A computing device has a motherboard, at least two daughter boards communicably connected to the motherboard, each of the at least two daughter boards having at least a specialized processor and a high-speed inter-processor communications port; and at least two high-speed inter-processor communication interconnects connecting at least two of the high-speed inter-processor communications ports. The configuration enables a flexible topology architecture, e.g., for different applications, and rapid reuse of system components even when new specialized processors become available.

An interface circuit is provided and includes a first switching device connected to a first power supply node supplying a first voltage, and controlled by a first input signal, a second switching device connected to a second power supply node supplying a second voltage lower than the first voltage, and controlled by a second input signal different from the first input signal, an output node through which the first switching device and the second switching device are connected to each other in series, outputting an output signal, a first resistor connected between the first power supply node and the first switching device, a second resistor connected between the second power supply node and the second switching device, a first capacitor connected to a node between the first resistor and the first switching device, and a second capacitor connected to a node between the second resistor and the second switching device.

Techniques and mechanisms for exchanging control signals in a data path module of a data stream processing engine. In an embodiment, the data path module may be configured to form a set of one or more data paths corresponding to an instruction which is to be executed. In another embodiment, data processing units of the data path module may be configured to exchange one or more control signals for elastic execution of the instruction.

Techniques and mechanisms for exchanging control signals in a data path module of a data stream processing engine. In an embodiment, the data path module may be configured to form a set of one or more data paths corresponding to an instruction which is to be executed. In another embodiment, data processing units of the data path module may be configured to exchange one or more control signals for elastic execution of the instruction.

Techniques are described for preserving desktop state between login sessions in desktop computing environments. During an active login session of a desktop by a user, the system intercepts all requests to open a file and records the requested file paths. The information can be recorded locally or at a remote location, such as a server accessed over a network connection. Before the login session is terminated, the system determines all open windows and captures a screenshot of each window that is open on the desktop at the time of terminating the login session. The location of each window is also determined and recorded along with the screenshots before the session is terminated. When the user starts a new active login session at a later time, the state of the desktop is restored using the recorded file paths, screenshots and window locations.

A computer system includes a plurality of servers connected to each other via a communication line, each server including a memory and a processor, an OS program and a storage program. The storage program is executed by the processor, and one of the plurality of servers acts as a request source server while one of the other servers acts as a request destination server. When the request source server reads data from the request destination server, the processor of the request source server executes the storage program to transmit a data read request to the request destination server. The processor of the request destination server then executes a storage memory driver incorporated in the OS program to read the requested data from an own memory and transmit the read data to the request source server. The request source server then executes the storage program to acquire the data.

A signal processing device and a vehicle communication device including the same are disclosed. The signal processing device according to an embodiment of the present disclosure includes: a first processor configured to receive a first message including a sensor signal in a vehicle based on a first communication scheme; a second processor configured to receive a second message including a communication message received from an external source based on a second communication scheme; and a shared memory configured to operate to transmit the first message or the second message between the first processor and the second processor. Accordingly, it is possible to reduce latency and to perform high-speed data transmission during inter-processor communication.

The present disclosure discloses a computing apparatus configured to perform a binary operation on multi-dimensional data, and related products. The computing apparatus is included in a combined processing apparatus. The combined processing apparatus further includes an interface apparatus and other processing apparatus. The computing 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 computing apparatus and other processing apparatus respectively and is configured to store data of the computing apparatus and other processing apparatus. The disclosed scheme may reduce the number of data exchange and loading, relieve throughput pressure, and improve processing efficiency of a machine by rationally allocating the loading frequency of operation data.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for determining, for each pair of adjacent chips in a plurality of chips connected in a series-ring arrangement of a semiconductor device, a corresponding loop latency for round trip data transmissions between the pair of chips. Identifying, from among the loop latencies, a maximum loop latency. Determining a ring latency for a data transmission originating from a chip of the plurality chips to be transmitted around the series-ring arrangement and back to the chip. Comparing half of the maximum loop latency to one N-th of the ring latency, where N is the number of chips in the plurality of chips, and storing the greater value as an inter-chip latency of the semiconductor device, the inter-chip latency representing an operational characteristic of the semiconductor device.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for determining, for each pair of adjacent chips in a plurality of chips connected in a series-ring arrangement of a semiconductor device, a corresponding loop latency for round trip data transmissions between the pair of chips. Identifying, from among the loop latencies, a maximum loop latency. Determining a ring latency for a data transmission originating from a chip of the plurality chips to be transmitted around the series-ring arrangement and back to the chip. Comparing half of the maximum loop latency to one N-th of the ring latency, where N is the number of chips in the plurality of chips, and storing the greater value as an inter-chip latency of the semiconductor device, the inter-chip latency representing an operational characteristic of the semiconductor device.