Examples disclosed herein relate to receiving, by a scheduler, a request for a window during which to send a data packet through a crossbar. Transmission of the data packet is dependent upon a pool of transmission credits. The scheduler determines whether the pool of transmission credits is sufficient for transmitting the data packet, and when it is determined that the pool of transmission credits is insufficient, the scheduler determines whether to block the request or to speculatively arbitrate the window based on a value of a speculative request counter.

A method is provided in one example embodiment and includes receiving at a network element a packet associated with a flow and determining whether a flow cache of the network element includes an entry for the flow indicating a classification for the flow. The method further includes, if the network element flow cache does not include an entry for the flow, punting the packet over a default path to a classifying service function, in which the classifying service function classifies the flow and determines a control plane service function for handling the flow, and receiving from the classifying service function a service path identifier (“SPI”) of a service path leading to the determined control plane service function. The flow is subsequently offloaded from the classifying service function to the network element.

The disclosure relates to technology for load balancing link utilization of a networking device based on fractal analysis. In one embodiment, link utilization of switches, routers, etc. in a data center is balanced based on a fractal model of the link utilization. Techniques disclosed herein are proactive. For example, instead of reacting to link congestion, the technique predicts future link utilization based on fractal analysis. Then, packet flows (or flowlets) may be assigned to links based on the predicted future link utilization. Hence, congestion on links may be reduced or prevented.

Selecting an output channel, from a plurality of output channels of a communication system associated with a database management system, for transmission of an entity document to an entity from the database management system. The determining based on an entity classification of the entity within the database management system. Responsive to receiving a service-orientated-architecture service request for the entity at the database management system, the service-orientated-architecture (SOA) service request is converted to a message having a format associated with the entity classification of the entity. Converting the SOA includes selecting, based on a content of the SOA service request, a template, having a predefined set of semantics, associated with the entity classification of the entity, selecting a semantic that corresponds to the SOA service request, and transmitting the message with the selected semantic through the output channel.

Embodiments of the present invention may provide improved handling of communication characteristics, such as burstiness, latency-sensitive applications, bandwidth-sensitive applications, etc., to improve peak performance while not compromising other characteristics, such as thermal design power of the input/output chip packages. In an embodiment, in a control circuit that may be connected to and control a data transmitter, a method of transmitting data in a network may comprise receiving at least one feed-forward signal from the data transmitter, receiving at least one feedback signal from at least a first node of the network, comparing the at least one feed-forward signal with at least one threshold or condition, comparing the at least one feedback signal with at least one threshold or condition, and generating a signal indicating that a burst transmission should be started or stopped.

The present invention discloses methods and systems for transmitting and receiving packets through a plurality of logical connections based on priority levels. When an encapsulating packets is received from a second network device via a logical network connection, priority level of a packet encapsulated in the encapsulating packet is determined, and the encapsulating packet is stored in a queue or transmitted to a host based on GSEQ, PSEQ, TSEQ, and the priority level. When a packet is received from a host via a LAN connection, the packet is retrieved from a priority queue based on the priority level a first logical network connection is selected for transmitting the packet. The packet is encapsulated in an encapsulating packet, and the payload of the encapsulating packet comprises the packet, GSEQ, TSEQ, PSEQ, and priority level of the packet. The encapsulating packet is then sent through the first logical network connection.

A method of controlling data packet congestion in a data packet network comprises determining a reference flow condition that results in data packet congestion at a node of a data packet network, and identifying a data packet flow having a flow condition substantially equal to the reference flow condition. For such an identified data packet flow the following actions are taken causing a data packet to be dropped from the identified data packet flow, allowing a predetermined number of data packets from the identified data packet flow to proceed, and dropping data packets from the identified data packet flow subsequent to the predetermined number of data packets, until the packets that were not dropped have been delivered to the egress ports of the network.

A network apparatus comprising a trunk end point associated with an Ethernet-tree (E-Tree) service in a network domain and configured to forward a frame that comprises a tag according to the tag in the frame, wherein the tag in the frame is a root tag that indicates a root source of the frame or a leaf tag that indicates a leaf source of the frame, and wherein the trunk end point is coupled to a second end point associated with the E-tree service outside the network domain.

A method for dynamic routing is provided. Status information of a multichannel video and data distribution service (MVDDS) channel from customer premises equipment (CPE) is received. The status information is evaluated to determine if data destined for the CPE over the MVDDS channel should be routed over a secondary channel. Data destined for the CPE is route over the secondary channel when the data is determined to be routed over the secondary channel.

The subject technology discloses configurations for receiving, at a first network device, a set of network packets corresponding to a first flow from a client, wherein the set of network packets includes a destination address of a second network device; detecting, in the received set of network packets, pacing rate information indicating a specified pacing rate for transmission of the network packets; determining, based on the detected pacing rate, a desired pacing rate to reduce packet dropping on route to the second network device; and transmitting, by the first network device, the set of network packets over an egress link at the desired pacing rate.