Abstract: A storage module is configured to store data segments, such as error-correcting code (ECC) codewords, within an array comprising two or more solid-state storage elements. The data segments may be arranged in a horizontal arrangement, a vertical arrangement, a hybrid channel arrangement, and/or vertical stripe arrangement within the array. The data arrangement may determine input/output performance characteristics. An optimal adaptive data storage configuration may be based on read and/or write patterns of storage clients, read time, stream time, and so on. Data of failed storage elements may be reconstructed by use of parity data and/or other ECC codewords stored within the array.

Abstract: An apparatus, system, and method are disclosed for bad block remapping. A bad block identifier module identifies one or more data blocks on a solid-state storage element as bad blocks. A log update module writes at least a location of each bad block identified by the bad block identifier module into each of two or more redundant bad block logs. A bad block mapping module accesses at least one bad block log during a start-up operation to create in memory a bad block map. The bad block map includes a mapping between the bad block locations in the bad block log and a corresponding location of a replacement block for each bad block location. Data is stored in each replacement block instead of the corresponding bad block. The bad block mapping module creates the bad block map using one of a replacement block location and a bad block mapping algorithm.

Abstract: An apparatus, system, and method are disclosed for improving performance in a non-volatile solid-state storage device. Non-volatile solid-state storage media includes a plurality of storage cells. An input module receives source data for storage in the plurality of storage cells of the non-volatile solid-state storage media. Some or all of the bits of the source data are transformed to take into account a voltage level of an empty state of the plurality of storage cells. A write module writes the transformed source data to the plurality of storage cells of the non-volatile solid-state storage media.

Abstract: Data of a vector storage request pertaining to one or more disjoint, non-adjacent, and/or non-contiguous logical identifier ranges are stored contiguously within a log on a non-volatile storage medium. A request consolidation module modifies one or more sub-requests of the vector storage request in response to other, cached storage requests. Data of an atomic vector storage request may comprise persistent indicators, such as persistent metadata flags, to identify data pertaining to incomplete atomic storage requests. A restart recovery module identifies and excludes data of incomplete atomic operations.

Abstract: Apparatuses, systems, and methods are disclosed for storing metadata. A mapping module is configured to maintain a mapping structure for logical addresses of a non-volatile device. A metadata module is configured to store membership metadata for the logical addresses with logical-to-physical mappings for the logical addresses in the mapping structure.

Abstract: A method and apparatus for storing data packets in two different logical erase blocks pursuant to an atomic storage request is disclosed. Each data packet stored in response to the atomic storage request comprises persistent metadata indicating that the data packet pertains to an atomic storage request. In addition, a method and apparatus for restart recovery is disclosed. A data packet preceding an append point is identified as satisfying a failed atomic write criteria, indicating that the data packet pertains to a failed atomic storage request. One or more data packets associated with the failed atomic storage request are identified and excluded from an index of a non-volatile storage media.

Abstract: Apparatuses, systems, and methods are disclosed for managing contents of a cache. A method includes receiving a read request for data stored in a non-volatile cache. A method includes determining whether a read request satisfies a frequent read threshold for a cache. A method includes writing data of a read request forward on a sequential log-based writing structure of a cache in response to determining that the read request satisfies a frequent read threshold.

Abstract: Methods, storage controllers, and systems for backing data of a non-volatile storage device using a backing store are described. One method includes satisfying storage operations using a non-volatile storage device, determining an age for data stored on the non-volatile storage device, and copying data of the non-volatile storage device having an age that satisfies a data retention time threshold to a dedicated backing store. One storage controller includes an operations module that satisfies storage operations using a non-volatile storage device, an age module that determines an age for data stored on the non-volatile storage device, and a backup module that copies data of the non-volatile storage device having an age that satisfies a data retention time threshold to a dedicated backing store.

Abstract: An apparatus, system, and method are disclosed to manage non-volatile media. A media characteristic module is configured to determine media characteristics for non-volatile media. A configuration parameter module is configured to determine different configuration parameters for different storage cell abodes and/or for different groups of pages of the non-volatile media based on the determined media characteristics. A cell configuration module is configured to use the different configuration parameters for the different storage cell abodes and/or the different groups of pages of the non-volatile media.

Abstract: An apparatus, system, and method are disclosed for storage space recovery in solid-state storage. A sequential storage module sequentially writes data packets in a storage division. The storage division includes a portion of a solid-state storage. The data packets are derived from an object. The data packets are sequentially stored by order of processing. A storage division selection module selects a storage division for recovery. A data recovery module reads valid data packets from the storage division selected for recovery, queues the valid data packets with other data packets to be written sequentially, and updates an index with a new physical address of the valid data. The index includes a mapping of physical addresses of data packets to object identifiers. A storage division recovery module marks the storage division selected for recovery as available for sequentially writing data packets in response to completing copying valid data from the storage division.

Abstract: Apparatuses, systems, and methods are disclosed for implementing a cache policy. A method may include determining a risk of data loss on a cache device. The cache device may comprise a non-volatile storage device configured to perform cache functions for a backing store. The cache device may implement a cache policy. A method may include determining that a risk of data loss on the cache devices exceeds a threshold risk level. A method may include implementing a modified cache policy for the cache device in response to the risk of data loss exceeding the threshold risk level. The modified cache policy may reduce the risk of data loss below the threshold level.

Abstract: An apparatus, system, and method are disclosed for storing information in a storage device that includes multi-level memory cells. The method involves storing data that is written to the storage device in the LSBs of the multi-level memory cells, and storing audit data in the MSBs of the multi-level memory cells. The audit data can be read separately from the data and used to determine whether or not there has been any unintended drift between states in the multi-level cells. The audit data may be used to correct data when the errors in the data are too numerous to be corrected using error correction code (ECC). The audit data may also be used to monitor the general health of the storage device. The monitoring process may run as a background process on the storage device. The storage device may transition the multi-level memory cells to operate as single-level memory cells.

Abstract: An apparatus, system, and method are disclosed for servicing storage requests for a non-volatile memory device. An interface module is configured to receive a storage request for a data set of a non-volatile memory device from a client. The data set is different from a block of the non-volatile memory device, and may have a length different from a block size of the non-volatile memory device. A block load module is configured to load data of at least the block size of the non-volatile memory device. A fulfillment module is configured to service the storage request using at least a portion of the loaded data.

Abstract: An apparatus, system, and method are disclosed for managing power consumption in a data storage device. An audit module monitors a power consumption rate of the data storage device relative to a power consumption target. A throttle module adjusts execution of one or more operations on the data storage device in response to the power consumption rate of the data storage device failing to satisfy the power consumption target. A verification module verifies whether the power consumption rate of the data storage device satisfies the power consumption target in response to adjusting the execution of the one or more operations.

Abstract: An apparatus, system, and method are disclosed for auto-commit memory management. The method includes receiving an auto-commit request from a client, such as a barrier request or a checkpoint request. The auto-commit request is associated with an auto-commit buffer of a non-volatile recording device. The method includes issuing a serializing instruction that flushes data from a processor complex to the auto-commit buffer. The method includes determining completion of the serializing instruction flushing the data to the auto-commit buffer.

Abstract: An apparatus, system, and method are disclosed for solid-state storage as cache for high-capacity, non-volatile storage. The apparatus, system, and method are provided with a plurality of modules including a cache front-end module and a cache back-end module. The cache front-end module manages data transfers associated with a storage request. The data transfers between a requesting device and solid-state storage function as cache for one or more HCNV storage devices, and the data transfers may include one or more of data, metadata, and metadata indexes. The solid-state storage may include an array of non-volatile, solid-state data storage elements. The cache back-end module manages data transfers between the solid-state storage and the one or more HCNV storage devices.

Abstract: An apparatus, system, and method are disclosed for a baseboard management controller (BMC) which includes an FPGA with a monitor module for monitoring the operations parameters of a host computer device. In addition, the BMC has a host connector that connects the BMC to the system bus of the host computing device, allowing the BMC access to the computing elements on the host. The host connector has reconfigurable pins with connection configuration controlled by the FPGA. In addition, the BMC has a server with a processor and associated non-volatile memory on board. The operating system provides services to the host computing device and its constituent components, as well as allowing advanced networking and interconnectivity with other BMCs in a management network.

Abstract: An apparatus, system, and method are disclosed for persistently storing data objects. An object store index module maintains an object store. The object store associates each data object of a plurality of data objects with a unique key value. A storage module persists object store data defining the object store to a logical block address of the solid-state storage device in response to an update event. The logical block address is a member of a restricted set of logical block addresses. The logical block address is mapped to a location of the object store data on the solid-state storage device. A read module provides a requested data object from the plurality of data objects to a requesting client in response to receiving a read request for the requested data object from the requesting client. The read request comprises the key value associated with the requested data object.

Abstract: An apparatus, system, and method are disclosed for data storage with progressive redundant array of independent drives (“RAID”). A storage request receiver module, a striping module, a parity-mirror module, and a parity progression module are included. The storage request receiver module receives a request to store data of a file or of an object. The striping module calculates a stripe pattern for the data. The stripe pattern includes one or more stripes, and each stripe includes a set of N data segments. The striping module writes the N data segments to N storage devices. Each data segment is written to a separate storage device within a set of storage devices assigned to the stripe. The parity-mirror module writes a set of N data segments to one or more parity-mirror storage devices within the set of storage devices. The parity progression module calculates a parity data segment on each parity-mirror device in response to a storage consolidation operation, and stores the parity data segments.

Abstract: Apparatus, systems, and methods are disclosed for managing concurrent storage requests. A multiple storage request receiver module is configured to recognize at least two storage requests from clients for data in storage devices of a storage device set. The at least two concurrent storage requests address a common portion of data. A sequencer module is configured to determine a first storage request and a second storage request from the concurrent storage requests by way of selection criteria. The sequencer module is configured to ensure completion of the first storage request prior to executing the second storage request by receiving an acknowledgment from each of the storage devices of the storage device set that received portions of the first storage request. The portions may be sent to the storage devices to execute the first storage request.