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/*
 * Copyright (c) 2007, 2013, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.  Oracle designates this
 * particular file as subject to the "Classpath" exception as provided
 * by Oracle in the LICENSE file that accompanied this code.
 *
 * This code 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 General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
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package com.sun.media.sound;

import java.util.Arrays;

/**
 * A chorus effect made using LFO and variable delay. One for each channel
 * (left,right), with different starting phase for stereo effect.
 *
 * @author Karl Helgason
 */
public final class SoftChorus implements SoftAudioProcessor {

    private static class VariableDelay {

        private final float[] delaybuffer;
        private int rovepos = 0;
        private float gain = 1;
        private float rgain = 0;
        private float delay = 0;
        private float lastdelay = 0;
        private float feedback = 0;

        VariableDelay(int maxbuffersize) {
            delaybuffer = new float[maxbuffersize];
        }

        public void setDelay(float delay) {
            this.delay = delay;
        }

        public void setFeedBack(float feedback) {
            this.feedback = feedback;
        }

        public void setGain(float gain) {
            this.gain = gain;
        }

        public void setReverbSendGain(float rgain) {
            this.rgain = rgain;
        }

        public void processMix(float[] in, float[] out, float[] rout) {
            float gain = this.gain;
            float delay = this.delay;
            float feedback = this.feedback;

            float[] delaybuffer = this.delaybuffer;
            int len = in.length;
            float delaydelta = (delay - lastdelay) / len;
            int rnlen = delaybuffer.length;
            int rovepos = this.rovepos;

            if (rout == null)
                for (int i = 0; i < len; i++) {
                    float r = rovepos - (lastdelay + 2) + rnlen;
                    int ri = (int) r;
                    float s = r - ri;
                    float a = delaybuffer[ri % rnlen];
                    float b = delaybuffer[(ri + 1) % rnlen];
                    float o = a * (1 - s) + b * (s);
                    out[i] += o * gain;
                    delaybuffer[rovepos] = in[i] + o * feedback;
                    rovepos = (rovepos + 1) % rnlen;
                    lastdelay += delaydelta;
                }
            else
                for (int i = 0; i < len; i++) {
                    float r = rovepos - (lastdelay + 2) + rnlen;
                    int ri = (int) r;
                    float s = r - ri;
                    float a = delaybuffer[ri % rnlen];
                    float b = delaybuffer[(ri + 1) % rnlen];
                    float o = a * (1 - s) + b * (s);
                    out[i] += o * gain;
                    rout[i] += o * rgain;
                    delaybuffer[rovepos] = in[i] + o * feedback;
                    rovepos = (rovepos + 1) % rnlen;
                    lastdelay += delaydelta;
                }
            this.rovepos = rovepos;
            lastdelay = delay;
        }

        public void processReplace(float[] in, float[] out, float[] rout) {
            Arrays.fill(out, 0);
            Arrays.fill(rout, 0);
            processMix(in, out, rout);
        }
    }

    private static class LFODelay {

        private double phase = 1;
        private double phase_step = 0;
        private double depth = 0;
        private VariableDelay vdelay;
        private final double samplerate;
        private final double controlrate;

        LFODelay(double samplerate, double controlrate) {
            this.samplerate = samplerate;
            this.controlrate = controlrate;
            // vdelay = new VariableDelay((int)(samplerate*4));
            vdelay = new VariableDelay((int) ((this.depth + 10) * 2));

        }

        public void setDepth(double depth) {
            this.depth = depth * samplerate;
            vdelay = new VariableDelay((int) ((this.depth + 10) * 2));
        }

        public void setRate(double rate) {
            double g = (Math.PI * 2) * (rate / controlrate);
            phase_step = g;
        }

        public void setPhase(double phase) {
            this.phase = phase;
        }

        public void setFeedBack(float feedback) {
            vdelay.setFeedBack(feedback);
        }

        public void setGain(float gain) {
            vdelay.setGain(gain);
        }

        public void setReverbSendGain(float rgain) {
            vdelay.setReverbSendGain(rgain);
        }

        public void processMix(float[] in, float[] out, float[] rout) {
            phase += phase_step;
            while(phase > (Math.PI * 2)) phase -= (Math.PI * 2);
            vdelay.setDelay((float) (depth * 0.5 * (Math.cos(phase) + 2)));
            vdelay.processMix(in, out, rout);
        }

        public void processReplace(float[] in, float[] out, float[] rout) {
            phase += phase_step;
            while(phase > (Math.PI * 2)) phase -= (Math.PI * 2);
            vdelay.setDelay((float) (depth * 0.5 * (Math.cos(phase) + 2)));
            vdelay.processReplace(in, out, rout);

        }
    }
    private boolean mix = true;
    private SoftAudioBuffer inputA;
    private SoftAudioBuffer left;
    private SoftAudioBuffer right;
    private SoftAudioBuffer reverb;
    private LFODelay vdelay1L;
    private LFODelay vdelay1R;
    private float rgain = 0;
    private boolean dirty = true;
    private double dirty_vdelay1L_rate;
    private double dirty_vdelay1R_rate;
    private double dirty_vdelay1L_depth;
    private double dirty_vdelay1R_depth;
    private float dirty_vdelay1L_feedback;
    private float dirty_vdelay1R_feedback;
    private float dirty_vdelay1L_reverbsendgain;
    private float dirty_vdelay1R_reverbsendgain;
    private float controlrate;

    @Override
    public void init(float samplerate, float controlrate) {
        this.controlrate = controlrate;
        vdelay1L = new LFODelay(samplerate, controlrate);
        vdelay1R = new LFODelay(samplerate, controlrate);
        vdelay1L.setGain(1.0f); // %
        vdelay1R.setGain(1.0f); // %
        vdelay1L.setPhase(0.5 * Math.PI);
        vdelay1R.setPhase(0);

        globalParameterControlChange(new int[]{0x01 * 128 + 0x02}, 0, 2);
    }

    @Override
    public void globalParameterControlChange(int[] slothpath, long param,
                                             long value) {
        if (slothpath.length == 1) {
            if (slothpath[0] == 0x01 * 128 + 0x02) {
                if (param == 0) { // Chorus Type
                    switch ((int)value) {
                    case 0: // Chorus 1 0 (0%) 3 (0.4Hz) 5 (1.9ms) 0 (0%)
                        globalParameterControlChange(slothpath, 3, 0);
                        globalParameterControlChange(slothpath, 1, 3);
                        globalParameterControlChange(slothpath, 2, 5);
                        globalParameterControlChange(slothpath, 4, 0);
                        break;
                    case 1: // Chorus 2 5 (4%) 9 (1.1Hz) 19 (6.3ms) 0 (0%)
                        globalParameterControlChange(slothpath, 3, 5);
                        globalParameterControlChange(slothpath, 1, 9);
                        globalParameterControlChange(slothpath, 2, 19);
                        globalParameterControlChange(slothpath, 4, 0);
                        break;
                    case 2: // Chorus 3 8 (6%) 3 (0.4Hz) 19 (6.3ms) 0 (0%)
                        globalParameterControlChange(slothpath, 3, 8);
                        globalParameterControlChange(slothpath, 1, 3);
                        globalParameterControlChange(slothpath, 2, 19);
                        globalParameterControlChange(slothpath, 4, 0);
                        break;
                    case 3: // Chorus 4 16 (12%) 9 (1.1Hz) 16 (5.3ms) 0 (0%)
                        globalParameterControlChange(slothpath, 3, 16);
                        globalParameterControlChange(slothpath, 1, 9);
                        globalParameterControlChange(slothpath, 2, 16);
                        globalParameterControlChange(slothpath, 4, 0);
                        break;
                    case 4: // FB Chorus 64 (49%) 2 (0.2Hz) 24 (7.8ms) 0 (0%)
                        globalParameterControlChange(slothpath, 3, 64);
                        globalParameterControlChange(slothpath, 1, 2);
                        globalParameterControlChange(slothpath, 2, 24);
                        globalParameterControlChange(slothpath, 4, 0);
                        break;
                    case 5: // Flanger 112 (86%) 1 (0.1Hz) 5 (1.9ms) 0 (0%)
                        globalParameterControlChange(slothpath, 3, 112);
                        globalParameterControlChange(slothpath, 1, 1);
                        globalParameterControlChange(slothpath, 2, 5);
                        globalParameterControlChange(slothpath, 4, 0);
                        break;
                    default:
                        break;
                    }
                } else if (param == 1) { // Mod Rate
                    dirty_vdelay1L_rate = (value * 0.122);
                    dirty_vdelay1R_rate = (value * 0.122);
                    dirty = true;
                } else if (param == 2) { // Mod Depth
                    dirty_vdelay1L_depth = ((value + 1) / 3200.0);
                    dirty_vdelay1R_depth = ((value + 1) / 3200.0);
                    dirty = true;
                } else if (param == 3) { // Feedback
                    dirty_vdelay1L_feedback = (value * 0.00763f);
                    dirty_vdelay1R_feedback = (value * 0.00763f);
                    dirty = true;
                }
                if (param == 4) { // Send to Reverb
                    rgain = value * 0.00787f;
                    dirty_vdelay1L_reverbsendgain = (value * 0.00787f);
                    dirty_vdelay1R_reverbsendgain = (value * 0.00787f);
                    dirty = true;
                }

            }
        }
    }

    @Override
    public void processControlLogic() {
        if (dirty) {
            dirty = false;
            vdelay1L.setRate(dirty_vdelay1L_rate);
            vdelay1R.setRate(dirty_vdelay1R_rate);
            vdelay1L.setDepth(dirty_vdelay1L_depth);
            vdelay1R.setDepth(dirty_vdelay1R_depth);
            vdelay1L.setFeedBack(dirty_vdelay1L_feedback);
            vdelay1R.setFeedBack(dirty_vdelay1R_feedback);
            vdelay1L.setReverbSendGain(dirty_vdelay1L_reverbsendgain);
            vdelay1R.setReverbSendGain(dirty_vdelay1R_reverbsendgain);
        }
    }
    double silentcounter = 1000;

    @Override
    public void processAudio() {

        if (inputA.isSilent()) {

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