rocket-chip
chipyard
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rocket-chip | chipyard | |
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12 | 5 | |
3,002 | 1,428 | |
2.1% | 4.3% | |
8.3 | 9.7 | |
7 days ago | 1 day ago | |
Scala | Scala | |
GNU General Public License v3.0 or later | BSD 3-clause "New" or "Revised" License |
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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.
rocket-chip
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Recommendations for RISC-V on FPGA
Hello. I'm looking into implementing RISC-V on an FPGA for a school project. The two repos I'm looking into using are the Ariane and RocketChip repos. Both look actively maintained, but RocketChip has more recent releases, and it's used by this other repo that creates a block design in Vivado with the RISC-V RTL. However, we would also like to be able to make changes to the core, and I'm afraid that scala/Chisel might be difficult to learn. Ariane looks like SystemVerilog while RocketChip is mostly Chisel. Does any have recommendations on which RISC-V repo would be good to use for a project?
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RISC-V Pushes into the Mainstream
You could do a trial build of an in-order Rocket RISC-V core [1] to see how much space it takes up.
[1] https://github.com/chipsalliance/rocket-chip
- Can anyone explain simply how OpenSource the RISC-V actually is?
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Stages of prototyping a RISC-V processor on an FPGA?
My definition of a RISC CPU is one that has a reduced instruction set. In other words, the category of CPU is defined by the size of the instruction set, not in how it is implemented. Consider for example RISC-V CPUs. These are defined by their open instruction set alone, in spite of the fact that many implementations of RISC-V CPUs exist: some pipelined, and some not.
- FPGA for RISC-V Processor
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How are modern processors and their architecture designed?
More complex CPUs are typically completely out of scope for hand coding, therefore you can implement generators like: https://github.com/chipsalliance/rocket-chip
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Anandtech: "IBM Power10 Coming To Market: E1080 for 'Frictionless Hybrid Cloud Experiences'"
We don't have Sifive's specifically but we do have the open source cores they've historically used to design their cores: https://github.com/riscv-boom/riscv-boom https://github.com/chipsalliance/rocket-chip
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Project ideas for RISC-V?
This would allow you to experiment with your own chip or something like [the RocketChip generator](https://github.com/chipsalliance/rocket-chip).
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Question: Does the 32bit version of Rocket still supports FPU
https://github.com/chipsalliance/rocket-chip/blob/c7da610430f51b02ebda37f3d444674dc8f2adbf/src/main/scala/system/Configs.scala#L28
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The First Affordable RISC-V Computer Designed to Run Linux
I don't know about the u74 specifically, but sifive does seem to invest in a open source risc-v core called rocket-chip.
chipyard
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Chisel: A Modern Hardware Design Language
It's probably true that Chisel isn't right for industry -- Google tried it too for the TPU project and eventually went back to Verilog. That said, I think it's main win is that it is great from a research / open-source perspective.
Taking advantage of the functional nature of Chisel enables a set of generators called Chipyard [0] for things like cores, networking peripherals, neural network accelerators, etc. If you're focusing on exploring the design space of one particular accelerator and don't care too much about the rest of the chip, you can get a customized version of the RTL for the rest of your chip with ease. All the research projects in the lab benefit from code changes to the generators.
Chisel even enables undergraduate students (like me!) to tape out a chip on a modern-ish process node in just a semester, letting Chisel significantly reduce the amount of RTL we have to write. Most of the remaining time is spent working on the actual physical design process.
[0]: https://github.com/ucb-bar/chipyard
[1]: https://classes.berkeley.edu/content/2023-Spring-ELENG-194-0...
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A repository that tracks upstream but allows separate tracking.
The repo in question is chipyard: https://github.com/ucb-bar/chipyard
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Ao486_MiSTer: i486 core for the MiSTer FPGA gaming system
Many companies do just write entire modern SoCs in straight Verilog (maybe with some autogenerated Verilog hacked in there) with no other major organization tools aside from the typical project management stuff. The load-store unit of a modern CPU alone easily exceeds 10k lines of Verilog. It's a similar thing as people who work with kernels—after all, the page table management code in a modern operating system like Linux is absolutely monstrous but still people are able to understand it well enough to be able to make the changes they need and get out.
If you are interested in other languages which hope to make this sort of stuff easier, I'd recommend taking a look at design productivity languages like Chisel and it's associated Chipyard [1], SpinalHDL [2], and Bluespec [3]. Each of these are meant to make defining extremely complex hardware more manageable for humans and there's a lot of interesting work going on right now with each of them.
[1] https://github.com/ucb-bar/chipyard
[2] https://github.com/SpinalHDL/SpinalHDL
[3] https://github.com/B-Lang-org/bsc
- Chipyard: An Open Source RISC-V SoC Design Framework
- How to use a RISC V core for other purposes?
What are some alternatives?
riscv-boom - SonicBOOM: The Berkeley Out-of-Order Machine
vivado-risc-v - Xilinx Vivado block designs for FPGA RISC-V SoC running Debian Linux distro
openlane - OpenLane is an automated RTL to GDSII flow based on several components including OpenROAD, Yosys, Magic, Netgen and custom methodology scripts for design exploration and optimization.
neorv32 - :rocket: A tiny, customizable and extensible MCU-class 32-bit RISC-V soft-core CPU and microcontroller-like SoC written in platform-independent VHDL.
picorv32 - PicoRV32 - A Size-Optimized RISC-V CPU
skywater-pdk - Open source process design kit for usage with SkyWater Technology Foundry's 130nm node.
RVVM - The RISC-V Virtual Machine
fusesoc - Package manager and build abstraction tool for FPGA/ASIC development
nuclei-sdk - Nuclei RISC-V Software Development Kit
opentitan - OpenTitan: Open source silicon root of trust
shecc - A self-hosting and educational C optimizing compiler