Techniques for improving performance of a backup system are disclosed. In one particular exemplary embodiment, the techniques may be realized as a method for improving performance of a backup system. The method may comprise performing a backup of a client device, tracking, using at least one computer processor, references to data segments that are located outside of a unit of storage associated with the backup, calculating utilization of the unit of storage associated with the backup based on the tracked references, determining if the calculated utilization meets a specified parameter, and determining one or more responsive actions in the event the calculated utilization meets the specified parameter.

A main data storage system has a main computer-implemented storage control and data storage, and a user interface, the main storage control in communication with a local computer-implemented storage control of a local data storage system with local data storage. In response to a request to increase data storage from the user interface, the main storage control determines whether the main data storage is out of space. If so, the main storage control sends a command to the local storage control to create data space in local data storage. The local storage control creates the data space and associates the data space with the main storage control; and, in response to a command from the user interface to rebalance data storage, the local storage control sends the command to the main storage control to search for storage space sufficient for the data space in the main storage.

Provided is an image forming apparatus performing effective automated storage tiering. When the system control part of the CPU causes the image processing part to perform image processing of data read from the SSD having a processing speed higher than that of the HDD, the tiering control part measures a ratio of an idle time by the image processing relative to a usage ratio per unit time of the CPU, and determines a movement destination of the data.

A method includes encoding input data into a plurality of slices. The plurality of slices are sent to a first plurality of distributed storage and task execution units for storage, the first plurality of distributed storage and task execution units being located at a corresponding first plurality of sites. Write slice data is received from the first plurality of distributed storage and task execution units. The method determines when replication is to be applied to the plurality of slices. When replication is to be applied to the plurality of slices, a second plurality of distributed storage and task execution units are selected, a plurality of replicated slices corresponding to the plurality of slices are generated, and the plurality of replicated slices are sent to the second plurality of distributed storage and task execution units.

A flash memory card reader and a single converter chip for reading both serial and parallel flash cards. The read has connectors for both serial and parallel data transfer flash memory cards. The reader has a single chip converter. The converter supports both serial I/O and parallel I/O. The serial I/O transfers data in multiple modes. Both single-bit and multi-bit serial data transfers modes are supported. The reader may have multiple slots, one have a connector for serial and one having a connector for parallel flash memory cards.

The system described herein allows for picking data to be moved from one physical location to another using certain criteria, such as expected activity level, to achieve load balancing or load optimization. Migrating data for a logical device includes subdividing the logical device into subsections, where each of the subsections corresponds to a particular address range of the logical device that is mapped to a physical device containing corresponding data and copying data for a first subsection from a first physical device to a second, different, physical device, where data for a second subsection is maintained indefinitely on the first physical device after copying the data for the first subsection to the second physical device. The first physical device may be provided in a different geographic location than the second physical device.

Methods and systems for a storage server are provided. One method includes storing data at a first storage tier by a processor executable storage operating system; tracking the data stored at the first storage tier for moving the data to a second storage tier; transferring the data from the first storage tier to the second storage tier; and updating a data structure that tracks a transfer block number of a block that stores the data, where the transfer block number is based on a virtual identifier, a generation count and an offset value of a storage chunk that is a portion of a physical volume block number address space.

A method for execution by one or more processing modules of one or more computing devices of a dispersed storage network (DSN), the method begins by determining an addressing range of a storage configuration of the DSN. The method continues by determining a storage performance level associated with the addressing range. The method continues by determining whether the storage performance level compares favorably to a storage performance threshold. The method continues, when the storage performance level does not compare favorably to a storage performance threshold, by determining an updated storage configuration associated with the addressing range and re-assigning storage resources in accordance with the updated storage configuration.

A storage device includes a memory device including a plurality of memory blocks, and a controller configured to move first data from a single level cell (SLC) memory block to a first memory block having a target density lower than a maximum density based on a waiting time and to move second data from the SLC memory block to a memory block having the maximum density based on the waiting time.

A bridge device includes a first controller and a second controller. The first controller includes a first transmission interface. The second controller includes a second transmission interface. The first transmission interface and the second transmission interface are flash memory interfaces. In a program mode, the first transmission interface receives a first command from the second transmission interface and obtains first transfer data from a bus in response to the first command. A value of the first command is optionally set to a first value or a second value. The first value indicates a memory command transfer operation in a first direction and the second value indicates a memory data transfer operation in the first direction. The first transmission interface processes the first transfer data according to the value of the first command to obtain a memory command or written data.