/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2004 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Implementation of ri_init routine for obtaining mapping * of system board attachment points to physical devices and to * the Reconfiguration Coordination Manager (RCM) client usage * of these devices. */ #include #include #include #include #include #include #include "rsrc_info_impl.h" /* * Occupant types exported by cfgadm sbd plugin via * config_admin(3CFGADM). */ #define SBD_CM_CPU "cpu" #define SBD_CM_MEM "memory" #define SBD_CM_IO "io" /* * RCM abstract resource names. */ #define RCM_MEM_ALL "SUNW_memory" #define RCM_CPU_ALL "SUNW_cpu" #define RCM_CPU RCM_CPU_ALL"/cpu" #define KBYTE 1024 #define MBYTE 1048576 #define USAGE_ALLOC_SIZE 128 /* * define to allow io_cm_info to return NODE is NULL to ri_init, * in order to skip over nodes w/unattached drivers */ #define RI_NODE_NIL 1 /* * This code is CMP aware as it parses the * cfgadm info field for individual cpuids. */ #define CPUID_SEP "," #define CPU_INFO_FMT "cpuid=%s speed=%d ecache=%d" typedef struct { cfga_list_data_t *cfga_list_data; int nlist; } apd_t; typedef struct { long pagesize; long syspages; long sysmb; } mem_stat_t; #define ms_syspages m_stat.syspages #define ms_pagesize m_stat.pagesize #define ms_sysmb m_stat.sysmb typedef int32_t cpuid_t; typedef struct { int cpuid_max; /* maximum cpuid value */ int *ecache_sizes; /* indexed by cpuid */ } ecache_info_t; typedef struct { rcm_handle_t *hdl; rcm_info_t *offline_query_info; char **rlist; int nrlist; cpuid_t *cpus; int ncpus; int ndevs; uint_t query_pages; mem_stat_t m_stat; ecache_info_t ecache_info; } rcmd_t; typedef struct { const char *rsrc; const char *info; } usage_t; /* Lookup table entry for matching IO devices to RCM resource usage */ typedef struct { int index; /* index into the table array */ di_node_t node; /* associated devinfo node */ char *name; /* device full path name */ int n_usage; usage_t *usage; } lookup_entry_t; typedef struct { int n_entries; int n_slots; lookup_entry_t *table; } lookup_table_t; typedef struct { int err; di_node_t node; char *pathbuf; lookup_table_t *table; di_devlink_handle_t linkhd; } devinfo_arg_t; static int dyn_ap_ids(char *, cfga_list_data_t **, int *); static int rcm_init(rcmd_t *, apd_t [], int, int); static void rcm_fini(rcmd_t *); static int rcm_query_init(rcmd_t *, apd_t [], int); static int cap_request(ri_hdl_t *, rcmd_t *); static int syscpus(cpuid_t **, int *); static int cpu_cap_request(ri_hdl_t *, rcmd_t *); static int mem_cap_request(ri_hdl_t *, rcmd_t *); static int (*cm_rcm_qpass_func(cfga_type_t))(cfga_list_data_t *, rcmd_t *); static int cpu_rcm_qpass(cfga_list_data_t *, rcmd_t *); static int mem_rcm_qpass(cfga_list_data_t *, rcmd_t *); static int io_rcm_qpass(cfga_list_data_t *, rcmd_t *); static int (*cm_info_func(cfga_type_t))(ri_ap_t *, cfga_list_data_t *, int, rcmd_t *); static int cpu_cm_info(ri_ap_t *, cfga_list_data_t *, int, rcmd_t *); static int i_cpu_cm_info(processorid_t, int, ri_ap_t *, rcmd_t *); static int mem_cm_info(ri_ap_t *, cfga_list_data_t *, int, rcmd_t *); static int io_cm_info(ri_ap_t *, cfga_list_data_t *, int, rcmd_t *); static int ident_leaf(di_node_t); static int mk_drv_inst(di_node_t, char [], char *); static int devinfo_node_walk(di_node_t, void *); static int devinfo_minor_walk(di_node_t, di_minor_t, void *); static int devinfo_devlink_walk(di_devlink_t, void *); static int add_rcm_clients(ri_client_t **, rcmd_t *, rcm_info_t *, int, int *); static int rcm_ignore(char *, char *); static int add_query_state(rcmd_t *, ri_client_t *, const char *, const char *); static int state2query(int); static void dev_list_append(ri_dev_t **, ri_dev_t *); static void dev_list_cpu_insert(ri_dev_t **, ri_dev_t *, processorid_t); static rcm_info_tuple_t *tuple_lookup(rcmd_t *, const char *, const char *); static ri_ap_t *ri_ap_alloc(char *, ri_hdl_t *); static ri_dev_t *ri_dev_alloc(void); static ri_dev_t *io_dev_alloc(char *); static ri_client_t *ri_client_alloc(char *, char *); static void apd_tbl_free(apd_t [], int); static char *pstate2str(int); static int ecache_info_init(ecache_info_t *); static int find_cpu_nodes(di_node_t, void *); static int prop_lookup_int(di_node_t, di_prom_handle_t, char *, int **); static int add_lookup_entry(lookup_table_t *, const char *, di_node_t); static int table_compare_names(const void *, const void *); static int table_compare_indices(const void *, const void *); static lookup_entry_t *lookup(lookup_table_t *table, const char *); static int add_usage(lookup_entry_t *, const char *, rcm_info_tuple_t *); static void empty_table(lookup_table_t *); #ifdef DEBUG static void dump_apd_tbl(FILE *, apd_t *, int); #endif /* DEBUG */ static struct { char *type; int (*cm_info)(ri_ap_t *, cfga_list_data_t *, int, rcmd_t *); int (*cm_rcm_qpass)(cfga_list_data_t *, rcmd_t *); } cm_ctl[] = { {SBD_CM_CPU, cpu_cm_info, cpu_rcm_qpass}, {SBD_CM_MEM, mem_cm_info, mem_rcm_qpass}, {SBD_CM_IO, io_cm_info, io_rcm_qpass} }; /* * Table of known info string prefixes for RCM modules that do not * represent actual resource usage, but instead provide name translations * or sequencing within the RCM namespace. Since RCM provides no way to * filter these out, we must maintain this hack. */ static char *rcm_info_filter[] = { "Network interface", /* Network naming module */ NULL }; /* * Allocate snapshot handle. */ int ri_init(int n_apids, char **ap_ids, int flags, ri_hdl_t **hdlp) { int i, j; ri_hdl_t *ri_hdl; ri_ap_t *ap_hdl; rcmd_t *rcm = NULL; cfga_list_data_t *cfga_ldata; apd_t *apd, *apd_tbl = NULL; int (*cm_info)(ri_ap_t *, cfga_list_data_t *, int, rcmd_t *); int rv = RI_SUCCESS; int cm_info_rv; if (n_apids <= 0 || ap_ids == NULL || hdlp == NULL) return (RI_INVAL); if (flags & ~RI_REQ_MASK) return (RI_NOTSUP); *hdlp = NULL; if ((ri_hdl = calloc(1, sizeof (*ri_hdl))) == NULL || (rcm = calloc(1, sizeof (*rcm))) == NULL || (apd_tbl = calloc(n_apids, sizeof (*apd_tbl))) == NULL) { dprintf((stderr, "calloc: %s\n", strerror(errno))); rv = RI_FAILURE; goto out; } /* * Create mapping of boards to components. */ for (i = 0, apd = apd_tbl; i < n_apids; i++, apd++) { if (dyn_ap_ids(ap_ids[i], &apd->cfga_list_data, &apd->nlist) == -1) { rv = RI_INVAL; goto out; } } #ifdef DEBUG dump_apd_tbl(stderr, apd_tbl, n_apids); #endif /* DEBUG */ if (rcm_init(rcm, apd_tbl, n_apids, flags) != 0) { rv = RI_FAILURE; goto out; } /* * Best effort attempt to read cpu ecache sizes from * OBP/Solaris device trees. These are later looked up * in i_cpu_cm_info(). */ (void) ecache_info_init(&rcm->ecache_info); for (i = 0, apd = apd_tbl; i < n_apids; i++, apd++) { if ((ap_hdl = ri_ap_alloc(ap_ids[i], ri_hdl)) == NULL) { rv = RI_FAILURE; goto out; } /* * Add component info based on occupant type. Note all * passes through the apd table skip over the first * cfgadm_list_data entry, which is the static system board * attachment point. */ for (j = 1, cfga_ldata = &apd->cfga_list_data[1]; j < apd->nlist; j++, cfga_ldata++) { if (cfga_ldata->ap_o_state != CFGA_STAT_CONFIGURED) { continue; } if ((cm_info = cm_info_func(cfga_ldata->ap_type)) != NULL) { cm_info_rv = (*cm_info)(ap_hdl, cfga_ldata, flags, rcm); if (cm_info_rv != 0) { /* * If we cannot obtain info for the ap, * skip it and do not fail the entire * operation. This case occurs when the * driver for a device is not attached: * di_init() returns failed back to * io_cm_info(). */ if (cm_info_rv == RI_NODE_NIL) continue; else { rv = RI_FAILURE; goto out; } } } } } if ((flags & RI_INCLUDE_QUERY) && cap_request(ri_hdl, rcm) != 0) rv = RI_FAILURE; out: if (apd_tbl != NULL) apd_tbl_free(apd_tbl, n_apids); if (rcm != NULL) rcm_fini(rcm); if (rv == RI_SUCCESS) *hdlp = ri_hdl; else ri_fini(ri_hdl); return (rv); } /* * Map static board attachment point to dynamic attachment points (components). */ static int dyn_ap_ids(char *ap_id, cfga_list_data_t **ap_id_list, int *nlist) { cfga_err_t cfga_err; char *errstr; char *opts = "parsable"; char *listops = "class=sbd"; cfga_err = config_list_ext(1, &ap_id, ap_id_list, nlist, opts, listops, &errstr, CFGA_FLAG_LIST_ALL); if (cfga_err != CFGA_OK) { dprintf((stderr, "config_list_ext: %s\n", config_strerror(cfga_err))); return (-1); } return (0); } /* * Initialize rcm handle, memory stats. Cache query result if necessary. */ static int rcm_init(rcmd_t *rcm, apd_t apd_tbl[], int napds, int flags) { longlong_t ii; int rv = 0; rcm->offline_query_info = NULL; rcm->rlist = NULL; rcm->cpus = NULL; if (rcm_alloc_handle(NULL, RCM_NOPID, NULL, &rcm->hdl) != RCM_SUCCESS) { dprintf((stderr, "rcm_alloc_handle (errno=%d)\n", errno)); return (-1); } if ((rcm->ms_pagesize = sysconf(_SC_PAGE_SIZE)) == -1 || (rcm->ms_syspages = sysconf(_SC_PHYS_PAGES)) == -1) { dprintf((stderr, "sysconf: %s\n", strerror(errno))); return (-1); } ii = (longlong_t)rcm->ms_pagesize * rcm->ms_syspages; rcm->ms_sysmb = (int)((ii+MBYTE-1) / MBYTE); if (flags & RI_INCLUDE_QUERY) rv = rcm_query_init(rcm, apd_tbl, napds); return (rv); } static void rcm_fini(rcmd_t *rcm) { char **cpp; assert(rcm != NULL); if (rcm->offline_query_info != NULL) rcm_free_info(rcm->offline_query_info); if (rcm->hdl != NULL) rcm_free_handle(rcm->hdl); if (rcm->rlist != NULL) { for (cpp = rcm->rlist; *cpp != NULL; cpp++) s_free(*cpp); free(rcm->rlist); } s_free(rcm->cpus); free(rcm); } #define NODENAME_CMP "cmp" #define NODENAME_SSM "ssm" #define PROP_CPUID "cpuid" #define PROP_DEVICE_TYPE "device-type" #define PROP_ECACHE_SIZE "ecache-size" #define PROP_L2_CACHE_SIZE "l2-cache-size" #define PROP_L3_CACHE_SIZE "l3-cache-size" typedef struct { di_node_t root; di_prom_handle_t ph; ecache_info_t *ecache_info; } di_arg_t; /* * The ecache sizes for individual cpus are read from the * OBP/Solaris device trees. This info cannot be derived * from the cfgadm_sbd cpu attachment point ecache info, * which may be a sum of multiple cores for CMP. */ static int ecache_info_init(ecache_info_t *ec) { di_arg_t di_arg; di_prom_handle_t ph = DI_PROM_HANDLE_NIL; di_node_t root = DI_NODE_NIL; int cpuid_max, rv = 0; assert(ec != NULL && ec->cpuid_max == 0 && ec->ecache_sizes == NULL); if ((cpuid_max = sysconf(_SC_CPUID_MAX)) == -1) { dprintf((stderr, "sysconf fail: %s\n", strerror(errno))); rv = -1; goto done; } if ((root = di_init("/", DINFOCPYALL)) == DI_NODE_NIL) { dprintf((stderr, "di_init fail: %s\n", strerror(errno))); rv = -1; goto done; } if ((ph = di_prom_init()) == DI_PROM_HANDLE_NIL) { dprintf((stderr, "di_prom_init fail: %s\n", strerror(errno))); rv = -1; goto done; } if ((ec->ecache_sizes = calloc(cpuid_max + 1, sizeof (int))) == NULL) { dprintf((stderr, "calloc fail: %s\n", strerror(errno))); rv = -1; goto done; } ec->cpuid_max = cpuid_max; dprintf((stderr, "cpuid_max is set to %d\n", ec->cpuid_max)); di_arg.ph = ph; di_arg.root = root; di_arg.ecache_info = ec; if (di_walk_node(root, DI_WALK_CLDFIRST, (void *)&di_arg, find_cpu_nodes) != 0) { dprintf((stderr, "di_walk_node fail: %s\n", strerror(errno))); rv = -1; } done: if (root != DI_NODE_NIL) di_fini(root); if (ph != DI_PROM_HANDLE_NIL) di_prom_fini(ph); return (rv); } /* * Libdevinfo node walk callback for reading ecache size * properties for cpu device nodes. Subtrees not containing * cpu nodes are filtered out. */ static int find_cpu_nodes(di_node_t node, void *arg) { char *name; int *cpuid, *ecache; di_arg_t *di_arg = (di_arg_t *)arg; ecache_info_t *ec = di_arg->ecache_info; di_prom_handle_t ph = di_arg->ph; if (node == DI_NODE_NIL) { return (DI_WALK_TERMINATE); } if (node == di_arg->root) { return (DI_WALK_CONTINUE); } if (di_nodeid(node) == DI_PSEUDO_NODEID) { return (DI_WALK_PRUNECHILD); } name = di_node_name(node); if (name != NULL) { /* * CMP nodes will be the parent of cpu nodes. On some platforms, * cpu nodes will be under the ssm node. In either case, * continue searching this subtree. */ if (strncmp(name, NODENAME_SSM, strlen(NODENAME_SSM)) == 0 || strncmp(name, NODENAME_CMP, strlen(NODENAME_CMP)) == 0) { return (DI_WALK_CONTINUE); } } dprintf((stderr, "find_cpu_nodes: node=%p, name=%s, binding_name=%s\n", node, di_node_name(node), di_binding_name(node))); /* * Ecache size property name differs with processor implementation. * Panther has both L2 and L3, so check for L3 first to differentiate * from Jaguar, which has only L2. */ if (prop_lookup_int(node, ph, PROP_CPUID, &cpuid) == 0 && (prop_lookup_int(node, ph, PROP_ECACHE_SIZE, &ecache) == 0 || prop_lookup_int(node, ph, PROP_L3_CACHE_SIZE, &ecache) == 0 || prop_lookup_int(node, ph, PROP_L2_CACHE_SIZE, &ecache) == 0)) { assert(ec != NULL && ec->ecache_sizes != NULL && *cpuid <= ec->cpuid_max); ec->ecache_sizes[*cpuid] = *ecache; } return (DI_WALK_PRUNECHILD); } /* * Given a di_node_t, call the appropriate int property lookup routine. * Note: This lookup fails if the int property has multiple value entries. */ static int prop_lookup_int(di_node_t node, di_prom_handle_t ph, char *propname, int **ival) { int rv; rv = (di_nodeid(node) == DI_PROM_NODEID) ? di_prom_prop_lookup_ints(ph, node, propname, ival) : di_prop_lookup_ints(DDI_DEV_T_ANY, node, propname, ival); return (rv == 1 ? 0 : -1); } /* * For offline queries, RCM must be given a list of all resources * so modules can have access to the full scope of the operation. * The rcm_get_info calls are made individually in order to map the * returned rcm_info_t's to physical devices. The rcm_request_offline * result is cached so the query state can be looked up as we process * the rcm_get_info calls. This routine also tallies up the amount of * memory going away and creates a list of cpu ids to be used * later for rcm_request_capacity_change. */ static int rcm_query_init(rcmd_t *rcm, apd_t apd_tbl[], int napds) { apd_t *apd; int i, j; cfga_list_data_t *cfga_ldata; int (*cm_rcm_qpass)(cfga_list_data_t *, rcmd_t *); #ifdef DEBUG char **cpp; #endif /* DEBUG */ /* * Initial pass to size cpu and resource name arrays needed to * interface with RCM. Attachment point ids for CMP can represent * multiple cpus (and resource names). Instead of parsing the * cfgadm info field here, use the worse case that all component * attachment points are CMP. */ rcm->ndevs = 0; for (i = 0, apd = apd_tbl; i < napds; i++, apd++) { for (j = 1, cfga_ldata = &apd->cfga_list_data[1]; j < apd->nlist; j++, cfga_ldata++) { if (cfga_ldata->ap_o_state != CFGA_STAT_CONFIGURED) { continue; } rcm->ndevs += SBD_MAX_CORES_PER_CMP; } } /* account for trailing NULL in rlist */ if (rcm->ndevs > 0 && ((rcm->cpus = calloc(rcm->ndevs, sizeof (cpuid_t))) == NULL || (rcm->rlist = calloc(rcm->ndevs + 1, sizeof (char *))) == NULL)) { dprintf((stderr, "calloc: %s\n", strerror(errno))); return (-1); } /* * Second pass to fill in the RCM resource and cpu lists. */ for (i = 0, apd = apd_tbl; i < napds; i++, apd++) { for (j = 1, cfga_ldata = &apd->cfga_list_data[1]; j < apd->nlist; j++, cfga_ldata++) { if (cfga_ldata->ap_o_state != CFGA_STAT_CONFIGURED) { continue; } if ((cm_rcm_qpass = cm_rcm_qpass_func(cfga_ldata->ap_type)) != NULL && (*cm_rcm_qpass)(cfga_ldata, rcm) != 0) { return (-1); } } } if (rcm->nrlist == 0) return (0); /* * Cache query result. Since we are only interested in the * set of RCM clients processed and not their request status, * the return value is irrelevant. */ (void) rcm_request_offline_list(rcm->hdl, rcm->rlist, RCM_QUERY|RCM_SCOPE, &rcm->offline_query_info); #ifdef DEBUG dprintf((stderr, "RCM rlist: nrlist=%d\n", rcm->nrlist)); for (cpp = rcm->rlist, i = 0; *cpp != NULL; cpp++, i++) { dprintf((stderr, "rlist[%d]=%s\n", i, *cpp)); } #endif /* DEBUG */ return (0); } static int cap_request(ri_hdl_t *ri_hdl, rcmd_t *rcm) { return (((rcm->ncpus > 0 && cpu_cap_request(ri_hdl, rcm) != 0) || (rcm->query_pages > 0 && mem_cap_request(ri_hdl, rcm) != 0)) ? -1 : 0); } /* * RCM capacity change request for cpus. */ static int cpu_cap_request(ri_hdl_t *ri_hdl, rcmd_t *rcm) { cpuid_t *syscpuids, *newcpuids; int sysncpus, newncpus; rcm_info_t *rcm_info = NULL; int i, j, k; nvlist_t *nvl; int rv = 0; /* get all cpus in the system */ if (syscpus(&syscpuids, &sysncpus) == -1) return (-1); newncpus = sysncpus - rcm->ncpus; if ((newcpuids = calloc(newncpus, sizeof (cpuid_t))) == NULL) { dprintf((stderr, "calloc: %s", strerror(errno))); rv = -1; goto out; } if (nvlist_alloc(&nvl, NV_UNIQUE_NAME, 0) != 0) { dprintf((stderr, "nvlist_alloc fail\n")); rv = -1; goto out; } /* * Construct the new cpu list. */ for (i = 0, j = 0; i < sysncpus; i++) { for (k = 0; k < rcm->ncpus; k++) { if (rcm->cpus[k] == syscpuids[i]) { break; } } if (k == rcm->ncpus) { newcpuids[j++] = syscpuids[i]; } } if (nvlist_add_int32(nvl, "old_total", sysncpus) != 0 || nvlist_add_int32(nvl, "new_total", newncpus) != 0 || nvlist_add_int32_array(nvl, "old_cpu_list", syscpuids, sysncpus) != 0 || nvlist_add_int32_array(nvl, "new_cpu_list", newcpuids, newncpus) != 0) { dprintf((stderr, "nvlist_add fail\n")); rv = -1; goto out; } #ifdef DEBUG dprintf((stderr, "old_total=%d\n", sysncpus)); for (i = 0; i < sysncpus; i++) { dprintf((stderr, "old_cpu_list[%d]=%d\n", i, syscpuids[i])); } dprintf((stderr, "new_total=%d\n", newncpus)); for (i = 0; i < newncpus; i++) { dprintf((stderr, "new_cpu_list[%d]=%d\n", i, newcpuids[i])); } #endif /* DEBUG */ (void) rcm_request_capacity_change(rcm->hdl, RCM_CPU_ALL, RCM_QUERY|RCM_SCOPE, nvl, &rcm_info); rv = add_rcm_clients(&ri_hdl->cpu_cap_clients, rcm, rcm_info, 0, NULL); out: s_free(syscpuids); s_free(newcpuids); if (nvl != NULL) nvlist_free(nvl); if (rcm_info != NULL) rcm_free_info(rcm_info); return (rv); } static int syscpus(cpuid_t **cpuids, int *ncpus) { kstat_t *ksp; kstat_ctl_t *kc; cpuid_t *cp; int i; if ((*ncpus = sysconf(_SC_NPROCESSORS_CONF)) == -1) { dprintf((stderr, "sysconf: %s\n", errno)); return (-1); } if ((kc = kstat_open()) == NULL) { dprintf((stderr, "kstat_open fail\n")); return (-1); } if ((cp = calloc(*ncpus, sizeof (cpuid_t))) == NULL) { dprintf((stderr, "calloc: %s\n", errno)); (void) kstat_close(kc); return (-1); } for (i = 0, ksp = kc->kc_chain; ksp != NULL; ksp = ksp->ks_next) { if (strcmp(ksp->ks_module, "cpu_info") == 0) { cp[i++] = ksp->ks_instance; } } (void) kstat_close(kc); *cpuids = cp; return (0); } /* * RCM capacity change request for memory. */ static int mem_cap_request(ri_hdl_t *ri_hdl, rcmd_t *rcm) { nvlist_t *nvl; rcm_info_t *rcm_info = NULL; long newpages; int rv = 0; if (nvlist_alloc(&nvl, NV_UNIQUE_NAME, 0) != 0) { dprintf((stderr, "nvlist_alloc fail\n")); return (-1); } newpages = rcm->ms_syspages - rcm->query_pages; if (nvlist_add_int32(nvl, "page_size", rcm->ms_pagesize) != 0 || nvlist_add_int32(nvl, "old_pages", rcm->ms_syspages) != 0 || nvlist_add_int32(nvl, "new_pages", newpages) != 0) { dprintf((stderr, "nvlist_add fail\n")); nvlist_free(nvl); return (-1); } dprintf((stderr, "memory capacity change req: " "page_size=%d, old_pages=%d, new_pages=%d\n", rcm->ms_pagesize, rcm->ms_syspages, newpages)); (void) rcm_request_capacity_change(rcm->hdl, RCM_MEM_ALL, RCM_QUERY|RCM_SCOPE, nvl, &rcm_info); rv = add_rcm_clients(&ri_hdl->mem_cap_clients, rcm, rcm_info, 0, NULL); nvlist_free(nvl); if (rcm_info != NULL) rcm_free_info(rcm_info); return (rv); } static int (*cm_rcm_qpass_func(cfga_type_t ap_type))(cfga_list_data_t *, rcmd_t *) { int i; for (i = 0; i < sizeof (cm_ctl) / sizeof (cm_ctl[0]); i++) { if (strcmp(cm_ctl[i].type, ap_type) == 0) { return (cm_ctl[i].cm_rcm_qpass); } } return (NULL); } /* * Save cpu ids and RCM abstract resource names. * Cpu ids will be used for the capacity change request. * Resource names will be used for the offline query. */ static int cpu_rcm_qpass(cfga_list_data_t *cfga_ldata, rcmd_t *rcm) { processorid_t cpuid; char *cpustr, *lasts, *rsrcname, rbuf[32]; char cbuf[CFGA_INFO_LEN]; int speed, ecache; assert(sscanf(cfga_ldata->ap_info, CPU_INFO_FMT, &cbuf, &speed, &ecache) == 3); for (cpustr = (char *)strtok_r(cbuf, CPUID_SEP, &lasts); cpustr != NULL; cpustr = (char *)strtok_r(NULL, CPUID_SEP, &lasts)) { cpuid = atoi(cpustr); (void) snprintf(rbuf, sizeof (rbuf), "%s%d", RCM_CPU, cpuid); if ((rsrcname = strdup(rbuf)) == NULL) { dprintf((stderr, "strdup fail\n")); return (-1); } assert(rcm->nrlist < rcm->ndevs && rcm->ncpus < rcm->ndevs); rcm->rlist[rcm->nrlist++] = rsrcname; rcm->cpus[rcm->ncpus++] = (cpuid_t)cpuid; dprintf((stderr, "cpu_cm_info: cpuid=%d, rsrcname=%s", cpuid, rsrcname)); } return (0); } /* * No RCM resource names for individual memory units, so * just add to offline query page count. */ static int mem_rcm_qpass(cfga_list_data_t *cfga, rcmd_t *rcm) { char *cp; uint_t kbytes; longlong_t ii; if ((cp = strstr(cfga->ap_info, "size")) == NULL || sscanf(cp, "size=%u", &kbytes) != 1) { dprintf((stderr, "unknown sbd info format: %s\n", cp)); return (-1); } ii = (longlong_t)kbytes * KBYTE; rcm->query_pages += (uint_t)(ii / rcm->ms_pagesize); dprintf((stderr, "%s: npages=%u\n", cfga->ap_log_id, (uint_t)(ii / rcm->ms_pagesize))); return (0); } /* * Add physical I/O bus name to RCM resource list. */ static int io_rcm_qpass(cfga_list_data_t *cfga, rcmd_t *rcm) { char path[MAXPATHLEN]; char buf[MAXPATHLEN]; char *rsrcname; if (sscanf(cfga->ap_info, "device=%s", path) != 1) { dprintf((stderr, "unknown sbd info format: %s\n", cfga->ap_info)); return (-1); } (void) snprintf(buf, sizeof (buf), "/devices%s", path); if ((rsrcname = strdup(buf)) == NULL) { dprintf((stderr, "strdup fail\n")); return (-1); } assert(rcm->nrlist < rcm->ndevs); rcm->rlist[rcm->nrlist++] = rsrcname; return (0); } static int (*cm_info_func(cfga_type_t ap_type))(ri_ap_t *, cfga_list_data_t *, int, rcmd_t *) { int i; for (i = 0; i < sizeof (cm_ctl) / sizeof (cm_ctl[0]); i++) { if (strcmp(cm_ctl[i].type, ap_type) == 0) { return (cm_ctl[i].cm_info); } } return (NULL); } /* * Create cpu handle, adding properties exported by sbd plugin and * RCM client usage. */ /* ARGSUSED */ static int cpu_cm_info(ri_ap_t *ap, cfga_list_data_t *cfga, int flags, rcmd_t *rcm) { processorid_t cpuid; int speed, ecache, rv = 0; char buf[CFGA_INFO_LEN], *cpustr, *lasts; if (sscanf(cfga->ap_info, CPU_INFO_FMT, &buf, &speed, &ecache) != 3) { dprintf((stderr, "unknown sbd info format: %s\n", cfga->ap_info)); return (-1); } /* parse cpuids */ for (cpustr = (char *)strtok_r(buf, CPUID_SEP, &lasts); cpustr != NULL; cpustr = (char *)strtok_r(NULL, CPUID_SEP, &lasts)) { cpuid = atoi(cpustr); if ((rv = i_cpu_cm_info(cpuid, speed, ap, rcm)) != 0) { break; } } return (rv); } static int i_cpu_cm_info(processorid_t cpuid, int speed, ri_ap_t *ap, rcmd_t *rcm) { int ecache = 0; char *state, buf[32]; processor_info_t cpu_info; ri_dev_t *cpu = NULL; rcm_info_t *rcm_info = NULL; /* * Could have been unconfigured in the interim, so cannot * count on processor_info recognizing it. */ state = (processor_info(cpuid, &cpu_info) == 0) ? pstate2str(cpu_info.pi_state) : "unknown"; if ((cpu = ri_dev_alloc()) == NULL) { dprintf((stderr, "ri_dev_alloc failed\n")); return (-1); } if (rcm->ecache_info.ecache_sizes != NULL) { assert(rcm->ecache_info.cpuid_max != 0 && cpuid <= rcm->ecache_info.cpuid_max); ecache = rcm->ecache_info.ecache_sizes[cpuid] / MBYTE; } dprintf((stderr, "i_cpu_cm_info: cpu(%d) ecache=%d MB\n", cpuid, ecache)); if (nvlist_add_int32(cpu->conf_props, RI_CPU_ID, cpuid) != 0 || nvlist_add_int32(cpu->conf_props, RI_CPU_SPEED, speed) != 0 || nvlist_add_int32(cpu->conf_props, RI_CPU_ECACHE, ecache) != 0 || nvlist_add_string(cpu->conf_props, RI_CPU_STATE, state) != 0) { dprintf((stderr, "nvlist_add fail\n")); ri_dev_free(cpu); return (-1); } (void) snprintf(buf, sizeof (buf), "%s%d", RCM_CPU, cpuid); dprintf((stderr, "rcm_get_info(%s)\n", buf)); if (rcm_get_info(rcm->hdl, buf, RCM_INCLUDE_DEPENDENT, &rcm_info) != RCM_SUCCESS) { dprintf((stderr, "rcm_get_info (errno=%d)\n", errno)); ri_dev_free(cpu); if (rcm_info != NULL) rcm_free_info(rcm_info); return (-1); } dev_list_cpu_insert(&ap->cpus, cpu, cpuid); return (0); } /* * Create memory handle, adding properties exported by sbd plugin. * No RCM tuples to be saved unless RCM is modified to export names * for individual memory units. */ /* ARGSUSED */ static int mem_cm_info(ri_ap_t *ap, cfga_list_data_t *cfga, int flags, rcmd_t *rcm) { ri_dev_t *mem; char *cp; uint64_t base_addr; /* required */ int32_t size_kb; /* required */ int32_t perm_kb = 0; /* optional */ char *target = NULL; /* optional */ int32_t del_kb = 0; /* optional */ int32_t rem_kb = 0; /* optional */ char *source = NULL; /* optional */ if (sscanf(cfga->ap_info, "address=0x%llx size=%u", &base_addr, &size_kb) != 2) { goto err_fmt; } if ((cp = strstr(cfga->ap_info, "permanent")) != NULL && sscanf(cp, "permanent=%u", &perm_kb) != 1) { goto err_fmt; } if ((cp = strstr(cfga->ap_info, "target")) != NULL && sscanf(cp, "target=%s deleted=%u remaining=%u", &target, &del_kb, &rem_kb) != 3) { goto err_fmt; } if ((cp = strstr(cfga->ap_info, "source")) != NULL && sscanf(cp, "source=%s", &source) != 1) { goto err_fmt; } dprintf((stderr, "%s: base=0x%llx, size=%u, permanent=%u\n", cfga->ap_log_id, base_addr, size_kb, perm_kb)); if ((mem = ri_dev_alloc()) == NULL) return (-1); /* * Convert memory sizes to MB (truncate). */ if (nvlist_add_uint64(mem->conf_props, RI_MEM_ADDR, base_addr) != 0 || nvlist_add_int32(mem->conf_props, RI_MEM_BRD, size_kb/KBYTE) != 0 || nvlist_add_int32(mem->conf_props, RI_MEM_PERM, perm_kb/KBYTE) != 0) { dprintf((stderr, "nvlist_add failure\n")); ri_dev_free(mem); return (-1); } if (target != NULL && (nvlist_add_string(mem->conf_props, RI_MEM_TARG, target) != 0 || nvlist_add_int32(mem->conf_props, RI_MEM_DEL, del_kb/KBYTE) != 0 || nvlist_add_int32(mem->conf_props, RI_MEM_REMAIN, rem_kb/KBYTE) != 0)) { dprintf((stderr, "nvlist_add failure\n")); ri_dev_free(mem); return (-1); } if (source != NULL && nvlist_add_string(mem->conf_props, RI_MEM_SRC, source) != 0) { dprintf((stderr, "nvlist_add failure\n")); ri_dev_free(mem); return (-1); } /* * XXX - move this property to attachment point hdl? */ if (nvlist_add_int32(mem->conf_props, RI_MEM_DOMAIN, rcm->ms_sysmb) != 0) { dprintf((stderr, "nvlist_add failure\n")); ri_dev_free(mem); return (-1); } dev_list_append(&ap->mems, mem); return (0); err_fmt: dprintf((stderr, "unknown sbd info format: %s\n", cfga->ap_info)); return (-1); } /* * Initiate a libdevinfo walk on the IO bus path. * XXX - investigate performance using two threads here: one thread to do the * libdevinfo snapshot and treewalk; and one thread to get RCM usage info */ static int io_cm_info(ri_ap_t *ap, cfga_list_data_t *cfga, int flags, rcmd_t *rcm) { int i; int j; int k; int set_size; int retval = 0; int n_usage; devinfo_arg_t di_arg; lookup_table_t devicetable; lookup_entry_t *deventry; lookup_entry_t *lastdeventry; ri_dev_t *io = NULL; ri_client_t *client; ri_client_t *tmp; di_devlink_handle_t linkhd = NULL; di_node_t root = DI_NODE_NIL; di_node_t node = DI_NODE_NIL; rcm_info_tuple_t *rcm_tuple; rcm_info_t *rcm_info = NULL; const char *rcm_rsrc = NULL; char drv_inst[MAXPATHLEN]; char path[MAXPATHLEN]; char pathbuf[MAXPATHLEN]; dprintf((stderr, "io_cm_info(%s)\n", cfga->ap_log_id)); /* Extract devfs path from cfgadm information */ if (sscanf(cfga->ap_info, "device=%s\n", path) != 1) { dprintf((stderr, "unknown sbd info format: %s\n", cfga->ap_info)); return (-1); } /* Initialize empty device lookup table */ devicetable.n_entries = 0; devicetable.n_slots = 0; devicetable.table = NULL; /* Get libdevinfo snapshot */ dprintf((stderr, "di_init(%s)\n", path)); if ((root = di_init(path, DINFOCPYALL)) == DI_NODE_NIL) { dprintf((stderr, "di_init: %s\n", strerror(errno))); retval = RI_NODE_NIL; /* tell ri_init to skip this node */ goto end; } /* * Map in devlinks database. * XXX - This could be moved to ri_init() for better performance. */ dprintf((stderr, "di_devlink_init()\n")); if ((linkhd = di_devlink_init(NULL, 0)) == NULL) { dprintf((stderr, "di_devlink_init: %s\n", strerror(errno))); retval = -1; goto end; } /* Initialize argument for devinfo treewalk */ di_arg.err = 0; di_arg.node = DI_NODE_NIL; di_arg.pathbuf = pathbuf; di_arg.table = &devicetable; di_arg.linkhd = linkhd; /* Use libdevinfo treewalk to build device lookup table */ if (di_walk_node(root, DI_WALK_CLDFIRST, (void *)&di_arg, devinfo_node_walk) != 0) { dprintf((stderr, "di_walk_node: %s\n", strerror(errno))); retval = -1; goto end; } if (di_arg.err != 0) { dprintf((stderr, "di_walk_node: device tree walk failed\n")); retval = -1; goto end; } /* Call RCM to gather usage information */ (void) snprintf(pathbuf, MAXPATHLEN, "/devices%s", path); dprintf((stderr, "rcm_get_info(%s)\n", pathbuf)); if (rcm_get_info(rcm->hdl, pathbuf, RCM_INCLUDE_SUBTREE|RCM_INCLUDE_DEPENDENT, &rcm_info) != RCM_SUCCESS) { dprintf((stderr, "rcm_get_info (errno=%d)\n", errno)); retval = -1; goto end; } /* Sort the device table by name (proper order for lookups) */ qsort(devicetable.table, devicetable.n_entries, sizeof (lookup_entry_t), table_compare_names); /* Perform mappings of RCM usage segments to device table entries */ lastdeventry = NULL; rcm_tuple = NULL; while ((rcm_tuple = rcm_info_next(rcm_info, rcm_tuple)) != NULL) { if ((rcm_rsrc = rcm_info_rsrc(rcm_tuple)) == NULL) continue; if (deventry = lookup(&devicetable, rcm_rsrc)) { if (add_usage(deventry, rcm_rsrc, rcm_tuple)) { retval = -1; goto end; } lastdeventry = deventry; } else { if (add_usage(lastdeventry, rcm_rsrc, rcm_tuple)) { retval = -1; goto end; } } } /* Re-sort the device table by index number (original treewalk order) */ qsort(devicetable.table, devicetable.n_entries, sizeof (lookup_entry_t), table_compare_indices); /* * Use the mapped usage and the device table to construct ri_dev_t's. * Construct one for each set of entries in the device table with * matching di_node_t's, if: 1) it has mapped RCM usage, or 2) it is * a leaf node and the caller has requested that unmanaged nodes be * included in the output. */ i = 0; while (i < devicetable.n_entries) { node = devicetable.table[i].node; /* Count how many usage records are mapped to this node's set */ n_usage = 0; set_size = 0; while (((i + set_size) < devicetable.n_entries) && (devicetable.table[i + set_size].node == node)) { n_usage += devicetable.table[i + set_size].n_usage; set_size += 1; } /* * If there's no usage, then the node is unmanaged. Skip this * set of devicetable entries unless the node is a leaf node * and the caller has requested information on unmanaged leaves. */ if ((n_usage == 0) && !((flags & RI_INCLUDE_UNMANAGED) && (ident_leaf(node)))) { i += set_size; continue; } /* * The checks above determined that this node is going in. * So determine its driver/instance name and allocate an * ri_dev_t for this node. */ if (mk_drv_inst(node, drv_inst, devicetable.table[i].name)) { dprintf((stderr, "mk_drv_inst failed\n")); retval = -1; break; } if ((io = io_dev_alloc(drv_inst)) == NULL) { dprintf((stderr, "io_dev_alloc failed\n")); retval = -1; break; } /* Now add all the RCM usage records (if any) to the ri_dev_t */ for (j = i; j < (i + set_size); j++) { for (k = 0; k < devicetable.table[j].n_usage; k++) { /* Create new ri_client_t for basic usage */ client = ri_client_alloc( (char *)devicetable.table[j].usage[k].rsrc, (char *)devicetable.table[j].usage[k].info); if (client == NULL) { dprintf((stderr, "ri_client_alloc failed\n")); ri_dev_free(io); retval = -1; goto end; } /* Add extra query usage to the ri_client_t */ if ((flags & RI_INCLUDE_QUERY) && (add_query_state(rcm, client, devicetable.table[j].usage[k].rsrc, devicetable.table[j].usage[k].info) != 0)) { dprintf((stderr, "add_query_state failed\n")); ri_dev_free(io); ri_client_free(client); retval = -1; goto end; } /* Link new ri_client_t to ri_dev_t */ if (io->rcm_clients) { tmp = io->rcm_clients; while (tmp->next) tmp = tmp->next; tmp->next = client; } else { io->rcm_clients = client; } } } /* Link the ri_dev_t into the return value */ dev_list_append(&ap->ios, io); /* Advance to the next node set */ i += set_size; } end: if (rcm_info != NULL) rcm_free_info(rcm_info); if (linkhd != NULL) di_devlink_fini(&linkhd); if (root != DI_NODE_NIL) di_fini(root); empty_table(&devicetable); dprintf((stderr, "io_cm_info: returning %d\n", retval)); return (retval); } static int ident_leaf(di_node_t node) { di_minor_t minor = DI_MINOR_NIL; return ((minor = di_minor_next(node, minor)) != DI_MINOR_NIL && di_child_node(node) == DI_NODE_NIL); } /* ARGSUSED */ static int mk_drv_inst(di_node_t node, char drv_inst[], char *devfs_path) { char *drv; int inst; if ((drv = di_driver_name(node)) == NULL) { dprintf((stderr, "no driver bound to %s\n", devfs_path)); return (-1); } if ((inst = di_instance(node)) == -1) { dprintf((stderr, "no instance assigned to %s\n", devfs_path)); return (-1); } (void) snprintf(drv_inst, MAXPATHLEN, "%s%d", drv, inst); return (0); } /* * Libdevinfo walker. * * During the tree walk of the attached IO devices, for each node * and all of its associated minors, the following actions are performed: * - The /devices path of the physical device node or minor * is stored in a lookup table along with a reference to the * libdevinfo node it represents via add_lookup_entry(). * - The device links associated with each device are also * stored in the same lookup table along with a reference to * the libdevinfo node it represents via the minor walk callback. * */ static int devinfo_node_walk(di_node_t node, void *arg) { char *devfs_path; #ifdef DEBUG char *drv; #endif /* DEBUG */ devinfo_arg_t *di_arg = (devinfo_arg_t *)arg; if (node == DI_NODE_NIL) { return (DI_WALK_TERMINATE); } if (((di_state(node) & DI_DRIVER_DETACHED) == 0) && ((devfs_path = di_devfs_path(node)) != NULL)) { /* Use the provided path buffer to create full /devices path */ (void) snprintf(di_arg->pathbuf, MAXPATHLEN, "/devices%s", devfs_path); #ifdef DEBUG dprintf((stderr, "devinfo_node_walk(%s)\n", di_arg->pathbuf)); if ((drv = di_driver_name(node)) != NULL) dprintf((stderr, " driver name %s instance %d\n", drv, di_instance(node))); #endif /* Free the devfs_path */ di_devfs_path_free(devfs_path); /* Add an entry to the lookup table for this physical device */ if (add_lookup_entry(di_arg->table, di_arg->pathbuf, node)) { dprintf((stderr, "add_lookup_entry: %s\n", strerror(errno))); di_arg->err = 1; return (DI_WALK_TERMINATE); } /* Check if this node has minors */ if ((di_minor_next(node, DI_MINOR_NIL)) != DI_MINOR_NIL) { /* Walk this node's minors */ di_arg->node = node; if (di_walk_minor(node, NULL, DI_CHECK_ALIAS, arg, devinfo_minor_walk) != 0) { dprintf((stderr, "di_walk_minor: %s\n", strerror(errno))); di_arg->err = 1; return (DI_WALK_TERMINATE); } } } return (DI_WALK_CONTINUE); } /* * Use di_devlink_walk to find the /dev link from /devices path for this minor */ static int devinfo_minor_walk(di_node_t node, di_minor_t minor, void *arg) { char *name; char *devfs_path; devinfo_arg_t *di_arg = (devinfo_arg_t *)arg; char pathbuf[MAXPATHLEN]; #ifdef DEBUG dprintf((stderr, "devinfo_minor_walk(%d) %s\n", minor, di_arg->pathbuf)); if ((name = di_minor_name(minor)) != NULL) { dprintf((stderr, " minor name %s\n", name)); } #endif /* DEBUG */ /* Terminate the walk when the device node changes */ if (node != di_arg->node) { return (DI_WALK_TERMINATE); } /* Construct full /devices path for this minor */ if ((name = di_minor_name(minor)) == NULL) { return (DI_WALK_CONTINUE); } (void) snprintf(pathbuf, MAXPATHLEN, "%s:%s", di_arg->pathbuf, name); /* Add lookup entry for this minor node */ if (add_lookup_entry(di_arg->table, pathbuf, node)) { dprintf((stderr, "add_lookup_entry: %s\n", strerror(errno))); di_arg->err = 1; return (DI_WALK_TERMINATE); } /* * Walk the associated device links. * Note that di_devlink_walk() doesn't want "/devices" in its paths. * Also note that di_devlink_walk() will fail if there are no device * links, which is fine; so ignore if it fails. Only check for * internal failures during such a walk. */ devfs_path = &pathbuf[strlen("/devices")]; (void) di_devlink_walk(di_arg->linkhd, NULL, devfs_path, 0, arg, devinfo_devlink_walk); if (di_arg->err != 0) { return (DI_WALK_TERMINATE); } return (DI_WALK_CONTINUE); } static int devinfo_devlink_walk(di_devlink_t devlink, void *arg) { const char *linkpath; devinfo_arg_t *di_arg = (devinfo_arg_t *)arg; /* Get the devlink's path */ if ((linkpath = di_devlink_path(devlink)) == NULL) { dprintf((stderr, "di_devlink_path: %s\n", strerror(errno))); di_arg->err = 1; return (DI_WALK_TERMINATE); } dprintf((stderr, "devinfo_devlink_walk: %s\n", linkpath)); /* Add lookup entry for this devlink */ if (add_lookup_entry(di_arg->table, linkpath, di_arg->node)) { dprintf((stderr, "add_lookup_entry: %s\n", strerror(errno))); di_arg->err = 1; return (DI_WALK_TERMINATE); } return (DI_WALK_CONTINUE); } /* * Map rcm_info_t's to ri_client_t's, filtering out "uninteresting" (hack) * RCM clients. The number of "interesting" ri_client_t's is returned * in cnt if passed non-NULL. */ static int add_rcm_clients(ri_client_t **client_list, rcmd_t *rcm, rcm_info_t *info, int flags, int *cnt) { rcm_info_tuple_t *tuple; char *rsrc, *usage; ri_client_t *client, *tmp; assert(client_list != NULL && rcm != NULL); if (info == NULL) return (0); if (cnt != NULL) *cnt = 0; tuple = NULL; while ((tuple = rcm_info_next(info, tuple)) != NULL) { if ((rsrc = (char *)rcm_info_rsrc(tuple)) == NULL || (usage = (char *)rcm_info_info(tuple)) == NULL) { continue; } if (rcm_ignore(rsrc, usage) == 0) continue; if ((client = ri_client_alloc(rsrc, usage)) == NULL) return (-1); if ((flags & RI_INCLUDE_QUERY) && add_query_state(rcm, client, rsrc, usage) != 0) { ri_client_free(client); return (-1); } if (cnt != NULL) ++*cnt; /* * Link in */ if ((tmp = *client_list) == NULL) { *client_list = client; continue; } while (tmp->next != NULL) { tmp = tmp->next; } tmp->next = client; } return (0); } /* * Currently only filtering out based on known info string prefixes. */ /* ARGSUSED */ static int rcm_ignore(char *rsrc, char *infostr) { char **cpp; for (cpp = rcm_info_filter; *cpp != NULL; cpp++) { if (strncmp(infostr, *cpp, strlen(*cpp)) == 0) { return (0); } } return (-1); } /* * If this tuple was cached in the offline query pass, add the * query state and error string to the ri_client_t. */ static int add_query_state(rcmd_t *rcm, ri_client_t *client, const char *rsrc, const char *info) { int qstate = RI_QUERY_UNKNOWN; char *errstr = NULL; rcm_info_tuple_t *cached_tuple; if ((cached_tuple = tuple_lookup(rcm, rsrc, info)) != NULL) { qstate = state2query(rcm_info_state(cached_tuple)); errstr = (char *)rcm_info_error(cached_tuple); } if (nvlist_add_int32(client->usg_props, RI_QUERY_STATE, qstate) != 0 || (errstr != NULL && nvlist_add_string(client->usg_props, RI_QUERY_ERR, errstr) != 0)) { dprintf((stderr, "nvlist_add fail\n")); return (-1); } return (0); } static int state2query(int rcm_state) { int query; switch (rcm_state) { case RCM_STATE_OFFLINE_QUERY: case RCM_STATE_SUSPEND_QUERY: query = RI_QUERY_OK; break; case RCM_STATE_OFFLINE_QUERY_FAIL: case RCM_STATE_SUSPEND_QUERY_FAIL: query = RI_QUERY_FAIL; break; default: query = RI_QUERY_UNKNOWN; break; } return (query); } static void dev_list_append(ri_dev_t **head, ri_dev_t *dev) { ri_dev_t *tmp; if ((tmp = *head) == NULL) { *head = dev; return; } while (tmp->next != NULL) { tmp = tmp->next; } tmp->next = dev; } /* * The cpu list is ordered on cpuid since CMP cpuids will not necessarily * be discovered in sequence. */ static void dev_list_cpu_insert(ri_dev_t **listp, ri_dev_t *dev, processorid_t newid) { ri_dev_t *tmp; int32_t cpuid; while ((tmp = *listp) != NULL && nvlist_lookup_int32(tmp->conf_props, RI_CPU_ID, &cpuid) == 0 && cpuid < newid) { listp = &tmp->next; } dev->next = tmp; *listp = dev; } /* * Linear lookup. Should convert to hash tab. */ static rcm_info_tuple_t * tuple_lookup(rcmd_t *rcm, const char *krsrc, const char *kinfo) { rcm_info_tuple_t *tuple = NULL; const char *rsrc, *info; if ((rcm == NULL) || (krsrc == NULL) || (kinfo == NULL)) { return (NULL); } while ((tuple = rcm_info_next(rcm->offline_query_info, tuple)) != NULL) { if ((rsrc = rcm_info_rsrc(tuple)) == NULL || (info = rcm_info_info(tuple)) == NULL) { continue; } if (strcmp(rsrc, krsrc) == 0 && strcmp(info, kinfo) == 0) { return (tuple); } } return (NULL); } /* * Create and link attachment point handle. */ static ri_ap_t * ri_ap_alloc(char *ap_id, ri_hdl_t *hdl) { ri_ap_t *ap, *tmp; if ((ap = calloc(1, sizeof (*ap))) == NULL) { dprintf((stderr, "calloc: %s\n", strerror(errno))); return (NULL); } if (nvlist_alloc(&ap->conf_props, NV_UNIQUE_NAME, 0) != 0 || nvlist_add_string(ap->conf_props, RI_AP_REQ_ID, ap_id) != 0) { if (ap->conf_props != NULL) nvlist_free(ap->conf_props); free(ap); return (NULL); } if ((tmp = hdl->aps) == NULL) { hdl->aps = ap; } else { while (tmp->next != NULL) { tmp = tmp->next; } tmp->next = ap; } return (ap); } static ri_dev_t * ri_dev_alloc(void) { ri_dev_t *dev; if ((dev = calloc(1, sizeof (*dev))) == NULL || nvlist_alloc(&dev->conf_props, NV_UNIQUE_NAME, 0) != 0) { s_free(dev); } return (dev); } static ri_dev_t * io_dev_alloc(char *drv_inst) { ri_dev_t *io; assert(drv_inst != NULL); if ((io = ri_dev_alloc()) == NULL) return (NULL); if (nvlist_add_string(io->conf_props, RI_IO_DRV_INST, drv_inst) != 0) { dprintf((stderr, "nvlist_add_string fail\n")); ri_dev_free(io); return (NULL); } return (io); } static ri_client_t * ri_client_alloc(char *rsrc, char *usage) { ri_client_t *client; assert(rsrc != NULL && usage != NULL); if ((client = calloc(1, sizeof (*client))) == NULL) { dprintf((stderr, "calloc: %s\n", strerror(errno))); return (NULL); } if (nvlist_alloc(&client->usg_props, NV_UNIQUE_NAME, 0) != 0) { dprintf((stderr, "nvlist_alloc fail\n")); free(client); return (NULL); } if (nvlist_add_string(client->usg_props, RI_CLIENT_RSRC, rsrc) != 0 || nvlist_add_string(client->usg_props, RI_CLIENT_USAGE, usage) != 0) { dprintf((stderr, "nvlist_add_string fail\n")); ri_client_free(client); return (NULL); } return (client); } static void apd_tbl_free(apd_t apd_tbl[], int napds) { int i; apd_t *apd; for (i = 0, apd = apd_tbl; i < napds; i++, apd++) s_free(apd->cfga_list_data); free(apd_tbl); } static char * pstate2str(int pi_state) { char *state; switch (pi_state) { case P_OFFLINE: state = PS_OFFLINE; break; case P_ONLINE: state = PS_ONLINE; break; case P_FAULTED: state = PS_FAULTED; break; case P_POWEROFF: state = PS_POWEROFF; break; case P_NOINTR: state = PS_NOINTR; break; case P_SPARE: state = PS_SPARE; break; default: state = "unknown"; break; } return (state); } #ifdef DEBUG static void dump_apd_tbl(FILE *fp, apd_t *apds, int n_apds) { int i, j; cfga_list_data_t *cfga_ldata; for (i = 0; i < n_apds; i++, apds++) { dprintf((stderr, "apd_tbl[%d].nlist=%d\n", i, apds->nlist)); for (j = 0, cfga_ldata = apds->cfga_list_data; j < apds->nlist; j++, cfga_ldata++) { dprintf((fp, "apd_tbl[%d].cfga_list_data[%d].ap_log_id=%s\n", i, j, cfga_ldata->ap_log_id)); } } } #endif /* DEBUG */ /* * The lookup table is a simple array that is grown in chunks * to optimize memory allocation. * Indices are assigned to each array entry in-order so that * the original device tree ordering can be discerned at a later time. * * add_lookup_entry is called from the libdevinfo tree traversal callbacks: * 1) devinfo_node_walk - physical device path for each node in * the devinfo tree via di_walk_node(), lookup entry name is * /devices/[di_devfs_path] * 2) devinfo_minor_walk - physical device path plus minor name for * each minor associated with a node via di_walk_minor(), lookup entry * name is /devices/[di_devfs_path:di_minor_name] * 3) devinfo_devlink_walk - for each minor's /dev link from its /devices * path via di_devlink_walk(), lookup entry name is di_devlink_path() */ static int add_lookup_entry(lookup_table_t *table, const char *name, di_node_t node) { size_t size; lookup_entry_t *new_table; /* Grow the lookup table by USAGE_ALLOC_SIZE slots if necessary */ if (table->n_entries == table->n_slots) { size = (table->n_slots + USAGE_ALLOC_SIZE) * sizeof (lookup_entry_t); new_table = (lookup_entry_t *)realloc(table->table, size); if (new_table == NULL) { dprintf((stderr, "add_lookup_entry: alloc failed: %s\n", strerror(errno))); errno = ENOMEM; return (-1); } table->table = new_table; table->n_slots += USAGE_ALLOC_SIZE; } dprintf((stderr, "add_lookup_entry[%d]:%s\n", table->n_entries, name)); /* Add this name to the next slot */ if ((table->table[table->n_entries].name = strdup(name)) == NULL) { dprintf((stderr, "add_lookup_entry: strdup failed: %s\n", strerror(errno))); errno = ENOMEM; return (-1); } table->table[table->n_entries].index = table->n_entries; table->table[table->n_entries].node = node; table->table[table->n_entries].n_usage = 0; table->table[table->n_entries].usage = NULL; table->n_entries += 1; return (0); } /* * lookup table entry names are full pathname strings, all start with / */ static int table_compare_names(const void *a, const void *b) { lookup_entry_t *entry1 = (lookup_entry_t *)a; lookup_entry_t *entry2 = (lookup_entry_t *)b; return (strcmp(entry1->name, entry2->name)); } /* * Compare two indices and return -1 for less, 1 for greater, 0 for equal */ static int table_compare_indices(const void *a, const void *b) { lookup_entry_t *entry1 = (lookup_entry_t *)a; lookup_entry_t *entry2 = (lookup_entry_t *)b; if (entry1->index < entry2->index) return (-1); if (entry1->index > entry2->index) return (1); return (0); } /* * Given a RCM resource name, find the matching entry in the IO device table */ static lookup_entry_t * lookup(lookup_table_t *table, const char *rcm_rsrc) { lookup_entry_t *entry; lookup_entry_t lookup_arg; dprintf((stderr, "lookup:%s\n", rcm_rsrc)); lookup_arg.name = (char *)rcm_rsrc; entry = bsearch(&lookup_arg, table->table, table->n_entries, sizeof (lookup_entry_t), table_compare_names); #ifdef DEBUG if (entry != NULL) { dprintf((stderr, " found entry:%d\n", entry->index)); } #endif /* DEBUG */ return (entry); } /* * Add RCM usage to the given device table entry. * Returns -1 on realloc failure. */ static int add_usage(lookup_entry_t *entry, const char *rcm_rsrc, rcm_info_tuple_t *tuple) { size_t size; const char *info; usage_t *new_usage; if ((entry == NULL) || ((info = rcm_info_info(tuple)) == NULL)) return (0); if (rcm_ignore((char *)rcm_rsrc, (char *)info) == 0) return (0); size = (entry->n_usage + 1) * sizeof (usage_t); new_usage = (usage_t *)realloc(entry->usage, size); if (new_usage == NULL) { dprintf((stderr, "add_usage: alloc failed: %s\n", strerror(errno))); return (-1); } dprintf((stderr, "add_usage: entry %d rsrc: %s info: %s\n", entry->index, rcm_rsrc, info)); entry->usage = new_usage; entry->usage[entry->n_usage].rsrc = rcm_rsrc; entry->usage[entry->n_usage].info = info; entry->n_usage += 1; return (0); } static void empty_table(lookup_table_t *table) { int i; if (table) { for (i = 0; i < table->n_entries; i++) { if (table->table[i].name) free(table->table[i].name); /* * Note: the strings pointed to from within * usage were freed already by rcm_free_info */ if (table->table[i].usage) free(table->table[i].usage); } if (table->table) free(table->table); table->table = NULL; table->n_entries = 0; table->n_slots = 0; } }