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/* Copyright (c) 2012 Patrick Ruoff
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*/
#include "ftnoir_tracker_pt.h"
#include <QHBoxLayout>
#include <cmath>
#include <QDebug>
#include <QFile>
#include <QCoreApplication>
#include "opentrack/camera-names.hpp"
//#define PT_PERF_LOG //log performance
//-----------------------------------------------------------------------------
Tracker_PT::Tracker_PT()
: mutex(QMutex::Recursive),
commands(0),
video_widget(NULL),
video_frame(NULL),
ever_success(false)
{
connect(s.b.get(), SIGNAL(saving()), this, SLOT(apply_settings()));
}
Tracker_PT::~Tracker_PT()
{
set_command(ABORT);
wait();
delete video_widget;
video_widget = NULL;
if (video_frame->layout()) delete video_frame->layout();
camera.stop();
}
void Tracker_PT::set_command(Command command)
{
//QMutexLocker lock(&mutex);
commands |= command;
}
void Tracker_PT::reset_command(Command command)
{
//QMutexLocker lock(&mutex);
commands &= ~command;
}
bool Tracker_PT::get_focal_length(float& ret)
{
static constexpr float pi = 3.1415926;
float fov_;
switch (s.fov)
{
default:
case 0:
fov_ = 56;
break;
case 1:
fov_ = 75;
break;
}
const double diag_fov = static_cast<int>(fov_) * pi / 180.f;
QMutexLocker l(&camera_mtx);
CamInfo info;
const bool res = camera.get_info(info);
if (res)
{
const int w = info.res_x, h = info.res_y;
const double diag = sqrt(1. + h/(double)w * h/(double)w);
const double fov = 2.*atan(tan(diag_fov/2.0)/diag);
ret = .5 / tan(.5 * fov);
return true;
}
return false;
}
void Tracker_PT::run()
{
#ifdef PT_PERF_LOG
QFile log_file(QCoreApplication::applicationDirPath() + "/PointTrackerPerformance.txt");
if (!log_file.open(QIODevice::WriteOnly | QIODevice::Text)) return;
QTextStream log_stream(&log_file);
#endif
apply_settings();
while((commands & ABORT) == 0)
{
const double dt = time.elapsed() * 1e-9;
time.start();
cv::Mat frame;
bool new_frame;
{
QMutexLocker l(&camera_mtx);
new_frame = camera.get_frame(dt, &frame);
}
if (new_frame && !frame.empty())
{
QMutexLocker lock(&mutex);
std::vector<cv::Vec2f> points = point_extractor.extract_points(frame);
// blobs are sorted in order of circularity
if (points.size() > PointModel::N_POINTS)
points.resize(PointModel::N_POINTS);
bool success = points.size() == PointModel::N_POINTS;
ever_success |= success;
float fx;
if (!get_focal_length(fx))
continue;
if (success)
{
point_tracker.track(points, PointModel(s), fx, s.dynamic_pose, s.init_phase_timeout);
}
{
Affine X_CM = pose();
Affine X_MH(cv::Matx33f::eye(), cv::Vec3f(s.t_MH_x, s.t_MH_y, s.t_MH_z)); // just copy pasted these lines from below
Affine X_GH = X_CM * X_MH;
cv::Vec3f p = X_GH.t; // head (center?) position in global space
cv::Vec2f p_(p[0] / p[2] * fx, p[1] / p[2] * fx); // projected to screen
points.push_back(p_);
}
for (unsigned i = 0; i < points.size(); i++)
{
auto& p = points[i];
auto p2 = cv::Point(p[0] * frame.cols + frame.cols/2, -p[1] * frame.cols + frame.rows/2);
cv::Scalar color(0, 255, 0);
if (i == points.size()-1)
color = cv::Scalar(0, 0, 255);
cv::line(frame,
cv::Point(p2.x - 20, p2.y),
cv::Point(p2.x + 20, p2.y),
color,
4);
cv::line(frame,
cv::Point(p2.x, p2.y - 20),
cv::Point(p2.x, p2.y + 20),
color,
4);
}
video_widget->update_image(frame);
}
#ifdef PT_PERF_LOG
log_stream<<"dt: "<<dt;
if (!frame.empty()) log_stream<<" fps: "<<camera.get_info().fps;
log_stream<<"\n";
#endif
}
qDebug()<<"Tracker:: Thread stopping";
}
void Tracker_PT::apply_settings()
{
qDebug()<<"Tracker:: Applying settings";
QMutexLocker l(&camera_mtx);
camera.set_device_index(camera_name_to_index("PS3Eye Camera"));
int res_x, res_y, cam_fps;
switch (s.camera_mode)
{
default:
case 0:
res_x = 640;
res_y = 480;
cam_fps = 75;
break;
case 1:
res_x = 640;
res_y = 480;
cam_fps = 60;
break;
case 2:
res_x = 320;
res_y = 240;
cam_fps = 189;
break;
case 3:
res_x = 320;
res_y = 240;
cam_fps = 120;
break;
}
camera.set_res(res_x, res_y);
camera.set_fps(cam_fps);
qDebug() << "camera start";
camera.start();
qDebug()<<"Tracker::apply ends";
}
void Tracker_PT::start_tracker(QFrame *parent_window)
{
this->video_frame = parent_window;
video_frame->setAttribute(Qt::WA_NativeWindow);
video_frame->show();
video_widget = new PTVideoWidget(video_frame);
QHBoxLayout* video_layout = new QHBoxLayout(parent_window);
video_layout->setContentsMargins(0, 0, 0, 0);
video_layout->addWidget(video_widget);
video_frame->setLayout(video_layout);
video_widget->resize(video_frame->width(), video_frame->height());
start();
}
void Tracker_PT::data(double *data)
{
if (ever_success)
{
Affine X_CM = pose();
Affine X_MH(cv::Matx33f::eye(), cv::Vec3f(s.t_MH_x, s.t_MH_y, s.t_MH_z));
Affine X_GH = X_CM * X_MH;
cv::Matx33f R = X_GH.R;
cv::Vec3f t = X_GH.t;
// translate rotation matrix from opengl (G) to roll-pitch-yaw (E) frame
// -z -> x, y -> z, x -> -y
cv::Matx33f R_EG(0, 0,-1,
-1, 0, 0,
0, 1, 0);
R = R_EG * R * R_EG.t();
// extract rotation angles
float alpha, beta, gamma;
beta = atan2( -R(2,0), sqrt(R(2,1)*R(2,1) + R(2,2)*R(2,2)) );
alpha = atan2( R(1,0), R(0,0));
gamma = atan2( R(2,1), R(2,2));
// extract rotation angles
data[Yaw] = rad2deg * alpha;
data[Pitch] = -rad2deg * beta;
data[Roll] = rad2deg * gamma;
// get translation(s)
data[TX] = t[0] / 10.0; // convert to cm
data[TY] = t[1] / 10.0;
data[TZ] = t[2] / 10.0;
}
}
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