pxmlw6n2f/Gazebo_Distributed_TCP/test/integration/world_playback.cc

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2019-03-28 10:57:49 +08:00
/*
* Copyright (C) 2015 Open Source Robotics Foundation
*
* 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.
*
*/
#include <chrono>
#include <map>
#include <string>
#include <thread>
#include <tuple>
#include <boost/filesystem.hpp>
#include "gazebo/common/Time.hh"
#include "gazebo/physics/physics.hh"
#include "gazebo/test/ServerFixture.hh"
#include "gazebo/transport/TransportTypes.hh"
using namespace gazebo;
/// \brief Features to check in each log file.
/// The 1st element is the initial simulation time (frame #1).
/// The 2nd element is the simulation time at frame #2.
/// The 3rd element is the simulation time at frame #4.
/// The 4rd element is the last simulation time.
using FeaturesT = std::tuple<double, double, double, double>;
/// \brief List of log files for testing with their expected features.
/// The key of the map is the log file name.
/// The value is a tuple containing features to test (e.g.: sim times).
using LogFeatures_M = std::map<std::string, FeaturesT>;
// Contains the expected values for each log file under test.
LogFeatures_M logs =
{
{"state.log", FeaturesT {28.457, 28.457, 28.459, 31.745}},
{"state2.log", FeaturesT {23.700, 23.700, 23.702, 26.168}},
{"state3.log", FeaturesT {13.130, 15.778, 18.376, 22.773}}
};
/// \brief Helper class that initializes each test.
class WorldPlaybackTest : public ServerFixture,
public testing::WithParamInterface<const char *>
{
/// \brief Class constructor.
public: WorldPlaybackTest()
{
this->logName = std::string(this->GetParam());
boost::filesystem::path logPath = TEST_PATH;
logPath /= "logs/";
logPath /= this->logName;
// Start the server with a log file and paused.
this->LoadArgs("-u -p " + logPath.string());
this->world = physics::get_world("default");
// Prepare the transport.
this->node = transport::NodePtr(new transport::Node());
this->node->Init();
this->logPlaybackPub =
this->node->Advertise<msgs::LogPlaybackControl>("~/playback_control");
// Read expected values.
this->features = logs[this->logName];
std::this_thread::sleep_for(std::chrono::milliseconds(300));
}
/// \brief Gazebo transport node.
public: transport::NodePtr node;
/// \brief Pointer to the world.
public: physics::WorldPtr world;
/// \brief Publisher to control the playback of the world via messages.
public: transport::PublisherPtr logPlaybackPub;
/// \brief The name of the log file used for testing.
public: std::string logName;
/// \brief Expected features for the current log under test.
public: FeaturesT features;
};
/////////////////////////////////////////////////
/// \brief Check "pause".
TEST_P(WorldPlaybackTest, Pause)
{
ASSERT_TRUE(this->world != NULL);
EXPECT_TRUE(this->world->IsPaused());
// Send a message to unpause the world.
msgs::LogPlaybackControl msg;
msg.set_pause(false);
this->logPlaybackPub->Publish(msg);
// Wait for message to be processed
int sleep = 0;
int maxSleep = 3000;
while (this->world->IsPaused() && sleep < maxSleep)
{
gazebo::common::Time::MSleep(1);
sleep++;
}
EXPECT_FALSE(this->world->IsPaused());
// Send a message to pause the world.
msg.set_pause(true);
this->logPlaybackPub->Publish(msg);
// Wait for message to be processed
sleep = 0;
while (!this->world->IsPaused() && sleep < maxSleep)
{
gazebo::common::Time::MSleep(1);
sleep++;
}
EXPECT_TRUE(this->world->IsPaused());
}
/////////////////////////////////////////////////
/// \brief Check "multi_step".
TEST_P(WorldPlaybackTest, Step)
{
ASSERT_TRUE(this->world != NULL);
msgs::LogPlaybackControl msg;
common::Time expectedSimTime;
// Rewind the world.
expectedSimTime.Set(std::get<0>(this->features));
msg.set_rewind(true);
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 10, 20);
// Step +1
msg.Clear();
expectedSimTime.Set(std::get<1>(this->features));
msg.set_multi_step(1);
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 10, 20);
EXPECT_EQ(world->GetSimTime(), expectedSimTime);
// Step -1
msg.Clear();
expectedSimTime.Set(std::get<0>(this->features));
msg.set_multi_step(-1);
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 10, 30);
EXPECT_EQ(world->GetSimTime(), expectedSimTime);
// Step +3
msg.Clear();
expectedSimTime.Set(std::get<2>(this->features));
msg.set_multi_step(3);
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 10, 20);
EXPECT_EQ(world->GetSimTime(), expectedSimTime);
// Step -2
msg.Clear();
expectedSimTime.Set(std::get<1>(this->features));
msg.set_multi_step(-2);
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 10, 20);
EXPECT_EQ(world->GetSimTime(), expectedSimTime);
// Insane backwards jump.
msg.Clear();
expectedSimTime.Set(std::get<0>(this->features));
msg.set_multi_step(-9999);
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 20, 20);
EXPECT_EQ(world->GetSimTime(), expectedSimTime);
// Insane forward jump.
msg.Clear();
expectedSimTime.Set(std::get<3>(this->features));
msg.set_multi_step(999999);
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 100, 50);
EXPECT_EQ(this->world->GetSimTime(), expectedSimTime);
}
/////////////////////////////////////////////////
/// \brief Check "rewind".
TEST_P(WorldPlaybackTest, Rewind)
{
ASSERT_TRUE(this->world != NULL);
for (const auto steps : {0, 1, -99999, 99999, 10, 100})
{
// Step forward.
world->Step(steps);
// Rewind the world.
msgs::LogPlaybackControl msg;
common::Time expectedSimTime;
expectedSimTime.Set(std::get<0>(this->features));
msg.set_rewind(true);
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 10, 20);
EXPECT_EQ(world->GetSimTime(), expectedSimTime);
}
}
/////////////////////////////////////////////////
/// \brief Check "forward".
TEST_P(WorldPlaybackTest, Forward)
{
ASSERT_TRUE(this->world != NULL);
for (const auto steps : {1, 10, 0, 100})
{
// Step forward.
world->Step(steps);
// Fast forward the world.
msgs::LogPlaybackControl msg;
common::Time expectedSimTime;
expectedSimTime.Set(std::get<3>(this->features));
msg.set_forward(true);
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 50, 400);
EXPECT_EQ(world->GetSimTime(), expectedSimTime);
}
}
/////////////////////////////////////////////////
/// \brief Check "seek".
TEST_P(WorldPlaybackTest, Seek)
{
ASSERT_TRUE(this->world != NULL);
common::Time expectedSimTime;
// Move the simulation to the time at frame #2.
expectedSimTime.Set(std::get<1>(this->features));
auto msgExpectedTime = msgs::Convert(expectedSimTime);
msgs::LogPlaybackControl msg;
msg.mutable_seek()->set_sec(msgExpectedTime.sec());
msg.mutable_seek()->set_nsec(msgExpectedTime.nsec());
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 50, 50);
EXPECT_EQ(this->world->GetSimTime(), expectedSimTime);
// Move the simulation to the time at last frame.
expectedSimTime.Set(std::get<3>(this->features));
msgExpectedTime = msgs::Convert(expectedSimTime);
msg.Clear();
msg.mutable_seek()->set_sec(msgExpectedTime.sec());
msg.mutable_seek()->set_nsec(msgExpectedTime.nsec());
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 50, 50);
EXPECT_EQ(this->world->GetSimTime(), expectedSimTime);
// Specify a time slightly before #4.
expectedSimTime.Set(std::get<2>(this->features));
msgExpectedTime = msgs::Convert(expectedSimTime - 0.000001);
msg.mutable_seek()->set_sec(msgExpectedTime.sec());
msg.mutable_seek()->set_nsec(msgExpectedTime.nsec());
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 50, 50);
EXPECT_EQ(this->world->GetSimTime(), expectedSimTime);
// Specify a time before the initial time.
expectedSimTime.Set(std::get<0>(this->features));
msgExpectedTime = msgs::Convert(expectedSimTime - 1.0);
msg.mutable_seek()->set_sec(msgExpectedTime.sec());
msg.mutable_seek()->set_nsec(msgExpectedTime.nsec());
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 50, 50);
EXPECT_EQ(this->world->GetSimTime(), expectedSimTime);
// Specify a time after the last frame.
expectedSimTime.Set(std::get<3>(this->features));
msgExpectedTime = msgs::Convert(expectedSimTime + 1.0);
msg.mutable_seek()->set_sec(msgExpectedTime.sec());
msg.mutable_seek()->set_nsec(msgExpectedTime.nsec());
this->logPlaybackPub->Publish(msg);
this->WaitUntilSimTime(expectedSimTime, 50, 50);
EXPECT_EQ(this->world->GetSimTime(), expectedSimTime);
}
// Test with different log files.
// - state.log: File without <iterations> in each frame.
// - state2.log: File with <iterations> in each frame.
// - state3.log: File recording a simulation with an object that didn't move
// much. Two consecutive frames don't have consecutive
// simulation "iterations".
INSTANTIATE_TEST_CASE_P(LogFiles,
WorldPlaybackTest,
::testing::Values("state.log",
"state2.log",
"state3.log"));
/////////////////////////////////////////////////
int main(int argc, char **argv)
{
::testing::InitGoogleTest(&argc, argv);
return RUN_ALL_TESTS();
}