// SPDX-License-Identifier: GPL-2.0-or-later /* * This is an implementation of RFC4970 Router Information * with support of RFC5088 PCE Capabilites announcement * * Module name: Router Information * Author: Olivier Dugeon * Copyright (C) 2012 - 2017 Orange Labs http://www.orange.com/ */ #include #include #include "linklist.h" #include "prefix.h" #include "if.h" #include "table.h" #include "memory.h" #include "command.h" #include "vty.h" #include "stream.h" #include "log.h" #include "frrevent.h" #include "hash.h" #include "sockunion.h" /* for inet_aton() */ #include "mpls.h" #include #include "ospfd/ospfd.h" #include "ospfd/ospf_interface.h" #include "ospfd/ospf_ism.h" #include "ospfd/ospf_asbr.h" #include "ospfd/ospf_lsa.h" #include "ospfd/ospf_lsdb.h" #include "ospfd/ospf_neighbor.h" #include "ospfd/ospf_nsm.h" #include "ospfd/ospf_flood.h" #include "ospfd/ospf_packet.h" #include "ospfd/ospf_spf.h" #include "ospfd/ospf_dump.h" #include "ospfd/ospf_route.h" #include "ospfd/ospf_ase.h" #include "ospfd/ospf_zebra.h" #include "ospfd/ospf_sr.h" #include "ospfd/ospf_ri.h" #include "ospfd/ospf_errors.h" /* * Global variable to manage Opaque-LSA/Router Information on this node. * Note that all parameter values are stored in network byte order. */ static struct ospf_router_info OspfRI; /*------------------------------------------------------------------------------* * Following are initialize/terminate functions for Router Information *handling. *------------------------------------------------------------------------------*/ static void ospf_router_info_ism_change(struct ospf_interface *oi, int old_status); static void ospf_router_info_config_write_router(struct vty *vty); static void ospf_router_info_show_info(struct vty *vty, struct json_object *json, struct ospf_lsa *lsa); static int ospf_router_info_lsa_originate(void *arg); static struct ospf_lsa *ospf_router_info_lsa_refresh(struct ospf_lsa *lsa); static void ospf_router_info_lsa_schedule(struct ospf_ri_area_info *ai, enum lsa_opcode opcode); static void ospf_router_info_register_vty(void); static int ospf_router_info_lsa_update(struct ospf_lsa *lsa); static void del_area_info(void *val); static void del_pce_info(void *val); int ospf_router_info_init(void) { zlog_info("RI (%s): Initialize Router Information", __func__); memset(&OspfRI, 0, sizeof(OspfRI)); OspfRI.enabled = false; OspfRI.registered = 0; OspfRI.scope = OSPF_OPAQUE_AS_LSA; OspfRI.as_flags = RIFLG_LSA_INACTIVE; OspfRI.area_info = list_new(); OspfRI.area_info->del = del_area_info; /* Initialize pce domain and neighbor list */ OspfRI.pce_info.enabled = false; OspfRI.pce_info.pce_domain = list_new(); OspfRI.pce_info.pce_domain->del = del_pce_info; OspfRI.pce_info.pce_neighbor = list_new(); OspfRI.pce_info.pce_neighbor->del = del_pce_info; /* Initialize Segment Routing information structure */ OspfRI.sr_info.enabled = false; ospf_router_info_register_vty(); return 0; } static int ospf_router_info_register(uint8_t scope) { int rc = 0; if (OspfRI.registered) return rc; zlog_info("RI (%s): Register Router Information with scope %s(%d)", __func__, scope == OSPF_OPAQUE_AREA_LSA ? "Area" : "AS", scope); rc = ospf_register_opaque_functab( scope, OPAQUE_TYPE_ROUTER_INFORMATION_LSA, NULL, /* new interface */ NULL, /* del interface */ ospf_router_info_ism_change, NULL, /* NSM change */ ospf_router_info_config_write_router, NULL, /* Config. write interface */ NULL, /* Config. write debug */ ospf_router_info_show_info, ospf_router_info_lsa_originate, ospf_router_info_lsa_refresh, ospf_router_info_lsa_update, NULL); /* del_lsa_hook */ if (rc != 0) { flog_warn( EC_OSPF_OPAQUE_REGISTRATION, "RI (%s): Failed to register functions", __func__); return rc; } OspfRI.registered = 1; OspfRI.scope = scope; return rc; } static int ospf_router_info_unregister(void) { if ((OspfRI.scope != OSPF_OPAQUE_AS_LSA) && (OspfRI.scope != OSPF_OPAQUE_AREA_LSA)) { assert("Unable to unregister Router Info functions: Wrong scope!" == NULL); return -1; } ospf_delete_opaque_functab(OspfRI.scope, OPAQUE_TYPE_ROUTER_INFORMATION_LSA); OspfRI.registered = 0; return 0; } void ospf_router_info_term(void) { list_delete(&OspfRI.area_info); list_delete(&OspfRI.pce_info.pce_domain); list_delete(&OspfRI.pce_info.pce_neighbor); OspfRI.enabled = false; ospf_router_info_unregister(); return; } void ospf_router_info_finish(void) { struct listnode *node, *nnode; struct ospf_ri_area_info *ai; /* Flush Router Info LSA */ for (ALL_LIST_ELEMENTS(OspfRI.area_info, node, nnode, ai)) if (CHECK_FLAG(ai->flags, RIFLG_LSA_ENGAGED)) ospf_router_info_lsa_schedule(ai, FLUSH_THIS_LSA); list_delete_all_node(OspfRI.pce_info.pce_domain); list_delete_all_node(OspfRI.pce_info.pce_neighbor); OspfRI.enabled = false; } static void del_area_info(void *val) { XFREE(MTYPE_OSPF_ROUTER_INFO, val); } static void del_pce_info(void *val) { XFREE(MTYPE_OSPF_PCE_PARAMS, val); } /* Catch RI LSA flooding Scope for ospf_ext.[h,c] code */ struct scope_info ospf_router_info_get_flooding_scope(void) { struct scope_info flooding_scope; if (OspfRI.scope == OSPF_OPAQUE_AS_LSA) { flooding_scope.scope = OSPF_OPAQUE_AS_LSA; flooding_scope.areas = NULL; return flooding_scope; } flooding_scope.scope = OSPF_OPAQUE_AREA_LSA; flooding_scope.areas = OspfRI.area_info; return flooding_scope; } static struct ospf_ri_area_info *lookup_by_area(struct ospf_area *area) { struct listnode *node, *nnode; struct ospf_ri_area_info *ai; for (ALL_LIST_ELEMENTS(OspfRI.area_info, node, nnode, ai)) if (ai->area == area) return ai; return NULL; } /*------------------------------------------------------------------------* * Following are control functions for ROUTER INFORMATION parameters *management. *------------------------------------------------------------------------*/ static void set_router_info_capabilities(struct ri_tlv_router_cap *ric, uint32_t cap) { ric->header.type = htons(RI_TLV_CAPABILITIES); ric->header.length = htons(RI_TLV_LENGTH); ric->value = htonl(cap); return; } static int set_pce_header(struct ospf_pce_info *pce) { uint16_t length = 0; struct listnode *node; struct ri_pce_subtlv_domain *domain; struct ri_pce_subtlv_neighbor *neighbor; /* PCE Address */ if (ntohs(pce->pce_address.header.type) != 0) length += TLV_SIZE(&pce->pce_address.header); /* PCE Path Scope */ if (ntohs(pce->pce_scope.header.type) != 0) length += TLV_SIZE(&pce->pce_scope.header); /* PCE Domain */ for (ALL_LIST_ELEMENTS_RO(pce->pce_domain, node, domain)) { if (ntohs(domain->header.type) != 0) length += TLV_SIZE(&domain->header); } /* PCE Neighbor */ for (ALL_LIST_ELEMENTS_RO(pce->pce_neighbor, node, neighbor)) { if (ntohs(neighbor->header.type) != 0) length += TLV_SIZE(&neighbor->header); } /* PCE Capabilities */ if (ntohs(pce->pce_cap_flag.header.type) != 0) length += TLV_SIZE(&pce->pce_cap_flag.header); if (length != 0) { pce->pce_header.header.type = htons(RI_TLV_PCE); pce->pce_header.header.length = htons(length); pce->enabled = true; } else { pce->pce_header.header.type = 0; pce->pce_header.header.length = 0; pce->enabled = false; } return length; } static void set_pce_address(struct in_addr ipv4, struct ospf_pce_info *pce) { /* Enable PCE Info */ pce->pce_header.header.type = htons(RI_TLV_PCE); /* Set PCE Address */ pce->pce_address.header.type = htons(RI_PCE_SUBTLV_ADDRESS); pce->pce_address.header.length = htons(PCE_ADDRESS_IPV4_SIZE); pce->pce_address.address.type = htons(PCE_ADDRESS_IPV4); pce->pce_address.address.value = ipv4; return; } static void set_pce_path_scope(uint32_t scope, struct ospf_pce_info *pce) { /* Set PCE Scope */ pce->pce_scope.header.type = htons(RI_PCE_SUBTLV_PATH_SCOPE); pce->pce_scope.header.length = htons(RI_TLV_LENGTH); pce->pce_scope.value = htonl(scope); return; } static void set_pce_domain(uint16_t type, uint32_t domain, struct ospf_pce_info *pce) { struct ri_pce_subtlv_domain *new; /* Create new domain info */ new = XCALLOC(MTYPE_OSPF_PCE_PARAMS, sizeof(struct ri_pce_subtlv_domain)); new->header.type = htons(RI_PCE_SUBTLV_DOMAIN); new->header.length = htons(PCE_ADDRESS_IPV4_SIZE); new->type = htons(type); new->value = htonl(domain); /* Add new domain to the list */ listnode_add(pce->pce_domain, new); return; } static void unset_pce_domain(uint16_t type, uint32_t domain, struct ospf_pce_info *pce) { struct listnode *node; struct ri_pce_subtlv_domain *old = NULL; int found = 0; /* Search the corresponding node */ for (ALL_LIST_ELEMENTS_RO(pce->pce_domain, node, old)) { if ((old->type == htons(type)) && (old->value == htonl(domain))) { found = 1; break; } } /* if found remove it */ if (found) { listnode_delete(pce->pce_domain, old); /* Finally free the old domain */ XFREE(MTYPE_OSPF_PCE_PARAMS, old); } } static void set_pce_neighbor(uint16_t type, uint32_t domain, struct ospf_pce_info *pce) { struct ri_pce_subtlv_neighbor *new; /* Create new neighbor info */ new = XCALLOC(MTYPE_OSPF_PCE_PARAMS, sizeof(struct ri_pce_subtlv_neighbor)); new->header.type = htons(RI_PCE_SUBTLV_NEIGHBOR); new->header.length = htons(PCE_ADDRESS_IPV4_SIZE); new->type = htons(type); new->value = htonl(domain); /* Add new domain to the list */ listnode_add(pce->pce_neighbor, new); return; } static void unset_pce_neighbor(uint16_t type, uint32_t domain, struct ospf_pce_info *pce) { struct listnode *node; struct ri_pce_subtlv_neighbor *old = NULL; int found = 0; /* Search the corresponding node */ for (ALL_LIST_ELEMENTS_RO(pce->pce_neighbor, node, old)) { if ((old->type == htons(type)) && (old->value == htonl(domain))) { found = 1; break; } } /* if found remove it */ if (found) { listnode_delete(pce->pce_neighbor, old); /* Finally free the old domain */ XFREE(MTYPE_OSPF_PCE_PARAMS, old); } } static void set_pce_cap_flag(uint32_t cap, struct ospf_pce_info *pce) { /* Set PCE Capabilities flag */ pce->pce_cap_flag.header.type = htons(RI_PCE_SUBTLV_CAP_FLAG); pce->pce_cap_flag.header.length = htons(RI_TLV_LENGTH); pce->pce_cap_flag.value = htonl(cap); return; } /* Segment Routing TLV setter */ /* Algorithm SubTLV - section 3.1 */ static void set_sr_algorithm(uint8_t algo) { OspfRI.sr_info.algo.value[0] = algo; for (int i = 1; i < ALGORITHM_COUNT; i++) OspfRI.sr_info.algo.value[i] = SR_ALGORITHM_UNSET; /* Set TLV type and length == only 1 Algorithm */ TLV_TYPE(OspfRI.sr_info.algo) = htons(RI_SR_TLV_SR_ALGORITHM); TLV_LEN(OspfRI.sr_info.algo) = htons(sizeof(uint8_t)); } /* unset Aglogithm SubTLV */ static void unset_sr_algorithm(uint8_t algo) { for (int i = 0; i < ALGORITHM_COUNT; i++) OspfRI.sr_info.algo.value[i] = SR_ALGORITHM_UNSET; /* Unset TLV type and length */ TLV_TYPE(OspfRI.sr_info.algo) = htons(0); TLV_LEN(OspfRI.sr_info.algo) = htons(0); } /* Set Segment Routing Global Block SubTLV - section 3.2 */ static void set_sr_global_label_range(struct sr_block srgb) { /* Set Header */ TLV_TYPE(OspfRI.sr_info.srgb) = htons(RI_SR_TLV_SRGB_LABEL_RANGE); TLV_LEN(OspfRI.sr_info.srgb) = htons(RI_SR_TLV_LABEL_RANGE_SIZE); /* Set Range Size */ OspfRI.sr_info.srgb.size = htonl(SET_RANGE_SIZE(srgb.range_size)); /* Set Lower bound label SubTLV */ TLV_TYPE(OspfRI.sr_info.srgb.lower) = htons(SUBTLV_SID_LABEL); TLV_LEN(OspfRI.sr_info.srgb.lower) = htons(SID_RANGE_LABEL_LENGTH); OspfRI.sr_info.srgb.lower.value = htonl(SET_LABEL(srgb.lower_bound)); } /* Unset Segment Routing Global Block SubTLV */ static void unset_sr_global_label_range(void) { TLV_TYPE(OspfRI.sr_info.srgb) = htons(0); TLV_LEN(OspfRI.sr_info.srgb) = htons(0); TLV_TYPE(OspfRI.sr_info.srgb.lower) = htons(0); TLV_LEN(OspfRI.sr_info.srgb.lower) = htons(0); } /* Set Segment Routing Local Block SubTLV - section 3.2 */ static void set_sr_local_label_range(struct sr_block srlb) { /* Set Header */ TLV_TYPE(OspfRI.sr_info.srlb) = htons(RI_SR_TLV_SRLB_LABEL_RANGE); TLV_LEN(OspfRI.sr_info.srlb) = htons(RI_SR_TLV_LABEL_RANGE_SIZE); /* Set Range Size */ OspfRI.sr_info.srlb.size = htonl(SET_RANGE_SIZE(srlb.range_size)); /* Set Lower bound label SubTLV */ TLV_TYPE(OspfRI.sr_info.srlb.lower) = htons(SUBTLV_SID_LABEL); TLV_LEN(OspfRI.sr_info.srlb.lower) = htons(SID_RANGE_LABEL_LENGTH); OspfRI.sr_info.srlb.lower.value = htonl(SET_LABEL(srlb.lower_bound)); } /* Unset Segment Routing Local Block SubTLV */ static void unset_sr_local_label_range(void) { TLV_TYPE(OspfRI.sr_info.srlb) = htons(0); TLV_LEN(OspfRI.sr_info.srlb) = htons(0); TLV_TYPE(OspfRI.sr_info.srlb.lower) = htons(0); TLV_LEN(OspfRI.sr_info.srlb.lower) = htons(0); } /* Set Maximum Stack Depth for this router */ static void set_sr_node_msd(uint8_t msd) { TLV_TYPE(OspfRI.sr_info.msd) = htons(RI_SR_TLV_NODE_MSD); TLV_LEN(OspfRI.sr_info.msd) = htons(sizeof(uint32_t)); OspfRI.sr_info.msd.value = msd; } /* Unset this router MSD */ static void unset_sr_node_msd(void) { TLV_TYPE(OspfRI.sr_info.msd) = htons(0); TLV_LEN(OspfRI.sr_info.msd) = htons(0); } static void unset_param(void *tlv_buffer) { struct tlv_header *tlv = (struct tlv_header *)tlv_buffer; tlv->type = 0; /* Fill the Value to 0 */ memset(TLV_DATA(tlv_buffer), 0, TLV_BODY_SIZE(tlv)); tlv->length = 0; return; } static void initialize_params(struct ospf_router_info *ori) { uint32_t cap = 0; struct ospf *top; struct listnode *node, *nnode; struct ospf_area *area; struct ospf_ri_area_info *new; /* * Initialize default Router Information Capabilities. */ cap = RI_TE_SUPPORT; set_router_info_capabilities(&ori->router_cap, cap); /* If Area address is not null and exist, retrieve corresponding * structure */ top = ospf_lookup_by_vrf_id(VRF_DEFAULT); zlog_info("RI (%s): Initialize Router Info for %s scope", __func__, OspfRI.scope == OSPF_OPAQUE_AREA_LSA ? "Area" : "AS"); /* Try to get available Area's context from ospf at this step. * Do it latter if not available */ if (OspfRI.scope == OSPF_OPAQUE_AREA_LSA) { if (!list_isempty(OspfRI.area_info)) list_delete_all_node(OspfRI.area_info); for (ALL_LIST_ELEMENTS(top->areas, node, nnode, area)) { zlog_debug("RI (%s): Add area %pI4 to Router Information", __func__, &area->area_id); new = XCALLOC(MTYPE_OSPF_ROUTER_INFO, sizeof(struct ospf_ri_area_info)); new->area = area; new->flags = RIFLG_LSA_INACTIVE; listnode_add(OspfRI.area_info, new); } } /* * Initialize default PCE Information values */ /* PCE address == OSPF Router ID */ set_pce_address(top->router_id, &ori->pce_info); /* PCE scope */ cap = 7; /* Set L, R and Rd bits to one = intra & inter-area path computation */ set_pce_path_scope(cap, &ori->pce_info); /* PCE Capabilities */ cap = PCE_CAP_BIDIRECTIONAL | PCE_CAP_DIVERSE_PATH | PCE_CAP_OBJECTIVES | PCE_CAP_ADDITIVE | PCE_CAP_MULTIPLE_REQ; set_pce_cap_flag(cap, &ori->pce_info); return; } static int is_mandated_params_set(struct ospf_router_info *ori) { int rc = 0; if (ori == NULL) return rc; if (ntohs(ori->router_cap.header.type) == 0) return rc; if ((ntohs(ori->pce_info.pce_header.header.type) == RI_TLV_PCE) && (ntohs(ori->pce_info.pce_address.header.type) == 0) && (ntohs(ori->pce_info.pce_cap_flag.header.type) == 0)) return rc; if ((ori->sr_info.enabled) && (ntohs(TLV_TYPE(ori->sr_info.algo)) == 0) && (ntohs(TLV_TYPE(ori->sr_info.srgb)) == 0)) return rc; rc = 1; return rc; } /* * Used by Segment Routing to set new TLVs and Sub-TLVs values * * @param enable To activate or not Segment Routing router Information flooding * @param srn Self Segment Routing node * * @return none */ void ospf_router_info_update_sr(bool enable, struct sr_node *srn) { struct listnode *node, *nnode; struct ospf_ri_area_info *ai; /* First, check if Router Information is registered or not */ if (!OspfRI.registered) ospf_router_info_register(OSPF_OPAQUE_AREA_LSA); /* Verify that scope is AREA */ if (OspfRI.scope != OSPF_OPAQUE_AREA_LSA) { zlog_err( "RI (%s): Router Info is %s flooding: Change scope to Area flooding for Segment Routing", __func__, OspfRI.scope == OSPF_OPAQUE_AREA_LSA ? "Area" : "AS"); return; } /* Then, activate and initialize Router Information if necessary */ if (!OspfRI.enabled) { OspfRI.enabled = true; initialize_params(&OspfRI); } /* Check that SR node is valid */ if (srn == NULL) return; if (IS_DEBUG_OSPF_SR) zlog_debug("RI (%s): %s Routing Information for Segment Routing", __func__, enable ? "Enable" : "Disable"); /* Unset or Set SR parameters */ if (!enable) { unset_sr_algorithm(SR_ALGORITHM_SPF); unset_sr_global_label_range(); unset_sr_local_label_range(); unset_sr_node_msd(); OspfRI.sr_info.enabled = false; } else { // Only SR_ALGORITHM_SPF is supported set_sr_algorithm(SR_ALGORITHM_SPF); set_sr_global_label_range(srn->srgb); set_sr_local_label_range(srn->srlb); if (srn->msd != 0) set_sr_node_msd(srn->msd); else unset_sr_node_msd(); OspfRI.sr_info.enabled = true; } /* Refresh if already engaged or originate RI LSA */ for (ALL_LIST_ELEMENTS(OspfRI.area_info, node, nnode, ai)) { if (CHECK_FLAG(ai->flags, RIFLG_LSA_ENGAGED)) ospf_router_info_lsa_schedule(ai, REFRESH_THIS_LSA); else ospf_router_info_lsa_schedule(ai, REORIGINATE_THIS_LSA); } } /*------------------------------------------------------------------------* * Following are callback functions against generic Opaque-LSAs handling. *------------------------------------------------------------------------*/ static void ospf_router_info_ism_change(struct ospf_interface *oi, int old_state) { struct ospf_ri_area_info *ai; /* Collect area information */ ai = lookup_by_area(oi->area); /* Check if area is not yet registered */ if (ai != NULL) return; /* Add this new area to the list */ ai = XCALLOC(MTYPE_OSPF_ROUTER_INFO, sizeof(struct ospf_ri_area_info)); ai->area = oi->area; ai->flags = RIFLG_LSA_INACTIVE; listnode_add(OspfRI.area_info, ai); return; } /*------------------------------------------------------------------------* * Following are OSPF protocol processing functions for ROUTER INFORMATION *------------------------------------------------------------------------*/ static void build_tlv_header(struct stream *s, struct tlv_header *tlvh) { stream_put(s, tlvh, sizeof(struct tlv_header)); return; } static void build_tlv(struct stream *s, struct tlv_header *tlvh) { if (ntohs(tlvh->type) != 0) { build_tlv_header(s, tlvh); stream_put(s, TLV_DATA(tlvh), TLV_BODY_SIZE(tlvh)); } return; } static void ospf_router_info_lsa_body_set(struct stream *s) { struct listnode *node; struct ri_pce_subtlv_domain *domain; struct ri_pce_subtlv_neighbor *neighbor; /* Build Router Information TLV */ build_tlv(s, &OspfRI.router_cap.header); /* Build Segment Routing TLVs if enabled */ if (OspfRI.sr_info.enabled) { /* Build Algorithm TLV */ build_tlv(s, &TLV_HDR(OspfRI.sr_info.algo)); /* Build SRGB TLV */ build_tlv(s, &TLV_HDR(OspfRI.sr_info.srgb)); /* Build SRLB TLV */ build_tlv(s, &TLV_HDR(OspfRI.sr_info.srlb)); /* Build MSD TLV */ build_tlv(s, &TLV_HDR(OspfRI.sr_info.msd)); } /* Add RI PCE TLV if it is set */ if (OspfRI.pce_info.enabled) { /* Compute PCE Info header first */ set_pce_header(&OspfRI.pce_info); /* Build PCE TLV */ build_tlv_header(s, &OspfRI.pce_info.pce_header.header); /* Build PCE address sub-tlv */ build_tlv(s, &OspfRI.pce_info.pce_address.header); /* Build PCE path scope sub-tlv */ build_tlv(s, &OspfRI.pce_info.pce_scope.header); /* Build PCE domain sub-tlv */ for (ALL_LIST_ELEMENTS_RO(OspfRI.pce_info.pce_domain, node, domain)) build_tlv(s, &domain->header); /* Build PCE neighbor sub-tlv */ for (ALL_LIST_ELEMENTS_RO(OspfRI.pce_info.pce_neighbor, node, neighbor)) build_tlv(s, &neighbor->header); /* Build PCE cap flag sub-tlv */ build_tlv(s, &OspfRI.pce_info.pce_cap_flag.header); } return; } /* Create new opaque-LSA. */ static struct ospf_lsa *ospf_router_info_lsa_new(struct ospf_area *area) { struct ospf *top; struct stream *s; struct lsa_header *lsah; struct ospf_lsa *new = NULL; uint8_t options, lsa_type; struct in_addr lsa_id; uint32_t tmp; uint16_t length; /* Create a stream for LSA. */ s = stream_new(OSPF_MAX_LSA_SIZE); lsah = (struct lsa_header *)STREAM_DATA(s); options = OSPF_OPTION_E; /* Enable AS external as we flood RI with Opaque Type 11 */ options |= OSPF_OPTION_O; /* Don't forget this :-) */ lsa_type = OspfRI.scope; /* LSA ID == 0 for Router Information see RFC 4970 */ tmp = SET_OPAQUE_LSID(OPAQUE_TYPE_ROUTER_INFORMATION_LSA, 0); lsa_id.s_addr = htonl(tmp); if (IS_DEBUG_OSPF(lsa, LSA_GENERATE)) zlog_debug( "LSA[Type%d:%pI4]: Create an Opaque-LSA/ROUTER INFORMATION instance", lsa_type, &lsa_id); top = ospf_lookup_by_vrf_id(VRF_DEFAULT); /* Set opaque-LSA header fields. */ lsa_header_set(s, options, lsa_type, lsa_id, top->router_id); /* Set opaque-LSA body fields. */ ospf_router_info_lsa_body_set(s); /* Set length. */ length = stream_get_endp(s); lsah->length = htons(length); /* Now, create an OSPF LSA instance. */ new = ospf_lsa_new_and_data(length); /* Routing Information is only supported for default VRF */ new->vrf_id = VRF_DEFAULT; new->area = area; SET_FLAG(new->flags, OSPF_LSA_SELF); memcpy(new->data, lsah, length); stream_free(s); return new; } static int ospf_router_info_lsa_originate_as(void *arg) { struct ospf_lsa *new; struct ospf *top; int rc = -1; /* Sanity Check */ if (OspfRI.scope == OSPF_OPAQUE_AREA_LSA) { flog_warn( EC_OSPF_LSA_INSTALL_FAILURE, "RI (%s): wrong flooding scope AREA instead of AS ?", __func__); return rc; } /* Create new Opaque-LSA/ROUTER INFORMATION instance. */ new = ospf_router_info_lsa_new(NULL); top = (struct ospf *)arg; /* Check ospf info */ if (top == NULL) { zlog_debug("RI (%s): ospf instance not found for vrf id %u", __func__, VRF_DEFAULT); ospf_lsa_unlock(&new); return rc; } /* Install this LSA into LSDB. */ if (ospf_lsa_install(top, NULL /*oi */, new) == NULL) { flog_warn( EC_OSPF_LSA_INSTALL_FAILURE, "RI (%s): ospf_lsa_install() ?", __func__); ospf_lsa_unlock(&new); return rc; } /* Update new LSA origination count. */ top->lsa_originate_count++; /* Flood new LSA through AREA or AS. */ SET_FLAG(OspfRI.as_flags, RIFLG_LSA_ENGAGED); ospf_flood_through_as(top, NULL /*nbr */, new); if (IS_DEBUG_OSPF(lsa, LSA_GENERATE)) { zlog_debug( "LSA[Type%d:%pI4]: Originate Opaque-LSA/ROUTER INFORMATION", new->data->type, &new->data->id); ospf_lsa_header_dump(new->data); } rc = 0; return rc; } static int ospf_router_info_lsa_originate_area(void *arg) { struct ospf_lsa *new; struct ospf *top; struct ospf_ri_area_info *ai = NULL; int rc = -1; /* Sanity Check */ if (OspfRI.scope == OSPF_OPAQUE_AS_LSA) { flog_warn( EC_OSPF_LSA_INSTALL_FAILURE, "RI (%s): wrong flooding scope AS instead of AREA ?", __func__); return rc; } /* Create new Opaque-LSA/ROUTER INFORMATION instance. */ ai = lookup_by_area((struct ospf_area *)arg); if (ai == NULL) { zlog_debug( "RI (%s): There is no context for this Router Information. Stop processing", __func__); return rc; } if (ai->area->ospf) top = ai->area->ospf; else top = ospf_lookup_by_vrf_id(VRF_DEFAULT); new = ospf_router_info_lsa_new(ai->area); /* Check ospf info */ if (top == NULL) { zlog_debug("RI (%s): ospf instance not found for vrf id %u", __func__, VRF_DEFAULT); ospf_lsa_unlock(&new); return rc; } /* Install this LSA into LSDB. */ if (ospf_lsa_install(top, NULL /*oi */, new) == NULL) { flog_warn( EC_OSPF_LSA_INSTALL_FAILURE, "RI (%s): ospf_lsa_install() ?", __func__); ospf_lsa_unlock(&new); return rc; } /* Update new LSA origination count. */ top->lsa_originate_count++; /* Flood new LSA through AREA or AS. */ SET_FLAG(ai->flags, RIFLG_LSA_ENGAGED); ospf_flood_through_area(ai->area, NULL /*nbr */, new); if (IS_DEBUG_OSPF(lsa, LSA_GENERATE)) { zlog_debug( "LSA[Type%d:%pI4]: Originate Opaque-LSA/ROUTER INFORMATION", new->data->type, &new->data->id); ospf_lsa_header_dump(new->data); } rc = 0; return rc; } static int ospf_router_info_lsa_originate(void *arg) { struct ospf_ri_area_info *ai; int rc = -1; if (!OspfRI.enabled) { zlog_info("RI (%s): ROUTER INFORMATION is disabled now.", __func__); rc = 0; /* This is not an error case. */ return rc; } /* Check if Router Information LSA is already engaged */ if (OspfRI.scope == OSPF_OPAQUE_AS_LSA) { if ((CHECK_FLAG(OspfRI.as_flags, RIFLG_LSA_ENGAGED)) && (CHECK_FLAG(OspfRI.as_flags, RIFLG_LSA_FORCED_REFRESH))) { UNSET_FLAG(OspfRI.as_flags, RIFLG_LSA_FORCED_REFRESH); ospf_router_info_lsa_schedule(NULL, REFRESH_THIS_LSA); rc = 0; return rc; } } else { ai = lookup_by_area((struct ospf_area *)arg); if (ai == NULL) { flog_warn( EC_OSPF_LSA, "RI (%s): Missing area information", __func__); return rc; } if ((CHECK_FLAG(ai->flags, RIFLG_LSA_ENGAGED)) && (CHECK_FLAG(ai->flags, RIFLG_LSA_FORCED_REFRESH))) { UNSET_FLAG(ai->flags, RIFLG_LSA_FORCED_REFRESH); ospf_router_info_lsa_schedule(ai, REFRESH_THIS_LSA); rc = 0; return rc; } } /* Router Information is not yet Engaged, check parameters */ if (!is_mandated_params_set(&OspfRI)) flog_warn( EC_OSPF_LSA, "RI (%s): lacks mandated ROUTER INFORMATION parameters", __func__); /* Ok, let's try to originate an LSA */ if (OspfRI.scope == OSPF_OPAQUE_AS_LSA) rc = ospf_router_info_lsa_originate_as(arg); else rc = ospf_router_info_lsa_originate_area(arg); return rc; } static struct ospf_lsa *ospf_router_info_lsa_refresh(struct ospf_lsa *lsa) { struct ospf_ri_area_info *ai = NULL; struct ospf_lsa *new = NULL; struct ospf *top; if (!OspfRI.enabled) { /* * This LSA must have flushed before due to ROUTER INFORMATION * status change. * It seems a slip among routers in the routing domain. */ zlog_info("RI (%s): ROUTER INFORMATION is disabled now.", __func__); lsa->data->ls_age = htons(OSPF_LSA_MAXAGE); /* Flush it anyway. */ } /* Verify that the Router Information ID is supported */ if (GET_OPAQUE_ID(ntohl(lsa->data->id.s_addr)) != 0) { flog_warn( EC_OSPF_LSA, "RI (%s): Unsupported Router Information ID", __func__); return NULL; } /* Process LSA depending of the flooding scope */ if (OspfRI.scope == OSPF_OPAQUE_AREA_LSA) { /* Get context AREA context */ ai = lookup_by_area(lsa->area); if (ai == NULL) { flog_warn( EC_OSPF_LSA, "RI (%s): No associated Area", __func__); return NULL; } /* Flush LSA, if the lsa's age reached to MaxAge. */ if (IS_LSA_MAXAGE(lsa)) { UNSET_FLAG(ai->flags, RIFLG_LSA_ENGAGED); ospf_opaque_lsa_flush_schedule(lsa); return NULL; } /* Create new Opaque-LSA/ROUTER INFORMATION instance. */ new = ospf_router_info_lsa_new(ai->area); new->data->ls_seqnum = lsa_seqnum_increment(lsa); /* Install this LSA into LSDB. */ /* Given "lsa" will be freed in the next function. */ top = ospf_lookup_by_vrf_id(VRF_DEFAULT); if (ospf_lsa_install(top, NULL /*oi */, new) == NULL) { flog_warn(EC_OSPF_LSA_INSTALL_FAILURE, "RI (%s): ospf_lsa_install() ?", __func__); ospf_lsa_unlock(&new); return new; } /* Flood updated LSA through AREA */ ospf_flood_through_area(ai->area, NULL /*nbr */, new); } else { /* AS Flooding scope */ /* Flush LSA, if the lsa's age reached to MaxAge. */ if (IS_LSA_MAXAGE(lsa)) { UNSET_FLAG(OspfRI.as_flags, RIFLG_LSA_ENGAGED); ospf_opaque_lsa_flush_schedule(lsa); return NULL; } /* Create new Opaque-LSA/ROUTER INFORMATION instance. */ new = ospf_router_info_lsa_new(NULL); new->data->ls_seqnum = lsa_seqnum_increment(lsa); /* Install this LSA into LSDB. */ /* Given "lsa" will be freed in the next function. */ top = ospf_lookup_by_vrf_id(VRF_DEFAULT); if (ospf_lsa_install(top, NULL /*oi */, new) == NULL) { flog_warn(EC_OSPF_LSA_INSTALL_FAILURE, "RI (%s): ospf_lsa_install() ?", __func__); ospf_lsa_unlock(&new); return new; } /* Flood updated LSA through AS */ ospf_flood_through_as(top, NULL /*nbr */, new); } /* Debug logging. */ if (IS_DEBUG_OSPF(lsa, LSA_GENERATE)) { zlog_debug( "LSA[Type%d:%pI4]: Refresh Opaque-LSA/ROUTER INFORMATION", new->data->type, &new->data->id); ospf_lsa_header_dump(new->data); } return new; } static void ospf_router_info_lsa_schedule(struct ospf_ri_area_info *ai, enum lsa_opcode opcode) { struct ospf_lsa lsa; struct lsa_header lsah; struct ospf *top; uint32_t tmp; memset(&lsa, 0, sizeof(lsa)); memset(&lsah, 0, sizeof(lsah)); zlog_debug("RI (%s): LSA schedule %s%s%s", __func__, opcode == REORIGINATE_THIS_LSA ? "Re-Originate" : "", opcode == REFRESH_THIS_LSA ? "Refresh" : "", opcode == FLUSH_THIS_LSA ? "Flush" : ""); /* Check LSA flags state coherence and collect area information */ if (OspfRI.scope == OSPF_OPAQUE_AREA_LSA) { if ((ai == NULL) || (ai->area == NULL)) { flog_warn( EC_OSPF_LSA, "RI (%s): Router Info is Area scope flooding but area is not set", __func__); return; } if (!CHECK_FLAG(ai->flags, RIFLG_LSA_ENGAGED) && (opcode != REORIGINATE_THIS_LSA)) return; if (CHECK_FLAG(ai->flags, RIFLG_LSA_ENGAGED) && (opcode == REORIGINATE_THIS_LSA)) opcode = REFRESH_THIS_LSA; lsa.area = ai->area; top = ai->area->ospf; } else { if (!CHECK_FLAG(OspfRI.as_flags, RIFLG_LSA_ENGAGED) && (opcode != REORIGINATE_THIS_LSA)) return; if (CHECK_FLAG(OspfRI.as_flags, RIFLG_LSA_ENGAGED) && (opcode == REORIGINATE_THIS_LSA)) opcode = REFRESH_THIS_LSA; top = ospf_lookup_by_vrf_id(VRF_DEFAULT); lsa.area = NULL; } lsa.data = &lsah; lsah.type = OspfRI.scope; /* LSA ID is set to 0 for the Router Information. See RFC 4970 */ tmp = SET_OPAQUE_LSID(OPAQUE_TYPE_ROUTER_INFORMATION_LSA, 0); lsah.id.s_addr = htonl(tmp); switch (opcode) { case REORIGINATE_THIS_LSA: if (OspfRI.scope == OSPF_OPAQUE_AREA_LSA) ospf_opaque_lsa_reoriginate_schedule( (void *)ai->area, OSPF_OPAQUE_AREA_LSA, OPAQUE_TYPE_ROUTER_INFORMATION_LSA); else ospf_opaque_lsa_reoriginate_schedule( (void *)top, OSPF_OPAQUE_AS_LSA, OPAQUE_TYPE_ROUTER_INFORMATION_LSA); break; case REFRESH_THIS_LSA: ospf_opaque_lsa_refresh_schedule(&lsa); break; case FLUSH_THIS_LSA: if (OspfRI.scope == OSPF_OPAQUE_AREA_LSA) UNSET_FLAG(ai->flags, RIFLG_LSA_ENGAGED); else UNSET_FLAG(OspfRI.as_flags, RIFLG_LSA_ENGAGED); ospf_opaque_lsa_flush_schedule(&lsa); break; } return; } /* Callback to handle Segment Routing information */ static int ospf_router_info_lsa_update(struct ospf_lsa *lsa) { /* Sanity Check */ if (lsa == NULL) { flog_warn(EC_OSPF_LSA, "RI (%s): Abort! LSA is NULL", __func__); return -1; } /* Process only Opaque LSA */ if ((lsa->data->type != OSPF_OPAQUE_AREA_LSA) && (lsa->data->type != OSPF_OPAQUE_AS_LSA)) return 0; /* Process only Router Information LSA */ if (GET_OPAQUE_TYPE(ntohl(lsa->data->id.s_addr)) != OPAQUE_TYPE_ROUTER_INFORMATION_LSA) return 0; /* Check if it is not my LSA */ if (IS_LSA_SELF(lsa)) return 0; /* Check if Router Info & Segment Routing are enable */ if (!OspfRI.enabled || !OspfRI.sr_info.enabled) return 0; /* Call Segment Routing LSA update or deletion */ if (!IS_LSA_MAXAGE(lsa)) ospf_sr_ri_lsa_update(lsa); else ospf_sr_ri_lsa_delete(lsa); return 0; } /*------------------------------------------------------------------------* * Following are vty session control functions. *------------------------------------------------------------------------*/ #define check_tlv_size(size, msg) \ do { \ if (ntohs(tlvh->length) > size) { \ if (vty != NULL) \ vty_out(vty, " Wrong %s TLV size: %d(%d)\n", \ msg, ntohs(tlvh->length), size); \ else \ zlog_debug(" Wrong %s TLV size: %d(%d)", \ msg, ntohs(tlvh->length), size); \ return size + TLV_HDR_SIZE; \ } \ } while (0) static uint16_t show_vty_router_cap(struct vty *vty, struct tlv_header *tlvh, json_object *json) { struct ri_tlv_router_cap *top = (struct ri_tlv_router_cap *)tlvh; check_tlv_size(RI_TLV_CAPABILITIES_SIZE, "Router Capabilities"); if (vty != NULL) if (!json) vty_out(vty, " Router Capabilities: 0x%x\n", ntohl(top->value)); else json_object_string_addf(json, "routerCapabilities", "0x%x", ntohl(top->value)); else zlog_debug(" Router Capabilities: 0x%x", ntohl(top->value)); return TLV_SIZE(tlvh); } static uint16_t show_vty_pce_subtlv_address(struct vty *vty, struct tlv_header *tlvh, json_object *json) { struct ri_pce_subtlv_address *top = (struct ri_pce_subtlv_address *)tlvh; if (ntohs(top->address.type) == PCE_ADDRESS_IPV4) { check_tlv_size(PCE_ADDRESS_IPV4_SIZE, "PCE Address"); if (vty != NULL) if (!json) vty_out(vty, " PCE Address: %pI4\n", &top->address.value); else json_object_string_addf(json, "pceAddress", "%pI4", &top->address.value); else zlog_debug(" PCE Address: %pI4", &top->address.value); } else if (ntohs(top->address.type) == PCE_ADDRESS_IPV6) { check_tlv_size(PCE_ADDRESS_IPV6_SIZE, "PCE Address"); if (vty != NULL) if (!json) vty_out(vty, " PCE Address: unsupported IPv6\n"); else json_object_string_add(json, "pceAddress", "unsupported IPv6"); else zlog_debug(" PCE Address: unsupported IPv6"); } else { if (vty != NULL) vty_out(vty, " Wrong PCE Address type: 0x%x\n", ntohl(top->address.type)); else zlog_debug(" Wrong PCE Address type: 0x%x", ntohl(top->address.type)); } return TLV_SIZE(tlvh); } static uint16_t show_vty_pce_subtlv_path_scope(struct vty *vty, struct tlv_header *tlvh, json_object *json) { struct ri_pce_subtlv_path_scope *top = (struct ri_pce_subtlv_path_scope *)tlvh; check_tlv_size(RI_PCE_SUBTLV_PATH_SCOPE_SIZE, "PCE Path Scope"); if (vty != NULL) if (!json) vty_out(vty, " PCE Path Scope: 0x%x\n", ntohl(top->value)); else json_object_string_addf(json, "pcePathScope", "0x%x", ntohl(top->value)); else zlog_debug(" PCE Path Scope: 0x%x", ntohl(top->value)); return TLV_SIZE(tlvh); } static uint16_t show_vty_pce_subtlv_domain(struct vty *vty, struct tlv_header *tlvh, json_object *json) { struct ri_pce_subtlv_domain *top = (struct ri_pce_subtlv_domain *)tlvh; struct in_addr tmp; check_tlv_size(RI_PCE_SUBTLV_DOMAIN_SIZE, "PCE Domain"); if (ntohs(top->type) == PCE_DOMAIN_TYPE_AREA) { tmp.s_addr = top->value; if (vty != NULL) if (!json) vty_out(vty, " PCE Domain Area: %pI4\n", &tmp); else json_object_string_addf(json, "pceDomainArea", "%pI4", &tmp); else zlog_debug(" PCE Domain Area: %pI4", &tmp); } else if (ntohs(top->type) == PCE_DOMAIN_TYPE_AS) { if (vty != NULL) if (!json) vty_out(vty, " PCE Domain AS: %d\n", ntohl(top->value)); else json_object_int_add(json, "pceDomainAS", ntohl(top->value)); else zlog_debug(" PCE Domain AS: %d", ntohl(top->value)); } else { if (vty != NULL) vty_out(vty, " Wrong PCE Domain type: %d\n", ntohl(top->type)); else zlog_debug(" Wrong PCE Domain type: %d", ntohl(top->type)); } return TLV_SIZE(tlvh); } static uint16_t show_vty_pce_subtlv_neighbor(struct vty *vty, struct tlv_header *tlvh, json_object *json) { struct ri_pce_subtlv_neighbor *top = (struct ri_pce_subtlv_neighbor *)tlvh; struct in_addr tmp; check_tlv_size(RI_PCE_SUBTLV_NEIGHBOR_SIZE, "PCE Neighbor"); if (ntohs(top->type) == PCE_DOMAIN_TYPE_AREA) { tmp.s_addr = top->value; if (vty != NULL) if (!json) vty_out(vty, " PCE Neighbor Area: %pI4\n", &tmp); else json_object_string_addf(json, "pceNeighborArea", "%pI4", &tmp); else zlog_debug(" PCE Neighbor Area: %pI4", &tmp); } else if (ntohs(top->type) == PCE_DOMAIN_TYPE_AS) { if (vty != NULL) if (!json) vty_out(vty, " PCE Neighbor AS: %d\n", ntohl(top->value)); else json_object_int_add(json, "pceNeighborAS", ntohl(top->value)); else zlog_debug(" PCE Neighbor AS: %d", ntohl(top->value)); } else { if (vty != NULL) vty_out(vty, " Wrong PCE Neighbor type: %d\n", ntohl(top->type)); else zlog_debug(" Wrong PCE Neighbor type: %d", ntohl(top->type)); } return TLV_SIZE(tlvh); } static uint16_t show_vty_pce_subtlv_cap_flag(struct vty *vty, struct tlv_header *tlvh, json_object *json) { struct ri_pce_subtlv_cap_flag *top = (struct ri_pce_subtlv_cap_flag *)tlvh; check_tlv_size(RI_PCE_SUBTLV_CAP_FLAG_SIZE, "PCE Capabilities"); if (vty != NULL) if (!json) vty_out(vty, " PCE Capabilities Flag: 0x%x\n", ntohl(top->value)); else json_object_string_addf(json, "pceCapabilities", "0x%x", ntohl(top->value)); else zlog_debug(" PCE Capabilities Flag: 0x%x", ntohl(top->value)); return TLV_SIZE(tlvh); } static uint16_t show_vty_unknown_tlv(struct vty *vty, struct tlv_header *tlvh, size_t buf_size, json_object *json) { json_object *obj; if (TLV_SIZE(tlvh) > buf_size) { if (vty != NULL) vty_out(vty, " TLV size %d exceeds buffer size. Abort!", TLV_SIZE(tlvh)); else zlog_debug( " TLV size %d exceeds buffer size. Abort!", TLV_SIZE(tlvh)); return buf_size; } if (vty != NULL) if (!json) vty_out(vty, " Unknown TLV: [type(0x%x), length(0x%x)]\n", ntohs(tlvh->type), ntohs(tlvh->length)); else { obj = json_object_new_object(); json_object_string_addf(obj, "type", "0x%x", ntohs(tlvh->type)); json_object_string_addf(obj, "length", "0x%x", ntohs(tlvh->length)); json_object_object_add(json, "unknownTLV", obj); } else zlog_debug(" Unknown TLV: [type(0x%x), length(0x%x)]", ntohs(tlvh->type), ntohs(tlvh->length)); return TLV_SIZE(tlvh); } static uint16_t show_vty_pce_info(struct vty *vty, struct tlv_header *ri, size_t buf_size, json_object *json) { struct tlv_header *tlvh; uint16_t length = ntohs(ri->length); uint16_t sum = 0; /* Verify that TLV length is valid against remaining buffer size */ if (length > buf_size) { vty_out(vty, " PCE Info TLV size %d exceeds buffer size. Abort!\n", length); return buf_size; } for (tlvh = ri; sum < length; tlvh = TLV_HDR_NEXT(tlvh)) { switch (ntohs(tlvh->type)) { case RI_PCE_SUBTLV_ADDRESS: sum += show_vty_pce_subtlv_address(vty, tlvh, json); break; case RI_PCE_SUBTLV_PATH_SCOPE: sum += show_vty_pce_subtlv_path_scope(vty, tlvh, json); break; case RI_PCE_SUBTLV_DOMAIN: sum += show_vty_pce_subtlv_domain(vty, tlvh, json); break; case RI_PCE_SUBTLV_NEIGHBOR: sum += show_vty_pce_subtlv_neighbor(vty, tlvh, json); break; case RI_PCE_SUBTLV_CAP_FLAG: sum += show_vty_pce_subtlv_cap_flag(vty, tlvh, json); break; default: sum += show_vty_unknown_tlv(vty, tlvh, length - sum, json); break; } } return sum; } /* Display Segment Routing Algorithm TLV information */ static uint16_t show_vty_sr_algorithm(struct vty *vty, struct tlv_header *tlvh, json_object *json) { struct ri_sr_tlv_sr_algorithm *algo = (struct ri_sr_tlv_sr_algorithm *)tlvh; int i; json_object *json_algo, *obj; char buf[2]; check_tlv_size(ALGORITHM_COUNT, "Segment Routing Algorithm"); if (vty != NULL) if (!json) { vty_out(vty, " Segment Routing Algorithm TLV:\n"); for (i = 0; i < ntohs(algo->header.length); i++) { switch (algo->value[i]) { case 0: vty_out(vty, " Algorithm %d: SPF\n", i); break; case 1: vty_out(vty, " Algorithm %d: Strict SPF\n", i); break; default: vty_out(vty, " Algorithm %d: Unknown value %d\n", i, algo->value[i]); break; } } } else { json_algo = json_object_new_array(); json_object_object_add(json, "algorithms", json_algo); for (i = 0; i < ntohs(algo->header.length); i++) { obj = json_object_new_object(); snprintfrr(buf, 2, "%d", i); switch (algo->value[i]) { case 0: json_object_string_add(obj, buf, "SPF"); break; case 1: json_object_string_add(obj, buf, "strictSPF"); break; default: json_object_string_add(obj, buf, "unknown"); break; } json_object_array_add(json_algo, obj); } } else { zlog_debug(" Segment Routing Algorithm TLV:"); for (i = 0; i < ntohs(algo->header.length); i++) switch (algo->value[i]) { case 0: zlog_debug(" Algorithm %d: SPF", i); break; case 1: zlog_debug(" Algorithm %d: Strict SPF", i); break; default: zlog_debug(" Algorithm %d: Unknown value %d", i, algo->value[i]); break; } } return TLV_SIZE(tlvh); } /* Display Segment Routing SID/Label Range TLV information */ static uint16_t show_vty_sr_range(struct vty *vty, struct tlv_header *tlvh, json_object *json) { struct ri_sr_tlv_sid_label_range *range = (struct ri_sr_tlv_sid_label_range *)tlvh; json_object *obj; uint32_t upper; check_tlv_size(RI_SR_TLV_LABEL_RANGE_SIZE, "SR Label Range"); if (vty != NULL) if (!json) { vty_out(vty, " Segment Routing %s Range TLV:\n" " Range Size = %d\n" " SID Label = %d\n\n", ntohs(range->header.type) == RI_SR_TLV_SRGB_LABEL_RANGE ? "Global" : "Local", GET_RANGE_SIZE(ntohl(range->size)), GET_LABEL(ntohl(range->lower.value))); } else { /* * According to draft-ietf-teas-yang-sr-te-topo, SRGB * and SRLB are describe with lower and upper bounds */ upper = GET_LABEL(ntohl(range->lower.value)) + GET_RANGE_SIZE(ntohl(range->size)) - 1; obj = json_object_new_object(); json_object_int_add(obj, "upperBound", upper); json_object_int_add(obj, "lowerBound", GET_LABEL(ntohl(range->lower.value))); json_object_object_add(json, ntohs(range->header.type) == RI_SR_TLV_SRGB_LABEL_RANGE ? "srgb" : "srlb", obj); } else { zlog_debug( " Segment Routing %s Range TLV: Range Size = %d SID Label = %d", ntohs(range->header.type) == RI_SR_TLV_SRGB_LABEL_RANGE ? "Global" : "Local", GET_RANGE_SIZE(ntohl(range->size)), GET_LABEL(ntohl(range->lower.value))); } return TLV_SIZE(tlvh); } /* Display Segment Routing Maximum Stack Depth TLV information */ static uint16_t show_vty_sr_msd(struct vty *vty, struct tlv_header *tlvh, json_object *json) { struct ri_sr_tlv_node_msd *msd = (struct ri_sr_tlv_node_msd *)tlvh; check_tlv_size(RI_SR_TLV_NODE_MSD_SIZE, "Node Maximum Stack Depth"); if (vty != NULL) if (!json) vty_out(vty, " Segment Routing MSD TLV:\n" " Node Maximum Stack Depth = %d\n", msd->value); else json_object_int_add(json, "nodeMsd", msd->value); else zlog_debug( " Segment Routing MSD TLV: Node Maximum Stack Depth = %d", msd->value); return TLV_SIZE(tlvh); } static void ospf_router_info_show_info(struct vty *vty, struct json_object *json, struct ospf_lsa *lsa) { struct lsa_header *lsah = lsa->data; struct tlv_header *tlvh; uint16_t length = 0, sum = 0; json_object *jri = NULL, *jpce = NULL, *jsr = NULL; if (json) { jri = json_object_new_object(); json_object_object_add(json, "routerInformation", jri); jpce = json_object_new_object(); jsr = json_object_new_object(); } /* Initialize TLV browsing */ length = lsa->size - OSPF_LSA_HEADER_SIZE; for (tlvh = TLV_HDR_TOP(lsah); sum < length && tlvh; tlvh = TLV_HDR_NEXT(tlvh)) { switch (ntohs(tlvh->type)) { case RI_TLV_CAPABILITIES: sum += show_vty_router_cap(vty, tlvh, jri); break; case RI_TLV_PCE: tlvh++; sum += TLV_HDR_SIZE; sum += show_vty_pce_info(vty, tlvh, length - sum, jpce); break; case RI_SR_TLV_SR_ALGORITHM: sum += show_vty_sr_algorithm(vty, tlvh, jsr); break; case RI_SR_TLV_SRGB_LABEL_RANGE: case RI_SR_TLV_SRLB_LABEL_RANGE: sum += show_vty_sr_range(vty, tlvh, jsr); break; case RI_SR_TLV_NODE_MSD: sum += show_vty_sr_msd(vty, tlvh, jsr); break; default: sum += show_vty_unknown_tlv(vty, tlvh, length, jri); break; } } if (json) { if (json_object_object_length(jpce) > 1) json_object_object_add(jri, "pceInformation", jpce); if (json_object_object_length(jsr) > 1) json_object_object_add(jri, "segmentRouting", jsr); } return; } static void ospf_router_info_config_write_router(struct vty *vty) { struct ospf_pce_info *pce = &OspfRI.pce_info; struct listnode *node; struct ri_pce_subtlv_domain *domain; struct ri_pce_subtlv_neighbor *neighbor; struct in_addr tmp; if (!OspfRI.enabled) return; if (OspfRI.scope == OSPF_OPAQUE_AS_LSA) vty_out(vty, " router-info as\n"); else vty_out(vty, " router-info area\n"); if (OspfRI.pce_info.enabled) { if (pce->pce_address.header.type != 0) vty_out(vty, " pce address %pI4\n", &pce->pce_address.address.value); if (pce->pce_cap_flag.header.type != 0) vty_out(vty, " pce flag 0x%x\n", ntohl(pce->pce_cap_flag.value)); for (ALL_LIST_ELEMENTS_RO(pce->pce_domain, node, domain)) { if (domain->header.type != 0) { if (domain->type == PCE_DOMAIN_TYPE_AREA) { tmp.s_addr = domain->value; vty_out(vty, " pce domain area %pI4\n", &tmp); } else { vty_out(vty, " pce domain as %d\n", ntohl(domain->value)); } } } for (ALL_LIST_ELEMENTS_RO(pce->pce_neighbor, node, neighbor)) { if (neighbor->header.type != 0) { if (neighbor->type == PCE_DOMAIN_TYPE_AREA) { tmp.s_addr = neighbor->value; vty_out(vty, " pce neighbor area %pI4\n", &tmp); } else { vty_out(vty, " pce neighbor as %d\n", ntohl(neighbor->value)); } } } if (pce->pce_scope.header.type != 0) vty_out(vty, " pce scope 0x%x\n", ntohl(OspfRI.pce_info.pce_scope.value)); } return; } /*------------------------------------------------------------------------* * Following are vty command functions. *------------------------------------------------------------------------*/ /* Simple wrapper schedule RI LSA action in function of the scope */ static void ospf_router_info_schedule(enum lsa_opcode opcode) { struct listnode *node, *nnode; struct ospf_ri_area_info *ai; if (OspfRI.scope == OSPF_OPAQUE_AS_LSA) { if (CHECK_FLAG(OspfRI.as_flags, RIFLG_LSA_ENGAGED)) ospf_router_info_lsa_schedule(NULL, opcode); else if (opcode == REORIGINATE_THIS_LSA) ospf_router_info_lsa_schedule(NULL, opcode); } else { for (ALL_LIST_ELEMENTS(OspfRI.area_info, node, nnode, ai)) { if (CHECK_FLAG(ai->flags, RIFLG_LSA_ENGAGED)) ospf_router_info_lsa_schedule(ai, opcode); } } } DEFUN (router_info, router_info_area_cmd, "router-info ", OSPF_RI_STR "Enable the Router Information functionality with AS flooding scope\n" "Enable the Router Information functionality with Area flooding scope\n" "OSPF area ID in IP format (deprecated)\n") { int idx_mode = 1; uint8_t scope; VTY_DECLVAR_INSTANCE_CONTEXT(ospf, ospf); if (OspfRI.enabled) return CMD_SUCCESS; /* Check that the OSPF is using default VRF */ if (ospf->vrf_id != VRF_DEFAULT) { vty_out(vty, "Router Information is only supported in default VRF\n"); return CMD_WARNING_CONFIG_FAILED; } /* Check and get Area value if present */ if (strncmp(argv[idx_mode]->arg, "as", 2) == 0) scope = OSPF_OPAQUE_AS_LSA; else scope = OSPF_OPAQUE_AREA_LSA; /* First start to register Router Information callbacks */ if (!OspfRI.registered && (ospf_router_info_register(scope)) != 0) { vty_out(vty, "%% Unable to register Router Information callbacks."); flog_err( EC_OSPF_INIT_FAIL, "RI (%s): Unable to register Router Information callbacks. Abort!", __func__); return CMD_WARNING_CONFIG_FAILED; } OspfRI.enabled = true; if (IS_DEBUG_OSPF_EVENT) zlog_debug("RI-> Router Information (%s flooding): OFF -> ON", OspfRI.scope == OSPF_OPAQUE_AREA_LSA ? "Area" : "AS"); /* * Following code is intended to handle two cases; * * 1) Router Information was disabled at startup time, but now become * enabled. * 2) Router Information was once enabled then disabled, and now enabled * again. */ initialize_params(&OspfRI); /* Originate or Refresh RI LSA if already engaged */ ospf_router_info_schedule(REORIGINATE_THIS_LSA); return CMD_SUCCESS; } DEFUN (no_router_info, no_router_info_cmd, "no router-info []", NO_STR "Disable the Router Information functionality\n" "Disable the Router Information functionality with AS flooding scope\n" "Disable the Router Information functionality with Area flooding scope\n") { if (!OspfRI.enabled) return CMD_SUCCESS; if (IS_DEBUG_OSPF_EVENT) zlog_debug("RI-> Router Information: ON -> OFF"); ospf_router_info_schedule(FLUSH_THIS_LSA); OspfRI.enabled = false; return CMD_SUCCESS; } static int ospf_ri_enabled(struct vty *vty) { if (OspfRI.enabled) return 1; if (vty) vty_out(vty, "%% OSPF RI is not turned on\n"); return 0; } DEFUN (pce_address, pce_address_cmd, "pce address A.B.C.D", PCE_STR "Stable IP address of the PCE\n" "PCE address in IPv4 address format\n") { int idx_ipv4 = 2; struct in_addr value; struct ospf_pce_info *pi = &OspfRI.pce_info; if (!ospf_ri_enabled(vty)) return CMD_WARNING_CONFIG_FAILED; if (!inet_aton(argv[idx_ipv4]->arg, &value)) { vty_out(vty, "Please specify PCE Address by A.B.C.D\n"); return CMD_WARNING_CONFIG_FAILED; } if (ntohs(pi->pce_address.header.type) == 0 || ntohl(pi->pce_address.address.value.s_addr) != ntohl(value.s_addr)) { set_pce_address(value, pi); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); } return CMD_SUCCESS; } DEFUN (no_pce_address, no_pce_address_cmd, "no pce address [A.B.C.D]", NO_STR PCE_STR "Disable PCE address\n" "PCE address in IPv4 address format\n") { unset_param(&OspfRI.pce_info.pce_address); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); return CMD_SUCCESS; } DEFUN (pce_path_scope, pce_path_scope_cmd, "pce scope BITPATTERN", PCE_STR "Path scope visibilities of the PCE for path computation\n" "32-bit Hexadecimal value\n") { int idx_bitpattern = 2; uint32_t scope; struct ospf_pce_info *pi = &OspfRI.pce_info; if (!ospf_ri_enabled(vty)) return CMD_WARNING_CONFIG_FAILED; if (sscanf(argv[idx_bitpattern]->arg, "0x%x", &scope) != 1) { vty_out(vty, "pce_path_scope: fscanf: %s\n", safe_strerror(errno)); return CMD_WARNING_CONFIG_FAILED; } if (ntohl(pi->pce_scope.header.type) == 0 || scope != pi->pce_scope.value) { set_pce_path_scope(scope, pi); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); } return CMD_SUCCESS; } DEFUN (no_pce_path_scope, no_pce_path_scope_cmd, "no pce scope [BITPATTERN]", NO_STR PCE_STR "Disable PCE path scope\n" "32-bit Hexadecimal value\n") { unset_param(&OspfRI.pce_info.pce_address); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); return CMD_SUCCESS; } DEFUN (pce_domain, pce_domain_cmd, "pce domain as (0-65535)", PCE_STR "Configure PCE domain AS number\n" "AS number where the PCE as visibilities for path computation\n" "AS number in decimal <0-65535>\n") { int idx_number = 3; uint32_t as; struct ospf_pce_info *pce = &OspfRI.pce_info; struct listnode *node; struct ri_pce_subtlv_domain *domain; if (!ospf_ri_enabled(vty)) return CMD_WARNING_CONFIG_FAILED; if (sscanf(argv[idx_number]->arg, "%" SCNu32, &as) != 1) { vty_out(vty, "pce_domain: fscanf: %s\n", safe_strerror(errno)); return CMD_WARNING_CONFIG_FAILED; } /* Check if the domain is not already in the domain list */ for (ALL_LIST_ELEMENTS_RO(pce->pce_domain, node, domain)) { if (ntohl(domain->header.type) == 0 && as == domain->value) return CMD_SUCCESS; } /* Create new domain if not found */ set_pce_domain(PCE_DOMAIN_TYPE_AS, as, pce); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); return CMD_SUCCESS; } DEFUN (no_pce_domain, no_pce_domain_cmd, "no pce domain as (0-65535)", NO_STR PCE_STR "Disable PCE domain AS number\n" "AS number where the PCE as visibilities for path computation\n" "AS number in decimal <0-65535>\n") { int idx_number = 4; uint32_t as; struct ospf_pce_info *pce = &OspfRI.pce_info; if (sscanf(argv[idx_number]->arg, "%" SCNu32, &as) != 1) { vty_out(vty, "no_pce_domain: fscanf: %s\n", safe_strerror(errno)); return CMD_WARNING_CONFIG_FAILED; } /* Unset corresponding PCE domain */ unset_pce_domain(PCE_DOMAIN_TYPE_AS, as, pce); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); return CMD_SUCCESS; } DEFUN (pce_neigbhor, pce_neighbor_cmd, "pce neighbor as (0-65535)", PCE_STR "Configure PCE neighbor domain AS number\n" "AS number of PCE neighbors\n" "AS number in decimal <0-65535>\n") { int idx_number = 3; uint32_t as; struct ospf_pce_info *pce = &OspfRI.pce_info; struct listnode *node; struct ri_pce_subtlv_neighbor *neighbor; if (!ospf_ri_enabled(vty)) return CMD_WARNING_CONFIG_FAILED; if (sscanf(argv[idx_number]->arg, "%" SCNu32, &as) != 1) { vty_out(vty, "pce_neighbor: fscanf: %s\n", safe_strerror(errno)); return CMD_WARNING_CONFIG_FAILED; } /* Check if the domain is not already in the domain list */ for (ALL_LIST_ELEMENTS_RO(pce->pce_neighbor, node, neighbor)) { if (ntohl(neighbor->header.type) == 0 && as == neighbor->value) return CMD_SUCCESS; } /* Create new domain if not found */ set_pce_neighbor(PCE_DOMAIN_TYPE_AS, as, pce); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); return CMD_SUCCESS; } DEFUN (no_pce_neighbor, no_pce_neighbor_cmd, "no pce neighbor as (0-65535)", NO_STR PCE_STR "Disable PCE neighbor AS number\n" "AS number of PCE neighbor\n" "AS number in decimal <0-65535>\n") { int idx_number = 4; uint32_t as; struct ospf_pce_info *pce = &OspfRI.pce_info; if (sscanf(argv[idx_number]->arg, "%" SCNu32, &as) != 1) { vty_out(vty, "no_pce_neighbor: fscanf: %s\n", safe_strerror(errno)); return CMD_WARNING_CONFIG_FAILED; } /* Unset corresponding PCE domain */ unset_pce_neighbor(PCE_DOMAIN_TYPE_AS, as, pce); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); return CMD_SUCCESS; } DEFUN (pce_cap_flag, pce_cap_flag_cmd, "pce flag BITPATTERN", PCE_STR "Capabilities of the PCE for path computation\n" "32-bit Hexadecimal value\n") { int idx_bitpattern = 2; uint32_t cap; struct ospf_pce_info *pce = &OspfRI.pce_info; if (!ospf_ri_enabled(vty)) return CMD_WARNING_CONFIG_FAILED; if (sscanf(argv[idx_bitpattern]->arg, "0x%x", &cap) != 1) { vty_out(vty, "pce_cap_flag: fscanf: %s\n", safe_strerror(errno)); return CMD_WARNING_CONFIG_FAILED; } if (ntohl(pce->pce_cap_flag.header.type) == 0 || cap != pce->pce_cap_flag.value) { set_pce_cap_flag(cap, pce); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); } return CMD_SUCCESS; } DEFUN (no_pce_cap_flag, no_pce_cap_flag_cmd, "no pce flag", NO_STR PCE_STR "Disable PCE capabilities\n") { unset_param(&OspfRI.pce_info.pce_cap_flag); /* Refresh RI LSA if already engaged */ ospf_router_info_schedule(REFRESH_THIS_LSA); return CMD_SUCCESS; } DEFUN (show_ip_ospf_router_info, show_ip_ospf_router_info_cmd, "show ip ospf router-info", SHOW_STR IP_STR OSPF_STR "Router Information\n") { if (OspfRI.enabled) { vty_out(vty, "--- Router Information parameters ---\n"); show_vty_router_cap(vty, &OspfRI.router_cap.header, NULL); } else { if (vty != NULL) vty_out(vty, " Router Information is disabled on this router\n"); } return CMD_SUCCESS; } DEFUN (show_ip_opsf_router_info_pce, show_ip_ospf_router_info_pce_cmd, "show ip ospf router-info pce", SHOW_STR IP_STR OSPF_STR "Router Information\n" "PCE information\n") { struct ospf_pce_info *pce = &OspfRI.pce_info; struct listnode *node; struct ri_pce_subtlv_domain *domain; struct ri_pce_subtlv_neighbor *neighbor; if ((OspfRI.enabled) && (OspfRI.pce_info.enabled)) { vty_out(vty, "--- PCE parameters ---\n"); if (pce->pce_address.header.type != 0) show_vty_pce_subtlv_address(vty, &pce->pce_address.header, NULL); if (pce->pce_scope.header.type != 0) show_vty_pce_subtlv_path_scope(vty, &pce->pce_scope.header, NULL); for (ALL_LIST_ELEMENTS_RO(pce->pce_domain, node, domain)) { if (domain->header.type != 0) show_vty_pce_subtlv_domain(vty, &domain->header, NULL); } for (ALL_LIST_ELEMENTS_RO(pce->pce_neighbor, node, neighbor)) { if (neighbor->header.type != 0) show_vty_pce_subtlv_neighbor(vty, &neighbor->header, NULL); } if (pce->pce_cap_flag.header.type != 0) show_vty_pce_subtlv_cap_flag(vty, &pce->pce_cap_flag.header, NULL); } else { vty_out(vty, " PCE info is disabled on this router\n"); } return CMD_SUCCESS; } /* Install new CLI commands */ static void ospf_router_info_register_vty(void) { install_element(VIEW_NODE, &show_ip_ospf_router_info_cmd); install_element(VIEW_NODE, &show_ip_ospf_router_info_pce_cmd); install_element(OSPF_NODE, &router_info_area_cmd); install_element(OSPF_NODE, &no_router_info_cmd); install_element(OSPF_NODE, &pce_address_cmd); install_element(OSPF_NODE, &no_pce_address_cmd); install_element(OSPF_NODE, &pce_path_scope_cmd); install_element(OSPF_NODE, &no_pce_path_scope_cmd); install_element(OSPF_NODE, &pce_domain_cmd); install_element(OSPF_NODE, &no_pce_domain_cmd); install_element(OSPF_NODE, &pce_neighbor_cmd); install_element(OSPF_NODE, &no_pce_neighbor_cmd); install_element(OSPF_NODE, &pce_cap_flag_cmd); install_element(OSPF_NODE, &no_pce_cap_flag_cmd); return; }