A port status synchronization method, related device, and system, where a physical layer (PHY) device or an external processor connected to the PHY device determines whether a first service interface of the PHY device changes, and when the first service interface changes, controls a second service interface of the PHY device to restart auto-negotiation and sends, using the second service interface, an auto-negotiation advertisement packet to a first device connected to the second service interface in order to trigger the first device to synchronize, according to the auto-negotiation advertisement packet, a status of the second service interface and a status of the first service interface such that performing port status negotiation and synchronization between a link layer (media access control (MAC)) device or the first device and the PHY device using a service interface is achieved, without a need of disposing a management data input/output (MDIO) interface.

A system for negotiating Ethernet link settings between interconnected nodes in a network having an Ethernet protocol stack that includes a PCS sub-layer with an auto-negotiation function. The system comprises connecting an intermediate device coupled between two network nodes via optical or copper interfaces, with the link settings between each node and the connected intermediate device being the same, thereby bypassing the auto-negotiation of the PCS sub-layer in the intermediate device. The intermediate device may transparently send negotiation messages from each node to the other during the link negotiation phase without interacting with those messages. Instead of the intermediate device, a single form pluggable (SFP) device may be connected between the two network nodes via optical or copper interfaces on the network side and via an SFP slot on the device side.

The amount of data being delivered across networks is constantly increasing. This system and method demonstrates an improved system and method for establishing secure network connections with increased scalability and reduced latency. This approach also includes arbitrary segmentation of incoming network traffic, and dynamic assignment of parallel processing resources to execute application code specific to the segmented packets. The method uses a modified network state model to optimize the delivery of information and compensate for overall network latencies by eliminating excessive messaging. Network data is application generated, and encoded into pixel values in a shared framebuffer using many processors in parallel. These pixel values are transported over existing high speed video links to the Advanced Network Interface Card, where the network data is extracted and placed directly on to high speed network links.

A transceiver of a first network device including an autonegotiation circuit and a first serializer interface. The auto-negotiation circuit is to negotiate a first data rate for transmission of data between the first network device and a second network device. The first serializer interface to receive the negotiated first data rate from the auto-negotiation circuit, receive first data from the second network device at the negotiated first data rate, replicate portions of the first data received from the second network device in accordance with the negotiated first data rate, and transmit, at a second data rate different from the first data rate, the first data including the replicated portions from the first serializer interface to a second serializer interface of the first network device.

A system comprises a network interface to receive a stream of packets from a network, insert each of the packets into a buffer in memory of a graphics processing unit using direct memory access, assign each of the packets an index representing an offset indicating a location in the memory of the graphics processing unit, determine that a pre-configured buffer flow capacity has been reached regarding a first buffer in the graphics processing unit, and transmit an interrupt to the graphics processing unit corresponding to the pre-configured buffer flow capacity regarding the first buffer in the graphics processing unit. The graphics processing unit is connected to the network interface over a bus and starts a first kernel specific to the first buffer in response to the interrupt.

Power Over Ethernet (POE)/universal power over Ethernet (UPoE) may be enabled at multigigabit port-channel connections. This may allow for additional speed support in auto-negotiation messages while employing multigigabit speeds. An integrated connector module (referred to herein as a ICM) compatible with UPoE with a modified local physical layer (PHY) circuit may be capable of supporting multi-gigabit data rates (such as between 1 G to 10 G, e.g., 2.5 G and 5 G) as to not limit the data rates to 1 G. The ICM may provide multi-gig data transmission through a first plurality of pins comprising a multi-gig data pin area. Furthermore, the ICM may provide UPoE power to support the multi-gig transmission through a second plurality of pins comprising a UPoE power pin area.

A first network device may determine a first auto-negotiation capability associated with the first network device. The first auto-negotiation capability may indicate whether the first network device is configured to establish a communication link with a second network device using auto-negotiation of transmission capabilities. The first network device may determine a second auto-negotiation capability associated with the second network device. The second auto-negotiation capability may indicate whether the second network device is configured to establish the communication link with the first network device using auto-negotiation of the transmission capabilities. The first network device may determine that an auto-negotiation process failed to establish the communication link between the first network device and the second network device. The first network device may enable or disable auto-negotiation on the first network device based on determining that the auto-negotiation process failed, and based on the first auto-negotiation capability and the second auto-negotiation capability.

A system for negotiating Ethernet link settings between interconnected nodes in a network having an Ethernet protocol stack that includes a PCS sub-layer with an auto-negotiation function. The system comprises connecting an intermediate device coupled between two network nodes via optical or copper interfaces, with the link settings between each node and the connected intermediate device being the same, thereby bypassing the auto-negotiation of the PCS sub-layer in the intermediate device. The intermediate device may transparently send negotiation messages from each node to the other during the link negotiation phase without interacting with those messages. Instead of the intermediate device, a single form pluggable (SFP) device may be connected between the two network nodes via optical or copper interfaces on the network side and via an SFP slot on the device side.

An embodiment may include determining at least one respective amount of buffer memory to be used to store at least one respective portion of network traffic. The determining may be based at least in part upon at least one respective parameter associated with the at least one respective network traffic portion. The at least one respective amount may be sufficient to store the at least one respective portion of the network traffic. The at least one respective parameter may reflect at least one actual characteristic of the at least one respective portion of the network traffic. This embodiment also may permit at least one respective portion of the buffer memory that may correspond to the at least one respective amount to be selectively powered-on to permit the at least one portion of the buffer memory to be used to store the at least one respective network traffic portion.

Methods and systems for dynamic port subdivision during link negotiation and initiation are provided. Embodiments include selecting a reference lane from port configuration information for the potential link partner; selecting a subdivision evaluation lane from the port configuration information for of the potential link partner; and comparing a GUID and port number of the reference lane with a GUID and port number of a subdivision evaluation lane. If the GUID and port number of a reference lane and the GUID and port number of a subdivision evaluation lane are not the same, embodiments include subdividing the port into a plurality of subdivided ports.