otherlibs/highgui/grfmt_imageio.cpp - platform/external/opencv - Git at Google

 /*
  *  grfmt_imageio.cpp
  *
  *
  *  Created by Morgan Conbere on 5/17/07.
  *
  */

 #include "_highgui.h"

 #ifdef HAVE_IMAGEIO

 #include "grfmt_imageio.h"
 #include <iostream>
 using namespace std;

 // ImageIO filter factory

 GrFmtImageIO::GrFmtImageIO()
 {
     m_sign_len = 0;
     m_signature = NULL;
     m_description = "Apple ImageIO (*.bmp;*.dib;*.exr;*.jpeg;*.jpg;*.jpe;*.jp2;*.pdf;*.png;*.tiff;*.tif)";
 }


 GrFmtImageIO::~GrFmtImageIO()
 {
 }


 bool  GrFmtImageIO::CheckFile( const char* filename )
 {
     if( !filename ) return false;

     // If a CFImageRef can be retrieved from an image file, it is
     // readable by ImageIO.  Effectively this is using ImageIO
     // to check the signatures and determine the file format for us.
     CFURLRef imageURLRef = CFURLCreateFromFileSystemRepresentation( NULL,
                                                                     (const UInt8*)filename,
                                                                     strlen( filename ),
                                                                     false );
     if( !imageURLRef ) return false;

     CGImageSourceRef sourceRef = CGImageSourceCreateWithURL( imageURLRef, NULL );
     CFRelease( imageURLRef );
     if( !sourceRef ) return false;

     CGImageRef imageRef = CGImageSourceCreateImageAtIndex( sourceRef, 0, NULL );
     CFRelease( sourceRef );
     if( !imageRef ) return false;

     return true;
 }


 GrFmtReader* GrFmtImageIO::NewReader( const char* filename )
 {
     return new GrFmtImageIOReader( filename );
 }


 GrFmtWriter* GrFmtImageIO::NewWriter( const char* filename )
 {
     return new GrFmtImageIOWriter( filename );
 }


 /////////////////////// GrFmtImageIOReader ///////////////////

 GrFmtImageIOReader::GrFmtImageIOReader( const char* filename ) : GrFmtReader( filename )
 {
     // Nothing to do here
 }


 GrFmtImageIOReader::~GrFmtImageIOReader()
 {
     Close();
 }


 void  GrFmtImageIOReader::Close()
 {
     CGImageRelease( imageRef );

     GrFmtReader::Close();
 }


 bool  GrFmtImageIOReader::ReadHeader()
 {
     CFURLRef         imageURLRef;
     CGImageSourceRef sourceRef;
     imageRef = NULL;

     imageURLRef = CFURLCreateFromFileSystemRepresentation( NULL,
                                                            (const UInt8*)m_filename,
                                                            strlen(m_filename),
                                                            false );

     sourceRef = CGImageSourceCreateWithURL( imageURLRef, NULL );
     CFRelease( imageURLRef );
     if ( !sourceRef )
         return false;

     imageRef = CGImageSourceCreateImageAtIndex( sourceRef, 0, NULL );
     CFRelease( sourceRef );
     if( !imageRef )
         return false;

     m_width = CGImageGetWidth( imageRef );
     m_height = CGImageGetHeight( imageRef );

     CGColorSpaceRef colorSpace = CGImageGetColorSpace( imageRef );
     if( !colorSpace )
         return false;

     m_iscolor = ( CGColorSpaceGetNumberOfComponents( colorSpace ) > 1 );

     return true;
 }


 bool  GrFmtImageIOReader::ReadData( uchar* data, int step, int color )
 {
     int bpp; // Bytes per pixel

     // Set color to either CV_IMAGE_LOAD_COLOR or CV_IMAGE_LOAD_GRAYSCALE if unchanged
     color = color > 0 || ( m_iscolor && color < 0 );

     // Get Height, Width, and color information
     if( !ReadHeader() )
         return false;

     CGContextRef     context = NULL; // The bitmap context
     CGColorSpaceRef  colorSpace = NULL;
     uchar*           bitmap = NULL;
     CGImageAlphaInfo alphaInfo;

     // CoreGraphics will take care of converting to grayscale and back as long as the
     // appropriate colorspace is set
     if( color == CV_LOAD_IMAGE_GRAYSCALE )
     {
         colorSpace = CGColorSpaceCreateDeviceGray();
         bpp = 1;
         alphaInfo = kCGImageAlphaNone;
     }
     else if( color == CV_LOAD_IMAGE_COLOR )
     {
         colorSpace = CGColorSpaceCreateDeviceRGB();
         bpp = 4; /* CG only has 8 and 32 bit color spaces, so we waste a byte */
         alphaInfo = kCGImageAlphaNoneSkipLast;
     }
     if( !colorSpace )
         return false;

     bitmap = (uchar*)malloc( bpp * m_height * m_width );
     if( !bitmap )
     {
         CGColorSpaceRelease( colorSpace );
         return false;
     }

     context = CGBitmapContextCreate( (void *)bitmap,
                                      m_width,        /* width */
                                      m_height,       /* height */
                                      m_bit_depth,    /* bit depth */
                                      bpp * m_width,  /* bytes per row */
                                      colorSpace,     /* color space */
                                      alphaInfo);

     CGColorSpaceRelease( colorSpace );
     if( !context )
     {
         free( bitmap );
         return false;
     }

     // Copy the image data into the bitmap region
     CGRect rect = {{0,0},{m_width,m_height}};
     CGContextDrawImage( context, rect, imageRef );

     uchar* bitdata = (uchar*)CGBitmapContextGetData( context );
     if( !bitdata )
     {
         free( bitmap);
         CGContextRelease( context );
         return false;
     }

     // Move the bitmap (in RGB) into data (in BGR)
     int bitmapIndex = 0;

     if( color == CV_LOAD_IMAGE_COLOR )
 	{
 		uchar * base = data;

 		for (int y = 0; y < m_height; y++)
 		{
 			uchar * line = base + y * step;

 		    for (int x = 0; x < m_width; x++)
 		    {
 				// Blue channel
 				line[0] = bitdata[bitmapIndex + 2];
 				// Green channel
 				line[1] = bitdata[bitmapIndex + 1];
 				// Red channel
 				line[2] = bitdata[bitmapIndex + 0];

 				line        += 3;
 				bitmapIndex += bpp;
 			}
 		}
     }
     else if( color == CV_LOAD_IMAGE_GRAYSCALE )
     {
 		for (int y = 0; y < m_height; y++)
 			memcpy (data + y * step, bitmap + y * m_width, m_width);
     }

     free( bitmap );
     CGContextRelease( context );
     return true;
 }


 /////////////////////// GrFmtImageIOWriter ///////////////////

 GrFmtImageIOWriter::GrFmtImageIOWriter( const char* filename ) : GrFmtWriter( filename )
 {
     // Nothing to do here
 }


 GrFmtImageIOWriter::~GrFmtImageIOWriter()
 {
     // Nothing to do here
 }


 static
 CFStringRef  FilenameToUTI( const char* filename )
 {
     const char* ext = filename;
     for(;;)
     {
         const char* temp = strchr( ext + 1, '.' );
         if( !temp ) break;
         ext = temp;
     }

     CFStringRef imageUTI = NULL;

     if( !strcmp(ext, ".bmp") || !strcmp(ext, ".dib") )
         imageUTI = CFSTR( "com.microsoft.bmp" );
     else if( !strcmp(ext, ".exr") )
         imageUTI = CFSTR( "com.ilm.openexr-image" );
     else if( !strcmp(ext, ".jpeg") || !strcmp(ext, ".jpg") || !strcmp(ext, ".jpe") )
         imageUTI = CFSTR( "public.jpeg" );
     else if( !strcmp(ext, ".jp2") )
         imageUTI = CFSTR( "public.jpeg-2000" );
     else if( !strcmp(ext, ".pdf") )
         imageUTI = CFSTR( "com.adobe.pdf" );
     else if( !strcmp(ext, ".png") )
         imageUTI = CFSTR( "public.png" );
     else if( !strcmp(ext, ".tiff") || !strcmp(ext, ".tif") )
         imageUTI = CFSTR( "public.tiff" );

     return imageUTI;
 }


 bool  GrFmtImageIOWriter::WriteImage( const uchar* data, int step,
                                       int width, int height, int /*depth*/, int _channels )
 {
     // Determine the appropriate UTI based on the filename extension
     CFStringRef imageUTI = FilenameToUTI( m_filename );

     // Determine the Bytes Per Pixel
     int bpp = (_channels == 1) ? 1 : 4;

     // Write the data into a bitmap context
     CGContextRef context;
     CGColorSpaceRef colorSpace;
     uchar* bitmapData = NULL;

     if( bpp == 1 )
         colorSpace = CGColorSpaceCreateWithName( kCGColorSpaceGenericGray );
     else if( bpp == 4 )
         colorSpace = CGColorSpaceCreateWithName( kCGColorSpaceGenericRGB );
     if( !colorSpace )
         return false;

     bitmapData = (uchar*)malloc( bpp * height * width );
     if( !bitmapData )
     {
         CGColorSpaceRelease( colorSpace );
         return false;
     }

     context = CGBitmapContextCreate( bitmapData,
                                      width,
                                      height,
                                      8,
                                      bpp * width,
                                      colorSpace,
                                      (bpp == 1) ? kCGImageAlphaNone :
                                      kCGImageAlphaNoneSkipLast );
     CGColorSpaceRelease( colorSpace );
     if( !context )
     {
         free( bitmapData );
         return false;
     }

     // Copy pixel information from data into bitmapData
     if (bpp == 4)
     {
         int           bitmapIndex = 0;
 		const uchar * base        = data;

 		for (int y = 0; y < height; y++)
 		{
 			const uchar * line = base + y * step;

 		    for (int x = 0; x < width; x++)
 		    {
 				// Blue channel
                 bitmapData[bitmapIndex + 2] = line[0];
 				// Green channel
 				bitmapData[bitmapIndex + 1] = line[1];
 				// Red channel
 				bitmapData[bitmapIndex + 0] = line[2];

 				line        += 3;
 				bitmapIndex += bpp;
 			}
 		}
     }
     else if (bpp == 1)
     {
 		for (int y = 0; y < height; y++)
 			memcpy (bitmapData + y * width, data + y * step, width);
     }

     // Turn the bitmap context into an imageRef
     CGImageRef imageRef = CGBitmapContextCreateImage( context );
     CGContextRelease( context );
     if( !imageRef )
     {
         free( bitmapData );
         return false;
     }

     // Write the imageRef to a file based on the UTI
     CFURLRef imageURLRef = CFURLCreateFromFileSystemRepresentation( NULL,
                                                                     (const UInt8*)m_filename,
                                                                     strlen(m_filename),
                                                                     false );
     if( !imageURLRef )
     {
         CGImageRelease( imageRef );
         free( bitmapData );
         return false;
     }

     CGImageDestinationRef destRef = CGImageDestinationCreateWithURL( imageURLRef,
                                                                      imageUTI,
                                                                      1,
                                                                      NULL);
     CFRelease( imageURLRef );
     if( !destRef )
     {
         CGImageRelease( imageRef );
         free( bitmapData );
         std::cerr << "!destRef" << std::endl << std::flush;
         return false;
     }

     CGImageDestinationAddImage(destRef, imageRef, NULL);
     if( !CGImageDestinationFinalize(destRef) )
     {
         std::cerr << "Finalize failed" << std::endl << std::flush;
         return false;
     }

     CFRelease( destRef );
     CGImageRelease( imageRef );
     free( bitmapData );

     return true;
 }

 #endif /* HAVE_IMAGEIO */
	/*
	* grfmt_imageio.cpp
	*
	*
	* Created by Morgan Conbere on 5/17/07.
	*
	*/

	#include "_highgui.h"

	#ifdef HAVE_IMAGEIO

	#include "grfmt_imageio.h"
	#include <iostream>
	using namespace std;

	// ImageIO filter factory

	GrFmtImageIO::GrFmtImageIO()
	{
	m_sign_len = 0;
	m_signature = NULL;
	m_description = "Apple ImageIO (.bmp;.dib;.exr;.jpeg;.jpg;.jpe;.jp2;.pdf;.png;.tiff;*.tif)";
	}


	GrFmtImageIO::~GrFmtImageIO()
	{
	}


	bool GrFmtImageIO::CheckFile( const char* filename )
	{
	if( !filename ) return false;

	// If a CFImageRef can be retrieved from an image file, it is
	// readable by ImageIO. Effectively this is using ImageIO
	// to check the signatures and determine the file format for us.
	CFURLRef imageURLRef = CFURLCreateFromFileSystemRepresentation( NULL,
	(const UInt8*)filename,
	strlen( filename ),
	false );
	if( !imageURLRef ) return false;

	CGImageSourceRef sourceRef = CGImageSourceCreateWithURL( imageURLRef, NULL );
	CFRelease( imageURLRef );
	if( !sourceRef ) return false;

	CGImageRef imageRef = CGImageSourceCreateImageAtIndex( sourceRef, 0, NULL );
	CFRelease( sourceRef );
	if( !imageRef ) return false;

	return true;
	}


	GrFmtReader* GrFmtImageIO::NewReader( const char* filename )
	{
	return new GrFmtImageIOReader( filename );
	}


	GrFmtWriter* GrFmtImageIO::NewWriter( const char* filename )
	{
	return new GrFmtImageIOWriter( filename );
	}


	/////////////////////// GrFmtImageIOReader ///////////////////

	GrFmtImageIOReader::GrFmtImageIOReader( const char* filename ) : GrFmtReader( filename )
	{
	// Nothing to do here
	}


	GrFmtImageIOReader::~GrFmtImageIOReader()
	{
	Close();
	}


	void GrFmtImageIOReader::Close()
	{
	CGImageRelease( imageRef );

	GrFmtReader::Close();
	}


	bool GrFmtImageIOReader::ReadHeader()
	{
	CFURLRef imageURLRef;
	CGImageSourceRef sourceRef;
	imageRef = NULL;

	imageURLRef = CFURLCreateFromFileSystemRepresentation( NULL,
	(const UInt8*)m_filename,
	strlen(m_filename),
	false );

	sourceRef = CGImageSourceCreateWithURL( imageURLRef, NULL );
	CFRelease( imageURLRef );
	if ( !sourceRef )
	return false;

	imageRef = CGImageSourceCreateImageAtIndex( sourceRef, 0, NULL );
	CFRelease( sourceRef );
	if( !imageRef )
	return false;

	m_width = CGImageGetWidth( imageRef );
	m_height = CGImageGetHeight( imageRef );

	CGColorSpaceRef colorSpace = CGImageGetColorSpace( imageRef );
	if( !colorSpace )
	return false;

	m_iscolor = ( CGColorSpaceGetNumberOfComponents( colorSpace ) > 1 );

	return true;
	}


	bool GrFmtImageIOReader::ReadData( uchar* data, int step, int color )
	{
	int bpp; // Bytes per pixel

	// Set color to either CV_IMAGE_LOAD_COLOR or CV_IMAGE_LOAD_GRAYSCALE if unchanged
	color = color > 0 \|\| ( m_iscolor && color < 0 );

	// Get Height, Width, and color information
	if( !ReadHeader() )
	return false;

	CGContextRef context = NULL; // The bitmap context
	CGColorSpaceRef colorSpace = NULL;
	uchar* bitmap = NULL;
	CGImageAlphaInfo alphaInfo;

	// CoreGraphics will take care of converting to grayscale and back as long as the
	// appropriate colorspace is set
	if( color == CV_LOAD_IMAGE_GRAYSCALE )
	{
	colorSpace = CGColorSpaceCreateDeviceGray();
	bpp = 1;
	alphaInfo = kCGImageAlphaNone;
	}
	else if( color == CV_LOAD_IMAGE_COLOR )
	{
	colorSpace = CGColorSpaceCreateDeviceRGB();
	bpp = 4; /* CG only has 8 and 32 bit color spaces, so we waste a byte */
	alphaInfo = kCGImageAlphaNoneSkipLast;
	}
	if( !colorSpace )
	return false;

	bitmap = (uchar)malloc( bpp m_height * m_width );
	if( !bitmap )
	{
	CGColorSpaceRelease( colorSpace );
	return false;
	}

	context = CGBitmapContextCreate( (void *)bitmap,
	m_width, /* width */
	m_height, /* height */
	m_bit_depth, /* bit depth */
	bpp * m_width, /* bytes per row */
	colorSpace, /* color space */
	alphaInfo);

	CGColorSpaceRelease( colorSpace );
	if( !context )
	{
	free( bitmap );
	return false;
	}

	// Copy the image data into the bitmap region
	CGRect rect = {{0,0},{m_width,m_height}};
	CGContextDrawImage( context, rect, imageRef );

	uchar* bitdata = (uchar*)CGBitmapContextGetData( context );
	if( !bitdata )
	{
	free( bitmap);
	CGContextRelease( context );
	return false;
	}

	// Move the bitmap (in RGB) into data (in BGR)
	int bitmapIndex = 0;

	if( color == CV_LOAD_IMAGE_COLOR )
	{
	uchar * base = data;

	for (int y = 0; y < m_height; y++)
	{
	uchar * line = base + y * step;

	for (int x = 0; x < m_width; x++)
	{
	// Blue channel
	line[0] = bitdata[bitmapIndex + 2];
	// Green channel
	line[1] = bitdata[bitmapIndex + 1];
	// Red channel
	line[2] = bitdata[bitmapIndex + 0];

	line += 3;
	bitmapIndex += bpp;
	}
	}
	}
	else if( color == CV_LOAD_IMAGE_GRAYSCALE )
	{
	for (int y = 0; y < m_height; y++)
	memcpy (data + y * step, bitmap + y * m_width, m_width);
	}

	free( bitmap );
	CGContextRelease( context );
	return true;
	}


	/////////////////////// GrFmtImageIOWriter ///////////////////

	GrFmtImageIOWriter::GrFmtImageIOWriter( const char* filename ) : GrFmtWriter( filename )
	{
	// Nothing to do here
	}


	GrFmtImageIOWriter::~GrFmtImageIOWriter()
	{
	// Nothing to do here
	}


	static
	CFStringRef FilenameToUTI( const char* filename )
	{
	const char* ext = filename;
	for(;;)
	{
	const char* temp = strchr( ext + 1, '.' );
	if( !temp ) break;
	ext = temp;
	}

	CFStringRef imageUTI = NULL;

	if( !strcmp(ext, ".bmp") \|\| !strcmp(ext, ".dib") )
	imageUTI = CFSTR( "com.microsoft.bmp" );
	else if( !strcmp(ext, ".exr") )
	imageUTI = CFSTR( "com.ilm.openexr-image" );
	else if( !strcmp(ext, ".jpeg") \|\| !strcmp(ext, ".jpg") \|\| !strcmp(ext, ".jpe") )
	imageUTI = CFSTR( "public.jpeg" );
	else if( !strcmp(ext, ".jp2") )
	imageUTI = CFSTR( "public.jpeg-2000" );
	else if( !strcmp(ext, ".pdf") )
	imageUTI = CFSTR( "com.adobe.pdf" );
	else if( !strcmp(ext, ".png") )
	imageUTI = CFSTR( "public.png" );
	else if( !strcmp(ext, ".tiff") \|\| !strcmp(ext, ".tif") )
	imageUTI = CFSTR( "public.tiff" );

	return imageUTI;
	}


	bool GrFmtImageIOWriter::WriteImage( const uchar* data, int step,
	int width, int height, int /depth/, int _channels )
	{
	// Determine the appropriate UTI based on the filename extension
	CFStringRef imageUTI = FilenameToUTI( m_filename );

	// Determine the Bytes Per Pixel
	int bpp = (_channels == 1) ? 1 : 4;

	// Write the data into a bitmap context
	CGContextRef context;
	CGColorSpaceRef colorSpace;
	uchar* bitmapData = NULL;

	if( bpp == 1 )
	colorSpace = CGColorSpaceCreateWithName( kCGColorSpaceGenericGray );
	else if( bpp == 4 )
	colorSpace = CGColorSpaceCreateWithName( kCGColorSpaceGenericRGB );
	if( !colorSpace )
	return false;

	bitmapData = (uchar)malloc( bpp height * width );
	if( !bitmapData )
	{
	CGColorSpaceRelease( colorSpace );
	return false;
	}

	context = CGBitmapContextCreate( bitmapData,
	width,
	height,
	8,
	bpp * width,
	colorSpace,
	(bpp == 1) ? kCGImageAlphaNone :
	kCGImageAlphaNoneSkipLast );
	CGColorSpaceRelease( colorSpace );
	if( !context )
	{
	free( bitmapData );
	return false;
	}

	// Copy pixel information from data into bitmapData
	if (bpp == 4)
	{
	int bitmapIndex = 0;
	const uchar * base = data;

	for (int y = 0; y < height; y++)
	{
	const uchar * line = base + y * step;

	for (int x = 0; x < width; x++)
	{
	// Blue channel
	bitmapData[bitmapIndex + 2] = line[0];
	// Green channel
	bitmapData[bitmapIndex + 1] = line[1];
	// Red channel
	bitmapData[bitmapIndex + 0] = line[2];

	line += 3;
	bitmapIndex += bpp;
	}
	}
	}
	else if (bpp == 1)
	{
	for (int y = 0; y < height; y++)
	memcpy (bitmapData + y * width, data + y * step, width);
	}

	// Turn the bitmap context into an imageRef
	CGImageRef imageRef = CGBitmapContextCreateImage( context );
	CGContextRelease( context );
	if( !imageRef )
	{
	free( bitmapData );
	return false;
	}

	// Write the imageRef to a file based on the UTI
	CFURLRef imageURLRef = CFURLCreateFromFileSystemRepresentation( NULL,
	(const UInt8*)m_filename,
	strlen(m_filename),
	false );
	if( !imageURLRef )
	{
	CGImageRelease( imageRef );
	free( bitmapData );
	return false;
	}

	CGImageDestinationRef destRef = CGImageDestinationCreateWithURL( imageURLRef,
	imageUTI,
	1,
	NULL);
	CFRelease( imageURLRef );
	if( !destRef )
	{
	CGImageRelease( imageRef );
	free( bitmapData );
	std::cerr << "!destRef" << std::endl << std::flush;
	return false;
	}

	CGImageDestinationAddImage(destRef, imageRef, NULL);
	if( !CGImageDestinationFinalize(destRef) )
	{
	std::cerr << "Finalize failed" << std::endl << std::flush;
	return false;
	}

	CFRelease( destRef );
	CGImageRelease( imageRef );
	free( bitmapData );

	return true;
	}

	#endif /* HAVE_IMAGEIO */