// // Copyright © 2021 Arm Ltd and Contributors. All rights reserved. // SPDX-License-Identifier: MIT // #include "MathUtils.hpp" #include #include #include #include #include #include "Wav2LetterPreprocessor.hpp" #include "Wav2LetterMFCC.hpp" float Wav2LetterPreprocessor::GetMean(Array2d& vec) { return MathUtils::MeanF32(vec.begin(), vec.totalSize()); } float Wav2LetterPreprocessor::GetStdDev(Array2d& vec, const float mean) { return MathUtils::StdDevF32(vec.begin(), vec.totalSize(), mean); } void Wav2LetterPreprocessor::NormaliseVec(Array2d& vec) { auto mean = Wav2LetterPreprocessor::GetMean(vec); auto stddev = Wav2LetterPreprocessor::GetStdDev(vec, mean); if (stddev == 0) { std::fill(vec.begin(), vec.end(), 0); } else { const float stddevInv = 1.f/stddev; const float normalisedMean = mean/stddev; auto NormalisingFunction = [=](float &value) { value = value * stddevInv - normalisedMean; }; std::for_each(vec.begin(), vec.end(), NormalisingFunction); } } void Wav2LetterPreprocessor::Normalise() { Wav2LetterPreprocessor::NormaliseVec(this->m_mfccBuf); Wav2LetterPreprocessor::NormaliseVec(this->m_delta1Buf); Wav2LetterPreprocessor::NormaliseVec(this->m_delta2Buf); } float Wav2LetterPreprocessor::GetQuantElem( const float elem, const float quantScale, const int quantOffset, const float minVal, const float maxVal) { float val = std::round((elem/quantScale) + quantOffset); float returnVal = std::min(std::max(val, minVal), maxVal); return returnVal; } bool Wav2LetterPreprocessor::Invoke(const float* audioData, const uint32_t audioDataLen, std::vector& output, int quantOffset, float quantScale) { this->m_window = SlidingWindow( audioData, audioDataLen, this->m_windowLen, this->m_windowStride); uint32_t mfccBufIdx = 0; // Init buffers with 0 std::fill(m_mfccBuf.begin(), m_mfccBuf.end(), 0.f); std::fill(m_delta1Buf.begin(), m_delta1Buf.end(), 0.f); std::fill(m_delta2Buf.begin(), m_delta2Buf.end(), 0.f); // While we can slide over the window while (this->m_window.HasNext()) { const float* mfccWindow = this->m_window.Next(); auto mfccAudioData = std::vector( mfccWindow, mfccWindow + this->m_windowLen); auto mfcc = this->m_mfcc->MfccCompute(mfccAudioData); for (size_t i = 0; i < this->m_mfccBuf.size(0); ++i) { this->m_mfccBuf(i, mfccBufIdx) = mfcc[i]; } ++mfccBufIdx; } // Pad MFCC if needed by repeating last feature vector while (mfccBufIdx != this->m_mfcc->m_params.m_numMfccVectors) { memcpy(&this->m_mfccBuf(0, mfccBufIdx), &this->m_mfccBuf(0, mfccBufIdx - 1), sizeof(float) * this->m_mfcc->m_params.m_numMfccFeatures); ++mfccBufIdx; } // Compute first and second order deltas from MFCCs Wav2LetterPreprocessor::ComputeDeltas(this->m_mfccBuf, this->m_delta1Buf, this->m_delta2Buf); // Normalise this->Normalise(); return this->Quantise(output.data(), quantOffset, quantScale); } bool Wav2LetterPreprocessor::ComputeDeltas(Array2d& mfcc, Array2d& delta1, Array2d& delta2) { const std::vector delta1Coeffs = {6.66666667e-02, 5.00000000e-02, 3.33333333e-02, 1.66666667e-02, -3.46944695e-18, -1.66666667e-02, -3.33333333e-02, -5.00000000e-02, -6.66666667e-02}; const std::vector delta2Coeffs = {0.06060606, 0.01515152, -0.01731602, -0.03679654, -0.04329004, -0.03679654, -0.01731602, 0.01515152, 0.06060606}; if (delta1.size(0) == 0 || delta2.size(0) != delta1.size(0) || mfcc.size(0) == 0 || mfcc.size(1) == 0) { return false; } // Get the middle index; coeff vec len should always be odd const size_t coeffLen = delta1Coeffs.size(); const size_t fMidIdx = (coeffLen - 1)/2; const size_t numFeatures = mfcc.size(0); const size_t numFeatVectors = mfcc.size(1); // iterate through features in MFCC vector for (size_t i = 0; i < numFeatures; ++i) { /* for each feature, iterate through time (t) samples representing feature evolution and * calculate d/dt and d^2/dt^2, using 1d convolution with differential kernels. * Convolution padding = valid, result size is `time length - kernel length + 1`. * The result is padded with 0 from both sides to match the size of initial time samples data. * * For the small filter, conv1d implementation as a simple loop is efficient enough. * Filters of a greater size would need CMSIS-DSP functions to be used, like arm_fir_f32. */ for (size_t j = fMidIdx; j < numFeatVectors - fMidIdx; ++j) { float d1 = 0; float d2 = 0; const size_t mfccStIdx = j - fMidIdx; for (size_t k = 0, m = coeffLen - 1; k < coeffLen; ++k, --m) { d1 += mfcc(i,mfccStIdx + k) * delta1Coeffs[m]; d2 += mfcc(i,mfccStIdx + k) * delta2Coeffs[m]; } delta1(i,j) = d1; delta2(i,j) = d2; } } return true; } Wav2LetterPreprocessor::Wav2LetterPreprocessor(const uint32_t windowLen, const uint32_t windowStride, std::unique_ptr mfccInst): m_mfcc(std::move(mfccInst)), m_mfccBuf(m_mfcc->m_params.m_numMfccFeatures, m_mfcc->m_params.m_numMfccVectors), m_delta1Buf(m_mfcc->m_params.m_numMfccFeatures, m_mfcc->m_params.m_numMfccVectors), m_delta2Buf(m_mfcc->m_params.m_numMfccFeatures, m_mfcc->m_params.m_numMfccVectors), m_windowLen(windowLen), m_windowStride(windowStride) { if (m_mfcc->m_params.m_numMfccFeatures > 0 && windowLen > 0) { this->m_mfcc->Init(); } std::fill(m_mfccBuf.begin(), m_mfccBuf.end(), 0.f); }