/* * Copyright (c) 2021-2022 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 "DataStructures.hpp" #include "AsrGoldenFeatures.hpp" #include "Wav2LetterPreprocess.hpp" #include "log_macros.h" #include #include class TestPreprocess : public arm::app::AsrPreProcess { public: static bool ComputeDeltas(arm::app::Array2d& mfcc, arm::app::Array2d& delta1, arm::app::Array2d& delta2) { return AsrPreProcess::ComputeDeltas(mfcc, delta1, delta2); } static void NormaliseVec(arm::app::Array2d& vec) { return AsrPreProcess::StandardizeVecF32(vec); } }; template void CheckOutputs(const std::vector goldenOutput, std::vector output) { const size_t goldenSize = goldenOutput.size(); const size_t realSize = output.size(); REQUIRE(realSize == goldenSize); REQUIRE_THAT(output, Catch::Approx( goldenOutput ).margin(0.0001)); } template void CheckOutputs(const std::vector goldenOutput, std::vector output); void populateBuffer(const float* input, size_t size, size_t numMfccFeats, std::vector>& buf) { size_t time = 0; for (size_t i = 0; i < size; ++i) { if (i > 0 && i % numMfccFeats == 0) { ++time; } float featureValue = *(input + i); buf[i % numMfccFeats][time] = featureValue; } } void populateArray2dWithVectorOfVector(std::vector> vec, arm::app::Array2d& buf) { for (size_t i = 0; i < vec.size(); ++i) { for (size_t j = 0; j < vec[i].size(); ++j) { buf(i, j) = vec[i][j]; } } } TEST_CASE("Floating point asr features calculation", "[ASR]") { SECTION("First and second diff") { constexpr uint32_t numMfccFeats = 13; constexpr uint32_t numFeatVectors = 296; arm::app::Array2d mfccBuf(numMfccFeats, numFeatVectors); arm::app::Array2d delta1Buf(numMfccFeats, numFeatVectors); arm::app::Array2d delta2Buf(numMfccFeats, numFeatVectors); std::vector> goldenMfccBuf(numMfccFeats, std::vector(numFeatVectors)); std::vector> goldenDelta1Buf(numMfccFeats, std::vector(numFeatVectors)); std::vector> goldenDelta2Buf(numMfccFeats, std::vector(numFeatVectors)); populateBuffer(golden_asr_mfcc, golden_asr_mfcc_len, numMfccFeats, goldenMfccBuf); populateBuffer(golden_diff1_features, golden_diff1_len, numMfccFeats, goldenDelta1Buf); populateBuffer(golden_diff2_features, golden_diff2_len, numMfccFeats, goldenDelta2Buf); populateArray2dWithVectorOfVector(goldenMfccBuf, mfccBuf); std::fill(delta1Buf.begin(), delta1Buf.end(), 0.f); std::fill(delta2Buf.begin(), delta2Buf.end(), 0.f); TestPreprocess::ComputeDeltas(mfccBuf, delta1Buf, delta2Buf); /* First 4 and last 4 values are different because we pad AFTER diff calculated. */ for (size_t i = 0; i < numMfccFeats; ++i) { const float* start_goldenDelta1Buf = goldenDelta1Buf[i].data() + 4; const float* start_delta1 = delta1Buf.begin() + i * delta1Buf.size(1) + 4; std::vector goldenDataDelta1(start_goldenDelta1Buf, start_goldenDelta1Buf + numFeatVectors - 8); std::vector tensorDataDelta1(start_delta1, start_delta1 + numFeatVectors - 8); CheckOutputs(goldenDataDelta1,tensorDataDelta1); const float* start_goldenDelta2Buf = goldenDelta2Buf[i].data() + 4; const float* start_delta2 = delta2Buf.begin() + i * delta2Buf.size(1) + 4; std::vector goldenDataDelta2(start_goldenDelta2Buf, start_goldenDelta2Buf + numFeatVectors - 8); std::vector tensorDataDelta2(start_delta2, start_delta2 + numFeatVectors - 8); CheckOutputs(goldenDataDelta2,tensorDataDelta2); } } SECTION("Norm") { auto checker = [&](arm::app::Array2d& d, std::vector& g) { TestPreprocess::NormaliseVec(d); std::vector d_vec(d.begin(), d.end()); REQUIRE_THAT(g, Catch::Approx(d_vec)); }; std::vector> norm0vec{{1, 1}, {1, 1}}; std::vector goldenNorm0 {0, 0, 0, 0}; arm::app::Array2d norm0(2, 2); populateArray2dWithVectorOfVector(norm0vec, norm0); checker(norm0, goldenNorm0); std::vector> norm1vec{{1, 2, 3, 4, 5}, {6, 7, 8, 9, 0}}; std::vector goldenNorm1 { -1.218543592, -0.87038828, -0.522232968, -0.174077656, 0.174077656, 0.522232968, 0.87038828, 1.218543592, 1.566698904, -1.566698904}; arm::app::Array2d norm1(2, 5); populateArray2dWithVectorOfVector(norm1vec, norm1); checker(norm1, goldenNorm1); } }