Storage device programming methods, systems and media are described. A method may include encoding data to generate an encoded set of data. A first programming operation may write the encoded set of data to a memory device. The method includes encoding, using a second encoding operation based on the data, to generate a second set of encoded data. The second set of encoded data is stored to a cache. A first decoding operation is performed, based on the second set of encoded data and the encoded set of data, to generate a decoded set of data. A second decoding operation is performed to generate a second decoded set of data. The second decoded set of data is encoded to generate a third set of encoded data. The method includes performing a second programming operation to write the third set of encoded data to the memory device.

A controller includes an internal memory to store an address and a memory control unit operatively coupled with the internal memory. The memory control unit includes logic to identify a malfunctioning address of primary data storage elements within an external memory device, the external memory device being another semiconductor device separate from the controller, store the malfunctioning address in the internal memory, and transmit, to the external memory device, a command to initiate a repair of the malfunctioning address using redundant data storage elements and an indication of an address associated with the malfunctioning address.

Embodiments of the disclosure are drawn to apparatuses and methods for storing an enable state of an address. The address may be broadcast from a fuse array to a fuse latch, and may be associated with enable information. The fuse latch may include a plurality of enable latch circuits, each of which may receive the enable information in common, and each of which may store the enable information as an enable bit. Each of the enable latch circuits may provide a respective enable signal based on a state of the stored enable bit. An enable logic circuit may provide an overall enable signal with a state determined by the states of all of the enable signals from the plurality of enable latch circuits.

Storage device programming methods, systems and media are described. A method may include encoding data to generate an encoded set of data. A first programming operation may write the encoded set of data to a memory device. The method includes encoding, using a second encoding operation based on the data, to generate a second set of encoded data. The second set of encoded data is stored to a cache. A first decoding operation is performed, based on the second set of encoded data and the encoded set of data, to generate a decoded set of data. A second decoding operation is performed to generate a second decoded set of data. The second decoded set of data is encoded to generate a third set of encoded data. The method includes performing a second programming operation to write the third set of encoded data to the memory device.

A controller includes an internal memory to store an address and a memory control unit operatively coupled with the internal memory. The memory control unit includes logic to identify a malfunctioning address of primary data storage elements within an external memory device, the external memory device being another semiconductor device separate from the controller, store the malfunctioning address in the internal memory, and transmit, to the external memory device, a command to initiate a repair of the malfunctioning address using redundant data storage elements and an indication of an address associated with the malfunctioning address.

Embodiments of the disclosure are drawn to apparatuses and methods for storing an enable state of an address. The address may be broadcast from a fuse array to a fuse latch, and may be associated with enable information. The fuse latch may include a plurality of enable latch circuits, each of which may receive the enable information in common, and each of which may store the enable information as an enable bit. Each of the enable latch circuits may provide a respective enable signal based on a state of the stored enable bit. An enable logic circuit may provide an overall enable signal with a state determined by the states of all of the enable signals from the plurality of enable latch circuits.

Storage device programming methods, systems and media are described. A method may include encoding data to generate an encoded set of data. A first programming operation may write the encoded set of data to a memory device. The method includes encoding, using a second encoding operation based on the data, to generate a second set of encoded data. The second set of encoded data is stored to a cache. A first decoding operation is performed, based on the second set of encoded data and the encoded set of data, to generate a decoded set of data. A second decoding operation is performed to generate a second decoded set of data. The second decoded set of data is encoded to generate a third set of encoded data. The method includes performing a second programming operation to write the third set of encoded data to the memory device.

A semiconductor device includes a cell array having an upper segment and a lower segment which are classified according to refresh units. The semiconductor device includes a first repair controller configured to output a first repair signal for controlling a repair operation of the upper segment based on a fuse address, a row address, a second control signal, and selection address being at a first level, and generate a first control signal for controlling a repair operation of the lower segment based on the fuse address, the row address, and selection address.

In an example, a method of memory repair may include receiving, by a memory repair unit, a plurality of memory identifiers. The method may include determining, by the memory repair unit, that a first memory identifier of the plurality of memory identifiers corresponds to a first memory of a plurality of memories. The method may include determining, by the memory repair unit, that a second memory identifier corresponds to a second memory of the plurality of memories. The method may include outputting, by the memory repair unit, in parallel: a first value to a repair enable input of the first memory, and a second value to a repair enable input of the second memory.

Various implementations described herein refer to a device having an encoder coupled to memory. The ECC encoder receives input data from memory built-in self-test circuitry, generates encoded data by encoding the input data and by adding check bits to the input data, and writes the encoded data to memory. The device may have an ECC decoder coupled to memory. The ECC decoder reads the encoded data from memory, generates corrected data by decoding the encoded data and by extracting the check bits from the encoded data, and provides the corrected data and double-bit error flag as output. The ECC decoder has error correction logic that performs error correction on the decoded data based on the check bits, wherein if the error correction logic detects a multi-bit error in the decoded data, the error correction logic corrects the multi-bit error in the decoded data to provide the corrected data.