Ibex Super System is DEPRECATED, and has become the Ibex Demo System which is maintained by lowRISC.
This an example RISC-V SoC targeting the Arty-A7 FPGA board. It comprises the lowRISC Ibex core along with the following features:
- RISC-V debug support (using the PULP RISC-V Debug Module)
- A UART (transmit only for now)
- GPIO (output only for now)
- Timer
Debug can be used via a USB connection to the Arty-A7 board. No external JTAG probe is required.
- Xilinx Vivado - https://www.xilinx.com/support/download.html
- rv32imc GCC toolchain - lowRISC provide one: https://github.com/lowRISC/lowrisc-toolchains/releases
- cmake
- python3 - Additional python dependencies in python-requirements.txt installed with pip
- openocd
To install python dependencies use pip, you may wish to do this inside a virtual environment to avoid disturbing you current python setup (note it uses a lowRISC fork of edalize and FuseSoC so if you already use these a virtual environment is recommended)
# Setup python venv
python3 -m venv .
source ./bin/activate
# Install python requirements
pip3 install -r python-requirements.txtYou may need to run the last command twice if you get the following error:
ERROR: Failed building wheel for fusesoc
First the software must be built. This is provide an initial binary for the FPGA build.
cd sw
mkdir build
cd build
cmake ../
make
Note the FPGA build relies on a fixed path to the initial binary (blank.vmem) so
if you want to create your build directory elsewhere you need to adjust the path
in ibex_super_system.core
FuseSoC handles the FPGA build. Vivado tools must be setup beforehand. From the repository root:
source /path/to/vivado/settings64.sh
fusesoc --cores-root=. run --target=synth --setup --build lowrisc:ibex:super_system
To program the FPGA, either use FuseSoC again
fusesoc --cores-root=. run --target=synth --run lowrisc:ibex:super_system
Or use the Vivado GUI
make -C ./build/lowrisc_ibex_super_system_0/synth-vivado/ build-gui
Inside Vivado you do not have to run the synthesis, the implementation or generate the bitstream. Simply click on "Open Hardware Manager", then on "Auto Connect" and finally on "Program Device".
The util/load_super_system.sh script can be used to load and run a program. You can choose to immediately run it or begin halted, allowing you to attach a debugger.
# Run demo
./util/load_super_system.sh run ./sw/build/demo/demo
# Load demo and start halted awaiting a debugger
./util/load_super_system.sh halt ./sw/build/demo/demoTo view terminal output use screen:
# Look in /dev to see available ttyUSB devices
screen /dev/ttyUSB1 115200If you see an immediate [screen is terminating], it may mean that you need super user rights.
In this case, you may try using sudo.
Either load a program and halt (see above) or start a new OpenOCD instance
openocd -f util/arty-a7-openocd-cfg.tcl
Then run GDB against the running binary and connect to localhost:3333 as a remote target
riscv32-unknown-elf-gdb ./sw/build/demo/demo
(gdb) target extended-remote localhost:3333