/* ============================================================================== This file is part of the JUCE library. Copyright (c) 2013 - Raw Material Software Ltd. Permission is granted to use this software under the terms of either: a) the GPL v2 (or any later version) b) the Affero GPL v3 Details of these licenses can be found at: www.gnu.org/licenses JUCE 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 General Public License for more details. ------------------------------------------------------------------------------ To release a closed-source product which uses JUCE, commercial licenses are available: visit www.juce.com for more information. ============================================================================== */ // (For the moment, we'll implement a few local operators for this complex class - one // day we'll probably either have a juce complex class, or use the C++11 one) static FFT::Complex operator+ (FFT::Complex a, FFT::Complex b) noexcept { FFT::Complex c = { a.r + b.r, a.i + b.i }; return c; } static FFT::Complex operator- (FFT::Complex a, FFT::Complex b) noexcept { FFT::Complex c = { a.r - b.r, a.i - b.i }; return c; } static FFT::Complex operator* (FFT::Complex a, FFT::Complex b) noexcept { FFT::Complex c = { a.r * b.r - a.i * b.i, a.r * b.i + a.i * b.r }; return c; } static FFT::Complex& operator+= (FFT::Complex& a, FFT::Complex b) noexcept { a.r += b.r; a.i += b.i; return a; } //============================================================================== struct FFT::FFTConfig { FFTConfig (int sizeOfFFT, bool isInverse) : fftSize (sizeOfFFT), inverse (isInverse), twiddleTable ((size_t) sizeOfFFT) { for (int i = 0; i < fftSize; ++i) { const double phase = (isInverse ? 2.0 : -2.0) * double_Pi * i / fftSize; twiddleTable[i].r = (float) cos (phase); twiddleTable[i].i = (float) sin (phase); } const int root = (int) std::sqrt ((double) fftSize); int divisor = 4, n = fftSize; for (int i = 0; i < numElementsInArray (factors); ++i) { while ((n % divisor) != 0) { if (divisor == 2) divisor = 3; else if (divisor == 4) divisor = 2; else divisor += 2; if (divisor > root) divisor = n; } n /= divisor; jassert (divisor == 1 || divisor == 2 || divisor == 4); factors[i].radix = divisor; factors[i].length = n; } } void perform (const Complex* input, Complex* output) const noexcept { perform (input, output, 1, 1, factors); } const int fftSize; const bool inverse; struct Factor { int radix, length; }; Factor factors[32]; HeapBlock twiddleTable; void perform (const Complex* input, Complex* output, const int stride, const int strideIn, const Factor* facs) const noexcept { const Factor factor (*facs++); Complex* const originalOutput = output; const Complex* const outputEnd = output + factor.radix * factor.length; if (stride == 1 && factor.radix <= 5) { for (int i = 0; i < factor.radix; ++i) perform (input + stride * strideIn * i, output + i * factor.length, stride * factor.radix, strideIn, facs); butterfly (factor, output, stride); return; } if (factor.length == 1) { do { *output++ = *input; input += stride * strideIn; } while (output < outputEnd); } else { do { perform (input, output, stride * factor.radix, strideIn, facs); input += stride * strideIn; output += factor.length; } while (output < outputEnd); } butterfly (factor, originalOutput, stride); } void butterfly (const Factor factor, Complex* data, const int stride) const noexcept { switch (factor.radix) { case 1: break; case 2: butterfly2 (data, stride, factor.length); return; case 4: butterfly4 (data, stride, factor.length); return; default: jassertfalse; break; } Complex* scratch = static_cast (alloca (sizeof (Complex) * (size_t) factor.radix)); for (int i = 0; i < factor.length; ++i) { for (int k = i, q1 = 0; q1 < factor.radix; ++q1) { scratch[q1] = data[k]; k += factor.length; } for (int k = i, q1 = 0; q1 < factor.radix; ++q1) { int twiddleIndex = 0; data[k] = scratch[0]; for (int q = 1; q < factor.radix; ++q) { twiddleIndex += stride * k; if (twiddleIndex >= fftSize) twiddleIndex -= fftSize; data[k] += scratch[q] * twiddleTable[twiddleIndex]; } k += factor.length; } } } void butterfly2 (Complex* data, const int stride, const int length) const noexcept { Complex* dataEnd = data + length; const Complex* tw = twiddleTable; for (int i = length; --i >= 0;) { const Complex s (*dataEnd * *tw); tw += stride; *dataEnd++ = *data - s; *data++ += s; } } void butterfly4 (Complex* data, const int stride, const int length) const noexcept { const int lengthX2 = length * 2; const int lengthX3 = length * 3; const Complex* twiddle1 = twiddleTable; const Complex* twiddle2 = twiddle1; const Complex* twiddle3 = twiddle1; for (int i = length; --i >= 0;) { const Complex s0 = data[length] * *twiddle1; const Complex s1 = data[lengthX2] * *twiddle2; const Complex s2 = data[lengthX3] * *twiddle3; const Complex s3 = s0 + s2; const Complex s4 = s0 - s2; const Complex s5 = *data - s1; *data += s1; data[lengthX2] = *data - s3; twiddle1 += stride; twiddle2 += stride * 2; twiddle3 += stride * 3; *data += s3; if (inverse) { data[length].r = s5.r - s4.i; data[length].i = s5.i + s4.r; data[lengthX3].r = s5.r + s4.i; data[lengthX3].i = s5.i - s4.r; } else { data[length].r = s5.r + s4.i; data[length].i = s5.i - s4.r; data[lengthX3].r = s5.r - s4.i; data[lengthX3].i = s5.i + s4.r; } ++data; } } JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (FFTConfig) }; //============================================================================== FFT::FFT (int order, bool inverse) : config (new FFTConfig (1 << order, inverse)), size (1 << order) {} FFT::~FFT() {} void FFT::perform (const Complex* const input, Complex* const output) const noexcept { config->perform (input, output); } void FFT::performRealOnlyForwardTransform (float* d) const noexcept { // This can only be called on an FFT object that was created to do forward transforms. jassert (! config->inverse); Complex* const scratch = static_cast (alloca (16 + sizeof (Complex) * (size_t) size)); for (int i = 0; i < size; ++i) { scratch[i].r = d[i]; scratch[i].i = 0; } perform (scratch, reinterpret_cast (d)); } void FFT::performRealOnlyInverseTransform (float* d) const noexcept { // This can only be called on an FFT object that was created to do inverse transforms. jassert (config->inverse); Complex* const scratch = static_cast (alloca (16 + sizeof (Complex) * (size_t) size)); perform (reinterpret_cast (d), scratch); const float scaleFactor = 1.0f / size; for (int i = 0; i < size; ++i) { d[i] = scratch[i].r * scaleFactor; d[i + size] = scratch[i].i * scaleFactor; } } void FFT::performFrequencyOnlyForwardTransform (float* d) const noexcept { performRealOnlyForwardTransform (d); const int twiceSize = size * 2; for (int i = 0; i < twiceSize; i += 2) { d[i / 2] = juce_hypot (d[i], d[i + 1]); if (i >= size) { d[i] = 0; d[i + 1] = 0; } } }