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mirror_smartmontools-debian/scsiprint.cpp
Giuseppe Iuculano 2127e1931e Imported Upstream version 5.38+svn2879
2009-08-30 18:43:15 +02:00

1733 lines
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/*
* scsiprint.cpp
*
* Home page of code is: http://smartmontools.sourceforge.net
*
* Copyright (C) 2002-9 Bruce Allen <smartmontools-support@lists.sourceforge.net>
* Copyright (C) 2000 Michael Cornwell <cornwell@acm.org>
*
* Additional SCSI work:
* Copyright (C) 2003-9 Douglas Gilbert <dougg@torque.net>
*
* 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, or (at your option)
* any later version.
*
* You should have received a copy of the GNU General Public License
* (for example COPYING); if not, write to the Free
* Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*
* This code was originally developed as a Senior Thesis by Michael Cornwell
* at the Concurrent Systems Laboratory (now part of the Storage Systems
* Research Center), Jack Baskin School of Engineering, University of
* California, Santa Cruz. http://ssrc.soe.ucsc.edu/
*
*/
#include <stdio.h>
#include <string.h>
#include <fcntl.h>
#include <errno.h>
#include "config.h"
#include "int64.h"
#include "extern.h"
#include "scsicmds.h"
#include "atacmds.h" // smart_command_set
#include "dev_interface.h"
#include "scsiprint.h"
#include "smartctl.h"
#include "utility.h"
#define GBUF_SIZE 65535
const char * scsiprint_c_cvsid = "$Id: scsiprint.cpp 2861 2009-07-24 16:47:03Z chrfranke $"
SCSIPRINT_H_CVSID;
// control block which points to external global control variables
extern smartmonctrl *con;
UINT8 gBuf[GBUF_SIZE];
#define LOG_RESP_LEN 252
#define LOG_RESP_LONG_LEN ((62 * 256) + 252)
#define LOG_RESP_TAPE_ALERT_LEN 0x144
/* Log pages supported */
static int gSmartLPage = 0; /* Informational Exceptions log page */
static int gTempLPage = 0;
static int gSelfTestLPage = 0;
static int gStartStopLPage = 0;
static int gReadECounterLPage = 0;
static int gWriteECounterLPage = 0;
static int gVerifyECounterLPage = 0;
static int gNonMediumELPage = 0;
static int gLastNErrorLPage = 0;
static int gBackgroundResultsLPage = 0;
static int gProtocolSpecificLPage = 0;
static int gTapeAlertsLPage = 0;
static int gSeagateCacheLPage = 0;
static int gSeagateFactoryLPage = 0;
/* Mode pages supported */
static int gIecMPage = 1; /* N.B. assume it until we know otherwise */
/* Remember last successful mode sense/select command */
static int modese_len = 0;
// Compares failure type to policy in effect, and either exits or
// simply returns to the calling routine.
extern void failuretest(int type, int returnvalue);
static void scsiGetSupportedLogPages(scsi_device * device)
{
int i, err;
if ((err = scsiLogSense(device, SUPPORTED_LPAGES, 0, gBuf,
LOG_RESP_LEN, 0))) {
if (con->reportscsiioctl > 0)
pout("Log Sense for supported pages failed [%s]\n",
scsiErrString(err));
return;
}
for (i = 4; i < gBuf[3] + LOGPAGEHDRSIZE; i++) {
switch (gBuf[i])
{
case READ_ERROR_COUNTER_LPAGE:
gReadECounterLPage = 1;
break;
case WRITE_ERROR_COUNTER_LPAGE:
gWriteECounterLPage = 1;
break;
case VERIFY_ERROR_COUNTER_LPAGE:
gVerifyECounterLPage = 1;
break;
case LAST_N_ERROR_LPAGE:
gLastNErrorLPage = 1;
break;
case NON_MEDIUM_ERROR_LPAGE:
gNonMediumELPage = 1;
break;
case TEMPERATURE_LPAGE:
gTempLPage = 1;
break;
case STARTSTOP_CYCLE_COUNTER_LPAGE:
gStartStopLPage = 1;
break;
case SELFTEST_RESULTS_LPAGE:
gSelfTestLPage = 1;
break;
case IE_LPAGE:
gSmartLPage = 1;
break;
case BACKGROUND_RESULTS_LPAGE:
gBackgroundResultsLPage = 1;
break;
case PROTOCOL_SPECIFIC_LPAGE:
gProtocolSpecificLPage = 1;
break;
case TAPE_ALERTS_LPAGE:
gTapeAlertsLPage = 1;
break;
case SEAGATE_CACHE_LPAGE:
gSeagateCacheLPage = 1;
break;
case SEAGATE_FACTORY_LPAGE:
gSeagateFactoryLPage = 1;
break;
default:
break;
}
}
}
/* Returns 0 if ok, -1 if can't check IE, -2 if can check and bad
(or at least something to report). */
static int scsiGetSmartData(scsi_device * device, bool attribs)
{
UINT8 asc;
UINT8 ascq;
UINT8 currenttemp = 0;
UINT8 triptemp = 0;
const char * cp;
int err = 0;
PRINT_ON(con);
if (scsiCheckIE(device, gSmartLPage, gTempLPage, &asc, &ascq,
&currenttemp, &triptemp)) {
/* error message already announced */
PRINT_OFF(con);
return -1;
}
PRINT_OFF(con);
cp = scsiGetIEString(asc, ascq);
if (cp) {
err = -2;
PRINT_ON(con);
pout("SMART Health Status: %s [asc=%x, ascq=%x]\n", cp, asc, ascq);
PRINT_OFF(con);
} else if (gIecMPage)
pout("SMART Health Status: OK\n");
if (attribs && !gTempLPage) {
if (currenttemp || triptemp)
pout("\n");
if (currenttemp) {
if (255 != currenttemp)
pout("Current Drive Temperature: %d C\n", currenttemp);
else
pout("Current Drive Temperature: <not available>\n");
}
if (triptemp)
pout("Drive Trip Temperature: %d C\n", triptemp);
}
return err;
}
// Returns number of logged errors or zero if none or -1 if fetching
// TapeAlerts fails
static const char * const severities = "CWI";
static int scsiGetTapeAlertsData(scsi_device * device, int peripheral_type)
{
unsigned short pagelength;
unsigned short parametercode;
int i, err;
const char *s;
const char *ts;
int failures = 0;
PRINT_ON(con);
if ((err = scsiLogSense(device, TAPE_ALERTS_LPAGE, 0, gBuf,
LOG_RESP_TAPE_ALERT_LEN, LOG_RESP_TAPE_ALERT_LEN))) {
pout("scsiGetTapesAlertData Failed [%s]\n", scsiErrString(err));
PRINT_OFF(con);
return -1;
}
if (gBuf[0] != 0x2e) {
pout("TapeAlerts Log Sense Failed\n");
PRINT_OFF(con);
return -1;
}
pagelength = (unsigned short) gBuf[2] << 8 | gBuf[3];
for (s=severities; *s; s++) {
for (i = 4; i < pagelength; i += 5) {
parametercode = (unsigned short) gBuf[i] << 8 | gBuf[i+1];
if (gBuf[i + 4]) {
ts = SCSI_PT_MEDIUM_CHANGER == peripheral_type ?
scsiTapeAlertsChangerDevice(parametercode) :
scsiTapeAlertsTapeDevice(parametercode);
if (*ts == *s) {
if (!failures)
pout("TapeAlert Errors (C=Critical, W=Warning, I=Informational):\n");
pout("[0x%02x] %s\n", parametercode, ts);
failures += 1;
}
}
}
}
PRINT_OFF(con);
if (! failures)
pout("TapeAlert: OK\n");
return failures;
}
static void scsiGetStartStopData(scsi_device * device)
{
UINT32 u;
int err, len, k, extra, pc;
unsigned char * ucp;
if ((err = scsiLogSense(device, STARTSTOP_CYCLE_COUNTER_LPAGE, 0, gBuf,
LOG_RESP_LEN, 0))) {
PRINT_ON(con);
pout("scsiGetStartStopData Failed [%s]\n", scsiErrString(err));
PRINT_OFF(con);
return;
}
if ((gBuf[0] & 0x3f) != STARTSTOP_CYCLE_COUNTER_LPAGE) {
PRINT_ON(con);
pout("StartStop Log Sense Failed, page mismatch\n");
PRINT_OFF(con);
return;
}
len = ((gBuf[2] << 8) | gBuf[3]);
ucp = gBuf + 4;
for (k = len; k > 0; k -= extra, ucp += extra) {
if (k < 3) {
PRINT_ON(con);
pout("StartStop Log Sense Failed: short\n");
PRINT_OFF(con);
return;
}
extra = ucp[3] + 4;
pc = (ucp[0] << 8) + ucp[1];
switch (pc) {
case 1:
if (10 == extra)
pout("Manufactured in week %.2s of year %.4s\n", ucp + 8,
ucp + 4);
break;
case 2:
/* ignore Accounting date */
break;
case 3:
if (extra > 7) {
u = (ucp[4] << 24) | (ucp[5] << 16) | (ucp[6] << 8) | ucp[7];
if (0xffffffff != u)
pout("Specified cycle count over device lifetime: %u\n",
u);
}
break;
case 4:
if (extra > 7) {
u = (ucp[4] << 24) | (ucp[5] << 16) | (ucp[6] << 8) | ucp[7];
if (0xffffffff != u)
pout("Accumulated start-stop cycles: %u\n", u);
}
break;
case 5:
if (extra > 7) {
u = (ucp[4] << 24) | (ucp[5] << 16) | (ucp[6] << 8) | ucp[7];
if (0xffffffff != u)
pout("Specified load-unload count over device "
"lifetime: %u\n", u);
}
break;
case 6:
if (extra > 7) {
u = (ucp[4] << 24) | (ucp[5] << 16) | (ucp[6] << 8) | ucp[7];
if (0xffffffff != u)
pout("Accumulated load-unload cycles: %u\n", u);
}
break;
default:
/* ignore */
break;
}
}
}
static void scsiPrintGrownDefectListLen(scsi_device * device)
{
int err, dl_format, dl_len, div;
memset(gBuf, 0, 4);
if ((err = scsiReadDefect10(device, 0 /* req_plist */, 1 /* req_glist */,
4 /* bytes from index */, gBuf, 4))) {
if (con->reportscsiioctl > 0) {
PRINT_ON(con);
pout("Read defect list (10) Failed: %s\n", scsiErrString(err));
PRINT_OFF(con);
}
return;
}
if (0x8 != (gBuf[1] & 0x18)) {
PRINT_ON(con);
pout("Read defect list: asked for grown list but didn't get it\n");
PRINT_OFF(con);
return;
}
div = 0;
dl_format = (gBuf[1] & 0x7);
switch (dl_format) {
case 0: /* short block */
div = 4;
break;
case 3: /* long block */
case 4: /* bytes from index */
case 5: /* physical sector */
div = 8;
break;
default:
PRINT_ON(con);
pout("defect list format %d unknown\n", dl_format);
PRINT_OFF(con);
break;
}
dl_len = (gBuf[2] << 8) + gBuf[3];
if (0 == dl_len)
pout("Elements in grown defect list: 0\n");
else {
if (0 == div)
pout("Grown defect list length=%d bytes [unknown "
"number of elements]\n", dl_len);
else
pout("Elements in grown defect list: %d\n", dl_len / div);
}
}
static void scsiPrintSeagateCacheLPage(scsi_device * device)
{
int k, j, num, pl, pc, err, len;
unsigned char * ucp;
unsigned char * xp;
uint64_t ull;
if ((err = scsiLogSense(device, SEAGATE_CACHE_LPAGE, 0, gBuf,
LOG_RESP_LEN, 0))) {
PRINT_ON(con);
pout("Seagate Cache Log Sense Failed: %s\n", scsiErrString(err));
PRINT_OFF(con);
return;
}
if ((gBuf[0] & 0x3f) != SEAGATE_CACHE_LPAGE) {
PRINT_ON(con);
pout("Seagate Cache Log Sense Failed, page mismatch\n");
PRINT_OFF(con);
return;
}
len = ((gBuf[2] << 8) | gBuf[3]) + 4;
num = len - 4;
ucp = &gBuf[0] + 4;
while (num > 3) {
pc = (ucp[0] << 8) | ucp[1];
pl = ucp[3] + 4;
switch (pc) {
case 0: case 1: case 2: case 3: case 4:
break;
default:
if (con->reportscsiioctl > 0) {
PRINT_ON(con);
pout("Vendor (Seagate) cache lpage has unexpected parameter"
", skip\n");
PRINT_OFF(con);
}
return;
}
num -= pl;
ucp += pl;
}
pout("Vendor (Seagate) cache information\n");
num = len - 4;
ucp = &gBuf[0] + 4;
while (num > 3) {
pc = (ucp[0] << 8) | ucp[1];
pl = ucp[3] + 4;
switch (pc) {
case 0: pout(" Blocks sent to initiator"); break;
case 1: pout(" Blocks received from initiator"); break;
case 2: pout(" Blocks read from cache and sent to initiator"); break;
case 3: pout(" Number of read and write commands whose size "
"<= segment size"); break;
case 4: pout(" Number of read and write commands whose size "
"> segment size"); break;
default: pout(" Unknown Seagate parameter code [0x%x]", pc); break;
}
k = pl - 4;
xp = ucp + 4;
if (k > (int)sizeof(ull)) {
xp += (k - (int)sizeof(ull));
k = (int)sizeof(ull);
}
ull = 0;
for (j = 0; j < k; ++j) {
if (j > 0)
ull <<= 8;
ull |= xp[j];
}
pout(" = %"PRIu64"\n", ull);
num -= pl;
ucp += pl;
}
}
static void scsiPrintSeagateFactoryLPage(scsi_device * device)
{
int k, j, num, pl, pc, len, err, good, bad;
unsigned char * ucp;
unsigned char * xp;
uint64_t ull;
if ((err = scsiLogSense(device, SEAGATE_FACTORY_LPAGE, 0, gBuf,
LOG_RESP_LEN, 0))) {
PRINT_ON(con);
pout("scsiPrintSeagateFactoryLPage Failed [%s]\n", scsiErrString(err));
PRINT_OFF(con);
return;
}
if ((gBuf[0] & 0x3f) != SEAGATE_FACTORY_LPAGE) {
PRINT_ON(con);
pout("Seagate/Hitachi Factory Log Sense Failed, page mismatch\n");
PRINT_OFF(con);
return;
}
len = ((gBuf[2] << 8) | gBuf[3]) + 4;
num = len - 4;
ucp = &gBuf[0] + 4;
good = 0;
bad = 0;
while (num > 3) {
pc = (ucp[0] << 8) | ucp[1];
pl = ucp[3] + 4;
switch (pc) {
case 0: case 8:
++good;
break;
default:
++bad;
break;
}
num -= pl;
ucp += pl;
}
if ((good < 2) || (bad > 4)) { /* heuristic */
if (con->reportscsiioctl > 0) {
PRINT_ON(con);
pout("\nVendor (Seagate/Hitachi) factory lpage has too many "
"unexpected parameters, skip\n");
PRINT_OFF(con);
}
return;
}
pout("Vendor (Seagate/Hitachi) factory information\n");
num = len - 4;
ucp = &gBuf[0] + 4;
while (num > 3) {
pc = (ucp[0] << 8) | ucp[1];
pl = ucp[3] + 4;
good = 0;
switch (pc) {
case 0: pout(" number of hours powered up");
good = 1;
break;
case 8: pout(" number of minutes until next internal SMART test");
good = 1;
break;
default:
if (con->reportscsiioctl > 0) {
PRINT_ON(con);
pout("Vendor (Seagate/Hitachi) factory lpage: "
"unknown parameter code [0x%x]\n", pc);
PRINT_OFF(con);
}
break;
}
if (good) {
k = pl - 4;
xp = ucp + 4;
if (k > (int)sizeof(ull)) {
xp += (k - (int)sizeof(ull));
k = (int)sizeof(ull);
}
ull = 0;
for (j = 0; j < k; ++j) {
if (j > 0)
ull <<= 8;
ull |= xp[j];
}
if (0 == pc)
pout(" = %.2f\n", uint64_to_double(ull) / 60.0 );
else
pout(" = %"PRIu64"\n", ull);
}
num -= pl;
ucp += pl;
}
}
static void scsiPrintErrorCounterLog(scsi_device * device)
{
struct scsiErrorCounter errCounterArr[3];
struct scsiErrorCounter * ecp;
struct scsiNonMediumError nme;
int found[3] = {0, 0, 0};
const char * pageNames[3] = {"read: ", "write: ", "verify: "};
int k;
double processed_gb;
if (gReadECounterLPage && (0 == scsiLogSense(device,
READ_ERROR_COUNTER_LPAGE, 0, gBuf, LOG_RESP_LEN, 0))) {
scsiDecodeErrCounterPage(gBuf, &errCounterArr[0]);
found[0] = 1;
}
if (gWriteECounterLPage && (0 == scsiLogSense(device,
WRITE_ERROR_COUNTER_LPAGE, 0, gBuf, LOG_RESP_LEN, 0))) {
scsiDecodeErrCounterPage(gBuf, &errCounterArr[1]);
found[1] = 1;
}
if (gVerifyECounterLPage && (0 == scsiLogSense(device,
VERIFY_ERROR_COUNTER_LPAGE, 0, gBuf, LOG_RESP_LEN, 0))) {
scsiDecodeErrCounterPage(gBuf, &errCounterArr[2]);
ecp = &errCounterArr[2];
for (k = 0; k < 7; ++k) {
if (ecp->gotPC[k] && ecp->counter[k]) {
found[2] = 1;
break;
}
}
}
if (found[0] || found[1] || found[2]) {
pout("\nError counter log:\n");
pout(" Errors Corrected by Total "
"Correction Gigabytes Total\n");
pout(" ECC rereads/ errors "
"algorithm processed uncorrected\n");
pout(" fast | delayed rewrites corrected "
"invocations [10^9 bytes] errors\n");
for (k = 0; k < 3; ++k) {
if (! found[k])
continue;
ecp = &errCounterArr[k];
pout("%s%8"PRIu64" %8"PRIu64" %8"PRIu64" %8"PRIu64" %8"PRIu64,
pageNames[k], ecp->counter[0], ecp->counter[1],
ecp->counter[2], ecp->counter[3], ecp->counter[4]);
processed_gb = uint64_to_double(ecp->counter[5]) / 1000000000.0;
pout(" %12.3f %8"PRIu64"\n", processed_gb, ecp->counter[6]);
}
}
else
pout("\nError Counter logging not supported\n");
if (gNonMediumELPage && (0 == scsiLogSense(device,
NON_MEDIUM_ERROR_LPAGE, 0, gBuf, LOG_RESP_LEN, 0))) {
scsiDecodeNonMediumErrPage(gBuf, &nme);
if (nme.gotPC0)
pout("\nNon-medium error count: %8"PRIu64"\n", nme.counterPC0);
if (nme.gotTFE_H)
pout("Track following error count [Hitachi]: %8"PRIu64"\n",
nme.counterTFE_H);
if (nme.gotPE_H)
pout("Positioning error count [Hitachi]: %8"PRIu64"\n",
nme.counterPE_H);
}
if (gLastNErrorLPage && (0 == scsiLogSense(device,
LAST_N_ERROR_LPAGE, 0, gBuf, LOG_RESP_LONG_LEN, 0))) {
unsigned char * ucp;
int num, k, pc, pl, truncated;
num = (gBuf[2] << 8) + gBuf[3] + 4;
truncated = (num > LOG_RESP_LONG_LEN) ? num : 0;
if (truncated)
num = LOG_RESP_LONG_LEN;
ucp = gBuf + 4;
num -= 4;
if (num < 4)
pout("\nNo error events logged\n");
else {
pout("\nLast n error events log page\n");
for (k = num; k > 0; k -= pl, ucp += pl) {
if (k < 3) {
pout(" <<short Last n error events log page>>\n");
break;
}
pl = ucp[3] + 4;
pc = (ucp[0] << 8) + ucp[1];
if (pl > 4) {
if ((ucp[2] & 0x1) && (ucp[2] & 0x2)) {
pout(" Error event %d:\n", pc);
pout(" [binary]:\n");
dStrHex((const char *)ucp + 4, pl - 4, 1);
} else if (ucp[2] & 0x1) {
pout(" Error event %d:\n", pc);
pout(" %.*s\n", pl - 4, (const char *)(ucp + 4));
} else {
if (con->reportscsiioctl > 0) {
pout(" Error event %d:\n", pc);
pout(" [data counter??]:\n");
dStrHex((const char *)ucp + 4, pl - 4, 1);
}
}
}
}
if (truncated)
pout(" >>>> log truncated, fetched %d of %d available "
"bytes\n", LOG_RESP_LONG_LEN, truncated);
}
}
}
static const char * self_test_code[] = {
"Default ",
"Background short",
"Background long ",
"Reserved(3) ",
"Abort background",
"Foreground short",
"Foreground long ",
"Reserved(7) "
};
static const char * self_test_result[] = {
"Completed ",
"Aborted (by user command)",
"Aborted (device reset ?) ",
"Unknown error, incomplete",
"Completed, segment failed",
"Failed in first segment ",
"Failed in second segment ",
"Failed in segment --> ",
"Reserved(8) ",
"Reserved(9) ",
"Reserved(10) ",
"Reserved(11) ",
"Reserved(12) ",
"Reserved(13) ",
"Reserved(14) ",
"Self test in progress ..."
};
// See SCSI Primary Commands - 3 (SPC-3) rev 23 (draft) section 7.2.10 .
// Returns 0 if ok else FAIL* bitmask. Note that if any of the most recent
// 20 self tests fail (result code 3 to 7 inclusive) then FAILLOG and/or
// FAILSMART is returned.
static int scsiPrintSelfTest(scsi_device * device)
{
int num, k, n, res, err, durationSec;
int noheader = 1;
int retval = 0;
UINT8 * ucp;
uint64_t ull=0;
if ((err = scsiLogSense(device, SELFTEST_RESULTS_LPAGE, 0, gBuf,
LOG_RESP_SELF_TEST_LEN, 0))) {
PRINT_ON(con);
pout("scsiPrintSelfTest Failed [%s]\n", scsiErrString(err));
PRINT_OFF(con);
return FAILSMART;
}
if ((gBuf[0] & 0x3f) != SELFTEST_RESULTS_LPAGE) {
PRINT_ON(con);
pout("Self-test Log Sense Failed, page mismatch\n");
PRINT_OFF(con);
return FAILSMART;
}
// compute page length
num = (gBuf[2] << 8) + gBuf[3];
// Log sense page length 0x190 bytes
if (num != 0x190) {
PRINT_ON(con);
pout("Self-test Log Sense length is 0x%x not 0x190 bytes\n",num);
PRINT_OFF(con);
return FAILSMART;
}
// loop through the twenty possible entries
for (k = 0, ucp = gBuf + 4; k < 20; ++k, ucp += 20 ) {
int i;
// timestamp in power-on hours (or zero if test in progress)
n = (ucp[6] << 8) | ucp[7];
// The spec says "all 20 bytes will be zero if no test" but
// DG has found otherwise. So this is a heuristic.
if ((0 == n) && (0 == ucp[4]))
break;
// only print header if needed
if (noheader) {
pout("\nSMART Self-test log\n");
pout("Num Test Status segment "
"LifeTime LBA_first_err [SK ASC ASQ]\n");
pout(" Description number "
"(hours)\n");
noheader=0;
}
// print parameter code (test number) & self-test code text
pout("#%2d %s", (ucp[0] << 8) | ucp[1],
self_test_code[(ucp[4] >> 5) & 0x7]);
// check the self-test result nibble, using the self-test results
// field table from T10/1416-D (SPC-3) Rev. 23, section 7.2.10:
switch ((res = ucp[4] & 0xf)) {
case 0x3:
// an unknown error occurred while the device server
// was processing the self-test and the device server
// was unable to complete the self-test
retval|=FAILSMART;
break;
case 0x4:
// the self-test completed with a failure in a test
// segment, and the test segment that failed is not
// known
retval|=FAILLOG;
break;
case 0x5:
// the first segment of the self-test failed
retval|=FAILLOG;
break;
case 0x6:
// the second segment of the self-test failed
retval|=FAILLOG;
break;
case 0x7:
// another segment of the self-test failed and which
// test is indicated by the contents of the SELF-TEST
// NUMBER field
retval|=FAILLOG;
break;
default:
break;
}
pout(" %s", self_test_result[res]);
// self-test number identifies test that failed and consists
// of either the number of the segment that failed during
// the test, or the number of the test that failed and the
// number of the segment in which the test was run, using a
// vendor-specific method of putting both numbers into a
// single byte.
if (ucp[5])
pout(" %3d", (int)ucp[5]);
else
pout(" -");
// print time that the self-test was completed
if (n==0 && res==0xf)
// self-test in progress
pout(" NOW");
else
pout(" %5d", n);
// construct 8-byte integer address of first failure
for (i = 0; i < 8; i++) {
ull <<= 8;
ull |= ucp[i+8];
}
// print Address of First Failure, if sensible
if ((~(uint64_t)0 != ull) && (res > 0) && (res < 0xf)) {
char buff[32];
// was hex but change to decimal to conform with ATA
snprintf(buff, sizeof(buff), "%"PRIu64, ull);
// snprintf(buff, sizeof(buff), "0x%"PRIx64, ull);
pout("%18s", buff);
} else
pout(" -");
// if sense key nonzero, then print it, along with
// additional sense code and additional sense code qualifier
if (ucp[16] & 0xf)
pout(" [0x%x 0x%x 0x%x]\n", ucp[16] & 0xf, ucp[17], ucp[18]);
else
pout(" [- - -]\n");
}
// if header never printed, then there was no output
if (noheader)
pout("No self-tests have been logged\n");
else
pout("\n");
if ((0 == scsiFetchExtendedSelfTestTime(device, &durationSec,
modese_len)) && (durationSec > 0)) {
pout("Long (extended) Self Test duration: %d seconds "
"[%.1f minutes]\n", durationSec, durationSec / 60.0);
}
return retval;
}
static const char * bms_status[] = {
"no scans active",
"scan is active",
"pre-scan is active",
"halted due to fatal error",
"halted due to a vendor specific pattern of error",
"halted due to medium formatted without P-List",
"halted - vendor specific cause",
"halted due to temperature out of range",
"waiting until BMS interval timer expires", /* 8 */
};
static const char * reassign_status[] = {
"Reserved [0x0]",
"Require Write or Reassign Blocks command",
"Successfully reassigned",
"Reserved [0x3]",
"Reassignment by disk failed",
"Recovered via rewrite in-place",
"Reassigned by app, has valid data",
"Reassigned by app, has no valid data",
"Unsuccessfully reassigned by app", /* 8 */
};
// See SCSI Block Commands - 3 (SBC-3) rev 6 (draft) section 6.2.2 .
// Returns 0 if ok else FAIL* bitmask. Note can have a status entry
// and up to 2048 events (although would hope to have less). May set
// FAILLOG if serious errors detected (in the future).
static int scsiPrintBackgroundResults(scsi_device * device)
{
int num, j, m, err, pc, pl, truncated;
int noheader = 1;
int firstresult = 1;
int retval = 0;
UINT8 * ucp;
if ((err = scsiLogSense(device, BACKGROUND_RESULTS_LPAGE, 0, gBuf,
LOG_RESP_LONG_LEN, 0))) {
PRINT_ON(con);
pout("scsiPrintBackgroundResults Failed [%s]\n", scsiErrString(err));
PRINT_OFF(con);
return FAILSMART;
}
if ((gBuf[0] & 0x3f) != BACKGROUND_RESULTS_LPAGE) {
PRINT_ON(con);
pout("Background scan results Log Sense Failed, page mismatch\n");
PRINT_OFF(con);
return FAILSMART;
}
// compute page length
num = (gBuf[2] << 8) + gBuf[3] + 4;
if (num < 20) {
PRINT_ON(con);
pout("Background scan results Log Sense length is %d, no scan "
"status\n", num);
PRINT_OFF(con);
return FAILSMART;
}
truncated = (num > LOG_RESP_LONG_LEN) ? num : 0;
if (truncated)
num = LOG_RESP_LONG_LEN;
ucp = gBuf + 4;
num -= 4;
while (num > 3) {
pc = (ucp[0] << 8) | ucp[1];
// pcb = ucp[2];
pl = ucp[3] + 4;
switch (pc) {
case 0:
if (noheader) {
noheader = 0;
pout("\nBackground scan results log\n");
}
pout(" Status: ");
if ((pl < 16) || (num < 16)) {
pout("\n");
break;
}
j = ucp[9];
if (j < (int)(sizeof(bms_status) / sizeof(bms_status[0])))
pout("%s\n", bms_status[j]);
else
pout("unknown [0x%x] background scan status value\n", j);
j = (ucp[4] << 24) + (ucp[5] << 16) + (ucp[6] << 8) + ucp[7];
pout(" Accumulated power on time, hours:minutes %d:%02d "
"[%d minutes]\n", (j / 60), (j % 60), j);
pout(" Number of background scans performed: %d, ",
(ucp[10] << 8) + ucp[11]);
pout("scan progress: %.2f%%\n",
(double)((ucp[12] << 8) + ucp[13]) * 100.0 / 65536.0);
pout(" Number of background medium scans performed: %d\n",
(ucp[14] << 8) + ucp[15]);
break;
default:
if (noheader) {
noheader = 0;
pout("\nBackground scan results log\n");
}
if (firstresult) {
firstresult = 0;
pout("\n # when lba(hex) [sk,asc,ascq] "
"reassign_status\n");
}
pout(" %3d ", pc);
if ((pl < 24) || (num < 24)) {
if (pl < 24)
pout("parameter length >= 24 expected, got %d\n", pl);
break;
}
j = (ucp[4] << 24) + (ucp[5] << 16) + (ucp[6] << 8) + ucp[7];
pout("%4d:%02d ", (j / 60), (j % 60));
for (m = 0; m < 8; ++m)
pout("%02x", ucp[16 + m]);
pout(" [%x,%x,%x] ", ucp[8] & 0xf, ucp[9], ucp[10]);
j = (ucp[8] >> 4) & 0xf;
if (j <
(int)(sizeof(reassign_status) / sizeof(reassign_status[0])))
pout("%s\n", reassign_status[j]);
else
pout("Reassign status: reserved [0x%x]\n", j);
break;
}
num -= pl;
ucp += pl;
}
if (truncated)
pout(" >>>> log truncated, fetched %d of %d available "
"bytes\n", LOG_RESP_LONG_LEN, truncated);
return retval;
}
static void show_sas_phy_event_info(int peis, unsigned int val,
unsigned thresh_val)
{
unsigned int u;
switch (peis) {
case 0:
pout(" No event\n");
break;
case 0x1:
pout(" Invalid word count: %u\n", val);
break;
case 0x2:
pout(" Running disparity error count: %u\n", val);
break;
case 0x3:
pout(" Loss of dword synchronization count: %u\n", val);
break;
case 0x4:
pout(" Phy reset problem count: %u\n", val);
break;
case 0x5:
pout(" Elasticity buffer overflow count: %u\n", val);
break;
case 0x6:
pout(" Received ERROR count: %u\n", val);
break;
case 0x20:
pout(" Received address frame error count: %u\n", val);
break;
case 0x21:
pout(" Transmitted abandon-class OPEN_REJECT count: %u\n", val);
break;
case 0x22:
pout(" Received abandon-class OPEN_REJECT count: %u\n", val);
break;
case 0x23:
pout(" Transmitted retry-class OPEN_REJECT count: %u\n", val);
break;
case 0x24:
pout(" Received retry-class OPEN_REJECT count: %u\n", val);
break;
case 0x25:
pout(" Received AIP (WATING ON PARTIAL) count: %u\n", val);
break;
case 0x26:
pout(" Received AIP (WAITING ON CONNECTION) count: %u\n", val);
break;
case 0x27:
pout(" Transmitted BREAK count: %u\n", val);
break;
case 0x28:
pout(" Received BREAK count: %u\n", val);
break;
case 0x29:
pout(" Break timeout count: %u\n", val);
break;
case 0x2a:
pout(" Connection count: %u\n", val);
break;
case 0x2b:
pout(" Peak transmitted pathway blocked count: %u\n",
val & 0xff);
pout(" Peak value detector threshold: %u\n",
thresh_val & 0xff);
break;
case 0x2c:
u = val & 0xffff;
if (u < 0x8000)
pout(" Peak transmitted arbitration wait time (us): "
"%u\n", u);
else
pout(" Peak transmitted arbitration wait time (ms): "
"%u\n", 33 + (u - 0x8000));
u = thresh_val & 0xffff;
if (u < 0x8000)
pout(" Peak value detector threshold (us): %u\n",
u);
else
pout(" Peak value detector threshold (ms): %u\n",
33 + (u - 0x8000));
break;
case 0x2d:
pout(" Peak arbitration time (us): %u\n", val);
pout(" Peak value detector threshold: %u\n", thresh_val);
break;
case 0x2e:
pout(" Peak connection time (us): %u\n", val);
pout(" Peak value detector threshold: %u\n", thresh_val);
break;
case 0x40:
pout(" Transmitted SSP frame count: %u\n", val);
break;
case 0x41:
pout(" Received SSP frame count: %u\n", val);
break;
case 0x42:
pout(" Transmitted SSP frame error count: %u\n", val);
break;
case 0x43:
pout(" Received SSP frame error count: %u\n", val);
break;
case 0x44:
pout(" Transmitted CREDIT_BLOCKED count: %u\n", val);
break;
case 0x45:
pout(" Received CREDIT_BLOCKED count: %u\n", val);
break;
case 0x50:
pout(" Transmitted SATA frame count: %u\n", val);
break;
case 0x51:
pout(" Received SATA frame count: %u\n", val);
break;
case 0x52:
pout(" SATA flow control buffer overflow count: %u\n", val);
break;
case 0x60:
pout(" Transmitted SMP frame count: %u\n", val);
break;
case 0x61:
pout(" Received SMP frame count: %u\n", val);
break;
case 0x63:
pout(" Received SMP frame error count: %u\n", val);
break;
default:
break;
}
}
static void show_sas_port_param(unsigned char * ucp, int param_len)
{
int j, m, n, nphys, pcb, t, sz, spld_len;
unsigned char * vcp;
uint64_t ull;
unsigned int ui;
char s[64];
sz = sizeof(s);
pcb = ucp[2];
t = (ucp[0] << 8) | ucp[1];
pout("relative target port id = %d\n", t);
pout(" generation code = %d\n", ucp[6]);
nphys = ucp[7];
pout(" number of phys = %d\n", nphys);
for (j = 0, vcp = ucp + 8; j < (param_len - 8);
vcp += spld_len, j += spld_len) {
pout(" phy identifier = %d\n", vcp[1]);
spld_len = vcp[3];
if (spld_len < 44)
spld_len = 48; /* in SAS-1 and SAS-1.1 vcp[3]==0 */
else
spld_len += 4;
t = ((0x70 & vcp[4]) >> 4);
switch (t) {
case 0: snprintf(s, sz, "no device attached"); break;
case 1: snprintf(s, sz, "end device"); break;
case 2: snprintf(s, sz, "expander device"); break;
case 3: snprintf(s, sz, "expander device (fanout)"); break;
default: snprintf(s, sz, "reserved [%d]", t); break;
}
pout(" attached device type: %s\n", s);
t = 0xf & vcp[4];
switch (t) {
case 0: snprintf(s, sz, "unknown"); break;
case 1: snprintf(s, sz, "power on"); break;
case 2: snprintf(s, sz, "hard reset"); break;
case 3: snprintf(s, sz, "SMP phy control function"); break;
case 4: snprintf(s, sz, "loss of dword synchronization"); break;
case 5: snprintf(s, sz, "mux mix up"); break;
case 6: snprintf(s, sz, "I_T nexus loss timeout for STP/SATA");
break;
case 7: snprintf(s, sz, "break timeout timer expired"); break;
case 8: snprintf(s, sz, "phy test function stopped"); break;
case 9: snprintf(s, sz, "expander device reduced functionality");
break;
default: snprintf(s, sz, "reserved [0x%x]", t); break;
}
pout(" attached reason: %s\n", s);
t = (vcp[5] & 0xf0) >> 4;
switch (t) {
case 0: snprintf(s, sz, "unknown"); break;
case 1: snprintf(s, sz, "power on"); break;
case 2: snprintf(s, sz, "hard reset"); break;
case 3: snprintf(s, sz, "SMP phy control function"); break;
case 4: snprintf(s, sz, "loss of dword synchronization"); break;
case 5: snprintf(s, sz, "mux mix up"); break;
case 6: snprintf(s, sz, "I_T nexus loss timeout for STP/SATA");
break;
case 7: snprintf(s, sz, "break timeout timer expired"); break;
case 8: snprintf(s, sz, "phy test function stopped"); break;
case 9: snprintf(s, sz, "expander device reduced functionality");
break;
default: snprintf(s, sz, "reserved [0x%x]", t); break;
}
pout(" reason: %s\n", s);
t = (0xf & vcp[5]);
switch (t) {
case 0: snprintf(s, sz, "phy enabled; unknown");
break;
case 1: snprintf(s, sz, "phy disabled"); break;
case 2: snprintf(s, sz, "phy enabled; speed negotiation failed");
break;
case 3: snprintf(s, sz, "phy enabled; SATA spinup hold state");
break;
case 4: snprintf(s, sz, "phy enabled; port selector");
break;
case 5: snprintf(s, sz, "phy enabled; reset in progress");
break;
case 6: snprintf(s, sz, "phy enabled; unsupported phy attached");
break;
case 8: snprintf(s, sz, "phy enabled; 1.5 Gbps"); break;
case 9: snprintf(s, sz, "phy enabled; 3 Gbps"); break;
case 0xa: snprintf(s, sz, "phy enabled; 6 Gbps"); break;
default: snprintf(s, sz, "reserved [%d]", t); break;
}
pout(" negotiated logical link rate: %s\n", s);
pout(" attached initiator port: ssp=%d stp=%d smp=%d\n",
!! (vcp[6] & 8), !! (vcp[6] & 4), !! (vcp[6] & 2));
pout(" attached target port: ssp=%d stp=%d smp=%d\n",
!! (vcp[7] & 8), !! (vcp[7] & 4), !! (vcp[7] & 2));
for (n = 0, ull = vcp[8]; n < 8; ++n) {
ull <<= 8; ull |= vcp[8 + n];
}
pout(" SAS address = 0x%" PRIx64 "\n", ull);
for (n = 0, ull = vcp[16]; n < 8; ++n) {
ull <<= 8; ull |= vcp[16 + n];
}
pout(" attached SAS address = 0x%" PRIx64 "\n", ull);
pout(" attached phy identifier = %d\n", vcp[24]);
ui = (vcp[32] << 24) | (vcp[33] << 16) | (vcp[34] << 8) | vcp[35];
pout(" Invalid DWORD count = %u\n", ui);
ui = (vcp[36] << 24) | (vcp[37] << 16) | (vcp[38] << 8) | vcp[39];
pout(" Running disparity error count = %u\n", ui);
ui = (vcp[40] << 24) | (vcp[41] << 16) | (vcp[42] << 8) | vcp[43];
pout(" Loss of DWORD synchronization = %u\n", ui);
ui = (vcp[44] << 24) | (vcp[45] << 16) | (vcp[46] << 8) | vcp[47];
pout(" Phy reset problem = %u\n", ui);
if (spld_len > 51) {
int num_ped, peis;
unsigned char * xcp;
unsigned int pvdt;
num_ped = vcp[51];
if (num_ped > 0)
pout(" Phy event descriptors:\n");
xcp = vcp + 52;
for (m = 0; m < (num_ped * 12); m += 12, xcp += 12) {
peis = xcp[3];
ui = (xcp[4] << 24) | (xcp[5] << 16) | (xcp[6] << 8) |
xcp[7];
pvdt = (xcp[8] << 24) | (xcp[9] << 16) | (xcp[10] << 8) |
xcp[11];
show_sas_phy_event_info(peis, ui, pvdt);
}
}
}
}
// Returns 1 if okay, 0 if non SAS descriptors
static int show_protocol_specific_page(unsigned char * resp, int len)
{
int k, num, param_len;
unsigned char * ucp;
num = len - 4;
for (k = 0, ucp = resp + 4; k < num; ) {
param_len = ucp[3] + 4;
if (6 != (0xf & ucp[4]))
return 0; /* only decode SAS log page */
if (0 == k)
pout("Protocol Specific port log page for SAS SSP\n");
show_sas_port_param(ucp, param_len);
k += param_len;
ucp += param_len;
}
return 1;
}
// See Serial Attached SCSI (SAS-2) (e.g. revision 16) the Protocol Specific
// log pageSerial Attached SCSI (SAS-2) (e.g. revision 16) the Protocol
// Specific log page.
// Returns 0 if ok else FAIL* bitmask. Note that if any of the most recent
// 20 self tests fail (result code 3 to 7 inclusive) then FAILLOG and/or
// FAILSMART is returned.
static int scsiPrintSasPhy(scsi_device * device, int reset)
{
int num, err;
if ((err = scsiLogSense(device, PROTOCOL_SPECIFIC_LPAGE, 0, gBuf,
LOG_RESP_LONG_LEN, 0))) {
PRINT_ON(con);
pout("scsiPrintSasPhy Log Sense Failed [%s]\n", scsiErrString(err));
PRINT_OFF(con);
return FAILSMART;
}
if ((gBuf[0] & 0x3f) != PROTOCOL_SPECIFIC_LPAGE) {
PRINT_ON(con);
pout("Protocol specific Log Sense Failed, page mismatch\n");
PRINT_OFF(con);
return FAILSMART;
}
// compute page length
num = (gBuf[2] << 8) + gBuf[3];
if (1 != show_protocol_specific_page(gBuf, num + 4)) {
PRINT_ON(con);
pout("Only support protocol specific log page on SAS devices\n");
PRINT_OFF(con);
return FAILSMART;
}
if (reset) {
if ((err = scsiLogSelect(device, 1 /* pcr */, 0 /* sp */, 0 /* pc */,
PROTOCOL_SPECIFIC_LPAGE, 0, NULL, 0))) {
PRINT_ON(con);
pout("scsiPrintSasPhy Log Select (reset) Failed [%s]\n",
scsiErrString(err));
PRINT_OFF(con);
return FAILSMART;
}
}
return 0;
}
static const char * peripheral_dt_arr[] = {
"disk",
"tape",
"printer",
"processor",
"optical disk(4)",
"CD/DVD",
"scanner",
"optical disk(7)",
"medium changer",
"communications",
"graphics(10)",
"graphics(11)",
"storage array",
"enclosure",
"simplified disk",
"optical card reader"
};
static const char * transport_proto_arr[] = {
"Fibre channel (FCP-2)",
"Parallel SCSI (SPI-4)",
"SSA",
"IEEE 1394 (SBP-2)",
"RDMA (SRP)",
"iSCSI",
"SAS",
"ADT",
"0x8",
"0x9",
"0xa",
"0xb",
"0xc",
"0xd",
"0xe",
"0xf"
};
/* Returns 0 on success, 1 on general error and 2 for early, clean exit */
static int scsiGetDriveInfo(scsi_device * device, UINT8 * peripheral_type, bool all)
{
char manufacturer[9];
char product[17];
char revision[5];
char timedatetz[DATEANDEPOCHLEN];
struct scsi_iec_mode_page iec;
int err, iec_err, len, req_len, avail_len, val;
int is_tape = 0;
int peri_dt = 0;
int returnval=0;
memset(gBuf, 0, 96);
req_len = 36;
if ((err = scsiStdInquiry(device, gBuf, req_len))) {
PRINT_ON(con);
pout("Standard Inquiry (36 bytes) failed [%s]\n", scsiErrString(err));
pout("Retrying with a 64 byte Standard Inquiry\n");
PRINT_OFF(con);
/* Marvell controllers fail on a 36 bytes StdInquiry, but 64 suffices */
req_len = 64;
if ((err = scsiStdInquiry(device, gBuf, req_len))) {
PRINT_ON(con);
pout("Standard Inquiry (64 bytes) failed [%s]\n",
scsiErrString(err));
PRINT_OFF(con);
return 1;
}
}
avail_len = gBuf[4] + 5;
len = (avail_len < req_len) ? avail_len : req_len;
peri_dt = gBuf[0] & 0x1f;
if (peripheral_type)
*peripheral_type = peri_dt;
if (len < 36) {
PRINT_ON(con);
pout("Short INQUIRY response, skip product id\n");
PRINT_OFF(con);
return 1;
}
memset(manufacturer, 0, sizeof(manufacturer));
strncpy(manufacturer, (char *)&gBuf[8], 8);
memset(product, 0, sizeof(product));
strncpy(product, (char *)&gBuf[16], 16);
memset(revision, 0, sizeof(revision));
strncpy(revision, (char *)&gBuf[32], 4);
if (all && (0 != strncmp(manufacturer, "ATA", 3)))
pout("Device: %s %s Version: %s\n", manufacturer, product, revision);
if (!*device->get_req_type()/*no type requested*/ &&
(0 == strncmp(manufacturer, "ATA", 3))) {
pout("\nProbable ATA device behind a SAT layer\n"
"Try an additional '-d ata' or '-d sat' argument.\n");
return 2;
}
if (! all)
return 0;
/* Do this here to try and detect badly conforming devices (some USB
keys) that will lock up on a InquiryVpd or log sense or ... */
if ((iec_err = scsiFetchIECmpage(device, &iec, modese_len))) {
if (SIMPLE_ERR_BAD_RESP == iec_err) {
pout(">> Terminate command early due to bad response to IEC "
"mode page\n");
PRINT_OFF(con);
gIecMPage = 0;
return 1;
}
} else
modese_len = iec.modese_len;
if (!con->dont_print_serial) {
if (0 == (err = scsiInquiryVpd(device, 0x80, gBuf, 64))) {
/* should use VPD page 0x83 and fall back to this page (0x80)
* if 0x83 not supported. NAA requires a lot of decoding code */
len = gBuf[3];
gBuf[4 + len] = '\0';
pout("Serial number: %s\n", &gBuf[4]);
}
else if (con->reportscsiioctl > 0) {
PRINT_ON(con);
if (SIMPLE_ERR_BAD_RESP == err)
pout("Vital Product Data (VPD) bit ignored in INQUIRY\n");
else
pout("Vital Product Data (VPD) INQUIRY failed [%d]\n", err);
PRINT_OFF(con);
}
}
// print SCSI peripheral device type
if (peri_dt < (int)(sizeof(peripheral_dt_arr) /
sizeof(peripheral_dt_arr[0])))
pout("Device type: %s\n", peripheral_dt_arr[peri_dt]);
else
pout("Device type: <%d>\n", peri_dt);
// See if transport protocol is known
val = scsiFetchTransportProtocol(device, modese_len);
if ((val >= 0) && (val <= 0xf))
pout("Transport protocol: %s\n", transport_proto_arr[val]);
// print current time and date and timezone
dateandtimezone(timedatetz);
pout("Local Time is: %s\n", timedatetz);
if ((SCSI_PT_SEQUENTIAL_ACCESS == *peripheral_type) ||
(SCSI_PT_MEDIUM_CHANGER == *peripheral_type))
is_tape = 1;
// See if unit accepts SCSI commmands from us
if ((err = scsiTestUnitReady(device))) {
if (SIMPLE_ERR_NOT_READY == err) {
PRINT_ON(con);
if (!is_tape)
pout("device is NOT READY (e.g. spun down, busy)\n");
else
pout("device is NOT READY (e.g. no tape)\n");
PRINT_OFF(con);
} else if (SIMPLE_ERR_NO_MEDIUM == err) {
PRINT_ON(con);
pout("NO MEDIUM present on device\n");
PRINT_OFF(con);
} else if (SIMPLE_ERR_BECOMING_READY == err) {
PRINT_ON(con);
pout("device becoming ready (wait)\n");
PRINT_OFF(con);
} else {
PRINT_ON(con);
pout("device Test Unit Ready [%s]\n", scsiErrString(err));
PRINT_OFF(con);
}
failuretest(MANDATORY_CMD, returnval|=FAILID);
}
if (iec_err) {
if (!is_tape) {
PRINT_ON(con);
pout("Device does not support SMART");
if (con->reportscsiioctl > 0)
pout(" [%s]\n", scsiErrString(iec_err));
else
pout("\n");
PRINT_OFF(con);
}
gIecMPage = 0;
return 0;
}
if (!is_tape)
pout("Device supports SMART and is %s\n",
(scsi_IsExceptionControlEnabled(&iec)) ? "Enabled" : "Disabled");
pout("%s\n", (scsi_IsWarningEnabled(&iec)) ?
"Temperature Warning Enabled" :
"Temperature Warning Disabled or Not Supported");
return 0;
}
static int scsiSmartEnable(scsi_device * device)
{
struct scsi_iec_mode_page iec;
int err;
if ((err = scsiFetchIECmpage(device, &iec, modese_len))) {
PRINT_ON(con);
pout("unable to fetch IEC (SMART) mode page [%s]\n",
scsiErrString(err));
PRINT_OFF(con);
return 1;
} else
modese_len = iec.modese_len;
if ((err = scsiSetExceptionControlAndWarning(device, 1, &iec))) {
PRINT_ON(con);
pout("unable to enable Exception control and warning [%s]\n",
scsiErrString(err));
PRINT_OFF(con);
return 1;
}
/* Need to refetch 'iec' since could be modified by previous call */
if ((err = scsiFetchIECmpage(device, &iec, modese_len))) {
pout("unable to fetch IEC (SMART) mode page [%s]\n",
scsiErrString(err));
return 1;
} else
modese_len = iec.modese_len;
pout("Informational Exceptions (SMART) %s\n",
scsi_IsExceptionControlEnabled(&iec) ? "enabled" : "disabled");
pout("Temperature warning %s\n",
scsi_IsWarningEnabled(&iec) ? "enabled" : "disabled");
return 0;
}
static int scsiSmartDisable(scsi_device * device)
{
struct scsi_iec_mode_page iec;
int err;
if ((err = scsiFetchIECmpage(device, &iec, modese_len))) {
PRINT_ON(con);
pout("unable to fetch IEC (SMART) mode page [%s]\n",
scsiErrString(err));
PRINT_OFF(con);
return 1;
} else
modese_len = iec.modese_len;
if ((err = scsiSetExceptionControlAndWarning(device, 0, &iec))) {
PRINT_ON(con);
pout("unable to disable Exception control and warning [%s]\n",
scsiErrString(err));
PRINT_OFF(con);
return 1;
}
/* Need to refetch 'iec' since could be modified by previous call */
if ((err = scsiFetchIECmpage(device, &iec, modese_len))) {
pout("unable to fetch IEC (SMART) mode page [%s]\n",
scsiErrString(err));
return 1;
} else
modese_len = iec.modese_len;
pout("Informational Exceptions (SMART) %s\n",
scsi_IsExceptionControlEnabled(&iec) ? "enabled" : "disabled");
pout("Temperature warning %s\n",
scsi_IsWarningEnabled(&iec) ? "enabled" : "disabled");
return 0;
}
static void scsiPrintTemp(scsi_device * device)
{
UINT8 temp = 0;
UINT8 trip = 0;
if (scsiGetTemp(device, &temp, &trip))
return;
if (temp) {
if (255 != temp)
pout("Current Drive Temperature: %d C\n", temp);
else
pout("Current Drive Temperature: <not available>\n");
}
if (trip)
pout("Drive Trip Temperature: %d C\n", trip);
}
/* Main entry point used by smartctl command. Return 0 for success */
int scsiPrintMain(scsi_device * device, const scsi_print_options & options)
{
int checkedSupportedLogPages = 0;
UINT8 peripheral_type = 0;
int returnval = 0;
int res, durationSec;
res = scsiGetDriveInfo(device, &peripheral_type, options.drive_info);
if (res) {
if (2 == res)
return 0;
else
failuretest(MANDATORY_CMD, returnval |= FAILID);
}
if (options.smart_enable) {
if (scsiSmartEnable(device))
failuretest(MANDATORY_CMD, returnval |= FAILSMART);
}
if (options.smart_disable) {
if (scsiSmartDisable(device))
failuretest(MANDATORY_CMD,returnval |= FAILSMART);
}
if (options.smart_auto_save_enable) {
if (scsiSetControlGLTSD(device, 0, modese_len)) {
pout("Enable autosave (clear GLTSD bit) failed\n");
failuretest(OPTIONAL_CMD,returnval |= FAILSMART);
}
}
if (options.smart_auto_save_disable) {
if (scsiSetControlGLTSD(device, 1, modese_len)) {
pout("Disable autosave (set GLTSD bit) failed\n");
failuretest(OPTIONAL_CMD,returnval |= FAILSMART);
}
}
if (options.smart_check_status) {
scsiGetSupportedLogPages(device);
checkedSupportedLogPages = 1;
if ((SCSI_PT_SEQUENTIAL_ACCESS == peripheral_type) ||
(SCSI_PT_MEDIUM_CHANGER == peripheral_type)) { /* tape device */
if (gTapeAlertsLPage) {
if (options.drive_info)
pout("TapeAlert Supported\n");
if (-1 == scsiGetTapeAlertsData(device, peripheral_type))
failuretest(OPTIONAL_CMD, returnval |= FAILSMART);
}
else
pout("TapeAlert Not Supported\n");
} else { /* disk, cd/dvd, enclosure, etc */
if ((res = scsiGetSmartData(device, options.smart_vendor_attrib))) {
if (-2 == res)
returnval |= FAILSTATUS;
else
returnval |= FAILSMART;
}
}
}
if (options.smart_vendor_attrib) {
if (! checkedSupportedLogPages)
scsiGetSupportedLogPages(device);
if (gTempLPage) {
if (options.smart_check_status)
pout("\n");
scsiPrintTemp(device);
}
if (gStartStopLPage)
scsiGetStartStopData(device);
if (SCSI_PT_DIRECT_ACCESS == peripheral_type) {
scsiPrintGrownDefectListLen(device);
if (gSeagateCacheLPage)
scsiPrintSeagateCacheLPage(device);
if (gSeagateFactoryLPage)
scsiPrintSeagateFactoryLPage(device);
}
}
if (options.smart_error_log) {
if (! checkedSupportedLogPages)
scsiGetSupportedLogPages(device);
scsiPrintErrorCounterLog(device);
if (1 == scsiFetchControlGLTSD(device, modese_len, 1))
pout("\n[GLTSD (Global Logging Target Save Disable) set. "
"Enable Save with '-S on']\n");
}
if (options.smart_selftest_log) {
if (! checkedSupportedLogPages)
scsiGetSupportedLogPages(device);
res = 0;
if (gSelfTestLPage)
res = scsiPrintSelfTest(device);
else {
pout("Device does not support Self Test logging\n");
failuretest(OPTIONAL_CMD, returnval|=FAILSMART);
}
if (0 != res)
failuretest(OPTIONAL_CMD, returnval|=res);
}
if (options.smart_background_log) {
if (! checkedSupportedLogPages)
scsiGetSupportedLogPages(device);
res = 0;
if (gBackgroundResultsLPage)
res = scsiPrintBackgroundResults(device);
else {
pout("Device does not support Background scan results logging\n");
failuretest(OPTIONAL_CMD, returnval|=FAILSMART);
}
if (0 != res)
failuretest(OPTIONAL_CMD, returnval|=res);
}
if (options.smart_default_selftest) {
if (scsiSmartDefaultSelfTest(device))
return returnval | FAILSMART;
pout("Default Self Test Successful\n");
}
if (options.smart_short_cap_selftest) {
if (scsiSmartShortCapSelfTest(device))
return returnval | FAILSMART;
pout("Short Foreground Self Test Successful\n");
}
if (options.smart_short_selftest) {
if (scsiSmartShortSelfTest(device))
return returnval | FAILSMART;
pout("Short Background Self Test has begun\n");
pout("Use smartctl -X to abort test\n");
}
if (options.smart_extend_selftest) {
if (scsiSmartExtendSelfTest(device))
return returnval | FAILSMART;
pout("Extended Background Self Test has begun\n");
if ((0 == scsiFetchExtendedSelfTestTime(device, &durationSec,
modese_len)) && (durationSec > 0)) {
time_t t = time(NULL);
t += durationSec;
pout("Please wait %d minutes for test to complete.\n",
durationSec / 60);
pout("Estimated completion time: %s\n", ctime(&t));
}
pout("Use smartctl -X to abort test\n");
}
if (options.smart_extend_cap_selftest) {
if (scsiSmartExtendCapSelfTest(device))
return returnval | FAILSMART;
pout("Extended Foreground Self Test Successful\n");
}
if (options.smart_selftest_abort) {
if (scsiSmartSelfTestAbort(device))
return returnval | FAILSMART;
pout("Self Test returned without error\n");
}
if (options.sasphy) {
if (scsiPrintSasPhy(device, options.sasphy_reset))
return returnval | FAILSMART;
}
return returnval;
}
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