An embodiment of the invention may include a method, computer program product, and system for data transfer management. The embodiment may include receiving a data packet, by a first server, from a load balancer. The received data packet is part of a data flow. The embodiment may include determining, by the first server, whether the received data packet is part of an existing data flow connection served by the first server. Based on determining that the received data packet is not part of an existing data flow served by the first server, the embodiment may include determining, by the first server, whether the received data packet is part of a new data flow connection. Based on determining that the received data packet is not part of a new data flow connection, the embodiment may include notifying, by the first server, the load balancer.

The present disclosure relates to a method and system for executing processes in Virtual Storage Area Network by an array controller. The array controller receives a request for executing a process in VSAN, calculates a time duration for execution of the received process, compares calculated time duration with a predefined time duration, where the received process is divided into a first part and a second part if the calculated time duration exceeds the pre-defined time duration, executes the first part of the received process and assigns the second part of received process to a management server for execution, where the management server comprises a plurality of processing units dedicated for executing the second part of the received process.

In one aspect, the present disclosure relates to a method comprising: receiving, at a client device, information from a node manager about a plurality of nodes in a computer cluster, the information comprising a network address associated each of the plurality of nodes and sending, by the client device, a request to a load balancer to access a first node from the plurality of nodes, the request comprising a first URL including an encoded representation of the network address associated with the first node. The load balancer is configured to determine the request should be routed to a first network address based on decoding the URL, the first network address associated with a first node from the plurality of nodes and forward the request to the first node in response to the determining.

Mechanisms are provided for dispatching requests to service instances based on data storage boundaries. A request specifying an identity is received and dispatched to a service instance of a data storage boundary, where each data storage boundary is defined by a regulation or policy restricting data storage of specific types of data to computing devices within a specified boundary. A feedback response, specifying a target location, is received from the service instance in response to determining that the service instance cannot access the data because the data is associated with a different data storage boundary. A dynamic dispatch rule specifying the identity and the target location is generated and a subsequent request specifying the identity is processed by executing this dynamic dispatch rule to dispatch the subsequent request directly to a service instance associated with the target location.

Various embodiments are described herein for systems and methods that can be used to determine a destination location in a network fabric. In one example embodiment, the method comprises receiving an application server attribute at a fabric controller from a source port, generating at the fabric controller a destination location based on the application server attribute and mapping information stored on the fabric controller, and transmitting the destination location to the source port, where the source port transmits packetized data to a destination location based on the destination location.

Various embodiments are described herein for systems and methods that can be used to determine a destination location in a network fabric. In one example embodiment, the method comprises receiving an application server attribute at a fabric controller from a source port, generating at the fabric controller a destination location based on the application server attribute and mapping information stored on the fabric controller, and transmitting the destination location to the source port, where the source port transmits packetized data to a destination location based on the destination location.

Systems, methods, and apparatus are disclosed for providing instant rebates before a transaction is completed. This involves ingest of customer and rebate data from two or more utilities, where the data is parsed and normalized into a standard format across all of the utilities. The customer data is then stored in an accounts database, while the rebate data is further processed along with utility rebate rules to determine a set of device and demand response rebate eligibilities for a variety of scenarios. The resulting rebate profiles can be stored in a rebates database and linked to corresponding customer account data in the accounts database. Third-party frontends can then request rebate eligibility based on a customer identifier and retail channel, and various services can work in tandem to query the rebated database and return a set of eligibilities with so little latency that the eligibility check appears instant from a customer's standpoint.

Implementing multiple load balancer drivers for a single load balancer is disclosed. A first request directed to a load balancer to load balance requests based on a first request selection instruction is received. A first particular load balancer driver is selected from a plurality of load balancer drivers based on a load balancer table that correlates request selection instructions to corresponding load balancer drivers of the plurality of load balancer drivers. Subsequent requests that are encompassed by the first request selection instruction directed to the load balancer are caused to be load balanced by the first particular load balancer driver.

Embodiments herein disclose path selection for data traffic within a software-defined wide area network using traffic metrics. Some embodiments relate to a method that includes polling peers of the SD-WAN for traffic metrics, receiving traffic metrics from at least a portion of the peers, combining the received traffic metrics, calculating performance of a plurality of possible paths from a source node to a destination node, the nodes being within the SD-WAN topology, and selecting a path from the source node to the destination node based on the calculated performance.

Various embodiments are described herein for systems and methods that can be used to determine a destination location in a network fabric. In one example embodiment, the method comprises receiving an application server attribute at a fabric controller from a source port, generating at the fabric controller a destination location based on the application server attribute and mapping information stored on the fabric controller, and transmitting the destination location to the source port, where the source port transmits packetized data to a destination location based on the destination location.