An example method of displaying a data visualization includes displaying a plurality of selectable fields and receiving user selections of two different fields from the plurality of selectable fields. The method also includes generating, in accordance with the received user selections, data marks to be displayed in a data visualization, each data mark corresponding to a respective retrieved tuple of data from a multidimensional database, where (i) each data mark has an x-position defined according to data for a first field in the respective tuple and (ii) each data mark has a y-position defined according to data for a second field in the respective tuple. The method also includes displaying the data visualization that includes the generated data marks.

A method of displaying data visualizations includes retrieving a dataset from a multidimensional database, where the dataset includes a plurality of fields, including first and second fields, and the first field is a data hierarchy that includes multiple subfields. The method further includes displaying a GUI with a first region displaying the plurality of fields (with the first field in a collapsed state), a second region with a plurality of shelves, and a third region. In response to receiving a user action to display the first field in an expanded state, the method displays the first field and the multiple subfields in a hierarchical structure. The method receives additional user actions to: (i) associate a first subfield of the plurality with a first shelf, and (ii) associate the second field with a second shelf, and then displays, in accordance with the user actions, a data visualization in the third region.

Methods, systems, and computer-readable media storing instructions are described for receiving, at a first adapter on a first computer system, a first Enterprise Quality Management (EQM) communication configured to pass EQM data between the first computer system and a second computer system on the computer network, transforming the EQM communication into a standardized data format, transmitting the standardized first EQM communication to a second adapter resident on a second computer system, receiving a second EQM communication comprising EQM response data from the second adapter in response to the first EQM communication, the second EQM communication being transmitted by the second adapter in the standardized data format, determine whether the second EQM communication is interpretable by the first computer system, and transforming the second EQM communication into a data format interpretable by the first computer system when the second EQM communication is not interpretable by the second computer system.

Methods, systems, and computer-readable media storing instructions are described for receiving an Enterprise Quality Management (EQM) communication from a first computer system on the computer network, the EQM communication being transmitted in a first data format and being configured to pass EQM data between the first computer system and a second computer system on the computer network, determining whether the EQM communication is in a data format interpretable by the second computer system, transforming the EQM communication into a second data format interpretable by the second computer system based at least in part on a determination that the EQM communication is not in a data format interpretable by the second computer system, and transmitting the transformed EQM communication to the second computer system.

An example method of displaying a data visualization includes displaying a graphical user interface that includes three distinct regions, and receiving user actions to associate two different fields with two different shelves. The method also includes generating, in accordance with the received user actions, data marks to be displayed in a data visualization, each data mark corresponding to a respective retrieved tuple of data from a multidimensional database, where (i) each data mark has an x-position defined according to data for a first field in the respective tuple and (ii) each data mark has a y-position defined according to data for a second field in the respective tuple. The method also includes displaying a data visualization that includes the generated data marks.

A system and method for implementing functionality within a network on behalf of first and second devices communicating with each other through the network. A front-end device is provided within the network that communicates data traffic with the first device. A back-end device is also implemented within the network and communicates data traffic with the second device. A communication channel couples the front-end device and the back-end device. Data traffic may be encoded into a different type or protocol for transport through the communication channel by the front-end device and back-end device. The front-end device and back-end device exchange quality of service information and may alter characteristics of the data traffic through the communication channel according to the quality of service information.

An example method of displaying a data visualization includes displaying a graphical user interface that includes three distinct regions, and receiving user actions to associate two different fields with two different shelves. The method also includes generating, in accordance with the received user actions, data marks to be displayed in a data visualization, each data mark corresponding to a respective retrieved tuple of data from a multidimensional database, where (i) each data mark has an x-position defined according to data for a first field in the respective tuple and (ii) each data mark has a y-position defined according to data for a second field in the respective tuple. The method also includes displaying a data visualization that includes the generated data marks.

Methods, systems, and computer-readable media storing instructions are described for implementing bidirectional exchange of quality data using a common protocol. An exemplary method comprises generating, at a first party computer system, a connection request communication including data relating to a project and sending the connection request communication to a second party computer system. The method further comprises receiving, from the second party computer system, a registration change communication comprising the data relating to the project, sending a record communication including a quality object associated with the project to the second party computer system, and sending an update communication updating information in the quality object, the update communication being one of a state changing communication or a non-state changing communication. The connection request communication, the record communication, and the update communication are sent in a first format that the second party computer system cannot interpret without reformatting.

Provided is a method, system, and program for providing an object discovery agent (ODA) client. There is one object discovery agent (ODA) client and at least one ODA, wherein each ODA is associated with one application and includes: (i) application programming interfaces (APIs) to communicate with the associated application to discover definition information on objects maintained by the application and (ii) code to communicate with the ODA client. The ODA client communicates with one of the at least one ODA to cause the ODA to gather definition information on at least one object used by one application. The gathered object definition information is provided to an integration server to integrate the object in an environment including heterogeneous objects from different applications.

A method of displaying data visualizations includes retrieving a dataset from a multidimensional database, where the dataset includes a plurality of fields, including first and second fields, and the first field is a data hierarchy that includes multiple subfields. The method further includes displaying a GUI with a first region displaying the plurality of fields (with the first field in a collapsed state), a second region with a plurality of shelves, and a third region. In response to receiving a user action to display the first field in an expanded state, the method displays the first field and the multiple subfields in a hierarchical structure. The method receives additional user actions to: (i) associate a first subfield of the plurality with a first shelf, and (ii) associate the second field with a second shelf, and then displays, in accordance with the user actions, a data visualization in the third region.