circt
amaranth
circt | amaranth | |
---|---|---|
6 | 7 | |
1,520 | 1,436 | |
2.1% | 1.3% | |
9.9 | 9.7 | |
5 days ago | 12 days ago | |
C++ | Python | |
GNU General Public License v3.0 or later | BSD 2-clause "Simplified" License |
Stars - the number of stars that a project has on GitHub. Growth - month over month growth in stars.
Activity is a relative number indicating how actively a project is being developed. Recent commits have higher weight than older ones.
For example, an activity of 9.0 indicates that a project is amongst the top 10% of the most actively developed projects that we are tracking.
circt
-
Ask HN: How to get a job as a compiler engineer?
MLIR (https://mlir.llvm.org/) is a quickly growing compiler toolkit which attempts to synthesize the learnings of LLVM and currently powers compilers for programming languages, machine learning and circuit design (https://github.com/llvm/circt). and there are a ton of companies with real employees working on it (including Microsoft) and MLIR is at the core of Chris Lattner’s new company, ModularAI. I’d recommend taking a look at it, there are a large number of ways to get involved and a number of paths from contributor to employee.
-
Rapid Open Hardware Development (ROHD) Framework by Intel
Might be good to target the CIRCT infrastructure at some point.
-
TSMC eyes Germany for first European chip production plant
Even small optimizations like removing unused pins from internal modules are often times opposed.
Chris Lattner and others are currently working on an "industry" version of firrtl as part of the CIRCT hardware compiler framework: https://github.com/llvm/circt
-
Chisel/Firrtl Hardware Compiler Framework
Did you see the work being done on CIRCT? https://github.com/llvm/circt
I remember one of the reasons you did not want to use firrtl was that its compiler is implemented in Scala and thus hard to integrate into other projexts. CIRCT will solve that problem by providing a firrtl compiler implemented in C++. Other languages like Verilog/VHDL and new high level languages for HLS-like designs are also on the todo list.
- Julia Receives DARPA Award to Accelerate Electronics Simulation by 1,000x
-
VHDL backend
Relevant: https://github.com/llvm/circt
amaranth
-
Why are there only 3 languages for FPGA development?
He probably meant Amaranth.
-
VRoom A high end RISC-V implementation
As an aside, the latest and active development of nMigen has been rebranded a few months ago to Amaranth and can be found here: https://github.com/amaranth-lang/amaranth . In case people googled nMigen and came to the repository that hasn't been updated in two years.
- NMigen – A Python toolbox for building complex digital hardware (FPGAs)
-
Facts every web dev should know before they burn out and turn to painting
Hmm. A followup question: are there any cheats/hacks that would make it possible (if painful) to for example explore the world of USB3, PCIe, or Linux on low-end-ish ARM (eg https://www.thirtythreeforty.net/posts/2019/12/my-business-c..., based on the 533MHz https://linux-sunxi.org/F1C100s), without needing to buy equipment in the mid-4-figure/low-5-figure range, if I were able to substitute a statistically larger-than-average amount of free time (and discipline)?
For example, I learned about https://github.com/GlasgowEmbedded/glasgow recently, a bit of a niche kitchen sink that uses https://github.com/nmigen/nmigen/ to lower a domain-specific subset of Python 3 (https://nmigen.info/nmigen/latest/lang.html) into Verilog which then runs on the Glasgow board's iCE40HX8K. The project basically makes it easier to use cheap FPGAs for rapid iteration. (The README makes a point that the synthesis is sufficiently fast that caching isn't needed.)
In certain extremely specific situations where circumstances align perfectly (caveat emptor), devices like this can sometimes present a temporary escape to the inevitable process of acquiring one's first second-hand high-end oscilloscope (fingers-crossed the expensive bits still have a few years left in them). To some extent they may also commoditize the exploration of very high-speed interfaces, which are rapidly becoming a commonplace principal of computers (eg, having 10Gbps everywhere when USB3.1 hits market saturation will be interesting) faster than test and analysis kit can keep up (eg to do proper hardware security analysis work). The Glasgow is perhaps not quite an answer to that entire statement, but maybe represents beginning steps in that sort of direction.
So, to reiterate - it's probably an unhelpfully broad question, and I'm still learning about the field so haven't quite got the preciseness I want yet, but I'm curious what gadgetry, techniques, etc would perhaps allow someone to "hack it" and dive into this stuff on a shoestring budget? :)
-
Awesome Lattice FPGA Boards
Worth knowing that are two "nmigen"s nowadays - the one originated in M-Labs and one under a project also called nmigen:
https://github.com/nmigen/nmigen
It's a fork, made for reasons, but more actively developed. whitequark (long time author/contributor) works on this fork, and no longer the M-Labs version.
- Chisel/Firrtl Hardware Compiler Framework
-
Unifying the CUDA Python Ecosystem
Sounds like nmigen might be a good open source successor to the project that you describe: https://github.com/nmigen/nmigen
What are some alternatives?
SpinalHDL - Scala based HDL
chisel - Chisel: A Modern Hardware Design Language
cocotb - cocotb, a coroutine based cosimulation library for writing VHDL and Verilog testbenches in Python
hdlConvertor - Fast Verilog/VHDL parser preprocessor and code generator for C++/Python based on ANTLR4
torch-mlir - The Torch-MLIR project aims to provide first class support from the PyTorch ecosystem to the MLIR ecosystem.
chiselverify - A dynamic verification library for Chisel.
mlir-aie - An MLIR-based toolchain for AMD AI Engine-enabled devices.
myhdl - The MyHDL development repository
pygears - HW Design: A Functional Approach