下面列出了com.google.zxing.BinaryBitmap#getHeight ( ) 实例代码,或者点击链接到github查看源代码,也可以在右侧发表评论。
@Override
public Result decode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException, FormatException {
try {
return doDecode(image, hints);
} catch (NotFoundException nfe) {
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
if (tryHarder && image.isRotateSupported()) {
BinaryBitmap rotatedImage = image.rotateCounterClockwise();
Result result = doDecode(rotatedImage, hints);
// Record that we found it rotated 90 degrees CCW / 270 degrees CW
Map<ResultMetadataType,?> metadata = result.getResultMetadata();
int orientation = 270;
if (metadata != null && metadata.containsKey(ResultMetadataType.ORIENTATION)) {
// But if we found it reversed in doDecode(), add in that result here:
orientation = (orientation +
(Integer) metadata.get(ResultMetadataType.ORIENTATION)) % 360;
}
result.putMetadata(ResultMetadataType.ORIENTATION, orientation);
// Update result points
ResultPoint[] points = result.getResultPoints();
if (points != null) {
int height = rotatedImage.getHeight();
for (int i = 0; i < points.length; i++) {
points[i] = new ResultPoint(height - points[i].getY() - 1, points[i].getX());
}
}
return result;
} else {
throw nfe;
}
}
}
@Override
public Result decode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException, FormatException {
try {
return doDecode(image, hints);
} catch (NotFoundException nfe) {
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
if (tryHarder && image.isRotateSupported()) {
BinaryBitmap rotatedImage = image.rotateCounterClockwise();
Result result = doDecode(rotatedImage, hints);
// Record that we found it rotated 90 degrees CCW / 270 degrees CW
Map<ResultMetadataType,?> metadata = result.getResultMetadata();
int orientation = 270;
if (metadata != null && metadata.containsKey(ResultMetadataType.ORIENTATION)) {
// But if we found it reversed in doDecode(), add in that result here:
orientation = (orientation +
(Integer) metadata.get(ResultMetadataType.ORIENTATION)) % 360;
}
result.putMetadata(ResultMetadataType.ORIENTATION, orientation);
// Update result points
ResultPoint[] points = result.getResultPoints();
if (points != null) {
int height = rotatedImage.getHeight();
for (int i = 0; i < points.length; i++) {
points[i] = new ResultPoint(height - points[i].getY() - 1, points[i].getX());
}
}
return result;
} else {
throw nfe;
}
}
}
@Override
public Result decode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException, FormatException {
try {
return doDecode(image, hints);
} catch (NotFoundException nfe) {
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
if (tryHarder && image.isRotateSupported()) {
BinaryBitmap rotatedImage = image.rotateCounterClockwise();
Result result = doDecode(rotatedImage, hints);
// Record that we found it rotated 90 degrees CCW / 270 degrees CW
Map<ResultMetadataType,?> metadata = result.getResultMetadata();
int orientation = 270;
if (metadata != null && metadata.containsKey(ResultMetadataType.ORIENTATION)) {
// But if we found it reversed in doDecode(), add in that result here:
orientation = (orientation +
(Integer) metadata.get(ResultMetadataType.ORIENTATION)) % 360;
}
result.putMetadata(ResultMetadataType.ORIENTATION, orientation);
// Update result points
ResultPoint[] points = result.getResultPoints();
if (points != null) {
int height = rotatedImage.getHeight();
for (int i = 0; i < points.length; i++) {
points[i] = new ResultPoint(height - points[i].getY() - 1, points[i].getX());
}
}
return result;
} else {
throw nfe;
}
}
}
@Override
public Result decode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException, FormatException {
try {
return doDecode(image, hints);
} catch (NotFoundException nfe) {
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
if (tryHarder && image.isRotateSupported()) {
BinaryBitmap rotatedImage = image.rotateCounterClockwise();
Result result = doDecode(rotatedImage, hints);
// Record that we found it rotated 90 degrees CCW / 270 degrees CW
Map<ResultMetadataType,?> metadata = result.getResultMetadata();
int orientation = 270;
if (metadata != null && metadata.containsKey(ResultMetadataType.ORIENTATION)) {
// But if we found it reversed in doDecode(), add in that result here:
orientation = (orientation +
(Integer) metadata.get(ResultMetadataType.ORIENTATION)) % 360;
}
result.putMetadata(ResultMetadataType.ORIENTATION, orientation);
// Update result points
ResultPoint[] points = result.getResultPoints();
if (points != null) {
int height = rotatedImage.getHeight();
for (int i = 0; i < points.length; i++) {
points[i] = new ResultPoint(height - points[i].getY() - 1, points[i].getX());
}
}
return result;
} else {
throw nfe;
}
}
}
@Override
public Result decode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException, FormatException {
try {
return doDecode(image, hints);
} catch (NotFoundException nfe) {
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
if (tryHarder && image.isRotateSupported()) {
BinaryBitmap rotatedImage = image.rotateCounterClockwise();
Result result = doDecode(rotatedImage, hints);
// Record that we found it rotated 90 degrees CCW / 270 degrees CW
Map<ResultMetadataType,?> metadata = result.getResultMetadata();
int orientation = 270;
if (metadata != null && metadata.containsKey(ResultMetadataType.ORIENTATION)) {
// But if we found it reversed in doDecode(), add in that result here:
orientation = (orientation +
(Integer) metadata.get(ResultMetadataType.ORIENTATION)) % 360;
}
result.putMetadata(ResultMetadataType.ORIENTATION, orientation);
// Update result points
ResultPoint[] points = result.getResultPoints();
if (points != null) {
int height = rotatedImage.getHeight();
for (int i = 0; i < points.length; i++) {
points[i] = new ResultPoint(height - points[i].getY() - 1, points[i].getX());
}
}
return result;
} else {
throw nfe;
}
}
}
/**
* We're going to examine rows from the middle outward, searching alternately above and below the
* middle, and farther out each time. rowStep is the number of rows between each successive
* attempt above and below the middle. So we'd scan row middle, then middle - rowStep, then
* middle + rowStep, then middle - (2 * rowStep), etc.
* rowStep is bigger as the image is taller, but is always at least 1. We've somewhat arbitrarily
* decided that moving up and down by about 1/16 of the image is pretty good; we try more of the
* image if "trying harder".
*
* @param image The image to decode
* @param hints Any hints that were requested
* @return The contents of the decoded barcode
* @throws NotFoundException Any spontaneous errors which occur
*/
private Result doDecode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException {
int width = image.getWidth();
int height = image.getHeight();
BitArray row = new BitArray(width);
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
int rowStep = Math.max(1, height >> (tryHarder ? 8 : 5));
int maxLines;
if (tryHarder) {
maxLines = height; // Look at the whole image, not just the center
} else {
maxLines = 15; // 15 rows spaced 1/32 apart is roughly the middle half of the image
}
int middle = height / 2;
for (int x = 0; x < maxLines; x++) {
// Scanning from the middle out. Determine which row we're looking at next:
int rowStepsAboveOrBelow = (x + 1) / 2;
boolean isAbove = (x & 0x01) == 0; // i.e. is x even?
int rowNumber = middle + rowStep * (isAbove ? rowStepsAboveOrBelow : -rowStepsAboveOrBelow);
if (rowNumber < 0 || rowNumber >= height) {
// Oops, if we run off the top or bottom, stop
break;
}
// Estimate black point for this row and load it:
try {
row = image.getBlackRow(rowNumber, row);
} catch (NotFoundException ignored) {
continue;
}
// While we have the image data in a BitArray, it's fairly cheap to reverse it in place to
// handle decoding upside down barcodes.
for (int attempt = 0; attempt < 2; attempt++) {
if (attempt == 1) { // trying again?
row.reverse(); // reverse the row and continue
// This means we will only ever draw result points *once* in the life of this method
// since we want to avoid drawing the wrong points after flipping the row, and,
// don't want to clutter with noise from every single row scan -- just the scans
// that start on the center line.
if (hints != null && hints.containsKey(DecodeHintType.NEED_RESULT_POINT_CALLBACK)) {
Map<DecodeHintType,Object> newHints = new EnumMap<>(DecodeHintType.class);
newHints.putAll(hints);
newHints.remove(DecodeHintType.NEED_RESULT_POINT_CALLBACK);
hints = newHints;
}
}
try {
// Look for a barcode
Result result = decodeRow(rowNumber, row, hints);
// We found our barcode
if (attempt == 1) {
// But it was upside down, so note that
result.putMetadata(ResultMetadataType.ORIENTATION, 180);
// And remember to flip the result points horizontally.
ResultPoint[] points = result.getResultPoints();
if (points != null) {
points[0] = new ResultPoint(width - points[0].getX() - 1, points[0].getY());
points[1] = new ResultPoint(width - points[1].getX() - 1, points[1].getY());
}
}
return result;
} catch (ReaderException re) {
// continue -- just couldn't decode this row
}
}
}
throw NotFoundException.getNotFoundInstance();
}
private void doDecodeMultiple(BinaryBitmap image,
Map<DecodeHintType,?> hints,
List<Result> results,
int xOffset,
int yOffset,
int currentDepth) {
if (currentDepth > MAX_DEPTH) {
return;
}
Result result;
try {
result = delegate.decode(image, hints);
} catch (ReaderException ignored) {
return;
}
boolean alreadyFound = false;
for (Result existingResult : results) {
if (existingResult.getText().equals(result.getText())) {
alreadyFound = true;
break;
}
}
if (!alreadyFound) {
results.add(translateResultPoints(result, xOffset, yOffset));
}
ResultPoint[] resultPoints = result.getResultPoints();
if (resultPoints == null || resultPoints.length == 0) {
return;
}
int width = image.getWidth();
int height = image.getHeight();
float minX = width;
float minY = height;
float maxX = 0.0f;
float maxY = 0.0f;
for (ResultPoint point : resultPoints) {
if (point == null) {
continue;
}
float x = point.getX();
float y = point.getY();
if (x < minX) {
minX = x;
}
if (y < minY) {
minY = y;
}
if (x > maxX) {
maxX = x;
}
if (y > maxY) {
maxY = y;
}
}
// Decode left of barcode
if (minX > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, (int) minX, height),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode above barcode
if (minY > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, width, (int) minY),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode right of barcode
if (maxX < width - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop((int) maxX, 0, width - (int) maxX, height),
hints, results,
xOffset + (int) maxX, yOffset,
currentDepth + 1);
}
// Decode below barcode
if (maxY < height - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, (int) maxY, width, height - (int) maxY),
hints, results,
xOffset, yOffset + (int) maxY,
currentDepth + 1);
}
}
/**
* We're going to examine rows from the middle outward, searching alternately above and below the
* middle, and farther out each time. rowStep is the number of rows between each successive
* attempt above and below the middle. So we'd scan row middle, then middle - rowStep, then
* middle + rowStep, then middle - (2 * rowStep), etc.
* rowStep is bigger as the image is taller, but is always at least 1. We've somewhat arbitrarily
* decided that moving up and down by about 1/16 of the image is pretty good; we try more of the
* image if "trying harder".
*
* @param image The image to decode
* @param hints Any hints that were requested
* @return The contents of the decoded barcode
* @throws NotFoundException Any spontaneous errors which occur
*/
private Result doDecode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException {
int width = image.getWidth();
int height = image.getHeight();
BitArray row = new BitArray(width);
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
int rowStep = Math.max(1, height >> (tryHarder ? 8 : 5));
int maxLines;
if (tryHarder) {
maxLines = height; // Look at the whole image, not just the center
} else {
maxLines = 15; // 15 rows spaced 1/32 apart is roughly the middle half of the image
}
int middle = height / 2;
for (int x = 0; x < maxLines; x++) {
// Scanning from the middle out. Determine which row we're looking at next:
int rowStepsAboveOrBelow = (x + 1) / 2;
boolean isAbove = (x & 0x01) == 0; // i.e. is x even?
int rowNumber = middle + rowStep * (isAbove ? rowStepsAboveOrBelow : -rowStepsAboveOrBelow);
if (rowNumber < 0 || rowNumber >= height) {
// Oops, if we run off the top or bottom, stop
break;
}
// Estimate black point for this row and load it:
try {
row = image.getBlackRow(rowNumber, row);
} catch (NotFoundException ignored) {
continue;
}
// While we have the image data in a BitArray, it's fairly cheap to reverse it in place to
// handle decoding upside down barcodes.
for (int attempt = 0; attempt < 2; attempt++) {
if (attempt == 1) { // trying again?
row.reverse(); // reverse the row and continue
// This means we will only ever draw result points *once* in the life of this method
// since we want to avoid drawing the wrong points after flipping the row, and,
// don't want to clutter with noise from every single row scan -- just the scans
// that start on the center line.
if (hints != null && hints.containsKey(DecodeHintType.NEED_RESULT_POINT_CALLBACK)) {
Map<DecodeHintType,Object> newHints = new EnumMap<>(DecodeHintType.class);
newHints.putAll(hints);
newHints.remove(DecodeHintType.NEED_RESULT_POINT_CALLBACK);
hints = newHints;
}
}
try {
// Look for a barcode
Result result = decodeRow(rowNumber, row, hints);
// We found our barcode
if (attempt == 1) {
// But it was upside down, so note that
result.putMetadata(ResultMetadataType.ORIENTATION, 180);
// And remember to flip the result points horizontally.
ResultPoint[] points = result.getResultPoints();
if (points != null) {
points[0] = new ResultPoint(width - points[0].getX() - 1, points[0].getY());
points[1] = new ResultPoint(width - points[1].getX() - 1, points[1].getY());
}
}
return result;
} catch (ReaderException re) {
// continue -- just couldn't decode this row
}
}
}
throw NotFoundException.getNotFoundInstance();
}
private void doDecodeMultiple(BinaryBitmap image,
Map<DecodeHintType,?> hints,
List<Result> results,
int xOffset,
int yOffset,
int currentDepth) {
if (currentDepth > MAX_DEPTH) {
return;
}
Result result;
try {
result = delegate.decode(image, hints);
} catch (ReaderException ignored) {
return;
}
boolean alreadyFound = false;
for (Result existingResult : results) {
if (existingResult.getText().equals(result.getText())) {
alreadyFound = true;
break;
}
}
if (!alreadyFound) {
results.add(translateResultPoints(result, xOffset, yOffset));
}
ResultPoint[] resultPoints = result.getResultPoints();
if (resultPoints == null || resultPoints.length == 0) {
return;
}
int width = image.getWidth();
int height = image.getHeight();
float minX = width;
float minY = height;
float maxX = 0.0f;
float maxY = 0.0f;
for (ResultPoint point : resultPoints) {
if (point == null) {
continue;
}
float x = point.getX();
float y = point.getY();
if (x < minX) {
minX = x;
}
if (y < minY) {
minY = y;
}
if (x > maxX) {
maxX = x;
}
if (y > maxY) {
maxY = y;
}
}
// Decode left of barcode
if (minX > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, (int) minX, height),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode above barcode
if (minY > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, width, (int) minY),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode right of barcode
if (maxX < width - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop((int) maxX, 0, width - (int) maxX, height),
hints, results,
xOffset + (int) maxX, yOffset,
currentDepth + 1);
}
// Decode below barcode
if (maxY < height - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, (int) maxY, width, height - (int) maxY),
hints, results,
xOffset, yOffset + (int) maxY,
currentDepth + 1);
}
}
/**
* We're going to examine rows from the middle outward, searching alternately above and below the
* middle, and farther out each time. rowStep is the number of rows between each successive
* attempt above and below the middle. So we'd scan row middle, then middle - rowStep, then
* middle + rowStep, then middle - (2 * rowStep), etc.
* rowStep is bigger as the image is taller, but is always at least 1. We've somewhat arbitrarily
* decided that moving up and down by about 1/16 of the image is pretty good; we try more of the
* image if "trying harder".
*
* @param image The image to decode
* @param hints Any hints that were requested
* @return The contents of the decoded barcode
* @throws NotFoundException Any spontaneous errors which occur
*/
private Result doDecode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException {
int width = image.getWidth();
int height = image.getHeight();
BitArray row = new BitArray(width);
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
int rowStep = Math.max(1, height >> (tryHarder ? 8 : 5));
int maxLines;
if (tryHarder) {
maxLines = height; // Look at the whole image, not just the center
} else {
maxLines = 15; // 15 rows spaced 1/32 apart is roughly the middle half of the image
}
int middle = height / 2;
for (int x = 0; x < maxLines; x++) {
// Scanning from the middle out. Determine which row we're looking at next:
int rowStepsAboveOrBelow = (x + 1) / 2;
boolean isAbove = (x & 0x01) == 0; // i.e. is x even?
int rowNumber = middle + rowStep * (isAbove ? rowStepsAboveOrBelow : -rowStepsAboveOrBelow);
if (rowNumber < 0 || rowNumber >= height) {
// Oops, if we run off the top or bottom, stop
break;
}
// Estimate black point for this row and load it:
try {
row = image.getBlackRow(rowNumber, row);
} catch (NotFoundException ignored) {
continue;
}
// While we have the image data in a BitArray, it's fairly cheap to reverse it in place to
// handle decoding upside down barcodes.
for (int attempt = 0; attempt < 2; attempt++) {
if (attempt == 1) { // trying again?
row.reverse(); // reverse the row and continue
// This means we will only ever draw result points *once* in the life of this method
// since we want to avoid drawing the wrong points after flipping the row, and,
// don't want to clutter with noise from every single row scan -- just the scans
// that start on the center line.
if (hints != null && hints.containsKey(DecodeHintType.NEED_RESULT_POINT_CALLBACK)) {
Map<DecodeHintType,Object> newHints = new EnumMap<>(DecodeHintType.class);
newHints.putAll(hints);
newHints.remove(DecodeHintType.NEED_RESULT_POINT_CALLBACK);
hints = newHints;
}
}
try {
// Look for a barcode
Result result = decodeRow(rowNumber, row, hints);
// We found our barcode
if (attempt == 1) {
// But it was upside down, so note that
result.putMetadata(ResultMetadataType.ORIENTATION, 180);
// And remember to flip the result points horizontally.
ResultPoint[] points = result.getResultPoints();
if (points != null) {
points[0] = new ResultPoint(width - points[0].getX() - 1, points[0].getY());
points[1] = new ResultPoint(width - points[1].getX() - 1, points[1].getY());
}
}
return result;
} catch (ReaderException re) {
// continue -- just couldn't decode this row
}
}
}
throw NotFoundException.getNotFoundInstance();
}
private void doDecodeMultiple(BinaryBitmap image,
Map<DecodeHintType,?> hints,
List<Result> results,
int xOffset,
int yOffset,
int currentDepth) {
if (currentDepth > MAX_DEPTH) {
return;
}
Result result;
try {
result = delegate.decode(image, hints);
} catch (ReaderException ignored) {
return;
}
boolean alreadyFound = false;
for (Result existingResult : results) {
if (existingResult.getText().equals(result.getText())) {
alreadyFound = true;
break;
}
}
if (!alreadyFound) {
results.add(translateResultPoints(result, xOffset, yOffset));
}
ResultPoint[] resultPoints = result.getResultPoints();
if (resultPoints == null || resultPoints.length == 0) {
return;
}
int width = image.getWidth();
int height = image.getHeight();
float minX = width;
float minY = height;
float maxX = 0.0f;
float maxY = 0.0f;
for (ResultPoint point : resultPoints) {
if (point == null) {
continue;
}
float x = point.getX();
float y = point.getY();
if (x < minX) {
minX = x;
}
if (y < minY) {
minY = y;
}
if (x > maxX) {
maxX = x;
}
if (y > maxY) {
maxY = y;
}
}
// Decode left of barcode
if (minX > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, (int) minX, height),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode above barcode
if (minY > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, width, (int) minY),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode right of barcode
if (maxX < width - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop((int) maxX, 0, width - (int) maxX, height),
hints, results,
xOffset + (int) maxX, yOffset,
currentDepth + 1);
}
// Decode below barcode
if (maxY < height - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, (int) maxY, width, height - (int) maxY),
hints, results,
xOffset, yOffset + (int) maxY,
currentDepth + 1);
}
}
/**
* We're going to examine rows from the middle outward, searching alternately above and below the
* middle, and farther out each time. rowStep is the number of rows between each successive
* attempt above and below the middle. So we'd scan row middle, then middle - rowStep, then
* middle + rowStep, then middle - (2 * rowStep), etc.
* rowStep is bigger as the image is taller, but is always at least 1. We've somewhat arbitrarily
* decided that moving up and down by about 1/16 of the image is pretty good; we try more of the
* image if "trying harder".
*
* @param image The image to decode
* @param hints Any hints that were requested
* @return The contents of the decoded barcode
* @throws NotFoundException Any spontaneous errors which occur
*/
private Result doDecode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException {
int width = image.getWidth();
int height = image.getHeight();
BitArray row = new BitArray(width);
int middle = height >> 1;
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
int rowStep = Math.max(1, height >> (tryHarder ? 8 : 5));
int maxLines;
if (tryHarder) {
maxLines = height; // Look at the whole image, not just the center
} else {
maxLines = 15; // 15 rows spaced 1/32 apart is roughly the middle half of the image
}
for (int x = 0; x < maxLines; x++) {
// Scanning from the middle out. Determine which row we're looking at next:
int rowStepsAboveOrBelow = (x + 1) / 2;
boolean isAbove = (x & 0x01) == 0; // i.e. is x even?
int rowNumber = middle + rowStep * (isAbove ? rowStepsAboveOrBelow : -rowStepsAboveOrBelow);
if (rowNumber < 0 || rowNumber >= height) {
// Oops, if we run off the top or bottom, stop
break;
}
// Estimate black point for this row and load it:
try {
row = image.getBlackRow(rowNumber, row);
} catch (NotFoundException ignored) {
continue;
}
// While we have the image data in a BitArray, it's fairly cheap to reverse it in place to
// handle decoding upside down barcodes.
for (int attempt = 0; attempt < 2; attempt++) {
if (attempt == 1) { // trying again?
row.reverse(); // reverse the row and continue
// This means we will only ever draw result points *once* in the life of this method
// since we want to avoid drawing the wrong points after flipping the row, and,
// don't want to clutter with noise from every single row scan -- just the scans
// that start on the center line.
if (hints != null && hints.containsKey(DecodeHintType.NEED_RESULT_POINT_CALLBACK)) {
Map<DecodeHintType,Object> newHints = new EnumMap<>(DecodeHintType.class);
newHints.putAll(hints);
newHints.remove(DecodeHintType.NEED_RESULT_POINT_CALLBACK);
hints = newHints;
}
}
try {
// Look for a barcode
Result result = decodeRow(rowNumber, row, hints);
// We found our barcode
if (attempt == 1) {
// But it was upside down, so note that
result.putMetadata(ResultMetadataType.ORIENTATION, 180);
// And remember to flip the result points horizontally.
ResultPoint[] points = result.getResultPoints();
if (points != null) {
points[0] = new ResultPoint(width - points[0].getX() - 1, points[0].getY());
points[1] = new ResultPoint(width - points[1].getX() - 1, points[1].getY());
}
}
return result;
} catch (ReaderException re) {
// continue -- just couldn't decode this row
}
}
}
throw NotFoundException.getNotFoundInstance();
}
private void doDecodeMultiple(BinaryBitmap image,
Map<DecodeHintType,?> hints,
List<Result> results,
int xOffset,
int yOffset,
int currentDepth) {
if (currentDepth > MAX_DEPTH) {
return;
}
Result result;
try {
result = delegate.decode(image, hints);
} catch (ReaderException ignored) {
return;
}
boolean alreadyFound = false;
for (Result existingResult : results) {
if (existingResult.getText().equals(result.getText())) {
alreadyFound = true;
break;
}
}
if (!alreadyFound) {
results.add(translateResultPoints(result, xOffset, yOffset));
}
ResultPoint[] resultPoints = result.getResultPoints();
if (resultPoints == null || resultPoints.length == 0) {
return;
}
int width = image.getWidth();
int height = image.getHeight();
float minX = width;
float minY = height;
float maxX = 0.0f;
float maxY = 0.0f;
for (ResultPoint point : resultPoints) {
float x = point.getX();
float y = point.getY();
if (x < minX) {
minX = x;
}
if (y < minY) {
minY = y;
}
if (x > maxX) {
maxX = x;
}
if (y > maxY) {
maxY = y;
}
}
// Decode left of barcode
if (minX > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, (int) minX, height),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode above barcode
if (minY > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, width, (int) minY),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode right of barcode
if (maxX < width - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop((int) maxX, 0, width - (int) maxX, height),
hints, results,
xOffset + (int) maxX, yOffset,
currentDepth + 1);
}
// Decode below barcode
if (maxY < height - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, (int) maxY, width, height - (int) maxY),
hints, results,
xOffset, yOffset + (int) maxY,
currentDepth + 1);
}
}
public Result decode(BinaryBitmap binarybitmap, Map map)
{
Result result1;
try
{
result1 = a(binarybitmap, map);
}
catch (NotFoundException notfoundexception)
{
boolean flag;
if (map != null && map.containsKey(DecodeHintType.TRY_HARDER))
{
flag = true;
} else
{
flag = false;
}
if (flag && binarybitmap.isRotateSupported())
{
BinaryBitmap binarybitmap1 = binarybitmap.rotateCounterClockwise();
Result result = a(binarybitmap1, map);
Map map1 = result.getResultMetadata();
int i;
ResultPoint aresultpoint[];
if (map1 != null && map1.containsKey(ResultMetadataType.ORIENTATION))
{
i = (270 + ((Integer)map1.get(ResultMetadataType.ORIENTATION)).intValue()) % 360;
} else
{
i = 270;
}
result.putMetadata(ResultMetadataType.ORIENTATION, Integer.valueOf(i));
aresultpoint = result.getResultPoints();
if (aresultpoint != null)
{
int j = binarybitmap1.getHeight();
for (int k = 0; k < aresultpoint.length; k++)
{
aresultpoint[k] = new ResultPoint((float)j - aresultpoint[k].getY() - 1.0F, aresultpoint[k].getX());
}
}
return result;
} else
{
throw notfoundexception;
}
}
return result1;
}
/**
* We're going to examine rows from the middle outward, searching
* alternately above and below the middle, and farther out each time.
* rowStep is the number of rows between each successive attempt above and
* below the middle. So we'd scan row middle, then middle - rowStep, then
* middle + rowStep, then middle - (2 * rowStep), etc. rowStep is bigger as
* the image is taller, but is always at least 1. We've somewhat arbitrarily
* decided that moving up and down by about 1/16 of the image is pretty
* good; we try more of the image if "trying harder".
*
* @param image
* The image to decode
* @param hints
* Any hints that were requested
* @return The contents of the decoded barcode
* @throws NotFoundException
* Any spontaneous errors which occur
*/
private Result doDecode(BinaryBitmap image, Map<DecodeHintType, ?> hints) throws NotFoundException {
int width = image.getWidth();
int height = image.getHeight();
BitArray row = new BitArray(width);
int middle = height >> 1;
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
int rowStep = Math.max(1, height >> (tryHarder ? 8 : 5));
int maxLines;
if (tryHarder) {
maxLines = height; // Look at the whole image, not just the center
} else {
maxLines = 15; // 15 rows spaced 1/32 apart is roughly the middle
// half of the image
}
for (int x = 0; x < maxLines; x++) {
// Scanning from the middle out. Determine which row we're looking
// at next:
int rowStepsAboveOrBelow = (x + 1) / 2;
boolean isAbove = (x & 0x01) == 0; // i.e. is x even?
int rowNumber = middle + rowStep * (isAbove ? rowStepsAboveOrBelow : -rowStepsAboveOrBelow);
if (rowNumber < 0 || rowNumber >= height) {
// Oops, if we run off the top or bottom, stop
break;
}
// Estimate black point for this row and load it:
try {
row = image.getBlackRow(rowNumber, row);
} catch (NotFoundException ignored) {
continue;
}
// While we have the image data in a BitArray, it's fairly cheap to
// reverse it in place to
// handle decoding upside down barcodes.
for (int attempt = 0; attempt < 2; attempt++) {
if (attempt == 1) { // trying again?
row.reverse(); // reverse the row and continue
// This means we will only ever draw result points *once* in
// the life of this method
// since we want to avoid drawing the wrong points after
// flipping the row, and,
// don't want to clutter with noise from every single row
// scan -- just the scans
// that start on the center line.
if (hints != null && hints.containsKey(DecodeHintType.NEED_RESULT_POINT_CALLBACK)) {
Map<DecodeHintType, Object> newHints = new EnumMap<>(DecodeHintType.class);
newHints.putAll(hints);
newHints.remove(DecodeHintType.NEED_RESULT_POINT_CALLBACK);
hints = newHints;
}
}
try {
// Look for a barcode
Result result = decodeRow(rowNumber, row, hints);
// We found our barcode
if (attempt == 1) {
// But it was upside down, so note that
result.putMetadata(ResultMetadataType.ORIENTATION, 180);
// And remember to flip the result points horizontally.
ResultPoint[] points = result.getResultPoints();
if (points != null) {
points[0] = new ResultPoint(width - points[0].getX() - 1, points[0].getY());
points[1] = new ResultPoint(width - points[1].getX() - 1, points[1].getY());
}
}
return result;
} catch (ReaderException re) {
// continue -- just couldn't decode this row
}
}
}
throw NotFoundException.getNotFoundInstance();
}
private void doDecodeMultiple(BinaryBitmap image,
Map<DecodeHintType,?> hints,
List<Result> results,
int xOffset,
int yOffset,
int currentDepth) {
if (currentDepth > MAX_DEPTH) {
return;
}
Result result;
try {
result = delegate.decode(image, hints);
} catch (ReaderException ignored) {
return;
}
boolean alreadyFound = false;
for (Result existingResult : results) {
if (existingResult.getText().equals(result.getText())) {
alreadyFound = true;
break;
}
}
if (!alreadyFound) {
results.add(translateResultPoints(result, xOffset, yOffset));
}
ResultPoint[] resultPoints = result.getResultPoints();
if (resultPoints == null || resultPoints.length == 0) {
return;
}
int width = image.getWidth();
int height = image.getHeight();
float minX = width;
float minY = height;
float maxX = 0.0f;
float maxY = 0.0f;
for (ResultPoint point : resultPoints) {
if (point == null) {
continue;
}
float x = point.getX();
float y = point.getY();
if (x < minX) {
minX = x;
}
if (y < minY) {
minY = y;
}
if (x > maxX) {
maxX = x;
}
if (y > maxY) {
maxY = y;
}
}
// Decode left of barcode
if (minX > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, (int) minX, height),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode above barcode
if (minY > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, width, (int) minY),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode right of barcode
if (maxX < width - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop((int) maxX, 0, width - (int) maxX, height),
hints, results,
xOffset + (int) maxX, yOffset,
currentDepth + 1);
}
// Decode below barcode
if (maxY < height - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, (int) maxY, width, height - (int) maxY),
hints, results,
xOffset, yOffset + (int) maxY,
currentDepth + 1);
}
}
/**
* We're going to examine rows from the middle outward, searching alternately above and below the
* middle, and farther out each time. rowStep is the number of rows between each successive
* attempt above and below the middle. So we'd scan row middle, then middle - rowStep, then
* middle + rowStep, then middle - (2 * rowStep), etc.
* rowStep is bigger as the image is taller, but is always at least 1. We've somewhat arbitrarily
* decided that moving up and down by about 1/16 of the image is pretty good; we try more of the
* image if "trying harder".
*
* @param image The image to decode
* @param hints Any hints that were requested
* @return The contents of the decoded barcode
* @throws NotFoundException Any spontaneous errors which occur
*/
private Result doDecode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException {
int width = image.getWidth();
int height = image.getHeight();
BitArray row = new BitArray(width);
int middle = height >> 1;
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
int rowStep = Math.max(1, height >> (tryHarder ? 8 : 5));
int maxLines;
if (tryHarder) {
maxLines = height; // Look at the whole image, not just the center
} else {
maxLines = 15; // 15 rows spaced 1/32 apart is roughly the middle half of the image
}
for (int x = 0; x < maxLines; x++) {
// Scanning from the middle out. Determine which row we're looking at next:
int rowStepsAboveOrBelow = (x + 1) >> 1;
boolean isAbove = (x & 0x01) == 0; // i.e. is x even?
int rowNumber = middle + rowStep * (isAbove ? rowStepsAboveOrBelow : -rowStepsAboveOrBelow);
if (rowNumber < 0 || rowNumber >= height) {
// Oops, if we run off the top or bottom, stop
break;
}
// Estimate black point for this row and load it:
try {
row = image.getBlackRow(rowNumber, row);
} catch (NotFoundException nfe) {
continue;
}
// While we have the image data in a BitArray, it's fairly cheap to reverse it in place to
// handle decoding upside down barcodes.
for (int attempt = 0; attempt < 2; attempt++) {
if (attempt == 1) { // trying again?
row.reverse(); // reverse the row and continue
// This means we will only ever draw result points *once* in the life of this method
// since we want to avoid drawing the wrong points after flipping the row, and,
// don't want to clutter with noise from every single row scan -- just the scans
// that start on the center line.
if (hints != null && hints.containsKey(DecodeHintType.NEED_RESULT_POINT_CALLBACK)) {
Map<DecodeHintType,Object> newHints = new EnumMap<DecodeHintType,Object>(DecodeHintType.class);
newHints.putAll(hints);
newHints.remove(DecodeHintType.NEED_RESULT_POINT_CALLBACK);
hints = newHints;
}
}
try {
// Look for a barcode
Result result = decodeRow(rowNumber, row, hints);
// We found our barcode
if (attempt == 1) {
// But it was upside down, so note that
result.putMetadata(ResultMetadataType.ORIENTATION, 180);
// And remember to flip the result points horizontally.
ResultPoint[] points = result.getResultPoints();
if (points != null) {
points[0] = new ResultPoint(width - points[0].getX() - 1, points[0].getY());
points[1] = new ResultPoint(width - points[1].getX() - 1, points[1].getY());
}
}
return result;
} catch (ReaderException re) {
// continue -- just couldn't decode this row
}
}
}
throw NotFoundException.getNotFoundInstance();
}
/**
* We're going to examine rows from the middle outward, searching alternately above and below the
* middle, and farther out each time. rowStep is the number of rows between each successive
* attempt above and below the middle. So we'd scan row middle, then middle - rowStep, then
* middle + rowStep, then middle - (2 * rowStep), etc.
* rowStep is bigger as the image is taller, but is always at least 1. We've somewhat arbitrarily
* decided that moving up and down by about 1/16 of the image is pretty good; we try more of the
* image if "trying harder".
*
* @param image The image to decode
* @param hints Any hints that were requested
* @return The contents of the decoded barcode
* @throws NotFoundException Any spontaneous errors which occur
*/
private Result doDecode(BinaryBitmap image,
Map<DecodeHintType,?> hints) throws NotFoundException {
int width = image.getWidth();
int height = image.getHeight();
BitArray row = new BitArray(width);
int middle = height >> 1;
boolean tryHarder = hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
int rowStep = Math.max(1, height >> (tryHarder ? 8 : 5));
int maxLines;
if (tryHarder) {
maxLines = height; // Look at the whole image, not just the center
} else {
maxLines = 15; // 15 rows spaced 1/32 apart is roughly the middle half of the image
}
for (int x = 0; x < maxLines; x++) {
// Scanning from the middle out. Determine which row we're looking at next:
int rowStepsAboveOrBelow = (x + 1) / 2;
boolean isAbove = (x & 0x01) == 0; // i.e. is x even?
int rowNumber = middle + rowStep * (isAbove ? rowStepsAboveOrBelow : -rowStepsAboveOrBelow);
if (rowNumber < 0 || rowNumber >= height) {
// Oops, if we run off the top or bottom, stop
break;
}
// Estimate black point for this row and load it:
try {
row = image.getBlackRow(rowNumber, row);
} catch (NotFoundException ignored) {
continue;
}
// While we have the image data in a BitArray, it's fairly cheap to reverse it in place to
// handle decoding upside down barcodes.
for (int attempt = 0; attempt < 2; attempt++) {
if (attempt == 1) { // trying again?
row.reverse(); // reverse the row and continue
// This means we will only ever draw result points *once* in the life of this method
// since we want to avoid drawing the wrong points after flipping the row, and,
// don't want to clutter with noise from every single row scan -- just the scans
// that start on the center line.
if (hints != null && hints.containsKey(DecodeHintType.NEED_RESULT_POINT_CALLBACK)) {
Map<DecodeHintType,Object> newHints = new EnumMap<>(DecodeHintType.class);
newHints.putAll(hints);
newHints.remove(DecodeHintType.NEED_RESULT_POINT_CALLBACK);
hints = newHints;
}
}
try {
// Look for a barcode
Result result = decodeRow(rowNumber, row, hints);
// We found our barcode
if (attempt == 1) {
// But it was upside down, so note that
result.putMetadata(ResultMetadataType.ORIENTATION, 180);
// And remember to flip the result points horizontally.
ResultPoint[] points = result.getResultPoints();
if (points != null) {
points[0] = new ResultPoint(width - points[0].getX() - 1, points[0].getY());
points[1] = new ResultPoint(width - points[1].getX() - 1, points[1].getY());
}
}
return result;
} catch (ReaderException re) {
// continue -- just couldn't decode this row
}
}
}
throw NotFoundException.getNotFoundInstance();
}
private void doDecodeMultiple(BinaryBitmap image,
Map<DecodeHintType,?> hints,
List<Result> results,
int xOffset,
int yOffset,
int currentDepth) {
if (currentDepth > MAX_DEPTH) {
return;
}
Result result;
try {
result = delegate.decode(image, hints);
} catch (ReaderException ignored) {
return;
}
boolean alreadyFound = false;
for (Result existingResult : results) {
if (existingResult.getText().equals(result.getText())) {
alreadyFound = true;
break;
}
}
if (!alreadyFound) {
results.add(translateResultPoints(result, xOffset, yOffset));
}
ResultPoint[] resultPoints = result.getResultPoints();
if (resultPoints == null || resultPoints.length == 0) {
return;
}
int width = image.getWidth();
int height = image.getHeight();
float minX = width;
float minY = height;
float maxX = 0.0f;
float maxY = 0.0f;
for (ResultPoint point : resultPoints) {
if (point == null) {
continue;
}
float x = point.getX();
float y = point.getY();
if (x < minX) {
minX = x;
}
if (y < minY) {
minY = y;
}
if (x > maxX) {
maxX = x;
}
if (y > maxY) {
maxY = y;
}
}
// Decode left of barcode
if (minX > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, (int) minX, height),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode above barcode
if (minY > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, width, (int) minY),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode right of barcode
if (maxX < width - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop((int) maxX, 0, width - (int) maxX, height),
hints, results,
xOffset + (int) maxX, yOffset,
currentDepth + 1);
}
// Decode below barcode
if (maxY < height - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, (int) maxY, width, height - (int) maxY),
hints, results,
xOffset, yOffset + (int) maxY,
currentDepth + 1);
}
}
private void doDecodeMultiple(BinaryBitmap image,
Map<DecodeHintType,?> hints,
List<Result> results,
int xOffset,
int yOffset,
int currentDepth) {
if (currentDepth > MAX_DEPTH) {
return;
}
Result result;
try {
result = delegate.decode(image, hints);
} catch (ReaderException ignored) {
return;
}
boolean alreadyFound = false;
for (Result existingResult : results) {
if (existingResult.getText().equals(result.getText())) {
alreadyFound = true;
break;
}
}
if (!alreadyFound) {
results.add(translateResultPoints(result, xOffset, yOffset));
}
ResultPoint[] resultPoints = result.getResultPoints();
if (resultPoints == null || resultPoints.length == 0) {
return;
}
int width = image.getWidth();
int height = image.getHeight();
float minX = width;
float minY = height;
float maxX = 0.0f;
float maxY = 0.0f;
for (ResultPoint point : resultPoints) {
if (point == null) {
continue;
}
float x = point.getX();
float y = point.getY();
if (x < minX) {
minX = x;
}
if (y < minY) {
minY = y;
}
if (x > maxX) {
maxX = x;
}
if (y > maxY) {
maxY = y;
}
}
// Decode left of barcode
if (minX > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, (int) minX, height),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode above barcode
if (minY > MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, 0, width, (int) minY),
hints, results,
xOffset, yOffset,
currentDepth + 1);
}
// Decode right of barcode
if (maxX < width - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop((int) maxX, 0, width - (int) maxX, height),
hints, results,
xOffset + (int) maxX, yOffset,
currentDepth + 1);
}
// Decode below barcode
if (maxY < height - MIN_DIMENSION_TO_RECUR) {
doDecodeMultiple(image.crop(0, (int) maxY, width, height - (int) maxY),
hints, results,
xOffset, yOffset + (int) maxY,
currentDepth + 1);
}
}