mirror of https://github.com/axmolengine/axmol.git
223 lines
6.1 KiB
C++
223 lines
6.1 KiB
C++
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#include "polyphase_resampler.h"
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#include <algorithm>
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#include <cmath>
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#include "math_defs.h"
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#include "opthelpers.h"
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namespace {
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constexpr double Epsilon{1e-9};
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using uint = unsigned int;
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/* This is the normalized cardinal sine (sinc) function.
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*
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* sinc(x) = { 1, x = 0
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* { sin(pi x) / (pi x), otherwise.
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*/
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double Sinc(const double x)
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{
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if UNLIKELY(std::abs(x) < Epsilon)
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return 1.0;
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return std::sin(al::MathDefs<double>::Pi()*x) / (al::MathDefs<double>::Pi()*x);
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}
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/* The zero-order modified Bessel function of the first kind, used for the
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* Kaiser window.
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*
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* I_0(x) = sum_{k=0}^inf (1 / k!)^2 (x / 2)^(2 k)
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* = sum_{k=0}^inf ((x / 2)^k / k!)^2
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*/
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constexpr double BesselI_0(const double x)
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{
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// Start at k=1 since k=0 is trivial.
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const double x2{x/2.0};
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double term{1.0};
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double sum{1.0};
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int k{1};
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// Let the integration converge until the term of the sum is no longer
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// significant.
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double last_sum{};
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do {
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const double y{x2 / k};
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++k;
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last_sum = sum;
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term *= y * y;
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sum += term;
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} while(sum != last_sum);
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return sum;
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}
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/* Calculate a Kaiser window from the given beta value and a normalized k
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* [-1, 1].
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*
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* w(k) = { I_0(B sqrt(1 - k^2)) / I_0(B), -1 <= k <= 1
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* { 0, elsewhere.
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*
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* Where k can be calculated as:
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*
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* k = i / l, where -l <= i <= l.
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*
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* or:
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*
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* k = 2 i / M - 1, where 0 <= i <= M.
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*/
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double Kaiser(const double b, const double k)
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{
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if(!(k >= -1.0 && k <= 1.0))
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return 0.0;
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return BesselI_0(b * std::sqrt(1.0 - k*k)) / BesselI_0(b);
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}
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// Calculates the greatest common divisor of a and b.
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constexpr uint Gcd(uint x, uint y)
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{
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while(y > 0)
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{
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const uint z{y};
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y = x % y;
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x = z;
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}
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return x;
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}
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/* Calculates the size (order) of the Kaiser window. Rejection is in dB and
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* the transition width is normalized frequency (0.5 is nyquist).
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*
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* M = { ceil((r - 7.95) / (2.285 2 pi f_t)), r > 21
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* { ceil(5.79 / 2 pi f_t), r <= 21.
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*
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*/
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constexpr uint CalcKaiserOrder(const double rejection, const double transition)
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{
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const double w_t{2.0 * al::MathDefs<double>::Pi() * transition};
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if LIKELY(rejection > 21.0)
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return static_cast<uint>(std::ceil((rejection - 7.95) / (2.285 * w_t)));
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return static_cast<uint>(std::ceil(5.79 / w_t));
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}
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// Calculates the beta value of the Kaiser window. Rejection is in dB.
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constexpr double CalcKaiserBeta(const double rejection)
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{
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if LIKELY(rejection > 50.0)
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return 0.1102 * (rejection - 8.7);
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if(rejection >= 21.0)
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return (0.5842 * std::pow(rejection - 21.0, 0.4)) +
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(0.07886 * (rejection - 21.0));
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return 0.0;
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}
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/* Calculates a point on the Kaiser-windowed sinc filter for the given half-
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* width, beta, gain, and cutoff. The point is specified in non-normalized
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* samples, from 0 to M, where M = (2 l + 1).
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*
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* w(k) 2 p f_t sinc(2 f_t x)
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*
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* x -- centered sample index (i - l)
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* k -- normalized and centered window index (x / l)
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* w(k) -- window function (Kaiser)
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* p -- gain compensation factor when sampling
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* f_t -- normalized center frequency (or cutoff; 0.5 is nyquist)
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*/
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double SincFilter(const uint l, const double b, const double gain, const double cutoff,
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const uint i)
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{
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const double x{static_cast<double>(i) - l};
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return Kaiser(b, x / l) * 2.0 * gain * cutoff * Sinc(2.0 * cutoff * x);
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}
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} // namespace
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// Calculate the resampling metrics and build the Kaiser-windowed sinc filter
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// that's used to cut frequencies above the destination nyquist.
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void PPhaseResampler::init(const uint srcRate, const uint dstRate)
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{
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const uint gcd{Gcd(srcRate, dstRate)};
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mP = dstRate / gcd;
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mQ = srcRate / gcd;
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/* The cutoff is adjusted by half the transition width, so the transition
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* ends before the nyquist (0.5). Both are scaled by the downsampling
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* factor.
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*/
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double cutoff, width;
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if(mP > mQ)
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{
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cutoff = 0.475 / mP;
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width = 0.05 / mP;
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}
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else
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{
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cutoff = 0.475 / mQ;
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width = 0.05 / mQ;
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}
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// A rejection of -180 dB is used for the stop band. Round up when
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// calculating the left offset to avoid increasing the transition width.
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const uint l{(CalcKaiserOrder(180.0, width)+1) / 2};
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const double beta{CalcKaiserBeta(180.0)};
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mM = l*2 + 1;
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mL = l;
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mF.resize(mM);
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for(uint i{0};i < mM;i++)
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mF[i] = SincFilter(l, beta, mP, cutoff, i);
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}
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// Perform the upsample-filter-downsample resampling operation using a
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// polyphase filter implementation.
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void PPhaseResampler::process(const uint inN, const double *in, const uint outN, double *out)
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{
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if UNLIKELY(outN == 0)
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return;
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// Handle in-place operation.
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std::vector<double> workspace;
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double *work{out};
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if UNLIKELY(work == in)
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{
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workspace.resize(outN);
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work = workspace.data();
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}
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// Resample the input.
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const uint p{mP}, q{mQ}, m{mM}, l{mL};
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const double *f{mF.data()};
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for(uint i{0};i < outN;i++)
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{
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// Input starts at l to compensate for the filter delay. This will
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// drop any build-up from the first half of the filter.
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size_t j_f{(l + q*i) % p};
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size_t j_s{(l + q*i) / p};
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// Only take input when 0 <= j_s < inN.
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double r{0.0};
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if LIKELY(j_f < m)
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{
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size_t filt_len{(m-j_f+p-1) / p};
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if LIKELY(j_s+1 > inN)
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{
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size_t skip{std::min<size_t>(j_s+1 - inN, filt_len)};
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j_f += p*skip;
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j_s -= skip;
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filt_len -= skip;
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}
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if(size_t todo{std::min<size_t>(j_s+1, filt_len)})
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{
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do {
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r += f[j_f] * in[j_s];
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j_f += p;
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--j_s;
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} while(--todo);
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}
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}
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work[i] = r;
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}
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// Clean up after in-place operation.
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if(work != out)
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std::copy_n(work, outN, out);
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}
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