* OneDReader.cpp
* ZXing
*
- * Created by Lukasz Warchol on 10-01-15.
* Copyright 2010 ZXing authors All rights reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
#include "OneDReader.h"
#include <zxing/ReaderException.h>
+#include <zxing/oned/OneDResultPoint.h>
#include <math.h>
#include <limits.h>
namespace zxing {
namespace oned {
using namespace std;
-
+
OneDReader::OneDReader() {
}
-
- Ref<Result> OneDReader::decode(Ref<BinaryBitmap> image) {
- try {
- return doDecode(image);
- }catch (ReaderException re) {
- if (false /*tryHarder && image.isRotateSupported()*/) {
- /*
- BinaryBitmap rotatedImage = image.rotateCounterClockwise();
- Result result = doDecode(rotatedImage, hints);
+
+ Ref<Result> OneDReader::decode(Ref<BinaryBitmap> image, DecodeHints hints) {
+ Ref<Result> result = doDecode(image, hints);
+ if (result.empty() && hints.getTryHarder() && image->isRotateSupported()) {
+ Ref<BinaryBitmap> rotatedImage(image->rotateCounterClockwise());
+ result = doDecode(rotatedImage, hints);
+ if (!result.empty()) {
+ /*
// Record that we found it rotated 90 degrees CCW / 270 degrees CW
Hashtable metadata = result.getResultMetadata();
int orientation = 270;
((Integer) metadata.get(ResultMetadataType.ORIENTATION)).intValue()) % 360;
}
result.putMetadata(ResultMetadataType.ORIENTATION, new Integer(orientation));
- // Update result points
- ResultPoint[] points = result.getResultPoints();
- 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 re;
+ // Update result points
+ std::vector<Ref<ResultPoint> > points (result->getResultPoints());
+ int height = rotatedImage->getHeight();
+ for (size_t i = 0; i < points.size(); i++) {
+ points[i].reset(new OneDResultPoint(height - points[i]->getY() - 1, points[i]->getX()));
+ }
}
- }
+ }
+ if (result.empty()) {
+ throw ReaderException("");
+ }
+ return result;
}
-
- Ref<Result> OneDReader::doDecode(Ref<BinaryBitmap> image){
+
+ Ref<Result> OneDReader::doDecode(Ref<BinaryBitmap> image, DecodeHints hints) {
int width = image->getWidth();
int height = image->getHeight();
Ref<BitArray> row(new BitArray(width));
-// BitArray row = new BitArray(width);
-
int middle = height >> 1;
- bool tryHarder = true;//hints != null && hints.containsKey(DecodeHintType.TRY_HARDER);
- int rowStep = (int)fmax(1, height >> (tryHarder ? 7 : 4));
+ bool tryHarder = hints.getTryHarder();
+ int rowStep = (int)fmax(1, height >> (tryHarder ? 8 : 5));
int maxLines;
if (tryHarder) {
maxLines = height; // Look at the whole image, not just the center
} else {
- maxLines = 9; // Nine rows spaced 1/16 apart is roughly the middle half of the image
+ 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;
bool isAbove = (x & 0x01) == 0; // i.e. is x even?
// 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 (ReaderException re) {
+ } catch (ReaderException re) {
continue;
+ } catch (IllegalArgumentException re) {
+ 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
}
- try {
- // Look for a barcode
- Ref<Result> result = decodeRow(rowNumber, row);
- // We found our barcode
- if (attempt == 1) {
- // // But it was upside down, so note that
- // result.putMetadata(ResultMetadataType.ORIENTATION, new Integer(180));
- // // And remember to flip the result points horizontally.
- // ResultPoint[] points = result.getResultPoints();
- // 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
- }
+
+ // Look for a barcode
+ Ref<Result> result = decodeRow(rowNumber, row);
+ // We found our barcode
+ if (!result.empty()) {
+ // // But it was upside down, so note that
+ // result.putMetadata(ResultMetadataType.ORIENTATION, new Integer(180));
+ // // And remember to flip the result points horizontally.
+ std::vector<Ref<ResultPoint> > points(result->getResultPoints());
+ // if there's exactly two points (which there should be), flip the x coordinate
+ // if there's not exactly 2, I don't know what do do with it
+ if (points.size() == 2) {
+ Ref<ResultPoint> pointZero(new OneDResultPoint(width - points[0]->getX() - 1,
+ points[0]->getY()));
+ points[0] = pointZero;
+
+ Ref<ResultPoint> pointOne(new OneDResultPoint(width - points[1]->getX() - 1,
+ points[1]->getY()));
+ points[1] = pointOne;
+
+ result.reset(new Result(result->getText(), result->getRawBytes(), points,
+ result->getBarcodeFormat()));
+ }
+ return result;
+ }
}
}
- throw ReaderException("");
+ return Ref<Result>();
}
-
- int OneDReader::patternMatchVariance(int counters[], int countersSize, const int pattern[], int maxIndividualVariance) {
+
+ unsigned int OneDReader::patternMatchVariance(int counters[], int countersSize,
+ const int pattern[], int maxIndividualVariance) {
int numCounters = countersSize;
- int total = 0;
- int patternLength = 0;
+ unsigned int total = 0;
+ unsigned int patternLength = 0;
for (int i = 0; i < numCounters; i++) {
total += counters[i];
patternLength += pattern[i];
// We're going to fake floating-point math in integers. We just need to use more bits.
// Scale up patternLength so that intermediate values below like scaledCounter will have
// more "significant digits"
- int unitBarWidth = (total << INTEGER_MATH_SHIFT) / patternLength;
+ unsigned int unitBarWidth = (total << INTEGER_MATH_SHIFT) / patternLength;
maxIndividualVariance = (maxIndividualVariance * unitBarWidth) >> INTEGER_MATH_SHIFT;
-
- int totalVariance = 0;
+
+ unsigned int totalVariance = 0;
for (int x = 0; x < numCounters; x++) {
int counter = counters[x] << INTEGER_MATH_SHIFT;
int scaledPattern = pattern[x] * unitBarWidth;
}
return totalVariance / total;
}
-
- void OneDReader::recordPattern(Ref<BitArray> row, int start, int counters[], int countersCount){
+
+ bool OneDReader::recordPattern(Ref<BitArray> row, int start, int counters[], int countersCount) {
int numCounters = countersCount;//sizeof(counters) / sizeof(int);
for (int i = 0; i < numCounters; i++) {
counters[i] = 0;
}
int end = row->getSize();
if (start >= end) {
- throw ReaderException("recordPattern: start >= end");
+ return false;
}
bool isWhite = !row->get(start);
int counterPosition = 0;
// If we read fully the last section of pixels and filled up our counters -- or filled
// the last counter but ran off the side of the image, OK. Otherwise, a problem.
if (!(counterPosition == numCounters || (counterPosition == numCounters - 1 && i == end))) {
- throw ReaderException("recordPattern");
+ return false;
}
+ return true;
}
-
+
OneDReader::~OneDReader() {
}
}