// Copyright 2016 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "IIRFilter.h" #include "DenormalDisabler.h" #include "mozilla/FloatingPoint.h" #include #include namespace blink { // The length of the memory buffers for the IIR filter. This MUST be a power of // two and must be greater than the possible length of the filter coefficients. const int kBufferLength = 32; static_assert(kBufferLength >= IIRFilter::kMaxOrder + 1, "Internal IIR buffer length must be greater than maximum IIR " "Filter order."); IIRFilter::IIRFilter(const AudioDoubleArray* feedforwardCoef, const AudioDoubleArray* feedbackCoef) : m_bufferIndex(0), m_feedback(feedbackCoef), m_feedforward(feedforwardCoef) { m_xBuffer.SetLength(kBufferLength); m_yBuffer.SetLength(kBufferLength); reset(); } IIRFilter::~IIRFilter() = default; void IIRFilter::reset() { memset(m_xBuffer.Elements(), 0, m_xBuffer.Length() * sizeof(double)); memset(m_yBuffer.Elements(), 0, m_yBuffer.Length() * sizeof(double)); } static std::complex evaluatePolynomial(const double* coef, std::complex z, int order) { // Use Horner's method to evaluate the polynomial P(z) = sum(coef[k]*z^k, k, // 0, order); std::complex result = 0; for (int k = order; k >= 0; --k) result = result * z + std::complex(coef[k]); return result; } void IIRFilter::process(const float* sourceP, float* destP, size_t framesToProcess) { // Compute // // y[n] = sum(b[k] * x[n - k], k = 0, M) - sum(a[k] * y[n - k], k = 1, N) // // where b[k] are the feedforward coefficients and a[k] are the feedback // coefficients of the filter. // This is a Direct Form I implementation of an IIR Filter. Should we // consider doing a different implementation such as Transposed Direct Form // II? const double* feedback = m_feedback->Elements(); const double* feedforward = m_feedforward->Elements(); MOZ_ASSERT(feedback); MOZ_ASSERT(feedforward); // Sanity check to see if the feedback coefficients have been scaled // appropriately. It must be EXACTLY 1! MOZ_ASSERT(feedback[0] == 1); int feedbackLength = m_feedback->Length(); int feedforwardLength = m_feedforward->Length(); int minLength = std::min(feedbackLength, feedforwardLength); double* xBuffer = m_xBuffer.Elements(); double* yBuffer = m_yBuffer.Elements(); for (size_t n = 0; n < framesToProcess; ++n) { // To help minimize roundoff, we compute using double's, even though the // filter coefficients only have single precision values. double yn = feedforward[0] * sourceP[n]; // Run both the feedforward and feedback terms together, when possible. for (int k = 1; k < minLength; ++k) { int n = (m_bufferIndex - k) & (kBufferLength - 1); yn += feedforward[k] * xBuffer[n]; yn -= feedback[k] * yBuffer[n]; } // Handle any remaining feedforward or feedback terms. for (int k = minLength; k < feedforwardLength; ++k) yn += feedforward[k] * xBuffer[(m_bufferIndex - k) & (kBufferLength - 1)]; for (int k = minLength; k < feedbackLength; ++k) yn -= feedback[k] * yBuffer[(m_bufferIndex - k) & (kBufferLength - 1)]; // Save the current input and output values in the memory buffers for the // next output. m_xBuffer[m_bufferIndex] = sourceP[n]; m_yBuffer[m_bufferIndex] = yn; m_bufferIndex = (m_bufferIndex + 1) & (kBufferLength - 1); // Avoid introducing a stream of subnormals destP[n] = WebCore::DenormalDisabler::flushDenormalFloatToZero(yn); MOZ_ASSERT(destP[n] == 0.0 || std::fabs(destP[n]) > FLT_MIN || std::isnan(destP[n]), "output should not be subnormal, but can be NaN"); } } void IIRFilter::getFrequencyResponse(int nFrequencies, const float* frequency, float* magResponse, float* phaseResponse) { // Evaluate the z-transform of the filter at the given normalized frequencies // from 0 to 1. (One corresponds to the Nyquist frequency.) // // The z-tranform of the filter is // // H(z) = sum(b[k]*z^(-k), k, 0, M) / sum(a[k]*z^(-k), k, 0, N); // // The desired frequency response is H(exp(j*omega)), where omega is in // [0, 1). // // Let P(x) = sum(c[k]*x^k, k, 0, P) be a polynomial of order P. Then each of // the sums in H(z) is equivalent to evaluating a polynomial at the point 1/z. for (int k = 0; k < nFrequencies; ++k) { // zRecip = 1/z = exp(-j*frequency) double omega = -M_PI * frequency[k]; std::complex zRecip = std::complex(cos(omega), sin(omega)); std::complex numerator = evaluatePolynomial( m_feedforward->Elements(), zRecip, m_feedforward->Length() - 1); std::complex denominator = evaluatePolynomial( m_feedback->Elements(), zRecip, m_feedback->Length() - 1); // Strangely enough, using complex division: // e.g. Complex response = numerator / denominator; // fails on our test machines, yielding infinities and NaNs, so we do // things the long way here. double n = norm(denominator); double r = (real(numerator) * real(denominator) + imag(numerator) * imag(denominator)) / n; double i = (imag(numerator) * real(denominator) - real(numerator) * imag(denominator)) / n; std::complex response = std::complex(r, i); magResponse[k] = static_cast(abs(response)); phaseResponse[k] = static_cast(atan2(imag(response), real(response))); } } bool IIRFilter::buffersAreZero() { double* xBuffer = m_xBuffer.Elements(); double* yBuffer = m_yBuffer.Elements(); for (size_t k = 0; k < m_feedforward->Length(); ++k) { if (xBuffer[(m_bufferIndex - k) & (kBufferLength - 1)] != 0.0) { return false; } } for (size_t k = 0; k < m_feedback->Length(); ++k) { if (fabs(yBuffer[(m_bufferIndex - k) & (kBufferLength - 1)]) >= FLT_MIN) { return false; } } return true; } } // namespace blink