5.2. Core Hammer

Hammer is a physical design flow which encourages reusability by partitioning physical design specifications into three distinct concerns: design, CAD tool, and process technology. Hammer wraps around vendor specific technologies and tools to provide a single API to address ASIC design concerns. Hammer allows for reusability in ASIC design while still providing the designers leeway to make their own modifications.

For more information, read the Hammer paper and see the GitHub repository and associated documentation.

Hammer implements a VLSI flow using the following high-level constructs:

5.2.1. Actions

Actions are the top-level tasks Hammer is capable of executing (e.g. synthesis, place-and-route, etc.)

5.2.2. Steps

Steps are the sub-components of actions that individually addressable in Hammer (e.g. placement in the place-and-route action).

5.2.3. Hooks

Hooks are modifications to steps or actions that are programmatically defined in a Hammer configuration.

5.3. Configuration (Hammer IR)

To configure a Hammer flow, supply a set yaml or json configuration files that chooses the tool and technology plugins and versions as well as any design specific configuration options. Collectively, this configuration API is referred to as Hammer IR and can be generated from higher-level abstractions.

The current set of all available Hammer APIs is codified here.

5.4. Tool Plugins

Hammer supports separately managed plugins for different CAD tool vendors. You may be able to acquire access to the included Cadence, Synopsys, and Mentor plugins repositories with permission from the respective CAD tool vendor. The types of tools (by Hammer names) supported currently include:

  • synthesis

  • par

  • drc

  • lvs

  • sram_generator

  • sim

  • power

  • pcb

Several configuration variables are needed to configure your tool plugin of choice.

First, select which tool to use for each action by setting vlsi.core.<tool_type>_tool to the name of your tool, e.g. vlsi.core.par_tool: "innovus".

Then, point Hammer to the folder that contains your tool plugin by setting vlsi.core.<tool_type>_tool_path. This directory should include a folder with the name of the tool, which itself includes a python file __init__.py and a yaml file defaults.yml. Customize the version of the tool by setting <tool_type>.<tool_name>.version to a tool specific string.

The __init__.py file should contain a variable, tool, that points to the class implementing this tool. This class should be a subclass of Hammer<tool_type>Tool, which will be a subclass of HammerTool. The class should implement methods for all the tool’s steps.

The defaults.yml file contains tool-specific configuration variables. The defaults may be overridden as necessary.

5.5. Technology Plugins

Hammer supports separately managed technology plugins to satisfy NDAs. You may be able to acquire access to certain pre-built technology plugins with permission from the technology vendor. Or, to build your own tech plugin, you need at least a <tech_name>.tech.json and defaults.yml. An __init__.py is optional if there are any technology-specific methods or hooks to run.

The ASAP7 plugin is a good starting point for setting up a technology plugin because it is an open-source example that is not suitable for taping out a chip. Refer to Hammer’s documentation for the schema and detailed setup instructions.

Several configuration variables are needed to configure your technology of choice.

First, choose the technology, e.g. vlsi.core.technology: asap7, then point to the location with the PDK tarball with technology.<tech_name>.tarball_dir or pre-installed directory with technology.<tech_name>.install_dir and (if applicable) the plugin repository with vlsi.core.technology_path.

Technology-specific options such as supplies, MMMC corners, etc. are defined in their respective vlsi.inputs... configurations. Options for the most common use case are already defined in the technology’s defaults.yml and can be overridden by the user.