def packet_to_flow_match(packet):
"""
Create a flow match that matches packet with the given wildcards
@param packet The packet to use as a flow template
@param pkt_format Currently only L2 is supported. Will indicate the
overall packet type for parsing
@return An ofp_match object if successful. None if format is not
recognized. The wildcards of the match will be cleared for the
values extracted from the packet.
@todo check min length of packet
@todo Check if packet is other than L2 format
@todo implement other fields covered by OpenFlow 1.2
"""
match_ls = match_list()
if Ether in packet:
ether = packet[Ether]
eth_type = match.eth_type(ether.type)
eth_dst = match.eth_dst(parse_mac(ether.dst))
eth_src = match.eth_src(parse_mac(ether.src))
match_ls.add(eth_type)
match_ls.add(eth_dst)
match_ls.add(eth_src)
else:
return match_ls
if Dot1Q in packet:
#TODO: nicer way to get last vlan tag?
vlan = packet[Dot1Q:0]
vlan_vid = match.vlan_vid(vlan.vlan)
vlan_pcp = match.vlan_pcp(vlan.prio)
match_ls.add(vlan_vid)
match_ls.add(vlan_pcp)
vlan_pl = vlan.payload
while vlan_pl is not None and vlan_pl.name == Dot1Q.name:
vlan = vlan_pl
vlan_pl = vlan.payload
#We need to overwrite the already
# inserted eth_type
eth_index = match.tlvs.index()
eth_type = match.eth_type(vlan.type)
match_ls.tlvs.insert(vlan.type,eth_index)
#TODO ARP
if MPLS in packet:
mpls = packet[MPLS:0]
mpls_label = match.mpls_label(mpls.label)
mpls_tc = match.mpls_tc(mpls.cos)
match_ls.add(mpls_label)
match_ls.add(mpls_tc)
return match_ls
if IP in packet:
ip = packet[IP]
ipv4_src = match.ipv4_src(parse_ip(ip.src))
ipv4_dst = match.ipv4_dst(parse_ip(ip.dst))
ip_dscp = match.ip_dscp(ip.tos >> 2)
ip_ecn = match.ip_ecn(ip.tos & 0x03)
match_ls.add(ipv4_src)
match_ls.add(ipv4_dst)
match_ls.add(ip_dscp)
match_ls.add(ip_ecn)
else:
return match_ls
if TCP in packet:
tcp = packet[TCP]
ip_proto = match.ip_proto(6)
tcp_src = match.tcp_src(tcp.sport)
tcp_dst = match.tcp_dst(tcp.dport)
match_ls.add(ip_proto)
match_ls.add(tcp_src)
match_ls.add(tcp_dst)
return match_ls
if UDP in packet:
udp = packet[UDP]
ip_proto = match.ip_proto(17)
udp_src = match.tcp_src(udp.sport)
udp_dst = match.tcp_dst(udp.dport)
match_ls.add(ip_proto)
match_ls.add(udp_src)
match_ls.add(udp_dst)
return match_ls
if ICMP in packet:
icmp = packet[ICMP]
ip_proto = match.ip_proto(1)
icmp_type = match.icmp_type(icmp.type)
icmp_code = match.icmp_code(icmp.code)
match_ls.add(icmp_type)
match_ls.add(icmp_code)
return match_ls
return match_ls
def init_lrp_egress_clause(options):
# figure out all linked lsp on a LS which has a connection with this LRP
opposite_side_changed_lsp(
LR, LRP, LSP, State) <= (lsp_link_lrp(
LSP1, LS, UUID_LS, LRP, LR, UUID_LR,
UUID_LR_CHASSIS, State1) & exchange_lsp_array(
UUID_LSP, LSP, UUID_LS, UUID_CHASSIS, UUID_LRP1, State2) &
(State == State1 + State2) & (State != 0))
# figure out all regular lsp
opposite_side_changed_lsp(LR, LRP, LSP, State) <= (
lrp_array(UUID_LRP, LRP, UUID_LR, UUID_LSP1, State1)
& exchange_lsp_array(UUID_LSP1, LSP1, UUID_LS, UUID_CHASSIS1, UUID_LRP,
State2) & ls_array(LS, UUID_LS, State3)
& lr_array(LR, UUID_LR, State4)
& lsp_array(UUID_LSP, LSP, UUID_LS, UUID_CHASSIS2, UUID_LRP2, State5) &
(UUID_CHASSIS2 != None) &
(State == State1 + State2 + State3 + State4 + State5) & (State != 0))
opposite_side_has_patch_port(LR, LRP, State) <= (
local_patchport(LSP, LS, State1) & lsp_link_lrp(
LSP1, LS, UUID_LS, LRP, LR, UUID_LR, UUID_LR_CHASSIS, State2) &
# NOTE only consider local_patchport, it means a gateway's oppsite
# LS has remote patchport cannot trigger this flow
(State == State1 + State2))
# update eth_dst by searching active lsp
lrp_update_eth_dst(LR, Priority, Match, Action, State) <= (
(Priority == 3) & opposite_side_changed_lsp(LR, LRP, LSP, State)
& match.ip_proto(Match1) &
# we have to match the lrp portID, because in ecmp,
# two ports may have same dst IP but different dst mac
match.reg_dst(LRP[LRP_PORTID], Match2)
& match.reg_2(LSP[LSP_IP_INT], Match3) &
(Match == Match1 + Match2 + Match3)
& action.load(LSP[LSP_MAC_INT], NXM_Reg(ETH_DST_IDX), Action1)
& action.resubmit_next(Action2) & (Action == Action1 + Action2))
# push packet to table TABLE_SEARCH_IP_MAC to search unknow mac,ip pair
lrp_update_eth_dst(LR, Priority, Match, Action, State) <= (
(Priority == 2) & lr_array(LR, UUID_LR, State) &
(State != 0) & match.match_none(Match)
& action.mod_dl_dst("00:00:00:00:00:00", Action1)
& action.resubmit_table(TABLE_SEARCH_IP_MAC, Action2)
& action.resubmit_next(Action3) &
(Action == Action1 + Action2 + Action3))
lrp_ip_undnat_stage1(LR, Priority, Match, Action,
State) <= (nat.lundnat_xlate_stage1(
LR, Priority, Match, Action, State))
lrp_ip_undnat_stage2(LR, Priority, Match, Action,
State) <= (nat.lundnat_xlate_stage2(
LR, Priority, Match, Action, State))
lrp_ip_snat_stage1(LR, Priority, Match, Action,
State) <= (nat.lsnat_xlate_stage1(
LR, Priority, Match, Action, State))
lrp_ip_snat_stage2(LR, Priority, Match, Action,
State) <= (nat.lsnat_xlate_stage2(
LR, Priority, Match, Action, State))
# ovs should drop it if the packet's dst_mac = 00:00:00:00:00:00 and
# it is a redirect packet. This flow avoids infinite loop.
lrp_handle_unknow_dst_pkt(LR, Priority, Match, Action, State) <= (
(Priority == 4) & lr_array(LR, UUID_LR, State) &
(State != 0) & match.reg_flag(FLAG_REDIRECT, Match1)
& match.eth_dst("00:00:00:00:00:00", Match2) &
(Match == Match1 + Match2)
& action.resubmit_table(TABLE_DROP_PACKET, Action))
# ask controller to generate arp, if we cannot found the ip,mac pair.
# If opposite LS has patch-port will create this flow
lrp_handle_unknow_dst_pkt(LR, Priority, Match, Action, State) <= (
(Priority == 3) &
# oppsite LS must has patchport
opposite_side_has_patch_port(LR, LRP, State) & (State != 0)
& match.ip_proto(Match1) & match.eth_dst("00:00:00:00:00:00", Match2)
& match.reg_dst(LRP[LRP_PORTID], Match3) &
(Match == Match1 + Match2 + Match3) &
# reg2 and reg3 were transfered to pkt_controller as well
action.generate_arp(TABLE_LRP_EGRESS_FORWARD_PACKET, Action1)
& action.resubmit_table(TABLE_DROP_PACKET, Action2) &
(Action == Action1 + Action2))
# upload packet to controller, if this packet cannot trigger generating
# arp and didn't know the destination's macaddress. controller will
# ask tuplenet to generate it.
if options.has_key('ONDEMAND'):
if options.has_key('ENABLE_REDIRECT'):
# A regular tuplenet node(with ondemand) may not know where dst lsp is,
# so it uploads packet to controller and redirects pkt to an edge node.
lrp_handle_unknow_dst_pkt(LR, Priority, Match, Action, State) <= (
(Priority == 2) & lr_array(LR, UUID_LR, State) &
(State != 0) & match.ip_proto(Match1) &
# set macaddress to 0, then other host know this packet
# should be threw to LR pipline
match.eth_dst("00:00:00:00:00:00", Match2) &
(Match == Match1 + Match2) & action.load(
1,
NXM_Reg(REG_FLAG_IDX, FLAG_REDIRECT_BIT_IDX,
FLAG_REDIRECT_BIT_IDX), Action1)
& action.upload_unknow_dst(Action2)
& action.resubmit_table(TABLE_EMBED2_METADATA, Action3)
& action.resubmit_table(TABLE_REDIRECT_CHASSIS, Action4) &
(Action == Action1 + Action2 + Action3 + Action4))
else:
lrp_handle_unknow_dst_pkt(LR, Priority, Match, Action, State) <= (
(Priority == 2) & lr_array(LR, UUID_LR, State) &
(State != 0) & match.ip_proto(Match1)
& match.eth_dst("00:00:00:00:00:00", Match2) &
(Match == Match1 + Match2) & action.upload_unknow_dst(Action))
else:
if options.has_key('ENABLE_REDIRECT'):
# A edge node(with ondemand disable) should know where is dst, but
# tuplenet instance may down so ovs-flow doesn't know the new dst(
# a lsp may be create while tuplenet is down, ovs-flow not updated).
# This ovs-flow should redirect this packet to other edge now as well,
# BUT NOT upload to controller
lrp_handle_unknow_dst_pkt(LR, Priority, Match, Action, State) <= (
(Priority == 2) & lr_array(LR, UUID_LR, State) &
(State != 0) & match.ip_proto(Match1) &
# set macaddress to 0, then other host know this packet
# should be threw to LR pipline
match.eth_dst("00:00:00:00:00:00", Match2) &
(Match == Match1 + Match2) & action.load(
1,
NXM_Reg(REG_FLAG_IDX, FLAG_REDIRECT_BIT_IDX,
FLAG_REDIRECT_BIT_IDX), Action1)
& action.resubmit_table(TABLE_EMBED2_METADATA, Action2)
& action.resubmit_table(TABLE_REDIRECT_CHASSIS, Action3) &
(Action == Action1 + Action2 + Action3))
lrp_handle_unknow_dst_pkt(LR, Priority, Match, Action, State) <= (
(Priority == 1) & lr_array(LR, UUID_LR, State) &
(State != 0) & match.eth_dst("00:00:00:00:00:00", Match)
& action.resubmit_table(TABLE_DROP_PACKET, Action))
lrp_handle_unknow_dst_pkt(LR, Priority, Match, Action, State) <= (
(Priority == 0) & lr_array(LR, UUID_LR, State) &
(State != 0) & match.match_none(Match) & action.resubmit_next(Action))
lrp_forward_packet(LR, Priority, Match, Action, State) <= (
(Priority == 3) & lsp_link_lrp(LSP, LS, UUID_LS, LRP, LR, UUID_LR,
UUID_LR_CHASSIS, State) &
(State != 0) & match.reg_dst(LRP[LRP_PORTID], Match)
& action.load(LS[LS_ID], NXM_Reg(REG_DP_IDX), Action1)
& action.load(LSP[LSP_PORTID], NXM_Reg(REG_SRC_IDX), Action2)
& action.resubmit_next(Action3) &
(Action == Action1 + Action2 + Action3))
def init_lsp_ingress_clause(options):
if options.has_key('GATEWAY'):
# push RARP to controller, only Edge node should consider receiving rarp
lsp_arp_controller(LS, Priority, Match, Action, State) <= (
(Priority == 2) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.arp_proto(Match1) &
match.arp_op(2, Match2) &
(Match == Match1 + Match2) &
action.upload_arp(Action)
)
if not options.has_key('ONDEMAND'):
# maybe gratuitous ARP, push to controller.
# maybe a unknow dst arp
lsp_arp_controller(LS, Priority, Match, Action, State) <= (
(Priority == 1) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.arp_proto(Match1) &
match.arp_op(1, Match2) &
(Match == Match1 + Match2) &
action.upload_arp(Action1) &
action.resubmit_next(Action2) &
(Action == Action1 + Action2)
)
lsp_arp_controller(LS, Priority, Match, Action, State) <= (
(Priority == 0) &
ls_array(LS, UUID_LS, State) & (State != 0) &
(match.match_none(Match)) &
action.resubmit_next(Action)
)
lsp_arp_response(LS, Priority, Match, Action, State) <= (
(Priority == 2) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.arp_proto(Match1) &
match.arp_op(1, Match2) &
(Match == Match1 + Match2) &
action.resubmit_table(TABLE_ARP_FEEDBACK_CONSTRUCT, Action1) &
action.resubmit_next(Action2) &
(Action == Action1 + Action2)
)
lsp_arp_response(LS, Priority, Match, Action, State) <= (
(Priority == 0) &
ls_array(LS, UUID_LS, State) & (State != 0) &
(match.match_none(Match)) &
action.resubmit_next(Action)
)
if options.has_key('ENABLE_UNTUNNEL') and options.has_key('dsrport'):
# NOTE: it helps reduce time-cost
_lsp_lrp_ls_changed(LS, LRP, State) <= (
ls_array(LS, UUID_LS, State1) &
lsp_link_lrp(LSP, LS1, UUID_LS1, LRP, LR,
UUID_LR, UUID_LR_CHASSIS, State2) &
(State == State1 + State2) & (State != 0)
)
lsp_untunnel_deliver(LS, Priority, Match, Action, State) <= (
_lsp_lrp_ls_changed(LS, LRP, State) &
(Priority == _cal_priority(LRP[LRP_PREFIX], 2, LRP[LRP_ILK_IDX])) &
match.ip_proto(Match1) &
match.ip_dst_prefix(LRP[LRP_IP], LRP[LRP_PREFIX], Match2) &
(Match == Match1 + Match2) &
action.resubmit_next(Action)
)
lsp_untunnel_deliver(LS, Priority, Match, Action, State) <= (
(Priority == 1) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.ip_proto(Match) &
# output packet to local port which is an internal port.
# packet goes into tcpip stack
action.mod_dl_dst(options['dsrport']['mac'], Action1) &
action.output(options['dsrport']['ofport'], Action2) &
(Action == Action1 + Action2)
)
lsp_untunnel_deliver(LS, Priority, Match, Action, State) <= (
(Priority == 0) &
ls_array(LS, UUID_LS, State) & (State != 0) &
(match.match_none(Match)) &
action.resubmit_next(Action)
)
# deliver to LR which has snat/dnat
lsp_lookup_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 5) &
# TODO optimize it
lnat_data(LNAT, LR, XLATE_TYPE, UUID_LR, State1) &
lsp_link_lrp(LSP, LS, UUID_LS, LRP, LR,
UUID_LR, UUID_LR_CHASSIS, State2) &
(State == State1 + State2) & (State != 0) &
match.eth_dst(LNAT[LNAT_XLATE_MAC], Match) &
action.load(LSP[LSP_PORTID], NXM_Reg(REG_DST_IDX), Action1) &
action.resubmit_next(Action2) &
(Action == Action1 + Action2)
)
# deliver to another lsp on local chassis
lsp_lookup_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 4) &
local_lsp(LSP, LS, State) & (State != 0) &
match.eth_dst(LSP[LSP_MAC], Match) &
action.load(LSP[LSP_PORTID],
NXM_Reg(REG_DST_IDX), Action1) &
action.resubmit_next(Action2) &
(Action == Action1 + Action2)
)
# it helps reduce time-cost
_lsp_remote_lsp_changed(LSP, LS, PHY_CHASSIS, State) <= (
remote_lsp(LSP, LS, PHY_CHASSIS, State) & (State != 0))
if options.has_key('ENABLE_REDIRECT'):
# output deliver to another remote chassis.
# use bundle_load to check if dst chassis is dead or live.
lsp_lookup_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 3) &
_lsp_remote_lsp_changed(LSP, LS, PHY_CHASSIS, State) &
match.eth_dst(LSP[LSP_MAC], Match) &
action.load(LSP[LSP_PORTID],
NXM_Reg(REG_DST_IDX), Action1) &
action.bundle_load(NXM_Reg(REG_OUTPORT_IDX),
[PHY_CHASSIS[PCH_OFPORT]], Action2) &
# if we want output this packet in next step, we set 1->reg5
# in next step flow, no need to clean this reg5, because
# it should output a port means the end of packet process
action.load(1, NXM_Reg(REG5_IDX), Action3) &
action.resubmit_next(Action4) &
(Action == Action1 + Action2 + Action3 + Action4)
)
else:
# deliver to remote chassis by using output,(set outport to reg4)
lsp_lookup_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 3) &
_lsp_remote_lsp_changed(LSP, LS, PHY_CHASSIS, State) &
match.eth_dst(LSP[LSP_MAC], Match) &
action.load(LSP[LSP_PORTID],
NXM_Reg(REG_DST_IDX), Action1) &
action.load(PHY_CHASSIS[PCH_OFPORT],
NXM_Reg(REG_OUTPORT_IDX), Action2) &
# if we want output this packet in next step, we set 1->reg5
# in next step flow, no need to clean this reg5, because
# it should output a a port means the end of packet process
action.load(1, NXM_Reg(REG5_IDX), Action3) &
action.resubmit_next(Action4) &
(Action == Action1 + Action2 + Action3 + Action4)
)
# deliver the packet which not match above flow to the patchport
# patch port's ip address should be 255.255.255.255
lsp_lookup_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 2) &
local_patchport(LSP, LS, State) & (State != 0) &
match.match_none(Match) &
action.load(LSP[LSP_PORTID],
NXM_Reg(REG_DST_IDX), Action1) &
action.resubmit_table(TABLE_LSP_EGRESS_FIRST, Action2) &
(Action == Action1 + Action2)
)
if options.has_key('ONDEMAND'):
# ovs must upload this packet to controller if cannot found the
# destination. controller will tell tuplenet to generate more flows
lsp_lookup_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 0) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.match_none(Match) &
action.upload_unknow_dst(Action1) &
# resubmit this packet to next stage, gateway host can
# do delivering if gateway enable redirect feature
action.load(st.TP_OFPORT_NONE, NXM_Reg(REG_OUTPORT_IDX), Action2) &
action.load(1, NXM_Reg(REG5_IDX), Action3) &
action.resubmit_next(Action4) &
(Action == Action1 + Action2 + Action3 + Action4)
)
else:
# deliver packet to drop table if this packet cannot
# found the destination.
lsp_lookup_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 0) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.match_none(Match) &
action.resubmit_table(TABLE_DROP_PACKET, Action)
)
if options.has_key('ENABLE_REDIRECT'):
# if it is a redirectd packet and reg4 is 0xffff, then we should drop
# it, because we don't want cause infinite loop
lsp_output_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 4) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.reg_5(1, Match1) &
match.reg_flag(FLAG_REDIRECT, Match2) &
match.reg_outport(st.TP_OFPORT_NONE, Match3) &
(Match == Match1 + Match2 + Match3) &
action.resubmit_table(TABLE_DROP_PACKET, Action)
)
# if this packet was failed to deliver to remote chassis, we send it to
# other gateway to help forwarding
lsp_output_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 3) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.reg_5(1, Match1) &
match.reg_outport(st.TP_OFPORT_NONE, Match2) &
(Match == Match1 + Match2) &
action.resubmit_table(TABLE_REDIRECT_CHASSIS, Action)
)
# output to a port base on reg4's value
lsp_output_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 2) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.reg_5(1, Match) &
action.resubmit_table(TABLE_EMBED2_METADATA, Action1) &
action.resubmit_table(TABLE_OUTPUT_PKT, Action2) &
(Action == Action1 + Action2)
)
# just deliver to next stage
lsp_output_dst_port(LS, Priority, Match, Action, State) <= (
(Priority == 1) &
ls_array(LS, UUID_LS, State) & (State != 0) &
match.match_none(Match) &
action.resubmit_table(TABLE_LSP_EGRESS_FIRST, Action)
)
action.move(NXM_Reg(TUN_ID_IDX, 0, 23),
NXM_Reg(REG_DP_IDX, 0, 23), Action1) &
action.move(NXM_Reg(TUN_METADATA0_IDX, 0, 15),
NXM_Reg(REG_SRC_IDX, 0, 15), Action2) &
action.move(NXM_Reg(TUN_METADATA0_IDX, 16, 31),
NXM_Reg(REG_DST_IDX, 0, 15), Action3) &
action.move(NXM_Reg(TUN_METADATA0_IDX, 32, 63),
NXM_Reg(REG_FLAG_IDX, 0, 31), Action4) &
(Action == Action1 + Action2 + Action3 + Action4)
)
pipeline_forward(Priority, Match, Action) <= (
(Priority == 1) &
match.ip_proto(Match1) &
# a ip packet with 00 macaddress means it was a redirect packet which
# send out by other host, deliver this packet to LR to help redirect
match.eth_dst("00:00:00:00:00:00", Match2) &
match.reg_flag(FLAG_REDIRECT, Match3) &
(Match == Match1 + Match2 + Match3) &
# TABLE_LRP_INGRESS_FIRST table is a tracing-point
# as well and dec_ttl, skip that table
action.resubmit_table(TABLE_LRP_INGRESS_IP_ROUTE, Action)
)
# it is a regular packet, foward to lsp egress table immediately
pipeline_forward(Priority, Match, Action) <= (
(Priority == 0) &
match.match_none(Match) &
action.resubmit_table(TABLE_LSP_EGRESS_FIRST, Action)
)
