Load balancing, Rrpp ring group, Fast detection mechanism – H3C Technologies H3C S10500 Series Switches User Manual

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Load balancing

In a ring network, maybe traffic of multiple VLANs is transmitted at the same time. RRPP can implement

load balancing for the traffic by transmitting traffic of different VLANs along different paths.
By configuring an individual RRPP domain for transmitting the traffic of the specified VLANs (protected

VLANs) in a ring network, traffic of different VLANs can be transmitted according to different topologies

in the ring network. In this way, load balancing is achieved.
As shown in

Figure

18

, Ring 1 is configured as the primary ring of Domain 1 and Domain 2, which are

configured with different protected VLANs. Device A is the master node of Ring 1 in Domain 1, and

Device B is the master node of Ring 1 in Domain 2. With such configurations, traffic of different VLANs
can be transmitted on different links to achieve load balancing in the single-ring network.

RRPP ring group

In an edge node RRPP ring group, only an activated subring with the lowest domain ID and ring ID can

send Edge-Hello packets. In an assistant-edge node RRPP ring group, any activated subring that has

received Edge-Hello packets will forward these packets to the other activated subrings. With an edge

node RRPP ring group and an assistant-edge node RRPP ring group configured, only one subring sends

Edge-Hello packets on the edge node, and only one subring receives Edge-Hello packets on the
assistant-edge node, reducing CPU workload.
As shown in

Figure

17

, Device B is the edge node of Ring 2 and Ring 3, and Device C is the

assistant-edge node of Ring 2 and Ring 3. Device B and Device C must send or receive Edge-Hello

packets frequently. If more subrings are configured or if load balancing is configured for multiple

domains, Device B and Device C will send or receive a mass of Edge-Hello packets.
To reduce Edge-Hello traffic, you can assign Ring 2 and Ring 3 to an RRPP ring group configured on the
edge node Device B and assign Ring 2 and Ring 3 to an RRPP ring group configured on Device C. After

such configurations, if all rings are activated, only Ring 2 on Device B sends Edge-Hello packets.

Fast detection mechanism

Ideally, an RRPP ring can fast converge because the transit nodes on it can detect link failures fast and

send out notifications immediately. In practice, some devices on an RRPP ring may not support RRPP. RRPP

can detect link failures between these devices only through the timeout mechanism. This results in
long-time traffic interruption and failure to implement millisecond-level convergence.
To address this problem, a fast detection mechanism was introduced. The mechanism works as follows:

•

The master node sends Fast-Hello packets out its primary port at the interval specified by the
Fast-Hello timer. If the secondary port receives the Fast-Hello packets sent by the local master node

before the Fast-Fail timer expires, the entire ring is in the Health state; otherwise, the ring transits into

the Disconnect state.

•

The edge node sends Fast-Edge-Hello packets out its common ports at the interval specified by the
timer resolution. If the assistant-edge node fails to receive the Fast-Edge-Hello packets within three

times the timer resolution, the SRPTs transit to Disconnect state.

As shown in

Figure

14

, with fast detection enabled for RRPP domain 1, Device A, the master node of Ring

1, sends out Fast-Hello packets periodically and determines the ring status according to whether

Fast-Hello packets are received before the Fast-Fail timer expires, implementing link status fast detection.

NOTE:
•

The timer resolution refers to the shortest-period timer provided on an RRPP node.

•

To implement fast detection on an RRPP ring, enable fast detection on the master node, edge node, and
assistant-edge node of the RRPP ring.