/// <summary> Increments the Integer associated with a key by one.</summary> private static void increment(System.Collections.Hashtable table, ResultPoint key) { //System.Int32 value_Renamed = (System.Int32) table[key]; ////UPGRADE_TODO: The 'System.Int32' structure does not have an equivalent to NULL. "ms-help://MS.VSCC.v80/dv_commoner/local/redirect.htm?index='!DefaultContextWindowIndex'&keyword='jlca1291'" //table[key] = value_Renamed == null?INTEGERS[1]:INTEGERS[value_Renamed + 1]; // Redivivus.in Java to c# Porting update // 30/01/2010 // Added // START System.Int32 value_Renamed = 0; try { if (table.Count > 0) { value_Renamed = (System.Int32)table[key]; } } catch { value_Renamed = 0; } table[key] = value_Renamed == 0 ? INTEGERS[1] : INTEGERS[value_Renamed + 1]; //END }
/// <summary> <p>Detects a Data Matrix Code in an image.</p> /// /// </summary> /// <returns> {@link DetectorResult} encapsulating results of detecting a QR Code /// </returns> /// <throws> ReaderException if no Data Matrix Code can be found </throws> public DetectorResult detect() { ResultPoint[] cornerPoints = rectangleDetector.detect(); ResultPoint pointA = cornerPoints[0]; ResultPoint pointB = cornerPoints[1]; ResultPoint pointC = cornerPoints[2]; ResultPoint pointD = cornerPoints[3]; // Point A and D are across the diagonal from one another, // as are B and C. Figure out which are the solid black lines // by counting transitions System.Collections.ArrayList transitions = System.Collections.ArrayList.Synchronized(new System.Collections.ArrayList(4)); transitions.Add(transitionsBetween(pointA, pointB)); transitions.Add(transitionsBetween(pointA, pointC)); transitions.Add(transitionsBetween(pointB, pointD)); transitions.Add(transitionsBetween(pointC, pointD)); Collections.insertionSort(transitions, new ResultPointsAndTransitionsComparator()); // Sort by number of transitions. First two will be the two solid sides; last two // will be the two alternating black/white sides ResultPointsAndTransitions lSideOne = (ResultPointsAndTransitions)transitions[0]; ResultPointsAndTransitions lSideTwo = (ResultPointsAndTransitions)transitions[1]; // Figure out which point is their intersection by tallying up the number of times we see the // endpoints in the four endpoints. One will show up twice. System.Collections.Hashtable pointCount = System.Collections.Hashtable.Synchronized(new System.Collections.Hashtable()); increment(pointCount, lSideOne.From); increment(pointCount, lSideOne.To); increment(pointCount, lSideTwo.From); increment(pointCount, lSideTwo.To); ResultPoint maybeTopLeft = null; ResultPoint bottomLeft = null; ResultPoint maybeBottomRight = null; System.Collections.IEnumerator points = pointCount.Keys.GetEnumerator(); //UPGRADE_TODO: Method 'java.util.Enumeration.hasMoreElements' was converted to 'System.Collections.IEnumerator.MoveNext' which has a different behavior. "ms-help://MS.VSCC.v80/dv_commoner/local/redirect.htm?index='!DefaultContextWindowIndex'&keyword='jlca1073_javautilEnumerationhasMoreElements'" while (points.MoveNext()) { //UPGRADE_TODO: Method 'java.util.Enumeration.nextElement' was converted to 'System.Collections.IEnumerator.Current' which has a different behavior. "ms-help://MS.VSCC.v80/dv_commoner/local/redirect.htm?index='!DefaultContextWindowIndex'&keyword='jlca1073_javautilEnumerationnextElement'" ResultPoint point = (ResultPoint)points.Current; System.Int32 value_Renamed = (System.Int32)pointCount[point]; if (value_Renamed == 2) { bottomLeft = point; // this is definitely the bottom left, then -- end of two L sides } else { // Otherwise it's either top left or bottom right -- just assign the two arbitrarily now if (maybeTopLeft == null) { maybeTopLeft = point; } else { maybeBottomRight = point; } } } if (maybeTopLeft == null || bottomLeft == null || maybeBottomRight == null) { throw ReaderException.Instance; } // Bottom left is correct but top left and bottom right might be switched ResultPoint[] corners = new ResultPoint[] { maybeTopLeft, bottomLeft, maybeBottomRight }; // Use the dot product trick to sort them out ResultPoint.orderBestPatterns(corners); // Now we know which is which: ResultPoint bottomRight = corners[0]; bottomLeft = corners[1]; ResultPoint topLeft = corners[2]; // Which point didn't we find in relation to the "L" sides? that's the top right corner ResultPoint topRight; if (!pointCount.ContainsKey(pointA)) { topRight = pointA; } else if (!pointCount.ContainsKey(pointB)) { topRight = pointB; } else if (!pointCount.ContainsKey(pointC)) { topRight = pointC; } else { topRight = pointD; } // Next determine the dimension by tracing along the top or right side and counting black/white // transitions. Since we start inside a black module, we should see a number of transitions // equal to 1 less than the code dimension. Well, actually 2 less, because we are going to // end on a black module: // The top right point is actually the corner of a module, which is one of the two black modules // adjacent to the white module at the top right. Tracing to that corner from either the top left // or bottom right should work here. The number of transitions could be higher than it should be // due to noise. So we try both and take the min. int dimension = System.Math.Min(transitionsBetween(topLeft, topRight).Transitions, transitionsBetween(bottomRight, topRight).Transitions); if ((dimension & 0x01) == 1) { // it can't be odd, so, round... up? dimension++; } dimension += 2; BitMatrix bits = sampleGrid(image, topLeft, bottomLeft, bottomRight, dimension); return(new DetectorResult(bits, new ResultPoint[] { pointA, pointB, pointC, pointD })); }
internal virtual FinderPatternInfo find(System.Collections.Hashtable hints) { bool tryHarder = hints != null && hints.ContainsKey(DecodeHintType.TRY_HARDER); int maxI = image.Height; int maxJ = image.Width; // We are looking for black/white/black/white/black modules in // 1:1:3:1:1 ratio; this tracks the number of such modules seen so far // Let's assume that the maximum version QR Code we support takes up 1/4 the height of the // image, and then account for the center being 3 modules in size. This gives the smallest // number of pixels the center could be, so skip this often. When trying harder, look for all // QR versions regardless of how dense they are. int iSkip = (3 * maxI) / (4 * MAX_MODULES); if (iSkip < MIN_SKIP || tryHarder) { iSkip = MIN_SKIP; } bool done = false; int[] stateCount = new int[5]; for (int i = iSkip - 1; i < maxI && !done; i += iSkip) { // Get a row of black/white values stateCount[0] = 0; stateCount[1] = 0; stateCount[2] = 0; stateCount[3] = 0; stateCount[4] = 0; int currentState = 0; for (int j = 0; j < maxJ; j++) { if (image.get_Renamed(j, i)) { // Black pixel if ((currentState & 1) == 1) { // Counting white pixels currentState++; } stateCount[currentState]++; } else { // White pixel if ((currentState & 1) == 0) { // Counting black pixels if (currentState == 4) { // A winner? if (foundPatternCross(stateCount)) { // Yes bool confirmed = handlePossibleCenter(stateCount, i, j); if (confirmed) { // Start examining every other line. Checking each line turned out to be too // expensive and didn't improve performance. iSkip = 2; if (hasSkipped) { done = haveMultiplyConfirmedCenters(); } else { int rowSkip = findRowSkip(); if (rowSkip > stateCount[2]) { // Skip rows between row of lower confirmed center // and top of presumed third confirmed center // but back up a bit to get a full chance of detecting // it, entire width of center of finder pattern // Skip by rowSkip, but back off by stateCount[2] (size of last center // of pattern we saw) to be conservative, and also back off by iSkip which // is about to be re-added i += rowSkip - stateCount[2] - iSkip; j = maxJ - 1; } } } else { // Advance to next black pixel do { j++; }while (j < maxJ && !image.get_Renamed(j, i)); j--; // back up to that last white pixel } // Clear state to start looking again currentState = 0; stateCount[0] = 0; stateCount[1] = 0; stateCount[2] = 0; stateCount[3] = 0; stateCount[4] = 0; } else { // No, shift counts back by two stateCount[0] = stateCount[2]; stateCount[1] = stateCount[3]; stateCount[2] = stateCount[4]; stateCount[3] = 1; stateCount[4] = 0; currentState = 3; } } else { stateCount[++currentState]++; } } else { // Counting white pixels stateCount[currentState]++; } } } if (foundPatternCross(stateCount)) { bool confirmed = handlePossibleCenter(stateCount, i, maxJ); if (confirmed) { iSkip = stateCount[0]; if (hasSkipped) { // Found a third one done = haveMultiplyConfirmedCenters(); } } } } FinderPattern[] patternInfo = selectBestPatterns(); ResultPoint.orderBestPatterns(patternInfo); return(new FinderPatternInfo(patternInfo)); }
public FinderPatternInfo[] findMulti(System.Collections.Hashtable hints) { bool tryHarder = hints != null && hints.ContainsKey(DecodeHintType.TRY_HARDER); BitMatrix image = Image; int maxI = image.Height; int maxJ = image.Width; // We are looking for black/white/black/white/black modules in // 1:1:3:1:1 ratio; this tracks the number of such modules seen so far // Let's assume that the maximum version QR Code we support takes up 1/4 the height of the // image, and then account for the center being 3 modules in size. This gives the smallest // number of pixels the center could be, so skip this often. When trying harder, look for all // QR versions regardless of how dense they are. //UPGRADE_WARNING: Data types in Visual C# might be different. Verify the accuracy of narrowing conversions. "ms-help://MS.VSCC.v80/dv_commoner/local/redirect.htm?index='!DefaultContextWindowIndex'&keyword='jlca1042'" int iSkip = (int)(maxI / (MAX_MODULES * 4.0f) * 3); if (iSkip < MIN_SKIP || tryHarder) { iSkip = MIN_SKIP; } int[] stateCount = new int[5]; for (int i = iSkip - 1; i < maxI; i += iSkip) { // Get a row of black/white values stateCount[0] = 0; stateCount[1] = 0; stateCount[2] = 0; stateCount[3] = 0; stateCount[4] = 0; int currentState = 0; for (int j = 0; j < maxJ; j++) { if (image.get_Renamed(j, i)) { // Black pixel if ((currentState & 1) == 1) { // Counting white pixels currentState++; } stateCount[currentState]++; } else { // White pixel if ((currentState & 1) == 0) { // Counting black pixels if (currentState == 4) { // A winner? if (foundPatternCross(stateCount)) { // Yes bool confirmed = handlePossibleCenter(stateCount, i, j); if (!confirmed) { do { // Advance to next black pixel j++; }while (j < maxJ && !image.get_Renamed(j, i)); j--; // back up to that last white pixel } // Clear state to start looking again currentState = 0; stateCount[0] = 0; stateCount[1] = 0; stateCount[2] = 0; stateCount[3] = 0; stateCount[4] = 0; } else { // No, shift counts back by two stateCount[0] = stateCount[2]; stateCount[1] = stateCount[3]; stateCount[2] = stateCount[4]; stateCount[3] = 1; stateCount[4] = 0; currentState = 3; } } else { stateCount[++currentState]++; } } else { // Counting white pixels stateCount[currentState]++; } } } // for j=... if (foundPatternCross(stateCount)) { handlePossibleCenter(stateCount, i, maxJ); } // end if foundPatternCross } // for i=iSkip-1 ... FinderPattern[][] patternInfo = selectBestPatterns(); System.Collections.ArrayList result = System.Collections.ArrayList.Synchronized(new System.Collections.ArrayList(10)); for (int i = 0; i < patternInfo.Length; i++) { FinderPattern[] pattern = patternInfo[i]; ResultPoint.orderBestPatterns(pattern); result.Add(new FinderPatternInfo(pattern)); } if ((result.Count == 0)) { return(EMPTY_RESULT_ARRAY); } else { FinderPatternInfo[] resultArray = new FinderPatternInfo[result.Count]; for (int i = 0; i < result.Count; i++) { resultArray[i] = (FinderPatternInfo)result[i]; } return(resultArray); } }