.. This work is licensed under a Creative Commons Attribution 4.0 International License. .. http://creativecommons.org/licenses/by/4.0 .. (c) Bin Hu L3VPNs are virtual layer 3 networks described in multiple standards and RFCs, such as [RFC4364]_ and [RFC7432]_. Connectivity as well as traffic separation is achieved by exchanging routes between VRFs (Virtual Routing and Forwarding). Moreover, a Service Providers' virtualized network infrastructure may consist of one or more SDN Controllers from different vendors. Those SDN Controllers may be managed within one cloud or multiple clouds. Jointly, those VIMs (e.g. OpenStack instances) and SDN Controllers work together in an interoperable framework to create L3 services in the Service Providers' virtualized network infrastructure. Three use cases of creating L3VPN service by multiple SDN Controllers are described as follows. Any-to-Any Base Case -------------------- Description ~~~~~~~~~~~ This any-to-any use case is the base scenario, providing layer 3 connectivity between VNFs in the same L3VPN while separating the traffic and IP address spaces of different L3VPNs belonging to different tenants. There are 2 hosts (compute nodes). SDN Controller A and vRouter A are provided by Vendor A, and run on host A. SDN Controller B and vRouter B are provided by Vendor B, and run on host B. There are 2 tenants. Tenant 1 creates L3VPN Blue with 2 subnets: 10.1.1.0/24 and 10.3.7.0/24. Tenant 2 creates L3VPN Red with 1 subnet and an overlapping address space: 10.1.1.0/24. The network topology is shown in :numref:`l3vpn-any2any-figure`. .. figure:: images/l3vpn-any2any.png :name: l3vpn-any2any-figure :width: 100% In L3VPN Blue, VMs G1 (10.1.1.5) and G2 (10.3.7.9) are spawned on host A, and attached to 2 subnets (10.1.1.0/24 and 10.3.7.0/24) and assigned IP addresses respectively. VMs G3 (10.1.1.6) and G4 (10.3.7.10) are spawned on host B, and attached to 2 subnets (10.1.1.0/24 and 10.3.7.0/24) and assigned IP addresses respectively. In L3VPN Red, VM G5 (10.1.1.5) is spawned on host A, and attached to subnet 10.1.1.0/24. VM G6 (10.1.1.6) is spawned on host B, and attached to the same subnet 10.1.1.0/24. Derrived Requirements ~~~~~~~~~~~~~~~~~~~~~ Northbound API / Workflow +++++++++++++++++++++++++ [**Georg: this section needs to be made more readable**] Exemplary workflow is described as follows: 1. Create Network 2. Create Network VRF Policy Resource ``Any-to-Any`` 2.1. This sets up that when this tenant is put on a HOST that: 2.1.1. There will be a RD assigned per VRF 2.1.2. There will be a RT used for the common any-to-any communication 3. Create Subnet 4. Create Port (subnet, network vrf policy resource). This causes controller to: 4.1. Create vrf in vRouter's FIB, or Update vrf if already exists 4.2. Install an entry for Guest's HOST-Route in FIBs of Vrouters serving this tenant Virtual Network 4.3. Announce Guest HOST-Route to WAN-GW via MP-BGP Data model objects ++++++++++++++++++ - TBD Orchestration +++++++++++++ - TBD Dependencies on compute services ++++++++++++++++++++++++++++++++ - TBD Current implementation ~~~~~~~~~~~~~~~~~~~~~~ Support for creating and managing L3VPNs is available in OpenStack Neutron by means of the [BGPVPN]_ project. In order to create the L3VPN network configuration described above using the API [BGPVPN]_ API, the following workflow is needed: 1. Create Neutron networks for tenant "Blue" ``neutron net-create --tenant-id Blue net1`` ``neutron net-create --tenant-id Blue net2`` 2. Create subnets for the Neutron networks for tenant "Blue" ``neutron subnet-create --tenant-id Blue --name subnet1 net1 10.1.1.0/24`` ``neutron subnet-create --tenant-id Blue --name subnet2 net2 10.3.7.0/24`` 3. Create Neutron ports in the corresponding networks for tenant "Blue" ``neutron port-create --tenant-id Blue --name G1 --fixed-ip subnet_id=subnet1,ip_address=10.1.1.5 net1`` ``neutron port-create --tenant-id Blue --name G2 --fixed-ip subnet_id=subnet1,ip_address=10.1.1.6 net1`` ``neutron port-create --tenant-id Blue --name G3 --fixed-ip subnet_id=subnet2,ip_address=10.3.7.9 net2`` ``neutron port-create --tenant-id Blue --name G4 --fixed-ip subnet_id=subnet2,ip_address=10.3.7.10 net2`` 4. Create Neutron network for tenant "Red" ``neutron net-create --tenant-id Red net3`` 5. Create subnet for the Neutron network of tenant "Red" ``neutron subnet-create --tenant-id Red --name subnet3 net3 10.1.1.0/24`` 6. Create Neutron ports in the networks of tenant "Red" ``neutron port-create --tenant-id Red --name G5 --fixed-ip subnet_id=subnet3,ip_address=10.1.1.5 net3`` ``neutron port-create --tenant-id Red --name G7 --fixed-ip subnet_id=subnet3,ip_address=10.1.1.6 net3`` 7. Create a L3VPN by means of the BGPVPN API for tenant "Blue" ``neutron bgpvpn-create --tenant-id Blue --route-targets AS:100 --name vpn1`` 8. Associate the L3VPN of tenant "Blue" with the previously created networks ``neutron bgpvpn-net-assoc-create --tenant-id Blue --network net1 --name vpn1`` ``neutron bgpvpn-net-assoc-create --tenant-id Blue --network net2 --name vpn1`` 9. Create a L3VPN by means of the BGPVPN API for tenant "Red" ``neutron bgpvpn-create --tenant-id Red --route-targets AS:200 --name vpn2`` 10. Associate the L3VPN of tenant "Red" with the previously created networks ``neutron bgpvpn-net-assoc-create --tenant-id Red --network net3 --name vpn2`` Comments: * In this configuration only one BGPVPN for each tenant is created. * The ports are associated indirectly to the VPN through their networks. * The BGPVPN backend takes care of distributing the /32 routes to the OVR instances and assigning appropriate RD values. Gaps in the current solution ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ There are no gaps in the currently available solution which prevent realizing this particular use case. [**Georg: there are no gaps in terms of functionality provided by the BGPVPN project. However, a better analysis of the multi-backend support in Neutron is needed**]