/*
Copyright (C) 2004, 2005, 2007, 2008, 2010, 2011
Rocky Bernstein <rocky@gnu.org>
Copyright (C) 1998, 2002 Monty monty@xiph.org
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
/******************************************************************
*
* CDROM communication common to all interface methods is done here
* (mostly ioctl stuff, but not ioctls specific to the 'cooked'
* interface)
*
******************************************************************/
/* common_interface.h has to come first else _FILE_OFFSET_BITS are
redefined in say opensolaris. */
#include "common_interface.h"
#include <math.h>
#include "utils.h"
#include "smallft.h"
/* Variables to hold debugger-helping enumerations */
enum paranoia_cdda_enums;
enum paranoia_jitter_enums;
/*! Determine Endian-ness of the CD-drive based on reading data from
it. Some drives return audio data Big Endian while some (most)
return data Little Endian. Drives known to return data bigendian are
SCSI drives from Kodak, Ricoh, HP, Philips, Plasmon, Grundig
CDR100IPW, and Mitsumi CD-R. ATAPI and MMC drives are little endian.
rocky: As someone who didn't write the code, I have to say this is
nothing less than brilliant. An FFT is done both ways and the the
transform is looked at to see which has data in the FFT (or audible)
portion. (Or so that's how I understand it.)
@return 1 if big-endian, 0 if little-endian, -1 if we couldn't
figure things out or some error.
*/
int
data_bigendianp(cdrom_drive_t *d)
{
float lsb_votes=0;
float msb_votes=0;
int i,checked;
int endiancache=d->bigendianp;
float *a=calloc(1024,sizeof(float));
float *b=calloc(1024,sizeof(float));
long readsectors=5;
int16_t *buff=malloc(readsectors*CDIO_CD_FRAMESIZE_RAW*sizeof(int16_t));
memset(buff, 0, readsectors*CDIO_CD_FRAMESIZE_RAW*sizeof(int16_t));
/* look at the starts of the audio tracks */
/* if real silence, tool in until some static is found */
/* Force no swap for now */
d->bigendianp=-1;
cdmessage(d,"\nAttempting to determine drive endianness from data...");
d->enable_cdda(d,1);
for(i=0,checked=0;i<d->tracks;i++){
float lsb_energy=0;
float msb_energy=0;
if(cdda_track_audiop(d,i+1)==1){
long firstsector=cdda_track_firstsector(d,i+1);
long lastsector=cdda_track_lastsector(d,i+1);
int zeroflag=-1;
long beginsec=0;
/* find a block with nonzero data */
while(firstsector+readsectors<=lastsector){
int j;
if(d->read_audio(d,buff,firstsector,readsectors)>0){
/* Avoid scanning through jitter at the edges */
for(beginsec=0;beginsec<readsectors;beginsec++){
int offset=beginsec*CDIO_CD_FRAMESIZE_RAW/2;
/* Search *half* */
for(j=460;j<128+460;j++)
if(buff[offset+j]!=0){
zeroflag=0;
break;
}
if(!zeroflag)break;
}
if(!zeroflag)break;
firstsector+=readsectors;
}else{
d->enable_cdda(d,0);
free(a);
free(b);
free(buff);
return(-1);
}
}
beginsec*=CDIO_CD_FRAMESIZE_RAW/2;
/* un-interleave for an FFT */
if(!zeroflag){
int j;
for(j=0;j<128;j++)
a[j] = le16_to_cpu(buff[j*2+beginsec+460]);
for(j=0;j<128;j++)
b[j] = le16_to_cpu(buff[j*2+beginsec+461]);
fft_forward(128,a,NULL,NULL);
fft_forward(128,b,NULL,NULL);
for(j=0;j<128;j++)
lsb_energy+=fabs(a[j])+fabs(b[j]);
for(j=0;j<128;j++)
a[j] = be16_to_cpu(buff[j*2+beginsec+460]);
for(j=0;j<128;j++)
b[j] = be16_to_cpu(buff[j*2+beginsec+461]);
fft_forward(128,a,NULL,NULL);
fft_forward(128,b,NULL,NULL);
for(j=0;j<128;j++)
msb_energy+=fabs(a[j])+fabs(b[j]);
}
}
if(lsb_energy<msb_energy){
lsb_votes+=msb_energy/lsb_energy;
checked++;
}else
if(lsb_energy>msb_energy){
msb_votes+=lsb_energy/msb_energy;
checked++;
}
if(checked==5 && (lsb_votes==0 || msb_votes==0))break;
cdmessage(d,".");
}
free(buff);
free(a);
free(b);
d->bigendianp=endiancache;
d->enable_cdda(d,0);
/* How did we vote? Be potentially noisy */
if (lsb_votes>msb_votes) {
char buffer[256];
cdmessage(d,"\n\tData appears to be coming back Little Endian.\n");
sprintf(buffer,"\tcertainty: %d%%\n",(int)
(100.*lsb_votes/(lsb_votes+msb_votes)+.5));
cdmessage(d,buffer);
return(0);
} else {
if(msb_votes>lsb_votes){
char buffer[256];
cdmessage(d,"\n\tData appears to be coming back Big Endian.\n");
sprintf(buffer,"\tcertainty: %d%%\n",(int)
(100.*msb_votes/(lsb_votes+msb_votes)+.5));
cdmessage(d,buffer);
return(1);
}
cdmessage(d,"\n\tCannot determine CDROM drive endianness.\n");
return(bigendianp());
}
}
/************************************************************************/
/*! Here we fix up a couple of things that will never happen. yeah,
right.
The multisession stuff is from Hannu code; it assumes it knows the
leadout/leadin size. [I think Hannu refers to Hannu Savolainen
from GNU/Linux Kernel code.]
@return -1 if we can't get multisession info, 0 if there is one
session only or the last session LBA is the same as the first audio
track and 1 if the multi-session lba is higher than first audio track
*/
int
FixupTOC(cdrom_drive_t *d, track_t i_tracks)
{
int j;
/* First off, make sure the 'starting sector' is >=0 */
for( j=0; j<i_tracks; j++){
if (d->disc_toc[j].dwStartSector<0 ) {
cdmessage(d,"\n\tTOC entry claims a negative start offset: massaging"
".\n");
d->disc_toc[j].dwStartSector=0;
}
if( j<i_tracks-1 && d->disc_toc[j].dwStartSector>
d->disc_toc[j+1].dwStartSector ) {
cdmessage(d,"\n\tTOC entry claims an overly large start offset: massaging"
".\n");
d->disc_toc[j].dwStartSector=0;
}
}
/* Make sure the listed 'starting sectors' are actually increasing.
Flag things that are blatant/stupid/wrong */
{
lsn_t last=d->disc_toc[0].dwStartSector;
for ( j=1; j<i_tracks; j++){
if ( d->disc_toc[j].dwStartSector<last ) {
cdmessage(d,"\n\tTOC entries claim non-increasing offsets: massaging"
".\n");
d->disc_toc[j].dwStartSector=last;
}
last=d->disc_toc[j].dwStartSector;
}
}
d->audio_last_sector = CDIO_INVALID_LSN;
{
lsn_t last_ses_lsn;
if (cdio_get_last_session (d->p_cdio, &last_ses_lsn) < 0)
return -1;
/* A Red Book Disc must have only one session, otherwise this is a
* CD Extra */
if (last_ses_lsn > d->disc_toc[0].dwStartSector) {
/* CD Extra discs have two session, the first one ending after
* the last audio track
* Thus the need to fix the length of the the audio data portion to
* not cross the lead-out of this session */
for (j = i_tracks-1; j > 1; j--) {
if (cdio_get_track_format(d->p_cdio, j+1) != TRACK_FORMAT_AUDIO &&
cdio_get_track_format(d->p_cdio, j) == TRACK_FORMAT_AUDIO) {
/* First session lead-out is 1:30
* Lead-ins are 1:00
* Every session's first track have a 0:02 pregap
*
* That makes a control data section of (90+60+2)*75 sectors in the
* last audio track */
const int gap = ((90+60+2) * CDIO_CD_FRAMES_PER_SEC);
if ((last_ses_lsn - gap >= d->disc_toc[j-1].dwStartSector) &&
(last_ses_lsn - gap < d->disc_toc[j].dwStartSector)) {
d->audio_last_sector = last_ses_lsn - gap - 1;
break;
}
}
}
return 1;
}
}
return 0;
}