test/java/awt/Graphics/LineClipTest.java - platform/external/oj-libjdwp - Gitiles

 /*
  * Copyright (c) 2002, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  */

 /**
  * @test
  * @bug   4780022 4862193 7179526
  * @summary  Tests that clipped lines are drawn over the same pixels
  * as unclipped lines (within the clip bounds)
  * @run main/timeout=600/othervm -Dsun.java2d.ddforcevram=true LineClipTest
  * @run main/timeout=600/othervm LineClipTest
  */


 /**
  * This app tests whether we are drawing clipped lines the same
  * as unclipped lines.  The problem occurred when we started
  * clipping d3d lines using simple integer clipping, which did not
  * account for sub-pixel precision and ended up drawing very different
  * pixels than the same line drawn unclipped.  A supposed fix
  * to that problem used floating-point clipping instead, but there
  * was some problem with very limited precision inside of d3d
  * (presumably in hardware) that caused some variation in pixels.
  * We decided that whatever the fix was, we needed a serious
  * line check test to make sure that all kinds of different
  * lines would be drawn exactly the same inside the clip area,
  * regardless of whether clipping was enabled.  This test should
  * check all kinds of different cases, such as lines that fall
  * completely outside, completely inside, start outside and
  * end inside, etc., and lines should end and originate in
  * all quadrants of the space divided up by the clip box.
  *
  * The test works as follows:
  * We create nine quadrants using the spaces bisected by the
  * edges of the clip bounds (note that only one of these
  * quadrants is actually visible when clipping is enabled).
  * We create several points in each of these quadrants
  * (three in each of the invisible quadrants, nine in the
  * center/visible quadrant).  Our resulting grid looks like
  * this:
  *
  *  x         x|x    x    x|x         x
  *             |           |
  *             |           |
  *             |           |
  *             |           |
  *             |           |
  *  x          |           |          x
  *  -----------------------------------
  *  x          |x    x    x|          x
  *             |           |
  *             |           |
  *  x          |x    x    x|          x
  *             |           |
  *             |           |
  *  x          |x    x    x|          x
  *  -----------------------------------
  *  x          |           |          x
  *             |           |
  *             |           |
  *             |           |
  *             |           |
  *             |           |
  *  x         x|x    x    x|x         x
  *
  * The test then draws lines from every point to every other
  * point.  First, we draw unclipped lines in blue and
  * then we draw clipped lines in red.
  * At certain times (after every point during the default
  * test, after every quadrant of lines if you run with the -quick
  * option), we check for errors and draw the current image
  * to the screen.  Error checking consists of copying the
  * VolatileImage to a BufferedImage (because we need access
  * to the pixels directly) and checking every pixel in the
  * image.  The check is simple: everything outside the
  * clip bounds should be blue (or the background color) and
  * everything inside the clip bounds should be red (or the
  * background color).  So any blue pixel inside or red
  * pixel outside means that there was a drawing error and
  * the test fails.
  * There are 4 modes that the test can run in (dynamic mode is
  * exclusive to the other modes, but the other modes are combinable):
  *
  *      (default): the clip is set
  *      to a default size (100x100) and the test is run.
  *
  *      -quick: The error
  *      check is run only after every quadrant of lines is
  *      drawn.  This speeds up the test considerably with
  *      some less accuracy in error checking (because pixels
  *      from some lines may overdrawn pixels from other lines
  *      before we have verified the correctness of those
  *      pixels).
  *
  *      -dynamic: There is no error checking, but this version
  *      of the test automatically resizes the clip bounds and
  *      reruns the test over and over.  Nothing besides the
  *      visual check verifies that the test is running correctly.
  *
  *      -rect: Instead of drawing lines, the test draws rectangles
  *      to/from all points in all quadrants.  This tests similar
  *      clipping functionality for drawRect().
  *
  *      n (where "n" is a number): sets the clip size to the
  *      given value.  Just like the default test except that
  *      the clip size is as specified.
  *
  * Note: this test must be run with the -Dsun.java2d.ddforcevram=true
  * option to force the test image to stay in VRAM.  We currently
  * punt VRAM images to system memory when we detect lots of
  * reads.  Since we read the whole buffer on every error check
  * to copy it to the BufferedImage), this causes us to punt the
  * buffer.  A system memory surface will have no d3d capabilities,
  * thus we are not testing the d3d line quality when this happens.
  * By using the ddforcevram flag, we make sure the buffer
  * stays put in VRAM and d3d is used to draw the lines.
  */

 import javax.swing.*;
 import java.awt.*;
 import java.awt.image.*;


 public class LineClipTest extends Component implements Runnable {

     int clipBumpVal = 5;
     static int clipSize = 100;
     int clipX1;
     int clipY1;
     static final int NUM_QUADS = 9;
     Point quadrants[][] = new Point[NUM_QUADS][];
     static boolean dynamic = false;
     BufferedImage imageChecker = null;
     Color unclippedColor = Color.blue;
     Color clippedColor = Color.red;
     int testW = -1, testH = -1;
     VolatileImage testImage = null;
     static boolean keepRunning = false;
     static boolean quickTest = false;
     static boolean rectTest = false;
     static boolean runTestDone = false;
     static Frame f = null;

     /**
      * Check for errors in the grid.  This error check consists of
      * copying the buffer into a BufferedImage and reading all pixels
      * in that image.  No pixel outside the clip bounds should be
      * of the color clippedColor and no pixel inside should be
      * of the color unclippedColor.  Any wrong color returns an error.
      */
     boolean gridError(Graphics g) {
         boolean error = false;
         if (imageChecker == null || (imageChecker.getWidth() != testW) ||
             (imageChecker.getHeight() != testH))
         {
             // Recreate BufferedImage as necessary
             GraphicsConfiguration gc = getGraphicsConfiguration();
             ColorModel cm = gc.getColorModel();
             WritableRaster wr =
                 cm.createCompatibleWritableRaster(getWidth(), getHeight());
             imageChecker =
                 new BufferedImage(cm, wr,
                                   cm.isAlphaPremultiplied(), null);
         }
         // Copy buffer to BufferedImage
         Graphics gChecker = imageChecker.getGraphics();
         gChecker.drawImage(testImage, 0, 0, this);

         // Set up pixel colors to check against
         int clippedPixelColor = clippedColor.getRGB();
         int unclippedPixelColor = unclippedColor.getRGB();
         int wrongPixelColor = clippedPixelColor;
         boolean insideClip = false;
         for (int row = 0; row < getHeight(); ++row) {
             for (int col = 0; col < getWidth(); ++col) {
                 if (row >= clipY1 && row < (clipY1 + clipSize) &&
                     col >= clipX1 && col < (clipX1 + clipSize))
                 {
                     // Inside clip bounds - should not see unclipped color
                     wrongPixelColor = unclippedPixelColor;
                 } else {
                     // Outside clip - should not see clipped color
                     wrongPixelColor = clippedPixelColor;
                 }
                 int pixel = imageChecker.getRGB(col, row);
                 if (pixel == wrongPixelColor) {
                     System.out.println("FAILED: pixel = " +
                                        Integer.toHexString(pixel) +
                                        " at (x, y) = " + col + ", " + row);
                     // Draw magenta rectangle around problem pixel in buffer
                     // for visual feedback to user
                     g.setColor(Color.magenta);
                     g.drawRect(col - 1, row - 1, 2, 2);
                     error = true;
                 }
             }
         }
         return error;
     }

     /**
      * Draw all test lines and check for errors (unless running
      * with -dynamic option)
      */
     void drawLineGrid(Graphics screenGraphics, Graphics g) {
         // Fill buffer with background color
         g.setColor(Color.white);
         g.fillRect(0, 0, getWidth(), getHeight());

         // Now, iterate through all quadrants
         for (int srcQuad = 0; srcQuad < NUM_QUADS; ++srcQuad) {
             // Draw lines to all other quadrants
             for (int dstQuad = 0; dstQuad < NUM_QUADS; ++dstQuad) {
                 for (int srcPoint = 0;
                      srcPoint < quadrants[srcQuad].length;
                      ++srcPoint)
                 {
                     // For every point in the source quadrant
                     int sx = quadrants[srcQuad][srcPoint].x;
                     int sy = quadrants[srcQuad][srcPoint].y;
                     for (int dstPoint = 0;
                          dstPoint < quadrants[dstQuad].length;
                          ++dstPoint)
                     {
                         int dx = quadrants[dstQuad][dstPoint].x;
                         int dy = quadrants[dstQuad][dstPoint].y;
                         if (!rectTest) {
                             // Draw unclipped/clipped lines to every
                             // point in the dst quadrant
                             g.setColor(unclippedColor);
                             g.drawLine(sx, sy, dx, dy);
                             g.setClip(clipX1, clipY1, clipSize, clipSize);
                             g.setColor(clippedColor);
                             g.drawLine(sx,sy, dx, dy);
                         } else {
                             // Draw unclipped/clipped rectangles to every
                             // point in the dst quadrant
                             g.setColor(unclippedColor);
                             int w = dx - sx;
                             int h = dy - sy;
                             g.drawRect(sx, sy, w, h);
                             g.setClip(clipX1, clipY1, clipSize, clipSize);
                             g.setColor(clippedColor);
                             g.drawRect(sx, sy, w, h);
                         }
                         g.setClip(null);
                     }
                     if (!dynamic) {
                         // Draw screen update for visual feedback
                         screenGraphics.drawImage(testImage, 0, 0, this);
                         // On default test, check for errors after every
                         // src point
                         if (!quickTest && gridError(g)) {
                             throw new java.lang.RuntimeException("Failed");
                         }
                     }
                 }
             }
             if (!dynamic && quickTest && gridError(g)) {
                 // On quick test, check for errors only after every
                 // src quadrant
                 throw new java.lang.RuntimeException("Failed");
                 //return;
             }
         }
         if (!dynamic) {
             System.out.println("PASSED");
             if (!keepRunning) {
                 f.dispose();
             }
         }
     }

     /**
      * If we have not yet run the test, or if the window size has
      * changed, or if we are running the test in -dynamic mode,
      * run the test.  Then draw the test buffer to the screen
      */
     public void paint(Graphics g) {
         if (dynamic || testImage == null ||
             getWidth() != testW || getHeight() != testH)
         {
             runTest(g);
         }
         if (testImage != null) {
             g.drawImage(testImage, 0, 0, this);
         }
     }

     /*
      * Create the quadrant of points and run the test to draw all the lines
      */
     public void runTest(Graphics screenGraphics) {
         if (getWidth() == 0 || getHeight() == 0) {
             // May get here before window is really ready
             return;
         }
         clipX1 = (getWidth() - clipSize) / 2;
         clipY1 = (getHeight() - clipSize) / 2;
         int clipX2 = clipX1 + clipSize;
         int clipY2 = clipY1 + clipSize;
         int centerX = getWidth()/2;
         int centerY = getHeight()/2;
         int leftX = 0;
         int topY = 0;
         int rightX = getWidth() - 1;
         int bottomY = getHeight() - 1;
         int quadIndex = 0;
         // Offsets are used to force diagonal (versus hor/vert) lines
         int xOffset = 0;
         int yOffset = 0;

         if (quadrants[0] == null) {
             for (int i = 0; i < 9; ++i) {
                 int numPoints = (i == 4) ? 9 : 3;
                 quadrants[i] = new Point[numPoints];
             }
         }
         // Upper-left
         quadrants[quadIndex] = new Point[] {
             new Point(leftX + xOffset,          clipY1 - 1 - yOffset),
             new Point(leftX + xOffset,          topY + yOffset),
             new Point(clipX1 - 1 - xOffset,     topY + yOffset),
         };

         quadIndex++;
         yOffset++;
         // Upper-middle
         quadrants[quadIndex] = new Point[] {
             new Point(clipX1 + 1 + xOffset,     topY + yOffset),
             new Point(centerX + xOffset,        topY + yOffset),
             new Point(clipX2 - 1 - xOffset,     topY + yOffset),
         };

         quadIndex++;
         ++yOffset;
         // Upper-right
         quadrants[quadIndex] = new Point[] {
             new Point(clipX2 + 1 + xOffset,     topY + yOffset),
             new Point(rightX - xOffset,         topY + yOffset),
             new Point(rightX - xOffset,         clipY1 - 1 - yOffset),
         };

         quadIndex++;
         yOffset = 0;
         ++xOffset;
         // Middle-left
         quadrants[quadIndex] = new Point[] {
             new Point(leftX + xOffset,          clipY1 + 1 + yOffset),
             new Point(leftX + xOffset,          centerY + yOffset),
             new Point(leftX + xOffset,          clipY2 - 1 - yOffset),
         };

         quadIndex++;
         ++yOffset;
         // Middle-middle
         quadrants[quadIndex] = new Point[] {
             new Point(clipX1 + 1 + xOffset,     clipY1 + 1 + yOffset),
             new Point(centerX + xOffset,        clipY1 + 1 + yOffset),
             new Point(clipX2 - 1 - xOffset,     clipY1 + 1 + yOffset),
             new Point(clipX1 + 1 + xOffset,     centerY + yOffset),
             new Point(centerX + xOffset,        centerY + yOffset),
             new Point(clipX2 - 1 - xOffset,     centerY + yOffset),
             new Point(clipX1 + 1 + xOffset,     clipY2 - 1 - yOffset),
             new Point(centerX + xOffset,        clipY2 - 1 - yOffset),
             new Point(clipX2 - 1 - xOffset,     clipY2 - 1 - yOffset),
         };

         quadIndex++;
         ++yOffset;
         // Middle-right
         quadrants[quadIndex] = new Point[] {
             new Point(rightX - xOffset,         clipY1 + 1 + yOffset),
             new Point(rightX - xOffset,         centerY + yOffset),
             new Point(rightX - xOffset,         clipY2 - 1 - yOffset),
         };

         quadIndex++;
         yOffset = 0;
         ++xOffset;
         // Lower-left
         quadrants[quadIndex] = new Point[] {
             new Point(leftX + xOffset,          clipY2 + 1 + yOffset),
             new Point(leftX + xOffset,          bottomY - yOffset),
             new Point(clipX1 - 1 - xOffset,     bottomY - yOffset),
         };

         quadIndex++;
         ++yOffset;
         // Lower-middle
         quadrants[quadIndex] = new Point[] {
             new Point(clipX1 + 1 + xOffset,     bottomY - yOffset),
             new Point(centerX + xOffset,        bottomY - yOffset),
             new Point(clipX2 - 1 - xOffset,     bottomY - yOffset),
         };

         quadIndex++;
         ++yOffset;
         // Lower-right
         quadrants[quadIndex] = new Point[] {
             new Point(clipX2 + 1 + xOffset,     bottomY - yOffset),
             new Point(rightX - xOffset,         bottomY - yOffset),
             new Point(rightX - xOffset,         clipY2 + 1 + yOffset),
         };


         if (testImage != null) {
             testImage.flush();
         }
         testW = getWidth();
         testH = getHeight();
         testImage = createVolatileImage(testW, testH);
         Graphics g = testImage.getGraphics();
         do {
             int valCode = testImage.validate(getGraphicsConfiguration());
             if (valCode == VolatileImage.IMAGE_INCOMPATIBLE) {
                 testImage.flush();
                 testImage = createVolatileImage(testW, testH);
                 g = testImage.getGraphics();
             }
             drawLineGrid(screenGraphics, g);
         } while (testImage.contentsLost());
         if (dynamic) {
             // Draw clip box if dynamic
             g.setClip(null);
             g.setColor(Color.black);
             g.drawRect(clipX1, clipY1, clipSize, clipSize);
             screenGraphics.drawImage(testImage, 0, 0, this);
         }
         runTestDone = true;
     }

     /**
      * When running -dynamic, resize the clip bounds and run the test
      * over and over
      */
     public void run() {
         while (true) {
             clipSize += clipBumpVal;
             if (clipSize > getWidth() || clipSize < 0) {
                 clipBumpVal = -clipBumpVal;
                 clipSize += clipBumpVal;
             }
             update(getGraphics());
             try {
                 Thread.sleep(50);
             } catch (Exception e) {}
         }
     }

     public static void main(String args[]) {
         for (int i = 0; i < args.length; ++i) {
             if (args[i].equals("-dynamic")) {
                 dynamic = true;
             } else if (args[i].equals("-rect")) {
                 rectTest = true;
             } else if (args[i].equals("-quick")) {
                 quickTest = true;
             } else if (args[i].equals("-keep")) {
                 keepRunning = true;
             } else {
                 // could be clipSize
                 try {
                     clipSize = Integer.parseInt(args[i]);
                 } catch (Exception e) {}
             }
         }
         f = new Frame();
         f.setSize(500, 500);
         LineClipTest test = new LineClipTest();
         f.add(test);
         if (dynamic) {
             Thread t = new Thread(test);
             t.start();
         }
         f.setVisible(true);
         while (!runTestDone) {
             // need to make sure jtreg doesn't exit before the
             // test is done...
             try {
                 Thread.sleep(50);
             } catch (Exception e) {}
         }
     }
 }
	/*
	* Copyright (c) 2002, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*/

	/**
	* @test
	* @bug 4780022 4862193 7179526
	* @summary Tests that clipped lines are drawn over the same pixels
	* as unclipped lines (within the clip bounds)
	* @run main/timeout=600/othervm -Dsun.java2d.ddforcevram=true LineClipTest
	* @run main/timeout=600/othervm LineClipTest
	*/


	/**
	* This app tests whether we are drawing clipped lines the same
	* as unclipped lines. The problem occurred when we started
	* clipping d3d lines using simple integer clipping, which did not
	* account for sub-pixel precision and ended up drawing very different
	* pixels than the same line drawn unclipped. A supposed fix
	* to that problem used floating-point clipping instead, but there
	* was some problem with very limited precision inside of d3d
	* (presumably in hardware) that caused some variation in pixels.
	* We decided that whatever the fix was, we needed a serious
	* line check test to make sure that all kinds of different
	* lines would be drawn exactly the same inside the clip area,
	* regardless of whether clipping was enabled. This test should
	* check all kinds of different cases, such as lines that fall
	* completely outside, completely inside, start outside and
	* end inside, etc., and lines should end and originate in
	* all quadrants of the space divided up by the clip box.
	*
	* The test works as follows:
	* We create nine quadrants using the spaces bisected by the
	* edges of the clip bounds (note that only one of these
	* quadrants is actually visible when clipping is enabled).
	* We create several points in each of these quadrants
	* (three in each of the invisible quadrants, nine in the
	* center/visible quadrant). Our resulting grid looks like
	* this:
	*
	* x x\|x x x\|x x
	* \| \|
	* \| \|
	* \| \|
	* \| \|
	* \| \|
	* x \| \| x
	* -----------------------------------
	* x \|x x x\| x
	* \| \|
	* \| \|
	* x \|x x x\| x
	* \| \|
	* \| \|
	* x \|x x x\| x
	* -----------------------------------
	* x \| \| x
	* \| \|
	* \| \|
	* \| \|
	* \| \|
	* \| \|
	* x x\|x x x\|x x
	*
	* The test then draws lines from every point to every other
	* point. First, we draw unclipped lines in blue and
	* then we draw clipped lines in red.
	* At certain times (after every point during the default
	* test, after every quadrant of lines if you run with the -quick
	* option), we check for errors and draw the current image
	* to the screen. Error checking consists of copying the
	* VolatileImage to a BufferedImage (because we need access
	* to the pixels directly) and checking every pixel in the
	* image. The check is simple: everything outside the
	* clip bounds should be blue (or the background color) and
	* everything inside the clip bounds should be red (or the
	* background color). So any blue pixel inside or red
	* pixel outside means that there was a drawing error and
	* the test fails.
	* There are 4 modes that the test can run in (dynamic mode is
	* exclusive to the other modes, but the other modes are combinable):
	*
	* (default): the clip is set
	* to a default size (100x100) and the test is run.
	*
	* -quick: The error
	* check is run only after every quadrant of lines is
	* drawn. This speeds up the test considerably with
	* some less accuracy in error checking (because pixels
	* from some lines may overdrawn pixels from other lines
	* before we have verified the correctness of those
	* pixels).
	*
	* -dynamic: There is no error checking, but this version
	* of the test automatically resizes the clip bounds and
	* reruns the test over and over. Nothing besides the
	* visual check verifies that the test is running correctly.
	*
	* -rect: Instead of drawing lines, the test draws rectangles
	* to/from all points in all quadrants. This tests similar
	* clipping functionality for drawRect().
	*
	* n (where "n" is a number): sets the clip size to the
	* given value. Just like the default test except that
	* the clip size is as specified.
	*
	* Note: this test must be run with the -Dsun.java2d.ddforcevram=true
	* option to force the test image to stay in VRAM. We currently
	* punt VRAM images to system memory when we detect lots of
	* reads. Since we read the whole buffer on every error check
	* to copy it to the BufferedImage), this causes us to punt the
	* buffer. A system memory surface will have no d3d capabilities,
	* thus we are not testing the d3d line quality when this happens.
	* By using the ddforcevram flag, we make sure the buffer
	* stays put in VRAM and d3d is used to draw the lines.
	*/

	import javax.swing.*;
	import java.awt.*;
	import java.awt.image.*;


	public class LineClipTest extends Component implements Runnable {

	int clipBumpVal = 5;
	static int clipSize = 100;
	int clipX1;
	int clipY1;
	static final int NUM_QUADS = 9;
	Point quadrants[][] = new Point[NUM_QUADS][];
	static boolean dynamic = false;
	BufferedImage imageChecker = null;
	Color unclippedColor = Color.blue;
	Color clippedColor = Color.red;
	int testW = -1, testH = -1;
	VolatileImage testImage = null;
	static boolean keepRunning = false;
	static boolean quickTest = false;
	static boolean rectTest = false;
	static boolean runTestDone = false;
	static Frame f = null;

	/**
	* Check for errors in the grid. This error check consists of
	* copying the buffer into a BufferedImage and reading all pixels
	* in that image. No pixel outside the clip bounds should be
	* of the color clippedColor and no pixel inside should be
	* of the color unclippedColor. Any wrong color returns an error.
	*/
	boolean gridError(Graphics g) {
	boolean error = false;
	if (imageChecker == null \|\| (imageChecker.getWidth() != testW) \|\|
	(imageChecker.getHeight() != testH))
	{
	// Recreate BufferedImage as necessary
	GraphicsConfiguration gc = getGraphicsConfiguration();
	ColorModel cm = gc.getColorModel();
	WritableRaster wr =
	cm.createCompatibleWritableRaster(getWidth(), getHeight());
	imageChecker =
	new BufferedImage(cm, wr,
	cm.isAlphaPremultiplied(), null);
	}
	// Copy buffer to BufferedImage
	Graphics gChecker = imageChecker.getGraphics();
	gChecker.drawImage(testImage, 0, 0, this);

	// Set up pixel colors to check against
	int clippedPixelColor = clippedColor.getRGB();
	int unclippedPixelColor = unclippedColor.getRGB();
	int wrongPixelColor = clippedPixelColor;
	boolean insideClip = false;
	for (int row = 0; row < getHeight(); ++row) {
	for (int col = 0; col < getWidth(); ++col) {
	if (row >= clipY1 && row < (clipY1 + clipSize) &&
	col >= clipX1 && col < (clipX1 + clipSize))
	{
	// Inside clip bounds - should not see unclipped color
	wrongPixelColor = unclippedPixelColor;
	} else {
	// Outside clip - should not see clipped color
	wrongPixelColor = clippedPixelColor;
	}
	int pixel = imageChecker.getRGB(col, row);
	if (pixel == wrongPixelColor) {
	System.out.println("FAILED: pixel = " +
	Integer.toHexString(pixel) +
	" at (x, y) = " + col + ", " + row);
	// Draw magenta rectangle around problem pixel in buffer
	// for visual feedback to user
	g.setColor(Color.magenta);
	g.drawRect(col - 1, row - 1, 2, 2);
	error = true;
	}
	}
	}
	return error;
	}

	/**
	* Draw all test lines and check for errors (unless running
	* with -dynamic option)
	*/
	void drawLineGrid(Graphics screenGraphics, Graphics g) {
	// Fill buffer with background color
	g.setColor(Color.white);
	g.fillRect(0, 0, getWidth(), getHeight());

	// Now, iterate through all quadrants
	for (int srcQuad = 0; srcQuad < NUM_QUADS; ++srcQuad) {
	// Draw lines to all other quadrants
	for (int dstQuad = 0; dstQuad < NUM_QUADS; ++dstQuad) {
	for (int srcPoint = 0;
	srcPoint < quadrants[srcQuad].length;
	++srcPoint)
	{
	// For every point in the source quadrant
	int sx = quadrants[srcQuad][srcPoint].x;
	int sy = quadrants[srcQuad][srcPoint].y;
	for (int dstPoint = 0;
	dstPoint < quadrants[dstQuad].length;
	++dstPoint)
	{
	int dx = quadrants[dstQuad][dstPoint].x;
	int dy = quadrants[dstQuad][dstPoint].y;
	if (!rectTest) {
	// Draw unclipped/clipped lines to every
	// point in the dst quadrant
	g.setColor(unclippedColor);
	g.drawLine(sx, sy, dx, dy);
	g.setClip(clipX1, clipY1, clipSize, clipSize);
	g.setColor(clippedColor);
	g.drawLine(sx,sy, dx, dy);
	} else {
	// Draw unclipped/clipped rectangles to every
	// point in the dst quadrant
	g.setColor(unclippedColor);
	int w = dx - sx;
	int h = dy - sy;
	g.drawRect(sx, sy, w, h);
	g.setClip(clipX1, clipY1, clipSize, clipSize);
	g.setColor(clippedColor);
	g.drawRect(sx, sy, w, h);
	}
	g.setClip(null);
	}
	if (!dynamic) {
	// Draw screen update for visual feedback
	screenGraphics.drawImage(testImage, 0, 0, this);
	// On default test, check for errors after every
	// src point
	if (!quickTest && gridError(g)) {
	throw new java.lang.RuntimeException("Failed");
	}
	}
	}
	}
	if (!dynamic && quickTest && gridError(g)) {
	// On quick test, check for errors only after every
	// src quadrant
	throw new java.lang.RuntimeException("Failed");
	//return;
	}
	}
	if (!dynamic) {
	System.out.println("PASSED");
	if (!keepRunning) {
	f.dispose();
	}
	}
	}

	/**
	* If we have not yet run the test, or if the window size has
	* changed, or if we are running the test in -dynamic mode,
	* run the test. Then draw the test buffer to the screen
	*/
	public void paint(Graphics g) {
	if (dynamic \|\| testImage == null \|\|
	getWidth() != testW \|\| getHeight() != testH)
	{
	runTest(g);
	}
	if (testImage != null) {
	g.drawImage(testImage, 0, 0, this);
	}
	}

	/*
	* Create the quadrant of points and run the test to draw all the lines
	*/
	public void runTest(Graphics screenGraphics) {
	if (getWidth() == 0 \|\| getHeight() == 0) {
	// May get here before window is really ready
	return;
	}
	clipX1 = (getWidth() - clipSize) / 2;
	clipY1 = (getHeight() - clipSize) / 2;
	int clipX2 = clipX1 + clipSize;
	int clipY2 = clipY1 + clipSize;
	int centerX = getWidth()/2;
	int centerY = getHeight()/2;
	int leftX = 0;
	int topY = 0;
	int rightX = getWidth() - 1;
	int bottomY = getHeight() - 1;
	int quadIndex = 0;
	// Offsets are used to force diagonal (versus hor/vert) lines
	int xOffset = 0;
	int yOffset = 0;

	if (quadrants[0] == null) {
	for (int i = 0; i < 9; ++i) {
	int numPoints = (i == 4) ? 9 : 3;
	quadrants[i] = new Point[numPoints];
	}
	}
	// Upper-left
	quadrants[quadIndex] = new Point[] {
	new Point(leftX + xOffset, clipY1 - 1 - yOffset),
	new Point(leftX + xOffset, topY + yOffset),
	new Point(clipX1 - 1 - xOffset, topY + yOffset),
	};

	quadIndex++;
	yOffset++;
	// Upper-middle
	quadrants[quadIndex] = new Point[] {
	new Point(clipX1 + 1 + xOffset, topY + yOffset),
	new Point(centerX + xOffset, topY + yOffset),
	new Point(clipX2 - 1 - xOffset, topY + yOffset),
	};

	quadIndex++;
	++yOffset;
	// Upper-right
	quadrants[quadIndex] = new Point[] {
	new Point(clipX2 + 1 + xOffset, topY + yOffset),
	new Point(rightX - xOffset, topY + yOffset),
	new Point(rightX - xOffset, clipY1 - 1 - yOffset),
	};

	quadIndex++;
	yOffset = 0;
	++xOffset;
	// Middle-left
	quadrants[quadIndex] = new Point[] {
	new Point(leftX + xOffset, clipY1 + 1 + yOffset),
	new Point(leftX + xOffset, centerY + yOffset),
	new Point(leftX + xOffset, clipY2 - 1 - yOffset),
	};

	quadIndex++;
	++yOffset;
	// Middle-middle
	quadrants[quadIndex] = new Point[] {
	new Point(clipX1 + 1 + xOffset, clipY1 + 1 + yOffset),
	new Point(centerX + xOffset, clipY1 + 1 + yOffset),
	new Point(clipX2 - 1 - xOffset, clipY1 + 1 + yOffset),
	new Point(clipX1 + 1 + xOffset, centerY + yOffset),
	new Point(centerX + xOffset, centerY + yOffset),
	new Point(clipX2 - 1 - xOffset, centerY + yOffset),
	new Point(clipX1 + 1 + xOffset, clipY2 - 1 - yOffset),
	new Point(centerX + xOffset, clipY2 - 1 - yOffset),
	new Point(clipX2 - 1 - xOffset, clipY2 - 1 - yOffset),
	};

	quadIndex++;
	++yOffset;
	// Middle-right
	quadrants[quadIndex] = new Point[] {
	new Point(rightX - xOffset, clipY1 + 1 + yOffset),
	new Point(rightX - xOffset, centerY + yOffset),
	new Point(rightX - xOffset, clipY2 - 1 - yOffset),
	};

	quadIndex++;
	yOffset = 0;
	++xOffset;
	// Lower-left
	quadrants[quadIndex] = new Point[] {
	new Point(leftX + xOffset, clipY2 + 1 + yOffset),
	new Point(leftX + xOffset, bottomY - yOffset),
	new Point(clipX1 - 1 - xOffset, bottomY - yOffset),
	};

	quadIndex++;
	++yOffset;
	// Lower-middle
	quadrants[quadIndex] = new Point[] {
	new Point(clipX1 + 1 + xOffset, bottomY - yOffset),
	new Point(centerX + xOffset, bottomY - yOffset),
	new Point(clipX2 - 1 - xOffset, bottomY - yOffset),
	};

	quadIndex++;
	++yOffset;
	// Lower-right
	quadrants[quadIndex] = new Point[] {
	new Point(clipX2 + 1 + xOffset, bottomY - yOffset),
	new Point(rightX - xOffset, bottomY - yOffset),
	new Point(rightX - xOffset, clipY2 + 1 + yOffset),
	};


	if (testImage != null) {
	testImage.flush();
	}
	testW = getWidth();
	testH = getHeight();
	testImage = createVolatileImage(testW, testH);
	Graphics g = testImage.getGraphics();
	do {
	int valCode = testImage.validate(getGraphicsConfiguration());
	if (valCode == VolatileImage.IMAGE_INCOMPATIBLE) {
	testImage.flush();
	testImage = createVolatileImage(testW, testH);
	g = testImage.getGraphics();
	}
	drawLineGrid(screenGraphics, g);
	} while (testImage.contentsLost());
	if (dynamic) {
	// Draw clip box if dynamic
	g.setClip(null);
	g.setColor(Color.black);
	g.drawRect(clipX1, clipY1, clipSize, clipSize);
	screenGraphics.drawImage(testImage, 0, 0, this);
	}
	runTestDone = true;
	}

	/**
	* When running -dynamic, resize the clip bounds and run the test
	* over and over
	*/
	public void run() {
	while (true) {
	clipSize += clipBumpVal;
	if (clipSize > getWidth() \|\| clipSize < 0) {
	clipBumpVal = -clipBumpVal;
	clipSize += clipBumpVal;
	}
	update(getGraphics());
	try {
	Thread.sleep(50);
	} catch (Exception e) {}
	}
	}

	public static void main(String args[]) {
	for (int i = 0; i < args.length; ++i) {
	if (args[i].equals("-dynamic")) {
	dynamic = true;
	} else if (args[i].equals("-rect")) {
	rectTest = true;
	} else if (args[i].equals("-quick")) {
	quickTest = true;
	} else if (args[i].equals("-keep")) {
	keepRunning = true;
	} else {
	// could be clipSize
	try {
	clipSize = Integer.parseInt(args[i]);
	} catch (Exception e) {}
	}
	}
	f = new Frame();
	f.setSize(500, 500);
	LineClipTest test = new LineClipTest();
	f.add(test);
	if (dynamic) {
	Thread t = new Thread(test);
	t.start();
	}
	f.setVisible(true);
	while (!runTestDone) {
	// need to make sure jtreg doesn't exit before the
	// test is done...
	try {
	Thread.sleep(50);
	} catch (Exception e) {}
	}
	}
	}