Embodiments of a device and a method for providing data are disclosed. In an embodiment, a device includes a processing system configured to split data of a request into messages by splitting the data based on a node of the data, where the messages fit a supported size, and provide the messages that include the data of the request to a communications interface.

The disclosure relates to modem and router modules for use with digital display systems, including televisions. A modem module is configurable to attach to a set-top box, a set-back box, directly to a digital display, or may even be integrated into display equipment. Router functions and ports can be integrated into the module to provide for networking of additional devices in proximity to the module and/or display, using either or both wired and wireless access technologies. Systems including the module convert power to the appropriate forms for delivery to the different devices, hardware, and components associated with the module. The modem and routing functions are configurable to provide separate security domains to isolate or direct traffic among the various networked devices.

A socket-intercept layer in kernel space on a network device may intercept a packet destined to egress out of the network device. The socket-intercept layer may then query a routing daemon for the Maximum Transmission Unit (MTU) value of the interface out of which that packet is to egress from the network device. In response to this query, the routing daemon may provide the socket-intercept layer with the MTU value of that interface. A tunnel driver in kernel space may identify the size of the packet and fragment the packet into segments whose sizes are each less than or equal to the MTU value of the interface. The tunnel driver may then push the segments of the packet to a packet forwarding engine on the network device. In turn, the packet forwarding engine may forward the segments of the packet to the corresponding destination via the interface.

A first terminal device has first data to be transmitted on a sidelink and has second data to be transmitted on an uplink. The first terminal device performs medium access control MAC protocol data unit PDU assembly on the first data or does not perform MAC PDU assembly on the first data based on a result of comparison between a transmission priority of the first data and a transmission priority of the second data.

Examples describe an egress subsystem that can be used to schedule fetching and transmission of packets from a switch fabric. Segments of a packet can be requested from a switch fabric and stored in a re-order buffer to re-order any segments that are received out of order from the switch fabric. A header segment re-order buffer can be used to re-order segments of a header. After a header of a packet is available in the header segment re-order buffer, the header can be processed before the entire associated body is received from the switch fabric. A jitter threshold scheme can gate egress of a body from a re-order buffer unless a time threshold or amount threshold is met. The egress subsystem can track a state of packet segments from request to transmission, A flow control message received at the egress subsystem can cause packets in certain states to be paused and not permitted to egress.

Some embodiments provide a method for a hardware forwarding element. The method adds a received packet to a buffer. The method determines whether adding the packet to the buffer causes the buffer to pass one of multiple flow control thresholds, each of which corresponds to a different packet priority. When adding the packet to the buffer causes the buffer to pass a particular flow control threshold corresponding to a particular priority, the method generates a flow control message for the particular priority.

A multi-endpoint adapter device includes a splitter device that is coupled to a network port and a plurality of endpoint subsystems that are each coupled to a processing subsystem. The splitter device receives, via the network port, a first data payload, and identifies both a first data sub-payload that is included in the first data payload and that is associated with a first endpoint subsystem included in the plurality of endpoint subsystems and a second data sub-payload that is included in the first data payload and that is associated with a second endpoint subsystem included in the plurality of endpoint subsystems. The splitter device then splits the first data payload into the first data sub-payload and the second data sub-payload, and forwards both the first data sub-payload to the first endpoint subsystem and the second data sub-payload to the second endpoint subsystem.

The disclosure relates to modem and router modules for use with digital display systems, including televisions. A modem module is configurable to attach to a set-top box, a set-back box, directly to a digital display, or may even be integrated into display equipment. Router functions and ports can be integrated into the module to provide for networking of additional devices in proximity to the module and/or display, using either or both wired and wireless access technologies. Systems including the module convert power to the appropriate forms for delivery to the different devices, hardware, and components associated with the module. The modem and routing functions are configurable to provide separate security domains to isolate or direct traffic among the various networked devices.

A network interface device having an FPGA for providing an FPGA application. A first interface between a host computing device and the FPGA application is provided, allowing the FPGA application to make use of data-path operations provided by a transport engine on the network interface device, as well as communicate with the host. The FPGA application sends and receives data with the host via a memory that is memory mapped to a shared memory location in the host computing device, whilst the transport engine sends and receives data packets with the host via a second memory. A second interface is provided to interface the FPGA application and transport engine with the network, wherein the second interface is configured to back-pressure the transport engine.

Methods and network interface modules for processing packet headers are provided. The method comprises: receiving a packet comprising a header and a payload; generating, using the header, an initial packet header vector (PHV); providing the initial PHV to a pipeline comprising a plurality of processing stages; and processing the initial PHV in the pipeline, wherein the processing comprises, for a current processing stage in the plurality of processing stages: receiving, by the current processing stage, an input PHV, wherein the input PHV (i) is the initial PHV or a modified version of the initial PHV and (ii) comprises one or more flits, and applying a feature to the input PHV to generate an output PHV, including increasing an initial length of the input PHV if the initial length is not sufficient to apply the feature.