Beispiel #1
0
void enigma_rotor_window::draw(Cairo::RefPtr<Cairo::Context> cr)
{
    vector<double> dashes;
    // Pattern used to draw a dashed line (15 pixels of line followed by 15 "empty" pixels)
    dashes.push_back(15.0);
    dashes.push_back(15.0);
    
    if (has_ellipse)
    {
        cr->save();
        
            // Draw background ellipse
            cr->set_source_rgb(bkg_r, bkg_g, bkg_b);
            draw_ellipse(cr, x, y, ellipse_width, ellipse_height);
            cr->fill();
            // Draw black border of background ellipse
            cr->set_source_rgb(BLACK);
            cr->set_line_width(1.2);
            draw_ellipse(cr, x, y, ellipse_width, ellipse_height);
            cr->stroke();
        
        cr->restore();
    }
    
    cr->save();  
    
        // Draw a line of width rotor_rim_width in the dash background colour
        cr->set_line_width(rotor_rim_width);
        cr->set_source_rgb(dash_bkg_r, dash_bkg_g, dash_bkg_b);
        cr->move_to(x + window_size, y - (2 * window_size));
        cr->line_to(x + window_size, y + (2 * window_size));
        cr->stroke();
        
        // Draw a dashed line in the dash colour inside the previously drawn line
        // This creates the impression of "notches" on the handle/rim
        cr->set_source_rgb(dash_r, dash_g, dash_b);
        cr->set_dash(dashes, ((wheel_pos - 'A') & 1) * 15); // modifying the offset creates illusion of movement
        
        cr->move_to(x + window_size, y - (2 * window_size));
        cr->line_to(x + window_size, y + (2 * window_size));
        cr->stroke();
        
        // Draw border around handle/rim
        cr->set_line_width(2.0);
        cr->unset_dash();
        cr->set_source_rgb(DARK_GREY);
        cr->rectangle(x + padded_size, y - (2 * window_size), rotor_rim_width, (4 * window_size));
        cr->stroke();
    
    cr->restore();

    draw_wheel_pos(cr, wheel_pos);
    
    if (has_ellipse)
    {
        // Draw screws
        upper->draw(cr);
        lower->draw(cr);    
    }
}
Beispiel #2
0
void MapDrawArea::DrawObstacles(const Cairo::RefPtr<Cairo::Context>& cr)
{
	// Get size characteristics of the window
	Gtk::Allocation allocation = get_allocation();
	const int width = allocation.get_width();
	const int height = allocation.get_height();
	const int lesser = MIN(width, height);

	// We should be able to just store the obstacles and path once
	// Do need to update based on the window size
	std::vector<Coord> vObstacles = guiMapData.copyObstacles();
	Coord maxXY = guiMapData.copyMaxCoord();
	Coord originCoord = guiMapData.copyStartCoord();
	Coord goalCoord = guiMapData.copyEndCoord();

	// These have to be updated each iteration
	originCoord.x = int( float(width)*float(originCoord.x)/float(maxXY.x) );
	originCoord.y = int( float(height)*float(originCoord.y)/float(maxXY.y) );
	goalCoord.x = int( float(width)*float(goalCoord.x)/float(maxXY.x) );
	goalCoord.y = int( float(height)*float(goalCoord.y)/float(maxXY.y) );

	// Draw obstacles
	std::vector<Coord> scaledObstacleCoord;
	std::vector<Coord> rawObstacleCoord = guiMapData.copyObstacles();
	Coord stdCoord;

	// Adjust obstacle values based on window size
	for(std::vector<Coord>::const_iterator itr=rawObstacleCoord.begin();itr!=rawObstacleCoord.end();++itr)
	{
		stdCoord.x = int( float(width)*float(itr->x)/float(maxXY.x) );
		stdCoord.y = int( height*float(itr->y)/float(maxXY.y) );
		scaledObstacleCoord.push_back(stdCoord);
	}

	cr->save();
	cr->set_source_rgb(0.0, 0.0, 0.0);	// black for obstacles
	cr->set_line_width(lesser * 0.005);
	cr->set_line_cap(Cairo::LINE_CAP_ROUND);

	// Plot obstacles
	for(std::vector<Coord>::iterator itr=scaledObstacleCoord.begin();itr != scaledObstacleCoord.end();++itr)
	{
		cr->move_to( itr->x,itr->y );
		cr->line_to( itr->x,itr->y );
		cr->stroke();
	}

	// Plot start/end coord
	cr->save();
	cr->set_line_width(lesser * 0.015);
	cr->set_source_rgb(1.0, 0.0, 0.0);	// red for start point
	cr->move_to( originCoord.x,originCoord.y );
	cr->line_to( originCoord.x,originCoord.y );
	cr->stroke();
	cr->save();
	cr->set_source_rgb(0.0, 1.0, 0.0);	// green for end point
	cr->move_to( goalCoord.x,goalCoord.y );
	cr->line_to( goalCoord.x,goalCoord.y );
	cr->stroke();
}
Beispiel #3
0
void cairo::draw_face_edge_sequences( const Cairo::RefPtr<Cairo::Context>& cr, const Geodesics::surface_type::edge_descriptor& edge, const Geodesics& m_geodesics )
{
  const auto    e0out = Geodesics::edge_handle( edge, m_geodesics.get_surface() );
  const auto 	e0w   = m_geodesics.edge_windows( e0out );
  const auto 	e0in  = e0out.opposite();
  const coord_t e0len = e0out.length();

  // draw base
  draw_edge_sequences( cr, e0w.first, e0w.second, m_geodesics );

  // draw lower left edge

  if( ! e0in.second ) return ;
  auto e1out = e0in.first.next().opposite();

  if( e1out.second )
  {
	auto e1w = m_geodesics.edge_windows( e1out.first );
    const coord_t e1len = e1out.first.length();
    cr->save();

      cr->rotate( - e0in.first.next_inner_angle() );

	  cr->translate( e1len, 0. );

	  cr->rotate( M_PI );
	  //cr->scale( -1., -1. );

      draw_edge_sequences( cr, e1w.first, e1w.second, m_geodesics );

    cr->restore();
  }


  // draw lower right edge

  const Geodesics::edge_handle e2in = e0in.first.previous();
  const auto e2out = e2in.opposite();

  if( ! e2out.second ) return;

  auto e2w = m_geodesics.edge_windows( e2out.first );

  cr->save();

	cr->translate( e0len, 0. );

    cr->rotate( e2in.next_inner_angle() );

    cr->scale( -1., -1. );

    draw_edge_sequences( cr, e2w.first, e2w.second, m_geodesics );

  cr->restore();
}
Beispiel #4
0
void Window::draw(Cairo::RefPtr<Cairo::Context> ctx)
{
	ctx->save();
    ctx->set_source_rgb(0.9, 0.9, 0.9);
    ctx->paint();
    ctx->restore();

    ctx->save();
    ctx->set_line_width(1.0);
    ctx->rectangle(0, 0, width, height);
    ctx->stroke();
    ctx->restore();
}
Beispiel #5
0
bool Canvas::on_expose_event(GdkEventExpose * evt) {
	Glib::RefPtr<Gdk::Window> window = get_window();
	if (!window) return false; // no window yet?

	if (!seen_first_expose_event) {
		seen_first_expose_event = true;
		main->controlsWindow().starting_position();
	}

	Cairo::RefPtr<Cairo::Context> cr = window->create_cairo_context();

	if (!surface) return true; // Haven't rendered yet? Nothing we can do
	if (evt) {
		cr->rectangle(evt->area.x, evt->area.y, evt->area.width, evt->area.height);
		cr->clip();
	}

	cr->set_source(surface, 0, 0);
	cr->paint();

	if (main->dragrect.is_active() && main->dragrect.surface_valid()) {
		cr->save();
		cr->set_source(main->dragrect.get_surface(), 0, 0);
		cr->paint();
		cr->restore();
	}

	if (main->hud_active()) {
		Cairo::RefPtr<Cairo::Surface>& sfc = main->get_hud_surface();
		if (sfc)
			cr->set_source(sfc, 0, 0); // TODO HUD position
		cr->paint();
	}
	return true;
}
Beispiel #6
0
bool RegionChooser::on_draw(const Cairo::RefPtr<Cairo::Context>& cr) {
    double clipx1, clipx2, clipy1, clipy2;
    cr->get_clip_extents(clipx1, clipy1, clipx2, clipy2);
#endif

    cr->save();
    cr->set_line_width(1);

#if (GTKMM_MAJOR_VERSION == 2 && GTKMM_MINOR_VERSION < 90) || GTKMM_MAJOR_VERSION < 2
    const Gdk::Color bg = get_style()->get_bg(Gtk::STATE_NORMAL);
#else
    const Gdk::RGBA bg = get_style_context()->get_background_color();
#endif
    Gdk::Cairo::set_source_rgba(cr, bg);
    cr->paint();

    if (clipy2 > h1) {
        draw_keyboard(cr, clipx1, clipx2);
    }

    if (clipy1 < h1 && instrument) {
        draw_regions(cr, clipx1, clipx2);
    }

    cr->restore();

    return true;
}
void ActivityDrawingArea::drawAxis() {
	// draw a reference axis and pod info
	Glib::RefPtr < Gdk::Window > window = get_window();
	Cairo::RefPtr < Cairo::Context > cr = window->create_cairo_context();
	Gtk::Allocation allocation = get_allocation();
	const int width = allocation.get_width();
	const int height = allocation.get_height();

	//draw axis
	cr->save();
	cr->set_line_width(2.0);
	this->setSourceRGB(cr, currentColourScheme.getAxisColour());
	cr->set_font_size(12);

	cr->move_to(0, height / 2);
	cr->line_to(width, height / 2);

	cr->move_to(190, 25 + height / 2);
	cr->show_text("20");
	cr->move_to(390, 25 + height / 2);
	cr->show_text("40");
	cr->move_to(590, 25 + height / 2);
	cr->show_text("60");
	cr->move_to(790, 25 + height / 2);
	cr->show_text("80");

	cr->stroke();
	cr->restore();
}
void
Renderer_Dragbox::render_vfunc(
	const Glib::RefPtr<Gdk::Window>& drawable,
	const Gdk::Rectangle& /*expose_area*/
)
{
	assert(get_work_area());
	if(!get_work_area())
		return;

	// const synfig::Vector focus_point(get_work_area()->get_focus_point());
	// Warning : Unused focus_point
	int drawable_w = drawable->get_width();
	int drawable_h = drawable->get_height();

	Cairo::RefPtr<Cairo::Context> cr = drawable->create_cairo_context();

	const synfig::Vector::value_type window_startx(get_work_area()->get_window_tl()[0]);
	const synfig::Vector::value_type window_starty(get_work_area()->get_window_tl()[1]);
	const float pw(get_pw()),ph(get_ph());

	const synfig::Point& curr_point(get_curr_point());
	const synfig::Point& drag_point(get_drag_point());

	{
		cr->save();
		cr->set_line_cap(Cairo::LINE_CAP_BUTT);
		cr->set_line_join(Cairo::LINE_JOIN_MITER);
		cr->set_antialias(Cairo::ANTIALIAS_NONE);

		cr->set_line_width(1.0);
		cr->set_source_rgb(0,0,0);
		std::valarray<double> dashes(2);
		dashes[0]=5.0;
		dashes[1]=5.0;
		cr->set_dash(dashes, 0);

		Point tl(std::min(drag_point[0],curr_point[0]),std::min(drag_point[1],curr_point[1]));
		Point br(std::max(drag_point[0],curr_point[0]),std::max(drag_point[1],curr_point[1]));

		tl[0]=(tl[0]-window_startx)/pw;
		tl[1]=(tl[1]-window_starty)/ph;
		br[0]=(br[0]-window_startx)/pw;
		br[1]=(br[1]-window_starty)/ph;
		if(tl[0]>br[0])
			swap(tl[0],br[0]);
		if(tl[1]>br[1])
			swap(tl[1],br[1]);

		cr->rectangle(
			tl[0],
			tl[1],
			br[0]-tl[0],
			br[1]-tl[1]
		);
		cr->stroke();

		cr->restore();
	}
}
Beispiel #9
0
void Drawable::draw(const Cairo::RefPtr<Cairo::Context>& context,
                    ImageBuffer& buff) {
  context->save();
  // std::cout << getImageName() << std::endl;
  auto image = buff.getImage(getImageName(), flipped_, scaleX, scaleY);

  // int width = image->get_width();
  // int height = image->get_height();
  proto::Position pos = getPosition();

  int x = c_.scaleWidth(pos.x);
  int y = c_.scaleHeight(pos.y);

  // Gdk::Cairo::set_source_pixbuf(context, image, pos.x + width / 2,
  //                               pos.y - height / 2);
  Gdk::Cairo::set_source_pixbuf(context, image, x, offset_ + y);
  context->paint();

  // context->set_source_rgb(0.8, 0.0, 0.0);
  // context->move_to(pos.x, pos.y);
  // context->line_to(pos.x + width / 2, pos.y - height / 2);
  // context->line_to(pos.x + width / 2, pos.y + height / 2);
  // context->line_to(pos.x - width / 2, pos.y + height / 2);
  // context->line_to(pos.x - width / 2, pos.y - height / 2);
  // context->line_to(pos.x + width / 2, pos.y - height / 2);
  // context->stroke();

  context->restore();
}
Beispiel #10
0
bool Balls::on_draw(const Cairo::RefPtr<Cairo::Context>& cr)
{
  Gtk::Allocation allocation = get_allocation();
  const int width = allocation.get_width();
  const int height = allocation.get_height();

  cr->save();
  cr->scale(width, height);

  cr->set_line_width(0.001);
  for (auto ball : balls_)
    {
      cr->set_source_rgb(ball.color_r,ball.color_g,ball.color_b);
      cr->arc(ball.p.x,ball.p.y,
              ball.rad,
              0,2*M_PI);
      cr->fill();
      cr->stroke();
    }

  cr->restore();

  const Ball &ball1 = balls_[balls_.size()-1];
  std::ostringstream info;
  info << "x = " << ball1.p.x << "\ny = " << ball1.p.y;
  infobox_.show(cr,width,height,info.str());

  return true;
}
Beispiel #11
0
void ItemView::drawReminderIcon(const Cairo::RefPtr<Cairo::Context>& cr, const int width, const int height)
{
    cr->save();

    //draw reminder icon
    cr->set_antialias(Cairo::ANTIALIAS_NONE);

    if (data.isReminder())
    {
        Gtk::Image* image = Resources::res->imgReminderIcon;

        if (getColorMode() == COLOR_ALARM)
            image = Resources::res->imgReminderOnIcon;

        const Glib::RefPtr<Gdk::Pixbuf> icon = image->get_pixbuf();

        const int iconLeft = (TIME_WIDTH * 0.5) - (icon->get_width() * 0.5);
        const int iconTop = (height - icon->get_height()) - (PADDING * 3);

        Gdk::Cairo::set_source_pixbuf(cr, icon, iconLeft, iconTop);

        cr->rectangle(iconLeft, iconTop, icon->get_width(), icon->get_height());
        cr->fill();
    }

    cr->restore();
}
Beispiel #12
0
void NodeRenderer::label(const Cairo::RefPtr<Cairo::Context>& cr,
		std::list<shared_ptr<Label> >& labels,
		AssetCache& cache)
{
	// nothing to print
	if (s->text.str().size() == 0 || s->font_size <= 0)
		return;

	cr->save();

	cr->set_font_size(s->font_size);

	cr->set_font_face(cache.getFont(
			s->font_family.str(),
			s->font_style == Style::STYLE_ITALIC ? Cairo::FONT_SLANT_ITALIC : Cairo::FONT_SLANT_NORMAL,
			s->font_weight == Style::WEIGHT_BOLD ? Cairo::FONT_WEIGHT_BOLD : Cairo::FONT_WEIGHT_NORMAL
		));

	Cairo::TextExtents textSize;
	cr->get_text_extents(s->text.str(), textSize);

	addLabel(labels, location + FloatPoint(0.0, s->text_offset), textSize);

	cr->restore();
}
Beispiel #13
0
void MapDrawArea::DrawOptimalPath(const Cairo::RefPtr<Cairo::Context>& cr)
{
	// This is where we draw on the window
	Gtk::Allocation allocation = get_allocation();
	const int width = allocation.get_width();
	const int height = allocation.get_height();
	const int lesser = MIN(width, height);
	const Coord maxXY = guiMapData.copyMaxCoord();

	// Copy the optimal path to the draw area
	std::vector<Coord> optimalPath = guiMapData.copyOptPath();

	// Plot the path
	cr->save();
	cr->set_source_rgb(1.0, 0.08, 0.58);	// pink for path
	cr->set_line_width(lesser * 0.005);
	cr->set_line_cap(Cairo::LINE_CAP_ROUND);

	for(std::vector<Coord>::iterator itr=optimalPath.begin();itr != optimalPath.end();++itr)
	{
		cr->move_to( int( float(width)*float(itr->x)/float(maxXY.x) ),int( height*float(itr->y)/float(maxXY.y)));
		cr->line_to( int( float(width)*float(itr->x)/float(maxXY.x) ),int( height*float(itr->y)/float(maxXY.y)));
		cr->stroke();
	}
}
Beispiel #14
0
void
HomVectorDrawer::draw(Cairo::RefPtr<Cairo::Context>& context)
{
  context->save();

  HomPoint start, end;
  if (m_offset)
    {
      start = HomPoint( m_offset->x(), m_offset->y() );
      end   = HomPoint( m_offset->x() + m_vector->x(),
			m_offset->y() + m_vector->y() );
    }
  else
    {
      start = HomPoint( 0.0, 0.0 );
      end   = HomPoint( m_vector->x(), m_vector->y() );
    }

  context->move_to( start.x(), start.y() );
  context->line_to( end.x()  , end.y()   );
  context->arc( end.x(), end.y(), 0.06, 0.0, 2.0 * M_PI);
  context->fill();

  context->stroke();
  context->restore();
}
void Simple_GOL_Area::draw_grid(const Cairo::RefPtr<Cairo::Context>& cr, int window_width, int window_height)
{	
	int data_amount = sim_data->get_size();
	
	if (data_amount != 0)
	{
		//sim_data->set_width(20);
		double step_value_x = double(window_width)/double(sim_data->get_width());
		double step_value_y = double(window_height)/double(sim_data->get_height());

		cr->save();
	
		cr->set_line_width(1.0);
		cr->set_source_rgb(0.5,0.5,1);
		cr->move_to(0,0);

		for(double i=0; i<window_width; i = i+ step_value_x)
		{
			cr->move_to(i, 0);
			cr->line_to(i, window_height);
		}
	
		for(double i=0; i<window_height; i = i+step_value_y)
		{
			cr->move_to(0, i);
			cr->line_to(window_width, i);
		}
	
		cr->stroke();
		cr->restore();
	}	
}
Beispiel #16
0
	void renderLabels(const char* path)
	{
		BOOST_TEST_MESSAGE("Render: " << path);

		Cairo::RefPtr<Cairo::Surface> surface = Cairo::ImageSurface::create(Cairo::FORMAT_ARGB32,
			META_TILE_SIZE * TILE_SIZE, META_TILE_SIZE * TILE_SIZE);
		Cairo::RefPtr<Cairo::Context> cr = Cairo::Context::create(surface);
		cr->set_source_rgba(0.0, 0.0, 0.0, 1.0);

		cr->save();
		cr->set_source_rgba(1.0, 1.0, 1.0, 1.0);
		cr->paint();
		cr->restore();

		std::vector<std::pair<string, FloatPoint>> toPlace;
		toPlace.push_back(std::pair<string, FloatPoint>("Karlsruhe", FloatPoint(40, 200)));
		toPlace.push_back(std::pair<string, FloatPoint>("Mannheim", FloatPoint(400, 200)));
		toPlace.push_back(std::pair<string, FloatPoint>("Stuttgard", FloatPoint(200, 260)));
		toPlace.push_back(std::pair<string, FloatPoint>("München", FloatPoint(380, 660)));
		toPlace.push_back(std::pair<string, FloatPoint>("Pforzheim", FloatPoint(200, 600)));
		toPlace.push_back(std::pair<string, FloatPoint>("Wien", FloatPoint(240, 680)));
		toPlace.push_back(std::pair<string, FloatPoint>("Paris", FloatPoint(40, 880)));
		toPlace.push_back(std::pair<string, FloatPoint>("Rom", FloatPoint(-40, 880)));
		toPlace.push_back(std::pair<string, FloatPoint>("Nothing", FloatPoint(400, 760)));
		toPlace.push_back(std::pair<string, FloatPoint>("To See", FloatPoint(720, 880)));
		toPlace.push_back(std::pair<string, FloatPoint>("Here", FloatPoint(720, 560)));
		toPlace.push_back(std::pair<string, FloatPoint>("Bielefeld", FloatPoint(420, 840)));
		renderer->renderLabels(cr, toPlace);

		BOOST_TEST_MESSAGE("Writing.");
		surface->flush();
		surface->write_to_png(path);
	}
Beispiel #17
0
void CairoPlugin::init()
{
    int height, width;

    preferredSize(width, height);

    m_img = Cairo::ImageSurface::create(Cairo::FORMAT_ARGB32, width, height);
    m_store = Cairo::ImageSurface::create(Cairo::FORMAT_ARGB32, width, height);
    m_ctx = Cairo::Context::create(m_img);

    Cairo::RefPtr < Cairo::Context > ctx = Cairo::Context::create(m_store);

    ctx->save();
    ctx->set_source_rgb(1.0, 1.0, 1.0);
    ctx->set_operator(Cairo::OPERATOR_SOURCE);
    ctx->paint();
    ctx->set_operator(Cairo::OPERATOR_OVER);
    ctx->restore();

    m_ctx->save();
    m_ctx->set_source_rgb(1.0, 1.0, 1.0);
    m_ctx->set_operator(Cairo::OPERATOR_SOURCE);
    m_ctx->paint();
    m_ctx->set_operator(Cairo::OPERATOR_OVER);
    m_ctx->restore();

    m_init = false;
    m_need = true;
}
Beispiel #18
0
void Format7DrawingArea::DrawDisabledText(Cairo::RefPtr<Cairo::Context> refCairo)
{
    refCairo->save();

    // Set the font parameters
    refCairo->select_font_face(
        "monospace",
        Cairo::FONT_SLANT_NORMAL,
        Cairo::FONT_WEIGHT_BOLD );
    refCairo->set_font_size( 10 );

    // Set draw color to black
    refCairo->set_source_rgb(0.0, 0.0, 0.0);

    // Print current cursor position
    char cursorPosition[128];
    sprintf(
        cursorPosition,
        "Custom Image is not supported by this camera.");

    // Get width / height of widget
    int width;
    int height;
    get_window()->get_size( width, height );

    Cairo::TextExtents textExtents;
    refCairo->get_text_extents( cursorPosition, textExtents );
    refCairo->move_to(
        (width/2) - (textExtents.width/2),
        (height/2) + textExtents.height + (textExtents.height/2));
    refCairo->show_text( cursorPosition );

    refCairo->restore();
}
Beispiel #19
0
void NodeRenderer::icon(const Cairo::RefPtr<Cairo::Context>& cr, AssetCache& cache)
{
	// path to icon not set
	if (s->icon_image.str().size() == 0 || s->icon_width == 0.0 || s->icon_height == 0.0)
		return;

	cr->save();

	Cairo::RefPtr<Cairo::ImageSurface> image = cache.getImage(s->icon_image.str());
	double width = s->icon_width < 0 ? image->get_width() : s->icon_width;
	double height = s->icon_height < 0 ? image->get_height() : s->icon_height;
	double x0 = floor(location.x - width/2.0);
	double y0 = floor(location.y - height/2.0);
	cr->translate(x0, y0);
	cr->scale(width / image->get_width(),
			  height / image->get_height());
	cr->set_source(image, 0, 0);

	if (s->icon_opacity < 1.0)
		cr->paint_with_alpha(s->icon_opacity);
	else
		cr->paint();

	cr->restore();
}
Beispiel #20
0
		bool on_expose_event(GdkEventExpose* ev) {
			Glib::RefPtr< Gdk::Window > window = get_window();
			if (window) {
				Cairo::RefPtr< Cairo::Context > ctx = window->create_cairo_context();
				Gtk::Allocation alloc = get_allocation();
				const int height = alloc.get_height();
				const int width = alloc.get_width();

				ctx->scale(width, height); //escala para que ocupe siempre toda la pantalla. Notar que es ancho y después alto.
				ctx->set_line_width(ANCHO_LINEA);
				
				// contorno
				ctx->move_to(0.0, 1.0); // muevo hacia el punto inicial, que arbitrariamente elegí que fuera el de la izquierda abajo
				ctx->line_to(0.0, 0.0); // línea hacia el punto de arriba a la izquierda
				ctx->line_to(1.0, 0.0); // línea hacia el punto de arriba a la derecha
				ctx->line_to(1.0, 1.0); // línea hacia el punto de abajo a la derecha
				ctx->close_path(); // cierro el camino
				ctx->save(); // salvo porque voy a cambiar el color
					ctx->set_source_rgb(1.0, 1.0, 1.0); // seteo el color al blanco
					ctx->fill_preserve(); // relleno todo el cuadrado, preservando el camino para dibujar el contorno
				ctx->restore();
				ctx->stroke(); // pinto el camino en negro

				// triángulo azul de abajo
				ctx->move_to(0.0, 1.0); // muevo hacia el punto inicial, que arbitrariamente elegí que fuera el de la izquierda
				ctx->line_to(0.5, 0.5); // línea hacia el punto del medio
				ctx->line_to(1.0, 1.0); // línea hacia el punto de abajo a la derecha
				ctx->close_path(); // cierro el camino
				ctx->save(); // salvo porque voy a cambiar el color
					ctx->set_source_rgb(0.0, 0.0, 1.0); // seteo el color al azul
					ctx->fill_preserve(); // relleno todo triángulo, preservando el camino para dibujar el contorno
				ctx->restore();
				ctx->stroke(); // pinto el camino en negro

				// triángulo azul de arriba
				ctx->move_to(0.0, 0.0); // muevo hacia el punto inicial, que arbitrariamente elegí que fuera el de la izquierda
				ctx->line_to(0.5, 0.5); // línea hacia el punto del medio
				ctx->line_to(1.0, 0.0); // línea hacia el punto de arriba a la derecha
				ctx->close_path(); // cierro el camino
				ctx->save(); // salvo porque voy a cambiar el color
					ctx->set_source_rgb(0.0, 0.0, 1.0); // seteo el color al azul
					ctx->fill_preserve(); // relleno todo triángulo, preservando el camino para dibujar el contorno
				ctx->restore();
				ctx->stroke(); // pinto el camino en negro				
			}
			return true;			
		}
int main() {
#ifdef CAIRO_HAS_PDF_SURFACE

	std::string filename = "image.pdf";
	int width = 600;
	int height = 400;
	Cairo::RefPtr<Cairo::PdfSurface> surface = Cairo::PdfSurface::create(
			filename, width, height);

	Cairo::RefPtr<Cairo::Context> cr = Cairo::Context::create(surface);

	cr->save(); // save the state of the context
	cr->set_source_rgb(0.86, 0.85, 0.47);
	cr->paint(); // fill image with the color
	cr->restore(); // color is back to black now

	cr->save();
	// draw a border around the image
	cr->set_line_width(20.0); // make the line wider
	cr->rectangle(0.0, 0.0, cairo_image_surface_get_width(surface->cobj()),
			height);
	cr->stroke();

	cr->set_source_rgba(0.0, 0.0, 0.0, 0.7);
	// draw a circle in the center of the image
	cr->arc(width / 2.0, height / 2.0, height / 4.0, 0.0, 2.0 * M_PI);
	cr->stroke();

	// draw a diagonal line
	cr->move_to(width / 4.0, height / 4.0);
	cr->line_to(width * 3.0 / 4.0, height * 3.0 / 4.0);
	cr->stroke();
	cr->restore();

	cr->show_page();

	std::cout << "Wrote PDF file \"" << filename << "\"" << std::endl;
	return 0;

#else

	std::cout << "You must compile cairo with PDF support for this example to work."
	<< std::endl;
	return 1;

#endif
}
void ActivityDrawingArea::drawPoints(std::map<double, double> & ps, const double reference_line) {
	//std::cout<<"ActivityDrawingArea::drawPoints: " <<std::endl;
	// This is where we draw on the window
	Glib::RefPtr < Gdk::Window > window = get_window();
	Cairo::RefPtr < Cairo::Context > cr = window->create_cairo_context();
	cr->save();
	Gtk::Allocation allocation = get_allocation();
	const int width = allocation.get_width();
	const int height = allocation.get_height();

	cr->set_line_width(2.0);
	//  std::cout<<"ActivityDrawingArea::drawPoints: colour: "<<"("<<main_colour[0]<<","<<main_colour[1]<<","<< main_colour[2] <<std::endl;
	this->setSourceRGB(cr, currentColourScheme.getMainColour());

	//scale the drawing in x and y
	double maxy = 0;
	std::map<double, double>::iterator it_ps = ps.begin();
	while (it_ps != ps.end()) {
		if (it_ps->second < 0 && -(it_ps->second) > maxy) {
			maxy = -(it_ps->second);
		} else if (it_ps->second > 0 && (it_ps->second) > maxy) {
			maxy = (it_ps->second);
		}
		++it_ps;
	}

	double scaley = 0.2 * (double) ActivityDrawingArea::ACTIVITY_HEIGHT / maxy;
	double scalex = 10;

	it_ps = ps.begin();
	if (it_ps != ps.end()) {
		cr->move_to(scalex * it_ps->first, (0.5 * height) - (scaley * it_ps->second));
	} else {
		cr->move_to(0, height / 2);
	}
	while (it_ps != ps.end()) {
		//	std::cout<<"ActivityDrawingArea::drawPoints: " << it_ps->first <<","<<-it_ps->second<<std::endl;
		cr->line_to((scalex * it_ps->first), (0.5 * height) - (scaley * it_ps->second));
		++it_ps;
	}
	cr->stroke();

	// draw reference line if not zero
	if (reference_line>0.00001 || reference_line < -0.00001) {
		Gdk::Color temp_colour(currentColourScheme.getMainColour());
		this->setSourceRGB(cr, Gdk::Color("tomato"));
		cr->set_line_width(1.0);
		const std::vector<double> dashed= { 1.0 };
		cr->set_dash(dashed, 1);
		double scaled_reference_line = (0.5 * height) - (scaley * reference_line);
		double neg_scaled_reference_line = (0.5 * height) + (scaley * reference_line);
		cr->move_to(0, scaled_reference_line);
		cr->line_to(width, scaled_reference_line);
		cr->move_to(0, neg_scaled_reference_line);
			cr->line_to(width, neg_scaled_reference_line);
		cr->stroke();
	}
	cr->restore();
}
Beispiel #23
0
void
Renderer_BBox::render_vfunc(
	const Glib::RefPtr<Gdk::Window>& drawable,
	const Gdk::Rectangle& /*expose_area*/
)
{
	assert(get_work_area());
	if(!get_work_area())
		return;

	Cairo::RefPtr<Cairo::Context> cr = drawable->create_cairo_context();

	const synfig::Vector::value_type window_startx(get_work_area()->get_window_tl()[0]);
	const synfig::Vector::value_type window_starty(get_work_area()->get_window_tl()[1]);
	const float pw(get_pw()),ph(get_ph());

	const synfig::Point curr_point(get_bbox().get_min());
	const synfig::Point drag_point(get_bbox().get_max());
	if(get_bbox().area()<10000000000000000.0 && get_bbox().area()>0.00000000000000001)
	{
		Point tl(std::min(drag_point[0],curr_point[0]),std::min(drag_point[1],curr_point[1]));
		Point br(std::max(drag_point[0],curr_point[0]),std::max(drag_point[1],curr_point[1]));

		tl[0]=(tl[0]-window_startx)/pw;
		tl[1]=(tl[1]-window_starty)/ph;
		br[0]=(br[0]-window_startx)/pw;
		br[1]=(br[1]-window_starty)/ph;
		if(tl[0]>br[0])
			swap(tl[0],br[0]);
		if(tl[1]>br[1])
			swap(tl[1],br[1]);

		cr->save();
		cr->set_line_cap(Cairo::LINE_CAP_BUTT);
		cr->set_line_join(Cairo::LINE_JOIN_MITER);

		cr->set_line_width(1.0);
		cr->set_source_rgb(1.0,1.0,1.0);

		// Operator difference was added in Cairo 1.9.4
		// It currently isn't supported by Cairomm
#if CAIRO_VERSION >= 10904
		cairo_set_operator(cr->cobj(), CAIRO_OPERATOR_DIFFERENCE);
#else
		// Fallback: set color to black
        cr->set_source_rgb(0,0,0);
#endif

		cr->rectangle(
			int(tl[0])+0.5,
			int(tl[1])+0.5,
			int(br[0]-tl[0]+1),
			int(br[1]-tl[1]+1)
		);
		cr->stroke();

		cr->restore();
	}
}
int drawCairo(const string& fname,
        const valarray<double>& Xin, const valarray<double>& Yin, 
        const Hull& hull) {
#ifdef CAIRO_HAS_SVG_SURFACE
    unsigned n=Xin.size();
    assert(Yin.size()==n);

    // normalise coords to range 0-1
    valarray<double> X=Xin, Y=Yin;
    X-=X.min();
    Y-=Y.min();
    X/=X.max();
    Y/=Y.max();

    Cairo::RefPtr<Cairo::SvgSurface> surface =
        Cairo::SvgSurface::create(fname, width+2*border, height+2*border);

    Cairo::RefPtr<Cairo::Context> cr = Cairo::Context::create(surface);

    cr->save(); // save the state of the context
    cr->set_source_rgba(0.0, 0.0, 0.0, 0.7);
    // draw a circle at each coordinate
    for(unsigned i=0;i<n;i++) {
        dot(cr,xcoord(X[i]),ycoord(Y[i]));
    }

    cr->set_source_rgba(0.0, 0.0, 0.0, 0.3);
    cr->move_to(xcoord(X[hull[0]]),ycoord(Y[hull[0]]));
    for(unsigned i=1;i<hull.size();i++) {
        cr->line_to(xcoord(X[hull[i]]),ycoord(Y[hull[i]]));
    }
    cr->line_to(xcoord(X[hull[0]]),ycoord(Y[hull[0]]));
    cr->stroke();
    cr->set_source_rgba(0.0, 0.0, 0.0, 1.);
    for(vector<unsigned>::const_iterator i=hull.begin();i!=hull.end();++i) {
        unsigned j=*i;
        stringstream ss;
        ss<<j;
        printf("p[%d]=(%f,%f)\n",j,X[j],Y[j]);
        cr->move_to(xcoord(X[j]),ycoord(Y[j]));
        cr->show_text(ss.str());
        cr->stroke();
    }
    cr->restore();

    cr->show_page();

    cout << "Wrote SVG file \"" << fname << "\"" << endl;
    return 0;

#else

    cout << "You must compile cairo with SVG support for this example to work."
        << endl;
    return 1;

#endif

}
Beispiel #25
0
int main()
{
  Cairo::RefPtr<Cairo::ImageSurface> surface =
    Cairo::ImageSurface::create(Cairo::FORMAT_ARGB32, 600, 400);

  Cairo::RefPtr<Cairo::Context> cr = Cairo::Context::create(surface);

  cr->save(); // save the state of the context
  cr->set_source_rgb(0.86, 0.85, 0.47);
  cr->paint();   // fill image with the color
  cr->restore(); // color is back to black now

  cr->save();
  // draw a border around the image
  cr->set_line_width(20.0); // make the line wider
  cr->rectangle(0.0, 0.0, surface->get_width(), surface->get_height());
  cr->stroke();

  cr->set_source_rgba(0.0, 0.0, 0.0, 0.7);
  // draw a circle in the center of the image
  cr->arc(surface->get_width() / 2.0, surface->get_height() / 2.0,
          surface->get_height() / 4.0, 0.0, 2.0 * M_PI);
  cr->stroke();

  // draw a diagonal line
  cr->move_to(surface->get_width() / 4.0, surface->get_height() / 4.0);
  cr->line_to(surface->get_width() * 3.0 / 4.0,
              surface->get_height() * 3.0 / 4.0);
  cr->stroke();
  cr->restore();

#ifdef CAIRO_HAS_PNG_FUNCTIONS

  std::string filename = "image.png";
  surface->write_to_png(filename);

  std::cout << "Wrote png file \"" << filename << "\"" << std::endl;

#else

  std::cout
    << "You must compile cairo with PNG support for this example to work."
    << std::endl;

#endif
}
    void Format7DrawingArea::DrawImageDimensionsText( 
        Cairo::RefPtr<Cairo::Context> refCairo,
        unsigned int left, unsigned int top, unsigned int width, unsigned int height )
    {        
        refCairo->save();

        // Set the font parameters
        refCairo->select_font_face( 
            "monospace",
            Cairo::FONT_SLANT_NORMAL, 
            Cairo::FONT_WEIGHT_BOLD );
        refCairo->set_font_size( 10 );

        // Set draw color to black
        refCairo->set_source_rgb(0.0, 0.0, 0.0);       

        // Get width / height of widget
        int widgetWidth = 0;
        int widgetHeight = 0;
        get_window()->get_size( widgetWidth, widgetHeight );

        // Create text for image offset
        char imageOffsets[128];
        sprintf(
            imageOffsets,
            "Start: (%d,%d) End: (%d,%d)",
            left,
            top,
            left + width,
            top + height );
        Cairo::TextExtents offsetExtents;
        refCairo->get_text_extents(imageOffsets, offsetExtents);

        // Draw the offset text
        refCairo->move_to( 
            (widgetWidth/2) - (offsetExtents.width/2),
            (widgetHeight/2) - offsetExtents.height - (offsetExtents.height/2));
        refCairo->show_text( imageOffsets );

        // Create text for image dimensions
        char imageDimensions[128];
        sprintf(
            imageDimensions,
            "Dimensions: %d x %d",
            width,
            height);
        Cairo::TextExtents dimensionsExtents;
        refCairo->get_text_extents(imageDimensions, dimensionsExtents);

        // Draw the dimensions text
        refCairo->move_to( 
            (widgetWidth/2) - (dimensionsExtents.width/2),
            (widgetHeight/2) + dimensionsExtents.height + (dimensionsExtents.height/2));
        refCairo->show_text( imageDimensions );

        refCairo->restore();
    }
Beispiel #27
0
void DependencyArrow::draw(const Cairo::RefPtr<Cairo::Context>& context) const
{
    // the way to compute the (tcx, tcy) single control point of the
    // quadratic
    double dX = mControlPoint.getX() - mOrigin->getX();
    double dY = mControlPoint.getY() - mOrigin->getY();
    double d1 = std::sqrt(dX * dX + dY * dY);
    double d = d1;

    dX = mDestination->getX() - mControlPoint.getX();
    dY = mDestination->getY() - mControlPoint.getY();
    d += std::sqrt(dX * dX + dY * dY);
    double t = d1/d;

    double t1 = 1.0 - t;
    double tSq = t * t;
    double denom = 2.0 * t * t1;

    double tcx = (mControlPoint.getX() - t1 * t1 * mOrigin->getX() -
        tSq * mDestination->getX()) / denom;
    double tcy = (mControlPoint.getY() - t1 * t1 * mOrigin->getY() -
        tSq * mDestination->getY()) / denom;

    // from the single point of the quadratic to the both of the cubic
    double tcxq1 = mOrigin->getX() + 2. * (tcx - mOrigin->getX()) / 3.;
    double tcyq1 = mOrigin->getY() + 2. * (tcy - mOrigin->getY()) / 3.;
    double tcxq2 = mDestination->getX() +
        2. * (tcx - mDestination->getX()) / 3.;
    double tcyq2 = mDestination->getY() +
        2. * (tcy - mDestination->getY()) / 3.;

    // and now to draw,
    std::valarray< double > dashes(2);
    double angle = atan2 (mDestination->getY() - tcyq2,
        mDestination->getX() - tcxq2) + M_PI;
    double x1 = mDestination->getX() + 9 * std::cos(angle - 0.35);
    double y1 = mDestination->getY() + 9 * std::sin(angle - 0.35);
    double x2 = mDestination->getX() + 9 * std::cos(angle + 0.35);
    double y2 = mDestination->getY() + 9 * std::sin(angle + 0.35);
    dashes[0] = 8.0;
    dashes[1] = 3.0;

    context->save();
    context->set_line_width(1);
    context->move_to(mDestination->getX(), mDestination->getY());
    context->line_to(x1,y1);
    context->line_to(x2,y2);
    context->line_to(mDestination->getX(), mDestination->getY());
    context->fill();

    context->set_dash(dashes,0.);
    context->move_to(mOrigin->getX(), mOrigin->getY());
    context->curve_to(tcxq1, tcyq1, tcxq2, tcyq2, mDestination->getX(),
        mDestination->getY());
    context->stroke();
    context->restore();
}
Beispiel #28
0
void Anchor::draw(const Cairo::RefPtr<Cairo::Context>& context) const
{
        context->save();
        context->move_to(mX,mY);
        context->set_source_rgb(0., 1., 0.);
        context->rectangle(mX, mY, ANCHOR_WIDTH, ANCHOR_HEIGHT);
        context->fill();
        context->restore();
}
Beispiel #29
0
void ICLayerLineString::draw(Cairo::RefPtr<Cairo::Context> cr, double scale,
    std::set<int> select, bool DisplayID, double Alpha)
{
  std::map<int, ICLayerObject*>::iterator it;
  for (it = m_ICLayerObject.begin(); it != m_ICLayerObject.end(); it++)
  {
    if ((*it).second->selfIdExisting())
    {
      bool isSelect = false;
      if (!select.empty())
      {
        std::set<int>::iterator it2;
        it2 = select.find((*it).first);
        if (it2 != select.end() && (*it2) == (*it).first)
        {
          drawLine(cr, (*it).second->getOGRGeometryObject(), scale, true);
          isSelect = true;
        } else
          drawLine(cr, (*it).second->getOGRGeometryObject(), scale, false);
      } else
        drawLine(cr, (*it).second->getOGRGeometryObject(), scale, false);
      if (DisplayID)
      {
        Cairo::TextExtents extents;

        std::stringstream str;
        str << (*it).first;
        std::string text = str.str();

        cr->select_font_face("Bitstream Vera Sans, Arial", Cairo::FONT_SLANT_NORMAL,
            Cairo::FONT_WEIGHT_NORMAL);
        cr->set_font_size(12 / scale);

        Cairo::FontOptions font_options;

        font_options.set_hint_style(Cairo::HINT_STYLE_NONE);
        font_options.set_hint_metrics(Cairo::HINT_METRICS_OFF);
        font_options.set_antialias(Cairo::ANTIALIAS_GRAY);

        cr->set_font_options(font_options);
        cr->save();

        cr->get_text_extents(text, extents);
        cr->move_to((*it).second->getCentroid().first,
            (*it).second->getCentroid().second);
        cr->scale(1, -1);
        if (isSelect)
          cr->set_source_rgba(0, 0, 0, Alpha);

        cr->show_text(text);
        cr->stroke();
        cr->restore();
      }
    }
  }
}
Beispiel #30
0
void enigma_rotor_window::draw_wheel_pos(Cairo::RefPtr<Cairo::Context> cr, gunichar new_pos)
{
    wheel_pos = new_pos; 
    const char *trans_2 = "00000000011111111112222222";
    const char *trans_1 = "12345678901234567890123456";
    int win_size = ((int)(padded_size)) - 1;
    
    cr->save();
        
        // Draw background of rotor window as a rectangle filled with the rotor background colour
        cr->set_source_rgb(rotor_r, rotor_g, rotor_b);
        cr->rectangle(x - win_size / 2, y - win_size / 2, win_size, win_size); // Set path
        cr->fill_preserve(); // Fill everyting inside the path and preserve the path
        
        // Draw black border around the path, i.e. the rectangle that represents the rotor window        
        cr->set_line_width(1.0);
        cr->set_source_rgb(BLACK);
        cr->stroke();
    
    cr->restore();
    
    cr->save();
        
        // Set colour in which to draw the rotor position
        if (!is_greek)
            cr->set_source_rgb(BLACK); // Default is black
        else
            cr->set_source_rgb(RED); // The greek wheel on M4 has red markings
        
        if (!is_numeric)
        {
            // rotor position is displayed as character A-Z
            print_char(cr, x, y, new_pos, font_size_char);
        }
        else
        {
            // rotor position is displayed as a number 01, 02, ..., 26
            print_char(cr, x - char_width_numeric / 2, y, trans_2[new_pos - 'A'], font_size_numeric);
            print_char(cr, x + char_width_numeric / 2, y, trans_1[new_pos - 'A'], font_size_numeric);   
        }
    
    cr->restore();    
}