/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (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 (c) 2008, 2010, Oracle and/or its affiliates. All rights reserved. * Copyright 2012 Milan Jurik. All rights reserved. * Copyright 2015 Nexenta Systems, Inc. All rights reserved. * Copyright 2020 Joyent, Inc. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "disk.h" #include "ses.h" #define SES_VERSION 1 #define SES_STARTING_SUBCHASSIS 256 /* valid subchassis IDs are uint8_t */ #define NO_SUBCHASSIS ((uint64_t)-1) static int ses_snap_freq = 250; /* in milliseconds */ #define SES_STATUS_UNAVAIL(s) \ ((s) == SES_ESC_UNSUPPORTED || (s) >= SES_ESC_NOT_INSTALLED) #define HR_SECOND 1000000000 #define SES_INST_NOTSET UINT64_MAX /* * Because multiple SES targets can be part of a single chassis, we construct * our own hierarchy that takes this into account. These SES targets may refer * to the same devices (multiple paths) or to different devices (managing * different portions of the space). We arrange things into a * ses_enum_enclosure_t, which contains a set of ses targets, and a list of all * nodes found so far. */ typedef struct ses_alt_node { topo_list_t san_link; ses_node_t *san_node; } ses_alt_node_t; typedef struct ses_enum_node { topo_list_t sen_link; ses_node_t *sen_node; topo_list_t sen_alt_nodes; uint64_t sen_type; uint64_t sen_instance; ses_enum_target_t *sen_target; } ses_enum_node_t; typedef struct ses_enum_chassis { topo_list_t sec_link; topo_list_t sec_subchassis; topo_list_t sec_nodes; topo_list_t sec_targets; const char *sec_csn; ses_node_t *sec_enclosure; ses_enum_target_t *sec_target; topo_instance_t sec_instance; topo_instance_t sec_scinstance; topo_instance_t sec_maxinstance; boolean_t sec_hasdev; boolean_t sec_internal; } ses_enum_chassis_t; typedef struct ses_enum_data { topo_list_t sed_devs; topo_list_t sed_chassis; ses_enum_chassis_t *sed_current; ses_enum_target_t *sed_target; int sed_errno; char *sed_name; topo_mod_t *sed_mod; topo_instance_t sed_instance; } ses_enum_data_t; typedef struct sas_connector_phy_data { uint64_t scpd_index; uint64_t scpd_pm; } sas_connector_phy_data_t; typedef struct sas_connector_type { uint64_t sct_type; char *sct_name; } sas_connector_type_t; static const sas_connector_type_t sas_connector_type_list[] = { { 0x0, "Information unknown" }, { 0x1, "External SAS 4x receptacle (see SAS-2 and SFF-8470)" }, { 0x2, "Exteranl Mini SAS 4x receptacle (see SAS-2 and SFF-8088)" }, { 0x3, "QSFP+ receptacle (see SAS-2.1 and SFF-8436)" }, { 0x4, "Mini SAS 4x active receptacle (see SAS-2.1 and SFF-8088)" }, { 0x5, "Mini SAS HD 4x receptacle (see SAS-2.1 and SFF-8644)" }, { 0x6, "Mini SAS HD 8x receptacle (see SAS-2.1 and SFF-8644)" }, { 0x7, "Mini SAS HD 16x receptacle (see SAS-2.1 and SFF-8644)" }, { 0xF, "Vendor-specific external connector" }, { 0x10, "Internal wide SAS 4i plug (see SAS-2 and SFF-8484)" }, { 0x11, "Internal wide Mini SAS 4i receptacle (see SAS-2 and SFF-8087)" }, { 0x12, "Mini SAS HD 4i receptacle (see SAS-2.1 and SFF-8643)" }, { 0x20, "Internal SAS Drive receptacle (see SAS-2 and SFF-8482)" }, { 0x21, "Internal SATA host plug (see SAS-2 and SATA-2)" }, { 0x22, "Internal SAS Drive plug (see SAS-2 and SFF-8482)" }, { 0x23, "Internal SATA device plug (see SAS-2 and SATA-2)" }, { 0x24, "Micro SAS receptacle (see SAS-2.14)" }, { 0x25, "Micro SATA device plug (see SAS-2.1 and SATA)" }, { 0x26, "Micro SAS plug (see SAS-2.1 and SFF-8486)" }, { 0x27, "Micro SAS/SATA plug (see SAS-2.1 and SFF-8486)" }, { 0x28, "12 Gb/s SAS Drive backplane receptacle (see SAS-34 and SFF-8680)" }, { 0x29, "12Gb/s SAS Drive Plug (see SAS-3 and SFF-8680)" }, { 0x2A, "Multifunction 12 Gb/s 6x Unshielded receptacle connector " "receptacle (see SAS-3 and SFF-8639)" }, { 0x2B, "Multifunction 12 Gb/s 6x Unshielded receptable connector " "plug (see SAS-3 and SFF-8639)" }, { 0x2F, "Internal SAS virtual connector" }, { 0x3F, "Vendor-specific internal connector" }, { 0x70, "Other Vendor-specific connector" }, { 0x71, "Other Vendor-specific connector" }, { 0x72, "Other Vendor-specific connector" }, { 0x73, "Other Vendor-specific connector" }, { 0x74, "Other Vendor-specific connector" }, { 0x75, "Other Vendor-specific connector" }, { 0x76, "Other Vendor-specific connector" }, { 0x77, "Other Vendor-specific connector" }, { 0x78, "Other Vendor-specific connector" }, { 0x79, "Other Vendor-specific connector" }, { 0x7A, "Other Vendor-specific connector" }, { 0x7B, "Other Vendor-specific connector" }, { 0x7C, "Other Vendor-specific connector" }, { 0x7D, "Other Vendor-specific connector" }, { 0x7E, "Other Vendor-specific connector" }, { 0x7F, "Other Vendor-specific connector" }, { 0x80, "Not Defined" } }; #define SAS_CONNECTOR_TYPE_CODE_NOT_DEFINED 0x80 #define SAS_CONNECTOR_TYPE_NOT_DEFINED \ "Connector type not defined by SES-2 standard" #define SAS_CONNECTOR_TYPE_RESERVED \ "Connector type reserved by SES-2 standard" typedef struct phys_enum_type { uint64_t pet_type; char *pet_nodename; char *pet_defaultlabel; boolean_t pet_dorange; } phys_enum_type_t; static const phys_enum_type_t phys_enum_type_list[] = { { SES_ET_ARRAY_DEVICE, BAY, "BAY", B_TRUE }, { SES_ET_COOLING, FAN, "FAN", B_TRUE }, { SES_ET_DEVICE, BAY, "BAY", B_TRUE }, { SES_ET_ESC_ELECTRONICS, CONTROLLER, "CONTROLLER", B_TRUE }, { SES_ET_POWER_SUPPLY, PSU, "PSU", B_TRUE }, { SES_ET_SUNW_FANBOARD, FANBOARD, "FANBOARD", B_TRUE }, { SES_ET_SUNW_FANMODULE, FANMODULE, "FANMODULE", B_TRUE }, { SES_ET_SUNW_POWERBOARD, POWERBOARD, "POWERBOARD", B_TRUE }, { SES_ET_SUNW_POWERMODULE, POWERMODULE, "POWERMODULE", B_TRUE } }; #define N_PHYS_ENUM_TYPES (sizeof (phys_enum_type_list) / \ sizeof (phys_enum_type_list[0])) /* * Structure for the hierarchical tree for element nodes. */ typedef struct ses_phys_tree { ses_node_t *spt_snode; ses_enum_node_t *spt_senumnode; boolean_t spt_isfru; uint64_t spt_eonlyindex; uint64_t spt_cindex; uint64_t spt_pindex; uint64_t spt_maxinst; struct ses_phys_tree *spt_parent; struct ses_phys_tree *spt_child; struct ses_phys_tree *spt_sibling; tnode_t *spt_tnode; } ses_phys_tree_t; typedef enum { SES_NEW_CHASSIS = 0x1, SES_NEW_SUBCHASSIS = 0x2, SES_DUP_CHASSIS = 0x4, SES_DUP_SUBCHASSIS = 0x8 } ses_chassis_type_e; static const topo_pgroup_info_t smp_pgroup = { TOPO_PGROUP_SMP, TOPO_STABILITY_PRIVATE, TOPO_STABILITY_PRIVATE, 1 }; static const topo_pgroup_info_t ses_pgroup = { TOPO_PGROUP_SES, TOPO_STABILITY_PRIVATE, TOPO_STABILITY_PRIVATE, 1 }; static int ses_present(topo_mod_t *, tnode_t *, topo_version_t, nvlist_t *, nvlist_t **); static int ses_contains(topo_mod_t *, tnode_t *, topo_version_t, nvlist_t *, nvlist_t **); static const topo_method_t ses_component_methods[] = { { TOPO_METH_PRESENT, TOPO_METH_PRESENT_DESC, TOPO_METH_PRESENT_VERSION0, TOPO_STABILITY_INTERNAL, ses_present }, { TOPO_METH_FAC_ENUM, TOPO_METH_FAC_ENUM_DESC, 0, TOPO_STABILITY_INTERNAL, ses_node_enum_facility }, { TOPO_METH_SENSOR_FAILURE, TOPO_METH_SENSOR_FAILURE_DESC, TOPO_METH_SENSOR_FAILURE_VERSION, TOPO_STABILITY_INTERNAL, topo_method_sensor_failure }, { NULL } }; #define TOPO_METH_SMCI_4U36_LABEL "smci_4u36_bay_label" #define TOPO_METH_SMCI_4U36_LABEL_DESC \ "compute bay labels on SMCI 4U36 storage platform variants" #define TOPO_METH_SMCI_4U36_LABEL_VERSION 0 static int smci_4u36_bay_label(topo_mod_t *, tnode_t *, topo_version_t, nvlist_t *, nvlist_t **); static const topo_method_t ses_bay_methods[] = { { TOPO_METH_FAC_ENUM, TOPO_METH_FAC_ENUM_DESC, 0, TOPO_STABILITY_INTERNAL, ses_node_enum_facility }, { TOPO_METH_OCCUPIED, TOPO_METH_OCCUPIED_DESC, TOPO_METH_OCCUPIED_VERSION, TOPO_STABILITY_INTERNAL, topo_mod_hc_occupied }, { TOPO_METH_SMCI_4U36_LABEL, TOPO_METH_SMCI_4U36_LABEL_DESC, TOPO_METH_SMCI_4U36_LABEL_VERSION, TOPO_STABILITY_INTERNAL, smci_4u36_bay_label }, { NULL } }; static const topo_method_t ses_recep_methods[] = { { TOPO_METH_OCCUPIED, TOPO_METH_OCCUPIED_DESC, TOPO_METH_OCCUPIED_VERSION, TOPO_STABILITY_INTERNAL, topo_mod_hc_occupied }, { NULL } }; static const topo_method_t ses_enclosure_methods[] = { { TOPO_METH_CONTAINS, TOPO_METH_CONTAINS_DESC, TOPO_METH_CONTAINS_VERSION, TOPO_STABILITY_INTERNAL, ses_contains }, { TOPO_METH_FAC_ENUM, TOPO_METH_FAC_ENUM_DESC, 0, TOPO_STABILITY_INTERNAL, ses_enc_enum_facility }, { NULL } }; /* * The bay_label_overrides table can be used to map a server product ID to a * topo method that will be invoked to override the value of the label property * for all bay nodes. By default the property value is static, derived from * the corresponding SES array device element's descriptor string. */ typedef struct ses_label_overrides { const char *slbl_product; const char *slbl_mname; } ses_label_overrides_t; /* * This table covers three generations of SMCI's 4U 36-bay storage server * (and the Joyent-branded versions). There was also an Ivy Bridge variant * which has been omitted due to an inability to find one to test on. */ static const ses_label_overrides_t bay_label_overrides[] = { /* Sandy Bridge variant */ { "SSG-6047R-E1R36L", TOPO_METH_SMCI_4U36_LABEL }, { "Joyent-Storage-Platform-5001", TOPO_METH_SMCI_4U36_LABEL }, /* Broadwell variant */ { "SSG-6048R-E1CR36L", TOPO_METH_SMCI_4U36_LABEL }, { "Joyent-Storage-Platform-7001", TOPO_METH_SMCI_4U36_LABEL }, /* Skylake variant */ { "SSG-6049P-E1CR36L", TOPO_METH_SMCI_4U36_LABEL }, { "Joyent-S10G5", TOPO_METH_SMCI_4U36_LABEL } }; #define N_BAY_LBL_OVERRIDES (sizeof (bay_label_overrides) / \ sizeof (bay_label_overrides[0])) /* * Functions for tracking ses devices which we were unable to open. We retry * these at regular intervals using ses_recheck_dir() and if we find that we * can now open any of them then we send a sysevent to indicate that a new topo * snapshot should be taken. */ typedef struct ses_open_fail_list { struct ses_open_fail_list *sof_next; char *sof_path; } ses_open_fail_list_t; static ses_open_fail_list_t *ses_sofh; static pthread_mutex_t ses_sofmt; static void ses_ct_print(char *ptr); static void ses_recheck_dir() { ses_target_t *target; sysevent_id_t eid; char buf[80]; ses_open_fail_list_t *sof; /* * check list of "unable to open" devices */ (void) pthread_mutex_lock(&ses_sofmt); for (sof = ses_sofh; sof != NULL; sof = sof->sof_next) { /* * see if we can open it now */ if ((target = ses_open(LIBSES_VERSION, sof->sof_path)) == NULL) { (void) snprintf(buf, sizeof (buf), "recheck_dir - still can't open %s", sof->sof_path); ses_ct_print(buf); continue; } /* * ok - better force a new snapshot */ (void) snprintf(buf, sizeof (buf), "recheck_dir - can now open %s", sof->sof_path); ses_ct_print(buf); (void) sysevent_post_event(EC_PLATFORM, ESC_PLATFORM_SP_RESET, SUNW_VENDOR, "fmd", NULL, &eid); ses_close(target); break; } (void) pthread_mutex_unlock(&ses_sofmt); } static void ses_sof_alloc(topo_mod_t *mod, char *path) { ses_open_fail_list_t *sof; (void) pthread_mutex_lock(&ses_sofmt); sof = topo_mod_zalloc(mod, sizeof (*sof)); topo_mod_dprintf(mod, "sof_alloc %s", path); sof->sof_path = path; sof->sof_next = ses_sofh; ses_sofh = sof; (void) pthread_mutex_unlock(&ses_sofmt); } static void ses_sof_freeall(topo_mod_t *mod) { ses_open_fail_list_t *sof, *next_sof; (void) pthread_mutex_lock(&ses_sofmt); for (sof = ses_sofh; sof != NULL; sof = next_sof) { next_sof = sof->sof_next; topo_mod_dprintf(mod, "sof_freeall %s", sof->sof_path); topo_mod_strfree(mod, sof->sof_path); topo_mod_free(mod, sof, sizeof (*sof)); } ses_sofh = NULL; (void) pthread_mutex_unlock(&ses_sofmt); } /* * functions for verifying that the ses_enum_target_t held in a device * contract's cookie field is still valid (it may have been freed by * ses_release()). */ typedef struct ses_stp_list { struct ses_stp_list *ssl_next; ses_enum_target_t *ssl_tgt; } ses_stp_list_t; static ses_stp_list_t *ses_sslh; static pthread_mutex_t ses_sslmt; static void ses_ssl_alloc(topo_mod_t *mod, ses_enum_target_t *stp) { ses_stp_list_t *ssl; (void) pthread_mutex_lock(&ses_sslmt); ssl = topo_mod_zalloc(mod, sizeof (*ssl)); topo_mod_dprintf(mod, "ssl_alloc %p", stp); ssl->ssl_tgt = stp; ssl->ssl_next = ses_sslh; ses_sslh = ssl; (void) pthread_mutex_unlock(&ses_sslmt); } static void ses_ssl_free(topo_mod_t *mod, ses_enum_target_t *stp) { ses_stp_list_t *ssl, *prev_ssl; (void) pthread_mutex_lock(&ses_sslmt); prev_ssl = NULL; for (ssl = ses_sslh; ssl != NULL; ssl = ssl->ssl_next) { if (ssl->ssl_tgt == stp) { topo_mod_dprintf(mod, "ssl_free %p", ssl->ssl_tgt); if (prev_ssl == NULL) ses_sslh = ssl->ssl_next; else prev_ssl->ssl_next = ssl->ssl_next; topo_mod_free(mod, ssl, sizeof (*ssl)); break; } prev_ssl = ssl; } (void) pthread_mutex_unlock(&ses_sslmt); } static int ses_ssl_valid(ses_enum_target_t *stp) { ses_stp_list_t *ssl; for (ssl = ses_sslh; ssl != NULL; ssl = ssl->ssl_next) if (ssl->ssl_tgt == stp) return (1); return (0); } /* * Functions for creating and destroying a background thread * (ses_contract_thread) used for detecting when ses devices have been * retired/unretired. */ static struct ses_thread_s { pthread_mutex_t mt; pthread_t tid; int thr_sig; int doexit; int count; } sesthread = { PTHREAD_MUTEX_INITIALIZER, 0, SIGTERM, 0, 0 }; typedef struct ses_mod_list { struct ses_mod_list *smod_next; topo_mod_t *smod_mod; } ses_mod_list_t; static ses_mod_list_t *ses_smod; static void ses_ct_print(char *ptr) { (void) pthread_mutex_lock(&sesthread.mt); if (ses_smod != NULL && ses_smod->smod_mod != NULL) topo_mod_dprintf(ses_smod->smod_mod, ptr); (void) pthread_mutex_unlock(&sesthread.mt); } /*ARGSUSED*/ static void * ses_contract_thread(void *arg) { int efd, ctlfd, statfd; ct_evthdl_t ev; ctevid_t evid; uint_t event; char path[PATH_MAX]; char buf[80]; ses_enum_target_t *stp; ct_stathdl_t stathdl; ctid_t ctid; struct pollfd fds; int pollret; sigset_t sigset; ses_ct_print("start contract event thread"); efd = open64(CTFS_ROOT "/device/pbundle", O_RDONLY); fds.fd = efd; fds.events = POLLIN; fds.revents = 0; (void) sigaddset(&sigset, sesthread.thr_sig); (void) pthread_sigmask(SIG_UNBLOCK, &sigset, NULL); for (;;) { /* check if we've been asked to exit */ (void) pthread_mutex_lock(&sesthread.mt); if (sesthread.doexit) { (void) pthread_mutex_unlock(&sesthread.mt); break; } (void) pthread_mutex_unlock(&sesthread.mt); /* poll until an event arrives */ if ((pollret = poll(&fds, 1, 10000)) <= 0) { if (pollret == 0) ses_recheck_dir(); continue; } /* read the event */ (void) pthread_mutex_lock(&ses_sslmt); ses_ct_print("read contract event"); if (ct_event_read(efd, &ev) != 0) { (void) pthread_mutex_unlock(&ses_sslmt); continue; } /* see if it is an event we are expecting */ ctid = ct_event_get_ctid(ev); (void) snprintf(buf, sizeof (buf), "got contract event ctid=%d", ctid); ses_ct_print(buf); event = ct_event_get_type(ev); if (event != CT_DEV_EV_OFFLINE && event != CT_EV_NEGEND) { (void) snprintf(buf, sizeof (buf), "bad contract event %x", event); ses_ct_print(buf); ct_event_free(ev); (void) pthread_mutex_unlock(&ses_sslmt); continue; } /* find target pointer saved in cookie */ evid = ct_event_get_evid(ev); (void) snprintf(path, PATH_MAX, CTFS_ROOT "/device/%ld/status", ctid); statfd = open64(path, O_RDONLY); (void) ct_status_read(statfd, CTD_COMMON, &stathdl); stp = (ses_enum_target_t *)(uintptr_t) ct_status_get_cookie(stathdl); ct_status_free(stathdl); (void) close(statfd); /* check if target pointer is still valid */ if (ses_ssl_valid(stp) == 0) { (void) snprintf(buf, sizeof (buf), "contract already abandoned %x", event); ses_ct_print(buf); (void) snprintf(path, PATH_MAX, CTFS_ROOT "/device/%ld/ctl", ctid); ctlfd = open64(path, O_WRONLY); if (event != CT_EV_NEGEND) (void) ct_ctl_ack(ctlfd, evid); else (void) ct_ctl_abandon(ctlfd); (void) close(ctlfd); ct_event_free(ev); (void) pthread_mutex_unlock(&ses_sslmt); continue; } /* find control device for ack/abandon */ (void) pthread_mutex_lock(&stp->set_lock); (void) snprintf(path, PATH_MAX, CTFS_ROOT "/device/%ld/ctl", ctid); ctlfd = open64(path, O_WRONLY); if (event != CT_EV_NEGEND) { /* if this is an offline event, do the offline */ ses_ct_print("got contract offline event"); if (stp->set_target) { ses_ct_print("contract thread rele"); ses_snap_rele(stp->set_snap); ses_close(stp->set_target); stp->set_target = NULL; } (void) ct_ctl_ack(ctlfd, evid); } else { /* if this is the negend, then abandon the contract */ ses_ct_print("got contract negend"); if (stp->set_ctid) { (void) snprintf(buf, sizeof (buf), "abandon old contract %d", stp->set_ctid); ses_ct_print(buf); stp->set_ctid = 0; } (void) ct_ctl_abandon(ctlfd); } (void) close(ctlfd); (void) pthread_mutex_unlock(&stp->set_lock); ct_event_free(ev); (void) pthread_mutex_unlock(&ses_sslmt); } (void) close(efd); return (NULL); } int find_thr_sig(void) { int i; sigset_t oset, rset; int sig[] = {SIGTERM, SIGUSR1, SIGUSR2}; int sig_sz = sizeof (sig) / sizeof (int); int rc = SIGTERM; /* prefered set of signals that are likely used to terminate threads */ (void) sigemptyset(&oset); (void) pthread_sigmask(SIG_SETMASK, NULL, &oset); for (i = 0; i < sig_sz; i++) { if (sigismember(&oset, sig[i]) == 0) { return (sig[i]); } } /* reserved set of signals that are not allowed to terminate thread */ (void) sigemptyset(&rset); (void) sigaddset(&rset, SIGABRT); (void) sigaddset(&rset, SIGKILL); (void) sigaddset(&rset, SIGSTOP); (void) sigaddset(&rset, SIGCANCEL); /* Find signal that is not masked and not in the reserved list. */ for (i = 1; i < MAXSIG; i++) { if (sigismember(&rset, i) == 1) { continue; } if (sigismember(&oset, i) == 0) { return (i); } } return (rc); } /*ARGSUSED*/ static void ses_handler(int sig) { } static void ses_thread_init(topo_mod_t *mod) { pthread_attr_t *attr = NULL; struct sigaction act; ses_mod_list_t *smod; (void) pthread_mutex_lock(&sesthread.mt); sesthread.count++; smod = topo_mod_zalloc(mod, sizeof (*smod)); smod->smod_mod = mod; smod->smod_next = ses_smod; ses_smod = smod; if (sesthread.tid == 0) { /* find a suitable signal to use for killing the thread below */ sesthread.thr_sig = find_thr_sig(); /* if don't have a handler for this signal, create one */ (void) sigaction(sesthread.thr_sig, NULL, &act); if (act.sa_handler == SIG_DFL || act.sa_handler == SIG_IGN) act.sa_handler = ses_handler; (void) sigaction(sesthread.thr_sig, &act, NULL); /* create a thread to listen for offline events */ (void) pthread_create(&sesthread.tid, attr, ses_contract_thread, NULL); } (void) pthread_mutex_unlock(&sesthread.mt); } static void ses_thread_fini(topo_mod_t *mod) { ses_mod_list_t *smod, *prev_smod; (void) pthread_mutex_lock(&sesthread.mt); prev_smod = NULL; for (smod = ses_smod; smod != NULL; smod = smod->smod_next) { if (smod->smod_mod == mod) { if (prev_smod == NULL) ses_smod = smod->smod_next; else prev_smod->smod_next = smod->smod_next; topo_mod_free(mod, smod, sizeof (*smod)); break; } prev_smod = smod; } if (--sesthread.count > 0) { (void) pthread_mutex_unlock(&sesthread.mt); return; } sesthread.doexit = 1; (void) pthread_mutex_unlock(&sesthread.mt); (void) pthread_kill(sesthread.tid, sesthread.thr_sig); (void) pthread_join(sesthread.tid, NULL); sesthread.tid = 0; } static void ses_create_contract(topo_mod_t *mod, ses_enum_target_t *stp) { int tfd, len, rval; char link_path[PATH_MAX]; stp->set_ctid = 0; /* convert "/dev" path into "/devices" path */ if ((len = readlink(stp->set_devpath, link_path, PATH_MAX)) < 0) { topo_mod_dprintf(mod, "readlink failed"); return; } link_path[len] = '\0'; /* set up template to create new contract */ tfd = open64(CTFS_ROOT "/device/template", O_RDWR); (void) ct_tmpl_set_critical(tfd, CT_DEV_EV_OFFLINE); (void) ct_tmpl_set_cookie(tfd, (uint64_t)(uintptr_t)stp); /* strip "../../devices" off the front and create the contract */ if ((rval = ct_dev_tmpl_set_minor(tfd, &link_path[13])) != 0) topo_mod_dprintf(mod, "failed to set minor %s rval = %d", &link_path[13], rval); else if ((rval = ct_tmpl_create(tfd, &stp->set_ctid)) != 0) topo_mod_dprintf(mod, "failed to create ctid rval = %d", rval); else topo_mod_dprintf(mod, "created ctid=%d", stp->set_ctid); (void) close(tfd); } static void ses_target_free(topo_mod_t *mod, ses_enum_target_t *stp) { if (--stp->set_refcount == 0) { /* check if already closed due to contract offline request */ (void) pthread_mutex_lock(&stp->set_lock); if (stp->set_target) { ses_snap_rele(stp->set_snap); ses_close(stp->set_target); stp->set_target = NULL; } if (stp->set_ctid) { int ctlfd; char path[PATH_MAX]; topo_mod_dprintf(mod, "abandon old contract %d", stp->set_ctid); (void) snprintf(path, PATH_MAX, CTFS_ROOT "/device/%ld/ctl", stp->set_ctid); ctlfd = open64(path, O_WRONLY); (void) ct_ctl_abandon(ctlfd); (void) close(ctlfd); stp->set_ctid = 0; } (void) pthread_mutex_unlock(&stp->set_lock); ses_ssl_free(mod, stp); topo_mod_strfree(mod, stp->set_devpath); topo_mod_free(mod, stp, sizeof (ses_enum_target_t)); } } static void ses_data_free(ses_enum_data_t *sdp, ses_enum_chassis_t *pcp) { topo_mod_t *mod = sdp->sed_mod; ses_enum_chassis_t *cp; ses_enum_node_t *np; ses_enum_target_t *tp; ses_alt_node_t *ap; topo_list_t *cpl; if (pcp != NULL) cpl = &pcp->sec_subchassis; else cpl = &sdp->sed_chassis; while ((cp = topo_list_next(cpl)) != NULL) { topo_list_delete(cpl, cp); while ((np = topo_list_next(&cp->sec_nodes)) != NULL) { while ((ap = topo_list_next(&np->sen_alt_nodes)) != NULL) { topo_list_delete(&np->sen_alt_nodes, ap); topo_mod_free(mod, ap, sizeof (ses_alt_node_t)); } topo_list_delete(&cp->sec_nodes, np); topo_mod_free(mod, np, sizeof (ses_enum_node_t)); } while ((tp = topo_list_next(&cp->sec_targets)) != NULL) { topo_list_delete(&cp->sec_targets, tp); ses_target_free(mod, tp); } topo_mod_free(mod, cp, sizeof (ses_enum_chassis_t)); } if (pcp == NULL) { dev_list_free(mod, &sdp->sed_devs); topo_mod_free(mod, sdp, sizeof (ses_enum_data_t)); } } /* * For enclosure nodes, we have a special contains method. By default, the hc * walker will compare the node name and instance number to determine if an * FMRI matches. For enclosures where the enumeration order is impossible to * predict, we instead use the chassis-id as a unique identifier, and ignore * the instance number. */ static int fmri_contains(topo_mod_t *mod, nvlist_t *nv1, nvlist_t *nv2) { uint8_t v1, v2; nvlist_t **hcp1, **hcp2; int err, i; uint_t nhcp1, nhcp2; nvlist_t *a1, *a2; char *c1, *c2; int mindepth; if (nvlist_lookup_uint8(nv1, FM_VERSION, &v1) != 0 || nvlist_lookup_uint8(nv2, FM_VERSION, &v2) != 0 || v1 > FM_HC_SCHEME_VERSION || v2 > FM_HC_SCHEME_VERSION) return (topo_mod_seterrno(mod, EMOD_FMRI_VERSION)); err = nvlist_lookup_nvlist_array(nv1, FM_FMRI_HC_LIST, &hcp1, &nhcp1); err |= nvlist_lookup_nvlist_array(nv2, FM_FMRI_HC_LIST, &hcp2, &nhcp2); if (err != 0) return (topo_mod_seterrno(mod, EMOD_FMRI_NVL)); /* * If the chassis-id doesn't match, then these FMRIs are not * equivalent. If one of the FMRIs doesn't have a chassis ID, then we * have no choice but to fall back to the instance ID. */ if (nvlist_lookup_nvlist(nv1, FM_FMRI_AUTHORITY, &a1) == 0 && nvlist_lookup_nvlist(nv2, FM_FMRI_AUTHORITY, &a2) == 0 && nvlist_lookup_string(a1, FM_FMRI_AUTH_CHASSIS, &c1) == 0 && nvlist_lookup_string(a2, FM_FMRI_AUTH_CHASSIS, &c2) == 0) { if (strcmp(c1, c2) != 0) return (0); mindepth = 1; } else { mindepth = 0; } if (nhcp2 < nhcp1) return (0); for (i = 0; i < nhcp1; i++) { char *nm1 = NULL; char *nm2 = NULL; char *id1 = NULL; char *id2 = NULL; (void) nvlist_lookup_string(hcp1[i], FM_FMRI_HC_NAME, &nm1); (void) nvlist_lookup_string(hcp2[i], FM_FMRI_HC_NAME, &nm2); (void) nvlist_lookup_string(hcp1[i], FM_FMRI_HC_ID, &id1); (void) nvlist_lookup_string(hcp2[i], FM_FMRI_HC_ID, &id2); if (nm1 == NULL || nm2 == NULL || id1 == NULL || id2 == NULL) return (topo_mod_seterrno(mod, EMOD_FMRI_NVL)); if (strcmp(nm1, nm2) == 0 && (i < mindepth || strcmp(id1, id2) == 0)) continue; return (0); } return (1); } /*ARGSUSED*/ static int ses_contains(topo_mod_t *mod, tnode_t *tn, topo_version_t version, nvlist_t *in, nvlist_t **out) { int ret; nvlist_t *nv1, *nv2; if (version > TOPO_METH_CONTAINS_VERSION) return (topo_mod_seterrno(mod, EMOD_VER_NEW)); if (nvlist_lookup_nvlist(in, TOPO_METH_FMRI_ARG_FMRI, &nv1) != 0 || nvlist_lookup_nvlist(in, TOPO_METH_FMRI_ARG_SUBFMRI, &nv2) != 0) return (topo_mod_seterrno(mod, EMOD_METHOD_INVAL)); ret = fmri_contains(mod, nv1, nv2); if (ret < 0) return (-1); if (topo_mod_nvalloc(mod, out, NV_UNIQUE_NAME) == 0) { if (nvlist_add_uint32(*out, TOPO_METH_CONTAINS_RET, ret) == 0) return (0); else nvlist_free(*out); } return (-1); } /* * Return a current instance of the node. This is somewhat complicated because * we need to take a new snapshot in order to get the new data, but we don't * want to be constantly taking SES snapshots if the consumer is going to do a * series of queries. So we adopt the strategy of assuming that the SES state * is not going to be rapidly changing, and limit our snapshot frequency to * some defined bounds. */ ses_node_t * ses_node_lock(topo_mod_t *mod, tnode_t *tn) { ses_enum_target_t *tp = topo_node_getspecific(tn); hrtime_t now; ses_snap_t *snap; int err; uint64_t nodeid; ses_node_t *np; if (tp == NULL) { (void) topo_mod_seterrno(mod, EMOD_METHOD_NOTSUP); return (NULL); } (void) pthread_mutex_lock(&tp->set_lock); /* * Determine if we need to take a new snapshot. */ now = gethrtime(); if (tp->set_target == NULL) { /* * We may have closed the device but not yet abandoned the * contract (ie we've had the offline event but not yet the * negend). If so, just return failure. */ if (tp->set_ctid != 0) { (void) topo_mod_seterrno(mod, EMOD_METHOD_NOTSUP); (void) pthread_mutex_unlock(&tp->set_lock); return (NULL); } /* * The device has been closed due to a contract offline * request, then we need to reopen it and create a new contract. */ if ((tp->set_target = ses_open(LIBSES_VERSION, tp->set_devpath)) == NULL) { sysevent_id_t eid; (void) topo_mod_seterrno(mod, EMOD_METHOD_NOTSUP); (void) pthread_mutex_unlock(&tp->set_lock); topo_mod_dprintf(mod, "recheck_dir - " "can no longer open %s", tp->set_devpath); (void) sysevent_post_event(EC_PLATFORM, ESC_PLATFORM_SP_RESET, SUNW_VENDOR, "fmd", NULL, &eid); return (NULL); } topo_mod_dprintf(mod, "reopen contract"); ses_create_contract(mod, tp); tp->set_snap = ses_snap_hold(tp->set_target); tp->set_snaptime = gethrtime(); } else if (now - tp->set_snaptime > (ses_snap_freq * 1000 * 1000) && (snap = ses_snap_new(tp->set_target)) != NULL) { if (ses_snap_generation(snap) != ses_snap_generation(tp->set_snap)) { /* * If we find ourselves in this situation, we're in * trouble. The generation count has changed, which * indicates that our current topology is out of date. * But we need to consult the new topology in order to * determine presence at this moment in time. We can't * go back and change the topo snapshot in situ, so * we'll just have to fail the call in this unlikely * scenario. */ ses_snap_rele(snap); (void) topo_mod_seterrno(mod, EMOD_METHOD_NOTSUP); (void) pthread_mutex_unlock(&tp->set_lock); return (NULL); } else { ses_snap_rele(tp->set_snap); tp->set_snap = snap; } tp->set_snaptime = gethrtime(); } snap = tp->set_snap; verify(topo_prop_get_uint64(tn, TOPO_PGROUP_SES, TOPO_PROP_NODE_ID, &nodeid, &err) == 0); verify((np = ses_node_lookup(snap, nodeid)) != NULL); return (np); } /*ARGSUSED*/ void ses_node_unlock(topo_mod_t *mod, tnode_t *tn) { ses_enum_target_t *tp = topo_node_getspecific(tn); verify(tp != NULL); (void) pthread_mutex_unlock(&tp->set_lock); } /* * Determine if the element is present. */ /*ARGSUSED*/ static int ses_present(topo_mod_t *mod, tnode_t *tn, topo_version_t version, nvlist_t *in, nvlist_t **out) { boolean_t present; ses_node_t *np; nvlist_t *props, *nvl; uint64_t status; if ((np = ses_node_lock(mod, tn)) == NULL) return (-1); verify((props = ses_node_props(np)) != NULL); verify(nvlist_lookup_uint64(props, SES_PROP_STATUS_CODE, &status) == 0); ses_node_unlock(mod, tn); present = (status != SES_ESC_NOT_INSTALLED); if (topo_mod_nvalloc(mod, &nvl, NV_UNIQUE_NAME) != 0) return (topo_mod_seterrno(mod, EMOD_FMRI_NVL)); if (nvlist_add_uint32(nvl, TOPO_METH_PRESENT_RET, present) != 0) { nvlist_free(nvl); return (topo_mod_seterrno(mod, EMOD_FMRI_NVL)); } *out = nvl; return (0); } /* * Sets standard properties for a ses node (enclosure, bay, controller * or expander). * This includes setting the FRU, as well as setting the * authority information. When the fru topo node(frutn) is not NULL * its resouce should be used as FRU. */ static int ses_set_standard_props(topo_mod_t *mod, tnode_t *frutn, tnode_t *tn, nvlist_t *auth, uint64_t nodeid, const char *path) { int err; char *product, *chassis; nvlist_t *fmri; /* * Set the authority explicitly if specified. */ if (auth) { verify(nvlist_lookup_string(auth, FM_FMRI_AUTH_PRODUCT, &product) == 0); verify(nvlist_lookup_string(auth, FM_FMRI_AUTH_CHASSIS, &chassis) == 0); if (topo_prop_set_string(tn, FM_FMRI_AUTHORITY, FM_FMRI_AUTH_PRODUCT, TOPO_PROP_IMMUTABLE, product, &err) != 0 || topo_prop_set_string(tn, FM_FMRI_AUTHORITY, FM_FMRI_AUTH_CHASSIS, TOPO_PROP_IMMUTABLE, chassis, &err) != 0 || topo_prop_set_string(tn, FM_FMRI_AUTHORITY, FM_FMRI_AUTH_SERVER, TOPO_PROP_IMMUTABLE, "", &err) != 0) { topo_mod_dprintf(mod, "failed to add authority " "properties: %s\n", topo_strerror(err)); return (topo_mod_seterrno(mod, err)); } } /* * Copy the resource and set that as the FRU. */ if (frutn != NULL) { if (topo_node_resource(frutn, &fmri, &err) != 0) { topo_mod_dprintf(mod, "topo_node_resource() failed : %s\n", topo_strerror(err)); return (topo_mod_seterrno(mod, err)); } } else { if (topo_node_resource(tn, &fmri, &err) != 0) { topo_mod_dprintf(mod, "topo_node_resource() failed : %s\n", topo_strerror(err)); return (topo_mod_seterrno(mod, err)); } } if (topo_node_fru_set(tn, fmri, 0, &err) != 0) { topo_mod_dprintf(mod, "topo_node_fru_set() failed : %s\n", topo_strerror(err)); nvlist_free(fmri); return (topo_mod_seterrno(mod, err)); } nvlist_free(fmri); /* * Set the SES-specific properties so that consumers can query * additional information about the particular SES element. */ if (topo_pgroup_create(tn, &ses_pgroup, &err) != 0) { topo_mod_dprintf(mod, "failed to create propgroup " "%s: %s\n", TOPO_PGROUP_SES, topo_strerror(err)); return (-1); } if (topo_prop_set_uint64(tn, TOPO_PGROUP_SES, TOPO_PROP_NODE_ID, TOPO_PROP_IMMUTABLE, nodeid, &err) != 0) { topo_mod_dprintf(mod, "failed to create property %s: %s\n", TOPO_PROP_NODE_ID, topo_strerror(err)); return (-1); } if (topo_prop_set_string(tn, TOPO_PGROUP_SES, TOPO_PROP_TARGET_PATH, TOPO_PROP_IMMUTABLE, path, &err) != 0) { topo_mod_dprintf(mod, "failed to create property %s: %s\n", TOPO_PROP_TARGET_PATH, topo_strerror(err)); return (-1); } return (0); } /* * Iterate over the SES phy information. If any of the ports indicates that it's * a SATA device and we haven't matched any disk devices yet, that means * that the HBA was able to create a WWN for the SATA device based on its GUID, * which is good. However, SES includes the WWN for the device's STP bridge. In * theory, if the driver includes the WWN based on the SATA guid then it should * also set the bridge-port property indicating the WWN that should match the * SATA device. */ static int ses_create_disk_bridge(ses_enum_data_t *sdp, tnode_t *pnode, nvlist_t *props, tnode_t **child) { nvlist_t **phys; uint_t i, n_phys; topo_mod_t *mod = sdp->sed_mod; if (nvlist_lookup_nvlist_array(props, SES_SAS_PROP_PHYS, &phys, &n_phys) != 0) return (1); for (i = 0; i < n_phys; i++) { uint64_t wwn; boolean_t sata; char wwnstr[64]; if (nvlist_lookup_uint64(phys[i], SES_SAS_PROP_ADDR, &wwn) != 0 || wwn == 0) { continue; } if (nvlist_lookup_boolean_value(phys[i], SES_SAS_PROP_SATA_DEVICE, &sata) != 0 || !sata) { continue; } if (scsi_wwn_to_wwnstr(wwn, 0, wwnstr) == NULL) continue; if (disk_declare_bridge(mod, pnode, &sdp->sed_devs, wwnstr, child) == 0) { return (0); } } return (1); } /* * Callback to add a disk to a given bay. We first check the status-code to * determine if a disk is present, ignoring those that aren't in an appropriate * state. We then scan the parent bay node's SAS address array to determine * possible attached SAS addresses. We create a disk node if the disk is not * SAS or the SES target does not support the necessary pages for this; if we * find the SAS address, we create a disk node and also correlate it with * the corresponding Solaris device node to fill in the rest of the data. */ static int ses_create_disk(ses_enum_data_t *sdp, tnode_t *pnode, nvlist_t *props) { topo_mod_t *mod = sdp->sed_mod; uint64_t status; uint_t s, nsas; char **paths; int err, ret; tnode_t *child = NULL; /* * Skip devices that are not in a present (and possibly damaged) state. * Also, skip devices that this expander is either not fully wired to, * or are hidden due to SAS zoning, as indicated by the * SES_ESC_NO_ACCESS state. */ if (nvlist_lookup_uint64(props, SES_PROP_STATUS_CODE, &status) != 0) return (0); if (status != SES_ESC_UNSUPPORTED && status != SES_ESC_OK && status != SES_ESC_CRITICAL && status != SES_ESC_NONCRITICAL && status != SES_ESC_UNRECOVERABLE && status != SES_ESC_UNKNOWN) return (0); topo_mod_dprintf(mod, "found attached disk"); /* * Create the disk range. */ if (topo_node_range_create(mod, pnode, DISK, 0, 0) != 0) { topo_mod_dprintf(mod, "topo_node_create_range() failed: %s", topo_mod_errmsg(mod)); return (-1); } /* * Look through all SAS addresses and attempt to correlate them to a * known Solaris device. If we don't find a matching node, then we * don't enumerate the disk node. * Note that TOPO_PROP_SAS_ADDR prop includes SAS address from * alternate elements that represent the same device. */ if (topo_prop_get_string_array(pnode, TOPO_PGROUP_SES, TOPO_PROP_SAS_ADDR, &paths, &nsas, &err) != 0) return (0); err = 0; for (s = 0; s < nsas; s++) { ret = disk_declare_addr(mod, pnode, &sdp->sed_devs, paths[s], &child); if (ret == 0) { break; } else if (ret < 0) { err = -1; break; } } /* * We need to take another pass through the properties for this bay by * iterating over the phys and noting if any of these are SATA. Note, * this information isn't commonly part of the topo tree at this time, * hence why we end up going back and iterating over the properties * ourselves. */ if (s == nsas) { if (ses_create_disk_bridge(sdp, pnode, props, &child) != 0) (void) disk_declare_non_enumerated(mod, pnode, &child); } /* copy sas_addresses (target-ports) from parent (with 'w'added) */ if (child != NULL) { int i; char **tports; uint64_t wwn; tports = topo_mod_zalloc(mod, sizeof (char *) * nsas); if (tports != NULL) { for (i = 0; i < nsas; i++) { if (scsi_wwnstr_to_wwn(paths[i], &wwn) != DDI_SUCCESS) break; tports[i] = scsi_wwn_to_wwnstr(wwn, 1, NULL); if (tports[i] == NULL) break; } /* if they all worked then create the property */ if (i == nsas) (void) topo_prop_set_string_array(child, TOPO_PGROUP_STORAGE, TOPO_STORAGE_TARGET_PORT_L0IDS, TOPO_PROP_IMMUTABLE, (const char **)tports, nsas, &err); for (i = 0; i < nsas; i++) if (tports[i] != NULL) scsi_free_wwnstr(tports[i]); topo_mod_free(mod, tports, sizeof (char *) * nsas); } } for (s = 0; s < nsas; s++) topo_mod_free(mod, paths[s], strlen(paths[s]) + 1); topo_mod_free(mod, paths, nsas * sizeof (char *)); return (err); } static int ses_add_bay_props(topo_mod_t *mod, tnode_t *tn, ses_enum_node_t *snp) { ses_alt_node_t *ap; ses_node_t *np; nvlist_t *props; nvlist_t **phys; uint_t i, j, n_phys, all_phys = 0; char **paths; uint64_t addr; size_t len; int terr, err = -1; for (ap = topo_list_next(&snp->sen_alt_nodes); ap != NULL; ap = topo_list_next(ap)) { np = ap->san_node; props = ses_node_props(np); if (nvlist_lookup_nvlist_array(props, SES_SAS_PROP_PHYS, &phys, &n_phys) != 0) continue; all_phys += n_phys; } if (all_phys == 0) return (0); if ((paths = topo_mod_zalloc(mod, all_phys * sizeof (char *))) == NULL) return (-1); for (i = 0, ap = topo_list_next(&snp->sen_alt_nodes); ap != NULL; ap = topo_list_next(ap)) { np = ap->san_node; props = ses_node_props(np); if (nvlist_lookup_nvlist_array(props, SES_SAS_PROP_PHYS, &phys, &n_phys) != 0) continue; for (j = 0; j < n_phys; j++) { if (nvlist_lookup_uint64(phys[j], SES_SAS_PROP_ADDR, &addr) != 0) continue; len = snprintf(NULL, 0, "%016llx", addr) + 1; if ((paths[i] = topo_mod_alloc(mod, len)) == NULL) goto error; (void) snprintf(paths[i], len, "%016llx", addr); ++i; } } err = topo_prop_set_string_array(tn, TOPO_PGROUP_SES, TOPO_PROP_SAS_ADDR, TOPO_PROP_IMMUTABLE, (const char **)paths, i, &terr); if (err != 0) err = topo_mod_seterrno(mod, terr); error: for (i = 0; i < all_phys && paths[i] != NULL; i++) topo_mod_free(mod, paths[i], strlen(paths[i]) + 1); topo_mod_free(mod, paths, all_phys * sizeof (char *)); return (err); } static const char * lookup_bay_override(const char *product_id) { for (uint_t i = 0; i < N_BAY_LBL_OVERRIDES; i++) { if (strcmp(product_id, bay_label_overrides[i].slbl_product) == 0) { return (bay_label_overrides[i].slbl_mname); } } return (NULL); } /* * Callback to create a basic node (bay, psu, fan, or controller and expander). */ static int ses_create_generic(ses_enum_data_t *sdp, ses_enum_node_t *snp, tnode_t *pnode, tnode_t *frutn, const char *nodename, const char *labelname, tnode_t **node) { ses_node_t *np = snp->sen_node; ses_node_t *parent; uint64_t instance = snp->sen_instance; topo_mod_t *mod = sdp->sed_mod; nvlist_t *props, *aprops; nvlist_t *auth = NULL, *fmri = NULL; tnode_t *tn = NULL; char *clean_label = NULL, label[128]; int err; char *part = NULL, *serial = NULL, *revision = NULL; char *desc; boolean_t report; props = ses_node_props(np); (void) nvlist_lookup_string(props, LIBSES_PROP_PART, &part); (void) nvlist_lookup_string(props, LIBSES_PROP_SERIAL, &serial); topo_mod_dprintf(mod, "adding %s %llu", nodename, instance); /* * Create the node. The interesting information is all copied from the * parent enclosure node, so there is not much to do. */ if ((auth = topo_mod_auth(mod, pnode)) == NULL) goto error; /* * We want to report revision information for the controller nodes, but * we do not get per-element revision information. However, we do have * revision information for the entire enclosure, and we can use the * 'reported-via' property to know that this controller corresponds to * the given revision information. This means we cannot get revision * information for targets we are not explicitly connected to, but * there is little we can do about the situation. */ if (strcmp(nodename, CONTROLLER) == 0 && nvlist_lookup_boolean_value(props, SES_PROP_REPORT, &report) == 0 && report) { for (parent = ses_node_parent(np); parent != NULL; parent = ses_node_parent(parent)) { if (ses_node_type(parent) == SES_NODE_ENCLOSURE) { (void) nvlist_lookup_string( ses_node_props(parent), SES_EN_PROP_REV, &revision); break; } } } if ((fmri = topo_mod_hcfmri(mod, pnode, FM_HC_SCHEME_VERSION, nodename, (topo_instance_t)instance, NULL, auth, part, revision, serial)) == NULL) { topo_mod_dprintf(mod, "topo_mod_hcfmri() failed: %s", topo_mod_errmsg(mod)); goto error; } if ((tn = topo_node_bind(mod, pnode, nodename, instance, fmri)) == NULL) { topo_mod_dprintf(mod, "topo_node_bind() failed: %s", topo_mod_errmsg(mod)); goto error; } /* * For the node label, we look for the following in order: * * * * */ if (nvlist_lookup_string(props, SES_PROP_DESCRIPTION, &desc) != 0 || desc[0] == '\0') { parent = ses_node_parent(np); aprops = ses_node_props(parent); if (nvlist_lookup_string(aprops, SES_PROP_CLASS_DESCRIPTION, &desc) != 0 || desc[0] == '\0') desc = (char *)labelname; (void) snprintf(label, sizeof (label), "%s %llu", desc, instance); desc = label; } if ((clean_label = topo_mod_clean_str(mod, desc)) == NULL) goto error; if (topo_prop_set_string(tn, TOPO_PGROUP_PROTOCOL, TOPO_PROP_LABEL, TOPO_PROP_MUTABLE, clean_label, &err) < 0) goto error; if (ses_set_standard_props(mod, frutn, tn, NULL, ses_node_id(np), snp->sen_target->set_devpath) != 0) goto error; if (strcmp(nodename, BAY) == 0) { const char *label_method; char *product; nvlist_t *args = NULL; if (ses_add_bay_props(mod, tn, snp) != 0) goto error; if (topo_method_register(mod, tn, ses_bay_methods) != 0) { topo_mod_dprintf(mod, "topo_method_register() failed: %s", topo_mod_errmsg(mod)); goto error; } /* * Ideally we'd perform this sort of override with a platform * specific XML map file, and that would work here if we only * wanted to override the bay node label. However, we'd also * like the disk node label (if the bay is occupied) to inherit * the overriden bay label. So we need to ensure the * propmethod is registered before we create the child disk * node. */ if ((product = topo_mod_product(mod)) == NULL) { (void) topo_mod_seterrno(mod, EMOD_NOMEM); goto error; } if ((label_method = lookup_bay_override(product)) != NULL) { if (topo_mod_nvalloc(mod, &args, NV_UNIQUE_NAME) != 0 || topo_prop_method_register(tn, TOPO_PGROUP_PROTOCOL, TOPO_PROP_LABEL, TOPO_TYPE_STRING, label_method, args, &err)) { topo_mod_dprintf(mod, "Failed to register method: %s on %s=%" PRIu64, label_method, BAY, topo_node_instance(tn)); topo_mod_strfree(mod, product); nvlist_free(args); goto error; } nvlist_free(args); } topo_mod_strfree(mod, product); if (ses_create_disk(sdp, tn, props) != 0) goto error; } else if ((strcmp(nodename, FAN) == 0) || (strcmp(nodename, PSU) == 0) || (strcmp(nodename, CONTROLLER) == 0)) { /* * Only fan, psu, and controller nodes have a 'present' method. * Bay nodes are always present, and disk nodes are present by * virtue of being enumerated and SAS expander nodes and * SAS connector nodes are also always present once * the parent controller is found. */ if (topo_method_register(mod, tn, ses_component_methods) != 0) { topo_mod_dprintf(mod, "topo_method_register() failed: %s", topo_mod_errmsg(mod)); goto error; } } snp->sen_target->set_refcount++; topo_node_setspecific(tn, snp->sen_target); nvlist_free(auth); nvlist_free(fmri); topo_mod_strfree(mod, clean_label); if (node != NULL) *node = tn; return (0); error: nvlist_free(auth); nvlist_free(fmri); topo_mod_strfree(mod, clean_label); return (-1); } /* * Create SAS expander specific props. */ /*ARGSUSED*/ static int ses_set_expander_props(ses_enum_data_t *sdp, ses_enum_node_t *snp, tnode_t *ptnode, tnode_t *tnode, int *phycount, int64_t *connlist) { ses_node_t *np = snp->sen_node; topo_mod_t *mod = sdp->sed_mod; nvlist_t *auth = NULL, *fmri = NULL; nvlist_t *props, **phylist; int err, i; uint_t pcount; uint64_t sasaddr, connidx; char sasaddr_str[17]; boolean_t found = B_FALSE, ses_found = B_FALSE; dev_di_node_t *dnode, *sesdnode; props = ses_node_props(np); /* * the uninstalled expander is not enumerated by checking * the element status code. No present present' method provided. */ /* * Get the Expander SAS address. It should exist. */ if (nvlist_lookup_uint64(props, SES_EXP_PROP_SAS_ADDR, &sasaddr) != 0) { topo_mod_dprintf(mod, "Failed to get prop %s.", SES_EXP_PROP_SAS_ADDR); goto error; } (void) sprintf(sasaddr_str, "%llx", sasaddr); /* search matching dev_di_node. */ for (dnode = topo_list_next(&sdp->sed_devs); dnode != NULL; dnode = topo_list_next(dnode)) { for (i = 0; i < dnode->ddn_ppath_count; i++) { if ((dnode->ddn_target_port[i] != NULL) && (strstr(dnode->ddn_target_port[i], sasaddr_str) != NULL)) { found = B_TRUE; break; } } if (found) break; } if (!found) { topo_mod_dprintf(mod, "ses_set_expander_props: Failed to find matching " "devinfo node for Exapnder SAS address %s", SES_EXP_PROP_SAS_ADDR); /* continue on to get storage group props. */ } else { /* create/set the devfs-path and devid in the smp group */ if (topo_pgroup_create(tnode, &smp_pgroup, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "failed to create smp property group %s\n", topo_strerror(err)); goto error; } else { if (topo_prop_set_string(tnode, TOPO_PGROUP_SMP, TOPO_PROP_SMP_TARGET_PORT, TOPO_PROP_IMMUTABLE, dnode->ddn_target_port[i], &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set %S error %s\n", TOPO_PROP_SAS_ADDR, topo_strerror(err)); } if (topo_prop_set_string(tnode, TOPO_PGROUP_SMP, TOPO_PROP_SMP_DEV_PATH, TOPO_PROP_IMMUTABLE, dnode->ddn_dpath, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set dev error %s\n", topo_strerror(err)); } if (topo_prop_set_string(tnode, TOPO_PGROUP_SMP, TOPO_PROP_SMP_DEVID, TOPO_PROP_IMMUTABLE, dnode->ddn_devid, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set devid error %s\n", topo_strerror(err)); } if (dnode->ddn_ppath_count != 0 && topo_prop_set_string_array(tnode, TOPO_PGROUP_SMP, TOPO_PROP_SMP_PHYS_PATH, TOPO_PROP_IMMUTABLE, (const char **)dnode->ddn_ppath, dnode->ddn_ppath_count, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set phys-path error %s\n", topo_strerror(err)); } } } /* update the ses property group with SES target info */ if ((topo_pgroup_create(tnode, &ses_pgroup, &err) != 0) && (err != ETOPO_PROP_DEFD)) { /* SES prop group doesn't exist but failed to be created. */ topo_mod_dprintf(mod, "ses_set_expander_props: " "ses pgroup create error %s\n", topo_strerror(err)); goto error; } else { /* locate assciated enclosure dev_di_node. */ for (sesdnode = topo_list_next(&sdp->sed_devs); sesdnode != NULL; sesdnode = topo_list_next(sesdnode)) { for (i = 0; i < sesdnode->ddn_ppath_count; i++) { /* * check if attached port exists and * its node type is enclosure and * attached port is same as sas address of * the expander and * bridge port for virtual phy indication * exist. */ if ((sesdnode->ddn_attached_port[i] != NULL) && (sesdnode->ddn_dtype == DTYPE_ESI) && (strstr(sesdnode->ddn_attached_port[i], sasaddr_str) != NULL) && (sesdnode->ddn_bridge_port[i] != NULL)) { ses_found = B_TRUE; break; } } if (ses_found) break; } if (ses_found) { if (topo_prop_set_string(tnode, TOPO_PGROUP_SES, TOPO_PROP_SES_TARGET_PORT, TOPO_PROP_IMMUTABLE, sesdnode->ddn_target_port[i], &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set ses %S error %s\n", TOPO_PROP_SAS_ADDR, topo_strerror(err)); } if (topo_prop_set_string(tnode, TOPO_PGROUP_SES, TOPO_PROP_SES_DEV_PATH, TOPO_PROP_IMMUTABLE, sesdnode->ddn_dpath, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set ses dev error %s\n", topo_strerror(err)); } if (topo_prop_set_string(tnode, TOPO_PGROUP_SES, TOPO_PROP_SES_DEVID, TOPO_PROP_IMMUTABLE, sesdnode->ddn_devid, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set ses devid error %s\n", topo_strerror(err)); } if (sesdnode->ddn_ppath_count != 0 && topo_prop_set_string_array(tnode, TOPO_PGROUP_SES, TOPO_PROP_SES_PHYS_PATH, TOPO_PROP_IMMUTABLE, (const char **)sesdnode->ddn_ppath, sesdnode->ddn_ppath_count, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set ses phys-path error %s\n", topo_strerror(err)); } } } /* create the storage group */ if (topo_pgroup_create(tnode, &storage_pgroup, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "create storage error %s\n", topo_strerror(err)); goto error; } else { /* set the SAS address prop out of expander element status. */ if (topo_prop_set_string(tnode, TOPO_PGROUP_STORAGE, TOPO_PROP_SAS_ADDR, TOPO_PROP_IMMUTABLE, sasaddr_str, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set %S error %s\n", TOPO_PROP_SAS_ADDR, topo_strerror(err)); } /* Get the phy information for the expander */ if (nvlist_lookup_nvlist_array(props, SES_SAS_PROP_PHYS, &phylist, &pcount) != 0) { topo_mod_dprintf(mod, "Failed to get prop %s.", SES_SAS_PROP_PHYS); } else { /* * For each phy, get the connector element index and * stores into connector element index array. */ *phycount = pcount; for (i = 0; i < pcount; i++) { if (nvlist_lookup_uint64(phylist[i], SES_PROP_CE_IDX, &connidx) == 0) { if (connidx != 0xff) { connlist[i] = connidx; } else { connlist[i] = -1; } } else { /* Fail to get the index. set to -1. */ connlist[i] = -1; } } /* set the phy count prop of the expander. */ if (topo_prop_set_uint64(tnode, TOPO_PGROUP_STORAGE, TOPO_PROP_PHY_COUNT, TOPO_PROP_IMMUTABLE, pcount, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set %S error %s\n", TOPO_PROP_PHY_COUNT, topo_strerror(err)); } /* * set the connector element index of * the expander phys. */ } /* populate other misc storage group properties */ if (found) { if (dnode->ddn_mfg && (topo_prop_set_string(tnode, TOPO_PGROUP_STORAGE, TOPO_STORAGE_MANUFACTURER, TOPO_PROP_IMMUTABLE, dnode->ddn_mfg, &err) != 0)) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set mfg error %s\n", topo_strerror(err)); } if (dnode->ddn_model && (topo_prop_set_string(tnode, TOPO_PGROUP_STORAGE, TOPO_STORAGE_MODEL, TOPO_PROP_IMMUTABLE, dnode->ddn_model, &err) != 0)) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set model error %s\n", topo_strerror(err)); } if (dnode->ddn_serial && (topo_prop_set_string(tnode, TOPO_PGROUP_STORAGE, TOPO_STORAGE_SERIAL_NUM, TOPO_PROP_IMMUTABLE, dnode->ddn_serial, &err) != 0)) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set serial error %s\n", topo_strerror(err)); } if (dnode->ddn_firm && (topo_prop_set_string(tnode, TOPO_PGROUP_STORAGE, TOPO_STORAGE_FIRMWARE_REV, TOPO_PROP_IMMUTABLE, dnode->ddn_firm, &err) != 0)) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set firm error %s\n", topo_strerror(err)); } } } return (0); error: nvlist_free(auth); nvlist_free(fmri); return (-1); } /* * Create SAS expander specific props. */ /*ARGSUSED*/ static int ses_set_connector_props(ses_enum_data_t *sdp, ses_enum_node_t *snp, tnode_t *tnode, int64_t phy_mask) { ses_node_t *np = snp->sen_node; topo_mod_t *mod = sdp->sed_mod; nvlist_t *props; int err, i; uint64_t conntype; char phymask_str[17], *conntype_str; boolean_t found; props = ses_node_props(np); /* * convert phy mask to string. */ (void) snprintf(phymask_str, 17, "%llx", phy_mask); /* create the storage group */ if (topo_pgroup_create(tnode, &storage_pgroup, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "create storage error %s\n", topo_strerror(err)); return (-1); } else { /* set the SAS address prop of the expander. */ if (topo_prop_set_string(tnode, TOPO_PGROUP_STORAGE, TOPO_STORAGE_SAS_PHY_MASK, TOPO_PROP_IMMUTABLE, phymask_str, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set %S error %s\n", TOPO_STORAGE_SAS_PHY_MASK, topo_strerror(err)); } /* Get the connector type information for the expander */ if (nvlist_lookup_uint64(props, SES_SC_PROP_CONNECTOR_TYPE, &conntype) != 0) { topo_mod_dprintf(mod, "Failed to get prop %s.", TOPO_STORAGE_SAS_PHY_MASK); } else { found = B_FALSE; for (i = 0; ; i++) { if (sas_connector_type_list[i].sct_type == SAS_CONNECTOR_TYPE_CODE_NOT_DEFINED) { break; } if (sas_connector_type_list[i].sct_type == conntype) { conntype_str = sas_connector_type_list[i].sct_name; found = B_TRUE; break; } } if (!found) { if (conntype < SAS_CONNECTOR_TYPE_CODE_NOT_DEFINED) { conntype_str = SAS_CONNECTOR_TYPE_RESERVED; } else { conntype_str = SAS_CONNECTOR_TYPE_NOT_DEFINED; } } /* set the phy count prop of the expander. */ if (topo_prop_set_string(tnode, TOPO_PGROUP_STORAGE, TOPO_STORAGE_SAS_CONNECTOR_TYPE, TOPO_PROP_IMMUTABLE, conntype_str, &err) != 0) { topo_mod_dprintf(mod, "ses_set_expander_props: " "set %S error %s\n", TOPO_PROP_PHY_COUNT, topo_strerror(err)); } } } return (0); } /* * Instantiate SAS expander nodes for a given ESC Electronics node(controller) * nodes. */ /*ARGSUSED*/ static int ses_create_esc_sasspecific(ses_enum_data_t *sdp, ses_enum_node_t *snp, tnode_t *pnode, ses_enum_chassis_t *cp, boolean_t dorange) { topo_mod_t *mod = sdp->sed_mod; tnode_t *exptn, *contn; boolean_t found; sas_connector_phy_data_t connectors[64] = {0}; uint64_t max; ses_enum_node_t *ctlsnp, *xsnp, *consnp; ses_node_t *np = snp->sen_node; nvlist_t *props, *psprops; uint64_t index, psindex, conindex, psstatus, i, j, count; int64_t cidxlist[256] = {0}; int phycount; props = ses_node_props(np); if (nvlist_lookup_uint64(props, SES_PROP_ELEMENT_ONLY_INDEX, &index) != 0) return (-1); /* * For SES constroller node, check to see if there are * associated SAS expanders. */ found = B_FALSE; max = 0; for (ctlsnp = topo_list_next(&cp->sec_nodes); ctlsnp != NULL; ctlsnp = topo_list_next(ctlsnp)) { if (ctlsnp->sen_type == SES_ET_SAS_EXPANDER) { found = B_TRUE; if (ctlsnp->sen_instance > max) max = ctlsnp->sen_instance; } } /* * No SAS expander found notthing to process. */ if (!found) return (0); topo_mod_dprintf(mod, "%s Controller %d: creating " "%llu %s nodes", cp->sec_csn, index, max + 1, SASEXPANDER); /* * The max number represent the number of elements * deducted from the highest SES_PROP_ELEMENT_CLASS_INDEX * of SET_ET_SAS_EXPANDER type element. * * There may be multiple ESC Electronics element(controllers) * within JBOD(typicall two for redundancy) and SAS expander * elements are associated with only one of them. We are * still creating the range based max number here. * That will cover the case that all expanders are associated * with one SES controller. */ if (dorange && topo_node_range_create(mod, pnode, SASEXPANDER, 0, max) != 0) { topo_mod_dprintf(mod, "topo_node_create_range() failed: %s", topo_mod_errmsg(mod)); return (-1); } /* * Search exapnders with the parent index matching with * ESC Electronics element index. * Note the index used here is a global index across * SES elements. */ for (xsnp = topo_list_next(&cp->sec_nodes); xsnp != NULL; xsnp = topo_list_next(xsnp)) { if (xsnp->sen_type == SES_ET_SAS_EXPANDER) { /* * get the parent ESC controller. */ psprops = ses_node_props(xsnp->sen_node); if (nvlist_lookup_uint64(psprops, SES_PROP_STATUS_CODE, &psstatus) == 0) { if (psstatus == SES_ESC_NOT_INSTALLED) { /* * Not installed. * Don't create a ndoe. */ continue; } } else { /* * The element should have status code. * If not there is no way to find * out if the expander element exist or * not. */ continue; } /* Get the physical parent index to compare. */ if (nvlist_lookup_uint64(psprops, LIBSES_PROP_PHYS_PARENT, &psindex) == 0) { if (index == psindex) { /* indentation moved forward */ /* * Handle basic node information of SAS expander * element - binding to parent node and * allocating FMRI... */ if (ses_create_generic(sdp, xsnp, pnode, pnode, SASEXPANDER, "SAS-EXPANDER", &exptn) != 0) continue; /* * Now handle SAS expander unique portion of node creation. * The max nubmer of the phy count is 256 since SES-2 * defines as 1 byte field. The cidxlist has the same * number of elements. * * We use size 64 array to store the connectors. * Typically a connectors associated with 4 phys so that * matches with the max number of connecters associated * with an expander. * The phy count goes up to 38 for Sun supported * JBOD. */ (void) memset(cidxlist, 0, sizeof (int64_t) * 64); if (ses_set_expander_props(sdp, xsnp, pnode, exptn, &phycount, cidxlist) != 0) { /* * error on getting specific prop failed. * continue on. Note that the node is * left bound. */ continue; } /* * count represetns the number of connectors discovered so far. */ count = 0; (void) memset(connectors, 0, sizeof (sas_connector_phy_data_t) * 64); for (i = 0; i < phycount; i++) { if (cidxlist[i] != -1) { /* connector index is valid. */ for (j = 0; j < count; j++) { if (connectors[j].scpd_index == cidxlist[i]) { /* * Just update phy mask. * The postion for connector * index lists(cidxlist index) * is set. */ connectors[j].scpd_pm = connectors[j].scpd_pm | (1ULL << i); break; } } /* * If j and count matche a new connector * index is found. */ if (j == count) { /* add a new index and phy mask. */ connectors[count].scpd_index = cidxlist[i]; connectors[count].scpd_pm = connectors[count].scpd_pm | (1ULL << i); count++; } } } /* * create range for the connector nodes. * The class index of the ses connector element * is set as the instance nubmer for the node. * Even though one expander may not have all connectors * are associated with we are creating the range with * max possible instance number. */ found = B_FALSE; max = 0; for (consnp = topo_list_next(&cp->sec_nodes); consnp != NULL; consnp = topo_list_next(consnp)) { if (consnp->sen_type == SES_ET_SAS_CONNECTOR) { psprops = ses_node_props(consnp->sen_node); found = B_TRUE; if (consnp->sen_instance > max) max = consnp->sen_instance; } } /* * No SAS connector found nothing to process. */ if (!found) return (0); if (dorange && topo_node_range_create(mod, exptn, RECEPTACLE, 0, max) != 0) { topo_mod_dprintf(mod, "topo_node_create_range() failed: %s", topo_mod_errmsg(mod)); return (-1); } /* search matching connector element using the index. */ for (i = 0; i < count; i++) { found = B_FALSE; for (consnp = topo_list_next(&cp->sec_nodes); consnp != NULL; consnp = topo_list_next(consnp)) { if (consnp->sen_type == SES_ET_SAS_CONNECTOR) { psprops = ses_node_props( consnp->sen_node); /* * Get the physical parent index to * compare. * The connector elements are children * of ESC Electronics element even * though we enumerate them under * an expander in libtopo. */ if (nvlist_lookup_uint64(psprops, SES_PROP_ELEMENT_ONLY_INDEX, &conindex) == 0) { if (conindex == connectors[i].scpd_index) { found = B_TRUE; break; } } } } /* now create a libtopo node. */ if (found) { /* Create generic props. */ if (ses_create_generic(sdp, consnp, exptn, topo_node_parent(exptn), RECEPTACLE, "RECEPTACLE", &contn) != 0) { continue; } /* Create connector specific props. */ if (ses_set_connector_props(sdp, consnp, contn, connectors[i].scpd_pm) != 0) { continue; } if (topo_method_register(mod, contn, ses_recep_methods) != 0) { topo_mod_dprintf(mod, "topo_method_register() failed: " "%s", topo_mod_errmsg(mod)); continue; } } } /* end indentation change */ } } } } return (0); } /* * Instantiate any protocol specific portion of a node. */ /*ARGSUSED*/ static int ses_create_protocol_specific(ses_enum_data_t *sdp, ses_enum_node_t *snp, tnode_t *pnode, uint64_t type, ses_enum_chassis_t *cp, boolean_t dorange) { if (type == SES_ET_ESC_ELECTRONICS) { /* create SAS specific children(expanders and connectors. */ return (ses_create_esc_sasspecific(sdp, snp, pnode, cp, dorange)); } return (0); } /* * Instantiate any children of a given type. */ static int ses_create_children(ses_enum_data_t *sdp, tnode_t *pnode, uint64_t type, const char *nodename, const char *defaultlabel, ses_enum_chassis_t *cp, boolean_t dorange) { topo_mod_t *mod = sdp->sed_mod; boolean_t found; uint64_t max; ses_enum_node_t *snp; tnode_t *tn; /* * First go through and count how many matching nodes we have. */ max = 0; found = B_FALSE; for (snp = topo_list_next(&cp->sec_nodes); snp != NULL; snp = topo_list_next(snp)) { if (snp->sen_type == type) { found = B_TRUE; if (snp->sen_instance > max) max = snp->sen_instance; } } /* * No enclosure should export both DEVICE and ARRAY_DEVICE elements. * Since we map both of these to 'disk', if an enclosure does this, we * just ignore the array elements. */ if (!found || (type == SES_ET_ARRAY_DEVICE && cp->sec_hasdev)) return (0); topo_mod_dprintf(mod, "%s: creating %llu %s nodes", cp->sec_csn, max + 1, nodename); if (dorange && topo_node_range_create(mod, pnode, nodename, 0, max) != 0) { topo_mod_dprintf(mod, "topo_node_create_range() failed: %s", topo_mod_errmsg(mod)); return (-1); } for (snp = topo_list_next(&cp->sec_nodes); snp != NULL; snp = topo_list_next(snp)) { if (snp->sen_type == type) { /* * With flat layout of ses nodes there is no * way to find out the direct FRU for a node. * Passing NULL for fru topo node. Note that * ses_create_children_from_phys_tree() provides * the actual direct FRU for a node. */ if (ses_create_generic(sdp, snp, pnode, NULL, nodename, defaultlabel, &tn) != 0) return (-1); /* * For some SES element there may be protocol specific * information to process. Here we are processing * the association between enclosure controller and * SAS expanders. */ if (type == SES_ET_ESC_ELECTRONICS) { /* create SAS expander node */ if (ses_create_protocol_specific(sdp, snp, tn, type, cp, dorange) != 0) { return (-1); } } } } return (0); } /* * Instantiate a new subchassis instance in the topology. */ static int ses_create_subchassis(ses_enum_data_t *sdp, tnode_t *pnode, ses_enum_chassis_t *scp) { topo_mod_t *mod = sdp->sed_mod; tnode_t *tn; nvlist_t *props; nvlist_t *auth = NULL, *fmri = NULL; uint64_t instance = scp->sec_instance; char *desc; char *clean_label = NULL, label[128]; char **paths; int i, err; ses_enum_target_t *stp; int ret = -1; /* * Copy authority information from parent enclosure node */ if ((auth = topo_mod_auth(mod, pnode)) == NULL) goto error; /* * Record the subchassis serial number in the FMRI. * For now, we assume that logical id is the subchassis serial number. * If this assumption changes in future, then the following * piece of code will need to be updated via an RFE. */ if ((fmri = topo_mod_hcfmri(mod, pnode, FM_HC_SCHEME_VERSION, SUBCHASSIS, (topo_instance_t)instance, NULL, auth, NULL, NULL, NULL)) == NULL) { topo_mod_dprintf(mod, "topo_mod_hcfmri() failed: %s", topo_mod_errmsg(mod)); goto error; } if ((tn = topo_node_bind(mod, pnode, SUBCHASSIS, instance, fmri)) == NULL) { topo_mod_dprintf(mod, "topo_node_bind() failed: %s", topo_mod_errmsg(mod)); goto error; } props = ses_node_props(scp->sec_enclosure); /* * Look for the subchassis label in the following order: * * * * * For subchassis, the default label is "SUBCHASSIS" */ if (nvlist_lookup_string(props, SES_PROP_DESCRIPTION, &desc) != 0 || desc[0] == '\0') { if (nvlist_lookup_string(props, SES_PROP_CLASS_DESCRIPTION, &desc) == 0 && desc[0] != '\0') (void) snprintf(label, sizeof (label), "%s %llu", desc, instance); else (void) snprintf(label, sizeof (label), "SUBCHASSIS %llu", instance); desc = label; } if ((clean_label = topo_mod_clean_str(mod, desc)) == NULL) goto error; if (topo_prop_set_string(tn, TOPO_PGROUP_PROTOCOL, TOPO_PROP_LABEL, TOPO_PROP_MUTABLE, clean_label, &err) < 0) goto error; if (ses_set_standard_props(mod, NULL, tn, NULL, ses_node_id(scp->sec_enclosure), scp->sec_target->set_devpath) != 0) goto error; /* * Set the 'chassis-type' property for this subchassis. This is either * 'ses-class-description' or 'subchassis'. */ if (nvlist_lookup_string(props, SES_PROP_CLASS_DESCRIPTION, &desc) != 0) desc = "subchassis"; if (topo_prop_set_string(tn, TOPO_PGROUP_SES, TOPO_PROP_CHASSIS_TYPE, TOPO_PROP_IMMUTABLE, desc, &err) != 0) { topo_mod_dprintf(mod, "failed to create property %s: %s\n", TOPO_PROP_CHASSIS_TYPE, topo_strerror(err)); goto error; } /* * For enclosures, we want to include all possible targets (for upgrade * purposes). */ for (i = 0, stp = topo_list_next(&scp->sec_targets); stp != NULL; stp = topo_list_next(stp), i++) ; verify(i != 0); paths = alloca(i * sizeof (char *)); for (i = 0, stp = topo_list_next(&scp->sec_targets); stp != NULL; stp = topo_list_next(stp), i++) paths[i] = stp->set_devpath; if (topo_prop_set_string_array(tn, TOPO_PGROUP_SES, TOPO_PROP_PATHS, TOPO_PROP_IMMUTABLE, (const char **)paths, i, &err) != 0) { topo_mod_dprintf(mod, "failed to create property %s: %s\n", TOPO_PROP_PATHS, topo_strerror(err)); goto error; } if (topo_method_register(mod, tn, ses_enclosure_methods) != 0) { topo_mod_dprintf(mod, "topo_method_register() failed: %s", topo_mod_errmsg(mod)); goto error; } /* * Create the nodes for controllers and bays. */ if (ses_create_children(sdp, tn, SES_ET_ESC_ELECTRONICS, CONTROLLER, "CONTROLLER", scp, B_TRUE) != 0 || ses_create_children(sdp, tn, SES_ET_DEVICE, BAY, "BAY", scp, B_TRUE) != 0 || ses_create_children(sdp, tn, SES_ET_ARRAY_DEVICE, BAY, "BAY", scp, B_TRUE) != 0) goto error; ret = 0; error: nvlist_free(auth); nvlist_free(fmri); topo_mod_strfree(mod, clean_label); return (ret); } /* * Function we use to insert a node. */ static int ses_phys_tree_insert(topo_mod_t *mod, ses_phys_tree_t **sproot, ses_phys_tree_t *child) { uint64_t ppindex, eindex, pindex; ses_phys_tree_t *node_ptr; int ret = 0; assert(sproot != NULL); assert(child != NULL); if (*sproot == NULL) { *sproot = child; return (0); } pindex = child->spt_pindex; ppindex = (*sproot)->spt_pindex; eindex = (*sproot)->spt_eonlyindex; /* * If the element only index of the root is same as the physical * parent index of a node to be added, add the node as a child of * the current root. */ if (eindex == pindex) { (void) ses_phys_tree_insert(mod, &(*sproot)->spt_child, child); child->spt_parent = *sproot; } else if (ppindex == pindex) { /* * if the physical parent of the current root and the child * is same, then this should be a sibling node. * Siblings can be different element types and arrange * them by group. */ if ((*sproot)->spt_senumnode->sen_type == child->spt_senumnode->sen_type) { child->spt_sibling = *sproot; *sproot = child; } else { /* add a node in front of matching element type. */ node_ptr = *sproot; while (node_ptr->spt_sibling != NULL) { if (node_ptr->spt_sibling-> spt_senumnode->sen_type == child->spt_senumnode->sen_type) { child->spt_sibling = node_ptr->spt_sibling; node_ptr->spt_sibling = child; break; } node_ptr = node_ptr->spt_sibling; } /* no matching. Add the child at the end. */ if (node_ptr->spt_sibling == NULL) { node_ptr->spt_sibling = child; } } child->spt_parent = (*sproot)->spt_parent; } else { /* * The root and the node is not directly related. * Try to insert to the child sub-tree first and then try to * insert to the sibling sub-trees. If fails for both * the caller will retry insertion later. */ if ((*sproot)->spt_child) { ret = ses_phys_tree_insert(mod, &(*sproot)->spt_child, child); } if ((*sproot)->spt_child == NULL || ret != 0) { if ((*sproot)->spt_sibling) { ret = ses_phys_tree_insert(mod, &(*sproot)->spt_sibling, child); } else { ret = 1; } } return (ret); } return (0); } /* * Construct tree view of ses elements through parent phyiscal element index. * The root of tree is already constructed using the enclosure element. */ static int ses_construct_phys_tree(ses_enum_data_t *sdp, ses_enum_chassis_t *cp, ses_phys_tree_t *sproot) { ses_enum_node_t *snp; ses_phys_tree_t *child; ses_phys_tree_t *u_watch = NULL; ses_phys_tree_t *u_head = NULL; ses_phys_tree_t *u_tail = NULL; int u_inserted = 0, u_left = 0; nvlist_t *props; topo_mod_t *mod = sdp->sed_mod; for (snp = topo_list_next(&cp->sec_nodes); snp != NULL; snp = topo_list_next(snp)) { if ((child = topo_mod_zalloc(mod, sizeof (ses_phys_tree_t))) == NULL) { topo_mod_dprintf(mod, "failed to allocate root."); return (-1); } child->spt_snode = snp->sen_node; props = ses_node_props(snp->sen_node); if (nvlist_lookup_uint64(props, LIBSES_PROP_PHYS_PARENT, &child->spt_pindex) != 0) { /* * the prop should exist. continue to see if * we can build a partial tree with other elements. */ topo_mod_dprintf(mod, "ses_construct_phys_tree(): Failed to find prop %s " "on ses element type %d and instance %d " "(CSN %s).", LIBSES_PROP_PHYS_PARENT, snp->sen_type, snp->sen_instance, cp->sec_csn); topo_mod_free(mod, child, sizeof (ses_phys_tree_t)); continue; } else { if (nvlist_lookup_boolean_value(props, LIBSES_PROP_FRU, &child->spt_isfru) != 0) { topo_mod_dprintf(mod, "ses_construct_phys_tree(): Failed to " "find prop %s on ses element type %d " "and instance %d (CSN %s).", LIBSES_PROP_FRU, snp->sen_type, snp->sen_instance, cp->sec_csn); /* * Ignore if the prop doesn't exist. * Note that the enclosure itself should be * a FRU so if no FRU found the enclosure FRU * can be a direct FRU. */ } verify(nvlist_lookup_uint64(props, SES_PROP_ELEMENT_ONLY_INDEX, &child->spt_eonlyindex) == 0); verify(nvlist_lookup_uint64(props, SES_PROP_ELEMENT_CLASS_INDEX, &child->spt_cindex) == 0); } child->spt_senumnode = snp; if (ses_phys_tree_insert(mod, &sproot, child) != 0) { /* collect unresolved element to process later. */ if (u_head == NULL) { u_head = child; u_tail = child; } else { child->spt_sibling = u_head; u_head = child; } } } /* * The parent of a child node may not be inserted yet. * Trying to insert the child until no child is left or * no child is not added further. For the latter * the hierarchical relationship between elements * should be checked through SUNW,FRUID page. * u_watch is a watch dog to check the prgress of unresolved * node. */ u_watch = u_tail; while (u_head) { child = u_head; u_head = u_head->spt_sibling; if (u_head == NULL) u_tail = NULL; child->spt_sibling = NULL; if (ses_phys_tree_insert(mod, &sproot, child) != 0) { u_tail->spt_sibling = child; u_tail = child; if (child == u_watch) { /* * We just scanned one round for the * unresolved list. Check to see whether we * have nodes inserted, if none, we should * break in case of an indefinite loop. */ if (u_inserted == 0) { /* * Indicate there is unhandled node. * Chain free the whole unsolved * list here. */ u_left++; break; } else { u_inserted = 0; u_watch = u_tail; } } } else { /* * We just inserted one rpnode, increment the * unsolved_inserted counter. We will utilize this * counter to detect an indefinite insertion loop. */ u_inserted++; if (child == u_watch) { /* * watch dog node itself is inserted. * Set it to the tail and refresh the watching. */ u_watch = u_tail; u_inserted = 0; u_left = 0; } } } /* check if there is left out unresolved nodes. */ if (u_left) { topo_mod_dprintf(mod, "ses_construct_phys_tree(): " "Failed to construct physical view of the following " "ses elements of Chassis CSN %s.", cp->sec_csn); while (u_head) { u_tail = u_head->spt_sibling; topo_mod_dprintf(mod, "\telement type (%d) and instance (%d)", u_head->spt_senumnode->sen_type, u_head->spt_senumnode->sen_instance); topo_mod_free(mod, u_head, sizeof (ses_phys_tree_t)); u_head = u_tail; } return (-1); } return (0); } /* * Free the whole phys tree. */ static void ses_phys_tree_free(topo_mod_t *mod, ses_phys_tree_t *sproot) { if (sproot == NULL) return; /* Free child tree. */ if (sproot->spt_child) { ses_phys_tree_free(mod, sproot->spt_child); } /* Free sibling trees. */ if (sproot->spt_sibling) { ses_phys_tree_free(mod, sproot->spt_sibling); } /* Free root node itself. */ topo_mod_free(mod, sproot, sizeof (ses_phys_tree_t)); } /* * Parses phys_enum_type table to get the index of the given type. */ static boolean_t is_type_enumerated(ses_phys_tree_t *node, int *index) { int i; for (i = 0; i < N_PHYS_ENUM_TYPES; i++) { if (node->spt_senumnode->sen_type == phys_enum_type_list[i].pet_type) { *index = i; return (B_TRUE); } } return (B_FALSE); } /* * Recusrive routine for top-down enumeration of the tree. */ static int ses_enumerate_node(ses_enum_data_t *sdp, tnode_t *pnode, ses_enum_chassis_t *cp, ses_phys_tree_t *parent, int mrange[]) { topo_mod_t *mod = sdp->sed_mod; ses_phys_tree_t *child = NULL; int i, ret = 0, ret_ch; uint64_t prevtype = SES_ET_UNSPECIFIED; ses_phys_tree_t *dirfru = NULL; tnode_t *tn = NULL, *frutn = NULL; if (parent == NULL) { return (0); } for (child = parent->spt_child; child != NULL; child = child->spt_sibling) { if (is_type_enumerated(child, &i)) { if (prevtype != phys_enum_type_list[i].pet_type) { /* check if range needs to be created. */ if (phys_enum_type_list[i].pet_dorange && topo_node_range_create(mod, pnode, phys_enum_type_list[i].pet_nodename, 0, mrange[i]) != 0) { topo_mod_dprintf(mod, "topo_node_create_range() failed: " "%s", topo_mod_errmsg(mod)); return (-1); } prevtype = phys_enum_type_list[i].pet_type; } if (!(child->spt_isfru)) { for (dirfru = parent; dirfru != NULL; dirfru = dirfru->spt_parent) { if (dirfru->spt_isfru) { break; } } /* found direct FRU node. */ if (dirfru) { frutn = dirfru->spt_tnode; } else { frutn = NULL; } } else { frutn = NULL; } if (ses_create_generic(sdp, child->spt_senumnode, pnode, frutn, phys_enum_type_list[i].pet_nodename, phys_enum_type_list[i].pet_defaultlabel, &tn) != 0) return (-1); child->spt_tnode = tn; /* * For some SES element there may be protocol specific * information to process. Here we are processing * the association between enclosure controller and * SAS expanders. */ if (phys_enum_type_list[i].pet_type == SES_ET_ESC_ELECTRONICS) { /* create SAS expander node */ if (ses_create_protocol_specific(sdp, child->spt_senumnode, tn, phys_enum_type_list[i].pet_type, cp, phys_enum_type_list[i].pet_dorange) != 0) { return (-1); } } } else { continue; } ret_ch = ses_enumerate_node(sdp, tn, cp, child, mrange); if (ret_ch) ret = ret_ch; /* there was an error and set the ret. */ } return (ret); } /* * Instantiate types of nodes that are specified in the hierarchy * element type list. */ static int ses_create_children_from_phys_tree(ses_enum_data_t *sdp, tnode_t *pnode, ses_enum_chassis_t *cp, ses_phys_tree_t *phys_tree) { topo_mod_t *mod = sdp->sed_mod; int mrange[N_PHYS_ENUM_TYPES] = { 0 }; ses_enum_node_t *snp; int i, ret; /* * First get max range for each type of element to be enumerated. */ for (i = 0; i < N_PHYS_ENUM_TYPES; i++) { if (phys_enum_type_list[i].pet_dorange) { for (snp = topo_list_next(&cp->sec_nodes); snp != NULL; snp = topo_list_next(snp)) { if (snp->sen_type == phys_enum_type_list[i].pet_type) { if (snp->sen_instance > mrange[i]) mrange[i] = snp->sen_instance; } } } } topo_mod_dprintf(mod, "%s: creating nodes from FRU hierarchy tree.", cp->sec_csn); if ((ret = ses_enumerate_node(sdp, pnode, cp, phys_tree, mrange)) != 0) { topo_mod_dprintf(mod, "ses_create_children_from_phys_tree() failed: "); return (ret); } return (0); } /* * Instantiate a new chassis instance in the topology. */ static int ses_create_chassis(ses_enum_data_t *sdp, tnode_t *pnode, ses_enum_chassis_t *cp) { topo_mod_t *mod = sdp->sed_mod; nvlist_t *props; char *raw_manufacturer, *raw_model, *raw_revision; char *manufacturer = NULL, *model = NULL, *product = NULL; char *revision = NULL; char *serial; char **paths; size_t prodlen; tnode_t *tn; nvlist_t *fmri = NULL, *auth = NULL; int ret = -1; ses_enum_node_t *snp; ses_enum_target_t *stp; ses_enum_chassis_t *scp; int i, err; uint64_t sc_count = 0, pindex; ses_phys_tree_t *sproot = NULL; hrtime_t start; hrtime_t end; double duration; /* * Ignore any internal enclosures. */ if (cp->sec_internal) return (0); /* * Check to see if there are any devices presennt in the chassis. If * not, ignore the chassis alltogether. This is most useful for * ignoring internal HBAs that present a SES target but don't actually * manage any of the devices. */ for (snp = topo_list_next(&cp->sec_nodes); snp != NULL; snp = topo_list_next(snp)) { if (snp->sen_type == SES_ET_DEVICE || snp->sen_type == SES_ET_ARRAY_DEVICE) break; } if (snp == NULL) return (0); props = ses_node_props(cp->sec_enclosure); /* * We use the following property mappings: * * manufacturer vendor-id * model product-id * serial-number libses-chassis-serial */ verify(nvlist_lookup_string(props, SES_EN_PROP_VID, &raw_manufacturer) == 0); verify(nvlist_lookup_string(props, SES_EN_PROP_PID, &raw_model) == 0); verify(nvlist_lookup_string(props, SES_EN_PROP_REV, &raw_revision) == 0); verify(nvlist_lookup_string(props, LIBSES_EN_PROP_CSN, &serial) == 0); /* * To construct the authority information, we 'clean' each string by * removing any offensive characters and trimmming whitespace. For the * 'product-id', we use a concatenation of 'manufacturer-model'. We * also take the numerical serial number and convert it to a string. */ if ((manufacturer = topo_mod_clean_str(mod, raw_manufacturer)) == NULL || (model = topo_mod_clean_str(mod, raw_model)) == NULL || (revision = topo_mod_clean_str(mod, raw_revision)) == NULL) { goto error; } prodlen = strlen(manufacturer) + strlen(model) + 2; if ((product = topo_mod_alloc(mod, prodlen)) == NULL) goto error; (void) snprintf(product, prodlen, "%s-%s", manufacturer, model); /* * Construct the topo node and bind it to our parent. */ if (topo_mod_nvalloc(mod, &auth, NV_UNIQUE_NAME) != 0) goto error; if (nvlist_add_string(auth, FM_FMRI_AUTH_PRODUCT, product) != 0 || nvlist_add_string(auth, FM_FMRI_AUTH_CHASSIS, serial) != 0) { (void) topo_mod_seterrno(mod, EMOD_NVL_INVAL); goto error; } /* * We pass NULL for the parent FMRI because there is no resource * associated with it. For the toplevel enclosure, we leave the * serial/part/revision portions empty, which are reserved for * individual components within the chassis. */ if ((fmri = topo_mod_hcfmri(mod, NULL, FM_HC_SCHEME_VERSION, SES_ENCLOSURE, cp->sec_instance, NULL, auth, model, revision, serial)) == NULL) { topo_mod_dprintf(mod, "topo_mod_hcfmri() failed: %s", topo_mod_errmsg(mod)); goto error; } if ((tn = topo_node_bind(mod, pnode, SES_ENCLOSURE, cp->sec_instance, fmri)) == NULL) { topo_mod_dprintf(mod, "topo_node_bind() failed: %s", topo_mod_errmsg(mod)); goto error; } if (topo_method_register(mod, tn, ses_enclosure_methods) != 0) { topo_mod_dprintf(mod, "topo_method_register() failed: %s", topo_mod_errmsg(mod)); goto error; } if (ses_set_standard_props(mod, NULL, tn, auth, ses_node_id(cp->sec_enclosure), cp->sec_target->set_devpath) != 0) goto error; /* * For enclosures, we want to include all possible targets (for upgrade * purposes). */ for (i = 0, stp = topo_list_next(&cp->sec_targets); stp != NULL; stp = topo_list_next(stp), i++) ; verify(i != 0); paths = alloca(i * sizeof (char *)); for (i = 0, stp = topo_list_next(&cp->sec_targets); stp != NULL; stp = topo_list_next(stp), i++) paths[i] = stp->set_devpath; if (topo_prop_set_string_array(tn, TOPO_PGROUP_SES, TOPO_PROP_PATHS, TOPO_PROP_IMMUTABLE, (const char **)paths, i, &err) != 0) { topo_mod_dprintf(mod, "failed to create property %s: %s\n", TOPO_PROP_PATHS, topo_strerror(err)); goto error; } if (nvlist_lookup_uint64(props, LIBSES_PROP_PHYS_PARENT, &pindex) == 0) { start = gethrtime(); /* to mearusre performance */ /* * The enclosure is supported through SUNW,FRUID. * Need to enumerate the nodes through hierarchical order. */ if ((sproot = topo_mod_zalloc(mod, sizeof (ses_phys_tree_t))) == NULL) { topo_mod_dprintf(mod, "failed to allocate root: %s\n", topo_strerror(err)); goto error; } sproot->spt_pindex = pindex; if (nvlist_lookup_boolean_value(props, LIBSES_PROP_FRU, &sproot->spt_isfru) != 0) { topo_mod_dprintf(mod, "ses_create_chassis(): Failed to find prop %s " "on enclosure element (CSN %s).", LIBSES_PROP_FRU, cp->sec_csn); /* an enclosure should be a FRU. continue to process. */ sproot->spt_isfru = B_TRUE; } if (nvlist_lookup_uint64(props, SES_PROP_ELEMENT_ONLY_INDEX, &sproot->spt_eonlyindex) != 0) { topo_mod_dprintf(mod, "ses_create_chassis(): Failed to find prop %s " "on enclosure element (CSN %s).", LIBSES_PROP_PHYS_PARENT, cp->sec_csn); topo_mod_free(mod, sproot, sizeof (ses_phys_tree_t)); goto error; } if (sproot->spt_pindex != sproot->spt_eonlyindex) { topo_mod_dprintf(mod, "ses_create_chassis(): " "Enclosure element(CSN %s) should have " "itself as the parent to be the root node " "of FRU hierarchical tree.)", cp->sec_csn); topo_mod_free(mod, sproot, sizeof (ses_phys_tree_t)); goto error; } else { sproot->spt_snode = cp->sec_enclosure; sproot->spt_tnode = tn; /* construct a tree. */ if (ses_construct_phys_tree(sdp, cp, sproot) != 0) { topo_mod_dprintf(mod, "ses_create_chassis(): " "Failed to construct FRU hierarchical " "tree on enclosure (CSN %s.)", cp->sec_csn); } /* enumerate elements from the tree. */ if (ses_create_children_from_phys_tree(sdp, tn, cp, sproot) != 0) { topo_mod_dprintf(mod, "ses_create_chassis(): " "Failed to create children topo nodes out " "of FRU hierarchical tree on enclosure " "(CSN %s).", cp->sec_csn); } /* destroy the phys tree. */ ses_phys_tree_free(mod, sproot); } end = gethrtime(); duration = end - start; duration /= HR_SECOND; topo_mod_dprintf(mod, "FRU boundary tree based enumeration: %.6f seconds", duration); } else { /* * Create the nodes for power supplies, fans, controllers and * devices. Note that SAS exopander nodes and connector nodes * are handled through protocol specific processing of * controllers. */ if (ses_create_children(sdp, tn, SES_ET_POWER_SUPPLY, PSU, "PSU", cp, B_TRUE) != 0 || ses_create_children(sdp, tn, SES_ET_COOLING, FAN, "FAN", cp, B_TRUE) != 0 || ses_create_children(sdp, tn, SES_ET_ESC_ELECTRONICS, CONTROLLER, "CONTROLLER", cp, B_TRUE) != 0 || ses_create_children(sdp, tn, SES_ET_DEVICE, BAY, "BAY", cp, B_TRUE) != 0 || ses_create_children(sdp, tn, SES_ET_ARRAY_DEVICE, BAY, "BAY", cp, B_TRUE) != 0) goto error; } if (cp->sec_maxinstance != SES_INST_NOTSET && (topo_node_range_create(mod, tn, SUBCHASSIS, 0, cp->sec_maxinstance) != 0)) { topo_mod_dprintf(mod, "topo_node_create_range() failed: %s", topo_mod_errmsg(mod)); goto error; } for (scp = topo_list_next(&cp->sec_subchassis); scp != NULL; scp = topo_list_next(scp)) { if (ses_create_subchassis(sdp, tn, scp) != 0) goto error; topo_mod_dprintf(mod, "created Subchassis node with " "instance %u\nand target (%s) under Chassis with CSN %s", scp->sec_instance, scp->sec_target->set_devpath, cp->sec_csn); sc_count++; } topo_mod_dprintf(mod, "%s: created %llu %s nodes", cp->sec_csn, sc_count, SUBCHASSIS); cp->sec_target->set_refcount++; topo_node_setspecific(tn, cp->sec_target); ret = 0; error: topo_mod_strfree(mod, manufacturer); topo_mod_strfree(mod, model); topo_mod_strfree(mod, revision); topo_mod_strfree(mod, product); nvlist_free(fmri); nvlist_free(auth); return (ret); } /* * Create a bay node explicitly enumerated via XML. */ static int ses_create_bays(ses_enum_data_t *sdp, tnode_t *pnode) { topo_mod_t *mod = sdp->sed_mod; ses_enum_chassis_t *cp; /* * Iterate over chassis looking for an internal enclosure. This * property is set via a vendor-specific plugin, and there should only * ever be a single internal chassis in a system. */ for (cp = topo_list_next(&sdp->sed_chassis); cp != NULL; cp = topo_list_next(cp)) { if (cp->sec_internal) break; } if (cp == NULL) { topo_mod_dprintf(mod, "failed to find internal chassis\n"); return (-1); } if (ses_create_children(sdp, pnode, SES_ET_DEVICE, BAY, "BAY", cp, B_FALSE) != 0 || ses_create_children(sdp, pnode, SES_ET_ARRAY_DEVICE, BAY, "BAY", cp, B_FALSE) != 0) return (-1); return (0); } /* * Initialize chassis or subchassis. */ static int ses_init_chassis(topo_mod_t *mod, ses_enum_data_t *sdp, ses_enum_chassis_t *pcp, ses_enum_chassis_t *cp, ses_node_t *np, nvlist_t *props, uint64_t subchassis, ses_chassis_type_e flags) { boolean_t internal, ident; assert((flags & (SES_NEW_CHASSIS | SES_NEW_SUBCHASSIS | SES_DUP_CHASSIS | SES_DUP_SUBCHASSIS)) != 0); assert(cp != NULL); assert(np != NULL); assert(props != NULL); if (flags & (SES_NEW_SUBCHASSIS | SES_DUP_SUBCHASSIS)) assert(pcp != NULL); topo_mod_dprintf(mod, "ses_init_chassis: %s: index %llu, flags (%d)", sdp->sed_name, subchassis, flags); if (flags & (SES_NEW_CHASSIS | SES_NEW_SUBCHASSIS)) { topo_mod_dprintf(mod, "new chassis/subchassis"); if (nvlist_lookup_boolean_value(props, LIBSES_EN_PROP_INTERNAL, &internal) == 0) cp->sec_internal = internal; cp->sec_enclosure = np; cp->sec_target = sdp->sed_target; if (flags & SES_NEW_CHASSIS) { if (!cp->sec_internal) cp->sec_instance = sdp->sed_instance++; topo_list_append(&sdp->sed_chassis, cp); } else { if (subchassis != NO_SUBCHASSIS) cp->sec_instance = subchassis; else cp->sec_instance = pcp->sec_scinstance++; if (cp->sec_instance > pcp->sec_maxinstance) pcp->sec_maxinstance = cp->sec_instance; topo_list_append(&pcp->sec_subchassis, cp); } } else { topo_mod_dprintf(mod, "dup chassis/subchassis"); if (nvlist_lookup_boolean_value(props, SES_PROP_IDENT, &ident) == 0) { topo_mod_dprintf(mod, "overriding enclosure node"); cp->sec_enclosure = np; cp->sec_target = sdp->sed_target; } } topo_list_append(&cp->sec_targets, sdp->sed_target); sdp->sed_current = cp; return (0); } /* * Gather nodes from the current SES target into our chassis list, merging the * results if necessary. */ static ses_walk_action_t ses_enum_gather(ses_node_t *np, void *data) { nvlist_t *props = ses_node_props(np); ses_enum_data_t *sdp = data; topo_mod_t *mod = sdp->sed_mod; ses_enum_chassis_t *cp, *scp; ses_enum_node_t *snp; ses_alt_node_t *sap; char *csn; uint64_t instance, type; uint64_t prevstatus, status; boolean_t report; uint64_t subchassis = NO_SUBCHASSIS; if (ses_node_type(np) == SES_NODE_ENCLOSURE) { /* * If we have already identified the chassis for this target, * then this is a secondary enclosure and we should ignore it, * along with the rest of the tree (since this is depth-first). */ if (sdp->sed_current != NULL) return (SES_WALK_ACTION_TERMINATE); /* * Go through the list of chassis we have seen so far and see * if this serial number matches one of the known values. * If so, check whether this enclosure is a subchassis. */ if (nvlist_lookup_string(props, LIBSES_EN_PROP_CSN, &csn) != 0) return (SES_WALK_ACTION_TERMINATE); (void) nvlist_lookup_uint64(props, LIBSES_EN_PROP_SUBCHASSIS_ID, &subchassis); topo_mod_dprintf(mod, "ses_enum_gather: Enclosure Node (%s) " "CSN (%s), subchassis (%llu)", sdp->sed_name, csn, subchassis); /* * We need to determine whether this enclosure node * represents a chassis or a subchassis. Since we may * receive the enclosure nodes in a non-deterministic * manner, we need to account for all possible combinations: * 1. Chassis for the current CSN has not yet been * allocated * 1.1 This is a new chassis: * allocate and instantiate the chassis * 1.2 This is a new subchassis: * allocate a placeholder chassis * allocate and instantiate the subchassis * link the subchassis to the chassis * 2. Chassis for the current CSN has been allocated * 2.1 This is a duplicate chassis enclosure * check whether to override old chassis * append to chassis' target list * 2.2 Only placeholder chassis exists * fill in the chassis fields * 2.3 This is a new subchassis * allocate and instantiate the subchassis * link the subchassis to the chassis * 2.4 This is a duplicate subchassis enclosure * check whether to override old chassis * append to chassis' target list */ for (cp = topo_list_next(&sdp->sed_chassis); cp != NULL; cp = topo_list_next(cp)) if (strcmp(cp->sec_csn, csn) == 0) break; if (cp == NULL) { /* 1. Haven't seen a chassis with this CSN before */ if ((cp = topo_mod_zalloc(mod, sizeof (ses_enum_chassis_t))) == NULL) goto error; cp->sec_scinstance = SES_STARTING_SUBCHASSIS; cp->sec_maxinstance = SES_INST_NOTSET; cp->sec_csn = csn; if (subchassis == NO_SUBCHASSIS) { /* 1.1 This is a new chassis */ topo_mod_dprintf(mod, "%s: Initialize new " "chassis with CSN %s", sdp->sed_name, csn); if (ses_init_chassis(mod, sdp, NULL, cp, np, props, NO_SUBCHASSIS, SES_NEW_CHASSIS) < 0) goto error; } else { /* 1.2 This is a new subchassis */ topo_mod_dprintf(mod, "%s: Initialize new " "subchassis with CSN %s and index %llu", sdp->sed_name, csn, subchassis); if ((scp = topo_mod_zalloc(mod, sizeof (ses_enum_chassis_t))) == NULL) goto error; scp->sec_csn = csn; if (ses_init_chassis(mod, sdp, cp, scp, np, props, subchassis, SES_NEW_SUBCHASSIS) < 0) goto error; } } else { /* * We have a chassis or subchassis with this CSN. If * it's a chassis, we must check to see whether it is * a placeholder previously created because we found a * subchassis with this CSN. We will know that because * the sec_target value will not be set; it is set only * in ses_init_chassis(). In that case, initialise it * as a new chassis; otherwise, it's a duplicate and we * need to append only. */ if (subchassis == NO_SUBCHASSIS) { if (cp->sec_target != NULL) { /* 2.1 This is a duplicate chassis */ topo_mod_dprintf(mod, "%s: Append " "duplicate chassis with CSN (%s)", sdp->sed_name, csn); if (ses_init_chassis(mod, sdp, NULL, cp, np, props, NO_SUBCHASSIS, SES_DUP_CHASSIS) < 0) goto error; } else { /* Placeholder chassis - init it up */ topo_mod_dprintf(mod, "%s: Initialize" "placeholder chassis with CSN %s", sdp->sed_name, csn); if (ses_init_chassis(mod, sdp, NULL, cp, np, props, NO_SUBCHASSIS, SES_NEW_CHASSIS) < 0) goto error; } } else { /* This is a subchassis */ for (scp = topo_list_next(&cp->sec_subchassis); scp != NULL; scp = topo_list_next(scp)) if (scp->sec_instance == subchassis) break; if (scp == NULL) { /* 2.3 This is a new subchassis */ topo_mod_dprintf(mod, "%s: Initialize " "new subchassis with CSN (%s) " "and LID (%s)", sdp->sed_name, csn); if ((scp = topo_mod_zalloc(mod, sizeof (ses_enum_chassis_t))) == NULL) goto error; scp->sec_csn = csn; if (ses_init_chassis(mod, sdp, cp, scp, np, props, subchassis, SES_NEW_SUBCHASSIS) < 0) goto error; } else { /* 2.4 This is a duplicate subchassis */ topo_mod_dprintf(mod, "%s: Append " "duplicate subchassis with " "CSN (%s)", sdp->sed_name, csn); if (ses_init_chassis(mod, sdp, cp, scp, np, props, subchassis, SES_DUP_SUBCHASSIS) < 0) goto error; } } } } else if (ses_node_type(np) == SES_NODE_ELEMENT) { /* * If we haven't yet seen an enclosure node and identified the * current chassis, something is very wrong; bail out. */ if (sdp->sed_current == NULL) return (SES_WALK_ACTION_TERMINATE); /* * If this isn't one of the element types we care about, then * ignore it. */ verify(nvlist_lookup_uint64(props, SES_PROP_ELEMENT_TYPE, &type) == 0); if (type != SES_ET_DEVICE && type != SES_ET_ARRAY_DEVICE && type != SES_ET_SUNW_FANBOARD && type != SES_ET_SUNW_FANMODULE && type != SES_ET_COOLING && type != SES_ET_SUNW_POWERBOARD && type != SES_ET_SUNW_POWERMODULE && type != SES_ET_POWER_SUPPLY && type != SES_ET_ESC_ELECTRONICS && type != SES_ET_SAS_EXPANDER && type != SES_ET_SAS_CONNECTOR) return (SES_WALK_ACTION_CONTINUE); /* * Get the current instance number and see if we already know * about this element. If so, it means we have multiple paths * to the same elements, and we should ignore the current path. */ verify(nvlist_lookup_uint64(props, SES_PROP_ELEMENT_CLASS_INDEX, &instance) == 0); if (type == SES_ET_DEVICE || type == SES_ET_ARRAY_DEVICE) (void) nvlist_lookup_uint64(props, SES_PROP_BAY_NUMBER, &instance); cp = sdp->sed_current; for (snp = topo_list_next(&cp->sec_nodes); snp != NULL; snp = topo_list_next(snp)) { if (snp->sen_type == type && snp->sen_instance == instance) break; } /* * We prefer the new element under the following circumstances: * * - The currently known element's status is unknown or not * available, but the new element has a known status. This * occurs if a given element is only available through a * particular target. * * - This is an ESC_ELECTRONICS element, and the 'reported-via' * property is set. This allows us to get reliable firmware * revision information from the enclosure node. */ if (snp != NULL) { if (nvlist_lookup_uint64( ses_node_props(snp->sen_node), SES_PROP_STATUS_CODE, &prevstatus) != 0) prevstatus = SES_ESC_UNSUPPORTED; if (nvlist_lookup_uint64( props, SES_PROP_STATUS_CODE, &status) != 0) status = SES_ESC_UNSUPPORTED; if (nvlist_lookup_boolean_value( props, SES_PROP_REPORT, &report) != 0) report = B_FALSE; if ((SES_STATUS_UNAVAIL(prevstatus) && !SES_STATUS_UNAVAIL(status)) || (type == SES_ET_ESC_ELECTRONICS && report)) { snp->sen_node = np; snp->sen_target = sdp->sed_target; } if ((sap = topo_mod_zalloc(mod, sizeof (ses_alt_node_t))) == NULL) goto error; sap->san_node = np; topo_list_append(&snp->sen_alt_nodes, sap); return (SES_WALK_ACTION_CONTINUE); } if ((snp = topo_mod_zalloc(mod, sizeof (ses_enum_node_t))) == NULL) goto error; if ((sap = topo_mod_zalloc(mod, sizeof (ses_alt_node_t))) == NULL) { topo_mod_free(mod, snp, sizeof (ses_enum_node_t)); goto error; } topo_mod_dprintf(mod, "%s: adding node (%llu, %llu)", sdp->sed_name, type, instance); snp->sen_node = np; snp->sen_type = type; snp->sen_instance = instance; snp->sen_target = sdp->sed_target; sap->san_node = np; topo_list_append(&snp->sen_alt_nodes, sap); topo_list_append(&cp->sec_nodes, snp); if (type == SES_ET_DEVICE) cp->sec_hasdev = B_TRUE; } return (SES_WALK_ACTION_CONTINUE); error: sdp->sed_errno = -1; return (SES_WALK_ACTION_TERMINATE); } static int ses_process_dir(const char *dirpath, ses_enum_data_t *sdp) { topo_mod_t *mod = sdp->sed_mod; DIR *dir; struct dirent *dp; char path[PATH_MAX]; ses_enum_target_t *stp; int err = -1; /* * Open the SES target directory and iterate over any available * targets. */ if ((dir = opendir(dirpath)) == NULL) { /* * If the SES target directory does not exist, then return as if * there are no active targets. */ topo_mod_dprintf(mod, "failed to open ses " "directory '%s'", dirpath); return (0); } while ((dp = readdir(dir)) != NULL) { if (strcmp(dp->d_name, ".") == 0 || strcmp(dp->d_name, "..") == 0) continue; /* * Create a new target instance and take a snapshot. */ if ((stp = topo_mod_zalloc(mod, sizeof (ses_enum_target_t))) == NULL) goto error; (void) pthread_mutex_init(&stp->set_lock, NULL); (void) snprintf(path, sizeof (path), "%s/%s", dirpath, dp->d_name); /* * We keep track of the SES device path and export it on a * per-node basis to allow higher level software to get to the * corresponding SES state. */ if ((stp->set_devpath = topo_mod_strdup(mod, path)) == NULL) { topo_mod_free(mod, stp, sizeof (ses_enum_target_t)); goto error; } if ((stp->set_target = ses_open(LIBSES_VERSION, path)) == NULL) { topo_mod_dprintf(mod, "failed to open ses target " "'%s': %s", dp->d_name, ses_errmsg()); ses_sof_alloc(mod, stp->set_devpath); topo_mod_free(mod, stp, sizeof (ses_enum_target_t)); continue; } topo_mod_dprintf(mod, "open contract"); ses_ssl_alloc(mod, stp); ses_create_contract(mod, stp); stp->set_refcount = 1; sdp->sed_target = stp; stp->set_snap = ses_snap_hold(stp->set_target); stp->set_snaptime = gethrtime(); /* * Enumerate over all SES elements and merge them into the * correct ses_enum_chassis_t. */ sdp->sed_current = NULL; sdp->sed_errno = 0; sdp->sed_name = dp->d_name; (void) ses_walk(stp->set_snap, ses_enum_gather, sdp); if (sdp->sed_errno != 0) goto error; } err = 0; error: (void) closedir(dir); return (err); } /* * Different generations of SMCI's 4U36 storage servers used different models * of front and rear SAS expanders. */ #define SMCI4U36_FRONT_EXPANDER_PID1 "LSI-SAS2X36" #define SMCI4U36_FRONT_EXPANDER_PID2 "LSI-SAS3x40" #define SMCI4U36_FRONT_EXPANDER_PID3 "SMC-SC846P" #define SMCI4U36_REAR_EXPANDER_PID1 "LSI-CORP-SAS2X28" #define SMCI4U36_REAR_EXPANDER_PID2 "LSI-SAS3x28" static int smci_4u36_bay_label(topo_mod_t *mod, tnode_t *node, topo_version_t version, nvlist_t *in, nvlist_t **out) { int err, ret = -1; nvlist_t *pargs, *auth, *nvl = NULL, *fmri; char *label = NULL, *product_id; /* * Now look for a private argument list to determine if the invoker is * trying to do a set operation and if so, return an error as this * method only supports get operations. */ if ((nvlist_lookup_nvlist(in, TOPO_PROP_PARGS, &pargs) == 0) && nvlist_exists(pargs, TOPO_PROP_VAL_VAL)) { topo_mod_dprintf(mod, "%s: set operation not suppported", __func__); return (topo_mod_seterrno(mod, EMOD_NVL_INVAL)); } if (topo_node_resource(node, &fmri, &err) != 0) { (void) topo_mod_seterrno(mod, err); goto err; } if (nvlist_lookup_nvlist(fmri, FM_FMRI_AUTHORITY, &auth) != 0 || nvlist_lookup_string(auth, FM_FMRI_AUTH_PRODUCT, &product_id) != 0) { topo_mod_dprintf(mod, "%s: malformed FMRI", __func__); (void) topo_mod_seterrno(mod, EMOD_UNKNOWN); nvlist_free(fmri); goto err; } nvlist_free(fmri); if (strcmp(product_id, SMCI4U36_FRONT_EXPANDER_PID1) == 0 || strcmp(product_id, SMCI4U36_FRONT_EXPANDER_PID2) == 0 || strcmp(product_id, SMCI4U36_FRONT_EXPANDER_PID3) == 0) { err = asprintf(&label, "Front Slot %" PRIu64, topo_node_instance(node)); } else if (strcmp(product_id, SMCI4U36_REAR_EXPANDER_PID1) == 0 || strcmp(product_id, SMCI4U36_REAR_EXPANDER_PID2) == 0) { err = asprintf(&label, "Rear Slot %" PRIu64, topo_node_instance(node)); } else { topo_mod_dprintf(mod, "%s: unexpected expander product id: %s", __func__, product_id); (void) topo_mod_seterrno(mod, EMOD_UNKNOWN); goto err; } if (err < 0) { (void) topo_mod_seterrno(mod, EMOD_NOMEM); goto err; } if (topo_mod_nvalloc(mod, &nvl, NV_UNIQUE_NAME) != 0 || nvlist_add_string(nvl, TOPO_PROP_VAL_NAME, TOPO_PROP_LABEL) != 0 || nvlist_add_uint32(nvl, TOPO_PROP_VAL_TYPE, TOPO_TYPE_STRING) != 0 || nvlist_add_string(nvl, TOPO_PROP_VAL_VAL, label) != 0) { topo_mod_dprintf(mod, "Failed to allocate 'out' nvlist"); nvlist_free(nvl); (void) topo_mod_seterrno(mod, EMOD_NOMEM); goto err; } *out = nvl; ret = 0; err: free(label); return (ret); } static void ses_release(topo_mod_t *mod, tnode_t *tn) { ses_enum_target_t *stp; if ((stp = topo_node_getspecific(tn)) != NULL) { topo_node_setspecific(tn, NULL); ses_target_free(mod, stp); } } /*ARGSUSED*/ static int ses_enum(topo_mod_t *mod, tnode_t *rnode, const char *name, topo_instance_t min, topo_instance_t max, void *arg, void *notused) { ses_enum_chassis_t *cp; ses_enum_data_t *data; /* * Check to make sure we're being invoked sensibly, and that we're not * being invoked as part of a post-processing step. */ if (strcmp(name, SES_ENCLOSURE) != 0 && strcmp(name, BAY) != 0) return (0); /* * If this is the first time we've called our enumeration method, then * gather information about any available enclosures. */ if ((data = topo_mod_getspecific(mod)) == NULL) { ses_sof_freeall(mod); if ((data = topo_mod_zalloc(mod, sizeof (ses_enum_data_t))) == NULL) return (-1); data->sed_mod = mod; topo_mod_setspecific(mod, data); if (dev_list_gather(mod, &data->sed_devs) != 0) goto error; /* * We search both the ses(7D) and sgen(7D) locations, so we are * independent of any particular driver class bindings. */ if (ses_process_dir("/dev/es", data) != 0 || ses_process_dir("/dev/scsi/ses", data) != 0) goto error; } if (strcmp(name, SES_ENCLOSURE) == 0) { /* * This is a request to enumerate external enclosures. Go * through all the targets and create chassis nodes where * necessary. */ for (cp = topo_list_next(&data->sed_chassis); cp != NULL; cp = topo_list_next(cp)) { if (ses_create_chassis(data, rnode, cp) != 0) goto error; } } else { /* * This is a request to enumerate a specific bay underneath the * root chassis (for internal disks). */ if (ses_create_bays(data, rnode) != 0) goto error; } /* * This is a bit of a kludge. In order to allow internal disks to be * enumerated and share snapshot-specific information with the external * enclosure enumeration, we rely on the fact that we will be invoked * for the 'ses-enclosure' node last. */ if (strcmp(name, SES_ENCLOSURE) == 0) { for (cp = topo_list_next(&data->sed_chassis); cp != NULL; cp = topo_list_next(cp)) ses_data_free(data, cp); ses_data_free(data, NULL); topo_mod_setspecific(mod, NULL); } return (0); error: for (cp = topo_list_next(&data->sed_chassis); cp != NULL; cp = topo_list_next(cp)) ses_data_free(data, cp); ses_data_free(data, NULL); topo_mod_setspecific(mod, NULL); return (-1); } static const topo_modops_t ses_ops = { ses_enum, ses_release }; static topo_modinfo_t ses_info = { SES_ENCLOSURE, FM_FMRI_SCHEME_HC, SES_VERSION, &ses_ops }; /*ARGSUSED*/ int _topo_init(topo_mod_t *mod, topo_version_t version) { int rval; if (getenv("TOPOSESDEBUG") != NULL) topo_mod_setdebug(mod); topo_mod_dprintf(mod, "initializing %s enumerator\n", SES_ENCLOSURE); if ((rval = topo_mod_register(mod, &ses_info, TOPO_VERSION)) == 0) ses_thread_init(mod); return (rval); } void _topo_fini(topo_mod_t *mod) { ses_thread_fini(mod); ses_sof_freeall(mod); topo_mod_unregister(mod); }