A management device that may communicate with at least one devices is disclosed. The management device may include a communication logic to communicate with the devices over a communication channels about data associated with the devices. The management device may also include reception logic that may receive a query from a host. The query may request information from the management device about the devices. The management device may also include a transmission logic to send the data about the devices to the host. The host may be configured to send a message to the devices.

A computing system includes host and a storage device. The host includes a host memory and a user interface. The storage device provides the host with a first request including device setting inquiry information, and sets a device configuration based on a first response to the device setting inquiry information received from the host. The host provides the storage device with the first response acquired from a user through the user interface in response to the first request. The device setting inquiry information includes at least one of information on allocation of a map buffer in the host memory, information on allocation of a write buffer in a buffer region of the storage device, or information on a power level of the storage device.

The disclosed embodiments relate to logging activities of memory devices and adjusting the operation of a controller based on the activities. In one embodiment, a method comprises collecting, by a memory device, profile data, the profile data associated with read and write commands and corresponding address information issued to the memory device from a host device; storing, by the memory device, the profile data in a portion of a storage array managed by the memory device; receiving, by the memory device, an update generated based on the profile data, the update adjusting a configuration setting of the memory device; and processing, by the memory device, a received command based on the configuration setting.

A memory management method is provided according to the invention. The method includes: reading a physical unit and updating a read count of the physical unit; scanning the physical unit if the updated read count is not less than a read count threshold; and adjusting the read count threshold according to the read count and a read error bit. Therefore, a data unit that needs to be scanned can be determined to reduce unnecessary data scanning.

Applying a rate limit across a plurality of storage systems, including: determining a rate limit for paired storage systems; receiving, by a first storage system, an amount of I/O operations serviced by the second storage system during a previous predetermined period of time; determining whether the amount of I/O operations serviced by the second storage system is less than half of the rate limit for the paired storage systems; if so, setting local a rate limit for a next predetermined period of time for the first storage system to the difference between the rate limit for the paired storage systems and the amount of I/O operations serviced by the second storage system during the previous predetermined period of time; and otherwise, setting a local rate limit for a next predetermined period of time for the first storage system to half of the rate limit for the paired storage systems.

It is made possible to pursue both higher speeds of rebuilds in the distributed RAID scheme and high availability due to acquisition of DE-failure tolerance. A virtual chunk includes k (k is an integer that is equal to or larger than two) virtual parcels including a virtual parcel having user data and a virtual parcel having element data that is redundant data for repairing the user data, the virtual parcels included in the same virtual chunk is stored by mapping the virtual parcels in storage areas of k mutually different physical storage drives among N (k<N) of the physical storage drives, and the maximum value of the numbers of the same virtual parcels to be mapped to the physical storage drives housed in the same drive enclosures is equal to or smaller than a predetermined value.

A control method for a flash memory, a flash memory die and the flash memory are provided. The control method includes: in a setup stage, under an operation mode of a command input, issuing by a host a setup command to map each port of an external data bus of each flash memory die respectively to a status index of each flash memory die; and in a request stage, under the operation mode of the command input, issuing by the host a request command to each flash memory die, and under the operation mode of a data output, a status of the status index of each flash memory die is transmitted to the host through the ports of the external data bus respectively.

A master profile may be created defining a plurality of values for a plurality of storage system parameters. The master profile may be stored and applied to a plurality of storage systems. In some embodiments, one or more values defined in the master profile may be changed and the resulting plurality of parameter values stored in a new master profile. Current values of storage system parameters may be monitored, for example, determined according to a predefined schedule or in response to user input, and the current values may be compared against the values defined in the master profiles. The results of these comparisons may be recorded as part of compliance information that indicates the extent of compliance of the parameter values of a storage system with the master profile parameter values. The compliance information may be included as part of a compliance report, notification or some other communication.

Technologies for dynamic accelerator selection include a compute sled. The compute sled includes a network interface controller to communicate with a remote accelerator of an accelerator sled over a network, where the network interface controller includes a local accelerator and a compute engine. The compute engine is to obtain network telemetry data indicative of a level of bandwidth saturation of the network. The compute engine is also to determine whether to accelerate a function managed by the compute sled. The compute engine is further to determine, in response to a determination to accelerate the function, whether to offload the function to the remote accelerator of the accelerator sled based on the telemetry data. Also the compute engine is to assign, in response a determination not to offload the function to the remote accelerator, the function to the local accelerator of the network interface controller.

One or more parameters indicative of a request to segment the memory device into multiple partitions for use by a host system are received. Responsive to receiving the one or more parameters indicative of the request to segment the memory device into multiple partitions, a first partition is configured with one or more configuration settings based on the one or more parameters. Configuring the first partition includes determining a memory type from multiple memory types based on the one or more parameters, and configuring the first partition to operate as the determined memory type. The memory types define a number of bits that a memory cell of the first partition is to store.