A receiving circuit of a communications link comprises: a first data buffer configured to input, under control of a first clock signal, data of a first data stream transmitted by a transmitting circuit, and to generate a credit trigger signal indicating when a data value is read from the first data buffer, wherein data is read from the first data buffer, or from a further data buffer coupled to the output of the first data buffer, under control of a second clock signal; and a credit generation circuit configured to generate, based on the credit trigger signal, a credit signal for transmission to the transmitting circuit under control of the first clock signal, the credit signal indicating that one or more further data values of the first data stream can be transmitted by the transmitting circuit.

Writing data to storage utilizing a diverged thread for asynchronous write operations is provided. On a first thread, an analysis engine analyzes and identifies changed information to write to storage and an I/O manager copies the writes into buffers and places the buffers into a queue, while on a second thread, a flushless transactional layer (FTL) drive executes the writes to storage. By allowing the analysis to continue and enqueue writes on a first thread while the writes are written to storage on a second thread, the CPU and I/O of the system are utilized in parallel. Accordingly, efficiency of the computing device is improved.

A first data item is programmed to a first set of logical units of a memory sub-system. The first set of logical units is associated with a first fault tolerant stripe. A second data item is programmed to a second set of logical units of a memory sub-system. The second set of logical units is associated with a second fault tolerant stripe. A first set of redundancy metadata corresponding to the first data item and a second set of redundancy metadata corresponding to the second data item is generated. A combined set of redundancy metadata is generated based on at least the first set of redundancy metadata and the second set of redundancy metadata. The combined set of redundancy metadata is stored at a specified memory device of the memory sub-system.

A solid state drive (SSD) device includes a first nonvolatile memory package, a second nonvolatile memory package, and a controller. The first nonvolatile memory package includes a first buffer chip and a plurality of first nonvolatile memory chips. The second nonvolatile memory package includes a plurality of second nonvolatile memory chips. The controller controls the first nonvolatile memory package and the second nonvolatile memory package. The first buffer chip communicates a first address signal and a first data with the controller, and selectively communicates the first data with one of the plurality of first nonvolatile memory chips and the plurality of second nonvolatile memory chips based on the first address signal.

In various examples, device comprises a memory and a memory controller. The memory controller comprises a write tracking buffer. The memory controller to: receive a write request bound for the memory, store an entry associated with the write request in the write tracking buffer, and determine an access pattern of the memory. The access pattern indicates a high or a low write bandwidth of the memory. The memory controller to execute the write request bound for the memory based on the determined memory access pattern, complete execution of the write request, and responsive to completing execution of the write request, free the entry associated with the write request from the write tracking buffer.

A memory system includes dynamic random-access memory (DRAM) components that include interconnected and redundant component data interfaces. The redundant interfaces facilitate memory interconnect topologies that accommodate considerably more DRAM components per memory channel than do traditional memory systems, and thus offer considerably more memory capacity per channel, without concomitant reductions in signaling speeds. The memory components can be configured to route data around defective data connections to maintain full capacity and continue to support memory transactions.

System and methods are disclosed including a plurality of memory devices and a processing device, operatively coupled with the plurality of memory devices, to perform operations comprising: receiving, from a host system, encrypted write data appended with error-checking data; determining whether the encrypted write data contains an error based on the error-checking data; and responsive to determining that the encrypted write data contains an error, notifying the host system that the encrypted write data contains an error.

A data backup method of a storage device which includes a storage controller, a buffer memory, and a plurality of nonvolatile memory devices, the method including: detecting a power-off event of an external power provided to the storage device; deactivating a host interface of the storage controller in response to the detection of the power-off event: moving data stored in the buffer memory to a static random access memory (SRAM) in the storage controller; blocking or deactivating a power of the buffer memory; setting an interleaving mode of the plurality of nonvolatile memory devices to a minimum power mode; and programming the data moved to the SRAM to at least one of the plurality of nonvolatile memory devices.

A memory system includes a controller, a buffer, and a nonvolatile memory including a plurality of blocks, wherein each of the blocks includes a plurality of pages and each of the pages includes a plurality of unit data portions. The controller is configured to carry out garbage collection by reading data from one or more pages of a target block of the garbage collection and selectively copying valid unit data portions included in the read data to another block, count a number of invalid unit data portions included in the read data, and accept, in the buffer, unit data portions from a host as write data, up to a number determined based on the counted number, during the garbage collection.

A memory sub-system configured to schedule the transfer of data from a host system for write commands to reduce the amount and time of data being buffered in the memory sub-system. For example, after receiving a plurality of streams of write commands from a host system, the memory sub-system identifies a plurality of media units in the memory sub-system for concurrent execution of a plurality of write commands respectively. In response to the plurality of commands being identified for concurrent execution in the plurality of media units respectively, the memory sub-system initiates communication of the data of the write commands from the host system to a local buffer memory of the memory sub-system. The memory sub-system has capacity to buffer write commands in a queue, for possible out of order execution, but limited capacity for buffering only the data of a portion of the write commands that are about to be executed.