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AlSaqr SoC

This repository contains the hardware files needed to build the AlSaqr-SoC. The architecture of the SoC is briefly described in the block diagram below.

alt text

The repository is organized as follows

|-- bootrom
|-- fpga 
|-- hardware
|-- software
  • The fpga folder contains some git submodules.

  • The hardware folder is organized as follows:

    • deps contains local component integrated in the SoC
    • host contains the host-system: it wraps the core and plugs it into the axi_node to which the slaves are attached
    • tb contains the testbench
    • fpga contains the scripts to generate the bitstream
    • docs contains the datasheet of AlSaqr SoC and the related padframe specification
  • software contains the bare metals tests you can run on the SoC

RISC-V Toolchain

AlSaqr requires the RISC-V toolchain which is available here: https://github.com/riscv-collab/riscv-gnu-toolchain

For the PULP CLuster make sure the PULP RV32 toolchain is in your PATH. Please refer to PULP RISCV GCC toolchain to use a pre-built release: https://github.com/pulp-platform/pulp-riscv-gcc

Repo initialization

Please change the setup file to point to your toolchains and Questasim installations in he-soc/setup.sh:

** NB: this fetches the current master branch, under costant developement. **

git clone [email protected]:AlSaqr-platform/he-soc.git
cd he-soc/
source setup.sh
source software/pulp-runtime/configs/pulp_cluster.sh

** NB: To target a specific release you should git checkout it as first step after cloning the repo. **

git clone [email protected]:AlSaqr-platform/he-soc.git
cd he-soc
git checkout tags/<tag-name> 
source setup.sh
source software/pulp-runtime/configs/pulp_cluster.sh

To install, configure bender and download the git dependencies + verification IPs, from he-soc/ run:

cd hardware/
make init

make init step may fail on slower networks as connection breaks before getting all repositories. Repeat 'make init' step until all repositories downloaded and bender lock generated.

To compile the hello world, in he-soc/hardware run:

make -C ../software/hello_culsans clean all

To compile the hello world for FPGA board, in he-soc/hardware run:

make -C ../software/hello_culsans fpga=1 clean all

This will generate the binaries and the hyperram*.slm that will be in the rams at t=0 (in case of preloading).

Generate TCL for simulation

Then, generate the tcl for simulation and synthesis. In he-soc/hardware run one of two following options accordingly to your target:

  • RTL simulation:
make scripts_vip
  • RTL simulation using gf22 macros (this requires the gf22 repository to be cloned and initialized into he-soc/hardware folder, as well as fll's one):
make scripts_vip_macro

By default, the elf binary will be preloaded into L3.

To load the code through JTAG interface, you can add the localjtag=1 option to the previous command, for instance: make localjtag=1 scripts_vip. Be aware that the preload of the code is slower in this case.

Run the test

  • Option 1: in the he-soc/hardware folder run (the test to be run shall be compiled first, as the command runs automatically the simulation with the last tests that has been compiled):
make -C ../software/"test you want to run" clean all
make clean sim

If you want to speed up the simulation (of about 2x), you can use the "max-opt" flag, which will deactivate the logs of all the waveforms. This is not suitable for debugging, but just to get the result of a test as fast as passible. To avoid the Questa GUI to be opened, you can use the "nogui=1" flag, which applies the same opts as max-opt and do not open the gui.

make scripts_vip max-opt=1
make clean sim max-opt=1

or

make scripts_vip nogui=1
make clean sim nogui=1

The code that will be laoded is the last that has been compiled. Thus, to run a test with preload in L3, you shall compile the test you want to run (as shown above) and then run the simulation without providing the path to the binary.

In case of localjtag preload, you need to provide the path to the binary you want to execute. make clean sim elf-bin=../software/hello_culsans/hello_culsans.riscv if you used the localjtag preload flag.

  • Option 2: go to the test folder (ex software/hello_culsans)
make clean all sim

Run test with OpenTitan:

To run mbox test between cva6 and ibex, in he-soc/hardware run:

make -C ../software/mbox_test clean all
make clean sim ibex-elf-bin=./opentitan/sw/tests/alsaqr/mbox_test/mbox_test.elf 

To run the full secure boot, use the following commands (for instance, opentitan boots CVA6 which runs an hello world):

make scripts_vip sec_boot=1
make -C ../software/hello_culsans/ clean all
make clean sim BOOTMODE=1 sec_boot=1

Running code on the cluster

To run code on the cluster we must first source its runtime:

cd software
source pulp-runtime/configs/pulp_cluster.sh

Each test designed for the cluster is structured as follows:

- your-test-folder
  |
  |
  -- stimuli

The parent folder contains the code executed by the host (CVA6) and the stimuli folder contains the cluster code.

You can compile all the needed files with the following commands:

cd your-test-folder
make -C stimuli clean all dump_header
make clean all CLUSTER_BIN=1

The tests that will run is the last that's been compiled. Thus, compile a test among the ones in software/cluster_regression.list then run the following commands:

cd ../../hardware
make scripts_vip
make clean sim

Run regressions

Before merging any modification into the master it is important to run the regression tests to check we did not break anything. To do so, execute the following commands:

To run the regressions including the CVA6 various dual boot mode, FLL bypass and secure boot/mbox test and periphs, run:

cd hardware/
make run_regression

The tests executed here can be found in hardware/regressions/regression.csv, they are 23 and all of them pass.

FPGA Emulation

We now support emulation on Xilinx VCU118. Please have a look to the README in the hardware/fpga folder.

Synthesize he-soc into your target technology

This requires the gf22 repository to be cloned and initialized into he-soc/hardware folder. In he-soc/hardware run:

make clean scripts-bender-synopsys

The command will generate the analyze_alsaqr.tcl within your technology folder

Post Synthesis Simulations

NB: Due to the padframe modifications this option is under development

The design synthesis of AlSaqr adopts a hierarchical approach. Individual components, such as CVA6, OpenTitan, HyperRAM, PULP Cluster, and FLL, are synthesized independently. However, at the top tier of the design, these submodules are integrated as hard macros, utilizing LEF geometric files alongside lib/db timing views for precision.

To validate the synthesis of AlSaqr we provide the following simulation targets, allowing flexibility and testability:

  • gf22_fll_behav

RTL + FLL BEHAVIOURAL (YOU NEED ACCESS TO THE PRIVATE FLL REPO FOR THIS)

  • post_synth_all

ONLY NETLSISTS: TOP - FLL - CVA6 -OPENTITAN - CLUSTER - HYPER

  • post_synth_top

RTL: OPENTITAN - CLUSTER - CVA6 / NETLIST: TOP - FLL - HYPER

  • post_synth_cva6_hyper

RTL: TOP - CLUSTER - OPENTITAN - FLL BEHAV (YOU NEED ACCESS TO THE FLL REPO FOR THIS) / NETLIST: CVA6 - HYPER

  • post_synth_cva6_hyper_fll

RTL: TOP - CLUSTER - OPENTITAN / NETLIST: CVA6 - HYPER - FLL

  • post_synth_fll

RTL + FLL NETLIST

  • post_synth_top_fll_behav

RTL + FLL NETLIST

  • post_synth_cva6

RTL: (USES FLL DUMMY) + CVA6 NETLIST

  • post_synth_opentitan

RTL (USES FLL DUMMY) + OPENTITAN NETLIST

  • post_synth_cluster

RTL (USES FLL DUMMY) + CLUSTER NETLIST

  • post_synth_hyper

RTL (USES FLL DUMMY) + HYPER NETLIST

To perform the post sythesis simulation of one of the previous target run the following command within he-soc/hardware (NB: the acc flag ensures that the simulation is fast, about 10 mins for an hello world):

make clean post_synth=1 <target_name> synth_sim acc=+acc=p+ariane_tb.

There is a framwork to run the regressions with the netlist of the chip as well. The netlist regression list is defined in hardware/regressions/regressions_netlist.csv while the transcript of each simulation will be stored in hardware/regressions/regressions_netlist_reports/ . To run the regression using the netlist do the following:

cd hardware/
make run_regression_netlist

Pubblication

If you use AlSaqr in your work, please cite us:

@ARTICLE{10423921,
  author={Valente, Luca and Nadalini, Alessandro and Veeran, Asif Hussain Chiralil and Sinigaglia, Mattia and Sá, Bruno and Wistoff, Nils and Tortorella, Yvan and Benatti, Simone and Psiakis, Rafail and Kulmala, Ari and Mohammad, Baker and Pinto, Sandro and Palossi, Daniele and Benini, Luca and Rossi, Davide},
  journal={IEEE Transactions on Circuits and Systems I: Regular Papers}, 
  title={A Heterogeneous RISC-V Based SoC for Secure Nano-UAV Navigation}, 
  year={2024},
  volume={},
  number={},
  pages={1-14},
  keywords={Standards;Energy efficiency;Drones;Virtual machine monitors;Silicon;Navigation;Internet of Things;Heterogeneous;Linux;low-power;autonomous nano-UAVs;RISC-V},
  doi={10.1109/TCSI.2024.3359044}}

@INPROCEEDINGS {10254698,
author = {L. Valente and A. Veeran and M. Sinigaglia and Y. Tortorella and A. Nadalini and N. Wistoff and B. Sa and A. Garofalo and R. Psiakis and M. Tolba and A. Kulmala and N. Limaye and O. Sinanoglu and S. Pinto and D. Palossi and L. Benini and B. Mohammad and D. Rossi},
booktitle = {2023 IEEE Hot Chips 35 Symposium (HCS)},
title = {Shaheen: An Open, Secure, and Scalable RV64 SoC for Autonomous Nano-UAVs},
year = {2023},
volume = {},
issn = {},
pages = {1-12},
abstract = {Open Source Hardware, the way it should be!},
keywords = {},
doi = {10.1109/HCS59251.2023.10254698},
url = {https://doi.ieeecomputersociety.org/10.1109/HCS59251.2023.10254698},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
month = {aug}
}

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