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- /*
- ==============================================================================
-
- This file is part of the JUCE library.
- Copyright (c) 2022 - Raw Material Software Limited
-
- JUCE is an open source library subject to commercial or open-source
- licensing.
-
- By using JUCE, you agree to the terms of both the JUCE 7 End-User License
- Agreement and JUCE Privacy Policy.
-
- End User License Agreement: www.juce.com/juce-7-licence
- Privacy Policy: www.juce.com/juce-privacy-policy
-
- Or: You may also use this code under the terms of the GPL v3 (see
- www.gnu.org/licenses).
-
- JUCE IS PROVIDED "AS IS" WITHOUT ANY WARRANTY, AND ALL WARRANTIES, WHETHER
- EXPRESSED OR IMPLIED, INCLUDING MERCHANTABILITY AND FITNESS FOR PURPOSE, ARE
- DISCLAIMED.
-
- ==============================================================================
- */
-
- namespace juce
- {
- namespace dsp
- {
-
- struct FFT::Instance
- {
- virtual ~Instance() = default;
- virtual void perform (const Complex<float>* input, Complex<float>* output, bool inverse) const noexcept = 0;
- virtual void performRealOnlyForwardTransform (float*, bool) const noexcept = 0;
- virtual void performRealOnlyInverseTransform (float*) const noexcept = 0;
- };
-
- struct FFT::Engine
- {
- Engine (int priorityToUse) : enginePriority (priorityToUse)
- {
- auto& list = getEngines();
- list.add (this);
- std::sort (list.begin(), list.end(), [] (Engine* a, Engine* b) { return b->enginePriority < a->enginePriority; });
- }
-
- virtual ~Engine() = default;
-
- virtual FFT::Instance* create (int order) const = 0;
-
- //==============================================================================
- static FFT::Instance* createBestEngineForPlatform (int order)
- {
- for (auto* engine : getEngines())
- if (auto* instance = engine->create (order))
- return instance;
-
- jassertfalse; // This should never happen as the fallback engine should always work!
- return nullptr;
- }
-
- private:
- static Array<Engine*>& getEngines()
- {
- static Array<Engine*> engines;
- return engines;
- }
-
- int enginePriority; // used so that faster engines have priority over slower ones
- };
-
- template <typename InstanceToUse>
- struct FFT::EngineImpl : public FFT::Engine
- {
- EngineImpl() : FFT::Engine (InstanceToUse::priority) {}
- FFT::Instance* create (int order) const override { return InstanceToUse::create (order); }
- };
-
- //==============================================================================
- //==============================================================================
- struct FFTFallback : public FFT::Instance
- {
- // this should have the least priority of all engines
- static constexpr int priority = -1;
-
- static FFTFallback* create (int order)
- {
- return new FFTFallback (order);
- }
-
- FFTFallback (int order)
- {
- configForward.reset (new FFTConfig (1 << order, false));
- configInverse.reset (new FFTConfig (1 << order, true));
-
- size = 1 << order;
- }
-
- void perform (const Complex<float>* input, Complex<float>* output, bool inverse) const noexcept override
- {
- if (size == 1)
- {
- *output = *input;
- return;
- }
-
- const SpinLock::ScopedLockType sl(processLock);
-
- jassert (configForward != nullptr);
-
- if (inverse)
- {
- configInverse->perform (input, output);
-
- const float scaleFactor = 1.0f / (float) size;
-
- for (int i = 0; i < size; ++i)
- output[i] *= scaleFactor;
- }
- else
- {
- configForward->perform (input, output);
- }
- }
-
- const size_t maxFFTScratchSpaceToAlloca = 256 * 1024;
-
- void performRealOnlyForwardTransform (float* d, bool) const noexcept override
- {
- if (size == 1)
- return;
-
- const size_t scratchSize = 16 + (size_t) size * sizeof (Complex<float>);
-
- if (scratchSize < maxFFTScratchSpaceToAlloca)
- {
- JUCE_BEGIN_IGNORE_WARNINGS_MSVC (6255)
- performRealOnlyForwardTransform (static_cast<Complex<float>*> (alloca (scratchSize)), d);
- JUCE_END_IGNORE_WARNINGS_MSVC
- }
- else
- {
- HeapBlock<char> heapSpace (scratchSize);
- performRealOnlyForwardTransform (unalignedPointerCast<Complex<float>*> (heapSpace.getData()), d);
- }
- }
-
- void performRealOnlyInverseTransform (float* d) const noexcept override
- {
- if (size == 1)
- return;
-
- const size_t scratchSize = 16 + (size_t) size * sizeof (Complex<float>);
-
- if (scratchSize < maxFFTScratchSpaceToAlloca)
- {
- JUCE_BEGIN_IGNORE_WARNINGS_MSVC (6255)
- performRealOnlyInverseTransform (static_cast<Complex<float>*> (alloca (scratchSize)), d);
- JUCE_END_IGNORE_WARNINGS_MSVC
- }
- else
- {
- HeapBlock<char> heapSpace (scratchSize);
- performRealOnlyInverseTransform (unalignedPointerCast<Complex<float>*> (heapSpace.getData()), d);
- }
- }
-
- void performRealOnlyForwardTransform (Complex<float>* scratch, float* d) const noexcept
- {
- for (int i = 0; i < size; ++i)
- scratch[i] = { d[i], 0 };
-
- perform (scratch, reinterpret_cast<Complex<float>*> (d), false);
- }
-
- void performRealOnlyInverseTransform (Complex<float>* scratch, float* d) const noexcept
- {
- auto* input = reinterpret_cast<Complex<float>*> (d);
-
- for (int i = size >> 1; i < size; ++i)
- input[i] = std::conj (input[size - i]);
-
- perform (input, scratch, true);
-
- for (int i = 0; i < size; ++i)
- {
- d[i] = scratch[i].real();
- d[i + size] = scratch[i].imag();
- }
- }
-
- //==============================================================================
- struct FFTConfig
- {
- FFTConfig (int sizeOfFFT, bool isInverse)
- : fftSize (sizeOfFFT), inverse (isInverse), twiddleTable ((size_t) sizeOfFFT)
- {
- auto inverseFactor = (inverse ? 2.0 : -2.0) * MathConstants<double>::pi / (double) fftSize;
-
- if (fftSize <= 4)
- {
- for (int i = 0; i < fftSize; ++i)
- {
- auto phase = i * inverseFactor;
-
- twiddleTable[i] = { (float) std::cos (phase),
- (float) std::sin (phase) };
- }
- }
- else
- {
- for (int i = 0; i < fftSize / 4; ++i)
- {
- auto phase = i * inverseFactor;
-
- twiddleTable[i] = { (float) std::cos (phase),
- (float) std::sin (phase) };
- }
-
- for (int i = fftSize / 4; i < fftSize / 2; ++i)
- {
- auto other = twiddleTable[i - fftSize / 4];
-
- twiddleTable[i] = { inverse ? -other.imag() : other.imag(),
- inverse ? other.real() : -other.real() };
- }
-
- twiddleTable[fftSize / 2].real (-1.0f);
- twiddleTable[fftSize / 2].imag (0.0f);
-
- for (int i = fftSize / 2; i < fftSize; ++i)
- {
- auto index = fftSize / 2 - (i - fftSize / 2);
- twiddleTable[i] = conj(twiddleTable[index]);
- }
- }
-
- auto 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<float>* input, Complex<float>* output) const noexcept
- {
- perform (input, output, 1, 1, factors);
- }
-
- const int fftSize;
- const bool inverse;
-
- struct Factor { int radix, length; };
- Factor factors[32];
- HeapBlock<Complex<float>> twiddleTable;
-
- void perform (const Complex<float>* input, Complex<float>* output, int stride, int strideIn, const Factor* facs) const noexcept
- {
- auto factor = *facs++;
- auto* originalOutput = output;
- auto* 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<float>* data, 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;
- }
-
- JUCE_BEGIN_IGNORE_WARNINGS_MSVC (6255)
- auto* scratch = static_cast<Complex<float>*> (alloca ((size_t) factor.radix * sizeof (Complex<float>)));
- JUCE_END_IGNORE_WARNINGS_MSVC
-
- for (int i = 0; i < factor.length; ++i)
- {
- for (int k = i, q1 = 0; q1 < factor.radix; ++q1)
- {
- JUCE_BEGIN_IGNORE_WARNINGS_MSVC (6386)
- scratch[q1] = data[k];
- JUCE_END_IGNORE_WARNINGS_MSVC
- 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;
-
- JUCE_BEGIN_IGNORE_WARNINGS_MSVC (6385)
- data[k] += scratch[q] * twiddleTable[twiddleIndex];
- JUCE_END_IGNORE_WARNINGS_MSVC
- }
-
- k += factor.length;
- }
- }
- }
-
- void butterfly2 (Complex<float>* data, const int stride, const int length) const noexcept
- {
- auto* dataEnd = data + length;
- auto* tw = twiddleTable.getData();
-
- for (int i = length; --i >= 0;)
- {
- auto s = *dataEnd;
- s *= (*tw);
- tw += stride;
- *dataEnd++ = *data - s;
- *data++ += s;
- }
- }
-
- void butterfly4 (Complex<float>* data, const int stride, const int length) const noexcept
- {
- auto lengthX2 = length * 2;
- auto lengthX3 = length * 3;
-
- auto strideX2 = stride * 2;
- auto strideX3 = stride * 3;
-
- auto* twiddle1 = twiddleTable.getData();
- auto* twiddle2 = twiddle1;
- auto* twiddle3 = twiddle1;
-
- for (int i = length; --i >= 0;)
- {
- auto s0 = data[length] * *twiddle1;
- auto s1 = data[lengthX2] * *twiddle2;
- auto s2 = data[lengthX3] * *twiddle3;
- auto s3 = s0; s3 += s2;
- auto s4 = s0; s4 -= s2;
- auto s5 = *data; s5 -= s1;
-
- *data += s1;
- data[lengthX2] = *data;
- data[lengthX2] -= s3;
- twiddle1 += stride;
- twiddle2 += strideX2;
- twiddle3 += strideX3;
- *data += s3;
-
- if (inverse)
- {
- data[length] = { s5.real() - s4.imag(),
- s5.imag() + s4.real() };
-
- data[lengthX3] = { s5.real() + s4.imag(),
- s5.imag() - s4.real() };
- }
- else
- {
- data[length] = { s5.real() + s4.imag(),
- s5.imag() - s4.real() };
-
- data[lengthX3] = { s5.real() - s4.imag(),
- s5.imag() + s4.real() };
- }
-
- ++data;
- }
- }
-
- JUCE_DECLARE_NON_COPYABLE_WITH_LEAK_DETECTOR (FFTConfig)
- };
-
- //==============================================================================
- SpinLock processLock;
- std::unique_ptr<FFTConfig> configForward, configInverse;
- int size;
- };
-
- FFT::EngineImpl<FFTFallback> fftFallback;
-
- //==============================================================================
- //==============================================================================
- #if (JUCE_MAC || JUCE_IOS) && JUCE_USE_VDSP_FRAMEWORK
- struct AppleFFT : public FFT::Instance
- {
- static constexpr int priority = 5;
-
- static AppleFFT* create (int order)
- {
- return new AppleFFT (order);
- }
-
- AppleFFT (int orderToUse)
- : order (static_cast<vDSP_Length> (orderToUse)),
- fftSetup (vDSP_create_fftsetup (order, 2)),
- forwardNormalisation (0.5f),
- inverseNormalisation (1.0f / static_cast<float> (1 << order))
- {}
-
- ~AppleFFT() override
- {
- if (fftSetup != nullptr)
- {
- vDSP_destroy_fftsetup (fftSetup);
- fftSetup = nullptr;
- }
- }
-
- void perform (const Complex<float>* input, Complex<float>* output, bool inverse) const noexcept override
- {
- auto size = (1 << order);
-
- DSPSplitComplex splitInput (toSplitComplex (const_cast<Complex<float>*> (input)));
- DSPSplitComplex splitOutput (toSplitComplex (output));
-
- vDSP_fft_zop (fftSetup, &splitInput, 2, &splitOutput, 2,
- order, inverse ? kFFTDirection_Inverse : kFFTDirection_Forward);
-
- float factor = (inverse ? inverseNormalisation : forwardNormalisation * 2.0f);
- vDSP_vsmul ((float*) output, 1, &factor, (float*) output, 1, static_cast<size_t> (size << 1));
- }
-
- void performRealOnlyForwardTransform (float* inoutData, bool ignoreNegativeFreqs) const noexcept override
- {
- auto size = (1 << order);
- auto* inout = reinterpret_cast<Complex<float>*> (inoutData);
- auto splitInOut (toSplitComplex (inout));
-
- inoutData[size] = 0.0f;
- vDSP_fft_zrip (fftSetup, &splitInOut, 2, order, kFFTDirection_Forward);
- vDSP_vsmul (inoutData, 1, &forwardNormalisation, inoutData, 1, static_cast<size_t> (size << 1));
-
- mirrorResult (inout, ignoreNegativeFreqs);
- }
-
- void performRealOnlyInverseTransform (float* inoutData) const noexcept override
- {
- auto* inout = reinterpret_cast<Complex<float>*> (inoutData);
- auto size = (1 << order);
- auto splitInOut (toSplitComplex (inout));
-
- // Imaginary part of nyquist and DC frequencies are always zero
- // so Apple uses the imaginary part of the DC frequency to store
- // the real part of the nyquist frequency
- if (size != 1)
- inout[0] = Complex<float> (inout[0].real(), inout[size >> 1].real());
-
- vDSP_fft_zrip (fftSetup, &splitInOut, 2, order, kFFTDirection_Inverse);
- vDSP_vsmul (inoutData, 1, &inverseNormalisation, inoutData, 1, static_cast<size_t> (size << 1));
- vDSP_vclr (inoutData + size, 1, static_cast<size_t> (size));
- }
-
- private:
- //==============================================================================
- void mirrorResult (Complex<float>* out, bool ignoreNegativeFreqs) const noexcept
- {
- auto size = (1 << order);
- auto i = size >> 1;
-
- // Imaginary part of nyquist and DC frequencies are always zero
- // so Apple uses the imaginary part of the DC frequency to store
- // the real part of the nyquist frequency
- out[i++] = { out[0].imag(), 0.0 };
- out[0] = { out[0].real(), 0.0 };
-
- if (! ignoreNegativeFreqs)
- for (; i < size; ++i)
- out[i] = std::conj (out[size - i]);
- }
-
- static DSPSplitComplex toSplitComplex (Complex<float>* data) noexcept
- {
- // this assumes that Complex interleaves real and imaginary parts
- // and is tightly packed.
- return { reinterpret_cast<float*> (data),
- reinterpret_cast<float*> (data) + 1};
- }
-
- //==============================================================================
- vDSP_Length order;
- FFTSetup fftSetup;
- float forwardNormalisation, inverseNormalisation;
- };
-
- FFT::EngineImpl<AppleFFT> appleFFT;
- #endif
-
- //==============================================================================
- //==============================================================================
- #if JUCE_DSP_USE_SHARED_FFTW || JUCE_DSP_USE_STATIC_FFTW
-
- #if JUCE_DSP_USE_STATIC_FFTW
- extern "C"
- {
- void* fftwf_plan_dft_1d (int, void*, void*, int, int);
- void* fftwf_plan_dft_r2c_1d (int, void*, void*, int);
- void* fftwf_plan_dft_c2r_1d (int, void*, void*, int);
- void fftwf_destroy_plan (void*);
- void fftwf_execute_dft (void*, void*, void*);
- void fftwf_execute_dft_r2c (void*, void*, void*);
- void fftwf_execute_dft_c2r (void*, void*, void*);
- }
- #endif
-
- struct FFTWImpl : public FFT::Instance
- {
- #if JUCE_DSP_USE_STATIC_FFTW
- // if the JUCE developer has gone through the hassle of statically
- // linking in fftw, they probably want to use it
- static constexpr int priority = 10;
- #else
- static constexpr int priority = 3;
- #endif
-
- struct FFTWPlan;
- using FFTWPlanRef = FFTWPlan*;
-
- enum
- {
- measure = 0,
- unaligned = (1 << 1),
- estimate = (1 << 6)
- };
-
- struct Symbols
- {
- FFTWPlanRef (*plan_dft_fftw) (unsigned, Complex<float>*, Complex<float>*, int, unsigned);
- FFTWPlanRef (*plan_r2c_fftw) (unsigned, float*, Complex<float>*, unsigned);
- FFTWPlanRef (*plan_c2r_fftw) (unsigned, Complex<float>*, float*, unsigned);
- void (*destroy_fftw) (FFTWPlanRef);
-
- void (*execute_dft_fftw) (FFTWPlanRef, const Complex<float>*, Complex<float>*);
- void (*execute_r2c_fftw) (FFTWPlanRef, float*, Complex<float>*);
- void (*execute_c2r_fftw) (FFTWPlanRef, Complex<float>*, float*);
-
- #if JUCE_DSP_USE_STATIC_FFTW
- template <typename FuncPtr, typename ActualSymbolType>
- static bool symbol (FuncPtr& dst, ActualSymbolType sym)
- {
- dst = reinterpret_cast<FuncPtr> (sym);
- return true;
- }
- #else
- template <typename FuncPtr>
- static bool symbol (DynamicLibrary& lib, FuncPtr& dst, const char* name)
- {
- dst = reinterpret_cast<FuncPtr> (lib.getFunction (name));
- return (dst != nullptr);
- }
- #endif
- };
-
- static FFTWImpl* create (int order)
- {
- DynamicLibrary lib;
-
- #if ! JUCE_DSP_USE_STATIC_FFTW
- #if JUCE_MAC
- auto libName = "libfftw3f.dylib";
- #elif JUCE_WINDOWS
- auto libName = "libfftw3f.dll";
- #else
- auto libName = "libfftw3f.so";
- #endif
-
- if (lib.open (libName))
- #endif
- {
- Symbols symbols;
-
- #if JUCE_DSP_USE_STATIC_FFTW
- if (! Symbols::symbol (symbols.plan_dft_fftw, fftwf_plan_dft_1d)) return nullptr;
- if (! Symbols::symbol (symbols.plan_r2c_fftw, fftwf_plan_dft_r2c_1d)) return nullptr;
- if (! Symbols::symbol (symbols.plan_c2r_fftw, fftwf_plan_dft_c2r_1d)) return nullptr;
- if (! Symbols::symbol (symbols.destroy_fftw, fftwf_destroy_plan)) return nullptr;
-
- if (! Symbols::symbol (symbols.execute_dft_fftw, fftwf_execute_dft)) return nullptr;
- if (! Symbols::symbol (symbols.execute_r2c_fftw, fftwf_execute_dft_r2c)) return nullptr;
- if (! Symbols::symbol (symbols.execute_c2r_fftw, fftwf_execute_dft_c2r)) return nullptr;
- #else
- if (! Symbols::symbol (lib, symbols.plan_dft_fftw, "fftwf_plan_dft_1d")) return nullptr;
- if (! Symbols::symbol (lib, symbols.plan_r2c_fftw, "fftwf_plan_dft_r2c_1d")) return nullptr;
- if (! Symbols::symbol (lib, symbols.plan_c2r_fftw, "fftwf_plan_dft_c2r_1d")) return nullptr;
- if (! Symbols::symbol (lib, symbols.destroy_fftw, "fftwf_destroy_plan")) return nullptr;
-
- if (! Symbols::symbol (lib, symbols.execute_dft_fftw, "fftwf_execute_dft")) return nullptr;
- if (! Symbols::symbol (lib, symbols.execute_r2c_fftw, "fftwf_execute_dft_r2c")) return nullptr;
- if (! Symbols::symbol (lib, symbols.execute_c2r_fftw, "fftwf_execute_dft_c2r")) return nullptr;
- #endif
-
- return new FFTWImpl (static_cast<size_t> (order), std::move (lib), symbols);
- }
-
- return nullptr;
- }
-
- FFTWImpl (size_t orderToUse, DynamicLibrary&& libraryToUse, const Symbols& symbols)
- : fftwLibrary (std::move (libraryToUse)), fftw (symbols), order (static_cast<size_t> (orderToUse))
- {
- ScopedLock lock (getFFTWPlanLock());
-
- auto n = (1u << order);
- HeapBlock<Complex<float>> in (n), out (n);
-
- c2cForward = fftw.plan_dft_fftw (n, in.getData(), out.getData(), -1, unaligned | estimate);
- c2cInverse = fftw.plan_dft_fftw (n, in.getData(), out.getData(), +1, unaligned | estimate);
-
- r2c = fftw.plan_r2c_fftw (n, (float*) in.getData(), in.getData(), unaligned | estimate);
- c2r = fftw.plan_c2r_fftw (n, in.getData(), (float*) in.getData(), unaligned | estimate);
- }
-
- ~FFTWImpl() override
- {
- ScopedLock lock (getFFTWPlanLock());
-
- fftw.destroy_fftw (c2cForward);
- fftw.destroy_fftw (c2cInverse);
- fftw.destroy_fftw (r2c);
- fftw.destroy_fftw (c2r);
- }
-
- void perform (const Complex<float>* input, Complex<float>* output, bool inverse) const noexcept override
- {
- if (inverse)
- {
- auto n = (1u << order);
- fftw.execute_dft_fftw (c2cInverse, input, output);
- FloatVectorOperations::multiply ((float*) output, 1.0f / static_cast<float> (n), (int) n << 1);
- }
- else
- {
- fftw.execute_dft_fftw (c2cForward, input, output);
- }
- }
-
- void performRealOnlyForwardTransform (float* inputOutputData, bool ignoreNegativeFreqs) const noexcept override
- {
- if (order == 0)
- return;
-
- auto* out = reinterpret_cast<Complex<float>*> (inputOutputData);
-
- fftw.execute_r2c_fftw (r2c, inputOutputData, out);
-
- auto size = (1 << order);
-
- if (! ignoreNegativeFreqs)
- for (int i = size >> 1; i < size; ++i)
- out[i] = std::conj (out[size - i]);
- }
-
- void performRealOnlyInverseTransform (float* inputOutputData) const noexcept override
- {
- auto n = (1u << order);
-
- fftw.execute_c2r_fftw (c2r, (Complex<float>*) inputOutputData, inputOutputData);
- FloatVectorOperations::multiply ((float*) inputOutputData, 1.0f / static_cast<float> (n), (int) n);
- }
-
- //==============================================================================
- // fftw's plan_* and destroy_* methods are NOT thread safe. So we need to share
- // a lock between all instances of FFTWImpl
- static CriticalSection& getFFTWPlanLock() noexcept
- {
- static CriticalSection cs;
- return cs;
- }
-
- //==============================================================================
- DynamicLibrary fftwLibrary;
- Symbols fftw;
- size_t order;
-
- FFTWPlanRef c2cForward, c2cInverse, r2c, c2r;
- };
-
- FFT::EngineImpl<FFTWImpl> fftwEngine;
- #endif
-
- //==============================================================================
- //==============================================================================
- #if JUCE_DSP_USE_INTEL_MKL
- struct IntelFFT : public FFT::Instance
- {
- static constexpr int priority = 8;
-
- static bool succeeded (MKL_LONG status) noexcept { return status == 0; }
-
- static IntelFFT* create (int orderToUse)
- {
- DFTI_DESCRIPTOR_HANDLE mklc2c, mklc2r;
-
- if (DftiCreateDescriptor (&mklc2c, DFTI_SINGLE, DFTI_COMPLEX, 1, 1 << orderToUse) == 0)
- {
- if (succeeded (DftiSetValue (mklc2c, DFTI_PLACEMENT, DFTI_NOT_INPLACE))
- && succeeded (DftiSetValue (mklc2c, DFTI_BACKWARD_SCALE, 1.0f / static_cast<float> (1 << orderToUse)))
- && succeeded (DftiCommitDescriptor (mklc2c)))
- {
- if (succeeded (DftiCreateDescriptor (&mklc2r, DFTI_SINGLE, DFTI_REAL, 1, 1 << orderToUse)))
- {
- if (succeeded (DftiSetValue (mklc2r, DFTI_PLACEMENT, DFTI_INPLACE))
- && succeeded (DftiSetValue (mklc2r, DFTI_BACKWARD_SCALE, 1.0f / static_cast<float> (1 << orderToUse)))
- && succeeded (DftiCommitDescriptor (mklc2r)))
- {
- return new IntelFFT (static_cast<size_t> (orderToUse), mklc2c, mklc2r);
- }
-
- DftiFreeDescriptor (&mklc2r);
- }
- }
-
- DftiFreeDescriptor (&mklc2c);
- }
-
- return {};
- }
-
- IntelFFT (size_t orderToUse, DFTI_DESCRIPTOR_HANDLE c2cToUse, DFTI_DESCRIPTOR_HANDLE cr2ToUse)
- : order (orderToUse), c2c (c2cToUse), c2r (cr2ToUse)
- {}
-
- ~IntelFFT() override
- {
- DftiFreeDescriptor (&c2c);
- DftiFreeDescriptor (&c2r);
- }
-
- void perform (const Complex<float>* input, Complex<float>* output, bool inverse) const noexcept override
- {
- if (inverse)
- DftiComputeBackward (c2c, (void*) input, output);
- else
- DftiComputeForward (c2c, (void*) input, output);
- }
-
- void performRealOnlyForwardTransform (float* inputOutputData, bool ignoreNegativeFreqs) const noexcept override
- {
- if (order == 0)
- return;
-
- DftiComputeForward (c2r, inputOutputData);
-
- auto* out = reinterpret_cast<Complex<float>*> (inputOutputData);
- auto size = (1 << order);
-
- if (! ignoreNegativeFreqs)
- for (int i = size >> 1; i < size; ++i)
- out[i] = std::conj (out[size - i]);
- }
-
- void performRealOnlyInverseTransform (float* inputOutputData) const noexcept override
- {
- DftiComputeBackward (c2r, inputOutputData);
- }
-
- size_t order;
- DFTI_DESCRIPTOR_HANDLE c2c, c2r;
- };
-
- FFT::EngineImpl<IntelFFT> fftwEngine;
- #endif
-
- //==============================================================================
- //==============================================================================
- // Visual Studio should define no more than one of these, depending on the
- // setting at 'Project' > 'Properties' > 'Configuration Properties' > 'Intel
- // Performance Libraries' > 'Use Intel(R) IPP'
- #if _IPP_SEQUENTIAL_STATIC || _IPP_SEQUENTIAL_DYNAMIC || _IPP_PARALLEL_STATIC || _IPP_PARALLEL_DYNAMIC
- class IntelPerformancePrimitivesFFT : public FFT::Instance
- {
- public:
- static constexpr auto priority = 9;
-
- static IntelPerformancePrimitivesFFT* create (const int order)
- {
- auto complexContext = Context<ComplexTraits>::create (order);
- auto realContext = Context<RealTraits> ::create (order);
-
- if (complexContext.isValid() && realContext.isValid())
- return new IntelPerformancePrimitivesFFT (std::move (complexContext), std::move (realContext), order);
-
- return {};
- }
-
- void perform (const Complex<float>* input, Complex<float>* output, bool inverse) const noexcept override
- {
- if (inverse)
- {
- ippsFFTInv_CToC_32fc (reinterpret_cast<const Ipp32fc*> (input),
- reinterpret_cast<Ipp32fc*> (output),
- cplx.specPtr,
- cplx.workBuf.get());
- }
- else
- {
- ippsFFTFwd_CToC_32fc (reinterpret_cast<const Ipp32fc*> (input),
- reinterpret_cast<Ipp32fc*> (output),
- cplx.specPtr,
- cplx.workBuf.get());
- }
- }
-
- void performRealOnlyForwardTransform (float* inoutData, bool ignoreNegativeFreqs) const noexcept override
- {
- ippsFFTFwd_RToCCS_32f_I (inoutData, real.specPtr, real.workBuf.get());
-
- if (order == 0)
- return;
-
- auto* out = reinterpret_cast<Complex<float>*> (inoutData);
- const auto size = (1 << order);
-
- if (! ignoreNegativeFreqs)
- for (auto i = size >> 1; i < size; ++i)
- out[i] = std::conj (out[size - i]);
- }
-
- void performRealOnlyInverseTransform (float* inoutData) const noexcept override
- {
- ippsFFTInv_CCSToR_32f_I (inoutData, real.specPtr, real.workBuf.get());
- }
-
- private:
- static constexpr auto flag = IPP_FFT_DIV_INV_BY_N;
- static constexpr auto hint = ippAlgHintFast;
-
- struct IppFree
- {
- template <typename Ptr>
- void operator() (Ptr* ptr) const noexcept { ippsFree (ptr); }
- };
-
- using IppPtr = std::unique_ptr<Ipp8u[], IppFree>;
-
- template <typename Traits>
- struct Context
- {
- using SpecPtr = typename Traits::Spec*;
-
- static Context create (const int order)
- {
- int specSize = 0, initSize = 0, workSize = 0;
-
- if (Traits::getSize (order, flag, hint, &specSize, &initSize, &workSize) != ippStsNoErr)
- return {};
-
- const auto initBuf = IppPtr (ippsMalloc_8u (initSize));
- auto specBuf = IppPtr (ippsMalloc_8u (specSize));
- SpecPtr specPtr = nullptr;
-
- if (Traits::init (&specPtr, order, flag, hint, specBuf.get(), initBuf.get()) != ippStsNoErr)
- return {};
-
- return { std::move (specBuf), IppPtr (ippsMalloc_8u (workSize)), specPtr };
- }
-
- Context() noexcept = default;
-
- Context (IppPtr&& spec, IppPtr&& work, typename Traits::Spec* ptr) noexcept
- : specBuf (std::move (spec)), workBuf (std::move (work)), specPtr (ptr)
- {}
-
- bool isValid() const noexcept { return specPtr != nullptr; }
-
- IppPtr specBuf, workBuf;
- SpecPtr specPtr = nullptr;
- };
-
- struct ComplexTraits
- {
- static constexpr auto getSize = ippsFFTGetSize_C_32fc;
- static constexpr auto init = ippsFFTInit_C_32fc;
- using Spec = IppsFFTSpec_C_32fc;
- };
-
- struct RealTraits
- {
- static constexpr auto getSize = ippsFFTGetSize_R_32f;
- static constexpr auto init = ippsFFTInit_R_32f;
- using Spec = IppsFFTSpec_R_32f;
- };
-
- IntelPerformancePrimitivesFFT (Context<ComplexTraits>&& complexToUse,
- Context<RealTraits>&& realToUse,
- const int orderToUse)
- : cplx (std::move (complexToUse)),
- real (std::move (realToUse)),
- order (orderToUse)
- {}
-
- Context<ComplexTraits> cplx;
- Context<RealTraits> real;
- int order = 0;
- };
-
- FFT::EngineImpl<IntelPerformancePrimitivesFFT> intelPerformancePrimitivesFFT;
- #endif
-
- //==============================================================================
- //==============================================================================
- FFT::FFT (int order)
- : engine (FFT::Engine::createBestEngineForPlatform (order)),
- size (1 << order)
- {
- }
-
- FFT::FFT (FFT&&) noexcept = default;
-
- FFT& FFT::operator= (FFT&&) noexcept = default;
-
- FFT::~FFT() = default;
-
- void FFT::perform (const Complex<float>* input, Complex<float>* output, bool inverse) const noexcept
- {
- if (engine != nullptr)
- engine->perform (input, output, inverse);
- }
-
- void FFT::performRealOnlyForwardTransform (float* inputOutputData, bool ignoreNegativeFreqs) const noexcept
- {
- if (engine != nullptr)
- engine->performRealOnlyForwardTransform (inputOutputData, ignoreNegativeFreqs);
- }
-
- void FFT::performRealOnlyInverseTransform (float* inputOutputData) const noexcept
- {
- if (engine != nullptr)
- engine->performRealOnlyInverseTransform (inputOutputData);
- }
-
- void FFT::performFrequencyOnlyForwardTransform (float* inputOutputData, bool ignoreNegativeFreqs) const noexcept
- {
- if (size == 1)
- return;
-
- performRealOnlyForwardTransform (inputOutputData, ignoreNegativeFreqs);
- auto* out = reinterpret_cast<Complex<float>*> (inputOutputData);
-
- const auto limit = ignoreNegativeFreqs ? (size / 2) + 1 : size;
-
- for (int i = 0; i < limit; ++i)
- inputOutputData[i] = std::abs (out[i]);
-
- zeromem (inputOutputData + limit, static_cast<size_t> (size * 2 - limit) * sizeof (float));
- }
-
- } // namespace dsp
- } // namespace juce
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