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414 lines
11 KiB
C++
414 lines
11 KiB
C++
/*
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* Autotune.cpp
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* ------------
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* Purpose: Class for tuning a sample to a given base note automatically.
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* Notes : (currently none)
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* Authors: OpenMPT Devs
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* The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
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*/
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#include "stdafx.h"
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#include "Autotune.h"
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#include <math.h>
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#include "../common/misc_util.h"
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#include "../soundlib/Sndfile.h"
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#include <algorithm>
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#include <execution>
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#include <numeric>
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#if defined(MPT_ENABLE_ARCH_INTRINSICS_SSE2)
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#include <emmintrin.h>
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#endif
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OPENMPT_NAMESPACE_BEGIN
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// The more bins, the more autocorrelations are done and the more precise the result is.
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#define BINS_PER_NOTE 32
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#define MIN_SAMPLE_LENGTH 2
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#define START_NOTE (24 * BINS_PER_NOTE) // C-2
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#define END_NOTE (96 * BINS_PER_NOTE) // C-8
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#define HISTORY_BINS (12 * BINS_PER_NOTE) // One octave
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static double FrequencyToNote(double freq, double pitchReference)
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{
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return ((12.0 * (log(freq / (pitchReference / 2.0)) / log(2.0))) + 57.0);
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}
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static double NoteToFrequency(double note, double pitchReference)
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{
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return pitchReference * pow(2.0, (note - 69.0) / 12.0);
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}
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// Calculate the amount of samples for autocorrelation shifting for a given note
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static SmpLength NoteToShift(uint32 sampleFreq, int note, double pitchReference)
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{
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const double fundamentalFrequency = NoteToFrequency((double)note / BINS_PER_NOTE, pitchReference);
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return std::max(mpt::saturate_round<SmpLength>((double)sampleFreq / fundamentalFrequency), SmpLength(1));
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}
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// Create an 8-Bit sample buffer with loop unrolling and mono conversion for autocorrelation.
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template <class T>
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void Autotune::CopySamples(const T* origSample, SmpLength sampleLoopStart, SmpLength sampleLoopEnd)
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{
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const uint8 channels = m_sample.GetNumChannels();
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sampleLoopStart *= channels;
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sampleLoopEnd *= channels;
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for(SmpLength i = 0, pos = 0; i < m_sampleLength; i++, pos += channels)
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{
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if(pos >= sampleLoopEnd)
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{
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pos = sampleLoopStart;
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}
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const T* smp = origSample + pos;
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int32 data = 0; // More than enough for 256 channels... :)
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for(uint8 chn = 0; chn < channels; chn++)
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{
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// We only want the MSB.
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data += static_cast<int32>(smp[chn] >> ((sizeof(T) - 1) * 8));
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}
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data /= channels;
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m_sampleData[i] = static_cast<int16>(data);
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}
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}
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// Prepare a sample buffer for autocorrelation
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bool Autotune::PrepareSample(SmpLength maxShift)
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{
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// Determine which parts of the sample should be examined.
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SmpLength sampleOffset = 0, sampleLoopStart = 0, sampleLoopEnd = m_sample.nLength;
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if(m_selectionEnd >= sampleLoopStart + MIN_SAMPLE_LENGTH)
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{
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// A selection has been specified: Examine selection
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sampleOffset = m_selectionStart;
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sampleLoopStart = 0;
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sampleLoopEnd = m_selectionEnd - m_selectionStart;
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} else if(m_sample.uFlags[CHN_SUSTAINLOOP] && m_sample.nSustainEnd >= m_sample.nSustainStart + MIN_SAMPLE_LENGTH)
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{
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// A sustain loop is set: Examine sample up to sustain loop and, if necessary, execute the loop several times
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sampleOffset = 0;
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sampleLoopStart = m_sample.nSustainStart;
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sampleLoopEnd = m_sample.nSustainEnd;
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} else if(m_sample.uFlags[CHN_LOOP] && m_sample.nLoopEnd >= m_sample.nLoopStart + MIN_SAMPLE_LENGTH)
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{
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// A normal loop is set: Examine sample up to loop and, if necessary, execute the loop several times
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sampleOffset = 0;
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sampleLoopStart = m_sample.nLoopStart;
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sampleLoopEnd = m_sample.nLoopEnd;
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}
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// We should analyse at least a one second (= GetSampleRate() samples) long sample.
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m_sampleLength = std::max(sampleLoopEnd, static_cast<SmpLength>(m_sample.GetSampleRate(m_modType))) + maxShift;
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m_sampleLength = (m_sampleLength + 7) & ~7;
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if(m_sampleData != nullptr)
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{
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delete[] m_sampleData;
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}
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m_sampleData = new int16[m_sampleLength];
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if(m_sampleData == nullptr)
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{
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return false;
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}
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// Copy sample over.
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switch(m_sample.GetElementarySampleSize())
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{
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case 1:
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CopySamples(m_sample.sample8() + sampleOffset * m_sample.GetNumChannels(), sampleLoopStart, sampleLoopEnd);
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return true;
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case 2:
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CopySamples(m_sample.sample16() + sampleOffset * m_sample.GetNumChannels(), sampleLoopStart, sampleLoopEnd);
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return true;
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}
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return false;
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}
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bool Autotune::CanApply() const
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{
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return (m_sample.HasSampleData() && m_sample.nLength >= MIN_SAMPLE_LENGTH) || m_sample.uFlags[CHN_ADLIB];
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}
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namespace
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{
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struct AutotuneHistogramEntry
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{
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int index;
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uint64 sum;
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};
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struct AutotuneHistogram
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{
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std::array<uint64, HISTORY_BINS> histogram{};
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};
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struct AutotuneContext
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{
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const int16 *m_sampleData;
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double pitchReference;
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SmpLength processLength;
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uint32 sampleFreq;
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};
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#if defined(MPT_ENABLE_ARCH_INTRINSICS_SSE2)
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static inline AutotuneHistogramEntry CalculateNoteHistogramSSE2(int note, AutotuneContext ctx)
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{
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const SmpLength autocorrShift = NoteToShift(ctx.sampleFreq, note, ctx.pitchReference);
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uint64 autocorrSum = 0;
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{
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const __m128i *normalData = reinterpret_cast<const __m128i *>(ctx.m_sampleData);
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const __m128i *shiftedData = reinterpret_cast<const __m128i *>(ctx.m_sampleData + autocorrShift);
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for(SmpLength i = ctx.processLength / 8; i != 0; i--)
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{
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__m128i normal = _mm_loadu_si128(normalData++);
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__m128i shifted = _mm_loadu_si128(shiftedData++);
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__m128i diff = _mm_sub_epi16(normal, shifted); // 8 16-bit differences
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__m128i squares = _mm_madd_epi16(diff, diff); // Multiply and add: 4 32-bit squares
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__m128i sum1 = _mm_shuffle_epi32(squares, _MM_SHUFFLE(0, 1, 2, 3)); // Move upper two integers to lower
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__m128i sum2 = _mm_add_epi32(squares, sum1); // Now we can add the (originally) upper two and lower two integers
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__m128i sum3 = _mm_shuffle_epi32(sum2, _MM_SHUFFLE(1, 1, 1, 1)); // Move the second-lowest integer to lowest position
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__m128i sum4 = _mm_add_epi32(sum2, sum3); // Add the two lowest positions
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autocorrSum += _mm_cvtsi128_si32(sum4);
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}
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}
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return {note % HISTORY_BINS, autocorrSum};
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}
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#endif
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static inline AutotuneHistogramEntry CalculateNoteHistogram(int note, AutotuneContext ctx)
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{
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const SmpLength autocorrShift = NoteToShift(ctx.sampleFreq, note, ctx.pitchReference);
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uint64 autocorrSum = 0;
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{
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const int16 *normalData = ctx.m_sampleData;
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const int16 *shiftedData = ctx.m_sampleData + autocorrShift;
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// Add up squared differences of all values
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for(SmpLength i = ctx.processLength; i != 0; i--, normalData++, shiftedData++)
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{
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autocorrSum += (*normalData - *shiftedData) * (*normalData - *shiftedData);
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}
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}
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return {note % HISTORY_BINS, autocorrSum};
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}
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static inline AutotuneHistogram operator+(AutotuneHistogram a, AutotuneHistogram b) noexcept
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{
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AutotuneHistogram result;
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for(std::size_t i = 0; i < HISTORY_BINS; ++i)
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{
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result.histogram[i] = a.histogram[i] + b.histogram[i];
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}
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return result;
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}
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static inline AutotuneHistogram & operator+=(AutotuneHistogram &a, AutotuneHistogram b) noexcept
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{
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for(std::size_t i = 0; i < HISTORY_BINS; ++i)
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{
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a.histogram[i] += b.histogram[i];
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}
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return a;
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}
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static inline AutotuneHistogram &operator+=(AutotuneHistogram &a, AutotuneHistogramEntry b) noexcept
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{
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a.histogram[b.index] += b.sum;
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return a;
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}
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struct AutotuneHistogramReduce
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{
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inline AutotuneHistogram operator()(AutotuneHistogram a, AutotuneHistogram b) noexcept
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{
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return a + b;
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}
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inline AutotuneHistogram operator()(AutotuneHistogramEntry a, AutotuneHistogramEntry b) noexcept
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{
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AutotuneHistogram result;
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result += a;
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result += b;
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return result;
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}
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inline AutotuneHistogram operator()(AutotuneHistogramEntry a, AutotuneHistogram b) noexcept
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{
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b += a;
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return b;
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}
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inline AutotuneHistogram operator()(AutotuneHistogram a, AutotuneHistogramEntry b) noexcept
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{
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a += b;
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return a;
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}
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};
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} // local
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bool Autotune::Apply(double pitchReference, int targetNote)
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{
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if(!CanApply())
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{
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return false;
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}
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const uint32 sampleFreq = m_sample.GetSampleRate(m_modType);
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// At the lowest frequency, we get the highest autocorrelation shift amount.
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const SmpLength maxShift = NoteToShift(sampleFreq, START_NOTE, pitchReference);
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if(!PrepareSample(maxShift))
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{
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return false;
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}
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// We don't process the autocorrelation overhead.
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const SmpLength processLength = m_sampleLength - maxShift;
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AutotuneContext ctx;
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ctx.m_sampleData = m_sampleData;
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ctx.pitchReference = pitchReference;
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ctx.processLength = processLength;
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ctx.sampleFreq = sampleFreq;
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// Note that we cannot use a fake integer iterator here because of the requirement on ForwardIterator to return a reference to the elements.
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std::array<int, END_NOTE - START_NOTE> notes;
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std::iota(notes.begin(), notes.end(), START_NOTE);
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AutotuneHistogram autocorr =
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#if defined(MPT_ENABLE_ARCH_INTRINSICS_SSE2)
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(CPU::HasFeatureSet(CPU::feature::sse2)) ? std::transform_reduce(std::execution::par_unseq, std::begin(notes), std::end(notes), AutotuneHistogram{}, AutotuneHistogramReduce{}, [ctx](int note) { return CalculateNoteHistogramSSE2(note, ctx); } ) :
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#endif
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std::transform_reduce(std::execution::par_unseq, std::begin(notes), std::end(notes), AutotuneHistogram{}, AutotuneHistogramReduce{}, [ctx](int note) { return CalculateNoteHistogram(note, ctx); } );
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// Interpolate the histogram...
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AutotuneHistogram interpolated;
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for(int i = 0; i < HISTORY_BINS; i++)
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{
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interpolated.histogram[i] = autocorr.histogram[i];
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const int kernelWidth = 4;
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for(int ki = kernelWidth; ki >= 0; ki--)
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{
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// Choose bins to interpolate with
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int left = i - ki;
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if(left < 0) left += HISTORY_BINS;
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int right = i + ki;
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if(right >= HISTORY_BINS) right -= HISTORY_BINS;
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interpolated.histogram[i] = interpolated.histogram[i] / 2 + (autocorr.histogram[left] + autocorr.histogram[right]) / 2;
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}
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}
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// ...and find global minimum
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int minimumBin = static_cast<int>(std::min_element(std::begin(interpolated.histogram), std::end(interpolated.histogram)) - std::begin(interpolated.histogram));
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// Center target notes around C
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if(targetNote >= 6)
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{
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targetNote -= 12;
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}
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// Center bins around target note
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minimumBin -= targetNote * BINS_PER_NOTE;
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if(minimumBin >= 6 * BINS_PER_NOTE)
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{
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minimumBin -= 12 * BINS_PER_NOTE;
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}
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minimumBin += targetNote * BINS_PER_NOTE;
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const double newFundamentalFreq = NoteToFrequency(static_cast<double>(69 - targetNote) + static_cast<double>(minimumBin) / BINS_PER_NOTE, pitchReference);
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if(const auto newFreq = mpt::saturate_round<uint32>(sampleFreq * pitchReference / newFundamentalFreq); newFreq != sampleFreq)
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m_sample.nC5Speed = newFreq;
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else
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return false;
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if((m_modType & (MOD_TYPE_XM | MOD_TYPE_MOD)))
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{
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m_sample.FrequencyToTranspose();
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if((m_modType & MOD_TYPE_MOD))
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{
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m_sample.RelativeTone = 0;
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}
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}
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return true;
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}
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/////////////////////////////////////////////////////////////
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// CAutotuneDlg
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int CAutotuneDlg::m_pitchReference = 440; // Pitch reference in Hz
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int CAutotuneDlg::m_targetNote = 0; // Target note (C- = 0, C# = 1, etc...)
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void CAutotuneDlg::DoDataExchange(CDataExchange* pDX)
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{
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CDialog::DoDataExchange(pDX);
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//{{AFX_DATA_MAP(CAutotuneDlg)
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DDX_Control(pDX, IDC_COMBO1, m_CbnNoteBox);
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//}}AFX_DATA_MAP
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}
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BOOL CAutotuneDlg::OnInitDialog()
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{
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CDialog::OnInitDialog();
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m_CbnNoteBox.ResetContent();
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for(int note = 0; note < 12; note++)
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{
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const int item = m_CbnNoteBox.AddString(mpt::ToCString(CSoundFile::GetDefaultNoteName(note)));
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m_CbnNoteBox.SetItemData(item, note);
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if(note == m_targetNote)
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{
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m_CbnNoteBox.SetCurSel(item);
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}
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}
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SetDlgItemInt(IDC_EDIT1, m_pitchReference, FALSE);
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return TRUE;
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}
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void CAutotuneDlg::OnOK()
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{
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int pitch = GetDlgItemInt(IDC_EDIT1);
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if(pitch <= 0)
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{
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MessageBeep(MB_ICONWARNING);
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return;
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}
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CDialog::OnOK();
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m_targetNote = (int)m_CbnNoteBox.GetItemData(m_CbnNoteBox.GetCurSel());
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m_pitchReference = pitch;
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}
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OPENMPT_NAMESPACE_END
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