A method, system, and computer program product for detecting and monitoring a signal is provided. The method includes detecting an alignment point for a periodic signal segment of a periodic signal generated by an apparatus being monitored for standard functionality In response, the apparatus is activated from a period prior to the alignment point to an end point of the periodic signal segment and a first point of the periodic signal segment is located. Likewise, a second point of an additional periodic signal segment of the periodic signal is located. The periodic signal is normalized based on results of locating the first point and the second point.

Disclosed are systems, methods, and computer-readable media for assuring tenant forwarding in a network environment. Network assurance can be determined in layer 1, layer 2 and layer 3 of the networked environment including, internal-internal (e.g., inter-fabric) forwarding and internal-external (e.g., outside the fabric) forwarding in the networked environment. The network assurance can be performed using logical configurations, software configurations and/or hardware configurations.

An on-chip debugging device and method is provided. The on-chip debugging device includes: an external interface module configured for outputting chip debugging state information to an external debugger and receiving a control instruction of the external debugger; a debugging mode control module configured for setting a to-be-sampled type of a specified chip internal signal and setting a debugging trigger condition according to the debugging configuration of the external debugger or the internal CPU; a debugging monitor module configured for sampling and recording the internal signal of the chip of the specified type so as to identify the running state of the chip; and a debugging information processing module configured for storing the running state of the chip in an internal debugging memory and sending it to the external debugger by the external interface module or sending it to the internal CPU via an internal bus. The on-chip debugging functions which are relatively simple, occupy less resources and have more powerful functions can be realized by the device and the method.

Described embodiments provide systems and methods for executing a plurality of validation tests to validate a plurality of microservices of one or more services. A device intermediary to a plurality of microservices of one or more services identifies a plurality of validation tests, each of the validation tests configured with a timeline, a target microservice and one of a synthetic error or a latency to implement to validate the target microservice. The device executes a first validation test of the plurality of validation tests to implement, over a first timeline, one of a first synthetic error or a first latency in responding to a first target microservice of the plurality of microservices. The device executes a second validation test of the plurality of validation tests to implement, over a second timeline, one of a second synthetic error or a second latency in responding to a second target microservice of the plurality of microservices. The device validates, responsive to executing each of the plurality of validation tests, the plurality of microservices of the one or more services.

An automotive control system includes a safety processor and a system-on-a-chip. The SoC includes a primary processor, a safety monitor, first and second GPIO banks, and a debug interface. The safety monitor is configured to detect a fault condition of the primary processor and to provide an indication of the fault condition to the safety processor. The first GPIO bank is coupled to the primary processor to provide input/output operations to a non-critical function of an automobile, while the second GPIO bank is coupled for a critical function of the automobile. The debug interface is coupled to the second GPIO bank to form a scan chain with input and output registers of the second GPIO bank, and is coupled to the safety processor to receive control information for the scan chain to provide input/output operations to the critical function of the automobile when the safety monitor provides the indication.

Automatic part testing includes: booting a part under testing into a first operating environment; executing, via the first operating environment, one or more test patterns on the part; performing a comparison between one or more observed characteristics associated with the one or more test patterns and one or more expected characteristics; and modifying one or more operational parameters of a central processing unit of the part based on the comparison.

A system for detecting a disruption in a communication system of a vehicle. The system includes a vehicle bus and an electronic processor. The electronic processor is configured to receive a message, from a vehicle bus. The message has a format and a plurality of signals. The electronic processor is configured to detect anomalies in a bus identifier, the message format, a time the message is received, and a signal parameter of a signal of the plurality of signals. The electronic processor is also configured to generate an error if an anomaly is detected in the message format, an anomaly is detected in the time the message is received, or an anomaly is detected in the signal parameter of the signal of the plurality of signals.

Disclosed are systems, methods, and computer-readable media for assuring tenant forwarding in a network environment. Network assurance can be determined in layer 1, layer 2 and layer 3 of the networked environment including, internal-internal (e.g., inter-fabric) forwarding and internal-external (e.g., outside the fabric) forwarding in the networked environment. The network assurance can be performed using logical configurations, software configurations and/or hardware configurations.

A Recovery Maturity Index 1 (RMM) is used to determine whether a particular Information Technology (IT) production environment is relatively mature enough to successfully execute the disaster recovery (DR). The RMI provides a quantitative analysis in terms of a set of categories for elements that characterize the environment and multiple elements for each category. At least some of the elements depend upon the extent to which automation components have been leveraged for disaster recovery. A summation of the scoring elements, which may be a weighted summation, results in an overall quantitative metric. The metric can used to determine whether or not disaster recovery can be expected to be successful.

The system verification program generation device 20 is equipped with a search unit 21 that searches a system design for execution entities and parameters of a verification program, which is a program that verifies whether the system design derived from system requirements satisfies one or more verification items extracted from the system requirements.