Embodiments are for using design context projection and wire editing in augmented media. Responsive to receiving an indication of an error in a design for an integrated circuit (IC), a localized area is extracted encompassing the error in the design. Augmented reality media of the localized area of the design is generated with a guide pattern, the localized area including objects. The augmented reality media of the localized area is caused to be presented in a three-dimensional (3D) projection on an augmented reality device for a user. Responsive to receiving at least one modification to the augmented media in the 3D projection, the design for the IC is updated with the modifications.

A system enhances a system design to incorporate safety measures. The system receives a system design for processing through various stages of design using design tools, for example electronic design automation tools for introducing safety features in a circuit design. The system receives safety requirements for the system design, the safety requirements specifying safety measures for the system design. The system generates from the safety requirements, a safety specification storing a set of commands. The system generates a system design enhanced with safety measures. The enhanced system design it generated for at least a subset of the plurality of tools. A tool processes the generated safety specification to implement safety measures in the system design according to the received safety requirements.

A system enhances a system design to incorporate safety measures. The system receives a system design for processing through various stages of design using design tools, for example electronic design automation tools for introducing safety features in a circuit design. The system receives safety requirements for the system design, the safety requirements specifying safety measures for the system design. The system generates from the safety requirements, a safety specification storing a set of commands. The system generates a system design enhanced with safety measures. The enhanced system design it generated for at least a subset of the plurality of tools. A tool processes the generated safety specification to implement safety measures in the system design according to the received safety requirements.

Automated circuit and layout generation is disclosed. Various embodiments may include a computer system and/or method for generating a circuit layout comprising specifying a circuit schematic to be converted to a circuit layout, receiving a layout script associated with the circuit schematic, the layout script configured to position a plurality of layout instances generated from the circuit schematic, converting the circuit schematic into the plurality of layout instances; and positioning the plurality of layout instances based on the layout script to produce the circuit layout. A circuit may be produced by fabricating a circuit using the layout.

Automated circuit and layout generation is disclosed. Various embodiments may include a computer system and/or method for generating a circuit layout comprising specifying a circuit schematic to be converted to a circuit layout, receiving a layout script associated with the circuit schematic, the layout script configured to position a plurality of layout instances generated from the circuit schematic, converting the circuit schematic into the plurality of layout instances; and positioning the plurality of layout instances based on the layout script to produce the circuit layout. A circuit may be produced by fabricating a circuit using the layout.

A method includes generating a plurality of intermediate designs for a chip by executing a first sub-step based on a first plurality of inputs, adding at least one intermediate design of the plurality of intermediate designs to a second plurality of inputs, generating a plurality of final designs by executing a second sub-step of the step of the design flow based on the second plurality of inputs, and selecting using a machine learning model a final design from the plurality of final designs. The first sub-step is a sub-step of a step of a design flow and the first plurality of inputs corresponds to input parameters associated with the first sub-step.

A method includes generating a plurality of intermediate designs for a chip by executing a first sub-step based on a first plurality of inputs, adding at least one intermediate design of the plurality of intermediate designs to a second plurality of inputs, generating a plurality of final designs by executing a second sub-step of the step of the design flow based on the second plurality of inputs, and selecting using a machine learning model a final design from the plurality of final designs. The first sub-step is a sub-step of a step of a design flow and the first plurality of inputs corresponds to input parameters associated with the first sub-step.

A computer/software tool for electronic design automation (EDA) uses parasitic elements from a post-layout netlist (PLN) file for a given IC design to assess routing-imposed RC-based signal degeneration. The computer/software tool facilitates selection of, and insertion location for, one or more “virtual repeaters,” based on modification to the PLN file. The tool generates a visual display based on the calculated design characteristics, facilitating adjustment and optimization of repeater cell and location by the designer. The repeater insertion is “virtual,” because modeling and adjustment can be based on abstractions (e.g., load capacitance presented by a repeater) and the already-extracted netlist file, and because an actual circuit design need not be created until after a designer has fine-tuned repeater insertion parameters.

A computer/software tool for electronic design automation (EDA) uses parasitic elements from a post-layout netlist (PLN) file for a given IC design to assess routing-imposed RC-based signal degeneration. The computer/software tool facilitates selection of, and insertion location for, one or more “virtual repeaters,” based on modification to the PLN file. The tool generates a visual display based on the calculated design characteristics, facilitating adjustment and optimization of repeater cell and location by the designer. The repeater insertion is “virtual,” because modeling and adjustment can be based on abstractions (e.g., load capacitance presented by a repeater) and the already-extracted netlist file, and because an actual circuit design need not be created until after a designer has fine-tuned repeater insertion parameters.

A method for generating a circuit layout includes generating a plurality of symbols. Each of the plurality of symbols identifies one of multiple versions of code describing a circuit layout. The method also includes loading the plurality of symbols into a design platform used to compile the code describing the circuit layout. The design platform has evaluators for the multiple versions of the code. The method further includes generating the circuit layout described by the code using the design platform.