/* Copyright (c) 2008, 2009, 2010, 2011, 2012, 2013, 2014, 2015 Nicira, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include "bridge.h" #include #include #include #include "async-append.h" #include "bfd.h" #include "bitmap.h" #include "cfm.h" #include "connectivity.h" #include "coverage.h" #include "daemon.h" #include "dirs.h" #include "dpif.h" #include "dynamic-string.h" #include "hash.h" #include "hmap.h" #include "hmapx.h" #include "jsonrpc.h" #include "lacp.h" #include "list.h" #include "ovs-lldp.h" #include "mac-learning.h" #include "mcast-snooping.h" #include "meta-flow.h" #include "netdev.h" #include "nx-match.h" #include "ofp-print.h" #include "ofp-util.h" #include "ofpbuf.h" #include "ofproto/bond.h" #include "ofproto/ofproto.h" #include "ovs-numa.h" #include "poll-loop.h" #include "if-notifier.h" #include "seq.h" #include "sha1.h" #include "shash.h" #include "smap.h" #include "socket-util.h" #include "stream.h" #include "stream-ssl.h" #include "sset.h" #include "system-stats.h" #include "timeval.h" #include "util.h" #include "unixctl.h" #include "vlandev.h" #include "lib/vswitch-idl.h" #include "xenserver.h" #include "openvswitch/vlog.h" #include "sflow_api.h" #include "vlan-bitmap.h" #include "packets.h" VLOG_DEFINE_THIS_MODULE(bridge); COVERAGE_DEFINE(bridge_reconfigure); struct iface { /* These members are always valid. * * They are immutable: they never change between iface_create() and * iface_destroy(). */ struct ovs_list port_elem; /* Element in struct port's "ifaces" list. */ struct hmap_node name_node; /* In struct bridge's "iface_by_name" hmap. */ struct hmap_node ofp_port_node; /* In struct bridge's "ifaces" hmap. */ struct port *port; /* Containing port. */ char *name; /* Host network device name. */ struct netdev *netdev; /* Network device. */ ofp_port_t ofp_port; /* OpenFlow port number. */ uint64_t change_seq; /* These members are valid only within bridge_reconfigure(). */ const char *type; /* Usually same as cfg->type. */ const struct ovsrec_interface *cfg; }; struct mirror { struct uuid uuid; /* UUID of this "mirror" record in database. */ struct hmap_node hmap_node; /* In struct bridge's "mirrors" hmap. */ struct bridge *bridge; char *name; const struct ovsrec_mirror *cfg; }; struct port { struct hmap_node hmap_node; /* Element in struct bridge's "ports" hmap. */ struct bridge *bridge; char *name; const struct ovsrec_port *cfg; /* An ordinary bridge port has 1 interface. * A bridge port for bonding has at least 2 interfaces. */ struct ovs_list ifaces; /* List of "struct iface"s. */ }; struct bridge { struct hmap_node node; /* In 'all_bridges'. */ char *name; /* User-specified arbitrary name. */ char *type; /* Datapath type. */ struct eth_addr ea; /* Bridge Ethernet Address. */ struct eth_addr default_ea; /* Default MAC. */ const struct ovsrec_bridge *cfg; /* OpenFlow switch processing. */ struct ofproto *ofproto; /* OpenFlow switch. */ /* Bridge ports. */ struct hmap ports; /* "struct port"s indexed by name. */ struct hmap ifaces; /* "struct iface"s indexed by ofp_port. */ struct hmap iface_by_name; /* "struct iface"s indexed by name. */ /* Port mirroring. */ struct hmap mirrors; /* "struct mirror" indexed by UUID. */ /* Auto Attach */ struct hmap mappings; /* "struct" indexed by UUID */ /* Used during reconfiguration. */ struct shash wanted_ports; /* Synthetic local port if necessary. */ struct ovsrec_port synth_local_port; struct ovsrec_interface synth_local_iface; struct ovsrec_interface *synth_local_ifacep; }; struct aa_mapping { struct hmap_node hmap_node; /* In struct bridge's "mappings" hmap. */ struct bridge *bridge; uint32_t isid; uint16_t vlan; char *br_name; }; /* All bridges, indexed by name. */ static struct hmap all_bridges = HMAP_INITIALIZER(&all_bridges); /* OVSDB IDL used to obtain configuration. */ static struct ovsdb_idl *idl; /* We want to complete daemonization, fully detaching from our parent process, * only after we have completed our initial configuration, committed our state * to the database, and received confirmation back from the database server * that it applied the commit. This allows our parent process to know that, * post-detach, ephemeral fields such as datapath-id and ofport are very likely * to have already been filled in. (It is only "very likely" rather than * certain because there is always a slim possibility that the transaction will * fail or that some other client has added new bridges, ports, etc. while * ovs-vswitchd was configuring using an old configuration.) * * We only need to do this once for our initial configuration at startup, so * 'initial_config_done' tracks whether we've already done it. While we are * waiting for a response to our commit, 'daemonize_txn' tracks the transaction * itself and is otherwise NULL. */ static bool initial_config_done; static struct ovsdb_idl_txn *daemonize_txn; /* Most recently processed IDL sequence number. */ static unsigned int idl_seqno; /* Track changes to port connectivity. */ static uint64_t connectivity_seqno = LLONG_MIN; /* Status update to database. * * Some information in the database must be kept as up-to-date as possible to * allow controllers to respond rapidly to network outages. Those status are * updated via the 'status_txn'. * * We use the global connectivity sequence number to detect the status change. * Also, to prevent the status update from sending too much to the database, * we check the return status of each update transaction and do not start new * update if the previous transaction status is 'TXN_INCOMPLETE'. * * 'statux_txn' is NULL if there is no ongoing status update. * * If the previous database transaction was failed (is not 'TXN_SUCCESS', * 'TXN_UNCHANGED' or 'TXN_INCOMPLETE'), 'status_txn_try_again' is set to true, * which will cause the main thread wake up soon and retry the status update. */ static struct ovsdb_idl_txn *status_txn; static bool status_txn_try_again; /* When the status update transaction returns 'TXN_INCOMPLETE', should register a * timeout in 'STATUS_CHECK_AGAIN_MSEC' to check again. */ #define STATUS_CHECK_AGAIN_MSEC 100 /* Statistics update to database. */ static struct ovsdb_idl_txn *stats_txn; /* Each time this timer expires, the bridge fetches interface and mirror * statistics and pushes them into the database. */ static int stats_timer_interval; static long long int stats_timer = LLONG_MIN; /* Each time this timer expires, the bridge fetches the list of port/VLAN * membership that has been modified by the AA. */ #define AA_REFRESH_INTERVAL (1000) /* In milliseconds. */ static long long int aa_refresh_timer = LLONG_MIN; /* Whenever system interfaces are added, removed or change state, the bridge * will be reconfigured. */ static struct if_notifier *ifnotifier; static bool ifaces_changed = false; static void add_del_bridges(const struct ovsrec_open_vswitch *); static void bridge_run__(void); static void bridge_create(const struct ovsrec_bridge *); static void bridge_destroy(struct bridge *); static struct bridge *bridge_lookup(const char *name); static unixctl_cb_func bridge_unixctl_dump_flows; static unixctl_cb_func bridge_unixctl_reconnect; static size_t bridge_get_controllers(const struct bridge *br, struct ovsrec_controller ***controllersp); static void bridge_collect_wanted_ports(struct bridge *, const unsigned long *splinter_vlans, struct shash *wanted_ports); static void bridge_delete_ofprotos(void); static void bridge_delete_or_reconfigure_ports(struct bridge *); static void bridge_del_ports(struct bridge *, const struct shash *wanted_ports); static void bridge_add_ports(struct bridge *, const struct shash *wanted_ports); static void bridge_configure_datapath_id(struct bridge *); static void bridge_configure_netflow(struct bridge *); static void bridge_configure_forward_bpdu(struct bridge *); static void bridge_configure_mac_table(struct bridge *); static void bridge_configure_mcast_snooping(struct bridge *); static void bridge_configure_sflow(struct bridge *, int *sflow_bridge_number); static void bridge_configure_ipfix(struct bridge *); static void bridge_configure_spanning_tree(struct bridge *); static void bridge_configure_tables(struct bridge *); static void bridge_configure_dp_desc(struct bridge *); static void bridge_configure_aa(struct bridge *); static void bridge_aa_refresh_queued(struct bridge *); static bool bridge_aa_need_refresh(struct bridge *); static void bridge_configure_remotes(struct bridge *, const struct sockaddr_in *managers, size_t n_managers); static void bridge_pick_local_hw_addr(struct bridge *, struct eth_addr *ea, struct iface **hw_addr_iface); static uint64_t bridge_pick_datapath_id(struct bridge *, const struct eth_addr bridge_ea, struct iface *hw_addr_iface); static uint64_t dpid_from_hash(const void *, size_t nbytes); static bool bridge_has_bond_fake_iface(const struct bridge *, const char *name); static bool port_is_bond_fake_iface(const struct port *); static unixctl_cb_func qos_unixctl_show; static struct port *port_create(struct bridge *, const struct ovsrec_port *); static void port_del_ifaces(struct port *); static void port_destroy(struct port *); static struct port *port_lookup(const struct bridge *, const char *name); static void port_configure(struct port *); static struct lacp_settings *port_configure_lacp(struct port *, struct lacp_settings *); static void port_configure_bond(struct port *, struct bond_settings *); static bool port_is_synthetic(const struct port *); static void reconfigure_system_stats(const struct ovsrec_open_vswitch *); static void run_system_stats(void); static void bridge_configure_mirrors(struct bridge *); static struct mirror *mirror_create(struct bridge *, const struct ovsrec_mirror *); static void mirror_destroy(struct mirror *); static bool mirror_configure(struct mirror *); static void mirror_refresh_stats(struct mirror *); static void iface_configure_lacp(struct iface *, struct lacp_slave_settings *); static bool iface_create(struct bridge *, const struct ovsrec_interface *, const struct ovsrec_port *); static bool iface_is_internal(const struct ovsrec_interface *iface, const struct ovsrec_bridge *br); static const char *iface_get_type(const struct ovsrec_interface *, const struct ovsrec_bridge *); static void iface_destroy(struct iface *); static void iface_destroy__(struct iface *); static struct iface *iface_lookup(const struct bridge *, const char *name); static struct iface *iface_find(const char *name); static struct iface *iface_from_ofp_port(const struct bridge *, ofp_port_t ofp_port); static void iface_set_mac(const struct bridge *, const struct port *, struct iface *); static void iface_set_ofport(const struct ovsrec_interface *, ofp_port_t ofport); static void iface_clear_db_record(const struct ovsrec_interface *if_cfg, char *errp); static void iface_configure_qos(struct iface *, const struct ovsrec_qos *); static void iface_configure_cfm(struct iface *); static void iface_refresh_cfm_stats(struct iface *); static void iface_refresh_stats(struct iface *); static void iface_refresh_netdev_status(struct iface *); static void iface_refresh_ofproto_status(struct iface *); static bool iface_is_synthetic(const struct iface *); static ofp_port_t iface_get_requested_ofp_port( const struct ovsrec_interface *); static ofp_port_t iface_pick_ofport(const struct ovsrec_interface *); /* Linux VLAN device support (e.g. "eth0.10" for VLAN 10.) * * This is deprecated. It is only for compatibility with broken device drivers * in old versions of Linux that do not properly support VLANs when VLAN * devices are not used. When broken device drivers are no longer in * widespread use, we will delete these interfaces. */ /* True if VLAN splinters are enabled on any interface, false otherwise.*/ static bool vlan_splinters_enabled_anywhere; static bool vlan_splinters_is_enabled(const struct ovsrec_interface *); static unsigned long int *collect_splinter_vlans( const struct ovsrec_open_vswitch *); static void configure_splinter_port(struct port *); static void add_vlan_splinter_ports(struct bridge *, const unsigned long int *splinter_vlans, struct shash *ports); static void discover_types(const struct ovsrec_open_vswitch *cfg); static void bridge_init_ofproto(const struct ovsrec_open_vswitch *cfg) { struct shash iface_hints; static bool initialized = false; int i; if (initialized) { return; } shash_init(&iface_hints); if (cfg) { for (i = 0; i < cfg->n_bridges; i++) { const struct ovsrec_bridge *br_cfg = cfg->bridges[i]; int j; for (j = 0; j < br_cfg->n_ports; j++) { struct ovsrec_port *port_cfg = br_cfg->ports[j]; int k; for (k = 0; k < port_cfg->n_interfaces; k++) { struct ovsrec_interface *if_cfg = port_cfg->interfaces[k]; struct iface_hint *iface_hint; iface_hint = xmalloc(sizeof *iface_hint); iface_hint->br_name = br_cfg->name; iface_hint->br_type = br_cfg->datapath_type; iface_hint->ofp_port = iface_pick_ofport(if_cfg); shash_add(&iface_hints, if_cfg->name, iface_hint); } } } } ofproto_init(&iface_hints); shash_destroy_free_data(&iface_hints); initialized = true; } static void if_change_cb(void *aux OVS_UNUSED) { ifaces_changed = true; } /* Public functions. */ /* Initializes the bridge module, configuring it to obtain its configuration * from an OVSDB server accessed over 'remote', which should be a string in a * form acceptable to ovsdb_idl_create(). */ void bridge_init(const char *remote) { /* Create connection to database. */ idl = ovsdb_idl_create(remote, &ovsrec_idl_class, true, true); idl_seqno = ovsdb_idl_get_seqno(idl); ovsdb_idl_set_lock(idl, "ovs_vswitchd"); ovsdb_idl_verify_write_only(idl); ovsdb_idl_omit_alert(idl, &ovsrec_open_vswitch_col_cur_cfg); ovsdb_idl_omit_alert(idl, &ovsrec_open_vswitch_col_statistics); ovsdb_idl_omit_alert(idl, &ovsrec_open_vswitch_col_datapath_types); ovsdb_idl_omit_alert(idl, &ovsrec_open_vswitch_col_iface_types); ovsdb_idl_omit(idl, &ovsrec_open_vswitch_col_external_ids); ovsdb_idl_omit(idl, &ovsrec_open_vswitch_col_ovs_version); ovsdb_idl_omit(idl, &ovsrec_open_vswitch_col_db_version); ovsdb_idl_omit(idl, &ovsrec_open_vswitch_col_system_type); ovsdb_idl_omit(idl, &ovsrec_open_vswitch_col_system_version); ovsdb_idl_omit_alert(idl, &ovsrec_bridge_col_datapath_id); ovsdb_idl_omit_alert(idl, &ovsrec_bridge_col_datapath_version); ovsdb_idl_omit_alert(idl, &ovsrec_bridge_col_status); ovsdb_idl_omit_alert(idl, &ovsrec_bridge_col_rstp_status); ovsdb_idl_omit_alert(idl, &ovsrec_bridge_col_stp_enable); ovsdb_idl_omit_alert(idl, &ovsrec_bridge_col_rstp_enable); ovsdb_idl_omit(idl, &ovsrec_bridge_col_external_ids); ovsdb_idl_omit_alert(idl, &ovsrec_port_col_status); ovsdb_idl_omit_alert(idl, &ovsrec_port_col_rstp_status); ovsdb_idl_omit_alert(idl, &ovsrec_port_col_rstp_statistics); ovsdb_idl_omit_alert(idl, &ovsrec_port_col_statistics); ovsdb_idl_omit_alert(idl, &ovsrec_port_col_bond_active_slave); ovsdb_idl_omit(idl, &ovsrec_port_col_external_ids); ovsdb_idl_omit_alert(idl, &ovsrec_port_col_trunks); ovsdb_idl_omit_alert(idl, &ovsrec_port_col_vlan_mode); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_admin_state); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_duplex); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_link_speed); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_link_state); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_link_resets); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_mac_in_use); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_ifindex); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_mtu); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_ofport); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_statistics); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_status); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_cfm_fault); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_cfm_fault_status); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_cfm_remote_mpids); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_cfm_flap_count); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_cfm_health); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_cfm_remote_opstate); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_bfd_status); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_lacp_current); ovsdb_idl_omit_alert(idl, &ovsrec_interface_col_error); ovsdb_idl_omit(idl, &ovsrec_interface_col_external_ids); ovsdb_idl_omit_alert(idl, &ovsrec_controller_col_is_connected); ovsdb_idl_omit_alert(idl, &ovsrec_controller_col_role); ovsdb_idl_omit_alert(idl, &ovsrec_controller_col_status); ovsdb_idl_omit(idl, &ovsrec_controller_col_external_ids); ovsdb_idl_omit(idl, &ovsrec_qos_col_external_ids); ovsdb_idl_omit(idl, &ovsrec_queue_col_external_ids); ovsdb_idl_omit(idl, &ovsrec_mirror_col_external_ids); ovsdb_idl_omit_alert(idl, &ovsrec_mirror_col_statistics); ovsdb_idl_omit(idl, &ovsrec_netflow_col_external_ids); ovsdb_idl_omit(idl, &ovsrec_sflow_col_external_ids); ovsdb_idl_omit(idl, &ovsrec_ipfix_col_external_ids); ovsdb_idl_omit(idl, &ovsrec_flow_sample_collector_set_col_external_ids); ovsdb_idl_omit(idl, &ovsrec_manager_col_external_ids); ovsdb_idl_omit(idl, &ovsrec_manager_col_inactivity_probe); ovsdb_idl_omit(idl, &ovsrec_manager_col_is_connected); ovsdb_idl_omit(idl, &ovsrec_manager_col_max_backoff); ovsdb_idl_omit(idl, &ovsrec_manager_col_status); ovsdb_idl_omit(idl, &ovsrec_ssl_col_external_ids); /* Register unixctl commands. */ unixctl_command_register("qos/show", "interface", 1, 1, qos_unixctl_show, NULL); unixctl_command_register("bridge/dump-flows", "bridge", 1, 1, bridge_unixctl_dump_flows, NULL); unixctl_command_register("bridge/reconnect", "[bridge]", 0, 1, bridge_unixctl_reconnect, NULL); lacp_init(); bond_init(); cfm_init(); bfd_init(); ovs_numa_init(); stp_init(); lldp_init(); rstp_init(); ifnotifier = if_notifier_create(if_change_cb, NULL); } void bridge_exit(void) { struct bridge *br, *next_br; if_notifier_destroy(ifnotifier); HMAP_FOR_EACH_SAFE (br, next_br, node, &all_bridges) { bridge_destroy(br); } ovsdb_idl_destroy(idl); } /* Looks at the list of managers in 'ovs_cfg' and extracts their remote IP * addresses and ports into '*managersp' and '*n_managersp'. The caller is * responsible for freeing '*managersp' (with free()). * * You may be asking yourself "why does ovs-vswitchd care?", because * ovsdb-server is responsible for connecting to the managers, and ovs-vswitchd * should not be and in fact is not directly involved in that. But * ovs-vswitchd needs to make sure that ovsdb-server can reach the managers, so * it has to tell in-band control where the managers are to enable that. * (Thus, only managers connected in-band and with non-loopback addresses * are collected.) */ static void collect_in_band_managers(const struct ovsrec_open_vswitch *ovs_cfg, struct sockaddr_in **managersp, size_t *n_managersp) { struct sockaddr_in *managers = NULL; size_t n_managers = 0; struct sset targets; size_t i; /* Collect all of the potential targets from the "targets" columns of the * rows pointed to by "manager_options", excluding any that are * out-of-band. */ sset_init(&targets); for (i = 0; i < ovs_cfg->n_manager_options; i++) { struct ovsrec_manager *m = ovs_cfg->manager_options[i]; if (m->connection_mode && !strcmp(m->connection_mode, "out-of-band")) { sset_find_and_delete(&targets, m->target); } else { sset_add(&targets, m->target); } } /* Now extract the targets' IP addresses. */ if (!sset_is_empty(&targets)) { const char *target; managers = xmalloc(sset_count(&targets) * sizeof *managers); SSET_FOR_EACH (target, &targets) { union { struct sockaddr_storage ss; struct sockaddr_in in; } sa; /* Ignore loopback. */ if (stream_parse_target_with_default_port(target, OVSDB_PORT, &sa.ss) && sa.ss.ss_family == AF_INET && sa.in.sin_addr.s_addr != htonl(INADDR_LOOPBACK)) { managers[n_managers++] = sa.in; } } } sset_destroy(&targets); *managersp = managers; *n_managersp = n_managers; } static void bridge_reconfigure(const struct ovsrec_open_vswitch *ovs_cfg) { unsigned long int *splinter_vlans; struct sockaddr_in *managers; struct bridge *br, *next; int sflow_bridge_number; size_t n_managers; COVERAGE_INC(bridge_reconfigure); ofproto_set_flow_limit(smap_get_int(&ovs_cfg->other_config, "flow-limit", OFPROTO_FLOW_LIMIT_DEFAULT)); ofproto_set_max_idle(smap_get_int(&ovs_cfg->other_config, "max-idle", OFPROTO_MAX_IDLE_DEFAULT)); ofproto_set_n_dpdk_rxqs(smap_get_int(&ovs_cfg->other_config, "n-dpdk-rxqs", 0)); ofproto_set_cpu_mask(smap_get(&ovs_cfg->other_config, "pmd-cpu-mask")); ofproto_set_threads( smap_get_int(&ovs_cfg->other_config, "n-handler-threads", 0), smap_get_int(&ovs_cfg->other_config, "n-revalidator-threads", 0)); /* Destroy "struct bridge"s, "struct port"s, and "struct iface"s according * to 'ovs_cfg', with only very minimal configuration otherwise. * * This is mostly an update to bridge data structures. Nothing is pushed * down to ofproto or lower layers. */ add_del_bridges(ovs_cfg); splinter_vlans = collect_splinter_vlans(ovs_cfg); HMAP_FOR_EACH (br, node, &all_bridges) { bridge_collect_wanted_ports(br, splinter_vlans, &br->wanted_ports); bridge_del_ports(br, &br->wanted_ports); } free(splinter_vlans); /* Start pushing configuration changes down to the ofproto layer: * * - Delete ofprotos that are no longer configured. * * - Delete ports that are no longer configured. * * - Reconfigure existing ports to their desired configurations, or * delete them if not possible. * * We have to do all the deletions before we can do any additions, because * the ports to be added might require resources that will be freed up by * deletions (they might especially overlap in name). */ bridge_delete_ofprotos(); HMAP_FOR_EACH (br, node, &all_bridges) { if (br->ofproto) { bridge_delete_or_reconfigure_ports(br); } } /* Finish pushing configuration changes to the ofproto layer: * * - Create ofprotos that are missing. * * - Add ports that are missing. */ HMAP_FOR_EACH_SAFE (br, next, node, &all_bridges) { if (!br->ofproto) { int error; error = ofproto_create(br->name, br->type, &br->ofproto); if (error) { VLOG_ERR("failed to create bridge %s: %s", br->name, ovs_strerror(error)); shash_destroy(&br->wanted_ports); bridge_destroy(br); } else { /* Trigger storing datapath version. */ seq_change(connectivity_seq_get()); } } } HMAP_FOR_EACH (br, node, &all_bridges) { bridge_add_ports(br, &br->wanted_ports); shash_destroy(&br->wanted_ports); } reconfigure_system_stats(ovs_cfg); /* Complete the configuration. */ sflow_bridge_number = 0; collect_in_band_managers(ovs_cfg, &managers, &n_managers); HMAP_FOR_EACH (br, node, &all_bridges) { struct port *port; /* We need the datapath ID early to allow LACP ports to use it as the * default system ID. */ bridge_configure_datapath_id(br); HMAP_FOR_EACH (port, hmap_node, &br->ports) { struct iface *iface; port_configure(port); LIST_FOR_EACH (iface, port_elem, &port->ifaces) { iface_set_ofport(iface->cfg, iface->ofp_port); /* Clear eventual previous errors */ ovsrec_interface_set_error(iface->cfg, NULL); iface_configure_cfm(iface); iface_configure_qos(iface, port->cfg->qos); iface_set_mac(br, port, iface); ofproto_port_set_bfd(br->ofproto, iface->ofp_port, &iface->cfg->bfd); ofproto_port_set_lldp(br->ofproto, iface->ofp_port, &iface->cfg->lldp); } } bridge_configure_mirrors(br); bridge_configure_forward_bpdu(br); bridge_configure_mac_table(br); bridge_configure_mcast_snooping(br); bridge_configure_remotes(br, managers, n_managers); bridge_configure_netflow(br); bridge_configure_sflow(br, &sflow_bridge_number); bridge_configure_ipfix(br); bridge_configure_spanning_tree(br); bridge_configure_tables(br); bridge_configure_dp_desc(br); bridge_configure_aa(br); } free(managers); /* The ofproto-dpif provider does some final reconfiguration in its * ->type_run() function. We have to call it before notifying the database * client that reconfiguration is complete, otherwise there is a very * narrow race window in which e.g. ofproto/trace will not recognize the * new configuration (sometimes this causes unit test failures). */ bridge_run__(); } /* Delete ofprotos which aren't configured or have the wrong type. Create * ofprotos which don't exist but need to. */ static void bridge_delete_ofprotos(void) { struct bridge *br; struct sset names; struct sset types; const char *type; /* Delete ofprotos with no bridge or with the wrong type. */ sset_init(&names); sset_init(&types); ofproto_enumerate_types(&types); SSET_FOR_EACH (type, &types) { const char *name; ofproto_enumerate_names(type, &names); SSET_FOR_EACH (name, &names) { br = bridge_lookup(name); if (!br || strcmp(type, br->type)) { ofproto_delete(name, type); } } } sset_destroy(&names); sset_destroy(&types); } static ofp_port_t * add_ofp_port(ofp_port_t port, ofp_port_t *ports, size_t *n, size_t *allocated) { if (*n >= *allocated) { ports = x2nrealloc(ports, allocated, sizeof *ports); } ports[(*n)++] = port; return ports; } static void bridge_delete_or_reconfigure_ports(struct bridge *br) { struct ofproto_port ofproto_port; struct ofproto_port_dump dump; struct sset ofproto_ports; struct port *port, *port_next; /* List of "ofp_port"s to delete. We make a list instead of deleting them * right away because ofproto implementations aren't necessarily able to * iterate through a changing list of ports in an entirely robust way. */ ofp_port_t *del; size_t n, allocated; size_t i; del = NULL; n = allocated = 0; sset_init(&ofproto_ports); /* Main task: Iterate over the ports in 'br->ofproto' and remove the ports * that are not configured in the database. (This commonly happens when * ports have been deleted, e.g. with "ovs-vsctl del-port".) * * Side tasks: Reconfigure the ports that are still in 'br'. Delete ports * that have the wrong OpenFlow port number (and arrange to add them back * with the correct OpenFlow port number). */ OFPROTO_PORT_FOR_EACH (&ofproto_port, &dump, br->ofproto) { ofp_port_t requested_ofp_port; struct iface *iface; sset_add(&ofproto_ports, ofproto_port.name); iface = iface_lookup(br, ofproto_port.name); if (!iface) { /* No such iface is configured, so we should delete this * ofproto_port. * * As a corner case exception, keep the port if it's a bond fake * interface. */ if (bridge_has_bond_fake_iface(br, ofproto_port.name) && !strcmp(ofproto_port.type, "internal")) { continue; } goto delete; } if (strcmp(ofproto_port.type, iface->type) || netdev_set_config(iface->netdev, &iface->cfg->options, NULL)) { /* The interface is the wrong type or can't be configured. * Delete it. */ goto delete; } /* If the requested OpenFlow port for 'iface' changed, and it's not * already the correct port, then we might want to temporarily delete * this interface, so we can add it back again with the new OpenFlow * port number. */ requested_ofp_port = iface_get_requested_ofp_port(iface->cfg); if (iface->ofp_port != OFPP_LOCAL && requested_ofp_port != OFPP_NONE && requested_ofp_port != iface->ofp_port) { ofp_port_t victim_request; struct iface *victim; /* Check for an existing OpenFlow port currently occupying * 'iface''s requested port number. If there isn't one, then * delete this port. Otherwise we need to consider further. */ victim = iface_from_ofp_port(br, requested_ofp_port); if (!victim) { goto delete; } /* 'victim' is a port currently using 'iface''s requested port * number. Unless 'victim' specifically requested that port * number, too, then we can delete both 'iface' and 'victim' * temporarily. (We'll add both of them back again later with new * OpenFlow port numbers.) * * If 'victim' did request port number 'requested_ofp_port', just * like 'iface', then that's a configuration inconsistency that we * can't resolve. We might as well let it keep its current port * number. */ victim_request = iface_get_requested_ofp_port(victim->cfg); if (victim_request != requested_ofp_port) { del = add_ofp_port(victim->ofp_port, del, &n, &allocated); iface_destroy(victim); goto delete; } } /* Keep it. */ continue; delete: iface_destroy(iface); del = add_ofp_port(ofproto_port.ofp_port, del, &n, &allocated); } for (i = 0; i < n; i++) { ofproto_port_del(br->ofproto, del[i]); } free(del); /* Iterate over this module's idea of interfaces in 'br'. Remove any ports * that we didn't see when we iterated through the datapath, i.e. ports * that disappeared underneath use. This is an unusual situation, but it * can happen in some cases: * * - An admin runs a command like "ovs-dpctl del-port" (which is a bad * idea but could happen). * * - The port represented a device that disappeared, e.g. a tuntap * device destroyed via "tunctl -d", a physical Ethernet device * whose module was just unloaded via "rmmod", or a virtual NIC for a * VM whose VM was just terminated. */ HMAP_FOR_EACH_SAFE (port, port_next, hmap_node, &br->ports) { struct iface *iface, *iface_next; LIST_FOR_EACH_SAFE (iface, iface_next, port_elem, &port->ifaces) { if (!sset_contains(&ofproto_ports, iface->name)) { iface_destroy__(iface); } } if (list_is_empty(&port->ifaces)) { port_destroy(port); } } sset_destroy(&ofproto_ports); } static void bridge_add_ports__(struct bridge *br, const struct shash *wanted_ports, bool with_requested_port) { struct shash_node *port_node; SHASH_FOR_EACH (port_node, wanted_ports) { const struct ovsrec_port *port_cfg = port_node->data; size_t i; for (i = 0; i < port_cfg->n_interfaces; i++) { const struct ovsrec_interface *iface_cfg = port_cfg->interfaces[i]; ofp_port_t requested_ofp_port; requested_ofp_port = iface_get_requested_ofp_port(iface_cfg); if ((requested_ofp_port != OFPP_NONE) == with_requested_port) { struct iface *iface = iface_lookup(br, iface_cfg->name); if (!iface) { iface_create(br, iface_cfg, port_cfg); } } } } } static void bridge_add_ports(struct bridge *br, const struct shash *wanted_ports) { /* First add interfaces that request a particular port number. */ bridge_add_ports__(br, wanted_ports, true); /* Then add interfaces that want automatic port number assignment. * We add these afterward to avoid accidentally taking a specifically * requested port number. */ bridge_add_ports__(br, wanted_ports, false); } static void port_configure(struct port *port) { const struct ovsrec_port *cfg = port->cfg; struct bond_settings bond_settings; struct lacp_settings lacp_settings; struct ofproto_bundle_settings s; struct iface *iface; if (cfg->vlan_mode && !strcmp(cfg->vlan_mode, "splinter")) { configure_splinter_port(port); return; } /* Get name. */ s.name = port->name; /* Get slaves. */ s.n_slaves = 0; s.slaves = xmalloc(list_size(&port->ifaces) * sizeof *s.slaves); LIST_FOR_EACH (iface, port_elem, &port->ifaces) { s.slaves[s.n_slaves++] = iface->ofp_port; } /* Get VLAN tag. */ s.vlan = -1; if (cfg->tag && *cfg->tag >= 0 && *cfg->tag <= 4095) { s.vlan = *cfg->tag; } /* Get VLAN trunks. */ s.trunks = NULL; if (cfg->n_trunks) { s.trunks = vlan_bitmap_from_array(cfg->trunks, cfg->n_trunks); } /* Get VLAN mode. */ if (cfg->vlan_mode) { if (!strcmp(cfg->vlan_mode, "access")) { s.vlan_mode = PORT_VLAN_ACCESS; } else if (!strcmp(cfg->vlan_mode, "trunk")) { s.vlan_mode = PORT_VLAN_TRUNK; } else if (!strcmp(cfg->vlan_mode, "native-tagged")) { s.vlan_mode = PORT_VLAN_NATIVE_TAGGED; } else if (!strcmp(cfg->vlan_mode, "native-untagged")) { s.vlan_mode = PORT_VLAN_NATIVE_UNTAGGED; } else { /* This "can't happen" because ovsdb-server should prevent it. */ VLOG_WARN("port %s: unknown VLAN mode %s, falling " "back to trunk mode", port->name, cfg->vlan_mode); s.vlan_mode = PORT_VLAN_TRUNK; } } else { if (s.vlan >= 0) { s.vlan_mode = PORT_VLAN_ACCESS; if (cfg->n_trunks) { VLOG_WARN("port %s: ignoring trunks in favor of implicit vlan", port->name); } } else { s.vlan_mode = PORT_VLAN_TRUNK; } } s.use_priority_tags = smap_get_bool(&cfg->other_config, "priority-tags", false); /* Get LACP settings. */ s.lacp = port_configure_lacp(port, &lacp_settings); if (s.lacp) { size_t i = 0; s.lacp_slaves = xmalloc(s.n_slaves * sizeof *s.lacp_slaves); LIST_FOR_EACH (iface, port_elem, &port->ifaces) { iface_configure_lacp(iface, &s.lacp_slaves[i++]); } } else { s.lacp_slaves = NULL; } /* Get bond settings. */ if (s.n_slaves > 1) { s.bond = &bond_settings; port_configure_bond(port, &bond_settings); } else { s.bond = NULL; LIST_FOR_EACH (iface, port_elem, &port->ifaces) { netdev_set_miimon_interval(iface->netdev, 0); } } /* Register. */ ofproto_bundle_register(port->bridge->ofproto, port, &s); /* Clean up. */ free(s.slaves); free(s.trunks); free(s.lacp_slaves); } /* Pick local port hardware address and datapath ID for 'br'. */ static void bridge_configure_datapath_id(struct bridge *br) { struct eth_addr ea; uint64_t dpid; struct iface *local_iface; struct iface *hw_addr_iface; char *dpid_string; bridge_pick_local_hw_addr(br, &ea, &hw_addr_iface); local_iface = iface_from_ofp_port(br, OFPP_LOCAL); if (local_iface) { int error = netdev_set_etheraddr(local_iface->netdev, ea); if (error) { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5); VLOG_ERR_RL(&rl, "bridge %s: failed to set bridge " "Ethernet address: %s", br->name, ovs_strerror(error)); } } br->ea = ea; dpid = bridge_pick_datapath_id(br, ea, hw_addr_iface); if (dpid != ofproto_get_datapath_id(br->ofproto)) { VLOG_INFO("bridge %s: using datapath ID %016"PRIx64, br->name, dpid); ofproto_set_datapath_id(br->ofproto, dpid); } dpid_string = xasprintf("%016"PRIx64, dpid); ovsrec_bridge_set_datapath_id(br->cfg, dpid_string); free(dpid_string); } /* Returns a bitmap of "enum ofputil_protocol"s that are allowed for use with * 'br'. */ static uint32_t bridge_get_allowed_versions(struct bridge *br) { if (!br->cfg->n_protocols) { return 0; } return ofputil_versions_from_strings(br->cfg->protocols, br->cfg->n_protocols); } /* Set NetFlow configuration on 'br'. */ static void bridge_configure_netflow(struct bridge *br) { struct ovsrec_netflow *cfg = br->cfg->netflow; struct netflow_options opts; if (!cfg) { ofproto_set_netflow(br->ofproto, NULL); return; } memset(&opts, 0, sizeof opts); /* Get default NetFlow configuration from datapath. * Apply overrides from 'cfg'. */ ofproto_get_netflow_ids(br->ofproto, &opts.engine_type, &opts.engine_id); if (cfg->engine_type) { opts.engine_type = *cfg->engine_type; } if (cfg->engine_id) { opts.engine_id = *cfg->engine_id; } /* Configure active timeout interval. */ opts.active_timeout = cfg->active_timeout; if (!opts.active_timeout) { opts.active_timeout = -1; } else if (opts.active_timeout < 0) { VLOG_WARN("bridge %s: active timeout interval set to negative " "value, using default instead (%d seconds)", br->name, NF_ACTIVE_TIMEOUT_DEFAULT); opts.active_timeout = -1; } /* Add engine ID to interface number to disambiguate bridgs? */ opts.add_id_to_iface = cfg->add_id_to_interface; if (opts.add_id_to_iface) { if (opts.engine_id > 0x7f) { VLOG_WARN("bridge %s: NetFlow port mangling may conflict with " "another vswitch, choose an engine id less than 128", br->name); } if (hmap_count(&br->ports) > 508) { VLOG_WARN("bridge %s: NetFlow port mangling will conflict with " "another port when more than 508 ports are used", br->name); } } /* Collectors. */ sset_init(&opts.collectors); sset_add_array(&opts.collectors, cfg->targets, cfg->n_targets); /* Configure. */ if (ofproto_set_netflow(br->ofproto, &opts)) { VLOG_ERR("bridge %s: problem setting netflow collectors", br->name); } sset_destroy(&opts.collectors); } /* Set sFlow configuration on 'br'. */ static void bridge_configure_sflow(struct bridge *br, int *sflow_bridge_number) { const struct ovsrec_sflow *cfg = br->cfg->sflow; struct ovsrec_controller **controllers; struct ofproto_sflow_options oso; size_t n_controllers; size_t i; if (!cfg) { ofproto_set_sflow(br->ofproto, NULL); return; } memset(&oso, 0, sizeof oso); sset_init(&oso.targets); sset_add_array(&oso.targets, cfg->targets, cfg->n_targets); oso.sampling_rate = SFL_DEFAULT_SAMPLING_RATE; if (cfg->sampling) { oso.sampling_rate = *cfg->sampling; } oso.polling_interval = SFL_DEFAULT_POLLING_INTERVAL; if (cfg->polling) { oso.polling_interval = *cfg->polling; } oso.header_len = SFL_DEFAULT_HEADER_SIZE; if (cfg->header) { oso.header_len = *cfg->header; } oso.sub_id = (*sflow_bridge_number)++; oso.agent_device = cfg->agent; oso.control_ip = NULL; n_controllers = bridge_get_controllers(br, &controllers); for (i = 0; i < n_controllers; i++) { if (controllers[i]->local_ip) { oso.control_ip = controllers[i]->local_ip; break; } } ofproto_set_sflow(br->ofproto, &oso); sset_destroy(&oso.targets); } /* Returns whether a IPFIX row is valid. */ static bool ovsrec_ipfix_is_valid(const struct ovsrec_ipfix *ipfix) { return ipfix && ipfix->n_targets > 0; } /* Returns whether a Flow_Sample_Collector_Set row is valid. */ static bool ovsrec_fscs_is_valid(const struct ovsrec_flow_sample_collector_set *fscs, const struct bridge *br) { return ovsrec_ipfix_is_valid(fscs->ipfix) && fscs->bridge == br->cfg; } /* Set IPFIX configuration on 'br'. */ static void bridge_configure_ipfix(struct bridge *br) { const struct ovsrec_ipfix *be_cfg = br->cfg->ipfix; bool valid_be_cfg = ovsrec_ipfix_is_valid(be_cfg); const struct ovsrec_flow_sample_collector_set *fe_cfg; struct ofproto_ipfix_bridge_exporter_options be_opts; struct ofproto_ipfix_flow_exporter_options *fe_opts = NULL; size_t n_fe_opts = 0; OVSREC_FLOW_SAMPLE_COLLECTOR_SET_FOR_EACH(fe_cfg, idl) { if (ovsrec_fscs_is_valid(fe_cfg, br)) { n_fe_opts++; } } if (!valid_be_cfg && n_fe_opts == 0) { ofproto_set_ipfix(br->ofproto, NULL, NULL, 0); return; } if (valid_be_cfg) { memset(&be_opts, 0, sizeof be_opts); sset_init(&be_opts.targets); sset_add_array(&be_opts.targets, be_cfg->targets, be_cfg->n_targets); if (be_cfg->sampling) { be_opts.sampling_rate = *be_cfg->sampling; } else { be_opts.sampling_rate = SFL_DEFAULT_SAMPLING_RATE; } if (be_cfg->obs_domain_id) { be_opts.obs_domain_id = *be_cfg->obs_domain_id; } if (be_cfg->obs_point_id) { be_opts.obs_point_id = *be_cfg->obs_point_id; } if (be_cfg->cache_active_timeout) { be_opts.cache_active_timeout = *be_cfg->cache_active_timeout; } if (be_cfg->cache_max_flows) { be_opts.cache_max_flows = *be_cfg->cache_max_flows; } be_opts.enable_tunnel_sampling = smap_get_bool(&be_cfg->other_config, "enable-tunnel-sampling", true); be_opts.enable_input_sampling = !smap_get_bool(&be_cfg->other_config, "enable-input-sampling", false); be_opts.enable_output_sampling = !smap_get_bool(&be_cfg->other_config, "enable-output-sampling", false); } if (n_fe_opts > 0) { struct ofproto_ipfix_flow_exporter_options *opts; fe_opts = xcalloc(n_fe_opts, sizeof *fe_opts); opts = fe_opts; OVSREC_FLOW_SAMPLE_COLLECTOR_SET_FOR_EACH(fe_cfg, idl) { if (ovsrec_fscs_is_valid(fe_cfg, br)) { opts->collector_set_id = fe_cfg->id; sset_init(&opts->targets); sset_add_array(&opts->targets, fe_cfg->ipfix->targets, fe_cfg->ipfix->n_targets); opts->cache_active_timeout = fe_cfg->ipfix->cache_active_timeout ? *fe_cfg->ipfix->cache_active_timeout : 0; opts->cache_max_flows = fe_cfg->ipfix->cache_max_flows ? *fe_cfg->ipfix->cache_max_flows : 0; opts++; } } } ofproto_set_ipfix(br->ofproto, valid_be_cfg ? &be_opts : NULL, fe_opts, n_fe_opts); if (valid_be_cfg) { sset_destroy(&be_opts.targets); } if (n_fe_opts > 0) { struct ofproto_ipfix_flow_exporter_options *opts = fe_opts; size_t i; for (i = 0; i < n_fe_opts; i++) { sset_destroy(&opts->targets); opts++; } free(fe_opts); } } static void port_configure_stp(const struct ofproto *ofproto, struct port *port, struct ofproto_port_stp_settings *port_s, int *port_num_counter, unsigned long *port_num_bitmap) { const char *config_str; struct iface *iface; if (!smap_get_bool(&port->cfg->other_config, "stp-enable", true)) { port_s->enable = false; return; } else { port_s->enable = true; } /* STP over bonds is not supported. */ if (!list_is_singleton(&port->ifaces)) { VLOG_ERR("port %s: cannot enable STP on bonds, disabling", port->name); port_s->enable = false; return; } iface = CONTAINER_OF(list_front(&port->ifaces), struct iface, port_elem); /* Internal ports shouldn't participate in spanning tree, so * skip them. */ if (!strcmp(iface->type, "internal")) { VLOG_DBG("port %s: disable STP on internal ports", port->name); port_s->enable = false; return; } /* STP on mirror output ports is not supported. */ if (ofproto_is_mirror_output_bundle(ofproto, port)) { VLOG_DBG("port %s: disable STP on mirror ports", port->name); port_s->enable = false; return; } config_str = smap_get(&port->cfg->other_config, "stp-port-num"); if (config_str) { unsigned long int port_num = strtoul(config_str, NULL, 0); int port_idx = port_num - 1; if (port_num < 1 || port_num > STP_MAX_PORTS) { VLOG_ERR("port %s: invalid stp-port-num", port->name); port_s->enable = false; return; } if (bitmap_is_set(port_num_bitmap, port_idx)) { VLOG_ERR("port %s: duplicate stp-port-num %lu, disabling", port->name, port_num); port_s->enable = false; return; } bitmap_set1(port_num_bitmap, port_idx); port_s->port_num = port_idx; } else { if (*port_num_counter >= STP_MAX_PORTS) { VLOG_ERR("port %s: too many STP ports, disabling", port->name); port_s->enable = false; return; } port_s->port_num = (*port_num_counter)++; } config_str = smap_get(&port->cfg->other_config, "stp-path-cost"); if (config_str) { port_s->path_cost = strtoul(config_str, NULL, 10); } else { enum netdev_features current; unsigned int mbps; netdev_get_features(iface->netdev, ¤t, NULL, NULL, NULL); mbps = netdev_features_to_bps(current, 100 * 1000 * 1000) / 1000000; port_s->path_cost = stp_convert_speed_to_cost(mbps); } config_str = smap_get(&port->cfg->other_config, "stp-port-priority"); if (config_str) { port_s->priority = strtoul(config_str, NULL, 0); } else { port_s->priority = STP_DEFAULT_PORT_PRIORITY; } } static void port_configure_rstp(const struct ofproto *ofproto, struct port *port, struct ofproto_port_rstp_settings *port_s, int *port_num_counter) { const char *config_str; struct iface *iface; if (!smap_get_bool(&port->cfg->other_config, "rstp-enable", true)) { port_s->enable = false; return; } else { port_s->enable = true; } /* RSTP over bonds is not supported. */ if (!list_is_singleton(&port->ifaces)) { VLOG_ERR("port %s: cannot enable RSTP on bonds, disabling", port->name); port_s->enable = false; return; } iface = CONTAINER_OF(list_front(&port->ifaces), struct iface, port_elem); /* Internal ports shouldn't participate in spanning tree, so * skip them. */ if (!strcmp(iface->type, "internal")) { VLOG_DBG("port %s: disable RSTP on internal ports", port->name); port_s->enable = false; return; } /* RSTP on mirror output ports is not supported. */ if (ofproto_is_mirror_output_bundle(ofproto, port)) { VLOG_DBG("port %s: disable RSTP on mirror ports", port->name); port_s->enable = false; return; } config_str = smap_get(&port->cfg->other_config, "rstp-port-num"); if (config_str) { unsigned long int port_num = strtoul(config_str, NULL, 0); if (port_num < 1 || port_num > RSTP_MAX_PORTS) { VLOG_ERR("port %s: invalid rstp-port-num", port->name); port_s->enable = false; return; } port_s->port_num = port_num; } else { if (*port_num_counter >= RSTP_MAX_PORTS) { VLOG_ERR("port %s: too many RSTP ports, disabling", port->name); port_s->enable = false; return; } /* If rstp-port-num is not specified, use 0. * rstp_port_set_port_number() will look for the first free one. */ port_s->port_num = 0; } config_str = smap_get(&port->cfg->other_config, "rstp-path-cost"); if (config_str) { port_s->path_cost = strtoul(config_str, NULL, 10); } else { enum netdev_features current; unsigned int mbps; netdev_get_features(iface->netdev, ¤t, NULL, NULL, NULL); mbps = netdev_features_to_bps(current, 100 * 1000 * 1000) / 1000000; port_s->path_cost = rstp_convert_speed_to_cost(mbps); } config_str = smap_get(&port->cfg->other_config, "rstp-port-priority"); if (config_str) { port_s->priority = strtoul(config_str, NULL, 0); } else { port_s->priority = RSTP_DEFAULT_PORT_PRIORITY; } config_str = smap_get(&port->cfg->other_config, "rstp-admin-p2p-mac"); if (config_str) { port_s->admin_p2p_mac_state = strtoul(config_str, NULL, 0); } else { port_s->admin_p2p_mac_state = RSTP_ADMIN_P2P_MAC_FORCE_TRUE; } port_s->admin_port_state = smap_get_bool(&port->cfg->other_config, "rstp-admin-port-state", true); port_s->admin_edge_port = smap_get_bool(&port->cfg->other_config, "rstp-port-admin-edge", false); port_s->auto_edge = smap_get_bool(&port->cfg->other_config, "rstp-port-auto-edge", true); port_s->mcheck = smap_get_bool(&port->cfg->other_config, "rstp-port-mcheck", false); } /* Set spanning tree configuration on 'br'. */ static void bridge_configure_stp(struct bridge *br, bool enable_stp) { if (!enable_stp) { ofproto_set_stp(br->ofproto, NULL); } else { struct ofproto_stp_settings br_s; const char *config_str; struct port *port; int port_num_counter; unsigned long *port_num_bitmap; config_str = smap_get(&br->cfg->other_config, "stp-system-id"); if (config_str) { struct eth_addr ea; if (eth_addr_from_string(config_str, &ea)) { br_s.system_id = eth_addr_to_uint64(ea); } else { br_s.system_id = eth_addr_to_uint64(br->ea); VLOG_ERR("bridge %s: invalid stp-system-id, defaulting " "to "ETH_ADDR_FMT, br->name, ETH_ADDR_ARGS(br->ea)); } } else { br_s.system_id = eth_addr_to_uint64(br->ea); } config_str = smap_get(&br->cfg->other_config, "stp-priority"); if (config_str) { br_s.priority = strtoul(config_str, NULL, 0); } else { br_s.priority = STP_DEFAULT_BRIDGE_PRIORITY; } config_str = smap_get(&br->cfg->other_config, "stp-hello-time"); if (config_str) { br_s.hello_time = strtoul(config_str, NULL, 10) * 1000; } else { br_s.hello_time = STP_DEFAULT_HELLO_TIME; } config_str = smap_get(&br->cfg->other_config, "stp-max-age"); if (config_str) { br_s.max_age = strtoul(config_str, NULL, 10) * 1000; } else { br_s.max_age = STP_DEFAULT_MAX_AGE; } config_str = smap_get(&br->cfg->other_config, "stp-forward-delay"); if (config_str) { br_s.fwd_delay = strtoul(config_str, NULL, 10) * 1000; } else { br_s.fwd_delay = STP_DEFAULT_FWD_DELAY; } /* Configure STP on the bridge. */ if (ofproto_set_stp(br->ofproto, &br_s)) { VLOG_ERR("bridge %s: could not enable STP", br->name); return; } /* Users must either set the port number with the "stp-port-num" * configuration on all ports or none. If manual configuration * is not done, then we allocate them sequentially. */ port_num_counter = 0; port_num_bitmap = bitmap_allocate(STP_MAX_PORTS); HMAP_FOR_EACH (port, hmap_node, &br->ports) { struct ofproto_port_stp_settings port_s; struct iface *iface; port_configure_stp(br->ofproto, port, &port_s, &port_num_counter, port_num_bitmap); /* As bonds are not supported, just apply configuration to * all interfaces. */ LIST_FOR_EACH (iface, port_elem, &port->ifaces) { if (ofproto_port_set_stp(br->ofproto, iface->ofp_port, &port_s)) { VLOG_ERR("port %s: could not enable STP", port->name); continue; } } } if (bitmap_scan(port_num_bitmap, 1, 0, STP_MAX_PORTS) != STP_MAX_PORTS && port_num_counter) { VLOG_ERR("bridge %s: must manually configure all STP port " "IDs or none, disabling", br->name); ofproto_set_stp(br->ofproto, NULL); } bitmap_free(port_num_bitmap); } } static void bridge_configure_rstp(struct bridge *br, bool enable_rstp) { if (!enable_rstp) { ofproto_set_rstp(br->ofproto, NULL); } else { struct ofproto_rstp_settings br_s; const char *config_str; struct port *port; int port_num_counter; config_str = smap_get(&br->cfg->other_config, "rstp-address"); if (config_str) { struct eth_addr ea; if (eth_addr_from_string(config_str, &ea)) { br_s.address = eth_addr_to_uint64(ea); } else { br_s.address = eth_addr_to_uint64(br->ea); VLOG_ERR("bridge %s: invalid rstp-address, defaulting " "to "ETH_ADDR_FMT, br->name, ETH_ADDR_ARGS(br->ea)); } } else { br_s.address = eth_addr_to_uint64(br->ea); } config_str = smap_get(&br->cfg->other_config, "rstp-priority"); if (config_str) { br_s.priority = strtoul(config_str, NULL, 0); } else { br_s.priority = RSTP_DEFAULT_PRIORITY; } config_str = smap_get(&br->cfg->other_config, "rstp-ageing-time"); if (config_str) { br_s.ageing_time = strtoul(config_str, NULL, 0); } else { br_s.ageing_time = RSTP_DEFAULT_AGEING_TIME; } config_str = smap_get(&br->cfg->other_config, "rstp-force-protocol-version"); if (config_str) { br_s.force_protocol_version = strtoul(config_str, NULL, 0); } else { br_s.force_protocol_version = FPV_DEFAULT; } config_str = smap_get(&br->cfg->other_config, "rstp-max-age"); if (config_str) { br_s.bridge_max_age = strtoul(config_str, NULL, 10); } else { br_s.bridge_max_age = RSTP_DEFAULT_BRIDGE_MAX_AGE; } config_str = smap_get(&br->cfg->other_config, "rstp-forward-delay"); if (config_str) { br_s.bridge_forward_delay = strtoul(config_str, NULL, 10); } else { br_s.bridge_forward_delay = RSTP_DEFAULT_BRIDGE_FORWARD_DELAY; } config_str = smap_get(&br->cfg->other_config, "rstp-transmit-hold-count"); if (config_str) { br_s.transmit_hold_count = strtoul(config_str, NULL, 10); } else { br_s.transmit_hold_count = RSTP_DEFAULT_TRANSMIT_HOLD_COUNT; } /* Configure RSTP on the bridge. */ if (ofproto_set_rstp(br->ofproto, &br_s)) { VLOG_ERR("bridge %s: could not enable RSTP", br->name); return; } port_num_counter = 0; HMAP_FOR_EACH (port, hmap_node, &br->ports) { struct ofproto_port_rstp_settings port_s; struct iface *iface; port_configure_rstp(br->ofproto, port, &port_s, &port_num_counter); /* As bonds are not supported, just apply configuration to * all interfaces. */ LIST_FOR_EACH (iface, port_elem, &port->ifaces) { if (ofproto_port_set_rstp(br->ofproto, iface->ofp_port, &port_s)) { VLOG_ERR("port %s: could not enable RSTP", port->name); continue; } } } } } static void bridge_configure_spanning_tree(struct bridge *br) { bool enable_rstp = br->cfg->rstp_enable; bool enable_stp = br->cfg->stp_enable; if (enable_rstp && enable_stp) { VLOG_WARN("%s: RSTP and STP are mutually exclusive but both are " "configured; enabling RSTP", br->name); enable_stp = false; } bridge_configure_stp(br, enable_stp); bridge_configure_rstp(br, enable_rstp); } static bool bridge_has_bond_fake_iface(const struct bridge *br, const char *name) { const struct port *port = port_lookup(br, name); return port && port_is_bond_fake_iface(port); } static bool port_is_bond_fake_iface(const struct port *port) { return port->cfg->bond_fake_iface && !list_is_short(&port->ifaces); } static void add_del_bridges(const struct ovsrec_open_vswitch *cfg) { struct bridge *br, *next; struct shash new_br; size_t i; /* Collect new bridges' names and types. */ shash_init(&new_br); for (i = 0; i < cfg->n_bridges; i++) { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5); const struct ovsrec_bridge *br_cfg = cfg->bridges[i]; if (strchr(br_cfg->name, '/')) { /* Prevent remote ovsdb-server users from accessing arbitrary * directories, e.g. consider a bridge named "../../../etc/". */ VLOG_WARN_RL(&rl, "ignoring bridge with invalid name \"%s\"", br_cfg->name); } else if (!shash_add_once(&new_br, br_cfg->name, br_cfg)) { VLOG_WARN_RL(&rl, "bridge %s specified twice", br_cfg->name); } } /* Get rid of deleted bridges or those whose types have changed. * Update 'cfg' of bridges that still exist. */ HMAP_FOR_EACH_SAFE (br, next, node, &all_bridges) { br->cfg = shash_find_data(&new_br, br->name); if (!br->cfg || strcmp(br->type, ofproto_normalize_type( br->cfg->datapath_type))) { bridge_destroy(br); } } /* Add new bridges. */ for (i = 0; i < cfg->n_bridges; i++) { const struct ovsrec_bridge *br_cfg = cfg->bridges[i]; struct bridge *br = bridge_lookup(br_cfg->name); if (!br) { bridge_create(br_cfg); } } shash_destroy(&new_br); } /* Configures 'netdev' based on the "options" column in 'iface_cfg'. * Returns 0 if successful, otherwise a positive errno value. */ static int iface_set_netdev_config(const struct ovsrec_interface *iface_cfg, struct netdev *netdev, char **errp) { return netdev_set_config(netdev, &iface_cfg->options, errp); } /* Opens a network device for 'if_cfg' and configures it. Adds the network * device to br->ofproto and stores the OpenFlow port number in '*ofp_portp'. * * If successful, returns 0 and stores the network device in '*netdevp'. On * failure, returns a positive errno value and stores NULL in '*netdevp'. */ static int iface_do_create(const struct bridge *br, const struct ovsrec_interface *iface_cfg, const struct ovsrec_port *port_cfg, ofp_port_t *ofp_portp, struct netdev **netdevp, char **errp) { struct netdev *netdev = NULL; int error; if (netdev_is_reserved_name(iface_cfg->name)) { VLOG_WARN("could not create interface %s, name is reserved", iface_cfg->name); error = EINVAL; goto error; } error = netdev_open(iface_cfg->name, iface_get_type(iface_cfg, br->cfg), &netdev); if (error) { VLOG_WARN_BUF(errp, "could not open network device %s (%s)", iface_cfg->name, ovs_strerror(error)); goto error; } error = iface_set_netdev_config(iface_cfg, netdev, errp); if (error) { goto error; } *ofp_portp = iface_pick_ofport(iface_cfg); error = ofproto_port_add(br->ofproto, netdev, ofp_portp); if (error) { goto error; } VLOG_INFO("bridge %s: added interface %s on port %d", br->name, iface_cfg->name, *ofp_portp); if (port_cfg->vlan_mode && !strcmp(port_cfg->vlan_mode, "splinter")) { netdev_turn_flags_on(netdev, NETDEV_UP, NULL); } *netdevp = netdev; return 0; error: *netdevp = NULL; netdev_close(netdev); return error; } /* Creates a new iface on 'br' based on 'if_cfg'. The new iface has OpenFlow * port number 'ofp_port'. If ofp_port is OFPP_NONE, an OpenFlow port is * automatically allocated for the iface. Takes ownership of and * deallocates 'if_cfg'. * * Return true if an iface is successfully created, false otherwise. */ static bool iface_create(struct bridge *br, const struct ovsrec_interface *iface_cfg, const struct ovsrec_port *port_cfg) { struct netdev *netdev; struct iface *iface; ofp_port_t ofp_port; struct port *port; char *errp = NULL; int error; /* Do the bits that can fail up front. */ ovs_assert(!iface_lookup(br, iface_cfg->name)); error = iface_do_create(br, iface_cfg, port_cfg, &ofp_port, &netdev, &errp); if (error) { iface_clear_db_record(iface_cfg, errp); free(errp); return false; } /* Get or create the port structure. */ port = port_lookup(br, port_cfg->name); if (!port) { port = port_create(br, port_cfg); } /* Create the iface structure. */ iface = xzalloc(sizeof *iface); list_push_back(&port->ifaces, &iface->port_elem); hmap_insert(&br->iface_by_name, &iface->name_node, hash_string(iface_cfg->name, 0)); iface->port = port; iface->name = xstrdup(iface_cfg->name); iface->ofp_port = ofp_port; iface->netdev = netdev; iface->type = iface_get_type(iface_cfg, br->cfg); iface->cfg = iface_cfg; hmap_insert(&br->ifaces, &iface->ofp_port_node, hash_ofp_port(ofp_port)); /* Populate initial status in database. */ iface_refresh_stats(iface); iface_refresh_netdev_status(iface); /* Add bond fake iface if necessary. */ if (port_is_bond_fake_iface(port)) { struct ofproto_port ofproto_port; if (ofproto_port_query_by_name(br->ofproto, port->name, &ofproto_port)) { struct netdev *netdev; int error; error = netdev_open(port->name, "internal", &netdev); if (!error) { ofp_port_t fake_ofp_port = OFPP_NONE; ofproto_port_add(br->ofproto, netdev, &fake_ofp_port); netdev_close(netdev); } else { VLOG_WARN("could not open network device %s (%s)", port->name, ovs_strerror(error)); } } else { /* Already exists, nothing to do. */ ofproto_port_destroy(&ofproto_port); } } return true; } /* Set forward BPDU option. */ static void bridge_configure_forward_bpdu(struct bridge *br) { ofproto_set_forward_bpdu(br->ofproto, smap_get_bool(&br->cfg->other_config, "forward-bpdu", false)); } /* Set MAC learning table configuration for 'br'. */ static void bridge_configure_mac_table(struct bridge *br) { const char *idle_time_str; int idle_time; const char *mac_table_size_str; int mac_table_size; idle_time_str = smap_get(&br->cfg->other_config, "mac-aging-time"); idle_time = (idle_time_str && atoi(idle_time_str) ? atoi(idle_time_str) : MAC_ENTRY_DEFAULT_IDLE_TIME); mac_table_size_str = smap_get(&br->cfg->other_config, "mac-table-size"); mac_table_size = (mac_table_size_str && atoi(mac_table_size_str) ? atoi(mac_table_size_str) : MAC_DEFAULT_MAX); ofproto_set_mac_table_config(br->ofproto, idle_time, mac_table_size); } /* Set multicast snooping table configuration for 'br'. */ static void bridge_configure_mcast_snooping(struct bridge *br) { if (!br->cfg->mcast_snooping_enable) { ofproto_set_mcast_snooping(br->ofproto, NULL); } else { struct port *port; struct ofproto_mcast_snooping_settings br_s; const char *idle_time_str; const char *max_entries_str; idle_time_str = smap_get(&br->cfg->other_config, "mcast-snooping-aging-time"); br_s.idle_time = (idle_time_str && atoi(idle_time_str) ? atoi(idle_time_str) : MCAST_ENTRY_DEFAULT_IDLE_TIME); max_entries_str = smap_get(&br->cfg->other_config, "mcast-snooping-table-size"); br_s.max_entries = (max_entries_str && atoi(max_entries_str) ? atoi(max_entries_str) : MCAST_DEFAULT_MAX_ENTRIES); br_s.flood_unreg = !smap_get_bool(&br->cfg->other_config, "mcast-snooping-disable-flood-unregistered", false); /* Configure multicast snooping on the bridge */ if (ofproto_set_mcast_snooping(br->ofproto, &br_s)) { VLOG_ERR("bridge %s: could not enable multicast snooping", br->name); return; } HMAP_FOR_EACH (port, hmap_node, &br->ports) { struct ofproto_mcast_snooping_port_settings port_s; port_s.flood = smap_get_bool(&port->cfg->other_config, "mcast-snooping-flood", false); port_s.flood_reports = smap_get_bool(&port->cfg->other_config, "mcast-snooping-flood-reports", false); if (ofproto_port_set_mcast_snooping(br->ofproto, port, &port_s)) { VLOG_ERR("port %s: could not configure mcast snooping", port->name); } } } } static void find_local_hw_addr(const struct bridge *br, struct eth_addr *ea, const struct port *fake_br, struct iface **hw_addr_iface) { struct hmapx mirror_output_ports; struct port *port; bool found_addr = false; int error; int i; /* Mirror output ports don't participate in picking the local hardware * address. ofproto can't help us find out whether a given port is a * mirror output because we haven't configured mirrors yet, so we need to * accumulate them ourselves. */ hmapx_init(&mirror_output_ports); for (i = 0; i < br->cfg->n_mirrors; i++) { struct ovsrec_mirror *m = br->cfg->mirrors[i]; if (m->output_port) { hmapx_add(&mirror_output_ports, m->output_port); } } /* Otherwise choose the minimum non-local MAC address among all of the * interfaces. */ HMAP_FOR_EACH (port, hmap_node, &br->ports) { struct eth_addr iface_ea; struct iface *candidate; struct iface *iface; /* Mirror output ports don't participate. */ if (hmapx_contains(&mirror_output_ports, port->cfg)) { continue; } /* Choose the MAC address to represent the port. */ iface = NULL; if (port->cfg->mac && eth_addr_from_string(port->cfg->mac, &iface_ea)) { /* Find the interface with this Ethernet address (if any) so that * we can provide the correct devname to the caller. */ LIST_FOR_EACH (candidate, port_elem, &port->ifaces) { struct eth_addr candidate_ea; if (!netdev_get_etheraddr(candidate->netdev, &candidate_ea) && eth_addr_equals(iface_ea, candidate_ea)) { iface = candidate; } } } else { /* Choose the interface whose MAC address will represent the port. * The Linux kernel bonding code always chooses the MAC address of * the first slave added to a bond, and the Fedora networking * scripts always add slaves to a bond in alphabetical order, so * for compatibility we choose the interface with the name that is * first in alphabetical order. */ LIST_FOR_EACH (candidate, port_elem, &port->ifaces) { if (!iface || strcmp(candidate->name, iface->name) < 0) { iface = candidate; } } /* The local port doesn't count (since we're trying to choose its * MAC address anyway). */ if (iface->ofp_port == OFPP_LOCAL) { continue; } /* For fake bridges we only choose from ports with the same tag */ if (fake_br && fake_br->cfg && fake_br->cfg->tag) { if (!port->cfg->tag) { continue; } if (*port->cfg->tag != *fake_br->cfg->tag) { continue; } } /* Grab MAC. */ error = netdev_get_etheraddr(iface->netdev, &iface_ea); if (error) { continue; } } /* Compare against our current choice. */ if (!eth_addr_is_multicast(iface_ea) && !eth_addr_is_local(iface_ea) && !eth_addr_is_reserved(iface_ea) && !eth_addr_is_zero(iface_ea) && (!found_addr || eth_addr_compare_3way(iface_ea, *ea) < 0)) { *ea = iface_ea; *hw_addr_iface = iface; found_addr = true; } } if (!found_addr) { *ea = br->default_ea; *hw_addr_iface = NULL; } hmapx_destroy(&mirror_output_ports); } static void bridge_pick_local_hw_addr(struct bridge *br, struct eth_addr *ea, struct iface **hw_addr_iface) { const char *hwaddr; *hw_addr_iface = NULL; /* Did the user request a particular MAC? */ hwaddr = smap_get(&br->cfg->other_config, "hwaddr"); if (hwaddr && eth_addr_from_string(hwaddr, ea)) { if (eth_addr_is_multicast(*ea)) { VLOG_ERR("bridge %s: cannot set MAC address to multicast " "address "ETH_ADDR_FMT, br->name, ETH_ADDR_ARGS(*ea)); } else if (eth_addr_is_zero(*ea)) { VLOG_ERR("bridge %s: cannot set MAC address to zero", br->name); } else { return; } } /* Find a local hw address */ find_local_hw_addr(br, ea, NULL, hw_addr_iface); } /* Choose and returns the datapath ID for bridge 'br' given that the bridge * Ethernet address is 'bridge_ea'. If 'bridge_ea' is the Ethernet address of * an interface on 'br', then that interface must be passed in as * 'hw_addr_iface'; if 'bridge_ea' was derived some other way, then * 'hw_addr_iface' must be passed in as a null pointer. */ static uint64_t bridge_pick_datapath_id(struct bridge *br, const struct eth_addr bridge_ea, struct iface *hw_addr_iface) { /* * The procedure for choosing a bridge MAC address will, in the most * ordinary case, also choose a unique MAC that we can use as a datapath * ID. In some special cases, though, multiple bridges will end up with * the same MAC address. This is OK for the bridges, but it will confuse * the OpenFlow controller, because each datapath needs a unique datapath * ID. * * Datapath IDs must be unique. It is also very desirable that they be * stable from one run to the next, so that policy set on a datapath * "sticks". */ const char *datapath_id; uint64_t dpid; datapath_id = smap_get(&br->cfg->other_config, "datapath-id"); if (datapath_id && dpid_from_string(datapath_id, &dpid)) { return dpid; } if (!hw_addr_iface) { /* * A purely internal bridge, that is, one that has no non-virtual * network devices on it at all, is difficult because it has no * natural unique identifier at all. * * When the host is a XenServer, we handle this case by hashing the * host's UUID with the name of the bridge. Names of bridges are * persistent across XenServer reboots, although they can be reused if * an internal network is destroyed and then a new one is later * created, so this is fairly effective. * * When the host is not a XenServer, we punt by using a random MAC * address on each run. */ const char *host_uuid = xenserver_get_host_uuid(); if (host_uuid) { char *combined = xasprintf("%s,%s", host_uuid, br->name); dpid = dpid_from_hash(combined, strlen(combined)); free(combined); return dpid; } } return eth_addr_to_uint64(bridge_ea); } static uint64_t dpid_from_hash(const void *data, size_t n) { union { uint8_t bytes[SHA1_DIGEST_SIZE]; struct eth_addr ea; } hash; sha1_bytes(data, n, hash.bytes); eth_addr_mark_random(&hash.ea); return eth_addr_to_uint64(hash.ea); } static void iface_refresh_netdev_status(struct iface *iface) { struct smap smap; enum netdev_features current; enum netdev_flags flags; const char *link_state; struct eth_addr mac; int64_t bps, mtu_64, ifindex64, link_resets; int mtu, error; if (iface_is_synthetic(iface)) { return; } if (iface->change_seq == netdev_get_change_seq(iface->netdev) && !status_txn_try_again) { return; } iface->change_seq = netdev_get_change_seq(iface->netdev); smap_init(&smap); if (!netdev_get_status(iface->netdev, &smap)) { ovsrec_interface_set_status(iface->cfg, &smap); } else { ovsrec_interface_set_status(iface->cfg, NULL); } smap_destroy(&smap); error = netdev_get_flags(iface->netdev, &flags); if (!error) { const char *state = flags & NETDEV_UP ? "up" : "down"; ovsrec_interface_set_admin_state(iface->cfg, state); } else { ovsrec_interface_set_admin_state(iface->cfg, NULL); } link_state = netdev_get_carrier(iface->netdev) ? "up" : "down"; ovsrec_interface_set_link_state(iface->cfg, link_state); link_resets = netdev_get_carrier_resets(iface->netdev); ovsrec_interface_set_link_resets(iface->cfg, &link_resets, 1); error = netdev_get_features(iface->netdev, ¤t, NULL, NULL, NULL); bps = !error ? netdev_features_to_bps(current, 0) : 0; if (bps) { ovsrec_interface_set_duplex(iface->cfg, netdev_features_is_full_duplex(current) ? "full" : "half"); ovsrec_interface_set_link_speed(iface->cfg, &bps, 1); } else { ovsrec_interface_set_duplex(iface->cfg, NULL); ovsrec_interface_set_link_speed(iface->cfg, NULL, 0); } error = netdev_get_mtu(iface->netdev, &mtu); if (!error) { mtu_64 = mtu; ovsrec_interface_set_mtu(iface->cfg, &mtu_64, 1); } else { ovsrec_interface_set_mtu(iface->cfg, NULL, 0); } error = netdev_get_etheraddr(iface->netdev, &mac); if (!error) { char mac_string[ETH_ADDR_STRLEN + 1]; snprintf(mac_string, sizeof mac_string, ETH_ADDR_FMT, ETH_ADDR_ARGS(mac)); ovsrec_interface_set_mac_in_use(iface->cfg, mac_string); } else { ovsrec_interface_set_mac_in_use(iface->cfg, NULL); } /* The netdev may return a negative number (such as -EOPNOTSUPP) * if there is no valid ifindex number. */ ifindex64 = netdev_get_ifindex(iface->netdev); if (ifindex64 < 0) { ifindex64 = 0; } ovsrec_interface_set_ifindex(iface->cfg, &ifindex64, 1); } static void iface_refresh_ofproto_status(struct iface *iface) { int current; if (iface_is_synthetic(iface)) { return; } current = ofproto_port_is_lacp_current(iface->port->bridge->ofproto, iface->ofp_port); if (current >= 0) { bool bl = current; ovsrec_interface_set_lacp_current(iface->cfg, &bl, 1); } else { ovsrec_interface_set_lacp_current(iface->cfg, NULL, 0); } if (ofproto_port_cfm_status_changed(iface->port->bridge->ofproto, iface->ofp_port) || status_txn_try_again) { iface_refresh_cfm_stats(iface); } if (ofproto_port_bfd_status_changed(iface->port->bridge->ofproto, iface->ofp_port) || status_txn_try_again) { struct smap smap; smap_init(&smap); ofproto_port_get_bfd_status(iface->port->bridge->ofproto, iface->ofp_port, &smap); ovsrec_interface_set_bfd_status(iface->cfg, &smap); smap_destroy(&smap); } } /* Writes 'iface''s CFM statistics to the database. 'iface' must not be * synthetic. */ static void iface_refresh_cfm_stats(struct iface *iface) { const struct ovsrec_interface *cfg = iface->cfg; struct cfm_status status; int error; error = ofproto_port_get_cfm_status(iface->port->bridge->ofproto, iface->ofp_port, &status); if (error > 0) { ovsrec_interface_set_cfm_fault(cfg, NULL, 0); ovsrec_interface_set_cfm_fault_status(cfg, NULL, 0); ovsrec_interface_set_cfm_remote_opstate(cfg, NULL); ovsrec_interface_set_cfm_flap_count(cfg, NULL, 0); ovsrec_interface_set_cfm_health(cfg, NULL, 0); ovsrec_interface_set_cfm_remote_mpids(cfg, NULL, 0); } else { const char *reasons[CFM_FAULT_N_REASONS]; int64_t cfm_health = status.health; int64_t cfm_flap_count = status.flap_count; bool faulted = status.faults != 0; size_t i, j; ovsrec_interface_set_cfm_fault(cfg, &faulted, 1); j = 0; for (i = 0; i < CFM_FAULT_N_REASONS; i++) { int reason = 1 << i; if (status.faults & reason) { reasons[j++] = cfm_fault_reason_to_str(reason); } } ovsrec_interface_set_cfm_fault_status(cfg, reasons, j); ovsrec_interface_set_cfm_flap_count(cfg, &cfm_flap_count, 1); if (status.remote_opstate >= 0) { const char *remote_opstate = status.remote_opstate ? "up" : "down"; ovsrec_interface_set_cfm_remote_opstate(cfg, remote_opstate); } else { ovsrec_interface_set_cfm_remote_opstate(cfg, NULL); } ovsrec_interface_set_cfm_remote_mpids(cfg, (const int64_t *)status.rmps, status.n_rmps); if (cfm_health >= 0) { ovsrec_interface_set_cfm_health(cfg, &cfm_health, 1); } else { ovsrec_interface_set_cfm_health(cfg, NULL, 0); } free(status.rmps); } } static void iface_refresh_stats(struct iface *iface) { #define IFACE_STATS \ IFACE_STAT(rx_packets, "rx_packets") \ IFACE_STAT(tx_packets, "tx_packets") \ IFACE_STAT(rx_bytes, "rx_bytes") \ IFACE_STAT(tx_bytes, "tx_bytes") \ IFACE_STAT(rx_dropped, "rx_dropped") \ IFACE_STAT(tx_dropped, "tx_dropped") \ IFACE_STAT(rx_errors, "rx_errors") \ IFACE_STAT(tx_errors, "tx_errors") \ IFACE_STAT(rx_frame_errors, "rx_frame_err") \ IFACE_STAT(rx_over_errors, "rx_over_err") \ IFACE_STAT(rx_crc_errors, "rx_crc_err") \ IFACE_STAT(collisions, "collisions") #define IFACE_STAT(MEMBER, NAME) + 1 enum { N_IFACE_STATS = IFACE_STATS }; #undef IFACE_STAT int64_t values[N_IFACE_STATS]; const char *keys[N_IFACE_STATS]; int n; struct netdev_stats stats; if (iface_is_synthetic(iface)) { return; } /* Intentionally ignore return value, since errors will set 'stats' to * all-1s, and we will deal with that correctly below. */ netdev_get_stats(iface->netdev, &stats); /* Copy statistics into keys[] and values[]. */ n = 0; #define IFACE_STAT(MEMBER, NAME) \ if (stats.MEMBER != UINT64_MAX) { \ keys[n] = NAME; \ values[n] = stats.MEMBER; \ n++; \ } IFACE_STATS; #undef IFACE_STAT ovs_assert(n <= N_IFACE_STATS); ovsrec_interface_set_statistics(iface->cfg, keys, values, n); #undef IFACE_STATS } static void br_refresh_datapath_info(struct bridge *br) { const char *version; version = (br->ofproto && br->ofproto->ofproto_class->get_datapath_version ? br->ofproto->ofproto_class->get_datapath_version(br->ofproto) : NULL); ovsrec_bridge_set_datapath_version(br->cfg, version ? version : ""); } static void br_refresh_stp_status(struct bridge *br) { struct smap smap = SMAP_INITIALIZER(&smap); struct ofproto *ofproto = br->ofproto; struct ofproto_stp_status status; if (ofproto_get_stp_status(ofproto, &status)) { return; } if (!status.enabled) { ovsrec_bridge_set_status(br->cfg, NULL); return; } smap_add_format(&smap, "stp_bridge_id", STP_ID_FMT, STP_ID_ARGS(status.bridge_id)); smap_add_format(&smap, "stp_designated_root", STP_ID_FMT, STP_ID_ARGS(status.designated_root)); smap_add_format(&smap, "stp_root_path_cost", "%d", status.root_path_cost); ovsrec_bridge_set_status(br->cfg, &smap); smap_destroy(&smap); } static void port_refresh_stp_status(struct port *port) { struct ofproto *ofproto = port->bridge->ofproto; struct iface *iface; struct ofproto_port_stp_status status; struct smap smap; if (port_is_synthetic(port)) { return; } /* STP doesn't currently support bonds. */ if (!list_is_singleton(&port->ifaces)) { ovsrec_port_set_status(port->cfg, NULL); return; } iface = CONTAINER_OF(list_front(&port->ifaces), struct iface, port_elem); if (ofproto_port_get_stp_status(ofproto, iface->ofp_port, &status)) { return; } if (!status.enabled) { ovsrec_port_set_status(port->cfg, NULL); return; } /* Set Status column. */ smap_init(&smap); smap_add_format(&smap, "stp_port_id", STP_PORT_ID_FMT, status.port_id); smap_add(&smap, "stp_state", stp_state_name(status.state)); smap_add_format(&smap, "stp_sec_in_state", "%u", status.sec_in_state); smap_add(&smap, "stp_role", stp_role_name(status.role)); ovsrec_port_set_status(port->cfg, &smap); smap_destroy(&smap); } static void port_refresh_stp_stats(struct port *port) { struct ofproto *ofproto = port->bridge->ofproto; struct iface *iface; struct ofproto_port_stp_stats stats; const char *keys[3]; int64_t int_values[3]; if (port_is_synthetic(port)) { return; } /* STP doesn't currently support bonds. */ if (!list_is_singleton(&port->ifaces)) { return; } iface = CONTAINER_OF(list_front(&port->ifaces), struct iface, port_elem); if (ofproto_port_get_stp_stats(ofproto, iface->ofp_port, &stats)) { return; } if (!stats.enabled) { ovsrec_port_set_statistics(port->cfg, NULL, NULL, 0); return; } /* Set Statistics column. */ keys[0] = "stp_tx_count"; int_values[0] = stats.tx_count; keys[1] = "stp_rx_count"; int_values[1] = stats.rx_count; keys[2] = "stp_error_count"; int_values[2] = stats.error_count; ovsrec_port_set_statistics(port->cfg, keys, int_values, ARRAY_SIZE(int_values)); } static void br_refresh_rstp_status(struct bridge *br) { struct smap smap = SMAP_INITIALIZER(&smap); struct ofproto *ofproto = br->ofproto; struct ofproto_rstp_status status; if (ofproto_get_rstp_status(ofproto, &status)) { return; } if (!status.enabled) { ovsrec_bridge_set_rstp_status(br->cfg, NULL); return; } smap_add_format(&smap, "rstp_bridge_id", RSTP_ID_FMT, RSTP_ID_ARGS(status.bridge_id)); smap_add_format(&smap, "rstp_root_path_cost", "%"PRIu32, status.root_path_cost); smap_add_format(&smap, "rstp_root_id", RSTP_ID_FMT, RSTP_ID_ARGS(status.root_id)); smap_add_format(&smap, "rstp_designated_id", RSTP_ID_FMT, RSTP_ID_ARGS(status.designated_id)); smap_add_format(&smap, "rstp_designated_port_id", RSTP_PORT_ID_FMT, status.designated_port_id); smap_add_format(&smap, "rstp_bridge_port_id", RSTP_PORT_ID_FMT, status.bridge_port_id); ovsrec_bridge_set_rstp_status(br->cfg, &smap); smap_destroy(&smap); } static void port_refresh_rstp_status(struct port *port) { struct ofproto *ofproto = port->bridge->ofproto; struct iface *iface; struct ofproto_port_rstp_status status; const char *keys[4]; int64_t int_values[4]; struct smap smap; if (port_is_synthetic(port)) { return; } /* RSTP doesn't currently support bonds. */ if (!list_is_singleton(&port->ifaces)) { ovsrec_port_set_rstp_status(port->cfg, NULL); return; } iface = CONTAINER_OF(list_front(&port->ifaces), struct iface, port_elem); if (ofproto_port_get_rstp_status(ofproto, iface->ofp_port, &status)) { return; } if (!status.enabled) { ovsrec_port_set_rstp_status(port->cfg, NULL); ovsrec_port_set_rstp_statistics(port->cfg, NULL, NULL, 0); return; } /* Set Status column. */ smap_init(&smap); smap_add_format(&smap, "rstp_port_id", RSTP_PORT_ID_FMT, status.port_id); smap_add_format(&smap, "rstp_port_role", "%s", rstp_port_role_name(status.role)); smap_add_format(&smap, "rstp_port_state", "%s", rstp_state_name(status.state)); smap_add_format(&smap, "rstp_designated_bridge_id", RSTP_ID_FMT, RSTP_ID_ARGS(status.designated_bridge_id)); smap_add_format(&smap, "rstp_designated_port_id", RSTP_PORT_ID_FMT, status.designated_port_id); smap_add_format(&smap, "rstp_designated_path_cost", "%"PRIu32, status.designated_path_cost); ovsrec_port_set_rstp_status(port->cfg, &smap); smap_destroy(&smap); /* Set Statistics column. */ keys[0] = "rstp_tx_count"; int_values[0] = status.tx_count; keys[1] = "rstp_rx_count"; int_values[1] = status.rx_count; keys[2] = "rstp_uptime"; int_values[2] = status.uptime; keys[3] = "rstp_error_count"; int_values[3] = status.error_count; ovsrec_port_set_rstp_statistics(port->cfg, keys, int_values, ARRAY_SIZE(int_values)); } static void port_refresh_bond_status(struct port *port, bool force_update) { struct eth_addr mac; /* Return if port is not a bond */ if (list_is_singleton(&port->ifaces)) { return; } if (bond_get_changed_active_slave(port->name, &mac, force_update)) { struct ds mac_s; ds_init(&mac_s); ds_put_format(&mac_s, ETH_ADDR_FMT, ETH_ADDR_ARGS(mac)); ovsrec_port_set_bond_active_slave(port->cfg, ds_cstr(&mac_s)); ds_destroy(&mac_s); } } static bool enable_system_stats(const struct ovsrec_open_vswitch *cfg) { return smap_get_bool(&cfg->other_config, "enable-statistics", false); } static void reconfigure_system_stats(const struct ovsrec_open_vswitch *cfg) { bool enable = enable_system_stats(cfg); system_stats_enable(enable); if (!enable) { ovsrec_open_vswitch_set_statistics(cfg, NULL); } } static void run_system_stats(void) { const struct ovsrec_open_vswitch *cfg = ovsrec_open_vswitch_first(idl); struct smap *stats; stats = system_stats_run(); if (stats && cfg) { struct ovsdb_idl_txn *txn; struct ovsdb_datum datum; txn = ovsdb_idl_txn_create(idl); ovsdb_datum_from_smap(&datum, stats); ovsdb_idl_txn_write(&cfg->header_, &ovsrec_open_vswitch_col_statistics, &datum); ovsdb_idl_txn_commit(txn); ovsdb_idl_txn_destroy(txn); free(stats); } } static const char * ofp12_controller_role_to_str(enum ofp12_controller_role role) { switch (role) { case OFPCR12_ROLE_EQUAL: return "other"; case OFPCR12_ROLE_MASTER: return "master"; case OFPCR12_ROLE_SLAVE: return "slave"; case OFPCR12_ROLE_NOCHANGE: default: return "*** INVALID ROLE ***"; } } static void refresh_controller_status(void) { struct bridge *br; struct shash info; const struct ovsrec_controller *cfg; shash_init(&info); /* Accumulate status for controllers on all bridges. */ HMAP_FOR_EACH (br, node, &all_bridges) { ofproto_get_ofproto_controller_info(br->ofproto, &info); } /* Update each controller in the database with current status. */ OVSREC_CONTROLLER_FOR_EACH(cfg, idl) { struct ofproto_controller_info *cinfo = shash_find_data(&info, cfg->target); if (cinfo) { ovsrec_controller_set_is_connected(cfg, cinfo->is_connected); ovsrec_controller_set_role(cfg, ofp12_controller_role_to_str( cinfo->role)); ovsrec_controller_set_status(cfg, &cinfo->pairs); } else { ovsrec_controller_set_is_connected(cfg, false); ovsrec_controller_set_role(cfg, NULL); ovsrec_controller_set_status(cfg, NULL); } } ofproto_free_ofproto_controller_info(&info); } /* Update interface and mirror statistics if necessary. */ static void run_stats_update(void) { const struct ovsrec_open_vswitch *cfg = ovsrec_open_vswitch_first(idl); int stats_interval; if (!cfg) { return; } /* Statistics update interval should always be greater than or equal to * 5000 ms. */ stats_interval = MAX(smap_get_int(&cfg->other_config, "stats-update-interval", 5000), 5000); if (stats_timer_interval != stats_interval) { stats_timer_interval = stats_interval; stats_timer = LLONG_MIN; } if (time_msec() >= stats_timer) { enum ovsdb_idl_txn_status status; /* Rate limit the update. Do not start a new update if the * previous one is not done. */ if (!stats_txn) { struct bridge *br; stats_txn = ovsdb_idl_txn_create(idl); HMAP_FOR_EACH (br, node, &all_bridges) { struct port *port; struct mirror *m; HMAP_FOR_EACH (port, hmap_node, &br->ports) { struct iface *iface; LIST_FOR_EACH (iface, port_elem, &port->ifaces) { iface_refresh_stats(iface); } port_refresh_stp_stats(port); } HMAP_FOR_EACH (m, hmap_node, &br->mirrors) { mirror_refresh_stats(m); } } refresh_controller_status(); } status = ovsdb_idl_txn_commit(stats_txn); if (status != TXN_INCOMPLETE) { stats_timer = time_msec() + stats_timer_interval; ovsdb_idl_txn_destroy(stats_txn); stats_txn = NULL; } } } static void stats_update_wait(void) { /* If the 'stats_txn' is non-null (transaction incomplete), waits for the * transaction to complete. Otherwise, waits for the 'stats_timer'. */ if (stats_txn) { ovsdb_idl_txn_wait(stats_txn); } else { poll_timer_wait_until(stats_timer); } } /* Update bridge/port/interface status if necessary. */ static void run_status_update(void) { if (!status_txn) { uint64_t seq; /* Rate limit the update. Do not start a new update if the * previous one is not done. */ seq = seq_read(connectivity_seq_get()); if (seq != connectivity_seqno || status_txn_try_again) { struct bridge *br; connectivity_seqno = seq; status_txn = ovsdb_idl_txn_create(idl); HMAP_FOR_EACH (br, node, &all_bridges) { struct port *port; br_refresh_stp_status(br); br_refresh_rstp_status(br); br_refresh_datapath_info(br); HMAP_FOR_EACH (port, hmap_node, &br->ports) { struct iface *iface; port_refresh_stp_status(port); port_refresh_rstp_status(port); port_refresh_bond_status(port, status_txn_try_again); LIST_FOR_EACH (iface, port_elem, &port->ifaces) { iface_refresh_netdev_status(iface); iface_refresh_ofproto_status(iface); } } } } } /* Commit the transaction and get the status. If the transaction finishes, * then destroy the transaction. Otherwise, keep it so that we can check * progress the next time that this function is called. */ if (status_txn) { enum ovsdb_idl_txn_status status; status = ovsdb_idl_txn_commit(status_txn); if (status != TXN_INCOMPLETE) { ovsdb_idl_txn_destroy(status_txn); status_txn = NULL; /* Sets the 'status_txn_try_again' if the transaction fails. */ if (status == TXN_SUCCESS || status == TXN_UNCHANGED) { status_txn_try_again = false; } else { status_txn_try_again = true; } } } /* Refresh AA port status if necessary. */ if (time_msec() >= aa_refresh_timer) { struct bridge *br; HMAP_FOR_EACH (br, node, &all_bridges) { if (bridge_aa_need_refresh(br)) { struct ovsdb_idl_txn *txn; txn = ovsdb_idl_txn_create(idl); bridge_aa_refresh_queued(br); ovsdb_idl_txn_commit(txn); ovsdb_idl_txn_destroy(txn); } } aa_refresh_timer = time_msec() + AA_REFRESH_INTERVAL; } } static void status_update_wait(void) { /* If the 'status_txn' is non-null (transaction incomplete), waits for the * transaction to complete. If the status update to database needs to be * run again (transaction fails), registers a timeout in * 'STATUS_CHECK_AGAIN_MSEC'. Otherwise, waits on the global connectivity * sequence number. */ if (status_txn) { ovsdb_idl_txn_wait(status_txn); } else if (status_txn_try_again) { poll_timer_wait_until(time_msec() + STATUS_CHECK_AGAIN_MSEC); } else { seq_wait(connectivity_seq_get(), connectivity_seqno); } } static void bridge_run__(void) { struct bridge *br; struct sset types; const char *type; /* Let each datapath type do the work that it needs to do. */ sset_init(&types); ofproto_enumerate_types(&types); SSET_FOR_EACH (type, &types) { ofproto_type_run(type); } sset_destroy(&types); /* Let each bridge do the work that it needs to do. */ HMAP_FOR_EACH (br, node, &all_bridges) { ofproto_run(br->ofproto); } } void bridge_run(void) { static struct ovsrec_open_vswitch null_cfg; const struct ovsrec_open_vswitch *cfg; bool vlan_splinters_changed; ovsrec_open_vswitch_init(&null_cfg); ovsdb_idl_run(idl); if_notifier_run(); if (ovsdb_idl_is_lock_contended(idl)) { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1); struct bridge *br, *next_br; VLOG_ERR_RL(&rl, "another ovs-vswitchd process is running, " "disabling this process (pid %ld) until it goes away", (long int) getpid()); HMAP_FOR_EACH_SAFE (br, next_br, node, &all_bridges) { bridge_destroy(br); } /* Since we will not be running system_stats_run() in this process * with the current situation of multiple ovs-vswitchd daemons, * disable system stats collection. */ system_stats_enable(false); return; } else if (!ovsdb_idl_has_lock(idl) || !ovsdb_idl_has_ever_connected(idl)) { /* Returns if not holding the lock or not done retrieving db * contents. */ return; } cfg = ovsrec_open_vswitch_first(idl); /* Initialize the ofproto library. This only needs to run once, but * it must be done after the configuration is set. If the * initialization has already occurred, bridge_init_ofproto() * returns immediately. */ bridge_init_ofproto(cfg); /* Once the value of flow-restore-wait is false, we no longer should * check its value from the database. */ if (cfg && ofproto_get_flow_restore_wait()) { ofproto_set_flow_restore_wait(smap_get_bool(&cfg->other_config, "flow-restore-wait", false)); } bridge_run__(); /* Re-configure SSL. We do this on every trip through the main loop, * instead of just when the database changes, because the contents of the * key and certificate files can change without the database changing. * * We do this before bridge_reconfigure() because that function might * initiate SSL connections and thus requires SSL to be configured. */ if (cfg && cfg->ssl) { const struct ovsrec_ssl *ssl = cfg->ssl; stream_ssl_set_key_and_cert(ssl->private_key, ssl->certificate); stream_ssl_set_ca_cert_file(ssl->ca_cert, ssl->bootstrap_ca_cert); } /* If VLAN splinters are in use, then we need to reconfigure if VLAN * usage has changed. */ vlan_splinters_changed = false; if (vlan_splinters_enabled_anywhere) { struct bridge *br; HMAP_FOR_EACH (br, node, &all_bridges) { if (ofproto_has_vlan_usage_changed(br->ofproto)) { vlan_splinters_changed = true; break; } } } if (ovsdb_idl_get_seqno(idl) != idl_seqno || vlan_splinters_changed || ifaces_changed) { struct ovsdb_idl_txn *txn; ifaces_changed = false; idl_seqno = ovsdb_idl_get_seqno(idl); txn = ovsdb_idl_txn_create(idl); bridge_reconfigure(cfg ? cfg : &null_cfg); if (cfg) { ovsrec_open_vswitch_set_cur_cfg(cfg, cfg->next_cfg); discover_types(cfg); } /* If we are completing our initial configuration for this run * of ovs-vswitchd, then keep the transaction around to monitor * it for completion. */ if (initial_config_done) { /* Always sets the 'status_txn_try_again' to check again, * in case that this transaction fails. */ status_txn_try_again = true; ovsdb_idl_txn_commit(txn); ovsdb_idl_txn_destroy(txn); } else { initial_config_done = true; daemonize_txn = txn; } } if (daemonize_txn) { enum ovsdb_idl_txn_status status = ovsdb_idl_txn_commit(daemonize_txn); if (status != TXN_INCOMPLETE) { ovsdb_idl_txn_destroy(daemonize_txn); daemonize_txn = NULL; /* ovs-vswitchd has completed initialization, so allow the * process that forked us to exit successfully. */ daemonize_complete(); vlog_enable_async(); VLOG_INFO_ONCE("%s (Open vSwitch) %s", program_name, VERSION); } } run_stats_update(); run_status_update(); run_system_stats(); } void bridge_wait(void) { struct sset types; const char *type; ovsdb_idl_wait(idl); if (daemonize_txn) { ovsdb_idl_txn_wait(daemonize_txn); } if_notifier_wait(); if (ifaces_changed) { poll_immediate_wake(); } sset_init(&types); ofproto_enumerate_types(&types); SSET_FOR_EACH (type, &types) { ofproto_type_wait(type); } sset_destroy(&types); if (!hmap_is_empty(&all_bridges)) { struct bridge *br; HMAP_FOR_EACH (br, node, &all_bridges) { ofproto_wait(br->ofproto); } stats_update_wait(); status_update_wait(); } system_stats_wait(); } /* Adds some memory usage statistics for bridges into 'usage', for use with * memory_report(). */ void bridge_get_memory_usage(struct simap *usage) { struct bridge *br; struct sset types; const char *type; sset_init(&types); ofproto_enumerate_types(&types); SSET_FOR_EACH (type, &types) { ofproto_type_get_memory_usage(type, usage); } sset_destroy(&types); HMAP_FOR_EACH (br, node, &all_bridges) { ofproto_get_memory_usage(br->ofproto, usage); } } /* QoS unixctl user interface functions. */ struct qos_unixctl_show_cbdata { struct ds *ds; struct iface *iface; }; static void qos_unixctl_show_queue(unsigned int queue_id, const struct smap *details, struct iface *iface, struct ds *ds) { struct netdev_queue_stats stats; struct smap_node *node; int error; ds_put_cstr(ds, "\n"); if (queue_id) { ds_put_format(ds, "Queue %u:\n", queue_id); } else { ds_put_cstr(ds, "Default:\n"); } SMAP_FOR_EACH (node, details) { ds_put_format(ds, "\t%s: %s\n", node->key, node->value); } error = netdev_get_queue_stats(iface->netdev, queue_id, &stats); if (!error) { if (stats.tx_packets != UINT64_MAX) { ds_put_format(ds, "\ttx_packets: %"PRIu64"\n", stats.tx_packets); } if (stats.tx_bytes != UINT64_MAX) { ds_put_format(ds, "\ttx_bytes: %"PRIu64"\n", stats.tx_bytes); } if (stats.tx_errors != UINT64_MAX) { ds_put_format(ds, "\ttx_errors: %"PRIu64"\n", stats.tx_errors); } } else { ds_put_format(ds, "\tFailed to get statistics for queue %u: %s", queue_id, ovs_strerror(error)); } } static void qos_unixctl_show(struct unixctl_conn *conn, int argc OVS_UNUSED, const char *argv[], void *aux OVS_UNUSED) { struct ds ds = DS_EMPTY_INITIALIZER; struct smap smap = SMAP_INITIALIZER(&smap); struct iface *iface; const char *type; struct smap_node *node; iface = iface_find(argv[1]); if (!iface) { unixctl_command_reply_error(conn, "no such interface"); return; } netdev_get_qos(iface->netdev, &type, &smap); if (*type != '\0') { struct netdev_queue_dump dump; struct smap details; unsigned int queue_id; ds_put_format(&ds, "QoS: %s %s\n", iface->name, type); SMAP_FOR_EACH (node, &smap) { ds_put_format(&ds, "%s: %s\n", node->key, node->value); } smap_init(&details); NETDEV_QUEUE_FOR_EACH (&queue_id, &details, &dump, iface->netdev) { qos_unixctl_show_queue(queue_id, &details, iface, &ds); } smap_destroy(&details); unixctl_command_reply(conn, ds_cstr(&ds)); } else { ds_put_format(&ds, "QoS not configured on %s\n", iface->name); unixctl_command_reply_error(conn, ds_cstr(&ds)); } smap_destroy(&smap); ds_destroy(&ds); } /* Bridge reconfiguration functions. */ static void bridge_create(const struct ovsrec_bridge *br_cfg) { struct bridge *br; ovs_assert(!bridge_lookup(br_cfg->name)); br = xzalloc(sizeof *br); br->name = xstrdup(br_cfg->name); br->type = xstrdup(ofproto_normalize_type(br_cfg->datapath_type)); br->cfg = br_cfg; /* Derive the default Ethernet address from the bridge's UUID. This should * be unique and it will be stable between ovs-vswitchd runs. */ memcpy(&br->default_ea, &br_cfg->header_.uuid, ETH_ADDR_LEN); eth_addr_mark_random(&br->default_ea); hmap_init(&br->ports); hmap_init(&br->ifaces); hmap_init(&br->iface_by_name); hmap_init(&br->mirrors); hmap_init(&br->mappings); hmap_insert(&all_bridges, &br->node, hash_string(br->name, 0)); } static void bridge_destroy(struct bridge *br) { if (br) { struct mirror *mirror, *next_mirror; struct port *port, *next_port; HMAP_FOR_EACH_SAFE (port, next_port, hmap_node, &br->ports) { port_destroy(port); } HMAP_FOR_EACH_SAFE (mirror, next_mirror, hmap_node, &br->mirrors) { mirror_destroy(mirror); } hmap_remove(&all_bridges, &br->node); ofproto_destroy(br->ofproto); hmap_destroy(&br->ifaces); hmap_destroy(&br->ports); hmap_destroy(&br->iface_by_name); hmap_destroy(&br->mirrors); hmap_destroy(&br->mappings); free(br->name); free(br->type); free(br); } } static struct bridge * bridge_lookup(const char *name) { struct bridge *br; HMAP_FOR_EACH_WITH_HASH (br, node, hash_string(name, 0), &all_bridges) { if (!strcmp(br->name, name)) { return br; } } return NULL; } /* Handle requests for a listing of all flows known by the OpenFlow * stack, including those normally hidden. */ static void bridge_unixctl_dump_flows(struct unixctl_conn *conn, int argc OVS_UNUSED, const char *argv[], void *aux OVS_UNUSED) { struct bridge *br; struct ds results; br = bridge_lookup(argv[1]); if (!br) { unixctl_command_reply_error(conn, "Unknown bridge"); return; } ds_init(&results); ofproto_get_all_flows(br->ofproto, &results); unixctl_command_reply(conn, ds_cstr(&results)); ds_destroy(&results); } /* "bridge/reconnect [BRIDGE]": makes BRIDGE drop all of its controller * connections and reconnect. If BRIDGE is not specified, then all bridges * drop their controller connections and reconnect. */ static void bridge_unixctl_reconnect(struct unixctl_conn *conn, int argc, const char *argv[], void *aux OVS_UNUSED) { struct bridge *br; if (argc > 1) { br = bridge_lookup(argv[1]); if (!br) { unixctl_command_reply_error(conn, "Unknown bridge"); return; } ofproto_reconnect_controllers(br->ofproto); } else { HMAP_FOR_EACH (br, node, &all_bridges) { ofproto_reconnect_controllers(br->ofproto); } } unixctl_command_reply(conn, NULL); } static size_t bridge_get_controllers(const struct bridge *br, struct ovsrec_controller ***controllersp) { struct ovsrec_controller **controllers; size_t n_controllers; controllers = br->cfg->controller; n_controllers = br->cfg->n_controller; if (n_controllers == 1 && !strcmp(controllers[0]->target, "none")) { controllers = NULL; n_controllers = 0; } if (controllersp) { *controllersp = controllers; } return n_controllers; } static void bridge_collect_wanted_ports(struct bridge *br, const unsigned long int *splinter_vlans, struct shash *wanted_ports) { size_t i; shash_init(wanted_ports); for (i = 0; i < br->cfg->n_ports; i++) { const char *name = br->cfg->ports[i]->name; if (!shash_add_once(wanted_ports, name, br->cfg->ports[i])) { VLOG_WARN("bridge %s: %s specified twice as bridge port", br->name, name); } } if (bridge_get_controllers(br, NULL) && !shash_find(wanted_ports, br->name)) { VLOG_WARN("bridge %s: no port named %s, synthesizing one", br->name, br->name); ovsrec_interface_init(&br->synth_local_iface); ovsrec_port_init(&br->synth_local_port); br->synth_local_port.interfaces = &br->synth_local_ifacep; br->synth_local_port.n_interfaces = 1; br->synth_local_port.name = br->name; br->synth_local_iface.name = br->name; br->synth_local_iface.type = "internal"; br->synth_local_ifacep = &br->synth_local_iface; shash_add(wanted_ports, br->name, &br->synth_local_port); } if (splinter_vlans) { add_vlan_splinter_ports(br, splinter_vlans, wanted_ports); } } /* Deletes "struct port"s and "struct iface"s under 'br' which aren't * consistent with 'br->cfg'. Updates 'br->if_cfg_queue' with interfaces which * 'br' needs to complete its configuration. */ static void bridge_del_ports(struct bridge *br, const struct shash *wanted_ports) { struct shash_node *port_node; struct port *port, *next; /* Get rid of deleted ports. * Get rid of deleted interfaces on ports that still exist. */ HMAP_FOR_EACH_SAFE (port, next, hmap_node, &br->ports) { port->cfg = shash_find_data(wanted_ports, port->name); if (!port->cfg) { port_destroy(port); } else { port_del_ifaces(port); } } /* Update iface->cfg and iface->type in interfaces that still exist. */ SHASH_FOR_EACH (port_node, wanted_ports) { const struct ovsrec_port *port = port_node->data; size_t i; for (i = 0; i < port->n_interfaces; i++) { const struct ovsrec_interface *cfg = port->interfaces[i]; struct iface *iface = iface_lookup(br, cfg->name); const char *type = iface_get_type(cfg, br->cfg); if (iface) { iface->cfg = cfg; iface->type = type; } else if (!strcmp(type, "null")) { VLOG_WARN_ONCE("%s: The null interface type is deprecated and" " may be removed in February 2013. Please email" " dev@openvswitch.org with concerns.", cfg->name); } else { /* We will add new interfaces later. */ } } } } /* Initializes 'oc' appropriately as a management service controller for * 'br'. * * The caller must free oc->target when it is no longer needed. */ static void bridge_ofproto_controller_for_mgmt(const struct bridge *br, struct ofproto_controller *oc) { oc->target = xasprintf("punix:%s/%s.mgmt", ovs_rundir(), br->name); oc->max_backoff = 0; oc->probe_interval = 60; oc->band = OFPROTO_OUT_OF_BAND; oc->rate_limit = 0; oc->burst_limit = 0; oc->enable_async_msgs = true; oc->dscp = 0; } /* Converts ovsrec_controller 'c' into an ofproto_controller in 'oc'. */ static void bridge_ofproto_controller_from_ovsrec(const struct ovsrec_controller *c, struct ofproto_controller *oc) { int dscp; oc->target = c->target; oc->max_backoff = c->max_backoff ? *c->max_backoff / 1000 : 8; oc->probe_interval = c->inactivity_probe ? *c->inactivity_probe / 1000 : 5; oc->band = (!c->connection_mode || !strcmp(c->connection_mode, "in-band") ? OFPROTO_IN_BAND : OFPROTO_OUT_OF_BAND); oc->rate_limit = c->controller_rate_limit ? *c->controller_rate_limit : 0; oc->burst_limit = (c->controller_burst_limit ? *c->controller_burst_limit : 0); oc->enable_async_msgs = (!c->enable_async_messages || *c->enable_async_messages); dscp = smap_get_int(&c->other_config, "dscp", DSCP_DEFAULT); if (dscp < 0 || dscp > 63) { dscp = DSCP_DEFAULT; } oc->dscp = dscp; } /* Configures the IP stack for 'br''s local interface properly according to the * configuration in 'c'. */ static void bridge_configure_local_iface_netdev(struct bridge *br, struct ovsrec_controller *c) { struct netdev *netdev; struct in_addr mask, gateway; struct iface *local_iface; struct in_addr ip; /* If there's no local interface or no IP address, give up. */ local_iface = iface_from_ofp_port(br, OFPP_LOCAL); if (!local_iface || !c->local_ip || !inet_pton(AF_INET, c->local_ip, &ip)) { return; } /* Bring up the local interface. */ netdev = local_iface->netdev; netdev_turn_flags_on(netdev, NETDEV_UP, NULL); /* Configure the IP address and netmask. */ if (!c->local_netmask || !inet_pton(AF_INET, c->local_netmask, &mask) || !mask.s_addr) { mask.s_addr = guess_netmask(ip.s_addr); } if (!netdev_set_in4(netdev, ip, mask)) { VLOG_INFO("bridge %s: configured IP address "IP_FMT", netmask "IP_FMT, br->name, IP_ARGS(ip.s_addr), IP_ARGS(mask.s_addr)); } /* Configure the default gateway. */ if (c->local_gateway && inet_pton(AF_INET, c->local_gateway, &gateway) && gateway.s_addr) { if (!netdev_add_router(netdev, gateway)) { VLOG_INFO("bridge %s: configured gateway "IP_FMT, br->name, IP_ARGS(gateway.s_addr)); } } } /* Returns true if 'a' and 'b' are the same except that any number of slashes * in either string are treated as equal to any number of slashes in the other, * e.g. "x///y" is equal to "x/y". * * Also, if 'b_stoplen' bytes from 'b' are found to be equal to corresponding * bytes from 'a', the function considers this success. Specify 'b_stoplen' as * SIZE_MAX to compare all of 'a' to all of 'b' rather than just a prefix of * 'b' against a prefix of 'a'. */ static bool equal_pathnames(const char *a, const char *b, size_t b_stoplen) { const char *b_start = b; for (;;) { if (b - b_start >= b_stoplen) { return true; } else if (*a != *b) { return false; } else if (*a == '/') { a += strspn(a, "/"); b += strspn(b, "/"); } else if (*a == '\0') { return true; } else { a++; b++; } } } static void bridge_configure_remotes(struct bridge *br, const struct sockaddr_in *managers, size_t n_managers) { bool disable_in_band; struct ovsrec_controller **controllers; size_t n_controllers; enum ofproto_fail_mode fail_mode; struct ofproto_controller *ocs; size_t n_ocs; size_t i; /* Check if we should disable in-band control on this bridge. */ disable_in_band = smap_get_bool(&br->cfg->other_config, "disable-in-band", false); /* Set OpenFlow queue ID for in-band control. */ ofproto_set_in_band_queue(br->ofproto, smap_get_int(&br->cfg->other_config, "in-band-queue", -1)); if (disable_in_band) { ofproto_set_extra_in_band_remotes(br->ofproto, NULL, 0); } else { ofproto_set_extra_in_band_remotes(br->ofproto, managers, n_managers); } n_controllers = bridge_get_controllers(br, &controllers); ocs = xmalloc((n_controllers + 1) * sizeof *ocs); n_ocs = 0; bridge_ofproto_controller_for_mgmt(br, &ocs[n_ocs++]); for (i = 0; i < n_controllers; i++) { struct ovsrec_controller *c = controllers[i]; if (!strncmp(c->target, "punix:", 6) || !strncmp(c->target, "unix:", 5)) { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5); char *whitelist; if (!strncmp(c->target, "unix:", 5)) { /* Connect to a listening socket */ whitelist = xasprintf("unix:%s/", ovs_rundir()); if (strchr(c->target, '/') && !equal_pathnames(c->target, whitelist, strlen(whitelist))) { /* Absolute path specified, but not in ovs_rundir */ VLOG_ERR_RL(&rl, "bridge %s: Not connecting to socket " "controller \"%s\" due to possibility for " "remote exploit. Instead, specify socket " "in whitelisted \"%s\" or connect to " "\"unix:%s/%s.mgmt\" (which is always " "available without special configuration).", br->name, c->target, whitelist, ovs_rundir(), br->name); free(whitelist); continue; } } else { whitelist = xasprintf("punix:%s/%s.", ovs_rundir(), br->name); if (!equal_pathnames(c->target, whitelist, strlen(whitelist)) || strchr(c->target + strlen(whitelist), '/')) { /* Prevent remote ovsdb-server users from accessing * arbitrary Unix domain sockets and overwriting arbitrary * local files. */ VLOG_ERR_RL(&rl, "bridge %s: Not adding Unix domain socket " "controller \"%s\" due to possibility of " "overwriting local files. Instead, specify " "path in whitelisted format \"%s*\" or " "connect to \"unix:%s/%s.mgmt\" (which is " "always available without special " "configuration).", br->name, c->target, whitelist, ovs_rundir(), br->name); free(whitelist); continue; } } free(whitelist); } bridge_configure_local_iface_netdev(br, c); bridge_ofproto_controller_from_ovsrec(c, &ocs[n_ocs]); if (disable_in_band) { ocs[n_ocs].band = OFPROTO_OUT_OF_BAND; } n_ocs++; } ofproto_set_controllers(br->ofproto, ocs, n_ocs, bridge_get_allowed_versions(br)); free(ocs[0].target); /* From bridge_ofproto_controller_for_mgmt(). */ free(ocs); /* Set the fail-mode. */ fail_mode = !br->cfg->fail_mode || !strcmp(br->cfg->fail_mode, "standalone") ? OFPROTO_FAIL_STANDALONE : OFPROTO_FAIL_SECURE; ofproto_set_fail_mode(br->ofproto, fail_mode); /* Configure OpenFlow controller connection snooping. */ if (!ofproto_has_snoops(br->ofproto)) { struct sset snoops; sset_init(&snoops); sset_add_and_free(&snoops, xasprintf("punix:%s/%s.snoop", ovs_rundir(), br->name)); ofproto_set_snoops(br->ofproto, &snoops); sset_destroy(&snoops); } } static void bridge_configure_tables(struct bridge *br) { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 5); int n_tables; int i, j, k; n_tables = ofproto_get_n_tables(br->ofproto); j = 0; for (i = 0; i < n_tables; i++) { struct ofproto_table_settings s; bool use_default_prefixes = true; s.name = NULL; s.max_flows = UINT_MAX; s.groups = NULL; s.enable_eviction = false; s.n_groups = 0; s.n_prefix_fields = 0; memset(s.prefix_fields, ~0, sizeof(s.prefix_fields)); if (j < br->cfg->n_flow_tables && i == br->cfg->key_flow_tables[j]) { struct ovsrec_flow_table *cfg = br->cfg->value_flow_tables[j++]; s.name = cfg->name; if (cfg->n_flow_limit && *cfg->flow_limit < UINT_MAX) { s.max_flows = *cfg->flow_limit; } s.enable_eviction = (cfg->overflow_policy && !strcmp(cfg->overflow_policy, "evict")); if (cfg->n_groups) { s.groups = xmalloc(cfg->n_groups * sizeof *s.groups); for (k = 0; k < cfg->n_groups; k++) { const char *string = cfg->groups[k]; char *msg; msg = mf_parse_subfield__(&s.groups[k], &string); if (msg) { VLOG_WARN_RL(&rl, "bridge %s table %d: error parsing " "'groups' (%s)", br->name, i, msg); free(msg); } else if (*string) { VLOG_WARN_RL(&rl, "bridge %s table %d: 'groups' " "element '%s' contains trailing garbage", br->name, i, cfg->groups[k]); } else { s.n_groups++; } } } /* Prefix lookup fields. */ s.n_prefix_fields = 0; for (k = 0; k < cfg->n_prefixes; k++) { const char *name = cfg->prefixes[k]; const struct mf_field *mf; if (strcmp(name, "none") == 0) { use_default_prefixes = false; s.n_prefix_fields = 0; break; } mf = mf_from_name(name); if (!mf) { VLOG_WARN("bridge %s: 'prefixes' with unknown field: %s", br->name, name); continue; } if (mf->flow_be32ofs < 0 || mf->n_bits % 32) { VLOG_WARN("bridge %s: 'prefixes' with incompatible field: " "%s", br->name, name); continue; } if (s.n_prefix_fields >= ARRAY_SIZE(s.prefix_fields)) { VLOG_WARN("bridge %s: 'prefixes' with too many fields, " "field not used: %s", br->name, name); continue; } use_default_prefixes = false; s.prefix_fields[s.n_prefix_fields++] = mf->id; } } if (use_default_prefixes) { /* Use default values. */ s.n_prefix_fields = ARRAY_SIZE(default_prefix_fields); memcpy(s.prefix_fields, default_prefix_fields, sizeof default_prefix_fields); } else { int k; struct ds ds = DS_EMPTY_INITIALIZER; for (k = 0; k < s.n_prefix_fields; k++) { if (k) { ds_put_char(&ds, ','); } ds_put_cstr(&ds, mf_from_id(s.prefix_fields[k])->name); } if (s.n_prefix_fields == 0) { ds_put_cstr(&ds, "none"); } VLOG_INFO("bridge %s table %d: Prefix lookup with: %s.", br->name, i, ds_cstr(&ds)); ds_destroy(&ds); } ofproto_configure_table(br->ofproto, i, &s); free(s.groups); } for (; j < br->cfg->n_flow_tables; j++) { VLOG_WARN_RL(&rl, "bridge %s: ignoring configuration for flow table " "%"PRId64" not supported by this datapath", br->name, br->cfg->key_flow_tables[j]); } } static void bridge_configure_dp_desc(struct bridge *br) { ofproto_set_dp_desc(br->ofproto, smap_get(&br->cfg->other_config, "dp-desc")); } static struct aa_mapping * bridge_aa_mapping_find(struct bridge *br, const int64_t isid) { struct aa_mapping *m; HMAP_FOR_EACH_IN_BUCKET (m, hmap_node, hash_bytes(&isid, sizeof isid, 0), &br->mappings) { if (isid == m->isid) { return m; } } return NULL; } static struct aa_mapping * bridge_aa_mapping_create(struct bridge *br, const int64_t isid, const int64_t vlan) { struct aa_mapping *m; m = xzalloc(sizeof *m); m->bridge = br; m->isid = isid; m->vlan = vlan; m->br_name = xstrdup(br->name); hmap_insert(&br->mappings, &m->hmap_node, hash_bytes(&isid, sizeof isid, 0)); return m; } static void bridge_aa_mapping_destroy(struct aa_mapping *m) { if (m) { struct bridge *br = m->bridge; if (br->ofproto) { ofproto_aa_mapping_unregister(br->ofproto, m); } hmap_remove(&br->mappings, &m->hmap_node); if (m->br_name) { free(m->br_name); } free(m); } } static bool bridge_aa_mapping_configure(struct aa_mapping *m) { struct aa_mapping_settings s; s.isid = m->isid; s.vlan = m->vlan; /* Configure. */ ofproto_aa_mapping_register(m->bridge->ofproto, m, &s); return true; } static void bridge_configure_aa(struct bridge *br) { const struct ovsdb_datum *mc; struct ovsrec_autoattach *auto_attach = br->cfg->auto_attach; struct aa_settings aa_s; struct aa_mapping *m, *next; size_t i; if (!auto_attach) { ofproto_set_aa(br->ofproto, NULL, NULL); return; } memset(&aa_s, 0, sizeof aa_s); aa_s.system_description = auto_attach->system_description; aa_s.system_name = auto_attach->system_name; ofproto_set_aa(br->ofproto, NULL, &aa_s); mc = ovsrec_autoattach_get_mappings(auto_attach, OVSDB_TYPE_INTEGER, OVSDB_TYPE_INTEGER); HMAP_FOR_EACH_SAFE (m, next, hmap_node, &br->mappings) { union ovsdb_atom atom; atom.integer = m->isid; if (ovsdb_datum_find_key(mc, &atom, OVSDB_TYPE_UUID) == UINT_MAX) { VLOG_INFO("Deleting isid=%"PRIu32", vlan=%"PRIu16, m->isid, m->vlan); bridge_aa_mapping_destroy(m); } } /* Add new mappings and reconfigure existing ones. */ for (i = 0; i < auto_attach->n_mappings; ++i) { struct aa_mapping *m = bridge_aa_mapping_find(br, auto_attach->key_mappings[i]); if (!m) { VLOG_INFO("Adding isid=%"PRId64", vlan=%"PRId64, auto_attach->key_mappings[i], auto_attach->value_mappings[i]); m = bridge_aa_mapping_create(br, auto_attach->key_mappings[i], auto_attach->value_mappings[i]); if (!bridge_aa_mapping_configure(m)) { bridge_aa_mapping_destroy(m); } } } } static bool bridge_aa_need_refresh(struct bridge *br) { return ofproto_aa_vlan_get_queue_size(br->ofproto) > 0; } static void bridge_aa_update_trunks(struct port *port, struct bridge_aa_vlan *m) { int64_t *trunks = NULL; unsigned int i = 0; bool found = false, reconfigure = false; for (i = 0; i < port->cfg->n_trunks; i++) { if (port->cfg->trunks[i] == m->vlan) { found = true; break; } } switch (m->oper) { case BRIDGE_AA_VLAN_OPER_ADD: if (!found) { trunks = xmalloc(sizeof *trunks * (port->cfg->n_trunks + 1)); for (i = 0; i < port->cfg->n_trunks; i++) { trunks[i] = port->cfg->trunks[i]; } trunks[i++] = m->vlan; reconfigure = true; } break; case BRIDGE_AA_VLAN_OPER_REMOVE: if (found) { unsigned int j = 0; trunks = xmalloc(sizeof *trunks * (port->cfg->n_trunks - 1)); for (i = 0; i < port->cfg->n_trunks; i++) { if (port->cfg->trunks[i] != m->vlan) { trunks[j++] = port->cfg->trunks[i]; } } i = j; reconfigure = true; } break; case BRIDGE_AA_VLAN_OPER_UNDEF: default: VLOG_WARN("unrecognized operation %u", m->oper); break; } if (reconfigure) { /* VLAN switching under trunk mode cause the trunk port to switch all * VLANs, see ovs-vswitchd.conf.db */ if (i == 0) { static char *vlan_mode_access = "access"; ovsrec_port_set_vlan_mode(port->cfg, vlan_mode_access); } if (i == 1) { static char *vlan_mode_trunk = "trunk"; ovsrec_port_set_vlan_mode(port->cfg, vlan_mode_trunk); } ovsrec_port_set_trunks(port->cfg, trunks, i); /* Force reconfigure of the port. */ port_configure(port); } } static void bridge_aa_refresh_queued(struct bridge *br) { struct ovs_list *list = xmalloc(sizeof *list); struct bridge_aa_vlan *node, *next; list_init(list); ofproto_aa_vlan_get_queued(br->ofproto, list); LIST_FOR_EACH_SAFE (node, next, list_node, list) { struct port *port; VLOG_INFO("ifname=%s, vlan=%u, oper=%u", node->port_name, node->vlan, node->oper); port = port_lookup(br, node->port_name); if (port) { bridge_aa_update_trunks(port, node); } list_remove(&node->list_node); free(node->port_name); free(node); } free(list); } /* Port functions. */ static struct port * port_create(struct bridge *br, const struct ovsrec_port *cfg) { struct port *port; port = xzalloc(sizeof *port); port->bridge = br; port->name = xstrdup(cfg->name); port->cfg = cfg; list_init(&port->ifaces); hmap_insert(&br->ports, &port->hmap_node, hash_string(port->name, 0)); return port; } /* Deletes interfaces from 'port' that are no longer configured for it. */ static void port_del_ifaces(struct port *port) { struct iface *iface, *next; struct sset new_ifaces; size_t i; /* Collect list of new interfaces. */ sset_init(&new_ifaces); for (i = 0; i < port->cfg->n_interfaces; i++) { const char *name = port->cfg->interfaces[i]->name; const char *type = port->cfg->interfaces[i]->type; if (strcmp(type, "null")) { sset_add(&new_ifaces, name); } } /* Get rid of deleted interfaces. */ LIST_FOR_EACH_SAFE (iface, next, port_elem, &port->ifaces) { if (!sset_contains(&new_ifaces, iface->name)) { iface_destroy(iface); } } sset_destroy(&new_ifaces); } static void port_destroy(struct port *port) { if (port) { struct bridge *br = port->bridge; struct iface *iface, *next; if (br->ofproto) { ofproto_bundle_unregister(br->ofproto, port); } LIST_FOR_EACH_SAFE (iface, next, port_elem, &port->ifaces) { iface_destroy__(iface); } hmap_remove(&br->ports, &port->hmap_node); free(port->name); free(port); } } static struct port * port_lookup(const struct bridge *br, const char *name) { struct port *port; HMAP_FOR_EACH_WITH_HASH (port, hmap_node, hash_string(name, 0), &br->ports) { if (!strcmp(port->name, name)) { return port; } } return NULL; } static bool enable_lacp(struct port *port, bool *activep) { if (!port->cfg->lacp) { /* XXX when LACP implementation has been sufficiently tested, enable by * default and make active on bonded ports. */ return false; } else if (!strcmp(port->cfg->lacp, "off")) { return false; } else if (!strcmp(port->cfg->lacp, "active")) { *activep = true; return true; } else if (!strcmp(port->cfg->lacp, "passive")) { *activep = false; return true; } else { VLOG_WARN("port %s: unknown LACP mode %s", port->name, port->cfg->lacp); return false; } } static struct lacp_settings * port_configure_lacp(struct port *port, struct lacp_settings *s) { const char *lacp_time, *system_id; int priority; if (!enable_lacp(port, &s->active)) { return NULL; } s->name = port->name; system_id = smap_get(&port->cfg->other_config, "lacp-system-id"); if (system_id) { if (!ovs_scan(system_id, ETH_ADDR_SCAN_FMT, ETH_ADDR_SCAN_ARGS(s->id))) { VLOG_WARN("port %s: LACP system ID (%s) must be an Ethernet" " address.", port->name, system_id); return NULL; } } else { s->id = port->bridge->ea; } if (eth_addr_is_zero(s->id)) { VLOG_WARN("port %s: Invalid zero LACP system ID.", port->name); return NULL; } /* Prefer bondable links if unspecified. */ priority = smap_get_int(&port->cfg->other_config, "lacp-system-priority", 0); s->priority = (priority > 0 && priority <= UINT16_MAX ? priority : UINT16_MAX - !list_is_short(&port->ifaces)); lacp_time = smap_get(&port->cfg->other_config, "lacp-time"); s->fast = lacp_time && !strcasecmp(lacp_time, "fast"); s->fallback_ab_cfg = smap_get_bool(&port->cfg->other_config, "lacp-fallback-ab", false); return s; } static void iface_configure_lacp(struct iface *iface, struct lacp_slave_settings *s) { int priority, portid, key; portid = smap_get_int(&iface->cfg->other_config, "lacp-port-id", 0); priority = smap_get_int(&iface->cfg->other_config, "lacp-port-priority", 0); key = smap_get_int(&iface->cfg->other_config, "lacp-aggregation-key", 0); if (portid <= 0 || portid > UINT16_MAX) { portid = ofp_to_u16(iface->ofp_port); } if (priority <= 0 || priority > UINT16_MAX) { priority = UINT16_MAX; } if (key < 0 || key > UINT16_MAX) { key = 0; } s->name = iface->name; s->id = portid; s->priority = priority; s->key = key; } static void port_configure_bond(struct port *port, struct bond_settings *s) { const char *detect_s; struct iface *iface; const char *mac_s; int miimon_interval; s->name = port->name; s->balance = BM_AB; if (port->cfg->bond_mode) { if (!bond_mode_from_string(&s->balance, port->cfg->bond_mode)) { VLOG_WARN("port %s: unknown bond_mode %s, defaulting to %s", port->name, port->cfg->bond_mode, bond_mode_to_string(s->balance)); } } else { static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(1, 1); /* XXX: Post version 1.5.*, the default bond_mode changed from SLB to * active-backup. At some point we should remove this warning. */ VLOG_WARN_RL(&rl, "port %s: Using the default bond_mode %s. Note that" " in previous versions, the default bond_mode was" " balance-slb", port->name, bond_mode_to_string(s->balance)); } if (s->balance == BM_SLB && port->bridge->cfg->n_flood_vlans) { VLOG_WARN("port %s: SLB bonds are incompatible with flood_vlans, " "please use another bond type or disable flood_vlans", port->name); } miimon_interval = smap_get_int(&port->cfg->other_config, "bond-miimon-interval", 0); if (miimon_interval <= 0) { miimon_interval = 200; } detect_s = smap_get(&port->cfg->other_config, "bond-detect-mode"); if (!detect_s || !strcmp(detect_s, "carrier")) { miimon_interval = 0; } else if (strcmp(detect_s, "miimon")) { VLOG_WARN("port %s: unsupported bond-detect-mode %s, " "defaulting to carrier", port->name, detect_s); miimon_interval = 0; } s->up_delay = MAX(0, port->cfg->bond_updelay); s->down_delay = MAX(0, port->cfg->bond_downdelay); s->basis = smap_get_int(&port->cfg->other_config, "bond-hash-basis", 0); s->rebalance_interval = smap_get_int(&port->cfg->other_config, "bond-rebalance-interval", 10000); if (s->rebalance_interval && s->rebalance_interval < 1000) { s->rebalance_interval = 1000; } s->lacp_fallback_ab_cfg = smap_get_bool(&port->cfg->other_config, "lacp-fallback-ab", false); LIST_FOR_EACH (iface, port_elem, &port->ifaces) { netdev_set_miimon_interval(iface->netdev, miimon_interval); } mac_s = port->cfg->bond_active_slave; if (!mac_s || !ovs_scan(mac_s, ETH_ADDR_SCAN_FMT, ETH_ADDR_SCAN_ARGS(s->active_slave_mac))) { /* OVSDB did not store the last active interface */ s->active_slave_mac = eth_addr_zero; } } /* Returns true if 'port' is synthetic, that is, if we constructed it locally * instead of obtaining it from the database. */ static bool port_is_synthetic(const struct port *port) { return ovsdb_idl_row_is_synthetic(&port->cfg->header_); } /* Interface functions. */ static bool iface_is_internal(const struct ovsrec_interface *iface, const struct ovsrec_bridge *br) { /* The local port and "internal" ports are always "internal". */ return !strcmp(iface->type, "internal") || !strcmp(iface->name, br->name); } /* Returns the correct network device type for interface 'iface' in bridge * 'br'. */ static const char * iface_get_type(const struct ovsrec_interface *iface, const struct ovsrec_bridge *br) { const char *type; /* The local port always has type "internal". Other ports take * their type from the database and default to "system" if none is * specified. */ if (iface_is_internal(iface, br)) { type = "internal"; } else { type = iface->type[0] ? iface->type : "system"; } return ofproto_port_open_type(br->datapath_type, type); } static void iface_destroy__(struct iface *iface) { if (iface) { struct port *port = iface->port; struct bridge *br = port->bridge; if (br->ofproto && iface->ofp_port != OFPP_NONE) { ofproto_port_unregister(br->ofproto, iface->ofp_port); } if (iface->ofp_port != OFPP_NONE) { hmap_remove(&br->ifaces, &iface->ofp_port_node); } list_remove(&iface->port_elem); hmap_remove(&br->iface_by_name, &iface->name_node); /* The user is changing configuration here, so netdev_remove needs to be * used as opposed to netdev_close */ netdev_remove(iface->netdev); free(iface->name); free(iface); } } static void iface_destroy(struct iface *iface) { if (iface) { struct port *port = iface->port; iface_destroy__(iface); if (list_is_empty(&port->ifaces)) { port_destroy(port); } } } static struct iface * iface_lookup(const struct bridge *br, const char *name) { struct iface *iface; HMAP_FOR_EACH_WITH_HASH (iface, name_node, hash_string(name, 0), &br->iface_by_name) { if (!strcmp(iface->name, name)) { return iface; } } return NULL; } static struct iface * iface_find(const char *name) { const struct bridge *br; HMAP_FOR_EACH (br, node, &all_bridges) { struct iface *iface = iface_lookup(br, name); if (iface) { return iface; } } return NULL; } static struct iface * iface_from_ofp_port(const struct bridge *br, ofp_port_t ofp_port) { struct iface *iface; HMAP_FOR_EACH_IN_BUCKET (iface, ofp_port_node, hash_ofp_port(ofp_port), &br->ifaces) { if (iface->ofp_port == ofp_port) { return iface; } } return NULL; } /* Set Ethernet address of 'iface', if one is specified in the configuration * file. */ static void iface_set_mac(const struct bridge *br, const struct port *port, struct iface *iface) { struct eth_addr ea, *mac = NULL; struct iface *hw_addr_iface; if (strcmp(iface->type, "internal")) { return; } if (iface->cfg->mac && eth_addr_from_string(iface->cfg->mac, &ea)) { mac = &ea; } else if (port->cfg->fake_bridge) { /* Fake bridge and no MAC set in the configuration. Pick a local one. */ find_local_hw_addr(br, &ea, port, &hw_addr_iface); mac = &ea; } if (mac) { if (iface->ofp_port == OFPP_LOCAL) { VLOG_ERR("interface %s: ignoring mac in Interface record " "(use Bridge record to set local port's mac)", iface->name); } else if (eth_addr_is_multicast(*mac)) { VLOG_ERR("interface %s: cannot set MAC to multicast address", iface->name); } else { int error = netdev_set_etheraddr(iface->netdev, *mac); if (error) { VLOG_ERR("interface %s: setting MAC failed (%s)", iface->name, ovs_strerror(error)); } } } } /* Sets the ofport column of 'if_cfg' to 'ofport'. */ static void iface_set_ofport(const struct ovsrec_interface *if_cfg, ofp_port_t ofport) { if (if_cfg && !ovsdb_idl_row_is_synthetic(&if_cfg->header_)) { int64_t port = ofport == OFPP_NONE ? -1 : ofp_to_u16(ofport); ovsrec_interface_set_ofport(if_cfg, &port, 1); } } /* Clears all of the fields in 'if_cfg' that indicate interface status, and * sets the "ofport" field to -1. * * This is appropriate when 'if_cfg''s interface cannot be created or is * otherwise invalid. */ static void iface_clear_db_record(const struct ovsrec_interface *if_cfg, char *errp) { if (!ovsdb_idl_row_is_synthetic(&if_cfg->header_)) { iface_set_ofport(if_cfg, OFPP_NONE); ovsrec_interface_set_error(if_cfg, errp); ovsrec_interface_set_status(if_cfg, NULL); ovsrec_interface_set_admin_state(if_cfg, NULL); ovsrec_interface_set_duplex(if_cfg, NULL); ovsrec_interface_set_link_speed(if_cfg, NULL, 0); ovsrec_interface_set_link_state(if_cfg, NULL); ovsrec_interface_set_mac_in_use(if_cfg, NULL); ovsrec_interface_set_mtu(if_cfg, NULL, 0); ovsrec_interface_set_cfm_fault(if_cfg, NULL, 0); ovsrec_interface_set_cfm_fault_status(if_cfg, NULL, 0); ovsrec_interface_set_cfm_remote_mpids(if_cfg, NULL, 0); ovsrec_interface_set_lacp_current(if_cfg, NULL, 0); ovsrec_interface_set_statistics(if_cfg, NULL, NULL, 0); ovsrec_interface_set_ifindex(if_cfg, NULL, 0); } } static bool queue_ids_include(const struct ovsdb_datum *queues, int64_t target) { union ovsdb_atom atom; atom.integer = target; return ovsdb_datum_find_key(queues, &atom, OVSDB_TYPE_INTEGER) != UINT_MAX; } static void iface_configure_qos(struct iface *iface, const struct ovsrec_qos *qos) { struct ofpbuf queues_buf; ofpbuf_init(&queues_buf, 0); if (!qos || qos->type[0] == '\0') { netdev_set_qos(iface->netdev, NULL, NULL); } else { const struct ovsdb_datum *queues; struct netdev_queue_dump dump; unsigned int queue_id; struct smap details; bool queue_zero; size_t i; /* Configure top-level Qos for 'iface'. */ netdev_set_qos(iface->netdev, qos->type, &qos->other_config); /* Deconfigure queues that were deleted. */ queues = ovsrec_qos_get_queues(qos, OVSDB_TYPE_INTEGER, OVSDB_TYPE_UUID); smap_init(&details); NETDEV_QUEUE_FOR_EACH (&queue_id, &details, &dump, iface->netdev) { if (!queue_ids_include(queues, queue_id)) { netdev_delete_queue(iface->netdev, queue_id); } } smap_destroy(&details); /* Configure queues for 'iface'. */ queue_zero = false; for (i = 0; i < qos->n_queues; i++) { const struct ovsrec_queue *queue = qos->value_queues[i]; unsigned int queue_id = qos->key_queues[i]; if (queue_id == 0) { queue_zero = true; } if (queue->n_dscp == 1) { struct ofproto_port_queue *port_queue; port_queue = ofpbuf_put_uninit(&queues_buf, sizeof *port_queue); port_queue->queue = queue_id; port_queue->dscp = queue->dscp[0]; } netdev_set_queue(iface->netdev, queue_id, &queue->other_config); } if (!queue_zero) { struct smap details; smap_init(&details); netdev_set_queue(iface->netdev, 0, &details); smap_destroy(&details); } } if (iface->ofp_port != OFPP_NONE) { const struct ofproto_port_queue *port_queues = queues_buf.data; size_t n_queues = queues_buf.size / sizeof *port_queues; ofproto_port_set_queues(iface->port->bridge->ofproto, iface->ofp_port, port_queues, n_queues); } netdev_set_policing(iface->netdev, MIN(UINT32_MAX, iface->cfg->ingress_policing_rate), MIN(UINT32_MAX, iface->cfg->ingress_policing_burst)); ofpbuf_uninit(&queues_buf); } static void iface_configure_cfm(struct iface *iface) { const struct ovsrec_interface *cfg = iface->cfg; const char *opstate_str; const char *cfm_ccm_vlan; struct cfm_settings s; struct smap netdev_args; if (!cfg->n_cfm_mpid) { ofproto_port_clear_cfm(iface->port->bridge->ofproto, iface->ofp_port); return; } s.check_tnl_key = false; smap_init(&netdev_args); if (!netdev_get_config(iface->netdev, &netdev_args)) { const char *key = smap_get(&netdev_args, "key"); const char *in_key = smap_get(&netdev_args, "in_key"); s.check_tnl_key = (key && !strcmp(key, "flow")) || (in_key && !strcmp(in_key, "flow")); } smap_destroy(&netdev_args); s.mpid = *cfg->cfm_mpid; s.interval = smap_get_int(&iface->cfg->other_config, "cfm_interval", 0); cfm_ccm_vlan = smap_get(&iface->cfg->other_config, "cfm_ccm_vlan"); s.ccm_pcp = smap_get_int(&iface->cfg->other_config, "cfm_ccm_pcp", 0); if (s.interval <= 0) { s.interval = 1000; } if (!cfm_ccm_vlan) { s.ccm_vlan = 0; } else if (!strcasecmp("random", cfm_ccm_vlan)) { s.ccm_vlan = CFM_RANDOM_VLAN; } else { s.ccm_vlan = atoi(cfm_ccm_vlan); if (s.ccm_vlan == CFM_RANDOM_VLAN) { s.ccm_vlan = 0; } } s.extended = smap_get_bool(&iface->cfg->other_config, "cfm_extended", false); s.demand = smap_get_bool(&iface->cfg->other_config, "cfm_demand", false); opstate_str = smap_get(&iface->cfg->other_config, "cfm_opstate"); s.opup = !opstate_str || !strcasecmp("up", opstate_str); ofproto_port_set_cfm(iface->port->bridge->ofproto, iface->ofp_port, &s); } /* Returns true if 'iface' is synthetic, that is, if we constructed it locally * instead of obtaining it from the database. */ static bool iface_is_synthetic(const struct iface *iface) { return ovsdb_idl_row_is_synthetic(&iface->cfg->header_); } static ofp_port_t iface_validate_ofport__(size_t n, int64_t *ofport) { return (n && *ofport >= 1 && *ofport < ofp_to_u16(OFPP_MAX) ? u16_to_ofp(*ofport) : OFPP_NONE); } static ofp_port_t iface_get_requested_ofp_port(const struct ovsrec_interface *cfg) { return iface_validate_ofport__(cfg->n_ofport_request, cfg->ofport_request); } static ofp_port_t iface_pick_ofport(const struct ovsrec_interface *cfg) { ofp_port_t requested_ofport = iface_get_requested_ofp_port(cfg); return (requested_ofport != OFPP_NONE ? requested_ofport : iface_validate_ofport__(cfg->n_ofport, cfg->ofport)); } /* Port mirroring. */ static struct mirror * mirror_find_by_uuid(struct bridge *br, const struct uuid *uuid) { struct mirror *m; HMAP_FOR_EACH_IN_BUCKET (m, hmap_node, uuid_hash(uuid), &br->mirrors) { if (uuid_equals(uuid, &m->uuid)) { return m; } } return NULL; } static void bridge_configure_mirrors(struct bridge *br) { const struct ovsdb_datum *mc; unsigned long *flood_vlans; struct mirror *m, *next; size_t i; /* Get rid of deleted mirrors. */ mc = ovsrec_bridge_get_mirrors(br->cfg, OVSDB_TYPE_UUID); HMAP_FOR_EACH_SAFE (m, next, hmap_node, &br->mirrors) { union ovsdb_atom atom; atom.uuid = m->uuid; if (ovsdb_datum_find_key(mc, &atom, OVSDB_TYPE_UUID) == UINT_MAX) { mirror_destroy(m); } } /* Add new mirrors and reconfigure existing ones. */ for (i = 0; i < br->cfg->n_mirrors; i++) { const struct ovsrec_mirror *cfg = br->cfg->mirrors[i]; struct mirror *m = mirror_find_by_uuid(br, &cfg->header_.uuid); if (!m) { m = mirror_create(br, cfg); } m->cfg = cfg; if (!mirror_configure(m)) { mirror_destroy(m); } } /* Update flooded vlans (for RSPAN). */ flood_vlans = vlan_bitmap_from_array(br->cfg->flood_vlans, br->cfg->n_flood_vlans); ofproto_set_flood_vlans(br->ofproto, flood_vlans); bitmap_free(flood_vlans); } static struct mirror * mirror_create(struct bridge *br, const struct ovsrec_mirror *cfg) { struct mirror *m; m = xzalloc(sizeof *m); m->uuid = cfg->header_.uuid; hmap_insert(&br->mirrors, &m->hmap_node, uuid_hash(&m->uuid)); m->bridge = br; m->name = xstrdup(cfg->name); return m; } static void mirror_destroy(struct mirror *m) { if (m) { struct bridge *br = m->bridge; if (br->ofproto) { ofproto_mirror_unregister(br->ofproto, m); } hmap_remove(&br->mirrors, &m->hmap_node); free(m->name); free(m); } } static void mirror_collect_ports(struct mirror *m, struct ovsrec_port **in_ports, int n_in_ports, void ***out_portsp, size_t *n_out_portsp) { void **out_ports = xmalloc(n_in_ports * sizeof *out_ports); size_t n_out_ports = 0; size_t i; for (i = 0; i < n_in_ports; i++) { const char *name = in_ports[i]->name; struct port *port = port_lookup(m->bridge, name); if (port) { out_ports[n_out_ports++] = port; } else { VLOG_WARN("bridge %s: mirror %s cannot match on nonexistent " "port %s", m->bridge->name, m->name, name); } } *out_portsp = out_ports; *n_out_portsp = n_out_ports; } static bool mirror_configure(struct mirror *m) { const struct ovsrec_mirror *cfg = m->cfg; struct ofproto_mirror_settings s; /* Set name. */ if (strcmp(cfg->name, m->name)) { free(m->name); m->name = xstrdup(cfg->name); } s.name = m->name; /* Get output port or VLAN. */ if (cfg->output_port) { s.out_bundle = port_lookup(m->bridge, cfg->output_port->name); if (!s.out_bundle) { VLOG_ERR("bridge %s: mirror %s outputs to port not on bridge", m->bridge->name, m->name); return false; } s.out_vlan = UINT16_MAX; if (cfg->output_vlan) { VLOG_ERR("bridge %s: mirror %s specifies both output port and " "output vlan; ignoring output vlan", m->bridge->name, m->name); } } else if (cfg->output_vlan) { /* The database should prevent invalid VLAN values. */ s.out_bundle = NULL; s.out_vlan = *cfg->output_vlan; } else { VLOG_ERR("bridge %s: mirror %s does not specify output; ignoring", m->bridge->name, m->name); return false; } /* Get port selection. */ if (cfg->select_all) { size_t n_ports = hmap_count(&m->bridge->ports); void **ports = xmalloc(n_ports * sizeof *ports); struct port *port; size_t i; i = 0; HMAP_FOR_EACH (port, hmap_node, &m->bridge->ports) { ports[i++] = port; } s.srcs = ports; s.n_srcs = n_ports; s.dsts = ports; s.n_dsts = n_ports; } else { /* Get ports, dropping ports that don't exist. * The IDL ensures that there are no duplicates. */ mirror_collect_ports(m, cfg->select_src_port, cfg->n_select_src_port, &s.srcs, &s.n_srcs); mirror_collect_ports(m, cfg->select_dst_port, cfg->n_select_dst_port, &s.dsts, &s.n_dsts); } /* Get VLAN selection. */ s.src_vlans = vlan_bitmap_from_array(cfg->select_vlan, cfg->n_select_vlan); /* Configure. */ ofproto_mirror_register(m->bridge->ofproto, m, &s); /* Clean up. */ if (s.srcs != s.dsts) { free(s.dsts); } free(s.srcs); free(s.src_vlans); return true; } /* Linux VLAN device support (e.g. "eth0.10" for VLAN 10.) * * This is deprecated. It is only for compatibility with broken device drivers * in old versions of Linux that do not properly support VLANs when VLAN * devices are not used. When broken device drivers are no longer in * widespread use, we will delete these interfaces. */ static struct ovsrec_port **recs; static size_t n_recs, allocated_recs; /* Adds 'rec' to a list of recs that have to be destroyed when the VLAN * splinters are reconfigured. */ static void register_rec(struct ovsrec_port *rec) { if (n_recs >= allocated_recs) { recs = x2nrealloc(recs, &allocated_recs, sizeof *recs); } recs[n_recs++] = rec; } /* Frees all of the ports registered with register_reg(). */ static void free_registered_recs(void) { size_t i; for (i = 0; i < n_recs; i++) { struct ovsrec_port *port = recs[i]; size_t j; for (j = 0; j < port->n_interfaces; j++) { struct ovsrec_interface *iface = port->interfaces[j]; free(iface->name); free(iface); } smap_destroy(&port->other_config); free(port->interfaces); free(port->name); free(port->tag); free(port); } n_recs = 0; } /* Returns true if VLAN splinters are enabled on 'iface_cfg', false * otherwise. */ static bool vlan_splinters_is_enabled(const struct ovsrec_interface *iface_cfg) { return smap_get_bool(&iface_cfg->other_config, "enable-vlan-splinters", false); } /* Figures out the set of VLANs that are in use for the purpose of VLAN * splinters. * * If VLAN splinters are enabled on at least one interface and any VLANs are in * use, returns a 4096-bit bitmap with a 1-bit for each in-use VLAN (bits 0 and * 4095 will not be set). The caller is responsible for freeing the bitmap, * with free(). * * If VLANs splinters are not enabled on any interface or if no VLANs are in * use, returns NULL. * * Updates 'vlan_splinters_enabled_anywhere'. */ static unsigned long int * collect_splinter_vlans(const struct ovsrec_open_vswitch *ovs_cfg) { unsigned long int *splinter_vlans; struct sset splinter_ifaces; const char *real_dev_name; struct shash *real_devs; struct shash_node *node; struct bridge *br; size_t i; /* Free space allocated for synthesized ports and interfaces, since we're * in the process of reconstructing all of them. */ free_registered_recs(); splinter_vlans = bitmap_allocate(4096); sset_init(&splinter_ifaces); vlan_splinters_enabled_anywhere = false; for (i = 0; i < ovs_cfg->n_bridges; i++) { struct ovsrec_bridge *br_cfg = ovs_cfg->bridges[i]; size_t j; for (j = 0; j < br_cfg->n_ports; j++) { struct ovsrec_port *port_cfg = br_cfg->ports[j]; int k; for (k = 0; k < port_cfg->n_interfaces; k++) { struct ovsrec_interface *iface_cfg = port_cfg->interfaces[k]; if (vlan_splinters_is_enabled(iface_cfg)) { vlan_splinters_enabled_anywhere = true; sset_add(&splinter_ifaces, iface_cfg->name); vlan_bitmap_from_array__(port_cfg->trunks, port_cfg->n_trunks, splinter_vlans); } } if (port_cfg->tag && *port_cfg->tag > 0 && *port_cfg->tag < 4095) { bitmap_set1(splinter_vlans, *port_cfg->tag); } } } if (!vlan_splinters_enabled_anywhere) { free(splinter_vlans); sset_destroy(&splinter_ifaces); return NULL; } HMAP_FOR_EACH (br, node, &all_bridges) { if (br->ofproto) { ofproto_get_vlan_usage(br->ofproto, splinter_vlans); } } /* Don't allow VLANs 0 or 4095 to be splintered. VLAN 0 should appear on * the real device. VLAN 4095 is reserved and Linux doesn't allow a VLAN * device to be created for it. */ bitmap_set0(splinter_vlans, 0); bitmap_set0(splinter_vlans, 4095); /* Delete all VLAN devices that we don't need. */ vlandev_refresh(); real_devs = vlandev_get_real_devs(); SHASH_FOR_EACH (node, real_devs) { const struct vlan_real_dev *real_dev = node->data; const struct vlan_dev *vlan_dev; bool real_dev_has_splinters; real_dev_has_splinters = sset_contains(&splinter_ifaces, real_dev->name); HMAP_FOR_EACH (vlan_dev, hmap_node, &real_dev->vlan_devs) { if (!real_dev_has_splinters || !bitmap_is_set(splinter_vlans, vlan_dev->vid)) { struct netdev *netdev; if (!netdev_open(vlan_dev->name, "system", &netdev)) { if (!netdev_get_in4(netdev, NULL, NULL) || !netdev_get_in6(netdev, NULL)) { /* It has an IP address configured, so we don't own * it. Don't delete it. */ } else { vlandev_del(vlan_dev->name); } netdev_close(netdev); } } } } /* Add all VLAN devices that we need. */ SSET_FOR_EACH (real_dev_name, &splinter_ifaces) { int vid; BITMAP_FOR_EACH_1 (vid, 4096, splinter_vlans) { if (!vlandev_get_name(real_dev_name, vid)) { vlandev_add(real_dev_name, vid); } } } vlandev_refresh(); sset_destroy(&splinter_ifaces); if (bitmap_scan(splinter_vlans, 1, 0, 4096) >= 4096) { free(splinter_vlans); return NULL; } return splinter_vlans; } /* Pushes the configure of VLAN splinter port 'port' (e.g. eth0.9) down to * ofproto. */ static void configure_splinter_port(struct port *port) { struct ofproto *ofproto = port->bridge->ofproto; ofp_port_t realdev_ofp_port; const char *realdev_name; struct iface *vlandev, *realdev; ofproto_bundle_unregister(port->bridge->ofproto, port); vlandev = CONTAINER_OF(list_front(&port->ifaces), struct iface, port_elem); realdev_name = smap_get(&port->cfg->other_config, "realdev"); realdev = iface_lookup(port->bridge, realdev_name); realdev_ofp_port = realdev ? realdev->ofp_port : 0; ofproto_port_set_realdev(ofproto, vlandev->ofp_port, realdev_ofp_port, *port->cfg->tag); } static struct ovsrec_port * synthesize_splinter_port(const char *real_dev_name, const char *vlan_dev_name, int vid) { struct ovsrec_interface *iface; struct ovsrec_port *port; iface = xmalloc(sizeof *iface); ovsrec_interface_init(iface); iface->name = xstrdup(vlan_dev_name); iface->type = "system"; port = xmalloc(sizeof *port); ovsrec_port_init(port); port->interfaces = xmemdup(&iface, sizeof iface); port->n_interfaces = 1; port->name = xstrdup(vlan_dev_name); port->vlan_mode = "splinter"; port->tag = xmalloc(sizeof *port->tag); *port->tag = vid; smap_add(&port->other_config, "realdev", real_dev_name); register_rec(port); return port; } /* For each interface with 'br' that has VLAN splinters enabled, adds a * corresponding ovsrec_port to 'ports' for each splinter VLAN marked with a * 1-bit in the 'splinter_vlans' bitmap. */ static void add_vlan_splinter_ports(struct bridge *br, const unsigned long int *splinter_vlans, struct shash *ports) { size_t i; /* We iterate through 'br->cfg->ports' instead of 'ports' here because * we're modifying 'ports'. */ for (i = 0; i < br->cfg->n_ports; i++) { const char *name = br->cfg->ports[i]->name; struct ovsrec_port *port_cfg = shash_find_data(ports, name); size_t j; for (j = 0; j < port_cfg->n_interfaces; j++) { struct ovsrec_interface *iface_cfg = port_cfg->interfaces[j]; if (vlan_splinters_is_enabled(iface_cfg)) { const char *real_dev_name; uint16_t vid; real_dev_name = iface_cfg->name; BITMAP_FOR_EACH_1 (vid, 4096, splinter_vlans) { const char *vlan_dev_name; vlan_dev_name = vlandev_get_name(real_dev_name, vid); if (vlan_dev_name && !shash_find(ports, vlan_dev_name)) { shash_add(ports, vlan_dev_name, synthesize_splinter_port( real_dev_name, vlan_dev_name, vid)); } } } } } } static void mirror_refresh_stats(struct mirror *m) { struct ofproto *ofproto = m->bridge->ofproto; uint64_t tx_packets, tx_bytes; const char *keys[2]; int64_t values[2]; size_t stat_cnt = 0; if (ofproto_mirror_get_stats(ofproto, m, &tx_packets, &tx_bytes)) { ovsrec_mirror_set_statistics(m->cfg, NULL, NULL, 0); return; } if (tx_packets != UINT64_MAX) { keys[stat_cnt] = "tx_packets"; values[stat_cnt] = tx_packets; stat_cnt++; } if (tx_bytes != UINT64_MAX) { keys[stat_cnt] = "tx_bytes"; values[stat_cnt] = tx_bytes; stat_cnt++; } ovsrec_mirror_set_statistics(m->cfg, keys, values, stat_cnt); } /* * Add registered netdev and dpif types to ovsdb to allow external * applications to query the capabilities of the Open vSwitch instance * running on the node. */ static void discover_types(const struct ovsrec_open_vswitch *cfg) { struct sset types; /* Datapath types. */ sset_init(&types); dp_enumerate_types(&types); const char **datapath_types = sset_array(&types); ovsrec_open_vswitch_set_datapath_types(cfg, datapath_types, sset_count(&types)); free(datapath_types); sset_destroy(&types); /* Port types. */ sset_init(&types); netdev_enumerate_types(&types); const char **iface_types = sset_array(&types); ovsrec_open_vswitch_set_iface_types(cfg, iface_types, sset_count(&types)); free(iface_types); sset_destroy(&types); }