A management method for multiple communication devices, wherein the multiple communication devices include a host device and a first peripheral device configured to electrically connect to a device platform, and the management method includes: by the host device, detecting a connection of the first peripheral device through the device platform; by the host device, receiving a first device identifier provided by the first peripheral device through the device platform; by the host device, storing the first device identifier in the host device; and by the host device, wirelessly pairing the host device with the first peripheral device, according to the first device identifier stored in the host device, to enable a first wireless communication between the host device and the first peripheral device.

A method of sharing a resource using a virtual device driver and an electronic device thereof are provided. The method includes generating a virtual device driver, which corresponds to a real device driver of a host electronic device, in the client electronic device, receiving a resource from the host electronic device by using the virtual device driver through a first communication mechanism designated in the host electronic device, and after the first communication mechanism is changed to a second communication mechanism designated in the host electronic device, receiving the resource from the host electronic device by using the virtual device driver.

According to the computer device and the configuration and management method of a computer device that are provided in the embodiments of the present invention, an SMM and a CPU are controlled to connect to a PCIE Switch at different stages of system startup, so that management of a PCIE device does not rely on involvement of the CPU of the computer device. In this way, the PCIE device can be configured and managed without involvement of an operating system of the computer device, and CPU resources are saved. Manageability of the computer device is improved, meeting a requirement of a large data center for simplifying computing device management. In addition, the PCIE device is connected to the PCIE Switch by using a downstream port, with no need to configure a special interface to connect to the SMM, thereby simplifying system configuration.

The invention provides a hot plug method and device for a byte-addressable persistent memory, which includes hot-add and hot-remove; wherein the hot-add includes physical add and logical add, and the hot-remove includes logical remove and physical remove; the physical add is used for converting the memory from an uncharged raw media into a manageable block of an operating system; the logical add is used for converting the memory from the manageable block of the operating system into a memory device which capable of mapping a virtual address; the logical remove is used for converting the memory device which capable of mapping the virtual address into the manageable block of the operating system; and the physical remove is used for converting the memory from the manageable block of the operating system into the uncharged raw media. The method and device provided in the invention are suitable for scheduling and deployment the byte addressable persistent memory resource on any computer architecture and have a sound market outlook and application value.

Systems and methods of controlling operation of a connection device associated with a modular computing system are disclosed. For instance, data indicative of a connection between a first connection device and a second connection device can be obtained. The first connection device can be associated with a modular computing device, and the second connection device can be associated with a modular component to be implemented within the modular computing device. Each connection device can include a plurality of connector elements. Data indicative of one or more configuration parameters of the second connection device can be obtained. An operating configuration of the first connection device can be determined based at least in part on the data indicative of the one or more configuration parameters. Operation of the first connection device can be controlled based at least in part on the operating configuration.

Methods, systems, and computer program products are included for providing a virtual machine guest with access to a host device. A method includes providing a hypervisor with access to an enhanced allocation capability entry of a host device. The host device performs input and output operations via a range of addresses that are provided by the enhanced allocation capability entry. The hypervisor runs a virtual machine and configures the virtual machine to include a virtual device corresponding to the host device. The virtual device includes the range of addresses in an enhanced allocation capability entry. The hypervisor modifies a context, such as a bit map, corresponding to the virtual machine to provide guests of the virtual machine with access to perform I/O operations corresponding to the host device using the range of addresses.

A data input circuit of a semiconductor apparatus may include a plurality of parallelizing units corresponding to a plurality of input/output pads in a one-to-one manner, and a data control block configured to transmit serial test data, which may be input through less than all of the plurality of input/output pads, to the plurality of parallelizing units in response to first and second control signals.

A secure peripheral switching system comprises a secure peripheral switch remotely coupled to a secure remote controller-indicator, wherein the secure peripheral switch is capable of interfacing with at least two coupled host computers while ensuring data isolation among said at least two coupled host computers, said secure peripheral switch comprising a first interface circuitry to securely link the secure peripheral switch with said secure remote controller-indicator; and a secure remote controller-indicator. The secure remote controller-indicator comprises a second interface circuitry to securely link said secure remote controller-indicator with said secure peripheral switch; a control function capable of enabling a remote user control of said coupled secure peripheral switch; an indication function capable of providing a remote user indications of coupled secure peripheral switch; and an anti-tampering circuitry to detect physical tampering event and report such event to said secure peripheral switch.

An example processor-implemented method for accessing peripheral devices with the present disclosure includes establishing connection between a portable computing device and a dock, determining a pairing status between the portable computing device and the dock, and managing access to at least one peripheral device by the portable computing device based on the pairing status. The dock is associated with the at least one peripheral device.

A universal serial bus (USB) multi-host device includes a plurality of upstream ports connected to a first host and a second host, a storage for storing data to be transmitted from the first host to the second host through the upstream ports, and a controller, and if the storage receives the data, the controller transmitting a signal based on the received data to the second host, and transmitting the stored data to the second host.