Examples described herein relate to a network interface device that includes circuitry to process data and circuitry to split a received flow of a mixture of control and data content and provide the control content to a control plane processor and provide the data content for access to the circuitry to process data, wherein the mixture of control and data content are received as part of a Remote Procedure Call. In some examples, provide the control content to a control plane processor, the circuitry is to remove data content from a received packet and include an indicator of a location of removed data content in the received packet.

Examples described herein relate to a network interface device that includes circuitry to process data and circuitry to split a received flow of a mixture of control and data content and provide the control content to a control plane processor and provide the data content for access to the circuitry to process data, wherein the mixture of control and data content are received as part of a Remote Procedure Call. In some examples, provide the control content to a control plane processor, the circuitry is to remove data content from a received packet and include an indicator of a location of removed data content in the received packet.

A robot control system includes a first control device including a first communication unit and one or more second control devices connected to the first control device through a network. Each of the second control devices includes a second communication unit that exchanges data with the first communication unit of the first control device using a communication resource of a network allocated thereto, and a command value generation unit that sequentially generates a command value for driving the robot, in accordance with a command from the first control device. The robot control system includes a communication resource setting unit that allocates the communication resource to each second control device.

A robot control system includes a first control device including a first communication unit and one or more second control devices connected to the first control device through a network. Each of the second control devices includes a second communication unit that exchanges data with the first communication unit of the first control device using a communication resource of a network allocated thereto, and a command value generation unit that sequentially generates a command value for driving the robot, in accordance with a command from the first control device. The robot control system includes a communication resource setting unit that allocates the communication resource to each second control device.

This disclosure describes systems, methods, and devices related to low latency preemption. A device may divide a first PPDU into a plurality of segmented PPDUs. The device may insert a plurality of time gaps between the plurality of segmented PPDUs, wherein the plurality of time gaps enable preemptive opportunities by a low latency transmitter. The device may identify a preemption request from a low latency transmitter of the one or more station devices during a first time gap between a first segmented PPDU and a second segmented PPDU. The device may preempt the second segmented PPDU based on a preemption bit in order to allow the low latency transmitter to transmit its low latency data.

This disclosure describes systems, methods, and devices related to low latency preemption. A device may divide a first PPDU into a plurality of segmented PPDUs. The device may insert a plurality of time gaps between the plurality of segmented PPDUs, wherein the plurality of time gaps enable preemptive opportunities by a low latency transmitter. The device may identify a preemption request from a low latency transmitter of the one or more station devices during a first time gap between a first segmented PPDU and a second segmented PPDU. The device may preempt the second segmented PPDU based on a preemption bit in order to allow the low latency transmitter to transmit its low latency data.

The method of some embodiments forwards packets to a destination node executing on a host computer. The method identifies a set of one or more attributes associated with a set of one or more packets of a data flow. Based on the identified set of attributes, the method dynamically specifies a set of parameters for aggregating, for the destination node, payloads of multiple groups of packets of the data flow. The method creates, according to the set of parameters, an aggregate packet for each group of packets and then forwards each aggregate packet to the destination node. In some embodiments, aggregating each group of packets includes setting headers for each aggregate packet, forwarded to the destination node, where the headers for each aggregate packet correspond to headers of the group of packets.

The method of some embodiments forwards packets to a destination node executing on a host computer. The method identifies a set of one or more attributes associated with a set of one or more packets of a data flow. Based on the identified set of attributes, the method dynamically specifies a set of parameters for aggregating, for the destination node, payloads of multiple groups of packets of the data flow. The method creates, according to the set of parameters, an aggregate packet for each group of packets and then forwards each aggregate packet to the destination node. In some embodiments, aggregating each group of packets includes setting headers for each aggregate packet, forwarded to the destination node, where the headers for each aggregate packet correspond to headers of the group of packets.

A packet processing technique can include receiving a packet, and parsing the packet based on a protocol field to generate a parse result vector. The parse result vector is used to select between forwarding the packet to a virtual machine executing on a host processing integrated circuit, forwarding the packet to a physical media access controller, multicasting the packet to multiple virtual machines executing on the host processing integrated circuit, and sending the packet to a hypervisor.

A flow-based network switching system includes a memory having a flow table and a packet processor coupled to the memory. The packet processor includes a user-programmable flow-based rule storage that includes a plurality of flow-based rules. A flow-based handler and session manager in the packet processor is operable to retrieve application layer metadata from a first packet received over a network, determine a first flow session associated with the first packet using the application layer metadata from the first packet and the flow table, and retrieve at least one of the plurality of flow-based rules from the programmable flow-based rule storage using the application layer metadata from the first packet. A flow-based rule processing engine in the packet processor is operable to apply the at least one flow-based rule to the first packet. Packets with applied flow-based rules are forwarded through the network.