A host controller interface configured to provide interfacing between a host device and a storage device includes processing circuitry; a doorbell register configured to store a head pointer and a tail pointer of one or more first queues; and an entry buffer configured to store a first command from one of the one or more first queues in the entry buffer, wherein the processing circuitry is configured to, determine an order in which the commands of the one or more first queues are to be processed, route the first command to be stored in the entry buffer according to the determined order, and route a first response to be stored in one of one or more second queues.

Example approaches for processing task deployment in adapter devices and accelerators, are described. In an example, a service request is received by an adapter device. The service request is indicative of a service associated with a virtual multi-layer network switch. An accelerator may be integrated to the adapter device or coupled to the adapter device. A set of processing tasks associated with the service is identified based on the service request. A processing task instance corresponding to at least one of the set of processing tasks is deployed in one of the adapter device and the accelerator, based on predefined configuration information. The predefined configuration information includes policies for executing each of the set processing tasks in one of the adapter device and the accelerator.

A storage system controller chip includes routing circuitry comprising a host interface for coupling to a host device and an extension interface for coupling to a secondary controller chip. A host controller is coupled to a logical interface of the routing circuitry for receiving a host data access command from the host device via the host interface and logical interface. The routing circuitry transfers the host data access command to the secondary controller chip via the extension interface. The storage system controller chip further includes processor circuitry coupled to the logical interface of the routing circuitry. The processor circuitry receives an indication from the secondary controller chip via the extension interface that execution of the host data access command has been completed by the secondary controller chip and instructs the host controller to notify the host device that execution of the host data access command has been completed.

A method of provisioning a system includes defining one or more virtual peripherals such that each of the virtual peripherals corresponds to a respective device; identifying one or more enabled virtual peripherals; and identifying one or more control modules. Each of the control modules includes one or more terminals for connecting to one or more devices. The method further includes linking each of the enabled virtual peripherals to a respective terminal of the one or more control modules to form a link; generating a provisioning configuration that represents the link between the respective terminal and the corresponding one of the enabled virtual peripherals; and writing the provisioning configuration to each of the control modules. The method further includes connecting the respective device to the respective terminal consistent with the link between the respective terminal and the corresponding one of the enabled virtual peripherals.

There is provided a communication apparatus comprising a connector that includes a plurality of signal lines and connects to an external recording device. The control unit performs control to determine whether a second signal has been input before a predetermined time period elapses since a first signal was output to the external recording device, the second signal indicating that the external recording device is compatible with a second transfer mode. In a case where it is determined that the second signal has been input, the control unit performs control to perform communication in the second transfer mode.

A circuitry includes a multi-mode switching multiplexer, a control circuit and a receiver. The multi-mode switching multiplexer is arranged to receive multiple mode settings, and select one of the multiple mode settings as an output mode setting. The control circuit is arranged to generate a mode switching signal to control the multi-mode switching multiplexer. The receiver is arranged to set its internal components according to the output mode setting.

A device for online gaming includes an actuation component and a controller communicatively coupled to a computer system. The controller is configured to perform operations including detecting an actuation of the actuation component, wherein the actuation component is associated with performing of an action in a video game executed by the computer system. Responsive to detecting the actuation, an instruction is provided to the computer system to perform the action, wherein, based on a current value of a timer, the computer system restricts the action from being performed. The timer, having been previously initiated based on a prior actuation of the actuation component, relates to a cooldown period during which the action cannot be repeated after the action is performed. Responsive to receiving a command from the computer system, a tactile effect is generated as an indication to a user that the action can be repeated.

Techniques for providing adaptive virtual function (VF) drivers capable of operating with physical devices having a plurality of different hardware configurations are described. In one embodiment, for example, an apparatus may include logic to implement a virtual machine (VM), the logic to initialize an adaptive virtual function (VF) driver to facilitate communication between the VM and a physical device to be virtualized, establish communication between the adaptive VF driver and a physical function (PF) driver of the hypervisor for the physical device, activate a standard feature set for the adaptive VF driver to execute on a PF of the physical device, and negotiate activation of an advanced feature set for the adaptive VF driver to execute on the PF, the adaptive VF driver to provide the advanced feature set to the PF, the PF activate each feature of the advanced feature set supported by the PF.

A host can include a programmable network interface card (NIC) or “Smart NIC” which accesses host-local drives hidden from a host processor. One configuration can include a switch with a one logical partition including the NIC as a root complex (RC) and the local drives as end points (EPs), and with another logical partition including the host processor as an RC and the NIC as an EP. A second configuration can include the NIC and switch directly connected to the host processor with an access control component (ACC) configured on switch ports connected to the local drives. A third configuration can include the NIC and local drives directly connected to the host processor with the ACC configured on host processor ports connected to the local drives. The NIC can use a multi-layer driver to communicate with the ACC and local drives hidden behind the ACC.

In one implementation, an adapter device includes a processor and a storage medium including instructions. The instructions are executable by the processor to: deploy a composer container in the adapter device, wherein the adapter device is coupled to a host device; receive, by the composer container, a plurality of adapter service requests from the host device; and in response to the plurality of service requests, deploy, by the composer container, a plurality of service containers in the adapter device, wherein each service container is to provide a particular adapter service to the host device, and wherein each service container is allocated a subset of the plurality of computing resources of the adapter device.