An integrated circuit includes an intellectual property core, scan data pipeline circuitry configured to convey scan data to the intellectual property core, and scan control pipeline circuitry configured to convey one or more scan control signals to the intellectual property core. The integrated circuit also includes a wave shaping circuit configured to detect a trigger event on the one or more scan control signals and, in response to detecting the trigger event, suppress a scan clock to the intellectual property core for a selected number of clock cycles.

In one embodiment, an apparatus includes at least one fabric to interface with a plurality of intellectual property (IP) blocks of the apparatus, the at least one fabric including at least one status storage, and a fabric bridge controller coupled to the at least one fabric. The fabric bridge controller may be configured to initiate a functional safety test of the at least one fabric in response to a fabric test signal received during functional operation of the apparatus, receive a result of the functional safety test via the at least one status storage, and send to a destination location a test report based on the result. Other embodiments are described and claimed.

In one embodiment, an apparatus includes at least one fabric to interface with a plurality of intellectual property (IP) blocks of the apparatus, the at least one fabric including at least one status storage, and a fabric bridge controller coupled to the at least one fabric. The fabric bridge controller may be configured to initiate a functional safety test of the at least one fabric in response to a fabric test signal received during functional operation of the apparatus, receive a result of the functional safety test via the at least one status storage, and send to a destination location a test report based on the result. Other embodiments are described and claimed.

A method for operating a control unit of a motor vehicle. A status inquiry is transmitted by a watchdog unit to a first monitoring unit, which is implemented on a first processor core of a multicore processor. A status response is ascertained by the first monitoring unit as a function of the status inquiry. A fault is ascertained by the watchdog unit as a function of the status response.

Manufacturers perform tests on chips before the chips are shipped to customers. However, defects can occur on a chip after the manufacturer testing and when the chips are used in a system or device. The defects can occur due to aging or the environment in which the chip is employed and can be critical; especially when the chips are used in systems such as autonomous vehicles. To verify the structural integrity of the IC during the lifetime of the product, an in-system test (IST) is disclosed. The IST enables self-testing mechanisms for an IC in working systems. The IST mechanisms provide structural testing of the ICs when in a functional system and at a manufacturer's level of testing. Unlike ATE tests that are running on a separate environment, the IST provides the ability to go from a functional world view to a test mode.

Manufacturers perform tests on chips before the chips are shipped to customers. However, defects can occur on a chip after the manufacturer testing and when the chips are used in a system or device. The defects can occur due to aging or the environment in which the chip is employed and can be critical; especially when the chips are used in systems such as autonomous vehicles. To verify the structural integrity of the IC during the lifetime of the product, an in-system test (IST) is disclosed. The IST enables self-testing mechanisms for an IC in working systems. The IST mechanisms provide structural testing of the ICs when in a functional system and at a manufacturer's level of testing. Unlike ATE tests that are running on a separate environment, the IST provides the ability to go from a functional world view to a test mode.

Voltage adjustment techniques for computing systems and processing devices are presented herein. In one example, a method of determining operating voltages for a processing device includes executing a voltage adjustment process to determine at least one input voltage for the processing device lower than a manufacturer specified operating voltage. During the voltage adjustment process, the method includes applying incrementally adjusted input voltages to the processing device, operating the processing device according to a functional test that exercises the processing device in context with associated system elements of a computing assembly, and monitoring for operational failures of at least the processing device during application of each of the incrementally adjusted input voltages. Responsive to the operational failures, the method includes determining corresponding values of the incrementally adjusted input voltages and establishing an input voltage based at least in part on the corresponding values of the incrementally adjusted input voltages.

Disclosed are systems and methods for providing in-service testing using a redundant segment. A device (e.g., memory, filter, GPU) is implemented as multiple device segments. For example, a filter including 1024 taps may be implemented as sixteen smaller filter segments that include 64 taps each. A redundant segment that is of similar size to the device segments is used to provide in-service testing of the individual device segments. For example, the redundant segment is provided the same input as a device segment and the output of the redundant segment and the device segment are compared to determine whether the device segment is operating correctly. Multiplexers are used to cycle use of the redundant segment to provide in-service testing of each of the device segments. For example, the multiplexers can be configured into different modes to provide for testing of the various device segments.

Disclosed are systems and methods for providing in-service testing using a redundant segment. A device (e.g., memory, filter, GPU) is implemented as multiple device segments. For example, a filter including 1024 taps may be implemented as sixteen smaller filter segments that include 64 taps each. A redundant segment that is of similar size to the device segments is used to provide in-service testing of the individual device segments. For example, the redundant segment is provided the same input as a device segment and the output of the redundant segment and the device segment are compared to determine whether the device segment is operating correctly. Multiplexers are used to cycle use of the redundant segment to provide in-service testing of each of the device segments. For example, the multiplexers can be configured into different modes to provide for testing of the various device segments.

This invention is a streaming engine employed in a digital signal processor. A fixed data stream sequence is specified by a control register. The streaming engine fetches stream data ahead of use by a central processing unit and stores it in a stream buffer. Upon occurrence of a fault reading data from memory, the streaming engine identifies the data element triggering the fault preferably storing this address in a fault address register. The streaming engine defers signaling the fault to the central processing unit until this data element is used as an operand. If the data element is never used by the central processing unit, the streaming engine never signals the fault. The streaming engine preferably stores data identifying the fault in a fault source register. The fault address register and the fault source register are preferably extended control registers accessible only via a debugger.