Abstract: A unified data model for creating a circuit design for a heterogeneous integrated circuit is provided. The unified data model is stored as a data structure in computer hardware. The unified data model includes a unified netlist specifying the circuit design and a unified device model representing the heterogeneous integrated circuit. The unified netlist includes netlist objects configured to communicate over bitwise connections and network connections representing packet-based communications. The unified netlist may be mapped to the unified device model using computer hardware. Using the computer hardware, at least a portion of the device model may be displayed in coordination with at least a portion of the unified netlist mapped thereto.

Abstract: Examples herein describe techniques for generating dataflow graphs using source code for defining kernels and communication links between those kernels. In one embodiment, the graph is formed using nodes (e.g., kernels) which are communicatively coupled by edges (e.g., the communication links between the kernels). A compiler converts the source code into a bitstream and/or binary code which configures programmable and non-programmable logic in a heterogeneous processing environment of a SoC to execute the graph. The compiler can also consider user-defined constraints when compiling the source code. The constraints can dictate where the kernels and buffers should be placed in the heterogeneous processing environment, performance requirements, data communication routes through the SoC, type of data path, delays, and the like.

Abstract: For an application specifying a software portion for implementation within a data processing engine (DPE) array of a device and a hardware portion for implementation within programmable logic (PL) of the device, a logical architecture for the application and a first interface solution specifying a mapping of logical resources to hardware of an interface circuit block between the DPE array and the programmable logic are generated. A block diagram of the hardware portion is built based on the logical architecture and the first interface solution. An implementation flow is performed on the block diagram. The software portion of the application is compiled for implementation in one or more DPEs of the DPE array.

Abstract: For an application specifying a software portion for implementation within a data processing engine (DPE) array of a device and a hardware portion for implementation within programmable logic (PL) of the device, a logical architecture for the application and a first interface solution specifying a mapping of logical resources to hardware of an interface circuit block between the DPE array and the programmable logic are generated. A block diagram of the hardware portion is built based on the logical architecture and the first interface solution. An implementation flow is performed on the block diagram. The software portion of the application is compiled for implementation in one or more DPEs of the DPE array.

Abstract: Constraint handling for a circuit design may include determining, using a processor, instances of parameterizable modules of a circuit design associated with constraints based upon a predefined hardware description language attribute within the instances, extracting, using the processor, parameter values from the instances of the parameterizable modules, and generating, using the processor, static constraint files for the instances of the parameterizable modules using the extracted parameter values.

Abstract: A method is provided for exporting design constraints from a circuit design. In response to a first user command indicating a design constraint and a pattern, the design constraint is assigned to each object in the circuit design that matches the pattern, and the pattern is stored in a database. In response to a second user command to export design constraints of the circuit design, for each design constraint assigned to a respective set of objects of the circuit design, a pattern stored in the database that matches the respective set of the objects is determined and the design constraint is added to an export file in a format that uses the determined pattern. Design constraints on individual ones of the set of the objects indicated by the determined pattern are omitted from the export file.

Abstract: In one embodiment, a method for propagating design constraints between a module and a module instance in a circuit design is provided. A port of the module and a port/pin of the circuit design are determined, between which constraints are to be propagated. The determination of the port/pin includes determining whether or not pin of the module instance corresponding to the port is directly connected to a top-level port of the circuit design. In response to determining that the pin is directly connected to a top-level port, the top-level port is selected as the port/pin. In response to determining that the pin is not directly connected to the top-level port, the pin is selected as the port/pin. Design constraints are propagated between the port and the selected port/pin. The propagated design constraints are stored in a storage device.