예제 #1
0
static int
icc_import_vec( im_object *argv )
{
	int intent = *((int *) argv[3]);

	return( im_icc_import( argv[0], argv[1], 
		argv[2], intent ) );
}
예제 #2
0
VALUE
img_icc_import(VALUE obj, VALUE input_profile_filename, VALUE intent)
{
	ID id_intent = SYM2ID(intent);
	GetImg(obj, data, im);
	OutImg(obj, new, data_new, im_new);

    if (im_icc_import(im, im_new, StringValuePtr(input_profile_filename),
		img_id_to_intent(id_intent)))
        vips_lib_error();

    return new;
}
예제 #3
0
static int
shrink_factor( IMAGE *in, IMAGE *out, 
	int shrink, double residual, VipsInterpolate *interp )
{
	IMAGE *t[9];
	VipsImage **s = (VipsImage **) 
		vips_object_local_array( VIPS_OBJECT( out ), 1 );
	IMAGE *x;
	int tile_width;
	int tile_height;
	int nlines;

	if( im_open_local_array( out, t, 9, "thumbnail", "p" ) )
		return( -1 );
	x = in;

	/* Unpack the two coded formats we support to float for processing.
	 */
	if( x->Coding == IM_CODING_LABQ ) {
		if( verbose ) 
			printf( "unpacking LAB to RGB\n" );

		if( im_LabQ2disp( x, t[1], im_col_displays( 7 ) ) )
			return( -1 );
		x = t[1];
	}
	else if( x->Coding == IM_CODING_RAD ) {
		if( verbose ) 
			printf( "unpacking Rad to float\n" );

		if( im_rad2float( x, t[1] ) )
			return( -1 );
		x = t[1];
	}

	if( im_shrink( x, t[2], shrink, shrink ) )
		return( -1 );

	/* We want to make sure we read the image sequentially.
	 * However, the convolution we may be doing later will force us 
	 * into SMALLTILE or maybe FATSTRIP mode and that will break
	 * sequentiality.
	 *
	 * So ... read into a cache where tiles are scanlines, and make sure
	 * we keep enough scanlines to be able to serve a line of tiles.
	 */
	vips_get_tile_size( t[2], 
		&tile_width, &tile_height, &nlines );
	if( vips_tilecache( t[2], &s[0], 
		"tile_width", t[2]->Xsize,
		"tile_height", 10,
		"max_tiles", (nlines * 2) / 10,
		"strategy", VIPS_CACHE_SEQUENTIAL,
		NULL ) ||
		im_affinei_all( s[0], t[4], 
			interp, residual, 0, 0, residual, 0, 0 ) )
		return( -1 );
	x = t[4];

	/* If we are upsampling, don't sharpen, since nearest looks dumb
	 * sharpened.
	 */
	if( shrink > 1 && residual <= 1.0 && !nosharpen ) {
		if( verbose ) 
			printf( "sharpening thumbnail\n" );

		if( im_conv( x, t[5], sharpen_filter() ) )
			return( -1 );
		x = t[5];
	}

	/* Colour management: we can transform the image if we have an output
	 * profile and an input profile. The input profile can be in the
	 * image, or if there is no profile there, supplied by the user.
	 */
	if( export_profile &&
		(im_header_get_typeof( x, IM_META_ICC_NAME ) || 
		 import_profile) ) {
		if( im_header_get_typeof( x, IM_META_ICC_NAME ) ) {
			if( verbose ) 
				printf( "importing with embedded profile\n" );

			if( im_icc_import_embedded( x, t[6], 
				IM_INTENT_RELATIVE_COLORIMETRIC ) )
				return( -1 );
		}
		else {
			if( verbose ) 
				printf( "importing with profile %s\n",
					import_profile );

			if( im_icc_import( x, t[6], 
				import_profile, 
				IM_INTENT_RELATIVE_COLORIMETRIC ) )
				return( -1 );
		}

		if( verbose ) 
			printf( "exporting with profile %s\n", export_profile );

		if( im_icc_export_depth( t[6], t[7], 
			8, export_profile, 
			IM_INTENT_RELATIVE_COLORIMETRIC ) )
			return( -1 );

		x = t[7];
	}

	if( delete_profile ) {
		if( verbose )
			printf( "deleting profile from output image\n" );

		if( im_meta_get_typeof( x, IM_META_ICC_NAME ) &&
			!im_meta_remove( x, IM_META_ICC_NAME ) )
			return( -1 );
	}

	if( im_copy( x, out ) )
		return( -1 );

	return( 0 );
}