ok, State};
handle_call({locations, InOpts}, _From, #state{ locks = Locks } = State) when is_list(InOpts) ->
Default = [
{sort, time},
{reverse, false},
{print, [name,entry,tries,colls,ratio,time,duration]},
{max_locks, 20},
{combine, true},
{thresholds, [{tries, 0}, {colls, 0}, {time, 0}] },
{locations, true}],
Opts = options(InOpts, Default),
Printables = filter_print([#print{
name = string_names(Names),
entry = term2string("~tp:~p", [Stats#stats.file, Stats#stats.line]),
colls = Stats#stats.colls,
tries = Stats#stats.tries,
cr = percent(Stats#stats.colls, Stats#stats.tries),
time = Stats#stats.time,
dtr = percent(Stats#stats.time, State#state.duration)
} || {Stats, Names} <- combine_locations(Locks) ], Opts),
print_lock_information(Printables, proplists:get_value(print, Opts)),
{reply, ok, State};
handle_call({inspect, Lockname, InOpts}, _From, #state{ duration=Duration, locks=Locks } = State) when is_list(InOpts) ->
Default = [
{sort, time},
{reverse, false},
{print, [name,id,tries,colls,ratio,time,duration,histogram]},
{max_locks, 20},
{combine, false},
{thresholds, []},
{locations, false}],
Opts = options(InOpts, Default),
Filtered = filter_locks(Locks, Lockname),
IDs = case {proplists:get_value(full_id, Opts), proplists:get_value(combine, Opts)} of
{true, true} -> locks_ids(Filtered);
_ -> []
end,
Combos = combine_classes(Filtered, proplists:get_value(combine, Opts)),
case proplists:get_value(locations, Opts) of
true ->
lists:foreach(fun
(#lock{ name = Name, id = Id, type = Type, stats = Stats }) ->
IdString = case proplists:get_value(full_id, Opts) of
true -> term2string(proplists:get_value(Name, IDs, Id));
_ -> term2string(Id)
end,
Combined = [CStats || {CStats,_} <- combine_locations(Stats)],
case Combined of
[] ->
ok;
_ ->
print("lock: " ++ term2string(Name)),
print("id: " ++ IdString),
print("type: " ++ term2string(Type)),
Ps = stats2print(Combined, Duration),
Opts1 = options([{print, [entry, tries,colls,ratio,time,duration,histogram]},
{thresholds, [{tries, -1}, {colls, -1}, {time, -1}]}], Opts),
print_lock_information(filter_print(Ps, Opts1), proplists:get_value(print, Opts1))
end
end, Combos);
_ ->
Print = filter_print(locks2print(Combos, Duration), Opts),
print_lock_information(Print, proplists:get_value(print, Opts))
end,
{reply, ok, State};
%% histogram
handle_call({histogram, Lockname, InOpts}, _From, #state{ duration=Duration, locks=Locks} = State)->
Default = [
{sort, time},
{reverse, false},
{print, [name,id,tries,colls,ratio,time,duration,histogram]},
{max_locks, 20},
{combine, true},
{thresholds, []},
{locations, false}],
Opts = options(InOpts, Default),
Filtered = filter_locks(Locks, Lockname),
Combos = combine_classes(Filtered, proplists:get_value(combine, Opts)),
lists:foreach(fun
(#lock{ stats = Stats }=L) ->
SumStats = summate_stats(Stats),
Opts1 = options([{print, [name,id,tries,colls,ratio,time,duration]},
{thresholds, [{tries, -1}, {colls, -1}, {time, -1}]}], Opts),
Prints = locks2print([L], Duration),
print_lock_information(Prints, proplists:get_value(print, Opts1)),
print_full_histogram(SumStats#stats.hist)
end, Combos),
{reply, ok, State};
handle_call(raw, _From, #state{ locks = Locks} = State)->
{reply, Locks, State};
% collecting
handle_call({collect, Data}, _From, State)->
{reply, ok, data2state(Data, State)};
% manipulate
handle_call(swap_pid_keys, _From, #state{ locks = Locks } = State)->
SwappedLocks = lists:map(fun
(L) when L#lock.name =:= port_lock; L#lock.type =:= proclock ->
L#lock{ id = L#lock.name, name = L#lock.id };
(L) ->
L
end, Locks),
{reply, ok, State#state{ locks = SwappedLocks}};
% settings
handle_call({set, data, Data}, _From, State)->
{reply, ok, data2state(Data, State)};
handle_call({set, duration, Duration}, _From, State)->
{reply, ok, State#state{ duration = Duration}};
% file operations
handle_call({load, Filename}, _From, State) ->
case file:read_file(Filename) of
{ok, Binary} ->
case binary_to_term(Binary) of
{?version, Statelist} ->
{reply, ok, list2state(Statelist)};
{Version, _} ->
{reply, {error, {mismatch, Version, ?version}}, State}
end;
Error ->
{reply, {error, Error}, State}
end;
handle_call({save, Filename}, _From, State) ->
Binary = term_to_binary({?version, state2list(State)}),
case file:write_file(Filename, Binary) of
ok ->
{reply, ok, State};
Error ->
{reply, {error, Error}, State}
end;
handle_call(stop, _From, State) ->
{stop, normal, ok, State};
handle_call(Command, _From, State) ->
{reply, {error, {undefined, Command}}, State}.
%% -------------------------------------------------------------------- %%
%%
%% handle_cast
%%
%% -------------------------------------------------------------------- %%
handle_cast(_, State) ->
{noreply, State}.
%% -------------------------------------------------------------------- %%
%%
%% handle_info
%%
%% -------------------------------------------------------------------- %%
handle_info(_Info, State) ->
{noreply, State}.
%% -------------------------------------------------------------------- %%
%%
%% termination
%%
%% -------------------------------------------------------------------- %%
terminate(_Reason, _State) ->
ok.
%% -------------------------------------------------------------------- %%
%%
%% code_change
%%
%% -------------------------------------------------------------------- %%
code_change(_OldVsn, State, _Extra) ->
{ok, State}.
%% -------------------------------------------------------------------- %%
%%
%% AUX
%%
%% -------------------------------------------------------------------- %%
% summate
summate_locks(Locks) -> summate_locks(Locks, #stats{ tries = 0, colls = 0, time = 0, nt = 0}).
summate_locks([], Stats) -> Stats;
summate_locks([L|Ls], #stats{ tries = Tries, colls = Colls, time = Time, nt = Nt, hist = Hist}) ->
S = summate_stats(L#lock.stats),
summate_locks(Ls, #stats{
tries = Tries + S#stats.tries,
colls = Colls + S#stats.colls,
time = Time + S#stats.time,
nt = Nt + S#stats.nt,
hist = summate_histogram(Hist, S#stats.hist)
}).
summate_stats(Stats) -> summate_stats(Stats, #stats{ tries = 0, colls = 0, time = 0, nt = 0}).
summate_stats([], Stats) -> Stats;
summate_stats([S|Ss], #stats{ tries = Tries, colls = Colls, time = Time, nt = Nt, hist = Hist}) ->
summate_stats(Ss, #stats{
tries = Tries + S#stats.tries,
colls = Colls + S#stats.colls,
time = Time + S#stats.time,
nt = Nt + S#stats.nt,
hist = summate_histogram(Hist, S#stats.hist)
}).
%% first call is undefined
summate_histogram(Tup,undefined) when is_tuple(Tup) -> Tup;
summate_histogram(undefined,Tup) when is_tuple(Tup) -> Tup;
summate_histogram(Hs1,Hs2) ->
list_to_tuple([ A + B || {A,B} <- lists:zip(tuple_to_list(Hs1),tuple_to_list(Hs2))]).
%% manipulators
filter_locks_type(Locks, undefined) -> Locks;
filter_locks_type(Locks, all) -> Locks;
filter_locks_type(Locks, Types) when is_list(Types) ->
[ L || L <- Locks, lists:member(L#lock.type, Types)];
filter_locks_type(Locks, Type) ->
[ L || L <- Locks, L#lock.type =:= Type].
filter_locks(Locks, {Lockname, Ids}) when is_list(Ids) ->
[ L || L <- Locks, L#lock.name =:= Lockname, lists:member(L#lock.id, Ids)];
filter_locks(Locks, {Lockname, Id}) ->
[ L || L <- Locks, L#lock.name =:= Lockname, L#lock.id =:= Id ];
filter_locks(Locks, Lockname) ->
[ L || L <- Locks, L#lock.name =:= Lockname ].
% order of processing
% 2. cut thresholds
% 3. sort locks
% 4. max length of locks
filter_print(PLs, Opts) ->
TLs = threshold_locks(PLs, proplists:get_value(thresholds, Opts, [])),
SLs = sort_locks(TLs, proplists:get_value(sort, Opts, time)),
CLs = cut_locks(SLs, proplists:get_value(max_locks, Opts, none)),
reverse_locks(CLs, proplists:get_value(reverse, Opts, false)).
sort_locks(Locks, name) -> reverse_sort_locks(#print.name, Locks);
sort_locks(Locks, id) -> reverse_sort_locks(#print.id, Locks);
sort_locks(Locks, type) -> reverse_sort_locks(#print.type, Locks);
sort_locks(Locks, tries) -> reverse_sort_locks(#print.tries, Locks);
sort_locks(Locks, colls) -> reverse_sort_locks(#print.colls, Locks);
sort_locks(Locks, ratio) -> reverse_sort_locks(#print.cr, Locks);
sort_locks(Locks, time) -> reverse_sort_locks(#print.time, Locks);
sort_locks(Locks, _) -> sort_locks(Locks, time).
reverse_sort_locks(Ix, Locks) ->
lists:reverse(lists:keysort(Ix, Locks)).
% cut locks not above certain thresholds
threshold_locks(Locks, Thresholds) ->
Tries = proplists:get_value(tries, Thresholds, -1),
Colls = proplists:get_value(colls, Thresholds, -1),
Time = proplists:get_value(time, Thresholds, -1),
[ L || L <- Locks, L#print.tries > Tries, L#print.colls > Colls, L#print.time > Time].
cut_locks(Locks, N) when is_integer(N), N > 0 -> lists:sublist(Locks, N);
cut_locks(Locks, _) -> Locks.
%% reversal
reverse_locks(Locks, true) -> lists:reverse(Locks);
reverse_locks(Locks, _) -> Locks.
%%
string_names([]) -> "";
string_names(Names) -> string_names(Names, []).
string_names([Name], Strings) -> strings(lists:reverse([term2string(Name) | Strings]));
string_names([Name|Names],Strings) -> string_names(Names, [term2string(Name) ++ ","|Strings]).
%% combine_locations
%% In:
%% Locations :: [#lock{}] | [#stats{}]
%% Out:
%% [{{File,Line}, #stats{}, [Lockname]}]
combine_locations(Locations) -> gb_trees:values(combine_locations(Locations, gb_trees:empty())).
combine_locations([], Tree) -> Tree;
combine_locations([S|_] = Stats, Tree) when is_record(S, stats) ->
combine_locations(Stats, undefined, Tree);
combine_locations([#lock{ stats = Stats, name = Name}|Ls], Tree) ->
combine_locations(Ls, combine_locations(Stats, Name, Tree)).
combine_locations([], _, Tree) -> Tree;
combine_locations([S|Ss], Name, Tree) when is_record(S, stats)->
Key = {S#stats.file, S#stats.line},
Tree1 = case gb_trees:lookup(Key, Tree) of
none ->
gb_trees:insert(Key, {S, [Name]}, Tree);
{value, {C, Names}} ->
NewNames = case lists:member(Name, Names) of
true -> Names;
_ -> [Name | Names]
end,
gb_trees:update(Key, {
C#stats{
tries = C#stats.tries + S#stats.tries,
colls = C#stats.colls + S#stats.colls,
time = C#stats.time + S#stats.time,
nt = C#stats.nt + S#stats.nt
}, NewNames}, Tree)
end,
combine_locations(Ss, Name, Tree1).
%% combines all statistics for a class (name) lock
%% id's are translated to #id's.
combine_classes(Locks, true) -> combine_classes1(Locks, gb_trees:empty());
combine_classes(Locks, _) -> Locks.
combine_classes1([], Tree) -> gb_trees:values(Tree);
combine_classes1([L|Ls], Tree) ->
Key = L#lock.name,
case gb_trees:lookup(Key, Tree) of
none ->
combine_classes1(Ls, gb_trees:insert(Key, L#lock{ id = 1 }, Tree));
{value, C} ->
combine_classes1(Ls, gb_trees:update(Key, C#lock{
id = C#lock.id + 1,
stats = L#lock.stats ++ C#lock.stats
}, Tree))
end.
locks_ids(Locks) -> locks_ids(Locks, []).
locks_ids([], Out) -> Out;
locks_ids([#lock{ name = Key } = L|Ls], Out) ->
case proplists:get_value(Key, Out) of
undefined -> locks_ids(Ls, [{Key, [L#lock.id]}|Out]);
Ids -> locks_ids(Ls, [{Key, [L#lock.id|Ids]}|proplists:delete(Key,Out)])
end.
stats2print(Stats, Duration) ->
lists:map(fun
(S) ->
#print{entry = term2string("~tp:~p", [S#stats.file, S#stats.line]),
colls = S#stats.colls,
tries = S#stats.tries,
cr = percent(S#stats.colls, S#stats.tries),
time = S#stats.time,
dtr = percent(S#stats.time, Duration),
hist = format_histogram(S#stats.hist)}
end, Stats).
locks2print(Locks, Duration) ->
lists:map( fun
(L) ->
#stats{tries = Tries,
colls = Colls,
time = Time,
hist = Hist} = summate_stats(L#lock.stats),
Cr = percent(Colls, Tries),
Dtr = percent(Time, Duration),
#print{name = L#lock.name,
id = L#lock.id,
type = L#lock.type,
tries = Tries,
colls = Colls,
hist = format_histogram(Hist),
cr = Cr,
time = Time,
dtr = Dtr}
end, Locks).
format_histogram(Tup) when is_tuple(Tup) ->
Vs = tuple_to_list(Tup),
Max = lists:max(Vs),
case Max of
0 -> string_histogram(Vs);
_ -> string_histogram([case V of 0 -> 0; _ -> V/Max end || V <- Vs])
end.
string_histogram(Vs) ->
[$||histogram_values_to_string(Vs,$|)].
histogram_values_to_string([0|Vs],End) ->
[$\s|histogram_values_to_string(Vs,End)];
histogram_values_to_string([V|Vs],End) when V > 0.66 ->
[$X|histogram_values_to_string(Vs,End)];
histogram_values_to_string([V|Vs],End) when V > 0.33 ->
[$x|histogram_values_to_string(Vs,End)];
histogram_values_to_string([_|Vs],End) ->
[$.|histogram_values_to_string(Vs,End)];
histogram_values_to_string([],End) ->
[End].
%% state making
data2state(Data, State) ->
Duration = time2us(proplists:get_value(duration, Data)),
Rawlocks = proplists:get_value(locks, Data),
Locks = locks2records(Rawlocks),
State#state{
duration = Duration,
locks = Locks
}.
locks2records([{Name, Id, Type, Stats}|Locks]) ->
[#lock{name = Name,
id = clean_id_creation(Id),
type = Type,
stats = stats2record(Stats)}|locks2records(Locks)];
locks2records([]) -> [].
%% new stats with histogram
stats2record([{{File,Line},{Tries,Colls,{S,Ns,N}},Hist}|Stats]) ->
[#stats{file = File,
line = Line,
hist = Hist,
tries = Tries,
colls = Colls,
time = time2us({S, Ns}),
nt = N} | stats2record(Stats)];
%% old stats without histogram
stats2record([{{File,Line},{Tries,Colls,{S,Ns,N}}}|Stats]) ->
[#stats{file = File,
line = Line,
hist = {},
tries = Tries,
colls = Colls,
time = time2us({S, Ns}),
nt = N} | stats2record(Stats)];
stats2record([]) -> [].
clean_id_creation(Id) when is_pid(Id) ->
Bin = term_to_binary(Id),
<<H:3/binary, L:16, Node:L/binary, Ids:8/binary, _Creation/binary>> = Bin,
Bin2 = list_to_binary([H, bytes16(L), Node, Ids, 0]),
binary_to_term(Bin2);
clean_id_creation(Id) when is_port(Id) ->
Bin = term_to_binary(Id),
<<H:3/binary, L:16, Node:L/binary, Ids:4/binary, _Creation/binary>> = Bin,
Bin2 = list_to_binary([H, bytes16(L), Node, Ids, 0]),
binary_to_term(Bin2);
clean_id_creation(Id) ->
Id.
%% serializer
state_default(Field) -> proplists:get_value(Field, state2list(#state{})).
state2list(State) ->
[_|Values] = tuple_to_list(State),
lists:zipwith(fun
(locks, Locks) -> {locks, [lock2list(Lock) || Lock <- Locks]};
(X, Y) -> {X,Y}
end, record_info(fields, state), Values).
lock_default(Field) -> proplists:get_value(Field, lock2list(#lock{})).
lock2list(Lock) ->
[_|Values] = tuple_to_list(Lock),
lists:zip(record_info(fields, lock), Values).
list2state(List) ->
list_to_tuple([state|list2state(record_info(fields, state), List)]).
list2state([], _) -> [];
list2state([locks|Fs], List) ->
Locks = [list2lock(Lock) || Lock <- proplists:get_value(locks, List, [])],
[Locks|list2state(Fs,List)];
list2state([F|Fs], List) ->
[proplists:get_value(F, List, state_default(F))|list2state(Fs, List)].
list2lock(Ls) ->
list_to_tuple([lock|list2lock(record_info(fields, lock), Ls)]).
list2lock([],_) -> [];
list2lock([stats=F|Fs], Ls) ->
Stats = stats2stats(proplists:get_value(F, Ls, lock_default(F))),
[Stats|list2lock(Fs, Ls)];
list2lock([F|Fs], Ls) ->
[proplists:get_value(F, Ls, lock_default(F))|list2lock(Fs, Ls)].
%% process old stats (hack)
%% old stats had no histograms
%% in future versions stats should be serialized as a list, not a record
stats2stats([]) -> [];
stats2stats([Stat|Stats]) ->
Sz = record_info(size, stats),
[stat2stat(Stat,Sz)|stats2stats(Stats)].
stat2stat(Stat,Sz) when tuple_size(Stat) =:= Sz -> Stat;
stat2stat(Stat,_) ->
%% assume no histogram at the end
list_to_tuple(tuple_to_list(Stat) ++ [{0}]).
%% printing
%% print_lock_information
%% In:
%% Locks :: [#lock{}]
%% Print :: [Type | {Type, integer()}]
%%
%% Out:
%% ok
auto_print_width(Locks, Print) ->
% iterate all lock entries to save all max length values
% these are records, so we do a little tuple <-> list smashing
R = lists:foldl(fun
(L, Max) ->
list_to_tuple(lists:reverse(lists:foldl(fun
({print,print}, Out) -> [print|Out];
({Str, Len}, Out) -> [erlang:min(erlang:max(length(s(Str))+1,Len),80)|Out]
end, [], lists:zip(tuple_to_list(L), tuple_to_list(Max)))))
end, #print{ id=4, type=5, entry=5, name=6, tries=8, colls=13, cr=16, time=11, dtr=14, hist=20 },
Locks),
% Setup the offsets for later pruning
Offsets = [
{id, R#print.id},
{name, R#print.name},
{type, R#print.type},
{entry, R#print.entry},
{tries, R#print.tries},
{colls, R#print.colls},
{ratio, R#print.cr},
{time, R#print.time},
{duration, R#print.dtr},
{histogram, R#print.hist}
],
% Prune offsets to only allow specified print options
lists:foldr(fun
({Type, W}, Out) -> [{Type, W}|Out];
(Type, Out) -> [proplists:lookup(Type, Offsets)|Out]
end, [], Print).
print_lock_information(Locks, Print) ->
% remake Print to autosize entries
AutoPrint = auto_print_width(Locks, Print),
print_header(AutoPrint),
lists:foreach(fun
(L) ->
print_lock(L, AutoPrint)
end, Locks),
ok.
print_header(Opts) ->
Header = #print{
name = "lock",
id = "id",
type = "type",
entry = "location",
tries = "#tries",
colls = "#collisions",
cr = "collisions [%]",
time = "time [us]",
dtr = "duration [%]",
hist = "histogram [log2(us)]"
},
Divider = #print{
name = lists:duplicate(1 + length(Header#print.name), 45),
id = lists:duplicate(1 + length(Header#print.id), 45),
type = lists:duplicate(1 + length(Header#print.type), 45),
entry = lists:duplicate(1 + length(Header#print.entry), 45),
tries = lists:duplicate(1 + length(Header#print.tries), 45),
colls = lists:duplicate(1 + length(Header#print.colls), 45),
cr = lists:duplicate(1 + length(Header#print.cr), 45),
time = lists:duplicate(1 + length(Header#print.time), 45),
dtr = lists:duplicate(1 + length(Header#print.dtr), 45),
hist = lists:duplicate(1 + length(Header#print.hist), 45)
},
print_lock(Header, Opts),
print_lock(Divider, Opts),
ok.
print_lock(L, Opts) ->
print(strings(format_lock(L, Opts))).
format_lock(_, []) -> [];
format_lock(L, [Opt|Opts]) ->
case Opt of
id -> [{space, 25, s(L#print.id) } | format_lock(L, Opts)];
{id, W} -> [{space, W, s(L#print.id) } | format_lock(L, Opts)];
type -> [{space, 18, s(L#print.type) } | format_lock(L, Opts)];
{type, W} -> [{space, W, s(L#print.type) } | format_lock(L, Opts)];
entry -> [{space, 30, s(L#print.entry)} | format_lock(L, Opts)];
{entry, W} -> [{space, W, s(L#print.entry)} | format_lock(L, Opts)];
name -> [{space, 22, s(L#print.name) } | format_lock(L, Opts)];
{name, W} -> [{space, W, s(L#print.name) } | format_lock(L, Opts)];
tries -> [{space, 12, s(L#print.tries)} | format_lock(L, Opts)];
{tries, W} -> [{space, W, s(L#print.tries)} | format_lock(L, Opts)];
colls -> [{space, 14, s(L#print.colls)} | format_lock(L, Opts)];
{colls, W} -> [{space, W, s(L#print.colls)} | format_lock(L, Opts)];
ratio -> [{space, 20, s(L#print.cr) } | format_lock(L, Opts)];
{ratio, W} -> [{space, W, s(L#print.cr) } | format_lock(L, Opts)];
time -> [{space, 15, s(L#print.time) } | format_lock(L, Opts)];
{time, W} -> [{space, W, s(L#print.time) } | format_lock(L, Opts)];
duration -> [{space, 20, s(L#print.dtr) } | format_lock(L, Opts)];
{duration, W} -> [{space, W, s(L#print.dtr) } | format_lock(L, Opts)];
histogram -> [{space, 20, s(L#print.hist) } | format_lock(L, Opts)];
{histogram, W} -> [{left, W - length(s(L#print.hist)) - 1, s(L#print.hist)} | format_lock(L, Opts)];
_ -> format_lock(L, Opts)
end.
print_state_information(#state{locks = Locks} = State) ->
Stats = summate_locks(Locks),
print("information:"),
print(kv("#locks", s(length(Locks)))),
print(kv("duration", s(State#state.duration) ++ " us" ++ " (" ++ s(State#state.duration/1000000) ++ " s)")),
print("\nsummated stats:"),
print(kv("#tries", s(Stats#stats.tries))),
print(kv("#colls", s(Stats#stats.colls))),
print(kv("wait time", s(Stats#stats.time) ++ " us" ++ " ( " ++ s(Stats#stats.time/1000000) ++ " s)")),
print(kv("percent of duration", s(Stats#stats.time/State#state.duration*100) ++ " %")),
ok.
print_full_histogram(T) when is_tuple(T) ->
Vs = tuple_to_list(T),
Max = lists:max(Vs),
W = 60,
print_full_histogram(0,Vs,Max,W).
print_full_histogram(_,[],_,_) -> ok;
print_full_histogram(Ix,[V|Vs],0,W) ->
io:format("~2w = log2 : ~8w |~n", [Ix,V]),
print_full_histogram(Ix+1,Vs,0,W);
print_full_histogram(Ix,[V|Vs],Max,W) ->
io:format("~2w = log2 : ~8w | ~s~n", [Ix,V,lists:duplicate(trunc(W*(V/Max)), $#)]),
print_full_histogram(Ix+1,Vs,Max,W).
%% AUX
time2us({S, Ns}) -> S*1000000 + (Ns div 1000).
percent(_,0) -> 0.0;
percent(T,N) -> T/N*100.
options(Opts, Default) when is_list(Default) ->
options1(proplists:unfold(Opts), Default).
options1([], Defaults) -> Defaults;
options1([{Key, Value}|Opts], Defaults) ->
case proplists:get_value(Key, Defaults) of
undefined -> options1(Opts, [{Key, Value} | Defaults]);
_ -> options1(Opts, [{Key, Value} | proplists:delete(Key, Defaults)])
end.
%%% AUX STRING FORMATTING
print(String) -> io:format("~ts~n", [String]).
kv(Key, Value) -> kv(Key, Value, 20).
kv(Key, Value, Offset) -> term2string(term2string("~~~ps : ~~s", [Offset]),[Key, Value]).
s(T) when is_float(T) -> term2string("~.4f", [T]);
s(T) when is_list(T) -> term2string("~ts", [T]);
s(T) -> term2string(T).
strings(Strings) -> strings(Strings, []).
strings([], Out) -> Out;
strings([{space, N, S} | Ss], Out) -> strings(Ss, Out ++ term2string(term2string("~~~ws", [N]), [S]));
strings([{left, N, S} | Ss], Out) -> strings(Ss, Out ++ term2string(term2string(" ~~s~~~ws", [N]), [S,""]));
strings([S|Ss], Out) -> strings(Ss, Out ++ term2string("~ts", [S])).
-define(SMALL_ATOM_UTF8_EXT, $w).
-define(ATOM_UTF8_EXT, $v).
-define(ATOM_EXT, $d).
term2string({M,F,A}) when is_atom(M), is_atom(F), is_integer(A) -> term2string("~p:~p/~p", [M,F,A]);
term2string(Term) when is_port(Term) ->
% ex #Port<6442.816>
case term_to_binary(Term) of
<<_:2/binary, ?SMALL_ATOM_UTF8_EXT, L:8, Node:L/binary, Ids:32, _/binary>> ->
term2string("#Port<~ts.~w>", [Node, Ids]);
<<_:2/binary, ?ATOM_UTF8_EXT, L:16, Node:L/binary, Ids:32, _/binary>> ->
term2string("#Port<~ts.~w>", [Node, Ids]);
<<_:2/binary, ?ATOM_EXT, L:16, Node:L/binary, Ids:32, _/binary>> ->
term2string("#Port<~s.~w>", [Node, Ids])
end;
term2string(Term) when is_pid(Term) ->
% ex <0.80.0>
case term_to_binary(Term) of
<<_:2/binary, ?SMALL_ATOM_UTF8_EXT, L:8, Node:L/binary, Ids:32, Serial:32, _/binary>> ->
term2string("<~ts.~w.~w>", [Node, Ids, Serial]);
<<_:2/binary, ?ATOM_UTF8_EXT, L:16, Node:L/binary, Ids:32, Serial:32, _/binary>> ->
term2string("<~ts.~w.~w>", [Node, Ids, Serial]);
<<_:2/binary, ?ATOM_EXT, L:16, Node:L/binary, Ids:32, Serial:32, _/binary>> ->
term2string("<~s.~w.~w>", [Node, Ids, Serial])
end;
term2string(Term) -> term2string("~w", [Term]).
term2string(Format, Terms) -> lists:flatten(io_lib:format(Format, Terms)).
%%% AUX id binary
bytes16(Value) ->
B0 = Value band 255,
B1 = (Value bsr 8) band 255,
<<B1, B0>>.
bytes32(Value) ->
B0 = Value band 255,
B1 = (Value bsr 8) band 255,
B2 = (Value bsr 16) band 255,
B3 = (Value bsr 24) band 255,
<<B3, B2, B1, B0>>.