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* DSP: Implement Pipe 2 Pipe 2 is a DSP pipe that is used to initialize both the DSP hardware (the application signals to the DSP to initialize) and the application (the DSP provides the memory location of structures in the shared memory region). * AudioCore: Implement codecs (DecodeADPCM, DecodePCM8, DecodePCM16) * DSP Pipes: Implement as FIFO * AudioCore: File structure * AudioCore: More structure * AudioCore: Buffer management * DSP/Source: Reorganise Source's AdvanceFrame. * Audio Output * lolidk * huh? * interp * More interp stuff * oops * Zero State * Don't mix Source frame if it's not enabled * DSP: Forgot to zero a buffer, adjusted thread synchronisation, adjusted format spec for buffers * asdf * Get it to compile and tweak stretching a bit. * revert stretch test * deleted accidental partial catch submodule commit * new audio stretching algorithm * update .gitmodule * fix OS X build * remove getopt from rubberband * #include <stddef> to audio_core.h * typo * -framework Accelerate * OptionTransientsSmooth -> OptionTransientsCrisp * tweak stretch tempo smoothing coefficient. also switch back to smooth. * tweak mroe * remove printf * sola * #include <cmath> * VERY QUICK MERGE TO GET IT WORKING DOESN'T ACTIVATE AUDIO FILTERS * Reminder to self * fix comparison * common/thread: Correct code style * Thread: Make Barrier reusable * fix threading synchonisation code * add profiling code * print error to console when audio clips * fix metallic sound * reduce logspam
287 lines
8.0 KiB
C++
287 lines
8.0 KiB
C++
////////////////////////////////////////////////////////////////////////////////
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///
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/// Peak detection routine.
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///
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/// The routine detects highest value on an array of values and calculates the
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/// precise peak location as a mass-center of the 'hump' around the peak value.
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///
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/// Author : Copyright (c) Olli Parviainen
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/// Author e-mail : oparviai 'at' iki.fi
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/// SoundTouch WWW: http://www.surina.net/soundtouch
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///
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////////////////////////////////////////////////////////////////////////////////
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//
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// Last changed : $Date: 2015-05-18 18:22:02 +0300 (Mon, 18 May 2015) $
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// File revision : $Revision: 4 $
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//
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// $Id: PeakFinder.cpp 213 2015-05-18 15:22:02Z oparviai $
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//
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////////////////////////////////////////////////////////////////////////////////
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//
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// License :
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//
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// SoundTouch audio processing library
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// Copyright (c) Olli Parviainen
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//
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// This library is free software; you can redistribute it and/or
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// modify it under the terms of the GNU Lesser General Public
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// License as published by the Free Software Foundation; either
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// version 2.1 of the License, or (at your option) any later version.
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//
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// This library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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// Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public
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// License along with this library; if not, write to the Free Software
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// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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//
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////////////////////////////////////////////////////////////////////////////////
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#include <math.h>
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#include <assert.h>
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#include "PeakFinder.h"
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using namespace soundtouch;
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#define max(x, y) (((x) > (y)) ? (x) : (y))
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PeakFinder::PeakFinder()
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{
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minPos = maxPos = 0;
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}
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// Finds real 'top' of a peak hump from neighnourhood of the given 'peakpos'.
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int PeakFinder::findTop(const float *data, int peakpos) const
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{
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int i;
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int start, end;
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float refvalue;
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refvalue = data[peakpos];
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// seek within <20>10 points
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start = peakpos - 10;
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if (start < minPos) start = minPos;
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end = peakpos + 10;
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if (end > maxPos) end = maxPos;
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for (i = start; i <= end; i ++)
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{
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if (data[i] > refvalue)
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{
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peakpos = i;
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refvalue = data[i];
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}
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}
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// failure if max value is at edges of seek range => it's not peak, it's at slope.
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if ((peakpos == start) || (peakpos == end)) return 0;
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return peakpos;
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}
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// Finds 'ground level' of a peak hump by starting from 'peakpos' and proceeding
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// to direction defined by 'direction' until next 'hump' after minimum value will
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// begin
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int PeakFinder::findGround(const float *data, int peakpos, int direction) const
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{
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int lowpos;
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int pos;
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int climb_count;
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float refvalue;
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float delta;
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climb_count = 0;
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refvalue = data[peakpos];
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lowpos = peakpos;
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pos = peakpos;
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while ((pos > minPos+1) && (pos < maxPos-1))
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{
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int prevpos;
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prevpos = pos;
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pos += direction;
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// calculate derivate
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delta = data[pos] - data[prevpos];
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if (delta <= 0)
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{
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// going downhill, ok
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if (climb_count)
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{
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climb_count --; // decrease climb count
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}
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// check if new minimum found
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if (data[pos] < refvalue)
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{
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// new minimum found
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lowpos = pos;
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refvalue = data[pos];
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}
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}
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else
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{
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// going uphill, increase climbing counter
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climb_count ++;
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if (climb_count > 5) break; // we've been climbing too long => it's next uphill => quit
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}
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}
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return lowpos;
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}
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// Find offset where the value crosses the given level, when starting from 'peakpos' and
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// proceeds to direction defined in 'direction'
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int PeakFinder::findCrossingLevel(const float *data, float level, int peakpos, int direction) const
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{
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float peaklevel;
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int pos;
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peaklevel = data[peakpos];
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assert(peaklevel >= level);
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pos = peakpos;
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while ((pos >= minPos) && (pos < maxPos))
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{
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if (data[pos + direction] < level) return pos; // crossing found
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pos += direction;
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}
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return -1; // not found
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}
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// Calculates the center of mass location of 'data' array items between 'firstPos' and 'lastPos'
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double PeakFinder::calcMassCenter(const float *data, int firstPos, int lastPos) const
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{
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int i;
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float sum;
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float wsum;
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sum = 0;
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wsum = 0;
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for (i = firstPos; i <= lastPos; i ++)
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{
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sum += (float)i * data[i];
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wsum += data[i];
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}
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if (wsum < 1e-6) return 0;
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return sum / wsum;
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}
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/// get exact center of peak near given position by calculating local mass of center
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double PeakFinder::getPeakCenter(const float *data, int peakpos) const
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{
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float peakLevel; // peak level
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int crosspos1, crosspos2; // position where the peak 'hump' crosses cutting level
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float cutLevel; // cutting value
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float groundLevel; // ground level of the peak
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int gp1, gp2; // bottom positions of the peak 'hump'
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// find ground positions.
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gp1 = findGround(data, peakpos, -1);
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gp2 = findGround(data, peakpos, 1);
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peakLevel = data[peakpos];
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if (gp1 == gp2)
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{
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// avoid rounding errors when all are equal
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assert(gp1 == peakpos);
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cutLevel = groundLevel = peakLevel;
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} else {
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// get average of the ground levels
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groundLevel = 0.5f * (data[gp1] + data[gp2]);
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// calculate 70%-level of the peak
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cutLevel = 0.70f * peakLevel + 0.30f * groundLevel;
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}
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// find mid-level crossings
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crosspos1 = findCrossingLevel(data, cutLevel, peakpos, -1);
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crosspos2 = findCrossingLevel(data, cutLevel, peakpos, 1);
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if ((crosspos1 < 0) || (crosspos2 < 0)) return 0; // no crossing, no peak..
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// calculate mass center of the peak surroundings
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return calcMassCenter(data, crosspos1, crosspos2);
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}
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double PeakFinder::detectPeak(const float *data, int aminPos, int amaxPos)
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{
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int i;
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int peakpos; // position of peak level
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double highPeak, peak;
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this->minPos = aminPos;
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this->maxPos = amaxPos;
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// find absolute peak
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peakpos = minPos;
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peak = data[minPos];
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for (i = minPos + 1; i < maxPos; i ++)
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{
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if (data[i] > peak)
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{
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peak = data[i];
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peakpos = i;
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}
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}
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// Calculate exact location of the highest peak mass center
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highPeak = getPeakCenter(data, peakpos);
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peak = highPeak;
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// Now check if the highest peak were in fact harmonic of the true base beat peak
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// - sometimes the highest peak can be Nth harmonic of the true base peak yet
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// just a slightly higher than the true base
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for (i = 3; i < 10; i ++)
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{
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double peaktmp, harmonic;
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int i1,i2;
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harmonic = (double)i * 0.5;
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peakpos = (int)(highPeak / harmonic + 0.5f);
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if (peakpos < minPos) break;
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peakpos = findTop(data, peakpos); // seek true local maximum index
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if (peakpos == 0) continue; // no local max here
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// calculate mass-center of possible harmonic peak
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peaktmp = getPeakCenter(data, peakpos);
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// accept harmonic peak if
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// (a) it is found
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// (b) is within <20>4% of the expected harmonic interval
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// (c) has at least half x-corr value of the max. peak
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double diff = harmonic * peaktmp / highPeak;
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if ((diff < 0.96) || (diff > 1.04)) continue; // peak too afar from expected
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// now compare to highest detected peak
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i1 = (int)(highPeak + 0.5);
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i2 = (int)(peaktmp + 0.5);
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if (data[i2] >= 0.4*data[i1])
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{
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// The harmonic is at least half as high primary peak,
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// thus use the harmonic peak instead
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peak = peaktmp;
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}
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}
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return peak;
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}
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