A CPU box of each mounting machine module obtains MAC addresses of communication devices of both an internal device and a base by communicating with the communication devices of both the internal device and the base after the power is turned on, compares the obtained MAC address of the internal device side and the obtained MAC address of the base side, with storage data of the MAC addresses of both the internal device side and the base side read from a non-volatile storage medium of the CPU box, obtains management data of the mounting machine module stored in association with the MAC address of the internal device side from the non-volatile storage medium of a management computer in a case where the MAC address of the internal device side does not match the storage data, and obtains the management data of the mounting machine module stored in association with the MAC address of the base side from the non-volatile storage medium of the management computer in a case where the MAC address of the base side does not match the storage data.

Example implementations relate to chipset reconfiguration based on device detection. For example, a method includes detecting, by a computing system, that a storage device is connected to an input/output (I/O) interface of the computing system, and reconfiguring a chipset of the computing system based on the detected storage device. The method also includes performing a power cycle on chipset standby power to trigger a chipset configuration reload.

Disclosed herein is a method including receiving, from a user application, data to be transmitted from a source address to a destination address using a single connection through a network; and splitting the data into a plurality of packets according to a communication protocol. For each packet of the plurality of packets, a respective flowlet for the packet to be transmitted in is determined from a plurality of flowlets. Assignment of the flowlets to the packets can be dynamically adjusted based on utilization of the flowlets.

Configuring an embedded device of a first type by means of a host device. The embedded device comprises a computing unit to provide configurable functionality according to input configuration items. The host device comprises an operating system to provide a means for communication with a number of predetermined types of embedded devices. The method includes coupling, via a coupling unit, the embedded device with the host device, including identifying the embedded device to the host device as a second type of device different from the first type or that operates in a different manner from the first type and is comprised of the predetermined types of embedded devices. The method includes presenting or offering a means for entering, retrieving, and supplying configuration items to the embedded device and receiving the configuration items by the computing unit, and performing configuration of the embedded device according to the received configuration items.

A system and method for processing a multiple data controller workflow fully honors data subject opt-outs but nevertheless takes advantage of the synergy of the combined data from multiple controllers to improve the effectiveness of messaging. A data services provider performs data resolution processing against the data from each data controller. Using the results of the resolution processing, opt-out lists that are in different formats and that may track different sorts of data may all be used for the joint campaign. Metadata is added to the data so that the source data controller is tracked through the processing. The data is then combined, resulting in a master opt-out list. If a data subject has opted out with respect to any controller, then the opt-out is applied to the joint campaign.

Techniques for implementing rollback of infrastructure changes in an infrastructure orchestration service are described. In certain examples, an infrastructure orchestration service is disclosed that manages both provisioning and deploying of infrastructure assets within a cloud environment. The service receives a plan comprising a set of instructions associated with a set of infrastructure assets of an execution target and identifies a first state of the set of infrastructure assets. The service executes the set of instructions in the plan to achieve a second state for the set of infrastructure assets. Based in part on the executing, the service receives a trigger for rolling back the plan to restore the set of infrastructure assets in the plan to the first state and executes a rollback plan for the plan. The service then transmits a result associated with the execution of the rollback plan.

A host system includes a device driver with application-specific settings for a hosted application. Input data is generated by one or more tablet devices at a client computer system. A host-side data transfer application receives the input data and forwards it to the host-side driver, which sends the input data to the hosted application. The tablet data sent to the hosted application is configured according to application-specific settings of the host-side driver, which may support multiple application programming interfaces. A dedicated driver-to-driver connection may also be used to transmit data between client-side and host-side drivers. In another aspect, a host sends an identifier of a hosted application currently in use to a client-side driver, which uses that identifier to look up and apply application-specific settings to tablet data sent to the hosted application. This can eliminate the need for a host-side driver while still allowing application-specific settings for hosted applications.

Various systems and methods for configuring a pluggable computing device are described herein. A pluggable computing device may be configured to be compatible with a pluggable host system using a default communication channel to obtain configuration settings and configure a programmable logic device on the pluggable computing device. The pluggable computing device may perform chain of trust processing on the pluggable host system. The pluggable computing device may be disposed on a compute card, which may include a heat sink in a particular configuration.

Systems, apparatuses, and methods are described herein for a communication bus that virtualizes physiological data. Sensors and/or physiological data acquisition devices have different physical connectors which provide physiological data from a patient to a shared interface such as a display or patient monitor. A transfer interface within a mount can receive and interpret data streams associated with one or more physiological data acquisition devices. The transfer interface can prioritize the various data streams associated with the one or more physiological data acquisition devices and generate a single, combined data stream based on the assigned prioritization. The transfer interface can provide the combined data stream for transmission to a patient monitor via an interchangeable transport medium. Another transfer interface can process and/or virtualize the data streams from the physiological data acquisition devices.

A print control apparatus for controlling a printing apparatus, comprises a display control unit configured to display, on a display unit, a setting content associated with setting processing of a default printing apparatus that can be used without accepting a selection operation by a user, an acquisition unit configured to acquire information about a function of setting, as the default printing apparatus, a printing apparatus instructed to execute printing, and a restriction unit configured to restrict, if the acquired information indicates enabling of the function, display processing of the setting content so the setting content is not operated.