CORDIC_Rotate_APFX/README.md
Camille Monière a0ce4ceab0
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# CORDIC Rotate APFX
[![CmakeDocker](https://github.com/DrasLorus/CORDIC_Rotate_APFX/actions/workflows/docker.yml/badge.svg)](https://github.com/DrasLorus/CORDIC_Rotate_APFX/actions/workflows/docker.yml)
A free way to implement a CORDIC-based rotation using HLS, with bit-accurate precision.
## Goal
[CORDIC](https://en.wikipedia.org/wiki/CORDIC) (COordinate Rotation DIgital Computer) is an efficient way to implement hardware complex rotations (e.g. `z * exp(jw)`, with `z = x + jy` a complex and `w` a real angle). It is also useful for microcontrollers or microprocessors lacking floating-point units, as such multiplications can consume a noticeable amount of CPU cycles.
This implementation in C++14 (`-std=c++14`) is suitable for hardware simulation and (with the right headers and maybe a few tweaks) for synthesis.
This repository defines two working CORDIC-based rotation units classes, `CCordicRotateRom` and `CCordicRotateConstexpr`, which both rely on a ROM.
They differ by the way the ROM is generated:
- `CCordicRotateRom` depends on ROM headers generated by the build system (i.e. CMake) using configure files and build-time dependencies,
- `CCordicRotateConstexpr` ROM is completely compiled using C++14 *constexpr* mechanism, which constraint the ROM type but allow cleaner build dependencies.
Currently, They can have from 2 to 7 stages, and the word length is a template.
ROM tables contain control signals for each CORDIC stage, the input angle being the address. There are two kinds of generators:
- A true *constexpr* one, that is entirely processed by the compiler.
- A Monte-Carlo one, that is evaluated at runtime.
Both can be used to produced ROM headers but only the first one can be used for `CCordicRotateConstexpr`.
Only rotations of pi and pi/2 are currently supported, but support for any pi/2^k might be added later.
`CCordicRotateSmart` is an unfinished template that would implement a *"smart"* CORDIC, which would not need a ROM.
## Test suite and dependencies
The [Catch2](https://github.com/catchorg/Catch) test framework has been used in conjunction with CTest to provides unit tests.
The [GitHub mirror of the repository](https://github.com/DrasLorus/CORDIC_Rotate_APFX) also make use of GitHub Actions and Docker as a CI/CD solution.
- Has been tested successfully compiled with:
- GNU GCC 6.2 (*Xilinx bundled version*), 6.5, 9.4, 10.1, 10.2 and 11.2,
- LLVM Clang 12.0 and 13.0,
- Uses Catch v2.13.7,
- Depends on Xilinx HLS arbitrary precision types, available as FOSS [here provided by Xilinx](https://github.com/Xilinx/HLS_arbitrary_Precision_Types) or [here patched by myself](https://github.com/DrasLorus/HLS_arbitrary_Precision_Types). Note: Xilinx also provides proprietary versions of those headers, suitable for synthesis and implementation, bundled with their products.
## License and copyright
Copyright 2022 Camille "DrasLorus" Monière.
This program is free software: you can redistribute it and/or modify it under the terms of the GNU
Lesser General Public License as published by the Free Software Foundation, either version 3 of
the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without
even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
A copy of the license is available [here in Markdown](lgpl-3.0.md) or [here in plain text](LICENSE).