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/* rorate.c
Copyright (c) 2003-2012 HandBrake Team
This file is part of the HandBrake source code
Homepage: <http://handbrake.fr/>.
It may be used under the terms of the GNU General Public License v2.
For full terms see the file COPYING file or visit http://www.gnu.org/licenses/gpl-2.0.html
*/
#include "hb.h"
#include "hbffmpeg.h"
//#include "mpeg2dec/mpeg2.h"
#include "taskset.h"
#define MODE_DEFAULT 3
// Mode 1: Flip vertically (y0 becomes yN and yN becomes y0)
// Mode 2: Flip horizontally (x0 becomes xN and xN becomes x0)
// Mode 3: Flip both horizontally and vertically (modes 1 and 2 combined)
typedef struct rotate_arguments_s {
hb_buffer_t *dst;
hb_buffer_t *src;
} rotate_arguments_t;
struct hb_filter_private_s
{
int mode;
int width;
int height;
int par_width;
int par_height;
int cpu_count;
taskset_t rotate_taskset; // Threads for Rotate - one per CPU
rotate_arguments_t *rotate_arguments; // Arguments to thread for work
};
static int hb_rotate_init( hb_filter_object_t * filter,
hb_filter_init_t * init );
static int hb_rotate_work( hb_filter_object_t * filter,
hb_buffer_t ** buf_in,
hb_buffer_t ** buf_out );
static void hb_rotate_close( hb_filter_object_t * filter );
static int hb_rotate_info( hb_filter_object_t * filter,
hb_filter_info_t * info );
hb_filter_object_t hb_filter_rotate =
{
.id = HB_FILTER_ROTATE,
.enforce_order = 0,
.name = "Rotate (rotate & flip image axes)",
.settings = NULL,
.init = hb_rotate_init,
.work = hb_rotate_work,
.close = hb_rotate_close,
.info = hb_rotate_info
};
typedef struct rotate_thread_arg_s {
hb_filter_private_t *pv;
int segment;
} rotate_thread_arg_t;
/*
* rotate this segment of all three planes in a single thread.
*/
void rotate_filter_thread( void *thread_args_v )
{
rotate_arguments_t *rotate_work = NULL;
hb_filter_private_t * pv;
int run = 1;
int plane;
int segment, segment_start, segment_stop;
rotate_thread_arg_t *thread_args = thread_args_v;
uint8_t *dst;
hb_buffer_t *dst_buf;
hb_buffer_t *src_buf;
int y;
pv = thread_args->pv;
segment = thread_args->segment;
hb_log("Rotate thread started for segment %d", segment);
while( run )
{
/*
* Wait here until there is work to do.
*/
taskset_thread_wait4start( &pv->rotate_taskset, segment );
if( taskset_thread_stop( &pv->rotate_taskset, segment ) )
{
/*
* No more work to do, exit this thread.
*/
run = 0;
goto report_completion;
}
rotate_work = &pv->rotate_arguments[segment];
if( rotate_work->dst == NULL )
{
hb_error( "Thread started when no work available" );
hb_snooze(500);
goto report_completion;
}
/*
* Process all three planes, but only this segment of it.
*/
dst_buf = rotate_work->dst;
src_buf = rotate_work->src;
for( plane = 0; plane < 3; plane++)
{
int dst_stride, src_stride;
dst = dst_buf->plane[plane].data;
dst_stride = dst_buf->plane[plane].stride;
src_stride = src_buf->plane[plane].stride;
int h = src_buf->plane[plane].height;
int w = src_buf->plane[plane].width;
segment_start = ( h / pv->cpu_count ) * segment;
if( segment == pv->cpu_count - 1 )
{
/*
* Final segment
*/
segment_stop = h;
} else {
segment_stop = ( h / pv->cpu_count ) * ( segment + 1 );
}
for( y = segment_start; y < segment_stop; y++ )
{
uint8_t * cur;
int x, xo, yo;
cur = &src_buf->plane[plane].data[y * src_stride];
for( x = 0; x < w; x++)
{
if( pv->mode & 1 )
{
yo = h - y - 1;
}
else
{
yo = y;
}
if( pv->mode & 2 )
{
xo = w - x - 1;
}
else
{
xo = x;
}
if( pv->mode & 4 ) // Rotate 90 clockwise
{
int tmp = xo;
xo = h - yo - 1;
yo = tmp;
}
dst[yo*dst_stride + xo] = cur[x];
}
}
}
report_completion:
/*
* Finished this segment, let everyone know.
*/
taskset_thread_complete( &pv->rotate_taskset, segment );
}
}
/*
* threaded rotate - each thread rotates a single segment of all
* three planes. Where a segment is defined as the frame divided by
* the number of CPUs.
*
* This function blocks until the frame is rotated.
*/
static void rotate_filter(
hb_filter_private_t * pv,
hb_buffer_t *out,
hb_buffer_t *in )
{
int segment;
for( segment = 0; segment < pv->cpu_count; segment++ )
{
/*
* Setup the work for this plane.
*/
pv->rotate_arguments[segment].dst = out;
pv->rotate_arguments[segment].src = in;
}
/*
* Allow the taskset threads to make one pass over the data.
*/
taskset_cycle( &pv->rotate_taskset );
/*
* Entire frame is now rotated.
*/
}
static int hb_rotate_init( hb_filter_object_t * filter,
hb_filter_init_t * init )
{
filter->private_data = calloc( 1, sizeof(struct hb_filter_private_s) );
hb_filter_private_t * pv = filter->private_data;
pv->mode = MODE_DEFAULT;
if( filter->settings )
{
sscanf( filter->settings, "%d",
&pv->mode );
}
pv->cpu_count = hb_get_cpu_count();
/*
* Create rotate taskset.
*/
pv->rotate_arguments = malloc( sizeof( rotate_arguments_t ) * pv->cpu_count );
if( pv->rotate_arguments == NULL ||
taskset_init( &pv->rotate_taskset, /*thread_count*/pv->cpu_count,
sizeof( rotate_thread_arg_t ) ) == 0 )
{
hb_error( "rotate could not initialize taskset" );
}
int i;
for( i = 0; i < pv->cpu_count; i++ )
{
rotate_thread_arg_t *thread_args;
thread_args = taskset_thread_args( &pv->rotate_taskset, i );
thread_args->pv = pv;
thread_args->segment = i;
pv->rotate_arguments[i].dst = NULL;
if( taskset_thread_spawn( &pv->rotate_taskset, i,
"rotate_filter_segment",
rotate_filter_thread,
HB_NORMAL_PRIORITY ) == 0 )
{
hb_error( "rotate could not spawn thread" );
}
}
// Set init width/height so the next stage in the pipline
// knows what it will be getting
if( pv->mode & 4 )
{
// 90 degree rotation, exchange width and height
int tmp = init->width;
init->width = init->height;
init->height = tmp;
tmp = init->par_width;
init->par_width = init->par_height;
init->par_height = tmp;
}
pv->width = init->width;
pv->height = init->height;
pv->par_width = init->par_width;
pv->par_height = init->par_height;
return 0;
}
static int hb_rotate_info( hb_filter_object_t * filter,
hb_filter_info_t * info )
{
hb_filter_private_t * pv = filter->private_data;
if( !pv )
return 1;
memset( info, 0, sizeof( hb_filter_info_t ) );
info->out.width = pv->width;
info->out.height = pv->height;
info->out.par_width = pv->par_width;
info->out.par_height = pv->par_height;
int pos = 0;
if( pv->mode & 1 )
pos += sprintf( &info->human_readable_desc[pos], "flip vertical" );
if( pv->mode & 2 )
{
if( pos )
pos += sprintf( &info->human_readable_desc[pos], "/" );
pos += sprintf( &info->human_readable_desc[pos], "flip horizontal" );
}
if( pv->mode & 4 )
{
if( pos )
pos += sprintf( &info->human_readable_desc[pos], "/" );
pos += sprintf( &info->human_readable_desc[pos], "rotate 90" );
}
return 0;
}
static void hb_rotate_close( hb_filter_object_t * filter )
{
hb_filter_private_t * pv = filter->private_data;
if( !pv )
{
return;
}
taskset_fini( &pv->rotate_taskset );
/*
* free memory for rotate structs
*/
free( pv->rotate_arguments );
free( pv );
filter->private_data = NULL;
}
static int hb_rotate_work( hb_filter_object_t * filter,
hb_buffer_t ** buf_in,
hb_buffer_t ** buf_out )
{
hb_filter_private_t * pv = filter->private_data;
hb_buffer_t * in = *buf_in, * out;
if ( in->size <= 0 )
{
*buf_out = in;
*buf_in = NULL;
return HB_FILTER_DONE;
}
int width_out, height_out;
if ( pv->mode & 4 )
{
width_out = in->f.height;
height_out = in->f.width;
}
else
{
width_out = in->f.width;
height_out = in->f.height;
}
out = hb_video_buffer_init( width_out, height_out );
// Rotate!
rotate_filter( pv, out, in );
out->s = in->s;
hb_buffer_move_subs( out, in );
*buf_out = out;
return HB_FILTER_OK;
}
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