A method for recording parity data of data stripes within shingled media recording bands in a redundant array of independent disks can be accomplished using a plurality of shingled media recording (SMR) hard disk drives (HDD) each with a plurality of shingled data bands. A data stream received from a host computer system is sequentially stored to a plurality of block segments in successive order, one stripe at a time successively. Each of the shingled data bands possess n data blocks (or multiple data blocks that are grouped together as a data unit) that are successively ordered, each corresponding successive data block from all of the SMR HDDs defines a data stripe, accordingly n data blocks in each SMR HDD defines n stripes across the shingled data bands. A transaction group sync triggers a halt to writing the data stream. The rest of the data stripe is written with fill bits. Parity data is written to a parity drive in one or more SMR parity blocks that correspond in size and sequence to the data blocks in the data stripes possessing the first data stream and any of the fill bits.

Example redundant array of independent disks (RAID) storage systems and methods provide rebuild of logical data groups in priority order. Storage devices are configured as a storage array for storing logical data groups distributed among the storage devices. The logical data groups are written in a configuration of RAID stripes in the storage devices. A logical group index includes a logical group map for each logical data group and identifies corresponding logical blocks. When a storage device fails, the rebuild queue is ordered based on the priority of the logical data groups and rebuild to the replacement storage device is completed in the priority order.

A storage control device includes a processor which performs first copy of copying first data stored in a first storage device into a first backup region upon detecting a failure presage in the first storage device. The processor performs first write of writing second data specified in a first write request to the first storage device and second write of writing the second data into the first backup region upon receiving the first write request while performing the first copy. The processor performs second copy of copying third data stored in the first backup region to a second storage device upon completing the first copy. The processor performs third write of writing fourth data specified in a second write request to the second storage device in place of the first storage device upon receiving the second write request after completion of the second copy.

Example redundant array of independent disks (RAID) storage systems and methods provide rebuild of logical data groups in priority order. Storage devices are configured as a storage array for storing logical data groups distributed among the storage devices. The logical data groups are written in a configuration of RAID stripes in the storage devices. A logical group index includes a logical group map for each logical data group and identifies corresponding logical blocks. When a storage device fails, the rebuild queue is ordered based on the priority of the logical data groups and rebuild to the replacement storage device is completed in the priority order.

Examples disclosed herein relate to storage drive management. Some examples disclosed herein a storage controller may adjust failure criteria for a storage drive and determine whether to fail the storage drive based on the adjusted failure criteria. The storage controller may adjust the failure criteria based on various factors, such as the quantity of input/output (I/O) command abort attempts corresponding to the storage drive issued by a host device.

Described is a tape library system that generally comprises a plurality of tape drives and a data bus that links a host computer system to a first tape drive address and a second tape drive address. However, the first tape drive address points to a first controller and switch system that assumes the identity of one of the tape drives. The first controller and switch system is linked to a first tape drive adapted to cooperate with a first type of tape cartridge and a second tape drive adapted to cooperate with second type of tape cartridge. The second tape drive address points to a second controller and switch system that assumes the identity of a different one of the tape drives. The second controller and switch system is linked to a third tape drive adapted to cooperate with the first type of tape cartridge and a third tape drive adapted to cooperate with the second type of tape cartridge.

A method for recording parity data of data stripes within shingled media recording bands in a redundant array of independent disks can be accomplished using a plurality of shingled media recording (SMR) hard disk drives (HDD) each with a plurality of shingled data bands. A data stream received from a host computer system is sequentially stored to a plurality of block segments in successive order, one stripe at a time successively. Each of the shingled data bands possess n data blocks (or multiple data blocks that are grouped together as a data unit) that are successively ordered, each corresponding successive data block from all of the SMR HDDs defines a data stripe, accordingly n data blocks in each SMR HDD defines n stripes across the shingled data bands. A transaction group sync triggers a halt to writing the data stream. The rest of the data stripe is written with fill bits. Parity data is written to a parity drive in one or more SMR parity blocks that correspond in size and sequence to the data blocks in the data stripes possessing the first data stream and any of the fill bits.

Systems and methods for switching between multiple video sources output to output a video stream via a single physical output are disclosed. An example method can include decoding a first encoded video file and populating a memory with corresponding first decoded video data. The process can include decoding a second encoded video file and populating the memory with corresponding second decoded video data at a particular location of the memory. The process can include causing a video player to read from the memory so as to output a video stream, via the single physical output, corresponding to the first decoded video data, and then causing the video player to switch to read from the particular location of the memory such that the video stream switches to corresponding to the second decoded video data.

A video storage apparatus is described which stores and provides access to a video sequence of images. The apparatus comprises an array of storage devices, each image in the sequence being stored on at least one of the storage devices in the array, or being distributed across the array of storage devices with each portion being independently reproducible. A driver is provided, the driver being operable to access the video sequence by reading images in time order from the array of storage devices, temporally adjacent ones of the images, or different portions of the same image, being read by the driver from different storage devices in the array. In this way, an array of independent drives can be used to store video and allow much faster access to the stored video than would be the case with a single drive, and in a way which is more robust to drive failure.

Examples disclosed herein relate to storage drive management. Some examples disclosed herein a storage controller may adjust failure criteria for a storage drive and determine whether to fail the storage drive based on the adjusted failure criteria. The storage controller may adjust the failure criteria based on various factors, such as the quantity of input/output (I/O) command abort attempts corresponding to the storage drive issued by a host device.