Ejemplo n.º 1
0
bool
RectangleIntersects::intersects(const geom::Geometry& geom)
{
	if (!rectEnv.intersects(geom.getEnvelopeInternal()))
		return false;

	// test envelope relationships
	EnvelopeIntersectsVisitor visitor(rectEnv);
	visitor.applyTo(geom);
	if (visitor.intersects()) return true;

	// test if any rectangle corner is contained in the target
	ContainsPointVisitor ecpVisitor(rectangle);
	ecpVisitor.applyTo(geom);
	if (ecpVisitor.containsPoint())
		return true;

	// test if any lines intersect
	LineIntersectsVisitor liVisitor(rectangle);
	liVisitor.applyTo(geom);
	if (liVisitor.intersects())
		return true;

	return false;
}
Ejemplo n.º 2
0
	void visit(const geom::Geometry &geom)
	{
		using GEOMETRY::algorithm::locate::SimplePointInAreaLocator;

		const geom::Polygon *poly;

		if ( !(poly=dynamic_cast<const geom::Polygon *>(&geom)) ) {
			return;
		}

		const geom::Envelope &elementEnv = *(geom.getEnvelopeInternal());

		if ( !rectEnv.intersects(elementEnv) ) {
			return;
		}

		// test each corner of rectangle for inclusion
		for (int i=0; i<4; i++)
		{

			const geom::Coordinate &rectPt=rectSeq.getAt(i);

			if ( !elementEnv.contains(rectPt) ) {
				continue;
			}

			// check rect point in poly (rect is known not to
			// touch polygon at this point)
			if ( SimplePointInAreaLocator::containsPointInPolygon(rectPt, poly) )
			{
				containsPointVar=true;
				return;
			}
		}
	}
Ejemplo n.º 3
0
/*public static*/
double
GeometrySnapper::computeSizeBasedSnapTolerance(const geom::Geometry& g)
{
	const Envelope* env = g.getEnvelopeInternal();
	double minDimension = (std::min)(env->getHeight(), env->getWidth());
	double snapTol = minDimension * snapPrecisionFactor;
	return snapTol;
}
Ejemplo n.º 4
0
	void visit(const geom::Geometry &geom)
	{
		const geom::Envelope &elementEnv = *(geom.getEnvelopeInternal());
		if (! rectEnv.intersects(elementEnv) ) {
			return;
		}

		// check if general relate algorithm should be used,
		// since it's faster for large inputs
		if (geom.getNumPoints() > RectangleIntersects::MAXIMUM_SCAN_SEGMENT_COUNT)
		{
			intersectsVar = rectangle.relate(geom)->isIntersects();
			return;
		}

		// if small enough, test for segment intersection directly
		computeSegmentIntersection(geom);
	}
Ejemplo n.º 5
0
	/**
	 * Reports whether it can be concluded that an intersection occurs,
	 * or whether further testing is required.
	 *
	 * @return <code>true</code> if an intersection must occur
	 * <code>false</code> if no conclusion can be made
	 */
	void visit(const geom::Geometry &element)
	{
		const geom::Envelope &elementEnv = *(element.getEnvelopeInternal());

		// disjoint
		if ( ! rectEnv.intersects(elementEnv) ) {
			return;
		}

		// fully contained - must intersect
		if ( rectEnv.contains(elementEnv) ) {
			intersectsVar = true;
			return;
		}

		/*
		 * Since the envelopes intersect and the test element is
		 * connected, if the test envelope is completely bisected by
		 * an edge of the rectangle the element and the rectangle
		 * must touch (This is basically an application of the
		 * Jordan Curve Theorem).  The alternative situation
		 * is that the test envelope is "on a corner" of the
		 * rectangle envelope, i.e. is not completely bisected.
		 * In this case it is not possible to make a conclusion
		 * about the presence of an intersection.
		 */
		if (elementEnv.getMinX() >= rectEnv.getMinX()
			&& elementEnv.getMaxX() <= rectEnv.getMaxX())
		{
			intersectsVar=true;
			return;
		}
		if (elementEnv.getMinY() >= rectEnv.getMinY()
			&& elementEnv.getMaxY() <= rectEnv.getMaxY())
		{
			intersectsVar = true;
			return;
		}
	}