2019-08-15 09:33:00 -03:00
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/*
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* This file is free software: you can redistribute it and/or modify it
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* under the terms of the GNU General Public License as published by the
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* Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This file is distributed in the hope that it will be useful, but
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* WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
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* See the GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License along
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* with this program. If not, see <http://www.gnu.org/licenses/>.
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*
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* Code by Andy Piper
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*/
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#include <AP_HAL/AP_HAL.h>
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#include "AP_HAL_SITL.h"
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#include <AP_Math/AP_Math.h>
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#include <GCS_MAVLink/GCS.h>
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#include "DSP.h"
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#include <cmath>
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2020-03-05 17:54:00 -04:00
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#include <assert.h>
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2019-08-15 09:33:00 -03:00
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using namespace HALSITL;
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extern const AP_HAL::HAL& hal;
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// The algorithms originally came from betaflight but are now substantially modified based on theory and experiment.
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// https://holometer.fnal.gov/GH_FFT.pdf "Spectrum and spectral density estimation by the Discrete Fourier transform (DFT),
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// including a comprehensive list of window functions and some new flat-top windows." - Heinzel et. al is a great reference
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// for understanding the underlying theory although we do not use spectral density here since time resolution is equally
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// important as frequency resolution. Referred to as [Heinz] throughout the code.
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// initialize the FFT state machine
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AP_HAL::DSP::FFTWindowState* DSP::fft_init(uint16_t window_size, uint16_t sample_rate, uint8_t harmonics)
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{
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DSP::FFTWindowStateSITL* fft = new DSP::FFTWindowStateSITL(window_size, sample_rate, harmonics);
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if (fft == nullptr || fft->_hanning_window == nullptr || fft->_rfft_data == nullptr || fft->_freq_bins == nullptr || fft->_derivative_freq_bins == nullptr) {
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delete fft;
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return nullptr;
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}
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return fft;
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}
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// start an FFT analysis
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void DSP::fft_start(AP_HAL::DSP::FFTWindowState* state, FloatBuffer& samples, uint16_t advance)
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{
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step_hanning((FFTWindowStateSITL*)state, samples, advance);
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}
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// perform remaining steps of an FFT analysis
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uint16_t DSP::fft_analyse(AP_HAL::DSP::FFTWindowState* state, uint16_t start_bin, uint16_t end_bin, float noise_att_cutoff)
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{
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FFTWindowStateSITL* fft = (FFTWindowStateSITL*)state;
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step_fft(fft);
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step_cmplx_mag(fft, start_bin, end_bin, noise_att_cutoff);
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return step_calc_frequencies(fft, start_bin, end_bin);
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}
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// create an instance of the FFT state machine
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DSP::FFTWindowStateSITL::FFTWindowStateSITL(uint16_t window_size, uint16_t sample_rate, uint8_t harmonics)
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: AP_HAL::DSP::FFTWindowState::FFTWindowState(window_size, sample_rate, harmonics)
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{
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if (_freq_bins == nullptr || _hanning_window == nullptr || _rfft_data == nullptr || _derivative_freq_bins == nullptr) {
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GCS_SEND_TEXT(MAV_SEVERITY_WARNING, "Failed to allocate window for DSP");
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return;
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}
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buf = new complexf[window_size];
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}
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DSP::FFTWindowStateSITL::~FFTWindowStateSITL()
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{
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delete[] buf;
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}
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// step 1: filter the incoming samples through a Hanning window
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void DSP::step_hanning(FFTWindowStateSITL* fft, FloatBuffer& samples, uint16_t advance)
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{
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// 5us
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// apply hanning window to gyro samples and store result in _freq_bins
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// hanning starts and ends with 0, could be skipped for minor speed improvement
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uint32_t read_window = samples.peek(&fft->_freq_bins[0], fft->_window_size);
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assert(read_window == fft->_window_size);
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samples.advance(advance);
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mult_f32(&fft->_freq_bins[0], &fft->_hanning_window[0], &fft->_freq_bins[0], fft->_window_size);
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}
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// step 2: performm an in-place FFT on the windowed data
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void DSP::step_fft(FFTWindowStateSITL* fft)
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{
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for (uint16_t i = 0; i < fft->_window_size; i++) {
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fft->buf[i] = complexf(fft->_freq_bins[i], 0);
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}
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calculate_fft(fft->buf, fft->_window_size);
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for (uint16_t i = 0; i < fft->_bin_count; i++) {
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fft->_freq_bins[i] = std::norm(fft->buf[i]);
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}
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// components at the nyquist frequency are real only
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for (uint16_t i = 0, j = 0; i <= fft->_bin_count; i++, j += 2) {
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fft->_rfft_data[j] = fft->buf[i].real();
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fft->_rfft_data[j+1] = fft->buf[i].imag();
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}
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}
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void DSP::mult_f32(const float* v1, const float* v2, float* vout, uint16_t len)
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{
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for (uint16_t i = 0; i < len; i++) {
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vout[i] = v1[i] * v2[i];
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}
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}
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void DSP::vector_max_float(const float* vin, uint16_t len, float* maxValue, uint16_t* maxIndex) const
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{
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*maxValue = vin[0];
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*maxIndex = 0;
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for (uint16_t i = 1; i < len; i++) {
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if (vin[i] > *maxValue) {
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*maxValue = vin[i];
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*maxIndex = i;
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}
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}
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}
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void DSP::vector_scale_float(const float* vin, float scale, float* vout, uint16_t len) const
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{
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for (uint16_t i = 0; i < len; i++) {
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vout[i] = vin[i] * scale;
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}
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}
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float DSP::vector_mean_float(const float* vin, uint16_t len) const
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{
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float mean_value = 0.0f;
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for (uint16_t i = 0; i < len; i++) {
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mean_value += vin[i];
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}
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mean_value /= len;
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return mean_value;
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}
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2019-08-15 09:33:00 -03:00
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// simple integer log2
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static uint16_t fft_log2(uint16_t n)
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{
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uint16_t k = n, i = 0;
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while (k) {
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k >>= 1;
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i++;
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}
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return i - 1;
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}
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// calculate the in-place FFT of the input using the Cooley–Tukey algorithm
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// this is a translation of Ron Nicholson's version in http://www.nicholson.com/dsp.fft1.html
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void DSP::calculate_fft(complexf *samples, uint16_t fftlen)
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{
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uint16_t m = fft_log2(fftlen);
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// shuffle data using bit reversed addressing ***
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for (uint16_t k = 0; k < fftlen; k++) {
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// generate a bit reversed address for samples[k] ***
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uint16_t ki = k, kr = 0;
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for (uint16_t i=1; i<=m; i++) {
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kr <<= 1; // left shift result kr by 1 bit
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if (ki % 2 == 1) {
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kr++;
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}
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ki >>= 1; // right shift temp ki by 1 bit
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}
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// swap data samples[k] to bit reversed address samples[kr]
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if (kr > k) {
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complexf t = samples[kr];
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samples[kr] = samples[k];
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samples[k] = t;
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}
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}
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// do fft butterflys in place
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uint16_t istep = 2;
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while (istep <= fftlen) {// layers 2,4,8,16, ... ,n
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uint16_t is2 = istep / 2;
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uint16_t astep = fftlen / istep;
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for (uint16_t km = 0; km < is2; km++) { // outer row loop
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uint16_t a = km * astep; // twiddle angle index
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complexf w(sinf(2 * M_PI * (a+(fftlen/4)) / fftlen), sinf(2 * M_PI * a / fftlen));
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for (uint16_t ki = 0; ki <= (fftlen - istep); ki += istep) { // inner column loop
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uint16_t i = km + ki;
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uint16_t j = is2 + i;
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complexf t = w * samples[j];
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complexf q = samples[i];
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samples[j] = q - t;
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samples[i] = q + t;
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}
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}
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istep <<= 1;
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}
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}
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