Systems and methods are provided for detecting and correcting address errors in a memory system. In the memory system, a memory device generates an error-detection code based on an address transmitted via an address bus and transmits the error-detection code to a memory controller. The memory controller transmits an error indication to the memory device in response to the error-detection code. The error indication causes the memory device to remove the received address and prevent a memory operation.

An integrated circuit (IC) chip can include a given core at a position in the IC chip that defines a given orientation, wherein the given core is designed to perform a particular function. The IC chip can include another core designed to perform the particular function. The other core can be flipped and rotated by 180 degrees relative to the given core such that the other core is asymmetrically oriented with respect to the given core. The IC chip can also include a compare unit configured to compare outputs of the given core and the other core to detect a fault in the IC chip.

The systems and methods described herein provide the ability to detect a clocking element fault within an IC device and switch to an alternate clock. In response to detection of a fault in a phase-lock-loop (PLL) clocking element, the device may switch to an alternate clock so that error reporting logic can make forward progress on generating error message. The error message may be generated within an Intellectual Property (IP) cores (e.g., IP blocks), and may send the error message from the IP core to a system-on-a-chip (SOC), such as through an SOC Functional Safety (FuSA) error reporting infrastructure. In various examples, the clocking error may also be output to a hardware SOC pin, such as to provide a redundant path for error indication.

In an example, a synchronization signal can be transmitted to a plurality of synchronizers. The plurality of synchronizers can include a plurality of upstream synchronizers and a downstream synchronizer. Each synchronizer of the plurality of upstream synchronizers can be caused to count from a respective count value until a predetermined end count sequence value in response to receiving the synchronization signal. The respective count value stored at each synchronizer can be representative of a difference in time between a respective upstream synchronizer of the plurality of upstream synchronizers receiving the synchronization signal and the downstream synchronizer receiving the synchronization signal. A respective processing element of a plurality of processing elements can be caused to start a respective function or operation in response to a respective upstream synchronizer reaching the predetermined end count sequence value.

A data processing apparatus (2) has scalar processing circuitry (32-42) and vector processing circuitry (38, 40, 42). When executing main scalar processing on the scalar processing circuitry (32-42), or main vector processing using a subset of said plurality of lanes on the vector processing circuitry (38, 40, 42), checker processing is executed using at least one lane of the plurality of lanes on the vector processing circuitry (38, 40, 42), the checker processing comprising operations corresponding to at least part of the main scalar/vector processing. Errors can then be detected based on a comparison of an outcome of the main processing and an outcome of the checker processing. This provides a technique for achieving functional safety in a high end processor with better performance and reduced hardware cost compared to a dual/triple core lockstep approach.

An embodiment method is disclosed for deriving an estimation value of a clock-error for a slave clock, wherein the slave clock is set at a nominal slave period and outputs a sequence of slave clock signals at an actual slave period, and wherein a difference between the actual slave period and the nominal slave period is approximated by the estimation value of the clock-error.

A synchronizing system including a generation unit for generating a synchronizing pulse from data of an independent clock, the synchronizing pulse being generated in a periodic manner, transmission links to transmit the synchronizing pulse to all the computation units, and in each of the computation units, a control element to compare the synchronizing pulse that has been received to a pulse generated by an internal clock of the computation unit and to detect a compliance or a lack of compliance, a scheduler of each of the computation units activating a sequence of partitions when the synchronizing pulse is received, and this only if the control element has detected a compliance. The synchronizing system is configured to synchronize the computation units in a reliable and accurate manner and to increase the operating safety of these computation units.

An integrated circuit has a transceiver circuit and a memory circuit. The transceiver circuit includes stage circuits that each perform at least one function specified by a data transmission protocol. The transceiver circuit is coupled to receive packets of timing test patterns. Each of the stage circuits in the transceiver circuit generates a timestamp in response to receiving each of the packets of timing test patterns. Each of the stage circuits in the transceiver circuit generates a trigger indicating receipt of a predefined reference point in each of the packets of timing test patterns. The memory circuit stores each of the timestamps generated by the stage circuits in response to a respective one of the triggers and outputs the timestamps for analysis.

Techniques are disclosed for processor synchronization within a reconfigurable computing environment for processor array redundancy. Processing elements are configured within a reconfigurable fabric to implement two or more redundant processors, where the two or more redundant processors are enabled for coincident operation. An agent is loaded on each of the two or more redundant processors, where the agent performs a function requiring data validation. The agent is fired on each of the two or more redundant processors to commence coincident operation. The coincident operation can include a lockstep operation. An output data result from each of the two or more redundant processors is compared to enable a data validation result. The data validation result is propagated. The propagating the data validation result can be based on comparing valid output data or can be based on comparing invalid output data.

A receiver device includes detection logic, an error counter, and an interrupt logic. The detection logic is to receive a first set of data frames and detect one or more frame errors in the first set of data frames. The error counter is to store a number of the one or more frame errors detected in the first set of data frames. The interrupt logic can be coupled to the error counter. The interrupt logic is to specify a period and compare the number of the one or more frame errors with a threshold number of frame errors during the period, where the interrupt logic is to indicate an interrupt responsive to the number of the one or more frame errors detected within the period satisfying the threshold number of frame errors.