Techniques are described for providing a simultaneous, multi-device user experience for one or more users, on computing devices that include different capabilities for data input and/or data output. A user may register multiple devices with a service, and the service may determine capabilities of the devices for data input and data output. During a communication session involving the user and another user, such as a service representative, the service may receive input data collected through one or more devices and/or provide output data to be presented on one or more devices, where such data input and data output is received and provided according to the various input/output capabilities of the various devices. The data input and/or data output may switch from device to device during a session. In some instances, data may be replicated for presentation through multiple devices simultaneously.

In some implementations, a computing device can test the client-side rendering capabilities of a map module running on a computing device. For example, the map module can include a test module that sends test data to a rendering module of the browser. The rendering module can render the test data into a rendering context based on the test data. The test module can compare the pixel data in the rendering context to expected pixel data to determine whether the rendering module is capable of accurately rendering an image based on the test data. If the rendering module is capable of accurately rendering the rendering context based on the test data, the map module can be configured to perform client-side rendering of images. For example, the map module can be configured to perform client-side rendering of map data based on map data received from a map server.

Techniques for redirecting a client device from a server to a mini-server are disclosed herein. Initially, the client device establishes a connection with the server. The server provides a landing page to the client device, where the landing page is programmed to include an element that, when selected, redirects the client device away from its connection with the server. In response to a selection of the element, the client device establishes a connection with the mini-server. The mini-server is part of a first local area network (LAN), and, as a result of switching networks, the client device is now a part of a second LAN. The two LANs are connected to one another via a network bridge. The mini-server is able to receive input from the client device and synchronize that input across other mini-servers in the first LAN in order to redundantly store the input.

A computer-implemented method is provided that includes receiving, from a first client device associated with a managed network, a request for a record from a plurality of records that relate to the managed network. A depiction of a first graphical user interface that visually represents part of the record is sent to the first device and a representation of a selected portion of the record, that includes text from the part of the record that was visually represented, is received from the first device. A request for the summary of the record is then received from a second client device associated with the managed network and a depiction of a second graphical user interface that visually represents the summary of the record is transmitted to the second device. The depiction of the second graphical user interface is representative of at least the selected portion.

Disclosed herein includes a system, a method, and a device for credential control among a plurality of client devices. A server can receive a modification to a credential for an identifier associated with a user of an application accessed via a first client device. The credential can be used for authenticating to the application by the user. The server can store the modification to the credential to a login history for the user. The login history can identify client devices and one or more applications accessed via the client devices by the user using the credential. The server can identify, using the login history, client devices through which applications are accessed by the user using the credential. The server can communicate the modification to the credential to the client devices to indicate to the user to update the credential using the modified credential on each of the client devices.

The described technology is generally directed towards transporting data out of isolated network environments. According to an embodiment, a system can comprise a processor, and a memory that stores executable instructions that, when executed by the processor, facilitate performance of operations, that include receiving a request string comprising request data related to a request from a first application of a device. The operations further include intercepting a processing of the request string, and based on the intercepting, extracting usage data of a second application of the device encoded in the request string, wherein the usage data is unrelated to the request.

Systems and methods are provided for automatic network scaling for data centers. One of the methods comprises storing respective configurations of a plurality of interconnectors, wherein each interconnector is in communication with a respective plurality of servers in a respective rack and a respective top-of-rack switch, and wherein each configuration describes connections between the respective servers and the respective top-of-rack switch, determining a traffic load of each interconnector, and transferring traffic between interconnectors having compatible configurations according to the traffic loads.

A method comprises creating template limited-administration ontologies, the template limited-administration ontologies each identifying a plurality of different managers, each of the different managers having distinct and limited system access privileges. A request is received for a limited-administration server system, the request being associated with a client entity. A particular template limited-administration ontology of the template limited-administration ontologies is selected based on the request. A deployment ontology is generated based on the particular template limited-administration ontology and the request. A limited-administration server system deployment package is generated based on the deployment ontology. The limited-administration server system deployment package is provided for execution, wherein execution of the limited-administration server system deployment package creates a limited-administration server system, the limited-administration server system being capable of controlling access to one or more other systems associated with the client entity, and the limited-administration server system being limited to administration according to the different managers.

Server and methods for performing synchronization and resynchronization of networking information with client devices. During standard operations, client networking data discovered by a given client device are received by the server from the given client device, stored by the server, and forwarded by the server to other client devices. Client networking data from the other client devices received and stored by the server are forwarded to the given client device. Upon occurrence of a pre-defined event at the given client device preventing exchange of information between the given client device and the server, a resynchronization of the client networking data is performed between the given client device and the server. The synchronization and resynchronization mechanisms are based on unique version numbers respectively generated by the server and the given client device.

Described herein is a system and method for testing a computing device, such as a server, to minimize network impact. A computing device that is new or needs to be evaluated, such as an edge server, in a content delivery network may be determined and a sibling edge server which shares a common characteristic with the edge server may be selected. Requests received on the sibling edge server may be collected and filtered to determine a subset of the requests. The subset of the requests are transmitted to the edge server for processing and evaluation.