/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * A CPR derivative specifically for starfire/starcat */ #include #include #include #include #include #define SUNDDI_IMPL #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include extern void e_ddi_enter_driver_list(struct devnames *dnp, int *listcnt); extern void e_ddi_exit_driver_list(struct devnames *dnp, int listcnt); extern int is_pseudo_device(dev_info_t *dip); extern kmutex_t cpu_lock; extern dr_unsafe_devs_t dr_unsafe_devs; static int dr_is_real_device(dev_info_t *dip); static int dr_is_unsafe_major(major_t major); static int dr_bypass_device(char *dname); static int dr_check_dip(dev_info_t *dip, void *arg, uint_t ref); static int dr_resolve_devname(dev_info_t *dip, char *buffer, char *alias); static sbd_error_t *drerr_int(int e_code, uint64_t *arr, int idx, int majors); static int dr_add_int(uint64_t *arr, int idx, int len, uint64_t val); int dr_pt_test_suspend(dr_handle_t *hp); /* * dr_quiesce.c interface * NOTE: states used internally by dr_suspend and dr_resume */ typedef enum dr_suspend_state { DR_SRSTATE_BEGIN = 0, DR_SRSTATE_USER, DR_SRSTATE_DRIVER, DR_SRSTATE_FULL } suspend_state_t; struct dr_sr_handle { dr_handle_t *sr_dr_handlep; dev_info_t *sr_failed_dip; suspend_state_t sr_suspend_state; uint_t sr_flags; uint64_t sr_err_ints[DR_MAX_ERR_INT]; int sr_err_idx; }; #define SR_FLAG_WATCHDOG 0x1 /* * XXX * This hack will go away before RTI. Just for testing. * List of drivers to bypass when performing a suspend. */ static char *dr_bypass_list[] = { "" }; #define SKIP_SYNC /* bypass sync ops in dr_suspend */ /* * dr_skip_user_threads is used to control if user threads should * be suspended. If dr_skip_user_threads is true, the rest of the * flags are not used; if it is false, dr_check_user_stop_result * will be used to control whether or not we need to check suspend * result, and dr_allow_blocked_threads will be used to control * whether or not we allow suspend to continue if there are blocked * threads. We allow all combinations of dr_check_user_stop_result * and dr_allow_block_threads, even though it might not make much * sense to not allow block threads when we don't even check stop * result. */ static int dr_skip_user_threads = 0; /* default to FALSE */ static int dr_check_user_stop_result = 1; /* default to TRUE */ static int dr_allow_blocked_threads = 1; /* default to TRUE */ #define DR_CPU_LOOP_MSEC 1000 static void dr_stop_intr(void) { ASSERT(MUTEX_HELD(&cpu_lock)); kpreempt_disable(); cyclic_suspend(); } static void dr_enable_intr(void) { ASSERT(MUTEX_HELD(&cpu_lock)); cyclic_resume(); kpreempt_enable(); } dr_sr_handle_t * dr_get_sr_handle(dr_handle_t *hp) { dr_sr_handle_t *srh; srh = GETSTRUCT(dr_sr_handle_t, 1); srh->sr_dr_handlep = hp; return (srh); } void dr_release_sr_handle(dr_sr_handle_t *srh) { ASSERT(srh->sr_failed_dip == NULL); FREESTRUCT(srh, dr_sr_handle_t, 1); } static int dr_is_real_device(dev_info_t *dip) { struct regspec *regbuf = NULL; int length = 0; int rc; if (ddi_get_driver(dip) == NULL) return (0); if (DEVI(dip)->devi_pm_flags & (PMC_NEEDS_SR|PMC_PARENTAL_SR)) return (1); if (DEVI(dip)->devi_pm_flags & PMC_NO_SR) return (0); /* * now the general case */ rc = ddi_getlongprop(DDI_DEV_T_ANY, dip, DDI_PROP_DONTPASS, "reg", (caddr_t)®buf, &length); ASSERT(rc != DDI_PROP_NO_MEMORY); if (rc != DDI_PROP_SUCCESS) { return (0); } else { if ((length > 0) && (regbuf != NULL)) kmem_free(regbuf, length); return (1); } } static int dr_is_unsafe_major(major_t major) { char *dname, **cpp; int i, ndevs; if ((dname = ddi_major_to_name(major)) == NULL) { PR_QR("dr_is_unsafe_major: invalid major # %d\n", major); return (0); } ndevs = dr_unsafe_devs.ndevs; for (i = 0, cpp = dr_unsafe_devs.devnames; i < ndevs; i++) { if (strcmp(dname, *cpp++) == 0) return (1); } return (0); } static int dr_bypass_device(char *dname) { int i; char **lname; /* check the bypass list */ for (i = 0, lname = &dr_bypass_list[i]; **lname != '\0'; lname++) { if (strcmp(dname, dr_bypass_list[i++]) == 0) return (1); } return (0); } static int dr_resolve_devname(dev_info_t *dip, char *buffer, char *alias) { major_t devmajor; char *aka, *name; *buffer = *alias = 0; if (dip == NULL) return (-1); if ((name = ddi_get_name(dip)) == NULL) name = ""; aka = name; if ((devmajor = ddi_name_to_major(aka)) != -1) aka = ddi_major_to_name(devmajor); strcpy(buffer, name); if (strcmp(name, aka)) strcpy(alias, aka); else *alias = 0; return (0); } struct dr_ref { int *refcount; uint64_t *arr; int *idx; int len; }; /* ARGSUSED */ static int dr_check_dip(dev_info_t *dip, void *arg, uint_t ref) { major_t major; char *dname; struct dr_ref *rp = (struct dr_ref *)arg; if (dip == NULL) return (DDI_WALK_CONTINUE); if (!dr_is_real_device(dip)) return (DDI_WALK_CONTINUE); dname = ddi_binding_name(dip); if (dr_bypass_device(dname)) return (DDI_WALK_CONTINUE); if (dname && ((major = ddi_name_to_major(dname)) != (major_t)-1)) { if (ref && rp->refcount) { *rp->refcount += ref; PR_QR("\n %s (major# %d) is referenced(%u)\n", dname, major, ref); } if (dr_is_unsafe_major(major) && i_ddi_node_state(dip) >= DS_ATTACHED) { PR_QR("\n %s (major# %d) not hotpluggable\n", dname, major); if (rp->arr != NULL && rp->idx != NULL) *rp->idx = dr_add_int(rp->arr, *rp->idx, rp->len, (uint64_t)major); } } return (DDI_WALK_CONTINUE); } static int dr_check_unsafe_major(dev_info_t *dip, void *arg) { return (dr_check_dip(dip, arg, 0)); } /*ARGSUSED*/ void dr_check_devices(dev_info_t *dip, int *refcount, dr_handle_t *handle, uint64_t *arr, int *idx, int len) { struct dr_ref bref = {0}; if (dip == NULL) return; bref.refcount = refcount; bref.arr = arr; bref.idx = idx; bref.len = len; ASSERT(e_ddi_branch_held(dip)); (void) e_ddi_branch_referenced(dip, dr_check_dip, &bref); } /* * The "dip" argument's parent (if it exists) must be held busy. */ static int dr_suspend_devices(dev_info_t *dip, dr_sr_handle_t *srh) { dr_handle_t *handle; major_t major; char *dname; int circ; /* * If dip is the root node, it has no siblings and it is * always held. If dip is not the root node, dr_suspend_devices() * will be invoked with the parent held busy. */ for (; dip != NULL; dip = ddi_get_next_sibling(dip)) { char d_name[40], d_alias[40], *d_info; ndi_devi_enter(dip, &circ); if (dr_suspend_devices(ddi_get_child(dip), srh)) { ndi_devi_exit(dip, circ); return (ENXIO); } ndi_devi_exit(dip, circ); if (!dr_is_real_device(dip)) continue; major = (major_t)-1; if ((dname = ddi_binding_name(dip)) != NULL) major = ddi_name_to_major(dname); if (dr_bypass_device(dname)) { PR_QR(" bypassed suspend of %s (major# %d)\n", dname, major); continue; } if (drmach_verify_sr(dip, 1)) { PR_QR(" bypassed suspend of %s (major# %d)\n", dname, major); continue; } if ((d_info = ddi_get_name_addr(dip)) == NULL) d_info = ""; d_name[0] = 0; if (dr_resolve_devname(dip, d_name, d_alias) == 0) { if (d_alias[0] != 0) { prom_printf("\tsuspending %s@%s (aka %s)\n", d_name, d_info, d_alias); } else { prom_printf("\tsuspending %s@%s\n", d_name, d_info); } } else { prom_printf("\tsuspending %s@%s\n", dname, d_info); } if (devi_detach(dip, DDI_SUSPEND) != DDI_SUCCESS) { prom_printf("\tFAILED to suspend %s@%s\n", d_name[0] ? d_name : dname, d_info); srh->sr_err_idx = dr_add_int(srh->sr_err_ints, srh->sr_err_idx, DR_MAX_ERR_INT, (uint64_t)major); ndi_hold_devi(dip); srh->sr_failed_dip = dip; handle = srh->sr_dr_handlep; dr_op_err(CE_IGNORE, handle, ESBD_SUSPEND, "%s@%s", d_name[0] ? d_name : dname, d_info); return (DDI_FAILURE); } } return (DDI_SUCCESS); } static void dr_resume_devices(dev_info_t *start, dr_sr_handle_t *srh) { dr_handle_t *handle; dev_info_t *dip, *next, *last = NULL; major_t major; char *bn; int circ; major = (major_t)-1; /* attach in reverse device tree order */ while (last != start) { dip = start; next = ddi_get_next_sibling(dip); while (next != last && dip != srh->sr_failed_dip) { dip = next; next = ddi_get_next_sibling(dip); } if (dip == srh->sr_failed_dip) { /* release hold acquired in dr_suspend_devices() */ srh->sr_failed_dip = NULL; ndi_rele_devi(dip); } else if (dr_is_real_device(dip) && srh->sr_failed_dip == NULL) { if ((bn = ddi_binding_name(dip)) != NULL) { major = ddi_name_to_major(bn); } else { bn = ""; } if (!dr_bypass_device(bn) && !drmach_verify_sr(dip, 0)) { char d_name[40], d_alias[40], *d_info; d_name[0] = 0; d_info = ddi_get_name_addr(dip); if (d_info == NULL) d_info = ""; if (!dr_resolve_devname(dip, d_name, d_alias)) { if (d_alias[0] != 0) { prom_printf("\tresuming " "%s@%s (aka %s)\n", d_name, d_info, d_alias); } else { prom_printf("\tresuming " "%s@%s\n", d_name, d_info); } } else { prom_printf("\tresuming %s@%s\n", bn, d_info); } if (devi_attach(dip, DDI_RESUME) != DDI_SUCCESS) { /* * Print a console warning, * set an e_code of ESBD_RESUME, * and save the driver major * number in the e_rsc. */ prom_printf("\tFAILED to resume %s@%s", d_name[0] ? d_name : bn, d_info); srh->sr_err_idx = dr_add_int(srh->sr_err_ints, srh->sr_err_idx, DR_MAX_ERR_INT, (uint64_t)major); handle = srh->sr_dr_handlep; dr_op_err(CE_IGNORE, handle, ESBD_RESUME, "%s@%s", d_name[0] ? d_name : bn, d_info); } } } /* Hold parent busy while walking its children */ ndi_devi_enter(dip, &circ); dr_resume_devices(ddi_get_child(dip), srh); ndi_devi_exit(dip, circ); last = dip; } } /* * True if thread is virtually stopped. Similar to CPR_VSTOPPED * but from DR point of view. These user threads are waiting in * the kernel. Once they complete in the kernel, they will process * the stop signal and stop. */ #define DR_VSTOPPED(t) \ ((t)->t_state == TS_SLEEP && \ (t)->t_wchan != NULL && \ (t)->t_astflag && \ ((t)->t_proc_flag & TP_CHKPT)) /* ARGSUSED */ static int dr_stop_user_threads(dr_sr_handle_t *srh) { int count; int bailout; dr_handle_t *handle = srh->sr_dr_handlep; static fn_t f = "dr_stop_user_threads"; kthread_id_t tp; extern void add_one_utstop(); extern void utstop_timedwait(clock_t); extern void utstop_init(void); #define DR_UTSTOP_RETRY 4 #define DR_UTSTOP_WAIT hz if (dr_skip_user_threads) return (DDI_SUCCESS); utstop_init(); /* we need to try a few times to get past fork, etc. */ srh->sr_err_idx = 0; for (count = 0; count < DR_UTSTOP_RETRY; count++) { /* walk the entire threadlist */ mutex_enter(&pidlock); for (tp = curthread->t_next; tp != curthread; tp = tp->t_next) { proc_t *p = ttoproc(tp); /* handle kernel threads separately */ if (p->p_as == &kas || p->p_stat == SZOMB) continue; mutex_enter(&p->p_lock); thread_lock(tp); if (tp->t_state == TS_STOPPED) { /* add another reason to stop this thread */ tp->t_schedflag &= ~TS_RESUME; } else { tp->t_proc_flag |= TP_CHKPT; thread_unlock(tp); mutex_exit(&p->p_lock); add_one_utstop(); mutex_enter(&p->p_lock); thread_lock(tp); aston(tp); if (tp->t_state == TS_SLEEP && (tp->t_flag & T_WAKEABLE)) { setrun_locked(tp); } } /* grab thread if needed */ if (tp->t_state == TS_ONPROC && tp->t_cpu != CPU) poke_cpu(tp->t_cpu->cpu_id); thread_unlock(tp); mutex_exit(&p->p_lock); } mutex_exit(&pidlock); /* let everything catch up */ utstop_timedwait(count * count * DR_UTSTOP_WAIT); /* now, walk the threadlist again to see if we are done */ mutex_enter(&pidlock); for (tp = curthread->t_next, bailout = 0; tp != curthread; tp = tp->t_next) { proc_t *p = ttoproc(tp); /* handle kernel threads separately */ if (p->p_as == &kas || p->p_stat == SZOMB) continue; /* * If this thread didn't stop, and we don't allow * unstopped blocked threads, bail. */ thread_lock(tp); if (!CPR_ISTOPPED(tp) && !(dr_allow_blocked_threads && DR_VSTOPPED(tp))) { bailout = 1; if (count == DR_UTSTOP_RETRY - 1) { /* * save the pid for later reporting */ srh->sr_err_idx = dr_add_int(srh->sr_err_ints, srh->sr_err_idx, DR_MAX_ERR_INT, (uint64_t)p->p_pid); cmn_err(CE_WARN, "%s: " "failed to stop thread: " "process=%s, pid=%d", f, p->p_user.u_psargs, p->p_pid); PR_QR("%s: failed to stop thread: " "process=%s, pid=%d, t_id=0x%p, " "t_state=0x%x, t_proc_flag=0x%x, " "t_schedflag=0x%x\n", f, p->p_user.u_psargs, p->p_pid, tp, tp->t_state, tp->t_proc_flag, tp->t_schedflag); } } thread_unlock(tp); } mutex_exit(&pidlock); /* were all the threads stopped? */ if (!bailout) break; } /* were we unable to stop all threads after a few tries? */ if (bailout) { handle->h_err = drerr_int(ESBD_UTHREAD, srh->sr_err_ints, srh->sr_err_idx, 0); return (ESRCH); } return (DDI_SUCCESS); } static void dr_start_user_threads(void) { kthread_id_t tp; mutex_enter(&pidlock); /* walk all threads and release them */ for (tp = curthread->t_next; tp != curthread; tp = tp->t_next) { proc_t *p = ttoproc(tp); /* skip kernel threads */ if (ttoproc(tp)->p_as == &kas) continue; mutex_enter(&p->p_lock); tp->t_proc_flag &= ~TP_CHKPT; mutex_exit(&p->p_lock); thread_lock(tp); if (CPR_ISTOPPED(tp)) { /* back on the runq */ tp->t_schedflag |= TS_RESUME; setrun_locked(tp); } thread_unlock(tp); } mutex_exit(&pidlock); } static void dr_signal_user(int sig) { struct proc *p; mutex_enter(&pidlock); for (p = practive; p != NULL; p = p->p_next) { /* only user threads */ if (p->p_exec == NULL || p->p_stat == SZOMB || p == proc_init || p == ttoproc(curthread)) continue; mutex_enter(&p->p_lock); sigtoproc(p, NULL, sig); mutex_exit(&p->p_lock); } mutex_exit(&pidlock); /* add a bit of delay */ delay(hz); } void dr_resume(dr_sr_handle_t *srh) { dr_handle_t *handle; handle = srh->sr_dr_handlep; if (srh->sr_suspend_state < DR_SRSTATE_FULL) { /* * Update the signature block. * If cpus are not paused, this can be done now. * See comments below. */ CPU_SIGNATURE(OS_SIG, SIGST_RESUME_INPROGRESS, SIGSUBST_NULL, CPU->cpu_id); } switch (srh->sr_suspend_state) { case DR_SRSTATE_FULL: ASSERT(MUTEX_HELD(&cpu_lock)); dr_enable_intr(); /* enable intr & clock */ start_cpus(); mutex_exit(&cpu_lock); /* * Update the signature block. * This must not be done while cpus are paused, since on * Starcat the cpu signature update aquires an adaptive * mutex in the iosram driver. Blocking with cpus paused * can lead to deadlock. */ CPU_SIGNATURE(OS_SIG, SIGST_RESUME_INPROGRESS, SIGSUBST_NULL, CPU->cpu_id); /* * If we suspended hw watchdog at suspend, * re-enable it now. */ if (srh->sr_flags & (SR_FLAG_WATCHDOG)) { mutex_enter(&tod_lock); tod_ops.tod_set_watchdog_timer( watchdog_timeout_seconds); mutex_exit(&tod_lock); } /* * This should only be called if drmach_suspend_last() * was called and state transitioned to DR_SRSTATE_FULL * to prevent resume attempts on device instances that * were not previously suspended. */ drmach_resume_first(); /* FALLTHROUGH */ case DR_SRSTATE_DRIVER: /* * resume drivers */ srh->sr_err_idx = 0; /* no parent dip to hold busy */ dr_resume_devices(ddi_root_node(), srh); if (srh->sr_err_idx && srh->sr_dr_handlep) { (srh->sr_dr_handlep)->h_err = drerr_int(ESBD_RESUME, srh->sr_err_ints, srh->sr_err_idx, 1); } /* * resume the lock manager */ lm_cprresume(); /* FALLTHROUGH */ case DR_SRSTATE_USER: /* * finally, resume user threads */ if (!dr_skip_user_threads) { prom_printf("DR: resuming user threads...\n"); dr_start_user_threads(); } /* FALLTHROUGH */ case DR_SRSTATE_BEGIN: default: /* * let those who care know that we've just resumed */ PR_QR("sending SIGTHAW...\n"); dr_signal_user(SIGTHAW); break; } i_ndi_allow_device_tree_changes(handle->h_ndi); /* * update the signature block */ CPU_SIGNATURE(OS_SIG, SIGST_RUN, SIGSUBST_NULL, CPU->cpu_id); prom_printf("DR: resume COMPLETED\n"); } int dr_suspend(dr_sr_handle_t *srh) { dr_handle_t *handle; int force; int dev_errs_idx; uint64_t dev_errs[DR_MAX_ERR_INT]; int rc = DDI_SUCCESS; handle = srh->sr_dr_handlep; force = dr_cmd_flags(handle) & SBD_FLAG_FORCE; /* * update the signature block */ CPU_SIGNATURE(OS_SIG, SIGST_QUIESCE_INPROGRESS, SIGSUBST_NULL, CPU->cpu_id); i_ndi_block_device_tree_changes(&handle->h_ndi); prom_printf("\nDR: suspending user threads...\n"); srh->sr_suspend_state = DR_SRSTATE_USER; if (((rc = dr_stop_user_threads(srh)) != DDI_SUCCESS) && dr_check_user_stop_result) { dr_resume(srh); return (rc); } if (!force) { struct dr_ref drc = {0}; prom_printf("\nDR: checking devices...\n"); dev_errs_idx = 0; drc.arr = dev_errs; drc.idx = &dev_errs_idx; drc.len = DR_MAX_ERR_INT; /* * Since the root node can never go away, it * doesn't have to be held. */ ddi_walk_devs(ddi_root_node(), dr_check_unsafe_major, &drc); if (dev_errs_idx) { handle->h_err = drerr_int(ESBD_UNSAFE, dev_errs, dev_errs_idx, 1); dr_resume(srh); return (DDI_FAILURE); } PR_QR("done\n"); } else { prom_printf("\nDR: dr_suspend invoked with force flag\n"); } #ifndef SKIP_SYNC /* * This sync swap out all user pages */ vfs_sync(SYNC_ALL); #endif /* * special treatment for lock manager */ lm_cprsuspend(); #ifndef SKIP_SYNC /* * sync the file system in case we never make it back */ sync(); #endif /* * now suspend drivers */ prom_printf("DR: suspending drivers...\n"); srh->sr_suspend_state = DR_SRSTATE_DRIVER; srh->sr_err_idx = 0; /* No parent to hold busy */ if ((rc = dr_suspend_devices(ddi_root_node(), srh)) != DDI_SUCCESS) { if (srh->sr_err_idx && srh->sr_dr_handlep) { (srh->sr_dr_handlep)->h_err = drerr_int(ESBD_SUSPEND, srh->sr_err_ints, srh->sr_err_idx, 1); } dr_resume(srh); return (rc); } drmach_suspend_last(); /* * finally, grab all cpus */ srh->sr_suspend_state = DR_SRSTATE_FULL; /* * if watchdog was activated, disable it */ if (watchdog_activated) { mutex_enter(&tod_lock); tod_ops.tod_clear_watchdog_timer(); mutex_exit(&tod_lock); srh->sr_flags |= SR_FLAG_WATCHDOG; } else { srh->sr_flags &= ~(SR_FLAG_WATCHDOG); } /* * Update the signature block. * This must be done before cpus are paused, since on Starcat the * cpu signature update aquires an adaptive mutex in the iosram driver. * Blocking with cpus paused can lead to deadlock. */ CPU_SIGNATURE(OS_SIG, SIGST_QUIESCED, SIGSUBST_NULL, CPU->cpu_id); mutex_enter(&cpu_lock); pause_cpus(NULL); dr_stop_intr(); return (rc); } int dr_pt_test_suspend(dr_handle_t *hp) { dr_sr_handle_t *srh; int err; uint_t psmerr; static fn_t f = "dr_pt_test_suspend"; PR_QR("%s...\n", f); srh = dr_get_sr_handle(hp); if ((err = dr_suspend(srh)) == DDI_SUCCESS) { dr_resume(srh); if ((hp->h_err) && ((psmerr = hp->h_err->e_code) != 0)) { PR_QR("%s: error on dr_resume()", f); switch (psmerr) { case ESBD_RESUME: PR_QR("Couldn't resume devices: %s\n", DR_GET_E_RSC(hp->h_err)); break; case ESBD_KTHREAD: PR_ALL("psmerr is ESBD_KTHREAD\n"); break; default: PR_ALL("Resume error unknown = %d\n", psmerr); break; } } } else { PR_ALL("%s: dr_suspend() failed, err = 0x%x\n", f, err); psmerr = hp->h_err ? hp->h_err->e_code : ESBD_NOERROR; switch (psmerr) { case ESBD_UNSAFE: PR_ALL("Unsafe devices (major #): %s\n", DR_GET_E_RSC(hp->h_err)); break; case ESBD_RTTHREAD: PR_ALL("RT threads (PIDs): %s\n", DR_GET_E_RSC(hp->h_err)); break; case ESBD_UTHREAD: PR_ALL("User threads (PIDs): %s\n", DR_GET_E_RSC(hp->h_err)); break; case ESBD_SUSPEND: PR_ALL("Non-suspendable devices (major #): %s\n", DR_GET_E_RSC(hp->h_err)); break; case ESBD_RESUME: PR_ALL("Could not resume devices (major #): %s\n", DR_GET_E_RSC(hp->h_err)); break; case ESBD_KTHREAD: PR_ALL("psmerr is ESBD_KTHREAD\n"); break; case ESBD_NOERROR: PR_ALL("sbd_error_t error code not set\n"); break; default: PR_ALL("Unknown error psmerr = %d\n", psmerr); break; } } dr_release_sr_handle(srh); return (0); } /* * Add a new integer value to the end of an array. Don't allow duplicates to * appear in the array, and don't allow the array to overflow. Return the new * total number of entries in the array. */ static int dr_add_int(uint64_t *arr, int idx, int len, uint64_t val) { int i; if (arr == NULL) return (0); if (idx >= len) return (idx); for (i = 0; i < idx; i++) { if (arr[i] == val) return (idx); } arr[idx++] = val; return (idx); } /* * Construct an sbd_error_t featuring a string representation of an array of * integers as its e_rsc. */ static sbd_error_t * drerr_int(int e_code, uint64_t *arr, int idx, int majors) { int i, n, buf_len, buf_idx, buf_avail; char *dname; char *buf; sbd_error_t *new_sbd_err; static char s_ellipsis[] = "..."; if (arr == NULL || idx <= 0) return (NULL); /* MAXPATHLEN is the size of the e_rsc field in sbd_error_t. */ buf = (char *)kmem_zalloc(MAXPATHLEN, KM_SLEEP); /* * This is the total working area of the buffer. It must be computed * as the size of 'buf', minus reserved space for the null terminator * and the ellipsis string. */ buf_len = MAXPATHLEN - (strlen(s_ellipsis) + 1); /* Construct a string representation of the array values */ for (buf_idx = 0, i = 0; i < idx; i++) { buf_avail = buf_len - buf_idx; if (majors) { dname = ddi_major_to_name(arr[i]); if (dname) { n = snprintf(&buf[buf_idx], buf_avail, "%s, ", dname); } else { n = snprintf(&buf[buf_idx], buf_avail, "major %lu, ", arr[i]); } } else { n = snprintf(&buf[buf_idx], buf_avail, "%lu, ", arr[i]); } /* An ellipsis gets appended when no more values fit */ if (n >= buf_avail) { (void) strcpy(&buf[buf_idx], s_ellipsis); break; } buf_idx += n; } /* If all the contents fit, remove the trailing comma */ if (n < buf_avail) { buf[--buf_idx] = '\0'; buf[--buf_idx] = '\0'; } /* Return an sbd_error_t with the buffer and e_code */ new_sbd_err = drerr_new(1, e_code, buf); kmem_free(buf, MAXPATHLEN); return (new_sbd_err); }