A server may receive from a software development kit (SDK) a channel identifier that represents an in-application communication channel of a software application that imports the SDK as part of the software application. In some cases, the software application is developed by a message publisher and the SDK is developed by the message management server. The server receives configuration data describing an in-application user interface (UI) element for display by the software application, the configuration data including a trigger condition for displaying the in-application UI element. The server transmits a message to the SDK via the in-application communication channel. The message includes the trigger condition from the configuration data for the in-application UI element. In response to the SDK determining that the trigger condition is satisfied, the server provides additional configuration data from the configuration data for the in-application UI element to the SDK.

A server may receive from a software development kit (SDK) a channel identifier that represents an in-application communication channel of a software application that imports the SDK as part of the software application. In some cases, the software application is developed by a message publisher and the SDK is developed by the message management server. The server receives configuration data describing an in-application user interface (UI) element for display by the software application, the configuration data including a trigger condition for displaying the in-application UI element. The server transmits a message to the SDK via the in-application communication channel. The message includes the trigger condition from the configuration data for the in-application UI element. In response to the SDK determining that the trigger condition is satisfied, the server provides additional configuration data from the configuration data for the in-application UI element to the SDK.

A software robot is designed to carry out an activity (e.g., a mouse click, a text input, etc.) on a target element (e.g., a button, an input field, etc.) of a user interface. The robot's code specification is configured to include an on-screen image of the target element and a text displayed by the target element. The robot is configured to automatically identify the target element at runtime according to an element ID specified in the source-code of the user interface, and when such identification fails, to identify the target element according to the text and image stored in the robot's code.

A software robot is designed to carry out an activity (e.g., a mouse click, a text input, etc.) on a target element (e.g., a button, an input field, etc.) of a user interface. The robot's code specification is configured to include an on-screen image of the target element and a text displayed by the target element. The robot is configured to automatically identify the target element at runtime according to an element ID specified in the source-code of the user interface, and when such identification fails, to identify the target element according to the text and image stored in the robot's code.

A multi-characteristic remeshing system that generates remeshed 3D graphical surfaces can include a compact geometric descriptive language (“CGDL”) conversion module, one or more geometric characteristic parsing modules, and a geometric computation module. The CGDL conversion module receives an input mesh for a 3D graphical object and CGDL source text that describes target characteristics of an output mesh of the 3D graphical object. Each geometric characteristic parsing module identifies inherent geometric characteristics of the input mesh, and generates a geometric characteristic map. The geometric characteristic map includes instructions to generate the output mesh with respective target characteristics. The instruction describes a relationship of the one or more inherent geometric characteristics with the respective target characteristic. The geometric computation module generates the output mesh with the target characteristics, based on the geometric characteristic maps from the geometric characteristic parsing modules.

In an embodiment, a data processing method comprises accessing a computer memory comprising a shareable cell-based computation notebook comprising: notebook metadata specifying a kernel for execution, and a computational cell comprising cell metadata, a source code reference, and an output reference, wherein the cell metadata identifies a particular version of source code of a function that defines an input dataset, a transformation, and one or more variables that are to be associated with output data that is to be generated as a result of executing the particular version of the source code; updating the source code reference to identify a first storage location that is to contain the particular version of the source code of the function; and updating the output reference to identify a second storage location that is to contain the output data that is to be generated as a result of executing the particular version of the source code identified in the cell metadata using the kernel specified in the notebook metadata, wherein the method is performed by one or more computing devices.

Rule data sets are received. These rule sets are associated with constraints controlling how records that are associated with the goods are consolidated. These goods are to be received for importing. An estimate score indicative of the risk for inspection for a first set of goods that are to be imported is generated. Based at least in part on the rule data sets and the generated estimate, a plurality of records are consolidated to a single instance for the first set of goods. Based on the consolidating, a user interface is caused to be generated that renders information associated with the consolidating.

Embodiments of a system and method are described for generating and distributing programming to mobile devices over a network. Devices are provided with Players specific to each device and Applications that are device independent. Embodiments include a full-featured WYSIWYG authoring environment, including the ability to bind web components to objects.

Programmer input in a first programming language is received, the programmer input including i) a built-in function of the first programming language, the built-in function corresponding to generating code for remotely invoking an electronic object deployed, or to be deployed, on a server via a communication network, and ii) a parameter that indicates the electronic object, wherein the code for invoking the electronic object comprises a) code in a second programming language different than the first programming language, or b) code in a markup language interpretable by a web browser. The programmer input is evaluated to: i) generate the code for remotely invoking the electronic object deployed, or to be deployed, on the server, and ii) if the electronic object is not yet deployed on the server, deploy the electronic object on the server. The code for remotely invoking the electronic object is generated for inclusion in a file corresponding to a web page or a program written in the second programming language.

In accordance with one embodiment, a method can be implemented that includes accessing a first data file associated with a first media application program, wherein the first data file includes a first identifier associated with a first designer-specified variable for controlling the first media application program; accessing a second data file associated with a second media application program, wherein the second data file includes a second identifier associated with a second designer-specified variable for controlling the second media application program; receiving with a computer processor the first designer-specified variable; receiving with the computer processor the second designer-specified variable.