A computer control-plane network controller proactively distributes network resources to network agents (nodes), on-demand, in a dynamic networking environment, based on threshold crossing events reported to the network controller by the nodes. A network agent has a local pool of resources, such as floating IP addresses and TCP/UDP ports, allocated to the network agent by the network controller. As workload assigned to an agent varies, the agent may use correspondingly varying amounts of resources in the local pool to process the workload. An agent reports resource utilization in processing workloads by sending messages to the network controller based on actual resource usage triggered by predefined threshold crossing events. The controller responds to the messages by reclaiming resources from agents reporting a surplus of resources, and re-allocating the resources to agents reporting a deficiency of resources.

The present disclosure relates to systems, non-transitory computer-readable media, and methods for dynamically updating the connection pool for a web server without any interruption to the resource. In particular, in one or more embodiments, the disclosed systems can continuously monitor load data for various web servers. Further, the disclosed systems can utilize load data, historical load data, and/or user settings to predict a number of connections over a future time period and can determine an updated connection pool size for a web server based on that predicted number of connections. The disclosed systems can also dynamically modify the connection pool size for the web server based on the updated connection pool size without interrupting the resource or any of its ongoing connections in any way.

Disclosed is a domain name bandwidth adjustment method and apparatus, wherein the method includes: determining whether a CDN system triggers a bandwidth speed limiting policy, if yes, determining a to-be-limited domain name from domain names served by the CDN system, and executing the bandwidth speed limiting policy on the target domain name; when the bandwidth speed limiting policy is being executed, determining an initial reference bandwidth of the target domain name, and comparing the initial reference bandwidth with an actual bandwidth of the target domain name within a specified observation duration, to determine whether to perform step adjustment on the initial reference bandwidth and determine whether to release the bandwidth speed limiting policy. In the technical solutions provided in the present disclosure, the bandwidth of the target domain name can be effectively controlled, and the bandwidth of the target domain name can be prevented from rising again.

Systems and methods for continuous evaluation of workspace definitions using endpoint context. In some embodiments, an Information Handling System (IHS) of a workspace orchestration service may include a processor and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution by the processor, cause the IHS to: receive context information from a local management agent of a client device; in response to the context information indicating that a current workspace provided via the local management agent is over-privileged, modify a current workspace definition into a modified workspace definition, where the modified workspace definition outlines fewer resources than the current workspace definition; and transmit, to the local management agent, one or more files configured to enable the local management agent to modify the current workspace based upon the modified workspace definition to reduce a number of resources available to a user of the client device.

Embodiments of the present application provide a method and apparatus for bandwidth adjustment, an electronic device and a computer-readable storage medium. The method comprise obtaining an overload node; determining whether an overload bandwidth of the overload node is greater than a total available bandwidth amount of all target nodes for the overload node; if not, determining the overload node as a to-be-adjusted node and determining a to-be-adjusted bandwidth amount of the to-be-adjusted node based on the overloaded bandwidth of the overload node; decreasing a total carrying bandwidth amount of the to-be-adjusted node by the to-be-adjusted bandwidth amount corresponding to the to-be-adjusted node, and increasing a total target carrying bandwidth amount of the to-be-adjusted node by the to-be-adjusted bandwidth amount corresponding to the to-be-adjusted node. By applying the method provided by the embodiments of the present application, the bandwidth can be adjusted more accurately.

A data rate management system that provides quality of service at the fine granularity of applications in the home network and home automation environment is provided. An application can be associated with a dynamic traffic flow, a physical port, a logical interface, or a host computer or device. Virtual queueing is applied to isolate and protect individual applications. Comprehensive rate management algorithms are developed to offer the bandwidth guarantee for the applications individually. The data rate management system includes a traffic classifier, virtual queueing, and a rate manager. The traffic classifier can statically or dynamically identify an application. The identified application is stored in a dedicated virtual queue. The rate manager schedules the packet transmission among virtual queues using the application-based traffic profiles.

A computer-implemented method and system for workload scheduling based on localizing virtual computing resources. The computer implemented method includes, in one embodiment, localizing a first computing resource having a workload under execution, the first computing resource being associated with a set of virtual computing resources. An embodiment includes rescheduling, responsive to the localizing, the workload for execution at least partially at a second computing resource in the set of virtual computing resources.

A method for physically displaying and manipulating a communication network through physical objects and an interactive display includes: positioning, on a surface of an interactive display screen, a plurality of physical objects, each representing a node in a communication network; displaying a topography of the communication network including at least a plurality of nodes, where each node represented by a physical object is displayed beneath the respective physical object, and where open communication channels between nodes are visually displayed on the screen; receiving a physical gesture performed by a user between two of the plurality of physical objects; transmitting a signal to one of the physical objects or an access point of the communication network causing manipulation of the communication network based on the physical gesture; and updating the displayed topography of the communication network based on the manipulation of the communication network in real-time.

A bursty traffic allocation method includes: receiving statistical data sent by a proxy server deployed in a service node, where the statistical data is used to characterize an operating state of the service node and/or one or more physical machines in the service node; determining whether there is a bursty condition in a target service, and if there is a bursty condition in the target service, generating a resource scheduling task matching the service node based on the statistical data; feeding back the resource scheduling task to the proxy server, to allow the proxy server to expand a physical machine in the service node according to a resource amount specified in the resource scheduling task; and receiving a resource expansion message fed back by the proxy server for the resource scheduling task, and pulling bursty traffic of the target service to a physical machine specified in the resource expansion message.

Embodiments relate to a software-defined networking (SDN) single-source enterprise workload manager. An aspect includes analyzing, by an enterprise server executing a workload compiler, a plurality of source code files of a workload during a workload compilation and build process to determine enterprise network connections between a plurality of subprograms of the workload as a plurality of compile-time information of the workload. The workload compiler generates a network flow graph as interactions between the subprograms of the workload in the enterprise network responsive to the compile-time information of the workload. The network flow graph is provided to an SDN controller to make network resource allocations for the workload based on the network flow graph. A workload manager of the enterprise server adjusts an allocation of compute resources based on a notification of a reallocation of network resources made by the SDN controller.