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This is the CORE-V MCU project, hosting CORE-V's embedded-class cores.

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License Documentation Status

CORE-V MCU

CORE-V MCU originated from PULPissimo [1], [2], and is now a stand-alone project within OpenHW Group independent from PULPIssimo.

In case you would be interested to join the project please feel free to open an issue, or involve yourself in any open issues/discussions. Contributions are always welcome! First time contributors should review the Contributing guide.

Quick Start Guide

The fastest way to get up and running with the CORE-V MCU is with pre-built bit streams for the Digilent Nexys A7 board. Check out the Quick Start Guide.

Getting Started

Install the required Python tools:

pip3 install --user -r python-requirements.txt

Install fusesoc: https://fusesoc.readthedocs.io/en/stable/user/installation.html#ug-installation

Install Verilator v4.100: https://verilator.org/guide/latest/install.html

Install Xilinx Vivado: see the Quick Start Guide.

Building

The build system uses make to capture the required steps. make with no argments will print a list of the current targets:

$ make
all:            generate build scripts, custom build files, doc and sw header files
bitstream:      generate nexysA7-100T.bit file for emulation
model-lib:      build a Verilator model library
lint:           run Verilator lint check
docs:           generate documentation
sw:             generate C header files (in ./sw)
nexys-emul:     generate bitstream for Nexys-A7-100T emulation)
genesys-emul:   generate bitstream for Genesys2 FPGA board
buildsim:       build for Questa sim
sim:            run Questa sim
downloadn:      Download bitstream to Nexys board
downloadg:      Download bitstream to Genesys2 board

Building an FPGA Image

To target the Nexys-A7-100T board:

$ make nexys-emul

Make sure you have the latest Xilinx board-parts installed. Current image is core_v_nexys_200122.bit

To target Genesys2 board:

$ make genesys-emul

Extra note for building on ubuntu - Vivado tools from Xilinx may require a larger swap size that the system default. The swap size can be increased by searching for "increase swapfile in ubuntu" and add your release.

Building documentation

$ make docs

The resulting documents are accessed using file ./docs/_build/html/index.html

Documentation of the Debug Unit

At present the details of the debug unit are not incorporated in the main documentation. The top level interface is an IEEE 1149.1 compliant JTAG Test Access port. It implements the reference JTAG Debug Transport Module documented in Section 6.1 of the RISC-V Debug Interface, version 0.13.2.

The RISC-V Debug Interface has many optional features. Those enabled for the CORE-V MCU are documented in the PULP Platform Debug Unit.

Building C header files

$ make sw

The resulting header files are located in ./sw

Running Modelsim/Questasim

$ make buildsim sim

The 'make buildsim' creates a work library in build/openhwgroup.org_systems_core-v-mcu_0/sim-modelsim, and then 'make sim' runs the simulation.

The test bench used by the simulation is 'core_v_mcu_tb.sv'

The resulting header files are located in ./sw

Experimental fuseSoC Support

Run Verilator lint target:

fusesoc --cores-root . run --target=lint --setup --build openhwgroup.org:systems:core-v-mcu

To build Verilator as a library which can be linked into other tools (such as the debug server):

fusesoc --cores-root . run --target=model-lib --setup --build openhwgroup.org:systems:core-v-mcu

The library will be in the obj_dir subdirectory of the work root.

Once can sanity check the top-level using QuestaSim:

fusesoc --cores-root . run --target=sim --setup --build --run openhwgroup.org:systems:core-v-mcu

Contributing: Pre-commit checks

If you are submitting a pull-request, it will be subject to pre-commit checks. The two that most likely cause problems are the Verilator Lint check and the Verible format check.

Verilator model library

The system will run

fusesoc --cores-root . run --target=model-lib --setup --build openhwgroup.org:systems:core-v-mcu

If your changes introduce any Verilator errors, you either need to fix these, or, if appropriate, add a rule to ignore them to rtl/core-v-mcu/verilator.waiver.

This will create the Verilator library Vcore_v_mcu_wrapper__ALL.a in build/openhwgroup.org_systems_core-v-mcu_0/model-lib-verilator/obj_dir.

Note that when you use this library to build an application you will need to ensure that the directory build/openhwgroup.org_systems_core-v-mcu_0/model-lib-verilator/mem_init is either symbolically linked or copied to the directory where the application will run. The model will load ROM images from this directory.

Note. The model is compiled at optimization level -O3, since performance is of importance with the likely applications, and with -fPIC, so it is suitable for inclusion in shared object libraries.

Verilator lint check

The system will run

fusesoc --cores-root . run --target=lint --setup --build openhwgroup.org:systems:core-v-mcu

If your changes introduce any more Verilator lint warnings, you either need to fix these, or, if appropriate, add a rule to ignore them to rtl/core-v-mcu/verilator.waiver.

Verible format check

Standard formating is enforced by Verible. The command used is

util/format-verible

at the top level of the repository, which will correct the format of any file. The check will fail if any file is changed.

Two important things to note.

  1. If you do not have Verible installed (which is likely), then util/format-verible will silently do nothing.

  2. You must install the correct version of Verible, currently v0.0-3410-g398a8505. Chips Alliance has prebuilt versions. The version may change in the future. In the event of the check failing, the details with the failure will tell you which version was used.

References

  1. Schiavone, Pasquale Davide, et al. "Quentin: an ultra-low-power pulpissimo soc in 22nm fdx." 2018 IEEE SOI-3D-Subthreshold Microelectronics Technology Unified Conference (S3S). IEEE, 2018.

  2. Schiavone, Pasquale Davide, et al. "Arnold: An eFPGA-Augmented RISC-V SoC for Flexible and Low-Power IoT End Nodes." IEEE Transactions on Very Large Scale Integration (VLSI) Systems 29.4 (2021): 677-690.

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