Envoy uses a single process with multiple threads architecture. A single primary thread controls various sporadic coordination tasks while some number of worker threads perform listening, filtering, and forwarding. Once a connection is accepted by a listener, the connection spends the rest of its lifetime bound to a single worker thread. This allows the majority of Envoy to be largely single threaded (embarrassingly parallel) with a small amount of more complex code handling coordination between the worker threads. Generally Envoy is written to be 100% non-blocking and for most workloads we recommend configuring the number of worker threads to be equal to the number of hardware threads on the machine.
Listener connection balancing¶
By default, there is no coordination between worker threads. This means that all worker threads independently attempt to accept connections on each listener and rely on the kernel to perform adequate balancing between threads. For most workloads, the kernel does a very good job of balancing incoming connections. However, for some workloads, particularly those that have a small number of very long lived connections (e.g., service mesh HTTP2/gRPC egress), it may be desirable to have Envoy forcibly balance connections between worker threads. To support this behavior, Envoy allows for different types of connection balancing to be configured on each listener.
On Windows the kernel is not able to balance the connections properly with the async IO model that Envoy is using. Until this is fixed by the platform, Envoy will enforce listener connection balancing on Windows. This allows us to balance connections between different worker threads. This behavior comes with a performance penalty.