The code follows the lowRISC coding style for Verilog for the most part. I wrote this myself in my free time so there will be deviations for no real reason.
- signals use snake case
- note: logical word units are joined without underscore
- eg: memwrite expands to memory write (one action)
- eg: mem_to_reg expands to memory to register (no joining)
- parameters use ALL CAPS
- task names, module names are all snake case
- common abbreviations are used where possible (reg for register, mem for memory, ctrl for control, etc)
While there is a great open source toolset for the iCESugar v1.5, it remains difficult to navigate the web of broken links to find what is really needed to get Verilog synthesized and 'running on' the FPGA. After lots of searching and reading tutorials, I've condensed it to this:
yosysfor synthesisnextpnrfor place n routeiverilogfor Verilog compilation and simulationicestormfor a few useful tools for the iCE40 family of FPGAsicesprogfor uploading the bitstream to the iCESugar board specifically
I recommend building each of these tools from source to ensure the latest (working) version and in the case of icesprog you'll also need to add the binary directory to your $PATH. Each of these tools has their own required dependencies so look them up to find them. Then, a standard make -j4 and sudo make install suffices, apart from the odd case when a ./configure was needed. While I was wrapping my head around this, I found https://f4pga.readthedocs.io/en/latest/flows/index.html quite helpful in explaining each step of the design flow and how that interlinks with these open source tools.
- turn instrmem and regfile into BRAM, memory maybe SPRAM
- write a simple linker script
- add pipeline stalls
- rename pc_incr to pc
- double sw hazard, extra pipeline?
- if a clocked module requires the output of a previous stage, it should take it directly from that previous stage, not the pipeline register!
It seems that Raspberry Pi OS couldn't mount the board since df turned up empty. It was evident that the device was correctly plugged in though as lsusb showed a new addition and dmesg didn't show any errors. This meant that the board had to be manually mounted (remember, it's not really a mass storage device but acts like one), so I ran blkid to get the device UUID:
/dev/sda: SEC_TYPE="msdos" LABEL_FATBOOT="DAPLINK-DND" LABEL="iCELink" UUID="2702-1974" BLOCK_SIZE="512" TYPE="vfat"
I then added an entry in fstab:
UUID=2702-1974 /mnt/iCELink vfat defaults,auto,users,rw,nofail 0 0
and that was it!
GTKWave underwent a complete rewrite and somewhere along the line compatibility with newer Macs was broken. The author does not work on a Mac so couldn't provide correct build instructions. Some nice guy on the internet created a custom Homebrew formula with all the right steps to compile from source. I'm also testing a new waveform visualizer called "surfer".
brew update
brew outdated
brew upgrade
brew cleanup
brew uninstall gtkwave
brew untap randomplum/gtkwave
brew install --HEAD randomplum/gtkwave/gtkwave
Full credits go to mattvenn for the initial code for the GTKWave filter process that takes RISC-V machine code and transforms it into RV32I assembly for easy visualization in the waveform viewer. It seems in between the time they wrote it and now, differences in risv64-unknown-elf-as output have broken it.
Note to self: the process file needs to be executable!
Format of the process file: I wasn't able to find any strict documentation on the process file but from my testing I found that the values of a particular signal that are currently rendered will be passed into the stdin of the script that is called as a hex string. You can then do whatever you want with this but make sure to add a \n to the end of your output string (if it doesn't already have one). Beware of xs!
https://github.com/riscv-software-src/homebrew-riscv?tab=readme-ov-file
FPGA
https://github.com/chipsalliance/verible/blob/master/verilog/tools/formatter/README.md
https://github.com/YosysHQ/riscv-formal https://github.com/riscv-software-src/riscv-tests/