HTTP dynamic forward proxy
Attention
HTTP dynamic forward proxy support should be considered alpha and not production ready.
Through the combination of both an HTTP filter and custom cluster, Envoy supports HTTP dynamic forward proxy. This means that Envoy can perform the role of an HTTP proxy without prior knowledge of all configured DNS addresses, while still retaining the vast majority of Envoy’s benefits including asynchronous DNS resolution. The implementation works as follows:
The dynamic forward proxy HTTP filter is used to pause requests if the target DNS host is not already in cache.
Envoy will begin asynchronously resolving the DNS address, unblocking any requests waiting on the response when the resolution completes.
Any future requests will not be blocked as the DNS address is already in cache. The resolution process works similarly to the logical DNS service discovery type with a single target address being remembered at any given time.
All known hosts are stored in the dynamic forward proxy cluster such that they can be displayed in admin output.
A special load balancer will select the right host to use based on the HTTP host/authority header during forwarding.
Hosts that have not been used for a period of time are subject to a TTL that will purge them.
When the upstream cluster has been configured with a TLS context, Envoy will automatically perform SAN verification for the resolved host name as well as specify the host name via SNI.
The above implementation details mean that at steady state Envoy can forward a large volume of HTTP proxy traffic while all DNS resolution happens asynchronously in the background. Additionally, all other Envoy filters and extensions can be used in conjunction with dynamic forward proxy support including authentication, RBAC, rate limiting, etc.
For further configuration information see the HTTP filter configuration documentation.
Memory usage details
Memory usage detail’s for Envoy’s dynamic forward proxy support are as follows:
Each resolved host/port pair uses a fixed amount of memory global to the server and shared amongst all workers.
Address changes are performed inline using read/write locks and require no host reallocations.
Hosts removed via TTL are purged once all active connections stop referring to them and all used memory is regained.
The max_hosts field can be used to limit the number of hosts that the DNS cache will store at any given time.
The cluster’s max_pending_requests circuit breaker can be used to limit the number of requests that are pending waiting for the DNS cache to load a host.
Long lived upstream connections can have the underlying logical host expire via TTL while the connection is still open. Upstream requests and connections are still bound by other cluster circuit breakers such as max_requests. The current assumption is that host data shared between connections uses a marginal amount of memory compared to the connections and requests themselves, making it not worth controlling independently.