#include <stdio.h>
#include <stdlib.h>
+static inline int is_big_endian( )
+{
+ union { int i; char c[ 4 ]; } big_endian_test;
+ big_endian_test.i = 1;
+
+ return big_endian_test.c[ 0 ] != 1;
+}
+
static inline int convert_mlt_to_av_cs( mlt_image_format format )
{
int value = 0;
static inline void convert_image( uint8_t *out, uint8_t *in, int out_fmt, int in_fmt, int width, int height )
{
- if ( in_fmt == PIX_FMT_YUV420P && out_fmt == PIX_FMT_YUV422 )
- {
- register int i, j;
- register int half = width >> 1;
- register uint8_t *Y = in;
- register uint8_t *U = Y + width * height;
- register uint8_t *V = U + width * height / 2;
- register uint8_t *d = out;
- register uint8_t *y, *u, *v;
-
- i = height >> 1;
- while ( i -- )
- {
- y = Y;
- u = U;
- v = V;
- j = half;
- while ( j -- )
- {
- *d ++ = *y ++;
- *d ++ = *u ++;
- *d ++ = *y ++;
- *d ++ = *v ++;
- }
-
- Y += width;
- y = Y;
- u = U;
- v = V;
- j = half;
- while ( j -- )
- {
- *d ++ = *y ++;
- *d ++ = *u ++;
- *d ++ = *y ++;
- *d ++ = *v ++;
- }
-
- Y += width;
- U += width / 2;
- V += width / 2;
- }
- }
- else
- {
- AVPicture input;
- AVPicture output;
- avpicture_fill( &output, out, out_fmt, width, height );
- avpicture_fill( &input, in, in_fmt, width, height );
- img_convert( &output, out_fmt, &input, in_fmt, width, height );
- }
+ AVPicture input;
+ AVPicture output;
+ avpicture_fill( &output, out, out_fmt, width, height );
+ avpicture_fill( &input, in, in_fmt, width, height );
+ img_convert( &output, out_fmt, &input, in_fmt, width, height );
}
/** Do it :-).
int size = avpicture_get_size( out_fmt, *width, *height );
uint8_t *output = mlt_pool_alloc( size );
convert_image( output, *image, out_fmt, in_fmt, *width, *height );
+
+ // Special case for alpha rgb input
+ if ( *format == mlt_image_rgb24a )
+ {
+ register uint8_t *alpha = mlt_frame_get_alpha_mask( this );
+ register int len = *width * *height;
+ register uint8_t *bits = *image;
+ register int n = ( len + 7 ) / 8;
+
+ if( !is_big_endian( ) )
+ bits += 3;
+
+ // Extract alpha mask from the image using Duff's Device
+ switch( len % 8 )
+ {
+ case 0: do { *alpha ++ = *bits; bits += 4;
+ case 7: *alpha ++ = *bits; bits += 4;
+ case 6: *alpha ++ = *bits; bits += 4;
+ case 5: *alpha ++ = *bits; bits += 4;
+ case 4: *alpha ++ = *bits; bits += 4;
+ case 3: *alpha ++ = *bits; bits += 4;
+ case 2: *alpha ++ = *bits; bits += 4;
+ case 1: *alpha ++ = *bits; bits += 4;
+ }
+ while( --n );
+ }
+ }
+
+ // Update the output
*image = output;
*format = output_format;
mlt_properties_set_data( properties, "image", output, size, mlt_pool_release, NULL );
mlt_properties_set_int( properties, "format", output_format );
- // Special case for alpha rgb - merge the alpha mask when it exists
+ // Special case for alpha rgb output
if ( *format == mlt_image_rgb24a )
{
// Fetch the alpha
register uint8_t *bits = *image;
register int len = *width * *height;
register int n = ( len + 7 ) / 8;
-
- // TODO: Proper check for big endian systems
- #ifndef __DARWIN__
- bits += 3;
- #endif
+
+ if( !is_big_endian( ) )
+ bits += 3;
// Merge the alpha mask into the RGB image using Duff's Device
switch( len % 8 )