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package com.sun.javafx.geom;

import com.sun.javafx.geom.transform.BaseTransform;

An implementation of ShapePair that represents the space between two concentric, non-intersecting Shapes. The pair of shapes could also be represented by a regular Path2D by simply concatenating the two shapes and using a WIND_EVEN_ODD winding rule. (Note that a WIND_NON_ZERO winding rule could be used if the two shapes have opposite windings, but that cannot be guaranteed without further inspection of the two shapes and the WIND_NON_ZERO rule works fine without that restriction.)
/** * An implementation of {@link ShapePair} that represents the space between * two concentric, non-intersecting Shapes. The pair of shapes could also be * represented by a regular {@link Path2D} by simply concatenating the two * shapes and using a {@code WIND_EVEN_ODD} winding rule. (Note that a * {@code WIND_NON_ZERO} winding rule could be used if the two shapes have * opposite windings, but that cannot be guaranteed without further inspection * of the two shapes and the {@code WIND_NON_ZERO} rule works fine without * that restriction.) * */
public final class ConcentricShapePair extends ShapePair { private final Shape outer; private final Shape inner; public ConcentricShapePair(Shape outer, Shape inner) { this.outer = outer; this.inner = inner; } @Override public int getCombinationType() { return TYPE_SUBTRACT; } @Override public Shape getOuterShape() { return outer; } @Override public Shape getInnerShape() { return inner; } @Override public Shape copy() { return new ConcentricShapePair(outer.copy(), inner.copy()); } @Override public boolean contains(float x, float y) { return outer.contains(x, y) && !inner.contains(x, y); } @Override public boolean intersects(float x, float y, float w, float h) { return outer.intersects(x, y, w, h) && !inner.contains(x, y, w, h); } @Override public boolean contains(float x, float y, float w, float h) { return outer.contains(x, y, w, h) && !inner.intersects(x, y, w, h); } @Override public RectBounds getBounds() { return outer.getBounds(); } @Override public PathIterator getPathIterator(BaseTransform tx) { return new PairIterator(outer.getPathIterator(tx), inner.getPathIterator(tx)); } @Override public PathIterator getPathIterator(BaseTransform tx, float flatness) { return new PairIterator(outer.getPathIterator(tx, flatness), inner.getPathIterator(tx, flatness)); } static class PairIterator implements PathIterator { PathIterator outer; PathIterator inner; PairIterator(PathIterator outer, PathIterator inner) { this.outer = outer; this.inner = inner; } public int getWindingRule() { return WIND_EVEN_ODD; } public int currentSegment(float[] coords) { if (outer.isDone()) { return inner.currentSegment(coords); } else { return outer.currentSegment(coords); } } public boolean isDone() { return outer.isDone() && inner.isDone(); } public void next() { if (outer.isDone()) { inner.next(); } else { outer.next(); } } } }