private void InitWithCGImage(CGImage image, All filter)
{
int width, height, i;
CGContext context = null;
IntPtr data;
CGColorSpace colorSpace;
IntPtr tempData;
bool hasAlpha;
CGImageAlphaInfo info;
CGAffineTransform transform;
Size imageSize;
SurfaceFormat pixelFormat;
//bool sizeToFit = false;
if (image == null) {
throw new ArgumentException (" NSImage is invalid! " );
}
info = image.AlphaInfo;
hasAlpha = ((info == CGImageAlphaInfo.PremultipliedLast) || (info == CGImageAlphaInfo.PremultipliedFirst) || (info == CGImageAlphaInfo.Last) || (info == CGImageAlphaInfo.First) ? true : false);
if (image.ColorSpace != null) {
if (hasAlpha) {
pixelFormat = SurfaceFormat.Color;
} else {
pixelFormat = SurfaceFormat.Color;
}
} else {
pixelFormat = SurfaceFormat.Alpha8;
}
imageSize = new Size (image.Width,image.Height);
transform = CGAffineTransform.MakeIdentity ();
width = imageSize.Width;
// Take out the width and height adjustments for power of 2
// If not then GetData and SetData is messed up.
// The Mac opengl version supports non power of 2 textures
// so we do not have to make them so
// if ((width != 1) && ((width & (width - 1)) != 0)) {
// i = 1;
// while ((sizeToFit ? 2 * i : i) < width)
// i *= 2;
// width = i;
// }
height = imageSize.Height;
// The Mac opengl version supports non power of 2 textures
// so we do not have to make them so
// if ((height != 1) && ((height & (height - 1)) != 0)) {
// i = 1;
// while ((sizeToFit ? 2 * i : i) < height)
// i *= 2;
// height = i;
// }
// TODO: kMaxTextureSize = 1024
// while ((width > 1024) || (height > 1024)) {
// width /= 2;
// height /= 2;
// transform = CGAffineTransform.MakeScale (0.5f, 0.5f);
// imageSize.Width /= 2;
// imageSize.Height /= 2;
// }
float size = Math.Max(width,height);
if(size > 1024)
{
float ratio = 1024 / size;
width = (int)(width * ratio);
height = (int)(height * ratio);
transform = CGAffineTransform.MakeScale(ratio, ratio);
imageSize.Width = (int)(imageSize.Width * ratio);
imageSize.Height = (int)(imageSize.Height * ratio);;
}
switch (pixelFormat) {
case SurfaceFormat.Color:
colorSpace = CGColorSpace.CreateDeviceRGB ();
data = Marshal.AllocHGlobal (height * width * 4);
context = new CGBitmapContext (data, width, height, 8, 4 * width, colorSpace,CGImageAlphaInfo.PremultipliedLast);
colorSpace.Dispose ();
break;
case SurfaceFormat.Alpha8:
data = Marshal.AllocHGlobal (height * width);
context = new CGBitmapContext (data, width, height, 8, width, null, CGImageAlphaInfo.Only);
break;
default:
throw new NotSupportedException ("Invalid pixel format");
}
context.ClearRect (new RectangleF (0,0,width,height));
context.TranslateCTM (0, height - imageSize.Height);
if (!transform.IsIdentity) {
context.ConcatCTM (transform);
}
context.DrawImage (new RectangleF (0, 0, image.Width, image.Height), image);
//Convert "RRRRRRRRRGGGGGGGGBBBBBBBBAAAAAAAA" to "RRRRRGGGGGGBBBBB"
/*
if(pixelFormat == SurfaceFormat.Rgb32) {
tempData = Marshal.AllocHGlobal(height * width * 2);
int d32;
short d16;
int inPixel32Count=0,outPixel16Count=0;
for(i = 0; i < width * height; ++i, inPixel32Count+=sizeof(int))
{
d32 = Marshal.ReadInt32(data,inPixel32Count);
short R = (short)((((d32 >> 0) & 0xFF) >> 3) << 11);
short G = (short)((((d32 >> 8) & 0xFF) >> 2) << 5);
short B = (short)((((d32 >> 16) & 0xFF) >> 3) << 0);
d16 = (short) (R | G | B);
Marshal.WriteInt16(tempData,outPixel16Count,d16);
outPixel16Count += sizeof(short);
}
Marshal.FreeHGlobal(data);
data = tempData;
}
*/
InitWithData (data, pixelFormat, width, height, imageSize, filter);
context.Dispose ();
Marshal.FreeHGlobal (data);
}
private void InitWithCGImage (CGImage image, All filter)
{
int width, height, i;
CGContext context = null;
IntPtr data;
CGColorSpace colorSpace;
IntPtr tempData;
bool hasAlpha;
CGImageAlphaInfo info;
CGAffineTransform transform;
Size imageSize;
SurfaceFormat pixelFormat;
bool sizeToFit = false;
if (image == null) {
throw new ArgumentException (" NSImage is invalid! " );
}
info = image.AlphaInfo;
hasAlpha = ((info == CGImageAlphaInfo.PremultipliedLast) || (info == CGImageAlphaInfo.PremultipliedFirst) || (info == CGImageAlphaInfo.Last) || (info == CGImageAlphaInfo.First) ? true : false);
if (image.ColorSpace != null) {
if (hasAlpha) {
pixelFormat = SurfaceFormat.Rgba32;
} else {
pixelFormat = SurfaceFormat.Rgb32;
}
} else {
pixelFormat = SurfaceFormat.Alpha8;
}
imageSize = new Size (image.Width,image.Height);
transform = CGAffineTransform.MakeIdentity ();
width = imageSize.Width;
if ((width != 1) && ((width & (width - 1)) != 0)) {
i = 1;
while ((sizeToFit ? 2 * i : i) < width)
i *= 2;
width = i;
}
height = imageSize.Height;
if ((height != 1) && ((height & (height - 1)) != 0)) {
i = 1;
while ((sizeToFit ? 2 * i : i) < height)
i *= 2;
height = i;
}
// TODO: kMaxTextureSize = 1024
while ((width > 1024) || (height > 1024)) {
width /= 2;
height /= 2;
transform = CGAffineTransform.MakeScale (0.5f, 0.5f);
imageSize.Width /= 2;
imageSize.Height /= 2;
}
switch (pixelFormat) {
case SurfaceFormat.Rgba32:
colorSpace = CGColorSpace.CreateDeviceRGB ();
data = Marshal.AllocHGlobal (height * width * 4);
context = new CGBitmapContext (data, width, height, 8, 4 * width, colorSpace,CGImageAlphaInfo.PremultipliedLast);
colorSpace.Dispose ();
break;
case SurfaceFormat.Rgb32:
colorSpace = CGColorSpace.CreateDeviceRGB ();
data = Marshal.AllocHGlobal (height * width * 4);
context = new CGBitmapContext (data, width, height, 8, 4 * width, colorSpace, CGImageAlphaInfo.NoneSkipLast);
colorSpace.Dispose ();
break;
case SurfaceFormat.Alpha8:
data = Marshal.AllocHGlobal (height * width);
context = new CGBitmapContext (data, width, height, 8, width, null, CGImageAlphaInfo.Only);
break;
default:
throw new NotSupportedException ("Invalid pixel format");
}
context.ClearRect (new RectangleF (0,0,width,height));
context.TranslateCTM (0, height - imageSize.Height);
if (!transform.IsIdentity) {
context.ConcatCTM (transform);
}
context.DrawImage (new RectangleF (0, 0, image.Width, image.Height), image);
//Convert "RRRRRRRRRGGGGGGGGBBBBBBBBAAAAAAAA" to "RRRRRGGGGGGBBBBB"
if (pixelFormat == SurfaceFormat.Rgb32) {
tempData = Marshal.AllocHGlobal (height * width * 2);
int d32;
short d16;
int inPixel32Count = 0, outPixel16Count=0;
for (i = 0; i < width * height; ++i, inPixel32Count+=sizeof(int)) {
d32 = Marshal.ReadInt32 (data, inPixel32Count);
short R = (short)((((d32 >> 0) & 0xFF) >> 3) << 11);
short G = (short)((((d32 >> 8) & 0xFF) >> 2) << 5);
short B = (short)((((d32 >> 16) & 0xFF) >> 3) << 0);
d16 = (short)(R | G | B);
Marshal.WriteInt16 (tempData, outPixel16Count, d16);
outPixel16Count += sizeof(short);
}
Marshal.FreeHGlobal (data);
data = tempData;
}
InitWithData (data, pixelFormat, width, height, imageSize, filter);
context.Dispose ();
Marshal.FreeHGlobal (data);
}
internal static void NativeDrawString (CGBitmapContext bitmapContext, string s, CTFont font, CCColor4B brush, CGRect layoutRectangle)
{
if (font == null)
throw new ArgumentNullException ("font");
if (s == null || s.Length == 0)
return;
bitmapContext.ConcatCTM (bitmapContext.GetCTM().Invert());
// This is not needed here since the color is set in the attributed string.
//bitmapContext.SetFillColor(brush.R/255f, brush.G/255f, brush.B/255f, brush.A/255f);
// I think we only Fill the text with no Stroke surrounding
//bitmapContext.SetTextDrawingMode(CGTextDrawingMode.Fill);
var attributedString = buildAttributedString(s, font, brush);
// Work out the geometry
CGRect insetBounds = layoutRectangle;
CGPoint textPosition = new CGPoint(insetBounds.X,
insetBounds.Y);
float boundsWidth = (float)insetBounds.Width;
// Calculate the lines
nint start = 0;
nint length = attributedString.Length;
var typesetter = new CTTypesetter(attributedString);
float baselineOffset = 0;
// First we need to calculate the offset for Vertical Alignment if we
// are using anything but Top
if (vertical != CCVerticalTextAlignment.Top) {
while (start < length) {
nint count = typesetter.SuggestLineBreak((int)start, (double)boundsWidth);
var line = typesetter.GetLine (new NSRange(start, count));
// Create and initialize some values from the bounds.
nfloat ascent;
nfloat descent;
nfloat leading;
line.GetTypographicBounds(out ascent, out descent, out leading);
baselineOffset += (float)Math.Ceiling ((float)(ascent + descent + leading + 1)); // +1 matches best to CTFramesetter's behavior
line.Dispose ();
start += count;
}
}
start = 0;
while (start < length && textPosition.Y < insetBounds.Bottom)
{
// Now we ask the typesetter to break off a line for us.
// This also will take into account line feeds embedded in the text.
// Example: "This is text \n with a line feed embedded inside it"
nint count = typesetter.SuggestLineBreak((int)start, (double)boundsWidth);
var line = typesetter.GetLine(new NSRange(start, count));
// Create and initialize some values from the bounds.
nfloat ascent;
nfloat descent;
nfloat leading;
line.GetTypographicBounds(out ascent, out descent, out leading);
// Calculate the string format if need be
var penFlushness = 0.0f;
if (horizontal == CCTextAlignment.Right)
penFlushness = (float)line.GetPenOffsetForFlush(1.0f, boundsWidth);
else if (horizontal == CCTextAlignment.Center)
penFlushness = (float)line.GetPenOffsetForFlush(0.5f, boundsWidth);
// initialize our Text Matrix or we could get trash in here
var textMatrix = CGAffineTransform.MakeIdentity();
if (vertical == CCVerticalTextAlignment.Top)
textMatrix.Translate(penFlushness, insetBounds.Height - textPosition.Y -(float)Math.Floor(ascent - 1));
if (vertical == CCVerticalTextAlignment.Center)
textMatrix.Translate(penFlushness, ((insetBounds.Height / 2) + (baselineOffset / 2)) - textPosition.Y -(float)Math.Floor(ascent - 1));
if (vertical == CCVerticalTextAlignment.Bottom)
textMatrix.Translate(penFlushness, baselineOffset - textPosition.Y -(float)Math.Floor(ascent - 1));
// Set our matrix
bitmapContext.TextMatrix = textMatrix;
// and draw the line
line.Draw(bitmapContext);
// Move the index beyond the line break.
start += count;
textPosition.Y += (float)Math.Ceiling(ascent + descent + leading + 1); // +1 matches best to CTFramesetter's behavior
line.Dispose();
}
}
private void InitWithCGImage(CGImage image)
{
int width, height;
CGBitmapContext bitmap = null;
bool hasAlpha;
CGImageAlphaInfo alphaInfo;
CGColorSpace colorSpace;
int bitsPerComponent, bytesPerRow;
CGBitmapFlags bitmapInfo;
bool premultiplied = false;
int bitsPerPixel = 0;
if (image == null) {
throw new ArgumentException (" image is invalid! " );
}
alphaInfo = image.AlphaInfo;
hasAlpha = ((alphaInfo == CGImageAlphaInfo.PremultipliedLast) || (alphaInfo == CGImageAlphaInfo.PremultipliedFirst) || (alphaInfo == CGImageAlphaInfo.Last) || (alphaInfo == CGImageAlphaInfo.First) ? true : false);
imageSize.Width = image.Width;
imageSize.Height = image.Height;
width = image.Width;
height = image.Height;
// Not sure yet if we need to keep the original image information
// before we change it internally. TODO look at what windows does
// and follow that.
bitmapInfo = image.BitmapInfo;
bitsPerComponent = image.BitsPerComponent;
bitsPerPixel = image.BitsPerPixel;
bytesPerRow = width * bitsPerPixel/bitsPerComponent;
int size = bytesPerRow * height;
colorSpace = image.ColorSpace;
// Right now internally we represent the images all the same
// I left the call here just in case we find that this is not
// possible. Read the comments for non alpha images.
if(colorSpace != null) {
if( hasAlpha ) {
premultiplied = true;
colorSpace = CGColorSpace.CreateDeviceRGB ();
bitsPerComponent = 8;
bitsPerPixel = 32;
bitmapInfo = CGBitmapFlags.PremultipliedLast;
}
else
{
// even for images without alpha we will internally
// represent them as RGB with alpha. There were problems
// if we do not do it this way and creating a bitmap context.
// The images were not drawing correctly and tearing. Also
// creating a Graphics to draw on was a nightmare. This
// should probably be looked into or maybe it is ok and we
// can continue representing internally with this representation
premultiplied = true;
colorSpace = CGColorSpace.CreateDeviceRGB ();
bitsPerComponent = 8;
bitsPerPixel = 32;
bitmapInfo = CGBitmapFlags.NoneSkipLast;
}
} else {
premultiplied = true;
colorSpace = CGColorSpace.CreateDeviceRGB ();
bitsPerComponent = 8;
bitsPerPixel = 32;
bitmapInfo = CGBitmapFlags.NoneSkipLast;
}
bytesPerRow = width * bitsPerPixel/bitsPerComponent;
size = bytesPerRow * height;
bitmapBlock = Marshal.AllocHGlobal (size);
bitmap = new CGBitmapContext (bitmapBlock,
width, height,
bitsPerComponent,
bytesPerRow,
colorSpace,
bitmapInfo);
bitmap.ClearRect (new RectangleF (0,0,width,height));
// We need to flip the Y axis to go from right handed to lefted handed coordinate system
var transform = new CGAffineTransform(1, 0, 0, -1, 0, image.Height);
bitmap.ConcatCTM(transform);
bitmap.DrawImage(new RectangleF (0, 0, image.Width, image.Height), image);
var provider = new CGDataProvider (bitmapBlock, size, true);
NativeCGImage = new CGImage (width, height, bitsPerComponent,
bitsPerPixel, bytesPerRow,
colorSpace,
bitmapInfo,
provider, null, true, image.RenderingIntent);
colorSpace.Dispose();
bitmap.Dispose();
}
