ppovb5fc7/gazebo/tools/gz_log.cc

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2019-03-25 11:01:43 +08:00
/*
* Copyright (C) 2012 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.
*
*/
#ifdef _WIN32
// Ensure that Winsock2.h is included before Windows.h, which can get
// pulled in by anybody (e.g., Boost).
#include <Winsock2.h>
#endif
#include <boost/algorithm/string.hpp>
#include <boost/date_time/posix_time/posix_time.hpp>
#include <boost/date_time/posix_time/posix_time_io.hpp>
#include <gazebo/util/util.hh>
#include "gz_log.hh"
sdf::ElementPtr g_stateSdf;
using namespace gazebo;
/////////////////////////////////////////////////
FilterBase::FilterBase(bool _xmlOutput, const std::string &_stamp)
: xmlOutput(_xmlOutput), stamp(_stamp)
{
}
/////////////////////////////////////////////////
std::ostringstream &FilterBase::Out(std::ostringstream &_stream,
const gazebo::physics::State &_state)
{
if (!this->xmlOutput && !this->stamp.empty())
{
std::ios_base::fmtflags flags = _stream.flags();
_stream.setf(std::ios::fixed);
if (this->stamp == "sim")
_stream << _state.GetSimTime().Double() << " ";
else if (this->stamp == "real")
_stream << _state.GetRealTime().Double() << " ";
else if (this->stamp == "wall")
_stream << _state.GetWallTime().Double() << " ";
else if (this->stamp == "iterations")
_stream << _state.GetIterations() << " ";
_stream.setf(flags);
}
return _stream;
}
/////////////////////////////////////////////////
std::string FilterBase::FilterPose(const gazebo::math::Pose &_pose,
const std::string &_xmlName,
std::string _filter,
const gazebo::physics::State &_state)
{
std::ostringstream result;
std::string xmlPrefix, xmlSuffix;
// Remove brackets, if they exist
boost::erase_all(_filter, "[");
boost::erase_all(_filter, "]");
// Output XML tags if required.
if (this->xmlOutput)
{
xmlPrefix = std::string("<") + _xmlName + ">";
xmlSuffix = std::string("</") + _xmlName + ">";
}
// Get the euler angles.
gazebo::math::Vector3 rpy = _pose.rot.GetAsEuler();
// If the filter is empty, then output the whole pose.
if (!_filter.empty())
{
// Get the list of pose elements from the filter
std::list<std::string> elements;
boost::split(elements, _filter, boost::is_any_of(","));
if (elements.empty() && !_filter.empty())
elements.push_back(_filter);
// Iterate over the list of pose elements.
for (std::list<std::string>::iterator elemIter =
elements.begin(); elemIter != elements.end();
++elemIter)
{
switch ((*elemIter)[0])
{
case 'X':
case 'x':
this->Out(result, _state) << std::fixed
<< _pose.pos.x << " ";
break;
case 'Y':
case 'y':
this->Out(result, _state) << std::fixed
<< _pose.pos.y << " ";
break;
case 'Z':
case 'z':
this->Out(result, _state) << std::fixed
<< _pose.pos.z << " ";
break;
case 'R':
case 'r':
this->Out(result, _state) << std::fixed << rpy.x << " ";
break;
case 'P':
case 'p':
this->Out(result, _state) << std::fixed << rpy.y << " ";
break;
case 'A':
case 'a':
this->Out(result, _state) << std::fixed << rpy.z << " ";
break;
default:
std::cerr << "Invalid pose value[" << *elemIter << "]\n";
break;
}
}
result << std::endl;
}
else
{
// No filter, so output the whole pose.
if (!xmlPrefix.empty())
{
result << std::fixed << xmlPrefix << _pose
<< xmlSuffix << std::endl;
}
else
this->Out(result, _state) << _pose << std::endl;
}
return result.str();
}
/////////////////////////////////////////////////
JointFilter::JointFilter(bool _xmlOutput, const std::string &_stamp)
: FilterBase(_xmlOutput, _stamp)
{
}
/////////////////////////////////////////////////
void JointFilter::Init(const std::string &_filter)
{
this->parts.clear();
if (!_filter.empty())
{
boost::split(this->parts, _filter, boost::is_any_of("."));
if (this->parts.empty())
this->parts.push_back(_filter);
}
}
/////////////////////////////////////////////////
std::string JointFilter::FilterParts(gazebo::physics::JointState &_state,
std::list<std::string>::iterator _partIter)
{
std::ostringstream result;
std::string part = *_partIter;
// Remove brackets, if they exist
boost::erase_all(part, "[");
boost::erase_all(part, "]");
// If the filter is empty, then output all the angles.
if (!part.empty())
{
// Get the list of axis elements from the filter
std::list<std::string> elements;
boost::split(elements, part, boost::is_any_of(","));
if (elements.empty() && !part.empty())
elements.push_back(part);
// Iterate over the list of axis elements.
for (std::list<std::string>::iterator elemIter =
elements.begin(); elemIter != elements.end();
++elemIter)
{
try
{
unsigned int axis =
boost::lexical_cast<unsigned int>(*elemIter);
if (axis >= _state.GetAngleCount())
continue;
gazebo::math::Angle angle = _state.GetAngle(axis);
if (this->xmlOutput)
{
result << "<angle axis='" << *elemIter << "'>"
<< std::fixed << angle << "</angle>\n";
}
else
this->Out(result, _state) << std::fixed << angle << " ";
}
catch(...)
{
std::cerr << "Invalid axis value[" << *elemIter << "]\n";
}
}
}
return result.str();
}
/////////////////////////////////////////////////
std::string JointFilter::Filter(gazebo::physics::ModelState &_state)
{
std::ostringstream result;
gazebo::physics::JointState_M states;
std::list<std::string>::iterator partIter;
/// Get an iterator to the list of the command line parts.
partIter = this->parts.begin();
// The first element in the filter must be a link name or a star.
std::string regexStr = *partIter;
boost::replace_all(regexStr, "*", ".*");
boost::regex regex(regexStr);
states = _state.GetJointStates(regex);
++partIter;
// Filter all the link states that were found.
for (gazebo::physics::JointState_M::iterator iter =
states.begin(); iter != states.end(); ++iter)
{
// Filter the elements of the joint (angle).
// If no filter parts were specified,
// then output the whole joint state.
if (partIter != this->parts.end())
{
if (this->xmlOutput)
result << "<joint name='" << iter->first << "'>\n";
result << this->FilterParts(iter->second, partIter);
if (this->xmlOutput)
result << "</joint>\n";
}
else
{
if (!this->xmlOutput && iter->second.GetAngleCount() == 1)
result << std::fixed << iter->second.GetAngle(0);
else
result << std::fixed << iter->second;
}
}
return result.str();
}
/////////////////////////////////////////////////
LinkFilter::LinkFilter(bool _xmlOutput, const std::string &_stamp)
: FilterBase(_xmlOutput, _stamp)
{
}
/////////////////////////////////////////////////
void LinkFilter::Init(const std::string &_filter)
{
this->parts.clear();
if (!_filter.empty())
{
boost::split(this->parts, _filter, boost::is_any_of("."));
if (this->parts.empty())
this->parts.push_back(_filter);
}
}
/////////////////////////////////////////////////
std::string LinkFilter::FilterParts(gazebo::physics::LinkState &_state,
std::list<std::string>::iterator _partIter)
{
std::ostringstream result;
std::string part = *_partIter;
std::string elemParts;
++_partIter;
if (_partIter != this->parts.end())
elemParts = *_partIter;
if (part == "pose")
result << this->FilterPose(_state.GetPose(), part, elemParts,
_state);
else if (part == "acceleration")
result << this->FilterPose(_state.GetAcceleration(), part,
elemParts, _state);
else if (part == "velocity")
result << this->FilterPose(_state.GetVelocity(), part, elemParts,
_state);
else if (part == "wrench")
result << this->FilterPose(_state.GetWrench(), part, elemParts,
_state);
return result.str();
}
/////////////////////////////////////////////////
std::string LinkFilter::Filter(gazebo::physics::ModelState &_state)
{
std::ostringstream result;
gazebo::physics::LinkState_M states;
std::list<std::string>::iterator partIter;
/// Get an iterator to the list of the command line parts.
partIter = this->parts.begin();
// The first element in the filter must be a link name or a star.
if (*partIter != "*")
{
std::string regexStr = *partIter;
boost::replace_all(regexStr, "*", ".*");
boost::regex regex(regexStr);
states = _state.GetLinkStates(regex);
}
else
states = _state.GetLinkStates();
++partIter;
// Filter all the link states that were found.
for (gazebo::physics::LinkState_M::iterator iter =
states.begin(); iter != states.end(); ++iter)
{
// Filter the elements of the link (pose, velocity,
// acceleration, wrench). If no filter parts were specified,
// then output the whole link state.
if (partIter != this->parts.end())
{
if (this->xmlOutput)
result << "<link name='" << iter->second.GetName() << "'>\n";
result << this->FilterParts(iter->second, partIter);
if (this->xmlOutput)
result << "</link>\n";
}
else
result << std::fixed << iter->second << std::endl;
}
return result.str();
}
/////////////////////////////////////////////////
ModelFilter::ModelFilter(bool _xmlOutput, const std::string &_stamp)
: FilterBase(_xmlOutput, _stamp)
{
this->linkFilter = NULL;
this->jointFilter = NULL;
}
/////////////////////////////////////////////////
ModelFilter::~ModelFilter()
{
delete this->linkFilter;
delete this->jointFilter;
}
/////////////////////////////////////////////////
void ModelFilter::Init(const std::string &_filter)
{
this->linkFilter = NULL;
this->jointFilter = NULL;
this->parts.clear();
if (_filter.empty())
return;
std::list<std::string> mainParts;
boost::split(mainParts, _filter, boost::is_any_of("/"));
// Create the model filter
if (!mainParts.empty())
{
boost::split(this->parts, mainParts.front(),
boost::is_any_of("."));
if (this->parts.empty() && !mainParts.front().empty())
this->parts.push_back(mainParts.front());
}
if (mainParts.empty())
return;
mainParts.pop_front();
// Create the link filter
if (!mainParts.empty() && !mainParts.front().empty())
{
this->linkFilter = new LinkFilter(this->xmlOutput, this->stamp);
this->linkFilter->Init(mainParts.front());
}
if (mainParts.empty())
return;
mainParts.pop_front();
// Create the joint filter
if (!mainParts.empty())
{
this->jointFilter = new JointFilter(this->xmlOutput,
this->stamp);
this->jointFilter->Init(mainParts.front());
}
}
/////////////////////////////////////////////////
std::string ModelFilter::FilterParts(gazebo::physics::ModelState &_state,
std::list<std::string>::iterator _partIter)
{
std::ostringstream result;
// Currently a model can only have a pose.
if (*_partIter == "pose")
{
// Get the model state pose
gazebo::math::Pose pose = _state.GetPose();
++_partIter;
// Get the elements to filter pose by.
std::string elemParts;
if (_partIter != this->parts.end())
elemParts = *_partIter;
// Output the filtered pose.
result << this->FilterPose(pose, "pose", elemParts, _state);
}
else
std::cerr << "Invalid model state component["
<< *_partIter << "]\n";
return result.str();
}
/////////////////////////////////////////////////
std::string ModelFilter::Filter(gazebo::physics::WorldState &_state)
{
std::ostringstream result;
gazebo::physics::ModelState_M states;
std::list<std::string>::iterator partIter = this->parts.begin();
// The first element in the filter must be a model name or a star.
if (partIter != this->parts.end() && !this->parts.empty() &&
!(*partIter).empty() && (*partIter) != "*")
{
std::string regexStr = *partIter;
boost::replace_all(regexStr, "*", ".*");
boost::regex regex(regexStr);
states = _state.GetModelStates(regex);
}
else
states = _state.GetModelStates();
++partIter;
// Filter all the model states that were found.
for (gazebo::physics::ModelState_M::iterator iter =
states.begin(); iter != states.end(); ++iter)
{
// If no link filter, and no model parts, then output the
// whole model state.
if (!this->linkFilter && !this->jointFilter &&
partIter == this->parts.end())
result << std::fixed << iter->second;
else
{
if (this->xmlOutput)
result << "<model name='" << iter->second.GetName() << "'>\n";
// Filter the pose of the model.
if (partIter != this->parts.end())
result << this->FilterParts(iter->second, partIter);
// Apply link filtering, if a link filter exists.
if (this->linkFilter)
result << this->linkFilter->Filter(iter->second);
// Apply link filtering, if a link filter exists.
if (this->jointFilter)
result << this->jointFilter->Filter(iter->second);
if (this->xmlOutput)
result << "</model>\n";
}
}
return result.str();
}
/////////////////////////////////////////////////
StateFilter::StateFilter(bool _xmlOutput, const std::string &_stamp,
double _hz)
: FilterBase(_xmlOutput, _stamp), filter(_xmlOutput, _stamp),
hz(_hz)
{}
/////////////////////////////////////////////////
void StateFilter::Init(const std::string &_filter)
{
this->filter.Init(_filter);
}
/////////////////////////////////////////////////
std::string StateFilter::Filter(const std::string &_stateString)
{
gazebo::physics::WorldState state;
// Read and parse the state information
g_stateSdf->ClearElements();
sdf::readString(_stateString, g_stateSdf);
state.Load(g_stateSdf);
std::ostringstream result;
if (this->hz > 0.0 && this->prevTime != gazebo::common::Time::Zero)
{
if ((state.GetSimTime() - this->prevTime).Double() <
1.0 / this->hz)
{
return result.str();
}
}
if (this->xmlOutput)
{
result << "<sdf version='" << SDF_VERSION << "'>\n"
<< "<state world_name='" << state.GetName() << "'>\n"
<< "<sim_time>" << state.GetSimTime() << "</sim_time>\n"
<< "<real_time>" << state.GetRealTime() << "</real_time>\n"
<< "<wall_time>" << state.GetWallTime() << "</wall_time>\n"
<< "<iterations>" << state.GetIterations() << "</iterations>\n";
auto insertions = state.Insertions();
if (insertions.size() > 0)
result << "<insertions>" << std::endl;
for (auto insertion : insertions)
result << insertion << std::endl;
if (insertions.size() > 0)
result << "</insertions>" << std::endl;
auto deletions = state.Deletions();
if (deletions.size() > 0)
result << "<deletions>" << std::endl;
for (auto deletion : deletions)
result << "<name>" << deletion << "</name>" << std::endl;
if (deletions.size() > 0)
result << "</deletions>" << std::endl;
}
result << this->filter.Filter(state);
if (this->xmlOutput)
result << "</state></sdf>\n";
this->prevTime = state.GetSimTime();
return result.str();
}
/////////////////////////////////////////////////
LogCommand::LogCommand()
: Command("log", "Introspects and manipulates Gazebo log files.")
{
// Options that are visible to the user through help.
this->visibleOptions.add_options()
("info,i", "Output information about a log file. "
"Log filename should be specified using the --file option")
("echo,e", "Output the contents of a log file to screen.")
("step,s", "Step through the contents of a log file.")
("record,d", po::value<bool>(),
"Start/stop recording a log file from an active Gazebo server."
"O=stop record, 1=start recording.")
("world-name,w", po::value<std::string>(), "World name, used when "
"starting or stopping recording.")
("raw,r", "Output the data from echo and step without XML formatting."
"Used in conjuction with --echo or --step.")
("stamp", po::value<std::string>(), "Add a timestamp to each line of "
"output. Valid values are (sim,real,wall)")
("hz,z", po::value<double>(), "Filter output to the specified Hz rate."
"Only valid for echo and step commands.")
("file,f", po::value<std::string>(), "Path to a log file.")
("filter", po::value<std::string>(),
"Filter output. Valid only for the echo and step commands");
}
/////////////////////////////////////////////////
void LogCommand::HelpDetailed()
{
std::cerr <<
"\tIntrospect and manipulate Gazebo log files. The log \n"
"\tcommand can also start and stop data log recording from \n"
"\tan active Gazebo server.\n"
<< std::endl;
}
/////////////////////////////////////////////////
bool LogCommand::TransportRequired()
{
return this->vm.count("record");
}
/////////////////////////////////////////////////
bool LogCommand::RunImpl()
{
std::string filename, filter, stamp, worldName;
double hz = 0;
bool raw = false;
if (this->vm.count("world-name"))
worldName = this->vm["world-name"].as<std::string>();
if (this->TransportRequired())
{
this->node.reset(new transport::Node());
this->node->Init(worldName);
}
// Get filter
filter = this->vm.count("filter") ? this->vm["filter"].as<std::string>() : "";
// Get stamp
stamp = this->vm.count("stamp") ? this->vm["stamp"].as<std::string>() : "";
// Get hz
hz = this->vm.count("hz") ? this->vm["hz"].as<double>() : 0;
raw = this->vm.count("raw");
if (!this->vm.count("record"))
{
// Load the log file
if (this->vm.count("file"))
filename = vm["file"].as<std::string>();
else
{
std::cerr << "No log file specified\n";
std::cerr << "For more info: gz help log\n";
return false;
}
// Load log file from string
if (!this->LoadLogFromFile(filename))
{
return false;
}
}
// Create a state sdf element.
g_stateSdf.reset(new sdf::Element);
sdf::initFile("state.sdf", g_stateSdf);
if (this->vm.count("echo"))
this->Echo(filter, raw, stamp, hz);
else if (this->vm.count("step"))
this->Step(filter, raw, stamp, hz);
else if (this->vm.count("record"))
this->Record(this->vm["record"].as<bool>());
else if (this->vm.count("info"))
this->Info(filename);
else
this->Help();
return true;
}
/////////////////////////////////////////////////
void LogCommand::Info(const std::string &_filename)
{
gazebo::util::LogPlay *play = gazebo::util::LogPlay::Instance();
// Get the SDF world description from the log file
std::string sdfString;
gazebo::util::LogPlay::Instance()->Step(sdfString);
// Parse the first SDF world description
sdf::ElementPtr sdf(new sdf::Element);
sdf::initFile("root.sdf", sdf);
sdf::readString(sdfString, sdf);
gazebo::physics::WorldState state;
// unsigned int modelCount = 0;
gazebo::common::Time endTime(0, 0);
gazebo::common::Time startTime(0, 0);
if (sdf)
{
// Check for a world element
if (sdf->HasElement("world"))
{
// Get a pointer to the world element
sdf::ElementPtr worldElem = sdf->GetElement("world");
// Check for a model
if (worldElem->HasElement("model"))
{
// Get a pointer to the first model element.
sdf::ElementPtr modelElem = worldElem->GetElement("model");
// Count all the model elements.
while (modelElem)
{
// modelCount++;
modelElem = modelElem->GetNextElement("model");
}
}
// Get the state for the world at the start.
if (worldElem->HasElement("state"))
{
state.Load(worldElem->GetElement("state"));
// Store the start time.
startTime = state.GetWallTime();
}
}
// Get the last chunk for the endTime
if (play->ChunkCount() > 1)
{
std::string stateString;
play->Chunk(play->ChunkCount()-1, stateString);
g_stateSdf->ClearElements();
sdf::readString(stateString, g_stateSdf);
state.Load(g_stateSdf);
endTime = state.GetWallTime();
}
else
endTime = startTime;
}
// Tell cout how to output boost dates
boost::posix_time::time_facet *facet =
new boost::posix_time::time_facet("%b %d %y %H:%M:%S");
std::cout.imbue(std::locale(std::locale::classic(), facet));
// Compute the duration
gazebo::common::Time deltaTime = endTime - startTime;
// int hours = deltaTime.sec / 3600;
// int minutes = (deltaTime.sec - hours * 3600) / 60;
// int seconds = (deltaTime.sec - hours * 3600 - minutes * 60);
// Output info
std::cout
<< "Log Version: " << play->LogVersion() << "\n"
<< "Gazebo Version: " << play->GazeboVersion() << "\n"
<< "Random Seed: " << play->RandSeed() << "\n"
// << "Start: " << boost::posix_time::from_time_t(startTime.sec)
// << "." << startTime.nsec << "\n"
// << "End: " << boost::posix_time::from_time_t(endTime.sec)
// << "." << endTime.nsec << "\n"
// << "Duration: " << std::setfill('0') << std::setw(2)
// << hours << ":"
// << std::setfill('0')
// << std::setw(2) << minutes << ":"
// << std::setfill('0') << std::setw(2)
// << seconds << "."
// << deltaTime.nsec << "\n"
// << "Steps: " << play->GetChunkCount() << "\n"
<< "Size: " << this->GetFileSizeStr(_filename) << "\n"
<< "Encoding: " << play->Encoding() << "\n"
// << "Model Count: " << modelCount << "\n"
<< "\n";
}
/////////////////////////////////////////////////
void LogCommand::Echo(const std::string &_filter, bool _raw,
const std::string &_stamp, double _hz)
{
gazebo::util::LogPlay *play = gazebo::util::LogPlay::Instance();
std::string stateString;
// Output the header
if (!_raw)
std::cout << play->Header() << std::endl;
StateFilter filter(!_raw, _stamp, _hz);
filter.Init(_filter);
unsigned int i = 0;
while (play->Step(stateString))
{
if (i > 0)
stateString = filter.Filter(stateString);
else if (i == 0 && _raw)
stateString.clear();
if (!stateString.empty())
{
if (!_raw)
std::cout << "<chunk encoding='txt'><![CDATA[\n";
std::cout << stateString;
if (!_raw)
std::cout << "]]></chunk>\n";
}
++i;
}
if (!_raw)
std::cout << "</gazebo_log>\n";
}
/////////////////////////////////////////////////
void LogCommand::Step(const std::string &_filter, bool _raw,
const std::string &_stamp, double _hz)
{
std::string stateString;
gazebo::util::LogPlay *play = gazebo::util::LogPlay::Instance();
if (!_raw)
std::cout << play->Header() << std::endl;
char c = '\0';
StateFilter filter(!_raw, _stamp, _hz);
filter.Init(_filter);
unsigned int i = 0;
while (play->Step(stateString) && c != 'q')
{
if (i > 0)
stateString = filter.Filter(stateString);
else if (i == 0 && _raw)
stateString.clear();
// Only wait for user input if there is some state to output.
if (!stateString.empty())
{
if (!_raw)
std::cout << "<chunk encoding='txt'><![CDATA[\n";
std::cout << stateString;
if (!_raw)
std::cout << "]]></chunk>\n";
std::cout << "\n--- Press space to continue, 'q' to quit ---\n";
c = '\0';
// Wait for a space or 'q' key press
while (c != ' ' && c != 'q')
c = this->GetChar();
}
++i;
}
if (!_raw)
std::cout << "</gazebo_log>\n";
}
/////////////////////////////////////////////////
void LogCommand::Record(bool _start)
{
gazebo::transport::PublisherPtr pub =
this->node->Advertise<gazebo::msgs::LogControl>("~/log/control");
if (!pub->WaitForConnection(gazebo::common::Time(10, 0)))
{
std::cerr << "Unable to create a connection to topic ~/log/control.\n";
return;
}
gazebo::msgs::LogControl msg;
_start ? msg.set_start(true) : msg.set_stop(true);
pub->Publish<gazebo::msgs::LogControl>(msg, true);
}
/////////////////////////////////////////////////
std::string LogCommand::GetFileSizeStr(const std::string &_filename)
{
std::ostringstream size;
// Open the file
std::ifstream ifs(_filename.c_str());
if (!ifs)
{
std::cerr << "Unable to open file[" << _filename << "]\n";
return std::string();
}
// Move to the end of the file
ifs.seekg(0, std::ios::end);
// Get the position of the file pointer, which is the number of bytes in
// the file.
int byteSize = ifs.tellg();
// Generate a human friendly string
if (byteSize < 1000)
size << byteSize << " B";
else if (byteSize < 1000000)
size << byteSize / 1000.0f << " KB";
else
size << byteSize / 1.0e6 << " MB";
return size.str();
}
/////////////////////////////////////////////////
int LogCommand::GetChar()
{
# ifndef _WIN32
struct termios oldt, newt;
tcgetattr(STDIN_FILENO, &oldt);
newt = oldt;
newt.c_lflag &= ~(ICANON | ECHO);
tcsetattr(STDIN_FILENO, TCSANOW, &newt);
int ch = getchar();
tcsetattr(STDIN_FILENO, TCSANOW, &oldt);
return ch;
# else
return 'q';
# endif
}
/////////////////////////////////////////////////
bool LogCommand::LoadLogFromFile(const std::string &_filename)
{
if (_filename.empty())
{
std::cerr << "Log filename is empty.\n";
return false;
}
try
{
gazebo::util::LogPlay::Instance()->Open(_filename);
}
catch(gazebo::common::Exception &_e)
{
std::cerr << "Unable to open log file[" << _filename << "]\n";
return false;
}
return true;
}