Provided are a message interaction processing method and device. The method includes: a first buffer with a preset size is applied for to a Central Processing Unit (CPU) and/or a chip; and message interaction is performed between the CPU and the chip through the first buffer, wherein the first buffer is used for storing at least two messages. By the disclosure, the problem that frequent switching between states may cause high resource overhead and low message transmission efficiency under the condition of large message interaction between the CPU and the chip is solved, and the effect of remarkably improving message sending and receiving efficiency and performance of network equipment is further achieved.

A communication configuration apparatus for constructing a communication topology structure based on a plurality of processing nodes may be included in a combined processing apparatus. The combined processing apparatus further includes an interconnection interface and other processing apparatus. The communication configuration apparatus interacts with other processing apparatus to jointly complete a computing operation specified by a user. The combined processing apparatus further includes a storage apparatus. The storage apparatus is connected to the communication configuration apparatus and other processing apparatuses, respectively. The storage apparatus is used for storing data of the communication configuration apparatus and other processing apparatus. A technical solution of the present disclosure may improve efficiency of inter-chip communication.

Apparatus and method for metasearching on a wireless sensor network, which comprises a plurality of spatially distributed autonomous devices, comprising a plurality of spatially distributed sensor nodes, comprising a plurality of motes, each of which has a mote transceiver and at least one sensor that monitors physical and environmental conditions and collects physical and environmental data at a plurality of locations; and a gateway node, comprising a metasearch engine that sends a plurality of queries to at least of the plurality of motes, via the gateway node, based upon a request executed on a client device; the gateway node receiving search results from the at least two motes, the metasearch engine comprising a processor that groups and sorts the search results into at least two different groups comprising a plurality of physical and environmental data lists; the metasearch engine sending a response, via the gateway node, to the client device.

Data exchange section 104 has a step of determining whether or not pairs of the transmission selecting conditions and reception selecting conditions satisfy a standard for exchanging, through a determined pair, data between a transmission user who corresponds to a transmission selecting condition in the determined pair and a reception user who corresponds to a reception selecting condition in the determined pair. Data exchange system 100 exchanges data satisfying both the transmission selecting condition and the reception selecting condition in the determined pair between the transmission user and the reception user, respectively corresponding to the transmission selecting condition and the reception selecting condition in the determined pair.

Systems and techniques facilitating resource frequency management are provided. An apparatus comprises: a processor; and a memory that stores executable instructions that, when executed by the processor, facilitate performance of operations. The operations comprise: receiving information indicative of an emergency condition in a defined area; and transmitting a command to a network device for the defined area to cause the base station device to send a communication for the emergency condition via a first wireless communication channel with a mobile device of mobile devices associated with a subscriber identity of respective subscriber identities assigned to provide a response to the emergency condition.

One embodiment provides a system that facilitates dynamic adjustment of forwarding information in a CCN. During operation, the system receives, by forwarding circuitry, an interest with a name that is a hierarchically structured variable length identifier which comprises contiguous name components ordered from a most general level to a most specific level. The system identifies in a first data structure an entry for one or more name components of the name, wherein the entry includes a list of outgoing interfaces associated with the one or more name components. The system determines network properties in response to forwarding the interest to a first interface of the list. The system reorders the list in order of priority based on the network properties, thereby facilitating the forwarding circuitry to dynamically adjust a likelihood of using a respective interface for forwarding interests associated with the one or more name components.

Various embodiments facilitate location-aware distributed competitions. In one embodiment, a system facilitates a distributed sporting event that includes multiple players traveling over non-uniform courses that are remote from one another. The system includes a manager that receives state information, such as location information, from client devices used by each of the players. The manager then transmits location information for each of the players to the client devices, which are each configured to present a graphical representation, such as a map annotated with the locations of each of the players. The system corrects for disparities between the non-uniform courses traveled by the players, for example by mapping a location on a course traveled by a first player to a location on a course traveled by a second player. Various mechanisms for establishing the mapping between non-uniform courses are also described.

A multiprocessor system includes a first microprocessor and a second microprocessor. A first signaling pathway is configured to send message transmission coordination signals from the first microprocessor to the second microprocessor. The first signaling pathway may be coupled to at least two flag registers associated with the second microprocessor. A second signaling pathway is configured to send message transmission coordination signals from the second microprocessor to the first microprocessor. The second signaling pathway may be coupled to at least two flag registers associated with the first microprocessor. The first signaling pathway is independent of the second signaling pathway.

Methods and apparatus for in-network parallel prefix scan. In one aspect, a dual binary tree topology is embedded in a network to compute prefix scan calculations as data packets traverse the binary tree topology. The dual binary tree topology includes up and down aggregation trees. Input values for a prefix scan are provided at leaves of the up tree. Prefix scan operations such as sum, multiplication, max, etc. are performed at aggregation nodes within the up tree as packets containing associated data propagate from the leaves to the root of the up tree. Output from aggregation nodes in the up tree are provide as input to aggregation nodes in the down tree. In the down tree, the packets containing associated data propagate from the root to its leaves. Output values for the prefix scan are provided at the leaves of the down tree.

Systems and methods for automatically removing and replacing outdated compute resources in a cluster. The systems and methods include a configurable monitoring system that is configured to detect outdated compute resources and trigger a cycling process to automatically replace the detected outdated compute resources with new compute resources. The disclosed systems and methods safely rotate a group of compute resources by identifying and detaching outdated compute resources, waiting until the outdated compute resources have been drained of pending jobs scheduled on these resources, waiting until replacement compute resources have started and then cordoning, draining, deleting and terminating the outdated compute resources.