An information handling system may include at least one processor and a memory. The information handling system may be configured to: receive information regarding equipment that is to be communicatively coupled to a data network; determine a topology for communicatively coupling the equipment to the data network, wherein the topology includes information regarding which equipment ports of the equipment are to be coupled to data network ports of the data network;

and transmit information regarding the topology to a user.

Embodiments for optimizing a backup operation for a data protection system, by connecting with network devices in a network implementing the backup operation, the backup operation implementing a policy that specifies a plurality of service requirements and that is initiated at a time within a plurality of time windows, and determining a size of dataset to be backed up by the backup operation. The method further monitors a flow of data between a source and a destination of data in the network, compiles historical data of operational parameters for data transfers between the source and destination, and determines an optimum time within the plurality of time windows based on the dataset size and the historical data.

As an example, a method includes storing, in non-transitory memory, prioritization rules that establish a priority preference for egress of data traffic for a first location. The first location includes a first location apparatus to control egress of data traffic for the first location apparatus and a second location apparatus at a second location, which is different from the first location, to receive data traffic and cooperate with the first apparatus to measure bandwidth with respect to the first location. The first location apparatus is coupled with the second location apparatus via at least one bidirectional network connection. The method also includes estimating capacity of the at least one network connection for the egress of data traffic with respect to the first location. The method also includes categorizing each packet in egress data traffic from the first location based on an evaluation of each packet with respect to the prioritization rules. The method also includes placing each packet in one of a plurality of egress queues associated with the at least one network connection at the first location apparatus according to the categorization of each respective packet and the estimated capacity. The method also includes sending the packets from the first location apparatus to the second location apparatus via a respective network connection according to a priority of the respective egress queue into which each packet is placed, such that the first location apparatus transmits at the estimated capacity for the egress of data traffic.

In accordance with embodiments disclosed herein, there are provided methods, systems, mechanisms, techniques, and apparatuses for traffic aggregation on multiple WAN backhauls and multiple distinct LAN networks; for traffic load balancing on multiple WAN backhauls and multiple distinct LAN networks; and for performing self-healing operations utilizing multiple WAN backhauls serving multiple distinct LAN networks. For example, in one embodiment, a first Local Area Network (LAN) access device is to establish a first LAN; a second LAN access device is to establish a second LAN; a first Wide Area Network (WAN) backhaul connection is to provide the first LAN access device with WAN connectivity; a second WAN backhaul connection to provide the second LAN access device with WAN connectivity; a management device is communicatively interfaced with each of the first LAN access device, the second LAN access device, the first WAN backhaul connection, and the second WAN backhaul connection; and the management device routes a first portion of traffic originating from the first LAN over the first WAN backhaul connection and routes a second portion of the traffic originating from the first LAN over the second WAN backhaul connection.

The present disclosure is to propose a method and device for improving a link aggregation protocol timeout. method for improving a link aggregation timeout. The method includes the following steps: setting a timeout value and a timeout threshold count of link aggregation control protocol data unit (LACPDU) packet reception of a switch; obtaining a timeout count statistically, in response to a timeout of reception of a link aggregation control protocol data unit (LACPDU) packet from a second switch by a first switch; determining, through a network controller, in response to that the timeout count is greater than the timeout threshold count and that an aggregated link between the switches is in an out-of-band management mode, whether a port of the second switch is abnormal; and removing, in response to the port of the second switch being abnormal, the abnormal port of the second switch from the aggregated link.

A method of managing a network of calculation nodes interconnected by a plurality of interconnection devices, includes organizing the calculation nodes into groups of calculation nodes, for each group of calculation nodes, connecting the interconnection devices interconnecting the nodes of the group to a group management node, the management node being dedicated to the group of calculation nodes on each management node execution of an administration function by the implementation of independent management modules, each management module of a management node being able to communicate with the other management modules of the same management node.

Systems and methods for transmitting encapsulated SNMP commands to virtual machines. An example method may comprise: receiving a Simple Network Management Protocol (SNMP) request; encapsulating, by a processing device, the SNMP request in a format compatible with respect to which a virtual machine is configured to communicate; and providing the encapsulated SNMP request to the virtual machine.

Some embodiments provide a novel method for distributing control-channel communication load between multiple controllers in a network control system. In some embodiments, the controllers manage physical forwarding elements that forward data between several computing devices (also called hosts or host computers), some or all of which execute one or more virtual machines (VMs). The method of some embodiments distributes a controller assignment list to the host computers. The host computers use this list to identify the controllers with which they need to interact to perform some of the forwarding operations of their associated logical forwarding elements. In some embodiments, agents executing on the host computers (1) review the controller assignment list to identify the appropriate controllers, and (2) establish control channel communications with these controllers to obtain the needed data for effectuating the forwarding operations of their associated physical forwarding elements. These agents in some embodiments are responsible for out-of-band control channel communication with the controllers.

A process for configuring hardware in a network environment, comprising retrieving a catalog index using a processor, selecting a catalog for a new hardware component, selecting a plurality of software applications for the new hardware product from the catalog, determining a context for the new hardware component, wherein the context identifies one or more variable parameters for one or more of a plurality of software applications and installing the plurality of software applications on the hardware product as a function of the context.

A bidirectional out-of-band management (OOBM) dongle comprises a serial port for receiving console traffic from a console port of a managed switch and an Ethernet port for receiving management port traffic from a management port of the managed switch. In operation, the OOBM dongle multiplexes, via an optional adapter, the console traffic and the management port traffic and generates Ethernet traffic that is then communicated, via an OOBM port on the dongle, to an OOBM switch port of an OOBM switch that acts as a power sourcing device for the OOBM dongle.