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/* -*- indent-tabs-mode: t; tab-width: 8; c-basic-offset: 8; -*- */
/*
Copyright (c) 2010 - 2016 Thomas Schmitt <scdbackup@gmx.net>
Provided under GPL version 2 or later.
*/
/*
This is the main operating system dependent SCSI part of libburn. It implements
the transport level aspects of SCSI control and command i/o.
Present implementation: Solaris uscsi, e.g. for SunOS 5.11
PORTING:
Porting libburn typically will consist of adding a new operating system case
to the following switcher files:
os.h Operating system specific libburn definitions and declarations.
sg.c Operating system dependent transport level modules.
and of deriving the following system specific files from existing examples:
os-*.h Included by os.h. You will need some general system knowledge
about signals and knowledge about the storage object needs of your
transport level module sg-*.c.
sg-*.c This source module. You will need special system knowledge about
how to detect all potentially available drives, how to open them,
eventually how to exclusively reserve them, how to perform
SCSI transactions, how to inquire the (pseudo-)SCSI driver.
You will not need to care about CD burning, MMC or other high-level
SCSI aspects.
Said sg-*.c operations are defined by a public function interface, which has
to be implemented in a way that provides libburn with the desired services:
sg_id_string() returns an id string of the SCSI transport adapter.
It may be called before initialization but then may
return only a preliminary id.
sg_initialize() performs global initialization of the SCSI transport
adapter and eventually needed operating system
facilities. Checks for compatibility of supporting
software components.
sg_shutdown() performs global finalizations and releases golbally
acquired resources.
sg_give_next_adr() iterates over the set of potentially useful drive
address strings.
scsi_enumerate_drives() brings all available, not-whitelist-banned, and
accessible drives into libburn's list of drives.
sg_dispose_drive() finalizes adapter specifics of struct burn_drive
on destruction. Releases resources which were acquired
underneath scsi_enumerate_drives().
sg_drive_is_open() tells wether libburn has the given drive in use.
sg_grab() opens the drive for SCSI commands and ensures
undisturbed access.
sg_release() closes a drive opened by sg_grab()
sg_issue_command() sends a SCSI command to the drive, receives reply,
and evaluates wether the command succeeded or shall
be retried or finally failed.
sg_obtain_scsi_adr() tries to obtain SCSI address parameters.
burn_os_is_2k_seekrw() tells whether the given path leads to a file object
that can be used in 2 kB granularity by lseek(2),
read(2), and possibly write(2) if not read-only..
E.g. a USB stick or a hard disk.
burn_os_stdio_capacity() estimates the emulated media space of stdio-drives.
burn_os_open_track_src() opens a disk file in a way that offers best
throughput with file reading and/or SCSI write command
transmission.
burn_os_alloc_buffer() allocates a memory area that is suitable for file
descriptors issued by burn_os_open_track_src().
The buffer size may be rounded up for alignment
reasons.
burn_os_free_buffer() delete a buffer obtained by burn_os_alloc_buffer().
Porting hints are marked by the text "PORTING:".
Send feedback to libburn-hackers@pykix.org .
*/
#ifdef HAVE_CONFIG_H
#include "../config.h"
#endif
/** PORTING : ------- OS dependent headers and definitions ------ */
#include <unistd.h>
#include <stropts.h>
#include <stdio.h>
#include <sys/types.h>
#include <errno.h>
#include <fcntl.h>
#include <sys/stat.h>
#include <string.h>
#include <stdlib.h>
#include <dirent.h>
#ifdef Libburn_os_has_statvfS
#include <sys/statvfs.h>
#endif /* Libburn_os_has_stavtfS */
#include <volmgt.h>
#include <sys/dkio.h>
#include <sys/vtoc.h>
#include <sys/scsi/impl/uscsi.h>
/* The waiting time before eventually retrying a failed SCSI command.
Before each retry wait Libburn_sg_linux_retry_incR longer than with
the previous one.
*/
#define Libburn_sg_solaris_retry_usleeP 100000
#define Libburn_sg_solaris_retry_incR 100000
/** PORTING : ------ libburn portable headers and definitions ----- */
#include "transport.h"
#include "drive.h"
#include "sg.h"
#include "spc.h"
#include "sbc.h"
#include "debug.h"
#include "toc.h"
#include "util.h"
#include "init.h"
#include "libdax_msgs.h"
extern struct libdax_msgs *libdax_messenger;
/* is in portable part of libburn */
int burn_drive_is_banned(char *device_address);
int burn_drive_resolve_link(char *path, char adr[],
int *recursion_count, int flag); /* drive.c */
/* Whether to log SCSI commands:
bit0= log in /tmp/libburn_sg_command_log
bit1= log to stderr
bit2= flush every line
*/
extern int burn_sg_log_scsi;
/* ------------------------------------------------------------------------ */
/* PORTING: Private definitions. Port only if needed by public functions. */
/* (Public functions are listed below) */
/* ------------------------------------------------------------------------ */
/* Storage object is in libburn/init.c
whether to strive for exclusive access to the drive
*/
extern int burn_sg_open_o_excl;
/* ------------------------------------------------------------------------ */
/* PORTING: Private functions. Port only if needed by public functions */
/* (Public functions are listed below) */
/* ------------------------------------------------------------------------ */
static int sg_close_drive(struct burn_drive * d)
{
if (d->fd != -1) {
close(d->fd);
d->fd = -1;
return 1;
}
return 0;
}
static int decode_btl_number(char **cpt, int stopper, int *no)
{
*no = 0;
for ((*cpt)++; **cpt != stopper; (*cpt)++) {
if (**cpt < '0' || **cpt > '9')
return 0;
*no = *no * 10 + **cpt - '0';
}
return 1;
}
/* Read bus, target, lun from name "cXtYdZs2" or "cXtYdZ/...".
Return 0 if name is not of the desired form.
*/
static int decode_btl_solaris(char *name, int *busno, int *tgtno, int *lunno,
int flag)
{
char *cpt, *cpt_mem;
int ret;
*busno = *tgtno = *lunno = -1;
cpt = name;
if (*cpt != 'c')
return 0;
ret = decode_btl_number(&cpt, 't', busno);
if (ret <= 0)
return ret;
ret = decode_btl_number(&cpt, 'd', tgtno);
if (ret <= 0)
return ret;
cpt_mem = cpt;
ret = decode_btl_number(&cpt, 's', lunno);
if (ret <= 0) {
cpt = cpt_mem;
ret = decode_btl_number(&cpt, '/', lunno);
if (ret <= 0)
return ret;
return(1);
}
cpt++;
if (*cpt != '2' || *(cpt + 1) != 0)
return 0;
return 1;
}
static int start_enum_cXtYdZs2(burn_drive_enumerator_t *idx, int flag)
{
DIR *dir;
idx->dir = NULL;
dir = opendir("/dev/rdsk");
if (dir == NULL) {
libdax_msgs_submit(libdax_messenger, -1,
0x0002000c, LIBDAX_MSGS_SEV_FAILURE, LIBDAX_MSGS_PRIO_HIGH,
"Cannot start device file enumeration. opendir(\"/dev/rdsk\") failed.",
errno, 0);
return 0;
}
idx->dir = dir;
return 1;
}
static int sg_solaris_convert_devname(char *path, char **dev_to_open, int flag)
{
char *sym_name = NULL, *media_name = NULL, *curr_name, *msg = NULL;
int ret;
BURN_ALLOC_MEM(msg, char, 4096);
BURN_FREE_MEM(*dev_to_open);
*dev_to_open = NULL;
curr_name = path;
if (! volmgt_running())
goto set_name;
sym_name = volmgt_symname(path);
sprintf(msg, "Volume Management symbolic name: '%s' -> %s",
path, sym_name == NULL ? "NULL" : sym_name);
libdax_msgs_submit(libdax_messenger, -1,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
if (sym_name != NULL)
media_name = media_findname(sym_name);
else
media_name = media_findname(path);
if (media_name != NULL)
curr_name = media_name;
sprintf(msg, "Media name: %s -> %s",
sym_name == NULL ? path : sym_name,
media_name == NULL ? "NULL" : media_name);
libdax_msgs_submit(libdax_messenger, -1,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
set_name:
BURN_ALLOC_MEM(*dev_to_open, char, strlen(curr_name) + 1);
strcpy(*dev_to_open, curr_name);
ret = 1;
ex:
if (media_name != NULL)
free(media_name);
if (sym_name != NULL)
free(sym_name);
BURN_FREE_MEM(msg);
return(ret);
}
static int next_enum_cXtYdZs2(burn_drive_enumerator_t *idx,
char adr[], int adr_size, int flag)
{
int busno, tgtno, lunno, ret, fd = -1, volpath_size = 160, os_errno;
char *volpath = NULL, *msg = NULL, *dev_to_open = NULL;
struct dirent *entry;
struct dk_cinfo cinfo;
DIR *dir;
BURN_ALLOC_MEM(volpath, char, volpath_size);
BURN_ALLOC_MEM(msg, char, 4096);
dir = idx->dir;
while (1) {
errno = 0;
entry = readdir(dir);
if (entry == NULL) {
if (errno) {
libdax_msgs_submit(libdax_messenger,
-1, 0x0002000d,
LIBDAX_MSGS_SEV_FAILURE, LIBDAX_MSGS_PRIO_HIGH,
"Cannot enumerate next device. readdir() from \"/dev/rdsk\" failed.",
errno, 0);
{ret = -1; goto ex;}
}
break;
}
if (strlen(entry->d_name) > (size_t) (volpath_size - 11))
continue;
ret = decode_btl_solaris(entry->d_name,
&busno, &tgtno, &lunno, 0);
if (ret <= 0)
continue; /* not cXtYdZs2 */
sprintf(volpath, "/dev/rdsk/%s", entry->d_name);
if (burn_drive_is_banned(volpath))
continue;
ret = sg_solaris_convert_devname(volpath, &dev_to_open, 0);
if (ret <= 0)
continue;
fd = open(dev_to_open, O_RDONLY | O_NDELAY);
if (fd < 0) {
os_errno = errno;
sprintf(msg, "Could not open '%s' , errno = %d",
dev_to_open, os_errno);
libdax_msgs_submit(libdax_messenger, -1,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
msg, os_errno, 0);
continue;
}
/* See man dkio */
ret = ioctl(fd, DKIOCINFO, &cinfo);
close(fd);
if (ret < 0) {
os_errno = errno;
sprintf(msg,
"ioctl(DKIOCINFO) failed on drive '%s', errno = %d",
volpath, os_errno);
libdax_msgs_submit(libdax_messenger, -1,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
msg, os_errno, 0);
continue;
}
if (cinfo.dki_ctype != DKC_CDROM) {
sprintf(msg,
"ioctl(DKIOCINFO) classifies drive '%s' as dki_ctype %ld, not as DKC_CDROM = %ld",
volpath, (long int) cinfo.dki_ctype,
(long int) DKC_CDROM);
libdax_msgs_submit(libdax_messenger, -1,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
continue;
}
if (adr_size <= (int) strlen(volpath)) {
sprintf(msg,
"Device path '%s' too long. (Max. %d)",
volpath, adr_size - 1);
libdax_msgs_submit(libdax_messenger, -1,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
{ret = -1; goto ex;}
}
strcpy(adr, volpath);
sprintf(msg, "Accepted as valid drive '%s'", volpath);
libdax_msgs_submit(libdax_messenger, -1,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
{ret = 1; goto ex;}
}
ret = 0;
ex:;
BURN_FREE_MEM(dev_to_open);
BURN_FREE_MEM(msg);
BURN_FREE_MEM(volpath);
return ret;
}
static int end_enum_cXtYdZs2(burn_drive_enumerator_t *idx, int flag)
{
DIR *dir;
dir = idx->dir;
if(dir != NULL)
closedir(dir);
idx->dir = NULL;
return 1;
}
/* ----------------------------------------------------------------------- */
/* PORTING: Private functions which contain publicly needed functionality. */
/* Their portable part must be performed. So it is probably best */
/* to replace the non-portable part and to call these functions */
/* in your port, too. */
/* ----------------------------------------------------------------------- */
/** Wraps a detected drive into libburn structures and hands it over to
libburn drive list.
*/
static void enumerate_common(char *fname,
int bus_no, int host_no,
int channel_no, int target_no, int lun_no)
{
int ret;
struct burn_drive out;
/* General libburn drive setup */
burn_setup_drive(&out, fname);
/* This transport adapter uses SCSI-family commands and models
(seems the adapter would know better than its boss, if ever) */
ret = burn_scsi_setup_drive(&out, bus_no, host_no, channel_no,
target_no, lun_no, 0);
if (ret <= 0)
return;
/* PORTING: ------------------- non portable part --------------- */
/* Transport adapter is Solaris uscsi */
/* Adapter specific handles and data */
out.fd = -1;
/* PORTING: ---------------- end of non portable part ------------ */
/* Adapter specific functions with standardized names */
out.grab = sg_grab;
out.release = sg_release;
out.drive_is_open = sg_drive_is_open;
out.issue_command = sg_issue_command;
/* Finally register drive and inquire drive information */
burn_drive_finish_enum(&out);
}
/* ------------------------------------------------------------------------ */
/* PORTING: Public functions. These MUST be ported. */
/* ------------------------------------------------------------------------ */
/** Returns the id string of the SCSI transport adapter and eventually
needed operating system facilities.
This call is usable even if sg_initialize() was not called yet. In that
case a preliminary constant message might be issued if detailed info is
not available yet.
@param msg returns id string
@param flag unused yet, submit 0
@return 1 = success, <=0 = failure
*/
int sg_id_string(char msg[1024], int flag)
{
sprintf(msg, "internal Solaris uscsi adapter sg-solaris");
return 1;
}
/** Performs global initialization of the SCSI transport adapter and eventually
needed operating system facilities. Checks for compatibility of supporting
software components.
@param msg returns ids and/or error messages of eventual helpers
@param flag unused yet, submit 0
@return 1 = success, <=0 = failure
*/
int sg_initialize(char msg[1024], int flag)
{
return sg_id_string(msg, 0);
}
/** Performs global finalization of the SCSI transport adapter and eventually
needed operating system facilities. Releases globally acquired resources.
@param flag unused yet, submit 0
@return 1 = success, <=0 = failure
*/
int sg_shutdown(int flag)
{
return 1;
}
/** Finalizes BURN_OS_TRANSPORT_DRIVE_ELEMENTS, the components of
struct burn_drive which are defined in os-*.h.
The eventual initialization of those components was made underneath
scsi_enumerate_drives().
This will be called when a burn_drive gets disposed.
@param d the drive to be finalized
@param flag unused yet, submit 0
@return 1 = success, <=0 = failure
*/
int sg_dispose_drive(struct burn_drive *d, int flag)
{
return 1;
}
/** Returns the next index number and the next enumerated drive address.
The enumeration has to cover all available and accessible drives. It is
allowed to return addresses of drives which are not available but under
some (even exotic) circumstances could be available. It is on the other
hand allowed, only to hand out addresses which can really be used right
in the moment of this call. (This implementation chooses the latter.)
@param idx An opaque handle. Make no own theories about it.
@param adr Takes the reply
@param adr_size Gives maximum size of reply including final 0
@param initialize 1 = start new,
0 = continue, use no other values for now
-1 = finish
@return 1 = reply is a valid address , 0 = no further address available
-1 = severe error (e.g. adr_size too small)
*/
int sg_give_next_adr(burn_drive_enumerator_t *idx,
char adr[], int adr_size, int initialize)
{
int ret;
if (initialize == 1) {
ret = start_enum_cXtYdZs2(idx, 0);
if (ret <= 0)
return ret;
} else if (initialize == -1) {
ret = end_enum_cXtYdZs2(idx, 0);
return 0;
}
ret = next_enum_cXtYdZs2(idx, adr, adr_size, 0);
return ret;
}
/** Brings all available, not-whitelist-banned, and accessible drives into
libburn's list of drives.
*/
int scsi_enumerate_drives(void)
{
burn_drive_enumerator_t idx;
int initialize = 1, ret, i_bus_no = -1, buf_size = 4096;
int i_host_no = -1, i_channel_no = -1, i_target_no = -1, i_lun_no = -1;
char *buf = NULL;
BURN_ALLOC_MEM(buf, char, buf_size);
while(1) {
ret = sg_give_next_adr(&idx, buf, buf_size, initialize);
initialize = 0;
if (ret <= 0)
break;
if (burn_drive_is_banned(buf))
continue;
sg_obtain_scsi_adr(buf, &i_bus_no, &i_host_no,
&i_channel_no, &i_target_no, &i_lun_no);
enumerate_common(buf,
i_bus_no, i_host_no, i_channel_no,
i_target_no, i_lun_no);
}
sg_give_next_adr(&idx, buf, buf_size, -1);
ret = 1;
ex:;
BURN_FREE_MEM(buf);
return ret;
}
/** Tells whether libburn has the given drive in use or exclusively reserved.
If it is "open" then libburn will eventually call sg_release() on it when
it is time to give up usage and reservation.
*/
/** Published as burn_drive.drive_is_open() */
int sg_drive_is_open(struct burn_drive * d)
{
return (d->fd != -1);
}
/** Opens the drive for SCSI commands and - if burn activities are prone
to external interference on your system - obtains an exclusive access lock
on the drive. (Note: this is not physical tray locking.)
A drive that has been opened with sg_grab() will eventually be handed
over to sg_release() for closing and unreserving.
*/
int sg_grab(struct burn_drive *d)
{
char *msg = NULL, *dev_to_open = NULL;
int os_errno, ret;
struct dk_cinfo cinfo;
BURN_ALLOC_MEM(msg, char, 4096);
if (d->fd != -1) {
d->released = 0;
{ret = 1; goto ex;}
}
ret = sg_solaris_convert_devname(d->devname, &dev_to_open, 0);
if (ret <= 0)
goto ex;
d->fd = open(dev_to_open, O_RDONLY | O_NDELAY);
if (d->fd == -1) {
os_errno = errno;
sprintf(msg, "Could not grab drive '%s'",
d->devname);
if (strcmp(d->devname, dev_to_open))
sprintf(msg + strlen(msg), " via '%s'", dev_to_open);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x00020003,
LIBDAX_MSGS_SEV_SORRY, LIBDAX_MSGS_PRIO_HIGH,
msg, os_errno, 0);
{ret = 0; goto ex;}
}
ret = ioctl(d->fd, DKIOCINFO, &cinfo);
if (ret < 0) {
os_errno = errno;
sprintf(msg, "ioctl(DKIOCINFO) failed on drive '%s'",
d->devname);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
msg, os_errno, 0);
goto revoke;
}
if (cinfo.dki_ctype != DKC_CDROM) {
sprintf(msg,
"ioctl(DKIOCINFO) classifies drive '%s' as dki_ctype %ld, not as DKC_CDROM = %ld",
d->devname, (long int) cinfo.dki_ctype,
(long int) DKC_CDROM);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x00000002,
LIBDAX_MSGS_SEV_DEBUG, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
goto revoke;
}
/* >>> obtain eventual locks */;
d->released = 0;
{ret = 1; goto ex;}
revoke:;
sprintf(msg, "Could not grab drive '%s'. Not a CDROM device.",
d->devname);
libdax_msgs_submit(libdax_messenger, d->global_index,
0x00020003,
LIBDAX_MSGS_SEV_SORRY, LIBDAX_MSGS_PRIO_HIGH,
msg, 0, 0);
ret = 0;
ex:;
BURN_FREE_MEM(dev_to_open);
BURN_FREE_MEM(msg);
return ret;
}
/** PORTING: Is mainly about the call to sg_close_drive() and whether it
implements the demanded functionality.
*/
/** Gives up the drive for SCSI commands and releases eventual access locks.
(Note: this is not physical tray locking.)
*/
int sg_release(struct burn_drive *d)
{
if (d->fd < 0)
return 0;
sg_close_drive(d);
return 0;
}
/** Sends a SCSI command to the drive, receives reply and evaluates wether
the command succeeded or shall be retried or finally failed.
Returned SCSI errors shall not lead to a return value indicating failure.
The callers get notified by c->error. An SCSI failure which leads not to
a retry shall be notified via scsi_notify_error().
The Libburn_log_sg_commandS facility might be of help when problems with
a drive have to be examined. It shall stay disabled for normal use.
@return: 1 success , <=0 failure
*/
int sg_issue_command(struct burn_drive *d, struct command *c)
{
int i, timeout_ms, ret, key, asc, ascq, done = 0, sense_len;
time_t start_time;
struct uscsi_cmd cgc;
char msg[80];
static FILE *fp = NULL;
c->error = 0;
memset(c->sense, 0, sizeof(c->sense));
if (d->fd == -1)
return 0;
if (burn_sg_log_scsi & 1) {
if (fp == NULL) {
fp= fopen("/tmp/libburn_sg_command_log", "a");
fprintf(fp,
"\n-----------------------------------------\n");
}
}
if (burn_sg_log_scsi & 3)
scsi_log_cmd(c,fp,0);
if (c->timeout > 0)
timeout_ms = c->timeout;
else
timeout_ms = 200000;
memset (&cgc, 0, sizeof (struct uscsi_cmd));
/* No error messages, no retries,
do not execute with other commands, request sense data
*/
cgc.uscsi_flags = USCSI_SILENT | USCSI_DIAGNOSE | USCSI_ISOLATE
| USCSI_RQENABLE;
cgc.uscsi_timeout = timeout_ms / 1000;
cgc.uscsi_cdb = (caddr_t) c->opcode;
cgc.uscsi_bufaddr = (caddr_t) c->page->data;
if (c->dir == TO_DRIVE) {
cgc.uscsi_flags |= USCSI_WRITE;
cgc.uscsi_buflen = c->page->bytes;
} else if (c->dir == FROM_DRIVE) {
cgc.uscsi_flags |= USCSI_READ;
if (c->dxfer_len >= 0)
cgc.uscsi_buflen = c->dxfer_len;
else
cgc.uscsi_buflen = BUFFER_SIZE;
/* touch page so we can use valgrind */
memset(c->page->data, 0, BUFFER_SIZE);
} else {
cgc.uscsi_buflen = 0;
}
cgc.uscsi_cdblen = c->oplen;
cgc.uscsi_rqlen = sizeof(c->sense);
cgc.uscsi_rqbuf = (caddr_t) c->sense;
/* retry-loop */
start_time = time(NULL);
for(i = 0; !done; i++) {
memset(c->sense, 0, sizeof(c->sense));
c->start_time = burn_get_time(0);
ret = ioctl(d->fd, USCSICMD, &cgc);
c->end_time = burn_get_time(0);
/* For cgc.uscsi_status see SAM-3 5.3.1, Table 22
0 = GOOD , 2 = CHECK CONDITION : Sense Data are delivered
8 = BUSY
*/
if (ret != 0 && cgc.uscsi_status != 2) {
sprintf(msg,
"Failed to transfer command to drive. (uscsi_status = 0x%X)",
(unsigned int) cgc.uscsi_status),
libdax_msgs_submit(libdax_messenger,
d->global_index, 0x0002010c,
LIBDAX_MSGS_SEV_FATAL, LIBDAX_MSGS_PRIO_HIGH,
msg, errno, 0);
sg_close_drive(d);
d->released = 1;
d->busy = BURN_DRIVE_IDLE;
c->error = 1;
return -1;
}
/* >>> Should replace "18" by realistic sense length.
What's about following older remark ?
*/
/* >>> valid sense: cgc.uscsi_rqlen - cgc.uscsi_rqresid */;
spc_decode_sense(c->sense, 0, &key, &asc, &ascq);
if (key || asc || ascq)
sense_len = 18;
else
sense_len = 0;
done = scsi_eval_cmd_outcome(d, c, fp, c->sense, sense_len,
start_time, timeout_ms, i, 0);
if (d->cancel)
done = 1;
} /* end of retry-loop */
return 1;
}
/** Tries to obtain SCSI address parameters.
@return 1 is success , 0 is failure
*/
int sg_obtain_scsi_adr(char *path, int *bus_no, int *host_no, int *channel_no,
int *target_no, int *lun_no)
{
int ret;
/* Try to guess from path */
if (strncmp("/dev/rdsk/", path, 10) == 0) {
ret = decode_btl_solaris(path + 10,
bus_no, target_no, lun_no, 0);
if (ret > 0) {
*host_no = *bus_no;
*channel_no = 0;
return 1;
}
}
*bus_no = *host_no = *channel_no = *target_no = *lun_no = -1;
/* >>> Could need a ioctl which gives SCSI numbers */;
return (0);
}
/** Tells wether a text is a persistent address as listed by the enumeration
functions.
*/
#ifndef NIX
int sg_is_enumerable_adr(char* path)
{
int ret;
int bus_no, target_no, lun_no;
struct stat stbuf;
if (strncmp("/dev/rdsk/", path, 10) != 0)
return 0;
ret = decode_btl_solaris(path + 10, &bus_no, &target_no, &lun_no, 0);
if (ret <= 0)
return 0;
if (stat(path, &stbuf) == -1)
return 0;
return 1;
}
#else /* ! NIX */
int sg_is_enumerable_adr(char* adr)
{
burn_drive_enumerator_t idx;
int initialize = 1, ret;
char buf[64];
while(1) {
ret = sg_give_next_adr(&idx, buf, sizeof(buf), initialize);
initialize = 0;
if (ret <= 0)
break;
if (strcmp(adr, buf) == 0) {
sg_give_next_adr(&idx, buf, sizeof(buf), -1);
return 1;
}
}
sg_give_next_adr(&idx, buf, sizeof(buf), -1);
return (0);
}
#endif /* NIX */
/* Return 1 if the given path leads to a regular file or a device that can be
fseeked, read, and possibly written with 2 kB granularity.
*/
int burn_os_is_2k_seekrw(char *path, int flag)
{
struct stat stbuf;
if (stat(path, &stbuf) == -1)
return 0;
if (S_ISREG(stbuf.st_mode))
return 1;
if (S_ISBLK(stbuf.st_mode))
return 1;
return 0;
}
/** Estimate the potential payload capacity of a file address.
@param path The address of the file to be examined. If it does not
exist yet, then the directory will be inquired.
@param bytes The pointed value gets modified, but only if an estimation is
possible.
@return -2 = cannot perform necessary operations on file object
-1 = neither path nor dirname of path exist
0 = could not estimate size capacity of file object
1 = estimation has been made, bytes was set
*/
int burn_os_stdio_capacity(char *path, off_t write_start, off_t *bytes)
{
struct stat stbuf;
int ret;
#ifdef Libburn_os_has_statvfS
struct statvfs vfsbuf;
#endif
char *testpath = NULL, *cpt;
off_t add_size = 0;
BURN_ALLOC_MEM(testpath, char, 4096);
testpath[0] = 0;
if (stat(path, &stbuf) == -1) {
strcpy(testpath, path);
cpt = strrchr(testpath, '/');
if(cpt == NULL)
strcpy(testpath, ".");
else if(cpt == testpath)
testpath[1] = 0;
else
*cpt = 0;
if (stat(testpath, &stbuf) == -1)
{ret = -1; goto ex;}
} else if(S_ISBLK(stbuf.st_mode)) {
int open_mode = O_RDONLY, fd;
fd = open(path, open_mode);
if (fd == -1)
{ret = -2; goto ex;}
*bytes = lseek(fd, 0, SEEK_END);
close(fd);
if (*bytes == -1) {
*bytes = 0;
{ret = 0; goto ex;}
}
} else if(S_ISREG(stbuf.st_mode)) {
add_size = burn_sparse_file_addsize(write_start, &stbuf);
strcpy(testpath, path);
} else
{ret = 0; goto ex;}
if (testpath[0]) {
#ifdef Libburn_os_has_statvfS
if (statvfs(testpath, &vfsbuf) == -1)
{ret = -2; goto ex;}
*bytes = add_size + ((off_t) vfsbuf.f_frsize) *
(off_t) vfsbuf.f_bavail;
#else /* Libburn_os_has_statvfS */
{ret = 0; goto ex;}
#endif /* ! Libburn_os_has_stavtfS */
}
ret = 1;
ex:;
BURN_FREE_MEM(testpath);
return ret;
}
/* ts A91122 : an interface to open(O_DIRECT) or similar OS tricks. */
#ifdef Libburn_read_o_direcT
/* No special O_DIRECT-like precautions are implemented here */
#endif /* Libburn_read_o_direcT */
int burn_os_open_track_src(char *path, int open_flags, int flag)
{
int fd;
fd = open(path, open_flags);
return fd;
}
void *burn_os_alloc_buffer(size_t amount, int flag)
{
void *buf = NULL;
buf = calloc(1, amount);
return buf;
}
int burn_os_free_buffer(void *buffer, size_t amount, int flag)
{
if (buffer == NULL)
return 0;
free(buffer);
return 1;
}