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Load Balancer TCP Reset and Idle Timeout

You can use Standard Load Balancer to create a more predictable application behavior for your scenarios by enabling TCP Reset on Idle for a given rule. Load Balancer's default behavior is to silently drop flows when the idle timeout of a flow is reached. Enabling TCP reset causes Load Balancer to send bidirectional TCP Resets (TCP reset packets) on idle timeout to inform your application endpoints that the connection timed out and is no longer usable. Endpoints can immediately establish a new connection if needed.

Diagram shows default TCP reset behavior of network nodes.

TCP reset

You change this default behavior and enable sending TCP Resets on idle timeout on inbound NAT rules, load balancing rules, and outbound rules. When enabled per rule, Load Balancer sends bidirectional TCP Resets (TCP RST packets) to both client and server endpoints at the time of idle timeout for all matching flows.

Endpoints receiving TCP rest packets close the corresponding socket immediately. This provides an immediate notification to the endpoint's connection release and any future communication on the same TCP connection will fail. Applications can purge connections when the socket closes and reestablish connections as needed without waiting for the TCP connection to eventually time out.

For many scenarios, TCP reset can reduce the need to send TCP (or application layer) keepalives to refresh the idle timeout of a flow.

If your idle durations exceed configuration limits or your application shows an undesirable behavior with TCP Resets enabled, you can still need to use TCP keepalives, or application layer keepalives, to monitor the liveness of the TCP connections. Further, keepalives can also remain useful for when the connection is proxied somewhere in the path, particularly application layer keepalives.

By carefully examining the entire end to end scenario, you can determine the benefits from enabling TCP Resets and adjusting the idle timeout. Then you decide if more steps can be required to ensure the desired application behavior.

Configurable TCP idle timeout

Azure Load Balancer Standard has a 4 minutes to 100-minutes timeout range for load balancer rules, outbound rules, and inbound NAT rules. The default is 4 minutes. If a period of inactivity is longer than the timeout value, there's no guarantee that the TCP or HTTP session is maintained between the client and your cloud service. Azure Load Balancer Basic has up to a 30 minute timeout range.

When the connection is closed, your client application can receive the following error message: "The underlying connection was closed: A connection that was expected to be kept alive was closed by the server."

If TCP resets are enabled, and it's missed for any reason, resets for any subsequent packets. If the TCP reset option isn't enabled, then packets are silently dropped.

A common practice is to use a TCP keep-alive. This practice keeps the connection active for a longer period. For more information, see these .NET examples. With keep-alive enabled, packets are sent during periods of inactivity on the connection. Keep-alive packets ensure the idle timeout value isn't reached and the connection is maintained for a long period.

The setting works for inbound connections only. To avoid losing the connection, configure the TCP keep-alive with an interval less than the idle timeout setting or increase the idle timeout value. To support these scenarios, support for a configurable idle timeout is available.

TCP keep-alive works for scenarios where battery life isn't a constraint. It isn't recommended for mobile applications. Using a TCP keep-alive in a mobile application can drain the device battery faster.

Order of precedence

It's important to take into account how the idle timeout values set for different IPs could potentially interact.

Inbound

  • If there's an (inbound) load balancer rule with an idle timeout value set differently than the idle timeout of the frontend IP it references, the load balancer frontend IP idle timeout takes precedence.
  • If there's an inbound NAT rule with an idle timeout value set differently than the idle timeout of the frontend IP it references, the load balancer frontend IP idle timeout takes precedence.

Outbound

  • If there's an outbound rule with an idle timeout value different than 4 minutes (which is what public IP outbound idle timeout is locked at), the outbound rule idle timeout takes precedence.
  • Because a NAT gateway will always take precedence over load balancer outbound rules (and over public IP addresses assigned directly to VMs), the idle timeout value assigned to the NAT gateway will be used. (Along the same lines, the locked public IP outbound idle timeouts of 4 minutes of any IPs assigned to the NAT GW aren't considered.)

Limitations

  • TCP reset only sent during TCP connection in ESTABLISHED state.
  • TCP idle timeout doesn't affect load balancing rules on UDP protocol.
  • TCP reset isn't supported for Internal Load Balancer HA ports when a network virtual appliance is in the path. A workaround could be to use outbound rule with TCP reset from Network Virtual Appliance.

Next steps