Aggregate Cluster

Aggregate cluster is used for failover between clusters with different configuration, e.g., from EDS upstream cluster to STRICT_DNS upstream cluster, from cluster using ROUND_ROBIN load balancing policy to cluster using MAGLEV, from cluster with 0.1s connection timeout to cluster with 1s connection timeout, etc. Aggregate cluster loosely couples multiple clusters by referencing their name in the configuration. The fallback priority is defined implicitly by the ordering in the clusters list. Aggregate cluster uses tiered load balancing. The load balancer chooses cluster and priority first and then delegates the load balancing to the load balancer of the selected cluster. The top level load balancer reuses the existing load balancing algorithm by linearizing the priority set of multiple clusters into one.

Linearize Priority Set

Upstream hosts are divided into multiple priority levels and each priority level contains a list of healthy, degraded and unhealthy hosts. Linearization is used to simplify the host selection during load balancing by merging priority levels from multiple clusters. For example, primary cluster has 3 priority levels, secondary has 2 and tertiary has 2 and the failover ordering is primary, secondary, tertiary.

Cluster

Priority Level

Priority Level after Linearization

Primary

0

0

Primary

1

1

Primary

2

2

Secondary

0

3

Secondary

1

4

Tertiary

0

5

Tertiary

1

6

Example

A sample aggregate cluster configuration could be:

name: aggregate_cluster
connect_timeout: 0.25s
lb_policy: CLUSTER_PROVIDED
cluster_type:
  name: envoy.clusters.aggregate
  typed_config:
    "@type": type.googleapis.com/envoy.config.cluster.aggregate.v2alpha.ClusterConfig
    clusters:
    # cluster primary, secondary and tertiary should be defined outside.
    - primary
    - secondary
    - tertiary

Note: PriorityLoad retry plugins won’t work for aggregate cluster because the aggregate load balancer will override the PriorityLoad during load balancing.

Load Balancing Example

Aggregate cluster uses tiered load balancing algorithm and the top tier is distributing traffic to different clusters according to the health score across all priorities in each cluster. The aggregate cluster in this section includes two clusters which is different from what the above configuration describes.

Cluster

Traffic to Primary

Traffic to Secondary

Primary

Secondary

P=0 Healthy Endpoints

P=1 Healthy Endpoints

P=2 Healthy Endpoints

P=0 Healthy Endpoints

P=1 Healthy Endpoints

100%

100%

100%

100%

100%

100%

0%

72%

100%

100%

100%

100%

100%

0%

71%

1%

0%

100%

100%

100%

0%

71%

0%

0%

100%

100%

99%

1%

50%

0%

0%

50%

0%

70%

30%

20%

20%

10%

25%

25%

70%

30%

20%

0%

0%

20%

0%

50%

50%

0%

0%

0%

100%

0%

0%

100%

0%

0%

0%

72%

0%

0%

100%

Note: The above load balancing uses default overprovisioning factor which is 1.4 which means if 80% of the endpoints in a priority level are healthy, that level is still considered fully healthy because 80 * 1.4 > 100.

The example shows how the aggregate cluster level load balancer selects the cluster. E.g., healths of {{20, 20, 10}, {25, 25}} would result in a priority load of {{28%, 28%, 14%}, {30%, 0%}} of traffic. When normalized total health drops below 100, traffic is distributed after normalizing the levels’ health scores to that sub-100 total. E.g. healths of {{20, 0, 0}, {20, 0}} (yielding a normalized total health of 56) would be normalized and each cluster will receive 20 * 1.4 / 56 = 50% of the traffic which results in a priority load of {{50%, 0%, 0%}, {50%, 0%, 0%}} of traffic.

The load balancer reuses priority level logic to help with the cluster selection. The priority level logic works with integer health scores. The health score of a level is (percent of healthy hosts in the level) * (overprovisioning factor), capped at 100%. P=0 endpoints receive level 0’s health score percent of the traffic, with the rest flowing to P=1 (assuming P=1 is 100% healthy - more on that later). The integer percents of traffic that each cluster receives are collectively called the system’s “cluster priority load”. For instance, for primary cluster, when 20% of P=0 endpoints are healthy, 20% of P=1 endpoints are healthy, and 10% of P=2 endpoints are healthy; for secondary, when 25% of P=0 endpoints are healthy and 25% of P=1 endpoints are healthy. The primary cluster will receive 20% * 1.4 + 20% * 1.4 + 10% * 1.4 = 70% of the traffic. The secondary cluster will receive min(100 - 70, 25% * 1.4 + 25% * 1.4) = 30% of the traffic. The traffic to all clusters sum up to 100. The normalized health score and priority load are pre-computed before selecting the cluster and priority.

To sum this up in pseudo algorithms:

health(P_X) = min(100, 1.4 * 100 * healthy_P_X_backends / total_P_X_backends), where
                total_P_X_backends is the number of backends for priority P_X after linearization
normalized_total_health = min(100, Σ(health(P_0)...health(P_X)))
cluster_priority_load(C_0) = min(100, Σ(health(P_0)...health(P_k)) * 100 / normalized_total_health),
                where P_0...P_k belong to C_0
cluster_priority_load(C_X) = min(100 - Σ(priority_load(C_0)..priority_load(C_X-1)),
                         Σ(health(P_x)...health(P_X)) * 100 / normalized_total_health),
                         where P_x...P_X belong to C_X
map from priorities to clusters:
  P_0 ... P_k ... ...P_x ... P_X
  ^       ^          ^       ^
  cluster C_0        cluster C_X

The second tier is delegating the load balancing to the cluster selected in the first step and the cluster could use any load balancing algorithms specified by load balancer type.