// SPDX-License-Identifier: GPL-2.0-or-later /* * Constraints Shortest Path First algorithms - cspf.c * * Author: Olivier Dugeon * * Copyright (C) 2022 Orange http://www.orange.com * * This file is part of Free Range Routing (FRR). */ #include #include "if.h" #include "linklist.h" #include "log.h" #include "hash.h" #include "memory.h" #include "prefix.h" #include "table.h" #include "stream.h" #include "printfrr.h" #include "link_state.h" #include "cspf.h" /* Link State Memory allocation */ DEFINE_MTYPE_STATIC(LIB, PCA, "Path Computation Algorithms"); /** * Create new Constrained Path. Memory is dynamically allocated. * * @param key Vertex key of the destination of this path * * @return Pointer to a new Constrained Path structure */ static struct c_path *cpath_new(uint64_t key) { struct c_path *path; /* Sanity Check */ if (key == 0) return NULL; path = XCALLOC(MTYPE_PCA, sizeof(struct c_path)); path->dst = key; path->status = IN_PROGRESS; path->edges = list_new(); path->weight = MAX_COST; return path; } /** * Copy src Constrained Path into dst Constrained Path. A new Constrained Path * structure is dynamically allocated if dst is NULL. If src is NULL, the * function return the dst disregarding if it is NULL or not. * * @param dest Destination Constrained Path structure * @param src Source Constrained Path structure * * @return Pointer to the destination Constrained Path structure */ static struct c_path *cpath_copy(struct c_path *dest, const struct c_path *src) { struct c_path *new_path; if (!src) return dest; if (!dest) { new_path = XCALLOC(MTYPE_PCA, sizeof(struct c_path)); } else { new_path = dest; if (dest->edges) list_delete(&new_path->edges); } new_path->dst = src->dst; new_path->weight = src->weight; new_path->edges = list_dup(src->edges); new_path->status = src->status; return new_path; } /** * Delete Constrained Path structure. Previous allocated memory is freed. * * @param path Constrained Path structure to be deleted */ void cpath_del(struct c_path *path) { if (!path) return; if (path->edges) list_delete(&path->edges); XFREE(MTYPE_PCA, path); path = NULL; } /** * Replace the list of edges in the next Constrained Path by the list of edges * in the current Constrained Path. * * @param next_path next Constrained Path structure * @param cur_path current Constrained Path structure */ static void cpath_replace(struct c_path *next_path, struct c_path *cur_path) { if (next_path->edges) list_delete(&next_path->edges); next_path->edges = list_dup(cur_path->edges); } /** * Create a new Visited Node structure from the provided Vertex. Structure is * dynamically allocated. * * @param vertex Vertex structure * * @return Pointer to the new Visited Node structure */ static struct v_node *vnode_new(struct ls_vertex *vertex) { struct v_node *vnode; if (!vertex) return NULL; vnode = XCALLOC(MTYPE_PCA, sizeof(struct v_node)); vnode->vertex = vertex; vnode->key = vertex->key; return vnode; } /** * Delete Visited Node structure. Previous allocated memory is freed. * * @param vnode Visited Node structure to be deleted */ static void vnode_del(struct v_node *vnode) { if (!vnode) return; XFREE(MTYPE_PCA, vnode); vnode = NULL; } /** * Search Vertex in TED by IPv4 address. The function search vertex by browsing * the subnets table. It allows to find not only vertex by router ID, but also * vertex by interface IPv4 address. * * @param ted Traffic Engineering Database * @param ipv4 IPv4 address * * @return Vertex if found, NULL otherwise */ static struct ls_vertex *get_vertex_by_ipv4(struct ls_ted *ted, struct in_addr ipv4) { struct ls_subnet *subnet; struct prefix p; p.family = AF_INET; p.u.prefix4 = ipv4; frr_each (subnets, &ted->subnets, subnet) { if (subnet->key.family != AF_INET) continue; p.prefixlen = subnet->key.prefixlen; if (prefix_same(&subnet->key, &p)) return subnet->vertex; } return NULL; } /** * Search Vertex in TED by IPv6 address. The function search vertex by browsing * the subnets table. It allows to find not only vertex by router ID, but also * vertex by interface IPv6 address. * * @param ted Traffic Engineering Database * @param ipv6 IPv6 address * * @return Vertex if found, NULL otherwise */ static struct ls_vertex *get_vertex_by_ipv6(struct ls_ted *ted, struct in6_addr ipv6) { struct ls_subnet *subnet; struct prefix p; p.family = AF_INET6; p.u.prefix6 = ipv6; frr_each (subnets, &ted->subnets, subnet) { if (subnet->key.family != AF_INET6) continue; p.prefixlen = subnet->key.prefixlen; if (prefix_cmp(&subnet->key, &p) == 0) return subnet->vertex; } return NULL; } struct cspf *cspf_new(void) { struct cspf *algo; /* Allocate New CSPF structure */ algo = XCALLOC(MTYPE_PCA, sizeof(struct cspf)); /* Initialize RB-Trees */ processed_init(&algo->processed); visited_init(&algo->visited); pqueue_init(&algo->pqueue); algo->path = NULL; algo->pdst = NULL; return algo; } struct cspf *cspf_init(struct cspf *algo, const struct ls_vertex *src, const struct ls_vertex *dst, struct constraints *csts) { struct cspf *new_algo; struct c_path *psrc; if (!csts) return NULL; if (!algo) new_algo = cspf_new(); else new_algo = algo; /* Initialize Processed Path and Priority Queue with Src & Dst */ if (src) { psrc = cpath_new(src->key); psrc->weight = 0; processed_add(&new_algo->processed, psrc); pqueue_add(&new_algo->pqueue, psrc); new_algo->path = psrc; } if (dst) { new_algo->pdst = cpath_new(dst->key); processed_add(&new_algo->processed, new_algo->pdst); } memcpy(&new_algo->csts, csts, sizeof(struct constraints)); return new_algo; } struct cspf *cspf_init_v4(struct cspf *algo, struct ls_ted *ted, const struct in_addr src, const struct in_addr dst, struct constraints *csts) { struct ls_vertex *vsrc; struct ls_vertex *vdst; struct cspf *new_algo; /* Sanity Check */ if (!ted) return algo; if (!algo) new_algo = cspf_new(); else new_algo = algo; /* Got Source and Destination Vertex from TED */ vsrc = get_vertex_by_ipv4(ted, src); vdst = get_vertex_by_ipv4(ted, dst); csts->family = AF_INET; return cspf_init(new_algo, vsrc, vdst, csts); } struct cspf *cspf_init_v6(struct cspf *algo, struct ls_ted *ted, const struct in6_addr src, const struct in6_addr dst, struct constraints *csts) { struct ls_vertex *vsrc; struct ls_vertex *vdst; struct cspf *new_algo; /* Sanity Check */ if (!ted) return algo; if (!algo) new_algo = cspf_new(); else new_algo = algo; /* Got Source and Destination Vertex from TED */ vsrc = get_vertex_by_ipv6(ted, src); vdst = get_vertex_by_ipv6(ted, dst); csts->family = AF_INET6; return cspf_init(new_algo, vsrc, vdst, csts); } void cspf_clean(struct cspf *algo) { struct c_path *path; struct v_node *vnode; if (!algo) return; /* Normally, Priority Queue is empty. Clean it in case of. */ if (pqueue_count(&algo->pqueue)) { frr_each_safe (pqueue, &algo->pqueue, path) { pqueue_del(&algo->pqueue, path); } } /* Empty Processed Path tree and associated Path */ if (processed_count(&algo->processed)) { frr_each_safe (processed, &algo->processed, path) { processed_del(&algo->processed, path); if (path == algo->pdst) algo->pdst = NULL; cpath_del(path); } } /* Empty visited Vertex tree and associated Node */ if (visited_count(&algo->visited)) { frr_each_safe (visited, &algo->visited, vnode) { visited_del(&algo->visited, vnode); vnode_del(vnode); } } if (algo->pdst) cpath_del(algo->pdst); memset(&algo->csts, 0, sizeof(struct constraints)); algo->path = NULL; algo->pdst = NULL; } void cspf_del(struct cspf *algo) { if (!algo) return; /* Empty Priority Queue and Processes Path */ cspf_clean(algo); /* Then, reset Priority Queue, Processed Path and Visited RB-Tree */ pqueue_fini(&algo->pqueue); processed_fini(&algo->processed); visited_fini(&algo->visited); XFREE(MTYPE_PCA, algo); algo = NULL; } /** * Prune Edge if constraints are not met by testing Edge Attributes against * given constraints and cumulative cost of the given constrained path. * * @param path On-going Computed Path with cumulative cost constraints * @param edge Edge to be validate against Constraints * @param csts Constraints for this path * * @return True if Edge should be prune, false if Edge is valid */ static bool prune_edge(const struct c_path *path, const struct ls_edge *edge, const struct constraints *csts) { struct ls_vertex *dst; struct ls_attributes *attr; /* Check that Path, Edge and Constraints are valid */ if (!path || !edge || !csts) return true; /* Check that Edge has a valid destination */ if (!edge->destination) return true; dst = edge->destination; /* Check that Edge has valid attributes */ if (!edge->attributes) return true; attr = edge->attributes; /* Check that Edge belongs to the requested Address Family and type */ if (csts->family == AF_INET) { if (IPV4_NET0(attr->standard.local.s_addr)) return true; if (csts->type == SR_TE) if (!CHECK_FLAG(attr->flags, LS_ATTR_ADJ_SID) || !CHECK_FLAG(dst->node->flags, LS_NODE_SR)) return true; } if (csts->family == AF_INET6) { if (IN6_IS_ADDR_UNSPECIFIED(&attr->standard.local6)) return true; if (csts->type == SR_TE) if (!CHECK_FLAG(attr->flags, LS_ATTR_ADJ_SID6) || !CHECK_FLAG(dst->node->flags, LS_NODE_SR)) return true; } /* * Check that total cost, up to this edge, respects the initial * constraints */ switch (csts->ctype) { case CSPF_METRIC: if (!CHECK_FLAG(attr->flags, LS_ATTR_METRIC)) return true; if ((attr->metric + path->weight) > csts->cost) return true; break; case CSPF_TE_METRIC: if (!CHECK_FLAG(attr->flags, LS_ATTR_TE_METRIC)) return true; if ((attr->standard.te_metric + path->weight) > csts->cost) return true; break; case CSPF_DELAY: if (!CHECK_FLAG(attr->flags, LS_ATTR_DELAY)) return true; if ((attr->extended.delay + path->weight) > csts->cost) return true; break; } /* If specified, check that Edge meet Bandwidth constraint */ if (csts->bw > 0.0) { if (attr->standard.max_bw < csts->bw || attr->standard.max_rsv_bw < csts->bw || attr->standard.unrsv_bw[csts->cos] < csts->bw) return true; } /* All is fine. We can consider this Edge valid, so not to be prune */ return false; } /** * Relax constraints of the current path up to the destination vertex of the * provided Edge. This function progress in the network topology by validating * the next vertex on the computed path. If Vertex has not already been visited, * list of edges of the current path is augmented with this edge if the new cost * is lower than prior path up to this vertex. Current path is re-inserted in * the Priority Queue with its new cost i.e. current cost + edge cost. * * @param algo CSPF structure * @param edge Next Edge to be added to the current computed path * * @return True if current path reach destination, false otherwise */ static bool relax_constraints(struct cspf *algo, struct ls_edge *edge) { struct c_path pkey = {}; struct c_path *next_path; struct v_node vnode = {}; uint32_t total_cost = MAX_COST; /* Verify that we have a current computed path */ if (!algo->path) return false; /* Verify if we have not visited the next Vertex to avoid loop */ vnode.key = edge->destination->key; if (visited_member(&algo->visited, &vnode)) { return false; } /* * Get Next Computed Path from next vertex key * or create a new one if it has not yet computed. */ pkey.dst = edge->destination->key; next_path = processed_find(&algo->processed, &pkey); if (!next_path) { next_path = cpath_new(pkey.dst); processed_add(&algo->processed, next_path); } /* * Add or update the Computed Path in the Priority Queue if total cost * is lower than cost associated to this next Vertex. This could occurs * if we process a Vertex that as not yet been visited in the Graph * or if we found a shortest path up to this Vertex. */ switch (algo->csts.ctype) { case CSPF_METRIC: total_cost = edge->attributes->metric + algo->path->weight; break; case CSPF_TE_METRIC: total_cost = edge->attributes->standard.te_metric + algo->path->weight; break; case CSPF_DELAY: total_cost = edge->attributes->extended.delay + algo->path->weight; break; default: break; } if (total_cost < next_path->weight) { /* * It is not possible to directly update the q_path in the * Priority Queue. Indeed, if we modify the path weight, the * Priority Queue must be re-ordered. So, we need fist to remove * the q_path if it is present in the Priority Queue, then, * update the Path, in particular the Weight, and finally * (re-)insert it in the Priority Queue. */ struct c_path *path; frr_each_safe (pqueue, &algo->pqueue, path) { if (path->dst == pkey.dst) { pqueue_del(&algo->pqueue, path); break; } } next_path->weight = total_cost; cpath_replace(next_path, algo->path); listnode_add(next_path->edges, edge); pqueue_add(&algo->pqueue, next_path); } /* Return True if we reach the destination */ return (next_path->dst == algo->pdst->dst); } struct c_path *compute_p2p_path(struct cspf *algo, struct ls_ted *ted) { struct listnode *node; struct ls_vertex *vertex; struct ls_edge *edge; struct c_path *optim_path; struct v_node *vnode; uint32_t cur_cost; optim_path = cpath_new(0xFFFFFFFFFFFFFFFF); optim_path->status = FAILED; /* Check that all is correctly initialized */ if (!algo) return optim_path; if (!algo->csts.ctype) return optim_path; if (!algo->pdst) { optim_path->status = NO_DESTINATION; return optim_path; } if (!algo->path) { optim_path->status = NO_SOURCE; return optim_path; } if (algo->pdst->dst == algo->path->dst) { optim_path->status = SAME_SRC_DST; return optim_path; } optim_path->dst = algo->pdst->dst; optim_path->status = IN_PROGRESS; /* * Process all Connected Vertex until priority queue becomes empty. * Connected Vertices are added into the priority queue when * processing the next Connected Vertex: see relax_constraints() */ cur_cost = MAX_COST; while (pqueue_count(&algo->pqueue) != 0) { /* Got shortest current Path from the Priority Queue */ algo->path = pqueue_pop(&algo->pqueue); /* Add destination Vertex of this path to the visited RB Tree */ vertex = ls_find_vertex_by_key(ted, algo->path->dst); if (!vertex) continue; vnode = vnode_new(vertex); visited_add(&algo->visited, vnode); /* Process all outgoing links from this Vertex */ for (ALL_LIST_ELEMENTS_RO(vertex->outgoing_edges, node, edge)) { /* * Skip Connected Edges that must be prune i.e. * Edges that not satisfy the given constraints, * in particular the Bandwidth, TE Metric and Delay. */ if (prune_edge(algo->path, edge, &algo->csts)) continue; /* * Relax constraints and check if we got a shorter * candidate path */ if (relax_constraints(algo, edge) && algo->pdst->weight < cur_cost) { cur_cost = algo->pdst->weight; cpath_copy(optim_path, algo->pdst); optim_path->status = SUCCESS; } } } /* * The priority queue is empty => all the possible (vertex, path) * elements have been explored. The optim_path contains the optimal * path if it exists. Otherwise an empty path with status failed is * returned. */ if (optim_path->status == IN_PROGRESS || listcount(optim_path->edges) == 0) optim_path->status = FAILED; cspf_clean(algo); return optim_path; }