Presented embodiments facilitate efficient and effective flexible implementation of different types of testing procedures in a test system. In one embodiment, a test system comprises pre-qualifying test components, functional test components, a controller, a transceiver, and a switch. The pre-qualifying test components are configured to perform pre-qualifying testing on a device under test. The functional test components are configured to perform functional testing on the device under test. The controller is configured to direct selection between the pre-qualifying testing and functional testing. The transceiver is configured to transmit and receive signals to/from the device under test. The switch is configured to selectively couple the transceiver to the pre-qualifying test components and functional test components.

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 device maintenance apparatus includes a setting operator configured to allow for setting a test pattern, the test pattern being set to define a change of output signals output from a device over time, and an execution operator configured to make the device output the output signals based on the set test pattern.

Apparatus and a method for processor core self-testing are disclosed. The apparatus comprises processor core circuitry to perform data processing operations by executing data processing instructions. Separate self-test control circuitry causes the processor core circuitry to temporarily switch from a first state of executing the data processing instructions to a second state of executing a self-test sequence of instructions, before returning to the first state of executing the data processing instructions without a reboot of the processor core circuitry being required. There is also self-test support circuitry, wherein the processor core circuitry is responsive to the self-test sequence of instructions to cause an export of at least one self-test data item via the self-test support circuitry to the self-test control circuitry.

Apparatus and a method for processor core self-testing are disclosed. The apparatus comprises processor core circuitry to perform data processing operations by executing data processing instructions. Separate self-test control circuitry causes the processor core circuitry to temporarily switch from a first state of executing the data processing instructions to a second state of executing a self-test sequence of instructions, before returning to the first state of executing the data processing instructions without a reboot of the processor core circuitry being required. There is also self-test support circuitry, wherein the processor core circuitry is responsive to the self-test sequence of instructions to cause an export of at least one self-test data item via the self-test support circuitry to the self-test control circuitry.

A system on chip (SoC) for testing a component in a system during runtime includes a plurality of functional components; a system bus for allowing the plurality of functional components to communicate with each other; one or more wrappers, each connected to one of the plurality of functional components; and an in-system component tester (ICT). The ICT monitors, via the wrappers, states of the functional components; selects, as a component under test (CUT), at least one functional component in an idle state; tests, via the wrappers, the selected at least one functional component; interrupts the testing step with respect to the selected at least one functional component, based on a detection of a collision with an access from the system bus to the selected at least one functional component; and allows a connection of the at least one functional component to the system bus, based on the interrupting step.

A system on chip (SoC) for testing a component in a system during runtime includes a plurality of functional components; a system bus for allowing the plurality of functional components to communicate with each other; one or more wrappers, each connected to one of the plurality of functional components; and an in-system component tester (ICT). The ICT monitors, via the wrappers, states of the functional components; selects, as a component under test (CUT), at least one functional component in an idle state; tests, via the wrappers, the selected at least one functional component; interrupts the testing step with respect to the selected at least one functional component, based on a detection of a collision with an access from the system bus to the selected at least one functional component; and allows a connection of the at least one functional component to the system bus, based on the interrupting step.

An apparatus and method are described for a scalable testing agent. For example, one embodiment of a scalable test engine comprises: an input interface to receive commands and/or data from a processor core or an external test system, the commands and/or data to specify one or more test operations to be performed on one or more intellectual property (IP) blocks of a chip; a first circuit to establish communication with an IP block over an interconnect fabric, the first circuit to transmit the one or more test operations to the IP block responsive to the received commands and/or data, the IP block to process the test operations and generate results; and a second circuit to receive the results from the IP block over the interconnect fabric, the results to be provided from the second circuit to the processor core and/or the external test system for analysis.

A test system, for example for set top boxes or game consoles, includes logic to reformat media signals output by a device under test, logic to receive the reformatted media signals and to analyze them for errors, and a pluggable interface coupling the device under test to the logic to reformat the media signals.

A test system, for example for set top boxes or game consoles, includes logic to reformat media signals output by a device under test, logic to receive the reformatted media signals and to analyze them for errors, and a pluggable interface coupling the device under test to the logic to reformat the media signals.