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DesignWare RISC-V nSIM and HAPS FPGA boards

Overview

This platform can be used to run Zephyr RTOS on the widest possible range of Synopsys RISC-V processors in simulation with Designware ARC nSIM or run same images on FPGA prototyping platform HAPS. The platform includes the following features:

  • RISC-V processor core, which implements riscv32 ISA

  • Virtual serial console (a standard ns16550 UART model)

Supported board targets for that platform are listed below:

  • nsim_arc_v/rmx100 - Synopsys RISC-V RMX100 core

It is recommended to look at precise description of a particular board target in .props files in boards/snps/nsim_arc_v/support/ directory to understand which options are configured and so will be used on invocation of the simulator.

Warning

All nSIM targets are used for demo and testing purposes. They are not meant to represent any real system and so might be renamed, removed or modified at any point.

Programming and Debugging

Required Hardware and Software

To run single-core Zephyr RTOS applications in simulation on this board, either DesignWare ARC nSIM or DesignWare ARC Free nSIM is required.

Building & Running Sample Applications

Most board targets support building with both GNU and ARC MWDT toolchains, however there might be exceptions from that, especially for newly added targets. You can check supported toolchains for the board targets in the corresponding .yaml file.

I.e. for the nsim_arc_v/rmx100 board we can check boards/snps/nsim_arc_v/nsim_arc_v_rmx100.yaml

The supported toolchains are listed in toolchain: array in .yaml file, where we can find:

  • zephyr - implies RISC-V GNU toolchain from Zephyr SDK. You can find more information about Zephyr SDK here.

  • cross-compile - implies RISC-V GNU cross toolchain, which is not a part of Zephyr SDK. Note that some (especially new) board targets may declare cross-compile toolchain support without zephyr toolchain support because corresponding target CPU support hasn’t been added to Zephyr SDK yet. You can find more information about its usage here: here.

  • arcmwdt - implies proprietary ARC MWDT toolchain. You can find more information about its usage here: here.

Note

Note that even if both GNU and MWDT toolchain support is declared for the target some tests or samples can be only built with either GNU or MWDT toolchain due to some features limited to a particular toolchain.

Use this configuration to run basic Zephyr applications and kernel tests in nSIM, for example, with the Basic Synchronization sample:

# From the root of the zephyr repository
west build -b nsim_arc_v/rmx100 samples/synchronization
west flash

This will build an image with the synchronization sample app, boot it using nSIM, and display the following console output:

*** Booting Zephyr OS build zephyr-v3.2.0-3948-gd351a024dc87 ***
thread_a: Hello World from cpu 0 on nsim_arc_v!
thread_b: Hello World from cpu 0 on nsim_arc_v!
thread_a: Hello World from cpu 0 on nsim_arc_v!
thread_b: Hello World from cpu 0 on nsim_arc_v!
thread_a: Hello World from cpu 0 on nsim_arc_v!

Note

To exit the simulator, use Ctrl+], then Ctrl+c

Tip

You can get more details about the building process by running build in verbose mode. It can be done by passing -v flag to the west: west -v build -b nsim_hs samples/synchronization

Debugging

Debugging with GDB

Note

Debugging on nSIM via GDB is only supported on single-core targets (which use standalone nSIM).

Note

The normal west debug command won’t work for debugging applications using nsim boards because both the nSIM simulator and the debugger use the same console for input / output. In case of GDB debugger it’s possible to use a separate terminal windows for GDB and nSIM to avoid intermixing their output.

After building your application, open two terminal windows. In terminal one, use nSIM to start a GDB server and wait for a remote connection with following command:

west debugserver --runner arc-nsim

In terminal two, connect to the GDB server using RISC-V GDB. You can find it in Zephyr SDK:

  • you should use riscv64-zephyr-elf-gdb

This command loads the symbol table from the elf binary file, for example the build/zephyr/zephyr.elf file:

riscv64-zephyr-elf-gdb  -ex 'target remote localhost:3333' -ex load build/zephyr/zephyr.elf

Now the debug environment has been set up, and it’s possible to debug the application with gdb commands.

Modifying the configuration

If modification of existing nsim configuration is required or even there’s a need in creation of a new one it’s required to maintain alignment between

  • Zephyr OS configuration

  • nSIM configuration

  • GNU & MWDT toolchain compiler options

Note

The .tcf configuration files are not supported by Zephyr directly. There are multiple reasons for that. .tcf perfectly suits building of bare-metal single-thread application - in that case all the compiler options from .tcf are passed to the compiler, so all the HW features are used by the application and optimal code is being generated. The situation is completely different when multi-thread feature-rich operation system is considered. Of course it is still possible to build all the code with all the options from .tcf - but that may be far from optimal solution. For example, such approach require so save & restore full register context for all tasks (and sometimes even for interrupts). And for DSP-enabled or for FPU-enabled systems that leads to dozens of extra registers save and restore even if the most of the user and kernel tasks don’t actually use DSP or FPU. Instead we prefer to fine-tune the HW features usage which (with all its pros) require us to maintain them separately from .tcf configuration.

Zephyr OS configuration

Zephyr OS configuration is defined via Kconfig and Device tree. These are non RISC-V-specific mechanisms which are described in board porting guide.

It is advised to look for <board_name>_defconfig, <board_name>.dts and <board_name>.yaml as an entry point for board target.

nSIM configuration

nSIM configuration is defined in props files. Generally they are identical to the values from corresponding .tcf configuration with few exceptions:

  • The UART model is added

  • CLINT model is added

GNU & MWDT toolchain compiler options

The hardware-specific compiler options are set in corresponding SoC cmake file. For nsim_arc_v board it is soc/snps/nsim/arc_v/CMakeLists.txt.

For the GNU toolchain the basic configuration is set via -march which is defined in generic code and based on the selected CPU model via Kconfig. It still can be forcefully set to required value on SoC level.

Note

The non hardware-specific compiler options like optimizations, library selections, C / C++ language options are still set in Zephyr generic code. It could be observed by running build in verbose mode.

References