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beetle-pce-fast-libretro/mednafen/cdrom/CDAccess_Physical.cpp
Themaister 377a85b857 Update PSX core to 0.9.31-wip.
2013-09-08 13:41:01 +02:00

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8.2 KiB
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/* Mednafen - Multi-system Emulator
*
* 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 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* 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, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*/
#define EXTERNAL_LIBCDIO_CONFIG_H 1
#include "../mednafen.h"
#include "../general.h"
#include "CDAccess.h"
#include "CDAccess_Physical.h"
#include <time.h>
#include <cdio/cdio.h>
#include <cdio/mmc.h>
//#include <cdio/logging.h>
#if LIBCDIO_VERSION_NUM >= 83
#include <cdio/mmc_cmds.h>
#endif
using namespace CDUtility;
void CDAccess_Physical::DetermineFeatures(void)
{
uint8 buf[256];
mmc_cdb_t cdb = {{0, }};
CDIO_MMC_SET_COMMAND(cdb.field, CDIO_MMC_GPCMD_MODE_SENSE_10);
memset(buf, 0, sizeof(buf));
cdb.field[2] = 0x2A;
cdb.field[7] = sizeof(buf) >> 8;
cdb.field[8] = sizeof(buf) & 0xFF;
if(mmc_run_cmd ((CdIo *)p_cdio, MMC_TIMEOUT_DEFAULT,
&cdb,
SCSI_MMC_DATA_READ,
sizeof(buf),
buf))
{
throw(MDFN_Error(0, _("MMC [MODE SENSE 10] command failed.")));
}
else
{
const uint8 *pd = &buf[8];
if(pd[0] != 0x2A || pd[1] < 0x14)
{
throw(MDFN_Error(0, _("MMC [MODE SENSE 10] command returned bogus data for mode page 0x2A.")));
}
if(!(pd[4] & 0x10))
{
throw(MDFN_Error(0, _("Drive does not support reading Mode 2 Form 1 sectors.")));
}
if(!(pd[4] & 0x20))
{
throw(MDFN_Error(0, _("Drive does not support reading Mode 2 Form 2 sectors.")));
}
if(!(pd[5] & 0x01))
{
throw(MDFN_Error(0, _("Reading CD-DA sectors via \"READ CD\" is not supported.")));
}
if(!(pd[5] & 0x02))
{
throw(MDFN_Error(0, _("Read CD-DA sectors via \"READ CD\" are not positionally-accurate.")));
}
if(!(pd[5] & 0x04))
{
throw(MDFN_Error(0, _("Reading raw subchannel data via \"READ CD\" is not supported.")));
}
}
}
void CDAccess_Physical::PreventAllowMediumRemoval(bool prevent)
{
#if 0
mmc_cdb_t cdb = {{0, }};
uint8 buf[8];
cdb.field[0] = 0x1E;
cdb.field[1] = 0x00;
cdb.field[2] = 0x00;
cdb.field[3] = 0x00;
cdb.field[4] = 0x00; //prevent;
cdb.field[5] = 0x00;
printf("%d\n", mmc_run_cmd_len (p_cdio, MMC_TIMEOUT_DEFAULT,
&cdb, 6,
SCSI_MMC_DATA_READ, 0, buf));
assert(0);
#endif
}
void CDAccess_Physical::ReadPhysDiscInfo(unsigned retry)
{
mmc_cdb_t cdb = {{0, }};
uint8 toc_buffer[8192];
int64 start_time = time(NULL);
int cdio_rc;
cdb.field[0] = 0x43; // Read TOC
cdb.field[1] = 0x00;
cdb.field[2] = 0x00; // Format 0000b
cdb.field[3] = 0x00;
cdb.field[4] = 0x00;
cdb.field[5] = 0x00;
cdb.field[6] = 0x01; // Track number
cdb.field[7] = sizeof(toc_buffer) >> 8;
cdb.field[8] = sizeof(toc_buffer) & 0xFF;
cdb.field[9] = 0x00;
memset(toc_buffer, 0, sizeof(toc_buffer));
while((cdio_rc = mmc_run_cmd ((CdIo *)p_cdio, MMC_TIMEOUT_DEFAULT,
&cdb,
SCSI_MMC_DATA_READ,
sizeof(toc_buffer),
toc_buffer)))
{
if(!retry || time(NULL) >= (start_time + retry))
{
throw(MDFN_Error(0, _("Error reading disc TOC.")));
}
}
PhysTOC.Clear();
PhysTOC.first_track = toc_buffer[2];
PhysTOC.last_track = toc_buffer[3];
if(PhysTOC.first_track < 1 || PhysTOC.first_track > 99)
{
throw(MDFN_Error(0, _("Invalid first track: %d\n"), PhysTOC.first_track));
}
if(PhysTOC.last_track > 99 || PhysTOC.last_track < PhysTOC.first_track)
{
throw(MDFN_Error(0, _("Invalid last track: %d\n"), PhysTOC.last_track));
}
int32 len_counter = MDFN_de16msb(&toc_buffer[0]) - 2;
uint8 *tbi = &toc_buffer[4];
assert(len_counter >= 0);
assert((len_counter & 7) == 0);
while(len_counter)
{
uint8 adr = tbi[1] >> 4;
uint8 control = tbi[1] & 0xF;
uint8 tnum = tbi[2];
uint32 lba = MDFN_de32msb(&tbi[4]);
if(tnum == 0xAA)
{
PhysTOC.tracks[100].adr = adr;
PhysTOC.tracks[100].control = control;
PhysTOC.tracks[100].lba = lba;
}
else if(tnum >= PhysTOC.first_track && tnum <= PhysTOC.last_track)
{
PhysTOC.tracks[tnum].adr = adr;
PhysTOC.tracks[tnum].control = control;
PhysTOC.tracks[tnum].lba = lba;
}
tbi += 8;
len_counter -= 8;
}
// Convenience leadout track duplication.
if(PhysTOC.last_track < 99)
PhysTOC.tracks[PhysTOC.last_track + 1] = PhysTOC.tracks[100];
}
void CDAccess_Physical::Read_TOC(TOC *toc)
{
*toc = PhysTOC;
}
void CDAccess_Physical::Read_Raw_Sector(uint8 *buf, int32 lba)
{
mmc_cdb_t cdb = {{0, }};
int cdio_rc;
CDIO_MMC_SET_COMMAND(cdb.field, CDIO_MMC_GPCMD_READ_CD);
CDIO_MMC_SET_READ_TYPE (cdb.field, CDIO_MMC_READ_TYPE_ANY);
CDIO_MMC_SET_READ_LBA (cdb.field, lba);
CDIO_MMC_SET_READ_LENGTH24(cdb.field, 1);
if(SkipSectorRead[(lba >> 3) & 0xFFFF] & (1 << (lba & 7)))
{
printf("Read(skipped): %d\n", lba);
memset(buf, 0, 2352);
cdb.field[9] = 0x00;
cdb.field[10] = 0x01;
if((cdio_rc = mmc_run_cmd ((CdIo *)p_cdio, MMC_TIMEOUT_DEFAULT,
&cdb,
SCSI_MMC_DATA_READ,
96,
buf + 2352)))
{
throw(MDFN_Error(0, _("MMC Read Error; libcdio return code %d"), cdio_rc));
}
}
else
{
cdb.field[9] = 0xF8;
cdb.field[10] = 0x01;
if((cdio_rc = mmc_run_cmd ((CdIo *)p_cdio, MMC_TIMEOUT_DEFAULT,
&cdb,
SCSI_MMC_DATA_READ,
2352 + 96,
buf)))
{
throw(MDFN_Error(0, _("MMC Read Error; libcdio return code %d"), cdio_rc));
}
}
}
//static void nlh(cdio_log_level_t level, const char message[])
//{
// printf("%s\n", message);
//}
CDAccess_Physical::CDAccess_Physical(const char *path)
{
char **devices = NULL;
char **parseit = NULL;
p_cdio = NULL;
cdio_init();
//cdio_log_set_handler(nlh);
//
//
//
try
{
devices = cdio_get_devices(DRIVER_DEVICE);
parseit = devices;
if(parseit)
{
MDFN_printf(_("Connected physical devices:\n"));
MDFN_indent(1);
while(*parseit)
{
MDFN_printf("%s\n", *parseit);
parseit++;
}
MDFN_indent(-1);
}
if(!parseit || parseit == devices)
{
throw(MDFN_Error(0, _("No CDROM drives detected(or no disc present).")));
}
if(devices)
{
cdio_free_device_list(devices);
devices = NULL;
}
p_cdio = cdio_open_cd(path);
if(!p_cdio)
{
throw(MDFN_Error(0, _("Unknown error opening physical CD")));
}
//PreventAllowMediumRemoval(true);
ReadPhysDiscInfo(0);
//
// Determine how we can read this CD.
//
DetermineFeatures();
memset(SkipSectorRead, 0, sizeof(SkipSectorRead));
}
catch(std::exception &e)
{
if(devices)
cdio_free_device_list(devices);
if(p_cdio)
cdio_destroy((CdIo *)p_cdio);
throw;
}
}
CDAccess_Physical::~CDAccess_Physical()
{
cdio_destroy((CdIo *)p_cdio);
}
bool CDAccess_Physical::Is_Physical(void) throw()
{
return(true);
}
void CDAccess_Physical::Eject(bool eject_status)
{
int cdio_rc;
#if LIBCDIO_VERSION_NUM >= 83
if((cdio_rc = mmc_start_stop_unit((CdIo *)p_cdio, eject_status, false, 0, 0)) != 0)
{
if(cdio_rc != DRIVER_OP_UNSUPPORTED) // Don't error out if it's just an unsupported operation.
throw(MDFN_Error(0, _("Error ejecting medium;; libcdio return code %d"), cdio_rc));
}
#else
if((cdio_rc = mmc_start_stop_media((CdIo *)p_cdio, eject_status, false, 0)) != 0)
{
if(cdio_rc != DRIVER_OP_UNSUPPORTED) // Don't error out if it's just an unsupported operation.
throw(MDFN_Error(0, _("Error ejecting medium;; libcdio return code %d"), cdio_rc));
}
#endif
if(!eject_status)
{
try
{
ReadPhysDiscInfo(10);
}
catch(std::exception &e)
{
#if LIBCDIO_VERSION_NUM >= 83
mmc_start_stop_unit((CdIo *)p_cdio, true, false, 0, 0); // Eject disc, if possible.
#else
mmc_start_stop_media((CdIo *)p_cdio, true, false, 0); // Eject disc, if possible.
#endif
throw;
}
}
}
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