Methods, non-transitory computer readable media, application delivery controller (ADC) apparatuses, and network traffic management systems that receive a request including an Internet Protocol (IP) version 6 (IPv6) source address and an IPv6 destination address. A client IP version 4 (IPv4) address of a client from which the request originated and a server IPv4 address of a server are determined from one or more extracted portions of one or more of the IPv6 source address or the IPv6 destination address. The request is modified to include an IPv4 source address and an IPv4 destination address. The IPv4 source address and the IPv4 destination address include the client IPv4 address and the server IPv4 address, respectively. The modified request is sent to the server based on the server IPv4 address included in the IPv4 destination address of the modified request.

Various techniques for dynamic path selection and data flow forwarding are disclosed. For example, various systems, processes, and computer program products for dynamic path selection and data flow forwarding are disclosed for providing dynamic path selection and data flow forwarding that can facilitate preserving/enforcing symmetry in data flows as disclosed with respect to various embodiments.

Methods, apparatuses and systems for cloud-based disaster recovery are provided. The method, for example, includes receiving, at a cloud-based computing platform, first internet protocol (IP) information relating to a first network environment associated with a server used by a client machine; translating the first IP information, without having to interpose a camouflage layer into the first IP information, and generating second IP information based on the translated first IP information, the second IP information used for creating a second network environment for the server; creating the second network environment for the server; and deploying the server in the created second environment.

Methods, apparatuses and systems for cloud-based disaster recovery are provided. The method, for example, includes receiving, at a cloud-based computing platform, first internet protocol (IP) information relating to a first network environment associated with a server used by a client machine; translating the first IP information, without having to interpose a camouflage layer into the first IP information, and generating second IP information based on the translated first IP information, the second IP information used for creating a second network environment for the server; creating the second network environment for the server; and deploying the server in the created second environment.

Systems and methods are disclosed for parallelizing service function chains. A method comprises receiving a sequential service function chain comprising a plurality of network functions, receiving a plurality of operations, determining at least two network functions are capable of being parallelized, aggregating operations of the plurality of operations associated with the at least two network functions into a network function segment, determining whether another network function is capable of being parallelized with the network function segment, based on the determining: aggregating an operation associated with the another network function into the network function segment when the another network function is capable of being parallelized with the network function segment, or pushing the network function segment as a completed segment of a hybrid service function chain when the another network function is not capable of being parallelized with the network function segment, and implementing the hybrid service function chain.

An electronic device is provided. The electronic device includes a network connection device, at least one processor, and a memory operably connected to the at least one processor, wherein the memory store instructions which are configured to, when executed, control the electronic device to receive a data packet from the network connection device, identify an Internet protocol (IP) type of a server, based on header information of the received data packet, identify information related to packet mergence set according to the identified IP type of the server and an IP type of the electronic device, and merge the data packets received from the network connection device or flush the data packets as a network stack, based on the identified information related to the packet mergence.

An electronic device is provided. The electronic device includes a network connection device, at least one processor, and a memory operably connected to the at least one processor, wherein the memory store instructions which are configured to, when executed, control the electronic device to receive a data packet from the network connection device, identify an Internet protocol (IP) type of a server, based on header information of the received data packet, identify information related to packet mergence set according to the identified IP type of the server and an IP type of the electronic device, and merge the data packets received from the network connection device or flush the data packets as a network stack, based on the identified information related to the packet mergence.

An example embodiment may include a computational instance and a computing device within a remote network management platform. The computing device may be configured to: receive, from a client device of the managed network, a request to redirect, to a second URL, future requests addressed to a first URL; provide, to the client device, instructions to generate a certificate that binds an identity of the entity that operates the managed network to the first URL; receive, from the client device, the certificate; store the certificate and a corresponding cryptographic key; and generate a mapping between the first URL and the second URL. The computational instance may be configured to, in response to receiving a content request referencing the destination, generate a content response containing content from the destination, where any hyperlinks to the second URL in the content are replaced with hyperlinks to the first URL.

An example embodiment may include a computational instance and a computing device within a remote network management platform. The computing device may be configured to: receive, from a client device of the managed network, a request to redirect, to a second URL, future requests addressed to a first URL; provide, to the client device, instructions to generate a certificate that binds an identity of the entity that operates the managed network to the first URL; receive, from the client device, the certificate; store the certificate and a corresponding cryptographic key; and generate a mapping between the first URL and the second URL. The computational instance may be configured to, in response to receiving a content request referencing the destination, generate a content response containing content from the destination, where any hyperlinks to the second URL in the content are replaced with hyperlinks to the first URL.

In order to enable dynamic scaling of network services at the edge, novel systems and methods are provided to enable addition of add new nodes or removal of existing nodes while retaining the affinity of the flows through the stateful services. The methods provide a cluster of network nodes that can be dynamically resized to handle and process network traffic that utilizes stateful network services. The existing traffic flows through the edge continue to function during and after the changes to membership of the cluster. All nodes in the cluster operate in active-active mode, i.e., they are receiving and processing traffic flows, thereby maximizing the utilization of the available processing power.