#include <unistd.h>
#include <string.h>
#include <sys/uio.h>
-#include <X11/Xlib.h>
-#include <X11/extensions/XShm.h>
#include "config.h"
#include "common.h"
#include "vpar_blocks.h"
#include "vpar_headers.h"
-#include "video_fifo.h"
#include "vpar_synchro.h"
#include "video_parser.h"
+#include "video_fifo.h"
#define MAX_COUNT 3
float vpar_SynchroUpdateTab( video_synchro_tab_t * tab, int count )
{
- tab->mean = ( tab->mean + 3 * count ) / 4;
- tab->deviation = ( tab->deviation + 3 * abs (tab->mean - count) ) / 4;
+ tab->mean = ( tab->mean + MAX_COUNT * count ) / ( MAX_COUNT + 1 );
+ tab->deviation = ( tab->deviation + MAX_COUNT * abs (tab->mean - count) )
+ / ( MAX_COUNT + 1 );
return tab->deviation;
}
* vpar_SynchroUpdateStructures : Update the synchro structures
*****************************************************************************/
void vpar_SynchroUpdateStructures( vpar_thread_t * p_vpar,
- int i_coding_type )
+ int i_coding_type, int dropped )
{
float candidate_deviation;
float optimal_deviation;
float predict;
+ mtime_t i_current_pts;
+ mtime_t i_delay;
+ mtime_t i_displaydate;
+ decoder_fifo_t * decoder_fifo = p_vpar->bit_stream.p_decoder_fifo;
+
+ /* interpolate the current _decode_ PTS */
+ i_current_pts = decoder_fifo->buffer[decoder_fifo->i_start]->b_has_pts ?
+ decoder_fifo->buffer[decoder_fifo->i_start]->i_pts :
+ 0;
+ if( !i_current_pts )
+ {
+ i_current_pts = p_vpar->synchro.i_last_decode_pts
+ + 1000000.0 / (1 + p_vpar->synchro.actual_fps);
+ }
+ p_vpar->synchro.i_last_decode_pts = i_current_pts;
+
+ /* see if the current image has a pts - if not, set to 0 */
+ p_vpar->synchro.fifo[p_vpar->synchro.i_fifo_stop].i_pts
+ = i_current_pts;
+
+ /* update display time */
+ i_displaydate = decoder_fifo->buffer[decoder_fifo->i_start]->b_has_pts ?
+ decoder_fifo->buffer[decoder_fifo->i_start]->i_pts :
+ 0;
+ if( !i_displaydate /* || i_coding_type != I_CODING_TYPE */ )
+ {
+ if (!p_vpar->synchro.i_images_since_pts )
+ p_vpar->synchro.i_images_since_pts = 10;
+
+ i_displaydate = p_vpar->synchro.i_last_display_pts
+ + 1000000.0 / (p_vpar->synchro.theorical_fps);
+ //fprintf (stderr, " ");
+ }
+
+ /* else fprintf (stderr, "R ");
+ if (dropped) fprintf (stderr, " "); else fprintf (stderr, "* ");
+ fprintf (stderr, "%i ", i_coding_type);
+ fprintf (stderr, "pts %lli delta %lli\n", i_displaydate, i_displaydate - p_vpar->synchro.i_last_display_pts); */
+ p_vpar->synchro.i_images_since_pts--;
+ p_vpar->synchro.i_last_display_pts = i_displaydate;
+
+
+
+ /* update structures */
switch(i_coding_type)
{
case P_CODING_TYPE:
+
p_vpar->synchro.current_p_count++;
+ if( !dropped ) p_vpar->synchro.nondropped_p_count++;
break;
+
case B_CODING_TYPE:
p_vpar->synchro.current_b_count++;
+ if( !dropped ) p_vpar->synchro.nondropped_b_count++;
break;
+
case I_CODING_TYPE:
+ /* update information about images we can decode */
+ if (i_current_pts != p_vpar->synchro.i_last_i_pts)
+ {
+ if ( p_vpar->synchro.i_last_i_pts && i_current_pts != p_vpar->synchro.i_last_i_pts)
+ {
+ p_vpar->synchro.theorical_fps = (p_vpar->synchro.theorical_fps + 1000000.0 * (1 + p_vpar->synchro.current_b_count + p_vpar->synchro.current_p_count) / (i_current_pts - p_vpar->synchro.i_last_i_pts)) / 2;
+ }
+ p_vpar->synchro.i_last_i_pts = i_current_pts;
+ }
+
+ if( !dropped )
+ {
+ if ( p_vpar->synchro.i_last_nondropped_i_pts && i_current_pts != p_vpar->synchro.i_last_nondropped_i_pts)
+ {
+ p_vpar->synchro.actual_fps = (p_vpar->synchro.actual_fps + 1000000.0 * (1 + p_vpar->synchro.nondropped_b_count + p_vpar->synchro.nondropped_p_count) / (i_current_pts - p_vpar->synchro.i_last_nondropped_i_pts)) / 2;
+ }
+
+ }
+
+
/* update all the structures for P images */
+
+ /* period == 1 */
optimal_deviation = vpar_SynchroUpdateTab(
&p_vpar->synchro.tab_p[0],
p_vpar->synchro.current_p_count);
predict = p_vpar->synchro.tab_p[0].mean;
+ /* period == 2 */
candidate_deviation = vpar_SynchroUpdateTab(
&p_vpar->synchro.tab_p[1 + (p_vpar->synchro.modulo & 0x1)],
p_vpar->synchro.current_p_count);
predict = p_vpar->synchro.tab_p[1 + (p_vpar->synchro.modulo & 0x1)].mean;
}
+ /* period == 3 */
candidate_deviation = vpar_SynchroUpdateTab(
&p_vpar->synchro.tab_p[3 + (p_vpar->synchro.modulo % 3)],
p_vpar->synchro.current_p_count);
/* update all the structures for B images */
+
+ /* period == 1 */
optimal_deviation = vpar_SynchroUpdateTab(
&p_vpar->synchro.tab_b[0],
p_vpar->synchro.current_b_count);
predict = p_vpar->synchro.tab_b[0].mean;
+ /* period == 2 */
candidate_deviation = vpar_SynchroUpdateTab(
&p_vpar->synchro.tab_b[1 + (p_vpar->synchro.modulo & 0x1)],
p_vpar->synchro.current_b_count);
predict = p_vpar->synchro.tab_b[1 + (p_vpar->synchro.modulo & 0x1)].mean;
}
+ /* period == 3 */
candidate_deviation = vpar_SynchroUpdateTab(
&p_vpar->synchro.tab_b[3 + (p_vpar->synchro.modulo % 3)],
p_vpar->synchro.current_b_count);
p_vpar->synchro.b_count_predict = predict;
p_vpar->synchro.current_b_count = 0;
-
+
+ /* now we calculated all statistics, it's time to
+ * decide what we have the time to display
+ */
+ i_delay = i_current_pts - p_vpar->synchro.i_last_nondropped_i_pts;
+
+ p_vpar->synchro.can_display_i
+ = ( p_vpar->synchro.i_mean_decode_time < i_delay );
+
+ p_vpar->synchro.can_display_p
+ = ( p_vpar->synchro.i_mean_decode_time
+ * (1 + p_vpar->synchro.p_count_predict) < i_delay );
+
+ if( !p_vpar->synchro.can_display_p )
+ {
+ p_vpar->synchro.displayable_p
+ = -1 + i_delay / p_vpar->synchro.i_mean_decode_time;
+ if( p_vpar->synchro.displayable_p < 0 )
+ p_vpar->synchro.displayable_p = 0;
+ }
+ else
+ p_vpar->synchro.displayable_p = 0;
+
+ if( p_vpar->synchro.can_display_p
+ && !(p_vpar->synchro.can_display_b
+ = ( p_vpar->synchro.i_mean_decode_time
+ * (1 + p_vpar->synchro.b_count_predict
+ + p_vpar->synchro.p_count_predict)) < i_delay) )
+ {
+ p_vpar->synchro.displayable_b
+ = -2.0 + i_delay / p_vpar->synchro.i_mean_decode_time
+ - p_vpar->synchro.can_display_p;
+ }
+ else
+ p_vpar->synchro.displayable_b = 0;
+
+#if 0
+ fprintf( stderr,
+ "I %i P %i (%f) B %i (%f)\n",
+ p_vpar->synchro.can_display_i,
+ p_vpar->synchro.can_display_p,
+ p_vpar->synchro.displayable_p,
+ p_vpar->synchro.can_display_b,
+ p_vpar->synchro.displayable_b );
+#endif
+
+ /* update some values */
+ if( !dropped )
+ {
+ p_vpar->synchro.i_last_nondropped_i_pts = i_current_pts;
+ p_vpar->synchro.nondropped_p_count = 0;
+ p_vpar->synchro.nondropped_b_count = 0;
+ }
break;
+
}
p_vpar->synchro.modulo++;
+
}
/*****************************************************************************
boolean_t vpar_SynchroChoose( vpar_thread_t * p_vpar, int i_coding_type,
int i_structure )
{
-// return( 1 );
- return( i_coding_type == I_CODING_TYPE || i_coding_type == P_CODING_TYPE );
- intf_DbgMsg("vpar debug: synchro image %i - modulo is %i\n", i_coding_type, p_vpar->synchro.modulo);
- intf_DbgMsg("vpar debug: synchro predict P %e - predict B %e\n", p_vpar->synchro.p_count_predict, p_vpar->synchro.b_count_predict);
+ mtime_t i_delay = p_vpar->synchro.i_last_decode_pts - mdate();
+
+ switch( i_coding_type )
+ {
+ case I_CODING_TYPE:
+
+ return( p_vpar->synchro.can_display_i );
+
+ case P_CODING_TYPE:
+
+ if( p_vpar->synchro.can_display_p )
+ return( 1 );
+
+ if( p_vpar->synchro.displayable_p * i_delay
+ < p_vpar->synchro.i_mean_decode_time )
+ {
+ //fprintf( stderr, "trashed a P\n");
+ return( 0 );
+ }
+
+ p_vpar->synchro.displayable_p--;
+ return( 1 );
+
+ case B_CODING_TYPE:
+
+ if( p_vpar->synchro.can_display_b )
+ return( 1 );
+
+ /* modulo & 0x3 is here to add some randomness */
+ if( i_delay < (1 + (p_vpar->synchro.modulo & 0x3))
+ * p_vpar->synchro.i_mean_decode_time )
+ {
+ //fprintf( stderr, "trashed a B\n");
+ return( 0 );
+ }
+
+ if( p_vpar->synchro.displayable_b <= 0 )
+ return( 0 );
+
+ p_vpar->synchro.displayable_b--;
+ return( 1 );
+ }
+
+ return( 0 );
- return(0);
- return( i_coding_type == I_CODING_TYPE );
}
/*****************************************************************************
void vpar_SynchroTrash( vpar_thread_t * p_vpar, int i_coding_type,
int i_structure )
{
- vpar_SynchroUpdateStructures (p_vpar, i_coding_type);
+ vpar_SynchroUpdateStructures (p_vpar, i_coding_type, 1);
}
void vpar_SynchroDecode( vpar_thread_t * p_vpar, int i_coding_type,
int i_structure )
{
- vpar_SynchroUpdateStructures (p_vpar, i_coding_type);
+ vpar_SynchroUpdateStructures (p_vpar, i_coding_type, 0);
+
+ p_vpar->synchro.fifo[p_vpar->synchro.i_fifo_stop].i_decode_date = mdate();
+ p_vpar->synchro.fifo[p_vpar->synchro.i_fifo_stop].i_image_type
+ = i_coding_type;
+
+ p_vpar->synchro.i_fifo_stop = (p_vpar->synchro.i_fifo_stop + 1) & 0xf;
}
*****************************************************************************/
void vpar_SynchroEnd( vpar_thread_t * p_vpar )
{
-
-// return mdate() + 700000;
+ mtime_t i_decode_time;
+
+ i_decode_time = (mdate() -
+ p_vpar->synchro.fifo[p_vpar->synchro.i_fifo_start].i_decode_date)
+ / (p_vpar->synchro.i_fifo_stop - p_vpar->synchro.i_fifo_start & 0x0f);
+
+ p_vpar->synchro.i_mean_decode_time =
+ ( 7 * p_vpar->synchro.i_mean_decode_time + i_decode_time ) / 8;
+
+ /* fprintf (stderr,
+ "decoding time was %lli\n",
+ p_vpar->synchro.i_mean_decode_time); */
+
+ p_vpar->synchro.i_fifo_start = (p_vpar->synchro.i_fifo_start + 1) & 0xf;
+
}
+/*****************************************************************************
+ * vpar_SynchroDate : When an image has been decoded, ask for its date
+ *****************************************************************************/
mtime_t vpar_SynchroDate( vpar_thread_t * p_vpar )
{
- return mdate() + 700000;
+ mtime_t i_displaydate = p_vpar->synchro.i_last_display_pts;
+
+#if 0
+ static mtime_t i_delta = 0;
+
+ fprintf( stderr,
+ "displaying type %i with delay %lli and delta %lli\n",
+ p_vpar->synchro.fifo[p_vpar->synchro.i_fifo_start].i_image_type,
+ i_displaydate - mdate(),
+ i_displaydate - i_delta );
+
+ fprintf (stderr,
+ "theorical fps: %f - actual fps: %f \n",
+ p_vpar->synchro.theorical_fps, p_vpar->synchro.actual_fps );
+
+ i_delta = i_displaydate;
+#endif
+
+ return i_displaydate;
}