A memory device system includes: a first memory that has m lines of addresses and in which different pieces of data are respectively stored at the m lines of addresses, and a parity bit; a second memory that has m lines of addresses and in which same pieces of data as the pieces of data stored in the first memory are stored in an initial state; a first register that is connected with the first memory; a second register that is connected with the second memory; a comparator; a transfer register that stores the piece of data of the first memory; an error data register that stores the piece of data of the second register; an error address register that stores an address of the second memory; a parity calculation portion that calculates parity of all pieces of data; and a controller that performs a predetermined control.

A memory system includes a processing device (e.g., a controller implemented using a CPU, FPGA, and/or logic circuitry) and memory regions (e.g., in a flash memory or other non-volatile memory) storing data. The processing device receives an access request from a host system that is requesting to read the stored data. In one approach, the memory system is configured to: receive, from the host system over a bus, a read command to access data associated with an address in a non-volatile memory; in response to receiving the read command, access, by the processing device, multiple copies of data stored in at least one memory region of the non-volatile memory; match, by the processing device, data from the copies with each other; select, based on matching data from the copies with each other, first data from a first copy of the copies; and provide, to the host system over the bus, the first data as output data.

A semiconductor device includes first and second CPUs, first and second SPUs for controlling a snoop operation, a controller supporting ASIL D of a functional safety standard and a memory. The controller sets permission of the snoop operation to the first and second SPUs when a software lock-step is not performed. The controller sets prohibition of the snoop operation to the first and second SPUs when the software lock-step is performed. The first CPU executes a first software for the software lock-step, and writes an execution result in a first area for the memory. The second CPU executes a second software for the software lock-step, and writes an execution result in a second area of the memory. The execution result written in the first area is compared with the execution result written in the second area.

Embodiments of the present disclosure relate to a memory system, a memory controller, and a method of operating the memory system. According to the embodiments of the present disclosure, when result data obtained by derandomizing data included in a flag area is different from reference data after a random data unit is derandomized based on a seed, it is possible to detect an error occurring in the seed in a process of derandomizing the data and to prevent malfunction of firmware in advance by searching for a target seed and derandomizing the random data unit based on the target seed.

Embodiments of the present disclosure are directed to dynamic shadow operations configured to dynamically shadow data-plane resources in a network device. In some embodiments, the dynamic resource shadow operations are used to locally maintain a shadow copy of data plane resources to avoid having to read them through a bus interconnect. In other embodiments, the dynamic shadow framework is used to provide memory protection for hardware resources against SEU failures. The dynamic shadow framework may operate in conjunction with adaptive memory scrubbing operations. In other embodiments, the dynamic shadow infrastructure is used to facilitate fast boot-up and fast upgrade operations.

An apparatus for controlling an operation in a memory system includes a volatile memory including plural memory cells, a column data checking circuitry configured to determine whether all pieces of data outputted from memory cells corresponding to a bit line are identical to each other, and an error correction circuitry configured to determine whether the pieces of data include an error based at least on a type of data, a state of data, and an output of the column data checking circuitry, and to resolve the error.

A method for use in a computing system, comprising: storing, in a random-access memory, a working copy of a data item, the working copy of the data item being stored in the random-access memory by a first processor; registering, with a second processor, a respective address in the random-access memory where the working copy of the data item is stored; and correcting, by the second processor, any modifications to the working copy of the data item that are made after the working copy of the data item is stored in the random-access memory, the modifications being corrected in parallel with the first processor executing software based on the working copy of the data item.

Systems, methods, and circuitries are provided for checking integrity of code received from an external memory. In one example, a system includes a non-volatile memory and a controller. The non-volatile memory includes a first partition configured to store first data corresponding to program code and a second partition configured to store second data corresponding to a copy of the first data. The controller that includes a processor and comparator circuitry. The comparator circuitry is configured to receive a portion of the first data and a corresponding portion of the second data, compare the portion of the first data to the portion of the second data, when the portion of the first data matches the portion of the second data, provide the portion of the first data to the processor, and when the portion of the first data does not match the portion of the second data, generate an alarm signal.

A circuit and method for verifying the operation of error checking circuitry. In one example, a circuit includes a memory, a first error checking circuit, a second error checking circuit, and a comparison circuit. The memory includes a data output. The first error checking circuit includes an input and an output. The input of the first error checking circuit is coupled to the data output of the memory. The second error checking circuit includes an input and an output. The input of the second error checking circuit is coupled to the data output of the memory. The comparison circuit includes a first input and a second input. The first input is coupled to the output of the first error checking circuit. The second input is coupled to the output of the second error checking circuit.

A processor, including a core; and a cache-coherent memory fabric coupled to the core and having a primary cache agent (PCA) configured to provide a primary access path; and a secondary cache agent (SCA) configured to provide a secondary access path that is redundant to the primary access path, wherein the PCA has a coherency controller configured to maintain data in the secondary access path coherent with data in the main access path.