/* * $Id: AUD_ButterworthReader.cpp 25645 2010-01-01 11:40:48Z nexyon $ * * ***** BEGIN LGPL LICENSE BLOCK ***** * * Copyright 2009 Jörg Hermann Müller * * This file is part of AudaSpace. * * AudaSpace is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * AudaSpace is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with AudaSpace. If not, see . * * ***** END LGPL LICENSE BLOCK ***** */ #include "AUD_ButterworthReader.h" #include "AUD_Buffer.h" #include #include #ifndef M_PI #define M_PI 3.14159265358979323846 #endif #define BWPB41 0.76536686473 #define BWPB42 1.84775906502 #define CC channels + channel AUD_ButterworthReader::AUD_ButterworthReader(AUD_IReader* reader, float frequency) : AUD_EffectReader(reader) { AUD_Specs specs = reader->getSpecs(); int samplesize = AUD_SAMPLE_SIZE(specs); m_buffer = new AUD_Buffer(); AUD_NEW("buffer") m_outvalues = new AUD_Buffer(samplesize * 5); AUD_NEW("buffer") memset(m_outvalues->getBuffer(), 0, samplesize * 5); m_invalues = new AUD_Buffer(samplesize * 5); AUD_NEW("buffer") memset(m_invalues->getBuffer(), 0, samplesize * 5); m_position = 0; // calculate coefficients float omega = 2 * tan(frequency * M_PI / specs.rate); float o2 = omega * omega; float o4 = o2 * o2; float x1 = o2 + 2 * BWPB41 * omega + 4; float x2 = o2 + 2 * BWPB42 * omega + 4; float y1 = o2 - 2 * BWPB41 * omega + 4; float y2 = o2 - 2 * BWPB42 * omega + 4; float o228 = 2 * o2 - 8; float norm = x1 * x2; m_coeff[0][0] = 0; m_coeff[0][1] = (x1 + x2) * o228 / norm; m_coeff[0][2] = (x1 * y2 + x2 * y1 + o228 * o228) / norm; m_coeff[0][3] = (y1 + y2) * o228 / norm; m_coeff[0][4] = y1 * y2 / norm; m_coeff[1][4] = m_coeff[1][0] = o4 / norm; m_coeff[1][3] = m_coeff[1][1] = 4 * o4 / norm; m_coeff[1][2] = 6 * o4 / norm; } AUD_ButterworthReader::~AUD_ButterworthReader() { delete m_buffer; AUD_DELETE("buffer") delete m_outvalues; AUD_DELETE("buffer") delete m_invalues; AUD_DELETE("buffer"); } void AUD_ButterworthReader::read(int & length, sample_t* & buffer) { sample_t* buf; sample_t* outvalues; sample_t* invalues; outvalues = m_outvalues->getBuffer(); invalues = m_invalues->getBuffer(); AUD_Specs specs = m_reader->getSpecs(); m_reader->read(length, buf); if(m_buffer->getSize() < length * AUD_SAMPLE_SIZE(specs)) m_buffer->resize(length * AUD_SAMPLE_SIZE(specs)); buffer = m_buffer->getBuffer(); int channels = specs.channels; for(int channel = 0; channel < channels; channel++) { for(int i = 0; i < length; i++) { invalues[m_position * CC] = buf[i * CC]; outvalues[m_position * CC] = 0; for(int j = 0; j < 4; j++) { outvalues[m_position * CC] += m_coeff[1][j] * invalues[((m_position + j) % 5) * CC] - m_coeff[0][j] * outvalues[((m_position + j) % 5) * CC]; } buffer[i * CC] = outvalues[m_position * CC]; m_position = (m_position + 4) % 5; } } }