Systems and methods are provided for passing data amongst a plurality of switches having a plurality of links attached between the plurality of switches. At a switch, a plurality of load signals are received from a plurality of neighboring switches. Each of the plurality of load signals are made up of a set of values indicative of a load at each of the plurality of neighboring switches providing the load signal. Each value within the set of values provides an indication for each link of the plurality of links attached thereto as to whether the link is busy or quiet. Based upon the plurality of load signals, an output link for routing a received packet is selected, and the received packet is routed via the selected output link.

A network interface controller (NIC) capable of performing message passing interface (MPI) list matching is provided. The NIC can include a host interface, a network interface, and a hardware list-processing engine (LPE). The host interface can couple the NIC to a host device. The network interface can couple the NIC to a network. During operation, the LPE can receive a match request and perform MPI list matching based on the received match request.

A network interface controller (NIC) capable of facilitating efficient data request management is provided. The NIC can be equipped with a command queue, a message chopping unit (MCU), and a traffic management logic block. During operation, the command queue can store a command issued via a host interface. The MCU can then determine a type of the command and a length of a response of the command. If the command is a data request, the traffic management logic block can determine whether the length of the response is within a threshold. If the length exceeds the threshold, the traffic management logic block can pace the command such that the response is within the threshold.

One embodiment provides a network interface controller (NIC). The NIC can include a storage device, a network interface, a hardware list-processing engine (LPE), and a message state table (MST) logic block. The storage device can store an MST. The network interface can couple the NIC to a network. The LPE can perform message matching on a first packet of a message received via the network interface. The MST logic block can store results of the message matching in the MST and receive a request to read the results of the message matching from the MST if the NIC receives a second packet associated with the message.

Systems and methods are described for providing per traffic class routing of data within a network. A network switch has the capability to classify traffic data based on High Performance Computing (HPC) related characteristics. Traffic classes are defined based on aspects of HPC, such as routing, ordering, redirection, quiesce, HPC protocol configuration, and telemetry. A switch can receive packets at an ingress port of a switch fabric, and determine traffic classifications for the packets. The traffic classification is selected from a group of defined traffic classes. Then, the switch can generate a fabric specific flag for the at least one packet that indicates the determined traffic classification, where the fabric specific flag is used for routing packets based on their assigned traffic classification. Examples of traffic classes include: low latency class; dedicated access class; bulk data class; best efforts class; and scavenger class.

A method is performed by a computing device in a data transport network. The computing device receives congestion-related information corresponding to current conditions of a portion of the network. The computing device determines whether a data transport session has a fair-share protocol. When the data transport session has the fair-share protocol, determining a congestion policy for the data transport session, and applying, using the congestion-related information, the congestion policy to the data transport session.

A method is performed by a computing device in a data transport network. The computing device receives congestion-related information corresponding to current conditions of a portion of the network. The computing device determines whether a data transport session has a fair-share protocol. When the data transport session has the fair-share protocol, determining a congestion policy for the data transport session, and applying, using the congestion-related information, the congestion policy to the data transport session.

A network interface controller (NIC) capable of efficiently utilizing an output buffer is provided. The NIC can be equipped with an output buffer, a host interface, an injector logic block, and an allocation logic block. The output buffer can include a plurality of cells, each of which can be a unit of storage in the output buffer. If the host interface receives a command from a host device, the injector logic block can generate a packet based on the command. The allocation logic block can then determine whether the packet is a multi-cell packet. If the packet is a multi-cell packet, the allocation logic block can determine a virtual index for the packet. The allocation logic block can then store, in an entry in a data structure, the virtual index, and a set of physical indices of cells storing the packet.

A switch equipped with a self-managing reduction engine is provided. During operation, the reduction engine can use a timeout mechanism to manage itself in different latency-induced or error scenarios. As a result, the network can facilitate an efficient and scalable environment for high performance computing.

Systems and methods are provided for managing multicast data transmission in a network having a plurality of switches arranged in a Dragonfly network topology, including: receiving a multicast transmission at an edge port of a switch and identifying the transmission as a network multicast transmission; creating an entry in a multicast table within the switch; routing the multicast transmission across the network to a plurality of destinations via a plurality of links, wherein at each of the links the multicast table is referenced to determine to which ports the multicast transmission should be forwarded; and changing, when necessary, the virtual channel used by each copy of the multicast transmission as the copy progresses through the network.