A method for generating and using network function (NF) set load information, the method includes, at a service communications proxy (SCP), receiving service based interface (SBI) requests from consumer NFs. The method further includes forwarding the SBI requests to producer NF instances that are members of an NF set. The method further includes receiving responses to the SBI requests from the producer NF instances. The method further includes determining NF instance load control information (LCI) for the producer NF instances using the responses. The method further includes computing, by the SCP and from the NF instance LCI for the producer NF instances, NF set LCI for the NF set. The method further includes communicating the NF set LCI for the NF set to at least one of the consumer NFs or using the NF set LCI for the NF set to select a producer NF instance within an NF set to provide a service for one of the consumer NFs.

A method for generating and using network function (NF) set load information, the method includes, at a service communications proxy (SCP), receiving service based interface (SBI) requests from consumer NFs. The method further includes forwarding the SBI requests to producer NF instances that are members of an NF set. The method further includes receiving responses to the SBI requests from the producer NF instances. The method further includes determining NF instance load control information (LCI) for the producer NF instances using the responses. The method further includes computing, by the SCP and from the NF instance LCI for the producer NF instances, NF set LCI for the NF set. The method further includes communicating the NF set LCI for the NF set to at least one of the consumer NFs or using the NF set LCI for the NF set to select a producer NF instance within an NF set to provide a service for one of the consumer NFs.

A system comprises a plurality of computing devices that are communicatively coupled via a network and have a file system distributed among them, and comprises one or more file system request buffers residing on one or more of the plurality of computing devices. File system choking management circuitry that resides on one or more of the plurality of computing devices is operable to separately control: a first rate at which a first type of file system requests (e.g., one of data requests, data read requests, data write requests, metadata requests, metadata read requests, and metadata write requests) are fetched from the one or more buffers , and a second rate at which a second type of file system requests (e.g., another of data requests, data read requests, data write requests, metadata requests, metadata read requests, and metadata write requests) are fetched from the one or more buffers.

A system comprises a plurality of computing devices that are communicatively coupled via a network and have a file system distributed among them, and comprises one or more file system request buffers residing on one or more of the plurality of computing devices. File system choking management circuitry that resides on one or more of the plurality of computing devices is operable to separately control: a first rate at which a first type of file system requests (e.g., one of data requests, data read requests, data write requests, metadata requests, metadata read requests, and metadata write requests) are fetched from the one or more buffers , and a second rate at which a second type of file system requests (e.g., another of data requests, data read requests, data write requests, metadata requests, metadata read requests, and metadata write requests) are fetched from the one or more buffers.

Described embodiments improve the performance of a computer network via selectively forwarding packets to bypass quality of service (QoS) processing, avoiding processing delays during critical periods of high demand, increasing throughput and efficiency may be increased by sacrificing a small amount of QoS accuracy. QoS processing may be applied to a subset of packets of a flow or connection, referred to herein as “lazy” processing or lazy byte batching. Packets that bypass QoS processing may be immediately forwarded with the same QoS settings as packets of the flow for which QoS processing is applied, resulting in tremendous overhead savings with only minimal decline in accuracy.

Described embodiments improve the performance of a computer network via selectively forwarding packets to bypass quality of service (QoS) processing, avoiding processing delays during critical periods of high demand, increasing throughput and efficiency may be increased by sacrificing a small amount of QoS accuracy. QoS processing may be applied to a subset of packets of a flow or connection, referred to herein as “lazy” processing or lazy byte batching. Packets that bypass QoS processing may be immediately forwarded with the same QoS settings as packets of the flow for which QoS processing is applied, resulting in tremendous overhead savings with only minimal decline in accuracy.

A network device includes a rate measurement circuit that is configured to measure respective egress rates at which respective data is being transmitted via respective ports associated with the network device. A marking ratio determination circuit is configured to select respective marking ratios based on respective measured egress rates, the marking ratios for marking packets to be transmitted via the respective ports to indicate respective levels of congestion corresponding to the respective ports. Different marking ratios correspond to different measured egress rates. A packet editor circuit is configured to mark selected packets to be transmitted via respective ports according to the respective selected marking ratios. The respective selected marking ratios indicate to other communication devices that respective network paths via which the selected packets travelled experienced congestion, and the respective marking ratios indicate respective levels of congestion.

A network device includes a rate measurement circuit that is configured to measure respective egress rates at which respective data is being transmitted via respective ports associated with the network device. A marking ratio determination circuit is configured to select respective marking ratios based on respective measured egress rates, the marking ratios for marking packets to be transmitted via the respective ports to indicate respective levels of congestion corresponding to the respective ports. Different marking ratios correspond to different measured egress rates. A packet editor circuit is configured to mark selected packets to be transmitted via respective ports according to the respective selected marking ratios. The respective selected marking ratios indicate to other communication devices that respective network paths via which the selected packets travelled experienced congestion, and the respective marking ratios indicate respective levels of congestion.

Packets received by a network switch device from upstream network devices, coupled to respective ones of a plurality of ports of the network switch device, are temporarily stored in an internal memory of the network switch device. In response to detecting congestion in the internal memory of the network switch device, a flow control engine triggers, during respective timeslots of a timing schedule and while the flow control engine continues to monitor congestion in the internal memory of the network switch device, transmission of respective flow control messages via different subsets of ports, among the plurality of ports, to control flow of packets from different subsets of upstream network device, among the plurality of upstream network devices, to the network switch device so that flow control is distributed over time among upstream network devices of the plurality of upstream network devices.

Packets received by a network switch device from upstream network devices, coupled to respective ones of a plurality of ports of the network switch device, are temporarily stored in an internal memory of the network switch device. In response to detecting congestion in the internal memory of the network switch device, a flow control engine triggers, during respective timeslots of a timing schedule and while the flow control engine continues to monitor congestion in the internal memory of the network switch device, transmission of respective flow control messages via different subsets of ports, among the plurality of ports, to control flow of packets from different subsets of upstream network device, among the plurality of upstream network devices, to the network switch device so that flow control is distributed over time among upstream network devices of the plurality of upstream network devices.