A request to separate a transfer into a plurality of parts may be received, the request defining a total amount and a total time period. A plurality of request for transfer links may be prepared. Each of the links may be associated with a different transfer time period, each transfer time period being less than or equal to the total time period. Each of the links may be associated with a separate transfer part amount, and a summation of the separate transfer part amounts may be equal to the total amount. A plurality of request for transfer links may be provided to a transferor device, each link allowing a transfer to fulfill the separate transfer part amount to be performed without requiring input of the separate transfer part amount or recipient information.

Aspects of the disclosure relate to cognitive automation-based engine processing to propagate data across multiple systems via a private network to overcome technical system, resource consumption, and architecture limitations. Data to be propagated can be manually input or extracted from a digital file. The data can be parsed by analyzing for correct syntax, normalized into first through sixth normal forms, segmented into packets for efficient data transmission, validated to ensure that the data satisfies defined formats and input criteria, and distributed into a plurality of data stores coupled to the private network, thereby propagating data without repetitive manual entry. The data may also be enriched by, for example, correcting for any errors or linking with other potentially related data. Based on data enrichment, recommendations of additional target(s) for propagation of data can be identified. Reports may also be generated. The cognitive automation may be performed in real-time to expedite processing.

A method for a first set of processors and a second set of processors comprises, the first set of processors processing a set of queries, as a result of a change in utilization of the first set of processors, processing the set of queries using the second set of processors. The change in processors is independent of a change in storage resources, the storage resources shared by the first set of processors and the second set of processors.

A method for a first set of processors and a second set of processors comprises, the first set of processors processing a set of queries, as a result of a change in utilization of the first set of processors, processing the set of queries using the second set of processors. The change in processors is independent of a change in storage resources, the storage resources shared by the first set of processors and the second set of processors.

A multi-function device is disclosed. A first port may be used to communicate with a host processor. A second port may be used to communicate with a storage device. A third port may be used to communicate with a computational storage unit. Circuit may be used to route a message from the host processor to at least one of the storage device or the computational storage unit.

A multi-function device is disclosed. A first port may be used to communicate with a host processor. A second port may be used to communicate with a storage device. A third port may be used to communicate with a computational storage unit. Circuit may be used to route a message from the host processor to at least one of the storage device or the computational storage unit.

Techniques for providing remote access to application content are described herein. A virtual computing node may be leased to a first user requesting access to an application. On the virtual computing node, a virtualization process may spawn the application as a child process. In response to a second request, by the same user, to access an additional application, the virtual computing node may be identified. The virtualization process may spawn the second application as a child process in the process space of the first application. Data may be exchanged between the applications within the process space.

Techniques for providing remote access to application content are described herein. A virtual computing node may be leased to a first user requesting access to an application. On the virtual computing node, a virtualization process may spawn the application as a child process. In response to a second request, by the same user, to access an additional application, the virtual computing node may be identified. The virtualization process may spawn the second application as a child process in the process space of the first application. Data may be exchanged between the applications within the process space.

An Orchestrated Data Recovery (ODR) Cyber Protection Automation (CPA) operates to ensure one-to-one creation of snapsets of a production site and corresponding snapsets of a cyber vault. During an initiation phase, the ODR CPA monitors synchronization of a snapset of production volumes from the production site to the cyber vault. If additional snapsets of the production volumes are created prior to completion of synchronization of the first snapset, the additional snapsets are also synchronized to the cyber vault. Once the initial synchronization of the storage volumes has been completed, the ODR CPA causes a Storage Volume Creation and Management System (SVCMS) to create a snapset of the storage volumes at the cyber vault. Subsequently, each time a snapset is created of the production site, the ODR CPA orchestrates synchronization of the snapset to the cyber vault and creation of a corresponding snapset at the cyber vault.

In one embodiment, a system for managing a virtualization environment includes a set of host machines, each of which includes a hypervisor, virtual machines, and a virtual machine controller, and a data migration system configured to identify one or more existing storage items stored at one or more existing File Server Virtual Machines (FSVMs) of an existing virtualized file server (VFS). For each of the existing storage items, the data migration system is configured to identify a new FSVMs of a new VFS based on the existing FSVM, send a representation of the storage item from the existing FSVM to the new FSVM, such that representations of storage items are sent between different pairs of FSVMs in parallel, and store a new storage item at the new FSVM, such that the new storage item is based on the representation of the existing storage item received by the new FSVM.