Methods, apparatus, systems and articles of manufacture are disclosed that implement cloud functionality in a cloud agnostic system. An example apparatus to implement cloud specific functionality in a cloud agnostic system includes a request interpreter to determine whether a first request includes an indication that a cloud resource is to be partially provisioned, a provision determiner to select the cloud resource based on the indication, and a cloud interface to transmit a first resource request to partially provision the cloud resource, and in response to a second request including constraints specific to the cloud resource, transmit a second resource request to fully provision the cloud resource.

The present disclosure generally relates to managing network connection settings of external devices. In some embodiments, an electronic device with a display and one or more wireless antennas, while the electronic device is connected, via the one or more wireless antennas, to a first local area network, displays a first external device management interface, wherein: the first external device management interface is associated with a first external device that is not connected to the first local area network; and the first external device management interface includes a first affordance. The electronic device receives a user input corresponding to selection of the first affordance and, in response to receiving the user input corresponding to selection of the first affordance, causes the first external device to connect to the first local area network.

Some embodiments provide a system for implementing a logical network that includes a set of end machines, a first logical middlebox, and a second logical middlebox connected by a set of logical forwarding elements. The system includes a set of nodes. Each of several nodes includes (i) a virtual machine for implementing an end machine of the logical network, (ii) a managed switching element for implementing the set of logical forwarding elements of the logical network, and (iii) a middlebox element for implementing the first logical middlebox of the logical network. The system includes a physical middlebox appliance for implementing the second logical middlebox.

A controller device manages a plurality of network devices. The controller device includes one or more processing units implemented in circuitry and configured to maintain a graph data structure representing device level configuration schemas for the plurality of network devices, the graph data structure including trie nodes for every first device level configuration schema element for a first model of a version of network device of the plurality of network devices; obtain corresponding second device level configuration schema elements based on a path for a second model of the version of the network device; determine a deviation between the second device level configuration schema element and the first device level configuration schema; and update the trie node to add a branch to a node representing the second device level configuration schema element.

The configuration method comprises: a step of receiving (E40, E80), by a first device of the network, a first control message (CMD, M1) comprising configuration elements for the activation of the dynamic routing protocol in the network; a step of configuring (E50, E90), by the first device, session establishment parameters according to said protocol used by the first device from configuration elements comprised in the first message; if the configuration elements comprised in the first message comprise at least one session management instruction according to said protocol in the network, a step of executing (E60, E110), by the first device, said at least one management instruction; and if the configuration elements comprised in the first message comprise a setpoint for the propagation of the configuration elements in the network, a step of sending (E70, E120), by the first device in accordance with said propagation setpoint, at least one second control message (M1, M2) to at least one second device of the network, this second control message comprising all or part of the configuration elements comprised in the first message.

A system and method for a self-adapting SDWAN to ensure compliance with client requirements. A SDWAN performance analyzer continuously monitors all of the nodes within an SDWAN, receiving a plurality of operational data regarding operational parameters of each node. Based on the operational data, a machine learning algorithm is applied to develop a tree-structure representative of a desired network configuration, based on the real-time state of the network, to ensure compliance with client requirements. The SDWAN performance analyzer can generate configuration commands to send to one or more of the nodes in the SDWAN to reconfigure the operational parameters of the nodes in line with the desired network configuration.

A multi-port configuration system includes a network switch including a plurality of ports and a user device that is configured to couple to the network switch. Each of the plurality of ports is configured to operate in at least one of a plurality of modes. A congruent graphical representation of the network switch is displayed on the user device, and a selection of a group of ports of the plurality of ports is received. Based on the received selection of the group of ports, available configuration settings for the group of ports are displayed on the user device. A configuration settings selection, selected from the available configuration settings, for configuring the group of ports is received. The configuration settings selection is provided to the network switch to configure the group of ports.

A method of automatic setup by a first device of a session complying with a dynamic routing protocol with a second device. The setup method includes, subsequent to detection by the first device of existence of a connectivity with the second device, the first device being associated with a first autonomous system number and not knowing any autonomous system number associated with the second device: an exchange with the second device including announcement to the second device of the first autonomous system number, and discovery of a second autonomous system number with which the second device is associated; or allocation to the second device of a third autonomous system number and announcement to the second device of the third autonomous system number which has been allocated to it; and setup with the second device of a session according to the routing protocol by using the autonomous system numbers exchanged.

Techniques for automated analysis and classification of network configurations are provided. Resource provisioning code used to provision resources in a network is received, and a set of constraints is generated based on the resource provisioning code, where the set of constraints define valid network configurations. A configuration tree for the network is received, and a set of candidates is generated for the network based at least in part on the configuration tree. Upon determining that a first candidate of the set of candidates does not fail any constraint in the set of constraints, the first candidate is recorded as a manual intent. The manual intent is integrated into an automated configuration system for the network.

Some embodiments of the invention provide a method for deploying software-implemented resources in a software defined datacenter (SDDC). The method initially receives a hierarchical API command that, in a declarative format, specifies several operation requests for several software-defined (SD) resources at several resource levels of a resource hierarchy in the SDDC. The method parses the API command to identify the SD resources at the plurality of resource levels. Based on the parsed API command, the method deploys the SD resources by using a deployment process that ensures that any first SD resource on which a second SD resource depends is deployed before the second resource. In some embodiments, a second SD resource depends on a first SD resource when the second SD resource is a child of the first SD resource. Alternatively, or conjunctively, a second SD resource can also depend on a first SD resource in some embodiments when the second SD resource has some operational dependency on the first SD resource. In some embodiments, the method parses the API command by identifying several sets of SD resources, with each set having one or more SD resources at one resource level. The deployment in some embodiments deploys the identified SD resource sets at higher resource levels before deploying SD resources at lower resource levels.