A method includes positioning a first active region adjacent to a pair of second active regions in an initial integrated circuit (IC) layout diagram of an initial cell, to align side edges of the first active region and corresponding side edges of each second active region of the pair of second active regions along a cell height direction. The first active region forms, together with the initial cell, a modified cell having a modified IC layout diagram. The side edges of the first active region and the corresponding side edges of each second active region extend along the cell height direction. A height dimension of the first active region in the cell height direction is less than half of a height dimension of each second active region of the pair of second active regions in the cell height direction. The positioning the first active region is executed by a processor.

The present disclosure relates to a system and method for electronic design. Embodiments may include receiving, using at least one processor, a plurality of distinct electronic designs at an electronic design database and storing the plurality of distinct electronic designs at the electronic design database. Embodiments may further include receiving a request to reuse one of the plurality of distinct electronic designs from a client electronic device associated with a user, wherein the request includes design connectivity information, block connectivity information, and page connectivity information. Embodiments may also include analyzing the design connectivity information, block connectivity information, and page connectivity information to identify one or more closest matches with the plurality of distinct electronic designs and providing the one or more closest matches to the client electronic device to allow for subsequent displaying at a graphical user interface.

Systems and methods are disclosed for automated generation of integrated circuit designs and associated data. These allow the design of processors and SoCs by a single, non-expert who understands high-level requirements; allow the en masse exploration of the design-space through the generation processors across the design-space via simulation, or emulation; allow the easy integration of IP cores from multiple third parties into an SoC; allow for delivery of a multi-tenant service for producing processors and SoCs that are customized while also being pre-verified and delivered with a complete set of developer tools, documentation and related outputs. Some embodiments, provide direct delivery, or delivery into a cloud hosting environment, of finished integrated circuits embodying the processors and SoCs.

Systems or methods of the present disclosure may provide a library including multiple personas that may be pre-generated by a manufacturer and/or custom generated by a designer that may be used to implement a design onto an integrated circuit device. The design may be decomposed into one or more personas to be implemented as coarse-grained operations on the integrated circuit device, thereby decreasing compilation time experienced by the designer. The personas may be loaded into one or more regions of the integrated circuit device to realize the design. That is, the design may be realized by one persona may be implemented across multiple regions, one region may be configured by multiple personas, one persona configuring one region, or any combination thereof. Additionally or alternatively, the integrated circuit device may include networks-on-chip to improve data routing between the regions.

Embodiments are directed towards a configurable accelerator framework device that includes a stream switch and a plurality of convolution accelerators. The stream switch has a plurality of input ports and a plurality of output ports. Each of the input ports is configurable at run time to unidirectionally pass data to any one or more of the output ports via a stream link. Each one of the plurality of convolution accelerators is configurable at run time to unidirectionally receive input data via at least two of the plurality of stream switch output ports, and each one of the plurality of convolution accelerators is further configurable at run time to unidirectionally communicate output data via an input port of the stream switch.

Embodiments herein provide for reverse engineering of integrated circuits (ICs) for design verification. In example embodiments, an apparatus receives a gate-level netlist for an integrated circuit (IC), generates a list of equivalence classes related to signals included in the gate-level netlist, determines control signals of the gate-level netlist based at least in part on the list of equivalence classes, determines a logic flow of a finite state transducer (FST) based at least in part on the control signals, and generates register transfer level (RTL) source code for the IC based on the FST.

A non-transitory computer-readable recording medium storing a timing library creation program of causing a computer to execute processing, the processing including: extracting, from a delay variation database that stores delay variation values of gates included in circuit design data, a delay variation value, out of the delay valuation values matching to characteristics which are characteristics of one of signal paths in the circuit design data and which include a threshold voltage, a drive force, and a number of gate stages of the signal path; calculating an extended delay variation coefficient based on the extracted delay variation value and the characteristics; and creating, based on a basic timing library in which the delay variation value is not reflected and the extended delay variation coefficient, an extended timing library in which the delay variation value is reflected.

Integrated circuits (IC) are provided. An IC includes a plurality of macros and a top channel. Each macro includes a macro boundary and a main pattern surrounded by the macro boundary. The top channel includes a plurality of first and second sub-channels. Each first sub-channel is arranged between a first macro and a second macro, and is formed by a plurality of first dummy boundary cells. Each second sub-channel is arranged between two of the second macros, and is formed by a plurality of second dummy boundary cells. The macro boundaries of the first macros are formed by the first dummy boundary cells, and the macro boundaries of the second macros are formed by the second dummy boundary cells. A first gate length of dummy patterns within the first dummy boundary cells is greater than a second gate length of dummy patterns within the second dummy boundary cells.

Computer-implemented systems and methods for automatically generating an electronic circuit IP block are provided. The disclosed systems and methods maintain the process design rules (DRC Clean), connectivity (LVS Clean) correctness, and obey Reliability Verification (RV) and DFM (Design for Manufacturability) constraints, including time constraints. Exemplary systems and methods may include an electronic circuit layout generator and/or IP generator to obtain manufacturing processes and design rules from an external source, define a type of electronic circuit to be fabricated, prepare a circuit schematic of the defined electronic circuit, and generate an IP block for the defined electronic circuit based on the circuit schematic. A computer program generator is provided to create the defined electronic circuit. A computer readable storage medium contains processing instructions for obtaining the manufacturing processes and design rules and for fabricating the electronic circuit.

Systems and methods are disclosed for automated generation of integrated circuit designs and associated data. These allow the design of processors and SoCs by a single, non-expert who understands high-level requirements; allow the en masse exploration of the design-space through the generation processors across the design-space via simulation, or emulation; allow the easy integration of IP cores from multiple third parties into an SoC; allow for delivery of a multi-tenant service for producing processors and SoCs that are customized while also being pre-verified and delivered with a complete set of developer tools, documentation and related outputs. Some embodiments, provide direct delivery, or delivery into a cloud hosting environment, of finished integrated circuits embodying the processors and SoCs.