java.awt.Shape Maven / Gradle / Ivy

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This work corresponds to the API signatures of JSR 217: Personal Basis Profile 1.1. In the event of a discrepency between this work and the JSR 217 specification, which is available at http://www.jcp.org/en/jsr/detail?id=217, the latter takes precedence. */ package java.awt; // import java.awt.geom.AffineTransform; // import java.awt.geom.PathIterator; // import java.awt.geom.Point2D; // import java.awt.geom.Rectangle2D; // PBP/PP /** * The Shape interface provides definitions for objects * that represent some form of geometric shape. *

* Definition of insideness: * A point is considered to lie inside a * Shape if and only if: *

*
• it lies completely * inside theShape boundary or *
• * it lies exactly on the Shape boundary and the * space immediately adjacent to the * point in the increasing X direction is * entirely inside the boundary or *
• * it lies exactly on a horizontal boundary segment and the * space immediately adjacent to the point in the * increasing Y direction is inside the boundary. *

The contains and intersects methods * consider the interior of a Shape to be the area it * encloses as if it were filled. This means that these methods * consider * unclosed shapes to be implicitly closed for the purpose of * determining if a shape contains or intersects a rectangle or if a * shape contains a point. * * @see * * @version 1.19 06/24/98 * @author Jim Graham */ public interface Shape { // PBP/PP /** * Returns an integer {@link Rectangle} that completely encloses the * Shape. Note that there is no guarantee that the * returned Rectangle is the smallest bounding box that * encloses the Shape, only that the Shape * lies entirely within the indicated Rectangle. The * returned Rectangle might also fail to completely * enclose the Shape if the Shape overflows * the limited range of the integer data type. * * @return an integer Rectangle that completely encloses * the Shape. */ public Rectangle getBounds(); // /** // * Returns a high precision and more accurate bounding box of // * the Shape than the getBounds method. // * Note that there is no guarantee that the returned // * {@link Rectangle2D} is the smallest bounding box that encloses // * the Shape, only that the Shape lies // * entirely within the indicated Rectangle2D. The // * bounding box returned by this method is usually tighter than that // * returned by the getBounds method and never fails due // * to overflow problems since the return value can be an instance of // * the Rectangle2D that uses double precision values to // * store the dimensions. // * @return an instance of Rectangle2D that is a // * high-precision bounding box of the Shape. // * @see #getBounds // */ // public Rectangle2D getBounds2D(); // // /** // * Tests if the specified coordinates are inside the boundary of the // * Shape. // * @param x the specified x coordinate // * @param y the specified y coordinate // * @return true if the specified coordinates are inside // * the Shape boundary; false // * otherwise. // */ // public boolean contains(double x, double y); // // /** // * Tests if a specified {@link Point2D} is inside the boundary // * of the Shape. // * @param p a specified Point2D // * @return true if the specified Point2D is // * inside the boundary of the Shape; // * false otherwise. // */ // public boolean contains(Point2D p); // // /** // * Tests if the interior of the Shape intersects the // * interior of a specified rectangular area. // * The rectangular area is considered to intersect the Shape // * if any point is contained in both the interior of the // * Shape and the specified rectangular area. // *

// * This method might conservatively return true when: // *

// *
• // * there is a high probability that the rectangular area and the // * Shape intersect, but // *
• // * the calculations to accurately determine this intersection // * are prohibitively expensive. // *

// *
• // * there is a high probability that the Rectangle2D and the // * Shape intersect, but // *
• // * the calculations to accurately determine this intersection // * are prohibitively expensive. // *

// * This method might conservatively return false when: // *

// *
• // * the intersect method returns true and // *
• // * the calculations to determine whether or not the // * Shape entirely contains the rectangular area are // * prohibitively expensive. // *

// *
• // * the intersect method returns true and // *
• // * the calculations to determine whether or not the // * Shape entirely contains the Rectangle2D // * are prohibitively expensive. // *

// * Each call to this method returns a fresh PathIterator // * object that traverses the geometry of the Shape object // * independently from any other PathIterator objects in use // * at the same time. // *

// * It is recommended, but not guaranteed, that objects // * implementing the Shape interface isolate iterations // * that are in process from any changes that might occur to the original // * object's geometry during such iterations. // *

// * Before using a particular implementation of the Shape // * interface in more than one thread simultaneously, refer to its // * documentation to verify that it guarantees that iterations are isolated // * from modifications. // * @param at an optional AffineTransform to be applied to the // * coordinates as they are returned in the iteration, or // * null if untransformed coordinates are desired // * @return a new PathIterator object, which independently // * traverses the geometry of the Shape. // */ // public PathIterator getPathIterator(AffineTransform at); // // /** // * Returns an iterator object that iterates along the Shape // * boundary and provides access to a flattened view of the // * Shape outline geometry. // *

// * Only SEG_MOVETO, SEG_LINETO, and SEG_CLOSE point types are // * returned by the iterator. // *

// * If an optional AffineTransform is specified, // * the coordinates returned in the iteration are transformed // * accordingly. // *

// * The amount of subdivision of the curved segments is controlled // * by the flatness parameter, which specifies the // * maximum distance that any point on the unflattened transformed // * curve can deviate from the returned flattened path segments. // * Note that a limit on the accuracy of the flattened path might be // * silently imposed, causing very small flattening parameters to be // * treated as larger values. This limit, if there is one, is // * defined by the particular implementation that is used. // *

// * Each call to this method returns a fresh PathIterator // * object that traverses the Shape object geometry // * independently from any other PathIterator objects in use at // * the same time. // *

// * It is recommended, but not guaranteed, that objects // * implementing the Shape interface isolate iterations // * that are in process from any changes that might occur to the original // * object's geometry during such iterations. // *