package com.google.zxing.qrcode.detector;
-import com.google.zxing.ReaderException;
+import com.google.zxing.DecodeHintType;
+import com.google.zxing.FormatException;
+import com.google.zxing.NotFoundException;
import com.google.zxing.ResultPoint;
+import com.google.zxing.ResultPointCallback;
import com.google.zxing.common.BitMatrix;
import com.google.zxing.common.DetectorResult;
import com.google.zxing.common.GridSampler;
+import com.google.zxing.common.PerspectiveTransform;
import com.google.zxing.qrcode.decoder.Version;
import java.util.Hashtable;
public class Detector {
private final BitMatrix image;
+ private ResultPointCallback resultPointCallback;
public Detector(BitMatrix image) {
this.image = image;
return image;
}
+ protected ResultPointCallback getResultPointCallback() {
+ return resultPointCallback;
+ }
+
/**
* <p>Detects a QR Code in an image, simply.</p>
*
* @return {@link DetectorResult} encapsulating results of detecting a QR Code
- * @throws ReaderException if no QR Code can be found
+ * @throws NotFoundException if no QR Code can be found
*/
- public DetectorResult detect() throws ReaderException {
+ public DetectorResult detect() throws NotFoundException, FormatException {
return detect(null);
}
* <p>Detects a QR Code in an image, simply.</p>
*
* @param hints optional hints to detector
- * @return {@link DetectorResult} encapsulating results of detecting a QR Code
- * @throws ReaderException if no QR Code can be found
+ * @return {@link NotFoundException} encapsulating results of detecting a QR Code
+ * @throws NotFoundException if QR Code cannot be found
+ * @throws FormatException if a QR Code cannot be decoded
*/
- public DetectorResult detect(Hashtable hints) throws ReaderException {
+ public DetectorResult detect(Hashtable hints) throws NotFoundException, FormatException {
- FinderPatternFinder finder = new FinderPatternFinder(image);
+ resultPointCallback = hints == null ? null :
+ (ResultPointCallback) hints.get(DecodeHintType.NEED_RESULT_POINT_CALLBACK);
+
+ FinderPatternFinder finder = new FinderPatternFinder(image, resultPointCallback);
FinderPatternInfo info = finder.find(hints);
return processFinderPatternInfo(info);
}
- protected DetectorResult processFinderPatternInfo(FinderPatternInfo info) throws ReaderException {
+ protected DetectorResult processFinderPatternInfo(FinderPatternInfo info)
+ throws NotFoundException, FormatException {
FinderPattern topLeft = info.getTopLeft();
FinderPattern topRight = info.getTopRight();
float moduleSize = calculateModuleSize(topLeft, topRight, bottomLeft);
if (moduleSize < 1.0f) {
- throw ReaderException.getInstance();
+ throw NotFoundException.getNotFoundInstance();
}
int dimension = computeDimension(topLeft, topRight, bottomLeft, moduleSize);
Version provisionalVersion = Version.getProvisionalVersionForDimension(dimension);
estAlignmentY,
(float) i);
break;
- } catch (ReaderException re) {
+ } catch (NotFoundException re) {
// try next round
}
}
// If we didn't find alignment pattern... well try anyway without it
}
- BitMatrix bits = sampleGrid(image, topLeft, topRight, bottomLeft, alignmentPattern, dimension);
+ PerspectiveTransform transform =
+ createTransform(topLeft, topRight, bottomLeft, alignmentPattern, dimension);
+
+ BitMatrix bits = sampleGrid(image, transform, dimension);
ResultPoint[] points;
if (alignmentPattern == null) {
return new DetectorResult(bits, points);
}
- private static BitMatrix sampleGrid(BitMatrix image,
- ResultPoint topLeft,
- ResultPoint topRight,
- ResultPoint bottomLeft,
- ResultPoint alignmentPattern,
- int dimension) throws ReaderException {
+ public PerspectiveTransform createTransform(ResultPoint topLeft,
+ ResultPoint topRight,
+ ResultPoint bottomLeft,
+ ResultPoint alignmentPattern,
+ int dimension) {
float dimMinusThree = (float) dimension - 3.5f;
float bottomRightX;
float bottomRightY;
sourceBottomRightX = sourceBottomRightY = dimMinusThree;
}
- GridSampler sampler = GridSampler.getInstance();
- return sampler.sampleGrid(
- image,
- dimension,
+ return PerspectiveTransform.quadrilateralToQuadrilateral(
3.5f,
3.5f,
dimMinusThree,
bottomLeft.getY());
}
+ private static BitMatrix sampleGrid(BitMatrix image,
+ PerspectiveTransform transform,
+ int dimension) throws NotFoundException {
+
+ GridSampler sampler = GridSampler.getInstance();
+ return sampler.sampleGrid(image, dimension, dimension, transform);
+ }
+
/**
* <p>Computes the dimension (number of modules on a size) of the QR Code based on the position
* of the finder patterns and estimated module size.</p>
*/
- private static int computeDimension(ResultPoint topLeft,
- ResultPoint topRight,
- ResultPoint bottomLeft,
- float moduleSize) throws ReaderException {
+ protected static int computeDimension(ResultPoint topLeft,
+ ResultPoint topRight,
+ ResultPoint bottomLeft,
+ float moduleSize) throws NotFoundException {
int tltrCentersDimension = round(ResultPoint.distance(topLeft, topRight) / moduleSize);
int tlblCentersDimension = round(ResultPoint.distance(topLeft, bottomLeft) / moduleSize);
int dimension = ((tltrCentersDimension + tlblCentersDimension) >> 1) + 7;
dimension--;
break;
case 3:
- throw ReaderException.getInstance();
+ throw NotFoundException.getNotFoundInstance();
}
return dimension;
}
* <p>Computes an average estimated module size based on estimated derived from the positions
* of the three finder patterns.</p>
*/
- private float calculateModuleSize(ResultPoint topLeft, ResultPoint topRight,
- ResultPoint bottomLeft) {
+ protected float calculateModuleSize(ResultPoint topLeft,
+ ResultPoint topRight,
+ ResultPoint bottomLeft) {
// Take the average
return (calculateModuleSizeOneWay(topLeft, topRight) +
calculateModuleSizeOneWay(topLeft, bottomLeft)) / 2.0f;
(int) pattern.getX(),
(int) pattern.getY());
if (Float.isNaN(moduleSizeEst1)) {
- return moduleSizeEst2;
+ return moduleSizeEst2 / 7.0f;
}
if (Float.isNaN(moduleSizeEst2)) {
- return moduleSizeEst1;
+ return moduleSizeEst1 / 7.0f;
}
// Average them, and divide by 7 since we've counted the width of 3 black modules,
// and 1 white and 1 black module on either side. Ergo, divide sum by 14.
*/
private float sizeOfBlackWhiteBlackRunBothWays(int fromX, int fromY, int toX, int toY) {
- float result = sizeOfBlackWhiteBlackRun(fromX, fromY, toX, toY);
-
- // Now count other way -- don't run off image though of course
- int otherToX = fromX - (toX - fromX);
- if (otherToX < 0) {
- // "to" should the be the first value not included, so, the first value off
- // the edge is -1
- otherToX = -1;
- } else if (otherToX >= image.getWidth()) {
- otherToX = image.getWidth();
- }
- int otherToY = fromY - (toY - fromY);
- if (otherToY < 0) {
- otherToY = -1;
- } else if (otherToY >= image.getHeight()) {
- otherToY = image.getHeight();
- }
- result += sizeOfBlackWhiteBlackRun(fromX, fromY, otherToX, otherToY);
- return result - 1.0f; // -1 because we counted the middle pixel twice
- }
+ float result = sizeOfBlackWhiteBlackRun(fromX, fromY, toX, toY);
+
+ // Now count other way -- don't run off image though of course
+ float scale = 1.0f;
+ int otherToX = fromX - (toX - fromX);
+ if (otherToX < 0) {
+ scale = (float) fromX / (float) (fromX - otherToX);
+ otherToX = 0;
+ } else if (otherToX > image.getWidth()) {
+ scale = (float) (image.getWidth() - fromX) / (float) (otherToX - fromX);
+ otherToX = image.getWidth();
+ }
+ int otherToY = (int) (fromY - (toY - fromY) * scale);
+
+ scale = 1.0f;
+ if (otherToY < 0) {
+ scale = (float) fromY / (float) (fromY - otherToY);
+ otherToY = 0;
+ } else if (otherToY > image.getHeight()) {
+ scale = (float) (image.getHeight() - fromY) / (float) (otherToY - fromY);
+ otherToY = image.getHeight();
+ }
+ otherToX = (int) (fromX + (otherToX - fromX) * scale);
+
+ result += sizeOfBlackWhiteBlackRun(fromX, fromY, otherToX, otherToY);
+ return result;
+ }
/**
* <p>This method traces a line from a point in the image, in the direction towards another point.
if (state == 3) { // Found black, white, black, and stumbled back onto white; done
int diffX = x - fromX;
int diffY = y - fromY;
+ if (xstep < 0) {
+ diffX++;
+ }
return (float) Math.sqrt((double) (diffX * diffX + diffY * diffY));
}
error += dy;
if (error > 0) {
+ if (y == toY) {
+ break;
+ }
y += ystep;
error -= dx;
}
* @param estAlignmentY y coordinate of above
* @param allowanceFactor number of pixels in all directions to search from the center
* @return {@link AlignmentPattern} if found, or null otherwise
- * @throws ReaderException if an unexpected error occurs during detection
+ * @throws NotFoundException if an unexpected error occurs during detection
*/
- private AlignmentPattern findAlignmentInRegion(float overallEstModuleSize,
- int estAlignmentX,
- int estAlignmentY,
- float allowanceFactor)
- throws ReaderException {
+ protected AlignmentPattern findAlignmentInRegion(float overallEstModuleSize,
+ int estAlignmentX,
+ int estAlignmentY,
+ float allowanceFactor)
+ throws NotFoundException {
// Look for an alignment pattern (3 modules in size) around where it
// should be
int allowance = (int) (allowanceFactor * overallEstModuleSize);
int alignmentAreaLeftX = Math.max(0, estAlignmentX - allowance);
int alignmentAreaRightX = Math.min(image.getWidth() - 1, estAlignmentX + allowance);
if (alignmentAreaRightX - alignmentAreaLeftX < overallEstModuleSize * 3) {
- throw ReaderException.getInstance();
+ throw NotFoundException.getNotFoundInstance();
}
int alignmentAreaTopY = Math.max(0, estAlignmentY - allowance);
int alignmentAreaBottomY = Math.min(image.getHeight() - 1, estAlignmentY + allowance);
+ if (alignmentAreaBottomY - alignmentAreaTopY < overallEstModuleSize * 3) {
+ throw NotFoundException.getNotFoundInstance();
+ }
AlignmentPatternFinder alignmentFinder =
new AlignmentPatternFinder(
alignmentAreaTopY,
alignmentAreaRightX - alignmentAreaLeftX,
alignmentAreaBottomY - alignmentAreaTopY,
- overallEstModuleSize);
+ overallEstModuleSize,
+ resultPointCallback);
return alignmentFinder.find();
}
private static int round(float d) {
return (int) (d + 0.5f);
}
-
}