void TextEditComponent::onCursorChanged()
{
	if(isMultiline())
	{
		Eigen::Vector2f textSize = mFont->getWrappedTextCursorOffset(mText, getTextAreaSize().x(), mCursor); 

		if(mScrollOffset.y() + getTextAreaSize().y() < textSize.y() + mFont->getHeight()) //need to scroll down?
		{
			mScrollOffset[1] = textSize.y() - getTextAreaSize().y() + mFont->getHeight();
		}else if(mScrollOffset.y() > textSize.y()) //need to scroll up?
		{
			mScrollOffset[1] = textSize.y();
		}
	}else{
		Eigen::Vector2f cursorPos = mFont->sizeText(mText.substr(0, mCursor));

		if(mScrollOffset.x() + getTextAreaSize().x() < cursorPos.x())
		{
			mScrollOffset[0] = cursorPos.x() - getTextAreaSize().x();
		}else if(mScrollOffset.x() > cursorPos.x())
		{
			mScrollOffset[0] = cursorPos.x();
		}
	}
}
Example #2
0
// Returns a list of points on the convex hull in counter-clockwise order.
// Note: the last point in the returned list is the same as the first one.
std::vector<int> convex_hull(std::vector<int> idxs, std::function<Eigen::Vector2f(int)> & getPoint){
    int n = idxs.size(), k = 0;
    std::vector<int> hull(2*n);

    // Sort points lexicographically
    sort(idxs.begin(), idxs.end(), [&getPoint](int a_, int b_){
        Eigen::Vector2f a = getPoint(a_);
        Eigen::Vector2f b = getPoint(b_);
        return a.x() < b.x() || (a.x() == b.x() && a.y() < b.y());
    });

    // Build lower hull
    for (int i = 0; i < n; ++i) {
        while (k >= 2 && cross(getPoint(hull[k-2]), getPoint(hull[k-1]), getPoint(idxs[i])) <= 0) k--;
        hull[k++] = idxs[i];
    }

    // Build upper hull
    for (int i = n-2, t = k+1; i >= 0; i--) {
        while (k >= t && cross(getPoint(hull[k-2]), getPoint(hull[k-1]), getPoint(idxs[i])) <= 0) k--;
        hull[k++] = idxs[i];
    }

    hull.resize(k);
    return hull;
}
Example #3
0
//this could probably be optimized
//draws text and ensures it's never longer than xLen
void Font::drawWrappedText(std::string text, const Eigen::Vector2f& offset, float xLen, unsigned int color)
{
	float y = offset.y();

	std::string line, word, temp;
	Eigen::Vector2f textSize;
	size_t space, newline;

	while(text.length() > 0 || !line.empty()) //while there's text or we still have text to render
	{
		space = text.find(' ', 0);
		if(space == std::string::npos)
			space = text.length() - 1;


		word = text.substr(0, space + 1);

		//check if the next word contains a newline
		newline = word.find('\n', 0);
		if(newline != std::string::npos)
		{
			word = word.substr(0, newline);
			text.erase(0, newline + 1);
		}else{
			text.erase(0, space + 1);
		}

		temp = line + word;

		textSize = sizeText(temp);

		//if we're on the last word and it'll fit on the line, just add it to the line
		if((textSize.x() <= xLen && text.length() == 0) || newline != std::string::npos)
		{
			line = temp;
			word = "";
		}


		//if the next line will be too long or we're on the last of the text, render it
		if(textSize.x() > xLen || text.length() == 0 || newline != std::string::npos)
		{
			//render line now
			if(textSize.x() > 0) //make sure it's not blank
				drawText(line, Eigen::Vector2f(offset.x(), y), color);

			//increment y by height and some extra padding for the next line
			y += textSize.y() + 4;

			//move the word we skipped to the next line
			line = word;
		}else{
			//there's still space, continue building the line
			line = temp;
		}

	}
}
Example #4
0
 /**
  * Checks if point is inside rectangle. Rectangle coordinate parameters are
  * ordered in this check!
  *
  * param [in]   p        point
  * param [in]   r0       lower left corner of rectange
  * param [in]   r1       upper right corner of rectange
  *
  * returns      true if point was inside or at the edge of rectangle,
  *              false otherwise
  */
 static inline bool pointInsideOrderedRectange(const Eigen::Vector2f & p, const Eigen::Vector2f & r0, const Eigen::Vector2f & r1)
 {
     if(r0.x() <= p.x() && p.x() <= r1.x() &&
         r0.y() <= p.y() && p.y() <= r1.y())
     {
         return true;
     }
     return false;
 }
void MainWindow::onCalculateButtonPress()
{
	arcr.setLinePoint(0, 
		ui->line0x0SpinBox->value(), ui->line0y0SpinBox->value(),
		ui->line0x1SpinBox->value(), ui->line0y1SpinBox->value(), 
		ui->line0x2SpinBox->value(), ui->line0y2SpinBox->value());
	
	arcr.setLinePoint(1,
		ui->line1x0SpinBox->value(), ui->line1y0SpinBox->value(),
		ui->line1x1SpinBox->value(), ui->line1y1SpinBox->value(),
		ui->line1x2SpinBox->value(), ui->line1y2SpinBox->value());

	arcr.computeHMatrix();

	Eigen::Vector3f img(inputImage.width(), inputImage.height(), 1.0f);
	float xmin = 0;
	float xmax = 0;
	float ymin = 0;
	float ymax = 0;
	arcr.computImageSize(0, 0, inputImage.width(), inputImage.height(), xmin, xmax, ymin, ymax);

	float aspect = (xmax - xmin) / (ymax - ymin);
	outputImage = QImage(inputImage.width(), inputImage.width() / aspect, inputImage.format());
	outputImage.fill(qRgb(0, 0, 0));

	std::cout << "Output size: " << outputImage.width() << ", " << outputImage.height() << std::endl;

	float dx = (xmax - xmin) / float(outputImage.width());
	float dy = (ymax - ymin) / float(outputImage.height());

	std::cout << std::fixed << "dx, dy: " << dx << ", " << dy << std::endl;

	for (int x = 0; x < outputImage.width(); ++x)
	{
		for (int y = 0; y < outputImage.height(); ++y)
		{
			Eigen::Vector3f px(x, y, 1);

			float tx = 0.0f;
			float ty = 0.0f;
			Eigen::Vector2f t = arcr.multiplyPointMatrixInverse(xmin + x * dx, ymin + y * dy);

			if (t.x() > -1 && t.y() > -1
				&& t.x() < inputImage.width()
				&& t.y() < inputImage.height())
			{
				QRgb rgb = bilinearInterpol(inputImage, t.x(), t.y(), dx, dy);
				outputImage.setPixel(x, y, rgb);
			}
		}
	}


	ui->outputRadioButton->setChecked(true);
	update();
}
Example #6
0
double Terrain::GetHeight(Eigen::Vector2f xy) const{
	
	Cube* temp_cube;
	Cylinder* temp_cylinder;

	double x = xy.x();
	double z = xy.y();
	//check if x y lands on a surface object
	for(int i = 0; i < m_surface_objects.size(); i++){
		
		switch (m_surface_objects[i]->m_type)
		{
		case TypeCube:
			temp_cube = dynamic_cast<Cube*>(m_surface_objects[i]);
			if(x < temp_cube->m_Center[0] + temp_cube->m_Size[0]*0.5
				&& x > temp_cube->m_Center[0] - temp_cube->m_Size[0]*0.5
				&& z < temp_cube->m_Center[2] + temp_cube->m_Size[2]*0.5
				&& z > temp_cube->m_Center[2] - temp_cube->m_Size[2]*0.5)
				return temp_cube->m_Size[1];
			break;
		case TypeCylinder:
			temp_cylinder = dynamic_cast<Cylinder*>(m_surface_objects[i]);
			if(x < temp_cylinder->m_Center[0] + temp_cylinder->m_Size[0]*0.5
				&&x > temp_cylinder->m_Center[0] - temp_cylinder->m_Size[0]*0.5
				&&z < temp_cylinder->m_Center[2] + temp_cylinder->m_Size[2]*0.5
				&&z > temp_cylinder->m_Center[0] - temp_cylinder->m_Size[2]*0.5)
				return sqrt(0.25*temp_cylinder->m_Size[1]*temp_cylinder->m_Size[1] - (x - temp_cylinder->m_Center[0])*(x - temp_cylinder->m_Center[0]));
			break;
		default:
			break;
		}
		
	
	}


	int idx, idz;
	idx = (xy.x() + 0.5*m_size_x)/m_dx;
	idz = (xy.y() + 0.5*m_size_z)/m_dz;

	//interpolation
	double upleft, upright, downleft, downright;
	downleft = m_height_data[idx*(m_res_z+1) + idz];
	downright = m_height_data[(idx+1)*(m_res_z+1) + idz];
	upleft = m_height_data[idx*(m_res_z+1) + idz+1];
	upright = m_height_data[(idx+1)*(m_res_z+1) + idz+1];

	double alpha, beta;
	alpha = 1 - (xy.x() + 0.5*m_size_x - idx*m_dx)/m_dx;
	beta = 1 - (xy.y() + 0.5*m_size_z - idz*m_dz)/m_dz;

	return alpha*beta*downleft + (1-alpha)*beta*downright + (1-beta)*alpha*upleft + (1-beta)*(1-alpha)*upright;
}
Example #7
0
bool CreditScene::init() {
  Graphics::getInstance()->fadeIn(0.6f);
  _isInit = true;

  auto playerInput = Factory::get()->loadEntityFromFile("playerInput");
  playerInput->init();
  Scene::setPlayerInput(playerInput);

 
  _credits = Factory::get()->loadEntityFromFile("credits");
  _credits->init();
  auto PosCmp = _credits->GET_CMP(PositionComponent);
  PosCmp->setPosition(Graphics::getInstance()->getScreenSize().cast<float>() * 0.5);
  auto SpCmp = _credits->GET_CMP(SpriteCmp);
  // 1.5 1.5 looks good
  SpCmp->rescale(2.0f, 2.0f);


  Eigen::Vector2f pos = Graphics::getInstance()->getScreenSize().cast<float>() * 0.75;
  pos.x() =  Graphics::getInstance()->getScreenSize().cast<float>().x() * 0.88;

  Entity* returnButton = Factory::get()->loadEntityFromFile("buttonBack");
  returnButton->init();
  std::function<void()> optionFunc = [this](){ free(); Director::get()->pushScene(new MenuScene()); };
  returnButton->GET_CMP(ButtonCmp)->setCallback(optionFunc);
  PositionComponent* posCmp = returnButton->GET_CMP(PositionComponent);
  pos.y() += 200.0f;
  posCmp->setPosition(pos);

  _buttons.push_back(returnButton);
  _cursor = _buttons.begin();
  _brighter();

  return _isInit;
}
Example #8
0
Terrain::Terrain(Eigen::Vector2f a_size, Eigen::Vector2i a_res, int n_hill, TerrainType a_type){
	m_type = TypeTerrain;
	m_frictness = 10;
	
	InitBase(a_size.x(), a_size.y(), a_res.x(), a_res.y(), n_hill, a_type);

	InitDraw();
}
void ComponentGrid::updateSeparators()
{
	mLines.clear();

	bool drawAll = Settings::getInstance()->getBool("DebugGrid");

	Eigen::Vector2f pos;
	Eigen::Vector2f size;
	for(auto it = mCells.begin(); it != mCells.end(); it++)
	{
		if(!it->border && !drawAll)
			continue;

		// find component position + size
		pos << 0, 0;
		size << 0, 0;
		for(int x = 0; x < it->pos.x(); x++)
			pos[0] += getColWidth(x);
		for(int y = 0; y < it->pos.y(); y++)
			pos[1] += getRowHeight(y);
		for(int x = it->pos.x(); x < it->pos.x() + it->dim.x(); x++)
			size[0] += getColWidth(x);
		for(int y = it->pos.y(); y < it->pos.y() + it->dim.y(); y++)
			size[1] += getRowHeight(y);

		if(it->border & BORDER_TOP || drawAll)
		{
			mLines.push_back(Vert(pos.x(), pos.y()));
			mLines.push_back(Vert(pos.x() + size.x(), pos.y()));
		}
		if(it->border & BORDER_BOTTOM || drawAll)
		{
			mLines.push_back(Vert(pos.x(), pos.y() + size.y()));
			mLines.push_back(Vert(pos.x() + size.x(), mLines.back().y));
		}
		if(it->border & BORDER_LEFT || drawAll)
		{
			mLines.push_back(Vert(pos.x(), pos.y()));
			mLines.push_back(Vert(pos.x(), pos.y() + size.y()));
		}
		if(it->border & BORDER_RIGHT || drawAll)
		{
			mLines.push_back(Vert(pos.x() + size.x(), pos.y()));
			mLines.push_back(Vert(mLines.back().x, pos.y() + size.y()));
		}
	}

	mLineColors.reserve(mLines.size());
	Renderer::buildGLColorArray((GLubyte*)mLineColors.data(), 0xC6C7C6FF, mLines.size());
}
void NinePatchComponent::fitTo(Eigen::Vector2f size, Eigen::Vector3f position, Eigen::Vector2f padding)
{
	size += padding;
	position[0] -= padding.x() / 2;
	position[1] -= padding.y() / 2;

	setSize(size + Eigen::Vector2f(getCornerSize().x() * 2, getCornerSize().y() * 2));
	setPosition(-getCornerSize().x() + position.x(), -getCornerSize().y() + position.y());
}
Example #11
0
/**
 * Convert from image plane to pixel coordinates
 * @param camera_coordinate The 2D coordinate in camera image plane
 * @return image_coordinate The 2D coordinate in the image space
 */
Eigen::Vector2i Camera::image_plane_to_pixel( const Eigen::Vector2f & camera_coordinate ) const {
    using namespace Eigen;

    Vector3f cam_h { camera_coordinate.x(), camera_coordinate.y(), 1.0f };
    Vector3f image_h = m_k * cam_h;
    Eigen::Vector2i image_coordinate;
    image_coordinate.x( ) = std::round( image_h.x() );
    image_coordinate.y( ) = std::round( image_h.y() );
    return image_coordinate;
}
void VideoComponent::applyTheme(const std::shared_ptr<ThemeData>& theme, const std::string& view, const std::string& element, unsigned int properties)
{
	using namespace ThemeFlags;

	const ThemeData::ThemeElement* elem = theme->getElement(view, element, "video");
	if(!elem)
	{
		return;
	}

	Eigen::Vector2f scale = getParent() ? getParent()->getSize() : Eigen::Vector2f((float)Renderer::getScreenWidth(), (float)Renderer::getScreenHeight());

	if ((properties & POSITION) && elem->has("pos"))
	{
		Eigen::Vector2f denormalized = elem->get<Eigen::Vector2f>("pos").cwiseProduct(scale);
		setPosition(Eigen::Vector3f(denormalized.x(), denormalized.y(), 0));
		mStaticImage.setPosition(Eigen::Vector3f(denormalized.x(), denormalized.y(), 0));
	}

	if(properties & ThemeFlags::SIZE)
	{
		if(elem->has("size"))
			setResize(elem->get<Eigen::Vector2f>("size").cwiseProduct(scale));
		else if(elem->has("maxSize"))
			setMaxSize(elem->get<Eigen::Vector2f>("maxSize").cwiseProduct(scale));
	}

	// position + size also implies origin
	if (((properties & ORIGIN) || ((properties & POSITION) && (properties & ThemeFlags::SIZE))) && elem->has("origin"))
		setOrigin(elem->get<Eigen::Vector2f>("origin"));

	if(elem->has("default"))
		mConfig.defaultVideoPath = elem->get<std::string>("default");

	if((properties & ThemeFlags::DELAY) && elem->has("delay"))
		mConfig.startDelay = (unsigned)(elem->get<float>("delay") * 1000.0f);

	if (elem->has("showSnapshotNoVideo"))
		mConfig.showSnapshotNoVideo = elem->get<bool>("showSnapshotNoVideo");

	if (elem->has("showSnapshotDelay"))
		mConfig.showSnapshotDelay = elem->get<bool>("showSnapshotDelay");
}
Example #13
0
Eigen::Vector3f Terrain::GetNormal(Eigen::Vector2f xy) const{

	//COULD HAVE BUG HERE

	int idx, idz;
	idx = (xy.x() + 0.5*m_size_x)/m_dx;
	idz = (xy.y() + 0.5*m_size_z)/m_dz;

	//interpolation
	Eigen::Vector3f upleft, upright, downleft, downright;
	downleft = m_normal_data[idx*(m_res_z+1) + idz];
	downright = m_normal_data[(idx+1)*(m_res_z+1) + idz];
	upleft = m_normal_data[idx*(m_res_z+1) + idz+1];
	upright = m_normal_data[(idx+1)*(m_res_z+1) + idz+1];

	double alpha, beta;
	alpha = 1 - (xy.x() + 0.5*m_size_x - idx*m_dx)/m_dx;
	beta = 1 - (xy.y() + 0.5*m_size_z - idz*m_dz)/m_dz;

	return alpha*beta*downleft + (1-alpha)*beta*downright + (1-beta)*alpha*upleft + (1-beta)*(1-alpha)*upright;

}
  void draw(MapWriterInterface *interface)
  {
    if (!initialized_) return;

    hector_worldmodel_msgs::GetObjectModel data;
    if (!service_client_.call(data)) {
      ROS_ERROR_NAMED(name_, "Cannot draw victims, service %s failed", service_client_.getService().c_str());
      return;
    }

    std::string team_name;
    std::string mission_name;
    nh_.getParamCached("/team", team_name);
    nh_.getParamCached("/mission", mission_name);

    boost::posix_time::ptime now = ros::Time::now().toBoost();
    boost::gregorian::date now_date(now.date());
    boost::posix_time::time_duration now_time(now.time_of_day().hours(), now.time_of_day().minutes(), now.time_of_day().seconds(), 0);

    std::ofstream description_file((interface->getBasePathAndFileName() + "_qr.csv").c_str());
    if (description_file.is_open()) {
      if (!team_name.empty()) description_file << team_name << std::endl;
      description_file << now_date << "; " << now_time << std::endl;
      if (!mission_name.empty()) description_file << mission_name << std::endl;
      description_file << std::endl;
    }

    int counter = 0;
    for(hector_worldmodel_msgs::ObjectModel::_objects_type::const_iterator it = data.response.model.objects.begin(); it != data.response.model.objects.end(); ++it) {
      const hector_worldmodel_msgs::Object& object = *it;
      if (!class_id_.empty() && object.info.class_id != class_id_) continue;
      if (!draw_all_objects_ && object.state.state != hector_worldmodel_msgs::ObjectState::CONFIRMED) continue;
      if (object.state.state == hector_worldmodel_msgs::ObjectState::DISCARDED) continue;

      Eigen::Vector2f coords;
      coords.x() = object.pose.pose.position.x;
      coords.y() = object.pose.pose.position.y;
      interface->drawObjectOfInterest(coords, boost::lexical_cast<std::string>(++counter), MapWriterInterface::Color(10,10,240));

      if (description_file.is_open()) {
        boost::posix_time::time_duration time_of_day(object.header.stamp.toBoost().time_of_day());
        boost::posix_time::time_duration time(time_of_day.hours(), time_of_day.minutes(), time_of_day.seconds(), 0);
        description_file << counter << ";" << time << ";" << object.info.object_id << ";" << object.pose.pose.position.x << ";" << object.pose.pose.position.y << ";" << object.pose.pose.position.z << std::endl;
      }
    }

    description_file.close();
  }
void HectorMappingRos::setServiceGetMapData(nav_msgs::GetMap::Response& map_, const hectorslam::GridMap& gridMap)
{
  Eigen::Vector2f mapOrigin (gridMap.getWorldCoords(Eigen::Vector2f::Zero()));
  mapOrigin.array() -= gridMap.getCellLength()*0.5f;

  map_.map.info.origin.position.x = mapOrigin.x();
  map_.map.info.origin.position.y = mapOrigin.y();
  map_.map.info.origin.orientation.w = 1.0;

  map_.map.info.resolution = gridMap.getCellLength();

  map_.map.info.width = gridMap.getSizeX();
  map_.map.info.height = gridMap.getSizeY();

  map_.map.header.frame_id = p_map_frame_;
  map_.map.data.resize(map_.map.info.width * map_.map.info.height);
}
void TextEditComponent::render(const Eigen::Affine3f& parentTrans)
{
	Eigen::Affine3f trans = getTransform() * parentTrans;
	renderChildren(trans);

	// text + cursor rendering
	// offset into our "text area" (padding)
	trans.translation() += Eigen::Vector3f(getTextAreaPos().x(), getTextAreaPos().y(), 0);

	Eigen::Vector2i clipPos((int)trans.translation().x(), (int)trans.translation().y());
	Eigen::Vector3f dimScaled = trans * Eigen::Vector3f(getTextAreaSize().x(), getTextAreaSize().y(), 0); // use "text area" size for clipping
	Eigen::Vector2i clipDim((int)dimScaled.x() - trans.translation().x(), (int)dimScaled.y() - trans.translation().y());
	Renderer::pushClipRect(clipPos, clipDim);

	trans.translate(Eigen::Vector3f(-mScrollOffset.x(), -mScrollOffset.y(), 0));
	trans = roundMatrix(trans);

	Renderer::setMatrix(trans);

	if(mTextCache)
	{
		mFont->renderTextCache(mTextCache.get());
	}

	// pop the clip early to allow the cursor to be drawn outside of the "text area"
	Renderer::popClipRect();

	// draw cursor
	if(mEditing)
	{
		Eigen::Vector2f cursorPos;
		if(isMultiline())
		{
			cursorPos = mFont->getWrappedTextCursorOffset(mText, getTextAreaSize().x(), mCursor);
		}else{
			cursorPos = mFont->sizeText(mText.substr(0, mCursor));
			cursorPos[1] = 0;
		}

		float cursorHeight = mFont->getHeight() * 0.8f;
		Renderer::drawRect(cursorPos.x(), cursorPos.y() + (mFont->getHeight() - cursorHeight) / 2, 2.0f, cursorHeight, 0x000000FF);
	}
}
  void draw(MapWriterInterface *interface)
  {
    if (!initialized_) return;

    hector_worldmodel_msgs::GetObjectModel data;
    if (!service_client_.call(data)) {
      ROS_ERROR_NAMED(name_, "Cannot draw victims, service %s failed", service_client_.getService().c_str());
      return;
    }

    int counter = 0;
    for(hector_worldmodel_msgs::ObjectModel::_objects_type::const_iterator it = data.response.model.objects.begin(); it != data.response.model.objects.end(); ++it) {
      const hector_worldmodel_msgs::Object& object = *it;
      if (!draw_all_objects_ && object.state.state != hector_worldmodel_msgs::ObjectState::CONFIRMED) continue;
      if (!class_id_.empty() && object.info.class_id != class_id_) continue;

      Eigen::Vector2f coords;
      coords.x() = object.pose.pose.position.x;
      coords.y() = object.pose.pose.position.y;
      interface->drawObjectOfInterest(coords, boost::lexical_cast<std::string>(++counter), MapWriterInterface::Color(240,10,10));
    }
  }
Example #18
0
// 2D cross product of OA and OB vectors, i.e. z-component of their 3D cross product.
// Returns a positive value, if OAB makes a counter-clockwise turn,
// negative for clockwise turn, and zero if the points are collinear.
float cross(const Eigen::Vector2f O, const Eigen::Vector2f A, const Eigen::Vector2f B) {
    return (long)(A.x() - O.x()) * (B.y() - O.y()) - (long)(A.y() - O.y()) * (B.x() - O.x());
}
Example #19
0
void PathCmp::search (Eigen::Vector2f targetPos_) {
    _level = LogicSystem::getInstance()->getLevel();
    for (auto it = _openList.begin(); it != _openList.end(); ++ it) {
        if (*it != nullptr)
            delete *it;
    }
    _openList.clear();

    for (auto it = _closedList.begin(); it != _closedList.end(); ++ it) {
        if (*it != nullptr)
            delete *it;
    }
    _closedList.clear();
    _shortestPath.clear();

    auto posCmp = getEntity()->GET_CMP(PositionComponent);
    _srcIdx = _level->posToTileIndex(posCmp->getPosition());
    _tarIdx = _level->posToTileIndex(targetPos_);
    if (_srcIdx == _tarIdx)
        return;

    if (_level->isTileObstacle(_tarIdx.x(), _tarIdx.y()))
        return;

    PathNode* srcNode = new PathNode(_srcIdx);
    calcCostH(srcNode);
    _openList.push_back(srcNode);
    do {
        PathNode* curNode = _openList[0];
        _closedList.push_back(curNode);
        _openList.erase(_openList.begin());

        if (curNode->getIndex() == _tarIdx) {
            PathNode* walkNode = curNode;
            _shortestPath.clear();
            do {
                Eigen::Vector2f pos;
                pos.x() = _level->tileIndexXToPosX(walkNode->getIndex().x());
                pos.y() = _level->tileIndexYToPosY(walkNode->getIndex().y());
                _shortestPath.push_front(pos);
                walkNode = walkNode->getParent();
            } while (walkNode);
            for (auto it = _openList.begin(); it != _openList.end(); ++ it) {
                if (*it != nullptr)
                    delete *it;
            }
            _openList.clear();
            for (auto it = _closedList.begin(); it != _closedList.end(); ++ it) {
                if (*it != nullptr)
                    delete *it;
            }
            _closedList.clear();
            break;
        }

        putAdjacentTiles(curNode);
        for (auto it = _adjacentTiles.begin(); it != _adjacentTiles.end(); ++ it) {
            bool isInClosedList = false;
            for (int i = 0; i < _closedList.size(); ++ i)
                if ((*it) == _closedList[i]->getIndex())
                    isInClosedList = true;
            if (isInClosedList) continue;

            auto node = new PathNode(*it);
            int costGToAdd = calcCostG(node, curNode);
            std::vector<PathNode *>::iterator opit = _openList.begin();
            while (opit != _openList.end()) {
                if ((*opit)->getIndex() == node->getIndex())
                    break;
                ++ opit;
            }

            // already on openlist
            if (opit!= _openList.end()) {
                delete node;
                node = (*opit);
                if (curNode->getCostG() + costGToAdd < node->getCostG())
                    node->setCostG(curNode->getCostG() + costGToAdd);
            } else {
                node->setParent(curNode);
                node->setCostG(curNode->getCostG() + costGToAdd);
                calcCostH(node);
                addOpenList(node);
            }
        }
    } while (_openList.size() > 0);
}
Example #20
0
	D2D1_POINT_2F PointConversion(const Eigen::Vector2f& p) {
		D2D1_POINT_2F rv;
		rv.x = p.x();
		rv.y = p.y();
		return rv;
	}
Example #21
0
 static float cross(const Eigen::Vector2f & a, const Eigen::Vector2f & b)
 {
     return a.x() * b.y() - a.y() * b.x();
 }
Example #22
0
void __AGE Button::update(float dt)
{
  Entity::update(dt);

  Input& input = Input::instance();


  if( transformationDirty )
  {
    // make sure the text passes the z test
    textEntity->setZ(z()+1e-3);
    computeClickBoundingBox();
  }

  // update state
  switch( state )
  {
  case 0:
  case 1:
    {
      for( int id = 0; id < MOUSE_POINTERS; ++id )
      {
        Eigen::Vector2f pos;
        input.mouseXY(pos.x(), pos.y(),id);
        bool inside_bb = isInside(pos, clickBoundingBoxMin, clickBoundingBoxMax);
        if( inside_bb )
        {
          if( input.mouseJustPressed(0,0,id) )
          {
            state = 2;
            mouse_id = id;
          }
          else
          {
#ifdef __ANDROID__
            state = 0; // no hover on touch devices
#else
            state = 1; // hover
#endif
          }
          break;
        }
        else
          state = 0;
      }

    }
    break;
  case 2:
    {
      Eigen::Vector2f pos;
      input.mouseXY(pos.x(), pos.y(),mouse_id);
      if( input.mouseJustReleased(0,0,mouse_id) )
      {
        bool inside_bb = isInside(pos, clickBoundingBoxMin, clickBoundingBoxMax);
        if( inside_bb )
        {
          _triggeredCallback(dt);
        }
        state = 0;
      }
    }
    break;
  }

}
 virtual bool isTouching(Eigen::Vector2f position_,
                         float width_, float height_) const {
   const Rect rectB(position_.x(), position_.y(), 
             width_, height_);
   return _rect.isIntersected(rectB);}};
Example #24
0
 static Eigen::Vector2f normal(const Eigen::Vector2f & line)
 {
     return Eigen::Vector2f(line.y(), -line.x());
 }
Example #25
0
void glsl_program::set_uniform(unsigned loc, const Eigen::Vector2f& value) const
{
    if (used_program != this)
	throw runtime_error("glsl_program::set_uniform, program not bound!");
    glUniform2f(loc, value.x(), value.y());
}
void SliderComponent::onValueChanged()
{
	// update suffix textcache
	if(mFont)
	{
		std::stringstream ss;
		ss << std::fixed;
		ss.precision(0);
		ss << mValue;
		ss << mSuffix;
		const std::string val = ss.str();

		ss.str("");
		ss.clear();
		ss << std::fixed;
		ss.precision(0);
		ss << mMax;
		ss << mSuffix;
		const std::string max = ss.str();

		Eigen::Vector2f textSize = mFont->sizeText(max);
		mValueCache = std::shared_ptr<TextCache>(mFont->buildTextCache(val, mSize.x() - textSize.x(), (mSize.y() - textSize.y()) / 2, 0x777777FF));
		mValueCache->metrics.size[0] = textSize.x(); // fudge the width
	}

	// update knob position/size
	mKnob.setResize(0, mSize.y() * 0.7f);
	float lineLength = mSize.x() - mKnob.getSize().x() - (mValueCache ? mValueCache->metrics.size.x() + 4 : 0);
	mKnob.setPosition(((mValue + mMin) / mMax) * lineLength + mKnob.getSize().x()/2, mSize.y() / 2);
}
void NinePatchComponent::buildVertices()
{
	if(mVertices != NULL)
		delete[] mVertices;

	if(mColors != NULL)
		delete[] mColors;

	mTexture = TextureResource::get(mPath);

	if(mTexture->getSize() == Eigen::Vector2i::Zero())
	{
		mVertices = NULL;
		mColors = NULL;
		LOG(LogWarning) << "NinePatchComponent missing texture!";
		return;
	}

	mVertices = new Vertex[6 * 9];
	mColors = new GLubyte[6 * 9 * 4];
	updateColors();

	const Eigen::Vector2f ts = mTexture->getSize().cast<float>();

	//coordinates on the image in pixels, top left origin
	const Eigen::Vector2f pieceCoords[9] = {
		Eigen::Vector2f(0,  0),
		Eigen::Vector2f(16, 0),
		Eigen::Vector2f(32, 0),
		Eigen::Vector2f(0,  16),
		Eigen::Vector2f(16, 16),
		Eigen::Vector2f(32, 16),
		Eigen::Vector2f(0,  32),
		Eigen::Vector2f(16, 32),
		Eigen::Vector2f(32, 32),
	};

	const Eigen::Vector2f pieceSizes = getCornerSize();

	//corners never stretch, so we calculate a width and height for slices 1, 3, 5, and 7
	float borderWidth = mSize.x() - (pieceSizes.x() * 2); //should be pieceSizes[0] and pieceSizes[2]
	//if(borderWidth < pieceSizes.x())
	//	borderWidth = pieceSizes.x();

	float borderHeight = mSize.y() - (pieceSizes.y() * 2); //should be pieceSizes[0] and pieceSizes[6]
	//if(borderHeight < pieceSizes.y())
	//	borderHeight = pieceSizes.y();

	mVertices[0 * 6].pos = pieceCoords[0]; //top left
	mVertices[1 * 6].pos = pieceCoords[1]; //top middle
	mVertices[2 * 6].pos = pieceCoords[1] + Eigen::Vector2f(borderWidth, 0); //top right

	mVertices[3 * 6].pos = mVertices[0 * 6].pos + Eigen::Vector2f(0, pieceSizes.y()); //mid left
	mVertices[4 * 6].pos = mVertices[3 * 6].pos + Eigen::Vector2f(pieceSizes.x(), 0); //mid middle
	mVertices[5 * 6].pos = mVertices[4 * 6].pos + Eigen::Vector2f(borderWidth, 0); //mid right

	mVertices[6 * 6].pos = mVertices[3 * 6].pos + Eigen::Vector2f(0, borderHeight); //bot left
	mVertices[7 * 6].pos = mVertices[6 * 6].pos + Eigen::Vector2f(pieceSizes.x(), 0); //bot middle
	mVertices[8 * 6].pos = mVertices[7 * 6].pos + Eigen::Vector2f(borderWidth, 0); //bot right

	int v = 0;
	for(int slice = 0; slice < 9; slice++)
	{
		Eigen::Vector2f size;

		//corners
		if(slice == 0 || slice == 2 || slice == 6 || slice == 8)
			size = pieceSizes;

		//vertical borders
		if(slice == 1 || slice == 7)
			size << borderWidth, pieceSizes.y();

		//horizontal borders
		if(slice == 3 || slice == 5)
			size << pieceSizes.x(), borderHeight;

		//center
		if(slice == 4)
			size << borderWidth, borderHeight;

		//no resizing will be necessary
		//mVertices[v + 0] is already correct
		mVertices[v + 1].pos = mVertices[v + 0].pos + size;
		mVertices[v + 2].pos << mVertices[v + 0].pos.x(), mVertices[v + 1].pos.y();

		mVertices[v + 3].pos << mVertices[v + 1].pos.x(), mVertices[v + 0].pos.y();
		mVertices[v + 4].pos = mVertices[v + 1].pos;
		mVertices[v + 5].pos = mVertices[v + 0].pos;

		//texture coordinates
		//the y = (1 - y) is to deal with texture coordinates having a bottom left corner origin vs. verticies having a top left origin
		mVertices[v + 0].tex << pieceCoords[slice].x() / ts.x(), 1 - (pieceCoords[slice].y() / ts.y());
		mVertices[v + 1].tex << (pieceCoords[slice].x() + pieceSizes.x()) / ts.x(), 1 - ((pieceCoords[slice].y() + pieceSizes.y()) / ts.y());
		mVertices[v + 2].tex << mVertices[v + 0].tex.x(), mVertices[v + 1].tex.y();

		mVertices[v + 3].tex << mVertices[v + 1].tex.x(), mVertices[v + 0].tex.y();
		mVertices[v + 4].tex = mVertices[v + 1].tex;
		mVertices[v + 5].tex = mVertices[v + 0].tex;

		v += 6;
	}

	// round vertices
	for(int i = 0; i < 6*9; i++)
	{
		mVertices[i].pos = roundVector(mVertices[i].pos);
	}
}
Example #28
0
 static inline float distance(const Eigen::Vector2f & v0, const Eigen::Vector2f & v1)
 {
     return sqrt(
         (v0.x() - v1.x()) * (v0.x() - v1.x()) +
         (v0.y() - v1.y()) * (v0.y() - v1.y()));
 }
Example #29
0
        /**
         * param [in]   point       point
         * param [in]   p1          line segments start
         * param [in]   p0          line segments end
         * param [out]  closest     closest point on segment for the point
         * returns      distance from point to the closest point
         *
         * Returns minimum distance between line segment vw and point p.
         * returns the closest point on the line segment.
         */
        static float pointDistanceToLine(const Eigen::Vector2f & point, const Eigen::Vector2f & p1, const Eigen::Vector2f & p2, Eigen::Vector2f & closest)
        {
            float dx = p2.x() - p1.x();
            float dy = p2.y() - p1.y();
            if((dx == 0) && (dy == 0))
            {
                // Line is a point!
                closest = p1;
                dx = point.x() - p1.x();
                dy = point.y() - p1.y();
            }
            else
            {
                // Calculate the t that minimizes the distance
                float t = ((point.x() - p1.x()) * dx + (point.y() - p1.y()) * dy) / (dx * dx + dy * dy);

                // See if this represents one of the segment's  end points or
                // a point in the middle.
                if(t < 0)
                {
                    closest = Eigen::Vector2f(p1.x(), p1.y());
                    dx = point.x() - p1.x();
                    dy = point.y() - p1.y();
                }
                else if(t > 1)
                {
                    closest = Eigen::Vector2f(p2.x(), p2.y());
                    dx = point.x() - p2.x();
                    dy = point.y() - p2.y();
                }
                else
                {
                    closest = Eigen::Vector2f(p1.x() + t * dx, p1.y() + t * dy);
                    dx = point.x() - closest.x();
                    dy = point.y() - closest.y();
                }
            }

            return sqrt(dx * dx + dy * dy);
        }
Example #30
0
		/** Sets normal from gradient */
		void setNormalFromGradient(const Eigen::Vector2f& g) {
			const float gx = g.x();
			const float gy = g.y();
			const float scl = Danvil::MoreMath::FastInverseSqrt(gx*gx + gy*gy + 1.0f);
			setNormal(Eigen::Vector3f(scl*gx, scl*gy, -scl));
		}