Skip to content
/ kfr Public

Fast, modern C++ DSP framework, FFT, Sample Rate Conversion, FIR/IIR/Biquad Filters (SSE, AVX, AVX-512, ARM NEON)

License

Notifications You must be signed in to change notification settings

kfrlib/kfr

Repository files navigation

KFR - Fast, modern C++ DSP framework

Build Test

License Release

https://www.kfrlib.com

KFR is an open source C++ DSP framework that contains high performance building blocks for DSP, audio, scientific and other applications. It is distributed under dual GPLv2/v3 and commercial license.

KFR6

New features, performance improvements, easier setup.

➑️ What's new in KFR6

➑️ Upgrade from a previous version

Our other projects

🟣 Brisk is a cross-platform C++20 GUI framework featuring MVVM architecture, reactive capabilities, and scalable, accelerated GPU rendering. (GPL/Commercial)

🟒 CxxDox β€” C++ documentation generator. (MIT)

KFR Installation

Compiler support:

Clang 11+ GCC 7+ MSVC 2019 Xcode 12+

KFR has no external dependencies except for a C++17-compatible standard C++ library. CMake is used as the build system.

Clang is highly recommended and proven to provide the best performance for KFR. You can use Clang as a drop-in replacement for both GCC on Linux and MSVC on Windows. On macOS, Clang is the default compiler and included in the official Xcode toolchain.

Note: Building the DFT module currently requires Clang due to internal compiler errors and a lack of optimization in GCC and MSVC.

➑️ See Installation docs for more details

Features

🌟 β€” new in KFR6

FFT/DFT

  • Optimized DFT implementation for any size (non-power of two sizes are supported)
  • DFT performance is on par with the most performant implementation currently available See Benchmarks
  • Real forward and inverse DFT
  • 🌟 Multidimensional complex and real DFT
  • Discrete Cosine Transform type II (and its inverse, also called DCT type III)
  • Convolution using FFT
  • Convolution filter

➑️ See also How to apply FFT with KFR

DSP

  • IIR filter design
    • Butterworth
    • Chebyshev type I and II
    • Bessel
    • Lowpass, highpass, bandpass and bandstop filters
    • Conversion of arbitrary filter from {Z, P, K} to SOS format (suitable for biquad function and filter)
  • Biquad filter See Benchmarks
  • Simple biquad filter design
  • FIR filter design using window method
  • Loudness measurement according to EBU R128
  • Window functions: Triangular, Bartlett, Cosine, Hann, Bartlett-Hann, Hamming, Bohman, Blackman, Blackman-Harris, Kaiser, Flattop, Gaussian, Lanczos, Rectangular
  • Sample rate conversion with configurable quality and linear phase
  • Oscillators, fast incremental sine/cosine generation, Goertzel algorithm, fractional delay

Base

  • Tensors (multidimensional arrays)
  • 🌟 .npy support (reading/writing)
  • 🌟 Matrix transpose
  • Statistical functions
  • Random number generation
  • Template expressions (See examples)
  • Ring (Circular) buffer
  • 🌟 Windows arm64 support
  • 🌟 Emscripten (wasm/wasm64) support

Math

  • Mathematical functions such as sin, log and cosh built on top of SIMD primitives
  • Most of the standard library functions are re-implemented to support vector of any length and data type

SIMD

  • vec<T, N> class and related functions that abstracts cpu-specific intrinsics
  • All code in the library is optimized for Intel, AMD (SSE2, SSE3, SSE4.x, AVX and AVX2 and AVX512) and ARM, AArch64 (NEON) processors
  • All data types are supported including complex numbers
  • All vector lengths are also supported. vec<float,1>, vec<unsigned,3>, vec<complex<float>, 11> all are valid vector types in KFR
  • Sorting

IO

  • Audio file reading/writing
  • WAV
  • FLAC
  • MP3

Multiarchitecture

The multiarchitecture mode enables building algorithms for multiple architectures with runtime dispatch to detect the CPU of the target machine and select the best code path

  • 🌟 Multiarchitecture for DFT, resampling, FIR and IIR filters.

C API

C API is available and includes a subset of KFR features including FFT and filter processing.

  • 🌟 Support for non x86 systems.

Benchmark results

DFT

Powers of 2, from 16 to 16777216 (Higher is better)

FFT Performance

Prime numbers from 17 to 127 (Higher is better)

DFT Performance

Small numbers from 18 to 119 (Higher is better)

DFT Performance

Random sizes from 120 to 30720000 (Higher is better)

DFT Performance

See fft benchmark for details about benchmarking process.

Biquad

(Higher is better)

Biquad Performance

Documentation

KFR 6 (latest) https://www.kfrlib.com/docs/latest/

KFR 5 https://www.kfrlib.com/docs/v5/

Built with

Branches

dev - current development version. Pull requests should go to dev.

main - current stable version passing all compiler/architecture tests.

v5 - previous version of KFR (no new features, fixes only)

License

KFR is dual-licensed, available under both commercial and open-source GPL 2+ license.

If you want to use KFR in a commercial product or a closed-source project, you need to purchase a Commercial License.