/* * Copyright (c) 2008, 2009, 2010, 2011, 2012, 2013 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 "learning-switch.h" #include #include #include #include #include #include "byte-order.h" #include "classifier.h" #include "flow.h" #include "hmap.h" #include "mac-learning.h" #include "ofpbuf.h" #include "ofp-actions.h" #include "ofp-errors.h" #include "ofp-msgs.h" #include "ofp-parse.h" #include "ofp-print.h" #include "ofp-util.h" #include "openflow/openflow.h" #include "poll-loop.h" #include "rconn.h" #include "shash.h" #include "simap.h" #include "timeval.h" #include "vconn.h" #include "vlog.h" VLOG_DEFINE_THIS_MODULE(learning_switch); struct lswitch_port { struct hmap_node hmap_node; /* Hash node for port number. */ ofp_port_t port_no; /* OpenFlow port number. */ uint32_t queue_id; /* OpenFlow queue number. */ }; enum lswitch_state { S_CONNECTING, /* Waiting for connection to complete. */ S_FEATURES_REPLY, /* Waiting for features reply. */ S_SWITCHING, /* Switching flows. */ }; struct lswitch { struct rconn *rconn; enum lswitch_state state; /* If nonnegative, the switch sets up flows that expire after the given * number of seconds (or never expire, if the value is OFP_FLOW_PERMANENT). * Otherwise, the switch processes every packet. */ int max_idle; enum ofputil_protocol protocol; unsigned long long int datapath_id; struct mac_learning *ml; /* NULL to act as hub instead of switch. */ struct flow_wildcards wc; /* Wildcards to apply to flows. */ bool action_normal; /* Use OFPP_NORMAL? */ /* Queue distribution. */ uint32_t default_queue; /* Default OpenFlow queue, or UINT32_MAX. */ struct hmap queue_numbers; /* Map from port number to lswitch_port. */ struct shash queue_names; /* Map from port name to lswitch_port. */ /* Number of outgoing queued packets on the rconn. */ struct rconn_packet_counter *queued; /* If true, do not reply to any messages from the switch (for debugging * fail-open mode). */ bool mute; /* Optional "flow mod" requests to send to the switch at connection time, * to set up the flow table. */ const struct ofputil_flow_mod *default_flows; size_t n_default_flows; enum ofputil_protocol usable_protocols; }; /* The log messages here could actually be useful in debugging, so keep the * rate limit relatively high. */ static struct vlog_rate_limit rl = VLOG_RATE_LIMIT_INIT(30, 300); static void queue_tx(struct lswitch *, struct ofpbuf *); static void send_features_request(struct lswitch *); static void lswitch_process_packet(struct lswitch *, const struct ofpbuf *); static enum ofperr process_switch_features(struct lswitch *, struct ofp_header *); static void process_packet_in(struct lswitch *, const struct ofp_header *); static void process_echo_request(struct lswitch *, const struct ofp_header *); /* Creates and returns a new learning switch whose configuration is given by * 'cfg'. * * 'rconn' is used to send out an OpenFlow features request. */ struct lswitch * lswitch_create(struct rconn *rconn, const struct lswitch_config *cfg) { struct lswitch *sw; uint32_t ofpfw; sw = xzalloc(sizeof *sw); sw->rconn = rconn; sw->state = S_CONNECTING; sw->max_idle = cfg->max_idle; sw->datapath_id = 0; sw->ml = (cfg->mode == LSW_LEARN ? mac_learning_create(MAC_ENTRY_DEFAULT_IDLE_TIME) : NULL); sw->action_normal = cfg->mode == LSW_NORMAL; switch (cfg->wildcards) { case 0: ofpfw = 0; break; case UINT32_MAX: /* Try to wildcard as many fields as possible, but we cannot * wildcard all fields. We need in_port to detect moves. We need * Ethernet source and dest and VLAN VID to do L2 learning. */ ofpfw = (OFPFW10_DL_TYPE | OFPFW10_DL_VLAN_PCP | OFPFW10_NW_SRC_ALL | OFPFW10_NW_DST_ALL | OFPFW10_NW_TOS | OFPFW10_NW_PROTO | OFPFW10_TP_SRC | OFPFW10_TP_DST); break; default: ofpfw = cfg->wildcards; break; } ofputil_wildcard_from_ofpfw10(ofpfw, &sw->wc); sw->default_queue = cfg->default_queue; hmap_init(&sw->queue_numbers); shash_init(&sw->queue_names); if (cfg->port_queues) { struct simap_node *node; SIMAP_FOR_EACH (node, cfg->port_queues) { struct lswitch_port *port = xmalloc(sizeof *port); hmap_node_nullify(&port->hmap_node); port->queue_id = node->data; shash_add(&sw->queue_names, node->name, port); } } sw->default_flows = cfg->default_flows; sw->n_default_flows = cfg->n_default_flows; sw->usable_protocols = cfg->usable_protocols; sw->queued = rconn_packet_counter_create(); return sw; } static void lswitch_handshake(struct lswitch *sw) { enum ofputil_protocol protocol; send_features_request(sw); protocol = ofputil_protocol_from_ofp_version(rconn_get_version(sw->rconn)); if (sw->default_flows) { struct ofpbuf *msg = NULL; int error = 0; size_t i; /* If the initial protocol isn't good enough for default_flows, then * pick one that will work and encode messages to set up that * protocol. * * This could be improved by actually negotiating a mutually acceptable * flow format with the switch, but that would require an asynchronous * state machine. This version ought to work fine in practice. */ if (!(protocol & sw->usable_protocols)) { enum ofputil_protocol want = rightmost_1bit(sw->usable_protocols); while (!error) { msg = ofputil_encode_set_protocol(protocol, want, &protocol); if (!msg) { break; } error = rconn_send(sw->rconn, msg, NULL); } } if (protocol & sw->usable_protocols) { for (i = 0; !error && i < sw->n_default_flows; i++) { msg = ofputil_encode_flow_mod(&sw->default_flows[i], protocol); error = rconn_send(sw->rconn, msg, NULL); } if (error) { VLOG_INFO_RL(&rl, "%s: failed to queue default flows (%s)", rconn_get_name(sw->rconn), ovs_strerror(error)); } } else { VLOG_INFO_RL(&rl, "%s: failed to set usable protocol", rconn_get_name(sw->rconn)); } } sw->protocol = protocol; } bool lswitch_is_alive(const struct lswitch *sw) { return rconn_is_alive(sw->rconn); } /* Destroys 'sw'. */ void lswitch_destroy(struct lswitch *sw) { if (sw) { struct lswitch_port *node, *next; rconn_destroy(sw->rconn); HMAP_FOR_EACH_SAFE (node, next, hmap_node, &sw->queue_numbers) { hmap_remove(&sw->queue_numbers, &node->hmap_node); free(node); } shash_destroy(&sw->queue_names); mac_learning_unref(sw->ml); rconn_packet_counter_destroy(sw->queued); free(sw); } } /* Takes care of necessary 'sw' activity, except for receiving packets (which * the caller must do). */ void lswitch_run(struct lswitch *sw) { int i; if (sw->ml) { ovs_rwlock_wrlock(&sw->ml->rwlock); mac_learning_run(sw->ml); ovs_rwlock_unlock(&sw->ml->rwlock); } rconn_run(sw->rconn); if (sw->state == S_CONNECTING) { if (rconn_get_version(sw->rconn) != -1) { lswitch_handshake(sw); sw->state = S_FEATURES_REPLY; } return; } for (i = 0; i < 50; i++) { struct ofpbuf *msg; msg = rconn_recv(sw->rconn); if (!msg) { break; } if (!sw->mute) { lswitch_process_packet(sw, msg); } ofpbuf_delete(msg); } } void lswitch_wait(struct lswitch *sw) { if (sw->ml) { ovs_rwlock_rdlock(&sw->ml->rwlock); mac_learning_wait(sw->ml); ovs_rwlock_unlock(&sw->ml->rwlock); } rconn_run_wait(sw->rconn); rconn_recv_wait(sw->rconn); } /* Processes 'msg', which should be an OpenFlow received on 'rconn', according * to the learning switch state in 'sw'. The most likely result of processing * is that flow-setup and packet-out OpenFlow messages will be sent out on * 'rconn'. */ static void lswitch_process_packet(struct lswitch *sw, const struct ofpbuf *msg) { enum ofptype type; struct ofpbuf b; b = *msg; if (ofptype_pull(&type, &b)) { return; } if (sw->state == S_FEATURES_REPLY && type != OFPTYPE_ECHO_REQUEST && type != OFPTYPE_FEATURES_REPLY) { return; } switch (type) { case OFPTYPE_ECHO_REQUEST: process_echo_request(sw, ofpbuf_data(msg)); break; case OFPTYPE_FEATURES_REPLY: if (sw->state == S_FEATURES_REPLY) { if (!process_switch_features(sw, ofpbuf_data(msg))) { sw->state = S_SWITCHING; } else { rconn_disconnect(sw->rconn); } } break; case OFPTYPE_PACKET_IN: process_packet_in(sw, ofpbuf_data(msg)); break; case OFPTYPE_FLOW_REMOVED: /* Nothing to do. */ break; case OFPTYPE_HELLO: case OFPTYPE_ERROR: case OFPTYPE_ECHO_REPLY: case OFPTYPE_FEATURES_REQUEST: case OFPTYPE_GET_CONFIG_REQUEST: case OFPTYPE_GET_CONFIG_REPLY: case OFPTYPE_SET_CONFIG: case OFPTYPE_PORT_STATUS: case OFPTYPE_PACKET_OUT: case OFPTYPE_FLOW_MOD: case OFPTYPE_GROUP_MOD: case OFPTYPE_PORT_MOD: case OFPTYPE_TABLE_MOD: case OFPTYPE_BARRIER_REQUEST: case OFPTYPE_BARRIER_REPLY: case OFPTYPE_QUEUE_GET_CONFIG_REQUEST: case OFPTYPE_QUEUE_GET_CONFIG_REPLY: case OFPTYPE_DESC_STATS_REQUEST: case OFPTYPE_DESC_STATS_REPLY: case OFPTYPE_FLOW_STATS_REQUEST: case OFPTYPE_FLOW_STATS_REPLY: case OFPTYPE_AGGREGATE_STATS_REQUEST: case OFPTYPE_AGGREGATE_STATS_REPLY: case OFPTYPE_TABLE_STATS_REQUEST: case OFPTYPE_TABLE_STATS_REPLY: case OFPTYPE_PORT_STATS_REQUEST: case OFPTYPE_PORT_STATS_REPLY: case OFPTYPE_QUEUE_STATS_REQUEST: case OFPTYPE_QUEUE_STATS_REPLY: case OFPTYPE_PORT_DESC_STATS_REQUEST: case OFPTYPE_PORT_DESC_STATS_REPLY: case OFPTYPE_ROLE_REQUEST: case OFPTYPE_ROLE_REPLY: case OFPTYPE_ROLE_STATUS: case OFPTYPE_SET_FLOW_FORMAT: case OFPTYPE_FLOW_MOD_TABLE_ID: case OFPTYPE_SET_PACKET_IN_FORMAT: case OFPTYPE_FLOW_AGE: case OFPTYPE_SET_CONTROLLER_ID: case OFPTYPE_FLOW_MONITOR_STATS_REQUEST: case OFPTYPE_FLOW_MONITOR_STATS_REPLY: case OFPTYPE_FLOW_MONITOR_CANCEL: case OFPTYPE_FLOW_MONITOR_PAUSED: case OFPTYPE_FLOW_MONITOR_RESUMED: case OFPTYPE_GET_ASYNC_REQUEST: case OFPTYPE_GET_ASYNC_REPLY: case OFPTYPE_SET_ASYNC_CONFIG: case OFPTYPE_METER_MOD: case OFPTYPE_GROUP_STATS_REQUEST: case OFPTYPE_GROUP_STATS_REPLY: case OFPTYPE_GROUP_DESC_STATS_REQUEST: case OFPTYPE_GROUP_DESC_STATS_REPLY: case OFPTYPE_GROUP_FEATURES_STATS_REQUEST: case OFPTYPE_GROUP_FEATURES_STATS_REPLY: case OFPTYPE_METER_STATS_REQUEST: case OFPTYPE_METER_STATS_REPLY: case OFPTYPE_METER_CONFIG_STATS_REQUEST: case OFPTYPE_METER_CONFIG_STATS_REPLY: case OFPTYPE_METER_FEATURES_STATS_REQUEST: case OFPTYPE_METER_FEATURES_STATS_REPLY: case OFPTYPE_TABLE_FEATURES_STATS_REQUEST: case OFPTYPE_TABLE_FEATURES_STATS_REPLY: case OFPTYPE_BUNDLE_CONTROL: case OFPTYPE_BUNDLE_ADD_MESSAGE: default: if (VLOG_IS_DBG_ENABLED()) { char *s = ofp_to_string(ofpbuf_data(msg), ofpbuf_size(msg), 2); VLOG_DBG_RL(&rl, "%016llx: OpenFlow packet ignored: %s", sw->datapath_id, s); free(s); } } } static void send_features_request(struct lswitch *sw) { struct ofpbuf *b; struct ofp_switch_config *osc; int ofp_version = rconn_get_version(sw->rconn); ovs_assert(ofp_version > 0 && ofp_version < 0xff); /* Send OFPT_FEATURES_REQUEST. */ b = ofpraw_alloc(OFPRAW_OFPT_FEATURES_REQUEST, ofp_version, 0); queue_tx(sw, b); /* Send OFPT_SET_CONFIG. */ b = ofpraw_alloc(OFPRAW_OFPT_SET_CONFIG, ofp_version, sizeof *osc); osc = ofpbuf_put_zeros(b, sizeof *osc); osc->miss_send_len = htons(OFP_DEFAULT_MISS_SEND_LEN); queue_tx(sw, b); } static void queue_tx(struct lswitch *sw, struct ofpbuf *b) { int retval = rconn_send_with_limit(sw->rconn, b, sw->queued, 10); if (retval && retval != ENOTCONN) { if (retval == EAGAIN) { VLOG_INFO_RL(&rl, "%016llx: %s: tx queue overflow", sw->datapath_id, rconn_get_name(sw->rconn)); } else { VLOG_WARN_RL(&rl, "%016llx: %s: send: %s", sw->datapath_id, rconn_get_name(sw->rconn), ovs_strerror(retval)); } } } static enum ofperr process_switch_features(struct lswitch *sw, struct ofp_header *oh) { struct ofputil_switch_features features; struct ofputil_phy_port port; enum ofperr error; struct ofpbuf b; error = ofputil_decode_switch_features(oh, &features, &b); if (error) { VLOG_ERR("received invalid switch feature reply (%s)", ofperr_to_string(error)); return error; } sw->datapath_id = features.datapath_id; while (!ofputil_pull_phy_port(oh->version, &b, &port)) { struct lswitch_port *lp = shash_find_data(&sw->queue_names, port.name); if (lp && hmap_node_is_null(&lp->hmap_node)) { lp->port_no = port.port_no; hmap_insert(&sw->queue_numbers, &lp->hmap_node, hash_ofp_port(lp->port_no)); } } return 0; } static ofp_port_t lswitch_choose_destination(struct lswitch *sw, const struct flow *flow) { ofp_port_t out_port; /* Learn the source MAC. */ if (sw->ml) { ovs_rwlock_wrlock(&sw->ml->rwlock); if (mac_learning_may_learn(sw->ml, flow->dl_src, 0)) { struct mac_entry *mac = mac_learning_insert(sw->ml, flow->dl_src, 0); if (mac->port.ofp_port != flow->in_port.ofp_port) { VLOG_DBG_RL(&rl, "%016llx: learned that "ETH_ADDR_FMT" is on " "port %"PRIu16, sw->datapath_id, ETH_ADDR_ARGS(flow->dl_src), flow->in_port.ofp_port); mac->port.ofp_port = flow->in_port.ofp_port; mac_learning_changed(sw->ml); } } ovs_rwlock_unlock(&sw->ml->rwlock); } /* Drop frames for reserved multicast addresses. */ if (eth_addr_is_reserved(flow->dl_dst)) { return OFPP_NONE; } out_port = OFPP_FLOOD; if (sw->ml) { struct mac_entry *mac; ovs_rwlock_rdlock(&sw->ml->rwlock); mac = mac_learning_lookup(sw->ml, flow->dl_dst, 0); if (mac) { out_port = mac->port.ofp_port; if (out_port == flow->in_port.ofp_port) { /* Don't send a packet back out its input port. */ ovs_rwlock_unlock(&sw->ml->rwlock); return OFPP_NONE; } } ovs_rwlock_unlock(&sw->ml->rwlock); } /* Check if we need to use "NORMAL" action. */ if (sw->action_normal && out_port != OFPP_FLOOD) { return OFPP_NORMAL; } return out_port; } static uint32_t get_queue_id(const struct lswitch *sw, ofp_port_t in_port) { const struct lswitch_port *port; HMAP_FOR_EACH_WITH_HASH (port, hmap_node, hash_ofp_port(in_port), &sw->queue_numbers) { if (port->port_no == in_port) { return port->queue_id; } } return sw->default_queue; } static void process_packet_in(struct lswitch *sw, const struct ofp_header *oh) { struct ofputil_packet_in pi; uint32_t queue_id; ofp_port_t out_port; uint64_t ofpacts_stub[64 / 8]; struct ofpbuf ofpacts; struct ofputil_packet_out po; enum ofperr error; struct ofpbuf pkt; struct flow flow; error = ofputil_decode_packet_in(&pi, oh); if (error) { VLOG_WARN_RL(&rl, "failed to decode packet-in: %s", ofperr_to_string(error)); return; } /* Ignore packets sent via output to OFPP_CONTROLLER. This library never * uses such an action. You never know what experiments might be going on, * though, and it seems best not to interfere with them. */ if (pi.reason != OFPR_NO_MATCH) { return; } /* Extract flow data from 'opi' into 'flow'. */ ofpbuf_use_const(&pkt, pi.packet, pi.packet_len); flow_extract(&pkt, NULL, &flow); flow.in_port.ofp_port = pi.fmd.in_port; flow.tunnel.tun_id = pi.fmd.tun_id; /* Choose output port. */ out_port = lswitch_choose_destination(sw, &flow); /* Make actions. */ queue_id = get_queue_id(sw, pi.fmd.in_port); ofpbuf_use_stack(&ofpacts, ofpacts_stub, sizeof ofpacts_stub); if (out_port == OFPP_NONE) { /* No actions. */ } else if (queue_id == UINT32_MAX || ofp_to_u16(out_port) >= ofp_to_u16(OFPP_MAX)) { ofpact_put_OUTPUT(&ofpacts)->port = out_port; } else { struct ofpact_enqueue *enqueue = ofpact_put_ENQUEUE(&ofpacts); enqueue->port = out_port; enqueue->queue = queue_id; } ofpact_pad(&ofpacts); /* Prepare packet_out in case we need one. */ po.buffer_id = pi.buffer_id; if (po.buffer_id == UINT32_MAX) { po.packet = ofpbuf_data(&pkt); po.packet_len = ofpbuf_size(&pkt); } else { po.packet = NULL; po.packet_len = 0; } po.in_port = pi.fmd.in_port; po.ofpacts = ofpbuf_data(&ofpacts); po.ofpacts_len = ofpbuf_size(&ofpacts); /* Send the packet, and possibly the whole flow, to the output port. */ if (sw->max_idle >= 0 && (!sw->ml || out_port != OFPP_FLOOD)) { struct ofputil_flow_mod fm; struct ofpbuf *buffer; /* The output port is known, or we always flood everything, so add a * new flow. */ memset(&fm, 0, sizeof fm); match_init(&fm.match, &flow, &sw->wc); ofputil_normalize_match_quiet(&fm.match); fm.priority = 0; fm.table_id = 0xff; fm.command = OFPFC_ADD; fm.idle_timeout = sw->max_idle; fm.buffer_id = pi.buffer_id; fm.out_port = OFPP_NONE; fm.ofpacts = ofpbuf_data(&ofpacts); fm.ofpacts_len = ofpbuf_size(&ofpacts); buffer = ofputil_encode_flow_mod(&fm, sw->protocol); queue_tx(sw, buffer); /* If the switch didn't buffer the packet, we need to send a copy. */ if (pi.buffer_id == UINT32_MAX && out_port != OFPP_NONE) { queue_tx(sw, ofputil_encode_packet_out(&po, sw->protocol)); } } else { /* We don't know that MAC, or we don't set up flows. Send along the * packet without setting up a flow. */ if (pi.buffer_id != UINT32_MAX || out_port != OFPP_NONE) { queue_tx(sw, ofputil_encode_packet_out(&po, sw->protocol)); } } } static void process_echo_request(struct lswitch *sw, const struct ofp_header *rq) { queue_tx(sw, make_echo_reply(rq)); }