const synfig::Time get_time_offset_from_vdesc(const synfigapp::ValueDesc &v)
{
#ifdef ADJUST_WAYPOINTS_FOR_TIME_OFFSET
	if(getenv("SYNFIG_SHOW_CANVAS_PARAM_WAYPOINTS") ||
	   v.get_value_type() != synfig::type_canvas)
		return synfig::Time::zero();

	synfig::Canvas::Handle canvasparam = v.get_value().get(Canvas::Handle());
	if(!canvasparam)
		return synfig::Time::zero();

	if (!v.parent_is_layer())
		return synfig::Time::zero();

	synfig::Layer::Handle layer = v.get_layer();

	if (etl::handle<Layer_PasteCanvas>::cast_dynamic(layer))
		return synfig::Time::zero();

	return layer->get_param("time_offset").get(Time());
#else // ADJUST_WAYPOINTS_FOR_TIME_OFFSET
	return synfig::Time::zero();
#endif
}
示例#2
0
	synfig::Real get_value(int chan, synfig::Real time, synfig::Real tolerance)
	{
		std::map<synfig::Real,synfig::Real>::iterator iter;

		// First check to see if we have a value
		// that is "close enough" to the time
		// we are looking for
		iter=channels[chan].values.lower_bound(time);
		if(iter!=channels[chan].values.end() && iter->first-time<=tolerance)
			return -iter->second;

		// Since that didn't work, we now need
		// to go ahead and figure out what the
		// actual value is at that time.
		ValueBase value(value_desc.get_value(time));
		Type &type(value.get_type());
		if (type == type_real)
			channels[0].values[time]=value.get(Real());
		else
		if (type == type_time)
			channels[0].values[time]=value.get(Time());
		else
		if (type == type_integer)
			channels[0].values[time]=value.get(int());
		else
		if (type == type_bool)
			channels[0].values[time]=value.get(bool());
		else
		if (type == type_angle)
			channels[0].values[time]=Angle::rad(value.get(Angle())).get();
		else
		if (type == type_color)
		{
			channels[0].values[time]=value.get(Color()).get_r();
			channels[1].values[time]=value.get(Color()).get_g();
			channels[2].values[time]=value.get(Color()).get_b();
			channels[3].values[time]=value.get(Color()).get_a();
		}
		else
		if (type == type_vector)
		{
			channels[0].values[time]=value.get(Vector())[0];
			channels[1].values[time]=value.get(Vector())[1];
		}
		else
		if (type == type_bline_point)
		{
			channels[0].values[time]=value.get(BLinePoint()).get_vertex()[0];
			channels[1].values[time]=value.get(BLinePoint()).get_vertex()[1];
			channels[2].values[time]=value.get(BLinePoint()).get_width();
			channels[3].values[time]=value.get(BLinePoint()).get_origin();
			channels[4].values[time]=value.get(BLinePoint()).get_split_tangent_both();
			channels[5].values[time]=value.get(BLinePoint()).get_tangent1()[0];
			channels[6].values[time]=value.get(BLinePoint()).get_tangent1()[1];
			channels[7].values[time]=value.get(BLinePoint()).get_tangent2()[0];
			channels[8].values[time]=value.get(BLinePoint()).get_tangent2()[1];
			channels[9].values[time]=value.get(BLinePoint()).get_split_tangent_radius();
			channels[10].values[time]=value.get(BLinePoint()).get_split_tangent_angle();
		}
		else
		if (type == type_width_point)
		{
			channels[0].values[time]=value.get(WidthPoint()).get_position();
			channels[1].values[time]=value.get(WidthPoint()).get_width();
		}
		else
		{
			return 0;
		}

		return -channels[chan].values[time];
	}