{
// Get the properties of the a frame
mlt_properties properties = mlt_frame_properties( frame );
- double gain = mlt_properties_get_double( properties, "gain" );
+ double gain = mlt_properties_get_double( properties, "volume.gain" );
double max_gain = mlt_properties_get_double( properties, "volume.max_gain" );
double limiter_level = 0.5; /* -6 dBFS */
int normalise = mlt_properties_get_int( properties, "volume.normalise" );
double amplitude = mlt_properties_get_double( properties, "volume.amplitude" );
- int i;
+ int i, j;
double sample;
int16_t peak;
+ // Get the filter from the frame
+ mlt_filter this = mlt_properties_get_data( properties, "filter_volume", NULL );
+
+ // Get the properties from the filter
+ mlt_properties filter_props = mlt_filter_properties( this );
+
if ( mlt_properties_get( properties, "volume.limiter" ) != NULL )
limiter_level = mlt_properties_get_double( properties, "volume.limiter" );
// Get the producer's audio
mlt_frame_get_audio( frame, buffer, format, frequency, channels, samples );
+// fprintf( stderr, "filter_volume: frequency %d\n", *frequency );
// Determine numeric limits
int bytes_per_samp = (samp_width - 1) / 8 + 1;
if ( normalise )
{
- int window = mlt_properties_get_int( properties, "volume.window" );
- double *smooth_buffer = mlt_properties_get_data( properties, "volume.smooth_buffer", NULL );
- int *smooth_index = mlt_properties_get_data( properties, "volume.smooth_index", NULL );
+ int window = mlt_properties_get_int( filter_props, "window" );
+ double *smooth_buffer = mlt_properties_get_data( filter_props, "smooth_buffer", NULL );
+ int *smooth_index = mlt_properties_get_data( filter_props, "smooth_index", NULL );
if ( window > 0 && smooth_buffer != NULL )
{
*smooth_index = ( *smooth_index + 1 ) % window;
// Smooth the data and compute the gain
- //fprintf( stderr, "smoothed %f over %d frames\n", get_smoothed_data( smooth_buffer, window ), window );
+// fprintf( stderr, "smoothed %f over %d frames\n", get_smoothed_data( smooth_buffer, window ), window );
gain *= amplitude / get_smoothed_data( smooth_buffer, window );
}
}
else
{
- gain = amplitude / signal_max_power( *buffer, *channels, *samples, &peak );
+ gain *= amplitude / signal_max_power( *buffer, *channels, *samples, &peak );
}
}
if ( max_gain > 0 && gain > max_gain )
gain = max_gain;
+ // Initialise filter's previous gain value to prevent an inadvertant jump from 0
+ if ( mlt_properties_get( filter_props, "previous_gain" ) == NULL )
+ mlt_properties_set_double( filter_props, "previous_gain", gain );
+
+ // Start the gain out at the previous
+ double previous_gain = mlt_properties_get_double( filter_props, "previous_gain" );
+
+ // Determine ramp increment
+ double gain_step = ( gain - previous_gain ) / *samples;
+// fprintf( stderr, "filter_volume: previous gain %f current gain %f step %f\n", previous_gain, gain, gain_step );
+
+ // Save the current gain for the next iteration
+ mlt_properties_set_double( filter_props, "previous_gain", gain );
+
+ // Ramp from the previous gain to the current
+ gain = previous_gain;
+
+ int16_t *p = *buffer;
+
// Apply the gain
- for ( i = 0; i < ( *channels * *samples ); i++ )
+ for ( i = 0; i < *samples; i++ )
{
- sample = (*buffer)[i] * gain;
- (*buffer)[i] = ROUND( sample );
-
- if ( gain > 1.0 )
+ for ( j = 0; j < *channels; j++ )
{
- /* use limiter function instead of clipping */
- if ( normalise )
- (*buffer)[i] = ROUND( samplemax * limiter( sample / (double) samplemax, limiter_level ) );
+ sample = *p * gain;
+ *p = ROUND( sample );
+
+ if ( gain > 1.0 )
+ {
+ /* use limiter function instead of clipping */
+ if ( normalise )
+ *p = ROUND( samplemax * limiter( sample / (double) samplemax, limiter_level ) );
- /* perform clipping */
- else if ( sample > samplemax )
- (*buffer)[i] = samplemax;
- else if ( sample < samplemin )
- (*buffer)[i] = samplemin;
+ /* perform clipping */
+ else if ( sample > samplemax )
+ *p = samplemax;
+ else if ( sample < samplemin )
+ *p = samplemin;
+ }
+ p++;
}
+ gain += gain_step;
}
return 0;
mlt_properties properties = mlt_frame_properties( frame );
mlt_properties filter_props = mlt_filter_properties( this );
- // Propogate the gain property
+ // Parse the gain property
if ( mlt_properties_get( properties, "gain" ) == NULL )
{
double gain = 1.0; // no adjustment
/* check if "dB" is given after number */
if ( strncaseeq( p, "db", 2 ) )
gain = DBFSTOAMP( gain );
+
+ // If there is an end adjust gain to the range
+ if ( mlt_properties_get( filter_props, "end" ) != NULL )
+ {
+ // Determine the time position of this frame in the transition duration
+ mlt_position in = mlt_filter_get_in( this );
+ mlt_position out = mlt_filter_get_out( this );
+ mlt_position time = mlt_frame_get_position( frame );
+ double position = ( double )( time - in ) / ( double )( out - in + 1 );
+
+ double end = -1;
+ char *p = mlt_properties_get( filter_props, "end" );
+ if ( strcmp( p, "" ) != 0 )
+ end = fabs( strtod( p, &p) );
+
+ while ( isspace( *p ) )
+ p++;
+
+ /* check if "dB" is given after number */
+ if ( strncaseeq( p, "db", 2 ) )
+ end = DBFSTOAMP( gain );
+
+ if ( end != -1 )
+ gain += ( end - gain ) * position;
+ }
}
}
- mlt_properties_set_double( properties, "gain", gain );
+ mlt_properties_set_double( properties, "volume.gain", gain );
}
- // Propogate the maximum gain property
+ // Parse the maximum gain property
if ( mlt_properties_get( filter_props, "max_gain" ) != NULL )
{
char *p = mlt_properties_get( filter_props, "max_gain" );
mlt_properties_set_double( properties, "volume.max_gain", gain );
}
- // Parse and propogate the limiter property
+ // Parse the limiter property
if ( mlt_properties_get( filter_props, "limiter" ) != NULL )
{
char *p = mlt_properties_get( filter_props, "limiter" );
mlt_properties_set_double( properties, "volume.limiter", level );
}
- // Parse and propogate the normalise property
+ // Parse the normalise property
if ( mlt_properties_get( filter_props, "normalise" ) != NULL )
{
char *p = mlt_properties_get( filter_props, "normalise" );
if ( amplitude > 1.0 )
amplitude = 1.0;
}
+
+ // If there is an end adjust gain to the range
+ if ( mlt_properties_get( filter_props, "end" ) != NULL )
+ {
+ // Determine the time position of this frame in the transition duration
+ mlt_position in = mlt_filter_get_in( this );
+ mlt_position out = mlt_filter_get_out( this );
+ mlt_position time = mlt_frame_get_position( frame );
+ double position = ( double )( time - in ) / ( double )( out - in + 1 );
+ amplitude *= position;
+ }
mlt_properties_set_int( properties, "volume.normalise", 1 );
mlt_properties_set_double( properties, "volume.amplitude", amplitude );
}
+ // Parse the window property and allocate smoothing buffer if needed
int window = mlt_properties_get_int( filter_props, "window" );
if ( mlt_properties_get( filter_props, "smooth_buffer" ) == NULL && window > 1 )
{
mlt_properties_set_data( filter_props, "smooth_index", smooth_index, 0, free, NULL );
}
- // Propogate the smoothing buffer properties
- mlt_properties_set_int( properties, "volume.window", window );
- mlt_properties_set_data( properties, "volume.smooth_buffer",
- mlt_properties_get_data( filter_props, "smooth_buffer", NULL ), 0, NULL, NULL );
- mlt_properties_set_data( properties, "volume.smooth_index",
- mlt_properties_get_data( filter_props, "smooth_index", NULL ), 0, NULL, NULL );
+ // Put a filter reference onto the frame
+ mlt_properties_set_data( properties, "filter_volume", this, 0, NULL, NULL );
// Backup the original get_audio (it's still needed)
mlt_properties_set_data( properties, "volume.get_audio", frame->get_audio, 0, NULL, NULL );