/*
videodevice . cpp - Kopete Video Device Low - level Support
Copyright ( c ) 2005 - 2006 by Cl á udio da Silveira Pinheiro < taupter @ gmail . com >
Kopete ( c ) 2002 - 2003 by the Kopete developers < kopete - devel @ kde . org >
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* *
* This library is free software ; you can redistribute it and / or *
* modify it under the terms of the GNU Lesser General Public *
* License as published by the Free Software Foundation ; either *
* version 2 of the License , or ( at your option ) any later version . *
* *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
*/
# define ENABLE_AV
# include <cstdlib>
# include <cerrno>
# include <cstring>
# include <kdebug.h>
# include "videoinput.h"
# include "videodevice.h"
# include "bayer.h"
# include "sonix_compress.h"
# define CLEAR(x) memset (&(x), 0, sizeof (x))
namespace Kopete {
namespace AV {
VideoDevice : : VideoDevice ( )
{
// kdDebug(14010) << "libkopete (avdevice): VideoDevice() called" << endl;
descriptor = - 1 ;
m_streambuffers = 0 ;
m_current_input = 0 ;
// kdDebug(14010) << "libkopete (avdevice): VideoDevice() exited successfuly" << endl;
maxwidth = 32767 ;
maxheight = 32767 ;
minwidth = 1 ;
minheight = 1 ;
}
VideoDevice : : ~ VideoDevice ( )
{
}
# ifdef V4L2_CAP_VIDEO_CAPTURE
void VideoDevice : : enumerateMenu ( void )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Menu items: " < < endl ;
memset ( & querymenu , 0 , sizeof ( querymenu ) ) ;
querymenu . id = queryctrl . id ;
for ( querymenu . index = queryctrl . minimum ; querymenu . index < = queryctrl . maximum ; querymenu . index + + )
{
if ( 0 = = xioctl ( VIDIOC_QUERYMENU , & querymenu ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " " < < TQString ( TQString : : fromLocal8Bit ( ( const char * ) querymenu . name ) ) < < endl ;
}
else
{
perror ( " VIDIOC_QUERYMENU " ) ;
exit ( EXIT_FAILURE ) ;
}
}
}
# endif
/*!
\ fn VideoDevice : : xioctl ( int fd , int request , void * arg )
*/
int VideoDevice : : xioctl ( int request , void * arg )
{
int r ;
do r = ioctl ( descriptor , request , arg ) ;
while ( - 1 = = r & & EINTR = = errno ) ;
return r ;
}
/*!
\ fn VideoDevice : : errnoReturn ( const char * s )
*/
int VideoDevice : : errnoReturn ( const char * s )
{
/// @todo implement me
fprintf ( stderr , " %s error %d, %s \n " , s , errno , strerror ( errno ) ) ;
return EXIT_FAILURE ;
}
/*!
\ fn VideoDevice : : setFileName ( TQString name )
*/
int VideoDevice : : setFileName ( TQString filename )
{
/// @todo implement me
full_filename = filename ;
return EXIT_SUCCESS ;
}
/*!
\ fn VideoDevice : : open ( )
*/
int VideoDevice : : open ( )
{
/// @todo implement me
kdDebug ( 14010 ) < < k_funcinfo < < " called " < < endl ;
if ( - 1 ! = descriptor )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device is already open " < < endl ;
return EXIT_SUCCESS ;
}
descriptor = : : open ( TQFile : : encodeName ( full_filename ) , O_RDWR , 0 ) ;
if ( isOpen ( ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " File " < < full_filename < < " was opened successfuly " < < endl ;
if ( EXIT_FAILURE = = checkDevice ( ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " File " < < full_filename < < " could not be opened " < < endl ;
close ( ) ;
return EXIT_FAILURE ;
}
}
else
{
kdDebug ( 14010 ) < < k_funcinfo < < " Unable to open file " < < full_filename < < " Err: " < < errno < < endl ;
return EXIT_FAILURE ;
}
initDevice ( ) ;
selectInput ( m_current_input ) ;
kdDebug ( 14010 ) < < k_funcinfo < < " exited successfuly " < < endl ;
return EXIT_SUCCESS ;
}
bool VideoDevice : : isOpen ( )
{
if ( - 1 = = descriptor )
{
// kdDebug(14010) << k_funcinfo << "VideoDevice::isOpen() File is not open" << endl;
return false ;
}
// kdDebug(14010) << k_funcinfo << "VideoDevice::isOpen() File is open" << endl;
return true ;
}
int VideoDevice : : checkDevice ( )
{
kdDebug ( 14010 ) < < k_funcinfo < < " checkDevice() called. " < < endl ;
if ( isOpen ( ) )
{
m_videocapture = false ;
m_videochromakey = false ;
m_videoscale = false ;
m_videooverlay = false ;
m_videoread = false ;
m_videoasyncio = false ;
m_videostream = false ;
m_driver = VIDEODEV_DRIVER_NONE ;
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
//if(!getWorkaroundBrokenDriver())
{
kdDebug ( 14010 ) < < k_funcinfo < < " checkDevice(): " < < full_filename < < " Trying V4L2 API. " < < endl ;
CLEAR ( V4L2_capabilities ) ;
if ( - 1 ! = xioctl ( VIDIOC_QUERYCAP , & V4L2_capabilities ) )
{
if ( ! ( V4L2_capabilities . capabilities & V4L2_CAP_VIDEO_CAPTURE ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " checkDevice(): " < < full_filename < < " is not a video capture device. " < < endl ;
m_driver = VIDEODEV_DRIVER_NONE ;
return EXIT_FAILURE ;
}
m_videocapture = true ;
kdDebug ( 14010 ) < < k_funcinfo < < " checkDevice(): " < < full_filename < < " is a V4L2 device. " < < endl ;
m_driver = VIDEODEV_DRIVER_V4L2 ;
m_model = TQString : : fromLocal8Bit ( ( const char * ) V4L2_capabilities . card ) ;
// Detect maximum and minimum resolution supported by the V4L2 device
CLEAR ( fmt ) ;
fmt . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
if ( - 1 = = xioctl ( VIDIOC_G_FMT , & fmt ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_G_FMT failed ( " < < errno < < " ). " < < endl ;
fmt . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
fmt . fmt . pix . width = 32767 ;
fmt . fmt . pix . height = 32767 ;
fmt . fmt . pix . field = V4L2_FIELD_ANY ;
if ( - 1 = = xioctl ( VIDIOC_S_FMT , & fmt ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Detecting maximum size with VIDIOC_S_FMT failed ( " < < errno < < " ).Returned maxwidth: " < < pixelFormatName ( fmt . fmt . pix . pixelformat ) < < " " < < fmt . fmt . pix . width < < " x " < < fmt . fmt . pix . height < < endl ;
// Note VIDIOC_S_FMT may change width and height.
}
else
{
maxwidth = fmt . fmt . pix . width ;
maxheight = fmt . fmt . pix . height ;
}
if ( - 1 = = xioctl ( VIDIOC_G_FMT , & fmt ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_G_FMT failed ( " < < errno < < " ). " < < endl ;
fmt . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
fmt . fmt . pix . width = 1 ;
fmt . fmt . pix . height = 1 ;
fmt . fmt . pix . field = V4L2_FIELD_ANY ;
if ( - 1 = = xioctl ( VIDIOC_S_FMT , & fmt ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Detecting minimum size with VIDIOC_S_FMT failed ( " < < errno < < " ).Returned maxwidth: " < < fmt . fmt . pix . width < < " x " < < fmt . fmt . pix . height < < endl ;
// Note VIDIOC_S_FMT may change width and height.
}
else
{
minwidth = fmt . fmt . pix . width ;
minheight = fmt . fmt . pix . height ;
}
// Buggy driver paranoia
/* min = fmt.fmt.pix.width * 2;
if ( fmt . fmt . pix . bytesperline < min )
fmt . fmt . pix . bytesperline = min ;
min = fmt . fmt . pix . bytesperline * fmt . fmt . pix . height ;
if ( fmt . fmt . pix . sizeimage < min )
fmt . fmt . pix . sizeimage = min ;
m_buffer_size = fmt . fmt . pix . sizeimage ; */
int inputisok = EXIT_SUCCESS ;
m_input . clear ( ) ;
for ( unsigned int loop = 0 ; inputisok = = EXIT_SUCCESS ; loop + + )
{
struct v4l2_input videoinput ;
CLEAR ( videoinput ) ;
videoinput . index = loop ;
inputisok = xioctl ( VIDIOC_ENUMINPUT , & videoinput ) ;
if ( inputisok = = EXIT_SUCCESS )
{
VideoInput tempinput ;
tempinput . name = TQString : : fromLocal8Bit ( ( const char * ) videoinput . name ) ;
tempinput . hastuner = videoinput . type & V4L2_INPUT_TYPE_TUNER ;
tempinput . m_standards = videoinput . std ;
m_input . push_back ( tempinput ) ;
kdDebug ( 14010 ) < < k_funcinfo < < " Input " < < loop < < " : " < < tempinput . name < < " (tuner: " < < ( ( videoinput . type & V4L2_INPUT_TYPE_TUNER ) ! = 0 ) < < " ) " < < endl ;
if ( ( videoinput . type & V4L2_INPUT_TYPE_TUNER ) ! = 0 )
{
// _tunerForInput[name] = desc.tuner;
// _isTuner = true;
}
else
{
// _tunerForInput[name] = -1;
}
}
}
// -----------------------------------------------------------------------------------------------------------------
// This must turn up to be a proper method to check for controls' existence.
CLEAR ( queryctrl ) ;
// v4l2_queryctrl may zero the .id in some cases, even if the IOCTL returns EXIT_SUCCESS (tested with a bttv card, when testing for V4L2_CID_AUDIO_VOLUME).
// As of 6th Aug 2007, according to the V4L2 specification version 0.21, this behavior is undocumented, and the example 1-8 code found at
// http://www.linuxtv.org/downloads/video4linux/API/V4L2_API/spec/x519.htm fails because of this behavior with a bttv card.
int currentid = V4L2_CID_BASE ;
kdDebug ( 14010 ) < < k_funcinfo < < " Checking CID controls " < < endl ;
for ( currentid = V4L2_CID_BASE ; currentid < V4L2_CID_LASTP1 ; currentid + + )
//for (queryctrl.id = 9963776; queryctrl.id < 9963800; queryctrl.id++)
{
queryctrl . id = currentid ;
//kdDebug(14010) << k_funcinfo << "Checking CID controls from " << V4L2_CID_BASE << " to " << V4L2_CID_LASTP1 << ". Current: " << queryctrl.id << ". IOCTL returns: " << resultado << endl;
if ( 0 = = xioctl ( VIDIOC_QUERYCTRL , & queryctrl ) )
{
if ( queryctrl . flags & V4L2_CTRL_FLAG_DISABLED )
continue ;
//kdDebug(14010) << k_funcinfo << " Control: " << TQString::fromLocal8Bit((const char*)queryctrl.name) << endl;
kdDebug ( 14010 ) < < k_funcinfo < < " Control: " < < TQString ( TQString : : fromLocal8Bit ( ( const char * ) queryctrl . name ) ) < < " Values from " < < queryctrl . minimum < < " to " < < queryctrl . maximum < < " with steps of " < < queryctrl . step < < " . Default: " < < queryctrl . default_value < < endl ;
/* switch (queryctrl.type)
{
case V4L2_CTRL_TYPE_INTEGER :
} */
if ( queryctrl . type = = V4L2_CTRL_TYPE_MENU )
enumerateMenu ( ) ;
}
else
{
if ( errno = = EINVAL )
continue ;
perror ( " VIDIOC_QUERYCTRL " ) ;
// exit (EXIT_FAILURE);
}
}
kdDebug ( 14010 ) < < k_funcinfo < < " Checking CID private controls " < < endl ;
for ( currentid = V4L2_CID_PRIVATE_BASE ; ; currentid + + )
//for (queryctrl.id = 9963776; queryctrl.id < 9963800; queryctrl.id++)
{
queryctrl . id = currentid ;
//kdDebug(14010) << k_funcinfo << "Checking CID private controls from " << V4L2_CID_PRIVATE_BASE << ". Current: " << queryctrl.id << ". IOCTL returns: " << resultado << endl;
if ( 0 = = xioctl ( VIDIOC_QUERYCTRL , & queryctrl ) )
{
if ( queryctrl . flags & V4L2_CTRL_FLAG_DISABLED )
continue ;
kdDebug ( 14010 ) < < k_funcinfo < < " Control: " < < TQString ( TQString : : fromLocal8Bit ( ( const char * ) queryctrl . name ) ) < < " Values from " < < queryctrl . minimum < < " to " < < queryctrl . maximum < < " with steps of " < < queryctrl . step < < " . Default: " < < queryctrl . default_value < < endl ;
if ( queryctrl . type = = V4L2_CTRL_TYPE_MENU )
enumerateMenu ( ) ;
}
else
{
if ( errno = = EINVAL )
break ;
perror ( " VIDIOC_QUERYCTRL " ) ;
// exit (EXIT_FAILURE);
}
}
}
else
{
// V4L-only drivers should return an EINVAL in errno to indicate they cannot handle V4L2 calls. Not every driver is compliant, so
// it will try the V4L api even if the error code is different than expected.
kdDebug ( 14010 ) < < k_funcinfo < < " checkDevice(): " < < full_filename < < " is not a V4L2 device. " < < endl ;
}
}
# endif
CLEAR ( V4L_capabilities ) ;
if ( m_driver = = VIDEODEV_DRIVER_NONE )
{
kdDebug ( 14010 ) < < k_funcinfo < < " checkDevice(): " < < full_filename < < " Trying V4L API. " < < endl ;
if ( - 1 = = xioctl ( VIDIOCGCAP , & V4L_capabilities ) )
{
perror ( " ioctl (VIDIOCGCAP) " ) ;
m_driver = VIDEODEV_DRIVER_NONE ;
return EXIT_FAILURE ;
}
else
{
kdDebug ( 14010 ) < < k_funcinfo < < full_filename < < " is a V4L device. " < < endl ;
m_driver = VIDEODEV_DRIVER_V4L ;
m_model = TQString : : fromLocal8Bit ( ( const char * ) V4L_capabilities . name ) ;
if ( V4L_capabilities . type & VID_TYPE_CAPTURE )
m_videocapture = true ;
if ( V4L_capabilities . type & VID_TYPE_CHROMAKEY )
m_videochromakey = true ;
if ( V4L_capabilities . type & VID_TYPE_SCALES )
m_videoscale = true ;
if ( V4L_capabilities . type & VID_TYPE_OVERLAY )
m_videooverlay = true ;
// kdDebug(14010) << "libkopete (avdevice): Inputs : " << V4L_capabilities.channels << endl;
// kdDebug(14010) << "libkopete (avdevice): Audios : " << V4L_capabilities.audios << endl;
minwidth = V4L_capabilities . minwidth ;
maxwidth = V4L_capabilities . maxwidth ;
minheight = V4L_capabilities . minheight ;
maxheight = V4L_capabilities . maxheight ;
int inputisok = EXIT_SUCCESS ;
m_input . clear ( ) ;
for ( int loop = 0 ; loop < V4L_capabilities . channels ; loop + + )
{
struct video_channel videoinput ;
CLEAR ( videoinput ) ;
videoinput . channel = loop ;
videoinput . norm = 1 ;
inputisok = xioctl ( VIDIOCGCHAN , & videoinput ) ;
if ( inputisok = = EXIT_SUCCESS )
{
VideoInput tempinput ;
tempinput . name = TQString : : fromLocal8Bit ( ( const char * ) videoinput . name ) ;
tempinput . hastuner = videoinput . flags & VIDEO_VC_TUNER ;
// TODO: The routine to detect the appropriate video standards for V4L must be placed here
m_input . push_back ( tempinput ) ;
// kdDebug(14010) << "libkopete (avdevice): Input " << loop << ": " << tempinput.name << " (tuner: " << ((videoinput.flags & VIDEO_VC_TUNER) != 0) << ")" << endl;
/* if((input.type & V4L2_INPUT_TYPE_TUNER) != 0)
{
// _tunerForInput[name] = desc.tuner;
// _isTuner = true;
}
else
{
// _tunerForInput[name] = -1;
}
*/ }
}
}
}
# endif
m_name = m_model ; // Take care about changing the name to be different from the model itself...
detectPixelFormats ( ) ;
// TODO: Now we must execute the proper initialization according to the type of the driver.
kdDebug ( 14010 ) < < k_funcinfo < < " checkDevice() exited successfuly. " < < endl ;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn VideoDevice : : showDeviceCapabilities ( )
*/
int VideoDevice : : showDeviceCapabilities ( )
{
kdDebug ( 14010 ) < < k_funcinfo < < " showDeviceCapabilities() called. " < < endl ;
if ( isOpen ( ) )
{
/* kdDebug(14010) << "libkopete (avdevice): Driver: " << (const char*)V4L2_capabilities.driver << " "
< < ( ( V4L2_capabilities . version > > 16 ) & 0xFF ) < < " . "
< < ( ( V4L2_capabilities . version > > 8 ) & 0xFF ) < < " . "
< < ( ( V4L2_capabilities . version ) & 0xFF ) < < endl ;
kdDebug ( 14010 ) < < " libkopete (avdevice): Card: " < < name < < endl ;
kdDebug ( 14010 ) < < " libkopete (avdevice): Capabilities: " < < endl ;
if ( V4L2_capabilities . capabilities & V4L2_CAP_VIDEO_CAPTURE )
kdDebug ( 14010 ) < < " libkopete (avdevice): Video capture " < < endl ;
if ( V4L2_capabilities . capabilities & V4L2_CAP_VIDEO_OUTPUT )
kdDebug ( 14010 ) < < " libkopete (avdevice): Video output " < < endl ;
if ( V4L2_capabilities . capabilities & V4L2_CAP_VIDEO_OVERLAY )
kdDebug ( 14010 ) < < " libkopete (avdevice): Video overlay " < < endl ;
if ( V4L2_capabilities . capabilities & V4L2_CAP_VBI_CAPTURE )
kdDebug ( 14010 ) < < " libkopete (avdevice): VBI capture " < < endl ;
if ( V4L2_capabilities . capabilities & V4L2_CAP_VBI_OUTPUT )
kdDebug ( 14010 ) < < " libkopete (avdevice): VBI output " < < endl ;
if ( V4L2_capabilities . capabilities & V4L2_CAP_RDS_CAPTURE )
kdDebug ( 14010 ) < < " libkopete (avdevice): RDS capture " < < endl ;
if ( V4L2_capabilities . capabilities & V4L2_CAP_TUNER )
kdDebug ( 14010 ) < < " libkopete (avdevice): Tuner IO " < < endl ;
if ( V4L2_capabilities . capabilities & V4L2_CAP_AUDIO )
kdDebug ( 14010 ) < < " libkopete (avdevice): Audio IO " < < endl ;
; */
kdDebug ( 14010 ) < < k_funcinfo < < " Card model: " < < m_model < < endl ;
kdDebug ( 14010 ) < < k_funcinfo < < " Card name : " < < m_name < < endl ;
kdDebug ( 14010 ) < < k_funcinfo < < " Capabilities: " < < endl ;
if ( canCapture ( ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Video capture " < < endl ;
if ( canRead ( ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Read " < < endl ;
if ( canAsyncIO ( ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Asynchronous input/output " < < endl ;
if ( canStream ( ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Streaming " < < endl ;
if ( canChromakey ( ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Video chromakey " < < endl ;
if ( canScale ( ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Video scales " < < endl ;
if ( canOverlay ( ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Video overlay " < < endl ;
// kdDebug(14010) << "libkopete (avdevice): Audios : " << V4L_capabilities.audios << endl;
kdDebug ( 14010 ) < < k_funcinfo < < " Max res: " < < maxWidth ( ) < < " x " < < maxHeight ( ) < < endl ;
kdDebug ( 14010 ) < < k_funcinfo < < " Min res: " < < minWidth ( ) < < " x " < < minHeight ( ) < < endl ;
kdDebug ( 14010 ) < < k_funcinfo < < " Inputs : " < < inputs ( ) < < endl ;
for ( unsigned int loop = 0 ; loop < inputs ( ) ; loop + + )
kdDebug ( 14010 ) < < k_funcinfo < < " Input " < < loop < < " : " < < m_input [ loop ] . name < < " (tuner: " < < m_input [ loop ] . hastuner < < " ) " < < endl ;
kdDebug ( 14010 ) < < k_funcinfo < < " showDeviceCapabilities() exited successfuly. " < < endl ;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn VideoDevicePool : : initDevice ( )
*/
int VideoDevice : : initDevice ( )
{
/// @todo implement me
kdDebug ( 14010 ) < < k_funcinfo < < " initDevice() started " < < endl ;
if ( - 1 = = descriptor )
{
kdDebug ( 14010 ) < < k_funcinfo < < " initDevice() Device is not open " < < endl ;
return EXIT_FAILURE ;
}
m_io_method = IO_METHOD_NONE ;
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
if ( V4L2_capabilities . capabilities & V4L2_CAP_READWRITE )
{
m_videoread = true ;
m_io_method = IO_METHOD_READ ;
kdDebug ( 14010 ) < < k_funcinfo < < " Read/Write interface " < < endl ;
}
if ( V4L2_capabilities . capabilities & V4L2_CAP_ASYNCIO )
{
m_videoasyncio = true ;
kdDebug ( 14010 ) < < k_funcinfo < < " Async IO interface " < < endl ;
}
if ( V4L2_capabilities . capabilities & V4L2_CAP_STREAMING )
{
m_videostream = true ;
m_io_method = IO_METHOD_MMAP ;
// m_io_method = IO_METHOD_USERPTR;
kdDebug ( 14010 ) < < k_funcinfo < < " Streaming interface " < < endl ;
}
if ( m_io_method = = IO_METHOD_NONE )
{
kdDebug ( 14010 ) < < k_funcinfo < < " initDevice() Found no suitable input/output method for " < < full_filename < < endl ;
return EXIT_FAILURE ;
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
m_videoread = true ;
m_io_method = IO_METHOD_READ ;
if ( - 1 ! = xioctl ( VIDIOCGFBUF , & V4L_videobuffer ) )
{
// m_videostream=true;
// m_io_method = IO_METHOD_MMAP;
kdDebug ( 14010 ) < < k_funcinfo < < " Streaming interface " < < endl ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
// Select video input, video standard and tune here.
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
cropcap . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
if ( - 1 = = xioctl ( VIDIOC_CROPCAP , & cropcap ) )
{ // Errors ignored.
}
crop . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
crop . c = cropcap . defrect ; // reset to default
if ( - 1 = = xioctl ( VIDIOC_S_CROP , & crop ) )
{
switch ( errno )
{
case EINVAL : break ; // Cropping not supported.
default : break ; // Errors ignored.
}
}
# endif
# endif
showDeviceCapabilities ( ) ;
kdDebug ( 14010 ) < < k_funcinfo < < " initDevice() exited successfuly " < < endl ;
return EXIT_SUCCESS ;
}
unsigned int VideoDevice : : inputs ( )
{
return m_input . size ( ) ;
}
int VideoDevice : : width ( )
{
return currentwidth ;
}
int VideoDevice : : minWidth ( )
{
return minwidth ;
}
int VideoDevice : : maxWidth ( )
{
return maxwidth ;
}
int VideoDevice : : height ( )
{
return currentheight ;
}
int VideoDevice : : minHeight ( )
{
return minheight ;
}
int VideoDevice : : maxHeight ( )
{
return maxheight ;
}
int VideoDevice : : setSize ( int newwidth , int newheight )
{
kdDebug ( 14010 ) < < k_funcinfo < < " setSize( " < < newwidth < < " , " < < newheight < < " ) called. " < < endl ;
if ( isOpen ( ) )
{
// It should not be there. It must remain in a completely distict place, cause this method should not change the pixelformat.
kdDebug ( 14010 ) < < k_funcinfo < < " Trying YUY422P " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_YUV422P ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support YUV422P format. Trying YUYV. " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_YUYV ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support YUYV format. Trying UYVY. " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_UYVY ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support UYVY format. Trying YUV420P. " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_YUV420P ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support YUV420P format. Trying RGB24. " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_RGB24 ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support RGB24 format. Trying BGR24. " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_BGR24 ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support RGB24 format. Trying RGB32. " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_RGB32 ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support RGB32 format. Trying BGR32. " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_BGR32 ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support BGR32 format. Trying SN9C10X. " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_SN9C10X ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support SN9C10X format. Trying Bayer RGB. " < < endl ;
if ( PIXELFORMAT_NONE = = setPixelFormat ( PIXELFORMAT_SBGGR8 ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Card doesn't seem to support SBGGR8 format. Fallback from it is not yet implemented. " < < endl ;
}
}
}
}
}
}
}
}
}
if ( newwidth > maxwidth ) newwidth = maxwidth ;
if ( newheight > maxheight ) newheight = maxheight ;
if ( newwidth < minwidth ) newwidth = minwidth ;
if ( newheight < minheight ) newheight = minheight ;
currentwidth = newwidth ;
currentheight = newheight ;
//kdDebug(14010) << k_funcinfo << "width: " << pixelFormatName(fmt.fmt.pix.pixelformat) << " " << width() << "x" << height() << endl;
// Change resolution for the video device
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
// CLEAR (fmt);
if ( - 1 = = xioctl ( VIDIOC_G_FMT , & fmt ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_G_FMT failed ( " < < errno < < " ).Returned width: " < < pixelFormatName ( fmt . fmt . pix . pixelformat ) < < " " < < fmt . fmt . pix . width < < " x " < < fmt . fmt . pix . height < < endl ;
fmt . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
fmt . fmt . pix . width = width ( ) ;
fmt . fmt . pix . height = height ( ) ;
fmt . fmt . pix . field = V4L2_FIELD_ANY ;
if ( - 1 = = xioctl ( VIDIOC_S_FMT , & fmt ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_S_FMT failed ( " < < errno < < " ).Returned width: " < < pixelFormatName ( fmt . fmt . pix . pixelformat ) < < " " < < fmt . fmt . pix . width < < " x " < < fmt . fmt . pix . height < < endl ;
// Note VIDIOC_S_FMT may change width and height.
}
else
{
// Buggy driver paranoia.
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_S_FMT worked ( " < < errno < < " ).Returned width: " < < pixelFormatName ( fmt . fmt . pix . pixelformat ) < < " " < < fmt . fmt . pix . width < < " x " < < fmt . fmt . pix . height < < endl ;
unsigned int min = fmt . fmt . pix . width * 2 ;
if ( fmt . fmt . pix . bytesperline < min )
fmt . fmt . pix . bytesperline = min ;
min = fmt . fmt . pix . bytesperline * fmt . fmt . pix . height ;
if ( fmt . fmt . pix . sizeimage < min )
fmt . fmt . pix . sizeimage = min ;
m_buffer_size = fmt . fmt . pix . sizeimage ;
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
{
struct video_window V4L_videowindow ;
kdDebug ( 14010 ) < < " ------------- width: " < < V4L_videowindow . width < < " Height: " < < V4L_videowindow . height < < " Clipcount: " < < V4L_videowindow . clipcount < < " ----------------- " < < endl ;
if ( xioctl ( VIDIOCGWIN , & V4L_videowindow ) = = - 1 )
{
perror ( " ioctl VIDIOCGWIN " ) ;
// return (NULL);
}
V4L_videowindow . width = width ( ) ;
V4L_videowindow . height = height ( ) ;
V4L_videowindow . clipcount = 0 ;
if ( xioctl ( VIDIOCSWIN , & V4L_videowindow ) = = - 1 )
{
perror ( " ioctl VIDIOCSWIN " ) ;
// return (NULL);
}
kdDebug ( 14010 ) < < " ------------- width: " < < V4L_videowindow . width < < " Height: " < < V4L_videowindow . height < < " Clipcount: " < < V4L_videowindow . clipcount < < " ----------------- " < < endl ;
// kdDebug(14010) << "libkopete (avdevice): V4L_picture.palette: " << V4L_picture.palette << " Depth: " << V4L_picture.depth << endl;
/* if(-1 == xioctl(VIDIOCGFBUF,&V4L_videobuffer))
kdDebug ( 14010 ) < < " libkopete (avdevice): VIDIOCGFBUF failed ( " < < errno < < " ): Card cannot stream " < < endl ; */
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
m_buffer_size = width ( ) * height ( ) * pixelFormatDepth ( m_pixelformat ) / 8 ;
kdDebug ( 14010 ) < < " ------------------------- ------- -- m_buffer_size: " < < m_buffer_size < < " !!! -- ------- ----------------------------------------- " < < endl ;
m_currentbuffer . pixelformat = m_pixelformat ;
m_currentbuffer . data . resize ( m_buffer_size ) ;
switch ( m_io_method )
{
case IO_METHOD_NONE : break ;
case IO_METHOD_READ : initRead ( ) ; break ;
case IO_METHOD_MMAP : initMmap ( ) ; break ;
case IO_METHOD_USERPTR : initUserptr ( ) ; break ;
}
kdDebug ( 14010 ) < < k_funcinfo < < " setSize( " < < newwidth < < " , " < < newheight < < " ) exited successfuly. " < < endl ;
return EXIT_SUCCESS ;
}
kdDebug ( 14010 ) < < k_funcinfo < < " setSize( " < < newwidth < < " , " < < newheight < < " ) Device is not open. " < < endl ;
return EXIT_FAILURE ;
}
pixel_format VideoDevice : : setPixelFormat ( pixel_format newformat )
{
pixel_format ret = PIXELFORMAT_NONE ;
//kdDebug(14010) << k_funcinfo << "called." << endl;
// Change the pixel format for the video device
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
// CLEAR (fmt);
if ( - 1 = = xioctl ( VIDIOC_G_FMT , & fmt ) )
{
// return errnoReturn ("VIDIOC_S_FMT");
// kdDebug(14010) << k_funcinfo << "VIDIOC_G_FMT failed (" << errno << ").Returned width: " << pixelFormatName(fmt.fmt.pix.pixelformat) << " " << fmt.fmt.pix.width << "x" << fmt.fmt.pix.height << endl;
}
else
m_pixelformat = pixelFormatForPalette ( fmt . fmt . pix . pixelformat ) ;
fmt . fmt . pix . pixelformat = pixelFormatCode ( newformat ) ;
if ( - 1 = = xioctl ( VIDIOC_S_FMT , & fmt ) )
{
// kdDebug(14010) << k_funcinfo << "VIDIOC_S_FMT failed (" << errno << ").Returned width: " << pixelFormatName(fmt.fmt.pix.pixelformat) << " " << fmt.fmt.pix.width << "x" << fmt.fmt.pix.height << endl;
}
else
{
if ( fmt . fmt . pix . pixelformat = = pixelFormatCode ( newformat ) )
{
m_pixelformat = newformat ;
ret = m_pixelformat ;
}
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
{
struct video_picture V4L_picture ;
if ( - 1 = = xioctl ( VIDIOCGPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOCGPICT failed ( " < < errno < < " ). " < < endl ;
// kdDebug(14010) << k_funcinfo << "V4L_picture.palette: " << V4L_picture.palette << " Depth: " << V4L_picture.depth << endl;
V4L_picture . palette = pixelFormatCode ( newformat ) ;
V4L_picture . depth = pixelFormatDepth ( newformat ) ;
if ( - 1 = = xioctl ( VIDIOCSPICT , & V4L_picture ) )
{
// kdDebug(14010) << k_funcinfo << "Card seems to not support " << pixelFormatName(newformat) << " format. Fallback to it is not yet implemented." << endl;
}
if ( - 1 = = xioctl ( VIDIOCGPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOCGPICT failed ( " < < errno < < " ). " < < endl ;
// kdDebug(14010) << k_funcinfo << "V4L_picture.palette: " << V4L_picture.palette << " Depth: " << V4L_picture.depth << endl;
m_pixelformat = pixelFormatForPalette ( V4L_picture . palette ) ;
if ( m_pixelformat = = newformat )
ret = newformat ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
return ret ;
}
/*!
\ fn Kopete : : AV : : VideoDevice : : currentInput ( )
*/
int VideoDevice : : currentInput ( )
{
/// @todo implement me
if ( isOpen ( ) )
{
return m_current_input ;
}
return 0 ;
}
/*!
\ fn Kopete : : AV : : VideoDevice : : selectInput ( int input )
*/
int VideoDevice : : selectInput ( int newinput )
{
/// @todo implement me
if ( m_current_input > = inputs ( ) )
return EXIT_FAILURE ;
if ( isOpen ( ) )
{
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
if ( - 1 = = ioctl ( descriptor , VIDIOC_S_INPUT , & newinput ) )
{
perror ( " VIDIOC_S_INPUT " ) ;
return EXIT_FAILURE ;
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
struct video_channel V4L_input ;
V4L_input . channel = newinput ;
V4L_input . norm = 4 ; // Hey, it's plain wrong! It should be input's signal standard!
if ( - 1 = = ioctl ( descriptor , VIDIOCSCHAN , & V4L_input ) )
{
perror ( " ioctl (VIDIOCSCHAN) " ) ;
return EXIT_FAILURE ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
kdDebug ( 14010 ) < < k_funcinfo < < " Selected input " < < newinput < < " ( " < < m_input [ newinput ] . name < < " ) " < < endl ;
m_current_input = newinput ;
setInputParameters ( ) ;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn Kopete : : AV : : VideoDevice : : setInputParameters ( )
*/
int VideoDevice : : setInputParameters ( )
{
/// @todo implement me
if ( ( isOpen ( ) ) & & ( m_current_input < inputs ( ) ) )
{
setBrightness ( getBrightness ( ) ) ;
setContrast ( getContrast ( ) ) ;
setSaturation ( getSaturation ( ) ) ;
setWhiteness ( getWhiteness ( ) ) ;
setHue ( getHue ( ) ) ;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn VideoDevice : : startCapturing ( )
*/
int VideoDevice : : startCapturing ( )
{
kdDebug ( 14010 ) < < k_funcinfo < < " called. " < < endl ;
if ( isOpen ( ) )
{
switch ( m_io_method )
{
case IO_METHOD_NONE : // Card cannot capture frames
return EXIT_FAILURE ;
break ;
case IO_METHOD_READ : // Nothing to do
break ;
case IO_METHOD_MMAP :
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
{
unsigned int loop ;
for ( loop = 0 ; loop < m_streambuffers ; + + loop )
{
struct v4l2_buffer buf ;
CLEAR ( buf ) ;
buf . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
buf . memory = V4L2_MEMORY_MMAP ;
buf . index = loop ;
if ( - 1 = = xioctl ( VIDIOC_QBUF , & buf ) )
return errnoReturn ( " VIDIOC_QBUF " ) ;
}
enum v4l2_buf_type type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
if ( - 1 = = xioctl ( VIDIOC_STREAMON , & type ) )
return errnoReturn ( " VIDIOC_STREAMON " ) ;
}
# endif
# endif
break ;
case IO_METHOD_USERPTR :
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
{
unsigned int loop ;
for ( loop = 0 ; loop < m_streambuffers ; + + loop )
{
struct v4l2_buffer buf ;
CLEAR ( buf ) ;
buf . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
buf . memory = V4L2_MEMORY_USERPTR ;
buf . m . userptr = ( unsigned long ) m_rawbuffers [ loop ] . start ;
buf . length = m_rawbuffers [ loop ] . length ;
if ( - 1 = = xioctl ( VIDIOC_QBUF , & buf ) )
return errnoReturn ( " VIDIOC_QBUF " ) ;
}
enum v4l2_buf_type type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
if ( - 1 = = xioctl ( VIDIOC_STREAMON , & type ) )
return errnoReturn ( " VIDIOC_STREAMON " ) ;
}
# endif
# endif
break ;
}
kdDebug ( 14010 ) < < k_funcinfo < < " exited successfuly. " < < endl ;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn VideoDevice : : getFrame ( )
*/
int VideoDevice : : getFrame ( )
{
/// @todo implement me
ssize_t bytesread ;
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
struct v4l2_buffer v4l2buffer ;
# endif
# endif
// kdDebug(14010) << k_funcinfo << "getFrame() called." << endl;
if ( isOpen ( ) )
{
switch ( m_io_method )
{
case IO_METHOD_NONE : // Card cannot capture frames
return EXIT_FAILURE ;
break ;
case IO_METHOD_READ :
// kdDebug(14010) << k_funcinfo << "Using IO_METHOD_READ.File descriptor: " << descriptor << " Buffer address: " << &m_currentbuffer.data[0] << " Size: " << m_currentbuffer.data.size() << endl;
bytesread = read ( descriptor , & m_currentbuffer . data [ 0 ] , m_currentbuffer . data . size ( ) ) ;
if ( - 1 = = bytesread ) // must verify this point with ov511 driver.
{
kdDebug ( 14010 ) < < k_funcinfo < < " IO_METHOD_READ failed. " < < endl ;
switch ( errno )
{
case EAGAIN :
return EXIT_FAILURE ;
case EIO : /* Could ignore EIO, see spec. fall through */
default :
return errnoReturn ( " read " ) ;
}
}
if ( ( int ) m_currentbuffer . data . size ( ) < bytesread )
{
kdDebug ( 14010 ) < < k_funcinfo < < " IO_METHOD_READ returned less bytes ( " < < bytesread < < " ) than it was asked for ( " < < m_currentbuffer . data . size ( ) < < " ). " < < endl ;
}
break ;
case IO_METHOD_MMAP :
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
CLEAR ( v4l2buffer ) ;
v4l2buffer . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
v4l2buffer . memory = V4L2_MEMORY_MMAP ;
if ( - 1 = = xioctl ( VIDIOC_DQBUF , & v4l2buffer ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < full_filename < < " MMAPed getFrame failed. " < < endl ;
switch ( errno )
{
case EAGAIN :
{
kdDebug ( 14010 ) < < k_funcinfo < < full_filename < < " MMAPed getFrame failed: EAGAIN. Pointer: " < < endl ;
return EXIT_FAILURE ;
}
case EIO : /* Could ignore EIO, see spec. fall through */
default :
return errnoReturn ( " VIDIOC_DQBUF " ) ;
}
}
/* if (v4l2buffer.index < m_streambuffers)
return EXIT_FAILURE ; */ //it was an assert()
//kdDebug(14010) << k_funcinfo << "m_rawbuffers[" << v4l2buffer.index << "].start: " << (void *)m_rawbuffers[v4l2buffer.index].start << " Size: " << m_currentbuffer.data.size() << endl;
/*{
unsigned long long result = 0 ;
unsigned long long R = 0 , G = 0 , B = 0 , A = 0 ;
int Rmax = 0 , Gmax = 0 , Bmax = 0 , Amax = 0 ;
int Rmin = 255 , Gmin = 255 , Bmin = 255 , Amin = 0 ;
for ( unsigned int loop = 0 ; loop < m_currentbuffer . data . size ( ) ; loop + = 4 )
{
R + = m_rawbuffers [ v4l2buffer . index ] . start [ loop ] ;
G + = m_rawbuffers [ v4l2buffer . index ] . start [ loop + 1 ] ;
B + = m_rawbuffers [ v4l2buffer . index ] . start [ loop + 2 ] ;
// A+=currentbuffer.data[loop+3];
if ( m_currentbuffer . data [ loop ] < Rmin ) Rmin = m_currentbuffer . data [ loop ] ;
if ( m_currentbuffer . data [ loop + 1 ] < Gmin ) Gmin = m_currentbuffer . data [ loop + 1 ] ;
if ( m_currentbuffer . data [ loop + 2 ] < Bmin ) Bmin = m_currentbuffer . data [ loop + 2 ] ;
// if (m_currentbuffer.data[loop+3] < Amin) Amin = m_currentbuffer.data[loop+3];
if ( m_currentbuffer . data [ loop ] > Rmax ) Rmax = m_currentbuffer . data [ loop ] ;
if ( m_currentbuffer . data [ loop + 1 ] > Gmax ) Gmax = m_currentbuffer . data [ loop + 1 ] ;
if ( m_currentbuffer . data [ loop + 2 ] > Bmax ) Bmax = m_currentbuffer . data [ loop + 2 ] ;
// if (m_currentbuffer.data[loop+3] > Amax) Amax = m_currentbuffer.data[loop+3];
}
kdDebug ( 14010 ) < < " R: " < < R < < " G: " < < G < < " B: " < < B < < " A: " < < A < <
" Rmin: " < < Rmin < < " Gmin: " < < Gmin < < " Bmin: " < < Bmin < < " Amin: " < < Amin < <
" Rmax: " < < Rmax < < " Gmax: " < < Gmax < < " Bmax: " < < Bmax < < " Amax: " < < Amax < < endl ;
} */
memcpy ( & m_currentbuffer . data [ 0 ] , m_rawbuffers [ v4l2buffer . index ] . start , m_currentbuffer . data . size ( ) ) ;
if ( - 1 = = xioctl ( VIDIOC_QBUF , & v4l2buffer ) )
return errnoReturn ( " VIDIOC_QBUF " ) ;
# endif
# endif
break ;
case IO_METHOD_USERPTR :
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
{
unsigned int i ;
CLEAR ( v4l2buffer ) ;
v4l2buffer . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
v4l2buffer . memory = V4L2_MEMORY_USERPTR ;
if ( - 1 = = xioctl ( VIDIOC_DQBUF , & v4l2buffer ) )
{
switch ( errno )
{
case EAGAIN :
return EXIT_FAILURE ;
case EIO : /* Could ignore EIO, see spec. fall through */
default :
return errnoReturn ( " VIDIOC_DQBUF " ) ;
}
}
for ( i = 0 ; i < m_streambuffers ; + + i )
if ( v4l2buffer . m . userptr = = ( unsigned long ) m_rawbuffers [ i ] . start & & v4l2buffer . length = = m_rawbuffers [ i ] . length )
break ;
if ( i < m_streambuffers )
return EXIT_FAILURE ;
if ( - 1 = = xioctl ( VIDIOC_QBUF , & v4l2buffer ) )
return errnoReturn ( " VIDIOC_QBUF " ) ;
}
# endif
# endif
break ;
}
/* Automatic color correction. Now it just swaps R and B channels in RGB24/BGR24 modes.
if ( m_input [ m_current_input ] . getAutoColorCorrection ( ) )
{
switch ( m_currentbuffer . pixelformat )
{
case PIXELFORMAT_NONE : break ;
case PIXELFORMAT_GREY : break ;
case PIXELFORMAT_RGB332 : break ;
case PIXELFORMAT_RGB555 : break ;
case PIXELFORMAT_RGB555X : break ;
case PIXELFORMAT_RGB565 : break ;
case PIXELFORMAT_RGB565X : break ;
case PIXELFORMAT_RGB24 :
case PIXELFORMAT_BGR24 :
{
unsigned char temp ;
for ( unsigned int loop = 0 ; loop < m_currentbuffer . data . size ( ) ; loop + = 3 )
{
temp = m_currentbuffer . data [ loop ] ;
m_currentbuffer . data [ loop ] = m_currentbuffer . data [ loop + 2 ] ;
m_currentbuffer . data [ loop + 2 ] = temp ;
}
}
break ;
case PIXELFORMAT_RGB32 :
case PIXELFORMAT_BGR32 :
{
unsigned char temp ;
for ( unsigned int loop = 0 ; loop < m_currentbuffer . data . size ( ) ; loop + = 4 )
{
temp = m_currentbuffer . data [ loop ] ;
m_currentbuffer . data [ loop ] = m_currentbuffer . data [ loop + 2 ] ;
m_currentbuffer . data [ loop + 2 ] = temp ;
}
}
break ;
case PIXELFORMAT_YUYV : break ;
case PIXELFORMAT_UYVY : break ;
case PIXELFORMAT_YUV420P : break ;
case PIXELFORMAT_YUV422P : break ;
}
} */
//kdDebug(14010) << k_funcinfo << "10 Using IO_METHOD_READ.File descriptor: " << descriptor << " Buffer address: " << &m_currentbuffer.data[0] << " Size: " << m_currentbuffer.data.size() << endl;
// put frame copy operation here
// kdDebug(14010) << k_funcinfo << "exited successfuly." << endl;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn VideoDevice : : getFrame ( imagebuffer * imgbuffer )
*/
int VideoDevice : : getFrame ( imagebuffer * imgbuffer )
{
if ( imgbuffer )
{
getFrame ( ) ;
imgbuffer - > height = m_currentbuffer . height ;
imgbuffer - > width = m_currentbuffer . width ;
imgbuffer - > pixelformat = m_currentbuffer . pixelformat ;
imgbuffer - > data = m_currentbuffer . data ;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn Kopete : : AV : : VideoDevice : : getImage ( const TQImage * qimage )
*/
int VideoDevice : : getImage ( TQImage * qimage )
{
/// @todo implement me
// do NOT delete qimage here, as it is received as a parameter
if ( qimage - > width ( ) ! = width ( ) | | qimage - > height ( ) ! = height ( ) )
qimage - > create ( width ( ) , height ( ) , 32 , TQImage : : IgnoreEndian ) ;
uchar * bits = qimage - > bits ( ) ;
// kDebug() << "Capturing in " << pixelFormatName(m_currentbuffer.pixelformat);
switch ( m_currentbuffer . pixelformat )
{
case PIXELFORMAT_NONE : break ;
// Packed RGB formats
case PIXELFORMAT_RGB332 : break ;
case PIXELFORMAT_RGB444 : break ;
case PIXELFORMAT_RGB555 : break ;
case PIXELFORMAT_RGB565 :
{
int step = 0 ;
for ( int loop = 0 ; loop < qimage - > numBytes ( ) ; loop + = 4 )
{
bits [ loop ] = ( m_currentbuffer . data [ step ] < < 3 ) + ( m_currentbuffer . data [ step ] < < 3 > > 5 ) ;
bits [ loop + 1 ] = ( ( m_currentbuffer . data [ step + 1 ] ) < < 5 ) | m_currentbuffer . data [ step ] > > 5 ;
bits [ loop + 2 ] = ( ( m_currentbuffer . data [ step + 1 ] ) & 248 ) + ( ( m_currentbuffer . data [ step + 1 ] ) > > 5 ) ;
bits [ loop + 3 ] = 255 ;
step + = 2 ;
}
}
break ;
case PIXELFORMAT_RGB555X : break ;
case PIXELFORMAT_RGB565X : break ;
case PIXELFORMAT_BGR24 :
{
int step = 0 ;
for ( int loop = 0 ; loop < qimage - > numBytes ( ) ; loop + = 4 )
{
bits [ loop ] = m_currentbuffer . data [ step + 2 ] ;
bits [ loop + 1 ] = m_currentbuffer . data [ step + 1 ] ;
bits [ loop + 2 ] = m_currentbuffer . data [ step ] ;
bits [ loop + 3 ] = 255 ;
step + = 3 ;
}
}
break ;
case PIXELFORMAT_RGB24 :
{
int step = 0 ;
for ( int loop = 0 ; loop < qimage - > numBytes ( ) ; loop + = 4 )
{
bits [ loop ] = m_currentbuffer . data [ step ] ;
bits [ loop + 1 ] = m_currentbuffer . data [ step + 1 ] ;
bits [ loop + 2 ] = m_currentbuffer . data [ step + 2 ] ;
bits [ loop + 3 ] = 255 ;
step + = 3 ;
}
}
break ;
case PIXELFORMAT_BGR32 : break ;
case PIXELFORMAT_RGB32 : memcpy ( bits , & m_currentbuffer . data [ 0 ] , m_currentbuffer . data . size ( ) ) ;
break ;
// Bayer RGB format
case PIXELFORMAT_SBGGR8 :
{
unsigned char * d = ( unsigned char * ) malloc ( width ( ) * height ( ) * 3 ) ;
bayer2rgb24 ( d , & m_currentbuffer . data . first ( ) , width ( ) , height ( ) ) ;
int step = 0 ;
for ( int loop = 0 ; loop < qimage - > numBytes ( ) ; loop + = 4 )
{
bits [ loop ] = d [ step + 2 ] ;
bits [ loop + 1 ] = d [ step + 1 ] ;
bits [ loop + 2 ] = d [ step ] ;
bits [ loop + 3 ] = 255 ;
step + = 3 ;
}
free ( d ) ;
}
break ;
// YUV formats
case PIXELFORMAT_GREY : break ;
case PIXELFORMAT_YUYV :
case PIXELFORMAT_UYVY :
case PIXELFORMAT_YUV420P :
case PIXELFORMAT_YUV422P :
{
uchar * yptr , * cbptr , * crptr ;
bool halfheight = false ;
bool packed = false ;
// Adjust algorythm to specific YUV data arrangements.
if ( m_currentbuffer . pixelformat = = PIXELFORMAT_YUV420P )
halfheight = true ;
if ( m_currentbuffer . pixelformat = = PIXELFORMAT_YUYV )
{
yptr = & m_currentbuffer . data [ 0 ] ;
cbptr = yptr + 1 ;
crptr = yptr + 3 ;
packed = true ;
}
else if ( m_currentbuffer . pixelformat = = PIXELFORMAT_UYVY )
{
cbptr = & m_currentbuffer . data [ 0 ] ;
yptr = cbptr + 1 ;
crptr = cbptr + 2 ;
packed = true ;
}
else
{
yptr = & m_currentbuffer . data [ 0 ] ;
cbptr = yptr + ( width ( ) * height ( ) ) ;
crptr = cbptr + ( width ( ) * height ( ) / ( halfheight ? 4 : 2 ) ) ;
}
for ( int y = 0 ; y < height ( ) ; y + + )
{
// Decode scanline
for ( int x = 0 ; x < width ( ) ; x + + )
{
int c , d , e ;
if ( packed )
{
c = ( yptr [ x < < 1 ] ) - 16 ;
d = ( cbptr [ x > > 1 < < 2 ] ) - 128 ;
e = ( crptr [ x > > 1 < < 2 ] ) - 128 ;
}
else
{
c = ( yptr [ x ] ) - 16 ;
d = ( cbptr [ x > > 1 ] ) - 128 ;
e = ( crptr [ x > > 1 ] ) - 128 ;
}
int r = ( 298 * c + 409 * e + 128 ) > > 8 ;
int g = ( 298 * c - 100 * d - 208 * e + 128 ) > > 8 ;
int b = ( 298 * c + 516 * d + 128 ) > > 8 ;
if ( r < 0 ) r = 0 ; if ( r > 255 ) r = 255 ;
if ( g < 0 ) g = 0 ; if ( g > 255 ) g = 255 ;
if ( b < 0 ) b = 0 ; if ( b > 255 ) b = 255 ;
uint * p = ( uint * ) qimage - > scanLine ( y ) + x ;
* p = tqRgba ( r , g , b , 255 ) ;
}
// Jump to next line
if ( packed )
{
yptr + = width ( ) * 2 ;
cbptr + = width ( ) * 2 ;
crptr + = width ( ) * 2 ;
}
else
{
yptr + = width ( ) ;
if ( ! halfheight | | y & 1 )
{
cbptr + = width ( ) / 2 ;
crptr + = width ( ) / 2 ;
}
}
}
}
break ;
// Compressed formats
case PIXELFORMAT_JPEG : break ;
case PIXELFORMAT_MPEG : break ;
// Reserved formats
case PIXELFORMAT_DV : break ;
case PIXELFORMAT_ET61X251 : break ;
case PIXELFORMAT_HI240 : break ;
case PIXELFORMAT_HM12 : break ;
case PIXELFORMAT_MJPEG : break ;
case PIXELFORMAT_PWC1 : break ;
case PIXELFORMAT_PWC2 : break ;
case PIXELFORMAT_SN9C10X :
{
unsigned char * s = new unsigned char [ width ( ) * height ( ) ] ;
unsigned char * d = new unsigned char [ width ( ) * height ( ) * 3 ] ;
sonix_decompress_init ( ) ;
sonix_decompress ( width ( ) , height ( ) , & m_currentbuffer . data . first ( ) , s ) ;
bayer2rgb24 ( d , s , width ( ) , height ( ) ) ;
int step = 0 ;
for ( int loop = 0 ; loop < qimage - > numBytes ( ) ; loop + = 4 )
{
bits [ loop ] = d [ step + 2 ] ;
bits [ loop + 1 ] = d [ step + 1 ] ;
bits [ loop + 2 ] = d [ step ] ;
bits [ loop + 3 ] = 255 ;
step + = 3 ;
}
delete [ ] s ;
delete [ ] d ;
}
break ;
case PIXELFORMAT_WNVA : break ;
case PIXELFORMAT_YYUV : break ;
}
return EXIT_SUCCESS ;
}
/*!
\ fn VideoDevice : : stopCapturing ( )
*/
int VideoDevice : : stopCapturing ( )
{
/// @todo implement me
kdDebug ( 14010 ) < < k_funcinfo < < " called. " < < endl ;
if ( isOpen ( ) )
{
switch ( m_io_method )
{
case IO_METHOD_NONE : // Card cannot capture frames
return EXIT_FAILURE ;
break ;
case IO_METHOD_READ : // Nothing to do
break ;
case IO_METHOD_MMAP :
case IO_METHOD_USERPTR :
# ifdef V4L2_CAP_VIDEO_CAPTURE
{
enum v4l2_buf_type type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
if ( - 1 = = xioctl ( VIDIOC_STREAMOFF , & type ) )
return errnoReturn ( " VIDIOC_STREAMOFF " ) ;
if ( m_io_method = = IO_METHOD_MMAP )
{
unsigned int loop ;
for ( loop = 0 ; loop < m_streambuffers ; + + loop )
{
if ( munmap ( m_rawbuffers [ loop ] . start , m_rawbuffers [ loop ] . length ) ! = 0 )
{
kdDebug ( 14010 ) < < k_funcinfo < < " unable to munmap. " < < endl ;
}
}
}
}
# endif
break ;
}
kdDebug ( 14010 ) < < k_funcinfo < < " exited successfuly. " < < endl ;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn VideoDevice : : close ( )
*/
int VideoDevice : : close ( )
{
/// @todo implement me
kdDebug ( 14010 ) < < k_funcinfo < < " called. " < < endl ;
if ( isOpen ( ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device is open. Trying to properly shutdown the device. " < < endl ;
stopCapturing ( ) ;
kdDebug ( 14010 ) < < k_funcinfo < < " ::close() returns " < < : : close ( descriptor ) < < endl ;
}
descriptor = - 1 ;
return EXIT_SUCCESS ;
}
float VideoDevice : : getBrightness ( )
{
if ( m_current_input < m_input . size ( ) )
return m_input [ m_current_input ] . getBrightness ( ) ;
else
return 0 ;
}
float VideoDevice : : setBrightness ( float brightness )
{
kdDebug ( 14010 ) < < k_funcinfo < < " called. " < < endl ;
m_input [ m_current_input ] . setBrightness ( brightness ) ; // Just to check bounds
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
{
struct v4l2_queryctrl queryctrl ;
struct v4l2_control control ;
CLEAR ( queryctrl ) ;
queryctrl . id = V4L2_CID_BRIGHTNESS ;
if ( - 1 = = xioctl ( VIDIOC_QUERYCTRL , & queryctrl ) )
{
if ( errno ! = EINVAL )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_QUERYCTRL failed ( " < < errno < < " ). " < < endl ;
} else
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Brightness control. " < < endl ;
}
} else
if ( queryctrl . flags & V4L2_CTRL_FLAG_DISABLED )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Brightness control. " < < endl ;
} else
{
CLEAR ( control ) ;
control . id = V4L2_CID_BRIGHTNESS ;
control . value = ( __s32 ) ( ( queryctrl . maximum - queryctrl . minimum ) * getBrightness ( ) ) ;
if ( - 1 = = xioctl ( VIDIOC_S_CTRL , & control ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_S_CTRL failed ( " < < errno < < " ). " < < endl ;
}
}
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
{
struct video_picture V4L_picture ;
if ( - 1 = = xioctl ( VIDIOCGPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOCGPICT failed ( " < < errno < < " ). " < < endl ;
V4L_picture . brightness = uint ( 65535 * getBrightness ( ) ) ;
if ( - 1 = = xioctl ( VIDIOCSPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Card seems to not support adjusting image brightness. Fallback to it is not yet implemented. " < < endl ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
return getBrightness ( ) ;
}
float VideoDevice : : getContrast ( )
{
if ( m_current_input < m_input . size ( ) )
return m_input [ m_current_input ] . getContrast ( ) ;
else
return 0 ;
}
float VideoDevice : : setContrast ( float contrast )
{
kdDebug ( 14010 ) < < k_funcinfo < < " called. " < < endl ;
m_input [ m_current_input ] . setContrast ( contrast ) ; // Just to check bounds
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
{
struct v4l2_queryctrl queryctrl ;
struct v4l2_control control ;
CLEAR ( queryctrl ) ;
queryctrl . id = V4L2_CID_CONTRAST ;
if ( - 1 = = xioctl ( VIDIOC_QUERYCTRL , & queryctrl ) )
{
if ( errno ! = EINVAL )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_QUERYCTRL failed ( " < < errno < < " ). " < < endl ;
} else
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Contrast control. " < < endl ;
}
} else
if ( queryctrl . flags & V4L2_CTRL_FLAG_DISABLED )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Contrast control. " < < endl ;
} else
{
CLEAR ( control ) ;
control . id = V4L2_CID_CONTRAST ;
control . value = ( __s32 ) ( ( queryctrl . maximum - queryctrl . minimum ) * getContrast ( ) ) ;
if ( - 1 = = xioctl ( VIDIOC_S_CTRL , & control ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_S_CTRL failed ( " < < errno < < " ). " < < endl ;
}
}
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
{
struct video_picture V4L_picture ;
if ( - 1 = = xioctl ( VIDIOCGPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOCGPICT failed ( " < < errno < < " ). " < < endl ;
V4L_picture . contrast = uint ( 65535 * getContrast ( ) ) ;
if ( - 1 = = xioctl ( VIDIOCSPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Card seems to not support adjusting image contrast. Fallback to it is not yet implemented. " < < endl ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
return getContrast ( ) ;
}
float VideoDevice : : getSaturation ( )
{
if ( m_current_input < m_input . size ( ) )
return m_input [ m_current_input ] . getSaturation ( ) ;
else
return 0 ;
}
float VideoDevice : : setSaturation ( float saturation )
{
kdDebug ( 14010 ) < < k_funcinfo < < " called. " < < endl ;
m_input [ m_current_input ] . setSaturation ( saturation ) ; // Just to check bounds
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
{
struct v4l2_queryctrl queryctrl ;
struct v4l2_control control ;
CLEAR ( queryctrl ) ;
queryctrl . id = V4L2_CID_SATURATION ;
if ( - 1 = = xioctl ( VIDIOC_QUERYCTRL , & queryctrl ) )
{
if ( errno ! = EINVAL )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_QUERYCTRL failed ( " < < errno < < " ). " < < endl ;
} else
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Saturation control. " < < endl ;
}
} else
if ( queryctrl . flags & V4L2_CTRL_FLAG_DISABLED )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Saturation control. " < < endl ;
} else
{
CLEAR ( control ) ;
control . id = V4L2_CID_SATURATION ;
control . value = ( __s32 ) ( ( queryctrl . maximum - queryctrl . minimum ) * getSaturation ( ) ) ;
if ( - 1 = = xioctl ( VIDIOC_S_CTRL , & control ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_S_CTRL failed ( " < < errno < < " ). " < < endl ;
}
}
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
{
struct video_picture V4L_picture ;
if ( - 1 = = xioctl ( VIDIOCGPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOCGPICT failed ( " < < errno < < " ). " < < endl ;
V4L_picture . colour = uint ( 65535 * getSaturation ( ) ) ;
if ( - 1 = = xioctl ( VIDIOCSPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Card seems to not support adjusting image saturation. Fallback to it is not yet implemented. " < < endl ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
return getSaturation ( ) ;
}
float VideoDevice : : getWhiteness ( )
{
if ( m_current_input < m_input . size ( ) )
return m_input [ m_current_input ] . getWhiteness ( ) ;
else
return 0 ;
}
float VideoDevice : : setWhiteness ( float whiteness )
{
kdDebug ( 14010 ) < < k_funcinfo < < " called. " < < endl ;
m_input [ m_current_input ] . setWhiteness ( whiteness ) ; // Just to check bounds
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
{
struct v4l2_queryctrl queryctrl ;
struct v4l2_control control ;
CLEAR ( queryctrl ) ;
queryctrl . id = V4L2_CID_WHITENESS ;
if ( - 1 = = xioctl ( VIDIOC_QUERYCTRL , & queryctrl ) )
{
if ( errno ! = EINVAL )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_QUERYCTRL failed ( " < < errno < < " ). " < < endl ;
} else
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Whiteness control. " < < endl ;
}
} else
if ( queryctrl . flags & V4L2_CTRL_FLAG_DISABLED )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Whiteness control. " < < endl ;
} else
{
CLEAR ( control ) ;
control . id = V4L2_CID_WHITENESS ;
control . value = ( __s32 ) ( ( queryctrl . maximum - queryctrl . minimum ) * getWhiteness ( ) ) ;
if ( - 1 = = xioctl ( VIDIOC_S_CTRL , & control ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_S_CTRL failed ( " < < errno < < " ). " < < endl ;
}
}
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
{
struct video_picture V4L_picture ;
if ( - 1 = = xioctl ( VIDIOCGPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOCGPICT failed ( " < < errno < < " ). " < < endl ;
V4L_picture . whiteness = uint ( 65535 * getWhiteness ( ) ) ;
if ( - 1 = = xioctl ( VIDIOCSPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Card seems to not support adjusting white level. Fallback to it is not yet implemented. " < < endl ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
return getWhiteness ( ) ;
}
float VideoDevice : : getHue ( )
{
if ( m_current_input < m_input . size ( ) )
return m_input [ m_current_input ] . getHue ( ) ;
else
return 0 ;
}
float VideoDevice : : setHue ( float hue )
{
kdDebug ( 14010 ) < < k_funcinfo < < " called. " < < endl ;
m_input [ m_current_input ] . setHue ( hue ) ; // Just to check bounds
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
{
struct v4l2_queryctrl queryctrl ;
struct v4l2_control control ;
CLEAR ( queryctrl ) ;
queryctrl . id = V4L2_CID_HUE ;
if ( - 1 = = xioctl ( VIDIOC_QUERYCTRL , & queryctrl ) )
{
if ( errno ! = EINVAL )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_QUERYCTRL failed ( " < < errno < < " ). " < < endl ;
} else
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Hue control. " < < endl ;
}
} else
if ( queryctrl . flags & V4L2_CTRL_FLAG_DISABLED )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Device doesn't support the Hue control. " < < endl ;
} else
{
CLEAR ( control ) ;
control . id = V4L2_CID_HUE ;
control . value = ( __s32 ) ( ( queryctrl . maximum - queryctrl . minimum ) * getHue ( ) ) ;
if ( - 1 = = xioctl ( VIDIOC_S_CTRL , & control ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOC_S_CTRL failed ( " < < errno < < " ). " < < endl ;
}
}
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
{
struct video_picture V4L_picture ;
if ( - 1 = = xioctl ( VIDIOCGPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " VIDIOCGPICT failed ( " < < errno < < " ). " < < endl ;
V4L_picture . hue = uint ( 65535 * getHue ( ) ) ;
if ( - 1 = = xioctl ( VIDIOCSPICT , & V4L_picture ) )
kdDebug ( 14010 ) < < k_funcinfo < < " Card seems to not support adjusting image hue. Fallback to it is not yet implemented. " < < endl ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
return getHue ( ) ;
}
bool VideoDevice : : getAutoBrightnessContrast ( )
{
if ( m_current_input < m_input . size ( ) )
return m_input [ m_current_input ] . getAutoBrightnessContrast ( ) ;
else
return false ;
}
bool VideoDevice : : setAutoBrightnessContrast ( bool brightnesscontrast )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VideoDevice::setAutoBrightnessContrast( " < < brightnesscontrast < < " ) called. " < < endl ;
if ( m_current_input < m_input . size ( ) )
{
m_input [ m_current_input ] . setAutoBrightnessContrast ( brightnesscontrast ) ;
return m_input [ m_current_input ] . getAutoBrightnessContrast ( ) ;
}
else
return false ;
}
bool VideoDevice : : getAutoColorCorrection ( )
{
if ( m_current_input < m_input . size ( ) )
return m_input [ m_current_input ] . getAutoColorCorrection ( ) ;
else
return false ;
}
bool VideoDevice : : setAutoColorCorrection ( bool colorcorrection )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VideoDevice::setAutoColorCorrection( " < < colorcorrection < < " ) called. " < < endl ;
if ( m_current_input < m_input . size ( ) )
{
m_input [ m_current_input ] . setAutoColorCorrection ( colorcorrection ) ;
return m_input [ m_current_input ] . getAutoColorCorrection ( ) ;
}
else
return false ;
}
bool VideoDevice : : getImageAsMirror ( )
{
if ( m_current_input < m_input . size ( ) )
return m_input [ m_current_input ] . getImageAsMirror ( ) ;
else
return false ;
}
bool VideoDevice : : setImageAsMirror ( bool imageasmirror )
{
kdDebug ( 14010 ) < < k_funcinfo < < " VideoDevice::setImageAsMirror( " < < imageasmirror < < " ) called. " < < endl ;
if ( m_current_input < m_input . size ( ) )
{
m_input [ m_current_input ] . setImageAsMirror ( imageasmirror ) ;
return m_input [ m_current_input ] . getImageAsMirror ( ) ;
}
else
return false ;
}
pixel_format VideoDevice : : pixelFormatForPalette ( int palette )
{
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
switch ( palette )
{
case 0 : return PIXELFORMAT_NONE ; break ;
// Packed RGB formats
case V4L2_PIX_FMT_RGB332 : return PIXELFORMAT_RGB332 ; break ;
# if defined( V4L2_PIX_FMT_RGB444 )
case V4L2_PIX_FMT_RGB444 : return PIXELFORMAT_RGB444 ; break ;
# endif
case V4L2_PIX_FMT_RGB555 : return PIXELFORMAT_RGB555 ; break ;
case V4L2_PIX_FMT_RGB565 : return PIXELFORMAT_RGB565 ; break ;
case V4L2_PIX_FMT_RGB555X : return PIXELFORMAT_RGB555X ; break ;
case V4L2_PIX_FMT_RGB565X : return PIXELFORMAT_RGB565X ; break ;
case V4L2_PIX_FMT_BGR24 : return PIXELFORMAT_BGR24 ; break ;
case V4L2_PIX_FMT_RGB24 : return PIXELFORMAT_RGB24 ; break ;
case V4L2_PIX_FMT_BGR32 : return PIXELFORMAT_BGR32 ; break ;
case V4L2_PIX_FMT_RGB32 : return PIXELFORMAT_RGB32 ; break ;
// Bayer RGB format
case V4L2_PIX_FMT_SBGGR8 : return PIXELFORMAT_SBGGR8 ; break ;
// YUV formats
case V4L2_PIX_FMT_GREY : return PIXELFORMAT_GREY ; break ;
case V4L2_PIX_FMT_YUYV : return PIXELFORMAT_YUYV ; break ;
case V4L2_PIX_FMT_UYVY : return PIXELFORMAT_UYVY ; break ;
case V4L2_PIX_FMT_YUV420 : return PIXELFORMAT_YUV420P ; break ;
case V4L2_PIX_FMT_YUV422P : return PIXELFORMAT_YUV422P ; break ;
// Compressed formats
case V4L2_PIX_FMT_JPEG : return PIXELFORMAT_JPEG ; break ;
case V4L2_PIX_FMT_MPEG : return PIXELFORMAT_MPEG ; break ;
// Reserved formats
case V4L2_PIX_FMT_DV : return PIXELFORMAT_DV ; break ;
case V4L2_PIX_FMT_ET61X251 : return PIXELFORMAT_ET61X251 ; break ;
case V4L2_PIX_FMT_HI240 : return PIXELFORMAT_HI240 ; break ;
# if defined( V4L2_PIX_FMT_HM12 )
case V4L2_PIX_FMT_HM12 : return PIXELFORMAT_HM12 ; break ;
# endif
case V4L2_PIX_FMT_MJPEG : return PIXELFORMAT_MJPEG ; break ;
case V4L2_PIX_FMT_PWC1 : return PIXELFORMAT_PWC1 ; break ;
case V4L2_PIX_FMT_PWC2 : return PIXELFORMAT_PWC2 ; break ;
case V4L2_PIX_FMT_SN9C10X : return PIXELFORMAT_SN9C10X ; break ;
case V4L2_PIX_FMT_WNVA : return PIXELFORMAT_WNVA ; break ;
case V4L2_PIX_FMT_YYUV : return PIXELFORMAT_YYUV ; break ;
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
switch ( palette )
{
case 0 : return PIXELFORMAT_NONE ; break ;
case VIDEO_PALETTE_GREY : return PIXELFORMAT_GREY ; break ;
case VIDEO_PALETTE_HI240 : return PIXELFORMAT_RGB332 ; break ;
case VIDEO_PALETTE_RGB555 : return PIXELFORMAT_RGB555 ; break ;
case VIDEO_PALETTE_RGB565 : return PIXELFORMAT_RGB565 ; break ;
case VIDEO_PALETTE_RGB24 : return PIXELFORMAT_RGB24 ; break ;
case VIDEO_PALETTE_RGB32 : return PIXELFORMAT_RGB32 ; break ;
case VIDEO_PALETTE_YUYV : return PIXELFORMAT_YUYV ; break ;
case VIDEO_PALETTE_UYVY : return PIXELFORMAT_UYVY ; break ;
case VIDEO_PALETTE_YUV420 :
case VIDEO_PALETTE_YUV420P : return PIXELFORMAT_YUV420P ; break ;
case VIDEO_PALETTE_YUV422P : return PIXELFORMAT_YUV422P ; break ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
return PIXELFORMAT_NONE ; break ;
}
return PIXELFORMAT_NONE ;
}
int VideoDevice : : pixelFormatCode ( pixel_format pixelformat )
{
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
switch ( pixelformat )
{
case PIXELFORMAT_NONE : return 0 ; break ;
// Packed RGB formats
case PIXELFORMAT_RGB332 : return V4L2_PIX_FMT_RGB332 ; break ;
# if defined( V4L2_PIX_FMT_RGB444 )
case PIXELFORMAT_RGB444 : return V4L2_PIX_FMT_RGB444 ; break ;
# endif
case PIXELFORMAT_RGB555 : return V4L2_PIX_FMT_RGB555 ; break ;
case PIXELFORMAT_RGB565 : return V4L2_PIX_FMT_RGB565 ; break ;
case PIXELFORMAT_RGB555X : return V4L2_PIX_FMT_RGB555X ; break ;
case PIXELFORMAT_RGB565X : return V4L2_PIX_FMT_RGB565X ; break ;
case PIXELFORMAT_BGR24 : return V4L2_PIX_FMT_BGR24 ; break ;
case PIXELFORMAT_RGB24 : return V4L2_PIX_FMT_RGB24 ; break ;
case PIXELFORMAT_BGR32 : return V4L2_PIX_FMT_BGR32 ; break ;
case PIXELFORMAT_RGB32 : return V4L2_PIX_FMT_RGB32 ; break ;
// Bayer RGB format
case PIXELFORMAT_SBGGR8 : return V4L2_PIX_FMT_SBGGR8 ; break ;
// YUV formats
case PIXELFORMAT_GREY : return V4L2_PIX_FMT_GREY ; break ;
case PIXELFORMAT_YUYV : return V4L2_PIX_FMT_YUYV ; break ;
case PIXELFORMAT_UYVY : return V4L2_PIX_FMT_UYVY ; break ;
case PIXELFORMAT_YUV420P : return V4L2_PIX_FMT_YUV420 ; break ;
case PIXELFORMAT_YUV422P : return V4L2_PIX_FMT_YUV422P ; break ;
// Compressed formats
case PIXELFORMAT_JPEG : return V4L2_PIX_FMT_JPEG ; break ;
case PIXELFORMAT_MPEG : return V4L2_PIX_FMT_MPEG ; break ;
// Reserved formats
case PIXELFORMAT_DV : return V4L2_PIX_FMT_DV ; break ;
case PIXELFORMAT_ET61X251 : return V4L2_PIX_FMT_ET61X251 ; break ;
case PIXELFORMAT_HI240 : return V4L2_PIX_FMT_HI240 ; break ;
# if defined( V4L2_PIX_FMT_HM12 )
case PIXELFORMAT_HM12 : return V4L2_PIX_FMT_HM12 ; break ;
# endif
case PIXELFORMAT_MJPEG : return V4L2_PIX_FMT_MJPEG ; break ;
case PIXELFORMAT_PWC1 : return V4L2_PIX_FMT_PWC1 ; break ;
case PIXELFORMAT_PWC2 : return V4L2_PIX_FMT_PWC2 ; break ;
case PIXELFORMAT_SN9C10X : return V4L2_PIX_FMT_SN9C10X ; break ;
case PIXELFORMAT_WNVA : return V4L2_PIX_FMT_WNVA ; break ;
case PIXELFORMAT_YYUV : return V4L2_PIX_FMT_YYUV ; break ;
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
switch ( pixelformat )
{
case PIXELFORMAT_NONE : return 0 ; break ;
// Packed RGB formats
case PIXELFORMAT_RGB332 : return VIDEO_PALETTE_HI240 ; break ;
case PIXELFORMAT_RGB444 : return 0 ; break ;
case PIXELFORMAT_RGB555 : return VIDEO_PALETTE_RGB555 ; break ;
case PIXELFORMAT_RGB565 : return VIDEO_PALETTE_RGB565 ; break ;
case PIXELFORMAT_RGB555X : return 0 ; break ;
case PIXELFORMAT_RGB565X : return 0 ; break ;
case PIXELFORMAT_BGR24 : return 0 ; break ;
case PIXELFORMAT_RGB24 : return VIDEO_PALETTE_RGB24 ; break ;
case PIXELFORMAT_BGR32 : return 0 ; break ;
case PIXELFORMAT_RGB32 : return VIDEO_PALETTE_RGB32 ; break ;
// Bayer RGB format
case PIXELFORMAT_SBGGR8 : return 0 ; break ;
// YUV formats
case PIXELFORMAT_GREY : return VIDEO_PALETTE_GREY ; break ;
case PIXELFORMAT_YUYV : return VIDEO_PALETTE_YUYV ; break ;
case PIXELFORMAT_UYVY : return VIDEO_PALETTE_UYVY ; break ;
case PIXELFORMAT_YUV420P : return VIDEO_PALETTE_YUV420 ; break ;
case PIXELFORMAT_YUV422P : return VIDEO_PALETTE_YUV422P ; break ;
// Compressed formats
case PIXELFORMAT_JPEG : return 0 ; break ;
case PIXELFORMAT_MPEG : return 0 ; break ;
// Reserved formats
case PIXELFORMAT_DV : return 0 ; break ;
case PIXELFORMAT_ET61X251 : return 0 ; break ;
case PIXELFORMAT_HI240 : return VIDEO_PALETTE_HI240 ; break ;
case PIXELFORMAT_HM12 : return 0 ; break ;
case PIXELFORMAT_MJPEG : return 0 ; break ;
case PIXELFORMAT_PWC1 : return 0 ; break ;
case PIXELFORMAT_PWC2 : return 0 ; break ;
case PIXELFORMAT_SN9C10X : return 0 ; break ;
case PIXELFORMAT_WNVA : return 0 ; break ;
case PIXELFORMAT_YYUV : return 0 ; break ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
return PIXELFORMAT_NONE ; break ;
}
return PIXELFORMAT_NONE ;
}
int VideoDevice : : pixelFormatDepth ( pixel_format pixelformat )
{
switch ( pixelformat )
{
case PIXELFORMAT_NONE : return 0 ; break ;
// Packed RGB formats
case PIXELFORMAT_RGB332 : return 8 ; break ;
case PIXELFORMAT_RGB444 : return 16 ; break ;
case PIXELFORMAT_RGB555 : return 16 ; break ;
case PIXELFORMAT_RGB565 : return 16 ; break ;
case PIXELFORMAT_RGB555X : return 16 ; break ;
case PIXELFORMAT_RGB565X : return 16 ; break ;
case PIXELFORMAT_BGR24 : return 24 ; break ;
case PIXELFORMAT_RGB24 : return 24 ; break ;
case PIXELFORMAT_BGR32 : return 32 ; break ;
case PIXELFORMAT_RGB32 : return 32 ; break ;
// Bayer RGB format
case PIXELFORMAT_SBGGR8 : return 0 ; break ;
// YUV formats
case PIXELFORMAT_GREY : return 8 ; break ;
case PIXELFORMAT_YUYV : return 16 ; break ;
case PIXELFORMAT_UYVY : return 16 ; break ;
case PIXELFORMAT_YUV420P : return 16 ; break ;
case PIXELFORMAT_YUV422P : return 16 ; break ;
// Compressed formats
case PIXELFORMAT_JPEG : return 0 ; break ;
case PIXELFORMAT_MPEG : return 0 ; break ;
// Reserved formats
case PIXELFORMAT_DV : return 0 ; break ;
case PIXELFORMAT_ET61X251 : return 0 ; break ;
case PIXELFORMAT_HI240 : return 8 ; break ;
case PIXELFORMAT_HM12 : return 0 ; break ;
case PIXELFORMAT_MJPEG : return 0 ; break ;
case PIXELFORMAT_PWC1 : return 0 ; break ;
case PIXELFORMAT_PWC2 : return 0 ; break ;
case PIXELFORMAT_SN9C10X : return 0 ; break ;
case PIXELFORMAT_WNVA : return 0 ; break ;
case PIXELFORMAT_YYUV : return 0 ; break ;
}
return 0 ;
}
TQString VideoDevice : : pixelFormatName ( pixel_format pixelformat )
{
TQString returnvalue ;
returnvalue = " None " ;
switch ( pixelformat )
{
case PIXELFORMAT_NONE : returnvalue = " None " ; break ;
// Packed RGB formats
case PIXELFORMAT_RGB332 : returnvalue = " 8-bit RGB332 " ; break ;
case PIXELFORMAT_RGB444 : returnvalue = " 8-bit RGB444 " ; break ;
case PIXELFORMAT_RGB555 : returnvalue = " 16-bit RGB555 " ; break ;
case PIXELFORMAT_RGB565 : returnvalue = " 16-bit RGB565 " ; break ;
case PIXELFORMAT_RGB555X : returnvalue = " 16-bit RGB555X " ; break ;
case PIXELFORMAT_RGB565X : returnvalue = " 16-bit RGB565X " ; break ;
case PIXELFORMAT_BGR24 : returnvalue = " 24-bit BGR24 " ; break ;
case PIXELFORMAT_RGB24 : returnvalue = " 24-bit RGB24 " ; break ;
case PIXELFORMAT_BGR32 : returnvalue = " 32-bit BGR32 " ; break ;
case PIXELFORMAT_RGB32 : returnvalue = " 32-bit RGB32 " ; break ;
// Bayer RGB format
case PIXELFORMAT_SBGGR8 : returnvalue = " Bayer RGB format " ; break ;
// YUV formats
case PIXELFORMAT_GREY : returnvalue = " 8-bit Grayscale " ; break ;
case PIXELFORMAT_YUYV : returnvalue = " Packed YUV 4:2:2 " ; break ;
case PIXELFORMAT_UYVY : returnvalue = " Packed YVU 4:2:2 " ; break ;
case PIXELFORMAT_YUV420P : returnvalue = " Planar YUV 4:2:0 " ; break ;
case PIXELFORMAT_YUV422P : returnvalue = " Planar YUV 4:2:2 " ; break ;
// Compressed formats
case PIXELFORMAT_JPEG : returnvalue = " JPEG image " ; break ;
case PIXELFORMAT_MPEG : returnvalue = " MPEG stream " ; break ;
// Reserved formats
case PIXELFORMAT_DV : returnvalue = " DV (unknown) " ; break ;
case PIXELFORMAT_ET61X251 : returnvalue = " ET61X251 " ; break ;
case PIXELFORMAT_HI240 : returnvalue = " 8-bit HI240 (RGB332) " ; break ;
case PIXELFORMAT_HM12 : returnvalue = " Packed YUV 4:2:2 " ; break ;
case PIXELFORMAT_MJPEG : returnvalue = " 8-bit Grayscale " ; break ;
case PIXELFORMAT_PWC1 : returnvalue = " PWC1 " ; break ;
case PIXELFORMAT_PWC2 : returnvalue = " PWC2 " ; break ;
case PIXELFORMAT_SN9C10X : returnvalue = " SN9C102 " ; break ;
case PIXELFORMAT_WNVA : returnvalue = " Winnov Videum " ; break ;
case PIXELFORMAT_YYUV : returnvalue = " YYUV (unknown) " ; break ;
}
return returnvalue ;
}
TQString VideoDevice : : pixelFormatName ( int pixelformat )
{
TQString returnvalue ;
returnvalue = " None " ;
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
switch ( pixelformat )
{
case 0 : returnvalue = pixelFormatName ( PIXELFORMAT_NONE ) ; break ;
// Packed RGB formats
case V4L2_PIX_FMT_RGB332 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB332 ) ; break ;
# if defined( V4L2_PIX_FMT_RGB444 )
case V4L2_PIX_FMT_RGB444 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB444 ) ; break ;
# endif
case V4L2_PIX_FMT_RGB555 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB555 ) ; break ;
case V4L2_PIX_FMT_RGB565 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB565 ) ; break ;
case V4L2_PIX_FMT_RGB555X : returnvalue = pixelFormatName ( PIXELFORMAT_RGB555X ) ; break ;
case V4L2_PIX_FMT_RGB565X : returnvalue = pixelFormatName ( PIXELFORMAT_RGB565X ) ; break ;
case V4L2_PIX_FMT_BGR24 : returnvalue = pixelFormatName ( PIXELFORMAT_BGR24 ) ; break ;
case V4L2_PIX_FMT_RGB24 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB24 ) ; break ;
case V4L2_PIX_FMT_BGR32 : returnvalue = pixelFormatName ( PIXELFORMAT_BGR32 ) ; break ;
case V4L2_PIX_FMT_RGB32 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB32 ) ; break ;
// Bayer RGB format
case V4L2_PIX_FMT_SBGGR8 : returnvalue = pixelFormatName ( PIXELFORMAT_SBGGR8 ) ; break ;
// YUV formats
case V4L2_PIX_FMT_GREY : returnvalue = pixelFormatName ( PIXELFORMAT_GREY ) ; break ;
case V4L2_PIX_FMT_YUYV : returnvalue = pixelFormatName ( PIXELFORMAT_YUYV ) ; break ;
case V4L2_PIX_FMT_UYVY : returnvalue = pixelFormatName ( PIXELFORMAT_UYVY ) ; break ;
case V4L2_PIX_FMT_YUV420 : returnvalue = pixelFormatName ( PIXELFORMAT_YUV420P ) ; break ;
case V4L2_PIX_FMT_YUV422P : returnvalue = pixelFormatName ( PIXELFORMAT_YUV422P ) ; break ;
// Compressed formats
case V4L2_PIX_FMT_JPEG : returnvalue = pixelFormatName ( PIXELFORMAT_JPEG ) ; break ;
case V4L2_PIX_FMT_MPEG : returnvalue = pixelFormatName ( PIXELFORMAT_MPEG ) ; break ;
// Reserved formats
case V4L2_PIX_FMT_DV : returnvalue = pixelFormatName ( PIXELFORMAT_DV ) ; break ;
case V4L2_PIX_FMT_ET61X251 : returnvalue = pixelFormatName ( PIXELFORMAT_ET61X251 ) ; break ;
case V4L2_PIX_FMT_HI240 : returnvalue = pixelFormatName ( PIXELFORMAT_HI240 ) ; break ;
# if defined( V4L2_PIX_FMT_HM12 )
case V4L2_PIX_FMT_HM12 : returnvalue = pixelFormatName ( PIXELFORMAT_HM12 ) ; break ;
# endif
case V4L2_PIX_FMT_MJPEG : returnvalue = pixelFormatName ( PIXELFORMAT_MJPEG ) ; break ;
case V4L2_PIX_FMT_PWC1 : returnvalue = pixelFormatName ( PIXELFORMAT_PWC1 ) ; break ;
case V4L2_PIX_FMT_PWC2 : returnvalue = pixelFormatName ( PIXELFORMAT_PWC2 ) ; break ;
case V4L2_PIX_FMT_SN9C10X : returnvalue = pixelFormatName ( PIXELFORMAT_SN9C10X ) ; break ;
case V4L2_PIX_FMT_WNVA : returnvalue = pixelFormatName ( PIXELFORMAT_WNVA ) ; break ;
case V4L2_PIX_FMT_YYUV : returnvalue = pixelFormatName ( PIXELFORMAT_YYUV ) ; break ;
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
switch ( pixelformat )
{
case VIDEO_PALETTE_GREY : returnvalue = pixelFormatName ( PIXELFORMAT_GREY ) ; break ;
case VIDEO_PALETTE_HI240 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB332 ) ; break ;
case VIDEO_PALETTE_RGB555 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB555 ) ; break ;
case VIDEO_PALETTE_RGB565 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB565 ) ; break ;
case VIDEO_PALETTE_RGB24 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB24 ) ; break ;
case VIDEO_PALETTE_RGB32 : returnvalue = pixelFormatName ( PIXELFORMAT_RGB32 ) ; break ;
case VIDEO_PALETTE_YUYV : returnvalue = pixelFormatName ( PIXELFORMAT_YUYV ) ; break ;
case VIDEO_PALETTE_UYVY : returnvalue = pixelFormatName ( PIXELFORMAT_UYVY ) ; break ;
case VIDEO_PALETTE_YUV420 :
case VIDEO_PALETTE_YUV420P : returnvalue = pixelFormatName ( PIXELFORMAT_YUV420P ) ; break ;
case VIDEO_PALETTE_YUV422P : returnvalue = pixelFormatName ( PIXELFORMAT_YUV422P ) ; break ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
return returnvalue ;
}
int VideoDevice : : detectPixelFormats ( )
{
int err = 0 ;
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
fmtdesc . index = 0 ;
fmtdesc . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
while ( err = = 0 )
{
if ( - 1 = = xioctl ( VIDIOC_ENUM_FMT , & fmtdesc ) )
// if (ioctl(fd, VIDIOC_ENUM_FMT, &fmtdesc) < 0 )
{
perror ( " VIDIOC_ENUM_FMT " ) ;
err = errno ;
}
else
{
kdDebug ( 14010 ) < < k_funcinfo < < fmtdesc . pixelformat < < " " < < pixelFormatName ( fmtdesc . pixelformat ) < < endl ; // Need a cleanup. PixelFormatForPalette is a really bad name
fmtdesc . index + + ;
}
}
// break;
# endif
case VIDEODEV_DRIVER_V4L :
// TODO: THis thing can be used to detec what pixel formats are supported in a API-independent way, but V4L2 has VIDIOC_ENUM_PIXFMT.
// The correct thing to do is to isolate these calls and do a proper implementation for V4L and another for V4L2 when this thing will be migrated to a plugin architecture.
// Packed RGB formats
kdDebug ( 14010 ) < < k_funcinfo < < " Supported pixel formats: " < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_RGB332 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_RGB332 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_RGB444 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_RGB444 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_RGB555 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_RGB555 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_RGB565 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_RGB565 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_RGB555X ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_RGB555X ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_RGB565X ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_RGB565X ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_BGR24 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_BGR24 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_RGB24 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_RGB24 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_BGR32 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_BGR32 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_RGB32 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_RGB32 ) < < endl ;
// Bayer RGB format
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_SBGGR8 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_SBGGR8 ) < < endl ;
// YUV formats
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_GREY ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_GREY ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_YUYV ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_YUYV ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_UYVY ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_UYVY ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_YUV420P ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_YUV420P ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_YUV422P ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_YUV422P ) < < endl ;
// Compressed formats
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_JPEG ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_JPEG ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_MPEG ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_MPEG ) < < endl ;
// Reserved formats
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_DV ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_DV ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_ET61X251 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_ET61X251 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_HI240 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_HI240 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_HM12 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_HM12 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_MJPEG ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_MJPEG ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_PWC1 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_PWC1 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_PWC2 ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_PWC2 ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_SN9C10X ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_SN9C10X ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_WNVA ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_WNVA ) < < endl ;
if ( PIXELFORMAT_NONE ! = setPixelFormat ( PIXELFORMAT_YYUV ) ) kdDebug ( 14010 ) < < k_funcinfo < < pixelFormatName ( PIXELFORMAT_YYUV ) < < endl ;
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
return PIXELFORMAT_NONE ; break ;
}
return PIXELFORMAT_NONE ;
}
__u64 VideoDevice : : signalStandardCode ( signal_standard standard )
{
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
switch ( standard )
{
case STANDARD_NONE : return V4L2_STD_UNKNOWN ; break ;
case STANDARD_PAL_B : return V4L2_STD_PAL_B ; break ;
case STANDARD_PAL_B1 : return V4L2_STD_PAL_B1 ; break ;
case STANDARD_PAL_G : return V4L2_STD_PAL_G ; break ;
case STANDARD_PAL_H : return V4L2_STD_PAL_H ; break ;
case STANDARD_PAL_I : return V4L2_STD_PAL_I ; break ;
case STANDARD_PAL_D : return V4L2_STD_PAL_D ; break ;
case STANDARD_PAL_D1 : return V4L2_STD_PAL_D1 ; break ;
case STANDARD_PAL_K : return V4L2_STD_PAL_K ; break ;
case STANDARD_PAL_M : return V4L2_STD_PAL_M ; break ;
case STANDARD_PAL_N : return V4L2_STD_PAL_N ; break ;
case STANDARD_PAL_Nc : return V4L2_STD_PAL_Nc ; break ;
case STANDARD_PAL_60 : return V4L2_STD_PAL_60 ; break ;
case STANDARD_NTSC_M : return V4L2_STD_NTSC_M ; break ;
case STANDARD_NTSC_M_JP : return V4L2_STD_NTSC_M_JP ; break ;
case STANDARD_NTSC_443 : return V4L2_STD_NTSC ; break ; // Using workaround value because my videodev2.h header seems to not include this standard in struct __u64 v4l2_std_id
case STANDARD_SECAM_B : return V4L2_STD_SECAM_B ; break ;
case STANDARD_SECAM_D : return V4L2_STD_SECAM_D ; break ;
case STANDARD_SECAM_G : return V4L2_STD_SECAM_G ; break ;
case STANDARD_SECAM_H : return V4L2_STD_SECAM_H ; break ;
case STANDARD_SECAM_K : return V4L2_STD_SECAM_K ; break ;
case STANDARD_SECAM_K1 : return V4L2_STD_SECAM_K1 ; break ;
case STANDARD_SECAM_L : return V4L2_STD_SECAM_L ; break ;
case STANDARD_SECAM_LC : return V4L2_STD_SECAM ; break ; // Using workaround value because my videodev2.h header seems to not include this standard in struct __u64 v4l2_std_id
case STANDARD_ATSC_8_VSB : return V4L2_STD_ATSC_8_VSB ; break ; // ATSC/HDTV Standard officially not supported by V4L2 but exists in videodev2.h
case STANDARD_ATSC_16_VSB : return V4L2_STD_ATSC_16_VSB ; break ; // ATSC/HDTV Standard officially not supported by V4L2 but exists in videodev2.h
case STANDARD_PAL_BG : return V4L2_STD_PAL_BG ; break ;
case STANDARD_PAL_DK : return V4L2_STD_PAL_DK ; break ;
case STANDARD_PAL : return V4L2_STD_PAL ; break ;
case STANDARD_NTSC : return V4L2_STD_NTSC ; break ;
case STANDARD_SECAM_DK : return V4L2_STD_SECAM_DK ; break ;
case STANDARD_SECAM : return V4L2_STD_SECAM ; break ;
case STANDARD_525_60 : return V4L2_STD_525_60 ; break ;
case STANDARD_625_50 : return V4L2_STD_625_50 ; break ;
case STANDARD_ALL : return V4L2_STD_ALL ; break ;
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
switch ( standard )
{
case STANDARD_NONE : return VIDEO_MODE_AUTO ; break ;
case STANDARD_PAL_B : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL_B1 : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL_G : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL_H : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL_I : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL_D : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL_D1 : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL_K : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL_M : return 5 ; break ; // Undocumented value found to be compatible with V4L bttv driver
case STANDARD_PAL_N : return 6 ; break ; // Undocumented value found to be compatible with V4L bttv driver
case STANDARD_PAL_Nc : return 4 ; break ; // Undocumented value found to be compatible with V4L bttv driver
case STANDARD_PAL_60 : return VIDEO_MODE_PAL ; break ;
case STANDARD_NTSC_M : return VIDEO_MODE_NTSC ; break ;
case STANDARD_NTSC_M_JP : return 7 ; break ; // Undocumented value found to be compatible with V4L bttv driver
case STANDARD_NTSC_443 : return VIDEO_MODE_NTSC ; break ; // Using workaround value because my videodev2.h header seems to not include this standard in struct __u64 v4l2_std_id
case STANDARD_SECAM_B : return VIDEO_MODE_SECAM ; break ;
case STANDARD_SECAM_D : return VIDEO_MODE_SECAM ; break ;
case STANDARD_SECAM_G : return VIDEO_MODE_SECAM ; break ;
case STANDARD_SECAM_H : return VIDEO_MODE_SECAM ; break ;
case STANDARD_SECAM_K : return VIDEO_MODE_SECAM ; break ;
case STANDARD_SECAM_K1 : return VIDEO_MODE_SECAM ; break ;
case STANDARD_SECAM_L : return VIDEO_MODE_SECAM ; break ;
case STANDARD_SECAM_LC : return VIDEO_MODE_SECAM ; break ; // Using workaround value because my videodev2.h header seems to not include this standard in struct __u64 v4l2_std_id
case STANDARD_ATSC_8_VSB : return VIDEO_MODE_AUTO ; break ; // ATSC/HDTV Standard officially not supported by V4L2 but exists in videodev2.h
case STANDARD_ATSC_16_VSB : return VIDEO_MODE_AUTO ; break ; // ATSC/HDTV Standard officially not supported by V4L2 but exists in videodev2.h
case STANDARD_PAL_BG : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL_DK : return VIDEO_MODE_PAL ; break ;
case STANDARD_PAL : return VIDEO_MODE_PAL ; break ;
case STANDARD_NTSC : return VIDEO_MODE_NTSC ; break ;
case STANDARD_SECAM_DK : return VIDEO_MODE_SECAM ; break ;
case STANDARD_SECAM : return VIDEO_MODE_SECAM ; break ;
case STANDARD_525_60 : return VIDEO_MODE_PAL ; break ;
case STANDARD_625_50 : return VIDEO_MODE_SECAM ; break ;
case STANDARD_ALL : return VIDEO_MODE_AUTO ; break ;
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
return STANDARD_NONE ; break ;
}
return STANDARD_NONE ;
}
TQString VideoDevice : : signalStandardName ( signal_standard standard )
{
TQString returnvalue ;
returnvalue = " None " ;
switch ( standard )
{
case STANDARD_NONE : returnvalue = " None " ; break ;
case STANDARD_PAL_B : returnvalue = " PAL-B " ; break ;
case STANDARD_PAL_B1 : returnvalue = " PAL-B1 " ; break ;
case STANDARD_PAL_G : returnvalue = " PAL-G " ; break ;
case STANDARD_PAL_H : returnvalue = " PAL-H " ; break ;
case STANDARD_PAL_I : returnvalue = " PAL-I " ; break ;
case STANDARD_PAL_D : returnvalue = " PAL-D " ; break ;
case STANDARD_PAL_D1 : returnvalue = " PAL-D1 " ; break ;
case STANDARD_PAL_K : returnvalue = " PAL-K " ; break ;
case STANDARD_PAL_M : returnvalue = " PAL-M " ; break ;
case STANDARD_PAL_N : returnvalue = " PAL-N " ; break ;
case STANDARD_PAL_Nc : returnvalue = " PAL-Nc " ; break ;
case STANDARD_PAL_60 : returnvalue = " PAL-60 " ; break ;
case STANDARD_NTSC_M : returnvalue = " NTSC-M " ; break ;
case STANDARD_NTSC_M_JP : returnvalue = " NTSC-M(JP) " ; break ;
case STANDARD_NTSC_443 : returnvalue = " NTSC-443 " ; break ;
case STANDARD_SECAM_B : returnvalue = " SECAM-B " ; break ;
case STANDARD_SECAM_D : returnvalue = " SECAM-D " ; break ;
case STANDARD_SECAM_G : returnvalue = " SECAM-G " ; break ;
case STANDARD_SECAM_H : returnvalue = " SECAM-H " ; break ;
case STANDARD_SECAM_K : returnvalue = " SECAM-K " ; break ;
case STANDARD_SECAM_K1 : returnvalue = " SECAM-K1 " ; break ;
case STANDARD_SECAM_L : returnvalue = " SECAM-L " ; break ;
case STANDARD_SECAM_LC : returnvalue = " SECAM-LC " ; break ;
case STANDARD_ATSC_8_VSB : returnvalue = " ATSC-8-VSB " ; break ; // ATSC/HDTV Standard officially not supported by V4L2 but exists in videodev2.h
case STANDARD_ATSC_16_VSB : returnvalue = " ATSC-16-VSB " ; break ; // ATSC/HDTV Standard officially not supported by V4L2 but exists in videodev2.h
case STANDARD_PAL_BG : returnvalue = " PAL-BG " ; break ;
case STANDARD_PAL_DK : returnvalue = " PAL-DK " ; break ;
case STANDARD_PAL : returnvalue = " PAL " ; break ;
case STANDARD_NTSC : returnvalue = " NTSC " ; break ;
case STANDARD_SECAM_DK : returnvalue = " SECAM-DK " ; break ;
case STANDARD_SECAM : returnvalue = " SECAM " ; break ;
case STANDARD_525_60 : returnvalue = " 525 lines 60Hz " ; break ;
case STANDARD_625_50 : returnvalue = " 625 lines 50Hz " ; break ;
case STANDARD_ALL : returnvalue = " All " ; break ;
}
return returnvalue ;
}
TQString VideoDevice : : signalStandardName ( int standard )
{
TQString returnvalue ;
returnvalue = " None " ;
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
switch ( standard )
{
case V4L2_STD_PAL_B : returnvalue = signalStandardName ( STANDARD_PAL_B ) ; break ;
case V4L2_STD_PAL_B1 : returnvalue = signalStandardName ( STANDARD_PAL_B1 ) ; break ;
case V4L2_STD_PAL_G : returnvalue = signalStandardName ( STANDARD_PAL_G ) ; break ;
case V4L2_STD_PAL_H : returnvalue = signalStandardName ( STANDARD_PAL_H ) ; break ;
case V4L2_STD_PAL_I : returnvalue = signalStandardName ( STANDARD_PAL_I ) ; break ;
case V4L2_STD_PAL_D : returnvalue = signalStandardName ( STANDARD_PAL_D ) ; break ;
case V4L2_STD_PAL_D1 : returnvalue = signalStandardName ( STANDARD_PAL_D1 ) ; break ;
case V4L2_STD_PAL_K : returnvalue = signalStandardName ( STANDARD_PAL_K ) ; break ;
case V4L2_STD_PAL_M : returnvalue = signalStandardName ( STANDARD_PAL_M ) ; break ;
case V4L2_STD_PAL_N : returnvalue = signalStandardName ( STANDARD_PAL_N ) ; break ;
case V4L2_STD_PAL_Nc : returnvalue = signalStandardName ( STANDARD_PAL_Nc ) ; break ;
case V4L2_STD_PAL_60 : returnvalue = signalStandardName ( STANDARD_PAL_60 ) ; break ;
case V4L2_STD_NTSC_M : returnvalue = signalStandardName ( STANDARD_NTSC_M ) ; break ;
case V4L2_STD_NTSC_M_JP : returnvalue = signalStandardName ( STANDARD_NTSC_M_JP ) ; break ;
// case V4L2_STD_NTSC_443 : returnvalue = signalStandardName(STANDARD_NTSC_443); break; // Commented out because my videodev2.h header seems to not include this standard in struct __u64 v4l2_std_id
case V4L2_STD_SECAM_B : returnvalue = signalStandardName ( STANDARD_SECAM_B ) ; break ;
case V4L2_STD_SECAM_D : returnvalue = signalStandardName ( STANDARD_SECAM_D ) ; break ;
case V4L2_STD_SECAM_G : returnvalue = signalStandardName ( STANDARD_SECAM_G ) ; break ;
case V4L2_STD_SECAM_H : returnvalue = signalStandardName ( STANDARD_SECAM_H ) ; break ;
case V4L2_STD_SECAM_K : returnvalue = signalStandardName ( STANDARD_SECAM_K ) ; break ;
case V4L2_STD_SECAM_K1 : returnvalue = signalStandardName ( STANDARD_SECAM_K1 ) ; break ;
case V4L2_STD_SECAM_L : returnvalue = signalStandardName ( STANDARD_SECAM_L ) ; break ;
// case V4L2_STD_SECAM_LC : returnvalue = signalStandardName(STANDARD_SECAM_LC); break; // Commented out because my videodev2.h header seems to not include this standard in struct __u64 v4l2_std_id
case V4L2_STD_ATSC_8_VSB : returnvalue = signalStandardName ( STANDARD_ATSC_8_VSB ) ; break ; // ATSC/HDTV Standard officially not supported by V4L2 but exists in videodev2.h
case V4L2_STD_ATSC_16_VSB : returnvalue = signalStandardName ( STANDARD_ATSC_16_VSB ) ; break ; // ATSC/HDTV Standard officially not supported by V4L2 but exists in videodev2.h
case V4L2_STD_PAL_BG : returnvalue = signalStandardName ( STANDARD_PAL_BG ) ; break ;
case V4L2_STD_PAL_DK : returnvalue = signalStandardName ( STANDARD_PAL_DK ) ; break ;
case V4L2_STD_PAL : returnvalue = signalStandardName ( STANDARD_PAL ) ; break ;
case V4L2_STD_NTSC : returnvalue = signalStandardName ( STANDARD_NTSC ) ; break ;
case V4L2_STD_SECAM_DK : returnvalue = signalStandardName ( STANDARD_SECAM_DK ) ; break ;
case V4L2_STD_SECAM : returnvalue = signalStandardName ( STANDARD_SECAM ) ; break ;
case V4L2_STD_525_60 : returnvalue = signalStandardName ( STANDARD_525_60 ) ; break ;
case V4L2_STD_625_50 : returnvalue = signalStandardName ( STANDARD_625_50 ) ; break ;
case V4L2_STD_ALL : returnvalue = signalStandardName ( STANDARD_ALL ) ; break ;
}
break ;
# endif
case VIDEODEV_DRIVER_V4L :
switch ( standard )
{
case VIDEO_MODE_PAL : returnvalue = signalStandardName ( STANDARD_PAL ) ; break ;
case VIDEO_MODE_NTSC : returnvalue = signalStandardName ( STANDARD_NTSC ) ; break ;
case VIDEO_MODE_SECAM : returnvalue = signalStandardName ( STANDARD_SECAM ) ; break ;
case VIDEO_MODE_AUTO : returnvalue = signalStandardName ( STANDARD_ALL ) ; break ; // It must be disabled until I find a correct way to handle those non-standard bttv modes
// case VIDEO_MODE_PAL_Nc : returnvalue = signalStandardName(STANDARD_PAL_Nc); break; // Undocumented value found to be compatible with V4L bttv driver
case VIDEO_MODE_PAL_M : returnvalue = signalStandardName ( STANDARD_PAL_M ) ; break ; // Undocumented value found to be compatible with V4L bttv driver
case VIDEO_MODE_PAL_N : returnvalue = signalStandardName ( STANDARD_PAL_N ) ; break ; // Undocumented value found to be compatible with V4L bttv driver
case VIDEO_MODE_NTSC_JP : returnvalue = signalStandardName ( STANDARD_NTSC_M_JP ) ; break ; // Undocumented value found to be compatible with V4L bttv driver
}
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
return returnvalue ;
}
/*!
\ fn VideoDevice : : detectSignalStandards ( )
*/
int VideoDevice : : detectSignalStandards ( )
{
switch ( m_driver )
{
# if defined(__linux__) && defined(ENABLE_AV)
# ifdef V4L2_CAP_VIDEO_CAPTURE
case VIDEODEV_DRIVER_V4L2 :
break ;
# endif
case VIDEODEV_DRIVER_V4L :
break ;
# endif
case VIDEODEV_DRIVER_NONE :
default :
break ;
}
//FIXME: return a real value
return 0 ;
}
/*!
\ fn VideoDevice : : initRead ( )
*/
int VideoDevice : : initRead ( )
{
/// @todo implement me
kdDebug ( 14010 ) < < k_funcinfo < < " called. " < < endl ;
if ( isOpen ( ) )
{
m_rawbuffers . resize ( 1 ) ;
if ( m_rawbuffers . size ( ) = = 0 )
{
fprintf ( stderr , " Out of memory \n " ) ;
return EXIT_FAILURE ;
}
kdDebug ( 14010 ) < < k_funcinfo < < " m_buffer_size: " < < m_buffer_size < < endl ;
// m_rawbuffers[0].pixelformat=m_pixelformat;
m_rawbuffers [ 0 ] . length = m_buffer_size ;
m_rawbuffers [ 0 ] . start = ( uchar * ) malloc ( m_buffer_size ) ;
if ( ! m_rawbuffers [ 0 ] . start )
{
fprintf ( stderr , " Out of memory \n " ) ;
return EXIT_FAILURE ;
}
kdDebug ( 14010 ) < < k_funcinfo < < " exited successfuly. " < < endl ;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn VideoDevice : : initMmap ( )
*/
int VideoDevice : : initMmap ( )
{
/// @todo implement me
# define BUFFERS 2
if ( isOpen ( ) )
{
kdDebug ( 14010 ) < < k_funcinfo < < full_filename < < " Trying to MMAP " < < endl ;
# ifdef V4L2_CAP_VIDEO_CAPTURE
struct v4l2_requestbuffers req ;
CLEAR ( req ) ;
req . count = BUFFERS ;
req . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
req . memory = V4L2_MEMORY_MMAP ;
if ( - 1 = = xioctl ( VIDIOC_REQBUFS , & req ) )
{
if ( EINVAL = = errno )
{
kdDebug ( 14010 ) < < k_funcinfo < < full_filename < < " does not support memory mapping " < < endl ;
return EXIT_FAILURE ;
}
else
{
return errnoReturn ( " VIDIOC_REQBUFS " ) ;
}
}
if ( req . count < BUFFERS )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Insufficient buffer memory on " < < full_filename < < endl ;
return EXIT_FAILURE ;
}
m_rawbuffers . resize ( req . count ) ;
if ( m_rawbuffers . size ( ) = = 0 )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Out of memory " < < endl ;
return EXIT_FAILURE ;
}
for ( m_streambuffers = 0 ; m_streambuffers < req . count ; + + m_streambuffers )
{
struct v4l2_buffer v4l2buffer ;
CLEAR ( v4l2buffer ) ;
v4l2buffer . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
v4l2buffer . memory = V4L2_MEMORY_MMAP ;
v4l2buffer . index = m_streambuffers ;
if ( - 1 = = xioctl ( VIDIOC_QUERYBUF , & v4l2buffer ) )
return errnoReturn ( " VIDIOC_QUERYBUF " ) ;
m_rawbuffers [ m_streambuffers ] . length = v4l2buffer . length ;
m_rawbuffers [ m_streambuffers ] . start = ( uchar * ) mmap ( NULL /* start anywhere */ , v4l2buffer . length , PROT_READ | PROT_WRITE /* required */ , MAP_SHARED /* recommended */ , descriptor , v4l2buffer . m . offset ) ;
if ( MAP_FAILED = = m_rawbuffers [ m_streambuffers ] . start )
return errnoReturn ( " mmap " ) ;
}
# endif
m_currentbuffer . data . resize ( m_rawbuffers [ 0 ] . length ) ; // Makes the imagesize.data buffer size equal to the rawbuffer size
kdDebug ( 14010 ) < < k_funcinfo < < full_filename < < " m_currentbuffer.data.size(): " < < m_currentbuffer . data . size ( ) < < endl ;
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
/*!
\ fn VideoDevice : : initUserptr ( )
*/
int VideoDevice : : initUserptr ( )
{
/// @todo implement me
if ( isOpen ( ) )
{
# ifdef V4L2_CAP_VIDEO_CAPTURE
struct v4l2_requestbuffers req ;
CLEAR ( req ) ;
req . count = 2 ;
req . type = V4L2_BUF_TYPE_VIDEO_CAPTURE ;
req . memory = V4L2_MEMORY_USERPTR ;
if ( - 1 = = xioctl ( VIDIOC_REQBUFS , & req ) )
{
if ( EINVAL = = errno )
{
kdDebug ( 14010 ) < < k_funcinfo < < full_filename < < " does not support memory mapping " < < endl ;
return EXIT_FAILURE ;
}
else
{
return errnoReturn ( " VIDIOC_REQBUFS " ) ;
}
}
m_rawbuffers . resize ( 4 ) ;
if ( m_rawbuffers . size ( ) = = 0 )
{
fprintf ( stderr , " Out of memory \n " ) ;
return EXIT_FAILURE ;
}
for ( m_streambuffers = 0 ; m_streambuffers < 4 ; + + m_streambuffers )
{
m_rawbuffers [ m_streambuffers ] . length = m_buffer_size ;
m_rawbuffers [ m_streambuffers ] . start = ( uchar * ) malloc ( m_buffer_size ) ;
if ( ! m_rawbuffers [ m_streambuffers ] . start )
{
kdDebug ( 14010 ) < < k_funcinfo < < " Out of memory " < < endl ;
return EXIT_FAILURE ;
}
}
# endif
return EXIT_SUCCESS ;
}
return EXIT_FAILURE ;
}
bool VideoDevice : : canCapture ( )
{
return m_videocapture ;
}
bool VideoDevice : : canChromakey ( )
{
return m_videochromakey ;
}
bool VideoDevice : : canScale ( )
{
return m_videoscale ;
}
bool VideoDevice : : canOverlay ( )
{
return m_videooverlay ;
}
bool VideoDevice : : canRead ( )
{
return m_videoread ;
}
bool VideoDevice : : canAsyncIO ( )
{
return m_videoasyncio ;
}
bool VideoDevice : : canStream ( )
{
return m_videostream ;
}
}
}