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Routing of Outgoing Packets with MP-TCP draft-handley-mptcp-routing-00 Mark Handley Costin Raiciu Marcelo Bagnulo.

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Presentation on theme: "Routing of Outgoing Packets with MP-TCP draft-handley-mptcp-routing-00 Mark Handley Costin Raiciu Marcelo Bagnulo."— Presentation transcript:

1 Routing of Outgoing Packets with MP-TCP draft-handley-mptcp-routing-00 Mark Handley Costin Raiciu Marcelo Bagnulo

2 Multiaddressed MP-TCP Host is connected to the Internet via more than one path.  Site where host resides is multihomed.  Host (eg phone) is multihomed. Host gets an IP address for each path it wishes to use.  IP addresses control incoming traffic via route advertisements, allowing load balancing.  By default, outgoing traffic would be routed based on destination. Doesn’t allow outgoing load balancing.

3 Example: Outgoing Connection D S XYZ 1.0.0.4 2.0.0.4 1.0.0.1 1.0.0.2 2.0.0.1 3.0.0.1 New TCP connection from S to D. In S’s host routing table, longest prefix match for 3.0.0.1 is via 1.0.0.2. TCP then binds the connection to 1.0.0.4. Packets are routed via 1.0.0.2 - no problem. SYN src: 1.0.0.4 dst: 3.0.0.1 SYN src: 1.0.0.4 dst: 3.0.0.1

4 Example: Incoming Connection D S XYZ 1.0.0.4 2.0.0.4 1.0.0.1 1.0.0.2 2.0.0.1 3.0.0.1 New TCP connection from D to S. SYN sent to 2.0.0.4, so connection is bound to 2.0.0.4 In S’s host routing table, longest prefix match for 3.0.0.1 is via 1.0.0.2. Problem! SYN src:3.0.0.1 dst:2.0.0.4 SYN src:3.0.0.1 dst:2.0.0.4 SYN/ACK src:2.0.0.4 dst:3.0.0.1 SYN/ACK src:2.0.0.4 dst:3.0.0.1 Dropped in ingress filter Dropped in ingress filter

5 Multi-addressing Because of the problems with incoming connections and ingress filtering, sites rarely configure addresses in this way. But we need multi-addressing for MP-TCP to work.  And an MP-TCP host has to fall back to regular TCP, so TCP needs to work too. Conclusion:  We need to revisit host routing to get most of the benefits of MP-TCP.

6 Traditional host routing Actually quite a wide range of different behaviours.  “strong” host vs “weak” host, etc. General idea:  OS has one best route to a particular prefix. All packets to that destination are sent using this route.

7 MP-TCP Host Routing Prerequisites To use an outgoing subnet, a host must have a route to the destination via a next-hop router on that subnet. We do longest prefix match:  All routes actively used for subflows to the same destination must have the same prefix length. Implication:  To use multiple local addresses to the same destination address, there must be multiple routes to the same prefix via different next-hop routers.

8 New host forwarding rules To send to a destination address from a source address: 1. Do longest prefix match.  This can give multiple routes with different metrics via different nexthop routers.  If no route exists, send fails. 2. If there are any routes via a next hop router on the same subnet as the source address:  Use the route via this subnet that has the lowest metric 3. Otherwise, send using the route with the lowest metric.  Even though it’s via the wrong subnet.

9 Motivation We need to make outgoing routing match addressing to the extent it’s possible  Even for regular TCP and UDP. For a multipath, we also need to force the use of multiple routes.  Normally only the lowest metric route would be used which gives no diversity. To achieve this we must override the route’s metric in favour of the source address choosing the outgoing subnet.  But only where such a route exists.  If no such route exists, do the best we can.

10 Example 1: Active Opener D S XYZ 1.0.0.4 2.0.0.4 1.0.0.1 1.0.0.2 2.0.0.1 3.0.0.1 MPTCP packet from 1.0.0.4 to 3.0.0.1 Routes at S: 3.0.0.0/16 via 1.0.0.1 metric 1 3.0.0.0/24 via 1.0.0.1 metric 10 3.0.0.0/24 via 1.0.0.2 metric 5 3.0.0.0/24 via 2.0.0.1 metric 2 Not longest prefix - eliminate. 2.0.0.1 on wrong subnet - eliminate. Both on correct subnet - prefer these. Lower metric - use this one.

11 Example 2: Passive Listener. S D XZ 1.0.0.4 2.0.0.4 1.0.0.1 2.0.0.1 3.0.0.1 SYN Src: 3.0.0.1 Dst: 2.0.0.4 SYN Src: 3.0.0.1 Dst: 2.0.0.4 Routes at D: 3.0.0.0/24 via 1.0.0.1 metric 1 3.0.0.0/24 via 2.0.0.1 metric 10 2.0.0.1 on wrong subnet - eliminate. On correct subnet, despite worse metric. Route is usable. On correct subnet, despite worse metric. Route is usable. Subflow is established. No problem

12 Example 3: Passive Listener. S D XZ 1.0.0.4 2.0.0.4 1.0.0.1 2.0.0.1 3.0.0.1 SYN Src: 3.0.0.1 Dst: 2.0.0.4 SYN Src: 3.0.0.1 Dst: 2.0.0.4 Routes at D: 3.0.0.0/24 via 1.0.0.1 metric 1 2.0.0.1 is on the wrong subnet, but no alternative route exists. 2.0.0.1 is on the wrong subnet, but no alternative route exists. Weak host: subflow is established, but unipath forwarding rules are used for its entire duration. Weak host: subflow is established, but unipath forwarding rules are used for its entire duration. Strong host: subflow is not established.

13 Usage examples. 1. Multi-interface host, directly connected to two (or more) ISPs.  Eg. smartphone. 2. Single-interface host at multi-homed site.  Eg. web server.

14 Multi-interface host. Directly connected to ISPs. Has complete control over which packet leaves via which link.  Host multipath forwarding rules are sufficient.

15 Single-interface host at multihomed site. Site has one address prefix per provider. Host gets one address from each prefix.

16 Multihoming: Case 1 Multihomed host is on the same L2 infrastructure as site exit routers.  Common in datacenters. Host multipath forwarding rules are sufficient. S XZ 1.0.0.4 2.0.0.4 1.0.0.12.0.0.1 ISP1ISP2 Internet

17 Multihoming: Case 2 Multihomed host is several IP hops from site exit routers.  E.g, UCL, organizations with lots of internal structure. Host multipath forwarding rules will allow multiple subflows to be set up, but host cannot ensure routing congruence. S XZ 1.0.64.4 2.0.64.4 1.0.0.12.0.0.1 ISP1ISP2 Internet A B 1.0.64.1 2.0.64.1 1.0.64/24 2.0.64/24 1.0.0.0/162.0.0.0/16

18 Multihoming: Case 2 Many possible solutions: Tunnel from S to X and Z. Source-address routing.  In this case, at B. MPLS from S. Virtual routers on A, then MPLS to X, Y. Loose-source-route from S via X or Z. S XZ 1.0.64.4 2.0.64.4 1.0.0.12.0.0.1 ISP1ISP2 Internet A B 1.0.64.1 2.0.64.1 1.0.64/24 2.0.64/24 1.0.0.0/162.0.0.0/16

19 Summary Important to specify how MP-TCP interacts with host routing.  New host forwarding rules cover what seem to be the most common cases for MP-TCP. Additional network mechanisms needed for full generality.  Existing mechanisms seem to suffice.  Not clear there’s a need to standardize these, or to choose just one mechanism.

20 Extra slides

21 What about route changes? For a directly connected interface.  If the interface goes down, the address is removed.  Subflows using that interface are paused (killed?). Only on hosts using a dynamic routing protocol can routes disappear.  Might then switch to an incongruent path.  Is this a problem? Worst case is that subflow stalls due to NAT or ingress filtering? Same problem with current forwarding rules.

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