/*****************************************************************************
* common.c : audio output management of common data structures
*****************************************************************************
- * Copyright (C) 2002 VideoLAN
- * $Id: common.c,v 1.2 2002/09/30 21:32:33 massiot Exp $
+ * Copyright (C) 2002-2007 the VideoLAN team
+ * $Id$
*
* Authors: Christophe Massiot <massiot@via.ecp.fr>
*
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
- *
+ *
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
- * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111, USA.
+ * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston MA 02110-1301, USA.
*****************************************************************************/
/*****************************************************************************
* Preamble
*****************************************************************************/
-#include <stdlib.h> /* calloc(), malloc(), free() */
-#include <string.h>
-
-#include <vlc/vlc.h>
+#ifdef HAVE_CONFIG_H
+# include "config.h"
+#endif
-#include "audio_output.h"
+#include <vlc_common.h>
+#include <vlc_aout.h>
#include "aout_internal.h"
-
/*
* Instances management (internal and external)
*/
+/* Local functions */
+static void aout_Destructor( vlc_object_t * p_this );
+
/*****************************************************************************
* aout_New: initialize aout structure
*****************************************************************************/
aout_instance_t * __aout_New( vlc_object_t * p_parent )
{
aout_instance_t * p_aout;
+ vlc_value_t val;
/* Allocate descriptor. */
p_aout = vlc_object_create( p_parent, VLC_OBJECT_AOUT );
}
/* Initialize members. */
- vlc_mutex_init( p_parent, &p_aout->input_fifos_lock );
- vlc_mutex_init( p_parent, &p_aout->mixer_lock );
- vlc_mutex_init( p_parent, &p_aout->output_fifo_lock );
+ vlc_mutex_init( &p_aout->input_fifos_lock );
+ vlc_mutex_init( &p_aout->mixer_lock );
+ vlc_mutex_init( &p_aout->output_fifo_lock );
p_aout->i_nb_inputs = 0;
p_aout->mixer.f_multiplier = 1.0;
p_aout->mixer.b_error = 1;
+ p_aout->output.b_error = 1;
+ p_aout->output.b_starving = 1;
+
+ var_Create( p_aout, "intf-change", VLC_VAR_BOOL );
+ val.b_bool = true;
+ var_Set( p_aout, "intf-change", val );
- vlc_object_attach( p_aout, p_parent->p_vlc );
+ vlc_object_set_destructor( p_aout, aout_Destructor );
return p_aout;
}
/*****************************************************************************
- * aout_Delete: destroy aout structure
+ * aout_Destructor: destroy aout structure
*****************************************************************************/
-void aout_Delete( aout_instance_t * p_aout )
+static void aout_Destructor( vlc_object_t * p_this )
{
+ aout_instance_t * p_aout = (aout_instance_t *)p_this;
vlc_mutex_destroy( &p_aout->input_fifos_lock );
vlc_mutex_destroy( &p_aout->mixer_lock );
vlc_mutex_destroy( &p_aout->output_fifo_lock );
-
- /* Free structure. */
- vlc_object_destroy( p_aout );
}
/*****************************************************************************
* aout_FormatNbChannels : return the number of channels
*****************************************************************************/
-int aout_FormatNbChannels( audio_sample_format_t * p_format )
+unsigned int aout_FormatNbChannels( const audio_sample_format_t * p_format )
{
- int i_nb;
+ static const uint32_t pi_channels[] =
+ { AOUT_CHAN_CENTER, AOUT_CHAN_LEFT, AOUT_CHAN_RIGHT,
+ AOUT_CHAN_REARCENTER, AOUT_CHAN_REARLEFT, AOUT_CHAN_REARRIGHT,
+ AOUT_CHAN_MIDDLELEFT, AOUT_CHAN_MIDDLERIGHT, AOUT_CHAN_LFE };
+ unsigned int i_nb = 0, i;
- switch ( p_format->i_channels & AOUT_CHAN_MASK )
+ for ( i = 0; i < sizeof(pi_channels)/sizeof(uint32_t); i++ )
{
- case AOUT_CHAN_CHANNEL1:
- case AOUT_CHAN_CHANNEL2:
- case AOUT_CHAN_MONO:
- i_nb = 1;
- break;
-
- case AOUT_CHAN_CHANNEL:
- case AOUT_CHAN_STEREO:
- case AOUT_CHAN_DOLBY:
- i_nb = 2;
- break;
-
- case AOUT_CHAN_3F:
- case AOUT_CHAN_2F1R:
- i_nb = 3;
- break;
-
- case AOUT_CHAN_3F1R:
- case AOUT_CHAN_2F2R:
- i_nb = 4;
- break;
-
- case AOUT_CHAN_3F2R:
- i_nb = 5;
- break;
-
- default:
- i_nb = 0;
+ if ( p_format->i_physical_channels & pi_channels[i] ) i_nb++;
}
- if ( p_format->i_channels & AOUT_CHAN_LFE )
- return i_nb + 1;
- else
- return i_nb;
+ return i_nb;
}
/*****************************************************************************
- * aout_FormatPrepare : compute the number of bytes per frame & frame length
+ * aout_BitsPerSample : get the number of bits per sample
*****************************************************************************/
-void aout_FormatPrepare( audio_sample_format_t * p_format )
+unsigned int aout_BitsPerSample( vlc_fourcc_t i_format )
{
- int i_result;
-
- switch ( p_format->i_format )
+ switch( i_format )
{
case VLC_FOURCC('u','8',' ',' '):
case VLC_FOURCC('s','8',' ',' '):
- i_result = 1;
- break;
+ return 8;
case VLC_FOURCC('u','1','6','l'):
case VLC_FOURCC('s','1','6','l'):
case VLC_FOURCC('u','1','6','b'):
case VLC_FOURCC('s','1','6','b'):
- i_result = 2;
- break;
+ return 16;
+
+ case VLC_FOURCC('u','2','4','l'):
+ case VLC_FOURCC('s','2','4','l'):
+ case VLC_FOURCC('u','2','4','b'):
+ case VLC_FOURCC('s','2','4','b'):
+ return 24;
case VLC_FOURCC('f','l','3','2'):
case VLC_FOURCC('f','i','3','2'):
- i_result = 4;
- break;
+ return 32;
+
+ case VLC_FOURCC('f','l','6','4'):
+ return 64;
- case VLC_FOURCC('s','p','d','i'):
- case VLC_FOURCC('a','5','2',' '):
- case VLC_FOURCC('d','t','s',' '):
default:
/* For these formats the caller has to indicate the parameters
* by hand. */
- return;
+ return 0;
+ }
+}
+
+/*****************************************************************************
+ * aout_FormatPrepare : compute the number of bytes per frame & frame length
+ *****************************************************************************/
+void aout_FormatPrepare( audio_sample_format_t * p_format )
+{
+ p_format->i_bitspersample = aout_BitsPerSample( p_format->i_format );
+ if( p_format->i_bitspersample > 0 )
+ {
+ p_format->i_bytes_per_frame = ( p_format->i_bitspersample / 8 )
+ * aout_FormatNbChannels( p_format );
+ p_format->i_frame_length = 1;
+ }
+}
+
+/*****************************************************************************
+ * aout_FormatPrintChannels : print a channel in a human-readable form
+ *****************************************************************************/
+const char * aout_FormatPrintChannels( const audio_sample_format_t * p_format )
+{
+ switch ( p_format->i_physical_channels & AOUT_CHAN_PHYSMASK )
+ {
+ case AOUT_CHAN_CENTER:
+ if ( (p_format->i_original_channels & AOUT_CHAN_CENTER)
+ || (p_format->i_original_channels
+ & (AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT)) )
+ return "Mono";
+ else if ( p_format->i_original_channels & AOUT_CHAN_LEFT )
+ return "Left";
+ return "Right";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT:
+ if ( p_format->i_original_channels & AOUT_CHAN_REVERSESTEREO )
+ {
+ if ( p_format->i_original_channels & AOUT_CHAN_DOLBYSTEREO )
+ return "Dolby/Reverse";
+ return "Stereo/Reverse";
+ }
+ else
+ {
+ if ( p_format->i_original_channels & AOUT_CHAN_DOLBYSTEREO )
+ return "Dolby";
+ else if ( p_format->i_original_channels & AOUT_CHAN_DUALMONO )
+ return "Dual-mono";
+ else if ( p_format->i_original_channels == AOUT_CHAN_CENTER )
+ return "Stereo/Mono";
+ else if ( !(p_format->i_original_channels & AOUT_CHAN_RIGHT) )
+ return "Stereo/Left";
+ else if ( !(p_format->i_original_channels & AOUT_CHAN_LEFT) )
+ return "Stereo/Right";
+ return "Stereo";
+ }
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_CENTER:
+ return "3F";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_REARCENTER:
+ return "2F1R";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_CENTER
+ | AOUT_CHAN_REARCENTER:
+ return "3F1R";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT
+ | AOUT_CHAN_REARLEFT | AOUT_CHAN_REARRIGHT:
+ return "2F2R";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_CENTER
+ | AOUT_CHAN_REARLEFT | AOUT_CHAN_REARRIGHT:
+ return "3F2R";
+
+ case AOUT_CHAN_CENTER | AOUT_CHAN_LFE:
+ if ( (p_format->i_original_channels & AOUT_CHAN_CENTER)
+ || (p_format->i_original_channels
+ & (AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT)) )
+ return "Mono/LFE";
+ else if ( p_format->i_original_channels & AOUT_CHAN_LEFT )
+ return "Left/LFE";
+ return "Right/LFE";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_LFE:
+ if ( p_format->i_original_channels & AOUT_CHAN_DOLBYSTEREO )
+ return "Dolby/LFE";
+ else if ( p_format->i_original_channels & AOUT_CHAN_DUALMONO )
+ return "Dual-mono/LFE";
+ else if ( p_format->i_original_channels == AOUT_CHAN_CENTER )
+ return "Mono/LFE";
+ else if ( !(p_format->i_original_channels & AOUT_CHAN_RIGHT) )
+ return "Stereo/Left/LFE";
+ else if ( !(p_format->i_original_channels & AOUT_CHAN_LEFT) )
+ return "Stereo/Right/LFE";
+ return "Stereo/LFE";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_CENTER | AOUT_CHAN_LFE:
+ return "3F/LFE";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_REARCENTER
+ | AOUT_CHAN_LFE:
+ return "2F1R/LFE";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_CENTER
+ | AOUT_CHAN_REARCENTER | AOUT_CHAN_LFE:
+ return "3F1R/LFE";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT
+ | AOUT_CHAN_REARLEFT | AOUT_CHAN_REARRIGHT | AOUT_CHAN_LFE:
+ return "2F2R/LFE";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_CENTER
+ | AOUT_CHAN_REARLEFT | AOUT_CHAN_REARRIGHT | AOUT_CHAN_LFE:
+ return "3F2R/LFE";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_CENTER
+ | AOUT_CHAN_REARLEFT | AOUT_CHAN_REARRIGHT | AOUT_CHAN_MIDDLELEFT
+ | AOUT_CHAN_MIDDLERIGHT:
+ return "3F2M2R";
+ case AOUT_CHAN_LEFT | AOUT_CHAN_RIGHT | AOUT_CHAN_CENTER
+ | AOUT_CHAN_REARLEFT | AOUT_CHAN_REARRIGHT | AOUT_CHAN_MIDDLELEFT
+ | AOUT_CHAN_MIDDLERIGHT | AOUT_CHAN_LFE:
+ return "3F2M2R/LFE";
}
- p_format->i_bytes_per_frame = i_result * aout_FormatNbChannels( p_format );
- p_format->i_frame_length = 1;
+ return "ERROR";
+}
+
+/*****************************************************************************
+ * aout_FormatPrint : print a format in a human-readable form
+ *****************************************************************************/
+void aout_FormatPrint( aout_instance_t * p_aout, const char * psz_text,
+ const audio_sample_format_t * p_format )
+{
+ msg_Dbg( p_aout, "%s '%4.4s' %d Hz %s frame=%d samples/%d bytes", psz_text,
+ (char *)&p_format->i_format, p_format->i_rate,
+ aout_FormatPrintChannels( p_format ),
+ p_format->i_frame_length, p_format->i_bytes_per_frame );
+}
+
+/*****************************************************************************
+ * aout_FormatsPrint : print two formats in a human-readable form
+ *****************************************************************************/
+void aout_FormatsPrint( aout_instance_t * p_aout, const char * psz_text,
+ const audio_sample_format_t * p_format1,
+ const audio_sample_format_t * p_format2 )
+{
+ msg_Dbg( p_aout, "%s '%4.4s'->'%4.4s' %d Hz->%d Hz %s->%s",
+ psz_text,
+ (char *)&p_format1->i_format, (char *)&p_format2->i_format,
+ p_format1->i_rate, p_format2->i_rate,
+ aout_FormatPrintChannels( p_format1 ),
+ aout_FormatPrintChannels( p_format2 ) );
}
* aout_FifoInit : initialize the members of a FIFO
*****************************************************************************/
void aout_FifoInit( aout_instance_t * p_aout, aout_fifo_t * p_fifo,
- u32 i_rate )
+ uint32_t i_rate )
{
+ if( i_rate == 0 )
+ {
+ msg_Err( p_aout, "initialising fifo with zero divider" );
+ }
+
p_fifo->p_first = NULL;
p_fifo->pp_last = &p_fifo->p_first;
aout_DateInit( &p_fifo->end_date, i_rate );
void aout_FifoPush( aout_instance_t * p_aout, aout_fifo_t * p_fifo,
aout_buffer_t * p_buffer )
{
+ (void)p_aout;
*p_fifo->pp_last = p_buffer;
p_fifo->pp_last = &p_buffer->p_next;
*p_fifo->pp_last = NULL;
{
p_buffer->start_date = aout_DateGet( &p_fifo->end_date );
p_buffer->end_date = aout_DateIncrement( &p_fifo->end_date,
- p_buffer->i_nb_samples );
+ p_buffer->i_nb_samples );
}
else
{
mtime_t date )
{
aout_buffer_t * p_buffer;
+ (void)p_aout;
aout_DateSet( &p_fifo->end_date, date );
p_buffer = p_fifo->p_first;
mtime_t difference )
{
aout_buffer_t * p_buffer;
+ (void)p_aout;
aout_DateMove( &p_fifo->end_date, difference );
p_buffer = p_fifo->p_first;
*****************************************************************************/
mtime_t aout_FifoNextStart( aout_instance_t * p_aout, aout_fifo_t * p_fifo )
{
+ (void)p_aout;
return aout_DateGet( &p_fifo->end_date );
}
+/*****************************************************************************
+ * aout_FifoFirstDate : return the playing date of the first buffer in the
+ * FIFO
+ *****************************************************************************/
+mtime_t aout_FifoFirstDate( aout_instance_t * p_aout, aout_fifo_t * p_fifo )
+{
+ (void)p_aout;
+ return p_fifo->p_first ? p_fifo->p_first->start_date : 0;
+}
+
/*****************************************************************************
* aout_FifoPop : get the next buffer out of the FIFO
*****************************************************************************/
aout_buffer_t * aout_FifoPop( aout_instance_t * p_aout, aout_fifo_t * p_fifo )
{
aout_buffer_t * p_buffer;
+ (void)p_aout;
+
p_buffer = p_fifo->p_first;
if ( p_buffer == NULL ) return NULL;
p_fifo->p_first = p_buffer->p_next;
void aout_FifoDestroy( aout_instance_t * p_aout, aout_fifo_t * p_fifo )
{
aout_buffer_t * p_buffer;
+ (void)p_aout;
p_buffer = p_fifo->p_first;
while ( p_buffer != NULL )
aout_BufferFree( p_buffer );
p_buffer = p_next;
}
+
+ p_fifo->p_first = NULL;
+ p_fifo->pp_last = &p_fifo->p_first;
}
/*****************************************************************************
* aout_DateInit : set the divider of an audio_date_t
*****************************************************************************/
-void aout_DateInit( audio_date_t * p_date, u32 i_divider )
+void aout_DateInit( audio_date_t * p_date, uint32_t i_divider )
{
p_date->date = 0;
p_date->i_divider = i_divider;
* aout_DateIncrement : increment the date and return the result, taking
* into account rounding errors
*****************************************************************************/
-mtime_t aout_DateIncrement( audio_date_t * p_date, u32 i_nb_samples )
+mtime_t aout_DateIncrement( audio_date_t * p_date, uint32_t i_nb_samples )
{
mtime_t i_dividend = (mtime_t)i_nb_samples * 1000000;
p_date->date += i_dividend / p_date->i_divider;
- p_date->i_remainder += i_dividend % p_date->i_divider;
+ p_date->i_remainder += (int)(i_dividend % p_date->i_divider);
if ( p_date->i_remainder >= p_date->i_divider )
{
/* This is Bresenham algorithm. */
return p_date->date;
}
+/*****************************************************************************
+ * aout_CheckChannelReorder : Check if we need to do some channel re-ordering
+ *****************************************************************************/
+int aout_CheckChannelReorder( const uint32_t *pi_chan_order_in,
+ const uint32_t *pi_chan_order_out,
+ uint32_t i_channel_mask,
+ int i_channels, int *pi_chan_table )
+{
+ bool b_chan_reorder = false;
+ int i, j, k, l;
+
+ if( i_channels > AOUT_CHAN_MAX ) return false;
+
+ for( i = 0, j = 0; pi_chan_order_in[i]; i++ )
+ {
+ if( !(i_channel_mask & pi_chan_order_in[i]) ) continue;
+
+ for( k = 0, l = 0; pi_chan_order_in[i] != pi_chan_order_out[k]; k++ )
+ {
+ if( i_channel_mask & pi_chan_order_out[k] ) l++;
+ }
+
+ pi_chan_table[j++] = l;
+ }
+
+ for( i = 0; i < i_channels; i++ )
+ {
+ if( pi_chan_table[i] != i ) b_chan_reorder = true;
+ }
+
+ return b_chan_reorder;
+}
+
+/*****************************************************************************
+ * aout_ChannelReorder :
+ *****************************************************************************/
+void aout_ChannelReorder( uint8_t *p_buf, int i_buffer,
+ int i_channels, const int *pi_chan_table,
+ int i_bits_per_sample )
+{
+ uint8_t p_tmp[AOUT_CHAN_MAX * 4];
+ int i, j;
+
+ if( i_bits_per_sample == 8 )
+ {
+ for( i = 0; i < i_buffer / i_channels; i++ )
+ {
+ for( j = 0; j < i_channels; j++ )
+ {
+ p_tmp[pi_chan_table[j]] = p_buf[j];
+ }
+
+ memcpy( p_buf, p_tmp, i_channels );
+ p_buf += i_channels;
+ }
+ }
+ else if( i_bits_per_sample == 16 )
+ {
+ for( i = 0; i < i_buffer / i_channels / 2; i++ )
+ {
+ for( j = 0; j < i_channels; j++ )
+ {
+ p_tmp[2 * pi_chan_table[j]] = p_buf[2 * j];
+ p_tmp[2 * pi_chan_table[j] + 1] = p_buf[2 * j + 1];
+ }
+
+ memcpy( p_buf, p_tmp, 2 * i_channels );
+ p_buf += 2 * i_channels;
+ }
+ }
+ else if( i_bits_per_sample == 24 )
+ {
+ for( i = 0; i < i_buffer / i_channels / 3; i++ )
+ {
+ for( j = 0; j < i_channels; j++ )
+ {
+ p_tmp[3 * pi_chan_table[j]] = p_buf[3 * j];
+ p_tmp[3 * pi_chan_table[j] + 1] = p_buf[3 * j + 1];
+ p_tmp[3 * pi_chan_table[j] + 2] = p_buf[3 * j + 2];
+ }
+
+ memcpy( p_buf, p_tmp, 3 * i_channels );
+ p_buf += 3 * i_channels;
+ }
+ }
+ else if( i_bits_per_sample == 32 )
+ {
+ for( i = 0; i < i_buffer / i_channels / 4; i++ )
+ {
+ for( j = 0; j < i_channels; j++ )
+ {
+ p_tmp[4 * pi_chan_table[j]] = p_buf[4 * j];
+ p_tmp[4 * pi_chan_table[j] + 1] = p_buf[4 * j + 1];
+ p_tmp[4 * pi_chan_table[j] + 2] = p_buf[4 * j + 2];
+ p_tmp[4 * pi_chan_table[j] + 3] = p_buf[4 * j + 3];
+ }
+
+ memcpy( p_buf, p_tmp, 4 * i_channels );
+ p_buf += 4 * i_channels;
+ }
+ }
+}
projects / vlc / blobdiff