/*****************************************************************
*
* This file is part of the GMAPPING project
*
* GMAPPING Copyright (c) 2004 Giorgio Grisetti,
* Cyrill Stachniss, and Wolfram Burgard
*
* This software is licensed under the 3-Clause BSD License
* and is copyrighted by Giorgio Grisetti, Cyrill Stachniss,
* and Wolfram Burgard.
*
* Further information on this license can be found at:
* https://opensource.org/licenses/BSD-3-Clause
*
* GMAPPING is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied
* warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
* PURPOSE.
*
*****************************************************************/
#include "gmapping/gui/gsp_thread.h"
#include <gmapping/utils/commandline.h>
#include <gmapping/utils/stat.h>
#include <gmapping/configfile/configfile.h>
#ifdef CARMEN_SUPPORT
#include <gmapping/carmenwrapper/carmenwrapper.h>
#endif
#define DEBUG cout << __func__
using namespace std;
int GridSlamProcessorThread::init(int argc, const char * const * argv){
m_argc=argc;
m_argv=argv;
std::string configfilename;
std::string ebuf="not_set";
CMD_PARSE_BEGIN_SILENT(1,argc);
parseStringSilent("-cfg",configfilename);
CMD_PARSE_END_SILENT;
if (configfilename.length()>0){
ConfigFile cfg(configfilename);
filename = (std::string) cfg.value("gfs","filename",filename);
outfilename = (std::string) cfg.value("gfs","outfilename",outfilename);
xmin = cfg.value("gfs","xmin", xmin);
xmax = cfg.value("gfs","xmax",xmax);
ymin = cfg.value("gfs","ymin",ymin);
ymax = cfg.value("gfs","ymax",ymax);
delta = cfg.value("gfs","delta",delta);
maxrange = cfg.value("gfs","maxrange",maxrange);
maxUrange = cfg.value("gfs","maxUrange",maxUrange);
regscore = cfg.value("gfs","regscore",regscore);
critscore = cfg.value("gfs","critscore",critscore);
kernelSize = cfg.value("gfs","kernelSize",kernelSize);
sigma = cfg.value("gfs","sigma",sigma);
iterations = cfg.value("gfs","iterations",iterations);
lstep = cfg.value("gfs","lstep",lstep);
astep = cfg.value("gfs","astep",astep);
maxMove = cfg.value("gfs","maxMove",maxMove);
srr = cfg.value("gfs","srr", srr);
srt = cfg.value("gfs","srt", srt);
str = cfg.value("gfs","str", str);
stt = cfg.value("gfs","stt", stt);
particles = cfg.value("gfs","particles",particles);
angularUpdate = cfg.value("gfs","angularUpdate", angularUpdate);
linearUpdate = cfg.value("gfs","linearUpdate", linearUpdate);
lsigma = cfg.value("gfs","lsigma", lsigma);
ogain = cfg.value("gfs","lobsGain", ogain);
lskip = (int)cfg.value("gfs","lskip", lskip);
mapUpdateTime = cfg.value("gfs","mapUpdate", mapUpdateTime);
randseed = cfg.value("gfs","randseed", randseed);
autosize = cfg.value("gfs","autosize", autosize);
readFromStdin = cfg.value("gfs","stdin", readFromStdin);
resampleThreshold = cfg.value("gfs","resampleThreshold", resampleThreshold);
skipMatching = cfg.value("gfs","skipMatching", skipMatching);
onLine = cfg.value("gfs","onLine", onLine);
generateMap = cfg.value("gfs","generateMap", generateMap);
m_minimumScore = cfg.value("gfs","minimumScore", m_minimumScore);
llsamplerange = cfg.value("gfs","llsamplerange", llsamplerange);
lasamplerange = cfg.value("gfs","lasamplerange",lasamplerange );
llsamplestep = cfg.value("gfs","llsamplestep", llsamplestep);
lasamplestep = cfg.value("gfs","lasamplestep", lasamplestep);
linearOdometryReliability = cfg.value("gfs","linearOdometryReliability",linearOdometryReliability);
angularOdometryReliability = cfg.value("gfs","angularOdometryReliability",angularOdometryReliability);
ebuf = (std::string) cfg.value("gfs","estrategy", ebuf);
considerOdometryCovariance = cfg.value("gfs","considerOdometryCovariance",considerOdometryCovariance);
}
CMD_PARSE_BEGIN(1,argc);
parseString("-cfg",configfilename); /* to avoid the warning*/
parseString("-filename",filename);
parseString("-outfilename",outfilename);
parseDouble("-xmin",xmin);
parseDouble("-xmax",xmax);
parseDouble("-ymin",ymin);
parseDouble("-ymax",ymax);
parseDouble("-delta",delta);
parseDouble("-maxrange",maxrange);
parseDouble("-maxUrange",maxUrange);
parseDouble("-regscore",regscore);
parseDouble("-critscore",critscore);
parseInt("-kernelSize",kernelSize);
parseDouble("-sigma",sigma);
parseInt("-iterations",iterations);
parseDouble("-lstep",lstep);
parseDouble("-astep",astep);
parseDouble("-maxMove",maxMove);
parseDouble("-srr", srr);
parseDouble("-srt", srt);
parseDouble("-str", str);
parseDouble("-stt", stt);
parseInt("-particles",particles);
parseDouble("-angularUpdate", angularUpdate);
parseDouble("-linearUpdate", linearUpdate);
parseDouble("-lsigma", lsigma);
parseDouble("-lobsGain", ogain);
parseInt("-lskip", lskip);
parseInt("-mapUpdate", mapUpdateTime);
parseInt("-randseed", randseed);
parseFlag("-autosize", autosize);
parseFlag("-stdin", readFromStdin);
parseDouble("-resampleThreshold", resampleThreshold);
parseFlag("-skipMatching", skipMatching);
parseFlag("-onLine", onLine);
parseFlag("-generateMap", generateMap);
parseDouble("-minimumScore", m_minimumScore);
parseDouble("-llsamplerange", llsamplerange);
parseDouble("-lasamplerange", lasamplerange);
parseDouble("-llsamplestep", llsamplestep);
parseDouble("-lasamplestep", lasamplestep);
parseDouble("-linearOdometryReliability",linearOdometryReliability);
parseDouble("-angularOdometryReliability",angularOdometryReliability);
parseString("-estrategy", ebuf);
parseFlag("-considerOdometryCovariance",considerOdometryCovariance);
CMD_PARSE_END;
if (filename.length() <=0){
cout << "no filename specified" << endl;
return -1;
}
return 0;
}
int GridSlamProcessorThread::loadFiles(const char * fn){
if (onLine){
cout << " onLineProcessing" << endl;
return 0;
}
ifstream is;
if (fn)
is.open(fn);
else
is.open(filename.c_str());
if (! is){
cout << "no file found" << endl;
return -1;
}
CarmenConfiguration conf;
conf.load(is);
is.close();
sensorMap=conf.computeSensorMap();
if (input)
delete input;
if (! readFromStdin){
plainStream.open(filename.c_str());
input=new InputSensorStream(sensorMap, plainStream);
cout << "Plain Stream opened="<< (bool) plainStream << endl;
} else {
input=new InputSensorStream(sensorMap, cin);
cout << "Plain Stream opened on stdin" << endl;
}
return 0;
}
GridSlamProcessorThread::GridSlamProcessorThread(): GridSlamProcessor(cerr){
//This are the processor parameters
filename="";
outfilename="";
xmin=-100.;
ymin=-100.;
xmax=100.;
ymax=100.;
delta=0.05;
//scan matching parameters
sigma=0.05;
maxrange=80.;
maxUrange=80.;
regscore=1e4;
lstep=.05;
astep=.05;
kernelSize=1;
iterations=5;
critscore=0.;
maxMove=1.;
lsigma=.075;
ogain=3;
lskip=0;
autosize=false;
skipMatching=false;
//motion model parameters
srr=0.1, srt=0.1, str=0.1, stt=0.1;
//particle parameters
particles=30;
randseed=0;
//gfs parameters
angularUpdate=0.5;
linearUpdate=1;
resampleThreshold=0.5;
input=0;
pthread_mutex_init(&hp_mutex,0);
pthread_mutex_init(&ind_mutex,0);
pthread_mutex_init(&hist_mutex,0);
running=false;
eventBufferLength=0;
mapUpdateTime=5;
mapTimer=0;
readFromStdin=false;
onLine=false;
generateMap=false;
// This are the dafault settings for a grid map of 5 cm
llsamplerange=0.01;
llsamplestep=0.01;
lasamplerange=0.005;
lasamplestep=0.005;
linearOdometryReliability=0.;
angularOdometryReliability=0.;
considerOdometryCovariance=false;
/*
// This are the dafault settings for a grid map of 10 cm
m_llsamplerange=0.1;
m_llsamplestep=0.1;
m_lasamplerange=0.02;
m_lasamplestep=0.01;
*/
// This are the dafault settings for a grid map of 20/25 cm
/*
m_llsamplerange=0.2;
m_llsamplestep=0.1;
m_lasamplerange=0.02;
m_lasamplestep=0.01;
m_generateMap=false;
*/
}
GridSlamProcessorThread::~GridSlamProcessorThread(){
pthread_mutex_destroy(&hp_mutex);
pthread_mutex_destroy(&ind_mutex);
pthread_mutex_destroy(&hist_mutex);
for (deque<Event*>::const_iterator it=eventBuffer.begin(); it!=eventBuffer.end(); it++)
delete *it;
}
void * GridSlamProcessorThread::fastslamthread(GridSlamProcessorThread* gpt){
if (! gpt->input && ! gpt->onLine)
return 0;
//if started online retrieve the settings from the connection
#ifdef CARMEN_SUPPORT
if (gpt->onLine){
cout << "starting the process:" << endl;
CarmenWrapper::initializeIPC(gpt->m_argv[0]);
CarmenWrapper::start(gpt->m_argv[0]);
cout << "Waiting for retrieving the sensor map:" << endl;
while (! CarmenWrapper::sensorMapComputed()){
usleep(500000);
cout << "." << flush;
}
gpt->sensorMap=CarmenWrapper::sensorMap();
cout << "Connected " << endl;
}
#else
if (gpt->onLine){
cout << "FATAL ERROR: cannot run online without the carmen support" << endl;
DoneEvent *done=new DoneEvent;
gpt->addEvent(done);
return 0;
}
#endif
gpt->setSensorMap(gpt->sensorMap);
gpt->setMatchingParameters(gpt->maxUrange, gpt->maxrange, gpt->sigma, gpt->kernelSize, gpt->lstep, gpt->astep, gpt->iterations, gpt->lsigma, gpt->ogain, gpt->lskip);
double xmin=gpt->xmin,
ymin=gpt->ymin,
xmax=gpt->xmax,
ymax=gpt->ymax;
OrientedPoint initialPose(0,0,0);
if (gpt->autosize){
if (gpt->readFromStdin || gpt->onLine)
cout << "Error, cant autosize form stdin" << endl;
SensorLog * log=new SensorLog(gpt->sensorMap);
ifstream is(gpt->filename.c_str());
log->load(is);
is.close();
initialPose=gpt->boundingBox(log, xmin, ymin, xmax, ymax);
delete log;
}
if( gpt->infoStream()){
gpt->infoStream() << " initialPose=" << initialPose.x << " " << initialPose.y << " " << initialPose.theta
<< cout << " xmin=" << xmin <<" ymin=" << ymin <<" xmax=" << xmax <<" ymax=" << ymax << endl;
}
gpt->setMotionModelParameters(gpt->srr, gpt->srt, gpt->str, gpt->stt);
gpt->setUpdateDistances(gpt->linearUpdate, gpt->angularUpdate, gpt->resampleThreshold);
gpt->setgenerateMap(gpt->generateMap);
gpt->GridSlamProcessor::init(gpt->particles, xmin, ymin, xmax, ymax, gpt->delta, initialPose);
gpt->setllsamplerange(gpt->llsamplerange);
gpt->setllsamplestep(gpt->llsamplestep);
gpt->setlasamplerange(gpt->llsamplerange);
gpt->setlasamplestep(gpt->llsamplestep);
#define printParam(n)\
gpt->outputStream() \
<< "PARAM " << \
#n \
<< " " << gpt->n << endl
if (gpt->outfilename.length()>0 ){
gpt->outputStream().open(gpt->outfilename.c_str());
printParam(filename);
printParam(outfilename);
printParam(xmin);
printParam(ymin);
printParam(xmax);
printParam(ymax);
printParam(delta);
//scan matching parameters
printParam(sigma);
printParam(maxrange);
printParam(maxUrange);
printParam(regscore);
printParam(lstep);
printParam(astep);
printParam(kernelSize);
printParam(iterations);
printParam(critscore);
printParam(maxMove);
printParam(lsigma);
printParam(ogain);
printParam(lskip);
printParam(autosize);
printParam(skipMatching);
//motion model parameters
printParam(srr);
printParam(srt);
printParam(str);
printParam(stt);
//particle parameters
printParam(particles);
printParam(randseed);
//gfs parameters
printParam(angularUpdate);
printParam(linearUpdate);
printParam(resampleThreshold);
printParam(llsamplerange);
printParam(lasamplerange);
printParam(llsamplestep);
printParam(lasamplestep);
}
#undef printParam
if (gpt->randseed!=0)
sampleGaussian(1,gpt->randseed);
if (!gpt->infoStream()){
cerr << "cant open info stream for writing by unuseful debug messages" << endl;
} else {
gpt->infoStream() << "setting randseed" << gpt->randseed<< endl;
}
#ifdef CARMEN_SUPPORT
list<RangeReading*> rrlist;
if (gpt->onLine){
RangeReading rr(0,0);
while (1){
while (CarmenWrapper::getReading(rr)){
RangeReading* nr=new RangeReading(rr);
rrlist.push_back(nr);
gpt->processScan(*nr);
}
}
}
#endif
ofstream rawpath("rawpath.dat");
if (!gpt->onLine){
while(*(gpt->input) && gpt->running){
const SensorReading* r;
(*(gpt->input)) >> r;
if (! r)
continue;
const RangeReading* rr=dynamic_cast<const RangeReading*>(r);
if (rr && gpt->running){
const RangeSensor* rs=dynamic_cast<const RangeSensor*>(rr->getSensor());
assert (rs && rs->beams().size()==rr->size());
bool processed=gpt->processScan(*rr);
rawpath << rr->getPose().x << " " << rr->getPose().y << " " << rr->getPose().theta << endl;
if (0 && processed){
cerr << "Retrieving state .. ";
TNodeVector trajetories=gpt->getTrajectories();
cerr << "Done" << endl;
cerr << "Deleting Tree state .. ";
for (TNodeVector::iterator it=trajetories.begin(); it!=trajetories.end(); it++)
delete *it;
cerr << "Done" << endl;
}
// if (0 && processed){
// cerr << "generating copy" << endl;;
// GridSlamProcessor* m_gsp=gpt->clone();
// Map<double, DoubleArray2D, false>* pmap=m_gsp->getParticles()[0].map.toDoubleMap() ;
// cerr << "deleting" << endl;
// delete m_gsp;
// delete pmap;
// }
}
const OdometryReading* o=dynamic_cast<const OdometryReading*>(r);
if (o && gpt->running){
gpt->processTruePos(*o);
TruePosEvent* truepos=new TruePosEvent;
truepos->pose=o->getPose();
}
}
}
rawpath.close();
TNodeVector trajetories=gpt->getTrajectories();
cerr << "WRITING WEIGHTS" << endl;
int pnumber=0;
for (TNodeVector::iterator it=trajetories.begin(); it!=trajetories.end(); it++){
char buf[10];
sprintf(buf, "w-%03d.dat",pnumber);
ofstream weightsStream(buf);
GridSlamProcessor::TNode* n=*it;
double oldWeight=0, oldgWeight=0;
while (n!=0){
double w=n->weight-oldWeight;
double gw=n->gweight-oldgWeight;
oldWeight=n->weight;
oldgWeight=n->gweight;
weightsStream << w << " " << gw << endl;
n=n->parent;
}
weightsStream.close();
pnumber++;
cerr << buf << endl;
}
DoneEvent *done=new DoneEvent;
gpt->addEvent(done);
gpt->infoStream() << "Hallo, I am the gsp thread. I have finished. Do you think it is the case of checking for unlocked mutexes." << endl;
return 0;
}
std::vector<OrientedPoint> GridSlamProcessorThread::getHypotheses(){
pthread_mutex_lock(&hp_mutex);
std::vector<OrientedPoint> retval(hypotheses);
pthread_mutex_unlock(&hp_mutex);
return retval;
}
std::vector<unsigned int> GridSlamProcessorThread::getIndexes(){
pthread_mutex_lock(&ind_mutex);
std::vector<unsigned int> retval(indexes);
pthread_mutex_unlock(&ind_mutex);
return retval;
}
void GridSlamProcessorThread::start(){
if (running)
return;
running=true;
pthread_create(&gfs_thread, 0, (void * (*)(void *))fastslamthread, (void *) this);
}
void GridSlamProcessorThread::stop(){
if (! running){
cout << "PORCO CAZZO" << endl;
return;
}
running=false;
void * retval;
pthread_join(gfs_thread, &retval);
}
void GridSlamProcessorThread::onOdometryUpdate(){
pthread_mutex_lock(&hp_mutex);
hypotheses.clear();
weightSums.clear();
for (GridSlamProcessor::ParticleVector::const_iterator part=getParticles().begin(); part!=getParticles().end(); part++ ){
hypotheses.push_back(part->pose);
weightSums.push_back(part->weightSum);
}
ParticleMoveEvent* event=new ParticleMoveEvent;
event->scanmatched=false;
event->hypotheses=hypotheses;
event->weightSums=weightSums;
event->neff=m_neff;
pthread_mutex_unlock(&hp_mutex);
addEvent(event);
syncOdometryUpdate();
}
void GridSlamProcessorThread::onResampleUpdate(){
pthread_mutex_lock(&ind_mutex);
pthread_mutex_lock(&hp_mutex);
indexes=GridSlamProcessor::getIndexes();
assert (indexes.size()==getParticles().size());
ResampleEvent* event=new ResampleEvent;
event->indexes=indexes;
pthread_mutex_unlock(&hp_mutex);
pthread_mutex_unlock(&ind_mutex);
addEvent(event);
syncResampleUpdate();
}
void GridSlamProcessorThread::onScanmatchUpdate(){
pthread_mutex_lock(&hp_mutex);
hypotheses.clear();
weightSums.clear();
unsigned int bestIdx=0;
double bestWeight=-1e1000;
unsigned int idx=0;
for (GridSlamProcessor::ParticleVector::const_iterator part=getParticles().begin(); part!=getParticles().end(); part++ ){
hypotheses.push_back(part->pose);
weightSums.push_back(part->weightSum);
if(part->weightSum>bestWeight){
bestIdx=idx;
bestWeight=part->weightSum;
}
idx++;
}
ParticleMoveEvent* event=new ParticleMoveEvent;
event->scanmatched=true;
event->hypotheses=hypotheses;
event->weightSums=weightSums;
event->neff=m_neff;
addEvent(event);
if (! mapTimer){
MapEvent* event=new MapEvent;
event->index=bestIdx;
event->pmap=new ScanMatcherMap(getParticles()[bestIdx].map);
event->pose=getParticles()[bestIdx].pose;
addEvent(event);
}
mapTimer++;
mapTimer=mapTimer%mapUpdateTime;
pthread_mutex_unlock(&hp_mutex);
syncOdometryUpdate();
}
void GridSlamProcessorThread::syncOdometryUpdate(){
}
void GridSlamProcessorThread::syncResampleUpdate(){
}
void GridSlamProcessorThread::syncScanmatchUpdate(){
}
void GridSlamProcessorThread::addEvent(GridSlamProcessorThread::Event * e){
pthread_mutex_lock(&hist_mutex);
while (eventBuffer.size()>eventBufferLength){
Event* event=eventBuffer.front();
delete event;
eventBuffer.pop_front();
}
eventBuffer.push_back(e);
pthread_mutex_unlock(&hist_mutex);
}
GridSlamProcessorThread::EventDeque GridSlamProcessorThread::getEvents(){
pthread_mutex_lock(&hist_mutex);
EventDeque copy(eventBuffer);
eventBuffer.clear();
pthread_mutex_unlock(&hist_mutex);
return copy;
}
GridSlamProcessorThread::Event::~Event(){}
GridSlamProcessorThread::MapEvent::~MapEvent(){
if (pmap)
delete pmap;
}
void GridSlamProcessorThread::setEventBufferSize(unsigned int length){
eventBufferLength=length;
}
OrientedPoint GridSlamProcessorThread::boundingBox(SensorLog* log, double& xmin, double& ymin, double& xmax, double& ymax) const{
OrientedPoint initialPose(0,0,0);
initialPose=log->boundingBox(xmin, ymin, xmax, ymax);
xmin-=3*maxrange;
ymin-=3*maxrange;
xmax+=3*maxrange;
ymax+=3*maxrange;
return initialPose;
}
