libburn/libburn/mmc.c

2368 lines
67 KiB
C

/* -*- indent-tabs-mode: t; tab-width: 8; c-basic-offset: 8; -*- */
/* ts A61009 */
/* #include <a ssert.h> */
#include <stdio.h>
#include <string.h>
#include <unistd.h>
#include <stdlib.h>
#include <pthread.h>
#include "error.h"
#include "sector.h"
#include "libburn.h"
#include "transport.h"
#include "mmc.h"
#include "spc.h"
#include "drive.h"
#include "debug.h"
#include "toc.h"
#include "structure.h"
#include "options.h"
#ifdef Libburn_log_in_and_out_streaM
/* <<< ts A61031 */
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#endif /* Libburn_log_in_and_out_streaM */
/* ts A61005 */
#include "libdax_msgs.h"
extern struct libdax_msgs *libdax_messenger;
/* ts A61219 : Based on knowlege from dvd+rw-tools-7.0 and mmc5r03c.pdf */
#define Libburn_support_dvd_plus_rW 1
/* ts A61229 */
#define Libburn_support_dvd_minusrw_overW 1
/* ts A70112 */
#define Libburn_support_dvd_raM 1
/* ts A70129 >>> EXPERIMENTAL UNTESTED
*/
#define Libburn_support_dvd_r_seQ 1
/* Progress report:
ts A61219 : It seems to work with a used (i.e. thoroughly formatted) DVD+RW.
Error messages of class DEBUG appear because of inability to
read TOC or track info. Nevertheless, the written images verify.
ts A61220 : Burned to a virgin DVD+RW by help of new mmc_format_unit()
(did not test wether it would work without). Burned to a
not completely formatted DVD+RW. (Had worked before without
mmc_format_unit() but i did not exceed the formatted range
as reported by dvd+rw-mediainfo.)
ts A61221 : Speed setting now works for both of my drives. The according
functions in dvd+rw-tools are a bit intimidating to the reader.
I hope it is possible to leave much of this to the drive.
And if it fails ... well, it's only speed setting. :))
ts A61229 : Burned to several DVD-RW formatted to mode Restricted Overwrite
by dvd+rw-format. Needs Libburn_support_dvd_minusrw_overW.
ts A61230 : Other than growisofs, libburn does not send a mode page 5 for
such DVD-RW (which the MMC-5 standard does deprecate) and it
really seems to work without such a page.
ts A70101 : Formatted DVD-RW media. Success is varying with media, but
dvd+rw-format does not do better with the same media.
ts A70112 : Support for writing to DVD-RAM.
ts A70130 : Burned a first non-multi sequential DVD-RW. Feature 0021h
Incremental Recording vanishes after that and media thus gets
not recognized as suitable any more.
After a run with -multi another disc still offers 0021h .
dvd+rw-mediainfo shows two tracks. The second, an afio archive
is readable by afio. Third and forth veryfy too. Suddenly
dvd+rw-mediainfo sees lba 0 with track 2. But #2 still verifies
if one knows its address.
ts A70203 : DVD-RW need to get blanked fully. Then feature 0021h persists.
Meanwhile Incremental streaming is supported like CD TAO:
with unpredicted size, multi-track, multi-session.
ts A70205 : Beginning to implement DVD-R[W] DAO : single track and session,
size prediction mandatory.
ts A70208 : Finally made tests with DVD-R. Worked exactly as new DVD-RW.
Todo:
Determine first free lba for appending data on overwriteables.
*/
static unsigned char MMC_GET_MSINFO[] =
{ 0x43, 0, 1, 0, 0, 0, 0, 16, 0, 0 };
static unsigned char MMC_GET_TOC[] = { 0x43, 2, 2, 0, 0, 0, 0, 16, 0, 0 };
static unsigned char MMC_GET_ATIP[] = { 0x43, 2, 4, 0, 0, 0, 0, 16, 0, 0 };
static unsigned char MMC_GET_DISC_INFO[] =
{ 0x51, 0, 0, 0, 0, 0, 0, 16, 0, 0 };
static unsigned char MMC_READ_CD[] = { 0xBE, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
static unsigned char MMC_BLANK[] = { 0xA1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
static unsigned char MMC_SEND_OPC[] = { 0x54, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
static unsigned char MMC_SET_SPEED[] =
{ 0xBB, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
static unsigned char MMC_WRITE_12[] =
{ 0xAA, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
static unsigned char MMC_WRITE_10[] = { 0x2A, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
/* ts A61201 : inserted 0, before 16, */
static unsigned char MMC_GET_CONFIGURATION[] =
{ 0x46, 0, 0, 0, 0, 0, 0, 16, 0, 0 };
static unsigned char MMC_SYNC_CACHE[] = { 0x35, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
static unsigned char MMC_GET_EVENT[] = { 0x4A, 1, 0, 0, 16, 0, 0, 0, 8, 0 };
static unsigned char MMC_CLOSE[] = { 0x5B, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
static unsigned char MMC_TRACK_INFO[] = { 0x52, 0, 0, 0, 0, 0, 0, 16, 0, 0 };
static unsigned char MMC_SEND_CUE_SHEET[] =
{ 0x5D, 0, 0, 0, 0, 0, 0, 0, 0, 0 };
/* ts A61023 : get size and free space of drive buffer */
static unsigned char MMC_READ_BUFFER_CAPACITY[] =
{ 0x5C, 0, 0, 0, 0, 0, 0, 16, 0, 0 };
/* ts A61219 : format DVD+RW (and various others) */
static unsigned char MMC_FORMAT_UNIT[] = { 0x04, 0x11, 0, 0, 0, 0 };
/* ts A61221 :
To set speed for DVD media (0xBB is for CD but works on my LG GSA drive) */
static unsigned char MMC_SET_STREAMING[] =
{ 0xB6, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
/* ts A61225 :
To obtain write speed descriptors (command can do other things too) */
static unsigned char MMC_GET_PERFORMANCE[] =
{ 0xAC, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};
/* ts A70108 : To obtain info about drive and media formatting opportunities */
static unsigned char MMC_READ_FORMAT_CAPACITIES[] =
{ 0x23, 0, 0, 0, 0, 0, 0, 0, 0, 0};
/* ts A70205 : To describe the layout of a DVD-R[W] DAO session */
static unsigned char MMC_RESERVE_TRACK[] =
{ 0x53, 0, 0, 0, 0, 0, 0, 0, 0, 0};
static int mmc_function_spy_do_tell = 0;
int mmc_function_spy(char * text)
{
if (mmc_function_spy_do_tell)
fprintf(stderr,"libburn: experimental: mmc_function_spy: %s\n",
text);
return 1;
}
int mmc_function_spy_ctrl(int do_tell)
{
mmc_function_spy_do_tell= !!do_tell;
return 1;
}
/* ts A70201 */
int mmc_four_char_to_int(unsigned char *data)
{
return (data[0] << 24) | (data[1] << 16) | (data[2] << 8) | data[3];
}
/* ts A70201 */
int mmc_int_to_four_char(unsigned char *data, int num)
{
data[0] = (num >> 24) & 0xff;
data[1] = (num >> 16) & 0xff;
data[2] = (num >> 8) & 0xff;
data[3] = num & 0xff;
return 1;
}
void mmc_send_cue_sheet(struct burn_drive *d, struct cue_sheet *s)
{
struct buffer buf;
struct command c;
mmc_function_spy("mmc_send_cue_sheet");
c.retry = 1;
c.oplen = sizeof(MMC_SEND_CUE_SHEET);
memcpy(c.opcode, MMC_SEND_CUE_SHEET, sizeof(MMC_SEND_CUE_SHEET));
c.page = &buf;
c.page->bytes = s->count * 8;
c.page->sectors = 0;
c.opcode[6] = (c.page->bytes >> 16) & 0xFF;
c.opcode[7] = (c.page->bytes >> 8) & 0xFF;
c.opcode[8] = c.page->bytes & 0xFF;
c.dir = TO_DRIVE;
memcpy(c.page->data, s->data, c.page->bytes);
d->issue_command(d, &c);
}
/* ts A70205 : Announce size of a DVD-R[W] DAO session.
@param size The size in bytes to be announced to the drive.
It will get rounded up to align to 32 KiB.
*/
int mmc_reserve_track(struct burn_drive *d, off_t size)
{
struct command c;
int lba;
char msg[80];
mmc_function_spy("mmc_reserve_track");
c.retry = 1;
c.oplen = sizeof(MMC_RESERVE_TRACK);
memcpy(c.opcode, MMC_RESERVE_TRACK, sizeof(MMC_RESERVE_TRACK));
/* Round to 32 KiB and divide by 2048
(by nice binary rounding trick learned from dvd+rw-tools) */
lba = ((size + (off_t) 0x7fff) >> 11) & ~0xf;
mmc_int_to_four_char(c.opcode+5, lba);
sprintf(msg, "reserving track of %d blocks", lba);
libdax_msgs_submit(libdax_messenger, -1, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
msg, 0, 0);
c.page = NULL;
c.dir = NO_TRANSFER;
d->issue_command(d, &c);
return !c.error;
}
/* ts A70201 :
Common track info fetcher for mmc_get_nwa() and mmc_fake_toc()
*/
int mmc_read_track_info(struct burn_drive *d, int trackno, struct buffer *buf)
{
struct command c;
int i;
mmc_function_spy("mmc_read_track_info");
c.retry = 1;
c.oplen = sizeof(MMC_TRACK_INFO);
memcpy(c.opcode, MMC_TRACK_INFO, sizeof(MMC_TRACK_INFO));
c.opcode[1] = 1;
if(trackno<=0) {
if (d->current_profile == 0x1a || d->current_profile == 0x13 ||
d->current_profile == 0x12 )
/* DVD+RW , DVD-RW restricted overwrite , DVD-RAM */
trackno = 1;
else if (d->current_profile == 0x10 ||
d->current_profile == 0x11 ||
d->current_profile == 0x14)
/* DVD-ROM , DVD-R[W] Sequential */
trackno = d->last_track_no;
else /* mmc5r03c.pdf: valid only for CD, DVD+R, DVD+R DL */
trackno = 0xFF;
}
for (i = 0; i < 4; i++)
c.opcode[2 + i] = (trackno >> (24 - 8 * i)) & 0xff;
c.page = buf;
memset(buf->data, 0, BUFFER_SIZE);
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
if (c.error)
return 0;
return 1;
}
/* ts A61110 : added parameters trackno, lba, nwa. Redefined return value.
@return 1=nwa is valid , 0=nwa is not valid , -1=error */
/* ts A70201 : outsourced 52h READ TRACK INFO command */
int mmc_get_nwa(struct burn_drive *d, int trackno, int *lba, int *nwa)
{
struct buffer buf;
int ret, num;
unsigned char *data;
mmc_function_spy("mmc_get_nwa");
if(trackno<=0) {
if (d->current_profile == 0x1a || d->current_profile == 0x13 ||
d->current_profile == 0x12 )
/* DVD+RW , DVD-RW restricted overwrite , DVD-RAM */
trackno = 1;
else if (d->current_profile == 0x10 ||
d->current_profile == 0x11 ||
d->current_profile == 0x14)
/* DVD-ROM, DVD-R[W] Sequential */
trackno = d->last_track_no;
else /* mmc5r03c.pdf: valid only for CD, DVD+R, DVD+R DL */
trackno = 0xFF;
}
ret = mmc_read_track_info(d, trackno, &buf);
if (ret <= 0)
return ret;
data = buf.data;
*lba = mmc_four_char_to_int(data + 8);
*nwa = mmc_four_char_to_int(data + 12);
num = mmc_four_char_to_int(data + 16);
if (d->current_profile == 0x1a || d->current_profile == 0x13 ||
d->current_profile == 0x12) {
/* overwriteable */
*lba = *nwa = num = 0;
} else if (!(data[7]&1)) {
/* ts A61106 : MMC-1 Table 142 : NWA_V = NWA Valid Flag */
libdax_msgs_submit(libdax_messenger, -1, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
"mmc_get_nwa: Track Info Block: NWA_V == 0", 0, 0);
return 0;
}
if (num > 0) {
d->media_capacity_remaining = ((off_t) num) * ((off_t) 2048);
d->media_lba_limit = *nwa + num;
} else
d->media_lba_limit = 0;
/*
fprintf(stderr, "LIBBURN_DEBUG: media_lba_limit= %d\n",
d->media_lba_limit);
*/
return 1;
}
/* ts A61009 : function is obviously unused. */
/* void mmc_close_disc(struct burn_drive *d, struct burn_write_opts *o) */
void mmc_close_disc(struct burn_write_opts *o)
{
struct burn_drive *d;
mmc_function_spy("mmc_close_disc");
libdax_msgs_submit(libdax_messenger, -1, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
"HOW THAT ? mmc_close_disc() was called", 0, 0);
/* ts A61009 : made impossible by removing redundant parameter d */
/* a ssert(o->drive == d); */
d = o->drive;
o->multi = 0;
spc_select_write_params(d, o);
mmc_close(d, 1, 0);
}
/* ts A61009 : function is obviously unused. */
/* void mmc_close_session(struct burn_drive *d, struct burn_write_opts *o) */
void mmc_close_session(struct burn_write_opts *o)
{
struct burn_drive *d;
mmc_function_spy("mmc_close_session");
libdax_msgs_submit(libdax_messenger, -1, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
"HOW THAT ? mmc_close_session() was called", 0, 0);
/* ts A61009 : made impossible by removing redundant parameter d */
/* a ssert(o->drive == d); */
d = o->drive;
o->multi = 3;
spc_select_write_params(d, o);
mmc_close(d, 1, 0);
}
void mmc_close(struct burn_drive *d, int session, int track)
{
struct command c;
mmc_function_spy("mmc_close");
c.retry = 1;
c.oplen = sizeof(MMC_CLOSE);
memcpy(c.opcode, MMC_CLOSE, sizeof(MMC_CLOSE));
/* ts A61030 : shifted !!session rather than or-ing plain session */
c.opcode[2] = ((!!session)<<1) | !!track;
c.opcode[4] = track >> 8;
c.opcode[5] = track & 0xFF;
c.page = NULL;
c.dir = NO_TRANSFER;
d->issue_command(d, &c);
}
void mmc_get_event(struct burn_drive *d)
{
struct buffer buf;
struct command c;
mmc_function_spy("mmc_get_event");
c.retry = 1;
c.oplen = sizeof(MMC_GET_EVENT);
memcpy(c.opcode, MMC_GET_EVENT, sizeof(MMC_GET_EVENT));
c.page = &buf;
c.page->bytes = 0;
c.page->sectors = 0;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
burn_print(12, "0x%x:0x%x:0x%x:0x%x\n",
c.page->data[0], c.page->data[1], c.page->data[2],
c.page->data[3]);
burn_print(12, "event: %d:%d:%d:%d\n", c.page->data[4],
c.page->data[5], c.page->data[6], c.page->data[7]);
}
void mmc_write_12(struct burn_drive *d, int start, struct buffer *buf)
{
struct command c;
int len;
mmc_function_spy("mmc_write_12");
len = buf->sectors;
/* ts A61009 */
/* a ssert(buf->bytes >= buf->sectors);*/ /* can be == at 0... */
burn_print(100, "trying to write %d at %d\n", len, start);
memcpy(c.opcode, MMC_WRITE_12, sizeof(MMC_WRITE_12));
c.retry = 1;
c.oplen = sizeof(MMC_WRITE_12);
c.opcode[2] = start >> 24;
c.opcode[3] = (start >> 16) & 0xFF;
c.opcode[4] = (start >> 8) & 0xFF;
c.opcode[5] = start & 0xFF;
c.opcode[6] = len >> 24;
c.opcode[7] = (len >> 16) & 0xFF;
c.opcode[8] = (len >> 8) & 0xFF;
c.opcode[9] = len & 0xFF;
c.page = buf;
c.dir = TO_DRIVE;
d->issue_command(d, &c);
}
int mmc_write(struct burn_drive *d, int start, struct buffer *buf)
{
int cancelled;
struct command c;
int len;
#ifdef Libburn_log_in_and_out_streaM
/* <<< ts A61031 */
static int tee_fd= -1;
if(tee_fd==-1)
tee_fd= open("/tmp/libburn_sg_written",
O_WRONLY|O_CREAT|O_TRUNC,S_IRUSR|S_IWUSR);
#endif /* Libburn_log_in_and_out_streaM */
mmc_function_spy("mmc_write");
pthread_mutex_lock(&d->access_lock);
cancelled = d->cancel;
pthread_mutex_unlock(&d->access_lock);
if (cancelled)
return BE_CANCELLED;
/* ts A70215 */
if (d->media_lba_limit > 0 && start >= d->media_lba_limit) {
char msg[160];
sprintf(msg,
"Exceeding range of permissible write addresses (%d >= %d)",
start, d->media_lba_limit);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x0002012d,
LIBDAX_MSGS_SEV_FATAL, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
d->cancel = 1; /* No need for mutexing because atomic */
return BE_CANCELLED;
}
len = buf->sectors;
/* ts A61009 : buffer fill problems are to be handled by caller */
/* a ssert(buf->bytes >= buf->sectors);*/ /* can be == at 0... */
burn_print(100, "trying to write %d at %d\n", len, start);
memcpy(c.opcode, MMC_WRITE_10, sizeof(MMC_WRITE_10));
c.retry = 1;
c.oplen = sizeof(MMC_WRITE_10);
c.opcode[2] = start >> 24;
c.opcode[3] = (start >> 16) & 0xFF;
c.opcode[4] = (start >> 8) & 0xFF;
c.opcode[5] = start & 0xFF;
c.opcode[6] = 0;
c.opcode[7] = (len >> 8) & 0xFF;
c.opcode[8] = len & 0xFF;
c.page = buf;
c.dir = TO_DRIVE;
/*
burn_print(12, "%d, %d, %d, %d - ", c->opcode[2], c->opcode[3], c->opcode[4], c->opcode[5]);
burn_print(12, "%d, %d, %d, %d\n", c->opcode[6], c->opcode[7], c->opcode[8], c->opcode[9]);
*/
#ifdef Libburn_log_in_and_out_streaM
/* <<< ts A61031 */
if(tee_fd!=-1) {
write(tee_fd,c.page->data,len*2048);
}
#endif /* Libburn_log_in_and_out_streaM */
d->issue_command(d, &c);
/* ts A61112 : react on eventual error condition */
if (c.error && c.sense[2]!=0) {
/* >>> make this scsi_notify_error() when liberated */
if (c.sense[2]!=0) {
char msg[160];
sprintf(msg,
"SCSI error on write(%d,%d): key=%X asc=%2.2Xh ascq=%2.2Xh",
start, len,
c.sense[2],c.sense[12],c.sense[13]);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x0002011d,
LIBDAX_MSGS_SEV_FATAL, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
}
pthread_mutex_lock(&d->access_lock);
d->cancel = 1;
pthread_mutex_unlock(&d->access_lock);
return BE_CANCELLED;
}
return 0;
}
/* ts A70201 : Set up an entry for mmc_fake_toc() */
int mmc_fake_toc_entry(struct burn_toc_entry *entry, int session_number,
int track_number,
unsigned char *size_data, unsigned char *start_data)
{
int min, sec, frames, num;
/* mark DVD extensions as valid */
entry->extensions_valid |= 1;
/* defaults are as of mmc5r03.pdf 6.26.3.2.4 Fabricated TOC */
entry->session = session_number & 0xff;
entry->session_msb = (session_number >> 8) & 0xff;
entry->adr = 1;
entry->control = 4;
entry->tno = 0;
entry->point = track_number & 0xff;
entry->point_msb = (track_number >> 8) & 0xff;
num = mmc_four_char_to_int(size_data);
entry->track_blocks = num;
burn_lba_to_msf(num, &min, &sec, &frames);
if (min > 255) {
min = 255;
sec = 255;
frames = 255;
}
entry->min = min;
entry->sec = sec;
entry->frame = frames;
entry->zero = 0;
num = mmc_four_char_to_int(start_data);
entry->start_lba = num;
burn_lba_to_msf(num, &min, &sec, &frames);
if (min > 255) {
min = 255;
sec = 255;
frames = 255;
}
entry->pmin = min;
entry->psec = sec;
entry->pframe = frames;
return 1;
}
/* ts A70131 : compose a disc TOC structure from d->complete_sessions
and 52h READ TRACK INFORMATION */
int mmc_fake_toc(struct burn_drive *d)
{
struct burn_track *track;
struct burn_session *session;
struct burn_toc_entry *entry;
struct buffer buf;
int i, session_number, prev_session = -1, ret, lba;
unsigned char *tdata, size_data[4], start_data[4];
char msg[160];
if (d->last_track_no <= 0 || d->complete_sessions <= 0 ||
d->status == BURN_DISC_BLANK)
return 2;
if (d->last_track_no > BURN_MMC_FAKE_TOC_MAX_SIZE) {
sprintf(msg,
"Too many logical tracks recorded (%d , max. %d)\n",
d->last_track_no, BURN_MMC_FAKE_TOC_MAX_SIZE);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x0002012c,
LIBDAX_MSGS_SEV_SORRY, LIBDAX_MSGS_PRIO_HIGH,
msg, 0,0);
return 0;
}
d->disc = burn_disc_create();
if (d->disc == NULL)
return -1;
d->toc_entries = d->last_track_no + d->complete_sessions;
d->toc_entry = malloc(d->toc_entries * sizeof(struct burn_toc_entry));
if (d->toc_entry == NULL)
return -1;
memset(d->toc_entry, 0,d->toc_entries * sizeof(struct burn_toc_entry));
for (i = 0; i < d->complete_sessions; i++) {
session = burn_session_create();
burn_disc_add_session(d->disc, session, BURN_POS_END);
burn_session_free(session);
}
memset(size_data, 0, 4);
memset(start_data, 0, 4);
/* Entry Layout :
session 1 track 1 entry 0
...
session 1 track N entry N-1
leadout 1 entry N
session 2 track N+1 entry N+1
...
session 2 track M+1 entry M+1
leadout 2 entry M+2
session X track K entry (K-1)+(X-1)
...
session X track i+1 entry i+(X-1)
leadout X entry i+X
*/
for (i = 0; i < d->last_track_no; i++) {
ret = mmc_read_track_info(d, i+1, &buf);
if (ret <= 0)
return ret;
tdata = buf.data;
session_number = (tdata[33] << 8) | tdata[3];
if (session_number <= 0)
continue;
if (session_number != prev_session && prev_session > 0) {
/* leadout entry previous session */
entry = &(d->toc_entry[(i - 1) + prev_session]);
lba = mmc_four_char_to_int(start_data) +
mmc_four_char_to_int(size_data);
mmc_int_to_four_char(start_data, lba);
mmc_int_to_four_char(size_data, 0);
mmc_fake_toc_entry(entry, prev_session, 0xA2,
size_data, start_data);
entry->min= entry->sec= entry->frame= 0;
d->disc->session[prev_session - 1]->leadout_entry =
entry;
}
if (session_number > d->disc->sessions) {
if (i == d->last_track_no - 1) {
/* ts A70212 : Last track field Free Blocks */
d->media_capacity_remaining =
((off_t) mmc_four_char_to_int(tdata + 16)) *
((off_t) 2048);
d->media_lba_limit = 0;
}
continue;
}
entry = &(d->toc_entry[i + session_number - 1]);
track = burn_track_create();
if (track == NULL)
return -1;
burn_session_add_track(
d->disc->session[session_number - 1],
track, BURN_POS_END);
track->entry = entry;
burn_track_free(track);
memcpy(size_data, tdata + 24, 4);
memcpy(start_data, tdata + 8, 4);
mmc_fake_toc_entry(entry, session_number, i + 1,
size_data, start_data);
if (prev_session != session_number)
d->disc->session[session_number - 1]->firsttrack = i+1;
d->disc->session[session_number - 1]->lasttrack = i+1;
prev_session = session_number;
}
if (prev_session > 0 && prev_session <= d->disc->sessions) {
/* leadout entry of last session of closed disc */
entry = &(d->toc_entry[(d->last_track_no - 1) + prev_session]);
lba = mmc_four_char_to_int(start_data) +
mmc_four_char_to_int(size_data);
mmc_int_to_four_char(start_data, lba);
mmc_int_to_four_char(size_data, 0);
mmc_fake_toc_entry(entry, prev_session, 0xA2,
size_data, start_data);
entry->min= entry->sec= entry->frame= 0;
d->disc->session[prev_session - 1]->leadout_entry = entry;
}
return 1;
}
void mmc_read_toc(struct burn_drive *d)
{
/* read full toc, all sessions, in m/s/f form, 4k buffer */
/* ts A70201 : or fake a toc from track information */
struct burn_track *track;
struct burn_session *session;
struct buffer buf;
struct command c;
int dlen;
int i, bpl= 12;
unsigned char *tdata;
mmc_function_spy("mmc_read_toc");
if (!(d->current_profile == -1 || d->current_is_cd_profile)) {
/* ts A70131 : MMC_GET_TOC uses Response Format 2
For DVD this fails with 5,24,00 */
/* One could try Response Format 0: mmc5r03.pdf 6.26.3.2
which does not yield the same result wit the same disc
on different drives.
*/
/* ts A70201 :
This uses the session count from 51h READ DISC INFORMATION
and the track records from 52h READ TRACK INFORMATION
*/
mmc_fake_toc(d);
if (d->status == BURN_DISC_UNREADY)
d->status = BURN_DISC_FULL;
return;
}
memcpy(c.opcode, MMC_GET_TOC, sizeof(MMC_GET_TOC));
c.retry = 1;
c.oplen = sizeof(MMC_GET_TOC);
c.page = &buf;
c.page->bytes = 0;
c.page->sectors = 0;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
if (c.error) {
/* ts A61020 : this snaps on non-blank DVD media */
/* ts A61106 : also snaps on CD with unclosed track/session */
/* Very unsure wether this old measure is ok.
Obviously higher levels do not care about this.
outdated info: DVD+RW burns go on after passing through here.
d->busy = BURN_DRIVE_IDLE;
*/
libdax_msgs_submit(libdax_messenger, d->global_index,
0x0002010d,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
"Could not inquire TOC", 0,0);
d->status = BURN_DISC_UNSUITABLE;
d->toc_entries = 0;
/* Prefering memory leaks over fandangos */
d->toc_entry = malloc(sizeof(struct burn_toc_entry));
memset(&(d->toc_entry[0]), 0, sizeof(struct burn_toc_entry));
return;
}
dlen = c.page->data[0] * 256 + c.page->data[1];
d->toc_entries = (dlen - 2) / 11;
/*
some drives fail this check.
ts A61007 : if re-enabled then not via Assert.
a ssert(((dlen - 2) % 11) == 0);
*/
d->toc_entry = malloc(d->toc_entries * sizeof(struct burn_toc_entry));
for (i = 0; i < d->toc_entries; i++)
memset(&(d->toc_entry[i]), 0, sizeof(struct burn_toc_entry));
tdata = c.page->data + 4;
burn_print(12, "TOC:\n");
d->disc = burn_disc_create();
for (i = 0; i < c.page->data[3]; i++) {
session = burn_session_create();
burn_disc_add_session(d->disc, session, BURN_POS_END);
burn_session_free(session);
}
/* ts A61022 */
burn_print(bpl, "-----------------------------------\n");
for (i = 0; i < d->toc_entries; i++, tdata += 11) {
/* ts A61022: was burn_print level 12 */
burn_print(bpl, "S %d, PT %2.2Xh, TNO %d :", tdata[0],tdata[3],
tdata[2]);
burn_print(bpl, " MSF(%d:%d:%d)", tdata[4],tdata[5],tdata[6]);
burn_print(bpl, " PMSF(%d:%d:%d %d)",
tdata[8], tdata[9], tdata[10],
burn_msf_to_lba(tdata[8], tdata[9], tdata[10]));
burn_print(bpl, " - control %d, adr %d\n", tdata[1] & 0xF,
tdata[1] >> 4);
/*
fprintf(stderr, "libburn_experimental: toc entry #%d : %d %d %d\n",i,tdata[8], tdata[9], tdata[10]);
*/
if (tdata[3] == 1) {
if (burn_msf_to_lba(tdata[8], tdata[9], tdata[10])) {
d->disc->session[0]->hidefirst = 1;
track = burn_track_create();
burn_session_add_track(d->disc->
session[tdata[0] - 1],
track, BURN_POS_END);
burn_track_free(track);
}
}
if (tdata[0] <= 0 || tdata[0] > d->disc->sessions)
tdata[0] = d->disc->sessions;
if (tdata[3] < 100 && tdata[0] > 0) {
track = burn_track_create();
burn_session_add_track(d->disc->session[tdata[0] - 1],
track, BURN_POS_END);
track->entry = &d->toc_entry[i];
burn_track_free(track);
}
d->toc_entry[i].session = tdata[0];
d->toc_entry[i].adr = tdata[1] >> 4;
d->toc_entry[i].control = tdata[1] & 0xF;
d->toc_entry[i].tno = tdata[2];
d->toc_entry[i].point = tdata[3];
d->toc_entry[i].min = tdata[4];
d->toc_entry[i].sec = tdata[5];
d->toc_entry[i].frame = tdata[6];
d->toc_entry[i].zero = tdata[7];
d->toc_entry[i].pmin = tdata[8];
d->toc_entry[i].psec = tdata[9];
d->toc_entry[i].pframe = tdata[10];
if (tdata[3] == 0xA0)
d->disc->session[tdata[0] - 1]->firsttrack = tdata[8];
if (tdata[3] == 0xA1)
d->disc->session[tdata[0] - 1]->lasttrack = tdata[8];
if (tdata[3] == 0xA2)
d->disc->session[tdata[0] - 1]->leadout_entry =
&d->toc_entry[i];
}
/* ts A61022 */
burn_print(bpl, "-----------------------------------\n");
/* ts A70131 : was (d->status != BURN_DISC_BLANK) */
if (d->status == BURN_DISC_UNREADY)
d->status = BURN_DISC_FULL;
toc_find_modes(d);
}
/* ts A70131 : This tries to get the start of the last complete session */
/* man mkisofs , option -C :
The first number is the sector number of the first sector in
the last session of the disk that should be appended to.
*/
int mmc_read_multi_session_c1(struct burn_drive *d, int *trackno, int *start)
{
struct buffer buf;
struct command c;
unsigned char *tdata;
int num_sessions, session_no, num_tracks;
struct burn_disc *disc;
struct burn_session **sessions;
struct burn_track **tracks;
struct burn_toc_entry toc_entry;
mmc_function_spy("mmc_read_multi_session_c1");
/* First try to evaluate the eventually loaded TOC before issueing
a MMC command. This search obtains the first track of the last
complete session which has a track.
*/
*trackno = 0;
disc = burn_drive_get_disc(d);
if (disc == NULL)
goto inquire_drive;
sessions = burn_disc_get_sessions(disc, &num_sessions);
for (session_no = 0; session_no<num_sessions; session_no++) {
tracks = burn_session_get_tracks(sessions[session_no],
&num_tracks);
if (tracks == NULL || num_tracks <= 0)
continue;
burn_track_get_entry(tracks[0], &toc_entry);
if (toc_entry.extensions_valid & 1) { /* DVD extension valid */
*start = toc_entry.start_lba;
*trackno = (toc_entry.point_msb << 8)| toc_entry.point;
} else {
*start = burn_msf_to_lba(toc_entry.pmin,
toc_entry.psec, toc_entry.pframe);
*trackno = toc_entry.point;
}
}
burn_disc_free(disc);
if(*trackno > 0)
return 1;
inquire_drive:;
/* mmc5r03.pdf 6.26.3.3.3 states that with non-CD this would
be a useless fake always starting at track 1, lba 0.
My drives return useful data, though.
MMC-3 states that DVD had no tracks. So maybe this mandatory fake
is a forgotten legacy ?
*/
memcpy(c.opcode, MMC_GET_MSINFO, sizeof(MMC_GET_MSINFO));
c.retry = 1;
c.oplen = sizeof(MMC_GET_MSINFO);
c.page = &buf;
c.page->bytes = 0;
c.page->sectors = 0;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
if (c.error)
return 0;
tdata = c.page->data + 4;
*trackno = tdata[2];
*start = mmc_four_char_to_int(tdata + 4);
return 1;
}
void mmc_read_disc_info(struct burn_drive *d)
{
struct buffer buf;
unsigned char *data;
struct command c;
char msg[160];
/* ts A70131 : had to move mmc_read_toc() to end of function */
int do_read_toc = 0, session_state, disc_status;
/* ts A61020 */
d->start_lba = d->end_lba = -2000000000;
d->erasable = 0;
d->last_track_no = 1;
/* ts A70212 - A70215 */
d->media_capacity_remaining = 0;
d->media_lba_limit = 0;
/* ts A61202 */
d->toc_entries = 0;
if (d->status == BURN_DISC_EMPTY)
return;
mmc_get_configuration(d);
mmc_function_spy("mmc_read_disc_info");
memcpy(c.opcode, MMC_GET_DISC_INFO, sizeof(MMC_GET_DISC_INFO));
c.retry = 1;
c.oplen = sizeof(MMC_GET_DISC_INFO);
c.page = &buf;
c.page->sectors = 0;
c.page->bytes = 0;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
if (c.error) {
d->busy = BURN_DRIVE_IDLE;
return;
}
data = c.page->data;
d->erasable = !!(data[2] & 16);
disc_status = data[2] & 3;
if (d->current_profile == 0x10) { /* DVD-ROM */
disc_status = 2; /* always full and finalized */
d->erasable = 0; /* never erasable */
}
switch (disc_status) {
case 0:
d->toc_entries = 0;
d->start_lba = burn_msf_to_lba(data[17], data[18], data[19]);
d->end_lba = burn_msf_to_lba(data[21], data[22], data[23]);
/*
fprintf(stderr, "libburn_experimental: start_lba = %d (%d %d %d) , end_lba = %d (%d %d %d)\n",
d->start_lba, data[17], data[18], data[19],
d->end_lba, data[21], data[22], data[23]);
*/
d->status = BURN_DISC_BLANK;
break;
case 1:
d->status = BURN_DISC_APPENDABLE;
case 2:
if (disc_status == 2)
d->status = BURN_DISC_FULL;
do_read_toc = 1;
break;
}
if ((d->current_profile != 0 || d->status != BURN_DISC_UNREADY)
&& ! d->current_is_supported_profile) {
if (!d->silent_on_scsi_error) {
sprintf(msg,
"Unsuitable media detected. Profile %4.4Xh %s",
d->current_profile, d->current_profile_text);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x0002011e,
LIBDAX_MSGS_SEV_SORRY, LIBDAX_MSGS_PRIO_HIGH,
msg, 0,0);
}
d->status = BURN_DISC_UNSUITABLE;
return;
}
/* >>> ts A61217 : Note for future
growisofs performs OPC if (data[0]<<8)|data[1]<=32
which indicates no OPC entries are attached to the
reply from the drive.
*/
/* ts A61219 : mmc5r03c.pdf 6.22.3.1.13 BG Format Status
0=blank (not yet started)
1=started but neither running nor complete
2=in progress
3=completed
*/
d->bg_format_status = data[7] & 3;
/* Preliminarily declare blank:
ts A61219 : DVD+RW (is not bg_format_status==0 "blank")
ts A61229 : same for DVD-RW Restricted overwrite
ts A70112 : same for DVD-RAM
*/
if (d->current_profile == 0x1a || d->current_profile == 0x13 ||
d->current_profile == 0x12)
d->status = BURN_DISC_BLANK;
if (d->status == BURN_DISC_BLANK) {
d->last_track_no = 1; /* The "incomplete track" */
d->complete_sessions = 0;
} else {
/* ts A70131 : number of non-empty sessions */
d->complete_sessions = (data[9] << 8) | data[4];
session_state = (data[2] >> 2) & 3;
/* mmc5r03c.pdf 6.22.3.1.3 State of Last Session: 3=complete */
if (session_state != 3 && d->complete_sessions >= 1)
d->complete_sessions--;
/* ts A70129 : mmc5r03c.pdf 6.22.3.1.7
This includes the "incomplete track" if the disk is
appendable. I.e number of complete tracks + 1. */
d->last_track_no = (data[11] << 8) | data[6];
}
if (do_read_toc)
mmc_read_toc(d);
}
void mmc_read_atip(struct burn_drive *d)
{
struct buffer buf;
struct command c;
/* ts A61021 */
unsigned char *data;
/* Speed values from A1:
With 4 cdrecord tells "10" or "8" where MMC-1 says "8".
cdrecord "8" appear on 4xCD-RW and thus seem to be quite invalid.
My CD-R (>=24 speed) tell no A1.
The higher non-MMC-1 values are hearsay.
*/
/* 0, 2, 4, 6, 10, -, 16, -, */
static int speed_value[16]= { 0, 353, 706, 1059, 1764, -5, 2824, -7,
4234, 5646, 7056, 8468, -12, -13, -14, -15};
/* 24, 32, 40, 48, -, -, -, - */
mmc_function_spy("mmc_read_atip");
memcpy(c.opcode, MMC_GET_ATIP, sizeof(MMC_GET_ATIP));
c.retry = 1;
c.oplen = sizeof(MMC_GET_ATIP);
c.page = &buf;
c.page->bytes = 0;
c.page->sectors = 0;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
burn_print(1, "atip shit for you\n");
/* ts A61021 */
data = c.page->data;
d->erasable= !!(data[6]&64);
d->start_lba= burn_msf_to_lba(data[8],data[9],data[10]);
d->end_lba= burn_msf_to_lba(data[12],data[13],data[14]);
if (data[6]&4) {
if (speed_value[(data[16]>>4)&7] > 0) {
d->mdata->min_write_speed =
speed_value[(data[16]>>4)&7];
if (speed_value[(data[16])&15] <= 0)
d->mdata->max_write_speed =
speed_value[(data[16]>>4)&7];
}
if (speed_value[(data[16])&15] > 0) {
d->mdata->max_write_speed =
speed_value[(data[16])&15];
if (speed_value[(data[16]>>4)&7] <= 0)
d->mdata->min_write_speed =
speed_value[(data[16])&15];
}
}
#ifdef Burn_mmc_be_verbous_about_atiP
{ int i;
fprintf(stderr,"libburn_experimental: Returned ATIP Data\n");
for(i= 0; i<28; i++)
fprintf(stderr,"%3.3d (0x%2.2x)%s",
data[i],data[i],((i+1)%5 ? " ":"\n"));
fprintf(stderr,"\n");
fprintf(stderr,
"libburn_experimental: Indicative Target Writing Power= %d\n",
(data[4]>>4)&7);
fprintf(stderr,
"libburn_experimental: Reference speed= %d ->%d\n",
data[4]&7, speed_value[data[4]&7]);
fprintf(stderr,
"libburn_experimental: Is %sunrestricted\n",
(data[5]&64?"":"not "));
fprintf(stderr,
"libburn_experimental: Is %serasable, sub-type %d\n",
(data[6]&64?"":"not "),(data[6]>>3)&3);
fprintf(stderr,
"libburn_experimental: lead in: %d (%-2.2d:%-2.2d/%-2.2d)\n",
burn_msf_to_lba(data[8],data[9],data[10]),
data[8],data[9],data[10]);
fprintf(stderr,
"libburn_experimental: lead out: %d (%-2.2d:%-2.2d/%-2.2d)\n",
burn_msf_to_lba(data[12],data[13],data[14]),
data[12],data[13],data[14]);
if(data[6]&4)
fprintf(stderr,
"libburn_experimental: A1 speed low %d speed high %d\n",
speed_value[(data[16]>>4)&7], speed_value[(data[16])&7]);
if(data[6]&2)
fprintf(stderr,
"libburn_experimental: A2 speed low %d speed high %d\n",
speed_value[(data[20]>>4)&7], speed_value[(data[20])&7]);
if(data[6]&1)
fprintf(stderr,
"libburn_experimental: A3 speed low %d speed high %d\n",
speed_value[(data[24]>>4)&7], speed_value[(data[24])&7]);
}
#endif /* Burn_mmc_be_verbous_about_atiP */
/* ts A61020
http://www.t10.org/ftp/t10/drafts/mmc/mmc-r10a.pdf , table 77 :
0 ATIP Data Length MSB
1 ATIP Data Length LSB
2 Reserved
3 Reserved
4 bit7=1, bit4-6="Indicative Target Writing Power", bit3=reserved ,
bit0-2="Reference speed"
5 bit7=0, bit6="URU" , bit0-5=reserved
6 bit7=1, bit6="Disc Type", bit3-4="Disc Sub-Type",
bit2="A1", bit1="A2", bit0="A3"
7 reserved
8 ATIP Start Time of lead-in (Min)
9 ATIP Start Time of lead-in (Sec)
10 ATIP Start Time of lead-in (Frame)
11 reserved
12 ATIP Last Possible Start Time of lead-out (Min)
13 ATIP Last Possible Start Time of lead-out (Sec)
14 ATIP Last Possible Start Time of lead-out (Frame)
15 reserved
16 bit7=0, bit4-6="Lowest Usable CLV Recording speed"
bit0-3="Highest Usable CLV Recording speed"
17 bit7=0, bit4-6="Power Multiplication Factor p",
bit1-3="Target y value of the Modulation/Power function", bit0=reserved
18 bit7=1, bit4-6="Recommended Erase/Write Power Ratio (P(inf)/W(inf))"
bit0-3=reserved
19 reserved
20-22 A2 Values
23 reserved
24-26 A3 Values
27 reserved
Disc Type - zero indicates CD-R media; one indicates CD-RW media.
Disc Sub-Type - shall be set to zero.
A1 - when set to one, indicates that bytes 16-18 are valid.
Lowest Usable CLV Recording Speed
000b Reserved
001b 2X
010b - 111b Reserved
Highest CLV Recording Speeds
000b Reserved
001b 2X
010b 4X
011b 6X
100b 8X
101b - 111b Reserved
MMC-3 seems to recommend MODE SENSE (5Ah) page 2Ah rather than A1, A2, A3.
This page is loaded in libburn function spc_sense_caps() .
Speed is given in kbytes/sec there. But i suspect this to be independent
of media. So one would habe to associate the speed descriptor blocks with
the ATIP media characteristics ? How ?
*/
}
void mmc_read_sectors(struct burn_drive *d,
int start,
int len,
const struct burn_read_opts *o, struct buffer *buf)
{
int temp;
int errorblock, req;
struct command c;
mmc_function_spy("mmc_read_sectors");
/* ts A61009 : to be ensured by callers */
/* a ssert(len >= 0); */
/* if the drive isn't busy, why the hell are we here? */
/* ts A61006 : i second that question */
/* a ssert(d->busy); */
burn_print(12, "reading %d from %d\n", len, start);
memcpy(c.opcode, MMC_READ_CD, sizeof(MMC_READ_CD));
c.retry = 1;
c.oplen = sizeof(MMC_READ_CD);
temp = start;
c.opcode[5] = temp & 0xFF;
temp >>= 8;
c.opcode[4] = temp & 0xFF;
temp >>= 8;
c.opcode[3] = temp & 0xFF;
temp >>= 8;
c.opcode[2] = temp & 0xFF;
c.opcode[8] = len & 0xFF;
len >>= 8;
c.opcode[7] = len & 0xFF;
len >>= 8;
c.opcode[6] = len & 0xFF;
req = 0xF8;
/* ts A61106 : LG GSA-4082B dislikes this. key=5h asc=24h ascq=00h
if (d->busy == BURN_DRIVE_GRABBING || o->report_recovered_errors)
req |= 2;
*/
c.opcode[10] = 0;
/* always read the subcode, throw it away later, since we don't know
what we're really reading
*/
if (d->busy == BURN_DRIVE_GRABBING || (o->subcodes_audio)
|| (o->subcodes_data))
c.opcode[10] = 1;
c.opcode[9] = req;
c.page = buf;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
if (c.error) {
burn_print(12, "got an error over here\n");
burn_print(12, "%d, %d, %d, %d\n", c.sense[3], c.sense[4],
c.sense[5], c.sense[6]);
errorblock =
(c.sense[3] << 24) + (c.sense[4] << 16) +
(c.sense[5] << 8) + c.sense[6];
c.page->sectors = errorblock - start + 1;
burn_print(1, "error on block %d\n", errorblock);
burn_print(12, "error on block %d\n", errorblock);
burn_print(12, "returning %d sectors\n", c.page->sectors);
}
}
void mmc_erase(struct burn_drive *d, int fast)
{
struct command c;
mmc_function_spy("mmc_erase");
memcpy(c.opcode, MMC_BLANK, sizeof(MMC_BLANK));
c.opcode[1] = 16; /* IMMED set to 1 */
c.opcode[1] |= !!fast;
c.retry = 1;
c.oplen = sizeof(MMC_BLANK);
c.page = NULL;
c.dir = NO_TRANSFER;
d->issue_command(d, &c);
}
void mmc_read_lead_in(struct burn_drive *d, struct buffer *buf)
{
int len;
struct command c;
mmc_function_spy("mmc_read_lead_in");
len = buf->sectors;
memcpy(c.opcode, MMC_READ_CD, sizeof(MMC_READ_CD));
c.retry = 1;
c.oplen = sizeof(MMC_READ_CD);
c.opcode[5] = 0;
c.opcode[4] = 0;
c.opcode[3] = 0;
c.opcode[2] = 0xF0;
c.opcode[8] = 1;
c.opcode[7] = 0;
c.opcode[6] = 0;
c.opcode[9] = 0;
c.opcode[10] = 2;
c.page = buf;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
}
void mmc_perform_opc(struct burn_drive *d)
{
struct command c;
mmc_function_spy("mmc_perform_opc");
memcpy(c.opcode, MMC_SEND_OPC, sizeof(MMC_SEND_OPC));
c.retry = 1;
c.oplen = sizeof(MMC_SEND_OPC);
c.opcode[1] = 1;
c.page = NULL;
c.dir = NO_TRANSFER;
d->issue_command(d, &c);
}
/* ts A61221 : Learned much from dvd+rw-tools-7.0 set_speed_B6h() but then
made own experiments on base of mmc5r03c.pdf 6.8.3 and 6.39 in the hope
to achieve a leaner solution */
int mmc_set_streaming(struct burn_drive *d, int r_speed, int w_speed)
{
struct buffer buf;
struct command c;
int b, end_lba;
char msg[160];
unsigned char *pd;
mmc_function_spy("mmc_set_streaming");
if (r_speed <= 0)
r_speed = 0x10000000; /* ~ 2 TB/s */
if (w_speed <= 0)
w_speed = 0x10000000; /* ~ 2 TB/s */
c.retry = 1;
c.oplen = sizeof(MMC_SET_STREAMING);
memcpy(c.opcode, MMC_SET_STREAMING, sizeof(MMC_SET_STREAMING));
c.page = &buf;
c.page->bytes = 28;
c.opcode[9] = (c.page->bytes >> 8) & 0xff;
c.opcode[10] = c.page->bytes & 0xff;
c.page->sectors = 0;
c.dir = TO_DRIVE;
memset(c.page->data, 0, c.page->bytes);
pd = c.page->data;
/* Trying to avoid inquiry of available speed descriptors but rather
to allow the drive to use the liberties of Exact==0.
*/
pd[0] = 0; /* WRC=0 (Default Rotation Control), RDD=Exact=RA=0 */
/* Default computed from 4.7e9 */
end_lba = 2294921 - 1;
if (d->mdata->max_end_lba > 0)
end_lba = d->mdata->max_end_lba - 1;
sprintf(msg, "mmc_set_streaming: end_lba=%d , r=%d , w=%d",
end_lba, r_speed, w_speed);
libdax_msgs_submit(libdax_messenger, d->global_index, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
msg, 0, 0);
/* start_lba is 0 , 1000 = 1 second as base time for data rate */
for (b = 0; b < 4 ; b++) {
pd[8+b] = (end_lba >> (24 - 8 * b)) & 0xff;
pd[12+b] = (r_speed >> (24 - 8 * b)) & 0xff;
pd[16+b] = (1000 >> (24 - 8 * b)) & 0xff;
pd[20+b] = (w_speed >> (24 - 8 * b)) & 0xff;
pd[24+b] = (1000 >> (24 - 8 * b)) & 0xff;
}
/* <<<
fprintf(stderr,"LIBBURN_EXPERIMENTAL : B6h Performance descriptor:\n");
for (b = 0; b < 28 ; b++)
fprintf(stderr, "%2.2X%c", pd[b], ((b+1)%4 ? ' ' : '\n'));
*/
d->issue_command(d, &c);
if (c.error) {
if (c.sense[2]!=0 && !d->silent_on_scsi_error) {
sprintf(msg,
"SCSI error on set_streaming(%d): key=%X asc=%2.2Xh ascq=%2.2Xh",
w_speed,
c.sense[2],c.sense[12],c.sense[13]);
libdax_msgs_submit(libdax_messenger,
d->global_index,
0x00020124,
LIBDAX_MSGS_SEV_SORRY, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
}
return 0;
}
return 1;
}
void mmc_set_speed(struct burn_drive *d, int r, int w)
{
struct command c;
int ret;
mmc_function_spy("mmc_set_speed");
/* ts A61221 : try to set DVD speed via command B6h */
if (strstr(d->current_profile_text, "DVD") == d->current_profile_text){
ret = mmc_set_streaming(d, r, w);
if (ret != 0)
return; /* success or really fatal failure */
}
/* ts A61112 : MMC standards prescribe FFFFh as max speed.
But libburn.h prescribes 0. */
if (r<=0 || r>0xffff)
r = 0xffff;
if (w<=0 || w>0xffff)
w = 0xffff;
memcpy(c.opcode, MMC_SET_SPEED, sizeof(MMC_SET_SPEED));
c.retry = 1;
c.oplen = sizeof(MMC_SET_SPEED);
c.opcode[2] = r >> 8;
c.opcode[3] = r & 0xFF;
c.opcode[4] = w >> 8;
c.opcode[5] = w & 0xFF;
c.page = NULL;
c.dir = NO_TRANSFER;
d->issue_command(d, &c);
}
/* ts A61201 */
static char *mmc_obtain_profile_name(int profile_number)
{
static char *texts[0x53] = {NULL};
int i, max_pno = 0x53;
if (texts[0] == NULL) {
for (i = 0; i<max_pno; i++)
texts[i] = "";
/* mmc5r03c.pdf , Table 89, Spelling: guessed cdrecord style */
texts[0x01] = "Non-removable disk";
texts[0x02] = "Removable disk";
texts[0x03] = "MO erasable";
texts[0x04] = "Optical write once";
texts[0x05] = "AS-MO";
texts[0x08] = "CD-ROM";
texts[0x09] = "CD-R";
texts[0x0a] = "CD-RW";
texts[0x10] = "DVD-ROM";
texts[0x11] = "DVD-R sequential recording";
texts[0x12] = "DVD-RAM";
texts[0x13] = "DVD-RW restricted overwrite";
texts[0x14] = "DVD-RW sequential recording";
texts[0x15] = "DVD-R/DL sequential recording";
texts[0x16] = "DVD-R/DL layer jump recording";
texts[0x1a] = "DVD+RW";
texts[0x1b] = "DVD+R";
texts[0x2a] = "DVD+RW/DL";
texts[0x2b] = "DVD+R/DL";
texts[0x40] = "BD-ROM";
texts[0x41] = "BD-R sequential recording";
texts[0x42] = "BD-R random recording";
texts[0x43] = "BD-RE";
texts[0x50] = "HD-DVD-ROM";
texts[0x51] = "HD-DVD-R";
texts[0x52] = "HD-DVD-RAM";
}
if (profile_number<0 || profile_number>=max_pno)
return "";
return texts[profile_number];
}
/* ts A61201 : found in unfunctional state */
void mmc_get_configuration(struct burn_drive *d)
{
struct buffer buf;
int len, cp, descr_len = 0, feature_code, prf_number, only_current = 1;
unsigned char *descr, *prf, *up_to, *prf_end;
struct command c;
d->current_profile = 0;
d->current_profile_text[0] = 0;
d->current_is_cd_profile = 0;
d->current_is_supported_profile = 0;
d->current_has_feat21h = 0;
d->current_feat21h_link_size = -1;
d->current_feat2fh_byte4 = -1;
mmc_function_spy("mmc_get_configuration");
memcpy(c.opcode, MMC_GET_CONFIGURATION, sizeof(MMC_GET_CONFIGURATION));
c.retry = 1;
c.oplen = sizeof(MMC_GET_CONFIGURATION);
c.page = &buf;
c.page->sectors = 0;
c.page->bytes = 0;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
if (c.error)
return;
len = mmc_four_char_to_int(c.page->data);
if (len<8)
return;
cp = (c.page->data[6]<<8) | c.page->data[7];
d->current_profile = cp;
strcpy(d->current_profile_text, mmc_obtain_profile_name(cp));
if (cp == 0x08 || cp == 0x09 || cp == 0x0a)
d->current_is_supported_profile = d->current_is_cd_profile = 1;
#ifdef Libburn_support_dvd_plus_rW
if (cp == 0x1a)
d->current_is_supported_profile = 1;
#endif
#ifdef Libburn_support_dvd_minusrw_overW
if (cp == 0x13)
d->current_is_supported_profile = 1;
#endif
#ifdef Libburn_support_dvd_raM
if (cp == 0x12)
d->current_is_supported_profile = 1;
#endif
#ifdef Libburn_support_dvd_r_seQ
if (cp == 0x10 || cp == 0x11 || cp == 0x14) /* DVD-ROM,DVD-R,DVD-RW */
d->current_is_supported_profile = 1;
#endif
/* Enable this to get loud and repeated reports about the feature set :
#define Libburn_print_feature_descriptorS 1
*/
/* ts A70127 : Interpret list of profile and feature descriptors.
see mmc5r03c.pdf 5.2
>>> Ouch: What to do if list is larger than buffer size.
Specs state that the call has to be repeated.
*/
up_to = c.page->data + (len < BUFFER_SIZE ? len : BUFFER_SIZE);
#ifdef Libburn_print_feature_descriptorS
fprintf(stderr,
"-----------------------------------------------------------------\n");
fprintf(stderr,
"LIBBURN_EXPERIMENTAL : feature list length = %d , shown = %d\n",
len, up_to - c.page->data);
#endif /* Libburn_print_feature_descriptorS */
for (descr = c.page->data + 8; descr + 3 < up_to; descr += descr_len) {
descr_len = 4 + descr[3];
feature_code = (descr[0] << 8) | descr[1];
if (only_current && !(descr[2] & 1))
continue;
#ifdef Libburn_print_feature_descriptorS
fprintf(stderr,
"LIBBURN_EXPERIMENTAL : %s feature %4.4Xh\n",
descr[2] & 1 ? "+" : "-",
feature_code);
#endif /* Libburn_print_feature_descriptorS */
if (feature_code == 0x0) {
prf_end = descr + 4 + descr[3];
for (prf = descr + 4; prf + 2 < prf_end; prf += 4) {
if (only_current && !(prf[2] & 1))
continue;
prf_number = (prf[0] << 8) | prf[1];
#ifdef Libburn_print_feature_descriptorS
fprintf(stderr,
"LIBBURN_EXPERIMENTAL : %s profile %4.4Xh \"%s\"\n",
prf[2] & 1 ? "+" : "-",
prf_number,
mmc_obtain_profile_name(prf_number));
#endif /* Libburn_print_feature_descriptorS */
}
} else if (feature_code == 0x21) {
int i;
d->current_has_feat21h = (descr[2] & 1);
for (i = 0; i < descr[7]; i++) {
if (i == 0 || descr[8 + i] == 16)
d->current_feat21h_link_size =
descr[8 + i];
#ifdef Libburn_print_feature_descriptorS
fprintf(stderr,
"LIBBURN_EXPERIMENTAL : + Link Size = %d\n",
descr[8 + i]);
#endif /* Libburn_print_feature_descriptorS */
}
} else if (feature_code == 0x2F) {
if (descr[2] & 1)
d->current_feat2fh_byte4 = descr[4];
#ifdef Libburn_print_feature_descriptorS
fprintf(stderr, "LIBBURN_EXPERIMENTAL : BUF = %d , Test Write = %d , DVD-RW = %d\n",
!!(descr[4] & 64), !!(descr[4] & 4),
!!(descr[4] & 2));
#endif /* Libburn_print_feature_descriptorS */
#ifdef Libburn_print_feature_descriptorS
} else if (feature_code == 0x01) {
int pys_if_std = 0;
char *phys_name = "";
pys_if_std = (descr[4] << 24) | (descr[5] << 16) |
(descr[6] << 8) | descr[9];
if (pys_if_std == 1)
phys_name = "SCSI Family";
else if(pys_if_std == 2)
phys_name = "ATAPI";
else if(pys_if_std == 3 || pys_if_std == 4 ||
pys_if_std == 6)
phys_name = "IEEE 1394 FireWire";
else if(pys_if_std == 7)
phys_name = "Serial ATAPI";
else if(pys_if_std == 7)
phys_name = "USB";
fprintf(stderr,
"LIBBURN_EXPERIMENTAL : Phys. Interface Standard %Xh \"%s\"\n",
pys_if_std, phys_name);
} else if (feature_code == 0x107) {
fprintf(stderr, "LIBBURN_EXPERIMENTAL : CD SPEED = %d , page 2Ah = %d , SET STREAMING = %d\n",
!!(descr[4] & 8), !!(descr[4] & 4),
!!(descr[4] & 2));
} else if (feature_code == 0x108 || feature_code == 0x10c) {
int i, c_limit;
fprintf(stderr, "LIBBURN_EXPERIMENTAL : %s = ",
feature_code == 0x108 ?
"Drive Serial Number" : "Drive Firmware Date");
c_limit = descr[3] - 2 * (feature_code == 0x10c);
for (i = 0; i < c_limit; i++)
if (descr[4 + i] < 0x20 || descr[4 + i] > 0x7e
|| descr[4 + i] == '\\')
fprintf(stderr,"\\%2.2X",descr[4 + i]);
else
fprintf(stderr, "%c", descr[4 + i]);
fprintf(stderr, "\n");
#endif /* Libburn_print_feature_descriptorS */
}
}
}
/* ts A70108 */
/* mmc5r03c.pdf 6.24 */
int mmc_read_format_capacities(struct burn_drive *d, int top_wanted)
{
struct buffer buf;
int len, type, score, num_descr, max_score = -2000000000, i, sign = 1;
off_t size, num_blocks;
struct command c;
unsigned char *dpt;
char msg[160];
mmc_function_spy("mmc_read_format_capacities");
d->format_descr_type = 3;
d->format_curr_max_size = 0;
d->format_curr_blsas = 0;
d->best_format_type = -1;
d->best_format_size = 0;
memcpy(c.opcode, MMC_READ_FORMAT_CAPACITIES,
sizeof(MMC_GET_CONFIGURATION));
c.retry = 1;
c.oplen = sizeof(MMC_READ_FORMAT_CAPACITIES);
c.opcode[7]= 0x02;
c.opcode[8]= 0x00; /* accept 512 bytes (not more than 260 possible) */
c.page = &buf;
c.page->sectors = 0;
c.page->bytes = 0;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
if (c.error)
return 0;
len = c.page->data[3];
if (len<8)
return 0;
dpt = c.page->data + 4;
/* decode 6.24.3.2 Current/Maximum Capacity Descriptor */
d->format_descr_type = dpt[4] & 3;
d->format_curr_max_size = (((off_t) dpt[0]) << 24)
+ (dpt[1] << 16) + (dpt[2] << 8) + dpt[3];
d->format_curr_blsas = (dpt[5] << 16) + (dpt[6] << 8) + dpt[7];
sprintf(msg,
"Current/Maximum Capacity Descriptor : type = %d : %.f",
d->format_descr_type, (double) d->format_curr_max_size);
libdax_msgs_submit(libdax_messenger, d->global_index, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
msg, 0, 0);
d->format_curr_max_size *= (off_t) 2048;
if (top_wanted == 0x00 || top_wanted == 0x10)
sign = -1; /* the caller clearly desires full format */
/* 6.24.3.3 Formattable Capacity Descriptors */
num_descr = (len - 8) / 8;
for (i = 0; i < num_descr; i++) {
dpt = c.page->data + 12 + 8 * i;
num_blocks = mmc_four_char_to_int(dpt);
size = num_blocks * (off_t) 2048;
type = dpt[4] >> 2;
if (i < 32) {
d->format_descriptors[i].type = type;
d->format_descriptors[i].size = size;
d->format_descriptors[i].tdp =
(dpt[5] << 16) + (dpt[6] << 8) + dpt[7];
d->num_format_descr = i + 1;
}
sprintf(msg, "Capacity Descriptor %2.2Xh %.fs = %.1f MB",type,
((double) size)/2048.0, ((double) size)/1024.0/1024.0);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
msg, 0, 0);
/* Criterion is proximity to quick intermediate state */
if (type == 0x00) { /* full format (with lead out) */
score = 1 * sign;
if(d->current_profile == 0x12 &&
d->media_capacity_remaining == 0) {
d->media_capacity_remaining = size;
d->media_lba_limit = num_blocks;
}
} else if (type == 0x10) { /* DVD-RW full format */
score = 10 * sign;
} else if(type == 0x13) { /* DVD-RW quick grow last session */
score = 100 * sign;
} else if(type == 0x15) { /* DVD-RW Quick */
score = 50 * sign;
if(d->current_profile == 0x13) {
d->media_capacity_remaining = size;
d->media_lba_limit = num_blocks;
}
} else if(type == 0x26) { /* DVD+RW */
score = 1 * sign;
d->media_capacity_remaining = size;
d->media_lba_limit = num_blocks;
} else {
continue;
}
if (type == top_wanted)
score += 1000000000;
if (score > max_score) {
d->best_format_type = type;
d->best_format_size = size;
max_score = score;
}
}
sprintf(msg,
"best_format_type = %2.2Xh , best_format_size = %.f",
d->best_format_type, (double) d->best_format_size);
libdax_msgs_submit(libdax_messenger, d->global_index, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
msg, 0, 0);
return 1;
}
void mmc_sync_cache(struct burn_drive *d)
{
struct command c;
mmc_function_spy("mmc_sync_cache");
memcpy(c.opcode, MMC_SYNC_CACHE, sizeof(MMC_SYNC_CACHE));
c.retry = 1;
c.oplen = sizeof(MMC_SYNC_CACHE);
c.page = NULL;
c.dir = NO_TRANSFER;
libdax_msgs_submit(libdax_messenger, -1, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
"syncing cache", 0, 0);
d->issue_command(d, &c);
}
/* ts A61023 : http://libburn.pykix.org/ticket/14
get size and free space of drive buffer
*/
int mmc_read_buffer_capacity(struct burn_drive *d)
{
struct buffer buf;
struct command c;
unsigned char *data;
mmc_function_spy("mmc_read_buffer_capacity");
memcpy(c.opcode, MMC_READ_BUFFER_CAPACITY,
sizeof(MMC_READ_BUFFER_CAPACITY));
c.retry = 1;
c.oplen = sizeof(MMC_READ_BUFFER_CAPACITY);
c.page = &buf;
c.page->bytes = 0;
c.page->sectors = 0;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
/* >>> ??? error diagnostics */
data = c.page->data;
d->progress.buffer_capacity =
(data[4]<<24)|(data[5]<<16)|(data[6]<<8)|data[7];
d->progress.buffer_available =
(data[8]<<24)|(data[9]<<16)|(data[10]<<8)|data[11];
if (d->progress.buffered_bytes >= d->progress.buffer_capacity){
double fill;
fill = d->progress.buffer_capacity
- d->progress.buffer_available;
if (fill < d->progress.buffer_min_fill && fill>=0)
d->progress.buffer_min_fill = fill;
}
return 1;
}
/* ts A61219 : learned much from dvd+rw-tools-7.0: plus_rw_format()
and mmc5r03c.pdf, 6.5 FORMAT UNIT */
/*
@param size The size (in bytes) to be sent with the FORMAT comand
@param flag bit1= insist in size 0 even if there is a better default known
bit2= format to maximum available size
bit3= expand format up to at least size
bit4= enforce re-format of (partly) formatted media
bit7= bit8 to bit15 contain the index of the format to use
bit8-bit15 = see bit7
*/
int mmc_format_unit(struct burn_drive *d, off_t size, int flag)
{
struct buffer buf;
struct command c;
int ret, tolerate_failure = 0, return_immediately = 0, i, format_type;
int index;
off_t num_of_blocks = 0, diff;
char msg[160],descr[80];
int full_format_type = 0x00; /* Full Format (or 0x10 for DVD-RW ?) */
mmc_function_spy("mmc_format_unit");
c.retry = 1;
c.oplen = sizeof(MMC_FORMAT_UNIT);
memcpy(c.opcode, MMC_FORMAT_UNIT, sizeof(MMC_FORMAT_UNIT));
c.page = &buf;
c.page->bytes = 12;
c.page->sectors = 0;
c.dir = TO_DRIVE;
memset(c.page->data, 0, c.page->bytes);
descr[0] = 0;
c.page->data[1] = 0x02; /* Immed */
c.page->data[3] = 8; /* Format descriptor length */
num_of_blocks = size / 2048;
for (i = 0; i < 4; i++)
c.page->data[4 + i] = (num_of_blocks >> (24 - 8 * i)) & 0xff;
if (flag & 128) { /* explicitely chosen format descriptor */
/* use case: the app knows what to do */
ret = mmc_read_format_capacities(d, -1);
if (ret <= 0)
goto selected_not_suitable;
index = (flag >> 8) & 0xff;
if(index < 0 || index > d->num_format_descr) {
selected_not_suitable:;
libdax_msgs_submit(libdax_messenger, d->global_index,
0x00020132,
LIBDAX_MSGS_SEV_SORRY, LIBDAX_MSGS_PRIO_HIGH,
"Selected format is not suitable for libburn",
0, 0);
return 0;
}
if (!(d->current_profile == 0x13 ||
d->current_profile == 0x14 ||
d->current_profile == 0x1a))
goto unsuitable_media;
format_type = d->format_descriptors[index].type;
if (!(format_type == 0x00 || format_type == 0x10 ||
format_type == 0x11 || format_type == 0x13 ||
format_type == 0x15 || format_type == 0x26))
goto selected_not_suitable;
if (flag & 4) {
num_of_blocks =
d->format_descriptors[index].size / 2048;
for (i = 0; i < 4; i++)
c.page->data[4 + i] =
(num_of_blocks >> (24 - 8 * i)) & 0xff;
}
if (format_type != 0x26)
for (i = 0; i < 3; i++)
c.page->data[9 + i] =
( d->format_descriptors[index].tdp >>
(16 - 8 * i)) & 0xff;
sprintf(descr, "%s (bit7)", d->current_profile_text);
return_immediately = 1; /* caller must do the waiting */
} else if (d->current_profile == 0x1a) { /* DVD+RW */
/* use case: background formatting during write !(flag&4)
de-icing as explicit formatting action (flag&4)
*/
/* mmc5r03c.pdf , 6.5.4.2.14, DVD+RW Basic Format */
format_type = 0x26;
if ((size <= 0 && !(flag & 2)) || (flag & (4 | 8))) {
/* maximum capacity */
memset(c.page->data + 4, 0xff, 4);
num_of_blocks = 0xffffffff;
}
if(d->bg_format_status == 2 ||
(d->bg_format_status == 3 && !(flag & 16))) {
sprintf(msg,"FORMAT UNIT ignored. Already %s.",
(d->bg_format_status == 2 ? "in progress" :
"completed"));
libdax_msgs_submit(libdax_messenger, d->global_index,
0x00020120,
LIBDAX_MSGS_SEV_NOTE, LIBDAX_MSGS_PRIO_HIGH,
msg, 0,0);
return 2;
}
if (!(flag & 16)) /* if not re-format is desired */
if (d->bg_format_status == 1) /* is partly formatted */
c.page->data[11] = 1; /* Restart bit */
sprintf(descr, "DVD+RW (fs=%d,rs=%d)",
d->bg_format_status, (c.page->data[11] == 1));
if (flag & 4)
return_immediately = 1;/* caller must do the waiting */
} else if (d->current_profile == 0x13 && !(flag & 16)) {
/*DVD-RW restricted overwrite*/
/* use case: quick grow formatting during write */
ret = mmc_read_format_capacities(d, 0x13);
if (ret > 0) {
if (d->best_format_type == 0x13) {
if (d->best_format_size <= 0)
return 1;
} else {
if (d->format_descr_type == 2) /* formatted */
return 1;
if (d->format_descr_type == 3){/*intermediate*/
d->needs_close_session = 1;
return 1;
}
/* does trying make sense at all ? */
tolerate_failure = 1;
}
}
if (d->best_format_type == 0x13 && (flag & (4 | 8))) {
num_of_blocks = d->best_format_size / 2048;
if (flag & 8) {
/* num_of_blocks needed to reach size */
diff = (size - d->format_curr_max_size) /32768;
if ((size - d->format_curr_max_size) % 32768)
diff++;
diff *= 16;
if (diff < num_of_blocks)
num_of_blocks = diff;
}
if (num_of_blocks > 0)
for (i = 0; i < 4; i++)
c.page->data[4 + i] =
(num_of_blocks >> (24 - 8 * i)) & 0xff;
}
/* 6.5.4.2.8 , DVD-RW Quick Grow Last Border */
format_type = 0x13;
c.page->data[11] = 16; /* block size * 2k */
sprintf(descr, "DVD-RW quick grow");
} else if (d->current_profile == 0x14 ||
(d->current_profile == 0x13 && (flag & 16))) {
/* DVD-RW sequential recording (or Overwrite for re-format) */
/* use case : transition from Sequential to Overwrite
re-formatting of Overwrite media */
/* To Restricted Overwrite */
/* 6.5.4.2.10 Format Type = 15h (DVD-RW Quick) */
/* or 6.5.4.2.1 Format Type = 00h (Full Format) */
/* or 6.5.4.2.5 Format Type = 10h (DVD-RW Full Format) */
mmc_read_format_capacities(d,
(flag & 4) ? full_format_type : 0x15);
if (d->best_format_type == 0x15 ||
d->best_format_type == full_format_type) {
if ((flag & 4)
|| d->best_format_type == full_format_type) {
num_of_blocks = d->best_format_size / 2048;
for (i = 0; i < 4; i++)
c.page->data[4 + i] =
(num_of_blocks >> (24 - 8 * i)) & 0xff;
}
} else {
libdax_msgs_submit(libdax_messenger, d->global_index,
0x00020131,
LIBDAX_MSGS_SEV_SORRY, LIBDAX_MSGS_PRIO_HIGH,
"No suitable formatting type offered by drive",
0, 0);
return 0;
}
format_type = d->best_format_type;
c.page->data[11] = 16; /* block size * 2k */
sprintf(descr, "DVD-RW %s",
format_type == 0x15 ? "quick" : "full");
return_immediately = 1; /* caller must do the waiting */
} else {
/* >>> other formattable types to come */
unsuitable_media:;
sprintf(msg, "Unsuitable media detected. Profile %4.4Xh %s",
d->current_profile, d->current_profile_text);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x0002011e,
LIBDAX_MSGS_SEV_SORRY, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
return 0;
}
c.page->data[8] = format_type << 2;
sprintf(msg, "Format type %2.2Xh \"%s\", blocks = %.f\n",
format_type, descr, (double) num_of_blocks);
libdax_msgs_submit(libdax_messenger, d->global_index, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
msg, 0, 0);
d->issue_command(d, &c);
if (c.error && !tolerate_failure) {
if (c.sense[2]!=0) {
sprintf(msg,
"SCSI error on format_unit(%s): key=%X asc=%2.2Xh ascq=%2.2Xh",
descr,
c.sense[2],c.sense[12],c.sense[13]);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x00020122,
LIBDAX_MSGS_SEV_FATAL, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
}
return 0;
} else if ((!c.error) && (format_type == 0x13 || format_type == 0x15))
d->needs_close_session = 1;
if (return_immediately)
return 1;
usleep(1000000); /* there seems to be a little race condition */
for (ret = 0; ret <= 0 ;) {
usleep(50000);
ret = spc_test_unit_ready(d);
}
mmc_sync_cache(d);
return 1;
}
/* ts A61225 */
int mmc_get_write_performance(struct burn_drive *d)
{
struct buffer buf;
int len, i, b, max_descr, num_descr, ret;
int exact_bit, read_speed, write_speed;
/* if this call delivers usable data then they should override
previously recorded min/max speed and not compete with them */
int min_write_speed = 0x7fffffff, max_write_speed = 0;
int min_read_speed = 0x7fffffff, max_read_speed = 0;
struct command c;
unsigned long end_lba;
unsigned char *pd;
struct burn_speed_descriptor *sd;
/* A61225 : 1 = report about speed descriptors */
static int speed_debug = 0;
mmc_function_spy("mmc_get_write_performance");
if (d->current_profile <= 0)
mmc_get_configuration(d);
memcpy(c.opcode, MMC_GET_PERFORMANCE, sizeof(MMC_GET_PERFORMANCE));
max_descr = ( BUFFER_SIZE - 8 ) / 16 - 1;
/* >>> future: maintain a list of write descriptors
if (max_descr > d->max_write_descr - d->num_write_descr)
max_descr = d->max_write_descr;
*/
c.opcode[8] = ( max_descr >> 8 ) & 0xff;
c.opcode[9] = ( max_descr >> 0 ) & 0xff;
c.opcode[10] = 3;
c.retry = 1;
c.oplen = sizeof(MMC_GET_PERFORMANCE);
c.page = &buf;
c.page->sectors = 0;
c.page->bytes = 0;
c.dir = FROM_DRIVE;
d->issue_command(d, &c);
if (c.error)
return 0;
len = (c.page->data[0] << 24)
+ (c.page->data[1] << 16)
+ (c.page->data[2] << 8)
+ c.page->data[3];
if (len<12)
return 0;
pd = c.page->data;
num_descr = ( len - 4 ) / 16;
if (num_descr > max_descr)
num_descr = max_descr;
for (i = 0; i < num_descr; i++) {
exact_bit = !!(pd[8 + i*16] & 2);
end_lba = read_speed = write_speed = 0;
for (b = 0; b < 4 ; b++) {
end_lba += pd[8 + i*16 + 4 + b] << (24 - 8 * b);
read_speed += pd[8 + i*16 + 8 + b] << (24 - 8 * b);
write_speed += pd[8 + i*16 + 12 + b] << (24 - 8 * b);
}
if (end_lba > 0x7ffffffe)
end_lba = 0x7ffffffe;
if (speed_debug)
fprintf(stderr,
"LIBBURN_DEBUG: kB/s: write=%d read=%d end=%lu exact=%d\n",
write_speed, read_speed, end_lba, exact_bit);
/* ts A61226 */
ret = burn_speed_descriptor_new(&(d->mdata->speed_descriptors),
NULL, d->mdata->speed_descriptors, 0);
if (ret > 0) {
sd = d->mdata->speed_descriptors;
sd->source = 2;
if (d->current_profile > 0) {
sd->profile_loaded = d->current_profile;
strcpy(sd->profile_name,
d->current_profile_text);
}
sd->wrc = (pd[8 + i*16] >> 3 ) & 3;
sd->exact = exact_bit;
sd->mrw = pd[8 + i*16] & 1;
sd->end_lba = end_lba;
sd->write_speed = write_speed;
sd->read_speed = read_speed;
}
if (end_lba > d->mdata->max_end_lba)
d->mdata->max_end_lba = end_lba;
if (end_lba < d->mdata->min_end_lba)
d->mdata->min_end_lba = end_lba;
if (write_speed < min_write_speed)
min_write_speed = write_speed;
if (write_speed > max_write_speed)
max_write_speed = write_speed;
if (read_speed < min_read_speed)
min_read_speed = read_speed;
if (read_speed > max_read_speed)
max_read_speed = read_speed;
}
if (min_write_speed < 0x7fffffff)
d->mdata->min_write_speed = min_write_speed;
if (max_write_speed > 0)
d->mdata->max_write_speed = max_write_speed;
/* there is no mdata->min_read_speed yet
if (min_read_speed < 0x7fffffff)
d->mdata->min_read_speed = min_read_speed;
*/
if (max_read_speed > 0)
d->mdata->max_read_speed = max_read_speed;
return num_descr;
}
/* ts A61021 : the mmc specific part of sg.c:enumerate_common()
*/
int mmc_setup_drive(struct burn_drive *d)
{
d->read_atip = mmc_read_atip;
d->read_toc = mmc_read_toc;
d->write = mmc_write;
d->erase = mmc_erase;
d->read_sectors = mmc_read_sectors;
d->perform_opc = mmc_perform_opc;
d->set_speed = mmc_set_speed;
d->send_cue_sheet = mmc_send_cue_sheet;
d->reserve_track = mmc_reserve_track;
d->sync_cache = mmc_sync_cache;
d->get_nwa = mmc_get_nwa;
d->read_multi_session_c1 = mmc_read_multi_session_c1;
d->close_disc = mmc_close_disc;
d->close_session = mmc_close_session;
d->close_track_session = mmc_close;
d->read_buffer_capacity = mmc_read_buffer_capacity;
d->format_unit = mmc_format_unit;
d->read_format_capacities = mmc_read_format_capacities;
/* ts A61020 */
d->start_lba = -2000000000;
d->end_lba = -2000000000;
/* ts A61201 - A70128 */
d->erasable = 0;
d->current_profile = -1;
d->current_profile_text[0] = 0;
d->current_is_cd_profile = 0;
d->current_is_supported_profile = 0;
d->current_has_feat21h = 0;
d->current_feat21h_link_size = -1;
d->current_feat2fh_byte4 = -1;
d->needs_close_session = 0;
d->bg_format_status = -1;
d->num_format_descr = 0;
d->complete_sessions = 0;
d->last_track_no = 1;
d->media_capacity_remaining = 0;
d->media_lba_limit = 0;
return 1;
}
/* ts A61229 : outsourced from spc_select_write_params() */
/* Note: Page data is not zeroed here to allow preset defaults. Thus
memset(pd, 0, 2 + d->mdata->write_page_length);
is the eventual duty of the caller.
*/
int mmc_compose_mode_page_5(struct burn_drive *d,
const struct burn_write_opts *o,
unsigned char *pd)
{
pd[0] = 5;
pd[1] = d->mdata->write_page_length;
if (d->current_profile == 0x13) {
/* A61229 : DVD-RW restricted overwrite */
/* learned from transport.hxx : page05_setup()
and mmc3r10g.pdf table 347 */
/* BUFE (burnproof), no LS_V (i.e. default Link Size, i hope),
no simulate, write type 0 = packet */
pd[2] = (1 << 6);
/* no multi, fixed packet, track mode 5 */
pd[3] = (1 << 5) | 5;
/* Data Block Type */
pd[4] = 8;
/* Link size dummy */
pd[5] = 0;
} else if ((d->current_profile == 0x14 || d->current_profile == 0x11)
&& o->write_type == BURN_WRITE_SAO) {
/* ts A70205 : DVD-R[W} : Disc-at-once, DAO */
/* Learned from dvd+rw-tools and mmc5r03c.pdf .
See doc/cookbook.txt for more detailed references. */
/* BUFE , LS_V = 0, Test Write, Write Type = 2 SAO (DAO) */
pd[2] = ((!!o->underrun_proof) << 6)
| ((!!o->simulate) << 4)
| 2;
/* No multi-session , FP = 0 , Track Mode = 5 */
pd[3] = 5;
/* Data Block Type = 8 */
pd[4] = 8;
} else if (d->current_profile == 0x14 || d->current_profile == 0x11) {
/* ts A70128 : DVD-R[W] Incremental Streaming */
/* Learned from transport.hxx : page05_setup()
and mmc5r03c.pdf 7.5, 4.2.3.4 Table 17
and spc3r23.pdf 6.8, 7.4.3 */
/* BUFE , LS_V = 1, Test Write,
Write Type = 0 Packet/Incremental */
pd[2] = ((!!o->underrun_proof) << 6)
| (1 << 5)
| ((!!o->simulate) << 4);
/* Multi-session , FP = 1 , Track Mode = 5 */
pd[3] = ((3 * !!o->multi) << 6) | (1 << 5) | 5;
/* Data Block Type = 8 */
pd[4] = 8;
/* Link Size */
if (d->current_feat21h_link_size >= 0)
pd[5] = d->current_feat21h_link_size;
else
pd[5] = 16;
if (d->current_feat21h_link_size != 16) {
char msg[80];
sprintf(msg,
"Feature 21h Link Size = %d (expected 16)\n",
d->current_feat21h_link_size);
libdax_msgs_submit(libdax_messenger, -1, 0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_ZERO,
msg, 0, 0);
}
/* Packet Size */
pd[13] = 16;
} else {
/* Traditional setup for CD */
pd[2] = ((!!o->underrun_proof) << 6)
| ((!!o->simulate) << 4)
| (o->write_type & 0x0f);
/* ts A61106 : MMC-1 table 110 : multi==0 or multi==3 */
pd[3] = ((3 * !!o->multi) << 6) | (o->control & 0x0f);
pd[4] = spc_block_type(o->block_type);
/* ts A61104 */
if(!(o->control&4)) /* audio (MMC-1 table 61) */
if(o->write_type == BURN_WRITE_TAO)
pd[4] = 0; /* Data Block Type: Raw Data */
pd[14] = 0; /* audio pause length MSB */
pd[15] = 150; /* audio pause length LSB */
/*XXX need session format! */
/* ts A61229 : but session format (pd[8]) = 0 seems ok */
}
return 1;
}