#include <arpa/inet.h>
#include <errno.h>
#include <inttypes.h>
+#include <sys/socket.h>
#include <net/if.h>
#include <string.h>
#include <stdlib.h>
+#include "classifier.h"
#include "dhcp.h"
#include "dpif.h"
#include "flow.h"
-#include "mac-learning.h"
#include "netdev.h"
+#include "netlink.h"
#include "odp-util.h"
-#include "ofp-print.h"
#include "ofproto.h"
#include "ofpbuf.h"
#include "openflow/openflow.h"
-#include "openvswitch/datapath-protocol.h"
#include "packets.h"
#include "poll-loop.h"
-#include "rconn.h"
#include "status.h"
#include "timeval.h"
-#include "vconn.h"
-
-#define THIS_MODULE VLM_in_band
#include "vlog.h"
+VLOG_DEFINE_THIS_MODULE(in_band);
+
/* In-band control allows a single network to be used for OpenFlow
- * traffic and other data traffic. Refer to ovs-vswitchd.conf(5) and
+ * traffic and other data traffic. Refer to ovs-vswitchd.conf(5) and
* secchan(8) for a description of configuring in-band control.
*
* This comment is an attempt to describe how in-band control works at a
* gone through many iterations. Please read through and understand the
* reasoning behind the chosen rules before making modifications.
*
- * In Open vSwitch, in-band control is implemented as "hidden" flows (in
- * that they are not visible through OpenFlow) and at a higher priority
- * than wildcarded flows can be set up by the controller. This is done
- * so that the controller cannot interfere with them and possibly break
- * connectivity with its switches. It is possible to see all flows,
- * including in-band ones, with the ovs-appctl "bridge/dump-flows"
- * command.
+ * In Open vSwitch, in-band control is implemented as "hidden" flows (in that
+ * they are not visible through OpenFlow) and at a higher priority than
+ * wildcarded flows can be set up by through OpenFlow. This is done so that
+ * the OpenFlow controller cannot interfere with them and possibly break
+ * connectivity with its switches. It is possible to see all flows, including
+ * in-band ones, with the ovs-appctl "bridge/dump-flows" command.
+ *
+ * The Open vSwitch implementation of in-band control can hide traffic to
+ * arbitrary "remotes", where each remote is one TCP port on one IP address.
+ * Currently the remotes are automatically configured as the in-band OpenFlow
+ * controllers plus the OVSDB managers, if any. (The latter is a requirement
+ * because OVSDB managers are responsible for configuring OpenFlow controllers,
+ * so if the manager cannot be reached then OpenFlow cannot be reconfigured.)
+ *
+ * The following rules (with the OFPP_NORMAL action) are set up on any bridge
+ * that has any remotes:
+ *
+ * (a) DHCP requests sent from the local port.
+ * (b) ARP replies to the local port's MAC address.
+ * (c) ARP requests from the local port's MAC address.
+ *
+ * In-band also sets up the following rules for each unique next-hop MAC
+ * address for the remotes' IPs (the "next hop" is either the remote
+ * itself, if it is on a local subnet, or the gateway to reach the remote):
+ *
+ * (d) ARP replies to the next hop's MAC address.
+ * (e) ARP requests from the next hop's MAC address.
+ *
+ * In-band also sets up the following rules for each unique remote IP address:
*
- * The following rules are always enabled with the "normal" action by a
- * switch with in-band control:
+ * (f) ARP replies containing the remote's IP address as a target.
+ * (g) ARP requests containing the remote's IP address as a source.
*
- * a. DHCP requests sent from the local port.
- * b. ARP replies to the local port's MAC address.
- * c. ARP requests from the local port's MAC address.
- * d. ARP replies to the remote side's MAC address. Note that the
- * remote side is either the controller or the gateway to reach
- * the controller.
- * e. ARP requests from the remote side's MAC address. Note that
- * like (d), the MAC is either for the controller or gateway.
- * f. ARP replies containing the controller's IP address as a target.
- * g. ARP requests containing the controller's IP address as a source.
- * h. OpenFlow (6633/tcp) traffic to the controller's IP.
- * i. OpenFlow (6633/tcp) traffic from the controller's IP.
+ * In-band also sets up the following rules for each unique remote (IP,port)
+ * pair:
+ *
+ * (h) TCP traffic to the remote's IP and port.
+ * (i) TCP traffic from the remote's IP and port.
*
* The goal of these rules is to be as narrow as possible to allow a
- * switch to join a network and be able to communicate with a
- * controller. As mentioned earlier, these rules have higher priority
- * than the controller's rules, so if they are too broad, they may
+ * switch to join a network and be able to communicate with the
+ * remotes. As mentioned earlier, these rules have higher priority
+ * than the controller's rules, so if they are too broad, they may
* prevent the controller from implementing its policy. As such,
* in-band actively monitors some aspects of flow and packet processing
* so that the rules can be made more precise.
* match entries, so in-band control is able to be very precise about
* the flows it prevents. Flows that miss in the datapath are sent to
* userspace to be processed, so preventing these flows from being
- * cached in the "fast path" does not affect correctness. The only type
- * of flow that is currently prevented is one that would prevent DHCP
- * replies from being seen by the local port. For example, a rule that
- * forwarded all DHCP traffic to the controller would not be allowed,
+ * cached in the "fast path" does not affect correctness. The only type
+ * of flow that is currently prevented is one that would prevent DHCP
+ * replies from being seen by the local port. For example, a rule that
+ * forwarded all DHCP traffic to the controller would not be allowed,
* but one that forwarded to all ports (including the local port) would.
*
* As mentioned earlier, packets that miss in the datapath are sent to
* the userspace for processing. The userspace has its own flow table,
- * the "classifier", so in-band checks whether any special processing
- * is needed before the classifier is consulted. If a packet is a DHCP
- * response to a request from the local port, the packet is forwarded to
- * the local port, regardless of the flow table. Note that this requires
- * L7 processing of DHCP replies to determine whether the 'chaddr' field
+ * the "classifier", so in-band checks whether any special processing
+ * is needed before the classifier is consulted. If a packet is a DHCP
+ * response to a request from the local port, the packet is forwarded to
+ * the local port, regardless of the flow table. Note that this requires
+ * L7 processing of DHCP replies to determine whether the 'chaddr' field
* matches the MAC address of the local port.
*
* It is interesting to note that for an L3-based in-band control
- * mechanism, the majority of rules are devoted to ARP traffic. At first
- * glance, some of these rules appear redundant. However, each serves an
- * important role. First, in order to determine the MAC address of the
- * remote side (controller or gateway) for other ARP rules, we must allow
- * ARP traffic for our local port with rules (b) and (c). If we are
- * between a switch and its connection to the controller, we have to
- * allow the other switch's ARP traffic to through. This is done with
+ * mechanism, the majority of rules are devoted to ARP traffic. At first
+ * glance, some of these rules appear redundant. However, each serves an
+ * important role. First, in order to determine the MAC address of the
+ * remote side (controller or gateway) for other ARP rules, we must allow
+ * ARP traffic for our local port with rules (b) and (c). If we are
+ * between a switch and its connection to the remote, we have to
+ * allow the other switch's ARP traffic to through. This is done with
* rules (d) and (e), since we do not know the addresses of the other
- * switches a priori, but do know the controller's or gateway's. Finally,
- * if the controller is running in a local guest VM that is not reached
- * through the local port, the switch that is connected to the VM must
- * allow ARP traffic based on the controller's IP address, since it will
- * not know the MAC address of the local port that is sending the traffic
- * or the MAC address of the controller in the guest VM.
+ * switches a priori, but do know the remote's or gateway's. Finally,
+ * if the remote is running in a local guest VM that is not reached
+ * through the local port, the switch that is connected to the VM must
+ * allow ARP traffic based on the remote's IP address, since it will
+ * not know the MAC address of the local port that is sending the traffic
+ * or the MAC address of the remote in the guest VM.
*
* With a few notable exceptions below, in-band should work in most
* network setups. The following are considered "supported' in the
- * current implementation:
+ * current implementation:
*
- * - Locally Connected. The switch and controller are on the same
+ * - Locally Connected. The switch and remote are on the same
* subnet. This uses rules (a), (b), (c), (h), and (i).
*
- * - Reached through Gateway. The switch and controller are on
+ * - Reached through Gateway. The switch and remote are on
* different subnets and must go through a gateway. This uses
* rules (a), (b), (c), (h), and (i).
*
- * - Between Switch and Controller. This switch is between another
- * switch and the controller, and we want to allow the other
+ * - Between Switch and Remote. This switch is between another
+ * switch and the remote, and we want to allow the other
* switch's traffic through. This uses rules (d), (e), (h), and
* (i). It uses (b) and (c) indirectly in order to know the MAC
* address for rules (d) and (e). Note that DHCP for the other
- * switch will not work unless the controller explicitly lets this
+ * switch will not work unless an OpenFlow controller explicitly lets this
* switch pass the traffic.
*
* - Between Switch and Gateway. This switch is between another
* switch and the gateway, and we want to allow the other switch's
* traffic through. This uses the same rules and logic as the
- * "Between Switch and Controller" configuration described earlier.
+ * "Between Switch and Remote" configuration described earlier.
*
- * - Controller on Local VM. The controller is a guest VM on the
- * system running in-band control. This uses rules (a), (b), (c),
+ * - Remote on Local VM. The remote is a guest VM on the
+ * system running in-band control. This uses rules (a), (b), (c),
* (h), and (i).
*
- * - Controller on Local VM with Different Networks. The controller
+ * - Remote on Local VM with Different Networks. The remote
* is a guest VM on the system running in-band control, but the
- * local port is not used to connect to the controller. For
+ * local port is not used to connect to the remote. For
* example, an IP address is configured on eth0 of the switch. The
- * controller's VM is connected through eth1 of the switch, but an
+ * remote's VM is connected through eth1 of the switch, but an
* IP address has not been configured for that port on the switch.
- * As such, the switch will use eth0 to connect to the controller,
+ * As such, the switch will use eth0 to connect to the remote,
* and eth1's rules about the local port will not work. In the
- * example, the switch attached to eth0 would use rules (a), (b),
- * (c), (h), and (i) on eth0. The switch attached to eth1 would use
+ * example, the switch attached to eth0 would use rules (a), (b),
+ * (c), (h), and (i) on eth0. The switch attached to eth1 would use
* rules (f), (g), (h), and (i).
*
* The following are explicitly *not* supported by in-band control:
*
- * - Specify Controller by Name. Currently, the controller must be
+ * - Specify Remote by Name. Currently, the remote must be
* identified by IP address. A naive approach would be to permit
* all DNS traffic. Unfortunately, this would prevent the
* controller from defining any policy over DNS. Since switches
- * that are located behind us need to connect to the controller,
+ * that are located behind us need to connect to the remote,
* in-band cannot simply add a rule that allows DNS traffic from
* the local port. The "correct" way to support this is to parse
* DNS requests to allow all traffic related to a request for the
- * controller's name through. Due to the potential security
+ * remote's name through. Due to the potential security
* problems and amount of processing, we decided to hold off for
* the time-being.
*
- * - Differing Controllers for Switches. All switches must know
- * the L3 addresses for all the controllers that other switches
+ * - Differing Remotes for Switches. All switches must know
+ * the L3 addresses for all the remotes that other switches
* may use, since rules need to be set up to allow traffic related
- * to those controllers through. See rules (f), (g), (h), and (i).
+ * to those remotes through. See rules (f), (g), (h), and (i).
*
- * - Differing Routes for Switches. In order for the switch to
- * allow other switches to connect to a controller through a
+ * - Differing Routes for Switches. In order for the switch to
+ * allow other switches to connect to a remote through a
* gateway, it allows the gateway's traffic through with rules (d)
- * and (e). If the routes to the controller differ for the two
- * switches, we will not know the MAC address of the alternate
+ * and (e). If the routes to the remote differ for the two
+ * switches, we will not know the MAC address of the alternate
* gateway.
*/
* by in-band control have the same action. The only reason to use more than
* one priority is to make the kind of flow easier to see during debugging. */
enum {
+ /* One set per bridge. */
IBR_FROM_LOCAL_DHCP = 180000, /* (a) From local port, DHCP. */
IBR_TO_LOCAL_ARP, /* (b) To local port, ARP. */
IBR_FROM_LOCAL_ARP, /* (c) From local port, ARP. */
- IBR_TO_REMOTE_ARP, /* (d) To remote MAC, ARP. */
- IBR_FROM_REMOTE_ARP, /* (e) From remote MAC, ARP. */
- IBR_TO_CTL_ARP, /* (f) To controller IP, ARP. */
- IBR_FROM_CTL_ARP, /* (g) From controller IP, ARP. */
- IBR_TO_CTL_OFP, /* (h) To controller, OpenFlow port. */
- IBR_FROM_CTL_OFP /* (i) From controller, OpenFlow port. */
-};
-struct in_band_rule {
- flow_t flow;
- uint32_t wildcards;
- unsigned int priority;
+ /* One set per unique next-hop MAC. */
+ IBR_TO_NEXT_HOP_ARP, /* (d) To remote MAC, ARP. */
+ IBR_FROM_NEXT_HOP_ARP, /* (e) From remote MAC, ARP. */
+
+ /* One set per unique remote IP address. */
+ IBR_TO_REMOTE_ARP, /* (f) To remote IP, ARP. */
+ IBR_FROM_REMOTE_ARP, /* (g) From remote IP, ARP. */
+
+ /* One set per unique remote (IP,port) pair. */
+ IBR_TO_REMOTE_TCP, /* (h) To remote IP, TCP port. */
+ IBR_FROM_REMOTE_TCP /* (i) From remote IP, TCP port. */
};
/* Track one remote IP and next hop information. */
struct in_band_remote {
- struct rconn *rconn; /* Connection to remote. */
- uint32_t remote_ip; /* Remote IP, 0 if unknown. */
+ struct sockaddr_in remote_addr; /* IP address, in network byte order. */
uint8_t remote_mac[ETH_ADDR_LEN]; /* Next-hop MAC, all-zeros if unknown. */
uint8_t last_remote_mac[ETH_ADDR_LEN]; /* Previous nonzero next-hop MAC. */
struct netdev *remote_netdev; /* Device to send to next-hop MAC. */
struct in_band {
struct ofproto *ofproto;
struct status_category *ss_cat;
+ int queue_id, prev_queue_id;
/* Remote information. */
time_t next_remote_refresh; /* Refresh timer. */
/* Local and remote addresses that are installed as flows. */
uint8_t installed_local_mac[ETH_ADDR_LEN];
- uint32_t *remote_ips;
- uint32_t n_remote_ips;
+ struct sockaddr_in *remote_addrs;
+ size_t n_remote_addrs;
uint8_t *remote_macs;
size_t n_remote_macs;
};
static int
refresh_remote(struct in_band *ib, struct in_band_remote *r)
{
- struct in_addr remote_inaddr;
struct in_addr next_hop_inaddr;
char *next_hop_dev;
int retval;
- /* Get remote IP address. */
- r->remote_ip = rconn_get_remote_ip(r->rconn);
-
/* Find the next-hop IP address. */
- remote_inaddr.s_addr = r->remote_ip;
memset(r->remote_mac, 0, sizeof r->remote_mac);
- retval = netdev_get_next_hop(ib->local_netdev, &remote_inaddr,
+ retval = netdev_get_next_hop(ib->local_netdev, &r->remote_addr.sin_addr,
&next_hop_inaddr, &next_hop_dev);
if (retval) {
VLOG_WARN("cannot find route for controller ("IP_FMT"): %s",
- IP_ARGS(&r->remote_ip), strerror(retval));
+ IP_ARGS(&r->remote_addr.sin_addr), strerror(retval));
return 1;
}
if (!next_hop_inaddr.s_addr) {
- next_hop_inaddr.s_addr = remote_inaddr.s_addr;
+ next_hop_inaddr = r->remote_addr.sin_addr;
}
- /* Get the next-hop IP and network device. */
+ /* Open the next-hop network device. */
if (!r->remote_netdev
|| strcmp(netdev_get_name(r->remote_netdev), next_hop_dev))
{
if (retval) {
VLOG_WARN_RL(&rl, "cannot open netdev %s (next hop "
"to controller "IP_FMT"): %s",
- next_hop_dev, IP_ARGS(&r->remote_ip),
+ next_hop_dev, IP_ARGS(&r->remote_addr.sin_addr),
strerror(retval));
free(next_hop_dev);
return 1;
IP_ARGS(&next_hop_inaddr.s_addr), strerror(retval));
}
- /* If we have an IP address but not a MAC address, then refresh quickly,
- * since we probably will get a MAC address soon (via ARP). Otherwise, we
- * can afford to wait a little while. */
- return r->remote_ip && eth_addr_is_zero(r->remote_mac) ? 1 : 10;
+ /* If we don't have a MAC address, then refresh quickly, since we probably
+ * will get a MAC address soon (via ARP). Otherwise, we can afford to wait
+ * a little while. */
+ return eth_addr_is_zero(r->remote_mac) ? 1 : 10;
}
static bool
{
struct in_band_remote *r;
bool any_changes;
- int min_refresh;
if (time_now() < ib->next_remote_refresh) {
return false;
}
any_changes = false;
- min_refresh = 10;
+ ib->next_remote_refresh = TIME_MAX;
for (r = ib->remotes; r < &ib->remotes[ib->n_remotes]; r++) {
uint8_t old_remote_mac[ETH_ADDR_LEN];
- uint32_t old_remote_ip;
- int refresh_interval;
+ time_t next_refresh;
- /* Save old remote information. */
- old_remote_ip = r->remote_ip;
+ /* Save old MAC. */
memcpy(old_remote_mac, r->remote_mac, ETH_ADDR_LEN);
/* Refresh remote information. */
- refresh_interval = refresh_remote(ib, r);
- min_refresh = MIN(min_refresh, refresh_interval);
+ next_refresh = refresh_remote(ib, r) + time_now();
+ ib->next_remote_refresh = MIN(ib->next_remote_refresh, next_refresh);
- /* If anything changed, log the changes. */
- if (old_remote_ip != r->remote_ip) {
- any_changes = true;
- if (r->remote_ip) {
- VLOG_DBG("remote IP address changed from "IP_FMT" to "IP_FMT,
- IP_ARGS(&old_remote_ip), IP_ARGS(&r->remote_ip));
- }
- }
+ /* If the MAC changed, log the changes. */
if (!eth_addr_equals(r->remote_mac, old_remote_mac)) {
any_changes = true;
if (!eth_addr_is_zero(r->remote_mac)
}
}
}
- ib->next_remote_refresh = time_now() + min_refresh;
return any_changes;
}
}
/* Returns true if 'packet' should be sent to the local port regardless
- * of the flow table. */
+ * of the flow table. */
bool
-in_band_msg_in_hook(struct in_band *in_band, const flow_t *flow,
+in_band_msg_in_hook(struct in_band *in_band, const struct flow *flow,
const struct ofpbuf *packet)
{
if (!in_band) {
return false;
}
-/* Returns true if the rule that would match 'flow' with 'actions' is
+/* Returns true if the rule that would match 'flow' with 'actions' is
* allowed to be set up in the datapath. */
bool
-in_band_rule_check(struct in_band *in_band, const flow_t *flow,
- const struct odp_actions *actions)
+in_band_rule_check(struct in_band *in_band, const struct flow *flow,
+ const struct nlattr *actions, size_t actions_len)
{
if (!in_band) {
return true;
* by the local port. */
if (flow->dl_type == htons(ETH_TYPE_IP)
&& flow->nw_proto == IP_TYPE_UDP
- && flow->tp_src == htons(DHCP_SERVER_PORT)
+ && flow->tp_src == htons(DHCP_SERVER_PORT)
&& flow->tp_dst == htons(DHCP_CLIENT_PORT)) {
- int i;
+ const struct nlattr *a;
+ unsigned int left;
- for (i=0; i<actions->n_actions; i++) {
- if (actions->actions[i].output.type == ODPAT_OUTPUT
- && actions->actions[i].output.port == ODPP_LOCAL) {
+ NL_ATTR_FOR_EACH_UNSAFE (a, left, actions, actions_len) {
+ if (nl_attr_type(a) == ODPAT_OUTPUT
+ && nl_attr_get_u32(a) == ODPP_LOCAL) {
return true;
- }
+ }
}
return false;
}
return true;
}
-static void
-init_rule(struct in_band_rule *rule, unsigned int priority)
-{
- rule->wildcards = OVSFW_ALL;
- rule->priority = priority;
-
- /* Not strictly necessary but seems cleaner. */
- memset(&rule->flow, 0, sizeof rule->flow);
-}
-
-static void
-set_in_port(struct in_band_rule *rule, uint16_t odp_port)
-{
- rule->wildcards &= ~OFPFW_IN_PORT;
- rule->flow.in_port = odp_port;
-}
-
-static void
-set_dl_type(struct in_band_rule *rule, uint16_t dl_type)
-{
- rule->wildcards &= ~OFPFW_DL_TYPE;
- rule->flow.dl_type = htons(dl_type);
-}
-
-static void
-set_dl_src(struct in_band_rule *rule, const uint8_t dl_src[ETH_ADDR_LEN])
-{
- rule->wildcards &= ~OFPFW_DL_SRC;
- memcpy(rule->flow.dl_src, dl_src, ETH_ADDR_LEN);
-}
-
-static void
-set_dl_dst(struct in_band_rule *rule, const uint8_t dl_dst[ETH_ADDR_LEN])
-{
- rule->wildcards &= ~OFPFW_DL_DST;
- memcpy(rule->flow.dl_dst, dl_dst, ETH_ADDR_LEN);
-}
-
-static void
-set_tp_src(struct in_band_rule *rule, uint16_t tp_src)
-{
- rule->wildcards &= ~OFPFW_TP_SRC;
- rule->flow.tp_src = htons(tp_src);
-}
-
-static void
-set_tp_dst(struct in_band_rule *rule, uint16_t tp_dst)
-{
- rule->wildcards &= ~OFPFW_TP_DST;
- rule->flow.tp_dst = htons(tp_dst);
-}
-
-static void
-set_nw_proto(struct in_band_rule *rule, uint8_t nw_proto)
-{
- rule->wildcards &= ~OFPFW_NW_PROTO;
- rule->flow.nw_proto = nw_proto;
-}
-
-static void
-set_nw_src(struct in_band_rule *rule, uint32_t nw_src)
-{
- rule->wildcards &= ~OFPFW_NW_SRC_MASK;
- rule->flow.nw_src = nw_src;
-}
-
-static void
-set_nw_dst(struct in_band_rule *rule, uint32_t nw_dst)
-{
- rule->wildcards &= ~OFPFW_NW_DST_MASK;
- rule->flow.nw_dst = nw_dst;
-}
-
static void
make_rules(struct in_band *ib,
- void (*cb)(struct in_band *, const struct in_band_rule *))
+ void (*cb)(struct in_band *, const struct cls_rule *))
{
- struct in_band_rule rule;
+ struct cls_rule rule;
size_t i;
if (!eth_addr_is_zero(ib->installed_local_mac)) {
- /* Allow DHCP requests to be sent from the local port. */
- init_rule(&rule, IBR_FROM_LOCAL_DHCP);
- set_in_port(&rule, ODPP_LOCAL);
- set_dl_type(&rule, ETH_TYPE_IP);
- set_dl_src(&rule, ib->installed_local_mac);
- set_nw_proto(&rule, IP_TYPE_UDP);
- set_tp_src(&rule, DHCP_CLIENT_PORT);
- set_tp_dst(&rule, DHCP_SERVER_PORT);
+ /* (a) Allow DHCP requests sent from the local port. */
+ cls_rule_init_catchall(&rule, IBR_FROM_LOCAL_DHCP);
+ cls_rule_set_in_port(&rule, ODPP_LOCAL);
+ cls_rule_set_dl_type(&rule, htons(ETH_TYPE_IP));
+ cls_rule_set_dl_src(&rule, ib->installed_local_mac);
+ cls_rule_set_nw_proto(&rule, IP_TYPE_UDP);
+ cls_rule_set_tp_src(&rule, htons(DHCP_CLIENT_PORT));
+ cls_rule_set_tp_dst(&rule, htons(DHCP_SERVER_PORT));
cb(ib, &rule);
- /* Allow the connection's interface to receive directed ARP traffic. */
- init_rule(&rule, IBR_TO_LOCAL_ARP);
- set_dl_type(&rule, ETH_TYPE_ARP);
- set_dl_dst(&rule, ib->installed_local_mac);
- set_nw_proto(&rule, ARP_OP_REPLY);
+ /* (b) Allow ARP replies to the local port's MAC address. */
+ cls_rule_init_catchall(&rule, IBR_TO_LOCAL_ARP);
+ cls_rule_set_dl_type(&rule, htons(ETH_TYPE_ARP));
+ cls_rule_set_dl_dst(&rule, ib->installed_local_mac);
+ cls_rule_set_nw_proto(&rule, ARP_OP_REPLY);
cb(ib, &rule);
- /* Allow the connection's interface to be the source of ARP traffic. */
- init_rule(&rule, IBR_FROM_LOCAL_ARP);
- set_dl_type(&rule, ETH_TYPE_ARP);
- set_dl_src(&rule, ib->installed_local_mac);
- set_nw_proto(&rule, ARP_OP_REQUEST);
+ /* (c) Allow ARP requests from the local port's MAC address. */
+ cls_rule_init_catchall(&rule, IBR_FROM_LOCAL_ARP);
+ cls_rule_set_dl_type(&rule, htons(ETH_TYPE_ARP));
+ cls_rule_set_dl_src(&rule, ib->installed_local_mac);
+ cls_rule_set_nw_proto(&rule, ARP_OP_REQUEST);
cb(ib, &rule);
}
}
}
- /* Allow ARP replies to the remote side's MAC. */
- init_rule(&rule, IBR_TO_REMOTE_ARP);
- set_dl_type(&rule, ETH_TYPE_ARP);
- set_dl_dst(&rule, remote_mac);
- set_nw_proto(&rule, ARP_OP_REPLY);
+ /* (d) Allow ARP replies to the next hop's MAC address. */
+ cls_rule_init_catchall(&rule, IBR_TO_NEXT_HOP_ARP);
+ cls_rule_set_dl_type(&rule, htons(ETH_TYPE_ARP));
+ cls_rule_set_dl_dst(&rule, remote_mac);
+ cls_rule_set_nw_proto(&rule, ARP_OP_REPLY);
cb(ib, &rule);
- /* Allow ARP requests from the remote side's MAC. */
- init_rule(&rule, IBR_FROM_REMOTE_ARP);
- set_dl_type(&rule, ETH_TYPE_ARP);
- set_dl_src(&rule, remote_mac);
- set_nw_proto(&rule, ARP_OP_REQUEST);
+ /* (e) Allow ARP requests from the next hop's MAC address. */
+ cls_rule_init_catchall(&rule, IBR_FROM_NEXT_HOP_ARP);
+ cls_rule_set_dl_type(&rule, htons(ETH_TYPE_ARP));
+ cls_rule_set_dl_src(&rule, remote_mac);
+ cls_rule_set_nw_proto(&rule, ARP_OP_REQUEST);
cb(ib, &rule);
}
- for (i = 0; i < ib->n_remote_ips; i++) {
- uint32_t remote_ip = ib->remote_ips[i];
-
- if (i > 0 && ib->remote_ips[i - 1] == remote_ip) {
- /* Skip duplicates. */
- continue;
+ for (i = 0; i < ib->n_remote_addrs; i++) {
+ const struct sockaddr_in *a = &ib->remote_addrs[i];
+
+ if (!i || a->sin_addr.s_addr != a[-1].sin_addr.s_addr) {
+ /* (f) Allow ARP replies containing the remote's IP address as a
+ * target. */
+ cls_rule_init_catchall(&rule, IBR_TO_REMOTE_ARP);
+ cls_rule_set_dl_type(&rule, htons(ETH_TYPE_ARP));
+ cls_rule_set_nw_proto(&rule, ARP_OP_REPLY);
+ cls_rule_set_nw_dst(&rule, a->sin_addr.s_addr);
+ cb(ib, &rule);
+
+ /* (g) Allow ARP requests containing the remote's IP address as a
+ * source. */
+ cls_rule_init_catchall(&rule, IBR_FROM_REMOTE_ARP);
+ cls_rule_set_dl_type(&rule, htons(ETH_TYPE_ARP));
+ cls_rule_set_nw_proto(&rule, ARP_OP_REQUEST);
+ cls_rule_set_nw_src(&rule, a->sin_addr.s_addr);
+ cb(ib, &rule);
}
- /* Allow ARP replies to the controller's IP. */
- init_rule(&rule, IBR_TO_CTL_ARP);
- set_dl_type(&rule, ETH_TYPE_ARP);
- set_nw_proto(&rule, ARP_OP_REPLY);
- set_nw_dst(&rule, remote_ip);
- cb(ib, &rule);
-
- /* Allow ARP requests from the controller's IP. */
- init_rule(&rule, IBR_FROM_CTL_ARP);
- set_dl_type(&rule, ETH_TYPE_ARP);
- set_nw_proto(&rule, ARP_OP_REQUEST);
- set_nw_src(&rule, remote_ip);
- cb(ib, &rule);
-
- /* OpenFlow traffic to the controller. */
- init_rule(&rule, IBR_TO_CTL_OFP);
- set_dl_type(&rule, ETH_TYPE_IP);
- set_nw_proto(&rule, IP_TYPE_TCP);
- set_nw_dst(&rule, remote_ip);
- set_tp_dst(&rule, OFP_TCP_PORT);
- cb(ib, &rule);
-
- /* OpenFlow traffic from the controller. */
- init_rule(&rule, IBR_FROM_CTL_OFP);
- set_dl_type(&rule, ETH_TYPE_IP);
- set_nw_proto(&rule, IP_TYPE_TCP);
- set_nw_src(&rule, remote_ip);
- set_tp_src(&rule, OFP_TCP_PORT);
- cb(ib, &rule);
+ if (!i
+ || a->sin_addr.s_addr != a[-1].sin_addr.s_addr
+ || a->sin_port != a[-1].sin_port) {
+ /* (h) Allow TCP traffic to the remote's IP and port. */
+ cls_rule_init_catchall(&rule, IBR_TO_REMOTE_TCP);
+ cls_rule_set_dl_type(&rule, htons(ETH_TYPE_IP));
+ cls_rule_set_nw_proto(&rule, IP_TYPE_TCP);
+ cls_rule_set_nw_dst(&rule, a->sin_addr.s_addr);
+ cls_rule_set_tp_dst(&rule, a->sin_port);
+ cb(ib, &rule);
+
+ /* (i) Allow TCP traffic from the remote's IP and port. */
+ cls_rule_init_catchall(&rule, IBR_FROM_REMOTE_TCP);
+ cls_rule_set_dl_type(&rule, htons(ETH_TYPE_IP));
+ cls_rule_set_nw_proto(&rule, IP_TYPE_TCP);
+ cls_rule_set_nw_src(&rule, a->sin_addr.s_addr);
+ cls_rule_set_tp_src(&rule, a->sin_port);
+ cb(ib, &rule);
+ }
}
}
static void
-clear_rules(struct in_band *ib)
+drop_rule(struct in_band *ib, const struct cls_rule *rule)
{
+ ofproto_delete_flow(ib->ofproto, rule);
+}
+
+/* Drops from the flow table all of the flows set up by 'ib', then clears out
+ * the information about the installed flows so that they can be filled in
+ * again if necessary. */
+static void
+drop_rules(struct in_band *ib)
+{
+ /* Drop rules. */
+ make_rules(ib, drop_rule);
+
+ /* Clear out state. */
memset(ib->installed_local_mac, 0, sizeof ib->installed_local_mac);
- free(ib->remote_ips);
- ib->remote_ips = NULL;
- ib->n_remote_ips = 0;
+ free(ib->remote_addrs);
+ ib->remote_addrs = NULL;
+ ib->n_remote_addrs = 0;
free(ib->remote_macs);
ib->remote_macs = NULL;
}
static void
-drop_rule(struct in_band *ib, const struct in_band_rule *rule)
+add_rule(struct in_band *ib, const struct cls_rule *rule)
{
- ofproto_delete_flow(ib->ofproto, &rule->flow,
- rule->wildcards, rule->priority);
-}
+ struct {
+ struct nx_action_set_queue nxsq;
+ struct ofp_action_output oao;
+ } actions;
-static void
-drop_rules(struct in_band *ib)
-{
- make_rules(ib, drop_rule);
- clear_rules(ib);
-}
+ memset(&actions, 0, sizeof actions);
-static void
-add_rule(struct in_band *ib, const struct in_band_rule *rule)
-{
- union ofp_action action;
-
- action.type = htons(OFPAT_OUTPUT);
- action.output.len = htons(sizeof action);
- action.output.port = htons(OFPP_NORMAL);
- action.output.max_len = htons(0);
- ofproto_add_flow(ib->ofproto, &rule->flow, rule->wildcards,
- rule->priority, &action, 1, 0);
+ actions.oao.type = htons(OFPAT_OUTPUT);
+ actions.oao.len = htons(sizeof actions.oao);
+ actions.oao.port = htons(OFPP_NORMAL);
+ actions.oao.max_len = htons(0);
+
+ if (ib->queue_id < 0) {
+ ofproto_add_flow(ib->ofproto, rule,
+ (union ofp_action *) &actions.oao, 1);
+ } else {
+ actions.nxsq.type = htons(OFPAT_VENDOR);
+ actions.nxsq.len = htons(sizeof actions.nxsq);
+ actions.nxsq.vendor = htonl(NX_VENDOR_ID);
+ actions.nxsq.subtype = htons(NXAST_SET_QUEUE);
+ actions.nxsq.queue_id = htonl(ib->queue_id);
+
+ ofproto_add_flow(ib->ofproto, rule, (union ofp_action *) &actions,
+ sizeof actions / sizeof(union ofp_action));
+ }
}
+/* Inserts flows into the flow table for the current state of 'ib'. */
static void
add_rules(struct in_band *ib)
{
}
static int
-compare_ips(const void *a, const void *b)
+compare_addrs(const void *a_, const void *b_)
{
- return memcmp(a, b, sizeof(uint32_t));
+ const struct sockaddr_in *a = a_;
+ const struct sockaddr_in *b = b_;
+ int cmp;
+
+ cmp = memcmp(&a->sin_addr.s_addr,
+ &b->sin_addr.s_addr,
+ sizeof a->sin_addr.s_addr);
+ if (cmp) {
+ return cmp;
+ }
+ return memcmp(&a->sin_port, &b->sin_port, sizeof a->sin_port);
}
static int
void
in_band_run(struct in_band *ib)
{
+ bool local_change, remote_change, queue_id_change;
struct in_band_remote *r;
- bool local_change, remote_change;
local_change = refresh_local(ib);
remote_change = refresh_remotes(ib);
- if (!local_change && !remote_change) {
+ queue_id_change = ib->queue_id != ib->prev_queue_id;
+ if (!local_change && !remote_change && !queue_id_change) {
/* Nothing changed, nothing to do. */
return;
}
+ ib->prev_queue_id = ib->queue_id;
/* Drop old rules. */
drop_rules(ib);
/* Figure out new rules. */
memcpy(ib->installed_local_mac, ib->local_mac, ETH_ADDR_LEN);
- ib->remote_ips = xmalloc(ib->n_remotes * sizeof *ib->remote_ips);
- ib->n_remote_ips = 0;
+ ib->remote_addrs = xmalloc(ib->n_remotes * sizeof *ib->remote_addrs);
+ ib->n_remote_addrs = 0;
ib->remote_macs = xmalloc(ib->n_remotes * ETH_ADDR_LEN);
ib->n_remote_macs = 0;
for (r = ib->remotes; r < &ib->remotes[ib->n_remotes]; r++) {
- if (r->remote_ip) {
- ib->remote_ips[ib->n_remote_ips++] = r->remote_ip;
- }
+ ib->remote_addrs[ib->n_remote_addrs++] = r->remote_addr;
if (!eth_addr_is_zero(r->remote_mac)) {
memcpy(&ib->remote_macs[ib->n_remote_macs * ETH_ADDR_LEN],
r->remote_mac, ETH_ADDR_LEN);
}
/* Sort, to allow make_rules() to easily skip duplicates. */
- qsort(ib->remote_ips, ib->n_remote_ips, sizeof *ib->remote_ips,
- compare_ips);
+ qsort(ib->remote_addrs, ib->n_remote_addrs, sizeof *ib->remote_addrs,
+ compare_addrs);
qsort(ib->remote_macs, ib->n_remote_macs, ETH_ADDR_LEN, compare_macs);
/* Add new rules. */
void
in_band_wait(struct in_band *in_band)
{
- time_t now = time_now();
- time_t wakeup
+ long long int wakeup
= MIN(in_band->next_remote_refresh, in_band->next_local_refresh);
- if (wakeup > now) {
- poll_timer_wait((wakeup - now) * 1000);
- } else {
- poll_immediate_wake();
- }
+ poll_timer_wait_until(wakeup * 1000);
}
/* ofproto has flushed all flows from the flow table and it is calling us back
struct netdev *local_netdev;
int error;
+ *in_bandp = NULL;
error = dpif_port_get_name(dpif, ODPP_LOCAL,
local_name, sizeof local_name);
if (error) {
in_band->ofproto = ofproto;
in_band->ss_cat = switch_status_register(ss, "in-band",
in_band_status_cb, in_band);
+ in_band->queue_id = in_band->prev_queue_id = -1;
in_band->next_remote_refresh = TIME_MIN;
in_band->next_local_refresh = TIME_MIN;
in_band->local_netdev = local_netdev;
}
}
-void
-in_band_set_remotes(struct in_band *ib, struct rconn **remotes, size_t n)
+static bool
+any_addresses_changed(struct in_band *ib,
+ const struct sockaddr_in *addresses, size_t n)
{
size_t i;
- /* Optimize the case where the rconns are the same as last time. */
- if (n == ib->n_remotes) {
- for (i = 0; i < n; i++) {
- if (ib->remotes[i].rconn != remotes[i]) {
- goto different;
- }
+ if (n != ib->n_remotes) {
+ return true;
+ }
+
+ for (i = 0; i < n; i++) {
+ const struct sockaddr_in *old = &ib->remotes[i].remote_addr;
+ const struct sockaddr_in *new = &addresses[i];
+
+ if (old->sin_addr.s_addr != new->sin_addr.s_addr ||
+ old->sin_port != new->sin_port) {
+ return true;
}
- return;
+ }
- different:;
+ return false;
+}
+
+void
+in_band_set_remotes(struct in_band *ib,
+ const struct sockaddr_in *addresses, size_t n)
+{
+ size_t i;
+
+ if (!any_addresses_changed(ib, addresses, n)) {
+ return;
}
+ /* Clear old remotes. */
for (i = 0; i < ib->n_remotes; i++) {
- /* We don't own the rconn. */
netdev_close(ib->remotes[i].remote_netdev);
}
free(ib->remotes);
- ib->next_remote_refresh = TIME_MIN;
- ib->remotes = n ? xzalloc(n * sizeof *ib->remotes) : 0;
+ /* Set up new remotes. */
+ ib->remotes = n ? xzalloc(n * sizeof *ib->remotes) : NULL;
ib->n_remotes = n;
for (i = 0; i < n; i++) {
- ib->remotes[i].rconn = remotes[i];
+ ib->remotes[i].remote_addr = addresses[i];
}
+
+ /* Force refresh in next call to in_band_run(). */
+ ib->next_remote_refresh = TIME_MIN;
}
+
+/* Sets the OpenFlow queue used by flows set up by 'ib' to 'queue_id'. If
+ * 'queue_id' is negative, 'ib' will not set any queue (which is also the
+ * default). */
+void
+in_band_set_queue(struct in_band *ib, int queue_id)
+{
+ ib->queue_id = queue_id;
+}
+