freebsd-nq/sys/cam/scsi/scsi_ses.c

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/* $FreeBSD$ */
/*
* Copyright (c) 2000 Matthew Jacob
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions, and the following disclaimer,
* without modification, immediately at the beginning of the file.
* 2. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
*/
#include <sys/param.h>
#include <sys/queue.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/types.h>
#include <sys/malloc.h>
#include <sys/fcntl.h>
#include <sys/conf.h>
#include <sys/errno.h>
#include <sys/devicestat.h>
#include <machine/stdarg.h>
#include <cam/cam.h>
#include <cam/cam_ccb.h>
#include <cam/cam_extend.h>
#include <cam/cam_periph.h>
#include <cam/cam_xpt_periph.h>
#include <cam/cam_debug.h>
#include <cam/scsi/scsi_all.h>
#include <cam/scsi/scsi_message.h>
#include <sys/ioccom.h>
#include <cam/scsi/scsi_ses.h>
#include <opt_ses.h>
/*
* Platform Independent Driver Internal Definitions for SES devices.
*/
typedef enum {
SES_NONE,
SES_SES_SCSI2,
SES_SES,
SES_SES_PASSTHROUGH,
SES_SEN,
SES_SAFT
} enctyp;
struct ses_softc;
typedef struct ses_softc ses_softc_t;
typedef struct {
int (*softc_init)(ses_softc_t *, int);
int (*init_enc)(ses_softc_t *);
int (*get_encstat)(ses_softc_t *, int);
int (*set_encstat)(ses_softc_t *, ses_encstat, int);
int (*get_objstat)(ses_softc_t *, ses_objstat *, int);
int (*set_objstat)(ses_softc_t *, ses_objstat *, int);
} encvec;
#define ENCI_SVALID 0x80
typedef struct {
uint32_t
enctype : 8, /* enclosure type */
subenclosure : 8, /* subenclosure id */
svalid : 1, /* enclosure information valid */
priv : 15; /* private data, per object */
uint8_t encstat[4]; /* state && stats */
} encobj;
#define SEN_ID "UNISYS SUN_SEN"
#define SEN_ID_LEN 24
static enctyp ses_type(void *, int);
/* Forward reference to Enclosure Functions */
static int ses_softc_init(ses_softc_t *, int);
static int ses_init_enc(ses_softc_t *);
static int ses_get_encstat(ses_softc_t *, int);
static int ses_set_encstat(ses_softc_t *, uint8_t, int);
static int ses_get_objstat(ses_softc_t *, ses_objstat *, int);
static int ses_set_objstat(ses_softc_t *, ses_objstat *, int);
static int safte_softc_init(ses_softc_t *, int);
static int safte_init_enc(ses_softc_t *);
static int safte_get_encstat(ses_softc_t *, int);
static int safte_set_encstat(ses_softc_t *, uint8_t, int);
static int safte_get_objstat(ses_softc_t *, ses_objstat *, int);
static int safte_set_objstat(ses_softc_t *, ses_objstat *, int);
/*
* Platform implementation defines/functions for SES internal kernel stuff
*/
#define STRNCMP strncmp
#define PRINTF printf
#define SES_LOG ses_log
#ifdef DEBUG
#define SES_DLOG ses_log
#else
#define SES_DLOG if (0) ses_log
#endif
#define SES_VLOG if (bootverbose) ses_log
#define SES_MALLOC(amt) malloc(amt, M_DEVBUF, M_NOWAIT)
#define SES_FREE(ptr, amt) free(ptr, M_DEVBUF)
#define MEMZERO bzero
#define MEMCPY(dest, src, amt) bcopy(src, dest, amt)
static int ses_runcmd(struct ses_softc *, char *, int, char *, int *);
static void ses_log(struct ses_softc *, const char *, ...);
/*
* Gerenal FreeBSD kernel stuff.
*/
#define ccb_state ppriv_field0
#define ccb_bp ppriv_ptr1
struct ses_softc {
enctyp ses_type; /* type of enclosure */
encvec ses_vec; /* vector to handlers */
void * ses_private; /* per-type private data */
encobj * ses_objmap; /* objects */
u_int32_t ses_nobjects; /* number of objects */
ses_encstat ses_encstat; /* overall status */
u_int8_t ses_flags;
union ccb ses_saved_ccb;
dev_t ses_dev;
struct cam_periph *periph;
};
#define SES_FLAG_INVALID 0x01
#define SES_FLAG_OPEN 0x02
#define SES_FLAG_INITIALIZED 0x04
#define SESUNIT(x) (minor((x)))
#define SES_CDEV_MAJOR 110
static d_open_t sesopen;
static d_close_t sesclose;
static d_ioctl_t sesioctl;
static periph_init_t sesinit;
static periph_ctor_t sesregister;
static periph_oninv_t sesoninvalidate;
static periph_dtor_t sescleanup;
static periph_start_t sesstart;
static void sesasync(void *, u_int32_t, struct cam_path *, void *);
static void sesdone(struct cam_periph *, union ccb *);
static int seserror(union ccb *, u_int32_t, u_int32_t);
static struct periph_driver sesdriver = {
sesinit, "ses",
TAILQ_HEAD_INITIALIZER(sesdriver.units), /* generation */ 0
};
PERIPHDRIVER_DECLARE(ses, sesdriver);
static struct cdevsw ses_cdevsw =
{
/* open */ sesopen,
/* close */ sesclose,
/* read */ noread,
/* write */ nowrite,
/* ioctl */ sesioctl,
/* poll */ nopoll,
/* mmap */ nommap,
/* strategy */ nostrategy,
/* name */ "ses",
/* maj */ SES_CDEV_MAJOR,
/* dump */ nodump,
/* psize */ nopsize,
/* flags */ 0,
};
static struct extend_array *sesperiphs;
void
sesinit(void)
{
cam_status status;
struct cam_path *path;
/*
* Create our extend array for storing the devices we attach to.
*/
sesperiphs = cam_extend_new();
if (sesperiphs == NULL) {
printf("ses: Failed to alloc extend array!\n");
return;
}
/*
* Install a global async callback. This callback will
* receive async callbacks like "new device found".
*/
status = xpt_create_path(&path, NULL, CAM_XPT_PATH_ID,
CAM_TARGET_WILDCARD, CAM_LUN_WILDCARD);
if (status == CAM_REQ_CMP) {
struct ccb_setasync csa;
xpt_setup_ccb(&csa.ccb_h, path, 5);
csa.ccb_h.func_code = XPT_SASYNC_CB;
csa.event_enable = AC_FOUND_DEVICE;
csa.callback = sesasync;
csa.callback_arg = NULL;
xpt_action((union ccb *)&csa);
status = csa.ccb_h.status;
xpt_free_path(path);
}
if (status != CAM_REQ_CMP) {
printf("ses: Failed to attach master async callback "
"due to status 0x%x!\n", status);
}
}
static void
sesoninvalidate(struct cam_periph *periph)
{
struct ses_softc *softc;
struct ccb_setasync csa;
softc = (struct ses_softc *)periph->softc;
/*
* Unregister any async callbacks.
*/
xpt_setup_ccb(&csa.ccb_h, periph->path, 5);
csa.ccb_h.func_code = XPT_SASYNC_CB;
csa.event_enable = 0;
csa.callback = sesasync;
csa.callback_arg = periph;
xpt_action((union ccb *)&csa);
softc->ses_flags |= SES_FLAG_INVALID;
xpt_print_path(periph->path);
printf("lost device\n");
}
static void
sescleanup(struct cam_periph *periph)
{
struct ses_softc *softc;
softc = (struct ses_softc *)periph->softc;
destroy_dev(softc->ses_dev);
cam_extend_release(sesperiphs, periph->unit_number);
xpt_print_path(periph->path);
printf("removing device entry\n");
free(softc, M_DEVBUF);
}
static void
sesasync(void *callback_arg, u_int32_t code, struct cam_path *path, void *arg)
{
struct cam_periph *periph;
periph = (struct cam_periph *)callback_arg;
switch(code) {
case AC_FOUND_DEVICE:
{
cam_status status;
struct ccb_getdev *cgd;
int inq_len;
cgd = (struct ccb_getdev *)arg;
if (arg == NULL) {
break;
}
inq_len = cgd->inq_data.additional_length + 4;
/*
* PROBLEM: WE NEED TO LOOK AT BYTES 48-53 TO SEE IF THIS IS
* PROBLEM: IS A SAF-TE DEVICE.
*/
switch (ses_type(&cgd->inq_data, inq_len)) {
case SES_SES:
case SES_SES_SCSI2:
case SES_SES_PASSTHROUGH:
case SES_SEN:
case SES_SAFT:
break;
default:
return;
}
status = cam_periph_alloc(sesregister, sesoninvalidate,
sescleanup, sesstart, "ses", CAM_PERIPH_BIO,
cgd->ccb_h.path, sesasync, AC_FOUND_DEVICE, cgd);
if (status != CAM_REQ_CMP && status != CAM_REQ_INPROG) {
printf("sesasync: Unable to probe new device due to "
"status 0x%x\n", status);
}
break;
}
default:
cam_periph_async(periph, code, path, arg);
break;
}
}
static cam_status
sesregister(struct cam_periph *periph, void *arg)
{
struct ses_softc *softc;
struct ccb_setasync csa;
struct ccb_getdev *cgd;
char *tname;
cgd = (struct ccb_getdev *)arg;
if (periph == NULL) {
printf("sesregister: periph was NULL!!\n");
return (CAM_REQ_CMP_ERR);
}
if (cgd == NULL) {
printf("sesregister: no getdev CCB, can't register device\n");
return (CAM_REQ_CMP_ERR);
}
softc = malloc(sizeof (struct ses_softc), M_DEVBUF, M_NOWAIT);
if (softc == NULL) {
printf("sesregister: Unable to probe new device. "
"Unable to allocate softc\n");
return (CAM_REQ_CMP_ERR);
}
bzero(softc, sizeof (struct ses_softc));
periph->softc = softc;
softc->periph = periph;
softc->ses_type = ses_type(&cgd->inq_data, sizeof (cgd->inq_data));
switch (softc->ses_type) {
case SES_SES:
case SES_SES_SCSI2:
case SES_SES_PASSTHROUGH:
softc->ses_vec.softc_init = ses_softc_init;
softc->ses_vec.init_enc = ses_init_enc;
softc->ses_vec.get_encstat = ses_get_encstat;
softc->ses_vec.set_encstat = ses_set_encstat;
softc->ses_vec.get_objstat = ses_get_objstat;
softc->ses_vec.set_objstat = ses_set_objstat;
break;
case SES_SAFT:
softc->ses_vec.softc_init = safte_softc_init;
softc->ses_vec.init_enc = safte_init_enc;
softc->ses_vec.get_encstat = safte_get_encstat;
softc->ses_vec.set_encstat = safte_set_encstat;
softc->ses_vec.get_objstat = safte_get_objstat;
softc->ses_vec.set_objstat = safte_set_objstat;
break;
case SES_SEN:
break;
case SES_NONE:
default:
free(softc, M_DEVBUF);
return (CAM_REQ_CMP_ERR);
}
cam_extend_set(sesperiphs, periph->unit_number, periph);
softc->ses_dev = make_dev(&ses_cdevsw, periph->unit_number,
UID_ROOT, GID_OPERATOR, 0600, "%s%d",
periph->periph_name, periph->unit_number);
/*
* Add an async callback so that we get
* notified if this device goes away.
*/
xpt_setup_ccb(&csa.ccb_h, periph->path, 5);
csa.ccb_h.func_code = XPT_SASYNC_CB;
csa.event_enable = AC_LOST_DEVICE;
csa.callback = sesasync;
csa.callback_arg = periph;
xpt_action((union ccb *)&csa);
switch (softc->ses_type) {
default:
case SES_NONE:
tname = "No SES device";
break;
case SES_SES_SCSI2:
tname = "SCSI-2 SES Device";
break;
case SES_SES:
tname = "SCSI-3 SES Device";
break;
case SES_SES_PASSTHROUGH:
tname = "SES Passthrough Device";
break;
case SES_SEN:
tname = "UNISYS SEN Device (NOT HANDLED YET)";
break;
case SES_SAFT:
tname = "SAF-TE Compliant Device";
break;
}
xpt_announce_periph(periph, tname);
return (CAM_REQ_CMP);
}
static int
sesopen(dev_t dev, int flags, int fmt, struct thread *td)
{
struct cam_periph *periph;
struct ses_softc *softc;
int error, s;
s = splsoftcam();
periph = cam_extend_get(sesperiphs, SESUNIT(dev));
if (periph == NULL) {
splx(s);
return (ENXIO);
}
if ((error = cam_periph_lock(periph, PRIBIO | PCATCH)) != 0) {
splx(s);
return (error);
}
splx(s);
if (cam_periph_acquire(periph) != CAM_REQ_CMP) {
cam_periph_unlock(periph);
return (ENXIO);
}
softc = (struct ses_softc *)periph->softc;
if (softc->ses_flags & SES_FLAG_INVALID) {
error = ENXIO;
goto out;
}
if (softc->ses_flags & SES_FLAG_OPEN) {
error = EBUSY;
goto out;
}
if (softc->ses_vec.softc_init == NULL) {
error = ENXIO;
goto out;
}
softc->ses_flags |= SES_FLAG_OPEN;
if ((softc->ses_flags & SES_FLAG_INITIALIZED) == 0) {
error = (*softc->ses_vec.softc_init)(softc, 1);
if (error)
softc->ses_flags &= ~SES_FLAG_OPEN;
else
softc->ses_flags |= SES_FLAG_INITIALIZED;
}
out:
if (error) {
cam_periph_release(periph);
}
cam_periph_unlock(periph);
return (error);
}
static int
sesclose(dev_t dev, int flag, int fmt, struct thread *td)
{
struct cam_periph *periph;
struct ses_softc *softc;
int unit, error;
error = 0;
unit = SESUNIT(dev);
periph = cam_extend_get(sesperiphs, unit);
if (periph == NULL)
return (ENXIO);
softc = (struct ses_softc *)periph->softc;
if ((error = cam_periph_lock(periph, PRIBIO)) != 0)
return (error);
softc->ses_flags &= ~SES_FLAG_OPEN;
cam_periph_unlock(periph);
cam_periph_release(periph);
return (0);
}
static void
sesstart(struct cam_periph *p, union ccb *sccb)
{
int s = splbio();
if (p->immediate_priority <= p->pinfo.priority) {
SLIST_INSERT_HEAD(&p->ccb_list, &sccb->ccb_h, periph_links.sle);
p->immediate_priority = CAM_PRIORITY_NONE;
wakeup(&p->ccb_list);
}
splx(s);
}
static void
sesdone(struct cam_periph *periph, union ccb *dccb)
{
wakeup(&dccb->ccb_h.cbfcnp);
}
static int
seserror(union ccb *ccb, u_int32_t cflags, u_int32_t sflags)
{
struct ses_softc *softc;
struct cam_periph *periph;
periph = xpt_path_periph(ccb->ccb_h.path);
softc = (struct ses_softc *)periph->softc;
return (cam_periph_error(ccb, cflags, sflags, &softc->ses_saved_ccb));
}
static int
sesioctl(dev_t dev, u_long cmd, caddr_t arg_addr, int flag, struct thread *td)
{
struct cam_periph *periph;
ses_encstat tmp;
ses_objstat objs;
ses_object obj, *uobj;
struct ses_softc *ssc;
void *addr;
int error, i;
if (arg_addr)
addr = *((caddr_t *) arg_addr);
else
addr = NULL;
periph = cam_extend_get(sesperiphs, SESUNIT(dev));
if (periph == NULL)
return (ENXIO);
CAM_DEBUG(periph->path, CAM_DEBUG_TRACE, ("entering sesioctl\n"));
ssc = (struct ses_softc *)periph->softc;
/*
* Now check to see whether we're initialized or not.
*/
if ((ssc->ses_flags & SES_FLAG_INITIALIZED) == 0) {
return (ENXIO);
}
error = 0;
CAM_DEBUG(periph->path, CAM_DEBUG_TRACE,
("trying to do ioctl %#lx\n", cmd));
/*
* If this command can change the device's state,
* we must have the device open for writing.
*/
switch (cmd) {
case SESIOC_GETNOBJ:
case SESIOC_GETOBJMAP:
case SESIOC_GETENCSTAT:
case SESIOC_GETOBJSTAT:
break;
default:
if ((flag & FWRITE) == 0) {
return (EBADF);
}
}
switch (cmd) {
case SESIOC_GETNOBJ:
error = copyout(&ssc->ses_nobjects, addr,
sizeof (ssc->ses_nobjects));
break;
case SESIOC_GETOBJMAP:
for (uobj = addr, i = 0; i != ssc->ses_nobjects; i++, uobj++) {
obj.obj_id = i;
obj.subencid = ssc->ses_objmap[i].subenclosure;
obj.object_type = ssc->ses_objmap[i].enctype;
error = copyout(&obj, uobj, sizeof (ses_object));
if (error) {
break;
}
}
break;
case SESIOC_GETENCSTAT:
error = (*ssc->ses_vec.get_encstat)(ssc, 1);
if (error)
break;
tmp = ssc->ses_encstat & ~ENCI_SVALID;
error = copyout(&tmp, addr, sizeof (ses_encstat));
ssc->ses_encstat = tmp;
break;
case SESIOC_SETENCSTAT:
error = copyin(addr, &tmp, sizeof (ses_encstat));
if (error)
break;
error = (*ssc->ses_vec.set_encstat)(ssc, tmp, 1);
break;
case SESIOC_GETOBJSTAT:
error = copyin(addr, &objs, sizeof (ses_objstat));
if (error)
break;
if (objs.obj_id >= ssc->ses_nobjects) {
error = EINVAL;
break;
}
error = (*ssc->ses_vec.get_objstat)(ssc, &objs, 1);
if (error)
break;
error = copyout(&objs, addr, sizeof (ses_objstat));
/*
* Always (for now) invalidate entry.
*/
ssc->ses_objmap[objs.obj_id].svalid = 0;
break;
case SESIOC_SETOBJSTAT:
error = copyin(addr, &objs, sizeof (ses_objstat));
if (error)
break;
if (objs.obj_id >= ssc->ses_nobjects) {
error = EINVAL;
break;
}
error = (*ssc->ses_vec.set_objstat)(ssc, &objs, 1);
/*
* Always (for now) invalidate entry.
*/
ssc->ses_objmap[objs.obj_id].svalid = 0;
break;
case SESIOC_INIT:
error = (*ssc->ses_vec.init_enc)(ssc);
break;
default:
error = cam_periph_ioctl(periph, cmd, arg_addr, seserror);
break;
}
return (error);
}
Rewrite of the CAM error recovery code. Some of the major changes include: - The SCSI error handling portion of cam_periph_error() has been broken out into a number of subfunctions to better modularize the code that handles the hierarchy of SCSI errors. As a result, the code is now much easier to read. - String handling and error printing has been significantly revamped. We now use sbufs to do string formatting instead of using printfs (for the kernel) and snprintf/strncat (for userland) as before. There is a new catchall error printing routine, cam_error_print() and its string-based counterpart, cam_error_string() that allow the kernel and userland applications to pass in a CCB and have errors printed out properly, whether or not they're SCSI errors. Among other things, this helped eliminate a fair amount of duplicate code in camcontrol. We now print out more information than before, including the CAM status and SCSI status and the error recovery action taken to remedy the problem. - sbufs are now available in userland, via libsbuf. This change was necessary since most of the error printing code is shared between libcam and the kernel. - A new transfer settings interface is included in this checkin. This code is #ifdef'ed out, and is primarily intended to aid discussion with HBA driver authors on the final form the interface should take. There is example code in the ahc(4) driver that implements the HBA driver side of the new interface. The new transfer settings code won't be enabled until we're ready to switch all HBA drivers over to the new interface. src/Makefile.inc1, lib/Makefile: Add libsbuf. It must be built before libcam, since libcam uses sbuf routines. libcam/Makefile: libcam now depends on libsbuf. libsbuf/Makefile: Add a makefile for libsbuf. This pulls in the sbuf sources from sys/kern. bsd.libnames.mk: Add LIBSBUF. camcontrol/Makefile: Add -lsbuf. Since camcontrol is statically linked, we can't depend on the dynamic linker to pull in libsbuf. camcontrol.c: Use cam_error_print() instead of checking for CAM_SCSI_STATUS_ERROR on every failed CCB. sbuf.9: Change the prototypes for sbuf_cat() and sbuf_cpy() so that the source string is now a const char *. This is more in line wth the standard system string functions, and helps eliminate warnings when dealing with a const source buffer. Fix a typo. cam.c: Add description strings for the various CAM error status values, as well as routines to look up those strings. Add new cam_error_string() and cam_error_print() routines for userland and the kernel. cam.h: Add a new CAM flag, CAM_RETRY_SELTO. Add enumerated types for the various options available with cam_error_print() and cam_error_string(). cam_ccb.h: Add new transfer negotiation structures/types. Change inq_len in the ccb_getdev structure to be "reserved". This field has never been filled in, and will be removed when we next bump the CAM version. cam_debug.h: Fix typo. cam_periph.c: Modularize cam_periph_error(). The SCSI error handling part of cam_periph_error() is now in camperiphscsistatuserror() and camperiphscsisenseerror(). In cam_periph_lock(), increase the reference count on the periph while we wait for our lock attempt to succeed so that the periph won't go away while we're sleeping. cam_xpt.c: Add new transfer negotiation code. (ifdefed out) Add a new function, xpt_path_string(). This is a string/sbuf analog to xpt_print_path(). scsi_all.c: Revamp string handing and error printing code. We now use sbufs for much of the string formatting code. More of that code is shared between userland the kernel. scsi_all.h: Get rid of SS_TURSTART, it wasn't terribly useful in the first place. Add a new error action, SS_REQSENSE. (Send a request sense and then retry the command.) This is useful when the controller hasn't performed autosense for some reason. Change the default actions around a bit. scsi_cd.c, scsi_da.c, scsi_pt.c, scsi_ses.c: SF_RETRY_SELTO -> CAM_RETRY_SELTO. Selection timeouts shouldn't be covered by a sense flag. scsi_pass.[ch]: SF_RETRY_SELTO -> CAM_RETRY_SELTO. Get rid of the last vestiges of a read/write interface. libkern/bsearch.c, sys/libkern.h, conf/files: Add bsearch.c, which is needed for some of the new table lookup routines. aic7xxx_freebsd.c: Define AHC_NEW_TRAN_SETTINGS if CAM_NEW_TRAN_CODE is defined. sbuf.h, subr_sbuf.c: Add the appropriate #ifdefs so sbufs can compile and run in userland. Change sbuf_printf() to use vsnprintf() instead of kvprintf(), which is only available in the kernel. Change the source string for sbuf_cpy() and sbuf_cat() to be a const char *. Add __BEGIN_DECLS and __END_DECLS around function prototypes since they're now exported to userland. kdump/mkioctls: Include stdio.h before cam.h since cam.h now includes a function with a FILE * argument. Submitted by: gibbs (mostly) Reviewed by: jdp, marcel (libsbuf makefile changes) Reviewed by: des (sbuf changes) Reviewed by: ken
2001-03-27 05:45:52 +00:00
#define SES_CFLAGS CAM_RETRY_SELTO
#define SES_FLAGS SF_NO_PRINT | SF_RETRY_UA
static int
ses_runcmd(struct ses_softc *ssc, char *cdb, int cdbl, char *dptr, int *dlenp)
{
int error, dlen;
ccb_flags ddf;
union ccb *ccb;
if (dptr) {
if ((dlen = *dlenp) < 0) {
dlen = -dlen;
ddf = CAM_DIR_OUT;
} else {
ddf = CAM_DIR_IN;
}
} else {
dlen = 0;
ddf = CAM_DIR_NONE;
}
if (cdbl > IOCDBLEN) {
cdbl = IOCDBLEN;
}
ccb = cam_periph_getccb(ssc->periph, 1);
cam_fill_csio(&ccb->csio, 0, sesdone, ddf, MSG_SIMPLE_Q_TAG, dptr,
dlen, sizeof (struct scsi_sense_data), cdbl, 60 * 1000);
bcopy(cdb, ccb->csio.cdb_io.cdb_bytes, cdbl);
Rewrite of the CAM error recovery code. Some of the major changes include: - The SCSI error handling portion of cam_periph_error() has been broken out into a number of subfunctions to better modularize the code that handles the hierarchy of SCSI errors. As a result, the code is now much easier to read. - String handling and error printing has been significantly revamped. We now use sbufs to do string formatting instead of using printfs (for the kernel) and snprintf/strncat (for userland) as before. There is a new catchall error printing routine, cam_error_print() and its string-based counterpart, cam_error_string() that allow the kernel and userland applications to pass in a CCB and have errors printed out properly, whether or not they're SCSI errors. Among other things, this helped eliminate a fair amount of duplicate code in camcontrol. We now print out more information than before, including the CAM status and SCSI status and the error recovery action taken to remedy the problem. - sbufs are now available in userland, via libsbuf. This change was necessary since most of the error printing code is shared between libcam and the kernel. - A new transfer settings interface is included in this checkin. This code is #ifdef'ed out, and is primarily intended to aid discussion with HBA driver authors on the final form the interface should take. There is example code in the ahc(4) driver that implements the HBA driver side of the new interface. The new transfer settings code won't be enabled until we're ready to switch all HBA drivers over to the new interface. src/Makefile.inc1, lib/Makefile: Add libsbuf. It must be built before libcam, since libcam uses sbuf routines. libcam/Makefile: libcam now depends on libsbuf. libsbuf/Makefile: Add a makefile for libsbuf. This pulls in the sbuf sources from sys/kern. bsd.libnames.mk: Add LIBSBUF. camcontrol/Makefile: Add -lsbuf. Since camcontrol is statically linked, we can't depend on the dynamic linker to pull in libsbuf. camcontrol.c: Use cam_error_print() instead of checking for CAM_SCSI_STATUS_ERROR on every failed CCB. sbuf.9: Change the prototypes for sbuf_cat() and sbuf_cpy() so that the source string is now a const char *. This is more in line wth the standard system string functions, and helps eliminate warnings when dealing with a const source buffer. Fix a typo. cam.c: Add description strings for the various CAM error status values, as well as routines to look up those strings. Add new cam_error_string() and cam_error_print() routines for userland and the kernel. cam.h: Add a new CAM flag, CAM_RETRY_SELTO. Add enumerated types for the various options available with cam_error_print() and cam_error_string(). cam_ccb.h: Add new transfer negotiation structures/types. Change inq_len in the ccb_getdev structure to be "reserved". This field has never been filled in, and will be removed when we next bump the CAM version. cam_debug.h: Fix typo. cam_periph.c: Modularize cam_periph_error(). The SCSI error handling part of cam_periph_error() is now in camperiphscsistatuserror() and camperiphscsisenseerror(). In cam_periph_lock(), increase the reference count on the periph while we wait for our lock attempt to succeed so that the periph won't go away while we're sleeping. cam_xpt.c: Add new transfer negotiation code. (ifdefed out) Add a new function, xpt_path_string(). This is a string/sbuf analog to xpt_print_path(). scsi_all.c: Revamp string handing and error printing code. We now use sbufs for much of the string formatting code. More of that code is shared between userland the kernel. scsi_all.h: Get rid of SS_TURSTART, it wasn't terribly useful in the first place. Add a new error action, SS_REQSENSE. (Send a request sense and then retry the command.) This is useful when the controller hasn't performed autosense for some reason. Change the default actions around a bit. scsi_cd.c, scsi_da.c, scsi_pt.c, scsi_ses.c: SF_RETRY_SELTO -> CAM_RETRY_SELTO. Selection timeouts shouldn't be covered by a sense flag. scsi_pass.[ch]: SF_RETRY_SELTO -> CAM_RETRY_SELTO. Get rid of the last vestiges of a read/write interface. libkern/bsearch.c, sys/libkern.h, conf/files: Add bsearch.c, which is needed for some of the new table lookup routines. aic7xxx_freebsd.c: Define AHC_NEW_TRAN_SETTINGS if CAM_NEW_TRAN_CODE is defined. sbuf.h, subr_sbuf.c: Add the appropriate #ifdefs so sbufs can compile and run in userland. Change sbuf_printf() to use vsnprintf() instead of kvprintf(), which is only available in the kernel. Change the source string for sbuf_cpy() and sbuf_cat() to be a const char *. Add __BEGIN_DECLS and __END_DECLS around function prototypes since they're now exported to userland. kdump/mkioctls: Include stdio.h before cam.h since cam.h now includes a function with a FILE * argument. Submitted by: gibbs (mostly) Reviewed by: jdp, marcel (libsbuf makefile changes) Reviewed by: des (sbuf changes) Reviewed by: ken
2001-03-27 05:45:52 +00:00
error = cam_periph_runccb(ccb, seserror, SES_CFLAGS, SES_FLAGS, NULL);
if ((ccb->ccb_h.status & CAM_DEV_QFRZN) != 0)
cam_release_devq(ccb->ccb_h.path, 0, 0, 0, FALSE);
if (error) {
if (dptr) {
*dlenp = dlen;
}
} else {
if (dptr) {
*dlenp = ccb->csio.resid;
}
}
xpt_release_ccb(ccb);
return (error);
}
static void
ses_log(struct ses_softc *ssc, const char *fmt, ...)
{
va_list ap;
printf("%s%d: ", ssc->periph->periph_name, ssc->periph->unit_number);
va_start(ap, fmt);
vprintf(fmt, ap);
va_end(ap);
}
/*
* The code after this point runs on many platforms,
* so forgive the slightly awkward and nonconforming
* appearance.
*/
/*
* Is this a device that supports enclosure services?
*
* It's a a pretty simple ruleset- if it is device type 0x0D (13), it's
* an SES device. If it happens to be an old UNISYS SEN device, we can
* handle that too.
*/
#define SAFTE_START 44
#define SAFTE_END 50
#define SAFTE_LEN SAFTE_END-SAFTE_START
static enctyp
ses_type(void *buf, int buflen)
{
unsigned char *iqd = buf;
if (buflen < 8+SEN_ID_LEN)
return (SES_NONE);
if ((iqd[0] & 0x1f) == T_ENCLOSURE) {
if (STRNCMP(&iqd[8], SEN_ID, SEN_ID_LEN) == 0) {
return (SES_SEN);
} else if ((iqd[2] & 0x7) > 2) {
return (SES_SES);
} else {
return (SES_SES_SCSI2);
}
return (SES_NONE);
}
#ifdef SES_ENABLE_PASSTHROUGH
if ((iqd[6] & 0x40) && (iqd[2] & 0x7) >= 2) {
/*
* PassThrough Device.
*/
2000-01-15 23:05:29 +00:00
return (SES_SES_PASSTHROUGH);
}
#endif
/*
* The comparison is short for a reason-
* some vendors were chopping it short.
*/
if (buflen < SAFTE_END - 2) {
return (SES_NONE);
}
if (STRNCMP((char *)&iqd[SAFTE_START], "SAF-TE", SAFTE_LEN - 2) == 0) {
return (SES_SAFT);
}
return (SES_NONE);
}
/*
* SES Native Type Device Support
*/
/*
* SES Diagnostic Page Codes
*/
typedef enum {
SesConfigPage = 0x1,
SesControlPage,
#define SesStatusPage SesControlPage
SesHelpTxt,
SesStringOut,
#define SesStringIn SesStringOut
SesThresholdOut,
#define SesThresholdIn SesThresholdOut
SesArrayControl,
#define SesArrayStatus SesArrayControl
SesElementDescriptor,
SesShortStatus
} SesDiagPageCodes;
/*
* minimal amounts
*/
/*
* Minimum amount of data, starting from byte 0, to have
* the config header.
*/
#define SES_CFGHDR_MINLEN 12
/*
* Minimum amount of data, starting from byte 0, to have
* the config header and one enclosure header.
*/
#define SES_ENCHDR_MINLEN 48
/*
* Take this value, subtract it from VEnclen and you know
* the length of the vendor unique bytes.
*/
#define SES_ENCHDR_VMIN 36
/*
* SES Data Structures
*/
typedef struct {
uint32_t GenCode; /* Generation Code */
uint8_t Nsubenc; /* Number of Subenclosures */
} SesCfgHdr;
typedef struct {
uint8_t Subencid; /* SubEnclosure Identifier */
uint8_t Ntypes; /* # of supported types */
uint8_t VEnclen; /* Enclosure Descriptor Length */
} SesEncHdr;
typedef struct {
uint8_t encWWN[8]; /* XXX- Not Right Yet */
uint8_t encVid[8];
uint8_t encPid[16];
uint8_t encRev[4];
uint8_t encVen[1];
} SesEncDesc;
typedef struct {
uint8_t enc_type; /* type of element */
uint8_t enc_maxelt; /* maximum supported */
uint8_t enc_subenc; /* in SubEnc # N */
uint8_t enc_tlen; /* Type Descriptor Text Length */
} SesThdr;
typedef struct {
uint8_t comstatus;
uint8_t comstat[3];
} SesComStat;
struct typidx {
int ses_tidx;
int ses_oidx;
};
struct sscfg {
uint8_t ses_ntypes; /* total number of types supported */
/*
* We need to keep a type index as well as an
* object index for each object in an enclosure.
*/
struct typidx *ses_typidx;
/*
* We also need to keep track of the number of elements
* per type of element. This is needed later so that we
* can find precisely in the returned status data the
* status for the Nth element of the Kth type.
*/
uint8_t * ses_eltmap;
};
/*
* (de)canonicalization defines
*/
#define sbyte(x, byte) ((((uint32_t)(x)) >> (byte * 8)) & 0xff)
#define sbit(x, bit) (((uint32_t)(x)) << bit)
#define sset8(outp, idx, sval) (((uint8_t *)(outp))[idx++]) = sbyte(sval, 0)
#define sset16(outp, idx, sval) \
(((uint8_t *)(outp))[idx++]) = sbyte(sval, 1), \
(((uint8_t *)(outp))[idx++]) = sbyte(sval, 0)
#define sset24(outp, idx, sval) \
(((uint8_t *)(outp))[idx++]) = sbyte(sval, 2), \
(((uint8_t *)(outp))[idx++]) = sbyte(sval, 1), \
(((uint8_t *)(outp))[idx++]) = sbyte(sval, 0)
#define sset32(outp, idx, sval) \
(((uint8_t *)(outp))[idx++]) = sbyte(sval, 3), \
(((uint8_t *)(outp))[idx++]) = sbyte(sval, 2), \
(((uint8_t *)(outp))[idx++]) = sbyte(sval, 1), \
(((uint8_t *)(outp))[idx++]) = sbyte(sval, 0)
#define gbyte(x, byte) ((((uint32_t)(x)) & 0xff) << (byte * 8))
#define gbit(lv, in, idx, shft, mask) lv = ((in[idx] >> shft) & mask)
#define sget8(inp, idx, lval) lval = (((uint8_t *)(inp))[idx++])
#define gget8(inp, idx, lval) lval = (((uint8_t *)(inp))[idx])
#define sget16(inp, idx, lval) \
lval = gbyte((((uint8_t *)(inp))[idx]), 1) | \
(((uint8_t *)(inp))[idx+1]), idx += 2
#define gget16(inp, idx, lval) \
lval = gbyte((((uint8_t *)(inp))[idx]), 1) | \
(((uint8_t *)(inp))[idx+1])
#define sget24(inp, idx, lval) \
lval = gbyte((((uint8_t *)(inp))[idx]), 2) | \
gbyte((((uint8_t *)(inp))[idx+1]), 1) | \
(((uint8_t *)(inp))[idx+2]), idx += 3
#define gget24(inp, idx, lval) \
lval = gbyte((((uint8_t *)(inp))[idx]), 2) | \
gbyte((((uint8_t *)(inp))[idx+1]), 1) | \
(((uint8_t *)(inp))[idx+2])
#define sget32(inp, idx, lval) \
lval = gbyte((((uint8_t *)(inp))[idx]), 3) | \
gbyte((((uint8_t *)(inp))[idx+1]), 2) | \
gbyte((((uint8_t *)(inp))[idx+2]), 1) | \
(((uint8_t *)(inp))[idx+3]), idx += 4
#define gget32(inp, idx, lval) \
lval = gbyte((((uint8_t *)(inp))[idx]), 3) | \
gbyte((((uint8_t *)(inp))[idx+1]), 2) | \
gbyte((((uint8_t *)(inp))[idx+2]), 1) | \
(((uint8_t *)(inp))[idx+3])
#define SCSZ 0x2000
#define CFLEN (256 + SES_ENCHDR_MINLEN)
/*
* Routines specific && private to SES only
*/
static int ses_getconfig(ses_softc_t *);
static int ses_getputstat(ses_softc_t *, int, SesComStat *, int, int);
static int ses_cfghdr(uint8_t *, int, SesCfgHdr *);
static int ses_enchdr(uint8_t *, int, uint8_t, SesEncHdr *);
static int ses_encdesc(uint8_t *, int, uint8_t, SesEncDesc *);
static int ses_getthdr(uint8_t *, int, int, SesThdr *);
static int ses_decode(char *, int, uint8_t *, int, int, SesComStat *);
static int ses_encode(char *, int, uint8_t *, int, int, SesComStat *);
static int
ses_softc_init(ses_softc_t *ssc, int doinit)
{
if (doinit == 0) {
struct sscfg *cc;
if (ssc->ses_nobjects) {
SES_FREE(ssc->ses_objmap,
ssc->ses_nobjects * sizeof (encobj));
ssc->ses_objmap = NULL;
}
if ((cc = ssc->ses_private) != NULL) {
if (cc->ses_eltmap && cc->ses_ntypes) {
SES_FREE(cc->ses_eltmap, cc->ses_ntypes);
cc->ses_eltmap = NULL;
cc->ses_ntypes = 0;
}
if (cc->ses_typidx && ssc->ses_nobjects) {
SES_FREE(cc->ses_typidx,
ssc->ses_nobjects * sizeof (struct typidx));
cc->ses_typidx = NULL;
}
SES_FREE(cc, sizeof (struct sscfg));
ssc->ses_private = NULL;
}
ssc->ses_nobjects = 0;
return (0);
}
if (ssc->ses_private == NULL) {
ssc->ses_private = SES_MALLOC(sizeof (struct sscfg));
}
if (ssc->ses_private == NULL) {
return (ENOMEM);
}
ssc->ses_nobjects = 0;
ssc->ses_encstat = 0;
return (ses_getconfig(ssc));
}
static int
ses_init_enc(ses_softc_t *ssc)
{
return (0);
}
static int
ses_get_encstat(ses_softc_t *ssc, int slpflag)
{
SesComStat ComStat;
int status;
if ((status = ses_getputstat(ssc, -1, &ComStat, slpflag, 1)) != 0) {
return (status);
}
ssc->ses_encstat = ComStat.comstatus | ENCI_SVALID;
return (0);
}
static int
ses_set_encstat(ses_softc_t *ssc, uint8_t encstat, int slpflag)
{
SesComStat ComStat;
int status;
ComStat.comstatus = encstat & 0xf;
if ((status = ses_getputstat(ssc, -1, &ComStat, slpflag, 0)) != 0) {
return (status);
}
ssc->ses_encstat = encstat & 0xf; /* note no SVALID set */
return (0);
}
static int
ses_get_objstat(ses_softc_t *ssc, ses_objstat *obp, int slpflag)
{
int i = (int)obp->obj_id;
if (ssc->ses_objmap[i].svalid == 0) {
SesComStat ComStat;
int err = ses_getputstat(ssc, i, &ComStat, slpflag, 1);
if (err)
return (err);
ssc->ses_objmap[i].encstat[0] = ComStat.comstatus;
ssc->ses_objmap[i].encstat[1] = ComStat.comstat[0];
ssc->ses_objmap[i].encstat[2] = ComStat.comstat[1];
ssc->ses_objmap[i].encstat[3] = ComStat.comstat[2];
ssc->ses_objmap[i].svalid = 1;
}
obp->cstat[0] = ssc->ses_objmap[i].encstat[0];
obp->cstat[1] = ssc->ses_objmap[i].encstat[1];
obp->cstat[2] = ssc->ses_objmap[i].encstat[2];
obp->cstat[3] = ssc->ses_objmap[i].encstat[3];
return (0);
}
static int
ses_set_objstat(ses_softc_t *ssc, ses_objstat *obp, int slpflag)
{
SesComStat ComStat;
int err;
/*
* If this is clear, we don't do diddly.
*/
if ((obp->cstat[0] & SESCTL_CSEL) == 0) {
return (0);
}
ComStat.comstatus = obp->cstat[0];
ComStat.comstat[0] = obp->cstat[1];
ComStat.comstat[1] = obp->cstat[2];
ComStat.comstat[2] = obp->cstat[3];
err = ses_getputstat(ssc, (int)obp->obj_id, &ComStat, slpflag, 0);
ssc->ses_objmap[(int)obp->obj_id].svalid = 0;
return (err);
}
static int
ses_getconfig(ses_softc_t *ssc)
{
struct sscfg *cc;
SesCfgHdr cf;
SesEncHdr hd;
SesEncDesc *cdp;
SesThdr thdr;
int err, amt, i, nobj, ntype, maxima;
char storage[CFLEN], *sdata;
static char cdb[6] = {
RECEIVE_DIAGNOSTIC, 0x1, SesConfigPage, SCSZ >> 8, SCSZ & 0xff, 0
};
cc = ssc->ses_private;
if (cc == NULL) {
return (ENXIO);
}
sdata = SES_MALLOC(SCSZ);
if (sdata == NULL)
return (ENOMEM);
amt = SCSZ;
err = ses_runcmd(ssc, cdb, 6, sdata, &amt);
if (err) {
SES_FREE(sdata, SCSZ);
return (err);
}
amt = SCSZ - amt;
if (ses_cfghdr((uint8_t *) sdata, amt, &cf)) {
SES_LOG(ssc, "Unable to parse SES Config Header\n");
SES_FREE(sdata, SCSZ);
return (EIO);
}
if (amt < SES_ENCHDR_MINLEN) {
SES_LOG(ssc, "runt enclosure length (%d)\n", amt);
SES_FREE(sdata, SCSZ);
return (EIO);
}
SES_VLOG(ssc, "GenCode %x %d Subenclosures\n", cf.GenCode, cf.Nsubenc);
/*
* Now waltz through all the subenclosures toting up the
* number of types available in each. For this, we only
* really need the enclosure header. However, we get the
* enclosure descriptor for debug purposes, as well
* as self-consistency checking purposes.
*/
maxima = cf.Nsubenc + 1;
cdp = (SesEncDesc *) storage;
for (ntype = i = 0; i < maxima; i++) {
MEMZERO((caddr_t)cdp, sizeof (*cdp));
if (ses_enchdr((uint8_t *) sdata, amt, i, &hd)) {
SES_LOG(ssc, "Cannot Extract Enclosure Header %d\n", i);
SES_FREE(sdata, SCSZ);
return (EIO);
}
SES_VLOG(ssc, " SubEnclosure ID %d, %d Types With this ID, En"
"closure Length %d\n", hd.Subencid, hd.Ntypes, hd.VEnclen);
if (ses_encdesc((uint8_t *)sdata, amt, i, cdp)) {
SES_LOG(ssc, "Can't get Enclosure Descriptor %d\n", i);
SES_FREE(sdata, SCSZ);
return (EIO);
}
SES_VLOG(ssc, " WWN: %02x%02x%02x%02x%02x%02x%02x%02x\n",
cdp->encWWN[0], cdp->encWWN[1], cdp->encWWN[2],
cdp->encWWN[3], cdp->encWWN[4], cdp->encWWN[5],
cdp->encWWN[6], cdp->encWWN[7]);
ntype += hd.Ntypes;
}
/*
* Now waltz through all the types that are available, getting
* the type header so we can start adding up the number of
* objects available.
*/
for (nobj = i = 0; i < ntype; i++) {
if (ses_getthdr((uint8_t *)sdata, amt, i, &thdr)) {
SES_LOG(ssc, "Can't get Enclosure Type Header %d\n", i);
SES_FREE(sdata, SCSZ);
return (EIO);
}
SES_LOG(ssc, " Type Desc[%d]: Type 0x%x, MaxElt %d, In Subenc "
"%d, Text Length %d\n", i, thdr.enc_type, thdr.enc_maxelt,
thdr.enc_subenc, thdr.enc_tlen);
nobj += thdr.enc_maxelt;
}
/*
* Now allocate the object array and type map.
*/
ssc->ses_objmap = SES_MALLOC(nobj * sizeof (encobj));
cc->ses_typidx = SES_MALLOC(nobj * sizeof (struct typidx));
cc->ses_eltmap = SES_MALLOC(ntype);
if (ssc->ses_objmap == NULL || cc->ses_typidx == NULL ||
cc->ses_eltmap == NULL) {
if (ssc->ses_objmap) {
SES_FREE(ssc->ses_objmap, (nobj * sizeof (encobj)));
ssc->ses_objmap = NULL;
}
if (cc->ses_typidx) {
SES_FREE(cc->ses_typidx,
(nobj * sizeof (struct typidx)));
cc->ses_typidx = NULL;
}
if (cc->ses_eltmap) {
SES_FREE(cc->ses_eltmap, ntype);
cc->ses_eltmap = NULL;
}
SES_FREE(sdata, SCSZ);
return (ENOMEM);
}
MEMZERO(ssc->ses_objmap, nobj * sizeof (encobj));
MEMZERO(cc->ses_typidx, nobj * sizeof (struct typidx));
MEMZERO(cc->ses_eltmap, ntype);
cc->ses_ntypes = (uint8_t) ntype;
ssc->ses_nobjects = nobj;
/*
* Now waltz through the # of types again to fill in the types
* (and subenclosure ids) of the allocated objects.
*/
nobj = 0;
for (i = 0; i < ntype; i++) {
int j;
if (ses_getthdr((uint8_t *)sdata, amt, i, &thdr)) {
continue;
}
cc->ses_eltmap[i] = thdr.enc_maxelt;
for (j = 0; j < thdr.enc_maxelt; j++) {
cc->ses_typidx[nobj].ses_tidx = i;
cc->ses_typidx[nobj].ses_oidx = j;
ssc->ses_objmap[nobj].subenclosure = thdr.enc_subenc;
ssc->ses_objmap[nobj++].enctype = thdr.enc_type;
}
}
SES_FREE(sdata, SCSZ);
return (0);
}
static int
ses_getputstat(ses_softc_t *ssc, int objid, SesComStat *sp, int slp, int in)
{
struct sscfg *cc;
int err, amt, bufsiz, tidx, oidx;
char cdb[6], *sdata;
cc = ssc->ses_private;
if (cc == NULL) {
return (ENXIO);
}
/*
* If we're just getting overall enclosure status,
* we only need 2 bytes of data storage.
*
* If we're getting anything else, we know how much
* storage we need by noting that starting at offset
* 8 in returned data, all object status bytes are 4
* bytes long, and are stored in chunks of types(M)
* and nth+1 instances of type M.
*/
if (objid == -1) {
bufsiz = 2;
} else {
bufsiz = (ssc->ses_nobjects * 4) + (cc->ses_ntypes * 4) + 8;
}
sdata = SES_MALLOC(bufsiz);
if (sdata == NULL)
return (ENOMEM);
cdb[0] = RECEIVE_DIAGNOSTIC;
cdb[1] = 1;
cdb[2] = SesStatusPage;
cdb[3] = bufsiz >> 8;
cdb[4] = bufsiz & 0xff;
cdb[5] = 0;
amt = bufsiz;
err = ses_runcmd(ssc, cdb, 6, sdata, &amt);
if (err) {
SES_FREE(sdata, bufsiz);
return (err);
}
amt = bufsiz - amt;
if (objid == -1) {
tidx = -1;
oidx = -1;
} else {
tidx = cc->ses_typidx[objid].ses_tidx;
oidx = cc->ses_typidx[objid].ses_oidx;
}
if (in) {
if (ses_decode(sdata, amt, cc->ses_eltmap, tidx, oidx, sp)) {
err = ENODEV;
}
} else {
if (ses_encode(sdata, amt, cc->ses_eltmap, tidx, oidx, sp)) {
err = ENODEV;
} else {
cdb[0] = SEND_DIAGNOSTIC;
cdb[1] = 0x10;
cdb[2] = 0;
cdb[3] = bufsiz >> 8;
cdb[4] = bufsiz & 0xff;
cdb[5] = 0;
amt = -bufsiz;
err = ses_runcmd(ssc, cdb, 6, sdata, &amt);
}
}
SES_FREE(sdata, bufsiz);
return (0);
}
/*
* Routines to parse returned SES data structures.
* Architecture and compiler independent.
*/
static int
ses_cfghdr(uint8_t *buffer, int buflen, SesCfgHdr *cfp)
{
if (buflen < SES_CFGHDR_MINLEN) {
return (-1);
}
gget8(buffer, 1, cfp->Nsubenc);
gget32(buffer, 4, cfp->GenCode);
return (0);
}
static int
ses_enchdr(uint8_t *buffer, int amt, uint8_t SubEncId, SesEncHdr *chp)
{
int s, off = 8;
for (s = 0; s < SubEncId; s++) {
if (off + 3 > amt)
return (-1);
off += buffer[off+3] + 4;
}
if (off + 3 > amt) {
return (-1);
}
gget8(buffer, off+1, chp->Subencid);
gget8(buffer, off+2, chp->Ntypes);
gget8(buffer, off+3, chp->VEnclen);
return (0);
}
static int
ses_encdesc(uint8_t *buffer, int amt, uint8_t SubEncId, SesEncDesc *cdp)
{
int s, e, enclen, off = 8;
for (s = 0; s < SubEncId; s++) {
if (off + 3 > amt)
return (-1);
off += buffer[off+3] + 4;
}
if (off + 3 > amt) {
return (-1);
}
gget8(buffer, off+3, enclen);
off += 4;
if (off >= amt)
return (-1);
e = off + enclen;
if (e > amt) {
e = amt;
}
MEMCPY(cdp, &buffer[off], e - off);
return (0);
}
static int
ses_getthdr(uint8_t *buffer, int amt, int nth, SesThdr *thp)
{
int s, off = 8;
if (amt < SES_CFGHDR_MINLEN) {
return (-1);
}
for (s = 0; s < buffer[1]; s++) {
if (off + 3 > amt)
return (-1);
off += buffer[off+3] + 4;
}
if (off + 3 > amt) {
return (-1);
}
off += buffer[off+3] + 4 + (nth * 4);
if (amt < (off + 4))
return (-1);
gget8(buffer, off++, thp->enc_type);
gget8(buffer, off++, thp->enc_maxelt);
gget8(buffer, off++, thp->enc_subenc);
gget8(buffer, off, thp->enc_tlen);
return (0);
}
/*
* This function needs a little explanation.
*
* The arguments are:
*
*
* char *b, int amt
*
* These describes the raw input SES status data and length.
*
* uint8_t *ep
*
* This is a map of the number of types for each element type
* in the enclosure.
*
* int elt
*
* This is the element type being sought. If elt is -1,
* then overall enclosure status is being sought.
*
* int elm
*
* This is the ordinal Mth element of type elt being sought.
*
* SesComStat *sp
*
* This is the output area to store the status for
* the Mth element of type Elt.
*/
static int
ses_decode(char *b, int amt, uint8_t *ep, int elt, int elm, SesComStat *sp)
{
int idx, i;
/*
* If it's overall enclosure status being sought, get that.
* We need at least 2 bytes of status data to get that.
*/
if (elt == -1) {
if (amt < 2)
return (-1);
gget8(b, 1, sp->comstatus);
sp->comstat[0] = 0;
sp->comstat[1] = 0;
sp->comstat[2] = 0;
return (0);
}
/*
* Check to make sure that the Mth element is legal for type Elt.
*/
if (elm >= ep[elt])
return (-1);
/*
* Starting at offset 8, start skipping over the storage
* for the element types we're not interested in.
*/
for (idx = 8, i = 0; i < elt; i++) {
idx += ((ep[i] + 1) * 4);
}
/*
* Skip over Overall status for this element type.
*/
idx += 4;
/*
* And skip to the index for the Mth element that we're going for.
*/
idx += (4 * elm);
/*
* Make sure we haven't overflowed the buffer.
*/
if (idx+4 > amt)
return (-1);
/*
* Retrieve the status.
*/
gget8(b, idx++, sp->comstatus);
gget8(b, idx++, sp->comstat[0]);
gget8(b, idx++, sp->comstat[1]);
gget8(b, idx++, sp->comstat[2]);
#if 0
PRINTF("Get Elt 0x%x Elm 0x%x (idx %d)\n", elt, elm, idx-4);
#endif
return (0);
}
/*
* This is the mirror function to ses_decode, but we set the 'select'
* bit for the object which we're interested in. All other objects,
* after a status fetch, should have that bit off. Hmm. It'd be easy
* enough to ensure this, so we will.
*/
static int
ses_encode(char *b, int amt, uint8_t *ep, int elt, int elm, SesComStat *sp)
{
int idx, i;
/*
* If it's overall enclosure status being sought, get that.
* We need at least 2 bytes of status data to get that.
*/
if (elt == -1) {
if (amt < 2)
return (-1);
i = 0;
sset8(b, i, 0);
sset8(b, i, sp->comstatus & 0xf);
#if 0
PRINTF("set EncStat %x\n", sp->comstatus);
#endif
return (0);
}
/*
* Check to make sure that the Mth element is legal for type Elt.
*/
if (elm >= ep[elt])
return (-1);
/*
* Starting at offset 8, start skipping over the storage
* for the element types we're not interested in.
*/
for (idx = 8, i = 0; i < elt; i++) {
idx += ((ep[i] + 1) * 4);
}
/*
* Skip over Overall status for this element type.
*/
idx += 4;
/*
* And skip to the index for the Mth element that we're going for.
*/
idx += (4 * elm);
/*
* Make sure we haven't overflowed the buffer.
*/
if (idx+4 > amt)
return (-1);
/*
* Set the status.
*/
sset8(b, idx, sp->comstatus);
sset8(b, idx, sp->comstat[0]);
sset8(b, idx, sp->comstat[1]);
sset8(b, idx, sp->comstat[2]);
idx -= 4;
#if 0
PRINTF("Set Elt 0x%x Elm 0x%x (idx %d) with %x %x %x %x\n",
elt, elm, idx, sp->comstatus, sp->comstat[0],
sp->comstat[1], sp->comstat[2]);
#endif
/*
* Now make sure all other 'Select' bits are off.
*/
for (i = 8; i < amt; i += 4) {
if (i != idx)
b[i] &= ~0x80;
}
/*
* And make sure the INVOP bit is clear.
*/
b[2] &= ~0x10;
return (0);
}
/*
* SAF-TE Type Device Emulation
*/
static int safte_getconfig(ses_softc_t *);
static int safte_rdstat(ses_softc_t *, int);;
static int set_objstat_sel(ses_softc_t *, ses_objstat *, int);
static int wrbuf16(ses_softc_t *, uint8_t, uint8_t, uint8_t, uint8_t, int);
static void wrslot_stat(ses_softc_t *, int);
static int perf_slotop(ses_softc_t *, uint8_t, uint8_t, int);
#define ALL_ENC_STAT (SES_ENCSTAT_CRITICAL | SES_ENCSTAT_UNRECOV | \
SES_ENCSTAT_NONCRITICAL | SES_ENCSTAT_INFO)
/*
* SAF-TE specific defines- Mandatory ones only...
*/
/*
* READ BUFFER ('get' commands) IDs- placed in offset 2 of cdb
*/
#define SAFTE_RD_RDCFG 0x00 /* read enclosure configuration */
#define SAFTE_RD_RDESTS 0x01 /* read enclosure status */
#define SAFTE_RD_RDDSTS 0x04 /* read drive slot status */
/*
* WRITE BUFFER ('set' commands) IDs- placed in offset 0 of databuf
*/
#define SAFTE_WT_DSTAT 0x10 /* write device slot status */
#define SAFTE_WT_SLTOP 0x12 /* perform slot operation */
#define SAFTE_WT_FANSPD 0x13 /* set fan speed */
#define SAFTE_WT_ACTPWS 0x14 /* turn on/off power supply */
#define SAFTE_WT_GLOBAL 0x15 /* send global command */
#define SAFT_SCRATCH 64
#define NPSEUDO_THERM 16
#define NPSEUDO_ALARM 1
struct scfg {
/*
* Cached Configuration
*/
uint8_t Nfans; /* Number of Fans */
uint8_t Npwr; /* Number of Power Supplies */
uint8_t Nslots; /* Number of Device Slots */
uint8_t DoorLock; /* Door Lock Installed */
uint8_t Ntherm; /* Number of Temperature Sensors */
uint8_t Nspkrs; /* Number of Speakers */
uint8_t Nalarm; /* Number of Alarms (at least one) */
/*
* Cached Flag Bytes for Global Status
*/
uint8_t flag1;
uint8_t flag2;
/*
* What object index ID is where various slots start.
*/
uint8_t pwroff;
uint8_t slotoff;
#define SAFT_ALARM_OFFSET(cc) (cc)->slotoff - 1
};
#define SAFT_FLG1_ALARM 0x1
#define SAFT_FLG1_GLOBFAIL 0x2
#define SAFT_FLG1_GLOBWARN 0x4
#define SAFT_FLG1_ENCPWROFF 0x8
#define SAFT_FLG1_ENCFANFAIL 0x10
#define SAFT_FLG1_ENCPWRFAIL 0x20
#define SAFT_FLG1_ENCDRVFAIL 0x40
#define SAFT_FLG1_ENCDRVWARN 0x80
#define SAFT_FLG2_LOCKDOOR 0x4
#define SAFT_PRIVATE sizeof (struct scfg)
static char *safte_2little = "Too Little Data Returned (%d) at line %d\n";
#define SAFT_BAIL(r, x, k, l) \
if (r >= x) { \
SES_LOG(ssc, safte_2little, x, __LINE__);\
SES_FREE(k, l); \
return (EIO); \
}
int
safte_softc_init(ses_softc_t *ssc, int doinit)
{
int err, i, r;
struct scfg *cc;
if (doinit == 0) {
if (ssc->ses_nobjects) {
if (ssc->ses_objmap) {
SES_FREE(ssc->ses_objmap,
ssc->ses_nobjects * sizeof (encobj));
ssc->ses_objmap = NULL;
}
ssc->ses_nobjects = 0;
}
if (ssc->ses_private) {
SES_FREE(ssc->ses_private, SAFT_PRIVATE);
ssc->ses_private = NULL;
}
return (0);
}
if (ssc->ses_private == NULL) {
ssc->ses_private = SES_MALLOC(SAFT_PRIVATE);
if (ssc->ses_private == NULL) {
return (ENOMEM);
}
MEMZERO(ssc->ses_private, SAFT_PRIVATE);
}
ssc->ses_nobjects = 0;
ssc->ses_encstat = 0;
if ((err = safte_getconfig(ssc)) != 0) {
return (err);
}
/*
* The number of objects here, as well as that reported by the
* READ_BUFFER/GET_CONFIG call, are the over-temperature flags (15)
* that get reported during READ_BUFFER/READ_ENC_STATUS.
*/
cc = ssc->ses_private;
ssc->ses_nobjects = cc->Nfans + cc->Npwr + cc->Nslots + cc->DoorLock +
cc->Ntherm + cc->Nspkrs + NPSEUDO_THERM + NPSEUDO_ALARM;
ssc->ses_objmap = (encobj *)
SES_MALLOC(ssc->ses_nobjects * sizeof (encobj));
if (ssc->ses_objmap == NULL) {
return (ENOMEM);
}
MEMZERO(ssc->ses_objmap, ssc->ses_nobjects * sizeof (encobj));
r = 0;
/*
* Note that this is all arranged for the convenience
* in later fetches of status.
*/
for (i = 0; i < cc->Nfans; i++)
ssc->ses_objmap[r++].enctype = SESTYP_FAN;
cc->pwroff = (uint8_t) r;
for (i = 0; i < cc->Npwr; i++)
ssc->ses_objmap[r++].enctype = SESTYP_POWER;
for (i = 0; i < cc->DoorLock; i++)
ssc->ses_objmap[r++].enctype = SESTYP_DOORLOCK;
for (i = 0; i < cc->Nspkrs; i++)
ssc->ses_objmap[r++].enctype = SESTYP_ALARM;
for (i = 0; i < cc->Ntherm; i++)
ssc->ses_objmap[r++].enctype = SESTYP_THERM;
for (i = 0; i < NPSEUDO_THERM; i++)
ssc->ses_objmap[r++].enctype = SESTYP_THERM;
ssc->ses_objmap[r++].enctype = SESTYP_ALARM;
cc->slotoff = (uint8_t) r;
for (i = 0; i < cc->Nslots; i++)
ssc->ses_objmap[r++].enctype = SESTYP_DEVICE;
return (0);
}
int
safte_init_enc(ses_softc_t *ssc)
{
int err;
static char cdb0[6] = { SEND_DIAGNOSTIC };
err = ses_runcmd(ssc, cdb0, 6, NULL, 0);
if (err) {
return (err);
}
DELAY(5000);
err = wrbuf16(ssc, SAFTE_WT_GLOBAL, 0, 0, 0, 1);
return (err);
}
int
safte_get_encstat(ses_softc_t *ssc, int slpflg)
{
return (safte_rdstat(ssc, slpflg));
}
int
safte_set_encstat(ses_softc_t *ssc, uint8_t encstat, int slpflg)
{
struct scfg *cc = ssc->ses_private;
if (cc == NULL)
return (0);
/*
* Since SAF-TE devices aren't necessarily sticky in terms
* of state, make our soft copy of enclosure status 'sticky'-
* that is, things set in enclosure status stay set (as implied
* by conditions set in reading object status) until cleared.
*/
ssc->ses_encstat &= ~ALL_ENC_STAT;
ssc->ses_encstat |= (encstat & ALL_ENC_STAT);
ssc->ses_encstat |= ENCI_SVALID;
cc->flag1 &= ~(SAFT_FLG1_ALARM|SAFT_FLG1_GLOBFAIL|SAFT_FLG1_GLOBWARN);
if ((encstat & (SES_ENCSTAT_CRITICAL|SES_ENCSTAT_UNRECOV)) != 0) {
cc->flag1 |= SAFT_FLG1_ALARM|SAFT_FLG1_GLOBFAIL;
} else if ((encstat & SES_ENCSTAT_NONCRITICAL) != 0) {
cc->flag1 |= SAFT_FLG1_GLOBWARN;
}
return (wrbuf16(ssc, SAFTE_WT_GLOBAL, cc->flag1, cc->flag2, 0, slpflg));
}
int
safte_get_objstat(ses_softc_t *ssc, ses_objstat *obp, int slpflg)
{
int i = (int)obp->obj_id;
if ((ssc->ses_encstat & ENCI_SVALID) == 0 ||
(ssc->ses_objmap[i].svalid) == 0) {
int err = safte_rdstat(ssc, slpflg);
if (err)
return (err);
}
obp->cstat[0] = ssc->ses_objmap[i].encstat[0];
obp->cstat[1] = ssc->ses_objmap[i].encstat[1];
obp->cstat[2] = ssc->ses_objmap[i].encstat[2];
obp->cstat[3] = ssc->ses_objmap[i].encstat[3];
return (0);
}
int
safte_set_objstat(ses_softc_t *ssc, ses_objstat *obp, int slp)
{
int idx, err;
encobj *ep;
struct scfg *cc;
SES_DLOG(ssc, "safte_set_objstat(%d): %x %x %x %x\n",
(int)obp->obj_id, obp->cstat[0], obp->cstat[1], obp->cstat[2],
obp->cstat[3]);
/*
* If this is clear, we don't do diddly.
*/
if ((obp->cstat[0] & SESCTL_CSEL) == 0) {
return (0);
}
err = 0;
/*
* Check to see if the common bits are set and do them first.
*/
if (obp->cstat[0] & ~SESCTL_CSEL) {
err = set_objstat_sel(ssc, obp, slp);
if (err)
return (err);
}
cc = ssc->ses_private;
if (cc == NULL)
return (0);
idx = (int)obp->obj_id;
ep = &ssc->ses_objmap[idx];
switch (ep->enctype) {
case SESTYP_DEVICE:
{
uint8_t slotop = 0;
/*
* XXX: I should probably cache the previous state
* XXX: of SESCTL_DEVOFF so that when it goes from
* XXX: true to false I can then set PREPARE FOR OPERATION
* XXX: flag in PERFORM SLOT OPERATION write buffer command.
*/
if (obp->cstat[2] & (SESCTL_RQSINS|SESCTL_RQSRMV)) {
slotop |= 0x2;
}
if (obp->cstat[2] & SESCTL_RQSID) {
slotop |= 0x4;
}
err = perf_slotop(ssc, (uint8_t) idx - (uint8_t) cc->slotoff,
slotop, slp);
if (err)
return (err);
if (obp->cstat[3] & SESCTL_RQSFLT) {
ep->priv |= 0x2;
} else {
ep->priv &= ~0x2;
}
if (ep->priv & 0xc6) {
ep->priv &= ~0x1;
} else {
ep->priv |= 0x1; /* no errors */
}
wrslot_stat(ssc, slp);
break;
}
case SESTYP_POWER:
if (obp->cstat[3] & SESCTL_RQSTFAIL) {
cc->flag1 |= SAFT_FLG1_ENCPWRFAIL;
} else {
cc->flag1 &= ~SAFT_FLG1_ENCPWRFAIL;
}
err = wrbuf16(ssc, SAFTE_WT_GLOBAL, cc->flag1,
cc->flag2, 0, slp);
if (err)
return (err);
if (obp->cstat[3] & SESCTL_RQSTON) {
(void) wrbuf16(ssc, SAFTE_WT_ACTPWS,
idx - cc->pwroff, 0, 0, slp);
} else {
(void) wrbuf16(ssc, SAFTE_WT_ACTPWS,
idx - cc->pwroff, 0, 1, slp);
}
break;
case SESTYP_FAN:
if (obp->cstat[3] & SESCTL_RQSTFAIL) {
cc->flag1 |= SAFT_FLG1_ENCFANFAIL;
} else {
cc->flag1 &= ~SAFT_FLG1_ENCFANFAIL;
}
err = wrbuf16(ssc, SAFTE_WT_GLOBAL, cc->flag1,
cc->flag2, 0, slp);
if (err)
return (err);
if (obp->cstat[3] & SESCTL_RQSTON) {
uint8_t fsp;
if ((obp->cstat[3] & 0x7) == 7) {
fsp = 4;
} else if ((obp->cstat[3] & 0x7) == 6) {
fsp = 3;
} else if ((obp->cstat[3] & 0x7) == 4) {
fsp = 2;
} else {
fsp = 1;
}
(void) wrbuf16(ssc, SAFTE_WT_FANSPD, idx, fsp, 0, slp);
} else {
(void) wrbuf16(ssc, SAFTE_WT_FANSPD, idx, 0, 0, slp);
}
break;
case SESTYP_DOORLOCK:
if (obp->cstat[3] & 0x1) {
cc->flag2 &= ~SAFT_FLG2_LOCKDOOR;
} else {
cc->flag2 |= SAFT_FLG2_LOCKDOOR;
}
(void) wrbuf16(ssc, SAFTE_WT_GLOBAL, cc->flag1,
cc->flag2, 0, slp);
break;
case SESTYP_ALARM:
/*
* On all nonzero but the 'muted' bit, we turn on the alarm,
*/
obp->cstat[3] &= ~0xa;
if (obp->cstat[3] & 0x40) {
cc->flag2 &= ~SAFT_FLG1_ALARM;
} else if (obp->cstat[3] != 0) {
cc->flag2 |= SAFT_FLG1_ALARM;
} else {
cc->flag2 &= ~SAFT_FLG1_ALARM;
}
ep->priv = obp->cstat[3];
(void) wrbuf16(ssc, SAFTE_WT_GLOBAL, cc->flag1,
cc->flag2, 0, slp);
break;
default:
break;
}
ep->svalid = 0;
return (0);
}
static int
safte_getconfig(ses_softc_t *ssc)
{
struct scfg *cfg;
int err, amt;
char *sdata;
static char cdb[10] =
{ READ_BUFFER, 1, SAFTE_RD_RDCFG, 0, 0, 0, 0, 0, SAFT_SCRATCH, 0 };
cfg = ssc->ses_private;
if (cfg == NULL)
return (ENXIO);
sdata = SES_MALLOC(SAFT_SCRATCH);
if (sdata == NULL)
return (ENOMEM);
amt = SAFT_SCRATCH;
err = ses_runcmd(ssc, cdb, 10, sdata, &amt);
if (err) {
SES_FREE(sdata, SAFT_SCRATCH);
return (err);
}
amt = SAFT_SCRATCH - amt;
if (amt < 6) {
SES_LOG(ssc, "too little data (%d) for configuration\n", amt);
SES_FREE(sdata, SAFT_SCRATCH);
return (EIO);
}
SES_VLOG(ssc, "Nfans %d Npwr %d Nslots %d Lck %d Ntherm %d Nspkrs %d\n",
sdata[0], sdata[1], sdata[2], sdata[3], sdata[4], sdata[5]);
cfg->Nfans = sdata[0];
cfg->Npwr = sdata[1];
cfg->Nslots = sdata[2];
cfg->DoorLock = sdata[3];
cfg->Ntherm = sdata[4];
cfg->Nspkrs = sdata[5];
cfg->Nalarm = NPSEUDO_ALARM;
SES_FREE(sdata, SAFT_SCRATCH);
return (0);
}
static int
safte_rdstat(ses_softc_t *ssc, int slpflg)
{
int err, oid, r, i, hiwater, nitems, amt;
uint16_t tempflags;
size_t buflen;
uint8_t status, oencstat;
char *sdata, cdb[10];
struct scfg *cc = ssc->ses_private;
/*
* The number of objects overstates things a bit,
* both for the bogus 'thermometer' entries and
* the drive status (which isn't read at the same
* time as the enclosure status), but that's okay.
*/
buflen = 4 * cc->Nslots;
if (ssc->ses_nobjects > buflen)
buflen = ssc->ses_nobjects;
sdata = SES_MALLOC(buflen);
if (sdata == NULL)
return (ENOMEM);
cdb[0] = READ_BUFFER;
cdb[1] = 1;
cdb[2] = SAFTE_RD_RDESTS;
cdb[3] = 0;
cdb[4] = 0;
cdb[5] = 0;
cdb[6] = 0;
cdb[7] = (buflen >> 8) & 0xff;
cdb[8] = buflen & 0xff;
cdb[9] = 0;
amt = buflen;
err = ses_runcmd(ssc, cdb, 10, sdata, &amt);
if (err) {
SES_FREE(sdata, buflen);
return (err);
}
hiwater = buflen - amt;
/*
* invalidate all status bits.
*/
for (i = 0; i < ssc->ses_nobjects; i++)
ssc->ses_objmap[i].svalid = 0;
oencstat = ssc->ses_encstat & ALL_ENC_STAT;
ssc->ses_encstat = 0;
/*
* Now parse returned buffer.
* If we didn't get enough data back,
* that's considered a fatal error.
*/
oid = r = 0;
for (nitems = i = 0; i < cc->Nfans; i++) {
SAFT_BAIL(r, hiwater, sdata, buflen);
/*
* 0 = Fan Operational
* 1 = Fan is malfunctioning
* 2 = Fan is not present
* 0x80 = Unknown or Not Reportable Status
*/
ssc->ses_objmap[oid].encstat[1] = 0; /* resvd */
ssc->ses_objmap[oid].encstat[2] = 0; /* resvd */
switch ((int)(uint8_t)sdata[r]) {
case 0:
nitems++;
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_OK;
/*
* We could get fancier and cache
* fan speeds that we have set, but
* that isn't done now.
*/
ssc->ses_objmap[oid].encstat[3] = 7;
break;
case 1:
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_CRIT;
/*
* FAIL and FAN STOPPED synthesized
*/
ssc->ses_objmap[oid].encstat[3] = 0x40;
/*
* Enclosure marked with CRITICAL error
* if only one fan or no thermometers,
* else the NONCRITICAL error is set.
*/
if (cc->Nfans == 1 || cc->Ntherm == 0)
ssc->ses_encstat |= SES_ENCSTAT_CRITICAL;
else
ssc->ses_encstat |= SES_ENCSTAT_NONCRITICAL;
break;
case 2:
ssc->ses_objmap[oid].encstat[0] =
SES_OBJSTAT_NOTINSTALLED;
ssc->ses_objmap[oid].encstat[3] = 0;
/*
* Enclosure marked with CRITICAL error
* if only one fan or no thermometers,
* else the NONCRITICAL error is set.
*/
if (cc->Nfans == 1)
ssc->ses_encstat |= SES_ENCSTAT_CRITICAL;
else
ssc->ses_encstat |= SES_ENCSTAT_NONCRITICAL;
break;
case 0x80:
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_UNKNOWN;
ssc->ses_objmap[oid].encstat[3] = 0;
ssc->ses_encstat |= SES_ENCSTAT_INFO;
break;
default:
ssc->ses_objmap[oid].encstat[0] =
SES_OBJSTAT_UNSUPPORTED;
SES_LOG(ssc, "Unknown fan%d status 0x%x\n", i,
sdata[r] & 0xff);
break;
}
ssc->ses_objmap[oid++].svalid = 1;
r++;
}
/*
* No matter how you cut it, no cooling elements when there
* should be some there is critical.
*/
if (cc->Nfans && nitems == 0) {
ssc->ses_encstat |= SES_ENCSTAT_CRITICAL;
}
for (i = 0; i < cc->Npwr; i++) {
SAFT_BAIL(r, hiwater, sdata, buflen);
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_UNKNOWN;
ssc->ses_objmap[oid].encstat[1] = 0; /* resvd */
ssc->ses_objmap[oid].encstat[2] = 0; /* resvd */
ssc->ses_objmap[oid].encstat[3] = 0x20; /* requested on */
switch ((uint8_t)sdata[r]) {
case 0x00: /* pws operational and on */
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_OK;
break;
case 0x01: /* pws operational and off */
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_OK;
ssc->ses_objmap[oid].encstat[3] = 0x10;
ssc->ses_encstat |= SES_ENCSTAT_INFO;
break;
case 0x10: /* pws is malfunctioning and commanded on */
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_CRIT;
ssc->ses_objmap[oid].encstat[3] = 0x61;
ssc->ses_encstat |= SES_ENCSTAT_NONCRITICAL;
break;
case 0x11: /* pws is malfunctioning and commanded off */
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_NONCRIT;
ssc->ses_objmap[oid].encstat[3] = 0x51;
ssc->ses_encstat |= SES_ENCSTAT_NONCRITICAL;
break;
case 0x20: /* pws is not present */
ssc->ses_objmap[oid].encstat[0] =
SES_OBJSTAT_NOTINSTALLED;
ssc->ses_objmap[oid].encstat[3] = 0;
ssc->ses_encstat |= SES_ENCSTAT_INFO;
break;
case 0x21: /* pws is present */
/*
* This is for enclosures that cannot tell whether the
* device is on or malfunctioning, but know that it is
* present. Just fall through.
*/
/* FALLTHROUGH */
case 0x80: /* Unknown or Not Reportable Status */
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_UNKNOWN;
ssc->ses_objmap[oid].encstat[3] = 0;
ssc->ses_encstat |= SES_ENCSTAT_INFO;
break;
default:
SES_LOG(ssc, "unknown power supply %d status (0x%x)\n",
i, sdata[r] & 0xff);
break;
}
ssc->ses_objmap[oid++].svalid = 1;
r++;
}
/*
* Skip over Slot SCSI IDs
*/
r += cc->Nslots;
/*
* We always have doorlock status, no matter what,
* but we only save the status if we have one.
*/
SAFT_BAIL(r, hiwater, sdata, buflen);
if (cc->DoorLock) {
/*
* 0 = Door Locked
* 1 = Door Unlocked, or no Lock Installed
* 0x80 = Unknown or Not Reportable Status
*/
ssc->ses_objmap[oid].encstat[1] = 0;
ssc->ses_objmap[oid].encstat[2] = 0;
switch ((uint8_t)sdata[r]) {
case 0:
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_OK;
ssc->ses_objmap[oid].encstat[3] = 0;
break;
case 1:
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_OK;
ssc->ses_objmap[oid].encstat[3] = 1;
break;
case 0x80:
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_UNKNOWN;
ssc->ses_objmap[oid].encstat[3] = 0;
ssc->ses_encstat |= SES_ENCSTAT_INFO;
break;
default:
ssc->ses_objmap[oid].encstat[0] =
SES_OBJSTAT_UNSUPPORTED;
SES_LOG(ssc, "unknown lock status 0x%x\n",
sdata[r] & 0xff);
break;
}
ssc->ses_objmap[oid++].svalid = 1;
}
r++;
/*
* We always have speaker status, no matter what,
* but we only save the status if we have one.
*/
SAFT_BAIL(r, hiwater, sdata, buflen);
if (cc->Nspkrs) {
ssc->ses_objmap[oid].encstat[1] = 0;
ssc->ses_objmap[oid].encstat[2] = 0;
if (sdata[r] == 1) {
/*
* We need to cache tone urgency indicators.
* Someday.
*/
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_NONCRIT;
ssc->ses_objmap[oid].encstat[3] = 0x8;
ssc->ses_encstat |= SES_ENCSTAT_NONCRITICAL;
} else if (sdata[r] == 0) {
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_OK;
ssc->ses_objmap[oid].encstat[3] = 0;
} else {
ssc->ses_objmap[oid].encstat[0] =
SES_OBJSTAT_UNSUPPORTED;
ssc->ses_objmap[oid].encstat[3] = 0;
SES_LOG(ssc, "unknown spkr status 0x%x\n",
sdata[r] & 0xff);
}
ssc->ses_objmap[oid++].svalid = 1;
}
r++;
for (i = 0; i < cc->Ntherm; i++) {
SAFT_BAIL(r, hiwater, sdata, buflen);
/*
* Status is a range from -10 to 245 deg Celsius,
* which we need to normalize to -20 to -245 according
* to the latest SCSI spec, which makes little
* sense since this would overflow an 8bit value.
* Well, still, the base normalization is -20,
* not -10, so we have to adjust.
*
* So what's over and under temperature?
* Hmm- we'll state that 'normal' operating
* is 10 to 40 deg Celsius.
*/
/*
* Actually.... All of the units that people out in the world
* seem to have do not come even close to setting a value that
* complies with this spec.
*
* The closest explanation I could find was in an
* LSI-Logic manual, which seemed to indicate that
* this value would be set by whatever the I2C code
* would interpolate from the output of an LM75
* temperature sensor.
*
* This means that it is impossible to use the actual
* numeric value to predict anything. But we don't want
* to lose the value. So, we'll propagate the *uncorrected*
* value and set SES_OBJSTAT_NOTAVAIL. We'll depend on the
* temperature flags for warnings.
*/
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_NOTAVAIL;
ssc->ses_objmap[oid].encstat[1] = 0;
ssc->ses_objmap[oid].encstat[2] = sdata[r];
ssc->ses_objmap[oid].encstat[3] = 0;;
ssc->ses_objmap[oid++].svalid = 1;
r++;
}
/*
* Now, for "pseudo" thermometers, we have two bytes
* of information in enclosure status- 16 bits. Actually,
* the MSB is a single TEMP ALERT flag indicating whether
* any other bits are set, but, thanks to fuzzy thinking,
* in the SAF-TE spec, this can also be set even if no
* other bits are set, thus making this really another
* binary temperature sensor.
*/
SAFT_BAIL(r, hiwater, sdata, buflen);
tempflags = sdata[r++];
SAFT_BAIL(r, hiwater, sdata, buflen);
tempflags |= (tempflags << 8) | sdata[r++];
for (i = 0; i < NPSEUDO_THERM; i++) {
ssc->ses_objmap[oid].encstat[1] = 0;
if (tempflags & (1 << (NPSEUDO_THERM - i - 1))) {
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_CRIT;
ssc->ses_objmap[4].encstat[2] = 0xff;
/*
* Set 'over temperature' failure.
*/
ssc->ses_objmap[oid].encstat[3] = 8;
ssc->ses_encstat |= SES_ENCSTAT_CRITICAL;
} else {
/*
* We used to say 'not available' and synthesize a
* nominal 30 deg (C)- that was wrong. Actually,
* Just say 'OK', and use the reserved value of
* zero.
*/
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_OK;
ssc->ses_objmap[oid].encstat[2] = 0;
ssc->ses_objmap[oid].encstat[3] = 0;
}
ssc->ses_objmap[oid++].svalid = 1;
}
/*
* Get alarm status.
*/
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_OK;
ssc->ses_objmap[oid].encstat[3] = ssc->ses_objmap[oid].priv;
ssc->ses_objmap[oid++].svalid = 1;
/*
* Now get drive slot status
*/
cdb[2] = SAFTE_RD_RDDSTS;
amt = buflen;
err = ses_runcmd(ssc, cdb, 10, sdata, &amt);
if (err) {
SES_FREE(sdata, buflen);
return (err);
}
hiwater = buflen - amt;
for (r = i = 0; i < cc->Nslots; i++, r += 4) {
SAFT_BAIL(r+3, hiwater, sdata, buflen);
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_UNSUPPORTED;
ssc->ses_objmap[oid].encstat[1] = (uint8_t) i;
ssc->ses_objmap[oid].encstat[2] = 0;
ssc->ses_objmap[oid].encstat[3] = 0;
status = sdata[r+3];
if ((status & 0x1) == 0) { /* no device */
ssc->ses_objmap[oid].encstat[0] =
SES_OBJSTAT_NOTINSTALLED;
} else {
ssc->ses_objmap[oid].encstat[0] = SES_OBJSTAT_OK;
}
if (status & 0x2) {
ssc->ses_objmap[oid].encstat[2] = 0x8;
}
if ((status & 0x4) == 0) {
ssc->ses_objmap[oid].encstat[3] = 0x10;
}
ssc->ses_objmap[oid++].svalid = 1;
}
/* see comment below about sticky enclosure status */
ssc->ses_encstat |= ENCI_SVALID | oencstat;
SES_FREE(sdata, buflen);
return (0);
}
static int
set_objstat_sel(ses_softc_t *ssc, ses_objstat *obp, int slp)
{
int idx;
encobj *ep;
struct scfg *cc = ssc->ses_private;
if (cc == NULL)
return (0);
idx = (int)obp->obj_id;
ep = &ssc->ses_objmap[idx];
switch (ep->enctype) {
case SESTYP_DEVICE:
if (obp->cstat[0] & SESCTL_PRDFAIL) {
ep->priv |= 0x40;
}
/* SESCTL_RSTSWAP has no correspondence in SAF-TE */
if (obp->cstat[0] & SESCTL_DISABLE) {
ep->priv |= 0x80;
/*
* Hmm. Try to set the 'No Drive' flag.
* Maybe that will count as a 'disable'.
*/
}
if (ep->priv & 0xc6) {
ep->priv &= ~0x1;
} else {
ep->priv |= 0x1; /* no errors */
}
wrslot_stat(ssc, slp);
break;
case SESTYP_POWER:
/*
* Okay- the only one that makes sense here is to
* do the 'disable' for a power supply.
*/
if (obp->cstat[0] & SESCTL_DISABLE) {
(void) wrbuf16(ssc, SAFTE_WT_ACTPWS,
idx - cc->pwroff, 0, 0, slp);
}
break;
case SESTYP_FAN:
/*
* Okay- the only one that makes sense here is to
* set fan speed to zero on disable.
*/
if (obp->cstat[0] & SESCTL_DISABLE) {
/* remember- fans are the first items, so idx works */
(void) wrbuf16(ssc, SAFTE_WT_FANSPD, idx, 0, 0, slp);
}
break;
case SESTYP_DOORLOCK:
/*
* Well, we can 'disable' the lock.
*/
if (obp->cstat[0] & SESCTL_DISABLE) {
cc->flag2 &= ~SAFT_FLG2_LOCKDOOR;
(void) wrbuf16(ssc, SAFTE_WT_GLOBAL, cc->flag1,
cc->flag2, 0, slp);
}
break;
case SESTYP_ALARM:
/*
* Well, we can 'disable' the alarm.
*/
if (obp->cstat[0] & SESCTL_DISABLE) {
cc->flag2 &= ~SAFT_FLG1_ALARM;
ep->priv |= 0x40; /* Muted */
(void) wrbuf16(ssc, SAFTE_WT_GLOBAL, cc->flag1,
cc->flag2, 0, slp);
}
break;
default:
break;
}
ep->svalid = 0;
return (0);
}
/*
* This function handles all of the 16 byte WRITE BUFFER commands.
*/
static int
wrbuf16(ses_softc_t *ssc, uint8_t op, uint8_t b1, uint8_t b2,
uint8_t b3, int slp)
{
int err, amt;
char *sdata;
struct scfg *cc = ssc->ses_private;
static char cdb[10] = { WRITE_BUFFER, 1, 0, 0, 0, 0, 0, 0, 16, 0 };
if (cc == NULL)
return (0);
sdata = SES_MALLOC(16);
if (sdata == NULL)
return (ENOMEM);
SES_DLOG(ssc, "saf_wrbuf16 %x %x %x %x\n", op, b1, b2, b3);
sdata[0] = op;
sdata[1] = b1;
sdata[2] = b2;
sdata[3] = b3;
MEMZERO(&sdata[4], 12);
amt = -16;
err = ses_runcmd(ssc, cdb, 10, sdata, &amt);
SES_FREE(sdata, 16);
return (err);
}
/*
* This function updates the status byte for the device slot described.
*
* Since this is an optional SAF-TE command, there's no point in
* returning an error.
*/
static void
wrslot_stat(ses_softc_t *ssc, int slp)
{
int i, amt;
encobj *ep;
char cdb[10], *sdata;
struct scfg *cc = ssc->ses_private;
if (cc == NULL)
return;
SES_DLOG(ssc, "saf_wrslot\n");
cdb[0] = WRITE_BUFFER;
cdb[1] = 1;
cdb[2] = 0;
cdb[3] = 0;
cdb[4] = 0;
cdb[5] = 0;
cdb[6] = 0;
cdb[7] = 0;
cdb[8] = cc->Nslots * 3 + 1;
cdb[9] = 0;
sdata = SES_MALLOC(cc->Nslots * 3 + 1);
if (sdata == NULL)
return;
MEMZERO(sdata, cc->Nslots * 3 + 1);
sdata[0] = SAFTE_WT_DSTAT;
for (i = 0; i < cc->Nslots; i++) {
ep = &ssc->ses_objmap[cc->slotoff + i];
SES_DLOG(ssc, "saf_wrslot %d <- %x\n", i, ep->priv & 0xff);
sdata[1 + (3 * i)] = ep->priv & 0xff;
}
amt = -(cc->Nslots * 3 + 1);
(void) ses_runcmd(ssc, cdb, 10, sdata, &amt);
SES_FREE(sdata, cc->Nslots * 3 + 1);
}
/*
* This function issues the "PERFORM SLOT OPERATION" command.
*/
static int
perf_slotop(ses_softc_t *ssc, uint8_t slot, uint8_t opflag, int slp)
{
int err, amt;
char *sdata;
struct scfg *cc = ssc->ses_private;
static char cdb[10] =
{ WRITE_BUFFER, 1, 0, 0, 0, 0, 0, 0, SAFT_SCRATCH, 0 };
if (cc == NULL)
return (0);
sdata = SES_MALLOC(SAFT_SCRATCH);
if (sdata == NULL)
return (ENOMEM);
MEMZERO(sdata, SAFT_SCRATCH);
sdata[0] = SAFTE_WT_SLTOP;
sdata[1] = slot;
sdata[2] = opflag;
SES_DLOG(ssc, "saf_slotop slot %d op %x\n", slot, opflag);
amt = -SAFT_SCRATCH;
err = ses_runcmd(ssc, cdb, 10, sdata, &amt);
SES_FREE(sdata, SAFT_SCRATCH);
return (err);
}