A memory module comprises a volatile memory subsystem including DRAM, a non-volatile memory subsystem including Flash memory, and a module control device. The Flash memory includes main Flash providing a main Flash memory space and scratch Flash providing a scratch Flash memory space. The module control device is configured to receive a request from the memory controller to move one or more segments of data in a first Flash block in the main Flash to the DRAM and to, for each respective segment of data: select a respective set of pages in the DRAM; transfer respective data stored in the respective set of pages from the DRAM to a corresponding segment in the scratch Flash; and transfer the respective segment of data to the respective set of pages in the DRAM. Thus, data can be moved segment by segment between the DRAM and the Flash memory.

A memory card is attached to a host device, and includes a data control circuit which transfers data with respect to the host device in synchronism with a rise edge and a fall edge of a clock signal.

A storage controller that improves performance of a storage device by reducing the number of data I/O operations. The storage controller, as part of a storage device and a storage system, and in a method of operating the storage controller, includes a host interface receiving data requested for storage from a host and lifetime information indicating a change period of the data, and a data placement manager determining a storage position of the data in a flash memory based on the lifetime information of the data.

The subject system and method are generally directed to ensuring reliable high speed data transfer in multiple data rate nonvolatile memory, such as double data rate (DDR) nonvolatile NAND flash memory and the like. The system and method provide measures to achieve read and write training for data signals (DQ) and the data strobe signal (DQS), one relative to the other. In such manner, high speed data transfers to and from nonvolatile memory such as flash devices may be performed with a reduced risk of data loss even at high operational frequencies.

A portion of a reprogrammable storage device is used to implement permanent data storage. The storage device includes a plurality of electrically erasable memory elements and a controller. The plurality of electrically erasable memory elements are configured to store data. Each memory element is programmable a number of write cycles before reaching a write failure state. The controller is coupled to the plurality of memory elements. The controller includes a receiver and a write engine. The receiver receives an instruction to drive a selected memory element to the write failure state. The write engine repeatedly writes a data value, in a plurality of write operations, to the selected memory element until the write failure state of the selected memory element is established.

The present disclosure relates to methods and systems for performing operations in a communications protocol. An example method can include submitting, from a device, a request for a queue entry representing a command from a host comprising a request for data stored at a device memory location; receiving the command from the host; and executing the command. An example method can also include selecting a bit string representing whether a requested data stream has been received, and storing the bit string into a memory buffer portion to mark the buffer portion. The method can include receiving, into the memory buffer, the stream. The method can include retrieving contents of the buffer portion, and determining whether the contents contain the bit string. If so, the method can include determining that portions of the stream have not been received. Otherwise, the method can include determining that the stream has been received.

Certain aspects of present disclosure are directed the present disclosure relates to a baseboard management controller (BMC) implemented method of installation of operating system (OS) on a host computer using virtual storage of BMC. The method includes: (a) receiving a device request from the host computer to access a storage device, (b) simulating the storage device to host computer according to the device request, (c) receiving a data request command from host computer, (d) transferring requested data to the host computer according to the data request command, (e) receiving a data storage command from host computer directed to the simulated storage device and writing a status file at request of the data storage command, (f) determining if the status file exists in the simulated storage, and (g) stopping emulating the storage device to the host computer through the first communication interface if it is determined that the status file exists.

A memory module comprises a volatile memory subsystem configured to coupled to a memory channel in computer system and capable of serving as main memory for the computer system, a non-volatile memory subsystem providing storage for the computer system, and a module controller coupled to the volatile memory subsystem, the non-volatile memory subsystem, and the C/A bus. The module controller is configured to control intra-module data transfers between the volatile memory subsystem and the non-volatile memory subsystem. The module controller is further configured to monitor C/A signals on the C/A bus and schedule the intra-module data transfers in accordance with the C/A signals so that the intra-module data transfers do not conflict with accesses to the volatile memory subsystem by the memory controller.

An enhanced Flash chip and a method for packaging chip are provided to solve the problems of high design complexity. The enhanced Flash chip comprises: a FLASH and a RPMC packaged integrally, wherein the same IO pins in the FLASH and in the RPMC are mutually connected and are connected to the same external sharing pin of the chip; an external instruction is transmitted to the FLASH and the RPMC through the external sharing pin of the chip, and the controller of the FLASH and the controller of the RPMC respectively judge whether to execute the external instruction; and the FLASH and the RPMC further comprise internal IO pins, respectively, the internal IO pins of the FLASH and the internal IO pins of the RPMC are mutually connected, and internal mutual communication between the FLASH and the RPMC is performed through the pair of mutually connected internal IO pins.

First and second data representation are stored in first and second blocks of a non-volatile, solid-state memory. The first and second blocks share series-connected bit lines. The first and second blocks are selected and other blocks of the non-volatile, solid-state memory that share the bit lines are deselected. The bit lines are read to determine a combination of the first and second data representations. The combination may include a union or an intersection.