ARP request and ND NS packets for router owned IPs were being flooded in the complete L2 domain (using the MC_FLOOD multicast group). However this creates a scaling issue in scenarios where aggregation logical switches are connected to more logical routers (~350). The logical pipelines of all routers would have to be executed before the packet is finally replied to by a single router, the owner of the IP address.
This commit limits the broadcast domain by bypassing the L2 Lookup stage for ARP requests that will be replied by a single router. The packets are forwarded only to the router port that owns the target IP address. IPs that are owned by the routers and for which this fix applies are: - IP addresses configured on the router ports. - VIPs. - NAT IPs. Reported-at: https://bugzilla.redhat.com/1756945 Reported-by: Anil Venkata <vkomm...@redhat.com> Signed-off-by: Dumitru Ceara <dce...@redhat.com> --- v7: - Address Han's comments: - Remove flooding for all ARPs received on VLAN networks. To avoid that we now identify self originated (G)ARPs by matching on source MAC address too. - Rename REGBIT_NOT_VXLAN to FLAGBIT_NOT_VXLAN. - Fix ovn-sb manpage. - Split patch in a series of 2: - patch1: fixes the get_router_load_balancer_ips() function. - patch2: limits the ARP/ND broadcast domain. v6: - Address Han's comments: - remove flooding of ARPs targeting OVN owned IP addresses. - update ovn-architecture documentation. - rename ARP handling functions. - Adapt "ovn -- 3 HVs, 3 LS, 3 lports/LS, 1 LR" autotest to take into account the new way of forwarding ARPs. - Also, properly deal with ARP packets on VLAN-backed networks. v5: Address Numan's comments: update comments & make autotest more robust. v4: Rebase. v3: Properly deal with VXLAN traffic. Address review comments from Numan (add autotests). Fix function get_router_load_balancer_ips. Rebase -> deal with IPv6 NAT too. v2: Move ARP broadcast domain limiting to table S_SWITCH_IN_L2_LKUP to address localnet ports too. --- northd/ovn-northd.8.xml | 14 ++ northd/ovn-northd.c | 230 +++++++++++++++++++++++++++++++---- ovn-architecture.7.xml | 19 +++ tests/ovn.at | 307 +++++++++++++++++++++++++++++++++++++++++++++-- 4 files changed, 530 insertions(+), 40 deletions(-) diff --git a/northd/ovn-northd.8.xml b/northd/ovn-northd.8.xml index 0a33dcd..344cc0d 100644 --- a/northd/ovn-northd.8.xml +++ b/northd/ovn-northd.8.xml @@ -1005,6 +1005,20 @@ output; </li> <li> + Priority-80 flows for each port connected to a logical router + matching self originated GARP/ARP request/ND packets. These packets + are flooded to the <code>MC_FLOOD</code> which contains all logical + ports. + </li> + + <li> + Priority-75 flows for each IP address/VIP/NAT address owned by a + router port connected to the switch. These flows match ARP requests + and ND packets for the specific IP addresses. Matched packets are + forwarded only to the router that owns the IP address. + </li> + + <li> A priority-70 flow that outputs all packets with an Ethernet broadcast or multicast <code>eth.dst</code> to the <code>MC_FLOOD</code> multicast group. diff --git a/northd/ovn-northd.c b/northd/ovn-northd.c index 32f3200..d6beb97 100644 --- a/northd/ovn-northd.c +++ b/northd/ovn-northd.c @@ -210,6 +210,8 @@ enum ovn_stage { #define REGBIT_LOOKUP_NEIGHBOR_RESULT "reg9[4]" #define REGBIT_SKIP_LOOKUP_NEIGHBOR "reg9[5]" +#define FLAGBIT_NOT_VXLAN "flags[1] == 0" + /* Returns an "enum ovn_stage" built from the arguments. */ static enum ovn_stage ovn_stage_build(enum ovn_datapath_type dp_type, enum ovn_pipeline pipeline, @@ -1202,6 +1204,34 @@ ovn_port_allocate_key(struct ovn_datapath *od) 1, (1u << 15) - 1, &od->port_key_hint); } +/* Returns true if the logical switch port 'enabled' column is empty or + * set to true. Otherwise, returns false. */ +static bool +lsp_is_enabled(const struct nbrec_logical_switch_port *lsp) +{ + return !lsp->n_enabled || *lsp->enabled; +} + +/* Returns true only if the logical switch port 'up' column is set to true. + * Otherwise, if the column is not set or set to false, returns false. */ +static bool +lsp_is_up(const struct nbrec_logical_switch_port *lsp) +{ + return lsp->n_up && *lsp->up; +} + +static bool +lsp_is_external(const struct nbrec_logical_switch_port *nbsp) +{ + return !strcmp(nbsp->type, "external"); +} + +static bool +lrport_is_enabled(const struct nbrec_logical_router_port *lrport) +{ + return !lrport->enabled || *lrport->enabled; +} + static char * chassis_redirect_name(const char *port_name) { @@ -3750,28 +3780,6 @@ build_port_security_ip(enum ovn_pipeline pipeline, struct ovn_port *op, } -/* Returns true if the logical switch port 'enabled' column is empty or - * set to true. Otherwise, returns false. */ -static bool -lsp_is_enabled(const struct nbrec_logical_switch_port *lsp) -{ - return !lsp->n_enabled || *lsp->enabled; -} - -/* Returns true only if the logical switch port 'up' column is set to true. - * Otherwise, if the column is not set or set to false, returns false. */ -static bool -lsp_is_up(const struct nbrec_logical_switch_port *lsp) -{ - return lsp->n_up && *lsp->up; -} - -static bool -lsp_is_external(const struct nbrec_logical_switch_port *nbsp) -{ - return !strcmp(nbsp->type, "external"); -} - static bool build_dhcpv4_action(struct ovn_port *op, ovs_be32 offer_ip, struct ds *options_action, struct ds *response_action, @@ -5174,6 +5182,170 @@ build_lrouter_groups(struct hmap *ports, struct ovs_list *lr_list) } } +/* + * Ingress table 17: Flows that flood self originated ARP/ND packets in the + * switching domain. + */ +static void +build_lswitch_rport_arp_req_self_orig_flow(struct ovn_port *op, + uint32_t priority, + struct ovn_datapath *od, + struct hmap *lflows) +{ + struct ds match = DS_EMPTY_INITIALIZER; + struct ds eth_src = DS_EMPTY_INITIALIZER; + + /* Self originated (G)ARP requests/ND need to be flooded as usual. + * Determine that packets are self originated by also matching on + * source MAC. Matching on ingress port is not reliable in case this + * is a VLAN-backed network. + * Priority: 80. + */ + ds_put_format(ð_src, "{ %s, ", op->lrp_networks.ea_s); + for (size_t i = 0; i < op->od->nbr->n_nat; i++) { + const struct nbrec_nat *nat = op->od->nbr->nat[i]; + + if (!nat->external_mac) { + continue; + } + + ds_put_format(ð_src, "%s, ", nat->external_mac); + } + ds_chomp(ð_src, ' '); + ds_chomp(ð_src, ','); + ds_put_cstr(ð_src, "}"); + + ds_put_format(&match, "eth.src == %s && (arp.op == 1 || nd_ns)", + ds_cstr(ð_src)); + ovn_lflow_add(lflows, od, S_SWITCH_IN_L2_LKUP, priority, + ds_cstr(&match), + "outport = \""MC_FLOOD"\"; output;"); + + ds_destroy(&match); + ds_destroy(ð_src); +} + +/* + * Ingress table 17: Flows that forward ARP/ND requests only to the routers + * that own the addresses. Other ARP/ND packets are still flooded in the + * switching domain as regular broadcast. + */ +static void +build_lswitch_rport_arp_req_flow_for_ip(struct sset *ips, + int addr_family, + struct ovn_port *patch_op, + struct ovn_datapath *od, + uint32_t priority, + struct hmap *lflows) +{ + struct ds match = DS_EMPTY_INITIALIZER; + struct ds actions = DS_EMPTY_INITIALIZER; + + /* Packets received from VXLAN tunnels have already been through the + * router pipeline so we should skip them. Normally this is done by the + * multicast_group implementation (VXLAN packets skip table 32 which + * delivers to patch ports) but we're bypassing multicast_groups. + */ + ds_put_cstr(&match, FLAGBIT_NOT_VXLAN " && "); + + if (addr_family == AF_INET) { + ds_put_cstr(&match, "arp.op == 1 && arp.tpa == { "); + } else { + ds_put_cstr(&match, "nd_ns && nd.target == { "); + } + + const char *ip_address; + SSET_FOR_EACH (ip_address, ips) { + ds_put_format(&match, "%s, ", ip_address); + } + + ds_chomp(&match, ' '); + ds_chomp(&match, ','); + ds_put_cstr(&match, "}"); + + /* Send a the packet only to the router pipeline and skip flooding it + * in the broadcast domain. + */ + ds_put_format(&actions, "outport = %s; output;", patch_op->json_key); + ovn_lflow_add(lflows, od, S_SWITCH_IN_L2_LKUP, priority, + ds_cstr(&match), ds_cstr(&actions)); + + ds_destroy(&match); + ds_destroy(&actions); +} + +/* + * Ingress table 17: Flows that forward ARP/ND requests only to the routers + * that own the addresses. + * Priorities: + * - 80: self originated GARPs that need to follow regular processing. + * - 75: ARP requests to router owned IPs (interface IP/LB/NAT). + */ +static void +build_lswitch_rport_arp_req_flows(struct ovn_port *op, + struct ovn_datapath *sw_od, + struct ovn_port *sw_op, + struct hmap *lflows) +{ + if (!op || !op->nbrp) { + return; + } + + if (!lrport_is_enabled(op->nbrp)) { + return; + } + + /* Self originated (G)ARP requests/ND need to be flooded as usual. + * Priority: 80. + */ + build_lswitch_rport_arp_req_self_orig_flow(op, 80, sw_od, lflows); + + /* Forward ARP requests for owned IP addresses (L3, VIP, NAT) only to this + * router port. + * Priority: 75. + */ + struct sset all_ips_v4 = SSET_INITIALIZER(&all_ips_v4); + struct sset all_ips_v6 = SSET_INITIALIZER(&all_ips_v6); + + for (size_t i = 0; i < op->lrp_networks.n_ipv4_addrs; i++) { + sset_add(&all_ips_v4, op->lrp_networks.ipv4_addrs[i].addr_s); + } + for (size_t i = 0; i < op->lrp_networks.n_ipv6_addrs; i++) { + sset_add(&all_ips_v6, op->lrp_networks.ipv6_addrs[i].addr_s); + } + + get_router_load_balancer_ips(op->od, &all_ips_v4, &all_ips_v6); + + for (size_t i = 0; i < op->od->nbr->n_nat; i++) { + const struct nbrec_nat *nat = op->od->nbr->nat[i]; + + if (!strcmp(nat->type, "snat")) { + continue; + } + + ovs_be32 ip; + ovs_be32 mask; + struct in6_addr ipv6; + struct in6_addr mask_v6; + + if (ip_parse_masked(nat->external_ip, &ip, &mask)) { + if (!ipv6_parse_masked(nat->external_ip, &ipv6, &mask_v6)) { + sset_add(&all_ips_v6, nat->external_ip); + } + } else { + sset_add(&all_ips_v4, nat->external_ip); + } + } + + build_lswitch_rport_arp_req_flow_for_ip(&all_ips_v4, AF_INET, sw_op, + sw_od, 75, lflows); + build_lswitch_rport_arp_req_flow_for_ip(&all_ips_v6, AF_INET6, sw_op, + sw_od, 75, lflows); + + sset_destroy(&all_ips_v4); + sset_destroy(&all_ips_v6); +} + static void build_lswitch_flows(struct hmap *datapaths, struct hmap *ports, struct hmap *port_groups, struct hmap *lflows, @@ -5761,6 +5933,14 @@ build_lswitch_flows(struct hmap *datapaths, struct hmap *ports, continue; } + /* For ports connected to logical routers add flows to bypass the + * broadcast flooding of ARP/ND requests in table 17. We direct the + * requests only to the router port that owns the IP address. + */ + if (!strcmp(op->nbsp->type, "router")) { + build_lswitch_rport_arp_req_flows(op->peer, op->od, op, lflows); + } + for (size_t i = 0; i < op->nbsp->n_addresses; i++) { /* Addresses are owned by the logical port. * Ethernet address followed by zero or more IPv4 @@ -5892,12 +6072,6 @@ build_lswitch_flows(struct hmap *datapaths, struct hmap *ports, ds_destroy(&actions); } -static bool -lrport_is_enabled(const struct nbrec_logical_router_port *lrport) -{ - return !lrport->enabled || *lrport->enabled; -} - /* Returns a string of the IP address of the router port 'op' that * overlaps with 'ip_s". If one is not found, returns NULL. * diff --git a/ovn-architecture.7.xml b/ovn-architecture.7.xml index 7966b65..c43f16d 100644 --- a/ovn-architecture.7.xml +++ b/ovn-architecture.7.xml @@ -1390,6 +1390,25 @@ http://docs.openvswitch.org/en/latest/topics/high-availability. </p> + <h3>ARP request and ND NS packet processing</h3> + + <p> + Due to the fact that ARP requests and ND NA packets are usually broadcast + packets, for performance reasons, OVN deals with requests that target OVN + owned IP addresses (i.e., IP addresses configured on the router ports, + VIPs, NAT IPs) in a specific way and only forwards them to the logical + router that owns the target IP address. This behavior is different than + that of traditional swithces and implies that other routers/hosts + connected to the logical switch will not learn the MAC/IP binding from + the request packet. + </p> + + <p> + All other ARP and ND packets are flooded in the L2 broadcast domain and + to all attached logical patch ports. + </p> + + <h2>Multiple localnet logical switches connected to a Logical Router</h2> <p> diff --git a/tests/ovn.at b/tests/ovn.at index 3e429e3..26e33d2 100644 --- a/tests/ovn.at +++ b/tests/ovn.at @@ -2877,7 +2877,7 @@ test_ip() { done } -# test_arp INPORT SHA SPA TPA [REPLY_HA] +# test_arp INPORT SHA SPA TPA FLOOD [REPLY_HA] # # Causes a packet to be received on INPORT. The packet is an ARP # request with SHA, SPA, and TPA as specified. If REPLY_HA is provided, then @@ -2888,21 +2888,25 @@ test_ip() { # SHA and REPLY_HA are each 12 hex digits. # SPA and TPA are each 8 hex digits. test_arp() { - local inport=$1 sha=$2 spa=$3 tpa=$4 reply_ha=$5 + local inport=$1 sha=$2 spa=$3 tpa=$4 flood=$5 reply_ha=$6 local request=ffffffffffff${sha}08060001080006040001${sha}${spa}ffffffffffff${tpa} hv=hv`vif_to_hv $inport` as $hv ovs-appctl netdev-dummy/receive vif$inport $request as $hv ovs-appctl ofproto/trace br-int in_port=$inport $request # Expect to receive the broadcast ARP on the other logical switch ports if - # IP address is not configured to the switch patch port. + # IP address is not configured on the switch patch port or on the router + # port (i.e, $flood == 1). local i=`vif_to_ls $inport` local j k for j in 1 2 3; do for k in 1 2 3; do - # 192.168.33.254 is configured to the switch patch port for lrp33, - # so no ARP flooding expected for it. - if test $i$j$k != $inport && test $tpa != `ip_to_hex 192 168 33 254`; then + # Skip ingress port. + if test $i$j$k == $inport; then + continue + fi + + if test X$flood == X1; then echo $request >> $i$j$k.expected fi done @@ -3039,9 +3043,9 @@ for i in 1 2 3; do otherip=`ip_to_hex 192 168 $i$j 55` # Some other IP in subnet externalip=`ip_to_hex 1 2 3 4` # Some other IP not in subnet - test_arp $i$j$k $smac $sip $rip $rmac #4 - test_arp $i$j$k $smac $otherip $rip $rmac #5 - test_arp $i$j$k $smac $sip $otherip #6 + test_arp $i$j$k $smac $sip $rip 0 $rmac #4 + test_arp $i$j$k $smac $otherip $rip 0 $rmac #5 + test_arp $i$j$k $smac $sip $otherip 1 #6 # When rip is 192.168.33.254, ARP request from externalip won't be # filtered, because 192.168.33.254 is configured to switch peer port @@ -3050,7 +3054,7 @@ for i in 1 2 3; do if test $i = 3 && test $j = 3; then lrp33_rsp=$rmac fi - test_arp $i$j$k $smac $externalip $rip $lrp33_rsp #7 + test_arp $i$j$k $smac $externalip $rip 0 $lrp33_rsp #7 # MAC binding should be learned from ARP request. host_mac_pretty=f0:00:00:00:0$i:$j$k @@ -9595,7 +9599,7 @@ ovn-nbctl --wait=hv --timeout=3 sync # Check that there is a logical flow in logical switch foo's pipeline # to set the outport to rp-foo (which is expected). OVS_WAIT_UNTIL([test 1 = `ovn-sbctl dump-flows foo | grep ls_in_l2_lkup | \ -grep rp-foo | grep -v is_chassis_resident | wc -l`]) +grep rp-foo | grep -v is_chassis_resident | grep priority=50 -c`]) # Set the option 'reside-on-redirect-chassis' for foo ovn-nbctl set logical_router_port foo options:reside-on-redirect-chassis=true @@ -9603,7 +9607,7 @@ ovn-nbctl set logical_router_port foo options:reside-on-redirect-chassis=true # to set the outport to rp-foo with the condition is_chassis_redirect. ovn-sbctl dump-flows foo OVS_WAIT_UNTIL([test 1 = `ovn-sbctl dump-flows foo | grep ls_in_l2_lkup | \ -grep rp-foo | grep is_chassis_resident | wc -l`]) +grep rp-foo | grep is_chassis_resident | grep priority=50 -c`]) echo "---------NB dump-----" ovn-nbctl show @@ -16694,3 +16698,282 @@ as hv4 ovs-appctl fdb/show br-phys OVN_CLEANUP([hv1],[hv2],[hv3],[hv4]) AT_CLEANUP + +AT_SETUP([ovn -- ARP/ND request broadcast limiting]) +AT_SKIP_IF([test $HAVE_PYTHON = no]) +ovn_start + +ip_to_hex() { + printf "%02x%02x%02x%02x" "$@" +} + +send_arp_request() { + local hv=$1 inport=$2 eth_src=$3 spa=$4 tpa=$5 + local eth_dst=ffffffffffff + local eth_type=0806 + local eth=${eth_dst}${eth_src}${eth_type} + + local arp=0001080006040001${eth_src}${spa}${eth_dst}${tpa} + + local request=${eth}${arp} + as hv$hv ovs-appctl netdev-dummy/receive hv${hv}-vif$inport $request +} + +send_nd_ns() { + local hv=$1 inport=$2 eth_src=$3 spa=$4 tpa=$5 cksum=$6 + + local eth_dst=ffffffffffff + local eth_type=86dd + local eth=${eth_dst}${eth_src}${eth_type} + + local ip_vhlen=60000000 + local ip_plen=0020 + local ip_next=3a + local ip_ttl=ff + local ip=${ip_vhlen}${ip_plen}${ip_next}${ip_ttl}${spa}${tpa} + + # Neighbor Solicitation + local icmp6_type=87 + local icmp6_code=00 + local icmp6_rsvd=00000000 + # ICMPv6 source lla option + local icmp6_opt=01 + local icmp6_optlen=01 + local icmp6=${icmp6_type}${icmp6_code}${cksum}${icmp6_rsvd}${tpa}${icmp6_opt}${icmp6_optlen}${eth_src} + + local request=${eth}${ip}${icmp6} + + as hv$hv ovs-appctl netdev-dummy/receive hv${hv}-vif$inport $request +} + +src_mac=000000000001 + +net_add n1 +sim_add hv1 +as hv1 +ovs-vsctl add-br br-phys +ovn_attach n1 br-phys 192.168.0.1 + +ovs-vsctl -- add-port br-int hv1-vif1 -- \ + set interface hv1-vif1 external-ids:iface-id=sw-agg-ext \ + options:tx_pcap=hv1/vif1-tx.pcap \ + options:rxq_pcap=hv1/vif1-rx.pcap \ + ofport-request=1 + +# One Aggregation Switch connected to two Logical networks (routers). +ovn-nbctl ls-add sw-agg +ovn-nbctl lsp-add sw-agg sw-agg-ext \ + -- lsp-set-addresses sw-agg-ext 00:00:00:00:00:01 + +ovn-nbctl lsp-add sw-agg sw-rtr1 \ + -- lsp-set-type sw-rtr1 router \ + -- lsp-set-addresses sw-rtr1 00:00:00:00:01:00 \ + -- lsp-set-options sw-rtr1 router-port=rtr1-sw +ovn-nbctl lsp-add sw-agg sw-rtr2 \ + -- lsp-set-type sw-rtr2 router \ + -- lsp-set-addresses sw-rtr2 00:00:00:00:02:00 \ + -- lsp-set-options sw-rtr2 router-port=rtr2-sw + +# Configure L3 interface IPv4 & IPv6 on both routers +ovn-nbctl lr-add rtr1 +ovn-nbctl lrp-add rtr1 rtr1-sw 00:00:00:00:01:00 10.0.0.1/24 10::1/64 + +ovn-nbctl lr-add rtr2 +ovn-nbctl lrp-add rtr2 rtr2-sw 00:00:00:00:02:00 10.0.0.2/24 10::2/64 + +OVN_POPULATE_ARP +ovn-nbctl --wait=hv sync + +sw_dp_uuid=$(ovn-sbctl --bare --columns _uuid list datapath_binding sw-agg) +sw_dp_key=$(ovn-sbctl --bare --columns tunnel_key list datapath_binding sw-agg) + +r1_tnl_key=$(ovn-sbctl --bare --columns tunnel_key list port_binding sw-rtr1) +r2_tnl_key=$(ovn-sbctl --bare --columns tunnel_key list port_binding sw-rtr2) + +mc_key=$(ovn-sbctl --bare --columns tunnel_key find multicast_group datapath=${sw_dp_uuid} name="_MC_flood") +mc_key=$(printf "%04x" $mc_key) + +match_sw_metadata="metadata=0x${sw_dp_key}" + +# Inject ARP request for first router owned IP address. +send_arp_request 1 1 ${src_mac} $(ip_to_hex 10 0 0 254) $(ip_to_hex 10 0 0 1) + +# Verify that the ARP request is sent only to rtr1. +match_arp_req="priority=75.*${match_sw_metadata}.*arp_tpa=10.0.0.1,arp_op=1" +match_send_rtr1="load:0x${r1_tnl_key}->NXM_NX_REG15" +match_send_rtr2="load:0x${r2_tnl_key}->NXM_NX_REG15" + +as hv1 +OVS_WAIT_UNTIL([ + pkts_to_rtr1=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_arp_req}" | grep "${match_send_rtr1}" | \ + grep n_packets=1 -c) + test "1" = "${pkts_to_rtr1}" +]) +OVS_WAIT_UNTIL([ + pkts_to_rtr2=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_arp_req}" | grep "${match_send_rtr2}" | \ + grep n_packets=1 -c) + test "0" = "${pkts_to_rtr2}" +]) +OVS_WAIT_UNTIL([ + pkts_flooded=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_sw_metadata}" | grep ${mc_key} | grep -v n_packets=0 -c) + test "0" = "${pkts_flooded}" +]) + +# Inject ND_NS for ofirst router owned IP address. +src_ipv6=00100000000000000000000000000254 +dst_ipv6=00100000000000000000000000000001 +send_nd_ns 1 1 ${src_mac} ${src_ipv6} ${dst_ipv6} 751d + +# Verify that the ND_NS is sent only to rtr1. +match_nd_ns="priority=75.*${match_sw_metadata}.*icmp_type=135.*nd_target=10::1" + +as hv1 +OVS_WAIT_UNTIL([ + pkts_to_rtr1=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_nd_ns}" | grep "${match_send_rtr1}" | \ + grep n_packets=1 -c) + test "1" = "${pkts_to_rtr1}" +]) +OVS_WAIT_UNTIL([ + pkts_to_rtr2=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_nd_ns}" | grep "${match_send_rtr2}" | \ + grep n_packets=1 -c) + test "0" = "${pkts_to_rtr2}" +]) +OVS_WAIT_UNTIL([ + pkts_flooded=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_sw_metadata}" | grep ${mc_key} | grep -v n_packets=0 -c) + test "0" = "${pkts_flooded}" +]) + +# Configure load balancing on both routers. +ovn-nbctl lb-add lb1-v4 10.0.0.11 42.42.42.1 +ovn-nbctl lb-add lb1-v6 10::11 42::1 +ovn-nbctl lr-lb-add rtr1 lb1-v4 +ovn-nbctl lr-lb-add rtr1 lb1-v6 + +ovn-nbctl lb-add lb2-v4 10.0.0.22 42.42.42.2 +ovn-nbctl lb-add lb2-v6 10::22 42::2 +ovn-nbctl lr-lb-add rtr2 lb2-v4 +ovn-nbctl lr-lb-add rtr2 lb2-v6 +ovn-nbctl --wait=hv sync + +# Inject ARP request for first router owned VIP address. +send_arp_request 1 1 ${src_mac} $(ip_to_hex 10 0 0 254) $(ip_to_hex 10 0 0 11) + +# Verify that the ARP request is sent only to rtr1. +match_arp_req="priority=75.*${match_sw_metadata}.*arp_tpa=10.0.0.11,arp_op=1" +match_send_rtr1="load:0x${r1_tnl_key}->NXM_NX_REG15" +match_send_rtr2="load:0x${r2_tnl_key}->NXM_NX_REG15" + +as hv1 +OVS_WAIT_UNTIL([ + pkts_to_rtr1=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_arp_req}" | grep "${match_send_rtr1}" | \ + grep n_packets=1 -c) + test "1" = "${pkts_to_rtr1}" +]) +OVS_WAIT_UNTIL([ + pkts_to_rtr2=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_arp_req}" | grep "${match_send_rtr2}" | \ + grep n_packets=1 -c) + test "0" = "${pkts_to_rtr2}" +]) +OVS_WAIT_UNTIL([ + pkts_flooded=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_sw_metadata}" | grep ${mc_key} | grep -v n_packets=0 -c) + test "0" = "${pkts_flooded}" +]) + +# Inject ND_NS for first router owned VIP address. +src_ipv6=00100000000000000000000000000254 +dst_ipv6=00100000000000000000000000000011 +send_nd_ns 1 1 ${src_mac} ${src_ipv6} ${dst_ipv6} 751d + +# Verify that the ND_NS is sent only to rtr1. +match_nd_ns="priority=75.*${match_sw_metadata}.*icmp_type=135.*nd_target=10::11" + +as hv1 +OVS_WAIT_UNTIL([ + pkts_to_rtr1=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_nd_ns}" | grep "${match_send_rtr1}" | \ + grep n_packets=1 -c) + test "1" = "${pkts_to_rtr1}" +]) +OVS_WAIT_UNTIL([ + pkts_to_rtr2=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_nd_ns}" | grep "${match_send_rtr2}" | \ + grep n_packets=1 -c) + test "0" = "${pkts_to_rtr2}" +]) +OVS_WAIT_UNTIL([ + pkts_flooded=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_sw_metadata}" | grep ${mc_key} | grep -v n_packets=0 -c) + test "0" = "${pkts_flooded}" +]) + +# Configure NAT on both routers +ovn-nbctl lr-nat-add rtr1 dnat_and_snat 10.0.0.111 42.42.42.1 +ovn-nbctl lr-nat-add rtr1 dnat_and_snat 10::111 42::1 +ovn-nbctl lr-nat-add rtr2 dnat_and_snat 10.0.0.222 42.42.42.2 +ovn-nbctl lr-nat-add rtr2 dnat_and_snat 10::222 42::2 + +# Inject ARP request for first router owned NAT address. +send_arp_request 1 1 ${src_mac} $(ip_to_hex 10 0 0 254) $(ip_to_hex 10 0 0 111) + +# Verify that the ARP request is sent only to rtr1. +match_arp_req="priority=75.*${match_sw_metadata}.*arp_tpa=10.0.0.111,arp_op=1" +match_send_rtr1="load:0x${r1_tnl_key}->NXM_NX_REG15" +match_send_rtr2="load:0x${r2_tnl_key}->NXM_NX_REG15" + +as hv1 +OVS_WAIT_UNTIL([ + pkts_to_rtr1=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_arp_req}" | grep "${match_send_rtr1}" | \ + grep n_packets=1 -c) + test "1" = "${pkts_to_rtr1}" +]) +OVS_WAIT_UNTIL([ + pkts_to_rtr2=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_arp_req}" | grep "${match_send_rtr2}" | \ + grep n_packets=1 -c) + test "0" = "${pkts_to_rtr2}" +]) +OVS_WAIT_UNTIL([ + pkts_flooded=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_sw_metadata}" | grep ${mc_key} | grep -v n_packets=0 -c) + test "0" = "${pkts_flooded}" +]) + +# Inject ND_NS for first router owned IP address. +src_ipv6=00100000000000000000000000000254 +dst_ipv6=00100000000000000000000000000111 +send_nd_ns 1 1 ${src_mac} ${src_ipv6} ${dst_ipv6} 751d + +# Verify that the ND_NS is sent only to rtr1. +match_nd_ns="priority=75.*${match_sw_metadata}.*icmp_type=135.*nd_target=10::111" + +as hv1 +OVS_WAIT_UNTIL([ + pkts_to_rtr1=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_nd_ns}" | grep "${match_send_rtr1}" | \ + grep n_packets=1 -c) + test "1" = "${pkts_to_rtr1}" +]) +OVS_WAIT_UNTIL([ + pkts_to_rtr2=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_nd_ns}" | grep "${match_send_rtr2}" | \ + grep n_packets=1 -c) + test "0" = "${pkts_to_rtr2}" +]) +OVS_WAIT_UNTIL([ + pkts_flooded=$(ovs-ofctl dump-flows br-int | \ + grep -E "${match_sw_metadata}" | grep ${mc_key} | grep -v n_packets=0 -c) + test "0" = "${pkts_flooded}" +]) + +OVN_CLEANUP([hv1]) +AT_CLEANUP 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