RISCBoy 是一款从零开始设计的开源便携式游戏机。
RISCBoy is an open-source portable games console, designed from scratch

原始链接: https://github.com/Wren6991/RISCBoy

RISCBoy 是一款开源的定制化便携式游戏机,旨在利用现代 RISC-V 架构复刻 2001 年代的掌机体验。它配备了定制的 RV32IMC 兼容 CPU、光栅图形流水线以及完整的芯片基础设施,所有组件均采用可综合的 Verilog 2005 语言编写。 该项目专为 iCE40-HX8k FPGA 设计,在性能与严苛的硬件限制之间取得了平衡,并使用 Icestorm 等开源工具链进行综合。处理器架构已通过 RISC-V 一致性测试和形式验证套件的验证,确保了其 RV32IMC 指令集的高可靠性。 项目仓库包含了完整的 KiCad PCB 布局、仿真脚本,以及总线结构、内存控制器和外设的模块化 HDL 源代码。RISCBoy 既是一款功能性的复古游戏设备,也是开源 FPGA 开发的技术展示平台。项目为 Linux 环境提供了详尽的文档和构建说明,使用户能够为各种 FPGA 开发板综合逻辑门电路。

```Hacker News最新 | 过往 | 评论 | 提问 | 展示 | 招聘 | 提交登录RISCBoy 是一款从零开始设计的开源便携式游戏机 (github.com/wren6991) 8 分,由 mariuz 发布于 1 小时前 | 隐藏 | 过往 | 收藏 | 1 条评论帮助 iFire 18 分钟前 [–] RISCBoy 能运行 Godot 引擎吗?我该如何让 RISCBoy 运行 Godot 引擎?回复 指导方针 | 常见问题 | 列表 | API | 安全 | 法律 | 申请 YC | 联系 搜索: ```
相关文章

原文

RISCBoy is an open-source portable games console, designed from scratch. This includes:

  • A RISC-V compatible CPU
  • A raster graphics pipeline and display controller
  • Other chip infrastructure: busfabric, memory controllers, UART, GPIO etc.
  • A PCB layout in KiCad

It is a Gameboy Advance from a parallel universe where RISC-V existed in 2001. A love letter to the handheld consoles from my childhood, and a 3AM drunk text to the technology that powered them.

The design is written in synthesisable Verilog 2005, and is intended to fit onto an iCE40-HX8k FPGA. This is a LUT4-based FPGA with 7680 logic elements, so fitting a 32 bit games console requires a crowbar and some vaseline, or perhaps just careful design. The HX8k was once the largest FPGA targeted by the open-source Icestorm FPGA toolchain, but that toolchain has since moved on to greater things.

More detailed information can be found in the documentation.

The processor supports the RV32IMC instruction set, and passes the RISC-V compliance suite for these instructions, as well as the riscv-formal verification suite, and some of my own formal property checks for instruction frontend consistency and basic bus compliance. It also supports M-mode CSRs, exceptions, and a simple compliant extension for vectored external interrupts.

This repository uses submodules for HDL as well as tests

git clone --recursive https://github.com/Wren6991/RISCBoy.git riscboy

Alternatively

git clone https://github.com/Wren6991/RISCBoy.git riscboy
cd riscboy
git submodule update --init --recursive

Note a recursive submodule update is required to run the processor's standalone tests. This is not necessary for building RISCBoy gateware.

Building RV32IMC Toolchain

The RV32IMC toolchain is required for compilation of software-based tests. Follow the instructions on the RISC-V GNU Toolchain GitHub, except for the configure line:

# Prerequisites for Ubuntu 20.04
sudo apt install -y autoconf automake autotools-dev curl python3 libmpc-dev libmpfr-dev libgmp-dev gawk build-essential bison flex texinfo gperf libtool patchutils bc zlib1g-dev libexpat-dev
cd /tmp
git clone --recursive https://github.com/riscv/riscv-gnu-toolchain
cd riscv-gnu-toolchain
# The ./configure arguments are the most important difference
./configure --prefix=/opt/riscv --with-arch=rv32imc --with-abi=ilp32 --with-multilib-generator="rv32i-ilp32--;rv32ic-ilp32--;rv32im-ilp32--;rv32imc-ilp32--"
sudo mkdir /opt/riscv
sudo chown $(whoami) /opt/riscv
make -j $(nproc)

On smaller FPGAs, like the iCE40 UP5k, RISCBoy may be configured to use a smaller RV32I variant of the processor, rather than the higher-performance RV32IMC version. The compiler will support any of the ISA variants available on RISCBoy, but we must also instruct the toolchain build scripts to produce standard libraries for these variants, via the --with-multilib arguments. Running a RV32I executable linked against an RV32IMC standard library on an RV32I-only processor will ruin your day!

The simulation flow is driven by Xilinx ISIM 14.x; makefiles are found in the scripts/ folder. This has only been tested with the Linux version of ISIM.

You will also need to checkout the RISC-V compliance suite in order to run these tests (note the -- test is required to stop git from looking in the KiCad directories and complaining about the library structure there).

$ git submodule update --init --recursive

Once this is ready, you should be able to run the following:

. sourceme
cd test
./runtests

which will run all of the HDL-level tests. Software tests will require the RV32IC toolchain. You may need to adjust some of the paths in sourceme if ISIM is installed in a non-default location. To graphically debug a test, run its makefile directly:

cd system
make TEST=helloworld gui

The image shows the Rev A PCB. It is compatible with iTead's 4-layer 5x5 cm prototyping service, which currently costs $65 for 10 boards.

The schematic can be viewed here (pdf)

Rev B will look quite different; I am waiting for the gateware and bootloader to mature before proceeding. My current dev hardware looks a lot like my Snowflake FPGA board.

FPGA synthesis for iCE40 uses an open-source toolchain. If you would like to build this project using the existing makefiles, you will first need to build the toolchain I used:

Note that I have only built these on Linux. I've heard it is possible to build these on Windows, but haven't tried it. However, they can be built on a Raspberry Pi, which is neat.

Once the toolchain is in place, run

. sourceme
cd synth
make -f HX8k-EVN.mk bit

to generate an FPGA image suitable for Lattice HX8k evaluation board.

There is also highly experimental support (i.e. not my main dev platform) for ECP5, with board files for the Lattice LEF5UM5G-85F-EVN evaluation board:

make -f ECP5-EVN.mk BUILD=full bit

This build replaces the external, 512 kiB, 16 bit wide SRAM of RISCBoy development hardware with an internal, 256 kiB, 32 bit wide synchronous memory, which Trellis builds out of ECP5 sysmem blocks.

  • board: KiCad files for main RISCBoy PCB and other small boards used during development
  • doc: LaTeX source and diagrams for documentation, and the most recently built PDF
  • hdl: The Verilog source for RISCBoy gateware.
    • busfabric: AHB-lite crossbar and APB peripheral fabric
    • graphics: Source for the pixel processing unit
    • hazard5: Source for the RISC-V processor. This is completely self-contained.
    • mem: Memory controllers, and inference/injection wrappers and models for the memories themselves
    • peris: Small peripherals such as UART, SPI, PWM
    • riscboy_core: Structural module to instantiate and connect the components that comprise RISCBoy
    • riscboy_fpga: Top-level wrappers for a few different FPGAs and boards: connect up IOs, provide clock and reset
  • reference: a few PDFs for standards used in RISCBoy, e.g. the RISC-V instruction set
  • scripts: Junk that I can't put anywhere else
  • software: Loose collection of C files that are used for system-level tests. Not really a useful software tree yet.
  • synth: Working directory for running whole-system synthesis. Top-level makefiles, pin constraint files.
  • test: Regression tests. Some are Verilog testbenches, others are software testcases that run on simulations of the processor or the full system.
联系我们 contact @ memedata.com