MPLS And The Data Center
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Transcript MPLS And The Data Center
MPLS And The Data Center
Adrian Farrel
Old Dog Consulting / Juniper Networks
[email protected]
[email protected]
www.mpls2012.com
Agenda
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What do I mean by “Data Center”?
Design goals and requirements
Handling mobility within the data center
Connectivity between data center sites
Can MPLS add value?
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Everyone’s Data Center is Different
• There are some common fundamental concepts
• Racks of servers
• VMs hosted on blades
• VMs connected
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DC
IP/MPLS Network
DC
Services
L3
On server
In rack
In DC
In other DCs
L2
VSw
Storage
• Connectivity to the external
services
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Top of Rack
Switch
VM VM
VMs on Server
Blades
NAT FW LB
VM-based
Appliances
Design Goals
• Provide separate logical tenant networks in Data Center over common
IP physical infrastructure
• Design Goal: 100K tenants, 10M Virtual Machines (VMs)
• Need a data plane encapsulation
• Examples exist
• Virtual Extensible Local Area Networks (VXLAN)
• Network Virtualization using Generic Routing Encapsulation (NVGRE)
• Discovery is needed
• Data plane learning seems popular
• ARP doesn’t scale and needs to be suppressed
• Maybe the control plane can help
• A control plane is also required
• Static configuration is a solution (Hypervisor with SDN?)
• A control plane can make life a lot easier
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Multi-Tenancy : Requirements
• Multi-tenancy has become a core requirement of data centers
• Including for Virtualized Machines (VMs) and VM multi-tenancy
• It prooves a real stretch
• Three key requirements needed to support multi-tenancy are
• Traffic isolation
• Address independence
• Fully flexible VM placement and migration
• IETF’s NVO3 WG considers approaches to multi-tenancy that reside
at the network layer rather than using traditional isolation (e.g.,
VLANs)
• An overlay model to interconnect VMs distributed across a data center
• We already have network layer overlay solutions
• More about this later
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Mobility
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Virtual Machines need to be moved between blades
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How often?
• Dynamic load balancing
• Planned service
• Failure recovery
How much?
• Blades, servers, racks
How seamless?
• Application re-start
• Packet loss
• Hitless
Challenges are recovery/preservation of connectivity
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VMs need to preserve identity
• L2 or L3?
Need rapid location discovery/advertisement
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Inter Data Center Connectivity
• Many reasons for connectivity
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Applications in different DCs need to talk
VMs may be gathered into VPNs (virtual VPNs?)
One application’s data might be stored in anther DC
Stored data has to be synched between DCs
• Connectivity between DC sites is like VPN
connectivity
• Except it may be “tunnelling” virtual VPN connectivity
• And, of course, connectivity to the outside world
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What do we Mean by MPLS?
• Odd time and place to be asking this question
• MPLS offers a versatile encapsulation technique
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Small headers
Nested encapsulation
Simple forwarding
Special meaning labels
• MPLS provides a range of control plane protocols
• These have different applicabilities
• Some are more complex than others
• Supports static configuration
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The E-VPN
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Designed for scalability and ease of deployment
• Provider Edge (PE) can be in ToR switch and/or Hypervisor
• Operator defined networks – mesh, hub & spoke, extranets, etc
• Control plane learning using BGP
• VM Mobility – all PEs know VM’s E-VPN location
• VPN and Virtual LAN auto-discovery
• ARP flood suppression
• Control-plane scaling using Route Reflectors, RT Constrain, ESI, MAC aggregation
• Control & data plane traffic for VPNs only sent to PE with active VPN members
• Scalable fast convergence using Block MAC address withdrawal
• Support for MAC prefixes (e.g., default MAC route to external DC)
• Broadcast & Multicast traffic over multicast trees or ingress replication
• Active/active multi-homing
• CE sees LAG, PEs see Ethernet Segment (set of attachments to same CE)
• 4B tenant VPNs, 4B virtual LANs per tenant VPN
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MPLS E-VPN Routes
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MAC Advertisement Route
• Distributes MAC & IP address to PE & MPLS label binding
Per EVI Ethernet AD Route
• Distributes Ethernet Segment to PE & MPLS label binding
• Used in active/active multi-homing
Both carry a 24 bit MPLS label field
Use of MPLS label is very similar to VNID but supports local significance
Distribute VNID in MPLS label field
• Either global or local significance
• Local significance allows it to represent EVI, Port, MAC address, or MAC
address range
Data plane encapsulation specified using Tunnel Encapsulation attribute
(RFC 5512)
• Distributed with both of the above routes
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E-VPN is Encapsulation Agnostic
• E-VPN Instance can support multiple data plane
encapsulations (MPLS, VXLAN, NVGRE, etc.)
• MPLS encapsulation is just one option
• Encapsulations advertised in BGP, ingress uses
encapsulation supported by egress
• This use of BGP is not complicated
• Broadcast & multicast use encapsulation-specific shared
trees
• Allows interoperability with existing E-VPN & L3VPN
deployments
• This makes inter-DC really easy
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Is MPLS The Answer?
• What was the question?
• Do we need another control plane protocol?
• Why can’t we use what we already have?
• Frankly, BGP is not that hard and does what we need
• Can we integrate the DC with the outside world?
• Gateways, tunnelling and encapsulation are always possible
• Protocol gateways are a bit of a mess
• E-VPN and L3VPN connectivity just works
• Do we need another L2 encapsulation?
• There are plenty available, just pick your favorite
• This is an MPLS conference
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Questions?
[email protected]
[email protected]
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