private void WriteDataChunksUncompressed()
{
// First setup some variables we're going to use later on so we can calculate how big of byte[] we need
// to store the entire PNG file in so we only keep a single copy of the data in memory.
// Figure out how much image data we're going to have:
// H * W * (number of bytes in an ARGB value) + H to account for the filter byte in PNG files
int dataLength = _bitmap.PixelWidth * _bitmap.PixelHeight * 4 + _bitmap.PixelHeight;
// Variables for the number of PNG blocks and how big the last block is going to be.
int blockCount;
int lastBlockSize;
// We could have an exactly even count of blocks (ie MaxBlockSize * x), but that seems unlikely.
// If we don't, then add one for the remainder of the data and figure out how much data will be
// left.
if ( ( dataLength % MaxBlockSize ) == 0 )
{
blockCount = dataLength / MaxBlockSize;
lastBlockSize = MaxBlockSize;
}
else
{
blockCount = ( dataLength / MaxBlockSize ) + 1;
lastBlockSize = dataLength - ( MaxBlockSize * ( blockCount - 1 ) );
}
// The size of the PNG file will be:
// 2 header bytes +
// ( blockCount - 1 ) *
// (
// 1 last block byte +
// 2 block size bytes +
// 2 block size one's complement bytes +
// maxBlockSize ) +
// (
// 1 last block byte +
// 2 block size bytes +
// 2 block size one's complement bytes +
// lastBlockSize ) +
// 4 Adler32 bytes +
//
// = 2 + ((blockCount-1)*(5+MaxBlockSize)) + (5+lastBlockSize) + 4
// = 11 + ((blockCount-1)*(5+MaxBlockSize)) + lastBlockSize
//
int pngLength;
pngLength = 11 + ( ( blockCount - 1 ) * ( 5 + MaxBlockSize ) ) + lastBlockSize;
// Make a buffer to store the PNG in.
byte[] data = new byte[pngLength];
// Write zlib headers.
data[0] = 0x78;
data[1] = 0xDA;
// zlib compression uses Adler32 CRCs instead of CRC32s, so setup on up to calculate.
Adler32 crcCode = new Adler32();
crcCode.Reset();
// Setup some variables to use in the loop.
var blockRemainder = 0; // How much of the current block we have left, 0 to start so we write the block header out on the first block.
var currentBlock = 0; // The current block we're working on, start with 0 as we increment in the first pass thorugh.
var dataPointer = 2; // A pointer to where we are in the data array, start at 2 as we 'wrote' two bytes a few lines ago.
var pixelSource = 0; // The current pixel we're working on from the image.
byte[] pixel = new byte[4]; // Temporary storage to store the current pixel in as a byte array.
// This is the main logic loop, we're going to be doing a lot of work so stick with me...
// The loop has three parts to it:
// 1. looping through each row (y)
// 2. looping through each pixel in the row (x)
// 3. looping through each byte of the pixel (z)
// Loop thorough each row in the image.
for ( int y = 0; y < _bitmap.PixelHeight; y++ )
{
// This code appears twice, once here and once in the pixel byte loop (loop 3).
// It checks to see if we're at the boundry for the PNG block and if so writes
// out a new block header. It get executed on the first time through to setup
// the first block but is unlikly to get executed again as it would mean the
// block boundry is at a row boundry, which seems unlikly.
if ( blockRemainder == 0 )
{
// Setup a temporary byte array to store the block size in.
byte[] tempBytes = new byte[2];
// Increment the current block count.
currentBlock++;
// Figure out the current block size and if we're at the last block, write
// out and 1 to let the zlib decompressor know. By default, use the MaxBlockSize.
int length = MaxBlockSize;
if ( currentBlock == blockCount )
{
length = lastBlockSize;
data[dataPointer] = 0x01;
}
else
{
data[dataPointer] = 0x00;
}
// Each and every time we write something to the data array, increment the pointer.
dataPointer++;
// Write the block length out.
tempBytes = BitConverter.GetBytes( length );
data[dataPointer + 0] = tempBytes[0];
data[dataPointer + 1] = tempBytes[1];
dataPointer += 2;
// Write one's compliment of length for error checking.
tempBytes = BitConverter.GetBytes( (ushort) ~length );
data[dataPointer + 0] = tempBytes[0];
data[dataPointer + 1] = tempBytes[1];
dataPointer += 2;
// Reset the remaining block size to the next block's length.
blockRemainder = length;
}
// Set the filter byte to 0, not really required as C# initalizes the byte array to 0 by default, but here for clarity.
data[dataPointer] = 0;
// Add the current byte to the running Adler32 value, note we ONLY add the filter byte and the pixel bytes to the
// Adler32 CRC, all other header and block header bytes are execluded from the CRC.
crcCode.Add( data, 1, (uint) dataPointer );
// Increment the data pointer and decrement the remain block value.
dataPointer++;
blockRemainder--;
// Loop thorough each pixel in the row, you have to do this as the source format and destination format may be different.
for ( int x = 0; x < _bitmap.PixelWidth; x++ )
{
// Data is in RGBA format but source may not be
pixel = BitConverter.GetBytes( _bitmap.Pixels[pixelSource] );
// Loop through the 4 bytes of the pixel and 'write' them to the data array.
for ( int z = 0; z < 4; z++ )
{
// This is the second appearance of this code code.
// It checks to see if we're at the boundry for the PNG block and if so writes
// out a new block header.
if ( blockRemainder == 0 )
{
// Setup a temporary byte array to store the block size in.
byte[] tempBytes = new byte[2];
// Increment the current block count.
currentBlock++;
// Figure out the current block size and if we're at the last block, write
// out and 1 to let the zlib decompressor know. By default, use the MaxBlockSize.
int length = MaxBlockSize;
if ( currentBlock == blockCount )
{
length = lastBlockSize;
data[dataPointer] = 0x01;
}
else
{
data[dataPointer] = 0x00;
}
// Each and every time we write something to the data array, increment the pointer.
dataPointer++;
// Write the block length out.
tempBytes = BitConverter.GetBytes( length );
data[dataPointer + 0] = tempBytes[0];
data[dataPointer + 1] = tempBytes[1];
dataPointer += 2;
// Write one's compliment of length for error checking.
tempBytes = BitConverter.GetBytes( (ushort) ~length );
data[dataPointer + 0] = tempBytes[0];
data[dataPointer + 1] = tempBytes[1];
dataPointer += 2;
// Reset the remaining block size to the next block's length.
blockRemainder = length;
}
// Store the pixel's byte in to the data array. We use the WBByteOrder array to ensure
// we have the write order of bytes to store in the PNG file.
if ( z != 3 && pixel[WBByteOrder[3]] != 0 && pixel[WBByteOrder[3]] != 255 )
{
// Calculate unmultiplied pixel value from premultiplied value (Windows Phone always uses premultiplied ARGB32)
data[dataPointer] = (byte) ( ( 255 * pixel[WBByteOrder[z]] ) / pixel[WBByteOrder[3]] );
}
else
{
// Alpha channel or no need to unpremultiply
data[dataPointer] = pixel[WBByteOrder[z]];
}
// Add the current byte to the running Adler32 value, note we ONLY add the filter byte and the pixel bytes to the
// Adler32 CRC, all other header and block header bytes are execluded from the CRC.
crcCode.Add( data, 1, (uint) dataPointer );
// Increment the data pointer and decrement the remain block value.
dataPointer++;
blockRemainder--;
}
// Increment where we start writting the next pixel and where we get the next pixel from.
pixelSource++;
}
}
// Whew, wipe that brow, we're done all the complex bits now!
// Write the Adler32 CRC out, but reverse the order of the bytes to match the zlib spec.
pixel = BitConverter.GetBytes( crcCode.CurrentValue );
data[dataPointer + 0] = pixel[3];
data[dataPointer + 1] = pixel[2];
data[dataPointer + 2] = pixel[1];
data[dataPointer + 3] = pixel[0];
// Yes, yes, I know I said "Each and every time we write something to the data array, increment the pointer."
// but we're done with it now so I'm not going to bother ;)
// Write the entire PNG data chunk out to the file stream.
WriteChunk( PngChunkTypes.Data, data, 0, pngLength );
}