A system and method for connecting one or more client applications with one or more knowledge representation servers and communicating there between includes an application programming interface (API) and a hypergraph transfer protocol (HGTP), for facilitating communication between the one or more client applications and one or more knowledge representation servers responsive to a client application request. The client application request includes an API call for a specific entity that is received by a first knowledge representation server. If the first knowledge representation server does not manage the specific entity, the first knowledge representation server forwards the specific entity call to a second knowledge representation server via the HGTP using a universal unique identifier (UUID) associated with the specific entity having encoded therein a network address for the second knowledge representation server.

A network device includes an antenna connected to an RF chip and a processor coupled to an Ethernet port, the RF chip, a program memory, a packet buffer memory, a pointer buffer memory, and a program memory. The program memory contains instruction that, when executed by the processor, cause a plurality of packets received by the antenna and the RF chip in a first order to be stored in the packet buffer memory in such order, cause a pointer associated with each one of the plurality of packets to be stored in the pointer buffer memory, cause the pointers stored in the pointer buffer memory to be placed in a second order in accordance with a timestamp that is included with each packet, cause the packets stored in the packet buffer memory to be passed along to the Ethernet port in accordance with the sorted pointer to each packet.

The disclosed embodiments relate generally to efficient data encoding and transmission. An encoding system determines an encoding interval at which to encode different groups of related data in a data structure. The encoding interval for each group encoded together optimizes the amount of newly received information that is encoded and transmitted in a continuous, repeating loop.

According to an example, a counter update determination module may receive a counter address for a local counter and map the counter address to a specific forwarding mode of a plurality of forwarding modes. In addition, a remote processing module may receive a posted value associated with the local counter. The remote processing module may include a plurality of forwarding engines respectively associated with a mapped forwarding mode. A forwarding engine of the plurality of forwarding engines may be selected based on the mapped forwarding mode, and the selected forwarding engine may forward the posted value to a remote device for remote processing.

According to an example, a counter update determination module may receive a counter address for a local counter and map the counter address to a specific forwarding mode of a plurality of forwarding modes. In addition, a remote processing module may receive a posted value associated with the local counter. The remote processing module may include a plurality of forwarding engines respectively associated with a mapped forwarding mode. A forwarding engine of the plurality of forwarding engines may be selected based on the mapped forwarding mode, and the selected forwarding engine may forward the posted value to a remote device for remote processing.

Techniques are described for establishing a second label switched path (LSP) instance of an LSP having a first LSP instance. In one example, for each downstream router designated for the second LSP instance of the LSP, the router determines whether the router is part of the first instance of the LSP and, if so, whether the first and second LSP instances for that downstream router share a common link to a nexthop router. If the first and second LSP instances share a common link to a nexthop router, the downstream router transmits a first message to the nexthop router, wherein the first message includes a suggested label. The downstream router receives, from the nexthop router, a second message, wherein the second message includes the suggested label. In another example, a label reuse indicator flag in a message from the ingress router causes routers on the second LSP instance to reuse the label of the first LSP instance when the same link is used to the upstream router for both LSP instances.

A system and method of providing direct data access between a non-volatile cache and a NIC in a computing system. A system is disclosed that includes a processing core embedded in a controller that controls a non-volatile cache; and a direct access manager for directing the processing core, wherein the direct access manager includes: a switch configuration system that includes logic to control a switch for either a remote direct access mode or a host access mode, wherein the switch couples each of the NIC, a local bus, and the non-volatile cache; a command processing system that includes logic to process data transfer commands; and a data transfer system that includes logic to manage the flow of data directly between the non-volatile cache and the NIC.

A system and method of providing direct data access between a non-volatile cache and a NIC in a computing system. A system is disclosed that includes a processing core embedded in a controller that controls a non-volatile cache; and a direct access manager for directing the processing core, wherein the direct access manager includes: a switch configuration system that includes logic to control a switch for either a remote direct access mode or a host access mode, wherein the switch couples each of the NIC, a local bus, and the non-volatile cache; a command processing system that includes logic to process data transfer commands; and a data transfer system that includes logic to manage the flow of data directly between the non-volatile cache and the NIC.

Systems and methods are provided for coordinating decisions between noncommunicating parties using quantum physics. The procedure includes recognizing and identifying features of a coordinating decisions between non-communicating parties (CDNP) problem, expressing these features in a precise and mathematical manner, finding a solution using quantum states and measurements, and physically implementing the solution. Since quantum mechanics can violate Bell inequalities, quantum solutions to a CDNP problem have advantages over non-quantum solutions.

Systems and methods are provided for coordinating decisions between noncommunicating parties using quantum physics. The procedure includes recognizing and identifying features of a coordinating decisions between non-communicating parties (CDNP) problem, expressing these features in a precise and mathematical manner, finding a solution using quantum states and measurements, and physically implementing the solution. Since quantum mechanics can violate Bell inequalities, quantum solutions to a CDNP problem have advantages over non-quantum solutions.