VLSI
Open source VLSI design notes.
From Verilog/VHDL to GDSII for SKY or IHP technologies.
Prerequisites
These notes assume the host has Linux, e.g. Ubuntu 24.04 set up. All tools will be running under it.
Open Tools
Essential OSS HW design tools
- gtkwave - Waveform viewer
- iverilog - Icarus Verilog compiler
- Verilator - compile RTL to C++, faster simulations
- Yosys - RTL to gate level netlist
- SymbiFlow - Toolchain to FPGA
- Magic VLSI - transistor level layout design editor
- KLayout - viewer and editor of GDSII files
- OpenRoad - Automates floorplanning, placement, routing and timing.
- OpenLane - Automated design flow, from verilog to GDSII, uses the tools above.
Open Technology PDKs
Process development kits (PDK) available for OSS VLSI:
- SKY 130 PDK - Process Design Kit by Google and Efabless
- IHP SG13G2 PDK
- This is a 130nm BiCMOS process from the Leibniz Institute for High Performance Microelectronics, which generally offers higher performance (faster transitions) than Sky130.
- ReadTheDocs
- GlobalFoundries 180nm MCU (GF180MCU)
- A mature 180nm CMOS process with 5 layers of metal, widely used for analog and mixed-signal design. It is fully supported by Efabless for open-source shuttle programs.
- ASAP7 (Arizona State Academic Process)
- A 7nm predictive PDK used exclusively for academic research and educational purposes. It is often used for evaluating next-generation PnR flows (e.g., using Synopsys tools).
- SCMOS (Scalable CMOS)
- An older "Lambda-based" design rule set used before modern open foundry efforts, helpful for learning layout concepts, though not used for modern, high-performance silicon fabrication.
Tapeout
TinyTapeout: from idea/design to chip/PCB
Setup Openline2
9https://openlane2.readthedocs.io/en/latest/getting_started/installation_overview.html The advised path] is to setup NIX environment and then run openline2 from there, rather than using a dockerized version.
Install Nix
Set up the Nix environment:
sudo apt-get install -y curl curl --proto '=https' --tlsv1.2 -sSf -L https://install.determinate.systems/nix | sh -s -- install --no-confirm --extra-conf " extra-substituters = https://openlane.cachix.org extra-trusted-public-keys = openlane.cachix.org-1:qqdwh+QMNGmZAuyeQJTH9ErW57OWSvdtuwfBKdS254E= "
Make sure to close all terminals after you’re done with this step.
If have Nix already
nix-env -f "<nixpkgs>" -iA cachix sudo env PATH="$PATH" cachix use openlane sudo pkill nix-daemon
Install OpenLane 2 after Nix
git clone https://github.com/efabless/openlane2 nix-shell openlane --smoke-test
Other tools
There are many other tools you could setup separately, just know that openlane2 expects and is sensitive to the versions of the tools, and may not work if your tool is older or newer.
My local setup
This is how I use the Openlane2 tools after the setup.
One important note is that they generate MANY intermediate and log files in the "runs" directory under your project, every time you run openlane. Usually my project is mapped toa cloud drive such as Dropbox, and spamming it with tons of files may create confusion when receiving an email later that someone has deleted 2000+ files from your account. Therefore I save the runs locally, outside the project directory. To achieve that, I run the following commands:
cd git.local/openlane2
nix-shell
openlane --smoke_test # Sanity test for the tools (optional)
cd your/project/
run_openlane_local.sh config.json # will save run logs under work.local/... (recommended)
or
opennlane config.json # will save the run logs in the project directory work/... (cloud?!)
Usecase: Simple counter
Usecase: RAM integration
TODO.
Usecase: NeoRV32 MCU
NeoRV32 is an open source MCU with many peripheral options written in VHDL.
