sys/cdrom/gstcdplayer_ioctl_bsd.h - mtk-gst-plugins-bad - Git at Google

 /* gstcdplay
  * Copyright (c) 2002 Charles Schmidt <cbschmid@uiuc.edu>

  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Library General Public
  * License as published by the Free Software Foundation; either
  * version 2 of the License, or (at your option) any later version.
  *
  * This library is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  * Library General Public License for more details.
  *
  * You should have received a copy of the GNU Library General Public
  * License along with this library; if not, write to the
  * Free Software Foundation, Inc., 51 Franklin St, Fifth Floor,
  * Boston, MA 02110-1301, USA.
  */

 #ifdef HAVE_CDROM_BSD_NETBSD /* net & open */
 #ifndef CDIOREADTOCHDR
 #define CDIOREADTOCHDR CDIOREADTOCHEADER
 #endif
 gboolean cd_init(struct cd *cd,const gchar *device)
 {
         struct ioc_toc_header toc_header;
         struct ioc_read_toc_entry toc_entry;
         struct cd_toc_entry toc_entry_data;
         guint i;

         cd->fd = open(device,O_RDONLY | O_NONBLOCK);

         if (cd->fd == -1) {
                 return FALSE;
         }

         /* get the toc header information */
         if (ioctl(cd->fd,CDIOREADTOCHDR,&toc_header) != 0) {
                 close(cd->fd);
                 cd->fd = -1;
                 return FALSE;
         }

         /* read each entry in the toc header */
         for (i = 1; i <= toc_header.ending_track; i++) {
                 toc_entry.address_format = CD_MSF_FORMAT;
                 toc_entry.starting_track = i;
                 toc_entry.data = &toc_entry_data;
                 toc_entry.data_len = sizeof(toc_entry_data);

                 if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
                         close(cd->fd);
                         cd->fd = -1;
                         return FALSE;
                 }

                 cd->tracks[i].minute = toc_entry.data->addr.msf.minute;
                 cd->tracks[i].second = toc_entry.data->addr.msf.second;
                 cd->tracks[i].frame = toc_entry.data->addr.msf.frame;
                 cd->tracks[i].data_track = (toc_entry.data->control & 4) == 4;
         }

         /* read the leadout */
         toc_entry.address_format = CD_MSF_FORMAT;
         toc_entry.starting_track = 0xAA; /* leadout */
         toc_entry.data = &toc_entry_data;
         toc_entry.data_len = sizeof(toc_entry_data);

         if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
                 close(cd->fd);
                 cd->fd = -1;
                 return FALSE;
         }

         cd->tracks[LEADOUT].minute = toc_entry.data->addr.msf.minute;
         cd->tracks[LEADOUT].second = toc_entry.data->addr.msf.second;
         cd->tracks[LEADOUT].frame = toc_entry.data->addr.msf.frame;

         cd->num_tracks = toc_header.ending_track;

         return TRUE;
 }
 #elif defined HAVE_CDROM_BSD_DARWIN
 gboolean cd_init(struct cd *cd,const gchar *device)
 {
         struct ioc_toc_header toc_header;
         struct ioc_read_toc_entry toc_entry;
         guint i;

         cd->fd = open(device,O_RDONLY | O_NONBLOCK);

         if (cd->fd == -1) {
                 return FALSE;
         }

         /* get the toc header information */
         if (ioctl(cd->fd,CDIOREADTOCHDR,&toc_header) != 0) {
                 close(cd->fd);
                 cd->fd = -1;
                 return FALSE;
         }

         /* read each entry in the toc header */
         for (i = 1; i <= toc_header.ending_track; i++) {
                 toc_entry.address_format = CD_MSF_FORMAT;
                 toc_entry.starting_track = i;

                 if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
                         close(cd->fd);
                         cd->fd = -1;
                         return FALSE;
                 }

                 cd->tracks[i].minute = toc_entry.data->addr[1];
                 cd->tracks[i].second = toc_entry.data->addr[2];
                 cd->tracks[i].frame = toc_entry.data->addr[3];
                 cd->tracks[i].data_track = (toc_entry.data->control & 4) == 4;
         }

         /* read the leadout */
         toc_entry.address_format = CD_MSF_FORMAT;
         toc_entry.starting_track = 0xAA; /* leadout */
         toc_entry.data = &toc_entry_data;
         toc_entry.data_len = sizeof(toc_entry_data);

         if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
                 close(cd->fd);
                 cd->fd = -1;
                 return FALSE;
         }

         cd->tracks[LEADOUT].minute = toc_entry.data->addr[1];
         cd->tracks[LEADOUT].second = toc_entry.data->addr[2];
         cd->tracks[LEADOUT].frame = toc_entry.data->addr[3];

         cd->num_tracks = toc_header.ending_track;

         return TRUE;
 }
 #else /* free */
 gboolean cd_init(struct cd *cd,const gchar *device)
 {
         struct ioc_toc_header toc_header;
         struct ioc_read_toc_entry toc_entry;
         guint i;

         cd->fd = open(device,O_RDONLY | O_NONBLOCK);

         if (cd->fd == -1) {
                 return FALSE;
         }

         /* get the toc header information */
         if (ioctl(cd->fd,CDIOREADTOCHDR,&toc_header) != 0) {
                 close(cd->fd);
                 cd->fd = -1;
                 return FALSE;
         }

         /* read each entry in the toc header */
         for (i = 1; i <= toc_header.ending_track; i++) {
                 toc_entry.address_format = CD_MSF_FORMAT;
                 toc_entry.starting_track = i;

                 if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
                         close(cd->fd);
                         cd->fd = -1;
                         return FALSE;
                 }

                 cd->tracks[i].minute = toc_entry.entry.addr.msf.minute;
                 cd->tracks[i].second = toc_entry.entry.addr.msf.second;
                 cd->tracks[i].frame = toc_entry.entry.addr.msf.frame;
                 cd->tracks[i].data_track = (toc_entry.data->control & 4) == 4;
         }

         /* read the leadout */
         toc_entry.address_format = CD_MSF_FORMAT;
         toc_entry.starting_track = 0xAA; /* leadout */
         toc_entry.data = &toc_entry_data;
         toc_entry.data_len = sizeof(toc_entry_data);

         if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
                 close(cd->fd);
                 cd->fd = -1;
                 return FALSE;
         }

         cd->tracks[LEADOUT].minute = toc_entry.entry.addr.msf.minute;
         cd->tracks[LEADOUT].second = toc_entry.entry.addr.msf.second;
         cd->tracks[LEADOUT].frame = toc_entry.entry.addr.msf.frame;

         cd->num_tracks = toc_header.ending_track;

         return TRUE;
 }
 #endif

 gboolean cd_start(struct cd *cd,gint start_track,gint end_track)
 {
         struct ioc_play_msf msf;

         if (cd->fd == -1) {
                 return FALSE;
         }

         cd_fix_track_range(cd,&start_track,&end_track);

         msf.start_m = cd->tracks[start_track].minute;
         msf.start_s = cd->tracks[start_track].second;
         msf.start_f = cd->tracks[start_track].frame;

         if (end_track == LEADOUT) {
                 msf.end_m = cd->tracks[end_track].minute;
                 msf.end_s = cd->tracks[end_track].second;
                 msf.end_f = cd->tracks[end_track].frame;
         } else {
                 msf.end_m = cd->tracks[end_track+1].minute;
                 msf.end_s = cd->tracks[end_track+1].second;
                 msf.end_f = cd->tracks[end_track+1].frame;
         }

         if (ioctl(cd->fd,CDIOCPLAYMSF,&msf) != 0) {
                 return FALSE;
         }

 }

 gboolean cd_pause(struct cd *cd)
 {
         if (cd->fd == -1) {
                 return FALSE;
         }

         if (ioctl(cd->fd,CDIOCPAUSE,NULL) != 0) {
                 return FALSE;
         }

         return TRUE;
 }

 gboolean cd_resume(struct cd *cd)
 {
         if (cd->fd == -1) {
                 return FALSE;
         }

         if (ioctl(cd->fd,CDIOCRESUME,NULL) != 0) {
                 return FALSE;
         }

         return TRUE;
 }

 gboolean cd_stop(struct cd *cd)
 {
         if (cd->fd == -1) {
                 return FALSE;
         }

         if (ioctl(cd->fd,CDIOCSTOP,NULL) != 0) {
                 return FALSE;
         }

         return TRUE;
 }

 /* -1 for error, 0 for not playing, 1 for playing */
 CDStatus cd_status(struct cd *cd)
 {
         struct ioc_read_subchannel sub_channel;
         struct cd_sub_channel_info sub_channel_info;

         if (cd->fd == -1) {
                 return -1;
         }

         sub_channel.address_format = CD_MSF_FORMAT;
         sub_channel.data_format = CD_CURRENT_POSITION;
         sub_channel.track = 0;
         sub_channel.data = &sub_channel_info;
         sub_channel.data_len = sizeof(sub_channel_info);

         if (ioctl(cd->fd,CDIOCREADSUBCHANNEL,&sub_channel) != 0) {
                 return FALSE;
         }

         switch (sub_channel.data->header.audio_status) {
                 case CD_AS_PLAY_IN_PROGRESS:
                 case CD_AS_PLAY_PAUSED:
                         return CD_PLAYING;
                         break;
                 case CD_AS_PLAY_COMPLETED:
                         return CD_COMPLETED;
                         break;
                 case CD_AS_AUDIO_INVALID:
                 case CD_AS_PLAY_ERROR:
                 default:
                         return CD_ERROR;
                         break;

         }
 }

 gint cd_current_track(struct cd *cd)
 {
         struct ioc_read_subchannel sub_channel;
         struct cd_sub_channel_info sub_channel_info;

         if (cd->fd == -1) {
                 return -1;
         }

         sub_channel.address_format = CD_MSF_FORMAT;
         sub_channel.data_format = CD_TRACK_INFO;
         sub_channel.track = 0;
         sub_channel.data = &sub_channel_info;
         sub_channel.data_len = sizeof(sub_channel_info);

         if (ioctl(cd->fd,CDIOCREADSUBCHANNEL,&sub_channel) != 0) {
                 return -1;
         }

 #ifdef __NetBSD__
         return sub_channel.data->what.track_info.track_number;
 #else
         return sub_channel.data->track_number;
 #endif
 }

 gboolean cd_close(struct cd *cd)
 {
         if (cd->fd == -1) {
                 return TRUE;
         }

         if (close(cd->fd) != 0) {
                 return FALSE;
         }

         cd->fd = -1;

         return TRUE;
 }
	/* gstcdplay
	* Copyright (c) 2002 Charles Schmidt <cbschmid@uiuc.edu>

	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Library General Public
	* License as published by the Free Software Foundation; either
	* version 2 of the License, or (at your option) any later version.
	*
	* This library is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* Library General Public License for more details.
	*
	* You should have received a copy of the GNU Library General Public
	* License along with this library; if not, write to the
	* Free Software Foundation, Inc., 51 Franklin St, Fifth Floor,
	* Boston, MA 02110-1301, USA.
	*/

	#ifdef HAVE_CDROM_BSD_NETBSD /* net & open */
	#ifndef CDIOREADTOCHDR
	#define CDIOREADTOCHDR CDIOREADTOCHEADER
	#endif
	gboolean cd_init(struct cd cd,const gchar device)
	{
	struct ioc_toc_header toc_header;
	struct ioc_read_toc_entry toc_entry;
	struct cd_toc_entry toc_entry_data;
	guint i;

	cd->fd = open(device,O_RDONLY \| O_NONBLOCK);

	if (cd->fd == -1) {
	return FALSE;
	}

	/* get the toc header information */
	if (ioctl(cd->fd,CDIOREADTOCHDR,&toc_header) != 0) {
	close(cd->fd);
	cd->fd = -1;
	return FALSE;
	}

	/* read each entry in the toc header */
	for (i = 1; i <= toc_header.ending_track; i++) {
	toc_entry.address_format = CD_MSF_FORMAT;
	toc_entry.starting_track = i;
	toc_entry.data = &toc_entry_data;
	toc_entry.data_len = sizeof(toc_entry_data);

	if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
	close(cd->fd);
	cd->fd = -1;
	return FALSE;
	}

	cd->tracks[i].minute = toc_entry.data->addr.msf.minute;
	cd->tracks[i].second = toc_entry.data->addr.msf.second;
	cd->tracks[i].frame = toc_entry.data->addr.msf.frame;
	cd->tracks[i].data_track = (toc_entry.data->control & 4) == 4;
	}

	/* read the leadout */
	toc_entry.address_format = CD_MSF_FORMAT;
	toc_entry.starting_track = 0xAA; /* leadout */
	toc_entry.data = &toc_entry_data;
	toc_entry.data_len = sizeof(toc_entry_data);

	if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
	close(cd->fd);
	cd->fd = -1;
	return FALSE;
	}

	cd->tracks[LEADOUT].minute = toc_entry.data->addr.msf.minute;
	cd->tracks[LEADOUT].second = toc_entry.data->addr.msf.second;
	cd->tracks[LEADOUT].frame = toc_entry.data->addr.msf.frame;

	cd->num_tracks = toc_header.ending_track;

	return TRUE;
	}
	#elif defined HAVE_CDROM_BSD_DARWIN
	gboolean cd_init(struct cd cd,const gchar device)
	{
	struct ioc_toc_header toc_header;
	struct ioc_read_toc_entry toc_entry;
	guint i;

	cd->fd = open(device,O_RDONLY \| O_NONBLOCK);

	if (cd->fd == -1) {
	return FALSE;
	}

	/* get the toc header information */
	if (ioctl(cd->fd,CDIOREADTOCHDR,&toc_header) != 0) {
	close(cd->fd);
	cd->fd = -1;
	return FALSE;
	}

	/* read each entry in the toc header */
	for (i = 1; i <= toc_header.ending_track; i++) {
	toc_entry.address_format = CD_MSF_FORMAT;
	toc_entry.starting_track = i;

	if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
	close(cd->fd);
	cd->fd = -1;
	return FALSE;
	}

	cd->tracks[i].minute = toc_entry.data->addr[1];
	cd->tracks[i].second = toc_entry.data->addr[2];
	cd->tracks[i].frame = toc_entry.data->addr[3];
	cd->tracks[i].data_track = (toc_entry.data->control & 4) == 4;
	}

	/* read the leadout */
	toc_entry.address_format = CD_MSF_FORMAT;
	toc_entry.starting_track = 0xAA; /* leadout */
	toc_entry.data = &toc_entry_data;
	toc_entry.data_len = sizeof(toc_entry_data);

	if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
	close(cd->fd);
	cd->fd = -1;
	return FALSE;
	}

	cd->tracks[LEADOUT].minute = toc_entry.data->addr[1];
	cd->tracks[LEADOUT].second = toc_entry.data->addr[2];
	cd->tracks[LEADOUT].frame = toc_entry.data->addr[3];

	cd->num_tracks = toc_header.ending_track;

	return TRUE;
	}
	#else /* free */
	gboolean cd_init(struct cd cd,const gchar device)
	{
	struct ioc_toc_header toc_header;
	struct ioc_read_toc_entry toc_entry;
	guint i;

	cd->fd = open(device,O_RDONLY \| O_NONBLOCK);

	if (cd->fd == -1) {
	return FALSE;
	}

	/* get the toc header information */
	if (ioctl(cd->fd,CDIOREADTOCHDR,&toc_header) != 0) {
	close(cd->fd);
	cd->fd = -1;
	return FALSE;
	}

	/* read each entry in the toc header */
	for (i = 1; i <= toc_header.ending_track; i++) {
	toc_entry.address_format = CD_MSF_FORMAT;
	toc_entry.starting_track = i;

	if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
	close(cd->fd);
	cd->fd = -1;
	return FALSE;
	}

	cd->tracks[i].minute = toc_entry.entry.addr.msf.minute;
	cd->tracks[i].second = toc_entry.entry.addr.msf.second;
	cd->tracks[i].frame = toc_entry.entry.addr.msf.frame;
	cd->tracks[i].data_track = (toc_entry.data->control & 4) == 4;
	}

	/* read the leadout */
	toc_entry.address_format = CD_MSF_FORMAT;
	toc_entry.starting_track = 0xAA; /* leadout */
	toc_entry.data = &toc_entry_data;
	toc_entry.data_len = sizeof(toc_entry_data);

	if (ioctl(cd->fd,CDIOREADTOCENTRYS,&toc_entry) != 0) {
	close(cd->fd);
	cd->fd = -1;
	return FALSE;
	}

	cd->tracks[LEADOUT].minute = toc_entry.entry.addr.msf.minute;
	cd->tracks[LEADOUT].second = toc_entry.entry.addr.msf.second;
	cd->tracks[LEADOUT].frame = toc_entry.entry.addr.msf.frame;

	cd->num_tracks = toc_header.ending_track;

	return TRUE;
	}
	#endif

	gboolean cd_start(struct cd *cd,gint start_track,gint end_track)
	{
	struct ioc_play_msf msf;

	if (cd->fd == -1) {
	return FALSE;
	}

	cd_fix_track_range(cd,&start_track,&end_track);

	msf.start_m = cd->tracks[start_track].minute;
	msf.start_s = cd->tracks[start_track].second;
	msf.start_f = cd->tracks[start_track].frame;

	if (end_track == LEADOUT) {
	msf.end_m = cd->tracks[end_track].minute;
	msf.end_s = cd->tracks[end_track].second;
	msf.end_f = cd->tracks[end_track].frame;
	} else {
	msf.end_m = cd->tracks[end_track+1].minute;
	msf.end_s = cd->tracks[end_track+1].second;
	msf.end_f = cd->tracks[end_track+1].frame;
	}

	if (ioctl(cd->fd,CDIOCPLAYMSF,&msf) != 0) {
	return FALSE;
	}

	}

	gboolean cd_pause(struct cd *cd)
	{
	if (cd->fd == -1) {
	return FALSE;
	}

	if (ioctl(cd->fd,CDIOCPAUSE,NULL) != 0) {
	return FALSE;
	}

	return TRUE;
	}

	gboolean cd_resume(struct cd *cd)
	{
	if (cd->fd == -1) {
	return FALSE;
	}

	if (ioctl(cd->fd,CDIOCRESUME,NULL) != 0) {
	return FALSE;
	}

	return TRUE;
	}

	gboolean cd_stop(struct cd *cd)
	{
	if (cd->fd == -1) {
	return FALSE;
	}

	if (ioctl(cd->fd,CDIOCSTOP,NULL) != 0) {
	return FALSE;
	}

	return TRUE;
	}

	/* -1 for error, 0 for not playing, 1 for playing */
	CDStatus cd_status(struct cd *cd)
	{
	struct ioc_read_subchannel sub_channel;
	struct cd_sub_channel_info sub_channel_info;

	if (cd->fd == -1) {
	return -1;
	}

	sub_channel.address_format = CD_MSF_FORMAT;
	sub_channel.data_format = CD_CURRENT_POSITION;
	sub_channel.track = 0;
	sub_channel.data = &sub_channel_info;
	sub_channel.data_len = sizeof(sub_channel_info);

	if (ioctl(cd->fd,CDIOCREADSUBCHANNEL,&sub_channel) != 0) {
	return FALSE;
	}

	switch (sub_channel.data->header.audio_status) {
	case CD_AS_PLAY_IN_PROGRESS:
	case CD_AS_PLAY_PAUSED:
	return CD_PLAYING;
	break;
	case CD_AS_PLAY_COMPLETED:
	return CD_COMPLETED;
	break;
	case CD_AS_AUDIO_INVALID:
	case CD_AS_PLAY_ERROR:
	default:
	return CD_ERROR;
	break;

	}
	}

	gint cd_current_track(struct cd *cd)
	{
	struct ioc_read_subchannel sub_channel;
	struct cd_sub_channel_info sub_channel_info;

	if (cd->fd == -1) {
	return -1;
	}

	sub_channel.address_format = CD_MSF_FORMAT;
	sub_channel.data_format = CD_TRACK_INFO;
	sub_channel.track = 0;
	sub_channel.data = &sub_channel_info;
	sub_channel.data_len = sizeof(sub_channel_info);

	if (ioctl(cd->fd,CDIOCREADSUBCHANNEL,&sub_channel) != 0) {
	return -1;
	}

	#ifdef __NetBSD__
	return sub_channel.data->what.track_info.track_number;
	#else
	return sub_channel.data->track_number;
	#endif
	}

	gboolean cd_close(struct cd *cd)
	{
	if (cd->fd == -1) {
	return TRUE;
	}

	if (close(cd->fd) != 0) {
	return FALSE;
	}

	cd->fd = -1;

	return TRUE;
	}