// Helper function for applyMaskPenaltyRule1. We need this for doing this calculation in both
// vertical and horizontal orders respectively.
private static int ApplyMaskPenaltyRule1Internal(ByteMatrix matrix, bool isHorizontal)
{
int penalty = 0;
int numSameBitCells = 0;
int prevBit = -1;
// Horizontal mode:
// for (int i = 0; i < matrix.height(); ++i) {
// for (int j = 0; j < matrix.width(); ++j) {
// int bit = matrix.get(i, j);
// Vertical mode:
// for (int i = 0; i < matrix.width(); ++i) {
// for (int j = 0; j < matrix.height(); ++j) {
// int bit = matrix.get(j, i);
int iLimit = isHorizontal ? matrix.GetHeight() : matrix.GetWidth();
int jLimit = isHorizontal ? matrix.GetWidth() : matrix.GetHeight();
byte[][] array = matrix.GetArray();
for (int i = 0; i < iLimit; ++i)
{
for (int j = 0; j < jLimit; ++j)
{
int bit = isHorizontal ? array[i][j] : array[j][i];
if (bit == prevBit)
{
numSameBitCells += 1;
// Found five repetitive cells with the same color (bit).
// We'll give penalty of 3.
if (numSameBitCells == 5)
{
penalty += 3;
}
else
{
if (numSameBitCells > 5)
{
// After five repetitive cells, we'll add the penalty one
// by one.
penalty += 1;
}
}
}
else
{
numSameBitCells = 1;
// Include the cell itself.
prevBit = bit;
}
}
numSameBitCells = 0;
}
// Clear at each row/column.
return(penalty);
}
// Apply mask penalty rule 3 and return the penalty. Find consecutive cells of 00001011101 or
// 10111010000, and give penalty to them. If we find patterns like 000010111010000, we give
// penalties twice (i.e. 40 * 2).
public static int ApplyMaskPenaltyRule3(ByteMatrix matrix)
{
int penalty = 0;
byte[][] array = matrix.GetArray();
int width = matrix.GetWidth();
int height = matrix.GetHeight();
for (int y = 0; y < height; ++y)
{
for (int x = 0; x < width; ++x)
{
// Tried to simplify following conditions but failed.
if (x + 6 < width && array[y][x] == 1 && array[y][x + 1] == 0 && array[y][x + 2] == 1 && array[y][x + 3] ==
1 && array[y][x + 4] == 1 && array[y][x + 5] == 0 && array[y][x + 6] == 1 && ((x + 10 < width && array
[y][x + 7] == 0 && array[y][x + 8] == 0 && array[y][x + 9] == 0 && array[y][x + 10] == 0) || (x - 4 >=
0 && array[y][x - 1] == 0 && array[y][x - 2] == 0 && array[y][x - 3] == 0 && array[y][x - 4] == 0)))
{
penalty += 40;
}
if (y + 6 < height && array[y][x] == 1 && array[y + 1][x] == 0 && array[y + 2][x] == 1 && array[y + 3][x]
== 1 && array[y + 4][x] == 1 && array[y + 5][x] == 0 && array[y + 6][x] == 1 && ((y + 10 < height && array
[y + 7][x] == 0 && array[y + 8][x] == 0 && array[y + 9][x] == 0 && array[y + 10][x] == 0) || (y - 4 >=
0 && array[y - 1][x] == 0 && array[y - 2][x] == 0 && array[y - 3][x] == 0 && array[y - 4][x] == 0)))
{
penalty += 40;
}
}
}
return(penalty);
}
/// <summary>Check the validity of all member variables</summary>
/// <returns>true if all variables are valid, false otherwise</returns>
public bool IsValid()
{
return(mode != null && ecLevel != null && version != -1 && matrixWidth != -1 && maskPattern != -1 && numTotalBytes
!= -1 && numDataBytes != -1 && numECBytes != -1 && numRSBlocks != -1 && IsValidMaskPattern(maskPattern
) && numTotalBytes == numDataBytes + numECBytes && matrix != null && matrixWidth == matrix.GetWidth() &&
matrix.GetWidth() == matrix.GetHeight());
}
// Apply mask penalty rule 4 and return the penalty. Calculate the ratio of dark cells and give
// penalty if the ratio is far from 50%. It gives 10 penalty for 5% distance. Examples:
// - 0% => 100
// - 40% => 20
// - 45% => 10
// - 50% => 0
// - 55% => 10
// - 55% => 20
// - 100% => 100
public static int ApplyMaskPenaltyRule4(ByteMatrix matrix)
{
int numDarkCells = 0;
byte[][] array = matrix.GetArray();
int width = matrix.GetWidth();
int height = matrix.GetHeight();
for (int y = 0; y < height; ++y)
{
for (int x = 0; x < width; ++x)
{
if (array[y][x] == 1)
{
numDarkCells += 1;
}
}
}
int numTotalCells = matrix.GetHeight() * matrix.GetWidth();
double darkRatio = (double)numDarkCells / numTotalCells;
return(Math.Abs((int)(darkRatio * 100 - 50)) / 5 * 10);
}
/// <summary>Check the validity of all member variables</summary>
/// <returns>true if all variables are valid, false otherwise</returns>
public bool IsValid()
{
return
// First check if all version are not uninitialized.
(mode != null && ecLevel != null && version != -1 && matrixWidth != -1 && maskPattern != -1 && numTotalBytes
!= -1 && numDataBytes != -1 && numECBytes != -1 && numRSBlocks != -1 &&
// Then check them in other ways..
IsValidMaskPattern(maskPattern) && numTotalBytes == numDataBytes + numECBytes &&
// ByteMatrix stuff.
matrix != null && matrixWidth == matrix.GetWidth() &&
// Must be square.
// See 7.3.1 of JISX0510:2004 (p.5).
matrix.GetWidth() == matrix.GetHeight());
}
// Apply mask penalty rule 2 and return the penalty. Find 2x2 blocks with the same color and give
// penalty to them.
public static int ApplyMaskPenaltyRule2(ByteMatrix matrix)
{
int penalty = 0;
byte[][] array = matrix.GetArray();
int width = matrix.GetWidth();
int height = matrix.GetHeight();
for (int y = 0; y < height - 1; ++y)
{
for (int x = 0; x < width - 1; ++x)
{
int value = array[y][x];
if (value == array[y][x + 1] && value == array[y + 1][x] && value == array[y + 1][x + 1])
{
penalty += 3;
}
}
}
return(penalty);
}
// Note that the input matrix uses 0 == white, 1 == black, while the output matrix uses
// 0 == black, 255 == white (i.e. an 8 bit greyscale bitmap).
private static ByteMatrix RenderResult(QRCode code, int width, int height)
{
ByteMatrix input = code.GetMatrix();
int inputWidth = input.GetWidth();
int inputHeight = input.GetHeight();
int qrWidth = inputWidth + (QUIET_ZONE_SIZE << 1);
int qrHeight = inputHeight + (QUIET_ZONE_SIZE << 1);
int outputWidth = Math.Max(width, qrWidth);
int outputHeight = Math.Max(height, qrHeight);
int multiple = Math.Min(outputWidth / qrWidth, outputHeight / qrHeight);
// Padding includes both the quiet zone and the extra white pixels to accommodate the requested
// dimensions. For example, if input is 25x25 the QR will be 33x33 including the quiet zone.
// If the requested size is 200x160, the multiple will be 4, for a QR of 132x132. These will
// handle all the padding from 100x100 (the actual QR) up to 200x160.
int leftPadding = (outputWidth - (inputWidth * multiple)) / 2;
int topPadding = (outputHeight - (inputHeight * multiple)) / 2;
ByteMatrix output = new ByteMatrix(outputWidth, outputHeight);
byte[][] outputArray = output.GetArray();
// We could be tricky and use the first row in each set of multiple as the temporary storage,
// instead of allocating this separate array.
byte[] row = new byte[outputWidth];
// 1. Write the white lines at the top
for (int y = 0; y < topPadding; y++)
{
SetRowColor(outputArray[y], (byte)255);
}
// 2. Expand the QR image to the multiple
byte[][] inputArray = input.GetArray();
for (int y = 0; y < inputHeight; y++)
{
// a. Write the white pixels at the left of each row
for (int x = 0; x < leftPadding; x++)
{
row[x] = (byte)255;
}
// b. Write the contents of this row of the barcode
int offset = leftPadding;
for (int x = 0; x < inputWidth; x++)
{
byte value = (inputArray[y][x] == 1) ? (byte)0 : (byte)255;
for (int z = 0; z < multiple; z++)
{
row[offset + z] = value;
}
offset += multiple;
}
// c. Write the white pixels at the right of each row
offset = leftPadding + (inputWidth * multiple);
for (int x = offset; x < outputWidth; x++)
{
row[x] = (byte)255;
}
// d. Write the completed row multiple times
offset = topPadding + (y * multiple);
for (int z = 0; z < multiple; z++)
{
Array.Copy(row, 0, outputArray[offset + z], 0, outputWidth);
}
}
// 3. Write the white lines at the bottom
int offset_1 = topPadding + (inputHeight * multiple);
for (int y = offset_1; y < outputHeight; y++)
{
SetRowColor(outputArray[y], (byte)255);
}
return(output);
}
