Basic concepts of mpls te, Lsp tunnel, Mpls te tunnel – H3C Technologies H3C S10500 Series Switches User Manual

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Reserve resources by establishing LSP tunnels to specific destinations, allowing traffic to bypass

congested nodes to achieve appropriate load distribution.

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When network resources are insufficient, MPLS TE allows bandwidth-hungry LSPs or critical user
traffic to occupy the bandwidth for lower priority LSP tunnels.

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In case an LSP tunnel fails or congestion occurs on a network node, MPLS TE can provide route
backup and Fast Reroute (FRR).

With MPLS TE, a network administrator can eliminate network congestion by creating some LSPs and
congestion bypass nodes. Special offline tools are also available for the traffic analysis performed when

the number of LSPs is large.

Basic concepts of MPLS TE

LSP tunnel

On an LSP, after packets are labeled at the ingress node, the packets are forwarded based on label. The

traffic is transparent to the transits nodes on the LSP. In this sense, an LSP can be regarded as a tunnel.

MPLS TE tunnel

Rerouting and transmission over multiple paths may involve multiple LSP tunnels. A set of such LSP tunnels

is called a traffic engineered tunnel (TE tunnel).

MPLS TE implementation

MPLS TE mainly accomplishes the following functions:

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Static Constraint-based Routed LSP (CR-LSP) processing to create and remove static CR-LSPs. The
bandwidth of a static CR-LSP must be configured manually.

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Dynamic CR-LSP processing to handle three types of CR-LSPs: basic CR-LSPs, backup CR-LSPs and
fast rerouted CR-LSPs.

Static CR-LSP processing is simple, while dynamic CR-LSP processing involves four phrases: advertising

TE attributes, calculating paths, establishing paths, and forwarding packets.

Advertising TE attributes

MPLS TE must be aware of dynamic TE attributes of each link on the network, which is achieved by
extending link state-based IGPs such as OSPF and IS-IS.
OSPF and IS-IS extensions add to link states such TE attributes as link bandwidth and color.
Each node collects the TE attributes of all links on all routers within the local area or at the same level to

build up a TE database (TEDB).

Calculating paths

Link state-based routing protocols use Shortest Path First (SPF) to calculate the shortest path to each

network node.
In MPLS TE, the Constraint-based Shortest Path First (CSPF) algorithm is used to calculate the shortest, TE

compliant path to a node. It is derived from SPF and makes calculations based on the following

conditions:

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Constraints on the LSP to be set up with respect to bandwidth, color, setup/holding priority, explicit
path and other constraints. They are configured at the LSP ingress.

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TEDB