source/use_case/asr/src/Wav2LetterMfcc.cc - ml/ethos-u/ml-embedded-evaluation-kit - Gitiles

 /*
  * Copyright (c) 2021 Arm Limited. All rights reserved.
  * SPDX-License-Identifier: Apache-2.0
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */
 #include "Wav2LetterMfcc.hpp"

 #include "PlatformMath.hpp"

 #include <cfloat>

 namespace arm {
 namespace app {
 namespace audio {

     bool Wav2LetterMFCC::ApplyMelFilterBank(
             std::vector<float>&                 fftVec,
             std::vector<std::vector<float>>&    melFilterBank,
             std::vector<uint32_t>&               filterBankFilterFirst,
             std::vector<uint32_t>&               filterBankFilterLast,
             std::vector<float>&                 melEnergies)
     {
         const size_t numBanks = melEnergies.size();

         if (numBanks != filterBankFilterFirst.size() ||
                 numBanks != filterBankFilterLast.size()) {
             printf_err("Unexpected filter bank lengths\n");
             return false;
         }

         for (size_t bin = 0; bin < numBanks; ++bin) {
             auto filterBankIter = melFilterBank[bin].begin();
             auto end = melFilterBank[bin].end();
             /* Avoid log of zero at later stages, same value used in librosa.
              * The number was used during our default wav2letter model training. */
             float melEnergy = 1e-10;
             const uint32_t firstIndex = filterBankFilterFirst[bin];
             const uint32_t lastIndex = std::min<uint32_t>(filterBankFilterLast[bin], fftVec.size() - 1);

             for (uint32_t i = firstIndex; i <= lastIndex && filterBankIter != end; ++i) {
                 melEnergy += (*filterBankIter++ * fftVec[i]);
             }

             melEnergies[bin] = melEnergy;
         }

         return true;
     }

     void Wav2LetterMFCC::ConvertToLogarithmicScale(
                             std::vector<float>& melEnergies)
     {
         float maxMelEnergy = -FLT_MAX;

         /* Container for natural logarithms of mel energies. */
         std::vector <float> vecLogEnergies(melEnergies.size(), 0.f);

         /* Because we are taking natural logs, we need to multiply by log10(e).
          * Also, for wav2letter model, we scale our log10 values by 10. */
         constexpr float multiplier = 10.0 *  /* Default scalar. */
                                       0.4342944819032518;  /* log10f(std::exp(1.0)) */

         /* Take log of the whole vector. */
         math::MathUtils::VecLogarithmF32(melEnergies, vecLogEnergies);

         /* Scale the log values and get the max. */
         for (auto iterM = melEnergies.begin(), iterL = vecLogEnergies.begin();
                   iterM != melEnergies.end() && iterL != vecLogEnergies.end(); ++iterM, ++iterL) {

             *iterM = *iterL * multiplier;

             /* Save the max mel energy. */
             if (*iterM > maxMelEnergy) {
                 maxMelEnergy = *iterM;
             }
         }

         /* Clamp the mel energies. */
         constexpr float maxDb = 80.0;
         const float clampLevelLowdB = maxMelEnergy - maxDb;
         for (float& melEnergy : melEnergies) {
             melEnergy = std::max(melEnergy, clampLevelLowdB);
         }
     }

     std::vector<float> Wav2LetterMFCC::CreateDCTMatrix(
                                         const int32_t inputLength,
                                         const int32_t coefficientCount)
     {
         std::vector<float> dctMatix(inputLength * coefficientCount);

         /* Orthonormal normalization. */
         const float normalizerK0 = 2 * math::MathUtils::SqrtF32(1.0f /
                                         static_cast<float>(4*inputLength));
         const float normalizer = 2 * math::MathUtils::SqrtF32(1.0f /
                                         static_cast<float>(2*inputLength));

         const float angleIncr = M_PI / inputLength;
         float angle = angleIncr;  /* We start using it at k = 1 loop. */

         /* First row of DCT will use normalizer K0. */
         for (int32_t n = 0; n < inputLength; ++n) {
             dctMatix[n] = normalizerK0  /* cos(0) = 1 */;
         }

         /* Second row (index = 1) onwards, we use standard normalizer. */
         for (int32_t k = 1, m = inputLength; k < coefficientCount; ++k, m += inputLength) {
             for (int32_t n = 0; n < inputLength; ++n) {
                 dctMatix[m+n] = normalizer *
                     math::MathUtils::CosineF32((n + 0.5f) * angle);
             }
             angle += angleIncr;
         }
         return dctMatix;
     }

     float Wav2LetterMFCC::GetMelFilterBankNormaliser(
                                     const float&    leftMel,
                                     const float&    rightMel,
                                     const bool      useHTKMethod)
     {
         /* Slaney normalization for mel weights. */
         return (2.0f / (MFCC::InverseMelScale(rightMel, useHTKMethod) -
                 MFCC::InverseMelScale(leftMel, useHTKMethod)));
     }

 } /* namespace audio */
 } /* namespace app */
 } /* namespace arm */
	/*
	* Copyright (c) 2021 Arm Limited. All rights reserved.
	* SPDX-License-Identifier: Apache-2.0
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/
	#include "Wav2LetterMfcc.hpp"

	#include "PlatformMath.hpp"

	#include <cfloat>

	namespace arm {
	namespace app {
	namespace audio {

	bool Wav2LetterMFCC::ApplyMelFilterBank(
	std::vector<float>& fftVec,
	std::vector<std::vector<float>>& melFilterBank,
	std::vector<uint32_t>& filterBankFilterFirst,
	std::vector<uint32_t>& filterBankFilterLast,
	std::vector<float>& melEnergies)
	{
	const size_t numBanks = melEnergies.size();

	if (numBanks != filterBankFilterFirst.size() \|\|
	numBanks != filterBankFilterLast.size()) {
	printf_err("Unexpected filter bank lengths\n");
	return false;
	}

	for (size_t bin = 0; bin < numBanks; ++bin) {
	auto filterBankIter = melFilterBank[bin].begin();
	auto end = melFilterBank[bin].end();
	/* Avoid log of zero at later stages, same value used in librosa.
	* The number was used during our default wav2letter model training. */
	float melEnergy = 1e-10;
	const uint32_t firstIndex = filterBankFilterFirst[bin];
	const uint32_t lastIndex = std::min<uint32_t>(filterBankFilterLast[bin], fftVec.size() - 1);

	for (uint32_t i = firstIndex; i <= lastIndex && filterBankIter != end; ++i) {
	melEnergy += (filterBankIter++ fftVec[i]);
	}

	melEnergies[bin] = melEnergy;
	}

	return true;
	}

	void Wav2LetterMFCC::ConvertToLogarithmicScale(
	std::vector<float>& melEnergies)
	{
	float maxMelEnergy = -FLT_MAX;

	/* Container for natural logarithms of mel energies. */
	std::vector <float> vecLogEnergies(melEnergies.size(), 0.f);

	/* Because we are taking natural logs, we need to multiply by log10(e).
	* Also, for wav2letter model, we scale our log10 values by 10. */
	constexpr float multiplier = 10.0 * /* Default scalar. */
	0.4342944819032518; /* log10f(std::exp(1.0)) */

	/* Take log of the whole vector. */
	math::MathUtils::VecLogarithmF32(melEnergies, vecLogEnergies);

	/* Scale the log values and get the max. */
	for (auto iterM = melEnergies.begin(), iterL = vecLogEnergies.begin();
	iterM != melEnergies.end() && iterL != vecLogEnergies.end(); ++iterM, ++iterL) {

	iterM = iterL * multiplier;

	/* Save the max mel energy. */
	if (*iterM > maxMelEnergy) {
	maxMelEnergy = *iterM;
	}
	}

	/* Clamp the mel energies. */
	constexpr float maxDb = 80.0;
	const float clampLevelLowdB = maxMelEnergy - maxDb;
	for (float& melEnergy : melEnergies) {
	melEnergy = std::max(melEnergy, clampLevelLowdB);
	}
	}

	std::vector<float> Wav2LetterMFCC::CreateDCTMatrix(
	const int32_t inputLength,
	const int32_t coefficientCount)
	{
	std::vector<float> dctMatix(inputLength * coefficientCount);

	/* Orthonormal normalization. */
	const float normalizerK0 = 2 * math::MathUtils::SqrtF32(1.0f /
	static_cast<float>(4*inputLength));
	const float normalizer = 2 * math::MathUtils::SqrtF32(1.0f /
	static_cast<float>(2*inputLength));

	const float angleIncr = M_PI / inputLength;
	float angle = angleIncr; /* We start using it at k = 1 loop. */

	/* First row of DCT will use normalizer K0. */
	for (int32_t n = 0; n < inputLength; ++n) {
	dctMatix[n] = normalizerK0 /* cos(0) = 1 */;
	}

	/* Second row (index = 1) onwards, we use standard normalizer. */
	for (int32_t k = 1, m = inputLength; k < coefficientCount; ++k, m += inputLength) {
	for (int32_t n = 0; n < inputLength; ++n) {
	dctMatix[m+n] = normalizer *
	math::MathUtils::CosineF32((n + 0.5f) * angle);
	}
	angle += angleIncr;
	}
	return dctMatix;
	}

	float Wav2LetterMFCC::GetMelFilterBankNormaliser(
	const float& leftMel,
	const float& rightMel,
	const bool useHTKMethod)
	{
	/* Slaney normalization for mel weights. */
	return (2.0f / (MFCC::InverseMelScale(rightMel, useHTKMethod) -
	MFCC::InverseMelScale(leftMel, useHTKMethod)));
	}

	} /* namespace audio */
	} /* namespace app */
	} /* namespace arm */