/* * Copyrightm (C) 2010 The Android Open Source Project * * 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 #include #include #include #include #define LOG_TAG "Echo" #include #include "EchoSuppressor.h" // It is very difficult to do echo cancellation at this level due to the lack of // the timing information of the samples being played and recorded. Therefore, // for the first release only echo suppression is implemented. // The algorithm is derived from the "previous works" summarized in // A new class of doubletalk detectors based on cross-correlation, // J Benesty, DR Morgan, JH Cho, IEEE Trans. on Speech and Audio Processing. // The method proposed in that paper is not used because of its high complexity. // It is well known that cross-correlation can be computed using convolution, // but unfortunately not every mobile processor has a (fast enough) FPU. Thus // we use integer arithmetic as much as possible and do lots of bookkeeping. // Again, parameters and thresholds are chosen by experiments. EchoSuppressor::EchoSuppressor(int sampleCount, int tailLength) { tailLength += sampleCount * 4; int shift = 0; while ((sampleCount >> shift) > 1 && (tailLength >> shift) > 256) { ++shift; } mShift = shift + 4; mScale = 1 << shift; mSampleCount = sampleCount; mWindowSize = sampleCount >> shift; mTailLength = tailLength >> shift; mRecordLength = tailLength * 2 / sampleCount; mRecordOffset = 0; mXs = new uint16_t[mTailLength + mWindowSize]; memset(mXs, 0, sizeof(*mXs) * (mTailLength + mWindowSize)); mXSums = new uint32_t[mTailLength]; memset(mXSums, 0, sizeof(*mXSums) * mTailLength); mX2Sums = new uint32_t[mTailLength]; memset(mX2Sums, 0, sizeof(*mX2Sums) * mTailLength); mXRecords = new uint16_t[mRecordLength * mWindowSize]; memset(mXRecords, 0, sizeof(*mXRecords) * mRecordLength * mWindowSize); mYSum = 0; mY2Sum = 0; mYRecords = new uint32_t[mRecordLength]; memset(mYRecords, 0, sizeof(*mYRecords) * mRecordLength); mY2Records = new uint32_t[mRecordLength]; memset(mY2Records, 0, sizeof(*mY2Records) * mRecordLength); mXYSums = new uint32_t[mTailLength]; memset(mXYSums, 0, sizeof(*mXYSums) * mTailLength); mXYRecords = new uint32_t[mRecordLength * mTailLength]; memset(mXYRecords, 0, sizeof(*mXYRecords) * mRecordLength * mTailLength); mLastX = 0; mLastY = 0; mWeight = 1.0f / (mRecordLength * mWindowSize); } EchoSuppressor::~EchoSuppressor() { delete [] mXs; delete [] mXSums; delete [] mX2Sums; delete [] mXRecords; delete [] mYRecords; delete [] mY2Records; delete [] mXYSums; delete [] mXYRecords; } void EchoSuppressor::run(int16_t *playbacked, int16_t *recorded) { // Update Xs. for (int i = mTailLength - 1; i >= 0; --i) { mXs[i + mWindowSize] = mXs[i]; } for (int i = mWindowSize - 1, j = 0; i >= 0; --i, j += mScale) { uint32_t sum = 0; for (int k = 0; k < mScale; ++k) { int32_t x = playbacked[j + k] << 15; mLastX += x; sum += ((mLastX >= 0) ? mLastX : -mLastX) >> 15; mLastX -= (mLastX >> 10) + x; } mXs[i] = sum >> mShift; } // Update XSums, X2Sums, and XRecords. for (int i = mTailLength - mWindowSize - 1; i >= 0; --i) { mXSums[i + mWindowSize] = mXSums[i]; mX2Sums[i + mWindowSize] = mX2Sums[i]; } uint16_t *xRecords = &mXRecords[mRecordOffset * mWindowSize]; for (int i = mWindowSize - 1; i >= 0; --i) { uint16_t x = mXs[i]; mXSums[i] = mXSums[i + 1] + x - xRecords[i]; mX2Sums[i] = mX2Sums[i + 1] + x * x - xRecords[i] * xRecords[i]; xRecords[i] = x; } // Compute Ys. uint16_t ys[mWindowSize]; for (int i = mWindowSize - 1, j = 0; i >= 0; --i, j += mScale) { uint32_t sum = 0; for (int k = 0; k < mScale; ++k) { int32_t y = recorded[j + k] << 15; mLastY += y; sum += ((mLastY >= 0) ? mLastY : -mLastY) >> 15; mLastY -= (mLastY >> 10) + y; } ys[i] = sum >> mShift; } // Update YSum, Y2Sum, YRecords, and Y2Records. uint32_t ySum = 0; uint32_t y2Sum = 0; for (int i = mWindowSize - 1; i >= 0; --i) { ySum += ys[i]; y2Sum += ys[i] * ys[i]; } mYSum += ySum - mYRecords[mRecordOffset]; mY2Sum += y2Sum - mY2Records[mRecordOffset]; mYRecords[mRecordOffset] = ySum; mY2Records[mRecordOffset] = y2Sum; // Update XYSums and XYRecords. uint32_t *xyRecords = &mXYRecords[mRecordOffset * mTailLength]; for (int i = mTailLength - 1; i >= 0; --i) { uint32_t xySum = 0; for (int j = mWindowSize - 1; j >= 0; --j) { xySum += mXs[i + j] * ys[j]; } mXYSums[i] += xySum - xyRecords[i]; xyRecords[i] = xySum; } // Compute correlations. int latency = 0; float corr2 = 0.0f; float varX = 0.0f; float varY = mY2Sum - mWeight * mYSum * mYSum; for (int i = mTailLength - 1; i >= 0; --i) { float cov = mXYSums[i] - mWeight * mXSums[i] * mYSum; if (cov > 0.0f) { float varXi = mX2Sums[i] - mWeight * mXSums[i] * mXSums[i]; float corr2i = cov * cov / (varXi * varY + 1); if (corr2i > corr2) { varX = varXi; corr2 = corr2i; latency = i; } } } //ALOGI("corr^2 %.5f, var %8.0f %8.0f, latency %d", corr2, varX, varY, // latency * mScale); // Do echo suppression. if (corr2 > 0.1f && varX > 10000.0f) { int factor = (corr2 > 1.0f) ? 0 : (1.0f - sqrtf(corr2)) * 4096; for (int i = 0; i < mSampleCount; ++i) { recorded[i] = recorded[i] * factor >> 16; } } // Increase RecordOffset. ++mRecordOffset; if (mRecordOffset == mRecordLength) { mRecordOffset = 0; } }