/* * 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 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include "ses_impl.h" #define NEXT_ED(eip) \ ((ses2_ed_impl_t *)((uint8_t *)(eip) + \ ((eip)->st_hdr.sehi_ed_len + sizeof (ses2_ed_hdr_impl_t)))) static ses_node_t * ses_find_enclosure(ses_snap_t *sp, uint64_t number) { ses_node_t *np; for (np = sp->ss_root->sn_first_child; np != NULL; np = np->sn_next_sibling) { ASSERT(np->sn_type == SES_NODE_ENCLOSURE); if (np->sn_enc_num == number) return ((ses_node_t *)np); } return (NULL); } void ses_node_teardown(ses_node_t *np) { ses_node_t *rp; if (np == NULL) return; for (; np != NULL; np = rp) { ses_node_teardown(np->sn_first_child); rp = np->sn_next_sibling; nvlist_free(np->sn_props); ses_free(np); } } static ses_node_t * ses_node_alloc(ses_snap_t *sp, ses_node_t *pnp) { ses_node_t *np; np = ses_zalloc(sizeof (ses_node_t)); if (np == NULL) goto fail; if (nvlist_alloc(&np->sn_props, NV_UNIQUE_NAME, 0) != 0) goto fail; np->sn_snapshot = sp; np->sn_id = sp->ss_n_nodes++; if (pnp == NULL) { ASSERT(sp->ss_root == NULL); sp->ss_root = np; } else { np->sn_parent = pnp; np->sn_prev_sibling = pnp->sn_last_child; if (pnp->sn_first_child == NULL) pnp->sn_first_child = np; else pnp->sn_last_child->sn_next_sibling = np; pnp->sn_last_child = np; } return (np); fail: ses_free(np); ses_node_teardown(sp->ss_root); sp->ss_root = NULL; return (NULL); } /* * Parse element type descriptor. */ static int elem_parse_td(ses2_td_hdr_impl_t *tip, const char *tp, nvlist_t *nvl) { int nverr; if (tp != NULL) SES_NV_ADD(fixed_string, nverr, nvl, SES_PROP_CLASS_DESCRIPTION, tp, tip->sthi_text_len); return (0); } /* * Build a skeleton tree of nodes in the given snapshot. This is the heart of * libses, and is responsible for parsing the config page into a tree and * populating nodes with data from the config page. */ static int ses_build_snap_skel(ses_snap_t *sp) { ses2_ed_impl_t *eip; ses2_td_hdr_impl_t *tip, *ftip; ses_node_t *np, *pnp, *cnp, *root; ses_snap_page_t *pp; ses2_config_page_impl_t *pip; int i, j, n_etds = 0; off_t toff; char *tp, *text; int err; uint64_t idx; pp = ses_snap_find_page(sp, SES2_DIAGPAGE_CONFIG, B_FALSE); if (pp == NULL) return (ses_error(ESES_BAD_RESPONSE, "target does not support " "configuration diagnostic page")); pip = (ses2_config_page_impl_t *)pp->ssp_page; if (pp->ssp_len < offsetof(ses2_config_page_impl_t, scpi_data)) return (ses_error(ESES_BAD_RESPONSE, "no enclosure " "descriptors found")); /* * Start with the root of the tree, which is a target node, containing * just the SCSI inquiry properties. */ if ((root = ses_node_alloc(sp, sp->ss_root)) == NULL) return (-1); root->sn_type = SES_NODE_TARGET; SES_NV_ADD(string, err, root->sn_props, SCSI_PROP_VENDOR, libscsi_vendor(sp->ss_target->st_target)); SES_NV_ADD(string, err, root->sn_props, SCSI_PROP_PRODUCT, libscsi_product(sp->ss_target->st_target)); SES_NV_ADD(string, err, root->sn_props, SCSI_PROP_REVISION, libscsi_revision(sp->ss_target->st_target)); for (eip = (ses2_ed_impl_t *)pip->scpi_data, i = 0; i < pip->scpi_n_subenclosures + 1; i++, eip = NEXT_ED(eip)) { if (!SES_WITHIN_PAGE_STRUCT(eip, pp->ssp_page, pp->ssp_len)) break; n_etds += eip->st_hdr.sehi_n_etd_hdrs; } ftip = (ses2_td_hdr_impl_t *)eip; /* * There should really be only one Enclosure element possible for a * give subenclosure ID. The standard never comes out and says this, * but it does describe this element as "managing the enclosure itself" * which implies rather strongly that the subenclosure ID field is that * of, well, the enclosure itself. Since an enclosure can't contain * itself, it follows logically that each subenclosure has at most one * Enclosure type descriptor elements matching its ID. Of course, some * enclosure firmware is buggy, so this may not always work out; in * this case we just ignore all but the first Enclosure-type element * with our subenclosure ID. */ for (eip = (ses2_ed_impl_t *)pip->scpi_data, i = 0; i < pip->scpi_n_subenclosures + 1; i++, eip = NEXT_ED(eip)) { if (!SES_WITHIN_PAGE_STRUCT(eip, pp->ssp_page, pp->ssp_len)) break; if ((np = ses_node_alloc(sp, root)) == NULL) return (-1); np->sn_type = SES_NODE_ENCLOSURE; np->sn_enc_num = eip->st_hdr.sehi_subenclosure_id; if (!SES_WITHIN_PAGE(eip, eip->st_hdr.sehi_ed_len + sizeof (ses2_ed_hdr_impl_t), pp->ssp_page, pp->ssp_len)) break; if (enc_parse_ed(eip, np->sn_props) != 0) return (-1); } if (root->sn_first_child == NULL) return (ses_error(ESES_BAD_RESPONSE, "no enclosure " "descriptors found")); tp = (char *)(ftip + n_etds); for (i = 0, toff = 0, idx = 0; i < n_etds; i++) { tip = ftip + i; if (!SES_WITHIN_PAGE_STRUCT(tip, pp->ssp_page, pp->ssp_len)) break; pnp = ses_find_enclosure(sp, tip->sthi_subenclosure_id); if (pnp == NULL) { idx += tip->sthi_max_elements + 1; toff += tip->sthi_text_len; continue; } if (tip->sthi_element_type == SES_ET_ENCLOSURE) { if (tip->sthi_max_elements == 0) { SES_NV_ADD(uint64, err, pnp->sn_props, SES_PROP_ELEMENT_INDEX, idx); pnp->sn_rootidx = idx; } else { SES_NV_ADD(uint64, err, pnp->sn_props, SES_PROP_ELEMENT_INDEX, idx + 1); pnp->sn_rootidx = idx + 1; } if (tip->sthi_text_len > 0 && SES_WITHIN_PAGE(tp + toff, tip->sthi_text_len, pp->ssp_page, pp->ssp_len)) { text = tp + toff; toff += tip->sthi_text_len; } else { text = NULL; } SES_NV_ADD(uint64, err, pnp->sn_props, SES_PROP_ELEMENT_TYPE, SES_ET_ENCLOSURE); if (enc_parse_td(tip, text, pnp->sn_props) != 0) return (-1); idx += tip->sthi_max_elements + 1; continue; } if ((np = ses_node_alloc(sp, pnp)) == NULL) return (-1); np->sn_type = SES_NODE_AGGREGATE; np->sn_enc_num = tip->sthi_subenclosure_id; np->sn_parent = pnp; np->sn_rootidx = idx; SES_NV_ADD(uint64, err, np->sn_props, SES_PROP_ELEMENT_INDEX, idx); SES_NV_ADD(uint64, err, np->sn_props, SES_PROP_ELEMENT_TYPE, tip->sthi_element_type); if (tip->sthi_text_len > 0 && SES_WITHIN_PAGE(tp + toff, tip->sthi_text_len, pp->ssp_page, pp->ssp_len)) { text = tp + toff; toff += tip->sthi_text_len; } else { text = NULL; } if (elem_parse_td(tip, text, np->sn_props) != 0) return (-1); idx += tip->sthi_max_elements + 1; if (tip->sthi_max_elements == 0) continue; for (j = 0; j < tip->sthi_max_elements; j++) { cnp = ses_node_alloc(sp, np); if (cnp == NULL) return (-1); cnp->sn_type = SES_NODE_ELEMENT; SES_NV_ADD(uint64, err, cnp->sn_props, SES_PROP_ELEMENT_INDEX, np->sn_rootidx + j + 1); SES_NV_ADD(uint64, err, cnp->sn_props, SES_PROP_ELEMENT_CLASS_INDEX, j); SES_NV_ADD(uint64, err, cnp->sn_props, SES_PROP_ELEMENT_TYPE, tip->sthi_element_type); } } np->sn_snapshot->ss_n_elem = idx; return (0); } static int ses_fill_tree(ses_node_t *np) { if (np == NULL) return (0); for (; np != NULL; np = np->sn_next_sibling) { if (ses_fill_node(np) != 0) return (-1); if (ses_fill_tree(np->sn_first_child) != 0) return (-1); } return (0); } int ses_fill_snap(ses_snap_t *sp) { if (ses_build_snap_skel(sp) != 0) return (-1); if (ses_fill_tree(sp->ss_root) != 0) return (-1); return (0); } ses_node_t * ses_root_node(ses_snap_t *sp) { return (sp->ss_root); } ses_node_t * ses_node_sibling(ses_node_t *np) { return (np->sn_next_sibling); } ses_node_t * ses_node_prev_sibling(ses_node_t *np) { return (np->sn_prev_sibling); } ses_node_t * ses_node_parent(ses_node_t *np) { return (np->sn_parent); } ses_node_t * ses_node_child(ses_node_t *np) { return (np->sn_first_child); } ses_node_type_t ses_node_type(ses_node_t *np) { return (np->sn_type); } ses_snap_t * ses_node_snapshot(ses_node_t *np) { return ((ses_snap_t *)np->sn_snapshot); } ses_target_t * ses_node_target(ses_node_t *np) { return (np->sn_snapshot->ss_target); } nvlist_t * ses_node_props(ses_node_t *np) { return (np->sn_props); } /* * A node identifier is a (generation, index) tuple that can be used to lookup a * node within this target at a later point. This will be valid across * snapshots, though it will return failure if the generation count has changed. */ uint64_t ses_node_id(ses_node_t *np) { return (((uint64_t)np->sn_snapshot->ss_generation << 32) | np->sn_id); }