In some examples, a method for converged system compliance checking can include identifying a converged system compliance checking field for hardware in a converged system. The compliance checking field can, for example, be based on the purpose of the hardware. The method can further include identifying baseline compliance data for the compliance checking field, identifying actual compliance data for the compliance checking field by testing the hardware, comparing the actual compliance data to the baseline compliance data, and determining whether the hardware is in compliance with the converged system based on the comparison between the actual compliance data and the baseline compliance data.

Aspects include detecting, by an agent of a remote debugging tool that a first controller currently associated with the agent for a debugging session has not responded to a status inquiry from the agent. The first controller interacts with an end user, sends requests to the agent to operate a target program, and processes responses from the agent. Based on detecting that the first controller has not responded to the status inquiry from the agent, the agent identifies a second controller, associates the second controller with the agent for the debugging session, and resumes the debugging session with the second controller in place of the first controller. The associating includes synchronizing a debugging session state between the second controller and the agent. The target program continues to execute during the identifying, associating, and resuming, and the debugging session state is not changed by the identifying, associating, and resuming.

A method of monitoring operations of a set of ICs. The method loads a first set of configuration data into a first IC for configuring a group of configurable circuits of the first IC to perform operations of a user design. The method receives a definition of an event based on values of a set of signals in the user design and a set of corresponding actions to take when the event occurs. The set of signals includes at least one signal received from a second IC. The method generates an incremental second set of configuration data based on the definition of the event and the set of corresponding actions. While the first IC is performing the operations of the user design, the method loads the incremental second set of configuration data into the first IC and monitors the signals received from the second IC at the first IC.

Disclosed are various embodiments of a computing device for validating the configuration of components of a component assembly. The computing device serves a boot image executable by a component of the component assembly. Expected configuration data associated with the component is identified by the computing device, and actual configuration data associated with the component is obtained by the computing device. The computing device determines a validation response for the component assembly based at least in part upon a comparison of the expected configuration data and the actual configuration data.

Embodiments of the present invention provide a method for checking whether hardware of an intelligent terminal runs abnormally. The method includes: checking, by an intelligent terminal at a service layer, whether load of an intelligent terminal system exceeds a preconfigured maximum threshold; if the intelligent terminal detects that the load of the intelligent terminal system does not exceed the maximum threshold, triggering, by the intelligent terminal at the service layer, execution of determining whether hardware runs abnormally; determining, by the intelligent terminal, whether the hardware runs abnormally; determining, by the intelligent terminal, target hardware that runs abnormally; and acquiring, by the intelligent terminal, exception information of the target hardware, and notifying a user that the target hardware runs abnormally. This avoids increasing load of the intelligent terminal system and thereby ensures that the intelligent terminal runs normally.

In an approach for testing the operations of a host system during a host system migration, a terminal agent exchanges messages already exchanged between the current host system and a terminal with the new host system. A manual operation replay unit replays messages generated by manual operations among the messages sent to the current host system by the terminal. An automatic response unit automatically generates a response message for messages received from the new host system. The automatic response unit also generates screen data for a screen displayed on the terminal on the basis of messages received from the new host system. A comparison unit compares and evaluates screen data generated by the automatic response unit and screen data from a screen generated by the terminal on the basis of messages received from the current host system.

In an approach for testing the operations of a host system during a host system migration, a terminal agent exchanges messages already exchanged between the current host system and a terminal with the new host system. A manual operation replay unit replays messages generated by manual operations among the messages sent to the current host system by the terminal. An automatic response unit automatically generates a response message for messages received from the new host system. The automatic response unit also generates screen data for a screen displayed on the terminal on the basis of messages received from the new host system. A comparison unit compares and evaluates screen data generated by the automatic response unit and screen data from a screen generated by the terminal on the basis of messages received from the current host system.

A semiconductor system may include a first semiconductor device and a second semiconductor device. The first semiconductor device may be configured to output commands and addresses. The first semiconductor device may be configured to output a strobe signal toggled and data after an initialization operation. The second semiconductor device may be configured to start the initialization operation if the commands have a first combination and stores internal data having a predetermined level during a set period of the initialization operation if the commands have a second combination.

In one embodiment, a semiconductor test control system includes a computer system having a plurality of hardware resources; a hypervisor installed on the computer system; and a test floor controller installed on the computer system. The hypervisor virtualizes the hardware resources and provides each of at least one virtual appliance with access to a respective virtual set of hardware resources. Each virtual set of hardware resources places its respective virtual appliance in controlling communication with at least a first aspect of a semiconductor test system, thereby enabling the respective virtual appliance to test a respective type of semiconductor device. The test floor controller is in controlling communication with i) at least a second aspect of the semiconductor test system, and ii) each of the at least one virtual appliance.

The subject matter described herein relates to methods, systems, and computer readable media for emulating network devices with different clocks. One method includes steps occurring in a network equipment test device. The steps include generating or obtaining timing information. The steps further include obtaining clock modification information. The steps further include emulating a plurality of different clocks using the timing information and the clock modification information. The method further includes emulating at least one network device that transmits test packets to a device under test using the different clocks.