A method of communicating data using virtualization includes splitting, at endpoint software running on a first device, first data for communication to a destination device into a first plurality of data streams; selecting, at the first device by the endpoint software, a first plurality of deflects for use in communicating the first plurality of data streams; communicating each of the first plurality of data streams over a different one of the selected first plurality of deflects; splitting, at the first deflect, a particular data stream of the first plurality of data streams into a second plurality of data streams; selecting, at the first deflect, a second plurality of deflects for use in communicating the second plurality of data streams; and communicating each of the second plurality of data streams over a different one of the selected second plurality of deflects.

A method of operating a hypercube network of processing devices includes determining that a plurality of the processing devices are storing data to be processed at a single processing device, obtaining the addresses of the plurality of processing devices storing the data to be processed, determining the most common number for each digit of the addresses of the plurality of processing devices storing the data to be processed, generating a new address comprising the determined most common number for each digit, and transferring the data to be processed to the processing device with the generated new address.

In accordance with one or more preferred implementations, an overlay network in the form of a dispersive virtual network is implemented utilizing data deflects to implement and facilitate routing in a data plane and call processing deflects to implement and facilitate routing in a control plane. Various nodes in the dispersive virtual network, such as end devices running dispersive virtual networking client software, establish communication channels to these deflects running dispersive virtual networking protocols transported by user datagram protocol (UDP) frames, transmission control protocol (TCP) streams, and hypertext transfer protocol (HTTP) streams. In accordance with one or more preferred implementations, software allows nodes in a dispersive virtual network to automatically detect the channel types that are available at the time the node must initiate a new session, and automatically configure the most efficient communication channel without requiring input from an end user or from a network administrator.

Systems and methods for controlling devices, including controller and actuators are disclosed. Actuators may be devices where remote control of the device or devices is convenient, such as lights, window shades, fans and similar items. In one method, controllers are adapted to send commands from a first controller to an actuator and to a second controller, and from the second controller to the actuator and to the first controller, where the controllers store a state of the actuator as a result of the actuator executing the command.

A method of operating a hypercube network of processing devices includes determining that a plurality of the processing devices are storing data to be processed at a single processing device, obtaining the addresses of the plurality of processing devices storing the data to be processed, determining the most common number for each digit of the addresses of the plurality of processing devices storing the data to be processed, generating a new address comprising the determined most common number for each digit, and transferring the data to be processed to the processing device with the generated new address.

Example routing systems and methods are described. In one implementation, a first set of routing systems is interfaced with a network connection via a network interface. A second set of routing systems interfaced with a secure system is configured to receive information from the first set of routing systems via a first unidirectional data channel. In some embodiments, the first set of routing systems is configured to receive information from the second set of routing systems via a second unidirectional data channel. The secure system is not visible from the network interface.

A method, system and computer program product are disclosed for routing data packet in a computing system comprising a multidimensional torus compute node network including a multitude of compute nodes, and an I/O node network including a plurality of I/O nodes. In one embodiment, the method comprises assigning to each of the data packets a destination address identifying one of the compute nodes; providing each of the data packets with a toio value; routing the data packets through the compute node network to the destination addresses of the data packets; and when each of the data packets reaches the destination address assigned to said each data packet, routing said each data packet to one of the I/O nodes if the toio value of said each data packet is a specified value. In one embodiment, each of the data packets is also provided with an ioreturn value used to route the data packets through the compute node network.

Systems, methods, and devices of the various embodiments may enable the mitigation of malicious botnets. Various embodiments may block communication of malicious botnets from customer computing devices to malicious command and control (C2) servers. Various embodiments may include mitigating botnets in a network by diverting Internet traffic bound for a malicious C2 server to a botnet mitigation controller of the network. In various embodiments, diverting Internet traffic may include programmatically injecting Border Gateway Protocol (BGP) routes in a network to route Internet traffic bound for a malicious C2 server to a botnet mitigation controller of the network. In various embodiments, a botnet mitigation controller may determine whether diverted Internet traffic is malicious and may handle malicious diverted Internet traffic according to one or more security settings.

With the advent of manycore architecture, on-chip interconnect connects a number of cores, caches, memory modules, accelerators, graphic processing unit (GPU) or chiplets in one system. However, on-chip interconnect architecture consumes a significant portion of total parallel computing chip power. Power-gating is an effective technique to reduce power consumption by powering off the routers, but it suffers from a large wake-up latency to resume the full activity of routers. Recent research aims to improve the wake-up latency penalty by hiding it through early wake-up techniques. However, these techniques do not exploit the full advantage of power-gating due to the early wake-up. Consequently, they do not achieve significant power savings. The present invention provides a new router architecture that remedies the large wake-up latency overheads while providing significant power savings. The invention takes advantage of a simple switch to transmit packets without waking up the router. Additionally, the technique hides the wake-up latency by continuing to provide packet transmission during the wake-up phase.

A method for the exchange of data between nodes of a server cluster includes a plurality of nodes interconnected together by a geographic interconnection network including a plurality of transmission segments linking the plurality of nodes together according to a predetermined limited number of several different connection directions respectively associated with several different coordinates of a system of coordinates, each transmission segment of the geographic interconnection network thus belonging to a single one of the different connection directions and the system of coordinates thus being defined such that each coordinate of the system of coordinates is associated with a single one of the different connection directions, the method including sending, by a sending node, data intended for at least one other receiving node; transmitting the data using the geographic interconnection network; and receiving the data by each the receiving node.