Gitiles
Code Review Sign In
realtimeroboticsgroup.org / RealtimeRoboticsGroup / test / 6bc3dcedf4a71eefba95085f56c48a7c0d0ceef3 / . / aos / events / logging / logger_test.cc
blob: b6a30cb40b75a32458ec2bef28df5c43a3c04cf6 [file] [log] [blame]
#include "aos/events/logging/logger.h"
#include "aos/events/event_loop.h"
#include "aos/events/ping_lib.h"
#include "aos/events/pong_lib.h"
#include "aos/events/simulated_event_loop.h"
#include "glog/logging.h"
#include "gmock/gmock.h"
#include "gtest/gtest.h"
namespace aos {
namespace logger {
namespace testing {
namespace chrono = std::chrono;
class LoggerTest : public ::testing::Test {
public:
LoggerTest()
: config_(
aos::configuration::ReadConfig("aos/events/pingpong_config.json")),
event_loop_factory_(&config_.message()),
ping_event_loop_(event_loop_factory_.MakeEventLoop("ping")),
ping_(ping_event_loop_.get()),
pong_event_loop_(event_loop_factory_.MakeEventLoop("pong")),
pong_(pong_event_loop_.get()) {}
// Config and factory.
aos::FlatbufferDetachedBuffer<aos::Configuration> config_;
SimulatedEventLoopFactory event_loop_factory_;
// Event loop and app for Ping
std::unique_ptr<EventLoop> ping_event_loop_;
Ping ping_;
// Event loop and app for Pong
std::unique_ptr<EventLoop> pong_event_loop_;
Pong pong_;
};
// Tests that we can startup at all. This confirms that the channels are all in
// the config.
TEST_F(LoggerTest, Starts) {
const ::std::string tmpdir(getenv("TEST_TMPDIR"));
const ::std::string logfile = tmpdir + "/logfile.bfbs";
// Remove it.
unlink(logfile.c_str());
LOG(INFO) << "Logging data to " << logfile;
{
DetachedBufferWriter writer(logfile);
std::unique_ptr<EventLoop> logger_event_loop =
event_loop_factory_.MakeEventLoop("logger");
event_loop_factory_.RunFor(chrono::milliseconds(95));
Logger logger(&writer, logger_event_loop.get(),
std::chrono::milliseconds(100));
event_loop_factory_.RunFor(chrono::milliseconds(20000));
}
// Even though it doesn't make any difference here, exercise the logic for
// passing in a separate config.
LogReader reader(logfile, &config_.message());
// Confirm that we can remap logged channels to point to new buses.
reader.RemapLoggedChannel<aos::examples::Ping>("/test", "/original");
// This sends out the fetched messages and advances time to the start of the
// log file.
reader.Register();
EXPECT_THAT(reader.Nodes(), ::testing::ElementsAre(nullptr));
std::unique_ptr<EventLoop> test_event_loop =
reader.event_loop_factory()->MakeEventLoop("log_reader");
int ping_count = 10;
int pong_count = 10;
// Confirm that the ping value matches in the remapped channel location.
test_event_loop->MakeWatcher("/original/test",
[&ping_count](const examples::Ping &ping) {
EXPECT_EQ(ping.value(), ping_count + 1);
++ping_count;
});
// Confirm that the ping and pong counts both match, and the value also
// matches.
test_event_loop->MakeWatcher(
"/test", [&pong_count, &ping_count](const examples::Pong &pong) {
EXPECT_EQ(pong.value(), pong_count + 1);
++pong_count;
EXPECT_EQ(ping_count, pong_count);
});
reader.event_loop_factory()->RunFor(std::chrono::seconds(100));
EXPECT_EQ(ping_count, 2010);
}
// Tests that we can read and write rotated log files.
TEST_F(LoggerTest, RotatedLogFile) {
const ::std::string tmpdir(getenv("TEST_TMPDIR"));
const ::std::string logfile0 = tmpdir + "/logfile0.bfbs";
const ::std::string logfile1 = tmpdir + "/logfile1.bfbs";
// Remove it.
unlink(logfile0.c_str());
unlink(logfile1.c_str());
LOG(INFO) << "Logging data to " << logfile0 << " and " << logfile1;
{
DetachedBufferWriter writer0(logfile0);
DetachedBufferWriter writer1(logfile1);
std::unique_ptr<EventLoop> logger_event_loop =
event_loop_factory_.MakeEventLoop("logger");
event_loop_factory_.RunFor(chrono::milliseconds(95));
Logger logger(&writer0, logger_event_loop.get(),
std::chrono::milliseconds(100));
event_loop_factory_.RunFor(chrono::milliseconds(10000));
logger.Rotate(&writer1);
event_loop_factory_.RunFor(chrono::milliseconds(10000));
}
// Even though it doesn't make any difference here, exercise the logic for
// passing in a separate config.
LogReader reader(std::vector<std::string>{logfile0, logfile1},
&config_.message());
// Confirm that we can remap logged channels to point to new buses.
reader.RemapLoggedChannel<aos::examples::Ping>("/test", "/original");
// This sends out the fetched messages and advances time to the start of the
// log file.
reader.Register();
EXPECT_THAT(reader.Nodes(), ::testing::ElementsAre(nullptr));
std::unique_ptr<EventLoop> test_event_loop =
reader.event_loop_factory()->MakeEventLoop("log_reader");
int ping_count = 10;
int pong_count = 10;
// Confirm that the ping value matches in the remapped channel location.
test_event_loop->MakeWatcher("/original/test",
[&ping_count](const examples::Ping &ping) {
EXPECT_EQ(ping.value(), ping_count + 1);
++ping_count;
});
// Confirm that the ping and pong counts both match, and the value also
// matches.
test_event_loop->MakeWatcher(
"/test", [&pong_count, &ping_count](const examples::Pong &pong) {
EXPECT_EQ(pong.value(), pong_count + 1);
++pong_count;
EXPECT_EQ(ping_count, pong_count);
});
reader.event_loop_factory()->RunFor(std::chrono::seconds(100));
EXPECT_EQ(ping_count, 2010);
}
// Tests that a large number of messages per second doesn't overwhelm writev.
TEST_F(LoggerTest, ManyMessages) {
const ::std::string tmpdir(getenv("TEST_TMPDIR"));
const ::std::string logfile = tmpdir + "/logfile.bfbs";
// Remove the log file.
unlink(logfile.c_str());
LOG(INFO) << "Logging data to " << logfile;
{
DetachedBufferWriter writer(logfile);
std::unique_ptr<EventLoop> logger_event_loop =
event_loop_factory_.MakeEventLoop("logger");
std::unique_ptr<EventLoop> ping_spammer_event_loop =
event_loop_factory_.MakeEventLoop("ping_spammer");
aos::Sender<examples::Ping> ping_sender =
ping_spammer_event_loop->MakeSender<examples::Ping>("/test");
aos::TimerHandler *timer_handler =
ping_spammer_event_loop->AddTimer([&ping_sender]() {
aos::Sender<examples::Ping>::Builder builder =
ping_sender.MakeBuilder();
examples::Ping::Builder ping_builder =
builder.MakeBuilder<examples::Ping>();
CHECK(builder.Send(ping_builder.Finish()));
});
// 100 ms / 0.05 ms -> 2000 messages. Should be enough to crash it.
ping_spammer_event_loop->OnRun([&ping_spammer_event_loop, timer_handler]() {
timer_handler->Setup(ping_spammer_event_loop->monotonic_now(),
chrono::microseconds(50));
});
Logger logger(&writer, logger_event_loop.get(),
std::chrono::milliseconds(100));
event_loop_factory_.RunFor(chrono::milliseconds(1000));
}
}
class MultinodeLoggerTest : public ::testing::Test {
public:
MultinodeLoggerTest()
: config_(aos::configuration::ReadConfig(
"aos/events/logging/multinode_pingpong_config.json")),
event_loop_factory_(&config_.message()),
pi1_(
configuration::GetNode(event_loop_factory_.configuration(), "pi1")),
pi2_(
configuration::GetNode(event_loop_factory_.configuration(), "pi2")),
tmp_dir_(getenv("TEST_TMPDIR")),
logfile_base_(tmp_dir_ + "/multi_logfile"),
logfiles_({logfile_base_ + "_pi1_data.bfbs",
logfile_base_ + "_pi2_data/test/aos.examples.Pong.bfbs",
logfile_base_ + "_pi2_data.bfbs"}),
ping_event_loop_(event_loop_factory_.MakeEventLoop("ping", pi1_)),
ping_(ping_event_loop_.get()),
pong_event_loop_(event_loop_factory_.MakeEventLoop("pong", pi2_)),
pong_(pong_event_loop_.get()) {
// Go through and remove the logfiles if they already exist.
for (const auto file : logfiles_) {
unlink(file.c_str());
}
LOG(INFO) << "Logging data to " << logfiles_[0] << ", " << logfiles_[1]
<< " and " << logfiles_[2];
}
struct LoggerState {
std::unique_ptr<EventLoop> event_loop;
std::unique_ptr<Logger> logger;
};
LoggerState MakeLogger(const Node *node) {
return {event_loop_factory_.MakeEventLoop("logger", node), {}};
}
void StartLogger(LoggerState *logger) {
logger->logger = std::make_unique<Logger>(
std::make_unique<MultiNodeLogNamer>(logfile_base_,
logger->event_loop->configuration(),
logger->event_loop->node()),
logger->event_loop.get(), chrono::milliseconds(100));
}
// Config and factory.
aos::FlatbufferDetachedBuffer<aos::Configuration> config_;
SimulatedEventLoopFactory event_loop_factory_;
const Node *pi1_;
const Node *pi2_;
std::string tmp_dir_;
std::string logfile_base_;
std::array<std::string, 3> logfiles_;
std::unique_ptr<EventLoop> ping_event_loop_;
Ping ping_;
std::unique_ptr<EventLoop> pong_event_loop_;
Pong pong_;
};
// Counts the number of messages on a channel (returns channel, count) for every
// message matching matcher()
std::vector<std::pair<int, int>> CountChannelsMatching(
std::string_view filename,
std::function<bool(const MessageHeader *)> matcher) {
MessageReader message_reader(filename);
std::vector<int> counts(
message_reader.log_file_header()->configuration()->channels()->size(), 0);
while (true) {
std::optional<FlatbufferVector<MessageHeader>> msg =
message_reader.ReadMessage();
if (!msg) {
break;
}
if (matcher(&msg.value().message())) {
counts[msg.value().message().channel_index()]++;
}
}
std::vector<std::pair<int, int>> result;
int channel = 0;
for (size_t i = 0; i < counts.size(); ++i) {
if (counts[i] != 0) {
result.push_back(std::make_pair(channel, counts[i]));
}
++channel;
}
return result;
}
// Counts the number of messages (channel, count) for all data messages.
std::vector<std::pair<int, int>> CountChannelsData(std::string_view filename) {
return CountChannelsMatching(filename, [](const MessageHeader *msg) {
if (msg->has_data()) {
CHECK(!msg->has_monotonic_remote_time());
CHECK(!msg->has_realtime_remote_time());
CHECK(!msg->has_remote_queue_index());
return true;
}
return false;
});
}
// Counts the number of messages (channel, count) for all timestamp messages.
std::vector<std::pair<int, int>> CountChannelsTimestamp(
std::string_view filename) {
return CountChannelsMatching(filename, [](const MessageHeader *msg) {
if (!msg->has_data()) {
CHECK(msg->has_monotonic_remote_time());
CHECK(msg->has_realtime_remote_time());
CHECK(msg->has_remote_queue_index());
return true;
}
return false;
});
}
// Tests that we can write and read simple multi-node log files.
TEST_F(MultinodeLoggerTest, SimpleMultiNode) {
{
LoggerState pi1_logger = MakeLogger(pi1_);
LoggerState pi2_logger = MakeLogger(pi2_);
event_loop_factory_.RunFor(chrono::milliseconds(95));
StartLogger(&pi1_logger);
StartLogger(&pi2_logger);
event_loop_factory_.RunFor(chrono::milliseconds(20000));
}
{
// Confirm that the headers are all for the correct nodes.
FlatbufferVector<LogFileHeader> logheader1 = ReadHeader(logfiles_[0]);
EXPECT_EQ(logheader1.message().node()->name()->string_view(), "pi1");
FlatbufferVector<LogFileHeader> logheader2 = ReadHeader(logfiles_[1]);
EXPECT_EQ(logheader2.message().node()->name()->string_view(), "pi2");
FlatbufferVector<LogFileHeader> logheader3 = ReadHeader(logfiles_[2]);
EXPECT_EQ(logheader3.message().node()->name()->string_view(), "pi2");
// Timing reports, pings
EXPECT_THAT(CountChannelsData(logfiles_[0]),
::testing::ElementsAre(::testing::Pair(1, 40),
::testing::Pair(4, 2001)));
// Timestamps for pong
EXPECT_THAT(CountChannelsTimestamp(logfiles_[0]),
::testing::ElementsAre(::testing::Pair(5, 2001)));
// Pong data.
EXPECT_THAT(CountChannelsData(logfiles_[1]),
::testing::ElementsAre(::testing::Pair(5, 2001)));
// No timestamps
EXPECT_THAT(CountChannelsTimestamp(logfiles_[1]), ::testing::ElementsAre());
// Timing reports and pongs.
EXPECT_THAT(CountChannelsData(logfiles_[2]),
::testing::ElementsAre(::testing::Pair(3, 40),
::testing::Pair(5, 2001)));
// And ping timestamps.
EXPECT_THAT(CountChannelsTimestamp(logfiles_[2]),
::testing::ElementsAre(::testing::Pair(4, 2001)));
}
LogReader reader({std::vector<std::string>{logfiles_[0]},
std::vector<std::string>{logfiles_[2]}});
SimulatedEventLoopFactory log_reader_factory(reader.logged_configuration());
log_reader_factory.set_send_delay(chrono::microseconds(0));
// This sends out the fetched messages and advances time to the start of the
// log file.
reader.Register(&log_reader_factory);
const Node *pi1 =
configuration::GetNode(log_reader_factory.configuration(), "pi1");
const Node *pi2 =
configuration::GetNode(log_reader_factory.configuration(), "pi2");
EXPECT_THAT(reader.Nodes(), ::testing::ElementsAre(pi1, pi2));
reader.event_loop_factory()->set_send_delay(chrono::microseconds(0));
std::unique_ptr<EventLoop> pi1_event_loop =
log_reader_factory.MakeEventLoop("test", pi1);
std::unique_ptr<EventLoop> pi2_event_loop =
log_reader_factory.MakeEventLoop("test", pi2);
int pi1_ping_count = 10;
int pi2_ping_count = 10;
int pi1_pong_count = 10;
int pi2_pong_count = 10;
// Confirm that the ping value matches.
pi1_event_loop->MakeWatcher(
"/test", [&pi1_ping_count, &pi1_event_loop](const examples::Ping &ping) {
VLOG(1) << "Pi1 ping " << FlatbufferToJson(&ping)
<< pi1_event_loop->context().monotonic_remote_time << " -> "
<< pi1_event_loop->context().monotonic_event_time;
EXPECT_EQ(ping.value(), pi1_ping_count + 1);
EXPECT_EQ(pi1_event_loop->context().monotonic_remote_time,
pi1_ping_count * chrono::milliseconds(10) +
monotonic_clock::epoch());
EXPECT_EQ(pi1_event_loop->context().realtime_remote_time,
pi1_ping_count * chrono::milliseconds(10) +
realtime_clock::epoch());
EXPECT_EQ(pi1_event_loop->context().monotonic_remote_time,
pi1_event_loop->context().monotonic_event_time);
EXPECT_EQ(pi1_event_loop->context().realtime_remote_time,
pi1_event_loop->context().realtime_event_time);
++pi1_ping_count;
});
pi2_event_loop->MakeWatcher(
"/test", [&pi2_ping_count, &pi2_event_loop](const examples::Ping &ping) {
VLOG(1) << "Pi2 ping " << FlatbufferToJson(&ping)
<< pi2_event_loop->context().monotonic_remote_time << " -> "
<< pi2_event_loop->context().monotonic_event_time;
EXPECT_EQ(ping.value(), pi2_ping_count + 1);
EXPECT_EQ(pi2_event_loop->context().monotonic_remote_time,
pi2_ping_count * chrono::milliseconds(10) +
monotonic_clock::epoch());
EXPECT_EQ(pi2_event_loop->context().realtime_remote_time,
pi2_ping_count * chrono::milliseconds(10) +
realtime_clock::epoch());
EXPECT_EQ(pi2_event_loop->context().monotonic_remote_time +
chrono::microseconds(150),
pi2_event_loop->context().monotonic_event_time);
EXPECT_EQ(pi2_event_loop->context().realtime_remote_time +
chrono::microseconds(150),
pi2_event_loop->context().realtime_event_time);
++pi2_ping_count;
});
constexpr ssize_t kQueueIndexOffset = 0;
// Confirm that the ping and pong counts both match, and the value also
// matches.
pi1_event_loop->MakeWatcher(
"/test", [&pi1_event_loop, &pi1_ping_count,
&pi1_pong_count](const examples::Pong &pong) {
VLOG(1) << "Pi1 pong " << FlatbufferToJson(&pong) << " at "
<< pi1_event_loop->context().monotonic_remote_time << " -> "
<< pi1_event_loop->context().monotonic_event_time;
EXPECT_EQ(pi1_event_loop->context().remote_queue_index,
pi1_pong_count + kQueueIndexOffset);
EXPECT_EQ(pi1_event_loop->context().monotonic_remote_time,
chrono::microseconds(200) +
pi1_pong_count * chrono::milliseconds(10) +
monotonic_clock::epoch());
EXPECT_EQ(pi1_event_loop->context().realtime_remote_time,
chrono::microseconds(200) +
pi1_pong_count * chrono::milliseconds(10) +
realtime_clock::epoch());
EXPECT_EQ(pi1_event_loop->context().monotonic_remote_time +
chrono::microseconds(150),
pi1_event_loop->context().monotonic_event_time);
EXPECT_EQ(pi1_event_loop->context().realtime_remote_time +
chrono::microseconds(150),
pi1_event_loop->context().realtime_event_time);
EXPECT_EQ(pong.value(), pi1_pong_count + 1);
++pi1_pong_count;
EXPECT_EQ(pi1_ping_count, pi1_pong_count);
});
pi2_event_loop->MakeWatcher(
"/test", [&pi2_event_loop, &pi2_ping_count,
&pi2_pong_count](const examples::Pong &pong) {
VLOG(1) << "Pi2 pong " << FlatbufferToJson(&pong) << " at "
<< pi2_event_loop->context().monotonic_remote_time << " -> "
<< pi2_event_loop->context().monotonic_event_time;
EXPECT_EQ(pi2_event_loop->context().remote_queue_index,
pi2_pong_count + kQueueIndexOffset - 9);
EXPECT_EQ(pi2_event_loop->context().monotonic_remote_time,
chrono::microseconds(200) +
pi2_pong_count * chrono::milliseconds(10) +
monotonic_clock::epoch());
EXPECT_EQ(pi2_event_loop->context().realtime_remote_time,
chrono::microseconds(200) +
pi2_pong_count * chrono::milliseconds(10) +
realtime_clock::epoch());
EXPECT_EQ(pi2_event_loop->context().monotonic_remote_time,
pi2_event_loop->context().monotonic_event_time);
EXPECT_EQ(pi2_event_loop->context().realtime_remote_time,
pi2_event_loop->context().realtime_event_time);
EXPECT_EQ(pong.value(), pi2_pong_count + 1);
++pi2_pong_count;
EXPECT_EQ(pi2_ping_count, pi2_pong_count);
});
log_reader_factory.Run();
EXPECT_EQ(pi1_ping_count, 2010);
EXPECT_EQ(pi2_ping_count, 2010);
EXPECT_EQ(pi1_pong_count, 2010);
EXPECT_EQ(pi2_pong_count, 2010);
reader.Deregister();
}
typedef MultinodeLoggerTest MultinodeLoggerDeathTest;
// Test that if we feed the replay with a mismatched node list that we die on
// the LogReader constructor.
TEST_F(MultinodeLoggerDeathTest, MultiNodeBadReplayConfig) {
{
LoggerState pi1_logger = MakeLogger(pi1_);
LoggerState pi2_logger = MakeLogger(pi2_);
event_loop_factory_.RunFor(chrono::milliseconds(95));
StartLogger(&pi1_logger);
StartLogger(&pi2_logger);
event_loop_factory_.RunFor(chrono::milliseconds(20000));
}
// Test that, if we add an additional node to the replay config that the
// logger complains about the mismatch in number of nodes.
FlatbufferDetachedBuffer<Configuration> extra_nodes_config =
configuration::MergeWithConfig(&config_.message(), R"({
"nodes": [
{
"name": "extra-node"
}
]
}
)");
EXPECT_DEATH(LogReader({std::vector<std::string>{logfiles_[0]},
std::vector<std::string>{logfiles_[2]}},
&extra_nodes_config.message()),
"Log file and replay config need to have matching nodes lists.");
;
}
// Tests that we can read log files where they don't start at the same monotonic
// time.
TEST_F(MultinodeLoggerTest, StaggeredStart) {
{
LoggerState pi1_logger = MakeLogger(pi1_);
LoggerState pi2_logger = MakeLogger(pi2_);
event_loop_factory_.RunFor(chrono::milliseconds(95));
StartLogger(&pi1_logger);
event_loop_factory_.RunFor(chrono::milliseconds(200));
StartLogger(&pi2_logger);
event_loop_factory_.RunFor(chrono::milliseconds(20000));
}
LogReader reader({std::vector<std::string>{logfiles_[0]},
std::vector<std::string>{logfiles_[2]}});
SimulatedEventLoopFactory log_reader_factory(reader.logged_configuration());
log_reader_factory.set_send_delay(chrono::microseconds(0));
// This sends out the fetched messages and advances time to the start of the
// log file.
reader.Register(&log_reader_factory);
const Node *pi1 =
configuration::GetNode(log_reader_factory.configuration(), "pi1");
const Node *pi2 =
configuration::GetNode(log_reader_factory.configuration(), "pi2");
EXPECT_THAT(reader.Nodes(), ::testing::ElementsAre(pi1, pi2));
reader.event_loop_factory()->set_send_delay(chrono::microseconds(0));
std::unique_ptr<EventLoop> pi1_event_loop =
log_reader_factory.MakeEventLoop("test", pi1);
std::unique_ptr<EventLoop> pi2_event_loop =
log_reader_factory.MakeEventLoop("test", pi2);
int pi1_ping_count = 30;
int pi2_ping_count = 30;
int pi1_pong_count = 30;
int pi2_pong_count = 30;
// Confirm that the ping value matches.
pi1_event_loop->MakeWatcher(
"/test", [&pi1_ping_count, &pi1_event_loop](const examples::Ping &ping) {
VLOG(1) << "Pi1 ping " << FlatbufferToJson(&ping)
<< pi1_event_loop->context().monotonic_remote_time << " -> "
<< pi1_event_loop->context().monotonic_event_time;
EXPECT_EQ(ping.value(), pi1_ping_count + 1);
++pi1_ping_count;
});
pi2_event_loop->MakeWatcher(
"/test", [&pi2_ping_count, &pi2_event_loop](const examples::Ping &ping) {
VLOG(1) << "Pi2 ping " << FlatbufferToJson(&ping)
<< pi2_event_loop->context().monotonic_remote_time << " -> "
<< pi2_event_loop->context().monotonic_event_time;
EXPECT_EQ(ping.value(), pi2_ping_count + 1);
++pi2_ping_count;
});
// Confirm that the ping and pong counts both match, and the value also
// matches.
pi1_event_loop->MakeWatcher(
"/test", [&pi1_event_loop, &pi1_ping_count,
&pi1_pong_count](const examples::Pong &pong) {
VLOG(1) << "Pi1 pong " << FlatbufferToJson(&pong) << " at "
<< pi1_event_loop->context().monotonic_remote_time << " -> "
<< pi1_event_loop->context().monotonic_event_time;
EXPECT_EQ(pong.value(), pi1_pong_count + 1);
++pi1_pong_count;
EXPECT_EQ(pi1_ping_count, pi1_pong_count);
});
pi2_event_loop->MakeWatcher(
"/test", [&pi2_event_loop, &pi2_ping_count,
&pi2_pong_count](const examples::Pong &pong) {
VLOG(1) << "Pi2 pong " << FlatbufferToJson(&pong) << " at "
<< pi2_event_loop->context().monotonic_remote_time << " -> "
<< pi2_event_loop->context().monotonic_event_time;
EXPECT_EQ(pong.value(), pi2_pong_count + 1);
++pi2_pong_count;
EXPECT_EQ(pi2_ping_count, pi2_pong_count);
});
log_reader_factory.Run();
EXPECT_EQ(pi1_ping_count, 2030);
EXPECT_EQ(pi2_ping_count, 2030);
EXPECT_EQ(pi1_pong_count, 2030);
EXPECT_EQ(pi2_pong_count, 2030);
reader.Deregister();
}
// Tests that we can read log files where the monotonic clocks drift and don't
// match correctly. While we are here, also test that different ending times
// also is readable.
TEST_F(MultinodeLoggerTest, MismatchedClocks) {
{
LoggerState pi2_logger = MakeLogger(pi2_);
NodeEventLoopFactory *pi2 =
event_loop_factory_.GetNodeEventLoopFactory(pi2_);
LOG(INFO) << "pi2 times: " << pi2->monotonic_now() << " "
<< pi2->realtime_now() << " distributed "
<< pi2->ToDistributedClock(pi2->monotonic_now());
const chrono::nanoseconds initial_pi2_offset = -chrono::seconds(1000);
chrono::nanoseconds pi2_offset = initial_pi2_offset;
pi2->SetDistributedOffset(-pi2_offset, 1.0);
LOG(INFO) << "pi2 times: " << pi2->monotonic_now() << " "
<< pi2->realtime_now() << " distributed "
<< pi2->ToDistributedClock(pi2->monotonic_now());
for (int i = 0; i < 95; ++i) {
pi2_offset += chrono::nanoseconds(200);
pi2->SetDistributedOffset(-pi2_offset, 1.0);
event_loop_factory_.RunFor(chrono::milliseconds(1));
}
StartLogger(&pi2_logger);
event_loop_factory_.RunFor(chrono::milliseconds(200));
{
// Run pi1's logger for only part of the time.
LoggerState pi1_logger = MakeLogger(pi1_);
StartLogger(&pi1_logger);
for (int i = 0; i < 20000; ++i) {
pi2_offset += chrono::nanoseconds(200);
pi2->SetDistributedOffset(-pi2_offset, 1.0);
event_loop_factory_.RunFor(chrono::milliseconds(1));
}
EXPECT_GT(pi2_offset - initial_pi2_offset,
event_loop_factory_.send_delay() +
event_loop_factory_.network_delay());
for (int i = 0; i < 40000; ++i) {
pi2_offset -= chrono::nanoseconds(200);
pi2->SetDistributedOffset(-pi2_offset, 1.0);
event_loop_factory_.RunFor(chrono::milliseconds(1));
}
}
// And log a bit more on pi2.
event_loop_factory_.RunFor(chrono::milliseconds(400));
}
LogReader reader({std::vector<std::string>{logfiles_[0]},
std::vector<std::string>{logfiles_[2]}});
SimulatedEventLoopFactory log_reader_factory(reader.logged_configuration());
log_reader_factory.set_send_delay(chrono::microseconds(0));
// This sends out the fetched messages and advances time to the start of the
// log file.
reader.Register(&log_reader_factory);
const Node *pi1 =
configuration::GetNode(log_reader_factory.configuration(), "pi1");
const Node *pi2 =
configuration::GetNode(log_reader_factory.configuration(), "pi2");
LOG(INFO) << "Done registering (pi1) "
<< log_reader_factory.GetNodeEventLoopFactory(pi1)->monotonic_now() << " "
<< log_reader_factory.GetNodeEventLoopFactory(pi1)->realtime_now();
LOG(INFO) << "Done registering (pi2) "
<< log_reader_factory.GetNodeEventLoopFactory(pi2)->monotonic_now() << " "
<< log_reader_factory.GetNodeEventLoopFactory(pi2)->realtime_now();
EXPECT_THAT(reader.Nodes(), ::testing::ElementsAre(pi1, pi2));
reader.event_loop_factory()->set_send_delay(chrono::microseconds(0));
std::unique_ptr<EventLoop> pi1_event_loop =
log_reader_factory.MakeEventLoop("test", pi1);
std::unique_ptr<EventLoop> pi2_event_loop =
log_reader_factory.MakeEventLoop("test", pi2);
int pi1_ping_count = 30;
int pi2_ping_count = 30;
int pi1_pong_count = 30;
int pi2_pong_count = 30;
// Confirm that the ping value matches.
pi1_event_loop->MakeWatcher(
"/test", [&pi1_ping_count, &pi1_event_loop](const examples::Ping &ping) {
VLOG(1) << "Pi1 ping " << FlatbufferToJson(&ping)
<< pi1_event_loop->context().monotonic_remote_time << " -> "
<< pi1_event_loop->context().monotonic_event_time;
EXPECT_EQ(ping.value(), pi1_ping_count + 1);
++pi1_ping_count;
});
pi2_event_loop->MakeWatcher(
"/test", [&pi2_ping_count, &pi2_event_loop](const examples::Ping &ping) {
VLOG(1) << "Pi2 ping " << FlatbufferToJson(&ping)
<< pi2_event_loop->context().monotonic_remote_time << " -> "
<< pi2_event_loop->context().monotonic_event_time;
EXPECT_EQ(ping.value(), pi2_ping_count + 1);
++pi2_ping_count;
});
// Confirm that the ping and pong counts both match, and the value also
// matches.
pi1_event_loop->MakeWatcher(
"/test", [&pi1_event_loop, &pi1_ping_count,
&pi1_pong_count](const examples::Pong &pong) {
VLOG(1) << "Pi1 pong " << FlatbufferToJson(&pong) << " at "
<< pi1_event_loop->context().monotonic_remote_time << " -> "
<< pi1_event_loop->context().monotonic_event_time;
EXPECT_EQ(pong.value(), pi1_pong_count + 1);
++pi1_pong_count;
EXPECT_EQ(pi1_ping_count, pi1_pong_count);
});
pi2_event_loop->MakeWatcher(
"/test", [&pi2_event_loop, &pi2_ping_count,
&pi2_pong_count](const examples::Pong &pong) {
VLOG(1) << "Pi2 pong " << FlatbufferToJson(&pong) << " at "
<< pi2_event_loop->context().monotonic_remote_time << " -> "
<< pi2_event_loop->context().monotonic_event_time;
EXPECT_EQ(pong.value(), pi2_pong_count + 1);
++pi2_pong_count;
EXPECT_EQ(pi2_ping_count, pi2_pong_count);
});
log_reader_factory.Run();
EXPECT_EQ(pi1_ping_count, 6030);
EXPECT_EQ(pi2_ping_count, 6030);
EXPECT_EQ(pi1_pong_count, 6030);
EXPECT_EQ(pi2_pong_count, 6030);
reader.Deregister();
}
// TODO(austin): We can write a test which recreates a logfile and confirms that
// we get it back. That is the ultimate test.
} // namespace testing
} // namespace logger
} // namespace aos